services/oboeservice/AAudioServiceEndpointMMAP.cpp - LeafOS-Project/android_frameworks_av - Gitiles

 /*
  * Copyright (C) 2017 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 "AAudioServiceEndpointMMAP"
 //#define LOG_NDEBUG 0
 #include <utils/Log.h>

 #include <algorithm>
 #include <assert.h>
 #include <map>
 #include <mutex>
 #include <sstream>
 #include <utils/Singleton.h>
 #include <vector>


 #include "AAudioEndpointManager.h"
 #include "AAudioServiceEndpoint.h"

 #include "core/AudioStreamBuilder.h"
 #include "AAudioServiceEndpoint.h"
 #include "AAudioServiceStreamShared.h"
 #include "AAudioServiceEndpointPlay.h"
 #include "AAudioServiceEndpointMMAP.h"


 #define AAUDIO_BUFFER_CAPACITY_MIN    4 * 512
 #define AAUDIO_SAMPLE_RATE_DEFAULT    48000

 // This is an estimate of the time difference between the HW and the MMAP time.
 // TODO Get presentation timestamps from the HAL instead of using these estimates.
 #define OUTPUT_ESTIMATED_HARDWARE_OFFSET_NANOS  (3 * AAUDIO_NANOS_PER_MILLISECOND)
 #define INPUT_ESTIMATED_HARDWARE_OFFSET_NANOS   (-1 * AAUDIO_NANOS_PER_MILLISECOND)

 using namespace android;  // TODO just import names needed
 using namespace aaudio;   // TODO just import names needed

 AAudioServiceEndpointMMAP::AAudioServiceEndpointMMAP()
         :  mMmapStream(nullptr) {}

 AAudioServiceEndpointMMAP::~AAudioServiceEndpointMMAP() {}

 std::string AAudioServiceEndpointMMAP::dump() const {
     std::stringstream result;

     result << "  MMAP: framesTransferred = " << mFramesTransferred.get();
     result << ", HW nanos = " << mHardwareTimeOffsetNanos;
     result << ", port handle = " << mPortHandle;
     result << ", audio data FD = " << mAudioDataFileDescriptor;
     result << "\n";

     result << "    HW Offset Micros:     " <<
                                       (getHardwareTimeOffsetNanos()
                                        / AAUDIO_NANOS_PER_MICROSECOND) << "\n";

     result << AAudioServiceEndpoint::dump();
     return result.str();
 }

 aaudio_result_t AAudioServiceEndpointMMAP::open(const aaudio::AAudioStreamRequest &request) {
     aaudio_result_t result = AAUDIO_OK;
     const audio_attributes_t attributes = {
             .content_type = AUDIO_CONTENT_TYPE_MUSIC,
             .usage = AUDIO_USAGE_MEDIA,
             .source = AUDIO_SOURCE_VOICE_RECOGNITION,
             .flags = AUDIO_FLAG_LOW_LATENCY,
             .tags = ""
     };
     audio_config_base_t config;
     audio_port_handle_t deviceId;

     int32_t burstMinMicros = AAudioProperty_getHardwareBurstMinMicros();
     int32_t burstMicros = 0;

     copyFrom(request.getConstantConfiguration());

     mMmapClient.clientUid = request.getUserId();
     mMmapClient.clientPid = request.getProcessId();
     mMmapClient.packageName.setTo(String16(""));

     mRequestedDeviceId = deviceId = getDeviceId();

     // Fill in config
     aaudio_format_t aaudioFormat = getFormat();
     if (aaudioFormat == AAUDIO_UNSPECIFIED || aaudioFormat == AAUDIO_FORMAT_PCM_FLOAT) {
         aaudioFormat = AAUDIO_FORMAT_PCM_I16;
     }
     config.format = AAudioConvert_aaudioToAndroidDataFormat(aaudioFormat);

     int32_t aaudioSampleRate = getSampleRate();
     if (aaudioSampleRate == AAUDIO_UNSPECIFIED) {
         aaudioSampleRate = AAUDIO_SAMPLE_RATE_DEFAULT;
     }
     config.sample_rate = aaudioSampleRate;

