Google Git
Sign in
android / platform / external / bluetooth / bluedroid / 0a8c803a48fe5afa71d1f8660539012e9b1f9642 / . / hci / src / hci_mct.c
blob: 5316326f11694840216f2835cf1e2460d85a4012 [file] [log] [blame]
/******************************************************************************
*
* Copyright (C) 2009-2012 Broadcom Corporation
*
* 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.
*
******************************************************************************/
/******************************************************************************
*
* Filename: hci_mct.c
*
* Description: Contains HCI transport send/receive functions
* for Multi-Channels Transport
*
******************************************************************************/
#define LOG_TAG "bt_mct"
#include <utils/Log.h>
#include <stdlib.h>
#include <fcntl.h>
#include "bt_hci_bdroid.h"
#include "btsnoop.h"
#include "hci.h"
#include "userial.h"
#include "utils.h"
#include "vendor.h"
/******************************************************************************
** Constants & Macros
******************************************************************************/
#ifndef HCI_DBG
#define HCI_DBG FALSE
#endif
#if (HCI_DBG == TRUE)
#define HCIDBG(param, ...) {LOGD(param, ## __VA_ARGS__);}
#else
#define HCIDBG(param, ...) {}
#endif
/* Preamble length for HCI Commands:
** 2-bytes for opcode and 1 byte for length
*/
#define HCI_CMD_PREAMBLE_SIZE 3
/* Preamble length for HCI Events:
** 1-byte for opcode and 1 byte for length
*/
#define HCI_EVT_PREAMBLE_SIZE 2
/* Preamble length for SCO Data:
** 2-byte for Handle and 1 byte for length
*/
#define HCI_SCO_PREAMBLE_SIZE 3
/* Preamble length for ACL Data:
** 2-byte for Handle and 2 byte for length
*/
#define HCI_ACL_PREAMBLE_SIZE 4
#define ACL_RX_PKT_START 2
#define ACL_RX_PKT_CONTINUE 1
#define L2CAP_HEADER_SIZE 4
/* Maximum numbers of allowed internal
** outstanding command packets at any time
*/
#define INT_CMD_PKT_MAX_COUNT 8
#define INT_CMD_PKT_IDX_MASK 0x07
#define HCI_COMMAND_COMPLETE_EVT 0x0E
#define HCI_COMMAND_STATUS_EVT 0x0F
#define HCI_READ_BUFFER_SIZE 0x1005
#define HCI_LE_READ_BUFFER_SIZE 0x2002
/******************************************************************************
** Local type definitions
******************************************************************************/
/* MCT Rx States */
typedef enum {
MCT_RX_NEWMSG_ST,
MCT_RX_LEN_ST,
MCT_RX_DATA_ST,
MCT_RX_IGNORE_ST
} tHCI_MCT_RCV_STATE;
/* Callback function for the returned event of internal issued command */
typedef void (*tINT_CMD_CBACK)(void *p_mem);
typedef struct
{
uint16_t opcode; /* OPCODE of outstanding internal commands */
tINT_CMD_CBACK cback; /* Callback function when return of internal
* command is received */
} tINT_CMD_Q;
typedef struct
{
HC_BT_HDR *p_rcv_msg; /* Buffer to hold current rx HCI message */
uint16_t rcv_len; /* Size of current incoming message */
tHCI_MCT_RCV_STATE rcv_state; /* Receive state of current rx message */
uint8_t preload_count; /* Count numbers of preload bytes */
uint8_t preload_buffer[6]; /* HCI_ACL_PREAMBLE_SIZE + 2 */
} tHCI_RCV_CB;
/* Control block for HCISU_MCT */
typedef struct
{
tHCI_RCV_CB rcv_evt;
tHCI_RCV_CB rcv_acl;
uint16_t hc_acl_data_size; /* Controller's max ACL data length */
uint16_t hc_ble_acl_data_size; /* Controller's max BLE ACL data length */
BUFFER_Q acl_rx_q; /* Queue of base buffers for fragmented ACL pkts */
int int_cmd_rsp_pending; /* Num of internal cmds pending for ack */
uint8_t int_cmd_rd_idx; /* Read index of int_cmd_opcode queue */
uint8_t int_cmd_wrt_idx; /* Write index of int_cmd_opcode queue */
tINT_CMD_Q int_cmd[INT_CMD_PKT_MAX_COUNT]; /* FIFO queue */
} tHCI_MCT_CB;
/******************************************************************************
** Externs
******************************************************************************/
uint8_t hci_mct_send_int_cmd(uint16_t opcode, HC_BT_HDR *p_buf, \
tINT_CMD_CBACK p_cback);
void lpm_wake_assert(void);
void lpm_tx_done(uint8_t is_tx_done);
/******************************************************************************
** Variables
******************************************************************************/
/* Num of allowed outstanding HCI CMD packets */
volatile int num_hci_cmd_pkts = 1;
/******************************************************************************
** Static variables
******************************************************************************/
static tHCI_MCT_CB mct_cb;
