/* Copyright (C) 2001-2006 Artifex Software, Inc. 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 that license. Refer to licensing information at http://www.artifex.com/ or contact Artifex Software, Inc., 7 Mt. Lassen Drive - Suite A-134, San Rafael, CA 94903, U.S.A., +1(415)492-9861, for further information. */ /* $Id: gscdevn.c 8764 2008-05-21 18:27:42Z mvrhel $ */ /* DeviceN color space and operation definition */ #include "memory_.h" #include "string_.h" #include "gx.h" #include "gserrors.h" #include "gscdevn.h" #include "gsfunc.h" #include "gsrefct.h" #include "gsmatrix.h" /* for gscolor2.h */ #include "gsstruct.h" #include "gxcspace.h" #include "gxcdevn.h" #include "gxfarith.h" #include "gxfrac.h" #include "gxcmap.h" #include "gxistate.h" #include "gscoord.h" #include "gzstate.h" #include "gxdevcli.h" #include "gsovrc.h" #include "stream.h" #include "gsnamecl.h" /* Custom color call back define */ /* ---------------- Color space ---------------- */ /* GC descriptors */ gs_private_st_composite(st_color_space_DeviceN, gs_color_space, "gs_color_space_DeviceN", cs_DeviceN_enum_ptrs, cs_DeviceN_reloc_ptrs); private_st_device_n_attributes(); private_st_device_n_map(); /* Define the DeviceN color space type. */ static cs_proc_num_components(gx_num_components_DeviceN); static cs_proc_init_color(gx_init_DeviceN); static cs_proc_restrict_color(gx_restrict_DeviceN); static cs_proc_concrete_space(gx_concrete_space_DeviceN); static cs_proc_concretize_color(gx_concretize_DeviceN); static cs_proc_remap_concrete_color(gx_remap_concrete_DeviceN); static cs_proc_install_cspace(gx_install_DeviceN); static cs_proc_set_overprint(gx_set_overprint_DeviceN); static cs_proc_final(gx_final_DeviceN); static cs_proc_serialize(gx_serialize_DeviceN); const gs_color_space_type gs_color_space_type_DeviceN = { gs_color_space_index_DeviceN, true, false, &st_color_space_DeviceN, gx_num_components_DeviceN, gx_init_DeviceN, gx_restrict_DeviceN, gx_concrete_space_DeviceN, gx_concretize_DeviceN, gx_remap_concrete_DeviceN, gx_default_remap_color, gx_install_DeviceN, gx_set_overprint_DeviceN, gx_final_DeviceN, gx_no_adjust_color_count, gx_serialize_DeviceN, gx_cspace_is_linear_default }; /* GC procedures */ static ENUM_PTRS_BEGIN(cs_DeviceN_enum_ptrs) return 0; ENUM_PTR(0, gs_color_space, params.device_n.names); ENUM_PTR(1, gs_color_space, params.device_n.map); ENUM_PTR(2, gs_color_space, params.device_n.colorants); ENUM_PTRS_END static RELOC_PTRS_BEGIN(cs_DeviceN_reloc_ptrs) { RELOC_PTR(gs_color_space, params.device_n.names); RELOC_PTR(gs_color_space, params.device_n.map); RELOC_PTR(gs_color_space, params.device_n.colorants); } RELOC_PTRS_END /* ------ Public procedures ------ */ /* * Create a new DeviceN colorspace. */ int gs_cspace_new_DeviceN( gs_color_space **ppcs, uint num_components, gs_color_space *palt_cspace, gs_memory_t *pmem ) { gs_color_space *pcs; gs_device_n_params *pcsdevn; gs_separation_name *pnames; int code; if (palt_cspace == 0 || !palt_cspace->type->can_be_alt_space) return_error(gs_error_rangecheck); pcs = gs_cspace_alloc(pmem, &gs_color_space_type_DeviceN); if (pcs == NULL) return_error(gs_error_VMerror); pcsdevn = &pcs->params.device_n; pcsdevn->names = NULL; pcsdevn->map = NULL; pcsdevn->colorants = NULL; /* Allocate space for color names list. */ code = alloc_device_n_map(&pcsdevn->map, pmem, "gs_cspace_build_DeviceN"); if (code < 0) { gs_free_object(pmem, pcs, "gs_cspace_new_DeviceN"); return code; } /* Allocate space for color names list. */ pnames = (gs_separation_name *) gs_alloc_byte_array(pmem, num_components, sizeof(gs_separation_name), ".gs_cspace_build_DeviceN(names)"); if (pnames == 0) { gs_free_object(pmem, pcsdevn->map, ".gs_cspace_build_DeviceN(map)"); gs_free_object(pmem, pcs, "gs_cspace_new_DeviceN"); return_error(gs_error_VMerror); } pcs->base_space = palt_cspace; rc_increment(palt_cspace); pcsdevn->names = pnames; pcsdevn->num_components = num_components; *ppcs = pcs; return 0; } /* Allocate and initialize a DeviceN map. */ int alloc_device_n_map(gs_device_n_map ** ppmap, gs_memory_t * mem, client_name_t cname) { gs_device_n_map *pimap; rc_alloc_struct_1(pimap, gs_device_n_map, &st_device_n_map, mem, return_error(gs_error_VMerror), cname); pimap->tint_transform = 0; pimap->tint_transform_data = 0; pimap->cache_valid = false; *ppmap = pimap; return 0; } /* * DeviceN and NChannel color spaces can have an attributes dict. In the * attribute dict can be a Colorants dict which contains Separation color * spaces. If the Colorant dict is present, the PS logic will build each of * the Separation color spaces in a temp gstate and then call this procedure * to attach the Separation color space to the DeviceN color space. * The parameter to this procedure is a colorant name. The Separation * color space is in the current (temp) gstate. The DeviceN color space is * in the next gstate down in the gstate list (pgs->saved). */ int gs_attachattributecolorspace(gs_separation_name sep_name, gs_state * pgs) { gs_color_space * pdevncs; gs_device_n_attributes * patt; /* Verify that we have a DeviceN color space */ if (!pgs->saved) return_error(gs_error_rangecheck); pdevncs = pgs->saved->color_space; if (pdevncs->type != &gs_color_space_type_DeviceN) return_error(gs_error_rangecheck); /* Allocate an attribute list element for our linked list of attributes */ rc_alloc_struct_1(patt, gs_device_n_attributes, &st_device_n_attributes, pgs->memory, return_error(gs_error_VMerror), "gs_attachattributrescolorspace"); /* Point our attribute list entry to the attribute color space */ patt->colorant_name = sep_name; patt->cspace = pgs->color_space; rc_increment(pgs->color_space); /* Link our new attribute color space to the DeviceN color space */ patt->next = pdevncs->params.device_n.colorants; pdevncs->params.device_n.colorants = patt; return 0; } #if 0 /* Unused; Unsupported by gx_serialize_device_n_map. */ /* * Set the DeviceN tint transformation procedure. */ int gs_cspace_set_devn_proc(gs_color_space * pcspace, int (*proc)(const float *, float *, const gs_imager_state *, void * ), void *proc_data ) { gs_device_n_map *pimap; if (gs_color_space_get_index(pcspace) != gs_color_space_index_DeviceN) return_error(gs_error_rangecheck); pimap = pcspace->params.device_n.map; pimap->tint_transform = proc; pimap->tint_transform_data = proc_data; pimap->cache_valid = false; return 0; } #endif /* * Check if we are using the alternate color space. */ bool using_alt_color_space(const gs_state * pgs) { return (pgs->color_component_map.use_alt_cspace); } /* Map a DeviceN color using a Function. */ int map_devn_using_function(const float *in, float *out, const gs_imager_state *pis, void *data) { gs_function_t *const pfn = data; return gs_function_evaluate(pfn, in, out); } /* * Set the DeviceN tint transformation procedure to a Function. */ int gs_cspace_set_devn_function(gs_color_space *pcspace, gs_function_t *pfn) { gs_device_n_map *pimap; if (gs_color_space_get_index(pcspace) != gs_color_space_index_DeviceN || pfn->params.m != pcspace->params.device_n.num_components || pfn->params.n != gs_color_space_num_components(pcspace->base_space) ) return_error(gs_error_rangecheck); pimap = pcspace->params.device_n.map; pimap->tint_transform = map_devn_using_function; pimap->tint_transform_data = pfn; pimap->cache_valid = false; return 0; } /* * If the DeviceN tint transformation procedure is a Function, * return the function object, otherwise return 0. */ gs_function_t * gs_cspace_get_devn_function(const gs_color_space *pcspace) { if (gs_color_space_get_index(pcspace) == gs_color_space_index_DeviceN && pcspace->params.device_n.map->tint_transform == map_devn_using_function) return pcspace->params.device_n.map->tint_transform_data; return 0; } /* ------ Color space implementation ------ */ /* Return the number of components of a DeviceN space. */ static int gx_num_components_DeviceN(const gs_color_space * pcs) { return pcs->params.device_n.num_components; } /* Initialize a DeviceN color. */ static void gx_init_DeviceN(gs_client_color * pcc, const gs_color_space * pcs) { uint i; for (i = 0; i < pcs->params.device_n.num_components; ++i) pcc->paint.values[i] = 1.0; } /* Force a DeviceN color into legal range. */ static void gx_restrict_DeviceN(gs_client_color * pcc, const gs_color_space * pcs) { uint i; for (i = 0; i < pcs->params.device_n.num_components; ++i) { floatp value = pcc->paint.values[i]; pcc->paint.values[i] = (value <= 0 ? 0 : value >= 1 ? 