/* * Copyright (c) 2001-2003, David Janssens * Copyright (c) 2002-2003, Yannick Verschueren * Copyright (c) 2003-2005, Francois Devaux and Antonin Descampe * Copyright (c) 2005, Hervcalloc Drolon, FreeImage Team * Copyright (c) 2002-2005, Communications and remote sensing Laboratory, Universite catholique de Louvain, Belgium * Copyright (c) 2006, Mónica Díez García, Image Processing Laboratory, University of Valladolid, Spain * 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 #include #include #include #include "../libjp3dvm/openjpeg3d.h" #include "getopt.h" #include "convert.h" #ifdef _WIN32 #include #else #define stricmp strcasecmp #define strnicmp strncasecmp #endif /* _WIN32 */ /* ----------------------------------------------------------------------- */ static double calc_PSNR(opj_volume_t *original, opj_volume_t *decoded) { int max, i, k, compno = 0, size; double sum, total = 0; int global = 1; max = (original->comps[compno].prec <= 8) ? 255 : (1 << original->comps[compno].prec) - 1; if (global) { size = (original->x1 - original->x0) * (original->y1 - original->y0) * (original->z1 - original->z0); for (compno = 0; compno < original->numcomps; compno++) { for(sum = 0, i = 0; i < size; ++i) { if ((decoded->comps[compno].data[i] < 0) || (decoded->comps[compno].data[i] > max)) fprintf(stdout,"[WARNING] Data out of range during PSNR computing...\n"); else sum += (original->comps[compno].data[i] - decoded->comps[compno].data[i]) * (original->comps[compno].data[i] - decoded->comps[compno].data[i]); } } sum /= size; total = ((sum==0.0) ? 0.0 : 10 * log10(max * max / sum)); } else { size = (original->x1 - original->x0) * (original->y1 - original->y0); for (k = 0; k < original->z1 - original->z0; k++) { int offset = k * size; for (sum = 0, compno = 0; compno < original->numcomps; compno++) { for(i = 0; i < size; ++i) { if ((decoded->comps[compno].data[i + offset] < 0) || (decoded->comps[compno].data[i + offset] > max)) fprintf(stdout,"[WARNING] Data out of range during PSNR computing...\n"); else sum += (original->comps[compno].data[i + offset] - decoded->comps[compno].data[i + offset]) * (original->comps[compno].data[i + offset] - decoded->comps[compno].data[i + offset]); } } sum /= size; total = total + ((sum==0.0) ? 0.0 : 10 * log10(max * max / sum)); } } if(total == 0) /* perfect reconstruction, PSNR should return infinity */ return -1.0; return total; //return 20 * log10((max - 1) / sqrt(sum)); } static double calc_SSIM(opj_volume_t *original, opj_volume_t *decoded) { int max, i, compno = 0, size, sizeM; double sum; double mux = 0.0, muy = 0.0, sigmax = 0.0, sigmay = 0.0, sigmaxy = 0.0, structx = 0.0, structy = 0.0; double lcomp,ccomp,scomp; double C1,C2,C3; max = (original->comps[compno].prec <= 8) ? 255 : (1 << original->comps[compno].prec) - 1; size = (original->x1 - original->x0) * (original->y1 - original->y0) * (original->z1 - original->z0); //MSSIM // sizeM = size / (original->z1 - original->z0); sizeM = size; for(sum = 0, i = 0; i < sizeM; ++i) { // First, the luminance of each signal is compared. mux += original->comps[compno].data[i]; muy += decoded->comps[compno].data[i]; } mux /= sizeM; muy /= sizeM; //We use the standard deviation (the square root of variance) as an estimate of the signal contrast. for(sum = 0, i = 0; i < sizeM; ++i) { // First, the luminance of each signal is compared. sigmax += (original->comps[compno].data[i] - mux) * (original->comps[compno].data[i] - mux); sigmay += (decoded->comps[compno].data[i] - muy) * (decoded->comps[compno].data[i] - muy); sigmaxy += (original->comps[compno].data[i] - mux) * (decoded->comps[compno].data[i] - muy); } sigmax /= sizeM - 1; sigmay /= sizeM - 1; sigmaxy /= sizeM - 1; sigmax = sqrt(sigmax); sigmay = sqrt(sigmay); sigmaxy = sqrt(sigmaxy); //Third, the signal is normalized (divided) by its own standard deviation, //so that the two signals being compared have unit standard deviation. //Luminance comparison C1 = (0.01 * max) * (0.01 * max); lcomp = ((2 * mux * muy) + C1)/((mux*mux) + (muy*mux) + C1); //Constrast comparison C2 = (0.03 * max) * (0.03 * max); ccomp = ((2 * sigmax * sigmay) + C2)/((sigmax*sigmax) + (sigmay*sigmay) + C2); //Structure comparison C3 = C2 / 2; scomp = (sigmaxy + C3) / (sigmax * sigmay + C3); //Similarity measure sum = lcomp * ccomp * scomp; return sum; } void decode_help_display() { fprintf(stdout,"HELP\n----\n\n"); fprintf(stdout,"- the -h option displays this help information on screen\n\n"); fprintf(stdout,"List of parameters for the JPEG 2000 encoder:\n"); fprintf(stdout,"\n"); fprintf(stdout," Required arguments \n"); fprintf(stdout," ---------------------------- \n"); fprintf(stdout," -i ( *.jp3d, *.j3d )\n"); fprintf(stdout," Currently accepts J3D-files. The file type is identified based on its suffix.\n"); fprintf(stdout," -o ( *.pgx, *.bin )\n"); fprintf(stdout," Currently accepts PGX-files and BIN-files. Binary data is written to the file (not ascii). \n"); fprintf(stdout," If a PGX filename is given, there will be as many output files as slices; \n"); fprintf(stdout," an indice starting from 0 will then be appended to the output filename,\n"); fprintf(stdout," just before the \"pgx\" extension.\n"); fprintf(stdout," -m ( *.img ) \n"); fprintf(stdout," Required only for BIN-files. Ascii data of volume characteristics is written. \n"); fprintf(stdout,"\n"); fprintf(stdout," Optional \n"); fprintf(stdout," ---------------------------- \n"); fprintf(stdout," -h \n "); fprintf(stdout," Display the help information\n"); fprintf(stdout," -r \n"); fprintf(stdout," Set the number of highest resolution levels to be discarded on each dimension. \n"); fprintf(stdout," The volume resolution is effectively divided by 2 to the power of the\n"); fprintf(stdout," number of discarded levels. The reduce factor is limited by the\n"); fprintf(stdout," smallest total number of decomposition levels among tiles.\n"); fprintf(stdout," -l \n"); fprintf(stdout," Set the maximum number of quality layers to decode. If there are\n"); fprintf(stdout," less quality layers than the specified number, all the quality layers\n"); fprintf(stdout," are decoded. \n"); fprintf(stdout," -O original-file \n"); fprintf(stdout," This option offers the possibility to compute some quality results \n"); fprintf(stdout," for the decompressed volume, like the PSNR value achieved or the global SSIM value. \n"); fprintf(stdout," Needs the original file in order to compare with the new one.\n"); fprintf(stdout," NOTE: Only valid when -r option is 0,0,0 (both original and decompressed volumes have same resolutions) \n"); fprintf(stdout," NOTE: If original file is .BIN file, the volume characteristics file shall be defined with the -m option. \n"); fprintf(stdout," (i.e. -O original-BIN-file -m original-IMG-file) \n"); fprintf(stdout," -BE \n"); fprintf(stdout," Define that the recovered volume data will be saved with big endian byte order.\n"); fprintf(stdout," By default, little endian byte order is used.\n"); fprintf(stdout,"\n"); } /* -------------------------------------------------------------------------- */ int get_file_format(char *filename) { int i; static const char *extension[] = {"pgx", "bin", "j3d", "jp3d", "j2k", "img"}; static const int format[] = { PGX_DFMT, BIN_DFMT, J3D_CFMT, J3D_CFMT, J2K_CFMT, IMG_DFMT}; char * ext = strrchr(filename, '.'); if(ext) { ext++; for(i = 0; i < sizeof(format) / sizeof(format[0]); i++) { if(strnicmp(ext, extension[i], 3) == 0) { return format[i]; } } } return -1; } /* -------------------------------------------------------------------------- */ int parse_cmdline_decoder(int argc, char **argv, opj_dparameters_t *parameters) { /* parse the command line */ while (1) { int c = getopt(argc, argv, "i:o:O:r:l:B:m:h"); if (c == -1) break; switch (c) { case 'i': /* input file */ { char *infile = optarg; parameters->decod_format = get_file_format(infile); switch(parameters->decod_format) { case J3D_CFMT: case J2K_CFMT: break; default: fprintf(stdout, "[ERROR] Unknown format for infile %s [only *.j3d]!! \n", infile); return 1; break; } strncpy(parameters->infile, infile, MAX_PATH); fprintf(stdout, "[INFO] Infile: %s \n", parameters->infile); } break; case 'm': /* img file */ { char *imgfile = optarg; int imgformat = get_file_format(imgfile); switch(imgformat) { case IMG_DFMT: break; default: fprintf(stdout, "[ERROR] Unrecognized format for imgfile : %s [accept only *.img] !!