/* ** ** Copyright 2012, The Android Open Source Project ** ** Licensed under the Apache License, Version 2.0 (the "License"); ** you may not use this file except in compliance with the License. ** You may obtain a copy of the License at ** ** http://www.apache.org/licenses/LICENSE-2.0 ** ** Unless required by applicable law or agreed to in writing, software ** distributed under the License is distributed on an "AS IS" BASIS, ** WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ** See the License for the specific language governing permissions and ** limitations under the License. */ #define LOG_TAG "AudioFlinger" //#define LOG_NDEBUG 0 #include #include "Configuration.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "AudioFlinger.h" // ---------------------------------------------------------------------------- // Note: the following macro is used for extremely verbose logging message. In // order to run with ALOG_ASSERT turned on, we need to have LOG_NDEBUG set to // 0; but one side effect of this is to turn all LOGV's as well. Some messages // are so verbose that we want to suppress them even when we have ALOG_ASSERT // turned on. Do not uncomment the #def below unless you really know what you // are doing and want to see all of the extremely verbose messages. //#define VERY_VERY_VERBOSE_LOGGING #ifdef VERY_VERY_VERBOSE_LOGGING #define ALOGVV ALOGV #else #define ALOGVV(a...) do { } while(0) #endif #define DEFAULT_OUTPUT_SAMPLE_RATE 48000 namespace android { using aidl_utils::statusTFromBinderStatus; using binder::Status; namespace { // Append a POD value into a vector of bytes. template void appendToBuffer(const T& value, std::vector* buffer) { const uint8_t* ar(reinterpret_cast(&value)); buffer->insert(buffer->end(), ar, ar + sizeof(T)); } // Write a POD value into a vector of bytes (clears the previous buffer // content). template void writeToBuffer(const T& value, std::vector* buffer) { buffer->clear(); appendToBuffer(value, buffer); } } // namespace // ---------------------------------------------------------------------------- // EffectBase implementation // ---------------------------------------------------------------------------- #undef LOG_TAG #define LOG_TAG "AudioFlinger::EffectBase" AudioFlinger::EffectBase::EffectBase(const sp& callback, effect_descriptor_t *desc, int id, audio_session_t sessionId, bool pinned) : mPinned(pinned), mCallback(callback), mId(id), mSessionId(sessionId), mDescriptor(*desc) { } // must be called with EffectModule::mLock held status_t AudioFlinger::EffectBase::setEnabled_l(bool enabled) { ALOGV("setEnabled %p enabled %d", this, enabled); if (enabled != isEnabled()) { switch (mState) { // going from disabled to enabled case IDLE: mState = STARTING; break; case STOPPED: mState = RESTART; break; case STOPPING: mState = ACTIVE; break; // going from enabled to disabled case RESTART: mState = STOPPED; break; case STARTING: mState = IDLE; break; case ACTIVE: mState = STOPPING; break; case DESTROYED: return NO_ERROR; // simply ignore as we are being destroyed } for (size_t i = 1; i < mHandles.size(); i++) { EffectHandle *h = mHandles[i]; if (h != NULL && !h->disconnected()) { h->setEnabled(enabled); } } } return NO_ERROR; } status_t AudioFlinger::EffectBase::setEnabled(bool enabled, bool fromHandle) { status_t status; { Mutex::Autolock _l(mLock); status = setEnabled_l(enabled); } if (fromHandle) { if (enabled) { if (status != NO_ERROR) { getCallback()->checkSuspendOnEffectEnabled(this, false, false /*threadLocked*/); } else { getCallback()->onEffectEnable(this); } } else { getCallback()->onEffectDisable(this); } } return status; } bool AudioFlinger::EffectBase::isEnabled() const { switch (mState) { case RESTART: case STARTING: case ACTIVE: return true; case IDLE: case STOPPING: case STOPPED: case DESTROYED: default: return false; } } void AudioFlinger::EffectBase::setSuspended(bool suspended) { Mutex::Autolock _l(mLock); mSuspended = suspended; } bool AudioFlinger::EffectBase::suspended() const { Mutex::Autolock _l(mLock); return mSuspended; } status_t AudioFlinger::EffectBase::addHandle(EffectHandle *handle) { status_t status; Mutex::Autolock _l(mLock); int priority = handle->priority(); size_t size = mHandles.size(); EffectHandle *controlHandle = NULL; size_t i; for (i = 0; i < size; i++) { EffectHandle *h = mHandles[i]; if (h == NULL || h->disconnected()) { continue; } // first non destroyed handle is considered in control if (controlHandle == NULL) { controlHandle = h; } if (h->priority() <= priority) { break; } } // if inserted in first place, move effect control from previous owner to this handle if (i == 0) { bool enabled = false; if (controlHandle != NULL) { enabled = controlHandle->enabled(); controlHandle->setControl(false/*hasControl*/, true /*signal*/, enabled /*enabled*/); } handle->setControl(true /*hasControl*/, false /*signal*/, enabled /*enabled*/); status = NO_ERROR; } else { status = ALREADY_EXISTS; } ALOGV("addHandle() %p added handle %p in position %zu", this, handle, i); mHandles.insertAt(handle, i); return status; } status_t AudioFlinger::EffectBase::updatePolicyState() { status_t status = NO_ERROR; bool doRegister = false; bool registered = false; bool doEnable = false; bool enabled = false; audio_io_handle_t io = AUDIO_IO_HANDLE_NONE; product_strategy_t strategy = PRODUCT_STRATEGY_NONE; { Mutex::Autolock _l(mLock); // register effect when first handle is attached and unregister when last handle is removed if (mPolicyRegistered != mHandles.size() > 0) { doRegister = true; mPolicyRegistered = mHandles.size() > 0; if (mPolicyRegistered) { const auto callback = getCallback(); io = callback->io(); strategy = callback->strategy(); } } // enable effect when registered according to enable state requested by controlling handle if (mHandles.size() > 0) { EffectHandle *handle = controlHandle_l(); if (handle != nullptr && mPolicyEnabled != handle->enabled()) { doEnable = true; mPolicyEnabled = handle->enabled(); } } registered = mPolicyRegistered; enabled = mPolicyEnabled; // The simultaneous release of two EffectHandles with the same EffectModule // may cause us to call this method at the same time. // This may deadlock under some circumstances (b/180941720). Avoid this. if (!doRegister && !(registered && doEnable)) { return NO_ERROR; } mPolicyLock.lock(); } ALOGV("%s name %s id %d session %d doRegister %d registered %d doEnable %d enabled %d", __func__, mDescriptor.name, mId, mSessionId, doRegister, registered, doEnable, enabled); if (doRegister) { if (registered) { status = AudioSystem::registerEffect( &mDescriptor, io, strategy, mSessionId, mId); } else { status = AudioSystem::unregisterEffect(mId); } } if (registered && doEnable) { status = AudioSystem::setEffectEnabled(mId, enabled); } mPolicyLock.unlock(); return status; } ssize_t AudioFlinger::EffectBase::removeHandle(EffectHandle *handle) { Mutex::Autolock _l(mLock); return removeHandle_l(handle); } ssize_t AudioFlinger::EffectBase::removeHandle_l(EffectHandle *handle) { size_t size = mHandles.size(); size_t i; for (i = 0; i < size; i++) { if (mHandles[i] == handle) { break; } } if (i == size) { ALOGW("%s %p handle not found %p", __FUNCTION__, this, handle); return BAD_VALUE; } ALOGV("removeHandle_l() %p removed handle %p in position %zu", this, handle, i); mHandles.removeAt(i); // if removed from first place, move effect control from this handle to next in line if (i == 0) { EffectHandle *h = controlHandle_l(); if (h != NULL) { h->setControl(true /*hasControl*/, true /*signal*/ , handle->enabled() /*enabled*/); } } // Prevent calls to process() and other functions on effect interface from now on. // The effect engine will be released by the destructor when the last strong reference on // this object is released which can happen after next process is called. if (mHandles.size() == 0 && !mPinned) { mState = DESTROYED; } return mHandles.size(); } // must be called with EffectModule::mLock held AudioFlinger::EffectHandle *AudioFlinger::EffectBase::controlHandle_l() { // the first valid handle in the list has control over the module for (size_t i = 0; i < mHandles.size(); i++) { EffectHandle *h = mHandles[i]; if (h != NULL && !h->disconnected()) { return h; } } return NULL; } // unsafe method called when the effect parent thread has been destroyed ssize_t AudioFlinger::EffectBase::disconnectHandle(EffectHandle *handle, bool unpinIfLast) { const auto callback = getCallback(); ALOGV("disconnect() %p handle %p", this, handle); if (callback->disconnectEffectHandle(handle, unpinIfLast)) { return mHandles.size(); } Mutex::Autolock _l(mLock); ssize_t numHandles = removeHandle_l(handle); if ((numHandles == 0) && (!mPinned || unpinIfLast)) { mLock.unlock(); callback->updateOrphanEffectChains(this); mLock.lock(); } return numHandles; } bool AudioFlinger::EffectBase::purgeHandles() { bool enabled = false; Mutex::Autolock _l(mLock); EffectHandle *handle = controlHandle_l(); if (handle != NULL) { enabled = handle->enabled(); } mHandles.clear(); return enabled; } void AudioFlinger::EffectBase::checkSuspendOnEffectEnabled(bool enabled, bool threadLocked) { getCallback()->checkSuspendOnEffectEnabled(this, enabled, threadLocked); } static String8 effectFlagsToString(uint32_t flags) { String8 s; s.append("conn. mode: "); switch (flags & EFFECT_FLAG_TYPE_MASK) { case EFFECT_FLAG_TYPE_INSERT: s.append("insert"); break; case EFFECT_FLAG_TYPE_AUXILIARY: s.append("auxiliary"); break; case EFFECT_FLAG_TYPE_REPLACE: s.append("replace"); break; case EFFECT_FLAG_TYPE_PRE_PROC: s.append("preproc"); break; case EFFECT_FLAG_TYPE_POST_PROC: s.append("postproc"); break; default: s.append("unknown/reserved"); break; } s.append(", "); s.append("insert pref: "); switch (flags & EFFECT_FLAG_INSERT_MASK) { case EFFECT_FLAG_INSERT_ANY: s.append("any"); break; case EFFECT_FLAG_INSERT_FIRST: s.append("first"); break; case EFFECT_FLAG_INSERT_LAST: s.append("last"); break; case EFFECT_FLAG_INSERT_EXCLUSIVE: s.append("exclusive"); break; default: s.append("unknown/reserved"); break; } s.append(", "); s.append("volume mgmt: "); switch (flags & EFFECT_FLAG_VOLUME_MASK) { case EFFECT_FLAG_VOLUME_NONE: s.append("none"); break; case EFFECT_FLAG_VOLUME_CTRL: s.append("implements control"); break; case EFFECT_FLAG_VOLUME_IND: s.append("requires indication"); break; case EFFECT_FLAG_VOLUME_MONITOR: s.append("monitors volume"); break; default: s.append("unknown/reserved"); break; } s.append(", "); uint32_t devind = flags & EFFECT_FLAG_DEVICE_MASK; if (devind) { s.append("device indication: "); switch (devind) { case EFFECT_FLAG_DEVICE_IND: s.append("requires updates"); break; default: s.append("unknown/reserved"); break; } s.append(", "); } s.append("input mode: "); switch (flags & EFFECT_FLAG_INPUT_MASK) { case EFFECT_FLAG_INPUT_DIRECT: s.append("direct"); break; case EFFECT_FLAG_INPUT_PROVIDER: s.append("provider"); break; case EFFECT_FLAG_INPUT_BOTH: s.append("direct+provider"); break; default: s.append("not set"); break; } s.append(", "); s.append("output mode: "); switch (flags & EFFECT_FLAG_OUTPUT_MASK) { case EFFECT_FLAG_OUTPUT_DIRECT: s.append("direct"); break; case EFFECT_FLAG_OUTPUT_PROVIDER: s.append("provider"); break; case EFFECT_FLAG_OUTPUT_BOTH: s.append("direct+provider"); break; default: s.append("not set"); break; } s.append(", "); uint32_t accel = flags & EFFECT_FLAG_HW_ACC_MASK; if (accel) { s.append("hardware acceleration: "); switch (accel) { case EFFECT_FLAG_HW_ACC_SIMPLE: s.append("non-tunneled"); break; case EFFECT_FLAG_HW_ACC_TUNNEL: s.append("tunneled"); break; default: s.append("unknown/reserved"); break; } s.append(", "); } uint32_t modeind = flags & EFFECT_FLAG_AUDIO_MODE_MASK; if (modeind) { s.append("mode indication: "); switch (modeind) { case EFFECT_FLAG_AUDIO_MODE_IND: s.append("required"); break; default: s.append("unknown/reserved"); break; } s.append(", "); } uint32_t srcind = flags & EFFECT_FLAG_AUDIO_SOURCE_MASK; if (srcind) { s.append("source indication: "); switch (srcind) { case EFFECT_FLAG_AUDIO_SOURCE_IND: s.append("required"); break; default: s.append("unknown/reserved"); break; } s.append(", "); } if (flags & EFFECT_FLAG_OFFLOAD_MASK) { s.append("offloadable, "); } int len = s.length(); if (s.length() > 2) { (void) s.lockBuffer(len); s.unlockBuffer(len - 2); } return s; } void AudioFlinger::EffectBase::dump(int fd, const Vector& args __unused) { String8 result; result.appendFormat("\tEffect ID %d:\n", mId); bool locked = AudioFlinger::dumpTryLock(mLock); // failed to lock - AudioFlinger is probably deadlocked if (!locked) { result.append("\t\tCould not lock Fx mutex:\n"); } result.append("\t\tSession State Registered Enabled Suspended:\n"); result.appendFormat("\t\t%05d %03d %s %s %s\n", mSessionId, mState, mPolicyRegistered ? "y" : "n", mPolicyEnabled ? "y" : "n", mSuspended ? "y" : "n"); result.append("\t\tDescriptor:\n"); char uuidStr[64]; AudioEffect::guidToString(&mDescriptor.uuid, uuidStr, sizeof(uuidStr)); result.appendFormat("\t\t- UUID: %s\n", uuidStr); AudioEffect::guidToString(&mDescriptor.type, uuidStr, sizeof(uuidStr)); result.appendFormat("\t\t- TYPE: %s\n", uuidStr); result.appendFormat("\t\t- apiVersion: %08X\n\t\t- flags: %08X (%s)\n", mDescriptor.apiVersion, mDescriptor.flags, effectFlagsToString(mDescriptor.flags).string()); result.appendFormat("\t\t- name: %s\n", mDescriptor.name); result.appendFormat("\t\t- implementor: %s\n", mDescriptor.implementor); result.appendFormat("\t\t%zu Clients:\n", mHandles.size()); result.append("\t\t\t Pid Priority Ctrl Locked client server\n"); char buffer[256]; for (size_t i = 0; i < mHandles.size(); ++i) { EffectHandle *handle = mHandles[i]; if (handle != NULL && !handle->disconnected()) { handle->dumpToBuffer(buffer, sizeof(buffer)); result.append(buffer); } } if (locked) { mLock.unlock(); } write(fd, result.string(), result.length()); } // ---------------------------------------------------------------------------- // EffectModule implementation // ---------------------------------------------------------------------------- #undef LOG_TAG #define LOG_TAG "AudioFlinger::EffectModule" AudioFlinger::EffectModule::EffectModule(const sp& callback, effect_descriptor_t *desc, int id, audio_session_t sessionId, bool pinned, audio_port_handle_t deviceId) : EffectBase(callback, desc, id, sessionId, pinned), // clear mConfig to ensure consistent initial value of buffer framecount // in case buffers are associated by setInBuffer() or setOutBuffer() // prior to configure(). mConfig{{}, {}}, mStatus(NO_INIT), mMaxDisableWaitCnt(1), // set by configure(), should be >= 1 mDisableWaitCnt(0), // set by process() and updateState() mOffloaded(false), mAddedToHal(false) #ifdef FLOAT_EFFECT_CHAIN , mSupportsFloat(false) #endif { ALOGV("Constructor %p pinned %d", this, pinned); int lStatus; // create effect engine from effect factory mStatus = callback->createEffectHal( &desc->uuid, sessionId, deviceId, &mEffectInterface); if (mStatus != NO_ERROR) { return; } lStatus = init(); if (lStatus < 0) { mStatus = lStatus; goto Error; } setOffloaded(callback->isOffload(), callback->io()); ALOGV("Constructor success name %s, Interface %p", mDescriptor.name, mEffectInterface.get()); return; Error: mEffectInterface.clear(); ALOGV("Constructor Error %d", mStatus); } AudioFlinger::EffectModule::~EffectModule() { ALOGV("Destructor %p", this); if (mEffectInterface != 0) { char uuidStr[64]; AudioEffect::guidToString(&mDescriptor.uuid, uuidStr, sizeof(uuidStr)); ALOGW("EffectModule %p destructor called with unreleased interface, effect %s", this, uuidStr); release_l(); } } bool AudioFlinger::EffectModule::updateState() { Mutex::Autolock _l(mLock); bool started = false; switch (mState) { case RESTART: reset_l(); FALLTHROUGH_INTENDED; case STARTING: // clear auxiliary effect input buffer for next accumulation if ((mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY) { memset(mConfig.inputCfg.buffer.raw, 0, mConfig.inputCfg.buffer.frameCount*sizeof(int32_t)); } if (start_l() == NO_ERROR) { mState = ACTIVE; started = true; } else { mState = IDLE; } break; case STOPPING: // volume control for offload and direct threads must take effect immediately. if (stop_l() == NO_ERROR && !(isVolumeControl() && isOffloadedOrDirect())) { mDisableWaitCnt = mMaxDisableWaitCnt; } else { mDisableWaitCnt = 1; // will cause immediate transition to IDLE } mState = STOPPED; break; case STOPPED: // mDisableWaitCnt is forced to 1 by process() when the engine indicates the end of the // turn off sequence. if (--mDisableWaitCnt == 0) { reset_l(); mState = IDLE; } break; default: //IDLE , ACTIVE, DESTROYED break; } return started; } void AudioFlinger::EffectModule::process() { Mutex::Autolock _l(mLock); if (mState == DESTROYED || mEffectInterface == 0 || mInBuffer == 0 || mOutBuffer == 0) { return; } const uint32_t inChannelCount = audio_channel_count_from_out_mask(mConfig.inputCfg.channels); const uint32_t outChannelCount = audio_channel_count_from_out_mask(mConfig.outputCfg.channels); const bool auxType = (mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY; // safeInputOutputSampleCount is 0 if the channel count between input and output // buffers do not match. This prevents automatic accumulation or copying between the // input and output effect buffers without an intermediary effect process. // TODO: consider implementing channel conversion. const size_t safeInputOutputSampleCount = mInChannelCountRequested != mOutChannelCountRequested ? 0 : mOutChannelCountRequested * std::min( mConfig.inputCfg.buffer.frameCount, mConfig.outputCfg.buffer.frameCount); const auto accumulateInputToOutput = [this, safeInputOutputSampleCount]() { #ifdef FLOAT_EFFECT_CHAIN accumulate_float( mConfig.outputCfg.buffer.f32, mConfig.inputCfg.buffer.f32, safeInputOutputSampleCount); #else accumulate_i16( mConfig.outputCfg.buffer.s16, mConfig.inputCfg.buffer.s16, safeInputOutputSampleCount); #endif }; const auto copyInputToOutput = [this, safeInputOutputSampleCount]() { #ifdef FLOAT_EFFECT_CHAIN memcpy( mConfig.outputCfg.buffer.f32, mConfig.inputCfg.buffer.f32, safeInputOutputSampleCount * sizeof(*mConfig.outputCfg.buffer.f32)); #else memcpy( mConfig.outputCfg.buffer.s16, mConfig.inputCfg.buffer.s16, safeInputOutputSampleCount * sizeof(*mConfig.outputCfg.buffer.s16)); #endif }; if (isProcessEnabled()) { int ret; if (isProcessImplemented()) { if (auxType) { // We overwrite the aux input buffer here and clear after processing. // aux input is always mono. #ifdef FLOAT_EFFECT_CHAIN if (mSupportsFloat) { #ifndef FLOAT_AUX // Do in-place float conversion for auxiliary effect input buffer. static_assert(sizeof(float) <= sizeof(int32_t), "in-place conversion requires sizeof(float) <= sizeof(int32_t)"); memcpy_to_float_from_q4_27( mConfig.inputCfg.buffer.f32, mConfig.inputCfg.buffer.s32, mConfig.inputCfg.buffer.frameCount); #endif // !FLOAT_AUX } else #endif // FLOAT_EFFECT_CHAIN { #ifdef FLOAT_AUX memcpy_to_i16_from_float( mConfig.inputCfg.buffer.s16, mConfig.inputCfg.buffer.f32, mConfig.inputCfg.buffer.frameCount); #else memcpy_to_i16_from_q4_27( mConfig.inputCfg.buffer.s16, mConfig.inputCfg.buffer.s32, mConfig.inputCfg.buffer.frameCount); #endif } } #ifdef FLOAT_EFFECT_CHAIN sp inBuffer = mInBuffer; sp outBuffer = mOutBuffer; if (!auxType && mInChannelCountRequested != inChannelCount) { adjust_channels( inBuffer->audioBuffer()->f32, mInChannelCountRequested, mInConversionBuffer->audioBuffer()->f32, inChannelCount, sizeof(float), sizeof(float) * mInChannelCountRequested * mConfig.inputCfg.buffer.frameCount); inBuffer = mInConversionBuffer; } if (mConfig.outputCfg.accessMode == EFFECT_BUFFER_ACCESS_ACCUMULATE && mOutChannelCountRequested != outChannelCount) { adjust_selected_channels( outBuffer->audioBuffer()->f32, mOutChannelCountRequested, mOutConversionBuffer->audioBuffer()->f32, outChannelCount, sizeof(float), sizeof(float) * mOutChannelCountRequested * mConfig.outputCfg.buffer.frameCount); outBuffer = mOutConversionBuffer; } if (!mSupportsFloat) { // convert input to int16_t as effect doesn't support float. if (!auxType) { if (mInConversionBuffer == nullptr) { ALOGW("%s: mInConversionBuffer is null, bypassing", __func__); goto data_bypass; } memcpy_to_i16_from_float( mInConversionBuffer->audioBuffer()->s16, inBuffer->audioBuffer()->f32, inChannelCount * mConfig.inputCfg.buffer.frameCount); inBuffer = mInConversionBuffer; } if (mConfig.outputCfg.accessMode == EFFECT_BUFFER_ACCESS_ACCUMULATE) { if (mOutConversionBuffer == nullptr) { ALOGW("%s: mOutConversionBuffer is null, bypassing", __func__); goto data_bypass; } memcpy_to_i16_from_float( mOutConversionBuffer->audioBuffer()->s16, outBuffer->audioBuffer()->f32, outChannelCount * mConfig.outputCfg.buffer.frameCount); outBuffer = mOutConversionBuffer; } } #endif ret = mEffectInterface->process(); #ifdef FLOAT_EFFECT_CHAIN if (!mSupportsFloat) { // convert output int16_t back to float. sp target = mOutChannelCountRequested != outChannelCount ? mOutConversionBuffer : mOutBuffer; memcpy_to_float_from_i16( target->audioBuffer()->f32, mOutConversionBuffer->audioBuffer()->s16, outChannelCount * mConfig.outputCfg.buffer.frameCount); } if (mOutChannelCountRequested != outChannelCount) { adjust_selected_channels(mOutConversionBuffer->audioBuffer()->f32, outChannelCount, mOutBuffer->audioBuffer()->f32, mOutChannelCountRequested, sizeof(float), sizeof(float) * outChannelCount * mConfig.outputCfg.buffer.frameCount); } #endif } else { #ifdef FLOAT_EFFECT_CHAIN data_bypass: #endif if (!auxType /* aux effects do not require data bypass */ && mConfig.inputCfg.buffer.raw != mConfig.outputCfg.buffer.raw) { if (mConfig.outputCfg.accessMode == EFFECT_BUFFER_ACCESS_ACCUMULATE) { accumulateInputToOutput(); } else { copyInputToOutput(); } } ret = -ENODATA; } // force transition to IDLE state when engine is ready if (mState == STOPPED && ret == -ENODATA) { mDisableWaitCnt = 1; } // clear auxiliary effect input buffer for next accumulation if (auxType) { #ifdef FLOAT_AUX const size_t size = mConfig.inputCfg.buffer.frameCount * inChannelCount * sizeof(float); #else const size_t size = mConfig.inputCfg.buffer.frameCount * inChannelCount * sizeof(int32_t); #endif memset(mConfig.inputCfg.buffer.raw, 0, size); } } else if ((mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_INSERT && // mInBuffer->audioBuffer()->raw != mOutBuffer->audioBuffer()->raw mConfig.inputCfg.buffer.raw != mConfig.outputCfg.buffer.raw) { // If an insert effect is idle and input buffer is different from output buffer, // accumulate input onto output if (getCallback()->activeTrackCnt() != 0) { // similar handling with data_bypass above. if (mConfig.outputCfg.accessMode == EFFECT_BUFFER_ACCESS_ACCUMULATE) { accumulateInputToOutput(); } else { // EFFECT_BUFFER_ACCESS_WRITE copyInputToOutput(); } } } } void AudioFlinger::EffectModule::reset_l() { if (mStatus != NO_ERROR || mEffectInterface == 0) { return; } mEffectInterface->command(EFFECT_CMD_RESET, 0, NULL, 0, NULL); } status_t AudioFlinger::EffectModule::configure() { ALOGVV("configure() started"); status_t