override public void pack(Object vr, csBuffer opb) { InfoResidue0 info=(InfoResidue0)vr; int acc=0; opb.write(info.begin,24); opb.write(info.end,24); opb.write(info.grouping-1,24); /* residue vectors to group and code with a partitioned book */ opb.write(info.partitions-1,6); /* possible partition choices */ opb.write(info.groupbook,8); /* group huffman book */ /* secondstages is a bitmask; as encoding progresses pass by pass, a bitmask of one indicates this partition class has bits to write this pass */ for(int j=0;j<info.partitions;j++) { if(ilog(info.secondstages[j])>3) { /* yes, this is a minor hack due to not thinking ahead */ opb.write(info.secondstages[j],3); opb.write(1,1); opb.write(info.secondstages[j] >> 3,5); } else { opb.write(info.secondstages[j],4); /* trailing zero */ } acc+=icount(info.secondstages[j]); } for(int j=0;j<acc;j++) { opb.write(info.booklist[j],8); } }
override public Object unpack(Info vi , csBuffer opb) { InfoFloor0 info=new InfoFloor0(); info.order=opb.read(8); info.rate=opb.read(16); info.barkmap=opb.read(16); info.ampbits=opb.read(6); info.ampdB=opb.read(8); info.numbooks=opb.read(4)+1; if((info.order<1)|| (info.rate<1)|| (info.barkmap<1)|| (info.numbooks<1)) { //free_info(info); return(null); } for(int j=0;j<info.numbooks;j++) { info.books[j]=opb.read(8); if(info.books[j]<0 || info.books[j]>=vi.books) { //free_info(info); return(null); } } return(info); // err_out: // free_info(info); // return(NULL); }
// returns the number of bits and *modifies a* to the quantization value internal int encodev(int best, float[] a, csBuffer b) { for(int k=0;k<dim;k++) { a[k]=valuelist[best*dim+k]; } return(encode(best,b)); }
override public void pack(Object i, csBuffer opb) { InfoFloor0 info=(InfoFloor0)i; opb.write(info.order,8); opb.write(info.rate,16); opb.write(info.barkmap,16); opb.write(info.ampbits,6); opb.write(info.ampdB,8); opb.write(info.numbooks-1,4); for(int j=0;j<info.numbooks;j++) opb.write(info.books[j],8); }
override public void pack(Info vi, Object imap, csBuffer opb) { InfoMapping0 info=(InfoMapping0)imap; /* another 'we meant to do it this way' hack... up to beta 4, we packed 4 binary zeros here to signify one submapping in use. We now redefine that to mean four bitflags that indicate use of deeper features; bit0:submappings, bit1:coupling, bit2,3:reserved. This is backward compatable with all actual uses of the beta code. */ if(info.submaps>1) { opb.write(1,1); opb.write(info.submaps-1,4); } else { opb.write(0,1); } if(info.coupling_steps>0) { opb.write(1,1); opb.write(info.coupling_steps-1,8); for(int i=0;i<info.coupling_steps;i++) { opb.write(info.coupling_mag[i],ilog2(vi.channels)); opb.write(info.coupling_ang[i],ilog2(vi.channels)); } } else { opb.write(0,1); } opb.write(0,2); /* 2,3:reserved */ /* we don't write the channel submappings if we only have one... */ if(info.submaps>1) { for(int i=0;i<vi.channels;i++) opb.write(info.chmuxlist[i],4); } for(int i=0;i<info.submaps;i++) { opb.write(info.timesubmap[i],8); opb.write(info.floorsubmap[i],8); opb.write(info.residuesubmap[i],8); } }
public int header_out(Packet op) { csBuffer opb=new csBuffer(); opb.writeinit(); if(pack(opb)!=0) return OV_EIMPL; op.packet_base = new byte[opb.bytes()]; op.packet=0; op.bytes=opb.bytes(); Array.Copy(opb.buf(), 0, op.packet_base, 0, op.bytes); op.b_o_s=0; op.e_o_s=0; op.granulepos=0; return 0; }
