ref: 00caf732431a47e023bd2eb834b43a9e9cdab320
dir: /src/opusdec.c/
/* Copyright (c) 2002-2007 Jean-Marc Valin Copyright (c) 2008 CSIRO Copyright (c) 2007-2012 Xiph.Org Foundation File: opusdec.c Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include <stdio.h> #if !defined WIN32 && !defined _WIN32 #include <unistd.h> #endif #ifdef HAVE_GETOPT_H #include <getopt.h> #endif /*#ifndef HAVE_GETOPT_LONG #include "getopt_win.h" #endif*/ #include <stdlib.h> #include <limits.h> #include <string.h> #include <ctype.h> /*tolower()*/ #include <opus.h> #include <opus_multistream.h> #include <ogg/ogg.h> #if defined WIN32 || defined _WIN32 || defined WIN64 || defined _WIN64 # include "unicode_support.h" # include "wave_out.h" /* We need the following two to set stdout to binary */ # include <io.h> # include <fcntl.h> # define I64FORMAT "I64d" #else # define I64FORMAT "lld" # define fopen_utf8(_x,_y) fopen((_x),(_y)) # define argc_utf8 argc # define argv_utf8 argv #endif #include <math.h> #ifdef HAVE_LRINTF # define float2int(x) lrintf(x) #else # define float2int(flt) ((int)(floor(.5+flt))) #endif #if defined HAVE_LIBSNDIO # include <sndio.h> #elif defined HAVE_SYS_SOUNDCARD_H || defined HAVE_MACHINE_SOUNDCARD_H || HAVE_SOUNDCARD_H # ifdef HAVE_SYS_SOUNDCARD_H # include <sys/soundcard.h> # elif HAVE_MACHINE_SOUNDCARD_H # include <machine/soundcard.h> # else # include <soundcard.h> # endif # include <sys/types.h> # include <sys/stat.h> # include <fcntl.h> # include <sys/ioctl.h> #elif defined HAVE_SYS_AUDIOIO_H # include <sys/types.h> # include <fcntl.h> # include <sys/ioctl.h> # include <sys/audioio.h> # ifndef AUDIO_ENCODING_SLINEAR # define AUDIO_ENCODING_SLINEAR AUDIO_ENCODING_LINEAR /* Solaris */ # endif #endif #include <string.h> #include "wav_io.h" #include "opus_header.h" #include "diag_range.h" #include "speex_resampler.h" #include "stack_alloc.h" #define MINI(_a,_b) ((_a)<(_b)?(_a):(_b)) #define MAXI(_a,_b) ((_a)>(_b)?(_a):(_b)) #define CLAMPI(_a,_b,_c) (MAXI(_a,MINI(_b,_c))) /* 120ms at 48000 */ #define MAX_FRAME_SIZE (960*6) #define readint(buf, base) (((buf[base+3]<<24)&0xff000000)| \ ((buf[base+2]<<16)&0xff0000)| \ ((buf[base+1]<<8)&0xff00)| \ (buf[base]&0xff)) #ifdef HAVE_LIBSNDIO struct sio_hdl *hdl; #endif typedef struct shapestate shapestate; struct shapestate { float * b_buf; float * a_buf; int fs; int mute; }; static unsigned int rngseed = 22222; static inline unsigned int fast_rand(void) { rngseed = (rngseed * 96314165) + 907633515; return rngseed; } #ifndef HAVE_FMINF # define fminf(_x,_y) ((_x)<(_y)?(_x):(_y)) #endif #ifndef HAVE_FMAXF # define fmaxf(_x,_y) ((_x)>(_y)?(_x):(_y)) #endif static void quit(int _x) { #ifdef WIN_UNICODE uninit_console_utf8(); #endif exit(_x); } /* This implements a 16 bit quantization with full triangular dither and IIR noise shaping. The noise shaping filters were designed by Sebastian Gesemann based on the LAME ATH curves with flattening to limit their peak gain to 20 dB. (Everyone elses' noise shaping filters are mildly crazy) The 48kHz version of this filter is just a warped version of the 44.1kHz filter and probably could be improved by shifting the HF shelf up in frequency a little bit since 48k has a bit more room and being more conservative against bat-ears is probably more important than more noise suppression. This process can increase the peak level of the signal (in theory by the peak error of 1.5 +20 dB though this much is unobservable rare) so to avoid clipping the signal is attenuated by a couple thousandths of a dB. Initially the approach taken here was to only attenuate by the 99.9th percentile, making clipping rare but not impossible (like SoX) but the limited gain of the filter means that the worst case was only two thousandths of a dB more, so this just uses the worst case. The attenuation is probably also helpful to prevent clipping in the DAC reconstruction filters or downstream resampling in any case.