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/*
* Copyright (C) 2022 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <algorithm>
#include <set>
#define LOG_TAG "AHAL_Module"
#include <aidl/android/media/audio/common/AudioInputFlags.h>
#include <aidl/android/media/audio/common/AudioOutputFlags.h>
#include <android-base/logging.h>
#include <android/binder_ibinder_platform.h>
#include <error/expected_utils.h>
#include "core-impl/Configuration.h"
#include "core-impl/Module.h"
#include "core-impl/ModuleBluetooth.h"
#include "core-impl/ModulePrimary.h"
#include "core-impl/ModuleRemoteSubmix.h"
#include "core-impl/ModuleStub.h"
#include "core-impl/ModuleUsb.h"
#include "core-impl/SoundDose.h"
#include "core-impl/utils.h"
using aidl::android::hardware::audio::common::frameCountFromDurationMs;
using aidl::android::hardware::audio::common::getFrameSizeInBytes;
using aidl::android::hardware::audio::common::isBitPositionFlagSet;
using aidl::android::hardware::audio::common::isValidAudioMode;
using aidl::android::hardware::audio::common::SinkMetadata;
using aidl::android::hardware::audio::common::SourceMetadata;
using aidl::android::hardware::audio::core::sounddose::ISoundDose;
using aidl::android::media::audio::common::AudioChannelLayout;
using aidl::android::media::audio::common::AudioDevice;
using aidl::android::media::audio::common::AudioDeviceType;
using aidl::android::media::audio::common::AudioFormatDescription;
using aidl::android::media::audio::common::AudioFormatType;
using aidl::android::media::audio::common::AudioInputFlags;
using aidl::android::media::audio::common::AudioIoFlags;
using aidl::android::media::audio::common::AudioMMapPolicy;
using aidl::android::media::audio::common::AudioMMapPolicyInfo;
using aidl::android::media::audio::common::AudioMMapPolicyType;
using aidl::android::media::audio::common::AudioMode;
using aidl::android::media::audio::common::AudioOffloadInfo;
using aidl::android::media::audio::common::AudioOutputFlags;
using aidl::android::media::audio::common::AudioPort;
using aidl::android::media::audio::common::AudioPortConfig;
using aidl::android::media::audio::common::AudioPortExt;
using aidl::android::media::audio::common::AudioProfile;
using aidl::android::media::audio::common::Boolean;
using aidl::android::media::audio::common::Int;
using aidl::android::media::audio::common::MicrophoneInfo;
using aidl::android::media::audio::common::PcmType;
namespace aidl::android::hardware::audio::core {
namespace {
inline bool hasDynamicChannelMasks(const std::vector<AudioChannelLayout>& channelMasks) {
return channelMasks.empty() ||
std::all_of(channelMasks.begin(), channelMasks.end(),
[](const auto& channelMask) { return channelMask == AudioChannelLayout{}; });
}
inline bool hasDynamicFormat(const AudioFormatDescription& format) {
return format == AudioFormatDescription{};
}
inline bool hasDynamicSampleRates(const std::vector<int32_t>& sampleRates) {
return sampleRates.empty() ||
std::all_of(sampleRates.begin(), sampleRates.end(),
[](const auto& sampleRate) { return sampleRate == 0; });
}
inline bool isDynamicProfile(const AudioProfile& profile) {
return hasDynamicFormat(profile.format) || hasDynamicChannelMasks(profile.channelMasks) ||
hasDynamicSampleRates(profile.sampleRates);
}
bool hasDynamicProfilesOnly(const std::vector<AudioProfile>& profiles) {
if (profiles.empty()) return true;
return std::all_of(profiles.begin(), profiles.end(), isDynamicProfile);
}
bool findAudioProfile(const AudioPort& port, const AudioFormatDescription& format,
AudioProfile* profile) {
if (auto profilesIt =
find_if(port.profiles.begin(), port.profiles.end(),
[&format](const auto& profile) { return profile.format == format; });
profilesIt != port.profiles.end()) {
*profile = *profilesIt;
return true;
}
return false;
}
} // namespace
// static
std::shared_ptr<Module> Module::createInstance(Type type, std::unique_ptr<Configuration>&& config) {
switch (type) {
case Type::DEFAULT:
return ndk::SharedRefBase::make<ModulePrimary>(std::move(config));
case Type::R_SUBMIX:
return ndk::SharedRefBase::make<ModuleRemoteSubmix>(std::move(config));
case Type::STUB:
return ndk::SharedRefBase::make<ModuleStub>(std::move(config));
case Type::USB:
return ndk::SharedRefBase::make<ModuleUsb>(std::move(config));
case Type::BLUETOOTH:
return ndk::SharedRefBase::make<ModuleBluetooth>(std::move(config));
}
}
// static
std::optional<Module::Type> Module::typeFromString(const std::string& type) {
if (type == "default")
return Module::Type::DEFAULT;
else if (type == "r_submix")
return Module::Type::R_SUBMIX;
else if (type == "stub")
return Module::Type::STUB;
else if (type == "usb")
return Module::Type::USB;
else if (type == "bluetooth")
return Module::Type::BLUETOOTH;
return {};
}
std::ostream& operator<<(std::ostream& os, Module::Type t) {
switch (t) {
case Module::Type::DEFAULT:
os << "default";
break;
case Module::Type::R_SUBMIX:
os << "r_submix";
break;
case Module::Type::STUB:
os << "stub";
break;
case Module::Type::USB:
os << "usb";
break;
case Module::Type::BLUETOOTH:
os << "bluetooth";
break;
}
return os;
}
Module::Module(Type type, std::unique_ptr<Configuration>&& config)
: mType(type), mConfig(std::move(config)) {
populateConnectedProfiles();
}
void Module::cleanUpPatch(int32_t patchId) {
erase_all_values(mPatches, std::set<int32_t>{patchId});
}
ndk::ScopedAStatus Module::createStreamContext(
int32_t in_portConfigId, int64_t in_bufferSizeFrames,
std::shared_ptr<IStreamCallback> asyncCallback,
std::shared_ptr<IStreamOutEventCallback> outEventCallback, StreamContext* out_context) {
if (in_bufferSizeFrames <= 0) {
LOG(ERROR) << __func__ << ": non-positive buffer size " << in_bufferSizeFrames;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto& configs = getConfig().portConfigs;
auto portConfigIt = findById<AudioPortConfig>(configs, in_portConfigId);
const int32_t nominalLatencyMs = getNominalLatencyMs(*portConfigIt);
// Since this is a private method, it is assumed that
// validity of the portConfigId has already been checked.
