1 // Parts of the code is adapted from Adriaensen's project Zita-ajbridge
2 // (as of November 2015), although it has been heavily reworked for this use
3 // case. Original copyright follows:
5 // Copyright (C) 2012-2015 Fons Adriaensen <fons@linuxaudio.org>
7 // This program is free software; you can redistribute it and/or modify
8 // it under the terms of the GNU General Public License as published by
9 // the Free Software Foundation; either version 3 of the License, or
10 // (at your option) any later version.
12 // This program is distributed in the hope that it will be useful,
13 // but WITHOUT ANY WARRANTY; without even the implied warranty of
14 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 // GNU General Public License for more details.
17 // You should have received a copy of the GNU General Public License
18 // along with this program. If not, see <http://www.gnu.org/licenses/>.
20 #include "resampling_queue.h"
29 #include <sys/types.h>
30 #include <zita-resampler/vresampler.h>
33 #include "shared/shared_defs.h"
36 using namespace std::chrono;
38 ResamplingQueue::ResamplingQueue(const std::string &debug_description, unsigned freq_in, unsigned freq_out, unsigned num_channels, double expected_delay_seconds)
39 : debug_description(debug_description), freq_in(freq_in), freq_out(freq_out), num_channels(num_channels),
40 current_estimated_freq_in(freq_in),
41 ratio(double(freq_out) / double(freq_in)), expected_delay(expected_delay_seconds * OUTPUT_FREQUENCY)
43 vresampler.setup(ratio, num_channels, /*hlen=*/32);
45 // Prime the resampler so there's no more delay.
46 vresampler.inp_count = vresampler.inpsize() / 2 - 1;
47 vresampler.out_count = 1048576;
48 vresampler.process ();
51 void ResamplingQueue::add_input_samples(steady_clock::time_point ts, const float *samples, ssize_t num_samples, ResamplingQueue::RateAdjustmentPolicy rate_adjustment_policy)
53 if (num_samples == 0) {
57 assert(duration<double>(ts.time_since_epoch()).count() >= 0.0);
59 bool good_sample = (rate_adjustment_policy == ADJUST_RATE);
60 if (good_sample && a1.good_sample) {
64 a1.input_samples_received += num_samples;
65 a1.good_sample = good_sample;
66 if (a0.good_sample && a1.good_sample) {
67 current_estimated_freq_in = (a1.input_samples_received - a0.input_samples_received) / duration<double>(a1.ts - a0.ts).count();
68 if (!(current_estimated_freq_in >= 0.0)) {
69 fprintf(stderr, "%s: PANIC: Input audio clock going backwards, ignoring.\n",
70 debug_description.c_str());
71 current_estimated_freq_in = freq_in;
74 // Bound the frequency, so that a single wild result won't throw the filter off guard.
75 current_estimated_freq_in = min(current_estimated_freq_in, 1.2 * freq_in);
76 current_estimated_freq_in = max(current_estimated_freq_in, 0.8 * freq_in);
79 buffer.insert(buffer.end(), samples, samples + num_samples * num_channels);
82 bool ResamplingQueue::get_output_samples(steady_clock::time_point ts, float *samples, ssize_t num_samples, ResamplingQueue::RateAdjustmentPolicy rate_adjustment_policy)
84 assert(num_samples > 0);
85 if (a1.input_samples_received == 0) {
86 // No data yet, just return zeros.
87 memset(samples, 0, num_samples * num_channels * sizeof(float));
91 // This can happen when we get dropped frames on the master card.
92 if (duration<double>(ts.time_since_epoch()).count() <= 0.0) {
93 rate_adjustment_policy = DO_NOT_ADJUST_RATE;
96 if (rate_adjustment_policy == ADJUST_RATE && (a0.good_sample || a1.good_sample)) {
97 // Estimate the current number of input samples produced at
98 // this instant in time, by extrapolating from the last known
99 // good point. Note that we could be extrapolating backward or
100 // forward, depending on the timing of the calls.
101 const InputPoint &base_point = a1.good_sample ? a1 : a0;
102 assert(duration<double>(base_point.ts.time_since_epoch()).count() >= 0.0);
104 // NOTE: Due to extrapolation, input_samples_received can
105 // actually go negative here the few first calls (ie., we asked
106 // about a timestamp where we hadn't actually started producing
107 // samples yet), but that is harmless.