*/ static inline void shape_dither_toshort(shapestate *_ss, short *_o, float *_i, int _n, int _CC) { const float gains[3]={32768.f-15.f,32768.f-15.f,32768.f-3.f}; const float fcoef[3][8] = { {2.2374f, -.7339f, -.1251f, -.6033f, 0.9030f, .0116f, -.5853f, -.2571f}, /* 48.0kHz noise shaping filter sd=2.34*/ {2.2061f, -.4706f, -.2534f, -.6214f, 1.0587f, .0676f, -.6054f, -.2738f}, /* 44.1kHz noise shaping filter sd=2.51*/ {1.0000f, 0.0000f, 0.0000f, 0.0000f, 0.0000f,0.0000f, 0.0000f, 0.0000f}, /* lowpass noise shaping filter sd=0.65*/ }; int i; int rate=_ss->fs==44100?1:(_ss->fs==48000?0:2); float gain=gains[rate]; float *b_buf; float *a_buf; int mute=_ss->mute; b_buf=_ss->b_buf; a_buf=_ss->a_buf; if(mute>64) memset(a_buf,0,sizeof(float)*_CC*4); for(i=0;i<_n;i++) { int c; int pos = i*_CC; int silent=1; for(c=0;c<_CC;c++) { int j, si; float r,s,err=0; silent&=_i[pos+c]==0; s=_i[pos+c]*gain; for(j=0;j<4;j++) err += fcoef[rate][j]*b_buf[c*4+j] - fcoef[rate][j+4]*a_buf[c*4+j]; memmove(&a_buf[c*4+1],&a_buf[c*4],sizeof(float)*3); memmove(&b_buf[c*4+1],&b_buf[c*4],sizeof(float)*3); a_buf[c*4]=err; s = s - err; r=(float)fast_rand()*(1/(float)UINT_MAX) - (float)fast_rand()*(1/(float)UINT_MAX); if (mute>16)r=0; /*Clamp in float out of paranoia that the input will be >96 dBFS and wrap if the integer is clamped.*/ _o[pos+c] = si = float2int(fmaxf(-32768,fminf(s + r,32767))); /*Including clipping in the noise shaping is generally disastrous: the futile effort to restore the clipped energy results in more clipping. However, small amounts-- at the level which could normally be created by dither and rounding-- are harmless and can even reduce clipping somewhat due to the clipping sometimes reducing the dither+rounding error.*/ b_buf[c*4] = (mute>16)?0:fmaxf(-1.5f,fminf(si - s,1.5f)); } mute++; if(!silent)mute=0; } _ss->mute=MINI(mute,960); } static void print_comments(char *comments, int length) { char *c=comments; int len, i, nb_fields, err=0; if (length<(8+4+4)) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } if (strncmp(c, "OpusTags", 8) != 0) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } c += 8; fprintf(stderr, "Encoded with "); len=readint(c, 0); c+=4; if (len < 0 || len>(length-16)) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } err&=fwrite(c, 1, len, stderr)!=(unsigned)len; c+=len; fprintf (stderr, "\n"); /*The -16 check above makes sure we can read this.*/ nb_fields=readint(c, 0); c+=4; length-=16+len; if (nb_fields < 0 || nb_fields>(length>>2)) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } for (i=0;i<nb_fields;i++) { if (length<4) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } len=readint(c, 0); c+=4; length-=4; if (len < 0 || len>length) { fprintf (stderr, "Invalid/corrupted comments\n"); return; } err&=fwrite(c, 1, len, stderr)!=(unsigned)len; c+=len; length-=len; fprintf (stderr, "\n"); } } FILE *out_file_open(char *outFile, int *wav_format, int rate, int mapping_family, int *channels) { FILE *fout=NULL; /*Open output file*/ if (strlen(outFile)==0) { #if defined HAVE_SYS_SOUNDCARD_H int audio_fd, format, stereo; audio_fd=open("/dev/dsp", O_WRONLY); if (audio_fd<0) { perror("Cannot open /dev/dsp"); quit(1); } format=AFMT_S16_NE; if (ioctl(audio_fd, SNDCTL_DSP_SETFMT, &format)==-1) { perror("SNDCTL_DSP_SETFMT"); close(audio_fd); quit(1); } stereo=0; if (*channels==2) stereo=1; if (ioctl(audio_fd, SNDCTL_DSP_STEREO, &stereo)==-1) { perror("SNDCTL_DSP_STEREO"); close(audio_fd); quit(1); } if (stereo!