cl_kernel/kernel_bayer_basic.cl - platform/external/libxcam - Git at Google

 /*
  * function: kernel_bayer_copy
  *     sample code of default kernel arguments
  * input:    image2d_t as read only
  * output:   image2d_t as write only
  */

 //#define ENABLE_IMAGE_2D_INPUT 0

 #ifndef STATS_BITS
 #define STATS_BITS 8
 #endif

 /*
  * GROUP_PIXEL_X_SIZE = 2 * GROUP_CELL_X_SIZE
  * GROUP_PIXEL_Y_SIZE = 2 * GROUP_CELL_Y_SIZE
 */

 #define GROUP_CELL_X_SIZE 64
 #define GROUP_CELL_Y_SIZE 4

 //float4; 16
 #define SLM_X_SIZE (GROUP_CELL_X_SIZE / 4)
 #define SLM_Y_SIZE GROUP_CELL_Y_SIZE

 #define STATS_3A_CELL_X_SIZE 8
 #define STATS_3A_CELL_Y_SIZE GROUP_CELL_Y_SIZE

 typedef struct  {
     float  level_gr;  /* Black level for GR pixels */
     float  level_r;   /* Black level for R pixels */
     float  level_b;   /* Black level for B pixels */
     float  level_gb;  /* Black level for GB pixels */
     uint   color_bits;
 } CLBLCConfig;


 typedef struct
 {
     float r_gain;
     float gr_gain;
     float gb_gain;
     float b_gain;
 } CLWBConfig;

 inline int slm_pos (const int x, const int y)
 {
     return mad24 (y, SLM_X_SIZE, x);
 }

 inline void gamma_correct(float8 *in_out, __global float *table)
 {
     in_out->s0 = table[clamp(convert_int(in_out->s0 * 255.0f), 0, 255)];
     in_out->s1 = table[clamp(convert_int(in_out->s1 * 255.0f), 0, 255)];
     in_out->s2 = table[clamp(convert_int(in_out->s2 * 255.0f), 0, 255)];
     in_out->s3 = table[clamp(convert_int(in_out->s3 * 255.0f), 0, 255)];
     in_out->s4 = table[clamp(convert_int(in_out->s4 * 255.0f), 0, 255)];
     in_out->s5 = table[clamp(convert_int(in_out->s5 * 255.0f), 0, 255)];
     in_out->s6 = table[clamp(convert_int(in_out->s6 * 255.0f), 0, 255)];
     in_out->s7 = table[clamp(convert_int(in_out->s7 * 255.0f), 0, 255)];
 }

 inline float avg_float8 (float8 data)
 {
     return (data.s0 + data.s1 + data.s2 + data.s3 + data.s4 + data.s5 + data.s6 + data.s7) * 0.125f;
 }

 inline void stats_3a_calculate (
     __local float4 * slm_gr,
     __local float4 * slm_r,
     __local float4 * slm_b,
     __local float4 * slm_gb,
     __global ushort8 * stats_output,
     CLWBConfig *wb_config)
 {
     const int group_x_size = get_num_groups (0);
     const int group_id_x = get_group_id (0);
     const int group_id_y = get_group_id (1);

     const int l_id_x = get_local_id (0);
     const int l_id_y = get_local_id (1);
     const int l_size_x = get_local_size (0);
     const int stats_float4_x_count = STATS_3A_CELL_X_SIZE / 4;
     int count =  stats_float4_x_count * STATS_3A_CELL_Y_SIZE / 4;

     int index = mad24 (l_id_y, l_size_x, l_id_x);
     int index_x = index % SLM_X_SIZE;
     int index_y = index / SLM_X_SIZE;

     if (mad24 (index_y,  stats_float4_x_count, index_x % stats_float4_x_count) < count) {
         int pitch_count = count / stats_float4_x_count * SLM_X_SIZE;
         int index1 = index + pitch_count;
         int index2 = index1 + pitch_count;
         int index3 = index2 + pitch_count;
         slm_gr[index] = (slm_gr[index] + slm_gr[index1] + slm_gr[index2] + slm_gr[index3]) * 0.25f;
         slm_r[index] = (slm_r[index] + slm_r[index1] + slm_r[index2] + slm_r[index3]) * 0.25f;
         slm_b[index] = (slm_b[index] + slm_b[index1] + slm_b[index2] + slm_b[index3]) * 0.25f;
         slm_gb[index] = (slm_gb[index] + slm_gb[index1] + slm_gb[index2] + slm_gb[index3]) * 0.25f;
     }
     barrier (CLK_LOCAL_MEM_FENCE);

