/* * Copyright 2022 The Android Open Source Project * * 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. */ #include #include "ultrahdr/gainmapmath.h" namespace ultrahdr { //////////////////////////////////////////////////////////////////////////////// // Framework float getReferenceDisplayPeakLuminanceInNits(uhdr_color_transfer_t transfer) { switch (transfer) { case UHDR_CT_LINEAR: return kPqMaxNits; case UHDR_CT_HLG: return kHlgMaxNits; case UHDR_CT_PQ: return kPqMaxNits; case UHDR_CT_SRGB: return kSdrWhiteNits; case UHDR_CT_UNSPECIFIED: return -1.0f; } return -1.0f; } //////////////////////////////////////////////////////////////////////////////// // Use Shepard's method for inverse distance weighting. float ShepardsIDW::euclideanDistance(float x1, float x2, float y1, float y2) { return sqrt(((y2 - y1) * (y2 - y1)) + (x2 - x1) * (x2 - x1)); } void ShepardsIDW::fillShepardsIDW(float* weights, int incR, int incB) { for (int y = 0; y < mMapScaleFactor; y++) { for (int x = 0; x < mMapScaleFactor; x++) { float pos_x = ((float)x) / mMapScaleFactor; float pos_y = ((float)y) / mMapScaleFactor; int curr_x = floor(pos_x); int curr_y = floor(pos_y); int next_x = curr_x + incR; int next_y = curr_y + incB; float e1_distance = euclideanDistance(pos_x, curr_x, pos_y, curr_y); int index = y * mMapScaleFactor * 4 + x * 4; if (e1_distance == 0) { weights[index++] = 1.f; weights[index++] = 0.f; weights[index++] = 0.f; weights[index++] = 0.f; } else { float e1_weight = 1.f / e1_distance; float e2_distance = euclideanDistance(pos_x, curr_x, pos_y, next_y); float e2_weight = 1.f / e2_distance; float e3_distance = euclideanDistance(pos_x, next_x, pos_y, curr_y); float e3_weight = 1.f / e3_distance; float e4_distance = euclideanDistance(pos_x, next_x, pos_y, next_y); float e4_weight = 1.f / e4_distance; float total_weight = e1_weight + e2_weight + e3_weight + e4_weight; weights[index++] = e1_weight / total_weight; weights[index++] = e2_weight / total_weight; weights[index++] = e3_weight / total_weight; weights[index++] = e4_weight / total_weight; } } } } //////////////////////////////////////////////////////////////////////////////// // sRGB transformations // See IEC 61966-2-1/Amd 1:2003, Equation F.7. static const float kSrgbR = 0.2126f, kSrgbG = 0.7152f, kSrgbB = 0.0722f; float srgbLuminance(Color e) { return kSrgbR * e.r + kSrgbG * e.g + kSrgbB * e.b; } // See ITU-R BT.709-6, Section 3. // Uses the same coefficients for deriving luma signal as // IEC 61966-2-1/Amd 1:2003 states for luminance, so we reuse the luminance // function above. static const float kSrgbCb = 1.8556f, kSrgbCr = 1.5748f; Color srgbRgbToYuv(Color e_gamma) { float y_gamma = srgbLuminance(e_gamma); return {{{y_gamma, (e_gamma.b - y_gamma) / kSrgbCb, (e_gamma.r - y_gamma) / kSrgbCr}}}; } // See ITU-R BT.709-6, Section 3. // Same derivation to BT.2100's YUV->RGB, below. Similar to srgbRgbToYuv, we // can reuse the luminance coefficients since they are the same. static const float kSrgbGCb = kSrgbB * kSrgbCb / kSrgbG; static const float kSrgbGCr = kSrgbR * kSrgbCr / kSrgbG; Color srgbYuvToRgb(Color e_gamma) { return {{{clampPixelFloat(e_gamma.y + kSrgbCr * e_gamma.v), clampPixelFloat(e_gamma.y - kSrgbGCb * e_gamma.u - kSrgbGCr * e_gamma.v), clampPixelFloat(e_gamma.y + kSrgbCb * e_gamma.u)}}}; } // See IEC 61966-2-1/Amd 1:2003, Equations F.5 and F.6. float srgbInvOetf(float e_gamma) { if (e_gamma <= 0.04045f) { return e_gamma / 12.92f; } else { return pow((e_gamma + 0.055f) / 1.055f, 2.4); } } Color srgbInvOetf(Color e_gamma) { return {{{srgbInvOetf(e_gamma.r), srgbInvOetf(e_gamma.g), srgbInvOetf(e_gamma.b)}}}; } // See IEC 61966-2-1, Equations F.5 and F.6. float srgbInvOetfLUT(float e_gamma) { int32_t value = static_cast(e_gamma * (kSrgbInvOETFNumEntries - 1) + 0.5); // TODO() : Remove once conversion modules have appropriate clamping in place value = CLIP3(value, 0, kSrgbInvOETFNumEntries - 1); static LookUpTable kSrgbLut(kSrgbInvOETFNumEntries, static_cast(srgbInvOetf)); return kSrgbLut.getTable()[value]; } Color srgbInvOetfLUT(Color e_gamma) { return {{{srgbInvOetfLUT(e_gamma.r), srgbInvOetfLUT(e_gamma.g), srgbInvOetfLUT(e_gamma.b)}}}; } float srgbOetf(float e) { constexpr float kThreshold = 0.0031308; constexpr float kLowSlope = 12.92; constexpr float kHighOffset = 0.055; constexpr float kPowerExponent = 1.0 / 2.4; if (e <= kThreshold) { return kLowSlope * e; } return (1.0 + kHighOffset) * std::pow(e, kPowerExponent) - kHighOffset; } Color srgbOetf(Color e) { return {{{srgbOetf(e.r), srgbOetf(e.g), srgbOetf(e.b)}}}; } //////////////////////////////////////////////////////////////////////////////// // Display-P3 transformations // See SMPTE EG 432-1, Equation 7-8. static const float kP3R = 0.20949f, kP3G = 0.72160f, kP3B = 0.06891f; float p3Luminance(Color e) { return kP3R * e.r + kP3G * e.g + kP3B * e.b; } // See ITU-R BT.601-7, Sections 2.5.1 and 2.5.2. // Unfortunately, calculation of luma signal differs from calculation of // luminance for Display-P3, so we can't reuse p3Luminance here. static const float kP3YR = 0.299f, kP3YG = 0.587f, kP3YB = 0.114f; static const float kP3Cb = 1.772f, kP3Cr = 1.402f; Color p3RgbToYuv(Color e_gamma) { float y_gamma = kP3YR * e_gamma.r + kP3YG * e_gamma.g + kP3YB * e_gamma.b; return {{{y_gamma, (e_gamma.b - y_gamma) / kP3Cb, (e_gamma.r - y_gamma) / kP3Cr}}}; } // See ITU-R BT.601-7, Sections 2.5.1 and 2.5.2. // Same derivation to BT.2100's YUV->RGB, below. Similar to p3RgbToYuv, we must // use luma signal coefficients rather than the luminance coefficients. static const float kP3GCb = kP3YB * kP3Cb / kP3YG; static const float kP3GCr = kP3YR * kP3Cr / kP3YG; Color p3YuvToRgb(Color e_gamma) { return {{{clampPixelFloat(e_gamma.y + kP3Cr * e_gamma.v), clampPixelFloat(e_gamma.y - kP3GCb * e_gamma.u - kP3GCr * e_gamma.v), clampPixelFloat(e_gamma.y + kP3Cb * e_gamma.u)}}}; } //////////////////////////////////////////////////////////////////////////////// // BT.2100 transformations - according to ITU-R BT.2100-2 // See ITU-R BT.2100-2, Table 5, HLG Reference OOTF static const float kBt2100R = 0.2627f, kBt2100G = 0.6780f, kBt2100B = 0.0593f; float bt2100Luminance(Color e) { return kBt2100R * e.r + kBt2100G * e.g + kBt2100B * e.b; } // See ITU-R BT.2100-2, Table 6, Derivation of colour difference signals. // BT.2100 uses the same coefficients for calculating luma signal and luminance, // so we reuse the luminance function here. static const float kBt2100Cb = 1.8814f, kBt2100Cr = 1.4746f; Color bt2100RgbToYuv(Color e_gamma) { float y_gamma = bt2100Luminance(e_gamma); return {{{y_gamma, (e_gamma.b - y_gamma) / kBt2100Cb, (e_gamma.r - y_gamma) / kBt2100Cr}}}; } // See ITU-R BT.2100-2, Table 6, Derivation of colour difference signals. // // Similar to bt2100RgbToYuv above, we can reuse the luminance coefficients. // // Derived by inversing bt2100RgbToYuv. The derivation for R and B are pretty // straight forward; we just invert the formulas for U and V above. But deriving // the formula for G is a bit more complicated: // // Start with equation for luminance: // Y = kBt2100R * R + kBt2100G * G + kBt2100B * B // Solve for G: // G = (Y - kBt2100R * R - kBt2100B * B) / kBt2100B // Substitute equations for R and B in terms YUV: // G = (Y - kBt2100R * (Y + kBt2100Cr * V) - kBt2100B * (Y + kBt2100Cb * U)) / kBt2100B // Simplify: // G = Y * ((1 - kBt2100R - kBt2100B) / kBt2100G) // + U * (kBt2100B * kBt2100Cb / kBt2100G) // + V * (kBt2100R * kBt2100Cr / kBt2100G) // // We then get the following coeficients for calculating G from YUV: // // Coef for Y = (1 - kBt2100R - kBt2100B) / kBt2100G = 1 // Coef for U = kBt2100B * kBt2100Cb / kBt2100G = kBt2100GCb = ~0.1645 // Coef for V = kBt2100R * kBt2100Cr / kBt2100G = kBt2100GCr = ~0.5713 static const float kBt2100GCb = kBt2100B * kBt2100Cb / kBt2100G; static const float kBt2100GCr = kBt2100R * kBt2100Cr / kBt2100G; Color bt2100YuvToRgb(Color e_gamma) { return {{{clampPixelFloat(e_gamma.y + kBt2100Cr * e_gamma.v), clampPixelFloat(e_gamma.y - kBt2100GCb * e_gamma.u - kBt2100GCr * e_gamma.v), clampPixelFloat(e_gamma.y + kBt2100Cb * e_gamma.u)}}}; } // See ITU-R BT.2100-2, Table 5, HLG Reference OETF. static const float kHlgA = 0.17883277f, kHlgB = 0.28466892f, kHlgC = 0.55991073; float hlgOetf(float e) { if (e <= 1.0f / 12.0f) { return sqrt(3.0f * e); } else { return kHlgA * log(12.0f * e - kHlgB) + kHlgC; } } Color hlgOetf(Color e) { return {{{hlgOetf(e.r), hlgOetf(e.g), hlgOetf(e.b)}}}; } float hlgOetfLUT(float e) { int32_t value = static_cast(e * (kHlgOETFNumEntries - 1) + 0.5); // TODO() : Remove once conversion modules have appropriate clamping in place value = CLIP3(value, 0, kHlgOETFNumEntries - 1); static LookUpTable kHlgLut(kHlgOETFNumEntries, static_cast(hlgOetf)); return kHlgLut.getTable()[value]; } Color hlgOetfLUT(Color e) { return {{{hlgOetfLUT(e.r), hlgOetfLUT(e.g), hlgOetfLUT(e.b)}}}; } // See ITU-R BT.2100-2, Table 5, HLG Reference EOTF. float hlgInvOetf(float e_gamma) { if (e_gamma <= 0.5f) { return pow(e_gamma, 2.0f) / 3.0f; } else { return (exp((e_gamma - kHlgC) / kHlgA) + kHlgB) / 12.0f; } } Color hlgInvOetf(Color e_gamma) { return {{{hlgInvOetf(e_gamma.r), hlgInvOetf(e_gamma.g), hlgInvOetf(e_gamma.b)}}}; } float hlgInvOetfLUT(float e_gamma) { int32_t value = static_cast(e_gamma * (kHlgInvOETFNumEntries - 1) + 0.5); // TODO() : Remove once conversion modules have appropriate clamping in place value = CLIP3(value, 0, kHlgInvOETFNumEntries - 1); static LookUpTable kHlgInvLut(kHlgInvOETFNumEntries, static_cast(hlgInvOetf)); return kHlgInvLut.getTable()[value]; } Color hlgInvOetfLUT(Color e_gamma) { return {{{hlgInvOetfLUT(e_gamma.r), hlgInvOetfLUT(e_gamma.g), hlgInvOetfLUT(e_gamma.b)}}}; } // 1.2f + 0.42 * log(kHlgMaxNits / 1000) static const float kOotfGamma = 1.2f; Color hlgOotf(Color e, LuminanceFn luminance) { float y = luminance(e); return e * std::pow(y, kOotfGamma - 1.0f); } Color hlgOotfApprox(Color e, [[maybe_unused]] LuminanceFn luminance) { return {{{std::pow(e.r, kOotfGamma), std::pow(e.g, kOotfGamma), std::pow(e.b, kOotfGamma)}}}; } Color hlgInverseOotf(Color e, LuminanceFn luminance) { float y = luminance(e); return e * std::pow(y, (1.0f / kOotfGamma) - 1.0f); } Color hlgInverseOotfApprox(Color e) { return {{{std::pow(e.r, 1.0f / kOotfGamma), std::pow(e.g, 1.0f / kOotfGamma), std::pow(e.b, 1.0f / kOotfGamma)}}}; } // See ITU-R BT.2100-2, Table 4, Reference PQ OETF. static const float kPqM1 = 2610.0f / 16384.0f, kPqM2 = 2523.0f / 4096.0f * 128.0f; static const float kPqC1 = 3424.0f / 4096.0f, kPqC2 = 2413.0f / 4096.0f * 32.0f, kPqC3 = 2392.0f / 4096.0f * 32.0f; float pqOetf(float e) { if (e <= 0.0f) return 0.0f; return pow((kPqC1 + kPqC2 * pow(e, kPqM1)) / (1 + kPqC3 * pow(e, kPqM1)), kPqM2); } Color pqOetf(Color e) { return {{{pqOetf(e.r), pqOetf(e.g), pqOetf(e.b)}}}; } float pqOetfLUT(float e) { int32_t value = static_cast(e * (kPqOETFNumEntries - 1) + 0.5); // TODO() : Remove once conversion modules have appropriate clamping in place value = CLIP3(value, 0, kPqOETFNumEntries - 1); static LookUpTable kPqLut(kPqOETFNumEntries, static_cast(pqOetf)); return kPqLut.getTable()[value]; } Color pqOetfLUT(Color e) { return {{{pqOetfLUT(e.r), pqOetfLUT(e.g), pqOetfLUT(e.b)}}}; } float pqInvOetf(float e_gamma) { float val = pow(e_gamma, (1 / kPqM2)); return pow((((std::max)(val - kPqC1, 0.0f)) / (kPqC2 - kPqC3 * val)), 1 / kPqM1); } Color pqInvOetf(Color e_gamma) { return {{{pqInvOetf(e_gamma.r), pqInvOetf(e_gamma.g), pqInvOetf(e_gamma.b)}}}; } float pqInvOetfLUT(float e_gamma) { int32_t value = static_cast(e_gamma * (kPqInvOETFNumEntries - 1) + 0.5); // TODO() : Remove once conversion modules have appropriate clamping in place value = CLIP3(value, 0, kPqInvOETFNumEntries - 1); static LookUpTable kPqInvLut(kPqInvOETFNumEntries, static_cast(pqInvOetf)); return kPqInvLut.getTable()[value]; } Color pqInvOetfLUT(Color e_gamma) { return {{{pqInvOetfLUT(e_gamma.r), pqInvOetfLUT(e_gamma.g), pqInvOetfLUT(e_gamma.b)}}}; } //////////////////////////////////////////////////////////////////////////////// // Color access functions Color getYuv4abPixel(uhdr_raw_image_t* image, size_t x, size_t y, int h_factor, int v_factor) { uint8_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; uint8_t* cb_data = reinterpret_cast(image->planes[UHDR_PLANE_U]); size_t cb_stride = image->stride[UHDR_PLANE_U]; uint8_t* cr_data = reinterpret_cast(image->planes[UHDR_PLANE_V]); size_t cr_stride = image->stride[UHDR_PLANE_V]; size_t pixel_y_idx = x + y * luma_stride; size_t pixel_cb_idx = x / h_factor + (y / v_factor) * cb_stride; size_t pixel_cr_idx = x / h_factor + (y / v_factor) * cr_stride; uint8_t y_uint = luma_data[pixel_y_idx]; uint8_t u_uint = cb_data[pixel_cb_idx]; uint8_t v_uint = cr_data[pixel_cr_idx]; // 128 bias for UV given we are using jpeglib; see: // https://github.com/kornelski/libjpeg/blob/master/structure.doc return { {{static_cast(y_uint) * (1 / 255.0f), static_cast(u_uint - 128) * (1 / 255.0f), static_cast(v_uint - 128) * (1 / 255.0f)}}}; } Color getYuv444Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { return getYuv4abPixel(image, x, y, 1, 1); } Color getYuv422Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { return getYuv4abPixel(image, x, y, 2, 1); } Color getYuv420Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { return getYuv4abPixel(image, x, y, 2, 2); } Color getYuv400Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint8_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; size_t pixel_y_idx = x + y * luma_stride; uint8_t y_uint = luma_data[pixel_y_idx]; return {{{static_cast(y_uint) * (1 / 255.0f), 0.f, 0.f}}}; } Color getYuv444Pixel10bit(uhdr_raw_image_t* image, size_t x, size_t y) { uint16_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; uint16_t* cb_data = reinterpret_cast(image->planes[UHDR_PLANE_U]); size_t cb_stride = image->stride[UHDR_PLANE_U]; uint16_t* cr_data = reinterpret_cast(image->planes[UHDR_PLANE_V]); size_t cr_stride = image->stride[UHDR_PLANE_V]; size_t pixel_y_idx = y * luma_stride + x; size_t pixel_u_idx = y * cb_stride + x; size_t pixel_v_idx = y * cr_stride + x; uint16_t y_uint = luma_data[pixel_y_idx]; uint16_t u_uint = cb_data[pixel_u_idx]; uint16_t v_uint = cr_data[pixel_v_idx]; if (image->range == UHDR_CR_FULL_RANGE) { return {{{static_cast(y_uint) / 1023.0f, static_cast(u_uint) / 1023.0f - 0.5f, static_cast(v_uint) / 1023.0f - 0.5f}}}; } // Conversions include taking narrow-range into account. return {{{static_cast(y_uint - 64) * (1 / 876.0f), static_cast(u_uint - 64) * (1 / 896.0f) - 0.5f, static_cast(v_uint - 64) * (1 / 896.0f) - 0.5f}}}; } Color getP010Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint16_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; uint16_t* chroma_data = reinterpret_cast(image->planes[UHDR_PLANE_UV]); size_t chroma_stride = image->stride[UHDR_PLANE_UV]; size_t pixel_y_idx = y * luma_stride + x; size_t