/* * Copyright(C) 2018 "IoT.bzh" * Author Fulup Ar Foll * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http : //www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * reference : * https://github.com/zonque/simple-alsa-loop/blob/master/loop.c * https://www.alsa-project.org/alsa-doc/alsa-lib/_2test_2pcm_8c-example.html#a31 * */ #define _GNU_SOURCE // needed for vasprintf #include "alsa-softmixer.h" #include #include #include #include "time_utils.h" static int xrun(snd_pcm_t * pcm, int error); static int suspend(snd_pcm_t * pcm, int error); STATIC int AlsaPeriodSize(snd_pcm_format_t pcmFormat) { int pcmSampleSize; switch (pcmFormat) { case SND_PCM_FORMAT_S8: case SND_PCM_FORMAT_U8: pcmSampleSize = 1; break; case SND_PCM_FORMAT_U16_LE: case SND_PCM_FORMAT_U16_BE: case SND_PCM_FORMAT_S16_LE: case SND_PCM_FORMAT_S16_BE: pcmSampleSize = 2; break; case SND_PCM_FORMAT_U24_LE: case SND_PCM_FORMAT_U24_BE: case SND_PCM_FORMAT_S24_LE: case SND_PCM_FORMAT_S24_BE: pcmSampleSize = 3; break; case SND_PCM_FORMAT_U32_LE: case SND_PCM_FORMAT_U32_BE: case SND_PCM_FORMAT_S32_LE: case SND_PCM_FORMAT_S32_BE: pcmSampleSize = 4; break; default: pcmSampleSize = 0; } return pcmSampleSize; } PUBLIC int AlsaPcmConf(SoftMixerT *mixer, AlsaPcmCtlT *pcm, int mode) { int error; snd_pcm_hw_params_t *pxmHwParams; snd_pcm_sw_params_t *pxmSwParams; snd_pcm_format_t format; snd_pcm_access_t access; AlsaPcmHwInfoT * opts = pcm->params; const char * modeS = mode==SND_PCM_STREAM_PLAYBACK?"PLAYBACK":"CAPTURE"; AFB_ApiInfo(mixer->api, "%s: mixer info %s uid %s , pcm %s, mode %s", __func__, mixer->info, mixer->uid, pcm->cid.cardid, modeS); // retrieve hardware config from PCM snd_pcm_hw_params_alloca(&pxmHwParams); error = snd_pcm_hw_params_any(pcm->handle, pxmHwParams); if (error < 0) { AFB_ApiError(mixer->api, "%s: Failed to get parameters: %s", __func__, snd_strerror(error)); goto OnErrorExit; } AFB_ApiNotice(mixer->api, "PARAMS before:\n"); AlsaDumpPcmParams(mixer, pxmHwParams); if (!opts->access) opts->access = SND_PCM_ACCESS_RW_INTERLEAVED; snd_pcm_hw_params_get_access(pxmHwParams, &access); error = snd_pcm_hw_params_set_access(pcm->handle, pxmHwParams, opts->access); if (error) { AFB_ApiError(mixer->api, "%s set_access failed (ignore this error): mixer=%s cardid=%s access=%d Fail current=%d mode error=%s", __func__, mixer->uid, pcm->cid.cardid, opts->access, access, snd_strerror(error)); //Fulup goto OnErrorExit; }; if (opts->format != SND_PCM_FORMAT_UNKNOWN) { snd_pcm_hw_params_get_format(pxmHwParams, &format); if ((error = snd_pcm_hw_params_set_format(pcm->handle, pxmHwParams, opts->format)) < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Set_Format=%s (%d) FAILED current=%d error=%s", __func__, mixer->uid, pcm->cid.cardid, opts->formatS, opts->format, format, snd_strerror(error)); AlsaDumpFormats(mixer, pcm->handle); goto OnErrorExit; } } if (opts->rate > 0 ) { AFB_ApiInfo(mixer->api," %s: set rate to %d", __func__, opts->rate); unsigned int pcmRate = opts->rate; /* Attempt to set