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

 /*
  * function: kernel_wavelet_haar_decomposition
  *     wavelet haar decomposition kernel
  * input:        input image data as read only
  * ll/hl/lh/hh:  wavelet decomposition image
  * layer:        wavelet decomposition layer
  * decomLevels:  wavelet decomposition levels
  */
 #ifndef WAVELET_DENOISE_Y
 #define WAVELET_DENOISE_Y 1
 #endif

 #ifndef WAVELET_DENOISE_UV
 #define WAVELET_DENOISE_UV 0
 #endif

 #ifndef WAVELET_BAYES_SHRINK
 #define WAVELET_BAYES_SHRINK 1
 #endif

 __kernel void kernel_wavelet_haar_decomposition (
     __read_only image2d_t input,
     __write_only image2d_t ll, __write_only image2d_t hl,
     __write_only image2d_t lh, __write_only image2d_t hh,
     int layer, int decomLevels,
     float hardThresh, float softThresh)
 {
     int x = get_global_id (0);
     int y = get_global_id (1);
     sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE | CLK_ADDRESS_CLAMP_TO_EDGE | CLK_FILTER_NEAREST;

     float8 line[2];
     line[0].lo = read_imagef(input, sampler, (int2)(2 * x, 2 * y));
     line[0].hi = read_imagef(input, sampler, (int2)(2 * x + 1, 2 * y));
     line[1].lo = read_imagef(input, sampler, (int2)(2 * x, 2 * y + 1));
     line[1].hi = read_imagef(input, sampler, (int2)(2 * x + 1, 2 * y + 1));

     // row transform
     float8 row_l;
     float8 row_h;
     row_l = (float8)(line[0].lo + line[1].lo, line[0].hi + line[1].hi) / 2.0f;
     row_h = (float8)(line[0].lo - line[1].lo, line[0].hi - line[1].hi) / 2.0f;

     float4 line_ll;
     float4 line_hl;
     float4 line_lh;
     float4 line_hh;

 #if WAVELET_DENOISE_Y
     // column transform
     line_ll = (row_l.odd + row_l.even) / 2.0f;
     line_hl = (row_l.odd - row_l.even) / 2.0f;
     line_lh = (row_h.odd + row_h.even) / 2.0f;
     line_hh = (row_h.odd - row_h.even) / 2.0f;
 #endif

 #if WAVELET_DENOISE_UV
     // U column transform
     line_ll.odd = (row_l.odd.odd + row_l.odd.even) / 2.0f;
     line_hl.odd = (row_l.odd.odd - row_l.odd.even) / 2.0f;
     line_lh.odd = (row_h.odd.odd + row_h.odd.even) / 2.0f;
     line_hh.odd = (row_h.odd.odd - row_h.odd.even) / 2.0f;

     // V column transform
     line_ll.even = (row_l.even.odd + row_l.even.even) / 2.0f;
     line_hl.even = (row_l.even.odd - row_l.even.even) / 2.0f;
     line_lh.even = (row_h.even.odd + row_h.even.even) / 2.0f;
     line_hh.even = (row_h.even.odd - row_h.even.even) / 2.0f;
 #endif

     write_imagef(ll, (int2)(x, y), line_ll);
     write_imagef(hl, (int2)(x, y), line_hl + 0.5f);
     write_imagef(lh, (int2)(x, y), line_lh + 0.5f);
     write_imagef(hh, (int2)(x, y), line_hh + 0.5f);
 }

 /*
  * function: kernel_wavelet_haar_reconstruction
  *     wavelet haar reconstruction kernel
  * output:      output wavelet reconstruction image
  * ll/hl/lh/hh: input wavelet transform data as read only
  * layer:       wavelet reconstruction layer
  * decomLevels: wavelet decomposition levels
  * threshold:   hard/soft denoise thresholding
  */

 __constant float uv_threshConst[5] = { 0.1659f, 0.06719f, 0.03343f, 0.01713f, 0.01043f };
 __constant float y_threshConst[5] = { 0.06129f, 0.027319f, 0.012643f, 0.006513f, 0.003443f };

