/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ // This file is available under and governed by the GNU General Public // License version 2 only, as published by the Free Software Foundation. // However, the following notice accompanied the original version of this // file: // //--------------------------------------------------------------------------------- // // Little Color Management System // Copyright (c) 1998-2011 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" // PostScript ColorRenderingDictionary and ColorSpaceArray #define MAXPSCOLS 60 // Columns on tables /* Implementation -------------- PostScript does use XYZ as its internal PCS. But since PostScript interpolation tables are limited to 8 bits, I use Lab as a way to improve the accuracy, favoring perceptual results. So, for the creation of each CRD, CSA the profiles are converted to Lab via a device link between profile -> Lab or Lab -> profile. The PS code necessary to convert Lab <-> XYZ is also included. Color Space Arrays (CSA) ================================================================================== In order to obtain precision, code chooses between three ways to implement the device -> XYZ transform. These cases identifies monochrome profiles (often implemented as a set of curves), matrix-shaper and Pipeline-based. Monochrome ----------- This is implemented as /CIEBasedA CSA. The prelinearization curve is placed into /DecodeA section, and matrix equals to D50. Since here is no interpolation tables, I do the conversion directly to XYZ NOTE: CLUT-based monochrome profiles are NOT supported. So, cmsFLAGS_MATRIXINPUT flag is forced on such profiles. [ /CIEBasedA << /DecodeA { transfer function } bind /MatrixA [D50] /RangeLMN [ 0.0 cmsD50X 0.0 cmsD50Y 0.0 cmsD50Z ] /WhitePoint [D50] /BlackPoint [BP] /RenderingIntent (intent) >> ] On simpler profiles, the PCS is already XYZ, so no conversion is required. Matrix-shaper based ------------------- This is implemented both with /CIEBasedABC or /CIEBasedDEF on dependig of profile implementation. Since here there are no interpolation tables, I do the conversion directly to XYZ [ /CIEBasedABC << /DecodeABC [ {transfer1} {transfer2} {transfer3} ] /MatrixABC [Matrix] /RangeLMN [ 0.0 cmsD50X 0.0 cmsD50Y 0.0 cmsD50Z ] /DecodeLMN [ { / 2} dup dup ] /WhitePoint [D50] /BlackPoint [BP] /RenderingIntent (intent) >> ] CLUT based ---------- Lab is used in such cases. [ /CIEBasedDEF << /DecodeDEF [ ] /Table [ p p p [<...>]] /RangeABC [ 0 1 0 1 0 1] /DecodeABC[ ] /RangeLMN [ -0.236 1.254 0 1 -0.635 1.640 ] % -128/500 1+127/500 0 1 -127/200 1+128/200 /MatrixABC [ 1 1 1 1 0 0 0 0 -1] /WhitePoint [D50] /BlackPoint [BP] /RenderingIntent (intent) ] Color Rendering Dictionaries (CRD) ================================== These are always implemented as CLUT, and always are using Lab. Since CRD are expected to be used as resources, the code adds the definition as well. << /ColorRenderingType 1 /WhitePoint [ D50 ] /BlackPoint [BP] /MatrixPQR [ Bradford ] /RangePQR [-0.125 1.375 -0.125 1.375 -0.125 1.375 ] /TransformPQR [ {4 index 3 get div 2 index 3 get mul exch pop exch pop exch pop exch pop } bind {4 index 4 get div 2 index 4 get mul exch pop exch pop exch pop exch pop } bind {4 index 5 get div 2 index 5 get mul exch pop exch pop exch pop exch pop } bind ] /MatrixABC <...> /EncodeABC <...> /RangeABC <.. used for XYZ -> Lab> /EncodeLMN /RenderTable [ p p p [<...>]] /RenderingIntent (Perceptual) >> /Current exch /ColorRendering defineresource pop The following stages are used to convert from XYZ to Lab -------------------------------------------------------- Input is given at LMN stage on X, Y, Z Encode LMN gives us f(X/Xn), f(Y/Yn), f(Z/Zn) /EncodeLMN [ { 0.964200 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind { 1.000000 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind { 0.824900 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind ] MatrixABC is used to compute f(Y/Yn), f(X/Xn) - f(Y/Yn), f(Y/Yn) - f(Z/Zn) | 0 1 0| | 1 -1 0| | 0 1 -1| /MatrixABC [ 0 1 0 1 -1 1 0 0 -1 ] EncodeABC finally gives Lab values. /EncodeABC [ { 116 mul 16 sub 100 div } bind { 500 mul 128 add 255 div } bind { 200 mul 128 add 255 div } bind ] The following stages are used to convert Lab to XYZ ---------------------------------------------------- /RangeABC [ 0 1 0 1 0 1] /DecodeABC [ { 100 mul 16 add 116 div } bind { 255 mul 128 sub 500 div } bind { 255 mul 128 sub 200 div } bind ] /MatrixABC [ 1 1 1 1 0 0 0 0 -1] /DecodeLMN [ {dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 