/src/ghostpdl/base/spngp.c

Source
/* 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.
*/


/* PNG pixel prediction filters */
#include "memory_.h"
#include "strimpl.h"
#include "spngpx.h"

/* ------ PNGPredictorEncode/Decode ------ */

private_st_PNGP_state();

/* Define values for case dispatch. */
#define cNone 10
#define cSub 11
#define cUp 12
#define cAverage 13
#define cPaeth 14
#define cOptimum 15
#define cEncode -10
#define cDecode -4
static const byte pngp_case_needs_prev[] = {
    0, 0, 1, 1, 1, 1
};

/* Set defaults */
static void
s_PNGP_set_defaults(stream_state * st)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;

    s_PNGP_set_defaults_inline(ss);
}

/* Common (re)initialization. */
static int
s_PNGP_reinit(stream_state * st)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;

    if (ss->prev_row != 0)
        memset(ss->prev_row + ss->bpp, 0, ss->row_count);
    ss->row_left = 0;
    return 0;
}

/* Common initialization. */
static int
s_pngp_init(stream_state * st, bool need_prev)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;
    int bits_per_pixel = ss->Colors * ss->BitsPerComponent;
    long bits_per_row = (long)bits_per_pixel * ss->Columns;
    byte *prev_row = 0;

#if ARCH_SIZEOF_LONG > ARCH_SIZEOF_INT
    if (bits_per_row > max_uint * 7L)
        return ERRC; /****** WRONG ******/
#endif
    ss->row_count = (uint) ((bits_per_row + 7) >> 3);
    ss->end_mask = (1 << (-bits_per_row & 7)) - 1;

    if (ss->Colors > s_PNG_max_Colors)
        return ERRC; /* Too many colorants */

    if (bits_per_row < 1)
        return ERRC;

    ss->bpp = (bits_per_pixel + 7) >> 3;
    if (need_prev) {
        prev_row = gs_alloc_bytes(st->memory, ss->bpp + ss->row_count,
                                  "PNGPredictor prev row");
        if (prev_row == 0)
            return ERRC; /****** WRONG ******/
        memset(prev_row, 0, ss->bpp);
    }
    ss->prev_row = prev_row;
    /* case_index is only preset for encoding */
    return s_PNGP_reinit(st);
}

/* Initialize PNGPredictorEncode filter. */
static int
s_PNGPE_init(stream_state * st)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;

    return s_pngp_init(st, pngp_case_needs_prev[ss->Predictor - cNone]);
}

/* Initialize PNGPredictorDecode filter. */
static int
s_PNGPD_init(stream_state * st)
{
    return s_pngp_init(st, true);
}

/* Release a PNGPredictor filter. */
static void
s_PNGP_release(stream_state *st)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;

    if (ss->prev_row)
        gs_free_object(st->memory, ss->prev_row, "PNGPredictor prev row");
}

/*
 * Process a partial buffer.  We pass in current and previous pointers
 * to both the current and preceding scan line.  Note that dprev is
 * p - bpp for encoding, q - bpp for decoding; similarly, the 'up' row
 * is the raw data for encoding, the filtered (encoded) data for decoding.
 * Note also that the case_index cannot be cOptimum.
 *
 * Uses ss->case_index; uses and updates ss->row_left, pr->ptr, pw->ptr.
 */
static int
paeth_predictor(int a, int b, int c)
{
    /* The definitions of ac and bc are correct, not a typo. */
    int ac = b - c, bc = a - c, abcc = ac + bc;
    int pa = (ac < 0 ? -ac : ac), pb = (bc < 0 ? -bc : bc),
        pc = (abcc < 0 ? -abcc : abcc);

    return (pa <= pb && pa <= pc ? a : pb <= pc ? b : c);
}
static void
s_pngp_process(stream_state * st, stream_cursor_write * pw,
               const byte * dprev, stream_cursor_read * pr,
               const byte * upprev, const byte * up, uint count)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;
    byte *q = pw->ptr + 1;
    const byte *p = pr->ptr + 1;