const int32_t minimumStreamBufferSizeFrames =
calculateBufferSizeFrames(nominalLatencyMs, portConfigIt->sampleRate.value().value);
if (in_bufferSizeFrames < minimumStreamBufferSizeFrames) {
LOG(ERROR) << __func__ << ": insufficient buffer size " << in_bufferSizeFrames
<< ", must be at least " << minimumStreamBufferSizeFrames;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const size_t frameSize =
getFrameSizeInBytes(portConfigIt->format.value(), portConfigIt->channelMask.value());
if (frameSize == 0) {
LOG(ERROR) << __func__ << ": could not calculate frame size for port config "
<< portConfigIt->toString();
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
LOG(DEBUG) << __func__ << ": frame size " << frameSize << " bytes";
if (frameSize > static_cast<size_t>(kMaximumStreamBufferSizeBytes / in_bufferSizeFrames)) {
LOG(ERROR) << __func__ << ": buffer size " << in_bufferSizeFrames
<< " frames is too large, maximum size is "
<< kMaximumStreamBufferSizeBytes / frameSize;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const auto& flags = portConfigIt->flags.value();
if ((flags.getTag() == AudioIoFlags::Tag::input &&
!isBitPositionFlagSet(flags.get<AudioIoFlags::Tag::input>(),
AudioInputFlags::MMAP_NOIRQ)) ||
(flags.getTag() == AudioIoFlags::Tag::output &&
!isBitPositionFlagSet(flags.get<AudioIoFlags::Tag::output>(),
AudioOutputFlags::MMAP_NOIRQ))) {
StreamContext::DebugParameters params{mDebug.streamTransientStateDelayMs,
mVendorDebug.forceTransientBurst,
mVendorDebug.forceSynchronousDrain};
std::shared_ptr<ISoundDose> soundDose;
if (!getSoundDose(&soundDose).isOk()) {
LOG(ERROR) << __func__ << ": could not create sound dose instance";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
StreamContext temp(
std::make_unique<StreamContext::CommandMQ>(1, true /*configureEventFlagWord*/),
std::make_unique<StreamContext::ReplyMQ>(1, true /*configureEventFlagWord*/),
portConfigIt->format.value(), portConfigIt->channelMask.value(),
portConfigIt->sampleRate.value().value, flags, nominalLatencyMs,
portConfigIt->ext.get<AudioPortExt::mix>().handle,
std::make_unique<StreamContext::DataMQ>(frameSize * in_bufferSizeFrames),
asyncCallback, outEventCallback, mSoundDose.getInstance(), params);
if (temp.isValid()) {
*out_context = std::move(temp);
} else {
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
} else {
// TODO: Implement simulation of MMAP buffer allocation
}
return ndk::ScopedAStatus::ok();
}
std::vector<AudioDevice> Module::findConnectedDevices(int32_t portConfigId) {
std::vector<AudioDevice> result;
auto& ports = getConfig().ports;
auto portIds = portIdsFromPortConfigIds(findConnectedPortConfigIds(portConfigId));
for (auto it = portIds.begin(); it != portIds.end(); ++it) {
auto portIt = findById<AudioPort>(ports, *it);
if (portIt != ports.end() && portIt->ext.getTag() == AudioPortExt::Tag::device) {
result.push_back(portIt->ext.template get<AudioPortExt::Tag::device>().device);
}
}
return result;
}
std::set<int32_t> Module::findConnectedPortConfigIds(int32_t portConfigId) {
std::set<int32_t> result;
auto patchIdsRange = mPatches.equal_range(portConfigId);
auto& patches = getConfig().patches;
for (auto it = patchIdsRange.first; it != patchIdsRange.second; ++it) {
auto patchIt = findById<AudioPatch>(patches, it->second);
if (patchIt == patches.end()) {
LOG(FATAL) << __func__ << ": patch with id " << it->second << " taken from mPatches "
<< "not found in the configuration";
}
if (std::find(patchIt->sourcePortConfigIds.begin(), patchIt->sourcePortConfigIds.end(),
portConfigId) != patchIt->sourcePortConfigIds.end()) {
result.insert(patchIt->sinkPortConfigIds.begin(), patchIt->sinkPortConfigIds.end());
} else {
result.insert(patchIt->sourcePortConfigIds.begin(), patchIt->sourcePortConfigIds.end());
}
}
return result;
}
ndk::ScopedAStatus Module::findPortIdForNewStream(int32_t in_portConfigId, AudioPort** port) {
auto& configs = getConfig().portConfigs;
auto portConfigIt = findById<AudioPortConfig>(configs, in_portConfigId);
if (portConfigIt == configs.end()) {
LOG(ERROR) << __func__ << ": existing port config id " << in_portConfigId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const int32_t portId = portConfigIt->portId;
// In our implementation, configs of mix ports always have unique IDs.
CHECK(portId != in_portConfigId);
auto& ports = getConfig().ports;
auto portIt = findById<AudioPort>(ports, portId);
if (portIt == ports.end()) {
LOG(ERROR) << __func__ << ": port id " << portId << " used by port config id "
<< in_portConfigId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (mStreams.count(in_portConfigId) != 0) {
LOG(ERROR) << __func__ << ": port config id " << in_portConfigId
<< " already has a stream opened on it";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
if (portIt->ext.getTag() != AudioPortExt::Tag::mix) {
LOG(ERROR) << __func__ << ": port config id " << in_portConfigId
<< " does not correspond to a mix port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const size_t maxOpenStreamCount = portIt->ext.get<AudioPortExt::Tag::mix>().maxOpenStreamCount;
if (maxOpenStreamCount != 0 && mStreams.count(portId) >= maxOpenStreamCount) {
LOG(ERROR) << __func__ << ": port id " << portId
<< " has already reached maximum allowed opened stream count: "
<< maxOpenStreamCount;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
*port = &(*portIt);
return ndk::ScopedAStatus::ok();
}
bool Module::generateDefaultPortConfig(const AudioPort& port, AudioPortConfig* config) {
const bool allowDynamicConfig = port.ext.getTag() == AudioPortExt::device;
for (const auto& profile : port.profiles) {
if (isDynamicProfile(profile)) continue;
config->format = profile.format;
config->channelMask = *profile.channelMasks.begin();
config->sampleRate = Int{.value = *profile.sampleRates.begin()};
config->flags = port.flags;
config->ext = port.ext;
return true;
}
if (allowDynamicConfig) {
config->format = AudioFormatDescription{};
config->channelMask = AudioChannelLayout{};
config->sampleRate = Int{.value = 0};
config->flags = port.flags;
config->ext = port.ext;
return true;
}
LOG(ERROR) << __func__ << ": port " << port.id << " only has dynamic profiles";
return false;
}
void Module::populateConnectedProfiles() {
Configuration& config = getConfig();
for (const AudioPort& port : config.ports) {
if (port.ext.getTag() == AudioPortExt::device) {
if (auto devicePort = port.ext.get<AudioPortExt::device>();
!devicePort.device.type.connection.empty() && port.profiles.empty()) {
if (auto connIt = config.connectedProfiles.find(port.id);
connIt == config.connectedProfiles.end()) {
config.connectedProfiles.emplace(
port.id, internal::getStandard16And24BitPcmAudioProfiles());
}
}
}
}
}
template <typename C>
std::set<int32_t> Module::portIdsFromPortConfigIds(C portConfigIds) {
std::set<int32_t> result;
auto& portConfigs = getConfig().portConfigs;
for (auto it = portConfigIds.begin(); it != portConfigIds.end(); ++it) {
auto portConfigIt = findById<AudioPortConfig>(portConfigs, *it);
if (portConfigIt != portConfigs.end()) {
result.insert(portConfigIt->portId);
}
}
return result;
}
std::unique_ptr<Module::Configuration> Module::initializeConfig() {
return internal::getConfiguration(getType());
}
int32_t Module::getNominalLatencyMs(const AudioPortConfig&) {
// Arbitrary value. Implementations must override this method to provide their actual latency.
static constexpr int32_t kLatencyMs = 5;
return kLatencyMs;
}
std::vector<AudioRoute*> Module::getAudioRoutesForAudioPortImpl(int32_t portId) {
std::vector<AudioRoute*> result;
auto& routes = getConfig().routes;
for (auto& r : routes) {
const auto& srcs = r.sourcePortIds;
if (r.sinkPortId == portId || std::find(srcs.begin(), srcs.end(), portId) != srcs.end()) {
result.push_back(&r);
}
}
return result;
}
Module::Configuration& Module::getConfig() {
if (!mConfig) {
mConfig = std::move(initializeConfig());
}
return *mConfig;
}
std::set<int32_t> Module::getRoutableAudioPortIds(int32_t portId,
std::vector<AudioRoute*>* routes) {
std::vector<AudioRoute*> routesStorage;
if (routes == nullptr) {
routesStorage = getAudioRoutesForAudioPortImpl(portId);
routes = &routesStorage;
}
std::set<int32_t> result;
for (AudioRoute* r : *routes) {
if (r->sinkPortId == portId) {
result.insert(r->sourcePortIds.begin(), r->sourcePortIds.end());
} else {
result.insert(r->sinkPortId);
}
}
return result;
}
void Module::registerPatch(const AudioPatch& patch) {
auto& configs = getConfig().portConfigs;
auto do_insert = [&](const std::vector<int32_t>& portConfigIds) {
for (auto portConfigId : portConfigIds) {
auto configIt = findById<AudioPortConfig>(configs, portConfigId);
if (configIt != configs.end()) {
mPatches.insert(std::pair{portConfigId, patch.id});
if (configIt->portId != portConfigId) {
mPatches.insert(std::pair{configIt->portId, patch.id});
}
}
};
};
do_insert(patch.sourcePortConfigIds);
do_insert(patch.sinkPortConfigIds);
}
ndk::ScopedAStatus Module::updateStreamsConnectedState(const AudioPatch& oldPatch,
const AudioPatch& newPatch) {
// Notify streams about the new set of devices they are connected to.
