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android / platform / system / chre / 74231c08 / . / host / common / include / chre_host / generated / host_messages_generated.h
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// automatically generated by the FlatBuffers compiler, do not modify
#ifndef FLATBUFFERS_GENERATED_HOSTMESSAGES_CHRE_FBS_H_
#define FLATBUFFERS_GENERATED_HOSTMESSAGES_CHRE_FBS_H_
#include "flatbuffers/flatbuffers.h"
namespace chre {
namespace fbs {
struct NanoappMessage;
struct NanoappMessageBuilder;
struct NanoappMessageT;
struct HubInfoRequest;
struct HubInfoRequestBuilder;
struct HubInfoRequestT;
struct HubInfoResponse;
struct HubInfoResponseBuilder;
struct HubInfoResponseT;
struct NanoappListRequest;
struct NanoappListRequestBuilder;
struct NanoappListRequestT;
struct NanoappRpcService;
struct NanoappRpcServiceBuilder;
struct NanoappRpcServiceT;
struct NanoappListEntry;
struct NanoappListEntryBuilder;
struct NanoappListEntryT;
struct NanoappListResponse;
struct NanoappListResponseBuilder;
struct NanoappListResponseT;
struct LoadNanoappRequest;
struct LoadNanoappRequestBuilder;
struct LoadNanoappRequestT;
struct LoadNanoappResponse;
struct LoadNanoappResponseBuilder;
struct LoadNanoappResponseT;
struct UnloadNanoappRequest;
struct UnloadNanoappRequestBuilder;
struct UnloadNanoappRequestT;
struct UnloadNanoappResponse;
struct UnloadNanoappResponseBuilder;
struct UnloadNanoappResponseT;
struct LogMessage;
struct LogMessageBuilder;
struct LogMessageT;
struct TimeSyncMessage;
struct TimeSyncMessageBuilder;
struct TimeSyncMessageT;
struct DebugDumpRequest;
struct DebugDumpRequestBuilder;
struct DebugDumpRequestT;
struct DebugDumpData;
struct DebugDumpDataBuilder;
struct DebugDumpDataT;
struct DebugDumpResponse;
struct DebugDumpResponseBuilder;
struct DebugDumpResponseT;
struct TimeSyncRequest;
struct TimeSyncRequestBuilder;
struct TimeSyncRequestT;
struct LowPowerMicAccessRequest;
struct LowPowerMicAccessRequestBuilder;
struct LowPowerMicAccessRequestT;
struct LowPowerMicAccessRelease;
struct LowPowerMicAccessReleaseBuilder;
struct LowPowerMicAccessReleaseT;
struct SettingChangeMessage;
struct SettingChangeMessageBuilder;
struct SettingChangeMessageT;
struct LogMessageV2;
struct LogMessageV2Builder;
struct LogMessageV2T;
struct SelfTestRequest;
struct SelfTestRequestBuilder;
struct SelfTestRequestT;
struct SelfTestResponse;
struct SelfTestResponseBuilder;
struct SelfTestResponseT;
struct HostEndpointConnected;
struct HostEndpointConnectedBuilder;
struct HostEndpointConnectedT;
struct HostEndpointDisconnected;
struct HostEndpointDisconnectedBuilder;
struct HostEndpointDisconnectedT;
struct MetricLog;
struct MetricLogBuilder;
struct MetricLogT;
struct BatchedMetricLog;
struct BatchedMetricLogBuilder;
struct BatchedMetricLogT;
struct NanConfigurationRequest;
struct NanConfigurationRequestBuilder;
struct NanConfigurationRequestT;
struct NanConfigurationUpdate;
struct NanConfigurationUpdateBuilder;
struct NanConfigurationUpdateT;
struct HostAddress;
struct MessageContainer;
struct MessageContainerBuilder;
struct MessageContainerT;
/// An enum describing the setting type.
enum class Setting : int8_t {
LOCATION = 0,
WIFI_AVAILABLE = 1,
AIRPLANE_MODE = 2,
MICROPHONE = 3,
BLE_AVAILABLE = 4,
MIN = LOCATION,
MAX = BLE_AVAILABLE
};
inline const Setting (&EnumValuesSetting())[5] {
static const Setting values[] = {
Setting::LOCATION,
Setting::WIFI_AVAILABLE,
Setting::AIRPLANE_MODE,
Setting::MICROPHONE,
Setting::BLE_AVAILABLE
};
return values;
}
inline const char * const *EnumNamesSetting() {
static const char * const names[6] = {
"LOCATION",
"WIFI_AVAILABLE",
"AIRPLANE_MODE",
"MICROPHONE",
"BLE_AVAILABLE",
nullptr
};
return names;
}
inline const char *EnumNameSetting(Setting e) {
if (flatbuffers::IsOutRange(e, Setting::LOCATION, Setting::BLE_AVAILABLE)) return "";
const size_t index = static_cast<size_t>(e);
return EnumNamesSetting()[index];
}
/// An enum describing the state of a setting.
enum class SettingState : int8_t {
DISABLED = 0,
ENABLED = 1,
MIN = DISABLED,
MAX = ENABLED
};
inline const SettingState (&EnumValuesSettingState())[2] {
static const SettingState values[] = {
SettingState::DISABLED,
SettingState::ENABLED
};
return values;
}
inline const char * const *EnumNamesSettingState() {
static const char * const names[3] = {
"DISABLED",
"ENABLED",
nullptr
};
return names;
}
inline const char *EnumNameSettingState(SettingState e) {
if (flatbuffers::IsOutRange(e, SettingState::DISABLED, SettingState::ENABLED)) return "";
const size_t index = static_cast<size_t>(e);
return EnumNamesSettingState()[index];
}
/// A union that joins together all possible messages. Note that in FlatBuffers,
/// unions have an implicit type
enum class ChreMessage : uint8_t {
NONE = 0,
NanoappMessage = 1,
HubInfoRequest = 2,
HubInfoResponse = 3,
NanoappListRequest = 4,
NanoappListResponse = 5,
LoadNanoappRequest = 6,
LoadNanoappResponse = 7,
UnloadNanoappRequest = 8,
UnloadNanoappResponse = 9,
LogMessage = 10,
TimeSyncMessage = 11,
DebugDumpRequest = 12,
DebugDumpData = 13,
DebugDumpResponse = 14,
TimeSyncRequest = 15,
LowPowerMicAccessRequest = 16,
LowPowerMicAccessRelease = 17,
SettingChangeMessage = 18,
LogMessageV2 = 19,
SelfTestRequest = 20,
SelfTestResponse = 21,
HostEndpointConnected = 22,
HostEndpointDisconnected = 23,
MetricLog = 24,
BatchedMetricLog = 25,
NanConfigurationRequest = 26,
NanConfigurationUpdate = 27,
MIN = NONE,
MAX = NanConfigurationUpdate
};
inline const ChreMessage (&EnumValuesChreMessage())[28] {
static const ChreMessage values[] = {
ChreMessage::NONE,
ChreMessage::NanoappMessage,
ChreMessage::HubInfoRequest,
ChreMessage::HubInfoResponse,
ChreMessage::NanoappListRequest,
ChreMessage::NanoappListResponse,
ChreMessage::LoadNanoappRequest,
ChreMessage::LoadNanoappResponse,
ChreMessage::UnloadNanoappRequest,
ChreMessage::UnloadNanoappResponse,
ChreMessage::LogMessage,
ChreMessage::TimeSyncMessage,
ChreMessage::DebugDumpRequest,
ChreMessage::DebugDumpData,
ChreMessage::DebugDumpResponse,
ChreMessage::TimeSyncRequest,
ChreMessage::LowPowerMicAccessRequest,
ChreMessage::LowPowerMicAccessRelease,
ChreMessage::SettingChangeMessage,
ChreMessage::LogMessageV2,
ChreMessage::SelfTestRequest,
ChreMessage::SelfTestResponse,
ChreMessage::HostEndpointConnected,
ChreMessage::HostEndpointDisconnected,
ChreMessage::MetricLog,
ChreMessage::BatchedMetricLog,
ChreMessage::NanConfigurationRequest,
ChreMessage::NanConfigurationUpdate
};
return values;
}
inline const char * const *EnumNamesChreMessage() {
static const char * const names[29] = {
"NONE",
"NanoappMessage",
"HubInfoRequest",
"HubInfoResponse",
"NanoappListRequest",
"NanoappListResponse",
"LoadNanoappRequest",
"LoadNanoappResponse",
"UnloadNanoappRequest",
"UnloadNanoappResponse",
"LogMessage",
"TimeSyncMessage",
"DebugDumpRequest",
"DebugDumpData",
"DebugDumpResponse",
"TimeSyncRequest",
"LowPowerMicAccessRequest",
"LowPowerMicAccessRelease",
"SettingChangeMessage",
"LogMessageV2",
"SelfTestRequest",
"SelfTestResponse",
"HostEndpointConnected",
"HostEndpointDisconnected",
"MetricLog",
"BatchedMetricLog",
"NanConfigurationRequest",
"NanConfigurationUpdate",
nullptr
};
return names;
}
inline const char *EnumNameChreMessage(ChreMessage e) {
if (flatbuffers::IsOutRange(e, ChreMessage::NONE, ChreMessage::NanConfigurationUpdate)) return "";
const size_t index = static_cast<size_t>(e);
return EnumNamesChreMessage()[index];
}
template<typename T> struct ChreMessageTraits {
static const ChreMessage enum_value = ChreMessage::NONE;
};
template<> struct ChreMessageTraits<chre::fbs::NanoappMessage> {
static const ChreMessage enum_value = ChreMessage::NanoappMessage;
};
template<> struct ChreMessageTraits<chre::fbs::HubInfoRequest> {
static const ChreMessage enum_value = ChreMessage::HubInfoRequest;
};
template<> struct ChreMessageTraits<chre::fbs::HubInfoResponse> {
static const ChreMessage enum_value = ChreMessage::HubInfoResponse;
};
template<> struct ChreMessageTraits<chre::fbs::NanoappListRequest> {
static const ChreMessage enum_value = ChreMessage::NanoappListRequest;
};
template<> struct ChreMessageTraits<chre::fbs::NanoappListResponse> {
static const ChreMessage enum_value = ChreMessage::NanoappListResponse;
};
template<> struct ChreMessageTraits<chre::fbs::LoadNanoappRequest> {
static const ChreMessage enum_value = ChreMessage::LoadNanoappRequest;
};
template<> struct ChreMessageTraits<chre::fbs::LoadNanoappResponse> {
static const ChreMessage enum_value = ChreMessage::LoadNanoappResponse;
};
template<> struct ChreMessageTraits<chre::fbs::UnloadNanoappRequest> {
static const ChreMessage enum_value = ChreMessage::UnloadNanoappRequest;
};
template<> struct ChreMessageTraits<chre::fbs::UnloadNanoappResponse> {
static const ChreMessage enum_value = ChreMessage::UnloadNanoappResponse;
};
template<> struct ChreMessageTraits<chre::fbs::LogMessage> {
static const ChreMessage enum_value = ChreMessage::LogMessage;
};
template<> struct ChreMessageTraits<chre::fbs::TimeSyncMessage> {
static const ChreMessage enum_value = ChreMessage::TimeSyncMessage;
};
template<> struct ChreMessageTraits<chre::fbs::DebugDumpRequest> {
static const ChreMessage enum_value = ChreMessage::DebugDumpRequest;
};
template<> struct ChreMessageTraits<chre::fbs::DebugDumpData> {
static const ChreMessage enum_value = ChreMessage::DebugDumpData;
};
template<> struct ChreMessageTraits<chre::fbs::DebugDumpResponse> {
static const ChreMessage enum_value = ChreMessage::DebugDumpResponse;
};
template<> struct ChreMessageTraits<chre::fbs::TimeSyncRequest> {
static const ChreMessage enum_value = ChreMessage::TimeSyncRequest;
};
template<> struct ChreMessageTraits<chre::fbs::LowPowerMicAccessRequest> {
static const ChreMessage enum_value = ChreMessage::LowPowerMicAccessRequest;
};
template<> struct ChreMessageTraits<chre::fbs::LowPowerMicAccessRelease> {
static const ChreMessage enum_value = ChreMessage::LowPowerMicAccessRelease;
};
template<> struct ChreMessageTraits<chre::fbs::SettingChangeMessage> {
static const ChreMessage enum_value = ChreMessage::SettingChangeMessage;
};
template<> struct ChreMessageTraits<chre::fbs::LogMessageV2> {
static const ChreMessage enum_value = ChreMessage::LogMessageV2;
};
template<> struct ChreMessageTraits<chre::fbs::SelfTestRequest> {
static const ChreMessage enum_value = ChreMessage::SelfTestRequest;
};
template<> struct ChreMessageTraits<chre::fbs::SelfTestResponse> {
static const ChreMessage enum_value = ChreMessage::SelfTestResponse;
};
template<> struct ChreMessageTraits<chre::fbs::HostEndpointConnected> {
static const ChreMessage enum_value = ChreMessage::HostEndpointConnected;
};
template<> struct ChreMessageTraits<chre::fbs::HostEndpointDisconnected> {
static const ChreMessage enum_value = ChreMessage::HostEndpointDisconnected;
};
template<> struct ChreMessageTraits<chre::fbs::MetricLog> {
static const ChreMessage enum_value = ChreMessage::MetricLog;
};
template<> struct ChreMessageTraits<chre::fbs::BatchedMetricLog> {
static const ChreMessage enum_value = ChreMessage::BatchedMetricLog;
};
template<> struct ChreMessageTraits<chre::fbs::NanConfigurationRequest> {
static const ChreMessage enum_value = ChreMessage::NanConfigurationRequest;
};
template<> struct ChreMessageTraits<chre::fbs::NanConfigurationUpdate> {
static const ChreMessage enum_value = ChreMessage::NanConfigurationUpdate;
};
struct ChreMessageUnion {
ChreMessage type;
void *value;
ChreMessageUnion() : type(ChreMessage::NONE), value(nullptr) {}
ChreMessageUnion(ChreMessageUnion&& u) FLATBUFFERS_NOEXCEPT :
type(ChreMessage::NONE), value(nullptr)
{ std::swap(type, u.type); std::swap(value, u.value); }
ChreMessageUnion(const ChreMessageUnion &);
ChreMessageUnion &operator=(const ChreMessageUnion &u)
{ ChreMessageUnion t(u); std::swap(type, t.type); std::swap(value, t.value); return *this; }
ChreMessageUnion &operator=(ChreMessageUnion &&u) FLATBUFFERS_NOEXCEPT
{ std::swap(type, u.type); std::swap(value, u.value); return *this; }
~ChreMessageUnion() { Reset(); }
void Reset();
#ifndef FLATBUFFERS_CPP98_STL
template <typename T>
void Set(T&& val) {
using RT = typename std::remove_reference<T>::type;
Reset();
type = ChreMessageTraits<typename RT::TableType>::enum_value;
if (type != ChreMessage::NONE) {
value = new RT(std::forward<T>(val));
}
}
#endif // FLATBUFFERS_CPP98_STL
static void *UnPack(const void *obj, ChreMessage type, const flatbuffers::resolver_function_t *resolver);
flatbuffers::Offset<void> Pack(flatbuffers::FlatBufferBuilder &_fbb, const flatbuffers::rehasher_function_t *_rehasher = nullptr) const;
chre::fbs::NanoappMessageT *AsNanoappMessage() {
return type == ChreMessage::NanoappMessage ?
reinterpret_cast<chre::fbs::NanoappMessageT *>(value) : nullptr;
}
const chre::fbs::NanoappMessageT *AsNanoappMessage() const {
return type == ChreMessage::NanoappMessage ?
reinterpret_cast<const chre::fbs::NanoappMessageT *>(value) : nullptr;
}
chre::fbs::HubInfoRequestT *AsHubInfoRequest() {
return type == ChreMessage::HubInfoRequest ?
reinterpret_cast<chre::fbs::HubInfoRequestT *>(value) : nullptr;
}
const chre::fbs::HubInfoRequestT *AsHubInfoRequest() const {
return type == ChreMessage::HubInfoRequest ?
reinterpret_cast<const chre::fbs::HubInfoRequestT *>(value) : nullptr;
}
chre::fbs::HubInfoResponseT *AsHubInfoResponse() {
return type == ChreMessage::HubInfoResponse ?
reinterpret_cast<chre::fbs::HubInfoResponseT *>(value) : nullptr;
}
const chre::fbs::HubInfoResponseT *AsHubInfoResponse() const {
return type == ChreMessage::HubInfoResponse ?
reinterpret_cast<const chre::fbs::HubInfoResponseT *>(value) : nullptr;
}
chre::fbs::NanoappListRequestT *AsNanoappListRequest() {
return type == ChreMessage::NanoappListRequest ?
reinterpret_cast<chre::fbs::NanoappListRequestT *>(value) : nullptr;
}
const chre::fbs::NanoappListRequestT *AsNanoappListRequest() const {
return type == ChreMessage::NanoappListRequest ?
reinterpret_cast<const chre::fbs::NanoappListRequestT *>(value) : nullptr;
}
chre::fbs::NanoappListResponseT *AsNanoappListResponse() {
return type == ChreMessage::NanoappListResponse ?
reinterpret_cast<chre::fbs::NanoappListResponseT *>(value) : nullptr;
}
const chre::fbs::NanoappListResponseT *AsNanoappListResponse() const {
return type == ChreMessage::NanoappListResponse ?
reinterpret_cast<const chre::fbs::NanoappListResponseT *>(value) : nullptr;
}
chre::fbs::LoadNanoappRequestT *AsLoadNanoappRequest() {
return type == ChreMessage::LoadNanoappRequest ?
reinterpret_cast<chre::fbs::LoadNanoappRequestT *>(value) : nullptr;
}
const chre::fbs::LoadNanoappRequestT *AsLoadNanoappRequest() const {
return type == ChreMessage::LoadNanoappRequest ?
reinterpret_cast<const chre::fbs::LoadNanoappRequestT *>(value) : nullptr;
}
chre::fbs::LoadNanoappResponseT *AsLoadNanoappResponse() {
return type == ChreMessage::LoadNanoappResponse ?
reinterpret_cast<chre::fbs::LoadNanoappResponseT *>(value) : nullptr;
}
const chre::fbs::LoadNanoappResponseT *AsLoadNanoappResponse() const {
return type == ChreMessage::LoadNanoappResponse ?
reinterpret_cast<const chre::fbs::LoadNanoappResponseT *>(value) : nullptr;
}
chre::fbs::UnloadNanoappRequestT *AsUnloadNanoappRequest() {
return type == ChreMessage::UnloadNanoappRequest ?
reinterpret_cast<chre::fbs::UnloadNanoappRequestT *>(value) : nullptr;
}
const chre::fbs::UnloadNanoappRequestT *AsUnloadNanoappRequest() const {
return type == ChreMessage::UnloadNanoappRequest ?
reinterpret_cast<const chre::fbs::UnloadNanoappRequestT *>(value) : nullptr;
}
chre::fbs::UnloadNanoappResponseT *AsUnloadNanoappResponse() {
return type == ChreMessage::UnloadNanoappResponse ?
reinterpret_cast<chre::fbs::UnloadNanoappResponseT *>(value) : nullptr;
}
const chre::fbs::UnloadNanoappResponseT *AsUnloadNanoappResponse() const {
return type == ChreMessage::UnloadNanoappResponse ?
reinterpret_cast<const chre::fbs::UnloadNanoappResponseT *>(value) : nullptr;
}
chre::fbs::LogMessageT *AsLogMessage() {
return type == ChreMessage::LogMessage ?
reinterpret_cast<chre::fbs::LogMessageT *>(value) : nullptr;
}
const chre::fbs::LogMessageT *AsLogMessage() const {
return type == ChreMessage::LogMessage ?
reinterpret_cast<const chre::fbs::LogMessageT *>(value) : nullptr;
}
chre::fbs::TimeSyncMessageT *AsTimeSyncMessage() {
return type == ChreMessage::TimeSyncMessage ?
reinterpret_cast<chre::fbs::TimeSyncMessageT *>(value) : nullptr;
}
const chre::fbs::TimeSyncMessageT *AsTimeSyncMessage() const {
return type == ChreMessage::TimeSyncMessage ?
reinterpret_cast<const chre::fbs::TimeSyncMessageT *>(value) : nullptr;
}
chre::fbs::DebugDumpRequestT *AsDebugDumpRequest() {
return type == ChreMessage::DebugDumpRequest ?
reinterpret_cast<chre::fbs::DebugDumpRequestT *>(value) : nullptr;
}
const chre::fbs::DebugDumpRequestT *AsDebugDumpRequest() const {
return type == ChreMessage::DebugDumpRequest ?
reinterpret_cast<const chre::fbs::DebugDumpRequestT *>(value) : nullptr;
}
chre::fbs::DebugDumpDataT *AsDebugDumpData() {
return type == ChreMessage::DebugDumpData ?
reinterpret_cast<chre::fbs::DebugDumpDataT *>(value) : nullptr;
}
const chre::fbs::DebugDumpDataT *AsDebugDumpData() const {
return type == ChreMessage::DebugDumpData ?
reinterpret_cast<const chre::fbs::DebugDumpDataT *>(value) : nullptr;
}
chre::fbs::DebugDumpResponseT *AsDebugDumpResponse() {
return type == ChreMessage::DebugDumpResponse ?
reinterpret_cast<chre::fbs::DebugDumpResponseT *>(value) : nullptr;
}
const chre::fbs::DebugDumpResponseT *AsDebugDumpResponse() const {
return type == ChreMessage::DebugDumpResponse ?
reinterpret_cast<const chre::fbs::DebugDumpResponseT *>(value) : nullptr;
}
chre::fbs::TimeSyncRequestT *AsTimeSyncRequest() {
return type == ChreMessage::TimeSyncRequest ?
reinterpret_cast<chre::fbs::TimeSyncRequestT *>(value) : nullptr;
}
const chre::fbs::TimeSyncRequestT *AsTimeSyncRequest() const {
return type == ChreMessage::TimeSyncRequest ?
reinterpret_cast<const chre::fbs::TimeSyncRequestT *>(value) : nullptr;
}
chre::fbs::LowPowerMicAccessRequestT *AsLowPowerMicAccessRequest() {
return type == ChreMessage::LowPowerMicAccessRequest ?
