camera/libcameraservice/FakeCamera.cpp - platform/frameworks/base - Gitiles

 /*
 **
 ** Copyright 2008, 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.
 */

 #define LOG_TAG "FakeCamera"
 #include <utils/Log.h>

 #include <string.h>
 #include <stdlib.h>
 #include <utils/String8.h>

 #include "FakeCamera.h"


 namespace android {

 // TODO: All this rgb to yuv should probably be in a util class.

 // TODO: I think something is wrong in this class because the shadow is kBlue
 // and the square color should alternate between kRed and kGreen. However on the
 // emulator screen these are all shades of gray. Y seems ok but the U and V are
 // probably not.

 static int tables_initialized = 0;
 uint8_t *gYTable, *gCbTable, *gCrTable;

 static int
 clamp(int  x)
 {
     if (x > 255) return 255;
     if (x < 0)   return 0;
     return x;
 }

 /* the equation used by the video code to translate YUV to RGB looks like this
  *
  *    Y  = (Y0 - 16)*k0
  *    Cb = Cb0 - 128
  *    Cr = Cr0 - 128
  *
  *    G = ( Y - k1*Cr - k2*Cb )
  *    R = ( Y + k3*Cr )
  *    B = ( Y + k4*Cb )
  *
  */

 static const double  k0 = 1.164;
 static const double  k1 = 0.813;
 static const double  k2 = 0.391;
 static const double  k3 = 1.596;
 static const double  k4 = 2.018;

 /* let's try to extract the value of Y
  *
  *   G + k1/k3*R + k2/k4*B = Y*( 1 + k1/k3 + k2/k4 )
  *
  *   Y  = ( G + k1/k3*R + k2/k4*B ) / (1 + k1/k3 + k2/k4)
  *   Y0 = ( G0 + k1/k3*R0 + k2/k4*B0 ) / ((1 + k1/k3 + k2/k4)*k0) + 16
  *
  * let define:
  *   kYr = k1/k3
  *   kYb = k2/k4
  *   kYy = k0 * ( 1 + kYr + kYb )
  *
  * we have:
  *    Y  = ( G + kYr*R + kYb*B )
  *    Y0 = clamp[ Y/kYy + 16 ]
  */

 static const double kYr = k1/k3;
 static const double kYb = k2/k4;
 static const double kYy = k0*( 1. + kYr + kYb );

 static void
 initYtab( void )
 {
     const  int imax = (int)( (kYr + kYb)*(31 << 2) + (61 << 3) + 0.1 );
     int    i;

     gYTable = (uint8_t *)malloc(imax);

     for(i=0; i<imax; i++) {
         int  x = (int)(i/kYy + 16.5);
         if (x < 16) x = 16;
         else if (x > 235) x = 235;
         gYTable[i] = (uint8_t) x;
     }
 }

 /*
  *   the source is RGB565, so adjust for 8-bit range of input values:
  *
  *   G = (pixels >> 3) & 0xFC;
  *   R = (pixels >> 8) & 0xF8;
  *   B = (pixels & 0x1f) << 3;
  *
  *   R2 = (pixels >> 11)      R = R2*8
  *   B2 = (pixels & 0x1f)     B = B2*8
  *
  *   kYr*R = kYr2*R2 =>  kYr2 = kYr*8
  *   kYb*B = kYb2*B2 =>  kYb2 = kYb*8
  *
  *   we want to use integer multiplications:
  *
  *   SHIFT1 = 9
  *
  *   (ALPHA*R2) >> SHIFT1 == R*kYr  =>  ALPHA = kYr*8*(1 << SHIFT1)
  *
  *   ALPHA = kYr*(1 << (SHIFT1+3))
  *   BETA  = kYb*(1 << (SHIFT1+3))
  */

 static const int  SHIFT1  = 9;
 static const int  ALPHA   = (int)( kYr*(1 << (SHIFT1+3)) + 0.5 );
 static const int  BETA    = (int)( kYb*(1 << (SHIFT1+3)) + 0.5 );

