openjpeg-sys 1.0.11

/*
 * The copyright in this software is being made available under the 2-clauses
 * BSD License, included below. This software may be subject to other third
 * party and contributor rights, including patent rights, and no such rights
 * are granted under this license.
 *
 * Copyright (c) 2002-2014, Universite catholique de Louvain (UCL), Belgium
 * Copyright (c) 2002-2014, Professor Benoit Macq
 * Copyright (c) 2001-2003, David Janssens
 * Copyright (c) 2002-2003, Yannick Verschueren
 * Copyright (c) 2003-2007, Francois-Olivier Devaux
 * Copyright (c) 2003-2014, Antonin Descampe
 * Copyright (c) 2005, Herve Drolon, FreeImage Team
 * Copyright (c) 2006-2007, Parvatha Elangovan
 * Copyright (c) 2008, 2011-2012, Centre National d'Etudes Spatiales (CNES), FR
 * Copyright (c) 2012, CS Systemes d'Information, France
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. 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.
 *
 * 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 OWNER 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.
 */
#include "opj_apps_config.h"

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
#include <limits.h>

#ifdef _WIN32
#include "windirent.h"
#else
#include <dirent.h>
#endif /* _WIN32 */

#ifdef _WIN32
#include <windows.h>
#define strcasecmp _stricmp
#define strncasecmp _strnicmp
#else
#include <strings.h>
#include <sys/time.h>
#include <sys/resource.h>
#include <sys/times.h>
#endif /* _WIN32 */

#include "openjpeg.h"
#include "opj_getopt.h"
#include "convert.h"
#include "index.h"

#ifdef OPJ_HAVE_LIBLCMS2
#include <lcms2.h>
#endif
#ifdef OPJ_HAVE_LIBLCMS1
#include <lcms.h>
#endif
#include "color.h"

#include "format_defs.h"
#include "opj_string.h"

typedef struct dircnt {
    /** Buffer for holding images read from Directory*/
    char *filename_buf;
    /** Pointer to the buffer*/
    char **filename;
} dircnt_t;


typedef struct img_folder {
    /** The directory path of the folder containing input images*/
    char *imgdirpath;
    /** Output format*/
    const char *out_format;
    /** Enable option*/
    char set_imgdir;
    /** Enable Cod Format for output*/
    char set_out_format;

} img_fol_t;

typedef enum opj_prec_mode {
    OPJ_PREC_MODE_CLIP,
    OPJ_PREC_MODE_SCALE
} opj_precision_mode;

typedef struct opj_prec {
    OPJ_UINT32         prec;
    opj_precision_mode mode;
} opj_precision;

typedef struct opj_decompress_params {
    /** core library parameters */
    opj_dparameters_t core;

    /** input file name */
    char infile[OPJ_PATH_LEN];
    /** output file name */
    char outfile[OPJ_PATH_LEN];
    /** input file format 0: J2K, 1: JP2, 2: JPT */
    int decod_format;
    /** output file format 0: PGX, 1: PxM, 2: BMP */
    int cod_format;
    /** index file name */
    char indexfilename[OPJ_PATH_LEN];

    /** Decoding area left boundary */
    OPJ_UINT32 DA_x0;
    /** Decoding area right boundary */
    OPJ_UINT32 DA_x1;
    /** Decoding area up boundary */
    OPJ_UINT32 DA_y0;
    /** Decoding area bottom boundary */
    OPJ_UINT32 DA_y1;
    /** Verbose mode */
    OPJ_BOOL m_verbose;

    /** tile number of the decoded tile */
    OPJ_UINT32 tile_index;
    /** Nb of tile to decode */
    OPJ_UINT32 nb_tile_to_decode;

    opj_precision* precision;
    OPJ_UINT32     nb_precision;

    /* force output colorspace to RGB */
    int force_rgb;
    /* upsample components according to their dx/dy values */
    int upsample;
    /* split output components to different files */
    int split_pnm;
    /** number of threads */
    int num_threads;
    /* Quiet */
    int quiet;
    /* Allow partial decode */
    int allow_partial;
    /** number of components to decode */
    OPJ_UINT32 numcomps;
    /** indices of components to decode */
    OPJ_UINT32* comps_indices;
} opj_decompress_parameters;

/* -------------------------------------------------------------------------- */
/* Declarations                                                               */
unsigned int get_num_images(char *imgdirpath);
int load_images(dircnt_t *dirptr, char *imgdirpath);
int get_file_format(const char *filename);
char get_next_file(unsigned int imageno, dircnt_t *dirptr, img_fol_t *img_fol,
                   opj_decompress_parameters *parameters);
static int infile_format(const char *fname);

int parse_cmdline_decoder(int argc, char **argv,
                          opj_decompress_parameters *parameters, img_fol_t *img_fol);
int parse_DA_values(char* inArg, unsigned int *DA_x0, unsigned int *DA_y0,
                    unsigned int *DA_x1, unsigned int *DA_y1);

static opj_image_t* convert_gray_to_rgb(opj_image_t* original);

/* -------------------------------------------------------------------------- */
static void decode_help_display(void)
{
    fprintf(stdout,
            "\nThis is the opj_decompress utility from the OpenJPEG project.\n"
            "It decompresses JPEG 2000 codestreams to various image formats.\n"
            "It has been compiled against openjp2 library v%s.\n\n", opj_version());

    fprintf(stdout, "Parameters:\n"
            "-----------\n"
            "\n"
            "  -ImgDir <directory> \n"
            "	Image file Directory path \n"
            "  -OutFor <PBM|PGM|PPM|PNM|PAM|PGX|PNG|BMP|TIF|TIFF|RAW|YUV|RAWL|TGA>\n"
            "    REQUIRED only if -ImgDir is used\n"
            "	Output format for decompressed images.\n");
    fprintf(stdout, "  -i <compressed file>\n"
            "    REQUIRED only if an Input image directory is not specified\n"
            "    Currently accepts J2K-files, JP2-files and JPT-files. The file type\n"
            "    is identified based on its suffix.\n");
    fprintf(stdout, "  -o <decompressed file>\n"
            "    REQUIRED\n"
            "    Currently accepts formats specified above (see OutFor option)\n"
            "    Binary data is written to the file (not ascii). If a PGX\n"
            "    filename is given, there will be as many output files as there are\n"
            "    components: an indice starting from 0 will then be appended to the\n"
            "    output filename, just before the \"pgx\" extension. If a PGM filename\n"
            "    is given and there are more than one component, only the first component\n"
            "    will be written to the file.\n");
    fprintf(stdout, "  -r <reduce factor>\n"
            "    Set the number of highest resolution levels to be discarded. The\n"
            "    image resolution is effectively divided by 2 to the power of the\n"
            "    number of discarded levels. The reduce factor is limited by the\n"
            "    smallest total number of decomposition levels among tiles.\n"
            "  -l <number of quality layers to decode>\n"
            "    Set the maximum number of quality layers to decode. If there are\n"
            "    less quality layers than the specified number, all the quality layers\n"
            "    are decoded.\n");
    fprintf(stdout, "  -x  \n"
            "    Create an index file *.Idx (-x index_name.Idx) \n"
            "  -d <x0,y0,x1,y1>\n"
            "    OPTIONAL\n"
            "    Decoding area\n"
            "    By default all the image is decoded.\n"
            "  -t <tile_number>\n"
            "    OPTIONAL\n"
            "    Set the tile number of the decoded tile. Follow the JPEG2000 convention from left-up to bottom-up\n"
            "    By default all tiles are decoded.\n");
    fprintf(stdout, "  -p <comp 0 precision>[C|S][,<comp 1 precision>[C|S][,...]]\n"
            "    OPTIONAL\n"
            "    Force the precision (bit depth) of components.\n");
    fprintf(stdout,
            "    There shall be at least 1 value. There is no limit on the number of values (comma separated, last values ignored if too much values).\n"
            "    If there are less values than components, the last value is used for remaining components.\n"
            "    If 'C' is specified (default), values are clipped.\n"
            "    If 'S' is specified, values are scaled.\n"
            "    A 0 value can be specified (meaning original bit depth).\n");
    fprintf(stdout, "  -c first_comp_index[,second_comp_index][,...]\n"
            "    OPTIONAL\n"
            "    To limit the number of components to decoded.\n"
            "    Component indices are numbered starting at 0.\n");
    fprintf(stdout, "  -force-rgb\n"
            "    Force output image colorspace to RGB\n"
            "  -upsample\n"
            "    Downsampled components will be upsampled to image size\n"
            "  -split-pnm\n"
            "    Split output components to different files when writing to PNM\n");
    if (opj_has_thread_support()) {
        fprintf(stdout, "  -threads <num_threads|ALL_CPUS>\n"
                "    Number of threads to use for decoding or ALL_CPUS for all available cores.\n");
    }
    fprintf(stdout, "  -allow-partial\n"
            "    Disable strict mode to allow decoding partial codestreams.\n");
    fprintf(stdout, "  -quiet\n"
            "    Disable output from the library and other output.\n");
    /* UniPG>> */
#ifdef USE_JPWL
    fprintf(stdout, "  -W <options>\n"
            "    Activates the JPWL correction capability, if the codestream complies.\n"
            "    Options can be a comma separated list of <param=val> tokens:\n"
            "    c, c=numcomps\n"
            "       numcomps is the number of expected components in the codestream\n"
            "       (search of first EPB rely upon this, default is %d)\n",
            JPWL_EXPECTED_COMPONENTS);
#endif /* USE_JPWL */
    /* <<UniPG */
    fprintf(stdout, "\n");
}

