1 //---------------------------------------------------------------------------------
2 //
3 //  Little Color Management System
4 //  Copyright (c) 1998-2012 Marti Maria Saguer
5 //
6 // Permission is hereby granted, free of charge, to any person obtaining
7 // a copy of this software and associated documentation files (the "Software"),
8 // to deal in the Software without restriction, including without limitation
9 // the rights to use, copy, modify, merge, publish, distribute, sublicense,
10 // and/or sell copies of the Software, and to permit persons to whom the Software
11 // is furnished to do so, subject to the following conditions:
12 //
13 // The above copyright notice and this permission notice shall be included in
14 // all copies or substantial portions of the Software.
15 //
16 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
17 // EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
18 // THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
19 // NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
20 // LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
21 // OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
22 // WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
23 //
24 //---------------------------------------------------------------------------------
25 //
26 
27 #include "lcms2_internal.h"
28 
29 
30 // Link several profiles to obtain a single LUT modelling the whole color transform. Intents, Black point
31 // compensation and Adaptation parameters may vary across profiles. BPC and Adaptation refers to the PCS
32 // after the profile. I.e, BPC[0] refers to connexion between profile(0) and profile(1)
33 cmsPipeline* _cmsLinkProfiles(cmsContext     ContextID,
34                               cmsUInt32Number nProfiles,
35                               cmsUInt32Number Intents[],
36                               cmsHPROFILE     hProfiles[],
37                               cmsBool         BPC[],
38                               cmsFloat64Number AdaptationStates[],
39                               cmsUInt32Number dwFlags);
40 
41 //---------------------------------------------------------------------------------
42 
43 // This is the default routine for ICC-style intents. A user may decide to override it by using a plugin.
44 // Supported intents are perceptual, relative colorimetric, saturation and ICC-absolute colorimetric
45 static
46 cmsPipeline* DefaultICCintents(cmsContext     ContextID,
47                                cmsUInt32Number nProfiles,
48                                cmsUInt32Number Intents[],
49                                cmsHPROFILE     hProfiles[],
50                                cmsBool         BPC[],
51                                cmsFloat64Number AdaptationStates[],
52                                cmsUInt32Number dwFlags);
53 
54 //---------------------------------------------------------------------------------
55 
56 // This is the entry for black-preserving K-only intents, which are non-ICC. Last profile have to be a output profile
57 // to do the trick (no devicelinks allowed at that position)
58 static
59 cmsPipeline*  BlackPreservingKOnlyIntents(cmsContext     ContextID,
60                                           cmsUInt32Number nProfiles,
61                                           cmsUInt32Number Intents[],
62                                           cmsHPROFILE     hProfiles[],
63                                           cmsBool         BPC[],
64                                           cmsFloat64Number AdaptationStates[],
65                                           cmsUInt32Number dwFlags);
66 
67 //---------------------------------------------------------------------------------
68 
69 // This is the entry for black-plane preserving, which are non-ICC. Again, Last profile have to be a output profile
70 // to do the trick (no devicelinks allowed at that position)
71 static
72 cmsPipeline*  BlackPreservingKPlaneIntents(cmsContext     ContextID,
73                                            cmsUInt32Number nProfiles,
74                                            cmsUInt32Number Intents[],
75                                            cmsHPROFILE     hProfiles[],
76                                            cmsBool         BPC[],
77                                            cmsFloat64Number AdaptationStates[],
78                                            cmsUInt32Number dwFlags);
79 
80 //---------------------------------------------------------------------------------
81 
82 
83 // This is a structure holding implementations for all supported intents.
84 typedef struct _cms_intents_list {
85 
86     cmsUInt32Number Intent;
87     char            Description[256];
88     cmsIntentFn     Link;
89     struct _cms_intents_list*  Next;
90 
91 } cmsIntentsList;
92 
93 
94 // Built-in intents
95 static cmsIntentsList DefaultIntents[] = {
96 
97     { INTENT_PERCEPTUAL,                            "Perceptual",                                   DefaultICCintents,            &DefaultIntents[1] },
98     { INTENT_RELATIVE_COLORIMETRIC,                 "Relative colorimetric",                        DefaultICCintents,            &DefaultIntents[2] },
99     { INTENT_SATURATION,                            "Saturation",                                   DefaultICCintents,            &DefaultIntents[3] },
100     { INTENT_ABSOLUTE_COLORIMETRIC,                 "Absolute colorimetric",                        DefaultICCintents,            &DefaultIntents[4] },
101     { INTENT_PRESERVE_K_ONLY_PERCEPTUAL,            "Perceptual preserving black ink",              BlackPreservingKOnlyIntents,  &DefaultIntents[5] },
102     { INTENT_PRESERVE_K_ONLY_RELATIVE_COLORIMETRIC, "Relative colorimetric preserving black ink",   BlackPreservingKOnlyIntents,  &DefaultIntents[6] },
103     { INTENT_PRESERVE_K_ONLY_SATURATION,            "Saturation preserving black ink",              BlackPreservingKOnlyIntents,  &DefaultIntents[7] },
104     { INTENT_PRESERVE_K_PLANE_PERCEPTUAL,           "Perceptual preserving black plane",            BlackPreservingKPlaneIntents, &DefaultIntents[8] },
105     { INTENT_PRESERVE_K_PLANE_RELATIVE_COLORIMETRIC,"Relative colorimetric preserving black plane", BlackPreservingKPlaneIntents, &DefaultIntents[9] },
106     { INTENT_PRESERVE_K_PLANE_SATURATION,           "Saturation preserving black plane",            BlackPreservingKPlaneIntents, NULL }
107 };
108 
109 
110 // A pointer to the begining of the list
111 _cmsIntentsPluginChunkType _cmsIntentsPluginChunk = { NULL };
112 