     int32_t aaudioSamplesPerFrame = getSamplesPerFrame();

     aaudio_direction_t direction = getDirection();
     if (direction == AAUDIO_DIRECTION_OUTPUT) {
         config.channel_mask = (aaudioSamplesPerFrame == AAUDIO_UNSPECIFIED)
                               ? AUDIO_CHANNEL_OUT_STEREO
                               : audio_channel_out_mask_from_count(aaudioSamplesPerFrame);
         mHardwareTimeOffsetNanos = OUTPUT_ESTIMATED_HARDWARE_OFFSET_NANOS; // frames at DAC later

     } else if (direction == AAUDIO_DIRECTION_INPUT) {
         config.channel_mask =  (aaudioSamplesPerFrame == AAUDIO_UNSPECIFIED)
                                ? AUDIO_CHANNEL_IN_STEREO
                                : audio_channel_in_mask_from_count(aaudioSamplesPerFrame);
         mHardwareTimeOffsetNanos = INPUT_ESTIMATED_HARDWARE_OFFSET_NANOS; // frames at ADC earlier

     } else {
         ALOGE("openMmapStream - invalid direction = %d", direction);
         return AAUDIO_ERROR_ILLEGAL_ARGUMENT;
     }

     MmapStreamInterface::stream_direction_t streamDirection =
             (direction == AAUDIO_DIRECTION_OUTPUT)
             ? MmapStreamInterface::DIRECTION_OUTPUT
             : MmapStreamInterface::DIRECTION_INPUT;

     // Open HAL stream. Set mMmapStream
     status_t status = MmapStreamInterface::openMmapStream(streamDirection,
                                                           &attributes,
                                                           &config,
                                                           mMmapClient,
                                                           &deviceId,
                                                           this, // callback
                                                           mMmapStream,
                                                           &mPortHandle);
     ALOGD("AAudioServiceEndpointMMAP::open() mMapClient.uid = %d, pid = %d => portHandle = %d\n",
           mMmapClient.clientUid,  mMmapClient.clientPid, mPortHandle);
     if (status != OK) {
         ALOGE("openMmapStream returned status %d", status);
         return AAUDIO_ERROR_UNAVAILABLE;
     }

     if (deviceId == AAUDIO_UNSPECIFIED) {
         ALOGW("AAudioServiceEndpointMMAP::open() - openMmapStream() failed to set deviceId");
     }
     setDeviceId(deviceId);

     // Create MMAP/NOIRQ buffer.
     int32_t minSizeFrames = getBufferCapacity();
     if (minSizeFrames <= 0) { // zero will get rejected
         minSizeFrames = AAUDIO_BUFFER_CAPACITY_MIN;
     }
     status = mMmapStream->createMmapBuffer(minSizeFrames, &mMmapBufferinfo);
     if (status != OK) {
         ALOGE("AAudioServiceEndpointMMAP::open() - createMmapBuffer() failed with status %d %s",
               status, strerror(-status));
         result = AAUDIO_ERROR_UNAVAILABLE;
         goto error;
     } else {
         ALOGD("createMmapBuffer status = %d, buffer_size = %d, burst_size %d"
                       ", Sharable FD: %s",
               status,
               abs(mMmapBufferinfo.buffer_size_frames),
               mMmapBufferinfo.burst_size_frames,
               mMmapBufferinfo.buffer_size_frames < 0 ? "Yes" : "No");
     }

     setBufferCapacity(mMmapBufferinfo.buffer_size_frames);
     // The audio HAL indicates if the shared memory fd can be shared outside of audioserver
     // by returning a negative buffer size
     if (getBufferCapacity() < 0) {
         // Exclusive mode can be used by client or service.
         setBufferCapacity(-getBufferCapacity());
     } else {
         // Exclusive mode can only be used by the service because the FD cannot be shared.
         uid_t audioServiceUid = getuid();
         if ((mMmapClient.clientUid != audioServiceUid) &&
             getSharingMode() == AAUDIO_SHARING_MODE_EXCLUSIVE) {
             // Fallback is handled by caller but indicate what is possible in case
             // this is used in the future
             setSharingMode(AAUDIO_SHARING_MODE_SHARED);
             ALOGW("AAudioServiceEndpointMMAP::open() - exclusive FD cannot be used by client");
             result = AAUDIO_ERROR_UNAVAILABLE;
             goto error;
         }
     }