reinterpret_cast<chre::fbs::LowPowerMicAccessRequestT *>(value) : nullptr;
}
const chre::fbs::LowPowerMicAccessRequestT *AsLowPowerMicAccessRequest() const {
return type == ChreMessage::LowPowerMicAccessRequest ?
reinterpret_cast<const chre::fbs::LowPowerMicAccessRequestT *>(value) : nullptr;
}
chre::fbs::LowPowerMicAccessReleaseT *AsLowPowerMicAccessRelease() {
return type == ChreMessage::LowPowerMicAccessRelease ?
reinterpret_cast<chre::fbs::LowPowerMicAccessReleaseT *>(value) : nullptr;
}
const chre::fbs::LowPowerMicAccessReleaseT *AsLowPowerMicAccessRelease() const {
return type == ChreMessage::LowPowerMicAccessRelease ?
reinterpret_cast<const chre::fbs::LowPowerMicAccessReleaseT *>(value) : nullptr;
}
chre::fbs::SettingChangeMessageT *AsSettingChangeMessage() {
return type == ChreMessage::SettingChangeMessage ?
reinterpret_cast<chre::fbs::SettingChangeMessageT *>(value) : nullptr;
}
const chre::fbs::SettingChangeMessageT *AsSettingChangeMessage() const {
return type == ChreMessage::SettingChangeMessage ?
reinterpret_cast<const chre::fbs::SettingChangeMessageT *>(value) : nullptr;
}
chre::fbs::LogMessageV2T *AsLogMessageV2() {
return type == ChreMessage::LogMessageV2 ?
reinterpret_cast<chre::fbs::LogMessageV2T *>(value) : nullptr;
}
const chre::fbs::LogMessageV2T *AsLogMessageV2() const {
return type == ChreMessage::LogMessageV2 ?
reinterpret_cast<const chre::fbs::LogMessageV2T *>(value) : nullptr;
}
chre::fbs::SelfTestRequestT *AsSelfTestRequest() {
return type == ChreMessage::SelfTestRequest ?
reinterpret_cast<chre::fbs::SelfTestRequestT *>(value) : nullptr;
}
const chre::fbs::SelfTestRequestT *AsSelfTestRequest() const {
return type == ChreMessage::SelfTestRequest ?
reinterpret_cast<const chre::fbs::SelfTestRequestT *>(value) : nullptr;
}
chre::fbs::SelfTestResponseT *AsSelfTestResponse() {
return type == ChreMessage::SelfTestResponse ?
reinterpret_cast<chre::fbs::SelfTestResponseT *>(value) : nullptr;
}
const chre::fbs::SelfTestResponseT *AsSelfTestResponse() const {
return type == ChreMessage::SelfTestResponse ?
reinterpret_cast<const chre::fbs::SelfTestResponseT *>(value) : nullptr;
}
chre::fbs::HostEndpointConnectedT *AsHostEndpointConnected() {
return type == ChreMessage::HostEndpointConnected ?
reinterpret_cast<chre::fbs::HostEndpointConnectedT *>(value) : nullptr;
}
const chre::fbs::HostEndpointConnectedT *AsHostEndpointConnected() const {
return type == ChreMessage::HostEndpointConnected ?
reinterpret_cast<const chre::fbs::HostEndpointConnectedT *>(value) : nullptr;
}
chre::fbs::HostEndpointDisconnectedT *AsHostEndpointDisconnected() {
return type == ChreMessage::HostEndpointDisconnected ?
reinterpret_cast<chre::fbs::HostEndpointDisconnectedT *>(value) : nullptr;
}
const chre::fbs::HostEndpointDisconnectedT *AsHostEndpointDisconnected() const {
return type == ChreMessage::HostEndpointDisconnected ?
reinterpret_cast<const chre::fbs::HostEndpointDisconnectedT *>(value) : nullptr;
}
chre::fbs::MetricLogT *AsMetricLog() {
return type == ChreMessage::MetricLog ?
reinterpret_cast<chre::fbs::MetricLogT *>(value) : nullptr;
}
const chre::fbs::MetricLogT *AsMetricLog() const {
return type == ChreMessage::MetricLog ?
reinterpret_cast<const chre::fbs::MetricLogT *>(value) : nullptr;
}
chre::fbs::BatchedMetricLogT *AsBatchedMetricLog() {
return type == ChreMessage::BatchedMetricLog ?
reinterpret_cast<chre::fbs::BatchedMetricLogT *>(value) : nullptr;
}
const chre::fbs::BatchedMetricLogT *AsBatchedMetricLog() const {
return type == ChreMessage::BatchedMetricLog ?
reinterpret_cast<const chre::fbs::BatchedMetricLogT *>(value) : nullptr;
}
chre::fbs::NanConfigurationRequestT *AsNanConfigurationRequest() {
return type == ChreMessage::NanConfigurationRequest ?
reinterpret_cast<chre::fbs::NanConfigurationRequestT *>(value) : nullptr;
}
const chre::fbs::NanConfigurationRequestT *AsNanConfigurationRequest() const {
return type == ChreMessage::NanConfigurationRequest ?
reinterpret_cast<const chre::fbs::NanConfigurationRequestT *>(value) : nullptr;
}
chre::fbs::NanConfigurationUpdateT *AsNanConfigurationUpdate() {
return type == ChreMessage::NanConfigurationUpdate ?
reinterpret_cast<chre::fbs::NanConfigurationUpdateT *>(value) : nullptr;
}
const chre::fbs::NanConfigurationUpdateT *AsNanConfigurationUpdate() const {
return type == ChreMessage::NanConfigurationUpdate ?
reinterpret_cast<const chre::fbs::NanConfigurationUpdateT *>(value) : nullptr;
}
};
bool VerifyChreMessage(flatbuffers::Verifier &verifier, const void *obj, ChreMessage type);
bool VerifyChreMessageVector(flatbuffers::Verifier &verifier, const flatbuffers::Vector<flatbuffers::Offset<void>> *values, const flatbuffers::Vector<uint8_t> *types);
FLATBUFFERS_MANUALLY_ALIGNED_STRUCT(2) HostAddress FLATBUFFERS_FINAL_CLASS {
private:
uint16_t client_id_;
public:
HostAddress() {
memset(static_cast<void *>(this), 0, sizeof(HostAddress));
}
HostAddress(uint16_t _client_id)
: client_id_(flatbuffers::EndianScalar(_client_id)) {
}
uint16_t client_id() const {
return flatbuffers::EndianScalar(client_id_);
}
void mutate_client_id(uint16_t _client_id) {
flatbuffers::WriteScalar(&client_id_, _client_id);
}
};
FLATBUFFERS_STRUCT_END(HostAddress, 2);
struct NanoappMessageT : public flatbuffers::NativeTable {
typedef NanoappMessage TableType;
uint64_t app_id;
uint32_t message_type;
uint16_t host_endpoint;
std::vector<uint8_t> message;
uint32_t message_permissions;
uint32_t permissions;
bool woke_host;
NanoappMessageT()
: app_id(0),
message_type(0),
host_endpoint(65534),
message_permissions(0),
permissions(0),
woke_host(false) {
}
};
/// Represents a message sent to/from a nanoapp from/to a client on the host
struct NanoappMessage FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanoappMessageT NativeTableType;
typedef NanoappMessageBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_APP_ID = 4,
VT_MESSAGE_TYPE = 6,
VT_HOST_ENDPOINT = 8,
VT_MESSAGE = 10,
VT_MESSAGE_PERMISSIONS = 12,
VT_PERMISSIONS = 14,
VT_WOKE_HOST = 16
};
uint64_t app_id() const {
return GetField<uint64_t>(VT_APP_ID, 0);
}
bool mutate_app_id(uint64_t _app_id) {
return SetField<uint64_t>(VT_APP_ID, _app_id, 0);
}
uint32_t message_type() const {
return GetField<uint32_t>(VT_MESSAGE_TYPE, 0);
}
bool mutate_message_type(uint32_t _message_type) {
return SetField<uint32_t>(VT_MESSAGE_TYPE, _message_type, 0);
}
/// Identifies the host-side endpoint on the host that sent or should receive
/// this message. The default value is a special value defined in the HAL and
/// elsewhere that indicates that the endpoint is unspecified.
uint16_t host_endpoint() const {
return GetField<uint16_t>(VT_HOST_ENDPOINT, 65534);
}
bool mutate_host_endpoint(uint16_t _host_endpoint) {
return SetField<uint16_t>(VT_HOST_ENDPOINT, _host_endpoint, 65534);
}
/// Vector containing arbitrary application-specific message data
const flatbuffers::Vector<uint8_t> *message() const {
return GetPointer<const flatbuffers::Vector<uint8_t> *>(VT_MESSAGE);
}
flatbuffers::Vector<uint8_t> *mutable_message() {
return GetPointer<flatbuffers::Vector<uint8_t> *>(VT_MESSAGE);
}
/// List of Android permissions that cover the contents of a message from a
/// nanoapp to the host.
/// These permissions are used to record and attribute access to
/// permissions-controlled resources.
uint32_t message_permissions() const {
return GetField<uint32_t>(VT_MESSAGE_PERMISSIONS, 0);
}
bool mutate_message_permissions(uint32_t _message_permissions) {
return SetField<uint32_t>(VT_MESSAGE_PERMISSIONS, _message_permissions, 0);
}
/// List of Android permissions declared by the nanoapp / granted to the host.
/// For messages from a nanoaapp to the host, this must be a superset of
/// message_permissions.
uint32_t permissions() const {
return GetField<uint32_t>(VT_PERMISSIONS, 0);
}
bool mutate_permissions(uint32_t _permissions) {
return SetField<uint32_t>(VT_PERMISSIONS, _permissions, 0);
}
bool woke_host() const {
return GetField<uint8_t>(VT_WOKE_HOST, 0) != 0;
}
bool mutate_woke_host(bool _woke_host) {
return SetField<uint8_t>(VT_WOKE_HOST, static_cast<uint8_t>(_woke_host), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint64_t>(verifier, VT_APP_ID) &&
VerifyField<uint32_t>(verifier, VT_MESSAGE_TYPE) &&
VerifyField<uint16_t>(verifier, VT_HOST_ENDPOINT) &&
VerifyOffsetRequired(verifier, VT_MESSAGE) &&
verifier.VerifyVector(message()) &&
VerifyField<uint32_t>(verifier, VT_MESSAGE_PERMISSIONS) &&
VerifyField<uint32_t>(verifier, VT_PERMISSIONS) &&
VerifyField<uint8_t>(verifier, VT_WOKE_HOST) &&
verifier.EndTable();
}
NanoappMessageT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanoappMessageT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanoappMessage> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanoappMessageBuilder {
typedef NanoappMessage Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_app_id(uint64_t app_id) {
fbb_.AddElement<uint64_t>(NanoappMessage::VT_APP_ID, app_id, 0);
}
void add_message_type(uint32_t message_type) {
fbb_.AddElement<uint32_t>(NanoappMessage::VT_MESSAGE_TYPE, message_type, 0);
}
void add_host_endpoint(uint16_t host_endpoint) {
fbb_.AddElement<uint16_t>(NanoappMessage::VT_HOST_ENDPOINT, host_endpoint, 65534);
}
void add_message(flatbuffers::Offset<flatbuffers::Vector<uint8_t>> message) {
fbb_.AddOffset(NanoappMessage::VT_MESSAGE, message);
}
void add_message_permissions(uint32_t message_permissions) {
fbb_.AddElement<uint32_t>(NanoappMessage::VT_MESSAGE_PERMISSIONS, message_permissions, 0);
}
void add_permissions(uint32_t permissions) {
fbb_.AddElement<uint32_t>(NanoappMessage::VT_PERMISSIONS, permissions, 0);
}
void add_woke_host(bool woke_host) {
fbb_.AddElement<uint8_t>(NanoappMessage::VT_WOKE_HOST, static_cast<uint8_t>(woke_host), 0);
}
explicit NanoappMessageBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanoappMessageBuilder &operator=(const NanoappMessageBuilder &);
flatbuffers::Offset<NanoappMessage> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanoappMessage>(end);
fbb_.Required(o, NanoappMessage::VT_MESSAGE);
return o;
}
};
inline flatbuffers::Offset<NanoappMessage> CreateNanoappMessage(
flatbuffers::FlatBufferBuilder &_fbb,
uint64_t app_id = 0,
uint32_t message_type = 0,
uint16_t host_endpoint = 65534,
flatbuffers::Offset<flatbuffers::Vector<uint8_t>> message = 0,
uint32_t message_permissions = 0,
uint32_t permissions = 0,
bool woke_host = false) {
NanoappMessageBuilder builder_(_fbb);
builder_.add_app_id(app_id);
builder_.add_permissions(permissions);
builder_.add_message_permissions(message_permissions);
builder_.add_message(message);
builder_.add_message_type(message_type);
builder_.add_host_endpoint(host_endpoint);
builder_.add_woke_host(woke_host);
return builder_.Finish();
}
inline flatbuffers::Offset<NanoappMessage> CreateNanoappMessageDirect(
flatbuffers::FlatBufferBuilder &_fbb,
uint64_t app_id = 0,
uint32_t message_type = 0,
uint16_t host_endpoint = 65534,
const std::vector<uint8_t> *message = nullptr,
uint32_t message_permissions = 0,
uint32_t permissions = 0,
bool woke_host = false) {
auto message__ = message ? _fbb.CreateVector<uint8_t>(*message) : 0;
return chre::fbs::CreateNanoappMessage(
_fbb,
app_id,
message_type,
host_endpoint,
message__,
message_permissions,
permissions,
woke_host);
}
flatbuffers::Offset<NanoappMessage> CreateNanoappMessage(flatbuffers::FlatBufferBuilder &_fbb, const NanoappMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct HubInfoRequestT : public flatbuffers::NativeTable {
typedef HubInfoRequest TableType;
HubInfoRequestT() {
}
};
struct HubInfoRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef HubInfoRequestT NativeTableType;
typedef HubInfoRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
HubInfoRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(HubInfoRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<HubInfoRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct HubInfoRequestBuilder {
typedef HubInfoRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit HubInfoRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
HubInfoRequestBuilder &operator=(const HubInfoRequestBuilder &);
flatbuffers::Offset<HubInfoRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<HubInfoRequest>(end);
return o;
}
};
inline flatbuffers::Offset<HubInfoRequest> CreateHubInfoRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
HubInfoRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<HubInfoRequest> CreateHubInfoRequest(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct HubInfoResponseT : public flatbuffers::NativeTable {
typedef HubInfoResponse TableType;
std::vector<int8_t> name;
std::vector<int8_t> vendor;
std::vector<int8_t> toolchain;
uint32_t platform_version;
uint32_t toolchain_version;
float peak_mips;
float stopped_power;
float sleep_power;
float peak_power;
uint32_t max_msg_len;
uint64_t platform_id;
uint32_t chre_platform_version;
HubInfoResponseT()
: platform_version(0),
toolchain_version(0),
peak_mips(0.0f),
stopped_power(0.0f),
sleep_power(0.0f),
peak_power(0.0f),
max_msg_len(0),
platform_id(0),
chre_platform_version(0) {
}
};
struct HubInfoResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef HubInfoResponseT NativeTableType;
typedef HubInfoResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_NAME = 4,
VT_VENDOR = 6,
VT_TOOLCHAIN = 8,
VT_PLATFORM_VERSION = 10,
VT_TOOLCHAIN_VERSION = 12,
VT_PEAK_MIPS = 14,
VT_STOPPED_POWER = 16,
VT_SLEEP_POWER = 18,
VT_PEAK_POWER = 20,
VT_MAX_MSG_LEN = 22,
VT_PLATFORM_ID = 24,
VT_CHRE_PLATFORM_VERSION = 26
};
/// The name of the hub. Nominally a UTF-8 string, but note that we're not
/// using the built-in "string" data type from FlatBuffers here, because the
/// generated C++ uses std::string which is not well-supported in CHRE. This
/// applies for vendor and toolchain as well.
const flatbuffers::Vector<int8_t> *name() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_NAME);
}
flatbuffers::Vector<int8_t> *mutable_name() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_NAME);
}
const flatbuffers::Vector<int8_t> *vendor() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_VENDOR);
}
flatbuffers::Vector<int8_t> *mutable_vendor() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_VENDOR);
}
const flatbuffers::Vector<int8_t> *toolchain() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_TOOLCHAIN);
}
flatbuffers::Vector<int8_t> *mutable_toolchain() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_TOOLCHAIN);
}
/// Legacy platform version reported in the HAL; semantics not strictly
/// defined
uint32_t platform_version() const {
return GetField<uint32_t>(VT_PLATFORM_VERSION, 0);
}
bool mutate_platform_version(uint32_t _platform_version) {
return SetField<uint32_t>(VT_PLATFORM_VERSION, _platform_version, 0);
}
/// Toolchain version reported in the HAL; semantics not strictly defined
uint32_t toolchain_version() const {
return GetField<uint32_t>(VT_TOOLCHAIN_VERSION, 0);
}
bool mutate_toolchain_version(uint32_t _toolchain_version) {
return SetField<uint32_t>(VT_TOOLCHAIN_VERSION, _toolchain_version, 0);
}
float peak_mips() const {
return GetField<float>(VT_PEAK_MIPS, 0.0f);
}
bool mutate_peak_mips(float _peak_mips) {
return SetField<float>(VT_PEAK_MIPS, _peak_mips, 0.0f);
}
float stopped_power() const {
return GetField<float>(VT_STOPPED_POWER, 0.0f);
}
bool mutate_stopped_power(float _stopped_power) {
return SetField<float>(VT_STOPPED_POWER, _stopped_power, 0.0f);
}
float sleep_power() const {
return GetField<float>(VT_SLEEP_POWER, 0.0f);
}
bool mutate_sleep_power(float _sleep_power) {
return SetField<float>(VT_SLEEP_POWER, _sleep_power, 0.0f);
}
float peak_power() const {
return GetField<float>(VT_PEAK_POWER, 0.0f);
}
bool mutate_peak_power(float _peak_power) {
return SetField<float>(VT_PEAK_POWER, _peak_power, 0.0f);
}
/// Maximum size message that can be sent to a nanoapp
uint32_t max_msg_len() const {
return GetField<uint32_t>(VT_MAX_MSG_LEN, 0);
}
bool mutate_max_msg_len(uint32_t _max_msg_len) {
return SetField<uint32_t>(VT_MAX_MSG_LEN, _max_msg_len, 0);
}
/// @see chreGetPlatformId()
uint64_t platform_id() const {
return GetField<uint64_t>(VT_PLATFORM_ID, 0);
}
bool mutate_platform_id(uint64_t _platform_id) {
return SetField<uint64_t>(VT_PLATFORM_ID, _platform_id, 0);
}
/// @see chreGetVersion()
uint32_t chre_platform_version() const {
return GetField<uint32_t>(VT_CHRE_PLATFORM_VERSION, 0);
}
bool mutate_chre_platform_version(uint32_t _chre_platform_version) {
return SetField<uint32_t>(VT_CHRE_PLATFORM_VERSION, _chre_platform_version, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffset(verifier, VT_NAME) &&
verifier.VerifyVector(name()) &&
VerifyOffset(verifier, VT_VENDOR) &&
verifier.VerifyVector(vendor()) &&
VerifyOffset(verifier, VT_TOOLCHAIN) &&
verifier.VerifyVector(toolchain()) &&
VerifyField<uint32_t>(verifier, VT_PLATFORM_VERSION) &&
VerifyField<uint32_t>(verifier, VT_TOOLCHAIN_VERSION) &&
VerifyField<float>(verifier, VT_PEAK_MIPS) &&
VerifyField<float>(verifier, VT_STOPPED_POWER) &&
VerifyField<float>(verifier, VT_SLEEP_POWER) &&
VerifyField<float>(verifier, VT_PEAK_POWER) &&
VerifyField<uint32_t>(verifier, VT_MAX_MSG_LEN) &&
VerifyField<uint64_t>(verifier, VT_PLATFORM_ID) &&
VerifyField<uint32_t>(verifier, VT_CHRE_PLATFORM_VERSION) &&
verifier.EndTable();
}
HubInfoResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(HubInfoResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<HubInfoResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct HubInfoResponseBuilder {
typedef HubInfoResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_name(flatbuffers::Offset<flatbuffers::Vector<int8_t>> name) {
fbb_.AddOffset(HubInfoResponse::VT_NAME, name);
}
void add_vendor(flatbuffers::Offset<flatbuffers::Vector<int8_t>> vendor) {
fbb_.AddOffset(HubInfoResponse::VT_VENDOR, vendor);
}
void add_toolchain(flatbuffers::Offset<flatbuffers::Vector<int8_t>> toolchain) {
fbb_.AddOffset(HubInfoResponse::VT_TOOLCHAIN, toolchain);
}
void add_platform_version(uint32_t platform_version) {
fbb_.AddElement<uint32_t>(HubInfoResponse::VT_PLATFORM_VERSION, platform_version, 0);
}
void add_toolchain_version(uint32_t toolchain_version) {
fbb_.AddElement<uint32_t>(HubInfoResponse::VT_TOOLCHAIN_VERSION, toolchain_version, 0);
}
void add_peak_mips(float peak_mips) {
fbb_.AddElement<float>(HubInfoResponse::VT_PEAK_MIPS, peak_mips, 0.0f);
}
void add_stopped_power(float stopped_power) {
fbb_.AddElement<float>(HubInfoResponse::VT_STOPPED_POWER, stopped_power, 0.0f);
}
void add_sleep_power(float sleep_power) {
fbb_.AddElement<float>(HubInfoResponse::VT_SLEEP_POWER, sleep_power, 0.0f);
}
void add_peak_power(float peak_power) {
fbb_.AddElement<float>(HubInfoResponse::VT_PEAK_POWER, peak_power, 0.0f);
}
void add_max_msg_len(uint32_t max_msg_len) {
fbb_.AddElement<uint32_t>(HubInfoResponse::VT_MAX_MSG_LEN, max_msg_len, 0);
}
void add_platform_id(uint64_t platform_id) {
fbb_.AddElement<uint64_t>(HubInfoResponse::VT_PLATFORM_ID, platform_id, 0);
}
void add_chre_platform_version(uint32_t chre_platform_version) {
fbb_.AddElement<uint32_t>(HubInfoResponse::VT_CHRE_PLATFORM_VERSION, chre_platform_version, 0);
}
explicit HubInfoResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
HubInfoResponseBuilder &operator=(const HubInfoResponseBuilder &);
flatbuffers::Offset<HubInfoResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<HubInfoResponse>(end);
return o;
}
};
inline flatbuffers::Offset<HubInfoResponse> CreateHubInfoResponse(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> name = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> vendor = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> toolchain = 0,
uint32_t platform_version = 0,
uint32_t toolchain_version = 0,
float peak_mips = 0.0f,
float stopped_power = 0.0f,
float sleep_power = 0.0f,
float peak_power = 0.0f,
uint32_t max_msg_len = 0,
uint64_t platform_id = 0,
uint32_t chre_platform_version = 0) {
HubInfoResponseBuilder builder_(_fbb);
builder_.add_platform_id(platform_id);
builder_.add_chre_platform_version(chre_platform_version);
builder_.add_max_msg_len(max_msg_len);
builder_.add_peak_power(peak_power);
builder_.add_sleep_power(sleep_power);
builder_.add_stopped_power(stopped_power);
builder_.add_peak_mips(peak_mips);
builder_.add_toolchain_version(toolchain_version);
builder_.add_platform_version(platform_version);
builder_.add_toolchain(toolchain);
builder_.add_vendor(vendor);
builder_.add_name(name);
return builder_.Finish();
}
inline flatbuffers::Offset<HubInfoResponse> CreateHubInfoResponseDirect(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<int8_t> *name = nullptr,
const std::vector<int8_t> *vendor = nullptr,
const std::vector<int8_t> *toolchain = nullptr,
uint32_t platform_version = 0,
uint32_t toolchain_version = 0,
float peak_mips = 0.0f,
float stopped_power = 0.0f,
float sleep_power = 0.0f,
float peak_power = 0.0f,
uint32_t max_msg_len = 0,
uint64_t platform_id = 0,
uint32_t chre_platform_version = 0) {
auto name__ = name ? _fbb.CreateVector<int8_t>(*name) : 0;
auto vendor__ = vendor ? _fbb.CreateVector<int8_t>(*vendor) : 0;
auto toolchain__ = toolchain ? _fbb.CreateVector<int8_t>(*toolchain) : 0;
return chre::fbs::CreateHubInfoResponse(
_fbb,
name__,
vendor__,
toolchain__,
platform_version,
toolchain_version,
peak_mips,
stopped_power,
sleep_power,
peak_power,
max_msg_len,
platform_id,
chre_platform_version);
}
flatbuffers::Offset<HubInfoResponse> CreateHubInfoResponse(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanoappListRequestT : public flatbuffers::NativeTable {
typedef NanoappListRequest TableType;
NanoappListRequestT() {
}
};
struct NanoappListRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanoappListRequestT NativeTableType;
typedef NanoappListRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
NanoappListRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanoappListRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanoappListRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanoappListRequestBuilder {
typedef NanoappListRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit NanoappListRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanoappListRequestBuilder &operator=(const NanoappListRequestBuilder &);
flatbuffers::Offset<NanoappListRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanoappListRequest>(end);
return o;
}
};
inline flatbuffers::Offset<NanoappListRequest> CreateNanoappListRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
NanoappListRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<NanoappListRequest> CreateNanoappListRequest(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanoappRpcServiceT : public flatbuffers::NativeTable {
typedef NanoappRpcService TableType;
uint64_t id;
uint32_t version;
NanoappRpcServiceT()
: id(0),
version(0) {
}
};
/// Metadata regarding a Nanoapp RPC service. See the Android API
/// core/java/android/hardware/location/NanoAppRpcService.java for more details
/// on how this value is used by the Android application.
