Pillow/src/libImaging/TiffDecode.c

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/*
* The Python Imaging Library.
* $Id: //modules/pil/libImaging/TiffDecode.c#1 $
*
* LibTiff-based Group3 and Group4 decoder
*
*
* started modding to use non-private tiff functions to port to libtiff 4.x
* eds 3/12/12
*
*/
#include "Imaging.h"
#ifdef HAVE_LIBTIFF
#ifndef uint
#define uint uint32
#endif
#include "TiffDecode.h"
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/* Convert C file descriptor to WinApi HFILE if LibTiff was compiled with tif_win32.c
*
* This cast is safe, as the top 32-bits of HFILE are guaranteed to be zero,
* see https://docs.microsoft.com/en-us/windows/win32/winprog64/interprocess-communication
*/
#ifndef USE_WIN32_FILEIO
#define fd_to_tiff_fd(fd) (fd)
#else
#define fd_to_tiff_fd(fd) ((int)_get_osfhandle(fd))
#endif
void dump_state(const TIFFSTATE *state){
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TRACE(("State: Location %u size %d eof %d data: %p ifd: %d\n", (uint)state->loc,
(int)state->size, (uint)state->eof, state->data, state->ifd));
}
/*
procs for TIFFOpenClient
*/
tsize_t _tiffReadProc(thandle_t hdata, tdata_t buf, tsize_t size) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
tsize_t to_read;
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TRACE(("_tiffReadProc: %d \n", (int)size));
dump_state(state);
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to_read = min(size, min(state->size, (tsize_t)state->eof) - (tsize_t)state->loc);
TRACE(("to_read: %d\n", (int)to_read));
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_TIFFmemcpy(buf, (UINT8 *)state->data + state->loc, to_read);
state->loc += (toff_t)to_read;
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TRACE( ("location: %u\n", (uint)state->loc));
return to_read;
}
tsize_t _tiffWriteProc(thandle_t hdata, tdata_t buf, tsize_t size) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
tsize_t to_write;
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TRACE(("_tiffWriteProc: %d \n", (int)size));
dump_state(state);
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to_write = min(size, state->size - (tsize_t)state->loc);
if (state->flrealloc && size>to_write) {
tdata_t new_data;
tsize_t newsize=state->size;
while (newsize < (size + state->size)) {
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if (newsize > INT_MAX - 64*1024){
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return 0;
}
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newsize += 64*1024;
// newsize*=2; // UNDONE, by 64k chunks?
}
TRACE(("Reallocing in write to %d bytes\n", (int)newsize));
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/* malloc check ok, overflow checked above */
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new_data = realloc(state->data, newsize);
if (!new_data) {
// fail out
return 0;
}
state->data = new_data;
state->size = newsize;
to_write = size;
}
TRACE(("to_write: %d\n", (int)to_write));
_TIFFmemcpy((UINT8 *)state->data + state->loc, buf, to_write);
state->loc += (toff_t)to_write;
state->eof = max(state->loc, state->eof);
dump_state(state);
return to_write;
}
toff_t _tiffSeekProc(thandle_t hdata, toff_t off, int whence) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
TRACE(("_tiffSeekProc: off: %u whence: %d \n", (uint)off, whence));
dump_state(state);
switch (whence) {
case 0:
state->loc = off;
break;
case 1:
state->loc += off;
break;
case 2:
state->loc = state->eof + off;
break;
}
dump_state(state);
return state->loc;
}
int _tiffCloseProc(thandle_t hdata) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
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TRACE(("_tiffCloseProc \n"));
dump_state(state);
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return 0;
}
toff_t _tiffSizeProc(thandle_t hdata) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
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TRACE(("_tiffSizeProc \n"));
dump_state(state);