     // Get information about the stream and pass it back to the caller.
     setSamplesPerFrame((direction == AAUDIO_DIRECTION_OUTPUT)
                        ? audio_channel_count_from_out_mask(config.channel_mask)
                        : audio_channel_count_from_in_mask(config.channel_mask));

     // AAudio creates a copy of this FD and retains ownership of the copy.
     // Assume that AudioFlinger will close the original shared_memory_fd.
     mAudioDataFileDescriptor.reset(dup(mMmapBufferinfo.shared_memory_fd));
     if (mAudioDataFileDescriptor.get() == -1) {
         ALOGE("AAudioServiceEndpointMMAP::open() - could not dup shared_memory_fd");
         result = AAUDIO_ERROR_INTERNAL;
         goto error;
     }
     mFramesPerBurst = mMmapBufferinfo.burst_size_frames;
     setFormat(AAudioConvert_androidToAAudioDataFormat(config.format));
     setSampleRate(config.sample_rate);

     // Scale up the burst size to meet the minimum equivalent in microseconds.
     // This is to avoid waking the CPU too often when the HW burst is very small
     // or at high sample rates.
     do {
         if (burstMicros > 0) {  // skip first loop
             mFramesPerBurst *= 2;
         }
         burstMicros = mFramesPerBurst * static_cast<int64_t>(1000000) / getSampleRate();
     } while (burstMicros < burstMinMicros);

     ALOGD("AAudioServiceEndpointMMAP::open() original burst = %d, minMicros = %d, to burst = %d\n",
           mMmapBufferinfo.burst_size_frames, burstMinMicros, mFramesPerBurst);

     ALOGD("AAudioServiceEndpointMMAP::open() actual rate = %d, channels = %d"
           ", deviceId = %d, capacity = %d\n",
           getSampleRate(), getSamplesPerFrame(), deviceId, getBufferCapacity());

     return result;

 error:
     close();
     return result;
 }

 aaudio_result_t AAudioServiceEndpointMMAP::close() {

     if (mMmapStream != 0) {
         ALOGD("AAudioServiceEndpointMMAP::close() clear() endpoint");
         // Needs to be explicitly cleared or CTS will fail but it is not clear why.
         mMmapStream.clear();
         // Apparently the above close is asynchronous. An attempt to open a new device
         // right after a close can fail. Also some callbacks may still be in flight!
         // FIXME Make closing synchronous.
         AudioClock::sleepForNanos(100 * AAUDIO_NANOS_PER_MILLISECOND);
     }

     return AAUDIO_OK;
 }

 aaudio_result_t AAudioServiceEndpointMMAP::startStream(sp<AAudioServiceStreamBase> stream,
                                                    audio_port_handle_t *clientHandle) {
     // Start the client on behalf of the AAudio service.
     // Use the port handle that was provided by openMmapStream().
     return startClient(mMmapClient, &mPortHandle);
 }

 aaudio_result_t AAudioServiceEndpointMMAP::stopStream(sp<AAudioServiceStreamBase> stream,
                                                   audio_port_handle_t clientHandle) {
     mFramesTransferred.reset32();
     return stopClient(mPortHandle);
 }

 aaudio_result_t AAudioServiceEndpointMMAP::startClient(const android::AudioClient& client,
                                                        audio_port_handle_t *clientHandle) {
     if (mMmapStream == nullptr) return AAUDIO_ERROR_NULL;
     ALOGD("AAudioServiceEndpointMMAP::startClient(%p(uid=%d, pid=%d))",
           &client, client.clientUid, client.clientPid);
     audio_port_handle_t originalHandle =  *clientHandle;
     status_t status = mMmapStream->start(client, clientHandle);
     aaudio_result_t result = AAudioConvert_androidToAAudioResult(status);
     ALOGD("AAudioServiceEndpointMMAP::startClient() , %d => %d returns %d",
           originalHandle, *clientHandle, result);
     return result;
 }