 /*
  *  now let's try to get the values of Cb and Cr
  *
  *  R-B = (k3*Cr - k4*Cb)
  *
  *    k3*Cr = k4*Cb + (R-B)
  *    k4*Cb = k3*Cr - (R-B)
  *
  *  R-G = (k1+k3)*Cr + k2*Cb
  *      = (k1+k3)*Cr + k2/k4*(k3*Cr - (R-B)/k0)
  *      = (k1 + k3 + k2*k3/k4)*Cr - k2/k4*(R-B)
  *
  *  kRr*Cr = (R-G) + kYb*(R-B)
  *
  *  Cr  = ((R-G) + kYb*(R-B))/kRr
  *  Cr0 = clamp(Cr + 128)
  */

 static const double  kRr = (k1 + k3 + k2*k3/k4);

 static void
 initCrtab( void )
 {
     uint8_t *pTable;
     int i;

     gCrTable = (uint8_t *)malloc(768*2);

     pTable = gCrTable + 384;
     for(i=-384; i<384; i++)
         pTable[i] = (uint8_t) clamp( i/kRr + 128.5 );
 }

 /*
  *  B-G = (k2 + k4)*Cb + k1*Cr
  *      = (k2 + k4)*Cb + k1/k3*(k4*Cb + (R-B))
  *      = (k2 + k4 + k1*k4/k3)*Cb + k1/k3*(R-B)
  *
  *  kBb*Cb = (B-G) - kYr*(R-B)
  *
  *  Cb   = ((B-G) - kYr*(R-B))/kBb
  *  Cb0  = clamp(Cb + 128)
  *
  */

 static const double  kBb = (k2 + k4 + k1*k4/k3);

 static void
 initCbtab( void )
 {
     uint8_t *pTable;
     int i;

     gCbTable = (uint8_t *)malloc(768*2);

     pTable = gCbTable + 384;
     for(i=-384; i<384; i++)
         pTable[i] = (uint8_t) clamp( i/kBb + 128.5 );
 }

 /*
  *   SHIFT2 = 16
  *
  *   DELTA = kYb*(1 << SHIFT2)
  *   GAMMA = kYr*(1 << SHIFT2)
  */

 static const int  SHIFT2 = 16;
 static const int  DELTA  = kYb*(1 << SHIFT2);
 static const int  GAMMA  = kYr*(1 << SHIFT2);

 int32_t ccrgb16toyuv_wo_colorkey(uint8_t *rgb16,uint8_t *yuv422,uint32_t *param,uint8_t *table[])
 {
     uint16_t *inputRGB = (uint16_t*)rgb16;
     uint8_t *outYUV =  yuv422;
     int32_t width_dst = param[0];
     int32_t height_dst = param[1];
     int32_t pitch_dst = param[2];
     int32_t mheight_dst = param[3];
     int32_t pitch_src = param[4];
     uint8_t *y_tab = table[0];
     uint8_t *cb_tab = table[1];
     uint8_t *cr_tab = table[2];

     int32_t size16 = pitch_dst*mheight_dst;
     int32_t i,j,count;
     int32_t ilimit,jlimit;
     uint8_t *tempY,*tempU,*tempV;
     uint16_t pixels;
     int   tmp;
 uint32_t temp;

     tempY = outYUV;
     tempU = outYUV + (height_dst * pitch_dst);
     tempV = tempU + 1;

     jlimit = height_dst;
     ilimit = width_dst;

     for(j=0; j<jlimit; j+=1)
     {
         for (i=0; i<ilimit; i+=2)
         {
             int32_t   G_ds = 0, B_ds = 0, R_ds = 0;
             uint8_t   y0, y1, u, v;

             pixels =  inputRGB[i];
             temp = (ALPHA*(pixels & 0x001F) + BETA*(pixels>>11) );
             y0   = y_tab[(temp>>SHIFT1) + ((pixels>>3) & 0x00FC)];