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return (toff_t)state->size;
}
int _tiffMapProc(thandle_t hdata, tdata_t* pbase, toff_t* psize) {
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TIFFSTATE *state = (TIFFSTATE *)hdata;
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TRACE(("_tiffMapProc input size: %u, data: %p\n", (uint)*psize, *pbase));
dump_state(state);
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*pbase = state->data;
*psize = state->size;
TRACE(("_tiffMapProc returning size: %u, data: %p\n", (uint)*psize, *pbase));
return (1);
}
int _tiffNullMapProc(thandle_t hdata, tdata_t* pbase, toff_t* psize) {
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(void) hdata; (void) pbase; (void) psize;
return (0);
}
void _tiffUnmapProc(thandle_t hdata, tdata_t base, toff_t size) {
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TRACE(("_tiffUnMapProc\n"));
(void) hdata; (void) base; (void) size;
}
int ImagingLibTiffInit(ImagingCodecState state, int fp, uint32 offset) {
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TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
TRACE(("initing libtiff\n"));
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TRACE(("filepointer: %d \n", fp));
TRACE(("State: count %d, state %d, x %d, y %d, ystep %d\n", state->count, state->state,
state->x, state->y, state->ystep));
TRACE(("State: xsize %d, ysize %d, xoff %d, yoff %d \n", state->xsize, state->ysize,
state->xoff, state->yoff));
TRACE(("State: bits %d, bytes %d \n", state->bits, state->bytes));
TRACE(("State: context %p \n", state->context));
clientstate->loc = 0;
clientstate->size = 0;
clientstate->data = 0;
clientstate->fp = fp;
clientstate->ifd = offset;
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clientstate->eof = 0;
return 1;
}
int ReadTile(TIFF* tiff, UINT32 col, UINT32 row, UINT32* buffer) {
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uint16 photometric = 0;
TIFFGetField(tiff, TIFFTAG_PHOTOMETRIC, &photometric);
// To avoid dealing with YCbCr subsampling, let libtiff handle it
if (photometric == PHOTOMETRIC_YCBCR) {
UINT32 tile_width, tile_height, swap_line_size, i_row;
UINT32* swap_line;
TIFFGetField(tiff, TIFFTAG_TILEWIDTH, &tile_width);
TIFFGetField(tiff, TIFFTAG_TILELENGTH, &tile_height);
swap_line_size = tile_width * sizeof(UINT32);
if (tile_width != swap_line_size / sizeof(UINT32)) {
return -1;
}
/* Read the tile into an RGBA array */
if (!TIFFReadRGBATile(tiff, col, row, buffer)) {
return -1;
}
swap_line = (UINT32*)malloc(swap_line_size);
if (swap_line == NULL) {
return -1;
}
/*
* For some reason the TIFFReadRGBATile() function chooses the
* lower left corner as the origin. Vertically mirror scanlines.
*/
for(i_row = 0; i_row < tile_height / 2; i_row++) {
UINT32 *top_line, *bottom_line;
top_line = buffer + tile_width * i_row;
bottom_line = buffer + tile_width * (tile_height - i_row - 1);
memcpy(swap_line, top_line, 4*tile_width);
memcpy(top_line, bottom_line, 4*tile_width);
memcpy(bottom_line, swap_line, 4*tile_width);
}
free(swap_line);
return 0;
}
if (TIFFReadTile(tiff, (tdata_t)buffer, col, row, 0, 0) == -1) {
TRACE(("Decode Error, Tile at %dx%d\n", col, row));
return -1;
}
TRACE(("Successfully read tile at %dx%d; \n\n", col, row));
return 0;
}
int ReadStrip(TIFF* tiff, UINT32 row, UINT32* buffer) {
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uint16 photometric = 0; // init to not PHOTOMETRIC_YCBCR
TIFFGetField(tiff, TIFFTAG_PHOTOMETRIC, &photometric);
// To avoid dealing with YCbCr subsampling, let libtiff handle it
if (photometric == PHOTOMETRIC_YCBCR) {
TIFFRGBAImage img;
char emsg[1024] = "";
UINT32 rows_per_strip, rows_to_read;
int ok;
TIFFGetFieldDefaulted(tiff, TIFFTAG_ROWSPERSTRIP, &rows_per_strip);
if ((row % rows_per_strip) != 0) {
TRACE(("Row passed to ReadStrip() must be first in a strip."));
return -1;
}
if (TIFFRGBAImageOK(tiff, emsg) && TIFFRGBAImageBegin(&img, tiff, 0, emsg)) {
