third_party/lcms/src/cmssamp.c - pdfium - Git at Google

 //---------------------------------------------------------------------------------
 //
 //  Little Color Management System
 //  Copyright (c) 1998-2016 Marti Maria Saguer
 //
 // Permission is hereby granted, free of charge, to any person obtaining
 // a copy of this software and associated documentation files (the "Software"),
 // to deal in the Software without restriction, including without limitation
 // the rights to use, copy, modify, merge, publish, distribute, sublicense,
 // and/or sell copies of the Software, and to permit persons to whom the Software
 // is furnished to do so, subject to the following conditions:
 //
 // The above copyright notice and this permission notice shall be included in
 // all copies or substantial portions of the Software.
 //
 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
 // THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 // NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
 // LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
 // OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 // WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 //
 //---------------------------------------------------------------------------------
 //

 #include "lcms2_internal.h"


 #define cmsmin(a, b) (((a) < (b)) ? (a) : (b))
 #define cmsmax(a, b) (((a) > (b)) ? (a) : (b))

 // This file contains routines for resampling and LUT optimization, black point detection
 // and black preservation.

 // Black point detection -------------------------------------------------------------------------


 // PCS -> PCS round trip transform, always uses relative intent on the device -> pcs
 static
 cmsHTRANSFORM CreateRoundtripXForm(cmsHPROFILE hProfile, cmsUInt32Number nIntent)
 {
     cmsContext ContextID = cmsGetProfileContextID(hProfile);
     cmsHPROFILE hLab = cmsCreateLab4ProfileTHR(ContextID, NULL);
     cmsHTRANSFORM xform;
     cmsBool BPC[4] = { FALSE, FALSE, FALSE, FALSE };
     cmsFloat64Number States[4] = { 1.0, 1.0, 1.0, 1.0 };
     cmsHPROFILE hProfiles[4];
     cmsUInt32Number Intents[4];

     hProfiles[0] = hLab; hProfiles[1] = hProfile; hProfiles[2] = hProfile; hProfiles[3] = hLab;
     Intents[0]   = INTENT_RELATIVE_COLORIMETRIC; Intents[1] = nIntent; Intents[2] = INTENT_RELATIVE_COLORIMETRIC; Intents[3] = INTENT_RELATIVE_COLORIMETRIC;

     xform =  cmsCreateExtendedTransform(ContextID, 4, hProfiles, BPC, Intents,
         States, NULL, 0, TYPE_Lab_DBL, TYPE_Lab_DBL, cmsFLAGS_NOCACHE|cmsFLAGS_NOOPTIMIZE);

     cmsCloseProfile(hLab);
     return xform;
 }

 // Use darker colorants to obtain black point. This works in the relative colorimetric intent and
 // assumes more ink results in darker colors. No ink limit is assumed.
 static
 cmsBool  BlackPointAsDarkerColorant(cmsHPROFILE    hInput,
                                     cmsUInt32Number Intent,
                                     cmsCIEXYZ* BlackPoint,
                                     cmsUInt32Number dwFlags)
 {
     cmsUInt16Number *Black;
     cmsHTRANSFORM xform;
     cmsColorSpaceSignature Space;
     cmsUInt32Number nChannels;
     cmsUInt32Number dwFormat;
     cmsHPROFILE hLab;
     cmsCIELab  Lab;
     cmsCIEXYZ  BlackXYZ;
     cmsContext ContextID = cmsGetProfileContextID(hInput);

     // If the profile does not support input direction, assume Black point 0
     if (!cmsIsIntentSupported(hInput, Intent, LCMS_USED_AS_INPUT)) {

         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }

     // Create a formatter which has n channels and floating point
     dwFormat = cmsFormatterForColorspaceOfProfile(hInput, 2, FALSE);

    // Try to get black by using black colorant
     Space = cmsGetColorSpace(hInput);

     // This function returns darker colorant in 16 bits for several spaces
     if (!_cmsEndPointsBySpace(Space, NULL, &Black, &nChannels)) {

         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }

     if (nChannels != T_CHANNELS(dwFormat)) {
        BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
        return FALSE;
     }

     // Lab will be used as the output space, but lab2 will avoid recursion
     hLab = cmsCreateLab2ProfileTHR(ContextID, NULL);
     if (hLab == NULL) {
        BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
        return FALSE;
     }

     // Create the transform
     xform = cmsCreateTransformTHR(ContextID, hInput, dwFormat,
                                 hLab, TYPE_Lab_DBL, Intent, cmsFLAGS_NOOPTIMIZE|cmsFLAGS_NOCACHE);
     cmsCloseProfile(hLab);

     if (xform == NULL) {

         // Something went wrong. Get rid of open resources and return zero as black
         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }

     // Convert black to Lab
     cmsDoTransform(xform, Black, &Lab, 1);

     // Force it to be neutral, clip to max. L* of 50
     Lab.a = Lab.b = 0;
     if (Lab.L > 50) Lab.L = 50;

