/* Copyright (C) 1999, 2000, 2001 Aladdin Enterprises. All rights reserved. This software is provided AS-IS with no warranty, either express or implied. This software is distributed under license and may not be copied, modified or distributed except as expressly authorized under the terms of the license contained in the file LICENSE in this distribution. For more information about licensing, please refer to http://www.ghostscript.com/licensing/. For information on commercial licensing, go to http://www.artifex.com/licensing/ or contact Artifex Software, Inc., 101 Lucas Valley Road #110, San Rafael, CA 94903, U.S.A., +1(415)492-9861. */ /* $Id: gdevpdfg.c,v 1.68 2005/09/12 11:34:50 leonardo Exp $ */ /* Graphics state management for pdfwrite driver */ #include "math_.h" #include "string_.h" #include "memory_.h" #include "gx.h" #include "gserrors.h" #include "gsfunc0.h" #include "gsstate.h" #include "gxbitmap.h" /* for gxhttile.h in gzht.h */ #include "gxdht.h" #include "gxfarith.h" /* for gs_sin/cos_degrees */ #include "gxfmap.h" #include "gxht.h" #include "gxistate.h" #include "gxdcolor.h" #include "gxpcolor.h" #include "gsptype2.h" #include "gzht.h" #include "gdevpdfx.h" #include "gdevpdfg.h" #include "gdevpdfo.h" #include "szlibx.h" /* ---------------- Miscellaneous ---------------- */ /* Save the viewer's graphic state. */ int pdf_save_viewer_state(gx_device_pdf *pdev, stream *s) { const int i = pdev->vgstack_depth; if (pdev->vgstack_depth >= count_of(pdev->vgstack)) return_error(gs_error_unregistered); /* Must not happen. */ pdev->vgstack[i].transfer_ids[0] = pdev->transfer_ids[0]; pdev->vgstack[i].transfer_ids[1] = pdev->transfer_ids[1]; pdev->vgstack[i].transfer_ids[2] = pdev->transfer_ids[2]; pdev->vgstack[i].transfer_ids[3] = pdev->transfer_ids[3]; pdev->vgstack[i].transfer_not_identity = pdev->transfer_not_identity; pdev->vgstack[i].opacity_alpha = pdev->state.opacity.alpha; pdev->vgstack[i].shape_alpha = pdev->state.shape.alpha; pdev->vgstack[i].blend_mode = pdev->state.blend_mode; pdev->vgstack[i].halftone_id = pdev->halftone_id; pdev->vgstack[i].black_generation_id = pdev->black_generation_id; pdev->vgstack[i].undercolor_removal_id = pdev->undercolor_removal_id; pdev->vgstack[i].overprint_mode = pdev->overprint_mode; pdev->vgstack[i].smoothness = pdev->state.smoothness; pdev->vgstack[i].flatness = pdev->state.flatness; pdev->vgstack[i].text_knockout = pdev->state.text_knockout; pdev->vgstack[i].fill_overprint = pdev->fill_overprint; pdev->vgstack[i].stroke_overprint = pdev->stroke_overprint; pdev->vgstack[i].stroke_adjust = pdev->state.stroke_adjust; pdev->vgstack[i].fill_used_process_color = pdev->fill_used_process_color; pdev->vgstack[i].stroke_used_process_color = pdev->stroke_used_process_color; pdev->vgstack[i].saved_fill_color = pdev->saved_fill_color; pdev->vgstack[i].saved_stroke_color = pdev->saved_stroke_color; pdev->vgstack[i].line_params = pdev->state.line_params; pdev->vgstack[i].line_params.dash.pattern = 0; /* Use pdev->dash_pattern instead. */ memcpy(pdev->vgstack[i].dash_pattern, pdev->dash_pattern, sizeof(pdev->vgstack[i].dash_pattern)); pdev->vgstack_depth++; if (s) stream_puts(s, "q\n"); return 0; } /* Load the viewer's graphic state. */ private void pdf_load_viewer_state(gx_device_pdf *pdev, pdf_viewer_state *s) { pdev->transfer_ids[0] = s->transfer_ids[0]; pdev->transfer_ids[1] = s->transfer_ids[1]; pdev->transfer_ids[2] = s->transfer_ids[2]; pdev->transfer_ids[3] = s->transfer_ids[3]; pdev->transfer_not_identity = s->transfer_not_identity; pdev->state.opacity.alpha = s->opacity_alpha; pdev->state.shape.alpha = s->shape_alpha; pdev->state.blend_mode = s->blend_mode; pdev->halftone_id = s->halftone_id; pdev->black_generation_id = s->black_generation_id; pdev->undercolor_removal_id = s->undercolor_removal_id; pdev->overprint_mode = s->overprint_mode; pdev->state.smoothness = s->smoothness; pdev->state.flatness = s->flatness; pdev->state.text_knockout = s->text_knockout; pdev->fill_overprint = s->fill_overprint; pdev->stroke_overprint = s->stroke_overprint; pdev->state.stroke_adjust = s->stroke_adjust; pdev->fill_used_process_color = s->fill_used_process_color; pdev->stroke_used_process_color = s->stroke_used_process_color; pdev->saved_fill_color = s->saved_fill_color; pdev->saved_stroke_color = s->saved_stroke_color; pdev->state.line_params = s->line_params; memcpy(pdev->dash_pattern, s->dash_pattern, sizeof(s->dash_pattern)); } /* Restore the viewer's graphic state. */ int pdf_restore_viewer_state(gx_device_pdf *pdev, stream *s) { const int i = --pdev->vgstack_depth; if (i < pdev->vgstack_bottom || i < 0) return_error(gs_error_unregistered); /* Must not happen. */ if (s) stream_puts(s, "Q\n"); pdf_load_viewer_state(pdev, pdev->vgstack + i); return 0; } /* Set initial color. */ void pdf_set_initial_color(gx_device_pdf * pdev, gx_hl_saved_color *saved_fill_color, gx_hl_saved_color *saved_stroke_color, bool *fill_used_process_color, bool *stroke_used_process_color) { gx_device_color black; pdev->black = gx_device_black((gx_device *)pdev); pdev->white = gx_device_white((gx_device *)pdev); set_nonclient_dev_color(&black, pdev->black); gx_hld_save_color(NULL, &black, saved_fill_color); gx_hld_save_color(NULL, &black, saved_stroke_color); *fill_used_process_color = true; *stroke_used_process_color = true; } /* Prepare intitial values for viewer's graphics state parameters. */ private void pdf_viewer_state_from_imager_state_aux(pdf_viewer_state *pvs, const gs_imager_state *pis) { pvs->transfer_not_identity = (pis->set_transfer.red != NULL ? pis->set_transfer.red->proc != gs_identity_transfer : 0) * 1 + (pis->set_transfer.green != NULL ? pis->set_transfer.green->proc != gs_identity_transfer : 0) * 2 + (pis->set_transfer.blue != NULL ? pis->set_transfer.blue->proc != gs_identity_transfer : 0) * 4 + (pis->set_transfer.gray != NULL ? pis->set_transfer.gray->proc != gs_identity_transfer : 0) * 8; pvs->transfer_ids[0] = (pis->set_transfer.red != NULL ? pis->set_transfer.red->id : 0); pvs->transfer_ids[1] = (pis->set_transfer.green != NULL ? pis->set_transfer.green->id : 0); pvs->transfer_ids[2] = (pis->set_transfer.blue != NULL ? pis->set_transfer.blue->id : 0); pvs->transfer_ids[3] = (pis->set_transfer.gray != NULL ? pis->set_transfer.gray->id : 0); pvs->opacity_alpha = pis->opacity.alpha; pvs->shape_alpha = pis->shape.alpha; pvs->blend_mode = pis->blend_mode; pvs->halftone_id = (pis->dev_ht != 0 ? pis->dev_ht->id : 0); pvs->black_generation_id = (pis->black_generation != 0 ? pis->black_generation->id : 0); pvs->undercolor_removal_id = (pis->undercolor_removal != 0 ? pis->undercolor_removal->id : 0); pvs->overprint_mode = 0; pvs->smoothness = pis->smoothness; pvs->text_knockout = pis->text_knockout; pvs->fill_overprint = false; pvs->stroke_overprint = false; pvs->stroke_adjust = false; pvs->line_params.half_width = 0.5; pvs->line_params.cap = 0; pvs->line_params.join = 0; pvs->line_params.curve_join = 0; pvs->line_params.miter_limit = 10.0; pvs->line_params.miter_check = 0; pvs->line_params.dot_length = pis->line_params.dot_length; pvs->line_params.dot_length_absolute = pis->line_params.dot_length_absolute; pvs->line_params.dot_orientation = pis->line_params.dot_orientation; memset(&pvs->line_params.dash, 0 , sizeof(pvs->line_params.dash)); memset(pvs->dash_pattern, 0, sizeof(pvs->dash_pattern)); } /* Copy viewer state from images state. */ void pdf_viewer_state_from_imager_state(gx_device_pdf * pdev, const gs_imager_state *pis, const gx_device_color *pdevc) { pdf_viewer_state vs; pdf_viewer_state_from_imager_state_aux(&vs, pis); gx_hld_save_color(pis, pdevc, &vs.saved_fill_color); gx_hld_save_color(pis, pdevc, &vs.saved_stroke_color); pdf_load_viewer_state(pdev, &vs); } /* Prepare intitial values for viewer's graphics state parameters. */ void pdf_prepare_initial_viewer_state(gx_device_pdf * pdev, const gs_imager_state *pis) { /* Parameter values, which are specified in PDF spec, are set here. * Parameter values, which are specified in PDF spec as "installation dependent", * are set here to intial values used with PS interpreter. * This allows to write differences to the output file * and skip initial values. */ pdf_set_initial_color(pdev, &pdev->vg_initial.saved_fill_color, &pdev->vg_initial.saved_stroke_color, &pdev->vg_initial.fill_used_process_color, &pdev->vg_initial.stroke_used_process_color); pdf_viewer_state_from_imager_state_aux(&pdev->vg_initial, pis); pdev->vg_initial_set = true; /* * Some parameters listed in PDF spec are missed here : * text state - it is initialized per page. * rendering intent - not sure why, fixme. */ } /* Reset the graphics state parameters to initial values. */ /* Used if pdf_prepare_initial_viewer_state was not callad. */ private void pdf_reset_graphics_old(gx_device_pdf * pdev) { pdf_set_initial_color(pdev, &pdev->saved_fill_color, &pdev->saved_stroke_color, &pdev->fill_used_process_color, &pdev->stroke_used_process_color); pdev->state.flatness = -1; { static const gx_line_params lp_initial = { gx_line_params_initial }; pdev->state.line_params = lp_initial; } pdev->fill_overprint = false; pdev->stroke_overprint = false; pdf_reset_text(pdev); } /* Reset the graphics state parameters to initial values. */ void pdf_reset_graphics(gx_device_pdf * pdev) { if (pdev->vg_initial_set) pdf_load_viewer_state(pdev, &pdev->vg_initial); else pdf_reset_graphics_old(pdev); pdf_reset_text(pdev); } /* Write client color. */ private int pdf_write_ccolor(gx_device_pdf * pdev, const gs_imager_state * pis, const gs_client_color *pcc) { int i, n = gx_hld_get_number_color_components(pis); pprintg1(pdev->strm, "%g", psdf_round(pcc->paint.values[0], 255, 8)); for (i = 1; i < n; i++) { pprintg1(pdev->strm, " %g", psdf_round(pcc->paint.values[i], 255, 8)); } return 0; } /* Set the fill or stroke color. */ private int pdf_reset_color(gx_device_pdf * pdev, const gs_imager_state * pis, const gx_drawing_color *pdc, gx_hl_saved_color * psc, bool *used_process_color, const psdf_set_color_commands_t *ppscc) { int code; gx_hl_saved_color temp; bool process_color; const gs_color_space *pcs, *pcs2; const gs_client_color *pcc; /* fixme: not needed due to gx_hld_get_color_component. */ cos_value_t cs_value; const char *command; int code1 = 0; gs_color_space_index csi; if (pdev->skip_colors) return 0; process_color = !gx_hld_save_color(pis, pdc, &temp); /* Since pdfwrite never applies halftones and patterns, but monitors * halftone/pattern IDs separately, we don't need to compare * halftone/pattern bodies here. */ if (gx_hld_saved_color_equal(&temp, psc)) return 0; /* * In principle, we can set colors in either stream or text * context. However, since we currently enclose all text * strings inside a gsave/grestore, this causes us to lose * track of the color when we leave text context. Therefore, * we require stream context for setting colors. */ code = pdf_open_page(pdev, PDF_IN_STREAM); if (code < 0) return code; switch (gx_hld_get_color_space_and_ccolor(pis, pdc, &pcs, &pcc)) { case non_pattern_color_space: switch (gs_color_space_get_index(pcs)) { case gs_color_space_index_DeviceGray: command = ppscc->setgray; break; case gs_color_space_index_DeviceRGB: command = ppscc->setrgbcolor; break; case gs_color_space_index_DeviceCMYK: command = ppscc->setcmykcolor; break; case gs_color_space_index_Indexed: if (pdev->CompatibilityLevel <= 1.2) { pcs2 = (const gs_color_space *)&pcs->params.indexed.base_space; csi = gs_color_space_get_index(pcs2); if (csi == gs_color_space_index_Separation) { pcs2 = (const gs_color_space *)&pcs2->params.separation.alt_space; goto check_pcs2; } goto check_pcs2; } goto scn; case gs_color_space_index_Separation: if (pdev->CompatibilityLevel <= 1.2) { pcs2 = (const gs_color_space *)&pcs->params.separation.alt_space; check_pcs2: csi = gs_color_space_get_index(pcs2); switch(gs_color_space_get_index(pcs2)) { case gs_color_space_index_DevicePixel : case gs_color_space_index_DeviceN: case gs_color_space_index_CIEICC: goto write_process_color; default: DO_NOTHING; } } goto scn; case gs_color_space_index_CIEICC: case gs_color_space_index_DevicePixel: case gs_color_space_index_DeviceN: if (pdev->CompatibilityLevel <= 1.2) goto write_process_color; goto scn; default : scn: command = ppscc->setcolorn; if (!gx_hld_saved_color_same_cspace(&temp, psc)) { code = pdf_color_space(pdev, &cs_value, NULL, pcs, &pdf_color_space_names, true); /* fixme : creates redundant PDF objects. */ if (code == gs_error_rangecheck) { /* The color space can't write to PDF. */ goto write_process_color; } if (code < 0) return code; code = cos_value_write(&cs_value, pdev); if (code < 0) return code; pprints1(pdev->strm, " %s\n", ppscc->setcolorspace); } else if (*used_process_color) goto write_process_color; break; } *used_process_color = false; code = pdf_write_ccolor(pdev, pis, pcc); if (code < 0) return code; pprints1(pdev->strm, " %s\n", command); break; case pattern_color_sapce: { pdf_resource_t *pres; if (pdc->type == gx_dc_type_pattern) code = pdf_put_colored_pattern(pdev, pdc, pcs, ppscc, pis->have_pattern_streams, &pres); else if (pdc->type == &gx_dc_pure_masked) { code = pdf_put_uncolored_pattern(pdev, pdc, pcs, ppscc, pis->have_pattern_streams, &pres); if (code < 0 || pres == 0) return code; if (pis->have_pattern_streams) code = pdf_write_ccolor(pdev, pis, pcc); } else if (pdc->type == &gx_dc_pattern2) { if (pdev->CompatibilityLevel <= 1.2) return_error(gs_error_rangecheck); code1 = pdf_put_pattern2(pdev, pdc, ppscc, &pres); } else return_error(gs_error_rangecheck); if (code < 0) return code; cos_value_write(cos_resource_value(&cs_value, pres->object), pdev); pprints1(pdev->strm, " %s\n", ppscc->setcolorn); code = pdf_add_resource(pdev, pdev->substream_Resources, "/Pattern", pres); if (code < 0) return code; } *used_process_color = false; break; default: /* must not happen. */ case use_process_color: write_process_color: code = psdf_set_color((gx_device_vector *)pdev, pdc, ppscc); if (code < 0) return code; *used_process_color = true; } *psc = temp; return code1; } int pdf_set_drawing_color(gx_device_pdf * pdev, const gs_imager_state * pis, const gx_drawing_color *pdc, gx_hl_saved_color * psc, bool *used_process_color, const psdf_set_color_commands_t *ppscc) { return pdf_reset_color(pdev, pis, pdc, psc, used_process_color, ppscc); } int pdf_set_pure_color(gx_device_pdf * pdev, gx_color_index color, gx_hl_saved_color * psc, bool *used_process_color, const psdf_set_color_commands_t *ppscc) { gx_drawing_color dcolor; set_nonclient_dev_color(&dcolor, color); return pdf_reset_color(pdev, NULL, &dcolor, psc, used_process_color, ppscc); } /* * Convert a string into cos name. */ int pdf_string_to_cos_name(gx_device_pdf *pdev, const byte *str, uint len, cos_value_t *pvalue) { byte *chars = gs_alloc_string(pdev->pdf_memory, len + 1, "pdf_string_to_cos_name"); if (chars == 0) return_error(gs_error_VMerror); chars[0] = '/'; memcpy(chars + 1, str, len); cos_string_value(pvalue, chars, len + 1); return 0; } /* ---------------- Graphics state updating ---------------- */ /* ------ Functions ------ */ /* Define the maximum size of a Function reference. */ #define MAX_FN_NAME_CHARS 9 /* /Default, /Identity */ #define MAX_FN_CHARS max(MAX_REF_CHARS + 4, MAX_FN_NAME_CHARS) /* * Create and write a Function for a gx_transfer_map. We use this for * transfer, BG, and UCR functions. If check_identity is true, check for * an identity map. Return 1 if the map is the identity map, otherwise * return 0. */ private data_source_proc_access(transfer_map_access); /* check prototype */ private int transfer_map_access(const gs_data_source_t *psrc, ulong start, uint length, byte *buf, const byte **ptr) { const gx_transfer_map *map = (const gx_transfer_map *)psrc->data.str.data; uint i; if (ptr) *ptr = buf; for (i = 0; i < length; ++i) buf[i] = frac2byte(map->values[(uint)start + i]); return 0; } private int transfer_map_access_signed(const gs_data_source_t *psrc, ulong start, uint length, byte *buf, const byte **ptr) { /* To prevent numeric errors, we need to map 0 to an integer. * We can't apply a general expression, because Decode isn't accessible here. * Assuming this works for UCR only. * Assuming the range of UCR is always [-1, 1]. * Assuming BitsPerSample = 8. */ const gx_transfer_map *map = (const gx_transfer_map *)psrc->data.str.data; uint i; *ptr = buf; for (i = 0; i < length; ++i) buf[i] = (byte) ((frac2float(map->values[(uint)start + i]) + 1) * 127); return 0; } private int pdf_write_transfer_map(gx_device_pdf *pdev, const gx_transfer_map *map, int range0, bool check_identity, const char *key, char *ids) { gs_memory_t *mem = pdev->pdf_memory; gs_function_Sd_params_t params; static const float domain01[2] = { 0, 1 }; static const int size = transfer_map_size; float range01[2], decode[2]; gs_function_t *pfn; long id; int code; if (map == 0) { *ids = 0; /* no map */ return 1; } if (check_identity) { /* Check for an identity map. */ int i; if (map->proc == gs_identity_transfer) i = transfer_map_size; else for (i = 0; i < transfer_map_size; ++i) { fixed d = map->values[i] - bits2frac(i, log2_transfer_map_size); if (any_abs(d) > fixed_epsilon) /* ignore small noise */ break; } if (i == transfer_map_size) { strcpy(ids, key); strcat(ids, "/Identity"); return 1; } } params.m = 1; params.Domain = domain01; params.n = 