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path: root/server/glz_encode_tmpl.c
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/*
   Copyright (C) 2009 Red Hat, Inc.

   This program is free software; you can redistribute it and/or
   modify it under the terms of the GNU General Public License as
   published by the Free Software Foundation; either version 2 of
   the License, or (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#define DJB2_START 5381;
#define DJB2_HASH(hash, c) (hash = ((hash << 5) + hash) ^ (c)) //|{hash = ((hash << 5) + hash) + c;}

/*
    For each pixel type the following macros are defined:
    PIXEL                         : input type
    FNAME(name)
    ENCODE_PIXEL(encoder, pixel) : writing a pixel to the compressed buffer (byte by byte)
    SAME_PIXEL(pix1, pix2)         : comparing two pixels
    HASH_FUNC(value, pix_ptr)    : hash func of 3 consecutive pixels
*/

#ifdef LZ_PLT
#define PIXEL one_byte_pixel_t
#define FNAME(name) glz_plt_##name
#define ENCODE_PIXEL(e, pix) encode(e, (pix).a)   // gets the pixel and write only the needed bytes
                                                  // from the pixel
#define SAME_PIXEL(pix1, pix2) ((pix1).a == (pix2).a)
#define MIN_REF_ENCODE_SIZE 4
#define MAX_REF_ENCODE_SIZE 7
#define HASH_FUNC(v, p) {  \
    v = DJB2_START;        \
    DJB2_HASH(v, p[0].a);  \
    DJB2_HASH(v, p[1].a);  \
    DJB2_HASH(v, p[2].a);  \
    v &= HASH_MASK;        \
    }
#endif

#ifdef LZ_RGB_ALPHA
//#undef LZ_RGB_ALPHA
#define PIXEL rgb32_pixel_t
#define FNAME(name) glz_rgb_alpha_##name
#define ENCODE_PIXEL(e, pix) {encode(e, (pix).pad);}
#define SAME_PIXEL(pix1, pix2) ((pix1).pad == (pix2).pad)
#define MIN_REF_ENCODE_SIZE 4
#define MAX_REF_ENCODE_SIZE 7
#define HASH_FUNC(v, p) {    \
    v = DJB2_START;          \
    DJB2_HASH(v, p[0].pad);  \
    DJB2_HASH(v, p[1].pad);  \
    DJB2_HASH(v, p[2].pad);  \
    v &= HASH_MASK;          \
    }
#endif


#ifdef LZ_RGB16
#define PIXEL rgb16_pixel_t
#define FNAME(name) glz_rgb16_##name
#define GET_r(pix) (((pix) >> 10) & 0x1f)
#define GET_g(pix) (((pix) >> 5) & 0x1f)
#define GET_b(pix) ((pix) & 0x1f)
#define ENCODE_PIXEL(e, pix) {encode(e, (pix) >> 8); encode(e, (pix) & 0xff);}
#define MIN_REF_ENCODE_SIZE 2
#define MAX_REF_ENCODE_SIZE 3
#define HASH_FUNC(v, p) {                  \
    v = DJB2_START;                        \
    DJB2_HASH(v, p[0] & (0x00ff));         \
    DJB2_HASH(v, (p[0] >> 8) & (0x007f));  \
    DJB2_HASH(v, p[1] & (0x00ff));         \
    DJB2_HASH(v, (p[1] >> 8) & (0x007f));  \
    DJB2_HASH(v, p[2] & (0x00ff));         \
    DJB2_HASH(v, (p[2] >> 8) & (0x007f));  \
    v &= HASH_MASK;                        \
}
#endif

#ifdef LZ_RGB24
#define PIXEL rgb24_pixel_t
#define FNAME(name) glz_rgb24_##name
#define ENCODE_PIXEL(e, pix) {encode(e, (pix).b); encode(e, (pix).g); encode(e, (pix).r);}
#define MIN_REF_ENCODE_SIZE 2
#define MAX_REF_ENCODE_SIZE 2
#endif

#ifdef LZ_RGB32
#define PIXEL rgb32_pixel_t
#define FNAME(name) glz_rgb32_##name
#define ENCODE_PIXEL(e, pix) {encode(e, (pix).b); encode(e, (pix).g); encode(e, (pix).r);}
#define MIN_REF_ENCODE_SIZE 2
#define MAX_REF_ENCODE_SIZE 2
#endif