     // Free the resources
     cmsDeleteTransform(xform);

     // Convert from Lab (which is now clipped) to XYZ.
     cmsLab2XYZ(NULL, &BlackXYZ, &Lab);

     if (BlackPoint != NULL)
         *BlackPoint = BlackXYZ;

     return TRUE;

     cmsUNUSED_PARAMETER(dwFlags);
 }

 // Get a black point of output CMYK profile, discounting any ink-limiting embedded
 // in the profile. For doing that, we use perceptual intent in input direction:
 // Lab (0, 0, 0) -> [Perceptual] Profile -> CMYK -> [Rel. colorimetric] Profile -> Lab
 static
 cmsBool BlackPointUsingPerceptualBlack(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile)
 {
     cmsHTRANSFORM hRoundTrip;
     cmsCIELab LabIn, LabOut;
     cmsCIEXYZ  BlackXYZ;

      // Is the intent supported by the profile?
     if (!cmsIsIntentSupported(hProfile, INTENT_PERCEPTUAL, LCMS_USED_AS_INPUT)) {

         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return TRUE;
     }

     hRoundTrip = CreateRoundtripXForm(hProfile, INTENT_PERCEPTUAL);
     if (hRoundTrip == NULL) {
         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }

     LabIn.L = LabIn.a = LabIn.b = 0;
     cmsDoTransform(hRoundTrip, &LabIn, &LabOut, 1);

     // Clip Lab to reasonable limits
     if (LabOut.L > 50) LabOut.L = 50;
     LabOut.a = LabOut.b = 0;

     cmsDeleteTransform(hRoundTrip);

     // Convert it to XYZ
     cmsLab2XYZ(NULL, &BlackXYZ, &LabOut);

     if (BlackPoint != NULL)
         *BlackPoint = BlackXYZ;

     return TRUE;
 }

 // This function shouldn't exist at all -- there is such quantity of broken
 // profiles on black point tag, that we must somehow fix chromaticity to
 // avoid huge tint when doing Black point compensation. This function does
 // just that. There is a special flag for using black point tag, but turned
 // off by default because it is bogus on most profiles. The detection algorithm
 // involves to turn BP to neutral and to use only L component.
 cmsBool CMSEXPORT cmsDetectBlackPoint(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags)
 {
     cmsProfileClassSignature devClass;

     // Make sure the device class is adequate
     devClass = cmsGetDeviceClass(hProfile);
     if (devClass == cmsSigLinkClass ||
         devClass == cmsSigAbstractClass ||
         devClass == cmsSigNamedColorClass) {
             BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
             return FALSE;
     }

     // Make sure intent is adequate
     if (Intent != INTENT_PERCEPTUAL &&
         Intent != INTENT_RELATIVE_COLORIMETRIC &&
         Intent != INTENT_SATURATION) {
             BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
             return FALSE;
     }

     // v4 + perceptual & saturation intents does have its own black point, and it is
     // well specified enough to use it. Black point tag is deprecated in V4.
     if ((cmsGetEncodedICCversion(hProfile) >= 0x4000000) &&
         (Intent == INTENT_PERCEPTUAL || Intent == INTENT_SATURATION)) {

             // Matrix shaper share MRC & perceptual intents
             if (cmsIsMatrixShaper(hProfile))
                 return BlackPointAsDarkerColorant(hProfile, INTENT_RELATIVE_COLORIMETRIC, BlackPoint, 0);

             // Get Perceptual black out of v4 profiles. That is fixed for perceptual & saturation intents
             BlackPoint -> X = cmsPERCEPTUAL_BLACK_X;
             BlackPoint -> Y = cmsPERCEPTUAL_BLACK_Y;
             BlackPoint -> Z = cmsPERCEPTUAL_BLACK_Z;

             return TRUE;
     }


 #ifdef CMS_USE_PROFILE_BLACK_POINT_TAG

     // v2, v4 rel/abs colorimetric
     if (cmsIsTag(hProfile, cmsSigMediaBlackPointTag) &&
         Intent == INTENT_RELATIVE_COLORIMETRIC) {

             cmsCIEXYZ *BlackPtr, BlackXYZ, UntrustedBlackPoint, TrustedBlackPoint, MediaWhite;
             cmsCIELab Lab;

             // If black point is specified, then use it,

             BlackPtr = cmsReadTag(hProfile, cmsSigMediaBlackPointTag);
             if (BlackPtr != NULL) {

                 BlackXYZ = *BlackPtr;
                 _cmsReadMediaWhitePoint(&MediaWhite, hProfile);

                 // Black point is absolute XYZ, so adapt to D50 to get PCS value
                 cmsAdaptToIlluminant(&UntrustedBlackPoint, &MediaWhite, cmsD50_XYZ(), &BlackXYZ);

                 // Force a=b=0 to get rid of any chroma
                 cmsXYZ2Lab(NULL, &Lab, &UntrustedBlackPoint);
                 Lab.a = Lab.b = 0;
                 if (Lab.L > 50) Lab.L = 50; // Clip to L* <= 50
                 cmsLab2XYZ(NULL, &TrustedBlackPoint, &Lab);

                 if (BlackPoint != NULL)
                     *BlackPoint = TrustedBlackPoint;

                 return TRUE;
             }
     }
 #endif

     // That is about v2 profiles.

