diff options
Diffstat (limited to 'intern/cycles/kernel/bvh/obvh_shadow_all.h')
-rw-r--r-- | intern/cycles/kernel/bvh/obvh_shadow_all.h | 664 |
1 files changed, 0 insertions, 664 deletions
diff --git a/intern/cycles/kernel/bvh/obvh_shadow_all.h b/intern/cycles/kernel/bvh/obvh_shadow_all.h deleted file mode 100644 index b7ab75b723c..00000000000 --- a/intern/cycles/kernel/bvh/obvh_shadow_all.h +++ /dev/null @@ -1,664 +0,0 @@ -/* - * Copyright 2011-2013 Blender Foundation - * - * Licensed under the Apache License, Version 2.0 (the "License"); - * you may not use this file except in compliance with the License. - * You may obtain a copy of the License at - * - * http://www.apache.org/licenses/LICENSE-2.0 - * - * Unless required by applicable law or agreed to in writing, software - * distributed under the License is distributed on an "AS IS" BASIS, - * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. - * See the License for the specific language governing permissions and - * limitations under the License. - */ - -/* This is a template BVH traversal function, where various features can be - * enabled/disabled. This way we can compile optimized versions for each case - * without new features slowing things down. - * - * BVH_INSTANCING: object instancing - * BVH_HAIR: hair curve rendering - * BVH_MOTION: motion blur rendering - */ - -#if BVH_FEATURE(BVH_HAIR) -# define NODE_INTERSECT obvh_node_intersect -#else -# define NODE_INTERSECT obvh_aligned_node_intersect -#endif - -ccl_device bool BVH_FUNCTION_FULL_NAME(OBVH)(KernelGlobals *kg, - const Ray *ray, - Intersection *isect_array, - const int skip_object, - const uint max_hits, - uint *num_hits) -{ - /* TODO(sergey): - * - Test if pushing distance on the stack helps. - * - Likely and unlikely for if() statements. - * - Test restrict attribute for pointers. - */ - - /* Traversal stack in CUDA thread-local memory. */ - OBVHStackItem traversal_stack[BVH_OSTACK_SIZE]; - traversal_stack[0].addr = ENTRYPOINT_SENTINEL; - - /* Traversal variables in registers. */ - int stack_ptr = 0; - int node_addr = kernel_data.bvh.root; - - /* Ray parameters in registers. */ - const float tmax = ray->t; - float3 P = ray->P; - float3 dir = bvh_clamp_direction(ray->D); - float3 idir = bvh_inverse_direction(dir); - int object = OBJECT_NONE; - float isect_t = tmax; - -#if BVH_FEATURE(BVH_MOTION) - Transform ob_itfm; -#endif - - *num_hits = 0; - isect_array->t = tmax; - -#if BVH_FEATURE(BVH_INSTANCING) - int num_hits_in_instance = 0; -#endif - - avxf tnear(0.0f), tfar(isect_t); -#if BVH_FEATURE(BVH_HAIR) - avx3f dir4(avxf(dir.x), avxf(dir.y), avxf(dir.z)); -#endif - avx3f idir4(avxf(idir.x), avxf(idir.y), avxf(idir.z)); - -#ifdef __KERNEL_AVX2__ - float3 P_idir = P * idir; - avx3f P_idir4(P_idir.x, P_idir.y, P_idir.z); -#endif -#if BVH_FEATURE(BVH_HAIR) || !defined(__KERNEL_AVX2__) - avx3f org4(avxf(P.x), avxf(P.y), avxf(P.z)); -#endif - - /* Offsets to select the side that becomes the lower or upper bound. */ - int near_x, near_y, near_z; - int far_x, far_y, far_z; - obvh_near_far_idx_calc(idir, &near_x, &near_y, &near_z, &far_x, &far_y, &far_z); - - /* Traversal loop. */ - do { - do { - /* Traverse internal nodes. */ - while (node_addr >= 0 && node_addr != ENTRYPOINT_SENTINEL) { - float4 inodes = kernel_tex_fetch(__bvh_nodes, node_addr + 0); - (void)inodes; - - if (false -#ifdef __VISIBILITY_FLAG__ - || ((__float_as_uint(inodes.x) & PATH_RAY_SHADOW) == 0) -#endif -#if BVH_FEATURE(BVH_MOTION) - || UNLIKELY(ray->time < inodes.y) || UNLIKELY(ray->time > inodes.z) -#endif - ) { - /* Pop. */ - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - avxf dist; - int child_mask = NODE_INTERSECT(kg, - tnear, - tfar, -#ifdef __KERNEL_AVX2__ - P_idir4, -#endif -#if BVH_FEATURE(BVH_HAIR) || !defined(__KERNEL_AVX2__) - //#if !defined(__KERNEL_AVX2__) - org4, -#endif -#if BVH_FEATURE(BVH_HAIR) - dir4, -#endif - idir4, - near_x, - near_y, - near_z, - far_x, - far_y, - far_z, - node_addr, - &dist); - - if (child_mask != 0) { - avxf cnodes; -#if BVH_FEATURE(BVH_HAIR) - if (__float_as_uint(inodes.x) & PATH_RAY_NODE_UNALIGNED) { - cnodes = kernel_tex_fetch_avxf(__bvh_nodes, node_addr + 26); - } - else -#endif - { - cnodes = kernel_tex_fetch_avxf(__bvh_nodes, node_addr + 14); - } - - /* One child is hit, continue with that child. */ - int r = __bscf(child_mask); - if (child_mask == 0) { - node_addr = __float_as_int(cnodes[r]); - continue; - } - - /* Two children are hit, push far child, and continue with - * closer child. - */ - int c0 = __float_as_int(cnodes[r]); - float d0 = ((float *)&dist)[r]; - r = __bscf(child_mask); - int c1 = __float_as_int(cnodes[r]); - float d1 = ((float *)&dist)[r]; - if (child_mask == 0) { - if (d1 < d0) { - node_addr = c1; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c0; - traversal_stack[stack_ptr].dist = d0; - continue; - } - else { - node_addr = c0; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c1; - traversal_stack[stack_ptr].dist = d1; - continue; - } - } - - /* Here starts the slow path for 3 or 4 hit children. We push - * all nodes onto the stack to sort them there. - */ - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c1; - traversal_stack[stack_ptr].dist = d1; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c0; - traversal_stack[stack_ptr].dist = d0; - - /* Three children are hit, push all onto stack and sort 3 - * stack items, continue with closest child. - */ - r = __bscf(child_mask); - int c2 = __float_as_int(cnodes[r]); - float d2 = ((float *)&dist)[r]; - if (child_mask == 0) { - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c2; - traversal_stack[stack_ptr].dist = d2; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - /* Four children are hit, push all onto stack and sort 4 - * stack items, continue with closest child. - */ - r = __bscf(child_mask); - int c3 = __float_as_int(cnodes[r]); - float d3 = ((float *)&dist)[r]; - if (child_mask == 0) { - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c3; - traversal_stack[stack_ptr].dist = d3; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c2; - traversal_stack[stack_ptr].dist = d2; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2], - &traversal_stack[stack_ptr - 3]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c3; - traversal_stack[stack_ptr].dist = d3; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c2; - traversal_stack[stack_ptr].dist = d2; - - /* Five children are hit, push all onto stack and sort 5 - * stack items, continue with closest child - */ - r = __bscf(child_mask); - int c4 = __float_as_int(cnodes[r]); - float d4 = ((float *)&dist)[r]; - if (child_mask == 0) { - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c4; - traversal_stack[stack_ptr].dist = d4; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2], - &traversal_stack[stack_ptr - 3], - &traversal_stack[stack_ptr - 4]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - /* Six children are hit, push all onto stack and sort 6 - * stack items, continue with closest child. - */ - r = __bscf(child_mask); - int c5 = __float_as_int(cnodes[r]); - float d5 = ((float *)&dist)[r]; - if (child_mask == 0) { - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c5; - traversal_stack[stack_ptr].dist = d5; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c4; - traversal_stack[stack_ptr].dist = d4; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2], - &traversal_stack[stack_ptr - 3], - &traversal_stack[stack_ptr - 4], - &traversal_stack[stack_ptr - 5]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c5; - traversal_stack[stack_ptr].dist = d5; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c4; - traversal_stack[stack_ptr].dist = d4; - - /* Seven children are hit, push all onto stack and sort 7 - * stack items, continue with closest child. - */ - r = __bscf(child_mask); - int c6 = __float_as_int(cnodes[r]); - float d6 = ((float *)&dist)[r]; - if (child_mask == 0) { - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c6; - traversal_stack[stack_ptr].dist = d6; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2], - &traversal_stack[stack_ptr - 3], - &traversal_stack[stack_ptr - 4], - &traversal_stack[stack_ptr - 5], - &traversal_stack[stack_ptr - 6]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - /* Eight children are hit, push all onto stack and sort 8 - * stack items, continue with closest child. - */ - r = __bscf(child_mask); - int c7 = __float_as_int(cnodes[r]); - float d7 = ((float *)&dist)[r]; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c7; - traversal_stack[stack_ptr].dist = d7; - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = c6; - traversal_stack[stack_ptr].dist = d6; - obvh_stack_sort(&traversal_stack[stack_ptr], - &traversal_stack[stack_ptr - 1], - &traversal_stack[stack_ptr - 2], - &traversal_stack[stack_ptr - 3], - &traversal_stack[stack_ptr - 4], - &traversal_stack[stack_ptr - 5], - &traversal_stack[stack_ptr - 6], - &traversal_stack[stack_ptr - 7]); - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } - - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - } - - /* If node is leaf, fetch triangle list. */ - if (node_addr < 0) { - float4 leaf = kernel_tex_fetch(__bvh_leaf_nodes, (-node_addr - 1)); -#ifdef __VISIBILITY_FLAG__ - if ((__float_as_uint(leaf.z) & PATH_RAY_SHADOW) == 0) { - /* Pop. */ - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - continue; - } -#endif - - int prim_addr = __float_as_int(leaf.x); - -#if BVH_FEATURE(BVH_INSTANCING) - if (prim_addr >= 0) { -#endif - int prim_addr2 = __float_as_int(leaf.y); - const uint type = __float_as_int(leaf.w); - const uint p_type = type & PRIMITIVE_ALL; - - /* Pop. */ - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - - /* Primitive intersection. */ - if (p_type == PRIMITIVE_TRIANGLE) { - int prim_count = prim_addr2 - prim_addr; - if (prim_count < 3) { - while (prim_addr < prim_addr2) { - kernel_assert((kernel_tex_fetch(__prim_type, prim_addr) & PRIMITIVE_ALL) == - p_type); - int hit = triangle_intersect( - kg, isect_array, P, dir, PATH_RAY_SHADOW, object, prim_addr); - /* Shadow