media/engine/simulcast.cc - src - Git at Google

 /*
  *  Copyright (c) 2014 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 <stdio.h>
 #include <algorithm>
 #include <string>

 #include "media/base/streamparams.h"
 #include "media/engine/constants.h"
 #include "media/engine/simulcast.h"
 #include "rtc_base/arraysize.h"
 #include "rtc_base/logging.h"
 #include "system_wrappers/include/field_trial.h"

 namespace cricket {

 struct SimulcastFormat {
   int width;
   int height;
   // The maximum number of simulcast layers can be used for
   // resolutions at |widthxheigh|.
   size_t max_layers;
   // The maximum bitrate for encoding stream at |widthxheight|, when we are
   // not sending the next higher spatial stream.
   int max_bitrate_kbps;
   // The target bitrate for encoding stream at |widthxheight|, when this layer
   // is not the highest layer (i.e., when we are sending another higher spatial
   // stream).
   int target_bitrate_kbps;
   // The minimum bitrate needed for encoding stream at |widthxheight|.
   int min_bitrate_kbps;
 };

 // These tables describe from which resolution we can use how many
 // simulcast layers at what bitrates (maximum, target, and minimum).
 // Important!! Keep this table from high resolution to low resolution.
 const SimulcastFormat kSimulcastFormats[] = {
   {1920, 1080, 3, 5000, 4000, 800},
   {1280, 720, 3,  2500, 2500, 600},
   {960, 540, 3, 900, 900, 450},
   {640, 360, 2, 700, 500, 150},
   {480, 270, 2, 450, 350, 150},
   {320, 180, 1, 200, 150, 30},
   {0, 0, 1, 200, 150, 30}
 };

 const int kMaxScreenshareSimulcastStreams = 2;

 // Multiway: Number of temporal layers for each simulcast stream, for maximum
 // possible number of simulcast streams |kMaxSimulcastStreams|. The array
 // goes from lowest resolution at position 0 to highest resolution.
 // For example, first three elements correspond to say: QVGA, VGA, WHD.
 static const int
     kDefaultConferenceNumberOfTemporalLayers[webrtc::kMaxSimulcastStreams] =
     {3, 3, 3, 3};

 void GetSimulcastSsrcs(const StreamParams& sp, std::vector<uint32_t>* ssrcs) {
   const SsrcGroup* sim_group = sp.get_ssrc_group(kSimSsrcGroupSemantics);
   if (sim_group) {
     ssrcs->insert(
         ssrcs->end(), sim_group->ssrcs.begin(), sim_group->ssrcs.end());
   }
 }

 void MaybeExchangeWidthHeight(int* width, int* height) {
   // |kSimulcastFormats| assumes |width| >= |height|. If not, exchange them
   // before comparing.
   if (*width < *height) {
     int temp = *width;
     *width = *height;
     *height = temp;
   }
 }

 int FindSimulcastFormatIndex(int width, int height) {
   MaybeExchangeWidthHeight(&width, &height);

   for (uint32_t i = 0; i < arraysize(kSimulcastFormats); ++i) {
     if (width * height >=
         kSimulcastFormats[i].width * kSimulcastFormats[i].height) {
       return i;
     }
   }
   return -1;
 }

 int FindSimulcastFormatIndex(int width, int height, size_t max_layers) {
   MaybeExchangeWidthHeight(&width, &height);

   for (uint32_t i = 0; i < arraysize(kSimulcastFormats); ++i) {
     if (width * height >=
             kSimulcastFormats[i].width * kSimulcastFormats[i].height &&
         max_layers == kSimulcastFormats[i].max_layers) {
       return i;
     }
   }
   return -1;
 }

