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464 lines
12 KiB
464 lines
12 KiB
/*
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* Copyright (c) 2016 The WebRTC project authors. All Rights Reserved.
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*
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* Use of this source code is governed by a BSD-style license
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* that can be found in the LICENSE file in the root of the source
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* tree. An additional intellectual property rights grant can be found
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* in the file PATENTS. All contributing project authors may
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* be found in the AUTHORS file in the root of the source tree.
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*/
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#include "video/stats_counter.h"
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#include <algorithm>
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#include <limits>
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#include <map>
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#include "rtc_base/checks.h"
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#include "rtc_base/strings/string_builder.h"
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#include "system_wrappers/include/clock.h"
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namespace webrtc {
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namespace {
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// Default periodic time interval for processing samples.
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const int64_t kDefaultProcessIntervalMs = 2000;
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const uint32_t kStreamId0 = 0;
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} // namespace
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std::string AggregatedStats::ToString() const {
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return ToStringWithMultiplier(1);
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}
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std::string AggregatedStats::ToStringWithMultiplier(int multiplier) const {
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rtc::StringBuilder ss;
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ss << "periodic_samples:" << num_samples << ", {";
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ss << "min:" << (min * multiplier) << ", ";
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ss << "avg:" << (average * multiplier) << ", ";
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ss << "max:" << (max * multiplier) << "}";
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return ss.Release();
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}
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// Class holding periodically computed metrics.
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class AggregatedCounter {
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public:
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AggregatedCounter() : last_sample_(0), sum_samples_(0) {}
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~AggregatedCounter() {}
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void Add(int sample) {
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last_sample_ = sample;
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sum_samples_ += sample;
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++stats_.num_samples;
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if (stats_.num_samples == 1) {
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stats_.min = sample;
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stats_.max = sample;
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}
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stats_.min = std::min(sample, stats_.min);
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stats_.max = std::max(sample, stats_.max);
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}
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AggregatedStats ComputeStats() {
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Compute();
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return stats_;
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}
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bool Empty() const { return stats_.num_samples == 0; }
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int last_sample() const { return last_sample_; }
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private:
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void Compute() {
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if (stats_.num_samples == 0)
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return;
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stats_.average =
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(sum_samples_ + stats_.num_samples / 2) / stats_.num_samples;
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}
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int last_sample_;
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int64_t sum_samples_;
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AggregatedStats stats_;
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};
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// Class holding gathered samples within a process interval.
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class Samples {
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public:
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Samples() : total_count_(0) {}
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~Samples() {}
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void Add(int sample, uint32_t stream_id) {
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samples_[stream_id].Add(sample);
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++total_count_;
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}
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void Set(int64_t sample, uint32_t stream_id) {
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samples_[stream_id].Set(sample);
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++total_count_;
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}
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void SetLast(int64_t sample, uint32_t stream_id) {
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samples_[stream_id].SetLast(sample);
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}
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int64_t GetLast(uint32_t stream_id) { return samples_[stream_id].GetLast(); }
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int64_t Count() const { return total_count_; }
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bool Empty() const { return total_count_ == 0; }
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int64_t Sum() const {
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int64_t sum = 0;
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for (const auto& it : samples_)
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sum += it.second.sum_;
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return sum;
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}
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int Max() const {
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int max = std::numeric_limits<int>::min();
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for (const auto& it : samples_)
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max = std::max(it.second.max_, max);
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return max;
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}
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void Reset() {
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for (auto& it : samples_)
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it.second.Reset();
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total_count_ = 0;
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}
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int64_t Diff() const {
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int64_t sum_diff = 0;
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int count = 0;
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for (const auto& it : samples_) {
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if (it.second.count_ > 0) {
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int64_t diff = it.second.sum_ - it.second.last_sum_;
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if (diff >= 0) {
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sum_diff += diff;
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++count;
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}
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}
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}
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return (count > 0) ? sum_diff : -1;
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}
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private:
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struct Stats {
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void Add(int sample) {
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sum_ += sample;
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++count_;
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max_ = std::max(sample, max_);
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}
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void Set(int64_t sample) {
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sum_ = sample;
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++count_;
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}
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void SetLast(int64_t sample) { last_sum_ = sample; }
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int64_t GetLast() const { return last_sum_; }
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void Reset() {
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if (count_ > 0)
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last_sum_ = sum_;
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sum_ = 0;
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count_ = 0;
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max_ = std::numeric_limits<int>::min();
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}
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int max_ = std::numeric_limits<int>::min();
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int64_t count_ = 0;
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int64_t sum_ = 0;
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int64_t last_sum_ = 0;
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};
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int64_t total_count_;
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std::map<uint32_t, Stats> samples_; // Gathered samples mapped by stream id.
