Fork legacy ril into cuttlefish to support radio hal 1.4.
Use forked ril stack in cuttlefish ril instead of soon deprecated
one under hardware/ril/libril after platform version P.
Test: Vts
Change-Id: Ifb4b750c867af6833b674704401b328b153bf9c2
diff --git a/guest/hals/ril/Android.mk b/guest/hals/ril/Android.mk
index 56e9779..71bbd42 100644
--- a/guest/hals/ril/Android.mk
+++ b/guest/hals/ril/Android.mk
@@ -23,7 +23,6 @@
liblog \
libcutils \
libutils \
- libril \
libcuttlefish_fs \
cuttlefish_net \
cuttlefish_auto_resources \
@@ -39,6 +38,59 @@
-Werror \
$(VSOC_VERSION_CFLAGS)
+# only for PLATFORM_VERSION greater or equal to Q
+ifeq ($(PLATFORM_VERSION), $(word 1, $(sort Q $(PLATFORM_VERSION))))
+ $(info Use updated hal for PLATFORM VERSION = $(PLATFORM_VERSION))
+
+ LOCAL_SRC_FILES += \
+ libril/ril.cpp \
+ libril/ril_service.cpp \
+ libril/ril_event.cpp \
+ libril/RilSapSocket.cpp \
+ libril/sap_service.cpp
+
+ LOCAL_SHARED_LIBRARIES += \
+ libhardware_legacy \
+ libhidlbase \
+ libhidltransport \
+ libhwbinder \
+ librilutils \
+ android.hardware.radio@1.0 \
+ android.hardware.radio@1.1 \
+ android.hardware.radio.deprecated@1.0 \
+ android.hardware.radio@1.2 \
+ android.hardware.radio@1.3 \
+ android.hardware.radio@1.4
+
+
+ LOCAL_STATIC_LIBRARIES := \
+ libprotobuf-c-nano-enable_malloc \
+
+ LOCAL_C_INCLUDES += \
+ external/nanopb-c \
+ hardware/ril/include \
+ hardware/ril/libril
+
+ LOCAL_CFLAGS += \
+ -Wextra \
+ -Wno-unused-parameter
+
+ LOCAL_EXPORT_C_INCLUDE_DIRS := $(LOCAL_PATH)
+
+ ifeq ($(SIM_COUNT), 2)
+ LOCAL_CFLAGS += -DANDROID_MULTI_SIM -DDSDA_RILD1
+ LOCAL_CFLAGS += -DANDROID_SIM_COUNT_2
+ endif
+
+ ifneq ($(DISABLE_RILD_OEM_HOOK),)
+ LOCAL_CFLAGS += -DOEM_HOOK_DISABLED
+ endif
+else
+ $(info Use deprecated libril)
+ LOCAL_SHARED_LIBRARIES += \
+ libril
+endif
+
LOCAL_MODULE:= libvsoc-ril
LOCAL_MODULE_TAGS := optional
LOCAL_VENDOR_MODULE := true
diff --git a/guest/hals/ril/libril/RilSapSocket.cpp b/guest/hals/ril/libril/RilSapSocket.cpp
new file mode 100644
index 0000000..3465807
--- /dev/null
+++ b/guest/hals/ril/libril/RilSapSocket.cpp
@@ -0,0 +1,295 @@
+/*
+* Copyright (C) 2014 The Android Open Source Project
+*
+* Licensed under the Apache License, Version 2.0 (the "License");
+* you may not use this file except in compliance with the License.
+* You may obtain a copy of the License at
+*
+* http://www.apache.org/licenses/LICENSE-2.0
+*
+* Unless required by applicable law or agreed to in writing, software
+* distributed under the License is distributed on an "AS IS" BASIS,
+* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+* See the License for the specific language governing permissions and
+* limitations under the License.
+*/
+
+#define __STDC_LIMIT_MACROS
+#include <stdint.h>
+#define RIL_SHLIB
+#include "RilSapSocket.h"
+#include "pb_decode.h"
+#include "pb_encode.h"
+#undef LOG_TAG
+#define LOG_TAG "RIL_UIM_SOCKET"
+#include <utils/Log.h>
+#include <arpa/inet.h>
+#include <errno.h>
+#include <sap_service.h>
+#include <guest/hals/ril/libril/ril.h>
+
+static RilSapSocket::RilSapSocketList *head = NULL;
+
+extern "C" void
+RIL_requestTimedCallback (RIL_TimedCallback callback, void *param,
+ const struct timeval *relativeTime);
+
+struct RIL_Env RilSapSocket::uimRilEnv = {
+ .OnRequestComplete = RilSapSocket::sOnRequestComplete,
+ .OnUnsolicitedResponse = RilSapSocket::sOnUnsolicitedResponse,
+ .RequestTimedCallback = RIL_requestTimedCallback
+};
+
+void RilSapSocket::sOnRequestComplete (RIL_Token t,
+ RIL_Errno e,
+ void *response,
+ size_t responselen) {
+ RilSapSocket *sap_socket;
+ SapSocketRequest *request = (SapSocketRequest*) t;
+
+ RLOGD("Socket id:%d", request->socketId);
+
+ sap_socket = getSocketById(request->socketId);
+
+ if (sap_socket) {
+ sap_socket->onRequestComplete(t,e,response,responselen);
+ } else {
+ RLOGE("Invalid socket id");
+ if (request->curr) {
+ free(request->curr);
+ }
+ free(request);
+ }
+}
+
+#if defined(ANDROID_MULTI_SIM)
+void RilSapSocket::sOnUnsolicitedResponse(int unsolResponse,
+ const void *data,
+ size_t datalen,
+ RIL_SOCKET_ID socketId) {
+ RilSapSocket *sap_socket = getSocketById(socketId);
+ if (sap_socket) {
+ sap_socket->onUnsolicitedResponse(unsolResponse, (void *)data, datalen);
+ }
+}
+#else
+void RilSapSocket::sOnUnsolicitedResponse(int unsolResponse,
+ const void *data,
+ size_t datalen) {
+ RilSapSocket *sap_socket = getSocketById(RIL_SOCKET_1);
+ if(sap_socket){
+ sap_socket->onUnsolicitedResponse(unsolResponse, (void *)data, datalen);
+ }
+}
+#endif
+
+void RilSapSocket::printList() {
+ RilSapSocketList *current = head;
+ RLOGD("Printing socket list");
+ while(NULL != current) {
+ RLOGD("SocketName:%s",current->socket->name);
+ RLOGD("Socket id:%d",current->socket->id);
+ current = current->next;
+ }
+}
+
+RilSapSocket *RilSapSocket::getSocketById(RIL_SOCKET_ID socketId) {
+ RilSapSocket *sap_socket;
+ RilSapSocketList *current = head;
+
+ RLOGD("Entered getSocketById");
+ printList();
+
+ while(NULL != current) {
+ if(socketId == current->socket->id) {
+ sap_socket = current->socket;
+ return sap_socket;
+ }
+ current = current->next;
+ }
+ return NULL;
+}
+
+void RilSapSocket::initSapSocket(const char *socketName,
+ const RIL_RadioFunctions *uimFuncs) {
+
+ if (strcmp(socketName, RIL1_SERVICE_NAME) == 0) {
+ if(!SocketExists(socketName)) {
+ addSocketToList(socketName, RIL_SOCKET_1, uimFuncs);
+ }
+ }
+
+#if (SIM_COUNT >= 2)
+ if (strcmp(socketName, RIL2_SERVICE_NAME) == 0) {
+ if(!SocketExists(socketName)) {
+ addSocketToList(socketName, RIL_SOCKET_2, uimFuncs);
+ }
+ }
+#endif
+
+#if (SIM_COUNT >= 3)
+ if (strcmp(socketName, RIL3_SERVICE_NAME) == 0) {
+ if(!SocketExists(socketName)) {
+ addSocketToList(socketName, RIL_SOCKET_3, uimFuncs);
+ }
+ }
+#endif
+
+#if (SIM_COUNT >= 4)
+ if (strcmp(socketName, RIL4_SERVICE_NAME) == 0) {
+ if(!SocketExists(socketName)) {
+ addSocketToList(socketName, RIL_SOCKET_4, uimFuncs);
+ }
+ }
+#endif
+}
+
+void RilSapSocket::addSocketToList(const char *socketName, RIL_SOCKET_ID socketid,
+ const RIL_RadioFunctions *uimFuncs) {
+ RilSapSocket* socket = NULL;
+ RilSapSocketList *current;
+
+ if(!SocketExists(socketName)) {
+ socket = new RilSapSocket(socketName, socketid, uimFuncs);
+ RilSapSocketList* listItem = (RilSapSocketList*)malloc(sizeof(RilSapSocketList));
+ if (!listItem) {
+ RLOGE("addSocketToList: OOM");
+ delete socket;
+ return;
+ }
+ listItem->socket = socket;
+ listItem->next = NULL;
+
+ RLOGD("Adding socket with id: %d", socket->id);
+
+ if(NULL == head) {
+ head = listItem;
+ head->next = NULL;
+ }
+ else {
+ current = head;
+ while(NULL != current->next) {
+ current = current->next;
+ }
+ current->next = listItem;
+ }
+ }
+}
+
+bool RilSapSocket::SocketExists(const char *socketName) {
+ RilSapSocketList* current = head;
+
+ while(NULL != current) {
+ if(strcmp(current->socket->name, socketName) == 0) {
+ return true;
+ }
+ current = current->next;
+ }
+ return false;
+}
+
+RilSapSocket::RilSapSocket(const char *socketName,
+ RIL_SOCKET_ID socketId,
+ const RIL_RadioFunctions *inputUimFuncs):
+ RilSocket(socketName, socketId) {
+ if (inputUimFuncs) {
+ uimFuncs = inputUimFuncs;
+ }
+}
+
+void RilSapSocket::dispatchRequest(MsgHeader *req) {
+ // SapSocketRequest will be deallocated in onRequestComplete()
+ SapSocketRequest* currRequest=(SapSocketRequest*)malloc(sizeof(SapSocketRequest));
+ if (!currRequest) {
+ RLOGE("dispatchRequest: OOM");
+ // Free MsgHeader allocated in pushRecord()
+ free(req);
+ return;
+ }
+ currRequest->token = req->token;
+ currRequest->curr = req;
+ currRequest->p_next = NULL;
+ currRequest->socketId = id;
+
+ pendingResponseQueue.enqueue(currRequest);
+
+ if (uimFuncs) {
+ RLOGI("RilSapSocket::dispatchRequest [%d] > SAP REQUEST type: %d. id: %d. error: %d, \
+ token 0x%p",
+ req->token,
+ req->type,
+ req->id,
+ req->error,
+ currRequest );
+
+#if defined(ANDROID_MULTI_SIM)
+ uimFuncs->onRequest(req->id, req->payload->bytes, req->payload->size, currRequest, id);
+#else
+ uimFuncs->onRequest(req->id, req->payload->bytes, req->payload->size, currRequest);
+#endif
+ }
+}
+
+void RilSapSocket::onRequestComplete(RIL_Token t, RIL_Errno e, void *response,
+ size_t response_len) {
+ SapSocketRequest* request= (SapSocketRequest*)t;
+
+ if (!request || !request->curr) {
+ RLOGE("RilSapSocket::onRequestComplete: request/request->curr is NULL");
+ return;
+ }
+
+ MsgHeader *hdr = request->curr;
+
+ MsgHeader rsp;
+ rsp.token = request->curr->token;
+ rsp.type = MsgType_RESPONSE;
+ rsp.id = request->curr->id;
+ rsp.error = (Error)e;
+ rsp.payload = (pb_bytes_array_t *)calloc(1, sizeof(pb_bytes_array_t) + response_len);
+ if (!rsp.payload) {
+ RLOGE("onRequestComplete: OOM");
+ } else {
+ if (response && response_len > 0) {
+ memcpy(rsp.payload->bytes, response, response_len);
+ rsp.payload->size = response_len;
+ } else {
+ rsp.payload->size = 0;
+ }
+
+ RLOGE("RilSapSocket::onRequestComplete: Token:%d, MessageId:%d ril token 0x%p",
+ hdr->token, hdr->id, t);
+
+ sap::processResponse(&rsp, this);
+ free(rsp.payload);
+ }
+
+ // Deallocate SapSocketRequest
+ if(!pendingResponseQueue.checkAndDequeue(hdr->id, hdr->token)) {
+ RLOGE("Token:%d, MessageId:%d", hdr->token, hdr->id);
+ RLOGE ("RilSapSocket::onRequestComplete: invalid Token or Message Id");
+ }
+
+ // Deallocate MsgHeader
+ free(hdr);
+}
+
+void RilSapSocket::onUnsolicitedResponse(int unsolResponse, void *data, size_t datalen) {
+ if (data && datalen > 0) {
+ pb_bytes_array_t *payload = (pb_bytes_array_t *)calloc(1,
+ sizeof(pb_bytes_array_t) + datalen);
+ if (!payload) {
+ RLOGE("onUnsolicitedResponse: OOM");
+ return;
+ }
+ memcpy(payload->bytes, data, datalen);
+ payload->size = datalen;
+ MsgHeader rsp;
+ rsp.payload = payload;
+ rsp.type = MsgType_UNSOL_RESPONSE;
+ rsp.id = (MsgId)unsolResponse;
+ rsp.error = Error_RIL_E_SUCCESS;
+ sap::processUnsolResponse(&rsp, this);
+ free(payload);
+ }
+}
diff --git a/guest/hals/ril/libril/ril.cpp b/guest/hals/ril/libril/ril.cpp
new file mode 100644
index 0000000..58a984d
--- /dev/null
+++ b/guest/hals/ril/libril/ril.cpp
@@ -0,0 +1,1247 @@
+/* //guest/hals/ril/ril.cpp
+**
+** Copyright 2006, The Android Open Source Project
+**
+** Licensed under the Apache License, Version 2.0 (the "License");
+** you may not use this file except in compliance with the License.
+** You may obtain a copy of the License at
+**
+** http://www.apache.org/licenses/LICENSE-2.0
+**
+** Unless required by applicable law or agreed to in writing, software
+** distributed under the License is distributed on an "AS IS" BASIS,
+** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+** See the License for the specific language governing permissions and
+** limitations under the License.
+*/
+
+#define LOG_TAG "RILC"
+
+#include <hardware_legacy/power.h>
+#include <guest/hals/ril/libril/ril.h>
+#include <telephony/ril_cdma_sms.h>
+#include <cutils/sockets.h>
+#include <cutils/jstring.h>
+#include <telephony/record_stream.h>
+#include <utils/Log.h>
+#include <utils/SystemClock.h>
+#include <pthread.h>
+#include <cutils/jstring.h>
+#include <sys/types.h>
+#include <sys/limits.h>
+#include <sys/system_properties.h>
+#include <pwd.h>
+#include <stdio.h>
+#include <stdlib.h>
+#include <stdarg.h>
+#include <string.h>
+#include <unistd.h>
+#include <fcntl.h>
+#include <time.h>
+#include <errno.h>
+#include <assert.h>
+#include <ctype.h>
+#include <sys/un.h>
+#include <assert.h>
+#include <netinet/in.h>
+#include <cutils/properties.h>
+#include <RilSapSocket.h>
+#include <guest/hals/ril/libril/ril_service.h>
+#include <sap_service.h>
+
+extern "C" void
+RIL_onRequestComplete(RIL_Token t, RIL_Errno e, void *response, size_t responselen);
+
+extern "C" void
+RIL_onRequestAck(RIL_Token t);
+namespace android {
+
+#define PHONE_PROCESS "radio"
+#define BLUETOOTH_PROCESS "bluetooth"
+
+#define ANDROID_WAKE_LOCK_NAME "radio-interface"
+
+#define ANDROID_WAKE_LOCK_SECS 0
+#define ANDROID_WAKE_LOCK_USECS 200000
+
+#define PROPERTY_RIL_IMPL "gsm.version.ril-impl"
+
+// match with constant in RIL.java
+#define MAX_COMMAND_BYTES (8 * 1024)
+
+// Basically: memset buffers that the client library
+// shouldn't be using anymore in an attempt to find
+// memory usage issues sooner.
+#define MEMSET_FREED 1
+
+#define NUM_ELEMS(a) (sizeof (a) / sizeof (a)[0])
+
+/* Negative values for private RIL errno's */
+#define RIL_ERRNO_INVALID_RESPONSE (-1)
+#define RIL_ERRNO_NO_MEMORY (-12)
+
+// request, response, and unsolicited msg print macro
+#define PRINTBUF_SIZE 8096
+
+enum WakeType {DONT_WAKE, WAKE_PARTIAL};
+
+typedef struct {
+ int requestNumber;
+ int (*responseFunction) (int slotId, int responseType, int token,
+ RIL_Errno e, void *response, size_t responselen);
+ WakeType wakeType;
+} UnsolResponseInfo;
+
+typedef struct UserCallbackInfo {
+ RIL_TimedCallback p_callback;
+ void *userParam;
+ struct ril_event event;
+ struct UserCallbackInfo *p_next;
+} UserCallbackInfo;
+
+extern "C" const char * failCauseToString(RIL_Errno);
+extern "C" const char * callStateToString(RIL_CallState);
+extern "C" const char * radioStateToString(RIL_RadioState);
+extern "C" const char * rilSocketIdToString(RIL_SOCKET_ID socket_id);
+
+extern "C"
+char ril_service_name_base[MAX_SERVICE_NAME_LENGTH] = RIL_SERVICE_NAME_BASE;
+extern "C"
+char ril_service_name[MAX_SERVICE_NAME_LENGTH] = RIL1_SERVICE_NAME;
+/*******************************************************************/
+
+RIL_RadioFunctions s_callbacks = {0, NULL, NULL, NULL, NULL, NULL};
+static int s_registerCalled = 0;
+
+static pthread_t s_tid_dispatch;
+static int s_started = 0;
+
+static int s_fdWakeupRead;
+static int s_fdWakeupWrite;
+
+int s_wakelock_count = 0;
+
+static struct ril_event s_wakeupfd_event;
+
+static pthread_mutex_t s_pendingRequestsMutex = PTHREAD_MUTEX_INITIALIZER;
+static pthread_mutex_t s_wakeLockCountMutex = PTHREAD_MUTEX_INITIALIZER;
+static RequestInfo *s_pendingRequests = NULL;
+
+#if (SIM_COUNT >= 2)
+static pthread_mutex_t s_pendingRequestsMutex_socket2 = PTHREAD_MUTEX_INITIALIZER;
+static RequestInfo *s_pendingRequests_socket2 = NULL;
+#endif
+
+#if (SIM_COUNT >= 3)
+static pthread_mutex_t s_pendingRequestsMutex_socket3 = PTHREAD_MUTEX_INITIALIZER;
+static RequestInfo *s_pendingRequests_socket3 = NULL;
+#endif
+
+#if (SIM_COUNT >= 4)
+static pthread_mutex_t s_pendingRequestsMutex_socket4 = PTHREAD_MUTEX_INITIALIZER;
+static RequestInfo *s_pendingRequests_socket4 = NULL;
+#endif
+
+static const struct timeval TIMEVAL_WAKE_TIMEOUT = {ANDROID_WAKE_LOCK_SECS,ANDROID_WAKE_LOCK_USECS};
+
+
+static pthread_mutex_t s_startupMutex = PTHREAD_MUTEX_INITIALIZER;
+static pthread_cond_t s_startupCond = PTHREAD_COND_INITIALIZER;
+
+static UserCallbackInfo *s_last_wake_timeout_info = NULL;
+
+static void *s_lastNITZTimeData = NULL;
+static size_t s_lastNITZTimeDataSize;
+
+#if RILC_LOG
+ static char printBuf[PRINTBUF_SIZE];
+#endif
+
+/*******************************************************************/
+static void grabPartialWakeLock();
+void releaseWakeLock();
+static void wakeTimeoutCallback(void *);
+
+#ifdef RIL_SHLIB
+#if defined(ANDROID_MULTI_SIM)
+extern "C" void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen, RIL_SOCKET_ID socket_id);
+#else
+extern "C" void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen);
+#endif
+#endif
+
+#if defined(ANDROID_MULTI_SIM)
+#define RIL_UNSOL_RESPONSE(a, b, c, d) RIL_onUnsolicitedResponse((a), (b), (c), (d))
+#else
+#define RIL_UNSOL_RESPONSE(a, b, c, d) RIL_onUnsolicitedResponse((a), (b), (c))
+#endif
+
+static UserCallbackInfo * internalRequestTimedCallback
+ (RIL_TimedCallback callback, void *param,
+ const struct timeval *relativeTime);
+
+/** Index == requestNumber */
+static CommandInfo s_commands[] = {
+#include "ril_commands.h"
+};
+
+static UnsolResponseInfo s_unsolResponses[] = {
+#include "ril_unsol_commands.h"
+};
+
+char * RIL_getServiceName() {
+ return ril_service_name;
+}
+
+RequestInfo *
+addRequestToList(int serial, int slotId, int request) {
+ RequestInfo *pRI;
+ int ret;
+ RIL_SOCKET_ID socket_id = (RIL_SOCKET_ID) slotId;
+ /* Hook for current context */
+ /* pendingRequestsMutextHook refer to &s_pendingRequestsMutex */
+ pthread_mutex_t* pendingRequestsMutexHook = &s_pendingRequestsMutex;
+ /* pendingRequestsHook refer to &s_pendingRequests */
+ RequestInfo** pendingRequestsHook = &s_pendingRequests;
+
+#if (SIM_COUNT >= 2)
+ if (socket_id == RIL_SOCKET_2) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket2;
+ pendingRequestsHook = &s_pendingRequests_socket2;
+ }
+#if (SIM_COUNT >= 3)
+ else if (socket_id == RIL_SOCKET_3) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket3;
+ pendingRequestsHook = &s_pendingRequests_socket3;
+ }
+#endif
+#if (SIM_COUNT >= 4)
+ else if (socket_id == RIL_SOCKET_4) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket4;
+ pendingRequestsHook = &s_pendingRequests_socket4;
+ }
+#endif
+#endif
+
+ pRI = (RequestInfo *)calloc(1, sizeof(RequestInfo));
+ if (pRI == NULL) {
+ RLOGE("Memory allocation failed for request %s", requestToString(request));
+ return NULL;
+ }
+
+ pRI->token = serial;
+ pRI->pCI = &(s_commands[request]);
+ pRI->socket_id = socket_id;
+
+ ret = pthread_mutex_lock(pendingRequestsMutexHook);
+ assert (ret == 0);
+
+ pRI->p_next = *pendingRequestsHook;
+ *pendingRequestsHook = pRI;
+
+ ret = pthread_mutex_unlock(pendingRequestsMutexHook);
+ assert (ret == 0);
+
+ return pRI;
+}
+
+static void triggerEvLoop() {
+ int ret;
+ if (!pthread_equal(pthread_self(), s_tid_dispatch)) {
+ /* trigger event loop to wakeup. No reason to do this,
+ * if we're in the event loop thread */
+ do {
+ ret = write (s_fdWakeupWrite, " ", 1);
+ } while (ret < 0 && errno == EINTR);
+ }
+}
+
+static void rilEventAddWakeup(struct ril_event *ev) {
+ ril_event_add(ev);
+ triggerEvLoop();
+}
+
+/**
+ * A write on the wakeup fd is done just to pop us out of select()
+ * We empty the buffer here and then ril_event will reset the timers on the
+ * way back down
+ */
+static void processWakeupCallback(int fd, short flags, void *param) {
+ char buff[16];
+ int ret;
+
+ RLOGV("processWakeupCallback");
+
+ /* empty our wakeup socket out */
+ do {
+ ret = read(s_fdWakeupRead, &buff, sizeof(buff));
+ } while (ret > 0 || (ret < 0 && errno == EINTR));
+}
+
+static void resendLastNITZTimeData(RIL_SOCKET_ID socket_id) {
+ if (s_lastNITZTimeData != NULL) {
+ int responseType = (s_callbacks.version >= 13)
+ ? RESPONSE_UNSOLICITED_ACK_EXP
+ : RESPONSE_UNSOLICITED;
+ // acquire read lock for the service before calling nitzTimeReceivedInd() since it reads
+ // nitzTimeReceived in ril_service
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock(
+ (int) socket_id);
+ int rwlockRet = pthread_rwlock_rdlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+
+ int ret = radio_1_4::nitzTimeReceivedInd(
+ (int)socket_id, responseType, 0,
+ RIL_E_SUCCESS, s_lastNITZTimeData, s_lastNITZTimeDataSize);
+ if (ret == 0) {
+ free(s_lastNITZTimeData);
+ s_lastNITZTimeData = NULL;
+ }
+
+ rwlockRet = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+ }
+}
+
+void onNewCommandConnect(RIL_SOCKET_ID socket_id) {
+ // Inform we are connected and the ril version
+ int rilVer = s_callbacks.version;
+ RIL_UNSOL_RESPONSE(RIL_UNSOL_RIL_CONNECTED,
+ &rilVer, sizeof(rilVer), socket_id);
+
+ // implicit radio state changed
+ RIL_UNSOL_RESPONSE(RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED,
+ NULL, 0, socket_id);
+
+ // Send last NITZ time data, in case it was missed
+ if (s_lastNITZTimeData != NULL) {
+ resendLastNITZTimeData(socket_id);
+ }
+
+ // Get version string
+ if (s_callbacks.getVersion != NULL) {
+ const char *version;
+ version = s_callbacks.getVersion();
+ RLOGI("RIL Daemon version: %s\n", version);
+
+ property_set(PROPERTY_RIL_IMPL, version);
+ } else {
+ RLOGI("RIL Daemon version: unavailable\n");
+ property_set(PROPERTY_RIL_IMPL, "unavailable");
+ }
+
+}
+
+static void userTimerCallback (int fd, short flags, void *param) {
+ UserCallbackInfo *p_info;
+
+ p_info = (UserCallbackInfo *)param;
+
+ p_info->p_callback(p_info->userParam);
+
+
+ // FIXME generalize this...there should be a cancel mechanism
+ if (s_last_wake_timeout_info != NULL && s_last_wake_timeout_info == p_info) {
+ s_last_wake_timeout_info = NULL;
+ }
+
+ free(p_info);
+}
+
+
+static void *
+eventLoop(void *param) {
+ int ret;
+ int filedes[2];
+
+ ril_event_init();
+
+ pthread_mutex_lock(&s_startupMutex);
+
+ s_started = 1;
+ pthread_cond_broadcast(&s_startupCond);
+
+ pthread_mutex_unlock(&s_startupMutex);
+
+ ret = pipe(filedes);
+
+ if (ret < 0) {
+ RLOGE("Error in pipe() errno:%d", errno);
+ return NULL;
+ }
+
+ s_fdWakeupRead = filedes[0];
+ s_fdWakeupWrite = filedes[1];
+
+ fcntl(s_fdWakeupRead, F_SETFL, O_NONBLOCK);
+
+ ril_event_set (&s_wakeupfd_event, s_fdWakeupRead, true,
+ processWakeupCallback, NULL);
+
+ rilEventAddWakeup (&s_wakeupfd_event);
+
+ // Only returns on error
+ ril_event_loop();
+ RLOGE ("error in event_loop_base errno:%d", errno);
+ // kill self to restart on error
+ kill(0, SIGKILL);
+
+ return NULL;
+}
+
+extern "C" void
+RIL_startEventLoop(void) {
+ /* spin up eventLoop thread and wait for it to get started */
+ s_started = 0;
+ pthread_mutex_lock(&s_startupMutex);
+
+ pthread_attr_t attr;
+ pthread_attr_init(&attr);
+ pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);
+
+ int result = pthread_create(&s_tid_dispatch, &attr, eventLoop, NULL);
+ if (result != 0) {
+ RLOGE("Failed to create dispatch thread: %s", strerror(result));
+ goto done;
+ }
+
+ while (s_started == 0) {
+ pthread_cond_wait(&s_startupCond, &s_startupMutex);
+ }
+
+done:
+ pthread_mutex_unlock(&s_startupMutex);
+}
+
+// Used for testing purpose only.
+extern "C" void RIL_setcallbacks (const RIL_RadioFunctions *callbacks) {
+ memcpy(&s_callbacks, callbacks, sizeof (RIL_RadioFunctions));
+}
+
+extern "C" void
+RIL_register (const RIL_RadioFunctions *callbacks) {
+ RLOGI("SIM_COUNT: %d", SIM_COUNT);
+
+ if (callbacks == NULL) {
+ RLOGE("RIL_register: RIL_RadioFunctions * null");
+ return;
+ }
+ if (callbacks->version < RIL_VERSION_MIN) {
+ RLOGE("RIL_register: version %d is to old, min version is %d",
+ callbacks->version, RIL_VERSION_MIN);
+ return;
+ }
+
+ RLOGD("RIL_register: Vsoc RIL version %d", callbacks->version);
+
+ if (s_registerCalled > 0) {
+ RLOGE("RIL_register has been called more than once. "
+ "Subsequent call ignored");
+ return;
+ }
+
+ memcpy(&s_callbacks, callbacks, sizeof (RIL_RadioFunctions));
+
+ s_registerCalled = 1;
+
+ RLOGI("s_registerCalled flag set, %d", s_started);
+ // Little self-check
+
+ for (int i = 0; i < (int)NUM_ELEMS(s_commands); i++) {
+ assert(i == s_commands[i].requestNumber);
+ }
+
+ for (int i = 0; i < (int)NUM_ELEMS(s_unsolResponses); i++) {
+ assert(i + RIL_UNSOL_RESPONSE_BASE
+ == s_unsolResponses[i].requestNumber);
+ }
+
+ radio_1_4::registerService(&s_callbacks, s_commands);
+ RLOGI("RILHIDL called registerService");
+
+}
+
+extern "C" void
+RIL_register_socket (const RIL_RadioFunctions *(*Init)(const struct RIL_Env *, int, char **),
+ RIL_SOCKET_TYPE socketType, int argc, char **argv) {
+
+ const RIL_RadioFunctions* UimFuncs = NULL;
+
+ if(Init) {
+ UimFuncs = Init(&RilSapSocket::uimRilEnv, argc, argv);
+
+ switch(socketType) {
+ case RIL_SAP_SOCKET:
+ RilSapSocket::initSapSocket(RIL1_SERVICE_NAME, UimFuncs);
+
+#if (SIM_COUNT >= 2)
+ RilSapSocket::initSapSocket(RIL2_SERVICE_NAME, UimFuncs);
+#endif
+
+#if (SIM_COUNT >= 3)
+ RilSapSocket::initSapSocket(RIL3_SERVICE_NAME, UimFuncs);
+#endif
+
+#if (SIM_COUNT >= 4)
+ RilSapSocket::initSapSocket(RIL4_SERVICE_NAME, UimFuncs);
+#endif
+ break;
+ default:;
+ }
+
+ RLOGI("RIL_register_socket: calling registerService");
+ sap::registerService(UimFuncs);
+ }
+}
+
+// Check and remove RequestInfo if its a response and not just ack sent back
+static int
+checkAndDequeueRequestInfoIfAck(struct RequestInfo *pRI, bool isAck) {
+ int ret = 0;
+ /* Hook for current context
+ pendingRequestsMutextHook refer to &s_pendingRequestsMutex */
+ pthread_mutex_t* pendingRequestsMutexHook = &s_pendingRequestsMutex;
+ /* pendingRequestsHook refer to &s_pendingRequests */
+ RequestInfo ** pendingRequestsHook = &s_pendingRequests;
+
+ if (pRI == NULL) {
+ return 0;
+ }
+
+#if (SIM_COUNT >= 2)
+ if (pRI->socket_id == RIL_SOCKET_2) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket2;
+ pendingRequestsHook = &s_pendingRequests_socket2;
+ }
+#if (SIM_COUNT >= 3)
+ if (pRI->socket_id == RIL_SOCKET_3) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket3;
+ pendingRequestsHook = &s_pendingRequests_socket3;
+ }
+#endif
+#if (SIM_COUNT >= 4)
+ if (pRI->socket_id == RIL_SOCKET_4) {
+ pendingRequestsMutexHook = &s_pendingRequestsMutex_socket4;
+ pendingRequestsHook = &s_pendingRequests_socket4;
+ }
+#endif
+#endif
+ pthread_mutex_lock(pendingRequestsMutexHook);
+
+ for(RequestInfo **ppCur = pendingRequestsHook
+ ; *ppCur != NULL
+ ; ppCur = &((*ppCur)->p_next)
+ ) {
+ if (pRI == *ppCur) {
+ ret = 1;
+ if (isAck) { // Async ack
+ if (pRI->wasAckSent == 1) {
+ RLOGD("Ack was already sent for %s", requestToString(pRI->pCI->requestNumber));
+ } else {
+ pRI->wasAckSent = 1;
+ }
+ } else {
+ *ppCur = (*ppCur)->p_next;
+ }
+ break;
+ }
+ }
+
+ pthread_mutex_unlock(pendingRequestsMutexHook);
+
+ return ret;
+}
+
+extern "C" void
+RIL_onRequestAck(RIL_Token t) {
+ RequestInfo *pRI;
+
+ RIL_SOCKET_ID socket_id = RIL_SOCKET_1;
+
+ pRI = (RequestInfo *)t;
+
+ if (!checkAndDequeueRequestInfoIfAck(pRI, true)) {
+ RLOGE ("RIL_onRequestAck: invalid RIL_Token");
+ return;
+ }
+
+ socket_id = pRI->socket_id;
+
+#if VDBG
+ RLOGD("Request Ack, %s", rilSocketIdToString(socket_id));
+#endif
+
+ appendPrintBuf("Ack [%04d]< %s", pRI->token, requestToString(pRI->pCI->requestNumber));
+
+ if (pRI->cancelled == 0) {
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock(
+ (int) socket_id);
+ int rwlockRet = pthread_rwlock_rdlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+
+ radio_1_4::acknowledgeRequest((int) socket_id, pRI->token);
+
+ rwlockRet = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+ }
+}
+extern "C" void
+RIL_onRequestComplete(RIL_Token t, RIL_Errno e, void *response, size_t responselen) {
+ RequestInfo *pRI;
+ int ret;
+ RIL_SOCKET_ID socket_id = RIL_SOCKET_1;
+
+ pRI = (RequestInfo *)t;
+
+ if (!checkAndDequeueRequestInfoIfAck(pRI, false)) {
+ RLOGE ("RIL_onRequestComplete: invalid RIL_Token");
+ return;
+ }
+
+ socket_id = pRI->socket_id;
+ RLOGD("RequestComplete, %s", rilSocketIdToString(socket_id));
+#if VDBG
+ RLOGD("RequestComplete, %s", rilSocketIdToString(socket_id));
+#endif
+
+ if (pRI->local > 0) {
+ // Locally issued command...void only!
+ // response does not go back up the command socket
+ RLOGD("C[locl]< %s", requestToString(pRI->pCI->requestNumber));
+
+ free(pRI);
+ return;
+ }
+
+ appendPrintBuf("[%04d]< %s",
+ pRI->token, requestToString(pRI->pCI->requestNumber));
+
+ if (pRI->cancelled == 0) {
+ int responseType;
+ if (s_callbacks.version >= 13 && pRI->wasAckSent == 1) {
+ // If ack was already sent, then this call is an asynchronous response. So we need to
+ // send id indicating that we expect an ack from RIL.java as we acquire wakelock here.
+ responseType = RESPONSE_SOLICITED_ACK_EXP;
+ grabPartialWakeLock();
+ } else {
+ responseType = RESPONSE_SOLICITED;
+ }
+
+ // there is a response payload, no matter success or not.
+#if VDBG
+ RLOGE ("Calling responseFunction() for token %d", pRI->token);
+#endif
+
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock((int) socket_id);
+ int rwlockRet = pthread_rwlock_rdlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+
+ ret = pRI->pCI->responseFunction((int) socket_id,
+ responseType, pRI->token, e, response, responselen);
+
+ rwlockRet = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+ }
+ free(pRI);
+}
+
+static void
+grabPartialWakeLock() {
+ if (s_callbacks.version >= 13) {
+ int ret;
+ ret = pthread_mutex_lock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+ acquire_wake_lock(PARTIAL_WAKE_LOCK, ANDROID_WAKE_LOCK_NAME);
+
+ UserCallbackInfo *p_info =
+ internalRequestTimedCallback(wakeTimeoutCallback, NULL, &TIMEVAL_WAKE_TIMEOUT);
+ if (p_info == NULL) {
+ release_wake_lock(ANDROID_WAKE_LOCK_NAME);
+ } else {
+ s_wakelock_count++;
+ if (s_last_wake_timeout_info != NULL) {
+ s_last_wake_timeout_info->userParam = (void *)1;
+ }
+ s_last_wake_timeout_info = p_info;
+ }
+ ret = pthread_mutex_unlock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+ } else {
+ acquire_wake_lock(PARTIAL_WAKE_LOCK, ANDROID_WAKE_LOCK_NAME);
+ }
+}
+
+void
+releaseWakeLock() {
+ if (s_callbacks.version >= 13) {
+ int ret;
+ ret = pthread_mutex_lock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+
+ if (s_wakelock_count > 1) {
+ s_wakelock_count--;
+ } else {
+ s_wakelock_count = 0;
+ release_wake_lock(ANDROID_WAKE_LOCK_NAME);
+ if (s_last_wake_timeout_info != NULL) {
+ s_last_wake_timeout_info->userParam = (void *)1;
+ }
+ }
+
+ ret = pthread_mutex_unlock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+ } else {
+ release_wake_lock(ANDROID_WAKE_LOCK_NAME);
+ }
+}
+
+/**
+ * Timer callback to put us back to sleep before the default timeout
+ */
+static void
+wakeTimeoutCallback (void *param) {
+ // We're using "param != NULL" as a cancellation mechanism
+ if (s_callbacks.version >= 13) {
+ if (param == NULL) {
+ int ret;
+ ret = pthread_mutex_lock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+ s_wakelock_count = 0;
+ release_wake_lock(ANDROID_WAKE_LOCK_NAME);
+ ret = pthread_mutex_unlock(&s_wakeLockCountMutex);
+ assert(ret == 0);
+ }
+ } else {
+ if (param == NULL) {
+ releaseWakeLock();
+ }
+ }
+}
+
+#if defined(ANDROID_MULTI_SIM)
+extern "C"
+void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen, RIL_SOCKET_ID socket_id)
+#else
+extern "C"
+void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen)
+#endif
+{
+ int unsolResponseIndex;
+ int ret;
+ bool shouldScheduleTimeout = false;
+ RIL_SOCKET_ID soc_id = RIL_SOCKET_1;
+
+#if defined(ANDROID_MULTI_SIM)
+ soc_id = socket_id;
+#endif
+
+
+ if (s_registerCalled == 0) {
+ // Ignore RIL_onUnsolicitedResponse before RIL_register
+ RLOGW("RIL_onUnsolicitedResponse called before RIL_register");
+ return;
+ }
+
+ unsolResponseIndex = unsolResponse - RIL_UNSOL_RESPONSE_BASE;
+
+ if ((unsolResponseIndex < 0)
+ || (unsolResponseIndex >= (int32_t)NUM_ELEMS(s_unsolResponses))) {
+ RLOGE("unsupported unsolicited response code %d", unsolResponse);
+ return;
+ }
+
+ // Grab a wake lock if needed for this reponse,
+ // as we exit we'll either release it immediately
+ // or set a timer to release it later.
+ switch (s_unsolResponses[unsolResponseIndex].wakeType) {
+ case WAKE_PARTIAL:
+ grabPartialWakeLock();
+ shouldScheduleTimeout = true;
+ break;
+
+ case DONT_WAKE:
+ default:
+ // No wake lock is grabed so don't set timeout
+ shouldScheduleTimeout = false;
+ break;
+ }
+
+ appendPrintBuf("[UNSL]< %s", requestToString(unsolResponse));
+
+ int responseType;
+ if (s_callbacks.version >= 13
+ && s_unsolResponses[unsolResponseIndex].wakeType == WAKE_PARTIAL) {
+ responseType = RESPONSE_UNSOLICITED_ACK_EXP;
+ } else {
+ responseType = RESPONSE_UNSOLICITED;
+ }
+
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock((int) soc_id);
+ int rwlockRet;
+
+ if (unsolResponse == RIL_UNSOL_NITZ_TIME_RECEIVED) {
+ // get a write lock in caes of NITZ since setNitzTimeReceived() is called
+ rwlockRet = pthread_rwlock_wrlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+ radio_1_4::setNitzTimeReceived((int) soc_id, android::elapsedRealtime());
+ } else {
+ rwlockRet = pthread_rwlock_rdlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+ }
+
+ if (s_unsolResponses[unsolResponseIndex].responseFunction) {
+ RLOGD("calling UNSOLICITED responseFunction for index %d", unsolResponseIndex);
+ ret = s_unsolResponses[unsolResponseIndex].responseFunction(
+ (int) soc_id, responseType, 0, RIL_E_SUCCESS, const_cast<void*>(data),
+ datalen);
+ } else {
+ RLOGW("No call responseFunction defined for UNSOLICITED");
+ }
+
+ rwlockRet = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(rwlockRet == 0);
+
+ if (s_callbacks.version < 13) {
+ if (shouldScheduleTimeout) {
+ UserCallbackInfo *p_info = internalRequestTimedCallback(wakeTimeoutCallback, NULL,
+ &TIMEVAL_WAKE_TIMEOUT);
+
+ if (p_info == NULL) {
+ goto error_exit;
+ } else {
+ // Cancel the previous request
+ if (s_last_wake_timeout_info != NULL) {
+ s_last_wake_timeout_info->userParam = (void *)1;
+ }
+ s_last_wake_timeout_info = p_info;
+ }
+ }
+ }
+
+#if VDBG
+ RLOGI("%s UNSOLICITED: %s length:%zu", rilSocketIdToString(soc_id),
+ requestToString(unsolResponse), datalen);
+#endif
+
+ if (ret != 0 && unsolResponse == RIL_UNSOL_NITZ_TIME_RECEIVED) {
+ // Unfortunately, NITZ time is not poll/update like everything
+ // else in the system. So, if the upstream client isn't connected,
+ // keep a copy of the last NITZ response (with receive time noted
+ // above) around so we can deliver it when it is connected
+
+ if (s_lastNITZTimeData != NULL) {
+ free(s_lastNITZTimeData);
+ s_lastNITZTimeData = NULL;
+ }
+
+ s_lastNITZTimeData = calloc(datalen, 1);
+ if (s_lastNITZTimeData == NULL) {
+ RLOGE("Memory allocation failed in RIL_onUnsolicitedResponse");
+ goto error_exit;
+ }
+ s_lastNITZTimeDataSize = datalen;
+ memcpy(s_lastNITZTimeData, data, datalen);
+ }
+
+ // Normal exit
+ return;
+
+error_exit:
+ if (shouldScheduleTimeout) {
+ releaseWakeLock();
+ }
+}
+
+/** FIXME generalize this if you track UserCAllbackInfo, clear it
+ when the callback occurs
+*/
+static UserCallbackInfo *
+internalRequestTimedCallback (RIL_TimedCallback callback, void *param,
+ const struct timeval *relativeTime)
+{
+ struct timeval myRelativeTime;
+ UserCallbackInfo *p_info;
+
+ p_info = (UserCallbackInfo *) calloc(1, sizeof(UserCallbackInfo));
+ if (p_info == NULL) {
+ RLOGE("Memory allocation failed in internalRequestTimedCallback");
+ return p_info;
+
+ }
+
+ p_info->p_callback = callback;
+ p_info->userParam = param;
+
+ if (relativeTime == NULL) {
+ /* treat null parameter as a 0 relative time */
+ memset (&myRelativeTime, 0, sizeof(myRelativeTime));
+ } else {
+ /* FIXME I think event_add's tv param is really const anyway */
+ memcpy (&myRelativeTime, relativeTime, sizeof(myRelativeTime));
+ }
+
+ ril_event_set(&(p_info->event), -1, false, userTimerCallback, p_info);
+
+ ril_timer_add(&(p_info->event), &myRelativeTime);
+
+ triggerEvLoop();
+ return p_info;
+}
+
+
+extern "C" void
+RIL_requestTimedCallback (RIL_TimedCallback callback, void *param,
+ const struct timeval *relativeTime) {
+ internalRequestTimedCallback (callback, param, relativeTime);
+}
+
+const char *
+failCauseToString(RIL_Errno e) {
+ switch(e) {
+ case RIL_E_SUCCESS: return "E_SUCCESS";
+ case RIL_E_RADIO_NOT_AVAILABLE: return "E_RADIO_NOT_AVAILABLE";
+ case RIL_E_GENERIC_FAILURE: return "E_GENERIC_FAILURE";
+ case RIL_E_PASSWORD_INCORRECT: return "E_PASSWORD_INCORRECT";
+ case RIL_E_SIM_PIN2: return "E_SIM_PIN2";
+ case RIL_E_SIM_PUK2: return "E_SIM_PUK2";
+ case RIL_E_REQUEST_NOT_SUPPORTED: return "E_REQUEST_NOT_SUPPORTED";
+ case RIL_E_CANCELLED: return "E_CANCELLED";
+ case RIL_E_OP_NOT_ALLOWED_DURING_VOICE_CALL: return "E_OP_NOT_ALLOWED_DURING_VOICE_CALL";
+ case RIL_E_OP_NOT_ALLOWED_BEFORE_REG_TO_NW: return "E_OP_NOT_ALLOWED_BEFORE_REG_TO_NW";
+ case RIL_E_SMS_SEND_FAIL_RETRY: return "E_SMS_SEND_FAIL_RETRY";
+ case RIL_E_SIM_ABSENT:return "E_SIM_ABSENT";
+ case RIL_E_ILLEGAL_SIM_OR_ME:return "E_ILLEGAL_SIM_OR_ME";
+#ifdef FEATURE_MULTIMODE_ANDROID
+ case RIL_E_SUBSCRIPTION_NOT_AVAILABLE:return "E_SUBSCRIPTION_NOT_AVAILABLE";
+ case RIL_E_MODE_NOT_SUPPORTED:return "E_MODE_NOT_SUPPORTED";
+#endif
+ case RIL_E_FDN_CHECK_FAILURE: return "E_FDN_CHECK_FAILURE";
+ case RIL_E_MISSING_RESOURCE: return "E_MISSING_RESOURCE";
+ case RIL_E_NO_SUCH_ELEMENT: return "E_NO_SUCH_ELEMENT";
+ case RIL_E_DIAL_MODIFIED_TO_USSD: return "E_DIAL_MODIFIED_TO_USSD";
+ case RIL_E_DIAL_MODIFIED_TO_SS: return "E_DIAL_MODIFIED_TO_SS";
+ case RIL_E_DIAL_MODIFIED_TO_DIAL: return "E_DIAL_MODIFIED_TO_DIAL";
+ case RIL_E_USSD_MODIFIED_TO_DIAL: return "E_USSD_MODIFIED_TO_DIAL";
+ case RIL_E_USSD_MODIFIED_TO_SS: return "E_USSD_MODIFIED_TO_SS";
+ case RIL_E_USSD_MODIFIED_TO_USSD: return "E_USSD_MODIFIED_TO_USSD";
+ case RIL_E_SS_MODIFIED_TO_DIAL: return "E_SS_MODIFIED_TO_DIAL";
+ case RIL_E_SS_MODIFIED_TO_USSD: return "E_SS_MODIFIED_TO_USSD";
+ case RIL_E_SUBSCRIPTION_NOT_SUPPORTED: return "E_SUBSCRIPTION_NOT_SUPPORTED";
+ case RIL_E_SS_MODIFIED_TO_SS: return "E_SS_MODIFIED_TO_SS";
+ case RIL_E_LCE_NOT_SUPPORTED: return "E_LCE_NOT_SUPPORTED";
+ case RIL_E_NO_MEMORY: return "E_NO_MEMORY";
+ case RIL_E_INTERNAL_ERR: return "E_INTERNAL_ERR";
+ case RIL_E_SYSTEM_ERR: return "E_SYSTEM_ERR";
+ case RIL_E_MODEM_ERR: return "E_MODEM_ERR";
+ case RIL_E_INVALID_STATE: return "E_INVALID_STATE";
+ case RIL_E_NO_RESOURCES: return "E_NO_RESOURCES";
+ case RIL_E_SIM_ERR: return "E_SIM_ERR";
+ case RIL_E_INVALID_ARGUMENTS: return "E_INVALID_ARGUMENTS";
+ case RIL_E_INVALID_SIM_STATE: return "E_INVALID_SIM_STATE";
+ case RIL_E_INVALID_MODEM_STATE: return "E_INVALID_MODEM_STATE";
+ case RIL_E_INVALID_CALL_ID: return "E_INVALID_CALL_ID";
+ case RIL_E_NO_SMS_TO_ACK: return "E_NO_SMS_TO_ACK";
+ case RIL_E_NETWORK_ERR: return "E_NETWORK_ERR";
+ case RIL_E_REQUEST_RATE_LIMITED: return "E_REQUEST_RATE_LIMITED";
+ case RIL_E_SIM_BUSY: return "E_SIM_BUSY";
+ case RIL_E_SIM_FULL: return "E_SIM_FULL";
+ case RIL_E_NETWORK_REJECT: return "E_NETWORK_REJECT";
+ case RIL_E_OPERATION_NOT_ALLOWED: return "E_OPERATION_NOT_ALLOWED";
+ case RIL_E_EMPTY_RECORD: return "E_EMPTY_RECORD";
+ case RIL_E_INVALID_SMS_FORMAT: return "E_INVALID_SMS_FORMAT";
+ case RIL_E_ENCODING_ERR: return "E_ENCODING_ERR";
+ case RIL_E_INVALID_SMSC_ADDRESS: return "E_INVALID_SMSC_ADDRESS";
+ case RIL_E_NO_SUCH_ENTRY: return "E_NO_SUCH_ENTRY";
+ case RIL_E_NETWORK_NOT_READY: return "E_NETWORK_NOT_READY";
+ case RIL_E_NOT_PROVISIONED: return "E_NOT_PROVISIONED";
+ case RIL_E_NO_SUBSCRIPTION: return "E_NO_SUBSCRIPTION";
+ case RIL_E_NO_NETWORK_FOUND: return "E_NO_NETWORK_FOUND";
+ case RIL_E_DEVICE_IN_USE: return "E_DEVICE_IN_USE";
+ case RIL_E_ABORTED: return "E_ABORTED";
+ case RIL_E_INVALID_RESPONSE: return "INVALID_RESPONSE";
+ case RIL_E_OEM_ERROR_1: return "E_OEM_ERROR_1";
+ case RIL_E_OEM_ERROR_2: return "E_OEM_ERROR_2";
+ case RIL_E_OEM_ERROR_3: return "E_OEM_ERROR_3";
+ case RIL_E_OEM_ERROR_4: return "E_OEM_ERROR_4";
+ case RIL_E_OEM_ERROR_5: return "E_OEM_ERROR_5";
+ case RIL_E_OEM_ERROR_6: return "E_OEM_ERROR_6";
+ case RIL_E_OEM_ERROR_7: return "E_OEM_ERROR_7";
+ case RIL_E_OEM_ERROR_8: return "E_OEM_ERROR_8";
+ case RIL_E_OEM_ERROR_9: return "E_OEM_ERROR_9";
+ case RIL_E_OEM_ERROR_10: return "E_OEM_ERROR_10";
+ case RIL_E_OEM_ERROR_11: return "E_OEM_ERROR_11";
+ case RIL_E_OEM_ERROR_12: return "E_OEM_ERROR_12";
+ case RIL_E_OEM_ERROR_13: return "E_OEM_ERROR_13";
+ case RIL_E_OEM_ERROR_14: return "E_OEM_ERROR_14";
+ case RIL_E_OEM_ERROR_15: return "E_OEM_ERROR_15";
+ case RIL_E_OEM_ERROR_16: return "E_OEM_ERROR_16";
+ case RIL_E_OEM_ERROR_17: return "E_OEM_ERROR_17";
+ case RIL_E_OEM_ERROR_18: return "E_OEM_ERROR_18";
+ case RIL_E_OEM_ERROR_19: return "E_OEM_ERROR_19";
+ case RIL_E_OEM_ERROR_20: return "E_OEM_ERROR_20";
+ case RIL_E_OEM_ERROR_21: return "E_OEM_ERROR_21";
+ case RIL_E_OEM_ERROR_22: return "E_OEM_ERROR_22";
+ case RIL_E_OEM_ERROR_23: return "E_OEM_ERROR_23";
+ case RIL_E_OEM_ERROR_24: return "E_OEM_ERROR_24";
+ case RIL_E_OEM_ERROR_25: return "E_OEM_ERROR_25";
+ default: return "<unknown error>";
+ }
+}
+
+const char *
+radioStateToString(RIL_RadioState s) {
+ switch(s) {
+ case RADIO_STATE_OFF: return "RADIO_OFF";
+ case RADIO_STATE_UNAVAILABLE: return "RADIO_UNAVAILABLE";
+ case RADIO_STATE_ON:return"RADIO_ON";
+ default: return "<unknown state>";
+ }
+}
+
+const char *
+callStateToString(RIL_CallState s) {
+ switch(s) {
+ case RIL_CALL_ACTIVE : return "ACTIVE";
+ case RIL_CALL_HOLDING: return "HOLDING";
+ case RIL_CALL_DIALING: return "DIALING";
+ case RIL_CALL_ALERTING: return "ALERTING";
+ case RIL_CALL_INCOMING: return "INCOMING";
+ case RIL_CALL_WAITING: return "WAITING";
+ default: return "<unknown state>";
+ }
+}
+
+const char *
+requestToString(int request) {
+/*
+ cat guest/hals/ril/libril/ril_commands.h \
+ | egrep "^ *{RIL_" \
+ | sed -re 's/\{RIL_([^,]+),[^,]+,([^}]+).+/case RIL_\1: return "\1";/'
+
+
+ cat guest/hals/ril/libril/ril_unsol_commands.h \
+ | egrep "^ *{RIL_" \
+ | sed -re 's/\{RIL_([^,]+),([^}]+).+/case RIL_\1: return "\1";/'
+
+*/
+ switch(request) {
+ case RIL_REQUEST_GET_SIM_STATUS: return "GET_SIM_STATUS";
+ case RIL_REQUEST_ENTER_SIM_PIN: return "ENTER_SIM_PIN";
+ case RIL_REQUEST_ENTER_SIM_PUK: return "ENTER_SIM_PUK";
+ case RIL_REQUEST_ENTER_SIM_PIN2: return "ENTER_SIM_PIN2";
+ case RIL_REQUEST_ENTER_SIM_PUK2: return "ENTER_SIM_PUK2";
+ case RIL_REQUEST_CHANGE_SIM_PIN: return "CHANGE_SIM_PIN";
+ case RIL_REQUEST_CHANGE_SIM_PIN2: return "CHANGE_SIM_PIN2";
+ case RIL_REQUEST_ENTER_NETWORK_DEPERSONALIZATION: return "ENTER_NETWORK_DEPERSONALIZATION";
+ case RIL_REQUEST_GET_CURRENT_CALLS: return "GET_CURRENT_CALLS";
+ case RIL_REQUEST_DIAL: return "DIAL";
+ case RIL_REQUEST_GET_IMSI: return "GET_IMSI";
+ case RIL_REQUEST_HANGUP: return "HANGUP";
+ case RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND: return "HANGUP_WAITING_OR_BACKGROUND";
+ case RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND: return "HANGUP_FOREGROUND_RESUME_BACKGROUND";
+ case RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE: return "SWITCH_WAITING_OR_HOLDING_AND_ACTIVE";
+ case RIL_REQUEST_CONFERENCE: return "CONFERENCE";
+ case RIL_REQUEST_UDUB: return "UDUB";
+ case RIL_REQUEST_LAST_CALL_FAIL_CAUSE: return "LAST_CALL_FAIL_CAUSE";
+ case RIL_REQUEST_SIGNAL_STRENGTH: return "SIGNAL_STRENGTH";
+ case RIL_REQUEST_VOICE_REGISTRATION_STATE: return "VOICE_REGISTRATION_STATE";
+ case RIL_REQUEST_DATA_REGISTRATION_STATE: return "DATA_REGISTRATION_STATE";
+ case RIL_REQUEST_OPERATOR: return "OPERATOR";
+ case RIL_REQUEST_RADIO_POWER: return "RADIO_POWER";
+ case RIL_REQUEST_DTMF: return "DTMF";
+ case RIL_REQUEST_SEND_SMS: return "SEND_SMS";
+ case RIL_REQUEST_SEND_SMS_EXPECT_MORE: return "SEND_SMS_EXPECT_MORE";
+ case RIL_REQUEST_SETUP_DATA_CALL: return "SETUP_DATA_CALL";
+ case RIL_REQUEST_SIM_IO: return "SIM_IO";
+ case RIL_REQUEST_SEND_USSD: return "SEND_USSD";
+ case RIL_REQUEST_CANCEL_USSD: return "CANCEL_USSD";
+ case RIL_REQUEST_GET_CLIR: return "GET_CLIR";
+ case RIL_REQUEST_SET_CLIR: return "SET_CLIR";
+ case RIL_REQUEST_QUERY_CALL_FORWARD_STATUS: return "QUERY_CALL_FORWARD_STATUS";
+ case RIL_REQUEST_SET_CALL_FORWARD: return "SET_CALL_FORWARD";
+ case RIL_REQUEST_QUERY_CALL_WAITING: return "QUERY_CALL_WAITING";
+ case RIL_REQUEST_SET_CALL_WAITING: return "SET_CALL_WAITING";
+ case RIL_REQUEST_SMS_ACKNOWLEDGE: return "SMS_ACKNOWLEDGE";
+ case RIL_REQUEST_GET_IMEI: return "GET_IMEI";
+ case RIL_REQUEST_GET_IMEISV: return "GET_IMEISV";
+ case RIL_REQUEST_ANSWER: return "ANSWER";
+ case RIL_REQUEST_DEACTIVATE_DATA_CALL: return "DEACTIVATE_DATA_CALL";
+ case RIL_REQUEST_QUERY_FACILITY_LOCK: return "QUERY_FACILITY_LOCK";
+ case RIL_REQUEST_SET_FACILITY_LOCK: return "SET_FACILITY_LOCK";
+ case RIL_REQUEST_CHANGE_BARRING_PASSWORD: return "CHANGE_BARRING_PASSWORD";
+ case RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE: return "QUERY_NETWORK_SELECTION_MODE";
+ case RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC: return "SET_NETWORK_SELECTION_AUTOMATIC";
+ case RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL: return "SET_NETWORK_SELECTION_MANUAL";
+ case RIL_REQUEST_QUERY_AVAILABLE_NETWORKS: return "QUERY_AVAILABLE_NETWORKS";
+ case RIL_REQUEST_DTMF_START: return "DTMF_START";
+ case RIL_REQUEST_DTMF_STOP: return "DTMF_STOP";
+ case RIL_REQUEST_BASEBAND_VERSION: return "BASEBAND_VERSION";
+ case RIL_REQUEST_SEPARATE_CONNECTION: return "SEPARATE_CONNECTION";
+ case RIL_REQUEST_SET_MUTE: return "SET_MUTE";
+ case RIL_REQUEST_GET_MUTE: return "GET_MUTE";
+ case RIL_REQUEST_QUERY_CLIP: return "QUERY_CLIP";
+ case RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE: return "LAST_DATA_CALL_FAIL_CAUSE";
+ case RIL_REQUEST_DATA_CALL_LIST: return "DATA_CALL_LIST";
+ case RIL_REQUEST_RESET_RADIO: return "RESET_RADIO";
+ case RIL_REQUEST_OEM_HOOK_RAW: return "OEM_HOOK_RAW";
+ case RIL_REQUEST_OEM_HOOK_STRINGS: return "OEM_HOOK_STRINGS";
+ case RIL_REQUEST_SCREEN_STATE: return "SCREEN_STATE";
+ case RIL_REQUEST_SET_SUPP_SVC_NOTIFICATION: return "SET_SUPP_SVC_NOTIFICATION";
+ case RIL_REQUEST_WRITE_SMS_TO_SIM: return "WRITE_SMS_TO_SIM";
+ case RIL_REQUEST_DELETE_SMS_ON_SIM: return "DELETE_SMS_ON_SIM";
+ case RIL_REQUEST_SET_BAND_MODE: return "SET_BAND_MODE";
+ case RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE: return "QUERY_AVAILABLE_BAND_MODE";
+ case RIL_REQUEST_STK_GET_PROFILE: return "STK_GET_PROFILE";
+ case RIL_REQUEST_STK_SET_PROFILE: return "STK_SET_PROFILE";
+ case RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND: return "STK_SEND_ENVELOPE_COMMAND";
+ case RIL_REQUEST_STK_SEND_TERMINAL_RESPONSE: return "STK_SEND_TERMINAL_RESPONSE";
+ case RIL_REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM: return "STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM";
+ case RIL_REQUEST_EXPLICIT_CALL_TRANSFER: return "EXPLICIT_CALL_TRANSFER";
+ case RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE: return "SET_PREFERRED_NETWORK_TYPE";
+ case RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE: return "GET_PREFERRED_NETWORK_TYPE";
+ case RIL_REQUEST_GET_NEIGHBORING_CELL_IDS: return "GET_NEIGHBORING_CELL_IDS";
+ case RIL_REQUEST_SET_LOCATION_UPDATES: return "SET_LOCATION_UPDATES";
+ case RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE: return "CDMA_SET_SUBSCRIPTION_SOURCE";
+ case RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE: return "CDMA_SET_ROAMING_PREFERENCE";
+ case RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE: return "CDMA_QUERY_ROAMING_PREFERENCE";
+ case RIL_REQUEST_SET_TTY_MODE: return "SET_TTY_MODE";
+ case RIL_REQUEST_QUERY_TTY_MODE: return "QUERY_TTY_MODE";
+ case RIL_REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE: return "CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE";
+ case RIL_REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE: return "CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE";
+ case RIL_REQUEST_CDMA_FLASH: return "CDMA_FLASH";
+ case RIL_REQUEST_CDMA_BURST_DTMF: return "CDMA_BURST_DTMF";
+ case RIL_REQUEST_CDMA_VALIDATE_AND_WRITE_AKEY: return "CDMA_VALIDATE_AND_WRITE_AKEY";
+ case RIL_REQUEST_CDMA_SEND_SMS: return "CDMA_SEND_SMS";
+ case RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE: return "CDMA_SMS_ACKNOWLEDGE";
+ case RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG: return "GSM_GET_BROADCAST_SMS_CONFIG";
+ case RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG: return "GSM_SET_BROADCAST_SMS_CONFIG";
+ case RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION: return "GSM_SMS_BROADCAST_ACTIVATION";
+ case RIL_REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG: return "CDMA_GET_BROADCAST_SMS_CONFIG";
+ case RIL_REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG: return "CDMA_SET_BROADCAST_SMS_CONFIG";
+ case RIL_REQUEST_CDMA_SMS_BROADCAST_ACTIVATION: return "CDMA_SMS_BROADCAST_ACTIVATION";
+ case RIL_REQUEST_CDMA_SUBSCRIPTION: return "CDMA_SUBSCRIPTION";
+ case RIL_REQUEST_CDMA_WRITE_SMS_TO_RUIM: return "CDMA_WRITE_SMS_TO_RUIM";
+ case RIL_REQUEST_CDMA_DELETE_SMS_ON_RUIM: return "CDMA_DELETE_SMS_ON_RUIM";
+ case RIL_REQUEST_DEVICE_IDENTITY: return "DEVICE_IDENTITY";
+ case RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE: return "EXIT_EMERGENCY_CALLBACK_MODE";
+ case RIL_REQUEST_GET_SMSC_ADDRESS: return "GET_SMSC_ADDRESS";
+ case RIL_REQUEST_SET_SMSC_ADDRESS: return "SET_SMSC_ADDRESS";
+ case RIL_REQUEST_REPORT_SMS_MEMORY_STATUS: return "REPORT_SMS_MEMORY_STATUS";
+ case RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING: return "REPORT_STK_SERVICE_IS_RUNNING";
+ case RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE: return "CDMA_GET_SUBSCRIPTION_SOURCE";
+ case RIL_REQUEST_ISIM_AUTHENTICATION: return "ISIM_AUTHENTICATION";
+ case RIL_REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU: return "ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU";
+ case RIL_REQUEST_STK_SEND_ENVELOPE_WITH_STATUS: return "STK_SEND_ENVELOPE_WITH_STATUS";
+ case RIL_REQUEST_VOICE_RADIO_TECH: return "VOICE_RADIO_TECH";
+ case RIL_REQUEST_GET_CELL_INFO_LIST: return "GET_CELL_INFO_LIST";
+ case RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE: return "SET_UNSOL_CELL_INFO_LIST_RATE";
+ case RIL_REQUEST_SET_INITIAL_ATTACH_APN: return "SET_INITIAL_ATTACH_APN";
+ case RIL_REQUEST_IMS_REGISTRATION_STATE: return "IMS_REGISTRATION_STATE";
+ case RIL_REQUEST_IMS_SEND_SMS: return "IMS_SEND_SMS";
+ case RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC: return "SIM_TRANSMIT_APDU_BASIC";
+ case RIL_REQUEST_SIM_OPEN_CHANNEL: return "SIM_OPEN_CHANNEL";
+ case RIL_REQUEST_SIM_CLOSE_CHANNEL: return "SIM_CLOSE_CHANNEL";
+ case RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL: return "SIM_TRANSMIT_APDU_CHANNEL";
+ case RIL_REQUEST_NV_READ_ITEM: return "NV_READ_ITEM";
+ case RIL_REQUEST_NV_WRITE_ITEM: return "NV_WRITE_ITEM";
+ case RIL_REQUEST_NV_WRITE_CDMA_PRL: return "NV_WRITE_CDMA_PRL";
+ case RIL_REQUEST_NV_RESET_CONFIG: return "NV_RESET_CONFIG";
+ case RIL_REQUEST_SET_UICC_SUBSCRIPTION: return "SET_UICC_SUBSCRIPTION";
+ case RIL_REQUEST_ALLOW_DATA: return "ALLOW_DATA";
+ case RIL_REQUEST_GET_HARDWARE_CONFIG: return "GET_HARDWARE_CONFIG";
+ case RIL_REQUEST_SIM_AUTHENTICATION: return "SIM_AUTHENTICATION";
+ case RIL_REQUEST_GET_DC_RT_INFO: return "GET_DC_RT_INFO";
+ case RIL_REQUEST_SET_DC_RT_INFO_RATE: return "SET_DC_RT_INFO_RATE";
+ case RIL_REQUEST_SET_DATA_PROFILE: return "SET_DATA_PROFILE";
+ case RIL_REQUEST_SHUTDOWN: return "SHUTDOWN";
+ case RIL_REQUEST_GET_RADIO_CAPABILITY: return "GET_RADIO_CAPABILITY";
+ case RIL_REQUEST_SET_RADIO_CAPABILITY: return "SET_RADIO_CAPABILITY";
+ case RIL_REQUEST_START_LCE: return "START_LCE";
+ case RIL_REQUEST_STOP_LCE: return "STOP_LCE";
+ case RIL_REQUEST_PULL_LCEDATA: return "PULL_LCEDATA";
+ case RIL_REQUEST_GET_ACTIVITY_INFO: return "GET_ACTIVITY_INFO";
+ case RIL_REQUEST_SET_CARRIER_RESTRICTIONS: return "SET_CARRIER_RESTRICTIONS";
+ case RIL_REQUEST_GET_CARRIER_RESTRICTIONS: return "GET_CARRIER_RESTRICTIONS";
+ case RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION: return "SET_CARRIER_INFO_IMSI_ENCRYPTION";
+ case RIL_RESPONSE_ACKNOWLEDGEMENT: return "RESPONSE_ACKNOWLEDGEMENT";
+ case RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED: return "UNSOL_RESPONSE_RADIO_STATE_CHANGED";
+ case RIL_UNSOL_RESPONSE_CALL_STATE_CHANGED: return "UNSOL_RESPONSE_CALL_STATE_CHANGED";
+ case RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED: return "UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED";
+ case RIL_UNSOL_RESPONSE_NEW_SMS: return "UNSOL_RESPONSE_NEW_SMS";
+ case RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT: return "UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT";
+ case RIL_UNSOL_RESPONSE_NEW_SMS_ON_SIM: return "UNSOL_RESPONSE_NEW_SMS_ON_SIM";
+ case RIL_UNSOL_ON_USSD: return "UNSOL_ON_USSD";
+ case RIL_UNSOL_ON_USSD_REQUEST: return "UNSOL_ON_USSD_REQUEST";
+ case RIL_UNSOL_NITZ_TIME_RECEIVED: return "UNSOL_NITZ_TIME_RECEIVED";
+ case RIL_UNSOL_SIGNAL_STRENGTH: return "UNSOL_SIGNAL_STRENGTH";
+ case RIL_UNSOL_DATA_CALL_LIST_CHANGED: return "UNSOL_DATA_CALL_LIST_CHANGED";
+ case RIL_UNSOL_SUPP_SVC_NOTIFICATION: return "UNSOL_SUPP_SVC_NOTIFICATION";
+ case RIL_UNSOL_STK_SESSION_END: return "UNSOL_STK_SESSION_END";
+ case RIL_UNSOL_STK_PROACTIVE_COMMAND: return "UNSOL_STK_PROACTIVE_COMMAND";
+ case RIL_UNSOL_STK_EVENT_NOTIFY: return "UNSOL_STK_EVENT_NOTIFY";
+ case RIL_UNSOL_STK_CALL_SETUP: return "UNSOL_STK_CALL_SETUP";
+ case RIL_UNSOL_SIM_SMS_STORAGE_FULL: return "UNSOL_SIM_SMS_STORAGE_FULL";
+ case RIL_UNSOL_SIM_REFRESH: return "UNSOL_SIM_REFRESH";
+ case RIL_UNSOL_CALL_RING: return "UNSOL_CALL_RING";
+ case RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED: return "UNSOL_RESPONSE_SIM_STATUS_CHANGED";
+ case RIL_UNSOL_RESPONSE_CDMA_NEW_SMS: return "UNSOL_RESPONSE_CDMA_NEW_SMS";
+ case RIL_UNSOL_RESPONSE_NEW_BROADCAST_SMS: return "UNSOL_RESPONSE_NEW_BROADCAST_SMS";
+ case RIL_UNSOL_CDMA_RUIM_SMS_STORAGE_FULL: return "UNSOL_CDMA_RUIM_SMS_STORAGE_FULL";
+ case RIL_UNSOL_RESTRICTED_STATE_CHANGED: return "UNSOL_RESTRICTED_STATE_CHANGED";
+ case RIL_UNSOL_ENTER_EMERGENCY_CALLBACK_MODE: return "UNSOL_ENTER_EMERGENCY_CALLBACK_MODE";
+ case RIL_UNSOL_CDMA_CALL_WAITING: return "UNSOL_CDMA_CALL_WAITING";
+ case RIL_UNSOL_CDMA_OTA_PROVISION_STATUS: return "UNSOL_CDMA_OTA_PROVISION_STATUS";
+ case RIL_UNSOL_CDMA_INFO_REC: return "UNSOL_CDMA_INFO_REC";
+ case RIL_UNSOL_OEM_HOOK_RAW: return "UNSOL_OEM_HOOK_RAW";
+ case RIL_UNSOL_RINGBACK_TONE: return "UNSOL_RINGBACK_TONE";
+ case RIL_UNSOL_RESEND_INCALL_MUTE: return "UNSOL_RESEND_INCALL_MUTE";
+ case RIL_UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED: return "UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED";
+ case RIL_UNSOL_CDMA_PRL_CHANGED: return "UNSOL_CDMA_PRL_CHANGED";
+ case RIL_UNSOL_EXIT_EMERGENCY_CALLBACK_MODE: return "UNSOL_EXIT_EMERGENCY_CALLBACK_MODE";
+ case RIL_UNSOL_RIL_CONNECTED: return "UNSOL_RIL_CONNECTED";
+ case RIL_UNSOL_VOICE_RADIO_TECH_CHANGED: return "UNSOL_VOICE_RADIO_TECH_CHANGED";
+ case RIL_UNSOL_CELL_INFO_LIST: return "UNSOL_CELL_INFO_LIST";
+ case RIL_UNSOL_RESPONSE_IMS_NETWORK_STATE_CHANGED: return "UNSOL_RESPONSE_IMS_NETWORK_STATE_CHANGED";
+ case RIL_UNSOL_UICC_SUBSCRIPTION_STATUS_CHANGED: return "UNSOL_UICC_SUBSCRIPTION_STATUS_CHANGED";
+ case RIL_UNSOL_SRVCC_STATE_NOTIFY: return "UNSOL_SRVCC_STATE_NOTIFY";
+ case RIL_UNSOL_HARDWARE_CONFIG_CHANGED: return "UNSOL_HARDWARE_CONFIG_CHANGED";
+ case RIL_UNSOL_DC_RT_INFO_CHANGED: return "UNSOL_DC_RT_INFO_CHANGED";
+ case RIL_UNSOL_RADIO_CAPABILITY: return "UNSOL_RADIO_CAPABILITY";
+ case RIL_UNSOL_MODEM_RESTART: return "UNSOL_MODEM_RESTART";
+ case RIL_UNSOL_CARRIER_INFO_IMSI_ENCRYPTION: return "UNSOL_CARRIER_INFO_IMSI_ENCRYPTION";
+ case RIL_UNSOL_ON_SS: return "UNSOL_ON_SS";
+ case RIL_UNSOL_STK_CC_ALPHA_NOTIFY: return "UNSOL_STK_CC_ALPHA_NOTIFY";
+ case RIL_UNSOL_LCEDATA_RECV: return "UNSOL_LCEDATA_RECV";
+ case RIL_UNSOL_PCO_DATA: return "UNSOL_PCO_DATA";
+ default: return "<unknown request>";
+ }
+}
+
+const char *
+rilSocketIdToString(RIL_SOCKET_ID socket_id)
+{
+ switch(socket_id) {
+ case RIL_SOCKET_1:
+ return "RIL_SOCKET_1";
+#if (SIM_COUNT >= 2)
+ case RIL_SOCKET_2:
+ return "RIL_SOCKET_2";
+#endif
+#if (SIM_COUNT >= 3)
+ case RIL_SOCKET_3:
+ return "RIL_SOCKET_3";
+#endif
+#if (SIM_COUNT >= 4)
+ case RIL_SOCKET_4:
+ return "RIL_SOCKET_4";
+#endif
+ default:
+ return "not a valid RIL";
+ }
+}
+
+} /* namespace android */
diff --git a/guest/hals/ril/libril/ril.h b/guest/hals/ril/libril/ril.h
new file mode 100644
index 0000000..fb41b01
--- /dev/null
+++ b/guest/hals/ril/libril/ril.h
@@ -0,0 +1,7451 @@
+/*
+ * Copyright (C) 2006 The Android Open Source Project
+ *
+ * Licensed under the Apache License, Version 2.0 (the "License");
+ * you may not use this file except in compliance with the License.
+ * You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#ifndef ANDROID_RIL_H
+#define ANDROID_RIL_H 1
+
+#include <stdlib.h>
+#include <stdint.h>
+#include <telephony/ril_cdma_sms.h>
+#include <telephony/ril_nv_items.h>
+#include <telephony/ril_msim.h>
+
+#ifndef FEATURE_UNIT_TEST
+#include <sys/time.h>
+#endif /* !FEATURE_UNIT_TEST */
+
+#ifdef __cplusplus
+extern "C" {
+#endif
+
+#ifndef SIM_COUNT
+#if defined(ANDROID_SIM_COUNT_2)
+#define SIM_COUNT 2
+#elif defined(ANDROID_SIM_COUNT_3)
+#define SIM_COUNT 3
+#elif defined(ANDROID_SIM_COUNT_4)
+#define SIM_COUNT 4
+#else
+#define SIM_COUNT 1
+#endif
+
+#ifndef ANDROID_MULTI_SIM
+#define SIM_COUNT 1
+#endif
+#endif
+
+/*
+ * RIL version.
+ * Value of RIL_VERSION should not be changed in future. Here onwards,
+ * when a new change is supposed to be introduced which could involve new
+ * schemes added like Wakelocks, data structures added/updated, etc, we would
+ * just document RIL version associated with that change below. When OEM updates its
+ * RIL with those changes, they would return that new RIL version during RIL_REGISTER.
+ * We should make use of the returned version by vendor to identify appropriate scheme
+ * or data structure version to use.
+ *
+ * Documentation of RIL version and associated changes
+ * RIL_VERSION = 12 : This version corresponds to updated data structures namely
+ * RIL_Data_Call_Response_v11, RIL_SIM_IO_v6, RIL_CardStatus_v6,
+ * RIL_SimRefreshResponse_v7, RIL_CDMA_CallWaiting_v6,
+ * RIL_LTE_SignalStrength_v8, RIL_SignalStrength_v10, RIL_CellIdentityGsm_v12
+ * RIL_CellIdentityWcdma_v12, RIL_CellIdentityLte_v12,RIL_CellInfoGsm_v12,
+ * RIL_CellInfoWcdma_v12, RIL_CellInfoLte_v12, RIL_CellInfo_v12.
+ *
+ * RIL_VERSION = 13 : This version includes new wakelock semantics and as the first
+ * strongly versioned version it enforces structure use.
+ *
+ * RIL_VERSION = 14 : New data structures are added, namely RIL_CarrierMatchType,
+ * RIL_Carrier, RIL_CarrierRestrictions and RIL_PCO_Data.
+ * New commands added: RIL_REQUEST_SET_CARRIER_RESTRICTIONS,
+ * RIL_REQUEST_SET_CARRIER_RESTRICTIONS and RIL_UNSOL_PCO_DATA.
+ *
+ * RIL_VERSION = 15 : New commands added:
+ * RIL_UNSOL_MODEM_RESTART,
+ * RIL_REQUEST_SEND_DEVICE_STATE,
+ * RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER,
+ * RIL_REQUEST_SET_SIM_CARD_POWER,
+ * RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION,
+ * RIL_UNSOL_CARRIER_INFO_IMSI_ENCRYPTION
+ * The new parameters for RIL_REQUEST_SETUP_DATA_CALL,
+ * Updated data structures: RIL_DataProfileInfo_v15, RIL_InitialAttachApn_v15
+ * New data structure RIL_DataRegistrationStateResponse,
+ * RIL_VoiceRegistrationStateResponse same is
+ * used in RIL_REQUEST_DATA_REGISTRATION_STATE and
+ * RIL_REQUEST_VOICE_REGISTRATION_STATE respectively.
+ * New data structure RIL_OpenChannelParams.