pixel_u_idx = (y >> 1) * chroma_stride + (x & ~0x1); size_t pixel_v_idx = pixel_u_idx + 1; uint16_t y_uint = luma_data[pixel_y_idx] >> 6; uint16_t u_uint = chroma_data[pixel_u_idx] >> 6; uint16_t v_uint = chroma_data[pixel_v_idx] >> 6; if (image->range == UHDR_CR_FULL_RANGE) { return {{{static_cast(y_uint) / 1023.0f, static_cast(u_uint) / 1023.0f - 0.5f, static_cast(v_uint) / 1023.0f - 0.5f}}}; } // Conversions include taking narrow-range into account. return {{{static_cast(y_uint - 64) * (1 / 876.0f), static_cast(u_uint - 64) * (1 / 896.0f) - 0.5f, static_cast(v_uint - 64) * (1 / 896.0f) - 0.5f}}}; } Color getRgb888Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint8_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; size_t offset = x * 3 + y * srcStride * 3; Color pixel; pixel.r = float(rgbData[offset]); pixel.g = float(rgbData[offset + 1]); pixel.b = float(rgbData[offset + 2]); return pixel / 255.0f; } Color getRgba8888Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint32_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; Color pixel; pixel.r = float(rgbData[x + y * srcStride] & 0xff); pixel.g = float((rgbData[x + y * srcStride] >> 8) & 0xff); pixel.b = float((rgbData[x + y * srcStride] >> 16) & 0xff); return pixel / 255.0f; } Color getRgba1010102Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint32_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; Color pixel; pixel.r = float(rgbData[x + y * srcStride] & 0x3ff); pixel.g = float((rgbData[x + y * srcStride] >> 10) & 0x3ff); pixel.b = float((rgbData[x + y * srcStride] >> 20) & 0x3ff); return pixel / 1023.0f; } Color getRgbaF16Pixel(uhdr_raw_image_t* image, size_t x, size_t y) { uint64_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; Color pixel; pixel.r = halfToFloat(rgbData[x + y * srcStride] & 0xffff); pixel.g = halfToFloat((rgbData[x + y * srcStride] >> 16) & 0xffff); pixel.b = halfToFloat((rgbData[x + y * srcStride] >> 32) & 0xffff); return sanitizePixel(pixel); } static Color samplePixels(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y, GetPixelFn get_pixel_fn) { Color e = {{{0.0f, 0.0f, 0.0f}}}; for (size_t dy = 0; dy < map_scale_factor; ++dy) { for (size_t dx = 0; dx < map_scale_factor; ++dx) { e += get_pixel_fn(image, x * map_scale_factor + dx, y * map_scale_factor + dy); } } return e / static_cast(map_scale_factor * map_scale_factor); } Color sampleYuv444(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getYuv444Pixel); } Color sampleYuv422(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getYuv422Pixel); } Color sampleYuv420(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getYuv420Pixel); } Color sampleP010(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getP010Pixel); } Color sampleYuv44410bit(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getYuv444Pixel10bit); } Color sampleRgba8888(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getRgba8888Pixel); } Color sampleRgba1010102(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getRgba1010102Pixel); } Color sampleRgbaF16(uhdr_raw_image_t* image, size_t map_scale_factor, size_t x, size_t y) { return samplePixels(image, map_scale_factor, x, y, getRgbaF16Pixel); } void putRgba8888Pixel(uhdr_raw_image_t* image, size_t x, size_t y, Color& pixel) { uint32_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; pixel *= 255.0f; pixel += 0.5f; pixel.r = CLIP3(pixel.r, 0.0f, 255.0f); pixel.g = CLIP3(pixel.g, 0.0f, 255.0f); pixel.b = CLIP3(pixel.b, 0.0f, 255.0f); int32_t r0 = int32_t(pixel.r); int32_t g0 = int32_t(pixel.g); int32_t b0 = int32_t(pixel.b); rgbData[x + y * srcStride] = r0 | (g0 << 8) | (b0 << 16) | (255 << 24); // Set alpha to 1.0 } void putRgb888Pixel(uhdr_raw_image_t* image, size_t x, size_t y, Color& pixel) { uint8_t* rgbData = static_cast(image->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = image->stride[UHDR_PLANE_PACKED]; size_t offset = x * 3 + y * srcStride * 3; pixel *= 255.0f; pixel += 0.5f; pixel.r = CLIP3(pixel.r, 0.0f, 255.0f); pixel.g = CLIP3(pixel.g, 0.0f, 255.0f); pixel.b = CLIP3(pixel.b, 0.0f, 255.0f); rgbData[offset] = uint8_t(pixel.r); rgbData[offset + 1] = uint8_t(pixel.r); rgbData[offset + 2] = uint8_t(pixel.b); } void putYuv400Pixel(uhdr_raw_image_t* image, size_t x, size_t y, Color& pixel) { uint8_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; pixel *= 255.0f; pixel += 0.5f; pixel.y = CLIP3(pixel.y, 0.0f, 255.0f); luma_data[x + y * luma_stride] = uint8_t(pixel.y); } void putYuv444Pixel(uhdr_raw_image_t* image, size_t x, size_t y, Color& pixel) { uint8_t* luma_data = reinterpret_cast(image->planes[UHDR_PLANE_Y]); uint8_t* cb_data = reinterpret_cast(image->planes[UHDR_PLANE_U]); uint8_t* cr_data = reinterpret_cast(image->planes[UHDR_PLANE_V]); size_t luma_stride = image->stride[UHDR_PLANE_Y]; size_t cb_stride = image->stride[UHDR_PLANE_U]; size_t cr_stride = image->stride[UHDR_PLANE_V]; pixel *= 255.0f; pixel += 0.5f; pixel.y = CLIP3(pixel.y, 0.0f, 255.0f); pixel.u = CLIP3(pixel.u, 0.0f, 255.0f); pixel.v = CLIP3(pixel.v, 0.0f, 255.0f); luma_data[x + y * luma_stride] = uint8_t(pixel.y); cb_data[x + y * cb_stride] = uint8_t(pixel.u); cr_data[x + y * cr_stride] = uint8_t(pixel.v); } //////////////////////////////////////////////////////////////////////////////// // Color space conversions Color bt709ToP3(Color e) { return {{{0.82254f * e.r + 0.17755f * e.g + 0.00006f * e.b, 0.03312f * e.r + 0.96684f * e.g + -0.00001f * e.b, 0.01706f * e.r + 0.07240f * e.g + 0.91049f * e.b}}}; } Color bt709ToBt2100(Color e) { return {{{0.62740f * e.r + 0.32930f * e.g + 0.04332f * e.b, 0.06904f * e.r + 0.91958f * e.g + 0.01138f * e.b, 0.01636f * e.r + 0.08799f * e.g + 0.89555f * e.b}}}; } Color p3ToBt709(Color e) { return {{{1.22482f * e.r + -0.22490f * e.g + -0.00007f * e.b, -0.04196f * e.r + 1.04199f * e.g + 0.00001f * e.b, -0.01961f * e.r + -0.07865f * e.g + 1.09831f * e.b}}}; } Color p3ToBt2100(Color e) { return {{{0.75378f * e.r + 0.19862f * e.g + 0.04754f * e.b, 0.04576f * e.r + 0.94177f * e.g + 0.01250f * e.b, -0.00121f * e.r + 0.01757f * e.g + 0.98359f * e.b}}}; } Color bt2100ToBt709(Color e) { return {{{1.66045f * e.r + -0.58764f * e.g + -0.07286f * e.b, -0.12445f * e.r + 1.13282f * e.g + -0.00837f * e.b, -0.01811f * e.r + -0.10057f * e.g + 1.11878f * e.b}}}; } Color bt2100ToP3(Color e) { return {{{1.34369f * e.r + -0.28223f * e.g + -0.06135f * e.b, -0.06533f * e.r + 1.07580f * e.g + -0.01051f * e.b, 0.00283f * e.r + -0.01957f * e.g + 1.01679f * e.b}}}; } // All of these conversions are derived from the respective input YUV->RGB conversion followed by // the RGB->YUV for the receiving encoding. They are consistent with the RGB<->YUV functions in // gainmapmath.cpp, given that we use BT.709 encoding for sRGB and BT.601 encoding for Display-P3, // to match DataSpace. // Yuv Bt709 -> Yuv Bt601 // Y' = (1.0 * Y) + ( 0.101579 * U) + ( 0.196076 * V) // U' = (0.0 * Y) + ( 0.989854 * U) + (-0.110653 * V) // V' = (0.0 * Y) + (-0.072453 * U) + ( 0.983398 * V) const std::array kYuvBt709ToBt601 = { 1.0f, 0.101579f, 0.196076f, 0.0f, 0.989854f, -0.110653f, 0.0f, -0.072453f, 0.983398f}; // Yuv Bt709 -> Yuv Bt2100 // Y' = (1.0 * Y) + (-0.016969 * U) + ( 0.096312 * V) // U' = (0.0 * Y) + ( 0.995306 * U) + (-0.051192 * V) // V' = (0.0 * Y) + ( 0.011507 * U) + ( 1.002637 * V) const std::array kYuvBt709ToBt2100 = { 1.0f, -0.016969f, 0.096312f, 0.0f, 0.995306f, -0.051192f, 0.0f, 0.011507f, 1.002637f}; // Yuv Bt601 -> Yuv Bt709 // Y' = (1.0 * Y) + (-0.118188 * U) + (-0.212685 * V) // U' = (0.0 * Y) + ( 1.018640 * U) + ( 0.114618 * V) // V' = (0.0 * Y) + ( 0.075049 * U) + ( 1.025327 * V) const std::array kYuvBt601ToBt709 = { 1.0f, -0.118188f, -0.212685f, 0.0f, 1.018640f, 0.114618f, 0.0f, 0.075049f, 1.025327f}; // Yuv Bt601 -> Yuv Bt2100 // Y' = (1.0 * Y) + (-0.128245 * U) + (-0.115879 * V) // U' = (0.0 * Y) + ( 1.010016 * U) + ( 0.061592 * V) // V' = (0.0 * Y) + ( 0.086969 * U) + ( 1.029350 * V) const std::array kYuvBt601ToBt2100 = { 1.0f, -0.128245f, -0.115879, 0.0f, 1.010016f, 0.061592f, 0.0f, 0.086969f, 1.029350f}; // Yuv Bt2100 -> Yuv Bt709 // Y' = (1.0 * Y) + ( 0.018149 * U) + (-0.095132 * V) // U' = (0.0 * Y) + ( 1.004123 * U) + ( 0.051267 * V) // V' = (0.0 * Y) + (-0.011524 * U) + ( 0.996782 * V) const std::array kYuvBt2100ToBt709 = { 1.0f, 0.018149f, -0.095132f, 0.0f, 1.004123f, 0.051267f, 0.0f, -0.011524f, 0.996782f}; // Yuv Bt2100 -> Yuv Bt601 // Y' = (1.0 * Y) + ( 0.117887 * U) + ( 0.105521 * V) // U' = (0.0 * Y) + ( 0.995211 * U) + (-0.059549 * V) // V' = (0.0 * Y) + (-0.084085 * U) + ( 0.976518 * V) const std::array kYuvBt2100ToBt601 = { 1.0f, 0.117887f, 0.105521f, 0.0f, 0.995211f, -0.059549f, 0.0f, -0.084085f, 0.976518f}; Color yuvColorGamutConversion(Color e_gamma, const std::array& coeffs) { const float y = e_gamma.y * std::get<0>(coeffs) + e_gamma.u * std::get<1>(coeffs) + e_gamma.v * std::get<2>(coeffs); const float u = e_gamma.y * std::get<3>(coeffs) + e_gamma.u * std::get<4>(coeffs) + e_gamma.v * std::get<5>(coeffs); const float v = e_gamma.y * std::get<6>(coeffs) + e_gamma.u * std::get<7>(coeffs) + e_gamma.v * std::get<8>(coeffs); return {{{y, u, v}}}; } void transformYuv420(uhdr_raw_image_t* image, const std::array& coeffs) { for (size_t y = 0; y < image->h / 2; ++y) { for (size_t x = 0; x < image->w / 2; ++x) { Color yuv1 = getYuv420Pixel(image, x * 2, y * 2); Color yuv2 = getYuv420Pixel(image, x * 2 + 1, y * 2); Color yuv3 = getYuv420Pixel(image, x * 2, y * 2 + 1); Color yuv4 = getYuv420Pixel(image, x * 2 + 1, y * 2 + 1); yuv1 = yuvColorGamutConversion(yuv1, coeffs); yuv2 = yuvColorGamutConversion(yuv2, coeffs); yuv3 = yuvColorGamutConversion(yuv3, coeffs); yuv4 = yuvColorGamutConversion(yuv4, coeffs); Color new_uv = (yuv1 + yuv2 + yuv3 + yuv4) / 4.0f; size_t pixel_y1_idx = x * 2 + y * 2 * image->stride[UHDR_PLANE_Y]; size_t pixel_y2_idx = (x * 2 + 1) + y * 2 * image->stride[UHDR_PLANE_Y]; size_t pixel_y3_idx = x * 2 + (y * 2 + 1) * image->stride[UHDR_PLANE_Y]; size_t pixel_y4_idx = (x * 2 + 1) + (y * 2 + 1) * image->stride[UHDR_PLANE_Y]; uint8_t& y1_uint = reinterpret_cast(image->planes[UHDR_PLANE_Y])[pixel_y1_idx]; uint8_t& y2_uint = reinterpret_cast(image->planes[UHDR_PLANE_Y])[pixel_y2_idx]; uint8_t& y3_uint = reinterpret_cast(image->planes[UHDR_PLANE_Y])[pixel_y3_idx]; uint8_t& y4_uint = reinterpret_cast(image->planes[UHDR_PLANE_Y])[pixel_y4_idx]; size_t pixel_u_idx = x + y * image->stride[UHDR_PLANE_U]; uint8_t& u_uint = reinterpret_cast(image->planes[UHDR_PLANE_U])[pixel_u_idx]; size_t pixel_v_idx = x + y * image->stride[UHDR_PLANE_V]; uint8_t& v_uint = reinterpret_cast(image->planes[UHDR_PLANE_V])[pixel_v_idx]; y1_uint = static_cast(CLIP3((yuv1.y * 255.0f + 0.5f), 0, 255)); y2_uint = static_cast(CLIP3((yuv2.y * 255.0f + 0.5f), 0, 255)); y3_uint = static_cast(CLIP3((yuv3.y * 255.0f + 0.5f), 0, 255)); y4_uint = static_cast(CLIP3((yuv4.y * 255.0f + 0.5f), 0, 255)); u_uint = static_cast(CLIP3((new_uv.u * 255.0f + 128.0f + 0.5f), 0, 255)); v_uint = static_cast(CLIP3((new_uv.v * 255.0f + 128.0f + 0.5f), 0, 255)); } } } void transformYuv444(uhdr_raw_image_t* image, const std::array& coeffs) { for (size_t y = 0; y < image->h; ++y) { for (size_t x = 0; x < image->w; ++x) { Color yuv = getYuv444Pixel(image, x, y); yuv = yuvColorGamutConversion(yuv, coeffs); size_t pixel_y_idx = x + y * image->stride[UHDR_PLANE_Y]; uint8_t& y1_uint = reinterpret_cast(image->planes[UHDR_PLANE_Y])[pixel_y_idx]; size_t pixel_u_idx = x + y * image->stride[UHDR_PLANE_U]; uint8_t& u_uint = reinterpret_cast(image->planes[UHDR_PLANE_U])[pixel_u_idx]; size_t pixel_v_idx = x + y * image->stride[UHDR_PLANE_V]; uint8_t& v_uint = reinterpret_cast(image->planes[UHDR_PLANE_V])[pixel_v_idx]; y1_uint = static_cast(CLIP3((yuv.y * 255.0f + 0.5f), 0, 255)); u_uint = static_cast(CLIP3((yuv.u * 255.0f + 128.0f + 0.5f), 0, 255)); v_uint = static_cast(CLIP3((yuv.v * 255.0f + 128.0f + 0.5f), 0, 255)); } } } //////////////////////////////////////////////////////////////////////////////// // Gain map calculations uint8_t encodeGain(float y_sdr, float y_hdr, uhdr_gainmap_metadata_ext_t* metadata) { return encodeGain(y_sdr, y_hdr, metadata, log2(metadata->min_content_boost), log2(metadata->max_content_boost)); } uint8_t encodeGain(float y_sdr, float y_hdr, uhdr_gainmap_metadata_ext_t* metadata, float log2MinContentBoost, float log2MaxContentBoost) { float gain = 1.0f; if (y_sdr > 0.0f) { gain = y_hdr / y_sdr; } if (gain < metadata->min_content_boost) gain = metadata->min_content_boost; if (gain > metadata->max_content_boost) gain = metadata->max_content_boost; float gain_normalized = (log2(gain) - log2MinContentBoost) / (log2MaxContentBoost - log2MinContentBoost); float gain_normalized_gamma = powf(gain_normalized, metadata->gamma); return static_cast(gain_normalized_gamma * 255.0f); } float computeGain(float sdr, float hdr) { if (sdr == 0.0f) return 0.0f; // for sdr black return no gain if (hdr == 0.0f) { // for hdr black, return a gain large enough to attenuate the sdr pel float offset = (1.0f / 64); return log2(offset / (offset + sdr)); } return log2(hdr / sdr); } uint8_t affineMapGain(float gainlog2, float mingainlog2, float maxgainlog2, float gamma) { float mappedVal = (gainlog2 - mingainlog2) / (maxgainlog2 - mingainlog2); if (gamma != 1.0f) mappedVal = pow(mappedVal, gamma); mappedVal *= 255; return CLIP3(mappedVal + 0.5f, 0, 255); } Color applyGain(Color e, float gain, uhdr_gainmap_metadata_ext_t* metadata) { if (metadata->gamma != 1.0f) gain = pow(gain, 1.0f / metadata->gamma); float logBoost = log2(metadata->min_content_boost) * (1.0f - gain) + log2(metadata->max_content_boost) * gain; float gainFactor = exp2(logBoost); return ((e + metadata->offset_sdr) * gainFactor) - metadata->offset_hdr; } Color applyGain(Color e, float gain, uhdr_gainmap_metadata_ext_t* metadata, float gainmapWeight) { if (metadata->gamma != 1.0f) gain = pow(gain, 1.0f / metadata->gamma); float logBoost = log2(metadata->min_content_boost) * (1.0f - gain) + log2(metadata->max_content_boost) * gain; float gainFactor = exp2(logBoost * gainmapWeight); return ((e + metadata->offset_sdr) * gainFactor) - metadata->offset_hdr; } Color applyGainLUT(Color e, float gain, GainLUT& gainLUT, uhdr_gainmap_metadata_ext_t* metadata) { float gainFactor = gainLUT.getGainFactor(gain); return ((e + metadata->offset_sdr) * gainFactor) - metadata->offset_hdr; } Color applyGain(Color e, Color gain, uhdr_gainmap_metadata_ext_t* metadata) { if (metadata->gamma != 1.0f) { gain.r = pow(gain.r, 1.0f / metadata->gamma); gain.g = pow(gain.g, 1.0f / metadata->gamma); gain.b = pow(gain.b, 1.0f / metadata->gamma); } float logBoostR = log2(metadata->min_content_boost) * (1.0f - gain.r) + log2(metadata->max_content_boost) * gain.r; float logBoostG = log2(metadata->min_content_boost) * (1.0f - gain.g) + log2(metadata->max_content_boost) * gain.g; float logBoostB = log2(metadata->min_content_boost) * (1.0f - gain.b) + log2(metadata->max_content_boost) * gain.b; float gainFactorR = exp2(logBoostR); float gainFactorG = exp2(logBoostG); float gainFactorB = exp2(logBoostB); return {{{((e.r + metadata->offset_sdr) * gainFactorR) - metadata->offset_hdr, ((e.g + metadata->offset_sdr) * gainFactorG) - metadata->offset_hdr, ((e.b + metadata->offset_sdr) * gainFactorB) - metadata->offset_hdr}}}; } Color applyGain(Color e, Color gain, uhdr_gainmap_metadata_ext_t* metadata, float gainmapWeight) { if (metadata->gamma != 1.0f) { gain.r = pow(gain.r, 1.0f / metadata->gamma); gain.g = pow(gain.g, 1.0f / metadata->gamma); gain.b = pow(gain.b, 1.0f / metadata->gamma); } float logBoostR = log2(metadata->min_content_boost) * (1.0f - gain.r) + log2(metadata->max_content_boost) * gain.r; float logBoostG = log2(metadata->min_content_boost) * (1.0f - gain.g) + log2(metadata->max_content_boost) * gain.g; float logBoostB = log2(metadata->min_content_boost) * (1.0f - gain.b) + log2(metadata->max_content_boost) * gain.b; float gainFactorR = exp2(logBoostR * gainmapWeight); float gainFactorG = exp2(logBoostG * gainmapWeight); float gainFactorB = exp2(logBoostB * gainmapWeight); return {{{((e.r + metadata->offset_sdr) * gainFactorR) - metadata->offset_hdr, ((e.g + metadata->offset_sdr) * gainFactorG) - metadata->offset_hdr, ((e.b + metadata->offset_sdr) * gainFactorB) - metadata->offset_hdr}}}; } Color applyGainLUT(Color e, Color gain, GainLUT& gainLUT, uhdr_gainmap_metadata_ext_t* metadata) { float gainFactorR = gainLUT.getGainFactor(gain.r); float gainFactorG = gainLUT.getGainFactor(gain.g); float gainFactorB = gainLUT.getGainFactor(gain.b); return {{{((e.r + metadata->offset_sdr) * gainFactorR) - metadata->offset_hdr, ((e.g + metadata->offset_sdr) * gainFactorG) - metadata->offset_hdr, ((e.b + metadata->offset_sdr) * gainFactorB) - metadata->offset_hdr}}}; } // TODO: do we need something more clever for filtering either the map or images // to generate the map? static size_t clamp(const size_t& val, const size_t& low, const size_t& high) { return val < low ? low : (high < val ? high : val); } static float mapUintToFloat(uint8_t map_uint) { return static_cast(map_uint) / 255.0f; } static float pythDistance(float x_diff, float y_diff) { return sqrt(pow(x_diff, 2.0f) + pow(y_diff, 2.0f)); } // TODO: If map_scale_factor is guaranteed to be an integer, then remove the following. float sampleMap(uhdr_raw_image_t* map, float map_scale_factor, size_t x, size_t y) { float x_map = static_cast(x) / map_scale_factor; float y_map = static_cast(y) / map_scale_factor; size_t x_lower = static_cast(floor(x_map)); size_t x_upper = x_lower + 1; size_t y_lower = static_cast(floor(y_map)); size_t y_upper = y_lower + 1; x_lower = clamp(x_lower, 0, map->w - 1); x_upper = clamp(x_upper, 0, map->w - 1); y_lower = clamp(y_lower, 0, map->h - 1); y_upper = clamp(y_upper, 0, map->h - 1); // Use Shepard's method for inverse distance weighting. For more information: // en.wikipedia.org/wiki/Inverse_distance_weighting#Shepard's_method uint8_t* data = reinterpret_cast(map->planes[UHDR_PLANE_Y]); size_t stride = map->stride[UHDR_PLANE_Y]; float e1 = mapUintToFloat(data[x_lower + y_lower * stride]); float e1_dist = pythDistance(x_map - static_cast(x_lower), y_map - static_cast(y_lower)); if (e1_dist == 0.0f) return e1; float e2 = mapUintToFloat(data[x_lower + y_upper * stride]); float e2_dist = pythDistance(x_map - static_cast(x_lower), y_map - static_cast(y_upper)); if (e2_dist == 0.0f) return e2; float e3 = mapUintToFloat(data[x_upper + y_lower * stride]); float e3_dist = pythDistance(x_map - static_cast(x_upper), y_map - static_cast(y_lower)); if (e3_dist == 0.0f) return e3; float e4 = mapUintToFloat(data[x_upper + y_upper * stride]); float e4_dist = pythDistance(x_map - static_cast(x_upper), y_map - static_cast(y_upper)); if (e4_dist == 0.0f) return e2; float e1_weight = 1.0f / e1_dist; float e2_weight = 1.0f / e2_dist; float e3_weight = 1.0f / e3_dist; float e4_weight = 1.0f / e4_dist; float total_weight = e1_weight + e2_weight + e3_weight + e4_weight; return e1 * (e1_weight / total_weight) + e2 * (e2_weight / total_weight) + e3 * (e3_weight / total_weight) + e4 * (e4_weight / total_weight); } float sampleMap(uhdr_raw_image_t* map, size_t map_scale_factor, size_t x, size_t y, ShepardsIDW& weightTables) { // TODO: If map_scale_factor is guaranteed to be an integer power of 2, then optimize the // following by computing log2(map_scale_factor) once and then using >> log2(map_scale_factor) size_t x_lower = x / map_scale_factor; size_t x_upper = x_lower + 1; size_t y_lower = y / map_scale_factor; size_t y_upper = y_lower + 1; x_lower = std::min(x_lower, (size_t)map->w - 1); x_upper = std::min(x_upper, (size_t)map->w - 1); y_lower = std::min(y_lower, (size_t)map->h - 1); y_upper = std::min(y_upper, (size_t)map->h - 1); uint8_t* data = reinterpret_cast(map->planes[UHDR_PLANE_Y]); size_t stride = map->stride[UHDR_PLANE_Y]; float e1 = mapUintToFloat(data[x_lower + y_lower * stride]); float e2 = mapUintToFloat(data[x_lower + y_upper * stride]); float e3 = mapUintToFloat(data[x_upper + y_lower * stride]); float e4 = mapUintToFloat(data[x_upper + y_upper * stride]); // TODO: If map_scale_factor is guaranteed to be an integer power of 2, then optimize the // following by using & (map_scale_factor - 1) size_t offset_x = x % map_scale_factor; size_t offset_y = y % map_scale_factor; float* weights = weightTables.mWeights; if (x_lower == x_upper && y_lower == y_upper) weights = weightTables.mWeightsC; else if (x_lower == x_upper) weights = weightTables.mWeightsNR; else if (y_lower == y_upper) weights = weightTables.mWeightsNB; weights += offset_y * map_scale_factor * 4 + offset_x * 4; return e1 * weights[0] + e2 * weights[1] + e3 * weights[2] + e4 * weights[3]; } Color sampleMap3Channel(uhdr_raw_image_t* map, float map_scale_factor, size_t x, size_t y, bool has_alpha) { float x_map = static_cast(x) / map_scale_factor; float y_map = static_cast(y) / map_scale_factor; size_t x_lower = static_cast(floor(x_map)); size_t x_upper = x_lower + 1; size_t y_lower = static_cast(floor(y_map)); size_t y_upper = y_lower + 1; x_lower = std::min(x_lower, (size_t)map->w - 1); x_upper = std::min(x_upper, (size_t)map->w - 1); y_lower = std::min(y_lower, (size_t)map->h - 1); y_upper = std::min(y_upper, (size_t)map->h - 1); int factor = has_alpha ? 