/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * * Copyright (C) 2011 Sean Bartell * * 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. * ****************************************************************************/ #define _BSD_SOURCE /* htole64 from endian.h */ #include #include #include #include #include #include #include #include #include #include #include #include #include "buffering.h" /* TYPE_PACKET_AUDIO */ #include "codecs.h" #include "core_alloc.h" /* core_allocator_init */ #include "debug.h" #include "dsp.h" #include "metadata.h" #include "settings.h" #include "sound.h" #include "tdspeed.h" /***************** EXPORTED *****************/ struct user_settings global_settings; volatile long current_tick = 0; void yield(void) { } int set_irq_level(int level) { return 0; } void mutex_init(struct mutex *m) { } void mutex_lock(struct mutex *m) { } void mutex_unlock(struct mutex *m) { } void debugf(const char *fmt, ...) { va_list ap; va_start(ap, fmt); vfprintf(stderr, fmt, ap); va_end(ap); } int find_first_set_bit(uint32_t value) { if (value == 0) return 32; return __builtin_ctz(value); } /***************** INTERNAL *****************/ static enum { MODE_PLAY, MODE_WRITE } mode; static bool use_dsp = true; static bool enable_loop = false; static const char *config = ""; static int input_fd; static enum codec_command_action codec_action; static intptr_t codec_action_param = 0; static unsigned long num_output_samples = 0; static struct codec_api ci; static struct { intptr_t freq; intptr_t stereo_mode; intptr_t depth; int channels; } format; /***** MODE_WRITE *****/ #define WAVE_HEADER_SIZE 0x2e #define WAVE_FORMAT_PCM 1 #define WAVE_FORMAT_IEEE_FLOAT 3 static int output_fd; static bool write_raw = false; static bool write_header_written = false; static void write_init(const char *output_fn) { mode = MODE_WRITE; if (!strcmp(output_fn, "-")) { output_fd = STDOUT_FILENO; } else { output_fd = creat(output_fn, 0666); if (output_fd == -1) { perror(output_fn); exit(1); } } } static void set_le16(char *buf, uint16_t val) { buf[0] = val; buf[1] = val >> 8; } static void set_le32(char *buf, uint32_t val) { buf[0] = val; buf[1] = val >> 8; buf[2] = val >> 16; buf[3] = val >> 24; } static void write_wav_header(void) { int channels, sample_size, freq, type; if (use_dsp) { channels = 2; sample_size = 16; freq = NATIVE_FREQUENCY; type = WAVE_FORMAT_PCM; } else { channels = format.channels; sample_size = 64; freq = format.freq; type = WAVE_FORMAT_IEEE_FLOAT; } /* The size fields are normally overwritten by write_quit(). If that fails, * this fake size ensures the file can still be played. */ off_t total_size = 0x7fffff00 + WAVE_HEADER_SIZE; char header[WAVE_HEADER_SIZE] = {"RIFF____WAVEfmt \x12\0\0\0" "________________\0\0data____"}; set_le32(header + 0x04, total_size - 8); set_le16(header + 0x14, type); set_le16(header + 0x16, channels); set_le32(header + 0x18, freq); set_le32(header + 0x1c, freq * channels * sample_size / 8); set_le16(header + 0x20, channels * sample_size / 8); set_le16(header + 0x22, sample_size); set_le32(header + 0x2a, total_size - WAVE_HEADER_SIZE); write(output_fd, header, sizeof(header)); write_header_written = true; } static void write_quit(void) { if (!write_raw) { /* Write the correct size fields in the header. If lseek fails (e.g. * for a pipe) nothing is written. */ off_t