 __kernel void kernel_wavelet_haar_reconstruction (
     __write_only image2d_t output,
     __read_only image2d_t ll, __read_only image2d_t hl,
     __read_only image2d_t lh, __read_only image2d_t hh,
     int layer, int decomLevels,
     float hardThresh, float softThresh)
 {
     int x = get_global_id (0);
     int y = get_global_id (1);
     sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE | CLK_ADDRESS_CLAMP_TO_EDGE | CLK_FILTER_NEAREST;

     float thresh = 0.0f;

     float4 line_ll;
     float4 line_hl;
     float4 line_lh;
     float4 line_hh;

     line_ll = read_imagef(ll, sampler, (int2)(x, y));
     line_hl = read_imagef(hl, sampler, (int2)(x, y)) - 0.5f;
     line_lh = read_imagef(lh, sampler, (int2)(x, y)) - 0.5f;
     line_hh = read_imagef(hh, sampler, (int2)(x, y)) - 0.5f;

 #if WAVELET_DENOISE_Y
     thresh = hardThresh * y_threshConst[layer - 1];
 #endif

 #if WAVELET_DENOISE_UV
     thresh = hardThresh * uv_threshConst[layer - 1];
 #endif

 #if !WAVELET_BAYES_SHRINK
     // thresholding
     line_hl = (line_hl < -thresh) ? line_hl + (thresh - thresh * softThresh) : line_hl;
     line_hl = (line_hl > thresh) ? line_hl - (thresh - thresh * softThresh) : line_hl;
     line_hl = (line_hl > -thresh && line_hl < thresh) ? line_hl * softThresh : line_hl;

     line_lh = (line_lh < -thresh) ? line_lh + (thresh - thresh * softThresh) : line_lh;
     line_lh = (line_lh > thresh) ? line_lh - (thresh - thresh * softThresh) : line_lh;
     line_lh = (line_lh > -thresh && line_lh < thresh) ? line_lh * softThresh : line_lh;

     line_hh = (line_hh < -thresh) ? line_hh + (thresh - thresh * softThresh) : line_hh;
     line_hh = (line_hh > thresh) ? line_hh - (thresh - thresh * softThresh) : line_hh;
     line_hh = (line_hh > -thresh && line_hh < thresh) ? line_hh * softThresh : line_hh;
 #endif

 #if WAVELET_DENOISE_Y
     // row reconstruction
     float8 row_l;
     float8 row_h;
     row_l = (float8)(line_ll + line_lh, line_hl + line_hh);
     row_h = (float8)(line_ll - line_lh, line_hl - line_hh);

     // column reconstruction
     float8 line[2];
     line[0].odd = row_l.lo + row_l.hi;
     line[0].even = row_l.lo - row_l.hi;
     line[1].odd = row_h.lo + row_h.hi;
     line[1].even = row_h.lo - row_h.hi;

     write_imagef(output, (int2)(2 * x, 2 * y), line[0].lo);
     write_imagef(output, (int2)(2 * x + 1, 2 * y), line[0].hi);
     write_imagef(output, (int2)(2 * x, 2 * y + 1), line[1].lo);
     write_imagef(output, (int2)(2 * x + 1, 2 * y + 1), line[1].hi);
 #endif

 #if WAVELET_DENOISE_UV
     // row reconstruction
     float8 row_l;
     float8 row_h;
     row_l = (float8)(line_ll + line_lh, line_hl + line_hh);
     row_h = (float8)(line_ll - line_lh, line_hl - line_hh);

     float8 line[2];

     // U column reconstruction
     line[0].odd.odd = row_l.lo.odd + row_l.hi.odd;
     line[0].odd.even = row_l.lo.odd - row_l.hi.odd;
     line[1].odd.odd = row_h.lo.odd + row_h.hi.odd;
     line[1].odd.even = row_h.lo.odd - row_h.hi.odd;

     // V column reconstruction
     line[0].even.odd = row_l.lo.even + row_l.hi.even;
     line[0].even.even = row_l.lo.even - row_l.hi.even;
     line[1].even.odd = row_h.lo.even + row_h.hi.even;
     line[1].even.even = row_h.lo.even - row_h.hi.even;

     write_imagef(output, (int2)(2 * x, 2 * y), line[0].lo);
     write_imagef(output, (int2)(2 * x + 1, 2 * y), line[0].hi);
     write_imagef(output, (int2)(2 * x, 2 * y + 1), line[1].lo);
     write_imagef(output, (int2)(2 * x + 1, 2 * y + 1), line[1].hi);
 #endif
 }
	/*
	* function: kernel_wavelet_haar_decomposition
	* wavelet haar decomposition kernel
	* input: input image data as read only
	* ll/hl/lh/hh: wavelet decomposition image
	* layer: wavelet decomposition layer
	* decomLevels: wavelet decomposition levels
	*/
	#ifndef WAVELET_DENOISE_Y
	#define WAVELET_DENOISE_Y 1
	#endif