override public Object unpack(Info vi, csBuffer opb) { int acc=0; InfoResidue0 info=new InfoResidue0(); info.begin=opb.read(24); info.end=opb.read(24); info.grouping=opb.read(24)+1; info.partitions=opb.read(6)+1; info.groupbook=opb.read(8); for(int j=0;j<info.partitions;j++) { int cascade=opb.read(3); if(opb.read(1)!=0) { cascade|=(opb.read(5)<<3); } info.secondstages[j]=cascade; acc+=icount(cascade); } for(int j=0;j<acc;j++) { info.booklist[j]=opb.read(8); // if(info.booklist[j]==255)info.booklist[j]=-1; } if(info.groupbook>=vi.books) { free_info(info); return(null); } for(int j=0;j<acc;j++) { if(info.booklist[j]>=vi.books) { free_info(info); return(null); } } return(info); // errout: // free_info(info); // return(NULL); }
override public void pack(Object i, csBuffer opb) { InfoFloor1 info=(InfoFloor1)i; int count=0; int rangebits; int maxposit=info.postlist[1]; int maxclass=-1; /* save out partitions */ opb.write(info.partitions,5); /* only 0 to 31 legal */ for(int j=0;j<info.partitions;j++) { opb.write(info.partitionclass[j],4); /* only 0 to 15 legal */ if(maxclass<info.partitionclass[j]) maxclass=info.partitionclass[j]; } /* save out partition classes */ for(int j=0;j<maxclass+1;j++) { opb.write(info.class_dim[j]-1,3); /* 1 to 8 */ opb.write(info.class_subs[j],2); /* 0 to 3 */ if(info.class_subs[j]!=0) { opb.write(info.class_book[j],8); } for(int k=0;k<(1<<info.class_subs[j]);k++) { opb.write(info.class_subbook[j][k]+1,8); } } /* save out the post list */ opb.write(info.mult-1,2); /* only 1,2,3,4 legal now */ opb.write(ilog2(maxposit),4); rangebits=ilog2(maxposit); for(int j=0,k=0;j<info.partitions;j++) { count+=info.class_dim[info.partitionclass[j]]; for(;k<count;k++) { opb.write(info.postlist[k+2],rangebits); } } }
public override Object unpack(Info vi , csBuffer opb) { return ""; }
/* */ // unpacks a codebook from the packet buffer into the codebook struct, // readies the codebook auxiliary structures for decode internal int unpack(csBuffer opb) { int i; //memset(s,0,sizeof(static_codebook)); // make sure alignment is correct if(opb.read(24)!=0x564342) { // goto _eofout; clear(); return(-1); } // first the basic parameters dim=opb.read(16); entries=opb.read(24); if(entries==-1) { // goto _eofout; clear(); return(-1); } // codeword ordering.... length ordered or unordered? switch(opb.read(1)) { case 0: // unordered lengthlist=new int[entries]; // allocated but unused entries? if(opb.read(1)!=0) { // yes, unused entries for(i=0;i<entries;i++) { if(opb.read(1)!=0) { int num=opb.read(5); if(num==-1) { // goto _eofout; clear(); return(-1); } lengthlist[i]=num+1; } else { lengthlist[i]=0; } } } else { // all entries used; no tagging for(i=0;i<entries;i++) { int num=opb.read(5); if(num==-1) { // goto _eofout; clear(); return(-1); } lengthlist[i]=num+1; } } break; case 1: // ordered { int length=opb.read(5)+1; lengthlist=new int[entries]; for(i=0;i<entries;) { int num=opb.read(ilog(entries-i)); if(num==-1) { // goto _eofout; clear(); return(-1); } for(int j=0;j<num;j++,i++) { lengthlist[i]=length; } length++; } } break; default: // EOF return(-1); } // Do we have a mapping to unpack? switch((maptype=opb.read(4))) { case 0: // no mapping break; case 1: case 2: // implicitly populated value mapping // explicitly populated value mapping q_min=opb.read(32); q_delta=opb.read(32); q_quant=opb.read(4)+1; q_sequencep=opb.read(1); { int quantvals=0; switch(maptype) { case 1: quantvals=maptype1_quantvals(); break; case 2: quantvals=entries*dim; break; } // quantized values quantlist=new int[quantvals]; for(i=0;i<quantvals;i++) { quantlist[i]=opb.read(q_quant); } if(quantlist[quantvals-1]==-1) { // goto _eofout; clear(); return(-1); } } break; default: // goto _eofout; clear(); return(-1); } // all set return(0); // _errout: // _eofout: // vorbis_staticbook_clear(s); // return(-1); }
public override void pack(Object i, csBuffer opb) { }
// res0 (multistage, interleave, lattice) // returns the number of bits and *modifies a* to the remainder value internal int encodevs(float[] a, csBuffer b, int step,int addmul) { int best=besterror(a,step,addmul); return(encode(best,b)); }