status; uint32_t size; audio_channel_mask_t channelMask; sp callback; if (mEffectInterface == 0) { status = NO_INIT; goto exit; } // TODO: handle configuration of effects replacing track process // TODO: handle configuration of input (record) SW effects above the HAL, // similar to output EFFECT_FLAG_TYPE_INSERT/REPLACE, // in which case input channel masks should be used here. callback = getCallback(); channelMask = callback->channelMask(); mConfig.inputCfg.channels = channelMask; mConfig.outputCfg.channels = channelMask; if ((mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY) { if (mConfig.inputCfg.channels != AUDIO_CHANNEL_OUT_MONO) { mConfig.inputCfg.channels = AUDIO_CHANNEL_OUT_MONO; ALOGV("Overriding auxiliary effect input channels %#x as MONO", mConfig.inputCfg.channels); } #ifndef MULTICHANNEL_EFFECT_CHAIN if (mConfig.outputCfg.channels != AUDIO_CHANNEL_OUT_STEREO) { mConfig.outputCfg.channels = AUDIO_CHANNEL_OUT_STEREO; ALOGV("Overriding auxiliary effect output channels %#x as STEREO", mConfig.outputCfg.channels); } #endif } else { #ifndef MULTICHANNEL_EFFECT_CHAIN // TODO: Update this logic when multichannel effects are implemented. // For offloaded tracks consider mono output as stereo for proper effect initialization if (channelMask == AUDIO_CHANNEL_OUT_MONO) { mConfig.inputCfg.channels = AUDIO_CHANNEL_OUT_STEREO; mConfig.outputCfg.channels = AUDIO_CHANNEL_OUT_STEREO; ALOGV("Overriding effect input and output as STEREO"); } #endif } if (isHapticGenerator()) { audio_channel_mask_t hapticChannelMask = callback->hapticChannelMask(); mConfig.inputCfg.channels |= hapticChannelMask; mConfig.outputCfg.channels |= hapticChannelMask; } mInChannelCountRequested = audio_channel_count_from_out_mask(mConfig.inputCfg.channels); mOutChannelCountRequested = audio_channel_count_from_out_mask(mConfig.outputCfg.channels); mConfig.inputCfg.format = EFFECT_BUFFER_FORMAT; mConfig.outputCfg.format = EFFECT_BUFFER_FORMAT; // Don't use sample rate for thread if effect isn't offloadable. if (callback->isOffloadOrDirect() && !isOffloaded()) { mConfig.inputCfg.samplingRate = DEFAULT_OUTPUT_SAMPLE_RATE; ALOGV("Overriding effect input as 48kHz"); } else { mConfig.inputCfg.samplingRate = callback->sampleRate(); } mConfig.outputCfg.samplingRate = mConfig.inputCfg.samplingRate; mConfig.inputCfg.bufferProvider.cookie = NULL; mConfig.inputCfg.bufferProvider.getBuffer = NULL; mConfig.inputCfg.bufferProvider.releaseBuffer = NULL; mConfig.outputCfg.bufferProvider.cookie = NULL; mConfig.outputCfg.bufferProvider.getBuffer = NULL; mConfig.outputCfg.bufferProvider.releaseBuffer = NULL; mConfig.inputCfg.accessMode = EFFECT_BUFFER_ACCESS_READ; // Insert effect: // - in global sessions (e.g AUDIO_SESSION_OUTPUT_MIX), // always overwrites output buffer: input buffer == output buffer // - in other sessions: // last effect in the chain accumulates in output buffer: input buffer != output buffer // other effect: overwrites output buffer: input buffer == output buffer // Auxiliary effect: // accumulates in output buffer: input buffer != output buffer // Therefore: accumulate <=> input buffer != output buffer if (mConfig.inputCfg.buffer.raw != mConfig.outputCfg.buffer.raw) { mConfig.outputCfg.accessMode = EFFECT_BUFFER_ACCESS_ACCUMULATE; } else { mConfig.outputCfg.accessMode = EFFECT_BUFFER_ACCESS_WRITE; } mConfig.inputCfg.mask = EFFECT_CONFIG_ALL; mConfig.outputCfg.mask = EFFECT_CONFIG_ALL; mConfig.inputCfg.buffer.frameCount = callback->frameCount(); mConfig.outputCfg.buffer.frameCount = mConfig.inputCfg.buffer.frameCount; ALOGV("configure() %p chain %p buffer %p framecount %zu", this, callback->chain().promote().get(), mConfig.inputCfg.buffer.raw, mConfig.inputCfg.buffer.frameCount); status_t cmdStatus; size = sizeof(int); status = mEffectInterface->command(EFFECT_CMD_SET_CONFIG, sizeof(mConfig), &mConfig, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } #ifdef MULTICHANNEL_EFFECT_CHAIN if (status != NO_ERROR && callback->isOutput() && (mConfig.inputCfg.channels != AUDIO_CHANNEL_OUT_STEREO || mConfig.outputCfg.channels != AUDIO_CHANNEL_OUT_STEREO)) { // Older effects may require exact STEREO position mask. if (mConfig.inputCfg.channels != AUDIO_CHANNEL_OUT_STEREO && (mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) != EFFECT_FLAG_TYPE_AUXILIARY) { ALOGV("Overriding effect input channels %#x as STEREO", mConfig.inputCfg.channels); mConfig.inputCfg.channels = AUDIO_CHANNEL_OUT_STEREO; } if (mConfig.outputCfg.channels != AUDIO_CHANNEL_OUT_STEREO) { ALOGV("Overriding effect output channels %#x as STEREO", mConfig.outputCfg.channels); mConfig.outputCfg.channels = AUDIO_CHANNEL_OUT_STEREO; } size = sizeof(int); status = mEffectInterface->command(EFFECT_CMD_SET_CONFIG, sizeof(mConfig), &mConfig, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } } #endif #ifdef FLOAT_EFFECT_CHAIN if (status == NO_ERROR) { mSupportsFloat = true; } if (status != NO_ERROR) { ALOGV("EFFECT_CMD_SET_CONFIG failed with float format, retry with int16_t."); mConfig.inputCfg.format = AUDIO_FORMAT_PCM_16_BIT; mConfig.outputCfg.format = AUDIO_FORMAT_PCM_16_BIT; size = sizeof(int); status = mEffectInterface->command(EFFECT_CMD_SET_CONFIG, sizeof(mConfig), &mConfig, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } if (status == NO_ERROR) { mSupportsFloat = false; ALOGVV("config worked with 16 bit"); } else { ALOGE("%s failed %d with int16_t (as well as float)", __func__, status); } } #endif if (status == NO_ERROR) { // Establish Buffer strategy setInBuffer(mInBuffer); setOutBuffer(mOutBuffer); // Update visualizer latency if (memcmp(&mDescriptor.type, SL_IID_VISUALIZATION, sizeof(effect_uuid_t)) == 0) { uint32_t buf32[sizeof(effect_param_t) / sizeof(uint32_t) + 2]; effect_param_t *p = (effect_param_t *)buf32; p->psize = sizeof(uint32_t); p->vsize = sizeof(uint32_t); size = sizeof(int); *(int32_t *)p->data = VISUALIZER_PARAM_LATENCY; uint32_t latency = callback->latency(); *((int32_t *)p->data + 1)= latency; mEffectInterface->command(EFFECT_CMD_SET_PARAM, sizeof(effect_param_t) + 8, &buf32, &size, &cmdStatus); } } // mConfig.outputCfg.buffer.frameCount cannot be zero. mMaxDisableWaitCnt = (uint32_t)std::max( (uint64_t)1, // mMaxDisableWaitCnt must be greater than zero. (uint64_t)MAX_DISABLE_TIME_MS * mConfig.outputCfg.samplingRate / ((uint64_t)1000 * mConfig.outputCfg.buffer.frameCount)); exit: // TODO: consider clearing mConfig on error. mStatus = status; ALOGVV("configure ended"); return status; } status_t AudioFlinger::EffectModule::init() { Mutex::Autolock _l(mLock); if (mEffectInterface == 0) { return NO_INIT; } status_t cmdStatus; uint32_t size = sizeof(status_t); status_t status = mEffectInterface->command(EFFECT_CMD_INIT, 0, NULL, &size, &cmdStatus); if (status == 0) { status = cmdStatus; } return status; } void AudioFlinger::EffectModule::addEffectToHal_l() { if ((mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_PRE_PROC || (mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_POST_PROC) { if (mAddedToHal) { return; } (void)getCallback()->addEffectToHal(mEffectInterface); mAddedToHal = true; } } // start() must be called with PlaybackThread::mLock or EffectChain::mLock held status_t AudioFlinger::EffectModule::start() { status_t status; { Mutex::Autolock _l(mLock); status = start_l(); } if (status == NO_ERROR) { getCallback()->resetVolume(); } return status; } status_t AudioFlinger::EffectModule::start_l() { if (mEffectInterface == 0) { return NO_INIT; } if (mStatus != NO_ERROR) { return mStatus; } status_t cmdStatus; uint32_t size = sizeof(status_t); status_t status = mEffectInterface->command(EFFECT_CMD_ENABLE, 0, NULL, &size, &cmdStatus); if (status == 0) { status = cmdStatus; } if (status == 0) { addEffectToHal_l(); } return status; } status_t AudioFlinger::EffectModule::stop() { Mutex::Autolock _l(mLock); return stop_l(); } status_t AudioFlinger::EffectModule::stop_l() { if (mEffectInterface == 0) { return NO_INIT; } if (mStatus != NO_ERROR) { return mStatus; } status_t cmdStatus = NO_ERROR; uint32_t size = sizeof(status_t); if (isVolumeControl() && isOffloadedOrDirect()) { // We have the EffectChain and EffectModule lock, permit a reentrant call to setVolume: // resetVolume_l --> setVolume_l --> EffectModule::setVolume mSetVolumeReentrantTid = gettid(); getCallback()->resetVolume(); mSetVolumeReentrantTid = INVALID_PID; } status_t status = mEffectInterface->command(EFFECT_CMD_DISABLE, 0, NULL, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } if (status == NO_ERROR) { status = removeEffectFromHal_l(); } return status; } // must be called with EffectChain::mLock held void AudioFlinger::EffectModule::release_l() { if (mEffectInterface != 0) { removeEffectFromHal_l(); // release effect engine mEffectInterface->close(); mEffectInterface.clear(); } } status_t AudioFlinger::EffectModule::removeEffectFromHal_l() { if ((mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_PRE_PROC || (mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_POST_PROC) { if (!mAddedToHal) { return NO_ERROR; } getCallback()->removeEffectFromHal(mEffectInterface); mAddedToHal = false; } return NO_ERROR; } // round up delta valid if value and divisor are positive. template static T roundUpDelta(const T &value, const T &divisor) { T remainder = value % divisor; return remainder == 0 ? 0 : divisor - remainder; } status_t AudioFlinger::EffectModule::command(int32_t cmdCode, const std::vector& cmdData, int32_t maxReplySize, std::vector* reply) { Mutex::Autolock _l(mLock); ALOGVV("command(), cmdCode: %d, mEffectInterface: %p", cmdCode, mEffectInterface.get()); if (mState == DESTROYED || mEffectInterface == 0) { return NO_INIT; } if (mStatus != NO_ERROR) { return mStatus; } if (maxReplySize < 0 || maxReplySize > EFFECT_PARAM_SIZE_MAX) { return -EINVAL; } size_t cmdSize = cmdData.size(); const effect_param_t* param = cmdSize >= sizeof(effect_param_t) ? reinterpret_cast(cmdData.data()) : nullptr; if (cmdCode == EFFECT_CMD_GET_PARAM && (param == nullptr || param->psize > cmdSize - sizeof(effect_param_t))) { android_errorWriteLog(0x534e4554, "32438594"); android_errorWriteLog(0x534e4554, "33003822"); return -EINVAL; } if (cmdCode == EFFECT_CMD_GET_PARAM && (maxReplySize < sizeof(effect_param_t) || param->psize > maxReplySize - sizeof(effect_param_t))) { android_errorWriteLog(0x534e4554, "29251553"); return -EINVAL; } if (cmdCode == EFFECT_CMD_GET_PARAM && (sizeof(effect_param_t) > maxReplySize || param->psize > maxReplySize - sizeof(effect_param_t) || param->vsize > maxReplySize - sizeof(effect_param_t) - param->psize || roundUpDelta(param->psize, (uint32_t) sizeof(int)) > maxReplySize - sizeof(effect_param_t) - param->psize - param->vsize)) { ALOGV("\tLVM_ERROR : EFFECT_CMD_GET_PARAM: reply size inconsistent"); android_errorWriteLog(0x534e4554, "32705438"); return -EINVAL; } if ((cmdCode == EFFECT_CMD_SET_PARAM || cmdCode == EFFECT_CMD_SET_PARAM_DEFERRED) && // DEFERRED not generally used (param == nullptr || param->psize > cmdSize - sizeof(effect_param_t) || param->vsize > cmdSize - sizeof(effect_param_t) - param->psize || roundUpDelta(param->psize, (uint32_t) sizeof(int)) > cmdSize - sizeof(effect_param_t) - param->psize - param->vsize)) { android_errorWriteLog(0x534e4554, "30204301"); return -EINVAL; } uint32_t replySize = maxReplySize; reply->resize(replySize); status_t status = mEffectInterface->command(cmdCode, cmdSize, const_cast(cmdData.data()), &replySize, reply->data()); reply->resize(status == NO_ERROR ? replySize : 0); if (cmdCode != EFFECT_CMD_GET_PARAM && status == NO_ERROR) { for (size_t i = 1; i < mHandles.size(); i++) { EffectHandle *h = mHandles[i]; if (h != NULL && !h->disconnected()) { h->commandExecuted(cmdCode, cmdData, *reply); } } } return status; } bool AudioFlinger::EffectModule::isProcessEnabled() const { if (mStatus != NO_ERROR) { return false; } switch (mState) { case RESTART: case ACTIVE: case STOPPING: case STOPPED: return true; case IDLE: case STARTING: case DESTROYED: default: return false; } } bool AudioFlinger::EffectModule::isOffloadedOrDirect() const { return getCallback()->isOffloadOrDirect(); } bool AudioFlinger::EffectModule::isVolumeControlEnabled() const { return (isVolumeControl() && (isOffloadedOrDirect() ? isEnabled() : isProcessEnabled())); } void AudioFlinger::EffectModule::setInBuffer(const sp& buffer) { ALOGVV("setInBuffer %p",(&buffer)); // mConfig.inputCfg.buffer.frameCount may be zero if configure() is not called yet. if (buffer != 0) { mConfig.inputCfg.buffer.raw = buffer->audioBuffer()->raw; buffer->setFrameCount(mConfig.inputCfg.buffer.frameCount); } else { mConfig.inputCfg.buffer.raw = NULL; } mInBuffer = buffer; mEffectInterface->setInBuffer(buffer); #ifdef FLOAT_EFFECT_CHAIN // aux effects do in place conversion to float - we don't allocate mInConversionBuffer. // Theoretically insert effects can also do in-place conversions (destroying // the original buffer) when the output buffer is identical to the input buffer, // but we don't optimize for it here. const bool auxType = (mDescriptor.