virtualx-engine/thirdparty/embree/kernels/bvh/bvh_node_aabb.h

// Copyright 2009-2021 Intel Corporation
// SPDX-License-Identifier: Apache-2.0

#pragma once

#include "bvh_node_base.h"

namespace embree
{
  /*! BVHN AABBNode */
  template<typename NodeRef, int N>
    struct AABBNode_t : public BaseNode_t<NodeRef, N>
  {
    using BaseNode_t<NodeRef,N>::children;
    
    struct Create
    {
      __forceinline NodeRef operator() (const FastAllocator::CachedAllocator& alloc, size_t numChildren = 0) const
      {
        AABBNode_t* node = (AABBNode_t*) alloc.malloc0(sizeof(AABBNode_t),NodeRef::byteNodeAlignment); node->clear();
        return NodeRef::encodeNode(node);
      }
    };
    
    struct Set
    {
      __forceinline void operator() (NodeRef node, size_t i, NodeRef child, const BBox3fa& bounds) const {
        node.getAABBNode()->setRef(i,child);
        node.getAABBNode()->setBounds(i,bounds);
      }
    };
    
    struct Create2
    {
      template<typename BuildRecord>
      __forceinline NodeRef operator() (BuildRecord* children, const size_t num, const FastAllocator::CachedAllocator& alloc) const
      {
        AABBNode_t* node = (AABBNode_t*) alloc.malloc0(sizeof(AABBNode_t), NodeRef::byteNodeAlignment); node->clear();
        for (size_t i=0; i<num; i++) node->setBounds(i,children[i].bounds());
        return NodeRef::encodeNode(node);
      }
    };
    
    struct Set2
    {
      template<typename BuildRecord>
      __forceinline NodeRef operator() (const BuildRecord& precord, const BuildRecord* crecords, NodeRef ref, NodeRef* children, const size_t num) const
      {
#if defined(DEBUG)
        // check that empty children are only at the end of the child list
        bool emptyChild = false;
        for (size_t i=0; i<num; i++) {
          emptyChild |= (children[i] == NodeRef::emptyNode);
          assert(emptyChild == (children[i] == NodeRef::emptyNode));
        }
#endif
        AABBNode_t* node = ref.getAABBNode();
        for (size_t i=0; i<num; i++) node->setRef(i,children[i]);
        return ref;
      }
    };
    
    struct Set3
    {
      Set3 (FastAllocator* allocator, PrimRef* prims)
      : allocator(allocator), prims(prims) {}
      
      template<typename BuildRecord>
      __forceinline NodeRef operator() (const BuildRecord& precord, const BuildRecord* crecords, NodeRef ref, NodeRef* children, const size_t num) const
      {
#if defined(DEBUG)
        // check that empty children are only at the end of the child list
        bool emptyChild = false;
        for (size_t i=0; i<num; i++) {
          emptyChild |= (children[i] == NodeRef::emptyNode);
          assert(emptyChild == (children[i] == NodeRef::emptyNode));
        }
#endif
        AABBNode_t* node = ref.getAABBNode();
        for (size_t i=0; i<num; i++) node->setRef(i,children[i]);
        
        if (unlikely(precord.alloc_barrier))
        {
          PrimRef* begin = &prims[precord.prims.begin()];
          PrimRef* end   = &prims[precord.prims.end()]; // FIXME: extended end for spatial split builder!!!!!
          size_t bytes = (size_t)end - (size_t)begin;
          allocator->addBlock(begin,bytes);
        }
        
        return ref;
      }
      
      FastAllocator* const allocator;
      PrimRef* const prims;
    };
    
    /*! Clears the node. */
    __forceinline void clear() {
      lower_x = lower_y = lower_z = pos_inf;
      upper_x = upper_y = upper_z = neg_inf;
      BaseNode_t<NodeRef,N>::clear();
    }
    
    /*! Sets bounding box and ID of child. */
    __forceinline void setRef(size_t i, const NodeRef& ref) {
      assert(i < N);
      children[i] = ref;
    }
    
    /*! Sets bounding box of child. */
    __forceinline void setBounds(size_t i, const BBox3fa& bounds)
    {
      assert(i < N);
      lower_x[i] = bounds.lower.x; lower_y[i] = bounds.lower.y; lower_z[i] = bounds.lower.z;
      upper_x[i] = bounds.upper.x; upper_y[i] = bounds.upper.y; upper_z[i] = bounds.upper.z;
    }
    
