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|
#define _GNU_SOURCE
#include "utils.h"
#include <signal.h>
#include <stdlib.h>
#ifdef HAVE_GETTIMEOFDAY
#include <sys/time.h>
#else
#include <time.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif
#ifdef HAVE_FENV_H
#include <fenv.h>
#endif
#ifdef HAVE_LIBPNG
#include <png.h>
#endif
/* Random number seed
*/
uint32_t lcg_seed;
/*----------------------------------------------------------------------------*\
* CRC-32 version 2.0.0 by Craig Bruce, 2006-04-29.
*
* This program generates the CRC-32 values for the files named in the
* command-line arguments. These are the same CRC-32 values used by GZIP,
* PKZIP, and ZMODEM. The Crc32_ComputeBuf () can also be detached and
* used independently.
*
* THIS PROGRAM IS PUBLIC-DOMAIN SOFTWARE.
*
* Based on the byte-oriented implementation "File Verification Using CRC"
* by Mark R. Nelson in Dr. Dobb's Journal, May 1992, pp. 64-67.
*
* v1.0.0: original release.
* v1.0.1: fixed printf formats.
* v1.0.2: fixed something else.
* v1.0.3: replaced CRC constant table by generator function.
* v1.0.4: reformatted code, made ANSI C. 1994-12-05.
* v2.0.0: rewrote to use memory buffer & static table, 2006-04-29.
\*----------------------------------------------------------------------------*/
/*----------------------------------------------------------------------------*\
* NAME:
* Crc32_ComputeBuf () - computes the CRC-32 value of a memory buffer
* DESCRIPTION:
* Computes or accumulates the CRC-32 value for a memory buffer.
* The 'inCrc32' gives a previously accumulated CRC-32 value to allow
* a CRC to be generated for multiple sequential buffer-fuls of data.
* The 'inCrc32' for the first buffer must be zero.
* ARGUMENTS:
* inCrc32 - accumulated CRC-32 value, must be 0 on first call
* buf - buffer to compute CRC-32 value for
* bufLen - number of bytes in buffer
* RETURNS:
* crc32 - computed CRC-32 value
* ERRORS:
* (no errors are possible)
\*----------------------------------------------------------------------------*/
uint32_t
compute_crc32 (uint32_t in_crc32,
const void *buf,
size_t buf_len)
{
static const uint32_t crc_table[256] = {
0x00000000, 0x77073096, 0xEE0E612C, 0x990951BA, 0x076DC419, 0x706AF48F,
0xE963A535, 0x9E6495A3, 0x0EDB8832, 0x79DCB8A4, 0xE0D5E91E, 0x97D2D988,
0x09B64C2B, 0x7EB17CBD, 0xE7B82D07, 0x90BF1D91, 0x1DB71064, 0x6AB020F2,
0xF3B97148, 0x84BE41DE, 0x1ADAD47D, 0x6DDDE4EB, 0xF4D4B551, 0x83D385C7,
0x136C9856, 0x646BA8C0, 0xFD62F97A, 0x8A65C9EC, 0x14015C4F, 0x63066CD9,
0xFA0F3D63, 0x8D080DF5, 0x3B6E20C8, 0x4C69105E, 0xD56041E4, 0xA2677172,
0x3C03E4D1, 0x4B04D447, 0xD20D85FD, 0xA50AB56B, 0x35B5A8FA, 0x42B2986C,
0xDBBBC9D6, 0xACBCF940, 0x32D86CE3, 0x45DF5C75, 0xDCD60DCF, 0xABD13D59,
0x26D930AC, 0x51DE003A, 0xC8D75180, 0xBFD06116, 0x21B4F4B5, 0x56B3C423,