/******************************************************************************
** Static functions
******************************************************************************/
/*******************************************************************************
**
** Function get_acl_data_length_cback
**
** Description Callback function for HCI_READ_BUFFER_SIZE and
** HCI_LE_READ_BUFFER_SIZE commands if they were sent because
** of internal request.
**
** Returns None
**
*******************************************************************************/
void get_acl_data_length_cback(void *p_mem)
{
uint8_t *p, status;
uint16_t opcode, len=0;
HC_BT_HDR *p_buf = (HC_BT_HDR *) p_mem;
p = (uint8_t *)(p_buf + 1) + 3;
STREAM_TO_UINT16(opcode, p)
status = *p++;
if (status == 0) /* Success */
STREAM_TO_UINT16(len, p)
if (opcode == HCI_READ_BUFFER_SIZE)
{
if (status == 0)
mct_cb.hc_acl_data_size = len;
/* reuse the rx buffer for sending HCI_LE_READ_BUFFER_SIZE command */
p_buf->event = MSG_STACK_TO_HC_HCI_CMD;
p_buf->offset = 0;
p_buf->layer_specific = 0;
p_buf->len = 3;
p = (uint8_t *) (p_buf + 1);
UINT16_TO_STREAM(p, HCI_LE_READ_BUFFER_SIZE);
*p = 0;
if ((status = hci_mct_send_int_cmd(HCI_LE_READ_BUFFER_SIZE, p_buf, \
get_acl_data_length_cback)) == FALSE)
{
bt_hc_cbacks->dealloc(p_buf);
bt_hc_cbacks->postload_cb(NULL, BT_HC_POSTLOAD_SUCCESS);
}
}
else if (opcode == HCI_LE_READ_BUFFER_SIZE)
{
if (status == 0)
mct_cb.hc_ble_acl_data_size = (len) ? len : mct_cb.hc_acl_data_size;
if (bt_hc_cbacks)
{
bt_hc_cbacks->dealloc(p_buf);
ALOGE("hci lib postload completed");
bt_hc_cbacks->postload_cb(NULL, BT_HC_POSTLOAD_SUCCESS);
}
}
}
/*******************************************************************************
**
** Function internal_event_intercept
**
** Description This function is called to parse received HCI event and
** - update the Num_HCI_Command_Packets
** - intercept the event if it is the result of an early
** issued internal command.
**
** Returns TRUE : if the event had been intercepted for internal process
** FALSE : send this event to core stack
**
*******************************************************************************/
uint8_t internal_event_intercept(void)
{
uint8_t *p;
uint8_t event_code;
uint16_t opcode, len;
tHCI_MCT_CB *p_cb = &mct_cb;
p = (uint8_t *)(p_cb->rcv_evt.p_rcv_msg + 1);
event_code = *p++;
len = *p++;
if (event_code == HCI_COMMAND_COMPLETE_EVT)
{
utils_lock();
num_hci_cmd_pkts = *p++;
utils_unlock();
// Signal TX event so the worker thread can check if it has anything
// to send
bthc_tx(NULL);
if (p_cb->int_cmd_rsp_pending > 0)
{
STREAM_TO_UINT16(opcode, p)
if (opcode == p_cb->int_cmd[p_cb->int_cmd_rd_idx].opcode)
{
HCIDBG( \
"Intercept CommandCompleteEvent for internal command (0x%04X)",\
opcode);
if (p_cb->int_cmd[p_cb->int_cmd_rd_idx].cback != NULL)
{
p_cb->int_cmd[p_cb->int_cmd_rd_idx].cback(p_cb->rcv_evt.p_rcv_msg);
}
else
{
// Missing cback function!
