/* STARTHEADER * * File : sgi.c * * Author : Paul Obermeier (paul@poSoft.de) * * Date : Wed Nov 22 21:45:17 CET 2000 * * Copyright : (C) 2000-2002 Paul Obermeier * * Description : * * A photo image handler for Silicon Graphics' native file format. * * The following image types are supported: * * 24-bit pixels: True-color (RGB, each channel 8 bit). * 32-bit pixels: True-color with alpha channel (RGBA, each channel 8 bit). * 48-bit pixels: True-color (RGB, each channel 16 bit). * 64-bit pixels: True-color with alpha channel (RGBA, each channel 16 bit). * * List of currently supported features: * * Type | Read | Write | * | -file | -data | -file | -data | * ---------------------------------------- * 24-bit | Yes | Yes* | Yes | Yes* | * 32-bit | Yes | Yes* | Yes | Yes* | * 48-bit | Yes | Yes* | No | No | * 64-bit | Yes | Yes* | No | No | * * *: Implemented by reading/writing from/to a temporary file. This will * be slow for larger images. * * All images types may be either uncompressed or run-length encoded. * * * The following format options are available: * * Read SGI image: "sgi -matte -verbose " * Write SGI image: "sgi -matte -verbose -compression " * * -matte : If set to false, a matte (alpha) channel is ignored * during reading or writing. Default is true. * -verbose : If set to true, additional information about the file * format is printed to stdout. Default is false. * -compression : Set the compression mode to either "none" or "rle". * Default is "rle". * * Notes: * * - Parts of this code are taken from Paul Haeberli's original * image library code, written in 1984. * * - Due to the heavy use of file seeks in Haeberli's code and the behaviour * of Tcl_Seek on Windows when writing to files (sounds like smashing your * HD), there is some workaround to use fseek and fwrite instead. * See "#define TCLSEEK_WORKAROUND". * * ENDHEADER * * $Id: sgi.c,v 1.1.1.1 2016/01/25 21:20:47 joye Exp $ * */ /* #define DEBUG_LOCAL */ /* * Generic initialization code, parameterized via CPACKAGE and PACKAGE. */ #include "init.c" #ifdef WIN32 # define TCLSEEK_WORKAROUND #endif #ifdef TCLSEEK_WORKAROUND static int ioMode = 0; /* Needed for Windows patch */ static int MyWrite (Tcl_Channel chan, char *buf, int size) { if (1 == fwrite(buf, size, 1, (FILE *)chan)) { return size; } else { return -1; } } static int MyClose (Tcl_Interp *interp, Tcl_Channel chan) { if (0 == fclose((FILE *)chan)) { return TCL_OK; } else { return TCL_ERROR; } } static int MySeek (Tcl_Channel chan, int offset, int seekMode) { if (ioMode == 0) { /* Read mode */ return Tcl_Seek (chan, offset, seekMode); } else { return fseek((FILE *)chan, offset, seekMode); } } # define MYCHANNEL Tcl_Channel # undef Tcl_Seek # define Tcl_Seek MySeek # undef Tcl_Write # define Tcl_Write MyWrite # define MYCLOSE MyClose #else # define MYCHANNEL Tcl_Channel # define MYCLOSE Tcl_Close #endif /* Some defines and typedefs for compatibility reasons. */ #define TRUE 1 #define FALSE 0 typedef unsigned char Boln; /* Boolean value: TRUE or FALSE */ typedef unsigned char UByte; /* Unsigned 8 bit integer */ typedef char Byte; /* Signed 8 bit integer */ typedef short Short; /* Signed 16 bit integer */ typedef unsigned short UShort; /* Unsigned 16 bit integer */ typedef int Int; /* Signed 32 bit integer */ typedef unsigned int UInt; /* Unsigned 32 bit integer */ /* Start of original code from SGI image library, slightly modified. */ #define IMAGIC 0x01DA /* colormap of images */ #define CM_NORMAL 0 /* file contains rows of values which * are either RGB values (zsize == 3) * or greyramp values (zsize == 1) */ #define CM_DITHERED 1 #define CM_SCREEN 2 /* file contains data which is a screen * image; getrow returns buffer which * can be displayed directly with * writepixels */ #define CM_COLORMAP 3 /* a colormap file */ #define TYPEMASK 0xff00 #define BPPMASK 0x00ff #define ITYPE_UNCOMPRESSED 0x0000 #define ITYPE_RLE 0x0100 #define ISRLE(type) (((type) & 0xff00) == ITYPE_RLE) #define ISUNCOMPRESSED(type) (((type) & 0xff00) == ITYPE_UNCOMPRESSED) #define BPP(type) ((type) & BPPMASK) #define RLE(bpp) (ITYPE_RLE | (bpp)) #define UNCOMPRESSED(bpp) (ITYPE_UNCOMPRESSED | (bpp)) #define IBUFSIZE(pixels) ((pixels+(pixels>>6))<<2) #define RLE_NOP 0x00 #define ierror(p) (((p)->flags&_IOERR)!