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

 /*
  * function: kernel_newtonemapping
  *     implementation of tone mapping
  * input:    image2d_t as read only
  * output:   image2d_t as write only
  */

 #define WORK_ITEM_X_SIZE 8
 #define WORK_ITEM_Y_SIZE 8
 #define BLOCK_FACTOR 4

 __kernel void kernel_newtonemapping (
     __read_only image2d_t input, __write_only image2d_t output,
     __global float *y_max, __global float *y_avg, __global float *hist_leq,
     int image_width, int image_height)
 {
     int g_id_x = get_global_id (0);
     int g_id_y = get_global_id (1);

     int group_id_x = get_group_id(0);
     int group_id_y = get_group_id(1);

     int local_id_x = get_local_id(0);
     int local_id_y = get_local_id(1);

     int g_size_x = get_global_size (0);
     int g_size_y = get_global_size (1);

     int local_index = local_id_y * WORK_ITEM_X_SIZE + local_id_x;
     int row_per_block = image_height / BLOCK_FACTOR;
     int col_per_block = image_width / BLOCK_FACTOR;
     int row_block_id = g_id_y / row_per_block;
     int col_block_id = g_id_x * 4 / col_per_block;

     sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE | CLK_ADDRESS_CLAMP_TO_EDGE | CLK_FILTER_NEAREST;

     float4 src_data_Gr = read_imagef (input, sampler, (int2)(g_id_x, g_id_y));
     float4 src_data_R = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height));
     float4 src_data_B = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height * 2));
     float4 src_data_Gb = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height * 3));

     float4 src_data_G = (src_data_Gr + src_data_Gb) / 2;

     float4 src_y_data = 0.0f;
     src_y_data = mad(src_data_R, 0.299f, src_y_data);
     src_y_data = mad(src_data_G, 0.587f, src_y_data);
     src_y_data = mad(src_data_B, 0.114f, src_y_data);

     float4 dst_y_data;
     float4 d, wd, haleq, s, ws;
     float4 total_w = 0.0f;
     float4 total_haleq = 0.0f;

     float4 corrd_x = mad((float4)g_id_x, 4.0f, (float4)(0.0f, 1.0f, 2.0f, 3.0f));
     float4 src_y = mad(src_y_data, 65535.0f, 0.5f) / 16.0f;

     for(int i = 0; i < BLOCK_FACTOR; i++)
     {
         for(int j = 0; j < BLOCK_FACTOR; j++)
         {
             int center_x = mad24(col_per_block, j, col_per_block / 2);
             int center_y = mad24(row_per_block, i, row_per_block / 2);
             int start_index = mad24(i, BLOCK_FACTOR, j) * 4096;

             float4 dy = (float4)((g_id_y - center_y) * (g_id_y - center_y));
             float4 dx = corrd_x - (float4)center_x;

             d = mad(dx, dx, dy);

             d = sqrt(d) + 100.0f;
             //wd = 100.0f / (d + 100.0f);

             s = fabs(src_y_data - (float4)y_avg[mad24(i, BLOCK_FACTOR, j)]) / (float4)y_max[mad24(i, BLOCK_FACTOR, j)] + 1.0f;
             //ws = 1.0f / (s + 1.0f);

             float4 w = 100.0f / (d * s);
             //w = wd * ws;

             haleq.x = hist_leq[start_index + (int)src_y.x];
             haleq.y = hist_leq[start_index + (int)src_y.y];
             haleq.z = hist_leq[start_index + (int)src_y.z];
             haleq.w = hist_leq[start_index + (int)src_y.w];

             total_w = total_w + w;
             total_haleq = mad(haleq, w, total_haleq);
         }
     }

     dst_y_data = total_haleq / total_w;

     float4 gain = (dst_y_data + 0.0001f) / (src_y_data + 0.0001f);
     src_data_Gr = src_data_Gr * gain;
     src_data_R = src_data_R * gain;
     src_data_B = src_data_B * gain;
     src_data_Gb = src_data_Gb * gain;

     write_imagef(output, (int2)(g_id_x, g_id_y), src_data_Gr);
     write_imagef(output, (int2)(g_id_x, g_id_y + image_height), src_data_R);
     write_imagef(output, (int2)(g_id_x, g_id_y + image_height * 2), src_data_B);
     write_imagef(output, (int2)(g_id_x, g_id_y + image_height * 3), src_data_Gb);
 }
	/*
	* function: kernel_newtonemapping
	* implementation of tone mapping
	* input: image2d_t as read only
	* output: image2d_t as write only
	*/

