camera/Converters.h - device/generic/goldfish - Git at Google

 /*
  * Copyright (C) 2011 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.
  */

 #ifndef HW_EMULATOR_CAMERA_CONVERTERS_H
 #define HW_EMULATOR_CAMERA_CONVERTERS_H

 #include <endian.h>

 #ifndef __BYTE_ORDER
 #error "could not determine byte order"
 #endif

 /*
  * Contains declaration of framebuffer conversion routines.
  *
  * NOTE: RGB and big/little endian considerations. Wherewer in this code RGB
  * pixels are represented as WORD, or DWORD, the color order inside the
  * WORD / DWORD matches the one that would occur if that WORD / DWORD would have
  * been read from the typecasted framebuffer:
  *
  *      const uint32_t rgb = *reinterpret_cast<const uint32_t*>(framebuffer);
  *
  * So, if this code runs on the little endian CPU, red color in 'rgb' would be
  * masked as 0x000000ff, and blue color would be masked as 0x00ff0000, while if
  * the code runs on a big endian CPU, the red color in 'rgb' would be masked as
  * 0xff000000, and blue color would be masked as 0x0000ff00,
  */

 namespace android {

 /*
  * RGB565 color masks
  */

 #if __BYTE_ORDER == __LITTLE_ENDIAN
 static const uint16_t kRed5     = 0x001f;
 static const uint16_t kGreen6   = 0x07e0;
 static const uint16_t kBlue5    = 0xf800;
 #else   // __BYTE_ORDER
 static const uint16_t kRed5     = 0xf800;
 static const uint16_t kGreen6   = 0x07e0;
 static const uint16_t kBlue5    = 0x001f;
 #endif  // __BYTE_ORDER
 static const uint32_t kBlack16  = 0x0000;
 static const uint32_t kWhite16  = kRed5 | kGreen6 | kBlue5;

 /*
  * RGB32 color masks
  */

 #if __BYTE_ORDER == __LITTLE_ENDIAN
 static const uint32_t kRed8     = 0x000000ff;
 static const uint32_t kGreen8   = 0x0000ff00;
 static const uint32_t kBlue8    = 0x00ff0000;
 #else   // __BYTE_ORDER
 static const uint32_t kRed8     = 0x00ff0000;
 static const uint32_t kGreen8   = 0x0000ff00;
 static const uint32_t kBlue8    = 0x000000ff;
 #endif  // __BYTE_ORDER
 static const uint32_t kBlack32  = 0x00000000;
 static const uint32_t kWhite32  = kRed8 | kGreen8 | kBlue8;

 /*
  * Extracting, and saving color bytes from / to WORD / DWORD RGB.
  */

 #if __BYTE_ORDER == __LITTLE_ENDIAN
 /* Extract red, green, and blue bytes from RGB565 word. */
 #define R16(rgb)    static_cast<uint8_t>(rgb & kRed5)
 #define G16(rgb)    static_cast<uint8_t>((rgb & kGreen6) >> 5)
 #define B16(rgb)    static_cast<uint8_t>((rgb & kBlue5) >> 11)
 /* Make 8 bits red, green, and blue, extracted from RGB565 word. */
 #define R16_32(rgb) static_cast<uint8_t>(((rgb & kRed5) << 3) | ((rgb & kRed5) >> 2))
 #define G16_32(rgb) static_cast<uint8_t>(((rgb & kGreen6) >> 3) | ((rgb & kGreen6) >> 9))
 #define B16_32(rgb) static_cast<uint8_t>(((rgb & kBlue5) >> 8) | ((rgb & kBlue5) >> 14))
 /* Extract red, green, and blue bytes from RGB32 dword. */
 #define R32(rgb)    static_cast<uint8_t>(rgb & kRed8)
 #define G32(rgb)    static_cast<uint8_t>(((rgb & kGreen8) >> 8) & 0xff)
 #define B32(rgb)    static_cast<uint8_t>(((rgb & kBlue8) >> 16) & 0xff)
 /* Build RGB565 word from red, green, and blue bytes. */
 #define RGB565(r, g, b) static_cast<uint16_t>((((static_cast<uint16_t>(b) << 6) | g) << 5) | r)
 /* Build RGB32 dword from red, green, and blue bytes. */
 #define RGB32(r, g, b) static_cast<uint32_t>((((static_cast<uint32_t>(b) << 8) | g) << 8) | r)
 #else   // __BYTE_ORDER
 /* Extract red, green, and blue bytes from RGB565 word. */
 #define R16(rgb)    static_cast<uint8_t>((rgb & kRed5) >> 11)
 #define G16(rgb)    static_cast<uint8_t>((rgb & kGreen6) >> 5)
 #define B16(rgb)    static_cast<uint8_t>(rgb & kBlue5)
 /* Make 8 bits red, green, and blue, extracted from RGB565 word. */
 #define R16_32(rgb) static_cast<uint8_t>(((rgb & kRed5) >> 8) | ((rgb & kRed5) >> 14))
 #define G16_32(rgb) static_cast<uint8_t>(((rgb & kGreen6) >> 3) | ((rgb & kGreen6) >> 9))
 #define B16_32(rgb) static_cast<uint8_t>(((rgb & kBlue5) << 3) | ((rgb & kBlue5) >> 2))
 /* Extract red, green, and blue bytes from RGB32 dword. */
 #define R32(rgb)    static_cast<uint8_t>((rgb & kRed8) >> 16)
 #define G32(rgb)    static_cast<uint8_t>((rgb & kGreen8) >> 8)
 #define B32(rgb)    static_cast<uint8_t>(rgb & kBlue8)
 /* Build RGB565 word from red, green, and blue bytes. */
 #define RGB565(r, g, b) static_cast<uint16_t>((((static_cast<uint16_t>(r) << 6) | g) << 5) | b)
 /* Build RGB32 dword from red, green, and blue bytes. */
 #define RGB32(r, g, b) static_cast<uint32_t>((((static_cast<uint32_t>(r) << 8) | g) << 8) | b)
 #endif  // __BYTE_ORDER

