526 lines
19 KiB
C
526 lines
19 KiB
C
// Copyright 2022 Google Inc. All Rights Reserved.
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//
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// Use of this source code is governed by a BSD-style license
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// that can be found in the COPYING file in the root of the source
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// tree. An additional intellectual property rights grant can be found
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// in the file PATENTS. All contributing project authors may
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// be found in the AUTHORS file in the root of the source tree.
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// -----------------------------------------------------------------------------
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//
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// Sharp RGB to YUV conversion.
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//
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// Author: Skal (pascal.massimino@gmail.com)
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#include "sharpyuv/sharpyuv.h"
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#include <assert.h>
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#include <limits.h>
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#include <stddef.h>
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#include <stdlib.h>
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#include <string.h>
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#include "src/webp/types.h"
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#include "sharpyuv/sharpyuv_cpu.h"
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#include "sharpyuv/sharpyuv_dsp.h"
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#include "sharpyuv/sharpyuv_gamma.h"
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//------------------------------------------------------------------------------
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int SharpYuvGetVersion(void) {
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return SHARPYUV_VERSION;
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}
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//------------------------------------------------------------------------------
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// Sharp RGB->YUV conversion
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static const int kNumIterations = 4;
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#define YUV_FIX 16 // fixed-point precision for RGB->YUV
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static const int kYuvHalf = 1 << (YUV_FIX - 1);
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// Max bit depth so that intermediate calculations fit in 16 bits.
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static const int kMaxBitDepth = 14;
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// Returns the precision shift to use based on the input rgb_bit_depth.
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static int GetPrecisionShift(int rgb_bit_depth) {
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// Try to add 2 bits of precision if it fits in kMaxBitDepth. Otherwise remove
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// bits if needed.
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return ((rgb_bit_depth + 2) <= kMaxBitDepth) ? 2
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: (kMaxBitDepth - rgb_bit_depth);
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}
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typedef int16_t fixed_t; // signed type with extra precision for UV
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typedef uint16_t fixed_y_t; // unsigned type with extra precision for W
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//------------------------------------------------------------------------------
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static uint8_t clip_8b(fixed_t v) {
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return (!(v & ~0xff)) ? (uint8_t)v : (v < 0) ? 0u : 255u;
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}
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static uint16_t clip(fixed_t v, int max) {
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return (v < 0) ? 0 : (v > max) ? max : (uint16_t)v;
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}
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static fixed_y_t clip_bit_depth(int y, int bit_depth) {
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const int max = (1 << bit_depth) - 1;
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return (!(y & ~max)) ? (fixed_y_t)y : (y < 0) ? 0 : max;
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}
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//------------------------------------------------------------------------------
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static int RGBToGray(int64_t r, int64_t g, int64_t b) {
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const int64_t luma = 13933 * r + 46871 * g + 4732 * b + kYuvHalf;
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return (int)(luma >> YUV_FIX);
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}
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static uint32_t ScaleDown(uint16_t a, uint16_t b, uint16_t c, uint16_t d,
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int rgb_bit_depth) {
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const int bit_depth = rgb_bit_depth + GetPrecisionShift(rgb_bit_depth);
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const uint32_t A = SharpYuvGammaToLinear(a, bit_depth);
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const uint32_t B = SharpYuvGammaToLinear(b, bit_depth);
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const uint32_t C = SharpYuvGammaToLinear(c, bit_depth);
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const uint32_t D = SharpYuvGammaToLinear(d, bit_depth);
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return SharpYuvLinearToGamma((A + B + C + D + 2) >> 2, bit_depth);
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}
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static WEBP_INLINE void UpdateW(const fixed_y_t* src, fixed_y_t* dst, int w,
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int rgb_bit_depth) {
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const int bit_depth = rgb_bit_depth + GetPrecisionShift(rgb_bit_depth);
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int i;
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for (i = 0; i < w; ++i) {
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const uint32_t R = SharpYuvGammaToLinear(src[0 * w + i], bit_depth);
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const uint32_t G = SharpYuvGammaToLinear(src[1 * w + i], bit_depth);
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const uint32_t B = SharpYuvGammaToLinear(src[2 * w + i], bit_depth);
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const uint32_t Y = RGBToGray(R, G, B);
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dst[i] = (fixed_y_t)SharpYuvLinearToGamma(Y, bit_depth);
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}
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}
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static void UpdateChroma(const fixed_y_t* src1, const fixed_y_t* src2,
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fixed_t* dst, int uv_w, int rgb_bit_depth) {
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int i;
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for (i = 0; i < uv_w; ++i) {
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const int r =
