/src/ghostpdl/base/gxshade.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.
*/


/* Shading rendering support */
#include "math_.h"
#include "gx.h"
#include "gserrors.h"
#include "gsrect.h"
#include "gxcspace.h"
#include "gscindex.h"
#include "gscie.h"    /* requires gscspace.h */
#include "gxdevcli.h"
#include "gxgstate.h"
#include "gxdht.h"    /* for computing # of different colors */
#include "gxpaint.h"
#include "gxshade.h"
#include "gxshade4.h"
#include "gsicc.h"
#include "gsicc_cache.h"
#include "gxcdevn.h"
#include "gximage.h"

/* Define a maximum smoothness value. */
/* smoothness > 0.2 produces severely blocky output. */
#define MAX_SMOOTHNESS 0.2

/* ================ Packed coordinate streams ================ */

/* Forward references */
static int cs_next_packed_value(shade_coord_stream_t *, int, uint *);
static int cs_next_array_value(shade_coord_stream_t *, int, uint *);
static int cs_next_packed_decoded(shade_coord_stream_t *, int,
                                   const float[2], float *);
static int cs_next_array_decoded(shade_coord_stream_t *, int,
                                  const float[2], float *);
static void cs_packed_align(shade_coord_stream_t *cs, int radix);
static void cs_array_align(shade_coord_stream_t *cs, int radix);
static bool cs_eod(const shade_coord_stream_t * cs);

/* Initialize a packed value stream. */
void
shade_next_init(shade_coord_stream_t * cs,
                const gs_shading_mesh_params_t * params,
                const gs_gstate * pgs)
{
    cs->params = params;
    cs->pctm = &pgs->ctm;
    if (data_source_is_stream(params->DataSource)) {
        /*
         * Rewind the data stream iff it is reusable -- either a reusable
         * file or a reusable string.
         */
        stream *s = cs->s = params->DataSource.data.strm;

        if ((s->file != 0 && s->file_limit != max_long) ||
            (s->file == 0 && s->strm == 0)
            )
            sseek(s, 0);
    } else {
        s_init(&cs->ds, NULL);
        sread_string(&cs->ds, params->DataSource.data.str.data,
                     params->DataSource.data.str.size);
        cs->s = &cs->ds;
    }
    if (data_source_is_array(params->DataSource)) {
        cs->get_value = cs_next_array_value;
        cs->get_decoded = cs_next_array_decoded;
        cs->align = cs_array_align;
    } else {
        cs->get_value = cs_next_packed_value;
        cs->get_decoded = cs_next_packed_decoded;
        cs->align = cs_packed_align;
    }
    cs->is_eod = cs_eod;
    cs->left = 0;
    cs->ds_EOF = false;
    cs->first_patch = 1;
}

/* Check for the End-Of-Data state form a stream. */
static bool
cs_eod(const shade_coord_stream_t * cs)
{
    return cs->ds_EOF;
}

/* Get the next (integer) value from a packed value stream. */
/* 1 <= num_bits <= sizeof(uint) * 8. */
static int
cs_next_packed_value(shade_coord_stream_t * cs, int num_bits, uint * pvalue)
{
    uint bits = cs->bits;
    int left = cs->left;

    if (left >= num_bits) {
        /* We can satisfy this request with the current buffered bits. */
        cs->left = left -= num_bits;
        *pvalue = (bits >> left) & ((1 << num_bits) - 1);
    } else {
        /* We need more bits. */
        int needed = num_bits - left;
        uint value = bits & ((1 << left) - 1);  /* all the remaining bits */

        for (; needed >= 8; needed -= 8) {
            int b = sgetc(cs->s);

            if (b < 0) {
                cs->ds_EOF = true;
                return_error(gs_error_rangecheck);
            }
            value = (value << 8) + b;
        }
        if (needed == 0) {
            cs->left = 0;
            *pvalue = value;
        } else {
            int b = sgetc(cs->s);

            if (b < 0) {
                cs->ds_EOF = true;
                return_error(gs_error_rangecheck);
            }
            cs->bits = b;
            cs->left = left = 8 - needed;
            *pvalue = (value << needed) + (b >> left);
        }
    }
    return 0;
}

/*
 * Get the next (integer) value from an unpacked array.  Note that
 * num_bits may be 0 if we are reading a coordinate or color value.
 */
static int
cs_next_array_value(shade_coord_stream_t * cs, int num_bits, uint * pvalue)
{
    float value;
    uint read;

    if (sgets(cs->s, (byte *)&value, sizeof(float), &read) < 0 ||
        read != sizeof(float)) {
        cs->ds_EOF = true;
        return_error(gs_error_rangecheck);
    }
    if (value < 0 || (num_bits != 0 && num_bits < sizeof(uint) * 8 &&
         value >= (1 << num_bits)) ||
        value != (uint)value
        )
        return_error(gs_error_rangecheck);
    *pvalue = (uint) value;
    return 0;
}