internal int pack(csBuffer opb) { int i; bool ordered=false; opb.write(0x564342,24); opb.write(dim, 16); opb.write(entries, 24); // pack the codewords. There are two packings; length ordered and // length random. Decide between the two now. for(i=1;i<entries;i++) { if(lengthlist[i]<lengthlist[i-1])break; } if(i==entries)ordered=true; if(ordered) { // length ordered. We only need to say how many codewords of // each length. The actual codewords are generated // deterministically int count=0; opb.write(1,1); // ordered opb.write(lengthlist[0]-1,5); // 1 to 32 for(i=1;i<entries;i++) { int _this=lengthlist[i]; int _last=lengthlist[i-1]; if(_this>_last) { for(int j=_last;j<_this;j++) { opb.write(i-count,ilog(entries-count)); count=i; } } } opb.write(i-count,ilog(entries-count)); } else { // length random. Again, we don't code the codeword itself, just // the length. This time, though, we have to encode each length opb.write(0,1); // unordered // algortihmic mapping has use for 'unused entries', which we tag // here. The algorithmic mapping happens as usual, but the unused // entry has no codeword. for(i=0;i<entries;i++) { if(lengthlist[i]==0)break; } if(i==entries) { opb.write(0,1); // no unused entries for(i=0;i<entries;i++) { opb.write(lengthlist[i]-1,5); } } else { opb.write(1,1); // we have unused entries; thus we tag for(i=0;i<entries;i++) { if(lengthlist[i]==0) { opb.write(0,1); } else { opb.write(1,1); opb.write(lengthlist[i]-1,5); } } } } // is the entry number the desired return value, or do we have a // mapping? If we have a mapping, what type? opb.write(maptype,4); switch(maptype) { case 0: // no mapping break; case 1: case 2: // implicitly populated value mapping // explicitly populated value mapping if(quantlist==null) { // no quantlist? error return(-1); } // values that define the dequantization opb.write(q_min,32); opb.write(q_delta,32); opb.write(q_quant-1,4); opb.write(q_sequencep,1); { int quantvals=0; switch(maptype) { case 1: // a single column of (c->entries/c->dim) quantized values for // building a full value list algorithmically (square lattice) quantvals=maptype1_quantvals(); break; case 2: // every value (c->entries*c->dim total) specified explicitly quantvals=entries*dim; break; } // quantized values for(i=0;i<quantvals;i++) { opb.write(Math.Abs(quantlist[i]),q_quant); } } break; default: // error case; we don't have any other map types now return(-1); } return(0); }
int pack(csBuffer opb) { String temp="Xiphophorus libVorbis I 20000508"; Encoding AE = Encoding.UTF8; byte[] temp_byt = AE.GetBytes(temp); byte[] _vorbis_byt = AE.GetBytes(_vorbis); // preamble opb.write(0x03,8); opb.write(_vorbis_byt); // vendor opb.write(temp.Length,32); opb.write(temp_byt); // comments opb.write(comments,32); if(comments!=0) { for(int i=0;i<comments;i++) { if(user_comments[i]!=null) { opb.write(comment_lengths[i],32); opb.write(user_comments[i]); } else { opb.write(0,32); } } } opb.write(1,1); return(0); }
// all of the real encoding details are here. The modes, books, // everything int unpack_books(csBuffer opb) { //d* codebooks books=opb.read(8)+1; if(book_param==null || book_param.Length!=books) book_param=new StaticCodeBook[books]; for(int i=0;i<books;i++) { book_param[i]=new StaticCodeBook(); if(book_param[i].unpack(opb)!=0) { //goto err_out; clear(); return(-1); } } // time backend settings times=opb.read(6)+1; if(time_type==null || time_type.Length!=times) time_type=new int[times]; if(time_param==null || time_param.Length!