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY; const uint32_t inChannelCount = audio_channel_count_from_out_mask(mConfig.inputCfg.channels); const bool formatMismatch = !mSupportsFloat || mInChannelCountRequested != inChannelCount; if (!auxType && formatMismatch && mInBuffer != nullptr) { // we need to translate - create hidl shared buffer and intercept const size_t inFrameCount = mConfig.inputCfg.buffer.frameCount; // Use FCC_2 in case mInChannelCountRequested is mono and the effect is stereo. const uint32_t inChannels = std::max((uint32_t)FCC_2, mInChannelCountRequested); const size_t size = inChannels * inFrameCount * std::max(sizeof(int16_t), sizeof(float)); ALOGV("%s: setInBuffer updating for inChannels:%d inFrameCount:%zu total size:%zu", __func__, inChannels, inFrameCount, size); if (size > 0 && (mInConversionBuffer == nullptr || size > mInConversionBuffer->getSize())) { mInConversionBuffer.clear(); ALOGV("%s: allocating mInConversionBuffer %zu", __func__, size); (void)getCallback()->allocateHalBuffer(size, &mInConversionBuffer); } if (mInConversionBuffer != nullptr) { mInConversionBuffer->setFrameCount(inFrameCount); mEffectInterface->setInBuffer(mInConversionBuffer); } else if (size > 0) { ALOGE("%s cannot create mInConversionBuffer", __func__); } } #endif } void AudioFlinger::EffectModule::setOutBuffer(const sp& buffer) { ALOGVV("setOutBuffer %p",(&buffer)); // mConfig.outputCfg.buffer.frameCount may be zero if configure() is not called yet. if (buffer != 0) { mConfig.outputCfg.buffer.raw = buffer->audioBuffer()->raw; buffer->setFrameCount(mConfig.outputCfg.buffer.frameCount); } else { mConfig.outputCfg.buffer.raw = NULL; } mOutBuffer = buffer; mEffectInterface->setOutBuffer(buffer); #ifdef FLOAT_EFFECT_CHAIN // Note: Any effect that does not accumulate does not need mOutConversionBuffer and // can do in-place conversion from int16_t to float. We don't optimize here. const uint32_t outChannelCount = audio_channel_count_from_out_mask(mConfig.outputCfg.channels); const bool formatMismatch = !mSupportsFloat || mOutChannelCountRequested != outChannelCount; if (formatMismatch && mOutBuffer != nullptr) { const size_t outFrameCount = mConfig.outputCfg.buffer.frameCount; // Use FCC_2 in case mOutChannelCountRequested is mono and the effect is stereo. const uint32_t outChannels = std::max((uint32_t)FCC_2, mOutChannelCountRequested); const size_t size = outChannels * outFrameCount * std::max(sizeof(int16_t), sizeof(float)); ALOGV("%s: setOutBuffer updating for outChannels:%d outFrameCount:%zu total size:%zu", __func__, outChannels, outFrameCount, size); if (size > 0 && (mOutConversionBuffer == nullptr || size > mOutConversionBuffer->getSize())) { mOutConversionBuffer.clear(); ALOGV("%s: allocating mOutConversionBuffer %zu", __func__, size); (void)getCallback()->allocateHalBuffer(size, &mOutConversionBuffer); } if (mOutConversionBuffer != nullptr) { mOutConversionBuffer->setFrameCount(outFrameCount); mEffectInterface->setOutBuffer(mOutConversionBuffer); } else if (size > 0) { ALOGE("%s cannot create mOutConversionBuffer", __func__); } } #endif } status_t AudioFlinger::EffectModule::setVolume(uint32_t *left, uint32_t *right, bool controller) { AutoLockReentrant _l(mLock, mSetVolumeReentrantTid); if (mStatus != NO_ERROR) { return mStatus; } status_t status = NO_ERROR; // Send volume indication if EFFECT_FLAG_VOLUME_IND is set and read back altered volume // if controller flag is set (Note that controller == TRUE => EFFECT_FLAG_VOLUME_CTRL set) if (isProcessEnabled() && ((mDescriptor.flags & EFFECT_FLAG_VOLUME_MASK) == EFFECT_FLAG_VOLUME_CTRL || (mDescriptor.flags & EFFECT_FLAG_VOLUME_MASK) == EFFECT_FLAG_VOLUME_IND || (mDescriptor.flags & EFFECT_FLAG_VOLUME_MASK) == EFFECT_FLAG_VOLUME_MONITOR)) { uint32_t volume[2]; uint32_t *pVolume = NULL; uint32_t size = sizeof(volume); volume[0] = *left; volume[1] = *right; if (controller) { pVolume = volume; } status = mEffectInterface->command(EFFECT_CMD_SET_VOLUME, size, volume, &size, pVolume); if (controller && status == NO_ERROR && size == sizeof(volume)) { *left = volume[0]; *right = volume[1]; } } return status; } void AudioFlinger::EffectChain::setVolumeForOutput_l(uint32_t left, uint32_t right) { // for offload or direct thread, if the effect chain has non-offloadable // effect and any effect module within the chain has volume control, then // volume control is delegated to effect, otherwise, set volume to hal. if (mEffectCallback->isOffloadOrDirect() && !(isNonOffloadableEnabled_l() && hasVolumeControlEnabled_l())) { float vol_l = (float)left / (1 << 24); float vol_r = (float)right / (1 << 24); mEffectCallback->setVolumeForOutput(vol_l, vol_r); } } status_t AudioFlinger::EffectModule::sendSetAudioDevicesCommand( const AudioDeviceTypeAddrVector &devices, uint32_t cmdCode) { audio_devices_t deviceType = deviceTypesToBitMask(getAudioDeviceTypes(devices)); if (deviceType == AUDIO_DEVICE_NONE) { return NO_ERROR; } Mutex::Autolock _l(mLock); if (mStatus != NO_ERROR) { return mStatus; } status_t status = NO_ERROR; if ((mDescriptor.flags & EFFECT_FLAG_DEVICE_MASK) == EFFECT_FLAG_DEVICE_IND) { status_t cmdStatus; uint32_t size = sizeof(status_t); // FIXME: use audio device types and addresses when the hal interface is ready. status = mEffectInterface->command(cmdCode, sizeof(uint32_t), &deviceType, &size, &cmdStatus); } return status; } status_t AudioFlinger::EffectModule::setDevices(const AudioDeviceTypeAddrVector &devices) { return sendSetAudioDevicesCommand(devices, EFFECT_CMD_SET_DEVICE); } status_t AudioFlinger::EffectModule::setInputDevice(const AudioDeviceTypeAddr &device) { return sendSetAudioDevicesCommand({device}, EFFECT_CMD_SET_INPUT_DEVICE); } status_t AudioFlinger::EffectModule::setMode(audio_mode_t mode) { Mutex::Autolock _l(mLock); if (mStatus != NO_ERROR) { return mStatus; } status_t status = NO_ERROR; if ((mDescriptor.flags & EFFECT_FLAG_AUDIO_MODE_MASK) == EFFECT_FLAG_AUDIO_MODE_IND) { status_t cmdStatus; uint32_t size = sizeof(status_t); status = mEffectInterface->command(EFFECT_CMD_SET_AUDIO_MODE, sizeof(audio_mode_t), &mode, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } } return status; } status_t AudioFlinger::EffectModule::setAudioSource(audio_source_t source) { Mutex::Autolock _l(mLock); if (mStatus != NO_ERROR) { return mStatus; } status_t status = NO_ERROR; if ((mDescriptor.flags & EFFECT_FLAG_AUDIO_SOURCE_MASK) == EFFECT_FLAG_AUDIO_SOURCE_IND) { uint32_t size = 0; status = mEffectInterface->command(EFFECT_CMD_SET_AUDIO_SOURCE, sizeof(audio_source_t), &source, &size, NULL); } return status; } status_t AudioFlinger::EffectModule::setOffloaded(bool offloaded, audio_io_handle_t io) { Mutex::Autolock _l(mLock); if (mStatus != NO_ERROR) { return mStatus; } status_t status = NO_ERROR; if ((mDescriptor.flags & EFFECT_FLAG_OFFLOAD_SUPPORTED) != 0) { status_t cmdStatus; uint32_t size = sizeof(status_t); effect_offload_param_t cmd; cmd.isOffload = offloaded; cmd.ioHandle = io; status = mEffectInterface->command(EFFECT_CMD_OFFLOAD, sizeof(effect_offload_param_t), &cmd, &size, &cmdStatus); if (status == NO_ERROR) { status = cmdStatus; } mOffloaded = (status == NO_ERROR) ? offloaded : false; } else { if (offloaded) { status = INVALID_OPERATION; } mOffloaded = false; } ALOGV("setOffloaded() offloaded %d io %d status %d", offloaded, io, status); return status; } bool AudioFlinger::EffectModule::isOffloaded() const { Mutex::Autolock _l(mLock); return mOffloaded; } /*static*/ bool AudioFlinger::EffectModule::isHapticGenerator(const effect_uuid_t *type) { return memcmp(type, FX_IID_HAPTICGENERATOR, sizeof(effect_uuid_t)) == 0; } bool AudioFlinger::EffectModule::isHapticGenerator() const { return isHapticGenerator(&mDescriptor.type); } status_t AudioFlinger::EffectModule::setHapticIntensity(int id, int intensity) { if (mStatus != NO_ERROR) { return mStatus; } if (!isHapticGenerator()) { ALOGW("Should not set haptic intensity for effects that are not HapticGenerator"); return INVALID_OPERATION; } std::vector request(sizeof(effect_param_t) + 3 * sizeof(uint32_t)); effect_param_t *param = (effect_param_t*) request.data(); param->psize = sizeof(int32_t); param->vsize = sizeof(int32_t) * 2; *(int32_t*)param->data = HG_PARAM_HAPTIC_INTENSITY; *((int32_t*)param->data + 1) = id; *((int32_t*)param->data + 2) = intensity; std::vector response; status_t status = command(EFFECT_CMD_SET_PARAM, request, sizeof(int32_t), &response); if (status == NO_ERROR) { LOG_ALWAYS_FATAL_IF(response.size() != 4); status = *reinterpret_cast(response.data()); } return status; } status_t AudioFlinger::EffectModule::setVibratorInfo(const media::AudioVibratorInfo* vibratorInfo) { if (mStatus != NO_ERROR) { return mStatus; } if (!isHapticGenerator()) { ALOGW("Should not set vibrator info for effects that are not HapticGenerator"); return INVALID_OPERATION; } std::vector request( sizeof(effect_param_t) + sizeof(int32_t) + 2 * sizeof(float)); effect_param_t *param = (effect_param_t*) request.data(); param->psize = sizeof(int32_t); param->vsize = 2 * sizeof(float); *(int32_t*)param->data = HG_PARAM_VIBRATOR_INFO; float* vibratorInfoPtr = reinterpret_cast(param->data + sizeof(int32_t)); vibratorInfoPtr[0] = vibratorInfo->resonantFrequency; vibratorInfoPtr[1] = vibratorInfo->qFactor; std::vector response; status_t status = command(EFFECT_CMD_SET_PARAM, request, sizeof(int32_t), &response); if (status == NO_ERROR) { LOG_ALWAYS_FATAL_IF(response.size() != sizeof(status_t)); status = *reinterpret_cast(response.data()); } return status; } static std::string dumpInOutBuffer(bool isInput, const sp &buffer) { std::stringstream ss; if (buffer == nullptr) { return "nullptr"; // make different than below } else if (buffer->externalData() != nullptr) { ss << (isInput ? buffer->externalData() : buffer->audioBuffer()->raw) << " -> " << (isInput ? buffer->audioBuffer()->raw : buffer->externalData()); } else { ss << buffer->audioBuffer()->raw; } return ss.str(); } void AudioFlinger::EffectModule::dump(int