+ * RIL_REQUEST_START_NETWORK_SCAN
+ * RIL_REQUEST_STOP_NETWORK_SCAN
+ * RIL_UNSOL_NETWORK_SCAN_RESULT
+ */
+#define RIL_VERSION 12
+#define LAST_IMPRECISE_RIL_VERSION 12 // Better self-documented name
+#define RIL_VERSION_MIN 6 /* Minimum RIL_VERSION supported */
+
+#define CDMA_ALPHA_INFO_BUFFER_LENGTH 64
+#define CDMA_NUMBER_INFO_BUFFER_LENGTH 81
+
+#define MAX_RILDS 3
+#define MAX_SERVICE_NAME_LENGTH 6
+#define MAX_CLIENT_ID_LENGTH 2
+#define MAX_DEBUG_SOCKET_NAME_LENGTH 12
+#define MAX_QEMU_PIPE_NAME_LENGTH 11
+#define MAX_UUID_LENGTH 64
+#define MAX_BANDS 8
+#define MAX_CHANNELS 32
+#define MAX_RADIO_ACCESS_NETWORKS 8
+
+
+typedef void * RIL_Token;
+
+typedef enum {
+ RIL_SOCKET_1,
+#if (SIM_COUNT >= 2)
+ RIL_SOCKET_2,
+#if (SIM_COUNT >= 3)
+ RIL_SOCKET_3,
+#endif
+#if (SIM_COUNT >= 4)
+ RIL_SOCKET_4,
+#endif
+#endif
+ RIL_SOCKET_NUM
+} RIL_SOCKET_ID;
+
+
+typedef enum {
+ RIL_E_SUCCESS = 0,
+ RIL_E_RADIO_NOT_AVAILABLE = 1, /* If radio did not start or is resetting */
+ RIL_E_GENERIC_FAILURE = 2,
+ RIL_E_PASSWORD_INCORRECT = 3, /* for PIN/PIN2 methods only! */
+ RIL_E_SIM_PIN2 = 4, /* Operation requires SIM PIN2 to be entered */
+ RIL_E_SIM_PUK2 = 5, /* Operation requires SIM PIN2 to be entered */
+ RIL_E_REQUEST_NOT_SUPPORTED = 6,
+ RIL_E_CANCELLED = 7,
+ RIL_E_OP_NOT_ALLOWED_DURING_VOICE_CALL = 8, /* data ops are not allowed during voice
+ call on a Class C GPRS device */
+ RIL_E_OP_NOT_ALLOWED_BEFORE_REG_TO_NW = 9, /* data ops are not allowed before device
+ registers in network */
+ RIL_E_SMS_SEND_FAIL_RETRY = 10, /* fail to send sms and need retry */
+ RIL_E_SIM_ABSENT = 11, /* fail to set the location where CDMA subscription
+ shall be retrieved because of SIM or RUIM
+ card absent */
+ RIL_E_SUBSCRIPTION_NOT_AVAILABLE = 12, /* fail to find CDMA subscription from specified
+ location */
+ RIL_E_MODE_NOT_SUPPORTED = 13, /* HW does not support preferred network type */
+ RIL_E_FDN_CHECK_FAILURE = 14, /* command failed because recipient is not on FDN list */
+ RIL_E_ILLEGAL_SIM_OR_ME = 15, /* network selection failed due to
+ illegal SIM or ME */
+ RIL_E_MISSING_RESOURCE = 16, /* no logical channel available */
+ RIL_E_NO_SUCH_ELEMENT = 17, /* application not found on SIM */
+ RIL_E_DIAL_MODIFIED_TO_USSD = 18, /* DIAL request modified to USSD */
+ RIL_E_DIAL_MODIFIED_TO_SS = 19, /* DIAL request modified to SS */
+ RIL_E_DIAL_MODIFIED_TO_DIAL = 20, /* DIAL request modified to DIAL with different
+ data */
+ RIL_E_USSD_MODIFIED_TO_DIAL = 21, /* USSD request modified to DIAL */
+ RIL_E_USSD_MODIFIED_TO_SS = 22, /* USSD request modified to SS */
+ RIL_E_USSD_MODIFIED_TO_USSD = 23, /* USSD request modified to different USSD
+ request */
+ RIL_E_SS_MODIFIED_TO_DIAL = 24, /* SS request modified to DIAL */
+ RIL_E_SS_MODIFIED_TO_USSD = 25, /* SS request modified to USSD */
+ RIL_E_SUBSCRIPTION_NOT_SUPPORTED = 26, /* Subscription not supported by RIL */
+ RIL_E_SS_MODIFIED_TO_SS = 27, /* SS request modified to different SS request */
+ RIL_E_LCE_NOT_SUPPORTED = 36, /* LCE service not supported(36 in RILConstants.java) */
+ RIL_E_NO_MEMORY = 37, /* Not sufficient memory to process the request */
+ RIL_E_INTERNAL_ERR = 38, /* Modem hit unexpected error scenario while handling
+ this request */
+ RIL_E_SYSTEM_ERR = 39, /* Hit platform or system error */
+ RIL_E_MODEM_ERR = 40, /* Vendor RIL got unexpected or incorrect response
+ from modem for this request */
+ RIL_E_INVALID_STATE = 41, /* Unexpected request for the current state */
+ RIL_E_NO_RESOURCES = 42, /* Not sufficient resource to process the request */
+ RIL_E_SIM_ERR = 43, /* Received error from SIM card */
+ RIL_E_INVALID_ARGUMENTS = 44, /* Received invalid arguments in request */
+ RIL_E_INVALID_SIM_STATE = 45, /* Can not process the request in current SIM state */
+ RIL_E_INVALID_MODEM_STATE = 46, /* Can not process the request in current Modem state */
+ RIL_E_INVALID_CALL_ID = 47, /* Received invalid call id in request */
+ RIL_E_NO_SMS_TO_ACK = 48, /* ACK received when there is no SMS to ack */
+ RIL_E_NETWORK_ERR = 49, /* Received error from network */
+ RIL_E_REQUEST_RATE_LIMITED = 50, /* Operation denied due to overly-frequent requests */
+ RIL_E_SIM_BUSY = 51, /* SIM is busy */
+ RIL_E_SIM_FULL = 52, /* The target EF is full */
+ RIL_E_NETWORK_REJECT = 53, /* Request is rejected by network */
+ RIL_E_OPERATION_NOT_ALLOWED = 54, /* Not allowed the request now */
+ RIL_E_EMPTY_RECORD = 55, /* The request record is empty */
+ RIL_E_INVALID_SMS_FORMAT = 56, /* Invalid sms format */
+ RIL_E_ENCODING_ERR = 57, /* Message not encoded properly */
+ RIL_E_INVALID_SMSC_ADDRESS = 58, /* SMSC address specified is invalid */
+ RIL_E_NO_SUCH_ENTRY = 59, /* No such entry present to perform the request */
+ RIL_E_NETWORK_NOT_READY = 60, /* Network is not ready to perform the request */
+ RIL_E_NOT_PROVISIONED = 61, /* Device doesnot have this value provisioned */
+ RIL_E_NO_SUBSCRIPTION = 62, /* Device doesnot have subscription */
+ RIL_E_NO_NETWORK_FOUND = 63, /* Network cannot be found */
+ RIL_E_DEVICE_IN_USE = 64, /* Operation cannot be performed because the device
+ is currently in use */
+ RIL_E_ABORTED = 65, /* Operation aborted */
+ RIL_E_INVALID_RESPONSE = 66, /* Invalid response sent by vendor code */
+ // OEM specific error codes. To be used by OEM when they don't want to reveal
+ // specific error codes which would be replaced by Generic failure.
+ RIL_E_OEM_ERROR_1 = 501,
+ RIL_E_OEM_ERROR_2 = 502,
+ RIL_E_OEM_ERROR_3 = 503,
+ RIL_E_OEM_ERROR_4 = 504,
+ RIL_E_OEM_ERROR_5 = 505,
+ RIL_E_OEM_ERROR_6 = 506,
+ RIL_E_OEM_ERROR_7 = 507,
+ RIL_E_OEM_ERROR_8 = 508,
+ RIL_E_OEM_ERROR_9 = 509,
+ RIL_E_OEM_ERROR_10 = 510,
+ RIL_E_OEM_ERROR_11 = 511,
+ RIL_E_OEM_ERROR_12 = 512,
+ RIL_E_OEM_ERROR_13 = 513,
+ RIL_E_OEM_ERROR_14 = 514,
+ RIL_E_OEM_ERROR_15 = 515,
+ RIL_E_OEM_ERROR_16 = 516,
+ RIL_E_OEM_ERROR_17 = 517,
+ RIL_E_OEM_ERROR_18 = 518,
+ RIL_E_OEM_ERROR_19 = 519,
+ RIL_E_OEM_ERROR_20 = 520,
+ RIL_E_OEM_ERROR_21 = 521,
+ RIL_E_OEM_ERROR_22 = 522,
+ RIL_E_OEM_ERROR_23 = 523,
+ RIL_E_OEM_ERROR_24 = 524,
+ RIL_E_OEM_ERROR_25 = 525
+} RIL_Errno;
+
+typedef enum {
+ RIL_CALL_ACTIVE = 0,
+ RIL_CALL_HOLDING = 1,
+ RIL_CALL_DIALING = 2, /* MO call only */
+ RIL_CALL_ALERTING = 3, /* MO call only */
+ RIL_CALL_INCOMING = 4, /* MT call only */
+ RIL_CALL_WAITING = 5 /* MT call only */
+} RIL_CallState;
+
+typedef enum {
+ RADIO_STATE_OFF = 0, /* Radio explictly powered off (eg CFUN=0) */
+ RADIO_STATE_UNAVAILABLE = 1, /* Radio unavailable (eg, resetting or not booted) */
+ RADIO_STATE_ON = 10 /* Radio is on */
+} RIL_RadioState;
+
+typedef enum {
+ RADIO_TECH_UNKNOWN = 0,
+ RADIO_TECH_GPRS = 1,
+ RADIO_TECH_EDGE = 2,
+ RADIO_TECH_UMTS = 3,
+ RADIO_TECH_IS95A = 4,
+ RADIO_TECH_IS95B = 5,
+ RADIO_TECH_1xRTT = 6,
+ RADIO_TECH_EVDO_0 = 7,
+ RADIO_TECH_EVDO_A = 8,
+ RADIO_TECH_HSDPA = 9,
+ RADIO_TECH_HSUPA = 10,
+ RADIO_TECH_HSPA = 11,
+ RADIO_TECH_EVDO_B = 12,
+ RADIO_TECH_EHRPD = 13,
+ RADIO_TECH_LTE = 14,
+ RADIO_TECH_HSPAP = 15, // HSPA+
+ RADIO_TECH_GSM = 16, // Only supports voice
+ RADIO_TECH_TD_SCDMA = 17,
+ RADIO_TECH_IWLAN = 18,
+ RADIO_TECH_LTE_CA = 19
+} RIL_RadioTechnology;
+
+typedef enum {
+ RAF_UNKNOWN = (1 << RADIO_TECH_UNKNOWN),
+ RAF_GPRS = (1 << RADIO_TECH_GPRS),
+ RAF_EDGE = (1 << RADIO_TECH_EDGE),
+ RAF_UMTS = (1 << RADIO_TECH_UMTS),
+ RAF_IS95A = (1 << RADIO_TECH_IS95A),
+ RAF_IS95B = (1 << RADIO_TECH_IS95B),
+ RAF_1xRTT = (1 << RADIO_TECH_1xRTT),
+ RAF_EVDO_0 = (1 << RADIO_TECH_EVDO_0),
+ RAF_EVDO_A = (1 << RADIO_TECH_EVDO_A),
+ RAF_HSDPA = (1 << RADIO_TECH_HSDPA),
+ RAF_HSUPA = (1 << RADIO_TECH_HSUPA),
+ RAF_HSPA = (1 << RADIO_TECH_HSPA),
+ RAF_EVDO_B = (1 << RADIO_TECH_EVDO_B),
+ RAF_EHRPD = (1 << RADIO_TECH_EHRPD),
+ RAF_LTE = (1 << RADIO_TECH_LTE),
+ RAF_HSPAP = (1 << RADIO_TECH_HSPAP),
+ RAF_GSM = (1 << RADIO_TECH_GSM),
+ RAF_TD_SCDMA = (1 << RADIO_TECH_TD_SCDMA),
+ RAF_LTE_CA = (1 << RADIO_TECH_LTE_CA)
+} RIL_RadioAccessFamily;
+
+typedef enum {
+ BAND_MODE_UNSPECIFIED = 0, //"unspecified" (selected by baseband automatically)
+ BAND_MODE_EURO = 1, //"EURO band" (GSM-900 / DCS-1800 / WCDMA-IMT-2000)
+ BAND_MODE_USA = 2, //"US band" (GSM-850 / PCS-1900 / WCDMA-850 / WCDMA-PCS-1900)
+ BAND_MODE_JPN = 3, //"JPN band" (WCDMA-800 / WCDMA-IMT-2000)
+ BAND_MODE_AUS = 4, //"AUS band" (GSM-900 / DCS-1800 / WCDMA-850 / WCDMA-IMT-2000)
+ BAND_MODE_AUS_2 = 5, //"AUS band 2" (GSM-900 / DCS-1800 / WCDMA-850)
+ BAND_MODE_CELL_800 = 6, //"Cellular" (800-MHz Band)
+ BAND_MODE_PCS = 7, //"PCS" (1900-MHz Band)
+ BAND_MODE_JTACS = 8, //"Band Class 3" (JTACS Band)
+ BAND_MODE_KOREA_PCS = 9, //"Band Class 4" (Korean PCS Band)
+ BAND_MODE_5_450M = 10, //"Band Class 5" (450-MHz Band)
+ BAND_MODE_IMT2000 = 11, //"Band Class 6" (2-GMHz IMT2000 Band)
+ BAND_MODE_7_700M_2 = 12, //"Band Class 7" (Upper 700-MHz Band)
+ BAND_MODE_8_1800M = 13, //"Band Class 8" (1800-MHz Band)
+ BAND_MODE_9_900M = 14, //"Band Class 9" (900-MHz Band)
+ BAND_MODE_10_800M_2 = 15, //"Band Class 10" (Secondary 800-MHz Band)
+ BAND_MODE_EURO_PAMR_400M = 16, //"Band Class 11" (400-MHz European PAMR Band)
+ BAND_MODE_AWS = 17, //"Band Class 15" (AWS Band)
+ BAND_MODE_USA_2500M = 18 //"Band Class 16" (US 2.5-GHz Band)
+} RIL_RadioBandMode;
+
+typedef enum {
+ RC_PHASE_CONFIGURED = 0, // LM is configured is initial value and value after FINISH completes
+ RC_PHASE_START = 1, // START is sent before Apply and indicates that an APPLY will be
+ // forthcoming with these same parameters
+ RC_PHASE_APPLY = 2, // APPLY is sent after all LM's receive START and returned
+ // RIL_RadioCapability.status = 0, if any START's fail no
+ // APPLY will be sent
+ RC_PHASE_UNSOL_RSP = 3, // UNSOL_RSP is sent with RIL_UNSOL_RADIO_CAPABILITY
+ RC_PHASE_FINISH = 4 // FINISH is sent after all commands have completed. If an error
+ // occurs in any previous command the RIL_RadioAccessesFamily and
+ // logicalModemUuid fields will be the prior configuration thus
+ // restoring the configuration to the previous value. An error
+ // returned by this command will generally be ignored or may
+ // cause that logical modem to be removed from service.
+} RadioCapabilityPhase;
+
+typedef enum {
+ RC_STATUS_NONE = 0, // This parameter has no meaning with RC_PHASE_START,
+ // RC_PHASE_APPLY
+ RC_STATUS_SUCCESS = 1, // Tell modem the action transaction of set radio
+ // capability was success with RC_PHASE_FINISH
+ RC_STATUS_FAIL = 2, // Tell modem the action transaction of set radio
+ // capability is fail with RC_PHASE_FINISH.
+} RadioCapabilityStatus;
+
+#define RIL_RADIO_CAPABILITY_VERSION 1
+typedef struct {
+ int version; // Version of structure, RIL_RADIO_CAPABILITY_VERSION
+ int session; // Unique session value defined by framework returned in all "responses/unsol"
+ int phase; // CONFIGURED, START, APPLY, FINISH
+ int rat; // RIL_RadioAccessFamily for the radio
+ char logicalModemUuid[MAX_UUID_LENGTH]; // A UUID typically "com.xxxx.lmX where X is the logical modem.
+ int status; // Return status and an input parameter for RC_PHASE_FINISH
+} RIL_RadioCapability;
+
+// Do we want to split Data from Voice and the use
+// RIL_RadioTechnology for get/setPreferredVoice/Data ?
+typedef enum {
+ PREF_NET_TYPE_GSM_WCDMA = 0, /* GSM/WCDMA (WCDMA preferred) */
+ PREF_NET_TYPE_GSM_ONLY = 1, /* GSM only */
+ PREF_NET_TYPE_WCDMA = 2, /* WCDMA */
+ PREF_NET_TYPE_GSM_WCDMA_AUTO = 3, /* GSM/WCDMA (auto mode, according to PRL) */
+ PREF_NET_TYPE_CDMA_EVDO_AUTO = 4, /* CDMA and EvDo (auto mode, according to PRL) */
+ PREF_NET_TYPE_CDMA_ONLY = 5, /* CDMA only */
+ PREF_NET_TYPE_EVDO_ONLY = 6, /* EvDo only */
+ PREF_NET_TYPE_GSM_WCDMA_CDMA_EVDO_AUTO = 7, /* GSM/WCDMA, CDMA, and EvDo (auto mode, according to PRL) */
+ PREF_NET_TYPE_LTE_CDMA_EVDO = 8, /* LTE, CDMA and EvDo */
+ PREF_NET_TYPE_LTE_GSM_WCDMA = 9, /* LTE, GSM/WCDMA */
+ PREF_NET_TYPE_LTE_CMDA_EVDO_GSM_WCDMA = 10, /* LTE, CDMA, EvDo, GSM/WCDMA */
+ PREF_NET_TYPE_LTE_ONLY = 11, /* LTE only */
+ PREF_NET_TYPE_LTE_WCDMA = 12, /* LTE/WCDMA */
+ PREF_NET_TYPE_TD_SCDMA_ONLY = 13, /* TD-SCDMA only */
+ PREF_NET_TYPE_TD_SCDMA_WCDMA = 14, /* TD-SCDMA and WCDMA */
+ PREF_NET_TYPE_TD_SCDMA_LTE = 15, /* TD-SCDMA and LTE */
+ PREF_NET_TYPE_TD_SCDMA_GSM = 16, /* TD-SCDMA and GSM */
+ PREF_NET_TYPE_TD_SCDMA_GSM_LTE = 17, /* TD-SCDMA,GSM and LTE */
+ PREF_NET_TYPE_TD_SCDMA_GSM_WCDMA = 18, /* TD-SCDMA, GSM/WCDMA */
+ PREF_NET_TYPE_TD_SCDMA_WCDMA_LTE = 19, /* TD-SCDMA, WCDMA and LTE */
+ PREF_NET_TYPE_TD_SCDMA_GSM_WCDMA_LTE = 20, /* TD-SCDMA, GSM/WCDMA and LTE */
+ PREF_NET_TYPE_TD_SCDMA_GSM_WCDMA_CDMA_EVDO_AUTO = 21, /* TD-SCDMA, GSM/WCDMA, CDMA and EvDo */
+ PREF_NET_TYPE_TD_SCDMA_LTE_CDMA_EVDO_GSM_WCDMA = 22 /* TD-SCDMA, LTE, CDMA, EvDo GSM/WCDMA */
+} RIL_PreferredNetworkType;
+
+/* Source for cdma subscription */
+typedef enum {
+ CDMA_SUBSCRIPTION_SOURCE_RUIM_SIM = 0,
+ CDMA_SUBSCRIPTION_SOURCE_NV = 1
+} RIL_CdmaSubscriptionSource;
+
+/* User-to-User signaling Info activation types derived from 3GPP 23.087 v8.0 */
+typedef enum {
+ RIL_UUS_TYPE1_IMPLICIT = 0,
+ RIL_UUS_TYPE1_REQUIRED = 1,
+ RIL_UUS_TYPE1_NOT_REQUIRED = 2,
+ RIL_UUS_TYPE2_REQUIRED = 3,
+ RIL_UUS_TYPE2_NOT_REQUIRED = 4,
+ RIL_UUS_TYPE3_REQUIRED = 5,
+ RIL_UUS_TYPE3_NOT_REQUIRED = 6
+} RIL_UUS_Type;
+
+/* User-to-User Signaling Information data coding schemes. Possible values for
+ * Octet 3 (Protocol Discriminator field) in the UUIE. The values have been
+ * specified in section 10.5.4.25 of 3GPP TS 24.008 */
+typedef enum {
+ RIL_UUS_DCS_USP = 0, /* User specified protocol */
+ RIL_UUS_DCS_OSIHLP = 1, /* OSI higher layer protocol */
+ RIL_UUS_DCS_X244 = 2, /* X.244 */
+ RIL_UUS_DCS_RMCF = 3, /* Reserved for system mangement
+ convergence function */
+ RIL_UUS_DCS_IA5c = 4 /* IA5 characters */
+} RIL_UUS_DCS;
+
+/* User-to-User Signaling Information defined in 3GPP 23.087 v8.0
+ * This data is passed in RIL_ExtensionRecord and rec contains this
+ * structure when type is RIL_UUS_INFO_EXT_REC */
+typedef struct {
+ RIL_UUS_Type uusType; /* UUS Type */
+ RIL_UUS_DCS uusDcs; /* UUS Data Coding Scheme */
+ int uusLength; /* Length of UUS Data */
+ char * uusData; /* UUS Data */
+} RIL_UUS_Info;
+
+/* CDMA Signal Information Record as defined in C.S0005 section 3.7.5.5 */
+typedef struct {
+ char isPresent; /* non-zero if signal information record is present */
+ char signalType; /* as defined 3.7.5.5-1 */
+ char alertPitch; /* as defined 3.7.5.5-2 */
+ char signal; /* as defined 3.7.5.5-3, 3.7.5.5-4 or 3.7.5.5-5 */
+} RIL_CDMA_SignalInfoRecord;
+
+typedef struct {
+ RIL_CallState state;
+ int index; /* Connection Index for use with, eg, AT+CHLD */
+ int toa; /* type of address, eg 145 = intl */
+ char isMpty; /* nonzero if is mpty call */
+ char isMT; /* nonzero if call is mobile terminated */
+ char als; /* ALS line indicator if available
+ (0 = line 1) */
+ char isVoice; /* nonzero if this is is a voice call */
+ char isVoicePrivacy; /* nonzero if CDMA voice privacy mode is active */
+ char * number; /* Remote party number */
+ int numberPresentation; /* 0=Allowed, 1=Restricted, 2=Not Specified/Unknown 3=Payphone */
+ char * name; /* Remote party name */
+ int namePresentation; /* 0=Allowed, 1=Restricted, 2=Not Specified/Unknown 3=Payphone */
+ RIL_UUS_Info * uusInfo; /* NULL or Pointer to User-User Signaling Information */
+} RIL_Call;
+
+/* Deprecated, use RIL_Data_Call_Response_v6 */
+typedef struct {
+ int cid; /* Context ID, uniquely identifies this call */
+ int active; /* 0=inactive, 1=active/physical link down, 2=active/physical link up */
+ char * type; /* One of the PDP_type values in TS 27.007 section 10.1.1.
+ For example, "IP", "IPV6", "IPV4V6", or "PPP". */
+ char * apn; /* ignored */
+ char * address; /* An address, e.g., "192.0.1.3" or "2001:db8::1". */
+} RIL_Data_Call_Response_v4;
+
+/*
+ * Returned by RIL_REQUEST_SETUP_DATA_CALL, RIL_REQUEST_DATA_CALL_LIST
+ * and RIL_UNSOL_DATA_CALL_LIST_CHANGED, on error status != 0.
+ */
+typedef struct {
+ int status; /* A RIL_DataCallFailCause, 0 which is PDP_FAIL_NONE if no error */
+ int suggestedRetryTime; /* If status != 0, this fields indicates the suggested retry
+ back-off timer value RIL wants to override the one
+ pre-configured in FW.
+ The unit is miliseconds.
+ The value < 0 means no value is suggested.
+ The value 0 means retry should be done ASAP.
+ The value of INT_MAX(0x7fffffff) means no retry. */
+ int cid; /* Context ID, uniquely identifies this call */
+ int active; /* 0=inactive, 1=active/physical link down, 2=active/physical link up */
+ char * type; /* One of the PDP_type values in TS 27.007 section 10.1.1.
+ For example, "IP", "IPV6", "IPV4V6", or "PPP". If status is
+ PDP_FAIL_ONLY_SINGLE_BEARER_ALLOWED this is the type supported
+ such as "IP" or "IPV6" */
+ char * ifname; /* The network interface name */
+ char * addresses; /* A space-delimited list of addresses with optional "/" prefix length,
+ e.g., "192.0.1.3" or "192.0.1.11/16 2001:db8::1/64".
+ May not be empty, typically 1 IPv4 or 1 IPv6 or
+ one of each. If the prefix length is absent the addresses
+ are assumed to be point to point with IPv4 having a prefix
+ length of 32 and IPv6 128. */
+ char * dnses; /* A space-delimited list of DNS server addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty. */
+ char * gateways; /* A space-delimited list of default gateway addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty in which case the addresses represent point
+ to point connections. */
+} RIL_Data_Call_Response_v6;
+
+typedef struct {
+ int status; /* A RIL_DataCallFailCause, 0 which is PDP_FAIL_NONE if no error */
+ int suggestedRetryTime; /* If status != 0, this fields indicates the suggested retry
+ back-off timer value RIL wants to override the one
+ pre-configured in FW.
+ The unit is miliseconds.
+ The value < 0 means no value is suggested.
+ The value 0 means retry should be done ASAP.
+ The value of INT_MAX(0x7fffffff) means no retry. */
+ int cid; /* Context ID, uniquely identifies this call */
+ int active; /* 0=inactive, 1=active/physical link down, 2=active/physical link up */
+ char * type; /* One of the PDP_type values in TS 27.007 section 10.1.1.
+ For example, "IP", "IPV6", "IPV4V6", or "PPP". If status is
+ PDP_FAIL_ONLY_SINGLE_BEARER_ALLOWED this is the type supported
+ such as "IP" or "IPV6" */
+ char * ifname; /* The network interface name */
+ char * addresses; /* A space-delimited list of addresses with optional "/" prefix length,
+ e.g., "192.0.1.3" or "192.0.1.11/16 2001:db8::1/64".
+ May not be empty, typically 1 IPv4 or 1 IPv6 or
+ one of each. If the prefix length is absent the addresses
+ are assumed to be point to point with IPv4 having a prefix
+ length of 32 and IPv6 128. */
+ char * dnses; /* A space-delimited list of DNS server addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty. */
+ char * gateways; /* A space-delimited list of default gateway addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty in which case the addresses represent point
+ to point connections. */
+ char * pcscf; /* the Proxy Call State Control Function address
+ via PCO(Protocol Configuration Option) for IMS client. */
+} RIL_Data_Call_Response_v9;
+
+typedef struct {
+ int status; /* A RIL_DataCallFailCause, 0 which is PDP_FAIL_NONE if no error */
+ int suggestedRetryTime; /* If status != 0, this fields indicates the suggested retry
+ back-off timer value RIL wants to override the one
+ pre-configured in FW.
+ The unit is miliseconds.
+ The value < 0 means no value is suggested.
+ The value 0 means retry should be done ASAP.
+ The value of INT_MAX(0x7fffffff) means no retry. */
+ int cid; /* Context ID, uniquely identifies this call */
+ int active; /* 0=inactive, 1=active/physical link down, 2=active/physical link up */
+ char * type; /* One of the PDP_type values in TS 27.007 section 10.1.1.
+ For example, "IP", "IPV6", "IPV4V6", or "PPP". If status is
+ PDP_FAIL_ONLY_SINGLE_BEARER_ALLOWED this is the type supported
+ such as "IP" or "IPV6" */
+ char * ifname; /* The network interface name */
+ char * addresses; /* A space-delimited list of addresses with optional "/" prefix length,
+ e.g., "192.0.1.3" or "192.0.1.11/16 2001:db8::1/64".
+ May not be empty, typically 1 IPv4 or 1 IPv6 or
+ one of each. If the prefix length is absent the addresses
+ are assumed to be point to point with IPv4 having a prefix
+ length of 32 and IPv6 128. */
+ char * dnses; /* A space-delimited list of DNS server addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty. */
+ char * gateways; /* A space-delimited list of default gateway addresses,
+ e.g., "192.0.1.3" or "192.0.1.11 2001:db8::1".
+ May be empty in which case the addresses represent point
+ to point connections. */
+ char * pcscf; /* the Proxy Call State Control Function address
+ via PCO(Protocol Configuration Option) for IMS client. */
+ int mtu; /* MTU received from network
+ Value <= 0 means network has either not sent a value or
+ sent an invalid value */
+} RIL_Data_Call_Response_v11;
+
+typedef enum {
+ RADIO_TECH_3GPP = 1, /* 3GPP Technologies - GSM, WCDMA */
+ RADIO_TECH_3GPP2 = 2 /* 3GPP2 Technologies - CDMA */
+} RIL_RadioTechnologyFamily;
+
+typedef struct {
+ RIL_RadioTechnologyFamily tech;
+ unsigned char retry; /* 0 == not retry, nonzero == retry */
+ int messageRef; /* Valid field if retry is set to nonzero.
+ Contains messageRef from RIL_SMS_Response
+ corresponding to failed MO SMS.
+ */
+
+ union {
+ /* Valid field if tech is RADIO_TECH_3GPP2. See RIL_REQUEST_CDMA_SEND_SMS */
+ RIL_CDMA_SMS_Message* cdmaMessage;
+
+ /* Valid field if tech is RADIO_TECH_3GPP. See RIL_REQUEST_SEND_SMS */
+ char** gsmMessage; /* This is an array of pointers where pointers
+ are contiguous but elements pointed by those pointers
+ are not contiguous
+ */
+ } message;
+} RIL_IMS_SMS_Message;
+
+typedef struct {
+ int messageRef; /* TP-Message-Reference for GSM,
+ and BearerData MessageId for CDMA
+ (See 3GPP2 C.S0015-B, v2.0, table 4.5-1). */
+ char *ackPDU; /* or NULL if n/a */
+ int errorCode; /* See 3GPP 27.005, 3.2.5 for GSM/UMTS,
+ 3GPP2 N.S0005 (IS-41C) Table 171 for CDMA,
+ -1 if unknown or not applicable*/
+} RIL_SMS_Response;
+
+/** Used by RIL_REQUEST_WRITE_SMS_TO_SIM */
+typedef struct {
+ int status; /* Status of message. See TS 27.005 3.1, "<stat>": */
+ /* 0 = "REC UNREAD" */
+ /* 1 = "REC READ" */
+ /* 2 = "STO UNSENT" */
+ /* 3 = "STO SENT" */
+ char * pdu; /* PDU of message to write, as an ASCII hex string less the SMSC address,
+ the TP-layer length is "strlen(pdu)/2". */
+ char * smsc; /* SMSC address in GSM BCD format prefixed by a length byte
+ (as expected by TS 27.005) or NULL for default SMSC */
+} RIL_SMS_WriteArgs;
+
+/** Used by RIL_REQUEST_DIAL */
+typedef struct {
+ char * address;
+ int clir;
+ /* (same as 'n' paremeter in TS 27.007 7.7 "+CLIR"
+ * clir == 0 on "use subscription default value"
+ * clir == 1 on "CLIR invocation" (restrict CLI presentation)
+ * clir == 2 on "CLIR suppression" (allow CLI presentation)
+ */
+ RIL_UUS_Info * uusInfo; /* NULL or Pointer to User-User Signaling Information */
+} RIL_Dial;
+
+typedef struct {
+ int command; /* one of the commands listed for TS 27.007 +CRSM*/
+ int fileid; /* EF id */
+ char *path; /* "pathid" from TS 27.007 +CRSM command.
+ Path is in hex asciii format eg "7f205f70"
+ Path must always be provided.
+ */
+ int p1;
+ int p2;
+ int p3;
+ char *data; /* May be NULL*/
+ char *pin2; /* May be NULL*/
+} RIL_SIM_IO_v5;
+
+typedef struct {
+ int command; /* one of the commands listed for TS 27.007 +CRSM*/
+ int fileid; /* EF id */
+ char *path; /* "pathid" from TS 27.007 +CRSM command.
+ Path is in hex asciii format eg "7f205f70"
+ Path must always be provided.
+ */
+ int p1;
+ int p2;
+ int p3;
+ char *data; /* May be NULL*/
+ char *pin2; /* May be NULL*/
+ char *aidPtr; /* AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value. */
+} RIL_SIM_IO_v6;
+
+/* Used by RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL and
+ * RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC. */
+typedef struct {
+ int sessionid; /* "sessionid" from TS 27.007 +CGLA command. Should be
+ ignored for +CSIM command. */
+
+ /* Following fields are used to derive the APDU ("command" and "length"
+ values in TS 27.007 +CSIM and +CGLA commands). */
+ int cla;
+ int instruction;
+ int p1;
+ int p2;
+ int p3; /* A negative P3 implies a 4 byte APDU. */
+ char *data; /* May be NULL. In hex string format. */
+} RIL_SIM_APDU;
+
+typedef struct {
+ int sw1;
+ int sw2;
+ char *simResponse; /* In hex string format ([a-fA-F0-9]*), except for SIM_AUTHENTICATION
+ response for which it is in Base64 format, see 3GPP TS 31.102 7.1.2 */
+} RIL_SIM_IO_Response;
+
+/* See also com.android.internal.telephony.gsm.CallForwardInfo */
+
+typedef struct {
+ int status; /*
+ * For RIL_REQUEST_QUERY_CALL_FORWARD_STATUS
+ * status 1 = active, 0 = not active
+ *
+ * For RIL_REQUEST_SET_CALL_FORWARD:
+ * status is:
+ * 0 = disable
+ * 1 = enable
+ * 2 = interrogate
+ * 3 = registeration
+ * 4 = erasure
+ */
+
+ int reason; /* from TS 27.007 7.11 "reason" */
+ int serviceClass;/* From 27.007 +CCFC/+CLCK "class"
+ See table for Android mapping from
+ MMI service code
+ 0 means user doesn't input class */
+ int toa; /* "type" from TS 27.007 7.11 */
+ char * number; /* "number" from TS 27.007 7.11. May be NULL */
+ int timeSeconds; /* for CF no reply only */
+}RIL_CallForwardInfo;
+
+typedef struct {
+ char * cid; /* Combination of LAC and Cell Id in 32 bits in GSM.
+ * Upper 16 bits is LAC and lower 16 bits
+ * is CID (as described in TS 27.005)
+ * Primary Scrambling Code (as described in TS 25.331)
+ * in 9 bits in UMTS
+ * Valid values are hexadecimal 0x0000 - 0xffffffff.
+ */
+ int rssi; /* Received RSSI in GSM,
+ * Level index of CPICH Received Signal Code Power in UMTS
+ */
+} RIL_NeighboringCell;
+
+typedef struct {
+ char lce_status; /* LCE service status:
+ * -1 = not supported;
+ * 0 = stopped;
+ * 1 = active.
+ */
+ unsigned int actual_interval_ms; /* actual LCE reporting interval,
+ * meaningful only if LCEStatus = 1.
+ */
+} RIL_LceStatusInfo;
+
+typedef struct {
+ unsigned int last_hop_capacity_kbps; /* last-hop cellular capacity: kilobits/second. */
+ unsigned char confidence_level; /* capacity estimate confidence: 0-100 */
+ unsigned char lce_suspended; /* LCE report going to be suspended? (e.g., radio
+ * moves to inactive state or network type change)
+ * 1 = suspended;
+ * 0 = not suspended.
+ */
+} RIL_LceDataInfo;
+
+typedef enum {
+ RIL_MATCH_ALL = 0, /* Apply to all carriers with the same mcc/mnc */
+ RIL_MATCH_SPN = 1, /* Use SPN and mcc/mnc to identify the carrier */
+ RIL_MATCH_IMSI_PREFIX = 2, /* Use IMSI prefix and mcc/mnc to identify the carrier */
+ RIL_MATCH_GID1 = 3, /* Use GID1 and mcc/mnc to identify the carrier */
+ RIL_MATCH_GID2 = 4, /* Use GID2 and mcc/mnc to identify the carrier */
+} RIL_CarrierMatchType;
+
+typedef struct {
+ const char * mcc;
+ const char * mnc;
+ RIL_CarrierMatchType match_type; /* Specify match type for the carrier.
+ * If it’s RIL_MATCH_ALL, match_data is null;
+ * otherwise, match_data is the value for the match type.
+ */
+ const char * match_data;
+} RIL_Carrier;
+
+typedef struct {
+ int32_t len_allowed_carriers; /* length of array allowed_carriers */
+ int32_t len_excluded_carriers; /* length of array excluded_carriers */
+ RIL_Carrier * allowed_carriers; /* whitelist for allowed carriers */
+ RIL_Carrier * excluded_carriers; /* blacklist for explicitly excluded carriers
+ * which match allowed_carriers. Eg. allowed_carriers match
+ * mcc/mnc, excluded_carriers has same mcc/mnc and gid1
+ * is ABCD. It means except the carrier whose gid1 is ABCD,
+ * all carriers with the same mcc/mnc are allowed.
+ */
+} RIL_CarrierRestrictions;
+
+typedef struct {
+ char * mcc; /* MCC of the Carrier. */
+ char * mnc ; /* MNC of the Carrier. */
+ uint8_t * carrierKey; /* Public Key from the Carrier used to encrypt the
+ * IMSI/IMPI.
+ */
+ int32_t carrierKeyLength; /* Length of the Public Key. */
+ char * keyIdentifier; /* The keyIdentifier Attribute value pair that helps
+ * a server locate the private key to decrypt the
+ * permanent identity.
+ */
+ int64_t expirationTime; /* Date-Time (in UTC) when the key will expire. */
+
+} RIL_CarrierInfoForImsiEncryption;
+
+/* See RIL_REQUEST_LAST_CALL_FAIL_CAUSE */
+typedef enum {
+ CALL_FAIL_UNOBTAINABLE_NUMBER = 1,
+ CALL_FAIL_NO_ROUTE_TO_DESTINATION = 3,
+ CALL_FAIL_CHANNEL_UNACCEPTABLE = 6,
+ CALL_FAIL_OPERATOR_DETERMINED_BARRING = 8,
+ CALL_FAIL_NORMAL = 16,
+ CALL_FAIL_BUSY = 17,
+ CALL_FAIL_NO_USER_RESPONDING = 18,
+ CALL_FAIL_NO_ANSWER_FROM_USER = 19,
+ CALL_FAIL_CALL_REJECTED = 21,
+ CALL_FAIL_NUMBER_CHANGED = 22,
+ CALL_FAIL_PREEMPTION = 25,
+ CALL_FAIL_DESTINATION_OUT_OF_ORDER = 27,
+ CALL_FAIL_INVALID_NUMBER_FORMAT = 28,
+ CALL_FAIL_FACILITY_REJECTED = 29,
+ CALL_FAIL_RESP_TO_STATUS_ENQUIRY = 30,
+ CALL_FAIL_NORMAL_UNSPECIFIED = 31,
+ CALL_FAIL_CONGESTION = 34,
+ CALL_FAIL_NETWORK_OUT_OF_ORDER = 38,
+ CALL_FAIL_TEMPORARY_FAILURE = 41,
+ CALL_FAIL_SWITCHING_EQUIPMENT_CONGESTION = 42,
+ CALL_FAIL_ACCESS_INFORMATION_DISCARDED = 43,
+ CALL_FAIL_REQUESTED_CIRCUIT_OR_CHANNEL_NOT_AVAILABLE = 44,
+ CALL_FAIL_RESOURCES_UNAVAILABLE_OR_UNSPECIFIED = 47,
+ CALL_FAIL_QOS_UNAVAILABLE = 49,
+ CALL_FAIL_REQUESTED_FACILITY_NOT_SUBSCRIBED = 50,
+ CALL_FAIL_INCOMING_CALLS_BARRED_WITHIN_CUG = 55,
+ CALL_FAIL_BEARER_CAPABILITY_NOT_AUTHORIZED = 57,
+ CALL_FAIL_BEARER_CAPABILITY_UNAVAILABLE = 58,
+ CALL_FAIL_SERVICE_OPTION_NOT_AVAILABLE = 63,
+ CALL_FAIL_BEARER_SERVICE_NOT_IMPLEMENTED = 65,
+ CALL_FAIL_ACM_LIMIT_EXCEEDED = 68,
+ CALL_FAIL_REQUESTED_FACILITY_NOT_IMPLEMENTED = 69,
+ CALL_FAIL_ONLY_DIGITAL_INFORMATION_BEARER_AVAILABLE = 70,
+ CALL_FAIL_SERVICE_OR_OPTION_NOT_IMPLEMENTED = 79,
+ CALL_FAIL_INVALID_TRANSACTION_IDENTIFIER = 81,
+ CALL_FAIL_USER_NOT_MEMBER_OF_CUG = 87,
+ CALL_FAIL_INCOMPATIBLE_DESTINATION = 88,
+ CALL_FAIL_INVALID_TRANSIT_NW_SELECTION = 91,
+ CALL_FAIL_SEMANTICALLY_INCORRECT_MESSAGE = 95,
+ CALL_FAIL_INVALID_MANDATORY_INFORMATION = 96,
+ CALL_FAIL_MESSAGE_TYPE_NON_IMPLEMENTED = 97,
+ CALL_FAIL_MESSAGE_TYPE_NOT_COMPATIBLE_WITH_PROTOCOL_STATE = 98,
+ CALL_FAIL_INFORMATION_ELEMENT_NON_EXISTENT = 99,
+ CALL_FAIL_CONDITIONAL_IE_ERROR = 100,
+ CALL_FAIL_MESSAGE_NOT_COMPATIBLE_WITH_PROTOCOL_STATE = 101,
+ CALL_FAIL_RECOVERY_ON_TIMER_EXPIRED = 102,
+ CALL_FAIL_PROTOCOL_ERROR_UNSPECIFIED = 111,
+ CALL_FAIL_INTERWORKING_UNSPECIFIED = 127,
+ CALL_FAIL_CALL_BARRED = 240,
+ CALL_FAIL_FDN_BLOCKED = 241,
+ CALL_FAIL_IMSI_UNKNOWN_IN_VLR = 242,
+ CALL_FAIL_IMEI_NOT_ACCEPTED = 243,
+ CALL_FAIL_DIAL_MODIFIED_TO_USSD = 244, /* STK Call Control */
+ CALL_FAIL_DIAL_MODIFIED_TO_SS = 245,
+ CALL_FAIL_DIAL_MODIFIED_TO_DIAL = 246,
+ CALL_FAIL_RADIO_OFF = 247, /* Radio is OFF */
+ CALL_FAIL_OUT_OF_SERVICE = 248, /* No cellular coverage */
+ CALL_FAIL_NO_VALID_SIM = 249, /* No valid SIM is present */
+ CALL_FAIL_RADIO_INTERNAL_ERROR = 250, /* Internal error at Modem */
+ CALL_FAIL_NETWORK_RESP_TIMEOUT = 251, /* No response from network */
+ CALL_FAIL_NETWORK_REJECT = 252, /* Explicit network reject */
+ CALL_FAIL_RADIO_ACCESS_FAILURE = 253, /* RRC connection failure. Eg.RACH */
+ CALL_FAIL_RADIO_LINK_FAILURE = 254, /* Radio Link Failure */
+ CALL_FAIL_RADIO_LINK_LOST = 255, /* Radio link lost due to poor coverage */
+ CALL_FAIL_RADIO_UPLINK_FAILURE = 256, /* Radio uplink failure */
+ CALL_FAIL_RADIO_SETUP_FAILURE = 257, /* RRC connection setup failure */
+ CALL_FAIL_RADIO_RELEASE_NORMAL = 258, /* RRC connection release, normal */
+ CALL_FAIL_RADIO_RELEASE_ABNORMAL = 259, /* RRC connection release, abnormal */
+ CALL_FAIL_ACCESS_CLASS_BLOCKED = 260, /* Access class barring */
+ CALL_FAIL_NETWORK_DETACH = 261, /* Explicit network detach */
+ CALL_FAIL_CDMA_LOCKED_UNTIL_POWER_CYCLE = 1000,
+ CALL_FAIL_CDMA_DROP = 1001,
+ CALL_FAIL_CDMA_INTERCEPT = 1002,
+ CALL_FAIL_CDMA_REORDER = 1003,
+ CALL_FAIL_CDMA_SO_REJECT = 1004,
+ CALL_FAIL_CDMA_RETRY_ORDER = 1005,
+ CALL_FAIL_CDMA_ACCESS_FAILURE = 1006,
+ CALL_FAIL_CDMA_PREEMPTED = 1007,
+ CALL_FAIL_CDMA_NOT_EMERGENCY = 1008, /* For non-emergency number dialed
+ during emergency callback mode */
+ CALL_FAIL_CDMA_ACCESS_BLOCKED = 1009, /* CDMA network access probes blocked */
+
+ /* OEM specific error codes. Used to distinguish error from
+ * CALL_FAIL_ERROR_UNSPECIFIED and help assist debugging */
+ CALL_FAIL_OEM_CAUSE_1 = 0xf001,
+ CALL_FAIL_OEM_CAUSE_2 = 0xf002,
+ CALL_FAIL_OEM_CAUSE_3 = 0xf003,
+ CALL_FAIL_OEM_CAUSE_4 = 0xf004,
+ CALL_FAIL_OEM_CAUSE_5 = 0xf005,
+ CALL_FAIL_OEM_CAUSE_6 = 0xf006,
+ CALL_FAIL_OEM_CAUSE_7 = 0xf007,
+ CALL_FAIL_OEM_CAUSE_8 = 0xf008,
+ CALL_FAIL_OEM_CAUSE_9 = 0xf009,
+ CALL_FAIL_OEM_CAUSE_10 = 0xf00a,
+ CALL_FAIL_OEM_CAUSE_11 = 0xf00b,
+ CALL_FAIL_OEM_CAUSE_12 = 0xf00c,
+ CALL_FAIL_OEM_CAUSE_13 = 0xf00d,
+ CALL_FAIL_OEM_CAUSE_14 = 0xf00e,
+ CALL_FAIL_OEM_CAUSE_15 = 0xf00f,
+
+ CALL_FAIL_ERROR_UNSPECIFIED = 0xffff /* This error will be deprecated soon,
+ vendor code should make sure to map error
+ code to specific error */
+} RIL_LastCallFailCause;
+
+typedef struct {
+ RIL_LastCallFailCause cause_code;
+ char * vendor_cause;
+} RIL_LastCallFailCauseInfo;
+
+/* See RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE */
+typedef enum {
+ PDP_FAIL_NONE = 0, /* No error, connection ok */
+
+ /* an integer cause code defined in TS 24.008
+ section 6.1.3.1.3 or TS 24.301 Release 8+ Annex B.
+ If the implementation does not have access to the exact cause codes,
+ then it should return one of the following values,
+ as the UI layer needs to distinguish these
+ cases for error notification and potential retries. */
+ PDP_FAIL_OPERATOR_BARRED = 0x08, /* no retry */
+ PDP_FAIL_NAS_SIGNALLING = 0x0E,
+ PDP_FAIL_LLC_SNDCP = 0x19,
+ PDP_FAIL_INSUFFICIENT_RESOURCES = 0x1A,
+ PDP_FAIL_MISSING_UKNOWN_APN = 0x1B, /* no retry */
+ PDP_FAIL_UNKNOWN_PDP_ADDRESS_TYPE = 0x1C, /* no retry */
+ PDP_FAIL_USER_AUTHENTICATION = 0x1D, /* no retry */
+ PDP_FAIL_ACTIVATION_REJECT_GGSN = 0x1E, /* no retry */
+ PDP_FAIL_ACTIVATION_REJECT_UNSPECIFIED = 0x1F,
+ PDP_FAIL_SERVICE_OPTION_NOT_SUPPORTED = 0x20, /* no retry */
+ PDP_FAIL_SERVICE_OPTION_NOT_SUBSCRIBED = 0x21, /* no retry */
+ PDP_FAIL_SERVICE_OPTION_OUT_OF_ORDER = 0x22,
+ PDP_FAIL_NSAPI_IN_USE = 0x23, /* no retry */
+ PDP_FAIL_REGULAR_DEACTIVATION = 0x24, /* possibly restart radio,
+ based on framework config */
+ PDP_FAIL_QOS_NOT_ACCEPTED = 0x25,
+ PDP_FAIL_NETWORK_FAILURE = 0x26,
+ PDP_FAIL_UMTS_REACTIVATION_REQ = 0x27,
+ PDP_FAIL_FEATURE_NOT_SUPP = 0x28,
+ PDP_FAIL_TFT_SEMANTIC_ERROR = 0x29,
+ PDP_FAIL_TFT_SYTAX_ERROR = 0x2A,
+ PDP_FAIL_UNKNOWN_PDP_CONTEXT = 0x2B,
+ PDP_FAIL_FILTER_SEMANTIC_ERROR = 0x2C,
+ PDP_FAIL_FILTER_SYTAX_ERROR = 0x2D,
+ PDP_FAIL_PDP_WITHOUT_ACTIVE_TFT = 0x2E,
+ PDP_FAIL_ONLY_IPV4_ALLOWED = 0x32, /* no retry */
+ PDP_FAIL_ONLY_IPV6_ALLOWED = 0x33, /* no retry */
+ PDP_FAIL_ONLY_SINGLE_BEARER_ALLOWED = 0x34,
+ PDP_FAIL_ESM_INFO_NOT_RECEIVED = 0x35,
+ PDP_FAIL_PDN_CONN_DOES_NOT_EXIST = 0x36,
+ PDP_FAIL_MULTI_CONN_TO_SAME_PDN_NOT_ALLOWED = 0x37,
+ PDP_FAIL_MAX_ACTIVE_PDP_CONTEXT_REACHED = 0x41,
+ PDP_FAIL_UNSUPPORTED_APN_IN_CURRENT_PLMN = 0x42,
+ PDP_FAIL_INVALID_TRANSACTION_ID = 0x51,
+ PDP_FAIL_MESSAGE_INCORRECT_SEMANTIC = 0x5F,
+ PDP_FAIL_INVALID_MANDATORY_INFO = 0x60,
+ PDP_FAIL_MESSAGE_TYPE_UNSUPPORTED = 0x61,
+ PDP_FAIL_MSG_TYPE_NONCOMPATIBLE_STATE = 0x62,
+ PDP_FAIL_UNKNOWN_INFO_ELEMENT = 0x63,
+ PDP_FAIL_CONDITIONAL_IE_ERROR = 0x64,
+ PDP_FAIL_MSG_AND_PROTOCOL_STATE_UNCOMPATIBLE = 0x65,
+ PDP_FAIL_PROTOCOL_ERRORS = 0x6F, /* no retry */
+ PDP_FAIL_APN_TYPE_CONFLICT = 0x70,
+ PDP_FAIL_INVALID_PCSCF_ADDR = 0x71,
+ PDP_FAIL_INTERNAL_CALL_PREEMPT_BY_HIGH_PRIO_APN = 0x72,
+ PDP_FAIL_EMM_ACCESS_BARRED = 0x73,
+ PDP_FAIL_EMERGENCY_IFACE_ONLY = 0x74,
+ PDP_FAIL_IFACE_MISMATCH = 0x75,
+ PDP_FAIL_COMPANION_IFACE_IN_USE = 0x76,
+ PDP_FAIL_IP_ADDRESS_MISMATCH = 0x77,
+ PDP_FAIL_IFACE_AND_POL_FAMILY_MISMATCH = 0x78,
+ PDP_FAIL_EMM_ACCESS_BARRED_INFINITE_RETRY = 0x79,
+ PDP_FAIL_AUTH_FAILURE_ON_EMERGENCY_CALL = 0x7A,
+
+ // OEM specific error codes. To be used by OEMs when they don't want to
+ // reveal error code which would be replaced by PDP_FAIL_ERROR_UNSPECIFIED
+ PDP_FAIL_OEM_DCFAILCAUSE_1 = 0x1001,
+ PDP_FAIL_OEM_DCFAILCAUSE_2 = 0x1002,
+ PDP_FAIL_OEM_DCFAILCAUSE_3 = 0x1003,
+ PDP_FAIL_OEM_DCFAILCAUSE_4 = 0x1004,
+ PDP_FAIL_OEM_DCFAILCAUSE_5 = 0x1005,
+ PDP_FAIL_OEM_DCFAILCAUSE_6 = 0x1006,
+ PDP_FAIL_OEM_DCFAILCAUSE_7 = 0x1007,
+ PDP_FAIL_OEM_DCFAILCAUSE_8 = 0x1008,
+ PDP_FAIL_OEM_DCFAILCAUSE_9 = 0x1009,
+ PDP_FAIL_OEM_DCFAILCAUSE_10 = 0x100A,
+ PDP_FAIL_OEM_DCFAILCAUSE_11 = 0x100B,
+ PDP_FAIL_OEM_DCFAILCAUSE_12 = 0x100C,
+ PDP_FAIL_OEM_DCFAILCAUSE_13 = 0x100D,
+ PDP_FAIL_OEM_DCFAILCAUSE_14 = 0x100E,
+ PDP_FAIL_OEM_DCFAILCAUSE_15 = 0x100F,
+
+ /* Not mentioned in the specification */
+ PDP_FAIL_VOICE_REGISTRATION_FAIL = -1,
+ PDP_FAIL_DATA_REGISTRATION_FAIL = -2,
+
+ /* reasons for data call drop - network/modem disconnect */
+ PDP_FAIL_SIGNAL_LOST = -3,
+ PDP_FAIL_PREF_RADIO_TECH_CHANGED = -4,/* preferred technology has changed, should retry
+ with parameters appropriate for new technology */
+ PDP_FAIL_RADIO_POWER_OFF = -5, /* data call was disconnected because radio was resetting,
+ powered off - no retry */
+ PDP_FAIL_TETHERED_CALL_ACTIVE = -6, /* data call was disconnected by modem because tethered
+ mode was up on same APN/data profile - no retry until
+ tethered call is off */
+
+ PDP_FAIL_ERROR_UNSPECIFIED = 0xffff, /* retry silently. Will be deprecated soon as
+ new error codes are added making this unnecessary */
+} RIL_DataCallFailCause;
+
+/* See RIL_REQUEST_SETUP_DATA_CALL */
+typedef enum {
+ RIL_DATA_PROFILE_DEFAULT = 0,
+ RIL_DATA_PROFILE_TETHERED = 1,
+ RIL_DATA_PROFILE_IMS = 2,
+ RIL_DATA_PROFILE_FOTA = 3,
+ RIL_DATA_PROFILE_CBS = 4,
+ RIL_DATA_PROFILE_OEM_BASE = 1000, /* Start of OEM-specific profiles */
+ RIL_DATA_PROFILE_INVALID = 0xFFFFFFFF
+} RIL_DataProfile;
+
+/* Used by RIL_UNSOL_SUPP_SVC_NOTIFICATION */
+typedef struct {
+ int notificationType; /*
+ * 0 = MO intermediate result code
+ * 1 = MT unsolicited result code
+ */
+ int code; /* See 27.007 7.17
+ "code1" for MO
+ "code2" for MT. */
+ int index; /* CUG index. See 27.007 7.17. */
+ int type; /* "type" from 27.007 7.17 (MT only). */
+ char * number; /* "number" from 27.007 7.17
+ (MT only, may be NULL). */
+} RIL_SuppSvcNotification;
+
+#define RIL_CARD_MAX_APPS 8
+
+typedef enum {
+ RIL_CARDSTATE_ABSENT = 0,
+ RIL_CARDSTATE_PRESENT = 1,
+ RIL_CARDSTATE_ERROR = 2,
+ RIL_CARDSTATE_RESTRICTED = 3 /* card is present but not usable due to carrier restrictions.*/
+} RIL_CardState;
+
+typedef enum {
+ RIL_PERSOSUBSTATE_UNKNOWN = 0, /* initial state */
+ RIL_PERSOSUBSTATE_IN_PROGRESS = 1, /* in between each lock transition */
+ RIL_PERSOSUBSTATE_READY = 2, /* when either SIM or RUIM Perso is finished
+ since each app can only have 1 active perso
+ involved */
+ RIL_PERSOSUBSTATE_SIM_NETWORK = 3,
+ RIL_PERSOSUBSTATE_SIM_NETWORK_SUBSET = 4,
+ RIL_PERSOSUBSTATE_SIM_CORPORATE = 5,
+ RIL_PERSOSUBSTATE_SIM_SERVICE_PROVIDER = 6,
+ RIL_PERSOSUBSTATE_SIM_SIM = 7,
+ RIL_PERSOSUBSTATE_SIM_NETWORK_PUK = 8, /* The corresponding perso lock is blocked */
+ RIL_PERSOSUBSTATE_SIM_NETWORK_SUBSET_PUK = 9,
+ RIL_PERSOSUBSTATE_SIM_CORPORATE_PUK = 10,
+ RIL_PERSOSUBSTATE_SIM_SERVICE_PROVIDER_PUK = 11,
+ RIL_PERSOSUBSTATE_SIM_SIM_PUK = 12,
+ RIL_PERSOSUBSTATE_RUIM_NETWORK1 = 13,
+ RIL_PERSOSUBSTATE_RUIM_NETWORK2 = 14,
+ RIL_PERSOSUBSTATE_RUIM_HRPD = 15,
+ RIL_PERSOSUBSTATE_RUIM_CORPORATE = 16,
+ RIL_PERSOSUBSTATE_RUIM_SERVICE_PROVIDER = 17,
+ RIL_PERSOSUBSTATE_RUIM_RUIM = 18,
+ RIL_PERSOSUBSTATE_RUIM_NETWORK1_PUK = 19, /* The corresponding perso lock is blocked */
+ RIL_PERSOSUBSTATE_RUIM_NETWORK2_PUK = 20,
+ RIL_PERSOSUBSTATE_RUIM_HRPD_PUK = 21,
+ RIL_PERSOSUBSTATE_RUIM_CORPORATE_PUK = 22,
+ RIL_PERSOSUBSTATE_RUIM_SERVICE_PROVIDER_PUK = 23,
+ RIL_PERSOSUBSTATE_RUIM_RUIM_PUK = 24
+} RIL_PersoSubstate;
+
+typedef enum {
+ RIL_APPSTATE_UNKNOWN = 0,
+ RIL_APPSTATE_DETECTED = 1,
+ RIL_APPSTATE_PIN = 2, /* If PIN1 or UPin is required */
+ RIL_APPSTATE_PUK = 3, /* If PUK1 or Puk for UPin is required */
+ RIL_APPSTATE_SUBSCRIPTION_PERSO = 4, /* perso_substate should be look at
+ when app_state is assigned to this value */
+ RIL_APPSTATE_READY = 5
+} RIL_AppState;
+
+typedef enum {
+ RIL_PINSTATE_UNKNOWN = 0,
+ RIL_PINSTATE_ENABLED_NOT_VERIFIED = 1,
+ RIL_PINSTATE_ENABLED_VERIFIED = 2,
+ RIL_PINSTATE_DISABLED = 3,
+ RIL_PINSTATE_ENABLED_BLOCKED = 4,
+ RIL_PINSTATE_ENABLED_PERM_BLOCKED = 5
+} RIL_PinState;
+
+typedef enum {
+ RIL_APPTYPE_UNKNOWN = 0,
+ RIL_APPTYPE_SIM = 1,
+ RIL_APPTYPE_USIM = 2,
+ RIL_APPTYPE_RUIM = 3,
+ RIL_APPTYPE_CSIM = 4,
+ RIL_APPTYPE_ISIM = 5
+} RIL_AppType;
+
+/*
+ * Please note that registration state UNKNOWN is
+ * treated as "out of service" in the Android telephony.
+ * Registration state REG_DENIED must be returned if Location Update
+ * Reject (with cause 17 - Network Failure) is received
+ * repeatedly from the network, to facilitate
+ * "managed roaming"
+ */
+typedef enum {
+ RIL_NOT_REG_AND_NOT_SEARCHING = 0, // Not registered, MT is not currently searching
+ // a new operator to register
+ RIL_REG_HOME = 1, // Registered, home network
+ RIL_NOT_REG_AND_SEARCHING = 2, // Not registered, but MT is currently searching
+ // a new operator to register
+ RIL_REG_DENIED = 3, // Registration denied
+ RIL_UNKNOWN = 4, // Unknown
+ RIL_REG_ROAMING = 5, // Registered, roaming
+ RIL_NOT_REG_AND_EMERGENCY_AVAILABLE_AND_NOT_SEARCHING = 10, // Same as
+ // RIL_NOT_REG_AND_NOT_SEARCHING but indicates that
+ // emergency calls are enabled.
+ RIL_NOT_REG_AND_EMERGENCY_AVAILABLE_AND_SEARCHING = 12, // Same as RIL_NOT_REG_AND_SEARCHING
+ // but indicates that
+ // emergency calls are enabled.
+ RIL_REG_DENIED_AND_EMERGENCY_AVAILABLE = 13, // Same as REG_DENIED but indicates that
+ // emergency calls are enabled.
+ RIL_UNKNOWN_AND_EMERGENCY_AVAILABLE = 14, // Same as UNKNOWN but indicates that
+ // emergency calls are enabled.
+} RIL_RegState;
+
+typedef struct
+{
+ RIL_AppType app_type;
+ RIL_AppState app_state;
+ RIL_PersoSubstate perso_substate; /* applicable only if app_state ==
+ RIL_APPSTATE_SUBSCRIPTION_PERSO */
+ char *aid_ptr; /* null terminated string, e.g., from 0xA0, 0x00 -> 0x41,
+ 0x30, 0x30, 0x30 */
+ char *app_label_ptr; /* null terminated string */
+ int pin1_replaced; /* applicable to USIM, CSIM & ISIM */
+ RIL_PinState pin1;
+ RIL_PinState pin2;
+} RIL_AppStatus;
+
+/* Deprecated, use RIL_CardStatus_v6 */
+typedef struct
+{
+ RIL_CardState card_state;
+ RIL_PinState universal_pin_state; /* applicable to USIM and CSIM: RIL_PINSTATE_xxx */
+ int gsm_umts_subscription_app_index; /* value < RIL_CARD_MAX_APPS, -1 if none */
+ int cdma_subscription_app_index; /* value < RIL_CARD_MAX_APPS, -1 if none */
+ int num_applications; /* value <= RIL_CARD_MAX_APPS */
+ RIL_AppStatus applications[RIL_CARD_MAX_APPS];
+} RIL_CardStatus_v5;
+
+typedef struct
+{
+ RIL_CardState card_state;
+ RIL_PinState universal_pin_state; /* applicable to USIM and CSIM: RIL_PINSTATE_xxx */
+ int gsm_umts_subscription_app_index; /* value < RIL_CARD_MAX_APPS, -1 if none */
+ int cdma_subscription_app_index; /* value < RIL_CARD_MAX_APPS, -1 if none */
+ int ims_subscription_app_index; /* value < RIL_CARD_MAX_APPS, -1 if none */
+ int num_applications; /* value <= RIL_CARD_MAX_APPS */
+ RIL_AppStatus applications[RIL_CARD_MAX_APPS];
+} RIL_CardStatus_v6;
+
+/** The result of a SIM refresh, returned in data[0] of RIL_UNSOL_SIM_REFRESH
+ * or as part of RIL_SimRefreshResponse_v7
+ */
+typedef enum {
+ /* A file on SIM has been updated. data[1] contains the EFID. */
+ SIM_FILE_UPDATE = 0,
+ /* SIM initialized. All files should be re-read. */
+ SIM_INIT = 1,
+ /* SIM reset. SIM power required, SIM may be locked and all files should be re-read. */
+ SIM_RESET = 2
+} RIL_SimRefreshResult;
+
+typedef struct {
+ RIL_SimRefreshResult result;
+ int ef_id; /* is the EFID of the updated file if the result is */
+ /* SIM_FILE_UPDATE or 0 for any other result. */
+ char * aid; /* is AID(application ID) of the card application */
+ /* See ETSI 102.221 8.1 and 101.220 4 */
+ /* For SIM_FILE_UPDATE result it can be set to AID of */
+ /* application in which updated EF resides or it can be */
+ /* NULL if EF is outside of an application. */
+ /* For SIM_INIT result this field is set to AID of */
+ /* application that caused REFRESH */
+ /* For SIM_RESET result it is NULL. */
+} RIL_SimRefreshResponse_v7;
+
+/* Deprecated, use RIL_CDMA_CallWaiting_v6 */
+typedef struct {
+ char * number; /* Remote party number */
+ int numberPresentation; /* 0=Allowed, 1=Restricted, 2=Not Specified/Unknown */
+ char * name; /* Remote party name */
+ RIL_CDMA_SignalInfoRecord signalInfoRecord;
+} RIL_CDMA_CallWaiting_v5;
+
+typedef struct {
+ char * number; /* Remote party number */
+ int numberPresentation; /* 0=Allowed, 1=Restricted, 2=Not Specified/Unknown */
+ char * name; /* Remote party name */
+ RIL_CDMA_SignalInfoRecord signalInfoRecord;
+ /* Number type/Number plan required to support International Call Waiting */
+ int number_type; /* 0=Unknown, 1=International, 2=National,
+ 3=Network specific, 4=subscriber */
+ int number_plan; /* 0=Unknown, 1=ISDN, 3=Data, 4=Telex, 8=Nat'l, 9=Private */
+} RIL_CDMA_CallWaiting_v6;
+
+/**
+ * Which types of Cell Broadcast Message (CBM) are to be received by the ME
+ *
+ * uFromServiceID - uToServiceID defines a range of CBM message identifiers
+ * whose value is 0x0000 - 0xFFFF as defined in TS 23.041 9.4.1.2.2 for GMS
+ * and 9.4.4.2.2 for UMTS. All other values can be treated as empty
+ * CBM message ID.
+ *
+ * uFromCodeScheme - uToCodeScheme defines a range of CBM data coding schemes
+ * whose value is 0x00 - 0xFF as defined in TS 23.041 9.4.1.2.3 for GMS
+ * and 9.4.4.2.3 for UMTS.
+ * All other values can be treated as empty CBM data coding scheme.
+ *
+ * selected 0 means message types specified in <fromServiceId, toServiceId>
+ * and <fromCodeScheme, toCodeScheme>are not accepted, while 1 means accepted.
+ *
+ * Used by RIL_REQUEST_GSM_GET_BROADCAST_CONFIG and
+ * RIL_REQUEST_GSM_SET_BROADCAST_CONFIG.
+ */
+typedef struct {
+ int fromServiceId;
+ int toServiceId;
+ int fromCodeScheme;
+ int toCodeScheme;
+ unsigned char selected;
+} RIL_GSM_BroadcastSmsConfigInfo;
+
+/* No restriction at all including voice/SMS/USSD/SS/AV64 and packet data. */
+#define RIL_RESTRICTED_STATE_NONE 0x00
+/* Block emergency call due to restriction. But allow all normal voice/SMS/USSD/SS/AV64. */
+#define RIL_RESTRICTED_STATE_CS_EMERGENCY 0x01
+/* Block all normal voice/SMS/USSD/SS/AV64 due to restriction. Only Emergency call allowed. */
+#define RIL_RESTRICTED_STATE_CS_NORMAL 0x02
+/* Block all voice/SMS/USSD/SS/AV64 including emergency call due to restriction.*/
+#define RIL_RESTRICTED_STATE_CS_ALL 0x04
+/* Block packet data access due to restriction. */
+#define RIL_RESTRICTED_STATE_PS_ALL 0x10
+
+/* The status for an OTASP/OTAPA session */
+typedef enum {
+ CDMA_OTA_PROVISION_STATUS_SPL_UNLOCKED,
+ CDMA_OTA_PROVISION_STATUS_SPC_RETRIES_EXCEEDED,
+ CDMA_OTA_PROVISION_STATUS_A_KEY_EXCHANGED,
+ CDMA_OTA_PROVISION_STATUS_SSD_UPDATED,
+ CDMA_OTA_PROVISION_STATUS_NAM_DOWNLOADED,
+ CDMA_OTA_PROVISION_STATUS_MDN_DOWNLOADED,
+ CDMA_OTA_PROVISION_STATUS_IMSI_DOWNLOADED,
+ CDMA_OTA_PROVISION_STATUS_PRL_DOWNLOADED,
+ CDMA_OTA_PROVISION_STATUS_COMMITTED,
+ CDMA_OTA_PROVISION_STATUS_OTAPA_STARTED,
+ CDMA_OTA_PROVISION_STATUS_OTAPA_STOPPED,
+ CDMA_OTA_PROVISION_STATUS_OTAPA_ABORTED
+} RIL_CDMA_OTA_ProvisionStatus;
+
+typedef struct {
+ int signalStrength; /* Valid values are (0-31, 99) as defined in TS 27.007 8.5 */
+ int bitErrorRate; /* bit error rate (0-7, 99) as defined in TS 27.007 8.5 */
+} RIL_GW_SignalStrength;
+
+typedef struct {
+ int signalStrength; /* Valid values are (0-31, 99) as defined in TS 27.007 8.5 */
+ int bitErrorRate; /* bit error rate (0-7, 99) as defined in TS 27.007 8.5 */
+ int timingAdvance; /* Timing Advance in bit periods. 1 bit period = 48/13 us.
+ * INT_MAX denotes invalid value */
+} RIL_GSM_SignalStrength_v12;
+
+typedef struct {
+ int signalStrength; /* Valid values are (0-31, 99) as defined in TS 27.007 8.5 */
+ int bitErrorRate; /* bit error rate (0-7, 99) as defined in TS 27.007 8.5 */
+} RIL_SignalStrengthWcdma;
+
+typedef struct {
+ int dbm; /* Valid values are positive integers. This value is the actual RSSI value
+ * multiplied by -1. Example: If the actual RSSI is -75, then this response
+ * value will be 75.
+ */
+ int ecio; /* Valid values are positive integers. This value is the actual Ec/Io multiplied
+ * by -10. Example: If the actual Ec/Io is -12.5 dB, then this response value
+ * will be 125.
+ */
+} RIL_CDMA_SignalStrength;
+
+
+typedef struct {
+ int dbm; /* Valid values are positive integers. This value is the actual RSSI value
+ * multiplied by -1. Example: If the actual RSSI is -75, then this response
+ * value will be 75.
+ */
+ int ecio; /* Valid values are positive integers. This value is the actual Ec/Io multiplied
+ * by -10. Example: If the actual Ec/Io is -12.5 dB, then this response value
+ * will be 125.
+ */
+ int signalNoiseRatio; /* Valid values are 0-8. 8 is the highest signal to noise ratio. */
+} RIL_EVDO_SignalStrength;
+
+typedef struct {
+ int signalStrength; /* Valid values are (0-31, 99) as defined in TS 27.007 8.5 */
+ int rsrp; /* The current Reference Signal Receive Power in dBm multipled by -1.
+ * Range: 44 to 140 dBm
+ * INT_MAX: 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.133 9.1.4 */
+ int rsrq; /* The current Reference Signal Receive Quality in dB multiplied by -1.
+ * Range: 20 to 3 dB.
+ * INT_MAX: 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.133 9.1.7 */
+ int rssnr; /* The current reference signal signal-to-noise ratio in 0.1 dB units.
+ * Range: -200 to +300 (-200 = -20.0 dB, +300 = 30dB).
+ * INT_MAX : 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.101 8.1.1 */
+ int cqi; /* The current Channel Quality Indicator.
+ * Range: 0 to 15.
+ * INT_MAX : 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.101 9.2, 9.3, A.4 */
+} RIL_LTE_SignalStrength;
+
+typedef struct {
+ int signalStrength; /* Valid values are (0-31, 99) as defined in TS 27.007 8.5 */
+ int rsrp; /* The current Reference Signal Receive Power in dBm multipled by -1.
+ * Range: 44 to 140 dBm
+ * INT_MAX: 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.133 9.1.4 */
+ int rsrq; /* The current Reference Signal Receive Quality in dB multiplied by -1.
+ * Range: 20 to 3 dB.
+ * INT_MAX: 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.133 9.1.7 */
+ int rssnr; /* The current reference signal signal-to-noise ratio in 0.1 dB units.
+ * Range: -200 to +300 (-200 = -20.0 dB, +300 = 30dB).
+ * INT_MAX : 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.101 8.1.1 */
+ int cqi; /* The current Channel Quality Indicator.
+ * Range: 0 to 15.
+ * INT_MAX : 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 36.101 9.2, 9.3, A.4 */
+ int timingAdvance; /* timing advance in micro seconds for a one way trip from cell to device.
+ * Approximate distance can be calculated using 300m/us * timingAdvance.
+ * Range: 0 to 0x7FFFFFFE
+ * INT_MAX : 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP 36.321 section 6.1.3.5
+ * also: http://www.cellular-planningoptimization.com/2010/02/timing-advance-with-calculation.html */
+} RIL_LTE_SignalStrength_v8;
+
+typedef struct {
+ int rscp; /* The Received Signal Code Power in dBm multipled by -1.
+ * Range : 25 to 120
+ * INT_MAX: 0x7FFFFFFF denotes invalid value.
+ * Reference: 3GPP TS 25.123, section 9.1.1.1 */
+} RIL_TD_SCDMA_SignalStrength;
+
+/* Deprecated, use RIL_SignalStrength_v6 */
+typedef struct {
+ RIL_GW_SignalStrength GW_SignalStrength;
+ RIL_CDMA_SignalStrength CDMA_SignalStrength;
+ RIL_EVDO_SignalStrength EVDO_SignalStrength;
+} RIL_SignalStrength_v5;
+
+typedef struct {
+ RIL_GW_SignalStrength GW_SignalStrength;
+ RIL_CDMA_SignalStrength CDMA_SignalStrength;
+ RIL_EVDO_SignalStrength EVDO_SignalStrength;
+ RIL_LTE_SignalStrength LTE_SignalStrength;
+} RIL_SignalStrength_v6;
+
+typedef struct {
+ RIL_GW_SignalStrength GW_SignalStrength;
+ RIL_CDMA_SignalStrength CDMA_SignalStrength;
+ RIL_EVDO_SignalStrength EVDO_SignalStrength;
+ RIL_LTE_SignalStrength_v8 LTE_SignalStrength;
+} RIL_SignalStrength_v8;
+
+typedef struct {
+ RIL_GW_SignalStrength GW_SignalStrength;
+ RIL_CDMA_SignalStrength CDMA_SignalStrength;
+ RIL_EVDO_SignalStrength EVDO_SignalStrength;
+ RIL_LTE_SignalStrength_v8 LTE_SignalStrength;
+ RIL_TD_SCDMA_SignalStrength TD_SCDMA_SignalStrength;
+} RIL_SignalStrength_v10;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int lac; /* 16-bit Location Area Code, 0..65535, INT_MAX if unknown */
+ int cid; /* 16-bit GSM Cell Identity described in TS 27.007, 0..65535, INT_MAX if unknown */
+} RIL_CellIdentityGsm;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int lac; /* 16-bit Location Area Code, 0..65535, INT_MAX if unknown */
+ int cid; /* 16-bit GSM Cell Identity described in TS 27.007, 0..65535, INT_MAX if unknown */
+ int arfcn; /* 16-bit GSM Absolute RF channel number; this value must be reported */
+ uint8_t bsic; /* 6-bit Base Station Identity Code; 0xFF if unknown */
+} RIL_CellIdentityGsm_v12;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int lac; /* 16-bit Location Area Code, 0..65535, INT_MAX if unknown */
+ int cid; /* 28-bit UMTS Cell Identity described in TS 25.331, 0..268435455, INT_MAX if unknown */
+ int psc; /* 9-bit UMTS Primary Scrambling Code described in TS 25.331, 0..511, INT_MAX if unknown */
+} RIL_CellIdentityWcdma;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int lac; /* 16-bit Location Area Code, 0..65535, INT_MAX if unknown */
+ int cid; /* 28-bit UMTS Cell Identity described in TS 25.331, 0..268435455, INT_MAX if unknown */
+ int psc; /* 9-bit UMTS Primary Scrambling Code described in TS 25.331, 0..511; this value must be reported */
+ int uarfcn; /* 16-bit UMTS Absolute RF Channel Number; this value must be reported */
+} RIL_CellIdentityWcdma_v12;
+
+typedef struct {
+ int networkId; /* Network Id 0..65535, INT_MAX if unknown */
+ int systemId; /* CDMA System Id 0..32767, INT_MAX if unknown */
+ int basestationId; /* Base Station Id 0..65535, INT_MAX if unknown */
+ int longitude; /* Longitude is a decimal number as specified in 3GPP2 C.S0005-A v6.0.
+ * It is represented in units of 0.25 seconds and ranges from -2592000
+ * to 2592000, both values inclusive (corresponding to a range of -180
+ * to +180 degrees). INT_MAX if unknown */
+
+ int latitude; /* Latitude is a decimal number as specified in 3GPP2 C.S0005-A v6.0.
