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/*
* Copyright (C) 2009 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 "utils/Errors.h"
#define LOG_TAG "APM_AudioPolicyManager"
// Need to keep the log statements even in production builds
// to enable VERBOSE logging dynamically.
// You can enable VERBOSE logging as follows:
// adb shell setprop log.tag.APM_AudioPolicyManager V
#define LOG_NDEBUG 0
//#define VERY_VERBOSE_LOGGING
#ifdef VERY_VERBOSE_LOGGING
#define ALOGVV ALOGV
#else
#define ALOGVV(a...) do { } while(0)
#endif
#include <algorithm>
#include <inttypes.h>
#include <map>
#include <math.h>
#include <set>
#include <type_traits>
#include <unordered_set>
#include <vector>
#include <Serializer.h>
#include <android/media/audio/common/AudioPort.h>
#include <com_android_media_audio.h>
#include <android_media_audiopolicy.h>
#include <com_android_media_audioserver.h>
#include <cutils/bitops.h>
#include <cutils/properties.h>
#include <media/AudioParameter.h>
#include <policy.h>
#include <private/android_filesystem_config.h>
#include <system/audio.h>
#include <system/audio_config.h>
#include <system/audio_effects/effect_hapticgenerator.h>
#include <utils/Log.h>
#include "AudioPolicyManager.h"
#include "TypeConverter.h"
namespace android {
namespace audio_flags = android::media::audiopolicy;
using android::media::audio::common::AudioDevice;
using android::media::audio::common::AudioDeviceAddress;
using android::media::audio::common::AudioPortDeviceExt;
using android::media::audio::common::AudioPortExt;
using content::AttributionSourceState;
//FIXME: workaround for truncated touch sounds
// to be removed when the problem is handled by system UI
#define TOUCH_SOUND_FIXED_DELAY_MS 100
// Largest difference in dB on earpiece in call between the voice volume and another
// media / notification / system volume.
constexpr float IN_CALL_EARPIECE_HEADROOM_DB = 3.f;
template <typename T>
bool operator== (const SortedVector<T> &left, const SortedVector<T> &right)
{
if (left.size() != right.size()) {
return false;
}
for (size_t index = 0; index < right.size(); index++) {
if (left[index] != right[index]) {
return false;
}
}
return true;
}
template <typename T>
bool operator!= (const SortedVector<T> &left, const SortedVector<T> &right)
{
return !(left == right);
}
// ----------------------------------------------------------------------------
// AudioPolicyInterface implementation
// ----------------------------------------------------------------------------
status_t AudioPolicyManager::setDeviceConnectionState(audio_policy_dev_state_t state,
const android::media::audio::common::AudioPort& port, audio_format_t encodedFormat) {
status_t status = setDeviceConnectionStateInt(state, port, encodedFormat);
nextAudioPortGeneration();
return status;
}
status_t AudioPolicyManager::setDeviceConnectionState(audio_devices_t device,
audio_policy_dev_state_t state,
const char* device_address,
const char* device_name,
audio_format_t encodedFormat) {
media::AudioPortFw aidlPort;
if (status_t status = deviceToAudioPort(device, device_address, device_name, &aidlPort);
status == OK) {
return setDeviceConnectionState(state, aidlPort.hal, encodedFormat);
} else {
ALOGE("Failed to convert to AudioPort Parcelable: %s", statusToString(status).c_str());
return status;
}
}
void AudioPolicyManager::broadcastDeviceConnectionState(const sp<DeviceDescriptor> &device,
media::DeviceConnectedState state)
{
audio_port_v7 devicePort;
device->toAudioPort(&devicePort);
if (status_t status = mpClientInterface->setDeviceConnectedState(&devicePort, state);
status != OK) {
ALOGE("Error %d while setting connected state for device %s",
static_cast<int>(state),
device->getDeviceTypeAddr().toString(false).c_str());
}
}
status_t AudioPolicyManager::setDeviceConnectionStateInt(
audio_policy_dev_state_t state, const android::media::audio::common::AudioPort& port,
audio_format_t encodedFormat) {
if (port.ext.getTag() != AudioPortExt::device) {
return BAD_VALUE;
}
audio_devices_t device_type;
std::string device_address;
if (status_t status = aidl2legacy_AudioDevice_audio_device(
port.ext.get<AudioPortExt::device>().device, &device_type, &device_address);
status != OK) {
return status;
};
const char* device_name = port.name.c_str();
// connect/disconnect only 1 device at a time
if (!audio_is_output_device(device_type) && !audio_is_input_device(device_type))
return BAD_VALUE;
sp<DeviceDescriptor> device = mHwModules.getDeviceDescriptor(
device_type, device_address.c_str(), device_name, encodedFormat,
state == AUDIO_POLICY_DEVICE_STATE_AVAILABLE);
if (device == nullptr) {
return INVALID_OPERATION;
}
if (state == AUDIO_POLICY_DEVICE_STATE_AVAILABLE) {
device->setExtraAudioDescriptors(port.extraAudioDescriptors);
}
return setDeviceConnectionStateInt(device, state);
}
status_t AudioPolicyManager::setDeviceConnectionStateInt(audio_devices_t deviceType,
audio_policy_dev_state_t state,
const char* device_address,
const char* device_name,
audio_format_t encodedFormat) {
media::AudioPortFw aidlPort;
if (status_t status = deviceToAudioPort(deviceType, device_address, device_name, &aidlPort);
status == OK) {
return setDeviceConnectionStateInt(state, aidlPort.hal, encodedFormat);
} else {
ALOGE("Failed to convert to AudioPort Parcelable: %s", statusToString(status).c_str());
return status;
}
}
status_t AudioPolicyManager::setDeviceConnectionStateInt(const sp<DeviceDescriptor> &device,
audio_policy_dev_state_t state)
{
// handle output devices
if (audio_is_output_device(device->type())) {
SortedVector <audio_io_handle_t> outputs;
ssize_t index = mAvailableOutputDevices.indexOf(device);
// save a copy of the opened output descriptors before any output is opened or closed
// by checkOutputsForDevice(). This will be needed by checkOutputForAllStrategies()
mPreviousOutputs = mOutputs;
bool wasLeUnicastActive = isLeUnicastActive();
switch (state)
{
// handle output device connection
case AUDIO_POLICY_DEVICE_STATE_AVAILABLE: {
if (index >= 0) {
ALOGW("%s() device already connected: %s", __func__, device->toString().c_str());
return INVALID_OPERATION;
}
ALOGV("%s() connecting device %s format %x",
__func__, device->toString().c_str(), device->getEncodedFormat());
// register new device as available
if (mAvailableOutputDevices.add(device) < 0) {
return NO_MEMORY;
}
// Before checking outputs, broadcast connect event to allow HAL to retrieve dynamic
// parameters on newly connected devices (instead of opening the outputs...)
broadcastDeviceConnectionState(device, media::DeviceConnectedState::CONNECTED);
if (checkOutputsForDevice(device, state, outputs) != NO_ERROR) {
mAvailableOutputDevices.remove(device);
mHwModules.cleanUpForDevice(device);
broadcastDeviceConnectionState(device, media::DeviceConnectedState::DISCONNECTED);
return INVALID_OPERATION;
}
// Populate encapsulation information when a output device is connected.
device->setEncapsulationInfoFromHal(mpClientInterface);
// outputs should never be empty here
ALOG_ASSERT(outputs.size() != 0, "setDeviceConnectionState():"
"checkOutputsForDevice() returned no outputs but status OK");
ALOGV("%s() checkOutputsForDevice() returned %zu outputs", __func__, outputs.size());
} break;
// handle output device disconnection
case AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE: {
if (index < 0) {
ALOGW("%s() device not connected: %s", __func__, device->toString().c_str());
return INVALID_OPERATION;
}
ALOGV("%s() disconnecting output device %s", __func__, device->toString().c_str());
// Notify the HAL to prepare to disconnect device
broadcastDeviceConnectionState(
device, media::DeviceConnectedState::PREPARE_TO_DISCONNECT);
// remove device from available output devices
mAvailableOutputDevices.remove(device);
mOutputs.clearSessionRoutesForDevice(device);
checkOutputsForDevice(device, state, outputs);
// Send Disconnect to HALs
broadcastDeviceConnectionState(device, media::DeviceConnectedState::DISCONNECTED);
// Reset active device codec
device->setEncodedFormat(AUDIO_FORMAT_DEFAULT);
// remove device from mReportedFormatsMap cache
mReportedFormatsMap.erase(device);
// remove preferred mixer configurations
mPreferredMixerAttrInfos.erase(device->getId());
} break;
default:
ALOGE("%s() invalid state: %x", __func__, state);
return BAD_VALUE;
}
// Propagate device availability to Engine
setEngineDeviceConnectionState(device, state);
// No need to evaluate playback routing when connecting a remote submix
// output device used by a dynamic policy of type recorder as no
// playback use case is affected.
bool doCheckForDeviceAndOutputChanges = true;
if (device->type() == AUDIO_DEVICE_OUT_REMOTE_SUBMIX && device->address() != "0") {
for (audio_io_handle_t output : outputs) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueFor(output);
sp<AudioPolicyMix> policyMix = desc->mPolicyMix.promote();
if (policyMix != nullptr
&& policyMix->mMixType == MIX_TYPE_RECORDERS
&& device->address() == policyMix->mDeviceAddress.c_str()) {
doCheckForDeviceAndOutputChanges = false;
break;
}
}
}
auto checkCloseOutputs = [&]() {
// outputs must be closed after checkOutputForAllStrategies() is executed
if (!outputs.isEmpty()) {
for (audio_io_handle_t output : outputs) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueFor(output);
// close unused outputs after device disconnection or direct outputs that have
// been opened by checkOutputsForDevice() to query dynamic parameters
// "outputs" vector never contains duplicated outputs
if ((state == AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE)
|| (((desc->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) != 0) &&
(desc->mDirectOpenCount == 0))
|| (((desc->mFlags & AUDIO_OUTPUT_FLAG_SPATIALIZER) != 0) &&
!isOutputOnlyAvailableRouteToSomeDevice(desc))) {
clearAudioSourcesForOutput(output);
closeOutput(output);
}
}
// check A2DP again after closing A2DP output to reset mA2dpSuspended if needed
return true;
}
return false;
};
if (doCheckForDeviceAndOutputChanges) {
checkForDeviceAndOutputChanges(checkCloseOutputs);
} else {
checkCloseOutputs();
}
(void)updateCallRouting(false /*fromCache*/);
const DeviceVector msdOutDevices = getMsdAudioOutDevices();
const DeviceVector activeMediaDevices =
mEngine->getActiveMediaDevices(mAvailableOutputDevices);
std::map<audio_io_handle_t, DeviceVector> outputsToReopenWithDevices;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc->isActive() && ((mEngine->getPhoneState() != AUDIO_MODE_IN_CALL) ||
(desc != mPrimaryOutput))) {
DeviceVector newDevices = getNewOutputDevices(desc, true /*fromCache*/);
// do not force device change on duplicated output because if device is 0, it will
// also force a device 0 for the two outputs it is duplicated to which may override
// a valid device selection on those outputs.
bool force = (msdOutDevices.isEmpty() || msdOutDevices != desc->devices())
&& !desc->isDuplicated()
&& (!device_distinguishes_on_address(device->type())
// always force when disconnecting (a non-duplicated device)
|| (state == AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE));
if (desc->mUsePreferredMixerAttributes && newDevices != desc->devices()) {
// If the device is using preferred mixer attributes, the output need to reopen
// with default configuration when the new selected devices are different from
// current routing devices
outputsToReopenWithDevices.emplace(mOutputs.keyAt(i), newDevices);
continue;
}
setOutputDevices(__func__, desc, newDevices, force, 0);
}
if (!desc->isDuplicated() && desc->mProfile->hasDynamicAudioProfile() &&
!activeMediaDevices.empty() && desc->devices() != activeMediaDevices &&
desc->supportsDevicesForPlayback(activeMediaDevices)) {
// Reopen the output to query the dynamic profiles when there is not active
// clients or all active clients will be rerouted. Otherwise, set the flag
// `mPendingReopenToQueryProfiles` in the SwOutputDescriptor so that the output
// can be reopened to query dynamic profiles when all clients are inactive.
if (areAllActiveTracksRerouted(desc)) {
outputsToReopenWithDevices.emplace(mOutputs.keyAt(i), activeMediaDevices);
} else {
desc->mPendingReopenToQueryProfiles = true;
}
}
if (!desc->supportsDevicesForPlayback(activeMediaDevices)) {
// Clear the flag that previously set for re-querying profiles.
desc->mPendingReopenToQueryProfiles = false;
}
}
reopenOutputsWithDevices(outputsToReopenWithDevices);
if (state == AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE) {
cleanUpForDevice(device);
}
checkLeBroadcastRoutes(wasLeUnicastActive, nullptr, 0);
mpClientInterface->onAudioPortListUpdate();
return NO_ERROR;
} // end if is output device
// handle input devices
if (audio_is_input_device(device->type())) {
ssize_t index = mAvailableInputDevices.indexOf(device);
switch (state)
{
// handle input device connection
case AUDIO_POLICY_DEVICE_STATE_AVAILABLE: {
if (index >= 0) {
ALOGW("%s() device already connected: %s", __func__, device->toString().c_str());
return INVALID_OPERATION;
}
if (mAvailableInputDevices.add(device) < 0) {
return NO_MEMORY;
}
// Before checking intputs, broadcast connect event to allow HAL to retrieve dynamic
// parameters on newly connected devices (instead of opening the inputs...)
broadcastDeviceConnectionState(device, media::DeviceConnectedState::CONNECTED);
if (checkInputsForDevice(device, state) != NO_ERROR) {
mAvailableInputDevices.remove(device);
broadcastDeviceConnectionState(device, media::DeviceConnectedState::DISCONNECTED);
mHwModules.cleanUpForDevice(device);
return INVALID_OPERATION;
}
} break;
// handle input device disconnection
case AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE: {
if (index < 0) {
ALOGW("%s() device not connected: %s", __func__, device->toString().c_str());
return INVALID_OPERATION;
}
ALOGV("%s() disconnecting input device %s", __func__, device->toString().c_str());
// Notify the HAL to prepare to disconnect device
broadcastDeviceConnectionState(
device, media::DeviceConnectedState::PREPARE_TO_DISCONNECT);
mAvailableInputDevices.remove(device);
checkInputsForDevice(device, state);
// Set Disconnect to HALs
broadcastDeviceConnectionState(device, media::DeviceConnectedState::DISCONNECTED);
// remove device from mReportedFormatsMap cache
mReportedFormatsMap.erase(device);
} break;
default:
ALOGE("%s() invalid state: %x", __func__, state);
return BAD_VALUE;
}
// Propagate device availability to Engine
setEngineDeviceConnectionState(device, state);
checkCloseInputs();
// As the input device list can impact the output device selection, update
// getDeviceForStrategy() cache
updateDevicesAndOutputs();
(void)updateCallRouting(false /*fromCache*/);
// Reconnect Audio Source
for (const auto &strategy : mEngine->getOrderedProductStrategies()) {
auto attributes = mEngine->getAllAttributesForProductStrategy(strategy).front();
checkAudioSourceForAttributes(attributes);
}
if (state == AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE) {
cleanUpForDevice(device);
}
mpClientInterface->onAudioPortListUpdate();
return NO_ERROR;
} // end if is input device
ALOGW("%s() invalid device: %s", __func__, device->toString().c_str());
return BAD_VALUE;
}
status_t AudioPolicyManager::deviceToAudioPort(audio_devices_t device, const char* device_address,
const char* device_name,
media::AudioPortFw* aidlPort) {
const auto devDescr = sp<DeviceDescriptorBase>::make(device, device_address);
devDescr->setName(device_name);
return devDescr->writeToParcelable(aidlPort);
}
void AudioPolicyManager::setEngineDeviceConnectionState(const sp<DeviceDescriptor> device,
audio_policy_dev_state_t state) {
// the Engine does not have to know about remote submix devices used by dynamic audio policies
if (audio_is_remote_submix_device(device->type()) && device->address() != "0") {
return;
}
mEngine->setDeviceConnectionState(device, state);
}
audio_policy_dev_state_t AudioPolicyManager::getDeviceConnectionState(audio_devices_t device,
const char *device_address)
{
sp<DeviceDescriptor> devDesc =
mHwModules.getDeviceDescriptor(device, device_address, "", AUDIO_FORMAT_DEFAULT,
false /* allowToCreate */,
(strlen(device_address) != 0)/*matchAddress*/);
if (devDesc == 0) {
ALOGV("getDeviceConnectionState() undeclared device, type %08x, address: %s",
device, device_address);
return AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE;
}
DeviceVector *deviceVector;
if (audio_is_output_device(device)) {
deviceVector = &mAvailableOutputDevices;
} else if (audio_is_input_device(device)) {
deviceVector = &mAvailableInputDevices;
} else {
ALOGW("%s() invalid device type %08x", __func__, device);
return AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE;
}
return (deviceVector->getDevice(
device, String8(device_address), AUDIO_FORMAT_DEFAULT) != 0) ?
AUDIO_POLICY_DEVICE_STATE_AVAILABLE : AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE;
}
status_t AudioPolicyManager::handleDeviceConfigChange(audio_devices_t device,
const char *device_address,
const char *device_name,
audio_format_t encodedFormat)
{
ALOGV("handleDeviceConfigChange(() device: 0x%X, address %s name %s encodedFormat: 0x%X",
device, device_address, device_name, encodedFormat);
// connect/disconnect only 1 device at a time
if (!audio_is_output_device(device) && !audio_is_input_device(device)) return BAD_VALUE;
// Check if the device is currently connected
DeviceVector deviceList = mAvailableOutputDevices.getDevicesFromType(device);
if (deviceList.empty()) {
// Nothing to do: device is not connected
return NO_ERROR;
}
sp<DeviceDescriptor> devDesc = deviceList.itemAt(0);
// For offloaded A2DP, Hw modules may have the capability to
// configure codecs.
// Handle two specific cases by sending a set parameter to
// configure A2DP codecs. No need to toggle device state.
// Case 1: A2DP active device switches from primary to primary
// module
// Case 2: A2DP device config changes on primary module.
if (device_has_encoding_capability(device) && hasPrimaryOutput()) {
sp<HwModule> module = mHwModules.getModuleForDeviceType(device, encodedFormat);
audio_module_handle_t primaryHandle = mPrimaryOutput->getModuleHandle();
if (availablePrimaryOutputDevices().contains(devDesc) &&
(module != 0 && module->getHandle() == primaryHandle)) {
bool isA2dp = audio_is_a2dp_out_device(device);
const String8 supportKey = isA2dp ? String8(AudioParameter::keyReconfigA2dpSupported)
: String8(AudioParameter::keyReconfigLeSupported);
String8 reply = mpClientInterface->getParameters(AUDIO_IO_HANDLE_NONE, supportKey);
AudioParameter repliedParameters(reply);
int isReconfigSupported;
repliedParameters.getInt(supportKey, isReconfigSupported);
if (isReconfigSupported) {
const String8 key = isA2dp ? String8(AudioParameter::keyReconfigA2dp)
: String8(AudioParameter::keyReconfigLe);
AudioParameter param;
param.add(key, String8("true"));
mpClientInterface->setParameters(AUDIO_IO_HANDLE_NONE, param.toString());
devDesc->setEncodedFormat(encodedFormat);
return NO_ERROR;
}
}
}
auto musicStrategy = streamToStrategy(AUDIO_STREAM_MUSIC);
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
// mute media strategies and delay device switch by the largest
// This avoid sending the music tail into the earpiece or headset.
setStrategyMute(musicStrategy, true, desc);
setStrategyMute(musicStrategy, false, desc, MUTE_TIME_MS,
mEngine->getOutputDevicesForAttributes(attributes_initializer(AUDIO_USAGE_MEDIA),
nullptr, true /*fromCache*/).types());
}
// Toggle the device state: UNAVAILABLE -> AVAILABLE
// This will force reading again the device configuration
status_t status = setDeviceConnectionState(device,
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
device_address, device_name,
devDesc->getEncodedFormat());
if (status != NO_ERROR) {
ALOGW("handleDeviceConfigChange() error disabling connection state: %d",
status);
return status;
}
status = setDeviceConnectionState(device,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
device_address, device_name, encodedFormat);
if (status != NO_ERROR) {
ALOGW("handleDeviceConfigChange() error enabling connection state: %d",
status);
return status;
}
return NO_ERROR;
}
status_t AudioPolicyManager::getHwOffloadFormatsSupportedForBluetoothMedia(
audio_devices_t device, std::vector<audio_format_t> *formats)
{
ALOGV("getHwOffloadFormatsSupportedForBluetoothMedia()");
status_t status = NO_ERROR;
std::unordered_set<audio_format_t> formatSet;
sp<HwModule> primaryModule =
mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_PRIMARY);
if (primaryModule == nullptr) {
ALOGE("%s() unable to get primary module", __func__);
return NO_INIT;
}
DeviceTypeSet audioDeviceSet;
switch(device) {
case AUDIO_DEVICE_OUT_BLUETOOTH_A2DP:
audioDeviceSet = getAudioDeviceOutAllA2dpSet();
break;
case AUDIO_DEVICE_OUT_BLE_HEADSET:
audioDeviceSet = getAudioDeviceOutLeAudioUnicastSet();
break;
case AUDIO_DEVICE_OUT_BLE_BROADCAST:
audioDeviceSet = getAudioDeviceOutLeAudioBroadcastSet();
break;
default:
ALOGE("%s() device type 0x%08x not supported", __func__, device);
return BAD_VALUE;
}
DeviceVector declaredDevices = primaryModule->getDeclaredDevices().getDevicesFromTypes(
audioDeviceSet);
for (const auto& device : declaredDevices) {
formatSet.insert(device->encodedFormats().begin(), device->encodedFormats().end());
}
formats->assign(formatSet.begin(), formatSet.end());
return status;
}
DeviceVector AudioPolicyManager::selectBestRxSinkDevicesForCall(bool fromCache)
{
DeviceVector rxSinkdevices{};
rxSinkdevices = mEngine->getOutputDevicesForAttributes(
attributes_initializer(AUDIO_USAGE_VOICE_COMMUNICATION), nullptr, fromCache);
if (!rxSinkdevices.isEmpty() && mAvailableOutputDevices.contains(rxSinkdevices.itemAt(0))) {
auto rxSinkDevice = rxSinkdevices.itemAt(0);
auto telephonyRxModule = mHwModules.getModuleForDeviceType(
AUDIO_DEVICE_IN_TELEPHONY_RX, AUDIO_FORMAT_DEFAULT);
// retrieve Rx Source device descriptor
sp<DeviceDescriptor> rxSourceDevice = mAvailableInputDevices.getDevice(
AUDIO_DEVICE_IN_TELEPHONY_RX, String8(), AUDIO_FORMAT_DEFAULT);
// RX Telephony and Rx sink devices are declared by Primary Audio HAL
if (isPrimaryModule(telephonyRxModule) && (telephonyRxModule->getHalVersionMajor() >= 3) &&
telephonyRxModule->supportsPatch(rxSourceDevice, rxSinkDevice)) {
ALOGW("%s() device %s using HW Bridge", __func__, rxSinkDevice->toString().c_str());
return DeviceVector(rxSinkDevice);
}
}
// Note that despite the fact that getNewOutputDevices() is called on the primary output,
// the device returned is not necessarily reachable via this output
// (filter later by setOutputDevices())
return getNewOutputDevices(mPrimaryOutput, fromCache);
}
status_t AudioPolicyManager::updateCallRouting(bool fromCache, uint32_t delayMs, uint32_t *waitMs)
{
if (mEngine->getPhoneState() == AUDIO_MODE_IN_CALL) {
DeviceVector rxDevices = selectBestRxSinkDevicesForCall(fromCache);
return updateCallRoutingInternal(rxDevices, delayMs, waitMs);
}
return INVALID_OPERATION;
}
status_t AudioPolicyManager::updateCallRoutingInternal(
const DeviceVector &rxDevices, uint32_t delayMs, uint32_t *waitMs)
{
bool createTxPatch = false;
bool createRxPatch = false;
uint32_t muteWaitMs = 0;
if (hasPrimaryOutput() &&
mPrimaryOutput->devices().onlyContainsDevicesWithType(AUDIO_DEVICE_OUT_STUB)) {
return INVALID_OPERATION;
}
audio_attributes_t attr = { .source = AUDIO_SOURCE_VOICE_COMMUNICATION };
auto txSourceDevice = mEngine->getInputDeviceForAttributes(attr);
disconnectTelephonyAudioSource(mCallRxSourceClient);
disconnectTelephonyAudioSource(mCallTxSourceClient);
if (rxDevices.isEmpty()) {
ALOGW("%s() no selected output device", __func__);
return INVALID_OPERATION;
}
if (txSourceDevice == nullptr) {
ALOGE("%s() selected input device not available", __func__);
return INVALID_OPERATION;
}
ALOGV("%s device rxDevice %s txDevice %s", __func__,
rxDevices.itemAt(0)->toString().c_str(), txSourceDevice->toString().c_str());
auto telephonyRxModule =
mHwModules.getModuleForDeviceType(AUDIO_DEVICE_IN_TELEPHONY_RX, AUDIO_FORMAT_DEFAULT);
auto telephonyTxModule =
mHwModules.getModuleForDeviceType(AUDIO_DEVICE_OUT_TELEPHONY_TX, AUDIO_FORMAT_DEFAULT);
// retrieve Rx Source and Tx Sink device descriptors
sp<DeviceDescriptor> rxSourceDevice =
mAvailableInputDevices.getDevice(AUDIO_DEVICE_IN_TELEPHONY_RX,
String8(),
AUDIO_FORMAT_DEFAULT);
sp<DeviceDescriptor> txSinkDevice =
mAvailableOutputDevices.getDevice(AUDIO_DEVICE_OUT_TELEPHONY_TX,
String8(),
AUDIO_FORMAT_DEFAULT);
// RX and TX Telephony device are declared by Primary Audio HAL
if (isPrimaryModule(telephonyRxModule) && isPrimaryModule(telephonyTxModule) &&
(telephonyRxModule->getHalVersionMajor() >= 3)) {
if (rxSourceDevice == 0 || txSinkDevice == 0) {
// RX / TX Telephony device(s) is(are) not currently available
ALOGE("%s() no telephony Tx and/or RX device", __func__);
return INVALID_OPERATION;
}
// createAudioPatchInternal now supports both HW / SW bridging
createRxPatch = true;
createTxPatch = true;
} else {
// If the RX device is on the primary HW module, then use legacy routing method for
// voice calls via setOutputDevice() on primary output.
// Otherwise, create two audio patches for TX and RX path.
createRxPatch = !(availablePrimaryOutputDevices().contains(rxDevices.itemAt(0))) &&
(rxSourceDevice != 0);
// If the TX device is also on the primary HW module, setOutputDevice() will take care
// of it due to legacy implementation. If not, create a patch.
createTxPatch = !(availablePrimaryModuleInputDevices().contains(txSourceDevice)) &&
(txSinkDevice != 0);
}
// Use legacy routing method for voice calls via setOutputDevice() on primary output.
// Otherwise, create two audio patches for TX and RX path.
if (!createRxPatch) {
if (!hasPrimaryOutput()) {
ALOGW("%s() no primary output available", __func__);
return INVALID_OPERATION;
}
muteWaitMs = setOutputDevices(__func__, mPrimaryOutput, rxDevices, true, delayMs);
} else { // create RX path audio patch
connectTelephonyRxAudioSource();
// If the TX device is on the primary HW module but RX device is
// on other HW module, SinkMetaData of telephony input should handle it
// assuming the device uses audio HAL V5.0 and above
}
if (createTxPatch) { // create TX path audio patch
// terminate active capture if on the same HW module as the call TX source device
// FIXME: would be better to refine to only inputs whose profile connects to the
// call TX device but this information is not in the audio patch and logic here must be
// symmetric to the one in startInput()
for (const auto& activeDesc : mInputs.getActiveInputs()) {
if (activeDesc->hasSameHwModuleAs(txSourceDevice)) {
closeActiveClients(activeDesc);
}
}
connectTelephonyTxAudioSource(txSourceDevice, txSinkDevice, delayMs);
}
if (waitMs != nullptr) {
*waitMs = muteWaitMs;
}
return NO_ERROR;
}
bool AudioPolicyManager::isDeviceOfModule(
const sp<DeviceDescriptor>& devDesc, const char *moduleId) const {
sp<HwModule> module = mHwModules.getModuleFromName(moduleId);
if (module != 0) {
return mAvailableOutputDevices.getDevicesFromHwModule(module->getHandle())
.indexOf(devDesc) != NAME_NOT_FOUND
|| mAvailableInputDevices.getDevicesFromHwModule(module->getHandle())
.indexOf(devDesc) != NAME_NOT_FOUND;
}
return false;
}
void AudioPolicyManager::connectTelephonyRxAudioSource()
{
disconnectTelephonyAudioSource(mCallRxSourceClient);
const struct audio_port_config source = {
.role = AUDIO_PORT_ROLE_SOURCE, .type = AUDIO_PORT_TYPE_DEVICE,
.ext.device.type = AUDIO_DEVICE_IN_TELEPHONY_RX, .ext.device.address = ""
};
const auto aa = mEngine->getAttributesForStreamType(AUDIO_STREAM_VOICE_CALL);
audio_port_handle_t portId = AUDIO_PORT_HANDLE_NONE;
status_t status = startAudioSource(&source, &aa, &portId, 0 /*uid*/, true /*internal*/);
ALOGE_IF(status != OK, "%s: failed to start audio source (%d)", __func__, status);
mCallRxSourceClient = mAudioSources.valueFor(portId);
ALOGE_IF(mCallRxSourceClient == nullptr,
"%s failed to start Telephony Rx AudioSource", __func__);
}
void AudioPolicyManager::disconnectTelephonyAudioSource(sp<SourceClientDescriptor> &clientDesc)
{
if (clientDesc == nullptr) {
return;
}
ALOGW_IF(stopAudioSource(clientDesc->portId()) != NO_ERROR,
"%s error stopping audio source", __func__);
clientDesc.clear();
}
void AudioPolicyManager::connectTelephonyTxAudioSource(
const sp<DeviceDescriptor> &srcDevice, const sp<DeviceDescriptor> &sinkDevice,
uint32_t delayMs)
{
disconnectTelephonyAudioSource(mCallTxSourceClient);
if (srcDevice == nullptr || sinkDevice == nullptr) {
ALOGW("%s could not create patch, invalid sink and/or source device(s)", __func__);
return;
}
PatchBuilder patchBuilder;
patchBuilder.addSource(srcDevice).addSink(sinkDevice);
ALOGV("%s between source %s and sink %s", __func__,
srcDevice->toString().c_str(), sinkDevice->toString().c_str());
auto callTxSourceClientPortId = PolicyAudioPort::getNextUniqueId();
const auto aa = mEngine->getAttributesForStreamType(AUDIO_STREAM_VOICE_CALL);
struct audio_port_config source = {};
srcDevice->toAudioPortConfig(&source);
mCallTxSourceClient = new SourceClientDescriptor(
callTxSourceClientPortId, mUidCached, aa, source, srcDevice, AUDIO_STREAM_PATCH,
mCommunnicationStrategy, toVolumeSource(aa), true);
mCallTxSourceClient->setPreferredDeviceId(sinkDevice->getId());
audio_patch_handle_t patchHandle = AUDIO_PATCH_HANDLE_NONE;
status_t status = connectAudioSourceToSink(
mCallTxSourceClient, sinkDevice, patchBuilder.patch(), patchHandle, mUidCached,
delayMs);
ALOGE_IF(status != NO_ERROR, "%s() error %d creating TX audio patch", __func__, status);
if (status == NO_ERROR) {
mAudioSources.add(callTxSourceClientPortId, mCallTxSourceClient);
}
}
void AudioPolicyManager::setPhoneState(audio_mode_t state)
{
ALOGV("setPhoneState() state %d", state);
// store previous phone state for management of sonification strategy below
int oldState = mEngine->getPhoneState();
bool wasLeUnicastActive = isLeUnicastActive();
if (mEngine->setPhoneState(state) != NO_ERROR) {
ALOGW("setPhoneState() invalid or same state %d", state);
return;
}
/// Opens: can these line be executed after the switch of volume curves???
if (isStateInCall(oldState)) {
ALOGV("setPhoneState() in call state management: new state is %d", state);
// force reevaluating accessibility routing when call stops
invalidateStreams({AUDIO_STREAM_ACCESSIBILITY});
}
/**
* Switching to or from incall state or switching between telephony and VoIP lead to force
* routing command.
*/
bool force = ((isStateInCall(oldState) != isStateInCall(state))
|| (isStateInCall(state) && (state != oldState)));
// check for device and output changes triggered by new phone state
checkForDeviceAndOutputChanges();
int delayMs = 0;
if (isStateInCall(state)) {
nsecs_t sysTime = systemTime();
auto musicStrategy = streamToStrategy(AUDIO_STREAM_MUSIC);
auto sonificationStrategy = streamToStrategy(AUDIO_STREAM_ALARM);
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
// mute media and sonification strategies and delay device switch by the largest
// latency of any output where either strategy is active.
// This avoid sending the ring tone or music tail into the earpiece or headset.
if ((desc->isStrategyActive(musicStrategy, SONIFICATION_HEADSET_MUSIC_DELAY, sysTime) ||
desc->isStrategyActive(sonificationStrategy, SONIFICATION_HEADSET_MUSIC_DELAY,
sysTime)) &&
(delayMs < (int)desc->latency()*2)) {
delayMs = desc->latency()*2;
}
setStrategyMute(musicStrategy, true, desc);
setStrategyMute(musicStrategy, false, desc, MUTE_TIME_MS,
mEngine->getOutputDevicesForAttributes(attributes_initializer(AUDIO_USAGE_MEDIA),
nullptr, true /*fromCache*/).types());
setStrategyMute(sonificationStrategy, true, desc);
setStrategyMute(sonificationStrategy, false, desc, MUTE_TIME_MS,
mEngine->getOutputDevicesForAttributes(attributes_initializer(AUDIO_USAGE_ALARM),
nullptr, true /*fromCache*/).types());
}
}
if (state == AUDIO_MODE_IN_CALL) {
(void)updateCallRouting(false /*fromCache*/, delayMs);
} else {
if (oldState == AUDIO_MODE_IN_CALL) {
disconnectTelephonyAudioSource(mCallRxSourceClient);
disconnectTelephonyAudioSource(mCallTxSourceClient);
}
if (hasPrimaryOutput()) {
DeviceVector rxDevices = getNewOutputDevices(mPrimaryOutput, false /*fromCache*/);
// force routing command to audio hardware when ending call
// even if no device change is needed
if (isStateInCall(oldState) && rxDevices.isEmpty()) {
rxDevices = mPrimaryOutput->devices();
}
setOutputDevices(__func__, mPrimaryOutput, rxDevices, force, 0);
}
}
std::map<audio_io_handle_t, DeviceVector> outputsToReopen;
// reevaluate routing on all outputs in case tracks have been started during the call
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
DeviceVector newDevices = getNewOutputDevices(desc, true /*fromCache*/);
if (state != AUDIO_MODE_IN_CALL || (desc != mPrimaryOutput && !isTelephonyRxOrTx(desc))) {
bool forceRouting = !newDevices.isEmpty();
if (desc->mUsePreferredMixerAttributes && newDevices != desc->devices()) {
// If the device is using preferred mixer attributes, the output need to reopen
// with default configuration when the new selected devices are different from
// current routing devices.
outputsToReopen.emplace(mOutputs.keyAt(i), newDevices);
continue;
}
setOutputDevices(__func__, desc, newDevices, forceRouting, 0 /*delayMs*/, nullptr,
true /*requiresMuteCheck*/, !forceRouting /*requiresVolumeCheck*/);
}
}
reopenOutputsWithDevices(outputsToReopen);
checkLeBroadcastRoutes(wasLeUnicastActive, nullptr, delayMs);
if (isStateInCall(state)) {
ALOGV("setPhoneState() in call state management: new state is %d", state);
// force reevaluating accessibility routing when call starts
invalidateStreams({AUDIO_STREAM_ACCESSIBILITY});
}
// Flag that ringtone volume must be limited to music volume until we exit MODE_RINGTONE
mLimitRingtoneVolume = (state == AUDIO_MODE_RINGTONE &&
isStreamActive(AUDIO_STREAM_MUSIC, SONIFICATION_HEADSET_MUSIC_DELAY));
}
audio_mode_t AudioPolicyManager::getPhoneState() {
return mEngine->getPhoneState();
}
void AudioPolicyManager::setForceUse(audio_policy_force_use_t usage,
audio_policy_forced_cfg_t config)
{
ALOGV("setForceUse() usage %d, config %d, mPhoneState %d", usage, config, mEngine->getPhoneState());
if (config == mEngine->getForceUse(usage)) {
return;
}
if (mEngine->setForceUse(usage, config) != NO_ERROR) {
ALOGW("setForceUse() could not set force cfg %d for usage %d", config, usage);
return;
}
bool forceVolumeReeval = (usage == AUDIO_POLICY_FORCE_FOR_COMMUNICATION) ||
(usage == AUDIO_POLICY_FORCE_FOR_DOCK) ||
(usage == AUDIO_POLICY_FORCE_FOR_SYSTEM);
// check for device and output changes triggered by new force usage
checkForDeviceAndOutputChanges();
// force client reconnection to reevaluate flag AUDIO_FLAG_AUDIBILITY_ENFORCED
if (usage == AUDIO_POLICY_FORCE_FOR_SYSTEM) {
invalidateStreams({AUDIO_STREAM_SYSTEM, AUDIO_STREAM_ENFORCED_AUDIBLE});
}
//FIXME: workaround for truncated touch sounds
// to be removed when the problem is handled by system UI
uint32_t delayMs = 0;
if (usage == AUDIO_POLICY_FORCE_FOR_COMMUNICATION) {
delayMs = TOUCH_SOUND_FIXED_DELAY_MS;
}
updateCallAndOutputRouting(forceVolumeReeval, delayMs);
updateInputRouting();
}
void AudioPolicyManager::setSystemProperty(const char* property, const char* value)
{
ALOGV("setSystemProperty() property %s, value %s", property, value);
}
// Find an MSD output profile compatible with the parameters passed.
// When "directOnly" is set, restrict search to profiles for direct outputs.
sp<IOProfile> AudioPolicyManager::getMsdProfileForOutput(
const DeviceVector& devices,
uint32_t samplingRate,
audio_format_t format,
audio_channel_mask_t channelMask,
audio_output_flags_t flags,
bool directOnly)
{
flags = getRelevantFlags(flags, directOnly);
sp<HwModule> msdModule = mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD);
if (msdModule != nullptr) {
// for the msd module check if there are patches to the output devices
if (msdHasPatchesToAllDevices(devices.toTypeAddrVector())) {
HwModuleCollection modules;
modules.add(msdModule);
return searchCompatibleProfileHwModules(
modules, getMsdAudioOutDevices(), samplingRate, format, channelMask,
flags, directOnly);
}
}
return nullptr;
}
// Find an output profile compatible with the parameters passed. When "directOnly" is set, restrict
// search to profiles for direct outputs.
sp<IOProfile> AudioPolicyManager::getProfileForOutput(
const DeviceVector& devices,
uint32_t samplingRate,
audio_format_t format,
audio_channel_mask_t channelMask,
audio_output_flags_t flags,
bool directOnly)
{
flags = getRelevantFlags(flags, directOnly);
return searchCompatibleProfileHwModules(
mHwModules, devices, samplingRate, format, channelMask, flags, directOnly);
}
audio_output_flags_t AudioPolicyManager::getRelevantFlags (
audio_output_flags_t flags, bool directOnly) {
if (directOnly) {
// only retain flags that will drive the direct output profile selection
// if explicitly requested
static const uint32_t kRelevantFlags =
(AUDIO_OUTPUT_FLAG_HW_AV_SYNC | AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD |
AUDIO_OUTPUT_FLAG_VOIP_RX | AUDIO_OUTPUT_FLAG_MMAP_NOIRQ);
flags = (audio_output_flags_t)((flags & kRelevantFlags) | AUDIO_OUTPUT_FLAG_DIRECT);
}
return flags;
}
sp<IOProfile> AudioPolicyManager::searchCompatibleProfileHwModules (
const HwModuleCollection& hwModules,
const DeviceVector& devices,
uint32_t samplingRate,
audio_format_t format,
audio_channel_mask_t channelMask,
audio_output_flags_t flags,
bool directOnly) {
sp<IOProfile> profile;
for (const auto& hwModule : hwModules) {
for (const auto& curProfile : hwModule->getOutputProfiles()) {
if (curProfile->getCompatibilityScore(devices,
samplingRate, NULL /*updatedSamplingRate*/,
format, NULL /*updatedFormat*/,
channelMask, NULL /*updatedChannelMask*/,
flags) == IOProfile::NO_MATCH) {
continue;
}
// reject profiles not corresponding to a device currently available
if (!mAvailableOutputDevices.containsAtLeastOne(curProfile->getSupportedDevices())) {
continue;
}
// reject profiles if connected device does not support codec
if (!curProfile->devicesSupportEncodedFormats(devices.types())) {
continue;
}
if (!directOnly) {
return curProfile;
}
// when searching for direct outputs, if several profiles are compatible, give priority
// to one with offload capability
if (profile != 0 &&
((curProfile->getFlags() & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) == 0)) {
continue;
}
profile = curProfile;
if ((profile->getFlags() & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) != 0) {
break;
}
}
}
return profile;
}
sp<IOProfile> AudioPolicyManager::getSpatializerOutputProfile(
const audio_config_t *config __unused, const AudioDeviceTypeAddrVector &devices) const
{
for (const auto& hwModule : mHwModules) {
for (const auto& curProfile : hwModule->getOutputProfiles()) {
if (curProfile->getFlags() != AUDIO_OUTPUT_FLAG_SPATIALIZER) {
continue;
}
if (!devices.empty()) {
// reject profiles not corresponding to a device currently available
DeviceVector supportedDevices = curProfile->getSupportedDevices();
if (!mAvailableOutputDevices.containsAtLeastOne(supportedDevices)) {
continue;
}
if (supportedDevices.getDevicesFromDeviceTypeAddrVec(devices).size()
!= devices.size()) {
continue;
}
}
ALOGV("%s found profile %s", __func__, curProfile->getName().c_str());
return curProfile;
}
}
return nullptr;
}
audio_io_handle_t AudioPolicyManager::getOutput(audio_stream_type_t stream)
{
DeviceVector devices = mEngine->getOutputDevicesForStream(stream, false /*fromCache*/);
// Note that related method getOutputForAttr() uses getOutputForDevice() not selectOutput().
// We use selectOutput() here since we don't have the desired AudioTrack sample rate,
// format, flags, etc. This may result in some discrepancy for functions that utilize
// getOutput() solely on audio_stream_type such as AudioSystem::getOutputFrameCount()
// and AudioSystem::getOutputSamplingRate().
