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e8b40f3c2ba187ba95c13c3e8ce21c8534256df7
mozjpeg/example.c
DRC e8b40f3c2b Vastly improve 12-bit JPEG integration 
The Gordian knot that 7fec5074f9 attempted
to unravel was caused by the fact that there are several
data-precision-dependent (JSAMPLE-dependent) fields and methods in the
exposed libjpeg API structures, and if you change the exposed libjpeg
API structures, then you have to change the whole API.  If you change
the whole API, then you have to provide a whole new library to support
the new API, and that makes it difficult to support multiple data
precisions in the same application.  (It is not impossible, as example.c
demonstrated, but using data-precision-dependent libjpeg API structures
would have made the cjpeg, djpeg, and jpegtran source code hard to read,
so it made more sense to build, install, and package 12-bit-specific
versions of those applications.)

Unfortunately, the result of that initial integration effort was an
unreadable and unmaintainable mess, which is a problem for a library
that is an ISO/ITU-T reference implementation.  Also, as I dug into the
problem of lossless JPEG support, I realized that 16-bit lossless JPEG
images are a thing, and supporting yet another version of the libjpeg
API just for those images is untenable.

In fact, however, the touch points for JSAMPLE in the exposed libjpeg
API structures are minimal:

  - The colormap and sample_range_limit fields in jpeg_decompress_struct
  - The alloc_sarray() and access_virt_sarray() methods in
    jpeg_memory_mgr
  - jpeg_write_scanlines() and jpeg_write_raw_data()
  - jpeg_read_scanlines() and jpeg_read_raw_data()
  - jpeg_skip_scanlines() and jpeg_crop_scanline()
    (This is subtle, but both of those functions use JSAMPLE-dependent
    opaque structures behind the scenes.)

It is much more readable and maintainable to provide 12-bit-specific
versions of those six top-level API functions and to document that the
aforementioned methods and fields must be type-cast when using 12-bit
samples.  Since that eliminates the need to provide a 12-bit-specific
version of the exposed libjpeg API structures, we can:

  - Compile only the precision-dependent libjpeg modules (the
    coefficient buffer controllers, the colorspace converters, the
    DCT/IDCT managers, the main buffer controllers, the preprocessing
    and postprocessing controller, the downsampler and upsamplers, the
    quantizers, the integer DCT methods, and the IDCT methods) for
    multiple data precisions.
  - Introduce 12-bit-specific methods into the various internal
    structures defined in jpegint.h.
  - Create precision-independent data type, macro, method, field, and
    function names that are prefixed by an underscore, and use an
    internal header to convert those into precision-dependent data
    type, macro, method, field, and function names, based on the value
    of BITS_IN_JSAMPLE, when compiling the precision-dependent libjpeg
    modules.
  - Expose precision-dependent jinit*() functions for each of the
    precision-dependent libjpeg modules.
  - Abstract the precision-dependent libjpeg modules by calling the
    appropriate precision-dependent jinit*() function, based on the
    value of cinfo->data_precision, from top-level libjpeg API
    functions.
2022-11-04 12:30:33 -05:00

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/*
* example.c
*
* This file was part of the Independent JPEG Group's software.
* Copyright (C) 1992-1996, Thomas G. Lane.
* libjpeg-turbo Modifications:
* Copyright (C) 2017, 2019, 2022, D. R. Commander.
* For conditions of distribution and use, see the accompanying README.ijg
* file.
*
* This file illustrates how to use the IJG code as a subroutine library
* to read or write JPEG image files with 8-bit or 12-bit data precision. You
* should look at this code in conjunction with the documentation file
* libjpeg.txt.
*
* We present these routines in the same coding style used in the JPEG code
* (ANSI function definitions, etc); but you are of course free to code your
* routines in a different style if you prefer.
