src/media/base/simd/convert_yuv_to_rgb_c.cc - cobalt - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "media/base/simd/convert_yuv_to_rgb.h"
 #include "media/base/simd/yuv_to_rgb_table.h"

 #define packuswb(x) ((x) < 0 ? 0 : ((x) > 255 ? 255 : (x)))
 #define paddsw(x, y) (((x) + (y)) < -32768 ? -32768 : \
     (((x) + (y)) > 32767 ? 32767 : ((x) + (y))))

 static inline void ConvertYUVToRGB32_C(uint8 y,
                                        uint8 u,
                                        uint8 v,
                                        uint8* rgb_buf) {
   int b = kCoefficientsRgbY[256+u][0];
   int g = kCoefficientsRgbY[256+u][1];
   int r = kCoefficientsRgbY[256+u][2];
   int a = kCoefficientsRgbY[256+u][3];

   b = paddsw(b, kCoefficientsRgbY[512+v][0]);
   g = paddsw(g, kCoefficientsRgbY[512+v][1]);
   r = paddsw(r, kCoefficientsRgbY[512+v][2]);
   a = paddsw(a, kCoefficientsRgbY[512+v][3]);

   b = paddsw(b, kCoefficientsRgbY[y][0]);
   g = paddsw(g, kCoefficientsRgbY[y][1]);
   r = paddsw(r, kCoefficientsRgbY[y][2]);
   a = paddsw(a, kCoefficientsRgbY[y][3]);

   b >>= 6;
   g >>= 6;
   r >>= 6;
   a >>= 6;

   *reinterpret_cast<uint32*>(rgb_buf) = (packuswb(b)) |
                                         (packuswb(g) << 8) |
                                         (packuswb(r) << 16) |
                                         (packuswb(a) << 24);
 }

 extern "C" {

 void ConvertYUVToRGB32Row_C(const uint8* y_buf,
                             const uint8* u_buf,
                             const uint8* v_buf,
                             uint8* rgb_buf,
                             int width) {
   for (int x = 0; x < width; x += 2) {
     uint8 u = u_buf[x >> 1];
     uint8 v = v_buf[x >> 1];
     uint8 y0 = y_buf[x];
     ConvertYUVToRGB32_C(y0, u, v, rgb_buf);
     if ((x + 1) < width) {
       uint8 y1 = y_buf[x + 1];
       ConvertYUVToRGB32_C(y1, u, v, rgb_buf + 4);
     }
     rgb_buf += 8;  // Advance 2 pixels.
   }
 }

 // 16.16 fixed point is used.  A shift by 16 isolates the integer.
 // A shift by 17 is used to further subsample the chrominence channels.
 // & 0xffff isolates the fixed point fraction.  >> 2 to get the upper 2 bits,
 // for 1/65536 pixel accurate interpolation.
 void ScaleYUVToRGB32Row_C(const uint8* y_buf,
                           const uint8* u_buf,
                           const uint8* v_buf,
                           uint8* rgb_buf,
                           int width,
                           int source_dx) {
   int x = 0;
   for (int i = 0; i < width; i += 2) {
     int y = y_buf[x >> 16];
     int u = u_buf[(x >> 17)];
     int v = v_buf[(x >> 17)];
     ConvertYUVToRGB32_C(y, u, v, rgb_buf);
     x += source_dx;
     if ((i + 1) < width) {
       y = y_buf[x >> 16];
       ConvertYUVToRGB32_C(y, u, v, rgb_buf+4);
       x += source_dx;
     }
     rgb_buf += 8;
   }
 }

 void LinearScaleYUVToRGB32Row_C(const uint8* y_buf,
                                 const uint8* u_buf,
                                 const uint8* v_buf,
                                 uint8* rgb_buf,
                                 int width,
                                 int source_dx) {
   // Avoid point-sampling for down-scaling by > 2:1.
   int source_x = 0;
   if (source_dx >= 0x20000)
     source_x += 0x8000;
   LinearScaleYUVToRGB32RowWithRange_C(y_buf, u_buf, v_buf, rgb_buf, width,
                                       source_x, source_dx);
 }

