/rust/registry/src/index.crates.io-1949cf8c6b5b557f/bzip2-sys-0.1.13+1.0.8/bzip2-1.0.8/decompress.c

Source

/*-------------------------------------------------------------*/
/*--- Decompression machinery                               ---*/
/*---                                          decompress.c ---*/
/*-------------------------------------------------------------*/

/* ------------------------------------------------------------------
   This file is part of bzip2/libbzip2, a program and library for
   lossless, block-sorting data compression.

   bzip2/libbzip2 version 1.0.8 of 13 July 2019
   Copyright (C) 1996-2019 Julian Seward <jseward@acm.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.
   ------------------------------------------------------------------ */


#include "bzlib_private.h"


/*---------------------------------------------------*/
static
void makeMaps_d ( DState* s )
{
   Int32 i;
   s->nInUse = 0;
   for (i = 0; i < 256; i++)
      if (s->inUse[i]) {
         s->seqToUnseq[s->nInUse] = i;
         s->nInUse++;
      }
}


/*---------------------------------------------------*/
#define RETURN(rrr)                               \
   { retVal = rrr; goto save_state_and_return; };

#define GET_BITS(lll,vvv,nnn)                     \
   case lll: s->state = lll;                      \
   while (True) {                                 \
      if (s->bsLive >= nnn) {                     \
         UInt32 v;                                \
         v = (s->bsBuff >>                        \
             (s->bsLive-nnn)) & ((1 << nnn)-1);   \
         s->bsLive -= nnn;                        \
         vvv = v;                                 \
         break;                                   \
      }                                           \
      if (s->strm->avail_in == 0) RETURN(BZ_OK);  \
      s->bsBuff                                   \
         = (s->bsBuff << 8) |                     \
           ((UInt32)                              \
              (*((UChar*)(s->strm->next_in))));   \
      s->bsLive += 8;                             \
      s->strm->next_in++;                         \
      s->strm->avail_in--;                        \
      s->strm->total_in_lo32++;                   \
      if (s->strm->total_in_lo32 == 0)            \
         s->strm->total_in_hi32++;                \
   }

#define GET_UCHAR(lll,uuu)                        \
   GET_BITS(lll,uuu,8)

#define GET_BIT(lll,uuu)                          \
   GET_BITS(lll,uuu,1)

/*---------------------------------------------------*/
#define GET_MTF_VAL(label1,label2,lval)           \
{                                                 \
   if (groupPos == 0) {                           \
      groupNo++;                                  \
      if (groupNo >= nSelectors)                  \
         RETURN(BZ_DATA_ERROR);                   \
      groupPos = BZ_G_SIZE;                       \
      gSel = s->selector[groupNo];                \
      gMinlen = s->minLens[gSel];                 \
      gLimit = &(s->limit[gSel][0]);              \
      gPerm = &(s->perm[gSel][0]);                \
      gBase = &(s->base[gSel][0]);                \
   }                                              \
   groupPos--;                                    \
   zn = gMinlen;                                  \
   GET_BITS(label1, zvec, zn);                    \
   while (1) {                                    \
      if (zn > 20 /* the longest code */)         \
         RETURN(BZ_DATA_ERROR);                   \
      if (zvec <= gLimit[zn]) break;              \
      zn++;                                       \
      GET_BIT(label2, zj);                        \
      zvec = (zvec << 1) | zj;                    \
   };                                             \
   if (zvec - gBase[zn] < 0                       \
       || zvec - gBase[zn] >= BZ_MAX_ALPHA_SIZE)  \
      RETURN(BZ_DATA_ERROR);                      \
   lval = gPerm[zvec - gBase[zn]];                \
}


/*---------------------------------------------------*/
Int32 BZ2_decompress ( DState* s )
{
   UChar      uc;
   Int32      retVal;
   Int32      minLen, maxLen;
   bz_stream* strm = s->strm;

   /* stuff that needs to be saved/restored */
   Int32  i;
   Int32  j;
   Int32  t;
   Int32  alphaSize;
   Int32  nGroups;
   Int32  nSelectors;
   Int32  EOB;
   Int32  groupNo;
   Int32  groupPos;
   Int32  nextSym;
   Int32  nblockMAX;
   Int32  nblock;
   Int32  es;
   Int32  N;
   Int32  curr;
   Int32  zt;
   Int32  zn; 
   Int32  zvec;
   Int32  zj;
   Int32  gSel;
   Int32  gMinlen;
   Int32* gLimit;
   Int32* gBase;
   Int32* gPerm;

   if (s->state == BZ_X_MAGIC_1) {
      /*initialise the save area*/
      s->save_i           = 0;
      s->save_j           = 0;
      s->save_t           = 0;
      s->save_alphaSize   = 0;
      s->save_nGroups     = 0;
      s->save_nSelectors  = 0;
      s->save_EOB         = 0;
      s->save_groupNo     = 0;
      s->save_groupPos    = 0;
      s->save_nextSym     = 0;
      s->save_nblockMAX   = 0;
      s->save_nblock      = 0;
      s->save_es          = 0;
      s->save_N           = 0;
      s->save_curr        = 0;
      s->save_zt          = 0;
      s->save_zn          = 0;
      s->save_zvec        = 0;
      s->save_zj          = 0;
      s->save_gSel        = 0;
      s->save_gMinlen     = 0;
      s->save_gLimit      = NULL;
      s->save_gBase       = NULL;
      s->save_gPerm       = NULL;
   }

   /*restore from the save area*/
   i           = s->save_i;
   j           = s->save_j;
   t           = s->save_t;
   alphaSize   = s->save_alphaSize;
   nGroups     = s->save_nGroups;
   nSelectors  = s->save_nSelectors;
   EOB         = s->save_EOB;
   groupNo     = s->save_groupNo;
   groupPos    = s->save_groupPos;
   nextSym     = s->save_nextSym;
   nblockMAX   = s->save_nblockMAX;
   nblock      = s->save_nblock;
   es          = s->save_es;
   N           = s->save_N;
   curr        = s->save_curr;
   zt          = s->save_zt;
   zn          = s->save_zn; 
   zvec        = s->save_zvec;
   zj          = s->save_zj;
   gSel        = s->save_gSel;
   gMinlen     = s->save_gMinlen;
   gLimit      = s->save_gLimit;
   gBase       = s->save_gBase;
   gPerm       = s->save_gPerm;

   retVal = BZ_OK;

   switch (s->state) {

      GET_UCHAR(BZ_X_MAGIC_1, uc);
      if (uc != BZ_HDR_B) RETURN(BZ_DATA_ERROR_MAGIC);

      GET_UCHAR(BZ_X_MAGIC_2, uc);
      if (uc != BZ_HDR_Z) RETURN(BZ_DATA_ERROR_MAGIC);

      GET_UCHAR(BZ_X_MAGIC_3, uc)
      if (uc != BZ_HDR_h) RETURN(BZ_DATA_ERROR_MAGIC);

