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//---------------------------------------------------------------------------------
//
// 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"
// Read tags using low-level functions, provides necessary glue code to adapt versions, etc.
// LUT tags
static const cmsTagSignature Device2PCS16[] = {cmsSigAToB0Tag, // Perceptual
cmsSigAToB1Tag, // Relative colorimetric
cmsSigAToB2Tag, // Saturation
cmsSigAToB1Tag }; // Absolute colorimetric
static const cmsTagSignature Device2PCSFloat[] = {cmsSigDToB0Tag, // Perceptual
cmsSigDToB1Tag, // Relative colorimetric
cmsSigDToB2Tag, // Saturation
cmsSigDToB3Tag }; // Absolute colorimetric
static const cmsTagSignature PCS2Device16[] = {cmsSigBToA0Tag, // Perceptual
cmsSigBToA1Tag, // Relative colorimetric
cmsSigBToA2Tag, // Saturation
cmsSigBToA1Tag }; // Absolute colorimetric
static const cmsTagSignature PCS2DeviceFloat[] = {cmsSigBToD0Tag, // Perceptual
cmsSigBToD1Tag, // Relative colorimetric
cmsSigBToD2Tag, // Saturation
cmsSigBToD3Tag }; // Absolute colorimetric
// Factors to convert from 1.15 fixed point to 0..1.0 range and vice-versa
#define InpAdj (1.0/MAX_ENCODEABLE_XYZ) // (65536.0/(65535.0*2.0))
#define OutpAdj (MAX_ENCODEABLE_XYZ) // ((2.0*65535.0)/65536.0)
// Several resources for gray conversions.
static const cmsFloat64Number GrayInputMatrix[] = { (InpAdj*cmsD50X), (InpAdj*cmsD50Y), (InpAdj*cmsD50Z) };
static const cmsFloat64Number OneToThreeInputMatrix[] = { 1, 1, 1 };
static const cmsFloat64Number PickYMatrix[] = { 0, (OutpAdj*cmsD50Y), 0 };
static const cmsFloat64Number PickLstarMatrix[] = { 1, 0, 0 };
// Get a media white point fixing some issues found in certain old profiles
cmsBool _cmsReadMediaWhitePoint(cmsCIEXYZ* Dest, cmsHPROFILE hProfile)
{
cmsCIEXYZ* Tag;
_cmsAssert(Dest != NULL);
Tag = (cmsCIEXYZ*) cmsReadTag(hProfile, cmsSigMediaWhitePointTag);
// If no wp, take D50
if (Tag == NULL) {
*Dest = *cmsD50_XYZ();
return TRUE;
}
// V2 display profiles should give D50
if (cmsGetEncodedICCversion(hProfile) < 0x4000000) {
if (cmsGetDeviceClass(hProfile) == cmsSigDisplayClass) {
*Dest = *cmsD50_XYZ();
return TRUE;
}
}
// All seems ok
*Dest = *Tag;
return TRUE;
}
// Chromatic adaptation matrix. Fix some issues as well
cmsBool _cmsReadCHAD(cmsMAT3* Dest, cmsHPROFILE hProfile)
{
cmsMAT3* Tag;
_cmsAssert(Dest != NULL);
Tag = (cmsMAT3*) cmsReadTag(hProfile, cmsSigChromaticAdaptationTag);
if (Tag != NULL) {
*Dest = *Tag;
return TRUE;
}
// No CHAD available, default it to identity
_cmsMAT3identity(Dest);
// V2 display profiles should give D50
if (cmsGetEncodedICCversion(hProfile) < 0x4000000) {
if (cmsGetDeviceClass(hProfile) == cmsSigDisplayClass) {
cmsCIEXYZ* White = (cmsCIEXYZ*) cmsReadTag(hProfile, cmsSigMediaWhitePointTag);
if (White == NULL) {
_cmsMAT3identity(Dest);
return TRUE;
}
return _cmsAdaptationMatrix(Dest, NULL, cmsD50_XYZ(), White);
}
}
return TRUE;
}
// Auxiliar, read colorants as a MAT3 structure. Used by any function that needs a matrix-shaper
static
cmsBool ReadICCMatrixRGB2XYZ(cmsMAT3* r, cmsHPROFILE hProfile)
{
cmsCIEXYZ *PtrRed, *PtrGreen, *PtrBlue;
_cmsAssert(r != NULL);
PtrRed = (cmsCIEXYZ *) cmsReadTag(hProfile, cmsSigRedColorantTag);
PtrGreen = (cmsCIEXYZ *) cmsReadTag(hProfile, cmsSigGreenColorantTag);
PtrBlue = (cmsCIEXYZ *) cmsReadTag(hProfile, cmsSigBlueColorantTag);
if (PtrRed == NULL || PtrGreen == NULL || PtrBlue == NULL)
return FALSE;
_cmsVEC3init(&r -> v[0], PtrRed -> X, PtrGreen -> X, PtrBlue -> X);
_cmsVEC3init(&r -> v[1], PtrRed -> Y, PtrGreen -> Y, PtrBlue -> Y);
_cmsVEC3init(&r -> v[2], PtrRed -> Z, PtrGreen -> Z, PtrBlue -> Z);
return TRUE;
}
