示例#1
0
void OSLShader::eval_displacement(KernelGlobals *kg, ShaderData *sd, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;

	PathState state = {0};

	shaderdata_to_shaderglobals(kg, sd, &state, 0, tdata);

	/* execute shader */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];
	int shader = sd->shader & SHADER_MASK;

	if(kg->osl->displacement_state[shader]) {
#if OSL_LIBRARY_VERSION_CODE < 10600
		ss->execute(*octx, *(kg->osl->displacement_state[shader]), *globals);
#else
		ss->execute(octx, *(kg->osl->displacement_state[shader]), *globals);
#endif
	}

	/* get back position */
	sd->P = TO_FLOAT3(globals->P);
}
示例#2
0
void OSLShader::eval_volume(KernelGlobals *kg, ShaderData *sd, float randb, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, path_flag, tdata);

	/* execute shader */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];
	int shader = sd->shader & SHADER_MASK;

	if (kg->osl->volume_state[shader])
		ss->execute(*octx, *(kg->osl->volume_state[shader]), *globals);

	if (globals->Ci)
		flatten_volume_closure_tree(sd, globals->Ci);
}
示例#3
0
void OSLShader::eval_background(KernelGlobals *kg, ShaderData *sd, PathState *state, int path_flag)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, state, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context;

	if(kg->osl->background_state) {
		ss->execute(octx, *(kg->osl->background_state), *globals);
	}

	/* return background color immediately */
	if(globals->Ci)
		flatten_background_closure_tree(sd, globals->Ci);
}
示例#4
0
float3 OSLShader::eval_background(KernelGlobals *kg, ShaderData *sd, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];

	if (kg->osl->background_state)
		ss->execute(*octx, *(kg->osl->background_state), *globals);

	/* return background color immediately */
	if (globals->Ci)
		return flatten_background_closure_tree(globals->Ci);

	return make_float3(0.0f, 0.0f, 0.0f);
}
示例#5
0
void OSLShader::eval_displacement(KernelGlobals *kg, ShaderData *sd, PathState *state)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;

	shaderdata_to_shaderglobals(kg, sd, state, 0, tdata);

	/* execute shader */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context;
	int shader = sd->shader & SHADER_MASK;

	if(kg->osl->displacement_state[shader]) {
		ss->execute(octx, *(kg->osl->displacement_state[shader]), *globals);
	}

	/* get back position */
	sd->P = TO_FLOAT3(globals->P);
}
void OSLShader::eval_surface(KernelGlobals *kg, ShaderData *sd, float randb, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];
	int shader = sd->shader & SHADER_MASK;

	if (kg->osl->surface_state[shader])
		ss->execute(*octx, *(kg->osl->surface_state[shader]), *globals);

	/* flatten closure tree */
	sd->num_closure = 0;
	sd->randb_closure = randb;

	if (globals->Ci) {
		bool no_glossy = (path_flag & PATH_RAY_DIFFUSE) && kernel_data.integrator.no_caustics;
		flatten_surface_closure_tree(sd, no_glossy, globals->Ci);
	}
}
示例#7
0
static void flatten_volume_closure_tree(ShaderData *sd,
                                        const OSL::ClosureColor *closure, float3 weight = make_float3(1.0f, 1.0f, 1.0f))
{
	/* OSL gives us a closure tree, we flatten it into arrays per
	 * closure type, for evaluation, sampling, etc later on. */

#if OSL_LIBRARY_VERSION_CODE < 10700
	switch(closure->type) {
#else
	switch(closure->id) {
#endif
		case OSL::ClosureColor::MUL: {
			OSL::ClosureMul *mul = (OSL::ClosureMul *)closure;
			flatten_volume_closure_tree(sd, mul->closure, TO_FLOAT3(mul->weight) * weight);
			break;
		}
		case OSL::ClosureColor::ADD: {
			OSL::ClosureAdd *add = (OSL::ClosureAdd *)closure;
			flatten_volume_closure_tree(sd, add->closureA, weight);
			flatten_volume_closure_tree(sd, add->closureB, weight);
			break;
		}
		default: {
			OSL::ClosureComponent *comp = (OSL::ClosureComponent *)closure;
			CClosurePrimitive *prim = (CClosurePrimitive *)comp->data();

			if(prim) {
				ShaderClosure sc;