113 // Duplicates the zone of memory used by the plug-in in the new context
114 static
DupPluginIntentsList(struct _cmsContext_struct * ctx,const struct _cmsContext_struct * src)115 void DupPluginIntentsList(struct _cmsContext_struct* ctx,
116                                                const struct _cmsContext_struct* src)
117 {
118    _cmsIntentsPluginChunkType newHead = { NULL };
119    cmsIntentsList*  entry;
120    cmsIntentsList*  Anterior = NULL;
121    _cmsIntentsPluginChunkType* head = (_cmsIntentsPluginChunkType*) src->chunks[IntentPlugin];
122 
123     // Walk the list copying all nodes
124    for (entry = head->Intents;
125         entry != NULL;
126         entry = entry ->Next) {
127 
128             cmsIntentsList *newEntry = ( cmsIntentsList *) _cmsSubAllocDup(ctx ->MemPool, entry, sizeof(cmsIntentsList));
129 
130             if (newEntry == NULL)
131                 return;
132 
133             // We want to keep the linked list order, so this is a little bit tricky
134             newEntry -> Next = NULL;
135             if (Anterior)
136                 Anterior -> Next = newEntry;
137 
138             Anterior = newEntry;
139 
140             if (newHead.Intents == NULL)
141                 newHead.Intents = newEntry;
142     }
143 
144   ctx ->chunks[IntentPlugin] = _cmsSubAllocDup(ctx->MemPool, &newHead, sizeof(_cmsIntentsPluginChunkType));
145 }
146 
_cmsAllocIntentsPluginChunk(struct _cmsContext_struct * ctx,const struct _cmsContext_struct * src)147 void  _cmsAllocIntentsPluginChunk(struct _cmsContext_struct* ctx,
148                                          const struct _cmsContext_struct* src)
149 {
150     if (src != NULL) {
151 
152         // Copy all linked list
153         DupPluginIntentsList(ctx, src);
154     }
155     else {
156         static _cmsIntentsPluginChunkType IntentsPluginChunkType = { NULL };
157         ctx ->chunks[IntentPlugin] = _cmsSubAllocDup(ctx ->MemPool, &IntentsPluginChunkType, sizeof(_cmsIntentsPluginChunkType));
158     }
159 }
160 
161 
162 // Search the list for a suitable intent. Returns NULL if not found
163 static
SearchIntent(cmsContext ContextID,cmsUInt32Number Intent)164 cmsIntentsList* SearchIntent(cmsContext ContextID, cmsUInt32Number Intent)
165 {
166     _cmsIntentsPluginChunkType* ctx = ( _cmsIntentsPluginChunkType*) _cmsContextGetClientChunk(ContextID, IntentPlugin);
167     cmsIntentsList* pt;
168 
169     for (pt = ctx -> Intents; pt != NULL; pt = pt -> Next)
170         if (pt ->Intent == Intent) return pt;
171 
172     for (pt = DefaultIntents; pt != NULL; pt = pt -> Next)
173         if (pt ->Intent == Intent) return pt;
174 
175     return NULL;
176 }
177 
178 // Black point compensation. Implemented as a linear scaling in XYZ. Black points
179 // should come relative to the white point. Fills an matrix/offset element m
180 // which is organized as a 4x4 matrix.
181 static
ComputeBlackPointCompensation(const cmsCIEXYZ * BlackPointIn,const cmsCIEXYZ * BlackPointOut,cmsMAT3 * m,cmsVEC3 * off)182 void ComputeBlackPointCompensation(const cmsCIEXYZ* BlackPointIn,
183                                    const cmsCIEXYZ* BlackPointOut,
184                                    cmsMAT3* m, cmsVEC3* off)
185 {
186   cmsFloat64Number ax, ay, az, bx, by, bz, tx, ty, tz;
187 
188    // Now we need to compute a matrix plus an offset m and of such of
189    // [m]*bpin + off = bpout
190    // [m]*D50  + off = D50
191    //
192    // This is a linear scaling in the form ax+b, where
193    // a = (bpout - D50) / (bpin - D50)
194    // b = - D50* (bpout - bpin) / (bpin - D50)
195 
196    tx = BlackPointIn->X - cmsD50_XYZ()->X;
197    ty = BlackPointIn->Y - cmsD50_XYZ()->Y;
198    tz = BlackPointIn->Z - cmsD50_XYZ()->Z;
199 
200    ax = (BlackPointOut->X - cmsD50_XYZ()->X) / tx;
201    ay = (BlackPointOut->Y - cmsD50_XYZ()->Y) / ty;
202    az = (BlackPointOut->Z - cmsD50_XYZ()->Z) / tz;
203 
204    bx = - cmsD50_XYZ()-> X * (BlackPointOut->X - BlackPointIn->X) / tx;
205    by = - cmsD50_XYZ()-> Y * (BlackPointOut->Y - BlackPointIn->Y) / ty;
206    bz = - cmsD50_XYZ()-> Z * (BlackPointOut->Z - BlackPointIn->Z) / tz;
207 
208    _cmsVEC3init(&m ->v[0], ax, 0,  0);
209    _cmsVEC3init(&m ->v[1], 0, ay,  0);
210    _cmsVEC3init(&m ->v[2], 0,  0,  az);
211    _cmsVEC3init(off, bx, by, bz);
212 
213 }
214 
215 
216 // Approximate a blackbody illuminant based on CHAD information
217 static
CHAD2Temp(const cmsMAT3 * Chad)218 cmsFloat64Number CHAD2Temp(const cmsMAT3* Chad)
219 {
220     // Convert D50 across inverse CHAD to get the absolute white point
221     cmsVEC3 d, s;
222     cmsCIEXYZ Dest;
223     cmsCIExyY DestChromaticity;
224     cmsFloat64Number TempK;
225     cmsMAT3 m1, m2;
226 
227     m1 = *Chad;
228     if (!_cmsMAT3inverse(&m1, &m2)) return FALSE;
229 
230     s.n[VX] = cmsD50_XYZ() -> X;
231     s.n[VY] = cmsD50_XYZ() -> Y;
232     s.n[VZ] = cmsD50_XYZ() -> Z;
233 
234     _cmsMAT3eval(&d, &m2, &s);
235 
236     Dest.X = d.n[VX];
237     Dest.Y = d.n[VY];
238     Dest.Z = d.n[VZ];
239 
240     cmsXYZ2xyY(&DestChromaticity, &Dest);
241 
242     if (!cmsTempFromWhitePoint(&TempK, &DestChromaticity))
243         return -1.0;
244 
245     return TempK;
246 }
247 
248 // Compute a CHAD based on a given temperature
249 static
Temp2CHAD(cmsMAT3 * Chad,cmsFloat64Number Temp)250     void Temp2CHAD(cmsMAT3* Chad, cmsFloat64Number Temp)
251 {
252     cmsCIEXYZ White;
253     cmsCIExyY ChromaticityOfWhite;
254 
255     cmsWhitePointFromTemp(&ChromaticityOfWhite, Temp);
256     cmsxyY2XYZ(&White, &ChromaticityOfWhite);
257     _cmsAdaptationMatrix(Chad, NULL, &White, cmsD50_XYZ());
258 }
259 
260 // Join scalings to obtain relative input to absolute and then to relative output.
261 // Result is stored in a 3x3 matrix
262 static
ComputeAbsoluteIntent(cmsFloat64Number AdaptationState,const cmsCIEXYZ * WhitePointIn,const cmsMAT3 * ChromaticAdaptationMatrixIn,const cmsCIEXYZ * WhitePointOut,const cmsMAT3 * ChromaticAdaptationMatrixOut,cmsMAT3 * m)263 cmsBool  ComputeAbsoluteIntent(cmsFloat64Number AdaptationState,
264                                const cmsCIEXYZ* WhitePointIn,
265                                const cmsMAT3* ChromaticAdaptationMatrixIn,
266                                const cmsCIEXYZ* WhitePointOut,
267                                const cmsMAT3* ChromaticAdaptationMatrixOut,
268                                cmsMAT3* m)
269 {
270     cmsMAT3 Scale, m1, m2, m3, m4;
271 
272     // Adaptation state
273     if (AdaptationState == 1.0) {
274 
275         // Observer is fully adapted. Keep chromatic adaptation.
