/src/ghostpdl/base/gdevm64.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.
*/

/* 64-bit-per-pixel "memory" (stored bitmap) device */
#include "memory_.h"
#include "gx.h"
#include "gxdevice.h"
#include "gxdevmem.h"   /* semi-public definitions */
#include "gdevmem.h"    /* private definitions */

/* Define debugging statistics. */
/* #define COLLECT_STATS_MEM64 */

#ifdef COLLECT_STATS_MEM64
struct stats_mem64_s {
    long
        fill, fwide, fgray[101], fsetc, fcolor[101], fnarrow[5],
        fprevc[257];
    double ftotal;
} stats_mem64;
static int prev_count = 0;
static gx_color_index prev_colors[256];
# define INCR(v) (++(stats_mem64.v))
#else
# define INCR(v) DO_NOTHING
#endif

/* ================ Standard (byte-oriented) device ================ */

#undef chunk
#define chunk byte
#define PIXEL_SIZE 2

/* Procedures */
declare_mem_procs(mem_true64_copy_mono, mem_true64_copy_color, mem_true64_fill_rectangle);

/* The device descriptor. */
const gx_device_memory mem_true64_device =
    mem_device("image64", 64, 0, mem_dev_initialize_device_procs);

const gdev_mem_functions gdev_mem_fns_64 =
{
    gx_default_rgb_map_rgb_color,
    gx_default_rgb_map_color_rgb,
    mem_true64_fill_rectangle,
    mem_true64_copy_mono,
    mem_true64_copy_color,
    gx_default_copy_alpha,
    gx_default_strip_tile_rectangle,
    mem_default_strip_copy_rop2,
    mem_get_bits_rectangle
};

/* Convert x coordinate to byte offset in scan line. */
#undef x_to_byte
#define x_to_byte(x) ((x) << 3)

/* Put a 64-bit color into the bitmap. */
#define put8(ptr, abcd, efgh)\
        (ptr)[0] = abcd, (ptr)[1] = efgh
/* Free variables: [m]dev, abcd, degh. */
#if ARCH_IS_BIG_ENDIAN
/* Unpack a color into 32 bit chunks. */
#  define declare_unpack_color(abcd, efgh, color)\
        bits32 abcd = (bits32)((color) >> 32);\
        bits32 efgh = (bits32)(color)
#else
/* Unpack a color into 32 bit chunks. */
#  define declare_unpack_color(abcd, efgh, color)\
        bits32 abcd = (bits32)((0x000000ff & (((color) >> 28) >> 28)) |\
                               (0x0000ff00 & (((color) >> 24) >> 16)) |\
                               (0x00ff0000 & ((color) >> 24)) |\
                               (0xff000000 & ((color) >> 8)));\
        bits32 efgh = (bits32)((0x000000ff & ((color) >> 24)) |\
                               (0x0000ff00 & ((color) >> 8)) |\
                               (0x00ff0000 & ((color) << 8)) |\
                               (0xff000000 & ((color) << 24)))
#endif
#define dest32 ((bits32 *)dest)

/* Fill a rectangle with a color. */
static int
mem_true64_fill_rectangle(gx_device * dev,
                          int x, int y, int w, int h, gx_color_index color)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;
    declare_scan_ptr(dest);
    declare_unpack_color(abcd, efgh, color);

    /*
     * In order to avoid testing w > 0 and h > 0 twice, we defer
     * executing setup_rect, and use fit_fill_xywh instead of
     * fit_fill.
     */
    fit_fill_xywh(dev, x, y, w, h);
    INCR(fill);
#ifdef COLLECT_STATS_MEM64
    stats_mem64.ftotal += w;
#endif
    if (h <= 0)
        return 0;
    if (w >= 5) {
        INCR(fwide);
        setup_rect(dest);
#ifdef COLLECT_STATS_MEM64
        {
            int ci;
            for (ci = 0; ci < prev_count; ++ci)
                if (prev_colors[ci] == color)
                    break;
            INCR(fprevc[ci]);
            if (ci == prev_count) {
                if (ci < countof(prev_colors))
                    ++prev_count;
                else
                    --ci;
            }
            if (ci) {
                memmove(&prev_colors[1], &prev_colors[0],
                        ci * sizeof(prev_colors[0]));
                prev_colors[0] = color;
            }
        }
#endif
        INCR(fcolor[min(w, 100)]);
        while (h-- > 0) {
            register bits32 *pptr = dest32;
            int w1 = w;

