static int xps_paint_tiling_brush(const gs_client_color *pcc, gs_state *pgs) { const gs_client_pattern *ppat = gs_getpattern(pcc); struct tile_closure_s *c = ppat->client_data; xps_context_t *ctx = c->ctx; gs_state *saved_pgs; int code; saved_pgs = ctx->pgs; ctx->pgs = pgs; gs_gsave(ctx->pgs); code = xps_paint_tiling_brush_clipped(c); if (code) goto cleanup; gs_grestore(ctx->pgs); if (c->tile_mode == TILE_FLIP_X || c->tile_mode == TILE_FLIP_X_Y) { gs_gsave(ctx->pgs); gs_translate(ctx->pgs, c->viewbox.q.x * 2, 0.0); gs_scale(ctx->pgs, -1.0, 1.0); code = xps_paint_tiling_brush_clipped(c); if (code) goto cleanup; gs_grestore(ctx->pgs); } if (c->tile_mode == TILE_FLIP_Y || c->tile_mode == TILE_FLIP_X_Y) { gs_gsave(ctx->pgs); gs_translate(ctx->pgs, 0.0, c->viewbox.q.y * 2); gs_scale(ctx->pgs, 1.0, -1.0); code = xps_paint_tiling_brush_clipped(c); if (code) goto cleanup; gs_grestore(ctx->pgs); } if (c->tile_mode == TILE_FLIP_X_Y) { gs_gsave(ctx->pgs); gs_translate(ctx->pgs, c->viewbox.q.x * 2, c->viewbox.q.y * 2); gs_scale(ctx->pgs, -1.0, -1.0); code = xps_paint_tiling_brush_clipped(c); if (code) goto cleanup; gs_grestore(ctx->pgs); } ctx->pgs = saved_pgs; return 0; cleanup: gs_grestore(ctx->pgs); ctx->pgs = saved_pgs; return gs_rethrow(code, "cannot draw tile"); }
static int test2(gs_state * pgs, gs_memory_t * mem) { gs_client_color cc; gx_tile_bitmap tile; /*const */ byte tpdata[] = { /* Define a pattern that looks like this: ..xxxx .....x .....x ..xxxx .x.... x..... */ 0x3c, 0, 0, 0, 0x04, 0, 0, 0, 0x04, 0, 0, 0, 0x3c, 0, 0, 0, 0x40, 0, 0, 0, 0x80, 0, 0, 0 }; gs_newpath(pgs); gs_moveto(pgs, 100.0, 300.0); gs_lineto(pgs, 500.0, 500.0); gs_lineto(pgs, 200.0, 100.0); gs_lineto(pgs, 300.0, 500.0); gs_lineto(pgs, 500.0, 200.0); gs_closepath(pgs); gs_setrgbcolor(pgs, 0.0, 0.0, 0.0); gs_gsave(pgs); gs_fill(pgs); gs_grestore(pgs); tile.data = tpdata; tile.raster = 4; tile.size.x = tile.rep_width = 6; tile.size.y = tile.rep_height = 6; tile.id = gx_no_bitmap_id; gs_makebitmappattern(&cc, &tile, true, pgs, NULL); /* Note: color space is DeviceRGB */ cc.paint.values[0] = 0.0; cc.paint.values[1] = 1.0; cc.paint.values[2] = 1.0; gs_setpattern(pgs, &cc); gs_eofill(pgs); gs_makebitmappattern(&cc, &tile, false, pgs, NULL); gs_setcolor(pgs, &cc); gs_moveto(pgs, 50.0, 50.0); gs_lineto(pgs, 300.0, 50.0); gs_lineto(pgs, 50.0, 300.0); gs_closepath(pgs); gs_setrgbcolor(pgs, 1.0, 0.0, 0.0); gs_gsave(pgs); gs_fill(pgs); gs_grestore(pgs); gs_setpattern(pgs, &cc); gs_eofill(pgs); return 0; }
/* <userpath1> <userpath2> <matrix> inustroke <bool> */ static int zinustroke(i_ctx_t *i_ctx_p) { /* This is different because of the optional matrix operand. */ os_ptr op = osp; int code = gs_gsave(igs); int spop, npop; gs_matrix mat; gx_device hdev; if (code < 0) return code; if ((spop = upath_stroke(i_ctx_p, &mat, false)) < 0) { gs_grestore(igs); return spop; } if ((npop = in_path(op - spop, i_ctx_p, &hdev)) < 0) { gs_grestore(igs); return npop; } if (npop > 1) /* matrix was supplied */ code = gs_concat(igs, &mat); if (code >= 0) code = gs_stroke(igs); return in_upath_result(i_ctx_p, npop + spop, code); }
static int test1(gs_state * pgs, gs_memory_t * mem) { int n; gs_scale(pgs, 72.0, 72.0); gs_translate(pgs, 4.25, 5.5); gs_scale(pgs, 4.0, 4.0); gs_newpath(pgs); for (n = 200; --n >= 0;) { int j; #define rf() (rand() / (1.0 * 0x10000 * 0x8000)) double r = rf(), g = rf(), b = rf(); double x0 = rf(), y0 = rf(), x1 = rf(), y1 = rf(), x2 = rf(), y2 = rf(); gs_setrgbcolor(pgs, r, g, b); for (j = 0; j < 6; j++) { gs_gsave(pgs); gs_rotate(pgs, 60.0 * j); gs_moveto(pgs, x0, y0); gs_lineto(pgs, x1, y1); gs_lineto(pgs, x2, y2); gs_fill(pgs); gs_grestore(pgs); } } #undef mem return 0; }
/* - gsave - */ static int z2gsave(i_ctx_t *i_ctx_p) { if (!save_page_device(igs)) return gs_gsave(igs); return push_callout(i_ctx_p, "%gsavepagedevice"); }
int xps_begin_opacity(xps_context_t *ctx, char *base_uri, xps_resource_t *dict, char *opacity_att, xps_item_t *opacity_mask_tag) { gs_transparency_group_params_t tgp; gs_transparency_mask_params_t tmp; gs_rect bbox; float opacity; int save; int code; if (!opacity_att && !opacity_mask_tag) return 0; opacity = 1.0; if (opacity_att) opacity = atof(opacity_att); gs_setopacityalpha(ctx->pgs, opacity); xps_bounds_in_user_space(ctx, &bbox); if (opacity_mask_tag) { gs_trans_mask_params_init(&tmp, TRANSPARENCY_MASK_Luminosity); gs_begin_transparency_mask(ctx->pgs, &tmp, &bbox, 0); gs_gsave(ctx->pgs); /* Need a path to fill/clip for the brush */ gs_moveto(ctx->pgs, bbox.p.x, bbox.p.y); gs_lineto(ctx->pgs, bbox.p.x, bbox.q.y); gs_lineto(ctx->pgs, bbox.q.x, bbox.q.y); gs_lineto(ctx->pgs, bbox.q.x, bbox.p.y); gs_closepath(ctx->pgs); /* opacity-only mode: use alpha value as gray color to create luminosity mask */ save = ctx->opacity_only; ctx->opacity_only = 1; code = xps_parse_brush(ctx, base_uri, dict, opacity_mask_tag); if (code) { gs_grestore(ctx->pgs); gs_end_transparency_mask(ctx->pgs, TRANSPARENCY_CHANNEL_Opacity); ctx->opacity_only = save; return gs_rethrow(code, "cannot parse opacity mask brush"); } gs_grestore(ctx->pgs); gs_end_transparency_mask(ctx->pgs, TRANSPARENCY_CHANNEL_Opacity); ctx->opacity_only = save; } gs_trans_group_params_init(&tgp); gs_begin_transparency_group(ctx->pgs, &tgp, &bbox); return 0; }
