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Fast F-transform added.
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New method added plus minor fixes

Tests finalization

Whitespace fix.

Warning fixes.

Whitespace warning.
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Pavel Vlasanek committed May 16, 2017
1 parent fa94c16 commit aceaa03
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Showing 5 changed files with 370 additions and 5 deletions.
18 changes: 18 additions & 0 deletions modules/fuzzy/include/opencv2/fuzzy/fuzzy_F0_math.hpp
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Expand Up @@ -121,6 +121,24 @@ namespace ft
*/
CV_EXPORTS_W int FT02D_iteration(InputArray matrix, InputArray kernel, OutputArray output, InputArray mask, OutputArray maskOutput, bool firstStop);

/** @brief Sligtly less accurate version of F0-transfrom computation optimized for higher speed. The methods counts with linear basic function.
@param matrix Input 3 channels matrix.
@param radius Radius of the **LINEAR** basic function.
@param output Output array.
This function computes F-transfrom and inverse F-transfotm using linear basic function in one step. It is ~10 times faster than **FT02D_process** method.
*/
CV_EXPORTS_W void FT02D_FL_process(InputArray matrix, const int radius, OutputArray output);

/** @brief Sligtly less accurate version of F0-transfrom computation optimized for higher speed. The methods counts with linear basic function.
@param matrix Input 3 channels matrix.
@param radius Radius of the **LINEAR** basic function.
@param output Output array.
This function computes F-transfrom and inverse F-transfotm using linear basic function in one step. It is ~9 times faster then **FT02D_process** method and more accurate than **FT02D_FL_process** method.
*/
CV_EXPORTS_W void FT02D_FL_process_float(InputArray matrix, const int radius, OutputArray output);

//! @}
}
}
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4 changes: 2 additions & 2 deletions modules/fuzzy/include/opencv2/fuzzy/fuzzy_image.hpp
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Expand Up @@ -56,7 +56,7 @@ namespace ft
/** @brief Creates kernel from basic functions.
@param A Basic function used in axis **x**.
@param B Basic function used in axis **y**.
@param kernel Final 32-b kernel derived from **A** and **B**.
@param kernel Final 32-bit kernel derived from **A** and **B**.
@param chn Number of kernel channels.
The function creates kernel usable for latter fuzzy image processing.
Expand All @@ -67,7 +67,7 @@ namespace ft
@param function Function type could be one of the following:
- **LINEAR** Linear basic function.
@param radius Radius of the basic function.
@param kernel Final 32-b kernel.
@param kernel Final 32-bit kernel.
@param chn Number of kernel channels.
The function creates kernel from predefined functions.
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6 changes: 3 additions & 3 deletions modules/fuzzy/samples/fuzzy_inpainting.cpp
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Expand Up @@ -38,9 +38,9 @@ int main(void)
Mat I = imread("input.png");

// Various masks
Mat mask1 = imread("mask1.png");
Mat mask2 = imread("mask2.png");
Mat mask3 = imread("mask3.png");
Mat mask1 = imread("mask1.png", IMREAD_GRAYSCALE);
Mat mask2 = imread("mask2.png", IMREAD_GRAYSCALE);
Mat mask3 = imread("mask3.png", IMREAD_GRAYSCALE);

// Apply the damage
Mat input1, input2, input3;
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256 changes: 256 additions & 0 deletions modules/fuzzy/src/fuzzy_F0_math.cpp
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Expand Up @@ -43,6 +43,262 @@

using namespace cv;

void ft::FT02D_FL_process(InputArray matrix, const int radius, OutputArray output)
{
CV_Assert(matrix.channels() == 3);

int borderPadding = 2 * radius + 1;
Mat imagePadded;

copyMakeBorder(matrix, imagePadded, radius, borderPadding, radius, borderPadding, BORDER_CONSTANT, Scalar(0));

Mat channel[3];
split(imagePadded, channel);

uchar *im_r = channel[2].data;
uchar *im_g = channel[1].data;
uchar *im_b = channel[0].data;

int width = imagePadded.cols;
int height = imagePadded.rows;
int n_width = width / radius + 1;
int n_height = height / radius + 1;

std::vector<uchar> c_r(n_width * n_height);
std::vector<uchar> c_g(n_width * n_height);
std::vector<uchar> c_b(n_width * n_height);

int sum_r, sum_g, sum_b, num, c_wei;
int c_pos, pos, pos2, wy;
int cy = 0;
float num_f;

std::vector<int> wei(radius + 1);

for (int i = 0; i <= radius; i++)
{
wei[i] = radius - i;
}

for (int y = radius; y < height - radius; y += radius)
{
c_pos = cy;

for (int x = radius; x < width - radius; x += radius)
{
num = sum_r = sum_g = sum_b = 0;

for (int y1 = y - radius; y1 <= y + radius; y1++)
{
pos = y1 * width;
wy = wei[abs(y1 - y)];

for (int x1 = x - radius; x1 <= x + radius; x1++)
{
c_wei = wei[abs(x1 - x)] * wy;
pos2 = pos + x1;
sum_r += im_r[pos2] * c_wei;
sum_g += im_g[pos2] * c_wei;
sum_b += im_b[pos2] * c_wei;
num += c_wei;
}
}

num_f = 1.0f / (float)num;

c_r[c_pos] = (uchar)cvRound(sum_r * num_f);
c_g[c_pos] = (uchar)cvRound(sum_g * num_f);
c_b[c_pos] = (uchar)cvRound(sum_b * num_f);

c_pos++;
}

cy += n_width;
}

int p1, p2, p3, p4, yw, w1, w2, w3, w4, lx, ly, lx1, ly1, pos_iFT;
float num_iFT;

int output_height = matrix.rows();
int output_width = matrix.cols();