+ * It is represented in units of 0.25 seconds and ranges from -1296000
+ * to 1296000, both values inclusive (corresponding to a range of -90
+ * to +90 degrees). INT_MAX if unknown */
+} RIL_CellIdentityCdma;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int ci; /* 28-bit Cell Identity described in TS ???, INT_MAX if unknown */
+ int pci; /* physical cell id 0..503, INT_MAX if unknown */
+ int tac; /* 16-bit tracking area code, INT_MAX if unknown */
+} RIL_CellIdentityLte;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int ci; /* 28-bit Cell Identity described in TS ???, INT_MAX if unknown */
+ int pci; /* physical cell id 0..503; this value must be reported */
+ int tac; /* 16-bit tracking area code, INT_MAX if unknown */
+ int earfcn; /* 18-bit LTE Absolute RF Channel Number; this value must be reported */
+} RIL_CellIdentityLte_v12;
+
+typedef struct {
+ int mcc; /* 3-digit Mobile Country Code, 0..999, INT_MAX if unknown */
+ int mnc; /* 2 or 3-digit Mobile Network Code, 0..999;
+ the most significant nibble encodes the number of digits - {2, 3, 0 (unset)};
+ INT_MAX if unknown */
+ int lac; /* 16-bit Location Area Code, 0..65535, INT_MAX if unknown */
+ int cid; /* 28-bit UMTS Cell Identity described in TS 25.331, 0..268435455, INT_MAX if unknown */
+ int cpid; /* 8-bit Cell Parameters ID described in TS 25.331, 0..127, INT_MAX if unknown */
+} RIL_CellIdentityTdscdma;
+
+typedef struct {
+ RIL_CellIdentityGsm cellIdentityGsm;
+ RIL_GW_SignalStrength signalStrengthGsm;
+} RIL_CellInfoGsm;
+
+typedef struct {
+ RIL_CellIdentityGsm_v12 cellIdentityGsm;
+ RIL_GSM_SignalStrength_v12 signalStrengthGsm;
+} RIL_CellInfoGsm_v12;
+
+typedef struct {
+ RIL_CellIdentityWcdma cellIdentityWcdma;
+ RIL_SignalStrengthWcdma signalStrengthWcdma;
+} RIL_CellInfoWcdma;
+
+typedef struct {
+ RIL_CellIdentityWcdma_v12 cellIdentityWcdma;
+ RIL_SignalStrengthWcdma signalStrengthWcdma;
+} RIL_CellInfoWcdma_v12;
+
+typedef struct {
+ RIL_CellIdentityCdma cellIdentityCdma;
+ RIL_CDMA_SignalStrength signalStrengthCdma;
+ RIL_EVDO_SignalStrength signalStrengthEvdo;
+} RIL_CellInfoCdma;
+
+typedef struct {
+ RIL_CellIdentityLte cellIdentityLte;
+ RIL_LTE_SignalStrength_v8 signalStrengthLte;
+} RIL_CellInfoLte;
+
+typedef struct {
+ RIL_CellIdentityLte_v12 cellIdentityLte;
+ RIL_LTE_SignalStrength_v8 signalStrengthLte;
+} RIL_CellInfoLte_v12;
+
+typedef struct {
+ RIL_CellIdentityTdscdma cellIdentityTdscdma;
+ RIL_TD_SCDMA_SignalStrength signalStrengthTdscdma;
+} RIL_CellInfoTdscdma;
+
+// Must be the same as CellInfo.TYPE_XXX
+typedef enum {
+ RIL_CELL_INFO_TYPE_NONE = 0, /* indicates no cell information */
+ RIL_CELL_INFO_TYPE_GSM = 1,
+ RIL_CELL_INFO_TYPE_CDMA = 2,
+ RIL_CELL_INFO_TYPE_LTE = 3,
+ RIL_CELL_INFO_TYPE_WCDMA = 4,
+ RIL_CELL_INFO_TYPE_TD_SCDMA = 5
+} RIL_CellInfoType;
+
+// Must be the same as CellInfo.TIMESTAMP_TYPE_XXX
+typedef enum {
+ RIL_TIMESTAMP_TYPE_UNKNOWN = 0,
+ RIL_TIMESTAMP_TYPE_ANTENNA = 1,
+ RIL_TIMESTAMP_TYPE_MODEM = 2,
+ RIL_TIMESTAMP_TYPE_OEM_RIL = 3,
+ RIL_TIMESTAMP_TYPE_JAVA_RIL = 4,
+} RIL_TimeStampType;
+
+typedef struct {
+ RIL_CellInfoType cellInfoType; /* cell type for selecting from union CellInfo */
+ int registered; /* !0 if this cell is registered 0 if not registered */
+ RIL_TimeStampType timeStampType; /* type of time stamp represented by timeStamp */
+ uint64_t timeStamp; /* Time in nanos as returned by ril_nano_time */
+ union {
+ RIL_CellInfoGsm gsm;
+ RIL_CellInfoCdma cdma;
+ RIL_CellInfoLte lte;
+ RIL_CellInfoWcdma wcdma;
+ RIL_CellInfoTdscdma tdscdma;
+ } CellInfo;
+} RIL_CellInfo;
+
+typedef struct {
+ RIL_CellInfoType cellInfoType; /* cell type for selecting from union CellInfo */
+ int registered; /* !0 if this cell is registered 0 if not registered */
+ RIL_TimeStampType timeStampType; /* type of time stamp represented by timeStamp */
+ uint64_t timeStamp; /* Time in nanos as returned by ril_nano_time */
+ union {
+ RIL_CellInfoGsm_v12 gsm;
+ RIL_CellInfoCdma cdma;
+ RIL_CellInfoLte_v12 lte;
+ RIL_CellInfoWcdma_v12 wcdma;
+ RIL_CellInfoTdscdma tdscdma;
+ } CellInfo;
+} RIL_CellInfo_v12;
+
+typedef struct {
+ RIL_CellInfoType cellInfoType; /* cell type for selecting from union CellInfo */
+ union {
+ RIL_CellIdentityGsm_v12 cellIdentityGsm;
+ RIL_CellIdentityWcdma_v12 cellIdentityWcdma;
+ RIL_CellIdentityLte_v12 cellIdentityLte;
+ RIL_CellIdentityTdscdma cellIdentityTdscdma;
+ RIL_CellIdentityCdma cellIdentityCdma;
+ };
+}RIL_CellIdentity_v16;
+
+typedef struct {
+ RIL_RegState regState; // Valid reg states are RIL_NOT_REG_AND_NOT_SEARCHING,
+ // REG_HOME, RIL_NOT_REG_AND_SEARCHING, REG_DENIED,
+ // UNKNOWN, REG_ROAMING defined in RegState
+ RIL_RadioTechnology rat; // indicates the available voice radio technology,
+ // valid values as defined by RadioTechnology.
+ int32_t cssSupported; // concurrent services support indicator. if
+ // registered on a CDMA system.
+ // 0 - Concurrent services not supported,
+ // 1 - Concurrent services supported
+ int32_t roamingIndicator; // TSB-58 Roaming Indicator if registered
+ // on a CDMA or EVDO system or -1 if not.
+ // Valid values are 0-255.
+ int32_t systemIsInPrl; // indicates whether the current system is in the
+ // PRL if registered on a CDMA or EVDO system or -1 if
+ // not. 0=not in the PRL, 1=in the PRL
+ int32_t defaultRoamingIndicator; // default Roaming Indicator from the PRL,
+ // if registered on a CDMA or EVDO system or -1 if not.
+ // Valid values are 0-255.
+ int32_t reasonForDenial; // reasonForDenial if registration state is 3
+ // (Registration denied) this is an enumerated reason why
+ // registration was denied. See 3GPP TS 24.008,
+ // 10.5.3.6 and Annex G.
+ // 0 - General
+ // 1 - Authentication Failure
+ // 2 - IMSI unknown in HLR
+ // 3 - Illegal MS
+ // 4 - Illegal ME
+ // 5 - PLMN not allowed
+ // 6 - Location area not allowed
+ // 7 - Roaming not allowed
+ // 8 - No Suitable Cells in this Location Area
+ // 9 - Network failure
+ // 10 - Persistent location update reject
+ // 11 - PLMN not allowed
+ // 12 - Location area not allowed
+ // 13 - Roaming not allowed in this Location Area
+ // 15 - No Suitable Cells in this Location Area
+ // 17 - Network Failure
+ // 20 - MAC Failure
+ // 21 - Sync Failure
+ // 22 - Congestion
+ // 23 - GSM Authentication unacceptable
+ // 25 - Not Authorized for this CSG
+ // 32 - Service option not supported
+ // 33 - Requested service option not subscribed
+ // 34 - Service option temporarily out of order
+ // 38 - Call cannot be identified
+ // 48-63 - Retry upon entry into a new cell
+ // 95 - Semantically incorrect message
+ // 96 - Invalid mandatory information
+ // 97 - Message type non-existent or not implemented
+ // 98 - Message type not compatible with protocol state
+ // 99 - Information element non-existent or
+ // not implemented
+ // 100 - Conditional IE error
+ // 101 - Message not compatible with protocol state;
+ RIL_CellIdentity_v16 cellIdentity; // current cell information
+}RIL_VoiceRegistrationStateResponse;
+
+
+typedef struct {
+ RIL_RegState regState; // Valid reg states are RIL_NOT_REG_AND_NOT_SEARCHING,
+ // REG_HOME, RIL_NOT_REG_AND_SEARCHING, REG_DENIED,
+ // UNKNOWN, REG_ROAMING defined in RegState
+ RIL_RadioTechnology rat; // indicates the available data radio technology,
+ // valid values as defined by RadioTechnology.
+ int32_t reasonDataDenied; // if registration state is 3 (Registration
+ // denied) this is an enumerated reason why
+ // registration was denied. See 3GPP TS 24.008,
+ // Annex G.6 "Additional cause codes for GMM".
+ // 7 == GPRS services not allowed
+ // 8 == GPRS services and non-GPRS services not allowed
+ // 9 == MS identity cannot be derived by the network
+ // 10 == Implicitly detached
+ // 14 == GPRS services not allowed in this PLMN
+ // 16 == MSC temporarily not reachable
+ // 40 == No PDP context activated
+ int32_t maxDataCalls; // The maximum number of simultaneous Data Calls that
+ // must be established using setupDataCall().
+ RIL_CellIdentity_v16 cellIdentity; // Current cell information
+}RIL_DataRegistrationStateResponse;
+
+/* Names of the CDMA info records (C.S0005 section 3.7.5) */
+typedef enum {
+ RIL_CDMA_DISPLAY_INFO_REC,
+ RIL_CDMA_CALLED_PARTY_NUMBER_INFO_REC,
+ RIL_CDMA_CALLING_PARTY_NUMBER_INFO_REC,
+ RIL_CDMA_CONNECTED_NUMBER_INFO_REC,
+ RIL_CDMA_SIGNAL_INFO_REC,
+ RIL_CDMA_REDIRECTING_NUMBER_INFO_REC,
+ RIL_CDMA_LINE_CONTROL_INFO_REC,
+ RIL_CDMA_EXTENDED_DISPLAY_INFO_REC,
+ RIL_CDMA_T53_CLIR_INFO_REC,
+ RIL_CDMA_T53_RELEASE_INFO_REC,
+ RIL_CDMA_T53_AUDIO_CONTROL_INFO_REC
+} RIL_CDMA_InfoRecName;
+
+/* Display Info Rec as defined in C.S0005 section 3.7.5.1
+ Extended Display Info Rec as defined in C.S0005 section 3.7.5.16
+ Note: the Extended Display info rec contains multiple records of the
+ form: display_tag, display_len, and display_len occurrences of the
+ chari field if the display_tag is not 10000000 or 10000001.
+ To save space, the records are stored consecutively in a byte buffer.
+ The display_tag, display_len and chari fields are all 1 byte.
+*/
+
+typedef struct {
+ char alpha_len;
+ char alpha_buf[CDMA_ALPHA_INFO_BUFFER_LENGTH];
+} RIL_CDMA_DisplayInfoRecord;
+
+/* Called Party Number Info Rec as defined in C.S0005 section 3.7.5.2
+ Calling Party Number Info Rec as defined in C.S0005 section 3.7.5.3
+ Connected Number Info Rec as defined in C.S0005 section 3.7.5.4
+*/
+
+typedef struct {
+ char len;
+ char buf[CDMA_NUMBER_INFO_BUFFER_LENGTH];
+ char number_type;
+ char number_plan;
+ char pi;
+ char si;
+} RIL_CDMA_NumberInfoRecord;
+
+/* Redirecting Number Information Record as defined in C.S0005 section 3.7.5.11 */
+typedef enum {
+ RIL_REDIRECTING_REASON_UNKNOWN = 0,
+ RIL_REDIRECTING_REASON_CALL_FORWARDING_BUSY = 1,
+ RIL_REDIRECTING_REASON_CALL_FORWARDING_NO_REPLY = 2,
+ RIL_REDIRECTING_REASON_CALLED_DTE_OUT_OF_ORDER = 9,
+ RIL_REDIRECTING_REASON_CALL_FORWARDING_BY_THE_CALLED_DTE = 10,
+ RIL_REDIRECTING_REASON_CALL_FORWARDING_UNCONDITIONAL = 15,
+ RIL_REDIRECTING_REASON_RESERVED
+} RIL_CDMA_RedirectingReason;
+
+typedef struct {
+ RIL_CDMA_NumberInfoRecord redirectingNumber;
+ /* redirectingReason is set to RIL_REDIRECTING_REASON_UNKNOWN if not included */
+ RIL_CDMA_RedirectingReason redirectingReason;
+} RIL_CDMA_RedirectingNumberInfoRecord;
+
+/* Line Control Information Record as defined in C.S0005 section 3.7.5.15 */
+typedef struct {
+ char lineCtrlPolarityIncluded;
+ char lineCtrlToggle;
+ char lineCtrlReverse;
+ char lineCtrlPowerDenial;
+} RIL_CDMA_LineControlInfoRecord;
+
+/* T53 CLIR Information Record */
+typedef struct {
+ char cause;
+} RIL_CDMA_T53_CLIRInfoRecord;
+
+/* T53 Audio Control Information Record */
+typedef struct {
+ char upLink;
+ char downLink;
+} RIL_CDMA_T53_AudioControlInfoRecord;
+
+typedef struct {
+
+ RIL_CDMA_InfoRecName name;
+
+ union {
+ /* Display and Extended Display Info Rec */
+ RIL_CDMA_DisplayInfoRecord display;
+
+ /* Called Party Number, Calling Party Number, Connected Number Info Rec */
+ RIL_CDMA_NumberInfoRecord number;
+
+ /* Signal Info Rec */
+ RIL_CDMA_SignalInfoRecord signal;
+
+ /* Redirecting Number Info Rec */
+ RIL_CDMA_RedirectingNumberInfoRecord redir;
+
+ /* Line Control Info Rec */
+ RIL_CDMA_LineControlInfoRecord lineCtrl;
+
+ /* T53 CLIR Info Rec */
+ RIL_CDMA_T53_CLIRInfoRecord clir;
+
+ /* T53 Audio Control Info Rec */
+ RIL_CDMA_T53_AudioControlInfoRecord audioCtrl;
+ } rec;
+} RIL_CDMA_InformationRecord;
+
+#define RIL_CDMA_MAX_NUMBER_OF_INFO_RECS 10
+
+typedef struct {
+ char numberOfInfoRecs;
+ RIL_CDMA_InformationRecord infoRec[RIL_CDMA_MAX_NUMBER_OF_INFO_RECS];
+} RIL_CDMA_InformationRecords;
+
+/* See RIL_REQUEST_NV_READ_ITEM */
+typedef struct {
+ RIL_NV_Item itemID;
+} RIL_NV_ReadItem;
+
+/* See RIL_REQUEST_NV_WRITE_ITEM */
+typedef struct {
+ RIL_NV_Item itemID;
+ char * value;
+} RIL_NV_WriteItem;
+
+typedef enum {
+ HANDOVER_STARTED = 0,
+ HANDOVER_COMPLETED = 1,
+ HANDOVER_FAILED = 2,
+ HANDOVER_CANCELED = 3
+} RIL_SrvccState;
+
+/* hardware configuration reported to RILJ. */
+typedef enum {
+ RIL_HARDWARE_CONFIG_MODEM = 0,
+ RIL_HARDWARE_CONFIG_SIM = 1,
+} RIL_HardwareConfig_Type;
+
+typedef enum {
+ RIL_HARDWARE_CONFIG_STATE_ENABLED = 0,
+ RIL_HARDWARE_CONFIG_STATE_STANDBY = 1,
+ RIL_HARDWARE_CONFIG_STATE_DISABLED = 2,
+} RIL_HardwareConfig_State;
+
+typedef struct {
+ int rilModel;
+ uint32_t rat; /* bitset - ref. RIL_RadioTechnology. */
+ int maxVoice;
+ int maxData;
+ int maxStandby;
+} RIL_HardwareConfig_Modem;
+
+typedef struct {
+ char modemUuid[MAX_UUID_LENGTH];
+} RIL_HardwareConfig_Sim;
+
+typedef struct {
+ RIL_HardwareConfig_Type type;
+ char uuid[MAX_UUID_LENGTH];
+ RIL_HardwareConfig_State state;
+ union {
+ RIL_HardwareConfig_Modem modem;
+ RIL_HardwareConfig_Sim sim;
+ } cfg;
+} RIL_HardwareConfig;
+
+typedef enum {
+ SS_CFU,
+ SS_CF_BUSY,
+ SS_CF_NO_REPLY,
+ SS_CF_NOT_REACHABLE,
+ SS_CF_ALL,
+ SS_CF_ALL_CONDITIONAL,
+ SS_CLIP,
+ SS_CLIR,
+ SS_COLP,
+ SS_COLR,
+ SS_WAIT,
+ SS_BAOC,
+ SS_BAOIC,
+ SS_BAOIC_EXC_HOME,
+ SS_BAIC,
+ SS_BAIC_ROAMING,
+ SS_ALL_BARRING,
+ SS_OUTGOING_BARRING,
+ SS_INCOMING_BARRING
+} RIL_SsServiceType;
+
+typedef enum {
+ SS_ACTIVATION,
+ SS_DEACTIVATION,
+ SS_INTERROGATION,
+ SS_REGISTRATION,
+ SS_ERASURE
+} RIL_SsRequestType;
+
+typedef enum {
+ SS_ALL_TELE_AND_BEARER_SERVICES,
+ SS_ALL_TELESEVICES,
+ SS_TELEPHONY,
+ SS_ALL_DATA_TELESERVICES,
+ SS_SMS_SERVICES,
+ SS_ALL_TELESERVICES_EXCEPT_SMS
+} RIL_SsTeleserviceType;
+
+#define SS_INFO_MAX 4
+#define NUM_SERVICE_CLASSES 7
+
+typedef struct {
+ int numValidIndexes; /* This gives the number of valid values in cfInfo.
+ For example if voice is forwarded to one number and data
+ is forwarded to a different one then numValidIndexes will be
+ 2 indicating total number of valid values in cfInfo.
+ Similarly if all the services are forwarded to the same
+ number then the value of numValidIndexes will be 1. */
+
+ RIL_CallForwardInfo cfInfo[NUM_SERVICE_CLASSES]; /* This is the response data
+ for SS request to query call
+ forward status. see
+ RIL_REQUEST_QUERY_CALL_FORWARD_STATUS */
+} RIL_CfData;
+
+typedef struct {
+ RIL_SsServiceType serviceType;
+ RIL_SsRequestType requestType;
+ RIL_SsTeleserviceType teleserviceType;
+ int serviceClass;
+ RIL_Errno result;
+
+ union {
+ int ssInfo[SS_INFO_MAX]; /* This is the response data for most of the SS GET/SET
+ RIL requests. E.g. RIL_REQUSET_GET_CLIR returns
+ two ints, so first two values of ssInfo[] will be
+ used for response if serviceType is SS_CLIR and
+ requestType is SS_INTERROGATION */
+
+ RIL_CfData cfData;
+ };
+} RIL_StkCcUnsolSsResponse;
+
+/**
+ * Data connection power state
+ */
+typedef enum {
+ RIL_DC_POWER_STATE_LOW = 1, // Low power state
+ RIL_DC_POWER_STATE_MEDIUM = 2, // Medium power state
+ RIL_DC_POWER_STATE_HIGH = 3, // High power state
+ RIL_DC_POWER_STATE_UNKNOWN = INT32_MAX // Unknown state
+} RIL_DcPowerStates;
+
+/**
+ * Data connection real time info
+ */
+typedef struct {
+ uint64_t time; // Time in nanos as returned by ril_nano_time
+ RIL_DcPowerStates powerState; // Current power state
+} RIL_DcRtInfo;
+
+/**
+ * Data profile to modem
+ */
+typedef struct {
+ /* id of the data profile */
+ int profileId;
+ /* the APN to connect to */
+ char* apn;
+ /** one of the PDP_type values in TS 27.007 section 10.1.1.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ */
+ char* protocol;
+ /** authentication protocol used for this PDP context
+ * (None: 0, PAP: 1, CHAP: 2, PAP&CHAP: 3)
+ */
+ int authType;
+ /* the username for APN, or NULL */
+ char* user;
+ /* the password for APN, or NULL */
+ char* password;
+ /* the profile type, TYPE_COMMON-0, TYPE_3GPP-1, TYPE_3GPP2-2 */
+ int type;
+ /* the period in seconds to limit the maximum connections */
+ int maxConnsTime;
+ /* the maximum connections during maxConnsTime */
+ int maxConns;
+ /** the required wait time in seconds after a successful UE initiated
+ * disconnect of a given PDN connection before the device can send
+ * a new PDN connection request for that given PDN
+ */
+ int waitTime;
+ /* true to enable the profile, 0 to disable, 1 to enable */
+ int enabled;
+} RIL_DataProfileInfo;
+
+typedef struct {
+ /* id of the data profile */
+ int profileId;
+ /* the APN to connect to */
+ char* apn;
+ /** one of the PDP_type values in TS 27.007 section 10.1.1.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ */
+ char* protocol;
+ /** one of the PDP_type values in TS 27.007 section 10.1.1 used on roaming network.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ */
+ char *roamingProtocol;
+ /** authentication protocol used for this PDP context
+ * (None: 0, PAP: 1, CHAP: 2, PAP&CHAP: 3)
+ */
+ int authType;
+ /* the username for APN, or NULL */
+ char* user;
+ /* the password for APN, or NULL */
+ char* password;
+ /* the profile type, TYPE_COMMON-0, TYPE_3GPP-1, TYPE_3GPP2-2 */
+ int type;
+ /* the period in seconds to limit the maximum connections */
+ int maxConnsTime;
+ /* the maximum connections during maxConnsTime */
+ int maxConns;
+ /** the required wait time in seconds after a successful UE initiated
+ * disconnect of a given PDN connection before the device can send
+ * a new PDN connection request for that given PDN
+ */
+ int waitTime;
+ /* true to enable the profile, 0 to disable, 1 to enable */
+ int enabled;
+ /* supported APN types bitmask. See RIL_ApnTypes for the value of each bit. */
+ int supportedTypesBitmask;
+ /** the bearer bitmask. See RIL_RadioAccessFamily for the value of each bit. */
+ int bearerBitmask;
+ /** maximum transmission unit (MTU) size in bytes */
+ int mtu;
+ /** the MVNO type: possible values are "imsi", "gid", "spn" */
+ char *mvnoType;
+ /** MVNO match data. Can be anything defined by the carrier. For example,
+ * SPN like: "A MOBILE", "BEN NL", etc...
+ * IMSI like: "302720x94", "2060188", etc...
+ * GID like: "4E", "33", etc...
+ */
+ char *mvnoMatchData;
+} RIL_DataProfileInfo_v15;
+
+/* Tx Power Levels */
+#define RIL_NUM_TX_POWER_LEVELS 5
+
+/**
+ * Aggregate modem activity information
+ */
+typedef struct {
+
+ /* total time (in ms) when modem is in a low power or
+ * sleep state
+ */
+ uint32_t sleep_mode_time_ms;
+
+ /* total time (in ms) when modem is awake but neither
+ * the transmitter nor receiver are active/awake */
+ uint32_t idle_mode_time_ms;
+
+ /* total time (in ms) during which the transmitter is active/awake,
+ * subdivided by manufacturer-defined device-specific
+ * contiguous increasing ranges of transmit power between
+ * 0 and the transmitter's maximum transmit power.
+ */
+ uint32_t tx_mode_time_ms[RIL_NUM_TX_POWER_LEVELS];
+
+ /* total time (in ms) for which receiver is active/awake and
+ * the transmitter is inactive */
+ uint32_t rx_mode_time_ms;
+} RIL_ActivityStatsInfo;
+
+typedef enum {
+ RIL_APN_TYPE_UNKNOWN = 0x0, // Unknown
+ RIL_APN_TYPE_DEFAULT = 0x1, // APN type for default data traffic
+ RIL_APN_TYPE_MMS = 0x2, // APN type for MMS traffic
+ RIL_APN_TYPE_SUPL = 0x4, // APN type for SUPL assisted GPS
+ RIL_APN_TYPE_DUN = 0x8, // APN type for DUN traffic
+ RIL_APN_TYPE_HIPRI = 0x10, // APN type for HiPri traffic
+ RIL_APN_TYPE_FOTA = 0x20, // APN type for FOTA
+ RIL_APN_TYPE_IMS = 0x40, // APN type for IMS
+ RIL_APN_TYPE_CBS = 0x80, // APN type for CBS
+ RIL_APN_TYPE_IA = 0x100, // APN type for IA Initial Attach APN
+ RIL_APN_TYPE_EMERGENCY = 0x200, // APN type for Emergency PDN. This is not an IA apn,
+ // but is used for access to carrier services in an
+ // emergency call situation.
+ RIL_APN_TYPE_ALL = 0xFFFFFFFF // All APN types
+} RIL_ApnTypes;
+
+typedef enum {
+ RIL_DST_POWER_SAVE_MODE, // Device power save mode (provided by PowerManager)
+ // True indicates the device is in power save mode.
+ RIL_DST_CHARGING_STATE, // Device charging state (provided by BatteryManager)
+ // True indicates the device is charging.
+ RIL_DST_LOW_DATA_EXPECTED // Low data expected mode. True indicates low data traffic
+ // is expected, for example, when the device is idle
+ // (e.g. not doing tethering in the background). Note
+ // this doesn't mean no data is expected.
+} RIL_DeviceStateType;
+
+typedef enum {
+ RIL_UR_SIGNAL_STRENGTH = 0x01, // When this bit is set, modem should always send the
+ // signal strength update through
+ // RIL_UNSOL_SIGNAL_STRENGTH, otherwise suppress it.
+ RIL_UR_FULL_NETWORK_STATE = 0x02, // When this bit is set, modem should always send
+ // RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED
+ // when any field in
+ // RIL_REQUEST_VOICE_REGISTRATION_STATE or
+ // RIL_REQUEST_DATA_REGISTRATION_STATE changes. When
+ // this bit is not set, modem should suppress
+ // RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED
+ // only when insignificant fields change
+ // (e.g. cell info).
+ // Modem should continue sending
+ // RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED
+ // when significant fields are updated even when this
+ // bit is not set. The following fields are
+ // considered significant, registration state and
+ // radio technology.
+ RIL_UR_DATA_CALL_DORMANCY_CHANGED = 0x04 // When this bit is set, modem should send the data
+ // call list changed unsolicited response
+ // RIL_UNSOL_DATA_CALL_LIST_CHANGED whenever any
+ // field in RIL_Data_Call_Response changes.
+ // Otherwise modem should suppress the unsolicited
+ // response when the only changed field is 'active'
+ // (for data dormancy). For all other fields change,
+ // modem should continue sending
+ // RIL_UNSOL_DATA_CALL_LIST_CHANGED regardless this
+ // bit is set or not.
+} RIL_UnsolicitedResponseFilter;
+
+typedef struct {
+ char * aidPtr; /* AID value, See ETSI 102.221 and 101.220*/
+ int p2; /* P2 parameter (described in ISO 7816-4)
+ P2Constants:NO_P2 if to be ignored */
+} RIL_OpenChannelParams;
+
+typedef enum {
+ RIL_ONE_SHOT = 0x01, // Performs the scan only once
+ RIL_PERIODIC = 0x02 // Performs the scan periodically until cancelled
+} RIL_ScanType;
+
+typedef enum {
+ GERAN = 0x01, // GSM EDGE Radio Access Network
+ UTRAN = 0x02, // Universal Terrestrial Radio Access Network
+ EUTRAN = 0x03, // Evolved Universal Terrestrial Radio Access Network
+} RIL_RadioAccessNetworks;
+
+typedef enum {
+ GERAN_BAND_T380 = 1,
+ GERAN_BAND_T410 = 2,
+ GERAN_BAND_450 = 3,
+ GERAN_BAND_480 = 4,
+ GERAN_BAND_710 = 5,
+ GERAN_BAND_750 = 6,
+ GERAN_BAND_T810 = 7,
+ GERAN_BAND_850 = 8,
+ GERAN_BAND_P900 = 9,
+ GERAN_BAND_E900 = 10,
+ GERAN_BAND_R900 = 11,
+ GERAN_BAND_DCS1800 = 12,
+ GERAN_BAND_PCS1900 = 13,
+ GERAN_BAND_ER900 = 14,
+} RIL_GeranBands;
+
+typedef enum {
+ UTRAN_BAND_1 = 1,
+ UTRAN_BAND_2 = 2,
+ UTRAN_BAND_3 = 3,
+ UTRAN_BAND_4 = 4,
+ UTRAN_BAND_5 = 5,
+ UTRAN_BAND_6 = 6,
+ UTRAN_BAND_7 = 7,
+ UTRAN_BAND_8 = 8,
+ UTRAN_BAND_9 = 9,
+ UTRAN_BAND_10 = 10,
+ UTRAN_BAND_11 = 11,
+ UTRAN_BAND_12 = 12,
+ UTRAN_BAND_13 = 13,
+ UTRAN_BAND_14 = 14,
+ UTRAN_BAND_19 = 19,
+ UTRAN_BAND_20 = 20,
+ UTRAN_BAND_21 = 21,
+ UTRAN_BAND_22 = 22,
+ UTRAN_BAND_25 = 25,
+ UTRAN_BAND_26 = 26,
+} RIL_UtranBands;
+
+typedef enum {
+ EUTRAN_BAND_1 = 1,
+ EUTRAN_BAND_2 = 2,
+ EUTRAN_BAND_3 = 3,
+ EUTRAN_BAND_4 = 4,
+ EUTRAN_BAND_5 = 5,
+ EUTRAN_BAND_6 = 6,
+ EUTRAN_BAND_7 = 7,
+ EUTRAN_BAND_8 = 8,
+ EUTRAN_BAND_9 = 9,
+ EUTRAN_BAND_10 = 10,
+ EUTRAN_BAND_11 = 11,
+ EUTRAN_BAND_12 = 12,
+ EUTRAN_BAND_13 = 13,
+ EUTRAN_BAND_14 = 14,
+ EUTRAN_BAND_17 = 17,
+ EUTRAN_BAND_18 = 18,
+ EUTRAN_BAND_19 = 19,
+ EUTRAN_BAND_20 = 20,
+ EUTRAN_BAND_21 = 21,
+ EUTRAN_BAND_22 = 22,
+ EUTRAN_BAND_23 = 23,
+ EUTRAN_BAND_24 = 24,
+ EUTRAN_BAND_25 = 25,
+ EUTRAN_BAND_26 = 26,
+ EUTRAN_BAND_27 = 27,
+ EUTRAN_BAND_28 = 28,
+ EUTRAN_BAND_30 = 30,
+ EUTRAN_BAND_31 = 31,
+ EUTRAN_BAND_33 = 33,
+ EUTRAN_BAND_34 = 34,
+ EUTRAN_BAND_35 = 35,
+ EUTRAN_BAND_36 = 36,
+ EUTRAN_BAND_37 = 37,
+ EUTRAN_BAND_38 = 38,
+ EUTRAN_BAND_39 = 39,
+ EUTRAN_BAND_40 = 40,
+ EUTRAN_BAND_41 = 41,
+ EUTRAN_BAND_42 = 42,
+ EUTRAN_BAND_43 = 43,
+ EUTRAN_BAND_44 = 44,
+ EUTRAN_BAND_45 = 45,
+ EUTRAN_BAND_46 = 46,
+ EUTRAN_BAND_47 = 47,
+ EUTRAN_BAND_48 = 48,
+ EUTRAN_BAND_65 = 65,
+ EUTRAN_BAND_66 = 66,
+ EUTRAN_BAND_68 = 68,
+ EUTRAN_BAND_70 = 70,
+} RIL_EutranBands;
+
+typedef struct {
+ RIL_RadioAccessNetworks radio_access_network; // The type of network to scan.
+ uint32_t bands_length; // Length of bands
+ union {
+ RIL_GeranBands geran_bands[MAX_BANDS];
+ RIL_UtranBands utran_bands[MAX_BANDS];
+ RIL_EutranBands eutran_bands[MAX_BANDS];
+ } bands;
+ uint32_t channels_length; // Length of channels
+ uint32_t channels[MAX_CHANNELS]; // Frequency channels to scan
+} RIL_RadioAccessSpecifier;
+
+typedef struct {
+ RIL_ScanType type; // Type of the scan
+ int32_t interval; // Time interval in seconds
+ // between periodic scans, only
+ // valid when type=RIL_PERIODIC
+ uint32_t specifiers_length; // Length of specifiers
+ RIL_RadioAccessSpecifier specifiers[MAX_RADIO_ACCESS_NETWORKS]; // Radio access networks
+ // with bands/channels.
+} RIL_NetworkScanRequest;
+
+typedef enum {
+ PARTIAL = 0x01, // The result contains a part of the scan results
+ COMPLETE = 0x02, // The result contains the last part of the scan results
+} RIL_ScanStatus;
+
+typedef struct {
+ RIL_ScanStatus status; // The status of the scan
+ uint32_t network_infos_length; // Total length of RIL_CellInfo
+ RIL_CellInfo_v12* network_infos; // List of network information
+ RIL_Errno error;
+} RIL_NetworkScanResult;
+
+/**
+ * RIL_REQUEST_GET_SIM_STATUS
+ *
+ * Requests status of the SIM interface and the SIM card
+ *
+ * "data" is NULL
+ *
+ * "response" is const RIL_CardStatus_v6 *
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_GET_SIM_STATUS 1
+
+/**
+ * RIL_REQUEST_ENTER_SIM_PIN
+ *
+ * Supplies SIM PIN. Only called if RIL_CardStatus has RIL_APPSTATE_PIN state
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is PIN value
+ * ((const char **)data)[1] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ENTER_SIM_PIN 2
+
+/**
+ * RIL_REQUEST_ENTER_SIM_PUK
+ *
+ * Supplies SIM PUK and new PIN.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is PUK value
+ * ((const char **)data)[1] is new PIN value
+ * ((const char **)data)[2] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * (PUK is invalid)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ENTER_SIM_PUK 3
+
+/**
+ * RIL_REQUEST_ENTER_SIM_PIN2
+ *
+ * Supplies SIM PIN2. Only called following operation where SIM_PIN2 was
+ * returned as a a failure from a previous operation.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is PIN2 value
+ * ((const char **)data)[1] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ENTER_SIM_PIN2 4
+
+/**
+ * RIL_REQUEST_ENTER_SIM_PUK2
+ *
+ * Supplies SIM PUK2 and new PIN2.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is PUK2 value
+ * ((const char **)data)[1] is new PIN2 value
+ * ((const char **)data)[2] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * (PUK2 is invalid)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ENTER_SIM_PUK2 5
+
+/**
+ * RIL_REQUEST_CHANGE_SIM_PIN
+ *
+ * Supplies old SIM PIN and new PIN.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is old PIN value
+ * ((const char **)data)[1] is new PIN value
+ * ((const char **)data)[2] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * (old PIN is invalid)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_CHANGE_SIM_PIN 6
+
+
+/**
+ * RIL_REQUEST_CHANGE_SIM_PIN2
+ *
+ * Supplies old SIM PIN2 and new PIN2.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is old PIN2 value
+ * ((const char **)data)[1] is new PIN2 value
+ * ((const char **)data)[2] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * (old PIN2 is invalid)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+
+#define RIL_REQUEST_CHANGE_SIM_PIN2 7
+
+/**
+ * RIL_REQUEST_ENTER_NETWORK_DEPERSONALIZATION
+ *
+ * Requests that network personlization be deactivated
+ *
+ * "data" is const char **
+ * ((const char **)(data))[0]] is network depersonlization code
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * PASSWORD_INCORRECT
+ * SIM_ABSENT
+ * (code is invalid)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ENTER_NETWORK_DEPERSONALIZATION 8
+
+/**
+ * RIL_REQUEST_GET_CURRENT_CALLS
+ *
+ * Requests current call list
+ *
+ * "data" is NULL
+ *
+ * "response" must be a "const RIL_Call **"
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * (request will be made again in a few hundred msec)
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_GET_CURRENT_CALLS 9
+
+
+/**
+ * RIL_REQUEST_DIAL
+ *
+ * Initiate voice call
+ *
+ * "data" is const RIL_Dial *
+ * "response" is NULL
+ *
+ * This method is never used for supplementary service codes
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * DIAL_MODIFIED_TO_USSD
+ * DIAL_MODIFIED_TO_SS
+ * DIAL_MODIFIED_TO_DIAL
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * INVALID_STATE
+ * NO_RESOURCES
+ * INTERNAL_ERR
+ * FDN_CHECK_FAILURE
+ * MODEM_ERR
+ * NO_SUBSCRIPTION
+ * NO_NETWORK_FOUND
+ * INVALID_CALL_ID
+ * DEVICE_IN_USE
+ * OPERATION_NOT_ALLOWED
+ * ABORTED
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_DIAL 10
+
+/**
+ * RIL_REQUEST_GET_IMSI
+ *
+ * Get the SIM IMSI
+ *
+ * Only valid when radio state is "RADIO_STATE_ON"
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ * "response" is a const char * containing the IMSI
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_SIM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_GET_IMSI 11
+
+/**
+ * RIL_REQUEST_HANGUP
+ *
+ * Hang up a specific line (like AT+CHLD=1x)
+ *
+ * After this HANGUP request returns, RIL should show the connection is NOT
+ * active anymore in next RIL_REQUEST_GET_CURRENT_CALLS query.
+ *
+ * "data" is an int *
+ * (int *)data)[0] contains Connection index (value of 'x' in CHLD above)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * INVALID_STATE
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_CALL_ID
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_HANGUP 12
+
+/**
+ * RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND
+ *
+ * Hang up waiting or held (like AT+CHLD=0)
+ *
+ * After this HANGUP request returns, RIL should show the connection is NOT
+ * active anymore in next RIL_REQUEST_GET_CURRENT_CALLS query.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_CALL_ID
+ * NO_RESOURCES
+ * OPERATION_NOT_ALLOWED
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND 13
+
+/**
+ * RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND
+ *
+ * Hang up waiting or held (like AT+CHLD=1)
+ *
+ * After this HANGUP request returns, RIL should show the connection is NOT
+ * active anymore in next RIL_REQUEST_GET_CURRENT_CALLS query.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * OPERATION_NOT_ALLOWED
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND 14
+
+/**
+ * RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE
+ *
+ * Switch waiting or holding call and active call (like AT+CHLD=2)
+ *
+ * State transitions should be is follows:
+ *
+ * If call 1 is waiting and call 2 is active, then if this re
+ *
+ * BEFORE AFTER
+ * Call 1 Call 2 Call 1 Call 2
+ * ACTIVE HOLDING HOLDING ACTIVE
+ * ACTIVE WAITING HOLDING ACTIVE
+ * HOLDING WAITING HOLDING ACTIVE
+ * ACTIVE IDLE HOLDING IDLE
+ * IDLE IDLE IDLE IDLE
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * INVALID_CALL_ID
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE 15
+#define RIL_REQUEST_SWITCH_HOLDING_AND_ACTIVE 15
+
+/**
+ * RIL_REQUEST_CONFERENCE
+ *
+ * Conference holding and active (like AT+CHLD=3)
+
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_STATE
+ * INVALID_CALL_ID
+ * INVALID_ARGUMENTS
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_CONFERENCE 16
+
+/**
+ * RIL_REQUEST_UDUB
+ *
+ * Send UDUB (user determined used busy) to ringing or
+ * waiting call answer)(RIL_BasicRequest r);
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_RESOURCES
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * OPERATION_NOT_ALLOWED
+ * INVALID_ARGUMENTS
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_UDUB 17
+
+/**
+ * RIL_REQUEST_LAST_CALL_FAIL_CAUSE
+ *
+ * Requests the failure cause code for the most recently terminated call
+ *
+ * "data" is NULL
+ * "response" is a const RIL_LastCallFailCauseInfo *
+ * RIL_LastCallFailCauseInfo contains LastCallFailCause and vendor cause.
+ * The vendor cause code must be used for debugging purpose only.
+ * The implementation must return one of the values of LastCallFailCause
+ * as mentioned below.
+ *
+ * GSM failure reasons codes for the cause codes defined in TS 24.008 Annex H
+ * where possible.
+ * CDMA failure reasons codes for the possible call failure scenarios
+ * described in the "CDMA IS-2000 Release A (C.S0005-A v6.0)" standard.
+ * Any of the following reason codes if the call is failed or dropped due to reason
+ * mentioned with in the braces.
+ *
+ * CALL_FAIL_RADIO_OFF (Radio is OFF)
+ * CALL_FAIL_OUT_OF_SERVICE (No cell coverage)
+ * CALL_FAIL_NO_VALID_SIM (No valid SIM)
+ * CALL_FAIL_RADIO_INTERNAL_ERROR (Modem hit unexpected error scenario)
+ * CALL_FAIL_NETWORK_RESP_TIMEOUT (No response from network)
+ * CALL_FAIL_NETWORK_REJECT (Explicit network reject)
+ * CALL_FAIL_RADIO_ACCESS_FAILURE (RRC connection failure. Eg.RACH)
+ * CALL_FAIL_RADIO_LINK_FAILURE (Radio Link Failure)
+ * CALL_FAIL_RADIO_LINK_LOST (Radio link lost due to poor coverage)
+ * CALL_FAIL_RADIO_UPLINK_FAILURE (Radio uplink failure)
+ * CALL_FAIL_RADIO_SETUP_FAILURE (RRC connection setup failure)
+ * CALL_FAIL_RADIO_RELEASE_NORMAL (RRC connection release, normal)
+ * CALL_FAIL_RADIO_RELEASE_ABNORMAL (RRC connection release, abnormal)
+ * CALL_FAIL_ACCESS_CLASS_BLOCKED (Access class barring)
+ * CALL_FAIL_NETWORK_DETACH (Explicit network detach)
+ *
+ * OEM causes (CALL_FAIL_OEM_CAUSE_XX) must be used for debug purpose only
+ *
+ * If the implementation does not have access to the exact cause codes,
+ * then it should return one of the values listed in RIL_LastCallFailCause,
+ * as the UI layer needs to distinguish these cases for tone generation or
+ * error notification.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE
+ */
+#define RIL_REQUEST_LAST_CALL_FAIL_CAUSE 18
+
+/**
+ * RIL_REQUEST_SIGNAL_STRENGTH
+ *
+ * Requests current signal strength and associated information
+ *
+ * Must succeed if radio is on.
+ *
+ * "data" is NULL
+ *
+ * "response" is a const RIL_SignalStrength *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SIGNAL_STRENGTH 19
+
+/**
+ * RIL_REQUEST_VOICE_REGISTRATION_STATE
+ *
+ * Request current registration state
+ *
+ * "data" is NULL
+ * "response" is a const RIL_VoiceRegistrationStateResponse *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_VOICE_REGISTRATION_STATE 20
+
+/**
+ * RIL_REQUEST_DATA_REGISTRATION_STATE
+ *
+ * Request current DATA registration state
+ *
+ * "data" is NULL
+ * "response" is a const RIL_DataRegistrationStateResponse *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_DATA_REGISTRATION_STATE 21
+
+/**
+ * RIL_REQUEST_OPERATOR
+ *
+ * Request current operator ONS or EONS
+ *
+ * "data" is NULL
+ * "response" is a "const char **"
+ * ((const char **)response)[0] is long alpha ONS or EONS
+ * or NULL if unregistered
+ *
+ * ((const char **)response)[1] is short alpha ONS or EONS
+ * or NULL if unregistered
+ * ((const char **)response)[2] is 5 or 6 digit numeric code (MCC + MNC)
+ * or NULL if unregistered
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_OPERATOR 22
+
+/**
+ * RIL_REQUEST_RADIO_POWER
+ *
+ * Toggle radio on and off (for "airplane" mode)
+ * If the radio is is turned off/on the radio modem subsystem
+ * is expected return to an initialized state. For instance,
+ * any voice and data calls will be terminated and all associated
+ * lists emptied.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is > 0 for "Radio On"
+ * ((int *)data)[0] is == 0 for "Radio Off"
+ *
+ * "response" is NULL
+ *
+ * Turn radio on if "on" > 0
+ * Turn radio off if "on" == 0
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * INVALID_STATE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * DEVICE_IN_USE
+ * OPERATION_NOT_ALLOWED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_RADIO_POWER 23
+
+/**
+ * RIL_REQUEST_DTMF
+ *
+ * Send a DTMF tone
+ *
+ * If the implementation is currently playing a tone requested via
+ * RIL_REQUEST_DTMF_START, that tone should be cancelled and the new tone
+ * should be played instead
+ *
+ * "data" is a char * containing a single character with one of 12 values: 0-9,*,#
+ * "response" is NULL
+ *
+ * FIXME should this block/mute microphone?
+ * How does this interact with local DTMF feedback?
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_DTMF_STOP, RIL_REQUEST_DTMF_START
+ *
+ */
+#define RIL_REQUEST_DTMF 24
+
+/**
+ * RIL_REQUEST_SEND_SMS
+ *
+ * Send an SMS message
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is SMSC address in GSM BCD format prefixed
+ * by a length byte (as expected by TS 27.005) or NULL for default SMSC
+ * ((const char **)data)[1] is SMS in PDU format as an ASCII hex string
+ * less the SMSC address
+ * TP-Layer-Length is be "strlen(((const char **)data)[1])/2"
+ *
+ * "response" is a const RIL_SMS_Response *
+ *
+ * Based on the return error, caller decides to resend if sending sms
+ * fails. SMS_SEND_FAIL_RETRY means retry (i.e. error cause is 332)
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SMS_SEND_FAIL_RETRY
+ * FDN_CHECK_FAILURE
+ * NETWORK_REJECT
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * INVALID_SMS_FORMAT
+ * SYSTEM_ERR
+ * ENCODING_ERR
+ * INVALID_SMSC_ADDRESS
+ * MODEM_ERR
+ * NETWORK_ERR
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * MODE_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ * FIXME how do we specify TP-Message-Reference if we need to resend?
+ */
+#define RIL_REQUEST_SEND_SMS 25
+
+
+/**
+ * RIL_REQUEST_SEND_SMS_EXPECT_MORE
+ *
+ * Send an SMS message. Identical to RIL_REQUEST_SEND_SMS,
+ * except that more messages are expected to be sent soon. If possible,
+ * keep SMS relay protocol link open (eg TS 27.005 AT+CMMS command)
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is SMSC address in GSM BCD format prefixed
+ * by a length byte (as expected by TS 27.005) or NULL for default SMSC
+ * ((const char **)data)[1] is SMS in PDU format as an ASCII hex string
+ * less the SMSC address
+ * TP-Layer-Length is be "strlen(((const char **)data)[1])/2"
+ *
+ * "response" is a const RIL_SMS_Response *
+ *
+ * Based on the return error, caller decides to resend if sending sms
+ * fails. SMS_SEND_FAIL_RETRY means retry (i.e. error cause is 332)
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SMS_SEND_FAIL_RETRY
+ * NETWORK_REJECT
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * INVALID_SMS_FORMAT
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * FDN_CHECK_FAILURE
+ * MODEM_ERR
+ * NETWORK_ERR
+ * ENCODING_ERR
+ * INVALID_SMSC_ADDRESS
+ * OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * MODE_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_SEND_SMS_EXPECT_MORE 26
+
+
+/**
+ * RIL_REQUEST_SETUP_DATA_CALL
+ *
+ * Setup a packet data connection. If RIL_Data_Call_Response_v6.status
+ * return success it is added to the list of data calls and a
+ * RIL_UNSOL_DATA_CALL_LIST_CHANGED is sent. The call remains in the
+ * list until RIL_REQUEST_DEACTIVATE_DATA_CALL is issued or the
+ * radio is powered off/on. This list is returned by RIL_REQUEST_DATA_CALL_LIST
+ * and RIL_UNSOL_DATA_CALL_LIST_CHANGED.
+ *
+ * The RIL is expected to:
+ * - Create one data call context.
+ * - Create and configure a dedicated interface for the context
+ * - The interface must be point to point.
+ * - The interface is configured with one or more addresses and
+ * is capable of sending and receiving packets. The prefix length
+ * of the addresses must be /32 for IPv4 and /128 for IPv6.
+ * - Must NOT change the linux routing table.
+ * - Support up to RIL_REQUEST_DATA_REGISTRATION_STATE response[5]
+ * number of simultaneous data call contexts.
+ *
+ * "data" is a const char **
+ * ((const char **)data)[0] Radio technology to use: 0-CDMA, 1-GSM/UMTS, 2...
+ * for values above 2 this is RIL_RadioTechnology + 2.
+ * ((const char **)data)[1] is a RIL_DataProfile (support is optional)
+ * ((const char **)data)[2] is the APN to connect to if radio technology is GSM/UMTS. This APN will
+ * override the one in the profile. NULL indicates no APN overrride.
+ * ((const char **)data)[3] is the username for APN, or NULL
+ * ((const char **)data)[4] is the password for APN, or NULL
+ * ((const char **)data)[5] is the PAP / CHAP auth type. Values:
+ * 0 => PAP and CHAP is never performed.
+ * 1 => PAP may be performed; CHAP is never performed.
+ * 2 => CHAP may be performed; PAP is never performed.
+ * 3 => PAP / CHAP may be performed - baseband dependent.
+ * ((const char **)data)[6] is the non-roaming/home connection type to request. Must be one of the
+ * PDP_type values in TS 27.007 section 10.1.1.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ * ((const char **)data)[7] is the roaming connection type to request. Must be one of the
+ * PDP_type values in TS 27.007 section 10.1.1.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ * ((const char **)data)[8] is the bitmask of APN type in decimal string format. The
+ * bitmask will encapsulate the following values:
+ * ia,mms,agps,supl,hipri,fota,dun,ims,default.
+ * ((const char **)data)[9] is the bearer bitmask in decimal string format. Each bit is a
+ * RIL_RadioAccessFamily. "0" or NULL indicates all RATs.
+ * ((const char **)data)[10] is the boolean in string format indicating the APN setting was
+ * sent to the modem through RIL_REQUEST_SET_DATA_PROFILE earlier.
+ * ((const char **)data)[11] is the mtu size in bytes of the mobile interface to which
+ * the apn is connected.
+ * ((const char **)data)[12] is the MVNO type:
+ * possible values are "imsi", "gid", "spn".
+ * ((const char **)data)[13] is MVNO match data in string. Can be anything defined by the carrier.
+ * For example,
+ * SPN like: "A MOBILE", "BEN NL", etc...
+ * IMSI like: "302720x94", "2060188", etc...
+ * GID like: "4E", "33", etc...
+ * ((const char **)data)[14] is the boolean string indicating data roaming is allowed or not. "1"
+ * indicates data roaming is enabled by the user, "0" indicates disabled.
+ *
+ * "response" is a RIL_Data_Call_Response_v11
+ *
+ * FIXME may need way to configure QoS settings
+ *
+ * Valid errors:
+ * SUCCESS should be returned on both success and failure of setup with
+ * the RIL_Data_Call_Response_v6.status containing the actual status.
+ * For all other errors the RIL_Data_Call_Resonse_v6 is ignored.
+ *
+ * Other errors could include:
+ * RADIO_NOT_AVAILABLE, OP_NOT_ALLOWED_BEFORE_REG_TO_NW,
+ * OP_NOT_ALLOWED_DURING_VOICE_CALL, REQUEST_NOT_SUPPORTED,
+ * INVALID_ARGUMENTS, INTERNAL_ERR, NO_MEMORY, NO_RESOURCES,
+ * CANCELLED and SIM_ABSENT
+ *
+ * See also: RIL_REQUEST_DEACTIVATE_DATA_CALL
+ */
+#define RIL_REQUEST_SETUP_DATA_CALL 27
+
+
+/**
+ * RIL_REQUEST_SIM_IO
+ *
+ * Request SIM I/O operation.
+ * This is similar to the TS 27.007 "restricted SIM" operation
+ * where it assumes all of the EF selection will be done by the
+ * callee.
+ *
+ * "data" is a const RIL_SIM_IO_v6 *
+ * Please note that RIL_SIM_IO has a "PIN2" field which may be NULL,
+ * or may specify a PIN2 for operations that require a PIN2 (eg
+ * updating FDN records)
+ *
+ * "response" is a const RIL_SIM_IO_Response *
+ *
+ * Arguments and responses that are unused for certain
+ * values of "command" should be ignored or set to NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SIM_PIN2
+ * SIM_PUK2
+ * INVALID_SIM_STATE
+ * SIM_ERR
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_IO 28
+
+/**
+ * RIL_REQUEST_SEND_USSD
+ *
+ * Send a USSD message
+ *
+ * If a USSD session already exists, the message should be sent in the
+ * context of that session. Otherwise, a new session should be created.
+ *
+ * The network reply should be reported via RIL_UNSOL_ON_USSD
+ *
+ * Only one USSD session may exist at a time, and the session is assumed
+ * to exist until:
+ * a) The android system invokes RIL_REQUEST_CANCEL_USSD
+ * b) The implementation sends a RIL_UNSOL_ON_USSD with a type code
+ * of "0" (USSD-Notify/no further action) or "2" (session terminated)
+ *
+ * "data" is a const char * containing the USSD request in UTF-8 format
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * FDN_CHECK_FAILURE
+ * USSD_MODIFIED_TO_DIAL
+ * USSD_MODIFIED_TO_SS
+ * USSD_MODIFIED_TO_USSD
+ * SIM_BUSY
+ * OPERATION_NOT_ALLOWED
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * ABORTED
+ * SYSTEM_ERR
+ * INVALID_STATE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_CANCEL_USSD, RIL_UNSOL_ON_USSD
+ */
+
+#define RIL_REQUEST_SEND_USSD 29
+
+/**
+ * RIL_REQUEST_CANCEL_USSD
+ *
+ * Cancel the current USSD session if one exists
+ *
+ * "data" is null
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SIM_BUSY
+ * OPERATION_NOT_ALLOWED
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_STATE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_CANCEL_USSD 30
+
+/**
+ * RIL_REQUEST_GET_CLIR
+ *
+ * Gets current CLIR status
+ * "data" is NULL
+ * "response" is int *
+ * ((int *)data)[0] is "n" parameter from TS 27.007 7.7
+ * ((int *)data)[1] is "m" parameter from TS 27.007 7.7
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * FDN_CHECK_FAILURE
+ * SYSTEM_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_GET_CLIR 31
+
+/**
+ * RIL_REQUEST_SET_CLIR
+ *
+ * "data" is int *
+ * ((int *)data)[0] is "n" parameter from TS 27.007 7.7
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SET_CLIR 32
+
+/**
+ * RIL_REQUEST_QUERY_CALL_FORWARD_STATUS
+ *
+ * "data" is const RIL_CallForwardInfo *
+ *
+ * "response" is const RIL_CallForwardInfo **
+ * "response" points to an array of RIL_CallForwardInfo *'s, one for
+ * each distinct registered phone number.
+ *
+ * For example, if data is forwarded to +18005551212 and voice is forwarded
+ * to +18005559999, then two separate RIL_CallForwardInfo's should be returned
+ *
+ * If, however, both data and voice are forwarded to +18005551212, then
+ * a single RIL_CallForwardInfo can be returned with the service class
+ * set to "data + voice = 3")
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_QUERY_CALL_FORWARD_STATUS 33
+
+
+/**
+ * RIL_REQUEST_SET_CALL_FORWARD
+ *
+ * Configure call forward rule
+ *
+ * "data" is const RIL_CallForwardInfo *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_STATE
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SET_CALL_FORWARD 34
+
+
+/**
+ * RIL_REQUEST_QUERY_CALL_WAITING
+ *
+ * Query current call waiting state
+ *
+ * "data" is const int *
+ * ((const int *)data)[0] is the TS 27.007 service class to query.
+ * "response" is a const int *
+ * ((const int *)response)[0] is 0 for "disabled" and 1 for "enabled"
+ *
+ * If ((const int *)response)[0] is = 1, then ((const int *)response)[1]
+ * must follow, with the TS 27.007 service class bit vector of services
+ * for which call waiting is enabled.
+ *
+ * For example, if ((const int *)response)[0] is 1 and
+ * ((const int *)response)[1] is 3, then call waiting is enabled for data
+ * and voice and disabled for everything else
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * FDN_CHECK_FAILURE
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_QUERY_CALL_WAITING 35
+
+
+/**
+ * RIL_REQUEST_SET_CALL_WAITING
+ *
+ * Configure current call waiting state
+ *
+ * "data" is const int *
+ * ((const int *)data)[0] is 0 for "disabled" and 1 for "enabled"
+ * ((const int *)data)[1] is the TS 27.007 service class bit vector of
+ * services to modify
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_STATE
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SET_CALL_WAITING 36
+
+/**
+ * RIL_REQUEST_SMS_ACKNOWLEDGE
+ *
+ * Acknowledge successful or failed receipt of SMS previously indicated
+ * via RIL_UNSOL_RESPONSE_NEW_SMS
+ *
+ * "data" is int *
+ * ((int *)data)[0] is 1 on successful receipt
+ * (basically, AT+CNMA=1 from TS 27.005
+ * is 0 on failed receipt
+ * (basically, AT+CNMA=2 from TS 27.005)
+ * ((int *)data)[1] if data[0] is 0, this contains the failure cause as defined
+ * in TS 23.040, 9.2.3.22. Currently only 0xD3 (memory
+ * capacity exceeded) and 0xFF (unspecified error) are
+ * reported.
+ *
+ * "response" is NULL
+ *
+ * FIXME would like request that specified RP-ACK/RP-ERROR PDU
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SMS_ACKNOWLEDGE 37
+
+/**
+ * RIL_REQUEST_GET_IMEI - DEPRECATED
+ *
+ * Get the device IMEI, including check digit
+ *
+ * The request is DEPRECATED, use RIL_REQUEST_DEVICE_IDENTITY
+ * Valid when RadioState is not RADIO_STATE_UNAVAILABLE
+ *
+ * "data" is NULL
+ * "response" is a const char * containing the IMEI
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+
+#define RIL_REQUEST_GET_IMEI 38
+
+/**
+ * RIL_REQUEST_GET_IMEISV - DEPRECATED
+ *
+ * Get the device IMEISV, which should be two decimal digits
+ *
+ * The request is DEPRECATED, use RIL_REQUEST_DEVICE_IDENTITY
+ * Valid when RadioState is not RADIO_STATE_UNAVAILABLE
+ *
+ * "data" is NULL
+ * "response" is a const char * containing the IMEISV
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+
+#define RIL_REQUEST_GET_IMEISV 39
+
+
+/**
+ * RIL_REQUEST_ANSWER
+ *
+ * Answer incoming call
+ *
+ * Will not be called for WAITING calls.
+ * RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE will be used in this case
+ * instead
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_ANSWER 40
+
+/**
+ * RIL_REQUEST_DEACTIVATE_DATA_CALL
+ *
+ * Deactivate packet data connection and remove from the
+ * data call list if SUCCESS is returned. Any other return
+ * values should also try to remove the call from the list,
+ * but that may not be possible. In any event a
+ * RIL_REQUEST_RADIO_POWER off/on must clear the list. An
+ * RIL_UNSOL_DATA_CALL_LIST_CHANGED is not expected to be
+ * issued because of an RIL_REQUEST_DEACTIVATE_DATA_CALL.
+ *
+ * "data" is const char **
+ * ((char**)data)[0] indicating CID
+ * ((char**)data)[1] indicating Disconnect Reason
+ * 0 => No specific reason specified
+ * 1 => Radio shutdown requested
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_CALL_ID
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * SIM_ABSENT
+ *
+ * See also: RIL_REQUEST_SETUP_DATA_CALL
+ */
+#define RIL_REQUEST_DEACTIVATE_DATA_CALL 41
+
+/**
+ * RIL_REQUEST_QUERY_FACILITY_LOCK
+ *
+ * Query the status of a facility lock state
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is the facility string code from TS 27.007 7.4
+ * (eg "AO" for BAOC, "SC" for SIM lock)
+ * ((const char **)data)[1] is the password, or "" if not required
+ * ((const char **)data)[2] is the TS 27.007 service class bit vector of
+ * services to query
+ * ((const char **)data)[3] is AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ * This is only applicable in the case of Fixed Dialing Numbers
+ * (FDN) requests.
+ *
+ * "response" is an int *
+ * ((const int *)response) 0 is the TS 27.007 service class bit vector of
+ * services for which the specified barring facility
+ * is active. "0" means "disabled for all"
+ *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_QUERY_FACILITY_LOCK 42
+
+/**
+ * RIL_REQUEST_SET_FACILITY_LOCK
+ *
+ * Enable/disable one facility lock
+ *
+ * "data" is const char **
+ *
+ * ((const char **)data)[0] = facility string code from TS 27.007 7.4
+ * (eg "AO" for BAOC)
+ * ((const char **)data)[1] = "0" for "unlock" and "1" for "lock"
+ * ((const char **)data)[2] = password
+ * ((const char **)data)[3] = string representation of decimal TS 27.007
+ * service class bit vector. Eg, the string
+ * "1" means "set this facility for voice services"
+ * ((const char **)data)[4] = AID value, See ETSI 102.221 8.1 and 101.220 4, NULL if no value.
+ * This is only applicable in the case of Fixed Dialing Numbers
+ * (FDN) requests.
+ *
+ * "response" is int *
+ * ((int *)response)[0] is the number of retries remaining, or -1 if unknown
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * MODEM_ERR
+ * INVALID_STATE
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_SET_FACILITY_LOCK 43
+
+/**
+ * RIL_REQUEST_CHANGE_BARRING_PASSWORD
+ *
+ * Change call barring facility password
+ *
+ * "data" is const char **
+ *
+ * ((const char **)data)[0] = facility string code from TS 27.007 7.4
+ * (eg "AO" for BAOC)
+ * ((const char **)data)[1] = old password
+ * ((const char **)data)[2] = new password
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CHANGE_BARRING_PASSWORD 44
+
+/**
+ * RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE
+ *
+ * Query current network selectin mode
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((const int *)response)[0] is
+ * 0 for automatic selection
+ * 1 for manual selection
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE 45
+
+/**
+ * RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC
+ *
+ * Specify that the network should be selected automatically
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * This request must not respond until the new operator is selected
+ * and registered
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * ILLEGAL_SIM_OR_ME
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * Note: Returns ILLEGAL_SIM_OR_ME when the failure is permanent and
+ * no retries needed, such as illegal SIM or ME.
+ *
+ */
+#define RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC 46
+
+/**
+ * RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL
+ *
+ * Manually select a specified network.
+ *
+ * "data" is const char * specifying MCCMNC of network to select (eg "310170")
+ * "response" is NULL
+ *
+ * This request must not respond until the new operator is selected
+ * and registered
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * ILLEGAL_SIM_OR_ME
+ * OPERATION_NOT_ALLOWED
+ * INVALID_STATE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * Note: Returns ILLEGAL_SIM_OR_ME when the failure is permanent and
+ * no retries needed, such as illegal SIM or ME.
+ *
+ */
+#define RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL 47
+
+/**
+ * RIL_REQUEST_QUERY_AVAILABLE_NETWORKS
+ *
+ * Scans for available networks
+ *
+ * "data" is NULL
+ * "response" is const char ** that should be an array of n*4 strings, where
+ * n is the number of available networks
+ * For each available network:
+ *
+ * ((const char **)response)[n+0] is long alpha ONS or EONS
+ * ((const char **)response)[n+1] is short alpha ONS or EONS
+ * ((const char **)response)[n+2] is 5 or 6 digit numeric code (MCC + MNC)
+ * ((const char **)response)[n+3] is a string value of the status:
+ * "unknown"
+ * "available"
+ * "current"
+ * "forbidden"
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * ABORTED
+ * DEVICE_IN_USE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * CANCELLED
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_QUERY_AVAILABLE_NETWORKS 48
+
+/**
+ * RIL_REQUEST_DTMF_START
+ *
+ * Start playing a DTMF tone. Continue playing DTMF tone until
+ * RIL_REQUEST_DTMF_STOP is received
+ *
+ * If a RIL_REQUEST_DTMF_START is received while a tone is currently playing,
+ * it should cancel the previous tone and play the new one.
+ *
+ * "data" is a char *
+ * ((char *)data)[0] is a single character with one of 12 values: 0-9,*,#
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_DTMF, RIL_REQUEST_DTMF_STOP
+ */
+#define RIL_REQUEST_DTMF_START 49
+
+/**
+ * RIL_REQUEST_DTMF_STOP
+ *
+ * Stop playing a currently playing DTMF tone.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * NO_MEMORY
+ * INVALID_ARGUMENTS
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_DTMF, RIL_REQUEST_DTMF_START
+ */
+#define RIL_REQUEST_DTMF_STOP 50
+
+/**
+ * RIL_REQUEST_BASEBAND_VERSION
+ *
+ * Return string value indicating baseband version, eg
+ * response from AT+CGMR
+ *
+ * "data" is NULL
+ * "response" is const char * containing version string for log reporting
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * EMPTY_RECORD
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_BASEBAND_VERSION 51
+
+/**
+ * RIL_REQUEST_SEPARATE_CONNECTION
+ *
+ * Separate a party from a multiparty call placing the multiparty call
+ * (less the specified party) on hold and leaving the specified party
+ * as the only other member of the current (active) call
+ *
+ * Like AT+CHLD=2x
+ *
+ * See TS 22.084 1.3.8.2 (iii)
+ * TS 22.030 6.5.5 "Entering "2X followed by send"
+ * TS 27.007 "AT+CHLD=2x"
+ *
+ * "data" is an int *
+ * (int *)data)[0] contains Connection index (value of 'x' in CHLD above) "response" is NULL
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_ARGUMENTS
+ * INVALID_STATE
+ * NO_RESOURCES
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * INVALID_STATE
+ * OPERATION_NOT_ALLOWED
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SEPARATE_CONNECTION 52
+
+
+/**
+ * RIL_REQUEST_SET_MUTE
+ *
+ * Turn on or off uplink (microphone) mute.
+ *
+ * Will only be sent while voice call is active.
+ * Will always be reset to "disable mute" when a new voice call is initiated
+ *
+ * "data" is an int *
+ * (int *)data)[0] is 1 for "enable mute" and 0 for "disable mute"
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_SET_MUTE 53
+
+/**
+ * RIL_REQUEST_GET_MUTE
+ *
+ * Queries the current state of the uplink mute setting
+ *
+ * "data" is NULL
+ * "response" is an int *
+ * (int *)response)[0] is 1 for "mute enabled" and 0 for "mute disabled"
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * SS_MODIFIED_TO_DIAL
+ * SS_MODIFIED_TO_USSD
+ * SS_MODIFIED_TO_SS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_GET_MUTE 54
+
+/**
+ * RIL_REQUEST_QUERY_CLIP
+ *
+ * Queries the status of the CLIP supplementary service
+ *
+ * (for MMI code "*#30#")
+ *
+ * "data" is NULL
+ * "response" is an int *
+ * (int *)response)[0] is 1 for "CLIP provisioned"
+ * and 0 for "CLIP not provisioned"
+ * and 2 for "unknown, e.g. no network etc"
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * FDN_CHECK_FAILURE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_QUERY_CLIP 55
+
+/**
+ * RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE - Deprecated use the status
+ * field in RIL_Data_Call_Response_v6.
+ *
+ * Requests the failure cause code for the most recently failed PDP
+ * context or CDMA data connection active
+ * replaces RIL_REQUEST_LAST_PDP_FAIL_CAUSE
+ *
+ * "data" is NULL
+ *
+ * "response" is a "int *"
+ * ((int *)response)[0] is an integer cause code defined in TS 24.008
+ * section 6.1.3.1.3 or close approximation
+ *
+ * If the implementation does not have access to the exact cause codes,
+ * then it should return one of the values listed in
+ * RIL_DataCallFailCause, as the UI layer needs to distinguish these
+ * cases for error notification
+ * and potential retries.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_LAST_CALL_FAIL_CAUSE
+ *
+ * Deprecated use the status field in RIL_Data_Call_Response_v6.
+ */
+
+#define RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE 56
+
+/**
+ * RIL_REQUEST_DATA_CALL_LIST
+ *
+ * Returns the data call list. An entry is added when a
+ * RIL_REQUEST_SETUP_DATA_CALL is issued and removed on a
+ * RIL_REQUEST_DEACTIVATE_DATA_CALL. The list is emptied
+ * when RIL_REQUEST_RADIO_POWER off/on is issued.
+ *
+ * "data" is NULL
+ * "response" is an array of RIL_Data_Call_Response_v6
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ * See also: RIL_UNSOL_DATA_CALL_LIST_CHANGED
+ */
+
+#define RIL_REQUEST_DATA_CALL_LIST 57
+
+/**
+ * RIL_REQUEST_RESET_RADIO - DEPRECATED
+ *
+ * Request a radio reset. The RIL implementation may postpone
+ * the reset until after this request is responded to if the baseband
+ * is presently busy.
+ *
+ * The request is DEPRECATED, use RIL_REQUEST_RADIO_POWER
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * REQUEST_NOT_SUPPORTED
+ */
+
+#define RIL_REQUEST_RESET_RADIO 58
+
+/**
+ * RIL_REQUEST_OEM_HOOK_RAW
+ *
+ * This request reserved for OEM-specific uses. It passes raw byte arrays
+ * back and forth.
+ *
+ * It can be invoked on the Java side from
+ * com.android.internal.telephony.Phone.invokeOemRilRequestRaw()
+ *
+ * "data" is a char * of bytes copied from the byte[] data argument in java
+ * "response" is a char * of bytes that will returned via the
+ * caller's "response" Message here:
+ * (byte[])(((AsyncResult)response.obj).result)
+ *
+ * An error response here will result in
+ * (((AsyncResult)response.obj).result) == null and
+ * (((AsyncResult)response.obj).exception) being an instance of
+ * com.android.internal.telephony.gsm.CommandException
+ *
+ * Valid errors:
+ * All
+ */
+
+#define RIL_REQUEST_OEM_HOOK_RAW 59
+
+/**
+ * RIL_REQUEST_OEM_HOOK_STRINGS
+ *
+ * This request reserved for OEM-specific uses. It passes strings
+ * back and forth.
+ *
+ * It can be invoked on the Java side from
+ * com.android.internal.telephony.Phone.invokeOemRilRequestStrings()
+ *
+ * "data" is a const char **, representing an array of null-terminated UTF-8
+ * strings copied from the "String[] strings" argument to
+ * invokeOemRilRequestStrings()
+ *
+ * "response" is a const char **, representing an array of null-terminated UTF-8
+ * stings that will be returned via the caller's response message here:
+ *
+ * (String[])(((AsyncResult)response.obj).result)
+ *
+ * An error response here will result in
+ * (((AsyncResult)response.obj).result) == null and
+ * (((AsyncResult)response.obj).exception) being an instance of
+ * com.android.internal.telephony.gsm.CommandException
+ *
+ * Valid errors:
+ * All
+ */
+
+#define RIL_REQUEST_OEM_HOOK_STRINGS 60
+
+/**
+ * RIL_REQUEST_SCREEN_STATE - DEPRECATED
+ *
+ * Indicates the current state of the screen. When the screen is off, the
+ * RIL should notify the baseband to suppress certain notifications (eg,
+ * signal strength and changes in LAC/CID or BID/SID/NID/latitude/longitude)
+ * in an effort to conserve power. These notifications should resume when the
+ * screen is on.
+ *
+ * Note this request is deprecated. Use RIL_REQUEST_SEND_DEVICE_STATE to report the device state
+ * to the modem and use RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER to turn on/off unsolicited
+ * response from the modem in different scenarios.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 1 for "Screen On"
+ * ((int *)data)[0] is == 0 for "Screen Off"
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SCREEN_STATE 61
+
+
+/**
+ * RIL_REQUEST_SET_SUPP_SVC_NOTIFICATION
+ *
+ * Enables/disables supplementary service related notifications
+ * from the network.
+ *
+ * Notifications are reported via RIL_UNSOL_SUPP_SVC_NOTIFICATION.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 1 for notifications enabled
+ * ((int *)data)[0] is == 0 for notifications disabled
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SIM_BUSY
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_UNSOL_SUPP_SVC_NOTIFICATION.
+ */
+#define RIL_REQUEST_SET_SUPP_SVC_NOTIFICATION 62
+
+/**
+ * RIL_REQUEST_WRITE_SMS_TO_SIM
+ *
+ * Stores a SMS message to SIM memory.
+ *
+ * "data" is RIL_SMS_WriteArgs *
+ *
+ * "response" is int *
+ * ((const int *)response)[0] is the record index where the message is stored.
+ *
+ * Valid errors:
+ * SUCCESS
+ * SIM_FULL
+ * INVALID_ARGUMENTS
+ * INVALID_SMS_FORMAT
+ * INTERNAL_ERR
+ * MODEM_ERR
+ * ENCODING_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * INVALID_MODEM_STATE
+ * OPERATION_NOT_ALLOWED
+ * INVALID_SMSC_ADDRESS
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_WRITE_SMS_TO_SIM 63
+
+/**
+ * RIL_REQUEST_DELETE_SMS_ON_SIM
+ *
+ * Deletes a SMS message from SIM memory.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is the record index of the message to delete.
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * SIM_FULL
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NO_SUCH_ENTRY
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_DELETE_SMS_ON_SIM 64
+
+/**
+ * RIL_REQUEST_SET_BAND_MODE
+ *
+ * Assign a specified band for RF configuration.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is a RIL_RadioBandMode
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * See also: RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE
+ */
+#define RIL_REQUEST_SET_BAND_MODE 65
+
+/**
+ * RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE
+ *
+ * Query the list of band mode supported by RF.
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * "response" points to an array of int's, the int[0] is the size of array;
+ * subsequent values are a list of RIL_RadioBandMode listing supported modes.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * See also: RIL_REQUEST_SET_BAND_MODE
+ */
+#define RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE 66
+
+/**
+ * RIL_REQUEST_STK_GET_PROFILE
+ *
+ * Requests the profile of SIM tool kit.
+ * The profile indicates the SAT/USAT features supported by ME.
+ * The SAT/USAT features refer to 3GPP TS 11.14 and 3GPP TS 31.111
+ *
+ * "data" is NULL
+ *
+ * "response" is a const char * containing SAT/USAT profile
+ * in hexadecimal format string starting with first byte of terminal profile
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_STK_GET_PROFILE 67
+
+/**
+ * RIL_REQUEST_STK_SET_PROFILE
+ *
+ * Download the STK terminal profile as part of SIM initialization
+ * procedure
+ *
+ * "data" is a const char * containing SAT/USAT profile
+ * in hexadecimal format string starting with first byte of terminal profile
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_STK_SET_PROFILE 68
+
+/**
+ * RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND
+ *
+ * Requests to send a SAT/USAT envelope command to SIM.
+ * The SAT/USAT envelope command refers to 3GPP TS 11.14 and 3GPP TS 31.111
+ *
+ * "data" is a const char * containing SAT/USAT command
+ * in hexadecimal format string starting with command tag
+ *
+ * "response" is a const char * containing SAT/USAT response
+ * in hexadecimal format string starting with first byte of response
+ * (May be NULL)
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * SIM_BUSY
+ * OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND 69
+
+/**
+ * RIL_REQUEST_STK_SEND_TERMINAL_RESPONSE
+ *
+ * Requests to send a terminal response to SIM for a received
+ * proactive command
+ *
+ * "data" is a const char * containing SAT/USAT response
+ * in hexadecimal format string starting with first byte of response data
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * RIL_E_OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_STK_SEND_TERMINAL_RESPONSE 70
+
+/**
+ * RIL_REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM
+ *
+ * When STK application gets RIL_UNSOL_STK_CALL_SETUP, the call actually has
+ * been initialized by ME already. (We could see the call has been in the 'call
+ * list') So, STK application needs to accept/reject the call according as user
+ * operations.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is > 0 for "accept" the call setup
+ * ((int *)data)[0] is == 0 for "reject" the call setup
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * RIL_E_OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM 71
+
+/**
+ * RIL_REQUEST_EXPLICIT_CALL_TRANSFER
+ *
+ * Connects the two calls and disconnects the subscriber from both calls.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * INVALID_STATE
+ * NO_RESOURCES
+ * NO_MEMORY
+ * INVALID_ARGUMENTS
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * INVALID_STATE
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_EXPLICIT_CALL_TRANSFER 72
+
+/**
+ * RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE
+ *
+ * Requests to set the preferred network type for searching and registering
+ * (CS/PS domain, RAT, and operation mode)
+ *
+ * "data" is int * which is RIL_PreferredNetworkType
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * OPERATION_NOT_ALLOWED
+ * MODE_NOT_SUPPORTED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE 73
+
+/**
+ * RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE
+ *
+ * Query the preferred network type (CS/PS domain, RAT, and operation mode)
+ * for searching and registering
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)reponse)[0] is == RIL_PreferredNetworkType
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * See also: RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE
+ */
+#define RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE 74
+
+/**
+ * RIL_REQUEST_NEIGHBORING_CELL_IDS
+ *
+ * Request neighboring cell id in GSM network
+ *
+ * "data" is NULL
+ * "response" must be a " const RIL_NeighboringCell** "
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NO_NETWORK_FOUND
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_GET_NEIGHBORING_CELL_IDS 75
+
+/**
+ * RIL_REQUEST_SET_LOCATION_UPDATES
+ *
+ * Enables/disables network state change notifications due to changes in
+ * LAC and/or CID (for GSM) or BID/SID/NID/latitude/longitude (for CDMA).
+ * Basically +CREG=2 vs. +CREG=1 (TS 27.007).
