/* * tiff.c * * $Id$ * * ***** BEGIN GPL LICENSE BLOCK ***** * * 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, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * Contributor(s): Jonathan Merritt. * * ***** END GPL LICENSE BLOCK ***** */ /** \file blender/imbuf/intern/tiff.c * \ingroup imbuf */ /** * Provides TIFF file loading and saving for Blender, via libtiff. * * The task of loading is complicated somewhat by the fact that Blender has * already loaded the file into a memory buffer. libtiff is not well * configured to handle files in memory, so a client wrapper is written to * surround the memory and turn it into a virtual file. Currently, reading * of TIFF files is done using libtiff's RGBAImage support. This is a * high-level routine that loads all images as 32-bit RGBA, handling all the * required conversions between many different TIFF types internally. * * Saving supports RGB, RGBA and BW (greyscale) images correctly, with * 8 bits per channel in all cases. The "deflate" compression algorithm is * used to compress images. */ #ifdef WITH_TIFF #include #include "imbuf.h" #include "BLI_math.h" #include "BLI_string.h" #include "BLI_utildefines.h" #include "BKE_global.h" #include "IMB_imbuf_types.h" #include "IMB_imbuf.h" #include "IMB_allocimbuf.h" #include "IMB_filetype.h" #include "IMB_filter.h" #include "tiffio.h" /*********************** * Local declarations. * ***********************/ /* Reading and writing of an in-memory TIFF file. */ static tsize_t imb_tiff_ReadProc(thandle_t handle, tdata_t data, tsize_t n); static tsize_t imb_tiff_WriteProc(thandle_t handle, tdata_t data, tsize_t n); static toff_t imb_tiff_SeekProc(thandle_t handle, toff_t ofs, int whence); static int imb_tiff_CloseProc(thandle_t handle); static toff_t imb_tiff_SizeProc(thandle_t handle); static int imb_tiff_DummyMapProc(thandle_t fd, tdata_t* pbase, toff_t* psize); static void imb_tiff_DummyUnmapProc(thandle_t fd, tdata_t base, toff_t size); /* Structure for in-memory TIFF file. */ typedef struct ImbTIFFMemFile { unsigned char *mem; /* Location of first byte of TIFF file. */ toff_t offset; /* Current offset within the file. */ tsize_t size; /* Size of the TIFF file. */ } ImbTIFFMemFile; #define IMB_TIFF_GET_MEMFILE(x) ((ImbTIFFMemFile*)(x)); /***************************** * Function implementations. * *****************************/ static void imb_tiff_DummyUnmapProc(thandle_t fd, tdata_t base, toff_t size) { (void)fd; (void)base; (void)size; } static int imb_tiff_DummyMapProc(thandle_t fd, tdata_t* pbase, toff_t* psize) { (void)fd; (void)pbase; (void)psize; return (0); } /** * Reads data from an in-memory TIFF file. * * @param handle: Handle of the TIFF file (pointer to ImbTIFFMemFile). * @param data: Buffer to contain data (treat as void*). * @param n: Number of bytes to read. * * @return: Number of bytes actually read. * 0 = EOF. */ static tsize_t imb_tiff_ReadProc(thandle_t handle, tdata_t data, tsize_t n) { tsize_t nRemaining, nCopy; ImbTIFFMemFile* mfile; void *srcAddr; /* get the pointer to the in-memory file */ mfile = IMB_TIFF_GET_MEMFILE(handle); if(!mfile || !mfile->mem) { fprintf(stderr, "imb_tiff_ReadProc: !mfile || !mfile->mem!