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#ifndef STIM_SCALARFIELD_H
#define STIM_SCALARFIELD_H
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#include "../math/rect.h"
#include "../math/complex.h"
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#include "../math/fft.h"
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#ifdef CUDA_FOUND
#include "../cuda/crop.cuh"
#endif
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namespace stim{
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template<typename T>
__global__ void cuda_abs(T* img, stim::complex<T>* field, size_t N){
size_t i = blockIdx.x * blockDim.x + threadIdx.x;
if(i >= N) return;
img[i] = field[i].abs();
}
template<typename T>
__global__ void cuda_real(T* img, stim::complex<T>* field, size_t N){
size_t i = blockIdx.x * blockDim.x + threadIdx.x;
if(i >= N) return;
img[i] = field[i].real();
}
template<typename T>
__global__ void cuda_imag(T* img, stim::complex<T>* field, size_t N){
size_t i = blockIdx.x * blockDim.x + threadIdx.x;
if(i >= N) return;
img[i] = field[i].imag();
}
template<typename T>
__global__ void cuda_intensity(T* img, stim::complex<T>* field, size_t N){
size_t i = blockIdx.x * blockDim.x + threadIdx.x;
if(i >= N) return;
img[i] = pow(field[i].abs(), 2);
}
template<typename T>
__global__ void cuda_sum_intensity(T* img, stim::complex<T>* field, size_t N){
size_t i = blockIdx.x * blockDim.x + threadIdx.x;
if(i >= N) return;
img[i] += pow(field[i].abs(), 2);
}
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/// Perform a k-space transform of a scalar field (FFT). The given field has a width of x and the calculated momentum space has a
/// width of kx (in radians).
/// @param K is a pointer to the output array of all plane waves in the field
/// @param kx is the width of the frame in momentum space
/// @param ky is the height of the frame in momentum space
/// @param E is the field to be transformed
/// @param x is the width of the field in the spatial domain
/// @param y is the height of the field in the spatial domain
/// @param nx is the number of pixels representing the field in the x (and kx) direction
/// @param ny is the number of pixels representing the field in the y (and ky) direction
template<typename T>
void cpu_scalar_to_kspace(stim::complex<T>* K, T& kx, T& ky, stim::complex<T>* E, T x, T y, size_t nx, size_t ny){
kx = stim::TAU * nx / x; //calculate the width of the momentum space
ky = stim::TAU * ny / y;
stim::complex<T>* dev_FFT;
HANDLE_ERROR( cudaMalloc(&dev_FFT, sizeof(stim::complex<T>) * nx * ny) ); //allocate space on the CUDA device for the output array
stim::complex<T>* dev_E;
HANDLE_ERROR( cudaMalloc(&dev_E, sizeof(stim::complex<T>) * nx * ny) ); //allocate space for the field
HANDLE_ERROR( cudaMemcpy(dev_E, E, sizeof(stim::complex<T>) * nx * ny, cudaMemcpyHostToDevice) ); //copy the field to GPU memory
cufftResult result;
cufftHandle plan;
result = cufftPlan2d(&plan, nx, ny, CUFFT_C2C);
if(result != CUFFT_SUCCESS){
std::cout<<"Error creating cuFFT plan."<<std::endl;
exit(1);
}
result = cufftExecC2C(plan, (cufftComplex*)dev_E, (cufftComplex*)dev_FFT, CUFFT_FORWARD);
if(result != CUFFT_SUCCESS){
std::cout<<"Error using cuFFT to perform a forward Fourier transform of the field."<<std::endl;
exit(1);
}
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cufftDestroy(plan);
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stim::complex<T>* fft = (stim::complex<T>*) malloc(sizeof(stim::complex<T>) * nx * ny);
HANDLE_ERROR( cudaMemcpy(fft, dev_FFT, sizeof(stim::complex<T>) * nx * ny, cudaMemcpyDeviceToHost) );
stim::cpu_fftshift(K, fft, nx, ny);