     if (index < SLM_X_SIZE / 2) {
         float result_gr, result_r, result_b, result_gb, avg_y;
         float8 tmp;
         tmp = ((__local float8*)slm_gr)[index];
         result_gr = avg_float8 (tmp);

         tmp = ((__local float8*)slm_r)[index];
         result_r = avg_float8 (tmp);

         tmp = ((__local float8*)slm_b)[index];
         result_b = avg_float8 (tmp);

         tmp = ((__local float8*)slm_gb)[index];
         result_gb = avg_float8 (tmp);

         int out_index = mad24 (mad24 (group_id_y, group_x_size, group_id_x),
                                (GROUP_CELL_X_SIZE / STATS_3A_CELL_X_SIZE) * (GROUP_CELL_Y_SIZE / STATS_3A_CELL_Y_SIZE),
                                index);

 #if STATS_BITS==8
         avg_y = mad ((result_gr * wb_config->gr_gain + result_gb * wb_config->gb_gain), 74.843f,
                      mad (result_r * wb_config->r_gain, 76.245f, result_b * 29.070f));

         //ushort avg_y; avg_r; avg_gr; avg_gb; avg_b; valid_wb_count; f_value1; f_value2;
         stats_output[out_index] = (ushort8) (
                                       convert_ushort (convert_uchar_sat (avg_y)),
                                       convert_ushort (convert_uchar_sat (result_r * 255.0f)),
                                       convert_ushort (convert_uchar_sat (result_gr * 255.0f)),
                                       convert_ushort (convert_uchar_sat (result_gb * 255.0f)),
                                       convert_ushort (convert_uchar_sat (result_b * 255.0f)),
                                       STATS_3A_CELL_X_SIZE * STATS_3A_CELL_Y_SIZE,
                                       0,
                                       0);
 #elif STATS_BITS==12
         avg_y = mad ((result_gr * wb_config->gr_gain + result_gb * wb_config->gb_gain), 1201.883f,
                      mad (result_r * wb_config->r_gain, 1224.405f, result_b * 466.830f));

         stats_output[out_index] = (ushort8) (
                                       convert_ushort (clamp (avg_y, 0.0f, 4095.0f)),
                                       convert_ushort (clamp (result_r * 4096.0f, 0.0f, 4095.0f)),
                                       convert_ushort (clamp (result_gr * 4096.0f, 0.0f, 4095.0f)),
                                       convert_ushort (clamp (result_gb * 4096.0f, 0.0f, 4095.0f)),
                                       convert_ushort (clamp (result_b * 4096.0f, 0.0f, 4095.0f)),
                                       STATS_3A_CELL_X_SIZE * STATS_3A_CELL_Y_SIZE,
                                       0,
                                       0);
 #else
         printf ("kernel 3a-stats error, wrong bit depth:%d\n", STATS_BITS);
 #endif
     }
 }


 __kernel void kernel_bayer_basic (
 #if ENABLE_IMAGE_2D_INPUT
     __read_only image2d_t input,
 #else
     __global const ushort8 *input,
 #endif
     uint input_aligned_width,
     __write_only image2d_t output,
     uint out_height,
     CLBLCConfig blc_config,
     CLWBConfig wb_config,
     __global float *gamma_table,
     __global ushort8 *stats_output
 )
 {
     int g_x = get_global_id (0);
     int g_y = get_global_id (1);

     const int l_x = get_local_id (0);
     const int l_y = get_local_id (1);
     const int l_x_size = get_local_size (0);
     const int l_y_size = get_local_size (1);
     const int group_id_x = get_group_id (0);
     const int group_id_y = get_group_id (1);

     sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE | CLK_ADDRESS_NONE | CLK_FILTER_NEAREST;

     int index = mad24 (l_y, l_x_size, l_x);
     int x_cell_start = (GROUP_CELL_X_SIZE / 4) * group_id_x;
     int y_cell_start = GROUP_CELL_Y_SIZE * group_id_y;
     int x, y;

     float blc_multiplier = (float)(1 << (16 - blc_config.color_bits));