\n\n", imgfile); return 1; break; } strncpy(parameters->imgfile, imgfile, MAX_PATH); fprintf(stdout, "[INFO] Imgfile: %s Format: %d\n", parameters->imgfile, imgformat); } break; /* ----------------------------------------------------- */ case 'o': /* output file */ { char *outfile = optarg; parameters->cod_format = get_file_format(outfile); switch(parameters->cod_format) { case PGX_DFMT: case BIN_DFMT: break; default: fprintf(stdout, "[ERROR] Unrecognized format for outfile : %s [accept only *.pgx or *.bin] !!\n\n", outfile); return 1; break; } strncpy(parameters->outfile, outfile, MAX_PATH); fprintf(stdout, "[INFO] Outfile: %s \n", parameters->outfile); } break; /* ----------------------------------------------------- */ case 'O': /* Original image for PSNR computing */ { char *original = optarg; parameters->orig_format = get_file_format(original); switch(parameters->orig_format) { case PGX_DFMT: case BIN_DFMT: break; default: fprintf(stdout, "[ERROR] Unrecognized format for original file : %s [accept only *.pgx or *.bin] !!\n\n", original); return 1; break; } strncpy(parameters->original, original, MAX_PATH); fprintf(stdout, "[INFO] Original file: %s \n", parameters->original); } break; /* ----------------------------------------------------- */ case 'r': /* reduce option */ { //sscanf(optarg, "%d, %d, %d", ¶meters->cp_reduce[0], ¶meters->cp_reduce[1], ¶meters->cp_reduce[2]); int aux; aux = sscanf(optarg, "%d,%d,%d", ¶meters->cp_reduce[0], ¶meters->cp_reduce[1], ¶meters->cp_reduce[2]); if (aux == 2) parameters->cp_reduce[2] = 0; else if (aux == 1) { parameters->cp_reduce[1] = parameters->cp_reduce[0]; parameters->cp_reduce[2] = 0; }else if (aux == 0){ parameters->cp_reduce[0] = 0; parameters->cp_reduce[1] = 0; parameters->cp_reduce[2] = 0; } } break; /* ----------------------------------------------------- */ case 'l': /* layering option */ { sscanf(optarg, "%d", ¶meters->cp_layer); } break; /* ----------------------------------------------------- */ case 'B': /* BIGENDIAN vs. LITTLEENDIAN */ { parameters->bigendian = 1; } break; /* ----------------------------------------------------- */ case 'L': /* BIGENDIAN vs. LITTLEENDIAN */ { parameters->decod_format = LSE_CFMT; } break; /* ----------------------------------------------------- */ case 'h': /* display an help description */ { decode_help_display(); return 1; } break; /* ----------------------------------------------------- */ default: fprintf(stdout,"[WARNING] This option is not valid \"-%c %s\"\n",c, optarg); break; } } /* check for possible errors */ if((parameters->infile[0] == 0) || (parameters->outfile[0] == 0)) { fprintf(stdout,"[ERROR] At least one required argument is missing\n Check jp3d_to_volume -help for usage information\n"); return 1; } return 0; } /* -------------------------------------------------------------------------- */ /** sample error callback expecting a FILE* client object */ void error_callback(const char *msg, void *client_data) { FILE *stream = (FILE*)client_data; fprintf(stream, "[ERROR] %s", msg); } /** sample warning callback expecting a FILE* client object */ void warning_callback(const char *msg, void *client_data) { FILE *stream = (FILE*)client_data; fprintf(stream, "[WARNING] %s", msg); } /** sample debug callback expecting no client object */ void info_callback(const char *msg, void *client_data) { fprintf(stdout, "[INFO] %s", msg); } /* -------------------------------------------------------------------------- */ int main(int argc, char **argv) { opj_dparameters_t parameters; /* decompression parameters */ opj_event_mgr_t event_mgr; /* event manager */ opj_volume_t *volume = NULL; opj_volume_t *original = NULL; opj_cparameters_t cparameters; /* original parameters */ FILE *fsrc = NULL; unsigned char *src = NULL; int file_length; int decodeok; double psnr, ssim; opj_dinfo_t* dinfo = NULL; /* handle to a decompressor */ opj_cio_t *cio = NULL; /* configure the event callbacks (not required) */ memset(&event_mgr, 0, sizeof(opj_event_mgr_t)); event_mgr.error_handler = error_callback; event_mgr.warning_handler = warning_callback; event_mgr.info_handler = info_callback; /* set decoding parameters to default values */ opj_set_default_decoder_parameters(¶meters); /* parse input and get user decoding parameters */ strcpy(parameters.original,"NULL"); strcpy(parameters.imgfile,"NULL"); if(parse_cmdline_decoder(argc, argv, ¶meters) == 1) { return 0; } /* read the input file and put it in memory */ /* ---------------------------------------- */ fprintf(stdout, "[INFO] Loading %s file \n",parameters.decod_format==J3D_CFMT ? ".jp3d" : ".j2k"); fsrc = fopen(parameters.infile, "rb"); if (!fsrc) { fprintf(stdout, "[ERROR] Failed to open %s for reading\n", parameters.infile); return 1; } fseek(fsrc, 0, SEEK_END); file_length = ftell(fsrc); fseek(fsrc, 0, SEEK_SET); src = (unsigned char *) malloc(file_length); fread(src, 1, file_length, fsrc); fclose(fsrc); /* decode the code-stream */ /* ---------------------- */ if (parameters.decod_format == J3D_CFMT || parameters.decod_format == J2K_CFMT) { /* get a JP3D or J2K decoder handle */ if (parameters.decod_format == J3D_CFMT) dinfo = opj_create_decompress(CODEC_J3D); else if (parameters.decod_format == J2K_CFMT) dinfo = opj_create_decompress(CODEC_J2K); /* catch events using our callbacks and give a local context */ opj_set_event_mgr((opj_common_ptr)dinfo, &event_mgr, stderr); /* setup the decoder decoding parameters using user parameters */ opj_setup_decoder(dinfo, ¶meters); /* open a byte stream */ cio = opj_cio_open((opj_common_ptr)dinfo, src, file_length); /* decode the stream and fill the volume structure */ volume = opj_decode(dinfo, cio); if(!volume) { fprintf(stdout, "[ERROR] jp3d_to_volume: failed to decode volume!\n"); opj_destroy_decompress(dinfo); opj_cio_close(cio); return 1; } /* close the byte stream */ opj_cio_close(cio); } /* free the memory containing the code-stream */ free(src); src = NULL; /* create output volume */ /* ------------------- */ switch (parameters.cod_format) { case PGX_DFMT: /* PGX */ decodeok = volumetopgx(volume, parameters.outfile); if (decodeok) fprintf(stdout,"[ERROR] Unable to write decoded volume into pgx files\n"); break; case BIN_DFMT: /* BMP */ decodeok = volumetobin(volume, parameters.outfile); if (decodeok) fprintf(stdout,"[ERROR] Unable to write decoded volume into pgx files\n"); break; } switch (parameters.orig_format) { case PGX_DFMT: /* PGX */ if (strcmp("NULL",parameters.original) != 0){ fprintf(stdout,"Loading original file %s \n",parameters.original); cparameters.subsampling_dx = 1; cparameters.subsampling_dy = 1; cparameters.subsampling_dz = 1; cparameters.volume_offset_x0 = 0;cparameters.volume_offset_y0 = 0;cparameters.volume_offset_z0 = 0; original = pgxtovolume(parameters.original,&cparameters); } break; case BIN_DFMT: /* BMP */ if (strcmp("NULL",parameters.original) != 0 && strcmp("NULL",parameters.imgfile) != 0){ fprintf(stdout,"Loading original file %s %s\n",parameters.original,parameters.imgfile); cparameters.subsampling_dx = 1; cparameters.subsampling_dy = 1; cparameters.subsampling_dz = 1; cparameters.volume_offset_x0 = 0;cparameters.volume_offset_y0 = 0;cparameters.volume_offset_z0 = 0; original = bintovolume(parameters.original,parameters.imgfile,&cparameters); } break; } fprintf(stdout, "[RESULT] Volume: %d x %d x %d (x %d bpv)\n ", (volume->comps[0].w >> volume->comps[0].factor[0]), (volume->comps[0].h >> volume->comps[0].factor[1]), (volume->comps[0].l >> volume->comps[0].factor[2]),volume->comps[0].prec); if(original){ psnr = calc_PSNR(original,volume); ssim = calc_SSIM(original,volume); if (psnr < 0.0) fprintf(stdout, " PSNR: Inf , SSMI %f -- Perfect reconstruction!\n",ssim); else fprintf(stdout, " PSNR: %f , SSIM %f \n",psnr,ssim); } /* free remaining structures */ if(dinfo) { opj_destroy_decompress(dinfo); } /* free volume data structure */ opj_volume_destroy(volume); return 0; }