0xCFBA9599, 0xB8BDA50F, 0x2802B89E, 0x5F058808, 0xC60CD9B2, 0xB10BE924,
0x2F6F7C87, 0x58684C11, 0xC1611DAB, 0xB6662D3D, 0x76DC4190, 0x01DB7106,
0x98D220BC, 0xEFD5102A, 0x71B18589, 0x06B6B51F, 0x9FBFE4A5, 0xE8B8D433,
0x7807C9A2, 0x0F00F934, 0x9609A88E, 0xE10E9818, 0x7F6A0DBB, 0x086D3D2D,
0x91646C97, 0xE6635C01, 0x6B6B51F4, 0x1C6C6162, 0x856530D8, 0xF262004E,
0x6C0695ED, 0x1B01A57B, 0x8208F4C1, 0xF50FC457, 0x65B0D9C6, 0x12B7E950,
0x8BBEB8EA, 0xFCB9887C, 0x62DD1DDF, 0x15DA2D49, 0x8CD37CF3, 0xFBD44C65,
0x4DB26158, 0x3AB551CE, 0xA3BC0074, 0xD4BB30E2, 0x4ADFA541, 0x3DD895D7,
0xA4D1C46D, 0xD3D6F4FB, 0x4369E96A, 0x346ED9FC, 0xAD678846, 0xDA60B8D0,
0x44042D73, 0x33031DE5, 0xAA0A4C5F, 0xDD0D7CC9, 0x5005713C, 0x270241AA,
0xBE0B1010, 0xC90C2086, 0x5768B525, 0x206F85B3, 0xB966D409, 0xCE61E49F,
0x5EDEF90E, 0x29D9C998, 0xB0D09822, 0xC7D7A8B4, 0x59B33D17, 0x2EB40D81,
0xB7BD5C3B, 0xC0BA6CAD, 0xEDB88320, 0x9ABFB3B6, 0x03B6E20C, 0x74B1D29A,
0xEAD54739, 0x9DD277AF, 0x04DB2615, 0x73DC1683, 0xE3630B12, 0x94643B84,
0x0D6D6A3E, 0x7A6A5AA8, 0xE40ECF0B, 0x9309FF9D, 0x0A00AE27, 0x7D079EB1,
0xF00F9344, 0x8708A3D2, 0x1E01F268, 0x6906C2FE, 0xF762575D, 0x806567CB,
0x196C3671, 0x6E6B06E7, 0xFED41B76, 0x89D32BE0, 0x10DA7A5A, 0x67DD4ACC,
0xF9B9DF6F, 0x8EBEEFF9, 0x17B7BE43, 0x60B08ED5, 0xD6D6A3E8, 0xA1D1937E,
0x38D8C2C4, 0x4FDFF252, 0xD1BB67F1, 0xA6BC5767, 0x3FB506DD, 0x48B2364B,
0xD80D2BDA, 0xAF0A1B4C, 0x36034AF6, 0x41047A60, 0xDF60EFC3, 0xA867DF55,
0x316E8EEF, 0x4669BE79, 0xCB61B38C, 0xBC66831A, 0x256FD2A0, 0x5268E236,
0xCC0C7795, 0xBB0B4703, 0x220216B9, 0x5505262F, 0xC5BA3BBE, 0xB2BD0B28,
0x2BB45A92, 0x5CB36A04, 0xC2D7FFA7, 0xB5D0CF31, 0x2CD99E8B, 0x5BDEAE1D,
0x9B64C2B0, 0xEC63F226, 0x756AA39C, 0x026D930A, 0x9C0906A9, 0xEB0E363F,
0x72076785, 0x05005713, 0x95BF4A82, 0xE2B87A14, 0x7BB12BAE, 0x0CB61B38,
0x92D28E9B, 0xE5D5BE0D, 0x7CDCEFB7, 0x0BDBDF21, 0x86D3D2D4, 0xF1D4E242,
0x68DDB3F8, 0x1FDA836E, 0x81BE16CD, 0xF6B9265B, 0x6FB077E1, 0x18B74777,
0x88085AE6, 0xFF0F6A70, 0x66063BCA, 0x11010B5C, 0x8F659EFF, 0xF862AE69,
0x616BFFD3, 0x166CCF45, 0xA00AE278, 0xD70DD2EE, 0x4E048354, 0x3903B3C2,
0xA7672661, 0xD06016F7, 0x4969474D, 0x3E6E77DB, 0xAED16A4A, 0xD9D65ADC,
0x40DF0B66, 0x37D83BF0, 0xA9BCAE53, 0xDEBB9EC5, 0x47B2CF7F, 0x30B5FFE9,
0xBDBDF21C, 0xCABAC28A, 0x53B39330, 0x24B4A3A6, 0xBAD03605, 0xCDD70693,
0x54DE5729, 0x23D967BF, 0xB3667A2E, 0xC4614AB8, 0x5D681B02, 0x2A6F2B94,
0xB40BBE37, 0xC30C8EA1, 0x5A05DF1B, 0x2D02EF8D
};
uint32_t crc32;
unsigned char * byte_buf;
size_t i;
/* accumulate crc32 for buffer */
crc32 = in_crc32 ^ 0xFFFFFFFF;
byte_buf = (unsigned char*) buf;
for (i = 0; i < buf_len; i++)
crc32 = (crc32 >> 8) ^ crc_table[(crc32 ^ byte_buf[i]) & 0xFF];
return (crc32 ^ 0xFFFFFFFF);
}
static uint32_t
compute_crc32_for_image_internal (uint32_t crc32,
pixman_image_t *img,
pixman_bool_t remove_alpha,
pixman_bool_t remove_rgb)
{