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ScaleDown(src1[0 * uv_w + 0], src1[0 * uv_w + 1], src2[0 * uv_w + 0],
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src2[0 * uv_w + 1], rgb_bit_depth);
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const int g =
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ScaleDown(src1[2 * uv_w + 0], src1[2 * uv_w + 1], src2[2 * uv_w + 0],
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src2[2 * uv_w + 1], rgb_bit_depth);
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const int b =
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ScaleDown(src1[4 * uv_w + 0], src1[4 * uv_w + 1], src2[4 * uv_w + 0],
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src2[4 * uv_w + 1], rgb_bit_depth);
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const int W = RGBToGray(r, g, b);
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dst[0 * uv_w] = (fixed_t)(r - W);
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dst[1 * uv_w] = (fixed_t)(g - W);
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dst[2 * uv_w] = (fixed_t)(b - W);
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dst += 1;
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src1 += 2;
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src2 += 2;
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}
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}
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static void StoreGray(const fixed_y_t* rgb, fixed_y_t* y, int w) {
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int i;
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assert(w > 0);
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for (i = 0; i < w; ++i) {
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y[i] = RGBToGray(rgb[0 * w + i], rgb[1 * w + i], rgb[2 * w + i]);
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}
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}
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//------------------------------------------------------------------------------
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static WEBP_INLINE fixed_y_t Filter2(int A, int B, int W0, int bit_depth) {
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const int v0 = (A * 3 + B + 2) >> 2;
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return clip_bit_depth(v0 + W0, bit_depth);
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}
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//------------------------------------------------------------------------------
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static WEBP_INLINE int Shift(int v, int shift) {
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return (shift >= 0) ? (v << shift) : (v >> -shift);
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}
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static void ImportOneRow(const uint8_t* const r_ptr,
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const uint8_t* const g_ptr,
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const uint8_t* const b_ptr,
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int rgb_step,
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int rgb_bit_depth,
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int pic_width,
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fixed_y_t* const dst) {
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// Convert the rgb_step from a number of bytes to a number of uint8_t or
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// uint16_t values depending the bit depth.
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const int step = (rgb_bit_depth > 8) ? rgb_step / 2 : rgb_step;
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int i;
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const int w = (pic_width + 1) & ~1;
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for (i = 0; i < pic_width; ++i) {
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const int off = i * step;
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const int shift = GetPrecisionShift(rgb_bit_depth);
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if (rgb_bit_depth == 8) {
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dst[i + 0 * w] = Shift(r_ptr[off], shift);
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dst[i + 1 * w] = Shift(g_ptr[off], shift);
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dst[i + 2 * w] = Shift(b_ptr[off], shift);
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} else {
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dst[i + 0 * w] = Shift(((uint16_t*)r_ptr)[off], shift);
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dst[i + 1 * w] = Shift(((uint16_t*)g_ptr)[off], shift);
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dst[i + 2 * w] = Shift(((uint16_t*)b_ptr)[off], shift);
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}
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}
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if (pic_width & 1) { // replicate rightmost pixel
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dst[pic_width + 0 * w] = dst[pic_width + 0 * w - 1];
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dst[pic_width + 1 * w] = dst[pic_width + 1 * w - 1];
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dst[pic_width + 2 * w] = dst[pic_width + 2 * w - 1];
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}
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}
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static void InterpolateTwoRows(const fixed_y_t* const best_y,
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const fixed_t* prev_uv,
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const fixed_t* cur_uv,
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const fixed_t* next_uv,
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int w,
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fixed_y_t* out1,
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fixed_y_t* out2,
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int rgb_bit_depth) {
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const int uv_w = w >> 1;
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const int len = (w - 1) >> 1; // length to filter
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int k = 3;
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const int bit_depth = rgb_bit_depth + GetPrecisionShift(rgb_bit_depth);
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while (k-- > 0) { // process each R/G/B segments in turn
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// special boundary case for i==0
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out1[0] = Filter2(cur_uv[0], prev_uv[0], best_y[0], bit_depth);
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out2[0] = Filter2(cur_uv[0], next_uv[0], best_y[w], bit_depth);
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SharpYuvFilterRow(cur_uv, prev_uv, len, best_y + 0 + 1, out1 + 1,
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bit_depth);
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SharpYuvFilterRow(cur_uv, next_uv, len, best_y + w + 1, out2 + 1,
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bit_depth);
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// special boundary case for i == w - 1 when w is even
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if (!(w & 1)) {
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out1[w - 1] = Filter2(cur_uv[uv_w - 1], prev_uv[uv_w - 1],
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best_y[w - 1 + 0], bit_depth);
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out2[w - 1] = Filter2(cur_uv[uv_w - 1], next_uv[uv_w - 1],
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best_y[w - 1 + w], bit_depth);
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}
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out1 += w;