     // If output profile, discount ink-limiting and that's all
     if (Intent == INTENT_RELATIVE_COLORIMETRIC &&
         (cmsGetDeviceClass(hProfile) == cmsSigOutputClass) &&
         (cmsGetColorSpace(hProfile)  == cmsSigCmykData))
         return BlackPointUsingPerceptualBlack(BlackPoint, hProfile);

     // Nope, compute BP using current intent.
     return BlackPointAsDarkerColorant(hProfile, Intent, BlackPoint, dwFlags);
 }


 // ---------------------------------------------------------------------------------------------------------

 // Least Squares Fit of a Quadratic Curve to Data
 // http://www.personal.psu.edu/jhm/f90/lectures/lsq2.html

 static
 cmsFloat64Number RootOfLeastSquaresFitQuadraticCurve(int n, cmsFloat64Number x[], cmsFloat64Number y[])
 {
     double sum_x = 0, sum_x2 = 0, sum_x3 = 0, sum_x4 = 0;
     double sum_y = 0, sum_yx = 0, sum_yx2 = 0;
     double d, a, b, c;
     int i;
     cmsMAT3 m;
     cmsVEC3 v, res;

     if (n < 4) return 0;

     for (i=0; i < n; i++) {

         double xn = x[i];
         double yn = y[i];

         sum_x  += xn;
         sum_x2 += xn*xn;
         sum_x3 += xn*xn*xn;
         sum_x4 += xn*xn*xn*xn;

         sum_y += yn;
         sum_yx += yn*xn;
         sum_yx2 += yn*xn*xn;
     }

     _cmsVEC3init(&m.v[0], n,      sum_x,  sum_x2);
     _cmsVEC3init(&m.v[1], sum_x,  sum_x2, sum_x3);
     _cmsVEC3init(&m.v[2], sum_x2, sum_x3, sum_x4);

     _cmsVEC3init(&v, sum_y, sum_yx, sum_yx2);

     if (!_cmsMAT3solve(&res, &m, &v)) return 0;


     a = res.n[2];
     b = res.n[1];
     c = res.n[0];

     if (fabs(a) < 1.0E-10) {

         return cmsmin(0, cmsmax(50, -c/b ));
     }
     else {

          d = b*b - 4.0 * a * c;
          if (d <= 0) {
              return 0;
          }
          else {

              double rt = (-b + sqrt(d)) / (2.0 * a);

              return cmsmax(0, cmsmin(50, rt));
          }
    }

 }


 // Calculates the black point of a destination profile.
 // This algorithm comes from the Adobe paper disclosing its black point compensation method.
 cmsBool CMSEXPORT cmsDetectDestinationBlackPoint(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags)
 {
     cmsColorSpaceSignature ColorSpace;
     cmsHTRANSFORM hRoundTrip = NULL;
     cmsCIELab InitialLab, destLab, Lab;
     cmsFloat64Number inRamp[256], outRamp[256];
     cmsFloat64Number MinL, MaxL;
     cmsBool NearlyStraightMidrange = TRUE;
     cmsFloat64Number yRamp[256];
     cmsFloat64Number x[256], y[256];
     cmsFloat64Number lo, hi;
     int n, l;
     cmsProfileClassSignature devClass;

     // Make sure the device class is adequate
     devClass = cmsGetDeviceClass(hProfile);
     if (devClass == cmsSigLinkClass ||
         devClass == cmsSigAbstractClass ||
         devClass == cmsSigNamedColorClass) {
             BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
             return FALSE;
     }

     // Make sure intent is adequate
     if (Intent != INTENT_PERCEPTUAL &&
         Intent != INTENT_RELATIVE_COLORIMETRIC &&
         Intent != INTENT_SATURATION) {
             BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
             return FALSE;
     }


     // v4 + perceptual & saturation intents does have its own black point, and it is
     // well specified enough to use it. Black point tag is deprecated in V4.
     if ((cmsGetEncodedICCversion(hProfile) >= 0x4000000) &&
         (Intent == INTENT_PERCEPTUAL || Intent == INTENT_SATURATION)) {

             // Matrix shaper share MRC & perceptual intents
             if (cmsIsMatrixShaper(hProfile))
                 return BlackPointAsDarkerColorant(hProfile, INTENT_RELATIVE_COLORIMETRIC, BlackPoint, 0);