276         // That is the standard V4 behaviour
277         _cmsVEC3init(&m->v[0], WhitePointIn->X / WhitePointOut->X, 0, 0);
278         _cmsVEC3init(&m->v[1], 0, WhitePointIn->Y / WhitePointOut->Y, 0);
279         _cmsVEC3init(&m->v[2], 0, 0, WhitePointIn->Z / WhitePointOut->Z);
280 
281     }
282     else  {
283 
284         // Incomplete adaptation. This is an advanced feature.
285         _cmsVEC3init(&Scale.v[0], WhitePointIn->X / WhitePointOut->X, 0, 0);
286         _cmsVEC3init(&Scale.v[1], 0,  WhitePointIn->Y / WhitePointOut->Y, 0);
287         _cmsVEC3init(&Scale.v[2], 0, 0,  WhitePointIn->Z / WhitePointOut->Z);
288 
289 
290         if (AdaptationState == 0.0) {
291 
292             m1 = *ChromaticAdaptationMatrixOut;
293             _cmsMAT3per(&m2, &m1, &Scale);
294             // m2 holds CHAD from output white to D50 times abs. col. scaling
295 
296             // Observer is not adapted, undo the chromatic adaptation
297             _cmsMAT3per(m, &m2, ChromaticAdaptationMatrixOut);
298 
299             m3 = *ChromaticAdaptationMatrixIn;
300             if (!_cmsMAT3inverse(&m3, &m4)) return FALSE;
301             _cmsMAT3per(m, &m2, &m4);
302 
303         } else {
304 
305             cmsMAT3 MixedCHAD;
306             cmsFloat64Number TempSrc, TempDest, Temp;
307 
308             m1 = *ChromaticAdaptationMatrixIn;
309             if (!_cmsMAT3inverse(&m1, &m2)) return FALSE;
310             _cmsMAT3per(&m3, &m2, &Scale);
311             // m3 holds CHAD from input white to D50 times abs. col. scaling
312 
313             TempSrc  = CHAD2Temp(ChromaticAdaptationMatrixIn);
314             TempDest = CHAD2Temp(ChromaticAdaptationMatrixOut);
315 
316             if (TempSrc < 0.0 || TempDest < 0.0) return FALSE; // Something went wrong
317 
318             if (_cmsMAT3isIdentity(&Scale) && fabs(TempSrc - TempDest) < 0.01) {
319 
320                 _cmsMAT3identity(m);
321                 return TRUE;
322             }
323 
324             Temp = (1.0 - AdaptationState) * TempDest + AdaptationState * TempSrc;
325 
326             // Get a CHAD from whatever output temperature to D50. This replaces output CHAD
327             Temp2CHAD(&MixedCHAD, Temp);
328 
329             _cmsMAT3per(m, &m3, &MixedCHAD);
330         }
331 
332     }
333     return TRUE;
334 
335 }
336 
337 // Just to see if m matrix should be applied
338 static
IsEmptyLayer(cmsMAT3 * m,cmsVEC3 * off)339 cmsBool IsEmptyLayer(cmsMAT3* m, cmsVEC3* off)
340 {
341     cmsFloat64Number diff = 0;
342     cmsMAT3 Ident;
343     int i;
344 
345     if (m == NULL && off == NULL) return TRUE;  // NULL is allowed as an empty layer
346     if (m == NULL && off != NULL) return FALSE; // This is an internal error
347 
348     _cmsMAT3identity(&Ident);
349 
350     for (i=0; i < 3*3; i++)
351         diff += fabs(((cmsFloat64Number*)m)[i] - ((cmsFloat64Number*)&Ident)[i]);
352 
353     for (i=0; i < 3; i++)
354         diff += fabs(((cmsFloat64Number*)off)[i]);
355 
356 
357     return (diff < 0.002);
358 }
359 
360 
361 // Compute the conversion layer
362 static
ComputeConversion(int i,cmsHPROFILE hProfiles[],cmsUInt32Number Intent,cmsBool BPC,cmsFloat64Number AdaptationState,cmsMAT3 * m,cmsVEC3 * off)363 cmsBool ComputeConversion(int i, cmsHPROFILE hProfiles[],
364                                  cmsUInt32Number Intent,
365                                  cmsBool BPC,
366                                  cmsFloat64Number AdaptationState,
367                                  cmsMAT3* m, cmsVEC3* off)
368 {
369 
370     int k;
371 
372     // m  and off are set to identity and this is detected latter on
373     _cmsMAT3identity(m);
374     _cmsVEC3init(off, 0, 0, 0);
375 
376     // If intent is abs. colorimetric,
377     if (Intent == INTENT_ABSOLUTE_COLORIMETRIC) {
378 
379         cmsCIEXYZ WhitePointIn, WhitePointOut;
380         cmsMAT3 ChromaticAdaptationMatrixIn, ChromaticAdaptationMatrixOut;
381 
382         _cmsReadMediaWhitePoint(&WhitePointIn,  hProfiles[i-1]);
383         _cmsReadCHAD(&ChromaticAdaptationMatrixIn, hProfiles[i-1]);
384 
385         _cmsReadMediaWhitePoint(&WhitePointOut,  hProfiles[i]);
386         _cmsReadCHAD(&ChromaticAdaptationMatrixOut, hProfiles[i]);
387 
388         if (!ComputeAbsoluteIntent(AdaptationState,
389                                   &WhitePointIn,  &ChromaticAdaptationMatrixIn,
390                                   &WhitePointOut, &ChromaticAdaptationMatrixOut, m)) return FALSE;
391 
392     }
393     else {
394         // Rest of intents may apply BPC.
395 
396         if (BPC) {
397 
398             cmsCIEXYZ BlackPointIn, BlackPointOut;
399 
400             cmsDetectBlackPoint(&BlackPointIn,  hProfiles[i-1], Intent, 0);
401             cmsDetectDestinationBlackPoint(&BlackPointOut, hProfiles[i], Intent, 0);
402 
403             // If black points are equal, then do nothing
404             if (BlackPointIn.X != BlackPointOut.X ||
405                 BlackPointIn.Y != BlackPointOut.Y ||
406                 BlackPointIn.Z != BlackPointOut.Z)
407                     ComputeBlackPointCompensation(&BlackPointIn, &BlackPointOut, m, off);
408         }
409     }
410 
411     // Offset should be adjusted because the encoding. We encode XYZ normalized to 0..1.0,
412     // to do that, we divide by MAX_ENCODEABLE_XZY. The conversion stage goes XYZ -> XYZ so
413     // we have first to convert from encoded to XYZ and then convert back to encoded.
