/*============================================================================ libpamcolor.c ============================================================================== These are the library functions, which belong in the libnetpbm library, that deal with colors in the PAM image format. This file was originally written by Bryan Henderson and is contributed to the public domain by him and subsequent authors. =============================================================================*/ /* See pmfileio.c for the complicated explanation of this 32/64 bit file offset stuff. */ #define _FILE_OFFSET_BITS 64 #define _LARGE_FILES #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 */ #include #include #include "netpbm/pm_c_util.h" #include "netpbm/mallocvar.h" #include "netpbm/nstring.h" #include "netpbm/colorname.h" #include "netpbm/pam.h" #include "netpbm/ppm.h" static unsigned int hexDigitValue(char const digit) { switch (digit) { case '0': return 0; case '1': return 1; case '2': return 2; case '3': return 3; case '4': return 4; case '5': return 5; case '6': return 6; case '7': return 7; case '8': return 8; case '9': return 9; case 'a': case 'A': return 10; case 'b': case 'B': return 11; case 'c': case 'C': return 12; case 'd': case 'D': return 13; case 'e': case 'E': return 14; case 'f': case 'F': return 15; default: pm_error("Invalid hex digit '%c'", digit); return 0; /* Defeat compiler warning */ } } static void parseHexDigits(const char * const string, char const delim, samplen * const nP, unsigned int * const digitCtP) { unsigned int digitCt; unsigned long n; unsigned long range; /* 16 for one hex digit, 256 for two hex digits, etc. */ for (digitCt = 0, n = 0, range = 1; string[digitCt] != delim; ) { char const digit = string[digitCt]; if (digit == '\0') pm_error("rgb: color spec '%s' ends prematurely", string); else { n = n * 16 + hexDigitValue(digit); range *= 16; ++digitCt; } } if (range <= 1) pm_error("No digits where hexadecimal number expected in rgb: " "color spec '%s'", string); *nP = (samplen) n / (range-1); *digitCtP = digitCt; } static void parseNewHexX11(char const colorname[], tuplen const color) { /*---------------------------------------------------------------------------- Determine what color colorname[] specifies in the new style hex color specification format (e.g. rgb:55/40/55). Return that color as *colorP. Assume colorname[] starts with "rgb:", but otherwise it might be gibberish. -----------------------------------------------------------------------------*/ const char * cp; unsigned int digitCt; cp = &colorname[4]; parseHexDigits(cp, '/', &color[PAM_RED_PLANE], &digitCt); cp += digitCt; ++cp; /* Skip the slash */ parseHexDigits(cp, '/', &color[PAM_GRN_PLANE], &digitCt); cp += digitCt; ++cp; /* Skip the slash */ parseHexDigits(cp, '\0', &color[PAM_BLU_PLANE], &digitCt); } static bool isNormal(samplen const arg) { return arg >= 0.0 && arg <= 1.0; } static void parseNewDecX11(const char * const colorname, tuplen const color) { int rc; rc = sscanf(colorname, "rgbi:%f/%f/%f", &color[PAM_RED_PLANE], &color[PAM_GRN_PLANE], &color[PAM_BLU_PLANE]); if (rc != 3) pm_error("invalid color specifier '%s'", colorname); if (!(isNormal(color[PAM_RED_PLANE]) && isNormal(color[PAM_GRN_PLANE]) && isNormal(color[PAM_BLU_PLANE]))) { pm_error("invalid color specifier '%s' - " "values must be between 0.0 and 1.0", colorname); } } static void parseOldX11(const char * const colorname, tuplen const color) { /*---------------------------------------------------------------------------- Return as *colorP the color specified by the old X11 style color specififier colorname[] (e.g. #554055). -----------------------------------------------------------------------------*/ if (!pm_strishex(&colorname[1])) pm_error("Non-hexadecimal characters in #-type color specification"); switch (strlen(colorname) - 1 /* (Number of hex digits) */) { case 3: color[PAM_RED_PLANE] = (samplen)hexDigitValue(colorname[1])/15; color[PAM_GRN_PLANE] = (samplen)hexDigitValue(colorname[2])/15; color[PAM_BLU_PLANE] = (samplen)hexDigitValue(colorname[3])/15; break; case 6: color[PAM_RED_PLANE] = ((samplen)(hexDigitValue(colorname[1]) << 4) + (samplen)(hexDigitValue(colorname[2]) << 0)) / 255; color[PAM_GRN_PLANE] = ((samplen)(hexDigitValue(colorname[3]) << 4) + (samplen)(hexDigitValue(colorname[4]) << 0)) / 255; color[PAM_BLU_PLANE] = ((samplen)(hexDigitValue(colorname[5]) << 4) + (samplen)(hexDigitValue(colorname[6]) << 0)) / 255; break; case 9: color[PAM_RED_PLANE] = ((samplen)(hexDigitValue(colorname[1]) << 8) + (samplen)(hexDigitValue(colorname[2]) << 4) + (samplen)(hexDigitValue(colorname[3]) << 0)) / 4095; color[PAM_GRN_PLANE] = ((samplen)(hexDigitValue(colorname[4]) << 