diff options
Diffstat (limited to 'source/blender/blenlib/intern/BLI_kdopbvh.c')
-rw-r--r-- | source/blender/blenlib/intern/BLI_kdopbvh.c | 722 |
1 files changed, 634 insertions, 88 deletions
diff --git a/source/blender/blenlib/intern/BLI_kdopbvh.c b/source/blender/blenlib/intern/BLI_kdopbvh.c index 4ceb9762a7b..ddea701dac5 100644 --- a/source/blender/blenlib/intern/BLI_kdopbvh.c +++ b/source/blender/blenlib/intern/BLI_kdopbvh.c @@ -1,5 +1,7 @@ /** * + * $Id$ + * * ***** BEGIN GPL LICENSE BLOCK ***** * * This program is free software; you can redistribute it and/or @@ -28,8 +30,9 @@ #include "math.h" #include <stdio.h> -#include <stdlib.h> +#include <stdlib.h> #include <string.h> +#include <assert.h> #include "MEM_guardedalloc.h" @@ -44,11 +47,11 @@ typedef struct BVHNode { - struct BVHNode **children; // max 8 children + struct BVHNode **children; // max 8 children struct BVHNode *parent; // needed for bottom - top update - float *bv; // Bounding volume of all nodes, max 13 axis - int index; /* face, edge, vertex index */ - char totnode; // how many nodes are used, used for speedup + float *bv; // Bounding volume of all nodes, max 13 axis + int index; // face, edge, vertex index + char totnode; // how many nodes are used, used for speedup char traversed; // how many nodes already traversed until this level? char main_axis; } BVHNode; @@ -73,7 +76,32 @@ typedef struct BVHOverlapData BVHTreeOverlap *overlap; int i, max_overlap; /* i is number of overlaps */ } BVHOverlapData; -//////////////////////////////////////// + +typedef struct BVHNearestData +{ + BVHTree *tree; + float *co; + BVHTree_NearestPointCallback callback; + void *userdata; + float proj[13]; //coordinates projection over axis + BVHTreeNearest nearest; + +} BVHNearestData; + +typedef struct BVHRayCastData +{ + BVHTree *tree; + + BVHTree_RayCastCallback callback; + void *userdata; + + + BVHTreeRay ray; + float ray_dot_axis[13]; + + BVHTreeRayHit hit; +} BVHRayCastData; +////////////////////////////////////////m //////////////////////////////////////////////////////////////////////// @@ -244,7 +272,7 @@ int partition_nth_element(BVHNode **a, int _begin, int _end, int n, int axis){ int begin = _begin, end = _end, cut; while(end-begin > 3) { - cut = bvh_partition(a, begin, end, bvh_medianof3(a, begin, (begin+end)/2, end-1, axis), axis ); + cut = bvh_partition(a, begin, end, bvh_medianof3(a, begin, (begin+end)/2, end-1, axis), axis ); if(cut <= n) begin = cut; else @@ -255,7 +283,6 @@ int partition_nth_element(BVHNode **a, int _begin, int _end, int n, int axis){ return n; } - ////////////////////////////////////////////////////////////////////////////////////////////////////// void BLI_bvhtree_free(BVHTree *tree) @@ -270,13 +297,35 @@ void BLI_bvhtree_free(BVHTree *tree) } } +// calculate max number of branches +int needed_branches(int tree_type, int leafs) +{ +#if 1 + //Worst case scenary ( return max(0, leafs-tree_type)+1 ) + if(leafs <= tree_type) + return 1; + else + return leafs-tree_type+1; + +#else + //If our bvh kdop is "almost perfect" + //TODO i dont trust the float arithmetic in here (and I am not sure this formula is according to our splitting method) + int i, numbranches = 0; + for(i = 1; i <= (int)ceil((float)((float)log(leafs)/(float)log(tree_type))); i++) + numbranches += (pow(tree_type, i) / tree_type); + + return numbranches; +#endif +} + + BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) { BVHTree *tree; - int numbranches=0, i; + int