/* * Copyright (c) 1988-1997 Sam Leffler * Copyright (c) 1991-1997 Silicon Graphics, Inc. * * Permission to use, copy, modify, distribute, and sell this software and * its documentation for any purpose is hereby granted without fee, provided * that (i) the above copyright notices and this permission notice appear in * all copies of the software and related documentation, and (ii) the names of * Sam Leffler and Silicon Graphics may not be used in any advertising or * publicity relating to the software without the specific, prior written * permission of Sam Leffler and Silicon Graphics. * * THE SOFTWARE IS PROVIDED "AS-IS" AND WITHOUT WARRANTY OF ANY KIND, * EXPRESS, IMPLIED OR OTHERWISE, INCLUDING WITHOUT LIMITATION, ANY * WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. * * IN NO EVENT SHALL SAM LEFFLER OR SILICON GRAPHICS BE LIABLE FOR * ANY SPECIAL, INCIDENTAL, INDIRECT OR CONSEQUENTIAL DAMAGES OF ANY KIND, * OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, * WHETHER OR NOT ADVISED OF THE POSSIBILITY OF DAMAGE, AND ON ANY THEORY OF * LIABILITY, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE * OF THIS SOFTWARE. */ /* * TIFF Library. * * Predictor Tag Support (used by multiple codecs). */ #include "tif_predict.h" #include "tiffiop.h" #define PredictorState(tif) ((TIFFPredictorState *)(tif)->tif_data) static int horAcc8(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horAcc16(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horAcc32(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horAcc64(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorAcc16(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorAcc32(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorAcc64(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horDiff8(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horDiff16(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horDiff32(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int horDiff64(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorDiff16(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorDiff32(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int swabHorDiff64(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int fpAcc(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int fpDiff(TIFF *tif, uint8_t *cp0, tmsize_t cc); static int PredictorDecodeRow(TIFF *tif, uint8_t *op0, tmsize_t occ0, uint16_t s); static int PredictorDecodeTile(TIFF *tif, uint8_t *op0, tmsize_t occ0, uint16_t s); static int PredictorEncodeRow(TIFF *tif, uint8_t *bp, tmsize_t cc, uint16_t s); static int PredictorEncodeTile(TIFF *tif, uint8_t *bp0, tmsize_t cc0, uint16_t s); static int PredictorSetup(TIFF *tif) { static const char module[] = "PredictorSetup"; TIFFPredictorState *sp = PredictorState(tif); TIFFDirectory *td = &tif->tif_dir; switch (sp->predictor) /* no differencing */ { case PREDICTOR_NONE: return 1; case PREDICTOR_HORIZONTAL: if (td->td_bitspersample != 8 && td->td_bitspersample != 16 && td->td_bitspersample != 32 && td->td_bitspersample != 64) { TIFFErrorExtR(tif, module, "Horizontal differencing \"Predictor\" not " "supported with %" PRIu16 "-bit samples", td->td_bitspersample); return 0; } break; case PREDICTOR_FLOATINGPOINT: if (td->td_sampleformat != SAMPLEFORMAT_IEEEFP) { TIFFErrorExtR( tif, module, "Floating point \"Predictor\" not supported with %" PRIu16 " data format", td->td_sampleformat); return 0; } if (td->td_bitspersample != 16 && td->td_bitspersample != 24 && td->td_bitspersample != 32 && td->td_bitspersample != 64) { /* Should 64 be allowed? */ TIFFErrorExtR( tif, module, "Floating point \"Predictor\" not supported with %" PRIu16 "-bit samples", td->td_bitspersample); return 0; } break; default: TIFFErrorExtR(tif, module, "\"Predictor\" value %d not supported", sp->predictor); return 0; } sp->stride = (td->td_planarconfig == PLANARCONFIG_CONTIG ? td->td_samplesperpixel : 1); /* * Calculate the scanline/tile-width size in bytes. */ if (isTiled(tif)) sp->rowsize = TIFFTileRowSize(tif); else sp->rowsize = TIFFScanlineSize(tif); if (sp->rowsize == 0) return 0; return 1; } static int PredictorSetupDecode(TIFF *tif) { TIFFPredictorState *sp = PredictorState(tif); TIFFDirectory *td = &tif->tif_dir; /* Note: when PredictorSetup() fails, the effets of setupdecode() */ /* will not be "canceled" so setupdecode() might be robust to */ /* be called several times. */ if (!(*sp->setupdecode)(tif) || !PredictorSetup(tif)) return 0; if (sp->predictor == 2) { switch (td->td_bitspersample) { case 8: sp->decodepfunc = horAcc8; break; case 16: sp->decodepfunc = horAcc16; break; case 32: sp->decodepfunc = horAcc32; break; case 64: sp->decodepfunc = horAcc64; break; } /* * Override default decoding method with one that does the * predictor stuff. */ if (tif->tif_decoderow != PredictorDecodeRow) { sp->decoderow = tif->tif_decoderow; tif->tif_decoderow = PredictorDecodeRow; sp->decodestrip = tif->tif_decodestrip; tif->tif_decodestrip = PredictorDecodeTile; sp->decodetile = tif->tif_decodetile; tif->tif_decodetile = PredictorDecodeTile; } /* * If the data is horizontally differenced 16-bit data that * requires byte-swapping, then it must be byte swapped before * the accumulation step. We do this with a special-purpose * routine and override the normal post decoding logic that * the library setup when the directory was read. */ if (tif->tif_flags & TIFF_SWAB) { if (sp->decodepfunc == horAcc16) { sp->decodepfunc = swabHorAcc16; tif->tif_postdecode = _TIFFNoPostDecode; } else if (sp->decodepfunc == horAcc32) { sp->decodepfunc = swabHorAcc32; tif->tif_postdecode = _TIFFNoPostDecode; } else if (sp->decodepfunc == horAcc64) { sp->decodepfunc = swabHorAcc64; tif->tif_postdecode = _TIFFNoPostDecode; } } } else if (sp->predictor == 3) { sp->decodepfunc = fpAcc; /* * Override default decoding method with one that does the * predictor stuff. */ if (tif->tif_decoderow != PredictorDecodeRow) { sp->decoderow = tif->tif_decoderow; tif->tif_decoderow = PredictorDecodeRow; sp->decodestrip = tif->tif_decodestrip; tif->tif_decodestrip = PredictorDecodeTile; sp->decodetile = tif->tif_decodetile; tif->tif_decodetile = PredictorDecodeTile; } /* * The data should not be swapped outside of the floating * point predictor, the accumulation routine should return * byres in the native order. */ if (tif->tif_flags & TIFF_SWAB) { tif->tif_postdecode = _TIFFNoPostDecode; } /* * Allocate buffer to keep the decoded bytes before * rearranging in the right order */ } return 1; } static int PredictorSetupEncode(TIFF *tif) { TIFFPredictorState *sp = PredictorState(tif); TIFFDirectory *td = &tif->tif_dir; if (!