#ifdef OSL_SUPPORTS_WEIGHTED_CLOSURE_COMPONENTS
				weight = weight*TO_FLOAT3(comp->w);
#endif
				sc.weight = weight;

				prim->setup();

				switch(prim->category) {
					case CClosurePrimitive::Volume: {
						CVolumeClosure *volume = (CVolumeClosure *)prim;
						/* sample weight */
						float sample_weight = fabsf(average(weight));

						sc.sample_weight = sample_weight;
						sc.type = volume->sc.type;
						sc.data0 = volume->sc.data0;
						sc.data1 = volume->sc.data1;

						/* add */
						if((sc.sample_weight > CLOSURE_WEIGHT_CUTOFF) &&
						   (sd->num_closure < MAX_CLOSURE))
						{
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= volume->shaderdata_flag();
						}
						break;
					}
					case CClosurePrimitive::Emissive: {
						/* sample weight */
						float sample_weight = fabsf(average(weight));

						sc.sample_weight = sample_weight;
						sc.type = CLOSURE_EMISSION_ID;
						sc.data0 = 0.0f;
						sc.data1 = 0.0f;
						sc.prim = NULL;

						/* flag */
						if(sd->num_closure < MAX_CLOSURE) {
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= SD_EMISSION;
						}
						break;
					}
					case CClosurePrimitive::Holdout:
						break; /* not implemented */
					case CClosurePrimitive::Background:
					case CClosurePrimitive::BSDF:
					case CClosurePrimitive::BSSRDF:
					case CClosurePrimitive::AmbientOcclusion:
						break; /* not relevant */
				}
			}
		}
	}
}

void OSLShader::eval_volume(KernelGlobals *kg, ShaderData *sd, PathState *state, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, state, path_flag, tdata);

	/* execute shader */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];
	int shader = sd->shader & SHADER_MASK;

	if(kg->osl->volume_state[shader]) {
#if OSL_LIBRARY_VERSION_CODE < 10600
		ss->execute(*octx, *(kg->osl->volume_state[shader]), *globals);
#else
		ss->execute(octx, *(kg->osl->volume_state[shader]), *globals);
#endif
	}
	
	/* flatten closure tree */
	if(globals->Ci)
		flatten_volume_closure_tree(sd, globals->Ci);
}
示例#8
0
static float3 flatten_background_closure_tree(const OSL::ClosureColor *closure)
{
	/* OSL gives us a closure tree, if we are shading for background there
	 * is only one supported closure type at the moment, which has no evaluation
	 * functions, so we just sum the weights */

#if OSL_LIBRARY_VERSION_CODE < 10700
	switch(closure->type) {
#else
	switch(closure->id) {
#endif
		case OSL::ClosureColor::MUL: {
			OSL::ClosureMul *mul = (OSL::ClosureMul *)closure;

			return TO_FLOAT3(mul->weight) * flatten_background_closure_tree(mul->closure);
		}
		case OSL::ClosureColor::ADD: {
			OSL::ClosureAdd *add = (OSL::ClosureAdd *)closure;

			return flatten_background_closure_tree(add->closureA) +
			       flatten_background_closure_tree(add->closureB);
		}
		default: {
			OSL::ClosureComponent *comp = (OSL::ClosureComponent *)closure;
			CClosurePrimitive *prim = (CClosurePrimitive *)comp->data();

			if(prim && prim->category == CClosurePrimitive::Background)
#ifdef OSL_SUPPORTS_WEIGHTED_CLOSURE_COMPONENTS
				return TO_FLOAT3(comp->w);
#else
				return make_float3(1.0f, 1.0f, 1.0f);
#endif
		}
	}

	return make_float3(0.0f, 0.0f, 0.0f);
}

float3 OSLShader::eval_background(KernelGlobals *kg, ShaderData *sd, PathState *state, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, state, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];

	if(kg->osl->background_state) {
#if OSL_LIBRARY_VERSION_CODE < 10600
		ss->execute(*octx, *(kg->osl->background_state), *globals);
#else
		ss->execute(octx, *(kg->osl->background_state), *globals);
#endif
	}

	/* return background color immediately */
	if(globals->Ci)
		return flatten_background_closure_tree(globals->Ci);

	return make_float3(0.0f, 0.0f, 0.0f);
}
示例#9
0
static void flatten_surface_closure_tree(ShaderData *sd, int path_flag,
                                         const OSL::ClosureColor *closure, float3 weight = make_float3(1.0f, 1.0f, 1.0f))
{
	/* OSL gives us a closure tree, we flatten it into arrays per
	 * closure type, for evaluation, sampling, etc later on. */