/* Get the next decoded floating point value. */
static int
cs_next_packed_decoded(shade_coord_stream_t * cs, int num_bits,
                       const float decode[2], float *pvalue)
{
    uint value;
    int code = cs->get_value(cs, num_bits, &value);
    double max_value = (double)(uint)
        (num_bits == sizeof(uint) * 8 ? ~0 : ((1 << num_bits) - 1));
    double dvalue = (double)value;

    if (code < 0)
        return code;
    *pvalue =
        (decode == 0 ? dvalue / max_value :
         decode[0] + dvalue * (decode[1] - decode[0]) / max_value);
    return 0;
}

/* Get the next floating point value from an array, without decoding. */
static int
cs_next_array_decoded(shade_coord_stream_t * cs, int num_bits,
                      const float decode[2], float *pvalue)
{
    float value;
    uint read;

    if (sgets(cs->s, (byte *)&value, sizeof(float), &read) < 0 ||
        read != sizeof(float)
    ) {
        cs->ds_EOF = true;
        return_error(gs_error_rangecheck);
    }
    *pvalue = value;
    return 0;
}

static void
cs_packed_align(shade_coord_stream_t *cs, int radix)
{
    cs->left = cs->left / radix * radix;
}

static void
cs_array_align(shade_coord_stream_t *cs, int radix)
{
}

/* Get the next flag value. */
/* Note that this always starts a new data byte. */
int
shade_next_flag(shade_coord_stream_t * cs, int BitsPerFlag)
{
    uint flag;
    int code;

    cs->left = 0;   /* start a new byte if packed */
    code = cs->get_value(cs, BitsPerFlag, &flag);
    return (code < 0 ? code : flag);
}

/* Get one or more coordinate pairs. */
int
shade_next_coords(shade_coord_stream_t * cs, gs_fixed_point * ppt,
                  int num_points)
{
    int num_bits = cs->params->BitsPerCoordinate;
    const float *decode = cs->params->Decode;
    int code = 0;
    int i;

    for (i = 0; i < num_points; ++i) {
        float x, y;

        if ((code = cs->get_decoded(cs, num_bits, decode, &x)) < 0 ||
            (code = cs->get_decoded(cs, num_bits, decode + 2, &y)) < 0 ||
            (code = gs_point_transform2fixed(cs->pctm, x, y, &ppt[i])) < 0
            )
            break;
    }
    return code;
}

/* Get a color.  Currently all this does is look up Indexed colors. */
int
shade_next_color(shade_coord_stream_t * cs, float *pc)
{
    const float *decode = cs->params->Decode + 4; /* skip coord decode */
    const gs_color_space *pcs = cs->params->ColorSpace;
    gs_color_space_index index = gs_color_space_get_index(pcs);
    int num_bits = cs->params->BitsPerComponent;

    if (index == gs_color_space_index_Indexed) {
        int ncomp = gs_color_space_num_components(gs_cspace_base_space(pcs));
        int ci;
        float cf;
        int code = cs->get_decoded(cs, num_bits, decode, &cf);
        gs_client_color cc;
        int i;

        if (code < 0)
            return code;
        if (cf < 0)
            return_error(gs_error_rangecheck);
        ci = (int)cf;
        if (ci >= gs_cspace_indexed_num_entries(pcs))
            return_error(gs_error_rangecheck);
        code = gs_cspace_indexed_lookup(pcs, ci, &cc);
        if (code < 0)
            return code;
        for (i = 0; i < ncomp; ++i)
            pc[i] = cc.paint.values[i];
    } else {
        int i, code;
        int ncomp = (cs->params->Function != 0 ? 1 :
                     gs_color_space_num_components(pcs));

        for (i = 0; i < ncomp; ++i) {
            if ((code = cs->get_decoded(cs, num_bits, decode + i * 2, &pc[i])) < 0)
                return code;
            if (cs->params->Function) {
                gs_function_params_t *params = &cs->params->Function->params;

                if (pc[i] < params->Domain[i + i])
                    pc[i] = params->Domain[i + i];
                else if (pc[i] > params->Domain[i + i + 1])
                    pc[i] = params->Domain[i + i + 1];
            }
        }
    }
    return 0;
}

