/* * Copyright 2015 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 "rtc_base/rate_tracker.h" #include #include "rtc_base/checks.h" #include "rtc_base/time_utils.h" namespace rtc { static const int64_t kTimeUnset = -1; RateTracker::RateTracker(int64_t bucket_milliseconds, size_t bucket_count) : bucket_milliseconds_(bucket_milliseconds), bucket_count_(bucket_count), sample_buckets_(new int64_t[bucket_count + 1]), total_sample_count_(0u), bucket_start_time_milliseconds_(kTimeUnset) { RTC_CHECK(bucket_milliseconds > 0); RTC_CHECK(bucket_count > 0); } RateTracker::~RateTracker() { delete[] sample_buckets_; } double RateTracker::ComputeRateForInterval( int64_t interval_milliseconds) const { if (bucket_start_time_milliseconds_ == kTimeUnset) { return 0.0; } int64_t current_time = Time(); // Calculate which buckets to sum up given the current time. If the time // has passed to a new bucket then we have to skip some of the oldest buckets. int64_t available_interval_milliseconds = std::min(interval_milliseconds, bucket_milliseconds_ * static_cast(bucket_count_)); // number of old buckets (i.e. after the current bucket in the ring buffer) // that are expired given our current time interval. size_t buckets_to_skip; // Number of milliseconds of the first bucket that are not a portion of the // current interval. int64_t milliseconds_to_skip; if (current_time > initialization_time_milliseconds_ + available_interval_milliseconds) { int64_t time_to_skip = current_time - bucket_start_time_milliseconds_ + static_cast(bucket_count_) * bucket_milliseconds_ - available_interval_milliseconds; buckets_to_skip = time_to_skip / bucket_milliseconds_; milliseconds_to_skip = time_to_skip % bucket_milliseconds_; } else { buckets_to_skip = bucket_count_ - current_bucket_; milliseconds_to_skip = 0; available_interval_milliseconds = TimeDiff(current_time, initialization_time_milliseconds_); // Let one bucket interval pass after initialization before reporting. if (available_interval_milliseconds < bucket_milliseconds_) { return 0.0; } } // If we're skipping all buckets that means that there have been no samples // within the sampling interval so report 0. if (buckets_to_skip > bucket_count_ || available_interval_milliseconds == 0) { return 0.0; } size_t start_bucket = NextBucketIndex(current_bucket_ + buckets_to_skip); // Only count a portion of the first bucket according to how much of the // first bucket is within the current interval. int64_t total_samples = ((sample_buckets_[start_bucket] * (bucket_milliseconds_ - milliseconds_to_skip)) + (bucket_milliseconds_ >> 1)) / bucket_milliseconds_; // All other buckets in the interval are counted in their entirety. for (size_t i = NextBucketIndex(start_bucket); i != NextBucketIndex(current_bucket_); i = NextBucketIndex(i)) { total_samples += sample_buckets_[i]; } // Convert to samples per second. return static_cast(total_samples * 1000) / static_cast(available_interval_milliseconds); } double RateTracker::ComputeTotalRate() const { if (bucket_start_time_milliseconds_ == kTimeUnset) { return 0.0; } int64_t current_time = Time(); if (current_time <= initialization_time_milliseconds_) { return 0.0; } return static_cast(total_sample_count_ * 1000) / static_cast( TimeDiff(current_time, initialization_time_milliseconds_)); } int64_t RateTracker::TotalSampleCount() const { return total_sample_count_; } void RateTracker::AddSamples(int64_t sample_count) { RTC_DCHECK_LE(0, sample_count); EnsureInitialized(); int64_t current_time = Time(); // Advance the current bucket as needed for the current time, and reset // bucket counts as we advance. for (size_t i = 0; i <= bucket_count_ && current_time >= bucket_start_time_milliseconds_ + bucket_milliseconds_; ++i) { bucket_start_time_milliseconds_ += bucket_milliseconds_; current_bucket_ = NextBucketIndex(current_bucket_); sample_buckets_[current_bucket_] = 0; } // Ensure that bucket_start_time_milliseconds_ is updated appropriately if // the entire buffer of samples has been expired. bucket_start_time_milliseconds_ += bucket_milliseconds_ * ((current_time - bucket_start_time_milliseconds_) / bucket_milliseconds_); // Add all samples in the bucket that includes the current time. sample_buckets_[current_bucket_] += sample_count; total_sample_count_ += sample_count; } int64_t RateTracker::Time() const { return rtc::TimeMillis(); } void RateTracker::EnsureInitialized() { if (bucket_start_time_milliseconds_ == kTimeUnset) { initialization_time_milliseconds_ = Time(); bucket_start_time_milliseconds_ = initialization_time_milliseconds_; current_bucket_ = 0; // We only need to initialize the first bucket because we reset buckets when // current_bucket_ increments. sample_buckets_[current_bucket_] = 0; } } size_t RateTracker::NextBucketIndex(size_t bucket_index) const { return (bucket_index + 1u) % (bucket_count_ + 1u); } } // namespace rtc