(*sp->setupencode)(tif) || !PredictorSetup(tif)) return 0; if (sp->predictor == 2) { switch (td->td_bitspersample) { case 8: sp->encodepfunc = horDiff8; break; case 16: sp->encodepfunc = horDiff16; break; case 32: sp->encodepfunc = horDiff32; break; case 64: sp->encodepfunc = horDiff64; break; } /* * Override default encoding method with one that does the * predictor stuff. */ if (tif->tif_encoderow != PredictorEncodeRow) { sp->encoderow = tif->tif_encoderow; tif->tif_encoderow = PredictorEncodeRow; sp->encodestrip = tif->tif_encodestrip; tif->tif_encodestrip = PredictorEncodeTile; sp->encodetile = tif->tif_encodetile; tif->tif_encodetile = PredictorEncodeTile; } /* * If the data is horizontally differenced 16-bit data that * requires byte-swapping, then it must be byte swapped after * the differentiation step. We do this with a special-purpose * routine and override the normal post decoding logic that * the library setup when the directory was read. */ if (tif->tif_flags & TIFF_SWAB) { if (sp->encodepfunc == horDiff16) { sp->encodepfunc = swabHorDiff16; tif->tif_postdecode = _TIFFNoPostDecode; } else if (sp->encodepfunc == horDiff32) { sp->encodepfunc = swabHorDiff32; tif->tif_postdecode = _TIFFNoPostDecode; } else if (sp->encodepfunc == horDiff64) { sp->encodepfunc = swabHorDiff64; tif->tif_postdecode = _TIFFNoPostDecode; } } } else if (sp->predictor == 3) { sp->encodepfunc = fpDiff; /* * Override default encoding method with one that does the * predictor stuff. */ if (tif->tif_encoderow != PredictorEncodeRow) { sp->encoderow = tif->tif_encoderow; tif->tif_encoderow = PredictorEncodeRow; sp->encodestrip = tif->tif_encodestrip; tif->tif_encodestrip = PredictorEncodeTile; sp->encodetile = tif->tif_encodetile; tif->tif_encodetile = PredictorEncodeTile; } } return 1; } #define REPEAT4(n, op) \ switch (n) \ { \ default: \ { \ tmsize_t i; \ for (i = n - 4; i > 0; i--) \ { \ op; \ } \ } /*-fallthrough*/ \ case 4: \ op; /*-fallthrough*/ \ case 3: \ op; /*-fallthrough*/ \ case 2: \ op; /*-fallthrough*/ \ case 1: \ op; /*-fallthrough*/ \ case 0:; \ } /* Remarks related to C standard compliance in all below functions : */ /* - to avoid any undefined behavior, we only operate on unsigned types */ /* since the behavior of "overflows" is defined (wrap over) */ /* - when storing into the byte stream, we explicitly mask with 0xff so */ /* as to make icc -check=conversions happy (not necessary by the standard) */ TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horAcc8(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; unsigned char *cp = (unsigned char *)cp0; if ((cc % stride) != 0) { TIFFErrorExtR(tif, "horAcc8", "%s", "(cc%stride)!