1 //--------------------------------------------------------------------------------- 2 // 3 // Little Color Management System 4 // Copyright (c) 1998-2016 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 // inter PCS conversions XYZ <-> CIE L* a* b* 30 /* 31 32 33 CIE 15:2004 CIELab is defined as: 34 35 L* = 116*f(Y/Yn) - 16 0 <= L* <= 100 36 a* = 500*[f(X/Xn) - f(Y/Yn)] 37 b* = 200*[f(Y/Yn) - f(Z/Zn)] 38 39 and 40 41 f(t) = t^(1/3) 1 >= t > (24/116)^3 42 (841/108)*t + (16/116) 0 <= t <= (24/116)^3 43 44 45 Reverse transform is: 46 47 X = Xn*[a* / 500 + (L* + 16) / 116] ^ 3 if (X/Xn) > (24/116) 48 = Xn*(a* / 500 + L* / 116) / 7.787 if (X/Xn) <= (24/116) 49 50 51 52 PCS in Lab2 is encoded as: 53 54 8 bit Lab PCS: 55 56 L* 0..100 into a 0..ff byte. 57 a* t + 128 range is -128.0 +127.0 58 b* 59 60 16 bit Lab PCS: 61 62 L* 0..100 into a 0..ff00 word. 63 a* t + 128 range is -128.0 +127.9961 64 b* 65 66 67 68 Interchange Space Component Actual Range Encoded Range 69 CIE XYZ X 0 -> 1.99997 0x0000 -> 0xffff 70 CIE XYZ Y 0 -> 1.99997 0x0000 -> 0xffff 71 CIE XYZ Z 0 -> 1.99997 0x0000 -> 0xffff 72 73 Version 2,3 74 ----------- 75 76 CIELAB (16 bit) L* 0 -> 100.0 0x0000 -> 0xff00 77 CIELAB (16 bit) a* -128.0 -> +127.996 0x0000 -> 0x8000 -> 0xffff 78 CIELAB (16 bit) b* -128.0 -> +127.996 0x0000 -> 0x8000 -> 0xffff 79 80 81 Version 4 82 --------- 83 84 CIELAB (16 bit) L* 0 -> 100.0 0x0000 -> 0xffff 85 CIELAB (16 bit) a* -128.0 -> +127 0x0000 -> 0x8080 -> 0xffff 86 CIELAB (16 bit) b* -128.0 -> +127 0x0000 -> 0x8080 -> 0xffff 87 88 */ 89 90 // Conversions 91 void CMSEXPORT cmsXYZ2xyY(cmsCIExyY* Dest, const cmsCIEXYZ* Source) 92 { 93 cmsFloat64Number ISum; 94 95 ISum = 1./(Source -> X + Source -> Y + Source -> Z); 96 97 Dest -> x = (Source -> X) * ISum; 98 Dest -> y = (Source -> Y) * ISum; 99 Dest -> Y = Source -> Y; 100 } 101 102 void CMSEXPORT cmsxyY2XYZ(cmsCIEXYZ* Dest, const cmsCIExyY* Source) 103 { 104 Dest -> X = (Source -> x / Source -> y) * Source -> Y; 105 Dest -> Y = Source -> Y; 106 Dest -> Z = ((1 - Source -> x - Source -> y) / Source -> y) * Source -> Y; 107 } 108 109 /* 110 The break point (24/116)^3 = (6/29)^3 is a very small amount of tristimulus 111 primary (0.008856). Generally, this only happens for 112 nearly ideal blacks and for some orange / amber colors in transmission mode. 113 For example, the Z value of the orange turn indicator lamp lens on an 114 automobile will often be below this value. But the Z does not 115 contribute to the perceived color directly. 116 */ 117 118 static 119 cmsFloat64Number f(cmsFloat64Number t) 120 { 121 const cmsFloat64Number Limit = (24.0/116.0) * (24.0/116.0) * (24.0/116.0); 122 123 if (t <= Limit) 124 return (841.0/108.0) * t + (16.0/116.0); 125 else 126 return pow(t, 1.0/3.0); 127 } 128 129 static 130 cmsFloat64Number f_1(cmsFloat64Number t) 131 { 132 const cmsFloat64Number Limit = (24.0/116.0); 133 134 if (t <= Limit) { 135 return (108.0/841.0) * (t - (16.0/116.0)); 136 } 137 138 return