modules/audio_coding/neteq/decision_logic_normal.cc - src.git - Git at Google

 /*
  *  Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "modules/audio_coding/neteq/decision_logic_normal.h"

 #include <assert.h>

 #include <algorithm>

 #include "modules/audio_coding/neteq/buffer_level_filter.h"
 #include "modules/audio_coding/neteq/decoder_database.h"
 #include "modules/audio_coding/neteq/delay_manager.h"
 #include "modules/audio_coding/neteq/expand.h"
 #include "modules/audio_coding/neteq/packet_buffer.h"
 #include "modules/audio_coding/neteq/sync_buffer.h"
 #include "modules/include/module_common_types.h"

 namespace webrtc {

 Operations DecisionLogicNormal::GetDecisionSpecialized(
     const SyncBuffer& sync_buffer,
     const Expand& expand,
     size_t decoder_frame_length,
     const Packet* next_packet,
     Modes prev_mode,
     bool play_dtmf,
     bool* reset_decoder,
     size_t generated_noise_samples) {
   assert(playout_mode_ == kPlayoutOn || playout_mode_ == kPlayoutStreaming);
   // Guard for errors, to avoid getting stuck in error mode.
   if (prev_mode == kModeError) {
     if (!next_packet) {
       return kExpand;
     } else {
       return kUndefined;  // Use kUndefined to flag for a reset.
     }
   }

   uint32_t target_timestamp = sync_buffer.end_timestamp();
   uint32_t available_timestamp = 0;
   bool is_cng_packet = false;
   if (next_packet) {
     available_timestamp = next_packet->timestamp;
     is_cng_packet =
         decoder_database_->IsComfortNoise(next_packet->payload_type);
   }

   if (is_cng_packet) {
     return CngOperation(prev_mode, target_timestamp, available_timestamp,
                         generated_noise_samples);
   }

   // Handle the case with no packet at all available (except maybe DTMF).
   if (!next_packet) {
     return NoPacket(play_dtmf);
   }

   // If the expand period was very long, reset NetEQ since it is likely that the
   // sender was restarted.
   if (num_consecutive_expands_ > kReinitAfterExpands) {
     *reset_decoder = true;
     return kNormal;
   }

   const uint32_t five_seconds_samples =
       static_cast<uint32_t>(5 * 8000 * fs_mult_);
   // Check if the required packet is available.
   if (target_timestamp == available_timestamp) {
     return ExpectedPacketAvailable(prev_mode, play_dtmf);
   } else if (!PacketBuffer::IsObsoleteTimestamp(
                  available_timestamp, target_timestamp, five_seconds_samples)) {
     return FuturePacketAvailable(sync_buffer, expand, decoder_frame_length,
                                  prev_mode, target_timestamp,
                                  available_timestamp, play_dtmf,
                                  generated_noise_samples);
   } else {
     // This implies that available_timestamp < target_timestamp, which can
     // happen when a new stream or codec is received. Signal for a reset.
     return kUndefined;
   }
 }

 Operations DecisionLogicNormal::CngOperation(Modes prev_mode,
                                              uint32_t target_timestamp,
                                              uint32_t available_timestamp,
                                              size_t generated_noise_samples) {
   // Signed difference between target and available timestamp.
   int32_t timestamp_diff = static_cast<int32_t>(
       static_cast<uint32_t>(generated_noise_samples + target_timestamp) -
       available_timestamp);
   int32_t optimal_level_samp = static_cast<int32_t>(
       (delay_manager_->TargetLevel() * packet_length_samples_) >> 8);
   const int64_t excess_waiting_time_samp =
       -static_cast<int64_t>(timestamp_diff) - optimal_level_samp;

   if (excess_waiting_time_samp > optimal_level_samp / 2) {
     // The waiting time for this packet will be longer than 1.5
     // times the wanted buffer delay. Apply fast-forward to cut the
     // waiting time down to the optimal.
     noise_fast_forward_ = rtc::dchecked_cast<size_t>(noise_fast_forward_ +
                                                      excess_waiting_time_samp);
     timestamp_diff =
         rtc::saturated_cast<int32_t>(timestamp_diff + excess_waiting_time_samp);
   }

   if (timestamp_diff < 0 && prev_mode == kModeRfc3389Cng) {
     // Not time to play this packet yet. Wait another round before using this
     // packet. Keep on playing CNG from previous CNG parameters.
     return kRfc3389CngNoPacket;
   } else {
     // Otherwise, go for the CNG packet now.
     noise_fast_forward_ = 0;
     return kRfc3389Cng;
   }
 }