*/
/* First-time users of libjpeg-turbo might be better served by looking at
* tjexample.c, which uses the more straightforward TurboJPEG API. Note that
* this example, like cjpeg and djpeg, interleaves disk I/O with JPEG
* compression/decompression, so it is not suitable for benchmarking purposes.
*/
#ifdef _MSC_VER
#define _CRT_SECURE_NO_DEPRECATE
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef _WIN32
#define strcasecmp stricmp
#define strncasecmp strnicmp
#endif
/*
* Include file for users of JPEG library.
* You will need to have included system headers that define at least
* the typedefs FILE and size_t before you can include jpeglib.h.
* (stdio.h is sufficient on ANSI-conforming systems.)
* You may also wish to include "jerror.h".
*/
#include "jpeglib.h"
#include "jerror.h"
/*
* <setjmp.h> is used for the optional error recovery mechanism shown in
* the second part of the example.
*/
#include <setjmp.h>
/******************** JPEG COMPRESSION SAMPLE INTERFACE *******************/
/* This half of the example shows how to feed data into the JPEG compressor.
* We present a minimal version that does not worry about refinements such
* as error recovery (the JPEG code will just exit() if it gets an error).
*/
/*
* IMAGE DATA FORMATS:
*
* The standard input image format is a rectangular array of pixels, with
* each pixel having the same number of "component" values (color channels).
* Each pixel row is an array of JSAMPLEs (which typically are unsigned chars)
* or J12SAMPLEs (which typically are shorts). If you are working with color
* data, then the color values for each pixel must be adjacent in the row; for
* example, R,G,B,R,G,B,R,G,B,... for 24-bit RGB color.
*
* For this example, we'll assume that this data structure matches the way
* our application has stored the image in memory, so we can just pass a
* pointer to our image buffer. In particular, let's say that the image is
* RGB color and is described by:
*/
#define WIDTH 640 /* Number of columns in image */
#define HEIGHT 480 /* Number of rows in image */
/*
* Sample routine for JPEG compression. We assume that the target file name,
* a compression quality factor, and a data precision are passed in.
*/
METHODDEF(void)
write_JPEG_file(char *filename, int quality, int data_precision)
{
/* This struct contains the JPEG compression parameters and pointers to
* working space (which is allocated as needed by the JPEG library).
* It is possible to have several such structures, representing multiple
* compression/decompression processes, in existence at once. We refer
* to any one struct (and its associated working data) as a "JPEG object".
*/
struct jpeg_compress_struct cinfo;
/* This struct represents a JPEG error handler. It is declared separately
* because applications often want to supply a specialized error handler
* (see the second half of this file for an example). But here we just
* take the easy way out and use the standard error handler, which will
* print a message on stderr and call exit() if compression fails.
* Note that this struct must live as long as the main JPEG parameter
* struct, to avoid dangling-pointer problems.
*/
struct jpeg_error_mgr jerr;
/* More stuff */
FILE *outfile; /* target file */
JSAMPARRAY image_buffer = NULL;
/* Points to large array of R,G,B-order data */
JSAMPROW row_pointer[1]; /* pointer to JSAMPLE row[s] */
#ifdef WITH_12BIT
J12SAMPARRAY image_buffer12 = NULL;
/* Points to large array of R,G,B-order 12-bit
data */
J12SAMPROW row_pointer12[1]; /* pointer to J12SAMPLE row[s] */
#endif
int row_stride; /* physical row width in image buffer */
int row, col;
/* Step 1: allocate and initialize JPEG compression object */
/* We have to set up the error handler first, in case the initialization
* step fails. (Unlikely, but it could happen if you are out of memory.)
* This routine fills in the contents of struct jerr, and returns jerr's
* address which we place into the link field in cinfo.
*/
cinfo.err = jpeg_std_error(&jerr);
/* Now we can initialize the JPEG compression object. */
jpeg_create_compress(&cinfo);
/* Step 2: specify data destination (eg, a file) */
/* Note: steps 2 and 3 can be done in either order. */
/* Here we use the library-supplied code to send compressed data to a
* stdio stream. You can also write your own code to do something else.