    pr->ptr += count;
    pw->ptr += count;
    ss->row_left -= count;
    switch (ss->case_index) {
        case cEncode + cNone:
        case cDecode + cNone:
            memcpy(q, p, count);
            break;
        case cEncode + cSub:
            for (; count; ++q, ++dprev, ++p, --count)
                *q = (byte) (*p - *dprev);
            break;
        case cDecode + cSub:
            for (; count; ++q, ++dprev, ++p, --count)
                *q = (byte) (*p + *dprev);
            break;
        case cEncode + cUp:
            for (; count; ++q, ++up, ++p, --count)
                *q = (byte) (*p - *up);
            break;
        case cDecode + cUp:
            for (; count; ++q, ++up, ++p, --count)
                *q = (byte) (*p + *up);
            break;
        case cEncode + cAverage:
            for (; count; ++q, ++dprev, ++up, ++p, --count)
                *q = (byte) (*p - arith_rshift_1((int)*dprev + (int)*up));
            break;
        case cDecode + cAverage:
            for (; count; ++q, ++dprev, ++up, ++p, --count)
                *q = (byte) (*p + arith_rshift_1((int)*dprev + (int)*up));
            break;
        case cEncode + cPaeth:
            for (; count; ++q, ++dprev, ++up, ++upprev, ++p, --count)
                *q = (byte) (*p - paeth_predictor(*dprev, *up, *upprev));
            break;
        case cDecode + cPaeth:
            for (; count; ++q, ++dprev, ++up, ++upprev, ++p, --count)
                *q = (byte) (*p + paeth_predictor(*dprev, *up, *upprev));
            break;
    }
}

/* Calculate the number of bytes for the next processing step, */
/* the min of (input data, output data, remaining row length). */
static uint
s_pngp_count(const stream_state * st_const, const stream_cursor_read * pr,
             const stream_cursor_write * pw)
{
    const stream_PNGP_state *const ss_const =
        (const stream_PNGP_state *)st_const;
    uint rcount = pr->limit - pr->ptr;
    uint wcount = pw->limit - pw->ptr;
    uint row_left = ss_const->row_left;

    if (rcount < row_left)
        row_left = rcount;
    if (wcount < row_left)
        row_left = wcount;
    return row_left;
}

/*
 * Encode a buffer.  Let N = ss->row_count, P = N - ss->row_left,
 * and B = ss->bpp.  Consider that bytes [-B .. -1] of every row are zero.
 * Then:
 *      prev_row[0 .. P - 1] contain bytes -B .. P - B - 1
 *        of the current input row.
 *      ss->prev[0 .. B - 1] contain bytes P - B .. P - 1
 *        of the current input row.
 *      prev_row[P .. N + B - 1] contain bytes P - B .. N - 1
 *        of the previous input row.
 * We must handle the edges of each row specially, by clearing ss->prev at
 * the beginning of each row, and copying trailing bytes from ss->prev (and
 * possibly the input) to prev_row at the end of each row.
 */
static int
optimum_predictor(const stream_state * st, const stream_cursor_read * pr)
{
    return cSub;
}
static int
s_PNGPE_process(stream_state * st, stream_cursor_read * pr,
                stream_cursor_write * pw, bool last)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;
    int bpp = ss->bpp;
    int status = 0;

    while (pr->ptr < pr->limit) {
        uint count;

        if (ss->row_left == 0) {
            /* Beginning of row, write algorithm byte. */
            int predictor;

            if (pw->ptr >= pw->limit) {
                status = 1;
                break;
            }
            predictor =
                (ss->Predictor == cOptimum ?
                 optimum_predictor(st, pr) :
                 ss->Predictor);
            *++(pw->ptr) = (byte) predictor - cNone;
            ss->case_index = predictor + cEncode;
            ss->row_left = ss->row_count;
            memset(ss->prev, 0, bpp);
            continue;
        }
        count = s_pngp_count(st, pr, pw);
        if (count == 0) {
            /* We know we have input, so output must be full. */
            status = 1;
            break;
        } {
            byte *up = ss->prev_row + bpp + ss->row_count - ss->row_left;
            uint n = min(count, bpp);