1 : value); } } /* Remap a DeviceN color. */ static const gs_color_space * gx_concrete_space_DeviceN(const gs_color_space * pcs, const gs_imager_state * pis) { #ifdef DEBUG /* * Verify that the color space and imager state info match. */ if (pcs->id != pis->color_component_map.cspace_id) dprintf("gx_concrete_space_DeviceN: color space id mismatch"); #endif /* * Check if we are using the alternate color space. */ if (pis->color_component_map.use_alt_cspace) { return cs_concrete_space(pcs->base_space, pis); } /* * DeviceN color spaces are concrete (when not using alt. color space). */ return pcs; } static int gx_concretize_DeviceN(const gs_client_color * pc, const gs_color_space * pcs, frac * pconc, const gs_imager_state * pis) { int code, tcode = 0; gs_client_color cc; const gs_color_space *pacs = pcs->base_space; gs_device_n_map *map = pcs->params.device_n.map; #ifdef DEBUG /* * Verify that the color space and imager state info match. */ if (pcs->id != pis->color_component_map.cspace_id) dprintf("gx_concretize_DeviceN: color space id mismatch"); #endif /* * Check if we need to map into the alternate color space. * We must preserve tcode for implementing a semi-hack in the interpreter. */ if (pis->color_component_map.use_alt_cspace) { /* Check the 1-element cache first. */ if (map->cache_valid) { int i; for (i = pcs->params.device_n.num_components; --i >= 0;) { if (map->tint[i] != pc->paint.values[i]) break; } if (i < 0) { int num_out = gs_color_space_num_components(pacs); for (i = 0; i < num_out; ++i) pconc[i] = map->conc[i]; return 0; } } tcode = (*pcs->params.device_n.map->tint_transform) (pc->paint.values, &cc.paint.values[0], pis, pcs->params.device_n.map->tint_transform_data); if (tcode < 0) return tcode; code = cs_concretize_color(&cc, pacs, pconc, pis); } else { int i; for (i = pcs->params.device_n.num_components; --i >= 0;) pconc[i] = gx_unit_frac(pc->paint.values[i]); return 0; } return (code < 0 || tcode == 0 ? code : tcode); } static int gx_remap_concrete_DeviceN(const frac * pconc, const gs_color_space * pcs, gx_device_color * pdc, const gs_imager_state * pis, gx_device * dev, gs_color_select_t select) { #ifdef DEBUG /* * Verify that the color space and imager state info match. */ if (pcs->id != pis->color_component_map.cspace_id) dprintf("gx_remap_concrete_DeviceN: color space id mismatch"); #endif #if ENABLE_CUSTOM_COLOR_CALLBACK if (pis->memory->gs_lib_ctx->custom_color_callback) { int code = gx_remap_concrete_custom_color_DeviceN(pconc, pcs, pdc, pis, dev, select); if (code >= 0) return code; } #endif if (pis->color_component_map.use_alt_cspace) { const gs_color_space *pacs = pcs->base_space; return (*pacs->type->remap_concrete_color) (pconc, pacs, pdc, pis, dev, select); } else { gx_remap_concrete_devicen(pconc, pdc, pis, dev, select); return 0; } } /* * Check that the color component names for a DeviceN color space * match the device colorant names. Also build a gs_devicen_color_map * structure. */ static int check_DeviceN_component_names(const gs_color_space * pcs, gs_state * pgs) { const gs_separation_name *names = pcs->params.device_n.names; int num_comp = pcs->params.device_n.num_components; int i, j; int colorant_number; byte * pname; uint name_size; gs_devicen_color_map * pcolor_component_map = &pgs->color_component_map; gx_device * dev = pgs->device; const char none_str[] = "None"; const uint none_size = strlen(none_str); bool non_match = false; pcolor_component_map->num_components = num_comp; pcolor_component_map->cspace_id = pcs->id; pcolor_component_map->num_colorants = dev->color_info.num_components; pcolor_component_map->sep_type = SEP_OTHER; /* * Always use the alternate color space if the current device is * using an additive color model. */ if (dev->color_info.polarity == GX_CINFO_POLARITY_ADDITIVE) { pcolor_component_map->use_alt_cspace = true; return 0; } /* * Now check the names of the color components. */ non_match = false; for(i = 0; i < num_comp; i++ ) { /* * Get the character string and length for the component name. */ pcs->params.device_n.get_colorname_string(dev->memory, names[i], &pname, &name_size); /* * Postscript does not accept /None as a color component but it is * allowed in PDF so we accept it. It is also accepted as a * separation name. */ if (name_size == none_size && (strncmp(none_str, (const char *)pname, name_size) == 0)) { pcolor_component_map->color_map[i] = -1; } else { /* * Check for duplicated names. Except for /None, no components * are allowed to have duplicated names. */ for (j = 0; j < i; j++) { if (names[i] == names[j]) return_error(gs_error_rangecheck); } /* * Compare the colorant name to the device's. If the device's * compare routine returns GX_DEVICE_COLOR_MAX_COMPONENTS then the * colorant is in the SeparationNames list but not in the * SeparationOrder list. */ colorant_number = (*dev_proc(dev, get_color_comp_index)) (dev, (const char *)pname, name_size, SEPARATION_NAME); if (colorant_number >= 0) { /* If valid colorant name */ pcolor_component_map->color_map[i] = (colorant_number == GX_DEVICE_COLOR_MAX_COMPONENTS) ? -1 : colorant_number; } else non_match = true; } } pcolor_component_map->use_alt_cspace = non_match; return 0; } /* Install a DeviceN color space. */ static int gx_install_DeviceN(gs_color_space * pcs, gs_state * pgs) { int code; #if ENABLE_CUSTOM_COLOR_CALLBACK /* * Check if we want to use the callback color processing for this * color space. */ bool use_custom_color_callback = custom_color_callback_install_DeviceN(pcs, pgs); if (use_custom_color_callback) { /* * We are using the callback instead of the alternate tint transform * for this color space. */ pgs->color_component_map.use_alt_cspace = pgs->color_space->params.device_n.use_alt_cspace = false; pgs->color_component_map.cspace_id = pcs->id; return 0; } #endif code = check_DeviceN_component_names(pcs, pgs); if (code < 0) return code; /* {csrc} was pgs->color_space->params.device_n.use_alt_cspace */ ((gs_color_space *)pcs)->params.device_n.use_alt_cspace = using_alt_color_space(pgs); if (pcs->params.device_n.use_alt_cspace) code = (pcs->base_space->type->install_cspace) (pcs->base_space, pgs); /* * Give the device an opportunity to capture equivalent colors for any * spot colors which might be present in the color space. */ if (code >= 0) code = dev_proc(pgs->device, update_spot_equivalent_colors) (pgs->device, pgs); return code; } /* Set overprint information for a DeviceN color space */ static int gx_set_overprint_DeviceN(const gs_color_space * pcs, gs_state * pgs) { gs_devicen_color_map * pcmap = &pgs->color_component_map; if (pcmap->use_alt_cspace) { const gs_color_space_type* base_type = pcs->base_space->type; /* If the base space is DeviceCMYK, handle overprint as DeviceCMYK */ if ( base_type->index == gs_color_space_index_DeviceCMYK ) return base_type->set_overprint( pcs->base_space, pgs ); else return gx_spot_colors_set_overprint( pcs->base_space, pgs); } else { gs_overprint_params_t params; if ((params.retain_any_comps = pgs->overprint)) { int i, ncomps = pcs->params.device_n.num_components; params.retain_spot_comps = false; params.drawn_comps = 0; for (i = 0; i < ncomps; i++) { int mcomp = pcmap->color_map[i]; if (mcomp >= 0) gs_overprint_set_drawn_comp( params.drawn_comps, mcomp); } } pgs->effective_overprint_mode = 0; return gs_state_update_overprint(pgs, ¶ms); } } /* Finalize contents of a DeviceN color space. */ static void gx_final_DeviceN(const gs_color_space * pcs) { gs_device_n_attributes * pnextatt, * patt = pcs->params.device_n.colorants; rc_decrement_only(pcs->params.device_n.map, "gx_adjust_DeviceN"); while (patt != NULL) { pnextatt = patt->next; rc_decrement(patt->cspace, "gx_final_DeviceN"); rc_decrement(patt, "gx_adjust_DeviceN"); patt = pnextatt; } } /* ---------------- Serialization. -------------------------------- */ int gx_serialize_device_n_map(const gs_color_space * pcs, gs_device_n_map * m, stream * s) { const gs_function_t *pfn; if (m->tint_transform != map_devn_using_function) return_error(gs_error_unregistered); /* Unimplemented. */ pfn = (const gs_function_t *)m->tint_transform_data; return gs_function_serialize(pfn, s); } static int gx_serialize_DeviceN(const gs_color_space * pcs, stream * s) { const gs_device_n_params * p = &pcs->params.device_n; uint n; int code = gx_serialize_cspace_type(pcs, s); if (code < 0) return code; code = sputs(s, (const byte *)&p->num_components, sizeof(p->num_components), &n); if (code < 0) return code; code = sputs(s, (const byte *)&p->names[0], sizeof(p->names[0]) * p->num_components, &n); if (code < 0) return code; code = cs_serialize(pcs->base_space, s); if (code < 0) return code; return gx_serialize_device_n_map(pcs, p->map, s); /* p->use_alt_cspace isn't a property of the space. */ }