/* -------------------------------------------------------------------------- */

static OPJ_BOOL parse_precision(const char* option,
                                opj_decompress_parameters* parameters)
{
    const char* l_remaining = option;
    OPJ_BOOL l_result = OPJ_TRUE;

    /* reset */
    if (parameters->precision) {
        free(parameters->precision);
        parameters->precision = NULL;
    }
    parameters->nb_precision = 0U;

    for (;;) {
        int prec;
        char mode;
        char comma;
        int count;

        count = sscanf(l_remaining, "%d%c%c", &prec, &mode, &comma);
        if (count == 1) {
            mode = 'C';
            count++;
        }
        if ((count == 2) || (mode == ',')) {
            if (mode == ',') {
                mode = 'C';
            }
            comma = ',';
            count = 3;
        }
        if (count == 3) {
            if ((prec < 1) || (prec > 32)) {
                fprintf(stderr, "Invalid precision %d in precision option %s\n", prec, option);
                l_result = OPJ_FALSE;
                break;
            }
            if ((mode != 'C') && (mode != 'S')) {
                fprintf(stderr, "Invalid precision mode %c in precision option %s\n", mode,
                        option);
                l_result = OPJ_FALSE;
                break;
            }
            if (comma != ',') {
                fprintf(stderr, "Invalid character %c in precision option %s\n", comma, option);
                l_result = OPJ_FALSE;
                break;
            }

            if (parameters->precision == NULL) {
                /* first one */
                parameters->precision = (opj_precision *)malloc(sizeof(opj_precision));
                if (parameters->precision == NULL) {
                    fprintf(stderr, "Could not allocate memory for precision option\n");
                    l_result = OPJ_FALSE;
                    break;
                }
            } else {
                OPJ_UINT32 l_new_size = parameters->nb_precision + 1U;
                opj_precision* l_new;

                if (l_new_size == 0U) {
                    fprintf(stderr, "Could not allocate memory for precision option\n");
                    l_result = OPJ_FALSE;
                    break;
                }

                l_new = (opj_precision *)realloc(parameters->precision,
                                                 l_new_size * sizeof(opj_precision));
                if (l_new == NULL) {
                    fprintf(stderr, "Could not allocate memory for precision option\n");
                    l_result = OPJ_FALSE;
                    break;
                }
                parameters->precision = l_new;
            }

            parameters->precision[parameters->nb_precision].prec = (OPJ_UINT32)prec;
            switch (mode) {
            case 'C':
                parameters->precision[parameters->nb_precision].mode = OPJ_PREC_MODE_CLIP;
                break;
            case 'S':
                parameters->precision[parameters->nb_precision].mode = OPJ_PREC_MODE_SCALE;
                break;
            default:
                break;
            }
            parameters->nb_precision++;

            l_remaining = strchr(l_remaining, ',');
            if (l_remaining == NULL) {
                break;
            }
            l_remaining += 1;
        } else {
            fprintf(stderr, "Could not parse precision option %s\n", option);
            l_result = OPJ_FALSE;
            break;
        }
    }

    return l_result;
}

/* -------------------------------------------------------------------------- */

unsigned int get_num_images(char *imgdirpath)
{
    DIR *dir;
    struct dirent* content;
    unsigned int num_images = 0;

    /*Reading the input images from given input directory*/

    dir = opendir(imgdirpath);
    if (!dir) {
        fprintf(stderr, "Could not open Folder %s\n", imgdirpath);
        return 0;
    }

    while ((content = readdir(dir)) != NULL) {
        if (strcmp(".", content->d_name) == 0 || strcmp("..", content->d_name) == 0) {
            continue;
        }
        if (num_images == UINT_MAX) {
            fprintf(stderr, "Too many files in folder %s\n", imgdirpath);
            num_images = 0;
            break;
        }
        num_images++;

    }
    closedir(dir);
    return num_images;
}

/* -------------------------------------------------------------------------- */
int load_images(dircnt_t *dirptr, char *imgdirpath)
{
    DIR *dir;
    struct dirent* content;
    int i = 0;

    /*Reading the input images from given input directory*/

    dir = opendir(imgdirpath);
    if (!dir) {
        fprintf(stderr, "Could not open Folder %s\n", imgdirpath);
        return 1;
    } else   {
        fprintf(stderr, "Folder opened successfully\n");
    }

    while ((content = readdir(dir)) != NULL) {
        if (strcmp(".", content->d_name) == 0 || strcmp("..", content->d_name) == 0) {
            continue;
        }

        strcpy(dirptr->filename[i], content->d_name);
        i++;
    }
    closedir(dir);
    return 0;
}

/* -------------------------------------------------------------------------- */
int get_file_format(const char *filename)
{
    unsigned int i;
    static const char * const extension[] = {
        "pgx", "pnm", "pgm", "ppm", "bmp",
        "tif", "tiff",
        "raw", "yuv", "rawl",
        "tga", "png",
        "j2k", "jp2", "jpt", "j2c", "jpc",
        "jph", /* HTJ2K with JP2 boxes */
        "jhc" /* HTJ2K codestream */
    };
    static const int format[] = {
        PGX_DFMT, PXM_DFMT, PXM_DFMT, PXM_DFMT, BMP_DFMT,
        TIF_DFMT, TIF_DFMT,
        RAW_DFMT, RAW_DFMT, RAWL_DFMT,
        TGA_DFMT, PNG_DFMT,
        J2K_CFMT, JP2_CFMT, JPT_CFMT, J2K_CFMT, J2K_CFMT,
        JP2_CFMT, /* HTJ2K with JP2 boxes */
        J2K_CFMT /* HTJ2K codestream */
    };
    const char * ext = strrchr(filename, '.');
    if (ext == NULL) {
        return -1;
    }
    ext++;
    if (*ext) {
        for (i = 0; i < sizeof(format) / sizeof(*format); i++) {
            if (strcasecmp(ext, extension[i]) == 0) {
                return format[i];
            }
        }
    }

    return -1;
}

#ifdef _WIN32
const char* path_separator = "\\";
#else
const char* path_separator = "/";
#endif

