/src/ghostpdl/base/gsdps1.c

Source (jump to first uncovered line)
/* Copyright (C) 2001-2023 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 the license contained in the file LICENSE in this distribution.

   Refer to licensing information at http://www.artifex.com or contact
   Artifex Software, Inc.,  39 Mesa Street, Suite 108A, San Francisco,
   CA 94129, USA, for further information.
*/


/* Display PostScript graphics additions for Ghostscript library */
#include "math_.h"
#include "gx.h"
#include "gserrors.h"
#include "gsmatrix.h"   /* for gscoord.h */
#include "gscoord.h"
#include "gspaint.h"
#include "gxdevice.h"
#include "gxfixed.h"
#include "gxmatrix.h"
#include "gxhldevc.h"
#include "gspath.h"
#include "gspath2.h"    /* defines interface */
#include "gzpath.h"
#include "gzcpath.h"
#include "gzstate.h"
#include "gsutil.h"
#include "gxdevsop.h"

/*
 * Define how much rounding slop setbbox should leave,
 * in device coordinates.  Because of rounding in transforming
 * path coordinates to fixed point, the minimum realistic value is:
 *
 *      #define box_rounding_slop_fixed (fixed_epsilon)
 *
 * But even this isn't enough to compensate for cumulative rounding error
 * in rmoveto or rcurveto.  Instead, we somewhat arbitrarily use:
 */
#define box_rounding_slop_fixed (fixed_epsilon * 3)

/* ------ Graphics state ------ */

/* Set the bounding box for the current path. */
int
gs_setbbox(gs_gstate * pgs, double llx, double lly, double urx, double ury)
{
    gs_rect ubox, dbox;
    gs_fixed_rect obox, bbox;
    gx_path *ppath = pgs->path;
    int code;

    if (llx > urx || lly > ury)
        return_error(gs_error_rangecheck);
    /* Transform box to device coordinates. */
    ubox.p.x = llx;
    ubox.p.y = lly;
    ubox.q.x = urx;
    ubox.q.y = ury;
    if ((code = gs_bbox_transform(&ubox, &ctm_only(pgs), &dbox)) < 0)
        return code;
    /* Round the corners in opposite directions. */
    /* Because we can't predict the magnitude of the dbox values, */
    /* we add/subtract the slop after fixing. */
    if (dbox.p.x < fixed2float(min_fixed + box_rounding_slop_fixed) ||
        dbox.p.y < fixed2float(min_fixed + box_rounding_slop_fixed) ||
        dbox.q.x >= fixed2float(max_fixed - box_rounding_slop_fixed + fixed_epsilon) ||
        dbox.q.y >= fixed2float(max_fixed - box_rounding_slop_fixed + fixed_epsilon)
        )
        return_error(gs_error_limitcheck);
    bbox.p.x =
        (fixed) floor(dbox.p.x * fixed_scale) - box_rounding_slop_fixed;
    bbox.p.y =
        (fixed) floor(dbox.p.y * fixed_scale) - box_rounding_slop_fixed;
    bbox.q.x =
        (fixed) ceil(dbox.q.x * fixed_scale) + box_rounding_slop_fixed;
    bbox.q.y =
        (fixed) ceil(dbox.q.y * fixed_scale) + box_rounding_slop_fixed;
    if (gx_path_bbox_set(ppath, &obox) >= 0) { /* Take the union of the bboxes. */
        ppath->bbox.p.x = min(obox.p.x, bbox.p.x);
        ppath->bbox.p.y = min(obox.p.y, bbox.p.y);
        ppath->bbox.q.x = max(obox.q.x, bbox.q.x);
        ppath->bbox.q.y = max(obox.q.y, bbox.q.y);
    } else {     /* empty path *//* Just set the bbox. */
        ppath->bbox = bbox;
    }
    ppath->bbox_set = 1;
    return 0;
}