            /* Process bytes whose predecessors are in prev. */
            s_pngp_process(st, pw, ss->prev, pr, up - bpp, up, n);
            if (ss->row_left == 0) {
                if (ss->prev_row) {
                    memcpy(up - bpp, ss->prev, bpp);
                    memcpy(up, pr->ptr - (n - 1), n);
                }
                continue;
            }
            if (ss->prev_row)
                memcpy(up - bpp, ss->prev, n);
            if (n < bpp) {
                /*
                 * We didn't have both enough input data and enough output
                 * space to use up all of prev.  Shift more data into prev
                 * and exit.
                 */
                int prev_left = bpp - n;

                memmove(ss->prev, ss->prev + n, prev_left);
                memcpy(ss->prev + prev_left, pr->ptr - (n - 1), n);
                if (pw->ptr >= pw->limit && pr->ptr < pr->limit)
                    status = 1;
                break;
            }
            /* Process bytes whose predecessors are in the input. */
            /* We know we have at least bpp input and output bytes, */
            /* and that n = bpp. */
            count -= bpp;
            s_pngp_process(st, pw, pr->ptr - (bpp - 1), pr,
                           up, up + bpp, count);
            memcpy(ss->prev, pr->ptr - (bpp - 1), bpp);
            if (ss->prev_row) {
                memcpy(up, pr->ptr - (bpp + count - 1), count);
                if (ss->row_left == 0)
                    memcpy(up + count, ss->prev, bpp);
            }
        }
    }
    return status;
}

/*
 * Decode a buffer.  Let N = ss->row_count, P = N - ss->row_left,
 * and B = ss->bpp.  Consider that bytes [-B .. -1] of every row are zero.
 * Then:
 *      prev_row[0 .. P - 1] contain bytes -B .. P - B - 1
 *        of the current output row.
 *      ss->prev[0 .. B - 1] contain bytes P - B .. P - 1
 *        of the current output row.
 *      prev_row[P .. N + B - 1] contain bytes P - B .. N - 1
 *        of the previous output row.
 * We must handle the edges of each row specially, by clearing ss->prev at
 * the beginning of each row, and copying trailing bytes from ss->prev (and
 * possibly the output) to prev_row at the end of each row.
 */
static int
s_PNGPD_process(stream_state * st, stream_cursor_read * pr,
                stream_cursor_write * pw, bool last)
{
    stream_PNGP_state *const ss = (stream_PNGP_state *) st;
    int bpp = ss->bpp;
    int status = 0;

    while (pr->ptr < pr->limit) {
        uint count;

        if (ss->row_left == 0) {
            /* Beginning of row, read algorithm byte. */
            int predictor = pr->ptr[1];

            if (predictor >= cOptimum - cNone) {
                status = ERRC;
                break;
            }
            pr->ptr++;
            ss->case_index = predictor + cNone + cDecode;
            ss->row_left = ss->row_count;
            memset(ss->prev, 0, bpp);
            continue;
        }
        count = s_pngp_count(st, pr, pw);
        if (count == 0) {
            /* We know we have input, so output must be full. */
            status = 1;
            break;
        } {
            byte *up = ss->prev_row + bpp + ss->row_count - ss->row_left;
            uint n = min(count, bpp);

            /* Process bytes whose predecessors are in prev. */
            s_pngp_process(st, pw, ss->prev, pr, up - bpp, up, n);
            if (ss->row_left == 0) {
                if (ss->prev_row) {
                    memcpy(up - bpp, ss->prev, bpp);
                    memcpy(up, pw->ptr - (n - 1), n);
                }
                continue;
            }
            if (ss->prev_row)
                memcpy(up - bpp, ss->prev, n);
            if (n < bpp) {
                /*
                 * We didn't have both enough input data and enough output
                 * space to use up all of prev.  Shift more data into prev
                 * and exit.
                 */
                int prev_left = bpp - n;

                memmove(ss->prev, ss->prev + n, prev_left);
                memcpy(ss->prev + prev_left, pw->ptr - (n - 1), n);
                if (pw->ptr >= pw->limit && pr->ptr < pr->limit)
                    status = 1;
                break;
            }
            /* Process bytes whose predecessors are in the output. */
            /* We know we have at least bpp input and output bytes, */
            /* and that n = bpp. */
            count -= bpp;
            s_pngp_process(st, pw, pw->ptr - (bpp - 1), pr,
                           up, up + bpp, count);
            memcpy(ss->prev, pw->ptr - (bpp - 1), bpp);
            if (ss->prev_row) {
                memcpy(up, pw->ptr - (bpp + count - 1), count);
                if (ss->row_left == 0)
                    memcpy(up + count, ss->prev, bpp);
            }
        }
    }
    return status;
}

/* Stream templates */
const stream_template s_PNGPE_template = {
    &st_PNGP_state, s_PNGPE_init, s_PNGPE_process, 1, 1, s_PNGP_release,
    s_PNGP_set_defaults, s_PNGP_reinit
};
const stream_template s_PNGPD_template = {
    &st_PNGP_state, s_PNGPD_init, s_PNGPD_process, 1, 1, s_PNGP_release,
    s_PNGP_set_defaults, s_PNGP_reinit
};