numnodes, i; - // only support up to octree - if(tree_type > 8) + // theres not support for trees below binary-trees :P + if(tree_type < 2) return NULL; tree = (BVHTree *)MEM_callocN(sizeof(BVHTree), "BVHTree"); @@ -319,11 +368,10 @@ BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) } - // calculate max number of branches, our bvh kdop is "almost perfect" - for(i = 1; i <= (int)ceil((float)((float)log(maxsize)/(float)log(tree_type))); i++) - numbranches += (pow(tree_type, i) / tree_type); - - tree->nodes = (BVHNode **)MEM_callocN(sizeof(BVHNode *)*(numbranches+maxsize + tree_type), "BVHNodes"); + //Allocate arrays + numnodes = maxsize + needed_branches(tree_type, maxsize) + tree_type; + + tree->nodes = (BVHNode **)MEM_callocN(sizeof(BVHNode *)*numnodes, "BVHNodes"); if(!tree->nodes) { @@ -331,14 +379,14 @@ BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) return NULL; } - tree->nodebv = (float*)MEM_callocN(sizeof(float)* axis * (numbranches+maxsize + tree_type), "BVHNodeBV"); + tree->nodebv = (float*)MEM_callocN(sizeof(float)* axis * numnodes, "BVHNodeBV"); if(!tree->nodebv) { MEM_freeN(tree->nodes); MEM_freeN(tree); } - tree->nodechild = (BVHNode**)MEM_callocN(sizeof(BVHNode*) * tree_type * (numbranches+maxsize + tree_type), "BVHNodeBV"); + tree->nodechild = (BVHNode**)MEM_callocN(sizeof(BVHNode*) * tree_type * numnodes, "BVHNodeBV"); if(!tree->nodechild) { MEM_freeN(tree->nodebv); @@ -346,7 +394,7 @@ BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) MEM_freeN(tree); } - tree->nodearray = (BVHNode *)MEM_callocN(sizeof(BVHNode)*(numbranches+maxsize + tree_type), "BVHNodeArray"); + tree->nodearray = (BVHNode *)MEM_callocN(sizeof(BVHNode)* numnodes, "BVHNodeArray"); if(!tree->nodearray) { @@ -358,7 +406,7 @@ BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) } //link the dynamic bv and child links - for(i=0; i< numbranches+maxsize + tree_type; i++) + for(i=0; i< numnodes; i++) { tree->nodearray[i].bv = tree->nodebv + i * axis; tree->nodearray[i].children = tree->nodechild + i * tree_type; @@ -373,6 +421,7 @@ BVHTree *BLI_bvhtree_new(int maxsize, float epsilon, char tree_type, char axis) static void create_kdop_hull(BVHTree *tree, BVHNode *node, float *co, int numpoints, int moving) { float newminmax; + float *bv = node->bv; int i, k; // don't init boudings for the moving case @@ -380,8 +429,8 @@ static void create_kdop_hull(BVHTree *tree, BVHNode *node, float *co, int numpoi { for (i = tree->start_axis; i < tree->stop_axis; i++) { - node->bv[2*i] = FLT_MAX; - node->bv[2*i + 1] = -FLT_MAX; + bv[2*i] = FLT_MAX; + bv[2*i + 1] = -FLT_MAX; } } @@ -391,10 +440,10 @@ static void create_kdop_hull(BVHTree *tree, BVHNode *node, float *co, int numpoi for (i = tree->start_axis; i < tree->stop_axis; i++) { newminmax = INPR(&co[k * 3], KDOP_AXES[i]); - if (newminmax < node->bv[2 * i]) - node->bv[2 * i] = newminmax; - if (newminmax > node->bv[(2 * i) + 1]) - node->bv[(2 * i) + 1] = newminmax; + if (newminmax < bv[2 * i]) + bv[2 * i] = newminmax; + if (newminmax > bv[(2 * i) + 1]) + bv[(2 * i) + 1] = newminmax; } } } @@ -405,6 +454,7 @@ static void refit_kdop_hull(BVHTree *tree, BVHNode *node, int start, int end) float newmin,newmax; int i, j; float *bv = node->bv; + for (i = tree->start_axis; i < tree->stop_axis; i++) { @@ -426,18 +476,19 @@ static void refit_kdop_hull(BVHTree *tree, BVHNode *node, int start, int end) bv[(2 * i) + 1] = newmax; } } + } int BLI_bvhtree_insert(BVHTree *tree, int index, float *co, int