diff options
Diffstat (limited to 'src/modules')
-rw-r--r-- | src/modules/Makefile.am | 2 | ||||
-rw-r--r-- | src/modules/flui2d/Makefile.am | 3 | ||||
-rw-r--r-- | src/modules/flui2d/flui2d.c | 291 |
3 files changed, 295 insertions, 1 deletions
diff --git a/src/modules/Makefile.am b/src/modules/Makefile.am index 8706332..de59b4a 100644 --- a/src/modules/Makefile.am +++ b/src/modules/Makefile.am @@ -1 +1 @@ -SUBDIRS = julia plasma ray roto sparkler stars submit +SUBDIRS = flui2d julia plasma ray roto sparkler stars submit diff --git a/src/modules/flui2d/Makefile.am b/src/modules/flui2d/Makefile.am new file mode 100644 index 0000000..239de9e --- /dev/null +++ b/src/modules/flui2d/Makefile.am @@ -0,0 +1,3 @@ +noinst_LIBRARIES = libflui2d.a +libflui2d_a_SOURCES = flui2d.c +libflui2d_a_CPPFLAGS = -I@top_srcdir@/src diff --git a/src/modules/flui2d/flui2d.c b/src/modules/flui2d/flui2d.c new file mode 100644 index 0000000..2f0a472 --- /dev/null +++ b/src/modules/flui2d/flui2d.c @@ -0,0 +1,291 @@ +#include <stdint.h> +#include <inttypes.h> +#include <math.h> +#include <stdlib.h> + +#include "fb.h" +#include "rototiller.h" + + +/* This code is almost entirely taken from the paper: + * Real-Time Fluid Dynamics for Games + * Joe Stam - Alias | Wavefront + * + * I take zero credit for it, I only wrote the rototiller integration. + * - Vito Caputo <vcaputo@pengaru.com> 10/13/2019 + */ + +#if 1 + /* These knobs affect how the simulated fluid behaves */ +#define VISCOSITY .000000001f +#define DIFFUSION .00001f +#else +#define VISCOSITY .00001f +#define DIFFUSION .000001f +#endif + +#define ROOT 128 // Change this to vary the density field resolution +#define SIZE ((ROOT + 2) * (ROOT + 2)) +#define IX(i, j) ((i) + (ROOT + 2) * (j)) +#define SWAP(x0, x) {float *tmp = x0; x0 = x; x = tmp;} + +typedef struct flui2d_t { + float u[SIZE], v[SIZE], u_prev[SIZE], v_prev[SIZE]; + float dens[SIZE], dens_prev[SIZE]; + float visc, diff; +} flui2d_t; + +static void set_bnd(int N, int b, float *x) +{ + for (int i = 1; i <= N; i++) { + x[IX(0, i)] = b == 1 ? -x[IX(1, i)] : x[IX(1, i)]; + x[IX(N + 1, i)] = b == 1 ? -x[IX(N, i)] : x[IX(N, i)]; + x[IX(i, 0)] = b == 2 ? -x[IX(i, 1)] : x[IX(i, 1)]; + x[IX(i, N + 1)] = b == 2 ? -x[IX(i, N)] : x[IX(i, N)]; + } + + x[IX(0 , 0)] = 0.5 * (x[IX(1, 0)] + x[IX(0, 1)]); + x[IX(0 , N + 1)] = 0.5 * (x[IX(1, N + 1)] + x[IX(0, N)]); + x[IX(N + 1, 0)] = 0.5 * (x[IX(N, 0)] + x[IX(N + 1, 1)]); + x[IX(N + 1, N + 1)] = 0.5 * (x[IX(N, N + 1)] + x[IX(N + 1, N)]); +} + +static void add_source(int N, float *x, float *s, float dt) +{ + int size = (N + 2) * (N + 2); + + for (int i = 0; i < size; i++) + x[i] += dt * s[i]; +} + +static void diffuse(int N, int b, float *x, float *x0, float diff, float dt) +{ + float a = dt * diff * (float)N * (float)N; + int i, j, k; + float z = 1.f / (1.f + 4.f * a); + + for (k = 0; k < 20; k++) { + for (i = 1; i <= N; i++) { + for (j = 1; j <= N; j++) { + x[IX(i, j)] = (x0[IX(i, j)] + a * (x[IX(i - 1, j)] + x[IX(i + 