             G_ds    += (pixels>>1) & 0x03E0;
             B_ds    += (pixels<<5) & 0x03E0;
             R_ds    += (pixels>>6) & 0x03E0;

             pixels =  inputRGB[i+1];
             temp = (ALPHA*(pixels & 0x001F) + BETA*(pixels>>11) );
             y1   = y_tab[(temp>>SHIFT1) + ((pixels>>3) & 0x00FC)];

             G_ds    += (pixels>>1) & 0x03E0;
             B_ds    += (pixels<<5) & 0x03E0;
             R_ds    += (pixels>>6) & 0x03E0;

             R_ds >>= 1;
             B_ds >>= 1;
             G_ds >>= 1;

             tmp = R_ds - B_ds;

             u = cb_tab[(((R_ds-G_ds)<<SHIFT2) + DELTA*tmp)>>(SHIFT2+2)];
             v = cr_tab[(((B_ds-G_ds)<<SHIFT2) - GAMMA*tmp)>>(SHIFT2+2)];

             tempY[0] = y0;
             tempY[1] = y1;
             tempU[0] = u;
             tempV[0] = v;

             tempY += 2;
             tempU += 2;
             tempV += 2;
         }

         inputRGB += pitch_src;
     }

     return 1;
 }

 #define min(a,b) ((a)<(b)?(a):(b))
 #define max(a,b) ((a)>(b)?(a):(b))

 static void convert_rgb16_to_yuv422(uint8_t *rgb, uint8_t *yuv, int width, int height)
 {
     if (!tables_initialized) {
         initYtab();
         initCrtab();
         initCbtab();
         tables_initialized = 1;
     }

     uint32_t param[6];
     param[0] = (uint32_t) width;
     param[1] = (uint32_t) height;
     param[2] = (uint32_t) width;
     param[3] = (uint32_t) height;
     param[4] = (uint32_t) width;
     param[5] = (uint32_t) 0;

     uint8_t *table[3];
     table[0] = gYTable;
     table[1] = gCbTable + 384;
     table[2] = gCrTable + 384;

     ccrgb16toyuv_wo_colorkey(rgb, yuv, param, table);
 }

 const int FakeCamera::kRed;
 const int FakeCamera::kGreen;
 const int FakeCamera::kBlue;

 FakeCamera::FakeCamera(int width, int height)
           : mTmpRgb16Buffer(0)
 {
     setSize(width, height);
 }

 FakeCamera::~FakeCamera()
 {
     delete[] mTmpRgb16Buffer;
 }

 void FakeCamera::setSize(int width, int height)
 {
     mWidth = width;
     mHeight = height;
     mCounter = 0;
     mCheckX = 0;
     mCheckY = 0;

     // This will cause it to be reallocated on the next call
     // to getNextFrameAsYuv422().
     delete[] mTmpRgb16Buffer;
     mTmpRgb16Buffer = 0;
 }

 void FakeCamera::getNextFrameAsRgb565(uint16_t *buffer)
 {
     int size = mWidth / 10;

     drawCheckerboard(buffer, size);

     int x = ((mCounter*3)&255);
     if(x>128) x = 255 - x;
     int y = ((mCounter*5)&255);
     if(y>128) y = 255 - y;

     drawSquare(buffer, x*size/32, y*size/32, (size*5)>>1, (mCounter&0x100)?kRed:kGreen, kBlue);

     mCounter++;
 }

 void FakeCamera::getNextFrameAsYuv422(uint8_t *buffer)
 {
     if (mTmpRgb16Buffer == 0)
         mTmpRgb16Buffer = new uint16_t[mWidth * mHeight];

     getNextFrameAsRgb565(mTmpRgb16Buffer);
     convert_rgb16_to_yuv422((uint8_t*)mTmpRgb16Buffer, buffer, mWidth, mHeight);
 }

 void FakeCamera::drawSquare(uint16_t *dst, int x, int y, int size, int color, int shadow)
 {
     int square_xstop, square_ystop, shadow_xstop, shadow_ystop;

     square_xstop = min(mWidth, x+size);
     square_ystop = min(mHeight, y+size);
     shadow_xstop = min(mWidth, x+size+(size/4));
     shadow_ystop = min(mHeight, y+size+(size/4));

