/* * Copyright 2021 Google LLC * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // This file is automatically generated. Do not modify it. package hct; import utils.ColorUtils; import utils.MathUtils; /** A class that solves the HCT equation. */ public class HctSolver { private HctSolver() {} static final double[][] SCALED_DISCOUNT_FROM_LINRGB = new double[][] { new double[] { 0.001200833568784504, 0.002389694492170889, 0.0002795742885861124, }, new double[] { 0.0005891086651375999, 0.0029785502573438758, 0.0003270666104008398, }, new double[] { 0.00010146692491640572, 0.0005364214359186694, 0.0032979401770712076, }, }; static final double[][] LINRGB_FROM_SCALED_DISCOUNT = new double[][] { new double[] { 1373.2198709594231, -1100.4251190754821, -7.278681089101213, }, new double[] { -271.815969077903, 559.6580465940733, -32.46047482791194, }, new double[] { 1.9622899599665666, -57.173814538844006, 308.7233197812385, }, }; static final double[] Y_FROM_LINRGB = new double[] {0.2126, 0.7152, 0.0722}; static final double[] CRITICAL_PLANES = new double[] { 0.015176349177441876, 0.045529047532325624, 0.07588174588720938, 0.10623444424209313, 0.13658714259697685, 0.16693984095186062, 0.19729253930674434, 0.2276452376616281, 0.2579979360165119, 0.28835063437139563, 0.3188300904430532, 0.350925934958123, 0.3848314933096426, 0.42057480301049466, 0.458183274052838, 0.4976837250274023, 0.5391024159806381, 0.5824650784040898, 0.6277969426914107, 0.6751227633498623, 0.7244668422128921, 0.775853049866786, 0.829304845476233, 0.8848452951698498, 0.942497089126609, 1.0022825574869039, 1.0642236851973577, 1.1283421258858297, 1.1946592148522128, 1.2631959812511864, 1.3339731595349034, 1.407011200216447, 1.4823302800086415, 1.5599503113873272, 1.6398909516233677, 1.7221716113234105, 1.8068114625156377, 1.8938294463134073, 1.9832442801866852, 2.075074464868551, 2.1693382909216234, 2.2660538449872063, 2.36523901573795, 2.4669114995532007, 2.5710888059345764, 2.6777882626779785, 2.7870270208169257, 2.898822059350997, 3.0131901897720907, 3.1301480604002863, 3.2497121605402226, 3.3718988244681087, 3.4967242352587946, 3.624204428461639, 3.754355295633311, 3.887192587735158, 4.022731918402185, 4.160988767090289, 4.301978482107941, 4.445716283538092, 4.592217266055746, 4.741496401646282, 4.893568542229298, 5.048448422192488, 5.20615066083972, 5.3666897647573375, 5.5300801301023865, 5.696336044816294, 5.865471690767354, 6.037501145825082, 6.212438385869475, 6.390297286737924, 6.571091626112461, 6.7548350853498045, 6.941541251256611, 7.131223617812143, 7.323895587840543, 7.5195704746346665, 7.7182615035334345, 7.919981813454504, 8.124744458384042, 8.332562408825165, 8.543448553206703, 8.757415699253682, 8.974476575321063, 9.194643831691977, 9.417930041841839, 9.644347703669503, 9.873909240696694, 10.106627003236781, 10.342513269534024, 10.58158024687427, 10.8238400726681, 11.069304815507364, 11.317986476196008, 11.569896988756009, 11.825048221409341, 12.083451977536606, 12.345119996613247, 12.610063955123938, 12.878295467455942, 13.149826086772048, 13.42466730586372, 13.702830557985108, 13.984327217668513, 14.269168601521828, 14.55736596900856, 14.848930523210871, 15.143873411576273, 15.44220572664832, 15.743938506781891, 16.04908273684337, 16.35764934889634, 16.66964922287304, 16.985093187232053, 17.30399201960269, 17.62635644741625, 17.95219714852476, 18.281524751807332, 18.614349837764564, 18.95068293910138, 19.290534541298456, 