the rate. Failing on a capture dev is acceptable */ error = snd_pcm_hw_params_set_rate_near(pcm->handle, pxmHwParams, &opts->rate, 0); if ( mode == SND_PCM_STREAM_PLAYBACK && error < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s FailSet_Rate=%d error=%s", __func__, mixer->uid, pcm->cid.cardid, opts->rate, snd_strerror(error)); goto OnErrorExit; } // check we got requested rate if (mode == SND_PCM_STREAM_PLAYBACK && opts->rate != pcmRate) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Set_Rate Fail ask=%dHz get=%dHz", __func__, mixer->uid, pcm->cid.cardid,pcmRate, opts->rate); goto OnErrorExit; } } if (opts->channels) { if ((error = snd_pcm_hw_params_set_channels(pcm->handle, pxmHwParams, opts->channels)) < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Set_Channels=%d Fail error=%s", __func__, mixer->uid, pcm->cid.cardid, opts->channels, snd_strerror(error)); goto OnErrorExit; }; } /* The following code, that * 1) sets period time/size; buffer time/size hardware params * 2) sets start and stop threashold in software params * ... is taken as such from 'aplay' in alsa-utils */ unsigned buffer_time = 0; unsigned period_time = 0; snd_pcm_uframes_t buffer_frames = 0; snd_pcm_uframes_t period_frames = 0; error = snd_pcm_hw_params_get_buffer_time_max(pxmHwParams, &buffer_time, 0); printf("HW_BUFFER_TIME MAX is %d\n", buffer_time); if (buffer_time > 500000) buffer_time = 500000; if (period_time == 0 && period_frames == 0) { if (buffer_time > 0) period_time = buffer_time / 4; else period_frames = buffer_frames / 4; } if (period_time > 0) { printf("SET PERIOD TIME to %d\n", period_time); error = snd_pcm_hw_params_set_period_time_near(pcm->handle, pxmHwParams, &period_time, 0); } else { printf("SET PERIOD SIZE\n"); error = snd_pcm_hw_params_set_period_size_near(pcm->handle, pxmHwParams, &period_frames, 0); } if (error < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail to set period in hwparams error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; } if (buffer_time > 0) { printf("SET BUFFER TIME to %d\n", buffer_time); error = snd_pcm_hw_params_set_buffer_time_near(pcm->handle, pxmHwParams, &buffer_time, 0); } else { printf("SET BUFFER SIZE\n"); error = snd_pcm_hw_params_set_buffer_size_near(pcm->handle, pxmHwParams, &buffer_frames); } if (error < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail to set buffer in hwparams error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; } // store selected values if ((error = snd_pcm_hw_params(pcm->handle, pxmHwParams)) < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail to apply hwparams error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; } AFB_ApiNotice(mixer->api, "PARAMS after:\n"); AlsaDumpPcmParams(mixer, pxmHwParams); // check we effective hw params after optional format change snd_pcm_hw_params_get_channels(pxmHwParams, &opts->channels); snd_pcm_hw_params_get_format(pxmHwParams, &opts->format); snd_pcm_hw_params_get_rate(pxmHwParams, &opts->rate, 0); AFB_ApiInfo(mixer->api, "rate