Switch to summaries instead of histograms for latency; they were not getting precise...

[nageru] / print_latency.cpp

#include "print_latency.h"

#include "flags.h"
#include "metrics.h"
#include "mixer.h"

#include <stdio.h>
#include <algorithm>
#include <chrono>
#include <string>

using namespace std;
using namespace std::chrono;

ReceivedTimestamps find_received_timestamp(const vector<RefCountedFrame> &input_frames)
{
        unsigned num_cards = global_mixer->get_num_cards();
        assert(input_frames.size() == num_cards * FRAME_HISTORY_LENGTH);

        ReceivedTimestamps ts;
        for (unsigned card_index = 0; card_index < num_cards; ++card_index) {
                for (unsigned frame_index = 0; frame_index < FRAME_HISTORY_LENGTH; ++frame_index) {
                        const RefCountedFrame &input_frame = input_frames[card_index * FRAME_HISTORY_LENGTH + frame_index];
                        if (input_frame == nullptr ||
                            (frame_index > 0 && input_frame.get() == input_frames[card_index * FRAME_HISTORY_LENGTH + frame_index - 1].get())) {
                                ts.ts.push_back(steady_clock::time_point::min());
                        } else {
                                ts.ts.push_back(input_frame->received_timestamp);
                        }
                }
        }
        return ts;
}

void LatencyHistogram::init(const string &measuring_point)
{
        unsigned num_cards = global_flags.num_cards;  // The mixer might not be ready yet.
        summaries.resize(num_cards * FRAME_HISTORY_LENGTH * 2);
        for (unsigned card_index = 0; card_index < num_cards; ++card_index) {
                char card_index_str[64];
                snprintf(card_index_str, sizeof(card_index_str), "%u", card_index);
                summaries[card_index].resize(FRAME_HISTORY_LENGTH);
                for (unsigned frame_index = 0; frame_index < FRAME_HISTORY_LENGTH; ++frame_index) {
                        char frame_index_str[64];
                        snprintf(frame_index_str, sizeof(frame_index_str), "%u", frame_index);

                        summaries[card_index][frame_index].reset(
                                new Summary[2]{{{0.01, 0.1, 0.25, 0.5, 0.75, 0.9, 0.99}, 60.0},
                                               {{0.01, 0.1, 0.25, 0.5, 0.75, 0.9, 0.99}, 60.0}});
                        global_metrics.add("latency_seconds",
                                {{ "measuring_point", measuring_point },
                                 { "card", card_index_str },
                                 { "frame_age", frame_index_str },
                                 { "frame_type", "i/p" }},
                                 &summaries[card_index][frame_index][0],
                                (frame_index == 0) ? Metrics::PRINT_ALWAYS : Metrics::PRINT_WHEN_NONEMPTY);
                        global_metrics.add("latency_seconds",
                                {{ "measuring_point", measuring_point },
                                 { "card", card_index_str },
                                 { "frame_age", frame_index_str },
                                 { "frame_type", "b" }},
                                 &summaries[card_index][frame_index][1],
                                Metrics::PRINT_WHEN_NONEMPTY);
                }
        }
}

void print_latency(const string &header, const ReceivedTimestamps &received_ts, bool is_b_frame, int *frameno, LatencyHistogram *histogram)
{
        if (received_ts.ts.empty())
                return;

        const steady_clock::time_point now = steady_clock::now();

        unsigned num_cards = global_mixer->get_num_cards();
        assert(received_ts.ts.size() == num_cards * FRAME_HISTORY_LENGTH);
        for (unsigned card_index = 0; card_index < num_cards; ++card_index) {
                for (unsigned frame_index = 0; frame_index < FRAME_HISTORY_LENGTH; ++frame_index) {
                        steady_clock::time_point ts = received_ts.ts[card_index * FRAME_HISTORY_LENGTH + frame_index];
                        if (ts == steady_clock::time_point::min()) {
                                continue;
                        }
                        duration<double> latency = now - ts;
                        histogram->summaries[card_index][frame_index][is_b_frame].count_event(latency.count());
                }
        }

        // 101 is chosen so that it's prime, which is unlikely to get the same frame type every time.
        if (global_flags.print_video_latency && (++*frameno % 101) == 0) {
                // Find min and max timestamp of all input frames that have a timestamp.
                steady_clock::time_point min_ts = steady_clock::time_point::max(), max_ts = steady_clock::time_point::min();
                for (const auto &ts : received_ts.ts) {
                        if (ts > steady_clock::time_point::min()) {
                                min_ts = min(min_ts, ts);
                                max_ts = max(max_ts, ts);
                        }
                }
                duration<double> lowest_latency = now - max_ts;
                duration<double> highest_latency = now - min_ts;

                printf("%-60s %4.0f ms (lowest-latency input), %4.0f ms (highest-latency input)",
                        header.c_str(), 1e3 * lowest_latency.count(), 1e3 * highest_latency.count());

                if (is_b_frame) {
                        printf("  [on B-frame; potential extra latency]\n");
                } else {
                        printf("\n");
                }
        }
}