=0) #define ifileno(p) ((p)->file) #define getpix(p) (--(p)->cnt>=0 ? *(p)->ptr++ : ifilbuf(p)) #define putpix(p,x) (--(p)->cnt>=0 \ ? ((int)(*(p)->ptr++=(unsigned)(x))) \ : iflsbuf(p,(unsigned)(x))) /* The number of bytes of the IMAGE struct, which must be written to disk. * All other information is needed only internally. It is filled with zeros * on disk. */ #define RELEVANT_HEADER_BYTES 108 typedef struct { UShort imagic; /* stuff saved on disk . . */ UShort type; UShort dim; UShort xsize; UShort ysize; UShort zsize; UInt min; UInt max; UInt wastebytes; char name[80]; UInt colormap; MYCHANNEL file; /* Stuff not stored in the file. */ UShort flags; Short dorev; Short x; Short y; Short z; Short cnt; UShort *ptr; UShort *base; UShort *tmpbuf; UInt offset; UInt rleend; /* for rle images */ UInt *rowstart; /* for rle images */ Int *rowsize; /* for rle images */ char dummy[512-146]; /* Fill bytes, so that this structure is greater than 512 bytes */ } IMAGE; #if !defined (_IOWRT) # define _IOWRT 1 #endif #if !defined (_IOREAD) # define _IOREAD 2 #endif #if !defined (_IORW) # define _IORW 4 #endif #if !defined (_IOERR) # define _IOERR 8 #endif #if !defined (_IOEOF) # define _IOEOF 16 #endif static int img_badrow(IMAGE *image, unsigned int y, unsigned int z); static int img_write(IMAGE *image, char *buffer,int count); static int img_writeheader(IMAGE *image); static int iflush(IMAGE *image); static unsigned short *ibufalloc(IMAGE *image); static unsigned int img_optseek(IMAGE *image, unsigned int offset); static int imgopen(int, MYCHANNEL, IMAGE *, const char *,unsigned int, unsigned int, unsigned int, unsigned int, unsigned int); static int getrow(IMAGE *image, unsigned short *buffer, unsigned int y, unsigned int z); static int putrow(IMAGE *image, unsigned short *buffer, unsigned int y, unsigned int z); /* error handler for the image library. If the iseterror() routine has been called, sprintf's the args into a string and calls the error function. Otherwise calls fprintf with the args and then exit. This allows 'old' programs to assume that no errors ever need be worried about, while programs that know how and want to can handle the errors themselves. Olson, 11/88 */ static void i_errhdlr(fmt, a1, a2, a3, a4) /* most args currently used is 2 */ char *fmt; { /* fprintf(stderr, fmt); */ return; } /* * isetname and isetcolormap - * * Paul Haeberli - 1984 * */ static void isetname(IMAGE *image, const char *name) { strncpy(image->name,name,80); } /* This function is commented out because it is not used anywhere static void isetcolormap(IMAGE *image, int colormap) { image->colormap = colormap; } */ static void cvtshorts( buffer, n) register unsigned short buffer[]; register int n; { register short i; register int nshorts = n>>1; register unsigned short swrd; for(i=0; i>8) | (swrd<<8); } } static void cvtlongs( buffer, n) register int buffer[]; register int n; { register short i; register int nlongs = n>>2; register int lwrd; Byte *bytePtr; bytePtr = (Byte *) buffer; for(i=0; i> 24); bytePtr++; *bytePtr = (Byte) (lwrd >> 16); bytePtr++; *bytePtr = (Byte) (lwrd >> 8); bytePtr++; *bytePtr = (Byte) (lwrd); bytePtr++; } } static void cvtimage( buffer ) int buffer[]; { cvtshorts((unsigned short *)buffer,12); cvtlongs(buffer+3,12); } /* * iopen - * * Paul Haeberli - 1984 * */ static unsigned short *ibufalloc(IMAGE *image) { return (unsigned short *)malloc(IBUFSIZE(image->xsize)); } static int imgOpenRead (MYCHANNEL file, IMAGE *image, const char *mode) { #ifdef TCLSEEK_WORKAROUND ioMode = 0; #endif return imgopen (0, file, image, mode, 0, 0, 0, 0, 0); } static int imgOpenWrite (MYCHANNEL file, IMAGE *image, const char *mode, unsigned int type, unsigned int dim, unsigned int xsize, unsigned int ysize, unsigned int zsize) { #ifdef TCLSEEK_WORKAROUND ioMode = 1; #endif return imgopen (0, file, image, mode, type, dim, xsize, ysize, zsize); } static int imgopen(int f, MYCHANNEL file, IMAGE *image, const char *mode, unsigned int type, unsigned int dim, unsigned int xsize, unsigned int ysize, unsigned int zsize) { register int rw; int tablesize; register int i, max; rw = mode[1] == '+'; if(rw) { i_errhdlr("iopen: read/write mode not supported\n"); return 0; } if (*mode=='w') { image->type = type; image->xsize = xsize; image->ysize = 1; image->zsize = 1; if (dim>1) image->ysize = ysize; if (dim>2) image->zsize = zsize; if(image->zsize == 1) { image->dim = 2; if(image->ysize == 1) image->dim = 1; } else { image->dim = 3; } image->min = 10000000; image->max = 0; isetname(image,"no name"); image->wastebytes = 0; if (512 != Tcl_Write (file, (char *)image, 512)) { i_errhdlr("iopen: error on write of image header\n"); return 0; } } else { if (512 != Tcl_Read (file, (char *)image, 512)) { i_errhdlr("iopen: error on read of image header\n"); return 0; } if( ((image->imagic>>8) | ((image->imagic&0xff)<<8)) == IMAGIC ) { image->dorev = 1; cvtimage((int *)image); } else image->dorev = 0; if (image->imagic != IMAGIC) { i_errhdlr("iopen: bad magic in image file %x\n",image->imagic); return 0; } } if (rw) image->flags = _IORW; else if (*mode != 'r') image->flags = _IOWRT; else image->flags = _IOREAD; if(ISRLE(image->type)) { tablesize = image->ysize*image->zsize*sizeof(int); image->rowstart = (unsigned int *)malloc(tablesize); image->rowsize = (int *)malloc(tablesize); if( image->rowstart == 0 || image->rowsize == 0 ) { i_errhdlr("iopen: error on table alloc\n"); return 0; } image->rleend = 512L+2*tablesize; if (*mode=='w') { max = image->ysize*image->zsize; for(i=0; irowstart[i] = 0; image->rowsize[i] = -1; } } else { tablesize = image->ysize*image->zsize*sizeof(int); Tcl_Seek (file, 512L, 0); if (tablesize != Tcl_Read (file, (char *)image->rowstart, tablesize)) { i_errhdlr("iopen: error on read of rowstart\n"); return 0; } if(image->dorev) cvtlongs(image->rowstart,tablesize); if (Tcl_Read (file, (char *)image->rowsize, tablesize) != tablesize) { i_errhdlr("iopen: error on read of rowsize\n"); return 0; } if(image->dorev) cvtlongs(image->rowsize,tablesize); } } image->cnt = 0; image->ptr = 0; image->base = 0; if( (image->tmpbuf = ibufalloc(image)) == 0 ) { i_errhdlr("iopen: error on tmpbuf alloc %d\n",image->xsize); return 0; } image->x = image->y = image->z = 0; image->file = file; image->offset = 512L; /* set up for img_optseek */ Tcl_Seek (image->file, 512L, 0); return 1; } /* * iclose and iflush - * * Paul Haeberli - 1984 * */ static int iclose(IMAGE *image) { int tablesize; iflush(image); img_optseek(image, 0); if (image->flags&_IOWRT) { if(image->dorev) cvtimage((int *)image); if ( !img_writeheader(image)) { i_errhdlr("iclose: error on write of image header\n"); return EOF; } if(image->dorev) cvtimage((int *)image); if(ISRLE(image->type)) { img_optseek(image, 512L); tablesize = image->ysize*image->zsize*sizeof(int); if(image->dorev) cvtlongs(image->rowstart,tablesize); if (img_write(image,(char *)(image->rowstart),tablesize) != tablesize) { i_errhdlr("iclose: error on write of rowstart\n"); return EOF; } if(image->dorev) cvtlongs(image->rowsize,tablesize); if (img_write(image,(char *)(image->rowsize),tablesize) != tablesize) { i_errhdlr("iclose: error on write of rowsize\n"); return EOF; } } } if(image->base) { free(image->base); image->base = 0; } if(image->tmpbuf) { free(image->tmpbuf); image->tmpbuf = 0; } if(ISRLE(image->type)) { free(image->rowstart); image->rowstart = 0; free(image->rowsize); image->rowsize = 0; } return 0; } static int iflush(IMAGE *image) { unsigned short *base; if ( (image->flags&_IOWRT) && (base=image->base)!=NULL && (image->ptr-base)>0) { if (putrow(image, base, image->y,image->z)!=image->xsize) { image->flags |= _IOERR; return(EOF); } } return(0); } /* * ifilbuf - * * Paul Haeberli - 1984 * */ /* This function is commented out because it is not used anywhere static int ifilbuf(IMAGE *image) { if ((image->flags&_IOREAD) == 0) return(EOF); if (image->base==NULL) { if ((image->base = ibufalloc(image)) == NULL) { i_errhdlr("can't alloc image buffer\n"); return EOF; } } image->cnt = getrow(image,image->base,image->y,image->z); image->ptr = image->base; if (--image->cnt < 0) { if (image->cnt == -1) { image->flags |= _IOEOF; if (image->flags & _IORW) image->flags &= ~_IOREAD; } else image->flags |= _IOERR; image->cnt = 0; return -1; } if(++image->y >= image->ysize) { image->y = 0; if(++image->z >= image->zsize) { image->z = image->zsize-1; image->flags |= _IOEOF; return -1; } } return *image->ptr++ & 0xffff; } */ /* * iflsbuf - * * Paul Haeberli - 1984 * */ /* This function is commented out because it is not used anywhere static unsigned int iflsbuf(IMAGE *image, unsigned int c) { register unsigned short *base; register int n, rn; if ((image->flags&_IOWRT)==0) return(EOF); if ((base=image->base)==NULL) { if ((image->base=base=ibufalloc(image)) == NULL) { i_errhdlr("flsbuf: error on buf alloc\n"); return EOF; } rn = n = 0; } else if ((rn = n = image->ptr - base) > 0) { n = putrow(image,base,image->y,image->z); if(++image->y >= image->ysize) { image->y = 0; if(++image->z >= image->zsize) { image->z = image->zsize-1; image->flags |= _IOEOF; return -1; } } } image->cnt = image->xsize-1; *base++ = c; image->ptr = base; if (rn != n) { image->flags |= _IOERR; return(EOF); } return(c); } */ /* * img_seek, img_write, img_read, img_optseek - * * Paul Haeberli - 1984 * */ static unsigned int img_seek(IMAGE *image, unsigned int y, unsigned int z) { if(img_badrow(image,y,z)) { i_errhdlr("img_seek: row number out of range\n"); return EOF; } image->x = 0; image->y = y; image->z = z; if(ISUNCOMPRESSED(image->type)) { switch(image->dim) { case 1: return img_optseek(image, 512L); case 2: return img_optseek(image,512L+(y*image->xsize)*BPP(image->type)); case 3: return img_optseek(image, 512L+(y*image->xsize+z*image->xsize*image->ysize)* BPP(image->type)); default: i_errhdlr("img_seek: weird dim\n"); break; } } else if(ISRLE(image->type)) { switch(image->dim) { case 1: return img_optseek(image, image->rowstart[0]); case 2: return img_optseek(image, image->rowstart[y]); case 3: return img_optseek(image, image->rowstart[y+z*image->ysize]); default: i_errhdlr("img_seek: weird dim\n"); break; } } else i_errhdlr("img_seek: weird image type\n"); return((unsigned int)-1); } static int img_badrow(IMAGE *image, unsigned int y, unsigned int z) { if(y>=image->ysize || z>=image->zsize) return 1; else return 0; } static int img_write(IMAGE *image, char *buffer,int count) { int retval; retval = Tcl_Write (image->file, buffer, count); if(retval == count) image->offset += count; else image->offset = -1; return retval; } static int