0.964200 mul} bind {dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse } bind {dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 0.824900 mul} bind ] */ /* PostScript algorithms discussion. ========================================================================================================= 1D interpolation algorithm 1D interpolation (float) ------------------------ val2 = Domain * Value; cell0 = (int) floor(val2); cell1 = (int) ceil(val2); rest = val2 - cell0; y0 = LutTable[cell0] ; y1 = LutTable[cell1] ; y = y0 + (y1 - y0) * rest; PostScript code Stack ================================================ { % v [array] % v tab dup % v tab tab length 1 sub % v tab dom 3 -1 roll % tab dom v mul % tab val2 dup % tab val2 val2 dup % tab val2 val2 val2 floor cvi % tab val2 val2 cell0 exch % tab val2 cell0 val2 ceiling cvi % tab val2 cell0 cell1 3 index % tab val2 cell0 cell1 tab exch % tab val2 cell0 tab cell1 get % tab val2 cell0 y1 4 -1 roll % val2 cell0 y1 tab 3 -1 roll % val2 y1 tab cell0 get % val2 y1 y0 dup % val2 y1 y0 y0 3 1 roll % val2 y0 y1 y0 sub % val2 y0 (y1-y0) 3 -1 roll % y0 (y1-y0) val2 dup % y0 (y1-y0) val2 val2 floor cvi % y0 (y1-y0) val2 floor(val2) sub % y0 (y1-y0) rest mul % y0 t1 add % y 65535 div % result } bind */ // This struct holds the memory block currently being write typedef struct { _cmsStageCLutData* Pipeline; cmsIOHANDLER* m; int FirstComponent; int SecondComponent; const char* PreMaj; const char* PostMaj; const char* PreMin; const char* PostMin; int FixWhite; // Force mapping of pure white cmsColorSpaceSignature ColorSpace; // ColorSpace of profile } cmsPsSamplerCargo; static int _cmsPSActualColumn = 0; // Convert to byte static cmsUInt8Number Word2Byte(cmsUInt16Number w) { return (cmsUInt8Number) floor((cmsFloat64Number) w / 257.0 + 0.5); } // Convert to byte (using ICC2 notation) /* static cmsUInt8Number L2Byte(cmsUInt16Number w) { int ww = w + 0x0080; if (ww > 0xFFFF) return 0xFF; return (cmsUInt8Number) ((cmsUInt16Number) (ww >> 8) & 0xFF); } */ // Write a cooked byte static void WriteByte(cmsIOHANDLER* m, cmsUInt8Number b) { _cmsIOPrintf(m, "%02x", b); _cmsPSActualColumn += 2; if (_cmsPSActualColumn > MAXPSCOLS) { _cmsIOPrintf(m, "\n"); _cmsPSActualColumn = 0; } } // ----------------------------------------------------------------- PostScript generation // Removes offending Carriage returns static char* RemoveCR(const char* txt) { static char Buffer[2048]; char* pt; strncpy(Buffer, txt, 2047); Buffer[2047] = 0; for (pt = Buffer; *pt; pt++) if (*pt == '\n' || *pt == '\r') *pt = ' '; return Buffer; } static void EmitHeader(cmsIOHANDLER* m, const char* Title, cmsHPROFILE hProfile) { time_t timer; cmsMLU *Description, *Copyright; char DescASCII[256], CopyrightASCII[256]; time(&timer); Description = (cmsMLU*) cmsReadTag(hProfile, cmsSigProfileDescriptionTag); Copyright = (cmsMLU*) cmsReadTag(hProfile, cmsSigCopyrightTag); DescASCII[0] = DescASCII[255] = 0; CopyrightASCII[0] = CopyrightASCII[255] = 0; if (Description != NULL) cmsMLUgetASCII(Description, cmsNoLanguage, cmsNoCountry, DescASCII, 255); if (Copyright != NULL) cmsMLUgetASCII(Copyright, cmsNoLanguage, cmsNoCountry, CopyrightASCII, 255); _cmsIOPrintf(m, "%%!PS-Adobe-3.0\n"); _cmsIOPrintf(m, "%%\n"); _cmsIOPrintf(m, "%% %s\n", Title); _cmsIOPrintf(m, "%% Source: %s\n", RemoveCR(DescASCII)); _cmsIOPrintf(m, "%% %s\n", RemoveCR(CopyrightASCII)); _cmsIOPrintf(m, "%% Created: %s", ctime(&timer)); // ctime appends a \n!!! _cmsIOPrintf(m, "%%\n"); _cmsIOPrintf(m, "%%%%BeginResource\n"); } // Emits White & Black point. White point is always D50, Black point is the device // Black point adapted to D50. static void EmitWhiteBlackD50(cmsIOHANDLER* m, cmsCIEXYZ* BlackPoint) { _cmsIOPrintf(m, "/BlackPoint [%f %f %f]\n", BlackPoint -> X, BlackPoint -> Y, BlackPoint -> Z); _cmsIOPrintf(m, "/WhitePoint [%f %f %f]\n", cmsD50_XYZ()->X, cmsD50_XYZ()->Y, cmsD50_XYZ()->Z); } static void EmitRangeCheck(cmsIOHANDLER* m) { _cmsIOPrintf(m, "dup 0.0 lt { pop 0.0 } if " "dup 1.0 gt { pop 1.0 } if "); } // Does write the intent static void EmitIntent(cmsIOHANDLER* m, int RenderingIntent) { const char *intent; switch (RenderingIntent) { case INTENT_PERCEPTUAL: intent = "Perceptual"; break; case INTENT_RELATIVE_COLORIMETRIC: intent = "RelativeColorimetric"; break; case INTENT_ABSOLUTE_COLORIMETRIC: intent = "AbsoluteColorimetric"; break; case INTENT_SATURATION: intent = "Saturation"; break; default: intent = "Undefined"; break; } _cmsIOPrintf(m, "/RenderingIntent (%s)\n", intent ); } // // Convert