/***************************************************************************** jpeg2kopam ****************************************************************************** Convert a JPEG-2000 code stream image to a PNM or PAM By Bryan Henderson, San Jose CA 2002.10.26 *****************************************************************************/ #define _DEFAULT_SOURCE 1 /* New name for SVID & BSD source defines */ #define _BSD_SOURCE 1 /* Make sure strdup() is in string.h */ #define _XOPEN_SOURCE 500 /* Make sure strdup() is in string.h */ /* In 2014.09, this was _XOPEN_SOURCE 600, with a comment saying it was necessary to make define int_fast32_t, etc. on AIX. does use int_fast32_t and does include , but plenty of source files of libjasper do to0, and they did not have _XOPEN_SOURCE 600, so it would seem to be superfluous here too. */ #include #include #include "pm_c_util.h" #include "pam.h" #include "shhopt.h" #include "nstring.h" #include "mallocvar.h" #include "libjasper_compat.h" struct CmdlineInfo { /* All the information the user supplied in the command line, in a form easy for the program to use. */ char * inputFilename; unsigned int debuglevel; /* Jasper library debug level */ unsigned int verbose; }; static void parseCommandLine(int argc, const char ** argv, struct CmdlineInfo * const cmdlineP) { /*---------------------------------------------------------------------------- Note that many of the strings that this function returns in the *cmdlineP structure are actually in the supplied argv array. And sometimes, one of these strings is actually just a suffix of an entry in argv! -----------------------------------------------------------------------------*/ optEntry * option_def; optStruct3 opt; unsigned int debuglevelSpec; unsigned int option_def_index; MALLOCARRAY_NOFAIL(option_def, 100); option_def_index = 0; /* incremented by OPTENTRY */ OPTENT3(0, "verbose", OPT_FLAG, NULL, &cmdlineP->verbose, 0); OPTENT3(0, "debuglevel", OPT_UINT, &cmdlineP->debuglevel, &debuglevelSpec, 0); opt.opt_table = option_def; opt.short_allowed = FALSE; /* We have no short (old-fashioned) options */ opt.allowNegNum = FALSE; /* We have no parms that are negative numbers */ pm_optParseOptions3(&argc, (char**)argv, opt, sizeof(opt), 0); if (!debuglevelSpec) cmdlineP->debuglevel = 0; if (argc - 1 == 0) cmdlineP->inputFilename = strdup("-"); /* he wants stdin */ else if (argc - 1 == 1) cmdlineP->inputFilename = strdup(argv[1]); else pm_error("Too many arguments. The only argument accepted\n" "is the input file specification"); free(option_def); } static void validateJ2k(jas_stream_t * const instreamP) { /*---------------------------------------------------------------------------- Abort program with error message if *instreamP is not a JPEG-2000 code stream (JPC) or image file (JP2). -----------------------------------------------------------------------------*/ assert(jas_image_lookupfmtbyname("jpc")); assert(jas_image_lookupfmtbyname("jp2")); if (jas_image_lookupfmtbyname("jpc")->ops.validate(instreamP) != 0 && jas_image_lookupfmtbyname("jp2")->ops.validate(instreamP) != 0) { pm_error("Input is not JPEG-2000 image file (JP2) " "or code stream (JPC). " "(the first few bytes of the file are not the required " "signature)"); } } static void readJ2k(const char * const inputFilename, jas_image_t ** const jasperPP) { const char * const options = ""; jas_image_t * jasperP; jas_stream_t * instreamP; const char * error; if (streq(inputFilename, "-")) { /* The input image is to be read from standard input. */ instreamP = jas_stream_fdopen(fileno(stdin), "rb"); if (instreamP == NULL) pm_error("error: cannot reopen standard input"); } else { instreamP = jas_stream_fopen(inputFilename, "rb"); if (instreamP == NULL ) pm_error("cannot open input image file '%s'", inputFilename); } validateJ2k(instreamP); pmjas_image_decode(instreamP, jas_image_getfmt(instreamP), options, &jasperP, &error); if (error) pm_error("Unable to interpret JPEG-2000 input. %s", error); jas_stream_close(instreamP); *jasperPP = jasperP; } static void getRgbComponents(int jasperCmpnt[], jas_image_t * const jasperP) { { int const rc = jas_image_getcmptbytype(jasperP, JAS_IMAGE_CT_COLOR(JAS_IMAGE_CT_RGB_R)); if (rc < 0) pm_error("Input says it has RGB color space, but contains " "no red component"); else jasperCmpnt[PAM_RED_PLANE] = rc; if (jas_image_cmptsgnd(jasperP, rc)) pm_error("Input image says it is RGB, but has signed values " "for what