img_writeheader(IMAGE *image) { int retval; retval = Tcl_Write (image->file, (char *)image, RELEVANT_HEADER_BYTES); if(retval == RELEVANT_HEADER_BYTES) image->offset += sizeof (IMAGE); else image->offset = -1; return retval; } static int img_read(IMAGE *image, char *buffer, int count) { int retval; retval = Tcl_Read (image->file, buffer, count); if (retval == count) image->offset += count; else image->offset = -1; return retval; } static unsigned int img_optseek(IMAGE *image, unsigned int offset) { if(image->offset != offset) { image->offset = offset; return ((unsigned int) Tcl_Seek (image->file,offset,0)); } return offset; } /* * getpix and putpix - * * Paul Haeberli - 1984 * */ #undef getpix #undef putpix /* These functions are commented out because they are not used anywhere static int getpix(IMAGE *image) { if(--(image)->cnt>=0) return (int)(*(image)->ptr++); else return ifilbuf(image); } static unsigned int putpix(IMAGE *image, unsigned int pix) { if(--(image)->cnt>=0) return (unsigned int)(*(image)->ptr++ = pix); else return iflsbuf(image,pix); } */ /* * img_getrowsize, img_setrowsize, img_rle_compact, img_rle_expand - * * Paul Haeberli - 1984 * */ static int img_getrowsize(IMAGE *image) { switch(image->dim) { case 1: return image->rowsize[0]; case 2: return image->rowsize[image->y]; case 3: return image->rowsize[image->y+image->z*image->ysize]; } return -1; } static void img_setrowsize(IMAGE *image, int cnt, int y, int z) { int *sizeptr; if(img_badrow(image,y,z)) return; switch(image->dim) { case 1: sizeptr = &image->rowsize[0]; image->rowstart[0] = image->rleend; break; case 2: sizeptr = &image->rowsize[y]; image->rowstart[y] = image->rleend; break; case 3: sizeptr = &image->rowsize[y+z*image->ysize]; image->rowstart[y+z*image->ysize] = image->rleend; break; default: i_errhdlr ("img_setrowsize: bad dim: %d\n", image->dim); return; } if(*sizeptr != -1) image->wastebytes += *sizeptr; *sizeptr = cnt; image->rleend += cnt; } #define docompact \ while(iptr126 ? 126:count; \ count -= todo; \ *optr++ = 0x80|todo; \ while(todo--) \ *optr++ = *sptr++; \ } \ sptr = iptr; \ cc = *iptr++; \ while( (iptr126 ? 126:count; \ count -= todo; \ *optr++ = todo; \ *optr++ = cc; \ } \ } \ *optr++ = 0; static int img_rle_compact(unsigned short *expbuf, int ibpp, unsigned short *rlebuf, int obpp, int cnt) { if(ibpp == 1 && obpp == 1) { register unsigned char *iptr = (unsigned char *)expbuf; register unsigned char *ibufend = iptr+cnt; register unsigned char *sptr; register unsigned char *optr = (unsigned char *)rlebuf; register short todo, cc; register int count; docompact; return optr - (unsigned char *)rlebuf; } else if(ibpp == 1 && obpp == 2) { register unsigned char *iptr = (unsigned char *)expbuf; register unsigned char *ibufend = iptr+cnt; register unsigned char *sptr; register unsigned short *optr = rlebuf; register short todo, cc; register int count; docompact; return optr - rlebuf; } else if(ibpp == 2 && obpp == 1) { register unsigned short *iptr = expbuf; register unsigned short *ibufend = iptr+cnt; register unsigned short *sptr; register unsigned char *optr = (unsigned char *)rlebuf; register short todo, cc; register int count; docompact; return optr - (unsigned char *)rlebuf; } else if(ibpp == 2 && obpp == 2) { register unsigned short *iptr = expbuf; register unsigned short *ibufend = iptr+cnt; register unsigned short *sptr; register unsigned short *optr = rlebuf; register short todo, cc; register int count; docompact; return optr - rlebuf; } else { i_errhdlr("rle_compact: bad bpp: %d %d\n",ibpp,obpp); return 0; } } #define doexpand \ while(1) { \ pixel = *iptr++; \ if ( !(count = (pixel & 0x7f)) ) \ return; \ if(pixel & 0x80) { \ while(count--) \ *optr++ = *iptr++; \ } else { \ pixel = *iptr++; \ while(count--) \ *optr++ = pixel; \ } \ } static void img_rle_expand(unsigned short *rlebuf, int ibpp, unsigned short *expbuf, int obpp) { if(ibpp == 1 && obpp == 1) { register unsigned char *iptr = (unsigned char *)rlebuf; register unsigned char *optr = (unsigned char *)expbuf; register unsigned short pixel,count; doexpand; } else if(ibpp == 1 && obpp == 2) { register unsigned char *iptr = (unsigned char *)rlebuf; register unsigned short *optr = expbuf; register unsigned short pixel,count; doexpand; } else if(ibpp == 2 && obpp == 1) { register unsigned short *iptr = rlebuf; register unsigned char *optr = (unsigned char *)expbuf; register unsigned short pixel,count; doexpand; } else if(ibpp == 2 && obpp == 2) { register unsigned short *iptr = rlebuf; register unsigned short *optr = expbuf; register unsigned short pixel,count; doexpand; } else i_errhdlr("rle_expand: bad bpp: %d %d\n",ibpp,obpp); } /* * putrow, getrow - * * Paul Haeberli - 1984 * */ static int putrow(IMAGE *image, unsigned short *buffer, unsigned int y, unsigned int z) { register unsigned short *sptr; register unsigned char *cptr; register unsigned int x; register unsigned int min, max; register int cnt; if( !