/******************************************************************** * * * THIS FILE IS PART OF THE OggVorbis SOFTWARE CODEC SOURCE CODE. * * USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS * * GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE * * IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. * * * * THE OggVorbis SOURCE CODE IS (C) COPYRIGHT 1994-2015 * * by the Xiph.Org Foundation http://www.xiph.org/ * * * ******************************************************************** function: simple programmatic interface for encoder mode setup last mod: $Id: vorbisenc.c 19457 2015-03-03 00:15:29Z giles $ ********************************************************************/ #include #include #include #include "vorbis/codec.h" #include "vorbis/vorbisenc.h" #include "codec_internal.h" #include "os.h" #include "misc.h" /* careful with this; it's using static array sizing to make managing all the modes a little less annoying. If we use a residue backend with > 12 partition types, or a different division of iteration, this needs to be updated. */ typedef struct { const static_codebook *books[12][4]; } static_bookblock; typedef struct { int res_type; int limit_type; /* 0 lowpass limited, 1 point stereo limited */ int grouping; const vorbis_info_residue0 *res; const static_codebook *book_aux; const static_codebook *book_aux_managed; const static_bookblock *books_base; const static_bookblock *books_base_managed; } vorbis_residue_template; typedef struct { const vorbis_info_mapping0 *map; const vorbis_residue_template *res; } vorbis_mapping_template; typedef struct vp_adjblock{ int block[P_BANDS]; } vp_adjblock; typedef struct { int data[NOISE_COMPAND_LEVELS]; } compandblock; /* high level configuration information for setting things up step-by-step with the detailed vorbis_encode_ctl interface. There's a fair amount of redundancy such that interactive setup does not directly deal with any vorbis_info or codec_setup_info initialization; it's all stored (until full init) in this highlevel setup, then flushed out to the real codec setup structs later. */ typedef struct { int att[P_NOISECURVES]; float boost; float decay; } att3; typedef struct { int data[P_NOISECURVES]; } adj3; typedef struct { int pre[PACKETBLOBS]; int post[PACKETBLOBS]; float kHz[PACKETBLOBS]; float lowpasskHz[PACKETBLOBS]; } adj_stereo; typedef struct { int lo; int hi; int fixed; } noiseguard; typedef struct { int data[P_NOISECURVES][17]; } noise3; typedef struct { int mappings; const double *rate_mapping; const double *quality_mapping; int coupling_restriction; long samplerate_min_restriction; long samplerate_max_restriction; const int *blocksize_short; const int *blocksize_long; const att3 *psy_tone_masteratt; const int *psy_tone_0dB; const int *psy_tone_dBsuppress; const vp_adjblock *psy_tone_adj_impulse; const vp_adjblock *psy_tone_adj_long; const vp_adjblock *psy_tone_adj_other; const noiseguard *psy_noiseguards; const noise3 *psy_noise_bias_impulse; const noise3 *psy_noise_bias_padding; const noise3 *psy_noise_bias_trans; const noise3 *psy_noise_bias_long; const int *psy_noise_dBsuppress; const compandblock *psy_noise_compand; const double *psy_noise_compand_short_mapping; const double *psy_noise_compand_long_mapping; const int *psy_noise_normal_start[2]; const int *psy_noise_normal_partition[2]; const double *psy_noise_normal_thresh; const int *psy_ath_float; const int *psy_ath_abs; const double *psy_lowpass; const vorbis_info_psy_global *global_params; const double *global_mapping; const adj_stereo *stereo_modes; const static_codebook *const *const *const floor_books; const vorbis_info_floor1 *floor_params; const int floor_mappings; const int **floor_mapping_list; const