source: MondoRescue/branches/3.2/mindi-busybox/archival/libarchive/bz/compress.c@ 3232

/*
 * bzip2 is written by Julian Seward <jseward@bzip.org>.
 * Adapted for busybox by Denys Vlasenko <vda.linux@googlemail.com>.
 * See README and LICENSE files in this directory for more information.
 */

/*-------------------------------------------------------------*/
/*--- 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 1.0.4 of 20 December 2006
Copyright (C) 1996-2006 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                              ---*/
/*---------------------------------------------------*/

/*---------------------------------------------------*/
static
void BZ2_bsInitWrite(EState* s)
{
    s->bsLive = 0;
    s->bsBuff = 0;
}


/*---------------------------------------------------*/
static NOINLINE
void bsFinishWrite(EState* s)
{
    while (s->bsLive > 0) {
        s->zbits[s->numZ] = (uint8_t)(s->bsBuff >> 24);
        s->numZ++;
        s->bsBuff <<= 8;
        s->bsLive -= 8;
    }
}


/*---------------------------------------------------*/
static
/* Helps only on level 5, on other levels hurts. ? */
#if CONFIG_BZIP2_FAST >= 5
ALWAYS_INLINE
#endif
void bsW(EState* s, int32_t n, uint32_t v)
{
    while (s->bsLive >= 8) {
        s->zbits[s->numZ] = (uint8_t)(s->bsBuff >> 24);
        s->numZ++;
        s->bsBuff <<= 8;
        s->bsLive -= 8;
    }
    s->bsBuff |= (v << (32 - s->bsLive - n));
    s->bsLive += n;
}


/*---------------------------------------------------*/
static
void bsPutU32(EState* s, unsigned u)
{
    bsW(s, 8, (u >> 24) & 0xff);
    bsW(s, 8, (u >> 16) & 0xff);
    bsW(s, 8, (u >>  8) & 0xff);
    bsW(s, 8,  u        & 0xff);
}


/*---------------------------------------------------*/
static
void bsPutU16(EState* s, unsigned u)
{
    bsW(s, 8, (u >>  8) & 0xff);
    bsW(s, 8,  u        & 0xff);
}


/*---------------------------------------------------*/
/*--- The back end proper                         ---*/
/*---------------------------------------------------*/

/*---------------------------------------------------*/
static
void makeMaps_e(EState* s)
{
    int i;
    s->nInUse = 0;
    for (i = 0; i < 256; i++) {
        if (s->inUse[i]) {
            s->unseqToSeq[i] = s->nInUse;
            s->nInUse++;
        }
    }
}


/*---------------------------------------------------*/
static NOINLINE
void generateMTFValues(EState* s)
{
    uint8_t yy[256];
    int32_t i, j;
    int32_t zPend;
    int32_t wr;
    int32_t EOB;

    /*
     * After sorting (eg, here),
     * s->arr1[0 .. s->nblock-1] holds sorted order,
     * and
     * ((uint8_t*)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_t*)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 &((uint8_t*)s->arr2)[s->nblock]
     *
     * These storage aliases are set up in bzCompressInit(),
     * except for the last one, which is arranged in
     * compressBlock().
     */
    uint32_t* ptr   = s->ptr;
    uint8_t*  block = s->block;
    uint16_t* 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] = (uint8_t) i;

    for (i = 0; i < s->nblock; i++) {
        uint8_t 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 (1) {
                    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 = (uint32_t)(zPend - 2) / 2;
                    /* bbox: unsigned div is easier */
                };
                zPend = 0;
            }
            {
                register uint8_t  rtmp;
                register uint8_t* ryy_j;
                register uint8_t  rll_i;
                rtmp  = yy[1];
                yy[1] = yy[0];
                ryy_j = &(yy[1]);
                rll_i = ll_i;
                while (rll_i != rtmp) {
                    register uint8_t 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 (1) {
            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 = (uint32_t)(zPend - 2) / 2;
            /* bbox: unsigned div is easier */
        };
        zPend = 0;
    }

    mtfv[wr] = EOB;
    wr++;
    s->mtfFreq[EOB]++;

    s->nMTF = wr;
}


/*---------------------------------------------------*/
#define BZ_LESSER_ICOST  0
#define BZ_GREATER_ICOST 15

static NOINLINE
void sendMTFValues(EState* s)
{
    int32_t v, t, i, j, gs, ge, totc, bt, bc, iter;
    int32_t nSelectors, alphaSize, minLen, maxLen, selCtr;
    int32_t nGroups;

    /*
     * uint8_t len[BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE];
     * is a global since the decoder also needs it.
     *
     * int32_t  code[BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE];
     * int32_t  rfreq[BZ_N_GROUPS][BZ_MAX_ALPHA_SIZE];
     * are also globals only used in this proc.
     * Made global to keep stack frame size small.
     */
#define code     sendMTFValues__code
#define rfreq    sendMTFValues__rfreq
#define len_pack sendMTFValues__len_pack

    uint16_t cost[BZ_N_GROUPS];
    int32_t  fave[BZ_N_GROUPS];

    uint16_t* mtfv = s->mtfv;

    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_t 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) /* bbox: can this be replaced by x & 1? */
            ) {
                aFreq -= s->mtfFreq[ge];
                ge--;
            }

            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;

