ryan/mozjpeg
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
96bc40c1b36775afdbad4ae05a6b3f48e2eebeb9
mozjpeg/tjunittest.c
DRC fc01f4673b TurboJPEG 3 API overhaul 
(ChangeLog update forthcoming)

- Prefix all function names with "tj3" and remove version suffixes from
  function names.  (Future API overhauls will increment the prefix to
  "tj4", etc., thus retaining backward API/ABI compatibility without
  versioning each individual function.)

- Replace stateless boolean flags (including TJ*FLAG_ARITHMETIC and
  TJ*FLAG_LOSSLESS, which were never released) with stateful integer
  parameters, the value of which persists between function calls.
  * Use parameters for the JPEG quality and subsampling as well, in
    order to eliminate the awkwardness of specifying function arguments
    that weren't relevant for lossless compression.
  * tj3DecompressHeader() now stores all relevant information about the
    JPEG image, including the width, height, subsampling type, entropy
    coding type, etc. in parameters rather than returning that
    information in its arguments.
  * TJ*FLAG_LIMITSCANS has been reimplemented as an integer parameter
    (TJ*PARAM_SCANLIMIT) that allows the number of scans to be
    specified.

- Use the const keyword for all pointer arguments to unmodified
  buffers, as well as for both dimensions of 2D pointers.  Addresses
  #395.

- Use size_t rather than unsigned long to represent buffer sizes, since
  unsigned long is a 32-bit type on Windows.  Addresses #24.

- Return 0 from all buffer size functions if an error occurs, rather
  than awkwardly trying to return -1 in an unsigned data type.

- Implement 12-bit and 16-bit data precision using dedicated
  compression, decompression, and image I/O functions/methods.
  * Suffix the names of all data-precision-specific functions with 8,
    12, or 16.
  * Because the YUV functions are intended to be used for video, they
    are currently only implemented with 8-bit data precision, but they
    can be expanded to 12-bit data precision in the future, if
    necessary.
  * Extend TJUnitTest and TJBench to test 12-bit and 16-bit data
    precision, using a new -precision option.
  * Add appropriate regression tests for all of the above to the 'test'
    target.
  * Extend tjbenchtest to test 12-bit and 16-bit data precision, and
    add separate 'tjtest12' and 'tjtest16' targets.
  * BufferedImage I/O in the Java API is currently limited to 8-bit
    data precision, since the BufferedImage class does not
    straightforwardly support higher data precisions.
  * Extend the PPM reader to convert 12-bit and 16-bit PBMPLUS files
    to grayscale or CMYK pixels, as it already does for 8-bit files.

- Properly accommodate lossless JPEG using dedicated parameters
  (TJ*PARAM_LOSSLESS, TJ*PARAM_LOSSLESSPSV, and TJ*PARAM_LOSSLESSPT),
  rather than using a flag and awkwardly repurposing the JPEG quality.
  Update TJBench to properly reflect whether a JPEG image is lossless.

- Re-organize the TJBench usage screen.

- Update the Java docs using Java 11, to improve the formatting and
  eliminate HTML frames.

- Use the accurate integer DCT algorithm by default for both
  compression and decompression, since the "fast" algorithm is a legacy
  feature, it does not pass the ISO compliance tests, and it is not
  actually faster on modern x86 CPUs.
  * Remove the -accuratedct option from TJBench and TJExample.

- Re-implement the 'tjtest' target using a CMake script that enables
  the appropriate tests, depending on the data precision and whether or
  not the Java API is part of the build.

- Consolidate the C and Java versions of tjbenchtest into one script.

- Consolidate the C and Java versions of tjexampletest into one script.

- Combine all initialization functions into a single function
  (tj3Init()) that accepts an integer parameter specifying the
  subsystems to initialize.

- Enable decompression scaling explicitly, using a new function/method
  (tj3SetScalingFactor()/TJDecompressor.setScalingFactor()), rather
  than implicitly using awkward "desired width"/"desired height"
  parameters.

- Introduce a new macro/constant (TJUNSCALED/TJ.UNSCALED) that maps to
  a scaling factor of 1/1.

- Implement partial image decompression, using a new function/method
  (tj3SetCroppingRegion()/TJDecompressor.setCroppingRegion()) and
  TJBench option (-crop).  Extend tjbenchtest to test the new feature.
  Addresses #1.

- Allow the JPEG colorspace to be specified explicitly when
  compressing, using a new parameter (TJ*PARAM_COLORSPACE).  This
  allows JPEG images with the RGB and CMYK colorspaces to be created.

- Remove the error/difference image feature from TJBench.  Identical
  images to the ones that TJBench created can be generated using
  ImageMagick with
  'magick composite <original_image> <output_image> -compose difference <diff_image>'

- Handle JPEG images with unknown subsampling types.  TJ*PARAM_SUBSAMP
  is set to TJ*SAMP_UNKNOWN (== -1) for such images, but they can still
  be decompressed fully into packed-pixel images or losslessly
  transformed (with the exception of lossless cropping.)  They cannot
  be partially decompressed or decompressed into planar YUV images.
  Note also that TJBench, due to its lack of support for imperfect
  transforms, requires that the subsampling type be known when
  rotating, flipping, or transversely transposing an image.  Addresses
  #436

- The Java version of TJBench now has identical functionality to the C
  version.  This was accomplished by (somewhat hackishly) calling the
  TurboJPEG C image I/O functions through JNI and copying the pixels
  between the C heap and the Java heap.

- Add parameters (TJ*PARAM_RESTARTROWS and TJ*PARAM_RESTARTBLOCKS) and
  a TJBench option (-restart) to allow the restart marker interval to
  be specified when compressing.  Eliminate the undocumented TJ_RESTART
  environment variable.

- Add a parameter (TJ*PARAM_OPTIMIZE), a transform option
  (TJ*OPT_OPTIMIZE), and a TJBench option (-optimize) to allow
  optimized baseline Huffman coding to be specified when compressing.
  Eliminate the undocumented TJ_OPTIMIZE environment variable.

- Add parameters (TJ*PARAM_XDENSITY, TJ*PARAM_DENSITY, and
  TJ*DENSITYUNITS) to allow the pixel density to be specified when
  compressing or saving a Windows BMP image and to be queried when
  decompressing or loading a Windows BMP image.  Addresses #77.

- Refactor the fuzz targets to use the new API.
  * Extend decompression coverage to 12-bit and 16-bit data precision.
  * Replace the awkward cjpeg12 and cjpeg16 targets with proper
    TurboJPEG-based compress12, compress12-lossless, and
    compress16-lossless targets

- Fix innocuous UBSan warnings uncovered by the new fuzzers.