/* -------------------------------------------------------------------------- */
char get_next_file(unsigned int imageno, dircnt_t *dirptr, img_fol_t *img_fol,
                   opj_decompress_parameters *parameters)
{
    char image_filename[OPJ_PATH_LEN], infilename[OPJ_PATH_LEN],
         outfilename[OPJ_PATH_LEN], temp_ofname[OPJ_PATH_LEN];
    char *temp_p, temp1[OPJ_PATH_LEN] = "";

    strcpy(image_filename, dirptr->filename[imageno]);
    fprintf(stderr, "File Number %u \"%s\"\n", imageno, image_filename);
    if (strlen(img_fol->imgdirpath) + strlen(path_separator) + strlen(
                image_filename) + 1 > sizeof(infilename)) {
        return 1;
    }
    strcpy(infilename, img_fol->imgdirpath);
    strcat(infilename, path_separator);
    strcat(infilename, image_filename);
    parameters->decod_format = infile_format(infilename);
    if (parameters->decod_format == -1) {
        return 1;
    }
    if (opj_strcpy_s(parameters->infile, sizeof(parameters->infile),
                     infilename) != 0) {
        return 1;
    }

    /*Set output file*/
    strcpy(temp_ofname, strtok(image_filename, "."));
    while ((temp_p = strtok(NULL, ".")) != NULL) {
        strcat(temp_ofname, temp1);
        sprintf(temp1, ".%s", temp_p);
    }
    if (img_fol->set_out_format == 1) {
        if (strlen(img_fol->imgdirpath) + 1 + strlen(temp_ofname) + 1 + strlen(
                    img_fol->out_format) + 1 > sizeof(outfilename)) {
            return 1;
        }
        strcpy(outfilename, img_fol->imgdirpath);
        strcat(outfilename, "/");
        strcat(outfilename, temp_ofname);
        strcat(outfilename, ".");
        strcat(outfilename, img_fol->out_format);
        if (opj_strcpy_s(parameters->outfile, sizeof(parameters->outfile),
                         outfilename) != 0) {
            return 1;
        }
    }
    return 0;
}

/* -------------------------------------------------------------------------- */
#define JP2_RFC3745_MAGIC "\x00\x00\x00\x0c\x6a\x50\x20\x20\x0d\x0a\x87\x0a"
#define JP2_MAGIC "\x0d\x0a\x87\x0a"
/* position 45: "\xff\x52" */
#define J2K_CODESTREAM_MAGIC "\xff\x4f\xff\x51"

static int infile_format(const char *fname)
{
    FILE *reader;
    const char *s, *magic_s;
    int ext_format, magic_format;
    unsigned char buf[12];
    OPJ_SIZE_T l_nb_read;

    reader = fopen(fname, "rb");

    if (reader == NULL) {
        return -2;
    }

    memset(buf, 0, 12);
    l_nb_read = fread(buf, 1, 12, reader);
    fclose(reader);
    if (l_nb_read != 12) {
        return -1;
    }



    ext_format = get_file_format(fname);

    if (ext_format == JPT_CFMT) {
        return JPT_CFMT;
    }

    if (memcmp(buf, JP2_RFC3745_MAGIC, 12) == 0 || memcmp(buf, JP2_MAGIC, 4) == 0) {
        magic_format = JP2_CFMT;
        magic_s = ".jp2 or .jph";
    } else if (memcmp(buf, J2K_CODESTREAM_MAGIC, 4) == 0) {
        magic_format = J2K_CFMT;
        magic_s = ".j2k or .jpc or .j2c or .jhc";
    } else {
        return -1;
    }

    if (magic_format == ext_format) {
        return ext_format;
    }

    s = fname + strlen(fname) - 4;

    fputs("\n===========================================\n", stderr);
    fprintf(stderr, "The extension of this file is incorrect.\n"
            "FOUND %s. SHOULD BE %s\n", s, magic_s);
    fputs("===========================================\n", stderr);

    return magic_format;
}

/* -------------------------------------------------------------------------- */
/**
 * Parse the command line
 */
/* -------------------------------------------------------------------------- */
int parse_cmdline_decoder(int argc, char **argv,
                          opj_decompress_parameters *parameters, img_fol_t *img_fol)
{
    /* parse the command line */
    int totlen, c;
    opj_option_t long_option[] = {
        {"ImgDir",    REQ_ARG, NULL, 'y'},
        {"OutFor",    REQ_ARG, NULL, 'O'},
        {"force-rgb", NO_ARG,  NULL, 1},
        {"upsample",  NO_ARG,  NULL, 1},
        {"split-pnm", NO_ARG,  NULL, 1},
        {"threads",   REQ_ARG, NULL, 'T'},
        {"quiet", NO_ARG,  NULL, 1},
        {"allow-partial", NO_ARG,  NULL, 1},
    };

    const char optlist[] = "i:o:r:l:x:d:t:p:c:"

                           /* UniPG>> */
#ifdef USE_JPWL
                           "W:"
#endif /* USE_JPWL */
                           /* <<UniPG */
                           "h"     ;

    long_option[2].flag = &(parameters->force_rgb);
    long_option[3].flag = &(parameters->upsample);
    long_option[4].flag = &(parameters->split_pnm);
    long_option[6].flag = &(parameters->quiet);
    long_option[7].flag = &(parameters->allow_partial);
    totlen = sizeof(long_option);
    opj_reset_options_reading();
    img_fol->set_out_format = 0;
    do {
        c = opj_getopt_long(argc, argv, optlist, long_option, totlen);
        if (c == -1) {
            break;
        }
        switch (c) {
        case 0: /* long opt with flag */
            break;
        case 'i': {         /* input file */
            char *infile = opj_optarg;
            parameters->decod_format = infile_format(infile);
            switch (parameters->decod_format) {
            case J2K_CFMT:
                break;
            case JP2_CFMT:
                break;
            case JPT_CFMT:
                break;
            case -2:
                fprintf(stderr,
                        "!! infile cannot be read: %s !!\n\n",
                        infile);
                return 1;
            default:
                fprintf(stderr,
                        "[ERROR] Unknown input file format: %s \n"
                        "        Known file formats are *.j2k, *.jp2, *.jpc or *.jpt\n",
                        infile);
                return 1;
            }
            if (opj_strcpy_s(parameters->infile, sizeof(parameters->infile), infile) != 0) {
                fprintf(stderr, "[ERROR] Path is too long\n");
                return 1;
            }
        }
        break;

        /* ----------------------------------------------------- */

        case 'o': {         /* output file */
            char *outfile = opj_optarg;
            parameters->cod_format = get_file_format(outfile);
            switch (parameters->cod_format) {
            case PGX_DFMT:
            case PXM_DFMT:
            case BMP_DFMT:
            case TIF_DFMT:
            case RAW_DFMT:
            case RAWL_DFMT:
            case TGA_DFMT:
            case PNG_DFMT:
                break;
            default:
                fprintf(stderr,
                        "Unknown output format image %s [only *.png, *.pnm, *.pgm, *.ppm, *.pgx, *.bmp, *.tif(f), *.raw, *.yuv or *.tga]!!\n",
                        outfile);
                return 1;
            }
            if (opj_strcpy_s(parameters->outfile, sizeof(parameters->outfile),
                             outfile) != 0) {
                fprintf(stderr, "[ERROR] Path is too long\n");
                return 1;
            }
        }
        break;

        /* ----------------------------------------------------- */

        case 'O': {         /* output format */
            char outformat[50];
            char *of = opj_optarg;
            sprintf(outformat, ".%s", of);
            img_fol->set_out_format = 1;
            parameters->cod_format = get_file_format(outformat);
            switch (parameters->cod_format) {
            case PGX_DFMT:
                img_fol->out_format = "pgx";
                break;
            case PXM_DFMT:
                img_fol->out_format = "ppm";
                break;
            case BMP_DFMT:
                img_fol->out_format = "bmp";
                break;
            case TIF_DFMT:
                img_fol->out_format = "tif";
                break;
            case RAW_DFMT:
                img_fol->out_format = "raw";
                break;
            case RAWL_DFMT:
                img_fol->out_format = "rawl";
                break;
            case TGA_DFMT:
                img_fol->out_format = "raw";
                break;
            case PNG_DFMT:
                img_fol->out_format = "png";
                break;
            default:
                fprintf(stderr,
                        "Unknown output format image %s [only *.png, *.pnm, *.pgm, *.ppm, *.pgx, *.bmp, *.tif(f), *.raw, *.yuv or *.tga]!!\n",
                        outformat);
                return 1;
                break;
            }
        }
        break;