t * t * t; 139 } 140 141 142 // Standard XYZ to Lab. it can handle negative XZY numbers in some cases 143 void CMSEXPORT cmsXYZ2Lab(const cmsCIEXYZ* WhitePoint, cmsCIELab* Lab, const cmsCIEXYZ* xyz) 144 { 145 cmsFloat64Number fx, fy, fz; 146 147 if (WhitePoint == NULL) 148 WhitePoint = cmsD50_XYZ(); 149 150 fx = f(xyz->X / WhitePoint->X); 151 fy = f(xyz->Y / WhitePoint->Y); 152 fz = f(xyz->Z / WhitePoint->Z); 153 154 Lab->L = 116.0*fy - 16.0; 155 Lab->a = 500.0*(fx - fy); 156 Lab->b = 200.0*(fy - fz); 157 } 158 159 160 // Standard XYZ to Lab. It can return negative XYZ in some cases 161 void CMSEXPORT cmsLab2XYZ(const cmsCIEXYZ* WhitePoint, cmsCIEXYZ* xyz, const cmsCIELab* Lab) 162 { 163 cmsFloat64Number x, y, z; 164 165 if (WhitePoint == NULL) 166 WhitePoint = cmsD50_XYZ(); 167 168 y = (Lab-> L + 16.0) / 116.0; 169 x = y + 0.002 * Lab -> a; 170 z = y - 0.005 * Lab -> b; 171 172 xyz -> X = f_1(x) * WhitePoint -> X; 173 xyz -> Y = f_1(y) * WhitePoint -> Y; 174 xyz -> Z = f_1(z) * WhitePoint -> Z; 175 176 } 177 178 static 179 cmsFloat64Number L2float2(cmsUInt16Number v) 180 { 181 return (cmsFloat64Number) v / 652.800; 182 } 183 184 // the a/b part 185 static 186 cmsFloat64Number ab2float2(cmsUInt16Number v) 187 { 188 return ((cmsFloat64Number) v / 256.0) - 128.0; 189 } 190 191 static 192 cmsUInt16Number L2Fix2(cmsFloat64Number L) 193 { 194 return _cmsQuickSaturateWord(L * 652.8); 195 } 196 197 static 198 cmsUInt16Number ab2Fix2(cmsFloat64Number ab) 199 { 200 return _cmsQuickSaturateWord((ab + 128.0) * 256.0); 201 } 202 203 204 static 205 cmsFloat64Number L2float4(cmsUInt16Number v) 206 { 207 return (cmsFloat64Number) v / 655.35; 208 } 209 210 // the a/b part 211 static 212 cmsFloat64Number ab2float4(cmsUInt16Number v) 213 { 214 return ((cmsFloat64Number) v / 257.0) - 128.0; 215 } 216 217 218 void CMSEXPORT cmsLabEncoded2FloatV2(cmsCIELab* Lab, const cmsUInt16Number wLab[3]) 219 { 220 Lab->L = L2float2(wLab[0]); 221 Lab->a = ab2float2(wLab[1]); 222 Lab->b = ab2float2(wLab[2]); 223 } 224 225 226 void CMSEXPORT cmsLabEncoded2Float(cmsCIELab* Lab, const cmsUInt16Number wLab[3]) 227 { 228 Lab->L = L2float4(wLab[0]); 229 Lab->a = ab2float4(wLab[1]); 230 Lab->b = ab2float4(wLab[2]); 231 } 232 233 static 234 cmsFloat64Number Clamp_L_doubleV2(cmsFloat64Number L) 235 { 236 const cmsFloat64Number L_max = (cmsFloat64Number) (0xFFFF * 100.0) / 0xFF00; 237 238 if (L < 0) L = 0; 239 if (L > L_max) L = L_max; 240 241 return L; 242 } 243 244 245 static 246 cmsFloat64Number Clamp_ab_doubleV2(cmsFloat64Number ab) 247 { 248 if (ab < MIN_ENCODEABLE_ab2) ab = MIN_ENCODEABLE_ab2; 249 if (ab > MAX_ENCODEABLE_ab2) ab = MAX_ENCODEABLE_ab2; 250 251 return ab; 252 } 253 254 void CMSEXPORT cmsFloat2LabEncodedV2(cmsUInt16Number wLab[3], const cmsCIELab* fLab) 255 { 256 cmsCIELab Lab; 257 258 Lab.L = Clamp_L_doubleV2(fLab ->L); 259 Lab.a = Clamp_ab_doubleV2(fLab ->a); 260 Lab.b = Clamp_ab_doubleV2(fLab ->b); 261 262 wLab[0] = L2Fix2(Lab.L); 263 wLab[1] = ab2Fix2(Lab.a); 