#if  defined(LZ_RGB24) || defined(LZ_RGB32)
#define GET_r(pix) ((pix).r)
#define GET_g(pix) ((pix).g)
#define GET_b(pix) ((pix).b)
#define HASH_FUNC(v, p) {    \
    v = DJB2_START;          \
    DJB2_HASH(v, p[0].r);    \
    DJB2_HASH(v, p[0].g);    \
    DJB2_HASH(v, p[0].b);    \
    DJB2_HASH(v, p[1].r);    \
    DJB2_HASH(v, p[1].g);    \
    DJB2_HASH(v, p[1].b);    \
    DJB2_HASH(v, p[2].r);    \
    DJB2_HASH(v, p[2].g);    \
    DJB2_HASH(v, p[2].b);    \
    v &= HASH_MASK;          \
    }
#endif

#if defined(LZ_RGB16) || defined(LZ_RGB24) || defined(LZ_RGB32)
#define SAME_PIXEL(p1, p2) (GET_r(p1) == GET_r(p2) && GET_g(p1) == GET_g(p2) && \
                            GET_b(p1) == GET_b(p2))

#endif

#ifndef LZ_PLT
#define PIXEL_ID(pix_ptr, seg_ptr) \
    ((pix_ptr) - ((PIXEL *)(seg_ptr)->lines) + (seg_ptr)->pixels_so_far)
#define PIXEL_DIST(src_pix_ptr, src_seg_ptr, ref_pix_ptr, ref_seg_ptr) \
    (PIXEL_ID(src_pix_ptr,src_seg_ptr) - PIXEL_ID(ref_pix_ptr, ref_seg_ptr))
#else
#define PIXEL_ID(pix_ptr, seg_ptr, pix_per_byte) \
    (((pix_ptr) - ((PIXEL *)(seg_ptr)->lines)) * pix_per_byte + (seg_ptr)->pixels_so_far)
#define PIXEL_DIST(src_pix_ptr, src_seg_ptr, ref_pix_ptr, ref_seg_ptr, pix_per_byte) \
    ((PIXEL_ID(src_pix_ptr,src_seg_ptr, pix_per_byte) - \
    PIXEL_ID(ref_pix_ptr, ref_seg_ptr, pix_per_byte)) / pix_per_byte)
#endif

/* returns the length of the match. 0 if no match.
  if image_distance = 0, pixel_distance is the distance between the matching pixels.
  Otherwise, it is the offset from the beginning of the referred image */
static INLINE size_t FNAME(do_match)(SharedDictionary *dict, 
                                     WindowImageSegment *ref_seg, const PIXEL *ref, 
                                     const PIXEL *ref_limit,
                                     WindowImageSegment *ip_seg,  const PIXEL *ip, 
                                     const PIXEL *ip_limit,
#ifdef  LZ_PLT
                                     int pix_per_byte,
#endif
                                     size_t *o_image_dist, size_t *o_pix_distance)
{
    int encode_size;
    const PIXEL *tmp_ip = ip;
    const PIXEL *tmp_ref = ref;

    if (ref > (ref_limit - MIN_REF_ENCODE_SIZE)) {
        return 0; // in case the hash entry is not relvant
    }


    /* min match lenght == MIN_REF_ENCODE_SIZE (depends on pixel type) */

    if (!SAME_PIXEL(*tmp_ref, *tmp_ip)) {
        return 0;
    } else {
        tmp_ref++;
        tmp_ip++;
    }


    if (!SAME_PIXEL(*tmp_ref, *tmp_ip)) {
        return 0;
    } else {
        tmp_ref++;
        tmp_ip++;
    }

#if defined(LZ_PLT) || defined(LZ_RGB_ALPHA)
    if (!SAME_PIXEL(*tmp_ref, *tmp_ip)) {
        return 0;
    } else {
        tmp_ref++;
        tmp_ip++;
    }


    if (!SAME_PIXEL(*tmp_ref, *tmp_ip)) {
        return 0;
    } else {
        tmp_ref++;
        tmp_ip++;
    }