// Release the p_rcv_msg buffer.
if (bt_hc_cbacks)
{
bt_hc_cbacks->dealloc(p_cb->rcv_evt.p_rcv_msg);
}
}
p_cb->int_cmd_rd_idx = ((p_cb->int_cmd_rd_idx+1) & \
INT_CMD_PKT_IDX_MASK);
p_cb->int_cmd_rsp_pending--;
return TRUE;
}
}
}
else if (event_code == HCI_COMMAND_STATUS_EVT)
{
utils_lock();
num_hci_cmd_pkts = *(++p);
utils_unlock();
// Signal TX event so the worker thread can check if it has anything
// to send
bthc_tx(NULL);
}
return FALSE;
}
/*******************************************************************************
**
** Function acl_rx_frame_buffer_alloc
**
** Description This function is called from the HCI transport when the
** first 4 or 6 bytes of an HCI ACL packet have been received:
** - Allocate a new buffer if it is a start pakcet of L2CAP
** message.
** - Return the buffer address of the starting L2CAP message
** frame if the packet is the next segment of a fragmented
** L2CAP message.
**
** Returns the address of the receive buffer caller should use
** (CR419: Modified to return NULL in case of error.)
**
** NOTE This assumes that the L2CAP MTU size is less than the size
** of an HCI ACL buffer, so the maximum L2CAP message will fit
** into one buffer.
**
*******************************************************************************/
static HC_BT_HDR *acl_rx_frame_buffer_alloc (void)
{
uint8_t *p;
uint16_t handle;
uint16_t hci_len;
uint16_t total_len;
uint8_t pkt_type;
HC_BT_HDR *p_return_buf = NULL;
tHCI_MCT_CB *p_cb = &mct_cb;
p = p_cb->rcv_acl.preload_buffer;
STREAM_TO_UINT16 (handle, p);
STREAM_TO_UINT16 (hci_len, p);
STREAM_TO_UINT16 (total_len, p);
pkt_type = (uint8_t)(((handle) >> 12) & 0x0003);
handle = (uint16_t)((handle) & 0x0FFF);
if (p_cb->acl_rx_q.count)
{
uint16_t save_handle;
HC_BT_HDR *p_hdr = p_cb->acl_rx_q.p_first;
while (p_hdr != NULL)
{
p = (uint8_t *)(p_hdr + 1);
STREAM_TO_UINT16 (save_handle, p);
save_handle = (uint16_t)((save_handle) & 0x0FFF);
if (save_handle == handle)
{
p_return_buf = p_hdr;
break;
}
p_hdr = utils_getnext(p_hdr);
}
}
if (pkt_type == ACL_RX_PKT_START) /*** START PACKET ***/
{
/* Might have read 2 bytes for the L2CAP payload length */
p_cb->rcv_acl.rcv_len = (hci_len) ? (hci_len - 2) : 0;
/* Start of packet. If we were in the middle of receiving */
/* a packet on the same ACL handle, the original packet is incomplete.
* Drop it. */
if (p_return_buf)
{
ALOGW("dropping incomplete ACL frame");
utils_remove_from_queue(&(p_cb->acl_rx_q), p_return_buf);
if (bt_hc_cbacks)
{
bt_hc_cbacks->dealloc(p_return_buf);
}
p_return_buf = NULL;
}
/* Allocate a buffer for message */
if (bt_hc_cbacks)
{
int len = total_len + HCI_ACL_PREAMBLE_SIZE + L2CAP_HEADER_SIZE + \
BT_HC_HDR_SIZE;
p_return_buf = (HC_BT_HDR *) bt_hc_cbacks->alloc(len);
}
if (p_return_buf)
{
/* Initialize buffer with preloaded data */
p_return_buf->offset = 0;
p_return_buf->layer_specific = 0;
p_return_buf->event = MSG_HC_TO_STACK_HCI_ACL;
p_return_buf->len = p_cb->rcv_acl.preload_count;
memcpy((uint8_t *)(p_return_buf + 1), p_cb->rcv_acl.preload_buffer, \
p_cb->rcv_acl.preload_count);
if (hci_len && ((total_len + L2CAP_HEADER_SIZE) > hci_len))
{
/* Will expect to see fragmented ACL packets */
/* Keep the base buffer address in the watching queue */
utils_enqueue(&(p_cb->acl_rx_q), p_return_buf);
}
}
}
else /*** CONTINUATION PACKET ***/
{
p_cb->rcv_acl.rcv_len = hci_len;
if (p_return_buf)
{
/* Packet continuation and found the original rx buffer */
uint8_t *p_f = p = (uint8_t *)(p_return_buf + 1) + 2;
STREAM_TO_UINT16 (total_len, p);
/* Update HCI header of first segment (base buffer) with new len */
total_len += hci_len;
UINT16_TO_STREAM (p_f, total_len);
}
}
return (p_return_buf);