auto maybeFailure = ndk::ScopedAStatus::ok();
using Connections =
std::map<int32_t /*mixPortConfigId*/, std::set<int32_t /*devicePortConfigId*/>>;
Connections oldConnections, newConnections;
auto fillConnectionsHelper = [&](Connections& connections,
const std::vector<int32_t>& mixPortCfgIds,
const std::vector<int32_t>& devicePortCfgIds) {
for (int32_t mixPortCfgId : mixPortCfgIds) {
connections[mixPortCfgId].insert(devicePortCfgIds.begin(), devicePortCfgIds.end());
}
};
auto fillConnections = [&](Connections& connections, const AudioPatch& patch) {
if (std::find_if(patch.sourcePortConfigIds.begin(), patch.sourcePortConfigIds.end(),
[&](int32_t portConfigId) { return mStreams.count(portConfigId) > 0; }) !=
patch.sourcePortConfigIds.end()) {
// Sources are mix ports.
fillConnectionsHelper(connections, patch.sourcePortConfigIds, patch.sinkPortConfigIds);
} else if (std::find_if(patch.sinkPortConfigIds.begin(), patch.sinkPortConfigIds.end(),
[&](int32_t portConfigId) {
return mStreams.count(portConfigId) > 0;
}) != patch.sinkPortConfigIds.end()) {
// Sources are device ports.
fillConnectionsHelper(connections, patch.sinkPortConfigIds, patch.sourcePortConfigIds);
} // Otherwise, there are no streams to notify.
};
fillConnections(oldConnections, oldPatch);
fillConnections(newConnections, newPatch);
std::for_each(oldConnections.begin(), oldConnections.end(), [&](const auto& connectionPair) {
const int32_t mixPortConfigId = connectionPair.first;
if (auto it = newConnections.find(mixPortConfigId);
it == newConnections.end() || it->second != connectionPair.second) {
if (auto status = mStreams.setStreamConnectedDevices(mixPortConfigId, {});
status.isOk()) {
LOG(DEBUG) << "updateStreamsConnectedState: The stream on port config id "
<< mixPortConfigId << " has been disconnected";
} else {
// Disconnection is tricky to roll back, just register a failure.
maybeFailure = std::move(status);
}
}
});
if (!maybeFailure.isOk()) return maybeFailure;
std::set<int32_t> idsToDisconnectOnFailure;
std::for_each(newConnections.begin(), newConnections.end(), [&](const auto& connectionPair) {
const int32_t mixPortConfigId = connectionPair.first;
if (auto it = oldConnections.find(mixPortConfigId);
it == oldConnections.end() || it->second != connectionPair.second) {
const auto connectedDevices = findConnectedDevices(mixPortConfigId);
if (connectedDevices.empty()) {
// This is important as workers use the vector size to derive the connection status.
LOG(FATAL) << "updateStreamsConnectedState: No connected devices found for port "
"config id "
<< mixPortConfigId;
}
if (auto status = mStreams.setStreamConnectedDevices(mixPortConfigId, connectedDevices);
status.isOk()) {
LOG(DEBUG) << "updateStreamsConnectedState: The stream on port config id "
<< mixPortConfigId << " has been connected to: "
<< ::android::internal::ToString(connectedDevices);
} else {
maybeFailure = std::move(status);
idsToDisconnectOnFailure.insert(mixPortConfigId);
}
}
});
if (!maybeFailure.isOk()) {
LOG(WARNING) << __func__ << ": Due to a failure, disconnecting streams on port config ids "
<< ::android::internal::ToString(idsToDisconnectOnFailure);
std::for_each(idsToDisconnectOnFailure.begin(), idsToDisconnectOnFailure.end(),
[&](const auto& portConfigId) {
auto status = mStreams.setStreamConnectedDevices(portConfigId, {});
(void)status.isOk(); // Can't do much about a failure here.
});
return maybeFailure;
}
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::setModuleDebug(
const ::aidl::android::hardware::audio::core::ModuleDebug& in_debug) {
LOG(DEBUG) << __func__ << ": " << mType << ": old flags:" << mDebug.toString()
<< ", new flags: " << in_debug.toString();
if (mDebug.simulateDeviceConnections != in_debug.simulateDeviceConnections &&
!mConnectedDevicePorts.empty()) {
LOG(ERROR) << __func__ << ": " << mType
<< ": attempting to change device connections simulation while having external "
<< "devices connected";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
if (in_debug.streamTransientStateDelayMs < 0) {
LOG(ERROR) << __func__ << ": " << mType << ": streamTransientStateDelayMs is negative: "
<< in_debug.streamTransientStateDelayMs;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
mDebug = in_debug;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getTelephony(std::shared_ptr<ITelephony>* _aidl_return) {
*_aidl_return = nullptr;
LOG(DEBUG) << __func__ << ": returning null";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getBluetooth(std::shared_ptr<IBluetooth>* _aidl_return) {
*_aidl_return = nullptr;
LOG(DEBUG) << __func__ << ": returning null";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getBluetoothA2dp(std::shared_ptr<IBluetoothA2dp>* _aidl_return) {
*_aidl_return = nullptr;
LOG(DEBUG) << __func__ << ": returning null";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getBluetoothLe(std::shared_ptr<IBluetoothLe>* _aidl_return) {
*_aidl_return = nullptr;
LOG(DEBUG) << __func__ << ": returning null";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::connectExternalDevice(const AudioPort& in_templateIdAndAdditionalData,
AudioPort* _aidl_return) {
const int32_t templateId = in_templateIdAndAdditionalData.id;
auto& ports = getConfig().ports;
AudioPort connectedPort;
{ // Scope the template port so that we don't accidentally modify it.
auto templateIt = findById<AudioPort>(ports, templateId);
if (templateIt == ports.end()) {
LOG(ERROR) << __func__ << ": port id " << templateId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (templateIt->ext.getTag() != AudioPortExt::Tag::device) {
LOG(ERROR) << __func__ << ": port id " << templateId << " is not a device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto& templateDevicePort = templateIt->ext.get<AudioPortExt::Tag::device>();
if (templateDevicePort.device.type.connection.empty()) {
LOG(ERROR) << __func__ << ": port id " << templateId << " is permanently attached";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (mConnectedDevicePorts.find(templateId) != mConnectedDevicePorts.end()) {
LOG(ERROR) << __func__ << ": port id " << templateId << " is a connected device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
// Postpone id allocation until we ensure that there are no client errors.
connectedPort = *templateIt;
connectedPort.extraAudioDescriptors = in_templateIdAndAdditionalData.extraAudioDescriptors;
const auto& inputDevicePort =
in_templateIdAndAdditionalData.ext.get<AudioPortExt::Tag::device>();
auto& connectedDevicePort = connectedPort.ext.get<AudioPortExt::Tag::device>();
connectedDevicePort.device.address = inputDevicePort.device.address;
LOG(DEBUG) << __func__ << ": device port " << connectedPort.id << " device set to "
<< connectedDevicePort.device.toString();
// Check if there is already a connected port with for the same external device.
for (auto connectedPortPair : mConnectedDevicePorts) {
auto connectedPortIt = findById<AudioPort>(ports, connectedPortPair.first);
if (connectedPortIt->ext.get<AudioPortExt::Tag::device>().device ==
connectedDevicePort.device) {
LOG(ERROR) << __func__ << ": device " << connectedDevicePort.device.toString()
<< " is already connected at the device port id "
<< connectedPortPair.first;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
}
}
// Two main cases are considered with regard to the profiles of the connected device port:
//
// 1. If the template device port has dynamic profiles, and at least one routable mix
// port also has dynamic profiles, it means that after connecting the device, the
// connected device port must have profiles populated with actual capabilities of
// the connected device, and dynamic of routable mix ports will be filled
// according to these capabilities. An example of this case is connection of an
// HDMI or USB device. For USB handled by ADSP, there can be mix ports with static
// profiles, and one dedicated mix port for "hi-fi" playback. The latter is left with
// dynamic profiles so that they can be populated with actual capabilities of
// the connected device.