L* to Y // // Y = Yn*[ (L* + 16) / 116] ^ 3 if (L*) >= 6 / 29 // = Yn*( L* / 116) / 7.787 if (L*) < 6 / 29 // /* static void EmitL2Y(cmsIOHANDLER* m) { _cmsIOPrintf(m, "{ " "100 mul 16 add 116 div " // (L * 100 + 16) / 116 "dup 6 29 div ge " // >= 6 / 29 ? "{ dup dup mul mul } " // yes, ^3 and done "{ 4 29 div sub 108 841 div mul } " // no, slope limiting "ifelse } bind "); } */ // Lab -> XYZ, see the discussion above static void EmitLab2XYZ(cmsIOHANDLER* m) { _cmsIOPrintf(m, "/RangeABC [ 0 1 0 1 0 1]\n"); _cmsIOPrintf(m, "/DecodeABC [\n"); _cmsIOPrintf(m, "{100 mul 16 add 116 div } bind\n"); _cmsIOPrintf(m, "{255 mul 128 sub 500 div } bind\n"); _cmsIOPrintf(m, "{255 mul 128 sub 200 div } bind\n"); _cmsIOPrintf(m, "]\n"); _cmsIOPrintf(m, "/MatrixABC [ 1 1 1 1 0 0 0 0 -1]\n"); _cmsIOPrintf(m, "/RangeLMN [ -0.236 1.254 0 1 -0.635 1.640 ]\n"); _cmsIOPrintf(m, "/DecodeLMN [\n"); _cmsIOPrintf(m, "{dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 0.964200 mul} bind\n"); _cmsIOPrintf(m, "{dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse } bind\n"); _cmsIOPrintf(m, "{dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 0.824900 mul} bind\n"); _cmsIOPrintf(m, "]\n"); } // Outputs a table of words. It does use 16 bits static void Emit1Gamma(cmsIOHANDLER* m, cmsToneCurve* Table) { cmsUInt32Number i; cmsFloat64Number gamma; if (Table == NULL) return; // Error if (Table ->nEntries <= 0) return; // Empty table // Suppress whole if identity if (cmsIsToneCurveLinear(Table)) return; // Check if is really an exponential. If so, emit "exp" gamma = cmsEstimateGamma(Table, 0.001); if (gamma > 0) { _cmsIOPrintf(m, "{ %g exp } bind ", gamma); return; } _cmsIOPrintf(m, "{ "); // Bounds check EmitRangeCheck(m); // Emit intepolation code // PostScript code Stack // =============== ======================== // v _cmsIOPrintf(m, " ["); for (i=0; i < Table->nEntries; i++) { _cmsIOPrintf(m, "%d ", Table->Table16[i]); } _cmsIOPrintf(m, "] "); // v tab _cmsIOPrintf(m, "dup "); // v tab tab _cmsIOPrintf(m, "length 1 sub "); // v tab dom _cmsIOPrintf(m, "3 -1 roll "); // tab dom v _cmsIOPrintf(m, "mul "); // tab val2 _cmsIOPrintf(m, "dup "); // tab val2 val2 _cmsIOPrintf(m, "dup "); // tab val2 val2 val2 _cmsIOPrintf(m, "floor cvi "); // tab val2 val2 cell0 _cmsIOPrintf(m, "exch "); // tab val2 cell0 val2 _cmsIOPrintf(m, "ceiling cvi "); // tab val2 cell0 cell1 _cmsIOPrintf(m, "3 index "); // tab val2 cell0 cell1 tab _cmsIOPrintf(m, "exch "); // tab val2 cell0 tab cell1 _cmsIOPrintf(m, "get "); // tab val2 cell0 y1 _cmsIOPrintf(m, "4 -1 roll "); // val2 cell0 y1 tab _cmsIOPrintf(m, "3 -1 roll "); // val2 y1 tab cell0 _cmsIOPrintf(m, "get "); // val2 y1 y0 _cmsIOPrintf(m, "dup "); // val2 y1 y0 y0 _cmsIOPrintf(m, "3 1 roll "); // val2 y0 y1 y0 _cmsIOPrintf(m, "sub "); // val2 y0 (y1-y0) _cmsIOPrintf(m, "3 -1 roll "); // y0 (y1-y0) val2 _cmsIOPrintf(m, "dup "); // y0 (y1-y0) val2 val2 _cmsIOPrintf(m, "floor cvi "); // y0 (y1-y0) val2 floor(val2) _cmsIOPrintf(m, "sub "); // y0 (y1-y0) rest _cmsIOPrintf(m, "mul "); // y0 t1 _cmsIOPrintf(m, "add "); // y _cmsIOPrintf(m, "65535 div "); // result _cmsIOPrintf(m, " } bind "); } // Compare gamma table static cmsBool GammaTableEquals(cmsUInt16Number* g1, cmsUInt16Number* g2, int nEntries) { return memcmp(g1, g2, nEntries* sizeof(cmsUInt16Number)) == 0; } // Does write a set of gamma curves static void EmitNGamma(cmsIOHANDLER* m, int n, cmsToneCurve* g[]) { int i; for( i=0; i < n; i++ ) { if (g[i] == NULL) return; // Error if (i > 0 && GammaTableEquals(g[i-1]->Table16, g[i]->Table16, g[i]->nEntries)) { _cmsIOPrintf(m, "dup "); } else { Emit1Gamma(m, g[i]); } } } // Following code dumps a LUT onto memory stream // This is the sampler. Intended to work in SAMPLER_INSPECT mode, // that is, the callback will be called for each knot with // // In[] The grid location coordinates, normalized to 0..ffff // Out[] The Pipeline values, normalized to 0..ffff // // Returning a value other than 0 does terminate the sampling process // // Each row contains Pipeline values for all but first component. So, I // detect row changing by keeping a copy of last value of first // component. -1 is used to mark begining of whole block. static int OutputValueSampler(register const cmsUInt16Number In[], register cmsUInt16Number Out[], register void* Cargo) { cmsPsSamplerCargo* sc = (cmsPsSamplerCargo*) Cargo; cmsUInt32Number i; if (sc -> FixWhite) { if (In[0] == 0xFFFF) { // Only in L* = 100, ab = [-8..8] if ((In[1] >= 0x7800 && In[1] <= 0x8800) && (In[2] >= 0x7800 && In[2] <= 0x8800)) { cmsUInt16Number* Black; cmsUInt16Number* White; cmsUInt32Number nOutputs; if (!