#include "fitz-imp.h" #include "draw-imp.h" #include #include #include #include #define STACK_SIZE 96 /* Enable the following to attempt to support knockout and/or isolated * blending groups. */ #define ATTEMPT_KNOCKOUT_AND_ISOLATED /* Enable the following to help debug group blending. */ #undef DUMP_GROUP_BLENDS /* Enable the following to help debug graphics stack pushes/pops */ #undef DUMP_STACK_CHANGES typedef struct fz_draw_device_s fz_draw_device; enum { FZ_DRAWDEV_FLAGS_TYPE3 = 1, }; typedef struct fz_draw_state_s fz_draw_state; struct fz_draw_state_s { fz_irect scissor; fz_pixmap *dest; fz_pixmap *mask; fz_pixmap *shape; fz_pixmap *group_alpha; int blendmode; int id, encache; float alpha; fz_matrix ctm; float xstep, ystep; fz_irect area; }; struct fz_draw_device_s { fz_device super; fz_matrix transform; fz_rasterizer *rast; fz_default_colorspaces *default_cs; fz_colorspace *proof_cs; int flags; int resolve_spots; int top; fz_scale_cache *cache_x; fz_scale_cache *cache_y; fz_draw_state *stack; int stack_cap; fz_draw_state init_stack[STACK_SIZE]; }; #ifdef DUMP_GROUP_BLENDS #include static int group_dump_count = 0; static void fz_dump_blend(fz_context *ctx, const char *s, fz_pixmap *pix) { char name[80]; int psd = 0; if (!pix) return; if (pix->s || fz_colorspace_is_subtractive(ctx, pix->colorspace)) psd = 1; fz_snprintf(name, sizeof(name), "dump%02d.%s", group_dump_count, psd ? "psd" : "png"); printf("%s%02d%s(%p)", s ? s : "", group_dump_count++, psd ? "(PSD)" : "", pix); if (psd) fz_save_pixmap_as_psd(ctx, pix, name); else fz_save_pixmap_as_png(ctx, pix, name); } static void dump_spaces(int x, const char *s) { int i; for (i = 0; i < x; i++) printf(" "); printf("%s", s); } #endif #ifdef DUMP_STACK_CHANGES #define STACK_PUSHED(A) stack_change(ctx, dev, '>', A) #define STACK_POPPED(A) stack_change(ctx, dev, '<', A) #define STACK_CONVERT(A) stack_change(ctx, dev, '=', A) static void stack_change(fz_context *ctx, fz_draw_device *dev, int c, const char *s) { int n, depth = dev->top; if (c != '<') depth--; n = depth; while (n-- > 0) fputc('\t', stderr); fprintf(stderr, "%c%s (%d)\n", c, s, depth); } #else #define STACK_PUSHED(A) do {} while (0) #define STACK_POPPED(A) do {} while (0) #define STACK_CONVERT(A) do {} while (0) #endif /* Logic below assumes that default cs is set to color context cs if there * was not a default in the document for that particular cs */ static fz_colorspace *fz_default_colorspace(fz_context *ctx, fz_default_colorspaces *default_cs, fz_colorspace *cs) { if (cs == NULL) return NULL; if (default_cs == NULL) return cs; switch (fz_colorspace_type(ctx, cs)) { case FZ_COLORSPACE_GRAY: if (cs == fz_device_gray(ctx)) return fz_default_gray(ctx, default_cs); break; case FZ_COLORSPACE_RGB: if (cs == fz_device_rgb(ctx)) return fz_default_rgb(ctx, default_cs); break; case FZ_COLORSPACE_CMYK: if (cs == fz_device_cmyk(ctx)) return fz_default_cmyk(ctx, default_cs); break; default: break; } return cs; } static void grow_stack(fz_context *ctx, fz_draw_device *dev) { int max = dev->stack_cap * 2; fz_draw_state *stack; if (dev->stack == &dev->init_stack[0]) { stack = fz_malloc_array(ctx, max, fz_draw_state); memcpy(stack, dev->stack, sizeof(*stack) * dev->stack_cap); } else { stack = fz_realloc_array(ctx, dev->stack, max, fz_draw_state); } dev->stack = stack; dev->stack_cap = max; } /* 'Push' the stack. Returns a pointer to the current state, with state[1] * already having been initialised to contain the same thing. Simply * change any contents of state[1] that you want to and continue. */ static fz_draw_state *push_stack(fz_context *ctx, fz_draw_device *dev, const char *message) { fz_draw_state *state; if (dev->top == dev->stack_cap-1) grow_stack(ctx, dev); state = &dev->stack[dev->top]; dev->top++; memcpy(&state[1], state, sizeof(*state)); STACK_PUSHED(message); return state; } static fz_draw_state *pop_stack(fz_context *ctx, fz_draw_device *dev, const char *message) { fz_draw_state *state = &dev->stack[--dev->top]; STACK_POPPED(message); return state; } static fz_draw_state *convert_stack(fz_context *ctx, fz_draw_device *dev, const char *message) { fz_draw_state *state = &dev->stack[dev->top-1]; STACK_CONVERT(message); return state; } static fz_draw_state * fz_knockout_begin(fz_context *ctx, fz_draw_device *dev) { fz_irect bbox, ga_bbox; fz_draw_state *state = &dev->stack[dev->top]; int isolated = state->blendmode & FZ_BLEND_ISOLATED; if ((state->blendmode & FZ_BLEND_KNOCKOUT) == 0) return state; state = push_stack(ctx, dev, "knockout"); bbox = fz_pixmap_bbox(ctx, state->dest); bbox = fz_intersect_irect(bbox, state->scissor); state[1].dest = fz_new_pixmap_with_bbox(ctx, state->dest->colorspace, bbox, state->dest->seps, state->dest->alpha); if (state[0].group_alpha) { ga_bbox = fz_pixmap_bbox(ctx, state->group_alpha); ga_bbox = fz_intersect_irect(ga_bbox, state->scissor); state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, state->group_alpha->colorspace, ga_bbox, state->group_alpha->seps, state->group_alpha->alpha); } if (isolated) { fz_clear_pixmap(ctx, state[1].dest); if (state[1].group_alpha) fz_clear_pixmap(ctx, state[1].group_alpha); } else { /* Find the last but one destination to copy */ int i = dev->top-1; /* i = the one on entry (i.e. the last one) */ fz_draw_state *prev = state; while (i > 0) { prev = &dev->stack[--i]; if (prev->dest != state->dest) break; } if (prev->dest) { fz_copy_pixmap_rect(ctx, state[1].dest, prev->dest, bbox, dev->default_cs); if (state[1].group_alpha) { if (prev->group_alpha) fz_copy_pixmap_rect(ctx, state[1].group_alpha, prev->group_alpha, ga_bbox, dev->default_cs); else fz_clear_pixmap(ctx, state[1].group_alpha); } } else { fz_clear_pixmap(ctx, state[1].dest); if (state[1].group_alpha) fz_clear_pixmap(ctx, state[1].group_alpha); } } /* Knockout groups (and only knockout groups) rely on shape */ state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, ""); fz_dump_blend(ctx, "Knockout begin: background is ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); printf("\n"); #endif state[1].scissor = bbox; state[1].blendmode &= ~(FZ_BLEND_MODEMASK | FZ_BLEND_ISOLATED); return &state[1]; } static void fz_knockout_end(fz_context *ctx, fz_draw_device *dev) { fz_draw_state *state; if (dev->top == 0) fz_throw(ctx, FZ_ERROR_GENERIC, "unexpected knockout end"); state = pop_stack(ctx, dev, "knockout"); if ((state[0].blendmode & FZ_BLEND_KNOCKOUT) == 0) return; assert((state[1].blendmode & FZ_BLEND_ISOLATED) == 0); assert((state[1].blendmode & FZ_BLEND_MODEMASK) == 0); assert(state[1].shape); #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Knockout end: blending ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); fz_dump_blend(ctx, " onto ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); if ((state->blendmode & FZ_BLEND_MODEMASK) != 0) printf(" (blend %d)", state->blendmode & FZ_BLEND_MODEMASK); if ((state->blendmode & FZ_BLEND_ISOLATED) != 0) printf(" (isolated)"); printf(" (knockout)"); #endif fz_blend_pixmap_knockout(ctx, state[0].dest, state[1].dest, state[1].shape); fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; if (state[1].group_alpha && state[0].group_alpha != state[1].group_alpha) { if (state[0].group_alpha) fz_blend_pixmap_knockout(ctx, state[0].group_alpha, state[1].group_alpha, state[1].shape); fz_drop_pixmap(ctx, state[1].group_alpha); state[1].group_alpha = NULL; } if (state[0].shape != state[1].shape) { if (state[0].shape) fz_paint_pixmap(state[0].shape, state[1].shape, 255); fz_drop_pixmap(ctx, state[1].shape); state[1].shape = NULL; } #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, " to get ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); printf("\n"); #endif } static int colors_supported(fz_context *ctx, fz_colorspace *cs, fz_pixmap *dest) { /* Even if we support separations in the destination, if the color space has CMY or K as one of * its colorants and we are in RGB or Gray we will want to do the tint transform */ if (!fz_colorspace_is_subtractive(ctx, dest->colorspace) && fz_colorspace_device_n_has_cmyk(ctx, cs)) return 0; /* If we have separations then we should support it */ if (dest->seps) return 1; /* If our destination is CMYK and the source color space is only C, M, Y or K we support it * even if we have no seps */ if (fz_colorspace_is_subtractive(ctx, dest->colorspace)) { int i, n; if (fz_colorspace_device_n_has_only_cmyk(ctx, cs)) return 1; n = fz_colorspace_n(ctx, cs); for (i = 0; i < n; i++) { const char *name = fz_colorspace_colorant(ctx, cs, i); if (!name) return 0; if (!strcmp(name, "All")) continue; if (!strcmp(name, "Cyan")) continue; if (!strcmp(name, "Magenta")) continue; if (!strcmp(name, "Yellow")) continue; if (!strcmp(name, "Black")) continue; if (!strcmp(name, "None")) continue; return 0; } return 1; } return 0; } static fz_overprint * set_op_from_spaces(fz_context *ctx, fz_overprint *op, const fz_pixmap *dest, fz_colorspace *src, int opm) { int dn, sn, i, j, dc; if (!op) return NULL; if (!fz_colorspace_is_subtractive(ctx, src) || !fz_colorspace_is_subtractive(ctx, dest->colorspace)) return NULL; sn = fz_colorspace_n(ctx, src); dn = dest->n - dest->alpha; dc = dn - dest->s; /* If a source colorant is not mentioned in the destination * colorants (either process or spots), then it will be mapped * to process colorants. In this case, the process colorants * can never be protected. */ for (j = 0; j < sn; j++) { /* Run through the colorants looking for one that isn't mentioned. * i.e. continue if we we find one, break if not. */ const char *sname = fz_colorspace_colorant(ctx, src, j); if (!sname) break; if (!strcmp(sname, "All") || !strcmp(sname, "None")) continue; for (i = 0; i < dc; i++) { const char *name = fz_colorspace_colorant(ctx, dest->colorspace, i); if (!name) continue; if (!strcmp(name, sname)) break; } if (i != dc) continue; for (; i < dn; i++) { const char *name = fz_separation_name(ctx, dest->seps, i - dc); if (!name) continue; if (!strcmp(name, sname)) break; } if (i == dn) { /* This source colorant wasn't mentioned */ break; } } if (j == sn) { /* We did not find any source colorants that weren't mentioned, so * process colorants might not be touched... */ for (i = 0; i < dc; i++) { const char *name = fz_colorspace_colorant(ctx, dest->colorspace, i); for (j = 0; j < sn; j++) { const char *sname = fz_colorspace_colorant(ctx, src, j); if (!name || !sname) continue; if (!strcmp(name, sname)) break; if (!strcmp(sname, "All")) break; } if (j == sn) fz_set_overprint(op, i); } } for (i = dc; i < dn; i++) { const char *name = fz_separation_name(ctx, dest->seps, i - dc); for (j = 0; j < sn; j++) { const char *sname = fz_colorspace_colorant(ctx, src, j); if (!name || !sname) continue; if (!strcmp(name, sname)) break; if (!strcmp(sname, "All")) break; } if (j == sn) fz_set_overprint(op, i); } return op; } static fz_overprint * resolve_color(fz_context *ctx, fz_overprint *op, const float *color, fz_colorspace *colorspace, float alpha, fz_color_params color_params, unsigned char *colorbv, fz_pixmap *dest) { float colorfv[FZ_MAX_COLORS]; int i; int n = dest->n - dest->alpha; fz_colorspace *model = dest->colorspace; int devn, devgray; int effective_opm; if (colorspace == NULL && model != NULL) fz_throw(ctx, FZ_ERROR_GENERIC, "color destination requires source color"); effective_opm = color_params.opm; devn = fz_colorspace_is_device_n(ctx, colorspace); devgray = fz_colorspace_is_device_gray(ctx, colorspace); /* We can only overprint when enabled, and when we are in a subtractive colorspace */ if (color_params.op == 0 || !fz_colorspace_is_subtractive(ctx, dest->colorspace)) op = NULL; /* Device Gray is additive, but seems to still be counted for overprint * (see Ghent_V3.0/030_Gray_K_black_OP_x1a.pdf 030.pdf). */ else if (devgray) { } /* If we are in a CMYK space (i.e. not a devn one, given we know we are subtractive at this point), * then we only adhere to overprint mode if it's the same space as the destination. */ /* FIXME: Possibly we need a better equivalency test here. */ else if (!devn && colorspace != dest->colorspace) { effective_opm = 0; } if (n == 0) i = 0; else if (devn && colors_supported(ctx, colorspace, dest)) { fz_convert_separation_colors(ctx, colorspace, color, dest->seps, dest->colorspace, colorfv, color_params); for (i = 0; i < n; i++) colorbv[i] = colorfv[i] * 255; op = set_op_from_spaces(ctx, op, dest, colorspace, effective_opm); } else { int c = n - dest->s; fz_convert_color(ctx, colorspace, color, dest->colorspace, colorfv, NULL, color_params); for (i = 0; i < c; i++) colorbv[i] = colorfv[i] * 255; for (; i < n; i++) { colorfv[i] = 0; colorbv[i] = 0; } } colorbv[i] = alpha * 255; /* op && !devn => overprinting in cmyk or devicegray. */ if (op && !devn) { /* We are overprinting, so protect all spots. */ for (i = 4; i < n; i++) fz_set_overprint(op, i); /* If OPM, then protect all components for which the color values are zero. * (but only if we're in devicecmyk). */ if (effective_opm == 1 && colorspace != fz_device_gray(ctx)) for (i = 0; i < n; i++) if (colorfv[i] == 0) fz_set_overprint(op, i); } return op; } static fz_draw_state * push_group_for_separations(fz_context *ctx, fz_draw_device *dev, fz_color_params color_params, fz_default_colorspaces *default_cs) { fz_separations *clone = fz_clone_separations_for_overprint(ctx, dev->stack[0].dest->seps); fz_colorspace *oi = fz_default_output_intent(ctx, default_cs); fz_colorspace *dcs = fz_device_cmyk(ctx); /* Pick sep target CMYK based upon proof and output intent settings. Priority * is oi, proof, devicecmyk. */ if (dev->proof_cs) { dcs = dev->proof_cs; } if (oi) { dcs = oi; } /* Not needed if dest has the seps, and we are not using a proof or the target is the same as the proof and we don't have an oi or the target is the same as the oi */ if ((clone == dev->stack[0].dest->seps) && (dev->proof_cs == NULL || dev->proof_cs == dev->stack[0].dest->colorspace) && (oi == NULL || oi == dev->stack[0].dest->colorspace)) { fz_drop_separations(ctx, clone); dev->resolve_spots = 0; return &dev->stack[0]; } /* Make a new pixmap to render to. */ fz_try(ctx) { push_stack(ctx, dev, "separations"); dev->stack[1].dest = fz_clone_pixmap_area_with_different_seps(ctx, dev->stack[0].dest, &dev->stack[0].scissor, dcs, clone, color_params, default_cs); } fz_always(ctx) fz_drop_separations(ctx, clone); fz_catch(ctx) fz_rethrow(ctx); return &dev->stack[1]; } static void fz_draw_fill_path(fz_context *ctx, fz_device *devp, const fz_path *path, int even_odd, fz_matrix in_ctm, fz_colorspace *colorspace_in, const float *color, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_rasterizer *rast = dev->rast; fz_colorspace *colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); float expansion = fz_matrix_expansion(ctm); float flatness; unsigned char colorbv[FZ_MAX_COLORS + 1]; fz_irect bbox; fz_draw_state *state = &dev->stack[dev->top]; fz_overprint op = { { 0 } }; fz_overprint *eop; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (expansion < FLT_EPSILON) expansion = 1; flatness = 0.3f / expansion; if (flatness < 0.001f) flatness = 0.001f; bbox = fz_intersect_irect(fz_pixmap_bbox(ctx, state->dest), state->scissor); if (fz_flatten_fill_path(ctx, rast, path, ctm, flatness, &bbox, &bbox)) return; if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); eop = resolve_color(ctx, &op, color, colorspace, alpha, color_params, colorbv, state->dest); fz_convert_rasterizer(ctx, rast, even_odd, state->dest, colorbv, eop); if (state->shape) { if (!rast->fns.reusable) fz_flatten_fill_path(ctx, rast, path, ctm, flatness, &bbox, NULL); colorbv[0] = 255; fz_convert_rasterizer(ctx, rast, even_odd, state->shape, colorbv, 0); } if (state->group_alpha) { if (!rast->fns.reusable) fz_flatten_fill_path(ctx, rast, path, ctm, flatness, &bbox, NULL); colorbv[0] = alpha * 255; fz_convert_rasterizer(ctx, rast, even_odd, state->group_alpha, colorbv, 0); } if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } static void fz_draw_stroke_path(fz_context *ctx, fz_device *devp, const fz_path *path, const fz_stroke_state *stroke, fz_matrix in_ctm, fz_colorspace *colorspace_in, const float *color, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_rasterizer *rast = dev->rast; fz_colorspace *colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); float expansion = fz_matrix_expansion(ctm); float flatness; float linewidth = stroke->linewidth; unsigned char colorbv[FZ_MAX_COLORS + 1]; fz_irect bbox; float aa_level = 2.0f/(fz_rasterizer_graphics_aa_level(rast)+2); fz_draw_state *state = &dev->stack[dev->top]; float mlw = fz_rasterizer_graphics_min_line_width(rast); fz_overprint op = { { 0 } }; fz_overprint *eop; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (mlw > aa_level) aa_level = mlw; if (expansion < FLT_EPSILON) expansion = 1; if (linewidth * expansion < aa_level) linewidth = aa_level / expansion; flatness = 0.3f / expansion; if (flatness < 0.001f) flatness = 0.001f; bbox = fz_intersect_irect(fz_pixmap_bbox_no_ctx(state->dest), state->scissor); if (fz_flatten_stroke_path(ctx, rast, path, stroke, ctm, flatness, linewidth, &bbox, &bbox)) return; if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); eop = resolve_color(ctx, &op, color, colorspace, alpha, color_params, colorbv, state->dest); #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Before stroke ", state->dest); if (state->shape) fz_dump_blend(ctx, "/S=", state->shape); if (state->group_alpha) fz_dump_blend(ctx, "/GA=", state->group_alpha); printf("\n"); #endif fz_convert_rasterizer(ctx, rast, 0, state->dest, colorbv, eop); if (state->shape) { if (!rast->fns.reusable) (void)fz_flatten_stroke_path(ctx, rast, path, stroke, ctm, flatness, linewidth, &bbox, NULL); colorbv[0] = 255; fz_convert_rasterizer(ctx, rast, 0, state->shape, colorbv, 0); } if (state->group_alpha) { if (!rast->fns.reusable) (void)fz_flatten_stroke_path(ctx, rast, path, stroke, ctm, flatness, linewidth, &bbox, NULL); colorbv[0] = 255 * alpha; fz_convert_rasterizer(ctx, rast, 0, state->group_alpha, colorbv, 0); } #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "After stroke ", state->dest); if (state->shape) fz_dump_blend(ctx, "/S=", state->shape); if (state->group_alpha) fz_dump_blend(ctx, "/GA=", state->group_alpha); printf("\n"); #endif if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } static void fz_draw_clip_path(fz_context *ctx, fz_device *devp, const fz_path *path, int even_odd, fz_matrix in_ctm, fz_rect scissor) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_rasterizer *rast = dev->rast; float expansion = fz_matrix_expansion(ctm); float flatness; fz_irect bbox; fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); if (expansion < FLT_EPSILON) expansion = 1; flatness = 0.3f / expansion; if (flatness < 0.001f) flatness = 0.001f; state = push_stack(ctx, dev, "clip path"); model = state->dest->colorspace; if (!fz_is_infinite_rect(scissor)) { bbox = fz_irect_from_rect(fz_transform_rect(scissor, dev->transform)); bbox = fz_intersect_irect(bbox, fz_pixmap_bbox(ctx, state->dest)); bbox = fz_intersect_irect(bbox, state->scissor); } else { bbox = fz_intersect_irect(fz_pixmap_bbox(ctx, state->dest), state->scissor); } if (fz_flatten_fill_path(ctx, rast, path, ctm, flatness, &bbox, &bbox) || fz_is_rect_rasterizer(ctx, rast)) { state[1].scissor = bbox; state[1].mask = NULL; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (rectangular) begin\n"); #endif return; } state[1].mask = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].mask); state[1].dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha); fz_copy_pixmap_rect(ctx, state[1].dest, state[0].dest, bbox, dev->default_cs); if (state[1].shape) { state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); } if (state[1].group_alpha) { state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } fz_convert_rasterizer(ctx, rast, even_odd, state[1].mask, NULL, 0); state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (non-rectangular) begin\n"); #endif } static void fz_draw_clip_stroke_path(fz_context *ctx, fz_device *devp, const fz_path *path, const fz_stroke_state *stroke, fz_matrix in_ctm, fz_rect scissor) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_rasterizer *rast = dev->rast; float expansion = fz_matrix_expansion(ctm); float flatness; float linewidth = stroke->linewidth; fz_irect bbox; fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model; float aa_level = 2.0f/(fz_rasterizer_graphics_aa_level(rast)+2); float mlw = fz_rasterizer_graphics_min_line_width(rast); if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); if (mlw > aa_level) aa_level = mlw; if (expansion < FLT_EPSILON) expansion = 1; if (linewidth * expansion < aa_level) linewidth = aa_level / expansion; flatness = 0.3f / expansion; if (flatness < 0.001f) flatness = 0.001f; state = push_stack(ctx, dev, "clip stroke"); model = state->dest->colorspace; if (!fz_is_infinite_rect(scissor)) { bbox = fz_irect_from_rect(fz_transform_rect(scissor, dev->transform)); bbox = fz_intersect_irect(bbox, fz_pixmap_bbox(ctx, state->dest)); bbox = fz_intersect_irect(bbox, state->scissor); } else { bbox = fz_intersect_irect(fz_pixmap_bbox(ctx, state->dest), state->scissor); } if (fz_flatten_stroke_path(ctx, rast, path, stroke, ctm, flatness, linewidth, &bbox, &bbox)) { state[1].scissor = bbox; state[1].mask = NULL; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (stroke, empty) begin\n"); #endif return; } state[1].mask = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].mask); /* When there is no alpha in the current destination (state[0].dest->alpha == 0) * we have a choice. We can either create the new destination WITH alpha, or * we can copy the old pixmap contents in. We opt for the latter here, but * may want to revisit this decision in the future. */ state[1].dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha); if (state[0].dest->alpha) fz_clear_pixmap(ctx, state[1].dest); else fz_copy_pixmap_rect(ctx, state[1].dest, state[0].dest, bbox, dev->default_cs); if (state->shape) { state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); } if (state->group_alpha) { state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } fz_convert_rasterizer(ctx, rast, 0, state[1].mask, NULL, 0); state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (stroke) begin\n"); #endif } static void draw_glyph(unsigned char *colorbv, fz_pixmap *dst, fz_glyph *glyph, int xorig, int yorig, const fz_irect *scissor, fz_overprint *eop) { unsigned char *dp; fz_irect bbox; int x, y, w, h; int skip_x, skip_y; fz_pixmap *msk; bbox = fz_glyph_bbox_no_ctx(glyph); bbox = fz_translate_irect(bbox, xorig, yorig); bbox = fz_intersect_irect(bbox, *scissor); /* scissor < dst */ bbox = fz_intersect_irect(bbox, fz_pixmap_bbox_no_ctx(dst)); if (fz_is_empty_irect(bbox)) return; x = bbox.x0; y = bbox.y0; w = bbox.x1 - bbox.x0; h = bbox.y1 - bbox.y0; skip_x = x - glyph->x - xorig; skip_y = y - glyph->y - yorig; msk = glyph->pixmap; dp = dst->samples + (unsigned int)((y - dst->y) * dst->stride + (x - dst->x) * dst->n); if (msk == NULL) { fz_paint_glyph(colorbv, dst, dp, glyph, w, h, skip_x, skip_y, eop); } else { unsigned char *mp = msk->samples + skip_y * msk->stride + skip_x; int da = dst->alpha; if (dst->colorspace) { fz_span_color_painter_t *fn; fn = fz_get_span_color_painter(dst->n, da, colorbv, eop); assert(fn); if (fn == NULL) return; while (h--) { (*fn)(dp, mp, dst->n, w, colorbv, da, eop); dp += dst->stride; mp += msk->stride; } } else { fz_span_painter_t *fn; fn = fz_get_span_painter(da, 1, 0, 255, eop); assert(fn); if (fn == NULL) return; while (h--) { (*fn)(dp, da, mp, 1, 0, w, 255, eop); dp += dst->stride; mp += msk->stride; } } } } static void fz_draw_fill_text(fz_context *ctx, fz_device *devp, const fz_text *text, fz_matrix in_ctm, fz_colorspace *colorspace_in, const float *color, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model = state->dest->colorspace; unsigned char colorbv[FZ_MAX_COLORS + 1]; unsigned char shapebv, shapebva; fz_text_span *span; int i; fz_colorspace *colorspace = NULL; fz_rasterizer *rast = dev->rast; fz_overprint op = { { 0 } }; fz_overprint *eop; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (colorspace_in) colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); if (colorspace == NULL && model != NULL) fz_throw(ctx, FZ_ERROR_GENERIC, "color destination requires source color"); if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); eop = resolve_color(ctx, &op, color, colorspace, alpha, color_params, colorbv, state->dest); shapebv = 255; shapebva = 255 * alpha; for (span = text->head; span; span = span->next) { fz_matrix tm, trm; fz_glyph *glyph; int gid; tm = span->trm; for (i = 0; i < span->len; i++) { gid = span->items[i].gid; if (gid < 0) continue; tm.e = span->items[i].x; tm.f = span->items[i].y; trm = fz_concat(tm, ctm); glyph = fz_render_glyph(ctx, span->font, gid, &trm, model, &state->scissor, state->dest->alpha, fz_rasterizer_text_aa_level(rast)); if (glyph) { fz_pixmap *pixmap = glyph->pixmap; int x = floorf(trm.e); int y = floorf(trm.f); if (pixmap == NULL || pixmap->n == 1) { draw_glyph(colorbv, state->dest, glyph, x, y, &state->scissor, eop); if (state->shape) draw_glyph(&shapebv, state->shape, glyph, x, y, &state->scissor, 0); if (state->group_alpha) draw_glyph(&shapebva, state->group_alpha, glyph, x, y, &state->scissor, 0); } else { fz_matrix mat; mat.a = pixmap->w; mat.b = mat.c = 0; mat.d = pixmap->h; mat.e = x + pixmap->x; mat.f = y + pixmap->y; fz_paint_image(ctx, state->dest, &state->scissor, state->shape, state->group_alpha, pixmap, mat, alpha * 255, !(devp->hints & FZ_DONT_INTERPOLATE_IMAGES), devp->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, eop); } fz_drop_glyph(ctx, glyph); } else { fz_path *path = fz_outline_glyph(ctx, span->font, gid, tm); if (path) { fz_draw_fill_path(ctx, devp, path, 0, in_ctm, colorspace, color, alpha, color_params); fz_drop_path(ctx, path); } else { fz_warn(ctx, "cannot render glyph"); } } } } if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } static void fz_draw_stroke_text(fz_context *ctx, fz_device *devp, const fz_text *text, const fz_stroke_state *stroke, fz_matrix in_ctm, fz_colorspace *colorspace_in, const float *color, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_draw_state *state = &dev->stack[dev->top]; unsigned char colorbv[FZ_MAX_COLORS + 1]; unsigned char solid = 255; unsigned char alpha_byte = alpha * 255; fz_text_span *span; int i; fz_colorspace *colorspace = NULL; int aa = fz_rasterizer_text_aa_level(dev->rast); fz_overprint op = { { 0 } }; fz_overprint *eop; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (colorspace_in) colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); eop = resolve_color(ctx, &op, color, colorspace, alpha, color_params, colorbv, state->dest); for (span = text->head; span; span = span->next) { fz_matrix tm, trm; fz_glyph *glyph; int gid; tm = span->trm; for (i = 0; i < span->len; i++) { gid = span->items[i].gid; if (gid < 0) continue; tm.e = span->items[i].x; tm.f = span->items[i].y; trm = fz_concat(tm, ctm); glyph = fz_render_stroked_glyph(ctx, span->font, gid, &trm, ctm, stroke, &state->scissor, aa); if (glyph) { int x = (int)trm.e; int y = (int)trm.f; draw_glyph(colorbv, state->dest, glyph, x, y, &state->scissor, eop); if (state->shape) draw_glyph(&solid, state->shape, glyph, x, y, &state->scissor, 0); if (state->group_alpha) draw_glyph(&alpha_byte, state->group_alpha, glyph, x, y, &state->scissor, 0); fz_drop_glyph(ctx, glyph); } else { fz_path *path = fz_outline_glyph(ctx, span->font, gid, tm); if (path) { fz_draw_stroke_path(ctx, devp, path, stroke, in_ctm, colorspace, color, alpha, color_params); fz_drop_path(ctx, path); } else { fz_warn(ctx, "cannot render glyph"); } } } } if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } static void fz_draw_clip_text(fz_context *ctx, fz_device *devp, const fz_text *text, fz_matrix in_ctm, fz_rect scissor) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_irect bbox; fz_matrix tm, trm; fz_glyph *glyph; int i, gid; fz_draw_state *state; fz_colorspace *model; fz_text_span *span; fz_rasterizer *rast = dev->rast; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); state = push_stack(ctx, dev, "clip text"); model = state->dest->colorspace; /* make the mask the exact size needed */ bbox = fz_irect_from_rect(fz_bound_text(ctx, text, NULL, ctm)); bbox = fz_intersect_irect(bbox, state->scissor); if (!fz_is_infinite_rect(scissor)) { fz_rect tscissor = fz_transform_rect(scissor, dev->transform); bbox = fz_intersect_irect(bbox, fz_irect_from_rect(tscissor)); } state[1].mask = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].mask); /* When there is no alpha in the current destination (state[0].dest->alpha == 0) * we have a choice. We can either create the new destination WITH alpha, or * we can copy the old pixmap contents in. We opt for the latter here, but * may want to revisit this decision in the future. */ state[1].dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha); if (state[0].dest->alpha) fz_clear_pixmap(ctx, state[1].dest); else fz_copy_pixmap_rect(ctx, state[1].dest, state[0].dest, bbox, dev->default_cs); if (state->shape) { state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); } else state[1].shape = NULL; if (state->group_alpha) { state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } else state[1].group_alpha = NULL; state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (text) begin\n"); #endif if (!fz_is_empty_irect(bbox) && state[1].mask) { for (span = text->head; span; span = span->next) { tm = span->trm; for (i = 0; i < span->len; i++) { gid = span->items[i].gid; if (gid < 0) continue; tm.e = span->items[i].x; tm.f = span->items[i].y; trm = fz_concat(tm, ctm); glyph = fz_render_glyph(ctx, span->font, gid, &trm, model, &state->scissor, state[1].dest->alpha, fz_rasterizer_text_aa_level(rast)); if (glyph) { int x = (int)trm.e; int y = (int)trm.f; draw_glyph(NULL, state[1].mask, glyph, x, y, &bbox, 0); if (state[1].shape) draw_glyph(NULL, state[1].shape, glyph, x, y, &bbox, 0); if (state[1].group_alpha) draw_glyph(NULL, state[1].group_alpha, glyph, x, y, &bbox, 0); fz_drop_glyph(ctx, glyph); } else { fz_path *path = fz_outline_glyph(ctx, span->font, gid, tm); if (path) { fz_pixmap *old_dest; float white = 1; old_dest = state[1].dest; state[1].dest = state[1].mask; state[1].mask = NULL; fz_try(ctx) { fz_draw_fill_path(ctx, devp, path, 0, in_ctm, fz_device_gray(ctx), &white, 1, fz_default_color_params); } fz_always(ctx) { state[1].mask = state[1].dest; state[1].dest = old_dest; fz_drop_path(ctx, path); } fz_catch(ctx) { fz_rethrow(ctx); } } else { fz_warn(ctx, "cannot render glyph for clipping"); } } } } } } static void fz_draw_clip_stroke_text(fz_context *ctx, fz_device *devp, const fz_text *text, const fz_stroke_state *stroke, fz_matrix in_ctm, fz_rect scissor) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_irect bbox; fz_pixmap *mask, *dest, *shape, *group_alpha; fz_matrix tm, trm; fz_glyph *glyph; int i, gid; fz_draw_state *state = push_stack(ctx, dev, "clip stroke text"); fz_colorspace *model = state->dest->colorspace; fz_text_span *span; int aa = fz_rasterizer_text_aa_level(dev->rast); if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); /* make the mask the exact size needed */ bbox = fz_irect_from_rect(fz_bound_text(ctx, text, stroke, ctm)); bbox = fz_intersect_irect(bbox, state->scissor); if (!fz_is_infinite_rect(scissor)) { fz_rect tscissor = fz_transform_rect(scissor, dev->transform); bbox = fz_intersect_irect(bbox, fz_irect_from_rect(tscissor)); } state[1].mask = mask = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, mask); /* When there is no alpha in the current destination (state[0].dest->alpha == 0) * we have a choice. We can either create the new destination WITH alpha, or * we can copy the old pixmap contents in. We opt for the latter here, but * may want to revisit this decision in the future. */ state[1].dest = dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha); if (state[0].dest->alpha) fz_clear_pixmap(ctx, state[1].dest); else fz_copy_pixmap_rect(ctx, state[1].dest, state[0].dest, bbox, dev->default_cs); if (state->shape) { state[1].shape = shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, shape); } else shape = state->shape; if (state->group_alpha) { state[1].group_alpha = group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, group_alpha); } else group_alpha = NULL; state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (stroke text) begin\n"); #endif if (!fz_is_empty_irect(bbox)) { for (span = text->head; span; span = span->next) { tm = span->trm; for (i = 0; i < span->len; i++) { gid = span->items[i].gid; if (gid < 0) continue; tm.e = span->items[i].x; tm.f = span->items[i].y; trm = fz_concat(tm, ctm); glyph = fz_render_stroked_glyph(ctx, span->font, gid, &trm, ctm, stroke, &state->scissor, aa); if (glyph) { int x = (int)trm.e; int y = (int)trm.f; draw_glyph(NULL, mask, glyph, x, y, &bbox, 0); if (shape) draw_glyph(NULL, shape, glyph, x, y, &bbox, 0); if (group_alpha) draw_glyph(NULL, group_alpha, glyph, x, y, &bbox, 0); fz_drop_glyph(ctx, glyph); } else { fz_path *path = fz_outline_glyph(ctx, span->font, gid, tm); if (path) { fz_pixmap *old_dest; float white = 1; state = &dev->stack[dev->top]; old_dest = state[0].dest; state[0].dest = state[0].mask; state[0].mask = NULL; fz_try(ctx) { fz_draw_stroke_path(ctx, devp, path, stroke, in_ctm, fz_device_gray(ctx), &white, 1, fz_default_color_params); } fz_always(ctx) { state[0].mask = state[0].dest; state[0].dest = old_dest; fz_drop_path(ctx, path); } fz_catch(ctx) { fz_rethrow(ctx); } } else { fz_warn(ctx, "cannot render glyph for stroked clipping"); } } } } } } static void fz_draw_ignore_text(fz_context *ctx, fz_device *dev, const fz_text *text, fz_matrix ctm) { } static void fz_draw_fill_shade(fz_context *ctx, fz_device *devp, fz_shade *shade, fz_matrix in_ctm, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_irect bbox, scissor; fz_pixmap *dest, *shape, *group_alpha; unsigned char colorbv[FZ_MAX_COLORS + 1]; unsigned char alpha_byte = 255 * alpha; fz_draw_state *state = &dev->stack[dev->top]; fz_overprint op = { { 0 } }; fz_overprint *eop; fz_colorspace *colorspace = fz_default_colorspace(ctx, dev->default_cs, shade->colorspace); if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); scissor = state->scissor; bbox = fz_irect_from_rect(fz_bound_shade(ctx, shade, ctm)); bbox = fz_intersect_irect(bbox, scissor); if (fz_is_empty_irect(bbox)) return; if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); fz_var(dest); fz_var(shape); fz_var(group_alpha); dest = state->dest; shape = state->shape; group_alpha = state->group_alpha; fz_try(ctx) { if (alpha < 1) { dest = fz_new_pixmap_with_bbox(ctx, state->dest->colorspace, bbox, state->dest->seps, state->dest->alpha); if (state->dest->alpha) fz_clear_pixmap(ctx, dest); else fz_copy_pixmap_rect(ctx, dest, state[0].dest, bbox, dev->default_cs); if (shape) { shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, shape); } if (group_alpha) { group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, group_alpha); } } if (shade->use_background) { unsigned char *s; int x, y, n, i; /* Disable OPM */ color_params.opm = 0; eop = resolve_color(ctx, &op, shade->background, colorspace, alpha, color_params, colorbv, state->dest); n = dest->n; if (fz_overprint_required(eop)) { for (y = scissor.y0; y < scissor.y1; y++) { s = dest->samples + (unsigned int)((y - dest->y) * dest->stride + (scissor.x0 - dest->x) * n); for (x = scissor.x0; x < scissor.x1; x++) { for (i = 0; i < n; i++) if (fz_overprint_component(eop, i)) *s++ = colorbv[i]; } } } else { for (y = scissor.y0; y < scissor.y1; y++) { s = dest->samples + (unsigned int)((y - dest->y) * dest->stride + (scissor.x0 - dest->x) * n); for (x = scissor.x0; x < scissor.x1; x++) { for (i = 0; i < n; i++) *s++ = colorbv[i]; } } } if (shape) { for (y = scissor.y0; y < scissor.y1; y++) { s = shape->samples + (unsigned int)((y - shape->y) * shape->stride + (scissor.x0 - shape->x)); for (x = scissor.x0; x < scissor.x1; x++) { *s++ = 255; } } } if (group_alpha) { for (y = scissor.y0; y < scissor.y1; y++) { s = group_alpha->samples + (unsigned int)((y - group_alpha->y) * group_alpha->stride + (scissor.x0 - group_alpha->x)); for (x = scissor.x0; x < scissor.x1; x++) { *s++ = alpha_byte; } } } } if (color_params.op) eop = set_op_from_spaces(ctx, &op, dest, colorspace, 0); else eop = NULL; fz_paint_shade(ctx, shade, colorspace, ctm, dest, color_params, bbox, eop); if (shape) fz_clear_pixmap_rect_with_value(ctx, shape, 255, bbox); if (group_alpha) fz_clear_pixmap_rect_with_value(ctx, group_alpha, 255, bbox); #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Shade ", dest); if (shape) fz_dump_blend(ctx, "/S=", shape); if (group_alpha) fz_dump_blend(ctx, "/GA=", group_alpha); printf("\n"); #endif if (alpha < 1) { /* FIXME: eop */ fz_paint_pixmap(state->dest, dest, alpha * 255); fz_drop_pixmap(ctx, dest); dest = NULL; if (shape) { fz_paint_pixmap(state->shape, shape, 255); fz_drop_pixmap(ctx, shape); shape = NULL; } if (group_alpha) { fz_paint_pixmap(state->group_alpha, group_alpha, alpha * 255); fz_drop_pixmap(ctx, group_alpha); group_alpha = NULL; } } if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } fz_catch(ctx) { if (dest != state[0].dest) fz_drop_pixmap(ctx, dest); if (shape != state[0].shape) fz_drop_pixmap(ctx, shape); if (group_alpha != state[0].group_alpha) fz_drop_pixmap(ctx, group_alpha); fz_rethrow(ctx); } } static fz_pixmap * fz_transform_pixmap(fz_context *ctx, fz_draw_device *dev, const fz_pixmap *image, fz_matrix *ctm, int x, int y, int dx, int dy, int gridfit, const fz_irect *clip) { fz_pixmap *scaled; if (ctm->a != 0 && ctm->b == 0 && ctm->c == 0 && ctm->d != 0) { /* Unrotated or X-flip or Y-flip or XY-flip */ fz_matrix m = *ctm; if (gridfit) { m = fz_gridfit_matrix(dev->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, m); } scaled = fz_scale_pixmap_cached(ctx, image, m.e, m.f, m.a, m.d, clip, dev->cache_x, dev->cache_y); if (!scaled) return NULL; ctm->a = scaled->w; ctm->d = scaled->h; ctm->e = scaled->x; ctm->f = scaled->y; return scaled; } if (ctm->a == 0 && ctm->b != 0 && ctm->c != 0 && ctm->d == 0) { /* Other orthogonal flip/rotation cases */ fz_matrix m = *ctm; fz_irect rclip; if (gridfit) m = fz_gridfit_matrix(dev->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, m); if (clip) { rclip.x0 = clip->y0; rclip.y0 = clip->x0; rclip.x1 = clip->y1; rclip.y1 = clip->x1; } scaled = fz_scale_pixmap_cached(ctx, image, m.f, m.e, m.b, m.c, (clip ? &rclip : NULL), dev->cache_x, dev->cache_y); if (!scaled) return NULL; ctm->b = scaled->w; ctm->c = scaled->h; ctm->f = scaled->x; ctm->e = scaled->y; return scaled; } /* Downscale, non rectilinear case */ if (dx > 0 && dy > 0) { scaled = fz_scale_pixmap_cached(ctx, image, 0, 0, dx, dy, NULL, dev->cache_x, dev->cache_y); return scaled; } return NULL; } int fz_default_image_scale(void *arg, int dst_w, int dst_h, int src_w, int src_h) { (void)arg; return dst_w < src_w && dst_h < src_h; } static fz_pixmap * convert_pixmap_for_painting(fz_context *ctx, fz_pixmap *pixmap, fz_colorspace *model, fz_colorspace *src_cs, fz_pixmap *dest, fz_color_params color_params, fz_draw_device *dev, fz_overprint **eop) { fz_pixmap *converted; if (fz_colorspace_is_device_n(ctx, src_cs) && dest->seps) { converted = fz_clone_pixmap_area_with_different_seps(ctx, pixmap, NULL, model, dest->seps, color_params, dev->default_cs); *eop = set_op_from_spaces(ctx, *eop, dest, src_cs, 0); } else { converted = fz_convert_pixmap(ctx, pixmap, model, NULL, dev->default_cs, color_params, 1); if (*eop) { if (fz_colorspace_type(ctx, model) != FZ_COLORSPACE_CMYK) { /* Can only overprint to CMYK based spaces */ *eop = NULL; } else if (!fz_colorspace_is_device_n(ctx, pixmap->colorspace)) { int i; int n = dest->n - dest->alpha; for (i = 4; i < n; i++) fz_set_overprint(*eop, i); } else { *eop = set_op_from_spaces(ctx, *eop, dest, src_cs, 0); } } } fz_drop_pixmap(ctx, pixmap); return converted; } static void fz_draw_fill_image(fz_context *ctx, fz_device *devp, fz_image *image, fz_matrix in_ctm, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix local_ctm = fz_concat(in_ctm, dev->transform); fz_pixmap *pixmap; int after; int dx, dy; fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model; fz_irect clip; fz_matrix inverse; fz_irect src_area; fz_colorspace *src_cs; fz_overprint op = { { 0 } }; fz_overprint *eop = &op; if (alpha == 0) return; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); model = state->dest->colorspace; clip = fz_intersect_irect(fz_pixmap_bbox(ctx, state->dest), state->scissor); if (image->w == 0 || image->h == 0) return; if (color_params.op == 0) eop = NULL; /* ctm maps the image (expressed as the unit square) onto the * destination device. Reverse that to get a mapping from * the destination device to the source pixels. */ if (fz_try_invert_matrix(&inverse, local_ctm)) { /* Not invertible. Could just bail? Use the whole image * for now. */ src_area.x0 = 0; src_area.x1 = image->w; src_area.y0 = 0; src_area.y1 = image->h; } else { float exp; fz_rect rect; fz_irect sane; /* We want to scale from image coords, not from unit square */ inverse = fz_post_scale(inverse, image->w, image->h); /* Are we scaling up or down? exp < 1 means scaling down. */ exp = fz_matrix_max_expansion(inverse); rect = fz_rect_from_irect(clip); rect = fz_transform_rect(rect, inverse); /* Allow for support requirements for scalers. */ rect = fz_expand_rect(rect, fz_max(exp, 1) * 4); src_area = fz_irect_from_rect(rect); sane.x0 = 0; sane.y0 = 0; sane.x1 = image->w; sane.y1 = image->h; src_area = fz_intersect_irect(src_area, sane); if (fz_is_empty_irect(src_area)) return; } pixmap = fz_get_pixmap_from_image(ctx, image, &src_area, &local_ctm, &dx, &dy); src_cs = fz_default_colorspace(ctx, dev->default_cs, pixmap->colorspace); /* convert images with more components (cmyk->rgb) before scaling */ /* convert images with fewer components (gray->rgb) after scaling */ /* convert images with expensive colorspace transforms after scaling */ fz_var(pixmap); fz_try(ctx) { int conversion_required = (src_cs != model || state->dest->seps); if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); switch (fz_colorspace_type(ctx, src_cs)) { case FZ_COLORSPACE_GRAY: after = 1; break; case FZ_COLORSPACE_INDEXED: after = 0; break; default: if (fz_colorspace_n(ctx, src_cs) <= fz_colorspace_n(ctx, model)) after = 1; else after = 0; break; } if (conversion_required && !after) pixmap = convert_pixmap_for_painting(ctx, pixmap, model, src_cs, state->dest, color_params, dev, &eop); if (!