\n"); return 0; } /* find the actual number of bytes to read (copy) */ nCopy = n; if((tsize_t)mfile->offset >= mfile->size) nRemaining = 0; else nRemaining = mfile->size - mfile->offset; if(nCopy > nRemaining) nCopy = nRemaining; /* on EOF, return immediately and read (copy) nothing */ if(nCopy <= 0) return (0); /* all set -> do the read (copy) */ srcAddr = (void*)(&(mfile->mem[mfile->offset])); memcpy((void*)data, srcAddr, nCopy); mfile->offset += nCopy; /* advance file ptr by copied bytes */ return nCopy; } /** * Writes data to an in-memory TIFF file. * * NOTE: The current Blender implementation should not need this function. It * is simply a stub. */ static tsize_t imb_tiff_WriteProc(thandle_t handle, tdata_t data, tsize_t n) { (void)handle; (void)data; (void)n; printf("imb_tiff_WriteProc: this function should not be called.\n"); return (-1); } /** * Seeks to a new location in an in-memory TIFF file. * * @param handle: Handle of the TIFF file (pointer to ImbTIFFMemFile). * @param ofs: Offset value (interpreted according to whence below). * @param whence: This can be one of three values: * SEEK_SET - The offset is set to ofs bytes. * SEEK_CUR - The offset is set to its current location plus ofs bytes. * SEEK_END - (This is unsupported and will return -1, indicating an * error). * * @return: Resulting offset location within the file, measured in bytes from * the beginning of the file. (-1) indicates an error. */ static toff_t imb_tiff_SeekProc(thandle_t handle, toff_t ofs, int whence) { ImbTIFFMemFile *mfile; toff_t new_offset; /* get the pointer to the in-memory file */ mfile = IMB_TIFF_GET_MEMFILE(handle); if(!mfile || !mfile->mem) { fprintf(stderr, "imb_tiff_SeekProc: !mfile || !mfile->mem!\n"); return (-1); } /* find the location we plan to seek to */ switch (whence) { case SEEK_SET: new_offset = ofs; break; case SEEK_CUR: new_offset = mfile->offset + ofs; break; default: /* no other types are supported - return an error */ fprintf(stderr, "imb_tiff_SeekProc: " "Unsupported TIFF SEEK type.\n"); return (-1); } /* set the new location */ mfile->offset = new_offset; return mfile->offset; } /** * Closes (virtually) an in-memory TIFF file. * * NOTE: All this function actually does is sets the data pointer within the * TIFF file to NULL. That should trigger assertion errors if attempts * are made to access the file after that point. However, no such * attempts should ever be made (in theory). * * @param handle: Handle of the TIFF file (pointer to ImbTIFFMemFile). * * @return: 0 */ static int imb_tiff_CloseProc(thandle_t handle) { ImbTIFFMemFile *mfile; /* get the pointer to the in-memory file */ mfile = IMB_TIFF_GET_MEMFILE(handle); if(!mfile || !mfile->mem) { fprintf(stderr,"imb_tiff_CloseProc: !mfile || !mfile->mem!\n"); return (0); } /* virtually close the file */ mfile->mem = NULL; mfile->offset = 0; mfile->size = 0; return (0); } /** * Returns the size of an in-memory TIFF file in bytes. * * @return: Size of file (in bytes). */ static toff_t imb_tiff_SizeProc(thandle_t handle) { ImbTIFFMemFile* mfile; /* get the pointer to the in-memory file */ mfile = IMB_TIFF_GET_MEMFILE(handle); if(!mfile || !mfile->mem) { fprintf(stderr,"imb_tiff_SizeProc: !mfile || !mfile->mem!