             // Get Perceptual black out of v4 profiles. That is fixed for perceptual & saturation intents
             BlackPoint -> X = cmsPERCEPTUAL_BLACK_X;
             BlackPoint -> Y = cmsPERCEPTUAL_BLACK_Y;
             BlackPoint -> Z = cmsPERCEPTUAL_BLACK_Z;
             return TRUE;
     }


     // Check if the profile is lut based and gray, rgb or cmyk (7.2 in Adobe's document)
     ColorSpace = cmsGetColorSpace(hProfile);
     if (!cmsIsCLUT(hProfile, Intent, LCMS_USED_AS_OUTPUT ) ||
         (ColorSpace != cmsSigGrayData &&
          ColorSpace != cmsSigRgbData  &&
          ColorSpace != cmsSigCmykData)) {

         // In this case, handle as input case
         return cmsDetectBlackPoint(BlackPoint, hProfile, Intent, dwFlags);
     }

     // It is one of the valid cases!, use Adobe algorithm


     // Set a first guess, that should work on good profiles.
     if (Intent == INTENT_RELATIVE_COLORIMETRIC) {

         cmsCIEXYZ IniXYZ;

         // calculate initial Lab as source black point
         if (!cmsDetectBlackPoint(&IniXYZ, hProfile, Intent, dwFlags)) {
             return FALSE;
         }

         // convert the XYZ to lab
         cmsXYZ2Lab(NULL, &InitialLab, &IniXYZ);

     } else {

         // set the initial Lab to zero, that should be the black point for perceptual and saturation
         InitialLab.L = 0;
         InitialLab.a = 0;
         InitialLab.b = 0;
     }


     // Step 2
     // ======

     // Create a roundtrip. Define a Transform BT for all x in L*a*b*
     hRoundTrip = CreateRoundtripXForm(hProfile, Intent);
     if (hRoundTrip == NULL)  return FALSE;

     // Compute ramps

     for (l=0; l < 256; l++) {

         Lab.L = (cmsFloat64Number) (l * 100.0) / 255.0;
         Lab.a = cmsmin(50, cmsmax(-50, InitialLab.a));
         Lab.b = cmsmin(50, cmsmax(-50, InitialLab.b));

         cmsDoTransform(hRoundTrip, &Lab, &destLab, 1);

         inRamp[l]  = Lab.L;
         outRamp[l] = destLab.L;
     }

     // Make monotonic
     for (l = 254; l > 0; --l) {
         outRamp[l] = cmsmin(outRamp[l], outRamp[l+1]);
     }

     // Check
     if (! (outRamp[0] < outRamp[255])) {

         cmsDeleteTransform(hRoundTrip);
         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }


     // Test for mid range straight (only on relative colorimetric)
     NearlyStraightMidrange = TRUE;
     MinL = outRamp[0]; MaxL = outRamp[255];
     if (Intent == INTENT_RELATIVE_COLORIMETRIC) {

         for (l=0; l < 256; l++) {

             if (! ((inRamp[l] <= MinL + 0.2 * (MaxL - MinL) ) ||
                 (fabs(inRamp[l] - outRamp[l]) < 4.0 )))
                 NearlyStraightMidrange = FALSE;
         }

         // If the mid range is straight (as determined above) then the
         // DestinationBlackPoint shall be the same as initialLab.
         // Otherwise, the DestinationBlackPoint shall be determined
         // using curve fitting.
         if (NearlyStraightMidrange) {

             cmsLab2XYZ(NULL, BlackPoint, &InitialLab);
             cmsDeleteTransform(hRoundTrip);
             return TRUE;
         }
     }


     // curve fitting: The round-trip curve normally looks like a nearly constant section at the black point,
     // with a corner and a nearly straight line to the white point.
     for (l=0; l < 256; l++) {

         yRamp[l] = (outRamp[l] - MinL) / (MaxL - MinL);
     }

     // find the black point using the least squares error quadratic curve fitting
     if (Intent == INTENT_RELATIVE_COLORIMETRIC) {
         lo = 0.1;
         hi = 0.5;
     }
     else {

         // Perceptual and saturation
         lo = 0.03;
         hi = 0.25;
     }

     // Capture shadow points for the fitting.
     n = 0;
     for (l=0; l < 256; l++) {

         cmsFloat64Number ff = yRamp[l];

         if (ff >= lo && ff < hi) {
             x[n] = inRamp[l];
             y[n] = yRamp[l];
             n++;
         }
     }


     // No suitable points
     if (n < 3 ) {
         cmsDeleteTransform(hRoundTrip);
         BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
         return FALSE;
     }


     // fit and get the vertex of quadratic curve
     Lab.L = RootOfLeastSquaresFitQuadraticCurve(n, x, y);

     if (Lab.L < 0.0) { // clip to zero L* if the vertex is negative
         Lab.L = 0;
     }