4 : 3; uint8_t* data = reinterpret_cast(map->planes[UHDR_PLANE_PACKED]); size_t stride = map->stride[UHDR_PLANE_PACKED]; float r1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor]); float r2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor]); float r3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor]); float r4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor]); float g1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor + 1]); float g2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor + 1]); float g3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor + 1]); float g4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor + 1]); float b1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor + 2]); float b2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor + 2]); float b3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor + 2]); float b4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor + 2]); Color rgb1 = {{{r1, g1, b1}}}; Color rgb2 = {{{r2, g2, b2}}}; Color rgb3 = {{{r3, g3, b3}}}; Color rgb4 = {{{r4, g4, b4}}}; // Use Shepard's method for inverse distance weighting. For more information: // en.wikipedia.org/wiki/Inverse_distance_weighting#Shepard's_method float e1_dist = pythDistance(x_map - static_cast(x_lower), y_map - static_cast(y_lower)); if (e1_dist == 0.0f) return rgb1; float e2_dist = pythDistance(x_map - static_cast(x_lower), y_map - static_cast(y_upper)); if (e2_dist == 0.0f) return rgb2; float e3_dist = pythDistance(x_map - static_cast(x_upper), y_map - static_cast(y_lower)); if (e3_dist == 0.0f) return rgb3; float e4_dist = pythDistance(x_map - static_cast(x_upper), y_map - static_cast(y_upper)); if (e4_dist == 0.0f) return rgb4; float e1_weight = 1.0f / e1_dist; float e2_weight = 1.0f / e2_dist; float e3_weight = 1.0f / e3_dist; float e4_weight = 1.0f / e4_dist; float total_weight = e1_weight + e2_weight + e3_weight + e4_weight; return rgb1 * (e1_weight / total_weight) + rgb2 * (e2_weight / total_weight) + rgb3 * (e3_weight / total_weight) + rgb4 * (e4_weight / total_weight); } Color sampleMap3Channel(uhdr_raw_image_t* map, size_t map_scale_factor, size_t x, size_t y, ShepardsIDW& weightTables, bool has_alpha) { // TODO: If map_scale_factor is guaranteed to be an integer power of 2, then optimize the // following by computing log2(map_scale_factor) once and then using >> log2(map_scale_factor) size_t x_lower = x / map_scale_factor; size_t x_upper = x_lower + 1; size_t y_lower = y / map_scale_factor; size_t y_upper = y_lower + 1; x_lower = std::min(x_lower, (size_t)map->w - 1); x_upper = std::min(x_upper, (size_t)map->w - 1); y_lower = std::min(y_lower, (size_t)map->h - 1); y_upper = std::min(y_upper, (size_t)map->h - 1); int factor = has_alpha ? 4 : 3; uint8_t* data = reinterpret_cast(map->planes[UHDR_PLANE_PACKED]); size_t stride = map->stride[UHDR_PLANE_PACKED]; float r1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor]); float r2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor]); float r3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor]); float r4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor]); float g1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor + 1]); float g2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor + 1]); float g3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor + 1]); float g4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor + 1]); float b1 = mapUintToFloat(data[(x_lower + y_lower * stride) * factor + 2]); float b2 = mapUintToFloat(data[(x_lower + y_upper * stride) * factor + 2]); float b3 = mapUintToFloat(data[(x_upper + y_lower * stride) * factor + 2]); float b4 = mapUintToFloat(data[(x_upper + y_upper * stride) * factor + 2]); Color rgb1 = {{{r1, g1, b1}}}; Color rgb2 = {{{r2, g2, b2}}}; Color rgb3 = {{{r3, g3, b3}}}; Color rgb4 = {{{r4, g4, b4}}}; // TODO: If map_scale_factor is guaranteed to be an integer power of 2, then optimize the // following by using & (map_scale_factor - 1) size_t offset_x = x % map_scale_factor; size_t offset_y = y % map_scale_factor; float* weights = weightTables.mWeights; if (x_lower == x_upper && y_lower == y_upper) weights = weightTables.mWeightsC; else if (x_lower == x_upper) weights = weightTables.mWeightsNR; else if (y_lower == y_upper) weights = weightTables.mWeightsNB; weights += offset_y * map_scale_factor * 4 + offset_x * 4; return rgb1 * weights[0] + rgb2 * weights[1] + rgb3 * weights[2] + rgb4 * weights[3]; } //////////////////////////////////////////////////////////////////////////////// // function selectors // TODO: confirm we always want to convert like this before calculating // luminance. ColorTransformFn getGamutConversionFn(uhdr_color_gamut_t dst_gamut, uhdr_color_gamut_t src_gamut) { switch (dst_gamut) { case UHDR_CG_BT_709: switch (src_gamut) { case UHDR_CG_BT_709: return identityConversion; case UHDR_CG_DISPLAY_P3: return p3ToBt709; case UHDR_CG_BT_2100: return bt2100ToBt709; case UHDR_CG_UNSPECIFIED: return nullptr; } break; case UHDR_CG_DISPLAY_P3: switch (src_gamut) { case UHDR_CG_BT_709: return bt709ToP3; case UHDR_CG_DISPLAY_P3: return identityConversion; case UHDR_CG_BT_2100: return bt2100ToP3; case UHDR_CG_UNSPECIFIED: return nullptr; } break; case UHDR_CG_BT_2100: switch (src_gamut) { case UHDR_CG_BT_709: return bt709ToBt2100; case UHDR_CG_DISPLAY_P3: return p3ToBt2100; case UHDR_CG_BT_2100: return identityConversion; case UHDR_CG_UNSPECIFIED: return nullptr; } break; case UHDR_CG_UNSPECIFIED: return nullptr; } return nullptr; } ColorTransformFn getYuvToRgbFn(uhdr_color_gamut_t gamut) { switch (gamut) { case UHDR_CG_BT_709: return srgbYuvToRgb; case UHDR_CG_DISPLAY_P3: return p3YuvToRgb; case UHDR_CG_BT_2100: return bt2100YuvToRgb; case UHDR_CG_UNSPECIFIED: return nullptr; } return nullptr; } LuminanceFn getLuminanceFn(uhdr_color_gamut_t gamut) { switch (gamut) { case UHDR_CG_BT_709: return srgbLuminance; case UHDR_CG_DISPLAY_P3: return p3Luminance; case UHDR_CG_BT_2100: return bt2100Luminance; case UHDR_CG_UNSPECIFIED: return nullptr; } return nullptr; } ColorTransformFn getInverseOetfFn(uhdr_color_transfer_t transfer) { switch (transfer) { case UHDR_CT_LINEAR: return identityConversion; case UHDR_CT_HLG: #if USE_HLG_INVOETF_LUT return hlgInvOetfLUT; #else return hlgInvOetf; #endif case UHDR_CT_PQ: #if USE_PQ_INVOETF_LUT return pqInvOetfLUT; #else return pqInvOetf; #endif case UHDR_CT_SRGB: #if USE_SRGB_INVOETF_LUT return srgbInvOetfLUT; #else return srgbInvOetf; #endif case UHDR_CT_UNSPECIFIED: return nullptr; } return nullptr; } SceneToDisplayLuminanceFn getOotfFn(uhdr_color_transfer_t transfer) { switch (transfer) { case UHDR_CT_LINEAR: return identityOotf; case UHDR_CT_HLG: return hlgOotfApprox; case UHDR_CT_PQ: return identityOotf; case UHDR_CT_SRGB: return identityOotf; case UHDR_CT_UNSPECIFIED: return nullptr; } return nullptr; } GetPixelFn getPixelFn(uhdr_img_fmt_t format) { switch (format) { case UHDR_IMG_FMT_24bppYCbCr444: return getYuv444Pixel; case UHDR_IMG_FMT_16bppYCbCr422: return getYuv422Pixel; case UHDR_IMG_FMT_12bppYCbCr420: return getYuv420Pixel; case UHDR_IMG_FMT_24bppYCbCrP010: return getP010Pixel; case UHDR_IMG_FMT_30bppYCbCr444: return getYuv444Pixel10bit; case UHDR_IMG_FMT_32bppRGBA8888: return getRgba8888Pixel; case UHDR_IMG_FMT_32bppRGBA1010102: return getRgba1010102Pixel; case UHDR_IMG_FMT_64bppRGBAHalfFloat: return getRgbaF16Pixel; case UHDR_IMG_FMT_8bppYCbCr400: return getYuv400Pixel; case UHDR_IMG_FMT_24bppRGB888: return getRgb888Pixel; default: return nullptr; } return nullptr; } PutPixelFn putPixelFn(uhdr_img_fmt_t format) { switch (format) { case UHDR_IMG_FMT_24bppYCbCr444: return putYuv444Pixel; case UHDR_IMG_FMT_32bppRGBA8888: return putRgba8888Pixel; case UHDR_IMG_FMT_8bppYCbCr400: return putYuv400Pixel; case UHDR_IMG_FMT_24bppRGB888: return putRgb888Pixel; default: return nullptr; } return nullptr; } SamplePixelFn getSamplePixelFn(uhdr_img_fmt_t format) { switch (format) { case UHDR_IMG_FMT_24bppYCbCr444: return sampleYuv444; case UHDR_IMG_FMT_16bppYCbCr422: return sampleYuv422; case UHDR_IMG_FMT_12bppYCbCr420: return sampleYuv420; case UHDR_IMG_FMT_24bppYCbCrP010: return sampleP010; case UHDR_IMG_FMT_30bppYCbCr444: return sampleYuv44410bit; case UHDR_IMG_FMT_32bppRGBA8888: return sampleRgba8888; case UHDR_IMG_FMT_32bppRGBA1010102: return sampleRgba1010102; case UHDR_IMG_FMT_64bppRGBAHalfFloat: return sampleRgbaF16; default: return nullptr; } return nullptr; } //////////////////////////////////////////////////////////////////////////////// // common utils bool