TRACE(("Initialized RGBAImage\n"));
img.req_orientation = ORIENTATION_TOPLEFT;
img.row_offset = row;
img.col_offset = 0;
rows_to_read = min(rows_per_strip, img.height - row);
TRACE(("rows to read: %d\n", rows_to_read));
ok = TIFFRGBAImageGet(&img, buffer, img.width, rows_to_read);
TIFFRGBAImageEnd(&img);
} else {
ok = 0;
}
if (ok == 0) {
TRACE(("Decode Error, row %d; msg: %s\n", row, emsg));
return -1;
}
return 0;
}
if (TIFFReadEncodedStrip(tiff, TIFFComputeStrip(tiff, row, 0), (tdata_t)buffer, -1) == -1) {
TRACE(("Decode Error, strip %d\n", TIFFComputeStrip(tiff, row, 0)));
return -1;
}
return 0;
}
int ImagingLibTiffDecode(Imaging im, ImagingCodecState state, UINT8* buffer, Py_ssize_t bytes) {
TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
char *filename = "tempfile.tif";
char *mode = "r";
TIFF *tiff;
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/* buffer is the encoded file, bytes is the length of the encoded file */
/* it all ends up in state->buffer, which is a uint8* from Imaging.h */
TRACE(("in decoder: bytes %d\n", bytes));
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TRACE(("State: count %d, state %d, x %d, y %d, ystep %d\n", state->count, state->state,
state->x, state->y, state->ystep));
TRACE(("State: xsize %d, ysize %d, xoff %d, yoff %d \n", state->xsize, state->ysize,
state->xoff, state->yoff));
TRACE(("State: bits %d, bytes %d \n", state->bits, state->bytes));
TRACE(("Buffer: %p: %c%c%c%c\n", buffer, (char)buffer[0], (char)buffer[1],(char)buffer[2], (char)buffer[3]));
TRACE(("State->Buffer: %c%c%c%c\n", (char)state->buffer[0], (char)state->buffer[1],(char)state->buffer[2], (char)state->buffer[3]));
TRACE(("Image: mode %s, type %d, bands: %d, xsize %d, ysize %d \n",
im->mode, im->type, im->bands, im->xsize, im->ysize));
TRACE(("Image: image8 %p, image32 %p, image %p, block %p \n",
im->image8, im->image32, im->image, im->block));
TRACE(("Image: pixelsize: %d, linesize %d \n",
im->pixelsize, im->linesize));
dump_state(clientstate);
clientstate->size = bytes;
clientstate->eof = clientstate->size;
clientstate->loc = 0;
clientstate->data = (tdata_t)buffer;
clientstate->flrealloc = 0;
dump_state(clientstate);
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TIFFSetWarningHandler(NULL);
TIFFSetWarningHandlerExt(NULL);
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if (clientstate->fp) {
TRACE(("Opening using fd: %d\n",clientstate->fp));
lseek(clientstate->fp,0,SEEK_SET); // Sometimes, I get it set to the end.
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tiff = TIFFFdOpen(fd_to_tiff_fd(clientstate->fp), filename, mode);
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} else {
TRACE(("Opening from string\n"));
tiff = TIFFClientOpen(filename, mode,
(thandle_t) clientstate,
_tiffReadProc, _tiffWriteProc,
_tiffSeekProc, _tiffCloseProc, _tiffSizeProc,
_tiffMapProc, _tiffUnmapProc);
}
if (!tiff){
TRACE(("Error, didn't get the tiff\n"));
state->errcode = IMAGING_CODEC_BROKEN;
return -1;
}
if (clientstate->ifd){
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int rv;
uint32 ifdoffset = clientstate->ifd;
TRACE(("reading tiff ifd %u\n", ifdoffset));
rv = TIFFSetSubDirectory(tiff, ifdoffset);
if (!rv){
TRACE(("error in TIFFSetSubDirectory"));
return -1;
}
}
if (TIFFIsTiled(tiff)) {
UINT32 x, y, tile_y, row_byte_size;
UINT32 tile_width, tile_length, current_tile_width;
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UINT8 *new_data;
TIFFGetField(tiff, TIFFTAG_TILEWIDTH, &tile_width);
TIFFGetField(tiff, TIFFTAG_TILELENGTH, &tile_length);
// We could use TIFFTileSize, but for YCbCr data it returns subsampled data size
row_byte_size = (tile_width * state->bits + 7) / 8;
/* overflow check for realloc */
if (INT_MAX / row_byte_size < tile_length) {
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
state->bytes = row_byte_size * tile_length;
if (TIFFTileSize(tiff) > state->bytes) {
// If the strip size as expected by LibTiff isn't what we're expecting, abort.