numpoints) { - BVHNode *node= NULL; int i; + BVHNode *node = NULL; // insert should only possible as long as tree->totbranch is 0 if(tree->totbranch > 0) return 0; - if(tree->totleaf+1 >= MEM_allocN_len(tree->nodes)) + if(tree->totleaf+1 >= MEM_allocN_len(tree->nodes)/sizeof(*(tree->nodes))) return 0; // TODO check if have enough nodes in array @@ -446,6 +497,7 @@ int BLI_bvhtree_insert(BVHTree *tree, int index, float *co, int numpoints) tree->totleaf++; create_kdop_hull(tree, node, co, numpoints, 0); + node->index= index; // inflate the bv with some epsilon for (i = tree->start_axis; i < tree->stop_axis; i++) @@ -454,8 +506,6 @@ int BLI_bvhtree_insert(BVHTree *tree, int index, float *co, int numpoints) node->bv[(2 * i) + 1] += tree->epsilon; // maximum } - node->index= index; - return 1; } @@ -484,21 +534,24 @@ static char get_largest_axis(float *bv) } } -static void bvh_div_nodes(BVHTree *tree, BVHNode *node, int start, int end) +static void bvh_div_nodes(BVHTree *tree, BVHNode *node, int start, int end, int free_node_index) { - int i, tend; - BVHNode *tnode; - int slice = (end-start+tree->tree_type-1)/tree->tree_type; //division rounded up + int i; + + const char laxis = get_largest_axis(node->bv); //determine longest axis to split along + const int slice = (end-start)/tree->tree_type; //division rounded down + const int rest = (end-start)%tree->tree_type; //remainder of division - // Determine which axis to split along - char laxis = get_largest_axis(node->bv); + assert( node->totnode == 0 ); + + node->main_axis = laxis/2; // split nodes along longest axis - for (i=0; start < end; start += slice, i++) //i counts the current child + for (i=0; start < end; node->totnode = ++i) //i counts the current child { - tend = start + slice; + int tend = start + slice + (i < rest ? 1 : 0); - if(tend > end) tend = end; + assert( tend <= end); if(tend-start == 1) // ok, we have 1 left for this node { @@ -507,87 +560,332 @@ static void bvh_div_nodes(BVHTree *tree, BVHNode *node, int start, int end) } else { - tnode = node->children[i] = tree->nodes[tree->totleaf + tree->totbranch] = &(tree->nodearray[tree->totbranch + tree->totleaf]); - tree->totbranch++; + BVHNode *tnode = node->children[i] = tree->nodes[free_node_index] = &(tree->nodearray[free_node_index]); tnode->parent = node; if(tend != end) partition_nth_element(tree->nodes, start, end, tend, laxis); + refit_kdop_hull(tree, tnode, start, tend); - bvh_div_nodes(tree, tnode, start, tend); + + bvh_div_nodes(tree, tnode, start, tend, free_node_index+1); + free_node_index += needed_branches(tree->tree_type, tend-start); } - node->totnode++; + start = tend; } return; } +static void omp_bvh_div_nodes(BVHTree *tree, BVHNode *node, int start, int end, int free_node_index) +{ + int i; + + const char laxis = get_largest_axis(node->bv); //determine longest axis to split along + const int slice = (end-start)/tree->tree_type; //division rounded down + const int rest = (end-start)%tree->tree_type; //remainder of division + + int omp_data_start[tree->tree_type]; + int omp_data_end [tree->tree_type]; + int omp_data_index[tree->tree_type]; + + assert( node->totnode == 0 ); + + node->main_axis = laxis/2; + + // split nodes along longest axis + for (i=0; start < end; node->totnode = ++i) //i counts the current child + { + //Split the rest from left to right (TODO: this doenst makes an optimal tree) + int tend = start + slice + (i < rest ? 