}
/*******************************************************************************
**
** Function acl_rx_frame_end_chk
**
** Description This function is called from the HCI transport when the last
** byte of an HCI ACL packet has been received. It checks if
** the L2CAP message is complete, i.e. no more continuation
** packets are expected.
**
** Returns TRUE if message complete, FALSE if continuation expected
**
*******************************************************************************/
static uint8_t acl_rx_frame_end_chk (void)
{
uint8_t *p;
uint16_t handle, hci_len, l2cap_len;
HC_BT_HDR *p_buf;
tHCI_MCT_CB *p_cb = &mct_cb;
uint8_t frame_end=TRUE;
p_buf = p_cb->rcv_acl.p_rcv_msg;
p = (uint8_t *)(p_buf + 1);
STREAM_TO_UINT16 (handle, p);
STREAM_TO_UINT16 (hci_len, p);
STREAM_TO_UINT16 (l2cap_len, p);
if (hci_len > 0)
{
if (l2cap_len > (p_buf->len-(HCI_ACL_PREAMBLE_SIZE+L2CAP_HEADER_SIZE)) )
{
/* If the L2CAP length has not been reached, tell caller not to send
* this buffer to stack */
frame_end = FALSE;
}
else
{
/*
* The current buffer coulb be in the watching list.
* Remove it from the list if it is in.
*/
if (p_cb->acl_rx_q.count)
utils_remove_from_queue(&(p_cb->acl_rx_q), p_buf);
}
}
/****
** Print snoop trace
****/
if (p_buf->offset)
{
/* CONTINUATION PACKET */
/* save original p_buf->len content */
uint16_t tmp_u16 = p_buf->len;
/* borrow HCI_ACL_PREAMBLE_SIZE bytes from the payload section */
p = (uint8_t *)(p_buf + 1) + p_buf->offset - HCI_ACL_PREAMBLE_SIZE;
/* save contents */
memcpy(p_cb->rcv_acl.preload_buffer, p, HCI_ACL_PREAMBLE_SIZE);
/* Set packet boundary flags to "continuation packet" */
handle = (handle & 0xCFFF) | 0x1000;
/* write handl & length info */
UINT16_TO_STREAM (p, handle);
UINT16_TO_STREAM (p, (p_buf->len - p_buf->offset));
/* roll pointer back */
p = p - HCI_ACL_PREAMBLE_SIZE;
/* adjust `p_buf->offset` & `p_buf->len`
* before calling btsnoop_capture() */
p_buf->offset = p_buf->offset - HCI_ACL_PREAMBLE_SIZE;
p_buf->len = p_buf->len - p_buf->offset;
btsnoop_capture(p_buf, true);
/* restore contents */
memcpy(p, p_cb->rcv_acl.preload_buffer, HCI_ACL_PREAMBLE_SIZE);
/* restore p_buf->len */
p_buf->len = tmp_u16;
}
else
{
/* START PACKET */
btsnoop_capture(p_buf, true);
}
if (frame_end == TRUE)
p_buf->offset = 0;
else
p_buf->offset = p_buf->len; /* save current buffer-end position */
return frame_end;
}
/*****************************************************************************
** HCI MCT INTERFACE FUNCTIONS
*****************************************************************************/
/*******************************************************************************
**
** Function hci_mct_init
**
** Description Initialize MCT module
**
** Returns None
**
*******************************************************************************/
void hci_mct_init(void)
{
HCIDBG("hci_mct_init");
memset(&mct_cb, 0, sizeof(tHCI_MCT_CB));
utils_queue_init(&(mct_cb.acl_rx_q));
/* Per HCI spec., always starts with 1 */