- Implement previous versions of the TurboJPEG API by wrapping the new
  functions (tested by running the 2.1.x versions of TJBench, via
  tjbenchtest, and TJUnitTest against the new implementation.)
  * Remove all JNI functions for deprecated Java methods and implement
    the deprecated methods using pure Java wrappers.  It should be
    understood that backward API compatibility in Java applies only to
    the Java classes and that one cannot mix and match a JAR file from
    one version of libjpeg-turbo with a JNI library from another
    version.

- tj3Destroy() now silently accepts a NULL handle.

- tj3Alloc() and tj3Free() now return/accept void pointers, as malloc()
  and free() do.

- The image I/O functions now accept a TurboJPEG instance handle, which
  is used to transmit/receive parameters and to receive error
  information.

Closes #517
2023-01-25 19:09:34 -06:00

1210 lines
40 KiB
C
Raw Blame History

/*
* Copyright (C)2009-2014, 2017-2019, 2022-2023 D. R. Commander.
* All Rights Reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* - Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* - Neither the name of the libjpeg-turbo Project nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS",
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* This program tests the various code paths in the TurboJPEG C Wrapper
*/
#ifdef _MSC_VER
#define _CRT_SECURE_NO_DEPRECATE
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <limits.h>
#include <errno.h>
#include "tjutil.h"
#include "turbojpeg.h"
#include "md5/md5.h"
#include "jconfigint.h"
#ifdef _WIN32
#include <time.h>
#define random() rand()
#else
#include <unistd.h>
#endif
static void usage(char *progName)
{
printf("\nUSAGE: %s [options]\n\n", progName);
printf("Options:\n");
printf("-yuv = test YUV encoding/compression/decompression/decoding\n");
printf(" (8-bit data precision only)\n");
printf("-noyuvpad = do not pad each row in each Y, U, and V plane to the nearest\n");
printf(" multiple of 4 bytes\n");
printf("-precision N = test N-bit data precision (N is 8, 12, or 16; default is 8; if N\n");
printf(" is 16, then -lossless is implied)\n");
printf("-lossless = test lossless JPEG compression/decompression\n");
printf("-alloc = test automatic JPEG buffer allocation\n");
printf("-bmp = test packed-pixel image I/O\n");
exit(1);
}
#define THROW_TJ(handle) { \
printf("TurboJPEG ERROR:\n%s\n", tj3GetErrorStr(handle)); \
BAILOUT() \
}
#define TRY_TJ(handle, f) { if ((f) == -1) THROW_TJ(handle); }
#define THROW(m) { printf("ERROR: %s\n", m); BAILOUT() }
#define THROW_MD5(filename, md5sum, ref) { \
printf("\n%s has an MD5 sum of %s.\n Should be %s.\n", filename, md5sum, \
ref); \
BAILOUT() \
}
const char *subNameLong[TJ_NUMSAMP] = {
"4:4:4", "4:2:2", "4:2:0", "GRAY", "4:4:0", "4:1:1"
};
const char *subName[TJ_NUMSAMP] = {
"444", "422", "420", "GRAY", "440", "411"
};
const char *pixFormatStr[TJ_NUMPF] = {
"RGB", "BGR", "RGBX", "BGRX", "XBGR", "XRGB", "Grayscale",
"RGBA", "BGRA", "ABGR", "ARGB", "CMYK"
};
const int _3sampleFormats[] = { TJPF_RGB, TJPF_BGR };
const int _4sampleFormats[] = {
TJPF_RGBX, TJPF_BGRX, TJPF_XBGR, TJPF_XRGB, TJPF_CMYK
};
const int _onlyGray[] = { TJPF_GRAY };
const int _onlyRGB[] = { TJPF_RGB };
int doYUV = 0, lossless = 0, psv = 1, alloc = 0, yuvAlign = 4;
int precision = 8, sampleSize, maxSample, tolerance, redToY, yellowToY;
int exitStatus = 0;
#define BAILOUT() { exitStatus = -1; goto bailout; }
static void setVal(void *buf, int index, int value)
{
if (precision == 8)
((unsigned char *)buf)[index] = (unsigned char)value;
else if (precision == 12)
((short *)buf)[index] = (short)value;
else
((unsigned short *)buf)[index] = (unsigned short)value;
}
static void initBuf(void *buf, int w, int h, int pf, int bottomUp)
{
int roffset = tjRedOffset[pf];
int goffset = tjGreenOffset[pf];
int boffset = tjBlueOffset[pf];
int ps = tjPixelSize[pf];
int i, index, row, col, halfway = 16;
if (pf == TJPF_GRAY) {
memset(buf, 0, w * h * ps * sampleSize);
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
if (bottomUp) index = (h - row - 1) * w + col;
else index = row * w + col;
if (((row / 8) + (col / 8)) % 2 == 0)
setVal(buf, index, (row < halfway) ? maxSample : 0);
else setVal(buf, index, (row < halfway) ? redToY : yellowToY);
}
}
} else if (pf == TJPF_CMYK) {
for (i = 0; i < w * h * ps; i++)
setVal(buf, i, maxSample);
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
if (bottomUp) index = (h - row - 1) * w + col;
else index = row * w + col;
if (((row / 8) + (col / 8)) % 2 == 0) {
if (row >= halfway) setVal(buf, index * ps + 3, 0);
} else {
setVal(buf, index * ps + 2, 0);
if (row < halfway) setVal(buf, index * ps + 1, 0);
}
}
}
} else {
memset(buf, 0, w * h * ps * sampleSize);
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
if (bottomUp) index = (h - row - 1) * w + col;
else index = row * w + col;
if (((row / 8) + (col / 8)) % 2 == 0) {
if (row < halfway) {
