opencv/modules/gpu/src/cuda/match_template.cu

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/*M///////////////////////////////////////////////////////////////////////////////////////
//
// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
//
// By downloading, copying, installing or using the software you agree to this license.
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// copy or use the software.
//
//
// License Agreement
// For Open Source Computer Vision Library
//
// Copyright (C) 2000-2008, Intel Corporation, all rights reserved.
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// Third party copyrights are property of their respective owners.
//
// Redistribution and use in source and binary forms, with or without modification,
// are permitted provided that the following conditions are met:
//
// * Redistribution's of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
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// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
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// and on any theory of liability, whether in contract, strict liability,
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#include "internal_shared.hpp"
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#include "opencv2/gpu/device/vecmath.hpp"
using namespace cv::gpu;
using namespace cv::gpu::device;
namespace cv { namespace gpu { namespace imgproc {
__device__ float sum(float v) { return v; }
__device__ float sum(float2 v) { return v.x + v.y; }
__device__ float sum(float3 v) { return v.x + v.y + v.z; }
__device__ float sum(float4 v) { return v.x + v.y + v.z + v.w; }
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__device__ float first(float v) { return v; }
__device__ float first(float2 v) { return v.x; }
__device__ float first(float3 v) { return v.x; }
__device__ float first(float4 v) { return v.x; }
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__device__ float mul(float a, float b) { return a * b; }
__device__ float2 mul(float2 a, float2 b) { return make_float2(a.x * b.x, a.y * b.y); }
__device__ float3 mul(float3 a, float3 b) { return make_float3(a.x * b.x, a.y * b.y, a.z * b.z); }
__device__ float4 mul(float4 a, float4 b) { return make_float4(a.x * b.x, a.y * b.y, a.z * b.z, a.w * b.w); }
__device__ float mul(uchar a, uchar b) { return a * b; }
__device__ float2 mul(uchar2 a, uchar2 b) { return make_float2(a.x * b.x, a.y * b.y); }
__device__ float3 mul(uchar3 a, uchar3 b) { return make_float3(a.x * b.x, a.y * b.y, a.z * b.z); }
__device__ float4 mul(uchar4 a, uchar4 b) { return make_float4(a.x * b.x, a.y * b.y, a.z * b.z, a.w * b.w); }
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__device__ float sub(float a, float b) { return a - b; }
__device__ float2 sub(float2 a, float2 b) { return make_float2(a.x - b.x, a.y - b.y); }
__device__ float3 sub(float3 a, float3 b) { return make_float3(a.x - b.x, a.y - b.y, a.z - b.z); }
__device__ float4 sub(float4 a, float4 b) { return make_float4(a.x - b.x, a.y - b.y, a.z - b.z, a.w - b.w); }
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__device__ float sub(uchar a, uchar b) { return a - b; }
__device__ float2 sub(uchar2 a, uchar2 b) { return make_float2(a.x - b.x, a.y - b.y); }
__device__ float3 sub(uchar3 a, uchar3 b) { return make_float3(a.x - b.x, a.y - b.y, a.z - b.z); }
__device__ float4 sub(uchar4 a, uchar4 b) { return make_float4(a.x - b.x, a.y - b.y, a.z - b.z, a.w - b.w); }
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template <typename T, int cn>
__global__ void matchTemplateNaiveKernel_CCORR(
int w, int h, const PtrStep image, const PtrStep templ,
DevMem2Df result)
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{
typedef typename TypeVec<T, cn>::vec_t Type;
