mirror of
https://gitlab.freedesktop.org/gstreamer/gst-plugins-rs.git
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9b96cfc452
Contrary to the existing Task Sink, the Async and Sync Mutex Sinks handle buffers in the `PadSinkHandler` directly. The Async Mutex Sink uses an async Mutex for the `PadSinkHandlerInner` while the Sync Mutex Sink uses... a sync Mutex. All Sinks share the same settings and stats manager. Use the `--sink` command line option to select the sink (default is `sync-mutex` since it allows evaluating the framework with as little overhead as possible. Also apply various fixes: - Only keep the segment start instead of the full `Segment`. This helps with cache locality (`Segment` is a plain struct with many fields) and avoids downcasting the generic `Segment` upon each buffer handling. - Box the `Stat`s. This should improve cache locality a bit. - Fix EOS handling which took ages for no benefits in this particular use case. - Use a macro to raise log level in the main element. - Move error handling during item processing in `handle_loop_error`. This function was precisely designed for this and it should reduce the `handle_item`'s Future size.
270 lines
8.7 KiB
Rust
270 lines
8.7 KiB
Rust
use gst::prelude::*;
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use std::time::{Duration, Instant};
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#[cfg(feature = "tuning")]
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use gstthreadshare::runtime::Context;
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use super::CAT;
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const LOG_PERIOD: Duration = Duration::from_secs(20);
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#[derive(Debug, Default)]
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pub struct Stats {
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ramp_up_instant: Option<Instant>,
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log_start_instant: Option<Instant>,
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last_delta_instant: Option<Instant>,
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max_buffers: Option<f32>,
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buffer_count: f32,
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buffer_count_delta: f32,
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latency_sum: f32,
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latency_square_sum: f32,
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latency_sum_delta: f32,
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latency_square_sum_delta: f32,
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latency_min: Duration,
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latency_min_delta: Duration,
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latency_max: Duration,
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latency_max_delta: Duration,
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interval_sum: f32,
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interval_square_sum: f32,
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interval_sum_delta: f32,
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interval_square_sum_delta: f32,
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interval_min: Duration,
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interval_min_delta: Duration,
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interval_max: Duration,
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interval_max_delta: Duration,
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interval_late_warn: Duration,
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interval_late_count: f32,
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interval_late_count_delta: f32,
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#[cfg(feature = "tuning")]
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parked_duration_init: Duration,
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}
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impl Stats {
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pub fn new(max_buffers: Option<u32>, interval_late_warn: Duration) -> Self {
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Stats {
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max_buffers: max_buffers.map(|max_buffers| max_buffers as f32),
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interval_late_warn,
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..Default::default()
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}
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}
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pub fn start(&mut self) {
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self.buffer_count = 0.0;
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self.buffer_count_delta = 0.0;
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self.latency_sum = 0.0;
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self.latency_square_sum = 0.0;
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self.latency_sum_delta = 0.0;
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self.latency_square_sum_delta = 0.0;
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self.latency_min = Duration::MAX;
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self.latency_min_delta = Duration::MAX;
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self.latency_max = Duration::ZERO;
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self.latency_max_delta = Duration::ZERO;
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self.interval_sum = 0.0;
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self.interval_square_sum = 0.0;
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self.interval_sum_delta = 0.0;
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self.interval_square_sum_delta = 0.0;
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self.interval_min = Duration::MAX;
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self.interval_min_delta = Duration::MAX;
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self.interval_max = Duration::ZERO;
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self.interval_max_delta = Duration::ZERO;
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self.interval_late_count = 0.0;
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self.interval_late_count_delta = 0.0;
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self.last_delta_instant = None;
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self.log_start_instant = None;
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self.ramp_up_instant = Some(Instant::now());
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gst::info!(CAT, "First stats logs in {:2?}", 2 * LOG_PERIOD);
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}
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pub fn is_active(&mut self) -> bool {
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if let Some(ramp_up_instant) = self.ramp_up_instant {
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if ramp_up_instant.elapsed() < LOG_PERIOD {
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return false;
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}
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self.ramp_up_instant = None;
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gst::info!(CAT, "Ramp up complete. Stats logs in {:2?}", LOG_PERIOD);
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self.log_start_instant = Some(Instant::now());
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self.last_delta_instant = self.log_start_instant;
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#[cfg(feature = "tuning")]
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{
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self.parked_duration_init = Context::current().unwrap().parked_duration();
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}
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}
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use std::cmp::Ordering::*;
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match self.max_buffers.opt_cmp(self.buffer_count) {
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Some(Equal) => {
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self.log_global();
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self.buffer_count += 1.0;
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false
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}
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Some(Less) => false,
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_ => true,
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}
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}
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pub fn add_buffer(&mut self, latency: Duration, interval: Duration) {
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if !self.is_active() {
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return;
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}
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self.buffer_count += 1.0;
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self.buffer_count_delta += 1.0;
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// Latency
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let latency_f32 = latency.as_nanos() as f32;
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let latency_square = latency_f32.powi(2);
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self.latency_sum += latency_f32;
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self.latency_square_sum += latency_square;
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self.latency_min = self.latency_min.min(latency);
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self.latency_max = self.latency_max.max(latency);
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self.latency_sum_delta += latency_f32;
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self.latency_square_sum_delta += latency_square;