=times) time_param=new Object[times]; for(int i=0;i<times;i++) { time_type[i]=opb.read(16); if(time_type[i]<0 || time_type[i]>=VI_TIMEB) { //goto err_out; clear(); return(-1); } time_param[i]=FuncTime.time_P[time_type[i]].unpack(this, opb); if(time_param[i]==null) { //goto err_out; clear(); return(-1); } } // floor backend settings floors=opb.read(6)+1; if(floor_type==null || floor_type.Length!=floors) floor_type=new int[floors]; if(floor_param==null || floor_param.Length!=floors) floor_param=new Object[floors]; for(int i=0;i<floors;i++) { floor_type[i]=opb.read(16); if(floor_type[i]<0 || floor_type[i]>=VI_FLOORB) { //goto err_out; clear(); return(-1); } floor_param[i]=FuncFloor.floor_P[floor_type[i]].unpack(this,opb); if(floor_param[i]==null) { //goto err_out; clear(); return(-1); } } // residue backend settings residues=opb.read(6)+1; if(residue_type==null || residue_type.Length!=residues) residue_type=new int[residues]; if(residue_param==null || residue_param.Length!=residues) residue_param=new Object[residues]; for(int i=0;i<residues;i++) { residue_type[i]=opb.read(16); if(residue_type[i]<0 || residue_type[i]>=VI_RESB) { // goto err_out; clear(); return(-1); } residue_param[i]=FuncResidue.residue_P[residue_type[i]].unpack(this,opb); if(residue_param[i]==null) { // goto err_out; clear(); return(-1); } } // map backend settings maps=opb.read(6)+1; if(map_type==null || map_type.Length!=maps) map_type=new int[maps]; if(map_param==null || map_param.Length!=maps) map_param=new Object[maps]; for(int i=0;i<maps;i++) { map_type[i]=opb.read(16); if(map_type[i]<0 || map_type[i]>=VI_MAPB) { // goto err_out; clear(); return(-1); } map_param[i]=FuncMapping.mapping_P[map_type[i]].unpack(this,opb); if(map_param[i]==null) { // goto err_out; clear(); return(-1); } } // mode settings modes=opb.read(6)+1; if(mode_param==null || mode_param.Length!=modes) mode_param=new InfoMode[modes]; for(int i=0;i<modes;i++) { mode_param[i]=new InfoMode(); mode_param[i].blockflag=opb.read(1); mode_param[i].windowtype=opb.read(16); mode_param[i].transformtype=opb.read(16); mode_param[i].mapping=opb.read(8); if((mode_param[i].windowtype>=VI_WINDOWB)|| (mode_param[i].transformtype>=VI_WINDOWB)|| (mode_param[i].mapping>=maps)) { // goto err_out; clear(); return(-1); } } if(opb.read(1)!=1) { //goto err_out; // top level EOP check clear(); return(-1); } return(0); // err_out: // vorbis_info_clear(vi); // return(-1); }
public abstract void pack(Object i, csBuffer opb);
public override Object unpack(Info vi, csBuffer opb) { // also responsible for range checking InfoMapping0 info=new InfoMapping0(); // !!!! if(opb.read(1)!=0) { info.submaps=opb.read(4)+1; } else { info.submaps=1; } if(opb.read(1)!=0) { info.coupling_steps=opb.read(8)+1; for(int i=0;i<info.coupling_steps;i++) { int testM=info.coupling_mag[i]=opb.read(ilog2(vi.channels)); int testA=info.coupling_ang[i]=opb.read(ilog2(vi.channels)); if(testM<0 || testA<0 || testM==testA || testM>=vi.channels || testA>=vi.channels) { //goto err_out; info.free(); return(null); } } } if(opb.read(2)>0) { /* 2,3:reserved */ //goto err_out; info.free(); return(null); } if(info.submaps>1) { for(int i=0;i<vi.channels;i++) { info.chmuxlist[i]=opb.read(4); if(info.chmuxlist[i]>=info.submaps) { //goto err_out; info.free(); return(null); } } } for(int i=0;i<info.submaps;i++) { info.timesubmap[i]=opb.read(8); if(info.timesubmap[i]>=vi.times) { //goto err_out; info.free(); return(null); } info.floorsubmap[i]=opb.read(8); if(info.floorsubmap[i]>=vi.floors) { //goto err_out; info.free(); return(null); } info.residuesubmap[i]=opb.read(8); if(info.residuesubmap[i]>=vi.residues) { //goto err_out; info.free(); return(null); } } return info; //err_out: //free_info(info); //return(NULL); }