typedef typename TypeVec<float, cn>::vec_t Typef;
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int x = blockDim.x * blockIdx.x + threadIdx.x;
int y = blockDim.y * blockIdx.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
Typef res = VecTraits<Typef>::all(0);
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for (int i = 0; i < h; ++i)
{
const Type* image_ptr = (const Type*)image.ptr(y + i);
const Type* templ_ptr = (const Type*)templ.ptr(i);
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for (int j = 0; j < w; ++j)
res = res + mul(image_ptr[x + j], templ_ptr[j]);
}
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result.ptr(y)[x] = sum(res);
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}
}
void matchTemplateNaive_CCORR_32F(const DevMem2D image, const DevMem2D templ,
DevMem2Df result, int cn)
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{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
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switch (cn)
{
case 1:
matchTemplateNaiveKernel_CCORR<float, 1><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 2:
matchTemplateNaiveKernel_CCORR<float, 2><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 3:
matchTemplateNaiveKernel_CCORR<float, 3><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 4:
matchTemplateNaiveKernel_CCORR<float, 4><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
}
cudaSafeCall( cudaGetLastError() );
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cudaSafeCall(cudaThreadSynchronize());
}
void matchTemplateNaive_CCORR_8U(const DevMem2D image, const DevMem2D templ,
DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
matchTemplateNaiveKernel_CCORR<uchar, 1><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 2:
matchTemplateNaiveKernel_CCORR<uchar, 2><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 3:
matchTemplateNaiveKernel_CCORR<uchar, 3><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 4:
matchTemplateNaiveKernel_CCORR<uchar, 4><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
template <typename T, int cn>
__global__ void matchTemplateNaiveKernel_SQDIFF(
int w, int h, const PtrStep image, const PtrStep templ,
DevMem2Df result)
{
typedef typename TypeVec<T, cn>::vec_t Type;
typedef typename TypeVec<float, cn>::vec_t Typef;
int x = blockDim.x * blockIdx.x + threadIdx.x;
int y = blockDim.y * blockIdx.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
Typef res = VecTraits<Typef>::all(0);
Typef delta;
for (int i = 0; i < h; ++i)
{
const Type* image_ptr = (const Type*)image.ptr(y + i);
const Type* templ_ptr = (const Type*)templ.ptr(i);
for (int j = 0; j < w; ++j)
{
delta = sub(image_ptr[x + j], templ_ptr[j]);
res = res + delta * delta;
}
}
result.ptr(y)[x] = sum(res);
}
}
void matchTemplateNaive_SQDIFF_32F(const DevMem2D image, const DevMem2D templ,
DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
matchTemplateNaiveKernel_SQDIFF<float, 1><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 2:
matchTemplateNaiveKernel_SQDIFF<float, 2><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 3:
matchTemplateNaiveKernel_SQDIFF<float, 3><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 4:
matchTemplateNaiveKernel_SQDIFF<float, 4><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
void matchTemplateNaive_SQDIFF_8U(const DevMem2D image, const DevMem2D templ,
DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
matchTemplateNaiveKernel_SQDIFF<uchar, 1><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 2:
matchTemplateNaiveKernel_SQDIFF<uchar, 2><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 3:
matchTemplateNaiveKernel_SQDIFF<uchar, 3><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
case 4:
matchTemplateNaiveKernel_SQDIFF<uchar, 4><<<grid, threads>>>(