            while (w1 >= 4) {
                put8(pptr, abcd, efgh);
                put8(pptr + 2, abcd, efgh);
                put8(pptr + 4, abcd, efgh);
                put8(pptr + 6, abcd, efgh);
                pptr += 4 * PIXEL_SIZE;
                w1 -= 4;
            }
            switch (w1) {
                case 1:
                    put8(pptr, abcd, efgh);
                    break;
                case 2:
                    put8(pptr, abcd, efgh);
                    put8(pptr + 2, abcd, efgh);
                    break;
                case 3:
                    put8(pptr, abcd, efgh);
                    put8(pptr + 2, abcd, efgh);
                    put8(pptr + 4, abcd, efgh);
                    break;
                case 0:
                    ;
            }
            inc_ptr(dest, draster);
        }
    } else {   /* w < 5 */
        INCR(fnarrow[max(w, 0)]);
        setup_rect(dest);
        switch (w) {
            case 4:
                do {
                    put8(dest32, abcd, efgh);
                    put8(dest32 + 2, abcd, efgh);
                    put8(dest32 + 4, abcd, efgh);
                    put8(dest32 + 6, abcd, efgh);
                    inc_ptr(dest, draster);
                }
                while (--h);
                break;
            case 3:
                do {
                    put8(dest32, abcd, efgh);
                    put8(dest32 + 2, abcd, efgh);
                    put8(dest32 + 4, abcd, efgh);
                    inc_ptr(dest, draster);
                }
                while (--h);
                break;
            case 2:
                do {
                    put8(dest32, abcd, efgh);
                    put8(dest32 + 2, abcd, efgh);
                    inc_ptr(dest, draster);
                }
                while (--h);
                break;
            case 1:
                do {
                    put8(dest32, abcd, efgh);
                    inc_ptr(dest, draster);
                }
                while (--h);
                break;
            case 0:
            default:
                ;
        }
    }
    return 0;
}

/* Copy a monochrome bitmap. */
static int
mem_true64_copy_mono(gx_device * dev,
               const byte * base, int sourcex, int sraster, gx_bitmap_id id,
        int x, int y, int w, int h, gx_color_index zero, gx_color_index one)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;
    const byte *line;
    int sbit;
    int first_bit;

    declare_scan_ptr(dest);

    fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
    setup_rect(dest);
    line = base + (sourcex >> 3);
    sbit = sourcex & 7;
    first_bit = 0x80 >> sbit;
    if (zero != gx_no_color_index) { /* Loop for halftones or inverted masks */
        /* (never used). */
        declare_unpack_color(abcd0, efgh0, zero);
        declare_unpack_color(abcd1, efgh1, one);
        while (h-- > 0) {
            register bits32 *pptr = dest32;
            const byte *sptr = line;
            register int sbyte = *sptr++;
            register int bit = first_bit;
            int count = w;

            do {
                if (sbyte & bit) {
                    if (one != gx_no_color_index)
                        put8(pptr, abcd1, efgh1);
                } else
                    put8(pptr, abcd0, efgh0);
                pptr += PIXEL_SIZE;
                if ((bit >>= 1) == 0)
                    bit = 0x80, sbyte = *sptr++;
            }
            while (--count > 0);
            line += sraster;
            inc_ptr(dest, draster);
        }
    } else if (one != gx_no_color_index) { /* Loop for character and pattern masks. */
        /* This is used heavily. */
        declare_unpack_color(abcd1, efgh1, one);
        int first_mask = first_bit << 1;
        int first_count, first_skip;

        if (sbit + w > 8)
            first_mask -= 1,
                first_count = 8 - sbit;
        else
            first_mask -= first_mask >> w,
                first_count = w;
        first_skip = first_count * PIXEL_SIZE;
        while (h-- > 0) {
            register bits32 *pptr = dest32;
            const byte *sptr = line;
            register int sbyte = *sptr++ & first_mask;
            int count = w - first_count;

            if (sbyte) {
                register int bit = first_bit;