8) + (samplen)(hexDigitValue(colorname[5]) << 4) + (samplen)(hexDigitValue(colorname[6]) << 0)) / 4095; color[PAM_BLU_PLANE] = ((samplen)(hexDigitValue(colorname[7]) << 8) + (samplen)(hexDigitValue(colorname[8]) << 4) + (samplen)(hexDigitValue(colorname[9]) << 0)) / 4095; break; case 12: color[PAM_RED_PLANE] = ((samplen)(hexDigitValue(colorname[1]) << 12) + (samplen)(hexDigitValue(colorname[2]) << 8) + (samplen)(hexDigitValue(colorname[3]) << 4) + (samplen)(hexDigitValue(colorname[4]) << 0)) / 65535; color[PAM_GRN_PLANE] = ((samplen)(hexDigitValue(colorname[5]) << 12) + (samplen)(hexDigitValue(colorname[6]) << 8) + (samplen)(hexDigitValue(colorname[7]) << 4) + (samplen)(hexDigitValue(colorname[8]) << 0)) / 65535; color[PAM_BLU_PLANE] = ((samplen)(hexDigitValue(colorname[ 9]) << 12) + (samplen)(hexDigitValue(colorname[10]) << 8) + (samplen)(hexDigitValue(colorname[11]) << 4) + (samplen)(hexDigitValue(colorname[12]) << 0)) / 65535; break; default: pm_error("invalid color specifier '%s'", colorname); } } static void parseOldX11Dec(const char* const colorname, tuplen const color) { int rc; rc = sscanf(colorname, "%f,%f,%f", &color[PAM_RED_PLANE], &color[PAM_GRN_PLANE], &color[PAM_BLU_PLANE]); if (rc != 3) pm_error("invalid color specifier '%s'", colorname); if (!(isNormal(color[PAM_RED_PLANE]) && isNormal(color[PAM_GRN_PLANE]) && isNormal(color[PAM_BLU_PLANE]))) { pm_error("invalid color specifier '%s' - " "values must be between 0.0 and 1.0", colorname); } } tuplen pnm_parsecolorn(const char * const colorname) { tuplen retval; MALLOCARRAY_NOFAIL(retval, 3); if (strncmp(colorname, "rgb:", 4) == 0) /* It's a new-X11-style hexadecimal rgb specifier. */ parseNewHexX11(colorname, retval); else if (strncmp(colorname, "rgbi:", 5) == 0) /* It's a new-X11-style decimal/float rgb specifier. */ parseNewDecX11(colorname, retval); else if (colorname[0] == '#') /* It's an old-X11-style hexadecimal rgb specifier. */ parseOldX11(colorname, retval); else if ((colorname[0] >= '0' && colorname[0] <= '9') || colorname[0] == '.') /* It's an old-style decimal/float rgb specifier. */ parseOldX11Dec(colorname, retval); else /* Must be a name from the X-style rgb file. */ pm_parse_dictionary_namen(colorname, retval); return retval; } tuple pnm_parsecolor(const char * const colorname, sample const maxval) { tuple retval; tuplen color; struct pam pam; pam.len = PAM_STRUCT_SIZE(bytes_per_sample); pam.depth = 3; pam.maxval = maxval; pam.bytes_per_sample = pnm_bytespersample(maxval); retval = pnm_allocpamtuple(&pam); color = pnm_parsecolorn(colorname); retval[PAM_RED_PLANE] = ROUNDU(color[PAM_RED_PLANE] * maxval); retval[PAM_GRN_PLANE] = ROUNDU(color[PAM_GRN_PLANE] * maxval); retval[PAM_BLU_PLANE] = ROUNDU(color[PAM_BLU_PLANE] * maxval); free(color); return retval; } const char * pnm_colorname(struct pam * const pamP, tuple const color, int const hexok) { const char * retval; pixel colorp; char * colorname; if (pamP->depth < 3) PPM_ASSIGN(colorp, color[0], color[0], color[0]); else PPM_ASSIGN(colorp, color[PAM_RED_PLANE], color[PAM_GRN_PLANE], color[PAM_BLU_PLANE]); colorname = ppm_colorname(&colorp, pamP->maxval, hexok); retval = strdup(colorname); if (retval == NULL) pm_error("Couldn't get memory for color name string"); return retval; } double pnm_lumin_factor[3] = {PPM_LUMINR, PPM_LUMING, PPM_LUMINB}; void pnm_YCbCrtuple(tuple const tuple, double * const YP, double * const CbP, double * const CrP) { /*---------------------------------------------------------------------------- Assuming that the tuple 'tuple' is of tupletype RGB, return the Y/Cb/Cr representation of the color represented by the tuple. -----------------------------------------------------------------------------*/ int const red = (int)tuple[PAM_RED_PLANE]; int const grn = (int)tuple[PAM_GRN_PLANE]; int const blu = (int)tuple[PAM_BLU_PLANE]; *YP = (+ PPM_LUMINR * red + PPM_LUMING * grn + PPM_LUMINB * blu); *CbP = (- 0.16874 * red - 0.33126 * grn + 0.50000 * blu); *CrP = (+ 0.50000 * red - 0.41869 * grn - 0.08131 * blu); } void pnm_YCbCr_to_rgbtuple(const struct pam * const pamP, tuple const tuple, double const Y, double const Cb, double const Cr, int * const overflowP) { double rgb[3]; unsigned int plane; bool overflow; rgb[PAM_RED_PLANE] = Y + 1.4022 * Cr + .5; rgb[PAM_GRN_PLANE] = Y - 0.7145 * Cr - 0.3456 * Cb + .5; rgb[PAM_BLU_PLANE] = Y + 1.7710 * Cb + .5; overflow = FALSE; /* initial assumption */ for (plane = 0; plane < 3; ++plane) { if (rgb[plane] > pamP->maxval) { overflow = TRUE; tuple[plane] = pamP->maxval; } else if (rgb[plane] < 0.0) { overflow = TRUE; tuple[plane] = 0; } else tuple[plane] = (sample)rgb[plane]; } if (overflowP) *overflowP = overflow; }