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out2 += w;
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prev_uv += uv_w;
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cur_uv += uv_w;
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next_uv += uv_w;
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}
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}
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static WEBP_INLINE int RGBToYUVComponent(int r, int g, int b,
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const int coeffs[4], int sfix) {
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const int srounder = 1 << (YUV_FIX + sfix - 1);
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const int luma = coeffs[0] * r + coeffs[1] * g + coeffs[2] * b +
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coeffs[3] + srounder;
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return (luma >> (YUV_FIX + sfix));
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}
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static int ConvertWRGBToYUV(const fixed_y_t* best_y, const fixed_t* best_uv,
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uint8_t* y_ptr, int y_stride, uint8_t* u_ptr,
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int u_stride, uint8_t* v_ptr, int v_stride,
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int rgb_bit_depth,
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int yuv_bit_depth, int width, int height,
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const SharpYuvConversionMatrix* yuv_matrix) {
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int i, j;
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const fixed_t* const best_uv_base = best_uv;
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const int w = (width + 1) & ~1;
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const int h = (height + 1) & ~1;
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const int uv_w = w >> 1;
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const int uv_h = h >> 1;
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const int sfix = GetPrecisionShift(rgb_bit_depth);
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const int yuv_max = (1 << yuv_bit_depth) - 1;
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for (best_uv = best_uv_base, j = 0; j < height; ++j) {
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for (i = 0; i < width; ++i) {
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const int off = (i >> 1);
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const int W = best_y[i];
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const int r = best_uv[off + 0 * uv_w] + W;
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const int g = best_uv[off + 1 * uv_w] + W;
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const int b = best_uv[off + 2 * uv_w] + W;
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const int y = RGBToYUVComponent(r, g, b, yuv_matrix->rgb_to_y, sfix);
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if (yuv_bit_depth <= 8) {
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y_ptr[i] = clip_8b(y);
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} else {
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((uint16_t*)y_ptr)[i] = clip(y, yuv_max);
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}
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}
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best_y += w;
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best_uv += (j & 1) * 3 * uv_w;
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y_ptr += y_stride;
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}
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for (best_uv = best_uv_base, j = 0; j < uv_h; ++j) {
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for (i = 0; i < uv_w; ++i) {
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const int off = i;
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// Note r, g and b values here are off by W, but a constant offset on all
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// 3 components doesn't change the value of u and v with a YCbCr matrix.
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const int r = best_uv[off + 0 * uv_w];
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const int g = best_uv[off + 1 * uv_w];
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const int b = best_uv[off + 2 * uv_w];
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const int u = RGBToYUVComponent(r, g, b, yuv_matrix->rgb_to_u, sfix);
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const int v = RGBToYUVComponent(r, g, b, yuv_matrix->rgb_to_v, sfix);
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if (yuv_bit_depth <= 8) {
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u_ptr[i] = clip_8b(u);
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v_ptr[i] = clip_8b(v);
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} else {
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((uint16_t*)u_ptr)[i] = clip(u, yuv_max);
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((uint16_t*)v_ptr)[i] = clip(v, yuv_max);
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}
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}
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best_uv += 3 * uv_w;
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u_ptr += u_stride;
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v_ptr += v_stride;
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}
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return 1;
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}
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//------------------------------------------------------------------------------
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// Main function
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static void* SafeMalloc(uint64_t nmemb, size_t size) {
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const uint64_t total_size = nmemb * (uint64_t)size;
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if (total_size != (size_t)total_size) return NULL;
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return malloc((size_t)total_size);
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}
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#define SAFE_ALLOC(W, H, T) ((T*)SafeMalloc((W) * (H), sizeof(T)))
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static int DoSharpArgbToYuv(const uint8_t* r_ptr, const uint8_t* g_ptr,
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const uint8_t* b_ptr, int rgb_step, int rgb_stride,
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int rgb_bit_depth, uint8_t* y_ptr, int y_stride,
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uint8_t* u_ptr, int u_stride, uint8_t* v_ptr,
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int v_stride, int yuv_bit_depth, int width,
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int height,
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const SharpYuvConversionMatrix* yuv_matrix) {
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// we expand the right/bottom border if needed
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const int w = (width + 1) & ~1;
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const int h = (height + 1) & ~1;
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const int uv_w = w >> 1;
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const int uv_h = h >> 1;
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uint64_t prev_diff_y_sum = ~0;
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int j, iter;
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// TODO(skal): allocate one big memory chunk. But for now, it's easier
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// for valgrind debugging to have several chunks.