     Lab.a = InitialLab.a;
     Lab.b = InitialLab.b;

     cmsLab2XYZ(NULL, BlackPoint, &Lab);

     cmsDeleteTransform(hRoundTrip);
     return TRUE;
 }
	//---------------------------------------------------------------------------------
	//
	// Little Color Management System
	// Copyright (c) 1998-2016 Marti Maria Saguer
	//
	// Permission is hereby granted, free of charge, to any person obtaining
	// a copy of this software and associated documentation files (the "Software"),
	// to deal in the Software without restriction, including without limitation
	// the rights to use, copy, modify, merge, publish, distribute, sublicense,
	// and/or sell copies of the Software, and to permit persons to whom the Software
	// is furnished to do so, subject to the following conditions:
	//
	// The above copyright notice and this permission notice shall be included in
	// all copies or substantial portions of the Software.
	//
	// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
	// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
	// THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
	// NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
	// LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
	// OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
	// WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
	//
	//---------------------------------------------------------------------------------
	//

	#include "lcms2_internal.h"


	#define cmsmin(a, b) (((a) < (b)) ? (a) : (b))
	#define cmsmax(a, b) (((a) > (b)) ? (a) : (b))

	// This file contains routines for resampling and LUT optimization, black point detection
	// and black preservation.

	// Black point detection -------------------------------------------------------------------------


	// PCS -> PCS round trip transform, always uses relative intent on the device -> pcs
	static
	cmsHTRANSFORM CreateRoundtripXForm(cmsHPROFILE hProfile, cmsUInt32Number nIntent)
	{
	cmsContext ContextID = cmsGetProfileContextID(hProfile);
	cmsHPROFILE hLab = cmsCreateLab4ProfileTHR(ContextID, NULL);
	cmsHTRANSFORM xform;
	cmsBool BPC[4] = { FALSE, FALSE, FALSE, FALSE };
	cmsFloat64Number States[4] = { 1.0, 1.0, 1.0, 1.0 };
	cmsHPROFILE hProfiles[4];
	cmsUInt32Number Intents[4];

	hProfiles[0] = hLab; hProfiles[1] = hProfile; hProfiles[2] = hProfile; hProfiles[3] = hLab;
	Intents[0] = INTENT_RELATIVE_COLORIMETRIC; Intents[1] = nIntent; Intents[2] = INTENT_RELATIVE_COLORIMETRIC; Intents[3] = INTENT_RELATIVE_COLORIMETRIC;

	xform = cmsCreateExtendedTransform(ContextID, 4, hProfiles, BPC, Intents,
	States, NULL, 0, TYPE_Lab_DBL, TYPE_Lab_DBL, cmsFLAGS_NOCACHE\|cmsFLAGS_NOOPTIMIZE);

	cmsCloseProfile(hLab);
	return xform;
	}

	// Use darker colorants to obtain black point. This works in the relative colorimetric intent and
	// assumes more ink results in darker colors. No ink limit is assumed.
	static
	cmsBool BlackPointAsDarkerColorant(cmsHPROFILE hInput,
	cmsUInt32Number Intent,
	cmsCIEXYZ* BlackPoint,
	cmsUInt32Number dwFlags)
	{
	cmsUInt16Number *Black;
	cmsHTRANSFORM xform;
	cmsColorSpaceSignature Space;
	cmsUInt32Number nChannels;
	cmsUInt32Number dwFormat;
	cmsHPROFILE hLab;
	cmsCIELab Lab;
	cmsCIEXYZ BlackXYZ;
	cmsContext ContextID = cmsGetProfileContextID(hInput);

	// If the profile does not support input direction, assume Black point 0
	if (!cmsIsIntentSupported(hInput, Intent, LCMS_USED_AS_INPUT)) {

	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Create a formatter which has n channels and floating point
	dwFormat = cmsFormatterForColorspaceOfProfile(hInput, 2, FALSE);

	// Try to get black by using black colorant
	Space = cmsGetColorSpace(hInput);

	// This function returns darker colorant in 16 bits for several spaces
	if (!_cmsEndPointsBySpace(Space, NULL, &Black, &nChannels)) {

	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	if (nChannels != T_CHANNELS(dwFormat)) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Lab will be used as the output space, but lab2 will avoid recursion
	hLab = cmsCreateLab2ProfileTHR(ContextID, NULL);
	if (hLab == NULL) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Create the transform
	xform = cmsCreateTransformTHR(ContextID, hInput, dwFormat,
	hLab, TYPE_Lab_DBL, Intent, cmsFLAGS_NOOPTIMIZE\|cmsFLAGS_NOCACHE);
	cmsCloseProfile(hLab);

	if (xform == NULL) {

	// Something went wrong. Get rid of open resources and return zero as black
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Convert black to Lab
	cmsDoTransform(xform, Black, &Lab, 1);

	// Force it to be neutral, clip to max. L* of 50
	Lab.a = Lab.b = 0;
	if (Lab.L > 50) Lab.L = 50;