    /*! Sets bounding box and ID of child. */
    __forceinline void set(size_t i, const NodeRef& ref, const BBox3fa& bounds) {
      setBounds(i,bounds);
      children[i] = ref;
    }
    
    /*! Returns bounds of node. */
    __forceinline BBox3fa bounds() const {
      const Vec3fa lower(reduce_min(lower_x),reduce_min(lower_y),reduce_min(lower_z));
      const Vec3fa upper(reduce_max(upper_x),reduce_max(upper_y),reduce_max(upper_z));
      return BBox3fa(lower,upper);
    }
    
    /*! Returns bounds of specified child. */
    __forceinline BBox3fa bounds(size_t i) const
    {
      assert(i < N);
      const Vec3fa lower(lower_x[i],lower_y[i],lower_z[i]);
      const Vec3fa upper(upper_x[i],upper_y[i],upper_z[i]);
      return BBox3fa(lower,upper);
    }
    
    /*! Returns extent of bounds of specified child. */
    __forceinline Vec3fa extend(size_t i) const {
      return bounds(i).size();
    }
    
    /*! Returns bounds of all children (implemented later as specializations) */
    __forceinline void bounds(BBox<vfloat4>& bounds0, BBox<vfloat4>& bounds1, BBox<vfloat4>& bounds2, BBox<vfloat4>& bounds3) const;
    
    /*! swap two children of the node */
    __forceinline void swap(size_t i, size_t j)
    {
      assert(i<N && j<N);
      std::swap(children[i],children[j]);
      std::swap(lower_x[i],lower_x[j]);
      std::swap(lower_y[i],lower_y[j]);
      std::swap(lower_z[i],lower_z[j]);
      std::swap(upper_x[i],upper_x[j]);
      std::swap(upper_y[i],upper_y[j]);
      std::swap(upper_z[i],upper_z[j]);
    }

    /*! swap the children of two nodes */
    __forceinline static void swap(AABBNode_t* a, size_t i, AABBNode_t* b, size_t j)
    {
      assert(i<N && j<N);
      std::swap(a->children[i],b->children[j]);
      std::swap(a->lower_x[i],b->lower_x[j]);
      std::swap(a->lower_y[i],b->lower_y[j]);
      std::swap(a->lower_z[i],b->lower_z[j]);
      std::swap(a->upper_x[i],b->upper_x[j]);
      std::swap(a->upper_y[i],b->upper_y[j]);
      std::swap(a->upper_z[i],b->upper_z[j]);
    }

    /*! compacts a node (moves empty children to the end) */
    __forceinline static void compact(AABBNode_t* a)
    {
      /* find right most filled node */
      ssize_t j=N;
      for (j=j-1; j>=0; j--)
        if (a->child(j) != NodeRef::emptyNode)
          break;

      /* replace empty nodes with filled nodes */
      for (ssize_t i=0; i<j; i++) {
        if (a->child(i) == NodeRef::emptyNode) {
          a->swap(i,j);
          for (j=j-1; j>i; j--)
            if (a->child(j) != NodeRef::emptyNode)
              break;
        }
      }
    }
    
    /*! Returns reference to specified child */
    __forceinline       NodeRef& child(size_t i)       { assert(i<N); return children[i]; }
    __forceinline const NodeRef& child(size_t i) const { assert(i<N); return children[i]; }
    
    /*! output operator */
    friend embree_ostream operator<<(embree_ostream o, const AABBNode_t& n)
    {
      o << "AABBNode { " << embree_endl;
      o << "  lower_x " << n.lower_x << embree_endl;
      o << "  upper_x " << n.upper_x << embree_endl;
      o << "  lower_y " << n.lower_y << embree_endl;
      o << "  upper_y " << n.upper_y << embree_endl;
      o << "  lower_z " << n.lower_z << embree_endl;
      o << "  upper_z " << n.upper_z << embree_endl;
      o << "  children = ";
      for (size_t i=0; i<N; i++) o << n.children[i] << " ";
      o << embree_endl;
      o << "}" << embree_endl;
      return o;
    }
    
  public:
    vfloat<N> lower_x;           //!< X dimension of lower bounds of all N children.
    vfloat<N> upper_x;           //!< X dimension of upper bounds of all N children.
    vfloat<N> lower_y;           //!< Y dimension of lower bounds of all N children.
    vfloat<N> upper_y;           //!< Y dimension of upper bounds of all N children.
    vfloat<N> lower_z;           //!< Z dimension of lower bounds of all N children.
    vfloat<N> upper_z;           //!< Z dimension of upper bounds of all N children.
  };