/* Get the next vertex for a mesh element. */
int
shade_next_vertex(shade_coord_stream_t * cs, shading_vertex_t * vertex, patch_color_t *c)
{   /* Assuming p->c == c, provides a non-const access. */
    int code = shade_next_coords(cs, &vertex->p, 1);

    if (code >= 0)
        code = shade_next_color(cs, c->cc.paint.values);
    if (code >= 0)
        cs->align(cs, 8); /* CET 09-47J.PS SpecialTestI04Test01. */
    return code;
}

/* ================ Shading rendering ================ */

/* Initialize the common parts of the recursion state. */
int
shade_init_fill_state(shading_fill_state_t * pfs, const gs_shading_t * psh,
                      gx_device * dev, gs_gstate * pgs)
{
    const gs_color_space *pcs = psh->params.ColorSpace;
    float max_error = min(pgs->smoothness, MAX_SMOOTHNESS);
    bool is_lab;
    bool cs_lin_test;
    int code;

    /*
     * There's no point in trying to achieve smoothness beyond what
     * the device can implement, i.e., the number of representable
     * colors times the number of halftone levels.
     */
    long num_colors =
        max(dev->color_info.max_gray, dev->color_info.max_color) + 1;
    const gs_range *ranges = 0;
    int ci;
    gsicc_rendering_param_t rendering_params;

    pfs->cs_always_linear = false;
    pfs->dev = dev;
    pfs->pgs = pgs;
top:
    pfs->direct_space = pcs;
    pfs->num_components = gs_color_space_num_components(pcs);
    switch ( gs_color_space_get_index(pcs) )
        {
        case gs_color_space_index_Indexed:
            pcs = gs_cspace_base_space(pcs);
            goto top;
        case gs_color_space_index_CIEDEFG:
            ranges = pcs->params.defg->RangeDEFG.ranges;
            break;
        case gs_color_space_index_CIEDEF:
            ranges = pcs->params.def->RangeDEF.ranges;
            break;
        case gs_color_space_index_CIEABC:
            ranges = pcs->params.abc->RangeABC.ranges;
            break;
        case gs_color_space_index_CIEA:
            ranges = &pcs->params.a->RangeA;
            break;
        case gs_color_space_index_ICC:
            ranges = pcs->cmm_icc_profile_data->Range.ranges;
            break;
        default:
            break;
        }
    if (num_colors <= 32) {
        /****** WRONG FOR MULTI-PLANE HALFTONES ******/
        num_colors *= pgs->dev_ht[HT_OBJTYPE_DEFAULT]->components[0].corder.num_levels;
    }
    if (psh->head.type == 2 || psh->head.type == 3) {
        max_error *= 0.25;
        num_colors *= 2;
    }
    if (max_error < 1.0 / num_colors)
        max_error = 1.0 / num_colors;
    for (ci = 0; ci < pfs->num_components; ++ci)
        pfs->cc_max_error[ci] =
            (ranges == 0 ? max_error :
             max_error * (ranges[ci].rmax - ranges[ci].rmin));
    if (pgs->has_transparency && pgs->trans_device != NULL) {
        pfs->trans_device = pgs->trans_device;
    } else {
        pfs->trans_device = dev;
    }
    /* If the CS is PS based and we have not yet converted to the ICC form
       then go ahead and do that now */
    if (gs_color_space_is_PSCIE(pcs) && pcs->icc_equivalent == NULL) {
        code = gs_colorspace_set_icc_equivalent((gs_color_space *)pcs, &(is_lab), pgs->memory);
        if (code < 0)
            return code;
    }
    rendering_params.black_point_comp = pgs->blackptcomp;
    rendering_params.graphics_type_tag = GS_VECTOR_TAG;
    rendering_params.override_icc = false;
    rendering_params.preserve_black = gsBKPRESNOTSPECIFIED;
    rendering_params.rendering_intent = pgs->renderingintent;
    rendering_params.cmm = gsCMM_DEFAULT;
    /* Grab the icc link transform that we need now */
    if (pcs->cmm_icc_profile_data != NULL) {
        pfs->icclink = gsicc_get_link(pgs, pgs->trans_device, pcs, NULL,
                                      &rendering_params, pgs->memory);
        if (pfs->icclink == NULL)
            return_error(gs_error_VMerror);
    } else {
        if (pcs->icc_equivalent != NULL ) {
            /* We have a PS equivalent ICC profile.  We may need to go
               through special range adjustments in this case */
            pfs->icclink = gsicc_get_link(pgs, pgs->trans_device,
                                          pcs->icc_equivalent, NULL,
                                          &rendering_params, pgs->memory);
            if (pfs->icclink == NULL)
                return_error(gs_error_VMerror);
        } else {
            pfs->icclink = NULL;
        }
    }
    /* Two possible cases of interest here for performance.  One is that the
    * icclink is NULL, which could occur if the source space were DeviceN or
    * a separation color space, while at the same time, the output device
    * supports these colorants (e.g. a separation device).   The other case is
    * that the icclink is the identity.  This could happen for example if the
    * source space were CMYK and we are going out to a CMYK device. For both
    * of these cases we can avoid going through the standard
    * color mappings to determine linearity. This is true, provided that the
    * transfer function is linear.  It is likely that we can improve
    * things even in cases where the transfer function is nonlinear, but for
    * now, we will punt on those and let them go through the longer processing
    * steps */
    if (pfs->icclink == NULL)
            cs_lin_test = !(using_alt_color_space((gs_gstate*)pgs));
    else
        cs_lin_test = pfs->icclink->is_identity;

