media/base/audio_discard_helper.cc - platform/external/chromium_org - Git at Google

 // Copyright 2014 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 "media/base/audio_discard_helper.h"

 #include <algorithm>

 #include "base/logging.h"
 #include "media/base/audio_buffer.h"
 #include "media/base/buffers.h"

 namespace media {

 static void WarnOnNonMonotonicTimestamps(base::TimeDelta last_timestamp,
                                          base::TimeDelta current_timestamp) {
   if (last_timestamp == kNoTimestamp() || last_timestamp < current_timestamp)
     return;

   const base::TimeDelta diff = current_timestamp - last_timestamp;
   DLOG(WARNING) << "Input timestamps are not monotonically increasing! "
                 << " ts " << current_timestamp.InMicroseconds() << " us"
                 << " diff " << diff.InMicroseconds() << " us";
 }

 AudioDiscardHelper::AudioDiscardHelper(int sample_rate, size_t decoder_delay)
     : sample_rate_(sample_rate),
       decoder_delay_(decoder_delay),
       timestamp_helper_(sample_rate_),
       discard_frames_(0),
       last_input_timestamp_(kNoTimestamp()),
       delayed_discard_(false) {
   DCHECK_GT(sample_rate_, 0);
 }

 AudioDiscardHelper::~AudioDiscardHelper() {
 }

 size_t AudioDiscardHelper::TimeDeltaToFrames(base::TimeDelta duration) const {
   DCHECK(duration >= base::TimeDelta());
   return duration.InSecondsF() * sample_rate_ + 0.5;
 }

 void AudioDiscardHelper::Reset(size_t initial_discard) {
   discard_frames_ = initial_discard;
   last_input_timestamp_ = kNoTimestamp();
   timestamp_helper_.SetBaseTimestamp(kNoTimestamp());
   delayed_discard_ = false;
   delayed_discard_padding_ = DecoderBuffer::DiscardPadding();
 }

 bool AudioDiscardHelper::ProcessBuffers(
     const scoped_refptr<DecoderBuffer>& encoded_buffer,
     const scoped_refptr<AudioBuffer>& decoded_buffer) {
   DCHECK(!encoded_buffer->end_of_stream());
   DCHECK(encoded_buffer->timestamp() != kNoTimestamp());

   // Issue a debug warning when we see non-monotonic timestamps.  Only a warning
   // to allow chained OGG playback.
   WarnOnNonMonotonicTimestamps(last_input_timestamp_,
                                encoded_buffer->timestamp());
   last_input_timestamp_ = encoded_buffer->timestamp();

   // If this is the first buffer seen, setup the timestamp helper.
   const bool first_buffer = !initialized();
   if (first_buffer) {
     // Clamp the base timestamp to zero.
     timestamp_helper_.SetBaseTimestamp(
         std::max(base::TimeDelta(), encoded_buffer->timestamp()));
   }
   DCHECK(initialized());

   if (!decoded_buffer) {
     // If there's a one buffer delay for decoding, we need to save it so it can
     // be processed with the next decoder buffer.
     if (first_buffer) {
       delayed_discard_ = true;
       delayed_discard_padding_ = encoded_buffer->discard_padding();
     }
     return false;
   }

   const size_t original_frame_count = decoded_buffer->frame_count();

   // If there's a one buffer delay for decoding, pick up the last encoded
   // buffer's discard padding for processing with the current decoded buffer.
   DecoderBuffer::DiscardPadding current_discard_padding =
       encoded_buffer->discard_padding();
   if (delayed_discard_) {
     // For simplicity disallow cases where decoder delay is present with delayed
     // discard (no codecs at present).  Doing so allows us to avoid complexity
     // around endpoint tracking when handling complete buffer discards.
     DCHECK_EQ(decoder_delay_, 0u);
     std::swap(current_discard_padding, delayed_discard_padding_);
   }

   if (discard_frames_ > 0) {
     const size_t decoded_frames = decoded_buffer->frame_count();
     const size_t frames_to_discard = std::min(discard_frames_, decoded_frames);
     discard_frames_ -= frames_to_discard;