#endif


    *o_image_dist = ip_seg->image->id - ref_seg->image->id;

    if (!(*o_image_dist)) { // the ref is inside the same image - encode distance
#ifndef LZ_PLT
        *o_pix_distance = PIXEL_DIST(ip, ip_seg, ref, ref_seg);
#else
        // in bytes
        *o_pix_distance = PIXEL_DIST(ip, ip_seg, ref, ref_seg, pix_per_byte);
#endif
    } else { // the ref is at different image - encode offset from the image start
#ifndef LZ_PLT
        *o_pix_distance = PIXEL_DIST(ref, ref_seg,
                                     (PIXEL *)(dict->window.segs[ref_seg->image->first_seg].lines),
                                     &dict->window.segs[ref_seg->image->first_seg]
                                     );
#else
        // in bytes
        *o_pix_distance = PIXEL_DIST(ref, ref_seg,
                                     (PIXEL *)(dict->window.segs[ref_seg->image->first_seg].lines),
                                     &dict->window.segs[ref_seg->image->first_seg],
                                     pix_per_byte);
#endif
    }

    if ((*o_pix_distance == 0) || (*o_pix_distance >= MAX_PIXEL_LONG_DISTANCE) ||
        (*o_image_dist > MAX_IMAGE_DIST)) {
        return 0;
    }


    /* continue the match*/
    while ((tmp_ip < ip_limit) && (tmp_ref < ref_limit)) {
        if (!SAME_PIXEL(*tmp_ref, *tmp_ip)) {
            break;
        } else {
            tmp_ref++;
            tmp_ip++;
        }
    }


    if ((tmp_ip - ip) > MAX_REF_ENCODE_SIZE) {
        return (tmp_ip - ip);
    }

    encode_size = get_encode_ref_size(*o_image_dist, *o_pix_distance);

    // min number of identical pixels for a match
#if defined(LZ_RGB16)
    encode_size /= 2;
#elif defined(LZ_RGB24) || defined(LZ_RGB32)
    encode_size /= 3;
#endif

    encode_size++; // the minimum match
    // match len is smaller than the encoding - not worth encoding
    if ((tmp_ip - ip) < encode_size) {
        return 0;
    }
    return (tmp_ip - ip);
}

/* compresses one segment starting from 'from'.
   In order to encode a match, we use pixels resolution when we encode RGB image,
   and bytes count when we encode PLT.
*/
static void FNAME(compress_seg)(Encoder *encoder, uint32_t seg_idx, PIXEL *from, int copied)
{
    WindowImageSegment *seg = &encoder->dict->window.segs[seg_idx];
    const PIXEL *ip = from;
    const PIXEL *ip_bound = (PIXEL *)(seg->lines_end) - BOUND_OFFSET;
    const PIXEL *ip_limit = (PIXEL *)(seg->lines_end) - LIMIT_OFFSET;
    int hval;
    int copy = copied;
#ifdef  LZ_PLT
    int pix_per_byte = PLT_PIXELS_PER_BYTE[encoder->cur_image.type];
#endif

#ifdef DEBUG_ENCODE
    int n_encoded = 0;
#endif

    if (copy == 0) {
        encode_copy_count(encoder, MAX_COPY - 1);
    }


    while (LZ_EXPECT_CONDITIONAL(ip < ip_limit)) {
        const PIXEL            *ref;
        const PIXEL            *ref_limit;
        WindowImageSegment     *ref_seg;
        uint32_t ref_seg_idx;
        size_t pix_dist;
        size_t image_dist;
        /* minimum match length */
        size_t len = 0;

        /* comparison starting-point */
        const PIXEL            *anchor = ip;
#ifdef CHAINED_HASH
        int hash_id = 0;
        size_t best_len = 0;
        size_t best_pix_dist = 0;
        size_t best_image_dist = 0;
#endif

        /* check for a run */

        if (LZ_EXPECT_CONDITIONAL(ip > (PIXEL *)(seg->lines))) {
            if (SAME_PIXEL(ip[-1], ip[0]) && SAME_PIXEL(ip[0], ip[1]) && SAME_PIXEL(ip[1], ip[2])) {
                PIXEL x;
                pix_dist = 1;
                image_dist = 0;

                ip += 3;
                ref = anchor + 2;
                ref_limit = (PIXEL *)(seg->lines_end);
                len = 3;

                x = *ref;

                while (ip < ip_bound) { // TODO: maybe separate a run from the same seg or from
                                       // different ones in order to spare ref < ref_limit
                    if (!SAME_PIXEL(*ip, x)) {
                        ip++;
                        break;
                    } else {
                        ip++;
                        len++;
                    }
                }

                goto match;
            } // END RLE MATCH
        }

        /* find potential match */
        HASH_FUNC(hval, ip);