isPixelFormatRgb(uhdr_img_fmt_t format) { return format == UHDR_IMG_FMT_64bppRGBAHalfFloat || format == UHDR_IMG_FMT_32bppRGBA8888 || format == UHDR_IMG_FMT_32bppRGBA1010102; } uint32_t colorToRgba1010102(Color e_gamma) { uint32_t r = CLIP3((e_gamma.r * 1023 + 0.5f), 0.0f, 1023.0f); uint32_t g = CLIP3((e_gamma.g * 1023 + 0.5f), 0.0f, 1023.0f); uint32_t b = CLIP3((e_gamma.b * 1023 + 0.5f), 0.0f, 1023.0f); return (r | (g << 10) | (b << 20) | (0x3 << 30)); // Set alpha to 1.0 } uint64_t colorToRgbaF16(Color e_gamma) { return (uint64_t)floatToHalf(e_gamma.r) | (((uint64_t)floatToHalf(e_gamma.g)) << 16) | (((uint64_t)floatToHalf(e_gamma.b)) << 32) | (((uint64_t)floatToHalf(1.0f)) << 48); } std::unique_ptr convert_raw_input_to_ycbcr(uhdr_raw_image_t* src, bool chroma_sampling_enabled) { std::unique_ptr dst = nullptr; Color (*rgbToyuv)(Color) = nullptr; if (src->fmt == UHDR_IMG_FMT_32bppRGBA1010102 || src->fmt == UHDR_IMG_FMT_32bppRGBA8888) { if (src->cg == UHDR_CG_BT_709) { rgbToyuv = srgbRgbToYuv; } else if (src->cg == UHDR_CG_BT_2100) { rgbToyuv = bt2100RgbToYuv; } else if (src->cg == UHDR_CG_DISPLAY_P3) { rgbToyuv = p3RgbToYuv; } else { return dst; } } if (src->fmt == UHDR_IMG_FMT_32bppRGBA1010102 && chroma_sampling_enabled) { dst = std::make_unique(UHDR_IMG_FMT_24bppYCbCrP010, src->cg, src->ct, UHDR_CR_FULL_RANGE, src->w, src->h, 64); uint32_t* rgbData = static_cast(src->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = src->stride[UHDR_PLANE_PACKED]; uint16_t* yData = static_cast(dst->planes[UHDR_PLANE_Y]); uint16_t* uData = static_cast(dst->planes[UHDR_PLANE_UV]); uint16_t* vData = uData + 1; for (size_t i = 0; i < dst->h; i += 2) { for (size_t j = 0; j < dst->w; j += 2) { Color pixel[4]; pixel[0].r = float(rgbData[srcStride * i + j] & 0x3ff); pixel[0].g = float((rgbData[srcStride * i + j] >> 10) & 0x3ff); pixel[0].b = float((rgbData[srcStride * i + j] >> 20) & 0x3ff); pixel[1].r = float(rgbData[srcStride * i + j + 1] & 0x3ff); pixel[1].g = float((rgbData[srcStride * i + j + 1] >> 10) & 0x3ff); pixel[1].b = float((rgbData[srcStride * i + j + 1] >> 20) & 0x3ff); pixel[2].r = float(rgbData[srcStride * (i + 1) + j] & 0x3ff); pixel[2].g = float((rgbData[srcStride * (i + 1) + j] >> 10) & 0x3ff); pixel[2].b = float((rgbData[srcStride * (i + 1) + j] >> 20) & 0x3ff); pixel[3].r = float(rgbData[srcStride * (i + 1) + j + 1] & 0x3ff); pixel[3].g = float((rgbData[srcStride * (i + 1) + j + 1] >> 10) & 0x3ff); pixel[3].b = float((rgbData[srcStride * (i + 1) + j + 1] >> 20) & 0x3ff); for (int k = 0; k < 4; k++) { // Now we only support the RGB input being full range pixel[k] /= 1023.0f; pixel[k] = (*rgbToyuv)(pixel[k]); pixel[k].y = (pixel[k].y * 1023.0f) + 0.5f; pixel[k].y = CLIP3(pixel[k].y, 0.0f, 1023.0f); } yData[dst->stride[UHDR_PLANE_Y] * i + j] = uint16_t(pixel[0].y) << 6; yData[dst->stride[UHDR_PLANE_Y] * i + j + 1] = uint16_t(pixel[1].y) << 6; yData[dst->stride[UHDR_PLANE_Y] * (i + 1) + j] = uint16_t(pixel[2].y) << 6; yData[dst->stride[UHDR_PLANE_Y] * (i + 1) + j + 1] = uint16_t(pixel[3].y) << 6; pixel[0].u = (pixel[0].u + pixel[1].u + pixel[2].u + pixel[3].u) / 4; pixel[0].v = (pixel[0].v + pixel[1].v + pixel[2].v + pixel[3].v) / 4; pixel[0].u = (pixel[0].u * 1023.0f) + 512.0f + 0.5f; pixel[0].v = (pixel[0].v * 1023.0f) + 512.0f + 0.5f; pixel[0].u = CLIP3(pixel[0].u, 0.0f, 1023.0f); pixel[0].v = CLIP3(pixel[0].v, 0.0f, 1023.0f); uData[dst->stride[UHDR_PLANE_UV] * (i / 2) + j] = uint16_t(pixel[0].u) << 6; vData[dst->stride[UHDR_PLANE_UV] * (i / 2) + j] = uint16_t(pixel[0].v) << 6; } } } else if (src->fmt == UHDR_IMG_FMT_32bppRGBA1010102) { dst = std::make_unique(UHDR_IMG_FMT_30bppYCbCr444, src->cg, src->ct, UHDR_CR_FULL_RANGE, src->w, src->h, 64); uint32_t* rgbData = static_cast(src->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = src->stride[UHDR_PLANE_PACKED]; uint16_t* yData = static_cast(dst->planes[UHDR_PLANE_Y]); uint16_t* uData = static_cast(dst->planes[UHDR_PLANE_U]); uint16_t* vData = static_cast(dst->planes[UHDR_PLANE_V]); for (size_t i = 0; i < dst->h; i++) { for (size_t j = 0; j < dst->w; j++) { Color pixel; pixel.r = float(rgbData[srcStride * i + j] & 0x3ff); pixel.g = float((rgbData[srcStride * i + j] >> 10) & 0x3ff); pixel.b = float((rgbData[srcStride * i + j] >> 20) & 0x3ff); // Now we only support the RGB input being full range pixel /= 1023.0f; pixel = (*rgbToyuv)(pixel); pixel.y = (pixel.y * 1023.0f) + 0.5f; pixel.y = CLIP3(pixel.y, 0.0f, 1023.0f); yData[dst->stride[UHDR_PLANE_Y] * i + j] = uint16_t(pixel.y); pixel.u = (pixel.u * 1023.0f) + 512.0f + 0.5f; pixel.v = (pixel.v * 1023.0f) + 512.0f + 0.5f; pixel.u = CLIP3(pixel.u, 0.0f, 1023.0f); pixel.v = CLIP3(pixel.v, 0.0f, 1023.0f); uData[dst->stride[UHDR_PLANE_U] * i + j] = uint16_t(pixel.u); vData[dst->stride[UHDR_PLANE_V] * i + j] = uint16_t(pixel.v); } } } else if (src->fmt == UHDR_IMG_FMT_32bppRGBA8888 && chroma_sampling_enabled) { dst = std::make_unique(UHDR_IMG_FMT_12bppYCbCr420, src->cg, src->ct, UHDR_CR_FULL_RANGE, src->w, src->h, 64); uint32_t* rgbData = static_cast(src->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = src->stride[UHDR_PLANE_PACKED]; uint8_t* yData = static_cast(dst->planes[UHDR_PLANE_Y]); uint8_t* uData = static_cast(dst->planes[UHDR_PLANE_U]); uint8_t* vData = static_cast(dst->planes[UHDR_PLANE_V]); for (size_t i = 0; i < dst->h; i += 2) { for (size_t j = 0; j < dst->w; j += 2) { Color pixel[4]; pixel[0].r = float(rgbData[srcStride * i + j] & 0xff); pixel[0].g = float((rgbData[srcStride * i + j] >> 8) & 0xff); pixel[0].b = float((rgbData[srcStride * i + j] >> 16) & 0xff); pixel[1].r = float(rgbData[srcStride * i + (j + 1)] & 0xff); pixel[1].g = float((rgbData[srcStride * i + (j + 1)] >> 8) & 0xff); pixel[1].b = float((rgbData[srcStride * i + (j + 1)] >> 16) & 0xff); pixel[2].r = float(rgbData[srcStride * (i + 1) + j] & 0xff); pixel[2].g = float((rgbData[srcStride * (i + 1) + j] >> 8) & 0xff); pixel[2].b = float((rgbData[srcStride * (i + 1) + j] >> 16) & 0xff); pixel[3].r = float(rgbData[srcStride * (i + 1) + (j + 1)] & 0xff); pixel[3].g = float((rgbData[srcStride * (i + 1) + (j + 1)] >> 8) & 0xff); pixel[3].b = float((rgbData[srcStride * (i + 1) + (j + 1)] >> 16) & 0xff); for (int k = 0; k < 4; k++) { // Now we only support the RGB input being full range pixel[k] /= 255.0f; pixel[k] = (*rgbToyuv)(pixel[k]); pixel[k].y = pixel[k].y * 255.0f + 0.5f; pixel[k].y = CLIP3(pixel[k].y, 0.0f, 255.0f); } yData[dst->stride[UHDR_PLANE_Y] * i + j] = uint8_t(pixel[0].y); yData[dst->stride[UHDR_PLANE_Y] * i + j + 1] = uint8_t(pixel[1].y); yData[dst->stride[UHDR_PLANE_Y] * (i + 1) + j] = uint8_t(pixel[2].y); yData[dst->stride[UHDR_PLANE_Y] * (i + 1) + j + 1] = uint8_t(pixel[3].y); pixel[0].u = (pixel[0].u + pixel[1].u + pixel[2].u + pixel[3].u) / 4; pixel[0].v = (pixel[0].v + pixel[1].v + pixel[2].v + pixel[3].v) / 4; pixel[0].u = pixel[0].u * 255.0f + 0.5f + 128.0f; pixel[0].v = pixel[0].v * 255.0f + 0.5f + 128.0f; pixel[0].u = CLIP3(pixel[0].u, 0.0f, 255.0f); pixel[0].v = CLIP3(pixel[0].v, 0.0f, 255.0f); uData[dst->stride[UHDR_PLANE_U] * (i / 2) + (j / 2)] = uint8_t(pixel[0].u); vData[dst->stride[UHDR_PLANE_V] * (i / 2) + (j / 2)] = uint8_t(pixel[0].v); } } } else if (src->fmt == UHDR_IMG_FMT_32bppRGBA8888) { dst = std::make_unique(UHDR_IMG_FMT_24bppYCbCr444, src->cg, src->ct, UHDR_CR_FULL_RANGE, src->w, src->h, 64); uint32_t* rgbData = static_cast(src->planes[UHDR_PLANE_PACKED]); unsigned int srcStride = src->stride[UHDR_PLANE_PACKED]; uint8_t* yData = static_cast(dst->planes[UHDR_PLANE_Y]); uint8_t* uData = static_cast(dst->planes[UHDR_PLANE_U]); uint8_t* vData = static_cast(dst->planes[UHDR_PLANE_V]); for (size_t i = 0; i < dst->h; i++) { for (size_t j = 0; j < dst->w; j++) { Color pixel; pixel.r = float(rgbData[srcStride * i + j] & 0xff); pixel.g = float((rgbData[srcStride * i + j] >> 8) & 0xff); pixel.b = float((rgbData[srcStride * i + j] >> 16) & 0xff); // Now we only support the RGB input being full range pixel /= 255.0f; pixel = (*rgbToyuv)(pixel); pixel.y = pixel.y * 255.0f + 0.5f; pixel.y = CLIP3(pixel.y, 0.0f, 255.0f); yData[dst->stride[UHDR_PLANE_Y] * i + j] = uint8_t(pixel.y); pixel.u = pixel.u * 255.0f + 0.5f + 128.0f; pixel.v = pixel.v * 255.0f + 0.5f + 128.0f; pixel.u = CLIP3(pixel.u, 0.0f, 255.0f); pixel.v = CLIP3(pixel.v, 0.0f, 255.0f); uData[dst->stride[UHDR_PLANE_U] * i + j] = uint8_t(pixel.u); vData[dst->stride[UHDR_PLANE_V] * i + j] = uint8_t(pixel.v); } } } else if (src->fmt == UHDR_IMG_FMT_12bppYCbCr420 || src->fmt == UHDR_IMG_FMT_24bppYCbCrP010) { dst = std::make_unique(src->fmt, src->cg, src->ct, src->range, src->w, src->h, 64); auto status = copy_raw_image(src, dst.get()); if (status.error_code != UHDR_CODEC_OK) return nullptr; } return dst; } std::unique_ptr copy_raw_image(uhdr_raw_image_t* src) { std::unique_ptr dst = std::make_unique( src->fmt, src->cg, src->ct, src->range, src->w, src->h, 64); auto status = copy_raw_image(src, dst.get()); if (status.error_code != UHDR_CODEC_OK) return nullptr; return dst; } uhdr_error_info_t copy_raw_image(uhdr_raw_image_t* src, uhdr_raw_image_t* dst) { if (dst->w != src->w || dst->h != src->h) { uhdr_error_info_t status; status.error_code = UHDR_CODEC_MEM_ERROR; status.has_detail = 1; snprintf(status.detail, sizeof status.detail, "destination image dimensions %dx%d and source image dimensions %dx%d are not " "identical for copy_raw_image", dst->w, dst->h, src->w, src->h); return status; } dst->cg = src->cg; dst->ct = src->ct; dst->range = src->range; if (dst->fmt == src->fmt) { if (src->fmt == UHDR_IMG_FMT_24bppYCbCrP010) { size_t bpp = 2; uint8_t* y_dst = static_cast(dst->planes[UHDR_PLANE_Y]); uint8_t* y_src = static_cast(src->planes[UHDR_PLANE_Y]); uint8_t* uv_dst = static_cast(dst->planes[UHDR_PLANE_UV]); uint8_t* uv_src = static_cast(src->planes[UHDR_PLANE_UV]); // copy y for (size_t i = 0; i < src->h; i++) { memcpy(y_dst, y_src, src->w * bpp); y_dst += (dst->stride[UHDR_PLANE_Y] * bpp); y_src += (src->stride[UHDR_PLANE_Y] * bpp); } // copy cbcr for (size_t i = 0; i < src->h / 2; i++) { memcpy(uv_dst, uv_src, src->w * bpp); uv_dst += (dst->stride[UHDR_PLANE_UV] * bpp); uv_src += (src->stride[UHDR_PLANE_UV] * bpp); } return g_no_error; } else if (src->fmt == UHDR_IMG_FMT_12bppYCbCr420) { uint8_t* y_dst = static_cast(dst->planes[UHDR_PLANE_Y]); uint8_t* y_src = static_cast(src->planes[UHDR_PLANE_Y]); uint8_t* u_dst = static_cast(dst->planes[UHDR_PLANE_U]); uint8_t* u_src = static_cast(src->planes[UHDR_PLANE_U]); uint8_t* v_dst = static_cast(dst->planes[UHDR_PLANE_V]); uint8_t* v_src = static_cast(src->planes[UHDR_PLANE_V]); // copy y for (size_t i = 0; i < src->h; i++) { memcpy(y_dst, y_src, src->w); y_dst += dst->stride[UHDR_PLANE_Y]; y_src += src->stride[UHDR_PLANE_Y]; } // copy cb & cr for (size_t i = 0; i < src->h / 2; i++) { memcpy(u_dst, u_src, src->w / 2); memcpy(v_dst, v_src, src->w / 2); u_dst += dst->stride[UHDR_PLANE_U]; v_dst += dst->stride[UHDR_PLANE_V]; u_src += src->stride[UHDR_PLANE_U]; v_src += src->stride[UHDR_PLANE_V]; } return g_no_error; } else if (src->fmt == UHDR_IMG_FMT_8bppYCbCr400 || src->fmt == UHDR_IMG_FMT_32bppRGBA8888 || src->fmt == UHDR_IMG_FMT_64bppRGBAHalfFloat || src->fmt == UHDR_IMG_FMT_32bppRGBA1010102 || src->fmt == UHDR_IMG_FMT_24bppRGB888) { uint8_t* plane_dst = static_cast(dst->planes[UHDR_PLANE_PACKED]); uint8_t* plane_src = static_cast(src->planes[UHDR_PLANE_PACKED]); size_t bpp = 1; if (src->fmt == UHDR_IMG_FMT_32bppRGBA1010102 || src->fmt == UHDR_IMG_FMT_32bppRGBA8888) bpp = 4; else if (src->fmt == UHDR_IMG_FMT_64bppRGBAHalfFloat) bpp = 8; else if (src->fmt == UHDR_IMG_FMT_24bppRGB888) bpp = 3; for (size_t i = 0; i < src->h; i++) { memcpy(plane_dst, plane_src, src->w * bpp); plane_dst += (bpp * dst->stride[UHDR_PLANE_PACKED]); plane_src += (bpp * src->stride[UHDR_PLANE_PACKED]); } return g_no_error; } } else { if (src->fmt == UHDR_IMG_FMT_24bppRGB888 && dst->fmt == UHDR_IMG_FMT_32bppRGBA8888) { uint32_t* plane_dst = static_cast(dst->planes[UHDR_PLANE_PACKED]); uint8_t* plane_src = static_cast(src->planes[UHDR_PLANE_PACKED]); for (size_t i = 0; i < src->h; i++) { uint32_t* pixel_dst = plane_dst; uint8_t* pixel_src = plane_src; for (size_t j = 0; j < src->w; j++) { *pixel_dst = pixel_src[0] | (pixel_src[1] << 8) | (pixel_src[2] << 16) | (0xff << 24); pixel_src += 3; pixel_dst += 1; } plane_dst += dst->stride[UHDR_PLANE_PACKED]; plane_src += (size_t)3 * src->stride[UHDR_PLANE_PACKED]; } return g_no_error; } } uhdr_error_info_t status; status.error_code = UHDR_CODEC_UNSUPPORTED_FEATURE; status.has_detail = 1; snprintf( status.detail, sizeof status.detail, "unsupported source / destinations color formats in copy_raw_image, src fmt %d, dst fmt %d", src->fmt, dst->fmt); return status; } // Use double type for intermediate results for better precision. static bool floatToUnsignedFractionImpl(float v, uint32_t maxNumerator, uint32_t* numerator, uint32_t* denominator) { if (std::isnan(v) || v < 0 || v > maxNumerator) { return false; } // Maximum denominator: makes sure that the numerator is <= maxNumerator and the denominator // is <= UINT32_MAX. const uint64_t maxD = (v <= 1) ? UINT32_MAX : (uint64_t)floor(maxNumerator / v); // Find the best approximation of v as a fraction using continued fractions, see // https://en.wikipedia.org/wiki/Continued_fraction *denominator = 1; uint32_t previousD = 0; double currentV = (double)v - floor(v); int iter = 0; // Set a maximum number of iterations to be safe. Most numbers should // converge in less than ~20 iterations. // The golden ratio is the worst case and takes 39 iterations. const int maxIter = 39; while (iter < maxIter) { const double numeratorDouble = (double)(*denominator) * v; if (numeratorDouble > maxNumerator) { return false; } *numerator = (uint32_t)round(numeratorDouble); if (fabs(numeratorDouble - (*numerator)) == 0.0) { return true; } currentV = 1.0 / currentV; const double newD = previousD + floor(currentV) * (*denominator); if (newD > maxD) { // This is the best we can do with a denominator <= max_d. return true; } previousD = *denominator; if (newD > (double)UINT32_MAX) { return false; } *denominator = (uint32_t)newD; currentV -= floor(currentV); ++iter; } // Maximum number of iterations reached, return what we've found. // For max_iter >= 39 we shouldn't get here. max_iter can be set // to a lower value to speed up the algorithm if needed. *numerator = (uint32_t)round((double)(*denominator) * v); return true; } bool floatToSignedFraction(float v, int32_t* numerator, uint32_t* denominator) { uint32_t positive_numerator; if (!floatToUnsignedFractionImpl(fabs(v), INT32_MAX, &positive_numerator, denominator)) { return false; } *numerator = (int32_t)positive_numerator; if (v < 0) { *numerator *= -1; } return true; } bool floatToUnsignedFraction(float v, uint32_t* numerator, uint32_t* denominator) { return floatToUnsignedFractionImpl(v, UINT32_MAX, numerator, denominator); } } // namespace ultrahdr