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};
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// StatsCounter class.
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StatsCounter::StatsCounter(Clock* clock,
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int64_t process_intervals_ms,
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bool include_empty_intervals,
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StatsCounterObserver* observer)
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: include_empty_intervals_(include_empty_intervals),
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process_intervals_ms_(process_intervals_ms),
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aggregated_counter_(new AggregatedCounter()),
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samples_(new Samples()),
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clock_(clock),
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observer_(observer),
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last_process_time_ms_(-1),
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paused_(false),
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pause_time_ms_(-1),
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min_pause_time_ms_(0) {
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RTC_DCHECK_GT(process_intervals_ms_, 0);
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}
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StatsCounter::~StatsCounter() {}
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AggregatedStats StatsCounter::GetStats() {
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return aggregated_counter_->ComputeStats();
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}
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AggregatedStats StatsCounter::ProcessAndGetStats() {
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if (HasSample())
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TryProcess();
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return aggregated_counter_->ComputeStats();
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}
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void StatsCounter::ProcessAndPauseForDuration(int64_t min_pause_time_ms) {
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ProcessAndPause();
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min_pause_time_ms_ = min_pause_time_ms;
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}
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void StatsCounter::ProcessAndPause() {
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if (HasSample())
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TryProcess();
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paused_ = true;
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pause_time_ms_ = clock_->TimeInMilliseconds();
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}
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void StatsCounter::ProcessAndStopPause() {
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if (HasSample())
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TryProcess();
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Resume();
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}
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bool StatsCounter::HasSample() const {
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return last_process_time_ms_ != -1;
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}
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bool StatsCounter::TimeToProcess(int* elapsed_intervals) {
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int64_t now = clock_->TimeInMilliseconds();
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if (last_process_time_ms_ == -1)
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last_process_time_ms_ = now;
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int64_t diff_ms = now - last_process_time_ms_;
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if (diff_ms < process_intervals_ms_)
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return false;
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// Advance number of complete |process_intervals_ms_| that have passed.
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int64_t num_intervals = diff_ms / process_intervals_ms_;
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last_process_time_ms_ += num_intervals * process_intervals_ms_;
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*elapsed_intervals = num_intervals;
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return true;
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}
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void StatsCounter::Add(int sample) {
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TryProcess();
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samples_->Add(sample, kStreamId0);
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ResumeIfMinTimePassed();
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}
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void StatsCounter::Set(int64_t sample, uint32_t stream_id) {
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if (paused_ && sample == samples_->GetLast(stream_id)) {
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// Do not add same sample while paused (will reset pause).
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return;
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}
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TryProcess();
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samples_->Set(sample, stream_id);
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ResumeIfMinTimePassed();
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}
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void StatsCounter::SetLast(int64_t sample, uint32_t stream_id) {
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RTC_DCHECK(!HasSample()) << "Should be set before first sample is added.";
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samples_->SetLast(sample, stream_id);
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}
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// Reports periodically computed metric.
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void StatsCounter::ReportMetricToAggregatedCounter(
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int value,
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int num_values_to_add) const {
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for (int i = 0; i < num_values_to_add; ++i) {
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aggregated_counter_->Add(value);
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if (observer_)
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observer_->OnMetricUpdated(value);
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}
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}
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void StatsCounter::TryProcess() {
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int elapsed_intervals;
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if (!TimeToProcess(&elapsed_intervals))
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return;
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// Get and report periodically computed metric.
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int metric;
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if (GetMetric(&metric))
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ReportMetricToAggregatedCounter(metric, 1);
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// Report value for elapsed intervals without samples.
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if (IncludeEmptyIntervals()) {
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// If there are no samples, all elapsed intervals are empty (otherwise one
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// interval contains sample(s), discard this interval).
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int empty_intervals =
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samples_->Empty() ? elapsed_intervals : (elapsed_intervals - 1);
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ReportMetricToAggregatedCounter(GetValueForEmptyInterval(),
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empty_intervals);
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}
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// Reset samples for elapsed interval.
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samples_->Reset();
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}
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bool StatsCounter::IncludeEmptyIntervals() const {
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return include_empty_intervals_ && !paused_ && !aggregated_counter_->Empty();
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}
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void StatsCounter::ResumeIfMinTimePassed() {
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if (paused_ &&
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(clock_->TimeInMilliseconds() - pause_time_ms_) >= min_pause_time_ms_) {
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Resume();
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}
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}
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void StatsCounter::Resume() {
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paused_ = false;
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min_pause_time_ms_ = 0;
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}
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// StatsCounter sub-classes.