setVal(buf, index * ps + roffset, maxSample);
setVal(buf, index * ps + goffset, maxSample);
setVal(buf, index * ps + boffset, maxSample);
}
} else {
setVal(buf, index * ps + roffset, maxSample);
if (row >= halfway) setVal(buf, index * ps + goffset, maxSample);
}
}
}
}
}
#define CHECKVAL(v, cv) { \
if (v < cv - tolerance || v > cv + tolerance) { \
printf("\nComp. %s at %d,%d should be %d, not %d\n", #v, row, col, cv, \
v); \
retval = 0; exitStatus = -1; goto bailout; \
} \
}
#define CHECKVAL0(v) { \
if (v > tolerance) { \
printf("\nComp. %s at %d,%d should be 0, not %d\n", #v, row, col, v); \
retval = 0; exitStatus = -1; goto bailout; \
} \
}
#define CHECKVALMAX(v) { \
if (v < maxSample - tolerance) { \
printf("\nComp. %s at %d,%d should be %d, not %d\n", #v, row, col, \
maxSample, v); \
retval = 0; exitStatus = -1; goto bailout; \
} \
}
static int getVal(void *buf, int index)
{
if (precision == 8)
return ((unsigned char *)buf)[index];
else if (precision == 12)
return ((short *)buf)[index];
else
return ((unsigned short *)buf)[index];
}
static int checkBuf(void *buf, int w, int h, int pf, int subsamp,
tjscalingfactor sf, int bottomUp)
{
int roffset = tjRedOffset[pf];
int goffset = tjGreenOffset[pf];
int boffset = tjBlueOffset[pf];
int aoffset = tjAlphaOffset[pf];
int ps = tjPixelSize[pf];
int index, row, col, retval = 1;
int halfway = 16 * sf.num / sf.denom;
int blocksize = 8 * sf.num / sf.denom;
if (pf == TJPF_GRAY) roffset = goffset = boffset = 0;
if (pf == TJPF_CMYK) {
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
int c, m, y, k;
if (bottomUp) index = (h - row - 1) * w + col;
else index = row * w + col;
c = getVal(buf, index * ps);
m = getVal(buf, index * ps + 1);
y = getVal(buf, index * ps + 2);
k = getVal(buf, index * ps + 3);
if (((row / blocksize) + (col / blocksize)) % 2 == 0) {
CHECKVALMAX(c); CHECKVALMAX(m); CHECKVALMAX(y);
if (row < halfway) CHECKVALMAX(k)
else CHECKVAL0(k)
} else {
CHECKVALMAX(c); CHECKVAL0(y); CHECKVALMAX(k);
if (row < halfway) CHECKVAL0(m)
else CHECKVALMAX(m)
}
}
}
return 1;
}
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
int r, g, b, a;
if (bottomUp) index = (h - row - 1) * w + col;
else index = row * w + col;
r = getVal(buf, index * ps + roffset);
g = getVal(buf, index * ps + goffset);
b = getVal(buf, index * ps + boffset);
a = aoffset >= 0 ? getVal(buf, index * ps + aoffset) : maxSample;
if (((row / blocksize) + (col / blocksize)) % 2 == 0) {
if (row < halfway) {
CHECKVALMAX(r); CHECKVALMAX(g); CHECKVALMAX(b);
} else {
CHECKVAL0(r); CHECKVAL0(g); CHECKVAL0(b);
}
} else {
if (subsamp == TJSAMP_GRAY) {
if (row < halfway) {
CHECKVAL(r, redToY); CHECKVAL(g, redToY); CHECKVAL(b, redToY);
} else {
CHECKVAL(r, yellowToY); CHECKVAL(g, yellowToY);
CHECKVAL(b, yellowToY);
}
} else {
if (row < halfway) {
CHECKVALMAX(r); CHECKVAL0(g); CHECKVAL0(b);
} else {
CHECKVALMAX(r); CHECKVALMAX(g); CHECKVAL0(b);
}
}
}
CHECKVALMAX(a);
}
}
bailout:
if (retval == 0) {
for (row = 0; row < h; row++) {
for (col = 0; col < w; col++) {
if (pf == TJPF_CMYK)
printf("%.3d/%.3d/%.3d/%.3d ", getVal(buf, (row * w + col) * ps),
getVal(buf, (row * w + col) * ps + 1),
getVal(buf, (row * w + col) * ps + 2),
getVal(buf, (row * w + col) * ps + 3));
else
printf("%.3d/%.3d/%.3d ",
getVal(buf, (row * w + col) * ps + roffset),
getVal(buf, (row * w + col) * ps + goffset),
getVal(buf, (row * w + col) * ps + boffset));
}
printf("\n");
}
}
return retval;
}
#define PAD(v, p) ((v + (p) - 1) & (~((p) - 1)))
static int checkBufYUV(unsigned char *buf, int w, int h, int subsamp,
tjscalingfactor sf)
{
int row, col;
int hsf = tjMCUWidth[subsamp] / 8, vsf = tjMCUHeight[subsamp] / 8;
int pw = PAD(w, hsf), ph = PAD(h, vsf);
int cw = pw / hsf, ch = ph / vsf;
int ypitch = PAD(pw, yuvAlign), uvpitch = PAD(cw, yuvAlign);
int retval = 1;
int halfway = 16 * sf.num / sf.denom;
int blocksize = 8 * sf.num / sf.denom;
for (row = 0; row < ph; row++) {
for (col = 0; col < pw; col++) {
unsigned char y = buf[ypitch * row + col];
if (((row / blocksize) + (col / blocksize)) % 2 == 0) {
if (row < halfway) CHECKVALMAX(y)
else CHECKVAL0(y);
} else {
if (row < halfway) CHECKVAL(y, 76)
else CHECKVAL(y, 225);
}
}
}
if (subsamp != TJSAMP_GRAY) {
halfway = 16 / vsf * sf.num / sf.denom;
for (row = 0; row < ch; row++) {
for (col = 0; col < cw; col++) {
unsigned char u = buf[ypitch * ph + (uvpitch * row + col)],
v = buf[ypitch * ph + uvpitch * ch + (uvpitch * row + col)];
if (((row * vsf / blocksize) + (col * hsf / blocksize)) % 2 == 0) {
CHECKVAL(u, 128); CHECKVAL(v, 128);
} else {
if (row < halfway) {
CHECKVAL(u, 85); CHECKVALMAX(v);
} else {
CHECKVAL0(u); CHECKVAL(v, 149);
}
}
}
}
}
bailout:
if (retval == 0) {
for (row = 0; row < ph; row++) {
for (col = 0; col < pw; col++)
printf("%.3d ", buf[ypitch * row + col]);
printf("\n");
}
printf("\n");
for (row = 0; row < ch; row++) {
for (col = 0; col < cw; col++)
printf("%.3d ", buf[ypitch * ph + (uvpitch * row + col)]);
printf("\n");