1; range01[0] = (float)range0, range01[1] = 1.0; params.Range = range01; params.Order = 1; params.DataSource.access = (range0 < 0 ? transfer_map_access_signed : transfer_map_access); params.DataSource.data.str.data = (const byte *)map; /* bogus */ /* DataSource */ params.BitsPerSample = 8; /* could be 16 */ params.Encode = 0; if (range01[0] < 0 && range01[1] > 0) { /* This works for UCR only. * Map 0 to an integer. * Rather the range of UCR is always [-1, 1], * we prefer a general expression. */ int r0 = (int)( -range01[0] * ((1 << params.BitsPerSample) - 1) / (range01[1] - range01[0]) ); /* Round down. */ float r1 = r0 * range01[1] / -range01[0]; /* r0 + r1 <= (1 << params.BitsPerSample) - 1 */ decode[0] = range01[0]; decode[1] = range01[0] + (range01[1] - range01[0]) * ((1 << params.BitsPerSample) - 1) / (r0 + r1); params.Decode = decode; } else params.Decode = 0; params.Size = &size; code = gs_function_Sd_init(&pfn, ¶ms, mem); if (code < 0) return code; code = pdf_write_function(pdev, pfn, &id); gs_function_free(pfn, false, mem); if (code < 0) return code; sprintf(ids, "%s%s%ld 0 R", key, (key[0] && key[0] != ' ' ? " " : ""), id); return 0; } private int pdf_write_transfer(gx_device_pdf *pdev, const gx_transfer_map *map, const char *key, char *ids) { return pdf_write_transfer_map(pdev, map, 0, true, key, ids); } /* ------ Halftones ------ */ /* * Recognize the predefined PDF halftone functions. Note that because the * corresponding PostScript functions use single-precision floats, the * functions used for testing must do the same in order to get identical * results. Currently we only do this for a few of the functions. */ #define HT_FUNC(name, expr)\ private floatp name(floatp xd, floatp yd) {\ float x = (float)xd, y = (float)yd;\ return d2f(expr);\ } /* * In most versions of gcc (e.g., 2.7.2.3, 2.95.4), return (float)xxx * doesn't actually do the coercion. Force this here. Note that if we * use 'inline', it doesn't work. */ private float d2f(floatp d) { float f = (float)d; return f; } private floatp ht_Round(floatp xf, floatp yf) { float x = (float)xf, y = (float)yf; float xabs = fabs(x), yabs = fabs(y); if (d2f(xabs + yabs) <= 1) return d2f(1 - d2f(d2f(x * x) + d2f(y * y))); xabs -= 1, yabs -= 1; return d2f(d2f(d2f(xabs * xabs) + d2f(yabs * yabs)) - 1); } private floatp ht_Diamond(floatp xf, floatp yf) { float x = (float)xf, y = (float)yf; float xabs = fabs(x), yabs = fabs(y); if (d2f(xabs + yabs) <= 0.75) return d2f(1 - d2f(d2f(x * x) + d2f(y * y))); if (d2f(xabs + yabs) <= d2f(1.23)) return d2f(1 - d2f(d2f(d2f(0.85) * xabs) + yabs)); xabs -= 1, yabs -= 1; return d2f(d2f(d2f(xabs * xabs) + d2f(yabs * yabs)) - 1); } private floatp ht_Ellipse(floatp xf, floatp yf) { float x = (float)xf, y = (float)yf; float xabs = fabs(x), yabs = fabs(y); /* * The PDF Reference, 2nd edition, incorrectly specifies the * computation w = 4 * |x| + 3 * |y| - 3. The PostScript code in the * same book correctly implements w = 3 * |x| + 4 * |y| - 3. */ float w = (float)(d2f(d2f(3 * xabs) + d2f(4 * yabs)) - 3); if (w < 0) { yabs /= 0.75; return d2f(1 - d2f((d2f(x * x) + d2f(yabs * yabs)) / 4)); } if (w > 1) { xabs = 1 - xabs, yabs = d2f(1 - yabs) / 0.75; return d2f(d2f((d2f(xabs * xabs) + d2f(yabs * yabs)) / 4) - 1); } return d2f(0.5 - w); } /* * Most of these are recognized properly even without d2f. We've only * added d2f where it apparently makes a difference. */ private float d2fsin_d(double x) { return d2f(gs_sin_degrees(d2f(x))); } private float d2fcos_d(double x) { return d2f(gs_cos_degrees(d2f(x))); } HT_FUNC(ht_EllipseA, 1 - (x * x + 0.9 * y * y)) HT_FUNC(ht_InvertedEllipseA, x * x + 0.9 * y * y - 1) HT_FUNC(ht_EllipseB, 1 - sqrt(x * x + 0.625 * y * y)) HT_FUNC(ht_EllipseC, 1 - (0.9 * x * x + y * y)) HT_FUNC(ht_InvertedEllipseC, 0.9 * x * x + y * y - 1) HT_FUNC(ht_Line, -fabs((x - x) + y)) /* quiet compiler (unused variable x) */ HT_FUNC(ht_LineX, (y - y) + x) /* quiet compiler (unused variable y) */ HT_FUNC(ht_LineY, (x - x) + y) /* quiet compiler (unused variable x) */ HT_FUNC(ht_Square, -max(fabs(x), fabs(y))) HT_FUNC(ht_Cross, -min(fabs(x), fabs(y))) HT_FUNC(ht_Rhomboid, (0.9 * fabs(x) + fabs(y)) / 2) HT_FUNC(ht_DoubleDot, (d2fsin_d(x * 360) + d2fsin_d(y * 360)) / 2) HT_FUNC(ht_InvertedDoubleDot, -(d2fsin_d(x * 360) + d2fsin_d(y * 360)) / 2) HT_FUNC(ht_SimpleDot, 1 - d2f(d2f(x * x) + d2f(y * y))) HT_FUNC(ht_InvertedSimpleDot, d2f(d2f(x * x) + d2f(y * y)) - 1) HT_FUNC(ht_CosineDot, (d2fcos_d(x * 180) + d2fcos_d(y * 180)) / 2) HT_FUNC(ht_Double, (d2fsin_d(x * 180) + d2fsin_d(y * 360)) / 2) HT_FUNC(ht_InvertedDouble, -(d2fsin_d(x * 180) + d2fsin_d(y * 360)) / 2) typedef struct ht_function_s { const char *fname; floatp (*proc)(floatp, floatp); } ht_function_t; private const ht_function_t ht_functions[] = { {"Round", ht_Round}, {"Diamond", ht_Diamond}, {"Ellipse", ht_Ellipse}, {"EllipseA", ht_EllipseA}, {"InvertedEllipseA", ht_InvertedEllipseA}, {"EllipseB", ht_EllipseB}, {"EllipseC", ht_EllipseC}, {"InvertedEllipseC", ht_InvertedEllipseC}, {"Line", ht_Line}, {"LineX", ht_LineX}, {"LineY", ht_LineY}, {"Square", ht_Square}, {"Cross", ht_Cross}, {"Rhomboid", ht_Rhomboid}, {"DoubleDot", ht_DoubleDot}, {"InvertedDoubleDot", ht_InvertedDoubleDot}, {"SimpleDot", ht_SimpleDot}, {"InvertedSimpleDot", ht_InvertedSimpleDot}, {"CosineDot", ht_CosineDot}, {"Double", ht_Double}, {"InvertedDouble", ht_InvertedDouble} }; /* Write each kind of halftone. */ private int pdf_write_spot_function(gx_device_pdf *pdev, const gx_ht_order *porder, long *pid) { /****** DOESN'T HANDLE STRIP HALFTONES ******/ int w = porder->width, h = porder->height; uint num_bits = porder->num_bits; gs_function_Sd_params_t params; static const float domain_spot[4] = { -1, 1, -1, 1 }; static const float range_spot[4] = { -1, 1 }; int size[2]; gs_memory_t *mem = pdev->pdf_memory; /* * Even though the values are logically ushort, we must always store * them in big-endian order, so we access them as bytes. */ byte *values; gs_function_t *pfn; uint i; int code = 0; params.m = 2; params.Domain = domain_spot; params.n = 1; params.Range = range_spot; params.Order = 0; /* default */ /* * We could use 8, 16, or 32 bits per sample to save space, but for * simplicity, we always use 16. */ if (num_bits > 0x10000) return_error(gs_error_rangecheck); params.BitsPerSample = 16; params.Encode = 0; /* * The default Decode array maps the actual data values [1 .. w*h] to a * sub-interval of the Range, but that's OK, since all that matters is * the relative values, not the absolute values. */ params.Decode = 0; size[0] = w; size[1] = h; params.Size = size; /* Create the (temporary) threshold array. */ values = gs_alloc_byte_array(mem, num_bits, 2, "pdf_write_spot_function"); if (values == 0) return_error(gs_error_VMerror); for (i = 0; i < num_bits; ++i) { gs_int_point pt; int value; if ((code = porder->procs->bit_index(porder, i, &pt)) < 0) break; value = pt.y * w + pt.x; /* Always store the values in big-endian order. */ values[i * 2] = (byte)(value >> 8); values[i * 2 + 1] = (byte)value; } data_source_init_bytes(¶ms.DataSource, (const byte *)values, sizeof(*values) * num_bits); if (code >= 0 && (code = gs_function_Sd_init(&pfn, ¶ms, mem)) >= 0 ) { code = pdf_write_function(pdev, pfn, pid); gs_function_free(pfn, false, mem); } gs_free_object(mem, values, "pdf_write_spot_function"); return code; } private int pdf_write_spot_halftone(gx_device_pdf *pdev, const gs_spot_halftone *psht, const gx_ht_order *porder, long *pid) { char trs[17 + MAX_FN_CHARS + 1]; int code = pdf_write_transfer(pdev, porder->transfer, "/TransferFunction", trs); long id, spot_id; stream *s; int i = countof(ht_functions); gs_memory_t *mem = pdev->pdf_memory; if (code < 0) return code; /* * See if we can recognize the spot function, by comparing its sampled * values against those in the order. */ { gs_screen_enum senum; gx_ht_order order; int code; order = *porder; code = gs_screen_order_alloc(&order, mem); if (code < 0) goto notrec; for (i = 0; i < countof(ht_functions); ++i) { floatp (*spot_proc)(floatp, floatp) = ht_functions[i].proc; gs_point pt; gs_screen_enum_init_memory(&senum, &order, NULL, &psht->screen, mem); while ((code = gs_screen_currentpoint(&senum, &pt)) == 0 && gs_screen_next(&senum, spot_proc(pt.x, pt.y)) >= 0) DO_NOTHING; if (code < 0) continue; /* Compare the bits and levels arrays. */ if (memcmp(order.levels, porder->levels, order.num_levels * sizeof(*order.levels))) continue; if (memcmp(order.bit_data, porder->bit_data, order.num_bits * porder->procs->bit_data_elt_size)) continue; /* We have a match. */ break; } gx_ht_order_release(&order, mem, false); } notrec: if (i == countof(ht_functions)) { /* Create and write a Function for the spot function. */ pdf_write_spot_function(pdev, porder, &spot_id); } *pid = id = pdf_begin_separate(pdev); s = pdev->strm; /* Use the original, requested frequency and angle. */ pprintg2(s, "<screen.frequency, psht->screen.angle); if (i < countof(ht_functions)) pprints1(s, "/SpotFunction/%s", ht_functions[i].fname); else pprintld1(s, "/SpotFunction %ld 0 R", spot_id); stream_puts(s, trs); if (psht->accurate_screens) stream_puts(s, "/AccurateScreens true"); stream_puts(s, ">>\n"); return pdf_end_separate(pdev); } private int pdf_write_screen_halftone(gx_device_pdf *pdev, const gs_screen_halftone *psht, const gx_ht_order *porder, long *pid) { gs_spot_halftone spot; spot.screen = *psht; spot.accurate_screens = false; spot.transfer = 0; spot.transfer_closure.proc = 0; return pdf_write_spot_halftone(pdev, &spot, porder, pid); } private int pdf_write_colorscreen_halftone(gx_device_pdf *pdev, const gs_colorscreen_halftone *pcsht, const gx_device_halftone *pdht, long *pid) { int i; stream *s; long ht_ids[4]; for (i = 0; i < pdht->num_comp ; ++i) { int code = pdf_write_screen_halftone(pdev, &pcsht->screens.indexed[i], &pdht->components[i].corder, &ht_ids[i]); if (code < 0) return code; } *pid = pdf_begin_separate(pdev); s = pdev->strm; /* Use Black, Gray as the Default unless we are in RGB colormodel */ /* (num_comp < 4) in which case we use Green (arbitrarily) */ pprintld1(s, "<num_comp > 3 ? ht_ids[3] : ht_ids[1]); pprintld2(s, "/Red %ld 0 R/Cyan %ld 0 R", ht_ids[0], ht_ids[0]); pprintld2(s, "/Green %ld 0 R/Magenta %ld 0 R", ht_ids[1], ht_ids[1]); pprintld2(s, "/Blue %ld 0 R/Yellow %ld 0 R", ht_ids[2], ht_ids[2]); if (pdht->num_comp > 3) pprintld2(s, "/Gray %ld 0 R/Black %ld 0 R", ht_ids[3], ht_ids[3]); stream_puts(s, ">>\n"); return pdf_end_separate(pdev); } #define CHECK(expr)\ BEGIN if ((code = (expr)) < 0) return code; END private int pdf_write_threshold_halftone(gx_device_pdf *pdev, const gs_threshold_halftone *ptht, const gx_ht_order *porder, long *pid) { char trs[17 + MAX_FN_CHARS + 1]; stream *s; pdf_data_writer_t writer; int code = pdf_write_transfer(pdev, porder->transfer, "", trs); if (code < 0) return code; CHECK(pdf_begin_data(pdev, &writer)); s = pdev->strm; *pid = writer.pres->object->id; CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/Type", "/Halftone")); CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/HalftoneType", "6")); CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Width", ptht->width)); CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Height", ptht->height)); if (*trs != 0) CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/TransferFunction", trs)); stream_write(writer.binary.strm, ptht->thresholds.data, ptht->thresholds.size); return pdf_end_data(&writer); } private int pdf_write_threshold2_halftone(gx_device_pdf *pdev, const gs_threshold2_halftone *ptht, const gx_ht_order *porder, long *pid) { char trs[17 + MAX_FN_CHARS + 1]; stream *s; pdf_data_writer_t writer; int code = pdf_write_transfer(pdev, porder->transfer, "/TransferFunction", trs); if (code < 0) return code; CHECK(pdf_begin_data(pdev, &writer)); s = pdev->strm; *pid = writer.pres->object->id; CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/Type", "/Halftone")); CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/HalftoneType", "16")); CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Width", ptht->width)); CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Height", ptht->height)); if (ptht->width2 && ptht->height2) { CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Width2", ptht->width2)); CHECK(cos_dict_put_c_key_int((cos_dict_t *)writer.pres->object, "/Height2", ptht->height2)); } if (*trs != 0) CHECK(cos_dict_put_c_strings((cos_dict_t *)writer.pres->object, "/TransferFunction", trs)); s = writer.binary.strm; if (ptht->bytes_per_sample == 2) stream_write(s, ptht->thresholds.data, ptht->thresholds.size); else { /* Expand 1-byte to 2-byte samples. */ int i; for (i = 0; i < ptht->thresholds.size; ++i) { byte b = ptht->thresholds.data[i]; stream_putc(s, b); stream_putc(s, b); } } return pdf_end_data(&writer); } private int pdf_get_halftone_component_index(const gs_multiple_halftone *pmht, const gx_device_halftone *pdht, int dht_index) { int j; for (j = 0; j < pmht->num_comp; j++) if (pmht->components[j].comp_number == dht_index) break; if (j == pmht->num_comp) { /* Look for Default. */ for (j = 0; j < pmht->num_comp; j++) if (pmht->components[j].comp_number == GX_DEVICE_COLOR_MAX_COMPONENTS) break; if (j == pmht->num_comp) return_error(gs_error_undefined); } return j; } private int pdf_write_multiple_halftone(gx_device_pdf *pdev, const gs_multiple_halftone *pmht, const gx_device_halftone *pdht, long *pid) { stream *s; int i, code, last_comp = 0; gs_memory_t *mem = pdev->pdf_memory; long *ids; bool done_Default = false; ids = (long *)gs_alloc_byte_array(mem, pmht->num_comp, sizeof(long), "pdf_write_multiple_halftone"); if (ids == 0) return_error(gs_error_VMerror); for (i = 0; i < pdht->num_comp; ++i) { const gs_halftone_component *phtc; const gx_ht_order *porder; code = pdf_get_halftone_component_index(pmht, pdht, i); if (code < 0) return code; if (pmht->components[code].comp_number == GX_DEVICE_COLOR_MAX_COMPONENTS) { if (done_Default) continue; done_Default = true; } phtc = &pmht->components[code]; porder = (pdht->components == 0 ? &pdht->order : &pdht->components[i].corder); switch (phtc->type) { case ht_type_spot: code = pdf_write_spot_halftone(pdev, &phtc->params.spot, porder, &ids[i]); break; case ht_type_threshold: code = pdf_write_threshold_halftone(pdev, &phtc->params.threshold, porder, &ids[i]); break; case ht_type_threshold2: code = pdf_write_threshold2_halftone(pdev, &phtc->params.threshold2, porder, &ids[i]); break; default: code = gs_note_error(gs_error_rangecheck); } if (code < 0) { gs_free_object(mem, ids, "pdf_write_multiple_halftone"); return code; } } *pid = pdf_begin_separate(pdev); s = pdev->strm; stream_puts(s, "<num_comp; ++i) { const gs_halftone_component *phtc; byte *str; uint len; cos_value_t value; code = pdf_get_halftone_component_index(pmht, pdht, i); if (code < 0) return code; if (pmht->components[code].comp_number == GX_DEVICE_COLOR_MAX_COMPONENTS) { if (done_Default) continue; done_Default = true; } phtc = &pmht->components[code]; if ((code = pmht->get_colorname_string(pdev->memory, phtc->cname, &str, &len)) < 0 || (code = pdf_string_to_cos_name(pdev, str, len, &value)) < 0) return code; cos_value_write(&value, pdev); gs_free_string(mem, value.contents.chars.data, value.contents.chars.size, "pdf_write_multiple_halftone"); pprintld1(s, " %ld 0 R\n", ids[i]); last_comp = i; } if (!done_Default) { /* * BOGUS: Type 5 halftones must contain Default component. * Perhaps we have no way to obtain it, * because pdht contains ProcessColorModel components only. * We copy the last component as Default one. */ pprintld1(s, " /Default %ld 0 R\n", ids[last_comp]); } stream_puts(s, ">>\n"); gs_free_object(mem, ids, "pdf_write_multiple_halftone"); return pdf_end_separate(pdev); } /* * Update the halftone. This is a separate procedure only for * readability. */ private int pdf_update_halftone(gx_device_pdf *pdev, const gs_imager_state *pis, char *hts) { const gs_halftone *pht = pis->halftone; const gx_device_halftone *pdht = pis->dev_ht; int code; long id; switch (pht->type) { case ht_type_screen: code = pdf_write_screen_halftone(pdev, &pht->params.screen, &pdht->components[0].corder, &id); break; case ht_type_colorscreen: code = pdf_write_colorscreen_halftone(pdev, &pht->params.colorscreen, pdht, &id); break; case ht_type_spot: code = pdf_write_spot_halftone(pdev, &pht->params.spot, &pdht->components[0].corder, &id); break; case ht_type_threshold: code = pdf_write_threshold_halftone(pdev, &pht->params.threshold, &pdht->components[0].corder, &id); break; case ht_type_threshold2: code = pdf_write_threshold2_halftone(pdev, &pht->params.threshold2, &pdht->components[0].corder, &id); break; case ht_type_multiple: case ht_type_multiple_colorscreen: code = pdf_write_multiple_halftone(pdev, &pht->params.multiple, pdht, &id); break; default: return_error(gs_error_rangecheck); } if (code < 0) return code; sprintf(hts, "%ld 0 R", id); pdev->halftone_id = pis->dev_ht->id; return code; } /* ------ Graphics state updating ------ */ private inline cos_dict_t * resource_dict(pdf_resource_t *pres) { return (cos_dict_t *)pres->object; } /* Open an ExtGState. */ private int pdf_open_gstate(gx_device_pdf *pdev, pdf_resource_t **ppres) { int code; if (*ppres) return 0; /* * We write gs command only in stream context. * If we are clipped, and the clip path is about to