#if CONFIG_BZIP2_FAST >= 5
        /*
         * 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];
            }
        }
#endif
        nSelectors = 0;
        totc = 0;
        gs = 0;
        while (1) {
            /*--- 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 CONFIG_BZIP2_FAST >= 5
            if (nGroups == 6 && 50 == ge-gs+1) {
                /*--- fast track the common case ---*/
                register uint32_t cost01, cost23, cost45;
                register uint16_t 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
#endif
            {
                /*--- slow version which correctly handles all situations ---*/
                for (i = gs; i <= ge; i++) {
                    uint16_t 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;*/
            bc = cost[0];
            bt = 0;
            for (t = 1 /*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.
             */
/* 1% faster compress. +800 bytes */
#if CONFIG_BZIP2_FAST >= 4
            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
                gs = ge + 1;
            } else
#endif
            {
                /*--- slow version which correctly handles all situations ---*/
                while (gs <= ge) {
                    s->rfreq[bt][mtfv[gs]]++;
                    gs++;
                }
                /* already is: gs = ge + 1; */
            }
        }

        /*
         * 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, &(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. ---*/
    {
        uint8_t 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. ---*/
    {
        /* bbox: optimized a bit more than in bzip2 */
        int inUse16 = 0;
        for (i = 0; i < 16; i++) {
            if (sizeof(long) <= 4) {
                inUse16 = inUse16*2 +
                    ((*(uint32_t*)&(s->inUse[i * 16 + 0])
                    | *(uint32_t*)&(s->inUse[i * 16 + 4])
                    | *(uint32_t*)&(s->inUse[i * 16 + 8])
                    | *(uint32_t*)&(s->inUse[i * 16 + 12])) != 0);
            } else { /* Our CPU can do better */
                inUse16 = inUse16*2 +
                    ((*(uint64_t*)&(s->inUse[i * 16 + 0])
                    | *(uint64_t*)&(s->inUse[i * 16 + 8])) != 0);
            }
        }

        bsW(s, 16, inUse16);

        inUse16 <<= (sizeof(int)*8 - 16); /* move 15th bit into sign bit */
        for (i = 0; i < 16; i++) {
            if (inUse16 < 0) {
                unsigned v16 = 0;
                for (j = 0; j < 16; j++)
                    v16 = v16*2 + s->inUse[i * 16 + j];
                bsW(s, 16, v16);
            }
            inUse16 <<= 1;
        }
    }

    /*--- Now the selectors. ---*/
    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);
    }

    /*--- Now the coding tables. ---*/
    for (t = 0; t < nGroups; t++) {
        int32_t 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);
        }
    }

    /*--- And finally, the block data proper ---*/
    selCtr = 0;
    gs = 0;
    while (1) {
        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);

/* Costs 1300 bytes and is _slower_ (on Intel Core 2) */
#if 0
        if (nGroups == 6 && 50 == ge-gs+1) {
            /*--- fast track the common case ---*/
            uint16_t mtfv_i;
            uint8_t* s_len_sel_selCtr  = &(s->len[s->selector[selCtr]][0]);
            int32_t* 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
            gs = ge+1;
        } else
#endif
        {
            /*--- slow version which correctly handles all situations ---*/
            /* code is bit bigger, but moves multiply out of the loop */
            uint8_t* s_len_sel_selCtr  = &(s->len [s->selector[selCtr]][0]);
            int32_t* s_code_sel_selCtr = &(s->code[s->selector[selCtr]][0]);
            while (gs <= ge) {
                bsW(s,
                    s_len_sel_selCtr[mtfv[gs]],
                    s_code_sel_selCtr[mtfv[gs]]
                );
                gs++;
            }
            /* already is: gs = ge+1; */
        }
        selCtr++;
    }
    AssertH(selCtr == nSelectors, 3007);
#undef code
#undef rfreq
#undef len_pack
}


/*---------------------------------------------------*/
static
void BZ2_compressBlock(EState* s, int 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;

        BZ2_blockSort(s);
    }

    s->zbits = &((uint8_t*)s->arr2)[s->nblock];

    /*-- If this is the first block, create the stream header. --*/
    if (s->blockNo == 1) {
        BZ2_bsInitWrite(s);
        /*bsPutU8(s, BZ_HDR_B);*/
        /*bsPutU8(s, BZ_HDR_Z);*/
        /*bsPutU8(s, BZ_HDR_h);*/
        /*bsPutU8(s, BZ_HDR_0 + s->blockSize100k);*/
        bsPutU32(s, BZ_HDR_BZh0 + s->blockSize100k);
    }

    if (s->nblock > 0) {
        /*bsPutU8(s, 0x31);*/
        /*bsPutU8(s, 0x41);*/
        /*bsPutU8(s, 0x59);*/
        /*bsPutU8(s, 0x26);*/
        bsPutU32(s, 0x31415926);
        /*bsPutU8(s, 0x53);*/
        /*bsPutU8(s, 0x59);*/
        bsPutU16(s, 0x5359);

        /*-- Now the block's CRC, so it is in a known place. --*/
        bsPutU32(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) {
        /*bsPutU8(s, 0x17);*/
        /*bsPutU8(s, 0x72);*/
        /*bsPutU8(s, 0x45);*/
        /*bsPutU8(s, 0x38);*/
        bsPutU32(s, 0x17724538);
        /*bsPutU8(s, 0x50);*/
        /*bsPutU8(s, 0x90);*/
        bsPutU16(s, 0x5090);
        bsPutU32(s, s->combinedCRC);
        bsFinishWrite(s);
    }
}


/*-------------------------------------------------------------*/
/*--- end                                        compress.c ---*/
/*-------------------------------------------------------------*/