     // Do the shadow.
     uint16_t *sh = &dst[(y+(size/4))*mWidth];
     for (int j = y + (size/4); j < shadow_ystop; j++) {
         for (int i = x + (size/4); i < shadow_xstop; i++) {
             sh[i] &= shadow;
         }
         sh += mWidth;
     }

     // Draw the square.
     uint16_t *sq = &dst[y*mWidth];
     for (int j = y; j < square_ystop; j++) {
         for (int i = x; i < square_xstop; i++) {
             sq[i] = color;
         }
         sq += mWidth;
     }
 }

 void FakeCamera::drawCheckerboard(uint16_t *dst, int size)
 {
     bool black = true;

     if((mCheckX/size)&1)
         black = false;
     if((mCheckY/size)&1)
         black = !black;

     int county = mCheckY%size;
     int checkxremainder = mCheckX%size;

     for(int y=0;y<mHeight;y++) {
         int countx = checkxremainder;
         bool current = black;
         for(int x=0;x<mWidth;x++) {
             dst[y*mWidth+x] = current?0:0xffff;
             if(countx++ >= size) {
                 countx=0;
                 current = !current;
             }
         }
         if(county++ >= size) {
             county=0;
             black = !black;
         }
     }
     mCheckX += 3;
     mCheckY++;
 }


 void FakeCamera::dump(int fd) const
 {
     const size_t SIZE = 256;
     char buffer[SIZE];
     String8 result;
     snprintf(buffer, 255, " width x height (%d x %d), counter (%d), check x-y coordinate(%d, %d)\n", mWidth, mHeight, mCounter, mCheckX, mCheckY);
     result.append(buffer);
     ::write(fd, result.string(), result.size());
 }


 }; // namespace android
	/*
	**
	** Copyright 2008, 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.
	*/

	#define LOG_TAG "FakeCamera"
	#include <utils/Log.h>

	#include <string.h>
	#include <stdlib.h>
	#include <utils/String8.h>

	#include "FakeCamera.h"


	namespace android {

	// TODO: All this rgb to yuv should probably be in a util class.

	// TODO: I think something is wrong in this class because the shadow is kBlue
	// and the square color should alternate between kRed and kGreen. However on the
	// emulator screen these are all shades of gray. Y seems ok but the U and V are
	// probably not.

	static int tables_initialized = 0;
	uint8_t gYTable, gCbTable, *gCrTable;

	static int
	clamp(int x)
	{
	if (x > 255) return 255;
	if (x < 0) return 0;
	return x;
	}

	/* the equation used by the video code to translate YUV to RGB looks like this
	*
	* Y = (Y0 - 16)*k0
	* Cb = Cb0 - 128
	* Cr = Cr0 - 128
	*
	* G = ( Y - k1Cr - k2Cb )
	* R = ( Y + k3*Cr )
	* B = ( Y + k4*Cb )
	*
	*/

	static const double k0 = 1.164;
	static const double k1 = 0.813;
	static const double k2 = 0.391;
	static const double k3 = 1.596;
	static const double k4 = 2.018;