        /* ----------------------------------------------------- */


        case 'r': {     /* reduce option */
            sscanf(opj_optarg, "%u", &(parameters->core.cp_reduce));
        }
        break;

        /* ----------------------------------------------------- */


        case 'l': {     /* layering option */
            sscanf(opj_optarg, "%u", &(parameters->core.cp_layer));
        }
        break;

        /* ----------------------------------------------------- */

        case 'h':           /* display an help description */
            decode_help_display();
            return 1;

        /* ----------------------------------------------------- */

        case 'y': {         /* Image Directory path */
            img_fol->imgdirpath = (char*)malloc(strlen(opj_optarg) + 1);
            if (img_fol->imgdirpath == NULL) {
                return 1;
            }
            strcpy(img_fol->imgdirpath, opj_optarg);
            img_fol->set_imgdir = 1;
        }
        break;

        /* ----------------------------------------------------- */

        case 'd': {         /* Input decode ROI */
            size_t size_optarg = (size_t)strlen(opj_optarg) + 1U;
            char *ROI_values = (char*) malloc(size_optarg);
            if (ROI_values == NULL) {
                fprintf(stderr, "[ERROR] Couldn't allocate memory\n");
                return 1;
            }
            ROI_values[0] = '\0';
            memcpy(ROI_values, opj_optarg, size_optarg);
            /*printf("ROI_values = %s [%d / %d]\n", ROI_values, strlen(ROI_values), size_optarg ); */
            parse_DA_values(ROI_values, &parameters->DA_x0, &parameters->DA_y0,
                            &parameters->DA_x1, &parameters->DA_y1);

            free(ROI_values);
        }
        break;

        /* ----------------------------------------------------- */

        case 't': {         /* Input tile index */
            sscanf(opj_optarg, "%u", &parameters->tile_index);
            parameters->nb_tile_to_decode = 1;
        }
        break;

        /* ----------------------------------------------------- */

        case 'x': {         /* Creation of index file */
            if (opj_strcpy_s(parameters->indexfilename, sizeof(parameters->indexfilename),
                             opj_optarg) != 0) {
                fprintf(stderr, "[ERROR] Path is too long\n");
                return 1;
            }
        }
        break;

        /* ----------------------------------------------------- */
        case 'p': { /* Force precision */
            if (!parse_precision(opj_optarg, parameters)) {
                return 1;
            }
        }
        break;

        /* ----------------------------------------------------- */
        case 'c': { /* Components */
            const char* iter = opj_optarg;
            while (1) {
                parameters->numcomps ++;
                parameters->comps_indices = (OPJ_UINT32*) realloc(
                                                parameters->comps_indices,
                                                parameters->numcomps * sizeof(OPJ_UINT32));
                parameters->comps_indices[parameters->numcomps - 1] =
                    (OPJ_UINT32) atoi(iter);
                iter = strchr(iter, ',');
                if (iter == NULL) {
                    break;
                }
                iter ++;
            }
        }
        break;
            /* ----------------------------------------------------- */

            /* UniPG>> */
#ifdef USE_JPWL

        case 'W': {         /* activate JPWL correction */
            char *token = NULL;

            token = strtok(opj_optarg, ",");
            while (token != NULL) {

                /* search expected number of components */
                if (*token == 'c') {

                    static int compno;

                    compno = JPWL_EXPECTED_COMPONENTS; /* predefined no. of components */

                    if (sscanf(token, "c=%d", &compno) == 1) {
                        /* Specified */
                        if ((compno < 1) || (compno > 256)) {
                            fprintf(stderr, "ERROR -> invalid number of components c = %d\n", compno);
                            return 1;
                        }
                        parameters->jpwl_exp_comps = compno;

                    } else if (!strcmp(token, "c")) {
                        /* default */
                        parameters->jpwl_exp_comps = compno; /* auto for default size */

                    } else {
                        fprintf(stderr, "ERROR -> invalid components specified = %s\n", token);
                        return 1;
                    };
                }

                /* search maximum number of tiles */
                if (*token == 't') {

                    static int tileno;

                    tileno = JPWL_MAXIMUM_TILES; /* maximum no. of tiles */

                    if (sscanf(token, "t=%d", &tileno) == 1) {
                        /* Specified */
                        if ((tileno < 1) || (tileno > JPWL_MAXIMUM_TILES)) {
                            fprintf(stderr, "ERROR -> invalid number of tiles t = %d\n", tileno);
                            return 1;
                        }
                        parameters->jpwl_max_tiles = tileno;

                    } else if (!strcmp(token, "t")) {
                        /* default */
                        parameters->jpwl_max_tiles = tileno; /* auto for default size */

                    } else {
                        fprintf(stderr, "ERROR -> invalid tiles specified = %s\n", token);
                        return 1;
                    };
                }

                /* next token or bust */
                token = strtok(NULL, ",");
            };
            parameters->jpwl_correct = OPJ_TRUE;
            if (!(parameter->quiet)) {
                fprintf(stdout, "JPWL correction capability activated\n");
                fprintf(stdout, "- expecting %d components\n", parameters->jpwl_exp_comps);
            }
        }
        break;
#endif /* USE_JPWL */
        /* <<UniPG */

        /* ----------------------------------------------------- */
        case 'T': { /* Number of threads */
            if (strcmp(opj_optarg, "ALL_CPUS") == 0) {
                parameters->num_threads = opj_get_num_cpus();
                if (parameters->num_threads == 1) {
                    parameters->num_threads = 0;
                }
            } else {
                sscanf(opj_optarg, "%d", &parameters->num_threads);
            }
        }
        break;

        /* ----------------------------------------------------- */

        default:
            fprintf(stderr, "[WARNING] An invalid option has been ignored.\n");
            break;
        }
    } while (c != -1);

    /* check for possible errors */
    if (img_fol->set_imgdir == 1) {
        if (!(parameters->infile[0] == 0)) {
            fprintf(stderr, "[ERROR] options -ImgDir and -i cannot be used together.\n");
            return 1;
        }
        if (img_fol->set_out_format == 0) {
            fprintf(stderr,
                    "[ERROR] When -ImgDir is used, -OutFor <FORMAT> must be used.\n");
            fprintf(stderr, "Only one format allowed.\n"
                    "Valid format are PGM, PPM, PNM, PGX, BMP, TIF, TIFF, RAW, YUV, and TGA.\n");
            return 1;
        }
        if (!((parameters->outfile[0] == 0))) {
            fprintf(stderr, "[ERROR] options -ImgDir and -o cannot be used together.\n");
            return 1;
        }
    } else {
        if ((parameters->infile[0] == 0) || (parameters->outfile[0] == 0)) {
            fprintf(stderr, "[ERROR] Required parameters are missing\n"
                    "Example: %s -i image.j2k -o image.pgm\n", argv[0]);
            fprintf(stderr, "   Help: %s -h\n", argv[0]);
            return 1;
        }
    }

    return 0;
}

/* -------------------------------------------------------------------------- */
/**
 * Parse decoding area input values
 * separator = ","
 */
/* -------------------------------------------------------------------------- */
int parse_DA_values(char* inArg, unsigned int *DA_x0, unsigned int *DA_y0,
                    unsigned int *DA_x1, unsigned int *DA_y1)
{
    int it = 0;
    int values[4];
    char delims[] = ",";
    char *result = NULL;
    result = strtok(inArg, delims);