num_hci_cmd_pkts = 1;
/* Give an initial values of Host Controller's ACL data packet length
* Will update with an internal HCI(_LE)_Read_Buffer_Size request
*/
mct_cb.hc_acl_data_size = 1021;
mct_cb.hc_ble_acl_data_size = 27;
}
/*******************************************************************************
**
** Function hci_mct_cleanup
**
** Description Clean MCT module
**
** Returns None
**
*******************************************************************************/
void hci_mct_cleanup(void)
{
HCIDBG("hci_mct_cleanup");
}
/*******************************************************************************
**
** Function hci_mct_send_msg
**
** Description Determine message type, then send message through according
** channel
**
** Returns None
**
*******************************************************************************/
void hci_mct_send_msg(HC_BT_HDR *p_msg)
{
uint16_t handle;
uint16_t lay_spec;
uint8_t *p = ((uint8_t *)(p_msg + 1)) + p_msg->offset;
uint16_t event = p_msg->event & MSG_EVT_MASK;
uint16_t sub_event = p_msg->event & MSG_SUB_EVT_MASK;
uint16_t acl_pkt_size = 0, acl_data_size = 0;
/* wake up BT device if its in sleep mode */
lpm_wake_assert();
if (sub_event == LOCAL_BR_EDR_CONTROLLER_ID)
{
acl_data_size = mct_cb.hc_acl_data_size;
acl_pkt_size = mct_cb.hc_acl_data_size + HCI_ACL_PREAMBLE_SIZE;
}
else
{
acl_data_size = mct_cb.hc_ble_acl_data_size;
acl_pkt_size = mct_cb.hc_ble_acl_data_size + HCI_ACL_PREAMBLE_SIZE;
}
/* Check if sending ACL data that needs fragmenting */
if ((event == MSG_STACK_TO_HC_HCI_ACL) && (p_msg->len > acl_pkt_size))
{
/* Get the handle from the packet */
STREAM_TO_UINT16 (handle, p);
/* Set packet boundary flags to "continuation packet" */
handle = (handle & 0xCFFF) | 0x1000;
/* Do all the first chunks */
while (p_msg->len > acl_pkt_size)
{
p = ((uint8_t *)(p_msg + 1)) + p_msg->offset;
userial_write(event, (uint8_t *) p, acl_pkt_size);
/* generate snoop trace message */
btsnoop_capture(p_msg, false);
/* Adjust offset and length for what we just sent */
p_msg->offset += acl_data_size;
p_msg->len -= acl_data_size;
p = ((uint8_t *)(p_msg + 1)) + p_msg->offset;
UINT16_TO_STREAM (p, handle);
if (p_msg->len > acl_pkt_size)
{
UINT16_TO_STREAM (p, acl_data_size);
}
else
{
UINT16_TO_STREAM (p, p_msg->len - HCI_ACL_PREAMBLE_SIZE);
}
/* If we were only to send partial buffer, stop when done. */
/* Send the buffer back to L2CAP to send the rest of it later */
if (p_msg->layer_specific)
{
if (--p_msg->layer_specific == 0)
{
p_msg->event = MSG_HC_TO_STACK_L2C_SEG_XMIT;
if (bt_hc_cbacks)
{
bt_hc_cbacks->tx_result((TRANSAC) p_msg, \
(char *) (p_msg + 1), \
BT_HC_TX_FRAGMENT);
}
return;
}
}
}
}
p = ((uint8_t *)(p_msg + 1)) + p_msg->offset;
if (event == MSG_STACK_TO_HC_HCI_CMD)
{
uint8_t *p_tmp = p;
utils_lock();
num_hci_cmd_pkts--;
utils_unlock();
/* If this is an internal Cmd packet, the layer_specific field would
* have stored with the opcode of HCI command.
* Retrieve the opcode from the Cmd packet.