/* ------ Rectangles ------ */

/* Append a list of rectangles to a path. */
static int
gs_rectappend_compat(gs_gstate * pgs, const gs_rect * pr, uint count, bool clip)
{
    bool CPSI_mode = gs_currentcpsimode(pgs->memory);

    for (; count != 0; count--, pr++) {
        double px = pr->p.x, py = pr->p.y, qx = pr->q.x, qy = pr->q.y;
        int code;

        if (CPSI_mode) {
            /* We believe that the result must be independent
               on the device initial matrix.
               Particularly for the correct dashing
               the starting point and the contour direction
               must be same with any device initial matrix.
               Only way to provide it is to choose the starting point
               and the direction in the user space. */
            if (clip) {
                /* CPSI starts a clippath with the upper right corner. */
                /* Debugged with CET 11-11.PS page 6 item much13.*/
                if ((code = gs_moveto(pgs, qx, qy)) < 0 ||
                    (code = gs_lineto(pgs, qx, py)) < 0 ||
                    (code = gs_lineto(pgs, px, py)) < 0 ||
                    (code = gs_lineto(pgs, px, qy)) < 0 ||
                    (code = gs_closepath(pgs)) < 0
                    )
                    return code;
            } else {
                /* Debugged with CET 12-12.PS page 10 item more20.*/
                if (px > qx) {
                    px = qx; qx = pr->p.x;
                }
                if (py > qy) {
                    py = qy; qy = pr->p.y;
                }
                if ((code = gs_moveto(pgs, px, py)) < 0 ||
                    (code = gs_lineto(pgs, qx, py)) < 0 ||
                    (code = gs_lineto(pgs, qx, qy)) < 0 ||
                    (code = gs_lineto(pgs, px, qy)) < 0 ||
                    (code = gs_closepath(pgs)) < 0
                    )
                    return code;
            }
        } else {
            /* Ensure counter-clockwise drawing. */
            if ((qx >= px) != (qy >= py))
                qx = px, px = pr->q.x; /* swap x values */
            if ((code = gs_moveto(pgs, px, py)) < 0 ||
                (code = gs_lineto(pgs, qx, py)) < 0 ||
                (code = gs_lineto(pgs, qx, qy)) < 0 ||
                (code = gs_lineto(pgs, px, qy)) < 0 ||
                (code = gs_closepath(pgs)) < 0
                )
                return code;
        }
    }
    return 0;
}
int
gs_rectappend(gs_gstate * pgs, const gs_rect * pr, uint count)
{
    return gs_rectappend_compat(pgs, pr, count, false);
}

/* Clip to a list of rectangles. */
int
gs_rectclip(gs_gstate * pgs, const gs_rect * pr, uint count)
{
    int code;
    gx_path save;

    gx_path_init_local(&save, pgs->memory);
    gx_path_assign_preserve(&save, pgs->path);
    gs_newpath(pgs);
    if ((code = gs_rectappend_compat(pgs, pr, count, true)) < 0 ||
        (code = gs_clip(pgs)) < 0
        ) {
        gx_path_assign_free(pgs->path, &save);
        return code;
    }
    gx_path_free(&save, "gs_rectclip");
    gs_newpath(pgs);
    return 0;
}

/* Setup for black vector handling */
static inline bool black_vectors(gs_gstate *pgs, gx_device *dev)
{
    if (dev->icc_struct != NULL && dev->icc_struct->blackvector &&
        pgs->black_textvec_state == NULL) {
        return gsicc_setup_blacktextvec(pgs, dev, false);
    }
    return false;
}

/* Fill a list of rectangles. */
/* We take the trouble to do this efficiently in the simple cases. */
int
gs_rectfill(gs_gstate * 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_gstate *pgs2 = (const gs_gstate *)pgs;
    bool hl_color_available = gx_hld_is_hl_color_available(pgs2, 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);
    bool black_vector = false;

    /* Processing a fill object operation */
    ensure_tag_is_set(pgs, pgs->device, GS_VECTOR_TAG); /* NB: may unset_dev_color */

    black_vector = black_vectors(pgs, pgs->device); /* Set vector fill to black */

    code = gx_set_dev_color(pgs);
    if (code != 0)
        goto exit;

    if ( !(pgs->device->page_uses_transparency ||
          dev_proc(pgs->device, dev_spec_op)(pgs->device,
              gxdso_is_pdf14_device, &(pgs->device),
              sizeof(pgs->device))) &&
        (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_gstate_color_load(pgs) >= 0 &&
        (*dev_proc(pdev, get_alpha_bits)) (pdev, go_graphics)
        <= 1 &&
        (!pgs->overprint || !gs_currentcolor_eopm(pgs))
        ) {
        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))
            goto exit;
        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, pgs2, pdc, pcpath);
                    if (code < 0)
                        goto exit;
                }
            } 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;
            }
        }
        code = 0;
        goto exit;
      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)
                goto exit;
            code = gs_newpath(pgs);
        }
        if ((code >= 0) &&
            (((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);
    }

exit:
    if (black_vector) {
        /* Restore color */
        gsicc_restore_blacktextvec(pgs, false);
    }
    return code;
}