// Gray input pipeline
static
cmsPipeline* BuildGrayInputMatrixPipeline(cmsHPROFILE hProfile)
{
cmsToneCurve *GrayTRC;
cmsPipeline* Lut;
cmsContext ContextID = cmsGetProfileContextID(hProfile);
GrayTRC = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigGrayTRCTag);
if (GrayTRC == NULL) return NULL;
Lut = cmsPipelineAlloc(ContextID, 1, 3);
if (Lut == NULL) return NULL;
if (cmsGetPCS(hProfile) == cmsSigLabData) {
// In this case we implement the profile as an identity matrix plus 3 tone curves
cmsUInt16Number Zero[2] = { 0x8080, 0x8080 };
cmsToneCurve* EmptyTab;
cmsToneCurve* LabCurves[3];
EmptyTab = cmsBuildTabulatedToneCurve16(ContextID, 2, Zero);
if (EmptyTab == NULL) {
cmsPipelineFree(Lut);
return NULL;
}
LabCurves[0] = GrayTRC;
LabCurves[1] = EmptyTab;
LabCurves[2] = EmptyTab;
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 3, 1, OneToThreeInputMatrix, NULL));
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocToneCurves(ContextID, 3, LabCurves));
cmsFreeToneCurve(EmptyTab);
}
else {
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocToneCurves(ContextID, 1, &GrayTRC));
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 3, 1, GrayInputMatrix, NULL));
}
return Lut;
}
// RGB Matrix shaper
static
cmsPipeline* BuildRGBInputMatrixShaper(cmsHPROFILE hProfile)
{
cmsPipeline* Lut;
cmsMAT3 Mat;
cmsToneCurve *Shapes[3];
cmsContext ContextID = cmsGetProfileContextID(hProfile);
int i, j;
if (!ReadICCMatrixRGB2XYZ(&Mat, hProfile)) return NULL;
// XYZ PCS in encoded in 1.15 format, and the matrix output comes in 0..0xffff range, so
// we need to adjust the output by a factor of (0x10000/0xffff) to put data in
// a 1.16 range, and then a >> 1 to obtain 1.15. The total factor is (65536.0)/(65535.0*2)
for (i=0; i < 3; i++)
for (j=0; j < 3; j++)
Mat.v[i].n[j] *= InpAdj;
Shapes[0] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigRedTRCTag);
Shapes[1] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigGreenTRCTag);
Shapes[2] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigBlueTRCTag);
if (!Shapes[0] || !Shapes[1] || !Shapes[2])
return NULL;
Lut = cmsPipelineAlloc(ContextID, 3, 3);
if (Lut != NULL) {
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocToneCurves(ContextID, 3, Shapes));
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 3, 3, (cmsFloat64Number*) &Mat, NULL));
}
return Lut;
}
// Read and create a BRAND NEW MPE LUT from a given profile. All stuff dependent of version, etc
// is adjusted here in order to create a LUT that takes care of all those details
cmsPipeline* _cmsReadInputLUT(cmsHPROFILE hProfile, int Intent)
{
cmsTagTypeSignature OriginalType;
cmsTagSignature tag16 = Device2PCS16[Intent];
cmsTagSignature tagFloat = Device2PCSFloat[Intent];
cmsContext ContextID = cmsGetProfileContextID(hProfile);
// On named color, take the appropiate tag
if (cmsGetDeviceClass(hProfile) == cmsSigNamedColorClass) {
cmsPipeline* Lut;
cmsNAMEDCOLORLIST* nc = (cmsNAMEDCOLORLIST*) cmsReadTag(hProfile, cmsSigNamedColor2Tag);
if (nc == NULL) return NULL;
Lut = cmsPipelineAlloc(ContextID, 0, 0);
if (Lut == NULL) {
cmsFreeNamedColorList(nc);
return NULL;
}
cmsPipelineInsertStage(Lut, cmsAT_BEGIN, _cmsStageAllocNamedColor(nc, TRUE));
cmsPipelineInsertStage(Lut, cmsAT_END, _cmsStageAllocLabV2ToV4(ContextID));
return Lut;
}
if (cmsIsTag(hProfile, tagFloat)) { // Float tag takes precedence
// Floating point LUT are always V4, so no adjustment is required
return cmsPipelineDup((cmsPipeline*) cmsReadTag(hProfile, tagFloat));
}
// Revert to perceptual if no tag is found
if (!cmsIsTag(hProfile, tag16)) {
tag16 = Device2PCS16[0];
}
if (cmsIsTag(hProfile, tag16)) { // Is there any LUT-Based table?