SortedVector<audio_io_handle_t> outputs = getOutputsForDevices(devices, mOutputs);
audio_output_flags_t flags = AUDIO_OUTPUT_FLAG_NONE;
if (stream == AUDIO_STREAM_MUSIC &&
property_get_bool("audio.deep_buffer.media", false /* default_value */)) {
flags = AUDIO_OUTPUT_FLAG_DEEP_BUFFER;
}
const audio_io_handle_t output = selectOutput(outputs, flags);
ALOGV("getOutput() stream %d selected devices %s, output %d", stream,
devices.toString().c_str(), output);
return output;
}
status_t AudioPolicyManager::getAudioAttributes(audio_attributes_t *dstAttr,
const audio_attributes_t *srcAttr,
audio_stream_type_t srcStream)
{
if (srcAttr != NULL) {
if (!isValidAttributes(srcAttr)) {
ALOGE("%s invalid attributes: usage=%d content=%d flags=0x%x tags=[%s]",
__func__,
srcAttr->usage, srcAttr->content_type, srcAttr->flags,
srcAttr->tags);
return BAD_VALUE;
}
*dstAttr = *srcAttr;
} else {
if (srcStream < AUDIO_STREAM_MIN || srcStream >= AUDIO_STREAM_PUBLIC_CNT) {
ALOGE("%s: invalid stream type", __func__);
return BAD_VALUE;
}
*dstAttr = mEngine->getAttributesForStreamType(srcStream);
}
// Only honor audibility enforced when required. The client will be
// forced to reconnect if the forced usage changes.
if (mEngine->getForceUse(AUDIO_POLICY_FORCE_FOR_SYSTEM) != AUDIO_POLICY_FORCE_SYSTEM_ENFORCED) {
dstAttr->flags = static_cast<audio_flags_mask_t>(
dstAttr->flags & ~AUDIO_FLAG_AUDIBILITY_ENFORCED);
}
return NO_ERROR;
}
status_t AudioPolicyManager::getOutputForAttrInt(
audio_attributes_t *resultAttr,
audio_io_handle_t *output,
audio_session_t session,
const audio_attributes_t *attr,
audio_stream_type_t *stream,
uid_t uid,
audio_config_t *config,
audio_output_flags_t *flags,
audio_port_handle_t *selectedDeviceId,
bool *isRequestedDeviceForExclusiveUse,
std::vector<sp<AudioPolicyMix>> *secondaryMixes,
output_type_t *outputType,
bool *isSpatialized,
bool *isBitPerfect)
{
DeviceVector outputDevices;
const audio_port_handle_t requestedPortId = *selectedDeviceId;
DeviceVector msdDevices = getMsdAudioOutDevices();
const sp<DeviceDescriptor> requestedDevice =
mAvailableOutputDevices.getDeviceFromId(requestedPortId);
*outputType = API_OUTPUT_INVALID;
*isSpatialized = false;
status_t status = getAudioAttributes(resultAttr, attr, *stream);
if (status != NO_ERROR) {
return status;
}
if (auto it = mAllowedCapturePolicies.find(uid); it != end(mAllowedCapturePolicies)) {
resultAttr->flags = static_cast<audio_flags_mask_t>(resultAttr->flags | it->second);
}
*stream = mEngine->getStreamTypeForAttributes(*resultAttr);
ALOGV("%s() attributes=%s stream=%s session %d selectedDeviceId %d", __func__,
toString(*resultAttr).c_str(), toString(*stream).c_str(), session, requestedPortId);
bool usePrimaryOutputFromPolicyMixes = false;
// The primary output is the explicit routing (eg. setPreferredDevice) if specified,
// otherwise, fallback to the dynamic policies, if none match, query the engine.
// Secondary outputs are always found by dynamic policies as the engine do not support them
sp<AudioPolicyMix> primaryMix;
const audio_config_base_t clientConfig = {.sample_rate = config->sample_rate,
.channel_mask = config->channel_mask,
.format = config->format,
};
status = mPolicyMixes.getOutputForAttr(*resultAttr, clientConfig, uid, session, *flags,
mAvailableOutputDevices, requestedDevice, primaryMix,
secondaryMixes, usePrimaryOutputFromPolicyMixes);
if (status != OK) {
return status;
}
// FIXME: in case of RENDER policy, the output capabilities should be checked
if ((secondaryMixes != nullptr && !secondaryMixes->empty())
&& !audio_is_linear_pcm(config->format)) {
ALOGD("%s: rejecting request as secondary mixes only support pcm", __func__);
return BAD_VALUE;
}
if (usePrimaryOutputFromPolicyMixes) {
sp<DeviceDescriptor> policyMixDevice =
mAvailableOutputDevices.getDevice(primaryMix->mDeviceType,
primaryMix->mDeviceAddress,
AUDIO_FORMAT_DEFAULT);
sp<SwAudioOutputDescriptor> policyDesc = primaryMix->getOutput();
bool tryDirectForFlags = policyDesc == nullptr ||
(policyDesc->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) ||
(*flags & (AUDIO_OUTPUT_FLAG_HW_AV_SYNC | AUDIO_OUTPUT_FLAG_MMAP_NOIRQ));
// if a direct output can be opened to deliver the track's multi-channel content to the
// output rather than being downmixed by the primary output, then use this direct
// output by by-passing the primary mix if possible, otherwise fall-through to primary
// mix.
bool tryDirectForChannelMask = policyDesc != nullptr
&& (audio_channel_count_from_out_mask(policyDesc->getConfig().channel_mask) <
audio_channel_count_from_out_mask(config->channel_mask));
if (policyMixDevice != nullptr && (tryDirectForFlags || tryDirectForChannelMask)) {
audio_io_handle_t newOutput;
status = openDirectOutput(
*stream, session, config,
(audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_DIRECT),
DeviceVector(policyMixDevice), &newOutput);
if (status == NO_ERROR) {
policyDesc = mOutputs.valueFor(newOutput);
primaryMix->setOutput(policyDesc);
} else if (tryDirectForFlags) {
ALOGW("%s, failed open direct, status: %d", __func__, status);
policyDesc = nullptr;
} // otherwise use primary if available.
}
if (policyDesc != nullptr) {
policyDesc->mPolicyMix = primaryMix;
*output = policyDesc->mIoHandle;
*selectedDeviceId = policyMixDevice != nullptr ? policyMixDevice->getId()
: AUDIO_PORT_HANDLE_NONE;
if ((policyDesc->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) != AUDIO_OUTPUT_FLAG_DIRECT) {
// Remove direct flag as it is not on a direct output.
*flags = (audio_output_flags_t) (*flags & ~AUDIO_OUTPUT_FLAG_DIRECT);
}
ALOGV("getOutputForAttr() returns output %d", *output);
if (resultAttr->usage == AUDIO_USAGE_VIRTUAL_SOURCE) {
*outputType = API_OUT_MIX_PLAYBACK;
} else {
*outputType = API_OUTPUT_LEGACY;
}
return NO_ERROR;
} else {
if (policyMixDevice != nullptr) {
ALOGE("%s, try to use primary mix but no output found", __func__);
return INVALID_OPERATION;
}
// Fallback to default engine selection as the selected primary mix device is not
// available.
}
}
// Virtual sources must always be dynamicaly or explicitly routed
if (resultAttr->usage == AUDIO_USAGE_VIRTUAL_SOURCE) {
ALOGW("getOutputForAttr() no policy mix found for usage AUDIO_USAGE_VIRTUAL_SOURCE");
return BAD_VALUE;
}
// explicit routing managed by getDeviceForStrategy in APM is now handled by engine
// in order to let the choice of the order to future vendor engine
outputDevices = mEngine->getOutputDevicesForAttributes(*resultAttr, requestedDevice, false);
if ((resultAttr->flags & AUDIO_FLAG_HW_AV_SYNC) != 0) {
*flags = (audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_HW_AV_SYNC);
}
// Set incall music only if device was explicitly set, and fallback to the device which is
// chosen by the engine if not.
// FIXME: provide a more generic approach which is not device specific and move this back
// to getOutputForDevice.
// TODO: Remove check of AUDIO_STREAM_MUSIC once migration is completed on the app side.
if (outputDevices.onlyContainsDevicesWithType(AUDIO_DEVICE_OUT_TELEPHONY_TX) &&
(*stream == AUDIO_STREAM_MUSIC || resultAttr->usage == AUDIO_USAGE_VOICE_COMMUNICATION) &&
audio_is_linear_pcm(config->format) &&
isCallAudioAccessible()) {
if (requestedPortId != AUDIO_PORT_HANDLE_NONE) {
*flags = (audio_output_flags_t)AUDIO_OUTPUT_FLAG_INCALL_MUSIC;
*isRequestedDeviceForExclusiveUse = true;
}
}
ALOGV("%s() device %s, sampling rate %d, format %#x, channel mask %#x, flags %#x stream %s",
__func__, outputDevices.toString().c_str(), config->sample_rate, config->format,
config->channel_mask, *flags, toString(*stream).c_str());
*output = AUDIO_IO_HANDLE_NONE;
if (!msdDevices.isEmpty()) {
*output = getOutputForDevices(msdDevices, session, resultAttr, config, flags, isSpatialized);
if (*output != AUDIO_IO_HANDLE_NONE && setMsdOutputPatches(&outputDevices) == NO_ERROR) {
ALOGV("%s() Using MSD devices %s instead of devices %s",
__func__, msdDevices.toString().c_str(), outputDevices.toString().c_str());
} else {
*output = AUDIO_IO_HANDLE_NONE;
}
}
if (*output == AUDIO_IO_HANDLE_NONE) {
sp<PreferredMixerAttributesInfo> info = nullptr;
if (outputDevices.size() == 1) {
info = getPreferredMixerAttributesInfo(
outputDevices.itemAt(0)->getId(),
mEngine->getProductStrategyForAttributes(*resultAttr),
true /*activeBitPerfectPreferred*/);
// Only use preferred mixer if the uid matches or the preferred mixer is bit-perfect
// and it is currently active.
if (info != nullptr && info->getUid() != uid &&
((info->getFlags() & AUDIO_OUTPUT_FLAG_BIT_PERFECT) == AUDIO_OUTPUT_FLAG_NONE ||
info->getActiveClientCount() == 0)) {
info = nullptr;
}
}
*output = getOutputForDevices(outputDevices, session, resultAttr, config,
flags, isSpatialized, info, resultAttr->flags & AUDIO_FLAG_MUTE_HAPTIC);
// The client will be active if the client is currently preferred mixer owner and the
// requested configuration matches the preferred mixer configuration.
*isBitPerfect = (info != nullptr
&& (info->getFlags() & AUDIO_OUTPUT_FLAG_BIT_PERFECT) != AUDIO_OUTPUT_FLAG_NONE
&& info->getUid() == uid
&& *output != AUDIO_IO_HANDLE_NONE
// When bit-perfect output is selected for the preferred mixer attributes owner,
// only need to consider the config matches.
&& mOutputs.valueFor(*output)->isConfigurationMatched(
clientConfig, AUDIO_OUTPUT_FLAG_NONE));
}
if (*output == AUDIO_IO_HANDLE_NONE) {
AudioProfileVector profiles;
status_t ret = getProfilesForDevices(outputDevices, profiles, *flags, false /*isInput*/);
if (ret == NO_ERROR && !profiles.empty()) {
const auto channels = profiles[0]->getChannels();
if (!channels.empty() && (channels.find(config->channel_mask) == channels.end())) {
config->channel_mask = *channels.begin();
}
const auto sampleRates = profiles[0]->getSampleRates();
if (!sampleRates.empty() &&
(sampleRates.find(config->sample_rate) == sampleRates.end())) {
config->sample_rate = *sampleRates.begin();
}
config->format = profiles[0]->getFormat();
}
return INVALID_OPERATION;
}
*selectedDeviceId = getFirstDeviceId(outputDevices);
for (auto &outputDevice : outputDevices) {
if (outputDevice->getId() == mConfig->getDefaultOutputDevice()->getId()) {
*selectedDeviceId = outputDevice->getId();
break;
}
}
if (outputDevices.onlyContainsDevicesWithType(AUDIO_DEVICE_OUT_TELEPHONY_TX)) {
*outputType = API_OUTPUT_TELEPHONY_TX;
} else {
*outputType = API_OUTPUT_LEGACY;
}
ALOGV("%s returns output %d selectedDeviceId %d", __func__, *output, *selectedDeviceId);
return NO_ERROR;
}
status_t AudioPolicyManager::getOutputForAttr(const audio_attributes_t *attr,
audio_io_handle_t *output,
audio_session_t session,
audio_stream_type_t *stream,
const AttributionSourceState& attributionSource,
audio_config_t *config,
audio_output_flags_t *flags,
audio_port_handle_t *selectedDeviceId,
audio_port_handle_t *portId,
std::vector<audio_io_handle_t> *secondaryOutputs,
output_type_t *outputType,
bool *isSpatialized,
bool *isBitPerfect)
{
// The supplied portId must be AUDIO_PORT_HANDLE_NONE
if (*portId != AUDIO_PORT_HANDLE_NONE) {
return INVALID_OPERATION;
}
const uid_t uid = VALUE_OR_RETURN_STATUS(
aidl2legacy_int32_t_uid_t(attributionSource.uid));
const audio_port_handle_t requestedPortId = *selectedDeviceId;
audio_attributes_t resultAttr;
bool isRequestedDeviceForExclusiveUse = false;
std::vector<sp<AudioPolicyMix>> secondaryMixes;
const sp<DeviceDescriptor> requestedDevice =
mAvailableOutputDevices.getDeviceFromId(requestedPortId);
// Prevent from storing invalid requested device id in clients
const audio_port_handle_t sanitizedRequestedPortId =
requestedDevice != nullptr ? requestedPortId : AUDIO_PORT_HANDLE_NONE;
*selectedDeviceId = sanitizedRequestedPortId;
status_t status = getOutputForAttrInt(&resultAttr, output, session, attr, stream, uid,
config, flags, selectedDeviceId, &isRequestedDeviceForExclusiveUse,
secondaryOutputs != nullptr ? &secondaryMixes : nullptr, outputType, isSpatialized,
isBitPerfect);
if (status != NO_ERROR) {
return status;
}
std::vector<wp<SwAudioOutputDescriptor>> weakSecondaryOutputDescs;
if (secondaryOutputs != nullptr) {
for (auto &secondaryMix : secondaryMixes) {
sp<SwAudioOutputDescriptor> outputDesc = secondaryMix->getOutput();
if (outputDesc != nullptr &&
outputDesc->mIoHandle != AUDIO_IO_HANDLE_NONE) {
secondaryOutputs->push_back(outputDesc->mIoHandle);
weakSecondaryOutputDescs.push_back(outputDesc);
}
}
}
audio_config_base_t clientConfig = {.sample_rate = config->sample_rate,
.channel_mask = config->channel_mask,
.format = config->format,
};
*portId = PolicyAudioPort::getNextUniqueId();
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.valueFor(*output);
sp<TrackClientDescriptor> clientDesc =
new TrackClientDescriptor(*portId, uid, session, resultAttr, clientConfig,
sanitizedRequestedPortId, *stream,
mEngine->getProductStrategyForAttributes(resultAttr),
toVolumeSource(resultAttr),
*flags, isRequestedDeviceForExclusiveUse,
std::move(weakSecondaryOutputDescs),
outputDesc->mPolicyMix);
outputDesc->addClient(clientDesc);
ALOGV("%s() returns output %d requestedPortId %d selectedDeviceId %d for port ID %d", __func__,
*output, requestedPortId, *selectedDeviceId, *portId);
return NO_ERROR;
}
status_t AudioPolicyManager::openDirectOutput(audio_stream_type_t stream,
audio_session_t session,
const audio_config_t *config,
audio_output_flags_t flags,
const DeviceVector &devices,
audio_io_handle_t *output) {
*output = AUDIO_IO_HANDLE_NONE;
// skip direct output selection if the request can obviously be attached to a mixed output
// and not explicitly requested
if (((flags & AUDIO_OUTPUT_FLAG_DIRECT) == 0) &&
audio_is_linear_pcm(config->format) && config->sample_rate <= SAMPLE_RATE_HZ_MAX &&
audio_channel_count_from_out_mask(config->channel_mask) <= 2) {
return NAME_NOT_FOUND;
}
// Do not allow offloading if one non offloadable effect is enabled or MasterMono is enabled.
// This prevents creating an offloaded track and tearing it down immediately after start
// when audioflinger detects there is an active non offloadable effect.
// FIXME: We should check the audio session here but we do not have it in this context.
// This may prevent offloading in rare situations where effects are left active by apps
// in the background.
sp<IOProfile> profile;
if (((flags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) == 0) ||
!(mEffects.isNonOffloadableEffectEnabled() || mMasterMono)) {
profile = getProfileForOutput(
devices, config->sample_rate, config->format, config->channel_mask,
flags, true /* directOnly */);
}
if (profile == nullptr) {
return NAME_NOT_FOUND;
}
// exclusive outputs for MMAP and Offload are enforced by different session ids.
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (!desc->isDuplicated() && (profile == desc->mProfile)) {
// reuse direct output if currently open by the same client
// and configured with same parameters
if ((config->sample_rate == desc->getSamplingRate()) &&
(config->format == desc->getFormat()) &&
(config->channel_mask == desc->getChannelMask()) &&
(session == desc->mDirectClientSession)) {
desc->mDirectOpenCount++;
ALOGV("%s reusing direct output %d for session %d", __func__,
mOutputs.keyAt(i), session);
*output = mOutputs.keyAt(i);
return NO_ERROR;
}
}
}
if (!profile->canOpenNewIo()) {
if (!com::android::media::audioserver::direct_track_reprioritization()) {
return NAME_NOT_FOUND;
} else if ((profile->getFlags() & AUDIO_OUTPUT_FLAG_MMAP_NOIRQ) != 0) {
// MMAP gracefully handles lack of an exclusive track resource by mixing
// above the audio framework. For AAudio to know that the limit is reached,
// return an error.
return NAME_NOT_FOUND;
} else {
// Close outputs on this profile, if available, to free resources for this request
for (int i = 0; i < mOutputs.size() && !profile->canOpenNewIo(); i++) {
const auto desc = mOutputs.valueAt(i);
if (desc->mProfile == profile) {
closeOutput(desc->mIoHandle);
}
}
}
}
// Unable to close streams to find free resources for this request
if (!profile->canOpenNewIo()) {
return NAME_NOT_FOUND;
}
auto outputDesc = sp<SwAudioOutputDescriptor>::make(profile, mpClientInterface);
// An MSD patch may be using the only output stream that can service this request. Release
// all MSD patches to prioritize this request over any active output on MSD.
releaseMsdOutputPatches(devices);
status_t status =
outputDesc->open(config, nullptr /* mixerConfig */, devices, stream, flags, output);
// only accept an output with the requested parameters
if (status != NO_ERROR ||
(config->sample_rate != 0 && config->sample_rate != outputDesc->getSamplingRate()) ||
(config->format != AUDIO_FORMAT_DEFAULT && config->format != outputDesc->getFormat()) ||
(config->channel_mask != 0 && config->channel_mask != outputDesc->getChannelMask())) {
ALOGV("%s failed opening direct output: output %d sample rate %d %d,"
"format %d %d, channel mask %04x %04x", __func__, *output, config->sample_rate,
outputDesc->getSamplingRate(), config->format, outputDesc->getFormat(),
config->channel_mask, outputDesc->getChannelMask());
if (*output != AUDIO_IO_HANDLE_NONE) {
outputDesc->close();
}
// fall back to mixer output if possible when the direct output could not be open
if (audio_is_linear_pcm(config->format) &&
config->sample_rate <= SAMPLE_RATE_HZ_MAX) {
return NAME_NOT_FOUND;
}
*output = AUDIO_IO_HANDLE_NONE;
return BAD_VALUE;
}
outputDesc->mDirectOpenCount = 1;
outputDesc->mDirectClientSession = session;
addOutput(*output, outputDesc);
mPreviousOutputs = mOutputs;
ALOGV("%s returns new direct output %d", __func__, *output);
mpClientInterface->onAudioPortListUpdate();
return NO_ERROR;
}
audio_io_handle_t AudioPolicyManager::getOutputForDevices(
const DeviceVector &devices,
audio_session_t session,
const audio_attributes_t *attr,
const audio_config_t *config,
audio_output_flags_t *flags,
bool *isSpatialized,
sp<PreferredMixerAttributesInfo> prefMixerConfigInfo,
bool forceMutingHaptic)
{
audio_io_handle_t output = AUDIO_IO_HANDLE_NONE;
// Discard haptic channel mask when forcing muting haptic channels.
audio_channel_mask_t channelMask = forceMutingHaptic
? static_cast<audio_channel_mask_t>(config->channel_mask & ~AUDIO_CHANNEL_HAPTIC_ALL)
: config->channel_mask;
// open a direct output if required by specified parameters
//force direct flag if offload flag is set: offloading implies a direct output stream
// and all common behaviors are driven by checking only the direct flag
// this should normally be set appropriately in the policy configuration file
if ((*flags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) != 0) {
*flags = (audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_DIRECT);
}
if ((*flags & AUDIO_OUTPUT_FLAG_HW_AV_SYNC) != 0) {
*flags = (audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_DIRECT);
}
audio_stream_type_t stream = mEngine->getStreamTypeForAttributes(*attr);
// only allow deep buffering for music stream type
if (stream != AUDIO_STREAM_MUSIC) {
*flags = (audio_output_flags_t)(*flags &~AUDIO_OUTPUT_FLAG_DEEP_BUFFER);
} else if (/* stream == AUDIO_STREAM_MUSIC && */
*flags == AUDIO_OUTPUT_FLAG_NONE &&
property_get_bool("audio.deep_buffer.media", false /* default_value */)) {
// use DEEP_BUFFER as default output for music stream type
*flags = (audio_output_flags_t)AUDIO_OUTPUT_FLAG_DEEP_BUFFER;
}
if (stream == AUDIO_STREAM_TTS) {
*flags = AUDIO_OUTPUT_FLAG_TTS;
} else if (stream == AUDIO_STREAM_VOICE_CALL &&
audio_is_linear_pcm(config->format) &&
(*flags & AUDIO_OUTPUT_FLAG_INCALL_MUSIC) == 0) {
*flags = (audio_output_flags_t)(AUDIO_OUTPUT_FLAG_VOIP_RX |
AUDIO_OUTPUT_FLAG_DIRECT);
ALOGV("Set VoIP and Direct output flags for PCM format");
}
// Attach the Ultrasound flag for the AUDIO_CONTENT_TYPE_ULTRASOUND
if (attr->content_type == AUDIO_CONTENT_TYPE_ULTRASOUND) {
*flags = (audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_ULTRASOUND);
}
// Use the spatializer output if the content can be spatialized, no preferred mixer
// was specified and offload or direct playback is not explicitly requested.
*isSpatialized = false;
if (mSpatializerOutput != nullptr
&& canBeSpatializedInt(attr, config, devices.toTypeAddrVector())
&& prefMixerConfigInfo == nullptr
&& ((*flags & (AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD | AUDIO_OUTPUT_FLAG_DIRECT)) == 0)) {
*isSpatialized = true;
return mSpatializerOutput->mIoHandle;
}
audio_config_t directConfig = *config;
directConfig.channel_mask = channelMask;
status_t status = openDirectOutput(stream, session, &directConfig, *flags, devices, &output);
if (status != NAME_NOT_FOUND) {
return output;
}
// A request for HW A/V sync cannot fallback to a mixed output because time
// stamps are embedded in audio data
if ((*flags & (AUDIO_OUTPUT_FLAG_HW_AV_SYNC | AUDIO_OUTPUT_FLAG_MMAP_NOIRQ)) != 0) {
return AUDIO_IO_HANDLE_NONE;
}
// A request for Tuner cannot fallback to a mixed output
if ((directConfig.offload_info.content_id || directConfig.offload_info.sync_id)) {
return AUDIO_IO_HANDLE_NONE;
}
// ignoring channel mask due to downmix capability in mixer
// open a non direct output
// for non direct outputs, only PCM is supported
if (audio_is_linear_pcm(config->format)) {
// get which output is suitable for the specified stream. The actual
// routing change will happen when startOutput() will be called
SortedVector<audio_io_handle_t> outputs = getOutputsForDevices(devices, mOutputs);
if (prefMixerConfigInfo != nullptr) {
for (audio_io_handle_t outputHandle : outputs) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.valueFor(outputHandle);
if (outputDesc->mProfile == prefMixerConfigInfo->getProfile()) {
output = outputHandle;
break;
}
}
if (output == AUDIO_IO_HANDLE_NONE) {
// No output open with the preferred profile. Open a new one.
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.channel_mask = prefMixerConfigInfo->getConfigBase().channel_mask;
config.sample_rate = prefMixerConfigInfo->getConfigBase().sample_rate;
config.format = prefMixerConfigInfo->getConfigBase().format;
sp<SwAudioOutputDescriptor> preferredOutput = openOutputWithProfileAndDevice(
prefMixerConfigInfo->getProfile(), devices, nullptr /*mixerConfig*/,
&config, prefMixerConfigInfo->getFlags());
if (preferredOutput == nullptr) {
ALOGE("%s failed to open output with preferred mixer config", __func__);
} else {
output = preferredOutput->mIoHandle;
}
}
} else {
// at this stage we should ignore the DIRECT flag as no direct output could be
// found earlier
*flags = (audio_output_flags_t) (*flags & ~AUDIO_OUTPUT_FLAG_DIRECT);
output = selectOutput(
outputs, *flags, config->format, channelMask, config->sample_rate, session);
}
}
ALOGW_IF((output == 0), "getOutputForDevices() could not find output for stream %d, "
"sampling rate %d, format %#x, channels %#x, flags %#x",
stream, config->sample_rate, config->format, channelMask, *flags);
return output;
}
sp<DeviceDescriptor> AudioPolicyManager::getMsdAudioInDevice() const {
auto msdInDevices = mHwModules.getAvailableDevicesFromModuleName(AUDIO_HARDWARE_MODULE_ID_MSD,
mAvailableInputDevices);
return msdInDevices.isEmpty()? nullptr : msdInDevices.itemAt(0);
}
DeviceVector AudioPolicyManager::getMsdAudioOutDevices() const {
return mHwModules.getAvailableDevicesFromModuleName(AUDIO_HARDWARE_MODULE_ID_MSD,
mAvailableOutputDevices);
}
const AudioPatchCollection AudioPolicyManager::getMsdOutputPatches() const {
AudioPatchCollection msdPatches;
sp<HwModule> msdModule = mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD);
if (msdModule != 0) {
for (size_t i = 0; i < mAudioPatches.size(); ++i) {
sp<AudioPatch> patch = mAudioPatches.valueAt(i);
for (size_t j = 0; j < patch->mPatch.num_sources; ++j) {
const struct audio_port_config *source = &patch->mPatch.sources[j];
if (source->type == AUDIO_PORT_TYPE_DEVICE &&
source->ext.device.hw_module == msdModule->getHandle()) {
msdPatches.addAudioPatch(patch->getHandle(), patch);
}
}
}
}
return msdPatches;
}
bool AudioPolicyManager::isMsdPatch(const audio_patch_handle_t &handle) const {
ssize_t index = mAudioPatches.indexOfKey(handle);
if (index < 0) {
return false;
}
const sp<AudioPatch> patch = mAudioPatches.valueAt(index);
sp<HwModule> msdModule = mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD);
if (msdModule == nullptr) {
return false;
}
const struct audio_port_config *sink = &patch->mPatch.sinks[0];
if (getMsdAudioOutDevices().contains(mAvailableOutputDevices.getDeviceFromId(sink->id))) {
return true;
}
index = getMsdOutputPatches().indexOfKey(handle);
if (index < 0) {
return false;
}
return true;
}
status_t AudioPolicyManager::getMsdProfiles(bool hwAvSync,
const InputProfileCollection &inputProfiles,
const OutputProfileCollection &outputProfiles,
const sp<DeviceDescriptor> &sourceDevice,
const sp<DeviceDescriptor> &sinkDevice,
AudioProfileVector& sourceProfiles,
AudioProfileVector& sinkProfiles) const {
if (inputProfiles.isEmpty()) {
ALOGE("%s() no input profiles for source module", __func__);
return NO_INIT;
}
if (outputProfiles.isEmpty()) {
ALOGE("%s() no output profiles for sink module", __func__);
return NO_INIT;
}
for (const auto &inProfile : inputProfiles) {
if (hwAvSync == ((inProfile->getFlags() & AUDIO_INPUT_FLAG_HW_AV_SYNC) != 0) &&
inProfile->supportsDevice(sourceDevice)) {
appendAudioProfiles(sourceProfiles, inProfile->getAudioProfiles());
}
}
for (const auto &outProfile : outputProfiles) {
if (hwAvSync == ((outProfile->getFlags() & AUDIO_OUTPUT_FLAG_HW_AV_SYNC) != 0) &&
outProfile->supportsDevice(sinkDevice)) {
appendAudioProfiles(sinkProfiles, outProfile->getAudioProfiles());
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::getBestMsdConfig(bool hwAvSync,
const AudioProfileVector &sourceProfiles, const AudioProfileVector &sinkProfiles,
audio_port_config *sourceConfig, audio_port_config *sinkConfig) const
{
// Compressed formats for MSD module, ordered from most preferred to least preferred.
static const std::vector<audio_format_t> formatsOrder = {{
AUDIO_FORMAT_IEC60958, AUDIO_FORMAT_MAT_2_1, AUDIO_FORMAT_MAT_2_0, AUDIO_FORMAT_E_AC3,
AUDIO_FORMAT_AC3, AUDIO_FORMAT_PCM_FLOAT, AUDIO_FORMAT_PCM_32_BIT,
AUDIO_FORMAT_PCM_8_24_BIT, AUDIO_FORMAT_PCM_24_BIT_PACKED, AUDIO_FORMAT_PCM_16_BIT }};
static const std::vector<audio_channel_mask_t> channelMasksOrder = [](){
// Channel position masks for MSD module, 3D > 2D > 1D ordering (most preferred to least
// preferred).
std::vector<audio_channel_mask_t> masks = {{
AUDIO_CHANNEL_OUT_3POINT1POINT2, AUDIO_CHANNEL_OUT_3POINT0POINT2,
AUDIO_CHANNEL_OUT_2POINT1POINT2, AUDIO_CHANNEL_OUT_2POINT0POINT2,
AUDIO_CHANNEL_OUT_5POINT1, AUDIO_CHANNEL_OUT_STEREO }};
// insert index masks (higher counts most preferred) as preferred over position masks
for (int i = 1; i <= AUDIO_CHANNEL_COUNT_MAX; i++) {
masks.insert(
masks.begin(), audio_channel_mask_for_index_assignment_from_count(i));
}
return masks;
}();
struct audio_config_base bestSinkConfig;
status_t result = findBestMatchingOutputConfig(sourceProfiles, sinkProfiles, formatsOrder,
channelMasksOrder, true /*preferHigherSamplingRates*/, bestSinkConfig);
if (result != NO_ERROR) {
ALOGD("%s() no matching config found for sink, hwAvSync: %d",
__func__, hwAvSync);
return result;
}
sinkConfig->sample_rate = bestSinkConfig.sample_rate;
sinkConfig->channel_mask = bestSinkConfig.channel_mask;
sinkConfig->format = bestSinkConfig.format;
// For encoded streams force direct flag to prevent downstream mixing.
sinkConfig->flags.output = static_cast<audio_output_flags_t>(
sinkConfig->flags.output | AUDIO_OUTPUT_FLAG_DIRECT);
if (audio_is_iec61937_compatible(sinkConfig->format)) {
// For formats compatible with IEC61937 encapsulation, assume that
// the input is IEC61937 framed (for proportional buffer sizing).
// Add the AUDIO_OUTPUT_FLAG_IEC958_NONAUDIO flag so downstream HAL can distinguish between
// raw and IEC61937 framed streams.
sinkConfig->flags.output = static_cast<audio_output_flags_t>(
sinkConfig->flags.output | AUDIO_OUTPUT_FLAG_IEC958_NONAUDIO);
}
sourceConfig->sample_rate = bestSinkConfig.sample_rate;
// Specify exact channel mask to prevent guessing by bit count in PatchPanel.
sourceConfig->channel_mask =
audio_channel_mask_get_representation(bestSinkConfig.channel_mask)
== AUDIO_CHANNEL_REPRESENTATION_INDEX ?
bestSinkConfig.channel_mask : audio_channel_mask_out_to_in(bestSinkConfig.channel_mask);
sourceConfig->format = bestSinkConfig.format;
// Copy input stream directly without any processing (e.g. resampling).
sourceConfig->flags.input = static_cast<audio_input_flags_t>(
sourceConfig->flags.input | AUDIO_INPUT_FLAG_DIRECT);
if (hwAvSync) {
sinkConfig->flags.output = static_cast<audio_output_flags_t>(
sinkConfig->flags.output | AUDIO_OUTPUT_FLAG_HW_AV_SYNC);
sourceConfig->flags.input = static_cast<audio_input_flags_t>(
sourceConfig->flags.input | AUDIO_INPUT_FLAG_HW_AV_SYNC);
}
const unsigned int config_mask = AUDIO_PORT_CONFIG_SAMPLE_RATE |
AUDIO_PORT_CONFIG_CHANNEL_MASK | AUDIO_PORT_CONFIG_FORMAT | AUDIO_PORT_CONFIG_FLAGS;
sinkConfig->config_mask |= config_mask;
sourceConfig->config_mask |= config_mask;
return NO_ERROR;
}
PatchBuilder AudioPolicyManager::buildMsdPatch(bool msdIsSource,
const sp<DeviceDescriptor> &device) const
{
PatchBuilder patchBuilder;
sp<HwModule> msdModule = mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD);
ALOG_ASSERT(msdModule != nullptr, "MSD module not available");
sp<HwModule> deviceModule = mHwModules.getModuleForDevice(device, AUDIO_FORMAT_DEFAULT);
if (deviceModule == nullptr) {
ALOGE("%s() unable to get module for %s", __func__, device->toString().c_str());
return patchBuilder;
}
const InputProfileCollection inputProfiles = msdIsSource ?
msdModule->getInputProfiles() : deviceModule->getInputProfiles();
const OutputProfileCollection outputProfiles = msdIsSource ?
deviceModule->getOutputProfiles() : msdModule->getOutputProfiles();
const sp<DeviceDescriptor> sourceDevice = msdIsSource ? getMsdAudioInDevice() : device;
const sp<DeviceDescriptor> sinkDevice = msdIsSource ?
device : getMsdAudioOutDevices().itemAt(0);
patchBuilder.addSource(sourceDevice).addSink(sinkDevice);
audio_port_config sourceConfig = patchBuilder.patch()->sources[0];
audio_port_config sinkConfig = patchBuilder.patch()->sinks[0];
AudioProfileVector sourceProfiles;
AudioProfileVector sinkProfiles;
// TODO: Figure out whether MSD module has HW_AV_SYNC flag set in the AP config file.
// For now, we just forcefully try with HwAvSync first.
for (auto hwAvSync : { true, false }) {
if (getMsdProfiles(hwAvSync, inputProfiles, outputProfiles, sourceDevice, sinkDevice,
sourceProfiles, sinkProfiles) != NO_ERROR) {
continue;
}
if (getBestMsdConfig(hwAvSync, sourceProfiles, sinkProfiles, &sourceConfig,
&sinkConfig) == NO_ERROR) {
// Found a matching config. Re-create PatchBuilder with this config.
return (PatchBuilder()).addSource(sourceConfig).addSink(sinkConfig);
}
}
ALOGV("%s() no matching config found. Fall through to default PCM patch"
" supporting PCM format conversion.", __func__);
return patchBuilder;
}
status_t AudioPolicyManager::setMsdOutputPatches(const DeviceVector *outputDevices) {
DeviceVector devices;
if (outputDevices != nullptr && outputDevices->size() > 0) {
devices.add(*outputDevices);
} else {
// Use media strategy for unspecified output device. This should only
// occur on checkForDeviceAndOutputChanges(). Device connection events may
// therefore invalidate explicit routing requests.
devices = mEngine->getOutputDevicesForAttributes(
attributes_initializer(AUDIO_USAGE_MEDIA), nullptr, false /*fromCache*/);
LOG_ALWAYS_FATAL_IF(devices.isEmpty(), "no output device to set MSD patch");
}
std::vector<PatchBuilder> patchesToCreate;
for (auto i = 0u; i < devices.size(); ++i) {
ALOGV("%s() for device %s", __func__, devices[i]->toString().c_str());
patchesToCreate.push_back(buildMsdPatch(true /*msdIsSource*/, devices[i]));
}
// Retain only the MSD patches associated with outputDevices request.
// Tear down the others, and create new ones as needed.
AudioPatchCollection patchesToRemove = getMsdOutputPatches();
for (auto it = patchesToCreate.begin(); it != patchesToCreate.end(); ) {
auto retainedPatch = false;
for (auto i = 0u; i < patchesToRemove.size(); ++i) {
if (audio_patches_are_equal(it->patch(), &patchesToRemove[i]->mPatch)) {
patchesToRemove.removeItemsAt(i);
retainedPatch = true;
break;
}
}
if (retainedPatch) {
it = patchesToCreate.erase(it);
continue;
}
++it;
}
if (patchesToCreate.size() == 0 && patchesToRemove.size() == 0) {
return NO_ERROR;
}
for (auto i = 0u; i < patchesToRemove.size(); ++i) {
auto &currentPatch = patchesToRemove.valueAt(i);
releaseAudioPatch(currentPatch->getHandle(), mUidCached);
}
status_t status = NO_ERROR;
for (const auto &p : patchesToCreate) {
auto currStatus = installPatch(__func__, -1 /*index*/, nullptr /*patchHandle*/,
p.patch(), 0 /*delayMs*/, mUidCached, nullptr /*patchDescPtr*/);
char message[256];
snprintf(message, sizeof(message), "%s() %s: creating MSD patch from device:IN_BUS to "
"device:%#x (format:%#x channels:%#x samplerate:%d)", __func__,
currStatus == NO_ERROR ? "Success" : "Error",
p.patch()->sinks[0].ext.device.type, p.patch()->sources[0].format,
p.patch()->sources[0].channel_mask, p.patch()->sources[0].sample_rate);
if (currStatus == NO_ERROR) {
ALOGD("%s", message);
} else {
ALOGE("%s", message);
if (status == NO_ERROR) {
status = currStatus;
}
}
}
return status;
}
void AudioPolicyManager::releaseMsdOutputPatches(const DeviceVector& devices) {
AudioPatchCollection msdPatches = getMsdOutputPatches();
for (size_t i = 0; i < msdPatches.size(); i++) {
const auto& patch = msdPatches[i];
for (size_t j = 0; j < patch->mPatch.num_sinks; ++j) {
const struct audio_port_config *sink = &patch->mPatch.sinks[j];
if (sink->type == AUDIO_PORT_TYPE_DEVICE && devices.getDevice(sink->ext.device.type,
String8(sink->ext.device.address), AUDIO_FORMAT_DEFAULT) != nullptr) {
releaseAudioPatch(patch->getHandle(), mUidCached);
break;
}
}
}
}
bool AudioPolicyManager::msdHasPatchesToAllDevices(const AudioDeviceTypeAddrVector& devices) {
DeviceVector devicesToCheck =
mConfig->getOutputDevices().getDevicesFromDeviceTypeAddrVec(devices);
AudioPatchCollection msdPatches = getMsdOutputPatches();
for (size_t i = 0; i < msdPatches.size(); i++) {
const auto& patch = msdPatches[i];
for (size_t j = 0; j < patch->mPatch.num_sinks; ++j) {
const struct audio_port_config *sink = &patch->mPatch.sinks[j];
if (sink->type == AUDIO_PORT_TYPE_DEVICE) {
const auto& foundDevice = devicesToCheck.getDevice(
sink->ext.device.type, String8(sink->ext.device.address), AUDIO_FORMAT_DEFAULT);
if (foundDevice != nullptr) {
devicesToCheck.remove(foundDevice);
if (devicesToCheck.isEmpty()) {
return true;
}
}
}
}
}
return false;
}
audio_io_handle_t AudioPolicyManager::selectOutput(const SortedVector<audio_io_handle_t>& outputs,
audio_output_flags_t flags,
audio_format_t format,
audio_channel_mask_t channelMask,
uint32_t samplingRate,
audio_session_t sessionId)
{
LOG_ALWAYS_FATAL_IF(!(format == AUDIO_FORMAT_INVALID || audio_is_linear_pcm(format)),
"%s called with format %#x", __func__, format);
// Return the output that haptic-generating attached to when 1) session id is specified,
// 2) haptic-generating effect exists for given session id and 3) the output that
// haptic-generating effect attached to is in given outputs.
if (sessionId != AUDIO_SESSION_NONE) {
audio_io_handle_t hapticGeneratingOutput = mEffects.getIoForSession(
sessionId, FX_IID_HAPTICGENERATOR);
if (outputs.indexOf(hapticGeneratingOutput) >= 0) {
return hapticGeneratingOutput;
}
}
// Flags disqualifying an output: the match must happen before calling selectOutput()
static const audio_output_flags_t kExcludedFlags = (audio_output_flags_t)
(AUDIO_OUTPUT_FLAG_HW_AV_SYNC | AUDIO_OUTPUT_FLAG_MMAP_NOIRQ | AUDIO_OUTPUT_FLAG_DIRECT);
// Flags expressing a functional request: must be honored in priority over
// other criteria
static const audio_output_flags_t kFunctionalFlags = (audio_output_flags_t)
(AUDIO_OUTPUT_FLAG_VOIP_RX | AUDIO_OUTPUT_FLAG_INCALL_MUSIC |
AUDIO_OUTPUT_FLAG_TTS | AUDIO_OUTPUT_FLAG_DIRECT_PCM | AUDIO_OUTPUT_FLAG_ULTRASOUND |
AUDIO_OUTPUT_FLAG_SPATIALIZER);
// Flags expressing a performance request: have lower priority than serving
// requested sampling rate or channel mask
static const audio_output_flags_t kPerformanceFlags = (audio_output_flags_t)
(AUDIO_OUTPUT_FLAG_FAST | AUDIO_OUTPUT_FLAG_DEEP_BUFFER |
AUDIO_OUTPUT_FLAG_RAW | AUDIO_OUTPUT_FLAG_SYNC);
const audio_output_flags_t functionalFlags =
(audio_output_flags_t)(flags & kFunctionalFlags);
const audio_output_flags_t performanceFlags =
(audio_output_flags_t)(flags & kPerformanceFlags);
audio_io_handle_t bestOutput = (outputs.size() == 0) ? AUDIO_IO_HANDLE_NONE : outputs[0];
// select one output among several that provide a path to a particular device or set of
// devices (the list was previously build by getOutputsForDevices()).
// The priority is as follows:
// 1: the output supporting haptic playback when requesting haptic playback
// 2: the output with the highest number of requested functional flags
// with tiebreak preferring the minimum number of extra functional flags
// (see b/200293124, the incorrect selection of AUDIO_OUTPUT_FLAG_VOIP_RX).
// 3: the output supporting the exact channel mask
// 4: the output with a higher channel count than requested
// 5: the output with the highest sampling rate if the requested sample rate is
// greater than default sampling rate
// 6: the output with the highest number of requested performance flags
// 7: the output with the bit depth the closest to the requested one
// 8: the primary output
// 9: the first output in the list
// matching criteria values in priority order for best matching output so far
std::vector<uint32_t> bestMatchCriteria(8, 0);
const uint32_t channelCount = audio_channel_count_from_out_mask(channelMask);
const uint32_t hapticChannelCount = audio_channel_count_from_out_mask(
channelMask & AUDIO_CHANNEL_HAPTIC_ALL);
for (audio_io_handle_t output : outputs) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.valueFor(output);
// matching criteria values in priority order for current output
std::vector<uint32_t> currentMatchCriteria(8, 0);
if (outputDesc->isDuplicated()) {
continue;
}
if ((kExcludedFlags & outputDesc->mFlags) != 0) {
continue;
}
// If haptic channel is specified, use the haptic output if present.