*/
p_tmp++;
STREAM_TO_UINT16(lay_spec, p_tmp);
}
userial_write(event, (uint8_t *) p, p_msg->len);
/* generate snoop trace message */
btsnoop_capture(p_msg, false);
if (bt_hc_cbacks)
{
if ((event == MSG_STACK_TO_HC_HCI_CMD) && \
(mct_cb.int_cmd_rsp_pending > 0) && \
(p_msg->layer_specific == lay_spec))
{
/* dealloc buffer of internal command */
bt_hc_cbacks->dealloc(p_msg);
}
else
{
bt_hc_cbacks->tx_result((TRANSAC) p_msg, (char *) (p_msg + 1), \
BT_HC_TX_SUCCESS);
}
}
lpm_tx_done(TRUE);
return;
}
/*******************************************************************************
**
** Function hci_mct_receive_evt_msg
**
** Description Construct HCI EVENT packet
**
** Returns Number of read bytes
**
*******************************************************************************/
uint16_t hci_mct_receive_evt_msg(void)
{
uint16_t bytes_read = 0;
uint8_t byte;
uint16_t msg_len, len;
uint8_t msg_received;
tHCI_RCV_CB *p_cb=&mct_cb.rcv_evt;
uint8_t continue_fetch_looping = TRUE;
while (continue_fetch_looping)
{
/* Read one byte to see if there is anything waiting to be read */
if (userial_read(MSG_HC_TO_STACK_HCI_EVT, &byte, 1) == 0)
{
break;
}
bytes_read++;
msg_received = FALSE;
switch (p_cb->rcv_state)
{
case MCT_RX_NEWMSG_ST:
/* Start of new message */
/* Initialize rx parameters */
memset(p_cb->preload_buffer, 0 , 6);
p_cb->preload_buffer[0] = byte;
p_cb->preload_count = 1;
p_cb->rcv_len = HCI_EVT_PREAMBLE_SIZE - 1;
// p_cb->p_rcv_msg = NULL;
p_cb->rcv_state = MCT_RX_LEN_ST; /* Next, wait for length to come */
break;
case MCT_RX_LEN_ST:
/* Receiving preamble */
p_cb->preload_buffer[p_cb->preload_count++] = byte;
p_cb->rcv_len--;
/* Check if we received entire preamble yet */
if (p_cb->rcv_len == 0)
{
/* Received entire preamble.
* Length is in the last received byte */
msg_len = byte;
p_cb->rcv_len = msg_len;
/* Allocate a buffer for message */
if (bt_hc_cbacks)
{
len = msg_len + p_cb->preload_count + BT_HC_HDR_SIZE;
p_cb->p_rcv_msg = \
(HC_BT_HDR *) bt_hc_cbacks->alloc(len);
}
if (p_cb->p_rcv_msg)
{
/* Initialize buffer with preloaded data */
p_cb->p_rcv_msg->offset = 0;
p_cb->p_rcv_msg->layer_specific = 0;
p_cb->p_rcv_msg->event = MSG_HC_TO_STACK_HCI_EVT;
p_cb->p_rcv_msg->len = p_cb->preload_count;
memcpy((uint8_t *)(p_cb->p_rcv_msg + 1), \
p_cb->preload_buffer, p_cb->preload_count);
}
else
{
/* Unable to acquire message buffer. */
ALOGE( \
"Unable to acquire buffer for incoming HCI message." \
);
if (msg_len == 0)
{
/* Wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
else
{
/* Ignore rest of the packet */
p_cb->rcv_state = MCT_RX_IGNORE_ST;
}
break;
}
/* Message length is valid */
if (msg_len)
{
/* Read rest of message */
p_cb->rcv_state = MCT_RX_DATA_ST;
}
else
{
/* Message has no additional parameters.