      GET_BITS(BZ_X_MAGIC_4, s->blockSize100k, 8)
      if (s->blockSize100k < (BZ_HDR_0 + 1) || 
          s->blockSize100k > (BZ_HDR_0 + 9)) RETURN(BZ_DATA_ERROR_MAGIC);
      s->blockSize100k -= BZ_HDR_0;

      if (s->smallDecompress) {
         s->ll16 = BZALLOC( s->blockSize100k * 100000 * sizeof(UInt16) );
         s->ll4  = BZALLOC( 
                      ((1 + s->blockSize100k * 100000) >> 1) * sizeof(UChar) 
                   );
         if (s->ll16 == NULL || s->ll4 == NULL) RETURN(BZ_MEM_ERROR);
      } else {
         s->tt  = BZALLOC( s->blockSize100k * 100000 * sizeof(Int32) );
         if (s->tt == NULL) RETURN(BZ_MEM_ERROR);
      }

      GET_UCHAR(BZ_X_BLKHDR_1, uc);

      if (uc == 0x17) goto endhdr_2;
      if (uc != 0x31) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_BLKHDR_2, uc);
      if (uc != 0x41) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_BLKHDR_3, uc);
      if (uc != 0x59) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_BLKHDR_4, uc);
      if (uc != 0x26) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_BLKHDR_5, uc);
      if (uc != 0x53) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_BLKHDR_6, uc);
      if (uc != 0x59) RETURN(BZ_DATA_ERROR);

      s->currBlockNo++;
      if (s->verbosity >= 2)
         VPrintf1 ( "\n    [%d: huff+mtf ", s->currBlockNo );
 
      s->storedBlockCRC = 0;
      GET_UCHAR(BZ_X_BCRC_1, uc);
      s->storedBlockCRC = (s->storedBlockCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_BCRC_2, uc);
      s->storedBlockCRC = (s->storedBlockCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_BCRC_3, uc);
      s->storedBlockCRC = (s->storedBlockCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_BCRC_4, uc);
      s->storedBlockCRC = (s->storedBlockCRC << 8) | ((UInt32)uc);

      GET_BITS(BZ_X_RANDBIT, s->blockRandomised, 1);

      s->origPtr = 0;
      GET_UCHAR(BZ_X_ORIGPTR_1, uc);
      s->origPtr = (s->origPtr << 8) | ((Int32)uc);
      GET_UCHAR(BZ_X_ORIGPTR_2, uc);
      s->origPtr = (s->origPtr << 8) | ((Int32)uc);
      GET_UCHAR(BZ_X_ORIGPTR_3, uc);
      s->origPtr = (s->origPtr << 8) | ((Int32)uc);

      if (s->origPtr < 0)
         RETURN(BZ_DATA_ERROR);
      if (s->origPtr > 10 + 100000*s->blockSize100k) 
         RETURN(BZ_DATA_ERROR);

      /*--- Receive the mapping table ---*/
      for (i = 0; i < 16; i++) {
         GET_BIT(BZ_X_MAPPING_1, uc);
         if (uc == 1) 
            s->inUse16[i] = True; else 
            s->inUse16[i] = False;
      }

      for (i = 0; i < 256; i++) s->inUse[i] = False;

      for (i = 0; i < 16; i++)
         if (s->inUse16[i])
            for (j = 0; j < 16; j++) {
               GET_BIT(BZ_X_MAPPING_2, uc);
               if (uc == 1) s->inUse[i * 16 + j] = True;
            }
      makeMaps_d ( s );
      if (s->nInUse == 0) RETURN(BZ_DATA_ERROR);
      alphaSize = s->nInUse+2;

      /*--- Now the selectors ---*/
      GET_BITS(BZ_X_SELECTOR_1, nGroups, 3);
      if (nGroups < 2 || nGroups > BZ_N_GROUPS) RETURN(BZ_DATA_ERROR);
      GET_BITS(BZ_X_SELECTOR_2, nSelectors, 15);
      if (nSelectors < 1) RETURN(BZ_DATA_ERROR);
      for (i = 0; i < nSelectors; i++) {
         j = 0;
         while (True) {
            GET_BIT(BZ_X_SELECTOR_3, uc);
            if (uc == 0) break;
            j++;
            if (j >= nGroups) RETURN(BZ_DATA_ERROR);
         }
         /* Having more than BZ_MAX_SELECTORS doesn't make much sense
            since they will never be used, but some implementations might
            "round up" the number of selectors, so just ignore those. */
         if (i < BZ_MAX_SELECTORS)
           s->selectorMtf[i] = j;
      }
      if (nSelectors > BZ_MAX_SELECTORS)
        nSelectors = BZ_MAX_SELECTORS;

      /*--- Undo the MTF values for the selectors. ---*/
      {
         UChar pos[BZ_N_GROUPS], tmp, v;
         for (v = 0; v < nGroups; v++) pos[v] = v;
   
         for (i = 0; i < nSelectors; i++) {
            v = s->selectorMtf[i];
            tmp = pos[v];
            while (v > 0) { pos[v] = pos[v-1]; v--; }
            pos[0] = tmp;
            s->selector[i] = tmp;
         }
      }

      /*--- Now the coding tables ---*/
      for (t = 0; t < nGroups; t++) {
         GET_BITS(BZ_X_CODING_1, curr, 5);
         for (i = 0; i < alphaSize; i++) {
            while (True) {
               if (curr < 1 || curr > 20) RETURN(BZ_DATA_ERROR);
               GET_BIT(BZ_X_CODING_2, uc);
               if (uc == 0) break;
               GET_BIT(BZ_X_CODING_3, uc);
               if (uc == 0) curr++; else curr--;
            }
            s->len[t][i] = curr;
         }
      }

      /*--- Create the Huffman decoding 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];
         }
         BZ2_hbCreateDecodeTables ( 
            &(s->limit[t][0]), 
            &(s->base[t][0]), 
            &(s->perm[t][0]), 
            &(s->len[t][0]),
            minLen, maxLen, alphaSize
         );
         s->minLens[t] = minLen;
      }

      /*--- Now the MTF values ---*/

      EOB      = s->nInUse+1;
      nblockMAX = 100000 * s->blockSize100k;
      groupNo  = -1;
      groupPos = 0;

      for (i = 0; i <= 255; i++) s->unzftab[i] = 0;