//
// 2. If the template device port has dynamic profiles, while all routable mix ports
// have static profiles, it means that after connecting the device, the connected
// device port can be left with dynamic profiles, and profiles of mix ports are
// left untouched. An example of this case is connection of an analog wired
// headset, it should be treated in the same way as a speaker.
//
// Yet another possible case is when both the template device port and all routable
// mix ports have static profiles. This is allowed and handled correctly, however, it
// is not very practical, since these profiles are likely duplicates of each other.
std::vector<AudioRoute*> routesToMixPorts = getAudioRoutesForAudioPortImpl(templateId);
std::set<int32_t> routableMixPortIds = getRoutableAudioPortIds(templateId, &routesToMixPorts);
const int32_t nextPortId = getConfig().nextPortId++;
if (!mDebug.simulateDeviceConnections) {
// Even if the device port has static profiles, the HAL module might need to update
// them, or abort the connection process.
RETURN_STATUS_IF_ERROR(populateConnectedDevicePort(&connectedPort, nextPortId));
} else if (hasDynamicProfilesOnly(connectedPort.profiles)) {
auto& connectedProfiles = getConfig().connectedProfiles;
if (auto connectedProfilesIt = connectedProfiles.find(templateId);
connectedProfilesIt != connectedProfiles.end()) {
connectedPort.profiles = connectedProfilesIt->second;
}
}
if (hasDynamicProfilesOnly(connectedPort.profiles)) {
// Possible case 2. Check if all routable mix ports have static profiles.
if (auto dynamicMixPortIt = std::find_if(ports.begin(), ports.end(),
[&routableMixPortIds](const auto& p) {
return routableMixPortIds.count(p.id) > 0 &&
hasDynamicProfilesOnly(p.profiles);
});
dynamicMixPortIt != ports.end()) {
LOG(ERROR) << __func__ << ": connected port only has dynamic profiles after connecting "
<< "external device " << connectedPort.toString() << ", and there exist "
<< "a routable mix port with dynamic profiles: "
<< dynamicMixPortIt->toString();
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
}
connectedPort.id = nextPortId;
auto [connectedPortsIt, _] =
mConnectedDevicePorts.insert(std::pair(connectedPort.id, std::set<int32_t>()));
LOG(DEBUG) << __func__ << ": template port " << templateId << " external device connected, "
<< "connected port ID " << connectedPort.id;
ports.push_back(connectedPort);
onExternalDeviceConnectionChanged(connectedPort, true /*connected*/);
// For routes where the template port is a source, add the connected port to sources,
// otherwise, create a new route by copying from the route for the template port.
std::vector<AudioRoute> newRoutes;
for (AudioRoute* r : routesToMixPorts) {
if (r->sinkPortId == templateId) {
newRoutes.push_back(AudioRoute{.sourcePortIds = r->sourcePortIds,
.sinkPortId = connectedPort.id,
.isExclusive = r->isExclusive});
} else {
r->sourcePortIds.push_back(connectedPort.id);
}
}
auto& routes = getConfig().routes;
routes.insert(routes.end(), newRoutes.begin(), newRoutes.end());
if (!hasDynamicProfilesOnly(connectedPort.profiles) && !routableMixPortIds.empty()) {
// Note: this is a simplistic approach assuming that a mix port can only be populated
// from a single device port. Implementing support for stuffing dynamic profiles with
// a superset of all profiles from all routable dynamic device ports would be more involved.
for (auto& port : ports) {
if (routableMixPortIds.count(port.id) == 0) continue;
if (hasDynamicProfilesOnly(port.profiles)) {
port.profiles = connectedPort.profiles;
connectedPortsIt->second.insert(port.id);
} else {
// Check if profiles are not all dynamic because they were populated by
// a previous connection. Otherwise, it means that they are actually static.
for (const auto& cp : mConnectedDevicePorts) {
if (cp.second.count(port.id) > 0) {
connectedPortsIt->second.insert(port.id);
break;
}
}
}
}
}
*_aidl_return = std::move(connectedPort);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::disconnectExternalDevice(int32_t in_portId) {
auto& ports = getConfig().ports;
auto portIt = findById<AudioPort>(ports, in_portId);
if (portIt == ports.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (portIt->ext.getTag() != AudioPortExt::Tag::device) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " is not a device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto connectedPortsIt = mConnectedDevicePorts.find(in_portId);
if (connectedPortsIt == mConnectedDevicePorts.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " is not a connected device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto& configs = getConfig().portConfigs;
auto& initials = getConfig().initialConfigs;
auto configIt = std::find_if(configs.begin(), configs.end(), [&](const auto& config) {
if (config.portId == in_portId) {
// Check if the configuration was provided by the client.
const auto& initialIt = findById<AudioPortConfig>(initials, config.id);
return initialIt == initials.end() || config != *initialIt;
}
return false;
});
if (configIt != configs.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " has a non-default config with id "
<< configIt->id;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
onExternalDeviceConnectionChanged(*portIt, false /*connected*/);
ports.erase(portIt);
LOG(DEBUG) << __func__ << ": connected device port " << in_portId << " released";
auto& routes = getConfig().routes;
for (auto routesIt = routes.begin(); routesIt != routes.end();) {
if (routesIt->sinkPortId == in_portId) {
routesIt = routes.erase(routesIt);
} else {
// Note: the list of sourcePortIds can't become empty because there must
// be the id of the template port in the route.
erase_if(routesIt->sourcePortIds, [in_portId](auto src) { return src == in_portId; });
++routesIt;
}
}
// Clear profiles for mix ports that are not connected to any other ports.