+ *
+ * Note: The RIL implementation should default to "updates enabled"
+ * when the screen is on and "updates disabled" when the screen is off.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 1 for updates enabled (+CREG=2)
+ * ((int *)data)[0] is == 0 for updates disabled (+CREG=1)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * See also: RIL_REQUEST_SCREEN_STATE, RIL_UNSOL_RESPONSE_NETWORK_STATE_CHANGED
+ */
+#define RIL_REQUEST_SET_LOCATION_UPDATES 76
+
+/**
+ * RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE
+ *
+ * Request to set the location where the CDMA subscription shall
+ * be retrieved
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == RIL_CdmaSubscriptionSource
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SIM_ABSENT
+ * SUBSCRIPTION_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE
+ */
+#define RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE 77
+
+/**
+ * RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE
+ *
+ * Request to set the roaming preferences in CDMA
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 0 for Home Networks only, as defined in PRL
+ * ((int *)data)[0] is == 1 for Roaming on Affiliated networks, as defined in PRL
+ * ((int *)data)[0] is == 2 for Roaming on Any Network, as defined in the PRL
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE 78
+
+/**
+ * RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE
+ *
+ * Request the actual setting of the roaming preferences in CDMA in the modem
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)response)[0] is == 0 for Home Networks only, as defined in PRL
+ * ((int *)response)[0] is == 1 for Roaming on Affiliated networks, as defined in PRL
+ * ((int *)response)[0] is == 2 for Roaming on Any Network, as defined in the PRL
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE 79
+
+/**
+ * RIL_REQUEST_SET_TTY_MODE
+ *
+ * Request to set the TTY mode
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 0 for TTY off
+ * ((int *)data)[0] is == 1 for TTY Full
+ * ((int *)data)[0] is == 2 for TTY HCO (hearing carryover)
+ * ((int *)data)[0] is == 3 for TTY VCO (voice carryover)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SET_TTY_MODE 80
+
+/**
+ * RIL_REQUEST_QUERY_TTY_MODE
+ *
+ * Request the setting of TTY mode
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)response)[0] is == 0 for TTY off
+ * ((int *)response)[0] is == 1 for TTY Full
+ * ((int *)response)[0] is == 2 for TTY HCO (hearing carryover)
+ * ((int *)response)[0] is == 3 for TTY VCO (voice carryover)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_QUERY_TTY_MODE 81
+
+/**
+ * RIL_REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE
+ *
+ * Request to set the preferred voice privacy mode used in voice
+ * scrambling
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == 0 for Standard Privacy Mode (Public Long Code Mask)
+ * ((int *)data)[0] is == 1 for Enhanced Privacy Mode (Private Long Code Mask)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_CALL_ID
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE 82
+
+/**
+ * RIL_REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE
+ *
+ * Request the setting of preferred voice privacy mode
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)response)[0] is == 0 for Standard Privacy Mode (Public Long Code Mask)
+ * ((int *)response)[0] is == 1 for Enhanced Privacy Mode (Private Long Code Mask)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE 83
+
+/**
+ * RIL_REQUEST_CDMA_FLASH
+ *
+ * Send FLASH
+ *
+ * "data" is const char *
+ * ((const char *)data)[0] is a FLASH string
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * INVALID_STATE
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_FLASH 84
+
+/**
+ * RIL_REQUEST_CDMA_BURST_DTMF
+ *
+ * Send DTMF string
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is a DTMF string
+ * ((const char **)data)[1] is the DTMF ON length in milliseconds, or 0 to use
+ * default
+ * ((const char **)data)[2] is the DTMF OFF length in milliseconds, or 0 to use
+ * default
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * INVALID_CALL_ID
+ * NO_RESOURCES
+ * CANCELLED
+ * OPERATION_NOT_ALLOWED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_BURST_DTMF 85
+
+/**
+ * RIL_REQUEST_CDMA_VALIDATE_AND_WRITE_AKEY
+ *
+ * Takes a 26 digit string (20 digit AKEY + 6 digit checksum).
+ * If the checksum is valid the 20 digit AKEY is written to NV,
+ * replacing the existing AKEY no matter what it was before.
+ *
+ * "data" is const char *
+ * ((const char *)data)[0] is a 26 digit string (ASCII digits '0'-'9')
+ * where the last 6 digits are a checksum of the
+ * first 20, as specified in TR45.AHAG
+ * "Common Cryptographic Algorithms, Revision D.1
+ * Section 2.2"
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_CDMA_VALIDATE_AND_WRITE_AKEY 86
+
+/**
+ * RIL_REQUEST_CDMA_SEND_SMS
+ *
+ * Send a CDMA SMS message
+ *
+ * "data" is const RIL_CDMA_SMS_Message *
+ *
+ * "response" is a const RIL_SMS_Response *
+ *
+ * Based on the return error, caller decides to resend if sending sms
+ * fails. The CDMA error class is derived as follows,
+ * SUCCESS is error class 0 (no error)
+ * SMS_SEND_FAIL_RETRY is error class 2 (temporary failure)
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SMS_SEND_FAIL_RETRY
+ * NETWORK_REJECT
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * INVALID_SMS_FORMAT
+ * SYSTEM_ERR
+ * FDN_CHECK_FAILURE
+ * MODEM_ERR
+ * NETWORK_ERR
+ * ENCODING_ERR
+ * INVALID_SMSC_ADDRESS
+ * OPERATION_NOT_ALLOWED
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * MODE_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_CDMA_SEND_SMS 87
+
+/**
+ * RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE
+ *
+ * Acknowledge the success or failure in the receipt of SMS
+ * previously indicated via RIL_UNSOL_RESPONSE_CDMA_NEW_SMS
+ *
+ * "data" is const RIL_CDMA_SMS_Ack *
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_SMS_TO_ACK
+ * INVALID_STATE
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INVALID_STATE
+ * OPERATION_NOT_ALLOWED
+ * NETWORK_NOT_READY
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE 88
+
+/**
+ * RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG
+ *
+ * Request the setting of GSM/WCDMA Cell Broadcast SMS config.
+ *
+ * "data" is NULL
+ *
+ * "response" is a const RIL_GSM_BroadcastSmsConfigInfo **
+ * "responselen" is count * sizeof (RIL_GSM_BroadcastSmsConfigInfo *)
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * NO_RESOURCES
+ * MODEM_ERR
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG 89
+
+/**
+ * RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG
+ *
+ * Set GSM/WCDMA Cell Broadcast SMS config
+ *
+ * "data" is a const RIL_GSM_BroadcastSmsConfigInfo **
+ * "datalen" is count * sizeof(RIL_GSM_BroadcastSmsConfigInfo *)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG 90
+
+/**
+ * RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION
+ *
+* Enable or disable the reception of GSM/WCDMA Cell Broadcast SMS
+ *
+ * "data" is const int *
+ * (const int *)data[0] indicates to activate or turn off the
+ * reception of GSM/WCDMA Cell Broadcast SMS, 0-1,
+ * 0 - Activate, 1 - Turn off
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+* MODEM_ERR
+* INTERNAL_ERR
+* NO_RESOURCES
+* CANCELLED
+* INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION 91
+
+/**
+ * RIL_REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG
+ *
+ * Request the setting of CDMA Broadcast SMS config
+ *
+ * "data" is NULL
+ *
+ * "response" is a const RIL_CDMA_BroadcastSmsConfigInfo **
+ * "responselen" is count * sizeof (RIL_CDMA_BroadcastSmsConfigInfo *)
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * NO_RESOURCES
+ * MODEM_ERR
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG 92
+
+/**
+ * RIL_REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG
+ *
+ * Set CDMA Broadcast SMS config
+ *
+ * "data" is a const RIL_CDMA_BroadcastSmsConfigInfo **
+ * "datalen" is count * sizeof(const RIL_CDMA_BroadcastSmsConfigInfo *)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG 93
+
+/**
+ * RIL_REQUEST_CDMA_SMS_BROADCAST_ACTIVATION
+ *
+ * Enable or disable the reception of CDMA Broadcast SMS
+ *
+ * "data" is const int *
+ * (const int *)data[0] indicates to activate or turn off the
+ * reception of CDMA Broadcast SMS, 0-1,
+ * 0 - Activate, 1 - Turn off
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_STATE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_CDMA_SMS_BROADCAST_ACTIVATION 94
+
+/**
+ * RIL_REQUEST_CDMA_SUBSCRIPTION
+ *
+ * Request the device MDN / H_SID / H_NID.
+ *
+ * The request is only allowed when CDMA subscription is available. When CDMA
+ * subscription is changed, application layer should re-issue the request to
+ * update the subscription information.
+ *
+ * If a NULL value is returned for any of the device id, it means that error
+ * accessing the device.
+ *
+ * "response" is const char **
+ * ((const char **)response)[0] is MDN if CDMA subscription is available
+ * ((const char **)response)[1] is a comma separated list of H_SID (Home SID) if
+ * CDMA subscription is available, in decimal format
+ * ((const char **)response)[2] is a comma separated list of H_NID (Home NID) if
+ * CDMA subscription is available, in decimal format
+ * ((const char **)response)[3] is MIN (10 digits, MIN2+MIN1) if CDMA subscription is available
+ * ((const char **)response)[4] is PRL version if CDMA subscription is available
+ *
+ * Valid errors:
+ * SUCCESS
+ * RIL_E_SUBSCRIPTION_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+
+#define RIL_REQUEST_CDMA_SUBSCRIPTION 95
+
+/**
+ * RIL_REQUEST_CDMA_WRITE_SMS_TO_RUIM
+ *
+ * Stores a CDMA SMS message to RUIM memory.
+ *
+ * "data" is RIL_CDMA_SMS_WriteArgs *
+ *
+ * "response" is int *
+ * ((const int *)response)[0] is the record index where the message is stored.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SIM_FULL
+ * INVALID_ARGUMENTS
+ * INVALID_SMS_FORMAT
+ * INTERNAL_ERR
+ * MODEM_ERR
+ * ENCODING_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * INVALID_MODEM_STATE
+ * OPERATION_NOT_ALLOWED
+ * INVALID_SMSC_ADDRESS
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_CDMA_WRITE_SMS_TO_RUIM 96
+
+/**
+ * RIL_REQUEST_CDMA_DELETE_SMS_ON_RUIM
+ *
+ * Deletes a CDMA SMS message from RUIM memory.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is the record index of the message to delete.
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NO_SUCH_ENTRY
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_CDMA_DELETE_SMS_ON_RUIM 97
+
+/**
+ * RIL_REQUEST_DEVICE_IDENTITY
+ *
+ * Request the device ESN / MEID / IMEI / IMEISV.
+ *
+ * The request is always allowed and contains GSM and CDMA device identity;
+ * it substitutes the deprecated requests RIL_REQUEST_GET_IMEI and
+ * RIL_REQUEST_GET_IMEISV.
+ *
+ * If a NULL value is returned for any of the device id, it means that error
+ * accessing the device.
+ *
+ * When CDMA subscription is changed the ESN/MEID may change. The application
+ * layer should re-issue the request to update the device identity in this case.
+ *
+ * "response" is const char **
+ * ((const char **)response)[0] is IMEI if GSM subscription is available
+ * ((const char **)response)[1] is IMEISV if GSM subscription is available
+ * ((const char **)response)[2] is ESN if CDMA subscription is available
+ * ((const char **)response)[3] is MEID if CDMA subscription is available
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_DEVICE_IDENTITY 98
+
+/**
+ * RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE
+ *
+ * Request the radio's system selection module to exit emergency
+ * callback mode. RIL will not respond with SUCCESS until the modem has
+ * completely exited from Emergency Callback Mode.
+ *
+ * "data" is NULL
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE 99
+
+/**
+ * RIL_REQUEST_GET_SMSC_ADDRESS
+ *
+ * Queries the default Short Message Service Center address on the device.
+ *
+ * "data" is NULL
+ *
+ * "response" is const char * containing the SMSC address.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * REQUEST_RATE_LIMITED
+ * SYSTEM_ERR
+ * INTERNAL_ERR
+ * MODEM_ERR
+ * INVALID_ARGUMENTS
+ * INVALID_MODEM_STATE
+ * NOT_PROVISIONED
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ *
+ */
+#define RIL_REQUEST_GET_SMSC_ADDRESS 100
+
+/**
+ * RIL_REQUEST_SET_SMSC_ADDRESS
+ *
+ * Sets the default Short Message Service Center address on the device.
+ *
+ * "data" is const char * containing the SMSC address.
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * INVALID_SMS_FORMAT
+ * NO_MEMORY
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * NO_RESOURCES
+ * INTERNAL_ERR
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_SET_SMSC_ADDRESS 101
+
+/**
+ * RIL_REQUEST_REPORT_SMS_MEMORY_STATUS
+ *
+ * Indicates whether there is storage available for new SMS messages.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is 1 if memory is available for storing new messages
+ * is 0 if memory capacity is exceeded
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INVALID_ARGUMENTS
+ * NO_MEMORY
+ * INVALID_STATE
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_REPORT_SMS_MEMORY_STATUS 102
+
+/**
+ * RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING
+ *
+ * Indicates that the StkSerivce is running and is
+ * ready to receive RIL_UNSOL_STK_XXXXX commands.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING 103
+
+/**
+ * RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE
+ *
+ * Request to query the location where the CDMA subscription shall
+ * be retrieved
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)data)[0] is == RIL_CdmaSubscriptionSource
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SUBSCRIPTION_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ * See also: RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE
+ */
+#define RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE 104
+
+/**
+ * RIL_REQUEST_ISIM_AUTHENTICATION
+ *
+ * Request the ISIM application on the UICC to perform AKA
+ * challenge/response algorithm for IMS authentication
+ *
+ * "data" is a const char * containing the challenge string in Base64 format
+ * "response" is a const char * containing the response in Base64 format
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_ISIM_AUTHENTICATION 105
+
+/**
+ * RIL_REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU
+ *
+ * Acknowledge successful or failed receipt of SMS previously indicated
+ * via RIL_UNSOL_RESPONSE_NEW_SMS, including acknowledgement TPDU to send
+ * as the RP-User-Data element of the RP-ACK or RP-ERROR PDU.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] is "1" on successful receipt (send RP-ACK)
+ * is "0" on failed receipt (send RP-ERROR)
+ * ((const char **)data)[1] is the acknowledgement TPDU in hexadecimal format
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU 106
+
+/**
+ * RIL_REQUEST_STK_SEND_ENVELOPE_WITH_STATUS
+ *
+ * Requests to send a SAT/USAT envelope command to SIM.
+ * The SAT/USAT envelope command refers to 3GPP TS 11.14 and 3GPP TS 31.111.
+ *
+ * This request has one difference from RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND:
+ * the SW1 and SW2 status bytes from the UICC response are returned along with
+ * the response data, using the same structure as RIL_REQUEST_SIM_IO.
+ *
+ * The RIL implementation shall perform the normal processing of a '91XX'
+ * response in SW1/SW2 to retrieve the pending proactive command and send it
+ * as an unsolicited response, as RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND does.
+ *
+ * "data" is a const char * containing the SAT/USAT command
+ * in hexadecimal format starting with command tag
+ *
+ * "response" is a const RIL_SIM_IO_Response *
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE (radio resetting)
+ * SIM_BUSY
+ * OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_STK_SEND_ENVELOPE_WITH_STATUS 107
+
+/**
+ * RIL_REQUEST_VOICE_RADIO_TECH
+ *
+ * Query the radio technology type (3GPP/3GPP2) used for voice. Query is valid only
+ * when radio state is not RADIO_STATE_UNAVAILABLE
+ *
+ * "data" is NULL
+ * "response" is int *
+ * ((int *) response)[0] is of type const RIL_RadioTechnology
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_VOICE_RADIO_TECH 108
+
+/**
+ * RIL_REQUEST_GET_CELL_INFO_LIST
+ *
+ * Request all of the current cell information known to the radio. The radio
+ * must a list of all current cells, including the neighboring cells. If for a particular
+ * cell information isn't known then the appropriate unknown value will be returned.
+ * This does not cause or change the rate of RIL_UNSOL_CELL_INFO_LIST.
+ *
+ * "data" is NULL
+ *
+ * "response" is an array of RIL_CellInfo_v12.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NO_NETWORK_FOUND
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_GET_CELL_INFO_LIST 109
+
+/**
+ * RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE
+ *
+ * Sets the minimum time between when RIL_UNSOL_CELL_INFO_LIST should be invoked.
+ * A value of 0, means invoke RIL_UNSOL_CELL_INFO_LIST when any of the reported
+ * information changes. Setting the value to INT_MAX(0x7fffffff) means never issue
+ * a RIL_UNSOL_CELL_INFO_LIST.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is minimum time in milliseconds
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE 110
+
+/**
+ * RIL_REQUEST_SET_INITIAL_ATTACH_APN
+ *
+ * Set an apn to initial attach network
+ *
+ * "data" is a const char **
+ * ((const char **)data)[0] is the APN to connect if radio technology is LTE
+ * ((const char **)data)[1] is the connection type to request must be one of the
+ * PDP_type values in TS 27.007 section 10.1.1.
+ * For example, "IP", "IPV6", "IPV4V6", or "PPP".
+ * ((const char **)data)[2] is the PAP / CHAP auth type. Values:
+ * 0 => PAP and CHAP is never performed.
+ * 1 => PAP may be performed; CHAP is never performed.
+ * 2 => CHAP may be performed; PAP is never performed.
+ * 3 => PAP / CHAP may be performed - baseband dependent.
+ * ((const char **)data)[3] is the username for APN, or NULL
+ * ((const char **)data)[4] is the password for APN, or NULL
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * SUBSCRIPTION_NOT_AVAILABLE
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_SET_INITIAL_ATTACH_APN 111
+
+/**
+ * RIL_REQUEST_IMS_REGISTRATION_STATE
+ *
+ * This message is DEPRECATED and shall be removed in a future release (target: 2018);
+ * instead, provide IMS registration status via an IMS Service.
+ *
+ * Request current IMS registration state
+ *
+ * "data" is NULL
+ *
+ * "response" is int *
+ * ((int *)response)[0] is registration state:
+ * 0 - Not registered
+ * 1 - Registered
+ *
+ * If ((int*)response)[0] is = 1, then ((int *) response)[1]
+ * must follow with IMS SMS format:
+ *
+ * ((int *) response)[1] is of type RIL_RadioTechnologyFamily
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_IMS_REGISTRATION_STATE 112
+
+/**
+ * RIL_REQUEST_IMS_SEND_SMS
+ *
+ * Send a SMS message over IMS
+ *
+ * "data" is const RIL_IMS_SMS_Message *
+ *
+ * "response" is a const RIL_SMS_Response *
+ *
+ * Based on the return error, caller decides to resend if sending sms
+ * fails. SMS_SEND_FAIL_RETRY means retry, and other errors means no retry.
+ * In case of retry, data is encoded based on Voice Technology available.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * SMS_SEND_FAIL_RETRY
+ * FDN_CHECK_FAILURE
+ * NETWORK_REJECT
+ * INVALID_ARGUMENTS
+ * INVALID_STATE
+ * NO_MEMORY
+ * INVALID_SMS_FORMAT
+ * SYSTEM_ERR
+ * REQUEST_RATE_LIMITED
+ * MODEM_ERR
+ * NETWORK_ERR
+ * ENCODING_ERR
+ * INVALID_SMSC_ADDRESS
+ * OPERATION_NOT_ALLOWED
+ * INTERNAL_ERR
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_IMS_SEND_SMS 113
+
+/**
+ * RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC
+ *
+ * Request APDU exchange on the basic channel. This command reflects TS 27.007
+ * "generic SIM access" operation (+CSIM). The modem must ensure proper function
+ * of GSM/CDMA, and filter commands appropriately. It should filter
+ * channel management and SELECT by DF name commands.
+ *
+ * "data" is a const RIL_SIM_APDU *
+ * "sessionid" field should be ignored.
+ *
+ * "response" is a const RIL_SIM_IO_Response *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC 114
+
+/**
+ * RIL_REQUEST_SIM_OPEN_CHANNEL
+ *
+ * Open a new logical channel and select the given application. This command
+ * reflects TS 27.007 "open logical channel" operation (+CCHO). This request
+ * also specifies the P2 parameter (described in ISO 7816-4).
+ *
+ * "data" is a const RIL_OpenChannelParam *
+ *
+ * "response" is int *
+ * ((int *)data)[0] contains the session id of the logical channel.
+ * ((int *)data)[1] onwards may optionally contain the select response for the
+ * open channel command with one byte per integer.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * MISSING_RESOURCE
+ * NO_SUCH_ELEMENT
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * SIM_ERR
+ * INVALID_SIM_STATE
+ * MISSING_RESOURCE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_OPEN_CHANNEL 115
+
+/**
+ * RIL_REQUEST_SIM_CLOSE_CHANNEL
+ *
+ * Close a previously opened logical channel. This command reflects TS 27.007
+ * "close logical channel" operation (+CCHC).
+ *
+ * "data" is int *
+ * ((int *)data)[0] is the session id of logical the channel to close.
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_CLOSE_CHANNEL 116
+
+/**
+ * RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL
+ *
+ * Exchange APDUs with a UICC over a previously opened logical channel. This
+ * command reflects TS 27.007 "generic logical channel access" operation
+ * (+CGLA). The modem should filter channel management and SELECT by DF name
+ * commands.
+ *
+ * "data" is a const RIL_SIM_APDU*
+ *
+ * "response" is a const RIL_SIM_IO_Response *
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL 117
+
+/**
+ * RIL_REQUEST_NV_READ_ITEM
+ *
+ * Read one of the radio NV items defined in RadioNVItems.java / ril_nv_items.h.
+ * This is used for device configuration by some CDMA operators.
+ *
+ * "data" is a const RIL_NV_ReadItem *
+ *
+ * "response" is const char * containing the contents of the NV item
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_NV_READ_ITEM 118
+
+/**
+ * RIL_REQUEST_NV_WRITE_ITEM
+ *
+ * Write one of the radio NV items defined in RadioNVItems.java / ril_nv_items.h.
+ * This is used for device configuration by some CDMA operators.
+ *
+ * "data" is a const RIL_NV_WriteItem *
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_NV_WRITE_ITEM 119
+
+/**
+ * RIL_REQUEST_NV_WRITE_CDMA_PRL
+ *
+ * Update the CDMA Preferred Roaming List (PRL) in the radio NV storage.
+ * This is used for device configuration by some CDMA operators.
+ *
+ * "data" is a const char * containing the PRL as a byte array
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_NV_WRITE_CDMA_PRL 120
+
+/**
+ * RIL_REQUEST_NV_RESET_CONFIG
+ *
+ * Reset the radio NV configuration to the factory state.
+ * This is used for device configuration by some CDMA operators.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is 1 to reload all NV items
+ * ((int *)data)[0] is 2 for erase NV reset (SCRTN)
+ * ((int *)data)[0] is 3 for factory reset (RTN)
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_NV_RESET_CONFIG 121
+
+ /** RIL_REQUEST_SET_UICC_SUBSCRIPTION
+ * FIXME This API needs to have more documentation.
+ *
+ * Selection/de-selection of a subscription from a SIM card
+ * "data" is const RIL_SelectUiccSub*
+
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * SUBSCRIPTION_NOT_SUPPORTED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_SET_UICC_SUBSCRIPTION 122
+
+/**
+ * RIL_REQUEST_ALLOW_DATA
+ *
+ * Tells the modem whether data calls are allowed or not
+ *
+ * "data" is int *
+ * FIXME slotId and aid will be added.
+ * ((int *)data)[0] is == 0 to allow data calls
+ * ((int *)data)[0] is == 1 to disallow data calls
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * INVALID_ARGUMENTS
+ * DEVICE_IN_USE
+ * INVALID_MODEM_STATE
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_ALLOW_DATA 123
+
+/**
+ * RIL_REQUEST_GET_HARDWARE_CONFIG
+ *
+ * Request all of the current hardware (modem and sim) associated
+ * with the RIL.
+ *
+ * "data" is NULL
+ *
+ * "response" is an array of RIL_HardwareConfig.
+ *
+ * Valid errors:
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_GET_HARDWARE_CONFIG 124
+
+/**
+ * RIL_REQUEST_SIM_AUTHENTICATION
+ *
+ * Returns the response of SIM Authentication through RIL to a
+ * challenge request.
+ *
+ * "data" Base64 encoded string containing challenge:
+ * int authContext; P2 value of authentication command, see P2 parameter in
+ * 3GPP TS 31.102 7.1.2
+ * char *authData; the challenge string in Base64 format, see 3GPP
+ * TS 31.102 7.1.2
+ * char *aid; AID value, See ETSI 102.221 8.1 and 101.220 4,
+ * NULL if no value
+ *
+ * "response" Base64 encoded strings containing response:
+ * int sw1; Status bytes per 3GPP TS 31.102 section 7.3
+ * int sw2;
+ * char *simResponse; Response in Base64 format, see 3GPP TS 31.102 7.1.2
+ *
+ * Valid errors:
+ * RADIO_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * INVALID_MODEM_STATE
+ * INVALID_ARGUMENTS
+ * SIM_ERR
+ * REQUEST_NOT_SUPPORTED
+ */
+#define RIL_REQUEST_SIM_AUTHENTICATION 125
+
+/**
+ * RIL_REQUEST_GET_DC_RT_INFO
+ *
+ * The request is DEPRECATED, use RIL_REQUEST_GET_ACTIVITY_INFO
+ * Requests the Data Connection Real Time Info
+ *
+ * "data" is NULL
+ *
+ * "response" is the most recent RIL_DcRtInfo
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ * See also: RIL_UNSOL_DC_RT_INFO_CHANGED
+ */
+#define RIL_REQUEST_GET_DC_RT_INFO 126
+
+/**
+ * RIL_REQUEST_SET_DC_RT_INFO_RATE
+ *
+ * The request is DEPRECATED
+ * This is the minimum number of milliseconds between successive
+ * RIL_UNSOL_DC_RT_INFO_CHANGED messages and defines the highest rate
+ * at which RIL_UNSOL_DC_RT_INFO_CHANGED's will be sent. A value of
+ * 0 means send as fast as possible.
+ *
+ * "data" The number of milliseconds as an int
+ *
+ * "response" is null
+ *
+ * Valid errors:
+ * SUCCESS must not fail
+ */
+#define RIL_REQUEST_SET_DC_RT_INFO_RATE 127
+
+/**
+ * RIL_REQUEST_SET_DATA_PROFILE
+ *
+ * Set data profile in modem
+ * Modem should erase existed profiles from framework, and apply new profiles
+ * "data" is a const RIL_DataProfileInfo **
+ * "datalen" is count * sizeof(const RIL_DataProfileInfo *)
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * SUBSCRIPTION_NOT_AVAILABLE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_SET_DATA_PROFILE 128
+
+/**
+ * RIL_REQUEST_SHUTDOWN
+ *
+ * Device is shutting down. All further commands are ignored
+ * and RADIO_NOT_AVAILABLE must be returned.
+ *
+ * "data" is null
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SHUTDOWN 129
+
+/**
+ * RIL_REQUEST_GET_RADIO_CAPABILITY
+ *
+ * Used to get phone radio capablility.
+ *
+ * "data" is the RIL_RadioCapability structure
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * INVALID_STATE
+ * REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_GET_RADIO_CAPABILITY 130
+
+/**
+ * RIL_REQUEST_SET_RADIO_CAPABILITY
+ *
+ * Used to set the phones radio capability. Be VERY careful
+ * using this request as it may cause some vendor modems to reset. Because
+ * of the possible modem reset any RIL commands after this one may not be
+ * processed.
+ *
+ * "data" is the RIL_RadioCapability structure
+ *
+ * "response" is the RIL_RadioCapability structure, used to feedback return status
+ *
+ * Valid errors:
+ * SUCCESS means a RIL_UNSOL_RADIO_CAPABILITY will be sent within 30 seconds.
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * MODEM_ERR
+ * INVALID_STATE
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_RADIO_CAPABILITY 131
+
+/**
+ * RIL_REQUEST_START_LCE
+ *
+ * Start Link Capacity Estimate (LCE) service if supported by the radio.
+ *
+ * "data" is const int *
+ * ((const int*)data)[0] specifies the desired reporting interval (ms).
+ * ((const int*)data)[1] specifies the LCE service mode. 1: PULL; 0: PUSH.
+ *
+ * "response" is the RIL_LceStatusInfo.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * LCE_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_START_LCE 132
+
+/**
+ * RIL_REQUEST_STOP_LCE
+ *
+ * Stop Link Capacity Estimate (LCE) service, the STOP operation should be
+ * idempotent for the radio modem.
+ *
+ * "response" is the RIL_LceStatusInfo.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * LCE_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_STOP_LCE 133
+
+/**
+ * RIL_REQUEST_PULL_LCEDATA
+ *
+ * Pull LCE service for capacity information.
+ *
+ * "response" is the RIL_LceDataInfo.
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * LCE_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ */
+#define RIL_REQUEST_PULL_LCEDATA 134
+
+/**
+ * RIL_REQUEST_GET_ACTIVITY_INFO
+ *
+ * Get modem activity information for power consumption estimation.
+ *
+ * Request clear-on-read statistics information that is used for
+ * estimating the per-millisecond power consumption of the cellular
+ * modem.
+ *
+ * "data" is null
+ * "response" is const RIL_ActivityStatsInfo *
+ *
+ * Valid errors:
+ *
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * MODEM_ERR
+ * NOT_PROVISIONED
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES CANCELLED
+ */
+#define RIL_REQUEST_GET_ACTIVITY_INFO 135
+
+/**
+ * RIL_REQUEST_SET_CARRIER_RESTRICTIONS
+ *
+ * Set carrier restrictions for this sim slot. Expected modem behavior:
+ * If never receives this command
+ * - Must allow all carriers
+ * Receives this command with data being NULL
+ * - Must allow all carriers. If a previously allowed SIM is present, modem must not reload
+ * the SIM. If a previously disallowed SIM is present, reload the SIM and notify Android.
+ * Receives this command with a list of carriers
+ * - Only allow specified carriers, persist across power cycles and FDR. If a present SIM
+ * is in the allowed list, modem must not reload the SIM. If a present SIM is *not* in
+ * the allowed list, modem must detach from the registered network and only keep emergency
+ * service, and notify Android SIM refresh reset with new SIM state being
+ * RIL_CARDSTATE_RESTRICTED. Emergency service must be enabled.
+ *
+ * "data" is const RIL_CarrierRestrictions *
+ * A list of allowed carriers and possibly a list of excluded carriers.
+ * If data is NULL, means to clear previous carrier restrictions and allow all carriers
+ *
+ * "response" is int *
+ * ((int *)data)[0] contains the number of allowed carriers which have been set correctly.
+ * On success, it should match the length of list data->allowed_carriers.
+ * If data is NULL, the value must be 0.
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_INVALID_ARGUMENTS
+ * RIL_E_RADIO_NOT_AVAILABLE
+ * RIL_E_REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_CARRIER_RESTRICTIONS 136
+
+/**
+ * RIL_REQUEST_GET_CARRIER_RESTRICTIONS
+ *
+ * Get carrier restrictions for this sim slot. Expected modem behavior:
+ * Return list of allowed carriers, or null if all carriers are allowed.
+ *
+ * "data" is NULL
+ *
+ * "response" is const RIL_CarrierRestrictions *.
+ * If response is NULL, it means all carriers are allowed.
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE
+ * RIL_E_REQUEST_NOT_SUPPORTED
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_GET_CARRIER_RESTRICTIONS 137
+
+/**
+ * RIL_REQUEST_SEND_DEVICE_STATE
+ *
+ * Send the updated device state.
+ * Modem can perform power saving based on the provided device state.
+ * "data" is const int *
+ * ((const int*)data)[0] A RIL_DeviceStateType that specifies the device state type.
+ * ((const int*)data)[1] Specifies the state. See RIL_DeviceStateType for the definition of each
+ * type.
+ *
+ * "datalen" is count * sizeof(const RIL_DeviceState *)
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * INVALID_ARGUMENTS
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SEND_DEVICE_STATE 138
+
+/**
+ * RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER
+ *
+ * Set the unsolicited response filter
+ * This is used to prevent unnecessary application processor
+ * wake up for power saving purposes by suppressing the
+ * unsolicited responses in certain scenarios.
+ *
+ * "data" is an int *
+ *
+ * ((int *)data)[0] is a 32-bit bitmask of RIL_UnsolicitedResponseFilter
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * INVALID_ARGUMENTS (e.g. the requested filter doesn't exist)
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * NO_MEMORY
+ * INTERNAL_ERR
+ * SYSTEM_ERR
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER 139
+
+ /**
+ * RIL_REQUEST_SET_SIM_CARD_POWER
+ *
+ * Set SIM card power up or down
+ *
+ * Request is equivalent to inserting and removing the card, with
+ * an additional effect where the ability to detect card removal/insertion
+ * is disabled when the SIM card is powered down.
+ *
+ * This will generate RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED
+ * as if the SIM had been inserted or removed.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is 1 for "SIM POWER UP"
+ * ((int *)data)[0] is 0 for "SIM POWER DOWN"
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * REQUEST_NOT_SUPPORTED
+ * SIM_ABSENT
+ * INVALID_ARGUMENTS
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_SIM_CARD_POWER 140
+
+/**
+ * RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION
+ *
+ * Provide Carrier specific information to the modem that will be used to
+ * encrypt the IMSI and IMPI. Sent by the framework during boot, carrier
+ * switch and everytime we receive a new certificate.
+ *
+ * "data" is the RIL_CarrierInfoForImsiEncryption * structure.
+ *
+ * "response" is NULL
+ *
+ * Valid errors:
+ * RIL_E_SUCCESS
+ * RIL_E_RADIO_NOT_AVAILABLE
+ * SIM_ABSENT
+ * RIL_E_REQUEST_NOT_SUPPORTED
+ * INVALID_ARGUMENTS
+ * MODEM_INTERNAL_FAILURE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ */
+#define RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION 141
+
+/**
+ * RIL_REQUEST_START_NETWORK_SCAN
+ *
+ * Starts a new network scan
+ *
+ * Request to start a network scan with specified radio access networks with frequency bands and/or
+ * channels.
+ *
+ * "data" is a const RIL_NetworkScanRequest *.
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * OPERATION_NOT_ALLOWED
+ * DEVICE_IN_USE
+ * INTERNAL_ERR
+ * NO_MEMORY
+ * MODEM_ERR
+ * INVALID_ARGUMENTS
+ * REQUEST_NOT_SUPPORTED
+ * NO_RESOURCES
+ * CANCELLED
+ *
+ */
+#define RIL_REQUEST_START_NETWORK_SCAN 142
+
+/**
+ * RIL_REQUEST_STOP_NETWORK_SCAN
+ *
+ * Stops an ongoing network scan
+ *
+ * Request to stop the ongoing network scan. Since the modem can only perform one scan at a time,
+ * there is no parameter for this request.
+ *
+ * "data" is NULL
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * INTERNAL_ERR
+ * MODEM_ERR
+ * NO_MEMORY
+ * NO_RESOURCES
+ * CANCELLED
+ * REQUEST_NOT_SUPPORTED
+ *
+ */
+#define RIL_REQUEST_STOP_NETWORK_SCAN 143
+
+/**
+ * RIL_REQUEST_START_KEEPALIVE
+ *
+ * Start a keepalive session
+ *
+ * Request that the modem begin sending keepalive packets on a particular
+ * data call, with a specified source, destination, and format.
+ *
+ * "data" is a const RIL_RequestKeepalive
+ * "response" is RIL_KeepaliveStatus with a valid "handle"
+ *
+ * Valid errors:
+ * SUCCESS
+ * NO_RESOURCES
+ * INVALID_ARGUMENTS
+ *
+ */
+#define RIL_REQUEST_START_KEEPALIVE 144
+
+/**
+ * RIL_REQUEST_STOP_KEEPALIVE
+ *
+ * Stops an ongoing keepalive session
+ *
+ * Requests that a keepalive session with the given handle be stopped.
+ * there is no parameter for this request.
+ *
+ * "data" is an integer handle
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * INVALID_ARGUMENTS
+ *
+ */
+#define RIL_REQUEST_STOP_KEEPALIVE 145
+
+/**
+ * RIL_REQUEST_EMERGENCY_DIAL
+ *
+ * Initiate emergency voice call, with zero or more emergency service category(s), zero or
+ * more emergency Uniform Resource Names (URN), and routing information for handling the call.
+ * Android uses this request to make its emergency call instead of using @1.0::IRadio.dial
+ * if the 'address' in the 'dialInfo' field is identified as an emergency number by Android.
+ *
+ * In multi-sim scenario, if the emergency number is from a specific subscription, this radio
+ * request is sent through the IRadio service that serves the subscription, no matter of the
+ * PUK/PIN state of the subscription and the service state of the radio.
+ *
+ * Some countries or carriers require some emergency numbers that must be handled with normal
+ * call routing or emergency routing. If the 'routing' field is specified as
+ * @1.4::EmergencyNumberRouting#NORMAL, the implementation must use normal call routing to
+ * handle the call; if it is specified as @1.4::EmergencyNumberRouting#EMERGENCY, the
+ * implementation must use emergency routing to handle the call; if it is
+ * @1.4::EmergencyNumberRouting#UNKNOWN, Android does not know how to handle the call.
+ *
+ * If the dialed emergency number does not have a specified emergency service category, the
+ * 'categories' field is set to @1.4::EmergencyServiceCategory#UNSPECIFIED; if the dialed
+ * emergency number does not have specified emergency Uniform Resource Names, the 'urns' field
+ * is set to an empty list. If the underlying technology used to request emergency services
+ * does not support the emergency service category or emergency uniform resource names, the
+ * field 'categories' or 'urns' may be ignored.
+ *
+ * 'fromEmergencyDialer' indicates if this request originated from emergency dialer/shortcut,
+ * which means an explicit intent from the user to dial an emergency number. The modem must
+ * treat this as an actual emergency dial and not try to disambiguate.
+ *
+ * If 'isTesting' is true, this request is for testing purpose, and must not be sent to a real
+ * emergency service; otherwise it's for a real emergency call request.
+ * Valid errors:
+ * NONE
+ * RADIO_NOT_AVAILABLE (radio resetting)
+ * DIAL_MODIFIED_TO_USSD
+ * DIAL_MODIFIED_TO_SS
+ * DIAL_MODIFIED_TO_DIAL
+ * INVALID_ARGUMENTS
+ * NO_RESOURCES
+ * INTERNAL_ERR
+ * FDN_CHECK_FAILURE
+ * MODEM_ERR
+ * NO_SUBSCRIPTION
+ * NO_NETWORK_FOUND
+ * INVALID_CALL_ID
+ * DEVICE_IN_USE
+ * ABORTED
+ * INVALID_MODEM_STATE
+ */
+#define RIL_REQUEST_EMERGENCY_DIAL 205
+
+/**
+ * RIL_REQUEST_START_NETWORK_SCAN4
+ *
+ * Starts a new network scan
+ *
+ * Request to start a network scan with specified radio access networks with frequency bands and/or
+ * channels.
+ *
+ * "data" is a const RIL_NetworkScanRequest *.
+ * "response" is NULL
+ *
+ * Valid errors:
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ * DEVICE_IN_USE
+ * INTERNAL_ERR
+ * MODEM_ERR
+ * INVALID_ARGUMENTS
+ *
+ */
+#define RIL_REQUEST_START_NETWORK_SCAN4 206
+
+/***********************************************************************/
+
+/**
+ * RIL_RESPONSE_ACKNOWLEDGEMENT
+ *
+ * This is used by Asynchronous solicited messages and Unsolicited messages
+ * to acknowledge the receipt of those messages in RIL.java so that the ack
+ * can be used to let ril.cpp to release wakelock.
+ *
+ * Valid errors
+ * SUCCESS
+ * RADIO_NOT_AVAILABLE
+ */
+
+#define RIL_RESPONSE_ACKNOWLEDGEMENT 800
+
+/***********************************************************************/
+
+
+#define RIL_UNSOL_RESPONSE_BASE 1000
+
+/**
+ * RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED
+ *
+ * Indicate when value of RIL_RadioState has changed.
+ *
+ * Callee will invoke RIL_RadioStateRequest method on main thread
+ *
+ * "data" is NULL
+ */
+
+#define RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED 1000
+
+
+/**
+ * RIL_UNSOL_RESPONSE_CALL_STATE_CHANGED
+ *
+ * Indicate when call state has changed
+ *
+ * Callee will invoke RIL_REQUEST_GET_CURRENT_CALLS on main thread
+ *
+ * "data" is NULL
+ *
+ * Response should be invoked on, for example,
+ * "RING", "BUSY", "NO CARRIER", and also call state
+ * transitions (DIALING->ALERTING ALERTING->ACTIVE)
+ *
+ * Redundent or extraneous invocations are tolerated
+ */
+#define RIL_UNSOL_RESPONSE_CALL_STATE_CHANGED 1001
+
+
+/**
+ * RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED
+ *
+ * Called when the voice network state changed
+ *
+ * Callee will invoke the following requests on main thread:
+ *
+ * RIL_REQUEST_VOICE_REGISTRATION_STATE
+ * RIL_REQUEST_OPERATOR
+ *
+ * "data" is NULL
+ *
+ * FIXME should this happen when SIM records are loaded? (eg, for
+ * EONS)
+ */
+#define RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED 1002
+
+/**
+ * RIL_UNSOL_RESPONSE_NEW_SMS
+ *
+ * Called when new SMS is received.
+ *
+ * "data" is const char *
+ * This is a pointer to a string containing the PDU of an SMS-DELIVER
+ * as an ascii string of hex digits. The PDU starts with the SMSC address
+ * per TS 27.005 (+CMT:)
+ *
+ * Callee will subsequently confirm the receipt of thei SMS with a
+ * RIL_REQUEST_SMS_ACKNOWLEDGE
+ *
+ * No new RIL_UNSOL_RESPONSE_NEW_SMS
+ * or RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT messages should be sent until a
+ * RIL_REQUEST_SMS_ACKNOWLEDGE has been received
+ */
+
+#define RIL_UNSOL_RESPONSE_NEW_SMS 1003
+
+/**
+ * RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT
+ *
+ * Called when new SMS Status Report is received.
+ *
+ * "data" is const char *
+ * This is a pointer to a string containing the PDU of an SMS-STATUS-REPORT
+ * as an ascii string of hex digits. The PDU starts with the SMSC address
+ * per TS 27.005 (+CDS:).
+ *
+ * Callee will subsequently confirm the receipt of the SMS with a
+ * RIL_REQUEST_SMS_ACKNOWLEDGE
+ *
+ * No new RIL_UNSOL_RESPONSE_NEW_SMS
+ * or RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT messages should be sent until a
+ * RIL_REQUEST_SMS_ACKNOWLEDGE has been received
+ */
+
+#define RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT 1004
+
+/**
+ * RIL_UNSOL_RESPONSE_NEW_SMS_ON_SIM
+ *
+ * Called when new SMS has been stored on SIM card
+ *
+ * "data" is const int *
+ * ((const int *)data)[0] contains the slot index on the SIM that contains
+ * the new message
+ */
+
+#define RIL_UNSOL_RESPONSE_NEW_SMS_ON_SIM 1005
+
+/**
+ * RIL_UNSOL_ON_USSD
+ *
+ * Called when a new USSD message is received.
+ *
+ * "data" is const char **
+ * ((const char **)data)[0] points to a type code, which is
+ * one of these string values:
+ * "0" USSD-Notify -- text in ((const char **)data)[1]
+ * "1" USSD-Request -- text in ((const char **)data)[1]
+ * "2" Session terminated by network
+ * "3" other local client (eg, SIM Toolkit) has responded
+ * "4" Operation not supported
+ * "5" Network timeout
+ *
+ * The USSD session is assumed to persist if the type code is "1", otherwise
+ * the current session (if any) is assumed to have terminated.
+ *
+ * ((const char **)data)[1] points to a message string if applicable, which
+ * should always be in UTF-8.
+ */
+#define RIL_UNSOL_ON_USSD 1006
+/* Previously #define RIL_UNSOL_ON_USSD_NOTIFY 1006 */
+
+/**
+ * RIL_UNSOL_ON_USSD_REQUEST
+ *
+ * Obsolete. Send via RIL_UNSOL_ON_USSD
+ */
+#define RIL_UNSOL_ON_USSD_REQUEST 1007
+
+/**
+ * RIL_UNSOL_NITZ_TIME_RECEIVED
+ *
+ * Called when radio has received a NITZ time message
+ *
+ * "data" is const char * pointing to NITZ time string
+ * in the form "yy/mm/dd,hh:mm:ss(+/-)tz,dt"
+ */
+#define RIL_UNSOL_NITZ_TIME_RECEIVED 1008
+
+/**
+ * RIL_UNSOL_SIGNAL_STRENGTH
+ *
+ * Radio may report signal strength rather han have it polled.
+ *
+ * "data" is a const RIL_SignalStrength *
+ */
+#define RIL_UNSOL_SIGNAL_STRENGTH 1009
+
+
+/**
+ * RIL_UNSOL_DATA_CALL_LIST_CHANGED
+ *
+ * "data" is an array of RIL_Data_Call_Response_v6 identical to that
+ * returned by RIL_REQUEST_DATA_CALL_LIST. It is the complete list
+ * of current data contexts including new contexts that have been
+ * activated. A data call is only removed from this list when the
+ * framework sends a RIL_REQUEST_DEACTIVATE_DATA_CALL or the radio
+ * is powered off/on.
+ *
+ * See also: RIL_REQUEST_DATA_CALL_LIST
+ */
+
+#define RIL_UNSOL_DATA_CALL_LIST_CHANGED 1010
+
+/**
+ * RIL_UNSOL_SUPP_SVC_NOTIFICATION
+ *
+ * Reports supplementary service related notification from the network.
+ *
+ * "data" is a const RIL_SuppSvcNotification *
+ *
+ */
+
+#define RIL_UNSOL_SUPP_SVC_NOTIFICATION 1011
+
+/**
+ * RIL_UNSOL_STK_SESSION_END
+ *
+ * Indicate when STK session is terminated by SIM.
+ *
+ * "data" is NULL
+ */
+#define RIL_UNSOL_STK_SESSION_END 1012
+
+/**
+ * RIL_UNSOL_STK_PROACTIVE_COMMAND
+ *
+ * Indicate when SIM issue a STK proactive command to applications
+ *
+ * "data" is a const char * containing SAT/USAT proactive command
+ * in hexadecimal format string starting with command tag
+ *
+ */
+#define RIL_UNSOL_STK_PROACTIVE_COMMAND 1013
+
+/**
+ * RIL_UNSOL_STK_EVENT_NOTIFY
+ *
+ * Indicate when SIM notifies applcations some event happens.
+ * Generally, application does not need to have any feedback to
+ * SIM but shall be able to indicate appropriate messages to users.
+ *
+ * "data" is a const char * containing SAT/USAT commands or responses
+ * sent by ME to SIM or commands handled by ME, in hexadecimal format string
+ * starting with first byte of response data or command tag
+ *
+ */
+#define RIL_UNSOL_STK_EVENT_NOTIFY 1014
+
+/**
+ * RIL_UNSOL_STK_CALL_SETUP
+ *
+ * Indicate when SIM wants application to setup a voice call.
+ *
+ * "data" is const int *
+ * ((const int *)data)[0] contains timeout value (in milliseconds)
+ */
+#define RIL_UNSOL_STK_CALL_SETUP 1015
+
+/**
+ * RIL_UNSOL_SIM_SMS_STORAGE_FULL
+ *
+ * Indicates that SMS storage on the SIM is full. Sent when the network
+ * attempts to deliver a new SMS message. Messages cannot be saved on the
+ * SIM until space is freed. In particular, incoming Class 2 messages
+ * cannot be stored.
+ *
+ * "data" is null
+ *
+ */
+#define RIL_UNSOL_SIM_SMS_STORAGE_FULL 1016
+
+/**
+ * RIL_UNSOL_SIM_REFRESH
+ *
+ * Indicates that file(s) on the SIM have been updated, or the SIM
+ * has been reinitialized.
+ *
+ * In the case where RIL is version 6 or older:
+ * "data" is an int *
+ * ((int *)data)[0] is a RIL_SimRefreshResult.
+ * ((int *)data)[1] is the EFID of the updated file if the result is
+ * SIM_FILE_UPDATE or NULL for any other result.
+ *
+ * In the case where RIL is version 7:
+ * "data" is a RIL_SimRefreshResponse_v7 *
+ *
+ * Note: If the SIM state changes as a result of the SIM refresh (eg,
+ * SIM_READY -> SIM_LOCKED_OR_ABSENT), RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED
+ * should be sent.
+ */
+#define RIL_UNSOL_SIM_REFRESH 1017
+
+/**
+ * RIL_UNSOL_CALL_RING
+ *
+ * Ring indication for an incoming call (eg, RING or CRING event).
+ * There must be at least one RIL_UNSOL_CALL_RING at the beginning
+ * of a call and sending multiple is optional. If the system property
+ * ro.telephony.call_ring.multiple is false then the upper layers
+ * will generate the multiple events internally. Otherwise the vendor
+ * ril must generate multiple RIL_UNSOL_CALL_RING if
+ * ro.telephony.call_ring.multiple is true or if it is absent.
+ *
+ * The rate of these events is controlled by ro.telephony.call_ring.delay
+ * and has a default value of 3000 (3 seconds) if absent.
+ *
+ * "data" is null for GSM
+ * "data" is const RIL_CDMA_SignalInfoRecord * if CDMA
+ */
+#define RIL_UNSOL_CALL_RING 1018
+
+/**
+ * RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED
+ *
+ * Indicates that SIM state changes.
+ *
+ * Callee will invoke RIL_REQUEST_GET_SIM_STATUS on main thread
+
+ * "data" is null
+ */
+#define RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED 1019
+
+/**
+ * RIL_UNSOL_RESPONSE_CDMA_NEW_SMS
+ *
+ * Called when new CDMA SMS is received
+ *
+ * "data" is const RIL_CDMA_SMS_Message *
+ *
+ * Callee will subsequently confirm the receipt of the SMS with
+ * a RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE
+ *
+ * No new RIL_UNSOL_RESPONSE_CDMA_NEW_SMS should be sent until
+ * RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE has been received
+ *
+ */
+#define RIL_UNSOL_RESPONSE_CDMA_NEW_SMS 1020
+
+/**
+ * RIL_UNSOL_RESPONSE_NEW_BROADCAST_SMS
+ *
+ * Called when new Broadcast SMS is received
+ *
+ * "data" can be one of the following:
+ * If received from GSM network, "data" is const char of 88 bytes
+ * which indicates each page of a CBS Message sent to the MS by the
+ * BTS as coded in 3GPP 23.041 Section 9.4.1.2.
+ * If received from UMTS network, "data" is const char of 90 up to 1252
+ * bytes which contain between 1 and 15 CBS Message pages sent as one
+ * packet to the MS by the BTS as coded in 3GPP 23.041 Section 9.4.2.2.
+ *
+ */
+#define RIL_UNSOL_RESPONSE_NEW_BROADCAST_SMS 1021
+
+/**
+ * RIL_UNSOL_CDMA_RUIM_SMS_STORAGE_FULL
+ *
+ * Indicates that SMS storage on the RUIM is full. Messages
+ * cannot be saved on the RUIM until space is freed.
+ *
+ * "data" is null
+ *
+ */
+#define RIL_UNSOL_CDMA_RUIM_SMS_STORAGE_FULL 1022
+
+/**
+ * RIL_UNSOL_RESTRICTED_STATE_CHANGED
+ *
+ * Indicates a restricted state change (eg, for Domain Specific Access Control).
+ *
+ * Radio need send this msg after radio off/on cycle no matter it is changed or not.
+ *
+ * "data" is an int *
+ * ((int *)data)[0] contains a bitmask of RIL_RESTRICTED_STATE_* values.
+ */
+#define RIL_UNSOL_RESTRICTED_STATE_CHANGED 1023
+
+/**
+ * RIL_UNSOL_ENTER_EMERGENCY_CALLBACK_MODE
+ *
+ * Indicates that the radio system selection module has
+ * autonomously entered emergency callback mode.
+ *
+ * "data" is null
+ *
+ */
+#define RIL_UNSOL_ENTER_EMERGENCY_CALLBACK_MODE 1024
+
+/**
+ * RIL_UNSOL_CDMA_CALL_WAITING
+ *
+ * Called when CDMA radio receives a call waiting indication.
+ *
+ * "data" is const RIL_CDMA_CallWaiting *
+ *
+ */
+#define RIL_UNSOL_CDMA_CALL_WAITING 1025
+
+/**
+ * RIL_UNSOL_CDMA_OTA_PROVISION_STATUS
+ *
+ * Called when CDMA radio receives an update of the progress of an
+ * OTASP/OTAPA call.
+ *
+ * "data" is const int *
+ * For CDMA this is an integer OTASP/OTAPA status listed in
+ * RIL_CDMA_OTA_ProvisionStatus.
+ *
+ */
+#define RIL_UNSOL_CDMA_OTA_PROVISION_STATUS 1026
+
+/**
+ * RIL_UNSOL_CDMA_INFO_REC
+ *
+ * Called when CDMA radio receives one or more info recs.
+ *
+ * "data" is const RIL_CDMA_InformationRecords *
+ *
+ */
+#define RIL_UNSOL_CDMA_INFO_REC 1027
+
+/**
+ * RIL_UNSOL_OEM_HOOK_RAW
+ *
+ * This is for OEM specific use.
+ *
+ * "data" is a byte[]
+ */
+#define RIL_UNSOL_OEM_HOOK_RAW 1028
+
+/**
+ * RIL_UNSOL_RINGBACK_TONE
+ *
+ * Indicates that nework doesn't have in-band information, need to
+ * play out-band tone.
+ *
+ * "data" is an int *
+ * ((int *)data)[0] == 0 for stop play ringback tone.
+ * ((int *)data)[0] == 1 for start play ringback tone.
+ */
+#define RIL_UNSOL_RINGBACK_TONE 1029
+
+/**
+ * RIL_UNSOL_RESEND_INCALL_MUTE
+ *
+ * Indicates that framework/application need reset the uplink mute state.
+ *
+ * There may be situations where the mute state becomes out of sync
+ * between the application and device in some GSM infrastructures.
+ *
+ * "data" is null
+ */
+#define RIL_UNSOL_RESEND_INCALL_MUTE 1030
+
+/**
+ * RIL_UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED
+ *
+ * Called when CDMA subscription source changed.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is == RIL_CdmaSubscriptionSource
+ */
+#define RIL_UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED 1031
+
+/**
+ * RIL_UNSOL_CDMA_PRL_CHANGED
+ *
+ * Called when PRL (preferred roaming list) changes.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is PRL_VERSION as would be returned by RIL_REQUEST_CDMA_SUBSCRIPTION
+ */
+#define RIL_UNSOL_CDMA_PRL_CHANGED 1032
+
+/**
+ * RIL_UNSOL_EXIT_EMERGENCY_CALLBACK_MODE
+ *
+ * Called when Emergency Callback Mode Ends
+ *
+ * Indicates that the radio system selection module has
+ * proactively exited emergency callback mode.
+ *
+ * "data" is NULL
+ *
+ */
+#define RIL_UNSOL_EXIT_EMERGENCY_CALLBACK_MODE 1033
+
+/**
+ * RIL_UNSOL_RIL_CONNECTED
+ *
+ * Called the ril connects and returns the version
+ *
+ * "data" is int *
+ * ((int *)data)[0] is RIL_VERSION
+ */
+#define RIL_UNSOL_RIL_CONNECTED 1034
+
+/**
+ * RIL_UNSOL_VOICE_RADIO_TECH_CHANGED
+ *
+ * Indicates that voice technology has changed. Contains new radio technology
+ * as a data in the message.
+ *
+ * "data" is int *
+ * ((int *)data)[0] is of type const RIL_RadioTechnology
+ *
+ */
+#define RIL_UNSOL_VOICE_RADIO_TECH_CHANGED 1035
+
+/**
+ * RIL_UNSOL_CELL_INFO_LIST
+ *
+ * Same information as returned by RIL_REQUEST_GET_CELL_INFO_LIST, but returned
+ * at the rate no greater than specified by RIL_REQUEST_SET_UNSOL_CELL_INFO_RATE.
+ *
+ * "data" is NULL
+ *
+ * "response" is an array of RIL_CellInfo_v12.
+ */
+#define RIL_UNSOL_CELL_INFO_LIST 1036
+
+/**
+ * RIL_UNSOL_RESPONSE_IMS_NETWORK_STATE_CHANGED
+ *
+ * This message is DEPRECATED and shall be removed in a future release (target: 2018);
+ * instead, provide IMS registration status via an IMS Service.
+ *
+ * Called when IMS registration state has changed
+ *
+ * To get IMS registration state and IMS SMS format, callee needs to invoke the
+ * following request on main thread:
+ *
+ * RIL_REQUEST_IMS_REGISTRATION_STATE
+ *
+ * "data" is NULL
+ *
+ */
+#define RIL_UNSOL_RESPONSE_IMS_NETWORK_STATE_CHANGED 1037
+
+/**
+ * RIL_UNSOL_UICC_SUBSCRIPTION_STATUS_CHANGED
+ *
+ * Indicated when there is a change in subscription status.
+ * This event will be sent in the following scenarios
+ * - subscription readiness at modem, which was selected by telephony layer
+ * - when subscription is deactivated by modem due to UICC card removal
+ * - When network invalidates the subscription i.e. attach reject due to authentication reject
+ *
+ * "data" is const int *
+ * ((const int *)data)[0] == 0 for Subscription Deactivated
+ * ((const int *)data)[0] == 1 for Subscription Activated
+ *
+ */
+#define RIL_UNSOL_UICC_SUBSCRIPTION_STATUS_CHANGED 1038
+
+/**
+ * RIL_UNSOL_SRVCC_STATE_NOTIFY
+ *
+ * Called when Single Radio Voice Call Continuity(SRVCC)
+ * progress state has changed
+ *
+ * "data" is int *
+ * ((int *)data)[0] is of type const RIL_SrvccState
+ *
+ */
+
+#define RIL_UNSOL_SRVCC_STATE_NOTIFY 1039
+
+/**
+ * RIL_UNSOL_HARDWARE_CONFIG_CHANGED
+ *
+ * Called when the hardware configuration associated with the RILd changes
+ *
+ * "data" is an array of RIL_HardwareConfig
+ *
+ */
+#define RIL_UNSOL_HARDWARE_CONFIG_CHANGED 1040
+
+/**
+ * RIL_UNSOL_DC_RT_INFO_CHANGED
+ *
+ * The message is DEPRECATED, use RIL_REQUEST_GET_ACTIVITY_INFO
+ * Sent when the DC_RT_STATE changes but the time
+ * between these messages must not be less than the
+ * value set by RIL_REQUEST_SET_DC_RT_RATE.
+ *
+ * "data" is the most recent RIL_DcRtInfo
+ *
+ */
+#define RIL_UNSOL_DC_RT_INFO_CHANGED 1041
+
+/**
+ * RIL_UNSOL_RADIO_CAPABILITY
+ *
+ * Sent when RIL_REQUEST_SET_RADIO_CAPABILITY completes.
+ * Returns the phone radio capability exactly as
+ * RIL_REQUEST_GET_RADIO_CAPABILITY and should be the
+ * same set as sent by RIL_REQUEST_SET_RADIO_CAPABILITY.
+ *
+ * "data" is the RIL_RadioCapability structure
+ */
+#define RIL_UNSOL_RADIO_CAPABILITY 1042
+
+/*
+ * RIL_UNSOL_ON_SS
+ *
+ * Called when SS response is received when DIAL/USSD/SS is changed to SS by
+ * call control.
+ *
+ * "data" is const RIL_StkCcUnsolSsResponse *
+ *
+ */
+#define RIL_UNSOL_ON_SS 1043
+
+/**
+ * RIL_UNSOL_STK_CC_ALPHA_NOTIFY
+ *
+ * Called when there is an ALPHA from UICC during Call Control.
+ *
+ * "data" is const char * containing ALPHA string from UICC in UTF-8 format.
+ *
+ */
+#define RIL_UNSOL_STK_CC_ALPHA_NOTIFY 1044
+
+/**
+ * RIL_UNSOL_LCEDATA_RECV
+ *
+ * Called when there is an incoming Link Capacity Estimate (LCE) info report.
+ *
+ * "data" is the RIL_LceDataInfo structure.
+ *
+ */
+#define RIL_UNSOL_LCEDATA_RECV 1045
+
+ /**
+ * RIL_UNSOL_PCO_DATA
+ *
+ * Called when there is new Carrier PCO data received for a data call. Ideally
+ * only new data will be forwarded, though this is not required. Multiple
+ * boxes of carrier PCO data for a given call should result in a series of
+ * RIL_UNSOL_PCO_DATA calls.
+ *
+ * "data" is the RIL_PCO_Data structure.
+ *
+ */
+#define RIL_UNSOL_PCO_DATA 1046
+
+ /**
+ * RIL_UNSOL_MODEM_RESTART
+ *
+ * Called when there is a modem reset.
+ *
+ * "reason" is "const char *" containing the reason for the reset. It
+ * could be a crash signature if the restart was due to a crash or some
+ * string such as "user-initiated restart" or "AT command initiated
+ * restart" that explains the cause of the modem restart.
+ *
+ * When modem restarts, one of the following radio state transitions will happen
+ * 1) RADIO_STATE_ON->RADIO_STATE_UNAVAILABLE->RADIO_STATE_ON or
+ * 2) RADIO_STATE_OFF->RADIO_STATE_UNAVAILABLE->RADIO_STATE_OFF
+ * This message can be sent either just before the RADIO_STATE changes to RADIO_STATE_UNAVAILABLE
+ * or just after but should never be sent after the RADIO_STATE changes from UNAVAILABLE to
+ * AVAILABLE(RADIO_STATE_ON/RADIO_STATE_OFF) again.
+ *
+ * It should NOT be sent after the RADIO_STATE changes to AVAILABLE after the
+ * modem restart as that could be interpreted as a second modem reset by the
+ * framework.
+ */
+#define RIL_UNSOL_MODEM_RESTART 1047
+
+/**
+ * RIL_UNSOL_CARRIER_INFO_IMSI_ENCRYPTION
+ *
+ * Called when the modem needs Carrier specific information that will
+ * be used to encrypt IMSI and IMPI.
+ *
+ * "data" is NULL
+ *
+ */
+#define RIL_UNSOL_CARRIER_INFO_IMSI_ENCRYPTION 1048
+
+/**
+ * RIL_UNSOL_NETWORK_SCAN_RESULT
+ *
+ * Returns incremental result for the network scan which is started by
+ * RIL_REQUEST_START_NETWORK_SCAN, sent to report results, status, or errors.
+ *
+ * "data" is NULL
+ * "response" is a const RIL_NetworkScanResult *
+ */
+#define RIL_UNSOL_NETWORK_SCAN_RESULT 1049
+
+/**
+ * RIL_UNSOL_KEEPALIVE_STATUS
+ *
+ * "data" is NULL
+ * "response" is a const RIL_KeepaliveStatus *
+ */
+#define RIL_UNSOL_KEEPALIVE_STATUS 1050
+
+/***********************************************************************/
+
+
+#if defined(ANDROID_MULTI_SIM)
+/**
+ * RIL_Request Function pointer
+ *
+ * @param request is one of RIL_REQUEST_*
+ * @param data is pointer to data defined for that RIL_REQUEST_*
+ * data is owned by caller, and should not be modified or freed by callee
+ * structures passed as data may contain pointers to non-contiguous memory
+ * @param t should be used in subsequent call to RIL_onResponse
+ * @param datalen is the length of "data" which is defined as other argument. It may or may
+ * not be equal to sizeof(data). Refer to the documentation of individual structures
+ * to find if pointers listed in the structure are contiguous and counted in the datalen
+ * length or not.
+ * (Eg: RIL_IMS_SMS_Message where we don't have datalen equal to sizeof(data))
+ *
+ */
+typedef void (*RIL_RequestFunc) (int request, void *data,
+ size_t datalen, RIL_Token t, RIL_SOCKET_ID socket_id);
+
+/**
+ * This function should return the current radio state synchronously
+ */
+typedef RIL_RadioState (*RIL_RadioStateRequest)(RIL_SOCKET_ID socket_id);
+
+#else
+/* Backward compatible */
+
+/**
+ * RIL_Request Function pointer
+ *
+ * @param request is one of RIL_REQUEST_*
+ * @param data is pointer to data defined for that RIL_REQUEST_*
+ * data is owned by caller, and should not be modified or freed by callee
+ * structures passed as data may contain pointers to non-contiguous memory
+ * @param t should be used in subsequent call to RIL_onResponse
+ * @param datalen is the length of "data" which is defined as other argument. It may or may
+ * not be equal to sizeof(data). Refer to the documentation of individual structures
+ * to find if pointers listed in the structure are contiguous and counted in the datalen
+ * length or not.
+ * (Eg: RIL_IMS_SMS_Message where we don't have datalen equal to sizeof(data))
+ *
+ */
+typedef void (*RIL_RequestFunc) (int request, void *data,
+ size_t datalen, RIL_Token t);
+
+/**
+ * This function should return the current radio state synchronously
+ */
+typedef RIL_RadioState (*RIL_RadioStateRequest)();
+
+#endif
+
+
+/**
+ * This function returns "1" if the specified RIL_REQUEST code is
+ * supported and 0 if it is not
+ *
+ * @param requestCode is one of RIL_REQUEST codes
+ */
+
+typedef int (*RIL_Supports)(int requestCode);
+
+/**
+ * This function is called from a separate thread--not the
+ * thread that calls RIL_RequestFunc--and indicates that a pending
+ * request should be cancelled.
+ *
+ * On cancel, the callee should do its best to abandon the request and
+ * call RIL_onRequestComplete with RIL_Errno CANCELLED at some later point.
+ *
+ * Subsequent calls to RIL_onRequestComplete for this request with
+ * other results will be tolerated but ignored. (That is, it is valid
+ * to ignore the cancellation request)
+ *
+ * RIL_Cancel calls should return immediately, and not wait for cancellation
+ *
+ * Please see ITU v.250 5.6.1 for how one might implement this on a TS 27.007
+ * interface
+ *
+ * @param t token wants to be canceled
+ */
+
+typedef void (*RIL_Cancel)(RIL_Token t);
+
+typedef void (*RIL_TimedCallback) (void *param);
+
+/**
+ * Return a version string for your RIL implementation
+ */
+typedef const char * (*RIL_GetVersion) (void);
+
+typedef struct {
+ int version; /* set to RIL_VERSION */
+ RIL_RequestFunc onRequest;
+ RIL_RadioStateRequest onStateRequest;
+ RIL_Supports supports;
+ RIL_Cancel onCancel;
+ RIL_GetVersion getVersion;
+} RIL_RadioFunctions;
+
+typedef struct {
+ char *apn; /* the APN to connect to */
+ char *protocol; /* one of the PDP_type values in TS 27.007 section 10.1.1 used on
+ roaming network. For example, "IP", "IPV6", "IPV4V6", or "PPP".*/
+ int authtype; /* authentication protocol used for this PDP context
+ (None: 0, PAP: 1, CHAP: 2, PAP&CHAP: 3) */
+ char *username; /* the username for APN, or NULL */
+ char *password; /* the password for APN, or NULL */
+} RIL_InitialAttachApn;
+
+typedef struct {
+ char *apn; /* the APN to connect to */
+ char *protocol; /* one of the PDP_type values in TS 27.007 section 10.1.1 used on
+ home network. For example, "IP", "IPV6", "IPV4V6", or "PPP". */
+ char *roamingProtocol; /* one of the PDP_type values in TS 27.007 section 10.1.1 used on
+ roaming network. For example, "IP", "IPV6", "IPV4V6", or "PPP".*/
+ int authtype; /* authentication protocol used for this PDP context
+ (None: 0, PAP: 1, CHAP: 2, PAP&CHAP: 3) */
+ char *username; /* the username for APN, or NULL */
+ char *password; /* the password for APN, or NULL */
+ int supportedTypesBitmask; /* supported APN types bitmask. See RIL_ApnTypes for the value of
+ each bit. */
+ int bearerBitmask; /* the bearer bitmask. See RIL_RadioAccessFamily for the value of
+ each bit. */
+ int modemCognitive; /* indicating the APN setting was sent to the modem through
+ setDataProfile earlier. */
+ int mtu; /* maximum transmission unit (MTU) size in bytes */
+ char *mvnoType; /* the MVNO type: possible values are "imsi", "gid", "spn" */
+ char *mvnoMatchData; /* MVNO match data. Can be anything defined by the carrier.
+ For example,
+ SPN like: "A MOBILE", "BEN NL", etc...
+ IMSI like: "302720x94", "2060188", etc...
+ GID like: "4E", "33", etc... */
+} RIL_InitialAttachApn_v15;
+
+typedef struct {
+ int authContext; /* P2 value of authentication command, see P2 parameter in
+ 3GPP TS 31.102 7.1.2 */
+ char *authData; /* the challenge string in Base64 format, see 3GPP
+ TS 31.102 7.1.2 */
+ char *aid; /* AID value, See ETSI 102.221 8.1 and 101.220 4,
+ NULL if no value. */
+} RIL_SimAuthentication;
+
+typedef struct {
+ int cid; /* Context ID, uniquely identifies this call */
+ char *bearer_proto; /* One of the PDP_type values in TS 27.007 section 10.1.1.
+ For example, "IP", "IPV6", "IPV4V6". */
+ int pco_id; /* The protocol ID for this box. Note that only IDs from
+ FF00H - FFFFH are accepted. If more than one is included
+ from the network, multiple calls should be made to send all
+ of them. */
+ int contents_length; /* The number of octets in the contents. */
+ char *contents; /* Carrier-defined content. It is binary, opaque and
+ loosely defined in LTE Layer 3 spec 24.008 */
+} RIL_PCO_Data;
+
+typedef enum {
+ NATT_IPV4 = 0, /* Keepalive specified by RFC 3948 Sec. 2.3 using IPv4 */
+ NATT_IPV6 = 1 /* Keepalive specified by RFC 3948 Sec. 2.3 using IPv6 */
+} RIL_KeepaliveType;
+
+#define MAX_INADDR_LEN 16
+typedef struct {
+ RIL_KeepaliveType type; /* Type of keepalive packet */
+ char sourceAddress[MAX_INADDR_LEN]; /* Source address in network-byte order */
+ int sourcePort; /* Source port if applicable, or 0x7FFFFFFF;
+ the maximum value is 65535 */
+ char destinationAddress[MAX_INADDR_LEN]; /* Destination address in network-byte order */
+ int destinationPort; /* Destination port if applicable or 0x7FFFFFFF;
+ the maximum value is 65535 */
+ int maxKeepaliveIntervalMillis; /* Maximum milliseconds between two packets */
+ int cid; /* Context ID, uniquely identifies this call */
+} RIL_KeepaliveRequest;
+
+typedef enum {
+ KEEPALIVE_ACTIVE, /* Keepalive session is active */
+ KEEPALIVE_INACTIVE, /* Keepalive session is inactive */
+ KEEPALIVE_PENDING /* Keepalive session status not available */
+} RIL_KeepaliveStatusCode;
+
+typedef struct {
+ uint32_t sessionHandle;
+ RIL_KeepaliveStatusCode code;
+} RIL_KeepaliveStatus;
+
+#ifdef RIL_SHLIB
+struct RIL_Env {
+ /**
+ * "t" is parameter passed in on previous call to RIL_Notification
+ * routine.
+ *
+ * If "e" != SUCCESS, then response can be null/is ignored
+ *
+ * "response" is owned by caller, and should not be modified or
+ * freed by callee
+ *
+ * RIL_onRequestComplete will return as soon as possible
+ */
+ void (*OnRequestComplete)(RIL_Token t, RIL_Errno e,
+ void *response, size_t responselen);
+
+#if defined(ANDROID_MULTI_SIM)
+ /**
+ * "unsolResponse" is one of RIL_UNSOL_RESPONSE_*
+ * "data" is pointer to data defined for that RIL_UNSOL_RESPONSE_*
+ *
+ * "data" is owned by caller, and should not be modified or freed by callee
+ */
+ void (*OnUnsolicitedResponse)(int unsolResponse, const void *data, size_t datalen, RIL_SOCKET_ID socket_id);
+#else
+ /**
+ * "unsolResponse" is one of RIL_UNSOL_RESPONSE_*
+ * "data" is pointer to data defined for that RIL_UNSOL_RESPONSE_*
+ *
+ * "data" is owned by caller, and should not be modified or freed by callee
+ */
+ void (*OnUnsolicitedResponse)(int unsolResponse, const void *data, size_t datalen);
+#endif
+ /**
+ * Call user-specifed "callback" function on on the same thread that
+ * RIL_RequestFunc is called. If "relativeTime" is specified, then it specifies
+ * a relative time value at which the callback is invoked. If relativeTime is
+ * NULL or points to a 0-filled structure, the callback will be invoked as
+ * soon as possible
+ */
+
+ void (*RequestTimedCallback) (RIL_TimedCallback callback,
+ void *param, const struct timeval *relativeTime);
+ /**
+ * "t" is parameter passed in on previous call RIL_Notification routine
+ *
+ * RIL_onRequestAck will be called by vendor when an Async RIL request was received
+ * by them and an ack needs to be sent back to java ril.
+ */
+ void (*OnRequestAck) (RIL_Token t);
+};
+
+
+/**
+ * RIL implementations must defined RIL_Init
+ * argc and argv will be command line arguments intended for the RIL implementation
+ * Return NULL on error
+ *
+ * @param env is environment point defined as RIL_Env
+ * @param argc number of arguments
+ * @param argv list fo arguments
+ *
+ */
+const RIL_RadioFunctions *RIL_Init(const struct RIL_Env *env, int argc, char **argv);
+
+/**
+ * If BT SAP(SIM Access Profile) is supported, then RIL implementations must define RIL_SAP_Init
+ * for initializing RIL_RadioFunctions used for BT SAP communcations. It is called whenever RILD
+ * starts or modem restarts. Returns handlers for SAP related request that are made on SAP
+ * sepecific socket, analogous to the RIL_RadioFunctions returned by the call to RIL_Init
+ * and used on the general RIL socket.
+ * argc and argv will be command line arguments intended for the RIL implementation
+ * Return NULL on error.
+ *
+ * @param env is environment point defined as RIL_Env
+ * @param argc number of arguments
+ * @param argv list fo arguments
+ *
+ */
+const RIL_RadioFunctions *RIL_SAP_Init(const struct RIL_Env *env, int argc, char **argv);
+
+#else /* RIL_SHLIB */
+
+/**
+ * Call this once at startup to register notification routine
+ *
+ * @param callbacks user-specifed callback function
+ */
+void RIL_register (const RIL_RadioFunctions *callbacks);
+
+void rilc_thread_pool();
+
+
+/**
+ *
+ * RIL_onRequestComplete will return as soon as possible
+ *
+ * @param t is parameter passed in on previous call to RIL_Notification
+ * routine.
+ * @param e error code
+ * if "e" != SUCCESS, then response can be null/is ignored
+ * @param response is owned by caller, and should not be modified or
+ * freed by callee
+ * @param responselen the length of response in byte
+ */
+void RIL_onRequestComplete(RIL_Token t, RIL_Errno e,
+ void *response, size_t responselen);
+
+/**
+ * RIL_onRequestAck will be called by vendor when an Async RIL request was received by them and
+ * an ack needs to be sent back to java ril. This doesn't mark the end of the command or it's
+ * results, just that the command was received and will take a while. After sending this Ack
+ * its vendor's responsibility to make sure that AP is up whenever needed while command is
+ * being processed.
+ *
+ * @param t is parameter passed in on previous call to RIL_Notification
+ * routine.
+ */
+void RIL_onRequestAck(RIL_Token t);
+
+#if defined(ANDROID_MULTI_SIM)
+/**
+ * @param unsolResponse is one of RIL_UNSOL_RESPONSE_*
+ * @param data is pointer to data defined for that RIL_UNSOL_RESPONSE_*
+ * "data" is owned by caller, and should not be modified or freed by callee
+ * @param datalen the length of data in byte
+ */
+
+void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen, RIL_SOCKET_ID socket_id);
+#else
+/**
+ * @param unsolResponse is one of RIL_UNSOL_RESPONSE_*
+ * @param data is pointer to data defined for that RIL_UNSOL_RESPONSE_*
+ * "data" is owned by caller, and should not be modified or freed by callee
+ * @param datalen the length of data in byte
+ */
+
+void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen);
+#endif
+
+/**
+ * Call user-specifed "callback" function on on the same thread that
+ * RIL_RequestFunc is called. If "relativeTime" is specified, then it specifies
+ * a relative time value at which the callback is invoked. If relativeTime is
+ * NULL or points to a 0-filled structure, the callback will be invoked as
+ * soon as possible
+ *
+ * @param callback user-specifed callback function
+ * @param param parameter list
+ * @param relativeTime a relative time value at which the callback is invoked
+ */
+
+void RIL_requestTimedCallback (RIL_TimedCallback callback,
+ void *param, const struct timeval *relativeTime);
+
+#endif /* RIL_SHLIB */
+
+#ifdef __cplusplus
+}
+#endif
+
+#endif /*ANDROID_RIL_H*/
diff --git a/guest/hals/ril/libril/ril_commands.h b/guest/hals/ril/libril/ril_commands.h
new file mode 100644
index 0000000..9aa7b56
--- /dev/null
+++ b/guest/hals/ril/libril/ril_commands.h
@@ -0,0 +1,162 @@
+/* //guest/hals/ril/libril/ril_commands.h
+**
+** Copyright 2006, The Android Open Source Project
+**
+** Licensed under the Apache License, Version 2.0 (the "License");
+** you may not use this file except in compliance with the License.
+** You may obtain a copy of the License at
+**
+** http://www.apache.org/licenses/LICENSE-2.0
+**
+** Unless required by applicable law or agreed to in writing, software
+** distributed under the License is distributed on an "AS IS" BASIS,
+** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+** See the License for the specific language governing permissions and
+** limitations under the License.