414     // y = Mx + Off
415     // x = x'c
416     // y = M x'c + Off
417     // y = y'c; y' = y / c
418     // y' = (Mx'c + Off) /c = Mx' + (Off / c)
419 
420     for (k=0; k < 3; k++) {
421         off ->n[k] /= MAX_ENCODEABLE_XYZ;
422     }
423 
424     return TRUE;
425 }
426 
427 
428 // Add a conversion stage if needed. If a matrix/offset m is given, it applies to XYZ space
429 static
AddConversion(cmsPipeline * Result,cmsColorSpaceSignature InPCS,cmsColorSpaceSignature OutPCS,cmsMAT3 * m,cmsVEC3 * off)430 cmsBool AddConversion(cmsPipeline* Result, cmsColorSpaceSignature InPCS, cmsColorSpaceSignature OutPCS, cmsMAT3* m, cmsVEC3* off)
431 {
432     cmsFloat64Number* m_as_dbl = (cmsFloat64Number*) m;
433     cmsFloat64Number* off_as_dbl = (cmsFloat64Number*) off;
434 
435     // Handle PCS mismatches. A specialized stage is added to the LUT in such case
436     switch (InPCS) {
437 
438     case cmsSigXYZData: // Input profile operates in XYZ
439 
440         switch (OutPCS) {
441 
442         case cmsSigXYZData:  // XYZ -> XYZ
443             if (!IsEmptyLayer(m, off) &&
444                 !cmsPipelineInsertStage(Result, cmsAT_END, cmsStageAllocMatrix(Result ->ContextID, 3, 3, m_as_dbl, off_as_dbl)))
445                 return FALSE;
446             break;
447 
448         case cmsSigLabData:  // XYZ -> Lab
449             if (!IsEmptyLayer(m, off) &&
450                 !cmsPipelineInsertStage(Result, cmsAT_END, cmsStageAllocMatrix(Result ->ContextID, 3, 3, m_as_dbl, off_as_dbl)))
451                 return FALSE;
452             if (!cmsPipelineInsertStage(Result, cmsAT_END, _cmsStageAllocXYZ2Lab(Result ->ContextID)))
453                 return FALSE;
454             break;
455 
456         default:
457             return FALSE;   // Colorspace mismatch
458         }
459         break;
460 
461     case cmsSigLabData: // Input profile operates in Lab
462 
463         switch (OutPCS) {
464 
465         case cmsSigXYZData:  // Lab -> XYZ
466 
467             if (!cmsPipelineInsertStage(Result, cmsAT_END, _cmsStageAllocLab2XYZ(Result ->ContextID)))
468                 return FALSE;
469             if (!IsEmptyLayer(m, off) &&
470                 !cmsPipelineInsertStage(Result, cmsAT_END, cmsStageAllocMatrix(Result ->ContextID, 3, 3, m_as_dbl, off_as_dbl)))
471                 return FALSE;
472             break;
473 
474         case cmsSigLabData:  // Lab -> Lab
475 
476             if (!IsEmptyLayer(m, off)) {
477                 if (!cmsPipelineInsertStage(Result, cmsAT_END, _cmsStageAllocLab2XYZ(Result ->ContextID)) ||
478                     !cmsPipelineInsertStage(Result, cmsAT_END, cmsStageAllocMatrix(Result ->ContextID, 3, 3, m_as_dbl, off_as_dbl)) ||
479                     !cmsPipelineInsertStage(Result, cmsAT_END, _cmsStageAllocXYZ2Lab(Result ->ContextID)))
480                     return FALSE;
481             }
482             break;
483 
484         default:
485             return FALSE;  // Mismatch
486         }
487         break;
488 
489         // On colorspaces other than PCS, check for same space
490     default:
491         if (InPCS != OutPCS) return FALSE;
492         break;
493     }
494 
495     return TRUE;
496 }
497 
498 
499 // Is a given space compatible with another?
500 static
ColorSpaceIsCompatible(cmsColorSpaceSignature a,cmsColorSpaceSignature b)501 cmsBool ColorSpaceIsCompatible(cmsColorSpaceSignature a, cmsColorSpaceSignature b)
502 {
503     // If they are same, they are compatible.
504     if (a == b) return TRUE;
505 
506     // Check for MCH4 substitution of CMYK
507     if ((a == cmsSig4colorData) && (b == cmsSigCmykData)) return TRUE;
508     if ((a == cmsSigCmykData) && (b == cmsSig4colorData)) return TRUE;
509 
510     // Check for XYZ/Lab. Those spaces are interchangeable as they can be computed one from other.
511     if ((a == cmsSigXYZData) && (b == cmsSigLabData)) return TRUE;
512     if ((a == cmsSigLabData) && (b == cmsSigXYZData)) return TRUE;
513 
514     return FALSE;
515 }
516 
517 
518 // Default handler for ICC-style intents
519 static
DefaultICCintents(cmsContext ContextID,cmsUInt32Number nProfiles,cmsUInt32Number TheIntents[],cmsHPROFILE hProfiles[],cmsBool BPC[],cmsFloat64Number AdaptationStates[],cmsUInt32Number dwFlags)520 cmsPipeline* DefaultICCintents(cmsContext       ContextID,
521                                cmsUInt32Number  nProfiles,
522                                cmsUInt32Number  TheIntents[],
523                                cmsHPROFILE      hProfiles[],
524                                cmsBool          BPC[],
525                                cmsFloat64Number AdaptationStates[],
526                                cmsUInt32Number  dwFlags)
527 {
528     cmsPipeline* Lut = NULL;
529     cmsPipeline* Result;
530     cmsHPROFILE hProfile;
531     cmsMAT3 m;
532     cmsVEC3 off;
533     cmsColorSpaceSignature ColorSpaceIn, ColorSpaceOut, CurrentColorSpace;
534     cmsProfileClassSignature ClassSig;
535     cmsUInt32Number  i, Intent;
536 
537     // For safety
538     if (nProfiles == 0) return NULL;
539 
540     // Allocate an empty LUT for holding the result. 0 as channel count means 'undefined'
541     Result = cmsPipelineAlloc(ContextID, 0, 0);
542     if (Result == NULL) return NULL;
543 
544     CurrentColorSpace = cmsGetColorSpace(hProfiles[0]);
545 
546     for (i=0; i < nProfiles; i++) {
547 
548         cmsBool  lIsDeviceLink, lIsInput;
549 
550         hProfile      = hProfiles[i];
551         ClassSig      = cmsGetDeviceClass(hProfile);
552         lIsDeviceLink = (ClassSig == cmsSigLinkClass || ClassSig == cmsSigAbstractClass );
553 
554         // First profile is used as input unless devicelink or abstract
555         if ((i == 0) && !lIsDeviceLink) {
556             lIsInput = TRUE;
557         }
558         else {
559           // Else use profile in the input direction if current space is not PCS
560         lIsInput      = (CurrentColorSpace != cmsSigXYZData) &&
561                         (CurrentColorSpace != cmsSigLabData);
562         }
563 
564         Intent        = TheIntents[i];
565 
566         if (lIsInput || lIsDeviceLink) {
567 
568             ColorSpaceIn    = cmsGetColorSpace(hProfile);
569             ColorSpaceOut   = cmsGetPCS(hProfile);
570         }
571         else {
572 
573             ColorSpaceIn    = cmsGetPCS(hProfile);
574             ColorSpaceOut   = cmsGetColorSpace(hProfile);
575         }
576 
577         if (!ColorSpaceIsCompatible(ColorSpaceIn, CurrentColorSpace)) {
578 
579             cmsSignalError(ContextID, cmsERROR_COLORSPACE_CHECK, "ColorSpace mismatch");
580             goto Error;
581         }
582 
583         // If devicelink is found, then no custom intent is allowed and we can
584         // read the LUT to be applied. Settings don't apply here.