is %d", opts->rate); opts->sampleSize = AlsaPeriodSize(opts->format); if (opts->sampleSize == 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail unsupported format format=%d", __func__, mixer->uid, pcm->cid.cardid, opts->format); goto OnErrorExit; } snd_pcm_uframes_t chunk_size, buffer_size; snd_pcm_hw_params_get_period_size(pxmHwParams, &chunk_size, 0); snd_pcm_hw_params_get_buffer_size(pxmHwParams, &buffer_size); if (chunk_size == buffer_size) { AFB_ApiError(mixer->api, "Can't use period equal to buffer size (%lu == %lu)", chunk_size, buffer_size); goto OnErrorExit; } int avail_min = -1; size_t n; int rate = opts->rate; if (avail_min < 0) n = chunk_size; else n = (size_t) ((double)rate * avail_min / 1000000); // retrieve software config from PCM snd_pcm_sw_params_alloca(&pxmSwParams); snd_pcm_sw_params_current(pcm->handle, pxmSwParams); // available_min is the minimum number of frames available to read, // when the call to poll returns. Assume this is the same for playback (not checked that) if ((error = snd_pcm_sw_params_set_avail_min(pcm->handle, pxmSwParams, n)) < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail set_buffersize error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; }; snd_pcm_sw_params_get_avail_min(pxmSwParams, &pcm->avail_min); int start_delay = 0; snd_pcm_uframes_t start_threshold; /* round up to closest transfer boundary */ n = buffer_size; if (start_delay <= 0) { start_threshold = n + (size_t)((double)rate * start_delay / 1000000); } else start_threshold = (size_t)((double)rate * start_delay / 1000000); if (start_threshold < 1) start_threshold = 1; if (start_threshold > n/2) start_threshold = n/2; printf("CALCULATED START THRESHOLD: %ld\n", start_threshold); if (mode == SND_PCM_STREAM_PLAYBACK) { start_threshold = 1; } AFB_ApiInfo(mixer->api, "%s: Set start threshold to %ld", modeS, start_threshold); error = snd_pcm_sw_params_set_start_threshold(pcm->handle, pxmSwParams, start_threshold); if (error < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s failed set start_threshold, error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; } // push software params into PCM if ((error = snd_pcm_sw_params(pcm->handle, pxmSwParams)) < 0) { AFB_ApiError(mixer->api, "%s: mixer=%s cardid=%s Fail to push SW params error=%s", __func__, mixer->uid, pcm->cid.cardid, snd_strerror(error)); goto OnErrorExit; }; AFB_ApiNotice(mixer->api, "%s: mixer=%s cardid=%s Done channels=%d rate=%d format=%d access=%d ... done !", __func__, mixer->uid, pcm->cid.cardid, opts->channels, opts->rate, opts->format, opts->access); return 0; OnErrorExit: return -1; } STATIC int AlsaPcmReadCB( struct pollfd * pfd, AlsaPcmCopyHandleT * pcmCopyHandle) { char string[32]; snd_pcm_sframes_t availIn; snd_pcm_t * pcmIn = pcmCopyHandle->pcmIn->handle; alsa_ringbuf_t * rbuf = pcmCopyHandle->rbuf; snd_pcm_uframes_t bufSize = alsa_ringbuf_buffer_size(rbuf); int err; // PCM has was closed if ((pfd->revents & POLLHUP) != 0) { AFB_ApiNotice(pcmCopyHandle->api, "%s PCM=%s hanghup/disconnected", __func__, ALSA_PCM_UID(pcmIn, string)); goto ExitOnSuccess; } // ignore any non input events. This is not supposed to happen ever if ((pfd->revents & EPOLLIN) == 0) { goto ExitOnSuccess; } // do we have waiting frames ? availIn = snd_pcm_avail_update(pcmIn); if (availIn <= 0) { if (availIn == -EPIPE) { int ret = xrun(pcmIn, (int)availIn); printf("XXX read EPIPE (recov=%d) !