#ifdef CHAINED_HASH
        for (hash_id = 0; hash_id < HASH_CHAIN_SIZE; hash_id++) {
            ref_seg_idx = encoder->dict->htab[hval][hash_id].image_seg_idx;
#else
        ref_seg_idx = encoder->dict->htab[hval].image_seg_idx;
#endif
            ref_seg = encoder->dict->window.segs + ref_seg_idx;
            if (REF_SEG_IS_VALID(encoder->dict, encoder->id,
                                 ref_seg, seg)) {
#ifdef CHAINED_HASH
                ref = ((PIXEL *)ref_seg->lines) + encoder->dict->htab[hval][hash_id].ref_pix_idx;
#else
                ref = ((PIXEL *)ref_seg->lines) + encoder->dict->htab[hval].ref_pix_idx;
#endif
                ref_limit = (PIXEL *)ref_seg->lines_end;

                len = FNAME(do_match)(encoder->dict, ref_seg, ref, ref_limit, seg, ip, ip_bound,
#ifdef  LZ_PLT
                                      pix_per_byte,
#endif
                                      &image_dist, &pix_dist);

#ifdef CHAINED_HASH
                // TODO. not compare len but rather len - encode_size
                if (len > best_len) {
                    best_len = len;
                    best_pix_dist = pix_dist;
                    best_image_dist = image_dist;
                }
#endif
            }

#ifdef CHAINED_HASH
        } // end chain loop
        len = best_len;
        pix_dist = best_pix_dist;
        image_dist = best_image_dist;
#endif

        /* update hash table */
        UPDATE_HASH(encoder->dict, hval, seg_idx, anchor - ((PIXEL *)seg->lines));

        if (!len) {
            goto literal;
        }

match:        // RLE or dictionary (both are encoded by distance from ref (-1) and length)
#ifdef DEBUG_ENCODE
        printf(", match(%d, %d, %d)", image_dist, pix_dist, len);
        n_encoded += len;
#endif

        /* distance is biased */
        if (!image_dist) {
            pix_dist--;
        }

        /* if we have copied something, adjust the copy count */
        if (copy) {
            /* copy is biased, '0' means 1 byte copy */
            update_copy_count(encoder, copy - 1);
        } else {
            /* back, to overwrite the copy count */
            compress_output_prev(encoder);
        }

        /* reset literal counter */
        copy = 0;

        /* length is biased, '1' means a match of 3 pixels for PLT and alpha*/
        /* for RGB 16 1 means 2 */
        /* for RGB24/32 1 means 1...*/
        ip = anchor + len - 2;

#if defined(LZ_RGB16)
        len--;
#elif defined(LZ_PLT) || defined(LZ_RGB_ALPHA)
        len -= 2;
#endif
        GLZ_ASSERT(encoder->usr, len > 0);
        encode_match(encoder, image_dist, pix_dist, len);

        /* update the hash at match boundary */
#if defined(LZ_RGB16) || defined(LZ_RGB24) || defined(LZ_RGB32)
        if (ip > anchor) {
#endif
            HASH_FUNC(hval, ip);
            UPDATE_HASH(encoder->dict, hval, seg_idx, ip - ((PIXEL *)seg->lines));
            ip++;
#if defined(LZ_RGB16) || defined(LZ_RGB24) || defined(LZ_RGB32)
        } else {ip++;
        }
#endif
#if defined(LZ_RGB24) || defined(LZ_RGB32)
        if (ip > anchor) {
#endif
            HASH_FUNC(hval, ip);
            UPDATE_HASH(encoder->dict, hval, seg_idx, ip - ((PIXEL *)seg->lines));
            ip++;
#if defined(LZ_RGB24) || defined(LZ_RGB32)
        } else {
            ip++;
        }
#endif
        /* assuming literal copy */
        encode_copy_count(encoder, MAX_COPY - 1);
        continue;

literal:
#ifdef DEBUG_ENCODE
        printf(", copy");
        n_encoded++;
#endif
        ENCODE_PIXEL(encoder, *anchor);
        anchor++;
        ip = anchor;
        copy++;

        if (LZ_UNEXPECT_CONDITIONAL(copy == MAX_COPY)) {
            copy = 0;
            encode_copy_count(encoder, MAX_COPY - 1);
        }
    } // END LOOP (ip < ip_limit)