    if (cs_lin_test && !gx_has_transfer(pgs, dev->color_info.num_components)) {
        pfs->cs_always_linear = true;
    }

#ifdef IGNORE_SPEC_MATCH_ADOBE_SHADINGS
    /* Per the spec. If the source space is DeviceN or Separation and the
       colorants are not supported (i.e. if we are using the alternate tint
       transform) the interpolation should occur in the source space to
       accommodate non-linear tint transform functions.
       e.g. We had a case where the transform function
       was an increasing staircase. Including that function in the
       gradient smoothness calculation gave us severe quantization. AR on
       the other hand is doing the interpolation in device color space
       and has a smooth result for that case. So AR is not following the spec. The
       bit below solves the issues for Type 4 and Type 5 shadings as
       this will avoid interpolations in source space. Type 6 and Type 7 will still
       have interpolations in the source space even if pfs->cs_always_linear == true.
       So the approach below does not solve those issues. To do that
       without changing the shading code, we could make a linear
       approximation to the alternate tint transform, which would
       ensure smoothness like what AR provides.
    */
    if ((gs_color_space_get_index(pcs) == gs_color_space_index_DeviceN ||
        gs_color_space_get_index(pcs) == gs_color_space_index_Separation) &&
        using_alt_color_space((gs_gstate*)pgs) && (psh->head.type == 4 ||
        psh->head.type == 5)) {
        pfs->cs_always_linear = true;
    }
#endif

    return 0;
}

/* Fill one piece of a shading. */
int
shade_fill_path(const shading_fill_state_t * pfs, gx_path * ppath,
                gx_device_color * pdevc, const gs_fixed_point *fill_adjust)
{
    gx_fill_params params;

    params.rule = -1;   /* irrelevant */
    params.adjust = *fill_adjust;
    params.flatness = 0;  /* irrelevant */
    return (*dev_proc(pfs->dev, fill_path)) (pfs->dev, pfs->pgs, ppath,
                                             &params, pdevc, NULL);
}