struct NanoappRpcService FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanoappRpcServiceT NativeTableType;
typedef NanoappRpcServiceBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_ID = 4,
VT_VERSION = 6
};
uint64_t id() const {
return GetField<uint64_t>(VT_ID, 0);
}
bool mutate_id(uint64_t _id) {
return SetField<uint64_t>(VT_ID, _id, 0);
}
uint32_t version() const {
return GetField<uint32_t>(VT_VERSION, 0);
}
bool mutate_version(uint32_t _version) {
return SetField<uint32_t>(VT_VERSION, _version, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint64_t>(verifier, VT_ID) &&
VerifyField<uint32_t>(verifier, VT_VERSION) &&
verifier.EndTable();
}
NanoappRpcServiceT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanoappRpcServiceT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanoappRpcService> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappRpcServiceT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanoappRpcServiceBuilder {
typedef NanoappRpcService Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_id(uint64_t id) {
fbb_.AddElement<uint64_t>(NanoappRpcService::VT_ID, id, 0);
}
void add_version(uint32_t version) {
fbb_.AddElement<uint32_t>(NanoappRpcService::VT_VERSION, version, 0);
}
explicit NanoappRpcServiceBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanoappRpcServiceBuilder &operator=(const NanoappRpcServiceBuilder &);
flatbuffers::Offset<NanoappRpcService> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanoappRpcService>(end);
return o;
}
};
inline flatbuffers::Offset<NanoappRpcService> CreateNanoappRpcService(
flatbuffers::FlatBufferBuilder &_fbb,
uint64_t id = 0,
uint32_t version = 0) {
NanoappRpcServiceBuilder builder_(_fbb);
builder_.add_id(id);
builder_.add_version(version);
return builder_.Finish();
}
flatbuffers::Offset<NanoappRpcService> CreateNanoappRpcService(flatbuffers::FlatBufferBuilder &_fbb, const NanoappRpcServiceT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanoappListEntryT : public flatbuffers::NativeTable {
typedef NanoappListEntry TableType;
uint64_t app_id;
uint32_t version;
bool enabled;
bool is_system;
uint32_t permissions;
std::vector<std::unique_ptr<chre::fbs::NanoappRpcServiceT>> rpc_services;
NanoappListEntryT()
: app_id(0),
version(0),
enabled(true),
is_system(false),
permissions(0) {
}
};
struct NanoappListEntry FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanoappListEntryT NativeTableType;
typedef NanoappListEntryBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_APP_ID = 4,
VT_VERSION = 6,
VT_ENABLED = 8,
VT_IS_SYSTEM = 10,
VT_PERMISSIONS = 12,
VT_RPC_SERVICES = 14
};
uint64_t app_id() const {
return GetField<uint64_t>(VT_APP_ID, 0);
}
bool mutate_app_id(uint64_t _app_id) {
return SetField<uint64_t>(VT_APP_ID, _app_id, 0);
}
uint32_t version() const {
return GetField<uint32_t>(VT_VERSION, 0);
}
bool mutate_version(uint32_t _version) {
return SetField<uint32_t>(VT_VERSION, _version, 0);
}
bool enabled() const {
return GetField<uint8_t>(VT_ENABLED, 1) != 0;
}
bool mutate_enabled(bool _enabled) {
return SetField<uint8_t>(VT_ENABLED, static_cast<uint8_t>(_enabled), 1);
}
/// Whether the nanoapp is a pre-loaded "system" nanoapp, i.e. one that should
/// not show up in the list of nanoapps in the context hub HAL. System
/// nanoapps are typically used to leverage CHRE for some device functionality
/// and do not interact via the context hub HAL.
bool is_system() const {
return GetField<uint8_t>(VT_IS_SYSTEM, 0) != 0;
}
bool mutate_is_system(bool _is_system) {
return SetField<uint8_t>(VT_IS_SYSTEM, static_cast<uint8_t>(_is_system), 0);
}
/// Nanoapp permissions, if supported. Nanoapp permissions are required on
/// CHRE API v1.5+, and are defined in chre/util/system/napp_permissions.h
uint32_t permissions() const {
return GetField<uint32_t>(VT_PERMISSIONS, 0);
}
bool mutate_permissions(uint32_t _permissions) {
return SetField<uint32_t>(VT_PERMISSIONS, _permissions, 0);
}
/// The list of RPC services supported by this nanoapp.
const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> *rpc_services() const {
return GetPointer<const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> *>(VT_RPC_SERVICES);
}
flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> *mutable_rpc_services() {
return GetPointer<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> *>(VT_RPC_SERVICES);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint64_t>(verifier, VT_APP_ID) &&
VerifyField<uint32_t>(verifier, VT_VERSION) &&
VerifyField<uint8_t>(verifier, VT_ENABLED) &&
VerifyField<uint8_t>(verifier, VT_IS_SYSTEM) &&
VerifyField<uint32_t>(verifier, VT_PERMISSIONS) &&
VerifyOffset(verifier, VT_RPC_SERVICES) &&
verifier.VerifyVector(rpc_services()) &&
verifier.VerifyVectorOfTables(rpc_services()) &&
verifier.EndTable();
}
NanoappListEntryT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanoappListEntryT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanoappListEntry> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListEntryT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanoappListEntryBuilder {
typedef NanoappListEntry Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_app_id(uint64_t app_id) {
fbb_.AddElement<uint64_t>(NanoappListEntry::VT_APP_ID, app_id, 0);
}
void add_version(uint32_t version) {
fbb_.AddElement<uint32_t>(NanoappListEntry::VT_VERSION, version, 0);
}
void add_enabled(bool enabled) {
fbb_.AddElement<uint8_t>(NanoappListEntry::VT_ENABLED, static_cast<uint8_t>(enabled), 1);
}
void add_is_system(bool is_system) {
fbb_.AddElement<uint8_t>(NanoappListEntry::VT_IS_SYSTEM, static_cast<uint8_t>(is_system), 0);
}
void add_permissions(uint32_t permissions) {
fbb_.AddElement<uint32_t>(NanoappListEntry::VT_PERMISSIONS, permissions, 0);
}
void add_rpc_services(flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>>> rpc_services) {
fbb_.AddOffset(NanoappListEntry::VT_RPC_SERVICES, rpc_services);
}
explicit NanoappListEntryBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanoappListEntryBuilder &operator=(const NanoappListEntryBuilder &);
flatbuffers::Offset<NanoappListEntry> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanoappListEntry>(end);
return o;
}
};
inline flatbuffers::Offset<NanoappListEntry> CreateNanoappListEntry(
flatbuffers::FlatBufferBuilder &_fbb,
uint64_t app_id = 0,
uint32_t version = 0,
bool enabled = true,
bool is_system = false,
uint32_t permissions = 0,
flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>>> rpc_services = 0) {
NanoappListEntryBuilder builder_(_fbb);
builder_.add_app_id(app_id);
builder_.add_rpc_services(rpc_services);
builder_.add_permissions(permissions);
builder_.add_version(version);
builder_.add_is_system(is_system);
builder_.add_enabled(enabled);
return builder_.Finish();
}
inline flatbuffers::Offset<NanoappListEntry> CreateNanoappListEntryDirect(
flatbuffers::FlatBufferBuilder &_fbb,
uint64_t app_id = 0,
uint32_t version = 0,
bool enabled = true,
bool is_system = false,
uint32_t permissions = 0,
const std::vector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> *rpc_services = nullptr) {
auto rpc_services__ = rpc_services ? _fbb.CreateVector<flatbuffers::Offset<chre::fbs::NanoappRpcService>>(*rpc_services) : 0;
return chre::fbs::CreateNanoappListEntry(
_fbb,
app_id,
version,
enabled,
is_system,
permissions,
rpc_services__);
}
flatbuffers::Offset<NanoappListEntry> CreateNanoappListEntry(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListEntryT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanoappListResponseT : public flatbuffers::NativeTable {
typedef NanoappListResponse TableType;
std::vector<std::unique_ptr<chre::fbs::NanoappListEntryT>> nanoapps;
NanoappListResponseT() {
}
};
struct NanoappListResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanoappListResponseT NativeTableType;
typedef NanoappListResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_NANOAPPS = 4
};
const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> *nanoapps() const {
return GetPointer<const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> *>(VT_NANOAPPS);
}
flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> *mutable_nanoapps() {
return GetPointer<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> *>(VT_NANOAPPS);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffsetRequired(verifier, VT_NANOAPPS) &&
verifier.VerifyVector(nanoapps()) &&
verifier.VerifyVectorOfTables(nanoapps()) &&
verifier.EndTable();
}
NanoappListResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanoappListResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanoappListResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanoappListResponseBuilder {
typedef NanoappListResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_nanoapps(flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>>> nanoapps) {
fbb_.AddOffset(NanoappListResponse::VT_NANOAPPS, nanoapps);
}
explicit NanoappListResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanoappListResponseBuilder &operator=(const NanoappListResponseBuilder &);
flatbuffers::Offset<NanoappListResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanoappListResponse>(end);
fbb_.Required(o, NanoappListResponse::VT_NANOAPPS);
return o;
}
};
inline flatbuffers::Offset<NanoappListResponse> CreateNanoappListResponse(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>>> nanoapps = 0) {
NanoappListResponseBuilder builder_(_fbb);
builder_.add_nanoapps(nanoapps);
return builder_.Finish();
}
inline flatbuffers::Offset<NanoappListResponse> CreateNanoappListResponseDirect(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> *nanoapps = nullptr) {
auto nanoapps__ = nanoapps ? _fbb.CreateVector<flatbuffers::Offset<chre::fbs::NanoappListEntry>>(*nanoapps) : 0;
return chre::fbs::CreateNanoappListResponse(
_fbb,
nanoapps__);
}
flatbuffers::Offset<NanoappListResponse> CreateNanoappListResponse(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LoadNanoappRequestT : public flatbuffers::NativeTable {
typedef LoadNanoappRequest TableType;
uint32_t transaction_id;
uint64_t app_id;
uint32_t app_version;
uint32_t target_api_version;
std::vector<uint8_t> app_binary;
uint32_t fragment_id;
uint32_t total_app_size;
std::vector<int8_t> app_binary_file_name;
uint32_t app_flags;
bool respond_before_start;
LoadNanoappRequestT()
: transaction_id(0),
app_id(0),
app_version(0),
target_api_version(0),
fragment_id(0),
total_app_size(0),
app_flags(0),
respond_before_start(false) {
}
};
/// Represents a request for loading a nanoapp.
/// The nanaopp can either be requested to be loaded via a file or via a buffer.
/// For loading via a file, the following steps will be taken:
/// 1. The loader sends a LoadNanoappRequest message to CHRE. app_binary must
/// be set for legacy purposes, but should be empty. Additionally,
/// fragment_id and total_app_size are unused in this request. The loading
/// that happens as part of this request is serialized, but asynchronous
/// meaning that load requests will be processed in the order they are sent
/// but multiple requests can be outstanding at any given time.
/// 2. CHRE stores the filename and waits until its event loop is able to
/// process the request.
/// 3. Once ready, the nanoapp will be loaded from the file specified in the
/// original request and will send a callback indicating the
/// completion/failure of the request.
/// For loading via a buffer, loading may optionally be fragmented into multiple
/// sequential requests, which will follow the following steps:
/// 1. The loader sends a LoadNanoappRequest message to CHRE. If the request
/// is fragmented, then the fields fragment_id and total_app_size must
/// be defined. Once the first fragment is sent to CHRE, all subsequent
/// fragments must be delivered before a new LoadNanoappRequest can be
/// issued. If a new request is received while a current request has
/// outstanding fragments, the current request will be overridden with the
/// new one.
/// 2. CHRE preallocates the required amount of memory, and loads app_binary,
/// appending to already loaded fragments as appropriate.
/// 3. If the request is fragmented, then the requestor must sequentially send
/// multiple LoadNanoappRequest with incremental nanoapp binary fragments.
/// CHRE will respond with LoadNanoappResponse for each request. For
/// requests starting from the second fragment, all fields except
/// fragment_id and app_binary should be ignored by CHRE.
///
/// Once the LoadNanoappRepsonse for the last fragment is received
/// by the HAL, the HAL client will receive a callback indicating the
/// completion/failure of a load request.
///
/// If any request fragment is lost, then the entire load request will be
/// considered to have failed. If the request times out (e.g. the requestor
/// process crashes), then the load request will be cancelled at CHRE and fail.
struct LoadNanoappRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LoadNanoappRequestT NativeTableType;
typedef LoadNanoappRequestBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_TRANSACTION_ID = 4,
VT_APP_ID = 6,
VT_APP_VERSION = 8,
VT_TARGET_API_VERSION = 10,
VT_APP_BINARY = 12,
VT_FRAGMENT_ID = 14,
VT_TOTAL_APP_SIZE = 16,
VT_APP_BINARY_FILE_NAME = 18,
VT_APP_FLAGS = 20,
VT_RESPOND_BEFORE_START = 22
};
uint32_t transaction_id() const {
return GetField<uint32_t>(VT_TRANSACTION_ID, 0);
}
bool mutate_transaction_id(uint32_t _transaction_id) {
return SetField<uint32_t>(VT_TRANSACTION_ID, _transaction_id, 0);
}
uint64_t app_id() const {
return GetField<uint64_t>(VT_APP_ID, 0);
}
bool mutate_app_id(uint64_t _app_id) {
return SetField<uint64_t>(VT_APP_ID, _app_id, 0);
}
uint32_t app_version() const {
return GetField<uint32_t>(VT_APP_VERSION, 0);
}
bool mutate_app_version(uint32_t _app_version) {
return SetField<uint32_t>(VT_APP_VERSION, _app_version, 0);
}
uint32_t target_api_version() const {
return GetField<uint32_t>(VT_TARGET_API_VERSION, 0);
}
bool mutate_target_api_version(uint32_t _target_api_version) {
return SetField<uint32_t>(VT_TARGET_API_VERSION, _target_api_version, 0);
}
const flatbuffers::Vector<uint8_t> *app_binary() const {
return GetPointer<const flatbuffers::Vector<uint8_t> *>(VT_APP_BINARY);
}
flatbuffers::Vector<uint8_t> *mutable_app_binary() {
return GetPointer<flatbuffers::Vector<uint8_t> *>(VT_APP_BINARY);
}
/// Fields that are relevant for fragmented loading
/// The framgent count starts at 1 and should end at the total number of
/// fragments. For clients that do not support fragmented loading, the
/// default behavior should be to assume one fragment.
uint32_t fragment_id() const {
return GetField<uint32_t>(VT_FRAGMENT_ID, 0);
}
bool mutate_fragment_id(uint32_t _fragment_id) {
return SetField<uint32_t>(VT_FRAGMENT_ID, _fragment_id, 0);
}
uint32_t total_app_size() const {
return GetField<uint32_t>(VT_TOTAL_APP_SIZE, 0);
}
bool mutate_total_app_size(uint32_t _total_app_size) {
return SetField<uint32_t>(VT_TOTAL_APP_SIZE, _total_app_size, 0);
}
/// Null-terminated ASCII string containing the file name that contains the
/// app binary to be loaded.
const flatbuffers::Vector<int8_t> *app_binary_file_name() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_APP_BINARY_FILE_NAME);
}
flatbuffers::Vector<int8_t> *mutable_app_binary_file_name() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_APP_BINARY_FILE_NAME);
}
/// The nanoapp flag values from the nanoapp header defined in
/// build/build_template.mk. Refer to that file for more details.
uint32_t app_flags() const {
return GetField<uint32_t>(VT_APP_FLAGS, 0);
}
bool mutate_app_flags(uint32_t _app_flags) {
return SetField<uint32_t>(VT_APP_FLAGS, _app_flags, 0);
}
/// If true and fragmented loading is requested, the LoadNanoappResponse
/// for the last fragment will be sent after the fragment was confirmed
/// to be placed in memory and no additional response will be sent after
/// the nanoapp is linked and started in the framework.