ray early termination. */ - if (hit) { - /* detect if this surface has a shader with transparent shadows */ - - /* todo: optimize so primitive visibility flag indicates if - * the primitive has a transparent shadow shader? */ - int prim = kernel_tex_fetch(__prim_index, isect_array->prim); - int shader = 0; - -#ifdef __HAIR__ - if (kernel_tex_fetch(__prim_type, isect_array->prim) & PRIMITIVE_ALL_TRIANGLE) -#endif - { - shader = kernel_tex_fetch(__tri_shader, prim); - } -#ifdef __HAIR__ - else { - float4 str = kernel_tex_fetch(__curves, prim); - shader = __float_as_int(str.z); - } -#endif - int flag = kernel_tex_fetch(__shaders, (shader & SHADER_MASK)).flags; - - /* if no transparent shadows, all light is blocked */ - if (!(flag & SD_HAS_TRANSPARENT_SHADOW)) { - return true; - } - /* if maximum number of hits reached, block all light */ - else if (*num_hits == max_hits) { - return true; - } - - /* move on to next entry in intersections array */ - isect_array++; - (*num_hits)++; -#if BVH_FEATURE(BVH_INSTANCING) - num_hits_in_instance++; -#endif - - isect_array->t = isect_t; - } - - prim_addr++; - } // while - } - else { - kernel_assert((kernel_tex_fetch(__prim_type, (prim_addr)) & PRIMITIVE_ALL) == - p_type); - -#if BVH_FEATURE(BVH_INSTANCING) - int *nhiptr = &num_hits_in_instance; -#else - int nhi = 0; - int *nhiptr = &nhi; -#endif - - int result = triangle_intersect8(kg, - &isect_array, - P, - dir, - PATH_RAY_SHADOW, - object, - prim_addr, - prim_count, - num_hits, - max_hits, - nhiptr, - isect_t); - if (result == 2) { - return true; - } - } // prim_count - } // PRIMITIVE_TRIANGLE - else { - while (prim_addr < prim_addr2) { - kernel_assert((kernel_tex_fetch(__prim_type, prim_addr) & PRIMITIVE_ALL) == p_type); - -#ifdef __SHADOW_TRICKS__ - uint tri_object = (object == OBJECT_NONE) ? - kernel_tex_fetch(__prim_object, prim_addr) : - object; - if (tri_object == skip_object) { - ++prim_addr; - continue; - } -#endif - - bool hit; - - /* todo: specialized intersect functions which don't fill in - * isect unless needed and check SD_HAS_TRANSPARENT_SHADOW? - * might give a few % performance improvement */ - - switch (p_type) { - -#if BVH_FEATURE(BVH_MOTION) - case PRIMITIVE_MOTION_TRIANGLE: { - hit = motion_triangle_intersect( - kg, isect_array, P, dir, ray->time, PATH_RAY_SHADOW, object, prim_addr); - break; - } -#endif -#if BVH_FEATURE(BVH_HAIR) - case PRIMITIVE_CURVE: - case PRIMITIVE_MOTION_CURVE: { - const uint curve_type = kernel_tex_fetch(__prim_type, prim_addr); - if (kernel_data.curve.curveflags & CURVE_KN_INTERPOLATE) { - hit = cardinal_curve_intersect(kg, - isect_array, - P, - dir, - PATH_RAY_SHADOW, - object, - prim_addr, - ray->time, - curve_type); - } - else { - hit = curve_intersect(kg, - isect_array, - P, - dir, - PATH_RAY_SHADOW, - object, - prim_addr, - ray->time, - curve_type); - } - break; - } -#endif - default: { - hit = false; - break; - } - } - - /* Shadow ray early termination. */ - if (hit) { - /* detect if this surface has a shader with transparent shadows */ - - /* todo: optimize so primitive visibility flag indicates if - * the primitive has a transparent shadow shader? */ - int prim = kernel_tex_fetch(__prim_index, isect_array->prim); - int shader = 0; - -#ifdef __HAIR__ - if (kernel_tex_fetch(__prim_type, isect_array->prim) & PRIMITIVE_ALL_TRIANGLE) -#endif - { - shader = kernel_tex_fetch(__tri_shader, prim); - } -#ifdef __HAIR__ - else { - float4 str = kernel_tex_fetch(__curves, prim); - shader = __float_as_int(str.z); - } -#endif - int flag = kernel_tex_fetch(__shaders, (shader & SHADER_MASK)).flags; - - /* if no transparent shadows, all light is blocked */ - if (!