Coverage Report

Created: 2025-06-10 06:58

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		/* Shading rendering support */
18		#include "math_.h"
19		#include "gx.h"
20		#include "gserrors.h"
21		#include "gsrect.h"
22		#include "gxcspace.h"
23		#include "gscindex.h"
24		#include "gscie.h" /* requires gscspace.h */
25		#include "gxdevcli.h"
26		#include "gxgstate.h"
27		#include "gxdht.h" /* for computing # of different colors */
28		#include "gxpaint.h"
29		#include "gxshade.h"
30		#include "gxshade4.h"
31		#include "gsicc.h"
32		#include "gsicc_cache.h"
33		#include "gxcdevn.h"
34		#include "gximage.h"
35
36		/* Define a maximum smoothness value. */
37		/* smoothness > 0.2 produces severely blocky output. */
38		#define MAX_SMOOTHNESS 0.2
39
40		/* ================ Packed coordinate streams ================ */
41
42		/* Forward references */
43		static int cs_next_packed_value(shade_coord_stream_t , int, uint );
44		static int cs_next_array_value(shade_coord_stream_t , int, uint );
45		static int cs_next_packed_decoded(shade_coord_stream_t *, int,
46		const float[2], float *);
47		static int cs_next_array_decoded(shade_coord_stream_t *, int,
48		const float[2], float *);
49		static void cs_packed_align(shade_coord_stream_t *cs, int radix);
50		static void cs_array_align(shade_coord_stream_t *cs, int radix);
51		static bool cs_eod(const shade_coord_stream_t * cs);
52
53		/* Initialize a packed value stream. */
54		void
55		shade_next_init(shade_coord_stream_t * cs,
56		const gs_shading_mesh_params_t * params,
57		const gs_gstate * pgs)
58	88	{
59	88	cs->params = params;
60	88	cs->pctm = &pgs->ctm;
61	88	if (data_source_is_stream(params->DataSource)) {
62		/*
63		* Rewind the data stream iff it is reusable -- either a reusable
64		* file or a reusable string.
65		*/
66	88	stream *s = cs->s = params->DataSource.data.strm;
67
68	88	if ((s->file != 0 && s->file_limit != max_long) \|\|
69	88	(s->file == 0 && s->strm == 0)
70	88	)
71	88	sseek(s, 0);
72	88	} else {
73	0	s_init(&cs->ds, NULL);
74	0	sread_string(&cs->ds, params->DataSource.data.str.data,
75	0	params->DataSource.data.str.size);
76	0	cs->s = &cs->ds;
77	0	}
78	88	if (data_source_is_array(params->DataSource)) {
79	0	cs->get_value = cs_next_array_value;
80	0	cs->get_decoded = cs_next_array_decoded;
81	0	cs->align = cs_array_align;
82	88	} else {
83	88	cs->get_value = cs_next_packed_value;
84	88	cs->get_decoded = cs_next_packed_decoded;
85	88	cs->align = cs_packed_align;
86	88	}
87	88	cs->is_eod = cs_eod;
88	88	cs->left = 0;
89	88	cs->ds_EOF = false;
90	88	cs->first_patch = 1;
91	88	}
92
93		/* Check for the End-Of-Data state form a stream. */
94		static bool
95		cs_eod(const shade_coord_stream_t * cs)
96	48	{
97	48	return cs->ds_EOF;
98	48	}
99
100		/* Get the next (integer) value from a packed value stream. */
101		/* 1 <= num_bits <= sizeof(uint) * 8. */
102		static int
103		cs_next_packed_value(shade_coord_stream_t * cs, int num_bits, uint * pvalue)
104	801k	{
105	801k	uint bits = cs->bits;
106	801k	int left = cs->left;
107
108	801k	if (left >= num_bits) {
109		/* We can satisfy this request with the current buffered bits. */
110	0	cs->left = left -= num_bits;
111	0	*pvalue = (bits >> left) & ((1 << num_bits) - 1);
112	801k	} else {
113		/* We need more bits. */
114	801k	int needed = num_bits - left;
115	801k	uint value = bits & ((1 << left) - 1); /* all the remaining bits */
116
117	3.17M	for (; needed >= 8; needed -= 8) {
118	2.36M	int b = sgetc(cs->s);
119
120	2.36M	if (b < 0) {
121	82	cs->ds_EOF = true;
122	82	return_error(gs_error_rangecheck);
123	82	}
124	2.36M	value = (value << 8) + b;
125	2.36M	}
126	801k	if (needed == 0) {
127	801k	cs->left = 0;
128	801k	*pvalue = value;
129	801k	} else {
130	0	int b = sgetc(cs->s);
131
132	0	if (b < 0) {
133	0	cs->ds_EOF = true;
134	0	return_error(gs_error_rangecheck);
135	0	}
136	0	cs->bits = b;
137	0	cs->left = left = 8 - needed;
138	0	*pvalue = (value << needed) + (b >> left);
139	0	}
140	801k	}
141	801k	return 0;
142	801k	}
143
144		/*
145		* Get the next (integer) value from an unpacked array. Note that