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HANDLE_ERROR( cudaFree(dev_FFT) ); //free GPU memory
HANDLE_ERROR( cudaFree(dev_E) );
free(fft); //free CPU memory
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}
template<typename T>
void cpu_scalar_from_kspace(stim::complex<T>* E, T& x, T& y, stim::complex<T>* K, T kx, T ky, size_t nx, size_t ny){
x = stim::TAU * nx / kx; //calculate the width of the momentum space
y = stim::TAU * ny / ky;
stim::complex<T>* fft = (stim::complex<T>*) malloc(sizeof(stim::complex<T>) * nx * ny);
stim::cpu_ifftshift(fft, K, nx, ny);
//memcpy(fft, K, sizeof(stim::complex<T>) * nx * ny);
stim::complex<T>* dev_FFT;
HANDLE_ERROR( cudaMalloc(&dev_FFT, sizeof(stim::complex<T>) * nx * ny) ); //allocate space on the CUDA device for the output array
HANDLE_ERROR( cudaMemcpy(dev_FFT, fft, sizeof(stim::complex<T>) * nx * ny, cudaMemcpyHostToDevice) ); //copy the field to GPU memory
stim::complex<T>* dev_E;
HANDLE_ERROR( cudaMalloc(&dev_E, sizeof(stim::complex<T>) * nx * ny) ); //allocate space for the field
cufftResult result;
cufftHandle plan;
result = cufftPlan2d(&plan, nx, ny, CUFFT_C2C);
if(result != CUFFT_SUCCESS){
std::cout<<"Error creating cuFFT plan."<<std::endl;
exit(1);
}
result = cufftExecC2C(plan, (cufftComplex*)dev_FFT, (cufftComplex*)dev_E, CUFFT_INVERSE);
if(result != CUFFT_SUCCESS){
std::cout<<"Error using cuFFT to perform a forward Fourier transform of the field."<<std::endl;
exit(1);
}
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cufftDestroy(plan);
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HANDLE_ERROR( cudaMemcpy(E, dev_E, sizeof(stim::complex<T>) * nx * ny, cudaMemcpyDeviceToHost) );
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HANDLE_ERROR( cudaFree(dev_FFT) ); //free GPU memory
HANDLE_ERROR( cudaFree(dev_E) );
free(fft); //free CPU memory
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}
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/// Propagate a field slice along its orthogonal direction by a given distance z
/// @param Enew is the resulting propogated field
/// @param E is the field to be propogated
/// @param sx is the size of the field in the lateral x direction
/// @param sy is the size of the field in the lateral y direction
/// @param z is the distance to be propagated
/// @param k is the wavenumber 2*pi/lambda
/// @param nx is the number of samples in the field along the lateral x direction
/// @param ny is the number of samples in the field along the lateral y direction
template<typename T>
void cpu_scalar_propagate(stim::complex<T>* Enew, stim::complex<T>* E, T sx, T sy, T z, T k, size_t nx, size_t ny){
stim::complex<T>* K = (stim::complex<T>*) malloc( sizeof(stim::complex<T>) * nx * ny );
T Kx, Ky; //width and height in k space
cpu_scalar_to_kspace(K, Kx, Ky, E ,sx, sy, nx, ny);
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//T* mag = (T*) malloc( sizeof(T) * nx * ny );
//stim::abs(mag, K, nx * ny);
//stim::cpu2image<float>(mag, "kspace_pre_shift.bmp", nx, ny, stim::cmBrewer);
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size_t kxi, kyi;
size_t i;
T kx, kx_sq, ky, ky_sq, k_sq;
T kz;
stim::complex<T> shift;
T min_kx = -Kx / 2;
T dkx = Kx / (nx);
T min_ky = -Ky / 2;
T dky = Ky / (ny);
for(kyi = 0; kyi < ny; kyi++){ //for each plane wave in the ky direction
for(kxi = 0; kxi < nx; kxi++){ //for each plane wave in the ky direction
i = kyi * nx + kxi;
kx = min_kx + kxi * dkx; //calculate the position of the current plane wave
ky = min_ky + kyi * dky;
kx_sq = kx * kx;
ky_sq = ky * ky;
k_sq = k*k;
if(kx_sq + ky_sq < k_sq){
kz = sqrt(k_sq - kx_sq - ky_sq); //estimate kz using the Fresnel approximation