std::set<int32_t> mixPortsToClear = std::move(connectedPortsIt->second);
mConnectedDevicePorts.erase(connectedPortsIt);
for (const auto& connectedPort : mConnectedDevicePorts) {
for (int32_t mixPortId : connectedPort.second) {
mixPortsToClear.erase(mixPortId);
}
}
for (int32_t mixPortId : mixPortsToClear) {
auto mixPortIt = findById<AudioPort>(ports, mixPortId);
if (mixPortIt != ports.end()) {
mixPortIt->profiles = {};
}
}
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::prepareToDisconnectExternalDevice(int32_t in_portId) {
auto& ports = getConfig().ports;
auto portIt = findById<AudioPort>(ports, in_portId);
if (portIt == ports.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (portIt->ext.getTag() != AudioPortExt::Tag::device) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " is not a device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto connectedPortsIt = mConnectedDevicePorts.find(in_portId);
if (connectedPortsIt == mConnectedDevicePorts.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " is not a connected device port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
onPrepareToDisconnectExternalDevice(*portIt);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAudioPatches(std::vector<AudioPatch>* _aidl_return) {
*_aidl_return = getConfig().patches;
LOG(DEBUG) << __func__ << ": returning " << _aidl_return->size() << " patches";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAudioPort(int32_t in_portId, AudioPort* _aidl_return) {
auto& ports = getConfig().ports;
auto portIt = findById<AudioPort>(ports, in_portId);
if (portIt != ports.end()) {
*_aidl_return = *portIt;
LOG(DEBUG) << __func__ << ": returning port by id " << in_portId;
return ndk::ScopedAStatus::ok();
}
LOG(ERROR) << __func__ << ": port id " << in_portId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
ndk::ScopedAStatus Module::getAudioPortConfigs(std::vector<AudioPortConfig>* _aidl_return) {
*_aidl_return = getConfig().portConfigs;
LOG(DEBUG) << __func__ << ": returning " << _aidl_return->size() << " port configs";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAudioPorts(std::vector<AudioPort>* _aidl_return) {
*_aidl_return = getConfig().ports;
LOG(DEBUG) << __func__ << ": returning " << _aidl_return->size() << " ports";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAudioRoutes(std::vector<AudioRoute>* _aidl_return) {
*_aidl_return = getConfig().routes;
LOG(DEBUG) << __func__ << ": returning " << _aidl_return->size() << " routes";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAudioRoutesForAudioPort(int32_t in_portId,
std::vector<AudioRoute>* _aidl_return) {
auto& ports = getConfig().ports;
if (auto portIt = findById<AudioPort>(ports, in_portId); portIt == ports.end()) {
LOG(ERROR) << __func__ << ": port id " << in_portId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
std::vector<AudioRoute*> routes = getAudioRoutesForAudioPortImpl(in_portId);
std::transform(routes.begin(), routes.end(), std::back_inserter(*_aidl_return),
[](auto rptr) { return *rptr; });
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::openInputStream(const OpenInputStreamArguments& in_args,
OpenInputStreamReturn* _aidl_return) {
LOG(DEBUG) << __func__ << ": port config id " << in_args.portConfigId << ", buffer size "
<< in_args.bufferSizeFrames << " frames";
AudioPort* port = nullptr;
RETURN_STATUS_IF_ERROR(findPortIdForNewStream(in_args.portConfigId, &port));
if (port->flags.getTag() != AudioIoFlags::Tag::input) {
LOG(ERROR) << __func__ << ": port config id " << in_args.portConfigId
<< " does not correspond to an input mix port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
StreamContext context;
RETURN_STATUS_IF_ERROR(createStreamContext(in_args.portConfigId, in_args.bufferSizeFrames,
nullptr, nullptr, &context));
context.fillDescriptor(&_aidl_return->desc);
std::shared_ptr<StreamIn> stream;
RETURN_STATUS_IF_ERROR(createInputStream(std::move(context), in_args.sinkMetadata,
getMicrophoneInfos(), &stream));
StreamWrapper streamWrapper(stream);
if (auto patchIt = mPatches.find(in_args.portConfigId); patchIt != mPatches.end()) {
RETURN_STATUS_IF_ERROR(
streamWrapper.setConnectedDevices(findConnectedDevices(in_args.portConfigId)));
}
AIBinder_setMinSchedulerPolicy(streamWrapper.getBinder().get(), SCHED_NORMAL,
ANDROID_PRIORITY_AUDIO);
mStreams.insert(port->id, in_args.portConfigId, std::move(streamWrapper));
_aidl_return->stream = std::move(stream);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::openOutputStream(const OpenOutputStreamArguments& in_args,
OpenOutputStreamReturn* _aidl_return) {
LOG(DEBUG) << __func__ << ": port config id " << in_args.portConfigId << ", has offload info? "
<< (in_args.offloadInfo.has_value()) << ", buffer size " << in_args.bufferSizeFrames
<< " frames";
AudioPort* port = nullptr;
RETURN_STATUS_IF_ERROR(findPortIdForNewStream(in_args.portConfigId, &port));
if (port->flags.getTag() != AudioIoFlags::Tag::output) {
LOG(ERROR) << __func__ << ": port config id " << in_args.portConfigId
<< " does not correspond to an output mix port";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const bool isOffload = isBitPositionFlagSet(port->flags.get<AudioIoFlags::Tag::output>(),
AudioOutputFlags::COMPRESS_OFFLOAD);
if (isOffload && !in_args.offloadInfo.has_value()) {
LOG(ERROR) << __func__ << ": port id " << port->id
<< " has COMPRESS_OFFLOAD flag set, requires offload info";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const bool isNonBlocking = isBitPositionFlagSet(port->flags.get<AudioIoFlags::Tag::output>(),
AudioOutputFlags::NON_BLOCKING);
if (isNonBlocking && in_args.callback == nullptr) {
LOG(ERROR) << __func__ << ": port id " << port->id
<< " has NON_BLOCKING flag set, requires async callback";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
StreamContext context;
RETURN_STATUS_IF_ERROR(createStreamContext(in_args.portConfigId, in_args.bufferSizeFrames,
isNonBlocking ? in_args.callback : nullptr,
in_args.eventCallback, &context));
context.fillDescriptor(&_aidl_return->desc);
std::shared_ptr<StreamOut> stream;
RETURN_STATUS_IF_ERROR(createOutputStream(std::move(context), in_args.sourceMetadata,
in_args.offloadInfo, &stream));
StreamWrapper streamWrapper(stream);
if (auto patchIt = mPatches.find(in_args.portConfigId); patchIt != mPatches.end()) {
RETURN_STATUS_IF_ERROR(
streamWrapper.setConnectedDevices(findConnectedDevices(in_args.portConfigId)));
}
AIBinder_setMinSchedulerPolicy(streamWrapper.getBinder().get(), SCHED_NORMAL,
ANDROID_PRIORITY_AUDIO);
mStreams.insert(port->id, in_args.portConfigId, std::move(streamWrapper));
_aidl_return->stream = std::move(stream);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getSupportedPlaybackRateFactors(
SupportedPlaybackRateFactors* _aidl_return) {
LOG(DEBUG) << __func__;
(void)_aidl_return;
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
ndk::ScopedAStatus Module::setAudioPatch(const AudioPatch& in_requested, AudioPatch* _aidl_return) {
LOG(DEBUG) << __func__ << ": requested patch " << in_requested.toString();
if (in_requested.sourcePortConfigIds.empty()) {
LOG(ERROR) << __func__ << ": requested patch has empty sources list";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (!all_unique<int32_t>(in_requested.sourcePortConfigIds)) {
LOG(ERROR) << __func__ << ": requested patch has duplicate ids in the sources list";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (in_requested.sinkPortConfigIds.empty()) {
LOG(ERROR) << __func__ << ": requested patch has empty sinks list";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (!all_unique<int32_t>(in_requested.sinkPortConfigIds)) {
LOG(ERROR) << __func__ << ": requested patch has duplicate ids in the sinks list";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto& configs = getConfig().portConfigs;
std::vector<int32_t> missingIds;
auto sources =
selectByIds<AudioPortConfig>(configs, in_requested.sourcePortConfigIds, &missingIds);
if (!missingIds.empty()) {
LOG(ERROR) << __func__ << ": following source port config ids not found: "
<< ::android::internal::ToString(missingIds);
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto sinks = selectByIds<AudioPortConfig>(configs, in_requested.sinkPortConfigIds, &missingIds);
if (!missingIds.empty()) {
LOG(ERROR) << __func__ << ": following sink port config ids not found: "
<< ::android::internal::ToString(missingIds);
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
// bool indicates whether a non-exclusive route is available.
// If only an exclusive route is available, that means the patch can not be
// established if there is any other patch which currently uses the sink port.
std::map<int32_t, bool> allowedSinkPorts;
auto& routes = getConfig().routes;
for (auto src : sources) {
for (const auto& r : routes) {
const auto& srcs = r.sourcePortIds;
if (std::find(srcs.begin(), srcs.end(), src->portId) != srcs.end()) {
if (!allowedSinkPorts[r.sinkPortId]) { // prefer non-exclusive
allowedSinkPorts[r.sinkPortId] = !r.isExclusive;
}
}
}
}
for (auto sink : sinks) {
if (allowedSinkPorts.count(sink->portId) == 0) {
LOG(ERROR) << __func__ << ": there is no route to the sink port id " << sink->portId;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
}
RETURN_STATUS_IF_ERROR(checkAudioPatchEndpointsMatch(sources, sinks));
auto& patches = getConfig().patches;
auto existing = patches.end();
std::optional<decltype(mPatches)> patchesBackup;
if (in_requested.id != 0) {
existing = findById<AudioPatch>(patches, in_requested.id);
if (existing != patches.end()) {
patchesBackup = mPatches;
cleanUpPatch(existing->id);
} else {
LOG(ERROR) << __func__ << ": not found existing patch id " << in_requested.id;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
}
// Validate the requested patch.
for (const auto& [sinkPortId, nonExclusive] : allowedSinkPorts) {
if (!nonExclusive && mPatches.count(sinkPortId) != 0) {
LOG(ERROR) << __func__ << ": sink port id " << sinkPortId
<< "is exclusive and is already used by some other patch";
if (patchesBackup.has_value()) {
mPatches = std::move(*patchesBackup);
}
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
}
// Find the highest sample rate among mix port configs.