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AvgCounter::AvgCounter(Clock* clock,
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StatsCounterObserver* observer,
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bool include_empty_intervals)
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: StatsCounter(clock,
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kDefaultProcessIntervalMs,
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include_empty_intervals,
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observer) {}
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void AvgCounter::Add(int sample) {
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StatsCounter::Add(sample);
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}
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bool AvgCounter::GetMetric(int* metric) const {
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int64_t count = samples_->Count();
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if (count == 0)
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return false;
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*metric = (samples_->Sum() + count / 2) / count;
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return true;
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}
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int AvgCounter::GetValueForEmptyInterval() const {
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return aggregated_counter_->last_sample();
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}
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MaxCounter::MaxCounter(Clock* clock,
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StatsCounterObserver* observer,
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int64_t process_intervals_ms)
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: StatsCounter(clock,
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process_intervals_ms,
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false, // |include_empty_intervals|
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observer) {}
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void MaxCounter::Add(int sample) {
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StatsCounter::Add(sample);
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}
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bool MaxCounter::GetMetric(int* metric) const {
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if (samples_->Empty())
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return false;
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*metric = samples_->Max();
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return true;
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}
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int MaxCounter::GetValueForEmptyInterval() const {
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RTC_NOTREACHED();
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return 0;
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}
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PercentCounter::PercentCounter(Clock* clock, StatsCounterObserver* observer)
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: StatsCounter(clock,
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kDefaultProcessIntervalMs,
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false, // |include_empty_intervals|
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observer) {}
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void PercentCounter::Add(bool sample) {
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StatsCounter::Add(sample ? 1 : 0);
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}
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bool PercentCounter::GetMetric(int* metric) const {
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int64_t count = samples_->Count();
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if (count == 0)
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return false;
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*metric = (samples_->Sum() * 100 + count / 2) / count;
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return true;
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}
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int PercentCounter::GetValueForEmptyInterval() const {
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RTC_NOTREACHED();
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return 0;
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}
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PermilleCounter::PermilleCounter(Clock* clock, StatsCounterObserver* observer)
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: StatsCounter(clock,
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kDefaultProcessIntervalMs,
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false, // |include_empty_intervals|
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observer) {}
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void PermilleCounter::Add(bool sample) {
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StatsCounter::Add(sample ? 1 : 0);
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}
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bool PermilleCounter::GetMetric(int* metric) const {
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int64_t count = samples_->Count();
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if (count == 0)
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return false;
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*metric = (samples_->Sum() * 1000 + count / 2) / count;
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return true;
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}
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int PermilleCounter::GetValueForEmptyInterval() const {
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RTC_NOTREACHED();
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return 0;
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}
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RateCounter::RateCounter(Clock* clock,
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StatsCounterObserver* observer,
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bool include_empty_intervals)
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: StatsCounter(clock,
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kDefaultProcessIntervalMs,
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include_empty_intervals,
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observer) {}
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void RateCounter::Add(int sample) {
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StatsCounter::Add(sample);
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}
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bool RateCounter::GetMetric(int* metric) const {
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if (samples_->Empty())
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return false;
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*metric = (samples_->Sum() * 1000 + process_intervals_ms_ / 2) /
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process_intervals_ms_;
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return true;
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}
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int RateCounter::GetValueForEmptyInterval() const {
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return 0;
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}
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RateAccCounter::RateAccCounter(Clock* clock,
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StatsCounterObserver* observer,
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bool include_empty_intervals)
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: StatsCounter(clock,
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kDefaultProcessIntervalMs,
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include_empty_intervals,
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observer) {}
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void RateAccCounter::Set(int64_t sample, uint32_t stream_id) {
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StatsCounter::Set(sample, stream_id);
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}
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void RateAccCounter::SetLast(int64_t sample, uint32_t stream_id) {
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StatsCounter::SetLast(sample, stream_id);
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}
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bool RateAccCounter::GetMetric(int* metric) const {
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int64_t diff = samples_->Diff();
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if (diff < 0 || (!include_empty_intervals_ && diff == 0))
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return false;
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*metric = (diff * 1000 + process_intervals_ms_ / 2) / process_intervals_ms_;
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return true;
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}
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int RateAccCounter::GetValueForEmptyInterval() const {
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return 0;
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}
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} // namespace webrtc
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