 // Simulcast stream width and height must both be dividable by
 // |2 ^ simulcast_layers - 1|.
 int NormalizeSimulcastSize(int size, size_t simulcast_layers) {
   const int base2_exponent = static_cast<int>(simulcast_layers) - 1;
   return ((size >> base2_exponent) << base2_exponent);
 }

 size_t FindSimulcastMaxLayers(int width, int height) {
   int index = FindSimulcastFormatIndex(width, height);
   if (index == -1) {
     return -1;
   }
   return kSimulcastFormats[index].max_layers;
 }

 // TODO(marpan): Investigate if we should return 0 instead of -1 in
 // FindSimulcast[Max/Target/Min]Bitrate functions below, since the
 // codec struct max/min/targeBitrates are unsigned.
 int FindSimulcastMaxBitrateBps(int width, int height) {
   const int format_index = FindSimulcastFormatIndex(width, height);
   if (format_index == -1) {
     return -1;
   }
   return kSimulcastFormats[format_index].max_bitrate_kbps * 1000;
 }

 int FindSimulcastTargetBitrateBps(int width, int height) {
   const int format_index = FindSimulcastFormatIndex(width, height);
   if (format_index == -1) {
     return -1;
   }
   return kSimulcastFormats[format_index].target_bitrate_kbps * 1000;
 }

 int FindSimulcastMinBitrateBps(int width, int height) {
   const int format_index = FindSimulcastFormatIndex(width, height);
   if (format_index == -1) {
     return -1;
   }
   return kSimulcastFormats[format_index].min_bitrate_kbps * 1000;
 }

 bool SlotSimulcastMaxResolution(size_t max_layers, int* width, int* height) {
   int index = FindSimulcastFormatIndex(*width, *height, max_layers);
   if (index == -1) {
     RTC_LOG(LS_ERROR) << "SlotSimulcastMaxResolution";
     return false;
   }

   *width = kSimulcastFormats[index].width;
   *height = kSimulcastFormats[index].height;
   RTC_LOG(LS_INFO) << "SlotSimulcastMaxResolution to width:" << *width
                    << " height:" << *height;
   return true;
 }

 int GetTotalMaxBitrateBps(const std::vector<webrtc::VideoStream>& streams) {
   int total_max_bitrate_bps = 0;
   for (size_t s = 0; s < streams.size() - 1; ++s) {
     total_max_bitrate_bps += streams[s].target_bitrate_bps;
   }
   total_max_bitrate_bps += streams.back().max_bitrate_bps;
   return total_max_bitrate_bps;
 }

 std::vector<webrtc::VideoStream> GetSimulcastConfig(size_t max_streams,
                                                     int width,
                                                     int height,
                                                     int max_bitrate_bps,
                                                     int max_qp,
                                                     int max_framerate,
                                                     bool is_screencast) {
   size_t num_simulcast_layers;
   if (is_screencast) {
     if (UseSimulcastScreenshare()) {
       num_simulcast_layers =
           std::min<int>(max_streams, kMaxScreenshareSimulcastStreams);
     } else {
       num_simulcast_layers = 1;
     }
   } else {
     num_simulcast_layers = FindSimulcastMaxLayers(width, height);
   }

   if (num_simulcast_layers > max_streams) {
     // If the number of SSRCs in the group differs from our target
     // number of simulcast streams for current resolution, switch down
     // to a resolution that matches our number of SSRCs.
     if (!SlotSimulcastMaxResolution(max_streams, &width, &height)) {
       return std::vector<webrtc::VideoStream>();
     }
     num_simulcast_layers = max_streams;
   }
   std::vector<webrtc::VideoStream> streams;
   streams.resize(num_simulcast_layers);

   if (is_screencast) {
     ScreenshareLayerConfig config = ScreenshareLayerConfig::GetDefault();
     // For legacy screenshare in conference mode, tl0 and tl1 bitrates are
     // piggybacked on the VideoCodec struct as target and max bitrates,
     // respectively. See eg. webrtc::VP8EncoderImpl::SetRates().
     streams[0].width = width;
     streams[0].height = height;
     streams[0].max_qp = max_qp;
     streams[0].max_framerate = 5;
     streams[0].min_bitrate_bps = kMinVideoBitrateBps;
     streams[0].target_bitrate_bps = config.tl0_bitrate_kbps * 1000;
     streams[0].max_bitrate_bps = config.tl1_bitrate_kbps * 1000;
     streams[0].temporal_layer_thresholds_bps.clear();
     streams[0].temporal_layer_thresholds_bps.push_back(config.tl0_bitrate_kbps *
                                                        1000);