* VERY IMPORTANT: use "b" option to fopen() if you are on a machine that
* requires it in order to write binary files.
*/
if ((outfile = fopen(filename, "wb")) == NULL)
ERREXIT(&cinfo, JERR_FILE_WRITE);
jpeg_stdio_dest(&cinfo, outfile);
/* Step 3: set parameters for compression */
/* First we supply a description of the input image.
* Four fields of the cinfo struct must be filled in:
*/
cinfo.image_width = WIDTH; /* image width and height, in pixels */
cinfo.image_height = HEIGHT;
cinfo.input_components = 3; /* # of color components per pixel */
cinfo.in_color_space = JCS_RGB; /* colorspace of input image */
cinfo.data_precision = data_precision; /* data precision of input image */
/* Now use the library's routine to set default compression parameters.
* (You must set at least cinfo.in_color_space before calling this,
* since the defaults depend on the source color space.)
*/
jpeg_set_defaults(&cinfo);
/* Now you can set any non-default parameters you wish to.
* Here we just illustrate the use of quality (quantization table) scaling:
*/
jpeg_set_quality(&cinfo, quality, TRUE /* limit to baseline-JPEG values */);
/* Use 4:4:4 subsampling (default is 4:2:0) */
cinfo.comp_info[0].h_samp_factor = cinfo.comp_info[0].v_samp_factor = 1;
/* Step 4: Start compressor */
/* TRUE ensures that we will write a complete interchange-JPEG file.
* Pass TRUE unless you are very sure of what you're doing.
*/
jpeg_start_compress(&cinfo, TRUE);
/* Step 5: allocate and initialize image buffer */
row_stride = WIDTH * 3; /* J[12]SAMPLEs per row in image_buffer */
/* Make a sample array that will go away when done with image. Note that,
* for the purposes of this example, we could also create a one-row-high
* sample array and initialize it for each successive scanline written in the
* scanline loop below.
*/
#ifdef WITH_12BIT
if (cinfo.data_precision == 12) {
image_buffer12 = (J12SAMPARRAY)(*cinfo.mem->alloc_sarray)
((j_common_ptr)&cinfo, JPOOL_IMAGE, row_stride, HEIGHT);
/* Initialize image buffer with a repeating pattern */
for (row = 0; row < HEIGHT; row++) {
for (col = 0; col < WIDTH; col++) {
image_buffer12[row][col * 3] =
(col * (MAXJ12SAMPLE + 1) / WIDTH) % (MAXJ12SAMPLE + 1);
image_buffer12[row][col * 3 + 1] =
(row * (MAXJ12SAMPLE + 1) / HEIGHT) % (MAXJ12SAMPLE + 1);
image_buffer12[row][col * 3 + 2] =
(row * (MAXJ12SAMPLE + 1) / HEIGHT +
col * (MAXJ12SAMPLE + 1) / WIDTH) % (MAXJ12SAMPLE + 1);
}
}
} else
#endif
{
image_buffer = (*cinfo.mem->alloc_sarray)
((j_common_ptr)&cinfo, JPOOL_IMAGE, row_stride, HEIGHT);
for (row = 0; row < HEIGHT; row++) {
for (col = 0; col < WIDTH; col++) {
image_buffer[row][col * 3] =
(col * (MAXJSAMPLE + 1) / WIDTH) % (MAXJSAMPLE + 1);
image_buffer[row][col * 3 + 1] =
(row * (MAXJSAMPLE + 1) / HEIGHT) % (MAXJSAMPLE + 1);
image_buffer[row][col * 3 + 2] =
(row * (MAXJSAMPLE + 1) / HEIGHT + col * (MAXJSAMPLE + 1) / WIDTH) %
(MAXJSAMPLE + 1);
}
}
}
/* Step 6: while (scan lines remain to be written) */
/* jpeg_write_scanlines(...); */
/* Here we use the library's state variable cinfo.next_scanline as the
* loop counter, so that we don't have to keep track ourselves.