      /*-- MTF init --*/
      {
         Int32 ii, jj, kk;
         kk = MTFA_SIZE-1;
         for (ii = 256 / MTFL_SIZE - 1; ii >= 0; ii--) {
            for (jj = MTFL_SIZE-1; jj >= 0; jj--) {
               s->mtfa[kk] = (UChar)(ii * MTFL_SIZE + jj);
               kk--;
            }
            s->mtfbase[ii] = kk + 1;
         }
      }
      /*-- end MTF init --*/

      nblock = 0;
      GET_MTF_VAL(BZ_X_MTF_1, BZ_X_MTF_2, nextSym);

      while (True) {

         if (nextSym == EOB) break;

         if (nextSym == BZ_RUNA || nextSym == BZ_RUNB) {

            es = -1;
            N = 1;
            do {
               /* Check that N doesn't get too big, so that es doesn't
                  go negative.  The maximum value that can be
                  RUNA/RUNB encoded is equal to the block size (post
                  the initial RLE), viz, 900k, so bounding N at 2
                  million should guard against overflow without
                  rejecting any legitimate inputs. */
               if (N >= 2*1024*1024) RETURN(BZ_DATA_ERROR);
               if (nextSym == BZ_RUNA) es = es + (0+1) * N; else
               if (nextSym == BZ_RUNB) es = es + (1+1) * N;
               N = N * 2;
               GET_MTF_VAL(BZ_X_MTF_3, BZ_X_MTF_4, nextSym);
            }
               while (nextSym == BZ_RUNA || nextSym == BZ_RUNB);

            es++;
            uc = s->seqToUnseq[ s->mtfa[s->mtfbase[0]] ];
            s->unzftab[uc] += es;

            if (s->smallDecompress)
               while (es > 0) {
                  if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);
                  s->ll16[nblock] = (UInt16)uc;
                  nblock++;
                  es--;
               }
            else
               while (es > 0) {
                  if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);
                  s->tt[nblock] = (UInt32)uc;
                  nblock++;
                  es--;
               };

            continue;

         } else {

            if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);

            /*-- uc = MTF ( nextSym-1 ) --*/
            {
               Int32 ii, jj, kk, pp, lno, off;
               UInt32 nn;
               nn = (UInt32)(nextSym - 1);

               if (nn < MTFL_SIZE) {
                  /* avoid general-case expense */
                  pp = s->mtfbase[0];
                  uc = s->mtfa[pp+nn];
                  while (nn > 3) {
                     Int32 z = pp+nn;
                     s->mtfa[(z)  ] = s->mtfa[(z)-1];
                     s->mtfa[(z)-1] = s->mtfa[(z)-2];
                     s->mtfa[(z)-2] = s->mtfa[(z)-3];
                     s->mtfa[(z)-3] = s->mtfa[(z)-4];
                     nn -= 4;
                  }
                  while (nn > 0) { 
                     s->mtfa[(pp+nn)] = s->mtfa[(pp+nn)-1]; nn--; 
                  };
                  s->mtfa[pp] = uc;
               } else { 
                  /* general case */
                  lno = nn / MTFL_SIZE;
                  off = nn % MTFL_SIZE;
                  pp = s->mtfbase[lno] + off;
                  uc = s->mtfa[pp];
                  while (pp > s->mtfbase[lno]) { 
                     s->mtfa[pp] = s->mtfa[pp-1]; pp--; 
                  };
                  s->mtfbase[lno]++;
                  while (lno > 0) {
                     s->mtfbase[lno]--;
                     s->mtfa[s->mtfbase[lno]] 
                        = s->mtfa[s->mtfbase[lno-1] + MTFL_SIZE - 1];
                     lno--;
                  }
                  s->mtfbase[0]--;
                  s->mtfa[s->mtfbase[0]] = uc;
                  if (s->mtfbase[0] == 0) {
                     kk = MTFA_SIZE-1;
                     for (ii = 256 / MTFL_SIZE-1; ii >= 0; ii--) {
                        for (jj = MTFL_SIZE-1; jj >= 0; jj--) {
                           s->mtfa[kk] = s->mtfa[s->mtfbase[ii] + jj];
                           kk--;
                        }
                        s->mtfbase[ii] = kk + 1;
                     }
                  }
               }
            }
            /*-- end uc = MTF ( nextSym-1 ) --*/

            s->unzftab[s->seqToUnseq[uc]]++;
            if (s->smallDecompress)
               s->ll16[nblock] = (UInt16)(s->seqToUnseq[uc]); else
               s->tt[nblock]   = (UInt32)(s->seqToUnseq[uc]);
            nblock++;

            GET_MTF_VAL(BZ_X_MTF_5, BZ_X_MTF_6, nextSym);
            continue;
         }
      }

      /* Now we know what nblock is, we can do a better sanity
         check on s->origPtr.
      */
      if (s->origPtr < 0 || s->origPtr >= nblock)
         RETURN(BZ_DATA_ERROR);

      /*-- Set up cftab to facilitate generation of T^(-1) --*/
      /* Check: unzftab entries in range. */
      for (i = 0; i <= 255; i++) {
         if (s->unzftab[i] < 0 || s->unzftab[i] > nblock)
            RETURN(BZ_DATA_ERROR);
      }
      /* Actually generate cftab. */
      s->cftab[0] = 0;
      for (i = 1; i <= 256; i++) s->cftab[i] = s->unzftab[i-1];
      for (i = 1; i <= 256; i++) s->cftab[i] += s->cftab[i-1];
      /* Check: cftab entries in range. */
      for (i = 0; i <= 256; i++) {
         if (s->cftab[i] < 0 || s->cftab[i] > nblock) {
            /* s->cftab[i] can legitimately be == nblock */
            RETURN(BZ_DATA_ERROR);
         }
      }
      /* Check: cftab entries non-descending. */
      for (i = 1; i <= 256; i++) {
         if (s->cftab[i-1] > s->cftab[i]) {
            RETURN(BZ_DATA_ERROR);
         }
      }

      s->state_out_len = 0;
      s->state_out_ch  = 0;
      BZ_INITIALISE_CRC ( s->calculatedBlockCRC );
      s->state = BZ_X_OUTPUT;
      if (s->verbosity >= 2) VPrintf0 ( "rt+rld" );

      if (s->smallDecompress) {

         /*-- Make a copy of cftab, used in generation of T --*/
         for (i = 0; i <= 256; i++) s->cftabCopy[i] = s->cftab[i];

         /*-- compute the T vector --*/
         for (i = 0; i < nblock; i++) {
            uc = (UChar)(s->ll16[i]);
            SET_LL(i, s->cftabCopy[uc]);
            s->cftabCopy[uc]++;
         }

         /*-- Compute T^(-1) by pointer reversal on T --*/
         i = s->origPtr;
         j = GET_LL(i);
         do {
            Int32 tmp = GET_LL(j);
            SET_LL(j, i);
            i = j;
            j = tmp;
         }
            while (i != s->origPtr);

         s->tPos = s->origPtr;
         s->nblock_used = 0;
         if (s->blockRandomised) {
            BZ_RAND_INIT_MASK;
            BZ_GET_SMALL(s->k0); s->nblock_used++;
            BZ_RAND_UPD_MASK; s->k0 ^= BZ_RAND_MASK; 
         } else {
            BZ_GET_SMALL(s->k0); s->nblock_used++;
         }