/* Stroke a list of rectangles. */
/* (We could do this a lot more efficiently.) */
int
gs_rectstroke(gs_gstate * 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;
}

Coverage Report

Created: 2025-06-10 06:59

Line	Count	Source (jump to first uncovered line)
1		/* Copyright (C) 2001-2023 Artifex Software, Inc.
2		All Rights Reserved.
3
4		This software is provided AS-IS with no warranty, either express or
5		implied.
6
7		This software is distributed under license and may not be copied,
8		modified or distributed except as expressly authorized under the terms
9		of the license contained in the file LICENSE in this distribution.
10
11		Refer to licensing information at http://www.artifex.com or contact
12		Artifex Software, Inc., 39 Mesa Street, Suite 108A, San Francisco,
13		CA 94129, USA, for further information.
14		*/
15
16
17		/* Display PostScript graphics additions for Ghostscript library */
18		#include "math_.h"
19		#include "gx.h"
20		#include "gserrors.h"
21		#include "gsmatrix.h" /* for gscoord.h */
22		#include "gscoord.h"
23		#include "gspaint.h"
24		#include "gxdevice.h"
25		#include "gxfixed.h"
26		#include "gxmatrix.h"
27		#include "gxhldevc.h"
28		#include "gspath.h"
29		#include "gspath2.h" /* defines interface */
30		#include "gzpath.h"
31		#include "gzcpath.h"
32		#include "gzstate.h"
33		#include "gsutil.h"
34		#include "gxdevsop.h"
35
36		/*
37		* Define how much rounding slop setbbox should leave,
38		* in device coordinates. Because of rounding in transforming
39		* path coordinates to fixed point, the minimum realistic value is:
40		*
41		* #define box_rounding_slop_fixed (fixed_epsilon)
42		*
43		* But even this isn't enough to compensate for cumulative rounding error
44		* in rmoveto or rcurveto. Instead, we somewhat arbitrarily use:
45		*/
46	0	#define box_rounding_slop_fixed (fixed_epsilon * 3)
47
48		/* ------ Graphics state ------ */
49
50		/* Set the bounding box for the current path. */
51		int
52		gs_setbbox(gs_gstate * pgs, double llx, double lly, double urx, double ury)
53	2	{
54	2	gs_rect ubox, dbox;
55	2	gs_fixed_rect obox, bbox;
56	2	gx_path *ppath = pgs->path;
57	2	int code;
58
59	2	if (llx > urx \|\| lly > ury)
60	2	return_error(gs_error_rangecheck);
61		/* Transform box to device coordinates. */
62	0	ubox.p.x = llx;
63	0	ubox.p.y = lly;
64	0	ubox.q.x = urx;
65	0	ubox.q.y = ury;
66	0	if ((code = gs_bbox_transform(&ubox, &ctm_only(pgs), &dbox)) < 0)
67	0	return code;
68		/* Round the corners in opposite directions. */
69		/* Because we can't predict the magnitude of the dbox values, */
70		/* we add/subtract the slop after fixing. */
71	0	if (dbox.p.x < fixed2float(min_fixed + box_rounding_slop_fixed) \|\|
72	0	dbox.p.y < fixed2float(min_fixed + box_rounding_slop_fixed) \|\|
73	0	dbox.q.x >= fixed2float(max_fixed - box_rounding_slop_fixed + fixed_epsilon) \|\|
74	0	dbox.q.y >= fixed2float(max_fixed - box_rounding_slop_fixed + fixed_epsilon)
75	0	)
76	0	return_error(gs_error_limitcheck);
77	0	bbox.p.x =
78	0	(fixed) floor(dbox.p.x * fixed_scale) - box_rounding_slop_fixed;
79	0	bbox.p.y =
80	0	(fixed) floor(dbox.p.y * fixed_scale) - box_rounding_slop_fixed;
81	0	bbox.q.x =
82	0	(fixed) ceil(dbox.q.x * fixed_scale) + box_rounding_slop_fixed;