 Operations DecisionLogicNormal::NoPacket(bool play_dtmf) {
   if (cng_state_ == kCngRfc3389On) {
     // Keep on playing comfort noise.
     return kRfc3389CngNoPacket;
   } else if (cng_state_ == kCngInternalOn) {
     // Keep on playing codec internal comfort noise.
     return kCodecInternalCng;
   } else if (play_dtmf) {
     return kDtmf;
   } else {
     // Nothing to play, do expand.
     return kExpand;
   }
 }

 Operations DecisionLogicNormal::ExpectedPacketAvailable(Modes prev_mode,
                                                         bool play_dtmf) {
   if (prev_mode != kModeExpand && !play_dtmf) {
     // Check criterion for time-stretching.
     int low_limit, high_limit;
     delay_manager_->BufferLimits(&low_limit, &high_limit);
     if (buffer_level_filter_->filtered_current_level() >= high_limit << 2)
       return kFastAccelerate;
     if (TimescaleAllowed()) {
       if (buffer_level_filter_->filtered_current_level() >= high_limit)
         return kAccelerate;
       if (buffer_level_filter_->filtered_current_level() < low_limit)
         return kPreemptiveExpand;
     }
   }
   return kNormal;
 }

 Operations DecisionLogicNormal::FuturePacketAvailable(
     const SyncBuffer& sync_buffer,
     const Expand& expand,
     size_t decoder_frame_length,
     Modes prev_mode,
     uint32_t target_timestamp,
     uint32_t available_timestamp,
     bool play_dtmf,
     size_t generated_noise_samples) {
   // Required packet is not available, but a future packet is.
   // Check if we should continue with an ongoing expand because the new packet
   // is too far into the future.
   uint32_t timestamp_leap = available_timestamp - target_timestamp;
   if ((prev_mode == kModeExpand) &&
       !ReinitAfterExpands(timestamp_leap) &&
       !MaxWaitForPacket() &&
       PacketTooEarly(timestamp_leap) &&
       UnderTargetLevel()) {
     if (play_dtmf) {
       // Still have DTMF to play, so do not do expand.
       return kDtmf;
     } else {
       // Nothing to play.
       return kExpand;
     }
   }

   const size_t samples_left =
       sync_buffer.FutureLength() - expand.overlap_length();
   const size_t cur_size_samples = samples_left +
       packet_buffer_.NumPacketsInBuffer() * decoder_frame_length;

   // If previous was comfort noise, then no merge is needed.
   if (prev_mode == kModeRfc3389Cng ||
       prev_mode == kModeCodecInternalCng) {
     // Keep the same delay as before the CNG, but make sure that the number of
     // samples in buffer is no higher than 4 times the optimal level. (Note that
     // TargetLevel() is in Q8.)
     if (static_cast<uint32_t>(generated_noise_samples + target_timestamp) >=
             available_timestamp ||
         cur_size_samples >
             ((delay_manager_->TargetLevel() * packet_length_samples_) >> 8) *
             4) {
       // Time to play this new packet.
       return kNormal;
     } else {
       // Too early to play this new packet; keep on playing comfort noise.
       if (prev_mode == kModeRfc3389Cng) {
         return kRfc3389CngNoPacket;
       } else {  // prevPlayMode == kModeCodecInternalCng.
         return kCodecInternalCng;
       }
     }
   }
   // Do not merge unless we have done an expand before.
   if (prev_mode == kModeExpand) {
     return kMerge;
   } else if (play_dtmf) {
     // Play DTMF instead of expand.
     return kDtmf;
   } else {
     return kExpand;
   }
 }

 bool DecisionLogicNormal::UnderTargetLevel() const {
   return buffer_level_filter_->filtered_current_level() <=
       delay_manager_->TargetLevel();
 }

 bool DecisionLogicNormal::ReinitAfterExpands(uint32_t timestamp_leap) const {
   return timestamp_leap >=
       static_cast<uint32_t>(output_size_samples_ * kReinitAfterExpands);
 }

 bool DecisionLogicNormal::PacketTooEarly(uint32_t timestamp_leap) const {
   return timestamp_leap >
       static_cast<uint32_t>(output_size_samples_ * num_consecutive_expands_);
 }

 bool DecisionLogicNormal::MaxWaitForPacket() const {
   return num_consecutive_expands_ >= kMaxWaitForPacket;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "modules/audio_coding/neteq/decision_logic_normal.h"