Coverage Report

Created: 2026-04-09 07:06

Line	Count	Source
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		/* PNG pixel prediction filters */
18		#include "memory_.h"
19		#include "strimpl.h"
20		#include "spngpx.h"
21
22		/* ------ PNGPredictorEncode/Decode ------ */
23
24		private_st_PNGP_state();
25
26		/* Define values for case dispatch. */
27	6.22M	#define cNone 10
28	3.38M	#define cSub 11
29	1.59M	#define cUp 12
30	80.8k	#define cAverage 13
31	331k	#define cPaeth 14
32	2.32M	#define cOptimum 15
33	2.61M	#define cEncode -10
34	6.66M	#define cDecode -4
35		static const byte pngp_case_needs_prev[] = {
36		0, 0, 1, 1, 1, 1
37		};
38
39		/* Set defaults */
40		static void
41		s_PNGP_set_defaults(stream_state * st)
42	38.8k	{
43	38.8k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
44
45	38.8k	s_PNGP_set_defaults_inline(ss);
46	38.8k	}
47
48		/* Common (re)initialization. */
49		static int
50		s_PNGP_reinit(stream_state * st)
51	38.8k	{
52	38.8k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
53
54	38.8k	if (ss->prev_row != 0)
55	38.8k	memset(ss->prev_row + ss->bpp, 0, ss->row_count);
56	38.8k	ss->row_left = 0;
57	38.8k	return 0;
58	38.8k	}
59
60		/* Common initialization. */
61		static int
62		s_pngp_init(stream_state * st, bool need_prev)
63	38.8k	{
64	38.8k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
65	38.8k	int bits_per_pixel = ss->Colors * ss->BitsPerComponent;
66	38.8k	long bits_per_row = (long)bits_per_pixel * ss->Columns;
67	38.8k	byte *prev_row = 0;
68
69	38.8k	#if ARCH_SIZEOF_LONG > ARCH_SIZEOF_INT
70	38.8k	if (bits_per_row > max_uint * 7L)
71	0	return ERRC; /**** WRONG ****/
72	38.8k	#endif
73	38.8k	ss->row_count = (uint) ((bits_per_row + 7) >> 3);
74	38.8k	ss->end_mask = (1 << (-bits_per_row & 7)) - 1;
75
76	38.8k	if (ss->Colors > s_PNG_max_Colors)
77	0	return ERRC; /* Too many colorants */
78
79	38.8k	if (bits_per_row < 1)
80	0	return ERRC;
81
82	38.8k	ss->bpp = (bits_per_pixel + 7) >> 3;
83	38.8k	if (need_prev) {
84	38.8k	prev_row = gs_alloc_bytes(st->memory, ss->bpp + ss->row_count,
85	38.8k	"PNGPredictor prev row");
86	38.8k	if (prev_row == 0)
87	0	return ERRC; /**** WRONG ****/
88	38.8k	memset(prev_row, 0, ss->bpp);
89	38.8k	}
90	38.8k	ss->prev_row = prev_row;
91		/* case_index is only preset for encoding */
92	38.8k	return s_PNGP_reinit(st);
93	38.8k	}
94
95		/* Initialize PNGPredictorEncode filter. */
96		static int
97		s_PNGPE_init(stream_state * st)
98	4.13k	{
99	4.13k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
100
101	4.13k	return s_pngp_init(st, pngp_case_needs_prev[ss->Predictor - cNone]);
102	4.13k	}
103
104		/* Initialize PNGPredictorDecode filter. */
105		static int
106		s_PNGPD_init(stream_state * st)
107	34.6k	{
108	34.6k	return s_pngp_init(st, true);
109	34.6k	}
110
111		/* Release a PNGPredictor filter. */
112		static void
113		s_PNGP_release(stream_state *st)
114	38.8k	{
115	38.8k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
116
117	38.8k	if (ss->prev_row)
118	38.8k	gs_free_object(st->memory, ss->prev_row, "PNGPredictor prev row");
119	38.8k	}
120
121		/*
122		* Process a partial buffer. We pass in current and previous pointers
123		* to both the current and preceding scan line. Note that dprev is
124		* p - bpp for encoding, q - bpp for decoding; similarly, the 'up' row