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
/* realloc to fit whole tile */
/* malloc check above */
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new_data = realloc (state->buffer, state->bytes);
if (!new_data) {
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
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state->buffer = new_data;
TRACE(("TIFFTileSize: %d\n", state->bytes));
for (y = state->yoff; y < state->ysize; y += tile_length) {
for (x = state->xoff; x < state->xsize; x += tile_width) {
if (ReadTile(tiff, x, y, (UINT32*) state->buffer) == -1) {
TRACE(("Decode Error, Tile at %dx%d\n", x, y));
state->errcode = IMAGING_CODEC_BROKEN;
TIFFClose(tiff);
return -1;
}
TRACE(("Read tile at %dx%d; \n\n", x, y));
current_tile_width = min(tile_width, state->xsize - x);
// iterate over each line in the tile and stuff data into image
for (tile_y = 0; tile_y < min(tile_length, state->ysize - y); tile_y++) {
TRACE(("Writing tile data at %dx%d using tile_width: %d; \n", tile_y + y, x, current_tile_width));
// UINT8 * bbb = state->buffer + tile_y * row_byte_size;
// TRACE(("chars: %x%x%x%x\n", ((UINT8 *)bbb)[0], ((UINT8 *)bbb)[1], ((UINT8 *)bbb)[2], ((UINT8 *)bbb)[3]));
state->shuffle((UINT8*) im->image[tile_y + y] + x * im->pixelsize,
state->buffer + tile_y * row_byte_size,
current_tile_width
);
}
}
}
} else {
UINT32 strip_row, row_byte_size;
UINT8 *new_data;
UINT32 rows_per_strip;
int ret;
ret = TIFFGetField(tiff, TIFFTAG_ROWSPERSTRIP, &rows_per_strip);
if (ret != 1) {
rows_per_strip = state->ysize;
}
TRACE(("RowsPerStrip: %u \n", rows_per_strip));
// We could use TIFFStripSize, but for YCbCr data it returns subsampled data size
row_byte_size = (state->xsize * state->bits + 7) / 8;
/* overflow check for realloc */
if (INT_MAX / row_byte_size < rows_per_strip) {
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
state->bytes = rows_per_strip * row_byte_size;
TRACE(("StripSize: %d \n", state->bytes));
if (TIFFStripSize(tiff) > state->bytes) {
// If the strip size as expected by LibTiff isn't what we're expecting, abort.
// man: TIFFStripSize returns the equivalent size for a strip of data as it would be returned in a
// call to TIFFReadEncodedStrip ...
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
/* realloc to fit whole strip */
/* malloc check above */
new_data = realloc (state->buffer, state->bytes);
if (!new_data) {
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
return -1;
}
state->buffer = new_data;
for (; state->y < state->ysize; state->y += rows_per_strip) {
if (ReadStrip(tiff, state->y, (UINT32 *)state->buffer) == -1) {
TRACE(("Decode Error, strip %d\n", TIFFComputeStrip(tiff, state->y, 0)));
state->errcode = IMAGING_CODEC_BROKEN;
TIFFClose(tiff);
return -1;
}
TRACE(("Decoded strip for row %d \n", state->y));
// iterate over each row in the strip and stuff data into image
for (strip_row = 0; strip_row < min(rows_per_strip, state->ysize - state->y); strip_row++) {
TRACE(("Writing data into line %d ; \n", state->y + strip_row));
// UINT8 * bbb = state->buffer + strip_row * (state->bytes / rows_per_strip);
// TRACE(("chars: %x %x %x %x\n", ((UINT8 *)bbb)[0], ((UINT8 *)bbb)[1], ((UINT8 *)bbb)[2], ((UINT8 *)bbb)[3]));
state->shuffle((UINT8*) im->image[state->y + state->yoff + strip_row] +
state->xoff * im->pixelsize,
state->buffer + strip_row * row_byte_size,
state->xsize);
}
}
}
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TIFFClose(tiff);
TRACE(("Done Decoding, Returning \n"));
// Returning -1 here to force ImageFile.load to break, rather than
// even think about looping back around.