templ.cols, templ.rows, image, templ, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
template <int cn>
__global__ void matchTemplatePreparedKernel_SQDIFF_8U(
int w, int h, const PtrStep_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result)
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{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
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float image_sqsum_ = (float)(
(image_sqsum.ptr(y + h)[(x + w) * cn] - image_sqsum.ptr(y)[(x + w) * cn]) -
(image_sqsum.ptr(y + h)[x * cn] - image_sqsum.ptr(y)[x * cn]));
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float ccorr = result.ptr(y)[x];
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result.ptr(y)[x] = image_sqsum_ - 2.f * ccorr + templ_sqsum;
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}
}
void matchTemplatePrepared_SQDIFF_8U(
int w, int h, const DevMem2D_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result, int cn)
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{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
matchTemplatePreparedKernel_SQDIFF_8U<1><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 2:
matchTemplatePreparedKernel_SQDIFF_8U<2><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 3:
matchTemplatePreparedKernel_SQDIFF_8U<3><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 4:
matchTemplatePreparedKernel_SQDIFF_8U<4><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
template <int cn>
__global__ void matchTemplatePreparedKernel_SQDIFF_NORMED_8U(
int w, int h, const PtrStep_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
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float image_sqsum_ = (float)(
(image_sqsum.ptr(y + h)[(x + w) * cn] - image_sqsum.ptr(y)[(x + w) * cn]) -
(image_sqsum.ptr(y + h)[x * cn] - image_sqsum.ptr(y)[x * cn]));
float ccorr = result.ptr(y)[x];
result.ptr(y)[x] = min(1.f, (image_sqsum_ - 2.f * ccorr + templ_sqsum) *
rsqrtf(image_sqsum_ * templ_sqsum));
}
}
void matchTemplatePrepared_SQDIFF_NORMED_8U(
int w, int h, const DevMem2D_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
matchTemplatePreparedKernel_SQDIFF_NORMED_8U<1><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 2:
matchTemplatePreparedKernel_SQDIFF_NORMED_8U<2><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 3:
matchTemplatePreparedKernel_SQDIFF_NORMED_8U<3><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
case 4:
matchTemplatePreparedKernel_SQDIFF_NORMED_8U<4><<<grid, threads>>>(
w, h, image_sqsum, templ_sqsum, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_8U(
int w, int h, float templ_sum_scale,
const PtrStep_<unsigned int> image_sum, DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_ = (float)(
(image_sum.ptr(y + h)[x + w] - image_sum.ptr(y)[x + w]) -
(image_sum.ptr(y + h)[x] - image_sum.ptr(y)[x]));
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float ccorr = result.ptr(y)[x];
result.ptr(y)[x] = ccorr - image_sum_ * templ_sum_scale;
}
}
void matchTemplatePrepared_CCOFF_8U(
int w, int h, const DevMem2D_<unsigned int> image_sum,
unsigned int templ_sum, DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
matchTemplatePreparedKernel_CCOFF_8U<<<grid, threads>>>(
w, h, (float)templ_sum / (w * h), image_sum, result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
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__global__ void matchTemplatePreparedKernel_CCOFF_8UC2(
int w, int h, float templ_sum_scale_r, float templ_sum_scale_g,
const PtrStep_<unsigned int> image_sum_r,
const PtrStep_<unsigned int> image_sum_g,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
result.ptr(y)[x] = ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g;
}
}