                do {
                    if (sbyte & bit)
                        put8(pptr, abcd1, efgh1);
                    pptr += PIXEL_SIZE;
                }
                while ((bit >>= 1) & first_mask);
            } else
                pptr += first_skip;
            while (count >= 8) {
                sbyte = *sptr++;
                if (sbyte & 0xf0) {
                    if (sbyte & 0x80)
                        put8(pptr, abcd1, efgh1);
                    if (sbyte & 0x40)
                        put8(pptr + 2, abcd1, efgh1);
                    if (sbyte & 0x20)
                        put8(pptr + 4, abcd1, efgh1);
                    if (sbyte & 0x10)
                        put8(pptr + 6, abcd1, efgh1);
                }
                if (sbyte & 0xf) {
                    if (sbyte & 8)
                        put8(pptr + 8, abcd1, efgh1);
                    if (sbyte & 4)
                        put8(pptr + 10, abcd1, efgh1);
                    if (sbyte & 2)
                        put8(pptr + 12, abcd1, efgh1);
                    if (sbyte & 1)
                        put8(pptr + 14, abcd1, efgh1);
                }
                pptr += 8 * PIXEL_SIZE;
                count -= 8;
            }
            if (count > 0) {
                register int bit = 0x80;

                sbyte = *sptr++;
                do {
                    if (sbyte & bit)
                        put8(pptr, abcd1, efgh1);
                    pptr += PIXEL_SIZE;
                    bit >>= 1;
                }
                while (--count > 0);
            }
            line += sraster;
            inc_ptr(dest, draster);
        }
    }
    return 0;
}

/* Copy a color bitmap. */
static int
mem_true64_copy_color(gx_device * dev,
               const byte * base, int sourcex, int sraster, gx_bitmap_id id,
                      int x, int y, int w, int h)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;

    fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
    mem_copy_byte_rect(mdev, base, sourcex, sraster, x, y, w, h);
    return 0;
}

/* ================ "Word"-oriented device ================ */

/* Note that on a big-endian machine, this is the same as the */
/* standard byte-oriented-device. */

#if !ARCH_IS_BIG_ENDIAN

/* Procedures */
declare_mem_procs(mem64_word_copy_mono, mem64_word_copy_color, mem64_word_fill_rectangle);

/* Here is the device descriptor. */
const gx_device_memory mem_true64_word_device =
    mem_device("image64w", 64, 0, mem_word_dev_initialize_device_procs);

const gdev_mem_functions gdev_mem_fns_64w =
{
    gx_default_rgb_map_rgb_color,
    gx_default_rgb_map_color_rgb,
    mem64_word_fill_rectangle,
    mem64_word_copy_mono,
    mem64_word_copy_color,
    gx_default_copy_alpha,
    gx_default_strip_tile_rectangle,
    gx_no_strip_copy_rop2,
    mem_word_get_bits_rectangle
};

/* Fill a rectangle with a color. */
static int
mem64_word_fill_rectangle(gx_device * dev, int x, int y, int w, int h,
                          gx_color_index color)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;
    byte *base;
    size_t raster;

    fit_fill(dev, x, y, w, h);
    base = scan_line_base(mdev, y);
    raster = mdev->raster;
    mem_swap_byte_rect(base, raster, x * 64, w * 64, h, true);
    mem_true64_fill_rectangle(dev, x, y, w, h, color);
    mem_swap_byte_rect(base, raster, x * 64, w * 64, h, false);
    return 0;
}

/* Copy a bitmap. */
static int
mem64_word_copy_mono(gx_device * dev,
               const byte * base, int sourcex, int sraster, gx_bitmap_id id,
        int x, int y, int w, int h, gx_color_index zero, gx_color_index one)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;
    byte *row;
    size_t raster;
    bool store;

    fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
    row = scan_line_base(mdev, y);
    raster = mdev->raster;
    store = (zero != gx_no_color_index && one != gx_no_color_index);
    mem_swap_byte_rect(row, raster, x * 64, w * 64, h, store);
    mem_true64_copy_mono(dev, base, sourcex, sraster, id,
                         x, y, w, h, zero, one);
    mem_swap_byte_rect(row, raster, x * 64, w * 64, h, false);
    return 0;
}