// When using haptic output, same audio format and sample rate are required.
const uint32_t outputHapticChannelCount = audio_channel_count_from_out_mask(
outputDesc->getChannelMask() & AUDIO_CHANNEL_HAPTIC_ALL);
if ((hapticChannelCount == 0) != (outputHapticChannelCount == 0)) {
continue;
}
if (outputHapticChannelCount >= hapticChannelCount
&& format == outputDesc->getFormat()
&& samplingRate == outputDesc->getSamplingRate()) {
currentMatchCriteria[0] = outputHapticChannelCount;
}
// functional flags match
const int matchingFunctionalFlags =
__builtin_popcount(outputDesc->mFlags & functionalFlags);
const int totalFunctionalFlags =
__builtin_popcount(outputDesc->mFlags & kFunctionalFlags);
// Prefer matching functional flags, but subtract unnecessary functional flags.
currentMatchCriteria[1] = 100 * (matchingFunctionalFlags + 1) - totalFunctionalFlags;
// channel mask and channel count match
uint32_t outputChannelCount = audio_channel_count_from_out_mask(
outputDesc->getChannelMask());
if (channelMask != AUDIO_CHANNEL_NONE && channelCount > 2 &&
channelCount <= outputChannelCount) {
if ((audio_channel_mask_get_representation(channelMask) ==
audio_channel_mask_get_representation(outputDesc->getChannelMask())) &&
((channelMask & outputDesc->getChannelMask()) == channelMask)) {
currentMatchCriteria[2] = outputChannelCount;
}
currentMatchCriteria[3] = outputChannelCount;
}
// sampling rate match
if (samplingRate > SAMPLE_RATE_HZ_DEFAULT) {
currentMatchCriteria[4] = outputDesc->getSamplingRate();
}
// performance flags match
currentMatchCriteria[5] = popcount(outputDesc->mFlags & performanceFlags);
// format match
if (format != AUDIO_FORMAT_INVALID) {
currentMatchCriteria[6] =
PolicyAudioPort::kFormatDistanceMax -
PolicyAudioPort::formatDistance(format, outputDesc->getFormat());
}
// primary output match
currentMatchCriteria[7] = outputDesc->mFlags & AUDIO_OUTPUT_FLAG_PRIMARY;
// compare match criteria by priority then value
if (std::lexicographical_compare(bestMatchCriteria.begin(), bestMatchCriteria.end(),
currentMatchCriteria.begin(), currentMatchCriteria.end())) {
bestMatchCriteria = currentMatchCriteria;
bestOutput = output;
std::stringstream result;
std::copy(bestMatchCriteria.begin(), bestMatchCriteria.end(),
std::ostream_iterator<int>(result, " "));
ALOGV("%s new bestOutput %d criteria %s",
__func__, bestOutput, result.str().c_str());
}
}
return bestOutput;
}
status_t AudioPolicyManager::startOutput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputForClient(portId);
if (outputDesc == 0) {
ALOGW("startOutput() no output for client %d", portId);
return BAD_VALUE;
}
sp<TrackClientDescriptor> client = outputDesc->getClient(portId);
ALOGV("startOutput() output %d, stream %d, session %d",
outputDesc->mIoHandle, client->stream(), client->session());
status_t status = outputDesc->start();
if (status != NO_ERROR) {
return status;
}
uint32_t delayMs;
status = startSource(outputDesc, client, &delayMs);
if (status != NO_ERROR) {
outputDesc->stop();
if (status == DEAD_OBJECT) {
sp<SwAudioOutputDescriptor> desc =
reopenOutput(outputDesc, nullptr /*config*/, AUDIO_OUTPUT_FLAG_NONE, __func__);
if (desc == nullptr) {
// This is not common, it may indicate something wrong with the HAL.
ALOGE("%s unable to open output with default config", __func__);
return status;
}
desc->mUsePreferredMixerAttributes = true;
}
return status;
}
// If the client is the first one active on preferred mixer parameters, reopen the output
// if the current mixer parameters doesn't match the preferred one.
if (outputDesc->devices().size() == 1) {
sp<PreferredMixerAttributesInfo> info = getPreferredMixerAttributesInfo(
outputDesc->devices()[0]->getId(), client->strategy());
if (info != nullptr && info->getUid() == client->uid()) {
if (info->getActiveClientCount() == 0 && !outputDesc->isConfigurationMatched(
info->getConfigBase(), info->getFlags())) {
stopSource(outputDesc, client);
outputDesc->stop();
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.channel_mask = info->getConfigBase().channel_mask;
config.sample_rate = info->getConfigBase().sample_rate;
config.format = info->getConfigBase().format;
sp<SwAudioOutputDescriptor> desc =
reopenOutput(outputDesc, &config, info->getFlags(), __func__);
if (desc == nullptr) {
return BAD_VALUE;
}
desc->mUsePreferredMixerAttributes = true;
// Intentionally return error to let the client side resending request for
// creating and starting.
return DEAD_OBJECT;
}
info->increaseActiveClient();
if (info->getActiveClientCount() == 1 &&
(info->getFlags() & AUDIO_OUTPUT_FLAG_BIT_PERFECT) != AUDIO_OUTPUT_FLAG_NONE) {
// If it is first bit-perfect client, reroute all clients that will be routed to
// the bit-perfect sink so that it is guaranteed only bit-perfect stream is active.
PortHandleVector clientsToInvalidate;
for (size_t i = 0; i < mOutputs.size(); i++) {
if (mOutputs[i] == outputDesc ||
mOutputs[i]->devices().filter(outputDesc->devices()).isEmpty()) {
continue;
}
for (const auto& c : mOutputs[i]->getClientIterable()) {
clientsToInvalidate.push_back(c->portId());
}
}
if (!clientsToInvalidate.empty()) {
ALOGD("%s Invalidate clients due to first bit-perfect client started",
__func__);
mpClientInterface->invalidateTracks(clientsToInvalidate);
}
}
}
}
if (client->hasPreferredDevice()) {
// playback activity with preferred device impacts routing occurred, inform upper layers
mpClientInterface->onRoutingUpdated();
}
if (delayMs != 0) {
usleep(delayMs * 1000);
}
return status;
}
bool AudioPolicyManager::isLeUnicastActive() const {
if (isInCall()) {
return true;
}
return isAnyDeviceTypeActive(getAudioDeviceOutLeAudioUnicastSet());
}
bool AudioPolicyManager::isAnyDeviceTypeActive(const DeviceTypeSet& deviceTypes) const {
if (mAvailableOutputDevices.getDevicesFromTypes(deviceTypes).isEmpty()) {
return false;
}
bool active = mOutputs.isAnyDeviceTypeActive(deviceTypes);
ALOGV("%s active %d", __func__, active);
return active;
}
status_t AudioPolicyManager::startSource(const sp<SwAudioOutputDescriptor>& outputDesc,
const sp<TrackClientDescriptor>& client,
uint32_t *delayMs)
{
// cannot start playback of STREAM_TTS if any other output is being used
uint32_t beaconMuteLatency = 0;
*delayMs = 0;
audio_stream_type_t stream = client->stream();
auto clientVolSrc = client->volumeSource();
auto clientStrategy = client->strategy();
auto clientAttr = client->attributes();
if (stream == AUDIO_STREAM_TTS) {
ALOGV("\t found BEACON stream");
if (!mTtsOutputAvailable && mOutputs.isAnyOutputActive(
toVolumeSource(AUDIO_STREAM_TTS, false) /*sourceToIgnore*/)) {
return INVALID_OPERATION;
} else {
beaconMuteLatency = handleEventForBeacon(STARTING_BEACON);
}
} else {
// some playback other than beacon starts
beaconMuteLatency = handleEventForBeacon(STARTING_OUTPUT);
}
// force device change if the output is inactive and no audio patch is already present.
// check active before incrementing usage count
bool force = !outputDesc->isActive() && !outputDesc->isRouted();
DeviceVector devices;
sp<AudioPolicyMix> policyMix = outputDesc->mPolicyMix.promote();
const char *address = NULL;
if (policyMix != nullptr) {
audio_devices_t newDeviceType;
address = policyMix->mDeviceAddress.c_str();
if ((policyMix->mRouteFlags & MIX_ROUTE_FLAG_LOOP_BACK) == MIX_ROUTE_FLAG_LOOP_BACK) {
newDeviceType = AUDIO_DEVICE_OUT_REMOTE_SUBMIX;
} else {
newDeviceType = policyMix->mDeviceType;
}
sp device = mAvailableOutputDevices.getDevice(newDeviceType, String8(address),
AUDIO_FORMAT_DEFAULT);
ALOG_ASSERT(device, "%s: no device found t=%u, a=%s", __func__, newDeviceType, address);
devices.add(device);
}
// requiresMuteCheck is false when we can bypass mute strategy.
// It covers a common case when there is no materially active audio
// and muting would result in unnecessary delay and dropped audio.
const uint32_t outputLatencyMs = outputDesc->latency();
bool requiresMuteCheck = outputDesc->isActive(outputLatencyMs * 2); // account for drain
bool wasLeUnicastActive = isLeUnicastActive();
// increment usage count for this stream on the requested output:
// NOTE that the usage count is the same for duplicated output and hardware output which is
// necessary for a correct control of hardware output routing by startOutput() and stopOutput()
outputDesc->setClientActive(client, true);
if (client->hasPreferredDevice(true)) {
if (outputDesc->sameExclusivePreferredDevicesCount() > 0) {
// Preferred device may be exclusive, use only if no other active clients on this output
devices = DeviceVector(
mAvailableOutputDevices.getDeviceFromId(client->preferredDeviceId()));
} else {
devices = getNewOutputDevices(outputDesc, false /*fromCache*/);
}
if (devices != outputDesc->devices()) {
checkStrategyRoute(clientStrategy, outputDesc->mIoHandle);
}
}
if (followsSameRouting(clientAttr, attributes_initializer(AUDIO_USAGE_MEDIA))) {
selectOutputForMusicEffects();
}
if (outputDesc->getActivityCount(clientVolSrc) == 1 || !devices.isEmpty()) {
// starting an output being rerouted?
if (devices.isEmpty()) {
devices = getNewOutputDevices(outputDesc, false /*fromCache*/);
}
bool shouldWait =
(followsSameRouting(clientAttr, attributes_initializer(AUDIO_USAGE_ALARM)) ||
followsSameRouting(clientAttr, attributes_initializer(AUDIO_USAGE_NOTIFICATION)) ||
(beaconMuteLatency > 0));
uint32_t waitMs = beaconMuteLatency;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc != outputDesc) {
// An output has a shared device if
// - managed by the same hw module
// - supports the currently selected device
const bool sharedDevice = outputDesc->sharesHwModuleWith(desc)
&& (!desc->filterSupportedDevices(devices).isEmpty());
// force a device change if any other output is:
// - managed by the same hw module
// - supports currently selected device
// - has a current device selection that differs from selected device.
// - has an active audio patch
// In this case, the audio HAL must receive the new device selection so that it can
// change the device currently selected by the other output.
if (sharedDevice &&
desc->devices() != devices &&
desc->getPatchHandle() != AUDIO_PATCH_HANDLE_NONE) {
force = true;
}
// wait for audio on other active outputs to be presented when starting
// a notification so that audio focus effect can propagate, or that a mute/unmute
// event occurred for beacon
const uint32_t latencyMs = desc->latency();
const bool isActive = desc->isActive(latencyMs * 2); // account for drain
if (shouldWait && isActive && (waitMs < latencyMs)) {
waitMs = latencyMs;
}
// Require mute check if another output is on a shared device
// and currently active to have proper drain and avoid pops.
// Note restoring AudioTracks onto this output needs to invoke
// a volume ramp if there is no mute.
requiresMuteCheck |= sharedDevice && isActive;
}
}
if (outputDesc->mUsePreferredMixerAttributes && devices != outputDesc->devices()) {
// If the output is open with preferred mixer attributes, but the routed device is
// changed when calling this function, returning DEAD_OBJECT to indicate routing
// changed.
return DEAD_OBJECT;
}
const uint32_t muteWaitMs =
setOutputDevices(__func__, outputDesc, devices, force, 0, nullptr,
requiresMuteCheck);
// apply volume rules for current stream and device if necessary
auto &curves = getVolumeCurves(client->attributes());
if (NO_ERROR != checkAndSetVolume(curves, client->volumeSource(),
curves.getVolumeIndex(outputDesc->devices().types()),
outputDesc,
outputDesc->devices().types(), 0 /*delay*/,
outputDesc->useHwGain() /*force*/)) {
// request AudioService to reinitialize the volume curves asynchronously
ALOGE("checkAndSetVolume failed, requesting volume range init");
mpClientInterface->onVolumeRangeInitRequest();
};
// update the outputs if starting an output with a stream that can affect notification
// routing
handleNotificationRoutingForStream(stream);
// force reevaluating accessibility routing when ringtone or alarm starts
if (followsSameRouting(clientAttr, attributes_initializer(AUDIO_USAGE_ALARM))) {
invalidateStreams({AUDIO_STREAM_ACCESSIBILITY});
}
if (waitMs > muteWaitMs) {
*delayMs = waitMs - muteWaitMs;
}
// FIXME: A device change (muteWaitMs > 0) likely introduces a volume change.
// A volume change enacted by APM with 0 delay is not synchronous, as it goes
// via AudioCommandThread to AudioFlinger. Hence it is possible that the volume
// change occurs after the MixerThread starts and causes a stream volume
// glitch.
//
// We do not introduce additional delay here.
}
if (stream == AUDIO_STREAM_ENFORCED_AUDIBLE &&
mEngine->getForceUse(
AUDIO_POLICY_FORCE_FOR_SYSTEM) == AUDIO_POLICY_FORCE_SYSTEM_ENFORCED) {
setStrategyMute(streamToStrategy(AUDIO_STREAM_ALARM), true, outputDesc);
}
// Automatically enable the remote submix input when output is started on a re routing mix
// of type MIX_TYPE_RECORDERS
if (isSingleDeviceType(devices.types(), &audio_is_remote_submix_device) &&
policyMix != NULL && policyMix->mMixType == MIX_TYPE_RECORDERS) {
setDeviceConnectionStateInt(AUDIO_DEVICE_IN_REMOTE_SUBMIX,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
address,
"remote-submix",
AUDIO_FORMAT_DEFAULT);
}
checkLeBroadcastRoutes(wasLeUnicastActive, outputDesc, *delayMs);
return NO_ERROR;
}
void AudioPolicyManager::checkLeBroadcastRoutes(bool wasUnicastActive,
sp<SwAudioOutputDescriptor> ignoredOutput, uint32_t delayMs) {
bool isUnicastActive = isLeUnicastActive();
if (wasUnicastActive != isUnicastActive) {
std::map<audio_io_handle_t, DeviceVector> outputsToReopen;
//reroute all outputs routed to LE broadcast if LE unicast activy changed on any output
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc != ignoredOutput && desc->isActive()
&& ((isUnicastActive &&
!desc->devices().
getDevicesFromType(AUDIO_DEVICE_OUT_BLE_BROADCAST).isEmpty())
|| (wasUnicastActive &&
!desc->devices().getDevicesFromTypes(
getAudioDeviceOutLeAudioUnicastSet()).isEmpty()))) {
DeviceVector newDevices = getNewOutputDevices(desc, false /*fromCache*/);
bool force = desc->devices() != newDevices;
if (desc->mUsePreferredMixerAttributes && force) {
// If the device is using preferred mixer attributes, the output need to reopen
// with default configuration when the new selected devices are different from
// current routing devices.
outputsToReopen.emplace(mOutputs.keyAt(i), newDevices);
continue;
}
setOutputDevices(__func__, desc, newDevices, force, delayMs);
// re-apply device specific volume if not done by setOutputDevice()
if (!force) {
applyStreamVolumes(desc, newDevices.types(), delayMs);
}
}
}
reopenOutputsWithDevices(outputsToReopen);
}
}
status_t AudioPolicyManager::stopOutput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputForClient(portId);
if (outputDesc == 0) {
ALOGW("stopOutput() no output for client %d", portId);
return BAD_VALUE;
}
sp<TrackClientDescriptor> client = outputDesc->getClient(portId);
if (client->hasPreferredDevice(true)) {
// playback activity with preferred device impacts routing occurred, inform upper layers
mpClientInterface->onRoutingUpdated();
}
ALOGV("stopOutput() output %d, stream %d, session %d",
outputDesc->mIoHandle, client->stream(), client->session());
status_t status = stopSource(outputDesc, client);
if (status == NO_ERROR ) {
outputDesc->stop();
} else {
return status;
}
if (outputDesc->devices().size() == 1) {
sp<PreferredMixerAttributesInfo> info = getPreferredMixerAttributesInfo(
outputDesc->devices()[0]->getId(), client->strategy());
if (info != nullptr && info->getUid() == client->uid()) {
info->decreaseActiveClient();
if (info->getActiveClientCount() == 0) {
reopenOutput(outputDesc, nullptr /*config*/, AUDIO_OUTPUT_FLAG_NONE, __func__);
}
}
}
return status;
}
status_t AudioPolicyManager::stopSource(const sp<SwAudioOutputDescriptor>& outputDesc,
const sp<TrackClientDescriptor>& client)
{
// always handle stream stop, check which stream type is stopping
audio_stream_type_t stream = client->stream();
auto clientVolSrc = client->volumeSource();
bool wasLeUnicastActive = isLeUnicastActive();
handleEventForBeacon(stream == AUDIO_STREAM_TTS ? STOPPING_BEACON : STOPPING_OUTPUT);
if (outputDesc->getActivityCount(clientVolSrc) > 0) {
if (outputDesc->getActivityCount(clientVolSrc) == 1) {
// Automatically disable the remote submix input when output is stopped on a
// re routing mix of type MIX_TYPE_RECORDERS
sp<AudioPolicyMix> policyMix = outputDesc->mPolicyMix.promote();
if (isSingleDeviceType(
outputDesc->devices().types(), &audio_is_remote_submix_device) &&
policyMix != nullptr &&
policyMix->mMixType == MIX_TYPE_RECORDERS) {
setDeviceConnectionStateInt(AUDIO_DEVICE_IN_REMOTE_SUBMIX,
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
policyMix->mDeviceAddress,
"remote-submix", AUDIO_FORMAT_DEFAULT);
}
}
bool forceDeviceUpdate = false;
if (client->hasPreferredDevice(true) &&
outputDesc->sameExclusivePreferredDevicesCount() < 2) {
checkStrategyRoute(client->strategy(), AUDIO_IO_HANDLE_NONE);
forceDeviceUpdate = true;
}
// decrement usage count of this stream on the output
outputDesc->setClientActive(client, false);
// store time at which the stream was stopped - see isStreamActive()
if (outputDesc->getActivityCount(clientVolSrc) == 0 || forceDeviceUpdate) {
outputDesc->setStopTime(client, systemTime());
DeviceVector newDevices = getNewOutputDevices(outputDesc, false /*fromCache*/);
// If the routing does not change, if an output is routed on a device using HwGain
// (aka setAudioPortConfig) and there are still active clients following different
// volume group(s), force reapply volume
bool requiresVolumeCheck = outputDesc->getActivityCount(clientVolSrc) == 0 &&
outputDesc->useHwGain() && outputDesc->isAnyActive(VOLUME_SOURCE_NONE);
// delay the device switch by twice the latency because stopOutput() is executed when
// the track stop() command is received and at that time the audio track buffer can
// still contain data that needs to be drained. The latency only covers the audio HAL
// and kernel buffers. Also the latency does not always include additional delay in the
// audio path (audio DSP, CODEC ...)
setOutputDevices(__func__, outputDesc, newDevices, false, outputDesc->latency()*2,
nullptr, true /*requiresMuteCheck*/, requiresVolumeCheck);
// force restoring the device selection on other active outputs if it differs from the
// one being selected for this output
std::map<audio_io_handle_t, DeviceVector> outputsToReopen;
uint32_t delayMs = outputDesc->latency()*2;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc != outputDesc &&
desc->isActive() &&
outputDesc->sharesHwModuleWith(desc) &&
(newDevices != desc->devices())) {
DeviceVector newDevices2 = getNewOutputDevices(desc, false /*fromCache*/);
bool force = desc->devices() != newDevices2;
if (desc->mUsePreferredMixerAttributes && force) {
// If the device is using preferred mixer attributes, the output need to
// reopen with default configuration when the new selected devices are
// different from current routing devices.
outputsToReopen.emplace(mOutputs.keyAt(i), newDevices2);
continue;
}
setOutputDevices(__func__, desc, newDevices2, force, delayMs);
// re-apply device specific volume if not done by setOutputDevice()
if (!force) {
applyStreamVolumes(desc, newDevices2.types(), delayMs);
}
}
}
reopenOutputsWithDevices(outputsToReopen);
// update the outputs if stopping one with a stream that can affect notification routing
handleNotificationRoutingForStream(stream);
}
if (stream == AUDIO_STREAM_ENFORCED_AUDIBLE &&
mEngine->getForceUse(AUDIO_POLICY_FORCE_FOR_SYSTEM) == AUDIO_POLICY_FORCE_SYSTEM_ENFORCED) {
setStrategyMute(streamToStrategy(AUDIO_STREAM_ALARM), false, outputDesc);
}
if (followsSameRouting(client->attributes(), attributes_initializer(AUDIO_USAGE_MEDIA))) {
selectOutputForMusicEffects();
}
checkLeBroadcastRoutes(wasLeUnicastActive, outputDesc, outputDesc->latency()*2);
return NO_ERROR;
} else {
ALOGW("stopOutput() refcount is already 0");
return INVALID_OPERATION;
}
}
bool AudioPolicyManager::releaseOutput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputForClient(portId);
if (outputDesc == 0) {
// If an output descriptor is closed due to a device routing change,
// then there are race conditions with releaseOutput from tracks
// that may be destroyed (with no PlaybackThread) or a PlaybackThread
// destroyed shortly thereafter.
//
// Here we just log a warning, instead of a fatal error.
ALOGW("releaseOutput() no output for client %d", portId);
return false;
}
ALOGV("releaseOutput() %d", outputDesc->mIoHandle);
sp<TrackClientDescriptor> client = outputDesc->getClient(portId);
if (outputDesc->isClientActive(client)) {
ALOGW("releaseOutput() inactivates portId %d in good faith", portId);
stopOutput(portId);
}
if (outputDesc->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) {
if (outputDesc->mDirectOpenCount <= 0) {
ALOGW("releaseOutput() invalid open count %d for output %d",
outputDesc->mDirectOpenCount, outputDesc->mIoHandle);
return false;
}
if (--outputDesc->mDirectOpenCount == 0) {
closeOutput(outputDesc->mIoHandle);
mpClientInterface->onAudioPortListUpdate();
}
}
outputDesc->removeClient(portId);
if (outputDesc->mPendingReopenToQueryProfiles && outputDesc->getClientCount() == 0) {
// The output is pending reopened to query dynamic profiles and
// there is no active clients
closeOutput(outputDesc->mIoHandle);
sp<SwAudioOutputDescriptor> newOutputDesc = openOutputWithProfileAndDevice(
outputDesc->mProfile, mEngine->getActiveMediaDevices(mAvailableOutputDevices));
if (newOutputDesc == nullptr) {
ALOGE("%s failed to open output", __func__);
}
return true;
}
return false;
}
status_t AudioPolicyManager::getInputForAttr(const audio_attributes_t *attr,
audio_io_handle_t *input,
audio_unique_id_t riid,
audio_session_t session,
const AttributionSourceState& attributionSource,
audio_config_base_t *config,
audio_input_flags_t flags,
audio_port_handle_t *selectedDeviceId,
input_type_t *inputType,
audio_port_handle_t *portId)
{
ALOGV("%s() source %d, sampling rate %d, format %#x, channel mask %#x, session %d, "
"flags %#x attributes=%s requested device ID %d",
__func__, attr->source, config->sample_rate, config->format, config->channel_mask,
session, flags, toString(*attr).c_str(), *selectedDeviceId);
status_t status = NO_ERROR;
audio_attributes_t attributes = *attr;
sp<AudioPolicyMix> policyMix;
sp<DeviceDescriptor> device;
sp<AudioInputDescriptor> inputDesc;
sp<AudioInputDescriptor> previousInputDesc;
sp<RecordClientDescriptor> clientDesc;
audio_port_handle_t requestedDeviceId = *selectedDeviceId;
uid_t uid = VALUE_OR_RETURN_STATUS(aidl2legacy_int32_t_uid_t(attributionSource.uid));
bool isSoundTrigger;
// The supplied portId must be AUDIO_PORT_HANDLE_NONE
if (*portId != AUDIO_PORT_HANDLE_NONE) {
return INVALID_OPERATION;
}
if (attr->source == AUDIO_SOURCE_DEFAULT) {
attributes.source = AUDIO_SOURCE_MIC;
}
// Explicit routing?
sp<DeviceDescriptor> explicitRoutingDevice =
mAvailableInputDevices.getDeviceFromId(*selectedDeviceId);
// special case for mmap capture: if an input IO handle is specified, we reuse this input if
// possible
if ((flags & AUDIO_INPUT_FLAG_MMAP_NOIRQ) == AUDIO_INPUT_FLAG_MMAP_NOIRQ &&
*input != AUDIO_IO_HANDLE_NONE) {
ssize_t index = mInputs.indexOfKey(*input);
if (index < 0) {
ALOGW("getInputForAttr() unknown MMAP input %d", *input);
status = BAD_VALUE;
goto error;
}
sp<AudioInputDescriptor> inputDesc = mInputs.valueAt(index);
RecordClientVector clients = inputDesc->getClientsForSession(session);
if (clients.size() == 0) {
ALOGW("getInputForAttr() unknown session %d on input %d", session, *input);
status = BAD_VALUE;
goto error;
}
// For MMAP mode, the first call to getInputForAttr() is made on behalf of audioflinger.
// The second call is for the first active client and sets the UID. Any further call
// corresponds to a new client and is only permitted from the same UID.
// If the first UID is silenced, allow a new UID connection and replace with new UID
if (clients.size() > 1) {
for (const auto& client : clients) {
// The client map is ordered by key values (portId) and portIds are allocated
// incrementaly. So the first client in this list is the one opened by audio flinger
// when the mmap stream is created and should be ignored as it does not correspond
// to an actual client
if (client == *clients.cbegin()) {
continue;
}
if (uid != client->uid() && !client->isSilenced()) {
ALOGW("getInputForAttr() bad uid %d for client %d uid %d",
uid, client->portId(), client->uid());
status = INVALID_OPERATION;
goto error;
}
}
}
*inputType = API_INPUT_LEGACY;
device = inputDesc->getDevice();
ALOGV("%s reusing MMAP input %d for session %d", __FUNCTION__, *input, session);
goto exit;
}
*input = AUDIO_IO_HANDLE_NONE;
*inputType = API_INPUT_INVALID;
if (attributes.source == AUDIO_SOURCE_REMOTE_SUBMIX &&
extractAddressFromAudioAttributes(attributes).has_value()) {
status = mPolicyMixes.getInputMixForAttr(attributes, &policyMix);
if (status != NO_ERROR) {
ALOGW("%s could not find input mix for attr %s",
__func__, toString(attributes).c_str());
goto error;
}
device = mAvailableInputDevices.getDevice(AUDIO_DEVICE_IN_REMOTE_SUBMIX,
String8(attr->tags + strlen("addr=")),
AUDIO_FORMAT_DEFAULT);
if (device == nullptr) {
ALOGW("%s could not find in Remote Submix device for source %d, tags %s",
__func__, attributes.source, attributes.tags);
status = BAD_VALUE;
goto error;
}
if (is_mix_loopback_render(policyMix->mRouteFlags)) {
*inputType = API_INPUT_MIX_PUBLIC_CAPTURE_PLAYBACK;
} else {
*inputType = API_INPUT_MIX_EXT_POLICY_REROUTE;
}
} else {
if (explicitRoutingDevice != nullptr) {
device = explicitRoutingDevice;
} else {
// Prevent from storing invalid requested device id in clients
requestedDeviceId = AUDIO_PORT_HANDLE_NONE;
device = mEngine->getInputDeviceForAttributes(attributes, uid, session, &policyMix);
ALOGV_IF(device != nullptr, "%s found device type is 0x%X",
__FUNCTION__, device->type());
}
if (device == nullptr) {
ALOGW("getInputForAttr() could not find device for source %d", attributes.source);
status = BAD_VALUE;
goto error;
}
if (device->type() == AUDIO_DEVICE_IN_ECHO_REFERENCE) {
*inputType = API_INPUT_MIX_CAPTURE;
} else if (policyMix) {
ALOG_ASSERT(policyMix->mMixType == MIX_TYPE_RECORDERS, "Invalid Mix Type");
// there is an external policy, but this input is attached to a mix of recorders,
// meaning it receives audio injected into the framework, so the recorder doesn't
// know about it and is therefore considered "legacy"
*inputType = API_INPUT_LEGACY;
} else if (audio_is_remote_submix_device(device->type())) {
*inputType = API_INPUT_MIX_CAPTURE;
} else if (device->type() == AUDIO_DEVICE_IN_TELEPHONY_RX) {
*inputType = API_INPUT_TELEPHONY_RX;
} else {
*inputType = API_INPUT_LEGACY;
}
}
*input = getInputForDevice(device, session, attributes, config, flags, policyMix);
if (*input == AUDIO_IO_HANDLE_NONE) {
status = INVALID_OPERATION;
AudioProfileVector profiles;
status_t ret = getProfilesForDevices(
DeviceVector(device), profiles, flags, true /*isInput*/);
if (ret == NO_ERROR && !profiles.empty()) {
const auto channels = profiles[0]->getChannels();
if (!channels.empty() && (channels.find(config->channel_mask) == channels.end())) {
config->channel_mask = *channels.begin();
}
const auto sampleRates = profiles[0]->getSampleRates();
if (!sampleRates.empty() &&
(sampleRates.find(config->sample_rate) == sampleRates.end())) {
config->sample_rate = *sampleRates.begin();
}
config->format = profiles[0]->getFormat();
}
goto error;
}
exit:
*selectedDeviceId = mAvailableInputDevices.contains(device) ?
device->getId() : AUDIO_PORT_HANDLE_NONE;
isSoundTrigger = attributes.source == AUDIO_SOURCE_HOTWORD &&
mSoundTriggerSessions.indexOfKey(session) >= 0;
*portId = PolicyAudioPort::getNextUniqueId();
clientDesc = new RecordClientDescriptor(*portId, riid, uid, session, attributes, *config,
requestedDeviceId, attributes.source, flags,
isSoundTrigger);
inputDesc = mInputs.valueFor(*input);
// Move (if found) effect for the client session to its input
mEffects.moveEffectsForIo(session, *input, &mInputs, mpClientInterface);
inputDesc->addClient(clientDesc);
ALOGV("getInputForAttr() returns input %d type %d selectedDeviceId %d for port ID %d",
*input, *inputType, *selectedDeviceId, *portId);
return NO_ERROR;
error:
return status;
}
audio_io_handle_t AudioPolicyManager::getInputForDevice(const sp<DeviceDescriptor> &device,
audio_session_t session,
const audio_attributes_t &attributes,
audio_config_base_t *config,
audio_input_flags_t flags,
const sp<AudioPolicyMix> &policyMix)
{
audio_io_handle_t input = AUDIO_IO_HANDLE_NONE;
audio_source_t halInputSource = attributes.source;
bool isSoundTrigger = false;
if (attributes.source == AUDIO_SOURCE_HOTWORD) {
ssize_t index = mSoundTriggerSessions.indexOfKey(session);
if (index >= 0) {
input = mSoundTriggerSessions.valueFor(session);
isSoundTrigger = true;
flags = (audio_input_flags_t)(flags | AUDIO_INPUT_FLAG_HW_HOTWORD);
ALOGV("SoundTrigger capture on session %d input %d", session, input);
} else {
halInputSource = AUDIO_SOURCE_VOICE_RECOGNITION;
}
} else if (attributes.source == AUDIO_SOURCE_VOICE_COMMUNICATION &&
audio_is_linear_pcm(config->format)) {
flags = (audio_input_flags_t)(flags | AUDIO_INPUT_FLAG_VOIP_TX);
}
if (attributes.source == AUDIO_SOURCE_ULTRASOUND) {
flags = (audio_input_flags_t)(flags | AUDIO_INPUT_FLAG_ULTRASOUND);
}
// sampling rate and flags may be updated by getInputProfile
uint32_t profileSamplingRate = (config->sample_rate == 0) ?
SAMPLE_RATE_HZ_DEFAULT : config->sample_rate;
audio_format_t profileFormat = config->format;
audio_channel_mask_t profileChannelMask = config->channel_mask;
audio_input_flags_t profileFlags = flags;
// find a compatible input profile (not necessarily identical in parameters)
sp<IOProfile> profile = getInputProfile(
device, profileSamplingRate, profileFormat, profileChannelMask, profileFlags);
if (profile == nullptr) {
return input;
}
// Pick input sampling rate if not specified by client
uint32_t samplingRate = config->sample_rate;
if (samplingRate == 0) {
samplingRate = profileSamplingRate;
}
if (profile->getModuleHandle() == 0) {
ALOGE("getInputForAttr(): HW module %s not opened", profile->getModuleName());
return input;
}
// Reuse an already opened input if a client with the same session ID already exists
// on that input
for (size_t i = 0; i < mInputs.size(); i++) {
sp <AudioInputDescriptor> desc = mInputs.valueAt(i);
if (desc->mProfile != profile) {
continue;
}
RecordClientVector clients = desc->clientsList();
for (const auto &client : clients) {
if (session == client->session()) {
return desc->mIoHandle;
}
}
}
if (!profile->canOpenNewIo()) {
for (size_t i = 0; i < mInputs.size(); ) {
sp<AudioInputDescriptor> desc = mInputs.valueAt(i);
if (desc->mProfile != profile) {
i++;
continue;
}
// if sound trigger, reuse input if used by other sound trigger on same session
// else
// reuse input if active client app is not in IDLE state
//
RecordClientVector clients = desc->clientsList();
bool doClose = false;
for (const auto& client : clients) {
if (isSoundTrigger != client->isSoundTrigger()) {
continue;
}
if (client->isSoundTrigger()) {
if (session == client->session()) {
return desc->mIoHandle;
}
continue;
}
if (client->active() && client->appState() != APP_STATE_IDLE) {
return desc->mIoHandle;
}
doClose = true;
}
if (doClose) {
closeInput(desc->mIoHandle);
} else {
i++;
}
}
}
sp<AudioInputDescriptor> inputDesc = new AudioInputDescriptor(profile, mpClientInterface);
audio_config_t lConfig = AUDIO_CONFIG_INITIALIZER;
lConfig.sample_rate = profileSamplingRate;
lConfig.channel_mask = profileChannelMask;
lConfig.format = profileFormat;
status_t status = inputDesc->open(&lConfig, device, halInputSource, profileFlags, &input);
// only accept input with the exact requested set of parameters
if (status != NO_ERROR || input == AUDIO_IO_HANDLE_NONE ||
(profileSamplingRate != lConfig.sample_rate) ||
!audio_formats_match(profileFormat, lConfig.format) ||
(profileChannelMask != lConfig.channel_mask)) {
ALOGW("getInputForAttr() failed opening input: sampling rate %d"
", format %#x, channel mask %#x",
profileSamplingRate, profileFormat, profileChannelMask);
if (input != AUDIO_IO_HANDLE_NONE) {
inputDesc->close();
}
return AUDIO_IO_HANDLE_NONE;
}
inputDesc->mPolicyMix = policyMix;
addInput(input, inputDesc);
mpClientInterface->onAudioPortListUpdate();
return input;
}
status_t AudioPolicyManager::startInput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<AudioInputDescriptor> inputDesc = mInputs.getInputForClient(portId);
if (inputDesc == 0) {
ALOGW("%s no input for client %d", __FUNCTION__, portId);
return DEAD_OBJECT;
}
audio_io_handle_t input = inputDesc->mIoHandle;
sp<RecordClientDescriptor> client = inputDesc->getClient(portId);
if (client->active()) {
ALOGW("%s input %d client %d already started", __FUNCTION__, input, client->portId());
return INVALID_OPERATION;
}
audio_session_t session = client->session();
ALOGV("%s input:%d, session:%d)", __FUNCTION__, input, session);
Vector<sp<AudioInputDescriptor>> activeInputs = mInputs.getActiveInputs();
status_t status = inputDesc->start();
if (status != NO_ERROR) {
return status;
}
// increment activity count before calling getNewInputDevice() below as only active sessions
// are considered for device selection
inputDesc->setClientActive(client, true);
// indicate active capture to sound trigger service if starting capture from a mic on
// primary HW module
sp<DeviceDescriptor> device = getNewInputDevice(inputDesc);
if (device != nullptr) {
status = setInputDevice(input, device, true /* force */);
} else {
ALOGW("%s no new input device can be found for descriptor %d",
__FUNCTION__, inputDesc->getId());
status = BAD_VALUE;
}
if (status == NO_ERROR && inputDesc->activeCount() == 1) {
sp<AudioPolicyMix> policyMix = inputDesc->mPolicyMix.promote();
// if input maps to a dynamic policy with an activity listener, notify of state change
if ((policyMix != nullptr)
&& ((policyMix->mCbFlags & AudioMix::kCbFlagNotifyActivity) != 0)) {
mpClientInterface->onDynamicPolicyMixStateUpdate(policyMix->mDeviceAddress,
MIX_STATE_MIXING);
}
DeviceVector primaryInputDevices = availablePrimaryModuleInputDevices();
if (primaryInputDevices.contains(device) &&
mInputs.activeInputsCountOnDevices(primaryInputDevices) == 1) {
mpClientInterface->setSoundTriggerCaptureState(true);
}
// automatically enable the remote submix output when input is started if not
// used by a policy mix of type MIX_TYPE_RECORDERS
// For remote submix (a virtual device), we open only one input per capture request.
if (audio_is_remote_submix_device(inputDesc->getDeviceType())) {
String8 address = String8("");
if (policyMix == nullptr) {
address = String8("0");
} else if (policyMix->mMixType == MIX_TYPE_PLAYERS) {
address = policyMix->mDeviceAddress;
}
if (address != "") {
setDeviceConnectionStateInt(AUDIO_DEVICE_OUT_REMOTE_SUBMIX,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
address, "remote-submix", AUDIO_FORMAT_DEFAULT);
}
}
} else if (status != NO_ERROR) {
// Restore client activity state.
inputDesc->setClientActive(client, false);
inputDesc->stop();
}
ALOGV("%s input %d source = %d status = %d exit",
__FUNCTION__, input, client->source(), status);
return status;
}
status_t AudioPolicyManager::stopInput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<AudioInputDescriptor> inputDesc = mInputs.getInputForClient(portId);
if (inputDesc == 0) {
ALOGW("%s no input for client %d", __FUNCTION__, portId);
return BAD_VALUE;
}
audio_io_handle_t input = inputDesc->mIoHandle;
sp<RecordClientDescriptor> client = inputDesc->getClient(portId);
if (!client->active()) {
ALOGW("%s input %d client %d already stopped", __FUNCTION__, input, client->portId());
return INVALID_OPERATION;
}
auto old_source = inputDesc->source();
inputDesc->setClientActive(client, false);
inputDesc->stop();
if (inputDesc->isActive()) {
auto current_source = inputDesc->source();
setInputDevice(input, getNewInputDevice(inputDesc),
old_source != current_source /* force */);
} else {
sp<AudioPolicyMix> policyMix = inputDesc->mPolicyMix.promote();
// if input maps to a dynamic policy with an activity listener, notify of state change
if ((policyMix != nullptr)
&& ((policyMix->mCbFlags & AudioMix::kCbFlagNotifyActivity) != 0)) {
mpClientInterface->onDynamicPolicyMixStateUpdate(policyMix->mDeviceAddress,
MIX_STATE_IDLE);
}
// automatically disable the remote submix output when input is stopped if not
// used by a policy mix of type MIX_TYPE_RECORDERS
if (audio_is_remote_submix_device(inputDesc->getDeviceType())) {
String8 address = String8("");
if (policyMix == nullptr) {
address = String8("0");
} else if (policyMix->mMixType == MIX_TYPE_PLAYERS) {
address = policyMix->mDeviceAddress;
}
if (address != "") {
setDeviceConnectionStateInt(AUDIO_DEVICE_OUT_REMOTE_SUBMIX,
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
address, "remote-submix", AUDIO_FORMAT_DEFAULT);
}
}
resetInputDevice(input);
// indicate inactive capture to sound trigger service if stopping capture from a mic on
// primary HW module
DeviceVector primaryInputDevices = availablePrimaryModuleInputDevices();
if (primaryInputDevices.contains(inputDesc->getDevice()) &&
mInputs.activeInputsCountOnDevices(primaryInputDevices) == 0) {
mpClientInterface->setSoundTriggerCaptureState(false);
}
inputDesc->clearPreemptedSessions();
}
return NO_ERROR;
}
void AudioPolicyManager::releaseInput(audio_port_handle_t portId)
{
ALOGV("%s portId %d", __FUNCTION__, portId);
sp<AudioInputDescriptor> inputDesc = mInputs.getInputForClient(portId);
if (inputDesc == 0) {
ALOGW("%s no input for client %d", __FUNCTION__, portId);
return;
}
sp<RecordClientDescriptor> client = inputDesc->getClient(portId);
audio_io_handle_t input = inputDesc->mIoHandle;
ALOGV("%s %d", __FUNCTION__, input);
inputDesc->removeClient(portId);
mEffects.putOrphanEffects(client->session(), input, &mInputs, mpClientInterface);
if (inputDesc->getClientCount() > 0) {
ALOGV("%s(%d) %zu clients remaining", __func__, portId, inputDesc->getClientCount());
return;
}
closeInput(input);
mpClientInterface->onAudioPortListUpdate();
ALOGV("%s exit", __FUNCTION__);
}
void AudioPolicyManager::closeActiveClients(const sp<AudioInputDescriptor>& input)
{
RecordClientVector clients = input->clientsList(true);
for (const auto& client : clients) {
closeClient(client->portId());
}
}
void AudioPolicyManager::closeClient(audio_port_handle_t portId)
{
stopInput(portId);
releaseInput(portId);
}
void AudioPolicyManager::checkCloseInputs() {
// After connecting or disconnecting an input device, close input if:
// - it has no client (was just opened to check profile) OR
// - none of its supported devices are connected anymore OR
// - one of its clients cannot be routed to one of its supported
// devices anymore. Otherwise update device selection
std::vector<audio_io_handle_t> inputsToClose;
for (size_t i = 0; i < mInputs.size(); i++) {
const sp<AudioInputDescriptor> input = mInputs.valueAt(i);
if (input->clientsList().size() == 0
|| !mAvailableInputDevices.containsAtLeastOne(input->supportedDevices())) {
inputsToClose.push_back(mInputs.keyAt(i));
} else {
bool close = false;
for (const auto& client : input->clientsList()) {
sp<DeviceDescriptor> device =
mEngine->getInputDeviceForAttributes(client->attributes(), client->uid(),
client->session());
if (!input->supportedDevices().contains(device)) {
close = true;
break;
}
}
if (close) {
inputsToClose.push_back(mInputs.keyAt(i));
} else {
setInputDevice(input->mIoHandle, getNewInputDevice(input));
}
}
}
for (const audio_io_handle_t handle : inputsToClose) {
ALOGV("%s closing input %d", __func__, handle);
closeInput(handle);
}
}
void AudioPolicyManager::initStreamVolume(audio_stream_type_t stream, int indexMin, int indexMax)
{
ALOGV("initStreamVolume() stream %d, min %d, max %d", stream , indexMin, indexMax);
if (indexMin < 0 || indexMax < 0) {
ALOGE("%s for stream %d: invalid min %d or max %d", __func__, stream , indexMin, indexMax);
return;
}
getVolumeCurves(stream).initVolume(indexMin, indexMax);
// initialize other private stream volumes which follow this one
for (int curStream = 0; curStream < AUDIO_STREAM_FOR_POLICY_CNT; curStream++) {
if (!streamsMatchForvolume(stream, (audio_stream_type_t)curStream)) {
continue;
}
getVolumeCurves((audio_stream_type_t)curStream).initVolume(indexMin, indexMax);
}
}
status_t AudioPolicyManager::setStreamVolumeIndex(audio_stream_type_t stream,
int index,
audio_devices_t device)
{
auto attributes = mEngine->getAttributesForStreamType(stream);
if (attributes == AUDIO_ATTRIBUTES_INITIALIZER) {
ALOGW("%s: no group for stream %s, bailing out", __func__, toString(stream).c_str());
return NO_ERROR;
}
ALOGV("%s: stream %s attributes=%s", __func__,
toString(stream).c_str(), toString(attributes).c_str());
return setVolumeIndexForAttributes(attributes, index, device);
}
status_t AudioPolicyManager::getStreamVolumeIndex(audio_stream_type_t stream,
int *index,
audio_devices_t device)
{
// if device is AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME, return volume for device selected for this
// stream by the engine.