// Check profile version and LUT type. Do the necessary adjustments if needed
// First read the tag
cmsPipeline* Lut = (cmsPipeline*) cmsReadTag(hProfile, tag16);
if (Lut == NULL) return NULL;
// After reading it, we have now info about the original type
OriginalType = _cmsGetTagTrueType(hProfile, tag16);
// The profile owns the Lut, so we need to copy it
Lut = cmsPipelineDup(Lut);
// We need to adjust data only for Lab16 on output
if (OriginalType != cmsSigLut16Type || cmsGetPCS(hProfile) != cmsSigLabData)
return Lut;
// If the input is Lab, add also a conversion at the begin
if (cmsGetColorSpace(hProfile) == cmsSigLabData)
cmsPipelineInsertStage(Lut, cmsAT_BEGIN, _cmsStageAllocLabV4ToV2(ContextID));
// Add a matrix for conversion V2 to V4 Lab PCS
cmsPipelineInsertStage(Lut, cmsAT_END, _cmsStageAllocLabV2ToV4(ContextID));
return Lut;
}
// Lut was not found, try to create a matrix-shaper
// Check if this is a grayscale profile.
if (cmsGetColorSpace(hProfile) == cmsSigGrayData) {
// if so, build appropiate conversion tables.
// The tables are the PCS iluminant, scaled across GrayTRC
return BuildGrayInputMatrixPipeline(hProfile);
}
// Not gray, create a normal matrix-shaper
return BuildRGBInputMatrixShaper(hProfile);
}
// ---------------------------------------------------------------------------------------------------------------
// Gray output pipeline.
// XYZ -> Gray or Lab -> Gray. Since we only know the GrayTRC, we need to do some assumptions. Gray component will be
// given by Y on XYZ PCS and by L* on Lab PCS, Both across inverse TRC curve.
// The complete pipeline on XYZ is Matrix[3:1] -> Tone curve and in Lab Matrix[3:1] -> Tone Curve as well.