	#define WORK_ITEM_X_SIZE 8
	#define WORK_ITEM_Y_SIZE 8
	#define BLOCK_FACTOR 4

	__kernel void kernel_newtonemapping (
	__read_only image2d_t input, __write_only image2d_t output,
	__global float y_max, __global float y_avg, __global float *hist_leq,
	int image_width, int image_height)
	{
	int g_id_x = get_global_id (0);
	int g_id_y = get_global_id (1);

	int group_id_x = get_group_id(0);
	int group_id_y = get_group_id(1);

	int local_id_x = get_local_id(0);
	int local_id_y = get_local_id(1);

	int g_size_x = get_global_size (0);
	int g_size_y = get_global_size (1);

	int local_index = local_id_y * WORK_ITEM_X_SIZE + local_id_x;
	int row_per_block = image_height / BLOCK_FACTOR;
	int col_per_block = image_width / BLOCK_FACTOR;
	int row_block_id = g_id_y / row_per_block;
	int col_block_id = g_id_x * 4 / col_per_block;

	sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE \| CLK_ADDRESS_CLAMP_TO_EDGE \| CLK_FILTER_NEAREST;

	float4 src_data_Gr = read_imagef (input, sampler, (int2)(g_id_x, g_id_y));
	float4 src_data_R = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height));
	float4 src_data_B = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height * 2));
	float4 src_data_Gb = read_imagef (input, sampler, (int2)(g_id_x, g_id_y + image_height * 3));

	float4 src_data_G = (src_data_Gr + src_data_Gb) / 2;

	float4 src_y_data = 0.0f;
	src_y_data = mad(src_data_R, 0.299f, src_y_data);
	src_y_data = mad(src_data_G, 0.587f, src_y_data);
	src_y_data = mad(src_data_B, 0.114f, src_y_data);

	float4 dst_y_data;
	float4 d, wd, haleq, s, ws;
	float4 total_w = 0.0f;
	float4 total_haleq = 0.0f;

	float4 corrd_x = mad((float4)g_id_x, 4.0f, (float4)(0.0f, 1.0f, 2.0f, 3.0f));
	float4 src_y = mad(src_y_data, 65535.0f, 0.5f) / 16.0f;

	for(int i = 0; i < BLOCK_FACTOR; i++)
	{
	for(int j = 0; j < BLOCK_FACTOR; j++)
	{
	int center_x = mad24(col_per_block, j, col_per_block / 2);
	int center_y = mad24(row_per_block, i, row_per_block / 2);
	int start_index = mad24(i, BLOCK_FACTOR, j) * 4096;

	float4 dy = (float4)((g_id_y - center_y) * (g_id_y - center_y));
	float4 dx = corrd_x - (float4)center_x;

	d = mad(dx, dx, dy);

	d = sqrt(d) + 100.0f;
	//wd = 100.0f / (d + 100.0f);

	s = fabs(src_y_data - (float4)y_avg[mad24(i, BLOCK_FACTOR, j)]) / (float4)y_max[mad24(i, BLOCK_FACTOR, j)] + 1.0f;
	//ws = 1.0f / (s + 1.0f);

	float4 w = 100.0f / (d * s);
	//w = wd * ws;

	haleq.x = hist_leq[start_index + (int)src_y.x];
	haleq.y = hist_leq[start_index + (int)src_y.y];
	haleq.z = hist_leq[start_index + (int)src_y.z];
	haleq.w = hist_leq[start_index + (int)src_y.w];

	total_w = total_w + w;
	total_haleq = mad(haleq, w, total_haleq);
	}
	}

	dst_y_data = total_haleq / total_w;

	float4 gain = (dst_y_data + 0.0001f) / (src_y_data + 0.0001f);
	src_data_Gr = src_data_Gr * gain;
	src_data_R = src_data_R * gain;
	src_data_B = src_data_B * gain;
	src_data_Gb = src_data_Gb * gain;

	write_imagef(output, (int2)(g_id_x, g_id_y), src_data_Gr);
	write_imagef(output, (int2)(g_id_x, g_id_y + image_height), src_data_R);
	write_imagef(output, (int2)(g_id_x, g_id_y + image_height * 2), src_data_B);
	write_imagef(output, (int2)(g_id_x, g_id_y + image_height * 3), src_data_Gb);
	}