DeviceTypeSet deviceTypes = {device};
if (device == AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME) {
deviceTypes = mEngine->getOutputDevicesForStream(
stream, true /*fromCache*/).types();
}
return getVolumeIndex(getVolumeCurves(stream), *index, deviceTypes);
}
status_t AudioPolicyManager::setVolumeIndexForAttributes(const audio_attributes_t &attributes,
int index,
audio_devices_t device)
{
// Get Volume group matching the Audio Attributes
auto group = mEngine->getVolumeGroupForAttributes(attributes);
if (group == VOLUME_GROUP_NONE) {
ALOGD("%s: no group matching with %s", __FUNCTION__, toString(attributes).c_str());
return BAD_VALUE;
}
ALOGV("%s: group %d matching with %s index %d",
__FUNCTION__, group, toString(attributes).c_str(), index);
status_t status = NO_ERROR;
IVolumeCurves &curves = getVolumeCurves(attributes);
VolumeSource vs = toVolumeSource(group);
// AUDIO_STREAM_BLUETOOTH_SCO is only used for volume control so we remap
// to AUDIO_STREAM_VOICE_CALL to match with relevant playback activity
VolumeSource activityVs = (vs == toVolumeSource(AUDIO_STREAM_BLUETOOTH_SCO, false)) ?
toVolumeSource(AUDIO_STREAM_VOICE_CALL, false) : vs;
product_strategy_t strategy = mEngine->getProductStrategyForAttributes(attributes);
status = setVolumeCurveIndex(index, device, curves);
if (status != NO_ERROR) {
ALOGE("%s failed to set curve index for group %d device 0x%X", __func__, group, device);
return status;
}
DeviceTypeSet curSrcDevices;
auto curCurvAttrs = curves.getAttributes();
if (!curCurvAttrs.empty() && curCurvAttrs.front() != defaultAttr) {
auto attr = curCurvAttrs.front();
curSrcDevices = mEngine->getOutputDevicesForAttributes(attr, nullptr, false).types();
} else if (!curves.getStreamTypes().empty()) {
auto stream = curves.getStreamTypes().front();
curSrcDevices = mEngine->getOutputDevicesForStream(stream, false).types();
} else {
ALOGE("%s: Invalid src %d: no valid attributes nor stream",__func__, vs);
return BAD_VALUE;
}
audio_devices_t curSrcDevice = Volume::getDeviceForVolume(curSrcDevices);
resetDeviceTypes(curSrcDevices, curSrcDevice);
// update volume on all outputs and streams matching the following:
// - The requested stream (or a stream matching for volume control) is active on the output
// - The device (or devices) selected by the engine for this stream includes
// the requested device
// - For non default requested device, currently selected device on the output is either the
// requested device or one of the devices selected by the engine for this stream
// - For default requested device (AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME), apply volume only if
// no specific device volume value exists for currently selected device.
// - Only apply the volume if the requested device is the desired device for volume control.
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
DeviceTypeSet curDevices = desc->devices().types();
if (curDevices.erase(AUDIO_DEVICE_OUT_SPEAKER_SAFE)) {
curDevices.insert(AUDIO_DEVICE_OUT_SPEAKER);
}
if (!(desc->isActive(activityVs) || isInCallOrScreening())) {
continue;
}
if (device != AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME &&
curDevices.find(device) == curDevices.end()) {
continue;
}
bool applyVolume = false;
if (device != AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME) {
curSrcDevices.insert(device);
applyVolume = (curSrcDevices.find(
Volume::getDeviceForVolume(curDevices)) != curSrcDevices.end())
&& Volume::getDeviceForVolume(curSrcDevices) == device;
} else {
applyVolume = !curves.hasVolumeIndexForDevice(curSrcDevice);
}
if (!applyVolume) {
continue; // next output
}
// Inter / intra volume group priority management: Loop on strategies arranged by priority
// If a higher priority strategy is active, and the output is routed to a device with a
// HW Gain management, do not change the volume
if (desc->useHwGain()) {
applyVolume = false;
// If the volume source is active with higher priority source, ensure at least Sw Muted
desc->setSwMute((index == 0), vs, curves.getStreamTypes(), curDevices, 0 /*delayMs*/);
for (const auto &productStrategy : mEngine->getOrderedProductStrategies()) {
auto activeClients = desc->clientsList(true /*activeOnly*/, productStrategy,
false /*preferredDevice*/);
if (activeClients.empty()) {
continue;
}
bool isPreempted = false;
bool isHigherPriority = productStrategy < strategy;
for (const auto &client : activeClients) {
if (isHigherPriority && (client->volumeSource() != activityVs)) {
ALOGV("%s: Strategy=%d (\nrequester:\n"
" group %d, volumeGroup=%d attributes=%s)\n"
" higher priority source active:\n"
" volumeGroup=%d attributes=%s) \n"
" on output %zu, bailing out", __func__, productStrategy,
group, group, toString(attributes).c_str(),
client->volumeSource(), toString(client->attributes()).c_str(), i);
applyVolume = false;
isPreempted = true;
break;
}
// However, continue for loop to ensure no higher prio clients running on output
if (client->volumeSource() == activityVs) {
applyVolume = true;
}
}
if (isPreempted || applyVolume) {
break;
}
}
if (!applyVolume) {
continue; // next output
}
}
//FIXME: workaround for truncated touch sounds
// delayed volume change for system stream to be removed when the problem is
// handled by system UI
status_t volStatus = checkAndSetVolume(
curves, vs, index, desc, curDevices,
((vs == toVolumeSource(AUDIO_STREAM_SYSTEM, false))?
TOUCH_SOUND_FIXED_DELAY_MS : 0));
if (volStatus != NO_ERROR) {
status = volStatus;
}
}
// update voice volume if the an active call route exists
if (mCallRxSourceClient != nullptr && mCallRxSourceClient->isConnected()
&& (curSrcDevices.find(
Volume::getDeviceForVolume({mCallRxSourceClient->sinkDevice()->type()}))
!= curSrcDevices.end())) {
bool isVoiceVolSrc;
bool isBtScoVolSrc;
if (isVolumeConsistentForCalls(vs, {mCallRxSourceClient->sinkDevice()->type()},
isVoiceVolSrc, isBtScoVolSrc, __func__)
&& (isVoiceVolSrc || isBtScoVolSrc)) {
setVoiceVolume(index, curves, isVoiceVolSrc, 0);
}
}
mpClientInterface->onAudioVolumeGroupChanged(group, 0 /*flags*/);
return status;
}
status_t AudioPolicyManager::setVolumeCurveIndex(int index,
audio_devices_t device,
IVolumeCurves &volumeCurves)
{
// VOICE_CALL stream has minVolumeIndex > 0 but can be muted directly by an
// app that has MODIFY_PHONE_STATE permission.
bool hasVoice = hasVoiceStream(volumeCurves.getStreamTypes());
if (((index < volumeCurves.getVolumeIndexMin()) && !(hasVoice && index == 0)) ||
(index > volumeCurves.getVolumeIndexMax())) {
ALOGD("%s: wrong index %d min=%d max=%d", __FUNCTION__, index,
volumeCurves.getVolumeIndexMin(), volumeCurves.getVolumeIndexMax());
return BAD_VALUE;
}
if (!audio_is_output_device(device)) {
return BAD_VALUE;
}
// Force max volume if stream cannot be muted
if (!volumeCurves.canBeMuted()) index = volumeCurves.getVolumeIndexMax();
ALOGV("%s device %08x, index %d", __FUNCTION__ , device, index);
volumeCurves.addCurrentVolumeIndex(device, index);
return NO_ERROR;
}
status_t AudioPolicyManager::getVolumeIndexForAttributes(const audio_attributes_t &attr,
int &index,
audio_devices_t device)
{
// if device is AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME, return volume for device selected for this
// stream by the engine.
DeviceTypeSet deviceTypes = {device};
if (device == AUDIO_DEVICE_OUT_DEFAULT_FOR_VOLUME) {
deviceTypes = mEngine->getOutputDevicesForAttributes(
attr, nullptr, true /*fromCache*/).types();
}
return getVolumeIndex(getVolumeCurves(attr), index, deviceTypes);
}
status_t AudioPolicyManager::getVolumeIndex(const IVolumeCurves &curves,
int &index,
const DeviceTypeSet& deviceTypes) const
{
if (!isSingleDeviceType(deviceTypes, audio_is_output_device)) {
return BAD_VALUE;
}
index = curves.getVolumeIndex(deviceTypes);
ALOGV("%s: device %s index %d", __FUNCTION__, dumpDeviceTypes(deviceTypes).c_str(), index);
return NO_ERROR;
}
status_t AudioPolicyManager::getMinVolumeIndexForAttributes(const audio_attributes_t &attr,
int &index)
{
index = getVolumeCurves(attr).getVolumeIndexMin();
return NO_ERROR;
}
status_t AudioPolicyManager::getMaxVolumeIndexForAttributes(const audio_attributes_t &attr,
int &index)
{
index = getVolumeCurves(attr).getVolumeIndexMax();
return NO_ERROR;
}
audio_io_handle_t AudioPolicyManager::selectOutputForMusicEffects()
{
// select one output among several suitable for global effects.
// The priority is as follows:
// 1: An offloaded output. If the effect ends up not being offloadable,
// AudioFlinger will invalidate the track and the offloaded output
// will be closed causing the effect to be moved to a PCM output.
// 2: A deep buffer output
// 3: The primary output
// 4: the first output in the list
DeviceVector devices = mEngine->getOutputDevicesForAttributes(
attributes_initializer(AUDIO_USAGE_MEDIA), nullptr, false /*fromCache*/);
SortedVector<audio_io_handle_t> outputs = getOutputsForDevices(devices, mOutputs);
if (outputs.size() == 0) {
return AUDIO_IO_HANDLE_NONE;
}
audio_io_handle_t output = AUDIO_IO_HANDLE_NONE;
bool activeOnly = true;
while (output == AUDIO_IO_HANDLE_NONE) {
audio_io_handle_t outputOffloaded = AUDIO_IO_HANDLE_NONE;
audio_io_handle_t outputDeepBuffer = AUDIO_IO_HANDLE_NONE;
audio_io_handle_t outputPrimary = AUDIO_IO_HANDLE_NONE;
for (audio_io_handle_t output : outputs) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueFor(output);
if (activeOnly && !desc->isActive(toVolumeSource(AUDIO_STREAM_MUSIC))) {
continue;
}
ALOGV("selectOutputForMusicEffects activeOnly %d output %d flags 0x%08x",
activeOnly, output, desc->mFlags);
if ((desc->mFlags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) != 0) {
outputOffloaded = output;
}
if ((desc->mFlags & AUDIO_OUTPUT_FLAG_DEEP_BUFFER) != 0) {
outputDeepBuffer = output;
}
if ((desc->mFlags & AUDIO_OUTPUT_FLAG_PRIMARY) != 0) {
outputPrimary = output;
}
}
if (outputOffloaded != AUDIO_IO_HANDLE_NONE) {
output = outputOffloaded;
} else if (outputDeepBuffer != AUDIO_IO_HANDLE_NONE) {
output = outputDeepBuffer;
} else if (outputPrimary != AUDIO_IO_HANDLE_NONE) {
output = outputPrimary;
} else {
output = outputs[0];
}
activeOnly = false;
}
if (output != mMusicEffectOutput) {
mEffects.moveEffects(AUDIO_SESSION_OUTPUT_MIX, mMusicEffectOutput, output,
mpClientInterface);
mMusicEffectOutput = output;
}
ALOGV("selectOutputForMusicEffects selected output %d", output);
return output;
}
audio_io_handle_t AudioPolicyManager::getOutputForEffect(const effect_descriptor_t *desc __unused)
{
return selectOutputForMusicEffects();
}
status_t AudioPolicyManager::registerEffect(const effect_descriptor_t *desc,
audio_io_handle_t io,
product_strategy_t strategy,
int session,
int id)
{
if (session != AUDIO_SESSION_DEVICE) {
ssize_t index = mOutputs.indexOfKey(io);
if (index < 0) {
index = mInputs.indexOfKey(io);
if (index < 0) {
ALOGW("registerEffect() unknown io %d", io);
return INVALID_OPERATION;
}
}
}
bool isMusicEffect = (session != AUDIO_SESSION_OUTPUT_STAGE)
&& ((strategy == streamToStrategy(AUDIO_STREAM_MUSIC)
|| strategy == PRODUCT_STRATEGY_NONE));
return mEffects.registerEffect(desc, io, session, id, isMusicEffect);
}
status_t AudioPolicyManager::unregisterEffect(int id)
{
if (mEffects.getEffect(id) == nullptr) {
return INVALID_OPERATION;
}
if (mEffects.isEffectEnabled(id)) {
ALOGW("%s effect %d enabled", __FUNCTION__, id);
setEffectEnabled(id, false);
}
return mEffects.unregisterEffect(id);
}
status_t AudioPolicyManager::setEffectEnabled(int id, bool enabled)
{
sp<EffectDescriptor> effect = mEffects.getEffect(id);
if (effect == nullptr) {
return INVALID_OPERATION;
}
status_t status = mEffects.setEffectEnabled(id, enabled);
if (status == NO_ERROR) {
mInputs.trackEffectEnabled(effect, enabled);
}
return status;
}
status_t AudioPolicyManager::moveEffectsToIo(const std::vector<int>& ids, audio_io_handle_t io)
{
mEffects.moveEffects(ids, io);
return NO_ERROR;
}
bool AudioPolicyManager::isStreamActive(audio_stream_type_t stream, uint32_t inPastMs) const
{
auto vs = toVolumeSource(stream, false);
return vs != VOLUME_SOURCE_NONE ? mOutputs.isActive(vs, inPastMs) : false;
}
bool AudioPolicyManager::isStreamActiveRemotely(audio_stream_type_t stream, uint32_t inPastMs) const
{
auto vs = toVolumeSource(stream, false);
return vs != VOLUME_SOURCE_NONE ? mOutputs.isActiveRemotely(vs, inPastMs) : false;
}
bool AudioPolicyManager::isSourceActive(audio_source_t source) const
{
for (size_t i = 0; i < mInputs.size(); i++) {
const sp<AudioInputDescriptor> inputDescriptor = mInputs.valueAt(i);
if (inputDescriptor->isSourceActive(source)) {
return true;
}
}
return false;
}
// Register a list of custom mixes with their attributes and format.
// When a mix is registered, corresponding input and output profiles are
// added to the remote submix hw module. The profile contains only the
// parameters (sampling rate, format...) specified by the mix.
// The corresponding input remote submix device is also connected.
//
// When a remote submix device is connected, the address is checked to select the
// appropriate profile and the corresponding input or output stream is opened.
//
// When capture starts, getInputForAttr() will:
// - 1 look for a mix matching the address passed in attribtutes tags if any
// - 2 if none found, getDeviceForInputSource() will:
// - 2.1 look for a mix matching the attributes source
// - 2.2 if none found, default to device selection by policy rules
// At this time, the corresponding output remote submix device is also connected
// and active playback use cases can be transferred to this mix if needed when reconnecting
// after AudioTracks are invalidated
//
// When playback starts, getOutputForAttr() will:
// - 1 look for a mix matching the address passed in attribtutes tags if any
// - 2 if none found, look for a mix matching the attributes usage
// - 3 if none found, default to device and output selection by policy rules.
status_t AudioPolicyManager::registerPolicyMixes(const Vector<AudioMix>& mixes)
{
ALOGV("registerPolicyMixes() %zu mix(es)", mixes.size());
status_t res = NO_ERROR;
bool checkOutputs = false;
sp<HwModule> rSubmixModule;
Vector<AudioMix> registeredMixes;
// examine each mix's route type
for (size_t i = 0; i < mixes.size(); i++) {
AudioMix mix = mixes[i];
// Only capture of playback is allowed in LOOP_BACK & RENDER mode
if (is_mix_loopback_render(mix.mRouteFlags) && mix.mMixType != MIX_TYPE_PLAYERS) {
ALOGE("Unsupported Policy Mix %zu of %zu: "
"Only capture of playback is allowed in LOOP_BACK & RENDER mode",
i, mixes.size());
res = INVALID_OPERATION;
break;
}
// LOOP_BACK and LOOP_BACK | RENDER have the same remote submix backend and are handled
// in the same way.
if ((mix.mRouteFlags & MIX_ROUTE_FLAG_LOOP_BACK) == MIX_ROUTE_FLAG_LOOP_BACK) {
ALOGV("registerPolicyMixes() mix %zu of %zu is LOOP_BACK %d", i, mixes.size(),
mix.mRouteFlags);
if (rSubmixModule == 0) {
rSubmixModule = mHwModules.getModuleFromName(
AUDIO_HARDWARE_MODULE_ID_REMOTE_SUBMIX);
if (rSubmixModule == 0) {
ALOGE("Unable to find audio module for submix, aborting mix %zu registration",
i);
res = INVALID_OPERATION;
break;
}
}
String8 address = mix.mDeviceAddress;
audio_devices_t deviceTypeToMakeAvailable;
if (mix.mMixType == MIX_TYPE_PLAYERS) {
mix.mDeviceType = AUDIO_DEVICE_OUT_REMOTE_SUBMIX;
deviceTypeToMakeAvailable = AUDIO_DEVICE_IN_REMOTE_SUBMIX;
} else {
mix.mDeviceType = AUDIO_DEVICE_IN_REMOTE_SUBMIX;
deviceTypeToMakeAvailable = AUDIO_DEVICE_OUT_REMOTE_SUBMIX;
}
if (mPolicyMixes.registerMix(mix, 0 /*output desc*/) != NO_ERROR) {
ALOGE("Error registering mix %zu for address %s", i, address.c_str());
res = INVALID_OPERATION;
break;
}
audio_config_t outputConfig = mix.mFormat;
audio_config_t inputConfig = mix.mFormat;
// NOTE: audio flinger mixer does not support mono output: configure remote submix HAL
// in stereo and let audio flinger do the channel conversion if needed.
outputConfig.channel_mask = AUDIO_CHANNEL_OUT_STEREO;
inputConfig.channel_mask = AUDIO_CHANNEL_IN_STEREO;
rSubmixModule->addOutputProfile(address.c_str(), &outputConfig,
AUDIO_DEVICE_OUT_REMOTE_SUBMIX, address,
audio_is_linear_pcm(outputConfig.format)
? AUDIO_OUTPUT_FLAG_NONE : AUDIO_OUTPUT_FLAG_DIRECT);
rSubmixModule->addInputProfile(address.c_str(), &inputConfig,
AUDIO_DEVICE_IN_REMOTE_SUBMIX, address,
audio_is_linear_pcm(inputConfig.format)
? AUDIO_INPUT_FLAG_NONE : AUDIO_INPUT_FLAG_DIRECT);
if ((res = setDeviceConnectionStateInt(deviceTypeToMakeAvailable,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
address.c_str(), "remote-submix", AUDIO_FORMAT_DEFAULT)) != NO_ERROR) {
ALOGE("Failed to set remote submix device available, type %u, address %s",
mix.mDeviceType, address.c_str());
break;
}
} else if ((mix.mRouteFlags & MIX_ROUTE_FLAG_RENDER) == MIX_ROUTE_FLAG_RENDER) {
String8 address = mix.mDeviceAddress;
audio_devices_t type = mix.mDeviceType;
ALOGV(" registerPolicyMixes() mix %zu of %zu is RENDER, dev=0x%X addr=%s",
i, mixes.size(), type, address.c_str());
sp<DeviceDescriptor> device = mHwModules.getDeviceDescriptor(
mix.mDeviceType, mix.mDeviceAddress,
String8(), AUDIO_FORMAT_DEFAULT);
if (device == nullptr) {
res = INVALID_OPERATION;
break;
}
bool foundOutput = false;
// First try to find an already opened output supporting the device
for (size_t j = 0 ; j < mOutputs.size() && !foundOutput && res == NO_ERROR; j++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(j);
if (!desc->isDuplicated() && desc->supportedDevices().contains(device)) {
if (mPolicyMixes.registerMix(mix, desc) != NO_ERROR) {
ALOGE("Could not register mix RENDER, dev=0x%X addr=%s", type,
address.c_str());
res = INVALID_OPERATION;
} else {
foundOutput = true;
}
}
}
// If no output found, try to find a direct output profile supporting the device
for (size_t i = 0; i < mHwModules.size() && !foundOutput && res == NO_ERROR; i++) {
sp<HwModule> module = mHwModules[i];
for (size_t j = 0;
j < module->getOutputProfiles().size() && !foundOutput && res == NO_ERROR;
j++) {
sp<IOProfile> profile = module->getOutputProfiles()[j];
if (profile->isDirectOutput() && profile->supportsDevice(device)) {
if (mPolicyMixes.registerMix(mix, nullptr) != NO_ERROR) {
ALOGE("Could not register mix RENDER, dev=0x%X addr=%s", type,
address.c_str());
res = INVALID_OPERATION;
} else {
foundOutput = true;
}
}
}
}
if (res != NO_ERROR) {
ALOGE(" Error registering mix %zu for device 0x%X addr %s",
i, type, address.c_str());
res = INVALID_OPERATION;
break;
} else if (!foundOutput) {
ALOGE(" Output not found for mix %zu for device 0x%X addr %s",
i, type, address.c_str());
res = INVALID_OPERATION;
break;
} else {
checkOutputs = true;
registeredMixes.add(mix);
}
}
}
if (res != NO_ERROR) {
if (audio_flags::audio_mix_ownership()) {
// Only unregister mixes that were actually registered to not accidentally unregister
// mixes that already existed previously.
unregisterPolicyMixes(registeredMixes);
registeredMixes.clear();
} else {
unregisterPolicyMixes(mixes);
}
} else if (checkOutputs) {
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
}
return res;
}
status_t AudioPolicyManager::unregisterPolicyMixes(Vector<AudioMix> mixes)
{
ALOGV("unregisterPolicyMixes() num mixes %zu", mixes.size());
status_t endResult = NO_ERROR;
status_t res = NO_ERROR;
bool checkOutputs = false;
sp<HwModule> rSubmixModule;
// examine each mix's route type
for (const auto& mix : mixes) {
if ((mix.mRouteFlags & MIX_ROUTE_FLAG_LOOP_BACK) == MIX_ROUTE_FLAG_LOOP_BACK) {
if (rSubmixModule == 0) {
rSubmixModule = mHwModules.getModuleFromName(
AUDIO_HARDWARE_MODULE_ID_REMOTE_SUBMIX);
if (rSubmixModule == 0) {
res = INVALID_OPERATION;
endResult = INVALID_OPERATION;
continue;
}
}
String8 address = mix.mDeviceAddress;
if (mPolicyMixes.unregisterMix(mix) != NO_ERROR) {
res = INVALID_OPERATION;
endResult = INVALID_OPERATION;
continue;
}
for (auto device : {AUDIO_DEVICE_IN_REMOTE_SUBMIX, AUDIO_DEVICE_OUT_REMOTE_SUBMIX}) {
if (getDeviceConnectionState(device, address.c_str()) ==
AUDIO_POLICY_DEVICE_STATE_AVAILABLE) {
res = setDeviceConnectionStateInt(device, AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
address.c_str(), "remote-submix",
AUDIO_FORMAT_DEFAULT);
if (res != OK) {
ALOGE("Error making RemoteSubmix device unavailable for mix "
"with type %d, address %s", device, address.c_str());
endResult = INVALID_OPERATION;
}
}
}
rSubmixModule->removeOutputProfile(address.c_str());
rSubmixModule->removeInputProfile(address.c_str());
} else if ((mix.mRouteFlags & MIX_ROUTE_FLAG_RENDER) == MIX_ROUTE_FLAG_RENDER) {
if (mPolicyMixes.unregisterMix(mix) != NO_ERROR) {
res = INVALID_OPERATION;
endResult = INVALID_OPERATION;
continue;
} else {
checkOutputs = true;
}
}
}
if (audio_flags::audio_mix_ownership()) {
res = endResult;
if (res == NO_ERROR && checkOutputs) {
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
}
} else {
if (res == NO_ERROR && checkOutputs) {
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
}
}
return res;
}
status_t AudioPolicyManager::getRegisteredPolicyMixes(std::vector<AudioMix>& _aidl_return) {
if (!audio_flags::audio_mix_test_api()) {
return INVALID_OPERATION;
}
_aidl_return.clear();
_aidl_return.reserve(mPolicyMixes.size());
for (const auto &policyMix: mPolicyMixes) {
_aidl_return.emplace_back(policyMix->mCriteria, policyMix->mMixType,
policyMix->mFormat, policyMix->mRouteFlags, policyMix->mDeviceAddress,
policyMix->mCbFlags);
_aidl_return.back().mDeviceType = policyMix->mDeviceType;
_aidl_return.back().mToken = policyMix->mToken;
}
ALOGVV("%s() returning %zu registered mixes", __func__, _aidl_return->size());
return OK;
}
status_t AudioPolicyManager::updatePolicyMix(
const AudioMix& mix,
const std::vector<AudioMixMatchCriterion>& updatedCriteria) {
status_t res = mPolicyMixes.updateMix(mix, updatedCriteria);
if (res == NO_ERROR) {
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
}
return res;
}
void AudioPolicyManager::dumpManualSurroundFormats(String8 *dst) const
{
size_t i = 0;
constexpr size_t audioFormatPrefixLen = sizeof("AUDIO_FORMAT_");
for (const auto& fmt : mManualSurroundFormats) {
if (i++ != 0) dst->append(", ");
std::string sfmt;
FormatConverter::toString(fmt, sfmt);
dst->append(sfmt.size() >= audioFormatPrefixLen ?
sfmt.c_str() + audioFormatPrefixLen - 1 : sfmt.c_str());
}
}
// Returns true if all devices types match the predicate and are supported by one HW module
bool AudioPolicyManager::areAllDevicesSupported(
const AudioDeviceTypeAddrVector& devices,
std::function<bool(audio_devices_t)> predicate,
const char *context,
bool matchAddress) {
for (size_t i = 0; i < devices.size(); i++) {
sp<DeviceDescriptor> devDesc = mHwModules.getDeviceDescriptor(
devices[i].mType, devices[i].getAddress(), String8(),
AUDIO_FORMAT_DEFAULT, false /*allowToCreate*/, matchAddress);
if (devDesc == nullptr || (predicate != nullptr && !predicate(devices[i].mType))) {
ALOGE("%s: device type %#x address %s not supported or not match predicate",
context, devices[i].mType, devices[i].getAddress());
return false;
}
}
return true;
}
void AudioPolicyManager::changeOutputDevicesMuteState(
const AudioDeviceTypeAddrVector& devices) {
ALOGVV("%s() num devices %zu", __func__, devices.size());
std::vector<sp<SwAudioOutputDescriptor>> outputs =
getSoftwareOutputsForDevices(devices);
for (size_t i = 0; i < outputs.size(); i++) {
sp<SwAudioOutputDescriptor> outputDesc = outputs[i];
DeviceVector prevDevices = outputDesc->devices();
checkDeviceMuteStrategies(outputDesc, prevDevices, 0 /* delayMs */);
}
}
std::vector<sp<SwAudioOutputDescriptor>> AudioPolicyManager::getSoftwareOutputsForDevices(
const AudioDeviceTypeAddrVector& devices) const
{
std::vector<sp<SwAudioOutputDescriptor>> outputs;
DeviceVector deviceDescriptors;
for (size_t j = 0; j < devices.size(); j++) {
sp<DeviceDescriptor> desc = mHwModules.getDeviceDescriptor(
devices[j].mType, devices[j].getAddress(), String8(), AUDIO_FORMAT_DEFAULT);
if (desc == nullptr || !audio_is_output_device(devices[j].mType)) {
ALOGE("%s: device type %#x address %s not supported or not an output device",
__func__, devices[j].mType, devices[j].getAddress());
continue;
}
deviceDescriptors.add(desc);
}
for (size_t i = 0; i < mOutputs.size(); i++) {
if (!mOutputs.valueAt(i)->supportsAtLeastOne(deviceDescriptors)) {
continue;
}
outputs.push_back(mOutputs.valueAt(i));
}
return outputs;
}
status_t AudioPolicyManager::setUidDeviceAffinities(uid_t uid,
const AudioDeviceTypeAddrVector& devices) {
ALOGV("%s() uid=%d num devices %zu", __FUNCTION__, uid, devices.size());
if (!areAllDevicesSupported(devices, audio_is_output_device, __func__)) {
return BAD_VALUE;
}
status_t res = mPolicyMixes.setUidDeviceAffinities(uid, devices);
if (res != NO_ERROR) {
ALOGE("%s() Could not set all device affinities for uid = %d", __FUNCTION__, uid);
return res;
}
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
return NO_ERROR;
}
status_t AudioPolicyManager::removeUidDeviceAffinities(uid_t uid) {
ALOGV("%s() uid=%d", __FUNCTION__, uid);
status_t res = mPolicyMixes.removeUidDeviceAffinities(uid);
if (res != NO_ERROR) {
ALOGE("%s() Could not remove all device affinities for uid = %d",
__FUNCTION__, uid);
return INVALID_OPERATION;
}
checkForDeviceAndOutputChanges();
updateCallAndOutputRouting();
return res;
}
status_t AudioPolicyManager::setDevicesRoleForStrategy(product_strategy_t strategy,
device_role_t role,
const AudioDeviceTypeAddrVector &devices) {
ALOGV("%s() strategy=%d role=%d %s", __func__, strategy, role,
dumpAudioDeviceTypeAddrVector(devices).c_str());
if (!areAllDevicesSupported(devices, audio_is_output_device, __func__)) {
return BAD_VALUE;
}
status_t status = mEngine->setDevicesRoleForStrategy(strategy, role, devices);
if (status != NO_ERROR) {
ALOGW("Engine could not set preferred devices %s for strategy %d role %d",
dumpAudioDeviceTypeAddrVector(devices).c_str(), strategy, role);
return status;
}
checkForDeviceAndOutputChanges();
bool forceVolumeReeval = false;
// FIXME: workaround for truncated touch sounds
// to be removed when the problem is handled by system UI
uint32_t delayMs = 0;
if (strategy == mCommunnicationStrategy) {
forceVolumeReeval = true;
delayMs = TOUCH_SOUND_FIXED_DELAY_MS;
updateInputRouting();
}
updateCallAndOutputRouting(forceVolumeReeval, delayMs);
return NO_ERROR;
}
void AudioPolicyManager::updateCallAndOutputRouting(bool forceVolumeReeval, uint32_t delayMs,
bool skipDelays)
{
uint32_t waitMs = 0;
bool wasLeUnicastActive = isLeUnicastActive();
if (updateCallRouting(true /*fromCache*/, delayMs, &waitMs) == NO_ERROR) {
// Only apply special touch sound delay once
delayMs = 0;
}
std::map<audio_io_handle_t, DeviceVector> outputsToReopen;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.valueAt(i);
DeviceVector newDevices = getNewOutputDevices(outputDesc, true /*fromCache*/);
if ((mEngine->getPhoneState() != AUDIO_MODE_IN_CALL) ||
(outputDesc != mPrimaryOutput && !isTelephonyRxOrTx(outputDesc))) {
// As done in setDeviceConnectionState, we could also fix default device issue by
// preventing the force re-routing in case of default dev that distinguishes on address.
// Let's give back to engine full device choice decision however.
bool forceRouting = !newDevices.isEmpty();
if (outputDesc->mUsePreferredMixerAttributes && newDevices != outputDesc->devices()) {
// If the device is using preferred mixer attributes, the output need to reopen
// with default configuration when the new selected devices are different from
// current routing devices.
outputsToReopen.emplace(mOutputs.keyAt(i), newDevices);
continue;
}
waitMs = setOutputDevices(__func__, outputDesc, newDevices, forceRouting, delayMs,
nullptr, !skipDelays /*requiresMuteCheck*/,
!forceRouting /*requiresVolumeCheck*/, skipDelays);
// Only apply special touch sound delay once
delayMs = 0;
}
if (forceVolumeReeval && !newDevices.isEmpty()) {
applyStreamVolumes(outputDesc, newDevices.types(), waitMs, true);
}
}
reopenOutputsWithDevices(outputsToReopen);
checkLeBroadcastRoutes(wasLeUnicastActive, nullptr, delayMs);
}
void AudioPolicyManager::updateInputRouting() {
for (const auto& activeDesc : mInputs.getActiveInputs()) {
// Skip for hotword recording as the input device switch
// is handled within sound trigger HAL
if (activeDesc->isSoundTrigger() && activeDesc->source() == AUDIO_SOURCE_HOTWORD) {
continue;
}
auto newDevice = getNewInputDevice(activeDesc);
// Force new input selection if the new device can not be reached via current input
if (activeDesc->mProfile->getSupportedDevices().contains(newDevice)) {
setInputDevice(activeDesc->mIoHandle, newDevice);
} else {
closeInput(activeDesc->mIoHandle);
}
}
}
status_t
AudioPolicyManager::removeDevicesRoleForStrategy(product_strategy_t strategy,
device_role_t role,
const AudioDeviceTypeAddrVector &devices) {
ALOGV("%s() strategy=%d role=%d %s", __func__, strategy, role,
dumpAudioDeviceTypeAddrVector(devices).c_str());
if (!areAllDevicesSupported(
devices, audio_is_output_device, __func__, /*matchAddress*/false)) {
return BAD_VALUE;
}
status_t status = mEngine->removeDevicesRoleForStrategy(strategy, role, devices);
if (status != NO_ERROR) {
ALOGW("Engine could not remove devices %s for strategy %d role %d",
dumpAudioDeviceTypeAddrVector(devices).c_str(), strategy, role);
return status;
}
checkForDeviceAndOutputChanges();
bool forceVolumeReeval = false;
// TODO(b/263479999): workaround for truncated touch sounds
// to be removed when the problem is handled by system UI
uint32_t delayMs = 0;
if (strategy == mCommunnicationStrategy) {
forceVolumeReeval = true;
delayMs = TOUCH_SOUND_FIXED_DELAY_MS;
updateInputRouting();
}
updateCallAndOutputRouting(forceVolumeReeval, delayMs);
return NO_ERROR;
}
status_t AudioPolicyManager::clearDevicesRoleForStrategy(product_strategy_t strategy,
device_role_t role)
{
ALOGV("%s() strategy=%d role=%d", __func__, strategy, role);
status_t status = mEngine->clearDevicesRoleForStrategy(strategy, role);
if (status != NO_ERROR) {
ALOGW_IF(status != NAME_NOT_FOUND,
"Engine could not remove device role for strategy %d status %d",
strategy, status);
return status;
}
checkForDeviceAndOutputChanges();
bool forceVolumeReeval = false;
// FIXME: workaround for truncated touch sounds
// to be removed when the problem is handled by system UI
uint32_t delayMs = 0;
if (strategy == mCommunnicationStrategy) {
forceVolumeReeval = true;
delayMs = TOUCH_SOUND_FIXED_DELAY_MS;
updateInputRouting();
}
updateCallAndOutputRouting(forceVolumeReeval, delayMs);
return NO_ERROR;
}
status_t AudioPolicyManager::getDevicesForRoleAndStrategy(product_strategy_t strategy,
device_role_t role,
AudioDeviceTypeAddrVector &devices) {
return mEngine->getDevicesForRoleAndStrategy(strategy, role, devices);
}
status_t AudioPolicyManager::setDevicesRoleForCapturePreset(
audio_source_t audioSource, device_role_t role, const AudioDeviceTypeAddrVector &devices) {
ALOGV("%s() audioSource=%d role=%d %s", __func__, audioSource, role,
dumpAudioDeviceTypeAddrVector(devices).c_str());
if (!areAllDevicesSupported(devices, audio_call_is_input_device, __func__)) {
return BAD_VALUE;
}
status_t status = mEngine->setDevicesRoleForCapturePreset(audioSource, role, devices);
ALOGW_IF(status != NO_ERROR,
"Engine could not set preferred devices %s for audio source %d role %d",
dumpAudioDeviceTypeAddrVector(devices).c_str(), audioSource, role);
return status;
}
status_t AudioPolicyManager::addDevicesRoleForCapturePreset(
audio_source_t audioSource, device_role_t role, const AudioDeviceTypeAddrVector &devices) {
ALOGV("%s() audioSource=%d role=%d %s", __func__, audioSource, role,
dumpAudioDeviceTypeAddrVector(devices).c_str());
if (!areAllDevicesSupported(devices, audio_call_is_input_device, __func__)) {
return BAD_VALUE;
}
status_t status = mEngine->addDevicesRoleForCapturePreset(audioSource, role, devices);
ALOGW_IF(status != NO_ERROR,
"Engine could not add preferred devices %s for audio source %d role %d",
dumpAudioDeviceTypeAddrVector(devices).c_str(), audioSource, role);
updateInputRouting();
return status;
}
status_t AudioPolicyManager::removeDevicesRoleForCapturePreset(
audio_source_t audioSource, device_role_t role, const AudioDeviceTypeAddrVector& devices)
{
ALOGV("%s() audioSource=%d role=%d devices=%s", __func__, audioSource, role,
dumpAudioDeviceTypeAddrVector(devices).c_str());
if (!areAllDevicesSupported(
devices, audio_call_is_input_device, __func__, /*matchAddress*/false)) {
return BAD_VALUE;
}
status_t status = mEngine->removeDevicesRoleForCapturePreset(
audioSource, role, devices);
ALOGW_IF(status != NO_ERROR && status != NAME_NOT_FOUND,
"Engine could not remove devices role (%d) for capture preset %d", role, audioSource);
if (status == NO_ERROR) {
updateInputRouting();
}
return status;
}
status_t AudioPolicyManager::clearDevicesRoleForCapturePreset(audio_source_t audioSource,
device_role_t role) {
ALOGV("%s() audioSource=%d role=%d", __func__, audioSource, role);
status_t status = mEngine->clearDevicesRoleForCapturePreset(audioSource, role);
ALOGW_IF(status != NO_ERROR && status != NAME_NOT_FOUND,
"Engine could not clear devices role (%d) for capture preset %d", role, audioSource);
if (status == NO_ERROR) {
updateInputRouting();
}
return status;
}
status_t AudioPolicyManager::getDevicesForRoleAndCapturePreset(
audio_source_t audioSource, device_role_t role, AudioDeviceTypeAddrVector &devices) {
return mEngine->getDevicesForRoleAndCapturePreset(audioSource, role, devices);
}
status_t AudioPolicyManager::setUserIdDeviceAffinities(int userId,
const AudioDeviceTypeAddrVector& devices) {
ALOGV("%s() userId=%d num devices %zu", __func__, userId, devices.size());
if (!areAllDevicesSupported(devices, audio_is_output_device, __func__)) {
return BAD_VALUE;
}
status_t status = mPolicyMixes.setUserIdDeviceAffinities(userId, devices);
if (status != NO_ERROR) {
ALOGE("%s() could not set device affinity for userId %d",
__FUNCTION__, userId);
return status;
}
// reevaluate outputs for all devices
checkForDeviceAndOutputChanges();
changeOutputDevicesMuteState(devices);
updateCallAndOutputRouting(false /* forceVolumeReeval */, 0 /* delayMs */,
true /* skipDelays */);
changeOutputDevicesMuteState(devices);
return NO_ERROR;
}
status_t AudioPolicyManager::removeUserIdDeviceAffinities(int userId) {
ALOGV("%s() userId=%d", __FUNCTION__, userId);
AudioDeviceTypeAddrVector devices;
mPolicyMixes.getDevicesForUserId(userId, devices);
status_t status = mPolicyMixes.removeUserIdDeviceAffinities(userId);
if (status != NO_ERROR) {
ALOGE("%s() Could not remove all device affinities fo userId = %d",
__FUNCTION__, userId);
return status;
}
// reevaluate outputs for all devices
checkForDeviceAndOutputChanges();
changeOutputDevicesMuteState(devices);
updateCallAndOutputRouting(false /* forceVolumeReeval */, 0 /* delayMs */,
true /* skipDelays */);
changeOutputDevicesMuteState(devices);
return NO_ERROR;
}
void AudioPolicyManager::dump(String8 *dst) const
{
dst->appendFormat("\nAudioPolicyManager Dump: %p\n", this);
dst->appendFormat(" Primary Output I/O handle: %d\n",
hasPrimaryOutput() ? mPrimaryOutput->mIoHandle : AUDIO_IO_HANDLE_NONE);
std::string stateLiteral;
AudioModeConverter::toString(mEngine->getPhoneState(), stateLiteral);
dst->appendFormat(" Phone state: %s\n", stateLiteral.c_str());
const char* forceUses[AUDIO_POLICY_FORCE_USE_CNT] = {
"communications", "media", "record", "dock", "system",
"HDMI system audio", "encoded surround output", "vibrate ringing" };
for (audio_policy_force_use_t i = AUDIO_POLICY_FORCE_FOR_COMMUNICATION;
i < AUDIO_POLICY_FORCE_USE_CNT; i = (audio_policy_force_use_t)((int)i + 1)) {
audio_policy_forced_cfg_t forceUseValue = mEngine->getForceUse(i);
dst->appendFormat(" Force use for %s: %d", forceUses[i], forceUseValue);
if (i == AUDIO_POLICY_FORCE_FOR_ENCODED_SURROUND &&
forceUseValue == AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL) {
dst->append(" (MANUAL: ");
dumpManualSurroundFormats(dst);
dst->append(")");
}
dst->append("\n");
}
dst->appendFormat(" TTS output %savailable\n", mTtsOutputAvailable ? "" : "not ");
dst->appendFormat(" Master mono: %s\n", mMasterMono ? "on" : "off");
dst->appendFormat(" Communication Strategy id: %d\n", mCommunnicationStrategy);
dst->appendFormat(" Config source: %s\n", mConfig->getSource().c_str());
dst->append("\n");
mAvailableOutputDevices.dump(dst, String8("Available output"), 1);
dst->append("\n");
mAvailableInputDevices.dump(dst, String8("Available input"), 1);
mHwModules.dump(dst);
mOutputs.dump(dst);
mInputs.dump(dst);
mEffects.dump(dst, 1);
mAudioPatches.dump(dst);
mPolicyMixes.dump(dst);
mAudioSources.dump(dst);
dst->appendFormat(" AllowedCapturePolicies:\n");
for (auto& policy : mAllowedCapturePolicies) {
dst->appendFormat(" - uid=%d flag_mask=%#x\n", policy.first, policy.second);
}
dst->appendFormat(" Preferred mixer audio configuration:\n");
for (const auto it : mPreferredMixerAttrInfos) {
dst->appendFormat(" - device port id: %d\n", it.first);
for (const auto preferredMixerInfoIt : it.second) {
dst->appendFormat(" - strategy: %d; ", preferredMixerInfoIt.first);
preferredMixerInfoIt.second->dump(dst);
}
}
dst->appendFormat("\nPolicy Engine dump:\n");
mEngine->dump(dst);
}
status_t AudioPolicyManager::dump(int fd)
{
String8 result;
dump(&result);
write(fd, result.c_str(), result.size());
return NO_ERROR;
}
status_t AudioPolicyManager::setAllowedCapturePolicy(uid_t uid, audio_flags_mask_t capturePolicy)
{
mAllowedCapturePolicies[uid] = capturePolicy;
return NO_ERROR;
}
// This function checks for the parameters which can be offloaded.
