webrtc/media/base/videoadapter.cc - src - Git at Google

 /*
  *  Copyright (c) 2010 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 "webrtc/media/base/videoadapter.h"

 #include <algorithm>
 #include <cstdlib>
 #include <limits>

 #include "webrtc/base/checks.h"
 #include "webrtc/base/logging.h"
 #include "webrtc/media/base/mediaconstants.h"
 #include "webrtc/media/base/videocommon.h"

 namespace {

 struct Fraction {
   int numerator;
   int denominator;
 };

 // Scale factors optimized for in libYUV that we accept.
 // Must be sorted in decreasing scale factors for FindScaleLargerThan to work.
 const Fraction kScaleFractions[] = {
   {1, 1},
   {3, 4},
   {1, 2},
   {3, 8},
   {1, 4},
   {3, 16},
 };

 // Round |valueToRound| to a multiple of |multiple|. Prefer rounding upwards,
 // but never more than |maxValue|.
 int roundUp(int valueToRound, int multiple, int maxValue) {
   const int roundedValue = (valueToRound + multiple - 1) / multiple * multiple;
   return roundedValue <= maxValue ? roundedValue
                                   : (maxValue / multiple * multiple);
 }

 Fraction FindScaleLessThanOrEqual(int input_num_pixels, int target_num_pixels) {
   float best_distance = std::numeric_limits<float>::max();
   Fraction best_scale = {0, 1};  // Default to 0 if nothing matches.
   for (const auto& fraction : kScaleFractions) {
     const float scale =
         fraction.numerator / static_cast<float>(fraction.denominator);
     float test_num_pixels = input_num_pixels * scale * scale;
     float diff = target_num_pixels - test_num_pixels;
     if (diff < 0) {
       continue;
     }
     if (diff < best_distance) {
       best_distance = diff;
       best_scale = fraction;
       if (best_distance == 0) {  // Found exact match.
         break;
       }
     }
   }
   return best_scale;
 }

 Fraction FindScaleLargerThan(int input_num_pixels,
                              int target_num_pixels,
                              int* resulting_number_of_pixels) {
   float best_distance = std::numeric_limits<float>::max();
   Fraction best_scale = {1, 1};  // Default to unscaled if nothing matches.
   // Default to input number of pixels.
   float best_number_of_pixels = input_num_pixels;
   for (const auto& fraction : kScaleFractions) {
     const float scale =
         fraction.numerator / static_cast<float>(fraction.denominator);
     float test_num_pixels = input_num_pixels * scale * scale;
     float diff = test_num_pixels - target_num_pixels;
     if (diff <= 0) {
       break;
     }
     if (diff < best_distance) {
       best_distance = diff;
       best_scale = fraction;
       best_number_of_pixels = test_num_pixels;
     }
   }

   *resulting_number_of_pixels = static_cast<int>(best_number_of_pixels + .5f);
   return best_scale;
 }

 Fraction FindScale(int input_num_pixels,
                    int max_pixel_count_step_up,
                    int max_pixel_count) {
   // Try scale just above |max_pixel_count_step_up_|.
   if (max_pixel_count_step_up > 0) {
     int resulting_pixel_count;
     const Fraction scale = FindScaleLargerThan(
         input_num_pixels, max_pixel_count_step_up, &resulting_pixel_count);
     if (resulting_pixel_count <= max_pixel_count)
       return scale;
   }
   // Return largest scale below |max_pixel_count|.
   return FindScaleLessThanOrEqual(input_num_pixels, max_pixel_count);
 }

 }  // namespace

 namespace cricket {

 VideoAdapter::VideoAdapter()
     : frames_in_(0),
       frames_out_(0),
       frames_scaled_(0),
       adaption_changes_(0),
       previous_width_(0),
       previous_height_(0),
       resolution_request_max_pixel_count_(std::numeric_limits<int>::max()),
       resolution_request_max_pixel_count_step_up_(0) {}

 VideoAdapter::~VideoAdapter() {}

 bool VideoAdapter::KeepFrame(int64_t in_timestamp_ns) {
   rtc::CritScope cs(&critical_section_);
   if (!requested_format_ || requested_format_->interval == 0)
     return true;

   if (next_frame_timestamp_ns_) {
     // Time until next frame should be outputted.
     const int64_t time_until_next_frame_ns =
         (*next_frame_timestamp_ns_ - in_timestamp_ns);

     // Continue if timestamp is withing expected range.
     if (std::abs(time_until_next_frame_ns) < 2 * requested_format_->interval) {
       // Drop if a frame shouldn't be outputted yet.
       if (time_until_next_frame_ns > 0)
         return false;
       // Time to output new frame.
       *next_frame_timestamp_ns_ += requested_format_->interval;
       return true;
     }
   }

