src/cobalt/media/base/audio_latency.cc - cobalt - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "cobalt/media/base/audio_latency.h"

 #include <algorithm>

 #include "base/logging.h"
 #include "build/build_config.h"
 #include "starboard/types.h"

 namespace cobalt {
 namespace media {

 namespace {
 #if !defined(OS_WIN)
 // Taken from "Bit Twiddling Hacks"
 // http://graphics.stanford.edu/~seander/bithacks.html#RoundUpPowerOf2
 uint32_t RoundUpToPowerOfTwo(uint32_t v) {
   v--;
   v |= v >> 1;
   v |= v >> 2;
   v |= v >> 4;
   v |= v >> 8;
   v |= v >> 16;
   v++;
   return v;
 }
 #endif
 }  // namespace

 // static
 int AudioLatency::GetHighLatencyBufferSize(int sample_rate,
                                            int preferred_buffer_size) {
   // Empirically, we consider 20ms of samples to be high latency.
   const double twenty_ms_size = 2.0 * sample_rate / 100;

 #if defined(OS_WIN)
   preferred_buffer_size = std::max(preferred_buffer_size, 1);

   // Windows doesn't use power of two buffer sizes, so we should always round up
   // to the nearest multiple of the output buffer size.
   const int high_latency_buffer_size =
       std::ceil(twenty_ms_size / preferred_buffer_size) * preferred_buffer_size;
 #else
   // On other platforms use the nearest higher power of two buffer size.  For a
   // given sample rate, this works out to:
   //
   //     <= 3200   : 64
   //     <= 6400   : 128
   //     <= 12800  : 256
   //     <= 25600  : 512
   //     <= 51200  : 1024
   //     <= 102400 : 2048
   //     <= 204800 : 4096
   //
   // On Linux, the minimum hardware buffer size is 512, so the lower calculated
   // values are unused.  OSX may have a value as low as 128.
   const int high_latency_buffer_size = RoundUpToPowerOfTwo(twenty_ms_size);
 #endif  // defined(OS_WIN)

 #if defined(OS_CHROMEOS)
   return high_latency_buffer_size;  // No preference.
 #else
   return std::max(preferred_buffer_size, high_latency_buffer_size);
 #endif  // defined(OS_CHROMEOS)
 }

 // static
 int AudioLatency::GetRtcBufferSize(int sample_rate, int hardware_buffer_size) {
   // Use native hardware buffer size as default. On Windows, we strive to open
   // up using this native hardware buffer size to achieve best
   // possible performance and to ensure that no FIFO is needed on the browser
   // side to match the client request. That is why there is no #if case for
   // Windows below.
   int frames_per_buffer = hardware_buffer_size;

   // No |hardware_buffer_size| is specified, fall back to 10 ms buffer size.
   if (!frames_per_buffer) {
     frames_per_buffer = sample_rate / 100;
     DVLOG(1) << "Using 10 ms sink output buffer size: " << frames_per_buffer;
     return frames_per_buffer;
   }

 #if defined(OS_LINUX) || defined(OS_MACOSX)
   // On Linux and MacOS, the low level IO implementations on the browser side
   // supports all buffer size the clients want. We use the native peer
   // connection buffer size (10ms) to achieve best possible performance.
   frames_per_buffer = sample_rate / 100;
 #elif defined(OS_ANDROID)
   // TODO(olka/henrika): This settings are very old, need to be revisited.
   int frames_per_10ms = sample_rate / 100;
   if (frames_per_buffer < 2 * frames_per_10ms) {
     // Examples of low-latency frame sizes and the resulting |buffer_size|:
     //  Nexus 7     : 240 audio frames => 2*480 = 960
     //  Nexus 10    : 256              => 2*441 = 882
     //  Galaxy Nexus: 144              => 2*441 = 882
     frames_per_buffer = 2 * frames_per_10ms;
     DVLOG(1) << "Low-latency output detected on Android";
   }
 #endif

   DVLOG(1) << "Using sink output buffer size: " << frames_per_buffer;
   return frames_per_buffer;
 }

 // static
 int AudioLatency::GetInteractiveBufferSize(int hardware_buffer_size) {
 #if defined(OS_ANDROID)
   // The optimum low-latency hardware buffer size is usually too small on
   // Android for WebAudio to render without glitching. So, if it is small, use
   // a larger size.
   //
   // Since WebAudio renders in 128-frame blocks, the small buffer sizes (144 for
   // a Galaxy Nexus), cause significant processing jitter. Sometimes multiple
   // blocks will processed, but other times will not be since the WebAudio can't
   // satisfy the request. By using a larger render buffer size, we smooth out
   // the jitter.
   const int kSmallBufferSize = 1024;
   const int kDefaultCallbackBufferSize = 2048;
   if (hardware_buffer_size <= kSmallBufferSize)
     return kDefaultCallbackBufferSize;
 #endif

   return hardware_buffer_size;
 }

 }  // namespace media
 }  // namespace cobalt
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "cobalt/media/base/audio_latency.h"