// This can be enhanced depending on the capability of the DSP and policy
// of the system.
audio_offload_mode_t AudioPolicyManager::getOffloadSupport(const audio_offload_info_t& offloadInfo)
{
ALOGV("%s: SR=%u, CM=0x%x, Format=0x%x, StreamType=%d,"
" BitRate=%u, duration=%" PRId64 " us, has_video=%d",
__func__, offloadInfo.sample_rate, offloadInfo.channel_mask,
offloadInfo.format,
offloadInfo.stream_type, offloadInfo.bit_rate, offloadInfo.duration_us,
offloadInfo.has_video);
if (!isOffloadPossible(offloadInfo)) {
return AUDIO_OFFLOAD_NOT_SUPPORTED;
}
// See if there is a profile to support this.
// AUDIO_DEVICE_NONE
sp<IOProfile> profile = getProfileForOutput(DeviceVector() /*ignore device */,
offloadInfo.sample_rate,
offloadInfo.format,
offloadInfo.channel_mask,
AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD,
true /* directOnly */);
ALOGV("%s: profile %sfound%s", __func__, profile != nullptr ? "" : "NOT ",
(profile != nullptr && (profile->getFlags() & AUDIO_OUTPUT_FLAG_GAPLESS_OFFLOAD) != 0)
? ", supports gapless" : "");
if (profile == nullptr) {
return AUDIO_OFFLOAD_NOT_SUPPORTED;
}
if ((profile->getFlags() & AUDIO_OUTPUT_FLAG_GAPLESS_OFFLOAD) != 0) {
return AUDIO_OFFLOAD_GAPLESS_SUPPORTED;
}
return AUDIO_OFFLOAD_SUPPORTED;
}
bool AudioPolicyManager::isDirectOutputSupported(const audio_config_base_t& config,
const audio_attributes_t& attributes) {
audio_output_flags_t output_flags = AUDIO_OUTPUT_FLAG_NONE;
audio_flags_to_audio_output_flags(attributes.flags, &output_flags);
DeviceVector outputDevices = mEngine->getOutputDevicesForAttributes(attributes);
sp<IOProfile> profile = getProfileForOutput(outputDevices,
config.sample_rate,
config.format,
config.channel_mask,
output_flags,
true /* directOnly */);
ALOGV("%s() profile %sfound with name: %s, "
"sample rate: %u, format: 0x%x, channel_mask: 0x%x, output flags: 0x%x",
__FUNCTION__, profile != 0 ? "" : "NOT ",
(profile != 0 ? profile->getTagName().c_str() : "null"),
config.sample_rate, config.format, config.channel_mask, output_flags);
// also try the MSD module if compatible profile not found
if (profile == nullptr) {
profile = getMsdProfileForOutput(outputDevices,
config.sample_rate,
config.format,
config.channel_mask,
output_flags,
true /* directOnly */);
ALOGV("%s() MSD profile %sfound with name: %s, "
"sample rate: %u, format: 0x%x, channel_mask: 0x%x, output flags: 0x%x",
__FUNCTION__, profile != 0 ? "" : "NOT ",
(profile != 0 ? profile->getTagName().c_str() : "null"),
config.sample_rate, config.format, config.channel_mask, output_flags);
}
return (profile != nullptr);
}
bool AudioPolicyManager::isOffloadPossible(const audio_offload_info_t &offloadInfo,
bool durationIgnored) {
if (mMasterMono) {
return false; // no offloading if mono is set.
}
// Check if offload has been disabled
if (property_get_bool("audio.offload.disable", false /* default_value */)) {
ALOGV("%s: offload disabled by audio.offload.disable", __func__);
return false;
}
// Check if stream type is music, then only allow offload as of now.
if (offloadInfo.stream_type != AUDIO_STREAM_MUSIC)
{
ALOGV("%s: stream_type != MUSIC, returning false", __func__);
return false;
}
//TODO: enable audio offloading with video when ready
const bool allowOffloadWithVideo =
property_get_bool("audio.offload.video", false /* default_value */);
if (offloadInfo.has_video && !allowOffloadWithVideo) {
ALOGV("%s: has_video == true, returning false", __func__);
return false;
}
//If duration is less than minimum value defined in property, return false
const int min_duration_secs = property_get_int32(
"audio.offload.min.duration.secs", -1 /* default_value */);
if (!durationIgnored) {
if (min_duration_secs >= 0) {
if (offloadInfo.duration_us < min_duration_secs * 1000000LL) {
ALOGV("%s: Offload denied by duration < audio.offload.min.duration.secs(=%d)",
__func__, min_duration_secs);
return false;
}
} else if (offloadInfo.duration_us < OFFLOAD_DEFAULT_MIN_DURATION_SECS * 1000000) {
ALOGV("%s: Offload denied by duration < default min(=%u)",
__func__, OFFLOAD_DEFAULT_MIN_DURATION_SECS);
return false;
}
}
// Do not allow offloading if one non offloadable effect is enabled. This prevents from
// creating an offloaded track and tearing it down immediately after start when audioflinger
// detects there is an active non offloadable effect.
// FIXME: We should check the audio session here but we do not have it in this context.
// This may prevent offloading in rare situations where effects are left active by apps
// in the background.
if (mEffects.isNonOffloadableEffectEnabled()) {
return false;
}
return true;
}
audio_direct_mode_t AudioPolicyManager::getDirectPlaybackSupport(const audio_attributes_t *attr,
const audio_config_t *config) {
audio_offload_info_t offloadInfo = AUDIO_INFO_INITIALIZER;
offloadInfo.format = config->format;
offloadInfo.sample_rate = config->sample_rate;
offloadInfo.channel_mask = config->channel_mask;
offloadInfo.stream_type = mEngine->getStreamTypeForAttributes(*attr);
offloadInfo.has_video = false;
offloadInfo.is_streaming = false;
const bool offloadPossible = isOffloadPossible(offloadInfo, true /*durationIgnored*/);
audio_direct_mode_t directMode = AUDIO_DIRECT_NOT_SUPPORTED;
audio_output_flags_t flags = AUDIO_OUTPUT_FLAG_NONE;
audio_flags_to_audio_output_flags(attr->flags, &flags);
// only retain flags that will drive compressed offload or passthrough
uint32_t relevantFlags = AUDIO_OUTPUT_FLAG_HW_AV_SYNC;
if (offloadPossible) {
relevantFlags |= AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD;
}
flags = (audio_output_flags_t)((flags & relevantFlags) | AUDIO_OUTPUT_FLAG_DIRECT);
DeviceVector engineOutputDevices = mEngine->getOutputDevicesForAttributes(*attr);
for (const auto& hwModule : mHwModules) {
DeviceVector outputDevices = engineOutputDevices;
// the MSD module checks for different conditions and output devices
if (strcmp(hwModule->getName(), AUDIO_HARDWARE_MODULE_ID_MSD) == 0) {
if (!msdHasPatchesToAllDevices(engineOutputDevices.toTypeAddrVector())) {
continue;
}
outputDevices = getMsdAudioOutDevices();
}
for (const auto& curProfile : hwModule->getOutputProfiles()) {
if (curProfile->getCompatibilityScore(outputDevices,
config->sample_rate, nullptr /*updatedSamplingRate*/,
config->format, nullptr /*updatedFormat*/,
config->channel_mask, nullptr /*updatedChannelMask*/,
flags) == IOProfile::NO_MATCH) {
continue;
}
// reject profiles not corresponding to a device currently available
if (!mAvailableOutputDevices.containsAtLeastOne(curProfile->getSupportedDevices())) {
continue;
}
if (offloadPossible && ((curProfile->getFlags() & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD)
!= AUDIO_OUTPUT_FLAG_NONE)) {
if ((directMode & AUDIO_DIRECT_OFFLOAD_GAPLESS_SUPPORTED)
!= AUDIO_DIRECT_NOT_SUPPORTED) {
// Already reports offload gapless supported. No need to report offload support.
continue;
}
if ((curProfile->getFlags() & AUDIO_OUTPUT_FLAG_GAPLESS_OFFLOAD)
!= AUDIO_OUTPUT_FLAG_NONE) {
// If offload gapless is reported, no need to report offload support.
directMode = (audio_direct_mode_t) ((directMode &
~AUDIO_DIRECT_OFFLOAD_SUPPORTED) |
AUDIO_DIRECT_OFFLOAD_GAPLESS_SUPPORTED);
} else {
directMode = (audio_direct_mode_t)(directMode | AUDIO_DIRECT_OFFLOAD_SUPPORTED);
}
} else {
directMode = (audio_direct_mode_t) (directMode | AUDIO_DIRECT_BITSTREAM_SUPPORTED);
}
}
}
return directMode;
}
status_t AudioPolicyManager::getDirectProfilesForAttributes(const audio_attributes_t* attr,
AudioProfileVector& audioProfilesVector) {
if (mEffects.isNonOffloadableEffectEnabled()) {
return OK;
}
DeviceVector devices;
status_t status = getDevicesForAttributes(*attr, devices, false /* forVolume */);
if (status != OK) {
return status;
}
ALOGV("%s: found %zu output devices for attributes.", __func__, devices.size());
if (devices.empty()) {
return OK; // no output devices for the attributes
}
return getProfilesForDevices(devices, audioProfilesVector,
AUDIO_OUTPUT_FLAG_DIRECT /*flags*/, false /*isInput*/);
}
status_t AudioPolicyManager::getSupportedMixerAttributes(
audio_port_handle_t portId, std::vector<audio_mixer_attributes_t> &mixerAttrs) {
ALOGV("%s, portId=%d", __func__, portId);
sp<DeviceDescriptor> deviceDescriptor = mAvailableOutputDevices.getDeviceFromId(portId);
if (deviceDescriptor == nullptr) {
ALOGE("%s the requested device is currently unavailable", __func__);
return BAD_VALUE;
}
if (!audio_is_usb_out_device(deviceDescriptor->type())) {
ALOGE("%s the requested device(type=%#x) is not usb device", __func__,
deviceDescriptor->type());
return BAD_VALUE;
}
for (const auto& hwModule : mHwModules) {
for (const auto& curProfile : hwModule->getOutputProfiles()) {
if (curProfile->supportsDevice(deviceDescriptor)) {
curProfile->toSupportedMixerAttributes(&mixerAttrs);
}
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::setPreferredMixerAttributes(
const audio_attributes_t *attr,
audio_port_handle_t portId,
uid_t uid,
const audio_mixer_attributes_t *mixerAttributes) {
ALOGV("%s, attr=%s, mixerAttributes={format=%#x, channelMask=%#x, samplingRate=%u, "
"mixerBehavior=%d}, uid=%d, portId=%u",
__func__, toString(*attr).c_str(), mixerAttributes->config.format,
mixerAttributes->config.channel_mask, mixerAttributes->config.sample_rate,
mixerAttributes->mixer_behavior, uid, portId);
if (attr->usage != AUDIO_USAGE_MEDIA) {
ALOGE("%s failed, only media is allowed, the given usage is %d", __func__, attr->usage);
return BAD_VALUE;
}
sp<DeviceDescriptor> deviceDescriptor = mAvailableOutputDevices.getDeviceFromId(portId);
if (deviceDescriptor == nullptr) {
ALOGE("%s the requested device is currently unavailable", __func__);
return BAD_VALUE;
}
if (!audio_is_usb_out_device(deviceDescriptor->type())) {
ALOGE("%s(%d), type=%d, is not a usb output device",
__func__, portId, deviceDescriptor->type());
return BAD_VALUE;
}
audio_output_flags_t flags = AUDIO_OUTPUT_FLAG_NONE;
audio_flags_to_audio_output_flags(attr->flags, &flags);
flags = (audio_output_flags_t) (flags |
audio_output_flags_from_mixer_behavior(mixerAttributes->mixer_behavior));
sp<IOProfile> profile = nullptr;
DeviceVector devices(deviceDescriptor);
for (const auto& hwModule : mHwModules) {
for (const auto& curProfile : hwModule->getOutputProfiles()) {
if (curProfile->hasDynamicAudioProfile()
&& curProfile->getCompatibilityScore(
devices,
mixerAttributes->config.sample_rate,
nullptr /*updatedSamplingRate*/,
mixerAttributes->config.format,
nullptr /*updatedFormat*/,
mixerAttributes->config.channel_mask,
nullptr /*updatedChannelMask*/,
flags,
false /*exactMatchRequiredForInputFlags*/)
!= IOProfile::NO_MATCH) {
profile = curProfile;
break;
}
}
}
if (profile == nullptr) {
ALOGE("%s, there is no compatible profile found", __func__);
return BAD_VALUE;
}
sp<PreferredMixerAttributesInfo> mixerAttrInfo =
sp<PreferredMixerAttributesInfo>::make(
uid, portId, profile, flags, *mixerAttributes);
const product_strategy_t strategy = mEngine->getProductStrategyForAttributes(*attr);
mPreferredMixerAttrInfos[portId][strategy] = mixerAttrInfo;
// If 1) there is any client from the preferred mixer configuration owner that is currently
// active and matches the strategy and 2) current output is on the preferred device and the
// mixer configuration doesn't match the preferred one, reopen output with preferred mixer
// configuration.
std::vector<audio_io_handle_t> outputsToReopen;
for (size_t i = 0; i < mOutputs.size(); i++) {
const auto output = mOutputs.valueAt(i);
if (output->mProfile == profile && output->devices().onlyContainsDevice(deviceDescriptor)) {
if (output->isConfigurationMatched(mixerAttributes->config, flags)) {
output->mUsePreferredMixerAttributes = true;
} else {
for (const auto &client: output->getActiveClients()) {
if (client->uid() == uid && client->strategy() == strategy) {
client->setIsInvalid();
outputsToReopen.push_back(output->mIoHandle);
}
}
}
}
}
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.sample_rate = mixerAttributes->config.sample_rate;
config.channel_mask = mixerAttributes->config.channel_mask;
config.format = mixerAttributes->config.format;
for (const auto output : outputsToReopen) {
sp<SwAudioOutputDescriptor> desc =
reopenOutput(mOutputs.valueFor(output), &config, flags, __func__);
if (desc == nullptr) {
ALOGE("%s, failed to reopen output with preferred mixer attributes", __func__);
continue;
}
desc->mUsePreferredMixerAttributes = true;
}
return NO_ERROR;
}
sp<PreferredMixerAttributesInfo> AudioPolicyManager::getPreferredMixerAttributesInfo(
audio_port_handle_t devicePortId,
product_strategy_t strategy,
bool activeBitPerfectPreferred) {
auto it = mPreferredMixerAttrInfos.find(devicePortId);
if (it == mPreferredMixerAttrInfos.end()) {
return nullptr;
}
if (activeBitPerfectPreferred) {
for (auto [strategy, info] : it->second) {
if ((info->getFlags() & AUDIO_OUTPUT_FLAG_BIT_PERFECT) != AUDIO_OUTPUT_FLAG_NONE
&& info->getActiveClientCount() != 0) {
return info;
}
}
}
auto strategyMatchedMixerAttrInfoIt = it->second.find(strategy);
return strategyMatchedMixerAttrInfoIt == it->second.end()
? nullptr : strategyMatchedMixerAttrInfoIt->second;
}
status_t AudioPolicyManager::getPreferredMixerAttributes(
const audio_attributes_t *attr,
audio_port_handle_t portId,
audio_mixer_attributes_t* mixerAttributes) {
sp<PreferredMixerAttributesInfo> info = getPreferredMixerAttributesInfo(
portId, mEngine->getProductStrategyForAttributes(*attr));
if (info == nullptr) {
return NAME_NOT_FOUND;
}
*mixerAttributes = info->getMixerAttributes();
return NO_ERROR;
}
status_t AudioPolicyManager::clearPreferredMixerAttributes(const audio_attributes_t *attr,
audio_port_handle_t portId,
uid_t uid) {
const product_strategy_t strategy = mEngine->getProductStrategyForAttributes(*attr);
const auto preferredMixerAttrInfo = getPreferredMixerAttributesInfo(portId, strategy);
if (preferredMixerAttrInfo == nullptr) {
return NAME_NOT_FOUND;
}
if (preferredMixerAttrInfo->getUid() != uid) {
ALOGE("%s, requested uid=%d, owned uid=%d",
__func__, uid, preferredMixerAttrInfo->getUid());
return PERMISSION_DENIED;
}
mPreferredMixerAttrInfos[portId].erase(strategy);
if (mPreferredMixerAttrInfos[portId].empty()) {
mPreferredMixerAttrInfos.erase(portId);
}
// Reconfig existing output
std::vector<audio_io_handle_t> potentialOutputsToReopen;
for (size_t i = 0; i < mOutputs.size(); i++) {
if (mOutputs.valueAt(i)->mProfile == preferredMixerAttrInfo->getProfile()) {
potentialOutputsToReopen.push_back(mOutputs.keyAt(i));
}
}
for (const auto output : potentialOutputsToReopen) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueFor(output);
if (desc->isConfigurationMatched(preferredMixerAttrInfo->getConfigBase(),
preferredMixerAttrInfo->getFlags())) {
reopenOutput(desc, nullptr /*config*/, AUDIO_OUTPUT_FLAG_NONE, __func__);
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::listAudioPorts(audio_port_role_t role,
audio_port_type_t type,
unsigned int *num_ports,
struct audio_port_v7 *ports,
unsigned int *generation)
{
if (num_ports == nullptr || (*num_ports != 0 && ports == nullptr) ||
generation == nullptr) {
return BAD_VALUE;
}
ALOGV("listAudioPorts() role %d type %d num_ports %d ports %p", role, type, *num_ports, ports);
if (ports == nullptr) {
*num_ports = 0;
}
size_t portsWritten = 0;
size_t portsMax = *num_ports;
*num_ports = 0;
if (type == AUDIO_PORT_TYPE_NONE || type == AUDIO_PORT_TYPE_DEVICE) {
// do not report devices with type AUDIO_DEVICE_IN_STUB or AUDIO_DEVICE_OUT_STUB
// as they are used by stub HALs by convention
if (role == AUDIO_PORT_ROLE_SINK || role == AUDIO_PORT_ROLE_NONE) {
for (const auto& dev : mAvailableOutputDevices) {
if (dev->type() == AUDIO_DEVICE_OUT_STUB) {
continue;
}
if (portsWritten < portsMax) {
dev->toAudioPort(&ports[portsWritten++]);
}
(*num_ports)++;
}
}
if (role == AUDIO_PORT_ROLE_SOURCE || role == AUDIO_PORT_ROLE_NONE) {
for (const auto& dev : mAvailableInputDevices) {
if (dev->type() == AUDIO_DEVICE_IN_STUB) {
continue;
}
if (portsWritten < portsMax) {
dev->toAudioPort(&ports[portsWritten++]);
}
(*num_ports)++;
}
}
}
if (type == AUDIO_PORT_TYPE_NONE || type == AUDIO_PORT_TYPE_MIX) {
if (role == AUDIO_PORT_ROLE_SINK || role == AUDIO_PORT_ROLE_NONE) {
for (size_t i = 0; i < mInputs.size() && portsWritten < portsMax; i++) {
mInputs[i]->toAudioPort(&ports[portsWritten++]);
}
*num_ports += mInputs.size();
}
if (role == AUDIO_PORT_ROLE_SOURCE || role == AUDIO_PORT_ROLE_NONE) {
size_t numOutputs = 0;
for (size_t i = 0; i < mOutputs.size(); i++) {
if (!mOutputs[i]->isDuplicated()) {
numOutputs++;
if (portsWritten < portsMax) {
mOutputs[i]->toAudioPort(&ports[portsWritten++]);
}
}
}
*num_ports += numOutputs;
}
}
*generation = curAudioPortGeneration();
ALOGV("listAudioPorts() got %zu ports needed %d", portsWritten, *num_ports);
return NO_ERROR;
}
status_t AudioPolicyManager::listDeclaredDevicePorts(media::AudioPortRole role,
std::vector<media::AudioPortFw>* _aidl_return) {
auto pushPort = [&](const sp<DeviceDescriptor>& dev) -> status_t {
audio_port_v7 port;
dev->toAudioPort(&port);
auto aidlPort = VALUE_OR_RETURN_STATUS(legacy2aidl_audio_port_v7_AudioPortFw(port));
_aidl_return->push_back(std::move(aidlPort));
return OK;
};
for (const auto& module : mHwModules) {
for (const auto& dev : module->getDeclaredDevices()) {
if (role == media::AudioPortRole::NONE ||
((role == media::AudioPortRole::SOURCE)
== audio_is_input_device(dev->type()))) {
RETURN_STATUS_IF_ERROR(pushPort(dev));
}
}
}
return OK;
}
status_t AudioPolicyManager::getAudioPort(struct audio_port_v7 *port)
{
if (port == nullptr || port->id == AUDIO_PORT_HANDLE_NONE) {
return BAD_VALUE;
}
sp<DeviceDescriptor> dev = mAvailableOutputDevices.getDeviceFromId(port->id);
if (dev != 0) {
dev->toAudioPort(port);
return NO_ERROR;
}
dev = mAvailableInputDevices.getDeviceFromId(port->id);
if (dev != 0) {
dev->toAudioPort(port);
return NO_ERROR;
}
sp<SwAudioOutputDescriptor> out = mOutputs.getOutputFromId(port->id);
if (out != 0) {
out->toAudioPort(port);
return NO_ERROR;
}
sp<AudioInputDescriptor> in = mInputs.getInputFromId(port->id);
if (in != 0) {
in->toAudioPort(port);
return NO_ERROR;
}
return BAD_VALUE;
}
status_t AudioPolicyManager::createAudioPatch(const struct audio_patch *patch,
audio_patch_handle_t *handle,
uid_t uid)
{
ALOGV("%s", __func__);
if (handle == NULL || patch == NULL) {
return BAD_VALUE;
}
ALOGV("%s num sources %d num sinks %d", __func__, patch->num_sources, patch->num_sinks);
if (!audio_patch_is_valid(patch)) {
return BAD_VALUE;
}
// only one source per audio patch supported for now
if (patch->num_sources > 1) {
return INVALID_OPERATION;
}
if (patch->sources[0].role != AUDIO_PORT_ROLE_SOURCE) {
return INVALID_OPERATION;
}
for (size_t i = 0; i < patch->num_sinks; i++) {
if (patch->sinks[i].role != AUDIO_PORT_ROLE_SINK) {
return INVALID_OPERATION;
}
}
sp<DeviceDescriptor> srcDevice = mAvailableInputDevices.getDeviceFromId(patch->sources[0].id);
sp<DeviceDescriptor> sinkDevice = mAvailableOutputDevices.getDeviceFromId(patch->sinks[0].id);
if (srcDevice == nullptr || sinkDevice == nullptr) {
ALOGW("%s could not create patch, invalid sink and/or source device(s)", __func__);
return BAD_VALUE;
}
ALOGV("%s between source %s and sink %s", __func__,
srcDevice->toString().c_str(), sinkDevice->toString().c_str());
audio_port_handle_t portId = PolicyAudioPort::getNextUniqueId();
// Default attributes, default volume priority, not to infer with non raw audio patches.
audio_attributes_t attributes = attributes_initializer(AUDIO_USAGE_MEDIA);
const struct audio_port_config *source = &patch->sources[0];
sp<SourceClientDescriptor> sourceDesc =
new SourceClientDescriptor(
portId, uid, attributes, *source, srcDevice, AUDIO_STREAM_PATCH,
mEngine->getProductStrategyForAttributes(attributes), toVolumeSource(attributes),
true);
sourceDesc->setPreferredDeviceId(sinkDevice->getId());
status_t status =
connectAudioSourceToSink(sourceDesc, sinkDevice, patch, *handle, uid, 0 /* delayMs */);
if (status != NO_ERROR) {
return INVALID_OPERATION;
}
mAudioSources.add(portId, sourceDesc);
return NO_ERROR;
}
status_t AudioPolicyManager::connectAudioSourceToSink(
const sp<SourceClientDescriptor>& sourceDesc, const sp<DeviceDescriptor> &sinkDevice,
const struct audio_patch *patch,
audio_patch_handle_t &handle,
uid_t uid, uint32_t delayMs)
{
status_t status = createAudioPatchInternal(patch, &handle, uid, delayMs, sourceDesc);
if (status != NO_ERROR || mAudioPatches.indexOfKey(handle) < 0) {
ALOGW("%s patch panel could not connect device patch, error %d", __func__, status);
return INVALID_OPERATION;
}
sourceDesc->connect(handle, sinkDevice);
if (isMsdPatch(handle)) {
return NO_ERROR;
}
// SW Bridge? (@todo: HW bridge, keep track of HwOutput for device selection "reconsideration")
sp<SwAudioOutputDescriptor> swOutput = sourceDesc->swOutput().promote();
ALOG_ASSERT(swOutput != nullptr, "%s: a swOutput shall always be associated", __func__);
if (swOutput->getClient(sourceDesc->portId()) != nullptr) {
ALOGW("%s source portId has already been attached to outputDesc", __func__);
goto FailurePatchAdded;
}
status = swOutput->start();
if (status != NO_ERROR) {
goto FailureSourceAdded;
}
swOutput->addClient(sourceDesc);
status = startSource(swOutput, sourceDesc, &delayMs);
if (status != NO_ERROR) {
ALOGW("%s failed to start source, error %d", __FUNCTION__, status);
goto FailureSourceActive;
}
if (delayMs != 0) {
usleep(delayMs * 1000);
}
return NO_ERROR;
FailureSourceActive:
swOutput->stop();
releaseOutput(sourceDesc->portId());
FailureSourceAdded:
sourceDesc->setSwOutput(nullptr);
FailurePatchAdded:
releaseAudioPatchInternal(handle);
return INVALID_OPERATION;
}
status_t AudioPolicyManager::createAudioPatchInternal(const struct audio_patch *patch,
audio_patch_handle_t *handle,
uid_t uid, uint32_t delayMs,
const sp<SourceClientDescriptor>& sourceDesc)
{
ALOGV("%s num sources %d num sinks %d", __func__, patch->num_sources, patch->num_sinks);
sp<AudioPatch> patchDesc;
ssize_t index = mAudioPatches.indexOfKey(*handle);
ALOGV("%s source id %d role %d type %d", __func__, patch->sources[0].id,
patch->sources[0].role,
patch->sources[0].type);
#if LOG_NDEBUG == 0
for (size_t i = 0; i < patch->num_sinks; i++) {
ALOGV("%s sink %zu: id %d role %d type %d", __func__ ,i, patch->sinks[i].id,
patch->sinks[i].role,
patch->sinks[i].type);
}
#endif
if (index >= 0) {
patchDesc = mAudioPatches.valueAt(index);
ALOGV("%s mUidCached %d patchDesc->mUid %d uid %d",
__func__, mUidCached, patchDesc->getUid(), uid);
if (patchDesc->getUid() != mUidCached && uid != patchDesc->getUid()) {
return INVALID_OPERATION;
}
} else {
*handle = AUDIO_PATCH_HANDLE_NONE;
}
if (patch->sources[0].type == AUDIO_PORT_TYPE_MIX) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputFromId(patch->sources[0].id);
if (outputDesc == NULL) {
ALOGV("%s output not found for id %d", __func__, patch->sources[0].id);
return BAD_VALUE;
}
ALOG_ASSERT(!outputDesc->isDuplicated(),"duplicated output %d in source in ports",
outputDesc->mIoHandle);
if (patchDesc != 0) {
if (patchDesc->mPatch.sources[0].id != patch->sources[0].id) {
ALOGV("%s source id differs for patch current id %d new id %d",
__func__, patchDesc->mPatch.sources[0].id, patch->sources[0].id);
return BAD_VALUE;
}
}
DeviceVector devices;
for (size_t i = 0; i < patch->num_sinks; i++) {
// Only support mix to devices connection
// TODO add support for mix to mix connection
if (patch->sinks[i].type != AUDIO_PORT_TYPE_DEVICE) {
ALOGV("%s source mix but sink is not a device", __func__);
return INVALID_OPERATION;
}
sp<DeviceDescriptor> devDesc =
mAvailableOutputDevices.getDeviceFromId(patch->sinks[i].id);
if (devDesc == 0) {
ALOGV("%s out device not found for id %d", __func__, patch->sinks[i].id);
return BAD_VALUE;
}
if (outputDesc->mProfile->getCompatibilityScore(
DeviceVector(devDesc),
patch->sources[0].sample_rate,
nullptr, // updatedSamplingRate
patch->sources[0].format,
nullptr, // updatedFormat
patch->sources[0].channel_mask,
nullptr, // updatedChannelMask
AUDIO_OUTPUT_FLAG_NONE /*FIXME*/) == IOProfile::NO_MATCH) {
ALOGV("%s profile not supported for device %08x", __func__, devDesc->type());
return INVALID_OPERATION;
}
devices.add(devDesc);
}
if (devices.size() == 0) {
return INVALID_OPERATION;
}
// TODO: reconfigure output format and channels here
ALOGV("%s setting device %s on output %d",
__func__, dumpDeviceTypes(devices.types()).c_str(), outputDesc->mIoHandle);
setOutputDevices(__func__, outputDesc, devices, true, 0, handle);
index = mAudioPatches.indexOfKey(*handle);
if (index >= 0) {
if (patchDesc != 0 && patchDesc != mAudioPatches.valueAt(index)) {
ALOGW("%s setOutputDevice() did not reuse the patch provided", __func__);
}
patchDesc = mAudioPatches.valueAt(index);
patchDesc->setUid(uid);
ALOGV("%s success", __func__);
} else {
ALOGW("%s setOutputDevice() failed to create a patch", __func__);
return INVALID_OPERATION;
}
} else if (patch->sources[0].type == AUDIO_PORT_TYPE_DEVICE) {
if (patch->sinks[0].type == AUDIO_PORT_TYPE_MIX) {
// input device to input mix connection
// only one sink supported when connecting an input device to a mix
if (patch->num_sinks > 1) {
return INVALID_OPERATION;
}
sp<AudioInputDescriptor> inputDesc = mInputs.getInputFromId(patch->sinks[0].id);
if (inputDesc == NULL) {
return BAD_VALUE;
}
if (patchDesc != 0) {
if (patchDesc->mPatch.sinks[0].id != patch->sinks[0].id) {
return BAD_VALUE;
}
}
sp<DeviceDescriptor> device =
mAvailableInputDevices.getDeviceFromId(patch->sources[0].id);
if (device == 0) {
return BAD_VALUE;
}
if (inputDesc->mProfile->getCompatibilityScore(
DeviceVector(device),
patch->sinks[0].sample_rate,
nullptr, /*updatedSampleRate*/
patch->sinks[0].format,
nullptr, /*updatedFormat*/
patch->sinks[0].channel_mask,
nullptr, /*updatedChannelMask*/
// FIXME for the parameter type,
// and the NONE
(audio_output_flags_t)
AUDIO_INPUT_FLAG_NONE) == IOProfile::NO_MATCH) {
return INVALID_OPERATION;
}
// TODO: reconfigure output format and channels here
ALOGV("%s setting device %s on output %d", __func__,
device->toString().c_str(), inputDesc->mIoHandle);
setInputDevice(inputDesc->mIoHandle, device, true, handle);
index = mAudioPatches.indexOfKey(*handle);
if (index >= 0) {
if (patchDesc != 0 && patchDesc != mAudioPatches.valueAt(index)) {
ALOGW("%s setInputDevice() did not reuse the patch provided", __func__);
}
patchDesc = mAudioPatches.valueAt(index);
patchDesc->setUid(uid);
ALOGV("%s success", __func__);
} else {
ALOGW("%s setInputDevice() failed to create a patch", __func__);
return INVALID_OPERATION;
}
} else if (patch->sinks[0].type == AUDIO_PORT_TYPE_DEVICE) {
// device to device connection
if (patchDesc != 0) {
if (patchDesc->mPatch.sources[0].id != patch->sources[0].id) {
return BAD_VALUE;
}
}
sp<DeviceDescriptor> srcDevice =
mAvailableInputDevices.getDeviceFromId(patch->sources[0].id);
if (srcDevice == 0) {
return BAD_VALUE;
}
//update source and sink with our own data as the data passed in the patch may
// be incomplete.
PatchBuilder patchBuilder;
audio_port_config sourcePortConfig = {};
// if first sink is to MSD, establish single MSD patch
if (getMsdAudioOutDevices().contains(
mAvailableOutputDevices.getDeviceFromId(patch->sinks[0].id))) {
ALOGV("%s patching to MSD", __FUNCTION__);
patchBuilder = buildMsdPatch(false /*msdIsSource*/, srcDevice);
goto installPatch;
}
srcDevice->toAudioPortConfig(&sourcePortConfig, &patch->sources[0]);
patchBuilder.addSource(sourcePortConfig);
for (size_t i = 0; i < patch->num_sinks; i++) {
if (patch->sinks[i].type != AUDIO_PORT_TYPE_DEVICE) {
ALOGV("%s source device but one sink is not a device", __func__);
return INVALID_OPERATION;
}
sp<DeviceDescriptor> sinkDevice =
mAvailableOutputDevices.getDeviceFromId(patch->sinks[i].id);
if (sinkDevice == 0) {
return BAD_VALUE;
}
audio_port_config sinkPortConfig = {};
sinkDevice->toAudioPortConfig(&sinkPortConfig, &patch->sinks[i]);
patchBuilder.addSink(sinkPortConfig);
// Whatever Sw or Hw bridge, we do attach an SwOutput to an Audio Source for
// volume management purpose (tracking activity)
// In case of Hw bridge, it is a Work Around. The mixPort used is the one declared
// in config XML to reach the sink so that is can be declared as available.
audio_io_handle_t output = AUDIO_IO_HANDLE_NONE;
sp<SwAudioOutputDescriptor> outputDesc;
if (!sourceDesc->isInternal()) {
// take care of dynamic routing for SwOutput selection,
audio_attributes_t attributes = sourceDesc->attributes();
audio_stream_type_t stream = sourceDesc->stream();
audio_attributes_t resultAttr;
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.sample_rate = sourceDesc->config().sample_rate;
audio_channel_mask_t sourceMask = sourceDesc->config().channel_mask;
config.channel_mask =
(audio_channel_mask_get_representation(sourceMask)
== AUDIO_CHANNEL_REPRESENTATION_INDEX) ? sourceMask
: audio_channel_mask_in_to_out(sourceMask);
config.format = sourceDesc->config().format;
audio_output_flags_t flags = AUDIO_OUTPUT_FLAG_NONE;
audio_port_handle_t selectedDeviceId = AUDIO_PORT_HANDLE_NONE;
bool isRequestedDeviceForExclusiveUse = false;
output_type_t outputType;
bool isSpatialized;
bool isBitPerfect;
getOutputForAttrInt(&resultAttr, &output, AUDIO_SESSION_NONE, &attributes,
&stream, sourceDesc->uid(), &config, &flags,
&selectedDeviceId, &isRequestedDeviceForExclusiveUse,
nullptr, &outputType, &isSpatialized, &isBitPerfect);
if (output == AUDIO_IO_HANDLE_NONE) {
ALOGV("%s no output for device %s",
__FUNCTION__, sinkDevice->toString().c_str());
return INVALID_OPERATION;
}
outputDesc = mOutputs.valueFor(output);
if (outputDesc->isDuplicated()) {
ALOGE("%s output is duplicated", __func__);
return INVALID_OPERATION;
}
bool closeOutput = outputDesc->mDirectOpenCount != 0;
sourceDesc->setSwOutput(outputDesc, closeOutput);
} else {
// Same for "raw patches" aka created from createAudioPatch API
SortedVector<audio_io_handle_t> outputs =
getOutputsForDevices(DeviceVector(sinkDevice), mOutputs);
// if the sink device is reachable via an opened output stream, request to
// go via this output stream by adding a second source to the patch
// description
output = selectOutput(outputs);
if (output == AUDIO_IO_HANDLE_NONE) {
ALOGE("%s no output available for internal patch sink", __func__);
return INVALID_OPERATION;
}
outputDesc = mOutputs.valueFor(output);
if (outputDesc->isDuplicated()) {
ALOGV("%s output for device %s is duplicated",
__func__, sinkDevice->toString().c_str());
return INVALID_OPERATION;
}
sourceDesc->setSwOutput(outputDesc, /* closeOutput= */ false);
}
// create a software bridge in PatchPanel if:
// - source and sink devices are on different HW modules OR
// - audio HAL version is < 3.0
// - audio HAL version is >= 3.0 but no route has been declared between devices
// - called from startAudioSource (aka sourceDesc is not internal) and source device
// does not have a gain controller
if (!srcDevice->hasSameHwModuleAs(sinkDevice) ||
(srcDevice->getModuleVersionMajor() < 3) ||
!srcDevice->getModule()->supportsPatch(srcDevice, sinkDevice) ||
(!sourceDesc->isInternal() &&
srcDevice->getAudioPort()->getGains().size() == 0)) {
// support only one sink device for now to simplify output selection logic
if (patch->num_sinks > 1) {
return INVALID_OPERATION;
}
sourceDesc->setUseSwBridge();
if (outputDesc != nullptr) {
audio_port_config srcMixPortConfig = {};
outputDesc->toAudioPortConfig(&srcMixPortConfig, nullptr);
// for volume control, we may need a valid stream
srcMixPortConfig.ext.mix.usecase.stream =
(!sourceDesc->isInternal() || isCallTxAudioSource(sourceDesc)) ?
mEngine->getStreamTypeForAttributes(sourceDesc->attributes()) :
AUDIO_STREAM_PATCH;
patchBuilder.addSource(srcMixPortConfig);
}
}
}
// TODO: check from routing capabilities in config file and other conflicting patches
installPatch:
status_t status = installPatch(
__func__, index, handle, patchBuilder.patch(), delayMs, uid, &patchDesc);
if (status != NO_ERROR) {
ALOGW("%s patch panel could not connect device patch, error %d", __func__, status);
return INVALID_OPERATION;
}
} else {
return BAD_VALUE;
}
} else {
return BAD_VALUE;
}
return NO_ERROR;
}
status_t AudioPolicyManager::releaseAudioPatch(audio_patch_handle_t handle, uid_t uid)
{
ALOGV("%s patch %d", __func__, handle);
ssize_t index = mAudioPatches.indexOfKey(handle);
if (index < 0) {
return BAD_VALUE;
}
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
ALOGV("%s() mUidCached %d patchDesc->mUid %d uid %d",
__func__, mUidCached, patchDesc->getUid(), uid);
if (patchDesc->getUid() != mUidCached && uid != patchDesc->getUid()) {
return INVALID_OPERATION;
}
audio_port_handle_t portId = AUDIO_PORT_HANDLE_NONE;
for (size_t i = 0; i < mAudioSources.size(); i++) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
if (sourceDesc != nullptr && sourceDesc->getPatchHandle() == handle) {
portId = sourceDesc->portId();
break;
}
}
return portId != AUDIO_PORT_HANDLE_NONE ?
stopAudioSource(portId) : releaseAudioPatchInternal(handle);
}
status_t AudioPolicyManager::releaseAudioPatchInternal(audio_patch_handle_t handle,
uint32_t delayMs,
const sp<SourceClientDescriptor>& sourceDesc)
{
ALOGV("%s patch %d", __func__, handle);
if (mAudioPatches.indexOfKey(handle) < 0) {
ALOGE("%s: no patch found with handle=%d", __func__, handle);
return BAD_VALUE;
}
sp<AudioPatch> patchDesc = mAudioPatches.valueFor(handle);
struct audio_patch *patch = &patchDesc->mPatch;
patchDesc->setUid(mUidCached);
if (patch->sources[0].type == AUDIO_PORT_TYPE_MIX) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputFromId(patch->sources[0].id);
if (outputDesc == NULL) {
ALOGV("%s output not found for id %d", __func__, patch->sources[0].id);
return BAD_VALUE;
}
setOutputDevices(__func__, outputDesc,
getNewOutputDevices(outputDesc, true /*fromCache*/),
true,
0,
NULL);
} else if (patch->sources[0].type == AUDIO_PORT_TYPE_DEVICE) {
if (patch->sinks[0].type == AUDIO_PORT_TYPE_MIX) {
sp<AudioInputDescriptor> inputDesc = mInputs.getInputFromId(patch->sinks[0].id);
if (inputDesc == NULL) {
ALOGV("%s input not found for id %d", __func__, patch->sinks[0].id);
return BAD_VALUE;
}
setInputDevice(inputDesc->mIoHandle,
getNewInputDevice(inputDesc),
true,
NULL);
} else if (patch->sinks[0].type == AUDIO_PORT_TYPE_DEVICE) {
status_t status =
mpClientInterface->releaseAudioPatch(patchDesc->getAfHandle(), delayMs);
ALOGV("%s patch panel returned %d patchHandle %d",
__func__, status, patchDesc->getAfHandle());
removeAudioPatch(patchDesc->getHandle());
nextAudioPortGeneration();
mpClientInterface->onAudioPatchListUpdate();
// SW or HW Bridge
sp<SwAudioOutputDescriptor> outputDesc = nullptr;
audio_patch_handle_t patchHandle = AUDIO_PATCH_HANDLE_NONE;
if (patch->num_sources > 1 && patch->sources[1].type == AUDIO_PORT_TYPE_MIX) {
outputDesc = mOutputs.getOutputFromId(patch->sources[1].id);
} else if (patch->num_sources == 1 && sourceDesc != nullptr) {
outputDesc = sourceDesc->swOutput().promote();
}
if (outputDesc == nullptr) {
ALOGW("%s no output for id %d", __func__, patch->sources[0].id);
// releaseOutput has already called closeOutput in case of direct output
return NO_ERROR;
}
patchHandle = outputDesc->getPatchHandle();
// While using a HwBridge, force reconsidering device only if not reusing an existing
// output and no more activity on output (will force to close).
const bool force = sourceDesc->canCloseOutput() && !outputDesc->isActive();
// APM pattern is to have always outputs opened / patch realized for reachable devices.
// Update device may result to NONE (empty), coupled with force, it releases the patch.