+*/
+ {0, NULL}, //none
+ {RIL_REQUEST_GET_SIM_STATUS, radio_1_4::getIccCardStatusResponse},
+ {RIL_REQUEST_ENTER_SIM_PIN, radio_1_4::supplyIccPinForAppResponse},
+ {RIL_REQUEST_ENTER_SIM_PUK, radio_1_4::supplyIccPukForAppResponse},
+ {RIL_REQUEST_ENTER_SIM_PIN2, radio_1_4::supplyIccPin2ForAppResponse},
+ {RIL_REQUEST_ENTER_SIM_PUK2, radio_1_4::supplyIccPuk2ForAppResponse},
+ {RIL_REQUEST_CHANGE_SIM_PIN, radio_1_4::changeIccPinForAppResponse},
+ {RIL_REQUEST_CHANGE_SIM_PIN2, radio_1_4::changeIccPin2ForAppResponse},
+ {RIL_REQUEST_ENTER_NETWORK_DEPERSONALIZATION, radio_1_4::supplyNetworkDepersonalizationResponse},
+ {RIL_REQUEST_GET_CURRENT_CALLS, radio_1_4::getCurrentCallsResponse},
+ {RIL_REQUEST_DIAL, radio_1_4::dialResponse},
+ {RIL_REQUEST_GET_IMSI, radio_1_4::getIMSIForAppResponse},
+ {RIL_REQUEST_HANGUP, radio_1_4::hangupConnectionResponse},
+ {RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND, radio_1_4::hangupWaitingOrBackgroundResponse},
+ {RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND, radio_1_4::hangupForegroundResumeBackgroundResponse},
+ {RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE, radio_1_4::switchWaitingOrHoldingAndActiveResponse},
+ {RIL_REQUEST_CONFERENCE, radio_1_4::conferenceResponse},
+ {RIL_REQUEST_UDUB, radio_1_4::rejectCallResponse},
+ {RIL_REQUEST_LAST_CALL_FAIL_CAUSE, radio_1_4::getLastCallFailCauseResponse},
+ {RIL_REQUEST_SIGNAL_STRENGTH, radio_1_4::getSignalStrengthResponse},
+ {RIL_REQUEST_VOICE_REGISTRATION_STATE, radio_1_4::getVoiceRegistrationStateResponse},
+ {RIL_REQUEST_DATA_REGISTRATION_STATE, radio_1_4::getDataRegistrationStateResponse},
+ {RIL_REQUEST_OPERATOR, radio_1_4::getOperatorResponse},
+ {RIL_REQUEST_RADIO_POWER, radio_1_4::setRadioPowerResponse},
+ {RIL_REQUEST_DTMF, radio_1_4::sendDtmfResponse},
+ {RIL_REQUEST_SEND_SMS, radio_1_4::sendSmsResponse},
+ {RIL_REQUEST_SEND_SMS_EXPECT_MORE, radio_1_4::sendSMSExpectMoreResponse},
+ {RIL_REQUEST_SETUP_DATA_CALL, radio_1_4::setupDataCallResponse},
+ {RIL_REQUEST_SIM_IO, radio_1_4::iccIOForAppResponse},
+ {RIL_REQUEST_SEND_USSD, radio_1_4::sendUssdResponse},
+ {RIL_REQUEST_CANCEL_USSD, radio_1_4::cancelPendingUssdResponse},
+ {RIL_REQUEST_GET_CLIR, radio_1_4::getClirResponse},
+ {RIL_REQUEST_SET_CLIR, radio_1_4::setClirResponse},
+ {RIL_REQUEST_QUERY_CALL_FORWARD_STATUS, radio_1_4::getCallForwardStatusResponse},
+ {RIL_REQUEST_SET_CALL_FORWARD, radio_1_4::setCallForwardResponse},
+ {RIL_REQUEST_QUERY_CALL_WAITING, radio_1_4::getCallWaitingResponse},
+ {RIL_REQUEST_SET_CALL_WAITING, radio_1_4::setCallWaitingResponse},
+ {RIL_REQUEST_SMS_ACKNOWLEDGE, radio_1_4::acknowledgeLastIncomingGsmSmsResponse},
+ {RIL_REQUEST_GET_IMEI, NULL},
+ {RIL_REQUEST_GET_IMEISV, NULL},
+ {RIL_REQUEST_ANSWER, radio_1_4::acceptCallResponse},
+ {RIL_REQUEST_DEACTIVATE_DATA_CALL, radio_1_4::deactivateDataCallResponse},
+ {RIL_REQUEST_QUERY_FACILITY_LOCK, radio_1_4::getFacilityLockForAppResponse},
+ {RIL_REQUEST_SET_FACILITY_LOCK, radio_1_4::setFacilityLockForAppResponse},
+ {RIL_REQUEST_CHANGE_BARRING_PASSWORD, radio_1_4::setBarringPasswordResponse},
+ {RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE, radio_1_4::getNetworkSelectionModeResponse},
+ {RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC, radio_1_4::setNetworkSelectionModeAutomaticResponse},
+ {RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL, radio_1_4::setNetworkSelectionModeManualResponse},
+ {RIL_REQUEST_QUERY_AVAILABLE_NETWORKS , radio_1_4::getAvailableNetworksResponse},
+ {RIL_REQUEST_DTMF_START, radio_1_4::startDtmfResponse},
+ {RIL_REQUEST_DTMF_STOP, radio_1_4::stopDtmfResponse},
+ {RIL_REQUEST_BASEBAND_VERSION, radio_1_4::getBasebandVersionResponse},
+ {RIL_REQUEST_SEPARATE_CONNECTION, radio_1_4::separateConnectionResponse},
+ {RIL_REQUEST_SET_MUTE, radio_1_4::setMuteResponse},
+ {RIL_REQUEST_GET_MUTE, radio_1_4::getMuteResponse},
+ {RIL_REQUEST_QUERY_CLIP, radio_1_4::getClipResponse},
+ {RIL_REQUEST_LAST_DATA_CALL_FAIL_CAUSE, NULL},
+ {RIL_REQUEST_DATA_CALL_LIST, radio_1_4::getDataCallListResponse},
+ {RIL_REQUEST_RESET_RADIO, NULL},
+ {RIL_REQUEST_OEM_HOOK_RAW, radio_1_4::sendRequestRawResponse},
+ {RIL_REQUEST_OEM_HOOK_STRINGS, radio_1_4::sendRequestStringsResponse},
+ {RIL_REQUEST_SCREEN_STATE, radio_1_4::sendDeviceStateResponse}, // Note the response function is different.
+ {RIL_REQUEST_SET_SUPP_SVC_NOTIFICATION, radio_1_4::setSuppServiceNotificationsResponse},
+ {RIL_REQUEST_WRITE_SMS_TO_SIM, radio_1_4::writeSmsToSimResponse},
+ {RIL_REQUEST_DELETE_SMS_ON_SIM, radio_1_4::deleteSmsOnSimResponse},
+ {RIL_REQUEST_SET_BAND_MODE, radio_1_4::setBandModeResponse},
+ {RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE, radio_1_4::getAvailableBandModesResponse},
+ {RIL_REQUEST_STK_GET_PROFILE, NULL},
+ {RIL_REQUEST_STK_SET_PROFILE, NULL},
+ {RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND, radio_1_4::sendEnvelopeResponse},
+ {RIL_REQUEST_STK_SEND_TERMINAL_RESPONSE, radio_1_4::sendTerminalResponseToSimResponse},
+ {RIL_REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM, radio_1_4::handleStkCallSetupRequestFromSimResponse},
+ {RIL_REQUEST_EXPLICIT_CALL_TRANSFER, radio_1_4::explicitCallTransferResponse},
+ {RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE, radio_1_4::setPreferredNetworkTypeResponse},
+ {RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE, radio_1_4::getPreferredNetworkTypeResponse},
+ {RIL_REQUEST_GET_NEIGHBORING_CELL_IDS, radio_1_4::getNeighboringCidsResponse},
+ {RIL_REQUEST_SET_LOCATION_UPDATES, radio_1_4::setLocationUpdatesResponse},
+ {RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE, radio_1_4::setCdmaSubscriptionSourceResponse},
+ {RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE, radio_1_4::setCdmaRoamingPreferenceResponse},
+ {RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE, radio_1_4::getCdmaRoamingPreferenceResponse},
+ {RIL_REQUEST_SET_TTY_MODE, radio_1_4::setTTYModeResponse},
+ {RIL_REQUEST_QUERY_TTY_MODE, radio_1_4::getTTYModeResponse},
+ {RIL_REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE, radio_1_4::setPreferredVoicePrivacyResponse},
+ {RIL_REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE, radio_1_4::getPreferredVoicePrivacyResponse},
+ {RIL_REQUEST_CDMA_FLASH, radio_1_4::sendCDMAFeatureCodeResponse},
+ {RIL_REQUEST_CDMA_BURST_DTMF, radio_1_4::sendBurstDtmfResponse},
+ {RIL_REQUEST_CDMA_VALIDATE_AND_WRITE_AKEY, NULL},
+ {RIL_REQUEST_CDMA_SEND_SMS, radio_1_4::sendCdmaSmsResponse},
+ {RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE, radio_1_4::acknowledgeLastIncomingCdmaSmsResponse},
+ {RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG, radio_1_4::getGsmBroadcastConfigResponse},
+ {RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG, radio_1_4::setGsmBroadcastConfigResponse},
+ {RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION, radio_1_4::setGsmBroadcastActivationResponse},
+ {RIL_REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG, radio_1_4::getCdmaBroadcastConfigResponse},
+ {RIL_REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG, radio_1_4::setCdmaBroadcastConfigResponse},
+ {RIL_REQUEST_CDMA_SMS_BROADCAST_ACTIVATION, radio_1_4::setCdmaBroadcastActivationResponse},
+ {RIL_REQUEST_CDMA_SUBSCRIPTION, radio_1_4::getCDMASubscriptionResponse},
+ {RIL_REQUEST_CDMA_WRITE_SMS_TO_RUIM, radio_1_4::writeSmsToRuimResponse},
+ {RIL_REQUEST_CDMA_DELETE_SMS_ON_RUIM, radio_1_4::deleteSmsOnRuimResponse},
+ {RIL_REQUEST_DEVICE_IDENTITY, radio_1_4::getDeviceIdentityResponse},
+ {RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE, radio_1_4::exitEmergencyCallbackModeResponse},
+ {RIL_REQUEST_GET_SMSC_ADDRESS, radio_1_4::getSmscAddressResponse},
+ {RIL_REQUEST_SET_SMSC_ADDRESS, radio_1_4::setSmscAddressResponse},
+ {RIL_REQUEST_REPORT_SMS_MEMORY_STATUS, radio_1_4::reportSmsMemoryStatusResponse},
+ {RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING, radio_1_4::reportStkServiceIsRunningResponse},
+ {RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE, radio_1_4::getCdmaSubscriptionSourceResponse},
+ {RIL_REQUEST_ISIM_AUTHENTICATION, radio_1_4::requestIsimAuthenticationResponse},
+ {RIL_REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU, radio_1_4::acknowledgeIncomingGsmSmsWithPduResponse},
+ {RIL_REQUEST_STK_SEND_ENVELOPE_WITH_STATUS, radio_1_4::sendEnvelopeWithStatusResponse},
+ {RIL_REQUEST_VOICE_RADIO_TECH, radio_1_4::getVoiceRadioTechnologyResponse},
+ {RIL_REQUEST_GET_CELL_INFO_LIST, radio_1_4::getCellInfoListResponse},
+ {RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE, radio_1_4::setCellInfoListRateResponse},
+ {RIL_REQUEST_SET_INITIAL_ATTACH_APN, radio_1_4::setInitialAttachApnResponse},
+ {RIL_REQUEST_IMS_REGISTRATION_STATE, radio_1_4::getImsRegistrationStateResponse},
+ {RIL_REQUEST_IMS_SEND_SMS, radio_1_4::sendImsSmsResponse},
+ {RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC, radio_1_4::iccTransmitApduBasicChannelResponse},
+ {RIL_REQUEST_SIM_OPEN_CHANNEL, radio_1_4::iccOpenLogicalChannelResponse},
+ {RIL_REQUEST_SIM_CLOSE_CHANNEL, radio_1_4::iccCloseLogicalChannelResponse},
+ {RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL, radio_1_4::iccTransmitApduLogicalChannelResponse},
+ {RIL_REQUEST_NV_READ_ITEM, radio_1_4::nvReadItemResponse},
+ {RIL_REQUEST_NV_WRITE_ITEM, radio_1_4::nvWriteItemResponse},
+ {RIL_REQUEST_NV_WRITE_CDMA_PRL, radio_1_4::nvWriteCdmaPrlResponse},
+ {RIL_REQUEST_NV_RESET_CONFIG, radio_1_4::nvResetConfigResponse},
+ {RIL_REQUEST_SET_UICC_SUBSCRIPTION, radio_1_4::setUiccSubscriptionResponse},
+ {RIL_REQUEST_ALLOW_DATA, radio_1_4::setDataAllowedResponse},
+ {RIL_REQUEST_GET_HARDWARE_CONFIG, radio_1_4::getHardwareConfigResponse},
+ {RIL_REQUEST_SIM_AUTHENTICATION, radio_1_4::requestIccSimAuthenticationResponse},
+ {RIL_REQUEST_GET_DC_RT_INFO, NULL},
+ {RIL_REQUEST_SET_DC_RT_INFO_RATE, NULL},
+ {RIL_REQUEST_SET_DATA_PROFILE, radio_1_4::setDataProfileResponse},
+ {RIL_REQUEST_SHUTDOWN, radio_1_4::requestShutdownResponse},
+ {RIL_REQUEST_GET_RADIO_CAPABILITY, radio_1_4::getRadioCapabilityResponse},
+ {RIL_REQUEST_SET_RADIO_CAPABILITY, radio_1_4::setRadioCapabilityResponse},
+ {RIL_REQUEST_START_LCE, radio_1_4::startLceServiceResponse},
+ {RIL_REQUEST_STOP_LCE, radio_1_4::stopLceServiceResponse},
+ {RIL_REQUEST_PULL_LCEDATA, radio_1_4::pullLceDataResponse},
+ {RIL_REQUEST_GET_ACTIVITY_INFO, radio_1_4::getModemActivityInfoResponse},
+ {RIL_REQUEST_SET_CARRIER_RESTRICTIONS, radio_1_4::setAllowedCarriersResponse},
+ {RIL_REQUEST_GET_CARRIER_RESTRICTIONS, radio_1_4::getAllowedCarriersResponse},
+ {RIL_REQUEST_SEND_DEVICE_STATE, radio_1_4::sendDeviceStateResponse},
+ {RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER, radio_1_4::setIndicationFilterResponse},
+ {RIL_REQUEST_SET_SIM_CARD_POWER, radio_1_4::setSimCardPowerResponse},
+ {RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION, radio_1_4::setCarrierInfoForImsiEncryptionResponse},
+ {RIL_REQUEST_START_NETWORK_SCAN, radio_1_4::startNetworkScanResponse},
+ {RIL_REQUEST_STOP_NETWORK_SCAN, radio_1_4::stopNetworkScanResponse},
+ {RIL_REQUEST_START_KEEPALIVE, radio_1_4::startKeepaliveResponse},
+ {RIL_REQUEST_STOP_KEEPALIVE, radio_1_4::stopKeepaliveResponse},
diff --git a/guest/hals/ril/libril/ril_event.cpp b/guest/hals/ril/libril/ril_event.cpp
new file mode 100644
index 0000000..84b8b72
--- /dev/null
+++ b/guest/hals/ril/libril/ril_event.cpp
@@ -0,0 +1,384 @@
+/* //device/libs/telephony/ril_event.cpp
+**
+** Copyright 2008, The Android Open Source Project
+**
+** Licensed under the Apache License, Version 2.0 (the "License");
+** you may not use this file except in compliance with the License.
+** You may obtain a copy of the License at
+**
+** http://www.apache.org/licenses/LICENSE-2.0
+**
+** Unless required by applicable law or agreed to in writing, software
+** distributed under the License is distributed on an "AS IS" BASIS,
+** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+** See the License for the specific language governing permissions and
+** limitations under the License.
+*/
+
+#define LOG_TAG "RILC"
+
+#include <stdlib.h>
+#include <unistd.h>
+#include <errno.h>
+#include <fcntl.h>
+#include <utils/Log.h>
+#include <ril_event.h>
+#include <string.h>
+#include <sys/time.h>
+#include <time.h>
+
+#include <pthread.h>
+static pthread_mutex_t listMutex;
+#define MUTEX_ACQUIRE() pthread_mutex_lock(&listMutex)
+#define MUTEX_RELEASE() pthread_mutex_unlock(&listMutex)
+#define MUTEX_INIT() pthread_mutex_init(&listMutex, NULL)
+#define MUTEX_DESTROY() pthread_mutex_destroy(&listMutex)
+
+#ifndef timeradd
+#define timeradd(tvp, uvp, vvp) \
+ do { \
+ (vvp)->tv_sec = (tvp)->tv_sec + (uvp)->tv_sec; \
+ (vvp)->tv_usec = (tvp)->tv_usec + (uvp)->tv_usec; \
+ if ((vvp)->tv_usec >= 1000000) { \
+ (vvp)->tv_sec++; \
+ (vvp)->tv_usec -= 1000000; \
+ } \
+ } while (0)
+#endif
+
+#ifndef timercmp
+#define timercmp(a, b, op) \
+ ((a)->tv_sec == (b)->tv_sec \
+ ? (a)->tv_usec op (b)->tv_usec \
+ : (a)->tv_sec op (b)->tv_sec)
+#endif
+
+#ifndef timersub
+#define timersub(a, b, res) \
+ do { \
+ (res)->tv_sec = (a)->tv_sec - (b)->tv_sec; \
+ (res)->tv_usec = (a)->tv_usec - (b)->tv_usec; \
+ if ((res)->tv_usec < 0) { \
+ (res)->tv_usec += 1000000; \
+ (res)->tv_sec -= 1; \
+ } \
+ } while(0);
+#endif
+
+static fd_set readFds;
+static int nfds = 0;
+
+static struct ril_event * watch_table[MAX_FD_EVENTS];
+static struct ril_event timer_list;
+static struct ril_event pending_list;
+
+#define DEBUG 0
+
+#if DEBUG
+#define dlog(x...) RLOGD( x )
+static void dump_event(struct ril_event * ev)
+{
+ dlog("~~~~ Event %x ~~~~", (unsigned int)ev);
+ dlog(" next = %x", (unsigned int)ev->next);
+ dlog(" prev = %x", (unsigned int)ev->prev);
+ dlog(" fd = %d", ev->fd);
+ dlog(" pers = %d", ev->persist);
+ dlog(" timeout = %ds + %dus", (int)ev->timeout.tv_sec, (int)ev->timeout.tv_usec);
+ dlog(" func = %x", (unsigned int)ev->func);
+ dlog(" param = %x", (unsigned int)ev->param);
+ dlog("~~~~~~~~~~~~~~~~~~");
+}
+#else
+#define dlog(x...) do {} while(0)
+#define dump_event(x) do {} while(0)
+#endif
+
+static void getNow(struct timeval * tv)
+{
+ struct timespec ts;
+ clock_gettime(CLOCK_MONOTONIC, &ts);
+ tv->tv_sec = ts.tv_sec;
+ tv->tv_usec = ts.tv_nsec/1000;
+}
+
+static void init_list(struct ril_event * list)
+{
+ memset(list, 0, sizeof(struct ril_event));
+ list->next = list;
+ list->prev = list;
+ list->fd = -1;
+}
+
+static void addToList(struct ril_event * ev, struct ril_event * list)
+{
+ ev->next = list;
+ ev->prev = list->prev;
+ ev->prev->next = ev;
+ list->prev = ev;
+ dump_event(ev);
+}
+
+static void removeFromList(struct ril_event * ev)
+{
+ dlog("~~~~ +removeFromList ~~~~");
+ dump_event(ev);
+
+ ev->next->prev = ev->prev;
+ ev->prev->next = ev->next;
+ ev->next = NULL;
+ ev->prev = NULL;
+ dlog("~~~~ -removeFromList ~~~~");
+}
+
+
+static void removeWatch(struct ril_event * ev, int index)
+{
+ dlog("~~~~ +removeWatch ~~~~");
+ watch_table[index] = NULL;
+ ev->index = -1;
+
+ FD_CLR(ev->fd, &readFds);
+
+ if (ev->fd+1 == nfds) {
+ int n = 0;
+
+ for (int i = 0; i < MAX_FD_EVENTS; i++) {
+ struct ril_event * rev = watch_table[i];
+
+ if ((rev != NULL) && (rev->fd > n)) {
+ n = rev->fd;
+ }
+ }
+ nfds = n + 1;
+ dlog("~~~~ nfds = %d ~~~~", nfds);
+ }
+ dlog("~~~~ -removeWatch ~~~~");
+}
+
+static void processTimeouts()
+{
+ dlog("~~~~ +processTimeouts ~~~~");
+ MUTEX_ACQUIRE();
+ struct timeval now;
+ struct ril_event * tev = timer_list.next;
+ struct ril_event * next;
+
+ getNow(&now);
+ // walk list, see if now >= ev->timeout for any events
+
+ dlog("~~~~ Looking for timers <= %ds + %dus ~~~~", (int)now.tv_sec, (int)now.tv_usec);
+ while ((tev != &timer_list) && (timercmp(&now, &tev->timeout, >))) {
+ // Timer expired
+ dlog("~~~~ firing timer ~~~~");
+ next = tev->next;
+ removeFromList(tev);
+ addToList(tev, &pending_list);
+ tev = next;
+ }
+ MUTEX_RELEASE();
+ dlog("~~~~ -processTimeouts ~~~~");
+}
+
+static void processReadReadies(fd_set * rfds, int n)
+{
+ dlog("~~~~ +processReadReadies (%d) ~~~~", n);
+ MUTEX_ACQUIRE();
+
+ for (int i = 0; (i < MAX_FD_EVENTS) && (n > 0); i++) {
+ struct ril_event * rev = watch_table[i];
+ if (rev != NULL && FD_ISSET(rev->fd, rfds)) {
+ addToList(rev, &pending_list);
+ if (rev->persist == false) {
+ removeWatch(rev, i);
+ }
+ n--;
+ }
+ }
+
+ MUTEX_RELEASE();
+ dlog("~~~~ -processReadReadies (%d) ~~~~", n);
+}
+
+static void firePending()
+{
+ dlog("~~~~ +firePending ~~~~");
+ struct ril_event * ev = pending_list.next;
+ while (ev != &pending_list) {
+ struct ril_event * next = ev->next;
+ removeFromList(ev);
+ ev->func(ev->fd, 0, ev->param);
+ ev = next;
+ }
+ dlog("~~~~ -firePending ~~~~");
+}
+
+static int calcNextTimeout(struct timeval * tv)
+{
+ struct ril_event * tev = timer_list.next;
+ struct timeval now;
+
+ getNow(&now);
+
+ // Sorted list, so calc based on first node
+ if (tev == &timer_list) {
+ // no pending timers
+ return -1;
+ }
+
+ dlog("~~~~ now = %ds + %dus ~~~~", (int)now.tv_sec, (int)now.tv_usec);
+ dlog("~~~~ next = %ds + %dus ~~~~",
+ (int)tev->timeout.tv_sec, (int)tev->timeout.tv_usec);
+ if (timercmp(&tev->timeout, &now, >)) {
+ timersub(&tev->timeout, &now, tv);
+ } else {
+ // timer already expired.
+ tv->tv_sec = tv->tv_usec = 0;
+ }
+ return 0;
+}
+
+// Initialize internal data structs
+void ril_event_init()
+{
+ MUTEX_INIT();
+
+ FD_ZERO(&readFds);
+ init_list(&timer_list);
+ init_list(&pending_list);
+ memset(watch_table, 0, sizeof(watch_table));
+}
+
+// Initialize an event
+void ril_event_set(struct ril_event * ev, int fd, bool persist, ril_event_cb func, void * param)
+{
+ dlog("~~~~ ril_event_set %x ~~~~", (unsigned int)ev);
+ memset(ev, 0, sizeof(struct ril_event));
+ ev->fd = fd;
+ ev->index = -1;
+ ev->persist = persist;
+ ev->func = func;
+ ev->param = param;
+ fcntl(fd, F_SETFL, O_NONBLOCK);
+}
+
+// Add event to watch list
+void ril_event_add(struct ril_event * ev)
+{
+ dlog("~~~~ +ril_event_add ~~~~");
+ MUTEX_ACQUIRE();
+ for (int i = 0; i < MAX_FD_EVENTS; i++) {
+ if (watch_table[i] == NULL) {
+ watch_table[i] = ev;
+ ev->index = i;
+ dlog("~~~~ added at %d ~~~~", i);
+ dump_event(ev);
+ FD_SET(ev->fd, &readFds);
+ if (ev->fd >= nfds) nfds = ev->fd+1;
+ dlog("~~~~ nfds = %d ~~~~", nfds);
+ break;
+ }
+ }
+ MUTEX_RELEASE();
+ dlog("~~~~ -ril_event_add ~~~~");
+}
+
+// Add timer event
+void ril_timer_add(struct ril_event * ev, struct timeval * tv)
+{
+ dlog("~~~~ +ril_timer_add ~~~~");
+ MUTEX_ACQUIRE();
+
+ struct ril_event * list;
+ if (tv != NULL) {
+ // add to timer list
+ list = timer_list.next;
+ ev->fd = -1; // make sure fd is invalid
+
+ struct timeval now;
+ getNow(&now);
+ timeradd(&now, tv, &ev->timeout);
+
+ // keep list sorted
+ while (timercmp(&list->timeout, &ev->timeout, < )
+ && (list != &timer_list)) {
+ list = list->next;
+ }
+ // list now points to the first event older than ev
+ addToList(ev, list);
+ }
+
+ MUTEX_RELEASE();
+ dlog("~~~~ -ril_timer_add ~~~~");
+}
+
+// Remove event from watch or timer list
+void ril_event_del(struct ril_event * ev)
+{
+ dlog("~~~~ +ril_event_del ~~~~");
+ MUTEX_ACQUIRE();
+
+ if (ev->index < 0 || ev->index >= MAX_FD_EVENTS) {
+ MUTEX_RELEASE();
+ return;
+ }
+
+ removeWatch(ev, ev->index);
+
+ MUTEX_RELEASE();
+ dlog("~~~~ -ril_event_del ~~~~");
+}
+
+#if DEBUG
+static void printReadies(fd_set * rfds)
+{
+ for (int i = 0; (i < MAX_FD_EVENTS); i++) {
+ struct ril_event * rev = watch_table[i];
+ if (rev != NULL && FD_ISSET(rev->fd, rfds)) {
+ dlog("DON: fd=%d is ready", rev->fd);
+ }
+ }
+}
+#else
+#define printReadies(rfds) do {} while(0)
+#endif
+
+void ril_event_loop()
+{
+ int n;
+ fd_set rfds;
+ struct timeval tv;
+ struct timeval * ptv;
+
+
+ for (;;) {
+
+ // make local copy of read fd_set
+ memcpy(&rfds, &readFds, sizeof(fd_set));
+ if (-1 == calcNextTimeout(&tv)) {
+ // no pending timers; block indefinitely
+ dlog("~~~~ no timers; blocking indefinitely ~~~~");
+ ptv = NULL;
+ } else {
+ dlog("~~~~ blocking for %ds + %dus ~~~~", (int)tv.tv_sec, (int)tv.tv_usec);
+ ptv = &tv;
+ }
+ printReadies(&rfds);
+ n = select(nfds, &rfds, NULL, NULL, ptv);
+ printReadies(&rfds);
+ dlog("~~~~ %d events fired ~~~~", n);
+ if (n < 0) {
+ if (errno == EINTR) continue;
+
+ RLOGE("ril_event: select error (%d)", errno);
+ // bail?
+ return;
+ }
+
+ // Check for timeouts
+ processTimeouts();
+ // Check for read-ready
+ processReadReadies(&rfds, n);
+ // Fire away
+ firePending();
+ }
+}
diff --git a/guest/hals/ril/libril/ril_ex.h b/guest/hals/ril/libril/ril_ex.h
new file mode 100644
index 0000000..e0fcd7b
--- /dev/null
+++ b/guest/hals/ril/libril/ril_ex.h
@@ -0,0 +1,49 @@
+/*
+* Copyright (C) 2014 The Android Open Source Project
+*
+* Licensed under the Apache License, Version 2.0 (the "License");
+* you may not use this file except in compliance with the License.
+* You may obtain a copy of the License at
+*
+* http://www.apache.org/licenses/LICENSE-2.0
+*
+* Unless required by applicable law or agreed to in writing, software
+* distributed under the License is distributed on an "AS IS" BASIS,
+* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+* See the License for the specific language governing permissions and
+* limitations under the License.
+*/
+
+#ifndef RIL_EX_H_INCLUDED
+#define RIL_EX_H_INCLUDED
+
+#include <guest/hals/ril/libril/ril.h>
+#include <telephony/record_stream.h>
+
+#define NUM_ELEMS_SOCKET(a) (sizeof (a) / sizeof (a)[0])
+
+struct ril_event;
+
+void rilEventAddWakeup_helper(struct ril_event *ev);
+int blockingWrite_helper(int fd, void* data, size_t len);
+
+enum SocketWakeType {DONT_WAKE, WAKE_PARTIAL};
+
+typedef enum {
+ RIL_TELEPHONY_SOCKET,
+ RIL_SAP_SOCKET
+} RIL_SOCKET_TYPE;
+
+typedef struct SocketListenParam {
+ RIL_SOCKET_ID socket_id;
+ int fdListen;
+ int fdCommand;
+ const char* processName;
+ struct ril_event* commands_event;
+ struct ril_event* listen_event;
+ void (*processCommandsCallback)(int fd, short flags, void *param);
+ RecordStream *p_rs;
+ RIL_SOCKET_TYPE type;
+} SocketListenParam;
+
+#endif
diff --git a/guest/hals/ril/libril/ril_service.cpp b/guest/hals/ril/libril/ril_service.cpp
new file mode 100755
index 0000000..ac41d7e
--- /dev/null
+++ b/guest/hals/ril/libril/ril_service.cpp
@@ -0,0 +1,8957 @@
+/*
+ * Copyright (c) 2016 The Android Open Source Project
+ *
+ * Licensed under the Apache License, Version 2.0 (the "License");
+ * you may not use this file except in compliance with the License.
+ * You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#define LOG_TAG "RILC"
+
+#include <android/hardware/radio/1.4/IRadio.h>
+#include <android/hardware/radio/1.4/IRadioResponse.h>
+#include <android/hardware/radio/1.4/IRadioIndication.h>
+#include <android/hardware/radio/1.4/types.h>
+
+#include <android/hardware/radio/deprecated/1.0/IOemHook.h>
+
+#include <hwbinder/IPCThreadState.h>
+#include <hwbinder/ProcessState.h>
+#include <guest/hals/ril/libril/ril.h>
+#include <telephony/ril_mnc.h>
+#include <guest/hals/ril/libril/ril_service.h>
+#include <hidl/HidlTransportSupport.h>
+#include <utils/SystemClock.h>
+#include <inttypes.h>
+
+#define INVALID_HEX_CHAR 16
+
+using namespace android::hardware::radio;
+using namespace android::hardware::radio::V1_0;
+using namespace android::hardware::radio::deprecated::V1_0;
+using ::android::hardware::configureRpcThreadpool;
+using ::android::hardware::joinRpcThreadpool;
+using ::android::hardware::Return;
+using ::android::hardware::hidl_bitfield;
+using ::android::hardware::hidl_string;
+using ::android::hardware::hidl_vec;
+using ::android::hardware::hidl_array;
+using ::android::hardware::Void;
+using android::CommandInfo;
+using android::RequestInfo;
+using android::requestToString;
+using android::sp;
+
+#define BOOL_TO_INT(x) (x ? 1 : 0)
+#define ATOI_NULL_HANDLED(x) (x ? atoi(x) : -1)
+#define ATOI_NULL_HANDLED_DEF(x, defaultVal) (x ? atoi(x) : defaultVal)
+
+#if defined(ANDROID_MULTI_SIM)
+#define CALL_ONREQUEST(a, b, c, d, e) \
+ s_vendorFunctions->onRequest((a), (b), (c), (d), ((RIL_SOCKET_ID)(e)))
+#define CALL_ONSTATEREQUEST(a) s_vendorFunctions->onStateRequest((RIL_SOCKET_ID)(a))
+#else
+#define CALL_ONREQUEST(a, b, c, d, e) s_vendorFunctions->onRequest((a), (b), (c), (d))
+#define CALL_ONSTATEREQUEST(a) s_vendorFunctions->onStateRequest()
+#endif
+
+#ifdef OEM_HOOK_DISABLED
+constexpr bool kOemHookEnabled = false;
+#else
+constexpr bool kOemHookEnabled = true;
+#endif
+
+RIL_RadioFunctions *s_vendorFunctions = NULL;
+static CommandInfo *s_commands;
+
+struct RadioImpl_1_4;
+struct OemHookImpl;
+
+#if (SIM_COUNT >= 2)
+sp<RadioImpl_1_4> radioService[SIM_COUNT];
+sp<OemHookImpl> oemHookService[SIM_COUNT];
+int64_t nitzTimeReceived[SIM_COUNT];
+// counter used for synchronization. It is incremented every time response callbacks are updated.
+volatile int32_t mCounterRadio[SIM_COUNT];
+volatile int32_t mCounterOemHook[SIM_COUNT];
+#else
+sp<RadioImpl_1_4> radioService[1];
+sp<OemHookImpl> oemHookService[1];
+int64_t nitzTimeReceived[1];
+// counter used for synchronization. It is incremented every time response callbacks are updated.
+volatile int32_t mCounterRadio[1];
+volatile int32_t mCounterOemHook[1];
+#endif
+
+static pthread_rwlock_t radioServiceRwlock = PTHREAD_RWLOCK_INITIALIZER;
+
+#if (SIM_COUNT >= 2)
+static pthread_rwlock_t radioServiceRwlock2 = PTHREAD_RWLOCK_INITIALIZER;
+#if (SIM_COUNT >= 3)
+static pthread_rwlock_t radioServiceRwlock3 = PTHREAD_RWLOCK_INITIALIZER;
+#if (SIM_COUNT >= 4)
+static pthread_rwlock_t radioServiceRwlock4 = PTHREAD_RWLOCK_INITIALIZER;
+#endif
+#endif
+#endif
+
+void convertRilHardwareConfigListToHal(void *response, size_t responseLen,
+ hidl_vec<HardwareConfig>& records);
+
+void convertRilRadioCapabilityToHal(void *response, size_t responseLen, RadioCapability& rc);
+
+void convertRilLceDataInfoToHal(void *response, size_t responseLen, LceDataInfo& lce);
+
+void convertRilSignalStrengthToHal(void *response, size_t responseLen,
+ SignalStrength& signalStrength);
+
+void convertRilDataCallToHal(RIL_Data_Call_Response_v11 *dcResponse,
+ SetupDataCallResult& dcResult);
+
+void convertRilDataCallListToHal(void *response, size_t responseLen,
+ hidl_vec<SetupDataCallResult>& dcResultList);
+
+void convertRilCellInfoListToHal(void *response, size_t responseLen, hidl_vec<CellInfo>& records);
+
+struct RadioImpl_1_4 : public V1_4::IRadio {
+ int32_t mSlotId;
+ sp<IRadioResponse> mRadioResponse;
+ sp<IRadioIndication> mRadioIndication;
+ sp<V1_4::IRadioResponse> mRadioResponseV1_4;
+ sp<V1_4::IRadioIndication> mRadioIndicationV1_4;
+
+ Return<void> setResponseFunctions(
+ const ::android::sp<IRadioResponse>& radioResponse,
+ const ::android::sp<IRadioIndication>& radioIndication);
+
+ Return<void> getIccCardStatus(int32_t serial);
+
+ Return<void> supplyIccPinForApp(int32_t serial, const hidl_string& pin,
+ const hidl_string& aid);
+
+ Return<void> supplyIccPukForApp(int32_t serial, const hidl_string& puk,
+ const hidl_string& pin, const hidl_string& aid);
+
+ Return<void> supplyIccPin2ForApp(int32_t serial,
+ const hidl_string& pin2,
+ const hidl_string& aid);
+
+ Return<void> supplyIccPuk2ForApp(int32_t serial, const hidl_string& puk2,
+ const hidl_string& pin2, const hidl_string& aid);
+
+ Return<void> changeIccPinForApp(int32_t serial, const hidl_string& oldPin,
+ const hidl_string& newPin, const hidl_string& aid);
+
+ Return<void> changeIccPin2ForApp(int32_t serial, const hidl_string& oldPin2,
+ const hidl_string& newPin2, const hidl_string& aid);
+
+ Return<void> supplyNetworkDepersonalization(int32_t serial, const hidl_string& netPin);
+
+ Return<void> getCurrentCalls(int32_t serial);
+
+ Return<void> dial(int32_t serial, const Dial& dialInfo);
+
+ Return<void> getImsiForApp(int32_t serial,
+ const ::android::hardware::hidl_string& aid);
+
+ Return<void> hangup(int32_t serial, int32_t gsmIndex);
+
+ Return<void> hangupWaitingOrBackground(int32_t serial);
+
+ Return<void> hangupForegroundResumeBackground(int32_t serial);
+
+ Return<void> switchWaitingOrHoldingAndActive(int32_t serial);
+
+ Return<void> conference(int32_t serial);
+
+ Return<void> rejectCall(int32_t serial);
+
+ Return<void> getLastCallFailCause(int32_t serial);
+
+ Return<void> getSignalStrength(int32_t serial);
+
+ Return<void> getVoiceRegistrationState(int32_t serial);
+
+ Return<void> getDataRegistrationState(int32_t serial);
+
+ Return<void> getOperator(int32_t serial);
+
+ Return<void> setRadioPower(int32_t serial, bool on);
+
+ Return<void> sendDtmf(int32_t serial,
+ const ::android::hardware::hidl_string& s);
+
+ Return<void> sendSms(int32_t serial, const GsmSmsMessage& message);
+
+ Return<void> sendSMSExpectMore(int32_t serial, const GsmSmsMessage& message);
+
+ Return<void> setupDataCall(int32_t serial,
+ RadioTechnology radioTechnology,
+ const DataProfileInfo& profileInfo,
+ bool modemCognitive,
+ bool roamingAllowed,
+ bool isRoaming);
+
+ Return<void> iccIOForApp(int32_t serial,
+ const IccIo& iccIo);
+
+ Return<void> sendUssd(int32_t serial,
+ const ::android::hardware::hidl_string& ussd);
+
+ Return<void> cancelPendingUssd(int32_t serial);
+
+ Return<void> getClir(int32_t serial);
+
+ Return<void> setClir(int32_t serial, int32_t status);
+
+ Return<void> getCallForwardStatus(int32_t serial,
+ const CallForwardInfo& callInfo);
+
+ Return<void> setCallForward(int32_t serial,
+ const CallForwardInfo& callInfo);
+
+ Return<void> getCallWaiting(int32_t serial, int32_t serviceClass);
+
+ Return<void> setCallWaiting(int32_t serial, bool enable, int32_t serviceClass);
+
+ Return<void> acknowledgeLastIncomingGsmSms(int32_t serial,
+ bool success, SmsAcknowledgeFailCause cause);
+
+ Return<void> acceptCall(int32_t serial);
+
+ Return<void> deactivateDataCall(int32_t serial,
+ int32_t cid, bool reasonRadioShutDown);
+
+ Return<void> getFacilityLockForApp(int32_t serial,
+ const ::android::hardware::hidl_string& facility,
+ const ::android::hardware::hidl_string& password,
+ int32_t serviceClass,
+ const ::android::hardware::hidl_string& appId);
+
+ Return<void> setFacilityLockForApp(int32_t serial,
+ const ::android::hardware::hidl_string& facility,
+ bool lockState,
+ const ::android::hardware::hidl_string& password,
+ int32_t serviceClass,
+ const ::android::hardware::hidl_string& appId);
+
+ Return<void> setBarringPassword(int32_t serial,
+ const ::android::hardware::hidl_string& facility,
+ const ::android::hardware::hidl_string& oldPassword,
+ const ::android::hardware::hidl_string& newPassword);
+
+ Return<void> getNetworkSelectionMode(int32_t serial);
+
+ Return<void> setNetworkSelectionModeAutomatic(int32_t serial);
+
+ Return<void> setNetworkSelectionModeManual(int32_t serial,
+ const ::android::hardware::hidl_string& operatorNumeric);
+
+ Return<void> getAvailableNetworks(int32_t serial);
+
+ Return<void> startNetworkScan(int32_t serial, const V1_1::NetworkScanRequest& request);
+
+ Return<void> stopNetworkScan(int32_t serial);
+
+ Return<void> startDtmf(int32_t serial,
+ const ::android::hardware::hidl_string& s);
+
+ Return<void> stopDtmf(int32_t serial);
+
+ Return<void> getBasebandVersion(int32_t serial);
+
+ Return<void> separateConnection(int32_t serial, int32_t gsmIndex);
+
+ Return<void> setMute(int32_t serial, bool enable);
+
+ Return<void> getMute(int32_t serial);
+
+ Return<void> getClip(int32_t serial);
+
+ Return<void> getDataCallList(int32_t serial);
+
+ Return<void> setSuppServiceNotifications(int32_t serial, bool enable);
+
+ Return<void> writeSmsToSim(int32_t serial,
+ const SmsWriteArgs& smsWriteArgs);
+
+ Return<void> deleteSmsOnSim(int32_t serial, int32_t index);
+
+ Return<void> setBandMode(int32_t serial, RadioBandMode mode);
+
+ Return<void> getAvailableBandModes(int32_t serial);
+
+ Return<void> sendEnvelope(int32_t serial,
+ const ::android::hardware::hidl_string& command);
+
+ Return<void> sendTerminalResponseToSim(int32_t serial,
+ const ::android::hardware::hidl_string& commandResponse);
+
+ Return<void> handleStkCallSetupRequestFromSim(int32_t serial, bool accept);
+
+ Return<void> explicitCallTransfer(int32_t serial);
+
+ Return<void> setPreferredNetworkType(int32_t serial, PreferredNetworkType nwType);
+
+ Return<void> getPreferredNetworkType(int32_t serial);
+
+ Return<void> getNeighboringCids(int32_t serial);
+
+ Return<void> setLocationUpdates(int32_t serial, bool enable);
+
+ Return<void> setCdmaSubscriptionSource(int32_t serial,
+ CdmaSubscriptionSource cdmaSub);
+
+ Return<void> setCdmaRoamingPreference(int32_t serial, CdmaRoamingType type);
+
+ Return<void> getCdmaRoamingPreference(int32_t serial);
+
+ Return<void> setTTYMode(int32_t serial, TtyMode mode);
+
+ Return<void> getTTYMode(int32_t serial);
+
+ Return<void> setPreferredVoicePrivacy(int32_t serial, bool enable);
+
+ Return<void> getPreferredVoicePrivacy(int32_t serial);
+
+ Return<void> sendCDMAFeatureCode(int32_t serial,
+ const ::android::hardware::hidl_string& featureCode);
+
+ Return<void> sendBurstDtmf(int32_t serial,
+ const ::android::hardware::hidl_string& dtmf,
+ int32_t on,
+ int32_t off);
+
+ Return<void> sendCdmaSms(int32_t serial, const CdmaSmsMessage& sms);
+
+ Return<void> acknowledgeLastIncomingCdmaSms(int32_t serial,
+ const CdmaSmsAck& smsAck);
+
+ Return<void> getGsmBroadcastConfig(int32_t serial);
+
+ Return<void> setGsmBroadcastConfig(int32_t serial,
+ const hidl_vec<GsmBroadcastSmsConfigInfo>& configInfo);
+
+ Return<void> setGsmBroadcastActivation(int32_t serial, bool activate);
+
+ Return<void> getCdmaBroadcastConfig(int32_t serial);
+
+ Return<void> setCdmaBroadcastConfig(int32_t serial,
+ const hidl_vec<CdmaBroadcastSmsConfigInfo>& configInfo);
+
+ Return<void> setCdmaBroadcastActivation(int32_t serial, bool activate);
+
+ Return<void> getCDMASubscription(int32_t serial);
+
+ Return<void> writeSmsToRuim(int32_t serial, const CdmaSmsWriteArgs& cdmaSms);
+
+ Return<void> deleteSmsOnRuim(int32_t serial, int32_t index);
+
+ Return<void> getDeviceIdentity(int32_t serial);
+
+ Return<void> exitEmergencyCallbackMode(int32_t serial);
+
+ Return<void> getSmscAddress(int32_t serial);
+
+ Return<void> setSmscAddress(int32_t serial,
+ const ::android::hardware::hidl_string& smsc);
+
+ Return<void> reportSmsMemoryStatus(int32_t serial, bool available);
+
+ Return<void> reportStkServiceIsRunning(int32_t serial);
+
+ Return<void> getCdmaSubscriptionSource(int32_t serial);
+
+ Return<void> requestIsimAuthentication(int32_t serial,
+ const ::android::hardware::hidl_string& challenge);
+
+ Return<void> acknowledgeIncomingGsmSmsWithPdu(int32_t serial,
+ bool success,
+ const ::android::hardware::hidl_string& ackPdu);
+
+ Return<void> sendEnvelopeWithStatus(int32_t serial,
+ const ::android::hardware::hidl_string& contents);
+
+ Return<void> getVoiceRadioTechnology(int32_t serial);
+
+ Return<void> getCellInfoList(int32_t serial);
+
+ Return<void> setCellInfoListRate(int32_t serial, int32_t rate);
+
+ Return<void> setInitialAttachApn(int32_t serial, const DataProfileInfo& dataProfileInfo,
+ bool modemCognitive, bool isRoaming);
+
+ Return<void> getImsRegistrationState(int32_t serial);
+
+ Return<void> sendImsSms(int32_t serial, const ImsSmsMessage& message);
+
+ Return<void> iccTransmitApduBasicChannel(int32_t serial, const SimApdu& message);
+
+ Return<void> iccOpenLogicalChannel(int32_t serial,
+ const ::android::hardware::hidl_string& aid, int32_t p2);
+
+ Return<void> iccCloseLogicalChannel(int32_t serial, int32_t channelId);
+
+ Return<void> iccTransmitApduLogicalChannel(int32_t serial, const SimApdu& message);
+
+ Return<void> nvReadItem(int32_t serial, NvItem itemId);
+
+ Return<void> nvWriteItem(int32_t serial, const NvWriteItem& item);
+
+ Return<void> nvWriteCdmaPrl(int32_t serial,
+ const ::android::hardware::hidl_vec<uint8_t>& prl);
+
+ Return<void> nvResetConfig(int32_t serial, ResetNvType resetType);
+
+ Return<void> setUiccSubscription(int32_t serial, const SelectUiccSub& uiccSub);
+
+ Return<void> setDataAllowed(int32_t serial, bool allow);
+
+ Return<void> getHardwareConfig(int32_t serial);
+
+ Return<void> requestIccSimAuthentication(int32_t serial,
+ int32_t authContext,
+ const ::android::hardware::hidl_string& authData,
+ const ::android::hardware::hidl_string& aid);
+
+ Return<void> setDataProfile(int32_t serial,
+ const ::android::hardware::hidl_vec<DataProfileInfo>& profiles, bool isRoaming);
+
+ Return<void> requestShutdown(int32_t serial);
+
+ Return<void> getRadioCapability(int32_t serial);
+
+ Return<void> setRadioCapability(int32_t serial, const RadioCapability& rc);
+
+ Return<void> startLceService(int32_t serial, int32_t reportInterval, bool pullMode);
+
+ Return<void> stopLceService(int32_t serial);
+
+ Return<void> pullLceData(int32_t serial);
+
+ Return<void> getModemActivityInfo(int32_t serial);
+
+ Return<void> setAllowedCarriers(int32_t serial,
+ bool allAllowed,
+ const CarrierRestrictions& carriers);
+
+ Return<void> getAllowedCarriers(int32_t serial);
+
+ Return<void> sendDeviceState(int32_t serial, DeviceStateType deviceStateType, bool state);
+
+ Return<void> setIndicationFilter(int32_t serial, int32_t indicationFilter);
+
+ Return<void> startKeepalive(int32_t serial, const V1_1::KeepaliveRequest& keepalive);
+
+ Return<void> stopKeepalive(int32_t serial, int32_t sessionHandle);
+
+ Return<void> setSimCardPower(int32_t serial, bool powerUp);
+ Return<void> setSimCardPower_1_1(int32_t serial,
+ const V1_1::CardPowerState state);
+
+ Return<void> responseAcknowledgement();
+
+ Return<void> setCarrierInfoForImsiEncryption(int32_t serial,
+ const V1_1::ImsiEncryptionInfo& message);
+
+ void checkReturnStatus(Return<void>& ret);
+
+ // Methods from ::android::hardware::radio::V1_2::IRadio follow.
+ Return<void> startNetworkScan_1_2(int32_t serial,
+ const ::android::hardware::radio::V1_2::NetworkScanRequest& request);
+ Return<void> setIndicationFilter_1_2(int32_t serial,
+ hidl_bitfield<::android::hardware::radio::V1_2::IndicationFilter> indicationFilter);
+ Return<void> setSignalStrengthReportingCriteria(int32_t serial, int32_t hysteresisMs,
+ int32_t hysteresisDb, const hidl_vec<int32_t>& thresholdsDbm,
+ ::android::hardware::radio::V1_2::AccessNetwork accessNetwork);
+ Return<void> setLinkCapacityReportingCriteria(int32_t serial, int32_t hysteresisMs,
+ int32_t hysteresisDlKbps, int32_t hysteresisUlKbps,
+ const hidl_vec<int32_t>& thresholdsDownlinkKbps,
+ const hidl_vec<int32_t>& thresholdsUplinkKbps,
+ ::android::hardware::radio::V1_2::AccessNetwork accessNetwork);
+ Return<void> setupDataCall_1_2(int32_t serial,
+ ::android::hardware::radio::V1_2::AccessNetwork accessNetwork,
+ const ::android::hardware::radio::V1_0::DataProfileInfo& dataProfileInfo,
+ bool modemCognitive, bool roamingAllowed, bool isRoaming,
+ ::android::hardware::radio::V1_2::DataRequestReason reason,
+ const hidl_vec<hidl_string>& addresses, const hidl_vec<hidl_string>& dnses);
+ Return<void> deactivateDataCall_1_2(int32_t serial, int32_t cid,
+ ::android::hardware::radio::V1_2::DataRequestReason reason);
+
+ // Methods from ::android::hardware::radio::V1_3::IRadio follow.
+ Return<void> setSystemSelectionChannels(int32_t serial, bool specifyChannels,
+ const hidl_vec<::android::hardware::radio::V1_1::RadioAccessSpecifier>& specifiers)
+ ;
+ Return<void> enableModem(int32_t serial, bool on);
+ Return<void> getModemStackStatus(int32_t serial);
+
+ // Methods from ::android::hardware::radio::V1_4::IRadio follow.
+ Return<void> setupDataCall_1_4(int32_t serial,
+ ::android::hardware::radio::V1_4::AccessNetwork accessNetwork,
+ const ::android::hardware::radio::V1_4::DataProfileInfo& dataProfileInfo,
+ bool roamingAllowed, ::android::hardware::radio::V1_2::DataRequestReason reason,
+ const hidl_vec<hidl_string>& addresses, const hidl_vec<hidl_string>& dnses);
+ Return<void> setInitialAttachApn_1_4(int32_t serial,
+ const ::android::hardware::radio::V1_4::DataProfileInfo& dataProfileInfo);
+ Return<void> setDataProfile_1_4(int32_t serial,
+ const hidl_vec<::android::hardware::radio::V1_4::DataProfileInfo>& profiles);
+ Return<void> emergencyDial(int32_t serial,
+ const ::android::hardware::radio::V1_0::Dial& dialInfo,
+ hidl_bitfield<android::hardware::radio::V1_4::EmergencyServiceCategory> categories,
+ const hidl_vec<hidl_string>& urns,
+ ::android::hardware::radio::V1_4::EmergencyCallRouting routing,
+ bool fromEmergencyDialer, bool isTesting);
+ Return<void> startNetworkScan_1_4(int32_t serial,
+ const ::android::hardware::radio::V1_2::NetworkScanRequest& request);
+ Return<void> getPreferredNetworkTypeBitmap(int32_t serial);
+ Return<void> setPreferredNetworkTypeBitmap(
+ int32_t serial, hidl_bitfield<RadioAccessFamily> networkTypeBitmap);
+ Return<void> setAllowedCarriers_1_4(int32_t serial,
+ const ::android::hardware::radio::V1_4::CarrierRestrictionsWithPriority& carriers,
+ ::android::hardware::radio::V1_4::SimLockMultiSimPolicy multiSimPolicy);
+ Return<void> getAllowedCarriers_1_4(int32_t serial);
+ Return<void> getSignalStrength_1_4(int32_t serial);
+};
+
+struct OemHookImpl : public IOemHook {
+ int32_t mSlotId;
+ sp<IOemHookResponse> mOemHookResponse;
+ sp<IOemHookIndication> mOemHookIndication;
+
+ Return<void> setResponseFunctions(
+ const ::android::sp<IOemHookResponse>& oemHookResponse,
+ const ::android::sp<IOemHookIndication>& oemHookIndication);
+
+ Return<void> sendRequestRaw(int32_t serial,
+ const ::android::hardware::hidl_vec<uint8_t>& data);
+
+ Return<void> sendRequestStrings(int32_t serial,
+ const ::android::hardware::hidl_vec<::android::hardware::hidl_string>& data);
+};
+
+void memsetAndFreeStrings(int numPointers, ...) {
+ va_list ap;
+ va_start(ap, numPointers);
+ for (int i = 0; i < numPointers; i++) {
+ char *ptr = va_arg(ap, char *);
+ if (ptr) {
+#ifdef MEMSET_FREED
+#define MAX_STRING_LENGTH 4096
+ memset(ptr, 0, strnlen(ptr, MAX_STRING_LENGTH));
+#endif
+ free(ptr);
+ }
+ }
+ va_end(ap);
+}
+
+void sendErrorResponse(RequestInfo *pRI, RIL_Errno err) {
+ pRI->pCI->responseFunction((int) pRI->socket_id,
+ (int) RadioResponseType::SOLICITED, pRI->token, err, NULL, 0);
+}
+
+/**
+ * Copies over src to dest. If memory allocation fails, responseFunction() is called for the
+ * request with error RIL_E_NO_MEMORY. The size() method is used to determine the size of the
+ * destination buffer into which the HIDL string is copied. If there is a discrepancy between
+ * the string length reported by the size() method, and the length of the string returned by
+ * the c_str() method, the function will return false indicating a failure.
+ *
+ * Returns true on success, and false on failure.
+ */
+bool copyHidlStringToRil(char **dest, const hidl_string &src, RequestInfo *pRI, bool allowEmpty) {
+ size_t len = src.size();
+ if (len == 0 && !allowEmpty) {
+ *dest = NULL;
+ return true;
+ }
+ *dest = (char *) calloc(len + 1, sizeof(char));
+ if (*dest == NULL) {
+ RLOGE("Memory allocation failed for request %s", requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return false;
+ }
+ if (strlcpy(*dest, src.c_str(), len + 1) >= (len + 1)) {
+ RLOGE("Copy of the HIDL string has been truncated, as "
+ "the string length reported by size() does not "
+ "match the length of string returned by c_str().");
+ free(*dest);
+ *dest = NULL;
+ sendErrorResponse(pRI, RIL_E_INTERNAL_ERR);
+ return false;
+ }
+ return true;
+}
+
+bool copyHidlStringToRil(char **dest, const hidl_string &src, RequestInfo *pRI) {
+ return copyHidlStringToRil(dest, src, pRI, false);
+}
+
+hidl_string convertCharPtrToHidlString(const char *ptr) {
+ hidl_string ret;
+ if (ptr != NULL) {
+ // TODO: replace this with strnlen
+ ret.setToExternal(ptr, strlen(ptr));
+ }
+ return ret;
+}
+
+bool dispatchVoid(int serial, int slotId, int request) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+ CALL_ONREQUEST(request, NULL, 0, pRI, slotId);
+ return true;
+}
+
+bool dispatchString(int serial, int slotId, int request, const char * str) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ char *pString;
+ if (!copyHidlStringToRil(&pString, str, pRI)) {
+ return false;
+ }
+
+ CALL_ONREQUEST(request, pString, sizeof(char *), pRI, slotId);
+
+ memsetAndFreeStrings(1, pString);
+ return true;
+}
+
+bool dispatchStrings(int serial, int slotId, int request, bool allowEmpty, int countStrings, ...) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ char **pStrings;
+ pStrings = (char **)calloc(countStrings, sizeof(char *));
+ if (pStrings == NULL) {
+ RLOGE("Memory allocation failed for request %s", requestToString(request));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return false;
+ }
+ va_list ap;
+ va_start(ap, countStrings);
+ for (int i = 0; i < countStrings; i++) {
+ const char* str = va_arg(ap, const char *);
+ if (!copyHidlStringToRil(&pStrings[i], hidl_string(str), pRI, allowEmpty)) {
+ va_end(ap);
+ for (int j = 0; j < i; j++) {
+ memsetAndFreeStrings(1, pStrings[j]);
+ }
+ free(pStrings);
+ return false;
+ }
+ }
+ va_end(ap);
+
+ CALL_ONREQUEST(request, pStrings, countStrings * sizeof(char *), pRI, slotId);
+
+ if (pStrings != NULL) {
+ for (int i = 0 ; i < countStrings ; i++) {
+ memsetAndFreeStrings(1, pStrings[i]);
+ }
+
+#ifdef MEMSET_FREED
+ memset(pStrings, 0, countStrings * sizeof(char *));
+#endif
+ free(pStrings);
+ }
+ return true;
+}
+
+bool dispatchStrings(int serial, int slotId, int request, const hidl_vec<hidl_string>& data) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ int countStrings = data.size();
+ char **pStrings;
+ pStrings = (char **)calloc(countStrings, sizeof(char *));
+ if (pStrings == NULL) {
+ RLOGE("Memory allocation failed for request %s", requestToString(request));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return false;
+ }
+
+ for (int i = 0; i < countStrings; i++) {
+ if (!copyHidlStringToRil(&pStrings[i], data[i], pRI)) {
+ for (int j = 0; j < i; j++) {
+ memsetAndFreeStrings(1, pStrings[j]);
+ }
+ free(pStrings);
+ return false;
+ }
+ }
+
+ CALL_ONREQUEST(request, pStrings, countStrings * sizeof(char *), pRI, slotId);
+
+ if (pStrings != NULL) {
+ for (int i = 0 ; i < countStrings ; i++) {
+ memsetAndFreeStrings(1, pStrings[i]);
+ }
+
+#ifdef MEMSET_FREED
+ memset(pStrings, 0, countStrings * sizeof(char *));
+#endif
+ free(pStrings);
+ }
+ return true;
+}
+
+bool dispatchInts(int serial, int slotId, int request, int countInts, ...) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ int *pInts = (int *)calloc(countInts, sizeof(int));
+
+ if (pInts == NULL) {
+ RLOGE("Memory allocation failed for request %s", requestToString(request));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return false;
+ }
+ va_list ap;
+ va_start(ap, countInts);
+ for (int i = 0; i < countInts; i++) {
+ pInts[i] = va_arg(ap, int);
+ }
+ va_end(ap);
+
+ CALL_ONREQUEST(request, pInts, countInts * sizeof(int), pRI, slotId);
+
+ if (pInts != NULL) {
+#ifdef MEMSET_FREED
+ memset(pInts, 0, countInts * sizeof(int));
+#endif
+ free(pInts);
+ }
+ return true;
+}
+
+bool dispatchCallForwardStatus(int serial, int slotId, int request,
+ const CallForwardInfo& callInfo) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ RIL_CallForwardInfo cf;
+ cf.status = (int) callInfo.status;
+ cf.reason = callInfo.reason;
+ cf.serviceClass = callInfo.serviceClass;
+ cf.toa = callInfo.toa;
+ cf.timeSeconds = callInfo.timeSeconds;
+
+ if (!copyHidlStringToRil(&cf.number, callInfo.number, pRI)) {
+ return false;
+ }
+
+ CALL_ONREQUEST(request, &cf, sizeof(cf), pRI, slotId);
+
+ memsetAndFreeStrings(1, cf.number);
+
+ return true;
+}
+
+bool dispatchRaw(int serial, int slotId, int request, const hidl_vec<uint8_t>& rawBytes) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ const uint8_t *uData = rawBytes.data();
+
+ CALL_ONREQUEST(request, (void *) uData, rawBytes.size(), pRI, slotId);
+
+ return true;
+}
+
+bool dispatchIccApdu(int serial, int slotId, int request, const SimApdu& message) {
+ RequestInfo *pRI = android::addRequestToList(serial, slotId, request);
+ if (pRI == NULL) {
+ return false;
+ }
+
+ RIL_SIM_APDU apdu = {};
+
+ apdu.sessionid = message.sessionId;
+ apdu.cla = message.cla;
+ apdu.instruction = message.instruction;
+ apdu.p1 = message.p1;
+ apdu.p2 = message.p2;
+ apdu.p3 = message.p3;
+
+ if (!copyHidlStringToRil(&apdu.data, message.data, pRI)) {
+ return false;
+ }
+
+ CALL_ONREQUEST(request, &apdu, sizeof(apdu), pRI, slotId);
+
+ memsetAndFreeStrings(1, apdu.data);
+
+ return true;
+}
+
+void checkReturnStatus(int32_t slotId, Return<void>& ret, bool isRadioService) {
+ RLOGD("checkReturnStatus: ret.isOK(). slotId = %d, isRadioService = %s", slotId,
+ isRadioService ? "Y" : "N");
+ if (ret.isOk() == false) {
+ RLOGE("checkReturnStatus: unable to call response/indication callback");
+ // Remote process hosting the callbacks must be dead. Reset the callback objects;
+ // there's no other recovery to be done here. When the client process is back up, it will
+ // call setResponseFunctions()
+
+ // Caller should already hold rdlock, release that first
+ // note the current counter to avoid overwriting updates made by another thread before
+ // write lock is acquired.
+ int counter = isRadioService ? mCounterRadio[slotId] : mCounterOemHook[slotId];
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock(slotId);
+ int ret = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ // acquire wrlock
+ ret = pthread_rwlock_wrlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ // make sure the counter value has not changed
+ if (counter == (isRadioService ? mCounterRadio[slotId] : mCounterOemHook[slotId])) {
+ if (isRadioService) {
+ radioService[slotId]->mRadioResponse = NULL;
+ radioService[slotId]->mRadioIndication = NULL;
+ radioService[slotId]->mRadioResponseV1_4 = NULL;
+ radioService[slotId]->mRadioIndicationV1_4 = NULL;
+ } else {
+ oemHookService[slotId]->mOemHookResponse = NULL;
+ oemHookService[slotId]->mOemHookIndication = NULL;
+ }
+ isRadioService ? mCounterRadio[slotId]++ : mCounterOemHook[slotId]++;
+ } else {
+ RLOGE("checkReturnStatus: not resetting responseFunctions as they likely "
+ "got updated on another thread");
+ }
+
+ // release wrlock
+ ret = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ // Reacquire rdlock
+ ret = pthread_rwlock_rdlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+ }
+}
+
+void RadioImpl_1_4::checkReturnStatus(Return<void>& ret) {
+ ::checkReturnStatus(mSlotId, ret, true);
+}
+
+Return<void> RadioImpl_1_4::setResponseFunctions(
+ const ::android::sp<IRadioResponse>& radioResponseParam,
+ const ::android::sp<IRadioIndication>& radioIndicationParam) {
+ RLOGD("setResponseFunctions");
+
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock(mSlotId);
+ int ret = pthread_rwlock_wrlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ mRadioResponse = radioResponseParam;
+ mRadioIndication = radioIndicationParam;
+ mRadioResponseV1_4 = V1_4::IRadioResponse::castFrom(mRadioResponse).withDefault(nullptr);
+ mRadioIndicationV1_4 = V1_4::IRadioIndication::castFrom(mRadioIndication).withDefault(nullptr);
+ if (mRadioResponseV1_4 == nullptr || mRadioIndicationV1_4 == nullptr) {
+ mRadioResponseV1_4 = nullptr;
+ mRadioIndicationV1_4 = nullptr;
+ }
+
+ mCounterRadio[mSlotId]++;
+
+ ret = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ // client is connected. Send initial indications.
