/* * Copyright 2021 The LibYuv Project Authors. All rights reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include #include #include #include // This utility computes values needed to generate yuvconstants based on // white point values. // The yuv formulas are tuned for 8 bit YUV channels. // See Also // https://mymusing.co/bt601-yuv-to-rgb-conversion-color/ // BT.709 full range YUV to RGB reference // R = Y + V * 1.5748 // G = Y - U * 0.18732 - V * 0.46812 // B = Y + U * 1.8556 // KR = 0.2126 // KB = 0.0722 // // Y contribution to R,G,B. Scale and bias. // #define YG 16320 /* round(1.000 * 64 * 256 * 256 / 257) */ // #define YB 32 /* 64 / 2 */ // // // U and V contributions to R,G,B. // #define UB 113 /* round(1.77200 * 64) */ // #define UG 22 /* round(0.34414 * 64) */ // #define VG 46 /* round(0.71414 * 64) */ // #define VR 90 /* round(1.40200 * 64) */ // // // Bias values to round, and subtract 128 from U and V. // #define BB (-UB * 128 + YB) // #define BG (UG * 128 + VG * 128 + YB) // #define BR (-VR * 128 + YB) int main(int argc, const char* argv[]) { if (argc < 3) { printf("yuvconstants [KR] [KB]\n"); printf(" e.g. yuvconstants 0.2126 0.0722\n"); printf(" MC BT KR KB\n"); printf(" 1 BT.709 KR = 0.2126; KB = 0.0722\n"); printf(" 4 FCC KR = 0.30; KB = 0.11\n"); printf(" 6 BT.601 KR = 0.299; KB = 0.114\n"); printf(" 7 SMPTE 240M KR = 0.212; KB = 0.087\n"); printf(" 9 BT.2020 KR = 0.2627; KB = 0.0593\n"); return -1; } float kr = (float)atof(argv[1]); float kb = (float)atof(argv[2]); float kg = 1 - kr - kb; float vr = 2 * (1 - kr); float ug = 2 * ((1 - kb) * kb / kg); float vg = 2 * ((1 - kr) * kr / kg); float ub = 2 * (1 - kb); printf("Full range\n"); printf("R = Y + V * %5f\n", vr); printf("G = Y - U * %6f - V * %6f\n", ug, vg); printf("B = Y + U * %5f\n", ub); printf("KR = %4f; ", kr); printf("KB = %4f\n", kb); // printf("KG = %4f\n", kg); // #define YG 16320 /* round(1.000 * 64 * 256 * 256 / 257) */ // #define YB 32 /* 64 / 2 */ // // // U and V contributions to R,G,B. printf("UB %-3.0f /* round(%f * 64 = %8.4f) */\n", round(ub * 64), ub, ub * 64); printf("UG %-3.0f /* round(%f * 64 = %8.4f) */\n", round(ug * 64), ug, ug * 64); printf("VG %-3.0f /* round(%f * 64 = %8.4f) */\n", round(vg * 64), vg, vg * 64); printf("VR %-3.0f /* round(%f * 64 = %8.4f) */\n", round(vr * 64), vr, vr * 64); vr = 255.f / 224.f * 2 * (1 - kr); ug = 255.f / 224.f * 2 * ((1 - kb) * kb / kg); vg = 255.f / 224.f * 2 * ((1 - kr) * kr / kg); ub = 255.f / 224.f * 2 * (1 - kb); printf("\nLimited range\n"); printf("R = (Y - 16) * 1.164 + V * %5f\n", vr); printf("G = (Y - 16) * 1.164 - U * %6f - V * %6f\n", ug, vg); printf("B = (Y - 16) * 1.164 + U * %5f\n", ub); // printf("KG = %4f\n", kg); // #define YG 16320 /* round(1.000 * 64 * 256 * 256 / 257) */ // #define YB 32 /* 64 / 2 */ // // // U and V contributions to R,G,B. printf("UB %-3.0f /* round(%f * 64 = %8.4f) */\n", round(ub * 64), ub, ub * 64); printf("UG %-3.0f /* round(%f * 64 = %8.4f) */\n", round(ug * 64), ug, ug * 64); printf("VG %-3.0f /* round(%f * 64 = %8.4f) */\n", round(vg * 64), vg, vg * 64); printf("VR %-3.0f /* round(%f * 64 = %8.4f) */\n", round(vr * 64), vr, vr * 64); return 0; }