#include #include "imageri.h" /* =head1 NAME bmp.c - read and write windows BMP files =head1 SYNOPSIS i_img *im; io_glue *ig; if (!i_writebmp_wiol(im, ig)) { ... error ... } im = i_readbmp(ig); =head1 DESCRIPTION Reads and writes Windows BMP files. =over =cut */ #define FILEHEAD_SIZE 14 #define INFOHEAD_SIZE 40 #define BI_RGB 0 #define BI_RLE8 1 #define BI_RLE4 2 #define BI_BITFIELDS 3 #define BMPRLE_ENDOFLINE 0 #define BMPRLE_ENDOFBMP 1 #define BMPRLE_DELTA 2 static int read_packed(io_glue *ig, char *format, ...); static int write_packed(io_glue *ig, char *format, ...); static int write_bmphead(io_glue *ig, i_img *im, int bit_count, int data_size); static int write_1bit_data(io_glue *ig, i_img *im); static int write_4bit_data(io_glue *ig, i_img *im); static int write_8bit_data(io_glue *ig, i_img *im); static int write_24bit_data(io_glue *ig, i_img *im); static int read_bmp_pal(io_glue *ig, i_img *im, int count); static i_img *read_1bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete); static i_img *read_4bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete); static i_img *read_8bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete); static i_img *read_direct_bmp(io_glue *ig, int xsize, int ysize, int bit_count, int clr_used, int compression, long offbits, int allow_incomplete); /* =item i_writebmp_wiol(im, io_glue) Writes the image as a BMP file. Uses 1-bit, 4-bit, 8-bit or 24-bit formats depending on the image. Never compresses the image. =cut */ int i_writebmp_wiol(i_img *im, io_glue *ig) { io_glue_commit_types(ig); i_clear_error(); /* pick a format */ if (im->type == i_direct_type) { return write_24bit_data(ig, im); } else { int pal_size; /* must be paletted */ pal_size = i_colorcount(im); if (pal_size <= 2) { return write_1bit_data(ig, im); } else if (pal_size <= 16) { return write_4bit_data(ig, im); } else { return write_8bit_data(ig, im); } } } /* =item i_readbmp_wiol(ig) Reads a Windows format bitmap from the given file. Handles BI_RLE4 and BI_RLE8 compressed images. Attempts to handle BI_BITFIELDS images too, but I need a test image. =cut */ i_img * i_readbmp_wiol(io_glue *ig, int allow_incomplete) { int b_magic, m_magic, filesize, res1, res2, infohead_size; int xsize, ysize, planes, bit_count, compression, size_image, xres, yres; int clr_used, clr_important, offbits; i_img *im; mm_log((1, "i_readbmp_wiol(ig %p)\n", ig)); io_glue_commit_types(ig); i_clear_error(); if (!read_packed(ig, "CCVvvVVVVvvVVVVVV", &b_magic, &m_magic, &filesize, &res1, &res2, &offbits, &infohead_size, &xsize, &ysize, &planes, &bit_count, &compression, &size_image, &xres, &yres, &clr_used, &clr_important)) { i_push_error(0, "file too short to be a BMP file"); return 0; } if (b_magic != 'B' || m_magic != 'M' || infohead_size != INFOHEAD_SIZE || planes != 1) { i_push_error(0, "not a BMP file"); return 0; } mm_log((1, " bmp header: filesize %d offbits %d xsize %d ysize %d planes %d " "bit_count %d compression %d size %d xres %d yres %d clr_used %d " "clr_important %d\n", filesize, offbits, xsize, ysize, planes, bit_count, compression, size_image, xres, yres, clr_used, clr_important)); if (!i_int_check_image_file_limits(xsize, abs(ysize), 3, sizeof(i_sample_t))) { mm_log((1, "i_readbmp_wiol: image size exceeds limits\n")); return NULL; } switch (bit_count) { case 1: im = read_1bit_bmp(ig, xsize, ysize, clr_used, compression, offbits, allow_incomplete); break; case 4: im = read_4bit_bmp(ig, xsize, ysize, clr_used, compression, offbits, allow_incomplete); break; case 8: im = read_8bit_bmp(ig, xsize, ysize, clr_used, compression, offbits, allow_incomplete); break; case 32: case 24: case 16: im = read_direct_bmp(ig, xsize, ysize, bit_count, clr_used, compression, offbits, allow_incomplete); break; default: i_push_errorf(0, "unknown bit count for BMP file (%d)", bit_count); return NULL; } if (im) { /* store the resolution */ if (xres && !yres) yres = xres; else if (yres && !xres) xres = yres; if (xres) { i_tags_set_float2(&im->tags, "i_xres", 0, xres * 0.0254, 4); i_tags_set_float2(&im->tags, "i_yres", 0, yres * 0.0254, 4); } i_tags_addn(&im->tags, "bmp_compression", 0, compression); i_tags_addn(&im->tags, "bmp_important_colors", 0, clr_important); i_tags_addn(&im->tags, "bmp_used_colors", 0, clr_used); i_tags_addn(&im->tags, "bmp_filesize", 0, filesize); i_tags_addn(&im->tags, "bmp_bit_count", 0, bit_count); i_tags_add(&im->tags, "i_format", 0, "bmp", 3, 0); } return im; } /* =back =head1 IMPLEMENTATION FUNCTIONS Internal functions used in the implementation. =over =item read_packed(ig, format, ...) Reads from the specified "file" the specified sizes. The format codes match those used by perl's pack() function, though only a few are implemented. In all cases the vararg arguement is an int *. Returns non-zero if all of the arguments were read. =cut */ static int read_packed(io_glue *ig, char *format, ...) { unsigned char buf[4]; va_list ap; int *p; va_start(ap, format); while (*format) { p = va_arg(ap, int *); switch (*format) { case 'v': if (ig->readcb(ig, buf, 2) != 2) return 0; *p = buf[0] + (buf[1] << 8); break; case 'V': if (ig->readcb(ig, buf, 4) != 4) return 0; *p = buf[0] + (buf[1] << 8) + (buf[2] << 16) + (buf[3] << 24); break; case 'C': if (ig->readcb(ig, buf, 1) != 1) return 0; *p = buf[0]; break; case 'c': if (ig->readcb(ig, buf, 1) != 1) return 0; *p = (char)buf[0]; break; case '3': /* extension - 24-bit number */ if (ig->readcb(ig, buf, 3) != 3) return 0; *p = buf[0] + (buf[1] << 8) + (buf[2] << 16); break; default: i_fatal(1, "Unknown read_packed format code 0x%02x", *format); } ++format; } return 1; } /* =item write_packed(ig, format, ...) Writes packed data to the specified io_glue. Returns non-zero on success. =cut */ static int write_packed(io_glue *ig, char *format, ...) { unsigned char buf[4]; va_list ap; int i; va_start(ap, format); while (*format) { i = va_arg(ap, unsigned int); switch (*format) { case 'v': buf[0] = i & 255; buf[1] = i / 256; if (ig->writecb(ig, buf, 2) == -1) return 0; break; case 'V': buf[0] = i & 0xFF; buf[1] = (i >> 8) & 0xFF; buf[2] = (i >> 16) & 0xFF; buf[3] = (i >> 24) & 0xFF; if (ig->writecb(ig, buf, 4) == -1) return 0; break; case 'C': case 'c': buf[0] = i & 0xFF; if (ig->writecb(ig, buf, 1) == -1) return 0; break; default: i_fatal(1, "Unknown write_packed format code 0x%02x", *format); } ++format; } va_end(ap); return 1; } /* =item write_bmphead(ig, im, bit_count, data_size) Writes a Windows BMP header to the file. Returns non-zero on success. =cut */ static int write_bmphead(io_glue *ig, i_img *im, int bit_count, int data_size) { double xres, yres; int got_xres, got_yres, aspect_only; int colors_used = 0; int offset = FILEHEAD_SIZE + INFOHEAD_SIZE; got_xres = i_tags_get_float(&im->tags, "i_xres", 0, &xres); got_yres = i_tags_get_float(&im->tags, "i_yres", 0, &yres); if (!i_tags_get_int(&im->tags, "i_aspect_only", 0,&aspect_only)) aspect_only = 0; if (!got_xres) { if (!got_yres) xres = yres = 72; else xres = yres; } else { if (!got_yres) yres = xres; } if (xres <= 0 || yres <= 0) xres = yres = 72; if (aspect_only) { /* scale so the smaller value is 72 */ double ratio; if (xres < yres) { ratio = 72.0 / xres; } else { ratio = 72.0 / yres; } xres *= ratio; yres *= ratio; } /* now to pels/meter */ xres *= 100.0/2.54; yres *= 100.0/2.54; if (im->type == i_palette_type) { colors_used = i_colorcount(im); offset += 4 * colors_used; } if (!write_packed(ig, "CCVvvVVVVvvVVVVVV", 'B', 'M', data_size+offset, 0, 0, offset, INFOHEAD_SIZE, im->xsize, im->ysize, 1, bit_count, BI_RGB, data_size, (int)(xres+0.5), (int)(yres+0.5), colors_used, colors_used)){ i_push_error(0, "cannot write bmp header"); return 0; } if (im->type == i_palette_type) { int i; i_color c; for (i = 0; i < colors_used; ++i) { i_getcolors(im, i, &c, 1); if (im->channels >= 3) { if (!write_packed(ig, "CCCC", c.channel[2], c.channel[1], c.channel[0], 0)) { i_push_error(0, "cannot write palette entry"); return 0; } } else { if (!write_packed(ig, "CCCC", c.channel[0], c.channel[0], c.channel[0], 0)) { i_push_error(0, "cannot write palette entry"); return 0; } } } } return 1; } /* =item write_1bit_data(ig, im) Writes the image data as a 1-bit/pixel image. Returns non-zero on success. =cut */ static int write_1bit_data(io_glue *ig, i_img *im) { i_palidx *line; unsigned char *packed; int byte; int mask; unsigned char *out; int line_size = (im->xsize+7) / 8; int x, y; int unpacked_size; /* round up to nearest multiple of four */ line_size = (line_size + 3) / 4 * 4; if (!write_bmphead(ig, im, 1, line_size * im->ysize)) return 0; /* this shouldn't be an issue, but let's be careful */ unpacked_size = im->xsize + 8; if (unpacked_size < im->xsize) { i_push_error(0, "integer overflow during memory allocation"); return 0; } line = mymalloc(unpacked_size); /* checked 29jun05 tonyc */ memset(line + im->xsize, 0, 8); /* size allocated here is always much smaller than xsize, hence can't overflow int */ packed = mymalloc(line_size); /* checked 29jun05 tonyc */ memset(packed, 0, line_size); for (y = im->ysize-1; y >= 0; --y) { i_gpal(im, 0, im->xsize, y, line); mask = 0x80; byte = 0; out = packed; for (x = 0; x < im->xsize; ++x) { if (line[x]) byte |= mask; if ((mask >>= 1) == 0) { *out++ = byte; byte = 0; mask = 0x80; } } if (mask != 0x80) { *out++ = byte; } if (ig->writecb(ig, packed, line_size) < 0) { myfree(packed); myfree(line); i_push_error(0, "writing 1 bit/pixel packed data"); return 0; } } myfree(packed); myfree(line); ig->closecb(ig); return 1; } /* =item write_4bit_data(ig, im) Writes the image data as a 4-bit/pixel image. Returns non-zero on success. =cut */ static int write_4bit_data(io_glue *ig, i_img *im) { i_palidx *line; unsigned char *packed; unsigned char *out; int line_size = (im->xsize+1) / 2; int x, y; int unpacked_size; /* round up to nearest multiple of four */ line_size = (line_size + 3) / 4 * 4; if (!write_bmphead(ig, im, 4, line_size * im->ysize)) return 0; /* this shouldn't be an issue, but let's be careful */ unpacked_size = im->xsize + 2; if (unpacked_size < im->xsize) { i_push_error(0, "integer overflow during memory allocation"); return 0; } line = mymalloc(unpacked_size); /* checked 29jun05 tonyc */ memset(line + im->xsize, 0, 2); /* size allocated here is always much smaller than xsize, hence can't overflow int */ packed = mymalloc(line_size); /* checked 