void matchTemplatePrepared_CCOFF_8UC2(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r,
const DevMem2D_<unsigned int> image_sum_g,
unsigned int templ_sum_r, unsigned int templ_sum_g,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
matchTemplatePreparedKernel_CCOFF_8UC2<<<grid, threads>>>(
w, h, (float)templ_sum_r / (w * h), (float)templ_sum_g / (w * h),
image_sum_r, image_sum_g, result);
cudaSafeCall( cudaGetLastError() );
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cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_8UC3(
int w, int h,
float templ_sum_scale_r,
float templ_sum_scale_g,
float templ_sum_scale_b,
const PtrStep_<unsigned int> image_sum_r,
const PtrStep_<unsigned int> image_sum_g,
const PtrStep_<unsigned int> image_sum_b,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float image_sum_b_ = (float)(
(image_sum_b.ptr(y + h)[x + w] - image_sum_b.ptr(y)[x + w]) -
(image_sum_b.ptr(y + h)[x] - image_sum_b.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
result.ptr(y)[x] = ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g
- image_sum_b_ * templ_sum_scale_b;
}
}
void matchTemplatePrepared_CCOFF_8UC3(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r,
const DevMem2D_<unsigned int> image_sum_g,
const DevMem2D_<unsigned int> image_sum_b,
unsigned int templ_sum_r,
unsigned int templ_sum_g,
unsigned int templ_sum_b,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
matchTemplatePreparedKernel_CCOFF_8UC3<<<grid, threads>>>(
w, h,
(float)templ_sum_r / (w * h),
(float)templ_sum_g / (w * h),
(float)templ_sum_b / (w * h),
image_sum_r, image_sum_g, image_sum_b, result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_8UC4(
int w, int h,
float templ_sum_scale_r,
float templ_sum_scale_g,
float templ_sum_scale_b,
float templ_sum_scale_a,
const PtrStep_<unsigned int> image_sum_r,
const PtrStep_<unsigned int> image_sum_g,
const PtrStep_<unsigned int> image_sum_b,
const PtrStep_<unsigned int> image_sum_a,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float image_sum_b_ = (float)(
(image_sum_b.ptr(y + h)[x + w] - image_sum_b.ptr(y)[x + w]) -
(image_sum_b.ptr(y + h)[x] - image_sum_b.ptr(y)[x]));
float image_sum_a_ = (float)(
(image_sum_a.ptr(y + h)[x + w] - image_sum_a.ptr(y)[x + w]) -
(image_sum_a.ptr(y + h)[x] - image_sum_a.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
result.ptr(y)[x] = ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g
- image_sum_b_ * templ_sum_scale_b
- image_sum_a_ * templ_sum_scale_a;
}
}
void matchTemplatePrepared_CCOFF_8UC4(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r,
const DevMem2D_<unsigned int> image_sum_g,
const DevMem2D_<unsigned int> image_sum_b,
const DevMem2D_<unsigned int> image_sum_a,
unsigned int templ_sum_r,
unsigned int templ_sum_g,
unsigned int templ_sum_b,
unsigned int templ_sum_a,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
matchTemplatePreparedKernel_CCOFF_8UC4<<<grid, threads>>>(
w, h,
(float)templ_sum_r / (w * h),
(float)templ_sum_g / (w * h),
(float)templ_sum_b / (w * h),
(float)templ_sum_a / (w * h),
image_sum_r, image_sum_g, image_sum_b, image_sum_a,
result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_NORMED_8U(
int w, int h, float weight,
float templ_sum_scale, float templ_sqsum_scale,
const PtrStep_<unsigned int> image_sum,
const PtrStep_<unsigned long long> image_sqsum,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float ccorr = result.ptr(y)[x];
float image_sum_ = (float)(
(image_sum.ptr(y + h)[x + w] - image_sum.ptr(y)[x + w]) -
(image_sum.ptr(y + h)[x] - image_sum.ptr(y)[x]));
float image_sqsum_ = (float)(
(image_sqsum.ptr(y + h)[x + w] - image_sqsum.ptr(y)[x + w]) -
(image_sqsum.ptr(y + h)[x] - image_sqsum.ptr(y)[x]));
result.ptr(y)[x] = (ccorr - image_sum_ * templ_sum_scale) *