19.633915083172692, 19.98083495742689, 20.331304511189067, 20.685334046541502, 21.042933821039977, 21.404114048223256, 21.76888489811322, 22.137256497705877, 22.50923893145328, 22.884842241736916, 23.264076429332462, 23.6469514538663, 24.033477234264016, 24.42366364919083, 24.817520537484558, 25.21505769858089, 25.61628489293138, 26.021211842414342, 26.429848230738664, 26.842203703840827, 27.258287870275353, 27.678110301598522, 28.10168053274597, 28.529008062403893, 28.96010235337422, 29.39497283293396, 29.83362889318845, 30.276079891419332, 30.722335150426627, 31.172403958865512, 31.62629557157785, 32.08401920991837, 32.54558406207592, 33.010999283389665, 33.4802739966603, 33.953417292456834, 34.430438229418264, 34.911345834551085, 35.39614910352207, 35.88485700094671, 36.37747846067349, 36.87402238606382, 37.37449765026789, 37.87891309649659, 38.38727753828926, 38.89959975977785, 39.41588851594697, 39.93615253289054, 40.460400508064545, 40.98864111053629, 41.520882981230194, 42.05713473317016, 42.597404951718396, 43.141702194811224, 43.6900349931913, 44.24241185063697, 44.798841244188324, 45.35933162437017, 45.92389141541209, 46.49252901546552, 47.065252796817916, 47.64207110610409, 48.22299226451468, 48.808024568002054, 49.3971762874833, 49.9904556690408, 50.587870934119984, 51.189430279724725, 51.79514187861014, 52.40501387947288, 53.0190544071392, 53.637271562750364, 54.259673423945976, 54.88626804504493, 55.517063457223934, 56.15206766869424, 56.79128866487574, 57.43473440856916, 58.08241284012621, 58.734331877617365, 59.39049941699807, 60.05092333227251, 60.715611475655585, 61.38457167773311, 62.057811747619894, 62.7353394731159, 63.417162620860914, 64.10328893648692, 64.79372614476921, 65.48848194977529, 66.18756403501224, 66.89098006357258, 67.59873767827808, 68.31084450182222, 69.02730813691093, 69.74813616640164, 70.47333615344107, 71.20291564160104, 71.93688215501312, 72.67524319850172, 73.41800625771542, 74.16517879925733, 74.9167682708136, 75.67278210128072, 76.43322770089146, 77.1981124613393, 77.96744375590167, 78.74122893956174, 79.51947534912904, 80.30219030335869, 81.08938110306934, 81.88105503125999, 82.67721935322541, 83.4778813166706, 84.28304815182372, 85.09272707154808, 85.90692527145302, 86.72564993000343, 87.54890820862819, 88.3767072518277, 89.2090541872801, 90.04595612594655, 90.88742016217518, 91.73345337380438, 92.58406282226491, 93.43925555268066, 94.29903859396902, 95.16341895893969, 96.03240364439274, 96.9059996312159, 97.78421388448044, 98.6670533535366, 99.55452497210776, }; /** * Sanitizes a small enough angle in radians. * * @param angle An angle in radians; must not deviate too much from 0. * @return A coterminal angle between 0 and 2pi. */ static double sanitizeRadians(double angle) { return (angle + Math.PI * 8) % (Math.PI * 2); } /** * Delinearizes an RGB component, returning a floating-point number. * * @param rgbComponent 0.0 <= rgb_component <= 100.0, represents linear R/G/B channel * @return 0.0 <= output <= 255.0, color channel converted to regular RGB space */ static double trueDelinearized(double rgbComponent) { double normalized = rgbComponent / 100.0; double delinearized = 0.0; if (normalized <= 0.0031308) { delinearized = normalized * 12.92; } else { delinearized = 1.055 * Math.pow(normalized, 1.0 / 2.4) - 0.055; } return delinearized * 255.0; } static double chromaticAdaptation(double component) { double af = Math.pow(Math.abs(component), 0.42); return