return -1;
}
int ImagingLibTiffEncodeInit(ImagingCodecState state, char *filename, int fp) {
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// Open the FD or the pointer as a tiff file, for writing.
// We may have to do some monkeying around to make this really work.
// If we have a fp, then we're good.
// If we have a memory string, we're probably going to have to malloc, then
// shuffle bytes into the writescanline process.
// Going to have to deal with the directory as well.
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TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
int bufsize = 64*1024;
char *mode = "w";
TRACE(("initing libtiff\n"));
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TRACE(("Filename %s, filepointer: %d \n", filename, fp));
TRACE(("State: count %d, state %d, x %d, y %d, ystep %d\n", state->count, state->state,
state->x, state->y, state->ystep));
TRACE(("State: xsize %d, ysize %d, xoff %d, yoff %d \n", state->xsize, state->ysize,
state->xoff, state->yoff));
TRACE(("State: bits %d, bytes %d \n", state->bits, state->bytes));
TRACE(("State: context %p \n", state->context));
clientstate->loc = 0;
clientstate->size = 0;
clientstate->eof =0;
clientstate->data = 0;
clientstate->flrealloc = 0;
clientstate->fp = fp;
state->state = 0;
if (fp) {
TRACE(("Opening using fd: %d for writing \n",clientstate->fp));
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clientstate->tiff = TIFFFdOpen(fd_to_tiff_fd(clientstate->fp), filename, mode);
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} else {
// malloc a buffer to write the tif, we're going to need to realloc or something if we need bigger.
TRACE(("Opening a buffer for writing \n"));
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/* malloc check ok, small constant allocation */
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clientstate->data = malloc(bufsize);
clientstate->size = bufsize;
clientstate->flrealloc=1;
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if (!clientstate->data) {
TRACE(("Error, couldn't allocate a buffer of size %d\n", bufsize));
return 0;
}
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clientstate->tiff = TIFFClientOpen(filename, mode,
(thandle_t) clientstate,
_tiffReadProc, _tiffWriteProc,
_tiffSeekProc, _tiffCloseProc, _tiffSizeProc,
_tiffNullMapProc, _tiffUnmapProc); /*force no mmap*/
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}
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if (!clientstate->tiff) {
TRACE(("Error, couldn't open tiff file\n"));
return 0;
}
return 1;
}
int ImagingLibTiffMergeFieldInfo(ImagingCodecState state, TIFFDataType field_type, int key, int is_var_length){
// Refer to libtiff docs (http://www.simplesystems.org/libtiff/addingtags.html)
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TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
char field_name[10];
uint32 n;
int status = 0;
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// custom fields added with ImagingLibTiffMergeFieldInfo are only used for
// decoding, ignore readcount;
int readcount = 0;
// we support writing a single value, or a variable number of values
int writecount = 1;
// whether the first value should encode the number of values.
int passcount = 0;
TIFFFieldInfo info[] = {
{ key, readcount, writecount, field_type, FIELD_CUSTOM, 1, passcount, field_name }
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};
if (is_var_length) {
info[0].field_writecount = -1;
}
if (is_var_length && field_type != TIFF_ASCII) {
info[0].field_passcount = 1;
}
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n = sizeof(info) / sizeof(info[0]);
// Test for libtiff 4.0 or later, excluding libtiff 3.9.6 and 3.9.7
#if TIFFLIB_VERSION >= 20111221 && TIFFLIB_VERSION != 20120218 && TIFFLIB_VERSION != 20120922
status = TIFFMergeFieldInfo(clientstate->tiff, info, n);
#else
TIFFMergeFieldInfo(clientstate->tiff, info, n);
#endif
return status;
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}
int ImagingLibTiffSetField(ImagingCodecState state, ttag_t tag, ...){
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// after tif_dir.c->TIFFSetField.
TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
va_list ap;
int status;
va_start(ap, tag);
status = TIFFVSetField(clientstate->tiff, tag, ap);
va_end(ap);
return status;
}
int ImagingLibTiffEncode(Imaging im, ImagingCodecState state, UINT8* buffer, int bytes) {
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/* One shot encoder. Encode everything to the tiff in the clientstate.
If we're running off of a FD, then run once, we're good, everything
ends up in the file, we close and we're done.
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If we're going to memory, then we need to write the whole file into memory, then
parcel it back out to the pystring buffer bytes at a time.
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*/
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TIFFSTATE *clientstate = (TIFFSTATE *)state->context;
TIFF *tiff = clientstate->tiff;
TRACE(("in encoder: bytes %d\n", bytes));
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TRACE(("State: count %d, state %d, x %d, y %d, ystep %d\n", state->count, state->state,
state->x, state->y, state->ystep));
TRACE(("State: xsize %d, ysize %d, xoff %d, yoff %d \n", state->xsize, state->ysize,
state->xoff, state->yoff));
TRACE(("State: bits %d, bytes %d \n", state->bits, state->bytes));
TRACE(("Buffer: %p: %c%c%c%c\n", buffer, (char)buffer[0], (char)buffer[1],(char)buffer[2], (char)buffer[3]));
TRACE(("State->Buffer: %c%c%c%c\n", (char)state->buffer[0], (char)state->buffer[1],(char)state->buffer[2], (char)state->buffer[3]));
TRACE(("Image: mode %s, type %d, bands: %d, xsize %d, ysize %d \n",
im->mode, im->type, im->bands, im->xsize, im->ysize));
TRACE(("Image: image8 %p, image32 %p, image %p, block %p \n",
im->image8, im->image32, im->image, im->block));
TRACE(("Image: pixelsize: %d, linesize %d \n",
im->pixelsize, im->linesize));
dump_state(clientstate);
if (state->state == 0) {
TRACE(("Encoding line bt line"));
while(state->y < state->ysize){
state->shuffle(state->buffer,
(UINT8*) im->image[state->y + state->yoff] +
state->xoff * im->pixelsize,
state->xsize);
if (TIFFWriteScanline(tiff, (tdata_t)(state->buffer), (uint32)state->y, 0) == -1) {
TRACE(("Encode Error, row %d\n", state->y));
state->errcode = IMAGING_CODEC_BROKEN;
TIFFClose(tiff);
if (!clientstate->fp){
free(clientstate->data);
}
return -1;
}
state->y++;
}
if (state->y == state->ysize) {
state->state=1;
TRACE(("Flushing \n"));
if (!TIFFFlush(tiff)) {
TRACE(("Error flushing the tiff"));
// likely reason is memory.
state->errcode = IMAGING_CODEC_MEMORY;
TIFFClose(tiff);
if (!clientstate->fp){
free(clientstate->data);
}
return -1;
}
TRACE(("Closing \n"));
TIFFClose(tiff);
// reset the clientstate metadata to use it to read out the buffer.
clientstate->loc = 0;
clientstate->size = clientstate->eof; // redundant?
}
}
if (state->state == 1 && !clientstate->fp) {
int read = (int)_tiffReadProc(clientstate, (tdata_t)buffer, (tsize_t)bytes);
TRACE(("Buffer: %p: %c%c%c%c\n", buffer, (char)buffer[0], (char)buffer[1],(char)buffer[2], (char)buffer[3]));
if (clientstate->loc == clientstate->eof) {
TRACE(("Hit EOF, calling an end, freeing data"));
state->errcode = IMAGING_CODEC_END;
free(clientstate->data);
}
return read;
}
state->errcode = IMAGING_CODEC_END;
return 0;
}
const char*
ImagingTiffVersion(void)
{
return TIFFGetVersion();
}
#endif