=0"); return 0; } if (cc > stride) { /* * Pipeline the most common cases. */ if (stride == 3) { unsigned int cr = cp[0]; unsigned int cg = cp[1]; unsigned int cb = cp[2]; tmsize_t i = stride; for (; i < cc; i += stride) { cp[i + 0] = (unsigned char)((cr += cp[i + 0]) & 0xff); cp[i + 1] = (unsigned char)((cg += cp[i + 1]) & 0xff); cp[i + 2] = (unsigned char)((cb += cp[i + 2]) & 0xff); } } else if (stride == 4) { unsigned int cr = cp[0]; unsigned int cg = cp[1]; unsigned int cb = cp[2]; unsigned int ca = cp[3]; tmsize_t i = stride; for (; i < cc; i += stride) { cp[i + 0] = (unsigned char)((cr += cp[i + 0]) & 0xff); cp[i + 1] = (unsigned char)((cg += cp[i + 1]) & 0xff); cp[i + 2] = (unsigned char)((cb += cp[i + 2]) & 0xff); cp[i + 3] = (unsigned char)((ca += cp[i + 3]) & 0xff); } } else { cc -= stride; do { REPEAT4(stride, cp[stride] = (unsigned char)((cp[stride] + *cp) & 0xff); cp++) cc -= stride; } while (cc > 0); } } return 1; } static int swabHorAcc16(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint16_t *wp = (uint16_t *)cp0; tmsize_t wc = cc / 2; TIFFSwabArrayOfShort(wp, wc); return horAcc16(tif, cp0, cc); } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horAcc16(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; uint16_t *wp = (uint16_t *)cp0; tmsize_t wc = cc / 2; if ((cc % (2 * stride)) != 0) { TIFFErrorExtR(tif, "horAcc16", "%s", "cc%(2*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; do { REPEAT4(stride, wp[stride] = (uint16_t)(((unsigned int)wp[stride] + (unsigned int)wp[0]) & 0xffff); wp++) wc -= stride; } while (wc > 0); } return 1; } static int swabHorAcc32(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint32_t *wp = (uint32_t *)cp0; tmsize_t wc = cc / 4; TIFFSwabArrayOfLong(wp, wc); return horAcc32(tif, cp0, cc); } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horAcc32(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; uint32_t *wp = (uint32_t *)cp0; tmsize_t wc = cc / 4; if ((cc % (4 * stride)) != 0) { TIFFErrorExtR(tif, "horAcc32", "%s", "cc%(4*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; do { REPEAT4(stride, wp[stride] += wp[0]; wp++) wc -= stride; } while (wc > 0); } return 1; } static int swabHorAcc64(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint64_t *wp = (uint64_t *)cp0; tmsize_t wc = cc / 8; TIFFSwabArrayOfLong8(wp, wc); return horAcc64(tif, cp0, cc); } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horAcc64(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; uint64_t *wp = (uint64_t *)cp0; tmsize_t wc = cc / 8; if ((cc % (8 * stride)) != 0) { TIFFErrorExtR(tif, "horAcc64", "%s", "cc%(8*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; do { REPEAT4(stride, wp[stride] += wp[0]; wp++) wc -= stride; } while (wc > 0); } return 1; } /* * Floating point predictor accumulation routine. */ static int fpAcc(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; uint32_t bps = tif->tif_dir.td_bitspersample / 8; tmsize_t wc = cc / bps; tmsize_t count = cc; uint8_t *cp = (uint8_t *)cp0; uint8_t *tmp; if (cc % (bps * stride) != 0) { TIFFErrorExtR(tif, "fpAcc", "%s", "cc%(bps*stride))!=0"); return 0; } tmp = (uint8_t *)_TIFFmallocExt(tif, cc); if (!tmp) return 0; while (count > stride) { REPEAT4(stride, cp[stride] = (unsigned char)((cp[stride] + cp[0]) & 0xff); cp++) count -= stride; } _TIFFmemcpy(tmp, cp0, cc); cp = (uint8_t *)cp0; for (count = 0; count < wc; count++) { uint32_t byte; for (byte = 0; byte < bps; byte++) { #if WORDS_BIGENDIAN cp[bps * count + byte] = tmp[byte * wc + count]; #else cp[bps * count + byte] = tmp[(bps - byte - 1) * wc + count]; #endif } } _TIFFfreeExt(tif, tmp); return 1; } /* * Decode a scanline and apply the predictor routine. */ static int PredictorDecodeRow(TIFF *tif, uint8_t *op0, tmsize_t occ0, uint16_t s) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != NULL); assert(sp->decoderow != NULL); assert(sp->decodepfunc != NULL); if ((*sp->decoderow)(tif, op0, occ0, s)) { return (*sp->decodepfunc)(tif, op0, occ0); } else return 0; } /* * Decode a tile/strip and apply the predictor routine. * Note that horizontal differencing must be done on a * row-by-row basis. The width of a "row" has already * been calculated at pre-decode time according to the * strip/tile dimensions. */ static int PredictorDecodeTile(TIFF *tif, uint8_t *op0, tmsize_t occ0, uint16_t s) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != NULL); assert(sp->decodetile != NULL); if ((*sp->decodetile)(tif, op0, occ0, s)) { tmsize_t rowsize = sp->rowsize; assert(rowsize > 0); if ((occ0 % rowsize) != 0) { TIFFErrorExtR(tif, "PredictorDecodeTile", "%s", "occ0%rowsize != 0"); return 0; } assert(sp->decodepfunc != NULL); while (occ0 > 0) { if (!(*sp->decodepfunc)(tif, op0, rowsize)) return 0; occ0 -= rowsize; op0 += rowsize; } return 1; } else return 0; } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horDiff8(TIFF *tif, uint8_t *cp0, tmsize_t cc) { TIFFPredictorState *sp = PredictorState(tif); tmsize_t stride = sp->stride; unsigned char *cp = (unsigned char *)cp0; if ((cc % stride) != 0) { TIFFErrorExtR(tif, "horDiff8", "%s", "(cc%stride)!=0"); return 0; } if (cc > stride) { cc -= stride; /* * Pipeline the most common cases. */ if (stride == 3) { unsigned int r1, g1, b1; unsigned int r2 = cp[0]; unsigned int g2 = cp[1]; unsigned int b2 = cp[2]; do { r1 = cp[3]; cp[3] = (unsigned char)((r1 - r2) & 0xff); r2 = r1; g1 = cp[4]; cp[4] = (unsigned char)((g1 - g2) & 0xff); g2 = g1; b1 = cp[5]; cp[5] = (unsigned char)((b1 - b2) & 0xff); b2 = b1; cp += 3; } while ((cc -= 3) > 0); } else if (stride == 4) { unsigned int r1, g1, b1, a1; unsigned int r2 = cp[0]; unsigned int g2 = cp[1]; unsigned int b2 = cp[2]; unsigned int a2 = cp[3]; do { r1 = cp[4]; cp[4] = (unsigned char)((r1 - r2) & 0xff); r2 = r1; g1 = cp[5]; cp[5] = (unsigned char)((g1 - g2) & 0xff); g2 = g1; b1 = cp[6]; cp[6] = (unsigned char)((b1 - b2) & 0xff); b2 = b1; a1 = cp[7]; cp[7] = (unsigned char)((a1 - a2) & 0xff); a2 = a1; cp += 4; } while ((cc -= 4) > 0); } else { cp += cc - 1; do { REPEAT4(stride, cp[stride] = (unsigned char)((cp[stride] - cp[0]) & 0xff); cp--) } while ((cc -= stride) > 0); } } return 1; } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horDiff16(TIFF *tif, uint8_t *cp0, tmsize_t cc) { TIFFPredictorState *sp = PredictorState(tif); tmsize_t stride = sp->stride; uint16_t *wp = (uint16_t *)cp0; tmsize_t wc = cc / 2; if ((cc % (2 * stride)) != 0) { TIFFErrorExtR(tif, "horDiff8", "%s", "(cc%(2*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; wp += wc - 1; do { REPEAT4(stride, wp[stride] = (uint16_t)(((unsigned int)wp[stride] - (unsigned int)wp[0]) & 0xffff); wp--) wc -= stride; } while (wc > 0); } return 1; } static int swabHorDiff16(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint16_t *wp = (uint16_t *)cp0; tmsize_t wc = cc / 2; if (!horDiff16(tif, cp0, cc)) return 0; TIFFSwabArrayOfShort(wp, wc); return 1; } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horDiff32(TIFF *tif, uint8_t *cp0, tmsize_t