bool respond_before_start() const {
return GetField<uint8_t>(VT_RESPOND_BEFORE_START, 0) != 0;
}
bool mutate_respond_before_start(bool _respond_before_start) {
return SetField<uint8_t>(VT_RESPOND_BEFORE_START, static_cast<uint8_t>(_respond_before_start), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint32_t>(verifier, VT_TRANSACTION_ID) &&
VerifyField<uint64_t>(verifier, VT_APP_ID) &&
VerifyField<uint32_t>(verifier, VT_APP_VERSION) &&
VerifyField<uint32_t>(verifier, VT_TARGET_API_VERSION) &&
VerifyOffsetRequired(verifier, VT_APP_BINARY) &&
verifier.VerifyVector(app_binary()) &&
VerifyField<uint32_t>(verifier, VT_FRAGMENT_ID) &&
VerifyField<uint32_t>(verifier, VT_TOTAL_APP_SIZE) &&
VerifyOffset(verifier, VT_APP_BINARY_FILE_NAME) &&
verifier.VerifyVector(app_binary_file_name()) &&
VerifyField<uint32_t>(verifier, VT_APP_FLAGS) &&
VerifyField<uint8_t>(verifier, VT_RESPOND_BEFORE_START) &&
verifier.EndTable();
}
LoadNanoappRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LoadNanoappRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LoadNanoappRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LoadNanoappRequestBuilder {
typedef LoadNanoappRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_transaction_id(uint32_t transaction_id) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_TRANSACTION_ID, transaction_id, 0);
}
void add_app_id(uint64_t app_id) {
fbb_.AddElement<uint64_t>(LoadNanoappRequest::VT_APP_ID, app_id, 0);
}
void add_app_version(uint32_t app_version) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_APP_VERSION, app_version, 0);
}
void add_target_api_version(uint32_t target_api_version) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_TARGET_API_VERSION, target_api_version, 0);
}
void add_app_binary(flatbuffers::Offset<flatbuffers::Vector<uint8_t>> app_binary) {
fbb_.AddOffset(LoadNanoappRequest::VT_APP_BINARY, app_binary);
}
void add_fragment_id(uint32_t fragment_id) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_FRAGMENT_ID, fragment_id, 0);
}
void add_total_app_size(uint32_t total_app_size) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_TOTAL_APP_SIZE, total_app_size, 0);
}
void add_app_binary_file_name(flatbuffers::Offset<flatbuffers::Vector<int8_t>> app_binary_file_name) {
fbb_.AddOffset(LoadNanoappRequest::VT_APP_BINARY_FILE_NAME, app_binary_file_name);
}
void add_app_flags(uint32_t app_flags) {
fbb_.AddElement<uint32_t>(LoadNanoappRequest::VT_APP_FLAGS, app_flags, 0);
}
void add_respond_before_start(bool respond_before_start) {
fbb_.AddElement<uint8_t>(LoadNanoappRequest::VT_RESPOND_BEFORE_START, static_cast<uint8_t>(respond_before_start), 0);
}
explicit LoadNanoappRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LoadNanoappRequestBuilder &operator=(const LoadNanoappRequestBuilder &);
flatbuffers::Offset<LoadNanoappRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LoadNanoappRequest>(end);
fbb_.Required(o, LoadNanoappRequest::VT_APP_BINARY);
return o;
}
};
inline flatbuffers::Offset<LoadNanoappRequest> CreateLoadNanoappRequest(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t transaction_id = 0,
uint64_t app_id = 0,
uint32_t app_version = 0,
uint32_t target_api_version = 0,
flatbuffers::Offset<flatbuffers::Vector<uint8_t>> app_binary = 0,
uint32_t fragment_id = 0,
uint32_t total_app_size = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> app_binary_file_name = 0,
uint32_t app_flags = 0,
bool respond_before_start = false) {
LoadNanoappRequestBuilder builder_(_fbb);
builder_.add_app_id(app_id);
builder_.add_app_flags(app_flags);
builder_.add_app_binary_file_name(app_binary_file_name);
builder_.add_total_app_size(total_app_size);
builder_.add_fragment_id(fragment_id);
builder_.add_app_binary(app_binary);
builder_.add_target_api_version(target_api_version);
builder_.add_app_version(app_version);
builder_.add_transaction_id(transaction_id);
builder_.add_respond_before_start(respond_before_start);
return builder_.Finish();
}
inline flatbuffers::Offset<LoadNanoappRequest> CreateLoadNanoappRequestDirect(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t transaction_id = 0,
uint64_t app_id = 0,
uint32_t app_version = 0,
uint32_t target_api_version = 0,
const std::vector<uint8_t> *app_binary = nullptr,
uint32_t fragment_id = 0,
uint32_t total_app_size = 0,
const std::vector<int8_t> *app_binary_file_name = nullptr,
uint32_t app_flags = 0,
bool respond_before_start = false) {
auto app_binary__ = app_binary ? _fbb.CreateVector<uint8_t>(*app_binary) : 0;
auto app_binary_file_name__ = app_binary_file_name ? _fbb.CreateVector<int8_t>(*app_binary_file_name) : 0;
return chre::fbs::CreateLoadNanoappRequest(
_fbb,
transaction_id,
app_id,
app_version,
target_api_version,
app_binary__,
fragment_id,
total_app_size,
app_binary_file_name__,
app_flags,
respond_before_start);
}
flatbuffers::Offset<LoadNanoappRequest> CreateLoadNanoappRequest(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LoadNanoappResponseT : public flatbuffers::NativeTable {
typedef LoadNanoappResponse TableType;
uint32_t transaction_id;
bool success;
uint32_t fragment_id;
LoadNanoappResponseT()
: transaction_id(0),
success(false),
fragment_id(0) {
}
};
struct LoadNanoappResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LoadNanoappResponseT NativeTableType;
typedef LoadNanoappResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_TRANSACTION_ID = 4,
VT_SUCCESS = 6,
VT_FRAGMENT_ID = 8
};
uint32_t transaction_id() const {
return GetField<uint32_t>(VT_TRANSACTION_ID, 0);
}
bool mutate_transaction_id(uint32_t _transaction_id) {
return SetField<uint32_t>(VT_TRANSACTION_ID, _transaction_id, 0);
}
/// Denotes whether a load request succeeded or failed.
/// If any fragment of a load request fails, the entire load request for
/// the same transaction will fail.
bool success() const {
return GetField<uint8_t>(VT_SUCCESS, 0) != 0;
}
bool mutate_success(bool _success) {
return SetField<uint8_t>(VT_SUCCESS, static_cast<uint8_t>(_success), 0);
}
/// The fragment count of the load reponse is for.
uint32_t fragment_id() const {
return GetField<uint32_t>(VT_FRAGMENT_ID, 0);
}
bool mutate_fragment_id(uint32_t _fragment_id) {
return SetField<uint32_t>(VT_FRAGMENT_ID, _fragment_id, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint32_t>(verifier, VT_TRANSACTION_ID) &&
VerifyField<uint8_t>(verifier, VT_SUCCESS) &&
VerifyField<uint32_t>(verifier, VT_FRAGMENT_ID) &&
verifier.EndTable();
}
LoadNanoappResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LoadNanoappResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LoadNanoappResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LoadNanoappResponseBuilder {
typedef LoadNanoappResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_transaction_id(uint32_t transaction_id) {
fbb_.AddElement<uint32_t>(LoadNanoappResponse::VT_TRANSACTION_ID, transaction_id, 0);
}
void add_success(bool success) {
fbb_.AddElement<uint8_t>(LoadNanoappResponse::VT_SUCCESS, static_cast<uint8_t>(success), 0);
}
void add_fragment_id(uint32_t fragment_id) {
fbb_.AddElement<uint32_t>(LoadNanoappResponse::VT_FRAGMENT_ID, fragment_id, 0);
}
explicit LoadNanoappResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LoadNanoappResponseBuilder &operator=(const LoadNanoappResponseBuilder &);
flatbuffers::Offset<LoadNanoappResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LoadNanoappResponse>(end);
return o;
}
};
inline flatbuffers::Offset<LoadNanoappResponse> CreateLoadNanoappResponse(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t transaction_id = 0,
bool success = false,
uint32_t fragment_id = 0) {
LoadNanoappResponseBuilder builder_(_fbb);
builder_.add_fragment_id(fragment_id);
builder_.add_transaction_id(transaction_id);
builder_.add_success(success);
return builder_.Finish();
}
flatbuffers::Offset<LoadNanoappResponse> CreateLoadNanoappResponse(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct UnloadNanoappRequestT : public flatbuffers::NativeTable {
typedef UnloadNanoappRequest TableType;
uint32_t transaction_id;
uint64_t app_id;
bool allow_system_nanoapp_unload;
UnloadNanoappRequestT()
: transaction_id(0),
app_id(0),
allow_system_nanoapp_unload(false) {
}
};
struct UnloadNanoappRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef UnloadNanoappRequestT NativeTableType;
typedef UnloadNanoappRequestBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_TRANSACTION_ID = 4,
VT_APP_ID = 6,
VT_ALLOW_SYSTEM_NANOAPP_UNLOAD = 8
};
uint32_t transaction_id() const {
return GetField<uint32_t>(VT_TRANSACTION_ID, 0);
}
bool mutate_transaction_id(uint32_t _transaction_id) {
return SetField<uint32_t>(VT_TRANSACTION_ID, _transaction_id, 0);
}
uint64_t app_id() const {
return GetField<uint64_t>(VT_APP_ID, 0);
}
bool mutate_app_id(uint64_t _app_id) {
return SetField<uint64_t>(VT_APP_ID, _app_id, 0);
}
/// Set to true to allow this request to unload nanoapps identified as "system
/// nanoapps", i.e. ones with is_system set to true in NanoappListResponse.
bool allow_system_nanoapp_unload() const {
return GetField<uint8_t>(VT_ALLOW_SYSTEM_NANOAPP_UNLOAD, 0) != 0;
}
bool mutate_allow_system_nanoapp_unload(bool _allow_system_nanoapp_unload) {
return SetField<uint8_t>(VT_ALLOW_SYSTEM_NANOAPP_UNLOAD, static_cast<uint8_t>(_allow_system_nanoapp_unload), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint32_t>(verifier, VT_TRANSACTION_ID) &&
VerifyField<uint64_t>(verifier, VT_APP_ID) &&
VerifyField<uint8_t>(verifier, VT_ALLOW_SYSTEM_NANOAPP_UNLOAD) &&
verifier.EndTable();
}
UnloadNanoappRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(UnloadNanoappRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<UnloadNanoappRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct UnloadNanoappRequestBuilder {
typedef UnloadNanoappRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_transaction_id(uint32_t transaction_id) {
fbb_.AddElement<uint32_t>(UnloadNanoappRequest::VT_TRANSACTION_ID, transaction_id, 0);
}
void add_app_id(uint64_t app_id) {
fbb_.AddElement<uint64_t>(UnloadNanoappRequest::VT_APP_ID, app_id, 0);
}
void add_allow_system_nanoapp_unload(bool allow_system_nanoapp_unload) {
fbb_.AddElement<uint8_t>(UnloadNanoappRequest::VT_ALLOW_SYSTEM_NANOAPP_UNLOAD, static_cast<uint8_t>(allow_system_nanoapp_unload), 0);
}
explicit UnloadNanoappRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
UnloadNanoappRequestBuilder &operator=(const UnloadNanoappRequestBuilder &);
flatbuffers::Offset<UnloadNanoappRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<UnloadNanoappRequest>(end);
return o;
}
};
inline flatbuffers::Offset<UnloadNanoappRequest> CreateUnloadNanoappRequest(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t transaction_id = 0,
uint64_t app_id = 0,
bool allow_system_nanoapp_unload = false) {
UnloadNanoappRequestBuilder builder_(_fbb);
builder_.add_app_id(app_id);
builder_.add_transaction_id(transaction_id);
builder_.add_allow_system_nanoapp_unload(allow_system_nanoapp_unload);
return builder_.Finish();
}
flatbuffers::Offset<UnloadNanoappRequest> CreateUnloadNanoappRequest(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct UnloadNanoappResponseT : public flatbuffers::NativeTable {
typedef UnloadNanoappResponse TableType;
uint32_t transaction_id;
bool success;
UnloadNanoappResponseT()
: transaction_id(0),
success(false) {
}
};
struct UnloadNanoappResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef UnloadNanoappResponseT NativeTableType;
typedef UnloadNanoappResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_TRANSACTION_ID = 4,
VT_SUCCESS = 6
};
uint32_t transaction_id() const {
return GetField<uint32_t>(VT_TRANSACTION_ID, 0);
}
bool mutate_transaction_id(uint32_t _transaction_id) {
return SetField<uint32_t>(VT_TRANSACTION_ID, _transaction_id, 0);
}
bool success() const {
return GetField<uint8_t>(VT_SUCCESS, 0) != 0;
}
bool mutate_success(bool _success) {
return SetField<uint8_t>(VT_SUCCESS, static_cast<uint8_t>(_success), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint32_t>(verifier, VT_TRANSACTION_ID) &&
VerifyField<uint8_t>(verifier, VT_SUCCESS) &&
verifier.EndTable();
}
UnloadNanoappResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(UnloadNanoappResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<UnloadNanoappResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct UnloadNanoappResponseBuilder {
typedef UnloadNanoappResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_transaction_id(uint32_t transaction_id) {
fbb_.AddElement<uint32_t>(UnloadNanoappResponse::VT_TRANSACTION_ID, transaction_id, 0);
}
void add_success(bool success) {
fbb_.AddElement<uint8_t>(UnloadNanoappResponse::VT_SUCCESS, static_cast<uint8_t>(success), 0);
}
explicit UnloadNanoappResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
UnloadNanoappResponseBuilder &operator=(const UnloadNanoappResponseBuilder &);
flatbuffers::Offset<UnloadNanoappResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<UnloadNanoappResponse>(end);
return o;
}
};
inline flatbuffers::Offset<UnloadNanoappResponse> CreateUnloadNanoappResponse(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t transaction_id = 0,
bool success = false) {
UnloadNanoappResponseBuilder builder_(_fbb);
builder_.add_transaction_id(transaction_id);
builder_.add_success(success);
return builder_.Finish();
}
flatbuffers::Offset<UnloadNanoappResponse> CreateUnloadNanoappResponse(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LogMessageT : public flatbuffers::NativeTable {
typedef LogMessage TableType;
std::vector<int8_t> buffer;
LogMessageT() {
}
};
/// Represents log messages from CHRE.
struct LogMessage FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LogMessageT NativeTableType;
typedef LogMessageBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_BUFFER = 4
};
/// A buffer containing formatted log data. A flat array is used here to avoid
/// overhead in serializing and deserializing. The format is as follows:
///
/// uint8_t - log level (1 = error, 2 = warning,
/// 3 = info, 4 = debug)
/// uint64_t, little-endian - timestamp in nanoseconds
/// char[] - message to log
/// char, \0 - null-terminator
///
/// This pattern repeats until the end of the buffer for multiple log
/// messages. The last byte will always be a null-terminator. There are no
/// padding bytes between these fields. Treat this like a packed struct and be
/// cautious with unaligned access when reading/writing this buffer.
const flatbuffers::Vector<int8_t> *buffer() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_BUFFER);
}
flatbuffers::Vector<int8_t> *mutable_buffer() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_BUFFER);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffset(verifier, VT_BUFFER) &&
verifier.VerifyVector(buffer()) &&
verifier.EndTable();
}
LogMessageT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LogMessageT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LogMessage> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LogMessageBuilder {
typedef LogMessage Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_buffer(flatbuffers::Offset<flatbuffers::Vector<int8_t>> buffer) {
fbb_.AddOffset(LogMessage::VT_BUFFER, buffer);
}
explicit LogMessageBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LogMessageBuilder &operator=(const LogMessageBuilder &);
flatbuffers::Offset<LogMessage> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LogMessage>(end);
return o;
}
};
inline flatbuffers::Offset<LogMessage> CreateLogMessage(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> buffer = 0) {
LogMessageBuilder builder_(_fbb);
builder_.add_buffer(buffer);
return builder_.Finish();
}
inline flatbuffers::Offset<LogMessage> CreateLogMessageDirect(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<int8_t> *buffer = nullptr) {
auto buffer__ = buffer ? _fbb.CreateVector<int8_t>(*buffer) : 0;
return chre::fbs::CreateLogMessage(
_fbb,
buffer__);
}
flatbuffers::Offset<LogMessage> CreateLogMessage(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct TimeSyncMessageT : public flatbuffers::NativeTable {
typedef TimeSyncMessage TableType;
int64_t offset;
TimeSyncMessageT()
: offset(0) {
}
};
/// Represents a message sent to CHRE to indicate AP timestamp for time sync
struct TimeSyncMessage FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef TimeSyncMessageT NativeTableType;
typedef TimeSyncMessageBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_OFFSET = 4
};
/// Offset between AP and CHRE timestamp
int64_t offset() const {
return GetField<int64_t>(VT_OFFSET, 0);
}
bool mutate_offset(int64_t _offset) {
return SetField<int64_t>(VT_OFFSET, _offset, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<int64_t>(verifier, VT_OFFSET) &&
verifier.EndTable();
}
TimeSyncMessageT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(TimeSyncMessageT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<TimeSyncMessage> Pack(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct TimeSyncMessageBuilder {
typedef TimeSyncMessage Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_offset(int64_t offset) {
fbb_.AddElement<int64_t>(TimeSyncMessage::VT_OFFSET, offset, 0);
}
explicit TimeSyncMessageBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
TimeSyncMessageBuilder &operator=(const TimeSyncMessageBuilder &);
flatbuffers::Offset<TimeSyncMessage> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<TimeSyncMessage>(end);
return o;
}
};
inline flatbuffers::Offset<TimeSyncMessage> CreateTimeSyncMessage(
flatbuffers::FlatBufferBuilder &_fbb,
int64_t offset = 0) {
TimeSyncMessageBuilder builder_(_fbb);
builder_.add_offset(offset);
return builder_.Finish();
}
flatbuffers::Offset<TimeSyncMessage> CreateTimeSyncMessage(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct DebugDumpRequestT : public flatbuffers::NativeTable {
typedef DebugDumpRequest TableType;
DebugDumpRequestT() {
}
};
/// A request to gather and return debugging information. Only one debug dump
/// session can be active at a time. Upon accepting a request, zero or more
/// DebugDumpData messages are generated, followed by a DebugDumpResponse
/// indicating the completion of the operation.
struct DebugDumpRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef DebugDumpRequestT NativeTableType;
typedef DebugDumpRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
DebugDumpRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(DebugDumpRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<DebugDumpRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct DebugDumpRequestBuilder {
typedef DebugDumpRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit DebugDumpRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
DebugDumpRequestBuilder &operator=(const DebugDumpRequestBuilder &);
flatbuffers::Offset<DebugDumpRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<DebugDumpRequest>(end);
return o;
}
};
inline flatbuffers::Offset<DebugDumpRequest> CreateDebugDumpRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
DebugDumpRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<DebugDumpRequest> CreateDebugDumpRequest(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct DebugDumpDataT : public flatbuffers::NativeTable {
typedef DebugDumpData TableType;
std::vector<int8_t> debug_str;
DebugDumpDataT() {
}
};
struct DebugDumpData FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef DebugDumpDataT NativeTableType;
typedef DebugDumpDataBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_DEBUG_STR = 4
};
/// Null-terminated ASCII string containing debugging information
const flatbuffers::Vector<int8_t> *debug_str() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_DEBUG_STR);
}
flatbuffers::Vector<int8_t> *mutable_debug_str() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_DEBUG_STR);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffset(verifier, VT_DEBUG_STR) &&
verifier.VerifyVector(debug_str()) &&
verifier.EndTable();
}
DebugDumpDataT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(DebugDumpDataT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<DebugDumpData> Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpDataT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct DebugDumpDataBuilder {
typedef DebugDumpData Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_debug_str(flatbuffers::Offset<flatbuffers::Vector<int8_t>> debug_str) {
fbb_.AddOffset(DebugDumpData::VT_DEBUG_STR, debug_str);
}
explicit DebugDumpDataBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
DebugDumpDataBuilder &operator=(const DebugDumpDataBuilder &);
flatbuffers::Offset<DebugDumpData> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<DebugDumpData>(end);
return o;
}
};
inline flatbuffers::Offset<DebugDumpData> CreateDebugDumpData(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> debug_str = 0) {
DebugDumpDataBuilder builder_(_fbb);
builder_.add_debug_str(debug_str);
return builder_.Finish();
}
inline flatbuffers::Offset<DebugDumpData> CreateDebugDumpDataDirect(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<int8_t> *debug_str = nullptr) {
auto debug_str__ = debug_str ? _fbb.CreateVector<int8_t>(*debug_str) : 0;
return chre::fbs::CreateDebugDumpData(
_fbb,
debug_str__);
}
flatbuffers::Offset<DebugDumpData> CreateDebugDumpData(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpDataT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct DebugDumpResponseT : public flatbuffers::NativeTable {
typedef DebugDumpResponse TableType;
bool success;
uint32_t data_count;
DebugDumpResponseT()
: success(false),
data_count(0) {
}
};
struct DebugDumpResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef DebugDumpResponseT NativeTableType;
typedef DebugDumpResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_SUCCESS = 4,
VT_DATA_COUNT = 6
};
/// true if the request was accepted and a dump was performed, false if it was
/// rejected or failed to complete for some reason
bool success() const {
return GetField<uint8_t>(VT_SUCCESS, 0) != 0;
}
bool mutate_success(bool _success) {
return SetField<uint8_t>(VT_SUCCESS, static_cast<uint8_t>(_success), 0);
}
/// The number of DebugDumpData messages sent in this session
uint32_t data_count() const {
return GetField<uint32_t>(VT_DATA_COUNT, 0);
}
bool mutate_data_count(uint32_t _data_count) {
return SetField<uint32_t>(VT_DATA_COUNT, _data_count, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint8_t>(verifier, VT_SUCCESS) &&
VerifyField<uint32_t>(verifier, VT_DATA_COUNT) &&
verifier.EndTable();
}
DebugDumpResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(DebugDumpResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<DebugDumpResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct DebugDumpResponseBuilder {
typedef DebugDumpResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_success(bool success) {
fbb_.AddElement<uint8_t>(DebugDumpResponse::VT_SUCCESS, static_cast<uint8_t>(success), 0);
}
void add_data_count(uint32_t data_count) {
fbb_.AddElement<uint32_t>(DebugDumpResponse::VT_DATA_COUNT, data_count, 0);
}
explicit DebugDumpResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
DebugDumpResponseBuilder &operator=(const DebugDumpResponseBuilder &);
flatbuffers::Offset<DebugDumpResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<DebugDumpResponse>(end);
return o;
}
};
inline flatbuffers::Offset<DebugDumpResponse> CreateDebugDumpResponse(
flatbuffers::FlatBufferBuilder &_fbb,
bool success = false,
uint32_t data_count = 0) {
DebugDumpResponseBuilder builder_(_fbb);
builder_.add_data_count(data_count);
builder_.add_success(success);
return builder_.Finish();
}
flatbuffers::Offset<DebugDumpResponse> CreateDebugDumpResponse(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct TimeSyncRequestT : public flatbuffers::NativeTable {
typedef TimeSyncRequest TableType;
TimeSyncRequestT() {
}
};
/// A request from CHRE for host to initiate a time sync message
/// (system feature, platform-specific - not all platforms necessarily use this)
struct TimeSyncRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef TimeSyncRequestT NativeTableType;
typedef TimeSyncRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
TimeSyncRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(TimeSyncRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<TimeSyncRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct TimeSyncRequestBuilder {
typedef TimeSyncRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit TimeSyncRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
TimeSyncRequestBuilder &operator=(const TimeSyncRequestBuilder &);
flatbuffers::Offset<TimeSyncRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<TimeSyncRequest>(end);
return o;
}
};
inline flatbuffers::Offset<TimeSyncRequest> CreateTimeSyncRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
TimeSyncRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<TimeSyncRequest> CreateTimeSyncRequest(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LowPowerMicAccessRequestT : public flatbuffers::NativeTable {
typedef LowPowerMicAccessRequest TableType;
LowPowerMicAccessRequestT() {
}
};
/// Request from CHRE to enable direct access to data from the low-power
/// microphone. On some systems, coordination via the AP (e.g. with
/// SoundTrigger HAL) is needed to ensure this capability is powered up when
/// CHRE needs it. The host does not send a response.