\n", ret); // For some (undocumented...) reason, a start is mandatory. snd_pcm_start(pcmIn); } goto ExitOnSuccess; } pthread_mutex_lock(&pcmCopyHandle->mutex); snd_pcm_sframes_t availInBuf = alsa_ringbuf_frames_free(rbuf); pthread_mutex_unlock(&pcmCopyHandle->mutex); /* we get too much data, take what we can now, * hopefully we will have more luck next time */ if (availIn > availInBuf) { // printf("INCOMING BUFFER TOO SMALL !\n"); availIn = availInBuf; } while (true) { pthread_mutex_lock(&pcmCopyHandle->mutex); snd_pcm_sframes_t r = alsa_ringbuf_frames_free(rbuf); if (r <= 0) { pthread_mutex_unlock(&pcmCopyHandle->mutex); // Wake up the reader, in case it is sleeping, // that lets it an opportunity to pop something. sem_post(&pcmCopyHandle->sem); break; } if (r < availIn) r = availIn; char buf[r*pcmCopyHandle->frame_size]; pthread_mutex_unlock(&pcmCopyHandle->mutex); r = snd_pcm_readi(pcmIn, buf, r); if (r == 0) { break; } if (r < 0) { if (r == -EPIPE) { err = xrun(pcmIn, (int)r); printf("read EPIPE (%d), recov %d\n", ++pcmCopyHandle->read_err_count, err); goto ExitOnSuccess; } else if (r == -ESTRPIPE) { printf("read ESTRPIPE\n"); if ((err = suspend(pcmIn, (int)r)) < 0) goto ExitOnSuccess; r = 0; } else { goto ExitOnSuccess; } } pthread_mutex_lock(&pcmCopyHandle->mutex); alsa_ringbuf_frames_push(rbuf, buf, r); snd_pcm_uframes_t used = alsa_ringbuf_frames_used(rbuf); pthread_mutex_unlock(&pcmCopyHandle->mutex); // Wait for having the buffer full enough before waking up the playback // else it will starve immediately. if (used > 0.8 * (double)bufSize) { sem_post(&pcmCopyHandle->sem); } availIn -= r; // completed, we have read everything if (availIn <= 0) { break; } } ExitOnSuccess: return 0; } static int xrun( snd_pcm_t * pcm, int error) { int err; if ((err = snd_pcm_recover(pcm, error, 1)) < 0) { return err; } return 0; } static int suspend( snd_pcm_t * pcm, int error) { int err; while ((err = snd_pcm_resume(pcm)) == -EAGAIN) { usleep(1); } if (err < 0) return xrun(pcm, error); return 0; } static void readSuspend(AlsaPcmCopyHandleT * pcmCopyHandle) { // will be deaf pcmCopyHandle->saveFd = pcmCopyHandle->pollFds[1].fd; pcmCopyHandle->pollFds[1].fd = -1; AFB_ApiNotice(pcmCopyHandle->api, "capture muted"); } static void readResume(AlsaPcmCopyHandleT * pcmCopyHandle) { // undeaf it pcmCopyHandle->pollFds[1].fd = pcmCopyHandle->saveFd; snd_pcm_prepare(pcmCopyHandle->pcmIn->handle); snd_pcm_start(pcmCopyHandle->pcmIn->handle); AFB_ApiNotice(pcmCopyHandle->api, "capture unmuted"); } static void *readThreadEntry(void *handle) { #define LOOP_TIMEOUT_MSEC 10*1000 /* 10 seconds */ AlsaPcmCopyHandleT *pcmCopyHandle = (AlsaPcmCopyHandleT*) handle; pcmCopyHandle->tid = (int) syscall(SYS_gettid); AFB_ApiNotice(pcmCopyHandle->api, "%s :%s/%d Started, muted=%d", __func__, pcmCopyHandle->info, pcmCopyHandle->tid, pcmCopyHandle->pcmIn->mute); struct pollfd * mutePfd = &pcmCopyHandle->pollFds[0]; struct pollfd * framePfd = &pcmCopyHandle->pollFds[1]; mutePfd->events = POLLIN | POLLHUP; framePfd->events = POLLIN | POLLHUP; bool muted = pcmCopyHandle->pcmIn->mute; if (muted) readSuspend(pcmCopyHandle); /* loop until end */ for (;;) { int err = poll(pcmCopyHandle->pollFds, pcmCopyHandle->nbPcmFds, LOOP_TIMEOUT_MSEC); if (err < 0) { AFB_ApiError(pcmCopyHandle->api, "%s: poll err %s", __func__, strerror(errno)); continue; } if (err == 0) { /* timeout */ AFB_ApiDebug(pcmCopyHandle->api, "%s(%s) alive, mute %d", __func__, pcmCopyHandle->pcmIn->cid.cardid, muted ); continue; } // handle the un/mute order if ((mutePfd->revents & EPOLLIN) != 0) { bool mute; size_t ret = read(mutePfd->fd, &mute, sizeof(mute)); if (ret <= 0) continue; if (mute == muted) continue; muted = mute; if (muted) { readSuspend(pcmCopyHandle); } else { readResume(pcmCopyHandle); } continue; } unsigned short revents; int ret = snd_pcm_poll_descriptors_revents(pcmCopyHandle->pcmIn->handle, &pcmCopyHandle->pollFds[1], 1, &revents); if (ret == -ENODEV) { sleep(1); continue; } if (framePfd->revents & POLLHUP) { AFB_ApiNotice(pcmCopyHandle->api, "Frame POLLHUP"); continue; } AlsaPcmReadCB(&pcmCopyHandle->pollFds[1], pcmCopyHandle); } pthread_exit(0); return NULL; } static void *writeThreadEntry(void *handle) { AlsaPcmCopyHandleT *pcmCopyHandle = (AlsaPcmCopyHandleT*) handle; snd_pcm_t * pcmOut = pcmCopyHandle->pcmOut->handle; alsa_ringbuf_t * rbuf = pcmCopyHandle->rbuf; const snd_pcm_sframes_t threshold = 1000; for (;;) { sem_wait(&pcmCopyHandle->sem); while (true) { snd_pcm_sframes_t r; snd_pcm_sframes_t availOut = snd_pcm_avail(pcmOut); if (availOut < 0) { if (availOut == -EPIPE) { printf("write update EPIPE\n"); xrun(pcmOut, (int)availOut); continue; } if (availOut == -ESTRPIPE) { printf("write update ESTRPIPE\n"); suspend(pcmOut, (int)availOut); continue; } } // no space for output if (availOut <= threshold) { usleep(500); continue; } pthread_mutex_lock(&pcmCopyHandle->mutex); r = alsa_ringbuf_frames_used(rbuf); if (r <= 0) { pthread_mutex_unlock(&pcmCopyHandle->mutex); break; // will wait again } if (r > availOut) r = availOut; char buf[r*pcmCopyHandle->frame_size]; alsa_ringbuf_frames_pop(rbuf, buf, r); pthread_mutex_unlock(&pcmCopyHandle->mutex); r = snd_pcm_writei( pcmOut, buf, r); if (r <= 0) { if (r == -EPIPE) { int err = xrun(pcmOut, (int)r); printf("XXX write EPIPE (%d), recov %d\n", ++pcmCopyHandle->write_err_count , err); continue; } else if (r == -ESTRPIPE) { printf("XXX write ESTRPIPE\n"); break; } printf("Unhandled error %s\n", strerror(errno)); break; } } } pthread_exit(0); return NULL; } PUBLIC int AlsaPcmCopyMuteSignal(SoftMixerT *mixer, AlsaPcmCtlT *pcmIn, bool mute) { ssize_t