+ android::onNewCommandConnect((RIL_SOCKET_ID) mSlotId);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getIccCardStatus(int32_t serial) {
+#if VDBG
+ RLOGD("getIccCardStatus: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_SIM_STATUS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::supplyIccPinForApp(int32_t serial, const hidl_string& pin,
+ const hidl_string& aid) {
+#if VDBG
+ RLOGD("supplyIccPinForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ENTER_SIM_PIN, true,
+ 2, pin.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::supplyIccPukForApp(int32_t serial, const hidl_string& puk,
+ const hidl_string& pin, const hidl_string& aid) {
+#if VDBG
+ RLOGD("supplyIccPukForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ENTER_SIM_PUK, true,
+ 3, puk.c_str(), pin.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::supplyIccPin2ForApp(int32_t serial, const hidl_string& pin2,
+ const hidl_string& aid) {
+#if VDBG
+ RLOGD("supplyIccPin2ForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ENTER_SIM_PIN2, true,
+ 2, pin2.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::supplyIccPuk2ForApp(int32_t serial, const hidl_string& puk2,
+ const hidl_string& pin2, const hidl_string& aid) {
+#if VDBG
+ RLOGD("supplyIccPuk2ForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ENTER_SIM_PUK2, true,
+ 3, puk2.c_str(), pin2.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::changeIccPinForApp(int32_t serial, const hidl_string& oldPin,
+ const hidl_string& newPin, const hidl_string& aid) {
+#if VDBG
+ RLOGD("changeIccPinForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_CHANGE_SIM_PIN, true,
+ 3, oldPin.c_str(), newPin.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::changeIccPin2ForApp(int32_t serial, const hidl_string& oldPin2,
+ const hidl_string& newPin2, const hidl_string& aid) {
+#if VDBG
+ RLOGD("changeIccPin2ForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_CHANGE_SIM_PIN2, true,
+ 3, oldPin2.c_str(), newPin2.c_str(), aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::supplyNetworkDepersonalization(int32_t serial,
+ const hidl_string& netPin) {
+#if VDBG
+ RLOGD("supplyNetworkDepersonalization: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ENTER_NETWORK_DEPERSONALIZATION, true,
+ 1, netPin.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCurrentCalls(int32_t serial) {
+#if VDBG
+ RLOGD("getCurrentCalls: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_CURRENT_CALLS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::dial(int32_t serial, const Dial& dialInfo) {
+#if VDBG
+ RLOGD("dial: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_DIAL);
+ if (pRI == NULL) {
+ return Void();
+ }
+ RIL_Dial dial = {};
+ RIL_UUS_Info uusInfo = {};
+ int32_t sizeOfDial = sizeof(dial);
+
+ if (!copyHidlStringToRil(&dial.address, dialInfo.address, pRI)) {
+ return Void();
+ }
+ dial.clir = (int) dialInfo.clir;
+
+ if (dialInfo.uusInfo.size() != 0) {
+ uusInfo.uusType = (RIL_UUS_Type) dialInfo.uusInfo[0].uusType;
+ uusInfo.uusDcs = (RIL_UUS_DCS) dialInfo.uusInfo[0].uusDcs;
+
+ if (dialInfo.uusInfo[0].uusData.size() == 0) {
+ uusInfo.uusData = NULL;
+ uusInfo.uusLength = 0;
+ } else {
+ if (!copyHidlStringToRil(&uusInfo.uusData, dialInfo.uusInfo[0].uusData, pRI)) {
+ memsetAndFreeStrings(1, dial.address);
+ return Void();
+ }
+ uusInfo.uusLength = dialInfo.uusInfo[0].uusData.size();
+ }
+
+ dial.uusInfo = &uusInfo;
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_DIAL, &dial, sizeOfDial, pRI, mSlotId);
+
+ memsetAndFreeStrings(2, dial.address, uusInfo.uusData);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getImsiForApp(int32_t serial, const hidl_string& aid) {
+#if VDBG
+ RLOGD("getImsiForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_GET_IMSI, false,
+ 1, aid.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::hangup(int32_t serial, int32_t gsmIndex) {
+#if VDBG
+ RLOGD("hangup: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_HANGUP, 1, gsmIndex);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::hangupWaitingOrBackground(int32_t serial) {
+#if VDBG
+ RLOGD("hangupWaitingOrBackground: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_HANGUP_WAITING_OR_BACKGROUND);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::hangupForegroundResumeBackground(int32_t serial) {
+#if VDBG
+ RLOGD("hangupForegroundResumeBackground: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_HANGUP_FOREGROUND_RESUME_BACKGROUND);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::switchWaitingOrHoldingAndActive(int32_t serial) {
+#if VDBG
+ RLOGD("switchWaitingOrHoldingAndActive: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_SWITCH_WAITING_OR_HOLDING_AND_ACTIVE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::conference(int32_t serial) {
+#if VDBG
+ RLOGD("conference: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CONFERENCE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::rejectCall(int32_t serial) {
+#if VDBG
+ RLOGD("rejectCall: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_UDUB);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getLastCallFailCause(int32_t serial) {
+#if VDBG
+ RLOGD("getLastCallFailCause: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_LAST_CALL_FAIL_CAUSE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getSignalStrength(int32_t serial) {
+#if VDBG
+ RLOGD("getSignalStrength: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_SIGNAL_STRENGTH);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getVoiceRegistrationState(int32_t serial) {
+#if VDBG
+ RLOGD("getVoiceRegistrationState: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_VOICE_REGISTRATION_STATE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getDataRegistrationState(int32_t serial) {
+#if VDBG
+ RLOGD("getDataRegistrationState: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_DATA_REGISTRATION_STATE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getOperator(int32_t serial) {
+#if VDBG
+ RLOGD("getOperator: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_OPERATOR);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setRadioPower(int32_t serial, bool on) {
+ RLOGD("setRadioPower: serial %d on %d", serial, on);
+ dispatchInts(serial, mSlotId, RIL_REQUEST_RADIO_POWER, 1, BOOL_TO_INT(on));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendDtmf(int32_t serial, const hidl_string& s) {
+#if VDBG
+ RLOGD("sendDtmf: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_DTMF, s.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendSms(int32_t serial, const GsmSmsMessage& message) {
+#if VDBG
+ RLOGD("sendSms: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SEND_SMS, false,
+ 2, message.smscPdu.c_str(), message.pdu.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendSMSExpectMore(int32_t serial, const GsmSmsMessage& message) {
+#if VDBG
+ RLOGD("sendSMSExpectMore: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SEND_SMS_EXPECT_MORE, false,
+ 2, message.smscPdu.c_str(), message.pdu.c_str());
+ return Void();
+}
+
+static bool convertMvnoTypeToString(MvnoType type, char *&str) {
+ switch (type) {
+ case MvnoType::IMSI:
+ str = (char *)"imsi";
+ return true;
+ case MvnoType::GID:
+ str = (char *)"gid";
+ return true;
+ case MvnoType::SPN:
+ str = (char *)"spn";
+ return true;
+ case MvnoType::NONE:
+ str = (char *)"";
+ return true;
+ }
+ return false;
+}
+
+Return<void> RadioImpl_1_4::setupDataCall(int32_t serial, RadioTechnology radioTechnology,
+ const DataProfileInfo& dataProfileInfo, bool modemCognitive,
+ bool roamingAllowed, bool isRoaming) {
+
+#if VDBG
+ RLOGD("setupDataCall: serial %d", serial);
+#endif
+
+ if (s_vendorFunctions->version >= 4 && s_vendorFunctions->version <= 14) {
+ const hidl_string &protocol =
+ (isRoaming ? dataProfileInfo.roamingProtocol : dataProfileInfo.protocol);
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SETUP_DATA_CALL, true, 7,
+ std::to_string((int) radioTechnology + 2).c_str(),
+ std::to_string((int) dataProfileInfo.profileId).c_str(),
+ dataProfileInfo.apn.c_str(),
+ dataProfileInfo.user.c_str(),
+ dataProfileInfo.password.c_str(),
+ std::to_string((int) dataProfileInfo.authType).c_str(),
+ protocol.c_str());
+ } else if (s_vendorFunctions->version >= 15) {
+ char *mvnoTypeStr = NULL;
+ if (!convertMvnoTypeToString(dataProfileInfo.mvnoType, mvnoTypeStr)) {
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SETUP_DATA_CALL);
+ if (pRI != NULL) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ }
+ return Void();
+ }
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SETUP_DATA_CALL, true, 15,
+ std::to_string((int) radioTechnology + 2).c_str(),
+ std::to_string((int) dataProfileInfo.profileId).c_str(),
+ dataProfileInfo.apn.c_str(),
+ dataProfileInfo.user.c_str(),
+ dataProfileInfo.password.c_str(),
+ std::to_string((int) dataProfileInfo.authType).c_str(),
+ dataProfileInfo.protocol.c_str(),
+ dataProfileInfo.roamingProtocol.c_str(),
+ std::to_string(dataProfileInfo.supportedApnTypesBitmap).c_str(),
+ std::to_string(dataProfileInfo.bearerBitmap).c_str(),
+ modemCognitive ? "1" : "0",
+ std::to_string(dataProfileInfo.mtu).c_str(),
+ mvnoTypeStr,
+ dataProfileInfo.mvnoMatchData.c_str(),
+ roamingAllowed ? "1" : "0");
+ } else {
+ RLOGE("Unsupported RIL version %d, min version expected 4", s_vendorFunctions->version);
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SETUP_DATA_CALL);
+ if (pRI != NULL) {
+ sendErrorResponse(pRI, RIL_E_REQUEST_NOT_SUPPORTED);
+ }
+ }
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::iccIOForApp(int32_t serial, const IccIo& iccIo) {
+#if VDBG
+ RLOGD("iccIOForApp: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_SIM_IO);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_SIM_IO_v6 rilIccIo = {};
+ rilIccIo.command = iccIo.command;
+ rilIccIo.fileid = iccIo.fileId;
+ if (!copyHidlStringToRil(&rilIccIo.path, iccIo.path, pRI)) {
+ return Void();
+ }
+
+ rilIccIo.p1 = iccIo.p1;
+ rilIccIo.p2 = iccIo.p2;
+ rilIccIo.p3 = iccIo.p3;
+
+ if (!copyHidlStringToRil(&rilIccIo.data, iccIo.data, pRI)) {
+ memsetAndFreeStrings(1, rilIccIo.path);
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&rilIccIo.pin2, iccIo.pin2, pRI)) {
+ memsetAndFreeStrings(2, rilIccIo.path, rilIccIo.data);
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&rilIccIo.aidPtr, iccIo.aid, pRI)) {
+ memsetAndFreeStrings(3, rilIccIo.path, rilIccIo.data, rilIccIo.pin2);
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_SIM_IO, &rilIccIo, sizeof(rilIccIo), pRI, mSlotId);
+
+ memsetAndFreeStrings(4, rilIccIo.path, rilIccIo.data, rilIccIo.pin2, rilIccIo.aidPtr);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendUssd(int32_t serial, const hidl_string& ussd) {
+#if VDBG
+ RLOGD("sendUssd: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_SEND_USSD, ussd.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::cancelPendingUssd(int32_t serial) {
+#if VDBG
+ RLOGD("cancelPendingUssd: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CANCEL_USSD);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getClir(int32_t serial) {
+#if VDBG
+ RLOGD("getClir: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_CLIR);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setClir(int32_t serial, int32_t status) {
+#if VDBG
+ RLOGD("setClir: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_CLIR, 1, status);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCallForwardStatus(int32_t serial, const CallForwardInfo& callInfo) {
+#if VDBG
+ RLOGD("getCallForwardStatus: serial %d", serial);
+#endif
+ dispatchCallForwardStatus(serial, mSlotId, RIL_REQUEST_QUERY_CALL_FORWARD_STATUS,
+ callInfo);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCallForward(int32_t serial, const CallForwardInfo& callInfo) {
+#if VDBG
+ RLOGD("setCallForward: serial %d", serial);
+#endif
+ dispatchCallForwardStatus(serial, mSlotId, RIL_REQUEST_SET_CALL_FORWARD,
+ callInfo);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCallWaiting(int32_t serial, int32_t serviceClass) {
+#if VDBG
+ RLOGD("getCallWaiting: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_QUERY_CALL_WAITING, 1, serviceClass);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCallWaiting(int32_t serial, bool enable, int32_t serviceClass) {
+#if VDBG
+ RLOGD("setCallWaiting: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_CALL_WAITING, 2, BOOL_TO_INT(enable),
+ serviceClass);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::acknowledgeLastIncomingGsmSms(int32_t serial,
+ bool success, SmsAcknowledgeFailCause cause) {
+#if VDBG
+ RLOGD("acknowledgeLastIncomingGsmSms: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SMS_ACKNOWLEDGE, 2, BOOL_TO_INT(success),
+ cause);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::acceptCall(int32_t serial) {
+#if VDBG
+ RLOGD("acceptCall: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_ANSWER);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::deactivateDataCall(int32_t serial,
+ int32_t cid, bool reasonRadioShutDown) {
+#if VDBG
+ RLOGD("deactivateDataCall: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_DEACTIVATE_DATA_CALL, false,
+ 2, (std::to_string(cid)).c_str(), reasonRadioShutDown ? "1" : "0");
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getFacilityLockForApp(int32_t serial, const hidl_string& facility,
+ const hidl_string& password, int32_t serviceClass,
+ const hidl_string& appId) {
+#if VDBG
+ RLOGD("getFacilityLockForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_QUERY_FACILITY_LOCK, true,
+ 4, facility.c_str(), password.c_str(),
+ (std::to_string(serviceClass)).c_str(), appId.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setFacilityLockForApp(int32_t serial, const hidl_string& facility,
+ bool lockState, const hidl_string& password,
+ int32_t serviceClass, const hidl_string& appId) {
+#if VDBG
+ RLOGD("setFacilityLockForApp: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SET_FACILITY_LOCK, true,
+ 5, facility.c_str(), lockState ? "1" : "0", password.c_str(),
+ (std::to_string(serviceClass)).c_str(), appId.c_str() );
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setBarringPassword(int32_t serial, const hidl_string& facility,
+ const hidl_string& oldPassword,
+ const hidl_string& newPassword) {
+#if VDBG
+ RLOGD("setBarringPassword: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_CHANGE_BARRING_PASSWORD, true,
+ 3, facility.c_str(), oldPassword.c_str(), newPassword.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getNetworkSelectionMode(int32_t serial) {
+#if VDBG
+ RLOGD("getNetworkSelectionMode: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_QUERY_NETWORK_SELECTION_MODE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setNetworkSelectionModeAutomatic(int32_t serial) {
+#if VDBG
+ RLOGD("setNetworkSelectionModeAutomatic: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_SET_NETWORK_SELECTION_AUTOMATIC);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setNetworkSelectionModeManual(int32_t serial,
+ const hidl_string& operatorNumeric) {
+#if VDBG
+ RLOGD("setNetworkSelectionModeManual: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_SET_NETWORK_SELECTION_MANUAL,
+ operatorNumeric.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getAvailableNetworks(int32_t serial) {
+#if VDBG
+ RLOGD("getAvailableNetworks: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_QUERY_AVAILABLE_NETWORKS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::startNetworkScan(int32_t serial, const V1_1::NetworkScanRequest& request) {
+#if VDBG
+ RLOGD("startNetworkScan: serial %d", serial);
+#endif
+
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_START_NETWORK_SCAN);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ if (request.specifiers.size() > MAX_RADIO_ACCESS_NETWORKS) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+
+ RIL_NetworkScanRequest scan_request = {};
+
+ scan_request.type = (RIL_ScanType) request.type;
+ scan_request.interval = request.interval;
+ scan_request.specifiers_length = request.specifiers.size();
+ for (size_t i = 0; i < request.specifiers.size(); ++i) {
+ if (request.specifiers[i].geranBands.size() > MAX_BANDS ||
+ request.specifiers[i].utranBands.size() > MAX_BANDS ||
+ request.specifiers[i].eutranBands.size() > MAX_BANDS ||
+ request.specifiers[i].channels.size() > MAX_CHANNELS) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+ const V1_1::RadioAccessSpecifier& ras_from =
+ request.specifiers[i];
+ RIL_RadioAccessSpecifier& ras_to = scan_request.specifiers[i];
+
+ ras_to.radio_access_network = (RIL_RadioAccessNetworks) ras_from.radioAccessNetwork;
+ ras_to.channels_length = ras_from.channels.size();
+
+ std::copy(ras_from.channels.begin(), ras_from.channels.end(), ras_to.channels);
+ const std::vector<uint32_t> * bands = nullptr;
+ switch (request.specifiers[i].radioAccessNetwork) {
+ case V1_1::RadioAccessNetworks::GERAN:
+ ras_to.bands_length = ras_from.geranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.geranBands;
+ break;
+ case V1_1::RadioAccessNetworks::UTRAN:
+ ras_to.bands_length = ras_from.utranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.utranBands;
+ break;
+ case V1_1::RadioAccessNetworks::EUTRAN:
+ ras_to.bands_length = ras_from.eutranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.eutranBands;
+ break;
+ default:
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+ // safe to copy to geran_bands because it's a union member
+ for (size_t idx = 0; idx < ras_to.bands_length; ++idx) {
+ ras_to.bands.geran_bands[idx] = (RIL_GeranBands) (*bands)[idx];
+ }
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_START_NETWORK_SCAN, &scan_request, sizeof(scan_request), pRI,
+ mSlotId);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::stopNetworkScan(int32_t serial) {
+#if VDBG
+ RLOGD("stopNetworkScan: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_STOP_NETWORK_SCAN);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::startDtmf(int32_t serial, const hidl_string& s) {
+#if VDBG
+ RLOGD("startDtmf: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_DTMF_START,
+ s.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::stopDtmf(int32_t serial) {
+#if VDBG
+ RLOGD("stopDtmf: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_DTMF_STOP);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getBasebandVersion(int32_t serial) {
+#if VDBG
+ RLOGD("getBasebandVersion: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_BASEBAND_VERSION);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::separateConnection(int32_t serial, int32_t gsmIndex) {
+#if VDBG
+ RLOGD("separateConnection: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SEPARATE_CONNECTION, 1, gsmIndex);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setMute(int32_t serial, bool enable) {
+#if VDBG
+ RLOGD("setMute: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_MUTE, 1, BOOL_TO_INT(enable));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getMute(int32_t serial) {
+#if VDBG
+ RLOGD("getMute: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_MUTE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getClip(int32_t serial) {
+#if VDBG
+ RLOGD("getClip: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_QUERY_CLIP);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getDataCallList(int32_t serial) {
+#if VDBG
+ RLOGD("getDataCallList: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_DATA_CALL_LIST);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setSuppServiceNotifications(int32_t serial, bool enable) {
+#if VDBG
+ RLOGD("setSuppServiceNotifications: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_SUPP_SVC_NOTIFICATION, 1,
+ BOOL_TO_INT(enable));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::writeSmsToSim(int32_t serial, const SmsWriteArgs& smsWriteArgs) {
+#if VDBG
+ RLOGD("writeSmsToSim: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_WRITE_SMS_TO_SIM);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_SMS_WriteArgs args;
+ args.status = (int) smsWriteArgs.status;
+
+ if (!copyHidlStringToRil(&args.pdu, smsWriteArgs.pdu, pRI)) {
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&args.smsc, smsWriteArgs.smsc, pRI)) {
+ memsetAndFreeStrings(1, args.pdu);
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_WRITE_SMS_TO_SIM, &args, sizeof(args), pRI, mSlotId);
+
+ memsetAndFreeStrings(2, args.smsc, args.pdu);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::deleteSmsOnSim(int32_t serial, int32_t index) {
+#if VDBG
+ RLOGD("deleteSmsOnSim: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_DELETE_SMS_ON_SIM, 1, index);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setBandMode(int32_t serial, RadioBandMode mode) {
+#if VDBG
+ RLOGD("setBandMode: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_BAND_MODE, 1, mode);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getAvailableBandModes(int32_t serial) {
+#if VDBG
+ RLOGD("getAvailableBandModes: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_QUERY_AVAILABLE_BAND_MODE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendEnvelope(int32_t serial, const hidl_string& command) {
+#if VDBG
+ RLOGD("sendEnvelope: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_STK_SEND_ENVELOPE_COMMAND,
+ command.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendTerminalResponseToSim(int32_t serial,
+ const hidl_string& commandResponse) {
+#if VDBG
+ RLOGD("sendTerminalResponseToSim: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_STK_SEND_TERMINAL_RESPONSE,
+ commandResponse.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::handleStkCallSetupRequestFromSim(int32_t serial, bool accept) {
+#if VDBG
+ RLOGD("handleStkCallSetupRequestFromSim: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_STK_HANDLE_CALL_SETUP_REQUESTED_FROM_SIM,
+ 1, BOOL_TO_INT(accept));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::explicitCallTransfer(int32_t serial) {
+#if VDBG
+ RLOGD("explicitCallTransfer: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_EXPLICIT_CALL_TRANSFER);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setPreferredNetworkType(int32_t serial, PreferredNetworkType nwType) {
+#if VDBG
+ RLOGD("setPreferredNetworkType: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_PREFERRED_NETWORK_TYPE, 1, nwType);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getPreferredNetworkType(int32_t serial) {
+#if VDBG
+ RLOGD("getPreferredNetworkType: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_PREFERRED_NETWORK_TYPE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getNeighboringCids(int32_t serial) {
+#if VDBG
+ RLOGD("getNeighboringCids: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_NEIGHBORING_CELL_IDS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setLocationUpdates(int32_t serial, bool enable) {
+#if VDBG
+ RLOGD("setLocationUpdates: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_LOCATION_UPDATES, 1, BOOL_TO_INT(enable));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCdmaSubscriptionSource(int32_t serial, CdmaSubscriptionSource cdmaSub) {
+#if VDBG
+ RLOGD("setCdmaSubscriptionSource: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_CDMA_SET_SUBSCRIPTION_SOURCE, 1, cdmaSub);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCdmaRoamingPreference(int32_t serial, CdmaRoamingType type) {
+#if VDBG
+ RLOGD("setCdmaRoamingPreference: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_CDMA_SET_ROAMING_PREFERENCE, 1, type);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCdmaRoamingPreference(int32_t serial) {
+#if VDBG
+ RLOGD("getCdmaRoamingPreference: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CDMA_QUERY_ROAMING_PREFERENCE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setTTYMode(int32_t serial, TtyMode mode) {
+#if VDBG
+ RLOGD("setTTYMode: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_TTY_MODE, 1, mode);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getTTYMode(int32_t serial) {
+#if VDBG
+ RLOGD("getTTYMode: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_QUERY_TTY_MODE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setPreferredVoicePrivacy(int32_t serial, bool enable) {
+#if VDBG
+ RLOGD("setPreferredVoicePrivacy: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_CDMA_SET_PREFERRED_VOICE_PRIVACY_MODE,
+ 1, BOOL_TO_INT(enable));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getPreferredVoicePrivacy(int32_t serial) {
+#if VDBG
+ RLOGD("getPreferredVoicePrivacy: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CDMA_QUERY_PREFERRED_VOICE_PRIVACY_MODE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendCDMAFeatureCode(int32_t serial, const hidl_string& featureCode) {
+#if VDBG
+ RLOGD("sendCDMAFeatureCode: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_CDMA_FLASH,
+ featureCode.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendBurstDtmf(int32_t serial, const hidl_string& dtmf, int32_t on,
+ int32_t off) {
+#if VDBG
+ RLOGD("sendBurstDtmf: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_CDMA_BURST_DTMF, false,
+ 3, dtmf.c_str(), (std::to_string(on)).c_str(),
+ (std::to_string(off)).c_str());
+ return Void();
+}
+
+void constructCdmaSms(RIL_CDMA_SMS_Message &rcsm, const CdmaSmsMessage& sms) {
+ rcsm.uTeleserviceID = sms.teleserviceId;
+ rcsm.bIsServicePresent = BOOL_TO_INT(sms.isServicePresent);
+ rcsm.uServicecategory = sms.serviceCategory;
+ rcsm.sAddress.digit_mode = (RIL_CDMA_SMS_DigitMode) sms.address.digitMode;
+ rcsm.sAddress.number_mode = (RIL_CDMA_SMS_NumberMode) sms.address.numberMode;
+ rcsm.sAddress.number_type = (RIL_CDMA_SMS_NumberType) sms.address.numberType;
+ rcsm.sAddress.number_plan = (RIL_CDMA_SMS_NumberPlan) sms.address.numberPlan;
+
+ rcsm.sAddress.number_of_digits = sms.address.digits.size();
+ int digitLimit= MIN((rcsm.sAddress.number_of_digits), RIL_CDMA_SMS_ADDRESS_MAX);
+ for (int i = 0; i < digitLimit; i++) {
+ rcsm.sAddress.digits[i] = sms.address.digits[i];
+ }
+
+ rcsm.sSubAddress.subaddressType = (RIL_CDMA_SMS_SubaddressType) sms.subAddress.subaddressType;
+ rcsm.sSubAddress.odd = BOOL_TO_INT(sms.subAddress.odd);
+
+ rcsm.sSubAddress.number_of_digits = sms.subAddress.digits.size();
+ digitLimit= MIN((rcsm.sSubAddress.number_of_digits), RIL_CDMA_SMS_SUBADDRESS_MAX);
+ for (int i = 0; i < digitLimit; i++) {
+ rcsm.sSubAddress.digits[i] = sms.subAddress.digits[i];
+ }
+
+ rcsm.uBearerDataLen = sms.bearerData.size();
+ digitLimit= MIN((rcsm.uBearerDataLen), RIL_CDMA_SMS_BEARER_DATA_MAX);
+ for (int i = 0; i < digitLimit; i++) {
+ rcsm.aBearerData[i] = sms.bearerData[i];
+ }
+}
+
+Return<void> RadioImpl_1_4::sendCdmaSms(int32_t serial, const CdmaSmsMessage& sms) {
+#if VDBG
+ RLOGD("sendCdmaSms: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_CDMA_SEND_SMS);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_CDMA_SMS_Message rcsm = {};
+ constructCdmaSms(rcsm, sms);
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rcsm, sizeof(rcsm), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::acknowledgeLastIncomingCdmaSms(int32_t serial, const CdmaSmsAck& smsAck) {
+#if VDBG
+ RLOGD("acknowledgeLastIncomingCdmaSms: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_CDMA_SMS_ACKNOWLEDGE);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_CDMA_SMS_Ack rcsa = {};
+
+ rcsa.uErrorClass = (RIL_CDMA_SMS_ErrorClass) smsAck.errorClass;
+ rcsa.uSMSCauseCode = smsAck.smsCauseCode;
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rcsa, sizeof(rcsa), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getGsmBroadcastConfig(int32_t serial) {
+#if VDBG
+ RLOGD("getGsmBroadcastConfig: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GSM_GET_BROADCAST_SMS_CONFIG);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setGsmBroadcastConfig(int32_t serial,
+ const hidl_vec<GsmBroadcastSmsConfigInfo>&
+ configInfo) {
+#if VDBG
+ RLOGD("setGsmBroadcastConfig: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_GSM_SET_BROADCAST_SMS_CONFIG);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ int num = configInfo.size();
+ RIL_GSM_BroadcastSmsConfigInfo gsmBci[num];
+ RIL_GSM_BroadcastSmsConfigInfo *gsmBciPtrs[num];
+
+ for (int i = 0 ; i < num ; i++ ) {
+ gsmBciPtrs[i] = &gsmBci[i];
+ gsmBci[i].fromServiceId = configInfo[i].fromServiceId;
+ gsmBci[i].toServiceId = configInfo[i].toServiceId;
+ gsmBci[i].fromCodeScheme = configInfo[i].fromCodeScheme;
+ gsmBci[i].toCodeScheme = configInfo[i].toCodeScheme;
+ gsmBci[i].selected = BOOL_TO_INT(configInfo[i].selected);
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, gsmBciPtrs,
+ num * sizeof(RIL_GSM_BroadcastSmsConfigInfo *), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setGsmBroadcastActivation(int32_t serial, bool activate) {
+#if VDBG
+ RLOGD("setGsmBroadcastActivation: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_GSM_SMS_BROADCAST_ACTIVATION,
+ 1, BOOL_TO_INT(!activate));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCdmaBroadcastConfig(int32_t serial) {
+#if VDBG
+ RLOGD("getCdmaBroadcastConfig: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CDMA_GET_BROADCAST_SMS_CONFIG);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCdmaBroadcastConfig(int32_t serial,
+ const hidl_vec<CdmaBroadcastSmsConfigInfo>&
+ configInfo) {
+#if VDBG
+ RLOGD("setCdmaBroadcastConfig: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_CDMA_SET_BROADCAST_SMS_CONFIG);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ int num = configInfo.size();
+ RIL_CDMA_BroadcastSmsConfigInfo cdmaBci[num];
+ RIL_CDMA_BroadcastSmsConfigInfo *cdmaBciPtrs[num];
+
+ for (int i = 0 ; i < num ; i++ ) {
+ cdmaBciPtrs[i] = &cdmaBci[i];
+ cdmaBci[i].service_category = configInfo[i].serviceCategory;
+ cdmaBci[i].language = configInfo[i].language;
+ cdmaBci[i].selected = BOOL_TO_INT(configInfo[i].selected);
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, cdmaBciPtrs,
+ num * sizeof(RIL_CDMA_BroadcastSmsConfigInfo *), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCdmaBroadcastActivation(int32_t serial, bool activate) {
+#if VDBG
+ RLOGD("setCdmaBroadcastActivation: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_CDMA_SMS_BROADCAST_ACTIVATION,
+ 1, BOOL_TO_INT(!activate));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCDMASubscription(int32_t serial) {
+#if VDBG
+ RLOGD("getCDMASubscription: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CDMA_SUBSCRIPTION);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::writeSmsToRuim(int32_t serial, const CdmaSmsWriteArgs& cdmaSms) {
+#if VDBG
+ RLOGD("writeSmsToRuim: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_CDMA_WRITE_SMS_TO_RUIM);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_CDMA_SMS_WriteArgs rcsw = {};
+ rcsw.status = (int) cdmaSms.status;
+ constructCdmaSms(rcsw.message, cdmaSms.message);
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rcsw, sizeof(rcsw), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::deleteSmsOnRuim(int32_t serial, int32_t index) {
+#if VDBG
+ RLOGD("deleteSmsOnRuim: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_CDMA_DELETE_SMS_ON_RUIM, 1, index);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getDeviceIdentity(int32_t serial) {
+#if VDBG
+ RLOGD("getDeviceIdentity: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_DEVICE_IDENTITY);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::exitEmergencyCallbackMode(int32_t serial) {
+#if VDBG
+ RLOGD("exitEmergencyCallbackMode: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_EXIT_EMERGENCY_CALLBACK_MODE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getSmscAddress(int32_t serial) {
+#if VDBG
+ RLOGD("getSmscAddress: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_SMSC_ADDRESS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setSmscAddress(int32_t serial, const hidl_string& smsc) {
+#if VDBG
+ RLOGD("setSmscAddress: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_SET_SMSC_ADDRESS,
+ smsc.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::reportSmsMemoryStatus(int32_t serial, bool available) {
+#if VDBG
+ RLOGD("reportSmsMemoryStatus: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_REPORT_SMS_MEMORY_STATUS, 1,
+ BOOL_TO_INT(available));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::reportStkServiceIsRunning(int32_t serial) {
+#if VDBG
+ RLOGD("reportStkServiceIsRunning: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCdmaSubscriptionSource(int32_t serial) {
+#if VDBG
+ RLOGD("getCdmaSubscriptionSource: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_CDMA_GET_SUBSCRIPTION_SOURCE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::requestIsimAuthentication(int32_t serial, const hidl_string& challenge) {
+#if VDBG
+ RLOGD("requestIsimAuthentication: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_ISIM_AUTHENTICATION,
+ challenge.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::acknowledgeIncomingGsmSmsWithPdu(int32_t serial, bool success,
+ const hidl_string& ackPdu) {
+#if VDBG
+ RLOGD("acknowledgeIncomingGsmSmsWithPdu: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_ACKNOWLEDGE_INCOMING_GSM_SMS_WITH_PDU, false,
+ 2, success ? "1" : "0", ackPdu.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendEnvelopeWithStatus(int32_t serial, const hidl_string& contents) {
+#if VDBG
+ RLOGD("sendEnvelopeWithStatus: serial %d", serial);
+#endif
+ dispatchString(serial, mSlotId, RIL_REQUEST_STK_SEND_ENVELOPE_WITH_STATUS,
+ contents.c_str());
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getVoiceRadioTechnology(int32_t serial) {
+#if VDBG
+ RLOGD("getVoiceRadioTechnology: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_VOICE_RADIO_TECH);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getCellInfoList(int32_t serial) {
+#if VDBG
+ RLOGD("getCellInfoList: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_CELL_INFO_LIST);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCellInfoListRate(int32_t serial, int32_t rate) {
+#if VDBG
+ RLOGD("setCellInfoListRate: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_UNSOL_CELL_INFO_LIST_RATE, 1, rate);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setInitialAttachApn(int32_t serial, const DataProfileInfo& dataProfileInfo,
+ bool modemCognitive, bool isRoaming) {
+#if VDBG
+ RLOGD("setInitialAttachApn: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SET_INITIAL_ATTACH_APN);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ if (s_vendorFunctions->version <= 14) {
+ RIL_InitialAttachApn iaa = {};
+
+ if (!copyHidlStringToRil(&iaa.apn, dataProfileInfo.apn, pRI, true)) {
+ return Void();
+ }
+
+ const hidl_string &protocol =
+ (isRoaming ? dataProfileInfo.roamingProtocol : dataProfileInfo.protocol);
+
+ if (!copyHidlStringToRil(&iaa.protocol, protocol, pRI)) {
+ memsetAndFreeStrings(1, iaa.apn);
+ return Void();
+ }
+ iaa.authtype = (int) dataProfileInfo.authType;
+ if (!copyHidlStringToRil(&iaa.username, dataProfileInfo.user, pRI)) {
+ memsetAndFreeStrings(2, iaa.apn, iaa.protocol);
+ return Void();
+ }
+ if (!copyHidlStringToRil(&iaa.password, dataProfileInfo.password, pRI)) {
+ memsetAndFreeStrings(3, iaa.apn, iaa.protocol, iaa.username);
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_SET_INITIAL_ATTACH_APN, &iaa, sizeof(iaa), pRI, mSlotId);
+
+ memsetAndFreeStrings(4, iaa.apn, iaa.protocol, iaa.username, iaa.password);
+ } else {
+ RIL_InitialAttachApn_v15 iaa = {};
+
+ if (!copyHidlStringToRil(&iaa.apn, dataProfileInfo.apn, pRI, true)) {
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&iaa.protocol, dataProfileInfo.protocol, pRI)) {
+ memsetAndFreeStrings(1, iaa.apn);
+ return Void();
+ }
+ if (!copyHidlStringToRil(&iaa.roamingProtocol, dataProfileInfo.roamingProtocol, pRI)) {
+ memsetAndFreeStrings(2, iaa.apn, iaa.protocol);
+ return Void();
+ }
+ iaa.authtype = (int) dataProfileInfo.authType;
+ if (!copyHidlStringToRil(&iaa.username, dataProfileInfo.user, pRI)) {
+ memsetAndFreeStrings(3, iaa.apn, iaa.protocol, iaa.roamingProtocol);
+ return Void();
+ }
+ if (!copyHidlStringToRil(&iaa.password, dataProfileInfo.password, pRI)) {
+ memsetAndFreeStrings(4, iaa.apn, iaa.protocol, iaa.roamingProtocol, iaa.username);
+ return Void();
+ }
+ iaa.supportedTypesBitmask = dataProfileInfo.supportedApnTypesBitmap;
+ iaa.bearerBitmask = dataProfileInfo.bearerBitmap;
+ iaa.modemCognitive = BOOL_TO_INT(modemCognitive);
+ iaa.mtu = dataProfileInfo.mtu;
+
+ if (!convertMvnoTypeToString(dataProfileInfo.mvnoType, iaa.mvnoType)) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ memsetAndFreeStrings(5, iaa.apn, iaa.protocol, iaa.roamingProtocol, iaa.username,
+ iaa.password);
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&iaa.mvnoMatchData, dataProfileInfo.mvnoMatchData, pRI)) {
+ memsetAndFreeStrings(5, iaa.apn, iaa.protocol, iaa.roamingProtocol, iaa.username,
+ iaa.password);
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_SET_INITIAL_ATTACH_APN, &iaa, sizeof(iaa), pRI, mSlotId);
+
+ memsetAndFreeStrings(6, iaa.apn, iaa.protocol, iaa.roamingProtocol, iaa.username,
+ iaa.password, iaa.mvnoMatchData);
+ }
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getImsRegistrationState(int32_t serial) {
+#if VDBG
+ RLOGD("getImsRegistrationState: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_IMS_REGISTRATION_STATE);
+ return Void();
+}
+
+bool dispatchImsGsmSms(const ImsSmsMessage& message, RequestInfo *pRI) {
+ RIL_IMS_SMS_Message rism = {};
+ char **pStrings;
+ int countStrings = 2;
+ int dataLen = sizeof(char *) * countStrings;
+
+ rism.tech = RADIO_TECH_3GPP;
+ rism.retry = BOOL_TO_INT(message.retry);
+ rism.messageRef = message.messageRef;
+
+ if (message.gsmMessage.size() != 1) {
+ RLOGE("dispatchImsGsmSms: Invalid len %s", requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return false;
+ }
+
+ pStrings = (char **)calloc(countStrings, sizeof(char *));
+ if (pStrings == NULL) {
+ RLOGE("dispatchImsGsmSms: Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return false;
+ }
+
+ if (!copyHidlStringToRil(&pStrings[0], message.gsmMessage[0].smscPdu, pRI)) {
+#ifdef MEMSET_FREED
+ memset(pStrings, 0, dataLen);
+#endif
+ free(pStrings);
+ return false;
+ }
+
+ if (!copyHidlStringToRil(&pStrings[1], message.gsmMessage[0].pdu, pRI)) {
+ memsetAndFreeStrings(1, pStrings[0]);
+#ifdef MEMSET_FREED
+ memset(pStrings, 0, dataLen);
+#endif
+ free(pStrings);
+ return false;
+ }
+
+ rism.message.gsmMessage = pStrings;
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rism, sizeof(RIL_RadioTechnologyFamily) +
+ sizeof(uint8_t) + sizeof(int32_t) + dataLen, pRI, pRI->socket_id);
+
+ for (int i = 0 ; i < countStrings ; i++) {
+ memsetAndFreeStrings(1, pStrings[i]);
+ }
+
+#ifdef MEMSET_FREED
+ memset(pStrings, 0, dataLen);
+#endif
+ free(pStrings);
+
+ return true;
+}
+
+struct ImsCdmaSms {
+ RIL_IMS_SMS_Message imsSms;
+ RIL_CDMA_SMS_Message cdmaSms;
+};
+
+bool dispatchImsCdmaSms(const ImsSmsMessage& message, RequestInfo *pRI) {
+ ImsCdmaSms temp = {};
+
+ if (message.cdmaMessage.size() != 1) {
+ RLOGE("dispatchImsCdmaSms: Invalid len %s", requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return false;
+ }
+
+ temp.imsSms.tech = RADIO_TECH_3GPP2;
+ temp.imsSms.retry = BOOL_TO_INT(message.retry);
+ temp.imsSms.messageRef = message.messageRef;
+ temp.imsSms.message.cdmaMessage = &temp.cdmaSms;
+
+ constructCdmaSms(temp.cdmaSms, message.cdmaMessage[0]);
+
+ // Vendor code expects payload length to include actual msg payload
+ // (sizeof(RIL_CDMA_SMS_Message)) instead of (RIL_CDMA_SMS_Message *) + size of other fields in
+ // RIL_IMS_SMS_Message
+ int payloadLen = sizeof(RIL_RadioTechnologyFamily) + sizeof(uint8_t) + sizeof(int32_t)
+ + sizeof(RIL_CDMA_SMS_Message);
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &temp.imsSms, payloadLen, pRI, pRI->socket_id);
+
+ return true;
+}
+
+Return<void> RadioImpl_1_4::sendImsSms(int32_t serial, const ImsSmsMessage& message) {
+#if VDBG
+ RLOGD("sendImsSms: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_IMS_SEND_SMS);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_RadioTechnologyFamily format = (RIL_RadioTechnologyFamily) message.tech;
+
+ if (RADIO_TECH_3GPP == format) {
+ dispatchImsGsmSms(message, pRI);
+ } else if (RADIO_TECH_3GPP2 == format) {
+ dispatchImsCdmaSms(message, pRI);
+ } else {
+ RLOGE("sendImsSms: Invalid radio tech %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ }
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::iccTransmitApduBasicChannel(int32_t serial, const SimApdu& message) {
+#if VDBG
+ RLOGD("iccTransmitApduBasicChannel: serial %d", serial);
+#endif
+ dispatchIccApdu(serial, mSlotId, RIL_REQUEST_SIM_TRANSMIT_APDU_BASIC, message);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::iccOpenLogicalChannel(int32_t serial, const hidl_string& aid, int32_t p2) {
+#if VDBG
+ RLOGD("iccOpenLogicalChannel: serial %d", serial);
+#endif
+ if (s_vendorFunctions->version < 15) {
+ dispatchString(serial, mSlotId, RIL_REQUEST_SIM_OPEN_CHANNEL, aid.c_str());
+ } else {
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_SIM_OPEN_CHANNEL);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_OpenChannelParams params = {};
+
+ params.p2 = p2;
+
+ if (!copyHidlStringToRil(¶ms.aidPtr, aid, pRI)) {
+ return Void();
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, ¶ms, sizeof(params), pRI, mSlotId);
+
+ memsetAndFreeStrings(1, params.aidPtr);
+ }
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::iccCloseLogicalChannel(int32_t serial, int32_t channelId) {
+#if VDBG
+ RLOGD("iccCloseLogicalChannel: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SIM_CLOSE_CHANNEL, 1, channelId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::iccTransmitApduLogicalChannel(int32_t serial, const SimApdu& message) {
+#if VDBG
+ RLOGD("iccTransmitApduLogicalChannel: serial %d", serial);
+#endif
+ dispatchIccApdu(serial, mSlotId, RIL_REQUEST_SIM_TRANSMIT_APDU_CHANNEL, message);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::nvReadItem(int32_t serial, NvItem itemId) {
+#if VDBG
+ RLOGD("nvReadItem: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_NV_READ_ITEM);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_NV_ReadItem nvri = {};
+ nvri.itemID = (RIL_NV_Item) itemId;
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &nvri, sizeof(nvri), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::nvWriteItem(int32_t serial, const NvWriteItem& item) {
+#if VDBG
+ RLOGD("nvWriteItem: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_NV_WRITE_ITEM);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_NV_WriteItem nvwi = {};
+
+ nvwi.itemID = (RIL_NV_Item) item.itemId;
+
+ if (!copyHidlStringToRil(&nvwi.value, item.value, pRI)) {
+ return Void();
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &nvwi, sizeof(nvwi), pRI, mSlotId);
+
+ memsetAndFreeStrings(1, nvwi.value);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::nvWriteCdmaPrl(int32_t serial, const hidl_vec<uint8_t>& prl) {
+#if VDBG
+ RLOGD("nvWriteCdmaPrl: serial %d", serial);
+#endif
+ dispatchRaw(serial, mSlotId, RIL_REQUEST_NV_WRITE_CDMA_PRL, prl);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::nvResetConfig(int32_t serial, ResetNvType resetType) {
+ int rilResetType = -1;
+#if VDBG
+ RLOGD("nvResetConfig: serial %d", serial);
+#endif
+ /* Convert ResetNvType to RIL.h values
+ * RIL_REQUEST_NV_RESET_CONFIG
+ * 1 - reload all NV items
+ * 2 - erase NV reset (SCRTN)
+ * 3 - factory reset (RTN)
+ */
+ switch(resetType) {
+ case ResetNvType::RELOAD:
+ rilResetType = 1;
+ break;
+ case ResetNvType::ERASE:
+ rilResetType = 2;
+ break;
+ case ResetNvType::FACTORY_RESET:
+ rilResetType = 3;
+ break;
+ }
+ dispatchInts(serial, mSlotId, RIL_REQUEST_NV_RESET_CONFIG, 1, rilResetType);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setUiccSubscription(int32_t serial, const SelectUiccSub& uiccSub) {
+#if VDBG
+ RLOGD("setUiccSubscription: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SET_UICC_SUBSCRIPTION);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_SelectUiccSub rilUiccSub = {};
+
+ rilUiccSub.slot = uiccSub.slot;
+ rilUiccSub.app_index = uiccSub.appIndex;
+ rilUiccSub.sub_type = (RIL_SubscriptionType) uiccSub.subType;
+ rilUiccSub.act_status = (RIL_UiccSubActStatus) uiccSub.actStatus;
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rilUiccSub, sizeof(rilUiccSub), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setDataAllowed(int32_t serial, bool allow) {
+#if VDBG
+ RLOGD("setDataAllowed: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_ALLOW_DATA, 1, BOOL_TO_INT(allow));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getHardwareConfig(int32_t serial) {
+#if VDBG
+ RLOGD("getHardwareConfig: serial %d", serial);
+#endif
+ RLOGD("getHardwareConfig: serial %d, mSlotId = %d", serial, mSlotId);
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_HARDWARE_CONFIG);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::requestIccSimAuthentication(int32_t serial, int32_t authContext,
+ const hidl_string& authData, const hidl_string& aid) {
+#if VDBG
+ RLOGD("requestIccSimAuthentication: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_SIM_AUTHENTICATION);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_SimAuthentication pf = {};
+
+ pf.authContext = authContext;
+
+ if (!copyHidlStringToRil(&pf.authData, authData, pRI)) {
+ return Void();
+ }
+
+ if (!copyHidlStringToRil(&pf.aid, aid, pRI)) {
+ memsetAndFreeStrings(1, pf.authData);
+ return Void();
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &pf, sizeof(pf), pRI, mSlotId);
+
+ memsetAndFreeStrings(2, pf.authData, pf.aid);
+ return Void();
+}
+
+/**
+ * @param numProfiles number of data profile
+ * @param dataProfiles the pointer to the actual data profiles. The acceptable type is
+ RIL_DataProfileInfo or RIL_DataProfileInfo_v15.
+ * @param dataProfilePtrs the pointer to the pointers that point to each data profile structure
+ * @param numfields number of string-type member in the data profile structure
+ * @param ... the variadic parameters are pointers to each string-type member
+ **/
+template <typename T>
+void freeSetDataProfileData(int numProfiles, T *dataProfiles, T **dataProfilePtrs,
+ int numfields, ...) {
+ va_list args;
+ va_start(args, numfields);
+
+ // Iterate through each string-type field that need to be free.
+ for (int i = 0; i < numfields; i++) {
+ // Iterate through each data profile and free that specific string-type field.
+ // The type 'char *T::*' is a type of pointer to a 'char *' member inside T structure.
+ char *T::*ptr = va_arg(args, char *T::*);
+ for (int j = 0; j < numProfiles; j++) {
+ memsetAndFreeStrings(1, dataProfiles[j].*ptr);
+ }
+ }
+
+ va_end(args);
+
+#ifdef MEMSET_FREED
+ memset(dataProfiles, 0, numProfiles * sizeof(T));
+ memset(dataProfilePtrs, 0, numProfiles * sizeof(T *));
+#endif
+ free(dataProfiles);
+ free(dataProfilePtrs);
+}
+
+Return<void> RadioImpl_1_4::setDataProfile(int32_t serial, const hidl_vec<DataProfileInfo>& profiles,
+ bool isRoaming) {
+#if VDBG
+ RLOGD("setDataProfile: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_SET_DATA_PROFILE);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ size_t num = profiles.size();
+ bool success = false;
+
+ if (s_vendorFunctions->version <= 14) {
+
+ RIL_DataProfileInfo *dataProfiles =
+ (RIL_DataProfileInfo *) calloc(num, sizeof(RIL_DataProfileInfo));
+
+ if (dataProfiles == NULL) {
+ RLOGE("Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return Void();
+ }
+
+ RIL_DataProfileInfo **dataProfilePtrs =
+ (RIL_DataProfileInfo **) calloc(num, sizeof(RIL_DataProfileInfo *));
+ if (dataProfilePtrs == NULL) {
+ RLOGE("Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ free(dataProfiles);
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return Void();
+ }
+
+ for (size_t i = 0; i < num; i++) {
+ dataProfilePtrs[i] = &dataProfiles[i];
+
+ success = copyHidlStringToRil(&dataProfiles[i].apn, profiles[i].apn, pRI, true);
+
+ const hidl_string &protocol =
+ (isRoaming ? profiles[i].roamingProtocol : profiles[i].protocol);
+
+ if (success && !copyHidlStringToRil(&dataProfiles[i].protocol, protocol, pRI, true)) {
+ success = false;
+ }
+
+ if (success && !copyHidlStringToRil(&dataProfiles[i].user, profiles[i].user, pRI,
+ true)) {
+ success = false;
+ }
+ if (success && !copyHidlStringToRil(&dataProfiles[i].password, profiles[i].password,
+ pRI, true)) {
+ success = false;
+ }
+
+ if (!success) {
+ freeSetDataProfileData(num, dataProfiles, dataProfilePtrs, 4,
+ &RIL_DataProfileInfo::apn, &RIL_DataProfileInfo::protocol,
+ &RIL_DataProfileInfo::user, &RIL_DataProfileInfo::password);
+ return Void();
+ }
+
+ dataProfiles[i].profileId = (RIL_DataProfile) profiles[i].profileId;
+ dataProfiles[i].authType = (int) profiles[i].authType;
+ dataProfiles[i].type = (int) profiles[i].type;
+ dataProfiles[i].maxConnsTime = profiles[i].maxConnsTime;
+ dataProfiles[i].maxConns = profiles[i].maxConns;
+ dataProfiles[i].waitTime = profiles[i].waitTime;
+ dataProfiles[i].enabled = BOOL_TO_INT(profiles[i].enabled);
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_SET_DATA_PROFILE, dataProfilePtrs,
+ num * sizeof(RIL_DataProfileInfo *), pRI, mSlotId);
+
+ freeSetDataProfileData(num, dataProfiles, dataProfilePtrs, 4,
+ &RIL_DataProfileInfo::apn, &RIL_DataProfileInfo::protocol,
+ &RIL_DataProfileInfo::user, &RIL_DataProfileInfo::password);
+ } else {
+ RIL_DataProfileInfo_v15 *dataProfiles =
+ (RIL_DataProfileInfo_v15 *) calloc(num, sizeof(RIL_DataProfileInfo_v15));
+
+ if (dataProfiles == NULL) {
+ RLOGE("Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return Void();
+ }
+
+ RIL_DataProfileInfo_v15 **dataProfilePtrs =
+ (RIL_DataProfileInfo_v15 **) calloc(num, sizeof(RIL_DataProfileInfo_v15 *));
+ if (dataProfilePtrs == NULL) {
+ RLOGE("Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ free(dataProfiles);
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return Void();
+ }
+
+ for (size_t i = 0; i < num; i++) {
+ dataProfilePtrs[i] = &dataProfiles[i];
+
+ success = copyHidlStringToRil(&dataProfiles[i].apn, profiles[i].apn, pRI, true);
+ if (success && !copyHidlStringToRil(&dataProfiles[i].protocol, profiles[i].protocol,
+ pRI)) {
+ success = false;
+ }
+ if (success && !copyHidlStringToRil(&dataProfiles[i].roamingProtocol,
+ profiles[i].roamingProtocol, pRI, true)) {
+ success = false;
+ }
+ if (success && !copyHidlStringToRil(&dataProfiles[i].user, profiles[i].user, pRI,
+ true)) {
+ success = false;
+ }
+ if (success && !copyHidlStringToRil(&dataProfiles[i].password, profiles[i].password,
+ pRI, true)) {
+ success = false;
+ }
+ if (success && !copyHidlStringToRil(&dataProfiles[i].mvnoMatchData,
+ profiles[i].mvnoMatchData, pRI, true)) {
+ success = false;
+ }
+
+ if (success && !convertMvnoTypeToString(profiles[i].mvnoType,
+ dataProfiles[i].mvnoType)) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ success = false;
+ }
+
+ if (!success) {
+ freeSetDataProfileData(num, dataProfiles, dataProfilePtrs, 6,
+ &RIL_DataProfileInfo_v15::apn, &RIL_DataProfileInfo_v15::protocol,
+ &RIL_DataProfileInfo_v15::roamingProtocol, &RIL_DataProfileInfo_v15::user,
+ &RIL_DataProfileInfo_v15::password, &RIL_DataProfileInfo_v15::mvnoMatchData);
+ return Void();
+ }
+
+ dataProfiles[i].profileId = (RIL_DataProfile) profiles[i].profileId;
+ dataProfiles[i].authType = (int) profiles[i].authType;
+ dataProfiles[i].type = (int) profiles[i].type;
+ dataProfiles[i].maxConnsTime = profiles[i].maxConnsTime;
+ dataProfiles[i].maxConns = profiles[i].maxConns;
+ dataProfiles[i].waitTime = profiles[i].waitTime;
+ dataProfiles[i].enabled = BOOL_TO_INT(profiles[i].enabled);
+ dataProfiles[i].supportedTypesBitmask = profiles[i].supportedApnTypesBitmap;
+ dataProfiles[i].bearerBitmask = profiles[i].bearerBitmap;
+ dataProfiles[i].mtu = profiles[i].mtu;
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_SET_DATA_PROFILE, dataProfilePtrs,
+ num * sizeof(RIL_DataProfileInfo_v15 *), pRI, mSlotId);
+
+ freeSetDataProfileData(num, dataProfiles, dataProfilePtrs, 6,
+ &RIL_DataProfileInfo_v15::apn, &RIL_DataProfileInfo_v15::protocol,
+ &RIL_DataProfileInfo_v15::roamingProtocol, &RIL_DataProfileInfo_v15::user,
+ &RIL_DataProfileInfo_v15::password, &RIL_DataProfileInfo_v15::mvnoMatchData);
+ }
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::requestShutdown(int32_t serial) {
+#if VDBG
+ RLOGD("requestShutdown: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_SHUTDOWN);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getRadioCapability(int32_t serial) {
+#if VDBG
+ RLOGD("getRadioCapability: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_RADIO_CAPABILITY);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setRadioCapability(int32_t serial, const RadioCapability& rc) {
+#if VDBG
+ RLOGD("setRadioCapability: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_SET_RADIO_CAPABILITY);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_RadioCapability rilRc = {};
+
+ // TODO : set rilRc.version using HIDL version ?
+ rilRc.session = rc.session;
+ rilRc.phase = (int) rc.phase;
+ rilRc.rat = (int) rc.raf;
+ rilRc.status = (int) rc.status;
+ strlcpy(rilRc.logicalModemUuid, rc.logicalModemUuid.c_str(), sizeof(rilRc.logicalModemUuid));
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &rilRc, sizeof(rilRc), pRI, mSlotId);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::startLceService(int32_t serial, int32_t reportInterval, bool pullMode) {
+#if VDBG
+ RLOGD("startLceService: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_START_LCE, 2, reportInterval,
+ BOOL_TO_INT(pullMode));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::stopLceService(int32_t serial) {
+#if VDBG
+ RLOGD("stopLceService: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_STOP_LCE);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::pullLceData(int32_t serial) {
+#if VDBG
+ RLOGD("pullLceData: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_PULL_LCEDATA);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getModemActivityInfo(int32_t serial) {
+#if VDBG
+ RLOGD("getModemActivityInfo: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_ACTIVITY_INFO);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setAllowedCarriers(int32_t serial, bool allAllowed,
+ const CarrierRestrictions& carriers) {
+#if VDBG
+ RLOGD("setAllowedCarriers: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SET_CARRIER_RESTRICTIONS);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_CarrierRestrictions cr = {};
+ RIL_Carrier *allowedCarriers = NULL;
+ RIL_Carrier *excludedCarriers = NULL;
+
+ cr.len_allowed_carriers = carriers.allowedCarriers.size();
+ allowedCarriers = (RIL_Carrier *)calloc(cr.len_allowed_carriers, sizeof(RIL_Carrier));
+ if (allowedCarriers == NULL) {
+ RLOGE("setAllowedCarriers: Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+ return Void();
+ }
+ cr.allowed_carriers = allowedCarriers;
+
+ cr.len_excluded_carriers = carriers.excludedCarriers.size();
+ excludedCarriers = (RIL_Carrier *)calloc(cr.len_excluded_carriers, sizeof(RIL_Carrier));
+ if (excludedCarriers == NULL) {
+ RLOGE("setAllowedCarriers: Memory allocation failed for request %s",
+ requestToString(pRI->pCI->requestNumber));
+ sendErrorResponse(pRI, RIL_E_NO_MEMORY);
+#ifdef MEMSET_FREED
+ memset(allowedCarriers, 0, cr.len_allowed_carriers * sizeof(RIL_Carrier));
+#endif
+ free(allowedCarriers);
+ return Void();
+ }
+ cr.excluded_carriers = excludedCarriers;
+
+ for (int i = 0; i < cr.len_allowed_carriers; i++) {
+ allowedCarriers[i].mcc = carriers.allowedCarriers[i].mcc.c_str();
+ allowedCarriers[i].mnc = carriers.allowedCarriers[i].mnc.c_str();
+ allowedCarriers[i].match_type = (RIL_CarrierMatchType) carriers.allowedCarriers[i].matchType;
+ allowedCarriers[i].match_data = carriers.allowedCarriers[i].matchData.c_str();
+ }
+
+ for (int i = 0; i < cr.len_excluded_carriers; i++) {
+ excludedCarriers[i].mcc = carriers.excludedCarriers[i].mcc.c_str();
+ excludedCarriers[i].mnc = carriers.excludedCarriers[i].mnc.c_str();
+ excludedCarriers[i].match_type =
+ (RIL_CarrierMatchType) carriers.excludedCarriers[i].matchType;
+ excludedCarriers[i].match_data = carriers.excludedCarriers[i].matchData.c_str();
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &cr, sizeof(RIL_CarrierRestrictions), pRI, mSlotId);
+
+#ifdef MEMSET_FREED
+ memset(allowedCarriers, 0, cr.len_allowed_carriers * sizeof(RIL_Carrier));
+ memset(excludedCarriers, 0, cr.len_excluded_carriers * sizeof(RIL_Carrier));
+#endif
+ free(allowedCarriers);
+ free(excludedCarriers);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getAllowedCarriers(int32_t serial) {
+#if VDBG
+ RLOGD("getAllowedCarriers: serial %d", serial);
+#endif
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_GET_CARRIER_RESTRICTIONS);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::sendDeviceState(int32_t serial, DeviceStateType deviceStateType,
+ bool state) {
+#if VDBG
+ RLOGD("sendDeviceState: serial %d", serial);
+#endif
+ if (s_vendorFunctions->version < 15) {
+ if (deviceStateType == DeviceStateType::LOW_DATA_EXPECTED) {
+ RLOGD("sendDeviceState: calling screen state %d", BOOL_TO_INT(!state));
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SCREEN_STATE, 1, BOOL_TO_INT(!state));
+ } else {
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SEND_DEVICE_STATE);
+ sendErrorResponse(pRI, RIL_E_REQUEST_NOT_SUPPORTED);
+ }
+ return Void();
+ }
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SEND_DEVICE_STATE, 2, (int) deviceStateType,
+ BOOL_TO_INT(state));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setIndicationFilter(int32_t serial, int32_t indicationFilter) {
+#if VDBG
+ RLOGD("setIndicationFilter: serial %d", serial);
+#endif
+ if (s_vendorFunctions->version < 15) {
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER);
+ sendErrorResponse(pRI, RIL_E_REQUEST_NOT_SUPPORTED);
+ return Void();
+ }
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_UNSOLICITED_RESPONSE_FILTER, 1, indicationFilter);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setSimCardPower(int32_t serial, bool powerUp) {
+#if VDBG
+ RLOGD("setSimCardPower: serial %d", serial);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_SIM_CARD_POWER, 1, BOOL_TO_INT(powerUp));
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setSimCardPower_1_1(int32_t serial, const V1_1::CardPowerState state) {
+#if VDBG
+ RLOGD("setSimCardPower_1_1: serial %d state %d", serial, state);
+#endif
+ dispatchInts(serial, mSlotId, RIL_REQUEST_SET_SIM_CARD_POWER, 1, state);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setCarrierInfoForImsiEncryption(int32_t serial,
+ const V1_1::ImsiEncryptionInfo& data) {
+#if VDBG
+ RLOGD("setCarrierInfoForImsiEncryption: serial %d", serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(
+ serial, mSlotId, RIL_REQUEST_SET_CARRIER_INFO_IMSI_ENCRYPTION);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_CarrierInfoForImsiEncryption imsiEncryption = {};
+
+ if (!copyHidlStringToRil(&imsiEncryption.mnc, data.mnc, pRI)) {
+ return Void();
+ }
+ if (!copyHidlStringToRil(&imsiEncryption.mcc, data.mcc, pRI)) {
+ memsetAndFreeStrings(1, imsiEncryption.mnc);
+ return Void();
+ }
+ if (!copyHidlStringToRil(&imsiEncryption.keyIdentifier, data.keyIdentifier, pRI)) {
+ memsetAndFreeStrings(2, imsiEncryption.mnc, imsiEncryption.mcc);
+ return Void();
+ }
+ imsiEncryption.carrierKeyLength = data.carrierKey.size();
+ imsiEncryption.carrierKey = new uint8_t[imsiEncryption.carrierKeyLength];
+ memcpy(imsiEncryption.carrierKey, data.carrierKey.data(), imsiEncryption.carrierKeyLength);
+ imsiEncryption.expirationTime = data.expirationTime;
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &imsiEncryption,
+ sizeof(RIL_CarrierInfoForImsiEncryption), pRI, mSlotId);
+ delete(imsiEncryption.carrierKey);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::startKeepalive(int32_t serial, const V1_1::KeepaliveRequest& keepalive) {
+#if VDBG
+ RLOGD("%s(): %d", __FUNCTION__, serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_START_KEEPALIVE);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ RIL_KeepaliveRequest kaReq = {};
+
+ kaReq.type = static_cast<RIL_KeepaliveType>(keepalive.type);
+ switch(kaReq.type) {
+ case NATT_IPV4:
+ if (keepalive.sourceAddress.size() != 4 ||
+ keepalive.destinationAddress.size() != 4) {
+ RLOGE("Invalid address for keepalive!");
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+ break;
+ case NATT_IPV6:
+ if (keepalive.sourceAddress.size() != 16 ||
+ keepalive.destinationAddress.size() != 16) {
+ RLOGE("Invalid address for keepalive!");
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+ break;
+ default:
+ RLOGE("Unknown packet keepalive type!");
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return Void();
+ }
+
+ ::memcpy(kaReq.sourceAddress, keepalive.sourceAddress.data(), keepalive.sourceAddress.size());
+ kaReq.sourcePort = keepalive.sourcePort;
+
+ ::memcpy(kaReq.destinationAddress,
+ keepalive.destinationAddress.data(), keepalive.destinationAddress.size());
+ kaReq.destinationPort = keepalive.destinationPort;
+
+ kaReq.maxKeepaliveIntervalMillis = keepalive.maxKeepaliveIntervalMillis;
+ kaReq.cid = keepalive.cid; // This is the context ID of the data call
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &kaReq, sizeof(RIL_KeepaliveRequest), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::stopKeepalive(int32_t serial, int32_t sessionHandle) {
+#if VDBG
+ RLOGD("%s(): %d", __FUNCTION__, serial);
+#endif
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_STOP_KEEPALIVE);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ CALL_ONREQUEST(pRI->pCI->requestNumber, &sessionHandle, sizeof(uint32_t), pRI, mSlotId);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::responseAcknowledgement() {
+ android::releaseWakeLock();
+ return Void();
+}
+
+int prepareNetworkScanRequest_1_2(RIL_NetworkScanRequest &scan_request,
+ const ::android::hardware::radio::V1_2::NetworkScanRequest& request,
+ RequestInfo *pRI) {
+
+ if (request.specifiers.size() > MAX_RADIO_ACCESS_NETWORKS) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return -1;
+ }
+
+ scan_request.type = (RIL_ScanType) request.type;
+ scan_request.interval = request.interval;
+ scan_request.specifiers_length = request.specifiers.size();
+ for (size_t i = 0; i < request.specifiers.size(); ++i) {
+ if (request.specifiers[i].geranBands.size() > MAX_BANDS ||
+ request.specifiers[i].utranBands.size() > MAX_BANDS ||
+ request.specifiers[i].eutranBands.size() > MAX_BANDS ||
+ request.specifiers[i].channels.size() > MAX_CHANNELS) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return -1;
+ }
+ const V1_1::RadioAccessSpecifier& ras_from =
+ request.specifiers[i];
+ RIL_RadioAccessSpecifier& ras_to = scan_request.specifiers[i];
+
+ ras_to.radio_access_network = (RIL_RadioAccessNetworks) ras_from.radioAccessNetwork;
+ ras_to.channels_length = ras_from.channels.size();
+
+ std::copy(ras_from.channels.begin(), ras_from.channels.end(), ras_to.channels);
+ const std::vector<uint32_t> * bands = nullptr;
+ switch (request.specifiers[i].radioAccessNetwork) {
+ case V1_1::RadioAccessNetworks::GERAN:
+ ras_to.bands_length = ras_from.geranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.geranBands;
+ break;
+ case V1_1::RadioAccessNetworks::UTRAN:
+ ras_to.bands_length = ras_from.utranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.utranBands;
+ break;
+ case V1_1::RadioAccessNetworks::EUTRAN:
+ ras_to.bands_length = ras_from.eutranBands.size();
+ bands = (std::vector<uint32_t> *) &ras_from.eutranBands;
+ break;
+ default:
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ return -1;
+ }
+ // safe to copy to geran_bands because it's a union member
+ for (size_t idx = 0; idx < ras_to.bands_length; ++idx) {
+ ras_to.bands.geran_bands[idx] = (RIL_GeranBands) (*bands)[idx];
+ }
+ }
+
+ return 0;
+}
+
+// Methods from ::android::hardware::radio::V1_2::IRadio follow.
+Return<void> RadioImpl_1_4::startNetworkScan_1_2(int32_t serial,
+ const ::android::hardware::radio::V1_2::NetworkScanRequest& request) {
+#if VDBG
+ RLOGD("startNetworkScan_1_2: serial %d", serial);
+#endif
+
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_START_NETWORK_SCAN);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ // TODO: implement checks for new fields.
+ // NetworkScanRequest added maxSearchTime, incrementalResults, incrementalResultsPeriodicity and
+ // mccMncs, could add more validations using request2 here.
+
+ RIL_NetworkScanRequest scan_request = {};
+
+ if (prepareNetworkScanRequest_1_2(scan_request, request, pRI) < 0) {
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_START_NETWORK_SCAN, &scan_request, sizeof(scan_request), pRI,
+ mSlotId);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setIndicationFilter_1_2(int32_t /* serial */,
+ hidl_bitfield<::android::hardware::radio::V1_2::IndicationFilter> /* indicationFilter */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setSignalStrengthReportingCriteria(int32_t /* serial */,
+ int32_t /* hysteresisMs */, int32_t /* hysteresisDb */,
+ const hidl_vec<int32_t>& /* thresholdsDbm */,
+ ::android::hardware::radio::V1_2::AccessNetwork /* accessNetwork */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setLinkCapacityReportingCriteria(int32_t /* serial */,
+ int32_t /* hysteresisMs */, int32_t /* hysteresisDlKbps */, int32_t /* hysteresisUlKbps */,
+ const hidl_vec<int32_t>& /* thresholdsDownlinkKbps */,
+ const hidl_vec<int32_t>& /* thresholdsUplinkKbps */,
+ ::android::hardware::radio::V1_2::AccessNetwork /* accessNetwork */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setupDataCall_1_2(int32_t /* serial */,
+ ::android::hardware::radio::V1_2::AccessNetwork /* accessNetwork */,
+ const ::android::hardware::radio::V1_0::DataProfileInfo& /* dataProfileInfo */,
+ bool /* modemCognitive */, bool /* roamingAllowed */, bool /* isRoaming */,
+ ::android::hardware::radio::V1_2::DataRequestReason /* reason */,
+ const hidl_vec<hidl_string>& /* addresses */, const hidl_vec<hidl_string>& /* dnses */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::deactivateDataCall_1_2(int32_t /* serial */, int32_t /* cid */,
+ ::android::hardware::radio::V1_2::DataRequestReason /* reason */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+// Methods from ::android::hardware::radio::V1_3::IRadio follow.
+Return<void> RadioImpl_1_4::setSystemSelectionChannels(int32_t /* serial */, bool /* specifyChannels */,
+ const hidl_vec<::android::hardware::radio::V1_1::RadioAccessSpecifier>& /* specifiers */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::enableModem(int32_t /* serial */, bool /* on */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getModemStackStatus(int32_t /* serial */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+const char * getProtocolString(const ::android::hardware::radio::V1_4::PdpProtocolType protocolVal) {
+ switch(protocolVal) {
+ case ::android::hardware::radio::V1_4::PdpProtocolType::IP:
+ return "IP";
+ case ::android::hardware::radio::V1_4::PdpProtocolType::IPV6:
+ return "IPV6";
+ case ::android::hardware::radio::V1_4::PdpProtocolType::IPV4V6:
+ return "IPV4V6";
+ case ::android::hardware::radio::V1_4::PdpProtocolType::PPP:
+ return "PPP";
+ case ::android::hardware::radio::V1_4::PdpProtocolType::NON_IP:
+ return "NON_IP";
+ case ::android::hardware::radio::V1_4::PdpProtocolType::UNSTRUCTURED:
+ return "UNSTRUCTURED";
+ default:
+ return "UNKNOWN";
+ }
+}
+
+// Methods from ::android::hardware::radio::V1_4::IRadio follow.
+Return<void> RadioImpl_1_4::setupDataCall_1_4(int32_t serial ,
+ ::android::hardware::radio::V1_4::AccessNetwork /* accessNetwork */,
+ const ::android::hardware::radio::V1_4::DataProfileInfo& dataProfileInfo,
+ bool roamingAllowed, ::android::hardware::radio::V1_2::DataRequestReason /* reason */,
+ const hidl_vec<hidl_string>& /* addresses */, const hidl_vec<hidl_string>& /* dnses */) {
+
+#if VDBG
+ RLOGD("setupDataCall_1_4: serial %d", serial);
+#endif
+
+ char *mvnoTypeStr = NULL;
+ if (!convertMvnoTypeToString(MvnoType::IMSI, mvnoTypeStr)) {
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId,
+ RIL_REQUEST_SETUP_DATA_CALL);
+ if (pRI != NULL) {
+ sendErrorResponse(pRI, RIL_E_INVALID_ARGUMENTS);
+ }
+ return Void();
+ }
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_SETUP_DATA_CALL, true, 15,
+ std::to_string((int) RadioTechnology::UNKNOWN + 2).c_str(),
+ std::to_string((int) dataProfileInfo.profileId).c_str(),
+ dataProfileInfo.apn.c_str(),
+ dataProfileInfo.user.c_str(),
+ dataProfileInfo.password.c_str(),
+ std::to_string((int) dataProfileInfo.authType).c_str(),
+ getProtocolString(dataProfileInfo.protocol),
+ getProtocolString(dataProfileInfo.roamingProtocol),
+ std::to_string(dataProfileInfo.supportedApnTypesBitmap).c_str(),
+ std::to_string(dataProfileInfo.bearerBitmap).c_str(),
+ dataProfileInfo.persistent ? "1" : "0",
+ std::to_string(dataProfileInfo.mtu).c_str(),
+ mvnoTypeStr,
+ "302720x94",
+ roamingAllowed ? "1" : "0");
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setInitialAttachApn_1_4(int32_t /* serial */,
+ const ::android::hardware::radio::V1_4::DataProfileInfo& /* dataProfileInfo */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setDataProfile_1_4(int32_t /* serial */,
+ const hidl_vec<::android::hardware::radio::V1_4::DataProfileInfo>& /* profiles */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::emergencyDial(int32_t serial,
+ const ::android::hardware::radio::V1_0::Dial& /* dialInfo */,
+ hidl_bitfield<android::hardware::radio::V1_4::EmergencyServiceCategory> /* categories */,
+ const hidl_vec<hidl_string>& /* urns */,
+ ::android::hardware::radio::V1_4::EmergencyCallRouting /* routing */,
+ bool /* fromEmergencyDialer */, bool /* isTesting */) {
+#if VDBG
+ RLOGD("emergencyDial: serial %d", serial);
+#endif
+ // TODO actual implementation
+ dispatchVoid(serial, mSlotId, RIL_REQUEST_EMERGENCY_DIAL);
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::startNetworkScan_1_4(int32_t serial,
+ const ::android::hardware::radio::V1_2::NetworkScanRequest& request) {
+#if VDBG
+ RLOGD("startNetworkScan_1_4: serial %d", serial);
+#endif
+
+ RequestInfo *pRI = android::addRequestToList(serial, mSlotId, RIL_REQUEST_START_NETWORK_SCAN4);
+ if (pRI == NULL) {
+ return Void();
+ }
+
+ // TODO: implement checks for new fields.
+ // NetworkScanRequest added maxSearchTime, incrementalResults, incrementalResultsPeriodicity and
+ // mccMncs, could add more validations using request2 here.
+
+ RIL_NetworkScanRequest scan_request = {};
+
+ if (prepareNetworkScanRequest_1_2(scan_request, request, pRI) < 0) {
+ return Void();
+ }
+
+ CALL_ONREQUEST(RIL_REQUEST_START_NETWORK_SCAN4, &scan_request, sizeof(scan_request), pRI,
+ mSlotId);
+
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getPreferredNetworkTypeBitmap(int32_t /* serial */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setPreferredNetworkTypeBitmap(
+ int32_t /* serial */, hidl_bitfield<RadioAccessFamily> /* networkTypeBitmap */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::setAllowedCarriers_1_4(int32_t /* serial */,
+ const ::android::hardware::radio::V1_4::CarrierRestrictionsWithPriority& /* carriers */,
+ ::android::hardware::radio::V1_4::SimLockMultiSimPolicy /* multiSimPolicy */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getAllowedCarriers_1_4(int32_t /* serial */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> RadioImpl_1_4::getSignalStrength_1_4(int32_t /* serial */) {
+ // TODO implement
+#if VDBG
+ RLOGE("[%04d]< %s", serial, "Method is not implemented");
+#endif
+ return Void();
+}
+
+Return<void> OemHookImpl::setResponseFunctions(
+ const ::android::sp<IOemHookResponse>& oemHookResponseParam,
+ const ::android::sp<IOemHookIndication>& oemHookIndicationParam) {
+#if VDBG
+ RLOGD("OemHookImpl::setResponseFunctions");
+#endif
+
+ pthread_rwlock_t *radioServiceRwlockPtr = radio_1_4::getRadioServiceRwlock(mSlotId);
+ int ret = pthread_rwlock_wrlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ mOemHookResponse = oemHookResponseParam;
+ mOemHookIndication = oemHookIndicationParam;
+ mCounterOemHook[mSlotId]++;
+
+ ret = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ return Void();
+}
+
+Return<void> OemHookImpl::sendRequestRaw(int32_t serial, const hidl_vec<uint8_t>& data) {
+#if VDBG
+ RLOGD("OemHookImpl::sendRequestRaw: serial %d", serial);
+#endif
+ dispatchRaw(serial, mSlotId, RIL_REQUEST_OEM_HOOK_RAW, data);
+ return Void();
+}
+
+Return<void> OemHookImpl::sendRequestStrings(int32_t serial,
+ const hidl_vec<hidl_string>& data) {
+#if VDBG
+ RLOGD("OemHookImpl::sendRequestStrings: serial %d", serial);
+#endif
+ dispatchStrings(serial, mSlotId, RIL_REQUEST_OEM_HOOK_STRINGS, data);
+ return Void();
+}
+
+/***************************************************************************************************
+ * RESPONSE FUNCTIONS
+ * Functions above are used for requests going from framework to vendor code. The ones below are
+ * responses for those requests coming back from the vendor code.
+ **************************************************************************************************/
+
+void radio_1_4::acknowledgeRequest(int slotId, int serial) {
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->acknowledgeRequest(serial);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acknowledgeRequest: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+}
+
+void populateResponseInfo(RadioResponseInfo& responseInfo, int serial, int responseType,
+ RIL_Errno e) {
+ responseInfo.serial = serial;
+ switch (responseType) {
+ case RESPONSE_SOLICITED:
+ responseInfo.type = RadioResponseType::SOLICITED;
+ break;
+ case RESPONSE_SOLICITED_ACK_EXP:
+ responseInfo.type = RadioResponseType::SOLICITED_ACK_EXP;
+ break;
+ }
+ responseInfo.error = (RadioError) e;
+}
+
+int responseIntOrEmpty(RadioResponseInfo& responseInfo, int serial, int responseType, RIL_Errno e,
+ void *response, size_t responseLen) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ int ret = -1;
+
+ if (response == NULL && responseLen == 0) {
+ // Earlier RILs did not send a response for some cases although the interface
+ // expected an integer as response. Do not return error if response is empty. Instead
+ // Return -1 in those cases to maintain backward compatibility.
+ } else if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("responseIntOrEmpty: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *p_int = (int *) response;
+ ret = p_int[0];
+ }
+ return ret;
+}
+
+int responseInt(RadioResponseInfo& responseInfo, int serial, int responseType, RIL_Errno e,
+ void *response, size_t responseLen) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ int ret = -1;
+
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("responseInt: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *p_int = (int *) response;
+ ret = p_int[0];
+ }
+ return ret;
+}
+
+int radio_1_4::getIccCardStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ CardStatus cardStatus = {CardState::ABSENT, PinState::UNKNOWN, -1, -1, -1, {}};
+ RIL_CardStatus_v6 *p_cur = ((RIL_CardStatus_v6 *) response);
+ if (response == NULL || responseLen != sizeof(RIL_CardStatus_v6)
+ || p_cur->gsm_umts_subscription_app_index >= p_cur->num_applications
+ || p_cur->cdma_subscription_app_index >= p_cur->num_applications
+ || p_cur->ims_subscription_app_index >= p_cur->num_applications) {
+ RLOGE("getIccCardStatusResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ cardStatus.cardState = (CardState) p_cur->card_state;
+ cardStatus.universalPinState = (PinState) p_cur->universal_pin_state;
+ cardStatus.gsmUmtsSubscriptionAppIndex = p_cur->gsm_umts_subscription_app_index;
+ cardStatus.cdmaSubscriptionAppIndex = p_cur->cdma_subscription_app_index;
+ cardStatus.imsSubscriptionAppIndex = p_cur->ims_subscription_app_index;
+
+ RIL_AppStatus *rilAppStatus = p_cur->applications;
+ cardStatus.applications.resize(p_cur->num_applications);
+ AppStatus *appStatus = cardStatus.applications.data();
+#if VDBG
+ RLOGD("getIccCardStatusResponse: num_applications %d", p_cur->num_applications);
+#endif
+ for (int i = 0; i < p_cur->num_applications; i++) {
+ appStatus[i].appType = (AppType) rilAppStatus[i].app_type;
+ appStatus[i].appState = (AppState) rilAppStatus[i].app_state;
+ appStatus[i].persoSubstate = (PersoSubstate) rilAppStatus[i].perso_substate;
+ appStatus[i].aidPtr = convertCharPtrToHidlString(rilAppStatus[i].aid_ptr);
+ appStatus[i].appLabelPtr = convertCharPtrToHidlString(
+ rilAppStatus[i].app_label_ptr);
+ appStatus[i].pin1Replaced = rilAppStatus[i].pin1_replaced;
+ appStatus[i].pin1 = (PinState) rilAppStatus[i].pin1;
+ appStatus[i].pin2 = (PinState) rilAppStatus[i].pin2;
+ }
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ getIccCardStatusResponse(responseInfo, cardStatus);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getIccCardStatusResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::supplyIccPinForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("supplyIccPinForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ supplyIccPinForAppResponse(responseInfo, ret);
+ RLOGE("supplyIccPinForAppResponse: amit ret %d", ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("supplyIccPinForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::supplyIccPukForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("supplyIccPukForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->supplyIccPukForAppResponse(
+ responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("supplyIccPukForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::supplyIccPin2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("supplyIccPin2ForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ supplyIccPin2ForAppResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("supplyIccPin2ForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::supplyIccPuk2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("supplyIccPuk2ForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ supplyIccPuk2ForAppResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("supplyIccPuk2ForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::changeIccPinForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("changeIccPinForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ changeIccPinForAppResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("changeIccPinForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::changeIccPin2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("changeIccPin2ForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ changeIccPin2ForAppResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("changeIccPin2ForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::supplyNetworkDepersonalizationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("supplyNetworkDepersonalizationResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ supplyNetworkDepersonalizationResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("supplyNetworkDepersonalizationResponse: radioService[%d]->mRadioResponse == "
+ "NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCurrentCallsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getCurrentCallsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ hidl_vec<Call> calls;
+ if ((response == NULL && responseLen != 0)
+ || (responseLen % sizeof(RIL_Call *)) != 0) {
+ RLOGE("getCurrentCallsResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int num = responseLen / sizeof(RIL_Call *);
+ calls.resize(num);
+
+ for (int i = 0 ; i < num ; i++) {
+ RIL_Call *p_cur = ((RIL_Call **) response)[i];
+ /* each call info */
+ calls[i].state = (CallState) p_cur->state;
+ calls[i].index = p_cur->index;
+ calls[i].toa = p_cur->toa;
+ calls[i].isMpty = p_cur->isMpty;
+ calls[i].isMT = p_cur->isMT;
+ calls[i].als = p_cur->als;
+ calls[i].isVoice = p_cur->isVoice;
+ calls[i].isVoicePrivacy = p_cur->isVoicePrivacy;
+ calls[i].number = convertCharPtrToHidlString(p_cur->number);
+ calls[i].numberPresentation = (CallPresentation) p_cur->numberPresentation;
+ calls[i].name = convertCharPtrToHidlString(p_cur->name);
+ calls[i].namePresentation = (CallPresentation) p_cur->namePresentation;
+ if (p_cur->uusInfo != NULL && p_cur->uusInfo->uusData != NULL) {
+ RIL_UUS_Info *uusInfo = p_cur->uusInfo;
+ calls[i].uusInfo.resize(1);
+ calls[i].uusInfo[0].uusType = (UusType) uusInfo->uusType;
+ calls[i].uusInfo[0].uusDcs = (UusDcs) uusInfo->uusDcs;
+ // convert uusInfo->uusData to a null-terminated string
+ char *nullTermStr = strndup(uusInfo->uusData, uusInfo->uusLength);
+ calls[i].uusInfo[0].uusData = nullTermStr;
+ free(nullTermStr);
+ }
+ }
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ getCurrentCallsResponse(responseInfo, calls);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCurrentCallsResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::dialResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("dialResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->dialResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("dialResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getIMSIForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getIMSIForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getIMSIForAppResponse(
+ responseInfo, convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getIMSIForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::hangupConnectionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("hangupConnectionResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->hangupConnectionResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("hangupConnectionResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::hangupWaitingOrBackgroundResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("hangupWaitingOrBackgroundResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->hangupWaitingOrBackgroundResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("hangupWaitingOrBackgroundResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::hangupForegroundResumeBackgroundResponse(int slotId, int responseType, int serial,
+ RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("hangupWaitingOrBackgroundResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->hangupWaitingOrBackgroundResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("hangupWaitingOrBackgroundResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::switchWaitingOrHoldingAndActiveResponse(int slotId, int responseType, int serial,
+ RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("switchWaitingOrHoldingAndActiveResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->switchWaitingOrHoldingAndActiveResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("switchWaitingOrHoldingAndActiveResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::conferenceResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("conferenceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->conferenceResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("conferenceResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::rejectCallResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("rejectCallResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->rejectCallResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("rejectCallResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getLastCallFailCauseResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getLastCallFailCauseResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ LastCallFailCauseInfo info = {};
+ info.vendorCause = hidl_string();
+ if (response == NULL) {
+ RLOGE("getCurrentCallsResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else if (responseLen == sizeof(int)) {
+ int *pInt = (int *) response;
+ info.causeCode = (LastCallFailCause) pInt[0];
+ } else if (responseLen == sizeof(RIL_LastCallFailCauseInfo)) {
+ RIL_LastCallFailCauseInfo *pFailCauseInfo = (RIL_LastCallFailCauseInfo *) response;
+ info.causeCode = (LastCallFailCause) pFailCauseInfo->cause_code;
+ info.vendorCause = convertCharPtrToHidlString(pFailCauseInfo->vendor_cause);
+ } else {
+ RLOGE("getCurrentCallsResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getLastCallFailCauseResponse(
+ responseInfo, info);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getLastCallFailCauseResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getSignalStrengthResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getSignalStrengthResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ SignalStrength signalStrength = {};
+ if (response == NULL || responseLen != sizeof(RIL_SignalStrength_v10)) {
+ RLOGE("getSignalStrengthResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilSignalStrengthToHal(response, responseLen, signalStrength);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getSignalStrengthResponse(
+ responseInfo, signalStrength);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getSignalStrengthResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+RIL_CellInfoType getCellInfoTypeRadioTechnology(char *rat) {
+ if (rat == NULL) {
+ return RIL_CELL_INFO_TYPE_NONE;
+ }
+
+ int radioTech = atoi(rat);
+
+ switch(radioTech) {
+
+ case RADIO_TECH_GPRS:
+ case RADIO_TECH_EDGE:
+ case RADIO_TECH_GSM: {
+ return RIL_CELL_INFO_TYPE_GSM;
+ }
+
+ case RADIO_TECH_UMTS:
+ case RADIO_TECH_HSDPA:
+ case RADIO_TECH_HSUPA:
+ case RADIO_TECH_HSPA:
+ case RADIO_TECH_HSPAP: {
+ return RIL_CELL_INFO_TYPE_WCDMA;
+ }
+
+ case RADIO_TECH_IS95A:
+ case RADIO_TECH_IS95B:
+ case RADIO_TECH_1xRTT:
+ case RADIO_TECH_EVDO_0:
+ case RADIO_TECH_EVDO_A:
+ case RADIO_TECH_EVDO_B:
+ case RADIO_TECH_EHRPD: {
+ return RIL_CELL_INFO_TYPE_CDMA;
+ }
+
+ case RADIO_TECH_LTE:
+ case RADIO_TECH_LTE_CA: {
+ return RIL_CELL_INFO_TYPE_LTE;
+ }
+
+ case RADIO_TECH_TD_SCDMA: {
+ return RIL_CELL_INFO_TYPE_TD_SCDMA;
+ }
+
+ default: {
+ break;
+ }
+ }
+
+ return RIL_CELL_INFO_TYPE_NONE;
+
+}
+
+void fillCellIdentityResponse(CellIdentity &cellIdentity, RIL_CellIdentity_v16 &rilCellIdentity) {
+
+ cellIdentity.cellIdentityGsm.resize(0);
+ cellIdentity.cellIdentityWcdma.resize(0);
+ cellIdentity.cellIdentityCdma.resize(0);
+ cellIdentity.cellIdentityTdscdma.resize(0);
+ cellIdentity.cellIdentityLte.resize(0);
+ cellIdentity.cellInfoType = (CellInfoType)rilCellIdentity.cellInfoType;
+ switch(rilCellIdentity.cellInfoType) {
+
+ case RIL_CELL_INFO_TYPE_GSM: {
+ cellIdentity.cellIdentityGsm.resize(1);
+ cellIdentity.cellIdentityGsm[0].mcc =
+ std::to_string(rilCellIdentity.cellIdentityGsm.mcc);
+ cellIdentity.cellIdentityGsm[0].mnc =
+ ril::util::mnc::decode(rilCellIdentity.cellIdentityGsm.mnc);
+ cellIdentity.cellIdentityGsm[0].lac = rilCellIdentity.cellIdentityGsm.lac;
+ cellIdentity.cellIdentityGsm[0].cid = rilCellIdentity.cellIdentityGsm.cid;
+ cellIdentity.cellIdentityGsm[0].arfcn = rilCellIdentity.cellIdentityGsm.arfcn;
+ cellIdentity.cellIdentityGsm[0].bsic = rilCellIdentity.cellIdentityGsm.bsic;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_WCDMA: {
+ cellIdentity.cellIdentityWcdma.resize(1);
+ cellIdentity.cellIdentityWcdma[0].mcc =
+ std::to_string(rilCellIdentity.cellIdentityWcdma.mcc);
+ cellIdentity.cellIdentityWcdma[0].mnc =
+ ril::util::mnc::decode(rilCellIdentity.cellIdentityWcdma.mnc);
+ cellIdentity.cellIdentityWcdma[0].lac = rilCellIdentity.cellIdentityWcdma.lac;
+ cellIdentity.cellIdentityWcdma[0].cid = rilCellIdentity.cellIdentityWcdma.cid;
+ cellIdentity.cellIdentityWcdma[0].psc = rilCellIdentity.cellIdentityWcdma.psc;
+ cellIdentity.cellIdentityWcdma[0].uarfcn = rilCellIdentity.cellIdentityWcdma.uarfcn;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_CDMA: {
+ cellIdentity.cellIdentityCdma.resize(1);
+ cellIdentity.cellIdentityCdma[0].networkId = rilCellIdentity.cellIdentityCdma.networkId;
+ cellIdentity.cellIdentityCdma[0].systemId = rilCellIdentity.cellIdentityCdma.systemId;
+ cellIdentity.cellIdentityCdma[0].baseStationId =
+ rilCellIdentity.cellIdentityCdma.basestationId;
+ cellIdentity.cellIdentityCdma[0].longitude = rilCellIdentity.cellIdentityCdma.longitude;
+ cellIdentity.cellIdentityCdma[0].latitude = rilCellIdentity.cellIdentityCdma.latitude;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_LTE: {
+ cellIdentity.cellIdentityLte.resize(1);
+ cellIdentity.cellIdentityLte[0].mcc =
+ std::to_string(rilCellIdentity.cellIdentityLte.mcc);
+ cellIdentity.cellIdentityLte[0].mnc =
+ ril::util::mnc::decode(rilCellIdentity.cellIdentityLte.mnc);
+ cellIdentity.cellIdentityLte[0].ci = rilCellIdentity.cellIdentityLte.ci;
+ cellIdentity.cellIdentityLte[0].pci = rilCellIdentity.cellIdentityLte.pci;
+ cellIdentity.cellIdentityLte[0].tac = rilCellIdentity.cellIdentityLte.tac;
+ cellIdentity.cellIdentityLte[0].earfcn = rilCellIdentity.cellIdentityLte.earfcn;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_TD_SCDMA: {
+ cellIdentity.cellIdentityTdscdma.resize(1);
+ cellIdentity.cellIdentityTdscdma[0].mcc =
+ std::to_string(rilCellIdentity.cellIdentityTdscdma.mcc);
+ cellIdentity.cellIdentityTdscdma[0].mnc =
+ ril::util::mnc::decode(rilCellIdentity.cellIdentityTdscdma.mnc);
+ cellIdentity.cellIdentityTdscdma[0].lac = rilCellIdentity.cellIdentityTdscdma.lac;
+ cellIdentity.cellIdentityTdscdma[0].cid = rilCellIdentity.cellIdentityTdscdma.cid;
+ cellIdentity.cellIdentityTdscdma[0].cpid = rilCellIdentity.cellIdentityTdscdma.cpid;
+ break;
+ }
+
+ default: {
+ break;
+ }
+ }
+}
+
+int convertResponseStringEntryToInt(char **response, int index, int numStrings) {
+ if ((response != NULL) && (numStrings > index) && (response[index] != NULL)) {
+ return atoi(response[index]);
+ }
+
+ return -1;
+}
+
+int convertResponseHexStringEntryToInt(char **response, int index, int numStrings) {
+ const int hexBase = 16;
+ if ((response != NULL) && (numStrings > index) && (response[index] != NULL)) {
+ return strtol(response[index], NULL, hexBase);
+ }
+
+ return -1;
+}
+
+/* Fill Cell Identity info from Voice Registration State Response.
+ * This fucntion is applicable only for RIL Version < 15.
+ * Response is a "char **".
+ * First and Second entries are in hex string format
+ * and rest are integers represented in ascii format. */
+void fillCellIdentityFromVoiceRegStateResponseString(CellIdentity &cellIdentity,
+ int numStrings, char** response) {
+
+ RIL_CellIdentity_v16 rilCellIdentity;
+ memset(&rilCellIdentity, -1, sizeof(RIL_CellIdentity_v16));
+
+ rilCellIdentity.cellInfoType = getCellInfoTypeRadioTechnology(response[3]);
+ switch(rilCellIdentity.cellInfoType) {
+
+ case RIL_CELL_INFO_TYPE_GSM: {
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityGsm.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityGsm.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_WCDMA: {
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityWcdma.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityWcdma.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ rilCellIdentity.cellIdentityWcdma.psc =
+ convertResponseStringEntryToInt(response, 14, numStrings);
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_TD_SCDMA:{
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityTdscdma.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityTdscdma.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_CDMA:{
+ rilCellIdentity.cellIdentityCdma.basestationId =
+ convertResponseStringEntryToInt(response, 4, numStrings);
+ /* Order of Lat. and Long. swapped between RIL and HIDL interface versions. */
+ rilCellIdentity.cellIdentityCdma.latitude =
+ convertResponseStringEntryToInt(response, 5, numStrings);
+ rilCellIdentity.cellIdentityCdma.longitude =
+ convertResponseStringEntryToInt(response, 6, numStrings);
+ rilCellIdentity.cellIdentityCdma.systemId =
+ convertResponseStringEntryToInt(response, 8, numStrings);
+ rilCellIdentity.cellIdentityCdma.networkId =
+ convertResponseStringEntryToInt(response, 9, numStrings);
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_LTE:{
+ /* valid TAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityLte.tac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityLte.ci =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+
+ default: {
+ break;
+ }
+ }
+
+ fillCellIdentityResponse(cellIdentity, rilCellIdentity);
+}
+
+/* Fill Cell Identity info from Data Registration State Response.
+ * This fucntion is applicable only for RIL Version < 15.
+ * Response is a "char **".