/* Copy a color bitmap. */
static int
mem64_word_copy_color(gx_device * dev,
               const byte * base, int sourcex, int sraster, gx_bitmap_id id,
                      int x, int y, int w, int h)
{
    gx_device_memory * const mdev = (gx_device_memory *)dev;
    byte *row;
    size_t raster;

    fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
    row = scan_line_base(mdev, y);
    raster = mdev->raster;
    mem_swap_byte_rect(row, raster, x * 64, w * 64, h, true);
    bytes_copy_rectangle(row + x * PIXEL_SIZE, raster, base + sourcex * PIXEL_SIZE,
                                sraster, w * PIXEL_SIZE, h);
    mem_swap_byte_rect(row, raster, x * 64, w * 64, h, false);
    return 0;
}

#endif /* !ARCH_IS_BIG_ENDIAN */

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		/* 64-bit-per-pixel "memory" (stored bitmap) device */
17		#include "memory_.h"
18		#include "gx.h"
19		#include "gxdevice.h"
20		#include "gxdevmem.h" /* semi-public definitions */
21		#include "gdevmem.h" /* private definitions */
22
23		/* Define debugging statistics. */
24		/* #define COLLECT_STATS_MEM64 */
25
26		#ifdef COLLECT_STATS_MEM64
27		struct stats_mem64_s {
28		long
29		fill, fwide, fgray[101], fsetc, fcolor[101], fnarrow[5],
30		fprevc[257];
31		double ftotal;
32		} stats_mem64;
33		static int prev_count = 0;
34		static gx_color_index prev_colors[256];
35		# define INCR(v) (++(stats_mem64.v))
36		#else
37	0	# define INCR(v) DO_NOTHING
38		#endif
39
40		/* ================ Standard (byte-oriented) device ================ */
41
42		#undef chunk
43		#define chunk byte
44	0	#define PIXEL_SIZE 2
45
46		/* Procedures */
47		declare_mem_procs(mem_true64_copy_mono, mem_true64_copy_color, mem_true64_fill_rectangle);
48
49		/* The device descriptor. */
50		const gx_device_memory mem_true64_device =
51		mem_device("image64", 64, 0, mem_dev_initialize_device_procs);
52
53		const gdev_mem_functions gdev_mem_fns_64 =
54		{
55		gx_default_rgb_map_rgb_color,
56		gx_default_rgb_map_color_rgb,
57		mem_true64_fill_rectangle,
58		mem_true64_copy_mono,
59		mem_true64_copy_color,
60		gx_default_copy_alpha,
61		gx_default_strip_tile_rectangle,
62		mem_default_strip_copy_rop2,
63		mem_get_bits_rectangle
64		};
65
66		/* Convert x coordinate to byte offset in scan line. */
67		#undef x_to_byte
68	0	#define x_to_byte(x) ((x) << 3)
69
70		/* Put a 64-bit color into the bitmap. */
71		#define put8(ptr, abcd, efgh)\
72	0	(ptr)[0] = abcd, (ptr)[1] = efgh
73		/* Free variables: [m]dev, abcd, degh. */
74		#if ARCH_IS_BIG_ENDIAN
75		/* Unpack a color into 32 bit chunks. */
76		# define declare_unpack_color(abcd, efgh, color)\
77		bits32 abcd = (bits32)((color) >> 32);\
78		bits32 efgh = (bits32)(color)
79		#else
80		/* Unpack a color into 32 bit chunks. */
81		# define declare_unpack_color(abcd, efgh, color)\
82	0	bits32 abcd = (bits32)((0x000000ff & (((color) >> 28) >> 28)) \|\
83	0	(0x0000ff00 & (((color) >> 24) >> 16)) \|\
84	0	(0x00ff0000 & ((color) >> 24)) \|\
85	0	(0xff000000 & ((color) >> 8)));\
86	0	bits32 efgh = (bits32)((0x000000ff & ((color) >> 24)) \|\
87	0	(0x0000ff00 & ((color) >> 8)) \|\