 aaudio_result_t AAudioServiceEndpointMMAP::stopClient(audio_port_handle_t clientHandle) {
     if (mMmapStream == nullptr) return AAUDIO_ERROR_NULL;
     aaudio_result_t result = AAudioConvert_androidToAAudioResult(mMmapStream->stop(clientHandle));
     ALOGD("AAudioServiceEndpointMMAP::stopClient(%d) returns %d", clientHandle, result);
     return result;
 }

 // Get free-running DSP or DMA hardware position from the HAL.
 aaudio_result_t AAudioServiceEndpointMMAP::getFreeRunningPosition(int64_t *positionFrames,
                                                                 int64_t *timeNanos) {
     struct audio_mmap_position position;
     if (mMmapStream == nullptr) {
         return AAUDIO_ERROR_NULL;
     }
     status_t status = mMmapStream->getMmapPosition(&position);
     ALOGV("AAudioServiceEndpointMMAP::getFreeRunningPosition() status= %d, pos = %d, nanos = %lld\n",
           status, position.position_frames, (long long) position.time_nanoseconds);
     aaudio_result_t result = AAudioConvert_androidToAAudioResult(status);
     if (result == AAUDIO_ERROR_UNAVAILABLE) {
         ALOGW("sendCurrentTimestamp(): getMmapPosition() has no position data available");
     } else if (result != AAUDIO_OK) {
         ALOGE("sendCurrentTimestamp(): getMmapPosition() returned status %d", status);
     } else {
         // Convert 32-bit position to 64-bit position.
         mFramesTransferred.update32(position.position_frames);
         *positionFrames = mFramesTransferred.get();
         *timeNanos = position.time_nanoseconds;
     }
     return result;
 }

 aaudio_result_t AAudioServiceEndpointMMAP::getTimestamp(int64_t *positionFrames,
                                                     int64_t *timeNanos) {
     return 0; // TODO
 }


 void AAudioServiceEndpointMMAP::onTearDown() {
     ALOGD("AAudioServiceEndpointMMAP::onTearDown() called");
     disconnectRegisteredStreams();
 };

 void AAudioServiceEndpointMMAP::onVolumeChanged(audio_channel_mask_t channels,
                                               android::Vector<float> values) {
     // TODO do we really need a different volume for each channel?
     float volume = values[0];
     ALOGD("AAudioServiceEndpointMMAP::onVolumeChanged() volume[0] = %f", volume);
     std::lock_guard<std::mutex> lock(mLockStreams);
     for(const auto stream : mRegisteredStreams) {
         stream->onVolumeChanged(volume);
     }
 };

 void AAudioServiceEndpointMMAP::onRoutingChanged(audio_port_handle_t deviceId) {
     ALOGD("AAudioServiceEndpointMMAP::onRoutingChanged() called with %d, old = %d",
           deviceId, getDeviceId());
     if (getDeviceId() != AUDIO_PORT_HANDLE_NONE  && getDeviceId() != deviceId) {
         disconnectRegisteredStreams();
     }
     setDeviceId(deviceId);
 };

 /**
  * Get an immutable description of the data queue from the HAL.
  */
 aaudio_result_t AAudioServiceEndpointMMAP::getDownDataDescription(AudioEndpointParcelable &parcelable)
 {
     // Gather information on the data queue based on HAL info.
     int32_t bytesPerFrame = calculateBytesPerFrame();
     int32_t capacityInBytes = getBufferCapacity() * bytesPerFrame;
     int fdIndex = parcelable.addFileDescriptor(mAudioDataFileDescriptor, capacityInBytes);
     parcelable.mDownDataQueueParcelable.setupMemory(fdIndex, 0, capacityInBytes);
     parcelable.mDownDataQueueParcelable.setBytesPerFrame(bytesPerFrame);
     parcelable.mDownDataQueueParcelable.setFramesPerBurst(mFramesPerBurst);
     parcelable.mDownDataQueueParcelable.setCapacityInFrames(getBufferCapacity());
     return AAUDIO_OK;
 }
	/*
	* Copyright (C) 2017 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 "AAudioServiceEndpointMMAP"
	//#define LOG_NDEBUG 0
	#include <utils/Log.h>