     __local float4 slm_gr[SLM_X_SIZE * SLM_Y_SIZE], slm_r[SLM_X_SIZE * SLM_Y_SIZE], slm_b[SLM_X_SIZE * SLM_Y_SIZE], slm_gb[SLM_X_SIZE * SLM_Y_SIZE];

     for (; index < SLM_X_SIZE * SLM_Y_SIZE; index += l_x_size * l_y_size) {
         float8 line1;
         float8 line2;

         x = index % SLM_X_SIZE + x_cell_start;
         y = index / SLM_X_SIZE + y_cell_start;

 #if ENABLE_IMAGE_2D_INPUT
         line1 = convert_float8 (as_ushort8 (read_imageui(input, sampler, (int2)(x, y * 2)))) / 65536.0f;
         line2 = convert_float8 (as_ushort8 (read_imageui(input, sampler, (int2)(x, y * 2 + 1)))) / 65536.0f;
 #else
         line1 = convert_float8 (input [y * 2 * input_aligned_width + x]) / 65536.0f;
         line2 = convert_float8 (input [(y * 2 + 1) * input_aligned_width + x]) / 65536.0f;
 #endif

         float4 gr = mad (line1.even, blc_multiplier, - blc_config.level_gr);
         float4 r = mad (line1.odd, blc_multiplier, - blc_config.level_r);
         float4 b = mad (line2.even, blc_multiplier, - blc_config.level_b);
         float4 gb = mad (line2.odd, blc_multiplier, - blc_config.level_gb);

         slm_gr[index] = gr;
         slm_r[index] =  r;
         slm_b[index] =  b;
         slm_gb[index] = gb;
     }
     barrier(CLK_LOCAL_MEM_FENCE);

     float8 data_gr, data_r, data_b, data_gb;
     index = mad24 (l_y, l_x_size, l_x);
     x = mad24 (GROUP_CELL_X_SIZE / 8, group_id_x,  index % (SLM_X_SIZE / 2));
     y = mad24 (GROUP_CELL_Y_SIZE, group_id_y,  index / (SLM_X_SIZE / 2));

     data_gr = ((__local float8*)slm_gr)[index];
     data_gr = data_gr * wb_config.gr_gain;

     data_r = ((__local float8*)slm_r)[index];
     data_r  = data_r * wb_config.r_gain;

     data_b = ((__local float8*)slm_b)[index];
     data_b = data_b * wb_config.b_gain;

     data_gb = ((__local float8*)slm_gb)[index];
     data_gb = data_gb * wb_config.gb_gain;

 #if ENABLE_GAMMA
     gamma_correct (&data_gr, gamma_table);
     gamma_correct (&data_r, gamma_table);
     gamma_correct (&data_b, gamma_table);
     gamma_correct (&data_gb, gamma_table);
 #endif

 #if 0
     if (x % 16 == 0 && y % 16 == 0) {
         uint8 value = convert_uint8(convert_uchar8_sat(data_gr * 255.0f));
         printf ("(x:%d, y:%d) (blc.bit:%d, level:%d) (wb.gr:%f)=> (%d, %d, %d, %d, %d, %d, %d, %d)\n",
                 x * 8, y,
                 blc_config.color_bits, convert_uint(blc_config.level_gr * 255.0f),
                 wb_config.gr_gain,
                 value.s0, value.s1, value.s2, value.s3, value.s4, value.s5, value.s6, value.s7);
     }
 #endif

     write_imageui (output, (int2)(x, y), as_uint4 (convert_ushort8 (data_gr * 65536.0f)));
     write_imageui (output, (int2)(x, y + out_height), as_uint4 (convert_ushort8 (data_r * 65536.0f)));
     write_imageui (output, (int2)(x, y + out_height * 2), as_uint4 (convert_ushort8 (data_b * 65536.0f)));
     write_imageui (output, (int2)(x, y + out_height * 3), as_uint4 (convert_ushort8 (data_gb * 65536.0f)));

     stats_3a_calculate (slm_gr, slm_r, slm_b, slm_gb, stats_output, &wb_config);
 }
	/*
	* function: kernel_bayer_copy
	* sample code of default kernel arguments
	* input: image2d_t as read only
	* output: image2d_t as write only
	*/