}
printf("\n");
for (row = 0; row < ch; row++) {
for (col = 0; col < cw; col++)
printf("%.3d ",
buf[ypitch * ph + uvpitch * ch + (uvpitch * row + col)]);
printf("\n");
}
}
return retval;
}
static void writeJPEG(unsigned char *jpegBuf, size_t jpegSize, char *filename)
{
FILE *file = fopen(filename, "wb");
if (!file || fwrite(jpegBuf, jpegSize, 1, file) != 1) {
printf("ERROR: Could not write to %s.\n%s\n", filename, strerror(errno));
BAILOUT()
}
bailout:
if (file) fclose(file);
}
static void compTest(tjhandle handle, unsigned char **dstBuf, size_t *dstSize,
int w, int h, int pf, char *basename)
{
char tempStr[1024];
void *srcBuf = NULL;
unsigned char *yuvBuf = NULL;
const char *pfStr = pixFormatStr[pf];
int bottomUp = tj3Get(handle, TJPARAM_BOTTOMUP);
int subsamp = tj3Get(handle, TJPARAM_SUBSAMP);
int jpegPSV = tj3Get(handle, TJPARAM_LOSSLESSPSV);
int jpegQual = tj3Get(handle, TJPARAM_QUALITY);
const char *buStrLong = bottomUp ? "Bottom-Up" : "Top-Down ";
const char *buStr = bottomUp ? "BU" : "TD";
if ((srcBuf = malloc(w * h * tjPixelSize[pf] * sampleSize)) == NULL)
THROW("Memory allocation failure");
initBuf(srcBuf, w, h, pf, bottomUp);
if (*dstBuf && *dstSize > 0) memset(*dstBuf, 0, *dstSize);
if (doYUV) {
size_t yuvSize = tj3YUVBufSize(w, yuvAlign, h, subsamp);
tjscalingfactor sf = { 1, 1 };
tjhandle handle2 = NULL;
if ((handle2 = tj3Init(TJINIT_COMPRESS)) == NULL)
THROW_TJ(NULL);
TRY_TJ(handle2, tj3Set(handle2, TJPARAM_BOTTOMUP, bottomUp));
TRY_TJ(handle2, tj3Set(handle2, TJPARAM_SUBSAMP, subsamp));
if ((yuvBuf = (unsigned char *)malloc(yuvSize)) == NULL)
THROW("Memory allocation failure");
memset(yuvBuf, 0, yuvSize);
printf("%s %s -> YUV %s ... ", pfStr, buStrLong, subNameLong[subsamp]);
TRY_TJ(handle2, tj3EncodeYUV8(handle2, (unsigned char *)srcBuf, w, 0, h,
pf, yuvBuf, yuvAlign));
tj3Destroy(handle2);
if (checkBufYUV(yuvBuf, w, h, subsamp, sf)) printf("Passed.\n");
else printf("FAILED!\n");
printf("YUV %s %s -> JPEG Q%d ... ", subNameLong[subsamp], buStrLong,
jpegQual);
TRY_TJ(handle, tj3CompressFromYUV8(handle, yuvBuf, w, yuvAlign, h, dstBuf,
dstSize));
} else {
if (lossless)
printf("%s %s -> LOSSLESS PSV%d ... ", pfStr, buStrLong, jpegPSV);
else
printf("%s %s -> %s Q%d ... ", pfStr, buStrLong, subNameLong[subsamp],
jpegQual);
if (precision == 8) {
TRY_TJ(handle, tj3Compress8(handle, (unsigned char *)srcBuf, w, 0, h, pf,
dstBuf, dstSize));
} else if (precision == 12) {
TRY_TJ(handle, tj3Compress12(handle, (short *)srcBuf, w, 0, h, pf,
dstBuf, dstSize));
} else {
TRY_TJ(handle, tj3Compress16(handle, (unsigned short *)srcBuf, w, 0, h,
pf, dstBuf, dstSize));
}
}
if (lossless)
SNPRINTF(tempStr, 1024, "%s_enc%d_%s_%s_LOSSLESS_PSV%d.jpg", basename,
precision, pfStr, buStr, jpegPSV);
else
SNPRINTF(tempStr, 1024, "%s_enc%d_%s_%s_%s_Q%d.jpg", basename, precision,
pfStr, buStr, subName[subsamp], jpegQual);
writeJPEG(*dstBuf, *dstSize, tempStr);
printf("Done.\n Result in %s\n", tempStr);
bailout:
free(yuvBuf);
free(srcBuf);
}
static void _decompTest(tjhandle handle, unsigned char *jpegBuf,
size_t jpegSize, int w, int h, int pf, char *basename,
int subsamp, tjscalingfactor sf)
{
void *dstBuf = NULL;
unsigned char *yuvBuf = NULL;
int _hdrw = 0, _hdrh = 0, _hdrsubsamp;
int scaledWidth = TJSCALED(w, sf);
int scaledHeight = TJSCALED(h, sf);
size_t dstSize = 0;
int bottomUp = tj3Get(handle, TJPARAM_BOTTOMUP);
TRY_TJ(handle, tj3SetScalingFactor(handle, sf));
TRY_TJ(handle, tj3DecompressHeader(handle, jpegBuf, jpegSize));
_hdrw = tj3Get(handle, TJPARAM_JPEGWIDTH);
_hdrh = tj3Get(handle, TJPARAM_JPEGHEIGHT);
_hdrsubsamp = tj3Get(handle, TJPARAM_SUBSAMP);
if (lossless && subsamp != TJSAMP_444 && subsamp != TJSAMP_GRAY)
subsamp = TJSAMP_444;
if (_hdrw != w || _hdrh != h || _hdrsubsamp != subsamp)
THROW("Incorrect JPEG header");
dstSize = scaledWidth * scaledHeight * tjPixelSize[pf];
if ((dstBuf = malloc(dstSize * sampleSize)) == NULL)
THROW("Memory allocation failure");
memset(dstBuf, 0, dstSize * sampleSize);
if (doYUV) {
size_t yuvSize = tj3YUVBufSize(scaledWidth, yuvAlign, scaledHeight,
subsamp);
tjhandle handle2 = NULL;
if ((handle2 = tj3Init(TJINIT_DECOMPRESS)) == NULL)
THROW_TJ(NULL);
TRY_TJ(handle2, tj3Set(handle2, TJPARAM_BOTTOMUP, bottomUp));
TRY_TJ(handle2, tj3Set(handle2, TJPARAM_SUBSAMP, subsamp));
if ((yuvBuf = (unsigned char *)malloc(yuvSize)) == NULL)
THROW("Memory allocation failure");
memset(yuvBuf, 0, yuvSize);
printf("JPEG -> YUV %s ", subNameLong[subsamp]);
if (sf.num != 1 || sf.denom != 1)
printf("%d/%d ... ", sf.num, sf.denom);
else printf("... ");
TRY_TJ(handle, tj3DecompressToYUV8(handle, jpegBuf, jpegSize, yuvBuf,
yuvAlign));
if (checkBufYUV(yuvBuf, scaledWidth, scaledHeight, subsamp, sf))
printf("Passed.\n");
else printf("FAILED!\n");
printf("YUV %s -> %s %s ... ", subNameLong[subsamp], pixFormatStr[pf],
bottomUp ? "Bottom-Up" : "Top-Down ");
TRY_TJ(handle2, tj3DecodeYUV8(handle2, yuvBuf, yuvAlign,
(unsigned char *)dstBuf, scaledWidth, 0,