(devp->hints & FZ_DONT_INTERPOLATE_IMAGES) && ctx->tuning->image_scale(ctx->tuning->image_scale_arg, dx, dy, pixmap->w, pixmap->h)) { int gridfit = alpha == 1.0f && !(dev->flags & FZ_DRAWDEV_FLAGS_TYPE3); fz_pixmap *scaled = fz_transform_pixmap(ctx, dev, pixmap, &local_ctm, state->dest->x, state->dest->y, dx, dy, gridfit, &clip); if (!scaled) { if (dx < 1) dx = 1; if (dy < 1) dy = 1; scaled = fz_scale_pixmap_cached(ctx, pixmap, pixmap->x, pixmap->y, dx, dy, NULL, dev->cache_x, dev->cache_y); } if (scaled) { fz_drop_pixmap(ctx, pixmap); pixmap = scaled; } } if (conversion_required && after) { #if FZ_PLOTTERS_RGB if (state->dest->seps == NULL && ((src_cs == fz_device_gray(ctx) && model == fz_device_rgb(ctx)) || (src_cs == fz_device_gray(ctx) && model == fz_device_bgr(ctx)))) { /* We have special case rendering code for gray -> rgb/bgr */ } else #endif pixmap = convert_pixmap_for_painting(ctx, pixmap, model, src_cs, state->dest, color_params, dev, &eop); } fz_paint_image(ctx, state->dest, &state->scissor, state->shape, state->group_alpha, pixmap, local_ctm, alpha * 255, !(devp->hints & FZ_DONT_INTERPOLATE_IMAGES), devp->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, eop); if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } fz_always(ctx) fz_drop_pixmap(ctx, pixmap); fz_catch(ctx) fz_rethrow(ctx); } static void fz_draw_fill_image_mask(fz_context *ctx, fz_device *devp, fz_image *image, fz_matrix in_ctm, fz_colorspace *colorspace_in, const float *color, float alpha, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix local_ctm = fz_concat(in_ctm, dev->transform); unsigned char colorbv[FZ_MAX_COLORS + 1]; fz_pixmap *scaled = NULL; fz_pixmap *pixmap; int dx, dy; fz_draw_state *state = &dev->stack[dev->top]; fz_irect clip; fz_matrix inverse; fz_irect src_area; fz_colorspace *colorspace = NULL; fz_overprint op = { { 0 } }; fz_overprint *eop; if (alpha == 0) return; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (colorspace_in) colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); clip = fz_pixmap_bbox(ctx, state->dest); clip = fz_intersect_irect(clip, state->scissor); if (image->w == 0 || image->h == 0) return; /* ctm maps the image (expressed as the unit square) onto the * destination device. Reverse that to get a mapping from * the destination device to the source pixels. */ if (fz_try_invert_matrix(&inverse, local_ctm)) { /* Not invertible. Could just bail? Use the whole image * for now. */ src_area.x0 = 0; src_area.x1 = image->w; src_area.y0 = 0; src_area.y1 = image->h; } else { float exp; fz_rect rect; fz_irect sane; /* We want to scale from image coords, not from unit square */ inverse = fz_post_scale(inverse, image->w, image->h); /* Are we scaling up or down? exp < 1 means scaling down. */ exp = fz_matrix_max_expansion(inverse); rect = fz_rect_from_irect(clip); rect = fz_transform_rect(rect, inverse); /* Allow for support requirements for scalers. */ rect = fz_expand_rect(rect, fz_max(exp, 1) * 4); src_area = fz_irect_from_rect(rect); sane.x0 = 0; sane.y0 = 0; sane.x1 = image->w; sane.y1 = image->h; src_area = fz_intersect_irect(src_area, sane); if (fz_is_empty_irect(src_area)) return; } pixmap = fz_get_pixmap_from_image(ctx, image, &src_area, &local_ctm, &dx, &dy); fz_var(pixmap); fz_try(ctx) { if (state->blendmode & FZ_BLEND_KNOCKOUT) state = fz_knockout_begin(ctx, dev); if (!(devp->hints & FZ_DONT_INTERPOLATE_IMAGES) && ctx->tuning->image_scale(ctx->tuning->image_scale_arg, dx, dy, pixmap->w, pixmap->h)) { int gridfit = alpha == 1.0f && !(dev->flags & FZ_DRAWDEV_FLAGS_TYPE3); scaled = fz_transform_pixmap(ctx, dev, pixmap, &local_ctm, state->dest->x, state->dest->y, dx, dy, gridfit, &clip); if (!scaled) { if (dx < 1) dx = 1; if (dy < 1) dy = 1; scaled = fz_scale_pixmap_cached(ctx, pixmap, pixmap->x, pixmap->y, dx, dy, NULL, dev->cache_x, dev->cache_y); } if (scaled) { fz_drop_pixmap(ctx, pixmap); pixmap = scaled; } } eop = resolve_color(ctx, &op, color, colorspace, alpha, color_params, colorbv, state->dest); fz_paint_image_with_color(ctx, state->dest, &state->scissor, state->shape, state->group_alpha, pixmap, local_ctm, colorbv, !(devp->hints & FZ_DONT_INTERPOLATE_IMAGES), devp->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, eop); if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } fz_always(ctx) fz_drop_pixmap(ctx, pixmap); fz_catch(ctx) fz_rethrow(ctx); } static void fz_draw_clip_image_mask(fz_context *ctx, fz_device *devp, fz_image *image, fz_matrix in_ctm, fz_rect scissor) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix local_ctm = fz_concat(in_ctm, dev->transform); fz_irect bbox; fz_pixmap *scaled = NULL; fz_pixmap *pixmap = NULL; int dx, dy; fz_draw_state *state = push_stack(ctx, dev, "clip image mask"); fz_colorspace *model = state->dest->colorspace; fz_irect clip; fz_var(pixmap); if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); clip = fz_pixmap_bbox(ctx, state->dest); clip = fz_intersect_irect(clip, state->scissor); if (image->w == 0 || image->h == 0) { #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (image mask) (empty) begin\n"); #endif state[1].scissor = fz_empty_irect; state[1].mask = NULL; return; } #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Clip (image mask) begin\n"); #endif bbox = fz_irect_from_rect(fz_transform_rect(fz_unit_rect, local_ctm)); bbox = fz_intersect_irect(bbox, state->scissor); if (!fz_is_infinite_rect(scissor)) { fz_rect tscissor = fz_transform_rect(scissor, dev->transform); bbox = fz_intersect_irect(bbox, fz_irect_from_rect(tscissor)); } fz_try(ctx) { pixmap = fz_get_pixmap_from_image(ctx, image, NULL, &local_ctm, &dx, &dy); state[1].mask = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].mask); state[1].dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha); fz_copy_pixmap_rect(ctx, state[1].dest, state[0].dest, bbox, dev->default_cs); if (state[0].shape) { state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); } if (state[0].group_alpha) { state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].scissor = bbox; if (!(devp->hints & FZ_DONT_INTERPOLATE_IMAGES) && ctx->tuning->image_scale(ctx->tuning->image_scale_arg, dx, dy, pixmap->w, pixmap->h)) { int gridfit = !(dev->flags & FZ_DRAWDEV_FLAGS_TYPE3); scaled = fz_transform_pixmap(ctx, dev, pixmap, &local_ctm, state->dest->x, state->dest->y, dx, dy, gridfit, &clip); if (!scaled) { if (dx < 1) dx = 1; if (dy < 1) dy = 1; scaled = fz_scale_pixmap_cached(ctx, pixmap, pixmap->x, pixmap->y, dx, dy, NULL, dev->cache_x, dev->cache_y); } if (scaled) { fz_drop_pixmap(ctx, pixmap); pixmap = scaled; } } #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Creating imagemask: plotting ", pixmap); fz_dump_blend(ctx, " onto ", state[1].mask); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); #endif fz_paint_image(ctx, state[1].mask, &bbox, state[1].shape, state[1].group_alpha, pixmap, local_ctm, 255, !(devp->hints & FZ_DONT_INTERPOLATE_IMAGES), devp->flags & FZ_DEVFLAG_GRIDFIT_AS_TILED, 0); #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, " to get ", state[1].mask); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); printf("\n"); #endif } fz_always(ctx) fz_drop_pixmap(ctx, pixmap); fz_catch(ctx) fz_rethrow(ctx); } static void fz_draw_pop_clip(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; fz_draw_state *state; if (dev->top == 0) fz_throw(ctx, FZ_ERROR_GENERIC, "unexpected pop clip"); state = pop_stack(ctx, dev, "clip"); /* We can get here with state[1].mask == NULL if the clipping actually * resolved to a rectangle earlier. */ if (state[1].mask) { #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Clipping ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); fz_dump_blend(ctx, " onto ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); fz_dump_blend(ctx, " with ", state[1].mask); #endif fz_paint_pixmap_with_mask(state[0].dest, state[1].dest, state[1].mask); if (state[0].shape != state[1].shape) { fz_paint_pixmap_with_mask(state[0].shape, state[1].shape, state[1].mask); fz_drop_pixmap(ctx, state[1].shape); state[1].shape = NULL; } if (state[0].group_alpha != state[1].group_alpha) { fz_paint_pixmap_with_mask(state[0].group_alpha, state[1].group_alpha, state[1].mask); fz_drop_pixmap(ctx, state[1].group_alpha); state[1].group_alpha = NULL; } fz_drop_pixmap(ctx, state[1].mask); state[1].mask = NULL; fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, " to get ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); printf("\n"); #endif } else { #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, "Clip end\n"); #endif } } static void fz_draw_begin_mask(fz_context *ctx, fz_device *devp, fz_rect area, int luminosity, fz_colorspace *colorspace_in, const float *colorfv, fz_color_params color_params) { fz_draw_device *dev = (fz_draw_device*)devp; fz_pixmap *dest; fz_irect bbox; fz_draw_state *state = push_stack(ctx, dev, "mask"); fz_pixmap *shape = state->shape; fz_pixmap *group_alpha = state->group_alpha; fz_rect trect; fz_colorspace *colorspace = NULL; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, color_params, dev->default_cs); if (colorspace_in) colorspace = fz_default_colorspace(ctx, dev->default_cs, colorspace_in); trect = fz_transform_rect(area, dev->transform); bbox = fz_intersect_irect(fz_irect_from_rect(trect), state->scissor); /* Reset the blendmode for the mask rendering. In particular, * don't carry forward knockout or isolated. */ state[1].blendmode = 0; /* If luminosity, then we generate a mask from the greyscale value of the shapes. * If !luminosity, then we generate a mask from the alpha value of the shapes. */ if (luminosity) state[1].dest = dest = fz_new_pixmap_with_bbox(ctx, fz_device_gray(ctx), bbox, NULL, 0); else state[1].dest = dest = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); if (state->shape) { /* FIXME: If we ever want to support AIS true, then * we probably want to create a shape pixmap here, * using: shape = fz_new_pixmap_with_bbox(NULL, bbox); * then, in the end_mask code, we create the mask * from this rather than dest. */ state[1].shape = shape = NULL; } if (state->group_alpha) { state[1].group_alpha = group_alpha = NULL; } if (luminosity) { float bc; if (!colorspace) colorspace = fz_device_gray(ctx); fz_convert_color(ctx, colorspace, colorfv, fz_device_gray(ctx), &bc, NULL, color_params); fz_clear_pixmap_with_value(ctx, dest, bc * 255); if (shape) fz_clear_pixmap_with_value(ctx, shape, 255); if (group_alpha) fz_clear_pixmap_with_value(ctx, group_alpha, 255); } else { fz_clear_pixmap(ctx, dest); if (shape) fz_clear_pixmap(ctx, shape); if (group_alpha) fz_clear_pixmap(ctx, group_alpha); } #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Mask begin\n"); #endif state[1].scissor = bbox; } static void fz_draw_end_mask(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; fz_pixmap *temp, *dest; fz_irect bbox; fz_draw_state *state; if (dev->top == 0) fz_throw(ctx, FZ_ERROR_GENERIC, "unexpected end mask"); state = convert_stack(ctx, dev, "mask"); #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Mask -> Clip: "); fz_dump_blend(ctx, "Mask ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); #endif { /* convert to alpha mask */ temp = fz_alpha_from_gray(ctx, state[1].dest); if (state[1].mask != state[0].mask) fz_drop_pixmap(ctx, state[1].mask); state[1].mask = temp; if (state[1].dest != state[0].dest) fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; if (state[1].shape != state[0].shape) fz_drop_pixmap(ctx, state[1].shape); state[1].shape = NULL; if (state[1].group_alpha != state[0].group_alpha) fz_drop_pixmap(ctx, state[1].group_alpha); state[1].group_alpha = NULL; #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, "-> Clip ", temp); printf("\n"); #endif /* create new dest scratch buffer */ bbox = fz_pixmap_bbox(ctx, temp); dest = fz_new_pixmap_with_bbox(ctx, state->dest->colorspace, bbox, state->dest->seps, state->dest->alpha); fz_copy_pixmap_rect(ctx, dest, state->dest, bbox, dev->default_cs); /* push soft mask as clip mask */ state[1].dest = dest; state[1].blendmode |= FZ_BLEND_ISOLATED; /* If we have a shape, then it'll need to be masked with the * clip mask when we pop. So create a new shape now. */ if (state[0].shape) { state[1].shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].shape); } if (state[0].group_alpha) { state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } state[1].scissor = bbox; } } static void fz_draw_begin_group(fz_context *ctx, fz_device *devp, fz_rect area, fz_colorspace *cs, int isolated, int knockout, int blendmode, float alpha) { fz_draw_device *dev = (fz_draw_device*)devp; fz_irect bbox; fz_pixmap *dest; fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model = state->dest->colorspace; fz_rect trect; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); if (cs != NULL) model = fz_default_colorspace(ctx, dev->default_cs, cs); if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_begin(ctx, dev); state = push_stack(ctx, dev, "group"); trect = fz_transform_rect(area, dev->transform); bbox = fz_intersect_irect(fz_irect_from_rect(trect), state->scissor); #ifndef ATTEMPT_KNOCKOUT_AND_ISOLATED knockout = 0; isolated = 1; #endif state[1].dest = dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, state[0].dest->alpha || isolated); if (isolated) { fz_clear_pixmap(ctx, dest); state[1].group_alpha = NULL; } else { fz_copy_pixmap_rect(ctx, dest, state[0].dest, bbox, dev->default_cs); state[1].group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, state[1].group_alpha); } /* shape is inherited from the previous group */ state[1].alpha = alpha; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, ""); { char text[240]; char atext[80]; char btext[80]; if (alpha != 1) sprintf(atext, " (alpha %g)", alpha); else atext[0] = 0; if (blendmode != 0) sprintf(btext, " (blend %d)", blendmode); else btext[0] = 0; sprintf(text, "Group begin%s%s%s%s: background is ", isolated ? " (isolated)" : "", knockout ? " (knockout)" : "", atext, btext); fz_dump_blend(ctx, text, state[1].dest); } if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); printf("\n"); #endif state[1].scissor = bbox; state[1].blendmode = blendmode | (isolated ? FZ_BLEND_ISOLATED : 0) | (knockout ? FZ_BLEND_KNOCKOUT : 0); } static void fz_draw_end_group(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; int blendmode; int isolated; float alpha; fz_draw_state *state; if (dev->top == 0) fz_throw(ctx, FZ_ERROR_GENERIC, "unexpected end group"); state = pop_stack(ctx, dev, "group"); alpha = state[1].alpha; blendmode = state[1].blendmode & FZ_BLEND_MODEMASK; isolated = state[1].blendmode & FZ_BLEND_ISOLATED; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Group end: blending ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); fz_dump_blend(ctx, " onto ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); if (alpha != 1.0f) printf(" (alpha %g)", alpha); if (blendmode != 0) printf(" (blend %d)", blendmode); if (isolated != 0) printf(" (isolated)"); if (state[1].blendmode & FZ_BLEND_KNOCKOUT) printf(" (knockout)"); #endif if (state[0].dest->colorspace != state[1].dest->colorspace) { fz_pixmap *converted = fz_convert_pixmap(ctx, state[1].dest, state[0].dest->colorspace, NULL, dev->default_cs, fz_default_color_params, 1); fz_drop_pixmap(ctx, state[1].dest); state[1].dest = converted; } if ((blendmode == 0) && (state[0].shape == state[1].shape) && (state[0].group_alpha == state[1].group_alpha)) fz_paint_pixmap(state[0].dest, state[1].dest, alpha * 255); else fz_blend_pixmap(ctx, state[0].dest, state[1].dest, alpha * 255, blendmode, isolated, state[1].group_alpha); if (state[0].shape != state[1].shape) { /* The 'D' on page 7 of Altona_Technical_v20_x4.pdf goes wrong if this * isn't alpha * 255, as the blend back fails to take account of alpha. */ if (state[0].shape) { if (state[1].shape) fz_paint_pixmap(state[0].shape, state[1].shape, alpha * 255); else fz_paint_pixmap_alpha(state[0].shape, state[1].dest, alpha * 255); } } assert(state[0].group_alpha == NULL || state[0].group_alpha != state[1].group_alpha); if (state[0].group_alpha && state[0].group_alpha != state[1].group_alpha) { /* The 'D' on page 7 of Altona_Technical_v20_x4.pdf uses an isolated group, * and goes wrong if this is 255 * alpha, as an alpha effectively gets * applied twice. CATX5233 page 7 uses a non-isolated group, and goes wrong * if alpha isn't applied here. */ if (state[1].group_alpha) fz_paint_pixmap(state[0].group_alpha, state[1].group_alpha, isolated ? 255 : alpha * 255); else fz_paint_pixmap_alpha(state[0].group_alpha, state[1].dest, isolated ? 255 : alpha * 255); } assert(state[0].dest != state[1].dest); #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, " to get ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); printf("\n"); #endif if (state[0].shape != state[1].shape) { fz_drop_pixmap(ctx, state[1].shape); state[1].shape = NULL; } fz_drop_pixmap(ctx, state[1].group_alpha); state[1].group_alpha = NULL; fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; if (state[0].blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } typedef struct { int refs; float ctm[4]; int id; char has_shape; char has_group_alpha; fz_colorspace *cs; } tile_key; typedef struct { fz_storable storable; fz_pixmap *dest; fz_pixmap *shape; fz_pixmap *group_alpha; } tile_record; static int fz_make_hash_tile_key(fz_context *ctx, fz_store_hash *hash, void *key_) { tile_key *key = key_; hash->u.im.id = key->id; hash->u.im.has_shape = key->has_shape; hash->u.im.has_group_alpha = key->has_group_alpha; hash->u.im.m[0] = key->ctm[0]; hash->u.im.m[1] = key->ctm[1]; hash->u.im.m[2] = key->ctm[2]; hash->u.im.m[3] = key->ctm[3]; hash->u.im.ptr = key->cs; return 1; } static void * fz_keep_tile_key(fz_context *ctx, void *key_) { tile_key *key = key_; return fz_keep_imp(ctx, key, &key->refs); } static void fz_drop_tile_key(fz_context *ctx, void *key_) { tile_key *key = key_; if (fz_drop_imp(ctx, key, &key->refs)) { fz_drop_colorspace_store_key(ctx, key->cs); fz_free(ctx, key); } } static int fz_cmp_tile_key(fz_context *ctx, void *k0_, void *k1_) { tile_key *k0 = k0_; tile_key *k1 = k1_; return k0->id == k1->id && k0->has_shape == k1->has_shape && k0->has_group_alpha == k1->has_group_alpha && k0->ctm[0] == k1->ctm[0] && k0->ctm[1] == k1->ctm[1] && k0->ctm[2] == k1->ctm[2] && k0->ctm[3] == k1->ctm[3] && k0->cs == k1->cs; } static void fz_format_tile_key(fz_context *ctx, char *s, int n, void *key_) { tile_key *key = (tile_key *)key_; fz_snprintf(s, n, "(tile id=%x, ctm=%g %g %g %g, cs=%x, shape=%d, ga=%d)", key->id, key->ctm[0], key->ctm[1], key->ctm[2], key->ctm[3], key->cs, key->has_shape, key->has_group_alpha); } static const fz_store_type fz_tile_store_type = { fz_make_hash_tile_key, fz_keep_tile_key, fz_drop_tile_key, fz_cmp_tile_key, fz_format_tile_key, NULL }; static void fz_drop_tile_record_imp(fz_context *ctx, fz_storable *storable) { tile_record *tr = (tile_record *)storable; fz_drop_pixmap(ctx, tr->dest); fz_drop_pixmap(ctx, tr->shape); fz_drop_pixmap(ctx, tr->group_alpha); fz_free(ctx, tr); } static void fz_drop_tile_record(fz_context *ctx, tile_record *tile) { fz_drop_storable(ctx, &tile->storable); } static tile_record * fz_new_tile_record(fz_context *ctx, fz_pixmap *dest, fz_pixmap *shape, fz_pixmap *group_alpha) { tile_record *tile = fz_malloc_struct(ctx, tile_record); FZ_INIT_STORABLE(tile, 1, fz_drop_tile_record_imp); tile->dest = fz_keep_pixmap(ctx, dest); tile->shape = fz_keep_pixmap(ctx, shape); tile->group_alpha = fz_keep_pixmap(ctx, group_alpha); return tile; } size_t fz_tile_size(fz_context *ctx, tile_record *tile) { if (!tile) return 0; return sizeof(*tile) + fz_pixmap_size(ctx, tile->dest) + fz_pixmap_size(ctx, tile->shape) + fz_pixmap_size(ctx, tile->group_alpha); } static int fz_draw_begin_tile(fz_context *ctx, fz_device *devp, fz_rect area, fz_rect view, float xstep, float ystep, fz_matrix in_ctm, int id) { fz_draw_device *dev = (fz_draw_device*)devp; fz_matrix ctm = fz_concat(in_ctm, dev->transform); fz_pixmap *dest = NULL; fz_pixmap *shape, *group_alpha; fz_irect bbox; fz_draw_state *state = &dev->stack[dev->top]; fz_colorspace *model = state->dest->colorspace; fz_rect local_view; if (dev->top == 0 && dev->resolve_spots) state = push_group_for_separations(ctx, dev, fz_default_color_params /* FIXME */, dev->default_cs); /* area, view, xstep, ystep are in pattern space */ /* ctm maps from pattern space to device space */ if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_begin(ctx, dev); state = push_stack(ctx, dev, "tile"); local_view = fz_transform_rect(view, ctm); bbox = fz_irect_from_rect(local_view); /* We should never have a bbox that entirely covers our destination. * If we do, then the check for only 1 tile being visible above has * failed. Actually, this *can* fail due to the round_rect, at extreme * resolutions, so disable this assert. * assert(bbox.x0 > state->dest->x || bbox.x1 < state->dest->x + state->dest->w || * bbox.y0 > state->dest->y || bbox.y1 < state->dest->y + state->dest->h); */ /* Check to see if we have one cached */ if (id) { tile_key tk; tile_record *tile; tk.ctm[0] = ctm.a; tk.ctm[1] = ctm.b; tk.ctm[2] = ctm.c; tk.ctm[3] = ctm.d; tk.id = id; tk.cs = state[1].dest->colorspace; tk.has_shape = (state[1].shape != NULL); tk.has_group_alpha = (state[1].group_alpha != NULL); tile = fz_find_item(ctx, fz_drop_tile_record_imp, &tk, &fz_tile_store_type); if (tile) { state[1].dest = fz_keep_pixmap(ctx, tile->dest); state[1].shape = fz_keep_pixmap(ctx, tile->shape); state[1].group_alpha = fz_keep_pixmap(ctx, tile->group_alpha); state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].xstep = xstep; state[1].ystep = ystep; state[1].id = id; state[1].encache = 0; state[1].area = fz_irect_from_rect(area); state[1].ctm = ctm; state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Tile begin (cached)\n"); #endif fz_drop_tile_record(ctx, tile); return 1; } } /* Patterns can be transparent, so we need to have an alpha here. */ state[1].dest = dest = fz_new_pixmap_with_bbox(ctx, model, bbox, state[0].dest->seps, 1); fz_clear_pixmap(ctx, dest); shape = state[0].shape; if (shape) { state[1].shape = shape = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, shape); } group_alpha = state[0].group_alpha; if (group_alpha) { state[1].group_alpha = group_alpha = fz_new_pixmap_with_bbox(ctx, NULL, bbox, NULL, 1); fz_clear_pixmap(ctx, group_alpha); } state[1].blendmode |= FZ_BLEND_ISOLATED; state[1].xstep = xstep; state[1].ystep = ystep; state[1].id = id; state[1].encache = 1; state[1].area = fz_irect_from_rect(area); state[1].ctm = ctm; state[1].scissor = bbox; #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top-1, "Tile begin\n"); #endif return 0; } static void fz_draw_end_tile(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; float xstep, ystep; fz_matrix ttm, ctm, shapectm, gactm; fz_irect area, scissor, tile_bbox; fz_rect scissor_tmp, tile_tmp; int x0, y0, x1, y1, x, y, extra_x, extra_y; fz_draw_state *state; fz_pixmap *dest = NULL; fz_pixmap *shape = NULL; fz_pixmap *group_alpha = NULL; if (dev->top == 0) fz_throw(ctx, FZ_ERROR_GENERIC, "unexpected end tile"); state = pop_stack(ctx, dev, "tile"); xstep = state[1].xstep; ystep = state[1].ystep; area = state[1].area; ctm = state[1].ctm; /* Fudge the scissor bbox a little to allow for inaccuracies in the * matrix inversion. */ ttm = fz_invert_matrix(ctm); scissor_tmp = fz_rect_from_irect(state[0].scissor); scissor_tmp = fz_expand_rect(scissor_tmp, 1); scissor_tmp = fz_transform_rect(scissor_tmp, ttm); scissor = fz_irect_from_rect(scissor_tmp); area = fz_intersect_irect(area, scissor); tile_bbox.x0 = state[1].dest->x; tile_bbox.y0 = state[1].dest->y; tile_bbox.x1 = state[1].dest->w + tile_bbox.x0; tile_bbox.y1 = state[1].dest->h + tile_bbox.y0; tile_tmp = fz_rect_from_irect(tile_bbox); tile_tmp = fz_expand_rect(tile_tmp, 1); tile_tmp = fz_transform_rect(tile_tmp, ttm); /* FIXME: area is a bbox, so FP not appropriate here */ /* In PDF files xstep/ystep can be smaller than view (the area of a * single tile) (see fts_15_1506.pdf for an example). This means that * we have to bias the left hand/bottom edge calculations by the * difference between the step and the width/height of the tile. */ /* scissor, xstep and area are all in pattern space. */ extra_x = tile_tmp.x1 - tile_tmp.x0 - xstep; if (extra_x < 0) extra_x = 0; extra_y = tile_tmp.y1 - tile_tmp.y0 - ystep; if (extra_y < 0) extra_y = 0; x0 = floorf((area.x0 - tile_tmp.x0 - extra_x) / xstep); y0 = floorf((area.y0 - tile_tmp.y0 - extra_y) / ystep); x1 = ceilf((area.x1 - tile_tmp.x0 + extra_x) / xstep); y1 = ceilf((area.y1 - tile_tmp.y0 + extra_y) / ystep); ctm.e = state[1].dest->x; ctm.f = state[1].dest->y; if (state[1].shape) { shapectm = ctm; shapectm.e = state[1].shape->x; shapectm.f = state[1].shape->y; } if (state[1].group_alpha) { gactm = ctm; gactm.e = state[1].group_alpha->x; gactm.f = state[1].group_alpha->y; } #ifdef DUMP_GROUP_BLENDS dump_spaces(dev->top, ""); fz_dump_blend(ctx, "Tiling ", state[1].dest); if (state[1].shape) fz_dump_blend(ctx, "/S=", state[1].shape); if (state[1].group_alpha) fz_dump_blend(ctx, "/GA=", state[1].group_alpha); fz_dump_blend(ctx, " onto ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); #endif dest = fz_new_pixmap_from_pixmap(ctx, state[1].dest, NULL); fz_var(shape); fz_var(group_alpha); fz_try(ctx) { shape = fz_new_pixmap_from_pixmap(ctx, state[1].shape, NULL); group_alpha = fz_new_pixmap_from_pixmap(ctx, state[1].group_alpha, NULL); for (y = y0; y < y1; y++) { for (x = x0; x < x1; x++) { ttm = fz_pre_translate(ctm, x * xstep, y * ystep); dest->x = ttm.e; dest->y = ttm.f; /* Check for overflow due to float -> int conversions */ if (dest->x > 0 && dest->x + dest->w < 0) continue; if (dest->y > 0 && dest->y + dest->h < 0) continue; fz_paint_pixmap_with_bbox(state[0].dest, dest, 255, state[0].scissor); if (shape) { ttm = fz_pre_translate(shapectm, x * xstep, y * ystep); shape->x = ttm.e; shape->y = ttm.f; fz_paint_pixmap_with_bbox(state[0].shape, shape, 255, state[0].scissor); } if (group_alpha) { ttm = fz_pre_translate(gactm, x * xstep, y * ystep); group_alpha->x = ttm.e; group_alpha->y = ttm.f; fz_paint_pixmap_with_bbox(state[0].group_alpha, group_alpha, 255, state[0].scissor); } } } } fz_always(ctx) { fz_drop_pixmap(ctx, dest); fz_drop_pixmap(ctx, shape); fz_drop_pixmap(ctx, group_alpha); } fz_catch(ctx) fz_rethrow(ctx); /* Now we try to cache the tiles. Any failure here will just result in us not caching. */ if (state[1].encache && state[1].id != 0) { tile_record *tile = NULL; tile_key *key = NULL; fz_var(tile); fz_var(key); fz_try(ctx) { tile_record *existing_tile; tile = fz_new_tile_record(ctx, state[1].dest, state[1].shape, state[1].group_alpha); key = fz_malloc_struct(ctx, tile_key); key->refs = 1; key->id = state[1].id; key->ctm[0] = ctm.a; key->ctm[1] = ctm.b; key->ctm[2] = ctm.c; key->ctm[3] = ctm.d; key->cs = fz_keep_colorspace_store_key(ctx, state[1].dest->colorspace); key->has_shape = (state[1].shape != NULL); key->has_group_alpha = (state[1].group_alpha != NULL); existing_tile = fz_store_item(ctx, key, tile, fz_tile_size(ctx, tile), &fz_tile_store_type); if (existing_tile) { /* We already have a tile. This will either have been * produced by a racing thread, or there is already * an entry for this one in the store. */ fz_drop_tile_record(ctx, tile); tile = existing_tile; } } fz_always(ctx) { fz_drop_tile_key(ctx, key); fz_drop_tile_record(ctx, tile); } fz_catch(ctx) { /* Do nothing */ } } fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; fz_drop_pixmap(ctx, state[1].shape); state[1].shape = NULL; fz_drop_pixmap(ctx, state[1].group_alpha); state[1].group_alpha = NULL; #ifdef DUMP_GROUP_BLENDS fz_dump_blend(ctx, " to get ", state[0].dest); if (state[0].shape) fz_dump_blend(ctx, "/S=", state[0].shape); if (state[0].group_alpha) fz_dump_blend(ctx, "/GA=", state[0].group_alpha); printf("\n"); #endif if (state->blendmode & FZ_BLEND_KNOCKOUT) fz_knockout_end(ctx, dev); } static void fz_draw_render_flags(fz_context *ctx, fz_device *devp, int set, int clear) { fz_draw_device *dev = (fz_draw_device*)devp; dev->flags = (dev->flags | set ) & ~clear; } static void fz_draw_set_default_colorspaces(fz_context *ctx, fz_device *devp, fz_default_colorspaces *default_cs) { fz_draw_device *dev = (fz_draw_device*)devp; fz_drop_default_colorspaces(ctx, dev->default_cs); dev->default_cs = fz_keep_default_colorspaces(ctx, default_cs); } static void fz_draw_close_device(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; /* pop and free the stacks */ if (dev->top > dev->resolve_spots) fz_throw(ctx, FZ_ERROR_GENERIC, "items left on stack in draw device: %d", dev->top); if (dev->resolve_spots && dev->top) { fz_draw_state *state = &dev->stack[--dev->top]; fz_try(ctx) { fz_copy_pixmap_area_converting_seps(ctx, state[1].dest, state[0].dest, dev->proof_cs, fz_default_color_params, dev->default_cs); assert(state[1].mask == NULL); assert(state[1].shape == NULL); assert(state[1].group_alpha == NULL); } fz_always(ctx) { fz_drop_pixmap(ctx, state[1].dest); state[1].dest = NULL; } fz_catch(ctx) fz_rethrow(ctx); } } static void fz_draw_drop_device(fz_context *ctx, fz_device *devp) { fz_draw_device *dev = (fz_draw_device*)devp; fz_rasterizer *rast = dev->rast; fz_drop_default_colorspaces(ctx, dev->default_cs); fz_drop_colorspace(ctx, dev->proof_cs); /* pop and free the stacks */ for (; dev->top > 0; dev->top--) { fz_draw_state *state = &dev->stack[dev->top - 1]; if (state[1].mask != state[0].mask) fz_drop_pixmap(ctx, state[1].mask); if (state[1].dest != state[0].dest) fz_drop_pixmap(ctx, state[1].dest); if (state[1].shape != state[0].shape) fz_drop_pixmap(ctx, state[1].shape); if (state[1].group_alpha != state[0].group_alpha) fz_drop_pixmap(ctx, state[1].group_alpha); } /* We never free the dest/mask/shape at level 0, as: * 1) dest is passed in and ownership remains with the caller. * 2) shape and mask are NULL at level 0. */ if (dev->stack != &dev->init_stack[0]) fz_free(ctx, dev->stack); fz_drop_scale_cache(ctx, dev->cache_x); fz_drop_scale_cache(ctx, dev->cache_y); fz_drop_rasterizer(ctx, rast); } fz_device * new_draw_device(fz_context *ctx, fz_matrix transform, fz_pixmap *dest, const fz_aa_context *aa, const fz_irect *clip, fz_colorspace *proof_cs) { fz_draw_device *dev = fz_new_derived_device(ctx, fz_draw_device); dev->super.drop_device = fz_draw_drop_device; dev->super.close_device = fz_draw_close_device; dev->super.fill_path = fz_draw_fill_path; dev->super.stroke_path = fz_draw_stroke_path; dev->super.clip_path = fz_draw_clip_path; dev->super.clip_stroke_path = fz_draw_clip_stroke_path; dev->super.fill_text = fz_draw_fill_text; dev->super.stroke_text = fz_draw_stroke_text; dev->super.clip_text = fz_draw_clip_text; dev->super.clip_stroke_text = fz_draw_clip_stroke_text; dev->super.ignore_text = fz_draw_ignore_text; dev->super.fill_image_mask = fz_draw_fill_image_mask; dev->super.clip_image_mask = fz_draw_clip_image_mask; dev->super.fill_image = fz_draw_fill_image; dev->super.fill_shade = fz_draw_fill_shade; dev->super.pop_clip = fz_draw_pop_clip; dev->super.begin_mask = fz_draw_begin_mask; dev->super.end_mask = fz_draw_end_mask; dev->super.begin_group = fz_draw_begin_group; dev->super.end_group = fz_draw_end_group; dev->super.begin_tile = fz_draw_begin_tile; dev->super.end_tile = fz_draw_end_tile; dev->super.render_flags = fz_draw_render_flags; dev->super.set_default_colorspaces = fz_draw_set_default_colorspaces; dev->proof_cs = fz_keep_colorspace(ctx, proof_cs); dev->transform = transform; dev->flags = 0; dev->resolve_spots = 0; dev->top = 0; dev->stack = &dev->init_stack[0]; dev->stack_cap = STACK_SIZE; dev->stack[0].dest = dest; dev->stack[0].shape = NULL; dev->stack[0].group_alpha = NULL; dev->stack[0].mask = NULL; dev->stack[0].blendmode = 0; dev->stack[0].scissor.x0 = dest->x; dev->stack[0].scissor.y0 = dest->y; dev->stack[0].scissor.x1 = dest->x + dest->w; dev->stack[0].scissor.y1 = dest->y + dest->h; if (clip) { if (clip->x0 > dev->stack[0].scissor.x0) dev->stack[0].scissor.x0 = clip->x0; if (clip->x1 < dev->stack[0].scissor.x1) dev->stack[0].scissor.x1 = clip->x1; if (clip->y0 > dev->stack[0].scissor.y0) dev->stack[0].scissor.y0 = clip->y0; if (clip->y1 < dev->stack[0].scissor.y1) dev->stack[0].scissor.y1 = clip->y1; } /* If we have no separations structure at all, then we want a * simple composite rendering (with no overprint simulation). * If we do have a separations structure, so: 1) Any * 'disabled' separations are ignored. 