29jun05 tonyc */ memset(packed, 0, line_size); for (y = im->ysize-1; y >= 0; --y) { i_gpal(im, 0, im->xsize, y, line); out = packed; for (x = 0; x < im->xsize; x += 2) { *out++ = (line[x] << 4) + line[x+1]; } if (ig->writecb(ig, packed, line_size) < 0) { myfree(packed); myfree(line); i_push_error(0, "writing 4 bit/pixel packed data"); return 0; } } myfree(packed); myfree(line); ig->closecb(ig); return 1; } /* =item write_8bit_data(ig, im) Writes the image data as a 8-bit/pixel image. Returns non-zero on success. =cut */ static int write_8bit_data(io_glue *ig, i_img *im) { i_palidx *line; int line_size = im->xsize; int y; int unpacked_size; /* round up to nearest multiple of four */ line_size = (line_size + 3) / 4 * 4; if (!write_bmphead(ig, im, 8, line_size * im->ysize)) return 0; /* this shouldn't be an issue, but let's be careful */ unpacked_size = im->xsize + 4; if (unpacked_size < im->xsize) { i_push_error(0, "integer overflow during memory allocation"); return 0; } line = mymalloc(unpacked_size); /* checked 29jun05 tonyc */ memset(line + im->xsize, 0, 4); for (y = im->ysize-1; y >= 0; --y) { i_gpal(im, 0, im->xsize, y, line); if (ig->writecb(ig, line, line_size) < 0) { myfree(line); i_push_error(0, "writing 8 bit/pixel packed data"); return 0; } } myfree(line); ig->closecb(ig); return 1; } /* =item write_24bit_data(ig, im) Writes the image data as a 24-bit/pixel image. Returns non-zero on success. =cut */ static int write_24bit_data(io_glue *ig, i_img *im) { unsigned char *samples; int y; int line_size = 3 * im->xsize; i_color bg; i_get_file_background(im, &bg); /* just in case we implement a direct format with 2bytes/pixel (unlikely though) */ if (line_size / 3 != im->xsize) { i_push_error(0, "integer overflow during memory allocation"); return 0; } line_size = (line_size + 3) / 4 * 4; if (!write_bmphead(ig, im, 24, line_size * im->ysize)) return 0; samples = mymalloc(4 * im->xsize); memset(samples, 0, line_size); for (y = im->ysize-1; y >= 0; --y) { unsigned char *samplep = samples; int x; i_gsamp_bg(im, 0, im->xsize, y, samples, 3, &bg); for (x = 0; x < im->xsize; ++x) { unsigned char tmp = samplep[2]; samplep[2] = samplep[0]; samplep[0] = tmp; samplep += 3; } if (ig->writecb(ig, samples, line_size) < 0) { i_push_error(0, "writing image data"); myfree(samples); return 0; } } myfree(samples); ig->closecb(ig); return 1; } /* =item read_bmp_pal(ig, im, count) Reads count palette entries from the file and add them to the image. Returns non-zero on success. =cut */ static int read_bmp_pal(io_glue *ig, i_img *im, int count) { int i; int r, g, b, x; i_color c; for (i = 0; i < count; ++i) { if (!read_packed(ig, "CCCC", &b, &g, &r, &x)) { i_push_error(0, "reading BMP palette"); return 0; } c.channel[0] = r; c.channel[1] = g; c.channel[2] = b; if (i_addcolors(im, &c, 1) < 0) { i_push_error(0, "out of space in image palette"); return 0; } } return 1; } /* =item read_1bit_bmp(ig, xsize, ysize, clr_used, compression, offbits) Reads in the palette and image data for a 1-bit/pixel image. Returns the image or NULL. =cut */ static i_img * read_1bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete) { i_img *im; int x, y, lasty, yinc, start_y; i_palidx *line, *p; unsigned char *packed; int line_size = (xsize + 7)/8; int bit; unsigned char *in; long base_offset; if (compression != BI_RGB) { i_push_errorf(0, "unknown 1-bit BMP compression (%d)", compression); return NULL; } if (xsize + 8 < xsize) { /* if there was overflow */ /* we check with 8 because we allocate that much for the decoded line buffer */ i_push_error(0, "integer overflow during memory allocation"); return NULL; } /* if xsize+7 is ok then (xsize+7)/8 will be and the minor adjustments below won't make it overflow */ line_size = (line_size+3) / 4 * 4; if (ysize > 0) { start_y = ysize-1; lasty = -1; yinc = -1; } else { /* when ysize is -ve it's a top-down image */ ysize = -ysize; start_y = 0; lasty = ysize; yinc = 1; } y = start_y; if (!clr_used) clr_used = 2; if (clr_used < 0 || clr_used > 2) { i_push_errorf(0, "out of range colors used (%d)", clr_used); return NULL; } base_offset = FILEHEAD_SIZE + INFOHEAD_SIZE + clr_used * 4; if (offbits < base_offset) { i_push_errorf(0, "image data offset too small (%ld)", offbits); return NULL; } im = i_img_pal_new(xsize, ysize, 3, 256); if (!im) return NULL; if (!read_bmp_pal(ig, im, clr_used)) { i_img_destroy(im); return NULL; } if (offbits > base_offset) { /* this will be slow if the offset is large, but that should be rare */ char buffer; while (base_offset < offbits) { if (ig->readcb(ig, &buffer, 1) != 1) { i_img_destroy(im); i_push_error(0, "failed skipping to image data offset"); return NULL; } ++base_offset; } } i_tags_add(&im->tags, "bmp_compression_name", 0, "BI_RGB", -1, 0); packed = mymalloc(line_size); /* checked 29jun05 tonyc */ line = mymalloc(xsize+8); /* checked 29jun05 tonyc */ while (y != lasty) { if (ig->readcb(ig, packed, line_size) != line_size) { myfree(packed); myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(start_y - y)); return im; } else { i_push_error(0, "failed reading 1-bit bmp data"); i_img_destroy(im); return NULL; } } in = packed; bit = 0x80; p = line; for (x = 0; x < xsize; ++x) { *p++ = (*in & bit) ? 1 : 0; bit >>= 1; if (!bit) { ++in; bit = 0x80; } } i_ppal(im, 0, xsize, y, line); y += yinc; } myfree(packed); myfree(line); return im; } /* =item read_4bit_bmp(ig, xsize, ysize, clr_used, compression) Reads in the palette and image data for a 4-bit/pixel image. Returns the image or NULL. Hopefully this will be combined with the following function at some point. =cut */ static i_img * read_4bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete) { i_img *im; int x, y, lasty, yinc; i_palidx *line, *p; unsigned char *packed; int line_size = (xsize + 1)/2; unsigned char *in; int size, i; long base_offset; int starty; /* line_size is going to be smaller than xsize in most cases (and when it's not, xsize is itself small), and hence not overflow */ line_size = (line_size+3) / 4 * 4; if (ysize > 0) { starty = ysize-1; lasty = -1; yinc = -1; } else { /* when ysize is -ve it's a top-down image */ ysize = -ysize; starty = 0; lasty = ysize; yinc = 1; } y = starty; if (!clr_used) clr_used = 16; if (clr_used > 16 || clr_used < 0) { i_push_errorf(0, "out of range colors used (%d)", clr_used); return NULL; } base_offset = FILEHEAD_SIZE + INFOHEAD_SIZE + clr_used * 4; if (offbits < base_offset) { i_push_errorf(0, "image data offset too small (%ld)", offbits); return NULL; } im = i_img_pal_new(xsize, ysize, 3, 256); if (!im) /* error should have been pushed already */ return NULL; if (!read_bmp_pal(ig, im, clr_used)) { i_img_destroy(im); return NULL; } if (offbits > base_offset) { /* this will be slow if the offset is large, but that should be rare */ char buffer; while (base_offset < offbits) { if (ig->readcb(ig, &buffer, 1) != 