scaledHeight, pf));
tj3Destroy(handle2);
} else {
printf("JPEG -> %s %s ", pixFormatStr[pf],
bottomUp ? "Bottom-Up" : "Top-Down ");
if (sf.num != 1 || sf.denom != 1)
printf("%d/%d ... ", sf.num, sf.denom);
else printf("... ");
if (precision == 8) {
TRY_TJ(handle, tj3Decompress8(handle, jpegBuf, jpegSize,
(unsigned char *)dstBuf, 0, pf));
} else if (precision == 12) {
TRY_TJ(handle, tj3Decompress12(handle, jpegBuf, jpegSize,
(short *)dstBuf, 0, pf));
} else {
TRY_TJ(handle, tj3Decompress16(handle, jpegBuf, jpegSize,
(unsigned short *)dstBuf, 0, pf));
}
}
if (checkBuf(dstBuf, scaledWidth, scaledHeight, pf, subsamp, sf, bottomUp))
printf("Passed.");
else printf("FAILED!");
printf("\n");
bailout:
free(yuvBuf);
free(dstBuf);
}
static void decompTest(tjhandle handle, unsigned char *jpegBuf,
size_t jpegSize, int w, int h, int pf, char *basename,
int subsamp)
{
int i, n = 0;
tjscalingfactor *sf = NULL;
if (lossless) {
_decompTest(handle, jpegBuf, jpegSize, w, h, pf, basename, subsamp,
TJUNSCALED);
return;
}
sf = tj3GetScalingFactors(&n);
if (!sf || !n) THROW_TJ(NULL);
for (i = 0; i < n; i++) {
if (subsamp == TJSAMP_444 || subsamp == TJSAMP_GRAY ||
(subsamp == TJSAMP_411 && sf[i].num == 1 &&
(sf[i].denom == 2 || sf[i].denom == 1)) ||
(subsamp != TJSAMP_411 && sf[i].num == 1 &&
(sf[i].denom == 4 || sf[i].denom == 2 || sf[i].denom == 1)))
_decompTest(handle, jpegBuf, jpegSize, w, h, pf, basename, subsamp,
sf[i]);
}
bailout:
return;
}
static void doTest(int w, int h, const int *formats, int nformats, int subsamp,
char *basename)
{
tjhandle chandle = NULL, dhandle = NULL;
unsigned char *dstBuf = NULL;
size_t size = 0;
int pfi, pf, i;
if (lossless && subsamp != TJSAMP_GRAY)
subsamp = TJSAMP_444;
if (!alloc)
size = tj3JPEGBufSize(w, h, subsamp);
if (size != 0)
if ((dstBuf = (unsigned char *)tj3Alloc(size)) == NULL)
THROW("Memory allocation failure.");
if ((chandle = tj3Init(TJINIT_COMPRESS)) == NULL ||
(dhandle = tj3Init(TJINIT_DECOMPRESS)) == NULL)
THROW_TJ(NULL);
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_NOREALLOC, !alloc));
if (lossless) {
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_LOSSLESS, lossless));
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_LOSSLESSPSV,
((psv++ - 1) % 7) + 1));
} else {
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_QUALITY, 100));
if (subsamp == TJSAMP_422 || subsamp == TJSAMP_420 ||
subsamp == TJSAMP_440 || subsamp == TJSAMP_411)
TRY_TJ(dhandle, tj3Set(dhandle, TJPARAM_FASTUPSAMPLE, 1));
}
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_SUBSAMP, subsamp));
for (pfi = 0; pfi < nformats; pfi++) {
for (i = 0; i < 2; i++) {
TRY_TJ(chandle, tj3Set(chandle, TJPARAM_BOTTOMUP, i == 1));
TRY_TJ(dhandle, tj3Set(dhandle, TJPARAM_BOTTOMUP, i == 1));
pf = formats[pfi];
compTest(chandle, &dstBuf, &size, w, h, pf, basename);
decompTest(dhandle, dstBuf, size, w, h, pf, basename, subsamp);
if (pf >= TJPF_RGBX && pf <= TJPF_XRGB) {
printf("\n");
decompTest(dhandle, dstBuf, size, w, h, pf + (TJPF_RGBA - TJPF_RGBX),
basename, subsamp);
}
printf("\n");
}
}
printf("--------------------\n\n");
bailout:
tj3Destroy(chandle);
tj3Destroy(dhandle);
tj3Free(dstBuf);
}
#if SIZEOF_SIZE_T == 8
#define CHECKSIZE(function) { \
if (size && size < (size_t)0xFFFFFFFF) \
THROW(#function " overflow"); \
}
#define CHECKSIZEUL(function) { \
if ((unsigned long long)ulsize < (unsigned long long)0xFFFFFFFF) \
THROW(#function " overflow"); \
}
#else
#define CHECKSIZE(function) { \
if (size != 0 || !strcmp(tj3GetErrorStr(NULL), "No error")) \
THROW(#function " overflow"); \
}
#define CHECKSIZEUL(function) { \
if (ulsize != (unsigned long)(-1) || \
!strcmp(tj3GetErrorStr(NULL), "No error")) \
THROW(#function " overflow"); \
}
#endif
#define CHECKSIZEINT(function) { \
if (intsize != 0 || !strcmp(tj3GetErrorStr(NULL), "No error")) \
THROW(#function " overflow"); \
}
static void overflowTest(void)
{
/* Ensure that the various buffer size functions don't overflow */
size_t size;
unsigned long ulsize;
int intsize;
size = tj3JPEGBufSize(26755, 26755, TJSAMP_444);
CHECKSIZE(tj3JPEGBufSize());
ulsize = tjBufSize(26755, 26755, TJSAMP_444);
CHECKSIZEUL(tjBufSize());
ulsize = TJBUFSIZE(26755, 26755);
CHECKSIZEUL(TJBUFSIZE());
size = tj3YUVBufSize(37838, 1, 37838, TJSAMP_444);
CHECKSIZE(tj3YUVBufSize());
size = tj3YUVBufSize(37837, 3, 37837, TJSAMP_444);
CHECKSIZE(tj3YUVBufSize());
size = tj3YUVBufSize(37837, -1, 37837, TJSAMP_444);
CHECKSIZE(tj3YUVBufSize());
ulsize = tjBufSizeYUV2(37838, 1, 37838, TJSAMP_444);
CHECKSIZEUL(tjBufSizeYUV2());
ulsize = tjBufSizeYUV2(37837, 3, 37837, TJSAMP_444);
CHECKSIZEUL(tjBufSizeYUV2());
ulsize = tjBufSizeYUV2(37837, -1, 37837, TJSAMP_444);
CHECKSIZEUL(tjBufSizeYUV2());
ulsize = TJBUFSIZEYUV(37838, 37838, TJSAMP_444);
CHECKSIZEUL(TJBUFSIZEYUV());
ulsize = tjBufSizeYUV(37838, 37838, TJSAMP_444);
CHECKSIZEUL(tjBufSizeYUV());
size = tj3YUVPlaneSize(0, 65536, 0, 65536, TJSAMP_444);