    while ((result != NULL) && (it < 4)) {
        values[it] = atoi(result);
        result = strtok(NULL, delims);
        it++;
    }

    if (it != 4) {
        return EXIT_FAILURE;
    } else {
        *DA_x0 = (OPJ_UINT32)values[0];
        *DA_y0 = (OPJ_UINT32)values[1];
        *DA_x1 = (OPJ_UINT32)values[2];
        *DA_y1 = (OPJ_UINT32)values[3];
        return EXIT_SUCCESS;
    }
}

static OPJ_FLOAT64 opj_clock(void)
{
#ifdef _WIN32
    /* _WIN32: use QueryPerformance (very accurate) */
    LARGE_INTEGER freq, t ;
    /* freq is the clock speed of the CPU */
    QueryPerformanceFrequency(&freq) ;
    /* cout << "freq = " << ((double) freq.QuadPart) << endl; */
    /* t is the high resolution performance counter (see MSDN) */
    QueryPerformanceCounter(& t) ;
    return freq.QuadPart ? ((OPJ_FLOAT64)t.QuadPart / (OPJ_FLOAT64)freq.QuadPart) :
           0;
#elif defined(__linux)
    struct timespec ts;
    clock_gettime(CLOCK_REALTIME, &ts);
    return ((OPJ_FLOAT64)ts.tv_sec + (OPJ_FLOAT64)ts.tv_nsec * 1e-9);
#else
    /* Unix : use resource usage */
    /* FIXME: this counts the total CPU time, instead of the user perceived time */
    struct rusage t;
    OPJ_FLOAT64 procTime;
    /* (1) Get the rusage data structure at this moment (man getrusage) */
    getrusage(0, &t);
    /* (2) What is the elapsed time ? - CPU time = User time + System time */
    /* (2a) Get the seconds */
    procTime = (OPJ_FLOAT64)(t.ru_utime.tv_sec + t.ru_stime.tv_sec);
    /* (2b) More precisely! Get the microseconds part ! */
    return (procTime + (OPJ_FLOAT64)(t.ru_utime.tv_usec + t.ru_stime.tv_usec) *
            1e-6) ;
#endif
}

/* -------------------------------------------------------------------------- */

/**
sample error callback expecting a FILE* client object
*/
static void error_callback(const char *msg, void *client_data)
{
    (void)client_data;
    fprintf(stdout, "[ERROR] %s", msg);
}
/**
sample warning callback expecting a FILE* client object
*/
static void warning_callback(const char *msg, void *client_data)
{
    (void)client_data;
    fprintf(stdout, "[WARNING] %s", msg);
}
/**
sample debug callback expecting no client object
*/
static void info_callback(const char *msg, void *client_data)
{
    (void)client_data;
    fprintf(stdout, "[INFO] %s", msg);
}
/**
sample quiet callback expecting no client object
*/
static void quiet_callback(const char *msg, void *client_data)
{
    (void)msg;
    (void)client_data;
}

static void set_default_parameters(opj_decompress_parameters* parameters)
{
    if (parameters) {
        memset(parameters, 0, sizeof(opj_decompress_parameters));

        /* default decoding parameters (command line specific) */
        parameters->decod_format = -1;
        parameters->cod_format = -1;

        /* default decoding parameters (core) */
        opj_set_default_decoder_parameters(&(parameters->core));
    }
}

static void destroy_parameters(opj_decompress_parameters* parameters)
{
    if (parameters) {
        if (parameters->precision) {
            free(parameters->precision);
            parameters->precision = NULL;
        }

        free(parameters->comps_indices);
        parameters->comps_indices = NULL;
    }
}

/* -------------------------------------------------------------------------- */

static opj_image_t* convert_gray_to_rgb(opj_image_t* original)
{
    OPJ_UINT32 compno;
    opj_image_t* l_new_image = NULL;
    opj_image_cmptparm_t* l_new_components = NULL;

    l_new_components = (opj_image_cmptparm_t*)malloc((original->numcomps + 2U) *
                       sizeof(opj_image_cmptparm_t));
    if (l_new_components == NULL) {
        fprintf(stderr,
                "ERROR -> opj_decompress: failed to allocate memory for RGB image!\n");
        opj_image_destroy(original);
        return NULL;
    }

    l_new_components[0].dx   = l_new_components[1].dx   = l_new_components[2].dx   =
                                   original->comps[0].dx;
    l_new_components[0].dy   = l_new_components[1].dy   = l_new_components[2].dy   =
                                   original->comps[0].dy;
    l_new_components[0].h    = l_new_components[1].h    = l_new_components[2].h    =
                                   original->comps[0].h;
    l_new_components[0].w    = l_new_components[1].w    = l_new_components[2].w    =
                                   original->comps[0].w;
    l_new_components[0].prec = l_new_components[1].prec = l_new_components[2].prec =
                                   original->comps[0].prec;
    l_new_components[0].sgnd = l_new_components[1].sgnd = l_new_components[2].sgnd =
                                   original->comps[0].sgnd;
    l_new_components[0].x0   = l_new_components[1].x0   = l_new_components[2].x0   =
                                   original->comps[0].x0;
    l_new_components[0].y0   = l_new_components[1].y0   = l_new_components[2].y0   =
                                   original->comps[0].y0;

    for (compno = 1U; compno < original->numcomps; ++compno) {
        l_new_components[compno + 2U].dx   = original->comps[compno].dx;
        l_new_components[compno + 2U].dy   = original->comps[compno].dy;
        l_new_components[compno + 2U].h    = original->comps[compno].h;
        l_new_components[compno + 2U].w    = original->comps[compno].w;
        l_new_components[compno + 2U].prec = original->comps[compno].prec;
        l_new_components[compno + 2U].sgnd = original->comps[compno].sgnd;
        l_new_components[compno + 2U].x0   = original->comps[compno].x0;
        l_new_components[compno + 2U].y0   = original->comps[compno].y0;
    }

    l_new_image = opj_image_create(original->numcomps + 2U, l_new_components,
                                   OPJ_CLRSPC_SRGB);
    free(l_new_components);
    if (l_new_image == NULL) {
        fprintf(stderr,
                "ERROR -> opj_decompress: failed to allocate memory for RGB image!\n");
        opj_image_destroy(original);
        return NULL;
    }

    l_new_image->x0 = original->x0;
    l_new_image->x1 = original->x1;
    l_new_image->y0 = original->y0;
    l_new_image->y1 = original->y1;

    l_new_image->comps[0].factor        = l_new_image->comps[1].factor        =
            l_new_image->comps[2].factor        = original->comps[0].factor;
    l_new_image->comps[0].alpha         = l_new_image->comps[1].alpha         =
            l_new_image->comps[2].alpha         = original->comps[0].alpha;
    l_new_image->comps[0].resno_decoded = l_new_image->comps[1].resno_decoded =
            l_new_image->comps[2].resno_decoded = original->comps[0].resno_decoded;

    memcpy(l_new_image->comps[0].data, original->comps[0].data,
           sizeof(OPJ_INT32) * original->comps[0].w * original->comps[0].h);
    memcpy(l_new_image->comps[1].data, original->comps[0].data,
           sizeof(OPJ_INT32) * original->comps[0].w * original->comps[0].h);
    memcpy(l_new_image->comps[2].data, original->comps[0].data,
           sizeof(OPJ_INT32) * original->comps[0].w * original->comps[0].h);

    for (compno = 1U; compno < original->numcomps; ++compno) {
        l_new_image->comps[compno + 2U].factor        = original->comps[compno].factor;
        l_new_image->comps[compno + 2U].alpha         = original->comps[compno].alpha;
        l_new_image->comps[compno + 2U].resno_decoded =
            original->comps[compno].resno_decoded;
        memcpy(l_new_image->comps[compno + 2U].data, original->comps[compno].data,
               sizeof(OPJ_INT32) * original->comps[compno].w * original->comps[compno].h);
    }
    opj_image_destroy(original);
    return l_new_image;
}