#if OSL_LIBRARY_VERSION_CODE < 10700
	switch(closure->type) {
#else
	switch(closure->id) {
#endif
		case OSL::ClosureColor::MUL: {
			OSL::ClosureMul *mul = (OSL::ClosureMul *)closure;
			flatten_surface_closure_tree(sd, path_flag, mul->closure, TO_FLOAT3(mul->weight) * weight);
			break;
		}
		case OSL::ClosureColor::ADD: {
			OSL::ClosureAdd *add = (OSL::ClosureAdd *)closure;
			flatten_surface_closure_tree(sd, path_flag, add->closureA, weight);
			flatten_surface_closure_tree(sd, path_flag, add->closureB, weight);
			break;
		}
		default: {
			OSL::ClosureComponent *comp = (OSL::ClosureComponent *)closure;
			CClosurePrimitive *prim = (CClosurePrimitive *)comp->data();

			if(prim) {
				ShaderClosure sc;

#ifdef OSL_SUPPORTS_WEIGHTED_CLOSURE_COMPONENTS
				weight = weight*TO_FLOAT3(comp->w);
#endif
				sc.weight = weight;

				prim->setup();

				switch(prim->category) {
					case CClosurePrimitive::BSDF: {
						CBSDFClosure *bsdf = (CBSDFClosure *)prim;
						int scattering = bsdf->scattering();

						/* caustic options */
						if((scattering & LABEL_GLOSSY) && (path_flag & PATH_RAY_DIFFUSE)) {
							KernelGlobals *kg = sd->osl_globals;

							if((!kernel_data.integrator.caustics_reflective && (scattering & LABEL_REFLECT)) ||
							   (!kernel_data.integrator.caustics_refractive && (scattering & LABEL_TRANSMIT)))
							{
								return;
							}
						}

						/* sample weight */
						float sample_weight = fabsf(average(weight));

						sc.sample_weight = sample_weight;

						sc.type = bsdf->sc.type;
						sc.N = bsdf->sc.N;
						sc.T = bsdf->sc.T;
						sc.data0 = bsdf->sc.data0;
						sc.data1 = bsdf->sc.data1;
						sc.data2 = bsdf->sc.data2;
						sc.prim = bsdf->sc.prim;

						/* add */
						if(sc.sample_weight > CLOSURE_WEIGHT_CUTOFF && sd->num_closure < MAX_CLOSURE) {
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= bsdf->shaderdata_flag();
						}
						break;
					}
					case CClosurePrimitive::Emissive: {
						/* sample weight */
						float sample_weight = fabsf(average(weight));

						sc.sample_weight = sample_weight;
						sc.type = CLOSURE_EMISSION_ID;
						sc.data0 = 0.0f;
						sc.data1 = 0.0f;
						sc.data2 = 0.0f;
						sc.prim = NULL;

						/* flag */
						if(sd->num_closure < MAX_CLOSURE) {
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= SD_EMISSION;
						}
						break;
					}
					case CClosurePrimitive::AmbientOcclusion: {
						/* sample weight */
						float sample_weight = fabsf(average(weight));

						sc.sample_weight = sample_weight;
						sc.type = CLOSURE_AMBIENT_OCCLUSION_ID;
						sc.data0 = 0.0f;
						sc.data1 = 0.0f;
						sc.data2 = 0.0f;
						sc.prim = NULL;

						if(sd->num_closure < MAX_CLOSURE) {
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= SD_AO;
						}
						break;
					}
					case CClosurePrimitive::Holdout: {
						sc.sample_weight = 0.0f;
						sc.type = CLOSURE_HOLDOUT_ID;
						sc.data0 = 0.0f;
						sc.data1 = 0.0f;
						sc.data2 = 0.0f;
						sc.prim = NULL;

						if(sd->num_closure < MAX_CLOSURE) {
							sd->closure[sd->num_closure++] = sc;
							sd->flag |= SD_HOLDOUT;
						}
						break;
					}
					case CClosurePrimitive::BSSRDF: {
						CBSSRDFClosure *bssrdf = (CBSSRDFClosure *)prim;
						float sample_weight = fabsf(average(weight));

						if(sample_weight > CLOSURE_WEIGHT_CUTOFF && sd->num_closure+2 < MAX_CLOSURE) {
							sc.sample_weight = sample_weight;

							sc.type = bssrdf->sc.type;
							sc.N = bssrdf->sc.N;
							sc.data1 = bssrdf->sc.data1;
							sc.T.x = bssrdf->sc.T.x;
							sc.prim = NULL;

							/* disable in case of diffuse ancestor, can't see it well then and
							 * adds considerably noise due to probabilities of continuing path
							 * getting lower and lower */
							if(path_flag & PATH_RAY_DIFFUSE_ANCESTOR)
								bssrdf->radius = make_float3(0.0f, 0.0f, 0.0f);

