nuclear@0: #include <stdio.h>
nuclear@2: #include <math.h>
nuclear@0: #include <assert.h>
nuclear@0: #include "ocl.h"
nuclear@0: 
nuclear@2: struct RendInfo {
nuclear@2: 	int xsz, ysz;
nuclear@3: 	int num_sph, num_lights;
nuclear@2: 	int max_iter;
nuclear@2: } __attribute__((packed));
nuclear@2: 
nuclear@1: struct Sphere {
nuclear@1: 	cl_float4 pos;
nuclear@1: 	cl_float radius;
nuclear@1: 
nuclear@4: 	cl_float4 kd, ks;
nuclear@4: 	cl_float spow;
nuclear@4: 	cl_float kr, kt;
nuclear@1: } __attribute__((packed));
nuclear@1: 
nuclear@1: struct Ray {
nuclear@1: 	cl_float4 origin, dir;
nuclear@1: } __attribute__((packed));
nuclear@1: 
nuclear@3: struct Light {
nuclear@3: 	cl_float4 pos, color;
nuclear@3: } __attribute__((packed));
nuclear@1: 
nuclear@2: 
nuclear@3: static Ray get_primary_ray(int x, int y, int w, int h, float vfov_deg);
nuclear@3: 
nuclear@3: static Ray *prim_rays;
nuclear@3: static CLProgram *prog;
nuclear@3: static int global_size;
nuclear@3: 
nuclear@4: static Sphere sphlist[] = {
nuclear@4: 	{{0, 0, 8, 1}, 1.0, {0.7, 0.2, 0.15, 1}, {1, 1, 1, 1}, 60, 0, 0},
nuclear@4: 	{{-0.2, 0.4, 5, 1}, 0.25, {0.2, 0.9, 0.3, 1}, {1, 1, 1, 1}, 40, 0, 0}
nuclear@4: };
nuclear@4: 
nuclear@4: static Light lightlist[] = {
nuclear@4: 	{{-10, 10, -20, 1}, {1, 1, 1, 1}}
nuclear@4: };
nuclear@4: 
nuclear@4: static RendInfo rinf;
nuclear@4: 
nuclear@4: 
nuclear@3: bool init_renderer(int xsz, int ysz, float *fb)
nuclear@0: {
nuclear@4: 	// render info
nuclear@4: 	rinf.xsz = xsz;
nuclear@4: 	rinf.ysz = ysz;
nuclear@4: 	rinf.num_sph = sizeof sphlist / sizeof *sphlist;
nuclear@4: 	rinf.num_lights = sizeof lightlist / sizeof *lightlist;
nuclear@4: 	rinf.max_iter = 6;
nuclear@4: 
nuclear@3: 	/* calculate primary rays */
nuclear@3: 	prim_rays = new Ray[xsz * ysz];
nuclear@2: 
nuclear@2: 	for(int i=0; i<ysz; i++) {
nuclear@2: 		for(int j=0; j<xsz; j++) {
nuclear@2: 			prim_rays[i * xsz + j] = get_primary_ray(j, i, xsz, ysz, 45.0);
nuclear@2: 		}
nuclear@0: 	}
nuclear@0: 
nuclear@2: 	/* setup opencl */
nuclear@3: 	prog = new CLProgram("render");
nuclear@3: 	if(!prog->load("rt.cl")) {
nuclear@0: 		return 1;
nuclear@0: 	}
nuclear@0: 
nuclear@3: 	/* setup argument buffers */
nuclear@3: 	prog->set_arg_buffer(0, ARG_WR, xsz * ysz * 4 * sizeof(float), fb);
nuclear@3: 	prog->set_arg_buffer(1, ARG_RD, sizeof rinf, &rinf);
nuclear@3: 	prog->set_arg_buffer(2, ARG_RD, sizeof sphlist, sphlist);
nuclear@3: 	prog->set_arg_buffer(3, ARG_RD, sizeof lightlist, lightlist);
nuclear@3: 	prog->set_arg_buffer(4, ARG_RD, xsz * ysz * sizeof *prim_rays, prim_rays);
nuclear@2: 
nuclear@3: 	global_size = xsz * ysz;
nuclear@3: 	return true;
nuclear@3: }
nuclear@3: 
nuclear@3: void destroy_renderer()
nuclear@3: {
nuclear@3: 	delete [] prim_rays;
nuclear@3: 	delete prog;
nuclear@3: }
nuclear@3: 
nuclear@3: bool render()
nuclear@3: {
nuclear@3: 	if(!prog->run(1, global_size)) {
nuclear@3: 		return false;
nuclear@0: 	}
nuclear@0: 
nuclear@3: 	CLMemBuffer *mbuf = prog->get_arg_buffer(0);
nuclear@0: 	map_mem_buffer(mbuf, MAP_RD);
nuclear@3: 	/*if(!write_ppm("out.ppm", fb, xsz, ysz)) {
nuclear@2: 		return 1;
nuclear@3: 	}*/
nuclear@2: 	unmap_mem_buffer(mbuf);
nuclear@3: 	return true;
nuclear@0: }
nuclear@2: 
nuclear@3: static Ray get_primary_ray(int x, int y, int w, int h, float vfov_deg)
nuclear@2: {
nuclear@2: 	float vfov = M_PI * vfov_deg / 180.0;
nuclear@2: 	float aspect = (float)w / (float)h;
nuclear@2: 
nuclear@2: 	float ysz = 2.0;
nuclear@2: 	float xsz = aspect * ysz;
nuclear@2: 
nuclear@2: 	float px = ((float)x / (float)w) * xsz - xsz / 2.0;
nuclear@2: 	float py = 1.0 - ((float)y / (float)h) * ysz;
nuclear@2: 	float pz = 1.0 / tan(0.5 * vfov);
nuclear@2: 
nuclear@4: 	px *= 100.0;
nuclear@4: 	py *= 100.0;
nuclear@4: 	pz *= 100.0;
nuclear@2: 
nuclear@2: 	Ray ray = {{0, 0, 0, 1}, {px, py, pz, 1}};
nuclear@2: 	return ray;
nuclear@2: }