 void LinearScaleYUVToRGB32RowWithRange_C(const uint8* y_buf,
                                          const uint8* u_buf,
                                          const uint8* v_buf,
                                          uint8* rgb_buf,
                                          int dest_width,
                                          int x,
                                          int source_dx) {
   for (int i = 0; i < dest_width; i += 2) {
     int y0 = y_buf[x >> 16];
     int y1 = y_buf[(x >> 16) + 1];
     int u0 = u_buf[(x >> 17)];
     int u1 = u_buf[(x >> 17) + 1];
     int v0 = v_buf[(x >> 17)];
     int v1 = v_buf[(x >> 17) + 1];
     int y_frac = (x & 65535);
     int uv_frac = ((x >> 1) & 65535);
     int y = (y_frac * y1 + (y_frac ^ 65535) * y0) >> 16;
     int u = (uv_frac * u1 + (uv_frac ^ 65535) * u0) >> 16;
     int v = (uv_frac * v1 + (uv_frac ^ 65535) * v0) >> 16;
     ConvertYUVToRGB32_C(y, u, v, rgb_buf);
     x += source_dx;
     if ((i + 1) < dest_width) {
       y0 = y_buf[x >> 16];
       y1 = y_buf[(x >> 16) + 1];
       y_frac = (x & 65535);
       y = (y_frac * y1 + (y_frac ^ 65535) * y0) >> 16;
       ConvertYUVToRGB32_C(y, u, v, rgb_buf+4);
       x += source_dx;
     }
     rgb_buf += 8;
   }
 }

 }

 namespace media {

 void ConvertYUVToRGB32_C(const uint8* yplane,
                          const uint8* uplane,
                          const uint8* vplane,
                          uint8* rgbframe,
                          int width,
                          int height,
                          int ystride,
                          int uvstride,
                          int rgbstride,
                          YUVType yuv_type) {
   unsigned int y_shift = yuv_type;
   for (int y = 0; y < height; ++y) {
     uint8* rgb_row = rgbframe + y * rgbstride;
     const uint8* y_ptr = yplane + y * ystride;
     const uint8* u_ptr = uplane + (y >> y_shift) * uvstride;
     const uint8* v_ptr = vplane + (y >> y_shift) * uvstride;

     ConvertYUVToRGB32Row_C(y_ptr,
                            u_ptr,
                            v_ptr,
                            rgb_row,
                            width);
   }
 }

 }  // namespace media
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "media/base/simd/convert_yuv_to_rgb.h"
	#include "media/base/simd/yuv_to_rgb_table.h"

	#define packuswb(x) ((x) < 0 ? 0 : ((x) > 255 ? 255 : (x)))
	#define paddsw(x, y) (((x) + (y)) < -32768 ? -32768 : \
	(((x) + (y)) > 32767 ? 32767 : ((x) + (y))))

	static inline void ConvertYUVToRGB32_C(uint8 y,
	uint8 u,
	uint8 v,
	uint8* rgb_buf) {
	int b = kCoefficientsRgbY[256+u][0];
	int g = kCoefficientsRgbY[256+u][1];
	int r = kCoefficientsRgbY[256+u][2];
	int a = kCoefficientsRgbY[256+u][3];

	b = paddsw(b, kCoefficientsRgbY[512+v][0]);
	g = paddsw(g, kCoefficientsRgbY[512+v][1]);
	r = paddsw(r, kCoefficientsRgbY[512+v][2]);
	a = paddsw(a, kCoefficientsRgbY[512+v][3]);

	b = paddsw(b, kCoefficientsRgbY[y][0]);
	g = paddsw(g, kCoefficientsRgbY[y][1]);
	r = paddsw(r, kCoefficientsRgbY[y][2]);
	a = paddsw(a, kCoefficientsRgbY[y][3]);

	b >>= 6;
	g >>= 6;
	r >>= 6;
	a >>= 6;

	reinterpret_cast<uint32>(rgb_buf) = (packuswb(b)) \|
	(packuswb(g) << 8) \|
	(packuswb(r) << 16) \|
	(packuswb(a) << 24);
	}

	extern "C" {

	void ConvertYUVToRGB32Row_C(const uint8* y_buf,
	const uint8* u_buf,
	const uint8* v_buf,
	uint8* rgb_buf,
	int width) {
	for (int x = 0; x < width; x += 2) {
	uint8 u = u_buf[x >> 1];
	uint8 v = v_buf[x >> 1];
	uint8 y0 = y_buf[x];
	ConvertYUVToRGB32_C(y0, u, v, rgb_buf);
	if ((x + 1) < width) {
	uint8 y1 = y_buf[x + 1];
	ConvertYUVToRGB32_C(y1, u, v, rgb_buf + 4);
	}
	rgb_buf += 8; // Advance 2 pixels.
	}
	}