146		* num_bits may be 0 if we are reading a coordinate or color value.
147		*/
148		static int
149		cs_next_array_value(shade_coord_stream_t * cs, int num_bits, uint * pvalue)
150	0	{
151	0	float value;
152	0	uint read;
153
154	0	if (sgets(cs->s, (byte *)&value, sizeof(float), &read) < 0 \|\|
155	0	read != sizeof(float)) {
156	0	cs->ds_EOF = true;
157	0	return_error(gs_error_rangecheck);
158	0	}
159	0	if (value < 0 \|\| (num_bits != 0 && num_bits < sizeof(uint) * 8 &&
160	0	value >= (1 << num_bits)) \|\|
161	0	value != (uint)value
162	0	)
163	0	return_error(gs_error_rangecheck);
164	0	*pvalue = (uint) value;
165	0	return 0;
166	0	}
167
168		/* Get the next decoded floating point value. */
169		static int
170		cs_next_packed_decoded(shade_coord_stream_t * cs, int num_bits,
171		const float decode[2], float *pvalue)
172	784k	{
173	784k	uint value;
174	784k	int code = cs->get_value(cs, num_bits, &value);
175	784k	double max_value = (double)(uint)
176	784k	(num_bits == sizeof(uint) * 8 ? ~0 : ((1 << num_bits) - 1));
177	784k	double dvalue = (double)value;
178
179	784k	if (code < 0)
180	39	return code;
181	784k	*pvalue =
182	784k	(decode == 0 ? dvalue / max_value :
183	784k	decode[0] + dvalue * (decode[1] - decode[0]) / max_value);
184	784k	return 0;
185	784k	}
186
187		/* Get the next floating point value from an array, without decoding. */
188		static int
189		cs_next_array_decoded(shade_coord_stream_t * cs, int num_bits,
190		const float decode[2], float *pvalue)
191	0	{
192	0	float value;
193	0	uint read;
194
195	0	if (sgets(cs->s, (byte *)&value, sizeof(float), &read) < 0 \|\|
196	0	read != sizeof(float)
197	0	) {
198	0	cs->ds_EOF = true;
199	0	return_error(gs_error_rangecheck);
200	0	}
201	0	*pvalue = value;
202	0	return 0;
203	0	}
204
205		static void
206		cs_packed_align(shade_coord_stream_t *cs, int radix)
207	78.0k	{
208	78.0k	cs->left = cs->left / radix * radix;
209	78.0k	}
210
211		static void
212		cs_array_align(shade_coord_stream_t *cs, int radix)
213	0	{
214	0	}
215
216		/* Get the next flag value. */
217		/* Note that this always starts a new data byte. */
218		int
219		shade_next_flag(shade_coord_stream_t * cs, int BitsPerFlag)
220	17.2k	{
221	17.2k	uint flag;
222	17.2k	int code;
223
224	17.2k	cs->left = 0; /* start a new byte if packed */
225	17.2k	code = cs->get_value(cs, BitsPerFlag, &flag);
226	17.2k	return (code < 0 ? code : flag);
227	17.2k	}
228
229		/* Get one or more coordinate pairs. */
230		int
231		shade_next_coords(shade_coord_stream_t * cs, gs_fixed_point * ppt,
232		int num_points)
233	175k	{
234	175k	int num_bits = cs->params->BitsPerCoordinate;
235	175k	const float *decode = cs->params->Decode;
236	175k	int code = 0;
237	175k	int i;
238
239	446k	for (i = 0; i < num_points; ++i) {
240	270k	float x, y;
241
242	270k	if ((code = cs->get_decoded(cs, num_bits, decode, &x)) < 0 \|\|
243	270k	(code = cs->get_decoded(cs, num_bits, decode + 2, &y)) < 0 \|\|
244	270k	(code = gs_point_transform2fixed(cs->pctm, x, y, &ppt[i])) < 0
245	270k	)
246	25	break;
247	270k	}
248	175k	return code;
249	175k	}
250
251		/* Get a color. Currently all this does is look up Indexed colors. */
252		int
253		shade_next_color(shade_coord_stream_t * cs, float *pc)
254	108k	{
255	108k	const float decode = cs->params->Decode + 4; / skip coord decode */
256	108k	const gs_color_space *pcs = cs->params->ColorSpace;
257	108k	gs_color_space_index index = gs_color_space_get_index(pcs);
258	108k	int num_bits = cs->params->BitsPerComponent;
259
260	108k	if (index == gs_color_space_index_Indexed) {
261	0	int ncomp = gs_color_space_num_components(gs_cspace_base_space(pcs));
262	0	int ci;
263	0	float cf;
264	0	int code = cs->get_decoded(cs, num_bits, decode, &cf);
265	0	gs_client_color cc;
266	0	int i;
267
268	0	if (code < 0)
269	0	return code;
270	0	if (cf < 0)
271	0	return_error(gs_error_rangecheck);
272	0	ci = (int)cf;
273	0	if (ci >= gs_cspace_indexed_num_entries(pcs))
274	0	return_error(gs_error_rangecheck);
275	0	code = gs_cspace_indexed_lookup(pcs, ci, &cc);
276	0	if (code < 0)
277	0	return code;
278	0	for (i = 0; i < ncomp; ++i)
279	0	pc[i] = cc.paint.values[i];
280	108k	} else {