	#include <algorithm>
	#include <assert.h>
	#include <map>
	#include <mutex>
	#include <sstream>
	#include <utils/Singleton.h>
	#include <vector>


	#include "AAudioEndpointManager.h"
	#include "AAudioServiceEndpoint.h"

	#include "core/AudioStreamBuilder.h"
	#include "AAudioServiceEndpoint.h"
	#include "AAudioServiceStreamShared.h"
	#include "AAudioServiceEndpointPlay.h"
	#include "AAudioServiceEndpointMMAP.h"


	#define AAUDIO_BUFFER_CAPACITY_MIN 4 * 512
	#define AAUDIO_SAMPLE_RATE_DEFAULT 48000

	// This is an estimate of the time difference between the HW and the MMAP time.
	// TODO Get presentation timestamps from the HAL instead of using these estimates.
	#define OUTPUT_ESTIMATED_HARDWARE_OFFSET_NANOS (3 * AAUDIO_NANOS_PER_MILLISECOND)
	#define INPUT_ESTIMATED_HARDWARE_OFFSET_NANOS (-1 * AAUDIO_NANOS_PER_MILLISECOND)

	using namespace android; // TODO just import names needed
	using namespace aaudio; // TODO just import names needed

	AAudioServiceEndpointMMAP::AAudioServiceEndpointMMAP()
	: mMmapStream(nullptr) {}

	AAudioServiceEndpointMMAP::~AAudioServiceEndpointMMAP() {}

	std::string AAudioServiceEndpointMMAP::dump() const {
	std::stringstream result;

	result << " MMAP: framesTransferred = " << mFramesTransferred.get();
	result << ", HW nanos = " << mHardwareTimeOffsetNanos;
	result << ", port handle = " << mPortHandle;
	result << ", audio data FD = " << mAudioDataFileDescriptor;
	result << "\n";

	result << " HW Offset Micros: " <<
	(getHardwareTimeOffsetNanos()
	/ AAUDIO_NANOS_PER_MICROSECOND) << "\n";

	result << AAudioServiceEndpoint::dump();
	return result.str();
	}

	aaudio_result_t AAudioServiceEndpointMMAP::open(const aaudio::AAudioStreamRequest &request) {
	aaudio_result_t result = AAUDIO_OK;
	const audio_attributes_t attributes = {
	.content_type = AUDIO_CONTENT_TYPE_MUSIC,
	.usage = AUDIO_USAGE_MEDIA,
	.source = AUDIO_SOURCE_VOICE_RECOGNITION,
	.flags = AUDIO_FLAG_LOW_LATENCY,
	.tags = ""
	};
	audio_config_base_t config;
	audio_port_handle_t deviceId;

	int32_t burstMinMicros = AAudioProperty_getHardwareBurstMinMicros();
	int32_t burstMicros = 0;

	copyFrom(request.getConstantConfiguration());

	mMmapClient.clientUid = request.getUserId();
	mMmapClient.clientPid = request.getProcessId();
	mMmapClient.packageName.setTo(String16(""));

	mRequestedDeviceId = deviceId = getDeviceId();

	// Fill in config
	aaudio_format_t aaudioFormat = getFormat();
	if (aaudioFormat == AAUDIO_UNSPECIFIED \|\| aaudioFormat == AAUDIO_FORMAT_PCM_FLOAT) {
	aaudioFormat = AAUDIO_FORMAT_PCM_I16;
	}
	config.format = AAudioConvert_aaudioToAndroidDataFormat(aaudioFormat);

	int32_t aaudioSampleRate = getSampleRate();
	if (aaudioSampleRate == AAUDIO_UNSPECIFIED) {
	aaudioSampleRate = AAUDIO_SAMPLE_RATE_DEFAULT;
	}
	config.sample_rate = aaudioSampleRate;