88	0	(0x00ff0000 & ((color) << 8)) \|\
89	0	(0xff000000 & ((color) << 24)))
90		#endif
91	0	#define dest32 ((bits32 *)dest)
92
93		/* Fill a rectangle with a color. */
94		static int
95		mem_true64_fill_rectangle(gx_device * dev,
96		int x, int y, int w, int h, gx_color_index color)
97	0	{
98	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
99	0	declare_scan_ptr(dest);
100	0	declare_unpack_color(abcd, efgh, color);
101
102		/*
103		* In order to avoid testing w > 0 and h > 0 twice, we defer
104		* executing setup_rect, and use fit_fill_xywh instead of
105		* fit_fill.
106		*/
107	0	fit_fill_xywh(dev, x, y, w, h);
108	0	INCR(fill);
109		#ifdef COLLECT_STATS_MEM64
110		stats_mem64.ftotal += w;
111		#endif
112	0	if (h <= 0)
113	0	return 0;
114	0	if (w >= 5) {
115	0	INCR(fwide);
116	0	setup_rect(dest);
117		#ifdef COLLECT_STATS_MEM64
118		{
119		int ci;
120		for (ci = 0; ci < prev_count; ++ci)
121		if (prev_colors[ci] == color)
122		break;
123		INCR(fprevc[ci]);
124		if (ci == prev_count) {
125		if (ci < countof(prev_colors))
126		++prev_count;
127		else
128		--ci;
129		}
130		if (ci) {
131		memmove(&prev_colors[1], &prev_colors[0],
132		ci * sizeof(prev_colors[0]));
133		prev_colors[0] = color;
134		}
135		}
136		#endif
137	0	INCR(fcolor[min(w, 100)]);
138	0	while (h-- > 0) {
139	0	register bits32 *pptr = dest32;
140	0	int w1 = w;
141
142	0	while (w1 >= 4) {
143	0	put8(pptr, abcd, efgh);
144	0	put8(pptr + 2, abcd, efgh);
145	0	put8(pptr + 4, abcd, efgh);
146	0	put8(pptr + 6, abcd, efgh);
147	0	pptr += 4 * PIXEL_SIZE;
148	0	w1 -= 4;
149	0	}
150	0	switch (w1) {
151	0	case 1:
152	0	put8(pptr, abcd, efgh);
153	0	break;
154	0	case 2:
155	0	put8(pptr, abcd, efgh);
156	0	put8(pptr + 2, abcd, efgh);
157	0	break;
158	0	case 3:
159	0	put8(pptr, abcd, efgh);
160	0	put8(pptr + 2, abcd, efgh);
161	0	put8(pptr + 4, abcd, efgh);
162	0	break;
163	0	case 0:
164	0	;
165	0	}
166	0	inc_ptr(dest, draster);
167	0	}
168	0	} else { /* w < 5 */
169	0	INCR(fnarrow[max(w, 0)]);
170	0	setup_rect(dest);
171	0	switch (w) {
172	0	case 4:
173	0	do {
174	0	put8(dest32, abcd, efgh);
175	0	put8(dest32 + 2, abcd, efgh);
176	0	put8(dest32 + 4, abcd, efgh);
177	0	put8(dest32 + 6, abcd, efgh);
178	0	inc_ptr(dest, draster);
179	0	}
180	0	while (--h);
181	0	break;
182	0	case 3:
183	0	do {
184	0	put8(dest32, abcd, efgh);
185	0	put8(dest32 + 2, abcd, efgh);
186	0	put8(dest32 + 4, abcd, efgh);
187	0	inc_ptr(dest, draster);
188	0	}
189	0	while (--h);
190	0	break;
191	0	case 2:
192	0	do {
193	0	put8(dest32, abcd, efgh);
194	0	put8(dest32 + 2, abcd, efgh);
195	0	inc_ptr(dest, draster);
196	0	}
197	0	while (--h);
198	0	break;
199	0	case 1:
200	0	do {
201	0	put8(dest32, abcd, efgh);
202	0	inc_ptr(dest, draster);
203	0	}
204	0	while (--h);
205	0	break;
206	0	case 0:
207	0	default:
208	0	;
209	0	}
210	0	}
211	0	return 0;
212	0	}
213
214		/* Copy a monochrome bitmap. */
215		static int
216		mem_true64_copy_mono(gx_device * dev,
217		const byte * base, int sourcex, int sraster, gx_bitmap_id id,
218		int x, int y, int w, int h, gx_color_index zero, gx_color_index one)
219	0	{
220	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