/* -------------------------------------------------------------------------- */

static opj_image_t* upsample_image_components(opj_image_t* original)
{
    opj_image_t* l_new_image = NULL;
    opj_image_cmptparm_t* l_new_components = NULL;
    OPJ_BOOL l_upsample_need = OPJ_FALSE;
    OPJ_UINT32 compno;

    for (compno = 0U; compno < original->numcomps; ++compno) {
        if (original->comps[compno].factor > 0U) {
            fprintf(stderr,
                    "ERROR -> opj_decompress: -upsample not supported with reduction\n");
            opj_image_destroy(original);
            return NULL;
        }
        if ((original->comps[compno].dx > 1U) || (original->comps[compno].dy > 1U)) {
            l_upsample_need = OPJ_TRUE;
            break;
        }
    }
    if (!l_upsample_need) {
        return original;
    }
    /* Upsample is needed */
    l_new_components = (opj_image_cmptparm_t*)malloc(original->numcomps * sizeof(
                           opj_image_cmptparm_t));
    if (l_new_components == NULL) {
        fprintf(stderr,
                "ERROR -> opj_decompress: failed to allocate memory for upsampled components!\n");
        opj_image_destroy(original);
        return NULL;
    }

    for (compno = 0U; compno < original->numcomps; ++compno) {
        opj_image_cmptparm_t* l_new_cmp = &(l_new_components[compno]);
        opj_image_comp_t*     l_org_cmp = &(original->comps[compno]);

        l_new_cmp->prec = l_org_cmp->prec;
        l_new_cmp->sgnd = l_org_cmp->sgnd;
        l_new_cmp->x0   = original->x0;
        l_new_cmp->y0   = original->y0;
        l_new_cmp->dx   = 1;
        l_new_cmp->dy   = 1;
        l_new_cmp->w    =
            l_org_cmp->w; /* should be original->x1 - original->x0 for dx==1 */
        l_new_cmp->h    =
            l_org_cmp->h; /* should be original->y1 - original->y0 for dy==0 */

        if (l_org_cmp->dx > 1U) {
            l_new_cmp->w = original->x1 - original->x0;
        }

        if (l_org_cmp->dy > 1U) {
            l_new_cmp->h = original->y1 - original->y0;
        }
    }

    l_new_image = opj_image_create(original->numcomps, l_new_components,
                                   original->color_space);
    free(l_new_components);
    if (l_new_image == NULL) {
        fprintf(stderr,
                "ERROR -> opj_decompress: failed to allocate memory for upsampled components!\n");
        opj_image_destroy(original);
        return NULL;
    }

    l_new_image->x0 = original->x0;
    l_new_image->x1 = original->x1;
    l_new_image->y0 = original->y0;
    l_new_image->y1 = original->y1;

    for (compno = 0U; compno < original->numcomps; ++compno) {
        opj_image_comp_t* l_new_cmp = &(l_new_image->comps[compno]);
        opj_image_comp_t* l_org_cmp = &(original->comps[compno]);

        l_new_cmp->factor        = l_org_cmp->factor;
        l_new_cmp->alpha         = l_org_cmp->alpha;
        l_new_cmp->resno_decoded = l_org_cmp->resno_decoded;

        if ((l_org_cmp->dx > 1U) || (l_org_cmp->dy > 1U)) {
            const OPJ_INT32* l_src = l_org_cmp->data;
            OPJ_INT32*       l_dst = l_new_cmp->data;
            OPJ_UINT32 y;
            OPJ_UINT32 xoff, yoff;

            /* need to take into account dx & dy */
            xoff = l_org_cmp->dx * l_org_cmp->x0 -  original->x0;
            yoff = l_org_cmp->dy * l_org_cmp->y0 -  original->y0;
            if ((xoff >= l_org_cmp->dx) || (yoff >= l_org_cmp->dy)) {
                fprintf(stderr,
                        "ERROR -> opj_decompress: Invalid image/component parameters found when upsampling\n");
                opj_image_destroy(original);
                opj_image_destroy(l_new_image);
                return NULL;
            }

            for (y = 0U; y < yoff; ++y) {
                memset(l_dst, 0U, l_new_cmp->w * sizeof(OPJ_INT32));
                l_dst += l_new_cmp->w;
            }

            if (l_new_cmp->h > (l_org_cmp->dy -
                                1U)) { /* check subtraction overflow for really small images */
                for (; y < l_new_cmp->h - (l_org_cmp->dy - 1U); y += l_org_cmp->dy) {
                    OPJ_UINT32 x, dy;
                    OPJ_UINT32 xorg;

                    xorg = 0U;
                    for (x = 0U; x < xoff; ++x) {
                        l_dst[x] = 0;
                    }
                    if (l_new_cmp->w > (l_org_cmp->dx -
                                        1U)) { /* check subtraction overflow for really small images */
                        for (; x < l_new_cmp->w - (l_org_cmp->dx - 1U); x += l_org_cmp->dx, ++xorg) {
                            OPJ_UINT32 dx;
                            for (dx = 0U; dx < l_org_cmp->dx; ++dx) {
                                l_dst[x + dx] = l_src[xorg];
                            }
                        }
                    }
                    for (; x < l_new_cmp->w; ++x) {
                        l_dst[x] = l_src[xorg];
                    }
                    l_dst += l_new_cmp->w;

                    for (dy = 1U; dy < l_org_cmp->dy; ++dy) {
                        memcpy(l_dst, l_dst - l_new_cmp->w, l_new_cmp->w * sizeof(OPJ_INT32));
                        l_dst += l_new_cmp->w;
                    }
                    l_src += l_org_cmp->w;
                }
            }
            if (y < l_new_cmp->h) {
                OPJ_UINT32 x;
                OPJ_UINT32 xorg;

                xorg = 0U;
                for (x = 0U; x < xoff; ++x) {
                    l_dst[x] = 0;
                }
                if (l_new_cmp->w > (l_org_cmp->dx -
                                    1U)) { /* check subtraction overflow for really small images */
                    for (; x < l_new_cmp->w - (l_org_cmp->dx - 1U); x += l_org_cmp->dx, ++xorg) {
                        OPJ_UINT32 dx;
                        for (dx = 0U; dx < l_org_cmp->dx; ++dx) {
                            l_dst[x + dx] = l_src[xorg];
                        }
                    }
                }
                for (; x < l_new_cmp->w; ++x) {
                    l_dst[x] = l_src[xorg];
                }
                l_dst += l_new_cmp->w;
                ++y;
                for (; y < l_new_cmp->h; ++y) {
                    memcpy(l_dst, l_dst - l_new_cmp->w, l_new_cmp->w * sizeof(OPJ_INT32));
                    l_dst += l_new_cmp->w;
                }
            }
        } else {
            memcpy(l_new_cmp->data, l_org_cmp->data,
                   sizeof(OPJ_INT32) * l_org_cmp->w * l_org_cmp->h);
        }
    }
    opj_image_destroy(original);
    return l_new_image;
}

/* -------------------------------------------------------------------------- */
/**
 * OPJ_DECOMPRESS MAIN
 */
/* -------------------------------------------------------------------------- */
int main(int argc, char **argv)
{
    opj_decompress_parameters parameters;           /* decompression parameters */

    unsigned int num_images, imageno;
    img_fol_t img_fol;
    dircnt_t *dirptr = NULL;
    int failed = 0;
    OPJ_FLOAT64 t, tCumulative = 0;
    OPJ_UINT32 numDecompressedImages = 0;
    OPJ_UINT32 cp_reduce;

    /* set decoding parameters to default values */
    set_default_parameters(&parameters);

    /* Initialize img_fol */
    memset(&img_fol, 0, sizeof(img_fol_t));