shift = -exp(stim::complex<T>(0, kz * z));
K[i] *= shift;
K[i] /= (nx*ny); //normalize the DFT
}
else{
K[i] = 0;
}
}
}
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//stim::abs(mag, K, nx * ny);
//stim::cpu2image<float>(mag, "kspace_post_shift.bmp", nx, ny, stim::cmBrewer);
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cpu_scalar_from_kspace(Enew, sx, sy, K, Kx, Ky, nx, ny);
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free(K);
}
template<typename T>
void gpu_scalar_propagate(stim::complex<T>* Enew, stim::complex<T>* E, T sx, T sy, T z, T k, size_t nx, size_t ny){
size_t field_bytes = sizeof(stim::complex<T>) * nx * ny;
stim::complex<T>* host_E = (stim::complex<T>*) malloc( field_bytes);
HANDLE_ERROR( cudaMemcpy(host_E, E, field_bytes, cudaMemcpyDeviceToHost) );
stim::complex<T>* host_Enew = (stim::complex<T>*) malloc(field_bytes);
cpu_scalar_propagate(host_Enew, host_E, sx, sy, z, k, nx, ny);
HANDLE_ERROR( cudaMemcpy(Enew, host_Enew, field_bytes, cudaMemcpyHostToDevice) );
free(host_E);
free(host_Enew);
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}
/// Apply a lowpass filter to a field slice
/// @param Enew is the resulting propogated field
/// @param E is the field to be propogated
/// @param sx is the size of the field in the lateral x direction
/// @param sy is the size of the field in the lateral y direction
/// @param highest is the highest spatial frequency that can pass through the filter
/// @param nx is the number of samples in the field along the lateral x direction
/// @param ny is the number of samples in the field along the lateral y direction
template<typename T>
void cpu_scalar_lowpass(stim::complex<T>* Enew, stim::complex<T>* E, T sx, T sy, T highest, size_t nx, size_t ny){
stim::complex<T>* K = (stim::complex<T>*) malloc( sizeof(stim::complex<T>) * nx * ny );
T Kx, Ky; //width and height in k space
cpu_scalar_to_kspace(K, Kx, Ky, E ,sx, sy, nx, ny);
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//T* mag = (T*) malloc( sizeof(T) * nx * ny );
//stim::abs(mag, K, nx * ny);
//stim::cpu2image<float>(mag, "kspace_pre_lowpass.bmp", nx, ny, stim::cmBrewer);
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size_t kxi, kyi;
size_t i;
T kx, kx_sq, ky, ky_sq, k_sq;
T kz;
stim::complex<T> shift;
T min_kx = -Kx / 2;
T dkx = Kx / (nx);
T min_ky = -Ky / 2;
T dky = Ky / (ny);
T highest_sq = highest * highest;
for(kyi = 0; kyi < ny; kyi++){ //for each plane wave in the ky direction
for(kxi = 0; kxi < nx; kxi++){ //for each plane wave in the ky direction
i = kyi * nx + kxi;
kx = min_kx + kxi * dkx; //calculate the position of the current plane wave
ky = min_ky + kyi * dky;
kx_sq = kx * kx;
ky_sq = ky * ky;
if(kx_sq + ky_sq > highest_sq){
K[i] = 0;
}
else
K[i] /= nx * ny; //normalize the DFT
}
}
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//stim::abs(mag, K, nx * ny);
//stim::cpu2image<float>(mag, "kspace_post_lowpass.bmp", nx, ny, stim::cmBrewer);
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cpu_scalar_from_kspace(Enew, sx, sy, K, Kx, Ky, nx, ny);
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free(K);
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}
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enum locationType {CPUmem, GPUmem};
/// Class represents a scalar optical field.
/// In general, this class is designed to operate between the CPU and GPU. So, make sure all functions have an option to create the output on either.
/// The field is stored *either* on the GPU or host memory, but not both. This enforces that there can't be different copies of the same field.