221	0	const byte *line;
222	0	int sbit;
223	0	int first_bit;
224
225	0	declare_scan_ptr(dest);
226
227	0	fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
228	0	setup_rect(dest);
229	0	line = base + (sourcex >> 3);
230	0	sbit = sourcex & 7;
231	0	first_bit = 0x80 >> sbit;
232	0	if (zero != gx_no_color_index) { /* Loop for halftones or inverted masks */
233		/* (never used). */
234	0	declare_unpack_color(abcd0, efgh0, zero);
235	0	declare_unpack_color(abcd1, efgh1, one);
236	0	while (h-- > 0) {
237	0	register bits32 *pptr = dest32;
238	0	const byte *sptr = line;
239	0	register int sbyte = *sptr++;
240	0	register int bit = first_bit;
241	0	int count = w;
242
243	0	do {
244	0	if (sbyte & bit) {
245	0	if (one != gx_no_color_index)
246	0	put8(pptr, abcd1, efgh1);
247	0	} else
248	0	put8(pptr, abcd0, efgh0);
249	0	pptr += PIXEL_SIZE;
250	0	if ((bit >>= 1) == 0)
251	0	bit = 0x80, sbyte = *sptr++;
252	0	}
253	0	while (--count > 0);
254	0	line += sraster;
255	0	inc_ptr(dest, draster);
256	0	}
257	0	} else if (one != gx_no_color_index) { /* Loop for character and pattern masks. */
258		/* This is used heavily. */
259	0	declare_unpack_color(abcd1, efgh1, one);
260	0	int first_mask = first_bit << 1;
261	0	int first_count, first_skip;
262
263	0	if (sbit + w > 8)
264	0	first_mask -= 1,
265	0	first_count = 8 - sbit;
266	0	else
267	0	first_mask -= first_mask >> w,
268	0	first_count = w;
269	0	first_skip = first_count * PIXEL_SIZE;
270	0	while (h-- > 0) {
271	0	register bits32 *pptr = dest32;
272	0	const byte *sptr = line;
273	0	register int sbyte = *sptr++ & first_mask;
274	0	int count = w - first_count;
275
276	0	if (sbyte) {
277	0	register int bit = first_bit;
278
279	0	do {
280	0	if (sbyte & bit)
281	0	put8(pptr, abcd1, efgh1);
282	0	pptr += PIXEL_SIZE;
283	0	}
284	0	while ((bit >>= 1) & first_mask);
285	0	} else
286	0	pptr += first_skip;
287	0	while (count >= 8) {
288	0	sbyte = *sptr++;
289	0	if (sbyte & 0xf0) {
290	0	if (sbyte & 0x80)
291	0	put8(pptr, abcd1, efgh1);
292	0	if (sbyte & 0x40)
293	0	put8(pptr + 2, abcd1, efgh1);
294	0	if (sbyte & 0x20)
295	0	put8(pptr + 4, abcd1, efgh1);
296	0	if (sbyte & 0x10)
297	0	put8(pptr + 6, abcd1, efgh1);
298	0	}
299	0	if (sbyte & 0xf) {
300	0	if (sbyte & 8)
301	0	put8(pptr + 8, abcd1, efgh1);
302	0	if (sbyte & 4)
303	0	put8(pptr + 10, abcd1, efgh1);
304	0	if (sbyte & 2)
305	0	put8(pptr + 12, abcd1, efgh1);
306	0	if (sbyte & 1)
307	0	put8(pptr + 14, abcd1, efgh1);
308	0	}
309	0	pptr += 8 * PIXEL_SIZE;
310	0	count -= 8;
311	0	}
312	0	if (count > 0) {
313	0	register int bit = 0x80;
314
315	0	sbyte = *sptr++;
316	0	do {
317	0	if (sbyte & bit)
318	0	put8(pptr, abcd1, efgh1);
319	0	pptr += PIXEL_SIZE;
320	0	bit >>= 1;
321	0	}
322	0	while (--count > 0);
323	0	}
324	0	line += sraster;
325	0	inc_ptr(dest, draster);
326	0	}
327	0	}
328	0	return 0;
329	0	}
330
331		/* Copy a color bitmap. */
332		static int
333		mem_true64_copy_color(gx_device * dev,
334		const byte * base, int sourcex, int sraster, gx_bitmap_id id,
335		int x, int y, int w, int h)
336	0	{
337	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
338