      } else {

         /*-- compute the T^(-1) vector --*/
         for (i = 0; i < nblock; i++) {
            uc = (UChar)(s->tt[i] & 0xff);
            s->tt[s->cftab[uc]] |= (i << 8);
            s->cftab[uc]++;
         }

         s->tPos = s->tt[s->origPtr] >> 8;
         s->nblock_used = 0;
         if (s->blockRandomised) {
            BZ_RAND_INIT_MASK;
            BZ_GET_FAST(s->k0); s->nblock_used++;
            BZ_RAND_UPD_MASK; s->k0 ^= BZ_RAND_MASK; 
         } else {
            BZ_GET_FAST(s->k0); s->nblock_used++;
         }

      }

      RETURN(BZ_OK);



    endhdr_2:

      GET_UCHAR(BZ_X_ENDHDR_2, uc);
      if (uc != 0x72) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_ENDHDR_3, uc);
      if (uc != 0x45) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_ENDHDR_4, uc);
      if (uc != 0x38) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_ENDHDR_5, uc);
      if (uc != 0x50) RETURN(BZ_DATA_ERROR);
      GET_UCHAR(BZ_X_ENDHDR_6, uc);
      if (uc != 0x90) RETURN(BZ_DATA_ERROR);

      s->storedCombinedCRC = 0;
      GET_UCHAR(BZ_X_CCRC_1, uc);
      s->storedCombinedCRC = (s->storedCombinedCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_CCRC_2, uc);
      s->storedCombinedCRC = (s->storedCombinedCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_CCRC_3, uc);
      s->storedCombinedCRC = (s->storedCombinedCRC << 8) | ((UInt32)uc);
      GET_UCHAR(BZ_X_CCRC_4, uc);
      s->storedCombinedCRC = (s->storedCombinedCRC << 8) | ((UInt32)uc);

      s->state = BZ_X_IDLE;
      RETURN(BZ_STREAM_END);

      default: AssertH ( False, 4001 );
   }

   AssertH ( False, 4002 );

   save_state_and_return:

   s->save_i           = i;
   s->save_j           = j;
   s->save_t           = t;
   s->save_alphaSize   = alphaSize;
   s->save_nGroups     = nGroups;
   s->save_nSelectors  = nSelectors;
   s->save_EOB         = EOB;
   s->save_groupNo     = groupNo;
   s->save_groupPos    = groupPos;
   s->save_nextSym     = nextSym;
   s->save_nblockMAX   = nblockMAX;
   s->save_nblock      = nblock;
   s->save_es          = es;
   s->save_N           = N;
   s->save_curr        = curr;
   s->save_zt          = zt;
   s->save_zn          = zn;
   s->save_zvec        = zvec;
   s->save_zj          = zj;
   s->save_gSel        = gSel;
   s->save_gMinlen     = gMinlen;
   s->save_gLimit      = gLimit;
   s->save_gBase       = gBase;
   s->save_gPerm       = gPerm;

   return retVal;   
}


/*-------------------------------------------------------------*/
/*--- end                                      decompress.c ---*/
/*-------------------------------------------------------------*/