264 wLab[2] = ab2Fix2(Lab.b); 265 } 266 267 268 static 269 cmsFloat64Number Clamp_L_doubleV4(cmsFloat64Number L) 270 { 271 if (L < 0) L = 0; 272 if (L > 100.0) L = 100.0; 273 274 return L; 275 } 276 277 static 278 cmsFloat64Number Clamp_ab_doubleV4(cmsFloat64Number ab) 279 { 280 if (ab < MIN_ENCODEABLE_ab4) ab = MIN_ENCODEABLE_ab4; 281 if (ab > MAX_ENCODEABLE_ab4) ab = MAX_ENCODEABLE_ab4; 282 283 return ab; 284 } 285 286 static 287 cmsUInt16Number L2Fix4(cmsFloat64Number L) 288 { 289 return _cmsQuickSaturateWord(L * 655.35); 290 } 291 292 static 293 cmsUInt16Number ab2Fix4(cmsFloat64Number ab) 294 { 295 return _cmsQuickSaturateWord((ab + 128.0) * 257.0); 296 } 297 298 void CMSEXPORT cmsFloat2LabEncoded(cmsUInt16Number wLab[3], const cmsCIELab* fLab) 299 { 300 cmsCIELab Lab; 301 302 Lab.L = Clamp_L_doubleV4(fLab ->L); 303 Lab.a = Clamp_ab_doubleV4(fLab ->a); 304 Lab.b = Clamp_ab_doubleV4(fLab ->b); 305 306 wLab[0] = L2Fix4(Lab.L); 307 wLab[1] = ab2Fix4(Lab.a); 308 wLab[2] = ab2Fix4(Lab.b); 309 } 310 311 // Auxiliary: convert to Radians 312 static 313 cmsFloat64Number RADIANS(cmsFloat64Number deg) 314 { 315 return (deg * M_PI) / 180.; 316 } 317 318 319 // Auxiliary: atan2 but operating in degrees and returning 0 if a==b==0 320 static 321 cmsFloat64Number atan2deg(cmsFloat64Number a, cmsFloat64Number b) 322 { 323 cmsFloat64Number h; 324 325 if (a == 0 && b == 0) 326 h = 0; 327 else 328 h = atan2(a, b); 329 330 h *= (180. / M_PI); 331 332 while (h > 360.) 333 h -= 360.; 334 335 while ( h < 0) 336 h += 360.; 337 338 return h; 339 } 340 341 342 // Auxiliary: Square 343 static 344 cmsFloat64Number Sqr(cmsFloat64Number v) 345 { 346 return v * v; 347 } 348 // From cylindrical coordinates. No check is performed, then negative values are allowed 349 void CMSEXPORT cmsLab2LCh(cmsCIELCh* LCh, const cmsCIELab* Lab) 350 { 351 LCh -> L = Lab -> L; 352 LCh -> C = pow(Sqr(Lab ->a) + Sqr(Lab ->b), 0.5); 353 LCh -> h = atan2deg(Lab ->b, Lab ->a); 354 } 355 356 357 // To cylindrical coordinates. No check is performed, then negative values are allowed 358 void CMSEXPORT cmsLCh2Lab(cmsCIELab* Lab, const cmsCIELCh* LCh) 359 { 360 cmsFloat64Number h = (LCh -> h * M_PI) / 180.0; 361 362 Lab -> L = LCh -> L; 363 Lab -> a = LCh -> C * cos(h); 364 Lab -> b = LCh -> C * sin(h); 365 } 366 367 // In XYZ All 3 components are encoded using 1.15 fixed point 368 static 369 cmsUInt16Number XYZ2Fix(cmsFloat64Number d) 370 { 371 return _cmsQuickSaturateWord(d * 32768.0); 372 } 373 374 void CMSEXPORT cmsFloat2XYZEncoded(cmsUInt16Number XYZ[3], const cmsCIEXYZ* fXYZ) 375 { 376 cmsCIEXYZ xyz; 377 378 xyz.X = fXYZ -> X; 379 xyz.Y = fXYZ -> Y; 380 xyz.Z = fXYZ -> Z; 381 382 // Clamp to encodeable values. 