MathUtils.signum(component) * 400.0 * af / (af + 27.13); } /** * Returns the hue of a linear RGB color in CAM16. * * @param linrgb The linear RGB coordinates of a color. * @return The hue of the color in CAM16, in radians. */ static double hueOf(double[] linrgb) { double[] scaledDiscount = MathUtils.matrixMultiply(linrgb, SCALED_DISCOUNT_FROM_LINRGB); double rA = chromaticAdaptation(scaledDiscount[0]); double gA = chromaticAdaptation(scaledDiscount[1]); double bA = chromaticAdaptation(scaledDiscount[2]); // redness-greenness double a = (11.0 * rA + -12.0 * gA + bA) / 11.0; // yellowness-blueness double b = (rA + gA - 2.0 * bA) / 9.0; return Math.atan2(b, a); } static boolean areInCyclicOrder(double a, double b, double c) { double deltaAB = sanitizeRadians(b - a); double deltaAC = sanitizeRadians(c - a); return deltaAB < deltaAC; } /** * Solves the lerp equation. * * @param source The starting number. * @param mid The number in the middle. * @param target The ending number. * @return A number t such that lerp(source, target, t) = mid. */ static double intercept(double source, double mid, double target) { return (mid - source) / (target - source); } static double[] lerpPoint(double[] source, double t, double[] target) { return new double[] { source[0] + (target[0] - source[0]) * t, source[1] + (target[1] - source[1]) * t, source[2] + (target[2] - source[2]) * t, }; } /** * Intersects a segment with a plane. * * @param source The coordinates of point A. * @param coordinate The R-, G-, or B-coordinate of the plane. * @param target The coordinates of point B. * @param axis The axis the plane is perpendicular with. (0: R, 1: G, 2: B) * @return The intersection point of the segment AB with the plane R=coordinate, G=coordinate, or * B=coordinate */ static double[] setCoordinate(double[] source, double coordinate, double[] target, int axis) { double t = intercept(source[axis], coordinate, target[axis]); return lerpPoint(source, t, target); } static boolean isBounded(double x) { return 0.0 <= x && x <= 100.0; } /** * Returns the nth possible vertex of the polygonal intersection. * * @param y The Y value of the plane. * @param n The zero-based index of the point. 0 <= n <= 11. * @return The nth possible vertex of the polygonal intersection of the y plane and the RGB cube, * in linear RGB coordinates, if it exists. If this possible vertex lies outside of the cube, * [-1.0, -1.0, -1.0] is returned. */ static double[] nthVertex(double y, int n) { double kR = Y_FROM_LINRGB[0]; double kG = Y_FROM_LINRGB[1]; double kB = Y_FROM_LINRGB[2]; double coordA = n % 4 <= 1 ? 0.0 : 100.0; double coordB = n % 2 == 0 ? 0.0 : 100.0; if (n < 4) { double g = coordA; double b = coordB; double r = (y - g * kG - b * kB) / kR; if (isBounded(r)) { return new double[] {r, g, b}; } else { return new double[] {-1.0, -1.0, -1.0}; } } else if (n < 8) { double b = coordA; double r = coordB; double g = (y - r * kR - b * kB) / kG; if (isBounded(g)) { return new double[] {r, g, b}; } else { return new double[] {-1.0, -1.0, -1.0}; } } else { double r = coordA; double g = coordB; double b = (y - r * kR - g * kG) / kB; if (isBounded(b)) { return new double[] {r, g, b}; } else { return new double[] {-1.0, -1.0, -1.0}; } } } /** * Finds the segment containing the desired color. * * @param y The Y value of the color. * @param targetHue The hue of the color. * @return A list of two sets of linear RGB coordinates, each corresponding to an endpoint of the * segment