vorbis_mapping_template *maps; } ve_setup_data_template; /* a few static coder conventions */ static const vorbis_info_mode _mode_template[2]={ {0,0,0,0}, {1,0,0,1} }; static const vorbis_info_mapping0 _map_nominal[2]={ {1, {0,0}, {0}, {0}, 1,{0},{1}}, {1, {0,0}, {1}, {1}, 1,{0},{1}} }; #include "modes/setup_44.h" #include "modes/setup_44u.h" #include "modes/setup_44p51.h" #include "modes/setup_32.h" #include "modes/setup_8.h" #include "modes/setup_11.h" #include "modes/setup_16.h" #include "modes/setup_22.h" #include "modes/setup_X.h" static const ve_setup_data_template *const setup_list[]={ &ve_setup_44_stereo, &ve_setup_44_51, &ve_setup_44_uncoupled, &ve_setup_32_stereo, &ve_setup_32_uncoupled, &ve_setup_22_stereo, &ve_setup_22_uncoupled, &ve_setup_16_stereo, &ve_setup_16_uncoupled, &ve_setup_11_stereo, &ve_setup_11_uncoupled, &ve_setup_8_stereo, &ve_setup_8_uncoupled, &ve_setup_X_stereo, &ve_setup_X_uncoupled, &ve_setup_XX_stereo, &ve_setup_XX_uncoupled, 0 }; static void vorbis_encode_floor_setup(vorbis_info *vi,int s, const static_codebook *const *const *const books, const vorbis_info_floor1 *in, const int *x){ int i,k,is=s; vorbis_info_floor1 *f=_ogg_calloc(1,sizeof(*f)); codec_setup_info *ci=vi->codec_setup; memcpy(f,in+x[is],sizeof(*f)); /* books */ { int partitions=f->partitions; int maxclass=-1; int maxbook=-1; for(i=0;ipartitionclass[i]>maxclass)maxclass=f->partitionclass[i]; for(i=0;i<=maxclass;i++){ if(f->class_book[i]>maxbook)maxbook=f->class_book[i]; f->class_book[i]+=ci->books; for(k=0;k<(1<class_subs[i]);k++){ if(f->class_subbook[i][k]>maxbook)maxbook=f->class_subbook[i][k]; if(f->class_subbook[i][k]>=0)f->class_subbook[i][k]+=ci->books; } } for(i=0;i<=maxbook;i++) ci->book_param[ci->books++]=(static_codebook *)books[x[is]][i]; } /* for now, we're only using floor 1 */ ci->floor_type[ci->floors]=1; ci->floor_param[ci->floors]=f; ci->floors++; return; } static void vorbis_encode_global_psych_setup(vorbis_info *vi,double s, const vorbis_info_psy_global *in, const double *x){ int i,is=s; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy_global *g=&ci->psy_g_param; memcpy(g,in+(int)x[is],sizeof(*g)); ds=x[is]*(1.-ds)+x[is+1]*ds; is=(int)ds; ds-=is; if(ds==0 && is>0){ is--; ds=1.; } /* interpolate the trigger threshholds */ for(i=0;i<4;i++){ g->preecho_thresh[i]=in[is].preecho_thresh[i]*(1.-ds)+in[is+1].preecho_thresh[i]*ds; g->postecho_thresh[i]=in[is].postecho_thresh[i]*(1.-ds)+in[is+1].postecho_thresh[i]*ds; } g->ampmax_att_per_sec=ci->hi.amplitude_track_dBpersec; return; } static void vorbis_encode_global_stereo(vorbis_info *vi, const highlevel_encode_setup *const hi, const adj_stereo *p){ float s=hi->stereo_point_setting; int i,is=s; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy_global *g=&ci->psy_g_param; if(p){ memcpy(g->coupling_prepointamp,p[is].pre,sizeof(*p[is].pre)*PACKETBLOBS); memcpy(g->coupling_postpointamp,p[is].post,sizeof(*p[is].post)*PACKETBLOBS); if(hi->managed){ /* interpolate the kHz threshholds */ for(i=0;icoupling_pointlimit[0][i]=kHz*1000./vi->rate*ci->blocksizes[0]; g->coupling_pointlimit[1][i]=kHz*1000./vi->rate*ci->blocksizes[1]; g->coupling_pkHz[i]=kHz; kHz=p[is].lowpasskHz[i]*(1.-ds)+p[is+1].lowpasskHz[i]*ds; g->sliding_lowpass[0][i]=kHz*1000./vi->rate*ci->blocksizes[0]; g->sliding_lowpass[1][i]=kHz*1000./vi->rate*ci->blocksizes[1]; } }else{ float kHz=p[is].kHz[PACKETBLOBS/2]*(1.-ds)+p[is+1].kHz[PACKETBLOBS/2]*ds; for(i=0;icoupling_pointlimit[0][i]=kHz*1000./vi->rate*ci->blocksizes[0]; g->coupling_pointlimit[1][i]=kHz*1000./vi->rate*ci->blocksizes[1]; g->coupling_pkHz[i]=kHz; } kHz=p[is].lowpasskHz[PACKETBLOBS/2]*(1.