// returns the entry number or -1 on eof internal int decodevs(float[] a, int index, csBuffer b, int step,int addmul) { int entry=decode(b); if(entry==-1)return(-1); switch(addmul) { case -1: for(int i=0,o=0;i<dim;i++,o+=step) a[index+o]=valuelist[entry*dim+i]; break; case 0: for(int i=0,o=0;i<dim;i++,o+=step) a[index+o]+=valuelist[entry*dim+i]; break; case 1: for(int i=0,o=0;i<dim;i++,o+=step) a[index+o]*=valuelist[entry*dim+i]; break; default: //nothing break; } return(entry); }
internal int decodevs_add(float[]a, int offset, csBuffer b, int n) { int step=n/dim; int entry; int i,j,o; if(t.Length<step) { t=new int[step]; } for(i = 0; i < step; i++) { entry=decode(b); if(entry==-1)return(-1); t[i]=entry*dim; } for(i=0,o=0;i<dim;i++,o+=step) { for(j=0;j<step;j++) { a[offset+o+j]+=valuelist[t[j]+i]; } } return(0); }
// Decode side is specced and easier, because we don't need to find // matches using different criteria; we simply read and map. There are // two things we need to do 'depending': // // We may need to support interleave. We don't really, but it's // convenient to do it here rather than rebuild the vector later. // // Cascades may be additive or multiplicitive; this is not inherent in // the codebook, but set in the code using the codebook. Like // interleaving, it's easiest to do it here. // stage==0 -> declarative (set the value) // stage==1 -> additive // stage==2 -> multiplicitive // returns the entry number or -1 on eof internal int decode(csBuffer b) { int ptr=0; DecodeAux t=decode_tree; int lok=b.look(t.tabn); //System.err.println(this+" "+t+" lok="+lok+", tabn="+t.tabn); if(lok>=0) { ptr=t.tab[lok]; b.adv(t.tabl[lok]); if(ptr<=0) { return -ptr; } } do { switch(b.read1()) { case 0: ptr=t.ptr0[ptr]; break; case 1: ptr=t.ptr1[ptr]; break; case -1: default: return(-1); } } while(ptr>0); return(-ptr); }
// static void v_writestring(csBuffer o, byte[] s){ // int i=0; // while(s[i]!=0){ // o.write(s[i++],8); // } // } // static void v_readstring(csBuffer o, byte[] buf, int bytes){ // int i=0 // while(bytes--!=0){ // buf[i++]=o.read(8); // } // } // private csBuffer opb_blocksize=new csBuffer(); public int blocksize(Packet op) { //codec_setup_info *ci=vi->codec_setup; csBuffer opb=new csBuffer(); // synchronized(opb_blocksize){ int mode; opb.readinit(op.packet_base, op.packet, op.bytes); /* Check the packet type */ if(opb.read(1)!=0) { /* Oops. This is not an audio data packet */ return(OV_ENOTAUDIO); } { int modebits=0; int v=modes; while(v>1) { modebits++; v = (int)((uint)v >> 1); } /* read our mode and pre/post windowsize */ mode=opb.read(modebits); } if(mode==-1)return(OV_EBADPACKET); return(blocksizes[mode_param[mode].blockflag]); // } }
int pack_books(csBuffer opb) { Encoding AE = Encoding.UTF8; byte[] _vorbis_byt = AE.GetBytes(_vorbis); opb.write(0x05,8); opb.write(_vorbis_byt); // books opb.write(books-1,8); for(int i=0;i<books;i++) { if(book_param[i].pack(opb)!=0) { //goto err_out; return(-1); } } // times opb.write(times-1,6); for(int i=0;i<times;i++) { opb.write(time_type[i],16); FuncTime.time_P[time_type[i]].pack(this.time_param[i],opb); } // floors opb.write(floors-1,6); for(int i=0;i<floors;i++) { opb.write(floor_type[i],16); FuncFloor.floor_P[floor_type[i]].pack(floor_param[i],opb); } // residues opb.write(residues-1,6); for(int i=0;i<residues;i++) { opb.write(residue_type[i],16); FuncResidue.residue_P[residue_type[i]].pack(residue_param[i],opb); } // maps opb.write(maps-1,6); for(int i=0;i<maps;i++) { opb.write(map_type[i],16); FuncMapping.mapping_P[map_type[i]].pack(this,map_param[i],opb); } // modes opb.write(modes-1,6); for(int i=0;i<modes;i++) { opb.write(mode_param[i].blockflag,1); opb.write(mode_param[i].windowtype,16); opb.write(mode_param[i].transformtype,16); opb.write(mode_param[i].mapping,8); } opb.write(1,1); return(0); //err_out: //return(-1); }