     // With simulcast enabled, add another spatial layer. This one will have a
     // more normal layout, with the regular 3 temporal layer pattern and no fps
     // restrictions. The base simulcast stream will still use legacy setup.
     if (num_simulcast_layers == kMaxScreenshareSimulcastStreams) {
       // Add optional upper simulcast layer.
       // Lowest temporal layers of a 3 layer setup will have 40% of the total
       // bitrate allocation for that stream. Make sure the gap between the
       // target of the lower stream and first temporal layer of the higher one
       // is at most 2x the bitrate, so that upswitching is not hampered by
       // stalled bitrate estimates.
       int max_bitrate_bps = 2 * ((streams[0].target_bitrate_bps * 10) / 4);
       // Cap max bitrate so it isn't overly high for the given resolution.
       max_bitrate_bps = std::min<int>(
           max_bitrate_bps, FindSimulcastMaxBitrateBps(width, height));

       streams[1].width = width;
       streams[1].height = height;
       streams[1].max_qp = max_qp;
       streams[1].max_framerate = max_framerate;
       // Three temporal layers means two thresholds.
       streams[1].temporal_layer_thresholds_bps.resize(2);
       streams[1].min_bitrate_bps = streams[0].target_bitrate_bps * 2;
       streams[1].target_bitrate_bps = max_bitrate_bps;
       streams[1].max_bitrate_bps = max_bitrate_bps;
     }
   } else {
     // Format width and height has to be divisible by |2 ^ number_streams - 1|.
     width = NormalizeSimulcastSize(width, num_simulcast_layers);
     height = NormalizeSimulcastSize(height, num_simulcast_layers);

     // Add simulcast sub-streams from lower resolution to higher resolutions.
     // Add simulcast streams, from highest resolution (|s| = number_streams -1)
     // to lowest resolution at |s| = 0.
     for (size_t s = num_simulcast_layers - 1;; --s) {
       streams[s].width = width;
       streams[s].height = height;
       // TODO(pbos): Fill actual temporal-layer bitrate thresholds.
       streams[s].max_qp = max_qp;
       streams[s].temporal_layer_thresholds_bps.resize(
           kDefaultConferenceNumberOfTemporalLayers[s] - 1);
       streams[s].max_bitrate_bps = FindSimulcastMaxBitrateBps(width, height);
       streams[s].target_bitrate_bps =
           FindSimulcastTargetBitrateBps(width, height);
       streams[s].min_bitrate_bps = FindSimulcastMinBitrateBps(width, height);
       streams[s].max_framerate = max_framerate;

       width /= 2;
       height /= 2;

       if (s == 0)
         break;
     }

     // Spend additional bits to boost the max stream.
     int bitrate_left_bps = max_bitrate_bps - GetTotalMaxBitrateBps(streams);
     if (bitrate_left_bps > 0) {
       streams.back().max_bitrate_bps += bitrate_left_bps;
     }
   }

   return streams;
 }

 static const int kScreenshareMinBitrateKbps = 50;
 static const int kScreenshareMaxBitrateKbps = 6000;
 static const int kScreenshareDefaultTl0BitrateKbps = 200;
 static const int kScreenshareDefaultTl1BitrateKbps = 1000;

 static const char* kScreencastLayerFieldTrialName =
     "WebRTC-ScreenshareLayerRates";
 static const char* kSimulcastScreenshareFieldTrialName =
     "WebRTC-SimulcastScreenshare";