/* Set up a clipping path and device for insideness testing. */ static int in_path(os_ptr oppath, i_ctx_t *i_ctx_p, gx_device * phdev) { int code = gs_gsave(igs); int npop; double uxy[2]; if (code < 0) return code; code = num_params(oppath, 2, uxy); if (code >= 0) { /* Aperture is a single pixel. */ gs_point dxy; gs_fixed_rect fr; gs_transform(igs, uxy[0], uxy[1], &dxy); fr.p.x = fixed_floor(float2fixed(dxy.x)); fr.p.y = fixed_floor(float2fixed(dxy.y)); fr.q.x = fr.p.x + fixed_1; fr.q.y = fr.p.y + fixed_1; code = gx_clip_to_rectangle(igs, &fr); npop = 2; } else if (code == e_stackunderflow) { /* If 0 elements, definitely a stackunderflow; otherwise, */ /* only 1 number, also a stackunderflow. */ npop = code; } else { /* Aperture is a user path. */ /* We have to set the clipping path without disturbing */ /* the current path. */ gx_path *ipath = igs->path; gx_path save; gx_path_init_local(&save, imemory); gx_path_assign_preserve(&save, ipath); gs_newpath(igs); code = upath_append(oppath, i_ctx_p, false); if (code >= 0) code = gx_clip_to_path(igs); gx_path_assign_free(igs->path, &save); npop = 1; } if (code < 0) { gs_grestore(igs); return code; } /* Install the hit detection device. */ gx_set_device_color_1(igs); gx_device_init((gx_device *) phdev, (const gx_device *)&gs_hit_device, NULL, true); phdev->width = phdev->height = max_int; gx_device_fill_in_procs(phdev); gx_set_device_only(igs, phdev); return npop; }
int pxSetClipIntersect(px_args_t *par, px_state_t *pxs) { gs_state *pgs = pxs->pgs; pxeClipRegion_t clip_region = par->pv[0]->value.i; int code; check_clip_region(par, pxs); /* * The discussion of ClipMode and ClipRegion in the published * specification is confused and incorrect. Based on testing with * the LaserJet 6MP, we believe that ClipMode works just like * PostScript clip and eoclip, and that ClipRegion applies only to * the *current* path (i.e., support for "outside clipping" in the * library is unnecessary). If we had only known.... */ #if 0 gs_setclipoutside(pgs, false); #endif if ( clip_region == eExterior ) { /* * We know clip_mode is eEvenOdd, so we can complement the * region defined by the current path by just adding a * rectangle that encloses the entire page. */ gs_rect bbox; code = gs_gsave(pgs); if ( code < 0 ) return code; px_initclip(pxs); if ( (code = gs_clippath(pgs)) < 0 || (code = gs_pathbbox(pgs, &bbox)) < 0 ) DO_NOTHING; gs_grestore(pgs); if ( code < 0 || (code = gs_rectappend(pgs, &bbox, 1)) < 0 ) return code; #ifdef CLIP_INTERSECT_EXTERIOR_REPLACES px_initclip(pxs); #endif } code = (pxs->pxgs->clip_mode == eEvenOdd ? gs_eoclip(pgs) : gs_clip(pgs)); if ( code < 0 ) return code; #if 0 gs_setclipoutside(pgs, clip_region == eExterior); #endif return gs_newpath(pgs); }
int pxPushGS(px_args_t *par, px_state_t *pxs) { gs_state *pgs = pxs->pgs; int code = gs_gsave(pgs); px_gstate_t *pxgs; if ( code < 0 ) return code; pxgs = pxs->pxgs = gs_state_client_data(pgs); if ( pxgs->palette.data ) pxgs->palette_is_shared = true; ++(pxgs->stack_depth); return code; }
/* <userpath> uappend - */ static int zuappend(i_ctx_t *i_ctx_p) { os_ptr op = osp; int code = gs_gsave(igs); if (code < 0) return code; if ((code = upath_append(op, i_ctx_p, false)) >= 0) code = gs_upmergepath(igs); gs_grestore(igs); if (code < 0) return code; pop(1); return 0; }
/* <userpath> <matrix> ustroke - */ static int zustroke(i_ctx_t *i_ctx_p) { int code = gs_gsave(igs); int npop; if (code < 0) return code; if ((code = npop = upath_stroke(i_ctx_p, NULL, gs_currentcpsimode(imemory))) >= 0) code = gs_stroke(igs); gs_grestore(igs); if (code < 0) return code; pop(npop); return 0; }
/* <userpath> ufill - */ static int zufill(i_ctx_t *i_ctx_p) { os_ptr op = osp; int code = gs_gsave(igs); if (code < 0) return code; if ((code = upath_append(op, i_ctx_p, gs_currentcpsimode(imemory))) >= 0) code = gs_fill(igs); gs_grestore(igs); if (code < 0) return code; pop(1); return 0; }
/* with a user path. */ static int in_upath(i_ctx_t *i_ctx_p, gx_device * phdev) { os_ptr op = osp; int code = gs_gsave(igs); int npop; if (code < 0) return code; if ((code = upath_append(op, i_ctx_p, false)) < 0 || (code = npop = in_path(op - 1, i_ctx_p, phdev)) < 0 ) { gs_grestore(igs); return code; } return npop + 1; }
/* Erase the page */ int gs_erasepage(gs_state * pgs) { /* * We can't just fill with device white; we must take the * transfer function into account. */ int code; if ((code = gs_gsave(pgs)) < 0) return code; if ((code = gs_setgray(pgs, 1.0)) >= 0) { /* Fill the page directly, ignoring clipping. */ code = gs_fillpage(pgs); } gs_grestore(pgs); return code; }
/* - save <save> */ int zsave(i_ctx_t *i_ctx_p) { os_ptr op = osp; uint space = icurrent_space; vm_save_t *vmsave; ulong sid; int code; gs_state *prev; if (I_VALIDATE_BEFORE_SAVE) ivalidate_clean_spaces(i_ctx_p); ialloc_set_space(idmemory, avm_local); vmsave = ialloc_struct(vm_save_t, &st_vm_save, "zsave"); ialloc_set_space(idmemory, space); if (vmsave == 0) return_error(e_VMerror); code = alloc_save_state(idmemory, vmsave, &sid); if (code < 0) return code; if (sid == 0) { ifree_object(vmsave, "zsave"); return_error(e_VMerror); } if_debug2('u', "[u]vmsave 0x%lx, id = %lu\n", (ulong) vmsave, (ulong) sid); code = gs_gsave_for_save(igs, &prev); if (code < 0) return code; code = gs_gsave(igs); if (code < 0) return code; vmsave->gsave = prev; push(1); make_tav(op, t_save, 0, saveid, sid); if (I_VALIDATE_AFTER_SAVE) ivalidate_clean_spaces(i_ctx_p); return 0; }