* (Entire message has been received) */
msg_received = TRUE;
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
}
break;
case MCT_RX_DATA_ST:
*((uint8_t *)(p_cb->p_rcv_msg + 1) + p_cb->p_rcv_msg->len++) = byte;
p_cb->rcv_len--;
if (p_cb->rcv_len > 0)
{
/* Read in the rest of the message */
len = userial_read(MSG_HC_TO_STACK_HCI_EVT, \
((uint8_t *)(p_cb->p_rcv_msg+1) + p_cb->p_rcv_msg->len), \
p_cb->rcv_len);
p_cb->p_rcv_msg->len += len;
p_cb->rcv_len -= len;
bytes_read += len;
}
/* Check if we read in entire message yet */
if (p_cb->rcv_len == 0)
{
/* Received entire packet. */
msg_received = TRUE;
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
break;
case MCT_RX_IGNORE_ST:
/* Ignore reset of packet */
p_cb->rcv_len--;
/* Check if we read in entire message yet */
if (p_cb->rcv_len == 0)
{
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
break;
}
/* If we received entire message, then send it to the task */
if (msg_received)
{
uint8_t intercepted = FALSE;
/* generate snoop trace message */
btsnoop_capture(p_cb->p_rcv_msg, true);
intercepted = internal_event_intercept();
if ((bt_hc_cbacks) && (intercepted == FALSE))
{
bt_hc_cbacks->data_ind((TRANSAC) p_cb->p_rcv_msg, \
(char *) (p_cb->p_rcv_msg + 1), \
p_cb->p_rcv_msg->len + BT_HC_HDR_SIZE);
}
p_cb->p_rcv_msg = NULL;
}
}
return (bytes_read);
}
/*******************************************************************************
**
** Function hci_mct_receive_acl_msg
**
** Description Construct HCI ACL packet
**
** Returns Number of read bytes
**
*******************************************************************************/
uint16_t hci_mct_receive_acl_msg(void)
{
uint16_t bytes_read = 0;
uint8_t byte;
uint16_t msg_len, len;
uint8_t msg_received;
tHCI_RCV_CB *p_cb=&mct_cb.rcv_acl;
uint8_t continue_fetch_looping = TRUE;
while (continue_fetch_looping)
{
/* Read one byte to see if there is anything waiting to be read */
if (userial_read(MSG_HC_TO_STACK_HCI_ACL, &byte, 1) == 0)
{
break;
}
bytes_read++;
msg_received = FALSE;
switch (p_cb->rcv_state)
{
case MCT_RX_NEWMSG_ST:
/* Start of new message */
/* Initialize rx parameters */
memset(p_cb->preload_buffer, 0 , 6);
p_cb->preload_buffer[0] = byte;
p_cb->preload_count = 1;
p_cb->rcv_len = HCI_ACL_PREAMBLE_SIZE - 1;
// p_cb->p_rcv_msg = NULL;
p_cb->rcv_state = MCT_RX_LEN_ST; /* Next, wait for length to come */
break;
case MCT_RX_LEN_ST:
/* Receiving preamble */
p_cb->preload_buffer[p_cb->preload_count++] = byte;
p_cb->rcv_len--;
/* Check if we received entire preamble yet */
if (p_cb->rcv_len == 0)
{
/* ACL data lengths are 16-bits */
msg_len = p_cb->preload_buffer[3];
msg_len = (msg_len << 8) + p_cb->preload_buffer[2];
if (msg_len && (p_cb->preload_count == 4))
{
/* Check if this is a start packet */
byte = ((p_cb->preload_buffer[1] >> 4) & 0x03);
if (byte == ACL_RX_PKT_START)
{
/*
* A start packet & with non-zero data payload length.
* We want to read 2 more bytes to get L2CAP payload
* length.
*/
p_cb->rcv_len = 2;
break;
}
}
/*
* Check for segmented packets. If this is a continuation
* packet, then we will continue appending data to the
* original rcv buffer.
*/
p_cb->p_rcv_msg = acl_rx_frame_buffer_alloc();
if (p_cb->p_rcv_msg == NULL)
{
/* Unable to acquire message buffer. */
ALOGE( \
"Unable to acquire buffer for incoming HCI message." \
);
if (msg_len == 0)
{
/* Wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
else
{
/* Ignore rest of the packet */
p_cb->rcv_state = MCT_RX_IGNORE_ST;
}
break;
}
/* Message length is valid */
if (msg_len)
{
/* Read rest of message */
p_cb->rcv_state = MCT_RX_DATA_ST;
}
else
{
/* Message has no additional parameters.