Coverage Report

Created: 2026-01-10 06:32

Line	Count	Source
1
2		/-------------------------------------------------------------/
3		/--- Decompression machinery ---/
4		/--- decompress.c ---/
5		/-------------------------------------------------------------/
6
7		/* ------------------------------------------------------------------
8		This file is part of bzip2/libbzip2, a program and library for
9		lossless, block-sorting data compression.
10
11		bzip2/libbzip2 version 1.0.8 of 13 July 2019
12		Copyright (C) 1996-2019 Julian Seward <jseward@acm.org>
13
14		Please read the WARNING, DISCLAIMER and PATENTS sections in the
15		README file.
16
17		This program is released under the terms of the license contained
18		in the file LICENSE.
19		------------------------------------------------------------------ */
20
21
22		#include "bzlib_private.h"
23
24
25		/---------------------------------------------------/
26		static
27		void makeMaps_d ( DState* s )
28	5.63k	{
29	5.63k	Int32 i;
30	5.63k	s->nInUse = 0;
31	1.44M	for (i = 0; i < 256; i++)
32	1.44M	if (s->inUse[i]) {
33	44.1k	s->seqToUnseq[s->nInUse] = i;
34	44.1k	s->nInUse++;
35	44.1k	}
36	5.63k	}
37
38
39		/---------------------------------------------------/
40		#define RETURN(rrr) \
41	5.26M	{ retVal = rrr; goto save_state_and_return; };
42
43		#define GET_BITS(lll,vvv,nnn) \
44	6.22M	case lll: s->state = lll; \
45	7.20M	while (True) { \
46	7.20M	if (s->bsLive >= nnn) { \
47	6.22M	UInt32 v; \
48	6.22M	v = (s->bsBuff >> \
49	6.22M	(s->bsLive-nnn)) & ((1 << nnn)-1); \
50	6.22M	s->bsLive -= nnn; \
51	6.22M	vvv = v; \
52	6.22M	break; \
53	6.22M	} \
54	7.20M	if (s->strm->avail_in == 0) RETURN(BZ_OK); \
55	979k	s->bsBuff \
56	979k	= (s->bsBuff << 8) \| \
57	979k	((UInt32) \
58	979k	(((UChar)(s->strm->next_in)))); \
59	979k	s->bsLive += 8; \
60	979k	s->strm->next_in++; \
61	979k	s->strm->avail_in--; \
62	979k	s->strm->total_in_lo32++; \
63	979k	if (s->strm->total_in_lo32 == 0) \
64	979k	s->strm->total_in_hi32++; \
65	979k	}
66
67		#define GET_UCHAR(lll,uuu) \
68	102k	GET_BITS(lll,uuu,8)
69
70		#define GET_BIT(lll,uuu) \
71	5.73M	GET_BITS(lll,uuu,1)
72
73		/---------------------------------------------------/
74	345k	#define GET_MTF_VAL(label1,label2,lval) \
75	345k	{ \
76	345k	if (groupPos == 0) { \
77	8.40k	groupNo++; \
78	8.40k	if (groupNo >= nSelectors) \
79	8.40k	RETURN(BZ_DATA_ERROR); \
80	8.39k	groupPos = BZ_G_SIZE; \
81	8.39k	gSel = s->selector[groupNo]; \
82	8.39k	gMinlen = s->minLens[gSel]; \
83	8.39k	gLimit = &(s->limit[gSel][0]); \
84	8.39k	gPerm = &(s->perm[gSel][0]); \
85	8.39k	gBase = &(s->base[gSel][0]); \
86	8.39k	} \
87	345k	groupPos--; \
88	345k	zn = gMinlen; \
89	345k	GET_BITS(label1, zvec, zn); \
90	611k	while (1) { \
91	611k	if (zn > 20 /* the longest code */) \
92	611k	RETURN(BZ_DATA_ERROR); \
93	610k	if (zvec <= gLimit[zn]) break; \
94	610k	zn++; \
95	265k	GET_BIT(label2, zj); \
96	265k	zvec = (zvec << 1) \| zj; \
97	345k	}; \
98	345k	if (zvec - gBase[zn] < 0 \
99	345k	\|\| zvec - gBase[zn] >= BZ_MAX_ALPHA_SIZE) \
100	345k	RETURN(BZ_DATA_ERROR); \
101	345k	lval = gPerm[zvec - gBase[zn]]; \
102	345k	}
103
104
105		/---------------------------------------------------/
106		Int32 BZ2_decompress ( DState* s )
107	7.46k	{
108	7.46k	UChar uc;
109	7.46k	Int32 retVal;
110	7.46k	Int32 minLen, maxLen;
111	7.46k	bz_stream* strm = s->strm;
112
113		/* stuff that needs to be saved/restored */
114	7.46k	Int32 i;
115	7.46k	Int32 j;
116	7.46k	Int32 t;
117	7.46k	Int32 alphaSize;
118	7.46k	Int32 nGroups;
119	7.46k	Int32 nSelectors;
120	7.46k	Int32 EOB;
121	7.46k	Int32 groupNo;
122	7.46k	Int32 groupPos;
123	7.46k	Int32 nextSym;
124	7.46k	Int32 nblockMAX;
125	7.46k	Int32 nblock;
126	7.46k	Int32 es;
127	7.46k	Int32 N;
128	7.46k	Int32 curr;
129	7.46k	Int32 zt;
130	7.46k	Int32 zn;
131	7.46k	Int32 zvec;
132	7.46k	Int32 zj;
133	7.46k	Int32 gSel;
134	7.46k	Int32 gMinlen;
135	7.46k	Int32* gLimit;
136	7.46k	Int32* gBase;
137	7.46k	Int32* gPerm;
138
139	7.46k	if (s->state == BZ_X_MAGIC_1) {
140		/initialise the save area/
141	6.36k	s->save_i = 0;
142	6.36k	s->save_j = 0;
143	6.36k	s->save_t = 0;
144	6.36k	s->save_alphaSize = 0;
145	6.36k	s->save_nGroups = 0;
146	6.36k	s->save_nSelectors = 0;
147	6.36k	s->save_EOB = 0;
148	6.36k	s->save_groupNo = 0;
149	6.36k	s->save_groupPos = 0;
150	6.36k	s->save_nextSym = 0;
151	6.36k	s->save_nblockMAX = 0;
152	6.36k	s->save_nblock = 0;
153	6.36k	s->save_es = 0;
154	6.36k	s->save_N = 0;
155	6.36k	s->save_curr = 0;
156	6.36k	s->save_zt = 0;
157	6.36k	s->save_zn = 0;
158	6.36k	s->save_zvec = 0;
159	6.36k	s->save_zj = 0;
160	6.36k	s->save_gSel = 0;
161	6.36k	s->save_gMinlen = 0;
162	6.36k	s->save_gLimit = NULL;
163	6.36k	s->save_gBase = NULL;
164	6.36k	s->save_gPerm = NULL;
165	6.36k	}
166
167		/restore from the save area/
168	7.46k	i = s->save_i;
169	7.46k	j = s->save_j;
170	7.46k	t = s->save_t;
171	7.46k	alphaSize = s->save_alphaSize;
172	7.46k	nGroups = s->save_nGroups;
173	7.46k	nSelectors = s->save_nSelectors;
174	7.46k	EOB = s->save_EOB;