   // First timestamp received or timestamp is way outside expected range, so
   // reset. Set first timestamp target to just half the interval to prefer
   // keeping frames in case of jitter.
   next_frame_timestamp_ns_ =
       rtc::Optional<int64_t>(in_timestamp_ns + requested_format_->interval / 2);
   return true;
 }

 bool VideoAdapter::AdaptFrameResolution(int in_width,
                                         int in_height,
                                         int64_t in_timestamp_ns,
                                         int* cropped_width,
                                         int* cropped_height,
                                         int* out_width,
                                         int* out_height) {
   rtc::CritScope cs(&critical_section_);
   ++frames_in_;

   // The max output pixel count is the minimum of the requests from
   // OnOutputFormatRequest and OnResolutionRequest.
   int max_pixel_count = resolution_request_max_pixel_count_;
   if (requested_format_) {
     max_pixel_count = std::min(
         max_pixel_count, requested_format_->width * requested_format_->height);
   }

   // Drop the input frame if necessary.
   if (max_pixel_count == 0 || !KeepFrame(in_timestamp_ns)) {
     // Show VAdapt log every 90 frames dropped. (3 seconds)
     if ((frames_in_ - frames_out_) % 90 == 0) {
       // TODO(fbarchard): Reduce to LS_VERBOSE when adapter info is not needed
       // in default calls.
       LOG(LS_INFO) << "VAdapt Drop Frame: scaled " << frames_scaled_
                    << " / out " << frames_out_
                    << " / in " << frames_in_
                    << " Changes: " << adaption_changes_
                    << " Input: " << in_width
                    << "x" << in_height
                    << " timestamp: " << in_timestamp_ns
                    << " Output: i"
                    << (requested_format_ ? requested_format_->interval : 0);
     }

     // Drop frame.
     return false;
   }

   // Calculate how the input should be cropped.
   if (!requested_format_ ||
       requested_format_->width == 0 || requested_format_->height == 0) {
     *cropped_width = in_width;
     *cropped_height = in_height;
   } else {
     // Adjust |requested_format_| orientation to match input.
     if ((in_width > in_height) !=
         (requested_format_->width > requested_format_->height)) {
       std::swap(requested_format_->width, requested_format_->height);
     }
     const float requested_aspect =
         requested_format_->width /
         static_cast<float>(requested_format_->height);
     *cropped_width =
         std::min(in_width, static_cast<int>(in_height * requested_aspect));
     *cropped_height =
         std::min(in_height, static_cast<int>(in_width / requested_aspect));
   }

   // Find best scale factor.
   const Fraction scale =
       FindScale(*cropped_width * *cropped_height,
                 resolution_request_max_pixel_count_step_up_, max_pixel_count);

   // Adjust cropping slightly to get even integer output size and a perfect
   // scale factor.
   *cropped_width = roundUp(*cropped_width, scale.denominator, in_width);
   *cropped_height = roundUp(*cropped_height, scale.denominator, in_height);
   RTC_DCHECK_EQ(0, *cropped_width % scale.denominator);
   RTC_DCHECK_EQ(0, *cropped_height % scale.denominator);

   // Calculate final output size.
   *out_width = *cropped_width / scale.denominator * scale.numerator;
   *out_height = *cropped_height / scale.denominator * scale.numerator;

   ++frames_out_;
   if (scale.numerator != scale.denominator)
     ++frames_scaled_;

   if (previous_width_ && (previous_width_ != *out_width ||
                           previous_height_ != *out_height)) {
     ++adaption_changes_;
     LOG(LS_INFO) << "Frame size changed: scaled " << frames_scaled_ << " / out "
                  << frames_out_ << " / in " << frames_in_
                  << " Changes: " << adaption_changes_ << " Input: " << in_width
                  << "x" << in_height
                  << " Scale: " << scale.numerator << "/" << scale.denominator
                  << " Output: " << *out_width << "x" << *out_height << " i"
                  << (requested_format_ ? requested_format_->interval : 0);
   }

   previous_width_ = *out_width;
   previous_height_ = *out_height;

   return true;
 }

 void VideoAdapter::OnOutputFormatRequest(const VideoFormat& format) {
   rtc::CritScope cs(&critical_section_);
   requested_format_ = rtc::Optional<VideoFormat>(format);
   next_frame_timestamp_ns_ = rtc::Optional<int64_t>();
 }

 void VideoAdapter::OnResolutionRequest(
     rtc::Optional<int> max_pixel_count,
     rtc::Optional<int> max_pixel_count_step_up) {
   rtc::CritScope cs(&critical_section_);
   resolution_request_max_pixel_count_ =
       max_pixel_count.value_or(std::numeric_limits<int>::max());
   resolution_request_max_pixel_count_step_up_ =
       max_pixel_count_step_up.value_or(0);
 }