	// Free the resources
	cmsDeleteTransform(xform);

	// Convert from Lab (which is now clipped) to XYZ.
	cmsLab2XYZ(NULL, &BlackXYZ, &Lab);

	if (BlackPoint != NULL)
	*BlackPoint = BlackXYZ;

	return TRUE;

	cmsUNUSED_PARAMETER(dwFlags);
	}

	// Get a black point of output CMYK profile, discounting any ink-limiting embedded
	// in the profile. For doing that, we use perceptual intent in input direction:
	// Lab (0, 0, 0) -> [Perceptual] Profile -> CMYK -> [Rel. colorimetric] Profile -> Lab
	static
	cmsBool BlackPointUsingPerceptualBlack(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile)
	{
	cmsHTRANSFORM hRoundTrip;
	cmsCIELab LabIn, LabOut;
	cmsCIEXYZ BlackXYZ;

	// Is the intent supported by the profile?
	if (!cmsIsIntentSupported(hProfile, INTENT_PERCEPTUAL, LCMS_USED_AS_INPUT)) {

	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return TRUE;
	}

	hRoundTrip = CreateRoundtripXForm(hProfile, INTENT_PERCEPTUAL);
	if (hRoundTrip == NULL) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	LabIn.L = LabIn.a = LabIn.b = 0;
	cmsDoTransform(hRoundTrip, &LabIn, &LabOut, 1);

	// Clip Lab to reasonable limits
	if (LabOut.L > 50) LabOut.L = 50;
	LabOut.a = LabOut.b = 0;

	cmsDeleteTransform(hRoundTrip);

	// Convert it to XYZ
	cmsLab2XYZ(NULL, &BlackXYZ, &LabOut);

	if (BlackPoint != NULL)
	*BlackPoint = BlackXYZ;

	return TRUE;
	}

	// This function shouldn't exist at all -- there is such quantity of broken
	// profiles on black point tag, that we must somehow fix chromaticity to
	// avoid huge tint when doing Black point compensation. This function does
	// just that. There is a special flag for using black point tag, but turned
	// off by default because it is bogus on most profiles. The detection algorithm
	// involves to turn BP to neutral and to use only L component.
	cmsBool CMSEXPORT cmsDetectBlackPoint(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags)
	{
	cmsProfileClassSignature devClass;

	// Make sure the device class is adequate
	devClass = cmsGetDeviceClass(hProfile);
	if (devClass == cmsSigLinkClass \|\|
	devClass == cmsSigAbstractClass \|\|
	devClass == cmsSigNamedColorClass) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Make sure intent is adequate
	if (Intent != INTENT_PERCEPTUAL &&
	Intent != INTENT_RELATIVE_COLORIMETRIC &&
	Intent != INTENT_SATURATION) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// v4 + perceptual & saturation intents does have its own black point, and it is
	// well specified enough to use it. Black point tag is deprecated in V4.
	if ((cmsGetEncodedICCversion(hProfile) >= 0x4000000) &&
	(Intent == INTENT_PERCEPTUAL \|\| Intent == INTENT_SATURATION)) {

	// Matrix shaper share MRC & perceptual intents
	if (cmsIsMatrixShaper(hProfile))
	return BlackPointAsDarkerColorant(hProfile, INTENT_RELATIVE_COLORIMETRIC, BlackPoint, 0);

	// Get Perceptual black out of v4 profiles. That is fixed for perceptual & saturation intents
	BlackPoint -> X = cmsPERCEPTUAL_BLACK_X;
	BlackPoint -> Y = cmsPERCEPTUAL_BLACK_Y;
	BlackPoint -> Z = cmsPERCEPTUAL_BLACK_Z;

	return TRUE;
	}


	#ifdef CMS_USE_PROFILE_BLACK_POINT_TAG

	// v2, v4 rel/abs colorimetric
	if (cmsIsTag(hProfile, cmsSigMediaBlackPointTag) &&
	Intent == INTENT_RELATIVE_COLORIMETRIC) {

	cmsCIEXYZ *BlackPtr, BlackXYZ, UntrustedBlackPoint, TrustedBlackPoint, MediaWhite;
	cmsCIELab Lab;

	// If black point is specified, then use it,

	BlackPtr = cmsReadTag(hProfile, cmsSigMediaBlackPointTag);
	if (BlackPtr != NULL) {

	BlackXYZ = *BlackPtr;
	_cmsReadMediaWhitePoint(&MediaWhite, hProfile);

	// Black point is absolute XYZ, so adapt to D50 to get PCS value
	cmsAdaptToIlluminant(&UntrustedBlackPoint, &MediaWhite, cmsD50_XYZ(), &BlackXYZ);

	// Force a=b=0 to get rid of any chroma
	cmsXYZ2Lab(NULL, &Lab, &UntrustedBlackPoint);
	Lab.a = Lab.b = 0;
	if (Lab.L > 50) Lab.L = 50; // Clip to L* <= 50
	cmsLab2XYZ(NULL, &TrustedBlackPoint, &Lab);

	if (BlackPoint != NULL)
	*BlackPoint = TrustedBlackPoint;

	return TRUE;
	}
	}
	#endif

	// That is about v2 profiles.