\n"); return (0); } /* return the size */ return (toff_t)(mfile->size); } static TIFF *imb_tiff_client_open(ImbTIFFMemFile *memFile, unsigned char *mem, size_t size) { /* open the TIFF client layer interface to the in-memory file */ memFile->mem = mem; memFile->offset = 0; memFile->size = size; return TIFFClientOpen("(Blender TIFF Interface Layer)", "r", (thandle_t)(memFile), imb_tiff_ReadProc, imb_tiff_WriteProc, imb_tiff_SeekProc, imb_tiff_CloseProc, imb_tiff_SizeProc, imb_tiff_DummyMapProc, imb_tiff_DummyUnmapProc); } /** * Checks whether a given memory buffer contains a TIFF file. * * This method uses the format identifiers from: * http://www.faqs.org/faqs/graphics/fileformats-faq/part4/section-9.html * The first four bytes of big-endian and little-endian TIFF files * respectively are (hex): * 4d 4d 00 2a * 49 49 2a 00 * Note that TIFF files on *any* platform can be either big- or little-endian; * it's not platform-specific. * * AFAICT, libtiff doesn't provide a method to do this automatically, and * hence my manual comparison. - Jonathan Merritt (lancelet) 4th Sept 2005. */ #define IMB_TIFF_NCB 4 /* number of comparison bytes used */ int imb_is_a_tiff(unsigned char *mem) { char big_endian[IMB_TIFF_NCB] = { 0x4d, 0x4d, 0x00, 0x2a }; char lil_endian[IMB_TIFF_NCB] = { 0x49, 0x49, 0x2a, 0x00 }; return ( (memcmp(big_endian, mem, IMB_TIFF_NCB) == 0) || (memcmp(lil_endian, mem, IMB_TIFF_NCB) == 0) ); } static void scanline_contig_16bit(float *rectf, unsigned short *sbuf, int scanline_w, int spp) { int i; for (i=0; i < scanline_w; i++) { rectf[i*4 + 0] = sbuf[i*spp + 0] / 65535.0; rectf[i*4 + 1] = sbuf[i*spp + 1] / 65535.0; rectf[i*4 + 2] = sbuf[i*spp + 2] / 65535.0; rectf[i*4 + 3] = (spp==4)?(sbuf[i*spp + 3] / 65535.0):1.0; } } static void scanline_contig_32bit(float *rectf, float *fbuf, int scanline_w, int spp) { int i; for (i=0; i < scanline_w; i++) { rectf[i*4 + 0] = fbuf[i*spp + 0]; rectf[i*4 + 1] = fbuf[i*spp + 1]; rectf[i*4 + 2] = fbuf[i*spp + 2]; rectf[i*4 + 3] = (spp==4)?fbuf[i*spp + 3]:1.0f; } } static void scanline_separate_16bit(float *rectf, unsigned short *sbuf, int scanline_w, int chan) { int i; for (i=0; i < scanline_w; i++) rectf[i*4 + chan] = sbuf[i] / 65535.0; } static void scanline_separate_32bit(float *rectf, float *fbuf, int scanline_w, int chan) { int i; for (i=0; i < scanline_w; i++) rectf[i*4 + chan] = fbuf[i]; } /* * Use the libTIFF scanline API to read a TIFF image. * This method is most flexible and can handle multiple different bit depths * and RGB channel orderings. */ static int imb_read_tiff_pixels(ImBuf *ibuf, TIFF *image, int premul) { ImBuf *tmpibuf; int success= 0; short bitspersample, spp, config; size_t scanline; int ib_flag=0, row, chan; float *fbuf=NULL; unsigned short *sbuf=NULL; TIFFGetField(image, TIFFTAG_BITSPERSAMPLE, &bitspersample); TIFFGetField(image, TIFFTAG_SAMPLESPERPIXEL, &spp); /* number of 'channels' */ TIFFGetField(image, TIFFTAG_PLANARCONFIG, &config); scanline = TIFFScanlineSize(image); if (bitspersample == 32) { ib_flag = IB_rectfloat; fbuf = (float *)_TIFFmalloc(scanline); } else if (bitspersample == 16) { ib_flag = IB_rectfloat; sbuf = (unsigned short *)_TIFFmalloc(scanline); } else { ib_flag = IB_rect; } tmpibuf= IMB_allocImBuf(ibuf->x, ibuf->y, ibuf->depth, ib_flag); /* simple RGBA image */ if (!(bitspersample == 32 || bitspersample == 16)) { success |= TIFFReadRGBAImage(image, ibuf->x, ibuf->y, tmpibuf->rect, 0); } /* contiguous channels: RGBRGBRGB */ else if (config == PLANARCONFIG_CONTIG) { for (row = 0; row < ibuf->y; row++) { int ib_offset = ibuf->x*ibuf->y*4 - ibuf->x*4 * (row+1); if (bitspersample == 32) { success |= TIFFReadScanline(image, fbuf, row, 0); scanline_contig_32bit(tmpibuf->rect_float+ib_offset, fbuf, ibuf->x, spp); } else if (bitspersample == 16) { success |= TIFFReadScanline(image, sbuf, row, 