585         if (lIsDeviceLink || ((ClassSig == cmsSigNamedColorClass) && (nProfiles == 1))) {
586 
587             // Get the involved LUT from the profile
588             Lut = _cmsReadDevicelinkLUT(hProfile, Intent);
589             if (Lut == NULL) goto Error;
590 
591             // What about abstract profiles?
592              if (ClassSig == cmsSigAbstractClass && i > 0) {
593                 if (!ComputeConversion(i, hProfiles, Intent, BPC[i], AdaptationStates[i], &m, &off)) goto Error;
594              }
595              else {
596                 _cmsMAT3identity(&m);
597                 _cmsVEC3init(&off, 0, 0, 0);
598              }
599 
600 
601             if (!AddConversion(Result, CurrentColorSpace, ColorSpaceIn, &m, &off)) goto Error;
602 
603         }
604         else {
605 
606             if (lIsInput) {
607                 // Input direction means non-pcs connection, so proceed like devicelinks
608                 Lut = _cmsReadInputLUT(hProfile, Intent);
609                 if (Lut == NULL) goto Error;
610             }
611             else {
612 
613                 // Output direction means PCS connection. Intent may apply here
614                 Lut = _cmsReadOutputLUT(hProfile, Intent);
615                 if (Lut == NULL) goto Error;
616 
617 
618                 if (!ComputeConversion(i, hProfiles, Intent, BPC[i], AdaptationStates[i], &m, &off)) goto Error;
619                 if (!AddConversion(Result, CurrentColorSpace, ColorSpaceIn, &m, &off)) goto Error;
620 
621             }
622         }
623 
624         // Concatenate to the output LUT
625         if (!cmsPipelineCat(Result, Lut))
626             goto Error;
627 
628         cmsPipelineFree(Lut);
629         Lut = NULL;
630 
631         // Update current space
632         CurrentColorSpace = ColorSpaceOut;
633     }
634 
635     return Result;
636 
637 Error:
638 
639     if (Lut != NULL) cmsPipelineFree(Lut);
640     if (Result != NULL) cmsPipelineFree(Result);
641     return NULL;
642 
643     cmsUNUSED_PARAMETER(dwFlags);
644 }
645 
646 
647 // Wrapper for DLL calling convention
_cmsDefaultICCintents(cmsContext ContextID,cmsUInt32Number nProfiles,cmsUInt32Number TheIntents[],cmsHPROFILE hProfiles[],cmsBool BPC[],cmsFloat64Number AdaptationStates[],cmsUInt32Number dwFlags)648 cmsPipeline*  CMSEXPORT _cmsDefaultICCintents(cmsContext     ContextID,
649                                               cmsUInt32Number nProfiles,
650                                               cmsUInt32Number TheIntents[],
651                                               cmsHPROFILE     hProfiles[],
652                                               cmsBool         BPC[],
653                                               cmsFloat64Number AdaptationStates[],
654                                               cmsUInt32Number dwFlags)
655 {
656     return DefaultICCintents(ContextID, nProfiles, TheIntents, hProfiles, BPC, AdaptationStates, dwFlags);
657 }
658 
659 // Black preserving intents ---------------------------------------------------------------------------------------------
660 
661 // Translate black-preserving intents to ICC ones
662 static
TranslateNonICCIntents(int Intent)663 int TranslateNonICCIntents(int Intent)
664 {
665     switch (Intent) {
666         case INTENT_PRESERVE_K_ONLY_PERCEPTUAL:
667         case INTENT_PRESERVE_K_PLANE_PERCEPTUAL:
668             return INTENT_PERCEPTUAL;
669 
670         case INTENT_PRESERVE_K_ONLY_RELATIVE_COLORIMETRIC:
671         case INTENT_PRESERVE_K_PLANE_RELATIVE_COLORIMETRIC:
672             return INTENT_RELATIVE_COLORIMETRIC;
673 
674         case INTENT_PRESERVE_K_ONLY_SATURATION:
675         case INTENT_PRESERVE_K_PLANE_SATURATION:
676             return INTENT_SATURATION;
677 
678         default: return Intent;
679     }
680 }
681 
682 // Sampler for Black-only preserving CMYK->CMYK transforms
683 
684 typedef struct {
685     cmsPipeline*    cmyk2cmyk;      // The original transform
686     cmsToneCurve*   KTone;          // Black-to-black tone curve
687 
688 } GrayOnlyParams;
689 
690 
691 // Preserve black only if that is the only ink used
692 static
BlackPreservingGrayOnlySampler(register const cmsUInt16Number In[],register cmsUInt16Number Out[],register void * Cargo)693 int BlackPreservingGrayOnlySampler(register const cmsUInt16Number In[], register cmsUInt16Number Out[], register void* Cargo)
694 {
695     GrayOnlyParams* bp = (GrayOnlyParams*) Cargo;
696 
697     // If going across black only, keep black only
698     if (In[0] == 0 && In[1] == 0 && In[2] == 0) {
699 
700         // TAC does not apply because it is black ink!