	int32_t aaudioSamplesPerFrame = getSamplesPerFrame();

	aaudio_direction_t direction = getDirection();
	if (direction == AAUDIO_DIRECTION_OUTPUT) {
	config.channel_mask = (aaudioSamplesPerFrame == AAUDIO_UNSPECIFIED)
	? AUDIO_CHANNEL_OUT_STEREO
	: audio_channel_out_mask_from_count(aaudioSamplesPerFrame);
	mHardwareTimeOffsetNanos = OUTPUT_ESTIMATED_HARDWARE_OFFSET_NANOS; // frames at DAC later

	} else if (direction == AAUDIO_DIRECTION_INPUT) {
	config.channel_mask = (aaudioSamplesPerFrame == AAUDIO_UNSPECIFIED)
	? AUDIO_CHANNEL_IN_STEREO
	: audio_channel_in_mask_from_count(aaudioSamplesPerFrame);
	mHardwareTimeOffsetNanos = INPUT_ESTIMATED_HARDWARE_OFFSET_NANOS; // frames at ADC earlier

	} else {
	ALOGE("openMmapStream - invalid direction = %d", direction);
	return AAUDIO_ERROR_ILLEGAL_ARGUMENT;
	}

	MmapStreamInterface::stream_direction_t streamDirection =
	(direction == AAUDIO_DIRECTION_OUTPUT)
	? MmapStreamInterface::DIRECTION_OUTPUT
	: MmapStreamInterface::DIRECTION_INPUT;

	// Open HAL stream. Set mMmapStream
	status_t status = MmapStreamInterface::openMmapStream(streamDirection,
	&attributes,
	&config,
	mMmapClient,
	&deviceId,
	this, // callback
	mMmapStream,
	&mPortHandle);
	ALOGD("AAudioServiceEndpointMMAP::open() mMapClient.uid = %d, pid = %d => portHandle = %d\n",
	mMmapClient.clientUid, mMmapClient.clientPid, mPortHandle);
	if (status != OK) {
	ALOGE("openMmapStream returned status %d", status);
	return AAUDIO_ERROR_UNAVAILABLE;
	}

	if (deviceId == AAUDIO_UNSPECIFIED) {
	ALOGW("AAudioServiceEndpointMMAP::open() - openMmapStream() failed to set deviceId");
	}
	setDeviceId(deviceId);

	// Create MMAP/NOIRQ buffer.
	int32_t minSizeFrames = getBufferCapacity();
	if (minSizeFrames <= 0) { // zero will get rejected
	minSizeFrames = AAUDIO_BUFFER_CAPACITY_MIN;
	}
	status = mMmapStream->createMmapBuffer(minSizeFrames, &mMmapBufferinfo);
	if (status != OK) {
	ALOGE("AAudioServiceEndpointMMAP::open() - createMmapBuffer() failed with status %d %s",
	status, strerror(-status));
	result = AAUDIO_ERROR_UNAVAILABLE;
	goto error;
	} else {
	ALOGD("createMmapBuffer status = %d, buffer_size = %d, burst_size %d"
	", Sharable FD: %s",
	status,
	abs(mMmapBufferinfo.buffer_size_frames),
	mMmapBufferinfo.burst_size_frames,
	mMmapBufferinfo.buffer_size_frames < 0 ? "Yes" : "No");
	}

	setBufferCapacity(mMmapBufferinfo.buffer_size_frames);
	// The audio HAL indicates if the shared memory fd can be shared outside of audioserver
	// by returning a negative buffer size
	if (getBufferCapacity() < 0) {
	// Exclusive mode can be used by client or service.
	setBufferCapacity(-getBufferCapacity());
	} else {
	// Exclusive mode can only be used by the service because the FD cannot be shared.
	uid_t audioServiceUid = getuid();
	if ((mMmapClient.clientUid != audioServiceUid) &&
	getSharingMode() == AAUDIO_SHARING_MODE_EXCLUSIVE) {
	// Fallback is handled by caller but indicate what is possible in case
	// this is used in the future
	setSharingMode(AAUDIO_SHARING_MODE_SHARED);
	ALOGW("AAudioServiceEndpointMMAP::open() - exclusive FD cannot be used by client");
	result = AAUDIO_ERROR_UNAVAILABLE;
	goto error;
	}
	}