1 : 0); + + assert( tend <= end); + + //save data for later OMP + omp_data_start[i] = start; + omp_data_end [i] = tend; + omp_data_index[i] = free_node_index; + + if(tend-start == 1) + { + node->children[i] = tree->nodes[start]; + node->children[i]->parent = node; + } + else + { + node->children[i] = tree->nodes[free_node_index] = &(tree->nodearray[free_node_index]); + node->children[i]->parent = node; + + if(tend != end) + partition_nth_element(tree->nodes, start, end, tend, laxis); + + free_node_index += needed_branches(tree->tree_type, tend-start); + } + + start = tend; + } + +#pragma omp parallel for private(i) schedule(static) + for( i = 0; i < node->totnode; i++) + { + if(omp_data_end[i]-omp_data_start[i] > 1) + { + BVHNode *tnode = node->children[i]; + refit_kdop_hull(tree, tnode, omp_data_start[i], omp_data_end[i]); + bvh_div_nodes (tree, tnode, omp_data_start[i], omp_data_end[i], omp_data_index[i]+1); + } + } + + return; +} + + +static void print_tree(BVHTree *tree, BVHNode *node, int depth) +{ + int i; + for(i=0; i<depth; i++) printf(" "); + printf(" - %d (%d): ", node->index, node - tree->nodearray); + for(i=2*tree->start_axis; i<2*tree->stop_axis; i++) + printf("%.3f ", node->bv[i]); + printf("\n"); + + for(i=0; i<tree->tree_type; i++) + if(node->children[i]) + print_tree(tree, node->children[i], depth+1); +} + #if 0 + static void verify_tree(BVHTree *tree) { int i, j, check = 0; // check the pointer list for(i = 0; i < tree->totleaf; i++) - { +{ if(tree->nodes[i]->parent == NULL) printf("Leaf has no parent: %d\n", i); - else - { - for(j = 0; j < tree->tree_type; j++) - { - if(tree->nodes[i]->parent->children[j] == tree->nodes[i]) - check = 1; - } - if(!check) - { - printf("Parent child relationship doesn't match: %d\n", i); - } - check = 0; - } - } + else +{ + for(j = 0; j < tree->tree_type; j++) +{ + if(tree->nodes[i]->parent->children[j] == tree->nodes[i]) + check = 1; +} + if(!check) +{ + printf("Parent child relationship doesn't match: %d\n", i); +} + check = 0; +} +} // check the leaf list - for(i = 0; i < tree->totleaf; i++) + for(i = 0; i < tree->totleaf; i++) +{ + if(tree->nodearray[i].parent == NULL) + printf("Leaf has no parent: %d\n", i); + else +{ + for(j = 0; j < tree->tree_type; j++) +{ + if(tree->nodearray[i].parent->children[j] == &tree->nodearray[i]) + check = 1; +} + if(!check) +{ + printf("Parent child relationship doesn't match: %d\n", i); +} + check = 0; +} +} + + printf("branches: %d, leafs: %d, total: %d\n", tree->totbranch, tree->totleaf, tree->totbranch + tree->totleaf); +} +#endif + +//Helper data and structures to build generalized implicit trees +//This code can be easily reduced +typedef struct BVHBuildHelper +{ + int tree_type; // + int totleafs; // + + int leafs_per_child [32]; //Min number of leafs that are archievable from a node at depth N + int branches_on_level[32]; //Number of nodes at depth N (tree_type^N) + + int remain_leafs; //Number of leafs that are placed on the level that is not 100% filled + +} BVHBuildHelper; + +static void build_implicit_tree_helper(BVHTree *tree, BVHBuildHelper *data) +{ + int depth = 0; + int remain; + int nnodes; + + data->totleafs = tree->totleaf; + data->tree_type= tree->tree_type; + + //Calculate the smallest tree_type^n such that tree_type^n >= num_leafs + for( + data->leafs_per_child[0] = 1; + data->leafs_per_child[0] < data->totleafs; + data->leafs_per_child[0] *= data->tree_type + ); + + data->branches_on_level[0] = 1; + + //We could stop the loop first (but I am lazy to find out when) + for(depth = 