/// This class is designed to be included in all of the other scalar optics classes, allowing them to render output data so make sure to keep it general and compatible.
template<typename T>
class scalarfield : public rect<T>{
protected:
stim::complex<T>* E;
size_t R[2];
locationType loc;
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using rect<T>::X;
using rect<T>::Y;
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T* p[3]; //scalar position for each point in E
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/// Convert the field to a k-space representation (do an FFT)
void to_kspace(T& kx, T& ky){
cpu_scalar_to_kspace(E, kx, ky, E, X.len(), Y.len(), R[0], R[1]);
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}
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void from_kspace(){
kx = stim::TAU * R[0] / X.len(); //calculate the width of the momentum space
ky = stim::TAU * R[1] / Y.len();
T x, y;
cpu_scalar_from_kspace(E, x, y, E, kx, ky, R[0], R[1]);
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}
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public:
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/// Returns the number of values in the field
CUDA_CALLABLE size_t size(){
return R[0] * R[1];
}
CUDA_CALLABLE size_t grid_bytes(){
return sizeof(stim::complex<T>) * R[0] * R[1];
}
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scalarfield(size_t X, size_t Y, T size = 1, T z_pos = 0) : rect<T>::rect(size, z_pos){
R[0] = X; //set the field resolution
R[1] = Y;
E = (stim::complex<T>*) malloc(grid_bytes()); //allocate in CPU memory
memset(E, 0, grid_bytes());
loc = CPUmem;
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p[0] = p[1] = p[2] = NULL; //set the position vector to NULL
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}
~scalarfield(){
if(loc == CPUmem) free(E);
else cudaFree(E);
}
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/// Calculates the distance between points on the grid
T spacing(){
T du = rect<T>::X.len() / R[0];
T dv = rect<T>::Y.len() / R[1];
return min<T>(du, dv);
}
/// Copy the field array to the GPU, if it isn't already there
void to_gpu(){
if(loc == GPUmem) return;
else{
stim::complex<T>* dev_E;
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HANDLE_ERROR( cudaMalloc(&dev_E, grid_bytes()) ); //allocate GPU memory
HANDLE_ERROR( cudaMemcpy(dev_E, E, grid_bytes(), cudaMemcpyHostToDevice) ); //copy the field to the GPU
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free(E); //free the CPU memory
E = dev_E; //swap pointers
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if(p[0]){
size_t meshgrid_bytes = size() * sizeof(T); //calculate the number of bytes in each meshgrid
T* dev_X; //allocate variables to store the device meshgrid
T* dev_Y;
T* dev_Z;
HANDLE_ERROR( cudaMalloc(&dev_X, meshgrid_bytes) ); //allocate space for the meshgrid on the device
HANDLE_ERROR( cudaMalloc(&dev_Y, meshgrid_bytes) );
HANDLE_ERROR( cudaMalloc(&dev_Z, meshgrid_bytes) );
HANDLE_ERROR( cudaMemcpy(dev_X, p[0], meshgrid_bytes, cudaMemcpyHostToDevice) ); //copy from the host to the device
HANDLE_ERROR( cudaMemcpy(dev_Y, p[1], meshgrid_bytes, cudaMemcpyHostToDevice) );
HANDLE_ERROR( cudaMemcpy(dev_Z, p[2], meshgrid_bytes, cudaMemcpyHostToDevice) );
free(p[0]); //free device memory
free(p[1]);
free(p[2]);
p[0] = dev_X; //swap in the new pointers to device memory
p[1] = dev_Y;
p[2] = dev_Z;
}
loc = GPUmem; //set the location flag
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}
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}
/// Copy the field array to the CPU, if it isn't already there
void to_cpu(){
if(loc == CPUmem) return;
else{
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stim::complex<T>* host_E = (stim::complex<T>*) malloc(grid_bytes()); //allocate space in main memory