pixman_format_code_t fmt = pixman_image_get_format (img);
uint32_t *data = pixman_image_get_data (img);
int stride = pixman_image_get_stride (img);
int height = pixman_image_get_height (img);
uint32_t mask = 0xffffffff;
int i;
/* mask unused 'x' part */
if (PIXMAN_FORMAT_BPP (fmt) - PIXMAN_FORMAT_DEPTH (fmt) &&
PIXMAN_FORMAT_DEPTH (fmt) != 0)
{
uint32_t m = (1 << PIXMAN_FORMAT_DEPTH (fmt)) - 1;
if (PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_BGRA ||
PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_RGBA)
{
m <<= (PIXMAN_FORMAT_BPP (fmt) - PIXMAN_FORMAT_DEPTH (fmt));
}
mask &= m;
}
/* mask alpha channel */
if (remove_alpha && PIXMAN_FORMAT_A (fmt))
{
uint32_t m;
if (PIXMAN_FORMAT_BPP (fmt) == 32)
m = 0xffffffff;
else
m = (1 << PIXMAN_FORMAT_BPP (fmt)) - 1;
m >>= PIXMAN_FORMAT_A (fmt);
if (PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_BGRA ||
PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_RGBA ||
PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_A)
{
/* Alpha is at the bottom of the pixel */
m <<= PIXMAN_FORMAT_A (fmt);
}
mask &= m;
}
/* mask rgb channels */
if (remove_rgb && PIXMAN_FORMAT_RGB (fmt))
{
uint32_t m = ((uint32_t)~0) >> (32 - PIXMAN_FORMAT_BPP (fmt));
uint32_t size = PIXMAN_FORMAT_R (fmt) + PIXMAN_FORMAT_G (fmt) + PIXMAN_FORMAT_B (fmt);
m &= ~((1 << size) - 1);
if (PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_BGRA ||
PIXMAN_FORMAT_TYPE (fmt) == PIXMAN_TYPE_RGBA)
{
/* RGB channels are at the top of the pixel */
m >>= size;
}
mask &= m;
}
for (i = 0; i * PIXMAN_FORMAT_BPP (fmt) < 32; i++)
mask |= mask << (i * PIXMAN_FORMAT_BPP (fmt));
for (i = 0; i < stride * height / 4; i++)
data[i] &= mask;
/* swap endiannes in order to provide identical results on both big
* and litte endian systems
*/
image_endian_swap (img);
return compute_crc32 (crc32, data, stride * height);
}
uint32_t
compute_crc32_for_image (uint32_t crc32,
pixman_image_t *img)
{
if (img->common.alpha_map)
{
crc32 = compute_crc32_for_image_internal (crc32, img, TRUE, FALSE);
crc32 = compute_crc32_for_image_internal (
crc32, (pixman_image_t *)img->common.alpha_map, FALSE, TRUE);
}
else
{
crc32 = compute_crc32_for_image_internal (crc32, img, FALSE, FALSE);
}
return crc32;
}
pixman_bool_t
is_little_endian (void)
{
volatile uint16_t endian_check_var = 0x1234;
return (*(volatile uint8_t *)&endian_check_var == 0x34);
}
/* perform endian conversion of pixel data
*/
void
image_endian_swap (pixman_image_t *img)
{
int stride = pixman_image_get_stride (img);
uint32_t *data = pixman_image_get_data (img);
int height = pixman_image_get_height (img);
int bpp = PIXMAN_FORMAT_BPP (pixman_image_get_format (img));
int i, j;
/* swap bytes only on big endian systems */
if (is_little_endian())
return;
if (bpp == 8)
return;
for (i = 0; i < height; i++)
{
uint8_t *line_data = (uint8_t *)data + stride * i;