 }  // namespace cricket
	/*
	* Copyright (c) 2010 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 "webrtc/media/base/videoadapter.h"

	#include <algorithm>
	#include <cstdlib>
	#include <limits>

	#include "webrtc/base/checks.h"
	#include "webrtc/base/logging.h"
	#include "webrtc/media/base/mediaconstants.h"
	#include "webrtc/media/base/videocommon.h"

	namespace {

	struct Fraction {
	int numerator;
	int denominator;
	};

	// Scale factors optimized for in libYUV that we accept.
	// Must be sorted in decreasing scale factors for FindScaleLargerThan to work.
	const Fraction kScaleFractions[] = {
	{1, 1},
	{3, 4},
	{1, 2},
	{3, 8},
	{1, 4},
	{3, 16},
	};

	// Round \|valueToRound\| to a multiple of \|multiple\|. Prefer rounding upwards,
	// but never more than \|maxValue\|.
	int roundUp(int valueToRound, int multiple, int maxValue) {
	const int roundedValue = (valueToRound + multiple - 1) / multiple * multiple;
	return roundedValue <= maxValue ? roundedValue
	: (maxValue / multiple * multiple);
	}

	Fraction FindScaleLessThanOrEqual(int input_num_pixels, int target_num_pixels) {
	float best_distance = std::numeric_limits<float>::max();
	Fraction best_scale = {0, 1}; // Default to 0 if nothing matches.
	for (const auto& fraction : kScaleFractions) {
	const float scale =
	fraction.numerator / static_cast<float>(fraction.denominator);
	float test_num_pixels = input_num_pixels * scale * scale;
	float diff = target_num_pixels - test_num_pixels;
	if (diff < 0) {
	continue;
	}
	if (diff < best_distance) {
	best_distance = diff;
	best_scale = fraction;
	if (best_distance == 0) { // Found exact match.
	break;
	}
	}
	}
	return best_scale;
	}

	Fraction FindScaleLargerThan(int input_num_pixels,
	int target_num_pixels,
	int* resulting_number_of_pixels) {
	float best_distance = std::numeric_limits<float>::max();
	Fraction best_scale = {1, 1}; // Default to unscaled if nothing matches.
	// Default to input number of pixels.
	float best_number_of_pixels = input_num_pixels;
	for (const auto& fraction : kScaleFractions) {
	const float scale =
	fraction.numerator / static_cast<float>(fraction.denominator);
	float test_num_pixels = input_num_pixels * scale * scale;
	float diff = test_num_pixels - target_num_pixels;
	if (diff <= 0) {
	break;
	}
	if (diff < best_distance) {
	best_distance = diff;
	best_scale = fraction;
	best_number_of_pixels = test_num_pixels;
	}
	}

	*resulting_number_of_pixels = static_cast<int>(best_number_of_pixels + .5f);
	return best_scale;
	}

	Fraction FindScale(int input_num_pixels,
	int max_pixel_count_step_up,
	int max_pixel_count) {
	// Try scale just above \|max_pixel_count_step_up_\|.
	if (max_pixel_count_step_up > 0) {
	int resulting_pixel_count;
	const Fraction scale = FindScaleLargerThan(
	input_num_pixels, max_pixel_count_step_up, &resulting_pixel_count);
	if (resulting_pixel_count <= max_pixel_count)
	return scale;
	}
	// Return largest scale below \|max_pixel_count\|.
	return FindScaleLessThanOrEqual(input_num_pixels, max_pixel_count);
	}

	} // namespace

	namespace cricket {

	VideoAdapter::VideoAdapter()
	: frames_in_(0),
	frames_out_(0),
	frames_scaled_(0),
	adaption_changes_(0),
	previous_width_(0),
	previous_height_(0),
	resolution_request_max_pixel_count_(std::numeric_limits<int>::max()),
	resolution_request_max_pixel_count_step_up_(0) {}

	VideoAdapter::~VideoAdapter() {}

	bool VideoAdapter::KeepFrame(int64_t in_timestamp_ns) {
	rtc::CritScope cs(&critical_section_);
	if (!requested_format_ \|\| requested_format_->interval == 0)
	return true;

	if (next_frame_timestamp_ns_) {
	// Time until next frame should be outputted.
	const int64_t time_until_next_frame_ns =
	(*next_frame_timestamp_ns_ - in_timestamp_ns);

	// Continue if timestamp is withing expected range.
	if (std::abs(time_until_next_frame_ns) < 2 * requested_format_->interval) {
	// Drop if a frame shouldn't be outputted yet.
	if (time_until_next_frame_ns > 0)
	return false;
	// Time to output new frame.
	*next_frame_timestamp_ns_ += requested_format_->interval;
	return true;
	}
	}