383 if (xyz.Y <= 0) { 384 385 xyz.X = 0; 386 xyz.Y = 0; 387 xyz.Z = 0; 388 } 389 390 if (xyz.X > MAX_ENCODEABLE_XYZ) 391 xyz.X = MAX_ENCODEABLE_XYZ; 392 393 if (xyz.X < 0) 394 xyz.X = 0; 395 396 if (xyz.Y > MAX_ENCODEABLE_XYZ) 397 xyz.Y = MAX_ENCODEABLE_XYZ; 398 399 if (xyz.Y < 0) 400 xyz.Y = 0; 401 402 if (xyz.Z > MAX_ENCODEABLE_XYZ) 403 xyz.Z = MAX_ENCODEABLE_XYZ; 404 405 if (xyz.Z < 0) 406 xyz.Z = 0; 407 408 409 XYZ[0] = XYZ2Fix(xyz.X); 410 XYZ[1] = XYZ2Fix(xyz.Y); 411 XYZ[2] = XYZ2Fix(xyz.Z); 412 } 413 414 415 // To convert from Fixed 1.15 point to cmsFloat64Number 416 static 417 cmsFloat64Number XYZ2float(cmsUInt16Number v) 418 { 419 cmsS15Fixed16Number fix32; 420 421 // From 1.15 to 15.16 422 fix32 = v << 1; 423 424 // From fixed 15.16 to cmsFloat64Number 425 return _cms15Fixed16toDouble(fix32); 426 } 427 428 429 void CMSEXPORT cmsXYZEncoded2Float(cmsCIEXYZ* fXYZ, const cmsUInt16Number XYZ[3]) 430 { 431 fXYZ -> X = XYZ2float(XYZ[0]); 432 fXYZ -> Y = XYZ2float(XYZ[1]); 433 fXYZ -> Z = XYZ2float(XYZ[2]); 434 } 435 436 437 // Returns dE on two Lab values 438 cmsFloat64Number CMSEXPORT cmsDeltaE(const cmsCIELab* Lab1, const cmsCIELab* Lab2) 439 { 440 cmsFloat64Number dL, da, db; 441 442 dL = fabs(Lab1 -> L - Lab2 -> L); 443 da = fabs(Lab1 -> a - Lab2 -> a); 444 db = fabs(Lab1 -> b - Lab2 -> b); 445 446 return pow(Sqr(dL) + Sqr(da) + Sqr(db), 0.5); 447 } 448 449 450 // Return the CIE94 Delta E 451 cmsFloat64Number CMSEXPORT cmsCIE94DeltaE(const cmsCIELab* Lab1, const cmsCIELab* Lab2) 452 { 453 cmsCIELCh LCh1, LCh2; 454 cmsFloat64Number dE, dL, dC, dh, dhsq; 455 cmsFloat64Number c12, sc, sh; 456 457 dL = fabs(Lab1 ->L - Lab2 ->L); 458 459 cmsLab2LCh(&LCh1, Lab1); 460 cmsLab2LCh(&LCh2, Lab2); 461 462 dC = fabs(LCh1.C - LCh2.C); 463 dE = cmsDeltaE(Lab1, Lab2); 464 465 dhsq = Sqr(dE) - Sqr(dL) - Sqr(dC); 466 if (dhsq < 0) 467 dh = 0; 468 else 469 dh = pow(dhsq, 0.5); 470 471 c12 = sqrt(LCh1.C * LCh2.C); 472 473 sc = 1.0 + (0.048 * c12); 474 sh = 1.0 + (0.014 * c12); 475 476 return sqrt(Sqr(dL) + Sqr(dC) / Sqr(sc) + Sqr(dh) / Sqr(sh)); 477 } 478 479 480 // Auxiliary 481 static 482 cmsFloat64Number ComputeLBFD(const cmsCIELab* Lab) 483 { 484 cmsFloat64Number yt; 485 486 if (Lab->L > 7.996969) 487 yt = (Sqr((Lab->L+16)/116)*((Lab->L+16)/116))*100; 488 else 489 yt = 100 * (Lab->L / 903.3); 490 491 return (54.6 * (M_LOG10E * (log(yt + 1.5))) - 9.6); 492 } 493 494 495 496 // bfd - gets BFD(1:1) difference between Lab1, Lab2 497 cmsFloat64Number CMSEXPORT cmsBFDdeltaE(const cmsCIELab* Lab1, const cmsCIELab* Lab2) 498 { 499 cmsFloat64Number lbfd1,lbfd2,AveC,Aveh,dE,deltaL, 500 deltaC,deltah,dc,t,g,dh,rh,rc,rt,bfd; 501 cmsCIELCh LCh1, LCh2; 502 503 504 lbfd1 = ComputeLBFD(Lab1); 505 lbfd2 = ComputeLBFD(Lab2); 506 deltaL = lbfd2 - lbfd1; 507 508 cmsLab2LCh(&LCh1, Lab1); 509 cmsLab2LCh(&LCh2, Lab2); 510 511 deltaC = LCh2.C - LCh1.C; 512 AveC = (LCh1.C+LCh2.C)/2; 513 Aveh = (LCh1.h+LCh2.h)/2; 514 515 dE = cmsDeltaE(Lab1, Lab2); 516 517 if (Sqr(dE)>(Sqr(Lab2->L-Lab1->L)+Sqr(deltaC))) 518 deltah = sqrt(Sqr(dE)-Sqr(Lab2->L-Lab1->L)-Sqr(deltaC)); 519 else 520 deltah =0; 521 522 523 dc = 0.035 * AveC / (1 + 0.00365 * AveC)+0.521; 524 g = sqrt(Sqr(Sqr(AveC))/(Sqr(Sqr(AveC))+14000)); 525 t = 0.627+(0.055*cos((Aveh-254)/(180/M_PI))- 