/* (We could do this a lot more efficiently.) */ int gs_rectstroke(gs_state * pgs, const gs_rect * pr, uint count, const gs_matrix * pmat) { bool do_save = pmat != NULL || !gx_path_is_null(pgs->path); int code; if (do_save) { if ((code = gs_gsave(pgs)) < 0) return code; gs_newpath(pgs); } if ((code = gs_rectappend(pgs, pr, count)) < 0 || (pmat != NULL && (code = gs_concat(pgs, pmat)) < 0) || (code = gs_stroke(pgs)) < 0 ) DO_NOTHING; if (do_save) gs_grestore(pgs); else if (code < 0) gs_newpath(pgs); return code; }
static int test5(gs_state * pgs, gs_memory_t * mem) { gx_device *dev = gs_currentdevice(pgs); gx_image_enum_common_t *info; gx_image_plane_t planes[5]; gx_drawing_color dcolor; int code; static const byte data3[] = { 0x00, 0x44, 0x88, 0xcc, 0x44, 0x88, 0xcc, 0x00, 0x88, 0xcc, 0x00, 0x44, 0xcc, 0x00, 0x44, 0x88 }; gs_color_space *gray_cs = gs_cspace_new_DeviceGray(mem); /* * Neither ImageType 3 nor 4 needs a current color, * but some intermediate code assumes it's valid. */ set_nonclient_dev_color(&dcolor, 0); /* Scale everything up, and fill the background. */ { gs_matrix mat; gs_currentmatrix(pgs, &mat); mat.xx = gs_copysign(98.6, mat.xx); mat.yy = gs_copysign(98.6, mat.yy); mat.tx = floor(mat.tx) + 0.499; mat.ty = floor(mat.ty) + 0.499; gs_setmatrix(pgs, &mat); } gs_setrgbcolor(pgs, 1.0, 0.9, 0.9); fill_rect1(pgs, 0.25, 0.25, 4.0, 6.0); gs_setrgbcolor(pgs, 0.5, 1.0, 0.5); #if 0 /* Make things a little more interesting.... */ gs_translate(pgs, 1.0, 1.0); gs_rotate(pgs, 10.0); gs_scale(pgs, 1.3, 0.9); #endif #define do_image(image, idata)\ BEGIN\ code = gx_device_begin_typed_image(dev, (gs_imager_state *)pgs, NULL,\ (gs_image_common_t *)&image, NULL, &dcolor, NULL, mem, &info);\ /****** TEST code >= 0 ******/\ planes[0].data = idata;\ planes[0].data_x = 0;\ planes[0].raster = (image.Height * image.BitsPerComponent + 7) >> 3;\ code = gx_image_plane_data(info, planes, image.Height);\ /****** TEST code == 1 ******/\ code = gx_image_end(info, true);\ /****** TEST code >= 0 ******/\ END #define W 4 #define H 4 /* Test an unmasked image. */ gs_gsave(pgs); { gs_image1_t image1; void *info1; gs_color_space *cs; cs = gs_cspace_new_DeviceGray(mem); gs_image_t_init(&image1, cs); /* image */ image1.ImageMatrix.xx = W; image1.ImageMatrix.yy = -H; image1.ImageMatrix.ty = H; /* data_image */ image1.Width = W; image1.Height = H; image1.BitsPerComponent = 8; gs_translate(pgs, 0.5, 4.0); code = gx_device_begin_image(dev, (gs_imager_state *) pgs, &image1, gs_image_format_chunky, NULL, &dcolor, NULL, mem, &info1); /****** TEST code >= 0 ******/ planes[0].data = data3; planes[0].data_x = 0; planes[0].raster = (image1.Height * image1.BitsPerComponent + 7) >> 3; /* Use the old image_data API. */ code = gx_image_data(info1, &planes[0].data, 0, planes[0].raster, image1.Height); /****** TEST code == 1 ******/ code = gx_image_end(info1, true); /****** TEST code >= 0 ******/ gs_free_object(mem, cs, "colorspace"); } gs_grestore(pgs); /* Test an explicitly masked image. */ gs_gsave(pgs); { gs_image3_t image3; static const byte data3mask[] = { 0x60, 0x90, 0x90, 0x60 }; static const byte data3x2mask[] = { 0x66, 0x99, 0x99, 0x66, 0x66, 0x99, 0x99, 0x66 }; gs_image3_t_init(&image3, gray_cs, interleave_scan_lines); /* image */ image3.ImageMatrix.xx = W; image3.ImageMatrix.yy = -H; image3.ImageMatrix.ty = H; /* data_image */ image3.Width = W; image3.Height = H; image3.BitsPerComponent = 8; /* MaskDict */ image3.MaskDict.ImageMatrix = image3.ImageMatrix; image3.MaskDict.Width = image3.Width; image3.MaskDict.Height = image3.Height; /* Display with 1-for-1 mask and image. */ gs_translate(pgs, 0.5, 2.0); code = gx_device_begin_typed_image(dev, (gs_imager_state *) pgs, NULL, (gs_image_common_t *) & image3, NULL, &dcolor, NULL, mem, &info); /****** TEST code >= 0 ******/ planes[0].data = data3mask; planes[0].data_x = 0; planes[0].raster = (image3.MaskDict.Height + 7) >> 3; planes[1].data = data3; planes[1].data_x = 0; planes[1].raster = (image3.Height * image3.BitsPerComponent + 7) >> 3; code = gx_image_plane_data(info, planes, image3.Height); /****** TEST code == 1 ******/ code = gx_image_end(info, true); /****** TEST code >= 0 ******/ /* Display with 2-for-1 mask and image. */ image3.MaskDict.ImageMatrix.xx *= 2; image3.MaskDict.ImageMatrix.yy *= 2; image3.MaskDict.ImageMatrix.ty *= 2; image3.MaskDict.Width *= 2; image3.MaskDict.Height *= 2; gs_translate(pgs, 1.5, 0.0); code = gx_device_begin_typed_image(dev, (gs_imager_state *) pgs, NULL, (gs_image_common_t *) & image3, NULL, &dcolor, NULL, mem, &info); /****** TEST code >= 0 ******/ planes[0].data = data3x2mask; planes[0].raster = (image3.MaskDict.Width + 7) >> 3; { int i; for (i = 0; i < H; ++i) { planes[1].data = 0; code = gx_image_plane_data(info, planes, 1); planes[0].data += planes[0].raster; /****** TEST code == 0 ******/ planes[1].data = data3 + i * planes[1].raster; code = gx_image_plane_data(info, planes, 1); planes[0].data += planes[0].raster; /****** TEST code >= 0 ******/ } } /****** TEST code == 1 ******/ code = gx_image_end(info, true); /****** TEST code >= 0 ******/ } gs_grestore(pgs); /* Test a chroma-keyed masked image. */ gs_gsave(pgs); { gs_image4_t image4; const byte *data4 = data3; gs_image4_t_init(&image4, gray_cs); /* image */ image4.ImageMatrix.xx = W; image4.ImageMatrix.yy = -H; image4.ImageMatrix.ty = H; /* data_image */ image4.Width = W; image4.Height = H; image4.BitsPerComponent = 8; /* Display with a single mask color. */ gs_translate(pgs, 0.5, 0.5); image4.MaskColor_is_range = false; image4.MaskColor[0] = 0xcc; do_image(image4, data4); /* Display a second time with a color range. */ gs_translate(pgs, 1.5, 0.0); image4.MaskColor_is_range = true; image4.MaskColor[0] = 0x40; image4.MaskColor[1] = 0x90; do_image(image4, data4); } gs_grestore(pgs); gs_free_object(mem, gray_cs, "test5 gray_cs"); #undef W #undef H #undef do_image return 0; }