 ScreenshareLayerConfig::ScreenshareLayerConfig(int tl0_bitrate, int tl1_bitrate)
     : tl0_bitrate_kbps(tl0_bitrate), tl1_bitrate_kbps(tl1_bitrate) {
 }

 ScreenshareLayerConfig ScreenshareLayerConfig::GetDefault() {
   std::string group =
       webrtc::field_trial::FindFullName(kScreencastLayerFieldTrialName);

   ScreenshareLayerConfig config(kScreenshareDefaultTl0BitrateKbps,
                                 kScreenshareDefaultTl1BitrateKbps);
   if (!group.empty() && !FromFieldTrialGroup(group, &config)) {
     RTC_LOG(LS_WARNING) << "Unable to parse WebRTC-ScreenshareLayerRates"
                            " field trial group: '"
                         << group << "'.";
   }
   return config;
 }

 bool ScreenshareLayerConfig::FromFieldTrialGroup(
     const std::string& group,
     ScreenshareLayerConfig* config) {
   // Parse field trial group name, containing bitrates for tl0 and tl1.
   int tl0_bitrate;
   int tl1_bitrate;
   if (sscanf(group.c_str(), "%d-%d", &tl0_bitrate, &tl1_bitrate) != 2) {
     return false;
   }

   // Sanity check.
   if (tl0_bitrate < kScreenshareMinBitrateKbps ||
       tl0_bitrate > kScreenshareMaxBitrateKbps ||
       tl1_bitrate < kScreenshareMinBitrateKbps ||
       tl1_bitrate > kScreenshareMaxBitrateKbps || tl0_bitrate > tl1_bitrate) {
     return false;
   }

   config->tl0_bitrate_kbps = tl0_bitrate;
   config->tl1_bitrate_kbps = tl1_bitrate;

   return true;
 }

 bool UseSimulcastScreenshare() {
   return webrtc::field_trial::IsEnabled(kSimulcastScreenshareFieldTrialName);
 }

 }  // namespace cricket
	/*
	* Copyright (c) 2014 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 <stdio.h>
	#include <algorithm>
	#include <string>

	#include "media/base/streamparams.h"
	#include "media/engine/constants.h"
	#include "media/engine/simulcast.h"
	#include "rtc_base/arraysize.h"
	#include "rtc_base/logging.h"
	#include "system_wrappers/include/field_trial.h"

	namespace cricket {

	struct SimulcastFormat {
	int width;
	int height;
	// The maximum number of simulcast layers can be used for
	// resolutions at \|widthxheigh\|.
	size_t max_layers;
	// The maximum bitrate for encoding stream at \|widthxheight\|, when we are
	// not sending the next higher spatial stream.
	int max_bitrate_kbps;
	// The target bitrate for encoding stream at \|widthxheight\|, when this layer
	// is not the highest layer (i.e., when we are sending another higher spatial
	// stream).
	int target_bitrate_kbps;
	// The minimum bitrate needed for encoding stream at \|widthxheight\|.
	int min_bitrate_kbps;
	};

	// These tables describe from which resolution we can use how many
	// simulcast layers at what bitrates (maximum, target, and minimum).
	// Important!! Keep this table from high resolution to low resolution.
	const SimulcastFormat kSimulcastFormats[] = {
	{1920, 1080, 3, 5000, 4000, 800},
	{1280, 720, 3, 2500, 2500, 600},
	{960, 540, 3, 900, 900, 450},
	{640, 360, 2, 700, 500, 150},
	{480, 270, 2, 450, 350, 150},
	{320, 180, 1, 200, 150, 30},
	{0, 0, 1, 200, 150, 30}
	};

	const int kMaxScreenshareSimulcastStreams = 2;