_cmsEndPointsBySpace(sc ->ColorSpace, &White, &Black, &nOutputs)) return 0; for (i=0; i < nOutputs; i++) Out[i] = White[i]; } } } // Hadle the parenthesis on rows if (In[0] != sc ->FirstComponent) { if (sc ->FirstComponent != -1) { _cmsIOPrintf(sc ->m, sc ->PostMin); sc ->SecondComponent = -1; _cmsIOPrintf(sc ->m, sc ->PostMaj); } // Begin block _cmsPSActualColumn = 0; _cmsIOPrintf(sc ->m, sc ->PreMaj); sc ->FirstComponent = In[0]; } if (In[1] != sc ->SecondComponent) { if (sc ->SecondComponent != -1) { _cmsIOPrintf(sc ->m, sc ->PostMin); } _cmsIOPrintf(sc ->m, sc ->PreMin); sc ->SecondComponent = In[1]; } // Dump table. for (i=0; i < sc -> Pipeline ->Params->nOutputs; i++) { cmsUInt16Number wWordOut = Out[i]; cmsUInt8Number wByteOut; // Value as byte // We always deal with Lab4 wByteOut = Word2Byte(wWordOut); WriteByte(sc -> m, wByteOut); } return 1; } // Writes a Pipeline on memstream. Could be 8 or 16 bits based static void WriteCLUT(cmsIOHANDLER* m, cmsStage* mpe, const char* PreMaj, const char* PostMaj, const char* PreMin, const char* PostMin, int FixWhite, cmsColorSpaceSignature ColorSpace) { cmsUInt32Number i; cmsPsSamplerCargo sc; sc.FirstComponent = -1; sc.SecondComponent = -1; sc.Pipeline = (_cmsStageCLutData *) mpe ->Data; sc.m = m; sc.PreMaj = PreMaj; sc.PostMaj= PostMaj; sc.PreMin = PreMin; sc.PostMin = PostMin; sc.FixWhite = FixWhite; sc.ColorSpace = ColorSpace; _cmsIOPrintf(m, "["); for (i=0; i < sc.Pipeline->Params->nInputs; i++) _cmsIOPrintf(m, " %d ", sc.Pipeline->Params->nSamples[i]); _cmsIOPrintf(m, " [\n"); cmsStageSampleCLut16bit(mpe, OutputValueSampler, (void*) &sc, SAMPLER_INSPECT); _cmsIOPrintf(m, PostMin); _cmsIOPrintf(m, PostMaj); _cmsIOPrintf(m, "] "); } // Dumps CIEBasedA Color Space Array static int EmitCIEBasedA(cmsIOHANDLER* m, cmsToneCurve* Curve, cmsCIEXYZ* BlackPoint) { _cmsIOPrintf(m, "[ /CIEBasedA\n"); _cmsIOPrintf(m, " <<\n"); _cmsIOPrintf(m, "/DecodeA "); Emit1Gamma(m, Curve); _cmsIOPrintf(m, " \n"); _cmsIOPrintf(m, "/MatrixA [ 0.9642 1.0000 0.8249 ]\n"); _cmsIOPrintf(m, "/RangeLMN [ 0.0 0.9642 0.0 1.0000 0.0 0.8249 ]\n"); EmitWhiteBlackD50(m, BlackPoint); EmitIntent(m, INTENT_PERCEPTUAL); _cmsIOPrintf(m, ">>\n"); _cmsIOPrintf(m, "]\n"); return 1; } // Dumps CIEBasedABC Color Space Array static int EmitCIEBasedABC(cmsIOHANDLER* m, cmsFloat64Number* Matrix, cmsToneCurve** CurveSet, cmsCIEXYZ* BlackPoint) { int i; _cmsIOPrintf(m, "[ /CIEBasedABC\n"); _cmsIOPrintf(m, "<<\n"); _cmsIOPrintf(m, "/DecodeABC [ "); EmitNGamma(m, 3, CurveSet); _cmsIOPrintf(m, "]\n"); _cmsIOPrintf(m, "/MatrixABC [ " ); for( i=0; i < 3; i++ ) { _cmsIOPrintf(m, "%.6f %.6f %.6f ", Matrix[i + 3*0], Matrix[i + 3*1], Matrix[i + 3*2]); } _cmsIOPrintf(m, "]\n"); _cmsIOPrintf(m, "/RangeLMN [ 0.0 0.9642 0.0 1.0000 0.0 0.8249 ]\n"); EmitWhiteBlackD50(m, BlackPoint); EmitIntent(m, INTENT_PERCEPTUAL); _cmsIOPrintf(m, ">>\n"); _cmsIOPrintf(m, "]\n"); return 1; } static int EmitCIEBasedDEF(cmsIOHANDLER* m, cmsPipeline* Pipeline, int Intent, cmsCIEXYZ* BlackPoint) { const char* PreMaj; const char* PostMaj; const char* PreMin, *PostMin; cmsStage* mpe; mpe = Pipeline ->Elements; switch (cmsStageInputChannels(mpe)) { case 3: _cmsIOPrintf(m, "[ /CIEBasedDEF\n"); PreMaj ="<"; PostMaj= ">\n"; PreMin = PostMin = ""; break; case 4: _cmsIOPrintf(m, "[ /CIEBasedDEFG\n"); PreMaj = "["; PostMaj = "]\n"; PreMin = "<"; PostMin = ">\n"; break; default: return 0; } _cmsIOPrintf(m, "<<\n"); if (cmsStageType(mpe) == cmsSigCurveSetElemType) { _cmsIOPrintf(m, "/DecodeDEF [ "); EmitNGamma(m, cmsStageOutputChannels(mpe), _cmsStageGetPtrToCurveSet(mpe)); _cmsIOPrintf(m, "]\n"); mpe = mpe ->Next; } if (cmsStageType(mpe) == cmsSigCLutElemType) { _cmsIOPrintf(m, "/Table "); WriteCLUT(m, mpe, PreMaj, PostMaj, PreMin, PostMin, FALSE, (cmsColorSpaceSignature) 0); _cmsIOPrintf(m, "]\n"); } EmitLab2XYZ(m); EmitWhiteBlackD50(m, BlackPoint); EmitIntent(m, Intent); _cmsIOPrintf(m, " >>\n"); _cmsIOPrintf(m, "]\n"); return 1; } // Generates a curve from a gray profile static cmsToneCurve* ExtractGray2Y(cmsContext ContextID, cmsHPROFILE hProfile, int Intent) { cmsToneCurve* Out = cmsBuildTabulatedToneCurve16(ContextID, 256, NULL); cmsHPROFILE hXYZ = cmsCreateXYZProfile(); cmsHTRANSFORM xform = cmsCreateTransformTHR(ContextID, hProfile, TYPE_GRAY_8, hXYZ, TYPE_XYZ_DBL, Intent, cmsFLAGS_NOOPTIMIZE); int i; if (Out != NULL) { for (i=0; i < 256; i++) { cmsUInt8Number Gray = (cmsUInt8Number) i; cmsCIEXYZ XYZ; cmsDoTransform(xform, &Gray, &XYZ, 