static
cmsPipeline* BuildGrayOutputPipeline(cmsHPROFILE hProfile)
{
cmsToneCurve *GrayTRC, *RevGrayTRC;
cmsPipeline* Lut;
cmsContext ContextID = cmsGetProfileContextID(hProfile);
GrayTRC = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigGrayTRCTag);
if (GrayTRC == NULL) return NULL;
RevGrayTRC = cmsReverseToneCurve(GrayTRC);
if (RevGrayTRC == NULL) return NULL;
Lut = cmsPipelineAlloc(ContextID, 3, 1);
if (Lut == NULL) {
cmsFreeToneCurve(RevGrayTRC);
return NULL;
}
if (cmsGetPCS(hProfile) == cmsSigLabData) {
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 1, 3, PickLstarMatrix, NULL));
}
else {
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 1, 3, PickYMatrix, NULL));
}
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocToneCurves(ContextID, 1, &RevGrayTRC));
cmsFreeToneCurve(RevGrayTRC);
return Lut;
}
static
cmsPipeline* BuildRGBOutputMatrixShaper(cmsHPROFILE hProfile)
{
cmsPipeline* Lut;
cmsToneCurve *Shapes[3], *InvShapes[3];
cmsMAT3 Mat, Inv;
int i, j;
cmsContext ContextID = cmsGetProfileContextID(hProfile);
if (!ReadICCMatrixRGB2XYZ(&Mat, hProfile))
return NULL;
if (!_cmsMAT3inverse(&Mat, &Inv))
return NULL;
// XYZ PCS in encoded in 1.15 format, and the matrix input should come in 0..0xffff range, so
// we need to adjust the input by a << 1 to obtain a 1.16 fixed and then by a factor of
// (0xffff/0x10000) to put data in 0..0xffff range. Total factor is (2.0*65535.0)/65536.0;
for (i=0; i < 3; i++)
for (j=0; j < 3; j++)
Inv.v[i].n[j] *= OutpAdj;
Shapes[0] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigRedTRCTag);
Shapes[1] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigGreenTRCTag);
Shapes[2] = (cmsToneCurve *) cmsReadTag(hProfile, cmsSigBlueTRCTag);
if (!Shapes[0] || !Shapes[1] || !Shapes[2])
return NULL;
InvShapes[0] = cmsReverseToneCurve(Shapes[0]);
InvShapes[1] = cmsReverseToneCurve(Shapes[1]);
InvShapes[2] = cmsReverseToneCurve(Shapes[2]);
if (!InvShapes[0] || !InvShapes[1] || !InvShapes[2]) {
return NULL;
}
Lut = cmsPipelineAlloc(ContextID, 3, 3);
if (Lut != NULL) {
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocMatrix(ContextID, 3, 3, (cmsFloat64Number*) &Inv, NULL));
cmsPipelineInsertStage(Lut, cmsAT_END, cmsStageAllocToneCurves(ContextID, 3, InvShapes));
}
cmsFreeToneCurveTriple(InvShapes);
return Lut;
}
// Change CLUT interpolation to trilinear
static
void ChangeInterpolationToTrilinear(cmsPipeline* Lut)
{
cmsStage* Stage;
for (Stage = cmsPipelineGetPtrToFirstStage(Lut);
Stage != NULL;
Stage = cmsStageNext(Stage)) {
if (cmsStageType(Stage) == cmsSigCLutElemType) {
_cmsStageCLutData* CLUT = (_cmsStageCLutData*) Stage ->Data;
CLUT ->Params->dwFlags |= CMS_LERP_FLAGS_TRILINEAR;
_cmsSetInterpolationRoutine(CLUT ->Params);
}
}
}
// Create an output MPE LUT from agiven profile. Version mismatches are handled here
cmsPipeline* _cmsReadOutputLUT(cmsHPROFILE hProfile, int Intent)
{
cmsTagTypeSignature OriginalType;
cmsTagSignature tag16 = PCS2Device16[Intent];
cmsTagSignature tagFloat = PCS2DeviceFloat[Intent];
cmsContext ContextID = cmsGetProfileContextID(hProfile);
if (cmsIsTag(hProfile, tagFloat)) { // Float tag takes precedence
// Floating point LUT are always V4, so no adjustment is required
return cmsPipelineDup((cmsPipeline*) cmsReadTag(hProfile, tagFloat));
}
// Revert to perceptual if no tag is found
if (!cmsIsTag(hProfile, tag16)) {
tag16 = PCS2Device16[0];
}
if (cmsIsTag(hProfile, tag16)) { // Is there any LUT-Based table?
// Check profile version and LUT type. Do the necessary adjustments if needed
// First read the tag
cmsPipeline* Lut = (cmsPipeline*) cmsReadTag(hProfile, tag16);
if (Lut == NULL) return NULL;
// After reading it, we have info about the original type
OriginalType = _cmsGetTagTrueType(hProfile, tag16);
// The profile owns the Lut, so we need to copy it
Lut = cmsPipelineDup(Lut);
if (Lut == NULL) return NULL;
// Now it is time for a controversial stuff. I found that for 3D LUTS using
// Lab used as indexer space, trilinear interpolation should be used
if (cmsGetPCS(hProfile) == cmsSigLabData)
ChangeInterpolationToTrilinear(Lut);
// We need to adjust data only for Lab and Lut16 type
if (OriginalType != cmsSigLut16Type || cmsGetPCS(hProfile) != cmsSigLabData)
return Lut;
// Add a matrix for conversion V4 to V2 Lab PCS
cmsPipelineInsertStage(Lut, cmsAT_BEGIN, _cmsStageAllocLabV4ToV2(ContextID));
// If the output is Lab, add also a conversion at the end
if (cmsGetColorSpace(hProfile) == cmsSigLabData)
cmsPipelineInsertStage(Lut, cmsAT_END, _cmsStageAllocLabV2ToV4(ContextID));
return Lut;
}
// Lut not found, try to create a matrix-shaper
// Check if this is a grayscale profile.
