diff options
| -rw-r--r-- | Core/regularisers_CPU/utils.c | 23 | ||||
| -rw-r--r-- | Core/regularisers_CPU/utils.h | 4 | ||||
| -rw-r--r-- | Wrappers/Matlab/demos/demoMatlab_3Ddenoise.m | 6 | ||||
| -rw-r--r-- | Wrappers/Matlab/demos/demoMatlab_denoise.m | 6 | ||||
| -rw-r--r-- | Wrappers/Matlab/mex_compile/regularisers_CPU/TV_energy.c | 9 |
5 files changed, 26 insertions, 22 deletions
diff --git a/Core/regularisers_CPU/utils.c b/Core/regularisers_CPU/utils.c index f21d383..ca5c59a 100644 --- a/Core/regularisers_CPU/utils.c +++ b/Core/regularisers_CPU/utils.c @@ -36,10 +36,11 @@ float copyIm(float *A, float *U, int dimX, int dimY, int dimZ) } */ -/* function that calculates TV energy (ROF model) - * min||\nabla u|| + 0.5*lambda*||u -u0||^2 +/* function that calculates TV energy + * type - 1: 2*lambda*min||\nabla u|| + ||u -u0||^2 + * type - 2: 2*lambda*min||\nabla u|| * */ -float TV_energy2D(float *U, float *U0, float *E_val, float lambda, int dimX, int dimY) +float TV_energy2D(float *U, float *U0, float *E_val, float lambda, int type, int dimX, int dimY) { int i, j, i1, j1, index; float NOMx_2, NOMy_2, E_Grad=0.0f, E_Data=0.0f; @@ -55,15 +56,16 @@ float TV_energy2D(float *U, float *U0, float *E_val, float lambda, int dimX, int /* Forward differences */ NOMx_2 = powf((float)(U[j1*dimX + i] - U[index]),2); /* x+ */ NOMy_2 = powf((float)(U[j*dimX + i1] - U[index]),2); /* y+ */ - E_Grad += sqrtf((float)(NOMx_2) + (float)(NOMy_2)); /* gradient term energy */ - E_Data += 0.5f * lambda*(powf((float)(U[index]-U0[index]),2)); /* fidelity term energy */ + E_Grad += 2.0f*lambda*sqrtf((float)(NOMx_2) + (float)(NOMy_2)); /* gradient term energy */ + E_Data += powf((float)(U[index]-U0[index]),2); /* fidelity term energy */ } } - E_val[0] = E_Grad + E_Data; + if (type == 1) E_val[0] = E_Grad + E_Data; + if (type == 2) E_val[0] = E_Grad; return *E_val; } -float TV_energy3D(float *U, float *U0, float *E_val, float lambda, int dimX, int dimY, int dimZ) +float TV_energy3D(float *U, float *U0, float *E_val, float lambda, int type, int dimX, int dimY, int dimZ) { int i, j, k, i1, j1, k1, index; float NOMx_2, NOMy_2, NOMz_2, E_Grad=0.0f, E_Data=0.0f; @@ -83,11 +85,12 @@ float TV_energy3D(float *U, float *U0, float *E_val, float lambda, int dimX, int NOMy_2 = powf((float)(U[(dimX*dimY)*k + j*dimX+i1] - U[index]),2); /* y+ */ NOMz_2 = powf((float)(U[(dimX*dimY)*k1 + j*dimX+i] - U[index]),2); /* z+ */ - E_Grad += sqrtf((float)(NOMx_2) + (float)(NOMy_2) + (float)(NOMz_2)); /* gradient term energy */ - E_Data += 0.5f * lambda*(powf((float)(U[index]-U0[index]),2)); /* fidelity term energy */ + E_Grad += 2.0f*lambda*sqrtf((float)(NOMx_2) + (float)(NOMy_2) + (float)(NOMz_2)); /* gradient term energy */ + E_Data += (powf((float)(U[index]-U0[index]),2)); /* fidelity term energy */ } } } - E_val[0] = E_Grad + E_Data; + if (type == 1) E_val[0] = E_Grad + E_Data; + if (type == 2) E_val[0] = E_Grad; return *E_val; } diff --git a/Core/regularisers_CPU/utils.h b/Core/regularisers_CPU/utils.h index fe08735..866bc01 100644 --- a/Core/regularisers_CPU/utils.h +++ b/Core/regularisers_CPU/utils.h @@ -28,8 +28,8 @@ limitations under the License. extern "C" { #endif CCPI_EXPORT float copyIm(float *A, float *U, int dimX, int dimY, int dimZ); -CCPI_EXPORT float TV_energy2D(float *U, float *U0, float *E_val, float lambda, int dimX, int dimY); -CCPI_EXPORT float TV_energy3D(float *U, float *U0, float *E_val, float lambda, int dimX, int dimY, int dimZ); +CCPI_EXPORT float TV_energy2D(float *U, float *U0, float *E_val, float lambda, int type, int dimX, int dimY); +CCPI_EXPORT float TV_energy3D(float *U, float *U0, float *E_val, float lambda, int type, int dimX, int dimY, int dimZ); #ifdef __cplusplus } #endif diff --git a/Wrappers/Matlab/demos/demoMatlab_3Ddenoise.m b/Wrappers/Matlab/demos/demoMatlab_3Ddenoise.m index 84889d7..5a54d18 100644 --- a/Wrappers/Matlab/demos/demoMatlab_3Ddenoise.m +++ b/Wrappers/Matlab/demos/demoMatlab_3Ddenoise.m @@ -21,7 +21,7 @@ fprintf('Denoise a volume using the ROF-TV model (CPU) \n'); tau_rof = 0.0025; % time-marching constant iter_rof = 300; % number of ROF iterations tic; u_rof = ROF_TV(single(vol3D), lambda_reg, iter_rof, tau_rof); toc; -energyfunc_val_rof = TV_energy(single(u_rof),single(vol3D),lambda_reg); % get energy function value +energyfunc_val_rof = TV_energy(single(u_rof),single(vol3D),lambda_reg, 1); % get energy function value figure; imshow(u_rof(:,:,15), [0 1]); title('ROF-TV denoised volume (CPU)'); %% % fprintf('Denoise a volume using the ROF-TV model (GPU) \n'); @@ -34,7 +34,7 @@ fprintf('Denoise a volume using the FGP-TV model (CPU) \n'); iter_fgp = 300; % number of FGP iterations epsil_tol = 1.0e-05; % tolerance tic; u_fgp = FGP_TV(single(vol3D), lambda_reg, iter_fgp, epsil_tol); toc; -energyfunc_val_fgp = TV_energy(single(u_fgp),single(vol3D),lambda_reg); % get energy function value +energyfunc_val_fgp = TV_energy(single(u_fgp),single(vol3D),lambda_reg, 1); % get energy function value figure; imshow(u_fgp(:,:,15), [0 1]); title('FGP-TV denoised volume (CPU)'); %% % fprintf('Denoise a volume using the FGP-TV model (GPU) \n'); @@ -47,7 +47,7 @@ fprintf('Denoise a volume using the SB-TV model (CPU) \n'); iter_sb = 150; % number of SB iterations epsil_tol = 1.0e-05; % tolerance tic; u_sb = SB_TV(single(vol3D), lambda_reg, iter_sb, epsil_tol); toc; -energyfunc_val_sb = TV_energy(single(u_sb),single(vol3D),lambda_reg); % get energy function value +energyfunc_val_sb = TV_energy(single(u_sb),single(vol3D),lambda_reg, 1); % get energy function value figure; imshow(u_sb(:,:,15), [0 1]); title('SB-TV denoised volume (CPU)'); %% % fprintf('Denoise a volume using the SB-TV model (GPU) \n'); diff --git a/Wrappers/Matlab/demos/demoMatlab_denoise.m b/Wrappers/Matlab/demos/demoMatlab_denoise.m index 526d21c..151a604 100644 --- a/Wrappers/Matlab/demos/demoMatlab_denoise.m +++ b/Wrappers/Matlab/demos/demoMatlab_denoise.m @@ -14,7 +14,7 @@ fprintf('Denoise using the ROF-TV model (CPU) \n'); tau_rof = 0.0025; % time-marching constant iter_rof = 750; % number of ROF iterations tic; u_rof = ROF_TV(single(u0), lambda_reg, iter_rof, tau_rof); toc; -energyfunc_val_rof = TV_energy(single(u_rof),single(u0),lambda_reg); % get