=0) { if (*channels==1) fprintf (stderr, "Cannot set mono mode, will decode in stereo\n"); *channels=2; } if (ioctl(audio_fd, SNDCTL_DSP_SPEED, &rate)==-1) { perror("SNDCTL_DSP_SPEED"); close(audio_fd); quit(1); } fout = fdopen(audio_fd, "w"); if(!fout) { perror("Cannot open output"); quit(1); } #elif defined HAVE_LIBSNDIO struct sio_par par; hdl = sio_open(NULL, SIO_PLAY, 0); if (!hdl) { fprintf(stderr, "Cannot open sndio device\n"); quit(1); } sio_initpar(&par); par.sig = 1; par.bits = 16; par.rate = rate; par.pchan = *channels; if (!sio_setpar(hdl, &par) || !sio_getpar(hdl, &par) || par.sig != 1 || par.bits != 16 || par.rate != rate) { fprintf(stderr, "could not set sndio parameters\n"); quit(1); } *channels = par.pchan; if (!sio_start(hdl)) { fprintf(stderr, "could not start sndio\n"); quit(1); } #elif defined HAVE_SYS_AUDIOIO_H audio_info_t info; int audio_fd; audio_fd = open("/dev/audio", O_WRONLY); if (audio_fd<0) { perror("Cannot open /dev/audio"); quit(1); } AUDIO_INITINFO(&info); #ifdef AUMODE_PLAY /* NetBSD/OpenBSD */ info.mode = AUMODE_PLAY; #endif info.play.encoding = AUDIO_ENCODING_SLINEAR; info.play.precision = 16; info.play.input_sample_rate = rate; info.play.channels = *channels; if (ioctl(audio_fd, AUDIO_SETINFO, &info) < 0) { perror ("AUDIO_SETINFO"); quit(1); } fout = fdopen(audio_fd, "w"); if(!fout) { perror("Cannot open output"); quit(1); } #elif defined WIN32 || defined _WIN32 { unsigned int opus_channels = *channels; if (Set_WIN_Params (INVALID_FILEDESC, rate, SAMPLE_SIZE, opus_channels)) { fprintf (stderr, "Can't access %s\n", "WAVE OUT"); quit(1); } } #else fprintf (stderr, "No soundcard support\n"); quit(1); #endif } else { if (strcmp(outFile,"-")==0) { #if defined WIN32 || defined _WIN32 _setmode(_fileno(stdout), _O_BINARY); #endif fout=stdout; } else { fout = fopen_utf8(outFile, "wb"); if (!fout) { perror(outFile); quit(1); } if (*wav_format) { *wav_format = write_wav_header(fout, rate, mapping_family, *channels); if (*wav_format < 0) { fprintf (stderr, "Error writing WAV header.\n"); quit(1); } } } } return fout; } void usage(void) { printf ("Usage: opusdec [options] input_file.opus [output_file]\n"); printf ("\n"); printf ("Decodes a Opus file and produce a WAV file or raw file\n"); printf ("\n"); printf ("input_file can be:\n"); printf (" filename.opus regular Opus file\n"); printf (" - stdin\n"); printf ("\n"); printf ("output_file can be:\n"); printf (" filename.wav Wav file\n"); printf (" filename.* Raw PCM file (any extension other than .wav)\n"); printf (" - stdout\n"); printf (" (nothing) Will be played to soundcard\n"); printf ("\n"); printf ("Options:\n"); printf (" --rate n Force decoding at sampling rate n Hz\n"); printf (" --gain n Manually adjust gain by n.nn dB (0 default)\n"); printf (" --no-dither Do not dither 16-bit output\n"); printf (" --packet-loss n Simulate n %% random packet loss\n"); printf (" --save-range file Saves check values for every frame to a file\n"); printf (" -h, --help This help\n"); printf (" -v, --version Version information\n"); printf (" --quiet Quiet mode\n"); printf ("\n"); } void version(void) { printf("opusdec %s %s (using %s)\n",PACKAGE,VERSION,opus_get_version_string()); printf("Copyright (C) 2008-2012 Xiph.Org Foundation\n"); } void version_short(void) { printf("opusdec %s %s (using %s)\n",PACKAGE,VERSION,opus_get_version_string()); printf("Copyright (C) 2008-2012 Xiph.Org Foundation\n"); } static OpusMSDecoder *process_header(ogg_packet *op, opus_int32 *rate, int *mapping_family, int *channels, int *preskip, float *gain, float manual_gain, int *streams, int wav_format, int quiet) { int err; OpusMSDecoder *st; OpusHeader header; if (opus_header_parse(op->packet, op->bytes, &header)==0) { fprintf(stderr, "Cannot parse header\n"); return NULL; } *mapping_family = header.channel_mapping; *channels = header.channels; if(wav_format)adjust_wav_mapping(*mapping_family, *channels, header.stream_map); if(!*rate)*rate=header.input_sample_rate; /*If the rate is unspecified we decode to 48000*/ if(*rate==0)*rate=48000; if(*rate<8000||*rate>192000){ fprintf(stderr,"Warning: Crazy input_rate %d, decoding to 48000 instead.\n",*rate); *rate=48000; } *preskip = header.preskip; st = opus_multistream_decoder_create(48000, header.channels, header.nb_streams, header.nb_coupled, header.stream_map, &err); if(err != OPUS_OK){ fprintf(stderr, "Cannot create encoder: %s\n", opus_strerror(err)); return NULL; } if (!st) { fprintf (stderr, "Decoder initialization failed: %s\n", opus_strerror(err)); return NULL; } *streams=header.nb_streams; if(header.gain!=0 || manual_gain!=0) { /*Gain API added in a newer libopus version, if we don't have it we apply the gain ourselves. We also add in a user provided manual gain at the same time.*/ int gainadj = (int)(manual_gain*256.)+header.gain; #ifdef OPUS_SET_GAIN err=opus_multistream_decoder_ctl(st,OPUS_SET_GAIN(gainadj)); if(err==OPUS_UNIMPLEMENTED) { #endif *gain = pow(10., gainadj/5120.); #ifdef OPUS_SET_GAIN } else if (err!=OPUS_OK) { fprintf (stderr, "Error setting gain: %s\n", opus_strerror(err)); return NULL; } #endif } if (!quiet) { fprintf(stderr, "Decoding to %d Hz (%d channel%s)", *rate, *channels, *channels>1?"s":""); if(header.version!=1)fprintf(stderr, ", Header v%d",header.version); fprintf(stderr, "\n"); if (header.gain!=0)fprintf(stderr,"Playback gain: %f dB\n", header.gain/256.); if (manual_gain!=0)fprintf(stderr,"Manual gain: %f dB\n", manual_gain); } return st; } opus_int64 audio_write(float *pcm, int channels, int frame_size, FILE *fout, SpeexResamplerState *resampler, int *skip, shapestate *shapemem, int file, opus_int64 maxout) { opus_int64 sampout=0; int i,ret,tmp_skip; unsigned out_len; short *out; float *buf; float *output; out=alloca(sizeof(short)*MAX_FRAME_SIZE*channels); buf=alloca(sizeof(float)*MAX_FRAME_SIZE*channels); maxout=maxout<0?0:maxout; do { if (skip){ tmp_skip = (*skip>frame_size) ? (int)frame_size : *skip; *skip -= tmp_skip; } else { tmp_skip = 0; } if (resampler){ unsigned in_len; output=buf; in_len = frame_size-tmp_skip; out_len = 1024<maxout?1024:maxout; speex_resampler_process_interleaved_float(resampler, pcm+channels*tmp_skip, &in_len, buf, &out_len); pcm += channels*(in_len+tmp_skip); frame_size -= in_len+tmp_skip; } else { output=pcm+channels*tmp_skip; out_len=frame_size-tmp_skip; frame_size=0; } /*Convert to short and save to output file*/ if (shapemem){ shape_dither_toshort(shapemem,out,output,out_len,channels); }else{ for (i=0;i<(int)out_len*channels;i++) out[i]=(short)float2int(fmaxf(-32768,fminf(output[i]*32768.f,32767))); } if ((le_short(1)!=1)&&file){ for (i=0;i<(int)out_len*channels;i++) out[i]=le_short(out[i]); } if(maxout>0) { #if defined WIN32 || defined _WIN32 if(!file){ ret=WIN_Play_Samples (out, sizeof(short) * channels * (out_len<maxout?out_len:maxout)); if(ret>0)ret/=sizeof(short)*channels; else fprintf(stderr, "Error playing audio.