HANDLE_ERROR( cudaMemcpy(host_E, E, grid_bytes(), cudaMemcpyDeviceToHost) ); //copy from GPU to CPU
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HANDLE_ERROR( cudaFree(E) ); //free device memory
E = host_E; //swap pointers
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//copy a meshgrid has been created
if(p[0]){
size_t meshgrid_bytes = size() * sizeof(T); //move X to the CPU
T* host_X = (T*) malloc( meshgrid_bytes );
T* host_Y = (T*) malloc( meshgrid_bytes );
T* host_Z = (T*) malloc( meshgrid_bytes );
HANDLE_ERROR( cudaMemcpy(host_X, p[0], meshgrid_bytes, cudaMemcpyDeviceToHost) );
HANDLE_ERROR( cudaMemcpy(host_Y, p[1], meshgrid_bytes, cudaMemcpyDeviceToHost) );
HANDLE_ERROR( cudaMemcpy(host_Z, p[2], meshgrid_bytes, cudaMemcpyDeviceToHost) );
HANDLE_ERROR( cudaFree(p[0]) );
HANDLE_ERROR( cudaFree(p[1]) );
HANDLE_ERROR( cudaFree(p[2]) );
p[0] = host_X;
p[1] = host_Y;
p[2] = host_Z;
}
loc = CPUmem;
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}
}
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bool gpu(){
if(loc == GPUmem) return true;
else return false;
}
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/// Propagate the field along its orthogonal direction by a distance d
void propagate(T d, T k){
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if(loc == CPUmem){
cpu_scalar_propagate(E, E, X.len(), Y.len(), d, k, R[0], R[1]);
}
else{
gpu_scalar_propagate(E, E, X.len(), Y.len(), d, k, R[0], R[1]);
}
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}
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/// Apply a low pass filter preserving all frequencies lower than or equal to "highest"
// @param highest is the highest frequency passed
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void lowpass(T highest){
cpu_scalar_lowpass(E, E, X.len(), Y.len(), highest, R[0], R[1]);
}
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/// Crop an image based on a given padding parameter (crop out the center)
void crop(size_t padding, stim::scalarfield<T>& cropped){
size_t Cx = R[0] / (2 * padding + 1); //calculate the size of the cropped image based on the padding value
size_t Cy = R[1] / (2 * padding + 1);
if(cropped.R[0] != Cx || cropped.R[1] != Cy){
std::cout<<"Error: cropped field resolution ("<<cropped.R[0]<<" x "<<cropped.R[1]<<") does not match the required resolution ("<<Cx<<" x "<<Cy<<")."<<std::endl;
exit(1);
}
if(loc == CPUmem){
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cropped.to_cpu(); //make sure that the cropped image is on the CPU
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size_t x, y;
size_t sx, sy, si, di;
for(y = 0; y < Cy; y++){
sy = y + Cy * padding; //calculate the y-index into the source image
for(x = 0; x < Cx; x++){
sx = x + Cx * padding; //calculate the x-index into the source image
si = sy * R[0] + sx; //calculate the 1D index into the source image
di = y * Cx + x;
cropped.E[di] = E[si];
}
}
}
else{
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cropped.to_gpu(); //make sure that the cropped image is also on the GPU
gpu_crop2d<stim::complex<T>>(cropped.E, E, R[0], R[1], Cx * padding, Cy * padding, Cx, Cy);
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}
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std::string str(){
std::stringstream ss;
ss<<rect<T>::str()<<std::endl;
ss<<"[ "<<R[0]<<" x "<<R[1]<<" ]"<<std::endl;
ss<<"location: ";
if(loc == CPUmem) ss<<"CPU";
else ss<<"GPU";
ss<<endl;
return ss.str();
}
stim::complex<T>* ptr(){
return E;
}
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T* x(){ return p[0]; }
T* y(){ return p[1]; }
T* z(){ return p[2]; }
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/// Evaluate the cartesian coordinates of each point in the field. The resulting arrays are allocated in the same memory where the field is stored.