0); scanline_contig_16bit(tmpibuf->rect_float+ib_offset, sbuf, ibuf->x, spp); } } /* separate channels: RRRGGGBBB */ } else if (config == PLANARCONFIG_SEPARATE) { /* imbufs always have 4 channels of data, so we iterate over all of them * but only fill in from the TIFF scanline where necessary. */ for (chan = 0; chan < 4; chan++) { for (row = 0; row < ibuf->y; row++) { int ib_offset = ibuf->x*ibuf->y*4 - ibuf->x*4 * (row+1); if (bitspersample == 32) { if (chan == 3 && spp == 3) /* fill alpha if only RGB TIFF */ memset(fbuf, 1.0, sizeof(fbuf)); else success |= TIFFReadScanline(image, fbuf, row, chan); scanline_separate_32bit(tmpibuf->rect_float+ib_offset, fbuf, ibuf->x, chan); } else if (bitspersample == 16) { if (chan == 3 && spp == 3) /* fill alpha if only RGB TIFF */ memset(sbuf, 65535, sizeof(sbuf)); else success |= TIFFReadScanline(image, sbuf, row, chan); scanline_separate_16bit(tmpibuf->rect_float+ib_offset, sbuf, ibuf->x, chan); } } } } if (bitspersample == 32) _TIFFfree(fbuf); else if (bitspersample == 16) _TIFFfree(sbuf); if(success) { ibuf->profile = (bitspersample==32)?IB_PROFILE_LINEAR_RGB:IB_PROFILE_SRGB; // Code seems to be not needed for 16 bits tif, on PPC G5 OSX (ton) if(bitspersample < 16) if(ENDIAN_ORDER == B_ENDIAN) IMB_convert_rgba_to_abgr(tmpibuf); if(premul) { IMB_premultiply_alpha(tmpibuf); ibuf->flags |= IB_premul; } /* assign rect last */ if (tmpibuf->rect_float) ibuf->rect_float= tmpibuf->rect_float; else ibuf->rect= tmpibuf->rect; ibuf->mall |= ib_flag; ibuf->flags |= ib_flag; tmpibuf->mall &= ~ib_flag; } IMB_freeImBuf(tmpibuf); return success; } void imb_inittiff(void) { if (!(G.f & G_DEBUG)) TIFFSetErrorHandler(NULL); } /** * Loads a TIFF file. * * * @param mem: Memory containing the TIFF file. * @param size: Size of the mem buffer. * @param flags: If flags has IB_test set then the file is not actually loaded, * but all other operations take place. * * @return: A newly allocated ImBuf structure if successful, otherwise NULL. */ ImBuf *imb_loadtiff(unsigned char *mem, size_t size, int flags) { TIFF *image = NULL; ImBuf *ibuf = NULL, *hbuf; ImbTIFFMemFile memFile; uint32 width, height; char *format = NULL; int level; short spp; int ib_depth; /* check whether or not we have a TIFF file */ if(size < IMB_TIFF_NCB) { fprintf(stderr, "imb_loadtiff: size < IMB_TIFF_NCB\n"); return NULL; } if(imb_is_a_tiff(mem) == 0) return NULL; image = imb_tiff_client_open(&memFile, mem, size); if(image == NULL) { printf("imb_loadtiff: could not open TIFF IO layer.\n"); return NULL; } /* allocate the image buffer */ TIFFGetField(image, TIFFTAG_IMAGEWIDTH, &width); TIFFGetField(image, TIFFTAG_IMAGELENGTH, &height); TIFFGetField(image, TIFFTAG_SAMPLESPERPIXEL, &spp); ib_depth = (spp==3)?24:32; ibuf = IMB_allocImBuf(width, height, ib_depth, 0); if(ibuf) { ibuf->ftype = TIF; } else { fprintf(stderr, "imb_loadtiff: could not allocate memory for TIFF " \ "image.