	// If output profile, discount ink-limiting and that's all
	if (Intent == INTENT_RELATIVE_COLORIMETRIC &&
	(cmsGetDeviceClass(hProfile) == cmsSigOutputClass) &&
	(cmsGetColorSpace(hProfile) == cmsSigCmykData))
	return BlackPointUsingPerceptualBlack(BlackPoint, hProfile);

	// Nope, compute BP using current intent.
	return BlackPointAsDarkerColorant(hProfile, Intent, BlackPoint, dwFlags);
	}



	// ---------------------------------------------------------------------------------------------------------

	// Least Squares Fit of a Quadratic Curve to Data
	// http://www.personal.psu.edu/jhm/f90/lectures/lsq2.html

	static
	cmsFloat64Number RootOfLeastSquaresFitQuadraticCurve(int n, cmsFloat64Number x[], cmsFloat64Number y[])
	{
	double sum_x = 0, sum_x2 = 0, sum_x3 = 0, sum_x4 = 0;
	double sum_y = 0, sum_yx = 0, sum_yx2 = 0;
	double d, a, b, c;
	int i;
	cmsMAT3 m;
	cmsVEC3 v, res;

	if (n < 4) return 0;

	for (i=0; i < n; i++) {

	double xn = x[i];
	double yn = y[i];

	sum_x += xn;
	sum_x2 += xn*xn;
	sum_x3 += xnxnxn;
	sum_x4 += xnxnxn*xn;

	sum_y += yn;
	sum_yx += yn*xn;
	sum_yx2 += ynxnxn;
	}

	_cmsVEC3init(&m.v[0], n, sum_x, sum_x2);
	_cmsVEC3init(&m.v[1], sum_x, sum_x2, sum_x3);
	_cmsVEC3init(&m.v[2], sum_x2, sum_x3, sum_x4);

	_cmsVEC3init(&v, sum_y, sum_yx, sum_yx2);

	if (!_cmsMAT3solve(&res, &m, &v)) return 0;


	a = res.n[2];
	b = res.n[1];
	c = res.n[0];

	if (fabs(a) < 1.0E-10) {

	return cmsmin(0, cmsmax(50, -c/b ));
	}
	else {

	d = bb - 4.0 a * c;
	if (d <= 0) {
	return 0;
	}
	else {

	double rt = (-b + sqrt(d)) / (2.0 * a);

	return cmsmax(0, cmsmin(50, rt));
	}
	}

	}



	// Calculates the black point of a destination profile.
	// This algorithm comes from the Adobe paper disclosing its black point compensation method.
	cmsBool CMSEXPORT cmsDetectDestinationBlackPoint(cmsCIEXYZ* BlackPoint, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags)
	{
	cmsColorSpaceSignature ColorSpace;
	cmsHTRANSFORM hRoundTrip = NULL;
	cmsCIELab InitialLab, destLab, Lab;
	cmsFloat64Number inRamp[256], outRamp[256];
	cmsFloat64Number MinL, MaxL;
	cmsBool NearlyStraightMidrange = TRUE;
	cmsFloat64Number yRamp[256];
	cmsFloat64Number x[256], y[256];
	cmsFloat64Number lo, hi;
	int n, l;
	cmsProfileClassSignature devClass;

	// Make sure the device class is adequate
	devClass = cmsGetDeviceClass(hProfile);
	if (devClass == cmsSigLinkClass \|\|
	devClass == cmsSigAbstractClass \|\|
	devClass == cmsSigNamedColorClass) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}

	// Make sure intent is adequate
	if (Intent != INTENT_PERCEPTUAL &&
	Intent != INTENT_RELATIVE_COLORIMETRIC &&
	Intent != INTENT_SATURATION) {
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}


	// v4 + perceptual & saturation intents does have its own black point, and it is
	// well specified enough to use it. Black point tag is deprecated in V4.
	if ((cmsGetEncodedICCversion(hProfile) >= 0x4000000) &&
	(Intent == INTENT_PERCEPTUAL \|\| Intent == INTENT_SATURATION)) {

	// Matrix shaper share MRC & perceptual intents
	if (cmsIsMatrixShaper(hProfile))
	return BlackPointAsDarkerColorant(hProfile, INTENT_RELATIVE_COLORIMETRIC, BlackPoint, 0);

	// Get Perceptual black out of v4 profiles. That is fixed for perceptual & saturation intents
	BlackPoint -> X = cmsPERCEPTUAL_BLACK_X;
	BlackPoint -> Y = cmsPERCEPTUAL_BLACK_Y;
	BlackPoint -> Z = cmsPERCEPTUAL_BLACK_Z;
	return TRUE;
	}