total_size = lseek(output_fd, 0, SEEK_CUR); if (total_size != (off_t)-1) { char buf[4]; set_le32(buf, total_size - 8); lseek(output_fd, 4, SEEK_SET); write(output_fd, buf, 4); set_le32(buf, total_size - WAVE_HEADER_SIZE); lseek(output_fd, 0x2a, SEEK_SET); write(output_fd, buf, 4); } } if (output_fd != STDOUT_FILENO) close(output_fd); } static uint64_t make_float64(int32_t sample, int shift) { /* TODO: be more portable */ double val = ldexp(sample, -shift); return *(uint64_t*)&val; } static void write_pcm(int16_t *pcm, int count) { if (!write_header_written) write_wav_header(); int i; for (i = 0; i < 2 * count; i++) pcm[i] = htole16(pcm[i]); write(output_fd, pcm, 4 * count); } static void write_pcm_raw(int32_t *pcm, int count) { if (write_raw) { write(output_fd, pcm, count * sizeof(*pcm)); } else { if (!write_header_written) write_wav_header(); int i; uint64_t buf[count]; for (i = 0; i < count; i++) buf[i] = htole64(make_float64(pcm[i], format.depth)); write(output_fd, buf, count * sizeof(*buf)); } } /***** MODE_PLAY *****/ /* MODE_PLAY uses a double buffer: one half is read by the playback thread and * the other half is written to by the main thread. When a thread is done with * its current half, it waits for the other thread and then switches. The main * advantage of this method is its simplicity; the main disadvantage is that it * has long latency. ALSA buffer underruns still occur sometimes, but this is * SDL's fault. */ #define PLAYBACK_BUFFER_SIZE 0x10000 static bool playback_running = false; static char playback_buffer[2][PLAYBACK_BUFFER_SIZE]; static int playback_play_ind, playback_decode_ind; static int playback_play_pos, playback_decode_pos; static SDL_sem *playback_play_sema, *playback_decode_sema; static void playback_init(void) { mode = MODE_PLAY; if (SDL_Init(SDL_INIT_AUDIO)) { fprintf(stderr, "error: Can't initialize SDL: %s\n", SDL_GetError()); exit(1); } playback_play_ind = 1; playback_play_pos = PLAYBACK_BUFFER_SIZE; playback_decode_ind = 0; playback_decode_pos = 0; playback_play_sema = SDL_CreateSemaphore(0); playback_decode_sema = SDL_CreateSemaphore(0); } static void playback_callback(void *userdata, Uint8 *stream, int len) { while (len > 0) { if (!playback_running && playback_play_ind == playback_decode_ind && playback_play_pos >= playback_decode_pos) { /* end of data */ memset(stream, 0, len); SDL_SemPost(playback_play_sema); return; } if (playback_play_pos >= PLAYBACK_BUFFER_SIZE) { SDL_SemPost(playback_play_sema); SDL_SemWait(playback_decode_sema); playback_play_ind = !playback_play_ind; playback_play_pos = 0; } char *play_buffer = playback_buffer[playback_play_ind]; int copy_len = MIN(len, PLAYBACK_BUFFER_SIZE - playback_play_pos); memcpy(stream, play_buffer + playback_play_pos, copy_len); len -= copy_len; stream += copy_len; playback_play_pos += copy_len; } } static void playback_start(void) { playback_running = true; SDL_AudioSpec spec = {0}; spec.freq = NATIVE_FREQUENCY; spec.format = AUDIO_S16SYS; spec.channels = 2; spec.samples = 0x400; spec.callback = playback_callback; spec.userdata = NULL; if (SDL_OpenAudio(&spec, NULL)) { fprintf(stderr, "error: Can't open SDL audio: %s\n", SDL_GetError()); exit(1); } SDL_PauseAudio(0); } static void playback_quit(void) { if (!playback_running) playback_start(); memset(playback_buffer[playback_decode_ind] + playback_decode_pos, 0, PLAYBACK_BUFFER_SIZE - playback_decode_pos); playback_running = false; SDL_SemPost(playback_decode_sema); SDL_SemWait(playback_play_sema); SDL_SemWait(playback_play_sema); SDL_Quit(); } static void playback_pcm(int16_t *pcm, int count) { const char *stream = (const char *)pcm; count *= 4; while (count > 0) { if (playback_decode_pos >= PLAYBACK_BUFFER_SIZE) { if (!playback_running) playback_start(); SDL_SemPost(playback_decode_sema); SDL_SemWait(playback_play_sema); playback_decode_ind = !playback_decode_ind; playback_decode_pos = 0; } char *decode_buffer = playback_buffer[playback_decode_ind]; int copy_len = MIN(count, PLAYBACK_BUFFER_SIZE - playback_decode_pos); memcpy(decode_buffer + playback_decode_pos, stream, copy_len); stream += copy_len; count -= copy_len; playback_decode_pos += copy_len; } } /***** ALL MODES *****/ static void perform_config(void) { /* TODO: equalizer, etc. */ while (config) { const char *name = config; const char *eq = strchr(config, '='); if (!eq) break; const char *val = eq + 1; const char *end = val + strcspn(val, ": \t\n"); if (!strncmp(name, "wait=", 5)) { if (atoi(val) > num_output_samples) return; } else if (!strncmp(name, "dither=", 7)) { dsp_dither_enable(atoi(val) ? true : false); } else if (!strncmp(name, "halt=", 5)) { if (atoi(val)) codec_action = CODEC_ACTION_HALT; } else if (!strncmp(name, "loop=", 5)) { enable_loop = atoi(val) != 0; } else if (!strncmp(name, "offset=", 7)) { ci.id3->offset = atoi(val); } else if (!strncmp(name, "rate=", 5)) { sound_set_pitch(atof(val) * PITCH_SPEED_100); } else if (!strncmp(name, "seek=", 5)) { codec_action = CODEC_ACTION_SEEK_TIME; codec_action_param = atoi(val); } else if (!strncmp(name, "tempo=", 6)) { dsp_set_timestretch(atof(val) * PITCH_SPEED_100); #ifdef HAVE_SW_VOLUME_CONTROL } else if (!strncmp(name, "vol=", 4)) { global_settings.volume = atoi(val); dsp_callback(DSP_CALLBACK_SET_SW_VOLUME, 0); #endif } else { fprintf(stderr, "error: unrecognized config \"%.*s\"\n", (int)(eq - name), name); exit(1); } if (*end) config = end + 1; else config = NULL; } } static void *ci_codec_get_buffer(size_t *size) { static char buffer[64 * 1024 * 1024]; char *ptr = buffer; *size = sizeof(buffer); if ((intptr_t)ptr & (CACHEALIGN_SIZE - 1)) ptr += CACHEALIGN_SIZE - ((intptr_t)ptr & (CACHEALIGN_SIZE - 1)); return ptr; } static void ci_pcmbuf_insert(const void *ch1, const void *ch2, int count) { num_output_samples += count; if (use_dsp) { struct dsp_buffer src; src.remcount = count; src.pin[0] = ch1; src.pin[1] = ch2; src.proc_mask = 0; while (1) { int out_count = MAX(count, 512); int16_t buf[2 * out_count]; struct dsp_buffer dst; dst.remcount = 0; dst.p16out = buf; dst.bufcount = out_count; dsp_process(ci.dsp, &src, &dst); if (dst.remcount > 0) { if (mode == MODE_WRITE) write_pcm(buf, dst.remcount); else if (mode == MODE_PLAY) playback_pcm(buf, dst.remcount); } else if (src.remcount <= 0) { break; } } } else { /* Convert to 32-bit interleaved. */ count *= format.channels; int i; int32_t buf[count]; if (format.depth > 16) { if (format.stereo_mode == STEREO_NONINTERLEAVED) { for (i = 0; i < count; i += 2) { buf[i+0] = ((int32_t*)ch1)[i/2]; buf[i+1] = ((int32_t*)ch2)[i/2]; } } else { memcpy(buf, ch1, sizeof(buf)); } } else { if (format.stereo_mode == STEREO_NONINTERLEAVED) { for (i = 0; i < count; i += 2) { buf[i+0] = ((int16_t*)ch1)[i/2]; buf[i+1] = ((int16_t*)ch2)[i/2]; } } else { for (i = 0; i < count; i++) { buf[i] = ((int16_t*)ch1)[i]; } } } if (mode == MODE_WRITE) write_pcm_raw(buf, count); } perform_config(); } static void ci_set_elapsed(unsigned long value) { //debugf("Time elapsed: %lu\n", value); } static char *input_buffer = 0; /* * Read part of the input file into a provided buffer. * * The entire size requested will be provided except at the end of the file. * The current file position will be moved, just like with advance_buffer, but * the offset is not updated. This invalidates buffers returned by * request_buffer. */ static size_t ci_read_filebuf(void *ptr, size_t size) { free(input_buffer); input_buffer = NULL; ssize_t actual = read(input_fd, ptr, size); if (actual < 0) actual = 0; ci.curpos += actual; return actual; } /* * Request a buffer containing part of the input file. * * The size provided will be the requested size, or the remaining size of the * file, whichever is smaller. Packet audio has an additional maximum of 32 * KiB. The returned buffer remains valid until the next time read_filebuf, * request_buffer, advance_buffer, or seek_buffer is called. */ static void *ci_request_buffer(size_t *realsize, size_t reqsize) { free(input_buffer); if (!rbcodec_format_is_atomic(ci.id3->codectype)) reqsize = MIN(reqsize, 32 * 1024); input_buffer = malloc(reqsize); *realsize = read(input_fd, input_buffer, reqsize); if (*realsize < 0) *realsize = 0; lseek(input_fd, -*realsize, SEEK_CUR); return input_buffer; } /* * Advance the current position in the input file. * * This automatically updates the current offset. This invalidates buffers * returned by request_buffer. */ static void ci_advance_buffer(size_t amount) { free(input_buffer); input_buffer = NULL; lseek(input_fd, amount, SEEK_CUR); ci.curpos += amount; ci.id3->offset = ci.curpos; } /* * Seek to a position in the input file. * * This invalidates buffers returned by request_buffer. */ static bool ci_seek_buffer(size_t newpos) { free(input_buffer); input_buffer = NULL; off_t actual = lseek(input_fd, newpos, SEEK_SET); if (actual >= 0) ci.curpos = actual; return actual != -1; } static void ci_seek_complete(void) { } static void ci_set_offset(size_t value) { ci.id3->offset = value; } static void ci_configure(int setting, intptr_t value) { if (use_dsp) { dsp_configure(ci.dsp, setting, value); } else { if (setting == DSP_SET_FREQUENCY || setting == DSP_SWITCH_FREQUENCY) format.freq = value; else if (setting == DSP_SET_SAMPLE_DEPTH) format.depth = value; else if (setting == DSP_SET_STEREO_MODE) { format.stereo_mode = value; format.channels = (value == STEREO_MONO) ? 1 : 2; } } } static enum codec_command_action ci_get_command(intptr_t *param) { enum codec_command_action ret = codec_action; *param = codec_action_param; codec_action = CODEC_ACTION_NULL; return ret; } static bool ci_should_loop(void) { return enable_loop; } static unsigned ci_sleep(unsigned ticks) { return 0; } static void ci_cpucache_flush(void) { } static void ci_cpucache_invalidate(void) { } static struct codec_api ci = { 0, /* filesize */ 0, /* curpos */ NULL, /* id3 */ -1, /* audio_hid */ NULL, /* struct dsp_config *dsp */ ci_codec_get_buffer, ci_pcmbuf_insert, ci_set_elapsed, ci_read_filebuf, ci_request_buffer, ci_advance_buffer, ci_seek_buffer, ci_seek_complete, ci_set_offset, ci_configure, ci_get_command, ci_should_loop, ci_sleep, yield, #if