	#ifndef WAVELET_DENOISE_UV
	#define WAVELET_DENOISE_UV 0
	#endif

	#ifndef WAVELET_BAYES_SHRINK
	#define WAVELET_BAYES_SHRINK 1
	#endif

	__kernel void kernel_wavelet_haar_decomposition (
	__read_only image2d_t input,
	__write_only image2d_t ll, __write_only image2d_t hl,
	__write_only image2d_t lh, __write_only image2d_t hh,
	int layer, int decomLevels,
	float hardThresh, float softThresh)
	{
	int x = get_global_id (0);
	int y = get_global_id (1);
	sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE \| CLK_ADDRESS_CLAMP_TO_EDGE \| CLK_FILTER_NEAREST;

	float8 line[2];
	line[0].lo = read_imagef(input, sampler, (int2)(2 * x, 2 * y));
	line[0].hi = read_imagef(input, sampler, (int2)(2 * x + 1, 2 * y));
	line[1].lo = read_imagef(input, sampler, (int2)(2 * x, 2 * y + 1));
	line[1].hi = read_imagef(input, sampler, (int2)(2 * x + 1, 2 * y + 1));

	// row transform
	float8 row_l;
	float8 row_h;
	row_l = (float8)(line[0].lo + line[1].lo, line[0].hi + line[1].hi) / 2.0f;
	row_h = (float8)(line[0].lo - line[1].lo, line[0].hi - line[1].hi) / 2.0f;

	float4 line_ll;
	float4 line_hl;
	float4 line_lh;
	float4 line_hh;

	#if WAVELET_DENOISE_Y
	// column transform
	line_ll = (row_l.odd + row_l.even) / 2.0f;
	line_hl = (row_l.odd - row_l.even) / 2.0f;
	line_lh = (row_h.odd + row_h.even) / 2.0f;
	line_hh = (row_h.odd - row_h.even) / 2.0f;
	#endif

	#if WAVELET_DENOISE_UV
	// U column transform
	line_ll.odd = (row_l.odd.odd + row_l.odd.even) / 2.0f;
	line_hl.odd = (row_l.odd.odd - row_l.odd.even) / 2.0f;
	line_lh.odd = (row_h.odd.odd + row_h.odd.even) / 2.0f;
	line_hh.odd = (row_h.odd.odd - row_h.odd.even) / 2.0f;

	// V column transform
	line_ll.even = (row_l.even.odd + row_l.even.even) / 2.0f;
	line_hl.even = (row_l.even.odd - row_l.even.even) / 2.0f;
	line_lh.even = (row_h.even.odd + row_h.even.even) / 2.0f;
	line_hh.even = (row_h.even.odd - row_h.even.even) / 2.0f;
	#endif

	write_imagef(ll, (int2)(x, y), line_ll);
	write_imagef(hl, (int2)(x, y), line_hl + 0.5f);
	write_imagef(lh, (int2)(x, y), line_lh + 0.5f);
	write_imagef(hh, (int2)(x, y), line_hh + 0.5f);
	}

	/*
	* function: kernel_wavelet_haar_reconstruction
	* wavelet haar reconstruction kernel
	* output: output wavelet reconstruction image
	* ll/hl/lh/hh: input wavelet transform data as read only
	* layer: wavelet reconstruction layer
	* decomLevels: wavelet decomposition levels
	* threshold: hard/soft denoise thresholding
	*/

	__constant float uv_threshConst[5] = { 0.1659f, 0.06719f, 0.03343f, 0.01713f, 0.01043f };
	__constant float y_threshConst[5] = { 0.06129f, 0.027319f, 0.012643f, 0.006513f, 0.003443f };