* To keep things simple, we pass one scanline per call; you can pass
* more if you wish, though.
*/
#ifdef WITH_12BIT
if (cinfo.data_precision == 12) {
while (cinfo.next_scanline < cinfo.image_height) {
/* jpeg12_write_scanlines expects an array of pointers to scanlines.
* Here the array is only one element long, but you could pass
* more than one scanline at a time if that's more convenient.
*/
row_pointer12[0] = image_buffer12[cinfo.next_scanline];
(void)jpeg12_write_scanlines(&cinfo, row_pointer12, 1);
}
} else
#endif
{
while (cinfo.next_scanline < cinfo.image_height) {
/* jpeg_write_scanlines expects an array of pointers to scanlines.
* Here the array is only one element long, but you could pass
* more than one scanline at a time if that's more convenient.
*/
row_pointer[0] = image_buffer[cinfo.next_scanline];
(void)jpeg_write_scanlines(&cinfo, row_pointer, 1);
}
}
/* Step 7: Finish compression */
jpeg_finish_compress(&cinfo);
/* After finish_compress, we can close the output file. */
fclose(outfile);
/* Step 8: release JPEG compression object */
/* This is an important step since it will release a good deal of memory. */
jpeg_destroy_compress(&cinfo);
/* And we're done! */
}
/*
* SOME FINE POINTS:
*
* In the above loop, we ignored the return value of jpeg_write_scanlines,
* which is the number of scanlines actually written. We could get away
* with this because we were only relying on the value of cinfo.next_scanline,
* which will be incremented correctly. If you maintain additional loop
* variables then you should be careful to increment them properly.
* Actually, for output to a stdio stream you needn't worry, because
* then jpeg_write_scanlines will write all the lines passed (or else exit
* with a fatal error). Partial writes can only occur if you use a data
* destination module that can demand suspension of the compressor.
* (If you don't know what that's for, you don't need it.)
*
* If the compressor requires full-image buffers (for entropy-coding
* optimization or a multi-scan JPEG file), it will create temporary
* files for anything that doesn't fit within the maximum-memory setting.
* (Note that temp files are NOT needed if you use the default parameters.)
* On some systems you may need to set up a signal handler to ensure that
* temporary files are deleted if the program is interrupted. See libjpeg.txt.
*
* Scanlines MUST be supplied in top-to-bottom order if you want your JPEG
* files to be compatible with everyone else's. If you cannot readily read
* your data in that order, you'll need an intermediate array to hold the
* image. See rdtarga.c or rdbmp.c for examples of handling bottom-to-top
* source data using the JPEG code's internal virtual-array mechanisms.
*/
/******************** JPEG DECOMPRESSION SAMPLE INTERFACE *******************/
/* This half of the example shows how to read data from the JPEG decompressor.
* It's a bit more refined than the above, in that we show:
* (a) how to modify the JPEG library's standard error-reporting behavior;
* (b) how to allocate workspace using the library's memory manager.
*
* Just to make this example a little different from the first one, we'll
* assume that we do not intend to put the whole image into an in-memory
* buffer, but to send it line-by-line someplace else. We need a one-
* scanline-high JSAMPLE or J12SAMPLE array as a work buffer, and we will let
* the JPEG memory manager allocate it for us. This approach is actually quite
* useful because we don't need to remember to deallocate the buffer
* separately: it will go away automatically when the JPEG object is cleaned
* up.
*/
/*
* ERROR HANDLING:
*
* The JPEG library's standard error handler (jerror.c) is divided into
* several "methods" which you can override individually. This lets you
* adjust the behavior without duplicating a lot of code, which you might
* have to update with each future release.
*
* Our example here shows how to override the "error_exit" method so that
* control is returned to the library's caller when a fatal error occurs,
* rather than calling exit() as the standard error_exit method does.