cc) { TIFFPredictorState *sp = PredictorState(tif); tmsize_t stride = sp->stride; uint32_t *wp = (uint32_t *)cp0; tmsize_t wc = cc / 4; if ((cc % (4 * stride)) != 0) { TIFFErrorExtR(tif, "horDiff32", "%s", "(cc%(4*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; wp += wc - 1; do { REPEAT4(stride, wp[stride] -= wp[0]; wp--) wc -= stride; } while (wc > 0); } return 1; } static int swabHorDiff32(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint32_t *wp = (uint32_t *)cp0; tmsize_t wc = cc / 4; if (!horDiff32(tif, cp0, cc)) return 0; TIFFSwabArrayOfLong(wp, wc); return 1; } TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int horDiff64(TIFF *tif, uint8_t *cp0, tmsize_t cc) { TIFFPredictorState *sp = PredictorState(tif); tmsize_t stride = sp->stride; uint64_t *wp = (uint64_t *)cp0; tmsize_t wc = cc / 8; if ((cc % (8 * stride)) != 0) { TIFFErrorExtR(tif, "horDiff64", "%s", "(cc%(8*stride))!=0"); return 0; } if (wc > stride) { wc -= stride; wp += wc - 1; do { REPEAT4(stride, wp[stride] -= wp[0]; wp--) wc -= stride; } while (wc > 0); } return 1; } static int swabHorDiff64(TIFF *tif, uint8_t *cp0, tmsize_t cc) { uint64_t *wp = (uint64_t *)cp0; tmsize_t wc = cc / 8; if (!horDiff64(tif, cp0, cc)) return 0; TIFFSwabArrayOfLong8(wp, wc); return 1; } /* * Floating point predictor differencing routine. */ TIFF_NOSANITIZE_UNSIGNED_INT_OVERFLOW static int fpDiff(TIFF *tif, uint8_t *cp0, tmsize_t cc) { tmsize_t stride = PredictorState(tif)->stride; uint32_t bps = tif->tif_dir.td_bitspersample / 8; tmsize_t wc = cc / bps; tmsize_t count; uint8_t *cp = (uint8_t *)cp0; uint8_t *tmp; if ((cc % (bps * stride)) != 0) { TIFFErrorExtR(tif, "fpDiff", "%s", "(cc%(bps*stride))!=0"); return 0; } tmp = (uint8_t *)_TIFFmallocExt(tif, cc); if (!tmp) return 0; _TIFFmemcpy(tmp, cp0, cc); for (count = 0; count < wc; count++) { uint32_t byte; for (byte = 0; byte < bps; byte++) { #if WORDS_BIGENDIAN cp[byte * wc + count] = tmp[bps * count + byte]; #else cp[(bps - byte - 1) * wc + count] = tmp[bps * count + byte]; #endif } } _TIFFfreeExt(tif, tmp); cp = (uint8_t *)cp0; cp += cc - stride - 1; for (count = cc; count > stride; count -= stride) REPEAT4(stride, cp[stride] = (unsigned char)((cp[stride] - cp[0]) & 0xff); cp--) return 1; } static int PredictorEncodeRow(TIFF *tif, uint8_t *bp, tmsize_t cc, uint16_t s) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != NULL); assert(sp->encodepfunc != NULL); assert(sp->encoderow != NULL); /* XXX horizontal differencing alters user's data XXX */ if (!(*sp->encodepfunc)(tif, bp, cc)) return 0; return (*sp->encoderow)(tif, bp, cc, s); } static int PredictorEncodeTile(TIFF *tif, uint8_t *bp0, tmsize_t cc0, uint16_t s) { static const char module[] = "PredictorEncodeTile"; TIFFPredictorState *sp = PredictorState(tif); uint8_t *working_copy; tmsize_t cc = cc0, rowsize; unsigned char *bp; int result_code; assert(sp != NULL); assert(sp->encodepfunc != NULL); assert(sp->encodetile != NULL); /* * Do predictor manipulation in a working buffer to avoid altering * the callers buffer. http://trac.osgeo.org/gdal/ticket/1965 */ working_copy = (uint8_t *)_TIFFmallocExt(tif, cc0); if (working_copy == NULL) { TIFFErrorExtR(tif, module, "Out of memory allocating %" PRId64 " byte temp buffer.", (int64_t)cc0); return 0; } memcpy(working_copy, bp0, cc0); bp = working_copy; rowsize = sp->rowsize; assert(rowsize > 0); if ((cc0 % rowsize) != 0) { TIFFErrorExtR(tif, "PredictorEncodeTile", "%s", "(cc0%rowsize)!