(flag & SD_HAS_TRANSPARENT_SHADOW)) { - return true; - } - /* if maximum number of hits reached, block all light */ - else if (*num_hits == max_hits) { - return true; - } - - /* move on to next entry in intersections array */ - isect_array++; - (*num_hits)++; -#if BVH_FEATURE(BVH_INSTANCING) - num_hits_in_instance++; -#endif - - isect_array->t = isect_t; - } - - prim_addr++; - } // while prim - } - } -#if BVH_FEATURE(BVH_INSTANCING) - else { - /* Instance push. */ - object = kernel_tex_fetch(__prim_object, -prim_addr - 1); - -# if BVH_FEATURE(BVH_MOTION) - isect_t = bvh_instance_motion_push(kg, object, ray, &P, &dir, &idir, isect_t, &ob_itfm); -# else - isect_t = bvh_instance_push(kg, object, ray, &P, &dir, &idir, isect_t); -# endif - - num_hits_in_instance = 0; - isect_array->t = isect_t; - - obvh_near_far_idx_calc(idir, &near_x, &near_y, &near_z, &far_x, &far_y, &far_z); - tfar = avxf(isect_t); -# if BVH_FEATURE(BVH_HAIR) - dir4 = avx3f(avxf(dir.x), avxf(dir.y), avxf(dir.z)); -# endif - idir4 = avx3f(avxf(idir.x), avxf(idir.y), avxf(idir.z)); -# ifdef __KERNEL_AVX2__ - P_idir = P * idir; - P_idir4 = avx3f(P_idir.x, P_idir.y, P_idir.z); -# endif -# if BVH_FEATURE(BVH_HAIR) || !defined(__KERNEL_AVX2__) - org4 = avx3f(avxf(P.x), avxf(P.y), avxf(P.z)); -# endif - - ++stack_ptr; - kernel_assert(stack_ptr < BVH_OSTACK_SIZE); - traversal_stack[stack_ptr].addr = ENTRYPOINT_SENTINEL; - - node_addr = kernel_tex_fetch(__object_node, object); - } - } -#endif /* FEATURE(BVH_INSTANCING) */ - } while (node_addr != ENTRYPOINT_SENTINEL); - -#if BVH_FEATURE(BVH_INSTANCING) - if (stack_ptr >= 0) { - kernel_assert(object != OBJECT_NONE); - - /* Instance pop. */ - if (num_hits_in_instance) { - float t_fac; -# if BVH_FEATURE(BVH_MOTION) - bvh_instance_motion_pop_factor(kg, object, ray, &P, &dir, &idir, &t_fac, &ob_itfm); -# else - bvh_instance_pop_factor(kg, object, ray, &P, &dir, &idir, &t_fac); -# endif - /* Scale isect->t to adjust for instancing. */ - for (int i = 0; i < num_hits_in_instance; i++) { - (isect_array - i - 1)->t *= t_fac; - } - } - else { -# if BVH_FEATURE(BVH_MOTION) - bvh_instance_motion_pop(kg, object, ray, &P, &dir, &idir, FLT_MAX, &ob_itfm); -# else - bvh_instance_pop(kg, object, ray, &P, &dir, &idir, FLT_MAX); -# endif - } - - isect_t = tmax; - isect_array->t = isect_t; - - obvh_near_far_idx_calc(idir, &near_x, &near_y, &near_z, &far_x, &far_y, &far_z); - tfar = avxf(isect_t); -# if BVH_FEATURE(BVH_HAIR) - dir4 = avx3f(avxf(dir.x), avxf(dir.y), avxf(dir.z)); -# endif - idir4 = avx3f(avxf(idir.x), avxf(idir.y), avxf(idir.z)); -# ifdef __KERNEL_AVX2__ - P_idir = P * idir; - P_idir4 = avx3f(P_idir.x, P_idir.y, P_idir.z); -# endif -# if BVH_FEATURE(BVH_HAIR) || !defined(__KERNEL_AVX2__) - org4 = avx3f(avxf(P.x), avxf(P.y), avxf(P.z)); -# endif - - object = OBJECT_NONE; - node_addr = traversal_stack[stack_ptr].addr; - --stack_ptr; - } -#endif /* FEATURE(BVH_INSTANCING) */ - } while (node_addr != ENTRYPOINT_SENTINEL); - - return false; -} - -#undef NODE_INTERSECT |