+ * First and Second entries are in hex string format
+ * and rest are integers represented in ascii format. */
+void fillCellIdentityFromDataRegStateResponseString(CellIdentity &cellIdentity,
+ int numStrings, char** response) {
+
+ RIL_CellIdentity_v16 rilCellIdentity;
+ memset(&rilCellIdentity, -1, sizeof(RIL_CellIdentity_v16));
+
+ rilCellIdentity.cellInfoType = getCellInfoTypeRadioTechnology(response[3]);
+ switch(rilCellIdentity.cellInfoType) {
+ case RIL_CELL_INFO_TYPE_GSM: {
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityGsm.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityGsm.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+ case RIL_CELL_INFO_TYPE_WCDMA: {
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityWcdma.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityWcdma.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+ case RIL_CELL_INFO_TYPE_TD_SCDMA:{
+ /* valid LAC are hexstrings in the range 0x0000 - 0xffff */
+ rilCellIdentity.cellIdentityTdscdma.lac =
+ convertResponseHexStringEntryToInt(response, 1, numStrings);
+
+ /* valid CID are hexstrings in the range 0x00000000 - 0xffffffff */
+ rilCellIdentity.cellIdentityTdscdma.cid =
+ convertResponseHexStringEntryToInt(response, 2, numStrings);
+ break;
+ }
+ case RIL_CELL_INFO_TYPE_LTE: {
+ rilCellIdentity.cellIdentityLte.tac =
+ convertResponseStringEntryToInt(response, 6, numStrings);
+ rilCellIdentity.cellIdentityLte.pci =
+ convertResponseStringEntryToInt(response, 7, numStrings);
+ rilCellIdentity.cellIdentityLte.ci =
+ convertResponseStringEntryToInt(response, 8, numStrings);
+ break;
+ }
+ default: {
+ break;
+ }
+ }
+
+ fillCellIdentityResponse(cellIdentity, rilCellIdentity);
+}
+
+int radio_1_4::getVoiceRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getVoiceRegistrationStateResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ VoiceRegStateResult voiceRegResponse = {};
+ int numStrings = responseLen / sizeof(char *);
+ if (response == NULL) {
+ RLOGE("getVoiceRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else if (s_vendorFunctions->version <= 14) {
+ if (numStrings != 15) {
+ RLOGE("getVoiceRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ char **resp = (char **) response;
+ voiceRegResponse.regState = (RegState) ATOI_NULL_HANDLED_DEF(resp[0], 4);
+ voiceRegResponse.rat = ATOI_NULL_HANDLED(resp[3]);
+ voiceRegResponse.cssSupported = ATOI_NULL_HANDLED_DEF(resp[7], 0);
+ voiceRegResponse.roamingIndicator = ATOI_NULL_HANDLED(resp[10]);
+ voiceRegResponse.systemIsInPrl = ATOI_NULL_HANDLED_DEF(resp[11], 0);
+ voiceRegResponse.defaultRoamingIndicator = ATOI_NULL_HANDLED_DEF(resp[12], 0);
+ voiceRegResponse.reasonForDenial = ATOI_NULL_HANDLED_DEF(resp[13], 0);
+ fillCellIdentityFromVoiceRegStateResponseString(voiceRegResponse.cellIdentity,
+ numStrings, resp);
+ }
+ } else {
+ RIL_VoiceRegistrationStateResponse *voiceRegState =
+ (RIL_VoiceRegistrationStateResponse *)response;
+
+ if (responseLen != sizeof(RIL_VoiceRegistrationStateResponse)) {
+ RLOGE("getVoiceRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ voiceRegResponse.regState = (RegState) voiceRegState->regState;
+ voiceRegResponse.rat = voiceRegState->rat;;
+ voiceRegResponse.cssSupported = voiceRegState->cssSupported;
+ voiceRegResponse.roamingIndicator = voiceRegState->roamingIndicator;
+ voiceRegResponse.systemIsInPrl = voiceRegState->systemIsInPrl;
+ voiceRegResponse.defaultRoamingIndicator = voiceRegState->defaultRoamingIndicator;
+ voiceRegResponse.reasonForDenial = voiceRegState->reasonForDenial;
+ fillCellIdentityResponse(voiceRegResponse.cellIdentity,
+ voiceRegState->cellIdentity);
+ }
+ }
+
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->getVoiceRegistrationStateResponse(
+ responseInfo, voiceRegResponse);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getVoiceRegistrationStateResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getDataRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getDataRegistrationStateResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ DataRegStateResult dataRegResponse = {};
+ if (response == NULL) {
+ RLOGE("getDataRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else if (s_vendorFunctions->version <= 14) {
+ int numStrings = responseLen / sizeof(char *);
+ if ((numStrings != 6) && (numStrings != 11)) {
+ RLOGE("getDataRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ char **resp = (char **) response;
+ dataRegResponse.regState = (RegState) ATOI_NULL_HANDLED_DEF(resp[0], 4);
+ dataRegResponse.rat = ATOI_NULL_HANDLED_DEF(resp[3], 0);
+ dataRegResponse.reasonDataDenied = ATOI_NULL_HANDLED(resp[4]);
+ dataRegResponse.maxDataCalls = ATOI_NULL_HANDLED_DEF(resp[5], 1);
+ fillCellIdentityFromDataRegStateResponseString(dataRegResponse.cellIdentity,
+ numStrings, resp);
+ }
+ } else {
+ RIL_DataRegistrationStateResponse *dataRegState =
+ (RIL_DataRegistrationStateResponse *)response;
+
+ if (responseLen != sizeof(RIL_DataRegistrationStateResponse)) {
+ RLOGE("getDataRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ dataRegResponse.regState = (RegState) dataRegState->regState;
+ dataRegResponse.rat = dataRegState->rat;;
+ dataRegResponse.reasonDataDenied = dataRegState->reasonDataDenied;
+ dataRegResponse.maxDataCalls = dataRegState->maxDataCalls;
+ fillCellIdentityResponse(dataRegResponse.cellIdentity, dataRegState->cellIdentity);
+ }
+ }
+
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->getDataRegistrationStateResponse(responseInfo,
+ dataRegResponse);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getDataRegistrationStateResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getOperatorResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getOperatorResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_string longName;
+ hidl_string shortName;
+ hidl_string numeric;
+ int numStrings = responseLen / sizeof(char *);
+ if (response == NULL || numStrings != 3) {
+ RLOGE("getOperatorResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+
+ } else {
+ char **resp = (char **) response;
+ longName = convertCharPtrToHidlString(resp[0]);
+ shortName = convertCharPtrToHidlString(resp[1]);
+ numeric = convertCharPtrToHidlString(resp[2]);
+ }
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getOperatorResponse(
+ responseInfo, longName, shortName, numeric);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getOperatorResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setRadioPowerResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+ RLOGD("setRadioPowerResponse: serial %d", serial);
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setRadioPowerResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setRadioPowerResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendDtmfResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->sendDtmfResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendDtmfResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+SendSmsResult makeSendSmsResult(RadioResponseInfo& responseInfo, int serial, int responseType,
+ RIL_Errno e, void *response, size_t responseLen) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ SendSmsResult result = {};
+
+ if (response == NULL || responseLen != sizeof(RIL_SMS_Response)) {
+ RLOGE("Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ result.ackPDU = hidl_string();
+ } else {
+ RIL_SMS_Response *resp = (RIL_SMS_Response *) response;
+ result.messageRef = resp->messageRef;
+ result.ackPDU = convertCharPtrToHidlString(resp->ackPDU);
+ result.errorCode = resp->errorCode;
+ }
+ return result;
+}
+
+int radio_1_4::sendSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendSmsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ SendSmsResult result = makeSendSmsResult(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->sendSmsResponse(responseInfo,
+ result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendSmsResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendSMSExpectMoreResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendSMSExpectMoreResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ SendSmsResult result = makeSendSmsResult(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->sendSMSExpectMoreResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendSMSExpectMoreResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setupDataCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setupDataCallResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ SetupDataCallResult result = {};
+ if (response == NULL || (responseLen % sizeof(RIL_Data_Call_Response_v11)) != 0) {
+ if (response != NULL) {
+ RLOGE("setupDataCallResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ }
+ result.status = DataCallFailCause::ERROR_UNSPECIFIED;
+ result.type = hidl_string();
+ result.ifname = hidl_string();
+ result.addresses = hidl_string();
+ result.dnses = hidl_string();
+ result.gateways = hidl_string();
+ result.pcscf = hidl_string();
+ } else {
+ convertRilDataCallToHal((RIL_Data_Call_Response_v11 *) response, result);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setupDataCallResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setupDataCallResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+IccIoResult responseIccIo(RadioResponseInfo& responseInfo, int serial, int responseType,
+ RIL_Errno e, void *response, size_t responseLen) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ IccIoResult result = {};
+
+ if (response == NULL || responseLen != sizeof(RIL_SIM_IO_Response)) {
+ RLOGE("Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ result.simResponse = hidl_string();
+ } else {
+ RIL_SIM_IO_Response *resp = (RIL_SIM_IO_Response *) response;
+ result.sw1 = resp->sw1;
+ result.sw2 = resp->sw2;
+ result.simResponse = convertCharPtrToHidlString(resp->simResponse);
+ }
+ return result;
+}
+
+int radio_1_4::iccIOForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("iccIOForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ IccIoResult result = responseIccIo(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->iccIOForAppResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("iccIOForAppResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendUssdResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendUssdResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->sendUssdResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendUssdResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cancelPendingUssdResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("cancelPendingUssdResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->cancelPendingUssdResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cancelPendingUssdResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getClirResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getClirResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ int n = -1, m = -1;
+ int numInts = responseLen / sizeof(int);
+ if (response == NULL || numInts != 2) {
+ RLOGE("getClirResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ n = pInt[0];
+ m = pInt[1];
+ }
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getClirResponse(responseInfo,
+ n, m);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getClirResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setClirResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setClirResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setClirResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setClirResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCallForwardStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getCallForwardStatusResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<CallForwardInfo> callForwardInfos;
+
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_CallForwardInfo *) != 0) {
+ RLOGE("getCallForwardStatusResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int num = responseLen / sizeof(RIL_CallForwardInfo *);
+ callForwardInfos.resize(num);
+ for (int i = 0 ; i < num; i++) {
+ RIL_CallForwardInfo *resp = ((RIL_CallForwardInfo **) response)[i];
+ callForwardInfos[i].status = (CallForwardInfoStatus) resp->status;
+ callForwardInfos[i].reason = resp->reason;
+ callForwardInfos[i].serviceClass = resp->serviceClass;
+ callForwardInfos[i].toa = resp->toa;
+ callForwardInfos[i].number = convertCharPtrToHidlString(resp->number);
+ callForwardInfos[i].timeSeconds = resp->timeSeconds;
+ }
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getCallForwardStatusResponse(
+ responseInfo, callForwardInfos);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCallForwardStatusResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCallForwardResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setCallForwardResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setCallForwardResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCallForwardResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCallWaitingResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getCallWaitingResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ bool enable = false;
+ int serviceClass = -1;
+ int numInts = responseLen / sizeof(int);
+ if (response == NULL || numInts != 2) {
+ RLOGE("getCallWaitingResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ enable = pInt[0] == 1 ? true : false;
+ serviceClass = pInt[1];
+ }
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getCallWaitingResponse(
+ responseInfo, enable, serviceClass);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCallWaitingResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCallWaitingResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setCallWaitingResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setCallWaitingResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCallWaitingResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::acknowledgeLastIncomingGsmSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("acknowledgeLastIncomingGsmSmsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponse->acknowledgeLastIncomingGsmSmsResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acknowledgeLastIncomingGsmSmsResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::acceptCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("acceptCallResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->acceptCallResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acceptCallResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::deactivateDataCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("deactivateDataCallResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->deactivateDataCallResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("deactivateDataCallResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getFacilityLockForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getFacilityLockForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ getFacilityLockForAppResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getFacilityLockForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setFacilityLockForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setFacilityLockForAppResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseIntOrEmpty(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setFacilityLockForAppResponse(responseInfo,
+ ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setFacilityLockForAppResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setBarringPasswordResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("acceptCallResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setBarringPasswordResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setBarringPasswordResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getNetworkSelectionModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getNetworkSelectionModeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ bool manual = false;
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("getNetworkSelectionModeResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ manual = pInt[0] == 1 ? true : false;
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getNetworkSelectionModeResponse(
+ responseInfo,
+ manual);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getNetworkSelectionModeResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setNetworkSelectionModeAutomaticResponse(int slotId, int responseType, int serial,
+ RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setNetworkSelectionModeAutomaticResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setNetworkSelectionModeAutomaticResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setNetworkSelectionModeAutomaticResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setNetworkSelectionModeManualResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setNetworkSelectionModeManualResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setNetworkSelectionModeManualResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acceptCallResponse: radioService[%d]->setNetworkSelectionModeManualResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int convertOperatorStatusToInt(const char *str) {
+ if (strncmp("unknown", str, 9) == 0) {
+ return (int) OperatorStatus::UNKNOWN;
+ } else if (strncmp("available", str, 9) == 0) {
+ return (int) OperatorStatus::AVAILABLE;
+ } else if (strncmp("current", str, 9) == 0) {
+ return (int) OperatorStatus::CURRENT;
+ } else if (strncmp("forbidden", str, 9) == 0) {
+ return (int) OperatorStatus::FORBIDDEN;
+ } else {
+ return -1;
+ }
+}
+
+int radio_1_4::getAvailableNetworksResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getAvailableNetworksResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<OperatorInfo> networks;
+ if ((response == NULL && responseLen != 0)
+ || responseLen % (4 * sizeof(char *))!= 0) {
+ RLOGE("getAvailableNetworksResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ char **resp = (char **) response;
+ int numStrings = responseLen / sizeof(char *);
+ networks.resize(numStrings/4);
+ for (int i = 0, j = 0; i < numStrings; i = i + 4, j++) {
+ networks[j].alphaLong = convertCharPtrToHidlString(resp[i]);
+ networks[j].alphaShort = convertCharPtrToHidlString(resp[i + 1]);
+ networks[j].operatorNumeric = convertCharPtrToHidlString(resp[i + 2]);
+ int status = convertOperatorStatusToInt(resp[i + 3]);
+ if (status == -1) {
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ networks[j].status = (OperatorStatus) status;
+ }
+ }
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getAvailableNetworksResponse(responseInfo,
+ networks);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getAvailableNetworksResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::startDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("startDtmfResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->startDtmfResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("startDtmfResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stopDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("stopDtmfResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->stopDtmfResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stopDtmfResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getBasebandVersionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getBasebandVersionResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getBasebandVersionResponse(responseInfo,
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getBasebandVersionResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::separateConnectionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("separateConnectionResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->separateConnectionResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("separateConnectionResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setMuteResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setMuteResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setMuteResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setMuteResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getMuteResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getMuteResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ bool enable = false;
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("getMuteResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ enable = pInt[0] == 1 ? true : false;
+ }
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getMuteResponse(responseInfo,
+ enable);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getMuteResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getClipResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getClipResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getClipResponse(responseInfo,
+ (ClipStatus) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getClipResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getDataCallListResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getDataCallListResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ hidl_vec<SetupDataCallResult> ret;
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_Data_Call_Response_v11) != 0) {
+ RLOGE("getDataCallListResponse: invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilDataCallListToHal(response, responseLen, ret);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getDataCallListResponse(
+ responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getDataCallListResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setSuppServiceNotificationsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setSuppServiceNotificationsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setSuppServiceNotificationsResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setSuppServiceNotificationsResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::deleteSmsOnSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("deleteSmsOnSimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->deleteSmsOnSimResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("deleteSmsOnSimResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setBandModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setBandModeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setBandModeResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setBandModeResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::writeSmsToSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("writeSmsToSimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->writeSmsToSimResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("writeSmsToSimResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getAvailableBandModesResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getAvailableBandModesResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<RadioBandMode> modes;
+ if ((response == NULL && responseLen != 0)|| responseLen % sizeof(int) != 0) {
+ RLOGE("getAvailableBandModesResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ int numInts = responseLen / sizeof(int);
+ modes.resize(numInts);
+ for (int i = 0; i < numInts; i++) {
+ modes[i] = (RadioBandMode) pInt[i];
+ }
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getAvailableBandModesResponse(responseInfo,
+ modes);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getAvailableBandModesResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendEnvelopeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendEnvelopeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendEnvelopeResponse(responseInfo,
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendEnvelopeResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendTerminalResponseToSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendTerminalResponseToSimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendTerminalResponseToSimResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendTerminalResponseToSimResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::handleStkCallSetupRequestFromSimResponse(int slotId,
+ int responseType, int serial,
+ RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("handleStkCallSetupRequestFromSimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->handleStkCallSetupRequestFromSimResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("handleStkCallSetupRequestFromSimResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::explicitCallTransferResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("explicitCallTransferResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->explicitCallTransferResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("explicitCallTransferResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setPreferredNetworkTypeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setPreferredNetworkTypeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setPreferredNetworkTypeResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setPreferredNetworkTypeResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+
+int radio_1_4::getPreferredNetworkTypeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getPreferredNetworkTypeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getPreferredNetworkTypeResponse(
+ responseInfo, (PreferredNetworkType) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getPreferredNetworkTypeResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getNeighboringCidsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getNeighboringCidsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<NeighboringCell> cells;
+
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_NeighboringCell *) != 0) {
+ RLOGE("getNeighboringCidsResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int num = responseLen / sizeof(RIL_NeighboringCell *);
+ cells.resize(num);
+ for (int i = 0 ; i < num; i++) {
+ RIL_NeighboringCell *resp = ((RIL_NeighboringCell **) response)[i];
+ cells[i].cid = convertCharPtrToHidlString(resp->cid);
+ cells[i].rssi = resp->rssi;
+ }
+ }
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getNeighboringCidsResponse(responseInfo,
+ cells);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getNeighboringCidsResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setLocationUpdatesResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setLocationUpdatesResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setLocationUpdatesResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setLocationUpdatesResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCdmaSubscriptionSourceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setCdmaSubscriptionSourceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setCdmaSubscriptionSourceResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCdmaSubscriptionSourceResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCdmaRoamingPreferenceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setCdmaRoamingPreferenceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setCdmaRoamingPreferenceResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCdmaRoamingPreferenceResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCdmaRoamingPreferenceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getCdmaRoamingPreferenceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getCdmaRoamingPreferenceResponse(
+ responseInfo, (CdmaRoamingType) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCdmaRoamingPreferenceResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setTTYModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setTTYModeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setTTYModeResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setTTYModeResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getTTYModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getTTYModeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getTTYModeResponse(responseInfo,
+ (TtyMode) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getTTYModeResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setPreferredVoicePrivacyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setPreferredVoicePrivacyResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setPreferredVoicePrivacyResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setPreferredVoicePrivacyResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getPreferredVoicePrivacyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getPreferredVoicePrivacyResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ bool enable = false;
+ int numInts = responseLen / sizeof(int);
+ if (response == NULL || numInts != 1) {
+ RLOGE("getPreferredVoicePrivacyResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ enable = pInt[0] == 1 ? true : false;
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getPreferredVoicePrivacyResponse(
+ responseInfo, enable);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getPreferredVoicePrivacyResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendCDMAFeatureCodeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendCDMAFeatureCodeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendCDMAFeatureCodeResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendCDMAFeatureCodeResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendBurstDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendBurstDtmfResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendBurstDtmfResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendBurstDtmfResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendCdmaSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendCdmaSmsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ SendSmsResult result = makeSendSmsResult(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendCdmaSmsResponse(responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendCdmaSmsResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::acknowledgeLastIncomingCdmaSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("acknowledgeLastIncomingCdmaSmsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->acknowledgeLastIncomingCdmaSmsResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acknowledgeLastIncomingCdmaSmsResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getGsmBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getGsmBroadcastConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<GsmBroadcastSmsConfigInfo> configs;
+
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_GSM_BroadcastSmsConfigInfo *) != 0) {
+ RLOGE("getGsmBroadcastConfigResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int num = responseLen / sizeof(RIL_GSM_BroadcastSmsConfigInfo *);
+ configs.resize(num);
+ for (int i = 0 ; i < num; i++) {
+ RIL_GSM_BroadcastSmsConfigInfo *resp =
+ ((RIL_GSM_BroadcastSmsConfigInfo **) response)[i];
+ configs[i].fromServiceId = resp->fromServiceId;
+ configs[i].toServiceId = resp->toServiceId;
+ configs[i].fromCodeScheme = resp->fromCodeScheme;
+ configs[i].toCodeScheme = resp->toCodeScheme;
+ configs[i].selected = resp->selected == 1 ? true : false;
+ }
+ }
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getGsmBroadcastConfigResponse(responseInfo,
+ configs);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getGsmBroadcastConfigResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setGsmBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setGsmBroadcastConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setGsmBroadcastConfigResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setGsmBroadcastConfigResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setGsmBroadcastActivationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setGsmBroadcastActivationResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setGsmBroadcastActivationResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setGsmBroadcastActivationResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCdmaBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getCdmaBroadcastConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<CdmaBroadcastSmsConfigInfo> configs;
+
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_CDMA_BroadcastSmsConfigInfo *) != 0) {
+ RLOGE("getCdmaBroadcastConfigResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int num = responseLen / sizeof(RIL_CDMA_BroadcastSmsConfigInfo *);
+ configs.resize(num);
+ for (int i = 0 ; i < num; i++) {
+ RIL_CDMA_BroadcastSmsConfigInfo *resp =
+ ((RIL_CDMA_BroadcastSmsConfigInfo **) response)[i];
+ configs[i].serviceCategory = resp->service_category;
+ configs[i].language = resp->language;
+ configs[i].selected = resp->selected == 1 ? true : false;
+ }
+ }
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getCdmaBroadcastConfigResponse(responseInfo,
+ configs);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCdmaBroadcastConfigResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCdmaBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setCdmaBroadcastConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setCdmaBroadcastConfigResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCdmaBroadcastConfigResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCdmaBroadcastActivationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setCdmaBroadcastActivationResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setCdmaBroadcastActivationResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCdmaBroadcastActivationResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCDMASubscriptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getCDMASubscriptionResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ int numStrings = responseLen / sizeof(char *);
+ hidl_string emptyString;
+ if (response == NULL || numStrings != 5) {
+ RLOGE("getOperatorResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getCDMASubscriptionResponse(
+ responseInfo, emptyString, emptyString, emptyString, emptyString, emptyString);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ char **resp = (char **) response;
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getCDMASubscriptionResponse(
+ responseInfo,
+ convertCharPtrToHidlString(resp[0]),
+ convertCharPtrToHidlString(resp[1]),
+ convertCharPtrToHidlString(resp[2]),
+ convertCharPtrToHidlString(resp[3]),
+ convertCharPtrToHidlString(resp[4]));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ }
+ } else {
+ RLOGE("getCDMASubscriptionResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::writeSmsToRuimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("writeSmsToRuimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->writeSmsToRuimResponse(responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("writeSmsToRuimResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::deleteSmsOnRuimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("deleteSmsOnRuimResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->deleteSmsOnRuimResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("deleteSmsOnRuimResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getDeviceIdentityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getDeviceIdentityResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ int numStrings = responseLen / sizeof(char *);
+ hidl_string emptyString;
+ if (response == NULL || numStrings != 4) {
+ RLOGE("getDeviceIdentityResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getDeviceIdentityResponse(responseInfo,
+ emptyString, emptyString, emptyString, emptyString);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ char **resp = (char **) response;
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getDeviceIdentityResponse(responseInfo,
+ convertCharPtrToHidlString(resp[0]),
+ convertCharPtrToHidlString(resp[1]),
+ convertCharPtrToHidlString(resp[2]),
+ convertCharPtrToHidlString(resp[3]));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ }
+ } else {
+ RLOGE("getDeviceIdentityResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::exitEmergencyCallbackModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("exitEmergencyCallbackModeResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->exitEmergencyCallbackModeResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("exitEmergencyCallbackModeResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getSmscAddressResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getSmscAddressResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getSmscAddressResponse(responseInfo,
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getSmscAddressResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setSmscAddressResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setSmscAddressResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setSmscAddressResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setSmscAddressResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::reportSmsMemoryStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("reportSmsMemoryStatusResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->reportSmsMemoryStatusResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("reportSmsMemoryStatusResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::reportStkServiceIsRunningResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("reportStkServiceIsRunningResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->
+ reportStkServiceIsRunningResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("reportStkServiceIsRunningResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCdmaSubscriptionSourceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getCdmaSubscriptionSourceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getCdmaSubscriptionSourceResponse(
+ responseInfo, (CdmaSubscriptionSource) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCdmaSubscriptionSourceResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::requestIsimAuthenticationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("requestIsimAuthenticationResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->requestIsimAuthenticationResponse(
+ responseInfo,
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("requestIsimAuthenticationResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::acknowledgeIncomingGsmSmsWithPduResponse(int slotId,
+ int responseType,
+ int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("acknowledgeIncomingGsmSmsWithPduResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->acknowledgeIncomingGsmSmsWithPduResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("acknowledgeIncomingGsmSmsWithPduResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendEnvelopeWithStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendEnvelopeWithStatusResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ IccIoResult result = responseIccIo(responseInfo, serial, responseType, e,
+ response, responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendEnvelopeWithStatusResponse(responseInfo,
+ result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendEnvelopeWithStatusResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getVoiceRadioTechnologyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getVoiceRadioTechnologyResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getVoiceRadioTechnologyResponse(
+ responseInfo, (RadioTechnology) ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getVoiceRadioTechnologyResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getCellInfoListResponse(int slotId,
+ int responseType,
+ int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("getCellInfoListResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ hidl_vec<CellInfo> ret;
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_CellInfo_v12) != 0) {
+ RLOGE("getCellInfoListResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilCellInfoListToHal(response, responseLen, ret);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getCellInfoListResponse(
+ responseInfo, ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getCellInfoListResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCellInfoListRateResponse(int slotId,
+ int responseType,
+ int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("setCellInfoListRateResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setCellInfoListRateResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCellInfoListRateResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setInitialAttachApnResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setInitialAttachApnResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setInitialAttachApnResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setInitialAttachApnResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getImsRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getImsRegistrationStateResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ bool isRegistered = false;
+ int ratFamily = 0;
+ int numInts = responseLen / sizeof(int);
+ if (response == NULL || numInts != 2) {
+ RLOGE("getImsRegistrationStateResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ int *pInt = (int *) response;
+ isRegistered = pInt[0] == 1 ? true : false;
+ ratFamily = pInt[1];
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getImsRegistrationStateResponse(
+ responseInfo, isRegistered, (RadioTechnologyFamily) ratFamily);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getImsRegistrationStateResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendImsSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("sendImsSmsResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ SendSmsResult result = makeSendSmsResult(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendImsSmsResponse(responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendSmsResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::iccTransmitApduBasicChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("iccTransmitApduBasicChannelResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ IccIoResult result = responseIccIo(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->iccTransmitApduBasicChannelResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("iccTransmitApduBasicChannelResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::iccOpenLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("iccOpenLogicalChannelResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ int channelId = -1;
+ hidl_vec<int8_t> selectResponse;
+ int numInts = responseLen / sizeof(int);
+ if (response == NULL || responseLen % sizeof(int) != 0) {
+ RLOGE("iccOpenLogicalChannelResponse Invalid response: NULL");
+ if (response != NULL) {
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ }
+ } else {
+ int *pInt = (int *) response;
+ channelId = pInt[0];
+ selectResponse.resize(numInts - 1);
+ for (int i = 1; i < numInts; i++) {
+ selectResponse[i - 1] = (int8_t) pInt[i];
+ }
+ }
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->iccOpenLogicalChannelResponse(responseInfo,
+ channelId, selectResponse);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("iccOpenLogicalChannelResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::iccCloseLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("iccCloseLogicalChannelResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->iccCloseLogicalChannelResponse(
+ responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("iccCloseLogicalChannelResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::iccTransmitApduLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("iccTransmitApduLogicalChannelResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ IccIoResult result = responseIccIo(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->iccTransmitApduLogicalChannelResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("iccTransmitApduLogicalChannelResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::nvReadItemResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("nvReadItemResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->nvReadItemResponse(
+ responseInfo,
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("nvReadItemResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::nvWriteItemResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("nvWriteItemResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->nvWriteItemResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("nvWriteItemResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::nvWriteCdmaPrlResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("nvWriteCdmaPrlResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->nvWriteCdmaPrlResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("nvWriteCdmaPrlResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::nvResetConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("nvResetConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->nvResetConfigResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("nvResetConfigResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setUiccSubscriptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setUiccSubscriptionResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setUiccSubscriptionResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setUiccSubscriptionResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setDataAllowedResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setDataAllowedResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setDataAllowedResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setDataAllowedResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getHardwareConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getHardwareConfigResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ hidl_vec<HardwareConfig> result;
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_HardwareConfig) != 0) {
+ RLOGE("hardwareConfigChangedInd: invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilHardwareConfigListToHal(response, responseLen, result);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getHardwareConfigResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getHardwareConfigResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::requestIccSimAuthenticationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("requestIccSimAuthenticationResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ IccIoResult result = responseIccIo(responseInfo, serial, responseType, e, response,
+ responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->requestIccSimAuthenticationResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("requestIccSimAuthenticationResponse: radioService[%d]->mRadioResponse "
+ "== NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setDataProfileResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setDataProfileResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setDataProfileResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setDataProfileResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::requestShutdownResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("requestShutdownResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->requestShutdownResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("requestShutdownResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+void responseRadioCapability(RadioResponseInfo& responseInfo, int serial,
+ int responseType, RIL_Errno e, void *response, size_t responseLen, RadioCapability& rc) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ if (response == NULL || responseLen != sizeof(RIL_RadioCapability)) {
+ RLOGE("responseRadioCapability: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ rc.logicalModemUuid = hidl_string();
+ } else {
+ convertRilRadioCapabilityToHal(response, responseLen, rc);
+ }
+}
+
+int radio_1_4::getRadioCapabilityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getRadioCapabilityResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ RadioCapability result = {};
+ responseRadioCapability(responseInfo, serial, responseType, e, response, responseLen,
+ result);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->getRadioCapabilityResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getRadioCapabilityResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setRadioCapabilityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setRadioCapabilityResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ RadioCapability result = {};
+ responseRadioCapability(responseInfo, serial, responseType, e, response, responseLen,
+ result);
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->setRadioCapabilityResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setRadioCapabilityResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+LceStatusInfo responseLceStatusInfo(RadioResponseInfo& responseInfo, int serial, int responseType,
+ RIL_Errno e, void *response, size_t responseLen) {
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ LceStatusInfo result = {};
+
+ if (response == NULL || responseLen != sizeof(RIL_LceStatusInfo)) {
+ RLOGE("Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ RIL_LceStatusInfo *resp = (RIL_LceStatusInfo *) response;
+ result.lceStatus = (LceStatus) resp->lce_status;
+ result.actualIntervalMs = (uint8_t) resp->actual_interval_ms;
+ }
+ return result;
+}
+
+int radio_1_4::startLceServiceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("startLceServiceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ LceStatusInfo result = responseLceStatusInfo(responseInfo, serial, responseType, e,
+ response, responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->startLceServiceResponse(responseInfo,
+ result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("startLceServiceResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stopLceServiceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("stopLceServiceResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ LceStatusInfo result = responseLceStatusInfo(responseInfo, serial, responseType, e,
+ response, responseLen);
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->stopLceServiceResponse(responseInfo,
+ result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stopLceServiceResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::pullLceDataResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("pullLceDataResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ LceDataInfo result = {};
+ if (response == NULL || responseLen != sizeof(RIL_LceDataInfo)) {
+ RLOGE("pullLceDataResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilLceDataInfoToHal(response, responseLen, result);
+ }
+
+ Return<void> retStatus = radioService[slotId]->mRadioResponse->pullLceDataResponse(
+ responseInfo, result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("pullLceDataResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getModemActivityInfoResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getModemActivityInfoResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ ActivityStatsInfo info;
+ if (response == NULL || responseLen != sizeof(RIL_ActivityStatsInfo)) {
+ RLOGE("getModemActivityInfoResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ RIL_ActivityStatsInfo *resp = (RIL_ActivityStatsInfo *)response;
+ info.sleepModeTimeMs = resp->sleep_mode_time_ms;
+ info.idleModeTimeMs = resp->idle_mode_time_ms;
+ for(int i = 0; i < RIL_NUM_TX_POWER_LEVELS; i++) {
+ info.txmModetimeMs[i] = resp->tx_mode_time_ms[i];
+ }
+ info.rxModeTimeMs = resp->rx_mode_time_ms;
+ }
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getModemActivityInfoResponse(responseInfo,
+ info);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getModemActivityInfoResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setAllowedCarriersResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setAllowedCarriersResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ int ret = responseInt(responseInfo, serial, responseType, e, response, responseLen);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setAllowedCarriersResponse(responseInfo,
+ ret);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setAllowedCarriersResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::getAllowedCarriersResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("getAllowedCarriersResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ CarrierRestrictions carrierInfo = {};
+ bool allAllowed = true;
+ if (response == NULL) {
+#if VDBG
+ RLOGD("getAllowedCarriersResponse response is NULL: all allowed");
+#endif
+ carrierInfo.allowedCarriers.resize(0);
+ carrierInfo.excludedCarriers.resize(0);
+ } else if (responseLen != sizeof(RIL_CarrierRestrictions)) {
+ RLOGE("getAllowedCarriersResponse Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ RIL_CarrierRestrictions *pCr = (RIL_CarrierRestrictions *)response;
+ if (pCr->len_allowed_carriers > 0 || pCr->len_excluded_carriers > 0) {
+ allAllowed = false;
+ }
+
+ carrierInfo.allowedCarriers.resize(pCr->len_allowed_carriers);
+ for(int i = 0; i < pCr->len_allowed_carriers; i++) {
+ RIL_Carrier *carrier = pCr->allowed_carriers + i;
+ carrierInfo.allowedCarriers[i].mcc = convertCharPtrToHidlString(carrier->mcc);
+ carrierInfo.allowedCarriers[i].mnc = convertCharPtrToHidlString(carrier->mnc);
+ carrierInfo.allowedCarriers[i].matchType = (CarrierMatchType) carrier->match_type;
+ carrierInfo.allowedCarriers[i].matchData =
+ convertCharPtrToHidlString(carrier->match_data);
+ }
+
+ carrierInfo.excludedCarriers.resize(pCr->len_excluded_carriers);
+ for(int i = 0; i < pCr->len_excluded_carriers; i++) {
+ RIL_Carrier *carrier = pCr->excluded_carriers + i;
+ carrierInfo.excludedCarriers[i].mcc = convertCharPtrToHidlString(carrier->mcc);
+ carrierInfo.excludedCarriers[i].mnc = convertCharPtrToHidlString(carrier->mnc);
+ carrierInfo.excludedCarriers[i].matchType = (CarrierMatchType) carrier->match_type;
+ carrierInfo.excludedCarriers[i].matchData =
+ convertCharPtrToHidlString(carrier->match_data);
+ }
+ }
+
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->getAllowedCarriersResponse(responseInfo,
+ allAllowed, carrierInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("getAllowedCarriersResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendDeviceStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen) {
+#if VDBG
+ RLOGD("sendDeviceStateResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->sendDeviceStateResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("sendDeviceStateResponse: radioService[%d]->mRadioResponse == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setCarrierInfoForImsiEncryptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+ RLOGD("setCarrierInfoForImsiEncryptionResponse: serial %d", serial);
+ if (radioService[slotId]->mRadioResponseV1_4 != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus = radioService[slotId]->mRadioResponseV1_4->
+ setCarrierInfoForImsiEncryptionResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setCarrierInfoForImsiEncryptionResponse: radioService[%d]->mRadioResponseV1_4 == "
+ "NULL", slotId);
+ }
+ return 0;
+}
+
+int radio_1_4::setIndicationFilterResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen) {
+#if VDBG
+ RLOGD("setIndicationFilterResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setIndicationFilterResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("setIndicationFilterResponse: radioService[%d]->mRadioResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::setSimCardPowerResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("setSimCardPowerResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponse != NULL
+ || radioService[slotId]->mRadioResponseV1_4 != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ if (radioService[slotId]->mRadioResponseV1_4 != NULL) {
+ Return<void> retStatus = radioService[slotId]->mRadioResponseV1_4->
+ setSimCardPowerResponse_1_1(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGD("setSimCardPowerResponse: radioService[%d]->mRadioResponseV1_4 == NULL",
+ slotId);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponse->setSimCardPowerResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ }
+ } else {
+ RLOGE("setSimCardPowerResponse: radioService[%d]->mRadioResponse == NULL && "
+ "radioService[%d]->mRadioResponseV1_4 == NULL", slotId, slotId);
+ }
+ return 0;
+}
+
+int radio_1_4::startNetworkScanResponse(int slotId, int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("startNetworkScanResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponseV1_4 != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponseV1_4->startNetworkScanResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("startNetworkScanResponse: radioService[%d]->mRadioResponseV1_4 == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stopNetworkScanResponse(int slotId, int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("stopNetworkScanResponse: serial %d", serial);
+#endif
+
+ if (radioService[slotId]->mRadioResponseV1_4 != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ Return<void> retStatus
+ = radioService[slotId]->mRadioResponseV1_4->stopNetworkScanResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stopNetworkScanResponse: radioService[%d]->mRadioResponseV1_4 == NULL", slotId);
+ }
+
+ return 0;
+}
+
+void convertRilKeepaliveStatusToHal(const RIL_KeepaliveStatus *rilStatus,
+ V1_1::KeepaliveStatus& halStatus) {
+ halStatus.sessionHandle = rilStatus->sessionHandle;
+ halStatus.code = static_cast<V1_1::KeepaliveStatusCode>(rilStatus->code);
+}
+
+int radio_1_4::startKeepaliveResponse(int slotId, int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("%s(): %d", __FUNCTION__, serial);
+#endif
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ // If we don't have a radio service, there's nothing we can do
+ if (radioService[slotId]->mRadioResponseV1_4 == NULL) {
+ RLOGE("%s: radioService[%d]->mRadioResponseV1_4 == NULL", __FUNCTION__, slotId);
+ return 0;
+ }
+
+ V1_1::KeepaliveStatus ks = {};
+ if (response == NULL || responseLen != sizeof(V1_1::KeepaliveStatus)) {
+ RLOGE("%s: invalid response - %d", __FUNCTION__, static_cast<int>(e));
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ convertRilKeepaliveStatusToHal(static_cast<RIL_KeepaliveStatus*>(response), ks);
+ }
+
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponseV1_4->startKeepaliveResponse(responseInfo, ks);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ return 0;
+}
+
+int radio_1_4::stopKeepaliveResponse(int slotId, int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("%s(): %d", __FUNCTION__, serial);
+#endif
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+
+ // If we don't have a radio service, there's nothing we can do
+ if (radioService[slotId]->mRadioResponseV1_4 == NULL) {
+ RLOGE("%s: radioService[%d]->mRadioResponseV1_4 == NULL", __FUNCTION__, slotId);
+ return 0;
+ }
+
+ Return<void> retStatus =
+ radioService[slotId]->mRadioResponseV1_4->stopKeepaliveResponse(responseInfo);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ return 0;
+}
+
+int radio_1_4::sendRequestRawResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendRequestRawResponse: serial %d", serial);
+#endif
+
+ if (!kOemHookEnabled) return 0;
+
+ if (oemHookService[slotId]->mOemHookResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<uint8_t> data;
+
+ if (response == NULL) {
+ RLOGE("sendRequestRawResponse: Invalid response");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ data.setToExternal((uint8_t *) response, responseLen);
+ }
+ Return<void> retStatus = oemHookService[slotId]->mOemHookResponse->
+ sendRequestRawResponse(responseInfo, data);
+ checkReturnStatus(slotId, retStatus, false);
+ } else {
+ RLOGE("sendRequestRawResponse: oemHookService[%d]->mOemHookResponse == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::sendRequestStringsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen) {
+#if VDBG
+ RLOGD("sendRequestStringsResponse: serial %d", serial);
+#endif
+
+ if (!kOemHookEnabled) return 0;
+
+ if (oemHookService[slotId]->mOemHookResponse != NULL) {
+ RadioResponseInfo responseInfo = {};
+ populateResponseInfo(responseInfo, serial, responseType, e);
+ hidl_vec<hidl_string> data;
+
+ if ((response == NULL && responseLen != 0) || responseLen % sizeof(char *) != 0) {
+ RLOGE("sendRequestStringsResponse Invalid response: NULL");
+ if (e == RIL_E_SUCCESS) responseInfo.error = RadioError::INVALID_RESPONSE;
+ } else {
+ char **resp = (char **) response;
+ int numStrings = responseLen / sizeof(char *);
+ data.resize(numStrings);
+ for (int i = 0; i < numStrings; i++) {
+ data[i] = convertCharPtrToHidlString(resp[i]);
+ }
+ }
+ Return<void> retStatus
+ = oemHookService[slotId]->mOemHookResponse->sendRequestStringsResponse(
+ responseInfo, data);
+ checkReturnStatus(slotId, retStatus, false);
+ } else {
+ RLOGE("sendRequestStringsResponse: oemHookService[%d]->mOemHookResponse == "
+ "NULL", slotId);
+ }
+
+ return 0;
+}
+
+/***************************************************************************************************
+ * INDICATION FUNCTIONS
+ * The below function handle unsolicited messages coming from the Radio
+ * (messages for which there is no pending request)
+ **************************************************************************************************/
+
+RadioIndicationType convertIntToRadioIndicationType(int indicationType) {
+ return indicationType == RESPONSE_UNSOLICITED ? (RadioIndicationType::UNSOLICITED) :
+ (RadioIndicationType::UNSOLICITED_ACK_EXP);
+}
+
+int radio_1_4::radioStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ RadioState radioState =
+ (RadioState) CALL_ONSTATEREQUEST(slotId);
+ RLOGD("radioStateChangedInd: radioState %d", radioState);
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->radioStateChanged(
+ convertIntToRadioIndicationType(indicationType), radioState);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("radioStateChangedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::callStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("callStateChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->callStateChanged(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("callStateChangedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::networkStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("networkStateChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->networkStateChanged(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("networkStateChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+uint8_t hexCharToInt(uint8_t c) {
+ if (c >= '0' && c <= '9') return (c - '0');
+ if (c >= 'A' && c <= 'F') return (c - 'A' + 10);
+ if (c >= 'a' && c <= 'f') return (c - 'a' + 10);
+
+ return INVALID_HEX_CHAR;
+}
+
+uint8_t * convertHexStringToBytes(void *response, size_t responseLen) {
+ if (responseLen % 2 != 0) {
+ return NULL;
+ }
+
+ uint8_t *bytes = (uint8_t *)calloc(responseLen/2, sizeof(uint8_t));
+ if (bytes == NULL) {
+ RLOGE("convertHexStringToBytes: cannot allocate memory for bytes string");
+ return NULL;
+ }
+ uint8_t *hexString = (uint8_t *)response;
+
+ for (size_t i = 0; i < responseLen; i += 2) {
+ uint8_t hexChar1 = hexCharToInt(hexString[i]);
+ uint8_t hexChar2 = hexCharToInt(hexString[i + 1]);
+
+ if (hexChar1 == INVALID_HEX_CHAR || hexChar2 == INVALID_HEX_CHAR) {
+ RLOGE("convertHexStringToBytes: invalid hex char %d %d",
+ hexString[i], hexString[i + 1]);
+ free(bytes);
+ return NULL;
+ }
+ bytes[i/2] = ((hexChar1 << 4) | hexChar2);
+ }
+
+ return bytes;
+}
+
+int radio_1_4::newSmsInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("newSmsInd: invalid response");
+ return 0;
+ }
+
+ uint8_t *bytes = convertHexStringToBytes(response, responseLen);
+ if (bytes == NULL) {
+ RLOGE("newSmsInd: convertHexStringToBytes failed");
+ return 0;
+ }
+
+ hidl_vec<uint8_t> pdu;
+ pdu.setToExternal(bytes, responseLen/2);
+#if VDBG
+ RLOGD("newSmsInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->newSms(
+ convertIntToRadioIndicationType(indicationType), pdu);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ free(bytes);
+ } else {
+ RLOGE("newSmsInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::newSmsStatusReportInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("newSmsStatusReportInd: invalid response");
+ return 0;
+ }
+
+ uint8_t *bytes = convertHexStringToBytes(response, responseLen);
+ if (bytes == NULL) {
+ RLOGE("newSmsStatusReportInd: convertHexStringToBytes failed");
+ return 0;
+ }
+
+ hidl_vec<uint8_t> pdu;
+ pdu.setToExternal(bytes, responseLen/2);
+#if VDBG
+ RLOGD("newSmsStatusReportInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->newSmsStatusReport(
+ convertIntToRadioIndicationType(indicationType), pdu);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ free(bytes);
+ } else {
+ RLOGE("newSmsStatusReportInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::newSmsOnSimInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("newSmsOnSimInd: invalid response");
+ return 0;
+ }
+ int32_t recordNumber = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("newSmsOnSimInd: slotIndex %d", recordNumber);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->newSmsOnSim(
+ convertIntToRadioIndicationType(indicationType), recordNumber);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("newSmsOnSimInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::onUssdInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != 2 * sizeof(char *)) {
+ RLOGE("onUssdInd: invalid response");
+ return 0;
+ }
+ char **strings = (char **) response;
+ char *mode = strings[0];
+ hidl_string msg = convertCharPtrToHidlString(strings[1]);
+ UssdModeType modeType = (UssdModeType) atoi(mode);
+#if VDBG
+ RLOGD("onUssdInd: mode %s", mode);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->onUssd(
+ convertIntToRadioIndicationType(indicationType), modeType, msg);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("onUssdInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::nitzTimeReceivedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("nitzTimeReceivedInd: invalid response");
+ return 0;
+ }
+ hidl_string nitzTime = convertCharPtrToHidlString((char *) response);
+#if VDBG
+ RLOGD("nitzTimeReceivedInd: nitzTime %s receivedTime %" PRId64, nitzTime.c_str(),
+ nitzTimeReceived[slotId]);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->nitzTimeReceived(
+ convertIntToRadioIndicationType(indicationType), nitzTime,
+ nitzTimeReceived[slotId]);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("nitzTimeReceivedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ return -1;
+ }
+
+ return 0;
+}
+
+void convertRilSignalStrengthToHal(void *response, size_t responseLen,
+ SignalStrength& signalStrength) {
+ RIL_SignalStrength_v10 *rilSignalStrength = (RIL_SignalStrength_v10 *) response;
+
+ // Fixup LTE for backwards compatibility
+ // signalStrength: -1 -> 99
+ if (rilSignalStrength->LTE_SignalStrength.signalStrength == -1) {
+ rilSignalStrength->LTE_SignalStrength.signalStrength = 99;
+ }
+ // rsrp: -1 -> INT_MAX all other negative value to positive.
+ // So remap here
+ if (rilSignalStrength->LTE_SignalStrength.rsrp == -1) {
+ rilSignalStrength->LTE_SignalStrength.rsrp = INT_MAX;
+ } else if (rilSignalStrength->LTE_SignalStrength.rsrp < -1) {
+ rilSignalStrength->LTE_SignalStrength.rsrp = -rilSignalStrength->LTE_SignalStrength.rsrp;
+ }
+ // rsrq: -1 -> INT_MAX
+ if (rilSignalStrength->LTE_SignalStrength.rsrq == -1) {
+ rilSignalStrength->LTE_SignalStrength.rsrq = INT_MAX;
+ }
+ // Not remapping rssnr is already using INT_MAX
+ // cqi: -1 -> INT_MAX
+ if (rilSignalStrength->LTE_SignalStrength.cqi == -1) {
+ rilSignalStrength->LTE_SignalStrength.cqi = INT_MAX;
+ }
+
+ signalStrength.gw.signalStrength = rilSignalStrength->GW_SignalStrength.signalStrength;
+ signalStrength.gw.bitErrorRate = rilSignalStrength->GW_SignalStrength.bitErrorRate;
+ // RIL_SignalStrength_v10 not support gw.timingAdvance. Set to INT_MAX as
+ // invalid value.
+ signalStrength.gw.timingAdvance = INT_MAX;
+
+ signalStrength.cdma.dbm = rilSignalStrength->CDMA_SignalStrength.dbm;
+ signalStrength.cdma.ecio = rilSignalStrength->CDMA_SignalStrength.ecio;
+ signalStrength.evdo.dbm = rilSignalStrength->EVDO_SignalStrength.dbm;
+ signalStrength.evdo.ecio = rilSignalStrength->EVDO_SignalStrength.ecio;
+ signalStrength.evdo.signalNoiseRatio =
+ rilSignalStrength->EVDO_SignalStrength.signalNoiseRatio;
+ signalStrength.lte.signalStrength = rilSignalStrength->LTE_SignalStrength.signalStrength;
+ signalStrength.lte.rsrp = rilSignalStrength->LTE_SignalStrength.rsrp;
+ signalStrength.lte.rsrq = rilSignalStrength->LTE_SignalStrength.rsrq;
+ signalStrength.lte.rssnr = rilSignalStrength->LTE_SignalStrength.rssnr;
+ signalStrength.lte.cqi = rilSignalStrength->LTE_SignalStrength.cqi;
+ signalStrength.lte.timingAdvance = rilSignalStrength->LTE_SignalStrength.timingAdvance;
+ signalStrength.tdScdma.rscp = rilSignalStrength->TD_SCDMA_SignalStrength.rscp;
+}
+
+int radio_1_4::currentSignalStrengthInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_SignalStrength_v10)) {
+ RLOGE("currentSignalStrengthInd: invalid response");
+ return 0;
+ }
+
+ SignalStrength signalStrength = {};
+ convertRilSignalStrengthToHal(response, responseLen, signalStrength);
+
+#if VDBG
+ RLOGD("currentSignalStrengthInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->currentSignalStrength(
+ convertIntToRadioIndicationType(indicationType), signalStrength);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("currentSignalStrengthInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+void convertRilDataCallToHal(RIL_Data_Call_Response_v11 *dcResponse,
+ SetupDataCallResult& dcResult) {
+ dcResult.status = (DataCallFailCause) dcResponse->status;
+ dcResult.suggestedRetryTime = dcResponse->suggestedRetryTime;
+ dcResult.cid = dcResponse->cid;
+ dcResult.active = dcResponse->active;
+ dcResult.type = convertCharPtrToHidlString(dcResponse->type);
+ dcResult.ifname = convertCharPtrToHidlString(dcResponse->ifname);
+ dcResult.addresses = convertCharPtrToHidlString(dcResponse->addresses);
+ dcResult.dnses = convertCharPtrToHidlString(dcResponse->dnses);
+ dcResult.gateways = convertCharPtrToHidlString(dcResponse->gateways);
+ dcResult.pcscf = convertCharPtrToHidlString(dcResponse->pcscf);
+ dcResult.mtu = dcResponse->mtu;
+}
+
+void convertRilDataCallListToHal(void *response, size_t responseLen,
+ hidl_vec<SetupDataCallResult>& dcResultList) {
+ int num = responseLen / sizeof(RIL_Data_Call_Response_v11);
+
+ RIL_Data_Call_Response_v11 *dcResponse = (RIL_Data_Call_Response_v11 *) response;
+ dcResultList.resize(num);
+ for (int i = 0; i < num; i++) {
+ convertRilDataCallToHal(&dcResponse[i], dcResultList[i]);
+ }
+}
+
+int radio_1_4::dataCallListChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_Data_Call_Response_v11) != 0) {
+ RLOGE("dataCallListChangedInd: invalid response");
+ return 0;
+ }
+ hidl_vec<SetupDataCallResult> dcList;
+ convertRilDataCallListToHal(response, responseLen, dcList);
+#if VDBG
+ RLOGD("dataCallListChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->dataCallListChanged(
+ convertIntToRadioIndicationType(indicationType), dcList);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("dataCallListChangedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::suppSvcNotifyInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_SuppSvcNotification)) {
+ RLOGE("suppSvcNotifyInd: invalid response");
+ return 0;
+ }
+
+ SuppSvcNotification suppSvc = {};
+ RIL_SuppSvcNotification *ssn = (RIL_SuppSvcNotification *) response;
+ suppSvc.isMT = ssn->notificationType;
+ suppSvc.code = ssn->code;
+ suppSvc.index = ssn->index;
+ suppSvc.type = ssn->type;
+ suppSvc.number = convertCharPtrToHidlString(ssn->number);
+
+#if VDBG
+ RLOGD("suppSvcNotifyInd: isMT %d code %d index %d type %d",
+ suppSvc.isMT, suppSvc.code, suppSvc.index, suppSvc.type);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->suppSvcNotify(
+ convertIntToRadioIndicationType(indicationType), suppSvc);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("suppSvcNotifyInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stkSessionEndInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("stkSessionEndInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->stkSessionEnd(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stkSessionEndInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stkProactiveCommandInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("stkProactiveCommandInd: invalid response");
+ return 0;
+ }
+#if VDBG
+ RLOGD("stkProactiveCommandInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->stkProactiveCommand(
+ convertIntToRadioIndicationType(indicationType),
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stkProactiveCommandInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stkEventNotifyInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("stkEventNotifyInd: invalid response");
+ return 0;
+ }
+#if VDBG
+ RLOGD("stkEventNotifyInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->stkEventNotify(
+ convertIntToRadioIndicationType(indicationType),
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stkEventNotifyInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stkCallSetupInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("stkCallSetupInd: invalid response");
+ return 0;
+ }
+ int32_t timeout = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("stkCallSetupInd: timeout %d", timeout);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->stkCallSetup(
+ convertIntToRadioIndicationType(indicationType), timeout);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stkCallSetupInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::simSmsStorageFullInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("simSmsStorageFullInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->simSmsStorageFull(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("simSmsStorageFullInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::simRefreshInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_SimRefreshResponse_v7)) {
+ RLOGE("simRefreshInd: invalid response");
+ return 0;
+ }
+
+ SimRefreshResult refreshResult = {};
+ RIL_SimRefreshResponse_v7 *simRefreshResponse = ((RIL_SimRefreshResponse_v7 *) response);
+ refreshResult.type =
+ (V1_0::SimRefreshType) simRefreshResponse->result;
+ refreshResult.efId = simRefreshResponse->ef_id;
+ refreshResult.aid = convertCharPtrToHidlString(simRefreshResponse->aid);
+
+#if VDBG
+ RLOGD("simRefreshInd: type %d efId %d", refreshResult.type, refreshResult.efId);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->simRefresh(
+ convertIntToRadioIndicationType(indicationType), refreshResult);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("simRefreshInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+void convertRilCdmaSignalInfoRecordToHal(RIL_CDMA_SignalInfoRecord *signalInfoRecord,
+ CdmaSignalInfoRecord& record) {
+ record.isPresent = signalInfoRecord->isPresent;
+ record.signalType = signalInfoRecord->signalType;
+ record.alertPitch = signalInfoRecord->alertPitch;
+ record.signal = signalInfoRecord->signal;
+}
+
+int radio_1_4::callRingInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ bool isGsm;
+ CdmaSignalInfoRecord record = {};
+ if (response == NULL || responseLen == 0) {
+ isGsm = true;
+ } else {
+ isGsm = false;
+ if (responseLen != sizeof (RIL_CDMA_SignalInfoRecord)) {
+ RLOGE("callRingInd: invalid response");
+ return 0;
+ }
+ convertRilCdmaSignalInfoRecordToHal((RIL_CDMA_SignalInfoRecord *) response, record);
+ }
+
+#if VDBG
+ RLOGD("callRingInd: isGsm %d", isGsm);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->callRing(
+ convertIntToRadioIndicationType(indicationType), isGsm, record);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("callRingInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::simStatusChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("simStatusChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->simStatusChanged(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("simStatusChangedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaNewSmsInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_CDMA_SMS_Message)) {
+ RLOGE("cdmaNewSmsInd: invalid response");
+ return 0;
+ }
+
+ CdmaSmsMessage msg = {};
+ RIL_CDMA_SMS_Message *rilMsg = (RIL_CDMA_SMS_Message *) response;
+ msg.teleserviceId = rilMsg->uTeleserviceID;
+ msg.isServicePresent = rilMsg->bIsServicePresent;
+ msg.serviceCategory = rilMsg->uServicecategory;
+ msg.address.digitMode =
+ (V1_0::CdmaSmsDigitMode) rilMsg->sAddress.digit_mode;
+ msg.address.numberMode =
+ (V1_0::CdmaSmsNumberMode) rilMsg->sAddress.number_mode;
+ msg.address.numberType =
+ (V1_0::CdmaSmsNumberType) rilMsg->sAddress.number_type;
+ msg.address.numberPlan =
+ (V1_0::CdmaSmsNumberPlan) rilMsg->sAddress.number_plan;
+
+ int digitLimit = MIN((rilMsg->sAddress.number_of_digits), RIL_CDMA_SMS_ADDRESS_MAX);
+ msg.address.digits.setToExternal(rilMsg->sAddress.digits, digitLimit);
+
+ msg.subAddress.subaddressType = (V1_0::CdmaSmsSubaddressType)
+ rilMsg->sSubAddress.subaddressType;
+ msg.subAddress.odd = rilMsg->sSubAddress.odd;
+
+ digitLimit= MIN((rilMsg->sSubAddress.number_of_digits), RIL_CDMA_SMS_SUBADDRESS_MAX);
+ msg.subAddress.digits.setToExternal(rilMsg->sSubAddress.digits, digitLimit);
+
+ digitLimit = MIN((rilMsg->uBearerDataLen), RIL_CDMA_SMS_BEARER_DATA_MAX);
+ msg.bearerData.setToExternal(rilMsg->aBearerData, digitLimit);
+
+#if VDBG
+ RLOGD("cdmaNewSmsInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaNewSms(
+ convertIntToRadioIndicationType(indicationType), msg);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaNewSmsInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::newBroadcastSmsInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("newBroadcastSmsInd: invalid response");
+ return 0;
+ }
+
+ hidl_vec<uint8_t> data;
+ data.setToExternal((uint8_t *) response, responseLen);
+#if VDBG
+ RLOGD("newBroadcastSmsInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->newBroadcastSms(
+ convertIntToRadioIndicationType(indicationType), data);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("newBroadcastSmsInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaRuimSmsStorageFullInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("cdmaRuimSmsStorageFullInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaRuimSmsStorageFull(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaRuimSmsStorageFullInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::restrictedStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("restrictedStateChangedInd: invalid response");
+ return 0;
+ }
+ int32_t state = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("restrictedStateChangedInd: state %d", state);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->restrictedStateChanged(
+ convertIntToRadioIndicationType(indicationType), (PhoneRestrictedState) state);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("restrictedStateChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::enterEmergencyCallbackModeInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("enterEmergencyCallbackModeInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->enterEmergencyCallbackMode(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("enterEmergencyCallbackModeInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaCallWaitingInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_CDMA_CallWaiting_v6)) {
+ RLOGE("cdmaCallWaitingInd: invalid response");
+ return 0;
+ }
+
+ CdmaCallWaiting callWaitingRecord = {};
+ RIL_CDMA_CallWaiting_v6 *callWaitingRil = ((RIL_CDMA_CallWaiting_v6 *) response);
+ callWaitingRecord.number = convertCharPtrToHidlString(callWaitingRil->number);
+ callWaitingRecord.numberPresentation =
+ (CdmaCallWaitingNumberPresentation) callWaitingRil->numberPresentation;
+ callWaitingRecord.name = convertCharPtrToHidlString(callWaitingRil->name);
+ convertRilCdmaSignalInfoRecordToHal(&callWaitingRil->signalInfoRecord,
+ callWaitingRecord.signalInfoRecord);
+ callWaitingRecord.numberType = (CdmaCallWaitingNumberType) callWaitingRil->number_type;
+ callWaitingRecord.numberPlan = (CdmaCallWaitingNumberPlan) callWaitingRil->number_plan;
+
+#if VDBG
+ RLOGD("cdmaCallWaitingInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaCallWaiting(
+ convertIntToRadioIndicationType(indicationType), callWaitingRecord);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaCallWaitingInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaOtaProvisionStatusInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("cdmaOtaProvisionStatusInd: invalid response");
+ return 0;
+ }
+ int32_t status = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("cdmaOtaProvisionStatusInd: status %d", status);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaOtaProvisionStatus(
+ convertIntToRadioIndicationType(indicationType), (CdmaOtaProvisionStatus) status);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaOtaProvisionStatusInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaInfoRecInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_CDMA_InformationRecords)) {
+ RLOGE("cdmaInfoRecInd: invalid response");
+ return 0;
+ }
+
+ CdmaInformationRecords records = {};
+ RIL_CDMA_InformationRecords *recordsRil = (RIL_CDMA_InformationRecords *) response;
+
+ char* string8 = NULL;
+ int num = MIN(recordsRil->numberOfInfoRecs, RIL_CDMA_MAX_NUMBER_OF_INFO_RECS);
+ if (recordsRil->numberOfInfoRecs > RIL_CDMA_MAX_NUMBER_OF_INFO_RECS) {
+ RLOGE("cdmaInfoRecInd: received %d recs which is more than %d, dropping "
+ "additional ones", recordsRil->numberOfInfoRecs,
+ RIL_CDMA_MAX_NUMBER_OF_INFO_RECS);
+ }
+ records.infoRec.resize(num);
+ for (int i = 0 ; i < num ; i++) {
+ CdmaInformationRecord *record = &records.infoRec[i];
+ RIL_CDMA_InformationRecord *infoRec = &recordsRil->infoRec[i];
+ record->name = (CdmaInfoRecName) infoRec->name;
+ // All vectors should be size 0 except one which will be size 1. Set everything to
+ // size 0 initially.
+ record->display.resize(0);
+ record->number.resize(0);
+ record->signal.resize(0);
+ record->redir.resize(0);
+ record->lineCtrl.resize(0);
+ record->clir.resize(0);
+ record->audioCtrl.resize(0);
+ switch (infoRec->name) {
+ case RIL_CDMA_DISPLAY_INFO_REC:
+ case RIL_CDMA_EXTENDED_DISPLAY_INFO_REC: {
+ if (infoRec->rec.display.alpha_len > CDMA_ALPHA_INFO_BUFFER_LENGTH) {
+ RLOGE("cdmaInfoRecInd: invalid display info response length %d "
+ "expected not more than %d", (int) infoRec->rec.display.alpha_len,
+ CDMA_ALPHA_INFO_BUFFER_LENGTH);
+ return 0;
+ }
+ string8 = (char*) malloc((infoRec->rec.display.alpha_len + 1) * sizeof(char));
+ if (string8 == NULL) {
+ RLOGE("cdmaInfoRecInd: Memory allocation failed for "
+ "responseCdmaInformationRecords");
+ return 0;
+ }
+ memcpy(string8, infoRec->rec.display.alpha_buf, infoRec->rec.display.alpha_len);
+ string8[(int)infoRec->rec.display.alpha_len] = '\0';
+
+ record->display.resize(1);
+ record->display[0].alphaBuf = string8;
+ free(string8);
+ string8 = NULL;
+ break;
+ }
+
+ case RIL_CDMA_CALLED_PARTY_NUMBER_INFO_REC:
+ case RIL_CDMA_CALLING_PARTY_NUMBER_INFO_REC:
+ case RIL_CDMA_CONNECTED_NUMBER_INFO_REC: {
+ if (infoRec->rec.number.len > CDMA_NUMBER_INFO_BUFFER_LENGTH) {
+ RLOGE("cdmaInfoRecInd: invalid display info response length %d "
+ "expected not more than %d", (int) infoRec->rec.number.len,
+ CDMA_NUMBER_INFO_BUFFER_LENGTH);
+ return 0;
+ }
+ string8 = (char*) malloc((infoRec->rec.number.len + 1) * sizeof(char));
+ if (string8 == NULL) {
+ RLOGE("cdmaInfoRecInd: Memory allocation failed for "
+ "responseCdmaInformationRecords");
+ return 0;
+ }
+ memcpy(string8, infoRec->rec.number.buf, infoRec->rec.number.len);
+ string8[(int)infoRec->rec.number.len] = '\0';
+
+ record->number.resize(1);
+ record->number[0].number = string8;
+ free(string8);
+ string8 = NULL;
+ record->number[0].numberType = infoRec->rec.number.number_type;
+ record->number[0].numberPlan = infoRec->rec.number.number_plan;
+ record->number[0].pi = infoRec->rec.number.pi;
+ record->number[0].si = infoRec->rec.number.si;
+ break;
+ }
+
+ case RIL_CDMA_SIGNAL_INFO_REC: {
+ record->signal.resize(1);
+ record->signal[0].isPresent = infoRec->rec.signal.isPresent;
+ record->signal[0].signalType = infoRec->rec.signal.signalType;
+ record->signal[0].alertPitch = infoRec->rec.signal.alertPitch;
+ record->signal[0].signal = infoRec->rec.signal.signal;
+ break;
+ }
+
+ case RIL_CDMA_REDIRECTING_NUMBER_INFO_REC: {
+ if (infoRec->rec.redir.redirectingNumber.len >
+ CDMA_NUMBER_INFO_BUFFER_LENGTH) {
+ RLOGE("cdmaInfoRecInd: invalid display info response length %d "
+ "expected not more than %d\n",
+ (int)infoRec->rec.redir.redirectingNumber.len,
+ CDMA_NUMBER_INFO_BUFFER_LENGTH);
+ return 0;
+ }
+ string8 = (char*) malloc((infoRec->rec.redir.redirectingNumber.len + 1) *
+ sizeof(char));
+ if (string8 == NULL) {
+ RLOGE("cdmaInfoRecInd: Memory allocation failed for "
+ "responseCdmaInformationRecords");
+ return 0;
+ }
+ memcpy(string8, infoRec->rec.redir.redirectingNumber.buf,
+ infoRec->rec.redir.redirectingNumber.len);
+ string8[(int)infoRec->rec.redir.redirectingNumber.len] = '\0';
+
+ record->redir.resize(1);
+ record->redir[0].redirectingNumber.number = string8;
+ free(string8);
+ string8 = NULL;
+ record->redir[0].redirectingNumber.numberType =
+ infoRec->rec.redir.redirectingNumber.number_type;
+ record->redir[0].redirectingNumber.numberPlan =
+ infoRec->rec.redir.redirectingNumber.number_plan;
+ record->redir[0].redirectingNumber.pi = infoRec->rec.redir.redirectingNumber.pi;
+ record->redir[0].redirectingNumber.si = infoRec->rec.redir.redirectingNumber.si;
+ record->redir[0].redirectingReason =
+ (CdmaRedirectingReason) infoRec->rec.redir.redirectingReason;
+ break;
+ }
+
+ case RIL_CDMA_LINE_CONTROL_INFO_REC: {
+ record->lineCtrl.resize(1);
+ record->lineCtrl[0].lineCtrlPolarityIncluded =
+ infoRec->rec.lineCtrl.lineCtrlPolarityIncluded;
+ record->lineCtrl[0].lineCtrlToggle = infoRec->rec.lineCtrl.lineCtrlToggle;
+ record->lineCtrl[0].lineCtrlReverse = infoRec->rec.lineCtrl.lineCtrlReverse;
+ record->lineCtrl[0].lineCtrlPowerDenial =
+ infoRec->rec.lineCtrl.lineCtrlPowerDenial;
+ break;
+ }
+
+ case RIL_CDMA_T53_CLIR_INFO_REC: {
+ record->clir.resize(1);
+ record->clir[0].cause = infoRec->rec.clir.cause;
+ break;
+ }
+
+ case RIL_CDMA_T53_AUDIO_CONTROL_INFO_REC: {
+ record->audioCtrl.resize(1);
+ record->audioCtrl[0].upLink = infoRec->rec.audioCtrl.upLink;
+ record->audioCtrl[0].downLink = infoRec->rec.audioCtrl.downLink;
+ break;
+ }
+
+ case RIL_CDMA_T53_RELEASE_INFO_REC:
+ RLOGE("cdmaInfoRecInd: RIL_CDMA_T53_RELEASE_INFO_REC: INVALID");
+ return 0;
+
+ default:
+ RLOGE("cdmaInfoRecInd: Incorrect name value");
+ return 0;
+ }
+ }
+
+#if VDBG
+ RLOGD("cdmaInfoRecInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaInfoRec(
+ convertIntToRadioIndicationType(indicationType), records);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaInfoRecInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::indicateRingbackToneInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("indicateRingbackToneInd: invalid response");
+ return 0;
+ }
+ bool start = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("indicateRingbackToneInd: start %d", start);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->indicateRingbackTone(
+ convertIntToRadioIndicationType(indicationType), start);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("indicateRingbackToneInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::resendIncallMuteInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("resendIncallMuteInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->resendIncallMute(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("resendIncallMuteInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaSubscriptionSourceChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("cdmaSubscriptionSourceChangedInd: invalid response");
+ return 0;
+ }
+ int32_t cdmaSource = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("cdmaSubscriptionSourceChangedInd: cdmaSource %d", cdmaSource);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->
+ cdmaSubscriptionSourceChanged(convertIntToRadioIndicationType(indicationType),
+ (CdmaSubscriptionSource) cdmaSource);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaSubscriptionSourceChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::cdmaPrlChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("cdmaPrlChangedInd: invalid response");
+ return 0;
+ }
+ int32_t version = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("cdmaPrlChangedInd: version %d", version);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cdmaPrlChanged(
+ convertIntToRadioIndicationType(indicationType), version);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cdmaPrlChangedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::exitEmergencyCallbackModeInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("exitEmergencyCallbackModeInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->exitEmergencyCallbackMode(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("exitEmergencyCallbackModeInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::rilConnectedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ RLOGD("rilConnectedInd");
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->rilConnected(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("rilConnectedInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::voiceRadioTechChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("voiceRadioTechChangedInd: invalid response");
+ return 0;
+ }
+ int32_t rat = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("voiceRadioTechChangedInd: rat %d", rat);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->voiceRadioTechChanged(
+ convertIntToRadioIndicationType(indicationType), (RadioTechnology) rat);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("voiceRadioTechChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+void convertRilCellInfoListToHal(void *response, size_t responseLen, hidl_vec<CellInfo>& records) {
+ int num = responseLen / sizeof(RIL_CellInfo_v12);
+ records.resize(num);
+
+ RIL_CellInfo_v12 *rillCellInfo = (RIL_CellInfo_v12 *) response;
+ for (int i = 0; i < num; i++) {
+ records[i].cellInfoType = (CellInfoType) rillCellInfo->cellInfoType;
+ records[i].registered = rillCellInfo->registered;
+ records[i].timeStampType = (TimeStampType) rillCellInfo->timeStampType;
+ records[i].timeStamp = rillCellInfo->timeStamp;
+ // All vectors should be size 0 except one which will be size 1. Set everything to
+ // size 0 initially.