1); Out ->Table16[i] =_cmsQuickSaturateWord(XYZ.Y * 65535.0); } } cmsDeleteTransform(xform); cmsCloseProfile(hXYZ); return Out; } // Because PostScript has only 8 bits in /Table, we should use // a more perceptually uniform space... I do choose Lab. static int WriteInputLUT(cmsIOHANDLER* m, cmsHPROFILE hProfile, int Intent, cmsUInt32Number dwFlags) { cmsHPROFILE hLab; cmsHTRANSFORM xform; cmsUInt32Number nChannels; cmsUInt32Number InputFormat; int rc; cmsHPROFILE Profiles[2]; cmsCIEXYZ BlackPointAdaptedToD50; // Does create a device-link based transform. // The DeviceLink is next dumped as working CSA. InputFormat = cmsFormatterForColorspaceOfProfile(hProfile, 2, FALSE); nChannels = T_CHANNELS(InputFormat); cmsDetectBlackPoint(&BlackPointAdaptedToD50, hProfile, Intent, 0); // Adjust output to Lab4 hLab = cmsCreateLab4ProfileTHR(m ->ContextID, NULL); Profiles[0] = hProfile; Profiles[1] = hLab; xform = cmsCreateMultiprofileTransform(Profiles, 2, InputFormat, TYPE_Lab_DBL, Intent, 0); cmsCloseProfile(hLab); if (xform == NULL) { cmsSignalError(m ->ContextID, cmsERROR_COLORSPACE_CHECK, "Cannot create transform Profile -> Lab"); return 0; } // Only 1, 3 and 4 channels are allowed switch (nChannels) { case 1: { cmsToneCurve* Gray2Y = ExtractGray2Y(m ->ContextID, hProfile, Intent); EmitCIEBasedA(m, Gray2Y, &BlackPointAdaptedToD50); cmsFreeToneCurve(Gray2Y); } break; case 3: case 4: { cmsUInt32Number OutFrm = TYPE_Lab_16; cmsPipeline* DeviceLink; _cmsTRANSFORM* v = (_cmsTRANSFORM*) xform; DeviceLink = cmsPipelineDup(v ->Lut); if (DeviceLink == NULL) return 0; dwFlags |= cmsFLAGS_FORCE_CLUT; _cmsOptimizePipeline(&DeviceLink, Intent, &InputFormat, &OutFrm, &dwFlags); rc = EmitCIEBasedDEF(m, DeviceLink, Intent, &BlackPointAdaptedToD50); cmsPipelineFree(DeviceLink); } break; default: cmsSignalError(m ->ContextID, cmsERROR_COLORSPACE_CHECK, "Only 3, 4 channels supported for CSA. This profile has %d channels.", nChannels); return 0; } cmsDeleteTransform(xform); return 1; } static cmsFloat64Number* GetPtrToMatrix(const cmsStage* mpe) { _cmsStageMatrixData* Data = (_cmsStageMatrixData*) mpe ->Data; return Data -> Double; } // Does create CSA based on matrix-shaper. Allowed types are gray and RGB based static int WriteInputMatrixShaper(cmsIOHANDLER* m, cmsHPROFILE hProfile, cmsStage* Matrix, cmsStage* Shaper) { cmsColorSpaceSignature ColorSpace; int rc; cmsCIEXYZ BlackPointAdaptedToD50; ColorSpace = cmsGetColorSpace(hProfile); cmsDetectBlackPoint(&BlackPointAdaptedToD50, hProfile, INTENT_RELATIVE_COLORIMETRIC, 0); if (ColorSpace == cmsSigGrayData) { cmsToneCurve** ShaperCurve = _cmsStageGetPtrToCurveSet(Shaper); rc = EmitCIEBasedA(m, ShaperCurve[0], &BlackPointAdaptedToD50); } else if (ColorSpace == cmsSigRgbData) { cmsMAT3 Mat; int i, j; memmove(&Mat, GetPtrToMatrix(Matrix), sizeof(Mat)); for (i=0; i < 3; i++) for (j=0; j < 3; j++) Mat.v[i].n[j] *= MAX_ENCODEABLE_XYZ; rc = EmitCIEBasedABC(m, (cmsFloat64Number *) &Mat, _cmsStageGetPtrToCurveSet(Shaper), &BlackPointAdaptedToD50); } else { cmsSignalError(m ->ContextID, cmsERROR_COLORSPACE_CHECK, "Profile is not suitable for CSA. Unsupported colorspace."); return 0; } return rc; } // Creates a PostScript color list from a named profile data. // This is a HP extension, and it works in Lab instead of XYZ static int WriteNamedColorCSA(cmsIOHANDLER* m, cmsHPROFILE hNamedColor, int Intent) { cmsHTRANSFORM xform; cmsHPROFILE hLab; int i, nColors; char ColorName[32]; cmsNAMEDCOLORLIST* NamedColorList; hLab = cmsCreateLab4ProfileTHR(m ->ContextID, NULL); xform = cmsCreateTransform(hNamedColor, TYPE_NAMED_COLOR_INDEX, hLab, TYPE_Lab_DBL, Intent, 0); if (xform == NULL) return 0; NamedColorList = cmsGetNamedColorList(xform); if (NamedColorList == NULL) return 0; _cmsIOPrintf(m, "<<\n"); _cmsIOPrintf(m, "(colorlistcomment) (%s)\n", "Named color CSA"); _cmsIOPrintf(m, "(Prefix) [ (Pantone ) (PANTONE ) ]\n"); _cmsIOPrintf(m, "(Suffix) [ ( CV) ( CVC) ( C) ]\n"); nColors = cmsNamedColorCount(NamedColorList); for (i=0; i < nColors; i++) { cmsUInt16Number In[1]; cmsCIELab Lab; In[0] = (cmsUInt16Number) i; if (!cmsNamedColorInfo(NamedColorList, i, ColorName, NULL, NULL, NULL, NULL)) continue; cmsDoTransform(xform, In, &Lab, 1); _cmsIOPrintf(m, " (%s) [ %.3f %.3f %.3f ]\n", ColorName, Lab.L, Lab.a, Lab.b); } _cmsIOPrintf(m, ">>\n"); cmsDeleteTransform(xform); cmsCloseProfile(hLab); return 1; } // Does create a Color Space Array on XYZ colorspace for PostScript usage static cmsUInt32Number GenerateCSA(cmsContext