std::map<int32_t, AudioPortConfig*> sampleRates;
std::vector<AudioPortConfig*>& mixPortConfigs =
sources[0]->ext.getTag() == AudioPortExt::mix ? sources : sinks;
for (auto mix : mixPortConfigs) {
sampleRates.emplace(mix->sampleRate.value().value, mix);
}
*_aidl_return = in_requested;
auto maxSampleRateIt = std::max_element(sampleRates.begin(), sampleRates.end());
const int32_t latencyMs = getNominalLatencyMs(*(maxSampleRateIt->second));
_aidl_return->minimumStreamBufferSizeFrames =
calculateBufferSizeFrames(latencyMs, maxSampleRateIt->first);
_aidl_return->latenciesMs.clear();
_aidl_return->latenciesMs.insert(_aidl_return->latenciesMs.end(),
_aidl_return->sinkPortConfigIds.size(), latencyMs);
AudioPatch oldPatch{};
if (existing == patches.end()) {
_aidl_return->id = getConfig().nextPatchId++;
patches.push_back(*_aidl_return);
} else {
oldPatch = *existing;
*existing = *_aidl_return;
}
patchesBackup = mPatches;
registerPatch(*_aidl_return);
if (auto status = updateStreamsConnectedState(oldPatch, *_aidl_return); !status.isOk()) {
mPatches = std::move(*patchesBackup);
if (existing == patches.end()) {
patches.pop_back();
} else {
*existing = oldPatch;
}
return status;
}
LOG(DEBUG) << __func__ << ": " << (oldPatch.id == 0 ? "created" : "updated") << " patch "
<< _aidl_return->toString();
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::setAudioPortConfig(const AudioPortConfig& in_requested,
AudioPortConfig* out_suggested, bool* _aidl_return) {
auto generate = [this](const AudioPort& port, AudioPortConfig* config) {
return generateDefaultPortConfig(port, config);
};
return setAudioPortConfigImpl(in_requested, generate, out_suggested, _aidl_return);
}
ndk::ScopedAStatus Module::setAudioPortConfigImpl(
const AudioPortConfig& in_requested,
const std::function<bool(const ::aidl::android::media::audio::common::AudioPort& port,
::aidl::android::media::audio::common::AudioPortConfig* config)>&
fillPortConfig,
AudioPortConfig* out_suggested, bool* applied) {
LOG(DEBUG) << __func__ << ": requested " << in_requested.toString();
auto& configs = getConfig().portConfigs;
auto existing = configs.end();
if (in_requested.id != 0) {
if (existing = findById<AudioPortConfig>(configs, in_requested.id);
existing == configs.end()) {
LOG(ERROR) << __func__ << ": existing port config id " << in_requested.id
<< " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
}
const int portId = existing != configs.end() ? existing->portId : in_requested.portId;
if (portId == 0) {
LOG(ERROR) << __func__ << ": requested port config does not specify portId";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
auto& ports = getConfig().ports;
auto portIt = findById<AudioPort>(ports, portId);
if (portIt == ports.end()) {
LOG(ERROR) << __func__ << ": requested port config points to non-existent portId "
<< portId;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (existing != configs.end()) {
*out_suggested = *existing;
} else {
AudioPortConfig newConfig;
newConfig.portId = portIt->id;
if (fillPortConfig(*portIt, &newConfig)) {
*out_suggested = newConfig;
} else {
LOG(ERROR) << __func__ << ": unable generate a default config for port " << portId;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
}
// From this moment, 'out_suggested' is either an existing port config,
// or a new generated config. Now attempt to update it according to the specified
// fields of 'in_requested'.
// Device ports with only dynamic profiles are used for devices that are connected via ADSP,
// which takes care of their actual configuration automatically.
const bool allowDynamicConfig = portIt->ext.getTag() == AudioPortExt::device &&
hasDynamicProfilesOnly(portIt->profiles);
bool requestedIsValid = true, requestedIsFullySpecified = true;
AudioIoFlags portFlags = portIt->flags;
if (in_requested.flags.has_value()) {
if (in_requested.flags.value() != portFlags) {
LOG(WARNING) << __func__ << ": requested flags "
<< in_requested.flags.value().toString() << " do not match port's "
<< portId << " flags " << portFlags.toString();
requestedIsValid = false;
}
} else {
requestedIsFullySpecified = false;
}
AudioProfile portProfile;
if (in_requested.format.has_value()) {
const auto& format = in_requested.format.value();
if ((format == AudioFormatDescription{} && allowDynamicConfig) ||
findAudioProfile(*portIt, format, &portProfile)) {
out_suggested->format = format;
} else {
LOG(WARNING) << __func__ << ": requested format " << format.toString()
<< " is not found in the profiles of port " << portId;
requestedIsValid = false;
}
} else {
requestedIsFullySpecified = false;
}
if (!(out_suggested->format.value() == AudioFormatDescription{} && allowDynamicConfig) &&
!findAudioProfile(*portIt, out_suggested->format.value(), &portProfile)) {
LOG(ERROR) << __func__ << ": port " << portId << " does not support format "
<< out_suggested->format.value().toString() << " anymore";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
if (in_requested.channelMask.has_value()) {
const auto& channelMask = in_requested.channelMask.value();
if ((channelMask == AudioChannelLayout{} && allowDynamicConfig) ||
find(portProfile.channelMasks.begin(), portProfile.channelMasks.end(), channelMask) !=
portProfile.channelMasks.end()) {
out_suggested->channelMask = channelMask;
} else {
LOG(WARNING) << __func__ << ": requested channel mask " << channelMask.toString()
<< " is not supported for the format " << portProfile.format.toString()
<< " by the port " << portId;
requestedIsValid = false;
}
} else {
requestedIsFullySpecified = false;
}
if (in_requested.sampleRate.has_value()) {
const auto& sampleRate = in_requested.sampleRate.value();
if ((sampleRate.value == 0 && allowDynamicConfig) ||
find(portProfile.sampleRates.begin(), portProfile.sampleRates.end(),
sampleRate.value) != portProfile.sampleRates.end()) {
out_suggested->sampleRate = sampleRate;
} else {
LOG(WARNING) << __func__ << ": requested sample rate " << sampleRate.value
<< " is not supported for the format " << portProfile.format.toString()
<< " by the port " << portId;
requestedIsValid = false;
}
} else {
requestedIsFullySpecified = false;
}
if (in_requested.gain.has_value()) {
// Let's pretend that gain can always be applied.