int main(int argc, const char *argv[]) { char achar = '0'; gs_memory_t *mem; gs_state *pgs; const gx_device *const *list; gx_device *dev; gx_device_bbox *bbdev; int code; gp_init(); mem = gs_malloc_init(); gs_lib_init1(mem); if (argc < 2 || (achar = argv[1][0]) < '1' || achar > '0' + countof(tests) - 1 ) { lprintf1("Usage: gslib 1..%c\n", '0' + (char)countof(tests) - 1); gs_abort(mem); } gs_debug['@'] = 1; gs_debug['?'] = 1; /*gs_debug['B'] = 1; *//****** PATCH ******/ /*gs_debug['L'] = 1; *//****** PATCH ******/ /* * gs_iodev_init must be called after the rest of the inits, for * obscure reasons that really should be documented! */ gs_iodev_init(mem); /****** WRONG ******/ gs_lib_device_list(&list, NULL); gs_copydevice(&dev, list[0], mem); check_device_separable(dev); gx_device_fill_in_procs(dev); bbdev = gs_alloc_struct_immovable(mem, gx_device_bbox, &st_device_bbox, "bbox"); gx_device_bbox_init(bbdev, dev, mem); code = dev_proc(dev, get_profile)(dev, &bbdev->icc_struct); rc_increment(bbdev->icc_struct); /* Print out the device name just to test the gsparam.c API. */ { gs_c_param_list list; gs_param_string nstr; gs_c_param_list_write(&list, mem); code = gs_getdeviceparams(dev, (gs_param_list *) & list); if (code < 0) { lprintf1("getdeviceparams failed! code = %d\n", code); gs_abort(mem); } gs_c_param_list_read(&list); code = param_read_string((gs_param_list *) & list, "Name", &nstr); if (code < 0) { lprintf1("reading Name failed! code = %d\n", code); gs_abort(mem); } dputs("Device name = "); debug_print_string(nstr.data, nstr.size); dputs("\n"); gs_c_param_list_release(&list); } /* * If this is a device that takes an OutputFile, set the OutputFile * to "-" in the copy. */ { gs_c_param_list list; gs_param_string nstr; gs_c_param_list_write(&list, mem); param_string_from_string(nstr, "-"); code = param_write_string((gs_param_list *)&list, "OutputFile", &nstr); if (code < 0) { lprintf1("writing OutputFile failed! code = %d\n", code); gs_abort(mem); } gs_c_param_list_read(&list); code = gs_putdeviceparams(dev, (gs_param_list *)&list); gs_c_param_list_release(&list); if (code < 0 && code != gs_error_undefined) { lprintf1("putdeviceparams failed! code = %d\n", code); gs_abort(mem); } } dev = (gx_device *) bbdev; pgs = gs_state_alloc(mem); gs_setdevice_no_erase(pgs, dev); /* can't erase yet */ { gs_point dpi; gs_screen_halftone ht; gs_dtransform(pgs, 72.0, 72.0, &dpi); ht.frequency = min(fabs(dpi.x), fabs(dpi.y)) / 16.001; ht.angle = 0; ht.spot_function = odsf; gs_setscreen(pgs, &ht); } /* gsave and grestore (among other places) assume that */ /* there are at least 2 gstates on the graphics stack. */ /* Ensure that now. */ gs_gsave(pgs); gs_erasepage(pgs); code = (*tests[achar - '1']) (pgs, mem); gs_output_page(pgs, 1, 1); { gs_rect bbox; gx_device_bbox_bbox(bbdev, &bbox); dprintf4("Bounding box: [%g %g %g %g]\n", bbox.p.x, bbox.p.y, bbox.q.x, bbox.q.y); } if (code) dprintf1("**** Test returned code = %d.\n", code); dputs("Done. Press <enter> to exit."); fgetc(mem->gs_lib_ctx->fstdin); gs_lib_finit(0, 0, mem); return 0; #undef mem }
int xps_parse_canvas(xps_context_t *ctx, char *base_uri, xps_resource_t *dict, xps_item_t *root) { xps_resource_t *new_dict = NULL; xps_item_t *node; char *opacity_mask_uri; int code; char *transform_att; char *clip_att; char *opacity_att; char *opacity_mask_att; xps_item_t *transform_tag = NULL; xps_item_t *clip_tag = NULL; xps_item_t *opacity_mask_tag = NULL; gs_matrix transform; transform_att = xps_att(root, "RenderTransform"); clip_att = xps_att(root, "Clip"); opacity_att = xps_att(root, "Opacity"); opacity_mask_att = xps_att(root, "OpacityMask"); for (node = xps_down(root); node; node = xps_next(node)) { if (!strcmp(xps_tag(node), "Canvas.Resources") && xps_down(node)) { code = xps_parse_resource_dictionary(ctx, &new_dict, base_uri, xps_down(node)); if (code) return gs_rethrow(code, "cannot load Canvas.Resources"); if (new_dict && new_dict != dict) { new_dict->parent = dict; dict = new_dict; } } if (!strcmp(xps_tag(node), "Canvas.RenderTransform")) transform_tag = xps_down(node); if (!strcmp(xps_tag(node), "Canvas.Clip")) clip_tag = xps_down(node); if (!strcmp(xps_tag(node), "Canvas.OpacityMask")) opacity_mask_tag = xps_down(node); } opacity_mask_uri = base_uri; xps_resolve_resource_reference(ctx, dict, &transform_att, &transform_tag, NULL); xps_resolve_resource_reference(ctx, dict, &clip_att, &clip_tag, NULL); xps_resolve_resource_reference(ctx, dict, &opacity_mask_att, &opacity_mask_tag, &opacity_mask_uri); gs_gsave(ctx->pgs); gs_make_identity(&transform); if (transform_att) xps_parse_render_transform(ctx, transform_att, &transform); if (transform_tag) xps_parse_matrix_transform(ctx, transform_tag, &transform); gs_concat(ctx->pgs, &transform); if (clip_att || clip_tag) { if (clip_att) xps_parse_abbreviated_geometry(ctx, clip_att); if (clip_tag) xps_parse_path_geometry(ctx, dict, clip_tag, 0); xps_clip(ctx); } code = xps_begin_opacity(ctx, opacity_mask_uri, dict, opacity_att, opacity_mask_tag, false, false); if (code) { gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot create transparency group"); } for (node = xps_down(root); node; node = xps_next(node)) { code = xps_parse_element(ctx, base_uri, dict, node); if (code) { xps_end_opacity(ctx, opacity_mask_uri, dict, opacity_att, opacity_mask_tag); gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot parse child of Canvas"); } } xps_end_opacity(ctx, opacity_mask_uri, dict, opacity_att, opacity_mask_tag); gs_grestore(ctx->pgs); if (new_dict) xps_free_resource_dictionary(ctx, new_dict); return 0; }