526 0.040*cos((2*Aveh-136)/(180/M_PI))+ 527 0.070*cos((3*Aveh-31)/(180/M_PI))+ 528 0.049*cos((4*Aveh+114)/(180/M_PI))- 529 0.015*cos((5*Aveh-103)/(180/M_PI))); 530 531 dh = dc*(g*t+1-g); 532 rh = -0.260*cos((Aveh-308)/(180/M_PI))- 533 0.379*cos((2*Aveh-160)/(180/M_PI))- 534 0.636*cos((3*Aveh+254)/(180/M_PI))+ 535 0.226*cos((4*Aveh+140)/(180/M_PI))- 536 0.194*cos((5*Aveh+280)/(180/M_PI)); 537 538 rc = sqrt((AveC*AveC*AveC*AveC*AveC*AveC)/((AveC*AveC*AveC*AveC*AveC*AveC)+70000000)); 539 rt = rh*rc; 540 541 bfd = sqrt(Sqr(deltaL)+Sqr(deltaC/dc)+Sqr(deltah/dh)+(rt*(deltaC/dc)*(deltah/dh))); 542 543 return bfd; 544 } 545 546 547 // cmc - CMC(l:c) difference between Lab1, Lab2 548 cmsFloat64Number CMSEXPORT cmsCMCdeltaE(const cmsCIELab* Lab1, const cmsCIELab* Lab2, cmsFloat64Number l, cmsFloat64Number c) 549 { 550 cmsFloat64Number dE,dL,dC,dh,sl,sc,sh,t,f,cmc; 551 cmsCIELCh LCh1, LCh2; 552 553 if (Lab1 ->L == 0 && Lab2 ->L == 0) return 0; 554 555 cmsLab2LCh(&LCh1, Lab1); 556 cmsLab2LCh(&LCh2, Lab2); 557 558 559 dL = Lab2->L-Lab1->L; 560 dC = LCh2.C-LCh1.C; 561 562 dE = cmsDeltaE(Lab1, Lab2); 563 564 if (Sqr(dE)>(Sqr(dL)+Sqr(dC))) 565 dh = sqrt(Sqr(dE)-Sqr(dL)-Sqr(dC)); 566 else 567 dh =0; 568 569 if ((LCh1.h > 164) && (LCh1.h < 345)) 570 t = 0.56 + fabs(0.2 * cos(((LCh1.h + 168)/(180/M_PI)))); 571 else 572 t = 0.36 + fabs(0.4 * cos(((LCh1.h + 35 )/(180/M_PI)))); 573 574 sc = 0.0638 * LCh1.C / (1 + 0.0131 * LCh1.C) + 0.638; 575 sl = 0.040975 * Lab1->L /(1 + 0.01765 * Lab1->L); 576 577 if (Lab1->L<16) 578 sl = 0.511; 579 580 f = sqrt((LCh1.C * LCh1.C * LCh1.C * LCh1.C)/((LCh1.C * LCh1.C * LCh1.C * LCh1.C)+1900)); 581 sh = sc*(t*f+1-f); 582 cmc = sqrt(Sqr(dL/(l*sl))+Sqr(dC/(c*sc))+Sqr(dh/sh)); 583 584 return cmc; 585 } 586 587 // dE2000 The weightings KL, KC and KH can be modified to reflect the relative 588 // importance of lightness, chroma and hue in different industrial applications 589 cmsFloat64Number CMSEXPORT cmsCIE2000DeltaE(const cmsCIELab* Lab1, const cmsCIELab* Lab2, 590 cmsFloat64Number Kl, cmsFloat64Number Kc, cmsFloat64Number Kh) 591 { 592 cmsFloat64Number L1 = Lab1->L; 593 cmsFloat64Number a1 = Lab1->a; 594 cmsFloat64Number b1 = Lab1->b; 595 cmsFloat64Number C = sqrt( Sqr(a1) + Sqr(b1) ); 596 597 cmsFloat64Number Ls = Lab2 ->L; 598 cmsFloat64Number as = Lab2 ->a; 599 cmsFloat64Number bs = Lab2 ->b; 600 cmsFloat64Number Cs = sqrt( Sqr(as) + Sqr(bs) ); 601 602 cmsFloat64Number G = 0.5 * ( 1 - sqrt(pow((C + Cs) / 2 , 7.0) / (pow((C + Cs) / 2, 7.0) + pow(25.0, 7.0) ) )); 603 604 cmsFloat64Number a_p = (1 + G ) * a1; 605 cmsFloat64Number b_p = b1; 606 cmsFloat64Number C_p = sqrt( Sqr(a_p) + Sqr(b_p)); 607 cmsFloat64Number h_p = atan2deg(b_p, a_p); 608 609 610 cmsFloat64Number a_ps = (1 + G) * as; 611 cmsFloat64Number b_ps = bs; 612 cmsFloat64Number C_ps = sqrt(Sqr(a_ps) + Sqr(b_ps)); 613 cmsFloat64Number h_ps = atan2deg(b_ps, a_ps); 614 615 cmsFloat64Number meanC_p =(C_p + C_ps) / 2; 616 617 cmsFloat64Number