	// Check if the profile is lut based and gray, rgb or cmyk (7.2 in Adobe's document)
	ColorSpace = cmsGetColorSpace(hProfile);
	if (!cmsIsCLUT(hProfile, Intent, LCMS_USED_AS_OUTPUT ) \|\|
	(ColorSpace != cmsSigGrayData &&
	ColorSpace != cmsSigRgbData &&
	ColorSpace != cmsSigCmykData)) {

	// In this case, handle as input case
	return cmsDetectBlackPoint(BlackPoint, hProfile, Intent, dwFlags);
	}

	// It is one of the valid cases!, use Adobe algorithm


	// Set a first guess, that should work on good profiles.
	if (Intent == INTENT_RELATIVE_COLORIMETRIC) {

	cmsCIEXYZ IniXYZ;

	// calculate initial Lab as source black point
	if (!cmsDetectBlackPoint(&IniXYZ, hProfile, Intent, dwFlags)) {
	return FALSE;
	}

	// convert the XYZ to lab
	cmsXYZ2Lab(NULL, &InitialLab, &IniXYZ);

	} else {

	// set the initial Lab to zero, that should be the black point for perceptual and saturation
	InitialLab.L = 0;
	InitialLab.a = 0;
	InitialLab.b = 0;
	}


	// Step 2
	// ======

	// Create a roundtrip. Define a Transform BT for all x in Lab*
	hRoundTrip = CreateRoundtripXForm(hProfile, Intent);
	if (hRoundTrip == NULL) return FALSE;

	// Compute ramps

	for (l=0; l < 256; l++) {

	Lab.L = (cmsFloat64Number) (l * 100.0) / 255.0;
	Lab.a = cmsmin(50, cmsmax(-50, InitialLab.a));
	Lab.b = cmsmin(50, cmsmax(-50, InitialLab.b));

	cmsDoTransform(hRoundTrip, &Lab, &destLab, 1);

	inRamp[l] = Lab.L;
	outRamp[l] = destLab.L;
	}

	// Make monotonic
	for (l = 254; l > 0; --l) {
	outRamp[l] = cmsmin(outRamp[l], outRamp[l+1]);
	}

	// Check
	if (! (outRamp[0] < outRamp[255])) {

	cmsDeleteTransform(hRoundTrip);
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}


	// Test for mid range straight (only on relative colorimetric)
	NearlyStraightMidrange = TRUE;
	MinL = outRamp[0]; MaxL = outRamp[255];
	if (Intent == INTENT_RELATIVE_COLORIMETRIC) {

	for (l=0; l < 256; l++) {

	if (! ((inRamp[l] <= MinL + 0.2 * (MaxL - MinL) ) \|\|
	(fabs(inRamp[l] - outRamp[l]) < 4.0 )))
	NearlyStraightMidrange = FALSE;
	}

	// If the mid range is straight (as determined above) then the
	// DestinationBlackPoint shall be the same as initialLab.
	// Otherwise, the DestinationBlackPoint shall be determined
	// using curve fitting.
	if (NearlyStraightMidrange) {

	cmsLab2XYZ(NULL, BlackPoint, &InitialLab);
	cmsDeleteTransform(hRoundTrip);
	return TRUE;
	}
	}


	// curve fitting: The round-trip curve normally looks like a nearly constant section at the black point,
	// with a corner and a nearly straight line to the white point.
	for (l=0; l < 256; l++) {

	yRamp[l] = (outRamp[l] - MinL) / (MaxL - MinL);
	}

	// find the black point using the least squares error quadratic curve fitting
	if (Intent == INTENT_RELATIVE_COLORIMETRIC) {
	lo = 0.1;
	hi = 0.5;
	}
	else {

	// Perceptual and saturation
	lo = 0.03;
	hi = 0.25;
	}

	// Capture shadow points for the fitting.
	n = 0;
	for (l=0; l < 256; l++) {

	cmsFloat64Number ff = yRamp[l];

	if (ff >= lo && ff < hi) {
	x[n] = inRamp[l];
	y[n] = yRamp[l];
	n++;
	}
	}


	// No suitable points
	if (n < 3 ) {
	cmsDeleteTransform(hRoundTrip);
	BlackPoint -> X = BlackPoint ->Y = BlackPoint -> Z = 0.0;
	return FALSE;
	}


	// fit and get the vertex of quadratic curve
	Lab.L = RootOfLeastSquaresFitQuadraticCurve(n, x, y);

	if (Lab.L < 0.0) { // clip to zero L* if the vertex is negative
	Lab.L = 0;
	}

	Lab.a = InitialLab.a;
	Lab.b = InitialLab.b;

	cmsLab2XYZ(NULL, BlackPoint, &Lab);

	cmsDeleteTransform(hRoundTrip);
	return TRUE;
	}