struct LowPowerMicAccessRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LowPowerMicAccessRequestT NativeTableType;
typedef LowPowerMicAccessRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
LowPowerMicAccessRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LowPowerMicAccessRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LowPowerMicAccessRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LowPowerMicAccessRequestBuilder {
typedef LowPowerMicAccessRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit LowPowerMicAccessRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LowPowerMicAccessRequestBuilder &operator=(const LowPowerMicAccessRequestBuilder &);
flatbuffers::Offset<LowPowerMicAccessRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LowPowerMicAccessRequest>(end);
return o;
}
};
inline flatbuffers::Offset<LowPowerMicAccessRequest> CreateLowPowerMicAccessRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
LowPowerMicAccessRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<LowPowerMicAccessRequest> CreateLowPowerMicAccessRequest(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LowPowerMicAccessReleaseT : public flatbuffers::NativeTable {
typedef LowPowerMicAccessRelease TableType;
LowPowerMicAccessReleaseT() {
}
};
/// Notification from CHRE that it no longer needs direct access to low-power
/// microphone data.
struct LowPowerMicAccessRelease FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LowPowerMicAccessReleaseT NativeTableType;
typedef LowPowerMicAccessReleaseBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
LowPowerMicAccessReleaseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LowPowerMicAccessReleaseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LowPowerMicAccessRelease> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessReleaseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LowPowerMicAccessReleaseBuilder {
typedef LowPowerMicAccessRelease Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit LowPowerMicAccessReleaseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LowPowerMicAccessReleaseBuilder &operator=(const LowPowerMicAccessReleaseBuilder &);
flatbuffers::Offset<LowPowerMicAccessRelease> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LowPowerMicAccessRelease>(end);
return o;
}
};
inline flatbuffers::Offset<LowPowerMicAccessRelease> CreateLowPowerMicAccessRelease(
flatbuffers::FlatBufferBuilder &_fbb) {
LowPowerMicAccessReleaseBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<LowPowerMicAccessRelease> CreateLowPowerMicAccessRelease(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessReleaseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct SettingChangeMessageT : public flatbuffers::NativeTable {
typedef SettingChangeMessage TableType;
chre::fbs::Setting setting;
chre::fbs::SettingState state;
SettingChangeMessageT()
: setting(chre::fbs::Setting::LOCATION),
state(chre::fbs::SettingState::DISABLED) {
}
};
/// Notification from the host that a system setting has changed
struct SettingChangeMessage FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef SettingChangeMessageT NativeTableType;
typedef SettingChangeMessageBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_SETTING = 4,
VT_STATE = 6
};
/// The setting that has changed
chre::fbs::Setting setting() const {
return static_cast<chre::fbs::Setting>(GetField<int8_t>(VT_SETTING, 0));
}
bool mutate_setting(chre::fbs::Setting _setting) {
return SetField<int8_t>(VT_SETTING, static_cast<int8_t>(_setting), 0);
}
/// The new setting value
chre::fbs::SettingState state() const {
return static_cast<chre::fbs::SettingState>(GetField<int8_t>(VT_STATE, 0));
}
bool mutate_state(chre::fbs::SettingState _state) {
return SetField<int8_t>(VT_STATE, static_cast<int8_t>(_state), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<int8_t>(verifier, VT_SETTING) &&
VerifyField<int8_t>(verifier, VT_STATE) &&
verifier.EndTable();
}
SettingChangeMessageT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(SettingChangeMessageT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<SettingChangeMessage> Pack(flatbuffers::FlatBufferBuilder &_fbb, const SettingChangeMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct SettingChangeMessageBuilder {
typedef SettingChangeMessage Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_setting(chre::fbs::Setting setting) {
fbb_.AddElement<int8_t>(SettingChangeMessage::VT_SETTING, static_cast<int8_t>(setting), 0);
}
void add_state(chre::fbs::SettingState state) {
fbb_.AddElement<int8_t>(SettingChangeMessage::VT_STATE, static_cast<int8_t>(state), 0);
}
explicit SettingChangeMessageBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
SettingChangeMessageBuilder &operator=(const SettingChangeMessageBuilder &);
flatbuffers::Offset<SettingChangeMessage> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<SettingChangeMessage>(end);
return o;
}
};
inline flatbuffers::Offset<SettingChangeMessage> CreateSettingChangeMessage(
flatbuffers::FlatBufferBuilder &_fbb,
chre::fbs::Setting setting = chre::fbs::Setting::LOCATION,
chre::fbs::SettingState state = chre::fbs::SettingState::DISABLED) {
SettingChangeMessageBuilder builder_(_fbb);
builder_.add_state(state);
builder_.add_setting(setting);
return builder_.Finish();
}
flatbuffers::Offset<SettingChangeMessage> CreateSettingChangeMessage(flatbuffers::FlatBufferBuilder &_fbb, const SettingChangeMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct LogMessageV2T : public flatbuffers::NativeTable {
typedef LogMessageV2 TableType;
std::vector<int8_t> buffer;
uint32_t num_logs_dropped;
LogMessageV2T()
: num_logs_dropped(0) {
}
};
/// Represents V2 log messages from CHRE.
struct LogMessageV2 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef LogMessageV2T NativeTableType;
typedef LogMessageV2Builder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_BUFFER = 4,
VT_NUM_LOGS_DROPPED = 6
};
/// A buffer containing formatted log data. A flat array is used here to avoid
/// overhead in serializing and deserializing. The format is as follows:
///
/// uint8_t - Log metadata, encoded as follows:
/// [EI(Upper nibble) | Level(Lower nibble)]
/// * EI: Encoding indicator (eg: via tokenization)
/// (0 = No encoding, 1 = Tokenized log)
/// * LogBuffer log level (1 = error, 2 = warn,
/// 3 = info, 4 = debug,
/// 5 = verbose)
/// uint32_t, little-endian - timestamp in milliseconds
/// char[] - Log data buffer
///
/// The log data buffer format is as follows:
/// * Unencoded (string) logs: The log buffer can be interpreted as a NULL
/// terminated string (eg: pass to string manipulation functions, get its
/// size via strlen(), etc.).
///
/// * Encoded logs: The first byte of the log buffer indicates the size of
/// the actual encoded data to follow. For example, if a tokenized log of
/// size 24 bytes were to be represented, a buffer of size 25 bytes would
/// be needed to encode this as: [Size(1B) | Data(24B)]. A decoder would
/// then have to decode this starting from a 1 byte offset from the
/// received buffer.
///
/// This pattern repeats until the end of the buffer for multiple log
/// messages. The last byte will always be a null-terminator. There are no
/// padding bytes between these fields. Treat this like a packed struct and be
/// cautious with unaligned access when reading/writing this buffer.
/// Note that the log message might not be null-terminated if an encoding is
/// used.
const flatbuffers::Vector<int8_t> *buffer() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_BUFFER);
}
flatbuffers::Vector<int8_t> *mutable_buffer() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_BUFFER);
}
/// The number of logs dropped since CHRE started
uint32_t num_logs_dropped() const {
return GetField<uint32_t>(VT_NUM_LOGS_DROPPED, 0);
}
bool mutate_num_logs_dropped(uint32_t _num_logs_dropped) {
return SetField<uint32_t>(VT_NUM_LOGS_DROPPED, _num_logs_dropped, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffset(verifier, VT_BUFFER) &&
verifier.VerifyVector(buffer()) &&
VerifyField<uint32_t>(verifier, VT_NUM_LOGS_DROPPED) &&
verifier.EndTable();
}
LogMessageV2T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(LogMessageV2T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<LogMessageV2> Pack(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageV2T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct LogMessageV2Builder {
typedef LogMessageV2 Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_buffer(flatbuffers::Offset<flatbuffers::Vector<int8_t>> buffer) {
fbb_.AddOffset(LogMessageV2::VT_BUFFER, buffer);
}
void add_num_logs_dropped(uint32_t num_logs_dropped) {
fbb_.AddElement<uint32_t>(LogMessageV2::VT_NUM_LOGS_DROPPED, num_logs_dropped, 0);
}
explicit LogMessageV2Builder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
LogMessageV2Builder &operator=(const LogMessageV2Builder &);
flatbuffers::Offset<LogMessageV2> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<LogMessageV2>(end);
return o;
}
};
inline flatbuffers::Offset<LogMessageV2> CreateLogMessageV2(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> buffer = 0,
uint32_t num_logs_dropped = 0) {
LogMessageV2Builder builder_(_fbb);
builder_.add_num_logs_dropped(num_logs_dropped);
builder_.add_buffer(buffer);
return builder_.Finish();
}
inline flatbuffers::Offset<LogMessageV2> CreateLogMessageV2Direct(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<int8_t> *buffer = nullptr,
uint32_t num_logs_dropped = 0) {
auto buffer__ = buffer ? _fbb.CreateVector<int8_t>(*buffer) : 0;
return chre::fbs::CreateLogMessageV2(
_fbb,
buffer__,
num_logs_dropped);
}
flatbuffers::Offset<LogMessageV2> CreateLogMessageV2(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageV2T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct SelfTestRequestT : public flatbuffers::NativeTable {
typedef SelfTestRequest TableType;
SelfTestRequestT() {
}
};
struct SelfTestRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef SelfTestRequestT NativeTableType;
typedef SelfTestRequestBuilder Builder;
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
verifier.EndTable();
}
SelfTestRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(SelfTestRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<SelfTestRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct SelfTestRequestBuilder {
typedef SelfTestRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
explicit SelfTestRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
SelfTestRequestBuilder &operator=(const SelfTestRequestBuilder &);
flatbuffers::Offset<SelfTestRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<SelfTestRequest>(end);
return o;
}
};
inline flatbuffers::Offset<SelfTestRequest> CreateSelfTestRequest(
flatbuffers::FlatBufferBuilder &_fbb) {
SelfTestRequestBuilder builder_(_fbb);
return builder_.Finish();
}
flatbuffers::Offset<SelfTestRequest> CreateSelfTestRequest(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct SelfTestResponseT : public flatbuffers::NativeTable {
typedef SelfTestResponse TableType;
bool success;
SelfTestResponseT()
: success(false) {
}
};
struct SelfTestResponse FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef SelfTestResponseT NativeTableType;
typedef SelfTestResponseBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_SUCCESS = 4
};
bool success() const {
return GetField<uint8_t>(VT_SUCCESS, 0) != 0;
}
bool mutate_success(bool _success) {
return SetField<uint8_t>(VT_SUCCESS, static_cast<uint8_t>(_success), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint8_t>(verifier, VT_SUCCESS) &&
verifier.EndTable();
}
SelfTestResponseT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(SelfTestResponseT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<SelfTestResponse> Pack(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct SelfTestResponseBuilder {
typedef SelfTestResponse Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_success(bool success) {
fbb_.AddElement<uint8_t>(SelfTestResponse::VT_SUCCESS, static_cast<uint8_t>(success), 0);
}
explicit SelfTestResponseBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
SelfTestResponseBuilder &operator=(const SelfTestResponseBuilder &);
flatbuffers::Offset<SelfTestResponse> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<SelfTestResponse>(end);
return o;
}
};
inline flatbuffers::Offset<SelfTestResponse> CreateSelfTestResponse(
flatbuffers::FlatBufferBuilder &_fbb,
bool success = false) {
SelfTestResponseBuilder builder_(_fbb);
builder_.add_success(success);
return builder_.Finish();
}
flatbuffers::Offset<SelfTestResponse> CreateSelfTestResponse(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct HostEndpointConnectedT : public flatbuffers::NativeTable {
typedef HostEndpointConnected TableType;
uint16_t host_endpoint;
uint8_t type;
std::vector<int8_t> package_name;
std::vector<int8_t> attribution_tag;
HostEndpointConnectedT()
: host_endpoint(0),
type(0) {
}
};
struct HostEndpointConnected FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef HostEndpointConnectedT NativeTableType;
typedef HostEndpointConnectedBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_HOST_ENDPOINT = 4,
VT_TYPE = 6,
VT_PACKAGE_NAME = 8,
VT_ATTRIBUTION_TAG = 10
};
/// The host-side endpoint that has connected to the framework.
uint16_t host_endpoint() const {
return GetField<uint16_t>(VT_HOST_ENDPOINT, 0);
}
bool mutate_host_endpoint(uint16_t _host_endpoint) {
return SetField<uint16_t>(VT_HOST_ENDPOINT, _host_endpoint, 0);
}
/// The type of host endpoint, which should be any of the CHRE_HOST_ENDPOINT_TYPE_*
/// values defined in the chre_api/chre/event.h.
uint8_t type() const {
return GetField<uint8_t>(VT_TYPE, 0);
}
bool mutate_type(uint8_t _type) {
return SetField<uint8_t>(VT_TYPE, _type, 0);
}
/// The (optional) package name associated with the host endpoint.
const flatbuffers::Vector<int8_t> *package_name() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_PACKAGE_NAME);
}
flatbuffers::Vector<int8_t> *mutable_package_name() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_PACKAGE_NAME);
}
/// The (optional) attribution tag associated with this host.
const flatbuffers::Vector<int8_t> *attribution_tag() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_ATTRIBUTION_TAG);
}
flatbuffers::Vector<int8_t> *mutable_attribution_tag() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_ATTRIBUTION_TAG);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint16_t>(verifier, VT_HOST_ENDPOINT) &&
VerifyField<uint8_t>(verifier, VT_TYPE) &&
VerifyOffset(verifier, VT_PACKAGE_NAME) &&
verifier.VerifyVector(package_name()) &&
VerifyOffset(verifier, VT_ATTRIBUTION_TAG) &&
verifier.VerifyVector(attribution_tag()) &&
verifier.EndTable();
}
HostEndpointConnectedT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(HostEndpointConnectedT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<HostEndpointConnected> Pack(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointConnectedT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct HostEndpointConnectedBuilder {
typedef HostEndpointConnected Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_host_endpoint(uint16_t host_endpoint) {
fbb_.AddElement<uint16_t>(HostEndpointConnected::VT_HOST_ENDPOINT, host_endpoint, 0);
}
void add_type(uint8_t type) {
fbb_.AddElement<uint8_t>(HostEndpointConnected::VT_TYPE, type, 0);
}
void add_package_name(flatbuffers::Offset<flatbuffers::Vector<int8_t>> package_name) {
fbb_.AddOffset(HostEndpointConnected::VT_PACKAGE_NAME, package_name);
}
void add_attribution_tag(flatbuffers::Offset<flatbuffers::Vector<int8_t>> attribution_tag) {
fbb_.AddOffset(HostEndpointConnected::VT_ATTRIBUTION_TAG, attribution_tag);
}
explicit HostEndpointConnectedBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
HostEndpointConnectedBuilder &operator=(const HostEndpointConnectedBuilder &);
flatbuffers::Offset<HostEndpointConnected> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<HostEndpointConnected>(end);
return o;
}
};
inline flatbuffers::Offset<HostEndpointConnected> CreateHostEndpointConnected(
flatbuffers::FlatBufferBuilder &_fbb,
uint16_t host_endpoint = 0,
uint8_t type = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> package_name = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> attribution_tag = 0) {
HostEndpointConnectedBuilder builder_(_fbb);
builder_.add_attribution_tag(attribution_tag);
builder_.add_package_name(package_name);
builder_.add_host_endpoint(host_endpoint);
builder_.add_type(type);
return builder_.Finish();
}
inline flatbuffers::Offset<HostEndpointConnected> CreateHostEndpointConnectedDirect(
flatbuffers::FlatBufferBuilder &_fbb,
uint16_t host_endpoint = 0,
uint8_t type = 0,
const std::vector<int8_t> *package_name = nullptr,
const std::vector<int8_t> *attribution_tag = nullptr) {
auto package_name__ = package_name ? _fbb.CreateVector<int8_t>(*package_name) : 0;
auto attribution_tag__ = attribution_tag ? _fbb.CreateVector<int8_t>(*attribution_tag) : 0;
return chre::fbs::CreateHostEndpointConnected(
_fbb,
host_endpoint,
type,
package_name__,
attribution_tag__);
}
flatbuffers::Offset<HostEndpointConnected> CreateHostEndpointConnected(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointConnectedT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct HostEndpointDisconnectedT : public flatbuffers::NativeTable {
typedef HostEndpointDisconnected TableType;
uint16_t host_endpoint;
HostEndpointDisconnectedT()
: host_endpoint(0) {
}
};
struct HostEndpointDisconnected FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef HostEndpointDisconnectedT NativeTableType;
typedef HostEndpointDisconnectedBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_HOST_ENDPOINT = 4
};
/// The host-side endpoint that has disconnected from the framework.
uint16_t host_endpoint() const {
return GetField<uint16_t>(VT_HOST_ENDPOINT, 0);
}
bool mutate_host_endpoint(uint16_t _host_endpoint) {
return SetField<uint16_t>(VT_HOST_ENDPOINT, _host_endpoint, 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint16_t>(verifier, VT_HOST_ENDPOINT) &&
verifier.EndTable();
}
HostEndpointDisconnectedT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(HostEndpointDisconnectedT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<HostEndpointDisconnected> Pack(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointDisconnectedT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct HostEndpointDisconnectedBuilder {
typedef HostEndpointDisconnected Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_host_endpoint(uint16_t host_endpoint) {
fbb_.AddElement<uint16_t>(HostEndpointDisconnected::VT_HOST_ENDPOINT, host_endpoint, 0);
}
explicit HostEndpointDisconnectedBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
HostEndpointDisconnectedBuilder &operator=(const HostEndpointDisconnectedBuilder &);
flatbuffers::Offset<HostEndpointDisconnected> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<HostEndpointDisconnected>(end);
return o;
}
};
inline flatbuffers::Offset<HostEndpointDisconnected> CreateHostEndpointDisconnected(
flatbuffers::FlatBufferBuilder &_fbb,
uint16_t host_endpoint = 0) {
HostEndpointDisconnectedBuilder builder_(_fbb);
builder_.add_host_endpoint(host_endpoint);
return builder_.Finish();
}
flatbuffers::Offset<HostEndpointDisconnected> CreateHostEndpointDisconnected(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointDisconnectedT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct MetricLogT : public flatbuffers::NativeTable {
typedef MetricLog TableType;
uint32_t id;
std::vector<int8_t> encoded_metric;
MetricLogT()
: id(0) {
}
};
struct MetricLog FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef MetricLogT NativeTableType;
typedef MetricLogBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_ID = 4,
VT_ENCODED_METRIC = 6
};
uint32_t id() const {
return GetField<uint32_t>(VT_ID, 0);
}
bool mutate_id(uint32_t _id) {
return SetField<uint32_t>(VT_ID, _id, 0);
}
const flatbuffers::Vector<int8_t> *encoded_metric() const {
return GetPointer<const flatbuffers::Vector<int8_t> *>(VT_ENCODED_METRIC);
}
flatbuffers::Vector<int8_t> *mutable_encoded_metric() {
return GetPointer<flatbuffers::Vector<int8_t> *>(VT_ENCODED_METRIC);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint32_t>(verifier, VT_ID) &&
VerifyOffset(verifier, VT_ENCODED_METRIC) &&
verifier.VerifyVector(encoded_metric()) &&
verifier.EndTable();
}
MetricLogT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(MetricLogT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<MetricLog> Pack(flatbuffers::FlatBufferBuilder &_fbb, const MetricLogT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct MetricLogBuilder {
typedef MetricLog Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_id(uint32_t id) {
fbb_.AddElement<uint32_t>(MetricLog::VT_ID, id, 0);
}
void add_encoded_metric(flatbuffers::Offset<flatbuffers::Vector<int8_t>> encoded_metric) {
fbb_.AddOffset(MetricLog::VT_ENCODED_METRIC, encoded_metric);
}
explicit MetricLogBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
MetricLogBuilder &operator=(const MetricLogBuilder &);
flatbuffers::Offset<MetricLog> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<MetricLog>(end);
return o;
}
};
inline flatbuffers::Offset<MetricLog> CreateMetricLog(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t id = 0,
flatbuffers::Offset<flatbuffers::Vector<int8_t>> encoded_metric = 0) {
MetricLogBuilder builder_(_fbb);
builder_.add_encoded_metric(encoded_metric);
builder_.add_id(id);
return builder_.Finish();
}
inline flatbuffers::Offset<MetricLog> CreateMetricLogDirect(
flatbuffers::FlatBufferBuilder &_fbb,
uint32_t id = 0,
const std::vector<int8_t> *encoded_metric = nullptr) {
auto encoded_metric__ = encoded_metric ? _fbb.CreateVector<int8_t>(*encoded_metric) : 0;
return chre::fbs::CreateMetricLog(
_fbb,
id,
encoded_metric__);
}
flatbuffers::Offset<MetricLog> CreateMetricLog(flatbuffers::FlatBufferBuilder &_fbb, const MetricLogT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct BatchedMetricLogT : public flatbuffers::NativeTable {
typedef BatchedMetricLog TableType;
std::vector<std::unique_ptr<chre::fbs::MetricLogT>> metrics;
BatchedMetricLogT() {
}
};
struct BatchedMetricLog FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef BatchedMetricLogT NativeTableType;
typedef BatchedMetricLogBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_METRICS = 4
};
const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>> *metrics() const {
return GetPointer<const flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>> *>(VT_METRICS);
}
flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>> *mutable_metrics() {
return GetPointer<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>> *>(VT_METRICS);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyOffset(verifier, VT_METRICS) &&
verifier.VerifyVector(metrics()) &&
verifier.VerifyVectorOfTables(metrics()) &&
verifier.EndTable();
}
BatchedMetricLogT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(BatchedMetricLogT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<BatchedMetricLog> Pack(flatbuffers::FlatBufferBuilder &_fbb, const BatchedMetricLogT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct BatchedMetricLogBuilder {
typedef BatchedMetricLog Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_metrics(flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>>> metrics) {
fbb_.AddOffset(BatchedMetricLog::VT_METRICS, metrics);
}
explicit BatchedMetricLogBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
BatchedMetricLogBuilder &operator=(const BatchedMetricLogBuilder &);
flatbuffers::Offset<BatchedMetricLog> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<BatchedMetricLog>(end);
return o;
}
};
inline flatbuffers::Offset<BatchedMetricLog> CreateBatchedMetricLog(
flatbuffers::FlatBufferBuilder &_fbb,
flatbuffers::Offset<flatbuffers::Vector<flatbuffers::Offset<chre::fbs::MetricLog>>> metrics = 0) {
BatchedMetricLogBuilder builder_(_fbb);
builder_.add_metrics(metrics);
return builder_.Finish();
}
inline flatbuffers::Offset<BatchedMetricLog> CreateBatchedMetricLogDirect(
flatbuffers::FlatBufferBuilder &_fbb,
const std::vector<flatbuffers::Offset<chre::fbs::MetricLog>> *metrics = nullptr) {
auto metrics__ = metrics ? _fbb.CreateVector<flatbuffers::Offset<chre::fbs::MetricLog>>(*metrics) : 0;
return chre::fbs::CreateBatchedMetricLog(
_fbb,
metrics__);
}
flatbuffers::Offset<BatchedMetricLog> CreateBatchedMetricLog(flatbuffers::FlatBufferBuilder &_fbb, const BatchedMetricLogT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanConfigurationRequestT : public flatbuffers::NativeTable {
typedef NanConfigurationRequest TableType;
bool enable;
NanConfigurationRequestT()
: enable(false) {
}
};
struct NanConfigurationRequest FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanConfigurationRequestT NativeTableType;
typedef NanConfigurationRequestBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_ENABLE = 4
};
bool enable() const {
return GetField<uint8_t>(VT_ENABLE, 0) != 0;
}
bool mutate_enable(bool _enable) {
return SetField<uint8_t>(VT_ENABLE, static_cast<uint8_t>(_enable), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint8_t>(verifier, VT_ENABLE) &&
verifier.EndTable();
}
NanConfigurationRequestT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanConfigurationRequestT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanConfigurationRequest> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanConfigurationRequestBuilder {
typedef NanConfigurationRequest Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_enable(bool enable) {
fbb_.AddElement<uint8_t>(NanConfigurationRequest::VT_ENABLE, static_cast<uint8_t>(enable), 0);
}
explicit NanConfigurationRequestBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanConfigurationRequestBuilder &operator=(const NanConfigurationRequestBuilder &);
flatbuffers::Offset<NanConfigurationRequest> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanConfigurationRequest>(end);
return o;
}
};
inline flatbuffers::Offset<NanConfigurationRequest> CreateNanConfigurationRequest(
flatbuffers::FlatBufferBuilder &_fbb,
bool enable = false) {
NanConfigurationRequestBuilder builder_(_fbb);
builder_.add_enable(enable);
return builder_.Finish();
}
flatbuffers::Offset<NanConfigurationRequest> CreateNanConfigurationRequest(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct NanConfigurationUpdateT : public flatbuffers::NativeTable {
typedef NanConfigurationUpdate TableType;
bool enabled;
NanConfigurationUpdateT()
: enabled(false) {
}
};
struct NanConfigurationUpdate FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef NanConfigurationUpdateT NativeTableType;
typedef NanConfigurationUpdateBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_ENABLED = 4
};
bool enabled() const {
return GetField<uint8_t>(VT_ENABLED, 0) != 0;
}
bool mutate_enabled(bool _enabled) {
return SetField<uint8_t>(VT_ENABLED, static_cast<uint8_t>(_enabled), 0);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint8_t>(verifier, VT_ENABLED) &&
verifier.EndTable();
}
NanConfigurationUpdateT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(NanConfigurationUpdateT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<NanConfigurationUpdate> Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationUpdateT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
struct NanConfigurationUpdateBuilder {
typedef NanConfigurationUpdate Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_enabled(bool enabled) {
fbb_.AddElement<uint8_t>(NanConfigurationUpdate::VT_ENABLED, static_cast<uint8_t>(enabled), 0);
}
explicit NanConfigurationUpdateBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
NanConfigurationUpdateBuilder &operator=(const NanConfigurationUpdateBuilder &);
flatbuffers::Offset<NanConfigurationUpdate> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<NanConfigurationUpdate>(end);
return o;
}
};
inline flatbuffers::Offset<NanConfigurationUpdate> CreateNanConfigurationUpdate(
flatbuffers::FlatBufferBuilder &_fbb,
bool enabled = false) {
NanConfigurationUpdateBuilder builder_(_fbb);
builder_.add_enabled(enabled);
return builder_.Finish();
}
flatbuffers::Offset<NanConfigurationUpdate> CreateNanConfigurationUpdate(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationUpdateT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
struct MessageContainerT : public flatbuffers::NativeTable {
typedef MessageContainer TableType;
chre::fbs::ChreMessageUnion message;
std::unique_ptr<chre::fbs::HostAddress> host_addr;
MessageContainerT() {
}
};
/// The top-level container that encapsulates all possible messages. Note that
/// per FlatBuffers requirements, we can't use a union as the top-level
/// structure (root type), so we must wrap it in a table.