	#include <assert.h>

	#include <algorithm>

	#include "modules/audio_coding/neteq/buffer_level_filter.h"
	#include "modules/audio_coding/neteq/decoder_database.h"
	#include "modules/audio_coding/neteq/delay_manager.h"
	#include "modules/audio_coding/neteq/expand.h"
	#include "modules/audio_coding/neteq/packet_buffer.h"
	#include "modules/audio_coding/neteq/sync_buffer.h"
	#include "modules/include/module_common_types.h"

	namespace webrtc {

	Operations DecisionLogicNormal::GetDecisionSpecialized(
	const SyncBuffer& sync_buffer,
	const Expand& expand,
	size_t decoder_frame_length,
	const Packet* next_packet,
	Modes prev_mode,
	bool play_dtmf,
	bool* reset_decoder,
	size_t generated_noise_samples) {
	assert(playout_mode_ == kPlayoutOn \|\| playout_mode_ == kPlayoutStreaming);
	// Guard for errors, to avoid getting stuck in error mode.
	if (prev_mode == kModeError) {
	if (!next_packet) {
	return kExpand;
	} else {
	return kUndefined; // Use kUndefined to flag for a reset.
	}
	}

	uint32_t target_timestamp = sync_buffer.end_timestamp();
	uint32_t available_timestamp = 0;
	bool is_cng_packet = false;
	if (next_packet) {
	available_timestamp = next_packet->timestamp;
	is_cng_packet =
	decoder_database_->IsComfortNoise(next_packet->payload_type);
	}

	if (is_cng_packet) {
	return CngOperation(prev_mode, target_timestamp, available_timestamp,
	generated_noise_samples);
	}

	// Handle the case with no packet at all available (except maybe DTMF).
	if (!next_packet) {
	return NoPacket(play_dtmf);
	}

	// If the expand period was very long, reset NetEQ since it is likely that the
	// sender was restarted.
	if (num_consecutive_expands_ > kReinitAfterExpands) {
	*reset_decoder = true;
	return kNormal;
	}

	const uint32_t five_seconds_samples =
	static_cast<uint32_t>(5 * 8000 * fs_mult_);
	// Check if the required packet is available.
	if (target_timestamp == available_timestamp) {
	return ExpectedPacketAvailable(prev_mode, play_dtmf);
	} else if (!PacketBuffer::IsObsoleteTimestamp(
	available_timestamp, target_timestamp, five_seconds_samples)) {
	return FuturePacketAvailable(sync_buffer, expand, decoder_frame_length,
	prev_mode, target_timestamp,
	available_timestamp, play_dtmf,
	generated_noise_samples);
	} else {
	// This implies that available_timestamp < target_timestamp, which can
	// happen when a new stream or codec is received. Signal for a reset.
	return kUndefined;
	}
	}

	Operations DecisionLogicNormal::CngOperation(Modes prev_mode,
	uint32_t target_timestamp,
	uint32_t available_timestamp,
	size_t generated_noise_samples) {
	// Signed difference between target and available timestamp.
	int32_t timestamp_diff = static_cast<int32_t>(
	static_cast<uint32_t>(generated_noise_samples + target_timestamp) -
	available_timestamp);
	int32_t optimal_level_samp = static_cast<int32_t>(
	(delay_manager_->TargetLevel() * packet_length_samples_) >> 8);
	const int64_t excess_waiting_time_samp =
	-static_cast<int64_t>(timestamp_diff) - optimal_level_samp;

	if (excess_waiting_time_samp > optimal_level_samp / 2) {
	// The waiting time for this packet will be longer than 1.5
	// times the wanted buffer delay. Apply fast-forward to cut the
	// waiting time down to the optimal.
	noise_fast_forward_ = rtc::dchecked_cast<size_t>(noise_fast_forward_ +
	excess_waiting_time_samp);
	timestamp_diff =
	rtc::saturated_cast<int32_t>(timestamp_diff + excess_waiting_time_samp);
	}

	if (timestamp_diff < 0 && prev_mode == kModeRfc3389Cng) {
	// Not time to play this packet yet. Wait another round before using this
	// packet. Keep on playing CNG from previous CNG parameters.
	return kRfc3389CngNoPacket;
	} else {
	// Otherwise, go for the CNG packet now.
	noise_fast_forward_ = 0;
	return kRfc3389Cng;
	}
	}