fd, const Vector& args) { EffectBase::dump(fd, args); String8 result; bool locked = AudioFlinger::dumpTryLock(mLock); result.append("\t\tStatus Engine:\n"); result.appendFormat("\t\t%03d %p\n", mStatus, mEffectInterface.get()); result.appendFormat("\t\t- data: %s\n", mSupportsFloat ? "float" : "int16"); result.append("\t\t- Input configuration:\n"); result.append("\t\t\tBuffer Frames Smp rate Channels Format\n"); result.appendFormat("\t\t\t%p %05zu %05d %08x %6d (%s)\n", mConfig.inputCfg.buffer.raw, mConfig.inputCfg.buffer.frameCount, mConfig.inputCfg.samplingRate, mConfig.inputCfg.channels, mConfig.inputCfg.format, formatToString((audio_format_t)mConfig.inputCfg.format).c_str()); result.append("\t\t- Output configuration:\n"); result.append("\t\t\tBuffer Frames Smp rate Channels Format\n"); result.appendFormat("\t\t\t%p %05zu %05d %08x %6d (%s)\n", mConfig.outputCfg.buffer.raw, mConfig.outputCfg.buffer.frameCount, mConfig.outputCfg.samplingRate, mConfig.outputCfg.channels, mConfig.outputCfg.format, formatToString((audio_format_t)mConfig.outputCfg.format).c_str()); #ifdef FLOAT_EFFECT_CHAIN result.appendFormat("\t\t- HAL buffers:\n" "\t\t\tIn(%s) InConversion(%s) Out(%s) OutConversion(%s)\n", dumpInOutBuffer(true /* isInput */, mInBuffer).c_str(), dumpInOutBuffer(true /* isInput */, mInConversionBuffer).c_str(), dumpInOutBuffer(false /* isInput */, mOutBuffer).c_str(), dumpInOutBuffer(false /* isInput */, mOutConversionBuffer).c_str()); #endif write(fd, result.string(), result.length()); if (mEffectInterface != 0) { dprintf(fd, "\tEffect ID %d HAL dump:\n", mId); (void)mEffectInterface->dump(fd); } if (locked) { mLock.unlock(); } } // ---------------------------------------------------------------------------- // EffectHandle implementation // ---------------------------------------------------------------------------- #undef LOG_TAG #define LOG_TAG "AudioFlinger::EffectHandle" AudioFlinger::EffectHandle::EffectHandle(const sp& effect, const sp& client, const sp& effectClient, int32_t priority) : BnEffect(), mEffect(effect), mEffectClient(effectClient), mClient(client), mCblk(NULL), mPriority(priority), mHasControl(false), mEnabled(false), mDisconnected(false) { ALOGV("constructor %p client %p", this, client.get()); if (client == 0) { return; } int bufOffset = ((sizeof(effect_param_cblk_t) - 1) / sizeof(int) + 1) * sizeof(int); mCblkMemory = client->heap()->allocate(EFFECT_PARAM_BUFFER_SIZE + bufOffset); if (mCblkMemory == 0 || (mCblk = static_cast(mCblkMemory->unsecurePointer())) == NULL) { ALOGE("not enough memory for Effect size=%zu", EFFECT_PARAM_BUFFER_SIZE + sizeof(effect_param_cblk_t)); mCblkMemory.clear(); return; } new(mCblk) effect_param_cblk_t(); mBuffer = (uint8_t *)mCblk + bufOffset; } AudioFlinger::EffectHandle::~EffectHandle() { ALOGV("Destructor %p", this); disconnect(false); } status_t AudioFlinger::EffectHandle::initCheck() { return mClient == 0 || mCblkMemory != 0 ? OK : NO_MEMORY; } #define RETURN(code) \ *_aidl_return = (code); \ return Status::ok(); Status AudioFlinger::EffectHandle::enable(int32_t* _aidl_return) { AutoMutex _l(mLock); ALOGV("enable %p", this); sp effect = mEffect.promote(); if (effect == 0 || mDisconnected) { RETURN(DEAD_OBJECT); } if (!mHasControl) { RETURN(INVALID_OPERATION); } if (mEnabled) { RETURN(NO_ERROR); } mEnabled = true; status_t status = effect->updatePolicyState(); if (status != NO_ERROR) { mEnabled = false; RETURN(status); } effect->checkSuspendOnEffectEnabled(true, false /*threadLocked*/); // checkSuspendOnEffectEnabled() can suspend this same effect when enabled if (effect->suspended()) { RETURN(NO_ERROR); } status = effect->setEnabled(true, true /*fromHandle*/); if (status != NO_ERROR) { mEnabled = false; } RETURN(status); } Status AudioFlinger::EffectHandle::disable(int32_t* _aidl_return) { ALOGV("disable %p", this); AutoMutex _l(mLock); sp effect = mEffect.promote(); if (effect == 0 || mDisconnected) { RETURN(DEAD_OBJECT); } if (!mHasControl) { RETURN(INVALID_OPERATION); } if (!mEnabled) { RETURN(NO_ERROR); } mEnabled = false; effect->updatePolicyState(); if (effect->suspended()) { RETURN(NO_ERROR); } status_t status = effect->setEnabled(false, true /*fromHandle*/); RETURN(status); } Status AudioFlinger::EffectHandle::disconnect() { ALOGV("%s %p", __FUNCTION__, this); disconnect(true); return Status::ok(); } void AudioFlinger::EffectHandle::disconnect(bool unpinIfLast) { AutoMutex _l(mLock); ALOGV("disconnect(%s) %p", unpinIfLast ? "true" : "false", this); if (mDisconnected) { if (unpinIfLast) { android_errorWriteLog(0x534e4554, "32707507"); } return; } mDisconnected = true; { sp effect = mEffect.promote(); if (effect != 0) { if (effect->disconnectHandle(this, unpinIfLast) > 0) { ALOGW("%s Effect handle %p disconnected after thread destruction", __func__, this); } effect->updatePolicyState(); } } if (mClient != 0) { if (mCblk != NULL) { // unlike ~TrackBase(), mCblk is never a local new, so don't delete mCblk->~effect_param_cblk_t(); // destroy our shared-structure. } mCblkMemory.clear(); // free the shared memory before releasing the heap it belongs to // Client destructor must run with AudioFlinger client mutex locked Mutex::Autolock _l(mClient->audioFlinger()->mClientLock); mClient.clear(); } } Status AudioFlinger::EffectHandle::getCblk(media::SharedFileRegion* _aidl_return) { LOG_ALWAYS_FATAL_IF(!convertIMemoryToSharedFileRegion(mCblkMemory, _aidl_return)); return Status::ok(); } Status AudioFlinger::EffectHandle::command(int32_t cmdCode, const std::vector& cmdData, int32_t maxResponseSize, std::vector* response, int32_t* _aidl_return) { ALOGVV("command(), cmdCode: %d, mHasControl: %d, mEffect: %p", cmdCode, mHasControl, mEffect.unsafe_get()); // reject commands reserved for internal use by audio framework if coming from outside // of audioserver switch(cmdCode) { case EFFECT_CMD_ENABLE: case EFFECT_CMD_DISABLE: case EFFECT_CMD_SET_PARAM: case EFFECT_CMD_SET_PARAM_DEFERRED: case EFFECT_CMD_SET_PARAM_COMMIT: case EFFECT_CMD_GET_PARAM: break; default: if (cmdCode >= EFFECT_CMD_FIRST_PROPRIETARY) { break; } android_errorWriteLog(0x534e4554, "62019992"); RETURN(BAD_VALUE); } if (cmdCode == EFFECT_CMD_ENABLE) { if (maxResponseSize < sizeof(int)) { android_errorWriteLog(0x534e4554, "32095713"); RETURN(BAD_VALUE); } writeToBuffer(NO_ERROR, response); return enable(_aidl_return); } else if (cmdCode == EFFECT_CMD_DISABLE) { if (maxResponseSize < sizeof(int)) { android_errorWriteLog(0x534e4554, "32095713"); RETURN(BAD_VALUE); } writeToBuffer(NO_ERROR, response); return disable(_aidl_return); } AutoMutex _l(mLock); sp effect = mEffect.promote(); if (effect == 0 || mDisconnected) { RETURN(DEAD_OBJECT); } // only get parameter command is permitted for applications not controlling the effect if (!mHasControl && cmdCode != EFFECT_CMD_GET_PARAM) { RETURN(INVALID_OPERATION); } // handle commands that are not forwarded transparently to effect engine if (cmdCode == EFFECT_CMD_SET_PARAM_COMMIT) { if (mClient == 0) { RETURN(INVALID_OPERATION); } if (maxResponseSize < sizeof(int)) { android_errorWriteLog(0x534e4554, "32095713"); RETURN(BAD_VALUE); } writeToBuffer(NO_ERROR, response); // No need to trylock() here as this function is executed in the binder thread serving a // particular client process: no risk to block the whole media server process or mixer // threads if we are stuck here Mutex::Autolock _l(mCblk->lock); // keep local copy of index in case of client corruption b/32220769 const uint32_t clientIndex = mCblk->clientIndex; const uint32_t serverIndex = mCblk->serverIndex; if (clientIndex > EFFECT_PARAM_BUFFER_SIZE || serverIndex > EFFECT_PARAM_BUFFER_SIZE) { mCblk->serverIndex = 0; mCblk->clientIndex = 0; RETURN(BAD_VALUE); } status_t status = NO_ERROR; std::vector param; for (uint32_t index = serverIndex; index < clientIndex;) { int *p = (int *)(mBuffer + index); const int size = *p++; if (size < 0 || size > EFFECT_PARAM_BUFFER_SIZE || ((uint8_t *)p + size) > mBuffer + clientIndex) { ALOGW("command(): invalid parameter block size"); status = BAD_VALUE; break; } std::copy(reinterpret_cast(p), reinterpret_cast(p) + size, std::back_inserter(param)); std::vector replyBuffer; status_t ret = effect->command(EFFECT_CMD_SET_PARAM, param, sizeof(int), &replyBuffer); int reply = *reinterpret_cast(replyBuffer.data()); // verify shared memory: server index shouldn't change; client index can't go back. if (serverIndex != mCblk->serverIndex || clientIndex > mCblk->clientIndex) { android_errorWriteLog(0x534e4554, "32220769"); status = BAD_VALUE; break; } // stop at first error encountered if (ret != NO_ERROR) { status = ret; writeToBuffer(reply, response); break; } else if (reply != NO_ERROR) { writeToBuffer(reply, response); break; } index += size; } mCblk->serverIndex = 0; mCblk->clientIndex = 0; RETURN(status); } status_t status = effect->command(cmdCode, cmdData, maxResponseSize, response); RETURN(status); } void AudioFlinger::EffectHandle::setControl(bool hasControl, bool signal, bool enabled) { ALOGV("setControl %p control %d", this, hasControl); mHasControl = hasControl; mEnabled = enabled; if (signal && mEffectClient != 0) { mEffectClient->controlStatusChanged(hasControl); } } void AudioFlinger::EffectHandle::commandExecuted(uint32_t cmdCode, const std::vector& cmdData, const std::vector& replyData) { if (mEffectClient != 0) { mEffectClient->commandExecuted(cmdCode, cmdData, replyData); } } void AudioFlinger::EffectHandle::setEnabled(bool enabled) { if (mEffectClient != 0) { mEffectClient->enableStatusChanged(enabled); } } void AudioFlinger::EffectHandle::dumpToBuffer(char* buffer, size_t size) { bool locked = mCblk != NULL && AudioFlinger::dumpTryLock(mCblk->lock); snprintf(buffer, size, "\t\t\t%5d %5d %3s %3s %5u %5u\n", (mClient == 0) ? getpid() : mClient->pid(), mPriority, mHasControl ? "yes" : "no", locked ? "yes" : "no", mCblk ? mCblk->clientIndex : 0, mCblk ? mCblk->serverIndex : 0 ); if (locked) { mCblk->lock.unlock(); } } #undef LOG_TAG #define LOG_TAG "AudioFlinger::EffectChain" AudioFlinger::EffectChain::EffectChain(const wp& thread, audio_session_t sessionId) : mSessionId(sessionId), mActiveTrackCnt(0), mTrackCnt(0), mTailBufferCount(0), mVolumeCtrlIdx(-1), mLeftVolume(UINT_MAX), mRightVolume(UINT_MAX), mNewLeftVolume(UINT_MAX), mNewRightVolume(UINT_MAX), mEffectCallback(new EffectCallback(wp(this), thread)) { mStrategy = AudioSystem::getStrategyForStream(AUDIO_STREAM_MUSIC); sp p = thread.promote(); if (p == nullptr) { return; } mMaxTailBuffers = ((kProcessTailDurationMs * p->sampleRate()) / 1000) / p->frameCount(); } AudioFlinger::EffectChain::~EffectChain() { } // getEffectFromDesc_l() must be called with ThreadBase::mLock held sp AudioFlinger::EffectChain::getEffectFromDesc_l( effect_descriptor_t *descriptor) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { if (memcmp(&mEffects[i]->desc().uuid, &descriptor->uuid, sizeof(effect_uuid_t)) == 0) { return mEffects[i]; } } return 0; } // getEffectFromId_l() must be called with ThreadBase::mLock held sp AudioFlinger::EffectChain::getEffectFromId_l(int id) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { // by convention, return first effect if id provided is 0 (0 is never a valid id) if (id == 0 || mEffects[i]->id() == id) { return mEffects[i]; } } return 0; } // getEffectFromType_l() must be called with ThreadBase::mLock held sp AudioFlinger::EffectChain::getEffectFromType_l( const effect_uuid_t *type) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { if (memcmp(&mEffects[i]->desc().type, type, sizeof(effect_uuid_t)) == 0) { return mEffects[i]; } } return 0; } std::vector AudioFlinger::EffectChain::getEffectIds() { std::vector ids; Mutex::Autolock _l(mLock); for (size_t i = 0; i < mEffects.size(); i++) { ids.push_back(mEffects[i]->id()); } return ids; } void AudioFlinger::EffectChain::clearInputBuffer() { Mutex::Autolock _l(mLock); clearInputBuffer_l(); } // Must be called with EffectChain::mLock locked void AudioFlinger::EffectChain::clearInputBuffer_l() { if (mInBuffer == NULL) { return; } const size_t frameSize = audio_bytes_per_sample(EFFECT_BUFFER_FORMAT) * mEffectCallback->channelCount(); memset(mInBuffer->audioBuffer()->raw, 0, mEffectCallback->frameCount() * frameSize); mInBuffer->commit(); } // Must be called with EffectChain::mLock locked void AudioFlinger::EffectChain::process_l() { // never process effects when: // - on an OFFLOAD thread // - no more tracks are on the session and the effect tail has been rendered bool doProcess = !mEffectCallback->isOffloadOrMmap(); if (!audio_is_global_session(mSessionId)) { bool tracksOnSession = (trackCnt() != 0); if (!tracksOnSession && mTailBufferCount == 0) { doProcess = false; } if (activeTrackCnt() == 0) { // if no track is active and the effect tail has not been rendered, // the input buffer must be cleared here as the mixer process will not do it if (tracksOnSession || mTailBufferCount > 0) { clearInputBuffer_l(); if (mTailBufferCount > 0) { mTailBufferCount--; } } } } size_t size = mEffects.size(); if (doProcess) { // Only the input and output buffers of the chain can be external, // and 'update' / 'commit' do nothing for allocated buffers, thus // it's not needed to consider any other buffers here. mInBuffer->update(); if (mInBuffer->audioBuffer()->raw != mOutBuffer->audioBuffer()->raw) { mOutBuffer->update(); } for (size_t i = 0; i < size; i++) { mEffects[i]->process(); } mInBuffer->commit(); if (mInBuffer->audioBuffer()->raw != mOutBuffer->audioBuffer()->raw) { mOutBuffer->commit(); } } bool doResetVolume = false; for (size_t i = 0; i < size; i++) { doResetVolume = mEffects[i]->updateState() || doResetVolume; } if (doResetVolume) { resetVolume_l(); } } // createEffect_l() must be called with ThreadBase::mLock held status_t AudioFlinger::EffectChain::createEffect_l(sp& effect, effect_descriptor_t *desc, int id, audio_session_t sessionId, bool pinned) { Mutex::Autolock _l(mLock); effect = new EffectModule(mEffectCallback, desc, id, sessionId, pinned, AUDIO_PORT_HANDLE_NONE); status_t lStatus = effect->status(); if (lStatus == NO_ERROR) { lStatus = addEffect_ll(effect); } if (lStatus != NO_ERROR) { effect.clear(); } return lStatus; } // addEffect_l() must be called with ThreadBase::mLock held status_t AudioFlinger::EffectChain::addEffect_l(const sp& effect) { Mutex::Autolock _l(mLock); return addEffect_ll(effect); } // addEffect_l() must be called with ThreadBase::mLock and EffectChain::mLock held status_t AudioFlinger::EffectChain::addEffect_ll(const sp& effect) { effect_descriptor_t desc = effect->desc(); uint32_t insertPref = desc.flags & EFFECT_FLAG_INSERT_MASK; effect->setCallback(mEffectCallback); if ((desc.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY) { // Auxiliary effects are inserted at the beginning of mEffects vector as // they are processed first and accumulated in chain input buffer mEffects.insertAt(effect, 0); // the input buffer for auxiliary effect contains mono samples in // 32 bit format. This is to avoid saturation in AudoMixer // accumulation stage. Saturation is done in EffectModule::process() before // calling the process in effect engine size_t numSamples = mEffectCallback->frameCount(); sp halBuffer; #ifdef FLOAT_EFFECT_CHAIN status_t result = mEffectCallback->allocateHalBuffer( numSamples * sizeof(float), &halBuffer); #else status_t result = mEffectCallback->allocateHalBuffer( numSamples * sizeof(int32_t), &halBuffer); #endif if (result != OK) return result; effect->setInBuffer(halBuffer); // auxiliary effects output samples to chain input buffer for further processing // by insert effects effect->setOutBuffer(mInBuffer); } else { // Insert effects are inserted at the end of mEffects vector as they are processed // after track and auxiliary effects. // Insert effect order as a function of indicated preference: // if EFFECT_FLAG_INSERT_EXCLUSIVE, insert in first position or reject if // another effect is present // else if EFFECT_FLAG_INSERT_FIRST, insert in first position or after the // last effect claiming first position // else if EFFECT_FLAG_INSERT_LAST, insert in last position or before the // first effect claiming last position // else if EFFECT_FLAG_INSERT_ANY insert after first or before last // Reject insertion if an effect with EFFECT_FLAG_INSERT_EXCLUSIVE is // already present size_t size = mEffects.size(); size_t idx_insert = size; ssize_t idx_insert_first = -1; ssize_t idx_insert_last = -1; for (size_t i = 0; i < size; i++) { effect_descriptor_t d = mEffects[i]->desc(); uint32_t iMode = d.flags & EFFECT_FLAG_TYPE_MASK; uint32_t iPref = d.flags & EFFECT_FLAG_INSERT_MASK; if (iMode == EFFECT_FLAG_TYPE_INSERT) { // check invalid effect chaining combinations if (insertPref == EFFECT_FLAG_INSERT_EXCLUSIVE || iPref == EFFECT_FLAG_INSERT_EXCLUSIVE) { ALOGW("addEffect_l() could not insert effect %s: exclusive conflict with %s", desc.name, d.name); return INVALID_OPERATION; } // remember position of first insert effect and by default // select this as insert position for new effect if (idx_insert == size) { idx_insert = i; } // remember position of last insert effect claiming // first position if (iPref == EFFECT_FLAG_INSERT_FIRST) { idx_insert_first = i; } // remember position of first insert effect claiming // last position if (iPref == EFFECT_FLAG_INSERT_LAST && idx_insert_last == -1) { idx_insert_last = i; } } } // modify idx_insert from first position if needed if (insertPref == EFFECT_FLAG_INSERT_LAST) { if (idx_insert_last != -1) { idx_insert = idx_insert_last; } else { idx_insert = size; } } else { if (idx_insert_first != -1) { idx_insert = idx_insert_first + 1; } } // always read samples from chain input buffer effect->setInBuffer(mInBuffer); // if last effect in the chain, output samples to chain // output buffer, otherwise to chain input buffer if (idx_insert == size) { if (idx_insert != 0) { mEffects[idx_insert-1]->setOutBuffer(mInBuffer); mEffects[idx_insert-1]->configure(); } effect->setOutBuffer(mOutBuffer); } else { effect->setOutBuffer(mInBuffer); } mEffects.insertAt(effect, idx_insert); ALOGV("addEffect_l() effect %p, added in chain %p at rank %zu", effect.get(), this, idx_insert); } effect->configure(); return NO_ERROR; } // removeEffect_l() must be called with ThreadBase::mLock held size_t AudioFlinger::EffectChain::removeEffect_l(const sp& effect, bool release) { Mutex::Autolock _l(mLock); size_t size = mEffects.size(); uint32_t type = effect->desc().flags & EFFECT_FLAG_TYPE_MASK; for (size_t i = 0; i < size; i++) { if (effect == mEffects[i]) { // calling stop here will remove pre-processing effect from the audio HAL. // This is safe as we hold the EffectChain mutex which guarantees that we are not in // the middle of a read from audio HAL if (mEffects[i]->state() == EffectModule::ACTIVE || mEffects[i]->state() == EffectModule::STOPPING) { mEffects[i]->stop(); } if (release) { mEffects[i]->release_l(); } if (type != EFFECT_FLAG_TYPE_AUXILIARY) { if (i == size - 1 && i != 0) { mEffects[i - 1]->setOutBuffer(mOutBuffer); mEffects[i - 1]->configure(); } } mEffects.removeAt(i); ALOGV("removeEffect_l() effect %p, removed from chain %p at rank %zu", effect.get(), this, i); break; } } return mEffects.size(); } // setDevices_l() must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setDevices_l(const AudioDeviceTypeAddrVector &devices) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { mEffects[i]->setDevices(devices); } } // setInputDevice_l() must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setInputDevice_l(const AudioDeviceTypeAddr &device) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { mEffects[i]->setInputDevice(device); } } // setMode_l() must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setMode_l(audio_mode_t mode) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { mEffects[i]->setMode(mode); } } // setAudioSource_l() must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setAudioSource_l(audio_source_t source) { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { mEffects[i]->setAudioSource(source); } } bool AudioFlinger::EffectChain::hasVolumeControlEnabled_l() const { for (const auto &effect : mEffects) { if (effect->isVolumeControlEnabled()) return true; } return false; } // setVolume_l() must be called with ThreadBase::mLock or EffectChain::mLock held bool AudioFlinger::EffectChain::setVolume_l(uint32_t *left, uint32_t *right, bool force) { uint32_t newLeft = *left; uint32_t newRight = *right; bool hasControl = false; int ctrlIdx = -1; size_t size = mEffects.size(); // first update volume controller for (size_t i = size; i > 0; i--) { if (mEffects[i - 1]->isVolumeControlEnabled()) { ctrlIdx = i - 1; hasControl = true; break; } } if (!force && ctrlIdx == mVolumeCtrlIdx && *left == mLeftVolume && *right == mRightVolume) { if (hasControl) { *left = mNewLeftVolume; *right = mNewRightVolume; } return hasControl; } mVolumeCtrlIdx = ctrlIdx; mLeftVolume = newLeft; mRightVolume = newRight; // second get volume update from volume controller if (ctrlIdx >= 0) { mEffects[ctrlIdx]->setVolume(&newLeft, &newRight, true); mNewLeftVolume = newLeft; mNewRightVolume = newRight; } // then indicate volume to all other effects in chain. // Pass altered volume to effects before volume controller // and requested volume to effects after controller or with volume monitor flag uint32_t lVol = newLeft; uint32_t rVol = newRight; for (size_t i = 0; i < size; i++) { if ((int)i == ctrlIdx) { continue; } // this also works for ctrlIdx == -1 when there is no volume controller if ((int)i > ctrlIdx) { lVol = *left; rVol = *right; } // Pass requested volume directly if this is volume monitor module if (mEffects[i]->isVolumeMonitor()) { mEffects[i]->setVolume(left, right, false); } else { mEffects[i]->setVolume(&lVol, &rVol, false); } } *left = newLeft; *right = newRight; setVolumeForOutput_l(*left, *right); return hasControl; } // resetVolume_l() must be called with ThreadBase::mLock or EffectChain::mLock held void AudioFlinger::EffectChain::resetVolume_l() { if ((mLeftVolume != UINT_MAX) && (mRightVolume != UINT_MAX)) { uint32_t left = mLeftVolume; uint32_t right = mRightVolume; (void)setVolume_l(&left, &right, true); } } // containsHapticGeneratingEffect_l must be called with ThreadBase::mLock or EffectChain::mLock held bool AudioFlinger::EffectChain::containsHapticGeneratingEffect_l() { for (size_t i = 0; i < mEffects.size(); ++i) { if (mEffects[i]->isHapticGenerator()) { return true; } } return false; } void AudioFlinger::EffectChain::setHapticIntensity_l(int id, int intensity) { Mutex::Autolock _l(mLock); for (size_t i = 0; i < mEffects.size(); ++i) { mEffects[i]->setHapticIntensity(id, intensity); } } void AudioFlinger::EffectChain::syncHalEffectsState() { Mutex::Autolock _l(mLock); for (size_t i = 0; i < mEffects.size(); i++) { if (mEffects[i]->state() == EffectModule::ACTIVE || mEffects[i]->state() == EffectModule::STOPPING) { mEffects[i]->addEffectToHal_l(); } } } void AudioFlinger::EffectChain::dump(int fd, const Vector& args) { String8 result; const size_t