containing the desired color. */ static double[][] bisectToSegment(double y, double targetHue) { double[] left = new double[] {-1.0, -1.0, -1.0}; double[] right = left; double leftHue = 0.0; double rightHue = 0.0; boolean initialized = false; boolean uncut = true; for (int n = 0; n < 12; n++) { double[] mid = nthVertex(y, n); if (mid[0] < 0) { continue; } double midHue = hueOf(mid); if (!initialized) { left = mid; right = mid; leftHue = midHue; rightHue = midHue; initialized = true; continue; } if (uncut || areInCyclicOrder(leftHue, midHue, rightHue)) { uncut = false; if (areInCyclicOrder(leftHue, targetHue, midHue)) { right = mid; rightHue = midHue; } else { left = mid; leftHue = midHue; } } } return new double[][] {left, right}; } static double[] midpoint(double[] a, double[] b) { return new double[] { (a[0] + b[0]) / 2, (a[1] + b[1]) / 2, (a[2] + b[2]) / 2, }; } static int criticalPlaneBelow(double x) { return (int) Math.floor(x - 0.5); } static int criticalPlaneAbove(double x) { return (int) Math.ceil(x - 0.5); } /** * Finds a color with the given Y and hue on the boundary of the cube. * * @param y The Y value of the color. * @param targetHue The hue of the color. * @return The desired color, in linear RGB coordinates. */ static double[] bisectToLimit(double y, double targetHue) { double[][] segment = bisectToSegment(y, targetHue); double[] left = segment[0]; double leftHue = hueOf(left); double[] right = segment[1]; for (int axis = 0; axis < 3; axis++) { if (left[axis] != right[axis]) { int lPlane = -1; int rPlane = 255; if (left[axis] < right[axis]) { lPlane = criticalPlaneBelow(trueDelinearized(left[axis])); rPlane = criticalPlaneAbove(trueDelinearized(right[axis])); } else { lPlane = criticalPlaneAbove(trueDelinearized(left[axis])); rPlane = criticalPlaneBelow(trueDelinearized(right[axis])); } for (int i = 0; i < 8; i++) { if (Math.abs(rPlane - lPlane) <= 1) { break; } else { int mPlane = (int) Math.floor((lPlane + rPlane) / 2.0); double midPlaneCoordinate = CRITICAL_PLANES[mPlane]; double[] mid = setCoordinate(left, midPlaneCoordinate, right, axis); double midHue = hueOf(mid); if (areInCyclicOrder(leftHue, targetHue, midHue)) { right = mid; rPlane = mPlane; } else { left = mid; leftHue = midHue; lPlane = mPlane; } } } } } return midpoint(left, right); } static double inverseChromaticAdaptation(double adapted) { double adaptedAbs = Math.abs(adapted); double base = Math.max(0, 27.13 * adaptedAbs / (400.0 - adaptedAbs)); return MathUtils.signum(adapted) * Math.pow(base, 1.0 / 0.42); } /** * Finds a color with the given hue, chroma, and Y. * * @param hueRadians The desired hue in radians. * @param chroma The desired chroma. * @param y The desired Y. * @return The desired color as a hexadecimal integer, if found; 0 otherwise. */ static int findResultByJ(double hueRadians, double chroma, double y) { // Initial estimate of j. double j = Math.sqrt(y) * 11.0; // =========================================================== // Operations inlined from Cam16 to avoid repeated calculation // =========================================================== ViewingConditions viewingConditions = ViewingConditions.DEFAULT; double tInnerCoeff = 1 / Math.pow(1.64 - Math.pow(0.29, viewingConditions.getN()), 0.73); double eHue = 0.25 * (Math.cos(hueRadians + 2.0) + 3.8); double p1 = eHue * (50000.0 / 13.0) * viewingConditions.getNc() * viewingConditions.getNcb(); double hSin = Math.sin(hueRadians); double hCos = Math.cos(hueRadians); for (int iterationRound = 0; iterationRound < 5; iterationRound++) { // =========================================================== // Operations inlined from Cam16 to avoid repeated calculation // =========================================================== double jNormalized = j / 100.0; double alpha = chroma == 0.0 || j == 0.0 ? 