701         Out[0] = Out[1] = Out[2] = 0;
702         Out[3] = cmsEvalToneCurve16(bp->KTone, In[3]);
703         return TRUE;
704     }
705 
706     // Keep normal transform for other colors
707     bp ->cmyk2cmyk ->Eval16Fn(In, Out, bp ->cmyk2cmyk->Data);
708     return TRUE;
709 }
710 
711 // This is the entry for black-preserving K-only intents, which are non-ICC
712 static
BlackPreservingKOnlyIntents(cmsContext ContextID,cmsUInt32Number nProfiles,cmsUInt32Number TheIntents[],cmsHPROFILE hProfiles[],cmsBool BPC[],cmsFloat64Number AdaptationStates[],cmsUInt32Number dwFlags)713 cmsPipeline*  BlackPreservingKOnlyIntents(cmsContext     ContextID,
714                                           cmsUInt32Number nProfiles,
715                                           cmsUInt32Number TheIntents[],
716                                           cmsHPROFILE     hProfiles[],
717                                           cmsBool         BPC[],
718                                           cmsFloat64Number AdaptationStates[],
719                                           cmsUInt32Number dwFlags)
720 {
721     GrayOnlyParams  bp;
722     cmsPipeline*    Result;
723     cmsUInt32Number ICCIntents[256];
724     cmsStage*         CLUT;
725     cmsUInt32Number i, nGridPoints;
726 
727 
728     // Sanity check
729     if (nProfiles < 1 || nProfiles > 255) return NULL;
730 
731     // Translate black-preserving intents to ICC ones
732     for (i=0; i < nProfiles; i++)
733         ICCIntents[i] = TranslateNonICCIntents(TheIntents[i]);
734 
735     // Check for non-cmyk profiles
736     if (cmsGetColorSpace(hProfiles[0]) != cmsSigCmykData ||
737         cmsGetColorSpace(hProfiles[nProfiles-1]) != cmsSigCmykData)
738            return DefaultICCintents(ContextID, nProfiles, ICCIntents, hProfiles, BPC, AdaptationStates, dwFlags);
739 
740     memset(&bp, 0, sizeof(bp));
741 
742     // Allocate an empty LUT for holding the result
743     Result = cmsPipelineAlloc(ContextID, 4, 4);
744     if (Result == NULL) return NULL;
745 
746     // Create a LUT holding normal ICC transform
747     bp.cmyk2cmyk = DefaultICCintents(ContextID,
748         nProfiles,
749         ICCIntents,
750         hProfiles,
751         BPC,
752         AdaptationStates,
753         dwFlags);
754 
755     if (bp.cmyk2cmyk == NULL) goto Error;
756 
757     // Now, compute the tone curve
758     bp.KTone = _cmsBuildKToneCurve(ContextID,
759         4096,
760         nProfiles,
761         ICCIntents,
762         hProfiles,
763         BPC,
764         AdaptationStates,
765         dwFlags);
766 
767     if (bp.KTone == NULL) goto Error;
768 
769 
770     // How many gridpoints are we going to use?
771     nGridPoints = _cmsReasonableGridpointsByColorspace(cmsSigCmykData, dwFlags);
772 
773     // Create the CLUT. 16 bits
774     CLUT = cmsStageAllocCLut16bit(ContextID, nGridPoints, 4, 4, NULL);
775     if (CLUT == NULL) goto Error;
776 
777     // This is the one and only MPE in this LUT
778     if (!cmsPipelineInsertStage(Result, cmsAT_BEGIN, CLUT))
779         goto Error;
780 
781     // Sample it. We cannot afford pre/post linearization this time.
782     if (!cmsStageSampleCLut16bit(CLUT, BlackPreservingGrayOnlySampler, (void*) &bp, 0))
783         goto Error;
784 
785     // Get rid of xform and tone curve
786     cmsPipelineFree(bp.cmyk2cmyk);
787     cmsFreeToneCurve(bp.KTone);
788 
789     return Result;
790 
791 Error:
792 
793     if (bp.cmyk2cmyk != NULL) cmsPipelineFree(bp.cmyk2cmyk);
794     if (bp.KTone != NULL)  cmsFreeToneCurve(bp.KTone);
795     if (Result != NULL) cmsPipelineFree(Result);
796     return NULL;
797 
798 }
799 
800 // K Plane-preserving CMYK to CMYK ------------------------------------------------------------------------------------
801 
802 typedef struct {
803 
804     cmsPipeline*     cmyk2cmyk;     // The original transform
805     cmsHTRANSFORM    hProofOutput;  // Output CMYK to Lab (last profile)
806     cmsHTRANSFORM    cmyk2Lab;      // The input chain
807     cmsToneCurve*    KTone;         // Black-to-black tone curve
808     cmsPipeline*     LabK2cmyk;     // The output profile
809     cmsFloat64Number MaxError;
810 
811     cmsHTRANSFORM    hRoundTrip;
812     cmsFloat64Number MaxTAC;
813 
814 
815 } PreserveKPlaneParams;
816 
817 
818 // The CLUT will be stored at 16 bits, but calculations are performed at cmsFloat32Number precision
819 static
BlackPreservingSampler(register const cmsUInt16Number In[],register cmsUInt16Number Out[],register void * Cargo)820 int BlackPreservingSampler(register const cmsUInt16Number In[], register cmsUInt16Number Out[], register void* Cargo)
821 {
822     int i;
823     cmsFloat32Number Inf[4], Outf[4];
824     cmsFloat32Number LabK[4];
825     cmsFloat64Number SumCMY, SumCMYK, Error, Ratio;
826     cmsCIELab ColorimetricLab, BlackPreservingLab;
827     PreserveKPlaneParams* bp = (PreserveKPlaneParams*) Cargo;
828 
829     // Convert from 16 bits to floating point
830     for (i=0; i < 4; i++)
831         Inf[i] = (cmsFloat32Number) (In[i] / 65535.0);
832 
833     // Get the K across Tone curve
834     LabK[3] = cmsEvalToneCurveFloat(bp ->KTone, Inf[3]);
835 
836     // If going across black only, keep black only
837     if (In[0] == 0 && In[1] == 0 && In[2] == 0) {
838 
839         Out[0] = Out[1] = Out[2] = 0;
840         Out[3] = _cmsQuickSaturateWord(LabK[3] * 65535.0);
841         return TRUE;
842     }
843 
844     // Try the original transform,
845     cmsPipelineEvalFloat( Inf, Outf, bp ->cmyk2cmyk);
846 
847     // Store a copy of the floating point result into 16-bit
848     for (i=0; i < 4; i++)
849             Out[i] = _cmsQuickSaturateWord(Outf[i] * 65535.0);
850 
851     // Maybe K is already ok (mostly on K=0)
852     if ( fabs(Outf[3] - LabK[3]) < (3.0 / 65535.0) ) {
853         return TRUE;
854     }
855 
856     // K differ, mesure and keep Lab measurement for further usage
857     // this is done in relative colorimetric intent
858     cmsDoTransform(bp->hProofOutput, Out, &ColorimetricLab, 1);
859 
860     // Is not black only and the transform doesn't keep black.