// Reconsider device only for cases:
// 1 / Active Output
// 2 / Inactive Output previously hosting HwBridge
// 3 / Inactive Output previously hosting SwBridge that can be closed.
bool updateDevice = outputDesc->isActive() || !sourceDesc->useSwBridge() ||
sourceDesc->canCloseOutput();
setOutputDevices(__func__, outputDesc,
updateDevice ? getNewOutputDevices(outputDesc, true /*fromCache*/) :
outputDesc->devices(),
force,
0,
patchHandle == AUDIO_PATCH_HANDLE_NONE ? nullptr : &patchHandle);
} else {
return BAD_VALUE;
}
} else {
return BAD_VALUE;
}
return NO_ERROR;
}
status_t AudioPolicyManager::listAudioPatches(unsigned int *num_patches,
struct audio_patch *patches,
unsigned int *generation)
{
if (generation == NULL) {
return BAD_VALUE;
}
*generation = curAudioPortGeneration();
return mAudioPatches.listAudioPatches(num_patches, patches);
}
status_t AudioPolicyManager::setAudioPortConfig(const struct audio_port_config *config)
{
ALOGV("setAudioPortConfig()");
if (config == NULL) {
return BAD_VALUE;
}
ALOGV("setAudioPortConfig() on port handle %d", config->id);
// Only support gain configuration for now
if (config->config_mask != AUDIO_PORT_CONFIG_GAIN) {
return INVALID_OPERATION;
}
sp<AudioPortConfig> audioPortConfig;
if (config->type == AUDIO_PORT_TYPE_MIX) {
if (config->role == AUDIO_PORT_ROLE_SOURCE) {
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.getOutputFromId(config->id);
if (outputDesc == NULL) {
return BAD_VALUE;
}
ALOG_ASSERT(!outputDesc->isDuplicated(),
"setAudioPortConfig() called on duplicated output %d",
outputDesc->mIoHandle);
audioPortConfig = outputDesc;
} else if (config->role == AUDIO_PORT_ROLE_SINK) {
sp<AudioInputDescriptor> inputDesc = mInputs.getInputFromId(config->id);
if (inputDesc == NULL) {
return BAD_VALUE;
}
audioPortConfig = inputDesc;
} else {
return BAD_VALUE;
}
} else if (config->type == AUDIO_PORT_TYPE_DEVICE) {
sp<DeviceDescriptor> deviceDesc;
if (config->role == AUDIO_PORT_ROLE_SOURCE) {
deviceDesc = mAvailableInputDevices.getDeviceFromId(config->id);
} else if (config->role == AUDIO_PORT_ROLE_SINK) {
deviceDesc = mAvailableOutputDevices.getDeviceFromId(config->id);
} else {
return BAD_VALUE;
}
if (deviceDesc == NULL) {
return BAD_VALUE;
}
audioPortConfig = deviceDesc;
} else {
return BAD_VALUE;
}
struct audio_port_config backupConfig = {};
status_t status = audioPortConfig->applyAudioPortConfig(config, &backupConfig);
if (status == NO_ERROR) {
struct audio_port_config newConfig = {};
audioPortConfig->toAudioPortConfig(&newConfig, config);
status = mpClientInterface->setAudioPortConfig(&newConfig, 0);
}
if (status != NO_ERROR) {
audioPortConfig->applyAudioPortConfig(&backupConfig);
}
return status;
}
void AudioPolicyManager::releaseResourcesForUid(uid_t uid)
{
clearAudioSources(uid);
clearAudioPatches(uid);
clearSessionRoutes(uid);
}
void AudioPolicyManager::clearAudioPatches(uid_t uid)
{
for (ssize_t i = (ssize_t)mAudioPatches.size() - 1; i >= 0; i--) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(i);
if (patchDesc->getUid() == uid) {
releaseAudioPatch(mAudioPatches.keyAt(i), uid);
}
}
}
void AudioPolicyManager::checkStrategyRoute(product_strategy_t ps, audio_io_handle_t ouptutToSkip)
{
// Take the first attributes following the product strategy as it is used to retrieve the routed
// device. All attributes wihin a strategy follows the same "routing strategy"
auto attributes = mEngine->getAllAttributesForProductStrategy(ps).front();
DeviceVector devices = mEngine->getOutputDevicesForAttributes(attributes, nullptr, false);
SortedVector<audio_io_handle_t> outputs = getOutputsForDevices(devices, mOutputs);
std::map<audio_io_handle_t, DeviceVector> outputsToReopen;
for (size_t j = 0; j < mOutputs.size(); j++) {
if (mOutputs.keyAt(j) == ouptutToSkip) {
continue;
}
sp<SwAudioOutputDescriptor> outputDesc = mOutputs.valueAt(j);
if (!outputDesc->isStrategyActive(ps)) {
continue;
}
// If the default device for this strategy is on another output mix,
// invalidate all tracks in this strategy to force re connection.
// Otherwise select new device on the output mix.
if (outputs.indexOf(mOutputs.keyAt(j)) < 0) {
invalidateStreams(mEngine->getStreamTypesForProductStrategy(ps));
} else {
DeviceVector newDevices = getNewOutputDevices(outputDesc, false /*fromCache*/);
if (outputDesc->mUsePreferredMixerAttributes && outputDesc->devices() != newDevices) {
// If the device is using preferred mixer attributes, the output need to reopen
// with default configuration when the new selected devices are different from
// current routing devices.
outputsToReopen.emplace(mOutputs.keyAt(j), newDevices);
continue;
}
setOutputDevices(__func__, outputDesc, newDevices, false);
}
}
reopenOutputsWithDevices(outputsToReopen);
}
void AudioPolicyManager::clearSessionRoutes(uid_t uid)
{
// remove output routes associated with this uid
std::vector<product_strategy_t> affectedStrategies;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<AudioOutputDescriptor> outputDesc = mOutputs.valueAt(i);
for (const auto& client : outputDesc->getClientIterable()) {
if (client->hasPreferredDevice() && client->uid() == uid) {
client->setPreferredDeviceId(AUDIO_PORT_HANDLE_NONE);
auto clientStrategy = client->strategy();
if (std::find(begin(affectedStrategies), end(affectedStrategies), clientStrategy) !=
end(affectedStrategies)) {
continue;
}
affectedStrategies.push_back(client->strategy());
}
}
}
// reroute outputs if necessary
for (const auto& strategy : affectedStrategies) {
checkStrategyRoute(strategy, AUDIO_IO_HANDLE_NONE);
}
// remove input routes associated with this uid
SortedVector<audio_source_t> affectedSources;
for (size_t i = 0; i < mInputs.size(); i++) {
sp<AudioInputDescriptor> inputDesc = mInputs.valueAt(i);
for (const auto& client : inputDesc->getClientIterable()) {
if (client->hasPreferredDevice() && client->uid() == uid) {
client->setPreferredDeviceId(AUDIO_PORT_HANDLE_NONE);
affectedSources.add(client->source());
}
}
}
// reroute inputs if necessary
SortedVector<audio_io_handle_t> inputsToClose;
for (size_t i = 0; i < mInputs.size(); i++) {
sp<AudioInputDescriptor> inputDesc = mInputs.valueAt(i);
if (affectedSources.indexOf(inputDesc->source()) >= 0) {
inputsToClose.add(inputDesc->mIoHandle);
}
}
for (const auto& input : inputsToClose) {
closeInput(input);
}
}
void AudioPolicyManager::clearAudioSources(uid_t uid)
{
for (ssize_t i = (ssize_t)mAudioSources.size() - 1; i >= 0; i--) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
if (sourceDesc->uid() == uid) {
stopAudioSource(mAudioSources.keyAt(i));
}
}
}
status_t AudioPolicyManager::acquireSoundTriggerSession(audio_session_t *session,
audio_io_handle_t *ioHandle,
audio_devices_t *device)
{
*session = (audio_session_t)mpClientInterface->newAudioUniqueId(AUDIO_UNIQUE_ID_USE_SESSION);
*ioHandle = (audio_io_handle_t)mpClientInterface->newAudioUniqueId(AUDIO_UNIQUE_ID_USE_INPUT);
audio_attributes_t attr = { .source = AUDIO_SOURCE_HOTWORD };
sp<DeviceDescriptor> deviceDesc = mEngine->getInputDeviceForAttributes(attr);
if (deviceDesc == nullptr) {
return INVALID_OPERATION;
}
*device = deviceDesc->type();
return mSoundTriggerSessions.acquireSession(*session, *ioHandle);
}
status_t AudioPolicyManager::startAudioSource(const struct audio_port_config *source,
const audio_attributes_t *attributes,
audio_port_handle_t *portId,
uid_t uid, bool internal)
{
ALOGV("%s", __FUNCTION__);
*portId = AUDIO_PORT_HANDLE_NONE;
if (source == NULL || attributes == NULL || portId == NULL) {
ALOGW("%s invalid argument: source %p attributes %p handle %p",
__FUNCTION__, source, attributes, portId);
return BAD_VALUE;
}
if (source->role != AUDIO_PORT_ROLE_SOURCE ||
source->type != AUDIO_PORT_TYPE_DEVICE) {
ALOGW("%s INVALID_OPERATION source->role %d source->type %d",
__FUNCTION__, source->role, source->type);
return INVALID_OPERATION;
}
sp<DeviceDescriptor> srcDevice =
mAvailableInputDevices.getDevice(source->ext.device.type,
String8(source->ext.device.address),
AUDIO_FORMAT_DEFAULT);
if (srcDevice == 0) {
ALOGW("%s source->ext.device.type %08x not found", __FUNCTION__, source->ext.device.type);
return BAD_VALUE;
}
*portId = PolicyAudioPort::getNextUniqueId();
sp<SourceClientDescriptor> sourceDesc =
new SourceClientDescriptor(*portId, uid, *attributes, *source, srcDevice,
mEngine->getStreamTypeForAttributes(*attributes),
mEngine->getProductStrategyForAttributes(*attributes),
toVolumeSource(*attributes), internal);
status_t status = connectAudioSource(sourceDesc);
if (status == NO_ERROR) {
mAudioSources.add(*portId, sourceDesc);
}
return status;
}
status_t AudioPolicyManager::connectAudioSource(const sp<SourceClientDescriptor>& sourceDesc)
{
ALOGV("%s handle %d", __FUNCTION__, sourceDesc->portId());
// make sure we only have one patch per source.
disconnectAudioSource(sourceDesc);
audio_attributes_t attributes = sourceDesc->attributes();
// May the device (dynamic) have been disconnected/reconnected, id has changed.
sp<DeviceDescriptor> srcDevice = mAvailableInputDevices.getDevice(
sourceDesc->srcDevice()->type(),
String8(sourceDesc->srcDevice()->address().c_str()),
AUDIO_FORMAT_DEFAULT);
DeviceVector sinkDevices =
mEngine->getOutputDevicesForAttributes(attributes, nullptr, false /*fromCache*/);
ALOG_ASSERT(!sinkDevices.isEmpty(), "connectAudioSource(): no device found for attributes");
sp<DeviceDescriptor> sinkDevice = sinkDevices.itemAt(0);
if (!mAvailableOutputDevices.contains(sinkDevice)) {
ALOGE("%s Device %s not available", __func__, sinkDevice->toString().c_str());
return INVALID_OPERATION;
}
PatchBuilder patchBuilder;
patchBuilder.addSink(sinkDevice).addSource(srcDevice);
audio_patch_handle_t handle = AUDIO_PATCH_HANDLE_NONE;
return connectAudioSourceToSink(
sourceDesc, sinkDevice, patchBuilder.patch(), handle, mUidCached, 0 /*delayMs*/);
}
status_t AudioPolicyManager::stopAudioSource(audio_port_handle_t portId)
{
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueFor(portId);
ALOGV("%s port ID %d", __FUNCTION__, portId);
if (sourceDesc == 0) {
ALOGW("%s unknown source for port ID %d", __FUNCTION__, portId);
return BAD_VALUE;
}
status_t status = disconnectAudioSource(sourceDesc);
mAudioSources.removeItem(portId);
return status;
}
status_t AudioPolicyManager::setMasterMono(bool mono)
{
if (mMasterMono == mono) {
return NO_ERROR;
}
mMasterMono = mono;
// if enabling mono we close all offloaded devices, which will invalidate the
// corresponding AudioTrack. The AudioTrack client/MediaPlayer is responsible
// for recreating the new AudioTrack as non-offloaded PCM.
//
// If disabling mono, we leave all tracks as is: we don't know which clients
// and tracks are able to be recreated as offloaded. The next "song" should
// play back offloaded.
if (mMasterMono) {
Vector<audio_io_handle_t> offloaded;
for (size_t i = 0; i < mOutputs.size(); ++i) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc->mFlags & AUDIO_OUTPUT_FLAG_COMPRESS_OFFLOAD) {
offloaded.push(desc->mIoHandle);
}
}
for (const auto& handle : offloaded) {
closeOutput(handle);
}
}
// update master mono for all remaining outputs
for (size_t i = 0; i < mOutputs.size(); ++i) {
updateMono(mOutputs.keyAt(i));
}
return NO_ERROR;
}
status_t AudioPolicyManager::getMasterMono(bool *mono)
{
*mono = mMasterMono;
return NO_ERROR;
}
float AudioPolicyManager::getStreamVolumeDB(
audio_stream_type_t stream, int index, audio_devices_t device)
{
return computeVolume(getVolumeCurves(stream), toVolumeSource(stream), index, {device});
}
status_t AudioPolicyManager::getSurroundFormats(unsigned int *numSurroundFormats,
audio_format_t *surroundFormats,
bool *surroundFormatsEnabled)
{
if (numSurroundFormats == nullptr || (*numSurroundFormats != 0 &&
(surroundFormats == nullptr || surroundFormatsEnabled == nullptr))) {
return BAD_VALUE;
}
ALOGV("%s() numSurroundFormats %d surroundFormats %p surroundFormatsEnabled %p",
__func__, *numSurroundFormats, surroundFormats, surroundFormatsEnabled);
size_t formatsWritten = 0;
size_t formatsMax = *numSurroundFormats;
*numSurroundFormats = mConfig->getSurroundFormats().size();
audio_policy_forced_cfg_t forceUse = mEngine->getForceUse(
AUDIO_POLICY_FORCE_FOR_ENCODED_SURROUND);
for (const auto& format: mConfig->getSurroundFormats()) {
if (formatsWritten < formatsMax) {
surroundFormats[formatsWritten] = format.first;
bool formatEnabled = true;
switch (forceUse) {
case AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL:
formatEnabled = mManualSurroundFormats.count(format.first) != 0;
break;
case AUDIO_POLICY_FORCE_ENCODED_SURROUND_NEVER:
formatEnabled = false;
break;
default: // AUTO or ALWAYS => true
break;
}
surroundFormatsEnabled[formatsWritten++] = formatEnabled;
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::getReportedSurroundFormats(unsigned int *numSurroundFormats,
audio_format_t *surroundFormats) {
if (numSurroundFormats == nullptr || (*numSurroundFormats != 0 && surroundFormats == nullptr)) {
return BAD_VALUE;
}
ALOGV("%s() numSurroundFormats %d surroundFormats %p",
__func__, *numSurroundFormats, surroundFormats);
size_t formatsWritten = 0;
size_t formatsMax = *numSurroundFormats;
std::unordered_set<audio_format_t> formats; // Uses primary surround formats only
// Return formats from all device profiles that have already been resolved by
// checkOutputsForDevice().
for (size_t i = 0; i < mAvailableOutputDevices.size(); i++) {
sp<DeviceDescriptor> device = mAvailableOutputDevices[i];
audio_devices_t deviceType = device->type();
// Enabling/disabling formats are applied to only HDMI devices. So, this function
// returns formats reported by HDMI devices.
if (deviceType != AUDIO_DEVICE_OUT_HDMI) {
continue;
}
// Formats reported by sink devices
std::unordered_set<audio_format_t> formatset;
if (auto it = mReportedFormatsMap.find(device); it != mReportedFormatsMap.end()) {
formatset.insert(it->second.begin(), it->second.end());
}
// Formats hard-coded in the in policy configuration file (if any).
FormatVector encodedFormats = device->encodedFormats();
formatset.insert(encodedFormats.begin(), encodedFormats.end());
// Filter the formats which are supported by the vendor hardware.
for (auto it = formatset.begin(); it != formatset.end(); ++it) {
if (mConfig->getSurroundFormats().count(*it) != 0) {
formats.insert(*it);
} else {
for (const auto& pair : mConfig->getSurroundFormats()) {
if (pair.second.count(*it) != 0) {
formats.insert(pair.first);
break;
}
}
}
}
}
*numSurroundFormats = formats.size();
for (const auto& format: formats) {
if (formatsWritten < formatsMax) {
surroundFormats[formatsWritten++] = format;
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::setSurroundFormatEnabled(audio_format_t audioFormat, bool enabled)
{
ALOGV("%s() format 0x%X enabled %d", __func__, audioFormat, enabled);
const auto& formatIter = mConfig->getSurroundFormats().find(audioFormat);
if (formatIter == mConfig->getSurroundFormats().end()) {
ALOGW("%s() format 0x%X is not a known surround format", __func__, audioFormat);
return BAD_VALUE;
}
if (mEngine->getForceUse(AUDIO_POLICY_FORCE_FOR_ENCODED_SURROUND) !=
AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL) {
ALOGW("%s() not in manual mode for surround sound format selection", __func__);
return INVALID_OPERATION;
}
if ((mManualSurroundFormats.count(audioFormat) != 0) == enabled) {
return NO_ERROR;
}
std::unordered_set<audio_format_t> surroundFormatsBackup(mManualSurroundFormats);
if (enabled) {
mManualSurroundFormats.insert(audioFormat);
for (const auto& subFormat : formatIter->second) {
mManualSurroundFormats.insert(subFormat);
}
} else {
mManualSurroundFormats.erase(audioFormat);
for (const auto& subFormat : formatIter->second) {
mManualSurroundFormats.erase(subFormat);
}
}
sp<SwAudioOutputDescriptor> outputDesc;
bool profileUpdated = false;
DeviceVector hdmiOutputDevices = mAvailableOutputDevices.getDevicesFromType(
AUDIO_DEVICE_OUT_HDMI);
for (size_t i = 0; i < hdmiOutputDevices.size(); i++) {
// Simulate reconnection to update enabled surround sound formats.
String8 address = String8(hdmiOutputDevices[i]->address().c_str());
std::string name = hdmiOutputDevices[i]->getName();
status_t status = setDeviceConnectionStateInt(AUDIO_DEVICE_OUT_HDMI,
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
address.c_str(),
name.c_str(),
AUDIO_FORMAT_DEFAULT);
if (status != NO_ERROR) {
continue;
}
status = setDeviceConnectionStateInt(AUDIO_DEVICE_OUT_HDMI,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
address.c_str(),
name.c_str(),
AUDIO_FORMAT_DEFAULT);
profileUpdated |= (status == NO_ERROR);
}
// FIXME: Why doing this for input HDMI devices if we don't augment their reported formats?
DeviceVector hdmiInputDevices = mAvailableInputDevices.getDevicesFromType(
AUDIO_DEVICE_IN_HDMI);
for (size_t i = 0; i < hdmiInputDevices.size(); i++) {
// Simulate reconnection to update enabled surround sound formats.
String8 address = String8(hdmiInputDevices[i]->address().c_str());
std::string name = hdmiInputDevices[i]->getName();
status_t status = setDeviceConnectionStateInt(AUDIO_DEVICE_IN_HDMI,
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
address.c_str(),
name.c_str(),
AUDIO_FORMAT_DEFAULT);
if (status != NO_ERROR) {
continue;
}
status = setDeviceConnectionStateInt(AUDIO_DEVICE_IN_HDMI,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
address.c_str(),
name.c_str(),
AUDIO_FORMAT_DEFAULT);
profileUpdated |= (status == NO_ERROR);
}
if (!profileUpdated) {
ALOGW("%s() no audio profiles updated, undoing surround formats change", __func__);
mManualSurroundFormats = std::move(surroundFormatsBackup);
}
return profileUpdated ? NO_ERROR : INVALID_OPERATION;
}
void AudioPolicyManager::setAppState(audio_port_handle_t portId, app_state_t state)
{
ALOGV("%s(portId:%d, state:%d)", __func__, portId, state);
for (size_t i = 0; i < mInputs.size(); i++) {
mInputs.valueAt(i)->setAppState(portId, state);
}
}
bool AudioPolicyManager::isHapticPlaybackSupported()
{
for (const auto& hwModule : mHwModules) {
const OutputProfileCollection &outputProfiles = hwModule->getOutputProfiles();
for (const auto &outProfile : outputProfiles) {
struct audio_port audioPort;
outProfile->toAudioPort(&audioPort);
for (size_t i = 0; i < audioPort.num_channel_masks; i++) {
if (audioPort.channel_masks[i] & AUDIO_CHANNEL_HAPTIC_ALL) {
return true;
}
}
}
}
return false;
}
bool AudioPolicyManager::isUltrasoundSupported()
{
bool hasUltrasoundOutput = false;
bool hasUltrasoundInput = false;
for (const auto& hwModule : mHwModules) {
const OutputProfileCollection &outputProfiles = hwModule->getOutputProfiles();
if (!hasUltrasoundOutput) {
for (const auto &outProfile : outputProfiles) {
if (outProfile->getFlags() & AUDIO_OUTPUT_FLAG_ULTRASOUND) {
hasUltrasoundOutput = true;
break;
}
}
}
const InputProfileCollection &inputProfiles = hwModule->getInputProfiles();
if (!hasUltrasoundInput) {
for (const auto &inputProfile : inputProfiles) {
if (inputProfile->getFlags() & AUDIO_INPUT_FLAG_ULTRASOUND) {
hasUltrasoundInput = true;
break;
}
}
}
if (hasUltrasoundOutput && hasUltrasoundInput)
return true;
}
return false;
}
bool AudioPolicyManager::isHotwordStreamSupported(bool lookbackAudio)
{
const auto mask = AUDIO_INPUT_FLAG_HOTWORD_TAP |
(lookbackAudio ? AUDIO_INPUT_FLAG_HW_LOOKBACK : 0);
for (const auto& hwModule : mHwModules) {
const InputProfileCollection &inputProfiles = hwModule->getInputProfiles();
for (const auto &inputProfile : inputProfiles) {
if ((inputProfile->getFlags() & mask) == mask) {
return true;
}
}
}
return false;
}
bool AudioPolicyManager::isCallScreenModeSupported()
{
return mConfig->isCallScreenModeSupported();
}
status_t AudioPolicyManager::disconnectAudioSource(const sp<SourceClientDescriptor>& sourceDesc)
{
ALOGV("%s port Id %d", __FUNCTION__, sourceDesc->portId());
if (!sourceDesc->isConnected()) {
ALOGV("%s port Id %d already disconnected", __FUNCTION__, sourceDesc->portId());
return NO_ERROR;
}
sp<SwAudioOutputDescriptor> swOutput = sourceDesc->swOutput().promote();
if (swOutput != 0) {
status_t status = stopSource(swOutput, sourceDesc);
if (status == NO_ERROR) {
swOutput->stop();
}
if (releaseOutput(sourceDesc->portId())) {
// The output descriptor is reopened to query dynamic profiles. In that case, there is
// no need to release audio patch here but just return NO_ERROR.
return NO_ERROR;
}
} else {
sp<HwAudioOutputDescriptor> hwOutputDesc = sourceDesc->hwOutput().promote();
if (hwOutputDesc != 0) {
// close Hwoutput and remove from mHwOutputs
} else {
ALOGW("%s source has neither SW nor HW output", __FUNCTION__);
}
}
status_t status = releaseAudioPatchInternal(sourceDesc->getPatchHandle(), 0, sourceDesc);
sourceDesc->disconnect();
return status;
}
sp<SourceClientDescriptor> AudioPolicyManager::getSourceForAttributesOnOutput(
audio_io_handle_t output, const audio_attributes_t &attr)
{
sp<SourceClientDescriptor> source;
for (size_t i = 0; i < mAudioSources.size(); i++) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
sp<SwAudioOutputDescriptor> outputDesc = sourceDesc->swOutput().promote();
if (followsSameRouting(attr, sourceDesc->attributes()) &&
outputDesc != 0 && outputDesc->mIoHandle == output) {
source = sourceDesc;
break;
}
}
return source;
}
bool AudioPolicyManager::canBeSpatializedInt(const audio_attributes_t *attr,
const audio_config_t *config,
const AudioDeviceTypeAddrVector &devices) const
{
// The caller can have the audio attributes criteria ignored by either passing a null ptr or
// the AUDIO_ATTRIBUTES_INITIALIZER value.
// If attributes are specified, current policy is to only allow spatialization for media
// and game usages.
if (attr != nullptr && *attr != AUDIO_ATTRIBUTES_INITIALIZER) {
if (attr->usage != AUDIO_USAGE_MEDIA && attr->usage != AUDIO_USAGE_GAME) {
return false;
}
if ((attr->flags & (AUDIO_FLAG_CONTENT_SPATIALIZED | AUDIO_FLAG_NEVER_SPATIALIZE)) != 0) {
return false;
}
}
// The caller can have the audio config criteria ignored by either passing a null ptr or
// the AUDIO_CONFIG_INITIALIZER value.
// If an audio config is specified, current policy is to only allow spatialization for
// some positional channel masks and PCM format and for stereo if low latency performance
// mode is not requested.
if (config != nullptr && *config != AUDIO_CONFIG_INITIALIZER) {
static const bool stereo_spatialization_enabled =
property_get_bool("ro.audio.stereo_spatialization_enabled", false);
const bool channel_mask_spatialized =
(stereo_spatialization_enabled && com_android_media_audio_stereo_spatialization())
? audio_channel_mask_contains_stereo(config->channel_mask)
: audio_is_channel_mask_spatialized(config->channel_mask);
if (!channel_mask_spatialized) {
return false;
}
if (!audio_is_linear_pcm(config->format)) {
return false;
}
if (config->channel_mask == AUDIO_CHANNEL_OUT_STEREO
&& ((attr->flags & AUDIO_FLAG_LOW_LATENCY) != 0)) {
return false;
}
}
sp<IOProfile> profile =
getSpatializerOutputProfile(config, devices);
if (profile == nullptr) {
return false;
}
return true;
}
void AudioPolicyManager::checkVirtualizerClientRoutes() {
std::set<audio_stream_type_t> streamsToInvalidate;
for (size_t i = 0; i < mOutputs.size(); i++) {
const sp<SwAudioOutputDescriptor>& desc = mOutputs[i];
for (const sp<TrackClientDescriptor>& client : desc->getClientIterable()) {
audio_attributes_t attr = client->attributes();
DeviceVector devices = mEngine->getOutputDevicesForAttributes(attr, nullptr, false);
AudioDeviceTypeAddrVector devicesTypeAddress = devices.toTypeAddrVector();
audio_config_base_t clientConfig = client->config();
audio_config_t config = audio_config_initializer(&clientConfig);
if (desc != mSpatializerOutput
&& canBeSpatializedInt(&attr, &config, devicesTypeAddress)) {
streamsToInvalidate.insert(client->stream());
}
}
}
invalidateStreams(StreamTypeVector(streamsToInvalidate.begin(), streamsToInvalidate.end()));
}
bool AudioPolicyManager::isOutputOnlyAvailableRouteToSomeDevice(
const sp<SwAudioOutputDescriptor>& outputDesc) {
if (outputDesc->isDuplicated()) {
return false;
}
DeviceVector devices = outputDesc->supportedDevices();
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (desc == outputDesc || desc->isDuplicated()) {
continue;
}
DeviceVector sharedDevices = desc->filterSupportedDevices(devices);
if (!sharedDevices.isEmpty()
&& (desc->devicesSupportEncodedFormats(sharedDevices.types())
== outputDesc->devicesSupportEncodedFormats(sharedDevices.types()))) {
return false;
}
}
return true;
}
status_t AudioPolicyManager::getSpatializerOutput(const audio_config_base_t *mixerConfig,
const audio_attributes_t *attr,
audio_io_handle_t *output) {
*output = AUDIO_IO_HANDLE_NONE;
DeviceVector devices = mEngine->getOutputDevicesForAttributes(*attr, nullptr, false);
AudioDeviceTypeAddrVector devicesTypeAddress = devices.toTypeAddrVector();
audio_config_t *configPtr = nullptr;
audio_config_t config;
if (mixerConfig != nullptr) {
config = audio_config_initializer(mixerConfig);
configPtr = &config;
}
if (!canBeSpatializedInt(attr, configPtr, devicesTypeAddress)) {
ALOGV("%s provided attributes or mixer config cannot be spatialized", __func__);
return BAD_VALUE;
}
sp<IOProfile> profile =
getSpatializerOutputProfile(configPtr, devicesTypeAddress);
if (profile == nullptr) {
ALOGV("%s no suitable output profile for provided attributes or mixer config", __func__);
return BAD_VALUE;
}
std::vector<sp<SwAudioOutputDescriptor>> spatializerOutputs;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if (!desc->isDuplicated()
&& (desc->mFlags & AUDIO_OUTPUT_FLAG_SPATIALIZER) != 0) {
spatializerOutputs.push_back(desc);
ALOGV("%s adding opened spatializer Output %d", __func__, desc->mIoHandle);
}
}
mSpatializerOutput.clear();
bool outputsChanged = false;
for (const auto& desc : spatializerOutputs) {
if (desc->mProfile == profile
&& (configPtr == nullptr
|| configPtr->channel_mask == desc->mMixerChannelMask)) {
mSpatializerOutput = desc;
ALOGV("%s reusing current spatializer output %d", __func__, desc->mIoHandle);
} else {
ALOGV("%s closing spatializerOutput output %d to match channel mask %#x"
" and devices %s", __func__, desc->mIoHandle,
configPtr != nullptr ? configPtr->channel_mask : 0,
devices.toString().c_str());
closeOutput(desc->mIoHandle);
outputsChanged = true;
}
}
if (mSpatializerOutput == nullptr) {
sp<SwAudioOutputDescriptor> desc =
openOutputWithProfileAndDevice(profile, devices, mixerConfig);
if (desc != nullptr) {
mSpatializerOutput = desc;
outputsChanged = true;
}
}
checkVirtualizerClientRoutes();
if (outputsChanged) {
mPreviousOutputs = mOutputs;
mpClientInterface->onAudioPortListUpdate();
}
if (mSpatializerOutput == nullptr) {
ALOGV("%s could not open spatializer output with requested config", __func__);
return BAD_VALUE;
}
*output = mSpatializerOutput->mIoHandle;
ALOGV("%s returning new spatializer output %d", __func__, *output);
return OK;
}
status_t AudioPolicyManager::releaseSpatializerOutput(audio_io_handle_t output) {
if (mSpatializerOutput == nullptr) {
return INVALID_OPERATION;
}
if (mSpatializerOutput->mIoHandle != output) {
return BAD_VALUE;
}
if (!isOutputOnlyAvailableRouteToSomeDevice(mSpatializerOutput)) {
ALOGV("%s closing spatializer output %d", __func__, mSpatializerOutput->mIoHandle);
closeOutput(mSpatializerOutput->mIoHandle);
//from now on mSpatializerOutput is null
checkVirtualizerClientRoutes();
}
return NO_ERROR;
}
// ----------------------------------------------------------------------------
// AudioPolicyManager
// ----------------------------------------------------------------------------
uint32_t AudioPolicyManager::nextAudioPortGeneration()
{
return mAudioPortGeneration++;
}
AudioPolicyManager::AudioPolicyManager(const sp<const AudioPolicyConfig>& config,
EngineInstance&& engine,
AudioPolicyClientInterface *clientInterface)
:
mUidCached(AID_AUDIOSERVER), // no need to call getuid(), there's only one of us running.
mConfig(config),
mEngine(std::move(engine)),
mpClientInterface(clientInterface),
mLimitRingtoneVolume(false), mLastVoiceVolume(-1.0f),
mA2dpSuspended(false),
mAudioPortGeneration(1),
mBeaconMuteRefCount(0),
mBeaconPlayingRefCount(0),
mBeaconMuted(false),
mTtsOutputAvailable(false),
mMasterMono(false),
mMusicEffectOutput(AUDIO_IO_HANDLE_NONE)
{
}
status_t AudioPolicyManager::initialize() {
if (mEngine == nullptr) {
return NO_INIT;
}
mEngine->setObserver(this);
status_t status = mEngine->initCheck();
if (status != NO_ERROR) {
LOG_FATAL("Policy engine not initialized(err=%d)", status);
return status;
}
// The actual device selection cache will be updated when calling `updateDevicesAndOutputs`
// at the end of this function.
mEngine->initializeDeviceSelectionCache();
mCommunnicationStrategy = mEngine->getProductStrategyForAttributes(
mEngine->getAttributesForStreamType(AUDIO_STREAM_VOICE_CALL));
// after parsing the config, mConfig contain all known devices;
// open all output streams needed to access attached devices
onNewAudioModulesAvailableInt(nullptr /*newDevices*/);
// make sure default device is reachable
if (const auto defaultOutputDevice = mConfig->getDefaultOutputDevice();
defaultOutputDevice == nullptr ||
!mAvailableOutputDevices.contains(defaultOutputDevice)) {
ALOGE_IF(defaultOutputDevice != nullptr, "Default device %s is unreachable",
defaultOutputDevice->toString().c_str());
status = NO_INIT;
}
ALOGW_IF(mPrimaryOutput == nullptr, "The policy configuration does not declare a primary output");
// Silence ALOGV statements
property_set("log.tag." LOG_TAG, "D");
updateDevicesAndOutputs();
return status;
}
AudioPolicyManager::~AudioPolicyManager()
{
for (size_t i = 0; i < mOutputs.size(); i++) {
mOutputs.valueAt(i)->close();
}
for (size_t i = 0; i < mInputs.size(); i++) {
mInputs.valueAt(i)->close();
}
mAvailableOutputDevices.clear();
mAvailableInputDevices.clear();
mOutputs.clear();
mInputs.clear();
mHwModules.clear();
mManualSurroundFormats.clear();
mConfig.clear();
}
status_t AudioPolicyManager::initCheck()
{
return hasPrimaryOutput() ? NO_ERROR : NO_INIT;
}
// ---
void AudioPolicyManager::onNewAudioModulesAvailable()
{
DeviceVector newDevices;
onNewAudioModulesAvailableInt(&newDevices);
if (!newDevices.empty()) {
nextAudioPortGeneration();
mpClientInterface->onAudioPortListUpdate();
}
}
void AudioPolicyManager::onNewAudioModulesAvailableInt(DeviceVector *newDevices)
{
for (const auto& hwModule : mConfig->getHwModules()) {
if (std::find(mHwModules.begin(), mHwModules.end(), hwModule) != mHwModules.end()) {
continue;
}
if (hwModule->getHandle() == AUDIO_MODULE_HANDLE_NONE) {
if (audio_module_handle_t handle = mpClientInterface->loadHwModule(hwModule->getName());
handle != AUDIO_MODULE_HANDLE_NONE) {
hwModule->setHandle(handle);
} else {
ALOGW("could not load HW module %s", hwModule->getName());
continue;
}
}
mHwModules.push_back(hwModule);
// open all output streams needed to access attached devices.
// direct outputs are closed immediately after checking the availability of attached devices
// This also validates mAvailableOutputDevices list
for (const auto& outProfile : hwModule->getOutputProfiles()) {
if (!outProfile->canOpenNewIo()) {
ALOGE("Invalid Output profile max open count %u for profile %s",
outProfile->maxOpenCount, outProfile->getTagName().c_str());
continue;
}
if (!outProfile->hasSupportedDevices()) {
ALOGW("Output profile contains no device on module %s", hwModule->getName());
continue;
}
if ((outProfile->getFlags() & AUDIO_OUTPUT_FLAG_TTS) != 0 ||
(outProfile->getFlags() & AUDIO_OUTPUT_FLAG_ULTRASOUND) != 0) {
mTtsOutputAvailable = true;
}
const DeviceVector &supportedDevices = outProfile->getSupportedDevices();
DeviceVector availProfileDevices = supportedDevices.filter(mConfig->getOutputDevices());
sp<DeviceDescriptor> supportedDevice = 0;
if (supportedDevices.contains(mConfig->getDefaultOutputDevice())) {
supportedDevice = mConfig->getDefaultOutputDevice();
} else {
// choose first device present in profile's SupportedDevices also part of
// mAvailableOutputDevices.
if (availProfileDevices.isEmpty()) {
continue;
}
supportedDevice = availProfileDevices.itemAt(0);
}
if (!mConfig->getOutputDevices().contains(supportedDevice)) {
continue;
}
sp<SwAudioOutputDescriptor> outputDesc = new SwAudioOutputDescriptor(outProfile,
mpClientInterface);
audio_io_handle_t output = AUDIO_IO_HANDLE_NONE;
status_t status = outputDesc->open(nullptr /* halConfig */, nullptr /* mixerConfig */,
DeviceVector(supportedDevice),
AUDIO_STREAM_DEFAULT,
AUDIO_OUTPUT_FLAG_NONE, &output);
if (status != NO_ERROR) {
ALOGW("Cannot open output stream for devices %s on hw module %s",
supportedDevice->toString().c_str(), hwModule->getName());
continue;
}
for (const auto &device : availProfileDevices) {
// give a valid ID to an attached device once confirmed it is reachable
if (!device->isAttached()) {
device->attach(hwModule);
mAvailableOutputDevices.add(device);
device->setEncapsulationInfoFromHal(mpClientInterface);
if (newDevices) newDevices->add(device);
setEngineDeviceConnectionState(device, AUDIO_POLICY_DEVICE_STATE_AVAILABLE);
}
}
if (mPrimaryOutput == nullptr &&
outProfile->getFlags() & AUDIO_OUTPUT_FLAG_PRIMARY) {
mPrimaryOutput = outputDesc;
mPrimaryModuleHandle = mPrimaryOutput->getModuleHandle();
}
if ((outProfile->getFlags() & AUDIO_OUTPUT_FLAG_DIRECT) != 0) {
outputDesc->close();
} else {
addOutput(output, outputDesc);
setOutputDevices(__func__, outputDesc,
DeviceVector(supportedDevice),
true,
0,
NULL);
}
}
// open input streams needed to access attached devices to validate
// mAvailableInputDevices list
for (const auto& inProfile : hwModule->getInputProfiles()) {
if (!inProfile->canOpenNewIo()) {
ALOGE("Invalid Input profile max open count %u for profile %s",
inProfile->maxOpenCount, inProfile->getTagName().c_str());
continue;
}
if (!inProfile->hasSupportedDevices()) {
ALOGW("Input profile contains no device on module %s", hwModule->getName());
continue;
}
// chose first device present in profile's SupportedDevices also part of
// available input devices
const DeviceVector &supportedDevices = inProfile->getSupportedDevices();
DeviceVector availProfileDevices = supportedDevices.filter(mConfig->getInputDevices());
if (availProfileDevices.isEmpty()) {
ALOGV("%s: Input device list is empty! for profile %s",
__func__, inProfile->getTagName().c_str());
continue;
}
sp<AudioInputDescriptor> inputDesc =
new AudioInputDescriptor(inProfile, mpClientInterface);
audio_io_handle_t input = AUDIO_IO_HANDLE_NONE;
status_t status = inputDesc->open(nullptr,
availProfileDevices.itemAt(0),
AUDIO_SOURCE_MIC,
AUDIO_INPUT_FLAG_NONE,
&input);
if (status != NO_ERROR) {
ALOGW("Cannot open input stream for device %s on hw module %s",
availProfileDevices.toString().c_str(),
hwModule->getName());
continue;
}
for (const auto &device : availProfileDevices) {
// give a valid ID to an attached device once confirmed it is reachable
if (!device->isAttached()) {
device->attach(hwModule);
device->importAudioPortAndPickAudioProfile(inProfile, true);
mAvailableInputDevices.add(device);
if (newDevices) newDevices->add(device);
setEngineDeviceConnectionState(device, AUDIO_POLICY_DEVICE_STATE_AVAILABLE);
}
}
inputDesc->close();
}
}
// Check if spatializer outputs can be closed until used.
