#include "fitz-imp.h" #include #include #include #define SANE_DPI 72.0f #define INSANE_DPI 4800.0f #define SCALABLE_IMAGE_DPI 600 struct fz_compressed_image_s { fz_image super; fz_pixmap *tile; fz_compressed_buffer *buffer; }; struct fz_pixmap_image_s { fz_image super; fz_pixmap *tile; }; typedef struct fz_image_key_s fz_image_key; struct fz_image_key_s { int refs; fz_image *image; int l2factor; fz_irect rect; }; fz_image * fz_keep_image(fz_context *ctx, fz_image *image) { return fz_keep_key_storable(ctx, &image->key_storable); } fz_image * fz_keep_image_store_key(fz_context *ctx, fz_image *image) { return fz_keep_key_storable_key(ctx, &image->key_storable); } void fz_drop_image_store_key(fz_context *ctx, fz_image *image) { fz_drop_key_storable_key(ctx, &image->key_storable); } static int fz_make_hash_image_key(fz_context *ctx, fz_store_hash *hash, void *key_) { fz_image_key *key = (fz_image_key *)key_; hash->u.pir.ptr = key->image; hash->u.pir.i = key->l2factor; hash->u.pir.r = key->rect; return 1; } static void * fz_keep_image_key(fz_context *ctx, void *key_) { fz_image_key *key = (fz_image_key *)key_; return fz_keep_imp(ctx, key, &key->refs); } static void fz_drop_image_key(fz_context *ctx, void *key_) { fz_image_key *key = (fz_image_key *)key_; if (fz_drop_imp(ctx, key, &key->refs)) { fz_drop_image_store_key(ctx, key->image); fz_free(ctx, key); } } static int fz_cmp_image_key(fz_context *ctx, void *k0_, void *k1_) { fz_image_key *k0 = (fz_image_key *)k0_; fz_image_key *k1 = (fz_image_key *)k1_; return k0->image == k1->image && k0->l2factor == k1->l2factor && k0->rect.x0 == k1->rect.x0 && k0->rect.y0 == k1->rect.y0 && k0->rect.x1 == k1->rect.x1 && k0->rect.y1 == k1->rect.y1; } static void fz_format_image_key(fz_context *ctx, char *s, int n, void *key_) { fz_image_key *key = (fz_image_key *)key_; fz_snprintf(s, n, "(image %d x %d sf=%d)", key->image->w, key->image->h, key->l2factor); } static int fz_needs_reap_image_key(fz_context *ctx, void *key_) { fz_image_key *key = (fz_image_key *)key_; return fz_key_storable_needs_reaping(ctx, &key->image->key_storable); } static const fz_store_type fz_image_store_type = { fz_make_hash_image_key, fz_keep_image_key, fz_drop_image_key, fz_cmp_image_key, fz_format_image_key, fz_needs_reap_image_key }; void fz_drop_image(fz_context *ctx, fz_image *image) { fz_drop_key_storable(ctx, &image->key_storable); } static void fz_mask_color_key(fz_pixmap *pix, int n, const int *colorkey) { unsigned char *p = pix->samples; int w; int k, t; int h = pix->h; int stride = pix->stride - pix->w * pix->n; if (pix->w == 0) return; while (h--) { w = pix->w; do { t = 1; for (k = 0; k < n; k++) if (p[k] < colorkey[k * 2] || p[k] > colorkey[k * 2 + 1]) t = 0; if (t) for (k = 0; k < pix->n; k++) p[k] = 0; p += pix->n; } while (--w); p += stride; } } static void fz_unblend_masked_tile(fz_context *ctx, fz_pixmap *tile, fz_image *image) { fz_pixmap *mask = fz_get_pixmap_from_image(ctx, image->mask, NULL, NULL, NULL, NULL); unsigned char *s = mask->samples; unsigned char *d = tile->samples; int n = tile->n; int k; int sstride = mask->stride - mask->w * mask->n; int dstride = tile->stride - tile->w * tile->n; int h = mask->h; if (tile->w != mask->w || tile->h != mask->h) { fz_warn(ctx, "mask must be of same size as image for /Matte"); fz_drop_pixmap(ctx, mask); return; } if (mask->w != 0) { while (h--) { int w = mask->w; do { if (*s == 0) for (k = 0; k < image->n; k++) d[k] = image->colorkey[k]; else for (k = 0; k < image->n; k++) d[k] = fz_clampi(image->colorkey[k] + (d[k] - image->colorkey[k]) * 255 / *s, 0, 255); s++; d += n; } while (--w); s += sstride; d += dstride; } } fz_drop_pixmap(ctx, mask); } fz_pixmap * fz_decomp_image_from_stream(fz_context *ctx, fz_stream *stm, fz_compressed_image *cimg, fz_irect *subarea, int indexed, int l2factor) { fz_image *image = &cimg->super; fz_pixmap *tile = NULL; size_t stride, len, i; unsigned char *samples = NULL; int f = 1<w; int h = image->h; if (subarea) { int bpp = image->bpc * image->n; int mask; switch (bpp) { case 1: mask = 8*f; break; case 2: mask = 4*f; break; case 4: mask = 2*f; break; default: mask = (bpp & 7) == 0 ? f : 0; break; } if (mask != 0) { subarea->x0 &= ~(mask - 1); subarea->x1 = (subarea->x1 + mask - 1) & ~(mask - 1); } else { /* Awkward case - mask cannot be a power of 2. */ mask = bpp*f; switch (bpp) { case 3: case 5: case 7: case 9: case 11: case 13: case 15: default: mask *= 8; break; case 6: case 10: case 14: mask *= 4; break; case 12: mask *= 2; break; } subarea->x0 = (subarea->x0 / mask) * mask; subarea->x1 = ((subarea->x1 + mask - 1) / mask) * mask; } subarea->y0 &= ~(f - 1); if (subarea->x1 > image->w) subarea->x1 = image->w; subarea->y1 = (subarea->y1 + f - 1) & ~(f - 1); if (subarea->y1 > image->h) subarea->y1 = image->h; w = (subarea->x1 - subarea->x0); h = (subarea->y1 - subarea->y0); } w = (w + f - 1) >> l2factor; h = (h + f - 1) >> l2factor; fz_var(tile); fz_var(samples); fz_try(ctx) { int alpha = (image->colorspace == NULL); if (image->use_colorkey) alpha = 1; tile = fz_new_pixmap(ctx, image->colorspace, w, h, alpha); tile->interpolate = image->interpolate; stride = (w * image->n * image->bpc + 7) / 8; samples = fz_malloc_array(ctx, h, stride); if (subarea) { int hh; unsigned char *s = samples; int stream_w = (image->w + f - 1)>>l2factor; size_t stream_stride = (stream_w * image->n * image->bpc + 7) / 8; int l_margin = subarea->x0 >> l2factor; int t_margin = subarea->y0 >> l2factor; int r_margin = (image->w + f - 1 - subarea->x1) >> l2factor; int b_margin = (image->h + f - 1 - subarea->y1) >> l2factor; int l_skip = (l_margin * image->n * image->bpc)/8; int r_skip = (r_margin * image->n * image->bpc + 7)/8; size_t t_skip = t_margin * stream_stride + l_skip; size_t b_skip = b_margin * stream_stride + r_skip; size_t l = fz_skip(ctx, stm, t_skip); len = 0; if (l == t_skip) { hh = h; do { l = fz_read(ctx, stm, s, stride); s += l; len += l; if (l < stride) break; if (--hh == 0) break; l = fz_skip(ctx, stm, r_skip + l_skip); if (l < (size_t)(r_skip + l_skip)) break; } while (1); (void)fz_skip(ctx, stm, r_skip + b_skip); } } else { len = fz_read(ctx, stm, samples, h * stride); } /* Pad truncated images */ if (len < stride * h) { fz_warn(ctx, "padding truncated image"); memset(samples + len, 0, stride * h - len); } /* Invert 1-bit image masks */ if (image->imagemask) { /* 0=opaque and 1=transparent so we need to invert */ unsigned