83	0	bbox.q.y =
84	0	(fixed) ceil(dbox.q.y * fixed_scale) + box_rounding_slop_fixed;
85	0	if (gx_path_bbox_set(ppath, &obox) >= 0) { /* Take the union of the bboxes. */
86	0	ppath->bbox.p.x = min(obox.p.x, bbox.p.x);
87	0	ppath->bbox.p.y = min(obox.p.y, bbox.p.y);
88	0	ppath->bbox.q.x = max(obox.q.x, bbox.q.x);
89	0	ppath->bbox.q.y = max(obox.q.y, bbox.q.y);
90	0	} else { /* empty path // Just set the bbox. */
91	0	ppath->bbox = bbox;
92	0	}
93	0	ppath->bbox_set = 1;
94	0	return 0;
95	0	}
96
97		/* ------ Rectangles ------ */
98
99		/* Append a list of rectangles to a path. */
100		static int
101		gs_rectappend_compat(gs_gstate * pgs, const gs_rect * pr, uint count, bool clip)
102	15.6k	{
103	15.6k	bool CPSI_mode = gs_currentcpsimode(pgs->memory);
104
105	31.3k	for (; count != 0; count--, pr++) {
106	15.6k	double px = pr->p.x, py = pr->p.y, qx = pr->q.x, qy = pr->q.y;
107	15.6k	int code;
108
109	15.6k	if (CPSI_mode) {
110		/* We believe that the result must be independent
111		on the device initial matrix.
112		Particularly for the correct dashing
113		the starting point and the contour direction
114		must be same with any device initial matrix.
115		Only way to provide it is to choose the starting point
116		and the direction in the user space. */
117	0	if (clip) {
118		/* CPSI starts a clippath with the upper right corner. */
119		/* Debugged with CET 11-11.PS page 6 item much13.*/
120	0	if ((code = gs_moveto(pgs, qx, qy)) < 0 \|\|
121	0	(code = gs_lineto(pgs, qx, py)) < 0 \|\|
122	0	(code = gs_lineto(pgs, px, py)) < 0 \|\|
123	0	(code = gs_lineto(pgs, px, qy)) < 0 \|\|
124	0	(code = gs_closepath(pgs)) < 0
125	0	)
126	0	return code;
127	0	} else {
128		/* Debugged with CET 12-12.PS page 10 item more20.*/
129	0	if (px > qx) {
130	0	px = qx; qx = pr->p.x;
131	0	}
132	0	if (py > qy) {
133	0	py = qy; qy = pr->p.y;
134	0	}
135	0	if ((code = gs_moveto(pgs, px, py)) < 0 \|\|
136	0	(code = gs_lineto(pgs, qx, py)) < 0 \|\|
137	0	(code = gs_lineto(pgs, qx, qy)) < 0 \|\|
138	0	(code = gs_lineto(pgs, px, qy)) < 0 \|\|
139	0	(code = gs_closepath(pgs)) < 0
140	0	)
141	0	return code;
142	0	}
143	15.6k	} else {
144		/* Ensure counter-clockwise drawing. */
145	15.6k	if ((qx >= px) != (qy >= py))
146	248	qx = px, px = pr->q.x; /* swap x values */
147	15.6k	if ((code = gs_moveto(pgs, px, py)) < 0 \|\|
148	15.6k	(code = gs_lineto(pgs, qx, py)) < 0 \|\|
149	15.6k	(code = gs_lineto(pgs, qx, qy)) < 0 \|\|
150	15.6k	(code = gs_lineto(pgs, px, qy)) < 0 \|\|
151	15.6k	(code = gs_closepath(pgs)) < 0
152	15.6k	)
153	0	return code;
154	15.6k	}
155	15.6k	}
156	15.6k	return 0;
157	15.6k	}
158		int
159		gs_rectappend(gs_gstate * pgs, const gs_rect * pr, uint count)
160	90	{
161	90	return gs_rectappend_compat(pgs, pr, count, false);
162	90	}
163
164		/* Clip to a list of rectangles. */
165		int
166		gs_rectclip(gs_gstate * pgs, const gs_rect * pr, uint count)
167	15.5k	{
168	15.5k	int code;
169	15.5k	gx_path save;
170
171	15.5k	gx_path_init_local(&save, pgs->memory);
172	15.5k	gx_path_assign_preserve(&save, pgs->path);
173	15.5k	gs_newpath(pgs);
174	15.5k	if ((code = gs_rectappend_compat(pgs, pr, count, true)) < 0 \|\|
175	15.5k	(code = gs_clip(pgs)) < 0