// mOutputs vector never contains duplicated outputs at this point.
std::vector<audio_io_handle_t> outputsClosed;
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
if ((desc->mFlags & AUDIO_OUTPUT_FLAG_SPATIALIZER) != 0
&& !isOutputOnlyAvailableRouteToSomeDevice(desc)) {
outputsClosed.push_back(desc->mIoHandle);
desc->close();
}
}
for (auto output : outputsClosed) {
removeOutput(output);
}
}
void AudioPolicyManager::addOutput(audio_io_handle_t output,
const sp<SwAudioOutputDescriptor>& outputDesc)
{
mOutputs.add(output, outputDesc);
applyStreamVolumes(outputDesc, DeviceTypeSet(), 0 /* delayMs */, true /* force */);
updateMono(output); // update mono status when adding to output list
selectOutputForMusicEffects();
nextAudioPortGeneration();
}
void AudioPolicyManager::removeOutput(audio_io_handle_t output)
{
if (mPrimaryOutput != 0 && mPrimaryOutput == mOutputs.valueFor(output)) {
ALOGV("%s: removing primary output", __func__);
mPrimaryOutput = nullptr;
}
mOutputs.removeItem(output);
selectOutputForMusicEffects();
}
void AudioPolicyManager::addInput(audio_io_handle_t input,
const sp<AudioInputDescriptor>& inputDesc)
{
mInputs.add(input, inputDesc);
nextAudioPortGeneration();
}
status_t AudioPolicyManager::checkOutputsForDevice(const sp<DeviceDescriptor>& device,
audio_policy_dev_state_t state,
SortedVector<audio_io_handle_t>& outputs)
{
audio_devices_t deviceType = device->type();
const String8 &address = String8(device->address().c_str());
sp<SwAudioOutputDescriptor> desc;
if (audio_device_is_digital(deviceType)) {
// erase all current sample rates, formats and channel masks
device->clearAudioProfiles();
}
if (state == AUDIO_POLICY_DEVICE_STATE_AVAILABLE) {
// first call getAudioPort to get the supported attributes from the HAL
struct audio_port_v7 port = {};
device->toAudioPort(&port);
status_t status = mpClientInterface->getAudioPort(&port);
if (status == NO_ERROR) {
device->importAudioPort(port);
}
// then list already open outputs that can be routed to this device
for (size_t i = 0; i < mOutputs.size(); i++) {
desc = mOutputs.valueAt(i);
if (!desc->isDuplicated() && desc->supportsDevice(device)
&& desc->devicesSupportEncodedFormats({deviceType})) {
ALOGV("checkOutputsForDevice(): adding opened output %d on device %s",
mOutputs.keyAt(i), device->toString().c_str());
outputs.add(mOutputs.keyAt(i));
}
}
// then look for output profiles that can be routed to this device
SortedVector< sp<IOProfile> > profiles;
for (const auto& hwModule : mHwModules) {
for (size_t j = 0; j < hwModule->getOutputProfiles().size(); j++) {
sp<IOProfile> profile = hwModule->getOutputProfiles()[j];
if (profile->supportsDevice(device)) {
profiles.add(profile);
ALOGV("checkOutputsForDevice(): adding profile %zu from module %s",
j, hwModule->getName());
}
}
}
ALOGV(" found %zu profiles, %zu outputs", profiles.size(), outputs.size());
if (profiles.isEmpty() && outputs.isEmpty()) {
ALOGW("checkOutputsForDevice(): No output available for device %04x", deviceType);
return BAD_VALUE;
}
// open outputs for matching profiles if needed. Direct outputs are also opened to
// query for dynamic parameters and will be closed later by setDeviceConnectionState()
for (ssize_t profile_index = 0; profile_index < (ssize_t)profiles.size(); profile_index++) {
sp<IOProfile> profile = profiles[profile_index];
// nothing to do if one output is already opened for this profile
size_t j;
for (j = 0; j < outputs.size(); j++) {
desc = mOutputs.valueFor(outputs.itemAt(j));
if (!desc->isDuplicated() && desc->mProfile == profile) {
// matching profile: save the sample rates, format and channel masks supported
// by the profile in our device descriptor
if (audio_device_is_digital(deviceType)) {
device->importAudioPortAndPickAudioProfile(profile);
}
break;
}
}
if (j != outputs.size()) {
continue;
}
if (!profile->canOpenNewIo()) {
ALOGW("Max Output number %u already opened for this profile %s",
profile->maxOpenCount, profile->getTagName().c_str());
continue;
}
ALOGV("opening output for device %08x with params %s profile %p name %s",
deviceType, address.c_str(), profile.get(), profile->getName().c_str());
desc = openOutputWithProfileAndDevice(profile, DeviceVector(device));
audio_io_handle_t output = desc == nullptr ? AUDIO_IO_HANDLE_NONE : desc->mIoHandle;
if (output == AUDIO_IO_HANDLE_NONE) {
ALOGW("checkOutputsForDevice() could not open output for device %x", deviceType);
profiles.removeAt(profile_index);
profile_index--;
} else {
outputs.add(output);
// Load digital format info only for digital devices
if (audio_device_is_digital(deviceType)) {
// TODO: when getAudioPort is ready, it may not be needed to import the audio
// port but just pick audio profile
device->importAudioPortAndPickAudioProfile(profile);
}
if (device_distinguishes_on_address(deviceType)) {
ALOGV("checkOutputsForDevice(): setOutputDevices %s",
device->toString().c_str());
setOutputDevices(__func__, desc, DeviceVector(device), true/*force*/,
0/*delay*/, NULL/*patch handle*/);
}
ALOGV("checkOutputsForDevice(): adding output %d", output);
}
}
if (profiles.isEmpty()) {
ALOGW("checkOutputsForDevice(): No output available for device %04x", deviceType);
return BAD_VALUE;
}
} else { // Disconnect
// check if one opened output is not needed any more after disconnecting one device
for (size_t i = 0; i < mOutputs.size(); i++) {
desc = mOutputs.valueAt(i);
if (!desc->isDuplicated()) {
// exact match on device
if (device_distinguishes_on_address(deviceType) && desc->supportsDevice(device)
&& desc->containsSingleDeviceSupportingEncodedFormats(device)) {
outputs.add(mOutputs.keyAt(i));
} else if (!mAvailableOutputDevices.containsAtLeastOne(desc->supportedDevices())) {
ALOGV("checkOutputsForDevice(): disconnecting adding output %d",
mOutputs.keyAt(i));
outputs.add(mOutputs.keyAt(i));
}
}
}
// Clear any profiles associated with the disconnected device.
for (const auto& hwModule : mHwModules) {
for (size_t j = 0; j < hwModule->getOutputProfiles().size(); j++) {
sp<IOProfile> profile = hwModule->getOutputProfiles()[j];
if (!profile->supportsDevice(device)) {
continue;
}
ALOGV("checkOutputsForDevice(): "
"clearing direct output profile %zu on module %s",
j, hwModule->getName());
profile->clearAudioProfiles();
if (!profile->hasDynamicAudioProfile()) {
continue;
}
// When a device is disconnected, if there is an IOProfile that contains dynamic
// profiles and supports the disconnected device, call getAudioPort to repopulate
// the capabilities of the devices that is supported by the IOProfile.
for (const auto& supportedDevice : profile->getSupportedDevices()) {
if (supportedDevice == device ||
!mAvailableOutputDevices.contains(supportedDevice)) {
continue;
}
struct audio_port_v7 port;
supportedDevice->toAudioPort(&port);
status_t status = mpClientInterface->getAudioPort(&port);
if (status == NO_ERROR) {
supportedDevice->importAudioPort(port);
}
}
}
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::checkInputsForDevice(const sp<DeviceDescriptor>& device,
audio_policy_dev_state_t state)
{
sp<AudioInputDescriptor> desc;
if (audio_device_is_digital(device->type())) {
// erase all current sample rates, formats and channel masks
device->clearAudioProfiles();
}
if (state == AUDIO_POLICY_DEVICE_STATE_AVAILABLE) {
// first call getAudioPort to get the supported attributes from the HAL
struct audio_port_v7 port = {};
device->toAudioPort(&port);
status_t status = mpClientInterface->getAudioPort(&port);
if (status == NO_ERROR) {
device->importAudioPort(port);
}
// look for input profiles that can be routed to this device
SortedVector< sp<IOProfile> > profiles;
for (const auto& hwModule : mHwModules) {
for (size_t profile_index = 0;
profile_index < hwModule->getInputProfiles().size();
profile_index++) {
sp<IOProfile> profile = hwModule->getInputProfiles()[profile_index];
if (profile->supportsDevice(device)) {
profiles.add(profile);
ALOGV("checkInputsForDevice(): adding profile %zu from module %s",
profile_index, hwModule->getName());
}
}
}
if (profiles.isEmpty()) {
ALOGW("%s: No input profile available for device %s",
__func__, device->toString().c_str());
return BAD_VALUE;
}
// open inputs for matching profiles if needed. Direct inputs are also opened to
// query for dynamic parameters and will be closed later by setDeviceConnectionState()
for (ssize_t profile_index = 0; profile_index < (ssize_t)profiles.size(); profile_index++) {
sp<IOProfile> profile = profiles[profile_index];
// nothing to do if one input is already opened for this profile
size_t input_index;
for (input_index = 0; input_index < mInputs.size(); input_index++) {
desc = mInputs.valueAt(input_index);
if (desc->mProfile == profile) {
if (audio_device_is_digital(device->type())) {
device->importAudioPortAndPickAudioProfile(profile);
}
break;
}
}
if (input_index != mInputs.size()) {
continue;
}
if (!profile->canOpenNewIo()) {
ALOGW("Max Input number %u already opened for this profile %s",
profile->maxOpenCount, profile->getTagName().c_str());
continue;
}
desc = new AudioInputDescriptor(profile, mpClientInterface);
audio_io_handle_t input = AUDIO_IO_HANDLE_NONE;
status = desc->open(nullptr, device, AUDIO_SOURCE_MIC, AUDIO_INPUT_FLAG_NONE, &input);
if (status == NO_ERROR) {
const String8& address = String8(device->address().c_str());
if (!address.empty()) {
char *param = audio_device_address_to_parameter(device->type(), address);
mpClientInterface->setParameters(input, String8(param));
free(param);
}
updateAudioProfiles(device, input, profile);
if (!profile->hasValidAudioProfile()) {
ALOGW("checkInputsForDevice() direct input missing param");
desc->close();
input = AUDIO_IO_HANDLE_NONE;
}
if (input != AUDIO_IO_HANDLE_NONE) {
addInput(input, desc);
}
} // endif input != 0
if (input == AUDIO_IO_HANDLE_NONE) {
ALOGW("%s could not open input for device %s", __func__,
device->toString().c_str());
profiles.removeAt(profile_index);
profile_index--;
} else {
if (audio_device_is_digital(device->type())) {
device->importAudioPortAndPickAudioProfile(profile);
}
ALOGV("checkInputsForDevice(): adding input %d", input);
}
} // end scan profiles
if (profiles.isEmpty()) {
ALOGW("%s: No input available for device %s", __func__, device->toString().c_str());
return BAD_VALUE;
}
} else {
// Disconnect
// Clear any profiles associated with the disconnected device.
for (const auto& hwModule : mHwModules) {
for (size_t profile_index = 0;
profile_index < hwModule->getInputProfiles().size();
profile_index++) {
sp<IOProfile> profile = hwModule->getInputProfiles()[profile_index];
if (profile->supportsDevice(device)) {
ALOGV("checkInputsForDevice(): clearing direct input profile %zu on module %s",
profile_index, hwModule->getName());
profile->clearAudioProfiles();
}
}
}
} // end disconnect
return NO_ERROR;
}
void AudioPolicyManager::closeOutput(audio_io_handle_t output)
{
ALOGV("closeOutput(%d)", output);
sp<SwAudioOutputDescriptor> closingOutput = mOutputs.valueFor(output);
if (closingOutput == NULL) {
ALOGW("closeOutput() unknown output %d", output);
return;
}
const bool closingOutputWasActive = closingOutput->isActive();
mPolicyMixes.closeOutput(closingOutput, mOutputs);
// look for duplicated outputs connected to the output being removed.
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> dupOutput = mOutputs.valueAt(i);
if (dupOutput->isDuplicated() &&
(dupOutput->mOutput1 == closingOutput || dupOutput->mOutput2 == closingOutput)) {
sp<SwAudioOutputDescriptor> remainingOutput =
dupOutput->mOutput1 == closingOutput ? dupOutput->mOutput2 : dupOutput->mOutput1;
// As all active tracks on duplicated output will be deleted,
// and as they were also referenced on the other output, the reference
// count for their stream type must be adjusted accordingly on
// the other output.
const bool wasActive = remainingOutput->isActive();
// Note: no-op on the closing output where all clients has already been set inactive
dupOutput->setAllClientsInactive();
// stop() will be a no op if the output is still active but is needed in case all
// active streams refcounts where cleared above
if (wasActive) {
remainingOutput->stop();
}
audio_io_handle_t duplicatedOutput = mOutputs.keyAt(i);
ALOGV("closeOutput() closing also duplicated output %d", duplicatedOutput);
mpClientInterface->closeOutput(duplicatedOutput);
removeOutput(duplicatedOutput);
}
}
nextAudioPortGeneration();
ssize_t index = mAudioPatches.indexOfKey(closingOutput->getPatchHandle());
if (index >= 0) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
(void) /*status_t status*/ mpClientInterface->releaseAudioPatch(
patchDesc->getAfHandle(), 0);
mAudioPatches.removeItemsAt(index);
mpClientInterface->onAudioPatchListUpdate();
}
if (closingOutputWasActive) {
closingOutput->stop();
}
closingOutput->close();
if ((closingOutput->getFlags().output & AUDIO_OUTPUT_FLAG_BIT_PERFECT)
== AUDIO_OUTPUT_FLAG_BIT_PERFECT) {
for (const auto device : closingOutput->devices()) {
device->setPreferredConfig(nullptr);
}
}
removeOutput(output);
mPreviousOutputs = mOutputs;
if (closingOutput == mSpatializerOutput) {
mSpatializerOutput.clear();
}
// MSD patches may have been released to support a non-MSD direct output. Reset MSD patch if
// no direct outputs are open.
if (!getMsdAudioOutDevices().isEmpty()) {
bool directOutputOpen = false;
for (size_t i = 0; i < mOutputs.size(); i++) {
if (mOutputs[i]->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) {
directOutputOpen = true;
break;
}
}
if (!directOutputOpen) {
ALOGV("no direct outputs open, reset MSD patches");
// TODO: The MSD patches to be established here may differ to current MSD patches due to
// how output devices for patching are resolved. Avoid by caching and reusing the
// arguments to mEngine->getOutputDevicesForAttributes() when resolving which output
// devices to patch to. This may be complicated by the fact that devices may become
// unavailable.
setMsdOutputPatches();
}
}
}
void AudioPolicyManager::closeInput(audio_io_handle_t input)
{
ALOGV("closeInput(%d)", input);
sp<AudioInputDescriptor> inputDesc = mInputs.valueFor(input);
if (inputDesc == NULL) {
ALOGW("closeInput() unknown input %d", input);
return;
}
nextAudioPortGeneration();
sp<DeviceDescriptor> device = inputDesc->getDevice();
ssize_t index = mAudioPatches.indexOfKey(inputDesc->getPatchHandle());
if (index >= 0) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
(void) /*status_t status*/ mpClientInterface->releaseAudioPatch(
patchDesc->getAfHandle(), 0);
mAudioPatches.removeItemsAt(index);
mpClientInterface->onAudioPatchListUpdate();
}
mEffects.putOrphanEffectsForIo(input);
inputDesc->close();
mInputs.removeItem(input);
DeviceVector primaryInputDevices = availablePrimaryModuleInputDevices();
if (primaryInputDevices.contains(device) &&
mInputs.activeInputsCountOnDevices(primaryInputDevices) == 0) {
mpClientInterface->setSoundTriggerCaptureState(false);
}
}
SortedVector<audio_io_handle_t> AudioPolicyManager::getOutputsForDevices(
const DeviceVector &devices,
const SwAudioOutputCollection& openOutputs)
{
SortedVector<audio_io_handle_t> outputs;
ALOGVV("%s() devices %s", __func__, devices.toString().c_str());
for (size_t i = 0; i < openOutputs.size(); i++) {
ALOGVV("output %zu isDuplicated=%d device=%s",
i, openOutputs.valueAt(i)->isDuplicated(),
openOutputs.valueAt(i)->supportedDevices().toString().c_str());
if (openOutputs.valueAt(i)->supportsAllDevices(devices)
&& openOutputs.valueAt(i)->devicesSupportEncodedFormats(devices.types())) {
ALOGVV("%s() found output %d", __func__, openOutputs.keyAt(i));
outputs.add(openOutputs.keyAt(i));
}
}
return outputs;
}
void AudioPolicyManager::checkForDeviceAndOutputChanges(std::function<bool()> onOutputsChecked)
{
// checkA2dpSuspend must run before checkOutputForAllStrategies so that A2DP
// output is suspended before any tracks are moved to it
checkA2dpSuspend();
checkOutputForAllStrategies();
checkSecondaryOutputs();
if (onOutputsChecked != nullptr && onOutputsChecked()) checkA2dpSuspend();
updateDevicesAndOutputs();
if (mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD) != 0) {
// TODO: The MSD patches to be established here may differ to current MSD patches due to how
// output devices for patching are resolved. Nevertheless, AudioTracks affected by device
// configuration changes will ultimately be rerouted correctly. We can still avoid
// unnecessary rerouting by caching and reusing the arguments to
// mEngine->getOutputDevicesForAttributes() when resolving which output devices to patch to.
// This may be complicated by the fact that devices may become unavailable.
setMsdOutputPatches();
}
// an event that changed routing likely occurred, inform upper layers
mpClientInterface->onRoutingUpdated();
}
bool AudioPolicyManager::followsSameRouting(const audio_attributes_t &lAttr,
const audio_attributes_t &rAttr) const
{
return mEngine->getProductStrategyForAttributes(lAttr) ==
mEngine->getProductStrategyForAttributes(rAttr);
}
void AudioPolicyManager::checkAudioSourceForAttributes(const audio_attributes_t &attr)
{
for (size_t i = 0; i < mAudioSources.size(); i++) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
if (sourceDesc != nullptr && followsSameRouting(attr, sourceDesc->attributes())
&& sourceDesc->getPatchHandle() == AUDIO_PATCH_HANDLE_NONE
&& !isCallRxAudioSource(sourceDesc) && !sourceDesc->isInternal()) {
connectAudioSource(sourceDesc);
}
}
}
void AudioPolicyManager::clearAudioSourcesForOutput(audio_io_handle_t output)
{
for (size_t i = 0; i < mAudioSources.size(); i++) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
if (sourceDesc != nullptr && sourceDesc->swOutput().promote() != nullptr
&& sourceDesc->swOutput().promote()->mIoHandle == output) {
disconnectAudioSource(sourceDesc);
}
}
}
void AudioPolicyManager::checkOutputForAttributes(const audio_attributes_t &attr)
{
auto psId = mEngine->getProductStrategyForAttributes(attr);
DeviceVector oldDevices = mEngine->getOutputDevicesForAttributes(attr, 0, true /*fromCache*/);
DeviceVector newDevices = mEngine->getOutputDevicesForAttributes(attr, 0, false /*fromCache*/);
SortedVector<audio_io_handle_t> srcOutputs = getOutputsForDevices(oldDevices, mPreviousOutputs);
SortedVector<audio_io_handle_t> dstOutputs = getOutputsForDevices(newDevices, mOutputs);
uint32_t maxLatency = 0;
bool unneededUsePrimaryOutputFromPolicyMixes = false;
std::vector<sp<SwAudioOutputDescriptor>> invalidatedOutputs;
// take into account dynamic audio policies related changes: if a client is now associated
// to a different policy mix than at creation time, invalidate corresponding stream
for (size_t i = 0; i < mPreviousOutputs.size(); i++) {
const sp<SwAudioOutputDescriptor>& desc = mPreviousOutputs.valueAt(i);
if (desc->isDuplicated()) {
continue;
}
for (const sp<TrackClientDescriptor>& client : desc->getClientIterable()) {
if (mEngine->getProductStrategyForAttributes(client->attributes()) != psId) {
continue;
}
sp<AudioPolicyMix> primaryMix;
status_t status = mPolicyMixes.getOutputForAttr(client->attributes(), client->config(),
client->uid(), client->session(), client->flags(), mAvailableOutputDevices,
nullptr /* requestedDevice */, primaryMix, nullptr /* secondaryMixes */,
unneededUsePrimaryOutputFromPolicyMixes);
if (status != OK) {
continue;
}
if (client->getPrimaryMix() != primaryMix || client->hasLostPrimaryMix()) {
if (desc->isStrategyActive(psId) && maxLatency < desc->latency()) {
maxLatency = desc->latency();
}
invalidatedOutputs.push_back(desc);
}
}
}
if (srcOutputs != dstOutputs || !invalidatedOutputs.empty()) {
// get maximum latency of all source outputs to determine the minimum mute time guaranteeing
// audio from invalidated tracks will be rendered when unmuting
for (audio_io_handle_t srcOut : srcOutputs) {
sp<SwAudioOutputDescriptor> desc = mPreviousOutputs.valueFor(srcOut);
if (desc == nullptr) continue;
if (desc->isStrategyActive(psId) && maxLatency < desc->latency()) {
maxLatency = desc->latency();
}
bool invalidate = false;
for (auto client : desc->clientsList(false /*activeOnly*/)) {
if (desc->isDuplicated() || !desc->mProfile->isDirectOutput()) {
// a client on a non direct outputs has necessarily a linear PCM format
// so we can call selectOutput() safely
const audio_io_handle_t newOutput = selectOutput(dstOutputs,
client->flags(),
client->config().format,
client->config().channel_mask,
client->config().sample_rate,
client->session());
if (newOutput != srcOut) {
invalidate = true;
break;
}
} else {
sp<IOProfile> profile = getProfileForOutput(newDevices,
client->config().sample_rate,
client->config().format,
client->config().channel_mask,
client->flags(),
true /* directOnly */);
if (profile != desc->mProfile) {
invalidate = true;
break;
}
}
}
// mute strategy while moving tracks from one output to another
if (invalidate) {
invalidatedOutputs.push_back(desc);
if (desc->isStrategyActive(psId)) {
setStrategyMute(psId, true, desc);
setStrategyMute(psId, false, desc, maxLatency * LATENCY_MUTE_FACTOR,
newDevices.types());
}
}
sp<SourceClientDescriptor> source = getSourceForAttributesOnOutput(srcOut, attr);
if (source != nullptr && !isCallRxAudioSource(source) && !source->isInternal()) {
connectAudioSource(source);
}
}
ALOGV_IF(!(srcOutputs.isEmpty() || dstOutputs.isEmpty()),
"%s: strategy %d, moving from output %s to output %s", __func__, psId,
std::to_string(srcOutputs[0]).c_str(),
std::to_string(dstOutputs[0]).c_str());
// Move effects associated to this stream from previous output to new output
if (followsSameRouting(attr, attributes_initializer(AUDIO_USAGE_MEDIA))) {
selectOutputForMusicEffects();
}
// Move tracks associated to this stream (and linked) from previous output to new output
if (!invalidatedOutputs.empty()) {
invalidateStreams(mEngine->getStreamTypesForProductStrategy(psId));
for (sp<SwAudioOutputDescriptor> desc : invalidatedOutputs) {
desc->setTracksInvalidatedStatusByStrategy(psId);
}
}
}
}
void AudioPolicyManager::checkOutputForAllStrategies()
{
for (const auto &strategy : mEngine->getOrderedProductStrategies()) {
auto attributes = mEngine->getAllAttributesForProductStrategy(strategy).front();
checkOutputForAttributes(attributes);
checkAudioSourceForAttributes(attributes);
}
}
void AudioPolicyManager::checkSecondaryOutputs() {
PortHandleVector clientsToInvalidate;
TrackSecondaryOutputsMap trackSecondaryOutputs;
bool unneededUsePrimaryOutputFromPolicyMixes = false;
for (size_t i = 0; i < mOutputs.size(); i++) {
const sp<SwAudioOutputDescriptor>& outputDescriptor = mOutputs[i];
for (const sp<TrackClientDescriptor>& client : outputDescriptor->getClientIterable()) {
sp<AudioPolicyMix> primaryMix;
std::vector<sp<AudioPolicyMix>> secondaryMixes;
status_t status = mPolicyMixes.getOutputForAttr(client->attributes(), client->config(),
client->uid(), client->session(), client->flags(), mAvailableOutputDevices,
nullptr /* requestedDevice */, primaryMix, &secondaryMixes,
unneededUsePrimaryOutputFromPolicyMixes);
std::vector<sp<SwAudioOutputDescriptor>> secondaryDescs;
for (auto &secondaryMix : secondaryMixes) {
sp<SwAudioOutputDescriptor> outputDesc = secondaryMix->getOutput();
if (outputDesc != nullptr &&
outputDesc->mIoHandle != AUDIO_IO_HANDLE_NONE) {
secondaryDescs.push_back(outputDesc);
}
}
if (status != OK &&
(client->flags() & AUDIO_OUTPUT_FLAG_MMAP_NOIRQ) == AUDIO_OUTPUT_FLAG_NONE) {
// When it failed to query secondary output, only invalidate the client that is not
// MMAP. The reason is that MMAP stream will not support secondary output.
clientsToInvalidate.push_back(client->portId());
} else if (!std::equal(
client->getSecondaryOutputs().begin(),
client->getSecondaryOutputs().end(),
secondaryDescs.begin(), secondaryDescs.end())) {
if (!audio_is_linear_pcm(client->config().format)) {
// If the format is not PCM, the tracks should be invalidated to get correct
// behavior when the secondary output is changed.
clientsToInvalidate.push_back(client->portId());
} else {
std::vector<wp<SwAudioOutputDescriptor>> weakSecondaryDescs;
std::vector<audio_io_handle_t> secondaryOutputIds;
for (const auto &secondaryDesc: secondaryDescs) {
secondaryOutputIds.push_back(secondaryDesc->mIoHandle);
weakSecondaryDescs.push_back(secondaryDesc);
}
trackSecondaryOutputs.emplace(client->portId(), secondaryOutputIds);
client->setSecondaryOutputs(std::move(weakSecondaryDescs));
}
}
}
}
if (!trackSecondaryOutputs.empty()) {
mpClientInterface->updateSecondaryOutputs(trackSecondaryOutputs);
}
if (!clientsToInvalidate.empty()) {
ALOGD("%s Invalidate clients due to fail getting output for attr", __func__);
mpClientInterface->invalidateTracks(clientsToInvalidate);
}
}
bool AudioPolicyManager::isScoRequestedForComm() const {
AudioDeviceTypeAddrVector devices;
mEngine->getDevicesForRoleAndStrategy(mCommunnicationStrategy, DEVICE_ROLE_PREFERRED, devices);
for (const auto &device : devices) {
if (audio_is_bluetooth_out_sco_device(device.mType)) {
return true;
}
}
return false;
}
bool AudioPolicyManager::isHearingAidUsedForComm() const {
DeviceVector devices = mEngine->getOutputDevicesForStream(AUDIO_STREAM_VOICE_CALL,
true /*fromCache*/);
for (const auto &device : devices) {
if (device->type() == AUDIO_DEVICE_OUT_HEARING_AID) {
return true;
}
}
return false;
}
void AudioPolicyManager::checkA2dpSuspend()
{
audio_io_handle_t a2dpOutput = mOutputs.getA2dpOutput();
if (a2dpOutput == 0 || mOutputs.isA2dpOffloadedOnPrimary()) {
mA2dpSuspended = false;
return;
}
bool isScoConnected =
(mAvailableInputDevices.types().count(AUDIO_DEVICE_IN_BLUETOOTH_SCO_HEADSET) != 0 ||
!Intersection(mAvailableOutputDevices.types(), getAudioDeviceOutAllScoSet()).empty());
bool isScoRequested = isScoRequestedForComm();
// if suspended, restore A2DP output if:
// ((SCO device is NOT connected) ||
// ((SCO is not requested) &&
// (phone state is NOT in call) && (phone state is NOT ringing)))
//
// if not suspended, suspend A2DP output if:
// (SCO device is connected) &&
// ((SCO is requested) ||
// ((phone state is in call) || (phone state is ringing)))
//
if (mA2dpSuspended) {
if (!isScoConnected ||
(!isScoRequested &&
(mEngine->getPhoneState() != AUDIO_MODE_IN_CALL) &&
(mEngine->getPhoneState() != AUDIO_MODE_RINGTONE))) {
mpClientInterface->restoreOutput(a2dpOutput);
mA2dpSuspended = false;
}
} else {
if (isScoConnected &&
(isScoRequested ||
(mEngine->getPhoneState() == AUDIO_MODE_IN_CALL) ||
(mEngine->getPhoneState() == AUDIO_MODE_RINGTONE))) {
mpClientInterface->suspendOutput(a2dpOutput);
mA2dpSuspended = true;
}
}
}
DeviceVector AudioPolicyManager::getNewOutputDevices(const sp<SwAudioOutputDescriptor>& outputDesc,
bool fromCache)
{
if (outputDesc == nullptr) {
return DeviceVector{};
}
ssize_t index = mAudioPatches.indexOfKey(outputDesc->getPatchHandle());
if (index >= 0) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
if (patchDesc->getUid() != mUidCached) {
ALOGV("%s device %s forced by patch %d", __func__,
outputDesc->devices().toString().c_str(), outputDesc->getPatchHandle());
return outputDesc->devices();
}
}
// Do not retrieve engine device for outputs through MSD
// TODO: support explicit routing requests by resetting MSD patch to engine device.
if (outputDesc->devices() == getMsdAudioOutDevices()) {
return outputDesc->devices();
}
// Honor explicit routing requests only if no client using default routing is active on this
// input: a specific app can not force routing for other apps by setting a preferred device.
bool active; // unused
sp<DeviceDescriptor> device =
findPreferredDevice(outputDesc, PRODUCT_STRATEGY_NONE, active, mAvailableOutputDevices);
if (device != nullptr) {
return DeviceVector(device);
}
// Legacy Engine cannot take care of bus devices and mix, so we need to handle the conflict
// of setForceUse / Default Bus device here
device = mPolicyMixes.getDeviceAndMixForOutput(outputDesc, mAvailableOutputDevices);
if (device != nullptr) {
return DeviceVector(device);
}
DeviceVector devices;
for (const auto &productStrategy : mEngine->getOrderedProductStrategies()) {
StreamTypeVector streams = mEngine->getStreamTypesForProductStrategy(productStrategy);
auto attr = mEngine->getAllAttributesForProductStrategy(productStrategy).front();
auto hasStreamActive = [&](auto stream) {
return hasStream(streams, stream) && isStreamActive(stream, 0);
};
auto doGetOutputDevicesForVoice = [&]() {
return hasVoiceStream(streams) && (outputDesc == mPrimaryOutput ||
outputDesc->isActive(toVolumeSource(AUDIO_STREAM_VOICE_CALL, false))) &&
(isInCall() ||
mOutputs.isStrategyActiveOnSameModule(productStrategy, outputDesc)) &&
!isStreamActive(AUDIO_STREAM_ENFORCED_AUDIBLE, 0);
};
// With low-latency playing on speaker, music on WFD, when the first low-latency
// output is stopped, getNewOutputDevices checks for a product strategy
// from the list, as STRATEGY_SONIFICATION comes prior to STRATEGY_MEDIA.
// If an ALARM or ENFORCED_AUDIBLE stream is supported by the product strategy,
// devices are returned for STRATEGY_SONIFICATION without checking whether the
// stream is associated to the output descriptor.
if (doGetOutputDevicesForVoice() || outputDesc->isStrategyActive(productStrategy) ||
((hasStreamActive(AUDIO_STREAM_ALARM) ||
hasStreamActive(AUDIO_STREAM_ENFORCED_AUDIBLE)) &&
mOutputs.isStrategyActiveOnSameModule(productStrategy, outputDesc))) {
// Retrieval of devices for voice DL is done on primary output profile, cannot
// check the route (would force modifying configuration file for this profile)
devices = mEngine->getOutputDevicesForAttributes(attr, nullptr, fromCache);
break;
}
}
ALOGV("%s selected devices %s", __func__, devices.toString().c_str());
return devices;
}
sp<DeviceDescriptor> AudioPolicyManager::getNewInputDevice(
const sp<AudioInputDescriptor>& inputDesc)
{
sp<DeviceDescriptor> device;
ssize_t index = mAudioPatches.indexOfKey(inputDesc->getPatchHandle());
if (index >= 0) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
if (patchDesc->getUid() != mUidCached) {
ALOGV("getNewInputDevice() device %s forced by patch %d",
inputDesc->getDevice()->toString().c_str(), inputDesc->getPatchHandle());
return inputDesc->getDevice();
}
}
// Honor explicit routing requests only if no client using default routing is active on this
// input: a specific app can not force routing for other apps by setting a preferred device.
bool active;
device = findPreferredDevice(inputDesc, AUDIO_SOURCE_DEFAULT, active, mAvailableInputDevices);
if (device != nullptr) {
return device;
}
// If we are not in call and no client is active on this input, this methods returns
// a null sp<>, causing the patch on the input stream to be released.
audio_attributes_t attributes;
uid_t uid;
audio_session_t session;
sp<RecordClientDescriptor> topClient = inputDesc->getHighestPriorityClient();
if (topClient != nullptr) {
attributes = topClient->attributes();
uid = topClient->uid();
session = topClient->session();
} else {
attributes = { .source = AUDIO_SOURCE_DEFAULT };
uid = 0;
session = AUDIO_SESSION_NONE;
}
if (attributes.source == AUDIO_SOURCE_DEFAULT && isInCall()) {
attributes.source = AUDIO_SOURCE_VOICE_COMMUNICATION;
}
if (attributes.source != AUDIO_SOURCE_DEFAULT) {
device = mEngine->getInputDeviceForAttributes(attributes, uid, session);
}
return device;
}
bool AudioPolicyManager::streamsMatchForvolume(audio_stream_type_t stream1,
audio_stream_type_t stream2) {
return (stream1 == stream2);
}
status_t AudioPolicyManager::getDevicesForAttributes(
const audio_attributes_t &attr, AudioDeviceTypeAddrVector *devices, bool forVolume) {
if (devices == nullptr) {
return BAD_VALUE;
}
DeviceVector curDevices;
if (status_t status = getDevicesForAttributes(attr, curDevices, forVolume); status != OK) {
return status;
}
for (const auto& device : curDevices) {
devices->push_back(device->getDeviceTypeAddr());
}
return NO_ERROR;
}
void AudioPolicyManager::handleNotificationRoutingForStream(audio_stream_type_t stream) {
switch(stream) {
case AUDIO_STREAM_MUSIC:
checkOutputForAttributes(attributes_initializer(AUDIO_USAGE_NOTIFICATION));
updateDevicesAndOutputs();
break;
default:
break;
}
}
uint32_t AudioPolicyManager::handleEventForBeacon(int event) {
// skip beacon mute management if a dedicated TTS output is available
if (mTtsOutputAvailable) {
return 0;
}
switch(event) {
case STARTING_OUTPUT:
mBeaconMuteRefCount++;
break;
case STOPPING_OUTPUT:
if (mBeaconMuteRefCount > 0) {
mBeaconMuteRefCount--;
}
break;
case STARTING_BEACON:
mBeaconPlayingRefCount++;
break;
case STOPPING_BEACON:
if (mBeaconPlayingRefCount > 0) {
mBeaconPlayingRefCount--;
}
break;
}
if (mBeaconMuteRefCount > 0) {
// any playback causes beacon to be muted
return setBeaconMute(true);
} else {
// no other playback: unmute when beacon starts playing, mute when it stops
return setBeaconMute(mBeaconPlayingRefCount == 0);
}
}
uint32_t AudioPolicyManager::setBeaconMute(bool mute) {
ALOGV("setBeaconMute(%d) mBeaconMuteRefCount=%d mBeaconPlayingRefCount=%d",
mute, mBeaconMuteRefCount, mBeaconPlayingRefCount);
// keep track of muted state to avoid repeating mute/unmute operations
if (mBeaconMuted != mute) {
// mute/unmute AUDIO_STREAM_TTS on all outputs
ALOGV("\t muting %d", mute);
uint32_t maxLatency = 0;
auto ttsVolumeSource = toVolumeSource(AUDIO_STREAM_TTS, false);
if (ttsVolumeSource == VOLUME_SOURCE_NONE) {
ALOGV("\t no tts volume source available");
return 0;
}
for (size_t i = 0; i < mOutputs.size(); i++) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueAt(i);
setVolumeSourceMute(ttsVolumeSource, mute/*on*/, desc, 0 /*delay*/, DeviceTypeSet());
const uint32_t latency = desc->latency() * 2;
if (desc->isActive(latency * 2) && latency > maxLatency) {
maxLatency = latency;
}
}
mBeaconMuted = mute;
return maxLatency;
}
return 0;
}
void AudioPolicyManager::updateDevicesAndOutputs()
{
mEngine->updateDeviceSelectionCache();
mPreviousOutputs = mOutputs;
}
uint32_t AudioPolicyManager::checkDeviceMuteStrategies(const sp<AudioOutputDescriptor>& outputDesc,
const DeviceVector &prevDevices,
uint32_t delayMs)
{
// mute/unmute strategies using an incompatible device combination
// if muting, wait for the audio in pcm buffer to be drained before proceeding
// if unmuting, unmute only after the specified delay
if (outputDesc->isDuplicated()) {
return 0;
}
uint32_t muteWaitMs = 0;
DeviceVector devices = outputDesc->devices();
bool shouldMute = outputDesc->isActive() && (devices.size() >= 2);
auto productStrategies = mEngine->getOrderedProductStrategies();
for (const auto &productStrategy : productStrategies) {
auto attributes = mEngine->getAllAttributesForProductStrategy(productStrategy).front();
DeviceVector curDevices =
mEngine->getOutputDevicesForAttributes(attributes, nullptr, false/*fromCache*/);
curDevices = curDevices.filter(outputDesc->supportedDevices());
bool mute = shouldMute && curDevices.containsAtLeastOne(devices) && curDevices != devices;
bool doMute = false;
if (mute && !outputDesc->isStrategyMutedByDevice(productStrategy)) {
doMute = true;
outputDesc->setStrategyMutedByDevice(productStrategy, true);
} else if (!mute && outputDesc->isStrategyMutedByDevice(productStrategy)) {
doMute = true;
outputDesc->setStrategyMutedByDevice(productStrategy, false);
}
if (doMute) {
for (size_t j = 0; j < mOutputs.size(); j++) {
sp<AudioOutputDescriptor> desc = mOutputs.valueAt(j);
// skip output if it does not share any device with current output
if (!desc->supportedDevices().containsAtLeastOne(outputDesc->supportedDevices())) {
continue;
}
ALOGVV("%s() output %s %s (curDevice %s)", __func__, desc->info().c_str(),
mute ? "muting" : "unmuting", curDevices.toString().c_str());
setStrategyMute(productStrategy, mute, desc, mute ? 0 : delayMs);
if (desc->isStrategyActive(productStrategy)) {
if (mute) {
// FIXME: should not need to double latency if volume could be applied
// immediately by the audioflinger mixer. We must account for the delay
// between now and the next time the audioflinger thread for this output
// will process a buffer (which corresponds to one buffer size,
// usually 1/2 or 1/4 of the latency).
if (muteWaitMs < desc->latency() * 2) {
muteWaitMs = desc->latency() * 2;
}
}
}
}
}
}
// temporary mute output if device selection changes to avoid volume bursts due to
// different per device volumes
if (outputDesc->isActive() && (devices != prevDevices)) {
uint32_t tempMuteWaitMs = outputDesc->latency() * 2;
if (muteWaitMs < tempMuteWaitMs) {
muteWaitMs = tempMuteWaitMs;
}
// If recommended duration is defined, replace temporary mute duration to avoid
// truncated notifications at beginning, which depends on duration of changing path in HAL.
// Otherwise, temporary mute duration is conservatively set to 4 times the reported latency.
uint32_t tempRecommendedMuteDuration = outputDesc->getRecommendedMuteDurationMs();
uint32_t tempMuteDurationMs = tempRecommendedMuteDuration > 0 ?
tempRecommendedMuteDuration : outputDesc->latency() * 4;
for (const auto &activeVs : outputDesc->getActiveVolumeSources()) {
// make sure that we do not start the temporary mute period too early in case of
// delayed device change
setVolumeSourceMute(activeVs, true, outputDesc, delayMs);
setVolumeSourceMute(activeVs, false, outputDesc, delayMs + tempMuteDurationMs,
devices.types());
}
}
// wait for the PCM output buffers to empty before proceeding with the rest of the command
if (muteWaitMs > delayMs) {
muteWaitMs -= delayMs;
usleep(muteWaitMs * 1000);
return muteWaitMs;
}
return 0;
}
uint32_t AudioPolicyManager::setOutputDevices(const char *caller,
const sp<SwAudioOutputDescriptor>& outputDesc,
const DeviceVector &devices,
bool force,
int delayMs,
audio_patch_handle_t *patchHandle,
bool requiresMuteCheck, bool requiresVolumeCheck,
bool skipMuteDelay)
{
// TODO(b/262404095): Consider if the output need to be reopened.
std::string logPrefix = std::string("caller ") + caller + outputDesc->info();
ALOGV("%s %s device %s delayMs %d", __func__, logPrefix.c_str(),
devices.toString().c_str(), delayMs);
uint32_t muteWaitMs;
if (outputDesc->isDuplicated()) {
muteWaitMs = setOutputDevices(__func__, outputDesc->subOutput1(), devices, force, delayMs,
nullptr /* patchHandle */, requiresMuteCheck, skipMuteDelay);
muteWaitMs += setOutputDevices(__func__, outputDesc->subOutput2(), devices, force, delayMs,
nullptr /* patchHandle */, requiresMuteCheck, skipMuteDelay);
return muteWaitMs;
}
// filter devices according to output selected
DeviceVector filteredDevices = outputDesc->filterSupportedDevices(devices);
DeviceVector prevDevices = outputDesc->devices();
DeviceVector availPrevDevices = mAvailableOutputDevices.filter(prevDevices);
ALOGV("%s %s prevDevice %s", __func__, logPrefix.c_str(),
prevDevices.toString().c_str());
if (!filteredDevices.isEmpty()) {
outputDesc->setDevices(filteredDevices);
}
// if the outputs are not materially active, there is no need to mute.
if (requiresMuteCheck) {
muteWaitMs = checkDeviceMuteStrategies(outputDesc, prevDevices, delayMs);
} else {
ALOGV("%s: %s suppressing checkDeviceMuteStrategies", __func__,
logPrefix.c_str());
muteWaitMs = 0;
}
bool outputRouted = outputDesc->isRouted();
// no need to proceed if new device is not AUDIO_DEVICE_NONE and not supported by current
// output profile or if new device is not supported AND previous device(s) is(are) still
// available (otherwise reset device must be done on the output)
if (!devices.isEmpty() && filteredDevices.isEmpty() && !availPrevDevices.empty()) {
ALOGV("%s: %s unsupported device %s for output", __func__, logPrefix.c_str(),
devices.toString().c_str());
// restore previous device after evaluating strategy mute state
outputDesc->setDevices(prevDevices);
return muteWaitMs;
}
// Do not change the routing if:
// the requested device is AUDIO_DEVICE_NONE
// OR the requested device is the same as current device
// AND force is not specified
// AND the output is connected by a valid audio patch.
// Doing this check here allows the caller to call setOutputDevices() without conditions
if ((filteredDevices.isEmpty() || filteredDevices == prevDevices) && !force && outputRouted) {
ALOGV("%s %s setting same device %s or null device, force=%d, patch handle=%d",
__func__, logPrefix.c_str(), filteredDevices.toString().c_str(), force,
outputDesc->getPatchHandle());
if (requiresVolumeCheck && !filteredDevices.isEmpty()) {
ALOGV("%s %s setting same device on routed output, force apply volumes",
__func__, logPrefix.c_str());
applyStreamVolumes(outputDesc, filteredDevices.types(), delayMs, true /*force*/);
}
return muteWaitMs;
}
ALOGV("%s %s changing device to %s", __func__, logPrefix.c_str(),
filteredDevices.toString().c_str());
// do the routing
if (filteredDevices.isEmpty() || mAvailableOutputDevices.filter(filteredDevices).empty()) {
resetOutputDevice(outputDesc, delayMs, NULL);
} else {
PatchBuilder patchBuilder;
patchBuilder.addSource(outputDesc);
ALOG_ASSERT(filteredDevices.size() <= AUDIO_PATCH_PORTS_MAX, "Too many sink ports");
for (const auto &filteredDevice : filteredDevices) {
patchBuilder.addSink(filteredDevice);
}
// Add half reported latency to delayMs when muteWaitMs is null in order
// to avoid disordered sequence of muting volume and changing devices.
int actualDelayMs = !skipMuteDelay && muteWaitMs == 0
? (delayMs + (outputDesc->latency() / 2)) : delayMs;
installPatch(__func__, patchHandle, outputDesc.get(), patchBuilder.patch(), actualDelayMs);
}
// Since the mute is skip, also skip the apply stream volume as that will be applied externally
if (!skipMuteDelay) {
// update stream volumes according to new device
applyStreamVolumes(outputDesc, filteredDevices.types(), delayMs);
}
return muteWaitMs;
}
status_t AudioPolicyManager::resetOutputDevice(const sp<AudioOutputDescriptor>& outputDesc,
int delayMs,
audio_patch_handle_t *patchHandle)
{
ssize_t index;
if (patchHandle == nullptr && !outputDesc->isRouted()) {
return INVALID_OPERATION;
}
if (patchHandle) {
index = mAudioPatches.indexOfKey(*patchHandle);
} else {
index = mAudioPatches.indexOfKey(outputDesc->getPatchHandle());
}
if (index < 0) {
return INVALID_OPERATION;
}
sp< AudioPatch> patchDesc = mAudioPatches.valueAt(index);
status_t status = mpClientInterface->releaseAudioPatch(patchDesc->getAfHandle(), delayMs);
ALOGV("resetOutputDevice() releaseAudioPatch returned %d", status);
outputDesc->setPatchHandle(AUDIO_PATCH_HANDLE_NONE);
removeAudioPatch(patchDesc->getHandle());
nextAudioPortGeneration();
mpClientInterface->onAudioPatchListUpdate();
return status;
}
status_t AudioPolicyManager::setInputDevice(audio_io_handle_t input,
const sp<DeviceDescriptor> &device,
bool force,
audio_patch_handle_t *patchHandle)
{
status_t status = NO_ERROR;
sp<AudioInputDescriptor> inputDesc = mInputs.valueFor(input);
if ((device != nullptr) && ((device != inputDesc->getDevice()) || force)) {
inputDesc->setDevice(device);
if (mAvailableInputDevices.contains(device)) {
PatchBuilder patchBuilder;
patchBuilder.addSink(inputDesc,
// AUDIO_SOURCE_HOTWORD is for internal use only:
// handled as AUDIO_SOURCE_VOICE_RECOGNITION by the audio HAL
[inputDesc](const PatchBuilder::mix_usecase_t& usecase) {
auto result = usecase;
if (result.source == AUDIO_SOURCE_HOTWORD && !inputDesc->isSoundTrigger()) {
result.source = AUDIO_SOURCE_VOICE_RECOGNITION;
}
return result; }).
//only one input device for now
addSource(device);
status = installPatch(__func__, patchHandle, inputDesc.get(), patchBuilder.patch(), 0);
}
}
return status;
}
status_t AudioPolicyManager::resetInputDevice(audio_io_handle_t input,
audio_patch_handle_t *patchHandle)
{
sp<AudioInputDescriptor> inputDesc = mInputs.valueFor(input);
ssize_t index;
if (patchHandle) {
index = mAudioPatches.indexOfKey(*patchHandle);
} else {
index = mAudioPatches.indexOfKey(inputDesc->getPatchHandle());
}
if (index < 0) {
return INVALID_OPERATION;
}
sp< AudioPatch> patchDesc = mAudioPatches.valueAt(index);
status_t status = mpClientInterface->releaseAudioPatch(patchDesc->getAfHandle(), 0);
ALOGV("resetInputDevice() releaseAudioPatch returned %d", status);
inputDesc->setPatchHandle(AUDIO_PATCH_HANDLE_NONE);
removeAudioPatch(patchDesc->getHandle());
nextAudioPortGeneration();
mpClientInterface->onAudioPatchListUpdate();
return status;
}
sp<IOProfile> AudioPolicyManager::getInputProfile(const sp<DeviceDescriptor> &device,
uint32_t& samplingRate,
audio_format_t& format,
audio_channel_mask_t& channelMask,
audio_input_flags_t flags)
{
// Choose an input profile based on the requested capture parameters: select the first available
// profile supporting all requested parameters.