(image->flags & (_IORW|_IOWRT)) ) return -1; if(image->dim<3) z = 0; if(image->dim<2) y = 0; if(ISUNCOMPRESSED(image->type)) { switch(BPP(image->type)) { case 1: min = image->min; max = image->max; cptr = (unsigned char *)image->tmpbuf; sptr = buffer; for(x=image->xsize; x--;) { *cptr = *sptr++; if (*cptr > max) max = *cptr; if (*cptr < min) min = *cptr; cptr++; } image->min = min; image->max = max; img_seek(image,y,z); cnt = image->xsize; if (img_write(image,(char *)(image->tmpbuf),cnt) != cnt) return -1; else return cnt; /* NOTREACHED */ case 2: min = image->min; max = image->max; sptr = buffer; for(x=image->xsize; x--;) { if (*sptr > max) max = *sptr; if (*sptr < min) min = *sptr; sptr++; } image->min = min; image->max = max; img_seek(image,y,z); cnt = image->xsize<<1; if(image->dorev) cvtshorts(buffer,cnt); if (img_write(image,(char *)(buffer),cnt) != cnt) { if(image->dorev) cvtshorts(buffer,cnt); return -1; } else { if(image->dorev) cvtshorts(buffer,cnt); return image->xsize; } /* NOTREACHED */ default: i_errhdlr("putrow: weird bpp\n"); } } else if(ISRLE(image->type)) { switch(BPP(image->type)) { case 1: min = image->min; max = image->max; sptr = buffer; for(x=image->xsize; x--;) { if (*sptr > max) max = *sptr; if (*sptr < min) min = *sptr; sptr++; } image->min = min; image->max = max; cnt = img_rle_compact(buffer,2,image->tmpbuf,1,image->xsize); img_setrowsize(image,cnt,y,z); img_seek(image,y,z); if (img_write(image,(char *)(image->tmpbuf),cnt) != cnt) return -1; else return image->xsize; /* NOTREACHED */ case 2: min = image->min; max = image->max; sptr = buffer; for(x=image->xsize; x--;) { if (*sptr > max) max = *sptr; if (*sptr < min) min = *sptr; sptr++; } image->min = min; image->max = max; cnt = img_rle_compact(buffer,2,image->tmpbuf,2,image->xsize); cnt <<= 1; img_setrowsize(image,cnt,y,z); img_seek(image,y,z); if(image->dorev) cvtshorts(image->tmpbuf,cnt); if (img_write(image,(char *)(image->tmpbuf),cnt) != cnt) { if(image->dorev) cvtshorts(image->tmpbuf,cnt); return -1; } else { if(image->dorev) cvtshorts(image->tmpbuf,cnt); return image->xsize; } /* NOTREACHED */ default: i_errhdlr("putrow: weird bpp\n"); } } else i_errhdlr("putrow: weird image type\n"); return(-1); } static int getrow(IMAGE *image, unsigned short *buffer, unsigned int y, unsigned int z) { register short i; register unsigned char *cptr; register unsigned short *sptr; register short cnt; if( !(image->flags & (_IORW|_IOREAD)) ) return -1; if(image->dim<3) z = 0; if(image->dim<2) y = 0; img_seek(image, y, z); if(ISUNCOMPRESSED(image->type)) { switch(BPP(image->type)) { case 1: if (img_read(image,(char *)image->tmpbuf,image->xsize) != image->xsize) return -1; else { cptr = (unsigned char *)image->tmpbuf; sptr = buffer; for(i=image->xsize; i--;) *sptr++ = *cptr++; } return image->xsize; /* NOTREACHED */ case 2: cnt = image->xsize<<1; if (img_read(image,(char *)(buffer),cnt) != cnt) return -1; else { if(image->dorev) cvtshorts(buffer,cnt); return image->xsize; } /* NOTREACHED */ default: i_errhdlr("getrow: weird bpp\n"); break; } } else if(ISRLE(image->type)) { switch(BPP(image->type)) { case 1: if( (cnt = img_getrowsize(image)) == -1 ) return -1; if( img_read(image,(char *)(image->tmpbuf),cnt) != cnt ) return -1; else { img_rle_expand(image->tmpbuf,1,buffer,2); return image->xsize; } /* NOTREACHED */ case 2: if( (cnt = img_getrowsize(image)) == -1 ) return -1; if( cnt != img_read(image,(char *)(image->tmpbuf),cnt) ) return -1; else { if(image->dorev) cvtshorts(image->tmpbuf,cnt); img_rle_expand(image->tmpbuf,2,buffer,2); return image->xsize; } /* NOTREACHED */ default: i_errhdlr("getrow: weird bpp\n"); break; } } else i_errhdlr("getrow: weird image type\n"); return -1; } /* End of original SGI image code */ /* Structure to hold information about the SGI file being processed. */ typedef struct { IMAGE th; UByte *red, /* Pointers to step through scanlines */ *green, *blue, *matte; UByte *redScan, /* Buffer for one scanline: Red channel */ *greenScan, /* Buffer for one scanline: Green channel */ *blueScan, /* Buffer for one scanline: Blue channel */ *matteScan; /* Buffer for one scanline: Matte channel */ UByte *scanline; unsigned short *pixbuf; } SGIFILE; /* This function determines at runtime, whether we have to switch bytes. The SGI image format expects data to be in big-endian format. */ static int isIntel (void) { unsigned long val = 513; /* On Intel (little-endian) systems this value is equal to "\01\02\00\00". On big-endian systems this value equals "\00\00\02\01" */ return memcmp(&val, "\01\02", 2) == 0; } static void sgiClose (SGIFILE *tf) { if (tf->redScan) ckfree ((char *)tf->redScan); if (tf->greenScan) ckfree ((char *)tf->greenScan); if (tf->blueScan) ckfree ((char *)tf->blueScan); if (tf->matteScan) ckfree ((char *)tf->matteScan); if (tf->pixbuf) ckfree ((char *)tf->pixbuf); return; } #define OUT Tcl_WriteChars (outChan, str, -1) static void printImgInfo (IMAGE *th, const