/src/ghostpdl/psi/ibnum.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.
*/


/* Level 2 encoded number reading utilities for Ghostscript */
#include "math_.h"
#include "memory_.h"
#include "ghost.h"
#include "opcheck.h"
#include "ierrors.h"
#include "stream.h"
#include "ibnum.h"
#include "imemory.h"    /* for iutil.h */
#include "iutil.h"

/* Define the number of bytes for a given format of encoded number. */
const byte enc_num_bytes[] = {
    enc_num_bytes_values
};

/* ------ Encoded number reading ------ */

/* Set up to read from an encoded number array/string. */
/* Return <0 for error, or a number format. */
int
num_array_format(const ref * op)
{
    int format;

    switch (r_type(op)) {
        case t_string:
            {
                /* Check that this is a legitimate encoded number string. */
                const byte *bp = op->value.bytes;

                if (r_size(op) < 4 || bp[0] != bt_num_array_value)
                    return_error(gs_error_typecheck);
                format = bp[1];
                if (!num_is_valid(format) ||
                    sdecodeshort(bp + 2, format) !=
                    (r_size(op) - 4) / encoded_number_bytes(format)
                    )
                    return_error(gs_error_rangecheck);
            }
            break;
        case t_array:
        case t_mixedarray:
        case t_shortarray:
            format = num_array;
            break;
        default:
            return_error(gs_error_typecheck);
    }
    check_read(*op);
    return format;
}

/* Get the number of elements in an encoded number array/string. */
uint
num_array_size(const ref * op, int format)
{
    return (format == num_array ? r_size(op) :
            (r_size(op) - 4) / encoded_number_bytes(format));
}

/* Get an encoded number from an array/string according to the given format. */
/* Put the value in np->value.{intval,realval}. */
/* Return t_int if integer, t_real if real, t_null if end of stream, */
/* or an error if the format is invalid. */
int
num_array_get(const gs_memory_t *mem, const ref * op, int format, uint index, ref * np)
{
    if (format == num_array) {
        int code = array_get(mem, op, (long)index, np);

        if (code < 0)
            return t_null;
        switch (r_type(np)) {
            case t_integer:
                return t_integer;
            case t_real:
                return t_real;
            default:
                return_error(gs_error_typecheck);
        }
    } else {
        uint nbytes = encoded_number_bytes(format);

        if (index >= (r_size(op) - 4) / nbytes)
            return t_null;
        return sdecode_number(op->value.bytes + 4 + index * nbytes,
                              format, np);
    }
}

/* Internal routine to decode a number in a given format. */
/* Same returns as sget_encoded_number. */
static const double binary_scale[32] = {
#define EXPN2(n) (0.5 / (1L << (n-1)))
    1.0, EXPN2(1), EXPN2(2), EXPN2(3),
    EXPN2(4), EXPN2(5), EXPN2(6), EXPN2(7),
    EXPN2(8), EXPN2(9), EXPN2(10), EXPN2(11),
    EXPN2(12), EXPN2(13), EXPN2(14), EXPN2(15),
    EXPN2(16), EXPN2(17), EXPN2(18), EXPN2(19),
    EXPN2(20), EXPN2(21), EXPN2(22), EXPN2(23),
    EXPN2(24), EXPN2(25), EXPN2(26), EXPN2(27),
    EXPN2(28), EXPN2(29), EXPN2(30), EXPN2(31)
#undef EXPN2
};
int
sdecode_number(const byte * str, int format, ref * np)
{
    switch (format & 0x170) {
        case num_int32:
        case num_int32 + 16:
            if ((format & 31) == 0) {
                np->value.intval = sdecodeint32(str, format);
                return t_integer;
            } else {
                np->value.realval =
                    (double)sdecodeint32(str, format) *
                    binary_scale[format & 31];
                return t_real;
            }
        case num_int16:
            if ((format & 15) == 0) {
                np->value.intval = sdecodeshort(str, format);
                return t_integer;
            } else {
                np->value.realval =
                    sdecodeshort(str, format) *
                    binary_scale[format & 15];
                return t_real;
            }
        case num_float:
            {
                float fval;
                int code = sdecode_float(str, format, &fval);

                if (code < 0)
                    return code;
                np->value.realval = fval;
                return t_real;
            }
        default:
            return_error(gs_error_syntaxerror); /* invalid format?? */
    }
}

