/* Copyright (C) 2000 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. */ /* $Id$ */ /* Implementation of transparency, other than rendering */ #include "gx.h" #include "gserrors.h" #include "gstrans.h" #include "gsutil.h" #include "gzstate.h" #include "gxdevcli.h" #define PUSH_TS 0 /* ------ Transparency-related graphics state elements ------ */ int gs_setblendmode(gs_state *pgs, gs_blend_mode_t mode) { #ifdef DEBUG if (gs_debug_c('v')) { static const char *const bm_names[] = { GS_BLEND_MODE_NAMES }; dlprintf1("[v](0x%lx)blend_mode = ", (ulong)pgs); if (mode >= 0 && mode < countof(bm_names)) dprintf1("%s\n", bm_names[mode]); else dprintf1("%d??\n", (int)mode); } #endif if (mode < 0 || mode > MAX_BLEND_MODE) return_error(gs_error_rangecheck); pgs->blend_mode = mode; return 0; } gs_blend_mode_t gs_currentblendmode(const gs_state *pgs) { return pgs->blend_mode; } int gs_setopacityalpha(gs_state *pgs, floatp alpha) { if_debug2('v', "[v](0x%lx)opacity.alpha = %g\n", (ulong)pgs, alpha); pgs->opacity.alpha = (alpha < 0.0 ? 0.0 : alpha > 1.0 ? 1.0 : alpha); return 0; } float gs_currentopacityalpha(const gs_state *pgs) { return pgs->opacity.alpha; } int gs_setshapealpha(gs_state *pgs, floatp alpha) { if_debug2('v', "[v](0x%lx)shape.alpha = %g\n", (ulong)pgs, alpha); pgs->shape.alpha = (alpha < 0.0 ? 0.0 : alpha > 1.0 ? 1.0 : alpha); return 0; } float gs_currentshapealpha(const gs_state *pgs) { return pgs->shape.alpha; } int gs_settextknockout(gs_state *pgs, bool knockout) { if_debug2('v', "[v](0x%lx)text_knockout = %s\n", (ulong)pgs, (knockout ? "true" : "false")); pgs->text_knockout = knockout; return 0; } bool gs_currenttextknockout(const gs_state *pgs) { return pgs->text_knockout; } /* ------ Transparency rendering stack ------ */ /* This area of the transparency facilities is in flux. Here is a proposal for extending the driver interface. The material below will eventually go in gxdevcli.h. */ /* Push the current transparency state (*ppts) onto the associated stack, and set *ppts to a new transparency state of the given dimension. The transparency state may copy some or all of the imager state, such as the current alpha and/or transparency mask values, and definitely copies the parameters. */ #define dev_t_proc_begin_transparency_group(proc, dev_t)\ int proc(gx_device *dev,\ const gs_transparency_group_params_t *ptgp,\ const gs_rect *pbbox,\ gs_imager_state *pis,\ gs_transparency_state_t **ppts,\ gs_memory_t *mem) #define dev_proc_begin_transparency_group(proc)\ dev_t_proc_begin_transparency_group(proc, gx_device) /* End a transparency group: blend the top element of the transparency stack, which must be a group, into the next-to-top element, popping the stack. If the stack only had a single element, blend into the device output. Set *ppts to 0 iff the stack is now empty. If end_group fails, the stack is *not* popped. */ #define dev_t_proc_end_transparency_group(proc, dev_t)\ int proc(gx_device *dev,\ gs_imager_state *pis,\ gs_transparency_state_t **ppts) #define dev_proc_end_transparency_group(proc)\ dev_t_proc_end_transparency_group(proc, gx_device) /* Push the transparency state and prepare to render a transparency mask. This is similar to begin_transparency_group except that it only accumulates coverage values, not full pixel values. */ #define dev_t_proc_begin_transparency_mask(proc, dev_t)\ int proc(gx_device *dev,\ const gs_transparency_mask_params_t *ptmp,\ const gs_rect *pbbox,\ gs_imager_state *pis,\ gs_transparency_state_t **ppts,\ gs_memory_t *mem) #define dev_proc_begin_transparency_mask(proc)\ dev_t_proc_begin_transparency_mask(proc, gx_device) /* Store a pointer to the rendered transparency mask into *pptm, popping the stack like end_group. Normally, the client will follow this by using rc_assign to store the rendered mask into pis->{opacity,shape}.mask. If end_mask fails, the stack is *not* popped. */ #define dev_t_proc_end_transparency_mask(proc, dev_t)\ int proc(gx_device *dev,\ gs_transparency_mask_t **pptm) #define dev_proc_end_transparency_mask(proc)\ dev_t_proc_end_transparency_mask(proc, gx_device) /* Pop the transparency stack, discarding the top element, which may be either a group or a mask. Set *ppts to 0 iff the stack is now empty. */ #define dev_t_proc_discard_transparency_layer(proc, dev_t)\ int proc(gx_device *dev,\ gs_transparency_state_t **ppts) #define dev_proc_discard_transparency_layer(proc)\ dev_t_proc_discard_transparency_layer(proc, gx_device) /* (end of proposed driver interface extensions) */ gs_transparency_state_type_t gs_current_transparency_type(const gs_state *pgs) { return (pgs->transparency_stack == 0 ? 