\n"); TIFFClose(image); return NULL; } /* if testing, we're done */ if(flags & IB_test) { TIFFClose(image); return ibuf; } /* detect if we are reading a tiled/mipmapped texture, in that case we don't read pixels but leave it to the cache to load tiles */ if(flags & IB_tilecache) { format= NULL; TIFFGetField(image, TIFFTAG_PIXAR_TEXTUREFORMAT, &format); if(format && strcmp(format, "Plain Texture")==0 && TIFFIsTiled(image)) { int numlevel = TIFFNumberOfDirectories(image); /* create empty mipmap levels in advance */ for(level=0; level 0) { width= (width > 1)? width/2: 1; height= (height > 1)? height/2: 1; hbuf= IMB_allocImBuf(width, height, 32, 0); hbuf->miplevel= level; hbuf->ftype= ibuf->ftype; ibuf->mipmap[level-1] = hbuf; if(flags & IB_premul) hbuf->flags |= IB_premul; } else hbuf= ibuf; hbuf->flags |= IB_tilecache; TIFFGetField(image, TIFFTAG_TILEWIDTH, &hbuf->tilex); TIFFGetField(image, TIFFTAG_TILELENGTH, &hbuf->tiley); hbuf->xtiles= ceil(hbuf->x/(float)hbuf->tilex); hbuf->ytiles= ceil(hbuf->y/(float)hbuf->tiley); imb_addtilesImBuf(hbuf); ibuf->miptot++; } } } /* read pixels */ if(!(ibuf->flags & IB_tilecache) && !imb_read_tiff_pixels(ibuf, image, 0)) { fprintf(stderr, "imb_loadtiff: Failed to read tiff image.\n"); TIFFClose(image); return NULL; } /* close the client layer interface to the in-memory file */ TIFFClose(image); /* return successfully */ return ibuf; } void imb_loadtiletiff(ImBuf *ibuf, unsigned char *mem, size_t size, int tx, int ty, unsigned int *rect) { TIFF *image = NULL; uint32 width, height; ImbTIFFMemFile memFile; image = imb_tiff_client_open(&memFile, mem, size); if(image == NULL) { printf("imb_loadtiff: could not open TIFF IO layer for loading mipmap level.\n"); return; } if(TIFFSetDirectory(image, ibuf->miplevel)) { /* allocate the image buffer */ TIFFGetField(image, TIFFTAG_IMAGEWIDTH, &width); TIFFGetField(image, TIFFTAG_IMAGELENGTH, &height); if(width == ibuf->x && height == ibuf->y) { if(rect) { /* tiff pixels are bottom to top, tiles are top to bottom */ if(TIFFReadRGBATile(image, tx*ibuf->tilex, (ibuf->ytiles - 1 - ty)*ibuf->tiley, rect) == 1) { if(ibuf->tiley > ibuf->y) memmove(rect, rect+ibuf->tilex*(ibuf->tiley - ibuf->y), sizeof(int)*ibuf->tilex*ibuf->y); if(ibuf->flags & IB_premul) IMB_premultiply_rect(rect, 32, ibuf->tilex, ibuf->tiley); } else printf("imb_loadtiff: failed to read tiff tile at mipmap level %d\n", ibuf->miplevel); } } else printf("imb_loadtiff: mipmap level %d has unexpected size %dx%d instead of %dx%d\n", ibuf->miplevel, width, height, ibuf->x, ibuf->y); } else printf("imb_loadtiff: could not find mipmap level %d\n", ibuf->miplevel); /* close the client layer interface to the in-memory file */ TIFFClose(image); } /** * Saves a TIFF file. * * ImBuf structures with 1, 3 or 4 bytes per pixel (GRAY, RGB, RGBA * respectively) are accepted, and interpreted correctly. Note that the TIFF * convention is to use pre-multiplied alpha, which can be achieved within * Blender by setting "Premul" alpha handling. Other alpha conventions are * not strictly correct, but are permitted anyhow. * * @param ibuf: Image buffer. * @param name: Name of the TIFF file to create. * @param flags: Currently largely ignored. * * @return: 1 if the function is successful, 0 on failure. */ int imb_savetiff(ImBuf *ibuf, const char *name, int flags) { TIFF *image = NULL; uint16 samplesperpixel, bitspersample; size_t npixels; unsigned char *pixels = NULL; unsigned char *from = NULL, *to = NULL; unsigned short *pixels16 = NULL, *to16 = NULL; float *fromf = NULL; int x, y, from_i, to_i, i; int extraSampleTypes[1] = { EXTRASAMPLE_ASSOCALPHA }; /* check for a valid number of bytes per pixel. Like the PNG writer, * the TIFF writer supports 1, 3 or 4 bytes per pixel, corresponding * to gray, RGB, RGBA respectively. */ samplesperpixel = (uint16)((ibuf->depth + 7) >> 3); if((samplesperpixel > 4) || (samplesperpixel == 2)) { fprintf(stderr, "imb_savetiff: unsupported number of bytes per " "pixel: %d\n", samplesperpixel); return (0); } if((ibuf->ftype & TIF_16BIT) && ibuf->rect_float) bitspersample = 16; else bitspersample = 8; /* open TIFF file for writing */ if(flags & IB_mem) { /* bork at the creation of a TIFF in memory */ fprintf(stderr, "imb_savetiff: creation of in-memory TIFF files is " "not yet supported.