*
* We use C's setjmp/longjmp facility to return control. This means that the
* routine which calls the JPEG library must first execute a setjmp() call to
* establish the return point. We want the replacement error_exit to do a
* longjmp(). But we need to make the setjmp buffer accessible to the
* error_exit routine. To do this, we make a private extension of the
* standard JPEG error handler object. (If we were using C++, we'd say we
* were making a subclass of the regular error handler.)
*
* Here's the extended error handler struct:
*/
struct my_error_mgr {
struct jpeg_error_mgr pub; /* "public" fields */
jmp_buf setjmp_buffer; /* for return to caller */
};
typedef struct my_error_mgr *my_error_ptr;
/*
* Here's the routine that will replace the standard error_exit method:
*/
METHODDEF(void)
my_error_exit(j_common_ptr cinfo)
{
/* cinfo->err really points to a my_error_mgr struct, so coerce pointer */
my_error_ptr myerr = (my_error_ptr)cinfo->err;
/* Always display the message. */
/* We could postpone this until after returning, if we chose. */
(*cinfo->err->output_message) (cinfo);
/* Return control to the setjmp point */
longjmp(myerr->setjmp_buffer, 1);
}
METHODDEF(int) do_read_JPEG_file(struct jpeg_decompress_struct *cinfo,
char *infilename, char *outfilename);
/*
* Sample routine for JPEG decompression. We assume that the source file name
* is passed in. We want to return 1 on success, 0 on error.
*/
METHODDEF(int)
read_JPEG_file(char *infilename, char *outfilename)
{
/* This struct contains the JPEG decompression parameters and pointers to
* working space (which is allocated as needed by the JPEG library).
*/
struct jpeg_decompress_struct cinfo;
return do_read_JPEG_file(&cinfo, infilename, outfilename);
}
/*
* We call the libjpeg API from within a separate function, because modifying
* the local non-volatile jpeg_decompress_struct instance below the setjmp()
* return point and then accessing the instance after setjmp() returns would
* result in undefined behavior that may potentially overwrite all or part of
* the structure.
*/
METHODDEF(int)
do_read_JPEG_file(struct jpeg_decompress_struct *cinfo, char *infilename,
char *outfilename)
{
/* We use our private extension JPEG error handler.
* Note that this struct must live as long as the main JPEG parameter
* struct, to avoid dangling-pointer problems.
*/
struct my_error_mgr jerr;
/* More stuff */
FILE *infile; /* source file */
FILE *outfile; /* output file */
JSAMPARRAY buffer; /* Output row buffer */
#ifdef WITH_12BIT
J12SAMPARRAY buffer12; /* 12-bit output row buffer */
int col;
#endif
int row_stride; /* physical row width in output buffer */
/* In this example we want to open the input and output files before doing
* anything else, so that the setjmp() error recovery below can assume the
* files are open.
*
* VERY IMPORTANT: use "b" option to fopen() if you are on a machine that
* requires it in order to read/write binary files.
*/
if ((infile = fopen(infilename, "rb")) == NULL) {
fprintf(stderr, "can't open %s\n", infilename);
return 0;
}
if ((outfile = fopen(outfilename, "wb")) == NULL) {
fprintf(stderr, "can't open %s\n", outfilename);
fclose(infile);
return 0;
}
/* Step 1: allocate and initialize JPEG decompression object */
/* We set up the normal JPEG error routines, then override error_exit. */
cinfo->err = jpeg_std_error(&jerr.pub);
jerr.pub.error_exit = my_error_exit;
/* Establish the setjmp return context for my_error_exit to use. */
if (setjmp(jerr.setjmp_buffer)) {
/* If we get here, the JPEG code has signaled an error.
* We need to clean up the JPEG object, close the input file, and return.