 /* An union that simplifies breaking 32 bit RGB into separate R, G, and B colors.
  */
 typedef union RGB32_t {
     uint32_t    color;
     struct {
 #if __BYTE_ORDER == __LITTLE_ENDIAN
         uint8_t r; uint8_t g; uint8_t b; uint8_t a;
 #else   // __BYTE_ORDER
         uint8_t a; uint8_t b; uint8_t g; uint8_t r;
 #endif  // __BYTE_ORDER
     };
 } RGB32_t;


 /* Clips a value to the unsigned 0-255 range, treating negative values as zero.
  */
 static __inline__ int
 clamp(int x)
 {
     if (x > 255) return 255;
     if (x < 0)   return 0;
     return x;
 }

 /********************************************************************************
  * Basics of RGB -> YUV conversion
  *******************************************************************************/

 /*
  * RGB -> YUV conversion macros
  */
 #define RGB2Y(r, g, b) (uint8_t)(((66 * (r) + 129 * (g) +  25 * (b) + 128) >> 8) +  16)
 #define RGB2U(r, g, b) (uint8_t)(((-38 * (r) - 74 * (g) + 112 * (b) + 128) >> 8) + 128)
 #define RGB2V(r, g, b) (uint8_t)(((112 * (r) - 94 * (g) -  18 * (b) + 128) >> 8) + 128)

 /* Converts R8 G8 B8 color to YUV. */
 static __inline__ void
 R8G8B8ToYUV(uint8_t r, uint8_t g, uint8_t b, uint8_t* y, uint8_t* u, uint8_t* v)
 {
     *y = RGB2Y((int)r, (int)g, (int)b);
     *u = RGB2U((int)r, (int)g, (int)b);
     *v = RGB2V((int)r, (int)g, (int)b);
 }

 /* Converts RGB565 color to YUV. */
 static __inline__ void
 RGB565ToYUV(uint16_t rgb, uint8_t* y, uint8_t* u, uint8_t* v)
 {
     R8G8B8ToYUV(R16_32(rgb), G16_32(rgb), B16_32(rgb), y, u, v);
 }

 /* Converts RGB32 color to YUV. */
 static __inline__ void
 RGB32ToYUV(uint32_t rgb, uint8_t* y, uint8_t* u, uint8_t* v)
 {
     RGB32_t rgb_c;
     rgb_c.color = rgb;
     R8G8B8ToYUV(rgb_c.r, rgb_c.g, rgb_c.b, y, u, v);
 }

 /********************************************************************************
  * Basics of YUV -> RGB conversion.
  * Note that due to the fact that guest uses RGB only on preview window, and the
  * RGB format that is used is RGB565, we can limit YUV -> RGB conversions to
  * RGB565 only.
  *******************************************************************************/