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self.latency_min_delta = self.latency_min_delta.min(latency);
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self.latency_max_delta = self.latency_max_delta.max(latency);
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// Interval
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let interval_f32 = interval.as_nanos() as f32;
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let interval_square = interval_f32.powi(2);
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self.interval_sum += interval_f32;
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self.interval_square_sum += interval_square;
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self.interval_min = self.interval_min.min(interval);
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self.interval_max = self.interval_max.max(interval);
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self.interval_sum_delta += interval_f32;
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self.interval_square_sum_delta += interval_square;
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self.interval_min_delta = self.interval_min_delta.min(interval);
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self.interval_max_delta = self.interval_max_delta.max(interval);
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if interval > self.interval_late_warn {
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self.interval_late_count += 1.0;
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self.interval_late_count_delta += 1.0;
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}
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let delta_duration = match self.last_delta_instant {
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Some(last_delta) => last_delta.elapsed(),
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None => return,
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};
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if delta_duration < LOG_PERIOD {
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return;
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}
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self.last_delta_instant = Some(Instant::now());
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gst::info!(CAT, "Delta stats:");
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let interval_mean = self.interval_sum_delta / self.buffer_count_delta;
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let interval_std_dev = f32::sqrt(
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self.interval_square_sum_delta / self.buffer_count_delta - interval_mean.powi(2),
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);
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gst::info!(
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CAT,
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"o interval: mean {:4.2?} σ {:4.1?} [{:4.1?}, {:4.1?}]",
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Duration::from_nanos(interval_mean as u64),
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Duration::from_nanos(interval_std_dev as u64),
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self.interval_min_delta,
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self.interval_max_delta,
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);
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if self.interval_late_count_delta > f32::EPSILON {
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gst::warning!(
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CAT,
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"o {:5.2}% late buffers",
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100f32 * self.interval_late_count_delta / self.buffer_count_delta
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);
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}
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self.interval_sum_delta = 0.0;
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self.interval_square_sum_delta = 0.0;
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self.interval_min_delta = Duration::MAX;
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self.interval_max_delta = Duration::ZERO;
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self.interval_late_count_delta = 0.0;
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let latency_mean = self.latency_sum_delta / self.buffer_count_delta;
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let latency_std_dev = f32::sqrt(
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self.latency_square_sum_delta / self.buffer_count_delta - latency_mean.powi(2),
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);
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gst::info!(
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CAT,
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"o latency: mean {:4.2?} σ {:4.1?} [{:4.1?}, {:4.1?}]",
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Duration::from_nanos(latency_mean as u64),
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Duration::from_nanos(latency_std_dev as u64),
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self.latency_min_delta,
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self.latency_max_delta,
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);
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self.latency_sum_delta = 0.0;
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self.latency_square_sum_delta = 0.0;
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self.latency_min_delta = Duration::MAX;
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self.latency_max_delta = Duration::ZERO;
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self.buffer_count_delta = 0.0;
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}
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pub fn log_global(&mut self) {
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if self.buffer_count < 1.0 {
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return;
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}
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let _log_start = if let Some(log_start) = self.log_start_instant {
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log_start
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} else {
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return;
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};
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gst::info!(CAT, "Global stats:");
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#[cfg(feature = "tuning")]
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{
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let duration = _log_start.elapsed();
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let parked_duration =
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Context::current().unwrap().parked_duration() - self.parked_duration_init;
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gst::info!(
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CAT,
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"o parked: {parked_duration:4.2?} ({:5.2?}%)",
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(parked_duration.as_nanos() as f32 * 100.0 / duration.as_nanos() as f32)
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);
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}
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let interval_mean = self.interval_sum / self.buffer_count;
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let interval_std_dev =
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f32::sqrt(self.interval_square_sum / self.buffer_count - interval_mean.powi(2));
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gst::info!(
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CAT,
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"o interval: mean {:4.2?} σ {:4.1?} [{:4.1?}, {:4.1?}]",
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Duration::from_nanos(interval_mean as u64),
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Duration::from_nanos(interval_std_dev as u64),
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self.interval_min,
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self.interval_max,
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);
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if self.interval_late_count > f32::EPSILON {
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gst::warning!(
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CAT,
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"o {:5.2}% late buffers",
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100f32 * self.interval_late_count / self.buffer_count
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);
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}
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let latency_mean = self.latency_sum / self.buffer_count;
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let latency_std_dev =
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f32::sqrt(self.latency_square_sum / self.buffer_count - latency_mean.powi(2));
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gst::info!(
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CAT,
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"o latency: mean {:4.2?} σ {:4.1?} [{:4.1?}, {:4.1?}]",
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Duration::from_nanos(latency_mean as u64),
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Duration::from_nanos(latency_std_dev as u64),
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self.latency_min,
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self.latency_max,
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);
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}
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}
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