rsqrtf(templ_sqsum_scale * max(1e-3f, image_sqsum_ - weight * image_sum_ * image_sum_));
}
}
void matchTemplatePrepared_CCOFF_NORMED_8U(
int w, int h, const DevMem2D_<unsigned int> image_sum,
const DevMem2D_<unsigned long long> image_sqsum,
unsigned int templ_sum, unsigned int templ_sqsum,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
float weight = 1.f / (w * h);
float templ_sum_scale = templ_sum * weight;
float templ_sqsum_scale = templ_sqsum - weight * templ_sum * templ_sum;
matchTemplatePreparedKernel_CCOFF_NORMED_8U<<<grid, threads>>>(
w, h, weight, templ_sum_scale, templ_sqsum_scale,
image_sum, image_sqsum, result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_NORMED_8UC2(
int w, int h, float weight,
float templ_sum_scale_r, float templ_sum_scale_g,
float templ_sqsum_scale,
const PtrStep_<unsigned int> image_sum_r, const PtrStep_<unsigned long long> image_sqsum_r,
const PtrStep_<unsigned int> image_sum_g, const PtrStep_<unsigned long long> image_sqsum_g,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sqsum_r_ = (float)(
(image_sqsum_r.ptr(y + h)[x + w] - image_sqsum_r.ptr(y)[x + w]) -
(image_sqsum_r.ptr(y + h)[x] - image_sqsum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float image_sqsum_g_ = (float)(
(image_sqsum_g.ptr(y + h)[x + w] - image_sqsum_g.ptr(y)[x + w]) -
(image_sqsum_g.ptr(y + h)[x] - image_sqsum_g.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
float rdenom = rsqrtf(templ_sqsum_scale * max(1e-3f, image_sqsum_r_ - weight * image_sum_r_ * image_sum_r_
+ image_sqsum_g_ - weight * image_sum_g_ * image_sum_g_));
result.ptr(y)[x] = (ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g) * rdenom;
}
}
void matchTemplatePrepared_CCOFF_NORMED_8UC2(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r, const DevMem2D_<unsigned long long> image_sqsum_r,
const DevMem2D_<unsigned int> image_sum_g, const DevMem2D_<unsigned long long> image_sqsum_g,
unsigned int templ_sum_r, unsigned int templ_sqsum_r,
unsigned int templ_sum_g, unsigned int templ_sqsum_g,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
float weight = 1.f / (w * h);
float templ_sum_scale_r = templ_sum_r * weight;
float templ_sum_scale_g = templ_sum_g * weight;
float templ_sqsum_scale = templ_sqsum_r - weight * templ_sum_r * templ_sum_r
+ templ_sqsum_g - weight * templ_sum_g * templ_sum_g;
matchTemplatePreparedKernel_CCOFF_NORMED_8UC2<<<grid, threads>>>(
w, h, weight,
templ_sum_scale_r, templ_sum_scale_g,
templ_sqsum_scale,
image_sum_r, image_sqsum_r,
image_sum_g, image_sqsum_g,
result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_NORMED_8UC3(
int w, int h, float weight,
float templ_sum_scale_r, float templ_sum_scale_g, float templ_sum_scale_b,
float templ_sqsum_scale,
const PtrStep_<unsigned int> image_sum_r, const PtrStep_<unsigned long long> image_sqsum_r,
const PtrStep_<unsigned int> image_sum_g, const PtrStep_<unsigned long long> image_sqsum_g,
const PtrStep_<unsigned int> image_sum_b, const PtrStep_<unsigned long long> image_sqsum_b,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sqsum_r_ = (float)(
(image_sqsum_r.ptr(y + h)[x + w] - image_sqsum_r.ptr(y)[x + w]) -
(image_sqsum_r.ptr(y + h)[x] - image_sqsum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float image_sqsum_g_ = (float)(
(image_sqsum_g.ptr(y + h)[x + w] - image_sqsum_g.ptr(y)[x + w]) -
(image_sqsum_g.ptr(y + h)[x] - image_sqsum_g.ptr(y)[x]));
float image_sum_b_ = (float)(
(image_sum_b.ptr(y + h)[x + w] - image_sum_b.ptr(y)[x + w]) -
(image_sum_b.ptr(y + h)[x] - image_sum_b.ptr(y)[x]));
float image_sqsum_b_ = (float)(
(image_sqsum_b.ptr(y + h)[x + w] - image_sqsum_b.ptr(y)[x + w]) -
(image_sqsum_b.ptr(y + h)[x] - image_sqsum_b.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
float rdenom = rsqrtf(templ_sqsum_scale * max(1e-3f, image_sqsum_r_ - weight * image_sum_r_ * image_sum_r_