* (Entire message has been received) */
acl_rx_frame_end_chk(); /* to print snoop trace */
msg_received = TRUE;
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
}
break;
case MCT_RX_DATA_ST:
*((uint8_t *)(p_cb->p_rcv_msg + 1) + p_cb->p_rcv_msg->len++) = byte;
p_cb->rcv_len--;
if (p_cb->rcv_len > 0)
{
/* Read in the rest of the message */
len = userial_read(MSG_HC_TO_STACK_HCI_ACL, \
((uint8_t *)(p_cb->p_rcv_msg+1) + p_cb->p_rcv_msg->len), \
p_cb->rcv_len);
p_cb->p_rcv_msg->len += len;
p_cb->rcv_len -= len;
bytes_read += len;
}
/* Check if we read in entire message yet */
if (p_cb->rcv_len == 0)
{
/* Received entire packet. */
/* Check for segmented l2cap packets */
if (acl_rx_frame_end_chk())
{
msg_received = TRUE;
}
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
break;
case MCT_RX_IGNORE_ST:
/* Ignore reset of packet */
p_cb->rcv_len--;
/* Check if we read in entire message yet */
if (p_cb->rcv_len == 0)
{
/* Next, wait for next message */
p_cb->rcv_state = MCT_RX_NEWMSG_ST;
continue_fetch_looping = FALSE;
}
break;
}
/* If we received entire message, then send it to the task */
if (msg_received)
{
if (bt_hc_cbacks)
{
bt_hc_cbacks->data_ind((TRANSAC) p_cb->p_rcv_msg, \
(char *) (p_cb->p_rcv_msg + 1), \
p_cb->p_rcv_msg->len + BT_HC_HDR_SIZE);
}
p_cb->p_rcv_msg = NULL;
}
}
return (bytes_read);
}
/*******************************************************************************
**
** Function hci_mct_send_int_cmd
**
** Description Place the internal commands (issued internally by hci or
** vendor lib) in the tx_q.
**
** Returns TRUE/FALSE
**
*******************************************************************************/
uint8_t hci_mct_send_int_cmd(uint16_t opcode, HC_BT_HDR *p_buf, \
tINT_CMD_CBACK p_cback)
{
if (mct_cb.int_cmd_rsp_pending > INT_CMD_PKT_MAX_COUNT)
{
ALOGE( \
"Allow only %d outstanding internal commands at a time [Reject 0x%04X]"\
, INT_CMD_PKT_MAX_COUNT, opcode);
return FALSE;
}
mct_cb.int_cmd_rsp_pending++;
mct_cb.int_cmd[mct_cb.int_cmd_wrt_idx].opcode = opcode;
mct_cb.int_cmd[mct_cb.int_cmd_wrt_idx].cback = p_cback;
mct_cb.int_cmd_wrt_idx = ((mct_cb.int_cmd_wrt_idx+1) & INT_CMD_PKT_IDX_MASK);
/* stamp signature to indicate an internal command */
p_buf->layer_specific = opcode;
bthc_tx(p_buf);
return TRUE;
}
/*******************************************************************************
**
** Function hci_mct_get_acl_data_length
**
** Description Issue HCI_READ_BUFFER_SIZE command to retrieve Controller's
** ACL data length setting
**
** Returns None
**
*******************************************************************************/
void hci_mct_get_acl_data_length(void)
{
HC_BT_HDR *p_buf = NULL;
uint8_t *p, ret;
if (bt_hc_cbacks)
{
p_buf = (HC_BT_HDR *) bt_hc_cbacks->alloc(BT_HC_HDR_SIZE + \
HCI_CMD_PREAMBLE_SIZE);
}
if (p_buf)
{
p_buf->event = MSG_STACK_TO_HC_HCI_CMD;
p_buf->offset = 0;
p_buf->layer_specific = 0;
p_buf->len = HCI_CMD_PREAMBLE_SIZE;
p = (uint8_t *) (p_buf + 1);
UINT16_TO_STREAM(p, HCI_READ_BUFFER_SIZE);
*p = 0;
if ((ret = hci_mct_send_int_cmd(HCI_READ_BUFFER_SIZE, p_buf, \
get_acl_data_length_cback)) == FALSE)
{
bt_hc_cbacks->dealloc(p_buf);
}
else
return;
}
if (bt_hc_cbacks)
{
ALOGE("hci lib postload aborted");
bt_hc_cbacks->postload_cb(NULL, BT_HC_POSTLOAD_FAIL);
}
}
/******************************************************************************
** HCI MCT Services interface table
******************************************************************************/
const tHCI_IF hci_mct_func_table =
{
hci_mct_init,
hci_mct_cleanup,
hci_mct_send_msg,
hci_mct_send_int_cmd,
hci_mct_get_acl_data_length,
hci_mct_receive_evt_msg,
hci_mct_receive_acl_msg
};