char *filename, const char *msg) { Tcl_Channel outChan; char str[256]; outChan = Tcl_GetStdChannel (TCL_STDOUT); if (!outChan) { return; } sprintf(str, "%s %s\n", msg, filename); OUT; sprintf(str, "\tSize in pixel : %d x %d\n", th->xsize, th->ysize); OUT; sprintf(str, "\tNo. of channels : %d\n", (th->zsize)); OUT; sprintf(str, "\tBytes per pixel : %d\n", BPP(th->type)); OUT; sprintf(str, "\tCompression : %s\n", ISRLE(th->type)? "RLE": "None"); OUT; Tcl_Flush(outChan); } #undef OUT static Boln readHeader (tkimg_MFile *handle, IMAGE *th) { if (512 != tkimg_Read(handle, (char *)th, 512)) { return FALSE; } if( ((th->imagic>>8) | ((th->imagic&0xff)<<8)) == IMAGIC ) { th->dorev = 1; cvtimage((int *)th); } else { th->dorev = 0; } if (th->imagic != IMAGIC) { return FALSE; } return TRUE; } static Boln writeHeader(tkimg_MFile *handle, IMAGE *th, UInt type, UInt dim, UInt xsize, UInt ysize, UInt zsize) { if (!imgOpenWrite ((MYCHANNEL)handle->data, th, "w", type, dim, xsize, ysize, zsize)) return FALSE; return TRUE; } static Boln readChannel (SGIFILE *tf, UByte *dest, Int sgichn, Int nchan, Int y, Int n) { unsigned short *src = tf->pixbuf; unsigned short *stop = src + n; if (-1 == getrow (&tf->th, tf->pixbuf, y, sgichn)) return FALSE; dest += sgichn; switch (BPP(tf->th.type)) { case 1: { /* 8-bit pixel values */ while (src < stop) { *dest = *(src++); dest += nchan; } break; } case 2: { /* 16-bit values will be linearly mapped to 8-bit. */ while (src < stop) { *dest = *(src++) >> 8; dest += nchan; } break; } } return TRUE; } static Boln sgiReadScan (Tcl_Interp *interp, tkimg_MFile *handle, SGIFILE *tf, Int y) { Int nchan; nchan = tf->th.zsize; /* Read 1. channel: This is either the red or brightness channel. */ if (!readChannel (tf, tf->scanline, 0, nchan, y, tf->th.xsize)) { return FALSE; } if ( nchan >= 3) { /* This is either a RGB or RGBA image. Read green and blue channels. */ if (!readChannel (tf, tf->scanline, 1, nchan, y, tf->th.xsize) || !readChannel (tf, tf->scanline, 2, nchan, y, tf->th.xsize)) return FALSE; } if (nchan > 3 || nchan == 2) { /* If nchan is 2, we have a brightness-alpha image, if nchan is 4, we have RGBA. */ if (!readChannel (tf, tf->scanline, nchan == 2? 1: 3, nchan, y, tf->th.xsize)) return FALSE; } return TRUE; } static Boln writeChannel (SGIFILE *tf, UByte *src, Int sgichn, Int y, Int n) { unsigned short *dest = tf->pixbuf; UByte *stop = src + n; while (src < stop) *(dest++) = *(src++); if (-1 == putrow (&tf->th, tf->pixbuf, y, sgichn)) return FALSE; return TRUE; } static Boln sgiWriteScan(Tcl_Interp *interp, tkimg_MFile *handle, SGIFILE *tf, Int y) { if (!writeChannel (tf, tf->redScan, 0, y, tf->th.xsize) || !writeChannel (tf, tf->greenScan, 1, y, tf->th.xsize) || !writeChannel (tf, tf->blueScan, 2, y, tf->th.xsize)) return FALSE; if (tf->th.zsize > 3) if (!writeChannel (tf, tf->matteScan, 3, y, tf->th.xsize)) return FALSE; return TRUE; } /* * Here is the start of the standard functions needed for every image format. */ /* * Prototypes for local procedures defined in this file: */ static int ParseFormatOpts(Tcl_Interp *interp, Tcl_Obj *format, int *comp, int *verb, int *matte); static int CommonMatch(tkimg_MFile *handle, int *widthPtr, int *heightPtr, IMAGE *sgiHeaderPtr); static int CommonRead(Tcl_Interp *interp, tkimg_MFile *handle, const char *filename, Tcl_Obj *format, Tk_PhotoHandle imageHandle, int destX, int destY, int width, int height, int srcX, int srcY); static int CommonWrite(Tcl_Interp *interp, const char *filename, Tcl_Obj *format, tkimg_MFile *handle, Tk_PhotoImageBlock *blockPtr); static int ParseFormatOpts (interp, format, comp, verb, matte) Tcl_Interp *interp; Tcl_Obj *format; int *comp; int *verb; int *matte; { static const char *const sgiOptions[] = {"-compression", "-verbose", "-matte", NULL}; int objc, length, c, i, index; Tcl_Obj **objv; const char *compression, *verbose, *transp; *comp = 1; *verb = 0; *matte = 1; if (tkimg_ListObjGetElements(interp, format, &objc, &objv) != TCL_OK) return TCL_ERROR; if (objc) { compression = "rle"; verbose = "0"; transp = "1"; for (i=1; i= objc) { Tcl_AppendResult(interp, "No value for option \"", Tcl_GetStringFromObj (objv[--i], (int *) NULL), "\"", (char *) NULL); return TCL_ERROR; } switch(index) { case 0: compression = Tcl_GetStringFromObj(objv[i], (int *) NULL); break; case 1: verbose = Tcl_GetStringFromObj(objv[i], (int *) NULL); break; case 2: transp = Tcl_GetStringFromObj(objv[i], (int *) NULL); break; } } c = compression[0]; length = strlen (compression); if ((c == 'n') && (!strncmp (compression, "none", length))) { *comp = ITYPE_UNCOMPRESSED; } else if ((c == 'r') && (!strncmp (compression, "rle",length))) { *comp = ITYPE_RLE; } else { Tcl_AppendResult(interp, "invalid compression mode \"", compression, "\": should be rle or none", (char *) NULL); return TCL_ERROR; } c = verbose[0]; length = strlen (verbose); if (!strncmp (verbose, "1", length) || \ !strncmp (verbose, "true", length) || \ !strncmp (verbose, "on", length)) { *verb = 1; } else if (!strncmp (verbose, "0", length) || \ !strncmp (verbose, "false", length) || \ !strncmp (verbose, "off", length)) { *verb = 0; } else { Tcl_AppendResult(interp, "invalid verbose mode \"", verbose, "\": should be 1 or 0, on or off, true or false", (char *) NULL); return TCL_ERROR; } c = transp[0]; length = strlen (transp); if (!strncmp (transp, "1", length) || \ !strncmp (transp, "true", length) || \ !strncmp (transp, "on", length)) { *matte = 1; } else if (!strncmp (transp, "0", length) || \ !strncmp (transp, "false", length) || \ !strncmp (transp, "off", length)) { *matte = 0; } else { Tcl_AppendResult(interp, "invalid alpha (matte) mode \"", transp, "\": should be 1 or 0, on or off, true or false", (char *) NULL); return TCL_ERROR; } } return TCL_OK; } static int ChnMatch( Tcl_Channel chan, const char *filename, Tcl_Obj *format, int *widthPtr, int *heightPtr, Tcl_Interp *interp ) { tkimg_MFile handle; handle.data = (char *) chan; handle.state = IMG_CHAN; return CommonMatch(&handle, widthPtr, heightPtr, NULL); } static int ObjMatch( Tcl_Obj *data, Tcl_Obj *format, int *widthPtr, int *heightPtr, Tcl_Interp *interp ) { tkimg_MFile handle; if (!tkimg_ReadInit(data, '\001', &handle)) { return 0; } return CommonMatch(&handle, widthPtr, heightPtr, NULL); } static int CommonMatch(handle, widthPtr, heightPtr, sgiHeaderPtr) tkimg_MFile *handle; int *widthPtr; int *heightPtr; IMAGE *sgiHeaderPtr; { IMAGE th; if (!sgiHeaderPtr) { if (!readHeader (handle, &th)) return 0; } else { if (!imgOpenRead ((MYCHANNEL)handle->data, &th, "r")) return 0; } if (th.xsize <= 0 || th.ysize <= 0) return 0; *widthPtr = th.xsize; *heightPtr = th.ysize; if (sgiHeaderPtr) *sgiHeaderPtr = th; return 1; } static int ChnRead(interp, chan, filename, format, imageHandle, destX, destY, width, height, srcX, srcY) Tcl_Interp *interp; Tcl_Channel chan; const char *filename; Tcl_Obj *format; Tk_PhotoHandle imageHandle; int destX, destY; int width, height; int srcX, srcY; { tkimg_MFile handle; handle.data = (char *) chan; handle.state = IMG_CHAN; return CommonRead (interp, &handle, filename, format, imageHandle, destX, destY, width, height, srcX, srcY); } #define BUFLEN 2048 static int ObjRead (interp, data, format, imageHandle, destX, destY, width, height, srcX, srcY) Tcl_Interp *interp; Tcl_Obj *data; Tcl_Obj *format; Tk_PhotoHandle imageHandle; int destX, destY; int width, height; int srcX, srcY; { tkimg_MFile handle; char *tempFileName, tempFileNameBuffer[256]; char buffer[BUFLEN]; MYCHANNEL outchan; Tcl_Channel inchan; int count, retVal; tkimg_ReadInit (data, '\001', &handle); tempFileName = tmpnam(tempFileNameBuffer); #ifdef TCLSEEK_WORKAROUND outchan = (Tcl_Channel)fopen (tempFileName, "wb"); #else outchan = tkimg_OpenFileChannel (interp, tempFileName, 0644); #endif if (!outchan) { return TCL_ERROR; } count = tkimg_Read(&handle, buffer, BUFLEN); while (count == BUFLEN) { Tcl_Write (outchan, buffer, count); count = tkimg_Read(&handle, buffer, BUFLEN); } if (count>0) { Tcl_Write (outchan, buffer, count); } if (MYCLOSE (interp, outchan) == TCL_ERROR) { return TCL_ERROR; } inchan = tkimg_OpenFileChannel (interp, tempFileName, 0); if (!inchan) { return TCL_ERROR; } handle.data = (char *) inchan; handle.state = IMG_CHAN; retVal = CommonRead (interp, &handle, tempFileName, format, imageHandle, destX, destY, width, height, srcX, srcY); if (Tcl_Close (interp, inchan) == TCL_ERROR) { return TCL_ERROR; } remove (tempFileName); return retVal; } static int CommonRead (interp, handle, filename, format, imageHandle, destX, destY, width, height, srcX, srcY) Tcl_Interp *interp; /* Interpreter to use for reporting errors. */ tkimg_MFile *handle; /* The image file, open for reading. */ const char *filename; /* The name of the image file. */ Tcl_Obj *format; /* User-specified format object, or NULL. */ Tk_PhotoHandle imageHandle; /* The photo image to write into. */ int destX, destY; /* Coordinates of top-left pixel in * photo image to be written to. */ int width, height; /* Dimensions of block of photo image to * be written to. */ int srcX, srcY; /* Coordinates of top-left pixel to be used * in image being read. */ { Tk_PhotoImageBlock block; Int y, nchan; int fileWidth, fileHeight; int stopY, outY, outWidth, outHeight; SGIFILE tf; int compr, verbose, matte; int result = TCL_OK; memset(&tf, 0, sizeof (SGIFILE)); if (ParseFormatOpts(interp, format, &compr, &verbose, &matte) != TCL_OK) { return TCL_ERROR; } CommonMatch(handle, &fileWidth, &fileHeight, &tf.th); if (verbose) printImgInfo (&tf.th, filename, "Reading image:"); if ((srcX + width) > fileWidth) { outWidth = fileWidth - srcX; } else { outWidth = width; } if ((srcY + height) > fileHeight) { outHeight = fileHeight - srcY; } else { outHeight = height; } if ((outWidth <= 0) || (outHeight <= 0) || (srcX >= fileWidth) || (srcY >= fileHeight)) { return TCL_OK; } if (tkimg_PhotoExpand(interp, imageHandle, destX + outWidth, destY + outHeight) == TCL_ERROR) { return TCL_ERROR; } nchan = tf.th.zsize; tf.pixbuf = (UShort *) ckalloc (fileWidth * nchan * sizeof (UShort)); tf.scanline = (UByte *) ckalloc (fileWidth * nchan); block.pixelSize = nchan; block.pitch = fileWidth * nchan; block.width = outWidth; block.height = 1; switch (nchan) { case 1: /* Brightness */ case 2: /* Brightness + Matte */ block.offset[0] = 0; block.offset[1] = 0; block.offset[2] = 0; block.offset[3] = matte? 