 /*
  * YUV -> RGB conversion macros
  */

 /* "Optimized" macros that take specialy prepared Y, U, and V values:
  *  C = Y - 16
  *  D = U - 128
  *  E = V - 128
  */
 #define YUV2RO(C, D, E) clamp((298 * (C) + 409 * (E) + 128) >> 8)
 #define YUV2GO(C, D, E) clamp((298 * (C) - 100 * (D) - 208 * (E) + 128) >> 8)
 #define YUV2BO(C, D, E) clamp((298 * (C) + 516 * (D) + 128) >> 8)

 /*
  *  Main macros that take the original Y, U, and V values
  */
 #define YUV2R(y, u, v) clamp((298 * ((y)-16) + 409 * ((v)-128) + 128) >> 8)
 #define YUV2G(y, u, v) clamp((298 * ((y)-16) - 100 * ((u)-128) - 208 * ((v)-128) + 128) >> 8)
 #define YUV2B(y, u, v) clamp((298 * ((y)-16) + 516 * ((u)-128) + 128) >> 8)


 /* Converts YUV color to RGB565. */
 static __inline__ uint16_t
 YUVToRGB565(int y, int u, int v)
 {
     /* Calculate C, D, and E values for the optimized macro. */
     y -= 16; u -= 128; v -= 128;
     const uint16_t r = (YUV2RO(y,u,v) >> 3) & 0x1f;
     const uint16_t g = (YUV2GO(y,u,v) >> 2) & 0x3f;
     const uint16_t b = (YUV2BO(y,u,v) >> 3) & 0x1f;
     return RGB565(r, g, b);
 }

 /* Converts YUV color to RGB32. */
 static __inline__ uint32_t
 YUVToRGB32(int y, int u, int v)
 {
     /* Calculate C, D, and E values for the optimized macro. */
     y -= 16; u -= 128; v -= 128;
     RGB32_t rgb;
     rgb.r = YUV2RO(y,u,v) & 0xff;
     rgb.g = YUV2GO(y,u,v) & 0xff;
     rgb.b = YUV2BO(y,u,v) & 0xff;
     return rgb.color;
 }

 /* YUV pixel descriptor. */
 struct YUVPixel {
     uint8_t     Y;
     uint8_t     U;
     uint8_t     V;

     inline YUVPixel()
         : Y(0), U(0), V(0)
     {
     }

     inline explicit YUVPixel(uint16_t rgb565)
     {
         RGB565ToYUV(rgb565, &Y, &U, &V);
     }

     inline explicit YUVPixel(uint32_t rgb32)
     {
         RGB32ToYUV(rgb32, &Y, &U, &V);
     }

     inline void get(uint8_t* pY, uint8_t* pU, uint8_t* pV) const
     {
         *pY = Y; *pU = U; *pV = V;
     }
 };

 /* Converts an YV12 framebuffer to RGB565 framebuffer.
  * Param:
  *  yv12 - YV12 framebuffer.
  *  rgb - RGB565 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void YV12ToRGB565(const void* yv12, void* rgb, int width, int height);

 /* Converts an YV12 framebuffer to RGB32 framebuffer.
  * Param:
  *  yv12 - YV12 framebuffer.
  *  rgb - RGB32 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void YV12ToRGB32(const void* yv12, void* rgb, int width, int height);

 /* Converts an YU12 framebuffer to RGB32 framebuffer.
  * Param:
  *  yu12 - YU12 framebuffer.
  *  rgb - RGB32 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void YU12ToRGB32(const void* yu12, void* rgb, int width, int height);

 /* Converts an NV12 framebuffer to RGB565 framebuffer.
  * Param:
  *  nv12 - NV12 framebuffer.
  *  rgb - RGB565 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void NV12ToRGB565(const void* nv12, void* rgb, int width, int height);

 /* Converts an NV12 framebuffer to RGB32 framebuffer.
  * Param:
  *  nv12 - NV12 framebuffer.
  *  rgb - RGB32 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void NV12ToRGB32(const void* nv12, void* rgb, int width, int height);

 /* Converts an NV21 framebuffer to RGB565 framebuffer.
  * Param:
  *  nv21 - NV21 framebuffer.
  *  rgb - RGB565 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void NV21ToRGB565(const void* nv21, void* rgb, int width, int height);

 /* Converts an NV21 framebuffer to RGB32 framebuffer.
  * Param:
  *  nv21 - NV21 framebuffer.
  *  rgb - RGB32 framebuffer.
  *  width, height - Dimensions for both framebuffers.
  */
 void NV21ToRGB32(const void* nv21, void* rgb, int width, int height);