1) { i_img_destroy(im); i_push_error(0, "failed skipping to image data offset"); return NULL; } ++base_offset; } } if (line_size < 260) packed = mymalloc(260); /* checked 29jun05 tonyc */ else packed = mymalloc(line_size); /* checked 29jun05 tonyc */ /* xsize won't approach MAXINT */ line = mymalloc(xsize+1); /* checked 29jun05 tonyc */ if (compression == BI_RGB) { i_tags_add(&im->tags, "bmp_compression_name", 0, "BI_RGB", -1, 0); while (y != lasty) { if (ig->readcb(ig, packed, line_size) != line_size) { myfree(packed); myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(y - starty)); return im; } else { i_push_error(0, "failed reading 4-bit bmp data"); i_img_destroy(im); return NULL; } } in = packed; p = line; for (x = 0; x < xsize; x+=2) { *p++ = *in >> 4; *p++ = *in & 0x0F; ++in; } i_ppal(im, 0, xsize, y, line); y += yinc; } myfree(packed); myfree(line); } else if (compression == BI_RLE4) { int read_size; int count; i_tags_add(&im->tags, "bmp_compression_name", 0, "BI_RLE4", -1, 0); x = 0; while (1) { /* there's always at least 2 bytes in a sequence */ if (ig->readcb(ig, packed, 2) != 2) { myfree(packed); myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(y - starty)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } else if (packed[0]) { if (x + packed[0] > xsize) { /* this file is corrupt */ myfree(packed); myfree(line); i_push_error(0, "invalid data during decompression"); i_img_destroy(im); return NULL; } line[0] = packed[1] >> 4; line[1] = packed[1] & 0x0F; for (i = 0; i < packed[0]; i += 2) { if (i < packed[0]-1) i_ppal(im, x, x+2, y, line); else i_ppal(im, x, x+(packed[0]-i), y, line); x += 2; } } else { switch (packed[1]) { case BMPRLE_ENDOFLINE: x = 0; y += yinc; break; case BMPRLE_ENDOFBMP: myfree(packed); myfree(line); return im; case BMPRLE_DELTA: if (ig->readcb(ig, packed, 2) != 2) { myfree(packed); myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(y - starty)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } x += packed[0]; y += yinc * packed[1]; break; default: count = packed[1]; if (x + count > xsize) { /* this file is corrupt */ myfree(packed); myfree(line); i_push_error(0, "invalid data during decompression"); i_img_destroy(im); return NULL; } size = (count + 1) / 2; read_size = (size+1) / 2 * 2; if (ig->readcb(ig, packed, read_size) != read_size) { myfree(packed); myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(y - starty)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } for (i = 0; i < size; ++i) { line[0] = packed[i] >> 4; line[1] = packed[i] & 0xF; i_ppal(im, x, x+2, y, line); x += 2; } break; } } } } else { /*if (compression == BI_RLE4) {*/ myfree(packed); myfree(line); i_push_errorf(0, "unknown 4-bit BMP compression (%d)", compression); i_img_destroy(im); return NULL; } return im; } /* =item read_8bit_bmp(ig, xsize, ysize, clr_used, compression, allow_incomplete) Reads in the palette and image data for a 8-bit/pixel image. Returns the image or NULL. =cut */ static i_img * read_8bit_bmp(io_glue *ig, int xsize, int ysize, int clr_used, int compression, long offbits, int allow_incomplete) { i_img *im; int x, y, lasty, yinc, start_y; i_palidx *line; int line_size = xsize; long base_offset; line_size = (line_size+3) / 4 * 4; if (line_size < xsize) { /* if it overflowed (unlikely, but check) */ i_push_error(0, "integer overflow during memory allocation"); return NULL; } if (ysize > 0) { start_y = ysize-1; lasty = -1; yinc = -1; } else { /* when