ContextID, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags, cmsIOHANDLER* mem) { cmsUInt32Number dwBytesUsed; cmsPipeline* lut = NULL; cmsStage* Matrix, *Shaper; // Is a named color profile? if (cmsGetDeviceClass(hProfile) == cmsSigNamedColorClass) { if (!WriteNamedColorCSA(mem, hProfile, Intent)) goto Error; } else { // Any profile class are allowed (including devicelink), but // output (PCS) colorspace must be XYZ or Lab cmsColorSpaceSignature ColorSpace = cmsGetPCS(hProfile); if (ColorSpace != cmsSigXYZData && ColorSpace != cmsSigLabData) { cmsSignalError(ContextID, cmsERROR_COLORSPACE_CHECK, "Invalid output color space"); goto Error; } // Read the lut with all necessary conversion stages lut = _cmsReadInputLUT(hProfile, Intent); if (lut == NULL) goto Error; // Tone curves + matrix can be implemented without any LUT if (cmsPipelineCheckAndRetreiveStages(lut, 2, cmsSigCurveSetElemType, cmsSigMatrixElemType, &Shaper, &Matrix)) { if (!WriteInputMatrixShaper(mem, hProfile, Matrix, Shaper)) goto Error; } else { // We need a LUT for the rest if (!WriteInputLUT(mem, hProfile, Intent, dwFlags)) goto Error; } } // Done, keep memory usage dwBytesUsed = mem ->UsedSpace; // Get rid of LUT if (lut != NULL) cmsPipelineFree(lut); // Finally, return used byte count return dwBytesUsed; Error: if (lut != NULL) cmsPipelineFree(lut); return 0; } // ------------------------------------------------------ Color Rendering Dictionary (CRD) /* Black point compensation plus chromatic adaptation: Step 1 - Chromatic adaptation ============================= WPout X = ------- PQR Wpin Step 2 - Black point compensation ================================= (WPout - BPout)*X - WPout*(BPin - BPout) out = --------------------------------------- WPout - BPin Algorithm discussion ==================== TransformPQR(WPin, BPin, WPout, BPout, PQR) Wpin,etc= { Xws Yws Zws Pws Qws Rws } Algorithm Stack 0...n =========================================================== PQR BPout WPout BPin WPin 4 index 3 get WPin PQR BPout WPout BPin WPin div (PQR/WPin) BPout WPout BPin WPin 2 index 3 get WPout (PQR/WPin) BPout WPout BPin WPin mult WPout*(PQR/WPin) BPout WPout BPin WPin 2 index 3 get WPout WPout*(PQR/WPin) BPout WPout BPin WPin 2 index 3 get BPout WPout WPout*(PQR/WPin) BPout WPout BPin WPin sub (WPout-BPout) WPout*(PQR/WPin) BPout WPout BPin WPin mult (WPout-BPout)* WPout*(PQR/WPin) BPout WPout BPin WPin 2 index 3 get WPout (BPout-WPout)* WPout*(PQR/WPin) BPout WPout BPin WPin 4 index 3 get BPin WPout (BPout-WPout)* WPout*(PQR/WPin) BPout WPout BPin WPin 3 index 3 get BPout BPin WPout (BPout-WPout)* WPout*(PQR/WPin) BPout WPout BPin WPin sub (BPin-BPout) WPout (BPout-WPout)* WPout*(PQR/WPin) BPout WPout BPin WPin mult (BPin-BPout)*WPout (BPout-WPout)* WPout*(PQR/WPin) BPout WPout BPin WPin sub (BPout-WPout)* WPout*(PQR/WPin)-(BPin-BPout)*WPout BPout WPout BPin WPin 3 index 3 get BPin (BPout-WPout)* WPout*(PQR/WPin)-(BPin-BPout)*WPout BPout WPout BPin WPin 3 index 3 get WPout BPin (BPout-WPout)* WPout*(PQR/WPin)-(BPin-BPout)*WPout BPout WPout BPin WPin exch sub (WPout-BPin) (BPout-WPout)* WPout*(PQR/WPin)-(BPin-BPout)*WPout BPout WPout BPin WPin div exch pop exch pop exch pop exch pop */ static void EmitPQRStage(cmsIOHANDLER* m, cmsHPROFILE hProfile, int DoBPC, int lIsAbsolute) { if (lIsAbsolute) { // For absolute colorimetric intent, encode back to relative // and generate a relative Pipeline // Relative encoding is obtained across XYZpcs*(D50/WhitePoint) cmsCIEXYZ White; _cmsReadMediaWhitePoint(&White, hProfile); _cmsIOPrintf(m,"/MatrixPQR [1 0 0 0 1 0 0 0 1 ]\n"); _cmsIOPrintf(m,"/RangePQR [ -0.5 2 -0.5 2 -0.5 2 ]\n"); _cmsIOPrintf(m, "%% Absolute colorimetric -- encode to relative to maximize LUT usage\n" "/TransformPQR [\n" "{0.9642 mul %g div exch pop exch pop exch pop exch pop} bind\n" "{1.0000 mul %g div exch pop exch pop exch pop exch pop} bind\n" "{0.8249 mul %g div exch pop exch pop exch pop exch pop} bind\n]\n", White.X, White.Y, White.Z); return; } _cmsIOPrintf(m,"%% Bradford Cone Space\n" "/MatrixPQR [0.8951 -0.7502 0.0389 0.2664 1.7135 -0.0685 -0.1614 0.0367 1.0296 ] \n"); _cmsIOPrintf(m, "/RangePQR [ -0.5 2 -0.5 2 -0.5 2 ]\n"); // No BPC if (!DoBPC) { _cmsIOPrintf(m, "%% VonKries-like transform in Bradford Cone Space\n" "/TransformPQR [\n" "{exch pop exch 3 get mul exch pop exch 3 get div} bind\n" "{exch pop exch 4 get mul exch pop exch 4 get div} bind\n" "{exch pop exch 5 get mul exch pop exch 5 get div} bind\n]\n"); } else { // BPC _cmsIOPrintf(m, "%% VonKries-like transform in Bradford Cone Space plus BPC\n" "/TransformPQR [\n"); _cmsIOPrintf(m, "{4 