/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2005 by Nick Lanham * Copyright (C) 2010 by Thomas Martitz * * 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "autoconf.h" #include #include #include #include "config.h" #include "debug.h" #include "sound.h" #include "audiohw.h" #include "system.h" #include "panic.h" #ifdef HAVE_RECORDING #include "audiohw.h" #ifdef HAVE_SPDIF_IN #include "spdif.h" #endif #endif #include "pcm.h" #include "pcm-internal.h" #include "pcm_sampr.h" /*#define LOGF_ENABLE*/ #include "logf.h" #ifdef DEBUG #include extern bool debug_audio; #endif static int sim_volume = 0; #if CONFIG_CODEC == SWCODEC static int cvt_status = -1; static const void *pcm_data; static size_t pcm_data_size; static size_t pcm_sample_bytes; static size_t pcm_channel_bytes; static struct pcm_udata { Uint8 *stream; Uint32 num_in; Uint32 num_out; #ifdef DEBUG FILE *debug; #endif } udata; static SDL_AudioSpec obtained; static SDL_AudioCVT cvt; static int audio_locked = 0; static SDL_mutex *audio_lock; void pcm_play_lock(void) { if (++audio_locked == 1) SDL_LockMutex(audio_lock); } void pcm_play_unlock(void) { if (--audio_locked == 0) SDL_UnlockMutex(audio_lock); } static void pcm_dma_apply_settings_nolock(void) { cvt_status = SDL_BuildAudioCVT(&cvt, AUDIO_S16SYS, 2, pcm_sampr, obtained.format, obtained.channels, obtained.freq); if (cvt_status < 0) { cvt.len_ratio = (double)obtained.freq / (double)pcm_sampr; } } void pcm_dma_apply_settings(void) { pcm_play_lock(); pcm_dma_apply_settings_nolock(); pcm_play_unlock(); } void pcm_play_dma_start(const void *addr, size_t size) { pcm_dma_apply_settings_nolock(); pcm_data = addr; pcm_data_size = size; SDL_PauseAudio(0); } void pcm_play_dma_stop(void) { SDL_PauseAudio(1); #ifdef DEBUG if (udata.debug != NULL) { fclose(udata.debug); udata.debug = NULL; DEBUGF("Audio debug file closed\n"); } #endif } void pcm_play_dma_pause(bool pause) { if (pause) SDL_PauseAudio(1); else SDL_PauseAudio(0); } size_t pcm_get_bytes_waiting(void) { return pcm_data_size; } static void write_to_soundcard(struct pcm_udata *udata) { #ifdef DEBUG if (debug_audio && (udata->debug == NULL)) { udata->debug = fopen("audiodebug.raw", "ab"); DEBUGF("Audio debug file open\n"); } #endif if (cvt.needed) { Uint32 rd = udata->num_in; Uint32 wr = (double)rd * cvt.len_ratio; if (wr > udata->num_out) { wr = udata->num_out; rd = (double)wr / cvt.len_ratio; if (rd > udata->num_in) { rd = udata->num_in; wr = (double)rd * cvt.len_ratio; } } if (wr == 0 || rd == 0) { udata->num_out = udata->num_in = 0; return; } if (cvt_status > 0) { cvt.len = rd * pcm_sample_bytes; cvt.buf = (Uint8 *) malloc(cvt.len * cvt.len_mult); memcpy(cvt.buf, pcm_data, cvt.len); SDL_ConvertAudio(&cvt); SDL_MixAudio(udata->stream, cvt.buf, cvt.len_cvt, sim_volume); udata->num_in = cvt.len / pcm_sample_bytes; udata->num_out = cvt.len_cvt / pcm_sample_bytes; #ifdef DEBUG if (udata->debug != NULL) { fwrite(cvt.buf, sizeof(Uint8), cvt.len_cvt, udata->debug); } #endif free(cvt.buf); } else { /* Convert is bad, so do silence */ Uint32 num = wr*obtained.channels; udata->num_in = rd; udata->num_out = wr; switch (pcm_channel_bytes) { case 1: { Uint8 *stream = udata->stream; while (num-- > 0) *stream++ = obtained.silence; break; } case 2: { Uint16 *stream = (Uint16 *)udata->stream; while (num-- > 0) *stream++ = obtained.silence; break; } } #ifdef DEBUG if (udata->debug != NULL) { fwrite(udata->stream, sizeof(Uint8), wr, udata->debug); } #endif } } else { udata->num_in = udata->num_out = MIN(udata->num_in, udata->num_out); SDL_MixAudio(udata->stream, pcm_data, udata->num_out * pcm_sample_bytes, sim_volume); #ifdef DEBUG if (udata->debug != NULL) { fwrite(pcm_data, sizeof(Uint8), udata->num_out * pcm_sample_bytes, udata->debug); } #endif } } static void sdl_audio_callback(struct pcm_udata *udata, Uint8 *stream, int len) { logf("sdl_audio_callback: len %d, pcm %d\n", len, pcm_data_size); bool new_buffer = false; udata->stream = stream; SDL_LockMutex(audio_lock); /* Write what we have in the PCM buffer */ if (pcm_data_size > 0) goto start; /* Audio card wants more? Get some more then. */ while (len > 0) { new_buffer = pcm_play_dma_complete_callback(PCM_DMAST_OK, &pcm_data, &pcm_data_size); if (!new_buffer) { DEBUGF("sdl_audio_callback: No Data.\n"); break; } start: udata->num_in = pcm_data_size / pcm_sample_bytes; udata->num_out = len / pcm_sample_bytes; write_to_soundcard(udata); udata->num_in *= pcm_sample_bytes; udata->num_out *= pcm_sample_bytes; if (new_buffer) { new_buffer = false; pcm_play_dma_status_callback(PCM_DMAST_STARTED); if ((size_t)len > udata->num_out) { int delay = pcm_data_size*250 / pcm_sampr - 1; if (delay > 0) { SDL_UnlockMutex(audio_lock); SDL_Delay(delay); SDL_LockMutex(audio_lock); if (!pcm_is_playing()) break; } } } pcm_data += udata->num_in; pcm_data_size -= udata->num_in; udata->stream += udata->num_out; len -= udata->num_out; } SDL_UnlockMutex(audio_lock); } const void * pcm_play_dma_get_peak_buffer(int *count) { uintptr_t addr = (uintptr_t)pcm_data; *count = pcm_data_size / 4; return (void *)((addr + 2) & ~3); } #ifdef HAVE_RECORDING void pcm_rec_lock(void) { } void pcm_rec_unlock(void) { } void pcm_rec_dma_init(void) { } void pcm_rec_dma_close(void) { } void pcm_rec_dma_start(void *start, size_t size) { (void)start; (void)size; } void pcm_rec_dma_stop(void) { } const void * pcm_rec_dma_get_peak_buffer(void) { return NULL; } void audiohw_set_recvol(int left, int right, int type) { (void)left; (void)right; (void)type; } #ifdef HAVE_SPDIF_IN unsigned long spdif_measure_frequency(void) { return 0; } #endif #endif /* HAVE_RECORDING */ void pcm_play_dma_init(void) { if (SDL_InitSubSystem(SDL_INIT_AUDIO)) { DEBUGF("Could not initialize SDL audio subsystem!\n"); return; } audio_lock = SDL_CreateMutex(); if (!audio_lock) { panicf("Could not create audio_lock\n"); return; } SDL_AudioSpec wanted_spec; #ifdef DEBUG udata.debug = NULL; if (debug_audio) { udata.debug = fopen("audiodebug.raw", "wb"); DEBUGF("Audio debug file open\n"); } #endif /* Set 16-bit stereo audio at 44Khz */ wanted_spec.freq = 44100; wanted_spec.format = AUDIO_S16SYS; wanted_spec.channels = 2; wanted_spec.samples = 2048; wanted_spec.callback = (void (SDLCALL *)(void *userdata, Uint8 *stream, int len))sdl_audio_callback; wanted_spec.userdata = &udata; /* Open the audio device and start playing sound! */ if(SDL_OpenAudio(&wanted_spec, &obtained) < 0) { DEBUGF("Unable to open audio: %s\n", SDL_GetError()); return; } switch (obtained.format) { case AUDIO_U8: case AUDIO_S8: pcm_channel_bytes = 1; break; case AUDIO_U16LSB: case AUDIO_S16LSB: case AUDIO_U16MSB: case AUDIO_S16MSB: pcm_channel_bytes = 2; break; default: DEBUGF("Unknown sample format obtained: %u\n", (unsigned)obtained.format); return; } pcm_sample_bytes = obtained.channels * pcm_channel_bytes; pcm_dma_apply_settings_nolock(); } void pcm_play_dma_postinit(void) { } void pcm_set_mixer_volume(int volume) { sim_volume = volume; } #endif /* CONFIG_CODEC == SWCODEC */