should be the red intensities."); } { int const rc = jas_image_getcmptbytype(jasperP, JAS_IMAGE_CT_COLOR(JAS_IMAGE_CT_RGB_G)); if (rc < 0) pm_error("Input says it has RGB color space, but contains " "no green component"); else jasperCmpnt[PAM_GRN_PLANE] = rc; if (jas_image_cmptsgnd(jasperP, rc)) pm_error("Input image says it is RGB, but has signed values " "for what should be the green intensities."); } { int const rc = jas_image_getcmptbytype(jasperP, JAS_IMAGE_CT_COLOR(JAS_IMAGE_CT_RGB_B)); if (rc < 0) pm_error("Input says it has RGB color space, but contains " "no blue component"); else jasperCmpnt[PAM_BLU_PLANE] = rc; if (jas_image_cmptsgnd(jasperP, rc)) pm_error("Input image says it is RGB, but has signed values " "for what should be the blue intensities."); } } static void getGrayComponent(int * jasperCmptP, jas_image_t * const jasperP) { int const rc = jas_image_getcmptbytype(jasperP, JAS_IMAGE_CT_COLOR(JAS_IMAGE_CT_GRAY_Y)); if (rc < 0) pm_error("Input says it has Grayscale color space, but contains " "no gray intensity component"); else *jasperCmptP = rc; if (jas_image_cmptsgnd(jasperP, 0)) pm_error("Input image says it is grayscale, but has signed values " "for what should be the gray levels."); } static void validateComponentsAlike(jas_image_t * const jasperP) { /*---------------------------------------------------------------------------- JPC allows each component to have its own width and height. But PAM requires all planes to have the same shape. So we validate now that all the channels are the same, and abort the program if not. -----------------------------------------------------------------------------*/ int cmptNo; for (cmptNo = 0; cmptNo < jas_image_numcmpts(jasperP); ++cmptNo) { if (jas_image_cmptwidth(jasperP, cmptNo) != jas_image_cmptwidth(jasperP, 0)) pm_message("Input image does not have components all the same " "width."); if (jas_image_cmptheight(jasperP, cmptNo) != jas_image_cmptheight(jasperP, 0)) pm_message("Input image does not have components all the same " "height."); } } static unsigned int maxJasperComponentPrecision(jas_image_t * const jasperP) { int cmptNo; unsigned int max; max = 1; for (cmptNo = 0; cmptNo < jas_image_numcmpts(jasperP); ++cmptNo) max = MAX(max, jas_image_cmptprec(jasperP, cmptNo)); return max; } static void computeOutputParm(jas_image_t * const jasperP, struct pam * const outpamP, int ** const jasperCmptNoP) { int * jasperCmptNo; /* Malloc'ed array. jaspercmptNo[P] is the component number for use with the Jasper library that corresponds to Plane P of the PAM. */ switch (jas_clrspc_fam(jas_image_clrspc(jasperP))) { case JAS_CLRSPC_FAM_GRAY: outpamP->depth = 1; MALLOCARRAY_NOFAIL(jasperCmptNo, 1); getGrayComponent(&jasperCmptNo[0], jasperP); if (jas_image_cmptprec(jasperP, jasperCmptNo[0]) == 1) { outpamP->format = RPBM_FORMAT; strcpy(outpamP->tuple_type, PAM_PBM_TUPLETYPE); } else { outpamP->format = RPGM_FORMAT; strcpy(outpamP->tuple_type, PAM_PGM_TUPLETYPE); } break; case JAS_CLRSPC_FAM_RGB: outpamP->depth = 3; MALLOCARRAY_NOFAIL(jasperCmptNo, 3); getRgbComponents(jasperCmptNo, jasperP); outpamP->format = RPPM_FORMAT; strcpy(outpamP->tuple_type, PAM_PPM_TUPLETYPE); break; default: outpamP->format = PAM_FORMAT; outpamP->depth = jas_image_numcmpts(jasperP); { unsigned int plane; MALLOCARRAY_NOFAIL(jasperCmptNo, outpamP->depth); for (plane = 0; plane < outpamP->depth; ++plane) jasperCmptNo[plane] = plane; } strcpy(outpamP->tuple_type, ""); if (jas_image_cmptsgnd(jasperP, 0)) pm_message("Warning: Input image has signed sample values. " "They will be represented in the PAM output in " "two's complement."); } outpamP->plainformat = FALSE; outpamP->width = jas_image_cmptwidth(jasperP, 0); outpamP->height = jas_image_cmptheight(jasperP, 0); validateComponentsAlike(jasperP); { unsigned int const maxPrecision = maxJasperComponentPrecision(jasperP); outpamP->maxval = pm_bitstomaxval(maxPrecision); outpamP->bytes_per_sample = (maxPrecision + 7)/8; } *jasperCmptNoP = jasperCmptNo; } static void createMatrices(struct pam * const outpamP, jas_matrix_t *** matrixP) { jas_matrix_t ** matrix; unsigned int plane; MALLOCARRAY_NOFAIL(matrix, outpamP->depth); for (plane = 0; plane < outpamP->depth; ++plane) { matrix[plane] = jas_matrix_create(1, outpamP->width); if (matrix[plane] == NULL) pm_error("Unable to create matrix for plane %u. " "jas_matrix_create() failed.", plane); } *matrixP = matrix; } static void destroyMatrices(struct pam * const