	//#define ENABLE_IMAGE_2D_INPUT 0

	#ifndef STATS_BITS
	#define STATS_BITS 8
	#endif

	/*
	* GROUP_PIXEL_X_SIZE = 2 * GROUP_CELL_X_SIZE
	* GROUP_PIXEL_Y_SIZE = 2 * GROUP_CELL_Y_SIZE
	*/

	#define GROUP_CELL_X_SIZE 64
	#define GROUP_CELL_Y_SIZE 4

	//float4; 16
	#define SLM_X_SIZE (GROUP_CELL_X_SIZE / 4)
	#define SLM_Y_SIZE GROUP_CELL_Y_SIZE

	#define STATS_3A_CELL_X_SIZE 8
	#define STATS_3A_CELL_Y_SIZE GROUP_CELL_Y_SIZE

	typedef struct {
	float level_gr; /* Black level for GR pixels */
	float level_r; /* Black level for R pixels */
	float level_b; /* Black level for B pixels */
	float level_gb; /* Black level for GB pixels */
	uint color_bits;
	} CLBLCConfig;


	typedef struct
	{
	float r_gain;
	float gr_gain;
	float gb_gain;
	float b_gain;
	} CLWBConfig;

	inline int slm_pos (const int x, const int y)
	{
	return mad24 (y, SLM_X_SIZE, x);
	}

	inline void gamma_correct(float8 in_out, __global float table)
	{
	in_out->s0 = table[clamp(convert_int(in_out->s0 * 255.0f), 0, 255)];
	in_out->s1 = table[clamp(convert_int(in_out->s1 * 255.0f), 0, 255)];
	in_out->s2 = table[clamp(convert_int(in_out->s2 * 255.0f), 0, 255)];
	in_out->s3 = table[clamp(convert_int(in_out->s3 * 255.0f), 0, 255)];
	in_out->s4 = table[clamp(convert_int(in_out->s4 * 255.0f), 0, 255)];
	in_out->s5 = table[clamp(convert_int(in_out->s5 * 255.0f), 0, 255)];
	in_out->s6 = table[clamp(convert_int(in_out->s6 * 255.0f), 0, 255)];
	in_out->s7 = table[clamp(convert_int(in_out->s7 * 255.0f), 0, 255)];
	}

	inline float avg_float8 (float8 data)
	{
	return (data.s0 + data.s1 + data.s2 + data.s3 + data.s4 + data.s5 + data.s6 + data.s7) * 0.125f;
	}

	inline void stats_3a_calculate (
	__local float4 * slm_gr,
	__local float4 * slm_r,
	__local float4 * slm_b,
	__local float4 * slm_gb,
	__global ushort8 * stats_output,
	CLWBConfig *wb_config)
	{
	const int group_x_size = get_num_groups (0);
	const int group_id_x = get_group_id (0);
	const int group_id_y = get_group_id (1);

	const int l_id_x = get_local_id (0);
	const int l_id_y = get_local_id (1);
	const int l_size_x = get_local_size (0);
	const int stats_float4_x_count = STATS_3A_CELL_X_SIZE / 4;
	int count = stats_float4_x_count * STATS_3A_CELL_Y_SIZE / 4;

	int index = mad24 (l_id_y, l_size_x, l_id_x);
	int index_x = index % SLM_X_SIZE;
	int index_y = index / SLM_X_SIZE;

	if (mad24 (index_y, stats_float4_x_count, index_x % stats_float4_x_count) < count) {
	int pitch_count = count / stats_float4_x_count * SLM_X_SIZE;
	int index1 = index + pitch_count;
	int index2 = index1 + pitch_count;
	int index3 = index2 + pitch_count;
	slm_gr[index] = (slm_gr[index] + slm_gr[index1] + slm_gr[index2] + slm_gr[index3]) * 0.25f;
	slm_r[index] = (slm_r[index] + slm_r[index1] + slm_r[index2] + slm_r[index3]) * 0.25f;
	slm_b[index] = (slm_b[index] + slm_b[index1] + slm_b[index2] + slm_b[index3]) * 0.25f;
	slm_gb[index] = (slm_gb[index] + slm_gb[index1] + slm_gb[index2] + slm_gb[index3]) * 0.25f;
	}
	barrier (CLK_LOCAL_MEM_FENCE);