2) Any 'composite' * separations means we will need to do an overprint * simulation. * * The supplied pixmaps 's' will match the number of * 'spots' separations. If we have any 'composite' * separations therefore, we'll need to make a new pixmap * with a new (completely 'spots') separations structure, * render to that, and then map down at the end. * * Unfortunately we can't produce this until we know what * the default_colorspaces etc are, so set a flag for us * to trigger on later. */ if (dest->seps || dev->proof_cs != NULL) #if FZ_ENABLE_SPOT_RENDERING dev->resolve_spots = 1; #else fz_throw(ctx, FZ_ERROR_GENERIC, "Spot rendering (and overprint/overprint simulation) not available in this build"); #endif fz_try(ctx) { dev->rast = fz_new_rasterizer(ctx, aa); dev->cache_x = fz_new_scale_cache(ctx); dev->cache_y = fz_new_scale_cache(ctx); } fz_catch(ctx) { fz_drop_device(ctx, (fz_device*)dev); fz_rethrow(ctx); } return (fz_device*)dev; } /* Create a device to draw on a pixmap. dest: Target pixmap for the draw device. See fz_new_pixmap* for how to obtain a pixmap. The pixmap is not cleared by the draw device, see fz_clear_pixmap* for how to clear it prior to calling fz_new_draw_device. Free the device by calling fz_drop_device. transform: Transform from user space in points to device space in pixels. */ fz_device * fz_new_draw_device(fz_context *ctx, fz_matrix transform, fz_pixmap *dest) { return new_draw_device(ctx, transform, dest, NULL, NULL, NULL); } /* Create a device to draw on a pixmap. dest: Target pixmap for the draw device. See fz_new_pixmap* for how to obtain a pixmap. The pixmap is not cleared by the draw device, see fz_clear_pixmap* for how to clear it prior to calling fz_new_draw_device. Free the device by calling fz_drop_device. transform: Transform from user space in points to device space in pixels. clip: Bounding box to restrict any marking operations of the draw device. */ fz_device * fz_new_draw_device_with_bbox(fz_context *ctx, fz_matrix transform, fz_pixmap *dest, const fz_irect *clip) { return new_draw_device(ctx, transform, dest, NULL, clip, NULL); } /* Create a device to draw on a pixmap. dest: Target pixmap for the draw device. See fz_new_pixmap* for how to obtain a pixmap. The pixmap is not cleared by the draw device, see fz_clear_pixmap* for how to clear it prior to calling fz_new_draw_device. Free the device by calling fz_drop_device. transform: Transform from user space in points to device space in pixels. proof_cs: Intermediate color space to map though when mapping to color space defined by pixmap. */ fz_device * fz_new_draw_device_with_proof(fz_context *ctx, fz_matrix transform, fz_pixmap *dest, fz_colorspace *cs) { return new_draw_device(ctx, transform, dest, NULL, NULL, cs); } /* Create a device to draw on a pixmap. dest: Target pixmap for the draw device. See fz_new_pixmap* for how to obtain a pixmap. The pixmap is not cleared by the draw device, see fz_clear_pixmap* for how to clear it prior to calling fz_new_draw_device. Free the device by calling fz_drop_device. transform: Transform from user space in points to device space in pixels. clip: Bounding box to restrict any marking operations of the draw device. proof_cs: Color space to render to prior to mapping to color space defined by pixmap. */ fz_device * fz_new_draw_device_with_bbox_proof(fz_context *ctx, fz_matrix transform, fz_pixmap *dest, const fz_irect *clip, fz_colorspace *cs) { return new_draw_device(ctx, transform, dest, NULL, clip, cs); } fz_device * fz_new_draw_device_type3(fz_context *ctx, fz_matrix transform, fz_pixmap *dest) { fz_draw_device *dev = (fz_draw_device*)fz_new_draw_device(ctx, transform, dest); dev->flags |= FZ_DRAWDEV_FLAGS_TYPE3; return (fz_device*)dev; } fz_irect * fz_bound_path_accurate(fz_context *ctx, fz_irect *bbox, const fz_irect *scissor, const fz_path *path, const fz_stroke_state *stroke, fz_matrix ctm, float flatness, float linewidth) { fz_rasterizer *rast = fz_new_rasterizer(ctx, NULL); fz_try(ctx) { if (stroke) (void)fz_flatten_stroke_path(ctx, rast, path, stroke, ctm, flatness, linewidth, scissor, bbox); else (void)fz_flatten_fill_path(ctx, rast, path, ctm, flatness, scissor, bbox); } fz_always(ctx) fz_drop_rasterizer(ctx, rast); fz_catch(ctx) fz_rethrow(ctx); return bbox; } const char *fz_draw_options_usage = "Raster output options:\n" "\trotate=N: rotate rendered pages N degrees counterclockwise\n" "\tresolution=N: set both X and Y resolution in pixels per inch\n" "\tx-resolution=N: X resolution of rendered pages in pixels per inch\n" "\ty-resolution=N: Y resolution of rendered pages in pixels per inch\n" "\twidth=N: render pages to fit N pixels wide (ignore resolution option)\n" "\theight=N: render pages to fit N pixels tall (ignore resolution option)\n" "\tcolorspace=(gray|rgb|cmyk): render using specified colorspace\n" "\talpha: render pages with alpha channel and transparent background\n" "\tgraphics=(aaN|cop|app): set the rasterizer to use\n" "\ttext=(aaN|cop|app): set the rasterizer to use for text\n" "\t\taaN=antialias with N bits (0 to 8)\n" "\t\tcop=center of pixel\n" "\t\tapp=any part of pixel\n" "\n"; static int parse_aa_opts(const char *val) { if (fz_option_eq(val, "cop")) return 9; if (fz_option_eq(val, "app")) return 10; if (val[0] == 'a' && val[1] == 'a' && val[2] >= '0' && val[2] <= '9') return fz_clampi(fz_atoi(&val[2]), 0, 8); return 8; } /* Parse draw device options from a comma separated key-value string. */ fz_draw_options * fz_parse_draw_options(fz_context *ctx, fz_draw_options *opts, const char *args) { const char *val; memset(opts, 0, sizeof *opts); opts->x_resolution = 96; opts->y_resolution = 96; opts->rotate = 0; opts->width = 0; opts->height = 0; opts->colorspace = fz_device_rgb(ctx); opts->alpha = 0; opts->graphics = fz_aa_level(ctx); opts->text = fz_text_aa_level(ctx); if (fz_has_option(ctx, args, "rotate", &val)) opts->rotate = fz_atoi(val); if (fz_has_option(ctx, args, "resolution", &val)) opts->x_resolution = opts->y_resolution = fz_atoi(val); if (fz_has_option(ctx, args, "x-resolution", &val)) opts->x_resolution = fz_atoi(val); if (fz_has_option(ctx, args, "y-resolution", &val)) opts->y_resolution = fz_atoi(val); if (fz_has_option(ctx, args, "width", &val)) opts->width = fz_atoi(val); if (fz_has_option(ctx, args, "height", &val)) opts->height = fz_atoi(val); if (fz_has_option(ctx, args, "colorspace", &val)) { if (fz_option_eq(val, "gray") || fz_option_eq(val, "grey") || fz_option_eq(val, "mono")) opts->colorspace = fz_device_gray(ctx); else if (fz_option_eq(val, "rgb")) opts->colorspace = fz_device_rgb(ctx); else if (fz_option_eq(val, "cmyk")) opts->colorspace = fz_device_cmyk(ctx); else fz_throw(ctx, FZ_ERROR_GENERIC, "unknown colorspace in options"); } if (fz_has_option(ctx, args, "alpha", &val)) opts->alpha = fz_option_eq(val, "yes"); if (fz_has_option(ctx, args, "graphics", &val)) opts->text = opts->graphics = parse_aa_opts(val); if (fz_has_option(ctx, args, "text", &val)) opts->text = parse_aa_opts(val); /* Sanity check values */ if (opts->x_resolution <= 0) opts->x_resolution = 96; if (opts->y_resolution <= 0) opts->y_resolution = 96; if (opts->width < 0) opts->width = 0; if (opts->height < 0) opts->height = 0; return opts; } /* Create a new pixmap and draw device, using the specified options. options: Options to configure the draw device, and choose the resolution and colorspace. mediabox: The bounds of the page in points. pixmap: An out parameter containing the newly created pixmap. */ fz_device * fz_new_draw_device_with_options(fz_context *ctx, const fz_draw_options *opts, fz_rect mediabox, fz_pixmap **pixmap) { fz_aa_context aa = ctx->aa; float x_zoom = opts->x_resolution / 72.0f; float y_zoom = opts->y_resolution / 72.0f; float page_w = mediabox.x1 - mediabox.x0; float page_h = mediabox.y1 - mediabox.y0; float w = opts->width; float h = opts->height; float x_scale, y_scale; fz_matrix transform; fz_irect bbox; fz_device *dev; fz_set_rasterizer_graphics_aa_level(ctx, &aa, opts->graphics); fz_set_rasterizer_text_aa_level(ctx, &aa, opts->text); if (w > 0) { x_scale = w / page_w; if (h > 0) y_scale = h / page_h; else y_scale = floorf(page_h * x_scale + 0.5f) / page_h; } else if (h > 0) { y_scale = h / page_h; x_scale = floorf(page_w * y_scale + 0.5f) / page_w; } else { x_scale = floorf(page_w * x_zoom + 0.5f) / page_w; y_scale = floorf(page_h * y_zoom + 0.5f) / page_h; } transform = fz_pre_rotate(fz_scale(x_scale, y_scale), opts->rotate); bbox = fz_irect_from_rect(fz_transform_rect(mediabox, transform)); *pixmap = fz_new_pixmap_with_bbox(ctx, opts->colorspace, bbox, NULL, opts->alpha); fz_try(ctx) { fz_set_pixmap_resolution(ctx, *pixmap, opts->x_resolution, opts->y_resolution); if (opts->alpha) fz_clear_pixmap(ctx, *pixmap); else fz_clear_pixmap_with_value(ctx, *pixmap, 255); dev = new_draw_device(ctx, transform, *pixmap, &aa, NULL, NULL); } fz_catch(ctx) { fz_drop_pixmap(ctx, *pixmap); *pixmap = NULL; fz_rethrow(ctx); } return dev; }