0.0 : chroma / Math.sqrt(jNormalized); double t = Math.pow(alpha * tInnerCoeff, 1.0 / 0.9); double ac = viewingConditions.getAw() * Math.pow(jNormalized, 1.0 / viewingConditions.getC() / viewingConditions.getZ()); double p2 = ac / viewingConditions.getNbb(); double gamma = 23.0 * (p2 + 0.305) * t / (23.0 * p1 + 11 * t * hCos + 108.0 * t * hSin); double a = gamma * hCos; double b = gamma * hSin; double rA = (460.0 * p2 + 451.0 * a + 288.0 * b) / 1403.0; double gA = (460.0 * p2 - 891.0 * a - 261.0 * b) / 1403.0; double bA = (460.0 * p2 - 220.0 * a - 6300.0 * b) / 1403.0; double rCScaled = inverseChromaticAdaptation(rA); double gCScaled = inverseChromaticAdaptation(gA); double bCScaled = inverseChromaticAdaptation(bA); double[] linrgb = MathUtils.matrixMultiply( new double[] {rCScaled, gCScaled, bCScaled}, LINRGB_FROM_SCALED_DISCOUNT); // =========================================================== // Operations inlined from Cam16 to avoid repeated calculation // =========================================================== if (linrgb[0] < 0 || linrgb[1] < 0 || linrgb[2] < 0) { return 0; } double kR = Y_FROM_LINRGB[0]; double kG = Y_FROM_LINRGB[1]; double kB = Y_FROM_LINRGB[2]; double fnj = kR * linrgb[0] + kG * linrgb[1] + kB * linrgb[2]; if (fnj <= 0) { return 0; } if (iterationRound == 4 || Math.abs(fnj - y) < 0.002) { if (linrgb[0] > 100.01 || linrgb[1] > 100.01 || linrgb[2] > 100.01) { return 0; } return ColorUtils.argbFromLinrgb(linrgb); } // Iterates with Newton method, // Using 2 * fn(j) / j as the approximation of fn'(j) j = j - (fnj - y) * j / (2 * fnj); } return 0; } /** * Finds an sRGB color with the given hue, chroma, and L*, if possible. * * @param hueDegrees The desired hue, in degrees. * @param chroma The desired chroma. * @param lstar The desired L*. * @return A hexadecimal representing the sRGB color. The color has sufficiently close hue, * chroma, and L* to the desired values, if possible; otherwise, the hue and L* will be * sufficiently close, and chroma will be maximized. */ public static int solveToInt(double hueDegrees, double chroma, double lstar) { if (chroma < 0.0001 || lstar < 0.0001 || lstar > 99.9999) { return ColorUtils.argbFromLstar(lstar); } hueDegrees = MathUtils.sanitizeDegreesDouble(hueDegrees); double hueRadians = hueDegrees / 180 * Math.PI; double y = ColorUtils.yFromLstar(lstar); int exactAnswer = findResultByJ(hueRadians, chroma, y); if (exactAnswer != 0) { return exactAnswer; } double[] linrgb = bisectToLimit(y, hueRadians); return ColorUtils.argbFromLinrgb(linrgb); } /** * Finds an sRGB color with the given hue, chroma, and L*, if possible. * * @param hueDegrees The desired hue, in degrees. * @param chroma The desired chroma. * @param lstar The desired L*. * @return An CAM16 object representing the sRGB color. The color has sufficiently close hue, * chroma, and L* to the desired values, if possible; otherwise, the hue and L* will be * sufficiently close, and chroma will be maximized. */ public static Cam16 solveToCam(double hueDegrees, double chroma, double lstar) { return Cam16.fromInt(solveToInt(hueDegrees, chroma, lstar)); } }