CHECKSIZE(tj3YUVPlaneSize());
ulsize = tjPlaneSizeYUV(0, 65536, 0, 65536, TJSAMP_444);
CHECKSIZEUL(tjPlaneSizeYUV());
intsize = tj3YUVPlaneWidth(0, INT_MAX, TJSAMP_420);
CHECKSIZEINT(tj3YUVPlaneWidth());
intsize = tj3YUVPlaneHeight(0, INT_MAX, TJSAMP_420);
CHECKSIZEINT(tj3YUVPlaneHeight());
bailout:
return;
}
static void bufSizeTest(void)
{
int w, h, i, subsamp;
void *srcBuf = NULL;
unsigned char *dstBuf = NULL;
tjhandle handle = NULL;
size_t dstSize = 0;
int numSamp = TJ_NUMSAMP;
if ((handle = tj3Init(TJINIT_COMPRESS)) == NULL)
THROW_TJ(NULL);
TRY_TJ(handle, tj3Set(handle, TJPARAM_NOREALLOC, !alloc));
if (lossless) {
TRY_TJ(handle, tj3Set(handle, TJPARAM_LOSSLESS, lossless));
TRY_TJ(handle, tj3Set(handle, TJPARAM_LOSSLESSPSV,
((psv++ - 1) % 7) + 1));
numSamp = 1;
} else
TRY_TJ(handle, tj3Set(handle, TJPARAM_QUALITY, 100));
printf("Buffer size regression test\n");
for (subsamp = 0; subsamp < numSamp; subsamp++) {
TRY_TJ(handle, tj3Set(handle, TJPARAM_SUBSAMP, subsamp));
for (w = 1; w < 48; w++) {
int maxh = (w == 1) ? 2048 : 48;
for (h = 1; h < maxh; h++) {
if (h % 100 == 0) printf("%.4d x %.4d\b\b\b\b\b\b\b\b\b\b\b", w, h);
if ((srcBuf = malloc(w * h * 4 * sampleSize)) == NULL)
THROW("Memory allocation failure");
if (!alloc || doYUV) {
if (doYUV) dstSize = tj3YUVBufSize(w, yuvAlign, h, subsamp);
else dstSize = tj3JPEGBufSize(w, h, subsamp);
if ((dstBuf = (unsigned char *)tj3Alloc(dstSize)) == NULL)
THROW("Memory allocation failure");
}
for (i = 0; i < w * h * 4; i++) {
if (random() < RAND_MAX / 2) setVal(srcBuf, i, 0);
else setVal(srcBuf, i, maxSample);
}
if (doYUV) {
TRY_TJ(handle, tj3EncodeYUV8(handle, (unsigned char *)srcBuf, w, 0,
h, TJPF_BGRX, dstBuf, yuvAlign));
} else {
if (precision == 8) {
TRY_TJ(handle, tj3Compress8(handle, (unsigned char *)srcBuf, w, 0,
h, TJPF_BGRX, &dstBuf, &dstSize));
} else if (precision == 12) {
TRY_TJ(handle, tj3Compress12(handle, (short *)srcBuf, w, 0, h,
TJPF_BGRX, &dstBuf, &dstSize));
} else {
TRY_TJ(handle, tj3Compress16(handle, (unsigned short *)srcBuf, w,
0, h, TJPF_BGRX, &dstBuf, &dstSize));
}
}
free(srcBuf); srcBuf = NULL;
if (!alloc || doYUV) {
tj3Free(dstBuf); dstBuf = NULL;
}
if ((srcBuf = malloc(h * w * 4 * sampleSize)) == NULL)
THROW("Memory allocation failure");
if (!alloc || doYUV) {
if (doYUV) dstSize = tj3YUVBufSize(h, yuvAlign, w, subsamp);
else dstSize = tj3JPEGBufSize(h, w, subsamp);
if ((dstBuf = (unsigned char *)tj3Alloc(dstSize)) == NULL)
THROW("Memory allocation failure");
}
for (i = 0; i < h * w * 4; i++) {
if (random() < RAND_MAX / 2) setVal(srcBuf, i, 0);
else setVal(srcBuf, i, maxSample);
}
if (doYUV) {
TRY_TJ(handle, tj3EncodeYUV8(handle, (unsigned char *)srcBuf, h, 0,
w, TJPF_BGRX, dstBuf, yuvAlign));
} else {
if (precision == 8) {
TRY_TJ(handle, tj3Compress8(handle, (unsigned char *)srcBuf, h, 0,
w, TJPF_BGRX, &dstBuf, &dstSize));
} else if (precision == 12) {
TRY_TJ(handle, tj3Compress12(handle, (short *)srcBuf, h, 0, w,
TJPF_BGRX, &dstBuf, &dstSize));
} else {
TRY_TJ(handle, tj3Compress16(handle, (unsigned short *)srcBuf, h,
0, w, TJPF_BGRX, &dstBuf, &dstSize));
}
}
free(srcBuf); srcBuf = NULL;
if (!alloc || doYUV) {
tj3Free(dstBuf); dstBuf = NULL;
}
}
}
}
printf("Done. \n");
bailout:
free(srcBuf);
tj3Free(dstBuf);
tj3Destroy(handle);
}
static void rgb_to_cmyk(int r, int g, int b, int *c, int *m, int *y, int *k)
{
double ctmp = 1.0 - ((double)r / (double)maxSample);
double mtmp = 1.0 - ((double)g / (double)maxSample);
double ytmp = 1.0 - ((double)b / (double)maxSample);
double ktmp = min(min(ctmp, mtmp), ytmp);
if (ktmp == 1.0) ctmp = mtmp = ytmp = 0.0;
else {
ctmp = (ctmp - ktmp) / (1.0 - ktmp);
mtmp = (mtmp - ktmp) / (1.0 - ktmp);
ytmp = (ytmp - ktmp) / (1.0 - ktmp);
}
*c = (int)((double)maxSample - ctmp * (double)maxSample + 0.5);
*m = (int)((double)maxSample - mtmp * (double)maxSample + 0.5);
*y = (int)((double)maxSample - ytmp * (double)maxSample + 0.5);
*k = (int)((double)maxSample - ktmp * (double)maxSample + 0.5);
}
static void initBitmap(void *buf, int width, int pitch, int height, int pf,
int bottomUp)
{
int roffset = tjRedOffset[pf];
int goffset = tjGreenOffset[pf];
int boffset = tjBlueOffset[pf];
int ps = tjPixelSize[pf];
int i, j, ci;
for (j = 0; j < height; j++) {
int row = bottomUp ? height - j - 1 : j;
for (i = 0; i < width; i++) {
int r = (i * (maxSample + 1) / width) % (maxSample + 1);
int g = (j * (maxSample + 1) / height) % (maxSample + 1);
int b = (j * (maxSample + 1) / height +
i * (maxSample + 1) / width) % (maxSample + 1);
for (ci = 0; ci < ps; ci++)
setVal(buf, row * pitch + i * ps + ci, 0);
if (pf == TJPF_GRAY) setVal(buf, row * pitch + i * ps, b);
else if (pf == TJPF_CMYK) {
int c, m, y, k;
rgb_to_cmyk(r, g, b, &c, &m, &y, &k);
setVal(buf, row * pitch + i * ps + 0, c);
setVal(buf, row * pitch + i * ps + 1, m);
setVal(buf, row * pitch + i * ps + 2, y);
setVal(buf, row * pitch + i * ps + 3, k);
} else {
setVal(buf, row * pitch + i * ps + roffset, r);