175	7.46k	groupNo = s->save_groupNo;
176	7.46k	groupPos = s->save_groupPos;
177	7.46k	nextSym = s->save_nextSym;
178	7.46k	nblockMAX = s->save_nblockMAX;
179	7.46k	nblock = s->save_nblock;
180	7.46k	es = s->save_es;
181	7.46k	N = s->save_N;
182	7.46k	curr = s->save_curr;
183	7.46k	zt = s->save_zt;
184	7.46k	zn = s->save_zn;
185	7.46k	zvec = s->save_zvec;
186	7.46k	zj = s->save_zj;
187	7.46k	gSel = s->save_gSel;
188	7.46k	gMinlen = s->save_gMinlen;
189	7.46k	gLimit = s->save_gLimit;
190	7.46k	gBase = s->save_gBase;
191	7.46k	gPerm = s->save_gPerm;
192
193	7.46k	retVal = BZ_OK;
194
195	7.46k	switch (s->state) {
196
197	6.36k	GET_UCHAR(BZ_X_MAGIC_1, uc);
198	6.36k	if (uc != BZ_HDR_B) RETURN(BZ_DATA_ERROR_MAGIC);
199
200	6.36k	GET_UCHAR(BZ_X_MAGIC_2, uc);
201	6.36k	if (uc != BZ_HDR_Z) RETURN(BZ_DATA_ERROR_MAGIC);
202
203	5.68k	GET_UCHAR(BZ_X_MAGIC_3, uc)
204	5.68k	if (uc != BZ_HDR_h) RETURN(BZ_DATA_ERROR_MAGIC);
205
206	5.68k	GET_BITS(BZ_X_MAGIC_4, s->blockSize100k, 8)
207	5.68k	if (s->blockSize100k < (BZ_HDR_0 + 1) \|\|
208	5.68k	s->blockSize100k > (BZ_HDR_0 + 9)) RETURN(BZ_DATA_ERROR_MAGIC);
209	5.68k	s->blockSize100k -= BZ_HDR_0;
210
211	5.68k	if (s->smallDecompress) {
212	0	s->ll16 = BZALLOC( s->blockSize100k * 100000 * sizeof(UInt16) );
213	0	s->ll4 = BZALLOC(
214	0	((1 + s->blockSize100k * 100000) >> 1) * sizeof(UChar)
215	0	);
216	0	if (s->ll16 == NULL \|\| s->ll4 == NULL) RETURN(BZ_MEM_ERROR);
217	5.68k	} else {
218	5.68k	s->tt = BZALLOC( s->blockSize100k * 100000 * sizeof(Int32) );
219	5.68k	if (s->tt == NULL) RETURN(BZ_MEM_ERROR);
220	5.68k	}
221
222	6.73k	GET_UCHAR(BZ_X_BLKHDR_1, uc);
223
224	6.73k	if (uc == 0x17) goto endhdr_2;
225	5.68k	if (uc != 0x31) RETURN(BZ_DATA_ERROR);
226	5.68k	GET_UCHAR(BZ_X_BLKHDR_2, uc);
227	5.68k	if (uc != 0x41) RETURN(BZ_DATA_ERROR);
228	5.68k	GET_UCHAR(BZ_X_BLKHDR_3, uc);
229	5.68k	if (uc != 0x59) RETURN(BZ_DATA_ERROR);
230	5.68k	GET_UCHAR(BZ_X_BLKHDR_4, uc);
231	5.68k	if (uc != 0x26) RETURN(BZ_DATA_ERROR);
232	5.66k	GET_UCHAR(BZ_X_BLKHDR_5, uc);
233	5.66k	if (uc != 0x53) RETURN(BZ_DATA_ERROR);
234	5.66k	GET_UCHAR(BZ_X_BLKHDR_6, uc);
235	5.66k	if (uc != 0x59) RETURN(BZ_DATA_ERROR);
236
237	5.66k	s->currBlockNo++;
238	5.66k	if (s->verbosity >= 2)
239	0	VPrintf1 ( "\n [%d: huff+mtf ", s->currBlockNo );
240
241	5.66k	s->storedBlockCRC = 0;
242	5.66k	GET_UCHAR(BZ_X_BCRC_1, uc);
243	5.66k	s->storedBlockCRC = (s->storedBlockCRC << 8) \| ((UInt32)uc);
244	5.66k	GET_UCHAR(BZ_X_BCRC_2, uc);
245	5.66k	s->storedBlockCRC = (s->storedBlockCRC << 8) \| ((UInt32)uc);
246	5.66k	GET_UCHAR(BZ_X_BCRC_3, uc);
247	5.66k	s->storedBlockCRC = (s->storedBlockCRC << 8) \| ((UInt32)uc);
248	5.66k	GET_UCHAR(BZ_X_BCRC_4, uc);
249	5.66k	s->storedBlockCRC = (s->storedBlockCRC << 8) \| ((UInt32)uc);
250
251	5.66k	GET_BITS(BZ_X_RANDBIT, s->blockRandomised, 1);
252
253	5.66k	s->origPtr = 0;
254	5.66k	GET_UCHAR(BZ_X_ORIGPTR_1, uc);
255	5.66k	s->origPtr = (s->origPtr << 8) \| ((Int32)uc);
256	5.66k	GET_UCHAR(BZ_X_ORIGPTR_2, uc);
257	5.66k	s->origPtr = (s->origPtr << 8) \| ((Int32)uc);
258	5.66k	GET_UCHAR(BZ_X_ORIGPTR_3, uc);
259	5.66k	s->origPtr = (s->origPtr << 8) \| ((Int32)uc);
260
261	5.66k	if (s->origPtr < 0)
262	5.66k	RETURN(BZ_DATA_ERROR);
263	5.66k	if (s->origPtr > 10 + 100000*s->blockSize100k)
264	5.66k	RETURN(BZ_DATA_ERROR);
265
266		/--- Receive the mapping table ---/
267	96.3k	for (i = 0; i < 16; i++) {
268	90.6k	GET_BIT(BZ_X_MAPPING_1, uc);
269	90.6k	if (uc == 1)
270	14.2k	s->inUse16[i] = True; else
271	76.3k	s->inUse16[i] = False;
272	90.6k	}
273
274	1.45M	for (i = 0; i < 256; i++) s->inUse[i] = False;
275
276	95.9k	for (i = 0; i < 16; i++)
277	90.3k	if (s->inUse16[i])
278	242k	for (j = 0; j < 16; j++) {
279	228k	GET_BIT(BZ_X_MAPPING_2, uc);
280	228k	if (uc == 1) s->inUse[i * 16 + j] = True;
281	228k	}
282	5.63k	makeMaps_d ( s );
283	5.63k	if (s->nInUse == 0) RETURN(BZ_DATA_ERROR);
284	5.63k	alphaSize = s->nInUse+2;
285
286		/--- Now the selectors ---/
287	5.63k	GET_BITS(BZ_X_SELECTOR_1, nGroups, 3);
288	5.63k	if (nGroups < 2 \|\| nGroups > BZ_N_GROUPS) RETURN(BZ_DATA_ERROR);
289	5.63k	GET_BITS(BZ_X_SELECTOR_2, nSelectors, 15);
290	5.63k	if (nSelectors < 1) RETURN(BZ_DATA_ERROR);
291	4.41M	for (i = 0; i < nSelectors; i++) {
292	4.41M	j = 0;
293	4.93M	while (True) {
294	4.93M	GET_BIT(BZ_X_SELECTOR_3, uc);
295	4.93M	if (uc == 0) break;
296	518k	j++;
297	518k	if (j >= nGroups) RETURN(BZ_DATA_ERROR);
298	518k	}
299		/* Having more than BZ_MAX_SELECTORS doesn't make much sense
300		since they will never be used, but some implementations might
301		"round up" the number of selectors, so just ignore those. */
302	4.41M	if (i < BZ_MAX_SELECTORS)
303	3.49M	s->selectorMtf[i] = j;
304	4.41M	}
305	5.62k	if (nSelectors > BZ_MAX_SELECTORS)
306	177	nSelectors = BZ_MAX_SELECTORS;
307
308		/--- Undo the MTF values for the selectors. ---/
309	5.62k	{
310	5.62k	UChar pos[BZ_N_GROUPS], tmp, v;
311	31.8k	for (v = 0; v < nGroups; v++) pos[v] = v;
312
313	3.40M	for (i = 0; i < nSelectors; i++) {
314	3.39M	v = s->selectorMtf[i];