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fixed_y_t* const tmp_buffer = SAFE_ALLOC(w * 3, 2, fixed_y_t); // scratch
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fixed_y_t* const best_y_base = SAFE_ALLOC(w, h, fixed_y_t);
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fixed_y_t* const target_y_base = SAFE_ALLOC(w, h, fixed_y_t);
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fixed_y_t* const best_rgb_y = SAFE_ALLOC(w, 2, fixed_y_t);
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fixed_t* const best_uv_base = SAFE_ALLOC(uv_w * 3, uv_h, fixed_t);
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fixed_t* const target_uv_base = SAFE_ALLOC(uv_w * 3, uv_h, fixed_t);
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fixed_t* const best_rgb_uv = SAFE_ALLOC(uv_w * 3, 1, fixed_t);
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fixed_y_t* best_y = best_y_base;
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fixed_y_t* target_y = target_y_base;
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fixed_t* best_uv = best_uv_base;
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fixed_t* target_uv = target_uv_base;
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const uint64_t diff_y_threshold = (uint64_t)(3.0 * w * h);
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int ok;
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assert(w > 0);
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assert(h > 0);
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if (best_y_base == NULL || best_uv_base == NULL ||
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target_y_base == NULL || target_uv_base == NULL ||
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best_rgb_y == NULL || best_rgb_uv == NULL ||
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tmp_buffer == NULL) {
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ok = 0;
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goto End;
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}
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// Import RGB samples to W/RGB representation.
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for (j = 0; j < height; j += 2) {
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const int is_last_row = (j == height - 1);
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fixed_y_t* const src1 = tmp_buffer + 0 * w;
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fixed_y_t* const src2 = tmp_buffer + 3 * w;
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// prepare two rows of input
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ImportOneRow(r_ptr, g_ptr, b_ptr, rgb_step, rgb_bit_depth, width,
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src1);
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if (!is_last_row) {
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ImportOneRow(r_ptr + rgb_stride, g_ptr + rgb_stride, b_ptr + rgb_stride,
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rgb_step, rgb_bit_depth, width, src2);
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} else {
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memcpy(src2, src1, 3 * w * sizeof(*src2));
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}
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StoreGray(src1, best_y + 0, w);
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StoreGray(src2, best_y + w, w);
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UpdateW(src1, target_y, w, rgb_bit_depth);
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UpdateW(src2, target_y + w, w, rgb_bit_depth);
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UpdateChroma(src1, src2, target_uv, uv_w, rgb_bit_depth);
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memcpy(best_uv, target_uv, 3 * uv_w * sizeof(*best_uv));
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best_y += 2 * w;
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best_uv += 3 * uv_w;
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target_y += 2 * w;
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target_uv += 3 * uv_w;
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r_ptr += 2 * rgb_stride;
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g_ptr += 2 * rgb_stride;
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b_ptr += 2 * rgb_stride;
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}
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// Iterate and resolve clipping conflicts.