108 const double input_samples_received = base_point.input_samples_received +
109 current_estimated_freq_in * duration<double>(ts - base_point.ts).count();
111 // Estimate the number of input samples _consumed_ after we've run the resampler.
112 const double input_samples_consumed = total_consumed_samples +
113 num_samples / (ratio * rcorr);
115 double actual_delay = input_samples_received - input_samples_consumed;
116 actual_delay += vresampler.inpdist(); // Delay in the resampler itself.
117 double err = actual_delay - expected_delay;
119 // Before the very first block, insert artificial delay based on our initial estimate,
120 // so that we don't need a long period to stabilize at the beginning.
122 int delay_samples_to_add = lrintf(-err);
123 for (ssize_t i = 0; i < delay_samples_to_add * int(num_channels); ++i) {
124 buffer.push_front(0.0f);
126 total_consumed_samples -= delay_samples_to_add; // Equivalent to increasing input_samples_received on a0 and a1.
127 err += delay_samples_to_add;
128 } else if (err > 0.0) {
129 int delay_samples_to_remove = min<int>(lrintf(err), buffer.size() / num_channels);
130 buffer.erase(buffer.begin(), buffer.begin() + delay_samples_to_remove * num_channels);
131 total_consumed_samples += delay_samples_to_remove;
132 err -= delay_samples_to_remove;
135 first_output = false;
137 // Compute loop filter coefficients for the two filters. We need to compute them
138 // every time, since they depend on the number of samples the user asked for.
140 // The loop bandwidth is at 0.02 Hz; our jitter is pretty large
141 // since none of the threads involved run at real-time priority.
142 // However, the first four seconds, we use a larger loop bandwidth (2 Hz),
143 // because there's a lot going on during startup, and thus the
144 // initial estimate might be tainted by jitter during that phase,
145 // and we want to converge faster.
147 // NOTE: The above logic might only hold during Nageru startup
148 // (we start ResamplingQueues also when we e.g. switch sound sources),
149 // but in general, a little bit of increased timing jitter is acceptable
150 // right after a setup change like this.
151 double loop_bandwidth_hz = (total_consumed_samples < 4 * int(freq_in)) ? 0.2 : 0.02;
153 // Set filters. The first filter much wider than the first one (20x as wide).
154 double w = (2.0 * M_PI) * loop_bandwidth_hz * num_samples / freq_out;
155 double w0 = 1.0 - exp(-20.0 * w);
156 double w1 = w * 1.5 / num_samples / ratio;
159 // Filter <err> through the loop filter to find the correction ratio.
160 z1 += w0 * (w1 * err - z1);
161 z2 += w0 * (z1 - z2);
163 rcorr = 1.0 - z2 - z3;
164 if (rcorr > 1.05) rcorr = 1.05;
165 if (rcorr < 0.95) rcorr = 0.95;
166 assert(!isnan(rcorr));
167 vresampler.set_rratio(rcorr);
170 // Finally actually resample, producing exactly <num_samples> output samples.
171 vresampler.out_data = samples;
172 vresampler.out_count = num_samples;
173 while (vresampler.out_count > 0) {
174 if (buffer.empty()) {
175 // This should never happen unless delay is set way too low,
176 // or we're dropping a lot of data.
177 fprintf(stderr, "%s: PANIC: Out of input samples to resample, still need %d output samples! (correction factor is %f)\n",
178 debug_description.c_str(), int(vresampler.out_count), rcorr);
179 memset(vresampler.out_data, 0, vresampler.out_count * num_channels * sizeof(float));
181 // Reset the loop filter.
188 size_t num_input_samples = sizeof(inbuf) / (sizeof(float) * num_channels);
189 if (num_input_samples * num_channels > buffer.size()) {
190 num_input_samples = buffer.size() / num_channels;
192 copy(buffer.begin(), buffer.begin() + num_input_samples * num_channels, inbuf);
194 vresampler.inp_count = num_input_samples;
195 vresampler.inp_data = inbuf;
197 int err = vresampler.process();
200 size_t consumed_samples = num_input_samples - vresampler.inp_count;
201 total_consumed_samples += consumed_samples;
202 buffer.erase(buffer.begin(), buffer.begin() + consumed_samples * num_channels);