int xps_parse_fixed_page(xps_context_t *ctx, xps_part_t *part) { xps_item_t *root, *node; xps_resource_t *dict; char *width_att; char *height_att; char base_uri[1024]; char *s; int code; if_debug1m('|', ctx->memory, "doc: parsing page %s\n", part->name); xps_strlcpy(base_uri, part->name, sizeof base_uri); s = strrchr(base_uri, '/'); if (s) s[1] = 0; root = xps_parse_xml(ctx, part->data, part->size); if (!root) return gs_rethrow(-1, "cannot parse xml"); if (strcmp(xps_tag(root), "FixedPage")) return gs_throw1(-1, "expected FixedPage element (found %s)", xps_tag(root)); width_att = xps_att(root, "Width"); height_att = xps_att(root, "Height"); if (!width_att) return gs_throw(-1, "FixedPage missing required attribute: Width"); if (!height_att) return gs_throw(-1, "FixedPage missing required attribute: Height"); dict = NULL; /* Setup new page */ { gs_memory_t *mem = ctx->memory; gs_state *pgs = ctx->pgs; gx_device *dev = gs_currentdevice(pgs); gs_param_float_array fa; float fv[2]; gs_c_param_list list; gs_c_param_list_write(&list, mem); fv[0] = atoi(width_att) / 96.0 * 72.0; fv[1] = atoi(height_att) / 96.0 * 72.0; fa.persistent = false; fa.data = fv; fa.size = 2; code = param_write_float_array((gs_param_list *)&list, ".MediaSize", &fa); if ( code >= 0 ) { gs_c_param_list_read(&list); code = gs_putdeviceparams(dev, (gs_param_list *)&list); } gs_c_param_list_release(&list); /* nb this is for the demo it is wrong and should be removed */ gs_initgraphics(pgs); /* 96 dpi default - and put the origin at the top of the page */ gs_initmatrix(pgs); code = gs_scale(pgs, 72.0/96.0, -72.0/96.0); if (code < 0) return gs_rethrow(code, "cannot set page transform"); code = gs_translate(pgs, 0.0, -atoi(height_att)); if (code < 0) return gs_rethrow(code, "cannot set page transform"); code = gs_erasepage(pgs); if (code < 0) return gs_rethrow(code, "cannot clear page"); } /* Pre-parse looking for transparency */ ctx->has_transparency = 0; for (node = xps_down(root); node; node = xps_next(node)) { if (!strcmp(xps_tag(node), "FixedPage.Resources") && xps_down(node)) if (xps_resource_dictionary_has_transparency(ctx, base_uri, xps_down(node))) ctx->has_transparency = 1; if (xps_element_has_transparency(ctx, base_uri, node)) ctx->has_transparency = 1; } /* save the state with the original device before we push */ gs_gsave(ctx->pgs); if (ctx->use_transparency && ctx->has_transparency) { code = gs_push_pdf14trans_device(ctx->pgs, false); if (code < 0) { gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot install transparency device"); } } /* Draw contents */ for (node = xps_down(root); node; node = xps_next(node)) { if (!strcmp(xps_tag(node), "FixedPage.Resources") && xps_down(node)) { code = xps_parse_resource_dictionary(ctx, &dict, base_uri, xps_down(node)); if (code) { gs_pop_pdf14trans_device(ctx->pgs, false); gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot load FixedPage.Resources"); } } code = xps_parse_element(ctx, base_uri, dict, node); if (code) { gs_pop_pdf14trans_device(ctx->pgs, false); gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot parse child of FixedPage"); } } if (ctx->use_transparency && ctx->has_transparency) { code = gs_pop_pdf14trans_device(ctx->pgs, false); if (code < 0) { gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot uninstall transparency device"); } } /* Flush page */ { code = xps_show_page(ctx, 1, true); /* copies, flush */ if (code < 0) { gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot flush page"); } } /* restore the original device, discarding the pdf14 compositor */ gs_grestore(ctx->pgs); if (dict) { xps_free_resource_dictionary(ctx, dict); } xps_free_item(ctx, root); return 0; }
/* Set a device into an interperter instance */ static int /* ret 0 ok, else -ve error code */ pxl_impl_set_device( pl_interp_instance_t *instance, /* interp instance to use */ gx_device *device /* device to set (open or closed) */ ) { int code; pxl_interp_instance_t *pxli = (pxl_interp_instance_t *)instance; px_state_t *pxs = pxli->pxs; enum {Sbegin, Ssetdevice, Sinitg, Sgsave, Serase, Sdone} stage; stage = Sbegin; gs_opendevice(device); pxs->interpolate = pxl_get_interpolation(instance); /* Set the device into the gstate */ stage = Ssetdevice; if ((code = gs_setdevice_no_erase(pxli->pgs, device)) < 0) /* can't erase yet */ goto pisdEnd; /* Initialize device ICC profile */ code = gsicc_init_device_profile(pxli->pgs, device); if (code < 0) return code; /* Init XL graphics */ stage = Sinitg; if ((code = px_initgraphics(pxli->pxs)) < 0) goto pisdEnd; /* Do inits of gstate that may be reset by setdevice */ gs_setaccuratecurves(pxli->pgs, true); /* All H-P languages want accurate curves. */ /* disable hinting at high res */ if (gs_currentdevice(pxli->pgs)->HWResolution[0] >= 300) gs_setgridfittt(pxs->font_dir, 0); /* gsave and grestore (among other places) assume that */ /* there are at least 2 gstates on the graphics stack. */ /* Ensure that now. */ stage = Sgsave; if ( (code = gs_gsave(pxli->pgs)) < 0) goto pisdEnd; stage = Serase; if ( (code = gs_erasepage(pxli->pgs)) < 0 ) goto pisdEnd; stage = Sdone; /* success */ /* Unwind any errors */ pisdEnd: switch (stage) { case Sdone: /* don't undo success */ break; case Serase: /* gs_erasepage failed */ /* undo gsave */ gs_grestore_only(pxli->pgs); /* destroys gs_save stack */ /* fall thru to next */ case Sgsave: /* gsave failed */ case Sinitg: /* undo setdevice */ gs_nulldevice(pxli->pgs); /* fall thru to next */ case Ssetdevice: /* gs_setdevice failed */ case Sbegin: /* nothing left to undo */ break; } return code; }