	// Multiway: Number of temporal layers for each simulcast stream, for maximum
	// possible number of simulcast streams \|kMaxSimulcastStreams\|. The array
	// goes from lowest resolution at position 0 to highest resolution.
	// For example, first three elements correspond to say: QVGA, VGA, WHD.
	static const int
	kDefaultConferenceNumberOfTemporalLayers[webrtc::kMaxSimulcastStreams] =
	{3, 3, 3, 3};

	void GetSimulcastSsrcs(const StreamParams& sp, std::vector<uint32_t>* ssrcs) {
	const SsrcGroup* sim_group = sp.get_ssrc_group(kSimSsrcGroupSemantics);
	if (sim_group) {
	ssrcs->insert(
	ssrcs->end(), sim_group->ssrcs.begin(), sim_group->ssrcs.end());
	}
	}

	void MaybeExchangeWidthHeight(int* width, int* height) {
	// \|kSimulcastFormats\| assumes \|width\| >= \|height\|. If not, exchange them
	// before comparing.
	if (width < height) {
	int temp = *width;
	width = height;
	*height = temp;
	}
	}

	int FindSimulcastFormatIndex(int width, int height) {
	MaybeExchangeWidthHeight(&width, &height);

	for (uint32_t i = 0; i < arraysize(kSimulcastFormats); ++i) {
	if (width * height >=
	kSimulcastFormats[i].width * kSimulcastFormats[i].height) {
	return i;
	}
	}
	return -1;
	}

	int FindSimulcastFormatIndex(int width, int height, size_t max_layers) {
	MaybeExchangeWidthHeight(&width, &height);

	for (uint32_t i = 0; i < arraysize(kSimulcastFormats); ++i) {
	if (width * height >=
	kSimulcastFormats[i].width * kSimulcastFormats[i].height &&
	max_layers == kSimulcastFormats[i].max_layers) {
	return i;
	}
	}
	return -1;
	}

	// Simulcast stream width and height must both be dividable by
	// \|2 ^ simulcast_layers - 1\|.
	int NormalizeSimulcastSize(int size, size_t simulcast_layers) {
	const int base2_exponent = static_cast<int>(simulcast_layers) - 1;
	return ((size >> base2_exponent) << base2_exponent);
	}

	size_t FindSimulcastMaxLayers(int width, int height) {
	int index = FindSimulcastFormatIndex(width, height);
	if (index == -1) {
	return -1;
	}
	return kSimulcastFormats[index].max_layers;
	}

	// TODO(marpan): Investigate if we should return 0 instead of -1 in
	// FindSimulcast[Max/Target/Min]Bitrate functions below, since the
	// codec struct max/min/targeBitrates are unsigned.
	int FindSimulcastMaxBitrateBps(int width, int height) {
	const int format_index = FindSimulcastFormatIndex(width, height);
	if (format_index == -1) {
	return -1;
	}
	return kSimulcastFormats[format_index].max_bitrate_kbps * 1000;
	}

	int FindSimulcastTargetBitrateBps(int width, int height) {
	const int format_index = FindSimulcastFormatIndex(width, height);
	if (format_index == -1) {
	return -1;
	}
	return kSimulcastFormats[format_index].target_bitrate_kbps * 1000;
	}

	int FindSimulcastMinBitrateBps(int width, int height) {
	const int format_index = FindSimulcastFormatIndex(width, height);
	if (format_index == -1) {
	return -1;
	}
	return kSimulcastFormats[format_index].min_bitrate_kbps * 1000;
	}

	bool SlotSimulcastMaxResolution(size_t max_layers, int* width, int* height) {
	int index = FindSimulcastFormatIndex(width, height, max_layers);
	if (index == -1) {
	RTC_LOG(LS_ERROR) << "SlotSimulcastMaxResolution";
	return false;
	}