switch (bpp)
{
case 1:
for (j = 0; j < stride; j++)
{
line_data[j] =
((line_data[j] & 0x80) >> 7) |
((line_data[j] & 0x40) >> 5) |
((line_data[j] & 0x20) >> 3) |
((line_data[j] & 0x10) >> 1) |
((line_data[j] & 0x08) << 1) |
((line_data[j] & 0x04) << 3) |
((line_data[j] & 0x02) << 5) |
((line_data[j] & 0x01) << 7);
}
break;
case 4:
for (j = 0; j < stride; j++)
{
line_data[j] = (line_data[j] >> 4) | (line_data[j] << 4);
}
break;
case 16:
for (j = 0; j + 2 <= stride; j += 2)
{
char t1 = line_data[j + 0];
char t2 = line_data[j + 1];
line_data[j + 1] = t1;
line_data[j + 0] = t2;
}
break;
case 24:
for (j = 0; j + 3 <= stride; j += 3)
{
char t1 = line_data[j + 0];
char t2 = line_data[j + 1];
char t3 = line_data[j + 2];
line_data[j + 2] = t1;
line_data[j + 1] = t2;
line_data[j + 0] = t3;
}
break;
case 32:
for (j = 0; j + 4 <= stride; j += 4)
{
char t1 = line_data[j + 0];
char t2 = line_data[j + 1];
char t3 = line_data[j + 2];
char t4 = line_data[j + 3];
line_data[j + 3] = t1;
line_data[j + 2] = t2;
line_data[j + 1] = t3;
line_data[j + 0] = t4;
}
break;
default:
assert (FALSE);
break;
}
}
}
#define N_LEADING_PROTECTED 10
#define N_TRAILING_PROTECTED 10
typedef struct
{
void *addr;
uint32_t len;
uint8_t *trailing;
int n_bytes;
} info_t;
#if defined(HAVE_MPROTECT) && defined(HAVE_GETPAGESIZE) && defined(HAVE_SYS_MMAN_H) && defined(HAVE_MMAP)
/* This is apparently necessary on at least OS X */
#ifndef MAP_ANONYMOUS
#define MAP_ANONYMOUS MAP_ANON
#endif
void *
fence_malloc (int64_t len)
{
unsigned long page_size = getpagesize();
unsigned long page_mask = page_size - 1;
uint32_t n_payload_bytes = (len + page_mask) & ~page_mask;
uint32_t n_bytes =
(page_size * (N_LEADING_PROTECTED + N_TRAILING_PROTECTED + 2) +
n_payload_bytes) & ~page_mask;
uint8_t *initial_page;
uint8_t *leading_protected;
uint8_t *trailing_protected;
uint8_t *payload;
uint8_t *addr;
if (len < 0)
abort();
addr = mmap (NULL, n_bytes, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS,
-1, 0);
if (addr == MAP_FAILED)
{
printf ("mmap failed on %lld %u\n", (long long int)len, n_bytes);
return NULL;
}
initial_page = (uint8_t *)(((unsigned long)addr + page_mask) & ~page_mask);
leading_protected = initial_page + page_size;
payload = leading_protected + N_LEADING_PROTECTED * page_size;
trailing_protected = payload + n_payload_bytes;
((info_t *)initial_page)->addr = addr;
((info_t *)initial_page)->len = len;
((info_t *)initial_page)->trailing = trailing_protected;
((info_t *)initial_page)->n_bytes = n_bytes;
if ((mprotect (leading_protected, N_LEADING_PROTECTED * page_size,
PROT_NONE) == -1) ||
(mprotect (trailing_protected, N_TRAILING_PROTECTED * page_size,
PROT_NONE) == -1))
{
munmap (addr, n_bytes);
return NULL;
}
return payload;
}
void
fence_free (void *data)
{
uint32_t page_size = getpagesize();
uint8_t *payload = data;