1: 0; break; case 3: /* RGB */ case 4: /* RGB + Matte */ block.offset[0] = 0; block.offset[1] = 1; block.offset[2] = 2; block.offset[3] = matte? 3: 0; break; default: printf("Invalid number of channels: %d\n", (int) nchan); return TCL_ERROR; break; } block.pixelPtr = tf.scanline + srcX * nchan; stopY = srcY + outHeight; outY = destY; for (y=0; y= srcY) { if (tkimg_PhotoPutBlock(interp, imageHandle, &block, destX, outY, outWidth, 1, matte? TK_PHOTO_COMPOSITE_OVERLAY: TK_PHOTO_COMPOSITE_SET) == TCL_ERROR) { result = TCL_ERROR; break; } outY++; } } sgiClose (&tf); return result; } static int ChnWrite (interp, filename, format, blockPtr) Tcl_Interp *interp; const char *filename; Tcl_Obj *format; Tk_PhotoImageBlock *blockPtr; { MYCHANNEL chan; tkimg_MFile handle; int result; #ifdef TCLSEEK_WORKAROUND chan = (Tcl_Channel)fopen(filename, "wb"); #else chan = tkimg_OpenFileChannel (interp, filename, 0644); #endif if (!chan) { return TCL_ERROR; } handle.data = (char *) chan; handle.state = IMG_CHAN; result = CommonWrite (interp, filename, format, &handle, blockPtr); if (MYCLOSE(interp, chan) == TCL_ERROR) { return TCL_ERROR; } return result; } static int StringWrite( Tcl_Interp *interp, Tcl_Obj *format, Tk_PhotoImageBlock *blockPtr ) { tkimg_MFile handle; int result; Tcl_DString data; Tcl_Channel inchan; MYCHANNEL outchan; char *tempFileName, tempFileNameBuffer[256]; char buffer[BUFLEN]; int count; Tcl_DStringInit(&data); tempFileName = tmpnam(tempFileNameBuffer); #ifdef TCLSEEK_WORKAROUND outchan = (Tcl_Channel)fopen(tempFileName, "wb"); #else outchan = tkimg_OpenFileChannel (interp, tempFileName, 0644); #endif if (!outchan) { return TCL_ERROR; } handle.data = (char *) outchan; handle.state = IMG_CHAN; result = CommonWrite(interp, tempFileName, format, &handle, blockPtr); if (MYCLOSE(interp, outchan) == TCL_ERROR) { return TCL_ERROR; } tkimg_WriteInit(&data, &handle); inchan = tkimg_OpenFileChannel(interp, tempFileName, 0); if (!inchan) { return TCL_ERROR; } count = Tcl_Read(inchan, buffer, BUFLEN); while (count == BUFLEN) { tkimg_Write(&handle, buffer, count); count = Tcl_Read(inchan, buffer, BUFLEN); } if (count>0) { tkimg_Write(&handle, buffer, count); } if (Tcl_Close(interp, inchan) == TCL_ERROR) { return TCL_ERROR; } remove (tempFileName); tkimg_Putc(IMG_DONE, &handle); if (result == TCL_OK) { Tcl_DStringResult(interp, &data); } else { Tcl_DStringFree(&data); } return result; } static int CommonWrite (interp, filename, format, handle, blockPtr) Tcl_Interp *interp; const char *filename; Tcl_Obj *format; tkimg_MFile *handle; Tk_PhotoImageBlock *blockPtr; { Int x, y, bpp, nchan; Int redOffset, greenOffset, blueOffset, alphaOffset; UByte *pixelPtr, *rowPixPtr; SGIFILE tf; int compr, verbose, matte; /* Format options */ memset (&tf, 0, sizeof (SGIFILE)); if (ParseFormatOpts(interp, format, &compr, &verbose, &matte) != TCL_OK) { return TCL_ERROR; } bpp = 1; redOffset = 0; greenOffset = blockPtr->offset[1] - blockPtr->offset[0]; blueOffset = blockPtr->offset[2] - blockPtr->offset[0]; alphaOffset = blockPtr->offset[0]; if (alphaOffset < blockPtr->offset[2]) { alphaOffset = blockPtr->offset[2]; } if (++alphaOffset < blockPtr->pixelSize) { alphaOffset -= blockPtr->offset[0]; } else { alphaOffset = 0; } nchan = ((matte && alphaOffset)? 4: 3); tf.redScan = (UByte *) ckalloc (blockPtr->width); tf.greenScan = (UByte *) ckalloc (blockPtr->width); tf.blueScan = (UByte *) ckalloc (blockPtr->width); tf.matteScan = (UByte *) ckalloc (blockPtr->width); tf.pixbuf = (UShort *) ckalloc (blockPtr->width * sizeof (UShort)); tf.th.imagic = IMAGIC; if (!writeHeader(handle, &tf.th, compr? RLE(bpp): UNCOMPRESSED(bpp), nchan, blockPtr->width, blockPtr->height, nchan)) { return TCL_ERROR; } tf.th.dorev = isIntel(); rowPixPtr = blockPtr->pixelPtr + blockPtr->offset[0]; for (y = blockPtr->height -1; y >=0; y--) { tf.red = tf.redScan; tf.green = tf.greenScan; tf.blue = tf.blueScan; tf.matte = tf.matteScan; pixelPtr = rowPixPtr; for (x = 0; x < blockPtr->width; x++) { *(tf.red++) = pixelPtr[redOffset]; *(tf.green++) = pixelPtr[greenOffset]; *(tf.blue++) = pixelPtr[blueOffset]; if (nchan == 4) { /* Have a matte channel and write it. */ *(tf.matte++) = pixelPtr[alphaOffset]; } pixelPtr += blockPtr->pixelSize; } if (!sgiWriteScan(interp, handle, &tf, y)) { sgiClose (&tf); return TCL_ERROR; } rowPixPtr += blockPtr->pitch; } if (verbose) printImgInfo (&tf.th, filename, "Saving image:"); iclose (&tf.th); sgiClose (&tf); return TCL_OK; }