\n"); }else #elif defined HAVE_LIBSNDIO if(!file){ ret=sio_write (hdl, out, sizeof(short) * channels * (out_len<maxout?out_len:maxout)); if(ret>0)ret/=sizeof(short)*channels; else fprintf(stderr, "Error playing audio.\n"); }else #endif ret=fwrite(out, 2*channels, out_len<maxout?out_len:maxout, fout); sampout+=ret; maxout-=ret; } } while (frame_size>0 && maxout>0); return sampout; } int main(int argc, char **argv) { int c; int option_index = 0; char *inFile, *outFile; FILE *fin, *fout=NULL, *frange=NULL; float *output; int frame_size=0; OpusMSDecoder *st=NULL; opus_int64 packet_count=0; int total_links=0; int stream_init = 0; int quiet = 0; ogg_int64_t page_granule=0; ogg_int64_t link_out=0; struct option long_options[] = { {"help", no_argument, NULL, 0}, {"quiet", no_argument, NULL, 0}, {"version", no_argument, NULL, 0}, {"version-short", no_argument, NULL, 0}, {"rate", required_argument, NULL, 0}, {"gain", required_argument, NULL, 0}, {"no-dither", no_argument, NULL, 0}, {"packet-loss", required_argument, NULL, 0}, {"save-range", required_argument, NULL, 0}, {0, 0, 0, 0} }; ogg_sync_state oy; ogg_page og; ogg_packet op; ogg_stream_state os; int close_in=0; int eos=0; ogg_int64_t audio_size=0; double last_coded_seconds=0; float loss_percent=-1; float manual_gain=0; int channels=-1; int mapping_family; int rate=0; int wav_format=0; int preskip=0; int gran_offset=0; int has_opus_stream=0; ogg_int32_t opus_serialno; int dither=1; shapestate shapemem; SpeexResamplerState *resampler=NULL; float gain=1; int streams=0; size_t last_spin=0; #ifdef WIN_UNICODE int argc_utf8; char **argv_utf8; (void)argc; (void)argv; init_console_utf8(); init_commandline_arguments_utf8(&argc_utf8, &argv_utf8); #endif output=0; shapemem.a_buf=0; shapemem.b_buf=0; shapemem.mute=960; shapemem.fs=0; /*Process options*/ while(1) { c = getopt_long (argc_utf8, argv_utf8, "hvV", long_options, &option_index); if (c==-1) break; switch(c) { case 0: if (strcmp(long_options[option_index].name,"help")==0) { usage(); quit(0); } else if (strcmp(long_options[option_index].name,"quiet")==0) { quiet = 1; } else if (strcmp(long_options[option_index].name,"version")==0) { version(); quit(0); } else if (strcmp(long_options[option_index].name,"version-short")==0) { version_short(); quit(0); } else if (strcmp(long_options[option_index].name,"no-dither")==0) { dither=0; } else if (strcmp(long_options[option_index].name,"rate")==0) { rate=atoi (optarg); } else if (strcmp(long_options[option_index].name,"gain")==0) { manual_gain=atof (optarg); }else if(strcmp(long_options[option_index].name,"save-range")==0){ frange=fopen_utf8(optarg,"w"); if(frange==NULL){ perror(optarg); fprintf(stderr,"Could not open save-range file: %s\n",optarg); fprintf(stderr,"Must provide a writable file name.\n"); quit(1); } } else if (strcmp(long_options[option_index].name,"packet-loss")==0) { loss_percent = atof(optarg); } break; case 'h': usage(); quit(0); break; case 'v': version(); quit(0); break; case '?': usage(); quit(1); break; } } if (argc_utf8-optind!=2 && argc_utf8-optind!=1) { usage(); quit(1); } inFile=argv_utf8[optind]; if (argc_utf8-optind==2){ int i; char *ext; outFile=argv_utf8[optind+1]; ext=".wav"; i=strlen(outFile)-4; wav_format=i>=0; while(wav_format&&ext&&outFile[i]) { wav_format&=tolower(outFile[i++])==*ext++; } }else { outFile=""; wav_format=0; /*If playing to audio out, default the rate to 48000 instead of the original rate. The original rate is only important for minimizing surprise about the rate of output files and preserving length, which aren't relevant for playback. Many audio devices sound better at 48kHz and not resampling also saves CPU.