281	108k	int i, code;
282	108k	int ncomp = (cs->params->Function != 0 ? 1 :
283	108k	gs_color_space_num_components(pcs));
284
285	351k	for (i = 0; i < ncomp; ++i) {
286	242k	if ((code = cs->get_decoded(cs, num_bits, decode + i * 2, &pc[i])) < 0)
287	14	return code;
288	242k	if (cs->params->Function) {
289	59.9k	gs_function_params_t *params = &cs->params->Function->params;
290
291	59.9k	if (pc[i] < params->Domain[i + i])
292	0	pc[i] = params->Domain[i + i];
293	59.9k	else if (pc[i] > params->Domain[i + i + 1])
294	0	pc[i] = params->Domain[i + i + 1];
295	59.9k	}
296	242k	}
297	108k	}
298	108k	return 0;
299	108k	}
300
301		/* Get the next vertex for a mesh element. */
302		int
303		shade_next_vertex(shade_coord_stream_t * cs, shading_vertex_t * vertex, patch_color_t *c)
304	62.6k	{ /* Assuming p->c == c, provides a non-const access. */
305	62.6k	int code = shade_next_coords(cs, &vertex->p, 1);
306
307	62.6k	if (code >= 0)
308	62.6k	code = shade_next_color(cs, c->cc.paint.values);
309	62.6k	if (code >= 0)
310	62.6k	cs->align(cs, 8); /* CET 09-47J.PS SpecialTestI04Test01. */
311	62.6k	return code;
312	62.6k	}
313
314		/* ================ Shading rendering ================ */
315
316		/* Initialize the common parts of the recursion state. */
317		int
318		shade_init_fill_state(shading_fill_state_t * pfs, const gs_shading_t * psh,
319		gx_device * dev, gs_gstate * pgs)
320	1.87k	{
321	1.87k	const gs_color_space *pcs = psh->params.ColorSpace;
322	1.87k	float max_error = min(pgs->smoothness, MAX_SMOOTHNESS);
323	1.87k	bool is_lab;
324	1.87k	bool cs_lin_test;
325	1.87k	int code;
326
327		/*
328		* There's no point in trying to achieve smoothness beyond what
329		* the device can implement, i.e., the number of representable
330		* colors times the number of halftone levels.
331		*/
332	1.87k	long num_colors =
333	1.87k	max(dev->color_info.max_gray, dev->color_info.max_color) + 1;
334	1.87k	const gs_range *ranges = 0;
335	1.87k	int ci;
336	1.87k	gsicc_rendering_param_t rendering_params;
337
338	1.87k	pfs->cs_always_linear = false;
339	1.87k	pfs->dev = dev;
340	1.87k	pfs->pgs = pgs;
341	1.87k	top:
342	1.87k	pfs->direct_space = pcs;
343	1.87k	pfs->num_components = gs_color_space_num_components(pcs);
344	1.87k	switch ( gs_color_space_get_index(pcs) )
345	1.87k	{
346	0	case gs_color_space_index_Indexed:
347	0	pcs = gs_cspace_base_space(pcs);
348	0	goto top;
349	0	case gs_color_space_index_CIEDEFG:
350	0	ranges = pcs->params.defg->RangeDEFG.ranges;
351	0	break;
352	0	case gs_color_space_index_CIEDEF:
353	0	ranges = pcs->params.def->RangeDEF.ranges;
354	0	break;
355	0	case gs_color_space_index_CIEABC:
356	0	ranges = pcs->params.abc->RangeABC.ranges;
357	0	break;
358	0	case gs_color_space_index_CIEA:
359	0	ranges = &pcs->params.a->RangeA;
360	0	break;
361	1.15k	case gs_color_space_index_ICC:
362	1.15k	ranges = pcs->cmm_icc_profile_data->Range.ranges;
363	1.15k	break;
364	717	default:
365	717	break;
366	1.87k	}
367	1.87k	if (num_colors <= 32) {
368		/**** WRONG FOR MULTI-PLANE HALFTONES ****/
369	458	num_colors *= pgs->dev_ht[HT_OBJTYPE_DEFAULT]->components[0].corder.num_levels;
370	458	}
371	1.87k	if (psh->head.type == 2 \|\| psh->head.type == 3) {
372	1.78k	max_error *= 0.25;
373	1.78k	num_colors *= 2;
374	1.78k	}
375	1.87k	if (max_error < 1.0 / num_colors)
376	458	max_error = 1.0 / num_colors;
377	6.54k	for (ci = 0; ci < pfs->num_components; ++ci)
378	4.67k	pfs->cc_max_error[ci] =
379	4.67k	(ranges == 0 ? max_error :
380	4.67k	max_error * (ranges[ci].rmax - ranges[ci].rmin));
381	1.87k	if (pgs->has_transparency && pgs->trans_device != NULL) {
382	1.41k	pfs->trans_device = pgs->trans_device;
383	1.41k	} else {
384	458	pfs->trans_device = dev;
385	458	}
386		/* If the CS is PS based and we have not yet converted to the ICC form
387		then go ahead and do that now */
388	1.87k	if (gs_color_space_is_PSCIE(pcs) && pcs->icc_equivalent == NULL) {
389	0	code = gs_colorspace_set_icc_equivalent((gs_color_space *)pcs, &(is_lab), pgs->memory);
390	0	if (code < 0)
391	0	return code;
392	0	}
393	1.87k	rendering_params.black_point_comp = pgs->blackptcomp;