change, * the old clipping must be undone before writing gs. */ if (pdev->context != PDF_IN_STREAM) { /* We apparently use gs_error_interrupt as a request to change context. */ return gs_error_interrupt; } code = pdf_alloc_resource(pdev, resourceExtGState, gs_no_id, ppres, -1L); if (code < 0) return code; cos_become((*ppres)->object, cos_type_dict); code = cos_dict_put_c_key_string(resource_dict(*ppres), "/Type", (const byte *)"/ExtGState", 10); if (code < 0) return code; return 0; } /* Finish writing an ExtGState. */ int pdf_end_gstate(gx_device_pdf *pdev, pdf_resource_t *pres) { if (pres) { int code = pdf_substitute_resource(pdev, &pres, resourceExtGState, NULL, true); if (code < 0) return code; code = pdf_open_page(pdev, PDF_IN_STREAM); if (code < 0) return code; code = pdf_add_resource(pdev, pdev->substream_Resources, "/ExtGState", pres); if (code < 0) return code; pprintld1(pdev->strm, "/R%ld gs\n", pdf_resource_id(pres)); pres->where_used |= pdev->used_mask; } return 0; } /* * Update the transfer functions(s). This is a separate procedure only * for readability. */ private int pdf_update_transfer(gx_device_pdf *pdev, const gs_imager_state *pis, char *trs) { int i, pi = -1; bool multiple = false, update = false; gs_id transfer_ids[4]; int code = 0; const gx_transfer_map *tm[4]; tm[0] = pis->set_transfer.red; tm[1] = pis->set_transfer.green; tm[2] = pis->set_transfer.blue; tm[3] = pis->set_transfer.gray; for (i = 0; i < 4; ++i) if (tm[i] != NULL) { transfer_ids[i] = tm[i]->id; if (pdev->transfer_ids[i] != tm[i]->id) update = true; if (pi != -1 && transfer_ids[i] != transfer_ids[pi]) multiple = true; pi = i; } else transfer_ids[i] = -1; if (update) { int mask; if (!multiple) { code = pdf_write_transfer(pdev, tm[pi], "", trs); if (code < 0) return code; mask = code == 0; } else { strcpy(trs, "["); mask = 0; for (i = 0; i < 4; ++i) if (tm[i] != NULL) { code = pdf_write_transfer_map(pdev, tm[i], 0, true, " ", trs + strlen(trs)); if (code < 0) return code; mask |= (code == 0) << i; } strcat(trs, "]"); } memcpy(pdev->transfer_ids, transfer_ids, sizeof(pdev->transfer_ids)); pdev->transfer_not_identity = mask; } return code; } /* * Update the current alpha if necessary. Note that because Ghostscript * stores separate opacity and shape alpha, a rangecheck will occur if * both are different from the current setting. */ private int pdf_update_alpha(gx_device_pdf *pdev, const gs_imager_state *pis, pdf_resource_t **ppres) { bool ais; floatp alpha; int code; if (pdev->state.soft_mask_id != pis->soft_mask_id) { char buf[20]; sprintf(buf, "%ld 0 R", pis->soft_mask_id); code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; code = cos_dict_put_c_key_string(resource_dict(*ppres), "/SMask", (byte *)buf, strlen(buf)); if (code < 0) return code; pdev->state.soft_mask_id = pis->soft_mask_id; } if (pdev->state.opacity.alpha != pis->opacity.alpha) { if (pdev->state.shape.alpha != pis->shape.alpha) return_error(gs_error_rangecheck); ais = false; alpha = pdev->state.opacity.alpha = pis->opacity.alpha; } else if (pdev->state.shape.alpha != pis->shape.alpha) { ais = true; alpha = pdev->state.shape.alpha = pis->shape.alpha; } else return 0; code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; code = cos_dict_put_c_key_bool(resource_dict(*ppres), "/AIS", ais); if (code < 0) return code; /* we never do the 'both' operations (b, B, b*, B*) so we set both */ /* CA and ca the same so that we stay in sync with state.*.alpha */ code = cos_dict_put_c_key_real(resource_dict(*ppres), "/CA", alpha); if (code < 0) return code; return cos_dict_put_c_key_real(resource_dict(*ppres), "/ca", alpha); } /* * Update the graphics subset common to all high-level drawing operations. */ int pdf_prepare_drawing(gx_device_pdf *pdev, const gs_imager_state *pis, pdf_resource_t **ppres) { int code = 0; int bottom; if (pdev->CompatibilityLevel >= 1.4) { if (pdev->state.blend_mode != pis->blend_mode) { static const char *const bm_names[] = { GS_BLEND_MODE_NAMES }; char buf[20]; code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; buf[0] = '/'; strncpy(buf + 1, bm_names[pis->blend_mode], sizeof(buf) - 2); code = cos_dict_put_string_copy(resource_dict(*ppres), "/BM", buf); if (code < 0) return code; pdev->state.blend_mode = pis->blend_mode; } code = pdf_update_alpha(pdev, pis, ppres); if (code < 0) return code; } else { /* * If the graphics state calls for any transparency functions, * we can't represent them, so return a rangecheck. */ if (pis->opacity.alpha != 1 || pis->opacity.mask != 0 || pis->shape.alpha != 1 || pis->shape.mask != 0 || pis->transparency_stack != 0 ) return_error(gs_error_rangecheck); } /* * We originally thought the remaining items were only needed for * fill and stroke, but in fact they are needed for images as well. */ /* * Update halftone, transfer function, black generation, undercolor * removal, halftone phase, overprint mode, smoothness, blend mode, text * knockout. */ bottom = (pdev->ResourcesBeforeUsage ? 