176	15.5k	) {
177	0	gx_path_assign_free(pgs->path, &save);
178	0	return code;
179	0	}
180	15.5k	gx_path_free(&save, "gs_rectclip");
181	15.5k	gs_newpath(pgs);
182	15.5k	return 0;
183	15.5k	}
184
185		/* Setup for black vector handling */
186		static inline bool black_vectors(gs_gstate pgs, gx_device dev)
187	283	{
188	283	if (dev->icc_struct != NULL && dev->icc_struct->blackvector &&
189	283	pgs->black_textvec_state == NULL) {
190	0	return gsicc_setup_blacktextvec(pgs, dev, false);
191	0	}
192	283	return false;
193	283	}
194
195		/* Fill a list of rectangles. */
196		/* We take the trouble to do this efficiently in the simple cases. */
197		int
198		gs_rectfill(gs_gstate * pgs, const gs_rect * pr, uint count)
199	283	{
200	283	const gs_rect *rlist = pr;
201	283	gx_clip_path *pcpath;
202	283	uint rcount = count;
203	283	int code;
204	283	gx_device * pdev = pgs->device;
205	283	gx_device_color *pdc = gs_currentdevicecolor_inline(pgs);
206	283	const gs_gstate pgs2 = (const gs_gstate )pgs;
207	283	bool hl_color_available = gx_hld_is_hl_color_available(pgs2, pdc);
208	283	bool hl_color = (hl_color_available &&
209	283	dev_proc(pdev, dev_spec_op)(pdev, gxdso_supports_hlcolor,
210	283	NULL, 0));
211	283	bool center_of_pixel = (pgs->fill_adjust.x == 0 && pgs->fill_adjust.y == 0);
212	283	bool black_vector = false;
213
214		/* Processing a fill object operation */
215	283	ensure_tag_is_set(pgs, pgs->device, GS_VECTOR_TAG); /* NB: may unset_dev_color */
216
217	283	black_vector = black_vectors(pgs, pgs->device); /* Set vector fill to black */
218
219	283	code = gx_set_dev_color(pgs);
220	283	if (code != 0)
221	0	goto exit;
222
223	283	if ( !(pgs->device->page_uses_transparency \|\|
224	283	dev_proc(pgs->device, dev_spec_op)(pgs->device,
225	283	gxdso_is_pdf14_device, &(pgs->device),
226	283	sizeof(pgs->device))) &&
227	283	(is_fzero2(pgs->ctm.xy, pgs->ctm.yx) \|\|
228	269	is_fzero2(pgs->ctm.xx, pgs->ctm.yy)) &&
229	283	gx_effective_clip_path(pgs, &pcpath) >= 0 &&
230	283	clip_list_is_rectangle(gx_cpath_list(pcpath)) &&
231	283	(hl_color \|\|
232	268	pdc->type == gx_dc_type_pure \|\|
233	268	pdc->type == gx_dc_type_ht_binary \|\|
234	268	pdc->type == gx_dc_type_ht_colored) &&
235	283	gs_gstate_color_load(pgs) >= 0 &&
236	283	(*dev_proc(pdev, get_alpha_bits)) (pdev, go_graphics)
237	268	<= 1 &&
238	283	(!pgs->overprint \|\| !gs_currentcolor_eopm(pgs))
239	283	) {
240	268	uint i;
241	268	gs_fixed_rect clip_rect;
242
243	268	gx_cpath_inner_box(pcpath, &clip_rect);
244		/* We should never plot anything for an empty clip rectangle */
245	268	if ((clip_rect.p.x >= clip_rect.q.x) &&
246	268	(clip_rect.p.y >= clip_rect.q.y))
247	0	goto exit;
248	533	for (i = 0; i < count; ++i) {
249	267	gs_fixed_point p, q;
250	267	gs_fixed_rect draw_rect;
251
252	267	if (gs_point_transform2fixed(&pgs->ctm, pr[i].p.x, pr[i].p.y, &p) < 0 \|\|
253	267	gs_point_transform2fixed(&pgs->ctm, pr[i].q.x, pr[i].q.y, &q) < 0
254	267	) { /* Switch to the slow algorithm. */
255	2	goto slow;
256	2	}
257	265	draw_rect.p.x = min(p.x, q.x);
258	265	draw_rect.p.y = min(p.y, q.y);
259	265	draw_rect.q.x = max(p.x, q.x);
260	265	draw_rect.q.y = max(p.y, q.y);
261	265	if (hl_color) {