	*width = kSimulcastFormats[index].width;
	*height = kSimulcastFormats[index].height;
	RTC_LOG(LS_INFO) << "SlotSimulcastMaxResolution to width:" << *width
	<< " height:" << *height;
	return true;
	}

	int GetTotalMaxBitrateBps(const std::vector<webrtc::VideoStream>& streams) {
	int total_max_bitrate_bps = 0;
	for (size_t s = 0; s < streams.size() - 1; ++s) {
	total_max_bitrate_bps += streams[s].target_bitrate_bps;
	}
	total_max_bitrate_bps += streams.back().max_bitrate_bps;
	return total_max_bitrate_bps;
	}

	std::vector<webrtc::VideoStream> GetSimulcastConfig(size_t max_streams,
	int width,
	int height,
	int max_bitrate_bps,
	int max_qp,
	int max_framerate,
	bool is_screencast) {
	size_t num_simulcast_layers;
	if (is_screencast) {
	if (UseSimulcastScreenshare()) {
	num_simulcast_layers =
	std::min<int>(max_streams, kMaxScreenshareSimulcastStreams);
	} else {
	num_simulcast_layers = 1;
	}
	} else {
	num_simulcast_layers = FindSimulcastMaxLayers(width, height);
	}

	if (num_simulcast_layers > max_streams) {
	// If the number of SSRCs in the group differs from our target
	// number of simulcast streams for current resolution, switch down
	// to a resolution that matches our number of SSRCs.
	if (!SlotSimulcastMaxResolution(max_streams, &width, &height)) {
	return std::vector<webrtc::VideoStream>();
	}
	num_simulcast_layers = max_streams;
	}
	std::vector<webrtc::VideoStream> streams;
	streams.resize(num_simulcast_layers);

	if (is_screencast) {
	ScreenshareLayerConfig config = ScreenshareLayerConfig::GetDefault();
	// For legacy screenshare in conference mode, tl0 and tl1 bitrates are
	// piggybacked on the VideoCodec struct as target and max bitrates,
	// respectively. See eg. webrtc::VP8EncoderImpl::SetRates().
	streams[0].width = width;
	streams[0].height = height;
	streams[0].max_qp = max_qp;
	streams[0].max_framerate = 5;
	streams[0].min_bitrate_bps = kMinVideoBitrateBps;
	streams[0].target_bitrate_bps = config.tl0_bitrate_kbps * 1000;
	streams[0].max_bitrate_bps = config.tl1_bitrate_kbps * 1000;
	streams[0].temporal_layer_thresholds_bps.clear();
	streams[0].temporal_layer_thresholds_bps.push_back(config.tl0_bitrate_kbps *
	1000);

	// With simulcast enabled, add another spatial layer. This one will have a
	// more normal layout, with the regular 3 temporal layer pattern and no fps
	// restrictions. The base simulcast stream will still use legacy setup.
	if (num_simulcast_layers == kMaxScreenshareSimulcastStreams) {
	// Add optional upper simulcast layer.
	// Lowest temporal layers of a 3 layer setup will have 40% of the total
	// bitrate allocation for that stream. Make sure the gap between the
	// target of the lower stream and first temporal layer of the higher one
	// is at most 2x the bitrate, so that upswitching is not hampered by
	// stalled bitrate estimates.
	int max_bitrate_bps = 2 * ((streams[0].target_bitrate_bps * 10) / 4);
	// Cap max bitrate so it isn't overly high for the given resolution.
	max_bitrate_bps = std::min<int>(
	max_bitrate_bps, FindSimulcastMaxBitrateBps(width, height));

	streams[1].width = width;
	streams[1].height = height;
	streams[1].max_qp = max_qp;
	streams[1].max_framerate = max_framerate;
	// Three temporal layers means two thresholds.
	streams[1].temporal_layer_thresholds_bps.resize(2);
	streams[1].min_bitrate_bps = streams[0].target_bitrate_bps * 2;
	streams[1].target_bitrate_bps = max_bitrate_bps;
	streams[1].max_bitrate_bps = max_bitrate_bps;
	}
	} else {
	// Format width and height has to be divisible by \|2 ^ number_streams - 1\|.
	width = NormalizeSimulcastSize(width, num_simulcast_layers);
	height = NormalizeSimulcastSize(height, num_simulcast_layers);