	if (index < SLM_X_SIZE / 2) {
	float result_gr, result_r, result_b, result_gb, avg_y;
	float8 tmp;
	tmp = ((__local float8*)slm_gr)[index];
	result_gr = avg_float8 (tmp);

	tmp = ((__local float8*)slm_r)[index];
	result_r = avg_float8 (tmp);

	tmp = ((__local float8*)slm_b)[index];
	result_b = avg_float8 (tmp);

	tmp = ((__local float8*)slm_gb)[index];
	result_gb = avg_float8 (tmp);

	int out_index = mad24 (mad24 (group_id_y, group_x_size, group_id_x),
	(GROUP_CELL_X_SIZE / STATS_3A_CELL_X_SIZE) * (GROUP_CELL_Y_SIZE / STATS_3A_CELL_Y_SIZE),
	index);

	#if STATS_BITS==8
	avg_y = mad ((result_gr * wb_config->gr_gain + result_gb * wb_config->gb_gain), 74.843f,
	mad (result_r * wb_config->r_gain, 76.245f, result_b * 29.070f));

	//ushort avg_y; avg_r; avg_gr; avg_gb; avg_b; valid_wb_count; f_value1; f_value2;
	stats_output[out_index] = (ushort8) (
	convert_ushort (convert_uchar_sat (avg_y)),
	convert_ushort (convert_uchar_sat (result_r * 255.0f)),
	convert_ushort (convert_uchar_sat (result_gr * 255.0f)),
	convert_ushort (convert_uchar_sat (result_gb * 255.0f)),
	convert_ushort (convert_uchar_sat (result_b * 255.0f)),
	STATS_3A_CELL_X_SIZE * STATS_3A_CELL_Y_SIZE,
	0,
	0);
	#elif STATS_BITS==12
	avg_y = mad ((result_gr * wb_config->gr_gain + result_gb * wb_config->gb_gain), 1201.883f,
	mad (result_r * wb_config->r_gain, 1224.405f, result_b * 466.830f));

	stats_output[out_index] = (ushort8) (
	convert_ushort (clamp (avg_y, 0.0f, 4095.0f)),
	convert_ushort (clamp (result_r * 4096.0f, 0.0f, 4095.0f)),
	convert_ushort (clamp (result_gr * 4096.0f, 0.0f, 4095.0f)),
	convert_ushort (clamp (result_gb * 4096.0f, 0.0f, 4095.0f)),
	convert_ushort (clamp (result_b * 4096.0f, 0.0f, 4095.0f)),
	STATS_3A_CELL_X_SIZE * STATS_3A_CELL_Y_SIZE,
	0,
	0);
	#else
	printf ("kernel 3a-stats error, wrong bit depth:%d\n", STATS_BITS);
	#endif
	}
	}


	__kernel void kernel_bayer_basic (
	#if ENABLE_IMAGE_2D_INPUT
	__read_only image2d_t input,
	#else
	__global const ushort8 *input,
	#endif
	uint input_aligned_width,
	__write_only image2d_t output,
	uint out_height,
	CLBLCConfig blc_config,
	CLWBConfig wb_config,
	__global float *gamma_table,
	__global ushort8 *stats_output
	)
	{
	int g_x = get_global_id (0);
	int g_y = get_global_id (1);

	const int l_x = get_local_id (0);
	const int l_y = get_local_id (1);
	const int l_x_size = get_local_size (0);
	const int l_y_size = get_local_size (1);
	const int group_id_x = get_group_id (0);
	const int group_id_y = get_group_id (1);

	sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE \| CLK_ADDRESS_NONE \| CLK_FILTER_NEAREST;

	int index = mad24 (l_y, l_x_size, l_x);
	int x_cell_start = (GROUP_CELL_X_SIZE / 4) * group_id_x;
	int y_cell_start = GROUP_CELL_Y_SIZE * group_id_y;
	int x, y;

	float blc_multiplier = (float)(1 << (16 - blc_config.color_bits));