*/
jpeg_destroy_decompress(cinfo);
fclose(infile);
fclose(outfile);
return 0;
}
/* Now we can initialize the JPEG decompression object. */
jpeg_create_decompress(cinfo);
/* Step 2: specify data source (eg, a file) */
jpeg_stdio_src(cinfo, infile);
/* Step 3: read file parameters with jpeg_read_header() */
(void)jpeg_read_header(cinfo, TRUE);
/* We can ignore the return value from jpeg_read_header since
* (a) suspension is not possible with the stdio data source, and
* (b) we passed TRUE to reject a tables-only JPEG file as an error.
* See libjpeg.txt for more info.
*/
/* emit header for raw PPM format */
#ifdef WITH_12BIT
fprintf(outfile, "P6\n%d %d\n%d\n", WIDTH, HEIGHT,
cinfo->data_precision == 12 ? MAXJ12SAMPLE : MAXJSAMPLE);
#else
fprintf(outfile, "P6\n%d %d\n%d\n", WIDTH, HEIGHT, MAXJSAMPLE);
#endif
/* Step 4: set parameters for decompression */
/* In this example, we don't need to change any of the defaults set by
* jpeg_read_header(), so we do nothing here.
*/
/* Step 5: Start decompressor */
(void)jpeg_start_decompress(cinfo);
/* We can ignore the return value since suspension is not possible
* with the stdio data source.
*/
/* We may need to do some setup of our own at this point before reading
* the data. After jpeg_start_decompress() we have the correct scaled
* output image dimensions available, as well as the output colormap
* if we asked for color quantization.
* In this example, we need to make an output work buffer of the right size.
*/
/* Samples per row in output buffer */
row_stride = cinfo->output_width * cinfo->output_components;
/* Make a one-row-high sample array that will go away when done with image */
#ifdef WITH_12BIT
if (cinfo->data_precision == 12)
buffer12 = (J12SAMPARRAY)(*cinfo->mem->alloc_sarray)
((j_common_ptr)cinfo, JPOOL_IMAGE, row_stride, 1);
else
#endif
buffer = (*cinfo->mem->alloc_sarray)
((j_common_ptr)cinfo, JPOOL_IMAGE, row_stride, 1);
/* Step 6: while (scan lines remain to be read) */
/* jpeg_read_scanlines(...); */
/* Here we use the library's state variable cinfo->output_scanline as the
* loop counter, so that we don't have to keep track ourselves.
*/
#ifdef WITH_12BIT
if (cinfo->data_precision == 12) {
while (cinfo->output_scanline < cinfo->output_height) {
/* jpeg12_read_scanlines expects an array of pointers to scanlines.
* Here the array is only one element long, but you could ask for
* more than one scanline at a time if that's more convenient.
*/
(void)jpeg12_read_scanlines(cinfo, buffer12, 1);
/* Swap MSB and LSB in each sample */
for (col = 0; col < row_stride; col++)
buffer12[0][col] = ((buffer12[0][col] & 0xFF) << 8) |
((buffer12[0][col] >> 8) & 0xFF);
fwrite(buffer12[0], 1, row_stride * sizeof(J12SAMPLE), outfile);
}
} else
#endif
{
while (cinfo->output_scanline < cinfo->output_height) {
/* jpeg_read_scanlines expects an array of pointers to scanlines.
* Here the array is only one element long, but you could ask for
* more than one scanline at a time if that's more convenient.
*/
(void)jpeg_read_scanlines(cinfo, buffer, 1);
fwrite(buffer[0], 1, row_stride, outfile);
}
}
/* Step 7: Finish decompression */
(void)jpeg_finish_decompress(cinfo);
/* We can ignore the return value since suspension is not possible
* with the stdio data source.
*/
/* Step 8: Release JPEG decompression object */
/* This is an important step since it will release a good deal of memory. */
jpeg_destroy_decompress(cinfo);
/* After finish_decompress, we can close the input and output files.
* Here we postpone it until after no more JPEG errors are possible,
* so as to simplify the setjmp error logic above. (Actually, I don't
* think that jpeg_destroy can do an error exit, but why assume anything...)