uint8_t *leading_protected = payload - N_LEADING_PROTECTED * page_size;
uint8_t *initial_page = leading_protected - page_size;
info_t *info = (info_t *)initial_page;
munmap (info->addr, info->n_bytes);
}
#else
void *
fence_malloc (int64_t len)
{
return malloc (len);
}
void
fence_free (void *data)
{
free (data);
}
#endif
uint8_t *
make_random_bytes (int n_bytes)
{
uint8_t *bytes = fence_malloc (n_bytes);
int i;
if (!bytes)
return NULL;
for (i = 0; i < n_bytes; ++i)
bytes[i] = lcg_rand () & 0xff;
return bytes;
}
void
a8r8g8b8_to_rgba_np (uint32_t *dst, uint32_t *src, int n_pixels)
{
uint8_t *dst8 = (uint8_t *)dst;
int i;
for (i = 0; i < n_pixels; ++i)
{
uint32_t p = src[i];
uint8_t a, r, g, b;
a = (p & 0xff000000) >> 24;
r = (p & 0x00ff0000) >> 16;
g = (p & 0x0000ff00) >> 8;
b = (p & 0x000000ff) >> 0;
if (a != 0)
{
#define DIVIDE(c, a) \
do \
{ \
int t = ((c) * 255) / a; \
(c) = t < 0? 0 : t > 255? 255 : t; \
} while (0)
DIVIDE (r, a);
DIVIDE (g, a);
DIVIDE (b, a);
}
*dst8++ = r;
*dst8++ = g;
*dst8++ = b;
*dst8++ = a;
}
}
#ifdef HAVE_LIBPNG
pixman_bool_t
write_png (pixman_image_t *image, const char *filename)
{
int width = pixman_image_get_width (image);
int height = pixman_image_get_height (image);
int stride = width * 4;
uint32_t *data = malloc (height * stride);
pixman_image_t *copy;
png_struct *write_struct;
png_info *info_struct;
pixman_bool_t result = FALSE;
FILE *f = fopen (filename, "wb");
png_bytep *row_pointers;
int i;
if (!f)
return FALSE;
row_pointers = malloc (height * sizeof (png_bytep));
copy = pixman_image_create_bits (
PIXMAN_a8r8g8b8, width, height, data, stride);
pixman_image_composite32 (
PIXMAN_OP_SRC, image, NULL, copy, 0, 0, 0, 0, 0, 0, width, height);
a8r8g8b8_to_rgba_np (data, data, height * width);
for (i = 0; i < height; ++i)
row_pointers[i] = (png_bytep)(data + i * width);
if (!(write_struct = png_create_write_struct (
PNG_LIBPNG_VER_STRING, NULL, NULL, NULL)))
goto out1;
if (!(info_struct = png_create_info_struct (write_struct)))
goto out2;
png_init_io (write_struct, f);
png_set_IHDR (write_struct, info_struct, width, height,
8, PNG_COLOR_TYPE_RGB_ALPHA,
PNG_INTERLACE_NONE, PNG_COMPRESSION_TYPE_BASE,
PNG_FILTER_TYPE_BASE);
png_write_info (write_struct, info_struct);
png_write_image (write_struct, row_pointers);
png_write_end (write_struct, NULL);
result = TRUE;
out2:
png_destroy_write_struct (&write_struct, &info_struct);
out1:
if (fclose (f) != 0)
result = FALSE;
pixman_image_unref (copy);
free (row_pointers);
free (data);
return result;
}
#else /* no libpng */
pixman_bool_t
write_png (pixman_image_t *image, const char *filename)
{
return FALSE;
}
#endif
/*
* A function, which can be used as a core part of the test programs,
* intended to detect various problems with the help of fuzzing input
* to pixman API (according to some templates, aka "smart" fuzzing).