 }; /* namespace android */

 #endif  /* HW_EMULATOR_CAMERA_CONVERTERS_H */
	/*
	* Copyright (C) 2011 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.
	*/

	#ifndef HW_EMULATOR_CAMERA_CONVERTERS_H
	#define HW_EMULATOR_CAMERA_CONVERTERS_H

	#include <endian.h>

	#ifndef __BYTE_ORDER
	#error "could not determine byte order"
	#endif

	/*
	* Contains declaration of framebuffer conversion routines.
	*
	* NOTE: RGB and big/little endian considerations. Wherewer in this code RGB
	* pixels are represented as WORD, or DWORD, the color order inside the
	* WORD / DWORD matches the one that would occur if that WORD / DWORD would have
	* been read from the typecasted framebuffer:
	*
	* const uint32_t rgb = reinterpret_cast<const uint32_t>(framebuffer);
	*
	* So, if this code runs on the little endian CPU, red color in 'rgb' would be
	* masked as 0x000000ff, and blue color would be masked as 0x00ff0000, while if
	* the code runs on a big endian CPU, the red color in 'rgb' would be masked as
	* 0xff000000, and blue color would be masked as 0x0000ff00,
	*/

	namespace android {

	/*
	* RGB565 color masks
	*/

	#if __BYTE_ORDER == __LITTLE_ENDIAN
	static const uint16_t kRed5 = 0x001f;
	static const uint16_t kGreen6 = 0x07e0;
	static const uint16_t kBlue5 = 0xf800;
	#else // __BYTE_ORDER
	static const uint16_t kRed5 = 0xf800;
	static const uint16_t kGreen6 = 0x07e0;
	static const uint16_t kBlue5 = 0x001f;
	#endif // __BYTE_ORDER
	static const uint32_t kBlack16 = 0x0000;
	static const uint32_t kWhite16 = kRed5 \| kGreen6 \| kBlue5;

	/*
	* RGB32 color masks
	*/

	#if __BYTE_ORDER == __LITTLE_ENDIAN
	static const uint32_t kRed8 = 0x000000ff;
	static const uint32_t kGreen8 = 0x0000ff00;
	static const uint32_t kBlue8 = 0x00ff0000;
	#else // __BYTE_ORDER
	static const uint32_t kRed8 = 0x00ff0000;
	static const uint32_t kGreen8 = 0x0000ff00;
	static const uint32_t kBlue8 = 0x000000ff;
	#endif // __BYTE_ORDER
	static const uint32_t kBlack32 = 0x00000000;
	static const uint32_t kWhite32 = kRed8 \| kGreen8 \| kBlue8;

	/*
	* Extracting, and saving color bytes from / to WORD / DWORD RGB.
	*/

	#if __BYTE_ORDER == __LITTLE_ENDIAN
	/* Extract red, green, and blue bytes from RGB565 word. */
	#define R16(rgb) static_cast<uint8_t>(rgb & kRed5)
	#define G16(rgb) static_cast<uint8_t>((rgb & kGreen6) >> 5)
	#define B16(rgb) static_cast<uint8_t>((rgb & kBlue5) >> 11)
	/* Make 8 bits red, green, and blue, extracted from RGB565 word. */
	#define R16_32(rgb) static_cast<uint8_t>(((rgb & kRed5) << 3) \| ((rgb & kRed5) >> 2))
	#define G16_32(rgb) static_cast<uint8_t>(((rgb & kGreen6) >> 3) \| ((rgb & kGreen6) >> 9))
	#define B16_32(rgb) static_cast<uint8_t>(((rgb & kBlue5) >> 8) \| ((rgb & kBlue5) >> 14))
	/* Extract red, green, and blue bytes from RGB32 dword. */
	#define R32(rgb) static_cast<uint8_t>(rgb & kRed8)
	#define G32(rgb) static_cast<uint8_t>(((rgb & kGreen8) >> 8) & 0xff)
	#define B32(rgb) static_cast<uint8_t>(((rgb & kBlue8) >> 16) & 0xff)
	/* Build RGB565 word from red, green, and blue bytes. */
	#define RGB565(r, g, b) static_cast<uint16_t>((((static_cast<uint16_t>(b) << 6) \| g) << 5) \| r)
	/* Build RGB32 dword from red, green, and blue bytes. */
	#define RGB32(r, g, b) static_cast<uint32_t>((((static_cast<uint32_t>(b) << 8) \| g) << 8) \| r)
	#else // __BYTE_ORDER
	/* Extract red, green, and blue bytes from RGB565 word. */
	#define R16(rgb) static_cast<uint8_t>((rgb & kRed5) >> 11)
	#define G16(rgb) static_cast<uint8_t>((rgb & kGreen6) >> 5)
	#define B16(rgb) static_cast<uint8_t>(rgb & kBlue5)
	/* Make 8 bits red, green, and blue, extracted from RGB565 word. */
	#define R16_32(rgb) static_cast<uint8_t>(((rgb & kRed5) >> 8) \| ((rgb & kRed5) >> 14))
	#define G16_32(rgb) static_cast<uint8_t>(((rgb & kGreen6) >> 3) \| ((rgb & kGreen6) >> 9))
	#define B16_32(rgb) static_cast<uint8_t>(((rgb & kBlue5) << 3) \| ((rgb & kBlue5) >> 2))
	/* Extract red, green, and blue bytes from RGB32 dword. */
	#define R32(rgb) static_cast<uint8_t>((rgb & kRed8) >> 16)
	#define G32(rgb) static_cast<uint8_t>((rgb & kGreen8) >> 8)
	#define B32(rgb) static_cast<uint8_t>(rgb & kBlue8)
	/* Build RGB565 word from red, green, and blue bytes. */
	#define RGB565(r, g, b) static_cast<uint16_t>((((static_cast<uint16_t>(r) << 6) \| g) << 5) \| b)
	/* Build RGB32 dword from red, green, and blue bytes. */
	#define RGB32(r, g, b) static_cast<uint32_t>((((static_cast<uint32_t>(r) << 8) \| g) << 8) \| b)
	#endif // __BYTE_ORDER