861     // Obtain the Lab of output CMYK. After that we have Lab + K
862     cmsDoTransform(bp ->cmyk2Lab, Outf, LabK, 1);
863 
864     // Obtain the corresponding CMY using reverse interpolation
865     // (K is fixed in LabK[3])
866     if (!cmsPipelineEvalReverseFloat(LabK, Outf, Outf, bp ->LabK2cmyk)) {
867 
868         // Cannot find a suitable value, so use colorimetric xform
869         // which is already stored in Out[]
870         return TRUE;
871     }
872 
873     // Make sure to pass thru K (which now is fixed)
874     Outf[3] = LabK[3];
875 
876     // Apply TAC if needed
877     SumCMY   = Outf[0]  + Outf[1] + Outf[2];
878     SumCMYK  = SumCMY + Outf[3];
879 
880     if (SumCMYK > bp ->MaxTAC) {
881 
882         Ratio = 1 - ((SumCMYK - bp->MaxTAC) / SumCMY);
883         if (Ratio < 0)
884             Ratio = 0;
885     }
886     else
887        Ratio = 1.0;
888 
889     Out[0] = _cmsQuickSaturateWord(Outf[0] * Ratio * 65535.0);     // C
890     Out[1] = _cmsQuickSaturateWord(Outf[1] * Ratio * 65535.0);     // M
891     Out[2] = _cmsQuickSaturateWord(Outf[2] * Ratio * 65535.0);     // Y
892     Out[3] = _cmsQuickSaturateWord(Outf[3] * 65535.0);
893 
894     // Estimate the error (this goes 16 bits to Lab DBL)
895     cmsDoTransform(bp->hProofOutput, Out, &BlackPreservingLab, 1);
896     Error = cmsDeltaE(&ColorimetricLab, &BlackPreservingLab);
897     if (Error > bp -> MaxError)
898         bp->MaxError = Error;
899 
900     return TRUE;
901 }
902 
903 // This is the entry for black-plane preserving, which are non-ICC
904 static
BlackPreservingKPlaneIntents(cmsContext ContextID,cmsUInt32Number nProfiles,cmsUInt32Number TheIntents[],cmsHPROFILE hProfiles[],cmsBool BPC[],cmsFloat64Number AdaptationStates[],cmsUInt32Number dwFlags)905 cmsPipeline* BlackPreservingKPlaneIntents(cmsContext     ContextID,
906                                           cmsUInt32Number nProfiles,
907                                           cmsUInt32Number TheIntents[],
908                                           cmsHPROFILE     hProfiles[],
909                                           cmsBool         BPC[],
910                                           cmsFloat64Number AdaptationStates[],
911                                           cmsUInt32Number dwFlags)
912 {
913     PreserveKPlaneParams bp;
914     cmsPipeline*    Result = NULL;
915     cmsUInt32Number ICCIntents[256];
916     cmsStage*         CLUT;
917     cmsUInt32Number i, nGridPoints;
918     cmsHPROFILE hLab;
919 
920     // Sanity check
921     if (nProfiles < 1 || nProfiles > 255) return NULL;
922 
923     // Translate black-preserving intents to ICC ones
924     for (i=0; i < nProfiles; i++)
925         ICCIntents[i] = TranslateNonICCIntents(TheIntents[i]);
926 
927     // Check for non-cmyk profiles
928     if (cmsGetColorSpace(hProfiles[0]) != cmsSigCmykData ||
929         !(cmsGetColorSpace(hProfiles[nProfiles-1]) == cmsSigCmykData ||
930         cmsGetDeviceClass(hProfiles[nProfiles-1]) == cmsSigOutputClass))
931            return  DefaultICCintents(ContextID, nProfiles, ICCIntents, hProfiles, BPC, AdaptationStates, dwFlags);
932 
933     // Allocate an empty LUT for holding the result
934     Result = cmsPipelineAlloc(ContextID, 4, 4);
935     if (Result == NULL) return NULL;
936 
937 
938     memset(&bp, 0, sizeof(bp));
939 
940     // We need the input LUT of the last profile, assuming this one is responsible of
941     // black generation. This LUT will be seached in inverse order.
942     bp.LabK2cmyk = _cmsReadInputLUT(hProfiles[nProfiles-1], INTENT_RELATIVE_COLORIMETRIC);
943     if (bp.LabK2cmyk == NULL) goto Cleanup;
944 
945     // Get total area coverage (in 0..1 domain)
946     bp.MaxTAC = cmsDetectTAC(hProfiles[nProfiles-1]) / 100.0;
947     if (bp.MaxTAC <= 0) goto Cleanup;
948 
949 
950     // Create a LUT holding normal ICC transform
951     bp.cmyk2cmyk = DefaultICCintents(ContextID,
952                                          nProfiles,
953                                          ICCIntents,
954                                          hProfiles,
955                                          BPC,
956                                          AdaptationStates,
957                                          dwFlags);
958     if (bp.cmyk2cmyk == NULL) goto Cleanup;
959 
960     // Now the tone curve
961     bp.KTone = _cmsBuildKToneCurve(ContextID, 4096, nProfiles,
962                                    ICCIntents,
963                                    hProfiles,
964                                    BPC,
965                                    AdaptationStates,
966                                    dwFlags);
967     if (bp.KTone == NULL) goto Cleanup;
968 
969     // To measure the output, Last profile to Lab
970     hLab = cmsCreateLab4ProfileTHR(ContextID, NULL);
971     bp.hProofOutput = cmsCreateTransformTHR(ContextID, hProfiles[nProfiles-1],
972                                          CHANNELS_SH(4)|BYTES_SH(2), hLab, TYPE_Lab_DBL,
973                                          INTENT_RELATIVE_COLORIMETRIC,
974                                          cmsFLAGS_NOCACHE|cmsFLAGS_NOOPTIMIZE);
975     if ( bp.hProofOutput == NULL) goto Cleanup;
976 
977     // Same as anterior, but lab in the 0..1 range
978     bp.cmyk2Lab = cmsCreateTransformTHR(ContextID, hProfiles[nProfiles-1],
979                                          FLOAT_SH(1)|CHANNELS_SH(4)|BYTES_SH(4), hLab,
980                                          FLOAT_SH(1)|CHANNELS_SH(3)|BYTES_SH(4),
981                                          INTENT_RELATIVE_COLORIMETRIC,
982                                          cmsFLAGS_NOCACHE|cmsFLAGS_NOOPTIMIZE);
983     if (bp.cmyk2Lab == NULL) goto Cleanup;
984     cmsCloseProfile(hLab);
985 
986     // Error estimation (for debug only)
987     bp.MaxError = 0;
988 
989     // How many gridpoints are we going to use?
990     nGridPoints = _cmsReasonableGridpointsByColorspace(cmsSigCmykData, dwFlags);
991 
992 
993     CLUT = cmsStageAllocCLut16bit(ContextID, nGridPoints, 4, 4, NULL);
994     if (CLUT == NULL) goto Cleanup;
995 
996     if (!cmsPipelineInsertStage(Result, cmsAT_BEGIN, CLUT))
997         goto Cleanup;
998 
999     cmsStageSampleCLut16bit(CLUT, BlackPreservingSampler, (void*) &bp, 0);
1000 
1001 Cleanup:
1002 
1003     if (bp.cmyk2cmyk) cmsPipelineFree(bp.cmyk2cmyk);
1004     if (bp.cmyk2Lab) cmsDeleteTransform(bp.cmyk2Lab);
1005     if (bp.hProofOutput) cmsDeleteTransform(bp.hProofOutput);
1006 
1007     if (bp.KTone) cmsFreeToneCurve(bp.KTone);
1008     if (bp.LabK2cmyk) cmsPipelineFree(bp.LabK2cmyk);
1009 
1010     return Result;
1011 }
1012 
1013 // Link routines ------------------------------------------------------------------------------------------------------
1014 
1015 // Chain several profiles into a single LUT. It just checks the parameters and then calls the handler
1016 // for the first intent in chain. The handler may be user-defined. Is up to the handler to deal with the
1017 // rest of intents in chain. A maximum of 255 profiles at time are supported, which is pretty reasonable.