index 3 get div 2 index 3 get mul " "2 index 3 get 2 index 3 get sub mul " "2 index 3 get 4 index 3 get 3 index 3 get sub mul sub " "3 index 3 get 3 index 3 get exch sub div " "exch pop exch pop exch pop exch pop } bind\n"); _cmsIOPrintf(m, "{4 index 4 get div 2 index 4 get mul " "2 index 4 get 2 index 4 get sub mul " "2 index 4 get 4 index 4 get 3 index 4 get sub mul sub " "3 index 4 get 3 index 4 get exch sub div " "exch pop exch pop exch pop exch pop } bind\n"); _cmsIOPrintf(m, "{4 index 5 get div 2 index 5 get mul " "2 index 5 get 2 index 5 get sub mul " "2 index 5 get 4 index 5 get 3 index 5 get sub mul sub " "3 index 5 get 3 index 5 get exch sub div " "exch pop exch pop exch pop exch pop } bind\n]\n"); } } static void EmitXYZ2Lab(cmsIOHANDLER* m) { _cmsIOPrintf(m, "/RangeLMN [ -0.635 2.0 0 2 -0.635 2.0 ]\n"); _cmsIOPrintf(m, "/EncodeLMN [\n"); _cmsIOPrintf(m, "{ 0.964200 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind\n"); _cmsIOPrintf(m, "{ 1.000000 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind\n"); _cmsIOPrintf(m, "{ 0.824900 div dup 0.008856 le {7.787 mul 16 116 div add}{1 3 div exp} ifelse } bind\n"); _cmsIOPrintf(m, "]\n"); _cmsIOPrintf(m, "/MatrixABC [ 0 1 0 1 -1 1 0 0 -1 ]\n"); _cmsIOPrintf(m, "/EncodeABC [\n"); _cmsIOPrintf(m, "{ 116 mul 16 sub 100 div } bind\n"); _cmsIOPrintf(m, "{ 500 mul 128 add 256 div } bind\n"); _cmsIOPrintf(m, "{ 200 mul 128 add 256 div } bind\n"); _cmsIOPrintf(m, "]\n"); } // Due to impedance mismatch between XYZ and almost all RGB and CMYK spaces // I choose to dump LUTS in Lab instead of XYZ. There is still a lot of wasted // space on 3D CLUT, but since space seems not to be a problem here, 33 points // would give a reasonable accurancy. Note also that CRD tables must operate in // 8 bits. static int WriteOutputLUT(cmsIOHANDLER* m, cmsHPROFILE hProfile, int Intent, cmsUInt32Number dwFlags) { cmsHPROFILE hLab; cmsHTRANSFORM xform; int i, nChannels; cmsUInt32Number OutputFormat; _cmsTRANSFORM* v; cmsPipeline* DeviceLink; cmsHPROFILE Profiles[3]; cmsCIEXYZ BlackPointAdaptedToD50; cmsBool lDoBPC = (dwFlags & cmsFLAGS_BLACKPOINTCOMPENSATION); cmsBool lFixWhite = !(dwFlags & cmsFLAGS_NOWHITEONWHITEFIXUP); cmsUInt32Number InFrm = TYPE_Lab_16; int RelativeEncodingIntent; cmsColorSpaceSignature ColorSpace; hLab = cmsCreateLab4ProfileTHR(m ->ContextID, NULL); if (hLab == NULL) return 0; OutputFormat = cmsFormatterForColorspaceOfProfile(hProfile, 2, FALSE); nChannels = T_CHANNELS(OutputFormat); ColorSpace = cmsGetColorSpace(hProfile); // For absolute colorimetric, the LUT is encoded as relative in order to preserve precision. RelativeEncodingIntent = Intent; if (RelativeEncodingIntent == INTENT_ABSOLUTE_COLORIMETRIC) RelativeEncodingIntent = INTENT_RELATIVE_COLORIMETRIC; // Use V4 Lab always Profiles[0] = hLab; Profiles[1] = hProfile; xform = cmsCreateMultiprofileTransformTHR(m ->ContextID, Profiles, 2, TYPE_Lab_DBL, OutputFormat, RelativeEncodingIntent, 0); cmsCloseProfile(hLab); if (xform == NULL) { cmsSignalError(m ->ContextID, cmsERROR_COLORSPACE_CHECK, "Cannot create transform Lab -> Profile in CRD creation"); return 0; } // Get a copy of the internal devicelink v = (_cmsTRANSFORM*) xform; DeviceLink = cmsPipelineDup(v ->Lut); if (DeviceLink == NULL) return 0; // We need a CLUT dwFlags |= cmsFLAGS_FORCE_CLUT; _cmsOptimizePipeline(&DeviceLink, RelativeEncodingIntent, &InFrm, &OutputFormat, &dwFlags); _cmsIOPrintf(m, "<<\n"); _cmsIOPrintf(m, "/ColorRenderingType 1\n"); cmsDetectBlackPoint(&BlackPointAdaptedToD50, hProfile, Intent, 0); // Emit headers, etc. EmitWhiteBlackD50(m, &BlackPointAdaptedToD50); EmitPQRStage(m, hProfile, lDoBPC, Intent == INTENT_ABSOLUTE_COLORIMETRIC); EmitXYZ2Lab(m); // FIXUP: map Lab (100, 0, 0) to perfect white, because the particular encoding for Lab // does map a=b=0 not falling into any specific node. Since range a,b goes -128..127, // zero is slightly moved towards right, so assure next node (in L=100 slice) is mapped to // zero. This would sacrifice a bit of highlights, but failure to do so would cause // scum dot. Ouch. if (Intent == INTENT_ABSOLUTE_COLORIMETRIC) lFixWhite = FALSE; _cmsIOPrintf(m, "/RenderTable "); WriteCLUT(m, cmsPipelineGetPtrToFirstStage(DeviceLink), "<", ">\n", "", "", lFixWhite, ColorSpace); _cmsIOPrintf(m, " %d {} bind ", nChannels); for (i=1; i < nChannels; i++) _cmsIOPrintf(m, "dup "); _cmsIOPrintf(m, "]\n"); EmitIntent(m, Intent); _cmsIOPrintf(m, ">>\n"); if (!