1; depth < 32; depth++) { - if(tree->nodearray[i].parent == NULL) - printf("Leaf has no parent: %d\n", i); - else + data->branches_on_level[depth] = data->branches_on_level[depth-1] * data->tree_type; + data->leafs_per_child [depth] = data->leafs_per_child [depth-1] / data->tree_type; + } + + remain = data->totleafs - data->leafs_per_child[1]; + nnodes = (remain + data->tree_type - 2) / (data->tree_type - 1); + data->remain_leafs = remain + nnodes; +} + +// return the min index of all the leafs archivable with the given branch +static int implicit_leafs_index(BVHBuildHelper *data, int depth, int child_index) +{ + int min_leaf_index = child_index * data->leafs_per_child[depth-1]; + if(min_leaf_index <= data->remain_leafs) + return min_leaf_index; + else if(data->leafs_per_child[depth]) + return data->totleafs - (data->branches_on_level[depth-1] - child_index) * data->leafs_per_child[depth]; + else + return data->remain_leafs; +} + +//WARNING: Beautiful/tricky code starts here :P +//Generalized implicit trees +static void non_recursive_bvh_div_nodes(BVHTree *tree) +{ + int i; + + const int tree_type = tree->tree_type; + const int tree_offset = 2 - tree->tree_type; //this value is 0 (on binary trees) and negative on the others + const int num_leafs = tree->totleaf; + const int num_branches= MAX2(1, (num_leafs + tree_type - 3) / (tree_type-1) ); + + BVHNode* branches_array = tree->nodearray + tree->totleaf - 1; // This code uses 1 index arrays + BVHNode** leafs_array = tree->nodes; + + BVHBuildHelper data; + int depth = 0; + + build_implicit_tree_helper(tree, &data); + + //YAY this could be 1 loop.. but had to split in 2 to remove OMP dependencies + for(i=1; i <= num_branches; i = i*tree_type + tree_offset) + { + const int first_of_next_level = i*tree_type + tree_offset; + const int end_j = MIN2(first_of_next_level, num_branches + 1); //index of last branch on this level + int j; + + depth++; + +#pragma omp parallel for private(j) schedule(static) + for(j = i; j < end_j; j++) { - for(j = 0; j < tree->tree_type; j++) - { - if(tree->nodearray[i].parent->children[j] == &tree->nodearray[i]) - check = 1; - } - if(!check) + int k; + const int parent_level_index= j-i; + BVHNode* parent = branches_array + j; + char split_axis; + + int parent_leafs_begin = implicit_leafs_index(&data, depth, parent_level_index); + int parent_leafs_end = implicit_leafs_index(&data, depth, parent_level_index+1); + + //split_axis = (depth*2 % 6); //use this instead of the 2 following lines for XYZ splitting + + refit_kdop_hull(tree, parent, parent_leafs_begin, parent_leafs_end); + split_axis = get_largest_axis(parent->bv); + + parent->main_axis = split_axis / 2; + + for(k = 0; k < tree_type; k++) { - printf("Parent child relationship doesn't match: %d\n", i); + int child_index = j * tree_type + tree_offset + k; + int child_level_index = child_index - first_of_next_level; //child level index + + int child_leafs_begin = implicit_leafs_index(&data, depth+1, child_level_index); + int child_leafs_end = implicit_leafs_index(&data, depth+1, child_level_index+1); + + assert( k != 0 || child_leafs_begin == parent_leafs_begin); + + if(child_leafs_end - child_leafs_begin > 1) + { + parent->children[k] = branches_array + child_index; + parent->children[k]->parent = parent; + +/* + printf("Add child %d (%d) to branch %d\n", + branches_array + child_index - tree->nodearray, + branches_array[ child_index ].index, + parent - tree->nodearray + ); +*/ + + partition_nth_element(leafs_array, child_leafs_begin, parent_leafs_end, child_leafs_end, split_axis); + } + else if(child_leafs_end - child_leafs_begin == 1) + { +/* + printf("Add child %d (%d) to branch %d\n", + leafs_array[ child_leafs_begin ] - tree->nodearray, + leafs_array[ child_leafs_begin ]->index, + parent - tree->nodearray + ); +*/ + parent->children[k] = leafs_array[ child_leafs_begin ]; + parent->children[k]->parent = parent; + } + else + { + parent->children[k] = NULL; + break; + } + parent->totnode = k+1; } - check = 0; } } - - printf("branches: %d, leafs: %d, total: %d\n", tree->totbranch, tree->totleaf, tree->totbranch + tree->totleaf); + + + for(i = 0; i<num_branches; i++) + tree->nodes[tree->totleaf + i] = branches_array + 1 + i; + + tree->totbranch = num_branches; + +// BLI_bvhtree_update_tree(tree); //Uncoment this for XYZ splitting } -#endif - + void BLI_bvhtree_balance(BVHTree *tree) { - BVHNode *node; - - if(tree->totleaf == 0) - return; - - // create root node - node = tree->nodes[tree->totleaf] = &(tree->nodearray[tree->totleaf]); + if(tree->totleaf == 0) return; + + assert(tree->totbranch == 0); + non_recursive_bvh_div_nodes(tree); + +/* + if(tree->totleaf != 0) + { + // create root node + BVHNode *node = tree->nodes[tree->totleaf] = &(tree->nodearray[tree->totleaf]); tree->totbranch++; - - // refit root bvh node - refit_kdop_hull(tree, tree->nodes[tree->totleaf], 0, tree->totleaf); - // create + balance tree - bvh_div_nodes(tree, tree->nodes[tree->totleaf], 0, tree->totleaf); - - // verify_tree(tree); + < + // refit root bvh node + refit_kdop_hull(tree, node, 0, tree->totleaf); + + // create + balance tree + omp_bvh_div_nodes(tree, node, 0, tree->totleaf, tree->totleaf+1); + tree->totbranch = needed_branches( tree->tree_type, tree->totleaf ); + // verify_tree(tree); +} +*/ + } // overlap - is it possbile for 2 bv's to collide ? @@ -724,6 +1022,7 @@ BVHTreeOverlap *BLI_bvhtree_overlap(BVHTree *tree1, BVHTree *tree2, int *result) } + // bottom up update of bvh tree: // join the 4 children here static void node_join(BVHTree *tree, BVHNode *node) @@ -809,3 +1108,250 @@ float BLI_bvhtree_getepsilon(BVHTree *tree) { return tree->epsilon; } + + + + +/* + * Nearest neighbour + */ +static float squared_dist(const float *a, const float *b) +{ + float tmp[3]; + VECSUB(tmp, a, b); + return INPR(tmp, tmp); +} + +static float calc_nearest_point(BVHNearestData *data, BVHNode *node, float *nearest) +{ + int i; + const float *bv = node->bv; + + //nearest on AABB hull + for(i=0; i != 3; i++, bv += 2) + { + if(bv[0] > data->proj[i]) + nearest[i] = bv[0]; + else if(bv[1] < data->proj[i]) + nearest[i] = bv[1]; + else + nearest[i] = data->proj[i]; + } + +/* + //nearest on a general hull + VECCOPY(nearest, data->co); + for(i = data->tree->start_axis; i != data->tree->stop_axis; i++, bv+=2) + { + float proj = INPR( nearest, KDOP_AXES[i]); + float dl = bv[0] - proj; + float du = bv[1] - proj; + + if(dl > 0) + { + VECADDFAC(nearest, nearest, KDOP_AXES[i], dl); +} + else if(du < 0) + { + VECADDFAC(nearest, nearest, KDOP_AXES[i], du); +} +} +*/ + return squared_dist(data->co, nearest); +} + + +// TODO: use a priority queue to reduce the number of nodes looked on +static void dfs_find_nearest(BVHNearestData *data, BVHNode *node) +{ + int i; + float nearest[3], sdist; + + sdist = calc_nearest_point(data, node, nearest); + if(sdist >= data->nearest.dist) return; + + if(node->totnode == 0) + { + if(data->callback) + data->callback(data->userdata , node->index, data->co, &data->nearest); + else + { + data->nearest.index = node->index; + VECCOPY(data->nearest.co, nearest); + data->nearest.dist = sdist; + } + } + else + { + for(i=0; i != node->totnode; i++) + dfs_find_nearest(data, node->children[i]); + } +} + +int BLI_bvhtree_find_nearest(BVHTree *tree, const float *co, BVHTreeNearest *nearest, BVHTree_NearestPointCallback callback, void *userdata) +{ + int i; + + BVHNearestData data; + + //init data to search + data.tree = tree; + data.co = co; + + data.callback = callback; + data.userdata = userdata; + + for(i = data.tree->start_axis; i != data.tree->stop_axis; i++) + { + data.proj[i] = INPR(data.co, KDOP_AXES[i]); + } + + if(nearest) + { + memcpy( &data.nearest , nearest, sizeof(*nearest) ); + } + else + { + data.nearest.index = -1; + data.nearest.dist = FLT_MAX; + } + + //dfs search + dfs_find_nearest(&data, tree->nodes[tree->totleaf] ); + + //copy back results + if(nearest) + { + memcpy(nearest, &data.nearest, sizeof(*nearest)); + } + + return data.nearest.index; +} + + + +/* + * Ray cast + */ + +static float ray_nearest_hit(BVHRayCastData *data, BVHNode *node) +{ + int i; + const float *bv = node->bv; + + float low = 0, upper = data->hit.dist; + + for(i=0; i != 3; i++, bv += 2) + { + if(data->ray_dot_axis[i] == 0.0f) + { + //axis aligned ray + if(data->ray.origin[i] < bv[0] + || data->ray.origin[i] > bv[1]) + return FLT_MAX; + } + else + { + float ll = (bv[0] - data->ray.origin[i]) / data->ray_dot_axis[i]; + float lu = (bv[1] - data->ray.origin[i]) / data->ray_dot_axis[i]; + + if(data->ray_dot_axis[i] > 0) + { + if(ll > low) low = ll; + if(lu < upper) upper = lu; + } + else + { + if(lu > low) low = lu; + if(ll < upper) upper = ll; + } + + if(low > upper) return FLT_MAX; + } + } + return low; +} + +static void dfs_raycast(BVHRayCastData *data, BVHNode *node) +{ + int i; + + //ray-bv is really fast.. and simple tests revealed its worth to test it + //before calling the ray-primitive functions + float dist = ray_nearest_hit(data, node); + if(dist >= data->hit.dist) return; + + if(node->totnode == 0) + { + if(data->callback) + data->callback(data->userdata, node->index, &data->ray, &data->hit); + else + { + data->hit.index = node->index; + data->hit.dist = dist; + VECADDFAC(data->hit.co, data->ray.origin, data->ray.direction, dist); + } + } + else + { + //pick loop direction to dive into the tree (based on ray direction and split axis) + if(data->ray_dot_axis[ node->main_axis ] > 0) + { + for(i=0; i != node->totnode; i++) + { + dfs_raycast(data, node->children[i]); + } + } + else + { + for(i=node->totnode-1; i >= 0; i--) + { + dfs_raycast(data, node->children[i]); + } + } + } +} + + + +int BLI_bvhtree_ray_cast(BVHTree *tree, const float *co, const float *dir, BVHTreeRayHit *hit, BVHTree_RayCastCallback callback, void *userdata) +{ + int i; + BVHRayCastData data; + + data.tree = tree; + + data.callback = callback; + data.userdata = userdata; + + VECCOPY(data.ray.origin, co); + VECCOPY(data.ray.direction, dir); + + Normalize(data.ray.direction); + + for(i=0; i<3; i++) + { + data.ray_dot_axis[i] = INPR( data.ray.direction, KDOP_AXES[i]); + + if(fabs(data.ray_dot_axis[i]) < 1e-7) + data.ray_dot_axis[i] = 0.0; + } + + + if(hit) + memcpy( &data.hit, hit, sizeof(*hit) ); + else + { + data.hit.index = -1; + data.hit.dist = FLT_MAX; + } + + dfs_raycast(&data, tree->nodes[tree->totleaf]); + + + if(hit) + memcpy( hit, &data.hit, sizeof(*hit) ); + + return data.hit.index; +} + |