ret = write(pcmIn->muteFd, &mute, sizeof(mute)); (void) ret; return 0; } PUBLIC int AlsaPcmCopy(SoftMixerT *mixer, AlsaStreamAudioT *stream, AlsaPcmCtlT *pcmIn, AlsaPcmCtlT *pcmOut, AlsaPcmHwInfoT * opts) { char string[32]; int error; // Fulup need to check https://www.alsa-project.org/alsa-doc/alsa-lib/group___p_c_m___direct.html AlsaDumpPcmInfo(mixer,"PcmIn",pcmIn->handle); AlsaDumpPcmInfo(mixer,"PcmOut",pcmOut->handle); AFB_ApiInfo(mixer->api, "%s: Configure CAPTURE PCM", __func__); /* remember configuration of capture */ pcmIn->params = (AlsaPcmHwInfoT*)malloc(sizeof(AlsaPcmHwInfoT)); memcpy(pcmIn->params, opts, sizeof(AlsaPcmHwInfoT)); pcmOut->params = (AlsaPcmHwInfoT*)malloc(sizeof(AlsaPcmHwInfoT)); memcpy(pcmOut->params, opts, sizeof(AlsaPcmHwInfoT)); pcmIn->mixer = mixer; pcmOut->mixer = mixer; AFB_ApiInfo(mixer->api, "%s: Configure CAPTURE PCM", __func__); // prepare PCM for capture and replay error = AlsaPcmConf(mixer, pcmIn, SND_PCM_STREAM_CAPTURE); if (error) { AFB_ApiError(mixer->api, "%s: PCM configuration for capture failed", __func__); goto OnErrorExit; } AFB_ApiInfo(mixer->api, "%s: Configure PLAYBACK PCM", __func__); // input and output should match error = AlsaPcmConf(mixer, pcmOut, SND_PCM_STREAM_PLAYBACK); if (error) { AFB_ApiError(mixer->api, "%s: PCM configuration for playback failed", __func__); goto OnErrorExit; } // Prepare PCM for usage if ((error = snd_pcm_prepare(pcmOut->handle)) < 0) { AFB_ApiError(mixer->api, "%s: Fail to prepare PLAYBACK PCM=%s error=%s", __func__, ALSA_PCM_UID(pcmOut->handle, string), snd_strerror(error)); goto OnErrorExit; }; // Prepare PCM for usage if ((error = snd_pcm_prepare(pcmIn->handle)) < 0) { AFB_ApiError(mixer->api, "%s: Fail to prepare CAPTURE PCM=%s error=%s", __func__, ALSA_PCM_UID(pcmOut->handle, string), snd_strerror(error)); goto OnErrorExit; }; // Start PCM if ((error = snd_pcm_start(pcmOut->handle)) < 0) { AFB_ApiError(mixer->api, "%s: Fail to start PLAYBACK PCM=%s error=%s", __func__, ALSA_PCM_UID(pcmIn->handle, string), snd_strerror(error)); goto OnErrorExit; }; // Start PCM if ((error = snd_pcm_start(pcmIn->handle)) < 0) { AFB_ApiError(mixer->api, "%s: Fail to start CAPTURE PCM=%s error=%s", __func__, ALSA_PCM_UID(pcmIn->handle, string), snd_strerror(error)); goto OnErrorExit; }; AlsaPcmCopyHandleT *cHandle= calloc(1, sizeof(AlsaPcmCopyHandleT)); cHandle->info = "pcmCpy"; cHandle->pcmIn = pcmIn; cHandle->pcmOut = pcmOut; cHandle->api = mixer->api; cHandle->channels = opts->channels; cHandle->frame_size = (snd_pcm_format_physical_width(opts->format) / 8) * opts->channels; AFB_ApiInfo(mixer->api, "%s: Frame size is %zu", __func__, cHandle->frame_size); snd_pcm_uframes_t nbFrames = 2 * opts->rate; // Exactly 2 second of buffer cHandle->rbuf = alsa_ringbuf_new(nbFrames, cHandle->frame_size); cHandle->read_err_count = 0; cHandle->write_err_count = 0; AFB_ApiInfo(mixer->api, "%s Copy buffer nbframes is %zu", __func__, nbFrames); // get FD poll descriptor for capture PCM int pcmInCount = snd_pcm_poll_descriptors_count(pcmIn->handle); if (pcmInCount <= 0) { AFB_ApiError(mixer->api, "%s: Fail pcmIn=%s get fds count error=%s", __func__, ALSA_PCM_UID(pcmIn->handle, string), snd_strerror(error)); goto OnErrorExit; }; if (pcmInCount > 1) { AFB_ApiError(mixer->api, "%s: Fail, pcmIn=%s; having more than one FD on capture PCM is not supported (here, %d)", __func__, ALSA_PCM_UID(pcmOut->handle, string) , pcmInCount); goto OnErrorExit; } struct pollfd pcmInFd; if ((error = snd_pcm_poll_descriptors(pcmIn->handle, &pcmInFd, 1)) < 0) { AFB_ApiError(mixer->api, "%s: Fail pcmIn=%s get pollfds error=%s", __func__, ALSA_PCM_UID(pcmOut->handle, string), snd_strerror(error)); goto OnErrorExit; }; // create the mute pipe int pMuteFd[2]; error = pipe(pMuteFd); if (error < 0) { AFB_ApiError(mixer->api, "Unable to create the mute signaling pipe\n"); goto OnErrorExit; } struct pollfd mutePFd; // read end mutePFd.fd = pMuteFd[0]; mutePFd.events = POLLIN; mutePFd.revents = 0; // write end pcmIn->muteFd = pMuteFd[1]; cHandle->pollFds[0] = mutePFd; cHandle->pollFds[1] = pcmInFd; cHandle->nbPcmFds = pcmInCount+1; error = sem_init(&cHandle->sem, 0 , 0); if (error < 0) { AFB_ApiError(mixer->api, "%s Fail initialize loop semaphore pcmIn=%s err=%d", __func__, ALSA_PCM_UID(pcmIn->handle, string), error); goto OnErrorExit; } pthread_mutexattr_t attr; pthread_mutexattr_init(&attr); pthread_mutexattr_setprotocol(&attr, PTHREAD_PRIO_INHERIT); error = pthread_mutex_init(&cHandle->mutex, &attr); if (error < 0) { AFB_ApiError(mixer->api, "%s Fail initialize loop mutex pcmIn=%s err=%d", __func__, ALSA_PCM_UID(pcmIn->handle, string), error); } /// start a thread for writing if ((error = pthread_create(&cHandle->wthread, NULL, &readThreadEntry, cHandle)) < 0) { AFB_ApiError(mixer->api, "%s Fail create write thread pcmOut=%s err=%d", __func__, ALSA_PCM_UID(pcmOut->handle, string), error); goto OnErrorExit; } // start a thread for reading if ((error = pthread_create(&cHandle->rthread, NULL, &writeThreadEntry, cHandle)) < 0) { AFB_ApiError(mixer->api, "%s Fail create read thread pcmIn=%s err=%d", __func__, ALSA_PCM_UID(pcmIn->handle, string), error); goto OnErrorExit; } // request a higher priority for each audio stream thread struct sched_param params; params.sched_priority = sched_get_priority_max(SCHED_FIFO); error= pthread_setschedparam(cHandle->rthread, SCHED_FIFO, ¶ms); if (error) { AFB_ApiWarning(mixer->api, "%s: Failed to increase stream read thread priority pcmIn=%s err=%s", __func__, ALSA_PCM_UID(pcmIn->handle, string), strerror(error)); } error= pthread_setschedparam(cHandle->wthread, SCHED_FIFO, ¶ms); if (error) { AFB_ApiWarning(mixer->api, "%s: Failed to increase stream write thread priority pcmIn=%s err=%s", __func__, ALSA_PCM_UID(pcmOut->handle, string), strerror(error)); } return 0; OnErrorExit: AFB_ApiError(mixer->api, "%s: - pcmIn=%s" , __func__, ALSA_PCM_UID(pcmIn->handle, string)); AFB_ApiError(mixer->api, "%s: - pcmOut=%s", __func__, ALSA_PCM_UID(pcmOut->handle, string)); return -1; }