(dwFlags & cmsFLAGS_NODEFAULTRESOURCEDEF)) { _cmsIOPrintf(m, "/Current exch /ColorRendering defineresource pop\n"); } cmsPipelineFree(DeviceLink); cmsDeleteTransform(xform); return 1; } // Builds a ASCII string containing colorant list in 0..1.0 range static void BuildColorantList(char *Colorant, int nColorant, cmsUInt16Number Out[]) { char Buff[32]; int j; Colorant[0] = 0; if (nColorant > cmsMAXCHANNELS) nColorant = cmsMAXCHANNELS; for (j=0; j < nColorant; j++) { sprintf(Buff, "%.3f", Out[j] / 65535.0); strcat(Colorant, Buff); if (j < nColorant -1) strcat(Colorant, " "); } } // Creates a PostScript color list from a named profile data. // This is a HP extension. static int WriteNamedColorCRD(cmsIOHANDLER* m, cmsHPROFILE hNamedColor, int Intent, cmsUInt32Number dwFlags) { cmsHTRANSFORM xform; int i, nColors, nColorant; cmsUInt32Number OutputFormat; char ColorName[32]; char Colorant[128]; cmsNAMEDCOLORLIST* NamedColorList; OutputFormat = cmsFormatterForColorspaceOfProfile(hNamedColor, 2, FALSE); nColorant = T_CHANNELS(OutputFormat); xform = cmsCreateTransform(hNamedColor, TYPE_NAMED_COLOR_INDEX, NULL, OutputFormat, Intent, dwFlags); if (xform == NULL) return 0; NamedColorList = cmsGetNamedColorList(xform); if (NamedColorList == NULL) return 0; _cmsIOPrintf(m, "<<\n"); _cmsIOPrintf(m, "(colorlistcomment) (%s) \n", "Named profile"); _cmsIOPrintf(m, "(Prefix) [ (Pantone ) (PANTONE ) ]\n"); _cmsIOPrintf(m, "(Suffix) [ ( CV) ( CVC) ( C) ]\n"); nColors = cmsNamedColorCount(NamedColorList); for (i=0; i < nColors; i++) { cmsUInt16Number In[1]; cmsUInt16Number Out[cmsMAXCHANNELS]; In[0] = (cmsUInt16Number) i; if (!cmsNamedColorInfo(NamedColorList, i, ColorName, NULL, NULL, NULL, NULL)) continue; cmsDoTransform(xform, In, Out, 1); BuildColorantList(Colorant, nColorant, Out); _cmsIOPrintf(m, " (%s) [ %s ]\n", ColorName, Colorant); } _cmsIOPrintf(m, " >>"); if (!(dwFlags & cmsFLAGS_NODEFAULTRESOURCEDEF)) { _cmsIOPrintf(m, " /Current exch /HPSpotTable defineresource pop\n"); } cmsDeleteTransform(xform); return 1; } // This one does create a Color Rendering Dictionary. // CRD are always LUT-Based, no matter if profile is // implemented as matrix-shaper. static cmsUInt32Number GenerateCRD(cmsContext ContextID, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags, cmsIOHANDLER* mem) { cmsUInt32Number dwBytesUsed; if (!(dwFlags & cmsFLAGS_NODEFAULTRESOURCEDEF)) { EmitHeader(mem, "Color Rendering Dictionary (CRD)", hProfile); } // Is a named color profile? if (cmsGetDeviceClass(hProfile) == cmsSigNamedColorClass) { if (!WriteNamedColorCRD(mem, hProfile, Intent, dwFlags)) { return 0; } } else { // CRD are always implemented as LUT if (!WriteOutputLUT(mem, hProfile, Intent, dwFlags)) { return 0; } } if (!(dwFlags & cmsFLAGS_NODEFAULTRESOURCEDEF)) { _cmsIOPrintf(mem, "%%%%EndResource\n"); _cmsIOPrintf(mem, "\n%% CRD End\n"); } // Done, keep memory usage dwBytesUsed = mem ->UsedSpace; // Finally, return used byte count return dwBytesUsed; cmsUNUSED_PARAMETER(ContextID); } cmsUInt32Number CMSEXPORT cmsGetPostScriptColorResource(cmsContext ContextID, cmsPSResourceType Type, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags, cmsIOHANDLER* io) { cmsUInt32Number rc; switch (Type) { case cmsPS_RESOURCE_CSA: rc = GenerateCSA(ContextID, hProfile, Intent, dwFlags, io); break; default: case cmsPS_RESOURCE_CRD: rc = GenerateCRD(ContextID, hProfile, Intent, dwFlags, io); break; } return rc; } cmsUInt32Number CMSEXPORT cmsGetPostScriptCRD(cmsContext ContextID, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags, void* Buffer, cmsUInt32Number dwBufferLen) { cmsIOHANDLER* mem; cmsUInt32Number dwBytesUsed; // Set up the serialization engine if (Buffer == NULL) mem = cmsOpenIOhandlerFromNULL(ContextID); else mem = cmsOpenIOhandlerFromMem(ContextID, Buffer, dwBufferLen, "w"); if (!mem) return 0; dwBytesUsed = cmsGetPostScriptColorResource(ContextID, cmsPS_RESOURCE_CRD, hProfile, Intent, dwFlags, mem); // Get rid of memory stream cmsCloseIOhandler(mem); return dwBytesUsed; } // Does create a Color Space Array on XYZ colorspace for PostScript usage cmsUInt32Number CMSEXPORT cmsGetPostScriptCSA(cmsContext ContextID, cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number dwFlags, void* Buffer, cmsUInt32Number dwBufferLen) { cmsIOHANDLER* mem; cmsUInt32Number dwBytesUsed; if (Buffer == NULL) mem = cmsOpenIOhandlerFromNULL(ContextID); else mem = cmsOpenIOhandlerFromMem(ContextID, Buffer, dwBufferLen, "w"); if (!mem) return 0; dwBytesUsed = cmsGetPostScriptColorResource(ContextID, cmsPS_RESOURCE_CSA, hProfile, Intent, dwFlags, mem); // Get rid of memory stream cmsCloseIOhandler(mem); return dwBytesUsed; }