+ image_sqsum_g_ - weight * image_sum_g_ * image_sum_g_
+ image_sqsum_b_ - weight * image_sum_b_ * image_sum_b_));
result.ptr(y)[x] = (ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g
- image_sum_b_ * templ_sum_scale_b) * rdenom;
}
}
void matchTemplatePrepared_CCOFF_NORMED_8UC3(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r, const DevMem2D_<unsigned long long> image_sqsum_r,
const DevMem2D_<unsigned int> image_sum_g, const DevMem2D_<unsigned long long> image_sqsum_g,
const DevMem2D_<unsigned int> image_sum_b, const DevMem2D_<unsigned long long> image_sqsum_b,
unsigned int templ_sum_r, unsigned int templ_sqsum_r,
unsigned int templ_sum_g, unsigned int templ_sqsum_g,
unsigned int templ_sum_b, unsigned int templ_sqsum_b,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
float weight = 1.f / (w * h);
float templ_sum_scale_r = templ_sum_r * weight;
float templ_sum_scale_g = templ_sum_g * weight;
float templ_sum_scale_b = templ_sum_b * weight;
float templ_sqsum_scale = templ_sqsum_r - weight * templ_sum_r * templ_sum_r
+ templ_sqsum_g - weight * templ_sum_g * templ_sum_g
+ templ_sqsum_b - weight * templ_sum_b * templ_sum_b;
matchTemplatePreparedKernel_CCOFF_NORMED_8UC3<<<grid, threads>>>(
w, h, weight,
templ_sum_scale_r, templ_sum_scale_g, templ_sum_scale_b,
templ_sqsum_scale,
image_sum_r, image_sqsum_r,
image_sum_g, image_sqsum_g,
image_sum_b, image_sqsum_b,
result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
__global__ void matchTemplatePreparedKernel_CCOFF_NORMED_8UC4(
int w, int h, float weight,
float templ_sum_scale_r, float templ_sum_scale_g, float templ_sum_scale_b,
float templ_sum_scale_a, float templ_sqsum_scale,
const PtrStep_<unsigned int> image_sum_r, const PtrStep_<unsigned long long> image_sqsum_r,
const PtrStep_<unsigned int> image_sum_g, const PtrStep_<unsigned long long> image_sqsum_g,
const PtrStep_<unsigned int> image_sum_b, const PtrStep_<unsigned long long> image_sqsum_b,
const PtrStep_<unsigned int> image_sum_a, const PtrStep_<unsigned long long> image_sqsum_a,
DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
float image_sum_r_ = (float)(
(image_sum_r.ptr(y + h)[x + w] - image_sum_r.ptr(y)[x + w]) -
(image_sum_r.ptr(y + h)[x] - image_sum_r.ptr(y)[x]));
float image_sqsum_r_ = (float)(
(image_sqsum_r.ptr(y + h)[x + w] - image_sqsum_r.ptr(y)[x + w]) -
(image_sqsum_r.ptr(y + h)[x] - image_sqsum_r.ptr(y)[x]));
float image_sum_g_ = (float)(
(image_sum_g.ptr(y + h)[x + w] - image_sum_g.ptr(y)[x + w]) -
(image_sum_g.ptr(y + h)[x] - image_sum_g.ptr(y)[x]));
float image_sqsum_g_ = (float)(
(image_sqsum_g.ptr(y + h)[x + w] - image_sqsum_g.ptr(y)[x + w]) -
(image_sqsum_g.ptr(y + h)[x] - image_sqsum_g.ptr(y)[x]));
float image_sum_b_ = (float)(
(image_sum_b.ptr(y + h)[x + w] - image_sum_b.ptr(y)[x + w]) -
(image_sum_b.ptr(y + h)[x] - image_sum_b.ptr(y)[x]));
float image_sqsum_b_ = (float)(
(image_sqsum_b.ptr(y + h)[x + w] - image_sqsum_b.ptr(y)[x + w]) -
(image_sqsum_b.ptr(y + h)[x] - image_sqsum_b.ptr(y)[x]));
float image_sum_a_ = (float)(
(image_sum_a.ptr(y + h)[x + w] - image_sum_a.ptr(y)[x + w]) -
(image_sum_a.ptr(y + h)[x] - image_sum_a.ptr(y)[x]));
float image_sqsum_a_ = (float)(
(image_sqsum_a.ptr(y + h)[x + w] - image_sqsum_a.ptr(y)[x + w]) -
(image_sqsum_a.ptr(y + h)[x] - image_sqsum_a.ptr(y)[x]));
float ccorr = result.ptr(y)[x];
float rdenom = rsqrtf(templ_sqsum_scale * max(1e-3f, image_sqsum_r_ - weight * image_sum_r_ * image_sum_r_
+ image_sqsum_g_ - weight * image_sum_g_ * image_sum_g_
+ image_sqsum_b_ - weight * image_sum_b_ * image_sum_b_
+ image_sqsum_a_ - weight * image_sum_a_ * image_sum_a_));
result.ptr(y)[x] = (ccorr - image_sum_r_ * templ_sum_scale_r
- image_sum_g_ * templ_sum_scale_g
- image_sum_b_ * templ_sum_scale_b