void meshgrid(T* X, T* Y, T* Z, locationType location){
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//size_t array_size = sizeof(T) * R[0] * R[1];
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if(location == CPUmem){
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T du = (T)1.0 / (R[0] - 1); //calculate the spacing between points in the grid
T dv = (T)1.0 / (R[1] - 1);
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size_t ui, vi, i;
stim::vec3<T> p;
for(vi = 0; vi < R[1]; vi++){
i = vi * R[0];
for(ui = 0; ui < R[0]; ui++){
p = rect<T>::p(ui * du, vi * dv);
X[i] = p[0];
Y[i] = p[1];
Z[i] = p[2];
i++;
}
}
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//stim::cpu2image(X, "X.bmp", R[0], R[1], stim::cmBrewer);
//stim::cpu2image(Y, "Y.bmp", R[0], R[1], stim::cmBrewer);
//stim::cpu2image(Z, "Z.bmp", R[0], R[1], stim::cmBrewer);
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}
else{
std::cout<<"GPU allocation of a meshgrid isn't supported yet. You'll have to write kernels to do the calculation.";
exit(1);
}
}
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/// Create a local meshgrid
void meshgrid(){
if(p[0]) return; //if the p[0] value is not NULL, a meshgrid has already been created
if(loc == CPUmem){
p[0] = (T*) malloc( size() * sizeof(T) );
p[1] = (T*) malloc( size() * sizeof(T) );
p[2] = (T*) malloc( size() * sizeof(T) );
}
else{
std::cout<<"GPUmem meshgrid isn't implemented yet."<<std::endl;
exit(1);
}
meshgrid(p[0], p[1], p[2], loc);
}
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//clear the field, setting all values to zero
void clear(){
if(loc == GPUmem)
HANDLE_ERROR(cudaMemset(E, 0, grid_bytes()));
else
memset(E, 0, grid_bytes());
}
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void image(std::string filename, stim::complexComponentType type = complexMag, stim::colormapType cmap = stim::cmBrewer){
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if(loc == GPUmem){
T* image;
HANDLE_ERROR( cudaMalloc(&image, sizeof(T) * size()) );
int threads = stim::maxThreadsPerBlock(); //get the maximum number of threads per block for the CUDA device
dim3 blocks( R[0] * R[1] / threads + 1 ); //create a 1D array of blocks
switch(type){
case complexMag:
cuda_abs<T><<< blocks, threads >>>(image, E, size());
break;
case complexReal:
cuda_real<T><<< blocks, threads >>>(image, E, size());
break;
case complexImaginary:
cuda_imag<T><<< blocks, threads >>>(image, E, size());
break;
case complexIntensity:
cuda_intensity<T><<< blocks, threads >>>(image, E, size());
break;
}
stim::gpu2image<T>(image, filename, R[0], R[1], stim::cmBrewer);
HANDLE_ERROR( cudaFree(image) );
}
else{
T* image = (T*) malloc( sizeof(T) * size() ); //allocate space for the real image
switch(type){ //get the specified component from the complex value
case complexMag:
stim::abs(image, E, size());
break;
case complexReal:
stim::real(image, E, size());
break;
case complexImaginary:
stim::imag(image, E, size());
break;
case complexIntensity:
stim::intensity(image, E, size());
break;
}
stim::cpu2image(image, filename, R[0], R[1], cmap); //save the resulting image
free(image); //free the real image
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}
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}
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void image(T* img, stim::complexComponentType type = complexMag){
if(loc == GPUmem) to_cpu(); //if the field is in the GPU, move it to the CPU
switch(type){ //get the specified component from the complex value
case complexMag:
stim::abs(img, E, size());
break;
case complexReal:
stim::real(img, E, size());
break;
case complexImaginary:
stim::imag(img, E, size());
break;
case complexIntensity:
stim::intensity(img, E, size());
break;
}
//stim::cpu2image(image, filename, R[0], R[1], cmap); //save the resulting image
//free(image); //free the real image
}
//adds the field intensity to the output array (useful for calculating detector response to incoherent fields)
void intensity(T* out){
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if(loc == GPUmem){
//T* image;
//HANDLE_ERROR( cudaMalloc(&image, sizeof(T) * size()) );
int threads = stim::maxThreadsPerBlock(); //get the maximum number of threads per block for the CUDA device
dim3 blocks( R[0] * R[1] / threads + 1 ); //create a 1D array of blocks
cuda_sum_intensity<T><<< blocks, threads >>>(out, E, size());
}
else{
T* image = (T*) malloc( sizeof(T) * size() ); //allocate space for the real image
stim::intensity(image, E, size()); //calculate the intensity
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size_t N = size(); //calculate the number of elements in the field
for(size_t n = 0; n < N; n++) //for each point in the field
out[n] += image[n]; //add the field intensity to the output image
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free(image); //free the temporary intensity image
}
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}
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}; //end class scalarfield
}
//stream insertion operator
template<typename T>
std::ostream& operator<<(std::ostream& os, stim::scalarfield<T>& rhs){
os<<rhs.str();
return os;
}
#endif
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