	// Get information about the stream and pass it back to the caller.
	setSamplesPerFrame((direction == AAUDIO_DIRECTION_OUTPUT)
	? audio_channel_count_from_out_mask(config.channel_mask)
	: audio_channel_count_from_in_mask(config.channel_mask));

	// AAudio creates a copy of this FD and retains ownership of the copy.
	// Assume that AudioFlinger will close the original shared_memory_fd.
	mAudioDataFileDescriptor.reset(dup(mMmapBufferinfo.shared_memory_fd));
	if (mAudioDataFileDescriptor.get() == -1) {
	ALOGE("AAudioServiceEndpointMMAP::open() - could not dup shared_memory_fd");
	result = AAUDIO_ERROR_INTERNAL;
	goto error;
	}
	mFramesPerBurst = mMmapBufferinfo.burst_size_frames;
	setFormat(AAudioConvert_androidToAAudioDataFormat(config.format));
	setSampleRate(config.sample_rate);

	// Scale up the burst size to meet the minimum equivalent in microseconds.
	// This is to avoid waking the CPU too often when the HW burst is very small
	// or at high sample rates.
	do {
	if (burstMicros > 0) { // skip first loop
	mFramesPerBurst *= 2;
	}
	burstMicros = mFramesPerBurst * static_cast<int64_t>(1000000) / getSampleRate();
	} while (burstMicros < burstMinMicros);

	ALOGD("AAudioServiceEndpointMMAP::open() original burst = %d, minMicros = %d, to burst = %d\n",
	mMmapBufferinfo.burst_size_frames, burstMinMicros, mFramesPerBurst);

	ALOGD("AAudioServiceEndpointMMAP::open() actual rate = %d, channels = %d"
	", deviceId = %d, capacity = %d\n",
	getSampleRate(), getSamplesPerFrame(), deviceId, getBufferCapacity());

	return result;

	error:
	close();
	return result;
	}

	aaudio_result_t AAudioServiceEndpointMMAP::close() {

	if (mMmapStream != 0) {
	ALOGD("AAudioServiceEndpointMMAP::close() clear() endpoint");
	// Needs to be explicitly cleared or CTS will fail but it is not clear why.
	mMmapStream.clear();
	// Apparently the above close is asynchronous. An attempt to open a new device
	// right after a close can fail. Also some callbacks may still be in flight!
	// FIXME Make closing synchronous.
	AudioClock::sleepForNanos(100 * AAUDIO_NANOS_PER_MILLISECOND);
	}

	return AAUDIO_OK;
	}

	aaudio_result_t AAudioServiceEndpointMMAP::startStream(sp<AAudioServiceStreamBase> stream,
	audio_port_handle_t *clientHandle) {
	// Start the client on behalf of the AAudio service.
	// Use the port handle that was provided by openMmapStream().
	return startClient(mMmapClient, &mPortHandle);
	}

	aaudio_result_t AAudioServiceEndpointMMAP::stopStream(sp<AAudioServiceStreamBase> stream,
	audio_port_handle_t clientHandle) {
	mFramesTransferred.reset32();
	return stopClient(mPortHandle);
	}

	aaudio_result_t AAudioServiceEndpointMMAP::startClient(const android::AudioClient& client,
	audio_port_handle_t *clientHandle) {
	if (mMmapStream == nullptr) return AAUDIO_ERROR_NULL;
	ALOGD("AAudioServiceEndpointMMAP::startClient(%p(uid=%d, pid=%d))",
	&client, client.clientUid, client.clientPid);
	audio_port_handle_t originalHandle = *clientHandle;
	status_t status = mMmapStream->start(client, clientHandle);
	aaudio_result_t result = AAudioConvert_androidToAAudioResult(status);
	ALOGD("AAudioServiceEndpointMMAP::startClient() , %d => %d returns %d",
	originalHandle, *clientHandle, result);
	return result;
	}

	aaudio_result_t AAudioServiceEndpointMMAP::stopClient(audio_port_handle_t clientHandle) {
	if (mMmapStream == nullptr) return AAUDIO_ERROR_NULL;
	aaudio_result_t result = AAudioConvert_androidToAAudioResult(mMmapStream->stop(clientHandle));
	ALOGD("AAudioServiceEndpointMMAP::stopClient(%d) returns %d", clientHandle, result);
	return result;
	}