125		* is the raw data for encoding, the filtered (encoded) data for decoding.
126		* Note also that the case_index cannot be cOptimum.
127		*
128		* Uses ss->case_index; uses and updates ss->row_left, pr->ptr, pw->ptr.
129		*/
130		static int
131		paeth_predictor(int a, int b, int c)
132	39.5M	{
133		/* The definitions of ac and bc are correct, not a typo. */
134	39.5M	int ac = b - c, bc = a - c, abcc = ac + bc;
135	39.5M	int pa = (ac < 0 ? -ac : ac), pb = (bc < 0 ? -bc : bc),
136	39.5M	pc = (abcc < 0 ? -abcc : abcc);
137
138	39.5M	return (pa <= pb && pa <= pc ? a : pb <= pc ? b : c);
139	39.5M	}
140		static void
141		s_pngp_process(stream_state * st, stream_cursor_write * pw,
142		const byte * dprev, stream_cursor_read * pr,
143		const byte * upprev, const byte * up, uint count)
144	6.96M	{
145	6.96M	stream_PNGP_state const ss = (stream_PNGP_state ) st;
146	6.96M	byte *q = pw->ptr + 1;
147	6.96M	const byte *p = pr->ptr + 1;
148
149	6.96M	pr->ptr += count;
150	6.96M	pw->ptr += count;
151	6.96M	ss->row_left -= count;
152	6.96M	switch (ss->case_index) {
153	0	case cEncode + cNone:
154	1.82M	case cDecode + cNone:
155	1.82M	memcpy(q, p, count);
156	1.82M	break;
157	2.36M	case cEncode + cSub:
158	123M	for (; count; ++q, ++dprev, ++p, --count)
159	121M	q = (byte) (p - *dprev);
160	2.36M	break;
161	770k	case cDecode + cSub:
162	219M	for (; count; ++q, ++dprev, ++p, --count)
163	218M	q = (byte) (p + *dprev);
164	770k	break;
165	0	case cEncode + cUp:
166	0	for (; count; ++q, ++up, ++p, --count)
167	0	q = (byte) (p - *up);
168	0	break;
169	1.59M	case cDecode + cUp:
170	15.3M	for (; count; ++q, ++up, ++p, --count)
171	13.7M	q = (byte) (p + *up);
172	1.59M	break;
173	0	case cEncode + cAverage:
174	0	for (; count; ++q, ++dprev, ++up, ++p, --count)
175	0	q = (byte) (p - arith_rshift_1((int)dprev + (int)up));
176	0	break;
177	80.8k	case cDecode + cAverage:
178	9.53M	for (; count; ++q, ++dprev, ++up, ++p, --count)
179	9.45M	q = (byte) (p + arith_rshift_1((int)dprev + (int)up));
180	80.8k	break;
181	0	case cEncode + cPaeth:
182	0	for (; count; ++q, ++dprev, ++up, ++upprev, ++p, --count)
183	0	q = (byte) (p - paeth_predictor(dprev, up, *upprev));
184	0	break;
185	331k	case cDecode + cPaeth:
186	39.8M	for (; count; ++q, ++dprev, ++up, ++upprev, ++p, --count)
187	39.5M	q = (byte) (p + paeth_predictor(dprev, up, *upprev));
188	331k	break;
189	6.96M	}
190	6.96M	}
191
192		/* Calculate the number of bytes for the next processing step, */
193		/* the min of (input data, output data, remaining row length). */
194		static uint
195		s_pngp_count(const stream_state * st_const, const stream_cursor_read * pr,
196		const stream_cursor_write * pw)
197	4.68M	{
198	4.68M	const stream_PNGP_state *const ss_const =
199	4.68M	(const stream_PNGP_state *)st_const;
200	4.68M	uint rcount = pr->limit - pr->ptr;
201	4.68M	uint wcount = pw->limit - pw->ptr;
202	4.68M	uint row_left = ss_const->row_left;
203
204	4.68M	if (rcount < row_left)
205	1.97M	row_left = rcount;
206	4.68M	if (wcount < row_left)
207	1.73M	row_left = wcount;
208	4.68M	return row_left;
209	4.68M	}
210
211		/*
212		* Encode a buffer. Let N = ss->row_count, P = N - ss->row_left,
213		* and B = ss->bpp. Consider that bytes [-B .. -1] of every row are zero.
214		* Then:
215		* prev_row[0 .. P - 1] contain bytes -B .. P - B - 1