numEffects = mEffects.size(); result.appendFormat(" %zu effects for session %d\n", numEffects, mSessionId); if (numEffects) { bool locked = AudioFlinger::dumpTryLock(mLock); // failed to lock - AudioFlinger is probably deadlocked if (!locked) { result.append("\tCould not lock mutex:\n"); } const std::string inBufferStr = dumpInOutBuffer(true /* isInput */, mInBuffer); const std::string outBufferStr = dumpInOutBuffer(false /* isInput */, mOutBuffer); result.appendFormat("\t%-*s%-*s Active tracks:\n", (int)inBufferStr.size(), "In buffer ", (int)outBufferStr.size(), "Out buffer "); result.appendFormat("\t%s %s %d\n", inBufferStr.c_str(), outBufferStr.c_str(), mActiveTrackCnt); write(fd, result.string(), result.size()); for (size_t i = 0; i < numEffects; ++i) { sp effect = mEffects[i]; if (effect != 0) { effect->dump(fd, args); } } if (locked) { mLock.unlock(); } } else { write(fd, result.string(), result.size()); } } // must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setEffectSuspended_l( const effect_uuid_t *type, bool suspend) { sp desc; // use effect type UUID timelow as key as there is no real risk of identical // timeLow fields among effect type UUIDs. ssize_t index = mSuspendedEffects.indexOfKey(type->timeLow); if (suspend) { if (index >= 0) { desc = mSuspendedEffects.valueAt(index); } else { desc = new SuspendedEffectDesc(); desc->mType = *type; mSuspendedEffects.add(type->timeLow, desc); ALOGV("setEffectSuspended_l() add entry for %08x", type->timeLow); } if (desc->mRefCount++ == 0) { sp effect = getEffectIfEnabled(type); if (effect != 0) { desc->mEffect = effect; effect->setSuspended(true); effect->setEnabled(false, false /*fromHandle*/); } } } else { if (index < 0) { return; } desc = mSuspendedEffects.valueAt(index); if (desc->mRefCount <= 0) { ALOGW("setEffectSuspended_l() restore refcount should not be 0 %d", desc->mRefCount); desc->mRefCount = 0; return; } if (--desc->mRefCount == 0) { ALOGV("setEffectSuspended_l() remove entry for %08x", mSuspendedEffects.keyAt(index)); if (desc->mEffect != 0) { sp effect = desc->mEffect.promote(); if (effect != 0) { effect->setSuspended(false); effect->lock(); EffectHandle *handle = effect->controlHandle_l(); if (handle != NULL && !handle->disconnected()) { effect->setEnabled_l(handle->enabled()); } effect->unlock(); } desc->mEffect.clear(); } mSuspendedEffects.removeItemsAt(index); } } } // must be called with ThreadBase::mLock held void AudioFlinger::EffectChain::setEffectSuspendedAll_l(bool suspend) { sp desc; ssize_t index = mSuspendedEffects.indexOfKey((int)kKeyForSuspendAll); if (suspend) { if (index >= 0) { desc = mSuspendedEffects.valueAt(index); } else { desc = new SuspendedEffectDesc(); mSuspendedEffects.add((int)kKeyForSuspendAll, desc); ALOGV("setEffectSuspendedAll_l() add entry for 0"); } if (desc->mRefCount++ == 0) { Vector< sp > effects; getSuspendEligibleEffects(effects); for (size_t i = 0; i < effects.size(); i++) { setEffectSuspended_l(&effects[i]->desc().type, true); } } } else { if (index < 0) { return; } desc = mSuspendedEffects.valueAt(index); if (desc->mRefCount <= 0) { ALOGW("setEffectSuspendedAll_l() restore refcount should not be 0 %d", desc->mRefCount); desc->mRefCount = 1; } if (--desc->mRefCount == 0) { Vector types; for (size_t i = 0; i < mSuspendedEffects.size(); i++) { if (mSuspendedEffects.keyAt(i) == (int)kKeyForSuspendAll) { continue; } types.add(&mSuspendedEffects.valueAt(i)->mType); } for (size_t i = 0; i < types.size(); i++) { setEffectSuspended_l(types[i], false); } ALOGV("setEffectSuspendedAll_l() remove entry for %08x", mSuspendedEffects.keyAt(index)); mSuspendedEffects.removeItem((int)kKeyForSuspendAll); } } } // The volume effect is used for automated tests only #ifndef OPENSL_ES_H_ static const effect_uuid_t SL_IID_VOLUME_ = { 0x09e8ede0, 0xddde, 0x11db, 0xb4f6, { 0x00, 0x02, 0xa5, 0xd5, 0xc5, 0x1b } }; const effect_uuid_t * const SL_IID_VOLUME = &SL_IID_VOLUME_; #endif //OPENSL_ES_H_ /* static */ bool AudioFlinger::EffectChain::isEffectEligibleForBtNrecSuspend(const effect_uuid_t *type) { // Only NS and AEC are suspended when BtNRec is off if ((memcmp(type, FX_IID_AEC, sizeof(effect_uuid_t)) == 0) || (memcmp(type, FX_IID_NS, sizeof(effect_uuid_t)) == 0)) { return true; } return false; } bool AudioFlinger::EffectChain::isEffectEligibleForSuspend(const effect_descriptor_t& desc) { // auxiliary effects and visualizer are never suspended on output mix if ((mSessionId == AUDIO_SESSION_OUTPUT_MIX) && (((desc.flags & EFFECT_FLAG_TYPE_MASK) == EFFECT_FLAG_TYPE_AUXILIARY) || (memcmp(&desc.type, SL_IID_VISUALIZATION, sizeof(effect_uuid_t)) == 0) || (memcmp(&desc.type, SL_IID_VOLUME, sizeof(effect_uuid_t)) == 0) || (memcmp(&desc.type, SL_IID_DYNAMICSPROCESSING, sizeof(effect_uuid_t)) == 0))) { return false; } return true; } void AudioFlinger::EffectChain::getSuspendEligibleEffects( Vector< sp > &effects) { effects.clear(); for (size_t i = 0; i < mEffects.size(); i++) { if (isEffectEligibleForSuspend(mEffects[i]->desc())) { effects.add(mEffects[i]); } } } sp AudioFlinger::EffectChain::getEffectIfEnabled( const effect_uuid_t *type) { sp effect = getEffectFromType_l(type); return effect != 0 && effect->isEnabled() ? effect : 0; } void AudioFlinger::EffectChain::checkSuspendOnEffectEnabled(const sp& effect, bool enabled) { ssize_t index = mSuspendedEffects.indexOfKey(effect->desc().type.timeLow); if (enabled) { if (index < 0) { // if the effect is not suspend check if all effects are suspended index = mSuspendedEffects.indexOfKey((int)kKeyForSuspendAll); if (index < 0) { return; } if (!isEffectEligibleForSuspend(effect->desc())) { return; } setEffectSuspended_l(&effect->desc().type, enabled); index = mSuspendedEffects.indexOfKey(effect->desc().type.timeLow); if (index < 0) { ALOGW("checkSuspendOnEffectEnabled() Fx should be suspended here!"); return; } } ALOGV("checkSuspendOnEffectEnabled() enable suspending fx %08x", effect->desc().type.timeLow); sp desc = mSuspendedEffects.valueAt(index); // if effect is requested to suspended but was not yet enabled, suspend it now. if (desc->mEffect == 0) { desc->mEffect = effect; effect->setEnabled(false, false /*fromHandle*/); effect->setSuspended(true); } } else { if (index < 0) { return; } ALOGV("checkSuspendOnEffectEnabled() disable restoring fx %08x", effect->desc().type.timeLow); sp desc = mSuspendedEffects.valueAt(index); desc->mEffect.clear(); effect->setSuspended(false); } } bool AudioFlinger::EffectChain::isNonOffloadableEnabled() { Mutex::Autolock _l(mLock); return isNonOffloadableEnabled_l(); } bool AudioFlinger::EffectChain::isNonOffloadableEnabled_l() { size_t size = mEffects.size(); for (size_t i = 0; i < size; i++) { if (mEffects[i]->isEnabled() && !mEffects[i]->isOffloadable()) { return true; } } return false; } void AudioFlinger::EffectChain::setThread(const sp& thread) { Mutex::Autolock _l(mLock); mEffectCallback->setThread(thread); } void AudioFlinger::EffectChain::checkOutputFlagCompatibility(audio_output_flags_t *flags) const { if ((*flags & AUDIO_OUTPUT_FLAG_RAW) != 0 && !isRawCompatible()) { *flags = (audio_output_flags_t)(*flags & ~AUDIO_OUTPUT_FLAG_RAW); } if ((*flags & AUDIO_OUTPUT_FLAG_FAST) != 0 && !isFastCompatible()) { *flags = (audio_output_flags_t)(*flags & ~AUDIO_OUTPUT_FLAG_FAST); } } void AudioFlinger::EffectChain::checkInputFlagCompatibility(audio_input_flags_t *flags) const { if ((*flags & AUDIO_INPUT_FLAG_RAW) != 0 && !isRawCompatible()) { *flags = (audio_input_flags_t)(*flags & ~AUDIO_INPUT_FLAG_RAW); } if ((*flags & AUDIO_INPUT_FLAG_FAST) != 0 && !isFastCompatible()) { *flags = (audio_input_flags_t)(*flags & ~AUDIO_INPUT_FLAG_FAST); } } bool AudioFlinger::EffectChain::isRawCompatible() const { Mutex::Autolock _l(mLock); for (const auto &effect : mEffects) { if (effect->isProcessImplemented()) { return false; } } // Allow effects without processing. return true; } bool AudioFlinger::EffectChain::isFastCompatible() const { Mutex::Autolock _l(mLock); for (const auto &effect : mEffects) { if (effect->isProcessImplemented() && effect->isImplementationSoftware()) { return false; } } // Allow effects without processing or hw accelerated effects. return true; } // isCompatibleWithThread_l() must be called with thread->mLock held bool AudioFlinger::EffectChain::isCompatibleWithThread_l(const sp& thread) const { Mutex::Autolock _l(mLock); for (size_t i = 0; i < mEffects.size(); i++) { if (thread->checkEffectCompatibility_l(&(mEffects[i]->desc()), mSessionId) != NO_ERROR) { return false; } } return true; } // EffectCallbackInterface implementation status_t AudioFlinger::EffectChain::EffectCallback::createEffectHal( const effect_uuid_t *pEffectUuid, int32_t sessionId, int32_t deviceId, sp *effect) { status_t status = NO_INIT; sp effectsFactory = mAudioFlinger.getEffectsFactory(); if (effectsFactory != 0) { status = effectsFactory->createEffect(pEffectUuid, sessionId, io(), deviceId, effect); } return status; } bool AudioFlinger::EffectChain::EffectCallback::updateOrphanEffectChains( const sp& effect) { // in EffectChain context, an EffectBase is always from an EffectModule so static cast is safe return mAudioFlinger.updateOrphanEffectChains(effect->asEffectModule()); } status_t AudioFlinger::EffectChain::EffectCallback::allocateHalBuffer( size_t size, sp* buffer) { return mAudioFlinger.mEffectsFactoryHal->allocateBuffer(size, buffer); } status_t AudioFlinger::EffectChain::EffectCallback::addEffectToHal( sp effect) { status_t result = NO_INIT; sp t = thread().promote(); if (t == nullptr) { return result; } sp st = t->stream(); if (st == nullptr) { return result; } result = st->addEffect(effect); ALOGE_IF(result != OK, "Error when adding effect: %d", result); return result; } status_t AudioFlinger::EffectChain::EffectCallback::removeEffectFromHal( sp effect) { status_t result = NO_INIT; sp t = thread().promote(); if (t == nullptr) { return result; } sp st = t->stream(); if (st == nullptr) { return result; } result = st->removeEffect(effect); ALOGE_IF(result != OK, "Error when removing effect: %d", result); return result; } audio_io_handle_t AudioFlinger::EffectChain::EffectCallback::io() const { sp t = thread().promote(); if (t == nullptr) { return AUDIO_IO_HANDLE_NONE; } return t->id(); } bool AudioFlinger::EffectChain::EffectCallback::isOutput() const { sp t = thread().promote(); if (t == nullptr) { return true; } return t->isOutput(); } bool AudioFlinger::EffectChain::EffectCallback::isOffload() const { sp t = thread().promote(); if (t == nullptr) { return false; } return t->type() == ThreadBase::OFFLOAD; } bool AudioFlinger::EffectChain::EffectCallback::isOffloadOrDirect() const { sp t = thread().promote(); if (t == nullptr) { return false; } return t->type() == ThreadBase::OFFLOAD || t->type() == ThreadBase::DIRECT; } bool AudioFlinger::EffectChain::EffectCallback::isOffloadOrMmap() const { sp t = thread().promote(); if (t == nullptr) { return false; } return t->isOffloadOrMmap(); } uint32_t AudioFlinger::EffectChain::EffectCallback::sampleRate() const { sp t = thread().promote(); if (t == nullptr) { return 0; } return t->sampleRate(); } audio_channel_mask_t AudioFlinger::EffectChain::EffectCallback::channelMask() const { sp t = thread().promote(); if (t == nullptr) { return AUDIO_CHANNEL_NONE; } return t->channelMask(); } uint32_t AudioFlinger::EffectChain::EffectCallback::channelCount() const { sp t = thread().promote(); if (t == nullptr) { return 0; } return t->channelCount(); } audio_channel_mask_t AudioFlinger::EffectChain::EffectCallback::hapticChannelMask() const { sp t = thread().promote(); if (t == nullptr) { return AUDIO_CHANNEL_NONE; } return t->hapticChannelMask(); } size_t AudioFlinger::EffectChain::EffectCallback::frameCount() const { sp t = thread().promote(); if (t == nullptr) { return 0; } return t->frameCount(); } uint32_t AudioFlinger::EffectChain::EffectCallback::latency() const { sp t = thread().promote(); if (t == nullptr) { return 0; } return t->latency_l(); } void AudioFlinger::EffectChain::EffectCallback::setVolumeForOutput(float left, float right) const { sp t = thread().promote(); if (t == nullptr) { return; } t->setVolumeForOutput_l(left, right); } void AudioFlinger::EffectChain::EffectCallback::checkSuspendOnEffectEnabled( const sp& effect, bool enabled, bool threadLocked) { sp t = thread().promote(); if (t == nullptr) { return; } t->checkSuspendOnEffectEnabled(enabled, effect->sessionId(), threadLocked); sp c = chain().promote(); if (c == nullptr) { return; } // in EffectChain context, an EffectBase is always from an EffectModule so static cast is safe c->checkSuspendOnEffectEnabled(effect->asEffectModule(), enabled); } void AudioFlinger::EffectChain::EffectCallback::onEffectEnable(const sp& effect) { sp t = thread().promote(); if (t == nullptr) { return; } // in EffectChain context, an EffectBase is always from an EffectModule so static cast is safe t->onEffectEnable(effect->asEffectModule()); } void AudioFlinger::EffectChain::EffectCallback::onEffectDisable(const sp& effect) { checkSuspendOnEffectEnabled(effect, false, false /*threadLocked*/); sp t = thread().promote(); if (t == nullptr) { return; } t->onEffectDisable(); } bool AudioFlinger::EffectChain::EffectCallback::disconnectEffectHandle(EffectHandle *handle, bool unpinIfLast) { sp t = thread().promote(); if (t == nullptr) { return false; } t->disconnectEffectHandle(handle, unpinIfLast); return true; } void AudioFlinger::EffectChain::EffectCallback::resetVolume() { sp c = chain().promote(); if (c == nullptr) { return; } c->resetVolume_l(); } product_strategy_t AudioFlinger::EffectChain::EffectCallback::strategy() const { sp c = chain().promote(); if (c == nullptr) { return PRODUCT_STRATEGY_NONE; } return c->strategy(); } int32_t AudioFlinger::EffectChain::EffectCallback::activeTrackCnt() const { sp c = chain().promote(); if (c == nullptr) { return 0; } return c->activeTrackCnt(); } #undef LOG_TAG #define LOG_TAG "AudioFlinger::DeviceEffectProxy" status_t AudioFlinger::DeviceEffectProxy::setEnabled(bool enabled, bool fromHandle) { status_t status = EffectBase::setEnabled(enabled, fromHandle); Mutex::Autolock _l(mProxyLock); if (status == NO_ERROR) { for (auto& handle : mEffectHandles) { Status bs; if (enabled) { bs = handle.second->enable(&status); } else { bs = handle.second->disable(&status); } if (!bs.isOk()) { status = statusTFromBinderStatus(bs); } } } ALOGV("%s enable %d status %d", __func__, enabled, status); return status; } status_t AudioFlinger::DeviceEffectProxy::init( const std::map & patches) { //For all audio patches //If src or sink device match //If the effect is HW accelerated // if no corresponding effect module // Create EffectModule: mHalEffect //Create and attach EffectHandle //If the effect is not HW accelerated and the patch sink or src is a mixer port // Create Effect on patch input or output thread on session -1 //Add EffectHandle to EffectHandle map of Effect Proxy: ALOGV("%s device type %d address %s", __func__, mDevice.mType, mDevice.getAddress()); status_t status = NO_ERROR; for (auto &patch : patches) { status = onCreatePatch(patch.first, patch.second); ALOGV("%s onCreatePatch status %d", __func__, status); if (status == BAD_VALUE) { return status; } } return status; } status_t AudioFlinger::DeviceEffectProxy::onCreatePatch( audio_patch_handle_t patchHandle, const AudioFlinger::PatchPanel::Patch& patch) { status_t status = NAME_NOT_FOUND; sp handle; // only consider source[0] as this is the only "true" source of a patch status = checkPort(patch, &patch.mAudioPatch.sources[0], &handle); ALOGV("%s source checkPort status %d", __func__, status); for (uint32_t i = 0; i < patch.mAudioPatch.num_sinks && status == NAME_NOT_FOUND; i++) { status = checkPort(patch, &patch.mAudioPatch.sinks[i], &handle); ALOGV("%s sink %d checkPort status %d", __func__, i, status); } if (status == NO_ERROR || status == ALREADY_EXISTS) { Mutex::Autolock _l(mProxyLock); mEffectHandles.emplace(patchHandle, handle); } ALOGW_IF(status == BAD_VALUE, "%s cannot attach effect %s on patch %d", __func__, mDescriptor.name, patchHandle); return status; } status_t AudioFlinger::DeviceEffectProxy::checkPort(const PatchPanel::Patch& patch, const struct audio_port_config *port, sp *handle) { ALOGV("%s type %d device type %d address %s device ID %d patch.isSoftware() %d", __func__, port->type, port->ext.device.type, port->ext.device.address, port->id, patch.isSoftware()); if (port->type != AUDIO_PORT_TYPE_DEVICE || port->ext.device.type != mDevice.mType || port->ext.device.address != mDevice.address()) { return NAME_NOT_FOUND; } status_t status = NAME_NOT_FOUND; if (mDescriptor.flags & EFFECT_FLAG_HW_ACC_TUNNEL) { Mutex::Autolock _l(mProxyLock); mDevicePort = *port; mHalEffect = new EffectModule(mMyCallback, const_cast(&mDescriptor), mMyCallback->newEffectId(), AUDIO_SESSION_DEVICE, false /* pinned */, port->id); if (audio_is_input_device(mDevice.mType)) { mHalEffect->setInputDevice(mDevice); } else { mHalEffect->setDevices({mDevice}); } *handle = new EffectHandle(mHalEffect, nullptr, nullptr, 0 /*priority*/); status = (*handle)->initCheck(); if (status == OK) { status = mHalEffect->addHandle((*handle).get()); } else { mHalEffect.clear(); mDevicePort.id = AUDIO_PORT_HANDLE_NONE; } } else if (patch.isSoftware() || patch.thread().promote() != nullptr) { sp thread; if (audio_port_config_has_input_direction(port)) { if (patch.isSoftware()) { thread = patch.mRecord.thread(); } else { thread = patch.thread().promote(); } } else { if (patch.isSoftware()) { thread = patch.mPlayback.thread(); } else { thread = patch.thread().promote(); } } int enabled; *handle = thread->createEffect_l(nullptr, nullptr, 0, AUDIO_SESSION_DEVICE, const_cast(&mDescriptor), &enabled, &status, false, false /*probe*/); ALOGV("%s thread->createEffect_l status %d", __func__, status); } else { status = BAD_VALUE; } if (status == NO_ERROR || status == ALREADY_EXISTS) { Status bs; if (isEnabled()) { bs = (*handle)->enable(&status); } else { bs = (*handle)->disable(&status); } if (!bs.isOk()) { status = statusTFromBinderStatus(bs); } } return status; } void AudioFlinger::DeviceEffectProxy::onReleasePatch(audio_patch_handle_t patchHandle) { Mutex::Autolock _l(mProxyLock); mEffectHandles.erase(patchHandle); } size_t AudioFlinger::DeviceEffectProxy::removeEffect(const sp& effect) { Mutex::Autolock _l(mProxyLock); if (effect == mHalEffect) { mHalEffect.clear(); mDevicePort.id = AUDIO_PORT_HANDLE_NONE; } return mHalEffect == nullptr ? 0 : 1; } status_t AudioFlinger::DeviceEffectProxy::addEffectToHal( sp effect) { if (mHalEffect == nullptr) { return NO_INIT; } return mManagerCallback->addEffectToHal( mDevicePort.id, mDevicePort.ext.device.hw_module, effect); } status_t AudioFlinger::DeviceEffectProxy::removeEffectFromHal( sp effect) { if (mHalEffect == nullptr) { return NO_INIT; } return mManagerCallback->removeEffectFromHal( mDevicePort.id, mDevicePort.ext.device.hw_module, effect); } bool AudioFlinger::DeviceEffectProxy::isOutput() const { if (mDevicePort.id != AUDIO_PORT_HANDLE_NONE) { return mDevicePort.role == AUDIO_PORT_ROLE_SINK; } return true; } uint32_t AudioFlinger::DeviceEffectProxy::sampleRate() const { if (mDevicePort.id != AUDIO_PORT_HANDLE_NONE && (mDevicePort.config_mask & AUDIO_PORT_CONFIG_SAMPLE_RATE) != 0) { return mDevicePort.sample_rate; } return DEFAULT_OUTPUT_SAMPLE_RATE; } audio_channel_mask_t AudioFlinger::DeviceEffectProxy::channelMask() const { if (mDevicePort.id != AUDIO_PORT_HANDLE_NONE && (mDevicePort.config_mask & AUDIO_PORT_CONFIG_CHANNEL_MASK) != 0) { return mDevicePort.channel_mask; } return AUDIO_CHANNEL_OUT_STEREO; } uint32_t AudioFlinger::DeviceEffectProxy::channelCount() const { if (isOutput()) { return audio_channel_count_from_out_mask(channelMask()); } return audio_channel_count_from_in_mask(channelMask()); } void AudioFlinger::DeviceEffectProxy::dump(int fd, int spaces) { const Vector args; EffectBase::dump(fd, args); const bool locked = dumpTryLock(mProxyLock); if (!locked) { String8 result("DeviceEffectProxy may be deadlocked\n"); write(fd, result.string(), result.size()); } String8 outStr; if (mHalEffect != nullptr) { outStr.appendFormat("%*sHAL Effect Id: %d\n", spaces, "", mHalEffect->id()); } else { outStr.appendFormat("%*sNO HAL Effect\n", spaces, ""); } write(fd, outStr.string(), outStr.size()); outStr.clear(); outStr.appendFormat("%*sSub Effects:\n", spaces, ""); write(fd, outStr.string(), outStr.size()); outStr.clear(); for (const auto& iter : mEffectHandles) { outStr.appendFormat("%*sEffect for patch handle %d:\n", spaces + 2, "", iter.first); write(fd, outStr.string(), outStr.size()); outStr.clear(); sp effect = iter.second->effect().promote(); if (effect != nullptr) { effect->dump(fd, args); } } if (locked) { mLock.unlock(); } } #undef LOG_TAG #define LOG_TAG "AudioFlinger::DeviceEffectProxy::ProxyCallback" int AudioFlinger::DeviceEffectProxy::ProxyCallback::newEffectId() { return mManagerCallback->newEffectId(); } bool AudioFlinger::DeviceEffectProxy::ProxyCallback::disconnectEffectHandle( EffectHandle *handle, bool unpinIfLast) { sp effectBase = handle->effect().promote(); if (effectBase == nullptr) { return false; } sp effect = effectBase->asEffectModule(); if (effect == nullptr) { return false; } // restore suspended effects if the disconnected handle was enabled and the last one. bool remove = (effect->removeHandle(handle) == 0) && (!effect->isPinned() || unpinIfLast); if (remove) { sp proxy = mProxy.promote(); if (proxy != nullptr) { proxy->removeEffect(effect); } if (handle->enabled()) { effectBase->checkSuspendOnEffectEnabled(false, false /*threadLocked*/); } } return true; } status_t AudioFlinger::DeviceEffectProxy::ProxyCallback::createEffectHal( const effect_uuid_t *pEffectUuid, int32_t sessionId, int32_t deviceId, sp *effect) { return mManagerCallback->createEffectHal(pEffectUuid, sessionId, deviceId, effect); } status_t AudioFlinger::DeviceEffectProxy::ProxyCallback::addEffectToHal( sp effect) { sp proxy = mProxy.promote(); if (proxy == nullptr) { return NO_INIT; } return proxy->addEffectToHal(effect); } status_t AudioFlinger::DeviceEffectProxy::ProxyCallback::removeEffectFromHal( sp effect) { sp proxy = mProxy.promote(); if (proxy == nullptr) { return NO_INIT; } return proxy->addEffectToHal(effect); } bool AudioFlinger::DeviceEffectProxy::ProxyCallback::isOutput() const { sp proxy = mProxy.promote(); if (proxy == nullptr) { return true; } return proxy->isOutput(); } uint32_t AudioFlinger::DeviceEffectProxy::ProxyCallback::sampleRate() const { sp proxy = mProxy.promote(); if (proxy == nullptr) { return DEFAULT_OUTPUT_SAMPLE_RATE; } return proxy->sampleRate(); } audio_channel_mask_t AudioFlinger::DeviceEffectProxy::ProxyCallback::channelMask() const { sp proxy = mProxy.promote(); if (proxy == nullptr) { return AUDIO_CHANNEL_OUT_STEREO; } return proxy->channelMask(); } uint32_t AudioFlinger::DeviceEffectProxy::ProxyCallback::channelCount() const { sp proxy = mProxy.promote(); if (proxy == nullptr) { return 2; } return proxy->channelCount(); } } // namespace android