setVal(buf, row * pitch + i * ps + goffset, g);
setVal(buf, row * pitch + i * ps + boffset, b);
}
}
}
}
static void cmyk_to_rgb(int c, int m, int y, int k, int *r, int *g, int *b)
{
*r = (int)((double)c * (double)k / (double)maxSample + 0.5);
*g = (int)((double)m * (double)k / (double)maxSample + 0.5);
*b = (int)((double)y * (double)k / (double)maxSample + 0.5);
}
static int cmpBitmap(void *buf, int width, int pitch, int height, int pf,
int bottomUp, int gray2rgb)
{
int roffset = tjRedOffset[pf];
int goffset = tjGreenOffset[pf];
int boffset = tjBlueOffset[pf];
int aoffset = tjAlphaOffset[pf];
int ps = tjPixelSize[pf];
int i, j;
for (j = 0; j < height; j++) {
int row = bottomUp ? height - j - 1 : j;
for (i = 0; i < width; i++) {
int r = (i * (maxSample + 1) / width) % (maxSample + 1);
int g = (j * (maxSample + 1) / height) % (maxSample + 1);
int b = (j * (maxSample + 1) / height +
i * (maxSample + 1) / width) % (maxSample + 1);
if (pf == TJPF_GRAY) {
if (getVal(buf, row * pitch + i * ps) != b)
return 0;
} else if (pf == TJPF_CMYK) {
int rf, gf, bf;
cmyk_to_rgb(getVal(buf, row * pitch + i * ps + 0),
getVal(buf, row * pitch + i * ps + 1),
getVal(buf, row * pitch + i * ps + 2),
getVal(buf, row * pitch + i * ps + 3), &rf, &gf, &bf);
if (gray2rgb) {
if (rf != b || gf != b || bf != b)
return 0;
} else if (rf != r || gf != g || bf != b) return 0;
} else {
if (gray2rgb) {
if (getVal(buf, row * pitch + i * ps + roffset) != b ||
getVal(buf, row * pitch + i * ps + goffset) != b ||
getVal(buf, row * pitch + i * ps + boffset) != b)
return 0;
} else if (getVal(buf, row * pitch + i * ps + roffset) != r ||
getVal(buf, row * pitch + i * ps + goffset) != g ||
getVal(buf, row * pitch + i * ps + boffset) != b)
return 0;
if (aoffset >= 0 &&
getVal(buf, row * pitch + i * ps + aoffset) != maxSample)
return 0;
}
}
}
return 1;
}
static int doBmpTest(const char *ext, int width, int align, int height, int pf,
int bottomUp)
{
tjhandle handle = NULL;
char filename[80], *md5sum, md5buf[65];
int ps = tjPixelSize[pf], pitch = PAD(width * ps, align), loadWidth = 0,
loadHeight = 0, retval = 0, pixelFormat = pf;
void *buf = NULL;
char *md5ref;
if ((handle = tj3Init(TJINIT_TRANSFORM)) == NULL)
THROW_TJ(NULL);
TRY_TJ(handle, tj3Set(handle, TJPARAM_BOTTOMUP, bottomUp));
if (pf == TJPF_GRAY) {
if (precision == 8)
md5ref = !strcasecmp(ext, "ppm") ? "112c682e82ce5de1cca089e20d60000b" :
"51976530acf75f02beddf5d21149101d";
else if (precision == 12)
md5ref = "0d1895c7e6f2b2c9af6e821a655c239c";
else
md5ref = "64f3320b226ea37fb58080713b4df1b2";
} else {
if (precision == 8)
md5ref = !strcasecmp(ext, "ppm") ? "c0c9f772b464d1896326883a5c79c545" :
"6d659071b9bfcdee2def22cb58ddadca";
else if (precision == 12)
md5ref = "2ff5299287017502832c99718450c90a";
else
md5ref = "623f54661b928d170bd2324bc3620565";
}
if ((buf = tj3Alloc(pitch * height * sampleSize)) == NULL)
THROW("Could not allocate memory");
initBitmap(buf, width, pitch, height, pf, bottomUp);
SNPRINTF(filename, 80, "test_bmp%d_%s_%d_%s.%s", precision, pixFormatStr[pf],
align, bottomUp ? "bu" : "td", ext);
if (precision == 8) {
TRY_TJ(handle, tj3SaveImage8(handle, filename, (unsigned char *)buf, width,
pitch, height, pf));
} else if (precision == 12) {
TRY_TJ(handle, tj3SaveImage12(handle, filename, (short *)buf, width, pitch,
height, pf));
} else {
TRY_TJ(handle, tj3SaveImage16(handle, filename, (unsigned short *)buf,
width, pitch, height, pf));
}
md5sum = MD5File(filename, md5buf);
if (strcasecmp(md5sum, md5ref))
THROW_MD5(filename, md5sum, md5ref);
tj3Free(buf); buf = NULL;
if (precision == 8) {
if ((buf = tj3LoadImage8(handle, filename, &loadWidth, align, &loadHeight,
&pf)) == NULL)
THROW_TJ(handle);
} else if (precision == 12) {
if ((buf = tj3LoadImage12(handle, filename, &loadWidth, align, &loadHeight,
&pf)) == NULL)
THROW_TJ(handle);
} else {
if ((buf = tj3LoadImage16(handle, filename, &loadWidth, align, &loadHeight,
&pf)) == NULL)
THROW_TJ(handle);
}
if (width != loadWidth || height != loadHeight) {
printf("\n Image dimensions of %s are bogus\n", filename);
retval = -1; goto bailout;
}
if (!cmpBitmap(buf, width, pitch, height, pf, bottomUp, 0)) {
printf("\n Pixel data in %s is bogus\n", filename);
retval = -1; goto bailout;
}
if (pf == TJPF_GRAY) {
tj3Free(buf); buf = NULL;
pf = TJPF_XBGR;
if (precision == 8) {
if ((buf = tj3LoadImage8(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
} else if (precision == 12) {
if ((buf = tj3LoadImage12(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
} else {
if ((buf = tj3LoadImage16(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
}
pitch = PAD(width * tjPixelSize[pf], align);
if (!cmpBitmap(buf, width, pitch, height, pf, bottomUp, 1)) {
printf("\n Converting %s to RGB failed\n", filename);
retval = -1; goto bailout;
}
tj3Free(buf); buf = NULL;
pf = TJPF_CMYK;
if (precision == 8) {
if ((buf = tj3LoadImage8(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
} else if (precision == 12) {