struct MessageContainer FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table {
typedef MessageContainerT NativeTableType;
typedef MessageContainerBuilder Builder;
enum FlatBuffersVTableOffset FLATBUFFERS_VTABLE_UNDERLYING_TYPE {
VT_MESSAGE_TYPE = 4,
VT_MESSAGE = 6,
VT_HOST_ADDR = 8
};
chre::fbs::ChreMessage message_type() const {
return static_cast<chre::fbs::ChreMessage>(GetField<uint8_t>(VT_MESSAGE_TYPE, 0));
}
const void *message() const {
return GetPointer<const void *>(VT_MESSAGE);
}
template<typename T> const T *message_as() const;
const chre::fbs::NanoappMessage *message_as_NanoappMessage() const {
return message_type() == chre::fbs::ChreMessage::NanoappMessage ? static_cast<const chre::fbs::NanoappMessage *>(message()) : nullptr;
}
const chre::fbs::HubInfoRequest *message_as_HubInfoRequest() const {
return message_type() == chre::fbs::ChreMessage::HubInfoRequest ? static_cast<const chre::fbs::HubInfoRequest *>(message()) : nullptr;
}
const chre::fbs::HubInfoResponse *message_as_HubInfoResponse() const {
return message_type() == chre::fbs::ChreMessage::HubInfoResponse ? static_cast<const chre::fbs::HubInfoResponse *>(message()) : nullptr;
}
const chre::fbs::NanoappListRequest *message_as_NanoappListRequest() const {
return message_type() == chre::fbs::ChreMessage::NanoappListRequest ? static_cast<const chre::fbs::NanoappListRequest *>(message()) : nullptr;
}
const chre::fbs::NanoappListResponse *message_as_NanoappListResponse() const {
return message_type() == chre::fbs::ChreMessage::NanoappListResponse ? static_cast<const chre::fbs::NanoappListResponse *>(message()) : nullptr;
}
const chre::fbs::LoadNanoappRequest *message_as_LoadNanoappRequest() const {
return message_type() == chre::fbs::ChreMessage::LoadNanoappRequest ? static_cast<const chre::fbs::LoadNanoappRequest *>(message()) : nullptr;
}
const chre::fbs::LoadNanoappResponse *message_as_LoadNanoappResponse() const {
return message_type() == chre::fbs::ChreMessage::LoadNanoappResponse ? static_cast<const chre::fbs::LoadNanoappResponse *>(message()) : nullptr;
}
const chre::fbs::UnloadNanoappRequest *message_as_UnloadNanoappRequest() const {
return message_type() == chre::fbs::ChreMessage::UnloadNanoappRequest ? static_cast<const chre::fbs::UnloadNanoappRequest *>(message()) : nullptr;
}
const chre::fbs::UnloadNanoappResponse *message_as_UnloadNanoappResponse() const {
return message_type() == chre::fbs::ChreMessage::UnloadNanoappResponse ? static_cast<const chre::fbs::UnloadNanoappResponse *>(message()) : nullptr;
}
const chre::fbs::LogMessage *message_as_LogMessage() const {
return message_type() == chre::fbs::ChreMessage::LogMessage ? static_cast<const chre::fbs::LogMessage *>(message()) : nullptr;
}
const chre::fbs::TimeSyncMessage *message_as_TimeSyncMessage() const {
return message_type() == chre::fbs::ChreMessage::TimeSyncMessage ? static_cast<const chre::fbs::TimeSyncMessage *>(message()) : nullptr;
}
const chre::fbs::DebugDumpRequest *message_as_DebugDumpRequest() const {
return message_type() == chre::fbs::ChreMessage::DebugDumpRequest ? static_cast<const chre::fbs::DebugDumpRequest *>(message()) : nullptr;
}
const chre::fbs::DebugDumpData *message_as_DebugDumpData() const {
return message_type() == chre::fbs::ChreMessage::DebugDumpData ? static_cast<const chre::fbs::DebugDumpData *>(message()) : nullptr;
}
const chre::fbs::DebugDumpResponse *message_as_DebugDumpResponse() const {
return message_type() == chre::fbs::ChreMessage::DebugDumpResponse ? static_cast<const chre::fbs::DebugDumpResponse *>(message()) : nullptr;
}
const chre::fbs::TimeSyncRequest *message_as_TimeSyncRequest() const {
return message_type() == chre::fbs::ChreMessage::TimeSyncRequest ? static_cast<const chre::fbs::TimeSyncRequest *>(message()) : nullptr;
}
const chre::fbs::LowPowerMicAccessRequest *message_as_LowPowerMicAccessRequest() const {
return message_type() == chre::fbs::ChreMessage::LowPowerMicAccessRequest ? static_cast<const chre::fbs::LowPowerMicAccessRequest *>(message()) : nullptr;
}
const chre::fbs::LowPowerMicAccessRelease *message_as_LowPowerMicAccessRelease() const {
return message_type() == chre::fbs::ChreMessage::LowPowerMicAccessRelease ? static_cast<const chre::fbs::LowPowerMicAccessRelease *>(message()) : nullptr;
}
const chre::fbs::SettingChangeMessage *message_as_SettingChangeMessage() const {
return message_type() == chre::fbs::ChreMessage::SettingChangeMessage ? static_cast<const chre::fbs::SettingChangeMessage *>(message()) : nullptr;
}
const chre::fbs::LogMessageV2 *message_as_LogMessageV2() const {
return message_type() == chre::fbs::ChreMessage::LogMessageV2 ? static_cast<const chre::fbs::LogMessageV2 *>(message()) : nullptr;
}
const chre::fbs::SelfTestRequest *message_as_SelfTestRequest() const {
return message_type() == chre::fbs::ChreMessage::SelfTestRequest ? static_cast<const chre::fbs::SelfTestRequest *>(message()) : nullptr;
}
const chre::fbs::SelfTestResponse *message_as_SelfTestResponse() const {
return message_type() == chre::fbs::ChreMessage::SelfTestResponse ? static_cast<const chre::fbs::SelfTestResponse *>(message()) : nullptr;
}
const chre::fbs::HostEndpointConnected *message_as_HostEndpointConnected() const {
return message_type() == chre::fbs::ChreMessage::HostEndpointConnected ? static_cast<const chre::fbs::HostEndpointConnected *>(message()) : nullptr;
}
const chre::fbs::HostEndpointDisconnected *message_as_HostEndpointDisconnected() const {
return message_type() == chre::fbs::ChreMessage::HostEndpointDisconnected ? static_cast<const chre::fbs::HostEndpointDisconnected *>(message()) : nullptr;
}
const chre::fbs::MetricLog *message_as_MetricLog() const {
return message_type() == chre::fbs::ChreMessage::MetricLog ? static_cast<const chre::fbs::MetricLog *>(message()) : nullptr;
}
const chre::fbs::BatchedMetricLog *message_as_BatchedMetricLog() const {
return message_type() == chre::fbs::ChreMessage::BatchedMetricLog ? static_cast<const chre::fbs::BatchedMetricLog *>(message()) : nullptr;
}
const chre::fbs::NanConfigurationRequest *message_as_NanConfigurationRequest() const {
return message_type() == chre::fbs::ChreMessage::NanConfigurationRequest ? static_cast<const chre::fbs::NanConfigurationRequest *>(message()) : nullptr;
}
const chre::fbs::NanConfigurationUpdate *message_as_NanConfigurationUpdate() const {
return message_type() == chre::fbs::ChreMessage::NanConfigurationUpdate ? static_cast<const chre::fbs::NanConfigurationUpdate *>(message()) : nullptr;
}
void *mutable_message() {
return GetPointer<void *>(VT_MESSAGE);
}
/// The originating or destination client ID on the host side, used to direct
/// responses only to the client that sent the request. Although initially
/// populated by the requesting client, this is enforced to be the correct
/// value by the entity guarding access to CHRE.
/// This is wrapped in a struct to ensure that it is always included when
/// encoding the message, so it can be mutated by the host daemon.
const chre::fbs::HostAddress *host_addr() const {
return GetStruct<const chre::fbs::HostAddress *>(VT_HOST_ADDR);
}
chre::fbs::HostAddress *mutable_host_addr() {
return GetStruct<chre::fbs::HostAddress *>(VT_HOST_ADDR);
}
bool Verify(flatbuffers::Verifier &verifier) const {
return VerifyTableStart(verifier) &&
VerifyField<uint8_t>(verifier, VT_MESSAGE_TYPE) &&
VerifyOffsetRequired(verifier, VT_MESSAGE) &&
VerifyChreMessage(verifier, message(), message_type()) &&
VerifyFieldRequired<chre::fbs::HostAddress>(verifier, VT_HOST_ADDR) &&
verifier.EndTable();
}
MessageContainerT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const;
void UnPackTo(MessageContainerT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const;
static flatbuffers::Offset<MessageContainer> Pack(flatbuffers::FlatBufferBuilder &_fbb, const MessageContainerT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
};
template<> inline const chre::fbs::NanoappMessage *MessageContainer::message_as<chre::fbs::NanoappMessage>() const {
return message_as_NanoappMessage();
}
template<> inline const chre::fbs::HubInfoRequest *MessageContainer::message_as<chre::fbs::HubInfoRequest>() const {
return message_as_HubInfoRequest();
}
template<> inline const chre::fbs::HubInfoResponse *MessageContainer::message_as<chre::fbs::HubInfoResponse>() const {
return message_as_HubInfoResponse();
}
template<> inline const chre::fbs::NanoappListRequest *MessageContainer::message_as<chre::fbs::NanoappListRequest>() const {
return message_as_NanoappListRequest();
}
template<> inline const chre::fbs::NanoappListResponse *MessageContainer::message_as<chre::fbs::NanoappListResponse>() const {
return message_as_NanoappListResponse();
}
template<> inline const chre::fbs::LoadNanoappRequest *MessageContainer::message_as<chre::fbs::LoadNanoappRequest>() const {
return message_as_LoadNanoappRequest();
}
template<> inline const chre::fbs::LoadNanoappResponse *MessageContainer::message_as<chre::fbs::LoadNanoappResponse>() const {
return message_as_LoadNanoappResponse();
}
template<> inline const chre::fbs::UnloadNanoappRequest *MessageContainer::message_as<chre::fbs::UnloadNanoappRequest>() const {
return message_as_UnloadNanoappRequest();
}
template<> inline const chre::fbs::UnloadNanoappResponse *MessageContainer::message_as<chre::fbs::UnloadNanoappResponse>() const {
return message_as_UnloadNanoappResponse();
}
template<> inline const chre::fbs::LogMessage *MessageContainer::message_as<chre::fbs::LogMessage>() const {
return message_as_LogMessage();
}
template<> inline const chre::fbs::TimeSyncMessage *MessageContainer::message_as<chre::fbs::TimeSyncMessage>() const {
return message_as_TimeSyncMessage();
}
template<> inline const chre::fbs::DebugDumpRequest *MessageContainer::message_as<chre::fbs::DebugDumpRequest>() const {
return message_as_DebugDumpRequest();
}
template<> inline const chre::fbs::DebugDumpData *MessageContainer::message_as<chre::fbs::DebugDumpData>() const {
return message_as_DebugDumpData();
}
template<> inline const chre::fbs::DebugDumpResponse *MessageContainer::message_as<chre::fbs::DebugDumpResponse>() const {
return message_as_DebugDumpResponse();
}
template<> inline const chre::fbs::TimeSyncRequest *MessageContainer::message_as<chre::fbs::TimeSyncRequest>() const {
return message_as_TimeSyncRequest();
}
template<> inline const chre::fbs::LowPowerMicAccessRequest *MessageContainer::message_as<chre::fbs::LowPowerMicAccessRequest>() const {
return message_as_LowPowerMicAccessRequest();
}
template<> inline const chre::fbs::LowPowerMicAccessRelease *MessageContainer::message_as<chre::fbs::LowPowerMicAccessRelease>() const {
return message_as_LowPowerMicAccessRelease();
}
template<> inline const chre::fbs::SettingChangeMessage *MessageContainer::message_as<chre::fbs::SettingChangeMessage>() const {
return message_as_SettingChangeMessage();
}
template<> inline const chre::fbs::LogMessageV2 *MessageContainer::message_as<chre::fbs::LogMessageV2>() const {
return message_as_LogMessageV2();
}
template<> inline const chre::fbs::SelfTestRequest *MessageContainer::message_as<chre::fbs::SelfTestRequest>() const {
return message_as_SelfTestRequest();
}
template<> inline const chre::fbs::SelfTestResponse *MessageContainer::message_as<chre::fbs::SelfTestResponse>() const {
return message_as_SelfTestResponse();
}
template<> inline const chre::fbs::HostEndpointConnected *MessageContainer::message_as<chre::fbs::HostEndpointConnected>() const {
return message_as_HostEndpointConnected();
}
template<> inline const chre::fbs::HostEndpointDisconnected *MessageContainer::message_as<chre::fbs::HostEndpointDisconnected>() const {
return message_as_HostEndpointDisconnected();
}
template<> inline const chre::fbs::MetricLog *MessageContainer::message_as<chre::fbs::MetricLog>() const {
return message_as_MetricLog();
}
template<> inline const chre::fbs::BatchedMetricLog *MessageContainer::message_as<chre::fbs::BatchedMetricLog>() const {
return message_as_BatchedMetricLog();
}
template<> inline const chre::fbs::NanConfigurationRequest *MessageContainer::message_as<chre::fbs::NanConfigurationRequest>() const {
return message_as_NanConfigurationRequest();
}
template<> inline const chre::fbs::NanConfigurationUpdate *MessageContainer::message_as<chre::fbs::NanConfigurationUpdate>() const {
return message_as_NanConfigurationUpdate();
}
struct MessageContainerBuilder {
typedef MessageContainer Table;
flatbuffers::FlatBufferBuilder &fbb_;
flatbuffers::uoffset_t start_;
void add_message_type(chre::fbs::ChreMessage message_type) {
fbb_.AddElement<uint8_t>(MessageContainer::VT_MESSAGE_TYPE, static_cast<uint8_t>(message_type), 0);
}
void add_message(flatbuffers::Offset<void> message) {
fbb_.AddOffset(MessageContainer::VT_MESSAGE, message);
}
void add_host_addr(const chre::fbs::HostAddress *host_addr) {
fbb_.AddStruct(MessageContainer::VT_HOST_ADDR, host_addr);
}
explicit MessageContainerBuilder(flatbuffers::FlatBufferBuilder &_fbb)
: fbb_(_fbb) {
start_ = fbb_.StartTable();
}
MessageContainerBuilder &operator=(const MessageContainerBuilder &);
flatbuffers::Offset<MessageContainer> Finish() {
const auto end = fbb_.EndTable(start_);
auto o = flatbuffers::Offset<MessageContainer>(end);
fbb_.Required(o, MessageContainer::VT_MESSAGE);
fbb_.Required(o, MessageContainer::VT_HOST_ADDR);
return o;
}
};
inline flatbuffers::Offset<MessageContainer> CreateMessageContainer(
flatbuffers::FlatBufferBuilder &_fbb,
chre::fbs::ChreMessage message_type = chre::fbs::ChreMessage::NONE,
flatbuffers::Offset<void> message = 0,
const chre::fbs::HostAddress *host_addr = 0) {
MessageContainerBuilder builder_(_fbb);
builder_.add_host_addr(host_addr);
builder_.add_message(message);
builder_.add_message_type(message_type);
return builder_.Finish();
}
flatbuffers::Offset<MessageContainer> CreateMessageContainer(flatbuffers::FlatBufferBuilder &_fbb, const MessageContainerT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr);
inline NanoappMessageT *NanoappMessage::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanoappMessageT> _o = std::unique_ptr<chre::fbs::NanoappMessageT>(new NanoappMessageT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanoappMessage::UnPackTo(NanoappMessageT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = app_id(); _o->app_id = _e; }
{ auto _e = message_type(); _o->message_type = _e; }
{ auto _e = host_endpoint(); _o->host_endpoint = _e; }
{ auto _e = message(); if (_e) { _o->message.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->message[_i] = _e->Get(_i); } } }
{ auto _e = message_permissions(); _o->message_permissions = _e; }
{ auto _e = permissions(); _o->permissions = _e; }
{ auto _e = woke_host(); _o->woke_host = _e; }
}
inline flatbuffers::Offset<NanoappMessage> NanoappMessage::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanoappMessage(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanoappMessage> CreateNanoappMessage(flatbuffers::FlatBufferBuilder &_fbb, const NanoappMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanoappMessageT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _app_id = _o->app_id;
auto _message_type = _o->message_type;
auto _host_endpoint = _o->host_endpoint;
auto _message = _fbb.CreateVector(_o->message);
auto _message_permissions = _o->message_permissions;
auto _permissions = _o->permissions;
auto _woke_host = _o->woke_host;
return chre::fbs::CreateNanoappMessage(
_fbb,
_app_id,
_message_type,
_host_endpoint,
_message,
_message_permissions,
_permissions,
_woke_host);
}
inline HubInfoRequestT *HubInfoRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::HubInfoRequestT> _o = std::unique_ptr<chre::fbs::HubInfoRequestT>(new HubInfoRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void HubInfoRequest::UnPackTo(HubInfoRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<HubInfoRequest> HubInfoRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateHubInfoRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<HubInfoRequest> CreateHubInfoRequest(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const HubInfoRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateHubInfoRequest(
_fbb);
}
inline HubInfoResponseT *HubInfoResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::HubInfoResponseT> _o = std::unique_ptr<chre::fbs::HubInfoResponseT>(new HubInfoResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void HubInfoResponse::UnPackTo(HubInfoResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = name(); if (_e) { _o->name.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->name[_i] = _e->Get(_i); } } }
{ auto _e = vendor(); if (_e) { _o->vendor.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->vendor[_i] = _e->Get(_i); } } }
{ auto _e = toolchain(); if (_e) { _o->toolchain.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->toolchain[_i] = _e->Get(_i); } } }
{ auto _e = platform_version(); _o->platform_version = _e; }
{ auto _e = toolchain_version(); _o->toolchain_version = _e; }
{ auto _e = peak_mips(); _o->peak_mips = _e; }
{ auto _e = stopped_power(); _o->stopped_power = _e; }
{ auto _e = sleep_power(); _o->sleep_power = _e; }
{ auto _e = peak_power(); _o->peak_power = _e; }
{ auto _e = max_msg_len(); _o->max_msg_len = _e; }
{ auto _e = platform_id(); _o->platform_id = _e; }
{ auto _e = chre_platform_version(); _o->chre_platform_version = _e; }
}
inline flatbuffers::Offset<HubInfoResponse> HubInfoResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateHubInfoResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<HubInfoResponse> CreateHubInfoResponse(flatbuffers::FlatBufferBuilder &_fbb, const HubInfoResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const HubInfoResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _name = _o->name.size() ? _fbb.CreateVector(_o->name) : 0;
auto _vendor = _o->vendor.size() ? _fbb.CreateVector(_o->vendor) : 0;
auto _toolchain = _o->toolchain.size() ? _fbb.CreateVector(_o->toolchain) : 0;
auto _platform_version = _o->platform_version;
auto _toolchain_version = _o->toolchain_version;
auto _peak_mips = _o->peak_mips;
auto _stopped_power = _o->stopped_power;
auto _sleep_power = _o->sleep_power;
auto _peak_power = _o->peak_power;
auto _max_msg_len = _o->max_msg_len;
auto _platform_id = _o->platform_id;
auto _chre_platform_version = _o->chre_platform_version;
return chre::fbs::CreateHubInfoResponse(
_fbb,
_name,
_vendor,
_toolchain,
_platform_version,
_toolchain_version,
_peak_mips,
_stopped_power,
_sleep_power,
_peak_power,
_max_msg_len,
_platform_id,
_chre_platform_version);
}
inline NanoappListRequestT *NanoappListRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanoappListRequestT> _o = std::unique_ptr<chre::fbs::NanoappListRequestT>(new NanoappListRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanoappListRequest::UnPackTo(NanoappListRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<NanoappListRequest> NanoappListRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanoappListRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanoappListRequest> CreateNanoappListRequest(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanoappListRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateNanoappListRequest(
_fbb);
}
inline NanoappRpcServiceT *NanoappRpcService::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanoappRpcServiceT> _o = std::unique_ptr<chre::fbs::NanoappRpcServiceT>(new NanoappRpcServiceT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanoappRpcService::UnPackTo(NanoappRpcServiceT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = id(); _o->id = _e; }
{ auto _e = version(); _o->version = _e; }
}
inline flatbuffers::Offset<NanoappRpcService> NanoappRpcService::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappRpcServiceT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanoappRpcService(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanoappRpcService> CreateNanoappRpcService(flatbuffers::FlatBufferBuilder &_fbb, const NanoappRpcServiceT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanoappRpcServiceT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _id = _o->id;
auto _version = _o->version;
return chre::fbs::CreateNanoappRpcService(
_fbb,
_id,
_version);
}
inline NanoappListEntryT *NanoappListEntry::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanoappListEntryT> _o = std::unique_ptr<chre::fbs::NanoappListEntryT>(new NanoappListEntryT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanoappListEntry::UnPackTo(NanoappListEntryT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = app_id(); _o->app_id = _e; }
{ auto _e = version(); _o->version = _e; }
{ auto _e = enabled(); _o->enabled = _e; }
{ auto _e = is_system(); _o->is_system = _e; }
{ auto _e = permissions(); _o->permissions = _e; }
{ auto _e = rpc_services(); if (_e) { _o->rpc_services.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->rpc_services[_i] = std::unique_ptr<chre::fbs::NanoappRpcServiceT>(_e->Get(_i)->UnPack(_resolver)); } } }
}
inline flatbuffers::Offset<NanoappListEntry> NanoappListEntry::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListEntryT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanoappListEntry(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanoappListEntry> CreateNanoappListEntry(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListEntryT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanoappListEntryT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _app_id = _o->app_id;
auto _version = _o->version;
auto _enabled = _o->enabled;
auto _is_system = _o->is_system;
auto _permissions = _o->permissions;
auto _rpc_services = _o->rpc_services.size() ? _fbb.CreateVector<flatbuffers::Offset<chre::fbs::NanoappRpcService>> (_o->rpc_services.size(), [](size_t i, _VectorArgs *__va) { return CreateNanoappRpcService(*__va->__fbb, __va->__o->rpc_services[i].get(), __va->__rehasher); }, &_va ) : 0;
return chre::fbs::CreateNanoappListEntry(
_fbb,
_app_id,
_version,
_enabled,
_is_system,
_permissions,
_rpc_services);
}
inline NanoappListResponseT *NanoappListResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanoappListResponseT> _o = std::unique_ptr<chre::fbs::NanoappListResponseT>(new NanoappListResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanoappListResponse::UnPackTo(NanoappListResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = nanoapps(); if (_e) { _o->nanoapps.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->nanoapps[_i] = std::unique_ptr<chre::fbs::NanoappListEntryT>(_e->Get(_i)->UnPack(_resolver)); } } }
}
inline flatbuffers::Offset<NanoappListResponse> NanoappListResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanoappListResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanoappListResponse> CreateNanoappListResponse(flatbuffers::FlatBufferBuilder &_fbb, const NanoappListResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanoappListResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _nanoapps = _fbb.CreateVector<flatbuffers::Offset<chre::fbs::NanoappListEntry>> (_o->nanoapps.size(), [](size_t i, _VectorArgs *__va) { return CreateNanoappListEntry(*__va->__fbb, __va->__o->nanoapps[i].get(), __va->__rehasher); }, &_va );