	/* An union that simplifies breaking 32 bit RGB into separate R, G, and B colors.
	*/
	typedef union RGB32_t {
	uint32_t color;
	struct {
	#if __BYTE_ORDER == __LITTLE_ENDIAN
	uint8_t r; uint8_t g; uint8_t b; uint8_t a;
	#else // __BYTE_ORDER
	uint8_t a; uint8_t b; uint8_t g; uint8_t r;
	#endif // __BYTE_ORDER
	};
	} RGB32_t;


	/* Clips a value to the unsigned 0-255 range, treating negative values as zero.
	*/
	static __inline__ int
	clamp(int x)
	{
	if (x > 255) return 255;
	if (x < 0) return 0;
	return x;
	}

	/********************************************************************************
	* Basics of RGB -> YUV conversion
	*******************************************************************************/

	/*
	* RGB -> YUV conversion macros
	*/
	#define RGB2Y(r, g, b) (uint8_t)(((66 * (r) + 129 * (g) + 25 * (b) + 128) >> 8) + 16)
	#define RGB2U(r, g, b) (uint8_t)(((-38 * (r) - 74 * (g) + 112 * (b) + 128) >> 8) + 128)
	#define RGB2V(r, g, b) (uint8_t)(((112 * (r) - 94 * (g) - 18 * (b) + 128) >> 8) + 128)

	/* Converts R8 G8 B8 color to YUV. */
	static __inline__ void
	R8G8B8ToYUV(uint8_t r, uint8_t g, uint8_t b, uint8_t* y, uint8_t* u, uint8_t* v)
	{
	*y = RGB2Y((int)r, (int)g, (int)b);
	*u = RGB2U((int)r, (int)g, (int)b);
	*v = RGB2V((int)r, (int)g, (int)b);
	}

	/* Converts RGB565 color to YUV. */
	static __inline__ void
	RGB565ToYUV(uint16_t rgb, uint8_t* y, uint8_t* u, uint8_t* v)
	{
	R8G8B8ToYUV(R16_32(rgb), G16_32(rgb), B16_32(rgb), y, u, v);
	}

	/* Converts RGB32 color to YUV. */
	static __inline__ void
	RGB32ToYUV(uint32_t rgb, uint8_t* y, uint8_t* u, uint8_t* v)
	{
	RGB32_t rgb_c;
	rgb_c.color = rgb;
	R8G8B8ToYUV(rgb_c.r, rgb_c.g, rgb_c.b, y, u, v);
	}

	/********************************************************************************
	* Basics of YUV -> RGB conversion.
	* Note that due to the fact that guest uses RGB only on preview window, and the
	* RGB format that is used is RGB565, we can limit YUV -> RGB conversions to
	* RGB565 only.
	*******************************************************************************/