	// Get free-running DSP or DMA hardware position from the HAL.
	aaudio_result_t AAudioServiceEndpointMMAP::getFreeRunningPosition(int64_t *positionFrames,
	int64_t *timeNanos) {
	struct audio_mmap_position position;
	if (mMmapStream == nullptr) {
	return AAUDIO_ERROR_NULL;
	}
	status_t status = mMmapStream->getMmapPosition(&position);
	ALOGV("AAudioServiceEndpointMMAP::getFreeRunningPosition() status= %d, pos = %d, nanos = %lld\n",
	status, position.position_frames, (long long) position.time_nanoseconds);
	aaudio_result_t result = AAudioConvert_androidToAAudioResult(status);
	if (result == AAUDIO_ERROR_UNAVAILABLE) {
	ALOGW("sendCurrentTimestamp(): getMmapPosition() has no position data available");
	} else if (result != AAUDIO_OK) {
	ALOGE("sendCurrentTimestamp(): getMmapPosition() returned status %d", status);
	} else {
	// Convert 32-bit position to 64-bit position.
	mFramesTransferred.update32(position.position_frames);
	*positionFrames = mFramesTransferred.get();
	*timeNanos = position.time_nanoseconds;
	}
	return result;
	}

	aaudio_result_t AAudioServiceEndpointMMAP::getTimestamp(int64_t *positionFrames,
	int64_t *timeNanos) {
	return 0; // TODO
	}


	void AAudioServiceEndpointMMAP::onTearDown() {
	ALOGD("AAudioServiceEndpointMMAP::onTearDown() called");
	disconnectRegisteredStreams();
	};

	void AAudioServiceEndpointMMAP::onVolumeChanged(audio_channel_mask_t channels,
	android::Vector<float> values) {
	// TODO do we really need a different volume for each channel?
	float volume = values[0];
	ALOGD("AAudioServiceEndpointMMAP::onVolumeChanged() volume[0] = %f", volume);
	std::lock_guard<std::mutex> lock(mLockStreams);
	for(const auto stream : mRegisteredStreams) {
	stream->onVolumeChanged(volume);
	}
	};

	void AAudioServiceEndpointMMAP::onRoutingChanged(audio_port_handle_t deviceId) {
	ALOGD("AAudioServiceEndpointMMAP::onRoutingChanged() called with %d, old = %d",
	deviceId, getDeviceId());
	if (getDeviceId() != AUDIO_PORT_HANDLE_NONE && getDeviceId() != deviceId) {
	disconnectRegisteredStreams();
	}
	setDeviceId(deviceId);
	};

	/**
	* Get an immutable description of the data queue from the HAL.
	*/
	aaudio_result_t AAudioServiceEndpointMMAP::getDownDataDescription(AudioEndpointParcelable &parcelable)
	{
	// Gather information on the data queue based on HAL info.
	int32_t bytesPerFrame = calculateBytesPerFrame();
	int32_t capacityInBytes = getBufferCapacity() * bytesPerFrame;
	int fdIndex = parcelable.addFileDescriptor(mAudioDataFileDescriptor, capacityInBytes);
	parcelable.mDownDataQueueParcelable.setupMemory(fdIndex, 0, capacityInBytes);
	parcelable.mDownDataQueueParcelable.setBytesPerFrame(bytesPerFrame);
	parcelable.mDownDataQueueParcelable.setFramesPerBurst(mFramesPerBurst);
	parcelable.mDownDataQueueParcelable.setCapacityInFrames(getBufferCapacity());
	return AAUDIO_OK;
	}