if (cmsGetColorSpace(hProfile) == cmsSigGrayData) {
// if so, build appropiate conversion tables.
// The tables are the PCS iluminant, scaled across GrayTRC
return BuildGrayOutputPipeline(hProfile);
}
// Not gray, create a normal matrix-shaper
return BuildRGBOutputMatrixShaper(hProfile);
}
// ---------------------------------------------------------------------------------------------------------------
// This one includes abstract profiles as well. Matrix-shaper cannot be obtained on that device class. The
// tag name here may default to AToB0
cmsPipeline* _cmsReadDevicelinkLUT(cmsHPROFILE hProfile, int Intent)
{
cmsPipeline* Lut;
cmsTagTypeSignature OriginalType;
cmsTagSignature tag16 = Device2PCS16[Intent];
cmsTagSignature tagFloat = Device2PCSFloat[Intent];
cmsContext ContextID = cmsGetProfileContextID(hProfile);
// On named color, take the appropiate tag
if (cmsGetDeviceClass(hProfile) == cmsSigNamedColorClass) {
cmsNAMEDCOLORLIST* nc = (cmsNAMEDCOLORLIST*) cmsReadTag(hProfile, cmsSigNamedColor2Tag);
if (nc == NULL) return NULL;
Lut = cmsPipelineAlloc(ContextID, 0, 0);
if (Lut == NULL) {
cmsFreeNamedColorList(nc);
return NULL;
}
cmsPipelineInsertStage(Lut, cmsAT_BEGIN, _cmsStageAllocNamedColor(nc, FALSE));
if (cmsGetColorSpace(hProfile) == cmsSigLabData)
cmsPipelineInsertStage(Lut, cmsAT_END, _cmsStageAllocLabV2ToV4(ContextID));
return Lut;
}
if (cmsIsTag(hProfile, tagFloat)) { // Float tag takes precedence
// Floating point LUT are always V4, no adjustment is required
return cmsPipelineDup((cmsPipeline*) cmsReadTag(hProfile, tagFloat));
}
tagFloat = Device2PCSFloat[0];
if (cmsIsTag(hProfile, tagFloat)) {
return cmsPipelineDup((cmsPipeline*) cmsReadTag(hProfile, tagFloat));
}
if (!cmsIsTag(hProfile, tag16)) { // Is there any LUT-Based table?