	// Add simulcast sub-streams from lower resolution to higher resolutions.
	// Add simulcast streams, from highest resolution (\|s\| = number_streams -1)
	// to lowest resolution at \|s\| = 0.
	for (size_t s = num_simulcast_layers - 1;; --s) {
	streams[s].width = width;
	streams[s].height = height;
	// TODO(pbos): Fill actual temporal-layer bitrate thresholds.
	streams[s].max_qp = max_qp;
	streams[s].temporal_layer_thresholds_bps.resize(
	kDefaultConferenceNumberOfTemporalLayers[s] - 1);
	streams[s].max_bitrate_bps = FindSimulcastMaxBitrateBps(width, height);
	streams[s].target_bitrate_bps =
	FindSimulcastTargetBitrateBps(width, height);
	streams[s].min_bitrate_bps = FindSimulcastMinBitrateBps(width, height);
	streams[s].max_framerate = max_framerate;

	width /= 2;
	height /= 2;

	if (s == 0)
	break;
	}

	// Spend additional bits to boost the max stream.
	int bitrate_left_bps = max_bitrate_bps - GetTotalMaxBitrateBps(streams);
	if (bitrate_left_bps > 0) {
	streams.back().max_bitrate_bps += bitrate_left_bps;
	}
	}

	return streams;
	}

	static const int kScreenshareMinBitrateKbps = 50;
	static const int kScreenshareMaxBitrateKbps = 6000;
	static const int kScreenshareDefaultTl0BitrateKbps = 200;
	static const int kScreenshareDefaultTl1BitrateKbps = 1000;

	static const char* kScreencastLayerFieldTrialName =
	"WebRTC-ScreenshareLayerRates";
	static const char* kSimulcastScreenshareFieldTrialName =
	"WebRTC-SimulcastScreenshare";

	ScreenshareLayerConfig::ScreenshareLayerConfig(int tl0_bitrate, int tl1_bitrate)
	: tl0_bitrate_kbps(tl0_bitrate), tl1_bitrate_kbps(tl1_bitrate) {
	}

	ScreenshareLayerConfig ScreenshareLayerConfig::GetDefault() {
	std::string group =
	webrtc::field_trial::FindFullName(kScreencastLayerFieldTrialName);

	ScreenshareLayerConfig config(kScreenshareDefaultTl0BitrateKbps,
	kScreenshareDefaultTl1BitrateKbps);
	if (!group.empty() && !FromFieldTrialGroup(group, &config)) {
	RTC_LOG(LS_WARNING) << "Unable to parse WebRTC-ScreenshareLayerRates"
	" field trial group: '"
	<< group << "'.";
	}
	return config;
	}

	bool ScreenshareLayerConfig::FromFieldTrialGroup(
	const std::string& group,
	ScreenshareLayerConfig* config) {
	// Parse field trial group name, containing bitrates for tl0 and tl1.
	int tl0_bitrate;
	int tl1_bitrate;
	if (sscanf(group.c_str(), "%d-%d", &tl0_bitrate, &tl1_bitrate) != 2) {
	return false;
	}

	// Sanity check.
	if (tl0_bitrate < kScreenshareMinBitrateKbps \|\|
	tl0_bitrate > kScreenshareMaxBitrateKbps \|\|
	tl1_bitrate < kScreenshareMinBitrateKbps \|\|
	tl1_bitrate > kScreenshareMaxBitrateKbps \|\| tl0_bitrate > tl1_bitrate) {
	return false;
	}

	config->tl0_bitrate_kbps = tl0_bitrate;
	config->tl1_bitrate_kbps = tl1_bitrate;

	return true;
	}

	bool UseSimulcastScreenshare() {
	return webrtc::field_trial::IsEnabled(kSimulcastScreenshareFieldTrialName);
	}

	} // namespace cricket