*/ if(rate==0)rate=48000; } /*Open input file*/ if (strcmp(inFile, "-")==0) { #if defined WIN32 || defined _WIN32 _setmode(_fileno(stdin), _O_BINARY); #endif fin=stdin; } else { fin = fopen_utf8(inFile, "rb"); if (!fin) { perror(inFile); quit(1); } close_in=1; } /*Init Ogg data struct*/ ogg_sync_init(&oy); /*Main decoding loop*/ while (1) { char *data; int i, nb_read; /*Get the ogg buffer for writing*/ data = ogg_sync_buffer(&oy, 200); /*Read bitstream from input file*/ nb_read = fread(data, sizeof(char), 200, fin); ogg_sync_wrote(&oy, nb_read); /*Loop for all complete pages we got (most likely only one)*/ while (ogg_sync_pageout(&oy, &og)==1) { if (stream_init == 0) { ogg_stream_init(&os, ogg_page_serialno(&og)); stream_init = 1; } if (ogg_page_serialno(&og) != os.serialno) { /* so all streams are read. */ ogg_stream_reset_serialno(&os, ogg_page_serialno(&og)); } /*Add page to the bitstream*/ ogg_stream_pagein(&os, &og); page_granule = ogg_page_granulepos(&og); /*Extract all available packets*/ while (ogg_stream_packetout(&os, &op) == 1) { /*OggOpus streams are identified by a magic string in the initial stream header.*/ if (op.b_o_s && op.bytes>=8 && !memcmp(op.packet, "OpusHead", 8)) { if(!has_opus_stream) { opus_serialno = os.serialno; has_opus_stream = 1; link_out = 0; packet_count = 0; eos = 0; total_links++; } else { fprintf(stderr,"Warning: ignoring opus stream %" I64FORMAT "\n",(long long)os.serialno); } } if (!has_opus_stream || os.serialno != opus_serialno) break; /*If first packet in a logical stream, process the Opus header*/ if (packet_count==0) { st = process_header(&op, &rate, &mapping_family, &channels, &preskip, &gain, manual_gain, &streams, wav_format, quiet); if (!st) quit(1); /*Remember how many samples at the front we were told to skip so that we can adjust the timestamp counting.*/ gran_offset=preskip; /*Setup the memory for the dithered output*/ if(!shapemem.a_buf) { shapemem.a_buf=calloc(channels,sizeof(float)*4); shapemem.b_buf=calloc(channels,sizeof(float)*4); shapemem.fs=rate; } if(!output)output=malloc(sizeof(float)*MAX_FRAME_SIZE*channels); /*Normal players should just play at 48000 or their maximum rate, as described in the OggOpus spec. But for commandline tools like opusdec it can be desirable to exactly preserve the original sampling rate and duration, so we have a resampler here.*/ if (rate != 48000) { int err; resampler = speex_resampler_init(channels, 48000, rate, 5, &err); if (err!=0) fprintf(stderr, "resampler error: %s\n", speex_resampler_strerror(err)); speex_resampler_skip_zeros(resampler); } if(!fout)fout=out_file_open(outFile, &wav_format, rate, mapping_family, &channels); } else if (packet_count==1) { if (!quiet) print_comments((char*)op.packet, op.bytes); } else { int ret; opus_int64 maxout; opus_int64 outsamp; int lost=0; if (loss_percent>0 && 100*((float)rand())/RAND_MAX<loss_percent) lost=1; /*End of stream condition*/ if (op.e_o_s && os.serialno == opus_serialno)eos=1; /* don't care for anything except opus eos */ if (!lost){ /*Decode Opus packet*/ ret = opus_multistream_decode_float(st, (unsigned char*)op.packet, op.bytes, output, MAX_FRAME_SIZE, 0); } else { /*Extract the original duration. Normally you wouldn't have it for a lost packet, but normally the transports used on lossy channels will effectively tell you. This avoids opusdec squaking when the decoded samples and granpos mismatches.