1, j)] + x[IX(i, j - 1)] + x[IX(i, j + 1)])) * z; + } + } + set_bnd(N, b, x); + } +} + +static void advect(int N, int b, float *d, float *d0, float *u, float *v, float dt) +{ + float x, y, s0, t0, s1, t1, dt0; + int i, j, i0, j0, i1, j1; + + dt0 = dt * (float)N; + for (i = 1 ; i <= N ; i++) { + for (j = 1 ; j <= N; j++) { + x = (float)i - dt0 * u[IX(i, j)]; + y = (float)j - dt0 * v[IX(i, j)]; + + if (x < .5f) + x = .5f; + if (x > (float)N + .5f) + x = (float)N + .5f; + + i0 = (int)x; + i1 = i0 + 1; + + if (y < .5f) + y = .5f; + if (y > (float)N + .5f) + y = (float)N + .5f; + + j0 = (int)y; + j1 = j0 + 1; + + s1 = x - (float)i0; + s0 = 1.f - s1; + t1 = y - (float)j0; + t0 = 1.f - t1; + + d[IX(i, j)] = s0 * (t0 * d0[IX(i0, j0)] + t1 * d0[IX(i0, j1)]) + s1 * (t0 * d0[IX(i1, j0)] + t1 * d0[IX(i1, j1)]); + } + } + set_bnd(N, b, d); +} + +static void project(int N, float *u, float *v, float *p, float *div) +{ + float h = 1.f / (float)N; + int i, j, k; + + for (i = 1; i <= N ; i++) { + for (j = 1; j <= N; j++) { + div[IX(i, j)] = -0.5 * h *(u[IX(i + 1, j)] - u[IX(i - 1, j)] + v[IX(i, j + 1)] - v[IX(i, j - 1)]); + p[IX(i, j)] = 0; + } + } + + set_bnd(N, 0, div); + set_bnd(N, 0, p); + + for (k = 0; k < 20; k++) { + for (i = 1; i <= N; i++) { + for (j = 1; j <= N; j++) { + p[IX(i, j)] = (div[IX(i, j)] + p[IX(i - 1, j)] + p[IX(i + 1, j)] + p[IX(i, j - 1)] + p[IX(i, j + 1)]) * .25f; + } + } + set_bnd(N, 0, p); + } + + for (i = 1; i <= N; i++) { + for (j = 1; j <= N; j++) { + u[IX(i, j)] -= 0.5 * (p[IX(i + 1, j)] - p[IX(i - 1, j)]) / h; + v[IX(i, j)] -= 0.5 * (p[IX(i, j + 1)] - p[IX(i, j - 1)]) / h; + } + } + + set_bnd(N, 1, u); + set_bnd(N, 2, v); +} + +static void dens_step(int N, float *x, float *x0, float *u, float *v, float diff, float dt) +{ + + /* + * The paper includes this, but it blows up the simulation. + * add_source(N, x, x0, dt); + * SWAP(x0, x); + */ + diffuse(N, 0, x, x0, diff, dt); + SWAP(x0, x); + advect(N, 0, x, x0, u, v, dt); +} + +static void vel_step(int N, float *u, float *v, float *u0, float *v0, float visc, float dt) +{ + add_source(N, u, u0, dt); + add_source(N, v, v0, dt); + SWAP(u0, u); + diffuse(N, 1, u, u0, visc, dt); + SWAP(v0, v); + diffuse(N, 2, v, v0, visc, dt); + project(N, u, v, u0, v0); + SWAP(u0, u); + SWAP(v0, v); + advect(N, 1, u, u0, u0, v0, dt); + advect(N, 2, v, v0, u0, v0, dt); + project(N, u, v, u0, v0); +} + + +typedef struct flui2d_context_t { + flui2d_t fluid; + float xf, yf; +} flui2d_context_t; + + +static void * flui2d_create_context(void) +{ + flui2d_context_t *ctxt; + + ctxt = calloc(1, sizeof(flui2d_context_t)); + if (!ctxt) + return NULL; + + ctxt->fluid.visc = VISCOSITY; + ctxt->fluid.diff = DIFFUSION; + + return ctxt; +} + + +static void flui2d_destroy_context(void *context) +{ + free(context); +} + + +static int flui2d_fragmenter(void *context, const fb_fragment_t *fragment, unsigned num, fb_fragment_t *res_fragment) +{ + return fb_fragment_tile_single(fragment, 64, num, res_fragment); +} + + +/* Prepare