	/* let's try to extract the value of Y
	*
	* G + k1/k3R + k2/k4B = Y*( 1 + k1/k3 + k2/k4 )
	*
	* Y = ( G + k1/k3R + k2/k4B ) / (1 + k1/k3 + k2/k4)
	* Y0 = ( G0 + k1/k3R0 + k2/k4B0 ) / ((1 + k1/k3 + k2/k4)*k0) + 16
	*
	* let define:
	* kYr = k1/k3
	* kYb = k2/k4
	* kYy = k0 * ( 1 + kYr + kYb )
	*
	* we have:
	* Y = ( G + kYrR + kYbB )
	* Y0 = clamp[ Y/kYy + 16 ]
	*/

	static const double kYr = k1/k3;
	static const double kYb = k2/k4;
	static const double kYy = k0*( 1. + kYr + kYb );

	static void
	initYtab( void )
	{
	const int imax = (int)( (kYr + kYb)*(31 << 2) + (61 << 3) + 0.1 );
	int i;

	gYTable = (uint8_t *)malloc(imax);

	for(i=0; i<imax; i++) {
	int x = (int)(i/kYy + 16.5);
	if (x < 16) x = 16;
	else if (x > 235) x = 235;
	gYTable[i] = (uint8_t) x;
	}
	}

	/*
	* the source is RGB565, so adjust for 8-bit range of input values:
	*
	* G = (pixels >> 3) & 0xFC;
	* R = (pixels >> 8) & 0xF8;
	* B = (pixels & 0x1f) << 3;
	*
	* R2 = (pixels >> 11) R = R2*8
	* B2 = (pixels & 0x1f) B = B2*8
	*
	* kYrR = kYr2R2 => kYr2 = kYr*8
	* kYbB = kYb2B2 => kYb2 = kYb*8
	*
	* we want to use integer multiplications:
	*
	* SHIFT1 = 9
	*
	* (ALPHAR2) >> SHIFT1 == RkYr => ALPHA = kYr8(1 << SHIFT1)
	*
	* ALPHA = kYr*(1 << (SHIFT1+3))
	* BETA = kYb*(1 << (SHIFT1+3))
	*/

	static const int SHIFT1 = 9;
	static const int ALPHA = (int)( kYr*(1 << (SHIFT1+3)) + 0.5 );
	static const int BETA = (int)( kYb*(1 << (SHIFT1+3)) + 0.5 );

	/*
	* now let's try to get the values of Cb and Cr
	*
	* R-B = (k3Cr - k4Cb)
	*
	* k3Cr = k4Cb + (R-B)
	* k4Cb = k3Cr - (R-B)
	*
	* R-G = (k1+k3)Cr + k2Cb
	* = (k1+k3)Cr + k2/k4(k3*Cr - (R-B)/k0)
	* = (k1 + k3 + k2k3/k4)Cr - k2/k4*(R-B)
	*
	* kRrCr = (R-G) + kYb(R-B)
	*
	* Cr = ((R-G) + kYb*(R-B))/kRr
	* Cr0 = clamp(Cr + 128)
	*/

	static const double kRr = (k1 + k3 + k2*k3/k4);

	static void
	initCrtab( void )
	{
	uint8_t *pTable;
	int i;

	gCrTable = (uint8_t )malloc(7682);

	pTable = gCrTable + 384;
	for(i=-384; i<384; i++)
	pTable[i] = (uint8_t) clamp( i/kRr + 128.5 );
	}

	/*
	* B-G = (k2 + k4)Cb + k1Cr
	* = (k2 + k4)Cb + k1/k3(k4*Cb + (R-B))
	* = (k2 + k4 + k1k4/k3)Cb + k1/k3*(R-B)
	*
	* kBbCb = (B-G) - kYr(R-B)
	*
	* Cb = ((B-G) - kYr*(R-B))/kBb
	* Cb0 = clamp(Cb + 128)
	*
	*/

	static const double kBb = (k2 + k4 + k1*k4/k3);

	static void
	initCbtab( void )
	{
	uint8_t *pTable;
	int i;

	gCbTable = (uint8_t )malloc(7682);

	pTable = gCbTable + 384;
	for(i=-384; i<384; i++)
	pTable[i] = (uint8_t) clamp( i/kBb + 128.5 );
	}