ysize is -ve it's a top-down image */ ysize = -ysize; start_y = 0; lasty = ysize; yinc = 1; } y = start_y; if (!clr_used) clr_used = 256; if (clr_used > 256 || clr_used < 0) { i_push_errorf(0, "out of range colors used (%d)", clr_used); return NULL; } base_offset = FILEHEAD_SIZE + INFOHEAD_SIZE + clr_used * 4; if (offbits < base_offset) { i_push_errorf(0, "image data offset too small (%ld)", offbits); return NULL; } im = i_img_pal_new(xsize, ysize, 3, 256); if (!im) return NULL; if (!read_bmp_pal(ig, im, clr_used)) { i_img_destroy(im); return NULL; } if (offbits > base_offset) { /* this will be slow if the offset is large, but that should be rare */ char buffer; while (base_offset < offbits) { if (ig->readcb(ig, &buffer, 1) != 1) { i_img_destroy(im); i_push_error(0, "failed skipping to image data offset"); return NULL; } ++base_offset; } } line = mymalloc(line_size); /* checked 29jun05 tonyc */ if (compression == BI_RGB) { i_tags_add(&im->tags, "bmp_compression_name", 0, "BI_RGB", -1, 0); while (y != lasty) { if (ig->readcb(ig, line, line_size) != line_size) { myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(start_y - y)); return im; } else { i_push_error(0, "failed reading 8-bit bmp data"); i_img_destroy(im); return NULL; } } i_ppal(im, 0, xsize, y, line); y += yinc; } myfree(line); } else if (compression == BI_RLE8) { int read_size; int count; unsigned char packed[2]; i_tags_add(&im->tags, "bmp_compression_name", 0, "BI_RLE8", -1, 0); x = 0; while (1) { /* there's always at least 2 bytes in a sequence */ if (ig->readcb(ig, packed, 2) != 2) { myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(start_y-y)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } if (packed[0]) { if (x + packed[0] > xsize) { /* this file isn't incomplete, it's corrupt */ myfree(line); i_push_error(0, "invalid data during decompression"); i_img_destroy(im); return NULL; } memset(line, packed[1], packed[0]); i_ppal(im, x, x+packed[0], y, line); x += packed[0]; } else { switch (packed[1]) { case BMPRLE_ENDOFLINE: x = 0; y += yinc; break; case BMPRLE_ENDOFBMP: myfree(line); return im; case BMPRLE_DELTA: if (ig->readcb(ig, packed, 2) != 2) { myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(start_y-y)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } x += packed[0]; y += yinc * packed[1]; break; default: count = packed[1]; if (x + count > xsize) { /* runs shouldn't cross a line boundary */ /* this file isn't incomplete, it's corrupt */ myfree(line); i_push_error(0, "invalid data during decompression"); i_img_destroy(im); return NULL; } read_size = (count+1) / 2 * 2; if (ig->readcb(ig, line, read_size) != read_size) { myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(start_y-y)); return im; } else { i_push_error(0, "missing data during decompression"); i_img_destroy(im); return NULL; } } i_ppal(im, x, x+count, y, line); x += count; break; } } } } else { myfree(line); i_push_errorf(0, "unknown 8-bit BMP compression (%d)", compression); i_img_destroy(im); return NULL; } return im; } struct bm_masks { unsigned masks[3]; int shifts[3]; }; static struct bm_masks std_masks[] = { { /* 16-bit */ { 0770000, 00007700, 00000077, }, { 10, 4, -2, }, }, { /* 24-bit */ { 0xFF0000, 0x00FF00, 0x0000FF, }, { 16, 8, 0, }, }, { /* 32-bit */ { 0xFF0000, 0x00FF00, 0x0000FF, }, { 16, 8, 0, }, }, }; /* =item read_direct_bmp(ig, xsize, ysize, bit_count, clr_used, compression, allow_incomplete) Skips the