394	1.87k	rendering_params.graphics_type_tag = GS_VECTOR_TAG;
395	1.87k	rendering_params.override_icc = false;
396	1.87k	rendering_params.preserve_black = gsBKPRESNOTSPECIFIED;
397	1.87k	rendering_params.rendering_intent = pgs->renderingintent;
398	1.87k	rendering_params.cmm = gsCMM_DEFAULT;
399		/* Grab the icc link transform that we need now */
400	1.87k	if (pcs->cmm_icc_profile_data != NULL) {
401	1.15k	pfs->icclink = gsicc_get_link(pgs, pgs->trans_device, pcs, NULL,
402	1.15k	&rendering_params, pgs->memory);
403	1.15k	if (pfs->icclink == NULL)
404	2	return_error(gs_error_VMerror);
405	1.15k	} else {
406	717	if (pcs->icc_equivalent != NULL ) {
407		/* We have a PS equivalent ICC profile. We may need to go
408		through special range adjustments in this case */
409	0	pfs->icclink = gsicc_get_link(pgs, pgs->trans_device,
410	0	pcs->icc_equivalent, NULL,
411	0	&rendering_params, pgs->memory);
412	0	if (pfs->icclink == NULL)
413	0	return_error(gs_error_VMerror);
414	717	} else {
415	717	pfs->icclink = NULL;
416	717	}
417	717	}
418		/* Two possible cases of interest here for performance. One is that the
419		* icclink is NULL, which could occur if the source space were DeviceN or
420		* a separation color space, while at the same time, the output device
421		* supports these colorants (e.g. a separation device). The other case is
422		* that the icclink is the identity. This could happen for example if the
423		* source space were CMYK and we are going out to a CMYK device. For both
424		* of these cases we can avoid going through the standard
425		* color mappings to determine linearity. This is true, provided that the
426		* transfer function is linear. It is likely that we can improve
427		* things even in cases where the transfer function is nonlinear, but for
428		* now, we will punt on those and let them go through the longer processing
429		* steps */
430	1.86k	if (pfs->icclink == NULL)
431	717	cs_lin_test = !(using_alt_color_space((gs_gstate*)pgs));
432	1.15k	else
433	1.15k	cs_lin_test = pfs->icclink->is_identity;
434
435	1.86k	if (cs_lin_test && !gx_has_transfer(pgs, dev->color_info.num_components)) {
436	0	pfs->cs_always_linear = true;
437	0	}
438
439		#ifdef IGNORE_SPEC_MATCH_ADOBE_SHADINGS
440		/* Per the spec. If the source space is DeviceN or Separation and the
441		colorants are not supported (i.e. if we are using the alternate tint
442		transform) the interpolation should occur in the source space to
443		accommodate non-linear tint transform functions.
444		e.g. We had a case where the transform function
445		was an increasing staircase. Including that function in the
446		gradient smoothness calculation gave us severe quantization. AR on
447		the other hand is doing the interpolation in device color space
448		and has a smooth result for that case. So AR is not following the spec. The
449		bit below solves the issues for Type 4 and Type 5 shadings as
450		this will avoid interpolations in source space. Type 6 and Type 7 will still
451		have interpolations in the source space even if pfs->cs_always_linear == true.
452		So the approach below does not solve those issues. To do that
453		without changing the shading code, we could make a linear
454		approximation to the alternate tint transform, which would
455		ensure smoothness like what AR provides.
456		*/
457		if ((gs_color_space_get_index(pcs) == gs_color_space_index_DeviceN \|\|
458		gs_color_space_get_index(pcs) == gs_color_space_index_Separation) &&
459		using_alt_color_space((gs_gstate*)pgs) && (psh->head.type == 4 \|\|
460		psh->head.type == 5)) {
461		pfs->cs_always_linear = true;
462		}
463		#endif
464
465	1.86k	return 0;
466	1.87k	}
467
468		/* Fill one piece of a shading. */
469		int
470		shade_fill_path(const shading_fill_state_t * pfs, gx_path * ppath,
471		gx_device_color * pdevc, const gs_fixed_point *fill_adjust)
472	0	{
473	0	gx_fill_params params;
474
475	0	params.rule = -1; /* irrelevant */
476	0	params.adjust = *fill_adjust;
477	0	params.flatness = 0; /* irrelevant */
478	0	return (*dev_proc(pfs->dev, fill_path)) (pfs->dev, pfs->pgs, ppath,
479	0	&params, pdevc, NULL);
480	0	}