/* We take the trouble to do this efficiently in the simple cases. */ int gs_rectfill(gs_state * pgs, const gs_rect * pr, uint count) { const gs_rect *rlist = pr; gx_clip_path *pcpath; uint rcount = count; int code; gx_device * pdev = pgs->device; gx_device_color *pdc = gs_currentdevicecolor_inline(pgs); const gs_imager_state *pis = (const gs_imager_state *)pgs; bool hl_color_available = gx_hld_is_hl_color_available(pis, pdc); bool hl_color = (hl_color_available && dev_proc(pdev, dev_spec_op)(pdev, gxdso_supports_hlcolor, NULL, 0)); bool center_of_pixel = (pgs->fill_adjust.x == 0 && pgs->fill_adjust.y == 0); /* Processing a fill object operation */ dev_proc(pgs->device, set_graphics_type_tag)(pgs->device, GS_PATH_TAG); code = gx_set_dev_color(pgs); if (code != 0) return code; if ((is_fzero2(pgs->ctm.xy, pgs->ctm.yx) || is_fzero2(pgs->ctm.xx, pgs->ctm.yy)) && gx_effective_clip_path(pgs, &pcpath) >= 0 && clip_list_is_rectangle(gx_cpath_list(pcpath)) && (hl_color || pdc->type == gx_dc_type_pure || pdc->type == gx_dc_type_ht_binary || pdc->type == gx_dc_type_ht_colored) && gs_state_color_load(pgs) >= 0 && (*dev_proc(pdev, get_alpha_bits)) (pdev, go_graphics) <= 1 && (!pgs->overprint || !pgs->effective_overprint_mode) ) { uint i; gs_fixed_rect clip_rect; gx_cpath_inner_box(pcpath, &clip_rect); /* We should never plot anything for an empty clip rectangle */ if ((clip_rect.p.x >= clip_rect.q.x) && (clip_rect.p.y >= clip_rect.q.y)) return 0; for (i = 0; i < count; ++i) { gs_fixed_point p, q; gs_fixed_rect draw_rect; if (gs_point_transform2fixed(&pgs->ctm, pr[i].p.x, pr[i].p.y, &p) < 0 || gs_point_transform2fixed(&pgs->ctm, pr[i].q.x, pr[i].q.y, &q) < 0 ) { /* Switch to the slow algorithm. */ goto slow; } draw_rect.p.x = min(p.x, q.x); draw_rect.p.y = min(p.y, q.y); draw_rect.q.x = max(p.x, q.x); draw_rect.q.y = max(p.y, q.y); if (hl_color) { rect_intersect(draw_rect, clip_rect); /* We do pass on 0 extant rectangles to high level devices. It isn't clear how a client and an output device should interact if one uses a center of pixel algorithm and the other uses any part of pixel. For now we punt and just pass the high level rectangle on without adjustment. */ if (draw_rect.p.x <= draw_rect.q.x && draw_rect.p.y <= draw_rect.q.y) { code = dev_proc(pdev, fill_rectangle_hl_color)(pdev, &draw_rect, pis, pdc, pcpath); if (code < 0) return code; } } else { int x, y, w, h; rect_intersect(draw_rect, clip_rect); if (center_of_pixel) { draw_rect.p.x = fixed_rounded(draw_rect.p.x); draw_rect.p.y = fixed_rounded(draw_rect.p.y); draw_rect.q.x = fixed_rounded(draw_rect.q.x); draw_rect.q.y = fixed_rounded(draw_rect.q.y); } else { /* any part of pixel rule - touched */ draw_rect.p.x = fixed_floor(draw_rect.p.x); draw_rect.p.y = fixed_floor(draw_rect.p.y); draw_rect.q.x = fixed_ceiling(draw_rect.q.x); draw_rect.q.y = fixed_ceiling(draw_rect.q.y); } x = fixed2int(draw_rect.p.x); y = fixed2int(draw_rect.p.y); w = fixed2int(draw_rect.q.x) - x; h = fixed2int(draw_rect.q.y) - y; /* clients that use the "any part of pixel" rule also fill 0 areas. This is true of current graphics library clients but not a general rule. */ if (!center_of_pixel) { if (w == 0) w = 1; /* yes Adobe Acrobat 8, seems to back up the y coordinate when the width is 0, sigh. */ if (h == 0) { y--; h = 1; } } if (gx_fill_rectangle(x, y, w, h, pdc, pgs) < 0) goto slow; } } return 0; slow:rlist = pr + i; rcount = count - i; } { bool do_save = !gx_path_is_null(pgs->path); if (do_save) { if ((code = gs_gsave(pgs)) < 0) return code; gs_newpath(pgs); } if ((code = gs_rectappend(pgs, rlist, rcount)) < 0 || (code = gs_fill(pgs)) < 0 ) DO_NOTHING; if (do_save) gs_grestore(pgs); else if (code < 0) gs_newpath(pgs); } return code; }
/* - gsave - */ int zgsave(i_ctx_t *i_ctx_p) { return gs_gsave(igs); }
int xps_parse_tiling_brush(xps_context_t *ctx, char *base_uri, xps_resource_t *dict, xps_item_t *root, int (*func)(xps_context_t*, char*, xps_resource_t*, xps_item_t*, void*), void *user) { xps_item_t *node; int code; char *opacity_att; char *transform_att; char *viewbox_att; char *viewport_att; char *tile_mode_att; /*char *viewbox_units_att;*/ /*char *viewport_units_att;*/ xps_item_t *transform_tag = NULL; gs_matrix transform; gs_rect viewbox; gs_rect viewport; float scalex, scaley; int tile_mode; opacity_att = xps_att(root, "Opacity"); transform_att = xps_att(root, "Transform"); viewbox_att = xps_att(root, "Viewbox"); viewport_att = xps_att(root, "Viewport"); tile_mode_att = xps_att(root, "TileMode"); /*viewbox_units_att = xps_att(root, "ViewboxUnits");*/ /*viewport_units_att = xps_att(root, "ViewportUnits");*/ for (node = xps_down(root); node; node = xps_next(node)) { if (!strcmp(xps_tag(node), "ImageBrush.Transform")) transform_tag = xps_down(node); if (!strcmp(xps_tag(node), "VisualBrush.Transform")) transform_tag = xps_down(node); } xps_resolve_resource_reference(ctx, dict, &transform_att, &transform_tag, NULL); gs_make_identity(&transform); if (transform_att) xps_parse_render_transform(ctx, transform_att, &transform); if (transform_tag) xps_parse_matrix_transform(ctx, transform_tag, &transform); viewbox.p.x = 0.0; viewbox.p.y = 0.0; viewbox.q.x = 1.0; viewbox.q.y = 1.0; if (viewbox_att) xps_parse_rectangle(ctx, viewbox_att, &viewbox); viewport.p.x = 0.0; viewport.p.y = 0.0; viewport.q.x = 1.0; viewport.q.y = 1.0; if (viewport_att) xps_parse_rectangle(ctx, viewport_att, &viewport); /* some sanity checks on the viewport/viewbox size */ if (fabs(viewport.q.x - viewport.p.x) < 0.01) { gs_warn("skipping tile with zero width view port"); return 0; } if (fabs(viewport.q.y - viewport.p.y) < 0.01) { gs_warn("skipping tile with zero height view port"); return 0; } if (fabs(viewbox.q.x - viewbox.p.x) < 0.01) { gs_warn("skipping tile with zero width view box"); return 0; } if (fabs(viewbox.q.y - viewbox.p.y) < 0.01) { gs_warn("skipping tile with zero height view box"); return 0; } scalex = (viewport.q.x - viewport.p.x) / (viewbox.q.x - viewbox.p.x); scaley = (viewport.q.y - viewport.p.y) / (viewbox.q.y - viewbox.p.y); tile_mode = TILE_NONE; if (tile_mode_att) { if (!strcmp(tile_mode_att, "None")) tile_mode = TILE_NONE; if (!strcmp(tile_mode_att, "Tile")) tile_mode = TILE_TILE; if (!strcmp(tile_mode_att, "FlipX")) tile_mode = TILE_FLIP_X; if (!strcmp(tile_mode_att, "FlipY")) tile_mode = TILE_FLIP_Y; if (!strcmp(tile_mode_att, "FlipXY")) tile_mode = TILE_FLIP_X_Y; } gs_gsave(ctx->pgs); code = xps_begin_opacity(ctx, base_uri, dict, opacity_att, NULL, false, false); if (code) { gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot create transparency group"); } /* TODO(tor): check viewport and tiling to see if we can set it to TILE_NONE */ if (tile_mode != TILE_NONE) { struct tile_closure_s closure; gs_client_pattern gspat; gs_client_color gscolor; gs_color_space *cs; bool sa; closure.ctx = ctx; closure.base_uri = base_uri; closure.dict = dict; closure.tag = root; closure.tile_mode = tile_mode; closure.user = user; closure.func = func; closure.viewbox.p.x = viewbox.p.x; closure.viewbox.p.y = viewbox.p.y; closure.viewbox.q.x = viewbox.q.x; closure.viewbox.q.y = viewbox.q.y; gs_pattern1_init(&gspat); uid_set_UniqueID(&gspat.uid, gs_next_ids(ctx->memory, 1)); gspat.PaintType = 1; gspat.TilingType = 2; gspat.PaintProc = xps_remap_pattern; gspat.client_data = &closure; /* We need to know if this tiling brush includes transparency. We could do a proper scan, but for now we'll be lazy and just look at the flag from scanning the page. */ gspat.uses_transparency = ctx->has_transparency; gspat.XStep = viewbox.q.x - viewbox.p.x; gspat.YStep = viewbox.q.y - viewbox.p.y; gspat.BBox.p.x = viewbox.p.x; gspat.BBox.p.y = viewbox.p.y; gspat.BBox.q.x = viewbox.q.x; gspat.BBox.q.y = viewbox.q.y; if (tile_mode == TILE_FLIP_X || tile_mode == TILE_FLIP_X_Y) { gspat.BBox.q.x += gspat.XStep; gspat.XStep *= 2; } if (tile_mode == TILE_FLIP_Y || tile_mode == TILE_FLIP_X_Y) { gspat.BBox.q.y += gspat.YStep; gspat.YStep *= 2; } gs_matrix_translate(&transform, viewport.p.x, viewport.p.y, &transform); gs_matrix_scale(&transform, scalex, scaley, &transform); gs_matrix_translate(&transform, -viewbox.p.x, -viewbox.p.y, &transform); cs = ctx->srgb; gs_setcolorspace(ctx->pgs, cs); gsicc_profile_reference(cs->cmm_icc_profile_data, 1); sa = gs_currentstrokeadjust(ctx->pgs); gs_setstrokeadjust(ctx->pgs, false); gs_makepattern(&gscolor, &gspat, &transform, ctx->pgs, NULL); gs_setpattern(ctx->pgs, &gscolor); xps_fill(ctx); gs_setstrokeadjust(ctx->pgs, sa); gsicc_profile_reference(cs->cmm_icc_profile_data, -1); /* gs_makepattern increments the pattern count stored in the color * structure. We will discard the color struct (its on the stack) * so we need to decrement the reference before we throw away * the structure. */ gs_pattern_reference(&gscolor, -1); } else { xps_clip(ctx); gs_concat(ctx->pgs, &transform); gs_translate(ctx->pgs, viewport.p.x, viewport.p.y); gs_scale(ctx->pgs, scalex, scaley); gs_translate(ctx->pgs, -viewbox.p.x, -viewbox.p.y); gs_moveto(ctx->pgs, viewbox.p.x, viewbox.p.y); gs_lineto(ctx->pgs, viewbox.p.x, viewbox.q.y); gs_lineto(ctx->pgs, viewbox.q.x, viewbox.q.y); gs_lineto(ctx->pgs, viewbox.q.x, viewbox.p.y); gs_closepath(ctx->pgs); gs_clip(ctx->pgs); gs_newpath(ctx->pgs); code = func(ctx, base_uri, dict, root, user); if (code < 0) { xps_end_opacity(ctx, base_uri, dict, opacity_att, NULL); gs_grestore(ctx->pgs); return gs_rethrow(code, "cannot draw tile"); } } xps_end_opacity(ctx, base_uri, dict, opacity_att, NULL); gs_grestore(ctx->pgs); return 0; }