    /* parse input and get user encoding parameters */
    if (parse_cmdline_decoder(argc, argv, &parameters, &img_fol) == 1) {
        failed = 1;
        goto fin;
    }

    cp_reduce = parameters.core.cp_reduce;
    if (getenv("USE_OPJ_SET_DECODED_RESOLUTION_FACTOR") != NULL) {
        /* For debugging/testing purposes, do not set the cp_reduce member */
        /* if USE_OPJ_SET_DECODED_RESOLUTION_FACTOR is defined, but used */
        /* the opj_set_decoded_resolution_factor() API instead */
        parameters.core.cp_reduce = 0;
    }


    /* Initialize reading of directory */
    if (img_fol.set_imgdir == 1) {
        unsigned int it_image;
        num_images = get_num_images(img_fol.imgdirpath);
        if (num_images == 0) {
            fprintf(stderr, "Folder is empty\n");
            failed = 1;
            goto fin;
        }
        dirptr = (dircnt_t*)calloc(1, sizeof(dircnt_t));
        if (!dirptr) {
            destroy_parameters(&parameters);
            return EXIT_FAILURE;
        }
        /* Stores at max 10 image file names */
        dirptr->filename_buf = calloc((size_t) num_images, sizeof(char) * OPJ_PATH_LEN);
        if (!dirptr->filename_buf) {
            failed = 1;
            goto fin;
        }

        dirptr->filename = (char**) calloc((size_t) num_images, sizeof(char*));

        if (!dirptr->filename) {
            failed = 1;
            goto fin;
        }
        for (it_image = 0; it_image < num_images; it_image++) {
            dirptr->filename[it_image] = dirptr->filename_buf + (size_t)it_image *
                                         OPJ_PATH_LEN;
        }

        if (load_images(dirptr, img_fol.imgdirpath) == 1) {
            failed = 1;
            goto fin;
        }

    } else {
        num_images = 1;
    }

    /*Decoding image one by one*/
    for (imageno = 0; imageno < num_images ; imageno++)  {
        opj_image_t* image = NULL;
        opj_stream_t *l_stream = NULL;              /* Stream */
        opj_codec_t* l_codec = NULL;                /* Handle to a decompressor */
        opj_codestream_index_t* cstr_index = NULL;

        if (!parameters.quiet) {
            fprintf(stderr, "\n");
        }

        if (img_fol.set_imgdir == 1) {
            if (get_next_file(imageno, dirptr, &img_fol, &parameters)) {
                fprintf(stderr, "skipping file...\n");
                destroy_parameters(&parameters);
                continue;
            }
        }

        /* read the input file and put it in memory */
        /* ---------------------------------------- */

        l_stream = opj_stream_create_default_file_stream(parameters.infile, 1);
        if (!l_stream) {
            fprintf(stderr, "ERROR -> failed to create the stream from the file %s\n",
                    parameters.infile);
            failed = 1;
            goto fin;
        }

        /* decode the JPEG2000 stream */
        /* ---------------------- */

        switch (parameters.decod_format) {
        case J2K_CFMT: { /* JPEG-2000 codestream */
            /* Get a decoder handle */
            l_codec = opj_create_decompress(OPJ_CODEC_J2K);
            break;
        }
        case JP2_CFMT: { /* JPEG 2000 compressed image data */
            /* Get a decoder handle */
            l_codec = opj_create_decompress(OPJ_CODEC_JP2);
            break;
        }
        case JPT_CFMT: { /* JPEG 2000, JPIP */
            /* Get a decoder handle */
            l_codec = opj_create_decompress(OPJ_CODEC_JPT);
            break;
        }
        default:
            fprintf(stderr, "skipping file..\n");
            destroy_parameters(&parameters);
            opj_stream_destroy(l_stream);
            continue;
        }

        if (parameters.quiet) {
            /* Set all callbacks to quiet */
            opj_set_info_handler(l_codec, quiet_callback, 00);
            opj_set_warning_handler(l_codec, quiet_callback, 00);
            opj_set_error_handler(l_codec, quiet_callback, 00);
        } else {
            /* catch events using our callbacks and give a local context */
            opj_set_info_handler(l_codec, info_callback, 00);
            opj_set_warning_handler(l_codec, warning_callback, 00);
            opj_set_error_handler(l_codec, error_callback, 00);
        }


        t = opj_clock();

        /* Setup the decoder decoding parameters using user parameters */
        if (!opj_setup_decoder(l_codec, &(parameters.core))) {
            fprintf(stderr, "ERROR -> opj_decompress: failed to setup the decoder\n");
            opj_stream_destroy(l_stream);
            opj_destroy_codec(l_codec);
            failed = 1;
            goto fin;
        }

        /* Disable strict mode if we want to decode partial codestreams. */
        if (parameters.allow_partial &&
                !opj_decoder_set_strict_mode(l_codec, OPJ_FALSE)) {
            fprintf(stderr, "ERROR -> opj_decompress: failed to disable strict mode\n");
            opj_stream_destroy(l_stream);
            opj_destroy_codec(l_codec);
            failed = 1;
            goto fin;
        }

        if (parameters.num_threads >= 1 &&
                !opj_codec_set_threads(l_codec, parameters.num_threads)) {
            fprintf(stderr, "ERROR -> opj_decompress: failed to set number of threads\n");
            opj_stream_destroy(l_stream);
            opj_destroy_codec(l_codec);
            failed = 1;
            goto fin;
        }

        /* Read the main header of the codestream and if necessary the JP2 boxes*/
        if (! opj_read_header(l_stream, l_codec, &image)) {
            fprintf(stderr, "ERROR -> opj_decompress: failed to read the header\n");
            opj_stream_destroy(l_stream);
            opj_destroy_codec(l_codec);
            opj_image_destroy(image);
            failed = 1;
            goto fin;
        }

        if (parameters.numcomps) {
            if (! opj_set_decoded_components(l_codec,
                                             parameters.numcomps,
                                             parameters.comps_indices,
                                             OPJ_FALSE)) {
                fprintf(stderr,
                        "ERROR -> opj_decompress: failed to set the component indices!\n");
                opj_destroy_codec(l_codec);
                opj_stream_destroy(l_stream);
                opj_image_destroy(image);
                failed = 1;
                goto fin;
            }
        }

        if (getenv("USE_OPJ_SET_DECODED_RESOLUTION_FACTOR") != NULL) {
            /* For debugging/testing purposes, and also an illustration on how to */
            /* use the alternative API opj_set_decoded_resolution_factor() instead */
            /* of setting parameters.cp_reduce */
            if (! opj_set_decoded_resolution_factor(l_codec, cp_reduce)) {
                fprintf(stderr,
                        "ERROR -> opj_decompress: failed to set the resolution factor tile!\n");
                opj_destroy_codec(l_codec);
                opj_stream_destroy(l_stream);
                opj_image_destroy(image);
                failed = 1;
                goto fin;
            }
        }

        if (!parameters.nb_tile_to_decode) {
            if (getenv("SKIP_OPJ_SET_DECODE_AREA") != NULL &&
                    parameters.DA_x0 == 0 &&
                    parameters.DA_y0 == 0 &&
                    parameters.DA_x1 == 0 &&
                    parameters.DA_y1 == 0) {
                /* For debugging/testing purposes, */
                /* do nothing if SKIP_OPJ_SET_DECODE_AREA env variable */
                /* is defined and no decoded area has been set */
            }
            /* Optional if you want decode the entire image */
            else if (!opj_set_decode_area(l_codec, image, (OPJ_INT32)parameters.DA_x0,
                                          (OPJ_INT32)parameters.DA_y0, (OPJ_INT32)parameters.DA_x1,
                                          (OPJ_INT32)parameters.DA_y1)) {
                fprintf(stderr, "ERROR -> opj_decompress: failed to set the decoded area\n");
                opj_stream_destroy(l_stream);
                opj_destroy_codec(l_codec);
                opj_image_destroy(image);
                failed = 1;
                goto fin;
            }

