Example #1
0
    def __init__(self,
                 film_width,
                 film_height,
                 camera2world,
                 vfov,
                 aperture=0.0,
                 focus_dist=1.0):
        self.m_film = Film(film_width, film_height)
        self.m_sv_camera2world = vki.SVMat4x4(camera2world)
        theta = vfov * math.pi / 180.0
        half_height = math.tan(theta * 0.5) * focus_dist
        size_pix = half_height * 2.0 / film_height
        lens_radius = aperture * 0.5
        self.m_sv_size_pix = vki.SVFloat(size_pix)
        self.m_sv_lens_radius = vki.SVFloat(lens_radius)
        self.m_sv_focus_dist = vki.SVFloat(focus_dist)
        self.m_cptr = SVCombine_Create(
            {
                'film': self.m_film,
                'camera2world': self.m_sv_camera2world,
                'size_pix': self.m_sv_size_pix,
                'lens_radius': self.m_sv_lens_radius,
                'focus_dist': self.m_sv_focus_dist
            }, '''
void generate_ray(in Comb_#hash# camera, float film_x, float film_y, float lens_x, float lens_y, out vec3 origin, out vec3 dir)
{
	origin = vec3(lens_x*camera.lens_radius, lens_y*camera.lens_radius, 0.0);
	origin = (camera.camera2world*vec4(origin, 1.0)).xyz;
	vec3 pos_pix = vec3((film_x - float(camera.film.width)*0.5)*camera.size_pix, (float(camera.film.height)*0.5 - film_y)*camera.size_pix, -camera.focus_dist);
	pos_pix = (camera.camera2world*vec4(pos_pix, 1.0)).xyz;
	dir = normalize(pos_pix - origin);	
}
''')
Example #2
0
    def __init__(self,
                 positions,
                 normals,
                 indices_pos,
                 indices_norm,
                 modelMat=glm.identity(glm.mat4),
                 color=(1.0, 1.0, 1.0)):
        Geometry.__init__(self, modelMat)
        self.m_gpuPos = vki.device_vector_from_numpy(positions)
        self.m_gpuNorm = vki.device_vector_from_numpy(normals)
        self.m_gpuIndPos = vki.device_vector_from_numpy(indices_pos)
        self.m_gpuIndNorm = vki.device_vector_from_numpy(indices_norm)
        self.m_blas = vki.BaseLevelAS(self.m_gpuIndPos, self.m_gpuPos)

        vert0 = positions[0]
        self.m_aabb = np.array(
            [vert0[0], vert0[1], vert0[2], vert0[0], vert0[1], vert0[2]],
            dtype=np.float32)
        for vert in positions:
            self.m_aabb[0] = min(self.m_aabb[0], vert[0])
            self.m_aabb[1] = min(self.m_aabb[1], vert[1])
            self.m_aabb[2] = min(self.m_aabb[2], vert[2])
            self.m_aabb[3] = max(self.m_aabb[3], vert[0])
            self.m_aabb[4] = max(self.m_aabb[4], vert[1])
            self.m_aabb[5] = max(self.m_aabb[5], vert[2])

        self.d_normMat = vki.SVMat4x4(self.m_normMat)
        self.d_color = Spectrum(color)
        self.m_cptr = SVCombine_Create(
            {
                'indices': self.m_gpuIndNorm,
                'normals': self.m_gpuNorm,
                'normalMat': self.d_normMat,
                'color': self.d_color
            }, '''
void closethit(in Comb_#hash# self, int primitiveId, in vec3 barycentrics, inout {HitInfo_Lambert} hitinfo)
{{    
    uint i0 = get_value(self.indices, 3 * primitiveId);
    uint i1 = get_value(self.indices, 3 * primitiveId + 1);
    uint i2 = get_value(self.indices, 3 * primitiveId + 2);

    vec3 norm0 = get_value(self.normals, i0);
    vec3 norm1 = get_value(self.normals, i1);
    vec3 norm2 = get_value(self.normals, i2);

    vec3 normal = norm0 * barycentrics.x + norm1 * barycentrics.y + norm2 * barycentrics.z;
    normal = normalize((self.normalMat * vec4(normal, 0.0)).xyz);   

    hitinfo.lambert.color = self.color;    
    hitinfo.normal = normal;

}}
'''.format(HitInfo_Lambert=Name_HitInfo_Lambert))
Example #3
0
    def __init__(self, modelMat=glm.identity(glm.mat4), color=(1.0, 1.0, 1.0)):
        Sphere.__init__(self, modelMat)
        self.d_normMat = vki.SVMat4x4(self.m_normMat)
        self.d_color = Spectrum(color)
        self.m_cptr = SVCombine_Create(
            {
                'normalMat': self.d_normMat,
                'color': self.d_color
            }, '''
void closethit(in Comb_#hash# self, in vec3 hitpoint, inout {HitInfo_Lambert} hitinfo)
{{
    hitinfo.lambert.color = self.color;
    hitinfo.normal = normalize((self.normalMat * vec4(hitpoint, 0.0)).xyz);   
}}
'''.format(HitInfo_Lambert=Name_HitInfo_Lambert))
Example #4
0
    def render(self, cube, filename = None):        
        colorBuf = vki.Texture2D(self.width, self.height, VK_FORMAT_R8G8B8A8_SRGB)
        colorBuf4x = vki.Texture2D(self.width, self.height, VK_FORMAT_R8G8B8A8_SRGB, samples=4)
        depthBuf4x = vki.Texture2D(self.width, self.height, VK_FORMAT_D32_SFLOAT, isDepth=True, samples=4)       
        
        gpu_matrix = vki.SVMat4x4(self.matrix)
        gpu_map = vki.device_vector_from_numpy(cube.map)
        gpu_dirs = vki.device_vector_from_numpy(cube.dirs)
        self.rp.launch([6*9*6], [colorBuf4x], depthBuf4x, self.bg_color, self.bg_depth, [gpu_matrix, gpu_map, gpu_dirs], resolveBufs=[colorBuf], cubemaps = [self.skin])

        image_out = np.empty((self.height, self.width, 4), dtype=np.uint8)
        colorBuf.download(image_out)

        if not filename is None:
            Image.fromarray(image_out, 'RGBA').save(filename)       

        return image_out
Example #5
0
{
	outColor = vec4(0.0, 0.0, 0.0, 1.0);

	vec3 norm = normalize(vNorm);
	vec3 light_dir = normalize(vec3(0.2, 0.5, -1.0));
	light_dir = reflect(light_dir, norm);

	if (light_dir.z>0.0)
	{
		float intensity = pow(light_dir.z, 5.0)*0.8;
		outColor += vec4(intensity, intensity, intensity, 0.0);
	}

	outColor = clamp(outColor, 0.0, 1.0);
	
}
'''))

proj = glm.perspective(glm.radians(45.0), width / height, 0.1, 2000.0)
modelView = glm.lookAt(glm.vec3(-100.0, 200.0, 200.0), glm.vec3(0.0, 0.0, 0.0),
                       glm.vec3(0.0, 1.0, 0.0))
mat_pos = vki.SVMat4x4(proj * modelView)
mat_norm = vki.SVMat4x4(glm.transpose(glm.inverse(modelView)))

rp.launch([len(vertex_inds)], [colorBuf], depthBuf, [0.5, 0.5, 0.5, 1.0], 1.0,
          [gpuPos, gpuNormals, gpuInd_pos, gpuInd_norm, mat_pos, mat_norm])

image_out = np.empty((height, width, 4), dtype=np.uint8)
colorBuf.download(image_out)
Image.fromarray(image_out, 'RGBA').save('output.png')