	/*
	* SHIFT2 = 16
	*
	* DELTA = kYb*(1 << SHIFT2)
	* GAMMA = kYr*(1 << SHIFT2)
	*/

	static const int SHIFT2 = 16;
	static const int DELTA = kYb*(1 << SHIFT2);
	static const int GAMMA = kYr*(1 << SHIFT2);

	int32_t ccrgb16toyuv_wo_colorkey(uint8_t rgb16,uint8_t yuv422,uint32_t param,uint8_t table[])
	{
	uint16_t inputRGB = (uint16_t)rgb16;
	uint8_t *outYUV = yuv422;
	int32_t width_dst = param[0];
	int32_t height_dst = param[1];
	int32_t pitch_dst = param[2];
	int32_t mheight_dst = param[3];
	int32_t pitch_src = param[4];
	uint8_t *y_tab = table[0];
	uint8_t *cb_tab = table[1];
	uint8_t *cr_tab = table[2];

	int32_t size16 = pitch_dst*mheight_dst;
	int32_t i,j,count;
	int32_t ilimit,jlimit;
	uint8_t tempY,tempU,*tempV;
	uint16_t pixels;
	int tmp;
	uint32_t temp;

	tempY = outYUV;
	tempU = outYUV + (height_dst * pitch_dst);
	tempV = tempU + 1;

	jlimit = height_dst;
	ilimit = width_dst;

	for(j=0; j<jlimit; j+=1)
	{
	for (i=0; i<ilimit; i+=2)
	{
	int32_t G_ds = 0, B_ds = 0, R_ds = 0;
	uint8_t y0, y1, u, v;

	pixels = inputRGB[i];
	temp = (ALPHA(pixels & 0x001F) + BETA(pixels>>11) );
	y0 = y_tab[(temp>>SHIFT1) + ((pixels>>3) & 0x00FC)];

	G_ds += (pixels>>1) & 0x03E0;
	B_ds += (pixels<<5) & 0x03E0;
	R_ds += (pixels>>6) & 0x03E0;

	pixels = inputRGB[i+1];
	temp = (ALPHA(pixels & 0x001F) + BETA(pixels>>11) );
	y1 = y_tab[(temp>>SHIFT1) + ((pixels>>3) & 0x00FC)];

	G_ds += (pixels>>1) & 0x03E0;
	B_ds += (pixels<<5) & 0x03E0;
	R_ds += (pixels>>6) & 0x03E0;

	R_ds >>= 1;
	B_ds >>= 1;
	G_ds >>= 1;

	tmp = R_ds - B_ds;

	u = cb_tab[(((R_ds-G_ds)<<SHIFT2) + DELTA*tmp)>>(SHIFT2+2)];
	v = cr_tab[(((B_ds-G_ds)<<SHIFT2) - GAMMA*tmp)>>(SHIFT2+2)];

	tempY[0] = y0;
	tempY[1] = y1;
	tempU[0] = u;
	tempV[0] = v;

	tempY += 2;
	tempU += 2;
	tempV += 2;
	}

	inputRGB += pitch_src;
	}

	return 1;
	}

	#define min(a,b) ((a)<(b)?(a):(b))
	#define max(a,b) ((a)>(b)?(a):(b))

	static void convert_rgb16_to_yuv422(uint8_t rgb, uint8_t yuv, int width, int height)
	{
	if (!tables_initialized) {
	initYtab();
	initCrtab();
	initCbtab();
	tables_initialized = 1;
	}

	uint32_t param[6];
	param[0] = (uint32_t) width;
	param[1] = (uint32_t) height;
	param[2] = (uint32_t) width;
	param[3] = (uint32_t) height;
	param[4] = (uint32_t) width;
	param[5] = (uint32_t) 0;

	uint8_t *table[3];
	table[0] = gYTable;
	table[1] = gCbTable + 384;
	table[2] = gCrTable + 384;

	ccrgb16toyuv_wo_colorkey(rgb, yuv, param, table);
	}

	const int FakeCamera::kRed;
	const int FakeCamera::kGreen;
	const int FakeCamera::kBlue;