char *p = samples; len = h * stride; for (i = 0; i < len; i++) p[i] = ~p[i]; } fz_unpack_tile(ctx, tile, samples, image->n, image->bpc, stride, indexed); fz_free(ctx, samples); samples = NULL; /* color keyed transparency */ if (image->use_colorkey && !image->mask) fz_mask_color_key(tile, image->n, image->colorkey); if (indexed) { fz_pixmap *conv; fz_decode_indexed_tile(ctx, tile, image->decode, (1 << image->bpc) - 1); conv = fz_expand_indexed_pixmap(ctx, tile, alpha); fz_drop_pixmap(ctx, tile); tile = conv; } else if (image->use_decode) { fz_decode_tile(ctx, tile, image->decode); } /* pre-blended matte color */ if (image->use_colorkey && image->mask) fz_unblend_masked_tile(ctx, tile, image); } fz_always(ctx) { fz_drop_stream(ctx, stm); } fz_catch(ctx) { fz_drop_pixmap(ctx, tile); fz_free(ctx, samples); fz_rethrow(ctx); } return tile; } void fz_drop_image_base(fz_context *ctx, fz_image *image) { fz_drop_colorspace(ctx, image->colorspace); fz_drop_image(ctx, image->mask); fz_free(ctx, image); } void fz_drop_image_imp(fz_context *ctx, fz_storable *image_) { fz_image *image = (fz_image *)image_; image->drop_image(ctx, image); fz_drop_image_base(ctx, image); } static void drop_compressed_image(fz_context *ctx, fz_image *image_) { fz_compressed_image *image = (fz_compressed_image *)image_; fz_drop_pixmap(ctx, image->tile); fz_drop_compressed_buffer(ctx, image->buffer); } static void drop_pixmap_image(fz_context *ctx, fz_image *image_) { fz_pixmap_image *image = (fz_pixmap_image *)image_; fz_drop_pixmap(ctx, image->tile); } static fz_pixmap * compressed_image_get_pixmap(fz_context *ctx, fz_image *image_, fz_irect *subarea, int w, int h, int *l2factor) { fz_compressed_image *image = (fz_compressed_image *)image_; int native_l2factor; fz_stream *stm; int indexed; fz_pixmap *tile; int can_sub = 0; /* We need to make a new one. */ /* First check for ones that we can't decode using streams */ switch (image->buffer->params.type) { case FZ_IMAGE_PNG: tile = fz_load_png(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_GIF: tile = fz_load_gif(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_BMP: tile = fz_load_bmp(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_TIFF: tile = fz_load_tiff(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_PNM: tile = fz_load_pnm(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_JXR: tile = fz_load_jxr(ctx, image->buffer->buffer->data, image->buffer->buffer->len); break; case FZ_IMAGE_JPX: tile = fz_load_jpx(ctx, image->buffer->buffer->data, image->buffer->buffer->len, NULL); break; case FZ_IMAGE_JPEG: /* Scan JPEG stream and patch missing height values in header */ { unsigned char *s = image->buffer->buffer->data; unsigned char *e = s + image->buffer->buffer->len; unsigned char *d; for (d = s + 2; s < d && d < e - 9 && d[0] == 0xFF; d += (d[2] << 8 | d[3]) + 2) { if (d[1] < 0xC0 || (0xC3 < d[1] && d[1] < 0xC9) || 0xCB < d[1]) continue; if ((d[5] == 0 && d[6] == 0) || ((d[5] << 8) | d[6]) > image->super.h) { d[5] = (image->super.h >> 8) & 0xFF; d[6] = image->super.h & 0xFF; } } } /* fall through */ default: native_l2factor = l2factor ? *l2factor : 0; stm = fz_open_image_decomp_stream_from_buffer(ctx, image->buffer, l2factor); if (l2factor) native_l2factor -= *l2factor; indexed = fz_colorspace_is_indexed(ctx, image->super.colorspace); can_sub = 1; tile = fz_decomp_image_from_stream(ctx, stm, image, subarea, indexed, native_l2factor); /* CMYK JPEGs in XPS documents have to be inverted */ if (image->super.invert_cmyk_jpeg && image->buffer->params.type == FZ_IMAGE_JPEG && image->super.colorspace == fz_device_cmyk(ctx) && image->buffer->params.u.jpeg.color_transform) { fz_invert_pixmap(ctx, tile); } break; } if (can_sub == 0 && subarea != NULL) { subarea->x0 = 0; subarea->y0 = 0; subarea->x1 = image->super.w; subarea->y1 = image->super.h; } return tile; } static fz_pixmap * pixmap_image_get_pixmap(fz_context *ctx, fz_image *image_, fz_irect *subarea, int w, int h, int *l2factor) { fz_pixmap_image *image = (fz_pixmap_image *)image_; /* 'Simple' images created direct from pixmaps will have no buffer * of compressed data. We cannot do any better than just returning * a pointer to the original 'tile'. */ return fz_keep_pixmap(ctx, image->tile); /* That's all we can give you! */ } static void update_ctm_for_subarea(fz_matrix *ctm, const fz_irect *subarea, int w, int h) { fz_matrix m; if (subarea->x0 == 0 && subarea->y0 == 0 && subarea->x1 == w && subarea->y1 == h) return; m.a = (subarea->x1 - subarea->x0) / (float)w; m.b = 0; m.c = 0; m.d = (subarea->y1 - subarea->y0) / (float)h; m.e = subarea->x0 / (float)w; m.f = subarea->y0 / (float)h; fz_concat(ctm, &m, ctm); } void fz_default_image_decode(void *arg, int w, int h, int l2factor, fz_irect *subarea) { (void)arg; if ((subarea->x1-subarea->x0)*(subarea->y1-subarea->y0) >= (w*h/10)*9) { /* Either no subarea specified, or a subarea 90% or more of the * whole area specified. Use the whole image. */ subarea->x0 = 0; subarea->y0 = 0; subarea->x1 = w; subarea->y1 = h; } else { /* Clip to the edges if they are within 1% */ if (subarea->x0 <= w/100) subarea->x0 = 0; if (subarea->y0 <= h/100) subarea->y0 = 0; if (subarea->x1 >= w*99/100) subarea->x1 = w; if (subarea->y1 >= h*99/100) subarea->y1 = h; } } fz_pixmap * fz_get_pixmap_from_image(fz_context *ctx, fz_image *image, const fz_irect *subarea, fz_matrix *ctm, int *dw, int *dh) { fz_pixmap *tile; int l2factor, l2factor_remaining; fz_image_key key; fz_image_key *keyp; int w; int h; if (!image) return NULL; /* Figure out the extent. */ if (ctm) { w = sqrtf(ctm->a * ctm->a + ctm->b * ctm->b); h = sqrtf(ctm->c * ctm->c + ctm->d * ctm->d); } else { w = image->w; h = image->h; } if (image->scalable) { /* If the image is scalable, we always want to re-render and never cache. */ fz_irect subarea_copy; if (subarea) subarea_copy = *subarea; l2factor_remaining = 0; if (dw) *dw = w; if (dh) *dh = h; return image->get_pixmap(ctx, image, subarea ? &subarea_copy : NULL, image->w, image->h, &l2factor_remaining); } /* Clamp requested image size, since we never want to magnify images here. */ if (w > image->w) w = image->w; if (h > image->h) h = image->h; if (image->decoded) { /* If the image is already decoded, then we can't offer a subarea, * or l2factor, and we don't want to cache. */ l2factor_remaining = 0; if (dw) *dw = w; if (dh) *dh = h; return image->get_pixmap(ctx, image, NULL, image->w, image->h, &l2factor_remaining); } /* What