315	3.39M	tmp = pos[v];
316	3.75M	while (v > 0) { pos[v] = pos[v-1]; v--; }
317	3.39M	pos[0] = tmp;
318	3.39M	s->selector[i] = tmp;
319	3.39M	}
320	5.62k	}
321
322		/--- Now the coding tables ---/
323	17.5k	for (t = 0; t < nGroups; t++) {
324	15.3k	GET_BITS(BZ_X_CODING_1, curr, 5);
325	129k	for (i = 0; i < alphaSize; i++) {
326	172k	while (True) {
327	172k	if (curr < 1 \|\| curr > 20) RETURN(BZ_DATA_ERROR);
328	168k	GET_BIT(BZ_X_CODING_2, uc);
329	168k	if (uc == 0) break;
330	54.1k	GET_BIT(BZ_X_CODING_3, uc);
331	54.1k	if (uc == 0) curr++; else curr--;
332	54.1k	}
333	114k	s->len[t][i] = curr;
334	114k	}
335	15.3k	}
336
337		/--- Create the Huffman decoding tables ---/
338	7.41k	for (t = 0; t < nGroups; t++) {
339	5.28k	minLen = 32;
340	5.28k	maxLen = 0;
341	99.1k	for (i = 0; i < alphaSize; i++) {
342	93.8k	if (s->len[t][i] > maxLen) maxLen = s->len[t][i];
343	93.8k	if (s->len[t][i] < minLen) minLen = s->len[t][i];
344	93.8k	}
345	5.28k	BZ2_hbCreateDecodeTables (
346	5.28k	&(s->limit[t][0]),
347	5.28k	&(s->base[t][0]),
348	5.28k	&(s->perm[t][0]),
349	5.28k	&(s->len[t][0]),
350	5.28k	minLen, maxLen, alphaSize
351	5.28k	);
352	5.28k	s->minLens[t] = minLen;
353	5.28k	}
354
355		/--- Now the MTF values ---/
356
357	2.13k	EOB = s->nInUse+1;
358	2.13k	nblockMAX = 100000 * s->blockSize100k;
359	2.13k	groupNo = -1;
360	2.13k	groupPos = 0;
361
362	547k	for (i = 0; i <= 255; i++) s->unzftab[i] = 0;
363
364		/-- MTF init --/
365	2.13k	{
366	2.13k	Int32 ii, jj, kk;
367	2.13k	kk = MTFA_SIZE-1;
368	36.2k	for (ii = 256 / MTFL_SIZE - 1; ii >= 0; ii--) {
369	579k	for (jj = MTFL_SIZE-1; jj >= 0; jj--) {
370	545k	s->mtfa[kk] = (UChar)(ii * MTFL_SIZE + jj);
371	545k	kk--;
372	545k	}
373	34.1k	s->mtfbase[ii] = kk + 1;
374	34.1k	}
375	2.13k	}
376		/-- end MTF init --/
377
378	2.13k	nblock = 0;
379	10.6k	GET_MTF_VAL(BZ_X_MTF_1, BZ_X_MTF_2, nextSym);
380
381	298k	while (True) {
382
383	298k	if (nextSym == EOB) break;
384
385	297k	if (nextSym == BZ_RUNA \|\| nextSym == BZ_RUNB) {
386
387	45.5k	es = -1;
388	45.5k	N = 1;
389	91.6k	do {
390		/* Check that N doesn't get too big, so that es doesn't
391		go negative. The maximum value that can be
392		RUNA/RUNB encoded is equal to the block size (post
393		the initial RLE), viz, 900k, so bounding N at 2
394		million should guard against overflow without
395		rejecting any legitimate inputs. */
396	91.6k	if (N >= 210241024) RETURN(BZ_DATA_ERROR);
397	91.6k	if (nextSym == BZ_RUNA) es = es + (0+1) * N; else
398	36.3k	if (nextSym == BZ_RUNB) es = es + (1+1) * N;
399	91.6k	N = N * 2;
400	458k	GET_MTF_VAL(BZ_X_MTF_3, BZ_X_MTF_4, nextSym);
401	458k	}
402	91.6k	while (nextSym == BZ_RUNA \|\| nextSym == BZ_RUNB);
403
404	45.5k	es++;
405	45.5k	uc = s->seqToUnseq[ s->mtfa[s->mtfbase[0]] ];
406	45.5k	s->unzftab[uc] += es;
407
408	45.5k	if (s->smallDecompress)
409	0	while (es > 0) {
410	0	if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);
411	0	s->ll16[nblock] = (UInt16)uc;
412	0	nblock++;
413	0	es--;
414	0	}
415	45.5k	else
416	1.82M	while (es > 0) {
417	1.78M	if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);
418	1.78M	s->tt[nblock] = (UInt32)uc;
419	1.78M	nblock++;
420	1.78M	es--;
421	1.78M	};
422
423	45.5k	continue;
424
425	251k	} else {
426
427	251k	if (nblock >= nblockMAX) RETURN(BZ_DATA_ERROR);
428
429		/-- uc = MTF ( nextSym-1 ) --/
430	251k	{
431	251k	Int32 ii, jj, kk, pp, lno, off;
432	251k	UInt32 nn;
433	251k	nn = (UInt32)(nextSym - 1);
434
435	251k	if (nn < MTFL_SIZE) {
436		/* avoid general-case expense */
437	108k	pp = s->mtfbase[0];
438	108k	uc = s->mtfa[pp+nn];
439	236k	while (nn > 3) {
440	128k	Int32 z = pp+nn;
441	128k	s->mtfa[(z) ] = s->mtfa[(z)-1];
442	128k	s->mtfa[(z)-1] = s->mtfa[(z)-2];
443	128k	s->mtfa[(z)-2] = s->mtfa[(z)-3];
444	128k	s->mtfa[(z)-3] = s->mtfa[(z)-4];
445	128k	nn -= 4;
446	128k	}
447	266k	while (nn > 0) {
448	157k	s->mtfa[(pp+nn)] = s->mtfa[(pp+nn)-1]; nn--;
449	157k	};
450	108k	s->mtfa[pp] = uc;
451	143k	} else {
452		/* general case */
453	143k	lno = nn / MTFL_SIZE;
454	143k	off = nn % MTFL_SIZE;
455	143k	pp = s->mtfbase[lno] + off;
456	143k	uc = s->mtfa[pp];
457	1.17M	while (pp > s->mtfbase[lno]) {
458	1.03M	s->mtfa[pp] = s->mtfa[pp-1]; pp--;
459	1.03M	};
460	143k	s->mtfbase[lno]++;
461	348k	while (lno > 0) {
462	204k	s->mtfbase[lno]--;
463	204k	s->mtfa[s->mtfbase[lno]]
464	204k	= s->mtfa[s->mtfbase[lno-1] + MTFL_SIZE - 1];
465	204k	lno--;
466	204k	}
467	143k	s->mtfbase[0]--;
468	143k	s->mtfa[s->mtfbase[0]] = uc;
469	143k	if (s->mtfbase[0] == 0) {
470	20	kk = MTFA_SIZE-1;
471	340	for (ii = 256 / MTFL_SIZE-1; ii >= 0; ii--) {
472	5.44k	for (jj = MTFL_SIZE-1; jj >= 0; jj--) {
473	5.12k	s->mtfa[kk] = s->mtfa[s->mtfbase[ii] + jj];
474	5.12k	kk--;
475	5.12k	}
476	320	s->mtfbase[ii] = kk + 1;
477	320	}
478	20	}
479	143k	}
480	251k	}
481		/-- end uc = MTF ( nextSym-1 ) --/
482
483	251k	s->unzftab[s->seqToUnseq[uc]]++;
484	251k	if (s->smallDecompress)
485	0	s->ll16[nblock] = (UInt16)(s->seqToUnseq[uc]); else
486	251k	s->tt[nblock] = (UInt32)(s->seqToUnseq[uc]);