int gslt_outline_font_glyph(gs_state *pgs, gslt_font_t *xf, int gid, gslt_outline_walker_t *walk) { gs_text_params_t params; gs_text_enum_t *textenum; gs_matrix matrix; segment *seg; curve_segment *cseg; gs_gsave(pgs); gs_make_identity(&matrix); gs_setmatrix(pgs, &matrix); gs_scale(pgs, 1000.0, 1000.0); /* otherwise we hit serious precision problems with fixpoint math */ /* set gstate params */ gs_setfont(pgs, xf->font); /* set pgs->font and invalidate existing charmatrix */ gs_make_identity(&matrix); gs_setcharmatrix(pgs, &matrix); /* set the charmatrix to identity */ /* reset the path */ gs_newpath(pgs); gs_moveto(pgs, 0.0, 0.0); /* draw the glyph, in charpath mode */ params.operation = TEXT_FROM_SINGLE_GLYPH | TEXT_DO_FALSE_CHARPATH | TEXT_RETURN_WIDTH; params.data.d_glyph = gid; params.size = 1; if (gs_text_begin(pgs, ¶ms, xf->font->memory, &textenum) != 0) return gs_throw(-1, "cannot gs_text_begin()"); if (gs_text_process(textenum) != 0) return gs_throw(-1, "cannot gs_text_process()"); gs_text_release(textenum, "gslt font outline"); /* walk the resulting path */ seg = (segment*)pgs->path->first_subpath; while (seg) { switch (seg->type) { case s_start: walk->moveto(walk->user, fixed2float(seg->pt.x) * 0.001, fixed2float(seg->pt.y) * 0.001); break; case s_line: walk->lineto(walk->user, fixed2float(seg->pt.x) * 0.001, fixed2float(seg->pt.y) * 0.001); break; case s_line_close: walk->closepath(walk->user); break; case s_curve: cseg = (curve_segment*)seg; walk->curveto(walk->user, fixed2float(cseg->p1.x) * 0.001, fixed2float(cseg->p1.y) * 0.001, fixed2float(cseg->p2.x) * 0.001, fixed2float(cseg->p2.y) * 0.001, fixed2float(seg->pt.x) * 0.001, fixed2float(seg->pt.y) * 0.001); break; } seg = seg->next; } /* and toss it away... */ gs_newpath(pgs); gs_grestore(pgs); return 0; }
int xps_high_level_pattern(xps_context_t *ctx) { gs_matrix m; gs_rect bbox; gs_fixed_rect clip_box; int code; gx_device_color *pdc = gs_currentdevicecolor_inline(ctx->pgs); const gs_client_pattern *ppat = gs_getpattern(&pdc->ccolor); gs_pattern1_instance_t *pinst = (gs_pattern1_instance_t *)gs_currentcolor(ctx->pgs)->pattern; code = gx_pattern_cache_add_dummy_entry((gs_imager_state *)ctx->pgs, pinst, ctx->pgs->device->color_info.depth); if (code < 0) return code; code = gs_gsave(ctx->pgs); if (code < 0) return code; dev_proc(ctx->pgs->device, get_initial_matrix)(ctx->pgs->device, &m); gs_setmatrix(ctx->pgs, &m); code = gs_bbox_transform(&ppat->BBox, &ctm_only(ctx->pgs), &bbox); if (code < 0) { gs_grestore(ctx->pgs); return code; } clip_box.p.x = float2fixed(bbox.p.x); clip_box.p.y = float2fixed(bbox.p.y); clip_box.q.x = float2fixed(bbox.q.x); clip_box.q.y = float2fixed(bbox.q.y); code = gx_clip_to_rectangle(ctx->pgs, &clip_box); if (code < 0) { gs_grestore(ctx->pgs); return code; } { pattern_accum_param_s param; param.pinst = (void *)pinst; param.graphics_state = (void *)ctx->pgs; param.pinst_id = pinst->id; code = (*dev_proc(ctx->pgs->device, dev_spec_op))((gx_device *)ctx->pgs->device, gxdso_pattern_start_accum, ¶m, sizeof(pattern_accum_param_s)); } if (code < 0) { gs_grestore(ctx->pgs); return code; } code = xps_paint_tiling_brush(&pdc->ccolor, ctx->pgs); if (code) { gs_grestore(ctx->pgs); return gs_rethrow(code, "high level pattern brush function failed"); } code = gs_grestore(ctx->pgs); if (code < 0) return code; { pattern_accum_param_s param; param.pinst = (void *)pinst; param.graphics_state = (void *)ctx->pgs; param.pinst_id = pinst->id; code = (*dev_proc(ctx->pgs->device, dev_spec_op))((gx_device *)ctx->pgs->device, gxdso_pattern_finish_accum, ¶m, sizeof(pattern_accum_param_s)); } return code; }
/* We take the trouble to do this efficiently in the simple cases. */ int gs_rectfill(gs_state * pgs, const gs_rect * pr, uint count) { const gs_rect *rlist = pr; gx_clip_path *pcpath; uint rcount = count; int code; gx_device * pdev = pgs->device; gx_device_color *pdc = pgs->dev_color; const gs_imager_state *pis = (const gs_imager_state *)pgs; bool hl_color_available = gx_hld_is_hl_color_available(pis, pdc); gs_fixed_rect empty = {{0, 0}, {0, 0}}; bool hl_color = (hl_color_available && dev_proc(pdev, fill_rectangle_hl_color)(pdev, &empty, pis, pdc, NULL) == 0); gx_set_dev_color(pgs); if ((is_fzero2(pgs->ctm.xy, pgs->ctm.yx) || is_fzero2(pgs->ctm.xx, pgs->ctm.yy)) && gx_effective_clip_path(pgs, &pcpath) >= 0 && clip_list_is_rectangle(gx_cpath_list(pcpath)) && (hl_color || pdc->type == gx_dc_type_pure || pdc->type == gx_dc_type_ht_binary || pdc->type == gx_dc_type_ht_colored /* DeviceN todo: add wts case */) && gs_state_color_load(pgs) >= 0 && (*dev_proc(pdev, get_alpha_bits)) (pdev, go_graphics) <= 1 && (!pgs->overprint || !pgs->effective_overprint_mode) ) { uint i; gs_fixed_rect clip_rect; gx_cpath_inner_box(pcpath, &clip_rect); for (i = 0; i < count; ++i) { gs_fixed_point p, q; gs_fixed_rect draw_rect; if (gs_point_transform2fixed(&pgs->ctm, pr[i].p.x, pr[i].p.y, &p) < 0 || gs_point_transform2fixed(&pgs->ctm, pr[i].q.x, pr[i].q.y, &q) < 0 ) { /* Switch to the slow algorithm. */ goto slow; } draw_rect.p.x = min(p.x, q.x); draw_rect.p.y = min(p.y, q.y); draw_rect.q.x = max(p.x, q.x); draw_rect.q.y = max(p.y, q.y); if (hl_color) { rect_intersect(draw_rect, clip_rect); if (draw_rect.p.x < draw_rect.q.x && draw_rect.p.y < draw_rect.q.y) { code = dev_proc(pdev, fill_rectangle_hl_color)(pdev, &draw_rect, pis, pdc, pcpath); if (code < 0) return code; } } else { int x, y, w, h; draw_rect.p.x -= pgs->fill_adjust.x; draw_rect.p.y -= pgs->fill_adjust.x; draw_rect.q.x += pgs->fill_adjust.x; draw_rect.q.y += pgs->fill_adjust.x; rect_intersect(draw_rect, clip_rect); x = fixed2int_pixround(draw_rect.p.x); y = fixed2int_pixround(draw_rect.p.y); w = fixed2int_pixround(draw_rect.q.x) - x; h = fixed2int_pixround(draw_rect.q.y) - y; if (w > 0 && h > 0) if (gx_fill_rectangle(x, y, w, h, pdc, pgs) < 0) goto slow; } } return 0; slow:rlist = pr + i; rcount = count - i; } { bool do_save = !gx_path_is_null(pgs->path); if (do_save) { if ((code = gs_gsave(pgs)) < 0) return code; gs_newpath(pgs); } if ((code = gs_rectappend(pgs, rlist, rcount)) < 0 || (code = gs_fill(pgs)) < 0 ) DO_NOTHING; if (do_save) gs_grestore(pgs); else if (code < 0) gs_newpath(pgs); } return code; }