- image_sum_a_ * templ_sum_scale_a) * rdenom;
}
}
void matchTemplatePrepared_CCOFF_NORMED_8UC4(
int w, int h,
const DevMem2D_<unsigned int> image_sum_r, const DevMem2D_<unsigned long long> image_sqsum_r,
const DevMem2D_<unsigned int> image_sum_g, const DevMem2D_<unsigned long long> image_sqsum_g,
const DevMem2D_<unsigned int> image_sum_b, const DevMem2D_<unsigned long long> image_sqsum_b,
const DevMem2D_<unsigned int> image_sum_a, const DevMem2D_<unsigned long long> image_sqsum_a,
unsigned int templ_sum_r, unsigned int templ_sqsum_r,
unsigned int templ_sum_g, unsigned int templ_sqsum_g,
unsigned int templ_sum_b, unsigned int templ_sqsum_b,
unsigned int templ_sum_a, unsigned int templ_sqsum_a,
DevMem2Df result)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
float weight = 1.f / (w * h);
float templ_sum_scale_r = templ_sum_r * weight;
float templ_sum_scale_g = templ_sum_g * weight;
float templ_sum_scale_b = templ_sum_b * weight;
float templ_sum_scale_a = templ_sum_a * weight;
float templ_sqsum_scale = templ_sqsum_r - weight * templ_sum_r * templ_sum_r
+ templ_sqsum_g - weight * templ_sum_g * templ_sum_g
+ templ_sqsum_b - weight * templ_sum_b * templ_sum_b
+ templ_sqsum_a - weight * templ_sum_a * templ_sum_a;
matchTemplatePreparedKernel_CCOFF_NORMED_8UC4<<<grid, threads>>>(
w, h, weight,
templ_sum_scale_r, templ_sum_scale_g, templ_sum_scale_b, templ_sum_scale_a,
templ_sqsum_scale,
image_sum_r, image_sqsum_r,
image_sum_g, image_sqsum_g,
image_sum_b, image_sqsum_b,
image_sum_a, image_sqsum_a,
result);
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
template <int cn>
__global__ void normalizeKernel_8U(
int w, int h, const PtrStep_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result)
{
const int x = blockIdx.x * blockDim.x + threadIdx.x;
const int y = blockIdx.y * blockDim.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
2010-12-14 16:45:11 +08:00
float image_sqsum_ = (float)(
(image_sqsum.ptr(y + h)[(x + w) * cn] - image_sqsum.ptr(y)[(x + w) * cn]) -
(image_sqsum.ptr(y + h)[x * cn] - image_sqsum.ptr(y)[x * cn]));
result.ptr(y)[x] = result.ptr(y)[x] * rsqrtf(max(1.f, image_sqsum_) * templ_sqsum);
}
}
void normalize_8U(int w, int h, const DevMem2D_<unsigned long long> image_sqsum,
unsigned int templ_sqsum, DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
normalizeKernel_8U<1><<<grid, threads>>>(w, h, image_sqsum, templ_sqsum, result);
break;
case 2:
normalizeKernel_8U<2><<<grid, threads>>>(w, h, image_sqsum, templ_sqsum, result);
break;
case 3:
normalizeKernel_8U<3><<<grid, threads>>>(w, h, image_sqsum, templ_sqsum, result);
break;
case 4:
normalizeKernel_8U<4><<<grid, threads>>>(w, h, image_sqsum, templ_sqsum, result);
break;
}
cudaSafeCall( cudaGetLastError() );
cudaSafeCall(cudaThreadSynchronize());
}
template <int cn>
__global__ void extractFirstChannel_32F(const PtrStep image, DevMem2Df result)
{
typedef typename TypeVec<float, cn>::vec_t Typef;
int x = blockDim.x * blockIdx.x + threadIdx.x;
int y = blockDim.y * blockIdx.y + threadIdx.y;
if (x < result.cols && y < result.rows)
{
Typef val = ((const Typef*)image.ptr(y))[x];
result.ptr(y)[x] = first(val);
}
}
void extractFirstChannel_32F(const DevMem2D image, DevMem2Df result, int cn)
{
dim3 threads(32, 8);
dim3 grid(divUp(result.cols, threads.x), divUp(result.rows, threads.y));
switch (cn)
{
case 1:
extractFirstChannel_32F<1><<<grid, threads>>>(image, result);
break;
case 2:
extractFirstChannel_32F<2><<<grid, threads>>>(image, result);
break;
case 3:
extractFirstChannel_32F<3><<<grid, threads>>>(image, result);
break;
case 4:
extractFirstChannel_32F<4><<<grid, threads>>>(image, result);
break;
}
cudaSafeCall( cudaGetLastError() );
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cudaSafeCall(cudaThreadSynchronize());
}
}}}