-ds)+p[is+1].lowpasskHz[PACKETBLOBS/2]*ds; for(i=0;isliding_lowpass[0][i]=kHz*1000./vi->rate*ci->blocksizes[0]; g->sliding_lowpass[1][i]=kHz*1000./vi->rate*ci->blocksizes[1]; } } }else{ for(i=0;isliding_lowpass[0][i]=ci->blocksizes[0]; g->sliding_lowpass[1][i]=ci->blocksizes[1]; } } return; } static void vorbis_encode_psyset_setup(vorbis_info *vi,double s, const int *nn_start, const int *nn_partition, const double *nn_thresh, int block){ codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; highlevel_encode_setup *hi=&ci->hi; int is=s; if(block>=ci->psys) ci->psys=block+1; if(!p){ p=_ogg_calloc(1,sizeof(*p)); ci->psy_param[block]=p; } memcpy(p,&_psy_info_template,sizeof(*p)); p->blockflag=block>>1; if(hi->noise_normalize_p){ p->normal_p=1; p->normal_start=nn_start[is]; p->normal_partition=nn_partition[is]; p->normal_thresh=nn_thresh[is]; } return; } static void vorbis_encode_tonemask_setup(vorbis_info *vi,double s,int block, const att3 *att, const int *max, const vp_adjblock *in){ int i,is=s; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; /* 0 and 2 are only used by bitmanagement, but there's no harm to always filling the values in here */ p->tone_masteratt[0]=att[is].att[0]*(1.-ds)+att[is+1].att[0]*ds; p->tone_masteratt[1]=att[is].att[1]*(1.-ds)+att[is+1].att[1]*ds; p->tone_masteratt[2]=att[is].att[2]*(1.-ds)+att[is+1].att[2]*ds; p->tone_centerboost=att[is].boost*(1.-ds)+att[is+1].boost*ds; p->tone_decay=att[is].decay*(1.-ds)+att[is+1].decay*ds; p->max_curve_dB=max[is]*(1.-ds)+max[is+1]*ds; for(i=0;itoneatt[i]=in[is].block[i]*(1.-ds)+in[is+1].block[i]*ds; return; } static void vorbis_encode_compand_setup(vorbis_info *vi,double s,int block, const compandblock *in, const double *x){ int i,is=s; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; ds=x[is]*(1.-ds)+x[is+1]*ds; is=(int)ds; ds-=is; if(ds==0 && is>0){ is--; ds=1.; } /* interpolate the compander settings */ for(i=0;inoisecompand[i]=in[is].data[i]*(1.-ds)+in[is+1].data[i]*ds; return; } static void vorbis_encode_peak_setup(vorbis_info *vi,double s,int block, const int *suppress){ int is=s; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; p->tone_abs_limit=suppress[is]*(1.-ds)+suppress[is+1]*ds; return; } static void vorbis_encode_noisebias_setup(vorbis_info *vi,double s,int block, const int *suppress, const noise3 *in, const noiseguard *guard, double userbias){ int i,is=s,j; double ds=s-is; codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; p->noisemaxsupp=suppress[is]*(1.-ds)+suppress[is+1]*ds; p->noisewindowlomin=guard[block].lo; p->noisewindowhimin=guard[block].hi; p->noisewindowfixed=guard[block].fixed; for(j=0;jnoiseoff[j][i]=in[is].data[j][i]*(1.-ds)+in[is+1].data[j][i]*ds; /* impulse blocks may take a user specified bias to boost the nominal/high noise encoding depth */ for(j=0;jnoiseoff[j][0]+6; /* the lowest it can go */ for(i=0;inoiseoff[j][i]+=userbias; if(p->noiseoff[j][i]noiseoff[j][i]=min; } } return; } static void vorbis_encode_ath_setup(vorbis_info *vi,int block){ codec_setup_info *ci=vi->codec_setup; vorbis_info_psy *p=ci->psy_param[block]; p->ath_adjatt=ci->hi.ath_floating_dB; p->ath_maxatt=ci->hi.ath_absolute_dB; return; } static int book_dup_or_new(codec_setup_info *ci,const static_codebook *book){ int i; for(i=0;ibooks;i++) if(ci->book_param[i]==book)return(i); return(ci->books++); } static void vorbis_encode_blocksize_setup(vorbis_info *vi,double s, const int *shortb,const int *longb){ codec_setup_info *ci=vi->codec_setup; int is=s; int blockshort=shortb[is]; int blocklong=longb[is]; ci->blocksizes[0]=blockshort; ci->blocksizes[1]=blocklong; } static void vorbis_encode_residue_setup(vorbis_info *vi, int number, int block, const vorbis_residue_template *res){ codec_setup_info *ci=vi->codec_setup; int i; vorbis_info_residue0 *r=ci->residue_param[number]= _ogg_malloc(sizeof(*r)); memcpy(r,res->res,sizeof(*r)); if(ci->residues<=number)ci->residues=number+1; r->grouping=res->grouping; ci->residue_type[number]=res->res_type; /* fill in all the books */ { int booklist=0,k; if(ci->hi.managed){ for(i=0;ipartitions;i++) for(k=0;k<4;k++) if(res->books_base_managed->books[i][k]) r->secondstages[i]|=(1<groupbook=book_dup_or_new(ci,res->book_aux_managed); ci->book_param[r->groupbook]=(static_codebook *)res->book_aux_managed; for(i=0;ipartitions;i++){ for(k=0;k<4;k++){ if(res->books_base_managed->books[i][k]){ int bookid=book_dup_or_new(ci,res->books_base_managed->books[i][k]); r->booklist[booklist++]=bookid; ci->book_param[bookid]=(static_codebook *)res->books_base_managed->books[i][k]; } } } }else{ for(i=0;ipartitions;i++) for(k=0;k<4;k++) if(res->books_base->books[i][k]) r->secondstages[i]|=(1<groupbook=book_dup_or_new(ci,res->book_aux); ci->book_param[r->groupbook]=(static_codebook *)res->book_aux; for(i=0;ipartitions;i++){ for(k=0;k<4;k++){ if(res->books_base->books[i][k]){ int bookid=book_dup_or_new(ci,res->books_base->books[i][k]); r->booklist[booklist++]=bookid; ci->book_param[bookid]=(static_codebook *)res->books_base->books[i][k]; } } } } } /* lowpass setup/pointlimit */ { double freq=ci->hi.lowpass_kHz*1000.; vorbis_info_floor1 *f=ci->floor_param[block]; /* by convention */ double nyq=vi->rate/2.; long blocksize=ci->blocksizes[block]>>1; /* lowpass needs to be set in the floor and the residue. */ if(freq>nyq)freq=nyq; /* in the floor, the granularity can be very fine; it doesn't alter the encoding structure, only the samples used to fit the floor approximation */ f->n=freq/nyq*blocksize; /* this res may by limited by the maximum pointlimit of the mode, not the lowpass. the floor is always lowpass limited. */ switch(res->limit_type){ case 1: /* point stereo limited */ if(ci->hi.managed) freq=ci->psy_g_param.coupling_pkHz[PACKETBLOBS-1]*1000.; else freq=ci->psy_g_param.coupling_pkHz[PACKETBLOBS/2]*1000.; if(freq>nyq)freq=nyq; break; case 2: /* LFE channel; lowpass at ~ 250Hz */ freq=250; break; default: /* already set */ break; } /* in the residue, we're constrained, physically, by partition boundaries. We still lowpass 'wherever', but we have to round up here to next boundary, or the vorbis spec will round it *down* to previous boundary in encode/decode */ if(ci->residue_type[number]==2){ /* residue 2 bundles together multiple channels; used by stereo and surround. Count the channels in use */ /* Multiple maps/submaps can point to the same residue. In the case of residue 2, they all better have the same number of channels/samples. */ int j,k,ch=0; for(i=0;imaps&&ch==0;i++){ vorbis_info_mapping0 *mi=(vorbis_info_mapping0 *)ci->map_param[i]; for(j=0;jsubmaps && ch==0;j++) if(mi->residuesubmap[j]==number) /* we found a submap referencing theis residue backend */ for(k=0;kchannels;k++) if(mi->chmuxlist[k]==j) /* this channel belongs to the submap */ ch++; } r->end=(int)((freq/nyq*blocksize*ch)/r->grouping+.9)* /* round up only if we're well past */ r->grouping; /* the blocksize and grouping may disagree at the end */ if(r->end>blocksize*ch)r->end=blocksize*ch/r->grouping*r->grouping; }else{ r->end=(int)((freq/nyq*blocksize)/r->grouping+.9)* /* round up only if we're well past */ r->grouping; /* the blocksize and grouping may disagree at the end */ if(r->end>blocksize)r->end=blocksize/r->grouping*r->grouping; } if(r->end==0)r->end=r->grouping; /* LFE channel */ } } /* we assume two maps in this encoder */ static void vorbis_encode_map_n_res_setup(vorbis_info *vi,double s, const vorbis_mapping_template *maps){ codec_setup_info *ci=vi->codec_setup; int i,j,is=s,modes=2; const vorbis_info_mapping0 *map=maps[is].map; const vorbis_info_mode *mode=_mode_template; const vorbis_residue_template *res=maps[is].res; if(ci->blocksizes[0]==ci->blocksizes[1])modes=1; for(i=0;imap_param[i]=_ogg_calloc(1,sizeof(*map)); ci->mode_param[i]=_ogg_calloc(1,sizeof(*mode)); memcpy(ci->mode_param[i],mode+i,sizeof(*_mode_template)); if(i>=ci->modes)ci->modes=i+1; ci->map_type[i]=0; memcpy(ci->map_param[i],map+i,sizeof(*map)); if(i>=ci->maps)ci->maps=i+1; for(j=0;jcodec_setup; highlevel_encode_setup *hi=&ci->hi; ve_setup_data_template *setup=(ve_setup_data_template *)hi->setup; int is=hi->base_setting; double ds=hi->base_setting-is; int ch=vi->channels; const double *r=setup->rate_mapping; if(r==NULL) return(-1); return((r[is]*(1.-ds)+r[is+1]*ds)*ch); } static const void *get_setup_template(long ch,long srate, double req,int q_or_bitrate, double *base_setting){ int i=0,j; if(q_or_bitrate)req/=ch; while(setup_list[i]){ if(setup_list[i]->coupling_restriction==-1 || setup_list[i]->coupling_restriction==ch){ if(srate>=setup_list[i]->samplerate_min_restriction && srate<=setup_list[i]->samplerate_max_restriction){ int mappings=setup_list[i]->mappings; const double *map=(q_or_bitrate? setup_list[i]->rate_mapping: setup_list[i]->quality_mapping); /* the template matches. Does the requested quality mode fall within this template's modes? */ if(reqmap[setup_list[i]->mappings]){++i;continue;} for(j=0;j=map[j] && reqcodec_setup; ve_setup_data_template *setup=NULL; highlevel_encode_setup *hi=&ci->hi; if(ci==NULL)return(OV_EINVAL); if(!hi->impulse_block_p)i0=1; /* too low/high an ATH floater is nonsensical, but doesn't break anything */ if(hi->ath_floating_dB>-80)hi->ath_floating_dB=-80; if(hi->ath_floating_dB<-200)hi->ath_floating_dB=-200; /* again, bound this to avoid the app shooting itself int he foot too badly */ if(hi->amplitude_track_dBpersec>0.)hi->amplitude_track_dBpersec=0.; if(hi->amplitude_track_dBpersec<-99999.)hi->amplitude_track_dBpersec=-99999.; /* get the appropriate setup template; matches the fetch in previous stages */ setup=(ve_setup_data_template *)hi->setup; if(setup==NULL)return(OV_EINVAL); hi->set_in_stone=1; /* choose block sizes from configured sizes as well as paying attention to long_block_p and short_block_p. If the configured short and long blocks are the same length, we set long_block_p and unset short_block_p */ vorbis_encode_blocksize_setup(vi,hi->base_setting, setup->blocksize_short, setup->blocksize_long); if(ci->blocksizes[0]==ci->blocksizes[1])singleblock=1; /* floor setup; choose proper floor params. Allocated on the floor stack in order; if we alloc only a single long floor, it's 0 */ for(i=0;ifloor_mappings;i++) vorbis_encode_floor_setup(vi,hi->base_setting, setup->floor_books, setup->floor_params, setup->floor_mapping_list[i]); /* setup of [mostly] short block detection and stereo*/ vorbis_encode_global_psych_setup(vi,hi->trigger_setting, setup->global_params, setup->global_mapping); vorbis_encode_global_stereo(vi,hi,setup->stereo_modes); /* basic psych setup and noise normalization */ vorbis_encode_psyset_setup(vi,hi->base_setting, setup->psy_noise_normal_start[0], setup->psy_noise_normal_partition[0], setup->psy_noise_normal_thresh, 0); vorbis_encode_psyset_setup(vi,hi->base_setting, setup->psy_noise_normal_start[0], setup->psy_noise_normal_partition[0], setup->psy_noise_normal_thresh, 1); if(!singleblock){ vorbis_encode_psyset_setup(vi,hi->base_setting, setup->psy_noise_normal_start[1], setup->psy_noise_normal_partition[1], setup->psy_noise_normal_thresh, 2); vorbis_encode_psyset_setup(vi,hi->base_setting, setup->psy_noise_normal_start[1], setup->psy_noise_normal_partition[1], setup->psy_noise_normal_thresh, 3); } /* tone masking setup */ vorbis_encode_tonemask_setup(vi,hi->block[i0].tone_mask_setting,0, setup->psy_tone_masteratt, setup->psy_tone_0dB, setup->psy_tone_adj_impulse); vorbis_encode_tonemask_setup(vi,hi->block[1].tone_mask_setting,1, setup->psy_tone_masteratt, setup->psy_tone_0dB, setup->psy_tone_adj_other); if(!singleblock){ vorbis_encode_tonemask_setup(vi,hi->block[2].tone_mask_setting,2, setup->psy_tone_masteratt, setup->psy_tone_0dB, setup->psy_tone_adj_other); vorbis_encode_tonemask_setup(vi,hi->block[3].tone_mask_setting,3, setup->psy_tone_masteratt, setup->psy_tone_0dB, setup->psy_tone_adj_long); } /* noise companding setup */ vorbis_encode_compand_setup(vi,hi->block[i0].noise_compand_setting,0, setup->psy_noise_compand, setup->psy_noise_compand_short_mapping); vorbis_encode_compand_setup(vi,hi->block[1].noise_compand_setting,1, setup->psy_noise_compand, setup->psy_noise_compand_short_mapping); if(!singleblock){ vorbis_encode_compand_setup(vi,hi->block[2].noise_compand_setting,2, setup->psy_noise_compand, setup->psy_noise_compand_long_mapping); vorbis_encode_compand_setup(vi,hi->block[3].noise_compand_setting,3, setup->psy_noise_compand, setup->psy_noise_compand_long_mapping); } /* peak guarding setup */ vorbis_encode_peak_setup(vi,hi->block[i0].tone_peaklimit_setting,0, setup->psy_tone_dBsuppress); vorbis_encode_peak_setup(vi,hi->block[1].tone_peaklimit_setting,1, setup->psy_tone_dBsuppress); if(!singleblock){ vorbis_encode_peak_setup(vi,hi->block[2].tone_peaklimit_setting,2, setup->psy_tone_dBsuppress); vorbis_encode_peak_setup(vi,hi->block[3].tone_peaklimit_setting,3, setup->psy_tone_dBsuppress); } /* noise bias setup */ vorbis_encode_noisebias_setup(vi,hi->block[i0].noise_bias_setting,0, setup->psy_noise_dBsuppress, setup->psy_noise_bias_impulse, setup->psy_noiseguards, (i0==0?hi->impulse_noisetune:0.)); vorbis_encode_noisebias_setup(vi,hi->block[1].noise_bias_setting,1, setup->psy_noise_dBsuppress, setup->psy_noise_bias_padding, setup->psy_noiseguards,0.); if(!singleblock){ vorbis_encode_noisebias_setup(vi,hi->block[2].noise_bias_setting,2, setup->psy_noise_dBsuppress, setup->psy_noise_bias_trans, setup->psy_noiseguards,0.); vorbis_encode_noisebias_setup(vi,hi->block[3].noise_bias_setting,3, setup->psy_noise_dBsuppress, setup->psy_noise_bias_long, setup->psy_noiseguards,0.); } vorbis_encode_ath_setup(vi,0); vorbis_encode_ath_setup(vi,1); if(!singleblock){ vorbis_encode_ath_setup(vi,2); vorbis_encode_ath_setup(vi,3); } vorbis_encode_map_n_res_setup(vi,hi->base_setting,setup->maps); /* set bitrate readonlies and management */ if(hi->bitrate_av>0) vi->bitrate_nominal=hi->bitrate_av; else{ vi->bitrate_nominal=setting_to_approx_bitrate(vi); } vi->bitrate_lower=hi->bitrate_min; vi->bitrate_upper=hi->bitrate_max; if(hi->bitrate_av) vi->bitrate_window=(double)hi->bitrate_reservoir/hi->bitrate_av; else vi->bitrate_window=0.; if(hi->managed){ ci->bi.avg_rate=hi->bitrate_av; ci->bi.min_rate=hi->bitrate_min; ci->bi.max_rate=hi->bitrate_max; ci->bi.reservoir_bits=hi->bitrate_reservoir; ci->bi.reservoir_bias= hi->bitrate_reservoir_bias; ci->bi.slew_damp=hi->bitrate_av_damp; } return(0); } static void vorbis_encode_setup_setting(vorbis_info *vi, long channels, long rate){ int i,is; codec_setup_info *ci=vi->codec_setup; highlevel_encode_setup *hi=&ci->hi; const ve_setup_data_template *setup=hi->setup; double ds; vi->version=0; vi->channels=channels; vi->rate=rate; hi->impulse_block_p=1; hi->noise_normalize_p=1; is=hi->base_setting; ds=hi->base_setting-is; hi->stereo_point_setting=hi->base_setting; if(!hi->lowpass_altered) hi->lowpass_kHz= setup->psy_lowpass[is]*(1.-ds)+setup->psy_lowpass[is+1]*ds; hi->ath_floating_dB=setup->psy_ath_float[is]*(1.-ds)+ setup->psy_ath_float[is+1]*ds; hi->ath_absolute_dB=setup->psy_ath_abs[is]*(1.