out_suggested->gain = in_requested.gain.value();
}
if (in_requested.ext.getTag() != AudioPortExt::Tag::unspecified) {
if (in_requested.ext.getTag() == out_suggested->ext.getTag()) {
if (out_suggested->ext.getTag() == AudioPortExt::Tag::mix) {
// 'AudioMixPortExt.handle' is set by the client, copy from in_requested
out_suggested->ext.get<AudioPortExt::Tag::mix>().handle =
in_requested.ext.get<AudioPortExt::Tag::mix>().handle;
}
} else {
LOG(WARNING) << __func__ << ": requested ext tag "
<< toString(in_requested.ext.getTag()) << " do not match port's tag "
<< toString(out_suggested->ext.getTag());
requestedIsValid = false;
}
}
if (existing == configs.end() && requestedIsValid && requestedIsFullySpecified) {
out_suggested->id = getConfig().nextPortId++;
configs.push_back(*out_suggested);
*applied = true;
LOG(DEBUG) << __func__ << ": created new port config " << out_suggested->toString();
} else if (existing != configs.end() && requestedIsValid) {
*existing = *out_suggested;
*applied = true;
LOG(DEBUG) << __func__ << ": updated port config " << out_suggested->toString();
} else {
LOG(DEBUG) << __func__ << ": not applied; existing config ? " << (existing != configs.end())
<< "; requested is valid? " << requestedIsValid << ", fully specified? "
<< requestedIsFullySpecified;
*applied = false;
}
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::resetAudioPatch(int32_t in_patchId) {
auto& patches = getConfig().patches;
auto patchIt = findById<AudioPatch>(patches, in_patchId);
if (patchIt != patches.end()) {
auto patchesBackup = mPatches;
cleanUpPatch(patchIt->id);
if (auto status = updateStreamsConnectedState(*patchIt, AudioPatch{}); !status.isOk()) {
mPatches = std::move(patchesBackup);
return status;
}
patches.erase(patchIt);
LOG(DEBUG) << __func__ << ": erased patch " << in_patchId;
return ndk::ScopedAStatus::ok();
}
LOG(ERROR) << __func__ << ": patch id " << in_patchId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
ndk::ScopedAStatus Module::resetAudioPortConfig(int32_t in_portConfigId) {
auto& configs = getConfig().portConfigs;
auto configIt = findById<AudioPortConfig>(configs, in_portConfigId);
if (configIt != configs.end()) {
if (mStreams.count(in_portConfigId) != 0) {
LOG(ERROR) << __func__ << ": port config id " << in_portConfigId
<< " has a stream opened on it";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
auto patchIt = mPatches.find(in_portConfigId);
if (patchIt != mPatches.end()) {
LOG(ERROR) << __func__ << ": port config id " << in_portConfigId
<< " is used by the patch with id " << patchIt->second;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
auto& initials = getConfig().initialConfigs;
auto initialIt = findById<AudioPortConfig>(initials, in_portConfigId);
if (initialIt == initials.end()) {
configs.erase(configIt);
LOG(DEBUG) << __func__ << ": erased port config " << in_portConfigId;
} else if (*configIt != *initialIt) {
*configIt = *initialIt;
LOG(DEBUG) << __func__ << ": reset port config " << in_portConfigId;
}
return ndk::ScopedAStatus::ok();
}
LOG(ERROR) << __func__ << ": port config id " << in_portConfigId << " not found";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
ndk::ScopedAStatus Module::getMasterMute(bool* _aidl_return) {
*_aidl_return = mMasterMute;
LOG(DEBUG) << __func__ << ": returning " << *_aidl_return;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::setMasterMute(bool in_mute) {
LOG(DEBUG) << __func__ << ": " << in_mute;
auto result = mDebug.simulateDeviceConnections ? ndk::ScopedAStatus::ok()
: onMasterMuteChanged(in_mute);
if (result.isOk()) {
mMasterMute = in_mute;
} else {
LOG(ERROR) << __func__ << ": failed calling onMasterMuteChanged(" << in_mute
<< "), error=" << result;
// Reset master mute if it failed.
onMasterMuteChanged(mMasterMute);
}
return result;
}
ndk::ScopedAStatus Module::getMasterVolume(float* _aidl_return) {
*_aidl_return = mMasterVolume;
LOG(DEBUG) << __func__ << ": returning " << *_aidl_return;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::setMasterVolume(float in_volume) {
LOG(DEBUG) << __func__ << ": " << in_volume;
if (in_volume >= 0.0f && in_volume <= 1.0f) {
auto result = mDebug.simulateDeviceConnections ? ndk::ScopedAStatus::ok()
: onMasterVolumeChanged(in_volume);
if (result.isOk()) {
mMasterVolume = in_volume;
} else {
// Reset master volume if it failed.
LOG(ERROR) << __func__ << ": failed calling onMasterVolumeChanged(" << in_volume
<< "), error=" << result;
onMasterVolumeChanged(mMasterVolume);
}
return result;
}
LOG(ERROR) << __func__ << ": invalid master volume value: " << in_volume;
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
ndk::ScopedAStatus Module::getMicMute(bool* _aidl_return) {
*_aidl_return = mMicMute;
LOG(DEBUG) << __func__ << ": returning " << *_aidl_return;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::setMicMute(bool in_mute) {
LOG(DEBUG) << __func__ << ": " << in_mute;
mMicMute = in_mute;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getMicrophones(std::vector<MicrophoneInfo>* _aidl_return) {
*_aidl_return = getMicrophoneInfos();
LOG(DEBUG) << __func__ << ": returning " << ::android::internal::ToString(*_aidl_return);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::updateAudioMode(AudioMode in_mode) {
if (!isValidAudioMode(in_mode)) {
LOG(ERROR) << __func__ << ": invalid mode " << toString(in_mode);
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
// No checks for supported audio modes here, it's an informative notification.
LOG(DEBUG) << __func__ << ": " << toString(in_mode);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::updateScreenRotation(ScreenRotation in_rotation) {
LOG(DEBUG) << __func__ << ": " << toString(in_rotation);
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::updateScreenState(bool in_isTurnedOn) {
LOG(DEBUG) << __func__ << ": " << in_isTurnedOn;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getSoundDose(std::shared_ptr<ISoundDose>* _aidl_return) {
if (!mSoundDose) {
mSoundDose = ndk::SharedRefBase::make<sounddose::SoundDose>();
}
*_aidl_return = mSoundDose.getInstance();
LOG(DEBUG) << __func__ << ": returning instance of ISoundDose: " << _aidl_return->get();
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::generateHwAvSyncId(int32_t* _aidl_return) {
LOG(DEBUG) << __func__;
(void)_aidl_return;
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
const std::string Module::VendorDebug::kForceTransientBurstName = "aosp.forceTransientBurst";
const std::string Module::VendorDebug::kForceSynchronousDrainName = "aosp.forceSynchronousDrain";
ndk::ScopedAStatus Module::getVendorParameters(const std::vector<std::string>& in_ids,
std::vector<VendorParameter>* _aidl_return) {
LOG(DEBUG) << __func__ << ": id count: " << in_ids.size();
bool allParametersKnown = true;
for (const auto& id : in_ids) {
if (id == VendorDebug::kForceTransientBurstName) {
VendorParameter forceTransientBurst{.id = id};
forceTransientBurst.ext.setParcelable(Boolean{mVendorDebug.forceTransientBurst});
_aidl_return->push_back(std::move(forceTransientBurst));
} else if (id == VendorDebug::kForceSynchronousDrainName) {
VendorParameter forceSynchronousDrain{.id = id};
forceSynchronousDrain.ext.setParcelable(Boolean{mVendorDebug.forceSynchronousDrain});
_aidl_return->push_back(std::move(forceSynchronousDrain));
} else {
allParametersKnown = false;
LOG(ERROR) << __func__ << ": unrecognized parameter \"" << id << "\"";
}
}
if (allParametersKnown) return ndk::ScopedAStatus::ok();
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
namespace {
template <typename W>
bool extractParameter(const VendorParameter& p, decltype(W::value)* v) {
std::optional<W> value;
binder_status_t result = p.ext.getParcelable(&value);
if (result == STATUS_OK && value.has_value()) {
*v = value.value().value;
return true;
}
LOG(ERROR) << __func__ << ": failed to read the value of the parameter \"" << p.id
<< "\": " << result;
return false;
}
} // namespace
ndk::ScopedAStatus Module::setVendorParameters(const std::vector<VendorParameter>& in_parameters,
bool in_async) {
LOG(DEBUG) << __func__ << ": parameter count " << in_parameters.size()
<< ", async: " << in_async;
bool allParametersKnown = true;
for (const auto& p : in_parameters) {
if (p.id == VendorDebug::kForceTransientBurstName) {
if (!extractParameter<Boolean>(p, &mVendorDebug.forceTransientBurst)) {
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
} else if (p.id == VendorDebug::kForceSynchronousDrainName) {
if (!extractParameter<Boolean>(p, &mVendorDebug.forceSynchronousDrain)) {
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
} else {
allParametersKnown = false;
LOG(ERROR) << __func__ << ": unrecognized parameter \"" << p.id << "\"";
}
}
if (allParametersKnown) return ndk::ScopedAStatus::ok();
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
ndk::ScopedAStatus Module::addDeviceEffect(
int32_t in_portConfigId,
const std::shared_ptr<::aidl::android::hardware::audio::effect::IEffect>& in_effect) {
if (in_effect == nullptr) {
LOG(DEBUG) << __func__ << ": port id " << in_portConfigId << ", null effect";
} else {
LOG(DEBUG) << __func__ << ": port id " << in_portConfigId << ", effect Binder "
<< in_effect->asBinder().get();
}
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
ndk::ScopedAStatus Module::removeDeviceEffect(
int32_t in_portConfigId,
const std::shared_ptr<::aidl::android::hardware::audio::effect::IEffect>& in_effect) {
if (in_effect == nullptr) {
LOG(DEBUG) << __func__ << ": port id " << in_portConfigId << ", null effect";
} else {
LOG(DEBUG) << __func__ << ": port id " << in_portConfigId << ", effect Binder "
<< in_effect->asBinder().get();
}
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
ndk::ScopedAStatus Module::getMmapPolicyInfos(AudioMMapPolicyType mmapPolicyType,
std::vector<AudioMMapPolicyInfo>* _aidl_return) {
LOG(DEBUG) << __func__ << ": mmap policy type " << toString(mmapPolicyType);
std::set<int32_t> mmapSinks;
std::set<int32_t> mmapSources;
auto& ports = getConfig().ports;
for (const auto& port : ports) {
if (port.flags.getTag() == AudioIoFlags::Tag::input &&
isBitPositionFlagSet(port.flags.get<AudioIoFlags::Tag::input>(),
AudioInputFlags::MMAP_NOIRQ)) {
mmapSinks.insert(port.id);
} else if (port.flags.getTag() == AudioIoFlags::Tag::output &&
isBitPositionFlagSet(port.flags.get<AudioIoFlags::Tag::output>(),
AudioOutputFlags::MMAP_NOIRQ)) {
mmapSources.insert(port.id);
}
}
if (mmapSources.empty() && mmapSinks.empty()) {
AudioMMapPolicyInfo never;
never.mmapPolicy = AudioMMapPolicy::NEVER;
_aidl_return->push_back(never);
return ndk::ScopedAStatus::ok();
}
for (const auto& route : getConfig().routes) {
if (mmapSinks.count(route.sinkPortId) != 0) {
// The sink is a mix port, add the sources if they are device ports.