return chre::fbs::CreateNanoappListResponse(
_fbb,
_nanoapps);
}
inline LoadNanoappRequestT *LoadNanoappRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LoadNanoappRequestT> _o = std::unique_ptr<chre::fbs::LoadNanoappRequestT>(new LoadNanoappRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LoadNanoappRequest::UnPackTo(LoadNanoappRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = transaction_id(); _o->transaction_id = _e; }
{ auto _e = app_id(); _o->app_id = _e; }
{ auto _e = app_version(); _o->app_version = _e; }
{ auto _e = target_api_version(); _o->target_api_version = _e; }
{ auto _e = app_binary(); if (_e) { _o->app_binary.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->app_binary[_i] = _e->Get(_i); } } }
{ auto _e = fragment_id(); _o->fragment_id = _e; }
{ auto _e = total_app_size(); _o->total_app_size = _e; }
{ auto _e = app_binary_file_name(); if (_e) { _o->app_binary_file_name.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->app_binary_file_name[_i] = _e->Get(_i); } } }
{ auto _e = app_flags(); _o->app_flags = _e; }
{ auto _e = respond_before_start(); _o->respond_before_start = _e; }
}
inline flatbuffers::Offset<LoadNanoappRequest> LoadNanoappRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLoadNanoappRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LoadNanoappRequest> CreateLoadNanoappRequest(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LoadNanoappRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _transaction_id = _o->transaction_id;
auto _app_id = _o->app_id;
auto _app_version = _o->app_version;
auto _target_api_version = _o->target_api_version;
auto _app_binary = _fbb.CreateVector(_o->app_binary);
auto _fragment_id = _o->fragment_id;
auto _total_app_size = _o->total_app_size;
auto _app_binary_file_name = _o->app_binary_file_name.size() ? _fbb.CreateVector(_o->app_binary_file_name) : 0;
auto _app_flags = _o->app_flags;
auto _respond_before_start = _o->respond_before_start;
return chre::fbs::CreateLoadNanoappRequest(
_fbb,
_transaction_id,
_app_id,
_app_version,
_target_api_version,
_app_binary,
_fragment_id,
_total_app_size,
_app_binary_file_name,
_app_flags,
_respond_before_start);
}
inline LoadNanoappResponseT *LoadNanoappResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LoadNanoappResponseT> _o = std::unique_ptr<chre::fbs::LoadNanoappResponseT>(new LoadNanoappResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LoadNanoappResponse::UnPackTo(LoadNanoappResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = transaction_id(); _o->transaction_id = _e; }
{ auto _e = success(); _o->success = _e; }
{ auto _e = fragment_id(); _o->fragment_id = _e; }
}
inline flatbuffers::Offset<LoadNanoappResponse> LoadNanoappResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLoadNanoappResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LoadNanoappResponse> CreateLoadNanoappResponse(flatbuffers::FlatBufferBuilder &_fbb, const LoadNanoappResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LoadNanoappResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _transaction_id = _o->transaction_id;
auto _success = _o->success;
auto _fragment_id = _o->fragment_id;
return chre::fbs::CreateLoadNanoappResponse(
_fbb,
_transaction_id,
_success,
_fragment_id);
}
inline UnloadNanoappRequestT *UnloadNanoappRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::UnloadNanoappRequestT> _o = std::unique_ptr<chre::fbs::UnloadNanoappRequestT>(new UnloadNanoappRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void UnloadNanoappRequest::UnPackTo(UnloadNanoappRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = transaction_id(); _o->transaction_id = _e; }
{ auto _e = app_id(); _o->app_id = _e; }
{ auto _e = allow_system_nanoapp_unload(); _o->allow_system_nanoapp_unload = _e; }
}
inline flatbuffers::Offset<UnloadNanoappRequest> UnloadNanoappRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateUnloadNanoappRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<UnloadNanoappRequest> CreateUnloadNanoappRequest(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const UnloadNanoappRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _transaction_id = _o->transaction_id;
auto _app_id = _o->app_id;
auto _allow_system_nanoapp_unload = _o->allow_system_nanoapp_unload;
return chre::fbs::CreateUnloadNanoappRequest(
_fbb,
_transaction_id,
_app_id,
_allow_system_nanoapp_unload);
}
inline UnloadNanoappResponseT *UnloadNanoappResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::UnloadNanoappResponseT> _o = std::unique_ptr<chre::fbs::UnloadNanoappResponseT>(new UnloadNanoappResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void UnloadNanoappResponse::UnPackTo(UnloadNanoappResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = transaction_id(); _o->transaction_id = _e; }
{ auto _e = success(); _o->success = _e; }
}
inline flatbuffers::Offset<UnloadNanoappResponse> UnloadNanoappResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateUnloadNanoappResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<UnloadNanoappResponse> CreateUnloadNanoappResponse(flatbuffers::FlatBufferBuilder &_fbb, const UnloadNanoappResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const UnloadNanoappResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _transaction_id = _o->transaction_id;
auto _success = _o->success;
return chre::fbs::CreateUnloadNanoappResponse(
_fbb,
_transaction_id,
_success);
}
inline LogMessageT *LogMessage::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LogMessageT> _o = std::unique_ptr<chre::fbs::LogMessageT>(new LogMessageT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LogMessage::UnPackTo(LogMessageT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = buffer(); if (_e) { _o->buffer.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->buffer[_i] = _e->Get(_i); } } }
}
inline flatbuffers::Offset<LogMessage> LogMessage::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLogMessage(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LogMessage> CreateLogMessage(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LogMessageT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _buffer = _o->buffer.size() ? _fbb.CreateVector(_o->buffer) : 0;
return chre::fbs::CreateLogMessage(
_fbb,
_buffer);
}
inline TimeSyncMessageT *TimeSyncMessage::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::TimeSyncMessageT> _o = std::unique_ptr<chre::fbs::TimeSyncMessageT>(new TimeSyncMessageT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void TimeSyncMessage::UnPackTo(TimeSyncMessageT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = offset(); _o->offset = _e; }
}
inline flatbuffers::Offset<TimeSyncMessage> TimeSyncMessage::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateTimeSyncMessage(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<TimeSyncMessage> CreateTimeSyncMessage(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TimeSyncMessageT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _offset = _o->offset;
return chre::fbs::CreateTimeSyncMessage(
_fbb,
_offset);
}
inline DebugDumpRequestT *DebugDumpRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::DebugDumpRequestT> _o = std::unique_ptr<chre::fbs::DebugDumpRequestT>(new DebugDumpRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void DebugDumpRequest::UnPackTo(DebugDumpRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<DebugDumpRequest> DebugDumpRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateDebugDumpRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<DebugDumpRequest> CreateDebugDumpRequest(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DebugDumpRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateDebugDumpRequest(
_fbb);
}
inline DebugDumpDataT *DebugDumpData::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::DebugDumpDataT> _o = std::unique_ptr<chre::fbs::DebugDumpDataT>(new DebugDumpDataT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void DebugDumpData::UnPackTo(DebugDumpDataT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = debug_str(); if (_e) { _o->debug_str.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->debug_str[_i] = _e->Get(_i); } } }
}
inline flatbuffers::Offset<DebugDumpData> DebugDumpData::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpDataT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateDebugDumpData(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<DebugDumpData> CreateDebugDumpData(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpDataT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DebugDumpDataT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _debug_str = _o->debug_str.size() ? _fbb.CreateVector(_o->debug_str) : 0;
return chre::fbs::CreateDebugDumpData(
_fbb,
_debug_str);
}
inline DebugDumpResponseT *DebugDumpResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::DebugDumpResponseT> _o = std::unique_ptr<chre::fbs::DebugDumpResponseT>(new DebugDumpResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void DebugDumpResponse::UnPackTo(DebugDumpResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = success(); _o->success = _e; }
{ auto _e = data_count(); _o->data_count = _e; }
}
inline flatbuffers::Offset<DebugDumpResponse> DebugDumpResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateDebugDumpResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<DebugDumpResponse> CreateDebugDumpResponse(flatbuffers::FlatBufferBuilder &_fbb, const DebugDumpResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DebugDumpResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _success = _o->success;
auto _data_count = _o->data_count;
return chre::fbs::CreateDebugDumpResponse(
_fbb,
_success,
_data_count);
}
inline TimeSyncRequestT *TimeSyncRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::TimeSyncRequestT> _o = std::unique_ptr<chre::fbs::TimeSyncRequestT>(new TimeSyncRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void TimeSyncRequest::UnPackTo(TimeSyncRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<TimeSyncRequest> TimeSyncRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateTimeSyncRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<TimeSyncRequest> CreateTimeSyncRequest(flatbuffers::FlatBufferBuilder &_fbb, const TimeSyncRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TimeSyncRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateTimeSyncRequest(
_fbb);
}
inline LowPowerMicAccessRequestT *LowPowerMicAccessRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LowPowerMicAccessRequestT> _o = std::unique_ptr<chre::fbs::LowPowerMicAccessRequestT>(new LowPowerMicAccessRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LowPowerMicAccessRequest::UnPackTo(LowPowerMicAccessRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<LowPowerMicAccessRequest> LowPowerMicAccessRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLowPowerMicAccessRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LowPowerMicAccessRequest> CreateLowPowerMicAccessRequest(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LowPowerMicAccessRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateLowPowerMicAccessRequest(
_fbb);
}
inline LowPowerMicAccessReleaseT *LowPowerMicAccessRelease::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LowPowerMicAccessReleaseT> _o = std::unique_ptr<chre::fbs::LowPowerMicAccessReleaseT>(new LowPowerMicAccessReleaseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LowPowerMicAccessRelease::UnPackTo(LowPowerMicAccessReleaseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<LowPowerMicAccessRelease> LowPowerMicAccessRelease::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessReleaseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLowPowerMicAccessRelease(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LowPowerMicAccessRelease> CreateLowPowerMicAccessRelease(flatbuffers::FlatBufferBuilder &_fbb, const LowPowerMicAccessReleaseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LowPowerMicAccessReleaseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateLowPowerMicAccessRelease(
_fbb);
}
inline SettingChangeMessageT *SettingChangeMessage::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::SettingChangeMessageT> _o = std::unique_ptr<chre::fbs::SettingChangeMessageT>(new SettingChangeMessageT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void SettingChangeMessage::UnPackTo(SettingChangeMessageT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = setting(); _o->setting = _e; }
{ auto _e = state(); _o->state = _e; }
}
inline flatbuffers::Offset<SettingChangeMessage> SettingChangeMessage::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SettingChangeMessageT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateSettingChangeMessage(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<SettingChangeMessage> CreateSettingChangeMessage(flatbuffers::FlatBufferBuilder &_fbb, const SettingChangeMessageT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SettingChangeMessageT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _setting = _o->setting;
auto _state = _o->state;
return chre::fbs::CreateSettingChangeMessage(
_fbb,
_setting,
_state);
}
inline LogMessageV2T *LogMessageV2::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::LogMessageV2T> _o = std::unique_ptr<chre::fbs::LogMessageV2T>(new LogMessageV2T());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void LogMessageV2::UnPackTo(LogMessageV2T *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = buffer(); if (_e) { _o->buffer.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->buffer[_i] = _e->Get(_i); } } }
{ auto _e = num_logs_dropped(); _o->num_logs_dropped = _e; }
}
inline flatbuffers::Offset<LogMessageV2> LogMessageV2::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageV2T* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateLogMessageV2(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<LogMessageV2> CreateLogMessageV2(flatbuffers::FlatBufferBuilder &_fbb, const LogMessageV2T *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LogMessageV2T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _buffer = _o->buffer.size() ? _fbb.CreateVector(_o->buffer) : 0;
auto _num_logs_dropped = _o->num_logs_dropped;
return chre::fbs::CreateLogMessageV2(
_fbb,
_buffer,
_num_logs_dropped);
}
inline SelfTestRequestT *SelfTestRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::SelfTestRequestT> _o = std::unique_ptr<chre::fbs::SelfTestRequestT>(new SelfTestRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void SelfTestRequest::UnPackTo(SelfTestRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
}
inline flatbuffers::Offset<SelfTestRequest> SelfTestRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateSelfTestRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<SelfTestRequest> CreateSelfTestRequest(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SelfTestRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
return chre::fbs::CreateSelfTestRequest(
_fbb);
}
inline SelfTestResponseT *SelfTestResponse::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::SelfTestResponseT> _o = std::unique_ptr<chre::fbs::SelfTestResponseT>(new SelfTestResponseT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void SelfTestResponse::UnPackTo(SelfTestResponseT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = success(); _o->success = _e; }
}
inline flatbuffers::Offset<SelfTestResponse> SelfTestResponse::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestResponseT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateSelfTestResponse(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<SelfTestResponse> CreateSelfTestResponse(flatbuffers::FlatBufferBuilder &_fbb, const SelfTestResponseT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SelfTestResponseT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _success = _o->success;
return chre::fbs::CreateSelfTestResponse(
_fbb,
_success);
}
inline HostEndpointConnectedT *HostEndpointConnected::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::HostEndpointConnectedT> _o = std::unique_ptr<chre::fbs::HostEndpointConnectedT>(new HostEndpointConnectedT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void HostEndpointConnected::UnPackTo(HostEndpointConnectedT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = host_endpoint(); _o->host_endpoint = _e; }
{ auto _e = type(); _o->type = _e; }
{ auto _e = package_name(); if (_e) { _o->package_name.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->package_name[_i] = _e->Get(_i); } } }
{ auto _e = attribution_tag(); if (_e) { _o->attribution_tag.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->attribution_tag[_i] = _e->Get(_i); } } }
}
inline flatbuffers::Offset<HostEndpointConnected> HostEndpointConnected::Pack(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointConnectedT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateHostEndpointConnected(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<HostEndpointConnected> CreateHostEndpointConnected(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointConnectedT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const HostEndpointConnectedT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _host_endpoint = _o->host_endpoint;
auto _type = _o->type;
auto _package_name = _o->package_name.size() ? _fbb.CreateVector(_o->package_name) : 0;
auto _attribution_tag = _o->attribution_tag.size() ? _fbb.CreateVector(_o->attribution_tag) : 0;
return chre::fbs::CreateHostEndpointConnected(
_fbb,
_host_endpoint,
_type,
_package_name,
_attribution_tag);
}
inline HostEndpointDisconnectedT *HostEndpointDisconnected::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::HostEndpointDisconnectedT> _o = std::unique_ptr<chre::fbs::HostEndpointDisconnectedT>(new HostEndpointDisconnectedT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void HostEndpointDisconnected::UnPackTo(HostEndpointDisconnectedT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = host_endpoint(); _o->host_endpoint = _e; }
}
inline flatbuffers::Offset<HostEndpointDisconnected> HostEndpointDisconnected::Pack(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointDisconnectedT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateHostEndpointDisconnected(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<HostEndpointDisconnected> CreateHostEndpointDisconnected(flatbuffers::FlatBufferBuilder &_fbb, const HostEndpointDisconnectedT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const HostEndpointDisconnectedT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _host_endpoint = _o->host_endpoint;
return chre::fbs::CreateHostEndpointDisconnected(
_fbb,
_host_endpoint);
}
inline MetricLogT *MetricLog::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::MetricLogT> _o = std::unique_ptr<chre::fbs::MetricLogT>(new MetricLogT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void MetricLog::UnPackTo(MetricLogT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = id(); _o->id = _e; }
{ auto _e = encoded_metric(); if (_e) { _o->encoded_metric.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->encoded_metric[_i] = _e->Get(_i); } } }
}
inline flatbuffers::Offset<MetricLog> MetricLog::Pack(flatbuffers::FlatBufferBuilder &_fbb, const MetricLogT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateMetricLog(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<MetricLog> CreateMetricLog(flatbuffers::FlatBufferBuilder &_fbb, const MetricLogT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const MetricLogT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _id = _o->id;
auto _encoded_metric = _o->encoded_metric.size() ? _fbb.CreateVector(_o->encoded_metric) : 0;
return chre::fbs::CreateMetricLog(
_fbb,
_id,
_encoded_metric);
}
inline BatchedMetricLogT *BatchedMetricLog::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::BatchedMetricLogT> _o = std::unique_ptr<chre::fbs::BatchedMetricLogT>(new BatchedMetricLogT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void BatchedMetricLog::UnPackTo(BatchedMetricLogT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = metrics(); if (_e) { _o->metrics.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->metrics[_i] = std::unique_ptr<chre::fbs::MetricLogT>(_e->Get(_i)->UnPack(_resolver)); } } }
}
inline flatbuffers::Offset<BatchedMetricLog> BatchedMetricLog::Pack(flatbuffers::FlatBufferBuilder &_fbb, const BatchedMetricLogT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateBatchedMetricLog(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<BatchedMetricLog> CreateBatchedMetricLog(flatbuffers::FlatBufferBuilder &_fbb, const BatchedMetricLogT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const BatchedMetricLogT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _metrics = _o->metrics.size() ? _fbb.CreateVector<flatbuffers::Offset<chre::fbs::MetricLog>> (_o->metrics.size(), [](size_t i, _VectorArgs *__va) { return CreateMetricLog(*__va->__fbb, __va->__o->metrics[i].get(), __va->__rehasher); }, &_va ) : 0;
return chre::fbs::CreateBatchedMetricLog(
_fbb,
_metrics);
}
inline NanConfigurationRequestT *NanConfigurationRequest::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanConfigurationRequestT> _o = std::unique_ptr<chre::fbs::NanConfigurationRequestT>(new NanConfigurationRequestT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanConfigurationRequest::UnPackTo(NanConfigurationRequestT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = enable(); _o->enable = _e; }
}
inline flatbuffers::Offset<NanConfigurationRequest> NanConfigurationRequest::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationRequestT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanConfigurationRequest(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanConfigurationRequest> CreateNanConfigurationRequest(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationRequestT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanConfigurationRequestT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _enable = _o->enable;
return chre::fbs::CreateNanConfigurationRequest(
_fbb,
_enable);
}
inline NanConfigurationUpdateT *NanConfigurationUpdate::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::NanConfigurationUpdateT> _o = std::unique_ptr<chre::fbs::NanConfigurationUpdateT>(new NanConfigurationUpdateT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void NanConfigurationUpdate::UnPackTo(NanConfigurationUpdateT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = enabled(); _o->enabled = _e; }
}