_cmsLinkProfiles(cmsContext ContextID,cmsUInt32Number nProfiles,cmsUInt32Number TheIntents[],cmsHPROFILE hProfiles[],cmsBool BPC[],cmsFloat64Number AdaptationStates[],cmsUInt32Number dwFlags)1018 cmsPipeline* _cmsLinkProfiles(cmsContext     ContextID,
1019                               cmsUInt32Number nProfiles,
1020                               cmsUInt32Number TheIntents[],
1021                               cmsHPROFILE     hProfiles[],
1022                               cmsBool         BPC[],
1023                               cmsFloat64Number AdaptationStates[],
1024                               cmsUInt32Number dwFlags)
1025 {
1026     cmsUInt32Number i;
1027     cmsIntentsList* Intent;
1028 
1029     // Make sure a reasonable number of profiles is provided
1030     if (nProfiles <= 0 || nProfiles > 255) {
1031          cmsSignalError(ContextID, cmsERROR_RANGE, "Couldn't link '%d' profiles", nProfiles);
1032         return NULL;
1033     }
1034 
1035     for (i=0; i < nProfiles; i++) {
1036 
1037         // Check if black point is really needed or allowed. Note that
1038         // following Adobe's document:
1039         // BPC does not apply to devicelink profiles, nor to abs colorimetric,
1040         // and applies always on V4 perceptual and saturation.
1041 
1042         if (TheIntents[i] == INTENT_ABSOLUTE_COLORIMETRIC)
1043             BPC[i] = FALSE;
1044 
1045         if (TheIntents[i] == INTENT_PERCEPTUAL || TheIntents[i] == INTENT_SATURATION) {
1046 
1047             // Force BPC for V4 profiles in perceptual and saturation
1048             if (cmsGetProfileVersion(hProfiles[i]) >= 4.0)
1049                 BPC[i] = TRUE;
1050         }
1051     }
1052 
1053     // Search for a handler. The first intent in the chain defines the handler. That would
1054     // prevent using multiple custom intents in a multiintent chain, but the behaviour of
1055     // this case would present some issues if the custom intent tries to do things like
1056     // preserve primaries. This solution is not perfect, but works well on most cases.
1057 
1058     Intent = SearchIntent(ContextID, TheIntents[0]);
1059     if (Intent == NULL) {
1060         cmsSignalError(ContextID, cmsERROR_UNKNOWN_EXTENSION, "Unsupported intent '%d'", TheIntents[0]);
1061         return NULL;
1062     }
1063 
1064     // Call the handler
1065     return Intent ->Link(ContextID, nProfiles, TheIntents, hProfiles, BPC, AdaptationStates, dwFlags);
1066 }
1067 
1068 // -------------------------------------------------------------------------------------------------
1069 
1070 // Get information about available intents. nMax is the maximum space for the supplied "Codes"
1071 // and "Descriptions" the function returns the total number of intents, which may be greater
1072 // than nMax, although the matrices are not populated beyond this level.
cmsGetSupportedIntentsTHR(cmsContext ContextID,cmsUInt32Number nMax,cmsUInt32Number * Codes,char ** Descriptions)1073 cmsUInt32Number CMSEXPORT cmsGetSupportedIntentsTHR(cmsContext ContextID, cmsUInt32Number nMax, cmsUInt32Number* Codes, char** Descriptions)
1074 {
1075     _cmsIntentsPluginChunkType* ctx = ( _cmsIntentsPluginChunkType*) _cmsContextGetClientChunk(ContextID, IntentPlugin);
1076     cmsIntentsList* pt;
1077     cmsUInt32Number nIntents;
1078 
1079 
1080     for (nIntents=0, pt = ctx->Intents; pt != NULL; pt = pt -> Next)
1081     {
1082         if (nIntents < nMax) {
1083             if (Codes != NULL)
1084                 Codes[nIntents] = pt ->Intent;
1085 
1086             if (Descriptions != NULL)
1087                 Descriptions[nIntents] = pt ->Description;
1088         }
1089 
1090         nIntents++;
1091     }
1092 
1093     for (nIntents=0, pt = DefaultIntents; pt != NULL; pt = pt -> Next)
1094     {
1095         if (nIntents < nMax) {
1096             if (Codes != NULL)
1097                 Codes[nIntents] = pt ->Intent;
1098 
1099             if (Descriptions != NULL)
1100                 Descriptions[nIntents] = pt ->Description;
1101         }
1102 
1103         nIntents++;
1104     }
1105     return nIntents;
1106 }
1107 
cmsGetSupportedIntents(cmsUInt32Number nMax,cmsUInt32Number * Codes,char ** Descriptions)1108 cmsUInt32Number CMSEXPORT cmsGetSupportedIntents(cmsUInt32Number nMax, cmsUInt32Number* Codes, char** Descriptions)
1109 {
1110     return cmsGetSupportedIntentsTHR(NULL, nMax, Codes, Descriptions);
1111 }
1112 
1113 // The plug-in registration. User can add new intents or override default routines
_cmsRegisterRenderingIntentPlugin(cmsContext id,cmsPluginBase * Data)1114 cmsBool  _cmsRegisterRenderingIntentPlugin(cmsContext id, cmsPluginBase* Data)
1115 {
1116     _cmsIntentsPluginChunkType* ctx = ( _cmsIntentsPluginChunkType*) _cmsContextGetClientChunk(id, IntentPlugin);
1117     cmsPluginRenderingIntent* Plugin = (cmsPluginRenderingIntent*) Data;
1118     cmsIntentsList* fl;
1119 
1120     // Do we have to reset the custom intents?
1121     if (Data == NULL) {
1122 
1123         ctx->Intents = NULL;
1124         return TRUE;
1125     }
1126 
1127     fl = (cmsIntentsList*) _cmsPluginMalloc(id, sizeof(cmsIntentsList));
1128     if (fl == NULL) return FALSE;
1129 
1130 
1131     fl ->Intent  = Plugin ->Intent;
1132     strncpy(fl ->Description, Plugin ->Description, sizeof(fl ->Description)-1);
1133     fl ->Description[sizeof(fl ->Description)-1] = 0;
1134 
1135     fl ->Link    = Plugin ->Link;
1136 
1137     fl ->Next = ctx ->Intents;
1138     ctx ->Intents = fl;
1139 
1140     return TRUE;
1141 }
1142 
1143