// The flags can be ignored if it doesn't contain a much match flag.
using underlying_input_flag_t = std::underlying_type_t<audio_input_flags_t>;
const underlying_input_flag_t mustMatchFlag = AUDIO_INPUT_FLAG_MMAP_NOIRQ |
AUDIO_INPUT_FLAG_HOTWORD_TAP | AUDIO_INPUT_FLAG_HW_LOOKBACK;
const underlying_input_flag_t oriFlags = flags;
for (;;) {
sp<IOProfile> firstInexact = nullptr;
uint32_t updatedSamplingRate = 0;
audio_format_t updatedFormat = AUDIO_FORMAT_INVALID;
audio_channel_mask_t updatedChannelMask = AUDIO_CHANNEL_INVALID;
for (const auto& hwModule : mHwModules) {
for (const auto& profile : hwModule->getInputProfiles()) {
// profile->log();
//updatedFormat = format;
if (profile->getCompatibilityScore(
DeviceVector(device),
samplingRate,
&updatedSamplingRate,
format,
&updatedFormat,
channelMask,
&updatedChannelMask,
// FIXME ugly cast
(audio_output_flags_t) flags,
true /*exactMatchRequiredForInputFlags*/) == IOProfile::EXACT_MATCH) {
samplingRate = updatedSamplingRate;
format = updatedFormat;
channelMask = updatedChannelMask;
return profile;
}
if (firstInexact == nullptr
&& profile->getCompatibilityScore(
DeviceVector(device),
samplingRate,
&updatedSamplingRate,
format,
&updatedFormat,
channelMask,
&updatedChannelMask,
// FIXME ugly cast
(audio_output_flags_t) flags,
false /*exactMatchRequiredForInputFlags*/)
!= IOProfile::NO_MATCH) {
firstInexact = profile;
}
}
}
if (firstInexact != nullptr) {
samplingRate = updatedSamplingRate;
format = updatedFormat;
channelMask = updatedChannelMask;
return firstInexact;
} else if (flags & AUDIO_INPUT_FLAG_RAW) {
flags = (audio_input_flags_t) (flags & ~AUDIO_INPUT_FLAG_RAW); // retry
} else if ((flags & mustMatchFlag) == AUDIO_INPUT_FLAG_NONE &&
flags != AUDIO_INPUT_FLAG_NONE && audio_is_linear_pcm(format)) {
flags = AUDIO_INPUT_FLAG_NONE;
} else { // fail
ALOGW("%s could not find profile for device %s, sampling rate %u, format %#x, "
"channel mask 0x%X, flags %#x", __func__, device->toString().c_str(),
samplingRate, format, channelMask, oriFlags);
break;
}
}
return nullptr;
}
float AudioPolicyManager::computeVolume(IVolumeCurves &curves,
VolumeSource volumeSource,
int index,
const DeviceTypeSet& deviceTypes)
{
float volumeDb = curves.volIndexToDb(Volume::getDeviceCategory(deviceTypes), index);
// handle the case of accessibility active while a ringtone is playing: if the ringtone is much
// louder than the accessibility prompt, the prompt cannot be heard, thus masking the touch
// exploration of the dialer UI. In this situation, bring the accessibility volume closer to
// the ringtone volume
const auto callVolumeSrc = toVolumeSource(AUDIO_STREAM_VOICE_CALL, false);
const auto ringVolumeSrc = toVolumeSource(AUDIO_STREAM_RING, false);
const auto musicVolumeSrc = toVolumeSource(AUDIO_STREAM_MUSIC, false);
const auto alarmVolumeSrc = toVolumeSource(AUDIO_STREAM_ALARM, false);
const auto a11yVolumeSrc = toVolumeSource(AUDIO_STREAM_ACCESSIBILITY, false);
// Verify that the current volume source is not the ringer volume to prevent recursively
// calling to compute volume. This could happen in cases where a11y and ringer sounds belong
// to the same volume group.
if (volumeSource != ringVolumeSrc && volumeSource == a11yVolumeSrc
&& (AUDIO_MODE_RINGTONE == mEngine->getPhoneState()) &&
mOutputs.isActive(ringVolumeSrc, 0)) {
auto &ringCurves = getVolumeCurves(AUDIO_STREAM_RING);
const float ringVolumeDb = computeVolume(ringCurves, ringVolumeSrc, index, deviceTypes);
return ringVolumeDb - 4 > volumeDb ? ringVolumeDb - 4 : volumeDb;
}
// in-call: always cap volume by voice volume + some low headroom
if ((volumeSource != callVolumeSrc && (isInCall() ||
mOutputs.isActiveLocally(callVolumeSrc))) &&
(volumeSource == toVolumeSource(AUDIO_STREAM_SYSTEM, false) ||
volumeSource == ringVolumeSrc || volumeSource == musicVolumeSrc ||
volumeSource == alarmVolumeSrc ||
volumeSource == toVolumeSource(AUDIO_STREAM_NOTIFICATION, false) ||
volumeSource == toVolumeSource(AUDIO_STREAM_ENFORCED_AUDIBLE, false) ||
volumeSource == toVolumeSource(AUDIO_STREAM_DTMF, false) ||
volumeSource == a11yVolumeSrc)) {
auto &voiceCurves = getVolumeCurves(callVolumeSrc);
int voiceVolumeIndex = voiceCurves.getVolumeIndex(deviceTypes);
const float maxVoiceVolDb =
computeVolume(voiceCurves, callVolumeSrc, voiceVolumeIndex, deviceTypes)
+ IN_CALL_EARPIECE_HEADROOM_DB;
// FIXME: Workaround for call screening applications until a proper audio mode is defined
// to support this scenario : Exempt the RING stream from the audio cap if the audio was
// programmatically muted.
// VOICE_CALL stream has minVolumeIndex > 0 : Users cannot set the volume of voice calls to
// 0. We don't want to cap volume when the system has programmatically muted the voice call
// stream. See setVolumeCurveIndex() for more information.
bool exemptFromCapping =
((volumeSource == ringVolumeSrc) || (volumeSource == a11yVolumeSrc))
&& (voiceVolumeIndex == 0);
ALOGV_IF(exemptFromCapping, "%s volume source %d at vol=%f not capped", __func__,
volumeSource, volumeDb);
if ((volumeDb > maxVoiceVolDb) && !exemptFromCapping) {
ALOGV("%s volume source %d at vol=%f overriden by volume group %d at vol=%f", __func__,
volumeSource, volumeDb, callVolumeSrc, maxVoiceVolDb);
volumeDb = maxVoiceVolDb;
}
}
// if a headset is connected, apply the following rules to ring tones and notifications
// to avoid sound level bursts in user's ears:
// - always attenuate notifications volume by 6dB
// - attenuate ring tones volume by 6dB unless music is not playing and
// speaker is part of the select devices
// - if music is playing, always limit the volume to current music volume,
// with a minimum threshold at -36dB so that notification is always perceived.
if (!Intersection(deviceTypes,
{AUDIO_DEVICE_OUT_BLUETOOTH_A2DP, AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_HEADPHONES,
AUDIO_DEVICE_OUT_WIRED_HEADSET, AUDIO_DEVICE_OUT_WIRED_HEADPHONE,
AUDIO_DEVICE_OUT_USB_HEADSET, AUDIO_DEVICE_OUT_HEARING_AID,
AUDIO_DEVICE_OUT_BLE_HEADSET}).empty() &&
((volumeSource == alarmVolumeSrc ||
volumeSource == ringVolumeSrc) ||
(volumeSource == toVolumeSource(AUDIO_STREAM_NOTIFICATION, false)) ||
(volumeSource == toVolumeSource(AUDIO_STREAM_SYSTEM, false)) ||
((volumeSource == toVolumeSource(AUDIO_STREAM_ENFORCED_AUDIBLE, false)) &&
(mEngine->getForceUse(AUDIO_POLICY_FORCE_FOR_SYSTEM) == AUDIO_POLICY_FORCE_NONE))) &&
curves.canBeMuted()) {
// when the phone is ringing we must consider that music could have been paused just before
// by the music application and behave as if music was active if the last music track was
// just stopped
// Verify that the current volume source is not the music volume to prevent recursively
// calling to compute volume. This could happen in cases where music and
// (alarm, ring, notification, system, etc.) sounds belong to the same volume group.
if (volumeSource != musicVolumeSrc &&
(isStreamActive(AUDIO_STREAM_MUSIC, SONIFICATION_HEADSET_MUSIC_DELAY)
|| mLimitRingtoneVolume)) {
volumeDb += SONIFICATION_HEADSET_VOLUME_FACTOR_DB;
DeviceTypeSet musicDevice =
mEngine->getOutputDevicesForAttributes(attributes_initializer(AUDIO_USAGE_MEDIA),
nullptr, true /*fromCache*/).types();
auto &musicCurves = getVolumeCurves(AUDIO_STREAM_MUSIC);
float musicVolDb = computeVolume(musicCurves,
musicVolumeSrc,
musicCurves.getVolumeIndex(musicDevice),
musicDevice);
float minVolDb = (musicVolDb > SONIFICATION_HEADSET_VOLUME_MIN_DB) ?
musicVolDb : SONIFICATION_HEADSET_VOLUME_MIN_DB;
if (volumeDb > minVolDb) {
volumeDb = minVolDb;
ALOGV("computeVolume limiting volume to %f musicVol %f", minVolDb, musicVolDb);
}
if (Volume::getDeviceForVolume(deviceTypes) != AUDIO_DEVICE_OUT_SPEAKER
&& !Intersection(deviceTypes, {AUDIO_DEVICE_OUT_BLUETOOTH_A2DP,
AUDIO_DEVICE_OUT_BLUETOOTH_A2DP_HEADPHONES}).empty()) {
// on A2DP, also ensure notification volume is not too low compared to media when
// intended to be played
if ((volumeDb > -96.0f) &&
(musicVolDb - SONIFICATION_A2DP_MAX_MEDIA_DIFF_DB > volumeDb)) {
ALOGV("%s increasing volume for volume source=%d device=%s from %f to %f",
__func__, volumeSource, dumpDeviceTypes(deviceTypes).c_str(), volumeDb,
musicVolDb - SONIFICATION_A2DP_MAX_MEDIA_DIFF_DB);
volumeDb = musicVolDb - SONIFICATION_A2DP_MAX_MEDIA_DIFF_DB;
}
}
} else if ((Volume::getDeviceForVolume(deviceTypes) != AUDIO_DEVICE_OUT_SPEAKER) ||
(!(volumeSource == alarmVolumeSrc || volumeSource == ringVolumeSrc))) {
volumeDb += SONIFICATION_HEADSET_VOLUME_FACTOR_DB;
}
}
return volumeDb;
}
int AudioPolicyManager::rescaleVolumeIndex(int srcIndex,
VolumeSource fromVolumeSource,
VolumeSource toVolumeSource)
{
if (fromVolumeSource == toVolumeSource) {
return srcIndex;
}
auto &srcCurves = getVolumeCurves(fromVolumeSource);
auto &dstCurves = getVolumeCurves(toVolumeSource);
float minSrc = (float)srcCurves.getVolumeIndexMin();
float maxSrc = (float)srcCurves.getVolumeIndexMax();
float minDst = (float)dstCurves.getVolumeIndexMin();
float maxDst = (float)dstCurves.getVolumeIndexMax();
// preserve mute request or correct range
if (srcIndex < minSrc) {
if (srcIndex == 0) {
return 0;
}
srcIndex = minSrc;
} else if (srcIndex > maxSrc) {
srcIndex = maxSrc;
}
return (int)(minDst + ((srcIndex - minSrc) * (maxDst - minDst)) / (maxSrc - minSrc));
}
status_t AudioPolicyManager::checkAndSetVolume(IVolumeCurves &curves,
VolumeSource volumeSource,
int index,
const sp<AudioOutputDescriptor>& outputDesc,
DeviceTypeSet deviceTypes,
int delayMs,
bool force)
{
// do not change actual attributes volume if the attributes is muted
if (outputDesc->isMuted(volumeSource)) {
ALOGVV("%s: volume source %d muted count %d active=%d", __func__, volumeSource,
outputDesc->getMuteCount(volumeSource), outputDesc->isActive(volumeSource));
return NO_ERROR;
}
bool isVoiceVolSrc;
bool isBtScoVolSrc;
if (!isVolumeConsistentForCalls(
volumeSource, deviceTypes, isVoiceVolSrc, isBtScoVolSrc, __func__)) {
// Do not return an error here as AudioService will always set both voice call
// and Bluetooth SCO volumes due to stream aliasing.
return NO_ERROR;
}
if (deviceTypes.empty()) {
deviceTypes = outputDesc->devices().types();
index = curves.getVolumeIndex(deviceTypes);
ALOGD("%s if deviceTypes is change from none to device %s, need get index %d",
__func__, dumpDeviceTypes(deviceTypes).c_str(), index);
}
if (curves.getVolumeIndexMin() < 0 || curves.getVolumeIndexMax() < 0) {
ALOGE("invalid volume index range");
return BAD_VALUE;
}
float volumeDb = computeVolume(curves, volumeSource, index, deviceTypes);
if (outputDesc->isFixedVolume(deviceTypes) ||
// Force VoIP volume to max for bluetooth SCO device except if muted
(index != 0 && (isVoiceVolSrc || isBtScoVolSrc) &&
isSingleDeviceType(deviceTypes, audio_is_bluetooth_out_sco_device))) {
volumeDb = 0.0f;
}
const bool muted = (index == 0) && (volumeDb != 0.0f);
outputDesc->setVolume(volumeDb, muted, volumeSource, curves.getStreamTypes(),
deviceTypes, delayMs, force, isVoiceVolSrc);
if (outputDesc == mPrimaryOutput && (isVoiceVolSrc || isBtScoVolSrc)) {
setVoiceVolume(index, curves, isVoiceVolSrc, delayMs);
}
return NO_ERROR;
}
void AudioPolicyManager::setVoiceVolume(
int index, IVolumeCurves &curves, bool isVoiceVolSrc, int delayMs) {
float voiceVolume;
// Force voice volume to max or mute for Bluetooth SCO as other attenuations are managed
// by the headset
if (isVoiceVolSrc) {
voiceVolume = (float)index/(float)curves.getVolumeIndexMax();
} else {
voiceVolume = index == 0 ? 0.0 : 1.0;
}
if (voiceVolume != mLastVoiceVolume) {
mpClientInterface->setVoiceVolume(voiceVolume, delayMs);
mLastVoiceVolume = voiceVolume;
}
}
bool AudioPolicyManager::isVolumeConsistentForCalls(VolumeSource volumeSource,
const DeviceTypeSet& deviceTypes,
bool& isVoiceVolSrc,
bool& isBtScoVolSrc,
const char* caller) {
const VolumeSource callVolSrc = toVolumeSource(AUDIO_STREAM_VOICE_CALL, false);
const VolumeSource btScoVolSrc = toVolumeSource(AUDIO_STREAM_BLUETOOTH_SCO, false);
const bool isScoRequested = isScoRequestedForComm();
const bool isHAUsed = isHearingAidUsedForComm();
isVoiceVolSrc = (volumeSource != VOLUME_SOURCE_NONE) && (callVolSrc == volumeSource);
isBtScoVolSrc = (volumeSource != VOLUME_SOURCE_NONE) && (btScoVolSrc == volumeSource);
if ((callVolSrc != btScoVolSrc) &&
((isVoiceVolSrc && isScoRequested) ||
(isBtScoVolSrc && !(isScoRequested || isHAUsed))) &&
!isSingleDeviceType(deviceTypes, AUDIO_DEVICE_OUT_TELEPHONY_TX)) {
ALOGV("%s cannot set volume group %d volume when is%srequested for comm", caller,
volumeSource, isScoRequested ? " " : " not ");
return false;
}
return true;
}
void AudioPolicyManager::applyStreamVolumes(const sp<AudioOutputDescriptor>& outputDesc,
const DeviceTypeSet& deviceTypes,
int delayMs,
bool force)
{
ALOGVV("applyStreamVolumes() for device %s", dumpDeviceTypes(deviceTypes).c_str());
for (const auto &volumeGroup : mEngine->getVolumeGroups()) {
auto &curves = getVolumeCurves(toVolumeSource(volumeGroup));
checkAndSetVolume(curves, toVolumeSource(volumeGroup),
curves.getVolumeIndex(deviceTypes),
outputDesc, deviceTypes, delayMs, force);
}
}
void AudioPolicyManager::setStrategyMute(product_strategy_t strategy,
bool on,
const sp<AudioOutputDescriptor>& outputDesc,
int delayMs,
DeviceTypeSet deviceTypes)
{
std::vector<VolumeSource> sourcesToMute;
for (auto attributes: mEngine->getAllAttributesForProductStrategy(strategy)) {
ALOGVV("%s() attributes %s, mute %d, output ID %d", __func__,
toString(attributes).c_str(), on, outputDesc->getId());
VolumeSource source = toVolumeSource(attributes, false);
if ((source != VOLUME_SOURCE_NONE) &&
(std::find(begin(sourcesToMute), end(sourcesToMute), source)
== end(sourcesToMute))) {
sourcesToMute.push_back(source);
}
}
for (auto source : sourcesToMute) {
setVolumeSourceMute(source, on, outputDesc, delayMs, deviceTypes);
}
}
void AudioPolicyManager::setVolumeSourceMute(VolumeSource volumeSource,
bool on,
const sp<AudioOutputDescriptor>& outputDesc,
int delayMs,
DeviceTypeSet deviceTypes)
{
if (deviceTypes.empty()) {
deviceTypes = outputDesc->devices().types();
}
auto &curves = getVolumeCurves(volumeSource);
if (on) {
if (!outputDesc->isMuted(volumeSource)) {
if (curves.canBeMuted() &&
(volumeSource != toVolumeSource(AUDIO_STREAM_ENFORCED_AUDIBLE, false) ||
(mEngine->getForceUse(AUDIO_POLICY_FORCE_FOR_SYSTEM) ==
AUDIO_POLICY_FORCE_NONE))) {
checkAndSetVolume(curves, volumeSource, 0, outputDesc, deviceTypes, delayMs);
}
}
// increment mMuteCount after calling checkAndSetVolume() so that volume change is not
// ignored
outputDesc->incMuteCount(volumeSource);
} else {
if (!outputDesc->isMuted(volumeSource)) {
ALOGV("%s unmuting non muted attributes!", __func__);
return;
}
if (outputDesc->decMuteCount(volumeSource) == 0) {
checkAndSetVolume(curves, volumeSource,
curves.getVolumeIndex(deviceTypes),
outputDesc,
deviceTypes,
delayMs);
}
}
}
bool AudioPolicyManager::isValidAttributes(const audio_attributes_t *paa)
{
// has flags that map to a stream type?
if ((paa->flags & (AUDIO_FLAG_AUDIBILITY_ENFORCED | AUDIO_FLAG_SCO | AUDIO_FLAG_BEACON)) != 0) {
return true;
}
// has known usage?
switch (paa->usage) {
case AUDIO_USAGE_UNKNOWN:
case AUDIO_USAGE_MEDIA:
case AUDIO_USAGE_VOICE_COMMUNICATION:
case AUDIO_USAGE_VOICE_COMMUNICATION_SIGNALLING:
case AUDIO_USAGE_ALARM:
case AUDIO_USAGE_NOTIFICATION:
case AUDIO_USAGE_NOTIFICATION_TELEPHONY_RINGTONE:
case AUDIO_USAGE_NOTIFICATION_COMMUNICATION_REQUEST:
case AUDIO_USAGE_NOTIFICATION_COMMUNICATION_INSTANT:
case AUDIO_USAGE_NOTIFICATION_COMMUNICATION_DELAYED:
case AUDIO_USAGE_NOTIFICATION_EVENT:
case AUDIO_USAGE_ASSISTANCE_ACCESSIBILITY:
case AUDIO_USAGE_ASSISTANCE_NAVIGATION_GUIDANCE:
case AUDIO_USAGE_ASSISTANCE_SONIFICATION:
case AUDIO_USAGE_GAME:
case AUDIO_USAGE_VIRTUAL_SOURCE:
case AUDIO_USAGE_ASSISTANT:
case AUDIO_USAGE_CALL_ASSISTANT:
case AUDIO_USAGE_EMERGENCY:
case AUDIO_USAGE_SAFETY:
case AUDIO_USAGE_VEHICLE_STATUS:
case AUDIO_USAGE_ANNOUNCEMENT:
break;
default:
return false;
}
return true;
}
audio_policy_forced_cfg_t AudioPolicyManager::getForceUse(audio_policy_force_use_t usage)
{
return mEngine->getForceUse(usage);
}
bool AudioPolicyManager::isInCall() const {
return isStateInCall(mEngine->getPhoneState());
}
bool AudioPolicyManager::isStateInCall(int state) const {
return is_state_in_call(state);
}
bool AudioPolicyManager::isCallAudioAccessible() const {
audio_mode_t mode = mEngine->getPhoneState();
return (mode == AUDIO_MODE_IN_CALL)
|| (mode == AUDIO_MODE_CALL_SCREEN)
|| (mode == AUDIO_MODE_CALL_REDIRECT);
}
bool AudioPolicyManager::isInCallOrScreening() const {
audio_mode_t mode = mEngine->getPhoneState();
return isStateInCall(mode) || mode == AUDIO_MODE_CALL_SCREEN;
}
void AudioPolicyManager::cleanUpForDevice(const sp<DeviceDescriptor>& deviceDesc)
{
for (ssize_t i = (ssize_t)mAudioSources.size() - 1; i >= 0; i--) {
sp<SourceClientDescriptor> sourceDesc = mAudioSources.valueAt(i);
if (sourceDesc->isConnected() && (sourceDesc->srcDevice()->equals(deviceDesc) ||
sourceDesc->sinkDevice()->equals(deviceDesc))
&& !isCallRxAudioSource(sourceDesc)) {
disconnectAudioSource(sourceDesc);
}
}
for (ssize_t i = (ssize_t)mAudioPatches.size() - 1; i >= 0; i--) {
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(i);
bool release = false;
for (size_t j = 0; j < patchDesc->mPatch.num_sources && !release; j++) {
const struct audio_port_config *source = &patchDesc->mPatch.sources[j];
if (source->type == AUDIO_PORT_TYPE_DEVICE &&
source->ext.device.type == deviceDesc->type()) {
release = true;
}
}
const char *address = deviceDesc->address().c_str();
for (size_t j = 0; j < patchDesc->mPatch.num_sinks && !release; j++) {
const struct audio_port_config *sink = &patchDesc->mPatch.sinks[j];
if (sink->type == AUDIO_PORT_TYPE_DEVICE &&
sink->ext.device.type == deviceDesc->type() &&
(strnlen(address, AUDIO_DEVICE_MAX_ADDRESS_LEN) == 0
|| strncmp(sink->ext.device.address, address,
AUDIO_DEVICE_MAX_ADDRESS_LEN) == 0)) {
release = true;
}
}
if (release) {
ALOGV("%s releasing patch %u", __FUNCTION__, patchDesc->getHandle());
releaseAudioPatch(patchDesc->getHandle(), patchDesc->getUid());
}
}
mInputs.clearSessionRoutesForDevice(deviceDesc);
mHwModules.cleanUpForDevice(deviceDesc);
}
void AudioPolicyManager::modifySurroundFormats(
const sp<DeviceDescriptor>& devDesc, FormatVector *formatsPtr) {
std::unordered_set<audio_format_t> enforcedSurround(
devDesc->encodedFormats().begin(), devDesc->encodedFormats().end());
std::unordered_set<audio_format_t> allSurround; // A flat set of all known surround formats
for (const auto& pair : mConfig->getSurroundFormats()) {
allSurround.insert(pair.first);
for (const auto& subformat : pair.second) allSurround.insert(subformat);
}
audio_policy_forced_cfg_t forceUse = mEngine->getForceUse(
AUDIO_POLICY_FORCE_FOR_ENCODED_SURROUND);
ALOGD("%s: forced use = %d", __FUNCTION__, forceUse);
// This is the resulting set of formats depending on the surround mode:
// 'all surround' = allSurround
// 'enforced surround' = enforcedSurround [may include IEC69137 which isn't raw surround fmt]
// 'non-surround' = not in 'all surround' and not in 'enforced surround'
// 'manual surround' = mManualSurroundFormats
// AUTO: formats v 'enforced surround'
// ALWAYS: formats v 'all surround' v 'enforced surround'
// NEVER: formats ^ 'non-surround'
// MANUAL: formats ^ ('non-surround' v 'manual surround' v (IEC69137 ^ 'enforced surround'))
std::unordered_set<audio_format_t> formatSet;
if (forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL
|| forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_NEVER) {
// formatSet is (formats ^ 'non-surround')
for (auto formatIter = formatsPtr->begin(); formatIter != formatsPtr->end(); ++formatIter) {
if (allSurround.count(*formatIter) == 0 && enforcedSurround.count(*formatIter) == 0) {
formatSet.insert(*formatIter);
}
}
} else {
formatSet.insert(formatsPtr->begin(), formatsPtr->end());
}
formatsPtr->clear(); // Re-filled from the formatSet at the end.
if (forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL) {
formatSet.insert(mManualSurroundFormats.begin(), mManualSurroundFormats.end());
// Enable IEC61937 when in MANUAL mode if it's enforced for this device.
if (enforcedSurround.count(AUDIO_FORMAT_IEC61937) != 0) {
formatSet.insert(AUDIO_FORMAT_IEC61937);
}
} else if (forceUse != AUDIO_POLICY_FORCE_ENCODED_SURROUND_NEVER) { // AUTO or ALWAYS
if (forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_ALWAYS) {
formatSet.insert(allSurround.begin(), allSurround.end());
}
formatSet.insert(enforcedSurround.begin(), enforcedSurround.end());
}
for (const auto& format : formatSet) {
formatsPtr->push_back(format);
}
}
void AudioPolicyManager::modifySurroundChannelMasks(ChannelMaskSet *channelMasksPtr) {
ChannelMaskSet &channelMasks = *channelMasksPtr;
audio_policy_forced_cfg_t forceUse = mEngine->getForceUse(
AUDIO_POLICY_FORCE_FOR_ENCODED_SURROUND);
// If NEVER, then remove support for channelMasks > stereo.
if (forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_NEVER) {
for (auto it = channelMasks.begin(); it != channelMasks.end();) {
audio_channel_mask_t channelMask = *it;
if (channelMask & ~AUDIO_CHANNEL_OUT_STEREO) {
ALOGV("%s: force NEVER, so remove channelMask 0x%08x", __FUNCTION__, channelMask);
it = channelMasks.erase(it);
} else {
++it;
}
}
// If ALWAYS or MANUAL, then make sure we at least support 5.1
} else if (forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_ALWAYS
|| forceUse == AUDIO_POLICY_FORCE_ENCODED_SURROUND_MANUAL) {
bool supports5dot1 = false;
// Are there any channel masks that can be considered "surround"?
for (audio_channel_mask_t channelMask : channelMasks) {
if ((channelMask & AUDIO_CHANNEL_OUT_5POINT1) == AUDIO_CHANNEL_OUT_5POINT1) {
supports5dot1 = true;
break;
}
}
// If not then add 5.1 support.
if (!supports5dot1) {
channelMasks.insert(AUDIO_CHANNEL_OUT_5POINT1);
ALOGV("%s: force MANUAL or ALWAYS, so adding channelMask for 5.1 surround", __func__);
}
}
}
void AudioPolicyManager::updateAudioProfiles(const sp<DeviceDescriptor>& devDesc,
audio_io_handle_t ioHandle,
const sp<IOProfile>& profile) {
if (!profile->hasDynamicAudioProfile()) {
return;
}
audio_port_v7 devicePort;
devDesc->toAudioPort(&devicePort);
audio_port_v7 mixPort;
profile->toAudioPort(&mixPort);
mixPort.ext.mix.handle = ioHandle;
status_t status = mpClientInterface->getAudioMixPort(&devicePort, &mixPort);
if (status != NO_ERROR) {
ALOGE("%s failed to query the attributes of the mix port", __func__);
return;
}
std::set<audio_format_t> supportedFormats;
for (size_t i = 0; i < mixPort.num_audio_profiles; ++i) {
supportedFormats.insert(mixPort.audio_profiles[i].format);
}
FormatVector formats(supportedFormats.begin(), supportedFormats.end());
mReportedFormatsMap[devDesc] = formats;
if (devDesc->type() == AUDIO_DEVICE_OUT_HDMI ||
isDeviceOfModule(devDesc,AUDIO_HARDWARE_MODULE_ID_MSD)) {
modifySurroundFormats(devDesc, &formats);
size_t modifiedNumProfiles = 0;
for (size_t i = 0; i < mixPort.num_audio_profiles; ++i) {
if (std::find(formats.begin(), formats.end(), mixPort.audio_profiles[i].format) ==
formats.end()) {
// Skip the format that is not present after modifying surround formats.
continue;
}
memcpy(&mixPort.audio_profiles[modifiedNumProfiles], &mixPort.audio_profiles[i],
sizeof(struct audio_profile));
ChannelMaskSet channels(mixPort.audio_profiles[modifiedNumProfiles].channel_masks,
mixPort.audio_profiles[modifiedNumProfiles].channel_masks +
mixPort.audio_profiles[modifiedNumProfiles].num_channel_masks);
modifySurroundChannelMasks(&channels);
std::copy(channels.begin(), channels.end(),
std::begin(mixPort.audio_profiles[modifiedNumProfiles].channel_masks));
mixPort.audio_profiles[modifiedNumProfiles++].num_channel_masks = channels.size();
}
mixPort.num_audio_profiles = modifiedNumProfiles;
}
profile->importAudioPort(mixPort);
}
status_t AudioPolicyManager::installPatch(const char *caller,
audio_patch_handle_t *patchHandle,
AudioIODescriptorInterface *ioDescriptor,
const struct audio_patch *patch,
int delayMs)
{
ssize_t index = mAudioPatches.indexOfKey(
patchHandle && *patchHandle != AUDIO_PATCH_HANDLE_NONE ?
*patchHandle : ioDescriptor->getPatchHandle());
sp<AudioPatch> patchDesc;
status_t status = installPatch(
caller, index, patchHandle, patch, delayMs, mUidCached, &patchDesc);
if (status == NO_ERROR) {
ioDescriptor->setPatchHandle(patchDesc->getHandle());
}
return status;
}
status_t AudioPolicyManager::installPatch(const char *caller,
ssize_t index,
audio_patch_handle_t *patchHandle,
const struct audio_patch *patch,
int delayMs,
uid_t uid,
sp<AudioPatch> *patchDescPtr)
{
sp<AudioPatch> patchDesc;
audio_patch_handle_t afPatchHandle = AUDIO_PATCH_HANDLE_NONE;
if (index >= 0) {
patchDesc = mAudioPatches.valueAt(index);
afPatchHandle = patchDesc->getAfHandle();
}
status_t status = mpClientInterface->createAudioPatch(patch, &afPatchHandle, delayMs);
ALOGV("%s() AF::createAudioPatch returned %d patchHandle %d num_sources %d num_sinks %d",
caller, status, afPatchHandle, patch->num_sources, patch->num_sinks);
if (status == NO_ERROR) {
if (index < 0) {
patchDesc = new AudioPatch(patch, uid);
addAudioPatch(patchDesc->getHandle(), patchDesc);
} else {
patchDesc->mPatch = *patch;
}
patchDesc->setAfHandle(afPatchHandle);
if (patchHandle) {
*patchHandle = patchDesc->getHandle();
}
nextAudioPortGeneration();
mpClientInterface->onAudioPatchListUpdate();
}
if (patchDescPtr) *patchDescPtr = patchDesc;
return status;
}
bool AudioPolicyManager::areAllActiveTracksRerouted(const sp<SwAudioOutputDescriptor>& output)
{
const TrackClientVector activeClients = output->getActiveClients();
if (activeClients.empty()) {
return true;
}
ssize_t index = mAudioPatches.indexOfKey(output->getPatchHandle());
if (index < 0) {
ALOGE("%s, no audio patch found while there are active clients on output %d",
__func__, output->getId());
return false;
}
sp<AudioPatch> patchDesc = mAudioPatches.valueAt(index);
DeviceVector routedDevices;
for (int i = 0; i < patchDesc->mPatch.num_sinks; ++i) {
sp<DeviceDescriptor> device = mAvailableOutputDevices.getDeviceFromId(
patchDesc->mPatch.sinks[i].id);
if (device == nullptr) {
ALOGE("%s, no audio device found with id(%d)",
__func__, patchDesc->mPatch.sinks[i].id);
return false;
}
routedDevices.add(device);
}
for (const auto& client : activeClients) {
if (client->isInvalid()) {
// No need to take care about invalidated clients.
continue;
}
sp<DeviceDescriptor> preferredDevice =
mAvailableOutputDevices.getDeviceFromId(client->preferredDeviceId());
if (mEngine->getOutputDevicesForAttributes(
client->attributes(), preferredDevice, false) == routedDevices) {
return false;
}
}
return true;
}
sp<SwAudioOutputDescriptor> AudioPolicyManager::openOutputWithProfileAndDevice(
const sp<IOProfile>& profile, const DeviceVector& devices,
const audio_config_base_t *mixerConfig, const audio_config_t *halConfig,
audio_output_flags_t flags)
{
for (const auto& device : devices) {
// TODO: This should be checking if the profile supports the device combo.
if (!profile->supportsDevice(device)) {
ALOGE("%s profile(%s) doesn't support device %#x", __func__, profile->getName().c_str(),
device->type());
return nullptr;
}
}
sp<SwAudioOutputDescriptor> desc = new SwAudioOutputDescriptor(profile, mpClientInterface);
audio_io_handle_t output = AUDIO_IO_HANDLE_NONE;
status_t status = desc->open(halConfig, mixerConfig, devices,
AUDIO_STREAM_DEFAULT, flags, &output);
if (status != NO_ERROR) {
ALOGE("%s failed to open output %d", __func__, status);
return nullptr;
}
if ((flags & AUDIO_OUTPUT_FLAG_BIT_PERFECT) == AUDIO_OUTPUT_FLAG_BIT_PERFECT) {
auto portConfig = desc->getConfig();
for (const auto& device : devices) {
device->setPreferredConfig(&portConfig);
}
}
// Here is where the out_set_parameters() for card & device gets called
sp<DeviceDescriptor> device = devices.getDeviceForOpening();
const audio_devices_t deviceType = device->type();
const String8 &address = String8(device->address().c_str());
if (!address.empty()) {
char *param = audio_device_address_to_parameter(deviceType, address.c_str());
mpClientInterface->setParameters(output, String8(param));
free(param);
}
updateAudioProfiles(device, output, profile);
if (!profile->hasValidAudioProfile()) {
ALOGW("%s() missing param", __func__);
desc->close();
return nullptr;
} else if (profile->hasDynamicAudioProfile() && halConfig == nullptr) {
// Reopen the output with the best audio profile picked by APM when the profile supports
// dynamic audio profile and the hal config is not specified.
desc->close();
output = AUDIO_IO_HANDLE_NONE;
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
profile->pickAudioProfile(
config.sample_rate, config.channel_mask, config.format);
config.offload_info.sample_rate = config.sample_rate;
config.offload_info.channel_mask = config.channel_mask;
config.offload_info.format = config.format;
status = desc->open(&config, mixerConfig, devices, AUDIO_STREAM_DEFAULT, flags, &output);
if (status != NO_ERROR) {
return nullptr;
}
}
addOutput(output, desc);
sp<DeviceDescriptor> speaker = mAvailableOutputDevices.getDevice(
AUDIO_DEVICE_OUT_SPEAKER, String8(""), AUDIO_FORMAT_DEFAULT);
if (audio_is_remote_submix_device(deviceType) && address != "0") {
sp<AudioPolicyMix> policyMix;
if (mPolicyMixes.getAudioPolicyMix(deviceType, address, policyMix) == NO_ERROR) {
policyMix->setOutput(desc);
desc->mPolicyMix = policyMix;
} else {
ALOGW("checkOutputsForDevice() cannot find policy for address %s",
address.c_str());
}
} else if (hasPrimaryOutput() && speaker != nullptr
&& mPrimaryOutput->supportsDevice(speaker) && !desc->supportsDevice(speaker)
&& ((desc->mFlags & AUDIO_OUTPUT_FLAG_DIRECT) == 0)) {
// no duplicated output for:
// - direct outputs
// - outputs used by dynamic policy mixes
// - outputs that supports SPEAKER while the primary output does not.
audio_io_handle_t duplicatedOutput = AUDIO_IO_HANDLE_NONE;
//TODO: configure audio effect output stage here
// open a duplicating output thread for the new output and the primary output
sp<SwAudioOutputDescriptor> dupOutputDesc =
new SwAudioOutputDescriptor(nullptr, mpClientInterface);
status = dupOutputDesc->openDuplicating(mPrimaryOutput, desc, &duplicatedOutput);
if (status == NO_ERROR) {
// add duplicated output descriptor
addOutput(duplicatedOutput, dupOutputDesc);
} else {
ALOGW("checkOutputsForDevice() could not open dup output for %d and %d",
mPrimaryOutput->mIoHandle, output);
desc->close();
removeOutput(output);
nextAudioPortGeneration();
return nullptr;
}
}
if (mPrimaryOutput == nullptr && profile->getFlags() & AUDIO_OUTPUT_FLAG_PRIMARY) {
ALOGV("%s(): re-assigning mPrimaryOutput", __func__);
mPrimaryOutput = desc;
mPrimaryModuleHandle = mPrimaryOutput->getModuleHandle();
}
return desc;
}
status_t AudioPolicyManager::getDevicesForAttributes(
const audio_attributes_t &attr, DeviceVector &devices, bool forVolume) {
// Devices are determined in the following precedence:
//
// 1) Devices associated with a dynamic policy matching the attributes. This is often
// a remote submix from MIX_ROUTE_FLAG_LOOP_BACK.
//
// If no such dynamic policy then
// 2) Devices containing an active client using setPreferredDevice
// with same strategy as the attributes.
// (from the default Engine::getOutputDevicesForAttributes() implementation).
//
// If no corresponding active client with setPreferredDevice then
// 3) Devices associated with the strategy determined by the attributes
// (from the default Engine::getOutputDevicesForAttributes() implementation).
//
// See related getOutputForAttrInt().
// check dynamic policies but only for primary descriptors (secondary not used for audible
// audio routing, only used for duplication for playback capture)
sp<AudioPolicyMix> policyMix;
bool unneededUsePrimaryOutputFromPolicyMixes = false;
status_t status = mPolicyMixes.getOutputForAttr(attr, AUDIO_CONFIG_BASE_INITIALIZER,
0 /*uid unknown here*/, AUDIO_SESSION_NONE, AUDIO_OUTPUT_FLAG_NONE,
mAvailableOutputDevices, nullptr /* requestedDevice */, policyMix,
nullptr /* secondaryMixes */, unneededUsePrimaryOutputFromPolicyMixes);
if (status != OK) {
return status;
}
if (policyMix != nullptr && policyMix->getOutput() != nullptr &&
// For volume control, skip LOOPBACK mixes which use AUDIO_DEVICE_OUT_REMOTE_SUBMIX
// as they are unaffected by device/stream volume
// (per SwAudioOutputDescriptor::isFixedVolume()).
(!forVolume || policyMix->mDeviceType != AUDIO_DEVICE_OUT_REMOTE_SUBMIX)
) {
sp<DeviceDescriptor> deviceDesc = mAvailableOutputDevices.getDevice(
policyMix->mDeviceType, policyMix->mDeviceAddress, AUDIO_FORMAT_DEFAULT);
devices.add(deviceDesc);
} else {
// The default Engine::getOutputDevicesForAttributes() uses findPreferredDevice()
// which selects setPreferredDevice if active. This means forVolume call
// will take an active setPreferredDevice, if such exists.
devices = mEngine->getOutputDevicesForAttributes(
attr, nullptr /* preferredDevice */, false /* fromCache */);
}
if (forVolume) {
// We alias the device AUDIO_DEVICE_OUT_SPEAKER_SAFE to AUDIO_DEVICE_OUT_SPEAKER
// for single volume control in AudioService (such relationship should exist if
// SPEAKER_SAFE is present).
//
// (This is unrelated to a different device grouping as Volume::getDeviceCategory)
DeviceVector speakerSafeDevices =
devices.getDevicesFromType(AUDIO_DEVICE_OUT_SPEAKER_SAFE);
if (!speakerSafeDevices.isEmpty()) {
devices.merge(mAvailableOutputDevices.getDevicesFromType(AUDIO_DEVICE_OUT_SPEAKER));
devices.remove(speakerSafeDevices);
}
}
return NO_ERROR;
}
status_t AudioPolicyManager::getProfilesForDevices(const DeviceVector& devices,
AudioProfileVector& audioProfiles,
uint32_t flags,
bool isInput) {
for (const auto& hwModule : mHwModules) {
// the MSD module checks for different conditions
if (strcmp(hwModule->getName(), AUDIO_HARDWARE_MODULE_ID_MSD) == 0) {
continue;
}
IOProfileCollection ioProfiles = isInput ? hwModule->getInputProfiles()
: hwModule->getOutputProfiles();
for (const auto& profile : ioProfiles) {
if (!profile->areAllDevicesSupported(devices) ||
!profile->isCompatibleProfileForFlags(
flags, false /*exactMatchRequiredForInputFlags*/)) {
continue;
}
audioProfiles.addAllValidProfiles(profile->asAudioPort()->getAudioProfiles());
}
}
if (!isInput) {
// add the direct profiles from MSD if present and has audio patches to all the output(s)
const auto &msdModule = mHwModules.getModuleFromName(AUDIO_HARDWARE_MODULE_ID_MSD);
if (msdModule != nullptr) {
if (msdHasPatchesToAllDevices(devices.toTypeAddrVector())) {
ALOGV("%s: MSD audio patches set to all output devices.", __func__);
for (const auto &profile: msdModule->getOutputProfiles()) {
if (!profile->asAudioPort()->isDirectOutput()) {
continue;
}
audioProfiles.addAllValidProfiles(profile->asAudioPort()->getAudioProfiles());
}
} else {
ALOGV("%s: MSD audio patches NOT set to all output devices.", __func__);
}
}
}
return NO_ERROR;
}
sp<SwAudioOutputDescriptor> AudioPolicyManager::reopenOutput(sp<SwAudioOutputDescriptor> outputDesc,
const audio_config_t *config,
audio_output_flags_t flags,
const char* caller) {
closeOutput(outputDesc->mIoHandle);
sp<SwAudioOutputDescriptor> preferredOutput = openOutputWithProfileAndDevice(
outputDesc->mProfile, outputDesc->devices(), nullptr /*mixerConfig*/, config, flags);
if (preferredOutput == nullptr) {
ALOGE("%s failed to reopen output device=%d, caller=%s",
__func__, outputDesc->devices()[0]->getId(), caller);
}
return preferredOutput;
}
void AudioPolicyManager::reopenOutputsWithDevices(
const std::map<audio_io_handle_t, DeviceVector> &outputsToReopen) {
for (const auto& [output, devices] : outputsToReopen) {
sp<SwAudioOutputDescriptor> desc = mOutputs.valueFor(output);
closeOutput(output);
openOutputWithProfileAndDevice(desc->mProfile, devices);
}
}
PortHandleVector AudioPolicyManager::getClientsForStream(
audio_stream_type_t streamType) const {
PortHandleVector clients;
for (size_t i = 0; i < mOutputs.size(); ++i) {
PortHandleVector clientsForStream = mOutputs.valueAt(i)->getClientsForStream(streamType);
clients.insert(clients.end(), clientsForStream.begin(), clientsForStream.end());
}
return clients;
}
void AudioPolicyManager::invalidateStreams(StreamTypeVector streams) const {
PortHandleVector clients;
for (auto stream : streams) {
PortHandleVector clientsForStream = getClientsForStream(stream);
clients.insert(clients.end(), clientsForStream.begin(), clientsForStream.end());
}
mpClientInterface->invalidateTracks(clients);
}
} // namespace android