for (int sourcePortId : route.sourcePortIds) {
auto sourcePortIt = findById<AudioPort>(ports, sourcePortId);
if (sourcePortIt == ports.end()) {
// This must not happen
LOG(ERROR) << __func__ << ": port id " << sourcePortId << " cannot be found";
continue;
}
if (sourcePortIt->ext.getTag() != AudioPortExt::Tag::device) {
// The source is not a device port, skip
continue;
}
AudioMMapPolicyInfo policyInfo;
policyInfo.device = sourcePortIt->ext.get<AudioPortExt::Tag::device>().device;
// Always return AudioMMapPolicy.AUTO if the device supports mmap for
// default implementation.
policyInfo.mmapPolicy = AudioMMapPolicy::AUTO;
_aidl_return->push_back(policyInfo);
}
} else {
auto sinkPortIt = findById<AudioPort>(ports, route.sinkPortId);
if (sinkPortIt == ports.end()) {
// This must not happen
LOG(ERROR) << __func__ << ": port id " << route.sinkPortId << " cannot be found";
continue;
}
if (sinkPortIt->ext.getTag() != AudioPortExt::Tag::device) {
// The sink is not a device port, skip
continue;
}
if (count_any(mmapSources, route.sourcePortIds)) {
AudioMMapPolicyInfo policyInfo;
policyInfo.device = sinkPortIt->ext.get<AudioPortExt::Tag::device>().device;
// Always return AudioMMapPolicy.AUTO if the device supports mmap for
// default implementation.
policyInfo.mmapPolicy = AudioMMapPolicy::AUTO;
_aidl_return->push_back(policyInfo);
}
}
}
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::supportsVariableLatency(bool* _aidl_return) {
LOG(DEBUG) << __func__;
*_aidl_return = false;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAAudioMixerBurstCount(int32_t* _aidl_return) {
if (!isMmapSupported()) {
LOG(DEBUG) << __func__ << ": mmap is not supported ";
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
*_aidl_return = DEFAULT_AAUDIO_MIXER_BURST_COUNT;
LOG(DEBUG) << __func__ << ": returning " << *_aidl_return;
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::getAAudioHardwareBurstMinUsec(int32_t* _aidl_return) {
if (!isMmapSupported()) {
LOG(DEBUG) << __func__ << ": mmap is not supported ";
return ndk::ScopedAStatus::fromExceptionCode(EX_UNSUPPORTED_OPERATION);
}
*_aidl_return = DEFAULT_AAUDIO_HARDWARE_BURST_MIN_DURATION_US;
LOG(DEBUG) << __func__ << ": returning " << *_aidl_return;
return ndk::ScopedAStatus::ok();
}
bool Module::isMmapSupported() {
if (mIsMmapSupported.has_value()) {
return mIsMmapSupported.value();
}
std::vector<AudioMMapPolicyInfo> mmapPolicyInfos;
if (!getMmapPolicyInfos(AudioMMapPolicyType::DEFAULT, &mmapPolicyInfos).isOk()) {
mIsMmapSupported = false;
} else {
mIsMmapSupported =
std::find_if(mmapPolicyInfos.begin(), mmapPolicyInfos.end(), [](const auto& info) {
return info.mmapPolicy == AudioMMapPolicy::AUTO ||
info.mmapPolicy == AudioMMapPolicy::ALWAYS;
}) != mmapPolicyInfos.end();
}
return mIsMmapSupported.value();
}
ndk::ScopedAStatus Module::populateConnectedDevicePort(AudioPort* audioPort, int32_t) {
if (audioPort->ext.getTag() != AudioPortExt::device) {
LOG(ERROR) << __func__ << ": not a device port: " << audioPort->toString();
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_ARGUMENT);
}
const auto& devicePort = audioPort->ext.get<AudioPortExt::device>();
if (!devicePort.device.type.connection.empty()) {
LOG(ERROR) << __func__
<< ": module implementation must override 'populateConnectedDevicePort' "
<< "to handle connection of external devices.";
return ndk::ScopedAStatus::fromExceptionCode(EX_ILLEGAL_STATE);
}
LOG(VERBOSE) << __func__ << ": do nothing and return ok";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::checkAudioPatchEndpointsMatch(
const std::vector<AudioPortConfig*>& sources __unused,
const std::vector<AudioPortConfig*>& sinks __unused) {
LOG(VERBOSE) << __func__ << ": do nothing and return ok";
return ndk::ScopedAStatus::ok();
}
void Module::onExternalDeviceConnectionChanged(
const ::aidl::android::media::audio::common::AudioPort& audioPort __unused,
bool connected __unused) {
LOG(DEBUG) << __func__ << ": do nothing and return";
}
void Module::onPrepareToDisconnectExternalDevice(
const ::aidl::android::media::audio::common::AudioPort& audioPort __unused) {
LOG(DEBUG) << __func__ << ": do nothing and return";
}
ndk::ScopedAStatus Module::onMasterMuteChanged(bool mute __unused) {
LOG(VERBOSE) << __func__ << ": do nothing and return ok";
return ndk::ScopedAStatus::ok();
}
ndk::ScopedAStatus Module::onMasterVolumeChanged(float volume __unused) {
LOG(VERBOSE) << __func__ << ": do nothing and return ok";
return ndk::ScopedAStatus::ok();
}
std::vector<MicrophoneInfo> Module::getMicrophoneInfos() {
std::vector<MicrophoneInfo> result;
Configuration& config = getConfig();
for (const AudioPort& port : config.ports) {
if (port.ext.getTag() == AudioPortExt::Tag::device) {
const AudioDeviceType deviceType =
port.ext.get<AudioPortExt::Tag::device>().device.type.type;
if (deviceType == AudioDeviceType::IN_MICROPHONE ||
deviceType == AudioDeviceType::IN_MICROPHONE_BACK) {
// Placeholder values. Vendor implementations must populate MicrophoneInfo
// accordingly based on their physical microphone parameters.
result.push_back(MicrophoneInfo{
.id = port.name,
.device = port.ext.get<AudioPortExt::Tag::device>().device,
.group = 0,
.indexInTheGroup = 0,
});
}
}
}
return result;
}
ndk::ScopedAStatus Module::bluetoothParametersUpdated() {
return mStreams.bluetoothParametersUpdated();
}
} // namespace aidl::android::hardware::audio::core