339	0	fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
340	0	mem_copy_byte_rect(mdev, base, sourcex, sraster, x, y, w, h);
341	0	return 0;
342	0	}
343
344		/* ================ "Word"-oriented device ================ */
345
346		/* Note that on a big-endian machine, this is the same as the */
347		/* standard byte-oriented-device. */
348
349		#if !ARCH_IS_BIG_ENDIAN
350
351		/* Procedures */
352		declare_mem_procs(mem64_word_copy_mono, mem64_word_copy_color, mem64_word_fill_rectangle);
353
354		/* Here is the device descriptor. */
355		const gx_device_memory mem_true64_word_device =
356		mem_device("image64w", 64, 0, mem_word_dev_initialize_device_procs);
357
358		const gdev_mem_functions gdev_mem_fns_64w =
359		{
360		gx_default_rgb_map_rgb_color,
361		gx_default_rgb_map_color_rgb,
362		mem64_word_fill_rectangle,
363		mem64_word_copy_mono,
364		mem64_word_copy_color,
365		gx_default_copy_alpha,
366		gx_default_strip_tile_rectangle,
367		gx_no_strip_copy_rop2,
368		mem_word_get_bits_rectangle
369		};
370
371		/* Fill a rectangle with a color. */
372		static int
373		mem64_word_fill_rectangle(gx_device * dev, int x, int y, int w, int h,
374		gx_color_index color)
375	0	{
376	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
377	0	byte *base;
378	0	size_t raster;
379
380	0	fit_fill(dev, x, y, w, h);
381	0	base = scan_line_base(mdev, y);
382	0	raster = mdev->raster;
383	0	mem_swap_byte_rect(base, raster, x * 64, w * 64, h, true);
384	0	mem_true64_fill_rectangle(dev, x, y, w, h, color);
385	0	mem_swap_byte_rect(base, raster, x * 64, w * 64, h, false);
386	0	return 0;
387	0	}
388
389		/* Copy a bitmap. */
390		static int
391		mem64_word_copy_mono(gx_device * dev,
392		const byte * base, int sourcex, int sraster, gx_bitmap_id id,
393		int x, int y, int w, int h, gx_color_index zero, gx_color_index one)
394	0	{
395	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
396	0	byte *row;
397	0	size_t raster;
398	0	bool store;
399
400	0	fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
401	0	row = scan_line_base(mdev, y);
402	0	raster = mdev->raster;
403	0	store = (zero != gx_no_color_index && one != gx_no_color_index);
404	0	mem_swap_byte_rect(row, raster, x * 64, w * 64, h, store);
405	0	mem_true64_copy_mono(dev, base, sourcex, sraster, id,
406	0	x, y, w, h, zero, one);
407	0	mem_swap_byte_rect(row, raster, x * 64, w * 64, h, false);
408	0	return 0;
409	0	}
410
411		/* Copy a color bitmap. */
412		static int
413		mem64_word_copy_color(gx_device * dev,
414		const byte * base, int sourcex, int sraster, gx_bitmap_id id,
415		int x, int y, int w, int h)
416	0	{
417	0	gx_device_memory * const mdev = (gx_device_memory *)dev;
418	0	byte *row;
419	0	size_t raster;
420
421	0	fit_copy(dev, base, sourcex, sraster, id, x, y, w, h);
422	0	row = scan_line_base(mdev, y);
423	0	raster = mdev->raster;
424	0	mem_swap_byte_rect(row, raster, x * 64, w * 64, h, true);
425	0	bytes_copy_rectangle(row + x * PIXEL_SIZE, raster, base + sourcex * PIXEL_SIZE,
426	0	sraster, w * PIXEL_SIZE, h);
427	0	mem_swap_byte_rect(row, raster, x * 64, w * 64, h, false);
428	0	return 0;
429	0	}
430
431		#endif /* !ARCH_IS_BIG_ENDIAN */