	// 16.16 fixed point is used. A shift by 16 isolates the integer.
	// A shift by 17 is used to further subsample the chrominence channels.
	// & 0xffff isolates the fixed point fraction. >> 2 to get the upper 2 bits,
	// for 1/65536 pixel accurate interpolation.
	void ScaleYUVToRGB32Row_C(const uint8* y_buf,
	const uint8* u_buf,
	const uint8* v_buf,
	uint8* rgb_buf,
	int width,
	int source_dx) {
	int x = 0;
	for (int i = 0; i < width; i += 2) {
	int y = y_buf[x >> 16];
	int u = u_buf[(x >> 17)];
	int v = v_buf[(x >> 17)];
	ConvertYUVToRGB32_C(y, u, v, rgb_buf);
	x += source_dx;
	if ((i + 1) < width) {
	y = y_buf[x >> 16];
	ConvertYUVToRGB32_C(y, u, v, rgb_buf+4);
	x += source_dx;
	}
	rgb_buf += 8;
	}
	}

	void LinearScaleYUVToRGB32Row_C(const uint8* y_buf,
	const uint8* u_buf,
	const uint8* v_buf,
	uint8* rgb_buf,
	int width,
	int source_dx) {
	// Avoid point-sampling for down-scaling by > 2:1.
	int source_x = 0;
	if (source_dx >= 0x20000)
	source_x += 0x8000;
	LinearScaleYUVToRGB32RowWithRange_C(y_buf, u_buf, v_buf, rgb_buf, width,
	source_x, source_dx);
	}

	void LinearScaleYUVToRGB32RowWithRange_C(const uint8* y_buf,
	const uint8* u_buf,
	const uint8* v_buf,
	uint8* rgb_buf,
	int dest_width,
	int x,
	int source_dx) {
	for (int i = 0; i < dest_width; i += 2) {
	int y0 = y_buf[x >> 16];
	int y1 = y_buf[(x >> 16) + 1];
	int u0 = u_buf[(x >> 17)];
	int u1 = u_buf[(x >> 17) + 1];
	int v0 = v_buf[(x >> 17)];
	int v1 = v_buf[(x >> 17) + 1];
	int y_frac = (x & 65535);
	int uv_frac = ((x >> 1) & 65535);
	int y = (y_frac * y1 + (y_frac ^ 65535) * y0) >> 16;
	int u = (uv_frac * u1 + (uv_frac ^ 65535) * u0) >> 16;
	int v = (uv_frac * v1 + (uv_frac ^ 65535) * v0) >> 16;
	ConvertYUVToRGB32_C(y, u, v, rgb_buf);
	x += source_dx;
	if ((i + 1) < dest_width) {
	y0 = y_buf[x >> 16];
	y1 = y_buf[(x >> 16) + 1];
	y_frac = (x & 65535);
	y = (y_frac * y1 + (y_frac ^ 65535) * y0) >> 16;
	ConvertYUVToRGB32_C(y, u, v, rgb_buf+4);
	x += source_dx;
	}
	rgb_buf += 8;
	}
	}

	}

	namespace media {

	void ConvertYUVToRGB32_C(const uint8* yplane,
	const uint8* uplane,
	const uint8* vplane,
	uint8* rgbframe,
	int width,
	int height,
	int ystride,
	int uvstride,
	int rgbstride,
	YUVType yuv_type) {
	unsigned int y_shift = yuv_type;
	for (int y = 0; y < height; ++y) {
	uint8* rgb_row = rgbframe + y * rgbstride;
	const uint8* y_ptr = yplane + y * ystride;
	const uint8* u_ptr = uplane + (y >> y_shift) * uvstride;
	const uint8* v_ptr = vplane + (y >> y_shift) * uvstride;

	ConvertYUVToRGB32Row_C(y_ptr,
	u_ptr,
	v_ptr,
	rgb_row,
	width);
	}
	}

	} // namespace media