is our ideal factor? We search for the largest factor where * we can subdivide and stay larger than the required size. We add * a fudge factor of +2 here to allow for the possibility of * expansion due to grid fitting. */ if (w == 0 || h == 0) l2factor = 0; else for (l2factor=0; image->w>>(l2factor+1) >= w+2 && image->h>>(l2factor+1) >= h+2 && l2factor < 6; l2factor++); /* Now figure out if we want to decode just a subarea */ if (subarea == NULL) { key.rect.x0 = 0; key.rect.y0 = 0; key.rect.x1 = image->w; key.rect.y1 = image->h; } else { key.rect = *subarea; ctx->tuning->image_decode(ctx->tuning->image_decode_arg, image->w, image->h, l2factor, &key.rect); } /* Based on that subarea, recalculate the extents */ if (ctm) { float frac_w = (key.rect.x1 - key.rect.x0) / (float)image->w; float frac_h = (key.rect.y1 - key.rect.y0) / (float)image->h; float a = ctm->a * frac_w; float b = ctm->b * frac_h; float c = ctm->c * frac_w; float d = ctm->d * frac_h; w = sqrtf(a * a + b * b); h = sqrtf(c * c + d * d); } else { w = image->w; h = image->h; } /* Return the true sizes to the caller */ if (dw) *dw = w; if (dh) *dh = h; if (w > image->w) w = image->w; if (h > image->h) h = image->h; if (w == 0 || h == 0) l2factor = 0; /* Can we find any suitable tiles in the cache? */ key.refs = 1; key.image = image; key.l2factor = l2factor; do { tile = fz_find_item(ctx, fz_drop_pixmap_imp, &key, &fz_image_store_type); if (tile) { update_ctm_for_subarea(ctm, &key.rect, image->w, image->h); return tile; } key.l2factor--; } while (key.l2factor >= 0); /* We'll have to decode the image; request the correct amount of * downscaling. */ l2factor_remaining = l2factor; tile = image->get_pixmap(ctx, image, &key.rect, w, h, &l2factor_remaining); /* Update the ctm to allow for subareas. */ update_ctm_for_subarea(ctm, &key.rect, image->w, image->h); /* l2factor_remaining is updated to the amount of subscaling left to do */ assert(l2factor_remaining >= 0 && l2factor_remaining <= 6); if (l2factor_remaining) { fz_subsample_pixmap(ctx, tile, l2factor_remaining); } /* Now we try to cache the pixmap. Any failure here will just result * in us not caching. */ fz_var(keyp); fz_try(ctx) { fz_pixmap *existing_tile; keyp = fz_malloc_struct(ctx, fz_image_key); keyp->refs = 1; keyp->image = fz_keep_image_store_key(ctx, image); keyp->l2factor = l2factor; keyp->rect = key.rect; existing_tile = fz_store_item(ctx, keyp, tile, fz_pixmap_size(ctx, tile), &fz_image_store_type); if (existing_tile) { /* We already have a tile. This must have been produced by a * racing thread. We'll throw away ours and use that one. */ fz_drop_pixmap(ctx, tile); tile = existing_tile; } } fz_always(ctx) { fz_drop_image_key(ctx, keyp); } fz_catch(ctx) { /* Do nothing */ } return tile; } static size_t pixmap_image_get_size(fz_context *ctx, fz_image *image) { fz_pixmap_image *im = (fz_pixmap_image *)image; if (image == NULL) return 0; return sizeof(fz_pixmap_image) + fz_pixmap_size(ctx, im->tile); } size_t fz_image_size(fz_context *ctx, fz_image *im) { if (im == NULL) return 0; return im->get_size(ctx, im); } fz_image * fz_new_image_from_pixmap(fz_context *ctx, fz_pixmap *pixmap, fz_image *mask) { fz_pixmap_image *image; image = fz_new_derived_image(ctx, pixmap->w, pixmap->h, 8, pixmap->colorspace, pixmap->xres, pixmap->yres, 0, 0, NULL, NULL, mask, fz_pixmap_image, pixmap_image_get_pixmap, pixmap_image_get_size, drop_pixmap_image); image->tile = fz_keep_pixmap(ctx, pixmap); image->super.decoded = 1; return &image->super; } fz_image * fz_new_image_of_size(fz_context *ctx, int w, int h, int bpc, fz_colorspace *colorspace, int xres, int yres, int interpolate, int imagemask, float *decode, int *colorkey, fz_image *mask, int size, fz_image_get_pixmap_fn *get_pixmap, fz_image_get_size_fn *get_size, fz_drop_image_fn *drop) { fz_image *image; int i; assert(mask == NULL || mask->mask == NULL); assert(size >= sizeof(fz_image)); image = Memento_label(fz_calloc(ctx, 1, size), "fz_image"); FZ_INIT_KEY_STORABLE(image, 1, fz_drop_image_imp); image->drop_image = drop; image->get_pixmap = get_pixmap; image->get_size = get_size; image->w = w; image->h = h; image->xres = xres; image->yres = yres; image->bpc = bpc; image->n = (colorspace ? fz_colorspace_n(ctx, colorspace) : 1); image->colorspace = fz_keep_colorspace(ctx, colorspace); image->invert_cmyk_jpeg = 1; image->interpolate = interpolate; image->imagemask = imagemask; image->use_colorkey = (colorkey != NULL); if (colorkey) memcpy(image->colorkey, colorkey, sizeof(int)*image->n*2); image->use_decode = 0; if (decode) { memcpy(image->decode, decode, sizeof(float)*image->n*2); } else { float maxval = fz_colorspace_is_indexed(ctx, colorspace) ? (1 << bpc) - 1 : 1; for (i = 0; i < image->n; i++) { image->decode[2*i] = 0; image->decode[2*i+1] = maxval; } } for (i = 0; i < image->n; i++) { if (image->decode[i * 2] * 255 != 0 || image->decode[i * 2 + 1] * 255 != 255) break; } if (i != image->n) image->use_decode = 1; image->mask = fz_keep_image(ctx, mask); return image; } static size_t compressed_image_get_size(fz_context *ctx, fz_image *image) { fz_compressed_image *im = (fz_compressed_image *)image; if (image == NULL) return 0; return sizeof(fz_pixmap_image) + fz_pixmap_size(ctx, im->tile) + (im->buffer && im->buffer->buffer ? im->buffer->buffer->cap : 0); } fz_image * fz_new_image_from_compressed_buffer(fz_context *ctx, int w, int h, int bpc, fz_colorspace *colorspace, int xres, int yres, int interpolate, int imagemask, float *decode, int *colorkey, fz_compressed_buffer *buffer, fz_image *mask) { fz_compressed_image *image; fz_try(ctx) { image = fz_new_derived_image(ctx, w, h, bpc, colorspace, xres, yres, interpolate, imagemask, decode, colorkey, mask, fz_compressed_image, compressed_image_get_pixmap, compressed_image_get_size, drop_compressed_image); image->buffer = buffer; } fz_catch(ctx) { fz_drop_compressed_buffer(ctx, buffer); fz_rethrow(ctx); } return &image->super; } fz_compressed_buffer *fz_compressed_image_buffer(fz_context *ctx, fz_image *image) { if (image == NULL || image->get_pixmap != compressed_image_get_pixmap) return NULL; return ((fz_compressed_image *)image)->buffer; } void fz_set_compressed_image_buffer(fz_context *ctx, fz_compressed_image *image, fz_compressed_buffer *buf) { assert(image != NULL && image->super.get_pixmap == compressed_image_get_pixmap); ((fz_compressed_image *)image)->buffer = buf; } fz_pixmap *fz_compressed_image_tile(fz_context *ctx, fz_compressed_image *image) { if (image == NULL || image->super.get_pixmap != compressed_image_get_pixmap) return NULL; return ((fz_compressed_image *)image)->tile; } void fz_set_compressed_image_tile(fz_context *ctx, fz_compressed_image *image, fz_pixmap *pix) { assert(image != NULL && image->super.get_pixmap == compressed_image_get_pixmap); ((fz_compressed_image *)image)->tile = pix; } fz_pixmap *fz_pixmap_image_tile(fz_context *ctx, fz_pixmap_image *image) { if (image == NULL || image->super.get_pixmap != pixmap_image_get_pixmap) return NULL; return ((fz_pixmap_image *)image)->tile; } void fz_set_pixmap_image_tile(fz_context *ctx, fz_pixmap_image *image, fz_pixmap *pix) { assert(image != NULL && image->super.get_pixmap == pixmap_image_get_pixmap); ((fz_pixmap_image *)image)->tile = pix; } fz_image * fz_new_image_from_buffer(fz_context *ctx, fz_buffer *buffer) { fz_compressed_buffer *bc; int w, h, xres, yres; fz_colorspace *cspace = NULL; size_t len = buffer->len; unsigned char *buf = buffer->data; fz_image *image; int type; if (len < 8) fz_throw(ctx, FZ_ERROR_GENERIC, "unknown image file format"); fz_var(cspace); fz_try(ctx) { if (buf[0] == 'P' && buf[1] >= '1' && buf[1] <= '7') { type = FZ_IMAGE_PNM; fz_load_pnm_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 0xff && buf[1] == 0x4f) { type = FZ_IMAGE_JPX; fz_load_jpx_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 0x00 && buf[1] == 0x00 && buf[2] == 0x00 && buf[3] == 0x0c && buf[4] == 0x6a && buf[5] == 0x50 && buf[6] == 0x20 && buf[7] == 0x20) { type = FZ_IMAGE_JPX; fz_load_jpx_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 0xff && buf[1] == 0xd8) { type = FZ_IMAGE_JPEG; fz_load_jpeg_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (memcmp(buf, "\211PNG\r\n\032\n", 8) == 0) { type = FZ_IMAGE_PNG; fz_load_png_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 'I' && buf[1] == 'I' && buf[2] == 0xBC) { type = FZ_IMAGE_JXR; fz_load_jxr_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 'I' && buf[1] == 'I' && buf[2] == 42 && buf[3] == 0) { type = FZ_IMAGE_TIFF; fz_load_tiff_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (buf[0] == 'M' && buf[1] == 'M' && buf[2] == 0 && buf[3] == 42) { type = FZ_IMAGE_TIFF; fz_load_tiff_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (memcmp(buf, "GIF", 3) == 0) { type = FZ_IMAGE_GIF; fz_load_gif_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else if (memcmp(buf, "BM", 2) == 0) { type = FZ_IMAGE_BMP; fz_load_bmp_info(ctx, buf, len, &w, &h, &xres, &yres, &cspace); } else fz_throw(ctx, FZ_ERROR_GENERIC, "unknown image file format"); bc = fz_malloc_struct(ctx, fz_compressed_buffer); bc->buffer = fz_keep_buffer(ctx, buffer); bc->params.type = type; if (type == FZ_IMAGE_JPEG) bc->params.u.jpeg.color_transform = -1; image = fz_new_image_from_compressed_buffer(ctx, w, h, 8, cspace, xres, yres, 0, 0, NULL, NULL, bc, NULL); } fz_always(ctx) fz_drop_colorspace(ctx, cspace); fz_catch(ctx) fz_rethrow(ctx); return image; } fz_image * fz_new_image_from_file(fz_context *ctx, const char *path) { fz_buffer *buffer; fz_image *image; buffer = fz_read_file(ctx, path); fz_try(ctx) image = fz_new_image_from_buffer(ctx, buffer); fz_always(ctx) fz_drop_buffer(ctx, buffer); fz_catch(ctx) fz_rethrow(ctx); return image; } void fz_image_resolution(fz_image *image, int *xres, int *yres) { *xres = image->xres; *yres = image->yres; if (*xres < 0 || *yres < 0 || (*xres == 0 && *yres == 0)) { /* If neither xres or yres is sane, pick a sane value */ *xres = SANE_DPI; *yres = SANE_DPI; } else if (*xres == 0) { *xres = *yres; } else if (*yres == 0) { *yres = *xres; } /* Scale xres and yres up until we get believable values */ if (*xres < SANE_DPI || *yres < SANE_DPI || *xres > INSANE_DPI || *yres > INSANE_DPI) { if (*xres == *yres) { *xres = SANE_DPI; *yres = SANE_DPI; } else if (*xres < *yres) { *yres = *yres * SANE_DPI / *xres; *xres = SANE_DPI; } else { *xres = *xres * SANE_DPI / *yres; *yres = SANE_DPI; } } } typedef struct fz_display_list_image_s { fz_image super; fz_matrix transform; fz_display_list *list; } fz_display_list_image; static fz_pixmap * display_list_image_get_pixmap(fz_context *ctx, fz_image *image_, fz_irect *subarea, int w, int h, int *l2factor) { fz_display_list_image *image = (fz_display_list_image *)image_; fz_matrix ctm; fz_device *dev; fz_pixmap *pix; if (subarea) { /* So, the whole image should be scaled to w * h, but we only want the * given subarea of it. */ int l = (subarea->x0 * w) / image->super.w; int t = (subarea->y0 * h) / image->super.h; int r = (subarea->x1 * w + image->super.w - 1) / image->super.w; int b = (subarea->y1 * h + image->super.h - 1) / image->super.h; pix = fz_new_pixmap(ctx, image->super.colorspace, r-l, b-t, 0); pix->x = l; pix->y = t; } else { pix = fz_new_pixmap(ctx, image->super.colorspace, w, h, 0); } /* If we render the display list into pix with the image matrix, we'll get a unit * square result. Therefore scale by w, h. */ ctm = image->transform; fz_pre_scale(&ctm, w, h); fz_clear_pixmap(ctx, pix); /* clear to transparent */ dev = fz_new_draw_device(ctx, &ctm, pix); fz_run_display_list(ctx, image->list, dev, &fz_identity, NULL, NULL); fz_close_device(ctx, dev); fz_drop_device(ctx, dev); /* Never do more subsampling, cos we've already given them the right size */ if (l2factor) *l2factor = 0; return pix; } static void drop_display_list_image(fz_context *ctx, fz_image *image_) { fz_display_list_image *image = (fz_display_list_image *)image_; if (image == NULL) return; fz_drop_display_list(ctx, image->list); } static size_t display_list_image_get_size(fz_context *ctx, fz_image *image_) { fz_display_list_image *image = (fz_display_list_image *)image_; if (image == NULL) return 0; return sizeof(fz_display_list_image) + 4096; /* FIXME */ } fz_image *fz_new_image_from_display_list(fz_context *ctx, float w, float h, fz_display_list *list) { fz_display_list_image *image; int iw, ih; iw = w * SCALABLE_IMAGE_DPI / 72; ih = h * SCALABLE_IMAGE_DPI / 72; image = fz_new_derived_image(ctx, iw, ih, 8, fz_device_rgb(ctx), SCALABLE_IMAGE_DPI, SCALABLE_IMAGE_DPI, 0, 0, NULL, NULL, NULL, fz_display_list_image, display_list_image_get_pixmap, display_list_image_get_size, drop_display_list_image); image->super.scalable = 1; fz_scale(&image->transform, 1 / w, 1 / h); image->list = fz_keep_display_list(ctx, list); return &image->super; }