energy function value +energyfunc_val_rof = TV_energy(single(u_rof),single(u0),lambda_reg, 1); % get energy function value figure; imshow(u_rof, [0 1]); title('ROF-TV denoised image (CPU)'); %% % fprintf('Denoise using the ROF-TV model (GPU) \n'); @@ -27,7 +27,7 @@ fprintf('Denoise using the FGP-TV model (CPU) \n'); iter_fgp = 1000; % number of FGP iterations epsil_tol = 1.0e-06; % tolerance tic; u_fgp = FGP_TV(single(u0), lambda_reg, iter_fgp, epsil_tol); toc; -energyfunc_val_fgp = TV_energy(single(u_fgp),single(u0),lambda_reg); % get energy function value +energyfunc_val_fgp = TV_energy(single(u_fgp),single(u0),lambda_reg, 1); % get energy function value figure; imshow(u_fgp, [0 1]); title('FGP-TV denoised image (CPU)'); %% @@ -41,7 +41,7 @@ fprintf('Denoise using the SB-TV model (CPU) \n'); iter_sb = 150; % number of SB iterations epsil_tol = 1.0e-06; % tolerance tic; u_sb = SB_TV(single(u0), lambda_reg, iter_sb, epsil_tol); toc; -energyfunc_val_sb = TV_energy(single(u_sb),single(u0),lambda_reg); % get energy function value +energyfunc_val_sb = TV_energy(single(u_sb),single(u0),lambda_reg, 1); % get energy function value figure; imshow(u_sb, [0 1]); title('SB-TV denoised image (CPU)'); %% % fprintf('Denoise using the SB-TV model (GPU) \n'); diff --git a/Wrappers/Matlab/mex_compile/regularisers_CPU/TV_energy.c b/Wrappers/Matlab/mex_compile/regularisers_CPU/TV_energy.c index 421bd4c..f9eb2ce 100644 --- a/Wrappers/Matlab/mex_compile/regularisers_CPU/TV_energy.c +++ b/Wrappers/Matlab/mex_compile/regularisers_CPU/TV_energy.c @@ -36,7 +36,7 @@ void mexFunction( int nrhs, const mxArray *prhs[]) { - int number_of_dims, dimX, dimY, dimZ; + int number_of_dims, dimX, dimY, dimZ, type; const int *dim_array; float *Input, *Input0, lambda; @@ -44,11 +44,12 @@ void mexFunction( dim_array = mxGetDimensions(prhs[0]); /*Handling Matlab input data*/ - if ((nrhs != 3)) mexErrMsgTxt("3 inputs: Two images or volumes of the same size required, estimated and the original (noisy), regularisation parameter"); + if ((nrhs != 4)) mexErrMsgTxt("4 inputs: Two images or volumes of the same size required, estimated and the original (noisy), regularisation parameter, type"); Input = (float *) mxGetData(prhs[0]); /* Denoised Image/volume */ Input0 = (float *) mxGetData(prhs[1]); /* Original (noisy) Image/volume */ lambda = (float) mxGetScalar(prhs[2]); /* regularisation parameter */ + type = (int) mxGetScalar(prhs[3]); /* type of energy */ if (mxGetClassID(prhs[0]) != mxSINGLE_CLASS) {mexErrMsgTxt("The input image must be in a single precision"); } if (mxGetClassID(prhs[1]) != mxSINGLE_CLASS) {mexErrMsgTxt("The input image must be in a single precision"); } @@ -61,9 +62,9 @@ void mexFunction( dimX = dim_array[0]; dimY = dim_array[1]; dimZ = dim_array[2]; if (number_of_dims == 2) { - TV_energy2D(Input, Input0, funcvalA, lambda, dimX, dimY); + TV_energy2D(Input, Input0, funcvalA, lambda, type, dimX, dimY); } if (number_of_dims == 3) { - TV_energy3D(Input, Input0, funcvalA, lambda, dimX, dimY, dimZ); + TV_energy3D(Input, Input0, funcvalA, lambda, type, dimX, dimY, dimZ); } } |