hps_plus_hp = h_ps + h_p; 618 cmsFloat64Number hps_minus_hp = h_ps - h_p; 619 620 cmsFloat64Number meanh_p = fabs(hps_minus_hp) <= 180.000001 ? (hps_plus_hp)/2 : 621 (hps_plus_hp) < 360 ? (hps_plus_hp + 360)/2 : 622 (hps_plus_hp - 360)/2; 623 624 cmsFloat64Number delta_h = (hps_minus_hp) <= -180.000001 ? (hps_minus_hp + 360) : 625 (hps_minus_hp) > 180 ? (hps_minus_hp - 360) : 626 (hps_minus_hp); 627 cmsFloat64Number delta_L = (Ls - L1); 628 cmsFloat64Number delta_C = (C_ps - C_p ); 629 630 631 cmsFloat64Number delta_H =2 * sqrt(C_ps*C_p) * sin(RADIANS(delta_h) / 2); 632 633 cmsFloat64Number T = 1 - 0.17 * cos(RADIANS(meanh_p-30)) 634 + 0.24 * cos(RADIANS(2*meanh_p)) 635 + 0.32 * cos(RADIANS(3*meanh_p + 6)) 636 - 0.2 * cos(RADIANS(4*meanh_p - 63)); 637 638 cmsFloat64Number Sl = 1 + (0.015 * Sqr((Ls + L1) /2- 50) )/ sqrt(20 + Sqr( (Ls+L1)/2 - 50) ); 639 640 cmsFloat64Number Sc = 1 + 0.045 * (C_p + C_ps)/2; 641 cmsFloat64Number Sh = 1 + 0.015 * ((C_ps + C_p)/2) * T; 642 643 cmsFloat64Number delta_ro = 30 * exp( -Sqr(((meanh_p - 275 ) / 25))); 644 645 cmsFloat64Number Rc = 2 * sqrt(( pow(meanC_p, 7.0) )/( pow(meanC_p, 7.0) + pow(25.0, 7.0))); 646 647 cmsFloat64Number Rt = -sin(2 * RADIANS(delta_ro)) * Rc; 648 649 cmsFloat64Number deltaE00 = sqrt( Sqr(delta_L /(Sl * Kl)) + 650 Sqr(delta_C/(Sc * Kc)) + 651 Sqr(delta_H/(Sh * Kh)) + 652 Rt*(delta_C/(Sc * Kc)) * (delta_H / (Sh * Kh))); 653 654 return deltaE00; 655 } 656 657 // This function returns a number of gridpoints to be used as LUT table. It assumes same number 658 // of gripdpoints in all dimensions. Flags may override the choice. 659 int _cmsReasonableGridpointsByColorspace(cmsColorSpaceSignature Colorspace, cmsUInt32Number dwFlags) 660 { 661 int nChannels; 662 663 // Already specified? 664 if (dwFlags & 0x00FF0000) { 665 // Yes, grab'em 666 return (dwFlags >> 16) & 0xFF; 667 } 668 669 nChannels = cmsChannelsOf(Colorspace); 670 671 // HighResPrecalc is maximum resolution 672 if (dwFlags & cmsFLAGS_HIGHRESPRECALC) { 673 674 if (nChannels > 4) 675 return 7; // 7 for Hifi 676 677 if (nChannels == 4) // 23 for CMYK 678 return 23; 679 680 return 49; // 49 for RGB and others 681 } 682 683 684 // LowResPrecal is lower resolution 685 if (dwFlags & cmsFLAGS_LOWRESPRECALC) { 686 687 if (nChannels > 4) 688 return 6; // 6 for more than 4 channels 689 690 if (nChannels == 1) 691 return 33; // For monochrome 692 693 return 17; // 17 for remaining 694 } 695 696 // Default values 697 if (nChannels > 4) 698 return 7; // 7 for Hifi 699 700 if (nChannels == 4) 701 return 17; // 17 for CMYK 702 703 return 33; // 33 for RGB 704 } 705 706 707 cmsBool _cmsEndPointsBySpace(cmsColorSpaceSignature Space, 708 cmsUInt16Number **White, 709 cmsUInt16Number **Black, 710 cmsUInt32Number *nOutputs) 711 { 712 // Only most common spaces 713 714 static cmsUInt16Number RGBblack[4] = { 0, 0, 0 }; 715 static cmsUInt16Number RGBwhite[4] = { 0xffff, 0xffff, 0xffff }; 716 static cmsUInt16Number CMYKblack[4] = { 0xffff, 0xffff, 