	__kernel void kernel_wavelet_haar_reconstruction (
	__write_only image2d_t output,
	__read_only image2d_t ll, __read_only image2d_t hl,
	__read_only image2d_t lh, __read_only image2d_t hh,
	int layer, int decomLevels,
	float hardThresh, float softThresh)
	{
	int x = get_global_id (0);
	int y = get_global_id (1);
	sampler_t sampler = CLK_NORMALIZED_COORDS_FALSE \| CLK_ADDRESS_CLAMP_TO_EDGE \| CLK_FILTER_NEAREST;

	float thresh = 0.0f;

	float4 line_ll;
	float4 line_hl;
	float4 line_lh;
	float4 line_hh;

	line_ll = read_imagef(ll, sampler, (int2)(x, y));
	line_hl = read_imagef(hl, sampler, (int2)(x, y)) - 0.5f;
	line_lh = read_imagef(lh, sampler, (int2)(x, y)) - 0.5f;
	line_hh = read_imagef(hh, sampler, (int2)(x, y)) - 0.5f;

	#if WAVELET_DENOISE_Y
	thresh = hardThresh * y_threshConst[layer - 1];
	#endif

	#if WAVELET_DENOISE_UV
	thresh = hardThresh * uv_threshConst[layer - 1];
	#endif

	#if !WAVELET_BAYES_SHRINK
	// thresholding
	line_hl = (line_hl < -thresh) ? line_hl + (thresh - thresh * softThresh) : line_hl;
	line_hl = (line_hl > thresh) ? line_hl - (thresh - thresh * softThresh) : line_hl;
	line_hl = (line_hl > -thresh && line_hl < thresh) ? line_hl * softThresh : line_hl;

	line_lh = (line_lh < -thresh) ? line_lh + (thresh - thresh * softThresh) : line_lh;
	line_lh = (line_lh > thresh) ? line_lh - (thresh - thresh * softThresh) : line_lh;
	line_lh = (line_lh > -thresh && line_lh < thresh) ? line_lh * softThresh : line_lh;

	line_hh = (line_hh < -thresh) ? line_hh + (thresh - thresh * softThresh) : line_hh;
	line_hh = (line_hh > thresh) ? line_hh - (thresh - thresh * softThresh) : line_hh;
	line_hh = (line_hh > -thresh && line_hh < thresh) ? line_hh * softThresh : line_hh;
	#endif

	#if WAVELET_DENOISE_Y
	// row reconstruction
	float8 row_l;
	float8 row_h;
	row_l = (float8)(line_ll + line_lh, line_hl + line_hh);
	row_h = (float8)(line_ll - line_lh, line_hl - line_hh);

	// column reconstruction
	float8 line[2];
	line[0].odd = row_l.lo + row_l.hi;
	line[0].even = row_l.lo - row_l.hi;
	line[1].odd = row_h.lo + row_h.hi;
	line[1].even = row_h.lo - row_h.hi;

	write_imagef(output, (int2)(2 * x, 2 * y), line[0].lo);
	write_imagef(output, (int2)(2 * x + 1, 2 * y), line[0].hi);
	write_imagef(output, (int2)(2 * x, 2 * y + 1), line[1].lo);
	write_imagef(output, (int2)(2 * x + 1, 2 * y + 1), line[1].hi);
	#endif

	#if WAVELET_DENOISE_UV
	// row reconstruction
	float8 row_l;
	float8 row_h;
	row_l = (float8)(line_ll + line_lh, line_hl + line_hh);
	row_h = (float8)(line_ll - line_lh, line_hl - line_hh);

	float8 line[2];

	// U column reconstruction
	line[0].odd.odd = row_l.lo.odd + row_l.hi.odd;
	line[0].odd.even = row_l.lo.odd - row_l.hi.odd;
	line[1].odd.odd = row_h.lo.odd + row_h.hi.odd;
	line[1].odd.even = row_h.lo.odd - row_h.hi.odd;

	// V column reconstruction
	line[0].even.odd = row_l.lo.even + row_l.hi.even;
	line[0].even.even = row_l.lo.even - row_l.hi.even;
	line[1].even.odd = row_h.lo.even + row_h.hi.even;
	line[1].even.even = row_h.lo.even - row_h.hi.even;

	write_imagef(output, (int2)(2 * x, 2 * y), line[0].lo);
	write_imagef(output, (int2)(2 * x + 1, 2 * y), line[0].hi);
	write_imagef(output, (int2)(2 * x, 2 * y + 1), line[1].lo);
	write_imagef(output, (int2)(2 * x + 1, 2 * y + 1), line[1].hi);
	#endif
	}