/* ------ Decode number ------ */

/* Decode encoded numbers from a string according to format. */

/* Decode a (16-bit, signed or unsigned) short. */
uint
sdecodeushort(const byte * p, int format)
{
    int a = p[0], b = p[1];

    return (num_is_lsb(format) ? (b << 8) + a : (a << 8) + b);
}
int
sdecodeshort(const byte * p, int format)
{
    int v = (int)sdecodeushort(p, format);

    return (v & 0x7fff) - (v & 0x8000);
}

/* Decode a (32-bit, signed) long. */
int
sdecodeint32(const byte * p, int format)
{
    int a = p[0], b = p[1], c = p[2], d = p[3];
    int v = (num_is_lsb(format) ?
              ((int)d << 24) + ((int)c << 16) + (b << 8) + a :
              ((int)a << 24) + ((int)b << 16) + (c << 8) + d);
    return v;
}

/* Decode a 32-bit number. Return the resukt through a pointer */
/* to work around a gcc 4.2.1 bug on PowerPC, bug 689586 */
static void
sdecodebits32(const byte * p, int format, bits32 *v)
{
  int a = p[0], b = p[1], c = p[2], d = p[3];
  *v = (num_is_lsb(format) ?
            ((long)d << 24) + ((long)c << 16) + (b << 8) + a :
            ((long)a << 24) + ((long)b << 16) + (c << 8) + d);

}

/* Decode a float.  We assume that native floats occupy 32 bits. */
/* If the float is an IEEE NaN or Inf, return gs_error_undefinedresult. */
int
sdecode_float(const byte * p, int format, float *pfnum)
{
    bits32 lnum;

    if ((format & ~(num_msb | num_lsb)) == num_float_native) {
        /*
         * Just read 4 bytes and interpret them as a float, ignoring
         * any indication of byte ordering.
         */
        memcpy(pfnum, p, 4);
#if !ARCH_FLOATS_ARE_IEEE
        return 0;   /* no way to check for anomalies */
#endif
        lnum = *(bits32 *)pfnum;
    } else {
        sdecodebits32(p, format, &lnum);

#if !ARCH_FLOATS_ARE_IEEE
        {
            /* We know IEEE floats take 32 bits. */
            /* Convert IEEE float to native float. */
            int sign_expt = lnum >> 23;
            int expt = sign_expt & 0xff;
            long mant = lnum & 0x7fffff;
            float fnum;

            if (expt == 0 && mant == 0)
                fnum = 0;
            else if (expt == 0xff)
                return_error(gs_error_undefinedresult); /* Inf or NaN */
            else {
                mant += 0x800000;
                fnum = (float)ldexp((float)mant, expt - 127 - 23);
            }
            if (sign_expt & 0x100)
                fnum = -fnum;
            *pfnum = fnum;
            return 0;   /* checked for Infs and NaNs above */
        }
#else
        *pfnum = *(float *)&lnum;
#endif
    }
    /*
     * Unfortunately, there is no portable way for testing whether a float
     * is a NaN or Inf.  Do it "by hand" if the input representation is
     * IEEE (which is the case if control arrives here).
     */
    if (!(~lnum & 0x7f800000)) /* i.e. exponent all 1's */
        return_error(gs_error_undefinedresult); /* Inf or NaN */
    return 0;
}