262	0	rect_intersect(draw_rect, clip_rect);
263		/* We do pass on 0 extant rectangles to high level
264		devices. It isn't clear how a client and an output
265		device should interact if one uses a center of
266		pixel algorithm and the other uses any part of
267		pixel. For now we punt and just pass the high
268		level rectangle on without adjustment. */
269	0	if (draw_rect.p.x <= draw_rect.q.x &&
270	0	draw_rect.p.y <= draw_rect.q.y) {
271	0	code = dev_proc(pdev, fill_rectangle_hl_color)(pdev,
272	0	&draw_rect, pgs2, pdc, pcpath);
273	0	if (code < 0)
274	0	goto exit;
275	0	}
276	265	} else {
277	265	int x, y, w, h;
278
279	265	rect_intersect(draw_rect, clip_rect);
280	265	if (center_of_pixel) {
281	0	draw_rect.p.x = fixed_rounded(draw_rect.p.x);
282	0	draw_rect.p.y = fixed_rounded(draw_rect.p.y);
283	0	draw_rect.q.x = fixed_rounded(draw_rect.q.x);
284	0	draw_rect.q.y = fixed_rounded(draw_rect.q.y);
285	265	} else { /* any part of pixel rule - touched */
286	265	draw_rect.p.x = fixed_floor(draw_rect.p.x);
287	265	draw_rect.p.y = fixed_floor(draw_rect.p.y);
288	265	draw_rect.q.x = fixed_ceiling(draw_rect.q.x);
289	265	draw_rect.q.y = fixed_ceiling(draw_rect.q.y);
290	265	}
291	265	x = fixed2int(draw_rect.p.x);
292	265	y = fixed2int(draw_rect.p.y);
293	265	w = fixed2int(draw_rect.q.x) - x;
294	265	h = fixed2int(draw_rect.q.y) - y;
295		/* clients that use the "any part of pixel" rule also
296		fill 0 areas. This is true of current graphics
297		library clients but not a general rule. */
298	265	if (!center_of_pixel) {
299	265	if (w == 0)
300	2	w = 1;
301		/* yes Adobe Acrobat 8, seems to back up the y
302		coordinate when the width is 0, sigh. */
303	265	if (h == 0) {
304	1	y--;
305	1	h = 1;
306	1	}
307	265	}
308	265	if (gx_fill_rectangle(x, y, w, h, pdc, pgs) < 0)
309	0	goto slow;
310	265	}
311	265	}
312	266	code = 0;
313	266	goto exit;
314	2	slow:rlist = pr + i;
315	2	rcount = count - i;
316	17	} {
317	17	bool do_save = !gx_path_is_null(pgs->path);
318
319	17	if (do_save) {
320	0	if ((code = gs_gsave(pgs)) < 0)
321	0	goto exit;
322	0	code = gs_newpath(pgs);
323	0	}
324	17	if ((code >= 0) &&
325	17	(((code = gs_rectappend(pgs, rlist, rcount)) < 0) \|\|
326	17	((code = gs_fill(pgs)) < 0))
327	17	)
328	17	DO_NOTHING;
329	17	if (do_save)
330	0	gs_grestore(pgs);
331	17	else if (code < 0)
332	0	gs_newpath(pgs);
333	17	}
334
335	283	exit:
336	283	if (black_vector) {
337		/* Restore color */
338	0	gsicc_restore_blacktextvec(pgs, false);
339	0	}
340	283	return code;
341	17	}
342
343		/* Stroke a list of rectangles. */
344		/* (We could do this a lot more efficiently.) */
345		int
346		gs_rectstroke(gs_gstate * pgs, const gs_rect * pr, uint count,
347		const gs_matrix * pmat)
348	73	{
349	73	bool do_save = pmat != NULL \|\| !gx_path_is_null(pgs->path);
350	73	int code;
351
352	73	if (do_save) {
353	0	if ((code = gs_gsave(pgs)) < 0)
354	0	return code;
355	0	gs_newpath(pgs);
356	0	}
357	73	if ((code = gs_rectappend(pgs, pr, count)) < 0 \|\|
358	73	(pmat != NULL && (code = gs_concat(pgs, pmat)) < 0) \|\|
359	73	(code = gs_stroke(pgs)) < 0
360	73	)
361	73	DO_NOTHING;
362	73	if (do_save)
363	0	gs_grestore(pgs);
364	73	else if (code < 0)
365	0	gs_newpath(pgs);
366	73	return code;
367	73	}