-ds)+ setup->psy_ath_abs[is+1]*ds; hi->amplitude_track_dBpersec=-6.; hi->trigger_setting=hi->base_setting; for(i=0;i<4;i++){ hi->block[i].tone_mask_setting=hi->base_setting; hi->block[i].tone_peaklimit_setting=hi->base_setting; hi->block[i].noise_bias_setting=hi->base_setting; hi->block[i].noise_compand_setting=hi->base_setting; } } int vorbis_encode_setup_vbr(vorbis_info *vi, long channels, long rate, float quality){ codec_setup_info *ci; highlevel_encode_setup *hi; if(rate<=0) return OV_EINVAL; ci=vi->codec_setup; hi=&ci->hi; quality+=.0000001; if(quality>=1.)quality=.9999; hi->req=quality; hi->setup=get_setup_template(channels,rate,quality,0,&hi->base_setting); if(!hi->setup)return OV_EIMPL; vorbis_encode_setup_setting(vi,channels,rate); hi->managed=0; hi->coupling_p=1; return 0; } int vorbis_encode_init_vbr(vorbis_info *vi, long channels, long rate, float base_quality /* 0. to 1. */ ){ int ret=0; ret=vorbis_encode_setup_vbr(vi,channels,rate,base_quality); if(ret){ vorbis_info_clear(vi); return ret; } ret=vorbis_encode_setup_init(vi); if(ret) vorbis_info_clear(vi); return(ret); } int vorbis_encode_setup_managed(vorbis_info *vi, long channels, long rate, long max_bitrate, long nominal_bitrate, long min_bitrate){ codec_setup_info *ci; highlevel_encode_setup *hi; double tnominal; if(rate<=0) return OV_EINVAL; ci=vi->codec_setup; hi=&ci->hi; tnominal=nominal_bitrate; if(nominal_bitrate<=0.){ if(max_bitrate>0.){ if(min_bitrate>0.) nominal_bitrate=(max_bitrate+min_bitrate)*.5; else nominal_bitrate=max_bitrate*.875; }else{ if(min_bitrate>0.){ nominal_bitrate=min_bitrate; }else{ return(OV_EINVAL); } } } hi->req=nominal_bitrate; hi->setup=get_setup_template(channels,rate,nominal_bitrate,1,&hi->base_setting); if(!hi->setup)return OV_EIMPL; vorbis_encode_setup_setting(vi,channels,rate); /* initialize management with sane defaults */ hi->coupling_p=1; hi->managed=1; hi->bitrate_min=min_bitrate; hi->bitrate_max=max_bitrate; hi->bitrate_av=tnominal; hi->bitrate_av_damp=1.5f; /* full range in no less than 1.5 second */ hi->bitrate_reservoir=nominal_bitrate*2; hi->bitrate_reservoir_bias=.1; /* bias toward hoarding bits */ return(0); } int vorbis_encode_init(vorbis_info *vi, long channels, long rate, long max_bitrate, long nominal_bitrate, long min_bitrate){ int ret=vorbis_encode_setup_managed(vi,channels,rate, max_bitrate, nominal_bitrate, min_bitrate); if(ret){ vorbis_info_clear(vi); return(ret); } ret=vorbis_encode_setup_init(vi); if(ret) vorbis_info_clear(vi); return(ret); } int vorbis_encode_ctl(vorbis_info *vi,int number,void *arg){ if(vi){ codec_setup_info *ci=vi->codec_setup; highlevel_encode_setup *hi=&ci->hi; int setp=(number&0xf); /* a read request has a low nibble of 0 */ if(setp && hi->set_in_stone)return(OV_EINVAL); switch(number){ /* now deprecated *****************/ case OV_ECTL_RATEMANAGE_GET: { struct ovectl_ratemanage_arg *ai= (struct ovectl_ratemanage_arg *)arg; ai->management_active=hi->managed; ai->bitrate_hard_window=ai->bitrate_av_window= (double)hi->bitrate_reservoir/vi->rate; ai->bitrate_av_window_center=1.; ai->bitrate_hard_min=hi->bitrate_min; ai->bitrate_hard_max=hi->bitrate_max; ai->bitrate_av_lo=hi->bitrate_av; ai->bitrate_av_hi=hi->bitrate_av; } return(0); /* now deprecated *****************/ case OV_ECTL_RATEMANAGE_SET: { struct ovectl_ratemanage_arg *ai= (struct ovectl_ratemanage_arg *)arg; if(ai==NULL){ hi->managed=0; }else{ hi->managed=ai->management_active; vorbis_encode_ctl(vi,OV_ECTL_RATEMANAGE_AVG,arg); vorbis_encode_ctl(vi,OV_ECTL_RATEMANAGE_HARD,arg); } } return 0; /* now deprecated *****************/ case OV_ECTL_RATEMANAGE_AVG: { struct ovectl_ratemanage_arg *ai= (struct ovectl_ratemanage_arg *)arg; if(ai==NULL){ hi->bitrate_av=0; }else{ hi->bitrate_av=(ai->bitrate_av_lo+ai->bitrate_av_hi)*.5; } } return(0); /* now deprecated *****************/ case OV_ECTL_RATEMANAGE_HARD: { struct ovectl_ratemanage_arg *ai= (struct ovectl_ratemanage_arg *)arg; if(ai==NULL){ hi->bitrate_min=0; hi->bitrate_max=0; }else{ hi->bitrate_min=ai->bitrate_hard_min; hi->bitrate_max=ai->bitrate_hard_max; hi->bitrate_reservoir=ai->bitrate_hard_window* (hi->bitrate_max+hi->bitrate_min)*.5; } if(hi->bitrate_reservoir<128.) hi->bitrate_reservoir=128.; } return(0); /* replacement ratemanage interface */ case OV_ECTL_RATEMANAGE2_GET: { struct ovectl_ratemanage2_arg *ai= (struct ovectl_ratemanage2_arg *)arg; if(ai==NULL)return OV_EINVAL; ai->management_active=hi->managed; ai->bitrate_limit_min_kbps=hi->bitrate_min/1000; ai->bitrate_limit_max_kbps=hi->bitrate_max/1000; ai->bitrate_average_kbps=hi->bitrate_av/1000; ai->bitrate_average_damping=hi->bitrate_av_damp; ai->bitrate_limit_reservoir_bits=hi->bitrate_reservoir; ai->bitrate_limit_reservoir_bias=hi->bitrate_reservoir_bias; } return (0); case OV_ECTL_RATEMANAGE2_SET: { struct ovectl_ratemanage2_arg *ai= (struct ovectl_ratemanage2_arg *)arg; if(ai==NULL){ hi->managed=0; }else{ /* sanity check; only catch invariant violations */ if(ai->bitrate_limit_min_kbps>0 && ai->bitrate_average_kbps>0 && ai->bitrate_limit_min_kbps>ai->bitrate_average_kbps) return OV_EINVAL; if(ai->bitrate_limit_max_kbps>0 && ai->bitrate_average_kbps>0 && ai->bitrate_limit_max_kbpsbitrate_average_kbps) return OV_EINVAL; if(ai->bitrate_limit_min_kbps>0 && ai->bitrate_limit_max_kbps>0 && ai->bitrate_limit_min_kbps>ai->bitrate_limit_max_kbps) return OV_EINVAL; if(ai->bitrate_average_damping <= 0.) return OV_EINVAL; if(ai->bitrate_limit_reservoir_bits < 0) return OV_EINVAL; if(ai->bitrate_limit_reservoir_bias < 0.) return OV_EINVAL; if(ai->bitrate_limit_reservoir_bias > 1.) return OV_EINVAL; hi->managed=ai->management_active; hi->bitrate_min=ai->bitrate_limit_min_kbps * 1000; hi->bitrate_max=ai->bitrate_limit_max_kbps * 1000; hi->bitrate_av=ai->bitrate_average_kbps * 1000; hi->bitrate_av_damp=ai->bitrate_average_damping; hi->bitrate_reservoir=ai->bitrate_limit_reservoir_bits; hi->bitrate_reservoir_bias=ai->bitrate_limit_reservoir_bias; } } return 0; case OV_ECTL_LOWPASS_GET: { double *farg=(double *)arg; *farg=hi->lowpass_kHz; } return(0); case OV_ECTL_LOWPASS_SET: { double *farg=(double *)arg; hi->lowpass_kHz=*farg; if(hi->lowpass_kHz<2.)hi->lowpass_kHz=2.; if(hi->lowpass_kHz>99.)hi->lowpass_kHz=99.; hi->lowpass_altered=1; } return(0); case OV_ECTL_IBLOCK_GET: { double *farg=(double *)arg; *farg=hi->impulse_noisetune; } return(0); case OV_ECTL_IBLOCK_SET: { double *farg=(double *)arg; hi->impulse_noisetune=*farg; if(hi->impulse_noisetune>0.)hi->impulse_noisetune=0.; if(hi->impulse_noisetune<-15.)hi->impulse_noisetune=-15.; } return(0); case OV_ECTL_COUPLING_GET: { int *iarg=(int *)arg; *iarg=hi->coupling_p; } return(0); case OV_ECTL_COUPLING_SET: { const void *new_template; double new_base=0.; int *iarg=(int *)arg; hi->coupling_p=((*iarg)!=0); /* Fetching a new template can alter the base_setting, which many other parameters are based on. Right now, the only parameter drawn from the base_setting that can be altered by an encctl is the lowpass, so that is explictly flagged to not be overwritten when we fetch a new template and recompute the dependant settings */ new_template = get_setup_template(hi->coupling_p?vi->channels:-1, vi->rate, hi->req, hi->managed, &new_base); if(!hi->setup)return OV_EIMPL; hi->setup=new_template; hi->base_setting=new_base; vorbis_encode_setup_setting(vi,vi->channels,vi->rate); } return(0); } return(OV_EIMPL); } return(OV_EINVAL); }