Coverage Report

Created: 2025-06-10 07:26

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		/* Level 2 encoded number reading utilities for Ghostscript */
18		#include "math_.h"
19		#include "memory_.h"
20		#include "ghost.h"
21		#include "opcheck.h"
22		#include "ierrors.h"
23		#include "stream.h"
24		#include "ibnum.h"
25		#include "imemory.h" /* for iutil.h */
26		#include "iutil.h"
27
28		/* Define the number of bytes for a given format of encoded number. */
29		const byte enc_num_bytes[] = {
30		enc_num_bytes_values
31		};
32
33		/* ------ Encoded number reading ------ */
34
35		/* Set up to read from an encoded number array/string. */
36		/* Return <0 for error, or a number format. */
37		int
38		num_array_format(const ref * op)
39	0	{
40	0	int format;
41
42	0	switch (r_type(op)) {
43	0	case t_string:
44	0	{
45		/* Check that this is a legitimate encoded number string. */
46	0	const byte *bp = op->value.bytes;
47
48	0	if (r_size(op) < 4 \|\| bp[0] != bt_num_array_value)
49	0	return_error(gs_error_typecheck);
50	0	format = bp[1];
51	0	if (!num_is_valid(format) \|\|
52	0	sdecodeshort(bp + 2, format) !=
53	0	(r_size(op) - 4) / encoded_number_bytes(format)
54	0	)
55	0	return_error(gs_error_rangecheck);
56	0	}
57	0	break;
58	0	case t_array:
59	0	case t_mixedarray:
60	0	case t_shortarray:
61	0	format = num_array;
62	0	break;
63	0	default:
64	0	return_error(gs_error_typecheck);
65	0	}
66	0	check_read(*op);
67	0	return format;
68	0	}
69
70		/* Get the number of elements in an encoded number array/string. */
71		uint
72		num_array_size(const ref * op, int format)
73	0	{
74	0	return (format == num_array ? r_size(op) :
75	0	(r_size(op) - 4) / encoded_number_bytes(format));
76	0	}
77
78		/* Get an encoded number from an array/string according to the given format. */
79		/* Put the value in np->value.{intval,realval}. */
80		/* Return t_int if integer, t_real if real, t_null if end of stream, */
81		/* or an error if the format is invalid. */
82		int
83		num_array_get(const gs_memory_t mem, const ref op, int format, uint index, ref * np)
84	0	{
85	0	if (format == num_array) {
86	0	int code = array_get(mem, op, (long)index, np);
87
88	0	if (code < 0)
89	0	return t_null;
90	0	switch (r_type(np)) {
91	0	case t_integer:
92	0	return t_integer;
93	0	case t_real:
94	0	return t_real;
95	0	default:
96	0	return_error(gs_error_typecheck);
97	0	}
98	0	} else {
99	0	uint nbytes = encoded_number_bytes(format);
100
101	0	if (index >= (r_size(op) - 4) / nbytes)
102	0	return t_null;
103	0	return sdecode_number(op->value.bytes + 4 + index * nbytes,
104	0	format, np);
105	0	}
106	0	}
107
108		/* Internal routine to decode a number in a given format. */
109		/* Same returns as sget_encoded_number. */
110		static const double binary_scale[32] = {
111		#define EXPN2(n) (0.5 / (1L << (n-1)))
112		1.0, EXPN2(1), EXPN2(2), EXPN2(3),
113		EXPN2(4), EXPN2(5), EXPN2(6), EXPN2(7),
114		EXPN2(8), EXPN2(9), EXPN2(10), EXPN2(11),
115		EXPN2(12), EXPN2(13), EXPN2(14), EXPN2(15),
116		EXPN2(16), EXPN2(17), EXPN2(18), EXPN2(19),
117		EXPN2(20), EXPN2(21), EXPN2(22), EXPN2(23),
118		EXPN2(24), EXPN2(25), EXPN2(26), EXPN2(27),
119		EXPN2(28), EXPN2(29), EXPN2(30), EXPN2(31)
120		#undef EXPN2
121		};
122		int
123		sdecode_number(const byte * str, int format, ref * np)
124	0	{
125	0	switch (format & 0x170) {
126	0	case num_int32:
127	0	case num_int32 + 16:
128	0	if ((format & 31) == 0) {
129	0	np->value.intval = sdecodeint32(str, format);
130	0	return t_integer;
131	0	} else {
132	0	np->value.realval =
133	0	(double)sdecodeint32(str, format) *