	// First timestamp received or timestamp is way outside expected range, so
	// reset. Set first timestamp target to just half the interval to prefer
	// keeping frames in case of jitter.
	next_frame_timestamp_ns_ =
	rtc::Optional<int64_t>(in_timestamp_ns + requested_format_->interval / 2);
	return true;
	}

	bool VideoAdapter::AdaptFrameResolution(int in_width,
	int in_height,
	int64_t in_timestamp_ns,
	int* cropped_width,
	int* cropped_height,
	int* out_width,
	int* out_height) {
	rtc::CritScope cs(&critical_section_);
	++frames_in_;

	// The max output pixel count is the minimum of the requests from
	// OnOutputFormatRequest and OnResolutionRequest.
	int max_pixel_count = resolution_request_max_pixel_count_;
	if (requested_format_) {
	max_pixel_count = std::min(
	max_pixel_count, requested_format_->width * requested_format_->height);
	}

	// Drop the input frame if necessary.
	if (max_pixel_count == 0 \|\| !KeepFrame(in_timestamp_ns)) {
	// Show VAdapt log every 90 frames dropped. (3 seconds)
	if ((frames_in_ - frames_out_) % 90 == 0) {
	// TODO(fbarchard): Reduce to LS_VERBOSE when adapter info is not needed
	// in default calls.
	LOG(LS_INFO) << "VAdapt Drop Frame: scaled " << frames_scaled_
	<< " / out " << frames_out_
	<< " / in " << frames_in_
	<< " Changes: " << adaption_changes_
	<< " Input: " << in_width
	<< "x" << in_height
	<< " timestamp: " << in_timestamp_ns
	<< " Output: i"
	<< (requested_format_ ? requested_format_->interval : 0);
	}

	// Drop frame.
	return false;
	}

	// Calculate how the input should be cropped.
	if (!requested_format_ \|\|
	requested_format_->width == 0 \|\| requested_format_->height == 0) {
	*cropped_width = in_width;
	*cropped_height = in_height;
	} else {
	// Adjust \|requested_format_\| orientation to match input.
	if ((in_width > in_height) !=
	(requested_format_->width > requested_format_->height)) {
	std::swap(requested_format_->width, requested_format_->height);
	}
	const float requested_aspect =
	requested_format_->width /
	static_cast<float>(requested_format_->height);
	*cropped_width =
	std::min(in_width, static_cast<int>(in_height * requested_aspect));
	*cropped_height =
	std::min(in_height, static_cast<int>(in_width / requested_aspect));
	}

	// Find best scale factor.
	const Fraction scale =
	FindScale(cropped_width *cropped_height,
	resolution_request_max_pixel_count_step_up_, max_pixel_count);

	// Adjust cropping slightly to get even integer output size and a perfect
	// scale factor.
	cropped_width = roundUp(cropped_width, scale.denominator, in_width);
	cropped_height = roundUp(cropped_height, scale.denominator, in_height);
	RTC_DCHECK_EQ(0, *cropped_width % scale.denominator);
	RTC_DCHECK_EQ(0, *cropped_height % scale.denominator);

	// Calculate final output size.
	out_width = cropped_width / scale.denominator * scale.numerator;
	out_height = cropped_height / scale.denominator * scale.numerator;

	++frames_out_;
	if (scale.numerator != scale.denominator)
	++frames_scaled_;

	if (previous_width_ && (previous_width_ != *out_width \|\|
	previous_height_ != *out_height)) {
	++adaption_changes_;
	LOG(LS_INFO) << "Frame size changed: scaled " << frames_scaled_ << " / out "
	<< frames_out_ << " / in " << frames_in_
	<< " Changes: " << adaption_changes_ << " Input: " << in_width
	<< "x" << in_height
	<< " Scale: " << scale.numerator << "/" << scale.denominator
	<< " Output: " << out_width << "x" << out_height << " i"
	<< (requested_format_ ? requested_format_->interval : 0);
	}

	previous_width_ = *out_width;
	previous_height_ = *out_height;

	return true;
	}

	void VideoAdapter::OnOutputFormatRequest(const VideoFormat& format) {
	rtc::CritScope cs(&critical_section_);
	requested_format_ = rtc::Optional<VideoFormat>(format);
	next_frame_timestamp_ns_ = rtc::Optional<int64_t>();
	}

	void VideoAdapter::OnResolutionRequest(
	rtc::Optional<int> max_pixel_count,
	rtc::Optional<int> max_pixel_count_step_up) {
	rtc::CritScope cs(&critical_section_);
	resolution_request_max_pixel_count_ =
	max_pixel_count.value_or(std::numeric_limits<int>::max());
	resolution_request_max_pixel_count_step_up_ =
	max_pixel_count_step_up.value_or(0);
	}

	} // namespace cricket