uchar *img_r = new uchar[output_height * output_width];
uchar *img_g = new uchar[output_height * output_width];
uchar *img_b = new uchar[output_height * output_width];

for (int y = 0; y < output_height; y++)
{
ly1 = (y % radius);
ly = radius - ly1;
yw = y / radius * n_width;
pos_iFT = y * output_width;

for (int x = 0; x < output_width; x++)
{
lx1 = (x % radius);
lx = radius - lx1;

p1 = x / radius + yw;
p2 = p1 + 1;
p3 = p1 + n_width;
p4 = p3 + 1;

w1 = lx * ly;
w2 = lx1 * ly;
w3 = lx * ly1;
w4 = lx1 * ly1;

num_iFT = 1.0f / (float)(w1 + w2 + w3 + w4);

img_r[pos_iFT] = (uchar)((c_r[p1] * w1 + c_r[p2] * w2 + c_r[p3] * w3 + c_r[p4] * w4) * num_iFT);
img_g[pos_iFT] = (uchar)((c_g[p1] * w1 + c_g[p2] * w2 + c_g[p3] * w3 + c_g[p4] * w4) * num_iFT);
img_b[pos_iFT] = (uchar)((c_b[p1] * w1 + c_b[p2] * w2 + c_b[p3] * w3 + c_b[p4] * w4) * num_iFT);

pos_iFT++;
}
}

Mat compR(output_height, output_width, CV_8UC1, img_r);
Mat compG(output_height, output_width, CV_8UC1, img_g);
Mat compB(output_height, output_width, CV_8UC1, img_b);

std::vector<Mat> oComp;

oComp.push_back(compB);
oComp.push_back(compG);
oComp.push_back(compR);

merge(oComp, output);
}

void ft::FT02D_FL_process_float(InputArray matrix, const int radius, OutputArray output)
{
CV_Assert(matrix.channels() == 3);

int borderPadding = 2 * radius + 1;
Mat imagePadded;

copyMakeBorder(matrix, imagePadded, radius, borderPadding, radius, borderPadding, BORDER_CONSTANT, Scalar(0));

Mat channel[3];
split(imagePadded, channel);

uchar *im_r = channel[2].data;
uchar *im_g = channel[1].data;
uchar *im_b = channel[0].data;

int width = imagePadded.cols;
int height = imagePadded.rows;
int n_width = width / radius + 1;
int n_height = height / radius + 1;

std::vector<float> c_r(n_width * n_height);
std::vector<float> c_g(n_width * n_height);
std::vector<float> c_b(n_width * n_height);

int sum_r, sum_g, sum_b, num, c_wei;
int c_pos, pos, pos2, wy;
int cy = 0;
float num_f;

std::vector<int> wei(radius + 1);

for (int i = 0; i <= radius; i++)
{
wei[i] = radius - i;
}

for (int y = radius; y < height - radius; y += radius)
{
c_pos = cy;

for (int x = radius; x < width - radius; x += radius)
{
num = sum_r = sum_g = sum_b = 0;

for (int y1 = y - radius; y1 <= y + radius; y1++)
{
pos = y1 * width;
wy = wei[abs(y1 - y)];

for (int x1 = x - radius; x1 <= x + radius; x1++)
{
c_wei = wei[abs(x1 - x)] * wy;
pos2 = pos + x1;
sum_r += im_r[pos2] * c_wei;
sum_g += im_g[pos2] * c_wei;
sum_b += im_b[pos2] * c_wei;
num += c_wei;
}
}

num_f = 1.0f / (float)num;

c_r[c_pos] = sum_r * num_f;
c_g[c_pos] = sum_g * num_f;
c_b[c_pos] = sum_b * num_f;

c_pos++;
}

cy += n_width;
}

int p1, p2, p3, p4, yw, w1, w2, w3, w4, lx, ly, lx1, ly1, pos_iFT;
float num_iFT;

int output_height = matrix.rows();
int output_width = matrix.cols();

float *img_r = new float[output_height * output_width];
float *img_g = new float[output_height * output_width];
float *img_b = new float[output_height * output_width];

for (int y = 0; y < output_height; y++)
{
ly1 = (y % radius);
ly = radius - ly1;
yw = y / radius * n_width;
pos_iFT = y * output_width;

for (int x = 0; x < output_width; x++)
{
lx1 = (x % radius);
lx = radius - lx1;

p1 = x / radius + yw;
p2 = p1 + 1;
p3 = p1 + n_width;
p4 = p3 + 1;

w1 = lx * ly;
w2 = lx1 * ly;
w3 = lx * ly1;
w4 = lx1 * ly1;

num_iFT = 1.0f / (float)(w1 + w2 + w3 + w4);

img_r[pos_iFT] = (c_r[p1] * w1 + c_r[p2] * w2 + c_r[p3] * w3 + c_r[p4] * w4) * num_iFT;
img_g[pos_iFT] = (c_g[p1] * w1 + c_g[p2] * w2 + c_g[p3] * w3 + c_g[p4] * w4) * num_iFT;
img_b[pos_iFT] = (c_b[p1] * w1 + c_b[p2] * w2 + c_b[p3] * w3 + c_b[p4] * w4) * num_iFT;

pos_iFT++;
}
}

Mat compR(output_height, output_width, CV_32FC1, img_r);
Mat compG(output_height, output_width, CV_32FC1, img_g);
Mat compB(output_height, output_width, CV_32FC1, img_b);

std::vector<Mat> oComp;

oComp.push_back(compB);
oComp.push_back(compG);
oComp.push_back(compR);

merge(oComp, output);
}

void ft::FT02D_components(InputArray matrix, InputArray kernel, OutputArray components, InputArray mask)
{
CV_Assert(matrix.channels() == kernel.channels() && mask.channels() == 1);
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