	Operations DecisionLogicNormal::NoPacket(bool play_dtmf) {
	if (cng_state_ == kCngRfc3389On) {
	// Keep on playing comfort noise.
	return kRfc3389CngNoPacket;
	} else if (cng_state_ == kCngInternalOn) {
	// Keep on playing codec internal comfort noise.
	return kCodecInternalCng;
	} else if (play_dtmf) {
	return kDtmf;
	} else {
	// Nothing to play, do expand.
	return kExpand;
	}
	}

	Operations DecisionLogicNormal::ExpectedPacketAvailable(Modes prev_mode,
	bool play_dtmf) {
	if (prev_mode != kModeExpand && !play_dtmf) {
	// Check criterion for time-stretching.
	int low_limit, high_limit;
	delay_manager_->BufferLimits(&low_limit, &high_limit);
	if (buffer_level_filter_->filtered_current_level() >= high_limit << 2)
	return kFastAccelerate;
	if (TimescaleAllowed()) {
	if (buffer_level_filter_->filtered_current_level() >= high_limit)
	return kAccelerate;
	if (buffer_level_filter_->filtered_current_level() < low_limit)
	return kPreemptiveExpand;
	}
	}
	return kNormal;
	}

	Operations DecisionLogicNormal::FuturePacketAvailable(
	const SyncBuffer& sync_buffer,
	const Expand& expand,
	size_t decoder_frame_length,
	Modes prev_mode,
	uint32_t target_timestamp,
	uint32_t available_timestamp,
	bool play_dtmf,
	size_t generated_noise_samples) {
	// Required packet is not available, but a future packet is.
	// Check if we should continue with an ongoing expand because the new packet
	// is too far into the future.
	uint32_t timestamp_leap = available_timestamp - target_timestamp;
	if ((prev_mode == kModeExpand) &&
	!ReinitAfterExpands(timestamp_leap) &&
	!MaxWaitForPacket() &&
	PacketTooEarly(timestamp_leap) &&
	UnderTargetLevel()) {
	if (play_dtmf) {
	// Still have DTMF to play, so do not do expand.
	return kDtmf;
	} else {
	// Nothing to play.
	return kExpand;
	}
	}

	const size_t samples_left =
	sync_buffer.FutureLength() - expand.overlap_length();
	const size_t cur_size_samples = samples_left +
	packet_buffer_.NumPacketsInBuffer() * decoder_frame_length;

	// If previous was comfort noise, then no merge is needed.
	if (prev_mode == kModeRfc3389Cng \|\|
	prev_mode == kModeCodecInternalCng) {
	// Keep the same delay as before the CNG, but make sure that the number of
	// samples in buffer is no higher than 4 times the optimal level. (Note that
	// TargetLevel() is in Q8.)
	if (static_cast<uint32_t>(generated_noise_samples + target_timestamp) >=
	available_timestamp \|\|
	cur_size_samples >
	((delay_manager_->TargetLevel() * packet_length_samples_) >> 8) *
	4) {
	// Time to play this new packet.
	return kNormal;
	} else {
	// Too early to play this new packet; keep on playing comfort noise.
	if (prev_mode == kModeRfc3389Cng) {
	return kRfc3389CngNoPacket;
	} else { // prevPlayMode == kModeCodecInternalCng.
	return kCodecInternalCng;
	}
	}
	}
	// Do not merge unless we have done an expand before.
	if (prev_mode == kModeExpand) {
	return kMerge;
	} else if (play_dtmf) {
	// Play DTMF instead of expand.
	return kDtmf;
	} else {
	return kExpand;
	}
	}

	bool DecisionLogicNormal::UnderTargetLevel() const {
	return buffer_level_filter_->filtered_current_level() <=
	delay_manager_->TargetLevel();
	}

	bool DecisionLogicNormal::ReinitAfterExpands(uint32_t timestamp_leap) const {
	return timestamp_leap >=
	static_cast<uint32_t>(output_size_samples_ * kReinitAfterExpands);
	}

	bool DecisionLogicNormal::PacketTooEarly(uint32_t timestamp_leap) const {
	return timestamp_leap >
	static_cast<uint32_t>(output_size_samples_ * num_consecutive_expands_);
	}

	bool DecisionLogicNormal::MaxWaitForPacket() const {
	return num_consecutive_expands_ >= kMaxWaitForPacket;
	}

	} // namespace webrtc