* Some general information about such testing can be found here:
* http://en.wikipedia.org/wiki/Fuzz_testing
*
* It may help detecting:
* - crashes on bad handling of valid or reasonably invalid input to
* pixman API.
* - deviations from the behavior of older pixman releases.
* - deviations from the behavior of the same pixman release, but
* configured in a different way (for example with SIMD optimizations
* disabled), or running on a different OS or hardware.
*
* The test is performed by calling a callback function a huge number
* of times. The callback function is expected to run some snippet of
* pixman code with pseudorandom variations to the data feeded to
* pixman API. A result of running each callback function should be
* some deterministic value which depends on test number (test number
* can be used as a seed for PRNG). When 'verbose' argument is nonzero,
* callback function is expected to print to stdout some information
* about what it does.
*
* Return values from many small tests are accumulated together and
* used as final checksum, which can be compared to some expected
* value. Running the tests not individually, but in a batch helps
* to reduce process start overhead and also allows to parallelize
* testing and utilize multiple CPU cores.
*
* The resulting executable can be run without any arguments. In
* this case it runs a batch of tests starting from 1 and up to
* 'default_number_of_iterations'. The resulting checksum is
* compared with 'expected_checksum' and FAIL or PASS verdict
* depends on the result of this comparison.
*
* If the executable is run with 2 numbers provided as command line
* arguments, they specify the starting and ending numbers for a test
* batch.
*
* If the executable is run with only one number provided as a command
* line argument, then this number is used to call the callback function
* once, and also with verbose flag set.
*/
int
fuzzer_test_main (const char *test_name,
int default_number_of_iterations,
uint32_t expected_checksum,
uint32_t (*test_function)(int testnum, int verbose),
int argc,
const char *argv[])
{
int i, n1 = 1, n2 = 0;
uint32_t checksum = 0;
int verbose = getenv ("VERBOSE") != NULL;
if (argc >= 3)
{
n1 = atoi (argv[1]);
n2 = atoi (argv[2]);
if (n2 < n1)
{
printf ("invalid test range\n");
return 1;
}
}
else if (argc >= 2)
{
n2 = atoi (argv[1]);
checksum = test_function (n2, 1);
printf ("%d: checksum=%08X\n", n2, checksum);
return 0;
}
else
{
n1 = 1;
n2 = default_number_of_iterations;
}
#ifdef USE_OPENMP
#pragma omp parallel for reduction(+:checksum) default(none) \
shared(n1, n2, test_function, verbose)
#endif
for (i = n1; i <= n2; i++)
{
uint32_t crc = test_function (i, 0);
if (verbose)
printf ("%d: %08X\n", i, crc);
checksum += crc;
}
if (n1 == 1 && n2 == default_number_of_iterations)
{
if (checksum == expected_checksum)
{
printf ("%s test passed (checksum=%08X)\n",
test_name, checksum);
}
else
{
printf ("%s test failed! (checksum=%08X, expected %08X)\n",
test_name, checksum, expected_checksum);
return 1;
}
}
else
{
printf ("%d-%d: checksum=%08X\n", n1, n2, checksum);
}
return 0;
}
/* Try to obtain current time in seconds */
double
gettime (void)
{
#ifdef HAVE_GETTIMEOFDAY
struct timeval tv;
gettimeofday (&tv, NULL);
return (double)((int64_t)tv.tv_sec * 1000000 + tv.tv_usec) / 1000000.;
#else
return (double)clock() / (double)CLOCKS_PER_SEC;
#endif
}
uint32_t
get_random_seed (void)
{
double d = gettime();
lcg_srand (*(uint32_t *)&d);
return lcg_rand_u32 ();
}
static const char *global_msg;
static void
on_alarm (int signo)
{
printf ("%s\n", global_msg);
exit (1);
}
void
fail_after (int seconds, const char *msg)
{
#ifdef HAVE_SIGACTION
#ifdef HAVE_ALARM
struct sigaction action;
global_msg = msg;
memset (&action, 0, sizeof (action));
action.sa_handler = on_alarm;
alarm (seconds);
sigaction (SIGALRM, &action, NULL);
#endif
#endif
}
void
enable_fp_exceptions (void)
{
#ifdef HAVE_FENV_H
#ifdef HAVE_FEENABLEEXCEPT
/* Note: we don't enable the FE_INEXACT trap because
* that happens quite commonly. It is possible that
* over- and underflow should similarly be considered
* okay, but for now the test suite passes with them
* enabled, and it's useful to know if they start
* occuring.