if ((buf = tj3LoadImage12(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
} else {
if ((buf = tj3LoadImage16(handle, filename, &loadWidth, align,
&loadHeight, &pf)) == NULL)
THROW_TJ(handle);
}
pitch = PAD(width * tjPixelSize[pf], align);
if (!cmpBitmap(buf, width, pitch, height, pf, bottomUp, 1)) {
printf("\n Converting %s to CMYK failed\n", filename);
retval = -1; goto bailout;
}
}
/* Verify that tj3LoadImage*() returns the proper "preferred" pixel format
for the file type. */
tj3Free(buf); buf = NULL;
pf = pixelFormat;
pixelFormat = TJPF_UNKNOWN;
if (precision == 8) {
if ((buf = tj3LoadImage8(handle, filename, &loadWidth, align, &loadHeight,
&pixelFormat)) == NULL)
THROW_TJ(handle);
} else if (precision == 12) {
if ((buf = tj3LoadImage12(handle, filename, &loadWidth, align, &loadHeight,
&pixelFormat)) == NULL)
THROW_TJ(handle);
} else {
if ((buf = tj3LoadImage16(handle, filename, &loadWidth, align, &loadHeight,
&pixelFormat)) == NULL)
THROW_TJ(handle);
}
if ((pf == TJPF_GRAY && pixelFormat != TJPF_GRAY) ||
(pf != TJPF_GRAY && !strcasecmp(ext, "bmp") &&
pixelFormat != TJPF_BGR) ||
(pf != TJPF_GRAY && !strcasecmp(ext, "ppm") &&
pixelFormat != TJPF_RGB)) {
printf("\n tj3LoadImage8() returned unexpected pixel format: %s\n",
pixFormatStr[pixelFormat]);
retval = -1;
}
unlink(filename);
bailout:
tj3Destroy(handle);
tj3Free(buf);
if (exitStatus < 0) return exitStatus;
return retval;
}
static int bmpTest(void)
{
int align, width = 35, height = 39, format;
for (align = 1; align <= 8; align *= 2) {
for (format = 0; format < TJ_NUMPF; format++) {
if (precision == 8) {
printf("%s Top-Down BMP (row alignment = %d samples) ... ",
pixFormatStr[format], align);
if (doBmpTest("bmp", width, align, height, format, 0) == -1)
return -1;
printf("OK.\n");
}
printf("%s Top-Down PPM (row alignment = %d samples) ... ",
pixFormatStr[format], align);
if (doBmpTest("ppm", width, align, height, format, 1) == -1)
return -1;
printf("OK.\n");
if (precision == 8) {
printf("%s Bottom-Up BMP (row alignment = %d samples) ... ",
pixFormatStr[format], align);
if (doBmpTest("bmp", width, align, height, format, 0) == -1)
return -1;
printf("OK.\n");
}
printf("%s Bottom-Up PPM (row alignment = %d samples) ... ",
pixFormatStr[format], align);
if (doBmpTest("ppm", width, align, height, format, 1) == -1)
return -1;
printf("OK.\n");
}
}
return 0;
}
int main(int argc, char *argv[])
{
int i, bmp = 0, num4bf = 5;
#ifdef _WIN32
srand((unsigned int)time(NULL));
#endif
if (argc > 1) {
for (i = 1; i < argc; i++) {
if (!strcasecmp(argv[i], "-yuv")) doYUV = 1;
else if (!strcasecmp(argv[i], "-noyuvpad")) yuvAlign = 1;
else if (!strcasecmp(argv[i], "-lossless")) lossless = 1;
else if (!strcasecmp(argv[i], "-alloc")) alloc = 1;
else if (!strcasecmp(argv[i], "-bmp")) bmp = 1;
else if (!strcasecmp(argv[i], "-precision") && i < argc - 1) {
int tempi = atoi(argv[++i]);
if (tempi != 8 && tempi != 12 && tempi != 16)
usage(argv[0]);
precision = tempi;
if (precision == 16) lossless = 1;
} else
usage(argv[0]);
}
}
if (lossless && doYUV)
THROW("Lossless JPEG and YUV encoding/decoding are incompatible.");
if (precision != 8 && doYUV)
THROW("YUV encoding/decoding requires 8-bit data precision.");
printf("Testing %d-bit precision\n", precision);
sampleSize = (precision == 8 ? sizeof(unsigned char) : sizeof(short));
maxSample = (1 << precision) - 1;
tolerance = (lossless ? 0 : (precision > 8 ? 2 : 1));
redToY = (19595U * maxSample) >> 16;
yellowToY = (58065U * maxSample) >> 16;
if (bmp) return bmpTest();
if (alloc) printf("Testing automatic buffer allocation\n");
if (doYUV) num4bf = 4;
overflowTest();
doTest(35, 39, _3sampleFormats, 2, TJSAMP_444, "test");
doTest(39, 41, _4sampleFormats, num4bf, TJSAMP_444, "test");
doTest(41, 35, _3sampleFormats, 2, TJSAMP_422, "test");
if (!lossless) {
doTest(35, 39, _4sampleFormats, num4bf, TJSAMP_422, "test");
doTest(39, 41, _3sampleFormats, 2, TJSAMP_420, "test");
doTest(41, 35, _4sampleFormats, num4bf, TJSAMP_420, "test");
doTest(35, 39, _3sampleFormats, 2, TJSAMP_440, "test");
doTest(39, 41, _4sampleFormats, num4bf, TJSAMP_440, "test");
doTest(41, 35, _3sampleFormats, 2, TJSAMP_411, "test");
doTest(35, 39, _4sampleFormats, num4bf, TJSAMP_411, "test");
}
doTest(39, 41, _onlyGray, 1, TJSAMP_GRAY, "test");
if (!lossless) {
doTest(41, 35, _3sampleFormats, 2, TJSAMP_GRAY, "test");
doTest(35, 39, _4sampleFormats, 4, TJSAMP_GRAY, "test");
}
bufSizeTest();
if (doYUV) {
printf("\n--------------------\n\n");
doTest(48, 48, _onlyRGB, 1, TJSAMP_444, "test_yuv0");
doTest(48, 48, _onlyRGB, 1, TJSAMP_422, "test_yuv0");
doTest(48, 48, _onlyRGB, 1, TJSAMP_420, "test_yuv0");
doTest(48, 48, _onlyRGB, 1, TJSAMP_440, "test_yuv0");
doTest(48, 48, _onlyRGB, 1, TJSAMP_411, "test_yuv0");
doTest(48, 48, _onlyRGB, 1, TJSAMP_GRAY, "test_yuv0");
doTest(48, 48, _onlyGray, 1, TJSAMP_GRAY, "test_yuv0");
}
bailout:
return exitStatus;
}
Reference in New Issue View Git Blame Copy Permalink