/*-------------------------------------------------------------*/ /*--- Compression machinery (not incl block sorting) ---*/ /*--- compress.c ---*/ /*-------------------------------------------------------------*/ /* ------------------------------------------------------------------ This file is part of bzip2/libbzip2, a program and library for lossless, block-sorting data compression. bzip2/libbzip2 version 1.0.5 of 10 December 2007 Copyright (C) 1996-2007 Julian Seward <jseward@bzip.org> Please read the WARNING, DISCLAIMER and PATENTS sections in the README file. This program is released under the terms of the license contained in the file LICENSE. ------------------------------------------------------------------ */ /* CHANGES 0.9.0 -- original version. 0.9.0a/b -- no changes in this file. 0.9.0c -- changed setting of nGroups in sendMTFValues() so as to do a bit better on small files */ #include "bzlib_private.h" /*---------------------------------------------------*/ /*--- Bit stream I/O ---*/ /*---------------------------------------------------*/ /*---------------------------------------------------*/ void BZ2_bsInitWrite ( EState* s ) { s->bsLive = 0; s->bsBuff = 0; } /*---------------------------------------------------*/ static void bsFinishWrite ( EState* s ) { while (s->bsLive > 0) { s->zbits[s->numZ] = (UChar)(s->bsBuff >> 24); s->numZ++; s->bsBuff <<= 8; s->bsLive -= 8; } } /*---------------------------------------------------*/ #define bsNEEDW(nz) \ { \ while (s->bsLive >= 8) { \ s->zbits[s->numZ] \ = (UChar)(s->bsBuff >> 24); \ s->numZ++; \ s->bsBuff <<= 8; \ s->bsLive -= 8; \ } \ } /*---------------------------------------------------*/ static __inline__ void bsW ( EState* s, Int32 n, UInt32 v ) { bsNEEDW ( n ); s->bsBuff |= (v << (32 - s->bsLive - n)); s->bsLive += n; } /*---------------------------------------------------*/ static void bsPutUInt32 ( EState* s, UInt32 u ) { bsW ( s, 8, (u >> 24) & 0xffL ); bsW ( s, 8, (u >> 16) & 0xffL ); bsW ( s, 8, (u >> 8) & 0xffL ); bsW ( s, 8, u & 0xffL ); } /*---------------------------------------------------*/ static void bsPutUChar ( EState* s, UChar c ) { bsW( s, 8, (UInt32)c ); } /*---------------------------------------------------*/ /*--- The back end proper ---*/ /*---------------------------------------------------*/ /*---------------------------------------------------*/ static void makeMaps_e ( EState* s ) { Int32 i; s->nInUse = 0; for (i = 0; i < 256; i++) if (s->inUse[i]) { s->unseqToSeq[i] = s->nInUse; s->nInUse++; } } /*---------------------------------------------------*/ static void generateMTFValues ( EState* s ) { UChar yy[256]; Int32 i, j; Int32 zPend; Int32 wr; Int32 EOB; /* After sorting (eg, here), s->arr1 [ 0 .. s->nblock-1 ] holds sorted order, and ((UChar*)s->arr2) [ 0 .. s->nblock-1 ] holds the original block data. The first thing to do is generate the MTF values, and put them in ((UInt16*)s->arr1) [ 0 .. s->nblock-1 ]. Because there are strictly fewer or equal MTF values than block values, ptr values in this area are overwritten with MTF values only when they are no longer needed. The final compressed bitstream is generated into the area starting at (UChar*) (&((UChar*)s->arr2)[s->nblock]) These storage aliases are set up in bzCompressInit(), except for the last one, which is arranged in compressBlock(). */ UInt32* ptr = s->ptr; UChar* block = s->block; UInt16* mtfv = s->mtfv; makeMaps_e ( s ); EOB = s->nInUse+1; for (i = 0; i <= EOB; i++) s->mtfFreq[i] = 0; wr = 0; zPend = 0; for (i = 0; i < s->nInUse; i++) yy[i] = (UChar) i; for (i = 0; i < s->nblock; i++) { UChar ll_i; AssertD ( wr <= i, "generateMTFValues(1)" ); j = ptr[i]-1; if (j < 0) j += s->nblock; ll_i = s->unseqToSeq[block[j]]; AssertD ( ll_i < s->nInUse, "generateMTFValues(2a)" ); if (yy[0] == ll_i) { zPend++; } else { if (zPend > 0) { zPend--; while (True) { if (zPend & 1) { mtfv[wr] = BZ_RUNB; wr++; s->mtfFreq[BZ_RUNB]++; } else { mtfv[wr] = BZ_RUNA; wr++; s->mtfFreq[BZ_RUNA]++; } if (zPend < 2) break; zPend = (zPend - 2) / 2; }; zPend = 0; } { register UChar rtmp; register UChar* ryy_j; register UChar rll_i; rtmp = yy[1]; yy[1] = yy[0]; ryy_j = &(yy[1]); rll_i = ll_i; while ( rll_i != rtmp ) { register UChar rtmp2; ryy_j++; rtmp2 = rtmp; rtmp = *ryy_j; *ryy_j = rtmp2; }; yy[0] = rtmp; j = ryy_j - &(yy[0]); mtfv[wr] = j+1; wr++; s->mtfFreq[j+1]++; } } } if (zPend > 0) { zPend--; while (True) { if (zPend & 1) { mtfv[wr] = BZ_RUNB; wr++; s->mtfFreq[BZ_RUNB]++; } else { mtfv[wr] = BZ_RUNA; wr++; s->mtfFreq[BZ_RUNA]++; } if (zPend < 2) break; zPend = (zPend - 2) / 2; }; zPend = 0; } mtfv[wr] = EOB; wr++; s->mtfFreq[EOB]++; s->nMTF = wr; } /*---------------------------------------------------*/ #define BZ_LESSER_ICOST 0 #define BZ_GREATER_ICOST 15 static void sendMTFValues ( EState* s ) { Int32 v, t, i, j, gs, ge, totc, bt, bc, iter; Int32 nSelectors, alphaSize, minLen, maxLen, selCtr; Int32 nGroups, nBytes; /*-- UChar len [BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE]; is a global since the decoder also needs it. Int32 code[BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE]; Int32 rfreq[BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE]; are also globals only used in this proc. Made global to keep stack frame size small. --*/ UInt16 cost[BZ_N_GROUPS]; Int32 fave[BZ_N_GROUPS]; UInt16* mtfv = s->mtfv; if (s->verbosity >= 3) VPrintf3( " %d in block, %d after MTF & 1-2 coding, " "%d+2 syms in use\n", s->nblock, s->nMTF, s->nInUse ); alphaSize = s->nInUse+2; for (t = 0; t < BZ_N_GROUPS; t++) for (v = 0; v < alphaSize; v++) s->len[t][v] = BZ_GREATER_ICOST; /*--- Decide how many coding tables to use ---*/ AssertH ( s->nMTF > 0, 3001 ); if (s->nMTF < 200) nGroups = 2; else if (s->nMTF < 600) nGroups = 3; else if (s->nMTF < 1200) nGroups = 4; else if (s->nMTF < 2400) nGroups = 5; else nGroups = 6; /*--- Generate an initial set of coding tables ---*/ { Int32 nPart, remF, tFreq, aFreq; nPart = nGroups; remF = s->nMTF; gs = 0; while (nPart > 0) { tFreq = remF / nPart; ge = gs-1; aFreq = 0; while (aFreq < tFreq && ge < alphaSize-1) { ge++; aFreq += s->mtfFreq[ge]; } if (ge > gs && nPart != nGroups && nPart != 1 && ((nGroups-nPart) % 2 == 1)) { aFreq -= s->mtfFreq[ge]; ge--; } if (s->verbosity >= 3) VPrintf5( " initial group %d, [%d .. %d], " "has %d syms (%4.1f%%)\n", nPart, gs, ge, aFreq, (100.0 * (float)aFreq) / (float)(s->nMTF) ); for (v = 0; v < alphaSize; v++) if (v >= gs && v <= ge) s->len[nPart-1][v] = BZ_LESSER_ICOST; else s->len[nPart-1][v] = BZ_GREATER_ICOST; nPart--; gs = ge+1; remF -= aFreq; } } /*--- Iterate up to BZ_N_ITERS times to improve the tables. ---*/ for (iter = 0; iter < BZ_N_ITERS; iter++) { for (t = 0; t < nGroups; t++) fave[t] = 0; for (t = 0; t < nGroups; t++) for (v = 0; v < alphaSize; v++) s->rfreq[t][v] = 0; /*--- Set up an auxiliary length table which is used to fast-track the common case (nGroups == 6). ---*/ if (nGroups == 6) { for (v = 0; v < alphaSize; v++) { s->len_pack[v][0] = (s->len[1][v] << 16) | s->len[0][v]; s->len_pack[v][1] = (s->len[3][v] << 16) | s->len[2][v]; s->len_pack[v][2] = (s->len[5][v] << 16) | s->len[4][v]; } } nSelectors = 0; totc = 0; gs = 0; while (True) { /*--- Set group start & end marks. --*/ if (gs >= s->nMTF) break; ge = gs + BZ_G_SIZE - 1; if (ge >= s->nMTF) ge = s->nMTF-1; /*-- Calculate the cost of this group as coded by each of the coding tables. --*/ for (t = 0; t < nGroups; t++) cost[t] = 0; if (nGroups == 6 && 50 == ge-gs+1) { /*--- fast track the common case ---*/ register UInt32 cost01, cost23, cost45; register UInt16 icv; cost01 = cost23 = cost45 = 0; # define BZ_ITER(nn) \ icv = mtfv[gs+(nn)]; \ cost01 += s->len_pack[icv][0]; \ cost23 += s->len_pack[icv][1]; \ cost45 += s->len_pack[icv][2]; \ BZ_ITER(0); BZ_ITER(1); BZ_ITER(2); BZ_ITER(3); BZ_ITER(4); BZ_ITER(5); BZ_ITER(6); BZ_ITER(7); BZ_ITER(8); BZ_ITER(9); BZ_ITER(10); BZ_ITER(11); BZ_ITER(12); BZ_ITER(13); BZ_ITER(14); BZ_ITER(15); BZ_ITER(16); BZ_ITER(17); BZ_ITER(18); BZ_ITER(19); BZ_ITER(20); BZ_ITER(21); BZ_ITER(22); BZ_ITER(23); BZ_ITER(24); BZ_ITER(25); BZ_ITER(26); BZ_ITER(27); BZ_ITER(28); BZ_ITER(29); BZ_ITER(30); BZ_ITER(31); BZ_ITER(32); BZ_ITER(33); BZ_ITER(34); BZ_ITER(35); BZ_ITER(36); BZ_ITER(37); BZ_ITER(38); BZ_ITER(39); BZ_ITER(40); BZ_ITER(41); BZ_ITER(42); BZ_ITER(43); BZ_ITER(44); BZ_ITER(45); BZ_ITER(46); BZ_ITER(47); BZ_ITER(48); BZ_ITER(49); # undef BZ_ITER cost[0] = cost01 & 0xffff; cost[1] = cost01 >> 16; cost[2] = cost23 & 0xffff; cost[3] = cost23 >> 16; cost[4] = cost45 & 0xffff; cost[5] = cost45 >> 16; } else { /*--- slow version which correctly handles all situations ---*/ for (i = gs; i <= ge; i++) { UInt16 icv = mtfv[i]; for (t = 0; t < nGroups; t++) cost[t] += s->len[t][icv]; } } /*-- Find the coding table which is best for this group, and record its identity in the selector table. --*/ bc = 999999999; bt = -1; for (t = 0; t < nGroups; t++) if (cost[t] < bc) { bc = cost[t]; bt = t; }; totc += bc; fave[bt]++; s->selector[nSelectors] = bt; nSelectors++; /*-- Increment the symbol frequencies for the selected table. --*/ if (nGroups == 6 && 50 == ge-gs+1) { /*--- fast track the common case ---*/ # define BZ_ITUR(nn) s->rfreq[bt][ mtfv[gs+(nn)] ]++ BZ_ITUR(0); BZ_ITUR(1); BZ_ITUR(2); BZ_ITUR(3); BZ_ITUR(4); BZ_ITUR(5); BZ_ITUR(6); BZ_ITUR(7); BZ_ITUR(8); BZ_ITUR(9); BZ_ITUR(10); BZ_ITUR(11); BZ_ITUR(12); BZ_ITUR(13); BZ_ITUR(14); BZ_ITUR(15); BZ_ITUR(16); BZ_ITUR(17); BZ_ITUR(18); BZ_ITUR(19); BZ_ITUR(20); BZ_ITUR(21); BZ_ITUR(22); BZ_ITUR(23); BZ_ITUR(24); BZ_ITUR(25); BZ_ITUR(26); BZ_ITUR(27); BZ_ITUR(28); BZ_ITUR(29); BZ_ITUR(30); BZ_ITUR(31); BZ_ITUR(32); BZ_ITUR(33); BZ_ITUR(34); BZ_ITUR(35); BZ_ITUR(36); BZ_ITUR(37); BZ_ITUR(38); BZ_ITUR(39); BZ_ITUR(40); BZ_ITUR(41); BZ_ITUR(42); BZ_ITUR(43); BZ_ITUR(44); BZ_ITUR(45); BZ_ITUR(46); BZ_ITUR(47); BZ_ITUR(48); BZ_ITUR(49); # undef