     // If everything would be discarded, indicate a new buffer is required.
     if (frames_to_discard == decoded_frames) {
       // For simplicity disallow cases where a buffer with discard padding is
       // present.  Doing so allows us to avoid complexity around tracking
       // discards across buffers.
       DCHECK(current_discard_padding.first == base::TimeDelta());
       DCHECK(current_discard_padding.second == base::TimeDelta());
       return false;
     }

     decoded_buffer->TrimStart(frames_to_discard);
   }

   // Handle front discard padding.
   if (current_discard_padding.first > base::TimeDelta()) {
     const size_t decoded_frames = decoded_buffer->frame_count();

     // If a complete buffer discard is requested and there's no decoder delay,
     // just discard all remaining frames from this buffer.  With decoder delay
     // we have to estimate the correct number of frames to discard based on the
     // duration of the encoded buffer.
     const size_t start_frames_to_discard =
         current_discard_padding.first == kInfiniteDuration()
             ? (decoder_delay_ > 0
                    ? TimeDeltaToFrames(encoded_buffer->duration())
                    : decoded_frames)
             : TimeDeltaToFrames(current_discard_padding.first);

     // Regardless of the timestamp on the encoded buffer, the corresponding
     // decoded output will appear |decoder_delay_| frames later.
     size_t discard_start = decoder_delay_;
     if (decoder_delay_ > 0) {
       // If we have a |decoder_delay_| and have already discarded frames from
       // this buffer, the |discard_start| must be adjusted by the number of
       // frames already discarded.
       const size_t frames_discarded_so_far =
           original_frame_count - decoded_buffer->frame_count();
       CHECK_LE(frames_discarded_so_far, decoder_delay_);
       discard_start -= frames_discarded_so_far;
     }

     // For simplicity require the start of the discard to be within the current
     // buffer.  Doing so allows us avoid complexity around tracking discards
     // across buffers.
     CHECK_LT(discard_start, decoded_frames);

     const size_t frames_to_discard =
         std::min(start_frames_to_discard, decoded_frames - discard_start);

     // Carry over any frames which need to be discarded from the front of the
     // next buffer.
     DCHECK(!discard_frames_);
     discard_frames_ = start_frames_to_discard - frames_to_discard;

     // If everything would be discarded, indicate a new buffer is required.
     if (frames_to_discard == decoded_frames) {
       // The buffer should not have been marked with end discard if the front
       // discard removes everything.
       DCHECK(current_discard_padding.second == base::TimeDelta());
       return false;
     }

     decoded_buffer->TrimRange(discard_start, discard_start + frames_to_discard);
   } else {
     DCHECK(current_discard_padding.first == base::TimeDelta());
   }

   // Handle end discard padding.
   if (current_discard_padding.second > base::TimeDelta()) {
     // Limit end discarding to when there is no |decoder_delay_|, otherwise it's
     // non-trivial determining where to start discarding end frames.
     CHECK(!decoder_delay_);

     const size_t decoded_frames = decoded_buffer->frame_count();
     const size_t end_frames_to_discard =
         TimeDeltaToFrames(current_discard_padding.second);

     if (end_frames_to_discard > decoded_frames) {
       DLOG(ERROR) << "Encountered invalid discard padding value.";
       return false;
     }

     // If everything would be discarded, indicate a new buffer is required.
     if (end_frames_to_discard == decoded_frames)
       return false;

     decoded_buffer->TrimEnd(end_frames_to_discard);
   } else {
     DCHECK(current_discard_padding.second == base::TimeDelta());
   }

   // Assign timestamp to the buffer.
   decoded_buffer->set_timestamp(timestamp_helper_.GetTimestamp());
   timestamp_helper_.AddFrames(decoded_buffer->frame_count());
   return true;
 }