	__local float4 slm_gr[SLM_X_SIZE * SLM_Y_SIZE], slm_r[SLM_X_SIZE * SLM_Y_SIZE], slm_b[SLM_X_SIZE * SLM_Y_SIZE], slm_gb[SLM_X_SIZE * SLM_Y_SIZE];

	for (; index < SLM_X_SIZE * SLM_Y_SIZE; index += l_x_size * l_y_size) {
	float8 line1;
	float8 line2;

	x = index % SLM_X_SIZE + x_cell_start;
	y = index / SLM_X_SIZE + y_cell_start;

	#if ENABLE_IMAGE_2D_INPUT
	line1 = convert_float8 (as_ushort8 (read_imageui(input, sampler, (int2)(x, y * 2)))) / 65536.0f;
	line2 = convert_float8 (as_ushort8 (read_imageui(input, sampler, (int2)(x, y * 2 + 1)))) / 65536.0f;
	#else
	line1 = convert_float8 (input [y * 2 * input_aligned_width + x]) / 65536.0f;
	line2 = convert_float8 (input [(y * 2 + 1) * input_aligned_width + x]) / 65536.0f;
	#endif

	float4 gr = mad (line1.even, blc_multiplier, - blc_config.level_gr);
	float4 r = mad (line1.odd, blc_multiplier, - blc_config.level_r);
	float4 b = mad (line2.even, blc_multiplier, - blc_config.level_b);
	float4 gb = mad (line2.odd, blc_multiplier, - blc_config.level_gb);

	slm_gr[index] = gr;
	slm_r[index] = r;
	slm_b[index] = b;
	slm_gb[index] = gb;
	}
	barrier(CLK_LOCAL_MEM_FENCE);

	float8 data_gr, data_r, data_b, data_gb;
	index = mad24 (l_y, l_x_size, l_x);
	x = mad24 (GROUP_CELL_X_SIZE / 8, group_id_x, index % (SLM_X_SIZE / 2));
	y = mad24 (GROUP_CELL_Y_SIZE, group_id_y, index / (SLM_X_SIZE / 2));

	data_gr = ((__local float8*)slm_gr)[index];
	data_gr = data_gr * wb_config.gr_gain;

	data_r = ((__local float8*)slm_r)[index];
	data_r = data_r * wb_config.r_gain;

	data_b = ((__local float8*)slm_b)[index];
	data_b = data_b * wb_config.b_gain;

	data_gb = ((__local float8*)slm_gb)[index];
	data_gb = data_gb * wb_config.gb_gain;

	#if ENABLE_GAMMA
	gamma_correct (&data_gr, gamma_table);
	gamma_correct (&data_r, gamma_table);
	gamma_correct (&data_b, gamma_table);
	gamma_correct (&data_gb, gamma_table);
	#endif

	#if 0
	if (x % 16 == 0 && y % 16 == 0) {
	uint8 value = convert_uint8(convert_uchar8_sat(data_gr * 255.0f));
	printf ("(x:%d, y:%d) (blc.bit:%d, level:%d) (wb.gr:%f)=> (%d, %d, %d, %d, %d, %d, %d, %d)\n",
	x * 8, y,
	blc_config.color_bits, convert_uint(blc_config.level_gr * 255.0f),
	wb_config.gr_gain,
	value.s0, value.s1, value.s2, value.s3, value.s4, value.s5, value.s6, value.s7);
	}
	#endif

	write_imageui (output, (int2)(x, y), as_uint4 (convert_ushort8 (data_gr * 65536.0f)));
	write_imageui (output, (int2)(x, y + out_height), as_uint4 (convert_ushort8 (data_r * 65536.0f)));
	write_imageui (output, (int2)(x, y + out_height * 2), as_uint4 (convert_ushort8 (data_b * 65536.0f)));
	write_imageui (output, (int2)(x, y + out_height * 3), as_uint4 (convert_ushort8 (data_gb * 65536.0f)));

	stats_3a_calculate (slm_gr, slm_r, slm_b, slm_gb, stats_output, &wb_config);
	}