tag16 = Device2PCS16[0];
if (!cmsIsTag(hProfile, tag16)) return NULL;
}
// Check profile version and LUT type. Do the necessary adjustments if needed
// Read the tag
Lut = (cmsPipeline*) cmsReadTag(hProfile, tag16);
if (Lut == NULL) return NULL;
// The profile owns the Lut, so we need to copy it
Lut = cmsPipelineDup(Lut);
if (Lut == NULL) return NULL;
// Now it is time for a controversial stuff. I found that for 3D LUTS using
// Lab used as indexer space, trilinear interpolation should be used
if (cmsGetColorSpace(hProfile) == cmsSigLabData)
ChangeInterpolationToTrilinear(Lut);
// After reading it, we have info about the original type
OriginalType = _cmsGetTagTrueType(hProfile, tag16);
// We need to adjust data for Lab16 on output
if (OriginalType != cmsSigLut16Type) return Lut;
// Here it is possible to get Lab on both sides
if (cmsGetPCS(hProfile) == cmsSigLabData) {
cmsPipelineInsertStage(Lut, cmsAT_BEGIN, _cmsStageAllocLabV4ToV2(ContextID));
}
if (cmsGetColorSpace(hProfile) == cmsSigLabData) {
cmsPipelineInsertStage(Lut, cmsAT_END, _cmsStageAllocLabV2ToV4(ContextID));
}
return Lut;
}
// ---------------------------------------------------------------------------------------------------------------
// Returns TRUE if the profile is implemented as matrix-shaper
cmsBool CMSEXPORT cmsIsMatrixShaper(cmsHPROFILE hProfile)
{
switch (cmsGetColorSpace(hProfile)) {
case cmsSigGrayData:
return cmsIsTag(hProfile, cmsSigGrayTRCTag);
case cmsSigRgbData:
return (cmsIsTag(hProfile, cmsSigRedColorantTag) &&
cmsIsTag(hProfile, cmsSigGreenColorantTag) &&
cmsIsTag(hProfile, cmsSigBlueColorantTag) &&
cmsIsTag(hProfile, cmsSigRedTRCTag) &&
cmsIsTag(hProfile, cmsSigGreenTRCTag) &&
cmsIsTag(hProfile, cmsSigBlueTRCTag));
default:
return FALSE;
}
}
// Returns TRUE if the intent is implemented as CLUT
cmsBool CMSEXPORT cmsIsCLUT(cmsHPROFILE hProfile, cmsUInt32Number Intent, cmsUInt32Number UsedDirection)
{
const cmsTagSignature* TagTable;
// For devicelinks, the supported intent is that one stated in the header
if (cmsGetDeviceClass(hProfile) == cmsSigLinkClass) {
return (cmsGetHeaderRenderingIntent(hProfile) == Intent);
}
switch (UsedDirection) {
case LCMS_USED_AS_INPUT: TagTable = Device2PCS16; break;
case LCMS_USED_AS_OUTPUT:TagTable = PCS2Device16; break;
// For proofing, we need rel. colorimetric in output. Let's do some recursion
case LCMS_USED_AS_PROOF:
return cmsIsIntentSupported(hProfile, Intent, LCMS_USED_AS_INPUT) &&
cmsIsIntentSupported(hProfile, INTENT_RELATIVE_COLORIMETRIC, LCMS_USED_AS_OUTPUT);
default:
cmsSignalError(cmsGetProfileContextID(hProfile), cmsERROR_RANGE, "Unexpected direction (%d)", UsedDirection);
return FALSE;
}
return cmsIsTag(hProfile, TagTable[Intent]);
}
// Return info about supported intents
cmsBool CMSEXPORT cmsIsIntentSupported(cmsHPROFILE hProfile,
cmsUInt32Number Intent, cmsUInt32Number UsedDirection)
{
if (cmsIsCLUT(hProfile, Intent, UsedDirection)) return TRUE;
// Is there any matrix-shaper? If so, the intent is supported. This is a bit odd, since V2 matrix shaper
// does not fully support relative colorimetric because they cannot deal with non-zero black points, but
// many profiles claims that, and this is certainly not true for V4 profiles. Lets answer "yes" no matter
// the accuracy would be less than optimal in rel.col and v2 case.
return cmsIsMatrixShaper(hProfile);
}
// ---------------------------------------------------------------------------------------------------------------
// Read both, profile sequence description and profile sequence id if present. Then combine both to
// create qa unique structure holding both. Shame on ICC to store things in such complicated way.
cmsSEQ* _cmsReadProfileSequence(cmsHPROFILE hProfile)
{
cmsSEQ* ProfileSeq;
cmsSEQ* ProfileId;
cmsSEQ* NewSeq;
cmsUInt32Number i;
// Take profile sequence description first
ProfileSeq = (cmsSEQ*) cmsReadTag(hProfile, cmsSigProfileSequenceDescTag);
// Take profile sequence ID
ProfileId = (cmsSEQ*) cmsReadTag(hProfile, cmsSigProfileSequenceIdTag);
if (ProfileSeq == NULL && ProfileId == NULL) return NULL;
if (ProfileSeq == NULL) return cmsDupProfileSequenceDescription(ProfileId);
if (ProfileId == NULL) return cmsDupProfileSequenceDescription(ProfileSeq);
// We have to mix both together. For that they must agree
if (ProfileSeq ->n != ProfileId ->n) return cmsDupProfileSequenceDescription(ProfileSeq);
NewSeq = cmsDupProfileSequenceDescription(ProfileSeq);
// Ok, proceed to the mixing
if (NewSeq != NULL) {
for (i=0; i < ProfileSeq ->n; i++) {
memmove(&NewSeq ->seq[i].ProfileID, &ProfileId ->seq[i].ProfileID, sizeof(cmsProfileID));
NewSeq ->seq[i].Description = cmsMLUdup(ProfileId ->seq[i].Description);
}
}
return NewSeq;
}
// Dump the contents of profile sequence in both tags (if v4 available)
cmsBool _cmsWriteProfileSequence(cmsHPROFILE hProfile, const cmsSEQ* seq)
{
if (!cmsWriteTag(hProfile, cmsSigProfileSequenceDescTag, seq)) return FALSE;
if (cmsGetProfileVersion(hProfile) >= 4.0) {
if (!cmsWriteTag(hProfile, cmsSigProfileSequenceIdTag, seq)) return FALSE;
}
return TRUE;
}
// Auxiliar, read and duplicate a MLU if found.