a frame for concurrent drawing of fragment using multiple fragments */ +static void flui2d_prepare_frame(void *context, unsigned n_cpus, fb_fragment_t *fragment, rototiller_fragmenter_t *res_fragmenter) +{ + flui2d_context_t *ctxt = context; + static float r; + int x = (cos(r += .01f) * .4f + .5f) * (float)ROOT; /* figure eight pattern for the added densities */ + int y = (sin(r * 2.f) * .4f + .5f) * (float)ROOT; + + *res_fragmenter = flui2d_fragmenter; + + ctxt->fluid.dens_prev[IX(x, y)] = 1.f; + + /* This orientation for the added velocities at the added densities isn't trying to + * emulate any sort of physical relationship to the movement - it's just creating a variety + * of turbulence. It'd be trivial to make it look like a rocket's jetstream or something. + */ + ctxt->fluid.u_prev[IX(x, y)] = cos(r * 3.f) * 10.f; + ctxt->fluid.v_prev[IX(x, y)] = sin(r * 3.f) * 10.f; + + /* These are the core of the simulation, and can't currently be threaded using the paper's implementation, so they + * must occur serialized here in prepare_frame. It would be interesting to try refactor the API and tweak the + * implementation for threading, as it would really open up larger field sizes as well as map more naturally to + * a GLSL implementation for a fragment shader. + */ + vel_step(ROOT, ctxt->fluid.u, ctxt->fluid.v, ctxt->fluid.u_prev, ctxt->fluid.v_prev, ctxt->fluid.visc, .1f); + dens_step(ROOT, ctxt->fluid.dens, ctxt->fluid.dens_prev, ctxt->fluid.u, ctxt->fluid.v, ctxt->fluid.diff, .1f); + + ctxt->xf = 1.f / fragment->frame_width; + ctxt->yf = 1.f / fragment->frame_height; +} + + +/* Draw a the flui2d densities */ +static void flui2d_render_fragment(void *context, fb_fragment_t *fragment) +{ + flui2d_context_t *ctxt = context; + + for (int y = fragment->y; y < fragment->y + fragment->height; y++) { + int y0, y1; + float Y; + + Y = (float)y * ctxt->yf * (float)ROOT; + y0 = (int)Y; + y1 = y0 + 1; + + for (int x = fragment->x; x < fragment->x + fragment->width; x++) { + float X, dens, dx0, dx1; + int x0, x1; + uint32_t pixel; + + X = (float)x * ctxt->xf * (float)ROOT; + x0 = (int)X; + x1 = x0 + 1; + + /* linear interpolation of density samples */ + dx0 = ctxt->fluid.dens[(int)IX(x0, y0)] * (1.f - (X - x0)); + dx0 += ctxt->fluid.dens[(int)IX(x1, y0)] * (X - x0); + dx1 = ctxt->fluid.dens[(int)IX(x0, y1)] * (1.f - (X - x0)); + dx1 += ctxt->fluid.dens[(int)IX(x1, y1)] * (X - x0); + dens = dx0 * (1.f - (Y - y0)) + dx1 * (Y - y0); + + pixel = ((float)dens * 256.f); + pixel = pixel << 16 | pixel << 8 | pixel; + fb_fragment_put_pixel_unchecked(fragment, x, y, pixel); + } + } +} + + +rototiller_module_t flui2d_module = { + .create_context = flui2d_create_context, + .destroy_context = flui2d_destroy_context, + .prepare_frame = flui2d_prepare_frame, + .render_fragment = flui2d_render_fragment, + .name = "flui2d", + .description = "Fluid dynamics simulation in 2D (threaded (poorly))", + .author = "Vito Caputo <vcaputo@pengaru.com>", + .license = "Unknown", +}; |