	FakeCamera::FakeCamera(int width, int height)
	: mTmpRgb16Buffer(0)
	{
	setSize(width, height);
	}

	FakeCamera::~FakeCamera()
	{
	delete[] mTmpRgb16Buffer;
	}

	void FakeCamera::setSize(int width, int height)
	{
	mWidth = width;
	mHeight = height;
	mCounter = 0;
	mCheckX = 0;
	mCheckY = 0;

	// This will cause it to be reallocated on the next call
	// to getNextFrameAsYuv422().
	delete[] mTmpRgb16Buffer;
	mTmpRgb16Buffer = 0;
	}

	void FakeCamera::getNextFrameAsRgb565(uint16_t *buffer)
	{
	int size = mWidth / 10;

	drawCheckerboard(buffer, size);

	int x = ((mCounter*3)&255);
	if(x>128) x = 255 - x;
	int y = ((mCounter*5)&255);
	if(y>128) y = 255 - y;

	drawSquare(buffer, xsize/32, ysize/32, (size*5)>>1, (mCounter&0x100)?kRed:kGreen, kBlue);

	mCounter++;
	}

	void FakeCamera::getNextFrameAsYuv422(uint8_t *buffer)
	{
	if (mTmpRgb16Buffer == 0)
	mTmpRgb16Buffer = new uint16_t[mWidth * mHeight];

	getNextFrameAsRgb565(mTmpRgb16Buffer);
	convert_rgb16_to_yuv422((uint8_t*)mTmpRgb16Buffer, buffer, mWidth, mHeight);
	}

	void FakeCamera::drawSquare(uint16_t *dst, int x, int y, int size, int color, int shadow)
	{
	int square_xstop, square_ystop, shadow_xstop, shadow_ystop;

	square_xstop = min(mWidth, x+size);
	square_ystop = min(mHeight, y+size);
	shadow_xstop = min(mWidth, x+size+(size/4));
	shadow_ystop = min(mHeight, y+size+(size/4));

	// Do the shadow.
	uint16_t sh = &dst[(y+(size/4))mWidth];
	for (int j = y + (size/4); j < shadow_ystop; j++) {
	for (int i = x + (size/4); i < shadow_xstop; i++) {
	sh[i] &= shadow;
	}
	sh += mWidth;
	}

	// Draw the square.
	uint16_t sq = &dst[ymWidth];
	for (int j = y; j < square_ystop; j++) {
	for (int i = x; i < square_xstop; i++) {
	sq[i] = color;
	}
	sq += mWidth;
	}
	}

	void FakeCamera::drawCheckerboard(uint16_t *dst, int size)
	{
	bool black = true;

	if((mCheckX/size)&1)
	black = false;
	if((mCheckY/size)&1)
	black = !black;

	int county = mCheckY%size;
	int checkxremainder = mCheckX%size;

	for(int y=0;y<mHeight;y++) {
	int countx = checkxremainder;
	bool current = black;
	for(int x=0;x<mWidth;x++) {
	dst[y*mWidth+x] = current?0:0xffff;
	if(countx++ >= size) {
	countx=0;
	current = !current;
	}
	}
	if(county++ >= size) {
	county=0;
	black = !black;
	}
	}
	mCheckX += 3;
	mCheckY++;
	}


	void FakeCamera::dump(int fd) const
	{
	const size_t SIZE = 256;
	char buffer[SIZE];
	String8 result;
	snprintf(buffer, 255, " width x height (%d x %d), counter (%d), check x-y coordinate(%d, %d)\n", mWidth, mHeight, mCounter, mCheckX, mCheckY);
	result.append(buffer);
	::write(fd, result.string(), result.size());
	}


	}; // namespace android