NUM_CORES > 1 ci_create_thread, ci_thread_thaw, ci_thread_wait, ci_semaphore_init, ci_semaphore_wait, ci_semaphore_release, #endif commit_dcache, commit_discard_dcache, commit_discard_idcache, /* strings and memory */ strcpy, strlen, strcmp, strcat, memset, memcpy, memmove, memcmp, memchr, #if defined(DEBUG) || defined(SIMULATOR) debugf, #endif #ifdef ROCKBOX_HAS_LOGF debugf, /* logf */ #endif qsort, #ifdef HAVE_RECORDING ci_enc_get_inputs, ci_enc_set_parameters, ci_enc_get_chunk, ci_enc_finish_chunk, ci_enc_get_pcm_data, ci_enc_unget_pcm_data, /* file */ open, close, read, lseek, write, ci_round_value_to_list32, #endif /* HAVE_RECORDING */ }; static void print_mp3entry(const struct mp3entry *id3, FILE *f) { fprintf(f, "Path: %s\n", id3->path); if (id3->title) fprintf(f, "Title: %s\n", id3->title); if (id3->artist) fprintf(f, "Artist: %s\n", id3->artist); if (id3->album) fprintf(f, "Album: %s\n", id3->album); if (id3->genre_string) fprintf(f, "Genre: %s\n", id3->genre_string); if (id3->disc_string || id3->discnum) fprintf(f, "Disc: %s (%d)\n", id3->disc_string, id3->discnum); if (id3->track_string || id3->tracknum) fprintf(f, "Track: %s (%d)\n", id3->track_string, id3->tracknum); if (id3->year_string || id3->year) fprintf(f, "Year: %s (%d)\n", id3->year_string, id3->year); if (id3->composer) fprintf(f, "Composer: %s\n", id3->composer); if (id3->comment) fprintf(f, "Comment: %s\n", id3->comment); if (id3->albumartist) fprintf(f, "Album artist: %s\n", id3->albumartist); if (id3->grouping) fprintf(f, "Grouping: %s\n", id3->grouping); if (id3->layer) fprintf(f, "Layer: %d\n", id3->layer); if (id3->id3version) fprintf(f, "ID3 version: %u\n", (int)id3->id3version); fprintf(f, "Codec: %s\n", audio_formats[id3->codectype].label); fprintf(f, "Bitrate: %d kb/s\n", id3->bitrate); fprintf(f, "Frequency: %lu Hz\n", id3->frequency); if (id3->id3v2len) fprintf(f, "ID3v2 length: %lu\n", id3->id3v2len); if (id3->id3v1len) fprintf(f, "ID3v1 length: %lu\n", id3->id3v1len); if (id3->first_frame_offset) fprintf(f, "First frame offset: %lu\n", id3->first_frame_offset); fprintf(f, "File size without headers: %lu\n", id3->filesize); fprintf(f, "Song length: %lu ms\n", id3->length); if (id3->lead_trim > 0 || id3->tail_trim > 0) fprintf(f, "Trim: %d/%d\n", id3->lead_trim, id3->tail_trim); if (id3->samples) fprintf(f, "Number of samples: %lu\n", id3->samples); if (id3->frame_count) fprintf(f, "Number of frames: %lu\n", id3->frame_count); if (id3->bytesperframe) fprintf(f, "Bytes per frame: %lu\n", id3->bytesperframe); if (id3->vbr) fprintf(f, "VBR: true\n"); if (id3->has_toc) fprintf(f, "Has TOC: true\n"); if (id3->channels) fprintf(f, "Number of channels: %u\n", id3->channels); if (id3->extradata_size) fprintf(f, "Size of extra data: %u\n", id3->extradata_size); if (id3->needs_upsampling_correction) fprintf(f, "Needs upsampling correction: true\n"); /* TODO: replaygain; albumart; cuesheet */ if (id3->mb_track_id) fprintf(f, "Musicbrainz track ID: %s\n", id3->mb_track_id); } static void decode_file(const char *input_fn) { /* Set up global settings */ memset(&global_settings, 0, sizeof(global_settings)); global_settings.timestretch_enabled = true; dsp_timestretch_enable(true); /* Open file */ if (!strcmp(input_fn, "-")) { input_fd = STDIN_FILENO; } else { input_fd = open(input_fn, O_RDONLY); if (input_fd == -1) { perror(input_fn); exit(1); } } /* Set up ci */ struct mp3entry id3; if (!get_metadata(&id3, input_fd, input_fn)) { fprintf(stderr, "error: metadata parsing failed\n"); exit(1); } print_mp3entry(&id3, stderr); ci.filesize = filesize(input_fd); ci.id3 = &id3; if (use_dsp) { ci.dsp = dsp_get_config(CODEC_IDX_AUDIO); dsp_configure(ci.dsp, DSP_RESET, 0); dsp_dither_enable(false); } perform_config(); /* Load codec */ char str[MAX_PATH]; snprintf(str, sizeof(str), CODECDIR"/%s.codec", audio_formats[id3.codectype].codec_root_fn); debugf("Loading %s\n", str); void *dlcodec = dlopen(str, RTLD_NOW); if (!dlcodec) { fprintf(stderr, "error: dlopen failed: %s\n", dlerror()); exit(1); } struct codec_header *c_hdr = NULL; c_hdr = dlsym(dlcodec, "__header"); if (c_hdr->lc_hdr.magic != CODEC_MAGIC) { fprintf(stderr, "error: %s invalid: incorrect magic\n", str); exit(1); } if (c_hdr->lc_hdr.target_id != TARGET_ID) { fprintf(stderr, "error: %s invalid: incorrect target id\n", str); exit(1); } if (c_hdr->lc_hdr.api_version != CODEC_API_VERSION) { fprintf(stderr, "error: %s invalid: incorrect API version\n", str); exit(1); } /* Run the codec */ *c_hdr->api = &ci; if (c_hdr->entry_point(CODEC_LOAD) != CODEC_OK) { fprintf(stderr, "error: codec returned error from codec_main\n"); exit(1); } if (c_hdr->run_proc() != CODEC_OK) { fprintf(stderr, "error: codec error\n"); } c_hdr->entry_point(CODEC_UNLOAD); /* Close */ dlclose(dlcodec); if (input_fd != STDIN_FILENO) close(input_fd); } static void print_help(const char *progname) { fprintf(stderr, "Usage:\n" " Play: %s [options] INPUTFILE\n" "Write to WAV: %s [options] INPUTFILE OUTPUTFILE\n" "\n" "general options:\n" " -c a=1:b=2 Configuration (see below)\n" " -h Show this help\n" "\n" "write to WAV options:\n" " -f Write raw codec output converted to 64-bit float\n" " -r Write raw 32-bit codec output without WAV header\n" "\n" "configuration:\n" " dither=<0|1> Enable/disable dithering [0]\n" " halt=<0|1> Stop decoding if 1 [0]\n" " loop=<0|1> Enable/disable looping [0]\n" " offset= Start at byte offset within the file [0]\n" " rate= Multiply rate by [1.0]\n" " seek= Seek ms into the file\n" " tempo= Timestretch by [1.0]\n" #ifdef HAVE_SW_VOLUME_CONTROL " vol= Set volume to dB [0]\n" #endif " wait= Don't apply remaining configuration until\n" " total samples have output\n" "\n" "examples:\n" " # Play while looping; stop after 44100 output samples\n" " %s in.adx -c loop=1:wait=44100:halt=1\n" " # Lower pitch 1 octave and write to out.wav\n" " %s in.ogg -c rate=0.5:tempo=2 out.wav\n" , progname, progname, progname, progname); } int main(int argc, char **argv) { int opt; while ((opt = getopt(argc, argv, "c:fhr")) != -1) { switch (opt) { case 'c': config = optarg; break; case 'f': use_dsp = false; break; case 'r': use_dsp = false; write_raw = true; break; case 'h': /* fallthrough */ default: print_help(argv[0]); exit(1); } } core_allocator_init(); if (argc == optind + 2) { write_init(argv[optind + 1]); } else if (argc == optind + 1) { if (!use_dsp) { fprintf(stderr, "error: -r can't be used for playback\n"); print_help(argv[0]); exit(1); } playback_init(); } else { if (argc > 1) fprintf(stderr, "error: wrong number of arguments\n"); print_help(argv[0]); exit(1); } decode_file(argv[optind]); if (mode == MODE_WRITE) write_quit(); else if (mode == MODE_PLAY) playback_quit(); return 0; }