1 : 0); /* When ResourcesBeforeUsage != 0, one sbstack element appears from the page contents stream. */ if (pdev->sbstack_depth == bottom) { gs_int_point phase, dev_phase; char hts[5 + MAX_FN_CHARS + 1], trs[5 + MAX_FN_CHARS * 4 + 6 + 1], bgs[5 + MAX_FN_CHARS + 1], ucrs[6 + MAX_FN_CHARS + 1]; hts[0] = trs[0] = bgs[0] = ucrs[0] = 0; if (pdev->params.PreserveHalftoneInfo && pdev->halftone_id != pis->dev_ht->id && !pdev->PDFX ) { code = pdf_update_halftone(pdev, pis, hts); if (code < 0) return code; } if (pdev->params.TransferFunctionInfo == tfi_Preserve && !pdev->PDFX ) { code = pdf_update_transfer(pdev, pis, trs); if (code < 0) return code; } if (pdev->params.UCRandBGInfo == ucrbg_Preserve) { if (pdev->black_generation_id != pis->black_generation->id) { code = pdf_write_transfer_map(pdev, pis->black_generation, 0, false, "", bgs); if (code < 0) return code; pdev->black_generation_id = pis->black_generation->id; } if (pdev->undercolor_removal_id != pis->undercolor_removal->id) { code = pdf_write_transfer_map(pdev, pis->undercolor_removal, -1, false, "", ucrs); if (code < 0) return code; pdev->undercolor_removal_id = pis->undercolor_removal->id; } } if (hts[0] || trs[0] || bgs[0] || ucrs[0]) { code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; } if (hts[0]) { code = cos_dict_put_string_copy(resource_dict(*ppres), "/HT", hts); if (code < 0) return code; } if (trs[0]) { code = cos_dict_put_string_copy(resource_dict(*ppres), "/TR", trs); if (code < 0) return code; } if (bgs[0]) { code = cos_dict_put_string_copy(resource_dict(*ppres), "/BG", bgs); if (code < 0) return code; } if (ucrs[0]) { code = cos_dict_put_string_copy(resource_dict(*ppres), "/UCR", ucrs); if (code < 0) return code; } if (!pdev->PDFX) { gs_currentscreenphase_pis(pis, &phase, 0); gs_currentscreenphase_pis(&pdev->state, &dev_phase, 0); if (dev_phase.x != phase.x || dev_phase.y != phase.y) { char buf[sizeof(int) * 3 + 5]; code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; sprintf(buf, "[%d %d]", phase.x, phase.y); code = cos_dict_put_string_copy(resource_dict(*ppres), "/HTP", buf); if (code < 0) return code; gx_imager_setscreenphase(&pdev->state, phase.x, phase.y, gs_color_select_all); } } } if (pdev->CompatibilityLevel >= 1.3 && pdev->sbstack_depth == bottom) { if (pdev->overprint_mode != pdev->params.OPM) { code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; code = cos_dict_put_c_key_int(resource_dict(*ppres), "/OPM", pdev->params.OPM); if (code < 0) return code; pdev->overprint_mode = pdev->params.OPM; } if (pdev->state.smoothness != pis->smoothness) { code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; code = cos_dict_put_c_key_real(resource_dict(*ppres), "/SM", pis->smoothness); if (code < 0) return code; pdev->state.smoothness = pis->smoothness; } if (pdev->CompatibilityLevel >= 1.4) { if (pdev->state.text_knockout != pis->text_knockout) { code = pdf_open_gstate(pdev, ppres); if (code < 0) return code; code = cos_dict_put_c_key_bool(resource_dict(*ppres), "/TK", pis->text_knockout); if (code < 0) return code; pdev->state.text_knockout = pis->text_knockout; } } } return code; } /* Update the graphics state for filling. */ int pdf_try_prepare_fill(gx_device_pdf *pdev, const gs_imager_state *pis) { pdf_resource_t *pres = 0; int code = pdf_prepare_drawing(pdev, pis, &pres); if (code < 0) return code; /* Update overprint. */ if (pdev->params.PreserveOverprintSettings && pdev->fill_overprint != pis->overprint && !pdev->skip_colors ) { code = pdf_open_gstate(pdev, &pres); if (code < 0) return code; /* PDF 1.2 only has a single overprint setting. */ if (pdev->CompatibilityLevel < 1.3) { code = cos_dict_put_c_key_bool(resource_dict(pres), "/OP", pis->overprint); if (code < 0) return code; pdev->stroke_overprint = pis->overprint; } else { code = cos_dict_put_c_key_bool(resource_dict(pres), "/op", pis->overprint); if (code < 0) return code; } pdev->fill_overprint = pis->overprint; } return pdf_end_gstate(pdev, pres); } int pdf_prepare_fill(gx_device_pdf *pdev, const gs_imager_state *pis) { int code; if (pdev->context != PDF_IN_STREAM) { code = pdf_try_prepare_fill(pdev, pis); if (code != gs_error_interrupt) /* See pdf_open_gstate */ return code; code = pdf_open_contents(pdev, PDF_IN_STREAM); if (code < 0) return code; } return pdf_try_prepare_fill(pdev, pis); } /* Update the graphics state for stroking. */ private int pdf_try_prepare_stroke(gx_device_pdf *pdev, const gs_imager_state *pis) { pdf_resource_t *pres = 0; int code = pdf_prepare_drawing(pdev, pis, &pres); if (code < 0) return code; /* Update overprint, stroke adjustment. */ if (pdev->params.PreserveOverprintSettings && pdev->stroke_overprint != pis->overprint && !pdev->skip_colors ) { code = pdf_open_gstate(pdev, &pres); if (code < 0) return code; code = cos_dict_put_c_key_bool(resource_dict(pres), "/OP", pis->overprint); if (code < 0) return code; pdev->stroke_overprint = pis->overprint; if (pdev->CompatibilityLevel < 1.3) { /* PDF 1.2 only has a single overprint setting. */ pdev->fill_overprint = pis->overprint; } else { /* According to PDF>=1.3 spec, OP also sets op, if there is no /op in same garphic state object. We don't write /op, so monitor the viewer's state here : */ pdev->fill_overprint = pis->overprint; } } if (pdev->state.stroke_adjust != pis->stroke_adjust) { code = pdf_open_gstate(pdev, &pres); if (code < 0) return code; code = cos_dict_put_c_key_bool(resource_dict(pres), "/SA", pis->stroke_adjust); if (code < 0) return code; pdev->state.stroke_adjust = pis->stroke_adjust; } return pdf_end_gstate(pdev, pres); } int pdf_prepare_stroke(gx_device_pdf *pdev, const gs_imager_state *pis) { int code; if (pdev->context != PDF_IN_STREAM) { code = pdf_try_prepare_stroke(pdev, pis); if (code != gs_error_interrupt) /* See pdf_open_gstate */ return code; code = pdf_open_contents(pdev, PDF_IN_STREAM); if (code < 0) return code; } return pdf_try_prepare_stroke(pdev, pis); } /* Update the graphics state for an image other than an ImageType 1 mask. */ int pdf_prepare_image(gx_device_pdf *pdev, const gs_imager_state *pis) { /* * As it turns out, this requires updating the same parameters as for * filling. */ return pdf_prepare_fill(pdev, pis); } /* Update the graphics state for an ImageType 1 mask. */ int pdf_prepare_imagemask(gx_device_pdf *pdev, const gs_imager_state *pis, const gx_drawing_color *pdcolor) { int code = pdf_prepare_image(pdev, pis); if (code < 0) return code; return pdf_set_drawing_color(pdev, pis, pdcolor, &pdev->saved_fill_color, &pdev->fill_used_process_color, &psdf_set_fill_color_commands); }