	/*
	* YUV -> RGB conversion macros
	*/

	/* "Optimized" macros that take specialy prepared Y, U, and V values:
	* C = Y - 16
	* D = U - 128
	* E = V - 128
	*/
	#define YUV2RO(C, D, E) clamp((298 * (C) + 409 * (E) + 128) >> 8)
	#define YUV2GO(C, D, E) clamp((298 * (C) - 100 * (D) - 208 * (E) + 128) >> 8)
	#define YUV2BO(C, D, E) clamp((298 * (C) + 516 * (D) + 128) >> 8)

	/*
	* Main macros that take the original Y, U, and V values
	*/
	#define YUV2R(y, u, v) clamp((298 * ((y)-16) + 409 * ((v)-128) + 128) >> 8)
	#define YUV2G(y, u, v) clamp((298 * ((y)-16) - 100 * ((u)-128) - 208 * ((v)-128) + 128) >> 8)
	#define YUV2B(y, u, v) clamp((298 * ((y)-16) + 516 * ((u)-128) + 128) >> 8)


	/* Converts YUV color to RGB565. */
	static __inline__ uint16_t
	YUVToRGB565(int y, int u, int v)
	{
	/* Calculate C, D, and E values for the optimized macro. */
	y -= 16; u -= 128; v -= 128;
	const uint16_t r = (YUV2RO(y,u,v) >> 3) & 0x1f;
	const uint16_t g = (YUV2GO(y,u,v) >> 2) & 0x3f;
	const uint16_t b = (YUV2BO(y,u,v) >> 3) & 0x1f;
	return RGB565(r, g, b);
	}

	/* Converts YUV color to RGB32. */
	static __inline__ uint32_t
	YUVToRGB32(int y, int u, int v)
	{
	/* Calculate C, D, and E values for the optimized macro. */
	y -= 16; u -= 128; v -= 128;
	RGB32_t rgb;
	rgb.r = YUV2RO(y,u,v) & 0xff;
	rgb.g = YUV2GO(y,u,v) & 0xff;
	rgb.b = YUV2BO(y,u,v) & 0xff;
	return rgb.color;
	}

	/* YUV pixel descriptor. */
	struct YUVPixel {
	uint8_t Y;
	uint8_t U;
	uint8_t V;

	inline YUVPixel()
	: Y(0), U(0), V(0)
	{
	}

	inline explicit YUVPixel(uint16_t rgb565)
	{
	RGB565ToYUV(rgb565, &Y, &U, &V);
	}

	inline explicit YUVPixel(uint32_t rgb32)
	{
	RGB32ToYUV(rgb32, &Y, &U, &V);
	}

	inline void get(uint8_t* pY, uint8_t* pU, uint8_t* pV) const
	{
	pY = Y; pU = U; *pV = V;
	}
	};

	/* Converts an YV12 framebuffer to RGB565 framebuffer.
	* Param:
	* yv12 - YV12 framebuffer.
	* rgb - RGB565 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void YV12ToRGB565(const void* yv12, void* rgb, int width, int height);

	/* Converts an YV12 framebuffer to RGB32 framebuffer.
	* Param:
	* yv12 - YV12 framebuffer.
	* rgb - RGB32 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void YV12ToRGB32(const void* yv12, void* rgb, int width, int height);

	/* Converts an YU12 framebuffer to RGB32 framebuffer.
	* Param:
	* yu12 - YU12 framebuffer.
	* rgb - RGB32 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void YU12ToRGB32(const void* yu12, void* rgb, int width, int height);

	/* Converts an NV12 framebuffer to RGB565 framebuffer.
	* Param:
	* nv12 - NV12 framebuffer.
	* rgb - RGB565 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void NV12ToRGB565(const void* nv12, void* rgb, int width, int height);

	/* Converts an NV12 framebuffer to RGB32 framebuffer.
	* Param:
	* nv12 - NV12 framebuffer.
	* rgb - RGB32 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void NV12ToRGB32(const void* nv12, void* rgb, int width, int height);

	/* Converts an NV21 framebuffer to RGB565 framebuffer.
	* Param:
	* nv21 - NV21 framebuffer.
	* rgb - RGB565 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void NV21ToRGB565(const void* nv21, void* rgb, int width, int height);

	/* Converts an NV21 framebuffer to RGB32 framebuffer.
	* Param:
	* nv21 - NV21 framebuffer.
	* rgb - RGB32 framebuffer.
	* width, height - Dimensions for both framebuffers.
	*/
	void NV21ToRGB32(const void* nv21, void* rgb, int width, int height);

	}; /* namespace android */

	#endif /* HW_EMULATOR_CAMERA_CONVERTERS_H */