    /* left-over as literal copy */
    ip_bound++;
    while (ip <= ip_bound) {
#ifdef DEBUG_ENCODE
        printf(", copy");
        n_encoded++;
#endif
        ENCODE_PIXEL(encoder, *ip);
        ip++;
        copy++;
        if (copy == MAX_COPY) {
            copy = 0;
            encode_copy_count(encoder, MAX_COPY - 1);
        }
    }

    /* if we have copied something, adjust the copy length */
    if (copy) {
        update_copy_count(encoder, copy - 1);
    } else {
        compress_output_prev(encoder);
    }
#ifdef DEBUG_ENCODE
    printf("\ntotal encoded=%d\n", n_encoded);
#endif
}


/*  If the file is very small, copies it.
    copies the first two pixels of the first segment, and sends the segments
    one by one to compress_seg.
    the number of bytes compressed are stored inside encoder. */
static void FNAME(compress)(Encoder *encoder)
{
    uint32_t seg_id = encoder->cur_image.first_win_seg;
    PIXEL    *ip;
    SharedDictionary *dict = encoder->dict;
    int hval;

    // fetch the first image segment that is not too small
    while ((seg_id != NULL_IMAGE_SEG_ID) &&
           (dict->window.segs[seg_id].image->id == encoder->cur_image.id) &&
           ((((PIXEL *)dict->window.segs[seg_id].lines_end) -
             ((PIXEL *)dict->window.segs[seg_id].lines)) < 4)) {
        // coping the segment
        if (dict->window.segs[seg_id].lines != dict->window.segs[seg_id].lines_end) {
            ip = (PIXEL *)dict->window.segs[seg_id].lines;
            // Note: we assume MAX_COPY > 3
            encode_copy_count(encoder, (uint8_t)(
                                  (((PIXEL *)dict->window.segs[seg_id].lines_end) -
                                   ((PIXEL *)dict->window.segs[seg_id].lines)) - 1));
            while (ip < (PIXEL *)dict->window.segs[seg_id].lines_end) {
                ENCODE_PIXEL(encoder, *ip);
                ip++;
            }
        }
        seg_id = dict->window.segs[seg_id].next;
    }

    if ((seg_id == NULL_IMAGE_SEG_ID) ||
        (dict->window.segs[seg_id].image->id != encoder->cur_image.id)) {
        return;
    }

    ip = (PIXEL *)dict->window.segs[seg_id].lines;


    encode_copy_count(encoder, MAX_COPY - 1);

    HASH_FUNC(hval, ip);
    UPDATE_HASH(encoder->dict, hval, seg_id, 0);

    ENCODE_PIXEL(encoder, *ip);
    ip++;
    ENCODE_PIXEL(encoder, *ip);
    ip++;
#ifdef DEBUG_ENCODE
    printf("copy, copy");
#endif
    // compressing the first segment
    FNAME(compress_seg)(encoder, seg_id, ip, 2);

    // compressing the next segments
    for (seg_id = dict->window.segs[seg_id].next; 
        seg_id != NULL_IMAGE_SEG_ID && (
        dict->window.segs[seg_id].image->id == encoder->cur_image.id); 
        seg_id = dict->window.segs[seg_id].next) {
        FNAME(compress_seg)(encoder, seg_id, (PIXEL *)dict->window.segs[seg_id].lines, 0);
    }
}

#undef FNAME
#undef PIXEL_ID
#undef PIXEL_DIST
#undef PIXEL
#undef ENCODE_PIXEL
#undef SAME_PIXEL
#undef HASH_FUNC
#undef GET_r
#undef GET_g
#undef GET_b
#undef GET_CODE
#undef LZ_PLT
#undef LZ_RGB_ALPHA
#undef LZ_RGB16
#undef LZ_RGB24
#undef LZ_RGB32
#undef MIN_REF_ENCODE_SIZE
#undef MAX_REF_ENCODE_SIZE