// pack side int pack_info(csBuffer opb) { Encoding AE = Encoding.UTF8; byte[] _vorbis_byt = AE.GetBytes(_vorbis); // preamble opb.write(0x01,8); opb.write(_vorbis_byt); // basic information about the stream opb.write(0x00,32); opb.write(channels,8); opb.write(rate,32); opb.write(bitrate_upper,32); opb.write(bitrate_nominal,32); opb.write(bitrate_lower,32); opb.write(ilog2(blocksizes[0]),4); opb.write(ilog2(blocksizes[1]),4); opb.write(1,1); return(0); }
// The Vorbis header is in three packets; the initial small packet in // the first page that identifies basic parameters, a second packet // with bitstream comments and a third packet that holds the // codebook. public int synthesis_headerin(Comment vc, Packet op) { csBuffer opb=new csBuffer(); if(op!=null) { opb.readinit(op.packet_base, op.packet, op.bytes); // Which of the three types of header is this? // Also verify header-ness, vorbis { byte[] buffer=new byte[6]; int packtype=opb.read(8); //memset(buffer,0,6); opb.read(buffer,6); if(buffer[0]!='v' || buffer[1]!='o' || buffer[2]!='r' || buffer[3]!='b' || buffer[4]!='i' || buffer[5]!='s') { // not a vorbis header return(-1); } switch(packtype) { case 0x01: // least significant *bit* is read first if(op.b_o_s==0) { // Not the initial packet return(-1); } if(rate!=0) { // previously initialized info header return(-1); } return(unpack_info(opb)); case 0x03: // least significant *bit* is read first if(rate==0) { // um... we didn't get the initial header return(-1); } return(vc.unpack(opb)); case 0x05: // least significant *bit* is read first if(rate==0 || vc.vendor==null) { // um... we didn;t get the initial header or comments yet return(-1); } return(unpack_books(opb)); default: // Not a valid vorbis header type //return(-1); break; } } } return(-1); }
public abstract Object unpack(Info vi , csBuffer opb);
internal int decodev_add(float[]a, int offset, csBuffer b,int n) { int i,j,k,entry; int t; if(dim>8) { for(i=0;i<n;) { entry = decode(b); if(entry==-1)return(-1); t=entry*dim; for(j=0;j<dim;) { a[offset+(i++)]+=valuelist[t+(j++)]; } } } else { for(i=0;i<n;) { entry=decode(b); if(entry==-1)return(-1); t=entry*dim; j=0; for(k=0; k < dim; k++) { a[offset+(i++)]+=valuelist[t+(j++)]; } } } return(0); }
internal int unpack(csBuffer opb) { int vendorlen=opb.read(32); if(vendorlen<0) { //goto err_out; clear(); return(-1); } vendor=new byte[vendorlen+1]; opb.read(vendor,vendorlen); comments=opb.read(32); if(comments<0) { //goto err_out; clear(); return(-1); } user_comments=new byte[comments+1][]; comment_lengths=new int[comments+1]; for(int i=0;i<comments;i++) { int len=opb.read(32); if(len<0) { //goto err_out; clear(); return(-1); } comment_lengths[i]=len; user_comments[i]=new byte[len+1]; opb.read(user_comments[i], len); } if(opb.read(1)!=1) { //goto err_out; // EOP check clear(); return(-1); } return(0); // err_out: // comment_clear(vc); // return(-1); }
internal int decodev_set(float[] a,int offset, csBuffer b, int n) { int i,j,entry; int t; for(i=0;i<n;) { entry = decode(b); if(entry==-1)return(-1); t=entry*dim; for(j=0;j<dim;) { a[offset+i++]=valuelist[t+(j++)]; } } return(0); }
internal int decodevv_add(float[][] a, int offset,int ch, csBuffer b,int n) { int i,j,entry; int chptr=0; //System.out.println("decodevv_add: a="+a+",b="+b+",valuelist="+valuelist); for(i=offset/ch;i<(offset+n)/ch;) { entry = decode(b); if(entry==-1)return(-1); int t = entry*dim; for(j=0;j<dim;j++) { a[chptr][i]+=valuelist[t+j]; chptr++; if(chptr==ch) { chptr=0; i++; } } } return(0); }
// returns the number of bits internal int encode(int a, csBuffer b) { b.write(codelist[a], c.lengthlist[a]); return(c.lengthlist[a]); }