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for (iter = 0; iter < kNumIterations; ++iter) {
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const fixed_t* cur_uv = best_uv_base;
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const fixed_t* prev_uv = best_uv_base;
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uint64_t diff_y_sum = 0;
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best_y = best_y_base;
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best_uv = best_uv_base;
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target_y = target_y_base;
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target_uv = target_uv_base;
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for (j = 0; j < h; j += 2) {
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fixed_y_t* const src1 = tmp_buffer + 0 * w;
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fixed_y_t* const src2 = tmp_buffer + 3 * w;
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{
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const fixed_t* const next_uv = cur_uv + ((j < h - 2) ? 3 * uv_w : 0);
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InterpolateTwoRows(best_y, prev_uv, cur_uv, next_uv, w,
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src1, src2, rgb_bit_depth);
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prev_uv = cur_uv;
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cur_uv = next_uv;
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}
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UpdateW(src1, best_rgb_y + 0 * w, w, rgb_bit_depth);
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UpdateW(src2, best_rgb_y + 1 * w, w, rgb_bit_depth);
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UpdateChroma(src1, src2, best_rgb_uv, uv_w, rgb_bit_depth);
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// update two rows of Y and one row of RGB
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diff_y_sum +=
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SharpYuvUpdateY(target_y, best_rgb_y, best_y, 2 * w,
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rgb_bit_depth + GetPrecisionShift(rgb_bit_depth));
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SharpYuvUpdateRGB(target_uv, best_rgb_uv, best_uv, 3 * uv_w);
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best_y += 2 * w;
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best_uv += 3 * uv_w;
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target_y += 2 * w;
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target_uv += 3 * uv_w;
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}
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// test exit condition
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if (iter > 0) {
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if (diff_y_sum < diff_y_threshold) break;
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if (diff_y_sum > prev_diff_y_sum) break;
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}
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prev_diff_y_sum = diff_y_sum;
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}
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// final reconstruction
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ok = ConvertWRGBToYUV(best_y_base, best_uv_base, y_ptr, y_stride, u_ptr,
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u_stride, v_ptr, v_stride, rgb_bit_depth, yuv_bit_depth,
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width, height, yuv_matrix);
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End:
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free(best_y_base);
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free(best_uv_base);
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free(target_y_base);
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free(target_uv_base);
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free(best_rgb_y);
|
|
free(best_rgb_uv);
|
|
free(tmp_buffer);
|
|
return ok;
|
|
}
|
|
#undef SAFE_ALLOC
|
|
|
|
#if defined(WEBP_USE_THREAD) && !defined(_WIN32)
|
|
#include <pthread.h> // NOLINT
|
|
|
|
#define LOCK_ACCESS \
|
|
static pthread_mutex_t sharpyuv_lock = PTHREAD_MUTEX_INITIALIZER; \
|
|
if (pthread_mutex_lock(&sharpyuv_lock)) return
|
|
#define UNLOCK_ACCESS_AND_RETURN \
|
|
do { \
|
|
(void)pthread_mutex_unlock(&sharpyuv_lock); \
|
|
return; \
|
|
} while (0)
|
|
#else // !(defined(WEBP_USE_THREAD) && !defined(_WIN32))
|
|
#define LOCK_ACCESS do {} while (0)
|
|
#define UNLOCK_ACCESS_AND_RETURN return
|
|
#endif // defined(WEBP_USE_THREAD) && !defined(_WIN32)
|
|
|
|
// Hidden exported init function.
|
|
// By default SharpYuvConvert calls it with SharpYuvGetCPUInfo. If needed,
|
|
// users can declare it as extern and call it with an alternate VP8CPUInfo
|
|
// function.
|
|
SHARPYUV_EXTERN void SharpYuvInit(VP8CPUInfo cpu_info_func);
|
|
void SharpYuvInit(VP8CPUInfo cpu_info_func) {
|
|
static volatile VP8CPUInfo sharpyuv_last_cpuinfo_used =
|
|
(VP8CPUInfo)&sharpyuv_last_cpuinfo_used;
|
|
LOCK_ACCESS;
|
|
// Only update SharpYuvGetCPUInfo when called from external code to avoid a
|
|
// race on reading the value in SharpYuvConvert().
