cuda-samples/Samples/fluidsGLES/fluidsGLES_kernels.h

/*
 * Copyright 1993-2015 NVIDIA Corporation.  All rights reserved.
 *
 * Please refer to the NVIDIA end user license agreement (EULA) associated
 * with this source code for terms and conditions that govern your use of
 * this software. Any use, reproduction, disclosure, or distribution of
 * this software and related documentation outside the terms of the EULA
 * is strictly prohibited.
 *
 */
#ifndef __STABLEFLUIDS_KERNELS_CUH_
#define __STABLEFLUIDS_KERNELS_CUH_

// Vector data type used to velocity and force fields
typedef float2 cData;

void setupTexture(int x, int y);
void updateTexture(cData *data, size_t w, size_t h, size_t pitch);
void deleteTexture(void);

// This method adds constant force vectors to the velocity field
// stored in 'v' according to v(x,t+1) = v(x,t) + dt * f.
__global__ void
addForces_k(cData *v, int dx, int dy, int spx, int spy, float fx, float fy, int r, size_t pitch);

// This method performs the velocity advection step, where we
// trace velocity vectors back in time to update each grid cell.
// That is, v(x,t+1) = v(p(x,-dt),t). Here we perform bilinear
// interpolation in the velocity space.
__global__ void
advectVelocity_k(cData *v, float *vx, float *vy,
                 int dx, int pdx, int dy, float dt, int lb, cudaTextureObject_t tex);

// This method performs velocity diffusion and forces mass conservation
// in the frequency domain. The inputs 'vx' and 'vy' are complex-valued
// arrays holding the Fourier coefficients of the velocity field in
// X and Y. Diffusion in this space takes a simple form described as:
// v(k,t) = v(k,t) / (1 + visc * dt * k^2), where visc is the viscosity,
// and k is the wavenumber. The projection step forces the Fourier
// velocity vectors to be orthogonal to the wave wave vectors for each
// wavenumber: v(k,t) = v(k,t) - ((k dot v(k,t) * k) / k^2.
__global__ void
diffuseProject_k(cData *vx, cData *vy, int dx, int dy, float dt,
                 float visc, int lb);

// This method updates the velocity field 'v' using the two complex
// arrays from the previous step: 'vx' and 'vy'. Here we scale the
// real components by 1/(dx*dy) to account for an unnormalized FFT.
__global__ void
updateVelocity_k(cData *v, float *vx, float *vy,
                 int dx, int pdx, int dy, int lb, size_t pitch);

// This method updates the particles by moving particle positions
// according to the velocity field and time step. That is, for each
// particle: p(t+1) = p(t) + dt * v(p(t)).
__global__ void
advectParticles_k(cData *part, cData *v, int dx, int dy,
                  float dt, int lb, size_t pitch);

#endif
add and update samples for CUDA 11.5 2021-10-21 19:04:49 +08:00			`/*`
			`* Copyright 1993-2015 NVIDIA Corporation. All rights reserved.`
			`*`
			`* Please refer to the NVIDIA end user license agreement (EULA) associated`
			`* with this source code for terms and conditions that govern your use of`
			`* this software. Any use, reproduction, disclosure, or distribution of`
			`* this software and related documentation outside the terms of the EULA`
			`* is strictly prohibited.`
			`*`
			`*/`
			`#ifndef __STABLEFLUIDS_KERNELS_CUH_`
			`#define __STABLEFLUIDS_KERNELS_CUH_`

			`// Vector data type used to velocity and force fields`
			`typedef float2 cData;`

			`void setupTexture(int x, int y);`
			`void updateTexture(cData *data, size_t w, size_t h, size_t pitch);`
			`void deleteTexture(void);`

			`// This method adds constant force vectors to the velocity field`
			`// stored in 'v' according to v(x,t+1) = v(x,t) + dt * f.`
			`__global__ void`
			`addForces_k(cData *v, int dx, int dy, int spx, int spy, float fx, float fy, int r, size_t pitch);`

			`// This method performs the velocity advection step, where we`
			`// trace velocity vectors back in time to update each grid cell.`
			`// That is, v(x,t+1) = v(p(x,-dt),t). Here we perform bilinear`
			`// interpolation in the velocity space.`
			`__global__ void`
			`advectVelocity_k(cData v, float vx, float *vy,`
			`int dx, int pdx, int dy, float dt, int lb, cudaTextureObject_t tex);`

			`// This method performs velocity diffusion and forces mass conservation`
			`// in the frequency domain. The inputs 'vx' and 'vy' are complex-valued`
			`// arrays holding the Fourier coefficients of the velocity field in`
			`// X and Y. Diffusion in this space takes a simple form described as:`
			`// v(k,t) = v(k,t) / (1 + visc * dt * k^2), where visc is the viscosity,`
			`// and k is the wavenumber. The projection step forces the Fourier`
			`// velocity vectors to be orthogonal to the wave wave vectors for each`
			`// wavenumber: v(k,t) = v(k,t) - ((k dot v(k,t) * k) / k^2.`
			`__global__ void`
			`diffuseProject_k(cData vx, cData vy, int dx, int dy, float dt,`
			`float visc, int lb);`

			`// This method updates the velocity field 'v' using the two complex`
			`// arrays from the previous step: 'vx' and 'vy'. Here we scale the`
			`// real components by 1/(dx*dy) to account for an unnormalized FFT.`
			`__global__ void`
			`updateVelocity_k(cData v, float vx, float *vy,`
			`int dx, int pdx, int dy, int lb, size_t pitch);`

			`// This method updates the particles by moving particle positions`
			`// according to the velocity field and time step. That is, for each`
			`// particle: p(t+1) = p(t) + dt * v(p(t)).`
			`__global__ void`
			`advectParticles_k(cData part, cData v, int dx, int dy,`
			`float dt, int lb, size_t pitch);`

			`#endif`