            /* Get the decoded image */
            if (!(opj_decode(l_codec, l_stream, image) &&
                    opj_end_decompress(l_codec,   l_stream))) {
                fprintf(stderr, "ERROR -> opj_decompress: failed to decode image!\n");
                opj_destroy_codec(l_codec);
                opj_stream_destroy(l_stream);
                opj_image_destroy(image);
                failed = 1;
                goto fin;
            }
        } else {
            if (!(parameters.DA_x0 == 0 &&
                    parameters.DA_y0 == 0 &&
                    parameters.DA_x1 == 0 &&
                    parameters.DA_y1 == 0)) {
                if (!(parameters.quiet)) {
                    fprintf(stderr, "WARNING: -d option ignored when used together with -t\n");
                }
            }

            if (!opj_get_decoded_tile(l_codec, l_stream, image, parameters.tile_index)) {
                fprintf(stderr, "ERROR -> opj_decompress: failed to decode tile!\n");
                opj_destroy_codec(l_codec);
                opj_stream_destroy(l_stream);
                opj_image_destroy(image);
                failed = 1;
                goto fin;
            }
            if (!(parameters.quiet)) {
                fprintf(stdout, "tile %d is decoded!\n\n", parameters.tile_index);
            }
        }

        tCumulative += opj_clock() - t;
        numDecompressedImages++;

        /* Close the byte stream */
        opj_stream_destroy(l_stream);

        if (image->color_space != OPJ_CLRSPC_SYCC
                && image->numcomps == 3 && image->comps[0].dx == image->comps[0].dy
                && image->comps[1].dx != 1) {
            image->color_space = OPJ_CLRSPC_SYCC;
        } else if (image->numcomps <= 2) {
            image->color_space = OPJ_CLRSPC_GRAY;
        }

        if (image->color_space == OPJ_CLRSPC_SYCC) {
            color_sycc_to_rgb(image);
        } else if ((image->color_space == OPJ_CLRSPC_CMYK) &&
                   (parameters.cod_format != TIF_DFMT)) {
            color_cmyk_to_rgb(image);
        } else if (image->color_space == OPJ_CLRSPC_EYCC) {
            color_esycc_to_rgb(image);
        }

        if (image->icc_profile_buf) {
#if defined(OPJ_HAVE_LIBLCMS1) || defined(OPJ_HAVE_LIBLCMS2)
            if (image->icc_profile_len) {
                color_apply_icc_profile(image);
            } else {
                color_cielab_to_rgb(image);
            }
#endif
            free(image->icc_profile_buf);
            image->icc_profile_buf = NULL;
            image->icc_profile_len = 0;
        }

        /* Force output precision */
        /* ---------------------- */
        if (parameters.precision != NULL) {
            OPJ_UINT32 compno;
            for (compno = 0; compno < image->numcomps; ++compno) {
                OPJ_UINT32 precno = compno;
                OPJ_UINT32 prec;

                if (precno >= parameters.nb_precision) {
                    precno = parameters.nb_precision - 1U;
                }

                prec = parameters.precision[precno].prec;
                if (prec == 0) {
                    prec = image->comps[compno].prec;
                }

                switch (parameters.precision[precno].mode) {
                case OPJ_PREC_MODE_CLIP:
                    clip_component(&(image->comps[compno]), prec);
                    break;
                case OPJ_PREC_MODE_SCALE:
                    scale_component(&(image->comps[compno]), prec);
                    break;
                default:
                    break;
                }

            }
        }

        /* Upsample components */
        /* ------------------- */
        if (parameters.upsample) {
            image = upsample_image_components(image);
            if (image == NULL) {
                fprintf(stderr,
                        "ERROR -> opj_decompress: failed to upsample image components!\n");
                opj_destroy_codec(l_codec);
                failed = 1;
                goto fin;
            }
        }

        /* Force RGB output */
        /* ---------------- */
        if (parameters.force_rgb) {
            switch (image->color_space) {
            case OPJ_CLRSPC_SRGB:
                break;
            case OPJ_CLRSPC_GRAY:
                image = convert_gray_to_rgb(image);
                break;
            default:
                fprintf(stderr,
                        "ERROR -> opj_decompress: don't know how to convert image to RGB colorspace!\n");
                opj_image_destroy(image);
                image = NULL;
                break;
            }
            if (image == NULL) {
                fprintf(stderr, "ERROR -> opj_decompress: failed to convert to RGB image!\n");
                opj_destroy_codec(l_codec);
                failed = 1;
                goto fin;
            }
        }

        /* create output image */
        /* ------------------- */
        switch (parameters.cod_format) {
        case PXM_DFMT:          /* PNM PGM PPM */
            if (imagetopnm(image, parameters.outfile, parameters.split_pnm)) {
                fprintf(stderr, "[ERROR] Outfile %s not generated\n", parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;

        case PGX_DFMT:          /* PGX */
            if (imagetopgx(image, parameters.outfile)) {
                fprintf(stderr, "[ERROR] Outfile %s not generated\n", parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;

        case BMP_DFMT:          /* BMP */
            if (imagetobmp(image, parameters.outfile)) {
                fprintf(stderr, "[ERROR] Outfile %s not generated\n", parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;
#ifdef OPJ_HAVE_LIBTIFF
        case TIF_DFMT:          /* TIF(F) */
            if (imagetotif(image, parameters.outfile)) {
                fprintf(stderr, "[ERROR] Outfile %s not generated\n", parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;
#endif /* OPJ_HAVE_LIBTIFF */
        case RAW_DFMT:          /* RAW */
            if (imagetoraw(image, parameters.outfile)) {
                fprintf(stderr,
                        "[ERROR] Error generating raw or yuv file. Outfile %s not generated\n",
                        parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;

        case RAWL_DFMT:         /* RAWL */
            if (imagetorawl(image, parameters.outfile)) {
                fprintf(stderr,
                        "[ERROR] Error generating rawl file. Outfile %s not generated\n",
                        parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;

        case TGA_DFMT:          /* TGA */
            if (imagetotga(image, parameters.outfile)) {
                fprintf(stderr, "[ERROR] Error generating tga file. Outfile %s not generated\n",
                        parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;
#ifdef OPJ_HAVE_LIBPNG
        case PNG_DFMT:          /* PNG */
            if (imagetopng(image, parameters.outfile)) {
                fprintf(stderr, "[ERROR] Error generating png file. Outfile %s not generated\n",
                        parameters.outfile);
                failed = 1;
            } else if (!(parameters.quiet)) {
                fprintf(stdout, "[INFO] Generated Outfile %s\n", parameters.outfile);
            }
            break;
#endif /* OPJ_HAVE_LIBPNG */
        /* Can happen if output file is TIF(F) or PNG
         * and OPJ_HAVE_LIBTIF or OPJ_HAVE_LIBPNG is undefined
        */
        default:
            fprintf(stderr, "[ERROR] Outfile %s not generated\n", parameters.outfile);
            failed = 1;
        }

        /* free remaining structures */
        if (l_codec) {
            opj_destroy_codec(l_codec);
        }


        /* free image data structure */
        opj_image_destroy(image);

        /* destroy the codestream index */
        opj_destroy_cstr_index(&cstr_index);

        if (failed) {
            (void)remove(parameters.outfile);    /* ignore return value */
        }
    }
fin:
    destroy_parameters(&parameters);
    if (failed && img_fol.imgdirpath) {
        free(img_fol.imgdirpath);
    }
    if (dirptr) {
        if (dirptr->filename) {
            free(dirptr->filename);
        }
        if (dirptr->filename_buf) {
            free(dirptr->filename_buf);
        }
        free(dirptr);
    }
    if (numDecompressedImages && !failed && !(parameters.quiet)) {
        fprintf(stdout, "decode time: %d ms\n",
                (int)((tCumulative * 1000.0) / (OPJ_FLOAT64)numDecompressedImages));
    }
    return failed ? EXIT_FAILURE : EXIT_SUCCESS;
}
/*end main()*/