|
|
if (cpu_info_func != (VP8CPUInfo)&SharpYuvGetCPUInfo) {
|
|
SharpYuvGetCPUInfo = cpu_info_func;
|
|
}
|
|
if (sharpyuv_last_cpuinfo_used == SharpYuvGetCPUInfo) {
|
|
UNLOCK_ACCESS_AND_RETURN;
|
|
}
|
|
|
|
SharpYuvInitDsp();
|
|
SharpYuvInitGammaTables();
|
|
|
|
sharpyuv_last_cpuinfo_used = SharpYuvGetCPUInfo;
|
|
UNLOCK_ACCESS_AND_RETURN;
|
|
}
|
|
|
|
int SharpYuvConvert(const void* r_ptr, const void* g_ptr,
|
|
const void* b_ptr, int rgb_step, int rgb_stride,
|
|
int rgb_bit_depth, void* y_ptr, int y_stride,
|
|
void* u_ptr, int u_stride, void* v_ptr,
|
|
int v_stride, int yuv_bit_depth, int width,
|
|
int height, const SharpYuvConversionMatrix* yuv_matrix) {
|
|
SharpYuvConversionMatrix scaled_matrix;
|
|
const int rgb_max = (1 << rgb_bit_depth) - 1;
|
|
const int rgb_round = 1 << (rgb_bit_depth - 1);
|
|
const int yuv_max = (1 << yuv_bit_depth) - 1;
|
|
const int sfix = GetPrecisionShift(rgb_bit_depth);
|
|
|
|
if (width < 1 || height < 1 || width == INT_MAX || height == INT_MAX ||
|
|
r_ptr == NULL || g_ptr == NULL || b_ptr == NULL || y_ptr == NULL ||
|
|
u_ptr == NULL || v_ptr == NULL) {
|
|
return 0;
|
|
}
|
|
if (rgb_bit_depth != 8 && rgb_bit_depth != 10 && rgb_bit_depth != 12 &&
|
|
rgb_bit_depth != 16) {
|
|
return 0;
|
|
}
|
|
if (yuv_bit_depth != 8 && yuv_bit_depth != 10 && yuv_bit_depth != 12) {
|
|
return 0;
|
|
}
|
|
if (rgb_bit_depth > 8 && (rgb_step % 2 != 0 || rgb_stride %2 != 0)) {
|
|
// Step/stride should be even for uint16_t buffers.
|
|
return 0;
|
|
}
|
|
if (yuv_bit_depth > 8 &&
|
|
(y_stride % 2 != 0 || u_stride % 2 != 0 || v_stride % 2 != 0)) {
|
|
// Stride should be even for uint16_t buffers.
|
|
return 0;
|
|
}
|
|
// The address of the function pointer is used to avoid a read race.
|
|
SharpYuvInit((VP8CPUInfo)&SharpYuvGetCPUInfo);
|
|
|
|
// Add scaling factor to go from rgb_bit_depth to yuv_bit_depth, to the
|
|
// rgb->yuv conversion matrix.
|
|
if (rgb_bit_depth == yuv_bit_depth) {
|
|
memcpy(&scaled_matrix, yuv_matrix, sizeof(scaled_matrix));
|
|
} else {
|
|
int i;
|
|
for (i = 0; i < 3; ++i) {
|
|
scaled_matrix.rgb_to_y[i] =
|
|
(yuv_matrix->rgb_to_y[i] * yuv_max + rgb_round) / rgb_max;
|
|
scaled_matrix.rgb_to_u[i] =
|
|
(yuv_matrix->rgb_to_u[i] * yuv_max + rgb_round) / rgb_max;
|
|
scaled_matrix.rgb_to_v[i] =
|
|
(yuv_matrix->rgb_to_v[i] * yuv_max + rgb_round) / rgb_max;
|
|
}
|
|
}
|
|
// Also incorporate precision change scaling.
|
|
scaled_matrix.rgb_to_y[3] = Shift(yuv_matrix->rgb_to_y[3], sfix);
|
|
scaled_matrix.rgb_to_u[3] = Shift(yuv_matrix->rgb_to_u[3], sfix);
|
|
scaled_matrix.rgb_to_v[3] = Shift(yuv_matrix->rgb_to_v[3], sfix);
|
|
|
|
return DoSharpArgbToYuv(r_ptr, g_ptr, b_ptr, rgb_step, rgb_stride,
|
|
rgb_bit_depth, y_ptr, y_stride, u_ptr, u_stride,
|
|
v_ptr, v_stride, yuv_bit_depth, width, height,
|
|
&scaled_matrix);
|
|
}
|
|
|
|
//------------------------------------------------------------------------------
|