static
cmsMLU* GetMLUFromProfile(cmsHPROFILE h, cmsTagSignature sig)
{
cmsMLU* mlu = (cmsMLU*) cmsReadTag(h, sig);
if (mlu == NULL) return NULL;
return cmsMLUdup(mlu);
}
// Create a sequence description out of an array of profiles
cmsSEQ* _cmsCompileProfileSequence(cmsContext ContextID, cmsUInt32Number nProfiles, cmsHPROFILE hProfiles[])
{
cmsUInt32Number i;
cmsSEQ* seq = cmsAllocProfileSequenceDescription(ContextID, nProfiles);
if (seq == NULL) return NULL;
for (i=0; i < nProfiles; i++) {
cmsPSEQDESC* ps = &seq ->seq[i];
cmsHPROFILE h = hProfiles[i];
cmsTechnologySignature* techpt;
cmsGetHeaderAttributes(h, &ps ->attributes);
cmsGetHeaderProfileID(h, ps ->ProfileID.ID8);
ps ->deviceMfg = cmsGetHeaderManufacturer(h);
ps ->deviceModel = cmsGetHeaderModel(h);
techpt = (cmsTechnologySignature*) cmsReadTag(h, cmsSigTechnologyTag);
if (techpt == NULL)
ps ->technology = (cmsTechnologySignature) 0;
else
ps ->technology = *techpt;
ps ->Manufacturer = GetMLUFromProfile(h, cmsSigDeviceMfgDescTag);
ps ->Model = GetMLUFromProfile(h, cmsSigDeviceModelDescTag);
ps ->Description = GetMLUFromProfile(h, cmsSigProfileDescriptionTag);
}
return seq;
}
// -------------------------------------------------------------------------------------------------------------------
static
const cmsMLU* GetInfo(cmsHPROFILE hProfile, cmsInfoType Info)
{
cmsTagSignature sig;
switch (Info) {
case cmsInfoDescription:
sig = cmsSigProfileDescriptionTag;
break;
case cmsInfoManufacturer:
sig = cmsSigDeviceMfgDescTag;
break;
case cmsInfoModel:
sig = cmsSigDeviceModelDescTag;
break;
case cmsInfoCopyright:
sig = cmsSigCopyrightTag;
break;
default: return NULL;
}
return (cmsMLU*) cmsReadTag(hProfile, sig);
}
cmsUInt32Number CMSEXPORT cmsGetProfileInfo(cmsHPROFILE hProfile, cmsInfoType Info,
const char LanguageCode[3], const char CountryCode[3],
wchar_t* Buffer, cmsUInt32Number BufferSize)
{
const cmsMLU* mlu = GetInfo(hProfile, Info);
if (mlu == NULL) return 0;
return cmsMLUgetWide(mlu, LanguageCode, CountryCode, Buffer, BufferSize);
}
cmsUInt32Number CMSEXPORT cmsGetProfileInfoASCII(cmsHPROFILE hProfile, cmsInfoType Info,
const char LanguageCode[3], const char CountryCode[3],
char* Buffer, cmsUInt32Number BufferSize)
{
const cmsMLU* mlu = GetInfo(hProfile, Info);
if (mlu == NULL) return 0;
return cmsMLUgetASCII(mlu, LanguageCode, CountryCode, Buffer, BufferSize);
}
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