/* * Copyright (C) 2013-2015 Intel Corporation * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include #include #include #include #include #include "common.h" #include "bat-signal.h" #include "gettext.h" /* How one measurement step works: - Listen and measure the average loudness of the environment for 1 second. - Create a threshold value 16 decibels higher than the average loudness. - Begin playing a ~1000 Hz sine wave and start counting the samples elapsed. - Stop counting and playing if the input's loudness is higher than the threshold, as the output wave is probably coming back. - Calculate the round trip audio latency value in milliseconds. */ static float sumaudio(struct bat *bat, short int *buffer, int frames) { float sum = 0; int n = 0; while (frames) { frames--; for (n = 0; n < bat->channels; n++) { sum += abs(buffer[0]); buffer++; } } sum = sum / bat->channels; return sum; } static void play_and_listen(struct bat *bat, void *buffer, int frames) { int averageinput; int n = 0; float sum = 0; float max = 0; float min = 100000.0f; short int *input; int num = bat->latency.number; averageinput = (int) (sumaudio(bat, buffer, frames) / frames); /* The signal is above threshold So our sine wave comes back on the input */ if (averageinput > bat->latency.threshold) { input = buffer; /* Check the location when it became loud enough */ while (n < frames) { if (*input++ > bat->latency.threshold) break; *input += bat->channels; n++; } /* Now we get the total round trip latency*/ bat->latency.samples += n; /* Expect at least 1 buffer of round trip latency. */ if (bat->latency.samples > frames) { bat->latency.result[num - 1] = (float) bat->latency.samples * 1000 / bat->rate; fprintf(bat->log, _("Test%d, round trip latency %dms\n"), num, (int) bat->latency.result[num - 1]); for (n = 0; n < num; n++) { if (bat->latency.result[n] > max) max = bat->latency.result[n]; if (bat->latency.result[n] < min) min = bat->latency.result[n]; sum += bat->latency.result[n]; } /* The maximum is higher than the minimum's double */ if (max / min > 2.0f) { bat->latency.state = LATENCY_STATE_COMPLETE_FAILURE; bat->latency.is_capturing = false; return; /* Final results */ } else if (num == LATENCY_TEST_NUMBER) { bat->latency.final_result = (int) (sum / LATENCY_TEST_NUMBER); fprintf(bat->log, _("Final round trip latency: %dms\n"), bat->latency.final_result); bat->latency.state = LATENCY_STATE_COMPLETE_SUCCESS; bat->latency.is_capturing = false; return; /* Next step */ } else bat->latency.state = LATENCY_STATE_WAITING; bat->latency.number++; } else /* Happens when an early noise comes in */ bat->latency.state = LATENCY_STATE_WAITING; } else { /* Still listening */ bat->latency.samples += frames; /* Do not listen to more than a second Maybe too much background noise */ if ((unsigned int)bat->latency.samples > bat->rate) { bat->latency.error++; if (bat->latency.error > LATENCY_TEST_NUMBER) { fprintf(bat->err, _("Could not detect signal.")); fprintf(bat->err, _("Too much background noise?\n")); bat->latency.state = LATENCY_STATE_COMPLETE_FAILURE; bat->latency.is_capturing = false; return; } /* let's start over */ bat->latency.state = LATENCY_STATE_WAITING; } } return; } static void calculate_threshold(struct bat *bat) { float average; float reference; /* Calculate the average loudness of the environment and create a threshold value 16 decibels higher than the average loudness */ average = bat->latency.sum / bat->latency.samples / 32767.0f; reference = 20.0f * log10f(average) + 16.0f; bat->latency.threshold = (int) (powf(10.0f, reference / 20.0f) * 32767.0f); } void roundtrip_latency_init(struct bat *bat) { bat->latency.number = 1; bat->latency.state = LATENCY_STATE_MEASURE_FOR_1_SECOND; bat->latency.final_result = 0; bat->latency.samples = 0; bat->latency.sum = 0; bat->latency.threshold = 0; bat->latency.is_capturing = false; bat->latency.is_playing = false; bat->latency.error = 0; bat->latency.xrun_error = false; bat->frames = LATENCY_TEST_TIME_LIMIT * bat->rate; bat->periods_played = 0; } int handleinput(struct bat *bat, void *buffer, int frames) { switch (bat->latency.state) { /* Measuring average loudness for 1 second */ case LATENCY_STATE_MEASURE_FOR_1_SECOND: bat->latency.sum += sumaudio(bat, buffer, frames); bat->latency.samples += frames; /* 1 second elapsed */ if ((unsigned int)bat->latency.samples >= bat->rate) { calculate_threshold(bat); bat->latency.state = LATENCY_STATE_PLAY_AND_LISTEN; bat->latency.samples = 0; bat->latency.sum = 0; } break; /* Playing sine wave and listening if it comes back */ case LATENCY_STATE_PLAY_AND_LISTEN: play_and_listen(bat, buffer, frames); break; /* Waiting 1 second */ case LATENCY_STATE_WAITING: bat->latency.samples += frames; if ((unsigned int)bat->latency.samples > bat->rate) { /* 1 second elapsed, start over */ bat->latency.samples = 0; bat->latency.state = LATENCY_STATE_MEASURE_FOR_1_SECOND; } break; default: return 0; } return 0; } int handleoutput(struct bat *bat, void *buffer, int bytes, int frames) { int err = 0; /* If capture completed, terminate the playback */ if (bat->periods_played * frames > 2 * bat->rate && bat->latency.is_capturing == false) return bat->latency.state; if (bat->latency.state == LATENCY_STATE_PLAY_AND_LISTEN) err = generate_sine_wave(bat, frames, buffer); else /* Output silence */ memset(buffer, 0, bytes); return err; }