\n"); return (0); } else { /* create image as a file */ image = TIFFOpen(name, "w"); } if(image == NULL) { fprintf(stderr, "imb_savetiff: could not open TIFF for writing.\n"); return (0); } /* allocate array for pixel data */ npixels = ibuf->x * ibuf->y; if(bitspersample == 16) pixels16 = (unsigned short*)_TIFFmalloc(npixels * samplesperpixel * sizeof(unsigned short)); else pixels = (unsigned char*)_TIFFmalloc(npixels * samplesperpixel * sizeof(unsigned char)); if(pixels == NULL && pixels16 == NULL) { fprintf(stderr, "imb_savetiff: could not allocate pixels array.\n"); TIFFClose(image); return (0); } /* setup pointers */ if(bitspersample == 16) { fromf = ibuf->rect_float; to16 = pixels16; } else { from = (unsigned char*)ibuf->rect; to = pixels; } /* setup samples per pixel */ TIFFSetField(image, TIFFTAG_BITSPERSAMPLE, bitspersample); TIFFSetField(image, TIFFTAG_SAMPLESPERPIXEL, samplesperpixel); if(samplesperpixel == 4) { /* RGBA images */ TIFFSetField(image, TIFFTAG_EXTRASAMPLES, 1, extraSampleTypes); TIFFSetField(image, TIFFTAG_PHOTOMETRIC, PHOTOMETRIC_RGB); } else if(samplesperpixel == 3) { /* RGB images */ TIFFSetField(image, TIFFTAG_PHOTOMETRIC, PHOTOMETRIC_RGB); } else if(samplesperpixel == 1) { /* greyscale images, 1 channel */ TIFFSetField(image, TIFFTAG_PHOTOMETRIC, PHOTOMETRIC_MINISBLACK); } /* copy pixel data. While copying, we flip the image vertically. */ for(x = 0; x < ibuf->x; x++) { for(y = 0; y < ibuf->y; y++) { from_i = 4*(y*ibuf->x+x); to_i = samplesperpixel*((ibuf->y-y-1)*ibuf->x+x); if(pixels16) { /* convert from float source */ float rgb[3]; if (ibuf->profile == IB_PROFILE_LINEAR_RGB) linearrgb_to_srgb_v3_v3(rgb, &fromf[from_i]); else copy_v3_v3(rgb, &fromf[from_i]); to16[to_i+0] = FTOUSHORT(rgb[0]); to16[to_i+1] = FTOUSHORT(rgb[1]); to16[to_i+2] = FTOUSHORT(rgb[2]); to_i += 3; from_i+=3; if (samplesperpixel == 4) { to16[to_i+3] = FTOUSHORT(fromf[from_i+3]); /*to_i++; from_i++;*/ /*unused, set on each loop */ } } else { for(i = 0; i < samplesperpixel; i++, to_i++, from_i++) to[to_i] = from[from_i]; } } } /* write the actual TIFF file */ TIFFSetField(image, TIFFTAG_IMAGEWIDTH, ibuf->x); TIFFSetField(image, TIFFTAG_IMAGELENGTH, ibuf->y); TIFFSetField(image, TIFFTAG_ROWSPERSTRIP, ibuf->y); TIFFSetField(image, TIFFTAG_COMPRESSION, COMPRESSION_DEFLATE); TIFFSetField(image, TIFFTAG_FILLORDER, FILLORDER_MSB2LSB); TIFFSetField(image, TIFFTAG_PLANARCONFIG, PLANARCONFIG_CONTIG); TIFFSetField(image, TIFFTAG_XRESOLUTION, 150.0); TIFFSetField(image, TIFFTAG_YRESOLUTION, 150.0); TIFFSetField(image, TIFFTAG_RESOLUTIONUNIT, RESUNIT_INCH); if(TIFFWriteEncodedStrip(image, 0, (bitspersample == 16)? (unsigned char*)pixels16: pixels, ibuf->x*ibuf->y*samplesperpixel*bitspersample/8) == -1) { fprintf(stderr, "imb_savetiff: Could not write encoded TIFF.\n"); TIFFClose(image); if(pixels) _TIFFfree(pixels); if(pixels16) _TIFFfree(pixels16); return (1); } /* close the TIFF file */ TIFFClose(image); if(pixels) _TIFFfree(pixels); if(pixels16) _TIFFfree(pixels16); return (1); } #endif /* WITH_TIFF */