216		* of the current input row.
217		* ss->prev[0 .. B - 1] contain bytes P - B .. P - 1
218		* of the current input row.
219		* prev_row[P .. N + B - 1] contain bytes P - B .. N - 1
220		* of the previous input row.
221		* We must handle the edges of each row specially, by clearing ss->prev at
222		* the beginning of each row, and copying trailing bytes from ss->prev (and
223		* possibly the input) to prev_row at the end of each row.
224		*/
225		static int
226		optimum_predictor(const stream_state * st, const stream_cursor_read * pr)
227	254k	{
228	254k	return cSub;
229	254k	}
230		static int
231		s_PNGPE_process(stream_state * st, stream_cursor_read * pr,
232		stream_cursor_write * pw, bool last)
233	1.42M	{
234	1.42M	stream_PNGP_state const ss = (stream_PNGP_state ) st;
235	1.42M	int bpp = ss->bpp;
236	1.42M	int status = 0;
237
238	2.85M	while (pr->ptr < pr->limit) {
239	2.38M	uint count;
240
241	2.38M	if (ss->row_left == 0) {
242		/* Beginning of row, write algorithm byte. */
243	254k	int predictor;
244
245	254k	if (pw->ptr >= pw->limit) {
246	336	status = 1;
247	336	break;
248	336	}
249	254k	predictor =
250	254k	(ss->Predictor == cOptimum ?
251	254k	optimum_predictor(st, pr) :
252	254k	ss->Predictor);
253	254k	*++(pw->ptr) = (byte) predictor - cNone;
254	254k	ss->case_index = predictor + cEncode;
255	254k	ss->row_left = ss->row_count;
256	254k	memset(ss->prev, 0, bpp);
257	254k	continue;
258	254k	}
259	2.12M	count = s_pngp_count(st, pr, pw);
260	2.12M	if (count == 0) {
261		/* We know we have input, so output must be full. */
262	942k	status = 1;
263	942k	break;
264	1.18M	} {
265	1.18M	byte *up = ss->prev_row + bpp + ss->row_count - ss->row_left;
266	1.18M	uint n = min(count, bpp);
267
268		/* Process bytes whose predecessors are in prev. */
269	1.18M	s_pngp_process(st, pw, ss->prev, pr, up - bpp, up, n);
270	1.18M	if (ss->row_left == 0) {
271	3.86k	if (ss->prev_row) {
272	3.86k	memcpy(up - bpp, ss->prev, bpp);
273	3.86k	memcpy(up, pr->ptr - (n - 1), n);
274	3.86k	}
275	3.86k	continue;
276	3.86k	}
277	1.18M	if (ss->prev_row)
278	1.18M	memcpy(up - bpp, ss->prev, n);
279	1.18M	if (n < bpp) {
280		/*
281		* We didn't have both enough input data and enough output
282		* space to use up all of prev. Shift more data into prev
283		* and exit.
284		*/
285	7.95k	int prev_left = bpp - n;
286
287	7.95k	memmove(ss->prev, ss->prev + n, prev_left);
288	7.95k	memcpy(ss->prev + prev_left, pr->ptr - (n - 1), n);
289	7.95k	if (pw->ptr >= pw->limit && pr->ptr < pr->limit)
290	2.72k	status = 1;
291	7.95k	break;
292	7.95k	}
293		/* Process bytes whose predecessors are in the input. */
294		/* We know we have at least bpp input and output bytes, */
295		/* and that n = bpp. */
296	1.17M	count -= bpp;
297	1.17M	s_pngp_process(st, pw, pr->ptr - (bpp - 1), pr,
298	1.17M	up, up + bpp, count);
299	1.17M	memcpy(ss->prev, pr->ptr - (bpp - 1), bpp);
300	1.17M	if (ss->prev_row) {
301	1.17M	memcpy(up, pr->ptr - (bpp + count - 1), count);
302	1.17M	if (ss->row_left == 0)
303	250k	memcpy(up + count, ss->prev, bpp);
304	1.17M	}
305	1.17M	}
306	1.17M	}
307	1.42M	return status;
308	1.42M	}
309
310		/*
311		* Decode a buffer. Let N = ss->row_count, P = N - ss->row_left,
312		* and B = ss->bpp. Consider that bytes [-B .. -1] of every row are zero.
313		* Then:
314		* prev_row[0 .. P - 1] contain bytes -B .. P - B - 1
315		* of the current output row.
316		* ss->prev[0 .. B - 1] contain bytes P - B .. P - 1
317		* of the current output row.
318		* prev_row[P .. N + B - 1] contain bytes P - B .. N - 1
319		* of the previous output row.
320		* We must handle the edges of each row specially, by clearing ss->prev at
321		* the beginning of each row, and copying trailing bytes from ss->prev (and
322		* possibly the output) to prev_row at the end of each row.
323		*/
324		static int
325		s_PNGPD_process(stream_state * st, stream_cursor_read * pr,
326		stream_cursor_write * pw, bool last)
327	402k	{
328	402k	stream_PNGP_state const ss = (stream_PNGP_state ) st;
329	402k	int bpp = ss->bpp;
330	402k	int status = 0;
331
332	4.86M	while (pr->ptr < pr->limit) {
333	4.63M	uint count;
334
335	4.63M	if (ss->row_left == 0) {
336		/* Beginning of row, read algorithm byte. */
337	2.07M	int predictor = pr->ptr[1];
338
339	2.07M	if (predictor >= cOptimum - cNone) {
340	8.45k	status = ERRC;
341	8.45k	break;
342	8.45k	}
343	2.06M	pr->ptr++;
344	2.06M	ss->case_index = predictor + cNone + cDecode;
345	2.06M	ss->row_left = ss->row_count;
346	2.06M	memset(ss->prev, 0, bpp);
347	2.06M	continue;
348	2.07M	}
349	2.55M	count = s_pngp_count(st, pr, pw);
350	2.55M	if (count == 0) {
351		/* We know we have input, so output must be full. */
352	162k	status = 1;
353	162k	break;
354	2.39M	} {
355	2.39M	byte *up = ss->prev_row + bpp + ss->row_count - ss->row_left;
356	2.39M	uint n = min(count, bpp);
357
358		/* Process bytes whose predecessors are in prev. */
359	2.39M	s_pngp_process(st, pw, ss->prev, pr, up - bpp, up, n);
360	2.39M	if (ss->row_left == 0) {
361	186k	if (ss->prev_row) {
362	186k	memcpy(up - bpp, ss->prev, bpp);
363	186k	memcpy(up, pw->ptr - (n - 1), n);
364	186k	}
365	186k	continue;
366	186k	}
367	2.20M	if (ss->prev_row)
368	2.20M	memcpy(up - bpp, ss->prev, n);
369	2.20M	if (n < bpp) {
370		/*
371		* We didn't have both enough input data and enough output
372		* space to use up all of prev. Shift more data into prev
373		* and exit.
374		*/
375	2.11k	int prev_left = bpp - n;
376
377	2.11k	memmove(ss->prev, ss->prev + n, prev_left);
378	2.11k	memcpy(ss->prev + prev_left, pw->ptr - (n - 1), n);
379	2.11k	if (pw->ptr >= pw->limit && pr->ptr < pr->limit)
380	158	status = 1;
381	2.11k	break;
382	2.11k	}
383		/* Process bytes whose predecessors are in the output. */
384		/* We know we have at least bpp input and output bytes, */
385		/* and that n = bpp. */
386	2.20M	count -= bpp;
387	2.20M	s_pngp_process(st, pw, pw->ptr - (bpp - 1), pr,
388	2.20M	up, up + bpp, count);
389	2.20M	memcpy(ss->prev, pw->ptr - (bpp - 1), bpp);
390	2.20M	if (ss->prev_row) {
391	2.20M	memcpy(up, pw->ptr - (bpp + count - 1), count);
392	2.20M	if (ss->row_left == 0)
393	1.87M	memcpy(up + count, ss->prev, bpp);
394	2.20M	}
395	2.20M	}
396	2.20M	}
397	402k	return status;
398	402k	}
399
400		/* Stream templates */
401		const stream_template s_PNGPE_template = {
402		&st_PNGP_state, s_PNGPE_init, s_PNGPE_process, 1, 1, s_PNGP_release,
403		s_PNGP_set_defaults, s_PNGP_reinit
404		};
405		const stream_template s_PNGPD_template = {
406		&st_PNGP_state, s_PNGPD_init, s_PNGPD_process, 1, 1, s_PNGP_release,
407		s_PNGP_set_defaults, s_PNGP_reinit
408		};