outpamP, jas_matrix_t ** const matrix ) { unsigned int plane; for (plane = 0; plane < outpamP->depth; ++plane) jas_matrix_destroy(matrix[plane]); free(matrix); } static void computeComponentMaxval(struct pam * const outpamP, jas_image_t * const jasperP, int const jasperCmpt[], sample ** const jasperMaxvalP, bool * const singleMaxvalP) { sample * jasperMaxval; unsigned int plane; MALLOCARRAY(jasperMaxval, outpamP->depth); *singleMaxvalP = TRUE; /* initial assumption */ for (plane = 0; plane < outpamP->depth; ++plane) { jasperMaxval[plane] = pm_bitstomaxval(jas_image_cmptprec(jasperP, jasperCmpt[plane])); if (jasperMaxval[plane] != jasperMaxval[0]) *singleMaxvalP = FALSE; } *jasperMaxvalP = jasperMaxval; } static void copyRowSingleMaxval(jas_seqent_t ** const jasperRow, tuple * const tuplerow, struct pam * const outpamP) { /*---------------------------------------------------------------------------- Copy row from Jasper library representation to Netpbm library representation, assuming all Jasper components have the same precision, which corresponds to the maxval of the output PAM, which means we don't have to do any maxval scaling. This is significantly faster than copyRowAnyMaxval(). -----------------------------------------------------------------------------*/ unsigned int col; for (col = 0; col < outpamP->width; ++col) { unsigned int plane; for (plane = 0; plane < outpamP->depth; ++plane) tuplerow[col][plane] = jasperRow[plane][col]; } } static void copyRowAnyMaxval(jas_seqent_t ** const jasperRow, tuple * const tuplerow, struct pam * const outpamP, sample const jasperMaxval[]) { /*---------------------------------------------------------------------------- Copy row from Jasper library representation to Netpbm library representation, allowing for each Jasper library component to have a different precision (number of bits) and for those precisions to be unrelated to the PAM maxval. This is significantly slower than copyRowSingleMaxval(). -----------------------------------------------------------------------------*/ unsigned int col; for (col = 0; col < outpamP->width; ++col) { unsigned int plane; for (plane = 0; plane < outpamP->depth; ++plane) tuplerow[col][plane] = jasperRow[plane][col] * outpamP->maxval / jasperMaxval[plane]; } } static void convertToPamPnm(struct pam * const outpamP, jas_image_t * const jasperP, int const jasperCmptNo[]) { jas_matrix_t ** matrix; /* malloc'ed */ /* matrix[X] is the data for Plane X of the current row */ sample * jasperMaxval; unsigned int row; tuple * tuplerow; jas_seqent_t ** jasperRow; /* malloc'ed */ /* A row of the raster from the Jasper library This is an array of pointers into the 'matrix' data structures, one for each plane in the row. */ bool singleMaxval; createMatrices(outpamP, &matrix); computeComponentMaxval(outpamP, jasperP, jasperCmptNo, &jasperMaxval, &singleMaxval); MALLOCARRAY(jasperRow, outpamP->depth); if (jasperRow == NULL) pm_error("Out of memory"); tuplerow = pnm_allocpamrow(outpamP); for (row = 0; row < outpamP->height; ++row) { unsigned int plane; for (plane = 0; plane < outpamP->depth; ++plane) { int rc; rc = jas_image_readcmpt(jasperP, jasperCmptNo[plane], 0, row, outpamP->width, 1, matrix[plane]); if (rc != 0) pm_error("jas_image_readcmpt() of row %u plane %u " "failed.", row, plane); jasperRow[plane] = jas_matrix_getref(matrix[plane], 0, 0); } if (singleMaxval) copyRowSingleMaxval(jasperRow, tuplerow, outpamP); else copyRowAnyMaxval(jasperRow, tuplerow, outpamP, jasperMaxval); pnm_writepamrow(outpamP, tuplerow); } pnm_freepamrow(tuplerow); destroyMatrices(outpamP, matrix); free(jasperRow); free(jasperMaxval); } int main(int argc, const char **argv) { struct CmdlineInfo cmdline; struct pam outpam; int * jasperCmpt; /* malloc'ed */ /* jaspercmpt[P] is the component number for use with the Jasper library that corresponds to Plane P of the PAM. */ jas_image_t * jasperP; pm_proginit(&argc, argv); parseCommandLine(argc, argv, &cmdline); { int rc; rc = jas_init(); if ( rc != 0 ) pm_error("Failed to initialize Jasper library. " "jas_init() returns rc %d", rc ); } jas_setdbglevel(cmdline.debuglevel); readJ2k(cmdline.inputFilename, &jasperP); outpam.file = stdout; outpam.size = sizeof(outpam); outpam.len = PAM_STRUCT_SIZE(tuple_type); computeOutputParm(jasperP, &outpam, &jasperCmpt); pnm_writepaminit(&outpam); convertToPamPnm(&outpam, jasperP, jasperCmpt); free(jasperCmpt); jas_image_destroy(jasperP); pm_close(stdout); return 0; }