0xffff, 0xffff }; // 400% of ink 717 static cmsUInt16Number CMYKwhite[4] = { 0, 0, 0, 0 }; 718 static cmsUInt16Number LABblack[4] = { 0, 0x8080, 0x8080 }; // V4 Lab encoding 719 static cmsUInt16Number LABwhite[4] = { 0xFFFF, 0x8080, 0x8080 }; 720 static cmsUInt16Number CMYblack[4] = { 0xffff, 0xffff, 0xffff }; 721 static cmsUInt16Number CMYwhite[4] = { 0, 0, 0 }; 722 static cmsUInt16Number Grayblack[4] = { 0 }; 723 static cmsUInt16Number GrayWhite[4] = { 0xffff }; 724 725 switch (Space) { 726 727 case cmsSigGrayData: if (White) *White = GrayWhite; 728 if (Black) *Black = Grayblack; 729 if (nOutputs) *nOutputs = 1; 730 return TRUE; 731 732 case cmsSigRgbData: if (White) *White = RGBwhite; 733 if (Black) *Black = RGBblack; 734 if (nOutputs) *nOutputs = 3; 735 return TRUE; 736 737 case cmsSigLabData: if (White) *White = LABwhite; 738 if (Black) *Black = LABblack; 739 if (nOutputs) *nOutputs = 3; 740 return TRUE; 741 742 case cmsSigCmykData: if (White) *White = CMYKwhite; 743 if (Black) *Black = CMYKblack; 744 if (nOutputs) *nOutputs = 4; 745 return TRUE; 746 747 case cmsSigCmyData: if (White) *White = CMYwhite; 748 if (Black) *Black = CMYblack; 749 if (nOutputs) *nOutputs = 3; 750 return TRUE; 751 752 default:; 753 } 754 755 return FALSE; 756 } 757 758 759 760 // Several utilities ------------------------------------------------------- 761 762 // Translate from our colorspace to ICC representation 763 764 cmsColorSpaceSignature CMSEXPORT _cmsICCcolorSpace(int OurNotation) 765 { 766 switch (OurNotation) { 767 768 case 1: 769 case PT_GRAY: return cmsSigGrayData; 770 771 case 2: 772 case PT_RGB: return cmsSigRgbData; 773 774 case PT_CMY: return cmsSigCmyData; 775 case PT_CMYK: return cmsSigCmykData; 776 case PT_YCbCr:return cmsSigYCbCrData; 777 case PT_YUV: return cmsSigLuvData; 778 case PT_XYZ: return cmsSigXYZData; 779 780 case PT_LabV2: 781 case PT_Lab: return cmsSigLabData; 782 783 case PT_YUVK: return cmsSigLuvKData; 784 case PT_HSV: return cmsSigHsvData; 785 case PT_HLS: return cmsSigHlsData; 786 case PT_Yxy: return cmsSigYxyData; 787 788 case PT_MCH1: return cmsSigMCH1Data; 789 case PT_MCH2: return cmsSigMCH2Data; 790 case PT_MCH3: return cmsSigMCH3Data; 791 case PT_MCH4: return cmsSigMCH4Data; 792 case PT_MCH5: return cmsSigMCH5Data; 793 case PT_MCH6: return cmsSigMCH6Data; 794 case PT_MCH7: return cmsSigMCH7Data; 795 case PT_MCH8: return cmsSigMCH8Data; 796 797 case PT_MCH9: return cmsSigMCH9Data; 798 case PT_MCH10: return cmsSigMCHAData; 799 case PT_MCH11: return cmsSigMCHBData; 800 case PT_MCH12: return cmsSigMCHCData; 801 case PT_MCH13: return cmsSigMCHDData; 802 case PT_MCH14: return cmsSigMCHEData; 803 case PT_MCH15: return cmsSigMCHFData; 804 805 default: return (cmsColorSpaceSignature) (-1); 806 } 807 } 808 809 810 int CMSEXPORT _cmsLCMScolorSpace(cmsColorSpaceSignature ProfileSpace) 811 { 812 switch (ProfileSpace) { 813 814 case cmsSigGrayData: return PT_GRAY; 815 case cmsSigRgbData: return PT_RGB; 816 case cmsSigCmyData: return PT_CMY; 817 case cmsSigCmykData: return PT_CMYK; 818 case cmsSigYCbCrData:return PT_YCbCr; 819 case cmsSigLuvData: return PT_YUV; 820 case cmsSigXYZData: return PT_XYZ; 821 case cmsSigLabData: return PT_Lab; 822 case cmsSigLuvKData: return PT_YUVK; 823 case cmsSigHsvData: return PT_HSV; 824 case cmsSigHlsData: return PT_HLS; 825 case cmsSigYxyData: return PT_Yxy; 826 827 case cmsSig1colorData: 828 case cmsSigMCH1Data: return PT_MCH1; 829 830 case cmsSig2colorData: 831 case cmsSigMCH2Data: return PT_MCH2; 832 833 case cmsSig3colorData: 834 case cmsSigMCH3Data: return PT_MCH3; 835 836 case cmsSig4colorData: 837 case cmsSigMCH4Data: return PT_MCH4; 838 839 case cmsSig5colorData: 840 case cmsSigMCH5Data: return PT_MCH5; 841 842 case cmsSig6colorData: 843 case cmsSigMCH6Data: return PT_MCH6; 844 845 case cmsSigMCH7Data: 846 case cmsSig7colorData:return PT_MCH7; 847 848 case cmsSigMCH8Data: 849 case cmsSig8colorData:return PT_MCH8; 850 851 case cmsSigMCH9Data: 852 case cmsSig9colorData:return PT_MCH9; 853 854 case cmsSigMCHAData: 855 case cmsSig10colorData:return PT_MCH10; 856 857 case cmsSigMCHBData: 858 case cmsSig11colorData:return PT_MCH11; 859 860 case cmsSigMCHCData: 861 case cmsSig12colorData:return PT_MCH12; 862 863 case cmsSigMCHDData: 864 case cmsSig13colorData:return PT_MCH13; 865 866 case cmsSigMCHEData: 867 case cmsSig14colorData:return PT_MCH14; 868 869 case cmsSigMCHFData: 870 case cmsSig15colorData:return PT_MCH15; 871 872 default: return (cmsColorSpaceSignature) (-1); 873 } 874 } 875 876 877 cmsUInt32Number CMSEXPORT cmsChannelsOf(cmsColorSpaceSignature ColorSpace) 878 { 879 switch (ColorSpace) { 880 881 case cmsSigMCH1Data: 882 case cmsSig1colorData: 883 case cmsSigGrayData: return 1; 884 885 case cmsSigMCH2Data: 886 case cmsSig2colorData: return 2; 887 888 case cmsSigXYZData: 889 case cmsSigLabData: 890 case cmsSigLuvData: 891 case cmsSigYCbCrData: 892 case cmsSigYxyData: 893 case cmsSigRgbData: 894 case cmsSigHsvData: 895 case cmsSigHlsData: 896 case cmsSigCmyData: 897 case cmsSigMCH3Data: 898 case cmsSig3colorData: return 3; 899 900 case cmsSigLuvKData: 901 case cmsSigCmykData: 902 case cmsSigMCH4Data: 903 case cmsSig4colorData: return 4; 904 905 case cmsSigMCH5Data: 906 case cmsSig5colorData: return 5; 907 908 case cmsSigMCH6Data: 909 case cmsSig6colorData: return 6; 910 911 case cmsSigMCH7Data: 912 case cmsSig7colorData: return 7; 913 914 case cmsSigMCH8Data: 915 case cmsSig8colorData: return 8; 916 917 case cmsSigMCH9Data: 918 case cmsSig9colorData: return 9; 919 920 case cmsSigMCHAData: 921 case cmsSig10colorData: return 10; 922 923 case cmsSigMCHBData: 924 case cmsSig11colorData: return 11; 925 926 case cmsSigMCHCData: 927 case cmsSig12colorData: return 12; 928 929 case cmsSigMCHDData: 930 case cmsSig13colorData: return 13; 931 932 case cmsSigMCHEData: 933 case cmsSig14colorData: return 14; 934 935 case cmsSigMCHFData: 936 case cmsSig15colorData: return 15; 937 938 default: return 3; 939 } 940 } 941