*/
feenableexcept (FE_DIVBYZERO |
FE_INVALID |
FE_OVERFLOW |
FE_UNDERFLOW);
#endif
#endif
}
void *
aligned_malloc (size_t align, size_t size)
{
void *result;
#ifdef HAVE_POSIX_MEMALIGN
if (posix_memalign (&result, align, size) != 0)
result = NULL;
#else
result = malloc (size);
#endif
return result;
}
#define CONVERT_15(c, is_rgb) \
(is_rgb? \
((((c) >> 3) & 0x001f) | \
(((c) >> 6) & 0x03e0) | \
(((c) >> 9) & 0x7c00)) : \
(((((c) >> 16) & 0xff) * 153 + \
(((c) >> 8) & 0xff) * 301 + \
(((c) ) & 0xff) * 58) >> 2))
void
initialize_palette (pixman_indexed_t *palette, uint32_t depth, int is_rgb)
{
int i;
uint32_t mask = (1 << depth) - 1;
for (i = 0; i < 32768; ++i)
palette->ent[i] = lcg_rand() & mask;
memset (palette->rgba, 0, sizeof (palette->rgba));
for (i = 0; i < mask + 1; ++i)
{
uint32_t rgba24;
pixman_bool_t retry;
uint32_t i15;
/* We filled the rgb->index map with random numbers, but we
* do need the ability to round trip, that is if some indexed
* color expands to an argb24, then the 15 bit version of that
* color must map back to the index. Anything else, we don't
* care about too much.
*/
do
{
uint32_t old_idx;
rgba24 = lcg_rand();
i15 = CONVERT_15 (rgba24, is_rgb);
old_idx = palette->ent[i15];
if (CONVERT_15 (palette->rgba[old_idx], is_rgb) == i15)
retry = 1;
else
retry = 0;
} while (retry);
palette->rgba[i] = rgba24;
palette->ent[i15] = i;
}
for (i = 0; i < mask + 1; ++i)
{
assert (palette->ent[CONVERT_15 (palette->rgba[i], is_rgb)] == i);
}
}
static double
round_channel (double p, int m)
{
int t;
double r;
t = p * ((1 << m));
t -= t >> m;
r = t / (double)((1 << m) - 1);
return r;
}
void
round_color (pixman_format_code_t format, color_t *color)
{
if (PIXMAN_FORMAT_R (format) == 0)
{
color->r = 0.0;
color->g = 0.0;
color->b = 0.0;
}
else
{
color->r = round_channel (color->r, PIXMAN_FORMAT_R (format));
color->g = round_channel (color->g, PIXMAN_FORMAT_G (format));
color->b = round_channel (color->b, PIXMAN_FORMAT_B (format));
}
if (PIXMAN_FORMAT_A (format) == 0)
color->a = 1;
else
color->a = round_channel (color->a, PIXMAN_FORMAT_A (format));
}
/* Check whether @pixel is a valid quantization of the a, r, g, b
* parameters. Some slack is permitted.