487	251k	nblock++;
488
489	251k	GET_MTF_VAL(BZ_X_MTF_5, BZ_X_MTF_6, nextSym);
490	251k	continue;
491	1.00M	}
492	297k	}
493
494		/* Now we know what nblock is, we can do a better sanity
495		check on s->origPtr.
496		*/
497	1.59k	if (s->origPtr < 0 \|\| s->origPtr >= nblock)
498	1.59k	RETURN(BZ_DATA_ERROR);
499
500		/-- Set up cftab to facilitate generation of T^(-1) --/
501		/* Check: unzftab entries in range. */
502	410k	for (i = 0; i <= 255; i++) {
503	408k	if (s->unzftab[i] < 0 \|\| s->unzftab[i] > nblock)
504	408k	RETURN(BZ_DATA_ERROR);
505	408k	}
506		/* Actually generate cftab. */
507	1.59k	s->cftab[0] = 0;
508	410k	for (i = 1; i <= 256; i++) s->cftab[i] = s->unzftab[i-1];
509	410k	for (i = 1; i <= 256; i++) s->cftab[i] += s->cftab[i-1];
510		/* Check: cftab entries in range. */
511	411k	for (i = 0; i <= 256; i++) {
512	410k	if (s->cftab[i] < 0 \|\| s->cftab[i] > nblock) {
513		/* s->cftab[i] can legitimately be == nblock */
514	0	RETURN(BZ_DATA_ERROR);
515	0	}
516	410k	}
517		/* Check: cftab entries non-descending. */
518	410k	for (i = 1; i <= 256; i++) {
519	408k	if (s->cftab[i-1] > s->cftab[i]) {
520	0	RETURN(BZ_DATA_ERROR);
521	0	}
522	408k	}
523
524	1.59k	s->state_out_len = 0;
525	1.59k	s->state_out_ch = 0;
526	1.59k	BZ_INITIALISE_CRC ( s->calculatedBlockCRC );
527	1.59k	s->state = BZ_X_OUTPUT;
528	1.59k	if (s->verbosity >= 2) VPrintf0 ( "rt+rld" );
529
530	1.59k	if (s->smallDecompress) {
531
532		/-- Make a copy of cftab, used in generation of T --/
533	0	for (i = 0; i <= 256; i++) s->cftabCopy[i] = s->cftab[i];
534
535		/-- compute the T vector --/
536	0	for (i = 0; i < nblock; i++) {
537	0	uc = (UChar)(s->ll16[i]);
538	0	SET_LL(i, s->cftabCopy[uc]);
539	0	s->cftabCopy[uc]++;
540	0	}
541
542		/-- Compute T^(-1) by pointer reversal on T --/
543	0	i = s->origPtr;
544	0	j = GET_LL(i);
545	0	do {
546	0	Int32 tmp = GET_LL(j);
547	0	SET_LL(j, i);
548	0	i = j;
549	0	j = tmp;
550	0	}
551	0	while (i != s->origPtr);
552
553	0	s->tPos = s->origPtr;
554	0	s->nblock_used = 0;
555	0	if (s->blockRandomised) {
556	0	BZ_RAND_INIT_MASK;
557	0	BZ_GET_SMALL(s->k0); s->nblock_used++;
558	0	BZ_RAND_UPD_MASK; s->k0 ^= BZ_RAND_MASK;
559	0	} else {
560	0	BZ_GET_SMALL(s->k0); s->nblock_used++;
561	0	}
562
563	1.59k	} else {
564
565		/-- compute the T^(-1) vector --/
566	1.30M	for (i = 0; i < nblock; i++) {
567	1.30M	uc = (UChar)(s->tt[i] & 0xff);
568	1.30M	s->tt[s->cftab[uc]] \|= (i << 8);
569	1.30M	s->cftab[uc]++;
570	1.30M	}
571
572	1.59k	s->tPos = s->tt[s->origPtr] >> 8;
573	1.59k	s->nblock_used = 0;
574	1.59k	if (s->blockRandomised) {
575	0	BZ_RAND_INIT_MASK;
576	0	BZ_GET_FAST(s->k0); s->nblock_used++;
577	0	BZ_RAND_UPD_MASK; s->k0 ^= BZ_RAND_MASK;
578	1.59k	} else {
579	1.59k	BZ_GET_FAST(s->k0); s->nblock_used++;
580	1.59k	}
581
582	1.59k	}
583
584	1.59k	RETURN(BZ_OK);
585
586
587
588	1.04k	endhdr_2:
589
590	1.04k	GET_UCHAR(BZ_X_ENDHDR_2, uc);
591	1.04k	if (uc != 0x72) RETURN(BZ_DATA_ERROR);
592	1.04k	GET_UCHAR(BZ_X_ENDHDR_3, uc);
593	1.04k	if (uc != 0x45) RETURN(BZ_DATA_ERROR);
594	1.04k	GET_UCHAR(BZ_X_ENDHDR_4, uc);
595	1.04k	if (uc != 0x38) RETURN(BZ_DATA_ERROR);
596	1.04k	GET_UCHAR(BZ_X_ENDHDR_5, uc);
597	1.04k	if (uc != 0x50) RETURN(BZ_DATA_ERROR);
598	1.04k	GET_UCHAR(BZ_X_ENDHDR_6, uc);
599	1.04k	if (uc != 0x90) RETURN(BZ_DATA_ERROR);
600
601	1.04k	s->storedCombinedCRC = 0;
602	1.04k	GET_UCHAR(BZ_X_CCRC_1, uc);
603	1.04k	s->storedCombinedCRC = (s->storedCombinedCRC << 8) \| ((UInt32)uc);
604	1.04k	GET_UCHAR(BZ_X_CCRC_2, uc);
605	1.04k	s->storedCombinedCRC = (s->storedCombinedCRC << 8) \| ((UInt32)uc);
606	1.04k	GET_UCHAR(BZ_X_CCRC_3, uc);
607	1.04k	s->storedCombinedCRC = (s->storedCombinedCRC << 8) \| ((UInt32)uc);
608	1.04k	GET_UCHAR(BZ_X_CCRC_4, uc);
609	1.04k	s->storedCombinedCRC = (s->storedCombinedCRC << 8) \| ((UInt32)uc);
610
611	1.04k	s->state = BZ_X_IDLE;
612	1.04k	RETURN(BZ_STREAM_END);
613
614	0	default: AssertH ( False, 4001 );
615	7.46k	}
616
617	0	AssertH ( False, 4002 );
618
619	7.46k	save_state_and_return:
620
621	7.46k	s->save_i = i;
622	7.46k	s->save_j = j;
623	7.46k	s->save_t = t;
624	7.46k	s->save_alphaSize = alphaSize;
625	7.46k	s->save_nGroups = nGroups;
626	7.46k	s->save_nSelectors = nSelectors;
627	7.46k	s->save_EOB = EOB;
628	7.46k	s->save_groupNo = groupNo;
629	7.46k	s->save_groupPos = groupPos;
630	7.46k	s->save_nextSym = nextSym;
631	7.46k	s->save_nblockMAX = nblockMAX;
632	7.46k	s->save_nblock = nblock;
633	7.46k	s->save_es = es;
634	7.46k	s->save_N = N;
635	7.46k	s->save_curr = curr;
636	7.46k	s->save_zt = zt;
637	7.46k	s->save_zn = zn;
638	7.46k	s->save_zvec = zvec;
639	7.46k	s->save_zj = zj;
640	7.46k	s->save_gSel = gSel;
641	7.46k	s->save_gMinlen = gMinlen;
642	7.46k	s->save_gLimit = gLimit;
643	7.46k	s->save_gBase = gBase;
644	7.46k	s->save_gPerm = gPerm;
645
646	7.46k	return retVal;
647	0	}
648
649
650		/-------------------------------------------------------------/
651		/--- end decompress.c ---/
652		/-------------------------------------------------------------/