134	0	binary_scale[format & 31];
135	0	return t_real;
136	0	}
137	0	case num_int16:
138	0	if ((format & 15) == 0) {
139	0	np->value.intval = sdecodeshort(str, format);
140	0	return t_integer;
141	0	} else {
142	0	np->value.realval =
143	0	sdecodeshort(str, format) *
144	0	binary_scale[format & 15];
145	0	return t_real;
146	0	}
147	0	case num_float:
148	0	{
149	0	float fval;
150	0	int code = sdecode_float(str, format, &fval);
151
152	0	if (code < 0)
153	0	return code;
154	0	np->value.realval = fval;
155	0	return t_real;
156	0	}
157	0	default:
158	0	return_error(gs_error_syntaxerror); /* invalid format?? */
159	0	}
160	0	}
161
162		/* ------ Decode number ------ */
163
164		/* Decode encoded numbers from a string according to format. */
165
166		/* Decode a (16-bit, signed or unsigned) short. */
167		uint
168		sdecodeushort(const byte * p, int format)
169	0	{
170	0	int a = p[0], b = p[1];
171
172	0	return (num_is_lsb(format) ? (b << 8) + a : (a << 8) + b);
173	0	}
174		int
175		sdecodeshort(const byte * p, int format)
176	0	{
177	0	int v = (int)sdecodeushort(p, format);
178
179	0	return (v & 0x7fff) - (v & 0x8000);
180	0	}
181
182		/* Decode a (32-bit, signed) long. */
183		int
184		sdecodeint32(const byte * p, int format)
185	0	{
186	0	int a = p[0], b = p[1], c = p[2], d = p[3];
187	0	int v = (num_is_lsb(format) ?
188	0	((int)d << 24) + ((int)c << 16) + (b << 8) + a :
189	0	((int)a << 24) + ((int)b << 16) + (c << 8) + d);
190	0	return v;
191	0	}
192
193		/* Decode a 32-bit number. Return the resukt through a pointer */
194		/* to work around a gcc 4.2.1 bug on PowerPC, bug 689586 */
195		static void
196		sdecodebits32(const byte * p, int format, bits32 *v)
197	0	{
198	0	int a = p[0], b = p[1], c = p[2], d = p[3];
199	0	*v = (num_is_lsb(format) ?
200	0	((long)d << 24) + ((long)c << 16) + (b << 8) + a :
201	0	((long)a << 24) + ((long)b << 16) + (c << 8) + d);
202
203	0	}
204
205		/* Decode a float. We assume that native floats occupy 32 bits. */
206		/* If the float is an IEEE NaN or Inf, return gs_error_undefinedresult. */
207		int
208		sdecode_float(const byte * p, int format, float *pfnum)
209	0	{
210	0	bits32 lnum;
211
212	0	if ((format & ~(num_msb \| num_lsb)) == num_float_native) {
213		/*
214		* Just read 4 bytes and interpret them as a float, ignoring
215		* any indication of byte ordering.
216		*/
217	0	memcpy(pfnum, p, 4);
218		#if !ARCH_FLOATS_ARE_IEEE
219		return 0; /* no way to check for anomalies */
220		#endif
221	0	lnum = (bits32 )pfnum;
222	0	} else {
223	0	sdecodebits32(p, format, &lnum);
224
225		#if !ARCH_FLOATS_ARE_IEEE
226		{
227		/* We know IEEE floats take 32 bits. */
228		/* Convert IEEE float to native float. */
229		int sign_expt = lnum >> 23;
230		int expt = sign_expt & 0xff;
231		long mant = lnum & 0x7fffff;
232		float fnum;
233
234		if (expt == 0 && mant == 0)
235		fnum = 0;
236		else if (expt == 0xff)
237		return_error(gs_error_undefinedresult); /* Inf or NaN */
238		else {
239		mant += 0x800000;
240		fnum = (float)ldexp((float)mant, expt - 127 - 23);
241		}
242		if (sign_expt & 0x100)
243		fnum = -fnum;
244		*pfnum = fnum;
245		return 0; /* checked for Infs and NaNs above */
246		}
247		#else
248	0	pfnum = (float *)&lnum;
249	0	#endif
250	0	}
251		/*
252		* Unfortunately, there is no portable way for testing whether a float
253		* is a NaN or Inf. Do it "by hand" if the input representation is
254		* IEEE (which is the case if control arrives here).
255		*/
256	0	if (!(~lnum & 0x7f800000)) /* i.e. exponent all 1's */
257	0	return_error(gs_error_undefinedresult); /* Inf or NaN */
258	0	return 0;
259	0	}