=0"); _TIFFfreeExt(tif, working_copy); return 0; } while (cc > 0) { (*sp->encodepfunc)(tif, bp, rowsize); cc -= rowsize; bp += rowsize; } result_code = (*sp->encodetile)(tif, working_copy, cc0, s); _TIFFfreeExt(tif, working_copy); return result_code; } #define FIELD_PREDICTOR (FIELD_CODEC + 0) /* XXX */ static const TIFFField predictFields[] = { {TIFFTAG_PREDICTOR, 1, 1, TIFF_SHORT, 0, TIFF_SETGET_UINT16, TIFF_SETGET_UINT16, FIELD_PREDICTOR, FALSE, FALSE, "Predictor", NULL}, }; static int PredictorVSetField(TIFF *tif, uint32_t tag, va_list ap) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != NULL); assert(sp->vsetparent != NULL); switch (tag) { case TIFFTAG_PREDICTOR: sp->predictor = (uint16_t)va_arg(ap, uint16_vap); TIFFSetFieldBit(tif, FIELD_PREDICTOR); break; default: return (*sp->vsetparent)(tif, tag, ap); } tif->tif_flags |= TIFF_DIRTYDIRECT; return 1; } static int PredictorVGetField(TIFF *tif, uint32_t tag, va_list ap) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != NULL); assert(sp->vgetparent != NULL); switch (tag) { case TIFFTAG_PREDICTOR: *va_arg(ap, uint16_t *) = (uint16_t)sp->predictor; break; default: return (*sp->vgetparent)(tif, tag, ap); } return 1; } static void PredictorPrintDir(TIFF *tif, FILE *fd, long flags) { TIFFPredictorState *sp = PredictorState(tif); (void)flags; if (TIFFFieldSet(tif, FIELD_PREDICTOR)) { fprintf(fd, " Predictor: "); switch (sp->predictor) { case 1: fprintf(fd, "none "); break; case 2: fprintf(fd, "horizontal differencing "); break; case 3: fprintf(fd, "floating point predictor "); break; } fprintf(fd, "%d (0x%x)\n", sp->predictor, sp->predictor); } if (sp->printdir) (*sp->printdir)(tif, fd, flags); } int TIFFPredictorInit(TIFF *tif) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != 0); /* * Merge codec-specific tag information. */ if (!_TIFFMergeFields(tif, predictFields, TIFFArrayCount(predictFields))) { TIFFErrorExtR(tif, "TIFFPredictorInit", "Merging Predictor codec-specific tags failed"); return 0; } /* * Override parent get/set field methods. */ sp->vgetparent = tif->tif_tagmethods.vgetfield; tif->tif_tagmethods.vgetfield = PredictorVGetField; /* hook for predictor tag */ sp->vsetparent = tif->tif_tagmethods.vsetfield; tif->tif_tagmethods.vsetfield = PredictorVSetField; /* hook for predictor tag */ sp->printdir = tif->tif_tagmethods.printdir; tif->tif_tagmethods.printdir = PredictorPrintDir; /* hook for predictor tag */ sp->setupdecode = tif->tif_setupdecode; tif->tif_setupdecode = PredictorSetupDecode; sp->setupencode = tif->tif_setupencode; tif->tif_setupencode = PredictorSetupEncode; sp->predictor = 1; /* default value */ sp->encodepfunc = NULL; /* no predictor routine */ sp->decodepfunc = NULL; /* no predictor routine */ return 1; } int TIFFPredictorCleanup(TIFF *tif) { TIFFPredictorState *sp = PredictorState(tif); assert(sp != 0); tif->tif_tagmethods.vgetfield = sp->vgetparent; tif->tif_tagmethods.vsetfield = sp->vsetparent; tif->tif_tagmethods.printdir = sp->printdir; tif->tif_setupdecode = sp->setupdecode; tif->tif_setupencode = sp->setupencode; return 1; }