*/ opus_int32 lost_size; lost_size = MAX_FRAME_SIZE; if(op.bytes>0){ opus_int32 spp; spp=opus_packet_get_nb_frames(op.packet,op.bytes); if(spp>0){ spp*=opus_packet_get_samples_per_frame(op.packet,48000/*decoding_rate*/); if(spp>0)lost_size=spp; } } /*Invoke packet loss concealment.*/ ret = opus_multistream_decode_float(st, NULL, 0, output, lost_size, 0); } if(!quiet){ static const char spinner[]="|/-\\"; double coded_seconds = (double)audio_size/(channels*rate*sizeof(short)); if(coded_seconds>=last_coded_seconds+1){ fprintf(stderr,"\r[%c] %02d:%02d:%02d", spinner[last_spin&3], (int)(coded_seconds/3600),(int)(coded_seconds/60)%60, (int)(coded_seconds)%60); fflush(stderr); last_spin++; last_coded_seconds=coded_seconds; } } if (ret<0) { fprintf (stderr, "Decoding error: %s\n", opus_strerror(ret)); break; } frame_size = ret; /*If we're collecting --save-range debugging data, collect it now.*/ if(frange!=NULL){ OpusDecoder *od; opus_uint32 rngs[256]; for(i=0;i<streams;i++){ ret=opus_multistream_decoder_ctl(st,OPUS_MULTISTREAM_GET_DECODER_STATE(i,&od)); ret=opus_decoder_ctl(od,OPUS_GET_FINAL_RANGE(&rngs[i])); } save_range(frange,frame_size*(48000/48000/*decoding_rate*/),op.packet,op.bytes, rngs,streams); } /*Apply header gain, if we're not using an opus library new enough to do this internally.*/ if (gain!=0){ for (i=0;i<frame_size*channels;i++) output[i] *= gain; } /*This handles making sure that our output duration respects the final end-trim by not letting the output sample count get ahead of the granpos indicated value.*/ maxout=((page_granule-gran_offset)*rate/48000)-link_out; outsamp=audio_write(output, channels, frame_size, fout, resampler, &preskip, dither?&shapemem:0, strlen(outFile)!=0,0>maxout?0:maxout); link_out+=outsamp; audio_size+=sizeof(short)*outsamp*channels; } packet_count++; } /*We're done, drain the resampler if we were using it.*/ if(eos && resampler) { float *zeros; int drain; zeros=(float *)calloc(100*channels,sizeof(float)); drain = speex_resampler_get_input_latency(resampler); do { opus_int64 outsamp; int tmp = drain; if (tmp > 100) tmp = 100; outsamp=audio_write(zeros, channels, tmp, fout, resampler, NULL, &shapemem, strlen(outFile)!=0, ((page_granule-gran_offset)*rate/48000)-link_out); link_out+=outsamp; audio_size+=sizeof(short)*outsamp*channels; drain -= tmp; } while (drain>0); free(zeros); speex_resampler_destroy(resampler); resampler=NULL; } if(eos) { has_opus_stream=0; if(st)opus_multistream_decoder_destroy(st); st=NULL; } } if (feof(fin)) { if(!quiet) { fprintf(stderr, "\rDecoding complete. \n"); fflush(stderr); } break; } } /*If we were writing wav, go set the duration.*/ if (strlen(outFile)!=0 && fout && wav_format>=0 && audio_size<0x7FFFFFFF) { if (fseek(fout,4,SEEK_SET)==0) { int tmp; tmp = le_int(audio_size+20+wav_format); if(fwrite(&tmp,4,1,fout)!=1)fprintf(stderr,"Error writing end length.\n"); if (fseek(fout,16+wav_format,SEEK_CUR)==0) { tmp = le_int(audio_size); if(fwrite(&tmp,4,1,fout)!=1)fprintf(stderr,"Error writing header length.\n"); } else { fprintf (stderr, "First seek worked, second didn't\n"); } } else { fprintf (stderr, "Cannot seek on wave file, size will be incorrect\n"); } } if(!total_links)fprintf (stderr, "This doesn't look like a Opus file\n"); if (stream_init) ogg_stream_clear(&os); ogg_sync_clear(&oy); #if defined WIN32 || defined _WIN32 if (strlen(outFile)==0) WIN_Audio_close (); #endif if(shapemem.a_buf)free(shapemem.a_buf); if(shapemem.b_buf)free(shapemem.b_buf); if(output)free(output); if(frange)fclose(frange); if (close_in) fclose(fin); if (fout != NULL) fclose(fout); #ifdef WIN_UNICODE free_commandline_arguments_utf8(&argc_utf8, &argv_utf8); uninit_console_utf8(); #endif return 0; }