0 : pgs->transparency_stack->type); } /* Support for dummy implementation */ gs_private_st_ptrs1(st_transparency_state, gs_transparency_state_t, "gs_transparency_state_t", transparency_state_enum_ptrs, transparency_state_reloc_ptrs, saved); #if PUSH_TS private int push_transparency_stack(gs_state *pgs, gs_transparency_state_type_t type, client_name_t cname) { gs_transparency_state_t *pts = gs_alloc_struct(pgs->memory, gs_transparency_state_t, &st_transparency_state, cname); if (pts == 0) return_error(gs_error_VMerror); pts->saved = pgs->transparency_stack; pts->type = type; pgs->transparency_stack = pts; return 0; } #endif private void pop_transparency_stack(gs_state *pgs, client_name_t cname) { gs_transparency_state_t *pts = pgs->transparency_stack; /* known non-0 */ gs_transparency_state_t *saved = pts->saved; gs_free_object(pgs->memory, pts, cname); pgs->transparency_stack = saved; } void gs_trans_group_params_init(gs_transparency_group_params_t *ptgp) { ptgp->ColorSpace = 0; /* bogus, but can't do better */ ptgp->Isolated = false; ptgp->Knockout = false; } int gs_begin_transparency_group(gs_state *pgs, const gs_transparency_group_params_t *ptgp, const gs_rect *pbbox) { #ifdef DEBUG if (gs_debug_c('v')) { static const char *const cs_names[] = { GS_COLOR_SPACE_TYPE_NAMES }; dlprintf5("[v](0x%lx)begin_transparency_group [%g %g %g %g]\n", (ulong)pgs, pbbox->p.x, pbbox->p.y, pbbox->q.x, pbbox->q.y); if (ptgp->ColorSpace) dprintf1(" CS = %s", cs_names[(int)gs_color_space_get_index(ptgp->ColorSpace)]); else dputs(" (no CS)"); dprintf2(" Isolated = %d Knockout = %d\n", ptgp->Isolated, ptgp->Knockout); } #endif if (dev_proc(pgs->device, begin_transparency_group) != 0) return (*dev_proc(pgs->device, begin_transparency_group)) (pgs->device, ptgp, pbbox, (gs_imager_state *)pgs, NULL, NULL); else return 0; #if PUSH_TS return push_transparency_stack(pgs, TRANSPARENCY_STATE_Group, "gs_begin_transparency_group"); #endif } int gs_end_transparency_group(gs_state *pgs) { if (dev_proc(pgs->device, end_transparency_group) != 0) return (*dev_proc(pgs->device, end_transparency_group)) (pgs->device, (gs_imager_state *)pgs, NULL); else return 0; #if 0 gs_transparency_state_t *pts = pgs->transparency_stack; if_debug1('v', "[v](0x%lx)end_transparency_group\n", (ulong)pgs); if (!pts || pts->type != TRANSPARENCY_STATE_Group) return_error(gs_error_rangecheck); pop_transparency_stack(pgs, "gs_end_transparency_group"); return 0; #endif } private int mask_transfer_identity(floatp in, float *out, void *proc_data) { *out = in; return 0; } void gs_trans_mask_params_init(gs_transparency_mask_params_t *ptmp, gs_transparency_mask_subtype_t subtype) { ptmp->subtype = subtype; ptmp->has_Background = false; ptmp->TransferFunction = mask_transfer_identity; ptmp->TransferFunction_data = 0; } int gs_begin_transparency_mask(gs_state *pgs, const gs_transparency_mask_params_t *ptmp, const gs_rect *pbbox) { if_debug8('v', "[v](0x%lx)begin_transparency_mask [%g %g %g %g]\n\ subtype = %d has_Background = %d %s\n", (ulong)pgs, pbbox->p.x, pbbox->p.y, pbbox->q.x, pbbox->q.y, (int)ptmp->subtype, ptmp->has_Background, (ptmp->TransferFunction == mask_transfer_identity ? "no TR" : "has TR")); if (dev_proc(pgs->device, begin_transparency_mask) != 0) return (*dev_proc(pgs->device, begin_transparency_mask)) (pgs->device, ptmp, pbbox, (gs_imager_state *)pgs, NULL, NULL); else return 0; #if PUSH_TS return push_transparency_stack(pgs, TRANSPARENCY_STATE_Mask, "gs_begin_transparency_group"); #endif } int gs_end_transparency_mask(gs_state *pgs, gs_transparency_channel_selector_t csel) { #if 0 gs_transparency_state_t *pts = pgs->transparency_stack; #endif if_debug2('v', "[v](0x%lx)end_transparency_mask(%d)\n", (ulong)pgs, (int)csel); /* todo: route csel */ if (dev_proc(pgs->device, end_transparency_mask) != 0) return (*dev_proc(pgs->device, end_transparency_mask)) (pgs->device, NULL); else return 0; #if 0 if (!pts || pts->type != TRANSPARENCY_STATE_Mask) return_error(gs_error_rangecheck); pop_transparency_stack(pgs, "gs_end_transparency_mask"); return 0; #endif } int gs_discard_transparency_layer(gs_state *pgs) { /****** NYI, DUMMY ******/ gs_transparency_state_t *pts = pgs->transparency_stack; if_debug1('v', "[v](0x%lx)discard_transparency_layer\n", (ulong)pgs); if (!pts) return_error(gs_error_rangecheck); pop_transparency_stack(pgs, "gs_discard_transparency_layer"); return 0; } int gs_init_transparency_mask(gs_state *pgs, gs_transparency_channel_selector_t csel) { /****** NYI, DUMMY ******/ gs_transparency_source_t *ptm; if_debug2('v', "[v](0x%lx)init_transparency_mask(%d)\n", (ulong)pgs, (int)csel); switch (csel) { case TRANSPARENCY_CHANNEL_Opacity: ptm = &pgs->opacity; break; case TRANSPARENCY_CHANNEL_Shape: ptm = &pgs->shape; break; default: return_error(gs_error_rangecheck); } rc_decrement_only(ptm->mask, "gs_init_transparency_mask"); ptm->mask = 0; return 0; }