palette and reads in the image data for a direct colour image. Returns the image or NULL. =cut */ static i_img * read_direct_bmp(io_glue *ig, int xsize, int ysize, int bit_count, int clr_used, int compression, long offbits, int allow_incomplete) { i_img *im; int x, y, starty, lasty, yinc; i_color *line, *p; int pix_size = bit_count / 8; int line_size = xsize * pix_size; struct bm_masks masks; char unpack_code[2] = ""; int i; int extras; char junk[4]; const char *compression_name; int bytes; long base_offset = FILEHEAD_SIZE + INFOHEAD_SIZE; unpack_code[0] = *("v3V"+pix_size-2); unpack_code[1] = '\0'; line_size = (line_size+3) / 4 * 4; extras = line_size - xsize * pix_size; if (ysize > 0) { starty = ysize-1; lasty = -1; yinc = -1; } else { /* when ysize is -ve it's a top-down image */ ysize = -ysize; starty = 0; lasty = ysize; yinc = 1; } y = starty; if (compression == BI_RGB) { compression_name = "BI_RGB"; masks = std_masks[pix_size-2]; /* there's a potential "palette" after the header */ for (i = 0; i < clr_used; ++clr_used) { char buf[4]; if (ig->readcb(ig, buf, 4) != 4) { i_push_error(0, "skipping colors"); return 0; } base_offset += 4; } } else if (compression == BI_BITFIELDS) { int pos, bit; compression_name = "BI_BITFIELDS"; for (i = 0; i < 3; ++i) { if (!read_packed(ig, "V", masks.masks+i)) { i_push_error(0, "reading pixel masks"); return 0; } /* work out a shift for the mask */ pos = 0; bit = masks.masks[i] & -masks.masks[i]; while (bit) { ++pos; bit >>= 1; } masks.shifts[i] = pos - 8; } base_offset += 4 * 4; } else { i_push_errorf(0, "unknown 24-bit BMP compression (%d)", compression); return NULL; } if (offbits < base_offset) { i_push_errorf(0, "image data offset too small (%ld)", offbits); return NULL; } if (offbits > base_offset) { /* this will be slow if the offset is large, but that should be rare */ char buffer; while (base_offset < offbits) { if (ig->readcb(ig, &buffer, 1) != 1) { i_push_error(0, "failed skipping to image data offset"); return NULL; } ++base_offset; } } im = i_img_empty(NULL, xsize, ysize); if (!im) return NULL; i_tags_add(&im->tags, "bmp_compression_name", 0, compression_name, -1, 0); /* I wasn't able to make this overflow in testing, but better to be safe */ bytes = sizeof(i_color) * xsize; if (bytes / sizeof(i_color) != xsize) { i_img_destroy(im); i_push_error(0, "integer overflow calculating buffer size"); return NULL; } line = mymalloc(bytes); /* checked 29jun05 tonyc */ while (y != lasty) { p = line; for (x = 0; x < xsize; ++x) { unsigned pixel; if (!read_packed(ig, unpack_code, &pixel)) { myfree(line); if (allow_incomplete) { i_tags_setn(&im->tags, "i_incomplete", 1); i_tags_setn(&im->tags, "i_lines_read", abs(starty - y)); return im; } else { i_push_error(0, "failed reading image data"); i_img_destroy(im); return NULL; } } for (i = 0; i < 3; ++i) { if (masks.shifts[i] > 0) p->channel[i] = (pixel & masks.masks[i]) >> masks.shifts[i]; else p->channel[i] = (pixel & masks.masks[i]) << -masks.shifts[i]; } ++p; } i_plin(im, 0, xsize, y, line); if (extras) ig->readcb(ig, junk, extras); y += yinc; } myfree(line); return im; } /* =head1 SEE ALSO Imager(3) =head1 AUTHOR Tony Cook =head1 RESTRICTIONS Cannot save as compressed BMP. =head1 BUGS Doesn't handle OS/2 bitmaps. 16-bit/pixel images haven't been tested. (I need an image). BI_BITFIELDS compression hasn't been tested (I need an image). The header handling for paletted images needs to be refactored =cut */