*/
void
pixel_checker_init (pixel_checker_t *checker, pixman_format_code_t format)
{
assert (PIXMAN_FORMAT_VIS (format));
checker->format = format;
switch (PIXMAN_FORMAT_TYPE (format))
{
case PIXMAN_TYPE_A:
checker->bs = 0;
checker->gs = 0;
checker->rs = 0;
checker->as = 0;
break;
case PIXMAN_TYPE_ARGB:
checker->bs = 0;
checker->gs = checker->bs + PIXMAN_FORMAT_B (format);
checker->rs = checker->gs + PIXMAN_FORMAT_G (format);
checker->as = checker->rs + PIXMAN_FORMAT_R (format);
break;
case PIXMAN_TYPE_ABGR:
checker->rs = 0;
checker->gs = checker->rs + PIXMAN_FORMAT_R (format);
checker->bs = checker->gs + PIXMAN_FORMAT_G (format);
checker->as = checker->bs + PIXMAN_FORMAT_B (format);
break;
case PIXMAN_TYPE_BGRA:
/* With BGRA formats we start counting at the high end of the pixel */
checker->bs = PIXMAN_FORMAT_BPP (format) - PIXMAN_FORMAT_B (format);
checker->gs = checker->bs - PIXMAN_FORMAT_B (format);
checker->rs = checker->gs - PIXMAN_FORMAT_G (format);
checker->as = checker->rs - PIXMAN_FORMAT_R (format);
break;
case PIXMAN_TYPE_RGBA:
/* With BGRA formats we start counting at the high end of the pixel */
checker->rs = PIXMAN_FORMAT_BPP (format) - PIXMAN_FORMAT_R (format);
checker->gs = checker->rs - PIXMAN_FORMAT_R (format);
checker->bs = checker->gs - PIXMAN_FORMAT_G (format);
checker->as = checker->bs - PIXMAN_FORMAT_B (format);
break;
default:
assert (0);
break;
}
checker->am = ((1 << PIXMAN_FORMAT_A (format)) - 1) << checker->as;
checker->rm = ((1 << PIXMAN_FORMAT_R (format)) - 1) << checker->rs;
checker->gm = ((1 << PIXMAN_FORMAT_G (format)) - 1) << checker->gs;
checker->bm = ((1 << PIXMAN_FORMAT_B (format)) - 1) << checker->bs;
checker->aw = PIXMAN_FORMAT_A (format);
checker->rw = PIXMAN_FORMAT_R (format);
checker->gw = PIXMAN_FORMAT_G (format);
checker->bw = PIXMAN_FORMAT_B (format);
}
void
pixel_checker_split_pixel (const pixel_checker_t *checker, uint32_t pixel,
int *a, int *r, int *g, int *b)
{
*a = (pixel & checker->am) >> checker->as;
*r = (pixel & checker->rm) >> checker->rs;
*g = (pixel & checker->gm) >> checker->gs;
*b = (pixel & checker->bm) >> checker->bs;
}
static int32_t
convert (double v, uint32_t width, uint32_t mask, uint32_t shift, double def)
{
int32_t r;
if (!mask)
v = def;
r = (v * ((mask >> shift) + 1));
r -= r >> width;
return r;
}
static void
get_limits (const pixel_checker_t *checker, double limit,
color_t *color,
int *ao, int *ro, int *go, int *bo)
{
*ao = convert (color->a + limit, checker->aw, checker->am, checker->as, 1.0);
*ro = convert (color->r + limit, checker->rw, checker->rm, checker->rs, 0.0);
*go = convert (color->g + limit, checker->gw, checker->gm, checker->gs, 0.0);
*bo = convert (color->b + limit, checker->bw, checker->bm, checker->bs, 0.0);
}
/* The acceptable deviation in units of [0.0, 1.0]
*/
#define DEVIATION (0.004)
void
pixel_checker_get_max (const pixel_checker_t *checker, color_t *color,
int *am, int *rm, int *gm, int *bm)
{
get_limits (checker, DEVIATION, color, am, rm, gm, bm);
}
void
pixel_checker_get_min (const pixel_checker_t *checker, color_t *color,
int *am, int *rm, int *gm, int *bm)
{
get_limits (checker, - DEVIATION, color, am, rm, gm, bm);
}
pixman_bool_t
pixel_checker_check (const pixel_checker_t *checker, uint32_t pixel,
color_t *color)
{
int32_t a_lo, a_hi, r_lo, r_hi, g_lo, g_hi, b_lo, b_hi;
int32_t ai, ri, gi, bi;
pixman_bool_t result;
pixel_checker_get_min (checker, color, &a_lo, &r_lo, &g_lo, &b_lo);
pixel_checker_get_max (checker, color, &a_hi, &r_hi, &g_hi, &b_hi);
pixel_checker_split_pixel (checker, pixel, &ai, &ri, &gi, &bi);
result =
a_lo <= ai && ai <= a_hi &&
r_lo <= ri && ri <= r_hi &&
g_lo <= gi && gi <= g_hi &&
b_lo <= bi && bi <= b_hi;
return result;
}
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