*/
fclose(infile);
fclose(outfile);
/* At this point you may want to check to see whether any corrupt-data
* warnings occurred (test whether jerr.pub.num_warnings is nonzero).
*/
/* And we're done! */
return 1;
}
/*
* SOME FINE POINTS:
*
* In the above code, we ignored the return value of jpeg_read_scanlines,
* which is the number of scanlines actually read. We could get away with
* this because we asked for only one line at a time and we weren't using
* a suspending data source. See libjpeg.txt for more info.
*
* We cheated a bit by calling alloc_sarray() after jpeg_start_decompress();
* we should have done it beforehand to ensure that the space would be
* counted against the JPEG max_memory setting. In some systems the above
* code would risk an out-of-memory error. However, in general we don't
* know the output image dimensions before jpeg_start_decompress(), unless we
* call jpeg_calc_output_dimensions(). See libjpeg.txt for more about this.
*
* Scanlines are returned in the same order as they appear in the JPEG file,
* which is standardly top-to-bottom. If you must emit data bottom-to-top,
* you can use one of the virtual arrays provided by the JPEG memory manager
* to invert the data. See wrbmp.c for an example.
*
* As with compression, some operating modes may require temporary files.
* On some systems you may need to set up a signal handler to ensure that
* temporary files are deleted if the program is interrupted. See libjpeg.txt.
*/
LOCAL(void)
usage(const char *progname)
{
fprintf(stderr, "usage: %s compress [switches] outputfile[.jpg]\n",
progname);
fprintf(stderr, " %s decompress inputfile[.jpg] outputfile[.ppm]\n",
progname);
fprintf(stderr, "Switches (names may be abbreviated):\n");
#ifdef WITH_12BIT
fprintf(stderr, " -precision N Create JPEG file with N-bit data precision\n");
fprintf(stderr, " (N is 8 or 12; default is 8)\n");
#endif
fprintf(stderr, " -quality N Compression quality (0..100; 5-95 is most useful range,\n");
fprintf(stderr, " default is 75)\n");
exit(EXIT_FAILURE);
}
typedef enum {
COMPRESS,
DECOMPRESS
} EXAMPLE_MODE;
int
main(int argc, char **argv)
{
int argn, quality = 75;
int data_precision = 8;
EXAMPLE_MODE mode = -1;
char *arg, *filename = NULL;
if (argc < 3)
usage(argv[0]);
if (!strcasecmp(argv[1], "compress"))
mode = COMPRESS;
else if (!strcasecmp(argv[1], "decompress"))
mode = DECOMPRESS;
else
usage(argv[0]);
for (argn = 2; argn < argc; argn++) {
arg = argv[argn];
if (*arg != '-') {
filename = arg;
/* Not a switch, must be a file name argument */
break; /* done parsing switches */
}
arg++; /* advance past switch marker character */
#ifdef WITH_12BIT
if (!strncasecmp(arg, "p", 1)) {
/* Set data precision. */
if (++argn >= argc) /* advance to next argument */
usage(argv[0]);
if (sscanf(argv[argn], "%d", &data_precision) < 1 ||
(data_precision != 8 && data_precision != 12))
usage(argv[0]);
} else
#endif
if (!strncasecmp(arg, "q", 1)) {
/* Quality rating (quantization table scaling factor). */
if (++argn >= argc) /* advance to next argument */
usage(argv[0]);
if (sscanf(argv[argn], "%d", &quality) < 1 || quality < 0 ||
quality > 100)
usage(argv[0]);
if (quality < 1)
quality = 1;
}
}
if (!filename)
usage(argv[0]);
if (mode == COMPRESS)
write_JPEG_file(filename, quality, data_precision);
else if (mode == DECOMPRESS) {
if (argc - argn < 2)
usage(argv[0]);
read_JPEG_file(argv[argn], argv[argn + 1]);
}
return 0;
}
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