 }  // namespace media
	// Copyright 2014 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 "media/base/audio_discard_helper.h"

	#include <algorithm>

	#include "base/logging.h"
	#include "media/base/audio_buffer.h"
	#include "media/base/buffers.h"

	namespace media {

	static void WarnOnNonMonotonicTimestamps(base::TimeDelta last_timestamp,
	base::TimeDelta current_timestamp) {
	if (last_timestamp == kNoTimestamp() \|\| last_timestamp < current_timestamp)
	return;

	const base::TimeDelta diff = current_timestamp - last_timestamp;
	DLOG(WARNING) << "Input timestamps are not monotonically increasing! "
	<< " ts " << current_timestamp.InMicroseconds() << " us"
	<< " diff " << diff.InMicroseconds() << " us";
	}

	AudioDiscardHelper::AudioDiscardHelper(int sample_rate, size_t decoder_delay)
	: sample_rate_(sample_rate),
	decoder_delay_(decoder_delay),
	timestamp_helper_(sample_rate_),
	discard_frames_(0),
	last_input_timestamp_(kNoTimestamp()),
	delayed_discard_(false) {
	DCHECK_GT(sample_rate_, 0);
	}

	AudioDiscardHelper::~AudioDiscardHelper() {
	}

	size_t AudioDiscardHelper::TimeDeltaToFrames(base::TimeDelta duration) const {
	DCHECK(duration >= base::TimeDelta());
	return duration.InSecondsF() * sample_rate_ + 0.5;
	}

	void AudioDiscardHelper::Reset(size_t initial_discard) {
	discard_frames_ = initial_discard;
	last_input_timestamp_ = kNoTimestamp();
	timestamp_helper_.SetBaseTimestamp(kNoTimestamp());
	delayed_discard_ = false;
	delayed_discard_padding_ = DecoderBuffer::DiscardPadding();
	}

	bool AudioDiscardHelper::ProcessBuffers(
	const scoped_refptr<DecoderBuffer>& encoded_buffer,
	const scoped_refptr<AudioBuffer>& decoded_buffer) {
	DCHECK(!encoded_buffer->end_of_stream());
	DCHECK(encoded_buffer->timestamp() != kNoTimestamp());

	// Issue a debug warning when we see non-monotonic timestamps. Only a warning
	// to allow chained OGG playback.
	WarnOnNonMonotonicTimestamps(last_input_timestamp_,
	encoded_buffer->timestamp());
	last_input_timestamp_ = encoded_buffer->timestamp();

	// If this is the first buffer seen, setup the timestamp helper.
	const bool first_buffer = !initialized();
	if (first_buffer) {
	// Clamp the base timestamp to zero.
	timestamp_helper_.SetBaseTimestamp(
	std::max(base::TimeDelta(), encoded_buffer->timestamp()));
	}
	DCHECK(initialized());

	if (!decoded_buffer) {
	// If there's a one buffer delay for decoding, we need to save it so it can
	// be processed with the next decoder buffer.
	if (first_buffer) {
	delayed_discard_ = true;
	delayed_discard_padding_ = encoded_buffer->discard_padding();
	}
	return false;
	}

	const size_t original_frame_count = decoded_buffer->frame_count();

	// If there's a one buffer delay for decoding, pick up the last encoded
	// buffer's discard padding for processing with the current decoded buffer.
	DecoderBuffer::DiscardPadding current_discard_padding =
	encoded_buffer->discard_padding();
	if (delayed_discard_) {
	// For simplicity disallow cases where decoder delay is present with delayed
	// discard (no codecs at present). Doing so allows us to avoid complexity
	// around endpoint tracking when handling complete buffer discards.
	DCHECK_EQ(decoder_delay_, 0u);
	std::swap(current_discard_padding, delayed_discard_padding_);
	}

	if (discard_frames_ > 0) {
	const size_t decoded_frames = decoded_buffer->frame_count();
	const size_t frames_to_discard = std::min(discard_frames_, decoded_frames);
	discard_frames_ -= frames_to_discard;