							/* create one closure for each color channel */
							if(fabsf(weight.x) > 0.0f) {
								sc.weight = make_float3(weight.x, 0.0f, 0.0f);
								sc.data0 = bssrdf->radius.x;
								sc.data1 = 0.0f;
								sd->flag |= bssrdf_setup(&sc, sc.type);
								sd->closure[sd->num_closure++] = sc;
							}

							if(fabsf(weight.y) > 0.0f) {
								sc.weight = make_float3(0.0f, weight.y, 0.0f);
								sc.data0 = bssrdf->radius.y;
								sc.data1 = 0.0f;
								sd->flag |= bssrdf_setup(&sc, sc.type);
								sd->closure[sd->num_closure++] = sc;
							}

							if(fabsf(weight.z) > 0.0f) {
								sc.weight = make_float3(0.0f, 0.0f, weight.z);
								sc.data0 = bssrdf->radius.z;
								sc.data1 = 0.0f;
								sd->flag |= bssrdf_setup(&sc, sc.type);
								sd->closure[sd->num_closure++] = sc;
							}
						}
						break;
					}
					case CClosurePrimitive::Background:
					case CClosurePrimitive::Volume:
						break; /* not relevant */
				}
			}
			break;
		}
	}
}

void OSLShader::eval_surface(KernelGlobals *kg, ShaderData *sd, PathState *state, int path_flag, ShaderContext ctx)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, state, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context[(int)ctx];
	int shader = sd->shader & SHADER_MASK;

	if(kg->osl->surface_state[shader]) {
#if OSL_LIBRARY_VERSION_CODE < 10600
		ss->execute(*octx, *(kg->osl->surface_state[shader]), *globals);
#else
		ss->execute(octx, *(kg->osl->surface_state[shader]), *globals);
#endif
	}

	/* flatten closure tree */
	if(globals->Ci)
		flatten_surface_closure_tree(sd, path_flag, globals->Ci);
}
示例#10
0
void OSLShader::eval_surface(KernelGlobals *kg, ShaderData *sd, PathState *state, int path_flag)
{
	/* setup shader globals from shader data */
	OSLThreadData *tdata = kg->osl_tdata;
	shaderdata_to_shaderglobals(kg, sd, state, path_flag, tdata);

	/* execute shader for this point */
	OSL::ShadingSystem *ss = (OSL::ShadingSystem*)kg->osl_ss;
	OSL::ShaderGlobals *globals = &tdata->globals;
	OSL::ShadingContext *octx = tdata->context;
	int shader = sd->shader & SHADER_MASK;

	/* automatic bump shader */
	if(kg->osl->bump_state[shader]) {
		/* save state */
		float3 P = sd->P;
		float3 dPdx = sd->dP.dx;
		float3 dPdy = sd->dP.dy;

		/* set state as if undisplaced */
		if(sd->flag & SD_HAS_DISPLACEMENT) {
			float data[9];
			bool found = kg->osl->services->get_attribute(sd, true, OSLRenderServices::u_empty, TypeDesc::TypeVector,
			                                              OSLRenderServices::u_geom_undisplaced, data);
			(void)found;
			assert(found);

			memcpy(&sd->P, data, sizeof(float)*3);
			memcpy(&sd->dP.dx, data+3, sizeof(float)*3);
			memcpy(&sd->dP.dy, data+6, sizeof(float)*3);

			object_position_transform(kg, sd, &sd->P);
			object_dir_transform(kg, sd, &sd->dP.dx);
			object_dir_transform(kg, sd, &sd->dP.dy);

			globals->P = TO_VEC3(sd->P);
			globals->dPdx = TO_VEC3(sd->dP.dx);
			globals->dPdy = TO_VEC3(sd->dP.dy);
		}

		/* execute bump shader */
		ss->execute(octx, *(kg->osl->bump_state[shader]), *globals);

		/* reset state */
		sd->P = P;
		sd->dP.dx = dPdx;
		sd->dP.dy = dPdy;

		globals->P = TO_VEC3(P);
		globals->dPdx = TO_VEC3(dPdx);
		globals->dPdy = TO_VEC3(dPdy);
	}

	/* surface shader */
	if(kg->osl->surface_state[shader]) {
		ss->execute(octx, *(kg->osl->surface_state[shader]), *globals);
	}

	/* flatten closure tree */
	if(globals->Ci)
		flatten_surface_closure_tree(sd, path_flag, globals->Ci);
}