BZ_ITUR } else { /*--- slow version which correctly handles all situations ---*/ for (i = gs; i <= ge; i++) s->rfreq[bt][ mtfv[i] ]++; } gs = ge+1; } if (s->verbosity >= 3) { VPrintf2 ( " pass %d: size is %d, grp uses are ", iter+1, totc/8 ); for (t = 0; t < nGroups; t++) VPrintf1 ( "%d ", fave[t] ); VPrintf0 ( "\n" ); } /*-- Recompute the tables based on the accumulated frequencies. --*/ /* maxLen was changed from 20 to 17 in bzip2-1.0.3. See comment in huffman.c for details. */ for (t = 0; t < nGroups; t++) BZ2_hbMakeCodeLengths ( &(s->len[t][0]), &(s->rfreq[t][0]), alphaSize, 17 /*20*/ ); } AssertH( nGroups < 8, 3002 ); AssertH( nSelectors < 32768 && nSelectors <= (2 + (900000 / BZ_G_SIZE)), 3003 ); /*--- Compute MTF values for the selectors. ---*/ { UChar pos[BZ_N_GROUPS], ll_i, tmp2, tmp; for (i = 0; i < nGroups; i++) pos[i] = i; for (i = 0; i < nSelectors; i++) { ll_i = s->selector[i]; j = 0; tmp = pos[j]; while ( ll_i != tmp ) { j++; tmp2 = tmp; tmp = pos[j]; pos[j] = tmp2; }; pos[0] = tmp; s->selectorMtf[i] = j; } }; /*--- Assign actual codes for the tables. --*/ for (t = 0; t < nGroups; t++) { minLen = 32; maxLen = 0; for (i = 0; i < alphaSize; i++) { if (s->len[t][i] > maxLen) maxLen = s->len[t][i]; if (s->len[t][i] < minLen) minLen = s->len[t][i]; } AssertH ( !(maxLen > 17 /*20*/ ), 3004 ); AssertH ( !(minLen < 1), 3005 ); BZ2_hbAssignCodes ( &(s->code[t][0]), &(s->len[t][0]), minLen, maxLen, alphaSize ); } /*--- Transmit the mapping table. ---*/ { Bool inUse16[16]; for (i = 0; i < 16; i++) { inUse16[i] = False; for (j = 0; j < 16; j++) if (s->inUse[i * 16 + j]) inUse16[i] = True; } nBytes = s->numZ; for (i = 0; i < 16; i++) if (inUse16[i]) bsW(s,1,1); else bsW(s,1,0); for (i = 0; i < 16; i++) if (inUse16[i]) for (j = 0; j < 16; j++) { if (s->inUse[i * 16 + j]) bsW(s,1,1); else bsW(s,1,0); } if (s->verbosity >= 3) VPrintf1( " bytes: mapping %d, ", s->numZ-nBytes ); } /*--- Now the selectors. ---*/ nBytes = s->numZ; bsW ( s, 3, nGroups ); bsW ( s, 15, nSelectors ); for (i = 0; i < nSelectors; i++) { for (j = 0; j < s->selectorMtf[i]; j++) bsW(s,1,1); bsW(s,1,0); } if (s->verbosity >= 3) VPrintf1( "selectors %d, ", s->numZ-nBytes ); /*--- Now the coding tables. ---*/ nBytes = s->numZ; for (t = 0; t < nGroups; t++) { Int32 curr = s->len[t][0]; bsW ( s, 5, curr ); for (i = 0; i < alphaSize; i++) { while (curr < s->len[t][i]) { bsW(s,2,2); curr++; /* 10 */ }; while (curr > s->len[t][i]) { bsW(s,2,3); curr--; /* 11 */ }; bsW ( s, 1, 0 ); } } if (s->verbosity >= 3) VPrintf1 ( "code lengths %d, ", s->numZ-nBytes ); /*--- And finally, the block data proper ---*/ nBytes = s->numZ; selCtr = 0; gs = 0; while (True) { if (gs >= s->nMTF) break; ge = gs + BZ_G_SIZE - 1; if (ge >= s->nMTF) ge = s->nMTF-1; AssertH ( s->selector[selCtr] < nGroups, 3006 ); if (nGroups == 6 && 50 == ge-gs+1) { /*--- fast track the common case ---*/ UInt16 mtfv_i; UChar* s_len_sel_selCtr = &(s->len[s->selector[selCtr]][0]); Int32* s_code_sel_selCtr = &(s->code[s->selector[selCtr]][0]); # define BZ_ITAH(nn) \ mtfv_i = mtfv[gs+(nn)]; \ bsW ( s, \ s_len_sel_selCtr[mtfv_i], \ s_code_sel_selCtr[mtfv_i] ) BZ_ITAH(0); BZ_ITAH(1); BZ_ITAH(2); BZ_ITAH(3); BZ_ITAH(4); BZ_ITAH(5); BZ_ITAH(6); BZ_ITAH(7); BZ_ITAH(8); BZ_ITAH(9); BZ_ITAH(10); BZ_ITAH(11); BZ_ITAH(12); BZ_ITAH(13); BZ_ITAH(14); BZ_ITAH(15); BZ_ITAH(16); BZ_ITAH(17); BZ_ITAH(18); BZ_ITAH(19); BZ_ITAH(20); BZ_ITAH(21); BZ_ITAH(22); BZ_ITAH(23); BZ_ITAH(24); BZ_ITAH(25); BZ_ITAH(26); BZ_ITAH(27); BZ_ITAH(28); BZ_ITAH(29); BZ_ITAH(30); BZ_ITAH(31); BZ_ITAH(32); BZ_ITAH(33); BZ_ITAH(34); BZ_ITAH(35); BZ_ITAH(36); BZ_ITAH(37); BZ_ITAH(38); BZ_ITAH(39); BZ_ITAH(40); BZ_ITAH(41); BZ_ITAH(42); BZ_ITAH(43); BZ_ITAH(44); BZ_ITAH(45); BZ_ITAH(46); BZ_ITAH(47); BZ_ITAH(48); BZ_ITAH(49); # undef BZ_ITAH } else { /*--- slow version which correctly handles all situations ---*/ for (i = gs; i <= ge; i++) { bsW ( s, s->len [s->selector[selCtr]] [mtfv[i]], s->code [s->selector[selCtr]] [mtfv[i]] ); } } gs = ge+1; selCtr++; } AssertH( selCtr == nSelectors, 3007 ); if (s->verbosity >= 3) VPrintf1( "codes %d\n", s->numZ-nBytes ); } /*---------------------------------------------------*/ void BZ2_compressBlock ( EState* s, Bool is_last_block ) { if (s->nblock > 0) { BZ_FINALISE_CRC ( s->blockCRC ); s->combinedCRC = (s->combinedCRC << 1) | (s->combinedCRC >> 31); s->combinedCRC ^= s->blockCRC; if (s->blockNo > 1) s->numZ = 0; if (s->verbosity >= 2) VPrintf4( " block %d: crc = 0x%08x, " "combined CRC = 0x%08x, size = %d\n", s->blockNo, s->blockCRC, s->combinedCRC, s->nblock ); BZ2_blockSort ( s ); } s->zbits = (UChar*) (&((UChar*)s->arr2)[s->nblock]); /*-- If this is the first block, create the stream header. --*/ if (s->blockNo == 1) { BZ2_bsInitWrite ( s ); bsPutUChar ( s, BZ_HDR_B ); bsPutUChar ( s, BZ_HDR_Z ); bsPutUChar ( s, BZ_HDR_h ); bsPutUChar ( s, (UChar)(BZ_HDR_0 + s->blockSize100k) ); } if (s->nblock > 0) { bsPutUChar ( s, 0x31 ); bsPutUChar ( s, 0x41 ); bsPutUChar ( s, 0x59 ); bsPutUChar ( s, 0x26 ); bsPutUChar ( s, 0x53 ); bsPutUChar ( s, 0x59 ); /*-- Now the block's CRC, so it is in a known place. --*/ bsPutUInt32 ( s, s->blockCRC ); /*-- Now a single bit indicating (non-)randomisation. As of version 0.9.5, we use a better sorting algorithm which makes randomisation unnecessary. So always set the randomised bit to 'no'. Of course, the decoder still needs to be able to handle randomised blocks so as to maintain backwards compatibility with older versions of bzip2. --*/ bsW(s,1,0); bsW ( s, 24, s->origPtr ); generateMTFValues ( s ); sendMTFValues ( s ); } /*-- If this is the last block, add the stream trailer. --*/ if (is_last_block) { bsPutUChar ( s, 0x17 ); bsPutUChar ( s, 0x72 ); bsPutUChar ( s, 0x45 ); bsPutUChar ( s, 0x38 ); bsPutUChar ( s, 0x50 ); bsPutUChar ( s, 0x90 ); bsPutUInt32 ( s, s->combinedCRC ); if (s->verbosity >= 2) VPrintf1( " final combined CRC = 0x%08x\n ", s->combinedCRC ); bsFinishWrite ( s ); } } /*-------------------------------------------------------------*/ /*--- end compress.c ---*/ /*-------------------------------------------------------------*/