	// If everything would be discarded, indicate a new buffer is required.
	if (frames_to_discard == decoded_frames) {
	// For simplicity disallow cases where a buffer with discard padding is
	// present. Doing so allows us to avoid complexity around tracking
	// discards across buffers.
	DCHECK(current_discard_padding.first == base::TimeDelta());
	DCHECK(current_discard_padding.second == base::TimeDelta());
	return false;
	}

	decoded_buffer->TrimStart(frames_to_discard);
	}

	// Handle front discard padding.
	if (current_discard_padding.first > base::TimeDelta()) {
	const size_t decoded_frames = decoded_buffer->frame_count();

	// If a complete buffer discard is requested and there's no decoder delay,
	// just discard all remaining frames from this buffer. With decoder delay
	// we have to estimate the correct number of frames to discard based on the
	// duration of the encoded buffer.
	const size_t start_frames_to_discard =
	current_discard_padding.first == kInfiniteDuration()
	? (decoder_delay_ > 0
	? TimeDeltaToFrames(encoded_buffer->duration())
	: decoded_frames)
	: TimeDeltaToFrames(current_discard_padding.first);

	// Regardless of the timestamp on the encoded buffer, the corresponding
	// decoded output will appear \|decoder_delay_\| frames later.
	size_t discard_start = decoder_delay_;
	if (decoder_delay_ > 0) {
	// If we have a \|decoder_delay_\| and have already discarded frames from
	// this buffer, the \|discard_start\| must be adjusted by the number of
	// frames already discarded.
	const size_t frames_discarded_so_far =
	original_frame_count - decoded_buffer->frame_count();
	CHECK_LE(frames_discarded_so_far, decoder_delay_);
	discard_start -= frames_discarded_so_far;
	}

	// For simplicity require the start of the discard to be within the current
	// buffer. Doing so allows us avoid complexity around tracking discards
	// across buffers.
	CHECK_LT(discard_start, decoded_frames);

	const size_t frames_to_discard =
	std::min(start_frames_to_discard, decoded_frames - discard_start);

	// Carry over any frames which need to be discarded from the front of the
	// next buffer.
	DCHECK(!discard_frames_);
	discard_frames_ = start_frames_to_discard - frames_to_discard;

	// If everything would be discarded, indicate a new buffer is required.
	if (frames_to_discard == decoded_frames) {
	// The buffer should not have been marked with end discard if the front
	// discard removes everything.
	DCHECK(current_discard_padding.second == base::TimeDelta());
	return false;
	}

	decoded_buffer->TrimRange(discard_start, discard_start + frames_to_discard);
	} else {
	DCHECK(current_discard_padding.first == base::TimeDelta());
	}

	// Handle end discard padding.
	if (current_discard_padding.second > base::TimeDelta()) {
	// Limit end discarding to when there is no \|decoder_delay_\|, otherwise it's
	// non-trivial determining where to start discarding end frames.
	CHECK(!decoder_delay_);

	const size_t decoded_frames = decoded_buffer->frame_count();
	const size_t end_frames_to_discard =
	TimeDeltaToFrames(current_discard_padding.second);

	if (end_frames_to_discard > decoded_frames) {
	DLOG(ERROR) << "Encountered invalid discard padding value.";
	return false;
	}

	// If everything would be discarded, indicate a new buffer is required.
	if (end_frames_to_discard == decoded_frames)
	return false;

	decoded_buffer->TrimEnd(end_frames_to_discard);
	} else {
	DCHECK(current_discard_padding.second == base::TimeDelta());
	}

	// Assign timestamp to the buffer.
	decoded_buffer->set_timestamp(timestamp_helper_.GetTimestamp());
	timestamp_helper_.AddFrames(decoded_buffer->frame_count());
	return true;
	}

	} // namespace media