inline flatbuffers::Offset<NanConfigurationUpdate> NanConfigurationUpdate::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationUpdateT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateNanConfigurationUpdate(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<NanConfigurationUpdate> CreateNanConfigurationUpdate(flatbuffers::FlatBufferBuilder &_fbb, const NanConfigurationUpdateT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NanConfigurationUpdateT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _enabled = _o->enabled;
return chre::fbs::CreateNanConfigurationUpdate(
_fbb,
_enabled);
}
inline MessageContainerT *MessageContainer::UnPack(const flatbuffers::resolver_function_t *_resolver) const {
std::unique_ptr<chre::fbs::MessageContainerT> _o = std::unique_ptr<chre::fbs::MessageContainerT>(new MessageContainerT());
UnPackTo(_o.get(), _resolver);
return _o.release();
}
inline void MessageContainer::UnPackTo(MessageContainerT *_o, const flatbuffers::resolver_function_t *_resolver) const {
(void)_o;
(void)_resolver;
{ auto _e = message_type(); _o->message.type = _e; }
{ auto _e = message(); if (_e) _o->message.value = chre::fbs::ChreMessageUnion::UnPack(_e, message_type(), _resolver); }
{ auto _e = host_addr(); if (_e) _o->host_addr = std::unique_ptr<chre::fbs::HostAddress>(new chre::fbs::HostAddress(*_e)); }
}
inline flatbuffers::Offset<MessageContainer> MessageContainer::Pack(flatbuffers::FlatBufferBuilder &_fbb, const MessageContainerT* _o, const flatbuffers::rehasher_function_t *_rehasher) {
return CreateMessageContainer(_fbb, _o, _rehasher);
}
inline flatbuffers::Offset<MessageContainer> CreateMessageContainer(flatbuffers::FlatBufferBuilder &_fbb, const MessageContainerT *_o, const flatbuffers::rehasher_function_t *_rehasher) {
(void)_rehasher;
(void)_o;
struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const MessageContainerT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va;
auto _message_type = _o->message.type;
auto _message = _o->message.Pack(_fbb);
auto _host_addr = _o->host_addr ? _o->host_addr.get() : 0;
return chre::fbs::CreateMessageContainer(
_fbb,
_message_type,
_message,
_host_addr);
}
inline bool VerifyChreMessage(flatbuffers::Verifier &verifier, const void *obj, ChreMessage type) {
switch (type) {
case ChreMessage::NONE: {
return true;
}
case ChreMessage::NanoappMessage: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappMessage *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::HubInfoRequest: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::HubInfoResponse: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::NanoappListRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::NanoappListResponse: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LoadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LoadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::UnloadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::UnloadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LogMessage: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessage *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::TimeSyncMessage: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncMessage *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::DebugDumpRequest: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::DebugDumpData: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpData *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::DebugDumpResponse: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::TimeSyncRequest: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LowPowerMicAccessRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LowPowerMicAccessRelease: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessRelease *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::SettingChangeMessage: {
auto ptr = reinterpret_cast<const chre::fbs::SettingChangeMessage *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::LogMessageV2: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessageV2 *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::SelfTestRequest: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::SelfTestResponse: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestResponse *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::HostEndpointConnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointConnected *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::HostEndpointDisconnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointDisconnected *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::MetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::MetricLog *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::BatchedMetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::BatchedMetricLog *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::NanConfigurationRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationRequest *>(obj);
return verifier.VerifyTable(ptr);
}
case ChreMessage::NanConfigurationUpdate: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationUpdate *>(obj);
return verifier.VerifyTable(ptr);
}
default: return true;
}
}
inline bool VerifyChreMessageVector(flatbuffers::Verifier &verifier, const flatbuffers::Vector<flatbuffers::Offset<void>> *values, const flatbuffers::Vector<uint8_t> *types) {
if (!values || !types) return !values && !types;
if (values->size() != types->size()) return false;
for (flatbuffers::uoffset_t i = 0; i < values->size(); ++i) {
if (!VerifyChreMessage(
verifier, values->Get(i), types->GetEnum<ChreMessage>(i))) {
return false;
}
}
return true;
}
inline void *ChreMessageUnion::UnPack(const void *obj, ChreMessage type, const flatbuffers::resolver_function_t *resolver) {
switch (type) {
case ChreMessage::NanoappMessage: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappMessage *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::HubInfoRequest: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::HubInfoResponse: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::NanoappListRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::NanoappListResponse: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LoadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LoadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::UnloadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::UnloadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LogMessage: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessage *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::TimeSyncMessage: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncMessage *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::DebugDumpRequest: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::DebugDumpData: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpData *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::DebugDumpResponse: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::TimeSyncRequest: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LowPowerMicAccessRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LowPowerMicAccessRelease: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessRelease *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::SettingChangeMessage: {
auto ptr = reinterpret_cast<const chre::fbs::SettingChangeMessage *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::LogMessageV2: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessageV2 *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::SelfTestRequest: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::SelfTestResponse: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestResponse *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::HostEndpointConnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointConnected *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::HostEndpointDisconnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointDisconnected *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::MetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::MetricLog *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::BatchedMetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::BatchedMetricLog *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::NanConfigurationRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationRequest *>(obj);
return ptr->UnPack(resolver);
}
case ChreMessage::NanConfigurationUpdate: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationUpdate *>(obj);
return ptr->UnPack(resolver);
}
default: return nullptr;
}
}
inline flatbuffers::Offset<void> ChreMessageUnion::Pack(flatbuffers::FlatBufferBuilder &_fbb, const flatbuffers::rehasher_function_t *_rehasher) const {
switch (type) {
case ChreMessage::NanoappMessage: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappMessageT *>(value);
return CreateNanoappMessage(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::HubInfoRequest: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoRequestT *>(value);
return CreateHubInfoRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::HubInfoResponse: {
auto ptr = reinterpret_cast<const chre::fbs::HubInfoResponseT *>(value);
return CreateHubInfoResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::NanoappListRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListRequestT *>(value);
return CreateNanoappListRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::NanoappListResponse: {
auto ptr = reinterpret_cast<const chre::fbs::NanoappListResponseT *>(value);
return CreateNanoappListResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LoadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappRequestT *>(value);
return CreateLoadNanoappRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LoadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::LoadNanoappResponseT *>(value);
return CreateLoadNanoappResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::UnloadNanoappRequest: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappRequestT *>(value);
return CreateUnloadNanoappRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::UnloadNanoappResponse: {
auto ptr = reinterpret_cast<const chre::fbs::UnloadNanoappResponseT *>(value);
return CreateUnloadNanoappResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LogMessage: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessageT *>(value);
return CreateLogMessage(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::TimeSyncMessage: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncMessageT *>(value);
return CreateTimeSyncMessage(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::DebugDumpRequest: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpRequestT *>(value);
return CreateDebugDumpRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::DebugDumpData: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpDataT *>(value);
return CreateDebugDumpData(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::DebugDumpResponse: {
auto ptr = reinterpret_cast<const chre::fbs::DebugDumpResponseT *>(value);
return CreateDebugDumpResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::TimeSyncRequest: {
auto ptr = reinterpret_cast<const chre::fbs::TimeSyncRequestT *>(value);
return CreateTimeSyncRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LowPowerMicAccessRequest: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessRequestT *>(value);
return CreateLowPowerMicAccessRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LowPowerMicAccessRelease: {
auto ptr = reinterpret_cast<const chre::fbs::LowPowerMicAccessReleaseT *>(value);
return CreateLowPowerMicAccessRelease(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::SettingChangeMessage: {
auto ptr = reinterpret_cast<const chre::fbs::SettingChangeMessageT *>(value);
return CreateSettingChangeMessage(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::LogMessageV2: {
auto ptr = reinterpret_cast<const chre::fbs::LogMessageV2T *>(value);
return CreateLogMessageV2(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::SelfTestRequest: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestRequestT *>(value);
return CreateSelfTestRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::SelfTestResponse: {
auto ptr = reinterpret_cast<const chre::fbs::SelfTestResponseT *>(value);
return CreateSelfTestResponse(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::HostEndpointConnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointConnectedT *>(value);
return CreateHostEndpointConnected(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::HostEndpointDisconnected: {
auto ptr = reinterpret_cast<const chre::fbs::HostEndpointDisconnectedT *>(value);
return CreateHostEndpointDisconnected(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::MetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::MetricLogT *>(value);
return CreateMetricLog(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::BatchedMetricLog: {
auto ptr = reinterpret_cast<const chre::fbs::BatchedMetricLogT *>(value);
return CreateBatchedMetricLog(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::NanConfigurationRequest: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationRequestT *>(value);
return CreateNanConfigurationRequest(_fbb, ptr, _rehasher).Union();
}
case ChreMessage::NanConfigurationUpdate: {
auto ptr = reinterpret_cast<const chre::fbs::NanConfigurationUpdateT *>(value);
return CreateNanConfigurationUpdate(_fbb, ptr, _rehasher).Union();
}
default: return 0;
}
}
inline ChreMessageUnion::ChreMessageUnion(const ChreMessageUnion &u) : type(u.type), value(nullptr) {
switch (type) {
case ChreMessage::NanoappMessage: {
value = new chre::fbs::NanoappMessageT(*reinterpret_cast<chre::fbs::NanoappMessageT *>(u.value));
break;
}
case ChreMessage::HubInfoRequest: {
value = new chre::fbs::HubInfoRequestT(*reinterpret_cast<chre::fbs::HubInfoRequestT *>(u.value));
break;
}
case ChreMessage::HubInfoResponse: {
value = new chre::fbs::HubInfoResponseT(*reinterpret_cast<chre::fbs::HubInfoResponseT *>(u.value));
break;
}
case ChreMessage::NanoappListRequest: {
value = new chre::fbs::NanoappListRequestT(*reinterpret_cast<chre::fbs::NanoappListRequestT *>(u.value));
break;
}
case ChreMessage::NanoappListResponse: {
FLATBUFFERS_ASSERT(false); // chre::fbs::NanoappListResponseT not copyable.
break;
}
case ChreMessage::LoadNanoappRequest: {
value = new chre::fbs::LoadNanoappRequestT(*reinterpret_cast<chre::fbs::LoadNanoappRequestT *>(u.value));
break;
}
case ChreMessage::LoadNanoappResponse: {
value = new chre::fbs::LoadNanoappResponseT(*reinterpret_cast<chre::fbs::LoadNanoappResponseT *>(u.value));
break;
}
case ChreMessage::UnloadNanoappRequest: {
value = new chre::fbs::UnloadNanoappRequestT(*reinterpret_cast<chre::fbs::UnloadNanoappRequestT *>(u.value));
break;
}
case ChreMessage::UnloadNanoappResponse: {
value = new chre::fbs::UnloadNanoappResponseT(*reinterpret_cast<chre::fbs::UnloadNanoappResponseT *>(u.value));
break;
}
case ChreMessage::LogMessage: {
value = new chre::fbs::LogMessageT(*reinterpret_cast<chre::fbs::LogMessageT *>(u.value));
break;
}
case ChreMessage::TimeSyncMessage: {
value = new chre::fbs::TimeSyncMessageT(*reinterpret_cast<chre::fbs::TimeSyncMessageT *>(u.value));
break;
}
case ChreMessage::DebugDumpRequest: {
value = new chre::fbs::DebugDumpRequestT(*reinterpret_cast<chre::fbs::DebugDumpRequestT *>(u.value));
break;
}
case ChreMessage::DebugDumpData: {
value = new chre::fbs::DebugDumpDataT(*reinterpret_cast<chre::fbs::DebugDumpDataT *>(u.value));
break;
}
case ChreMessage::DebugDumpResponse: {
value = new chre::fbs::DebugDumpResponseT(*reinterpret_cast<chre::fbs::DebugDumpResponseT *>(u.value));
break;
}
case ChreMessage::TimeSyncRequest: {
value = new chre::fbs::TimeSyncRequestT(*reinterpret_cast<chre::fbs::TimeSyncRequestT *>(u.value));
break;
}
case ChreMessage::LowPowerMicAccessRequest: {
value = new chre::fbs::LowPowerMicAccessRequestT(*reinterpret_cast<chre::fbs::LowPowerMicAccessRequestT *>(u.value));
break;
}
case ChreMessage::LowPowerMicAccessRelease: {
value = new chre::fbs::LowPowerMicAccessReleaseT(*reinterpret_cast<chre::fbs::LowPowerMicAccessReleaseT *>(u.value));
break;
}
case ChreMessage::SettingChangeMessage: {
value = new chre::fbs::SettingChangeMessageT(*reinterpret_cast<chre::fbs::SettingChangeMessageT *>(u.value));
break;
}
case ChreMessage::LogMessageV2: {
value = new chre::fbs::LogMessageV2T(*reinterpret_cast<chre::fbs::LogMessageV2T *>(u.value));
break;
}
case ChreMessage::SelfTestRequest: {
value = new chre::fbs::SelfTestRequestT(*reinterpret_cast<chre::fbs::SelfTestRequestT *>(u.value));
break;
}
case ChreMessage::SelfTestResponse: {
value = new chre::fbs::SelfTestResponseT(*reinterpret_cast<chre::fbs::SelfTestResponseT *>(u.value));
break;
}
case ChreMessage::HostEndpointConnected: {
value = new chre::fbs::HostEndpointConnectedT(*reinterpret_cast<chre::fbs::HostEndpointConnectedT *>(u.value));
break;
}
case ChreMessage::HostEndpointDisconnected: {
value = new chre::fbs::HostEndpointDisconnectedT(*reinterpret_cast<chre::fbs::HostEndpointDisconnectedT *>(u.value));
break;
}
case ChreMessage::MetricLog: {
value = new chre::fbs::MetricLogT(*reinterpret_cast<chre::fbs::MetricLogT *>(u.value));
break;
}
case ChreMessage::BatchedMetricLog: {
FLATBUFFERS_ASSERT(false); // chre::fbs::BatchedMetricLogT not copyable.
break;
}
case ChreMessage::NanConfigurationRequest: {
value = new chre::fbs::NanConfigurationRequestT(*reinterpret_cast<chre::fbs::NanConfigurationRequestT *>(u.value));
break;
}
case ChreMessage::NanConfigurationUpdate: {
value = new chre::fbs::NanConfigurationUpdateT(*reinterpret_cast<chre::fbs::NanConfigurationUpdateT *>(u.value));
break;
}
default:
break;
}
}
inline void ChreMessageUnion::Reset() {
switch (type) {
case ChreMessage::NanoappMessage: {
auto ptr = reinterpret_cast<chre::fbs::NanoappMessageT *>(value);
delete ptr;
break;
}
case ChreMessage::HubInfoRequest: {
auto ptr = reinterpret_cast<chre::fbs::HubInfoRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::HubInfoResponse: {
auto ptr = reinterpret_cast<chre::fbs::HubInfoResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::NanoappListRequest: {
auto ptr = reinterpret_cast<chre::fbs::NanoappListRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::NanoappListResponse: {
auto ptr = reinterpret_cast<chre::fbs::NanoappListResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::LoadNanoappRequest: {
auto ptr = reinterpret_cast<chre::fbs::LoadNanoappRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::LoadNanoappResponse: {
auto ptr = reinterpret_cast<chre::fbs::LoadNanoappResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::UnloadNanoappRequest: {
auto ptr = reinterpret_cast<chre::fbs::UnloadNanoappRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::UnloadNanoappResponse: {
auto ptr = reinterpret_cast<chre::fbs::UnloadNanoappResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::LogMessage: {
auto ptr = reinterpret_cast<chre::fbs::LogMessageT *>(value);
delete ptr;
break;
}
case ChreMessage::TimeSyncMessage: {
auto ptr = reinterpret_cast<chre::fbs::TimeSyncMessageT *>(value);
delete ptr;
break;
}
case ChreMessage::DebugDumpRequest: {
auto ptr = reinterpret_cast<chre::fbs::DebugDumpRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::DebugDumpData: {
auto ptr = reinterpret_cast<chre::fbs::DebugDumpDataT *>(value);
delete ptr;
break;
}
case ChreMessage::DebugDumpResponse: {
auto ptr = reinterpret_cast<chre::fbs::DebugDumpResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::TimeSyncRequest: {
auto ptr = reinterpret_cast<chre::fbs::TimeSyncRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::LowPowerMicAccessRequest: {
auto ptr = reinterpret_cast<chre::fbs::LowPowerMicAccessRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::LowPowerMicAccessRelease: {
auto ptr = reinterpret_cast<chre::fbs::LowPowerMicAccessReleaseT *>(value);
delete ptr;
break;
}
case ChreMessage::SettingChangeMessage: {
auto ptr = reinterpret_cast<chre::fbs::SettingChangeMessageT *>(value);
delete ptr;
break;
}
case ChreMessage::LogMessageV2: {
auto ptr = reinterpret_cast<chre::fbs::LogMessageV2T *>(value);
delete ptr;
break;
}
case ChreMessage::SelfTestRequest: {
auto ptr = reinterpret_cast<chre::fbs::SelfTestRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::SelfTestResponse: {
auto ptr = reinterpret_cast<chre::fbs::SelfTestResponseT *>(value);
delete ptr;
break;
}
case ChreMessage::HostEndpointConnected: {
auto ptr = reinterpret_cast<chre::fbs::HostEndpointConnectedT *>(value);
delete ptr;
break;
}
case ChreMessage::HostEndpointDisconnected: {
auto ptr = reinterpret_cast<chre::fbs::HostEndpointDisconnectedT *>(value);
delete ptr;
break;
}
case ChreMessage::MetricLog: {
auto ptr = reinterpret_cast<chre::fbs::MetricLogT *>(value);
delete ptr;
break;
}
case ChreMessage::BatchedMetricLog: {
auto ptr = reinterpret_cast<chre::fbs::BatchedMetricLogT *>(value);
delete ptr;
break;
}
case ChreMessage::NanConfigurationRequest: {
auto ptr = reinterpret_cast<chre::fbs::NanConfigurationRequestT *>(value);
delete ptr;
break;
}
case ChreMessage::NanConfigurationUpdate: {
auto ptr = reinterpret_cast<chre::fbs::NanConfigurationUpdateT *>(value);
delete ptr;
break;
}
default: break;
}
value = nullptr;
type = ChreMessage::NONE;
}
inline const chre::fbs::MessageContainer *GetMessageContainer(const void *buf) {
return flatbuffers::GetRoot<chre::fbs::MessageContainer>(buf);
}
inline const chre::fbs::MessageContainer *GetSizePrefixedMessageContainer(const void *buf) {
return flatbuffers::GetSizePrefixedRoot<chre::fbs::MessageContainer>(buf);
}
inline MessageContainer *GetMutableMessageContainer(void *buf) {
return flatbuffers::GetMutableRoot<MessageContainer>(buf);
}
inline bool VerifyMessageContainerBuffer(
flatbuffers::Verifier &verifier) {
return verifier.VerifyBuffer<chre::fbs::MessageContainer>(nullptr);
}
inline bool VerifySizePrefixedMessageContainerBuffer(
flatbuffers::Verifier &verifier) {
return verifier.VerifySizePrefixedBuffer<chre::fbs::MessageContainer>(nullptr);
}
inline void FinishMessageContainerBuffer(
flatbuffers::FlatBufferBuilder &fbb,
flatbuffers::Offset<chre::fbs::MessageContainer> root) {
fbb.Finish(root);
}
inline void FinishSizePrefixedMessageContainerBuffer(
flatbuffers::FlatBufferBuilder &fbb,
flatbuffers::Offset<chre::fbs::MessageContainer> root) {
fbb.FinishSizePrefixed(root);
}
inline std::unique_ptr<chre::fbs::MessageContainerT> UnPackMessageContainer(
const void *buf,
const flatbuffers::resolver_function_t *res = nullptr) {
return std::unique_ptr<chre::fbs::MessageContainerT>(GetMessageContainer(buf)->UnPack(res));
}
inline std::unique_ptr<chre::fbs::MessageContainerT> UnPackSizePrefixedMessageContainer(
const void *buf,
const flatbuffers::resolver_function_t *res = nullptr) {
return std::unique_ptr<chre::fbs::MessageContainerT>(GetSizePrefixedMessageContainer(buf)->UnPack(res));
}
} // namespace fbs
} // namespace chre
#endif // FLATBUFFERS_GENERATED_HOSTMESSAGES_CHRE_FBS_H_