	#include <algorithm>

	#include "base/logging.h"
	#include "build/build_config.h"
	#include "starboard/types.h"

	namespace cobalt {
	namespace media {

	namespace {
	#if !defined(OS_WIN)
	// Taken from "Bit Twiddling Hacks"
	// http://graphics.stanford.edu/~seander/bithacks.html#RoundUpPowerOf2
	uint32_t RoundUpToPowerOfTwo(uint32_t v) {
	v--;
	v \|= v >> 1;
	v \|= v >> 2;
	v \|= v >> 4;
	v \|= v >> 8;
	v \|= v >> 16;
	v++;
	return v;
	}
	#endif
	} // namespace

	// static
	int AudioLatency::GetHighLatencyBufferSize(int sample_rate,
	int preferred_buffer_size) {
	// Empirically, we consider 20ms of samples to be high latency.
	const double twenty_ms_size = 2.0 * sample_rate / 100;

	#if defined(OS_WIN)
	preferred_buffer_size = std::max(preferred_buffer_size, 1);

	// Windows doesn't use power of two buffer sizes, so we should always round up
	// to the nearest multiple of the output buffer size.
	const int high_latency_buffer_size =
	std::ceil(twenty_ms_size / preferred_buffer_size) * preferred_buffer_size;
	#else
	// On other platforms use the nearest higher power of two buffer size. For a
	// given sample rate, this works out to:
	//
	// <= 3200 : 64
	// <= 6400 : 128
	// <= 12800 : 256
	// <= 25600 : 512
	// <= 51200 : 1024
	// <= 102400 : 2048
	// <= 204800 : 4096
	//
	// On Linux, the minimum hardware buffer size is 512, so the lower calculated
	// values are unused. OSX may have a value as low as 128.
	const int high_latency_buffer_size = RoundUpToPowerOfTwo(twenty_ms_size);
	#endif // defined(OS_WIN)

	#if defined(OS_CHROMEOS)
	return high_latency_buffer_size; // No preference.
	#else
	return std::max(preferred_buffer_size, high_latency_buffer_size);
	#endif // defined(OS_CHROMEOS)
	}

	// static
	int AudioLatency::GetRtcBufferSize(int sample_rate, int hardware_buffer_size) {
	// Use native hardware buffer size as default. On Windows, we strive to open
	// up using this native hardware buffer size to achieve best
	// possible performance and to ensure that no FIFO is needed on the browser
	// side to match the client request. That is why there is no #if case for
	// Windows below.
	int frames_per_buffer = hardware_buffer_size;

	// No \|hardware_buffer_size\| is specified, fall back to 10 ms buffer size.
	if (!frames_per_buffer) {
	frames_per_buffer = sample_rate / 100;
	DVLOG(1) << "Using 10 ms sink output buffer size: " << frames_per_buffer;
	return frames_per_buffer;
	}

	#if defined(OS_LINUX) \|\| defined(OS_MACOSX)
	// On Linux and MacOS, the low level IO implementations on the browser side
	// supports all buffer size the clients want. We use the native peer
	// connection buffer size (10ms) to achieve best possible performance.
	frames_per_buffer = sample_rate / 100;
	#elif defined(OS_ANDROID)
	// TODO(olka/henrika): This settings are very old, need to be revisited.
	int frames_per_10ms = sample_rate / 100;
	if (frames_per_buffer < 2 * frames_per_10ms) {
	// Examples of low-latency frame sizes and the resulting \|buffer_size\|:
	// Nexus 7 : 240 audio frames => 2*480 = 960
	// Nexus 10 : 256 => 2*441 = 882
	// Galaxy Nexus: 144 => 2*441 = 882
	frames_per_buffer = 2 * frames_per_10ms;
	DVLOG(1) << "Low-latency output detected on Android";
	}
	#endif

	DVLOG(1) << "Using sink output buffer size: " << frames_per_buffer;
	return frames_per_buffer;
	}

	// static
	int AudioLatency::GetInteractiveBufferSize(int hardware_buffer_size) {
	#if defined(OS_ANDROID)
	// The optimum low-latency hardware buffer size is usually too small on
	// Android for WebAudio to render without glitching. So, if it is small, use
	// a larger size.
	//
	// Since WebAudio renders in 128-frame blocks, the small buffer sizes (144 for
	// a Galaxy Nexus), cause significant processing jitter. Sometimes multiple
	// blocks will processed, but other times will not be since the WebAudio can't
	// satisfy the request. By using a larger render buffer size, we smooth out
	// the jitter.
	const int kSmallBufferSize = 1024;
	const int kDefaultCallbackBufferSize = 2048;
	if (hardware_buffer_size <= kSmallBufferSize)
	return kDefaultCallbackBufferSize;
	#endif

	return hardware_buffer_size;
	}

	} // namespace media
	} // namespace cobalt