+ records[i].gsm.resize(0);
+ records[i].wcdma.resize(0);
+ records[i].cdma.resize(0);
+ records[i].lte.resize(0);
+ records[i].tdscdma.resize(0);
+ switch(rillCellInfo->cellInfoType) {
+ case RIL_CELL_INFO_TYPE_GSM: {
+ records[i].gsm.resize(1);
+ CellInfoGsm *cellInfoGsm = &records[i].gsm[0];
+ cellInfoGsm->cellIdentityGsm.mcc =
+ std::to_string(rillCellInfo->CellInfo.gsm.cellIdentityGsm.mcc);
+ cellInfoGsm->cellIdentityGsm.mnc =
+ ril::util::mnc::decode(rillCellInfo->CellInfo.gsm.cellIdentityGsm.mnc);
+ cellInfoGsm->cellIdentityGsm.lac =
+ rillCellInfo->CellInfo.gsm.cellIdentityGsm.lac;
+ cellInfoGsm->cellIdentityGsm.cid =
+ rillCellInfo->CellInfo.gsm.cellIdentityGsm.cid;
+ cellInfoGsm->cellIdentityGsm.arfcn =
+ rillCellInfo->CellInfo.gsm.cellIdentityGsm.arfcn;
+ cellInfoGsm->cellIdentityGsm.bsic =
+ rillCellInfo->CellInfo.gsm.cellIdentityGsm.bsic;
+ cellInfoGsm->signalStrengthGsm.signalStrength =
+ rillCellInfo->CellInfo.gsm.signalStrengthGsm.signalStrength;
+ cellInfoGsm->signalStrengthGsm.bitErrorRate =
+ rillCellInfo->CellInfo.gsm.signalStrengthGsm.bitErrorRate;
+ cellInfoGsm->signalStrengthGsm.timingAdvance =
+ rillCellInfo->CellInfo.gsm.signalStrengthGsm.timingAdvance;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_WCDMA: {
+ records[i].wcdma.resize(1);
+ CellInfoWcdma *cellInfoWcdma = &records[i].wcdma[0];
+ cellInfoWcdma->cellIdentityWcdma.mcc =
+ std::to_string(rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.mcc);
+ cellInfoWcdma->cellIdentityWcdma.mnc =
+ ril::util::mnc::decode(rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.mnc);
+ cellInfoWcdma->cellIdentityWcdma.lac =
+ rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.lac;
+ cellInfoWcdma->cellIdentityWcdma.cid =
+ rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.cid;
+ cellInfoWcdma->cellIdentityWcdma.psc =
+ rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.psc;
+ cellInfoWcdma->cellIdentityWcdma.uarfcn =
+ rillCellInfo->CellInfo.wcdma.cellIdentityWcdma.uarfcn;
+ cellInfoWcdma->signalStrengthWcdma.signalStrength =
+ rillCellInfo->CellInfo.wcdma.signalStrengthWcdma.signalStrength;
+ cellInfoWcdma->signalStrengthWcdma.bitErrorRate =
+ rillCellInfo->CellInfo.wcdma.signalStrengthWcdma.bitErrorRate;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_CDMA: {
+ records[i].cdma.resize(1);
+ CellInfoCdma *cellInfoCdma = &records[i].cdma[0];
+ cellInfoCdma->cellIdentityCdma.networkId =
+ rillCellInfo->CellInfo.cdma.cellIdentityCdma.networkId;
+ cellInfoCdma->cellIdentityCdma.systemId =
+ rillCellInfo->CellInfo.cdma.cellIdentityCdma.systemId;
+ cellInfoCdma->cellIdentityCdma.baseStationId =
+ rillCellInfo->CellInfo.cdma.cellIdentityCdma.basestationId;
+ cellInfoCdma->cellIdentityCdma.longitude =
+ rillCellInfo->CellInfo.cdma.cellIdentityCdma.longitude;
+ cellInfoCdma->cellIdentityCdma.latitude =
+ rillCellInfo->CellInfo.cdma.cellIdentityCdma.latitude;
+ cellInfoCdma->signalStrengthCdma.dbm =
+ rillCellInfo->CellInfo.cdma.signalStrengthCdma.dbm;
+ cellInfoCdma->signalStrengthCdma.ecio =
+ rillCellInfo->CellInfo.cdma.signalStrengthCdma.ecio;
+ cellInfoCdma->signalStrengthEvdo.dbm =
+ rillCellInfo->CellInfo.cdma.signalStrengthEvdo.dbm;
+ cellInfoCdma->signalStrengthEvdo.ecio =
+ rillCellInfo->CellInfo.cdma.signalStrengthEvdo.ecio;
+ cellInfoCdma->signalStrengthEvdo.signalNoiseRatio =
+ rillCellInfo->CellInfo.cdma.signalStrengthEvdo.signalNoiseRatio;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_LTE: {
+ records[i].lte.resize(1);
+ CellInfoLte *cellInfoLte = &records[i].lte[0];
+ cellInfoLte->cellIdentityLte.mcc =
+ std::to_string(rillCellInfo->CellInfo.lte.cellIdentityLte.mcc);
+ cellInfoLte->cellIdentityLte.mnc =
+ ril::util::mnc::decode(rillCellInfo->CellInfo.lte.cellIdentityLte.mnc);
+ cellInfoLte->cellIdentityLte.ci =
+ rillCellInfo->CellInfo.lte.cellIdentityLte.ci;
+ cellInfoLte->cellIdentityLte.pci =
+ rillCellInfo->CellInfo.lte.cellIdentityLte.pci;
+ cellInfoLte->cellIdentityLte.tac =
+ rillCellInfo->CellInfo.lte.cellIdentityLte.tac;
+ cellInfoLte->cellIdentityLte.earfcn =
+ rillCellInfo->CellInfo.lte.cellIdentityLte.earfcn;
+ cellInfoLte->signalStrengthLte.signalStrength =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.signalStrength;
+ cellInfoLte->signalStrengthLte.rsrp =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.rsrp;
+ cellInfoLte->signalStrengthLte.rsrq =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.rsrq;
+ cellInfoLte->signalStrengthLte.rssnr =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.rssnr;
+ cellInfoLte->signalStrengthLte.cqi =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.cqi;
+ cellInfoLte->signalStrengthLte.timingAdvance =
+ rillCellInfo->CellInfo.lte.signalStrengthLte.timingAdvance;
+ break;
+ }
+
+ case RIL_CELL_INFO_TYPE_TD_SCDMA: {
+ records[i].tdscdma.resize(1);
+ CellInfoTdscdma *cellInfoTdscdma = &records[i].tdscdma[0];
+ cellInfoTdscdma->cellIdentityTdscdma.mcc =
+ std::to_string(rillCellInfo->CellInfo.tdscdma.cellIdentityTdscdma.mcc);
+ cellInfoTdscdma->cellIdentityTdscdma.mnc =
+ ril::util::mnc::decode(
+ rillCellInfo->CellInfo.tdscdma.cellIdentityTdscdma.mnc);
+ cellInfoTdscdma->cellIdentityTdscdma.lac =
+ rillCellInfo->CellInfo.tdscdma.cellIdentityTdscdma.lac;
+ cellInfoTdscdma->cellIdentityTdscdma.cid =
+ rillCellInfo->CellInfo.tdscdma.cellIdentityTdscdma.cid;
+ cellInfoTdscdma->cellIdentityTdscdma.cpid =
+ rillCellInfo->CellInfo.tdscdma.cellIdentityTdscdma.cpid;
+ cellInfoTdscdma->signalStrengthTdscdma.rscp =
+ rillCellInfo->CellInfo.tdscdma.signalStrengthTdscdma.rscp;
+ break;
+ }
+ default: {
+ break;
+ }
+ }
+ rillCellInfo += 1;
+ }
+}
+
+int radio_1_4::cellInfoListInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if ((response == NULL && responseLen != 0) || responseLen % sizeof(RIL_CellInfo_v12) != 0) {
+ RLOGE("cellInfoListInd: invalid response");
+ return 0;
+ }
+
+ hidl_vec<CellInfo> records;
+ convertRilCellInfoListToHal(response, responseLen, records);
+
+#if VDBG
+ RLOGD("cellInfoListInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->cellInfoList(
+ convertIntToRadioIndicationType(indicationType), records);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("cellInfoListInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::imsNetworkStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+#if VDBG
+ RLOGD("imsNetworkStateChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->imsNetworkStateChanged(
+ convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("imsNetworkStateChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::subscriptionStatusChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("subscriptionStatusChangedInd: invalid response");
+ return 0;
+ }
+ bool activate = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("subscriptionStatusChangedInd: activate %d", activate);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->subscriptionStatusChanged(
+ convertIntToRadioIndicationType(indicationType), activate);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("subscriptionStatusChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::srvccStateNotifyInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(int)) {
+ RLOGE("srvccStateNotifyInd: invalid response");
+ return 0;
+ }
+ int32_t state = ((int32_t *) response)[0];
+#if VDBG
+ RLOGD("srvccStateNotifyInd: rat %d", state);
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->srvccStateNotify(
+ convertIntToRadioIndicationType(indicationType), (SrvccState) state);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("srvccStateNotifyInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+void convertRilHardwareConfigListToHal(void *response, size_t responseLen,
+ hidl_vec<HardwareConfig>& records) {
+ int num = responseLen / sizeof(RIL_HardwareConfig);
+ records.resize(num);
+
+ RIL_HardwareConfig *rilHardwareConfig = (RIL_HardwareConfig *) response;
+ for (int i = 0; i < num; i++) {
+ records[i].type = (HardwareConfigType) rilHardwareConfig[i].type;
+ records[i].uuid = convertCharPtrToHidlString(rilHardwareConfig[i].uuid);
+ records[i].state = (HardwareConfigState) rilHardwareConfig[i].state;
+ switch (rilHardwareConfig[i].type) {
+ case RIL_HARDWARE_CONFIG_MODEM: {
+ records[i].modem.resize(1);
+ records[i].sim.resize(0);
+ HardwareConfigModem *hwConfigModem = &records[i].modem[0];
+ hwConfigModem->rat = rilHardwareConfig[i].cfg.modem.rat;
+ hwConfigModem->maxVoice = rilHardwareConfig[i].cfg.modem.maxVoice;
+ hwConfigModem->maxData = rilHardwareConfig[i].cfg.modem.maxData;
+ hwConfigModem->maxStandby = rilHardwareConfig[i].cfg.modem.maxStandby;
+ break;
+ }
+
+ case RIL_HARDWARE_CONFIG_SIM: {
+ records[i].sim.resize(1);
+ records[i].modem.resize(0);
+ records[i].sim[0].modemUuid =
+ convertCharPtrToHidlString(rilHardwareConfig[i].cfg.sim.modemUuid);
+ break;
+ }
+ }
+ }
+}
+
+int radio_1_4::hardwareConfigChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if ((response == NULL && responseLen != 0)
+ || responseLen % sizeof(RIL_HardwareConfig) != 0) {
+ RLOGE("hardwareConfigChangedInd: invalid response");
+ return 0;
+ }
+
+ hidl_vec<HardwareConfig> configs;
+ convertRilHardwareConfigListToHal(response, responseLen, configs);
+
+#if VDBG
+ RLOGD("hardwareConfigChangedInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->hardwareConfigChanged(
+ convertIntToRadioIndicationType(indicationType), configs);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("hardwareConfigChangedInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+void convertRilRadioCapabilityToHal(void *response, size_t responseLen, RadioCapability& rc) {
+ RIL_RadioCapability *rilRadioCapability = (RIL_RadioCapability *) response;
+ rc.session = rilRadioCapability->session;
+ rc.phase = (V1_0::RadioCapabilityPhase) rilRadioCapability->phase;
+ rc.raf = rilRadioCapability->rat;
+ rc.logicalModemUuid = convertCharPtrToHidlString(rilRadioCapability->logicalModemUuid);
+ rc.status = (V1_0::RadioCapabilityStatus) rilRadioCapability->status;
+}
+
+int radio_1_4::radioCapabilityIndicationInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_RadioCapability)) {
+ RLOGE("radioCapabilityIndicationInd: invalid response");
+ return 0;
+ }
+
+ RadioCapability rc = {};
+ convertRilRadioCapabilityToHal(response, responseLen, rc);
+
+#if VDBG
+ RLOGD("radioCapabilityIndicationInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->radioCapabilityIndication(
+ convertIntToRadioIndicationType(indicationType), rc);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("radioCapabilityIndicationInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+bool isServiceTypeCfQuery(RIL_SsServiceType serType, RIL_SsRequestType reqType) {
+ if ((reqType == SS_INTERROGATION) &&
+ (serType == SS_CFU ||
+ serType == SS_CF_BUSY ||
+ serType == SS_CF_NO_REPLY ||
+ serType == SS_CF_NOT_REACHABLE ||
+ serType == SS_CF_ALL ||
+ serType == SS_CF_ALL_CONDITIONAL)) {
+ return true;
+ }
+ return false;
+}
+
+int radio_1_4::onSupplementaryServiceIndicationInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_StkCcUnsolSsResponse)) {
+ RLOGE("onSupplementaryServiceIndicationInd: invalid response");
+ return 0;
+ }
+
+ RIL_StkCcUnsolSsResponse *rilSsResponse = (RIL_StkCcUnsolSsResponse *) response;
+ StkCcUnsolSsResult ss = {};
+ ss.serviceType = (SsServiceType) rilSsResponse->serviceType;
+ ss.requestType = (SsRequestType) rilSsResponse->requestType;
+ ss.teleserviceType = (SsTeleserviceType) rilSsResponse->teleserviceType;
+ ss.serviceClass = rilSsResponse->serviceClass;
+ ss.result = (RadioError) rilSsResponse->result;
+
+ if (isServiceTypeCfQuery(rilSsResponse->serviceType, rilSsResponse->requestType)) {
+#if VDBG
+ RLOGD("onSupplementaryServiceIndicationInd CF type, num of Cf elements %d",
+ rilSsResponse->cfData.numValidIndexes);
+#endif
+ if (rilSsResponse->cfData.numValidIndexes > NUM_SERVICE_CLASSES) {
+ RLOGE("onSupplementaryServiceIndicationInd numValidIndexes is greater than "
+ "max value %d, truncating it to max value", NUM_SERVICE_CLASSES);
+ rilSsResponse->cfData.numValidIndexes = NUM_SERVICE_CLASSES;
+ }
+
+ ss.cfData.resize(1);
+ ss.ssInfo.resize(0);
+
+ /* number of call info's */
+ ss.cfData[0].cfInfo.resize(rilSsResponse->cfData.numValidIndexes);
+
+ for (int i = 0; i < rilSsResponse->cfData.numValidIndexes; i++) {
+ RIL_CallForwardInfo cf = rilSsResponse->cfData.cfInfo[i];
+ CallForwardInfo *cfInfo = &ss.cfData[0].cfInfo[i];
+
+ cfInfo->status = (CallForwardInfoStatus) cf.status;
+ cfInfo->reason = cf.reason;
+ cfInfo->serviceClass = cf.serviceClass;
+ cfInfo->toa = cf.toa;
+ cfInfo->number = convertCharPtrToHidlString(cf.number);
+ cfInfo->timeSeconds = cf.timeSeconds;
+#if VDBG
+ RLOGD("onSupplementaryServiceIndicationInd: "
+ "Data: %d,reason=%d,cls=%d,toa=%d,num=%s,tout=%d],", cf.status,
+ cf.reason, cf.serviceClass, cf.toa, (char*)cf.number, cf.timeSeconds);
+#endif
+ }
+ } else {
+ ss.ssInfo.resize(1);
+ ss.cfData.resize(0);
+
+ /* each int */
+ ss.ssInfo[0].ssInfo.resize(SS_INFO_MAX);
+ for (int i = 0; i < SS_INFO_MAX; i++) {
+#if VDBG
+ RLOGD("onSupplementaryServiceIndicationInd: Data: %d",
+ rilSsResponse->ssInfo[i]);
+#endif
+ ss.ssInfo[0].ssInfo[i] = rilSsResponse->ssInfo[i];
+ }
+ }
+
+#if VDBG
+ RLOGD("onSupplementaryServiceIndicationInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->
+ onSupplementaryServiceIndication(convertIntToRadioIndicationType(indicationType),
+ ss);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("onSupplementaryServiceIndicationInd: "
+ "radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::stkCallControlAlphaNotifyInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("stkCallControlAlphaNotifyInd: invalid response");
+ return 0;
+ }
+#if VDBG
+ RLOGD("stkCallControlAlphaNotifyInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->stkCallControlAlphaNotify(
+ convertIntToRadioIndicationType(indicationType),
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("stkCallControlAlphaNotifyInd: radioService[%d]->mRadioIndication == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+void convertRilLceDataInfoToHal(void *response, size_t responseLen, LceDataInfo& lce) {
+ RIL_LceDataInfo *rilLceDataInfo = (RIL_LceDataInfo *)response;
+ lce.lastHopCapacityKbps = rilLceDataInfo->last_hop_capacity_kbps;
+ lce.confidenceLevel = rilLceDataInfo->confidence_level;
+ lce.lceSuspended = rilLceDataInfo->lce_suspended;
+}
+
+int radio_1_4::lceDataInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_LceDataInfo)) {
+ RLOGE("lceDataInd: invalid response");
+ return 0;
+ }
+
+ LceDataInfo lce = {};
+ convertRilLceDataInfoToHal(response, responseLen, lce);
+#if VDBG
+ RLOGD("lceDataInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->lceData(
+ convertIntToRadioIndicationType(indicationType), lce);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("lceDataInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::pcoDataInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen != sizeof(RIL_PCO_Data)) {
+ RLOGE("pcoDataInd: invalid response");
+ return 0;
+ }
+
+ PcoDataInfo pco = {};
+ RIL_PCO_Data *rilPcoData = (RIL_PCO_Data *)response;
+ pco.cid = rilPcoData->cid;
+ pco.bearerProto = convertCharPtrToHidlString(rilPcoData->bearer_proto);
+ pco.pcoId = rilPcoData->pco_id;
+ pco.contents.setToExternal((uint8_t *) rilPcoData->contents, rilPcoData->contents_length);
+
+#if VDBG
+ RLOGD("pcoDataInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->pcoData(
+ convertIntToRadioIndicationType(indicationType), pco);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("pcoDataInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::modemResetInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("modemResetInd: invalid response");
+ return 0;
+ }
+#if VDBG
+ RLOGD("modemResetInd");
+#endif
+ Return<void> retStatus = radioService[slotId]->mRadioIndication->modemReset(
+ convertIntToRadioIndicationType(indicationType),
+ convertCharPtrToHidlString((char *) response));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("modemResetInd: radioService[%d]->mRadioIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::networkScanResultInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("networkScanResultInd");
+#endif
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndicationV1_4 != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("networkScanResultInd: invalid response");
+ return 0;
+ }
+ RLOGD("networkScanResultInd");
+
+#if VDBG
+ RLOGD("networkScanResultInd");
+#endif
+
+ RIL_NetworkScanResult *networkScanResult = (RIL_NetworkScanResult *) response;
+
+ V1_1::NetworkScanResult result;
+ result.status = (V1_1::ScanStatus) networkScanResult->status;
+ result.error = (RadioError) networkScanResult->error;
+ convertRilCellInfoListToHal(
+ networkScanResult->network_infos,
+ networkScanResult->network_infos_length * sizeof(RIL_CellInfo_v12),
+ result.networkInfos);
+
+ Return<void> retStatus = radioService[slotId]->mRadioIndicationV1_4->networkScanResult(
+ convertIntToRadioIndicationType(indicationType), result);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("networkScanResultInd: radioService[%d]->mRadioIndicationV1_4 == NULL", slotId);
+ }
+ return 0;
+}
+
+int radio_1_4::carrierInfoForImsiEncryption(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (radioService[slotId] != NULL && radioService[slotId]->mRadioIndicationV1_4 != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("carrierInfoForImsiEncryption: invalid response");
+ return 0;
+ }
+ RLOGD("carrierInfoForImsiEncryption");
+ Return<void> retStatus = radioService[slotId]->mRadioIndicationV1_4->
+ carrierInfoForImsiEncryption(convertIntToRadioIndicationType(indicationType));
+ radioService[slotId]->checkReturnStatus(retStatus);
+ } else {
+ RLOGE("carrierInfoForImsiEncryption: radioService[%d]->mRadioIndicationV1_4 == NULL",
+ slotId);
+ }
+
+ return 0;
+}
+
+int radio_1_4::keepaliveStatusInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+#if VDBG
+ RLOGD("%s(): token=%d", __FUNCTION__, token);
+#endif
+ if (radioService[slotId] == NULL || radioService[slotId]->mRadioIndication == NULL) {
+ RLOGE("%s: radioService[%d]->mRadioIndication == NULL", __FUNCTION__, slotId);
+ return 0;
+ }
+
+ auto ret = V1_1::IRadioIndication::castFrom(
+ radioService[slotId]->mRadioIndication);
+ if (!ret.isOk()) {
+ RLOGE("%s: ret.isOk() == false for radioService[%d]", __FUNCTION__, slotId);
+ return 0;
+ }
+ sp<V1_1::IRadioIndication> radioIndicationV1_1 = ret;
+
+ if (response == NULL || responseLen != sizeof(V1_1::KeepaliveStatus)) {
+ RLOGE("%s: invalid response", __FUNCTION__);
+ return 0;
+ }
+
+ V1_1::KeepaliveStatus ks;
+ convertRilKeepaliveStatusToHal(static_cast<RIL_KeepaliveStatus*>(response), ks);
+
+ Return<void> retStatus = radioIndicationV1_1->keepaliveStatus(
+ convertIntToRadioIndicationType(indicationType), ks);
+ radioService[slotId]->checkReturnStatus(retStatus);
+ return 0;
+}
+
+int radio_1_4::oemHookRawInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen) {
+ if (!kOemHookEnabled) return 0;
+
+ if (oemHookService[slotId] != NULL && oemHookService[slotId]->mOemHookIndication != NULL) {
+ if (response == NULL || responseLen == 0) {
+ RLOGE("oemHookRawInd: invalid response");
+ return 0;
+ }
+
+ hidl_vec<uint8_t> data;
+ data.setToExternal((uint8_t *) response, responseLen);
+#if VDBG
+ RLOGD("oemHookRawInd");
+#endif
+ Return<void> retStatus = oemHookService[slotId]->mOemHookIndication->oemHookRaw(
+ convertIntToRadioIndicationType(indicationType), data);
+ checkReturnStatus(slotId, retStatus, false);
+ } else {
+ RLOGE("oemHookRawInd: oemHookService[%d]->mOemHookIndication == NULL", slotId);
+ }
+
+ return 0;
+}
+
+void radio_1_4::registerService(RIL_RadioFunctions *callbacks, CommandInfo *commands) {
+ using namespace android::hardware;
+ int simCount = 1;
+ const char *serviceNames[] = {
+ android::RIL_getServiceName()
+ #if (SIM_COUNT >= 2)
+ , RIL2_SERVICE_NAME
+ #if (SIM_COUNT >= 3)
+ , RIL3_SERVICE_NAME
+ #if (SIM_COUNT >= 4)
+ , RIL4_SERVICE_NAME
+ #endif
+ #endif
+ #endif
+ };
+
+ #if (SIM_COUNT >= 2)
+ simCount = SIM_COUNT;
+ #endif
+
+ s_vendorFunctions = callbacks;
+ s_commands = commands;
+
+ configureRpcThreadpool(1, true /* callerWillJoin */);
+ for (int i = 0; i < simCount; i++) {
+ pthread_rwlock_t *radioServiceRwlockPtr = getRadioServiceRwlock(i);
+ int ret = pthread_rwlock_wrlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+
+ RLOGD("sim i = %d registering ...", i);
+
+ radioService[i] = new RadioImpl_1_4;
+ radioService[i]->mSlotId = i;
+ RLOGD("registerService: starting android::hardware::radio::V1_4::IRadio %s for slot %d",
+ serviceNames[i], i);
+ android::status_t status = radioService[i]->registerAsService(serviceNames[i]);
+
+ RLOGD("registerService: OemHook is enabled = %s", kOemHookEnabled ? "true" : "false");
+ if (kOemHookEnabled) {
+ oemHookService[i] = new OemHookImpl;
+ oemHookService[i]->mSlotId = i;
+ status = oemHookService[i]->registerAsService(serviceNames[i]);
+ }
+
+ ret = pthread_rwlock_unlock(radioServiceRwlockPtr);
+ assert(ret == 0);
+ }
+}
+
+void rilc_thread_pool() {
+ joinRpcThreadpool();
+}
+
+pthread_rwlock_t * radio_1_4::getRadioServiceRwlock(int slotId) {
+ pthread_rwlock_t *radioServiceRwlockPtr = &radioServiceRwlock;
+
+ #if (SIM_COUNT >= 2)
+ if (slotId == 2) radioServiceRwlockPtr = &radioServiceRwlock2;
+ #if (SIM_COUNT >= 3)
+ if (slotId == 3) radioServiceRwlockPtr = &radioServiceRwlock3;
+ #if (SIM_COUNT >= 4)
+ if (slotId == 4) radioServiceRwlockPtr = &radioServiceRwlock4;
+ #endif
+ #endif
+ #endif
+
+ return radioServiceRwlockPtr;
+}
+
+// should acquire write lock for the corresponding service before calling this
+void radio_1_4::setNitzTimeReceived(int slotId, long timeReceived) {
+ nitzTimeReceived[slotId] = timeReceived;
+}
diff --git a/guest/hals/ril/libril/ril_service.h b/guest/hals/ril/libril/ril_service.h
new file mode 100644
index 0000000..732a7f3
--- /dev/null
+++ b/guest/hals/ril/libril/ril_service.h
@@ -0,0 +1,750 @@
+/*
+ * Copyright (c) 2016 The Android Open Source Project
+ *
+ * Licensed under the Apache License, Version 2.0 (the "License");
+ * you may not use this file except in compliance with the License.
+ * You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#ifndef RIL_SERVICE_H
+#define RIL_SERVICE_H
+
+#include <guest/hals/ril/libril/ril.h>
+#include <ril_internal.h>
+
+namespace radio_1_4 {
+void registerService(RIL_RadioFunctions *callbacks, android::CommandInfo *commands);
+
+int getIccCardStatusResponse(int slotId, int responseType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int supplyIccPinForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int supplyIccPukForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int supplyIccPin2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int supplyIccPuk2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int changeIccPinForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int changeIccPin2ForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int supplyNetworkDepersonalizationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getCurrentCallsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int dialResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response, size_t responselen);
+
+int getIMSIForAppResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responselen);
+
+int hangupConnectionResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responselen);
+
+int hangupWaitingOrBackgroundResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int hangupForegroundResumeBackgroundResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int switchWaitingOrHoldingAndActiveResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int conferenceResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responselen);
+
+int rejectCallResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responselen);
+
+int getLastCallFailCauseResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getSignalStrengthResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int getVoiceRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getDataRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getOperatorResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setRadioPowerResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendSMSExpectMoreResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setupDataCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responseLen);
+
+int iccIOForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendUssdResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cancelPendingUssdResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getClirResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response, size_t responselen);
+
+int setClirResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response, size_t responselen);
+
+int getCallForwardStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCallForwardResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getCallWaitingResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCallWaitingResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int acknowledgeLastIncomingGsmSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int acceptCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int deactivateDataCallResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getFacilityLockForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setFacilityLockForAppResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setBarringPasswordResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getNetworkSelectionModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setNetworkSelectionModeAutomaticResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setNetworkSelectionModeManualResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getAvailableNetworksResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int startNetworkScanResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int stopNetworkScanResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int startDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int stopDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getBasebandVersionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int separateConnectionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setMuteResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getMuteResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getClipResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getDataCallListResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int setSuppServiceNotificationsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int writeSmsToSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int deleteSmsOnSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setBandModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getAvailableBandModesResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendEnvelopeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendTerminalResponseToSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int handleStkCallSetupRequestFromSimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int explicitCallTransferResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setPreferredNetworkTypeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getPreferredNetworkTypeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getNeighboringCidsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setLocationUpdatesResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCdmaSubscriptionSourceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCdmaRoamingPreferenceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getCdmaRoamingPreferenceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setTTYModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getTTYModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setPreferredVoicePrivacyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getPreferredVoicePrivacyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendCDMAFeatureCodeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int sendBurstDtmfResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendCdmaSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int acknowledgeLastIncomingCdmaSmsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getGsmBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setGsmBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setGsmBroadcastActivationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getCdmaBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCdmaBroadcastConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCdmaBroadcastActivationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getCDMASubscriptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int writeSmsToRuimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int deleteSmsOnRuimResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getDeviceIdentityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int exitEmergencyCallbackModeResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getSmscAddressResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int setCdmaBroadcastActivationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setSmscAddressResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int reportSmsMemoryStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int reportStkServiceIsRunningResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int getCdmaSubscriptionSourceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int requestIsimAuthenticationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int acknowledgeIncomingGsmSmsWithPduResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int sendEnvelopeWithStatusResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+int getVoiceRadioTechnologyResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getCellInfoListResponse(int slotId,
+ int responseType,
+ int serial, RIL_Errno e, void *response,
+ size_t responseLen);
+
+int setCellInfoListRateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setInitialAttachApnResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getImsRegistrationStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int sendImsSmsResponse(int slotId, int responseType,
+ int serial, RIL_Errno e, void *response, size_t responselen);
+
+int iccTransmitApduBasicChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int iccOpenLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e, void *response,
+ size_t responselen);
+
+
+int iccCloseLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int iccTransmitApduLogicalChannelResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int nvReadItemResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+
+int nvWriteItemResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int nvWriteCdmaPrlResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int nvResetConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setUiccSubscriptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setDataAllowedResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getHardwareConfigResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int requestIccSimAuthenticationResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setDataProfileResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int requestShutdownResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getRadioCapabilityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int setRadioCapabilityResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int startLceServiceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int stopLceServiceResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int pullLceDataResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int getModemActivityInfoResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setAllowedCarriersResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int getAllowedCarriersResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int sendDeviceStateResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setIndicationFilterResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int setSimCardPowerResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int startKeepaliveResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+int stopKeepaliveResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responselen);
+
+void acknowledgeRequest(int slotId, int serial);
+
+int radioStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responseLen);
+
+int callStateChangedInd(int slotId, int indType, int token,
+ RIL_Errno e, void *response, size_t responselen);
+
+int networkStateChangedInd(int slotId, int indType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int newSmsInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int newSmsStatusReportInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int newSmsOnSimInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int onUssdInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int nitzTimeReceivedInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int currentSignalStrengthInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responselen);
+
+int dataCallListChangedInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int suppSvcNotifyInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int stkSessionEndInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int stkProactiveCommandInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int stkEventNotifyInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int stkCallSetupInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int simSmsStorageFullInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int simRefreshInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int callRingInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int simStatusChangedInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int cdmaNewSmsInd(int slotId, int indicationType,
+ int token, RIL_Errno e, void *response, size_t responselen);
+
+int newBroadcastSmsInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cdmaRuimSmsStorageFullInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int restrictedStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int enterEmergencyCallbackModeInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cdmaCallWaitingInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cdmaOtaProvisionStatusInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cdmaInfoRecInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int oemHookRawInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int indicateRingbackToneInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int resendIncallMuteInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cdmaSubscriptionSourceChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responselen);
+
+int cdmaPrlChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int exitEmergencyCallbackModeInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int rilConnectedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int voiceRadioTechChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int cellInfoListInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int imsNetworkStateChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int subscriptionStatusChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int srvccStateNotifyInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int hardwareConfigChangedInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int radioCapabilityIndicationInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int onSupplementaryServiceIndicationInd(int slotId,
+ int indicationType, int token, RIL_Errno e,
+ void *response, size_t responselen);
+
+int stkCallControlAlphaNotifyInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int lceDataInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int pcoDataInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int modemResetInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int networkScanResultInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int keepaliveStatusInd(int slotId,
+ int indicationType, int token, RIL_Errno e, void *response,
+ size_t responselen);
+
+int sendRequestRawResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int sendRequestStringsResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int setCarrierInfoForImsiEncryptionResponse(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+int carrierInfoForImsiEncryption(int slotId,
+ int responseType, int serial, RIL_Errno e,
+ void *response, size_t responseLen);
+
+pthread_rwlock_t * getRadioServiceRwlock(int slotId);
+
+void setNitzTimeReceived(int slotId, long timeReceived);
+
+} // namespace radio
+
+#endif // RIL_SERVICE_H
diff --git a/guest/hals/ril/libril/ril_unsol_commands.h b/guest/hals/ril/libril/ril_unsol_commands.h
new file mode 100644
index 0000000..072a0fa
--- /dev/null
+++ b/guest/hals/ril/libril/ril_unsol_commands.h
@@ -0,0 +1,66 @@
+/* ///guest/hals/ril/libril/ril_unsol_commands.h
+**
+** Copyright 2006, The Android Open Source Project
+**
+** Licensed under the Apache License, Version 2.0 (the "License");
+** you may not use this file except in compliance with the License.
+** You may obtain a copy of the License at
+**
+** http://www.apache.org/licenses/LICENSE-2.0
+**
+** Unless required by applicable law or agreed to in writing, software
+** distributed under the License is distributed on an "AS IS" BASIS,
+** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+** See the License for the specific language governing permissions and
+** limitations under the License.
+*/
+ {RIL_UNSOL_RESPONSE_RADIO_STATE_CHANGED, radio_1_4::radioStateChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_CALL_STATE_CHANGED, radio_1_4::callStateChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_VOICE_NETWORK_STATE_CHANGED, radio_1_4::networkStateChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_NEW_SMS, radio_1_4::newSmsInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_NEW_SMS_STATUS_REPORT, radio_1_4::newSmsStatusReportInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_NEW_SMS_ON_SIM, radio_1_4::newSmsOnSimInd, WAKE_PARTIAL},
+ {RIL_UNSOL_ON_USSD, radio_1_4::onUssdInd, WAKE_PARTIAL},
+ {RIL_UNSOL_ON_USSD_REQUEST, radio_1_4::onUssdInd, DONT_WAKE},
+ {RIL_UNSOL_NITZ_TIME_RECEIVED, radio_1_4::nitzTimeReceivedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_SIGNAL_STRENGTH, radio_1_4::currentSignalStrengthInd, DONT_WAKE},
+ {RIL_UNSOL_DATA_CALL_LIST_CHANGED, radio_1_4::dataCallListChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_SUPP_SVC_NOTIFICATION, radio_1_4::suppSvcNotifyInd, WAKE_PARTIAL},
+ {RIL_UNSOL_STK_SESSION_END, radio_1_4::stkSessionEndInd, WAKE_PARTIAL},
+ {RIL_UNSOL_STK_PROACTIVE_COMMAND, radio_1_4::stkProactiveCommandInd, WAKE_PARTIAL},
+ {RIL_UNSOL_STK_EVENT_NOTIFY, radio_1_4::stkEventNotifyInd, WAKE_PARTIAL},
+ {RIL_UNSOL_STK_CALL_SETUP, radio_1_4::stkCallSetupInd, WAKE_PARTIAL},
+ {RIL_UNSOL_SIM_SMS_STORAGE_FULL, radio_1_4::simSmsStorageFullInd, WAKE_PARTIAL},
+ {RIL_UNSOL_SIM_REFRESH, radio_1_4::simRefreshInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CALL_RING, radio_1_4::callRingInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_SIM_STATUS_CHANGED, radio_1_4::simStatusChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_CDMA_NEW_SMS, radio_1_4::cdmaNewSmsInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_NEW_BROADCAST_SMS, radio_1_4::newBroadcastSmsInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_RUIM_SMS_STORAGE_FULL, radio_1_4::cdmaRuimSmsStorageFullInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESTRICTED_STATE_CHANGED, radio_1_4::restrictedStateChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_ENTER_EMERGENCY_CALLBACK_MODE, radio_1_4::enterEmergencyCallbackModeInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_CALL_WAITING, radio_1_4::cdmaCallWaitingInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_OTA_PROVISION_STATUS, radio_1_4::cdmaOtaProvisionStatusInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_INFO_REC, radio_1_4::cdmaInfoRecInd, WAKE_PARTIAL},
+ {RIL_UNSOL_OEM_HOOK_RAW, radio_1_4::oemHookRawInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RINGBACK_TONE, radio_1_4::indicateRingbackToneInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESEND_INCALL_MUTE, radio_1_4::resendIncallMuteInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_SUBSCRIPTION_SOURCE_CHANGED, radio_1_4::cdmaSubscriptionSourceChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CDMA_PRL_CHANGED, radio_1_4::cdmaPrlChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_EXIT_EMERGENCY_CALLBACK_MODE, radio_1_4::exitEmergencyCallbackModeInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RIL_CONNECTED, radio_1_4::rilConnectedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_VOICE_RADIO_TECH_CHANGED, radio_1_4::voiceRadioTechChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CELL_INFO_LIST, radio_1_4::cellInfoListInd, WAKE_PARTIAL},
+ {RIL_UNSOL_RESPONSE_IMS_NETWORK_STATE_CHANGED, radio_1_4::imsNetworkStateChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_UICC_SUBSCRIPTION_STATUS_CHANGED, radio_1_4::subscriptionStatusChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_SRVCC_STATE_NOTIFY, radio_1_4::srvccStateNotifyInd, WAKE_PARTIAL},
+ {RIL_UNSOL_HARDWARE_CONFIG_CHANGED, radio_1_4::hardwareConfigChangedInd, WAKE_PARTIAL},
+ {RIL_UNSOL_DC_RT_INFO_CHANGED, NULL, WAKE_PARTIAL},
+ {RIL_UNSOL_RADIO_CAPABILITY, radio_1_4::radioCapabilityIndicationInd, WAKE_PARTIAL},
+ {RIL_UNSOL_ON_SS, radio_1_4::onSupplementaryServiceIndicationInd, WAKE_PARTIAL},
+ {RIL_UNSOL_STK_CC_ALPHA_NOTIFY, radio_1_4::stkCallControlAlphaNotifyInd, WAKE_PARTIAL},
+ {RIL_UNSOL_LCEDATA_RECV, radio_1_4::lceDataInd, WAKE_PARTIAL},
+ {RIL_UNSOL_PCO_DATA, radio_1_4::pcoDataInd, WAKE_PARTIAL},
+ {RIL_UNSOL_MODEM_RESTART, radio_1_4::modemResetInd, WAKE_PARTIAL},
+ {RIL_UNSOL_CARRIER_INFO_IMSI_ENCRYPTION, radio_1_4::carrierInfoForImsiEncryption, WAKE_PARTIAL},
+ {RIL_UNSOL_NETWORK_SCAN_RESULT, radio_1_4::networkScanResultInd, WAKE_PARTIAL},
diff --git a/guest/hals/ril/libril/sap_service.cpp b/guest/hals/ril/libril/sap_service.cpp
new file mode 100644
index 0000000..cd5b137
--- /dev/null
+++ b/guest/hals/ril/libril/sap_service.cpp
@@ -0,0 +1,966 @@
+/*
+ * Copyright (c) 2016 The Android Open Source Project
+ *
+ * Licensed under the Apache License, Version 2.0 (the "License");
+ * you may not use this file except in compliance with the License.
+ * You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#define LOG_TAG "RIL_SAP"
+
+#include <android/hardware/radio/1.1/ISap.h>
+
+#include <hwbinder/IPCThreadState.h>
+#include <hwbinder/ProcessState.h>
+#include <sap_service.h>
+#include "pb_decode.h"
+#include "pb_encode.h"
+
+using namespace android::hardware::radio::V1_0;
+using ::android::hardware::Return;
+using ::android::hardware::hidl_vec;
+using ::android::hardware::hidl_array;
+using ::android::hardware::Void;
+using android::CommandInfo;
+using android::RequestInfo;
+using android::requestToString;
+using android::sp;
+
+struct SapImpl;
+
+#if (SIM_COUNT >= 2)
+sp<SapImpl> sapService[SIM_COUNT];
+#else
+sp<SapImpl> sapService[1];
+#endif
+
+struct SapImpl : public android::hardware::radio::V1_1::ISap {
+ int32_t slotId;
+ sp<ISapCallback> sapCallback;
+ RIL_SOCKET_ID rilSocketId;
+
+ Return<void> setCallback(const ::android::sp<ISapCallback>& sapCallbackParam);
+
+ Return<void> connectReq(int32_t token, int32_t maxMsgSize);
+
+ Return<void> disconnectReq(int32_t token);
+
+ Return<void> apduReq(int32_t token, SapApduType type, const hidl_vec<uint8_t>& command);
+
+ Return<void> transferAtrReq(int32_t token);
+
+ Return<void> powerReq(int32_t token, bool state);
+
+ Return<void> resetSimReq(int32_t token);
+
+ Return<void> transferCardReaderStatusReq(int32_t token);
+
+ Return<void> setTransferProtocolReq(int32_t token, SapTransferProtocol transferProtocol);
+
+ MsgHeader* createMsgHeader(MsgId msgId, int32_t token);
+
+ Return<void> addPayloadAndDispatchRequest(MsgHeader *msg, uint16_t reqLen, uint8_t *reqPtr);
+
+ void sendFailedResponse(MsgId msgId, int32_t token, int numPointers, ...);
+
+ void checkReturnStatus(Return<void>& ret);
+};
+
+void SapImpl::checkReturnStatus(Return<void>& ret) {
+ if (ret.isOk() == false) {
+ RLOGE("checkReturnStatus: unable to call response/indication callback: %s",
+ ret.description().c_str());
+ // Remote process (SapRilReceiver.java) hosting the callback must be dead. Reset the
+ // callback object; there's no other recovery to be done here. When the client process is
+ // back up, it will call setCallback()
+ sapCallback = NULL;
+ }
+}
+
+Return<void> SapImpl::setCallback(const ::android::sp<ISapCallback>& sapCallbackParam) {
+ RLOGD("SapImpl::setCallback for slotId %d", slotId);
+ sapCallback = sapCallbackParam;
+ return Void();
+}
+
+MsgHeader* SapImpl::createMsgHeader(MsgId msgId, int32_t token) {
+ // Memory for msg will be freed by RilSapSocket::onRequestComplete()
+ MsgHeader *msg = (MsgHeader *)calloc(1, sizeof(MsgHeader));
+ if (msg == NULL) {
+ return NULL;
+ }
+ msg->token = token;
+ msg->type = MsgType_REQUEST;
+ msg->id = msgId;
+ msg->error = Error_RIL_E_SUCCESS;
+ return msg;
+}
+
+Return<void> SapImpl::addPayloadAndDispatchRequest(MsgHeader *msg, uint16_t reqLen,
+ uint8_t *reqPtr) {
+ pb_bytes_array_t *payload = (pb_bytes_array_t *) malloc(sizeof(pb_bytes_array_t) - 1 + reqLen);
+ if (payload == NULL) {
+ sendFailedResponse(msg->id, msg->token, 2, reqPtr, msg);
+ return Void();
+ }
+
+ msg->payload = payload;
+ msg->payload->size = reqLen;
+ memcpy(msg->payload->bytes, reqPtr, reqLen);
+
+ RilSapSocket *sapSocket = RilSapSocket::getSocketById(rilSocketId);
+ if (sapSocket) {
+ RLOGD("SapImpl::addPayloadAndDispatchRequest: calling dispatchRequest");
+ sapSocket->dispatchRequest(msg);
+ } else {
+ RLOGE("SapImpl::addPayloadAndDispatchRequest: sapSocket is null");
+ sendFailedResponse(msg->id, msg->token, 3, payload, reqPtr, msg);
+ return Void();
+ }
+ free(msg->payload);
+ free(reqPtr);
+ return Void();
+}
+
+void SapImpl::sendFailedResponse(MsgId msgId, int32_t token, int numPointers, ...) {
+ va_list ap;
+ va_start(ap, numPointers);
+ for (int i = 0; i < numPointers; i++) {
+ void *ptr = va_arg(ap, void *);
+ if (ptr) free(ptr);
+ }
+ va_end(ap);
+ Return<void> retStatus;
+ switch(msgId) {
+ case MsgId_RIL_SIM_SAP_CONNECT:
+ retStatus = sapCallback->connectResponse(token, SapConnectRsp::CONNECT_FAILURE, 0);
+ break;
+
+ case MsgId_RIL_SIM_SAP_DISCONNECT:
+ retStatus = sapCallback->disconnectResponse(token);
+ break;
+
+ case MsgId_RIL_SIM_SAP_APDU: {
+ hidl_vec<uint8_t> apduRsp;
+ retStatus = sapCallback->apduResponse(token, SapResultCode::GENERIC_FAILURE, apduRsp);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_ATR: {
+ hidl_vec<uint8_t> atr;
+ retStatus = sapCallback->transferAtrResponse(token, SapResultCode::GENERIC_FAILURE,
+ atr);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_POWER:
+ retStatus = sapCallback->powerResponse(token, SapResultCode::GENERIC_FAILURE);
+ break;
+
+ case MsgId_RIL_SIM_SAP_RESET_SIM:
+ retStatus = sapCallback->resetSimResponse(token, SapResultCode::GENERIC_FAILURE);
+ break;
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS:
+ retStatus = sapCallback->transferCardReaderStatusResponse(token,
+ SapResultCode::GENERIC_FAILURE, 0);
+ break;
+
+ case MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL:
+ retStatus = sapCallback->transferProtocolResponse(token, SapResultCode::NOT_SUPPORTED);
+ break;
+
+ default:
+ return;
+ }
+ sapService[slotId]->checkReturnStatus(retStatus);
+}
+
+Return<void> SapImpl::connectReq(int32_t token, int32_t maxMsgSize) {
+ RLOGD("SapImpl::connectReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_CONNECT, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::connectReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_CONNECT, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_CONNECT_REQ *****/
+ RIL_SIM_SAP_CONNECT_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_CONNECT_REQ));
+ req.max_message_size = maxMsgSize;
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_CONNECT_REQ_fields, &req)) {
+ RLOGE("SapImpl::connectReq: Error getting encoded size for RIL_SIM_SAP_CONNECT_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_CONNECT, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::connectReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_CONNECT, token, 1, msg);
+ return Void();
+ }
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::connectReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_CONNECT_REQ_fields, &req)) {
+ RLOGE("SapImpl::connectReq: Error encoding RIL_SIM_SAP_CONNECT_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_CONNECT, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_CONNECT_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::disconnectReq(int32_t token) {
+ RLOGD("SapImpl::disconnectReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_DISCONNECT, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::disconnectReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_DISCONNECT, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_DISCONNECT_REQ *****/
+ RIL_SIM_SAP_DISCONNECT_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_DISCONNECT_REQ));
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_DISCONNECT_REQ_fields, &req)) {
+ RLOGE("SapImpl::disconnectReq: Error getting encoded size for RIL_SIM_SAP_DISCONNECT_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_DISCONNECT, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::disconnectReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_DISCONNECT, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::disconnectReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_DISCONNECT_REQ_fields, &req)) {
+ RLOGE("SapImpl::disconnectReq: Error encoding RIL_SIM_SAP_DISCONNECT_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_DISCONNECT, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_DISCONNECT_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::apduReq(int32_t token, SapApduType type, const hidl_vec<uint8_t>& command) {
+ RLOGD("SapImpl::apduReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_APDU, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::apduReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_APDU, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_APDU_REQ *****/
+ RIL_SIM_SAP_APDU_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_APDU_REQ));
+ req.type = (RIL_SIM_SAP_APDU_REQ_Type)type;
+
+ if (command.size() > 0) {
+ req.command = (pb_bytes_array_t *)malloc(sizeof(pb_bytes_array_t) - 1 + command.size());
+ if (req.command == NULL) {
+ RLOGE("SapImpl::apduReq: Error allocating memory for req.command");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_APDU, token, 1, msg);
+ return Void();
+ }
+ req.command->size = command.size();
+ memcpy(req.command->bytes, command.data(), command.size());
+ }
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_APDU_REQ_fields, &req)) {
+ RLOGE("SapImpl::apduReq: Error getting encoded size for RIL_SIM_SAP_APDU_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_APDU, token, 2, req.command, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::apduReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_APDU, token, 2, req.command, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::apduReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_APDU_REQ_fields, &req)) {
+ RLOGE("SapImpl::apduReq: Error encoding RIL_SIM_SAP_APDU_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_APDU, token, 3, req.command, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_APDU_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::transferAtrReq(int32_t token) {
+ RLOGD("SapImpl::transferAtrReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_TRANSFER_ATR, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::transferAtrReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_ATR, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_TRANSFER_ATR_REQ *****/
+ RIL_SIM_SAP_TRANSFER_ATR_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_TRANSFER_ATR_REQ));
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_TRANSFER_ATR_REQ_fields, &req)) {
+ RLOGE("SapImpl::transferAtrReq: Error getting encoded size for "
+ "RIL_SIM_SAP_TRANSFER_ATR_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_ATR, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::transferAtrReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_ATR, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::transferAtrReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_TRANSFER_ATR_REQ_fields, &req)) {
+ RLOGE("SapImpl::transferAtrReq: Error encoding RIL_SIM_SAP_TRANSFER_ATR_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_ATR, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_TRANSFER_ATR_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::powerReq(int32_t token, bool state) {
+ RLOGD("SapImpl::powerReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_POWER, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::powerReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_POWER, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_POWER_REQ *****/
+ RIL_SIM_SAP_POWER_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_POWER_REQ));
+ req.state = state;
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_POWER_REQ_fields, &req)) {
+ RLOGE("SapImpl::powerReq: Error getting encoded size for RIL_SIM_SAP_POWER_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_POWER, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::powerReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_POWER, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::powerReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_POWER_REQ_fields, &req)) {
+ RLOGE("SapImpl::powerReq: Error encoding RIL_SIM_SAP_POWER_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_POWER, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_POWER_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::resetSimReq(int32_t token) {
+ RLOGD("SapImpl::resetSimReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_RESET_SIM, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::resetSimReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_RESET_SIM, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_RESET_SIM_REQ *****/
+ RIL_SIM_SAP_RESET_SIM_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_RESET_SIM_REQ));
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_RESET_SIM_REQ_fields, &req)) {
+ RLOGE("SapImpl::resetSimReq: Error getting encoded size for RIL_SIM_SAP_RESET_SIM_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_RESET_SIM, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::resetSimReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_RESET_SIM, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::resetSimReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_RESET_SIM_REQ_fields, &req)) {
+ RLOGE("SapImpl::resetSimReq: Error encoding RIL_SIM_SAP_RESET_SIM_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_RESET_SIM, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_RESET_SIM_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::transferCardReaderStatusReq(int32_t token) {
+ RLOGD("SapImpl::transferCardReaderStatusReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::transferCardReaderStatusReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ *****/
+ RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ));
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ_fields,
+ &req)) {
+ RLOGE("SapImpl::transferCardReaderStatusReq: Error getting encoded size for "
+ "RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::transferCardReaderStatusReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::transferCardReaderStatusReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ_fields, &req)) {
+ RLOGE("SapImpl::transferCardReaderStatusReq: Error encoding "
+ "RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+Return<void> SapImpl::setTransferProtocolReq(int32_t token, SapTransferProtocol transferProtocol) {
+ RLOGD("SapImpl::setTransferProtocolReq");
+ MsgHeader *msg = createMsgHeader(MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL, token);
+ if (msg == NULL) {
+ RLOGE("SapImpl::setTransferProtocolReq: Error allocating memory for msg");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL, token, 0);
+ return Void();
+ }
+
+ /***** Encode RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ *****/
+ RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ req;
+ memset(&req, 0, sizeof(RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ));
+ req.protocol = (RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ_Protocol)transferProtocol;
+
+ size_t encodedSize = 0;
+ if (!pb_get_encoded_size(&encodedSize, RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ_fields, &req)) {
+ RLOGE("SapImpl::setTransferProtocolReq: Error getting encoded size for "
+ "RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL, token, 1, msg);
+ return Void();
+ }
+
+ uint8_t *buffer = (uint8_t *)calloc(1, encodedSize);
+ if (buffer == NULL) {
+ RLOGE("SapImpl::setTransferProtocolReq: Error allocating memory for buffer");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL, token, 1, msg);
+ return Void();
+ }
+
+ pb_ostream_t stream = pb_ostream_from_buffer(buffer, encodedSize);
+
+ RLOGD("SapImpl::setTransferProtocolReq calling pb_encode");
+ if (!pb_encode(&stream, RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ_fields, &req)) {
+ RLOGE("SapImpl::setTransferProtocolReq: Error encoding "
+ "RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ");
+ sendFailedResponse(MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL, token, 2, buffer, msg);
+ return Void();
+ }
+ /***** Encode RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_REQ done *****/
+
+ /* encoded req is payload */
+ return addPayloadAndDispatchRequest(msg, stream.bytes_written, buffer);
+}
+
+void *sapDecodeMessage(MsgId msgId, MsgType msgType, uint8_t *payloadPtr, size_t payloadLen) {
+ void *responsePtr = NULL;
+ pb_istream_t stream;
+
+ /* Create the stream */
+ stream = pb_istream_from_buffer((uint8_t *)payloadPtr, payloadLen);
+
+ /* Decode based on the message id */
+ switch (msgId)
+ {
+ case MsgId_RIL_SIM_SAP_CONNECT:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_CONNECT_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_CONNECT_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_CONNECT_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_DISCONNECT:
+ if (msgType == MsgType_RESPONSE) {
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_DISCONNECT_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_DISCONNECT_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_DISCONNECT_RSP");
+ return NULL;
+ }
+ }
+ } else {
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_DISCONNECT_IND));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_DISCONNECT_IND_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_DISCONNECT_IND");
+ return NULL;
+ }
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_APDU:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_APDU_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_APDU_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_APDU_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_ATR:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_TRANSFER_ATR_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_TRANSFER_ATR_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_TRANSFER_ATR_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_POWER:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_POWER_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_POWER_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_POWER_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_RESET_SIM:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_RESET_SIM_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_RESET_SIM_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_RESET_SIM_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_STATUS:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_STATUS_IND));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_STATUS_IND_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_STATUS_IND");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP_fields,
+ responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_ERROR_RESP:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_ERROR_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_ERROR_RSP_fields, responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_ERROR_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL:
+ responsePtr = malloc(sizeof(RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_RSP));
+ if (responsePtr) {
+ if (!pb_decode(&stream, RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_RSP_fields,
+ responsePtr)) {
+ RLOGE("Error decoding RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_RSP");
+ return NULL;
+ }
+ }
+ break;
+
+ default:
+ break;
+ }
+ return responsePtr;
+} /* sapDecodeMessage */
+
+sp<SapImpl> getSapImpl(RilSapSocket *sapSocket) {
+ switch (sapSocket->getSocketId()) {
+ case RIL_SOCKET_1:
+ RLOGD("getSapImpl: returning sapService[0]");
+ return sapService[0];
+ #if (SIM_COUNT >= 2)
+ case RIL_SOCKET_2:
+ return sapService[1];
+ #if (SIM_COUNT >= 3)
+ case RIL_SOCKET_3:
+ return sapService[2];
+ #if (SIM_COUNT >= 4)
+ case RIL_SOCKET_4:
+ return sapService[3];
+ #endif
+ #endif
+ #endif
+ default:
+ return NULL;
+ }
+}
+
+SapResultCode convertApduResponseProtoToHal(RIL_SIM_SAP_APDU_RSP_Response responseProto) {
+ switch(responseProto) {
+ case RIL_SIM_SAP_APDU_RSP_Response_RIL_E_SUCCESS:
+ return SapResultCode::SUCCESS;
+ case RIL_SIM_SAP_APDU_RSP_Response_RIL_E_GENERIC_FAILURE:
+ return SapResultCode::GENERIC_FAILURE;
+ case RIL_SIM_SAP_APDU_RSP_Response_RIL_E_SIM_NOT_READY:
+ return SapResultCode::CARD_NOT_ACCESSSIBLE;
+ case RIL_SIM_SAP_APDU_RSP_Response_RIL_E_SIM_ALREADY_POWERED_OFF:
+ return SapResultCode::CARD_ALREADY_POWERED_OFF;
+ case RIL_SIM_SAP_APDU_RSP_Response_RIL_E_SIM_ABSENT:
+ return SapResultCode::CARD_REMOVED;
+ default:
+ return SapResultCode::GENERIC_FAILURE;
+ }
+}
+
+SapResultCode convertTransferAtrResponseProtoToHal(
+ RIL_SIM_SAP_TRANSFER_ATR_RSP_Response responseProto) {
+ switch(responseProto) {
+ case RIL_SIM_SAP_TRANSFER_ATR_RSP_Response_RIL_E_SUCCESS:
+ return SapResultCode::SUCCESS;
+ case RIL_SIM_SAP_TRANSFER_ATR_RSP_Response_RIL_E_GENERIC_FAILURE:
+ return SapResultCode::GENERIC_FAILURE;
+ case RIL_SIM_SAP_TRANSFER_ATR_RSP_Response_RIL_E_SIM_ALREADY_POWERED_OFF:
+ return SapResultCode::CARD_ALREADY_POWERED_OFF;
+ case RIL_SIM_SAP_TRANSFER_ATR_RSP_Response_RIL_E_SIM_ABSENT:
+ return SapResultCode::CARD_REMOVED;
+ case RIL_SIM_SAP_TRANSFER_ATR_RSP_Response_RIL_E_SIM_DATA_NOT_AVAILABLE:
+ return SapResultCode::DATA_NOT_AVAILABLE;
+ default:
+ return SapResultCode::GENERIC_FAILURE;
+ }
+}
+
+SapResultCode convertPowerResponseProtoToHal(RIL_SIM_SAP_POWER_RSP_Response responseProto) {
+ switch(responseProto) {
+ case RIL_SIM_SAP_POWER_RSP_Response_RIL_E_SUCCESS:
+ return SapResultCode::SUCCESS;
+ case RIL_SIM_SAP_POWER_RSP_Response_RIL_E_GENERIC_FAILURE:
+ return SapResultCode::GENERIC_FAILURE;
+ case RIL_SIM_SAP_POWER_RSP_Response_RIL_E_SIM_ABSENT:
+ return SapResultCode::CARD_REMOVED;
+ case RIL_SIM_SAP_POWER_RSP_Response_RIL_E_SIM_ALREADY_POWERED_OFF:
+ return SapResultCode::CARD_ALREADY_POWERED_OFF;
+ case RIL_SIM_SAP_POWER_RSP_Response_RIL_E_SIM_ALREADY_POWERED_ON:
+ return SapResultCode::CARD_ALREADY_POWERED_ON;
+ default:
+ return SapResultCode::GENERIC_FAILURE;
+ }
+}
+
+SapResultCode convertResetSimResponseProtoToHal(RIL_SIM_SAP_RESET_SIM_RSP_Response responseProto) {
+ switch(responseProto) {
+ case RIL_SIM_SAP_RESET_SIM_RSP_Response_RIL_E_SUCCESS:
+ return SapResultCode::SUCCESS;
+ case RIL_SIM_SAP_RESET_SIM_RSP_Response_RIL_E_GENERIC_FAILURE:
+ return SapResultCode::GENERIC_FAILURE;
+ case RIL_SIM_SAP_RESET_SIM_RSP_Response_RIL_E_SIM_ABSENT:
+ return SapResultCode::CARD_REMOVED;
+ case RIL_SIM_SAP_RESET_SIM_RSP_Response_RIL_E_SIM_NOT_READY:
+ return SapResultCode::CARD_NOT_ACCESSSIBLE;
+ case RIL_SIM_SAP_RESET_SIM_RSP_Response_RIL_E_SIM_ALREADY_POWERED_OFF:
+ return SapResultCode::CARD_ALREADY_POWERED_OFF;
+ }
+ return SapResultCode::GENERIC_FAILURE;
+}
+
+SapResultCode convertTransferCardReaderStatusResponseProtoToHal(
+ RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP_Response responseProto) {
+ switch(responseProto) {
+ case RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP_Response_RIL_E_SUCCESS:
+ return SapResultCode::SUCCESS;
+ case RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP_Response_RIL_E_GENERIC_FAILURE:
+ return SapResultCode::GENERIC_FAILURE;
+ case RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP_Response_RIL_E_SIM_DATA_NOT_AVAILABLE:
+ return SapResultCode::DATA_NOT_AVAILABLE;
+ }
+ return SapResultCode::GENERIC_FAILURE;
+}
+
+void processResponse(MsgHeader *rsp, RilSapSocket *sapSocket, MsgType msgType) {
+ MsgId msgId = rsp->id;
+ uint8_t *data = rsp->payload->bytes;
+ size_t dataLen = rsp->payload->size;
+
+ void *messagePtr = sapDecodeMessage(msgId, msgType, data, dataLen);
+
+ sp<SapImpl> sapImpl = getSapImpl(sapSocket);
+ if (sapImpl->sapCallback == NULL) {
+ RLOGE("processResponse: sapCallback == NULL; msgId = %d; msgType = %d",
+ msgId, msgType);
+ return;
+ }
+
+ if (messagePtr == NULL) {
+ RLOGE("processResponse: *messagePtr == NULL; msgId = %d; msgType = %d",
+ msgId, msgType);
+ sapImpl->sendFailedResponse(msgId, rsp->token, 0);
+ return;
+ }
+
+ RLOGD("processResponse: sapCallback != NULL; msgId = %d; msgType = %d",
+ msgId, msgType);
+
+ Return<void> retStatus;
+ switch (msgId) {
+ case MsgId_RIL_SIM_SAP_CONNECT: {
+ RIL_SIM_SAP_CONNECT_RSP *connectRsp = (RIL_SIM_SAP_CONNECT_RSP *)messagePtr;
+ RLOGD("processResponse: calling sapCallback->connectResponse %d %d %d",
+ rsp->token,
+ connectRsp->response,
+ connectRsp->max_message_size);
+ retStatus = sapImpl->sapCallback->connectResponse(rsp->token,
+ (SapConnectRsp)connectRsp->response,
+ connectRsp->max_message_size);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_DISCONNECT:
+ if (msgType == MsgType_RESPONSE) {
+ RLOGD("processResponse: calling sapCallback->disconnectResponse %d", rsp->token);
+ retStatus = sapImpl->sapCallback->disconnectResponse(rsp->token);
+ } else {
+ RIL_SIM_SAP_DISCONNECT_IND *disconnectInd =
+ (RIL_SIM_SAP_DISCONNECT_IND *)messagePtr;
+ RLOGD("processResponse: calling sapCallback->disconnectIndication %d %d",
+ rsp->token, disconnectInd->disconnectType);
+ retStatus = sapImpl->sapCallback->disconnectIndication(rsp->token,
+ (SapDisconnectType)disconnectInd->disconnectType);
+ }
+ break;
+
+ case MsgId_RIL_SIM_SAP_APDU: {
+ RIL_SIM_SAP_APDU_RSP *apduRsp = (RIL_SIM_SAP_APDU_RSP *)messagePtr;
+ SapResultCode apduResponse = convertApduResponseProtoToHal(apduRsp->response);
+ RLOGD("processResponse: calling sapCallback->apduResponse %d %d",
+ rsp->token, apduResponse);
+ hidl_vec<uint8_t> apduRspVec;
+ if (apduRsp->apduResponse != NULL && apduRsp->apduResponse->size > 0) {
+ apduRspVec.setToExternal(apduRsp->apduResponse->bytes, apduRsp->apduResponse->size);
+ }
+ retStatus = sapImpl->sapCallback->apduResponse(rsp->token, apduResponse, apduRspVec);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_ATR: {
+ RIL_SIM_SAP_TRANSFER_ATR_RSP *transferAtrRsp =
+ (RIL_SIM_SAP_TRANSFER_ATR_RSP *)messagePtr;
+ SapResultCode transferAtrResponse =
+ convertTransferAtrResponseProtoToHal(transferAtrRsp->response);
+ RLOGD("processResponse: calling sapCallback->transferAtrResponse %d %d",
+ rsp->token, transferAtrResponse);
+ hidl_vec<uint8_t> transferAtrRspVec;
+ if (transferAtrRsp->atr != NULL && transferAtrRsp->atr->size > 0) {
+ transferAtrRspVec.setToExternal(transferAtrRsp->atr->bytes,
+ transferAtrRsp->atr->size);
+ }
+ retStatus = sapImpl->sapCallback->transferAtrResponse(rsp->token, transferAtrResponse,
+ transferAtrRspVec);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_POWER: {
+ SapResultCode powerResponse = convertPowerResponseProtoToHal(
+ ((RIL_SIM_SAP_POWER_RSP *)messagePtr)->response);
+ RLOGD("processResponse: calling sapCallback->powerResponse %d %d",
+ rsp->token, powerResponse);
+ retStatus = sapImpl->sapCallback->powerResponse(rsp->token, powerResponse);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_RESET_SIM: {
+ SapResultCode resetSimResponse = convertResetSimResponseProtoToHal(
+ ((RIL_SIM_SAP_RESET_SIM_RSP *)messagePtr)->response);
+ RLOGD("processResponse: calling sapCallback->resetSimResponse %d %d",
+ rsp->token, resetSimResponse);
+ retStatus = sapImpl->sapCallback->resetSimResponse(rsp->token, resetSimResponse);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_STATUS: {
+ RIL_SIM_SAP_STATUS_IND *statusInd = (RIL_SIM_SAP_STATUS_IND *)messagePtr;
+ RLOGD("processResponse: calling sapCallback->statusIndication %d %d",
+ rsp->token, statusInd->statusChange);
+ retStatus = sapImpl->sapCallback->statusIndication(rsp->token,
+ (SapStatus)statusInd->statusChange);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS: {
+ RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP *transferStatusRsp =
+ (RIL_SIM_SAP_TRANSFER_CARD_READER_STATUS_RSP *)messagePtr;
+ SapResultCode transferCardReaderStatusResponse =
+ convertTransferCardReaderStatusResponseProtoToHal(
+ transferStatusRsp->response);
+ RLOGD("processResponse: calling sapCallback->transferCardReaderStatusResponse %d %d %d",
+ rsp->token,
+ transferCardReaderStatusResponse,
+ transferStatusRsp->CardReaderStatus);
+ retStatus = sapImpl->sapCallback->transferCardReaderStatusResponse(rsp->token,
+ transferCardReaderStatusResponse,
+ transferStatusRsp->CardReaderStatus);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_ERROR_RESP: {
+ RLOGD("processResponse: calling sapCallback->errorResponse %d", rsp->token);
+ retStatus = sapImpl->sapCallback->errorResponse(rsp->token);
+ break;
+ }
+
+ case MsgId_RIL_SIM_SAP_SET_TRANSFER_PROTOCOL: {
+ SapResultCode setTransferProtocolResponse;
+ if (((RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_RSP *)messagePtr)->response ==
+ RIL_SIM_SAP_SET_TRANSFER_PROTOCOL_RSP_Response_RIL_E_SUCCESS) {
+ setTransferProtocolResponse = SapResultCode::SUCCESS;
+ } else {
+ setTransferProtocolResponse = SapResultCode::NOT_SUPPORTED;
+ }
+ RLOGD("processResponse: calling sapCallback->transferProtocolResponse %d %d",
+ rsp->token, setTransferProtocolResponse);
+ retStatus = sapImpl->sapCallback->transferProtocolResponse(rsp->token,
+ setTransferProtocolResponse);
+ break;
+ }
+
+ default:
+ return;
+ }
+ sapImpl->checkReturnStatus(retStatus);
+}
+
+void sap::processResponse(MsgHeader *rsp, RilSapSocket *sapSocket) {
+ processResponse(rsp, sapSocket, MsgType_RESPONSE);
+}
+
+void sap::processUnsolResponse(MsgHeader *rsp, RilSapSocket *sapSocket) {
+ processResponse(rsp, sapSocket, MsgType_UNSOL_RESPONSE);
+}
+
+void sap::registerService(const RIL_RadioFunctions *callbacks) {
+ using namespace android::hardware;
+ int simCount = 1;
+ const char *serviceNames[] = {
+ android::RIL_getServiceName()
+ #if (SIM_COUNT >= 2)
+ , RIL2_SERVICE_NAME
+ #if (SIM_COUNT >= 3)
+ , RIL3_SERVICE_NAME
+ #if (SIM_COUNT >= 4)
+ , RIL4_SERVICE_NAME
+ #endif
+ #endif
+ #endif
+ };
+
+ RIL_SOCKET_ID socketIds[] = {
+ RIL_SOCKET_1
+ #if (SIM_COUNT >= 2)
+ , RIL_SOCKET_2
+ #if (SIM_COUNT >= 3)
+ , RIL_SOCKET_3
+ #if (SIM_COUNT >= 4)
+ , RIL_SOCKET_4
+ #endif
+ #endif
+ #endif
+ };
+ #if (SIM_COUNT >= 2)
+ simCount = SIM_COUNT;
+ #endif
+
+ for (int i = 0; i < simCount; i++) {
+ sapService[i] = new SapImpl;
+ sapService[i]->slotId = i;
+ sapService[i]->rilSocketId = socketIds[i];
+ RLOGD("registerService: starting ISap %s for slotId %d", serviceNames[i], i);
+ android::status_t status = sapService[i]->registerAsService(serviceNames[i]);
+ RLOGD("registerService: started ISap %s status %d", serviceNames[i], status);
+ }
+}
diff --git a/guest/hals/ril/vsoc_ril.cpp b/guest/hals/ril/vsoc_ril.cpp
index 1eeff5b..f823b13 100644
--- a/guest/hals/ril/vsoc_ril.cpp
+++ b/guest/hals/ril/vsoc_ril.cpp
@@ -32,7 +32,7 @@
#include "common/vsoc/lib/ril_region_view.h"
#include "guest/libs/platform_support/api_level_fixes.h"
-#define VSOC_RIL_VERSION_STRING "Android VSoC RIL 1.0"
+#define VSOC_RIL_VERSION_STRING "Android VSoC RIL 1.4"
/* Modem Technology bits */
#define MDM_GSM 0x01
@@ -259,6 +259,7 @@
ALOGE("%s returning: called with small datalen %zu", __FUNCTION__, datalen);
return;
}
+
DataCall call;
int tech = atoi(details[0]);
switch (tech) {
@@ -2197,6 +2198,35 @@
gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, reply, sizeof(reply));
}
+// New functions after P.
+#if VSOC_PLATFORM_SDK_AFTER(P)
+static void request_start_network_scan(RIL_Token t) {
+ ALOGV("Scanning network - void");
+ gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0);
+ return;
+}
+
+static void request_start_network_scan4(RIL_Token t) {
+ ALOGV("Scanning network 1.4 - void");
+ gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0);
+ return;
+}
+
+static void request_emergency_dial(int /*request*/, void* /*data*/, size_t /*datalen*/,
+ RIL_Token t) {
+ ALOGV("Emergency dial - void");
+ gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0);
+ return;
+}
+
+static void request_set_sim_card_power(int /*request*/, void* /*data*/, size_t /*datalen*/,
+ RIL_Token t) {
+ ALOGV("Set sim card power - void");
+ gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0);
+ return;
+}
+#endif
+
static void gce_ril_on_request(int request, void* data, size_t datalen,
RIL_Token t) {
// Ignore all requests except RIL_REQUEST_GET_SIM_STATUS
@@ -2422,6 +2452,22 @@
break;
#endif
+
+// New requests after P.
+#if VSOC_PLATFORM_SDK_AFTER(P)
+ case RIL_REQUEST_START_NETWORK_SCAN:
+ request_start_network_scan(t);
+ break;
+ case RIL_REQUEST_START_NETWORK_SCAN4:
+ request_start_network_scan4(t);
+ break;
+ case RIL_REQUEST_EMERGENCY_DIAL:
+ request_emergency_dial(request, data, datalen, t);
+ break;
+ case RIL_REQUEST_SET_SIM_CARD_POWER:
+ request_set_sim_card_power(request, data, datalen, t);
+ break;
+#endif
case RIL_REQUEST_REPORT_STK_SERVICE_IS_RUNNING:
gce_ril_env->OnRequestComplete(t, RIL_E_SUCCESS, NULL, 0);
break;
diff --git a/guest/hals/ril/vsoc_ril.h b/guest/hals/ril/vsoc_ril.h
index 982ff56..19909bb 100644
--- a/guest/hals/ril/vsoc_ril.h
+++ b/guest/hals/ril/vsoc_ril.h
@@ -24,5 +24,13 @@
#include <stdint.h>
#include <stdlib.h>
#include <sys/time.h>
+
+// Start to use and maintain the local ril.h file from Q.
+#include "guest/libs/platform_support/api_level_fixes.h"
+#if VSOC_PLATFORM_SDK_BEFORE(Q)
#include <telephony/ril.h>
-#include <telephony/ril_cdma_sms.h>
+#else
+#include <guest/hals/ril/libril/ril.h>
+#endif
+
+#include <telephony/ril_cdma_sms.h>
\ No newline at end of file
diff --git a/guest/hals/rild/Android.mk b/guest/hals/rild/Android.mk
new file mode 100644
index 0000000..f3c9757
--- /dev/null
+++ b/guest/hals/rild/Android.mk
@@ -0,0 +1,63 @@
+# Copyright (C) 2006 The Android Open Source Project
+#
+# Licensed under the Apache License, Version 2.0 (the "License");
+# you may not use this file except in compliance with the License.
+# You may obtain a copy of the License at
+#
+# http://www.apache.org/licenses/LICENSE-2.0
+#
+# Unless required by applicable law or agreed to in writing, software
+# distributed under the License is distributed on an "AS IS" BASIS,
+# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+# See the License for the specific language governing permissions and
+# limitations under the License.
+
+# only for PLATFORM_VERSION greater or equal to Q
+ifeq ($(PLATFORM_VERSION), $(word 1, $(sort Q $(PLATFORM_VERSION))))
+
+ ifndef ENABLE_VENDOR_RIL_SERVICE
+
+ LOCAL_PATH:= $(call my-dir)
+ include $(CLEAR_VARS)
+
+ LOCAL_SRC_FILES:= \
+ rild_cuttlefish.c
+
+ LOCAL_SHARED_LIBRARIES := \
+ libcutils \
+ libdl \
+ liblog \
+ libvsoc-ril
+
+ LOCAL_C_INCLUDES += \
+ device/google/cuttlefish_common
+
+ # Temporary hack for broken vendor RILs.
+ LOCAL_WHOLE_STATIC_LIBRARIES := \
+ librilutils
+
+ LOCAL_CFLAGS := -DRIL_SHLIB
+ LOCAL_CFLAGS += -Wall -Wextra -Werror
+
+ ifeq ($(SIM_COUNT), 2)
+ LOCAL_CFLAGS += -DANDROID_MULTI_SIM
+ LOCAL_CFLAGS += -DANDROID_SIM_COUNT_2
+ endif
+
+ LOCAL_MODULE_RELATIVE_PATH := hw
+ LOCAL_PROPRIETARY_MODULE := true
+ LOCAL_MODULE:= libvsoc-rild
+ LOCAL_OVERRIDES_PACKAGES := rild
+ PACKAGES.$(LOCAL_MODULE).OVERRIDES := rild
+ ifeq ($(PRODUCT_COMPATIBLE_PROPERTY),true)
+ LOCAL_INIT_RC := rild_cuttlefish.rc
+ LOCAL_CFLAGS += -DPRODUCT_COMPATIBLE_PROPERTY
+ else
+ LOCAL_INIT_RC := rild_cuttlefish.legacy.rc
+ endif
+
+ include $(BUILD_EXECUTABLE)
+
+ endif
+
+endif
diff --git a/guest/hals/rild/rild_cuttlefish.c b/guest/hals/rild/rild_cuttlefish.c
new file mode 100644
index 0000000..23fae59
--- /dev/null
+++ b/guest/hals/rild/rild_cuttlefish.c
@@ -0,0 +1,238 @@
+/* //device/system/rild/rild.c
+**
+** Copyright 2006 The Android Open Source Project
+**
+** Licensed under the Apache License, Version 2.0 (the "License");
+** you may not use this file except in compliance with the License.
+** You may obtain a copy of the License at
+**
+** http://www.apache.org/licenses/LICENSE-2.0
+**
+** Unless required by applicable law or agreed to in writing, software
+** distributed under the License is distributed on an "AS IS" BASIS,
+** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+** See the License for the specific language governing permissions and
+** limitations under the License.
+*/
+
+#include <stdio.h>
+#include <stdlib.h>
+#include <dlfcn.h>
+#include <string.h>
+#include <stdint.h>
+#include <unistd.h>
+#include <fcntl.h>
+#include <errno.h>
+
+#include <guest/hals/ril/libril/ril.h>
+
+#define LOG_TAG "RILD"
+#include <log/log.h>
+#include <cutils/properties.h>
+#include <cutils/sockets.h>
+#include <sys/capability.h>
+#include <sys/prctl.h>
+#include <sys/stat.h>
+#include <sys/types.h>
+#include <guest/hals/ril/libril/ril_ex.h>
+
+#if defined(PRODUCT_COMPATIBLE_PROPERTY)
+#define LIB_PATH_PROPERTY "vendor.rild.libpath"
+#define LIB_ARGS_PROPERTY "vendor.rild.libargs"
+#else
+#define LIB_PATH_PROPERTY "rild.libpath"
+#define LIB_ARGS_PROPERTY "rild.libargs"
+#endif
+#define MAX_LIB_ARGS 16
+
+static void usage(const char *argv0) {
+ fprintf(stderr, "Usage: %s -l <ril impl library> [-- <args for impl library>]\n", argv0);
+ exit(EXIT_FAILURE);
+}
+
+extern char ril_service_name_base[MAX_SERVICE_NAME_LENGTH];
+extern char ril_service_name[MAX_SERVICE_NAME_LENGTH];
+
+extern void RIL_register (const RIL_RadioFunctions *callbacks);
+extern void rilc_thread_pool ();
+
+extern void RIL_register_socket (const RIL_RadioFunctions *(*rilUimInit)
+ (const struct RIL_Env *, int, char **), RIL_SOCKET_TYPE socketType, int argc, char **argv);
+
+extern void RIL_onRequestComplete(RIL_Token t, RIL_Errno e,
+ void *response, size_t responselen);
+
+extern void RIL_onRequestAck(RIL_Token t);
+
+#if defined(ANDROID_MULTI_SIM)
+extern void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen, RIL_SOCKET_ID socket_id);
+#else
+extern void RIL_onUnsolicitedResponse(int unsolResponse, const void *data,
+ size_t datalen);
+#endif
+
+extern void RIL_requestTimedCallback (RIL_TimedCallback callback,
+ void *param, const struct timeval *relativeTime);
+
+
+static struct RIL_Env s_rilEnv = {
+ RIL_onRequestComplete,
+ RIL_onUnsolicitedResponse,
+ RIL_requestTimedCallback,
+ RIL_onRequestAck
+};
+
+extern void RIL_startEventLoop();
+
+static int make_argv(char * args, char ** argv) {
+ // Note: reserve argv[0]
+ int count = 1;
+ char * tok;
+ char * s = args;
+
+ while ((tok = strtok(s, " \0"))) {
+ argv[count] = tok;
+ s = NULL;
+ count++;
+ }
+ return count;
+}
+
+int main(int argc, char **argv) {
+ // vendor ril lib path either passed in as -l parameter, or read from rild.libpath property
+ const char *rilLibPath = NULL;
+ // ril arguments either passed in as -- parameter, or read from rild.libargs property
+ char **rilArgv;
+ // handle for vendor ril lib
+ void *dlHandle;
+ // Pointer to ril init function in vendor ril
+ const RIL_RadioFunctions *(*rilInit)(const struct RIL_Env *, int, char **);
+ // Pointer to sap init function in vendor ril
+ const RIL_RadioFunctions *(*rilUimInit)(const struct RIL_Env *, int, char **);
+ const char *err_str = NULL;
+
+ // functions returned by ril init function in vendor ril
+ const RIL_RadioFunctions *funcs;
+ // lib path from rild.libpath property (if it's read)
+ char libPath[PROPERTY_VALUE_MAX];
+ // flat to indicate if -- parameters are present
+ unsigned char hasLibArgs = 0;
+
+ int i;
+ // ril/socket id received as -c parameter, otherwise set to 0
+ const char *clientId = NULL;
+
+ RLOGD("**RIL Daemon Started - Hola, Benito A 1.4**");
+ RLOGD("**RILd param count=%d**", argc);
+
+ umask(S_IRGRP | S_IWGRP | S_IXGRP | S_IROTH | S_IWOTH | S_IXOTH);
+ for (i = 1; i < argc ;) {
+ if (0 == strcmp(argv[i], "-l") && (argc - i > 1)) {
+ rilLibPath = argv[i + 1];
+ i += 2;
+ } else if (0 == strcmp(argv[i], "--")) {
+ i++;
+ hasLibArgs = 1;
+ break;
+ } else if (0 == strcmp(argv[i], "-c") && (argc - i > 1)) {
+ clientId = argv[i+1];
+ i += 2;
+ } else {
+ usage(argv[0]);
+ }
+ }
+
+ if (clientId == NULL) {
+ clientId = "0";
+ } else if (atoi(clientId) >= MAX_RILDS) {
+ RLOGE("Max Number of rild's supported is: %d", MAX_RILDS);
+ exit(0);
+ }
+ if (strncmp(clientId, "0", MAX_CLIENT_ID_LENGTH)) {
+ snprintf(ril_service_name, sizeof(ril_service_name), "%s%s", ril_service_name_base,
+ clientId);
+ }
+
+ if (rilLibPath == NULL) {
+ if ( 0 == property_get(LIB_PATH_PROPERTY, libPath, NULL)) {
+ // No lib sepcified on the command line, and nothing set in props.
+ // Assume "no-ril" case.
+ goto done;
+ } else {
+ rilLibPath = libPath;
+ }
+ }
+
+ dlHandle = dlopen(rilLibPath, RTLD_NOW);
+
+ if (dlHandle == NULL) {
+ RLOGE("dlopen failed: %s", dlerror());
+ exit(EXIT_FAILURE);
+ }
+
+ RIL_startEventLoop();
+
+ rilInit =
+ (const RIL_RadioFunctions *(*)(const struct RIL_Env *, int, char **))
+ dlsym(dlHandle, "RIL_Init");
+
+ if (rilInit == NULL) {
+ RLOGE("RIL_Init not defined or exported in %s\n", rilLibPath);
+ exit(EXIT_FAILURE);
+ }
+
+ dlerror(); // Clear any previous dlerror
+ rilUimInit =
+ (const RIL_RadioFunctions *(*)(const struct RIL_Env *, int, char **))
+ dlsym(dlHandle, "RIL_SAP_Init");
+ err_str = dlerror();
+ if (err_str) {
+ RLOGW("RIL_SAP_Init not defined or exported in %s: %s\n", rilLibPath, err_str);
+ } else if (!rilUimInit) {
+ RLOGW("RIL_SAP_Init defined as null in %s. SAP Not usable\n", rilLibPath);
+ }
+
+ if (hasLibArgs) {
+ rilArgv = argv + i - 1;
+ argc = argc -i + 1;
+ } else {
+ static char * newArgv[MAX_LIB_ARGS];
+ static char args[PROPERTY_VALUE_MAX];
+ rilArgv = newArgv;
+ property_get(LIB_ARGS_PROPERTY, args, "");
+ argc = make_argv(args, rilArgv);
+ }
+
+ rilArgv[argc++] = "-c";
+ rilArgv[argc++] = (char*)clientId;
+ RLOGD("RIL_Init argc = %d clientId = %s", argc, rilArgv[argc-1]);
+
+ // Make sure there's a reasonable argv[0]
+ rilArgv[0] = argv[0];
+
+ funcs = rilInit(&s_rilEnv, argc, rilArgv);
+ RLOGD("RIL_Init rilInit completed");
+
+ RLOGD("RIL_Init callback versions = %d", funcs->version);
+
+ RIL_register(funcs);
+
+ RLOGD("RIL_Init RIL_register completed");
+
+ if (rilUimInit) {
+ RLOGD("RIL_register_socket started");
+ RIL_register_socket(rilUimInit, RIL_SAP_SOCKET, argc, rilArgv);
+ }
+
+ RLOGD("RIL_register_socket completed");
+
+done:
+
+ rilc_thread_pool();
+
+ RLOGD("RIL_Init starting sleep loop");
+ while (true) {
+ sleep(UINT32_MAX);
+ }
+}
diff --git a/guest/hals/rild/rild_cuttlefish.legacy.rc b/guest/hals/rild/rild_cuttlefish.legacy.rc
new file mode 100644
index 0000000..43898ce
--- /dev/null
+++ b/guest/hals/rild/rild_cuttlefish.legacy.rc
@@ -0,0 +1,5 @@
+service ril-daemon /vendor/bin/hw/libvsoc-rild
+ class main
+ user radio
+ group radio cache inet misc audio log readproc wakelock
+ capabilities BLOCK_SUSPEND NET_ADMIN NET_RAW
diff --git a/guest/hals/rild/rild_cuttlefish.rc b/guest/hals/rild/rild_cuttlefish.rc
new file mode 100644
index 0000000..e7d8d9a
--- /dev/null
+++ b/guest/hals/rild/rild_cuttlefish.rc
@@ -0,0 +1,5 @@
+service vendor.ril-daemon /vendor/bin/hw/libvsoc-rild
+ class main
+ user radio
+ group radio cache inet misc audio log readproc wakelock
+ capabilities BLOCK_SUSPEND NET_ADMIN NET_RAW