  template<>
    __forceinline void AABBNode_t<NodeRefPtr<4>,4>::bounds(BBox<vfloat4>& bounds0, BBox<vfloat4>& bounds1, BBox<vfloat4>& bounds2, BBox<vfloat4>& bounds3) const {
    transpose(lower_x,lower_y,lower_z,vfloat4(zero),bounds0.lower,bounds1.lower,bounds2.lower,bounds3.lower);
    transpose(upper_x,upper_y,upper_z,vfloat4(zero),bounds0.upper,bounds1.upper,bounds2.upper,bounds3.upper);
  }
}
Upgrade Embree to the latest official release. Since Embree v3.13.0 supports AARCH64, switch back to the official repo instead of using Embree-aarch64. `thirdparty/embree/patches/godot-changes.patch` should now contain an accurate diff of the changes done to the library. (cherry picked from commit 767e374dced69b45db0afb30ca2ccf0bbbeef672) 2021-05-20 12:49:33 +02:00			`// Copyright 2009-2021 Intel Corporation`
Add Embree thirdparty library 2020-12-19 14:50:20 +01:00			`// SPDX-License-Identifier: Apache-2.0`

			`#pragma once`

			`#include "bvh_node_base.h"`

			`namespace embree`
			`{`
			`/! BVHN AABBNode /`
			`template<typename NodeRef, int N>`
			`struct AABBNode_t : public BaseNode_t<NodeRef, N>`
			`{`
			`using BaseNode_t<NodeRef,N>::children;`

			`struct Create`
			`{`
			`__forceinline NodeRef operator() (const FastAllocator::CachedAllocator& alloc, size_t numChildren = 0) const`
			`{`
			`AABBNode_t* node = (AABBNode_t*) alloc.malloc0(sizeof(AABBNode_t),NodeRef::byteNodeAlignment); node->clear();`
			`return NodeRef::encodeNode(node);`
			`}`
			`};`

			`struct Set`
			`{`
			`__forceinline void operator() (NodeRef node, size_t i, NodeRef child, const BBox3fa& bounds) const {`
			`node.getAABBNode()->setRef(i,child);`
			`node.getAABBNode()->setBounds(i,bounds);`
			`}`
			`};`

			`struct Create2`
			`{`
			`template<typename BuildRecord>`
			`__forceinline NodeRef operator() (BuildRecord* children, const size_t num, const FastAllocator::CachedAllocator& alloc) const`
			`{`
			`AABBNode_t* node = (AABBNode_t*) alloc.malloc0(sizeof(AABBNode_t), NodeRef::byteNodeAlignment); node->clear();`
			`for (size_t i=0; i<num; i++) node->setBounds(i,children[i].bounds());`
			`return NodeRef::encodeNode(node);`
			`}`
			`};`

			`struct Set2`
			`{`
			`template<typename BuildRecord>`
			`__forceinline NodeRef operator() (const BuildRecord& precord, const BuildRecord* crecords, NodeRef ref, NodeRef* children, const size_t num) const`
			`{`
Update embree to 3.13.5 (cherry picked from commit 5e4158eb4869427ac13a0fe57e9b688ea4c3b0f1) 2022-11-24 15:45:59 +01:00			`#if defined(DEBUG)`
			`// check that empty children are only at the end of the child list`
			`bool emptyChild = false;`
			`for (size_t i=0; i<num; i++) {`
			`emptyChild \|= (children[i] == NodeRef::emptyNode);`
			`assert(emptyChild == (children[i] == NodeRef::emptyNode));`
			`}`
			`#endif`
Add Embree thirdparty library 2020-12-19 14:50:20 +01:00			`AABBNode_t* node = ref.getAABBNode();`
			`for (size_t i=0; i<num; i++) node->setRef(i,children[i]);`
			`return ref;`
			`}`
			`};`

			`struct Set3`
			`{`
			`Set3 (FastAllocator* allocator, PrimRef* prims)`
			`: allocator(allocator), prims(prims) {}`

			`template<typename BuildRecord>`
			`__forceinline NodeRef operator() (const BuildRecord& precord, const BuildRecord* crecords, NodeRef ref, NodeRef* children, const size_t num) const`
			`{`
Update embree to 3.13.5 (cherry picked from commit 5e4158eb4869427ac13a0fe57e9b688ea4c3b0f1) 2022-11-24 15:45:59 +01:00			`#if defined(DEBUG)`
			`// check that empty children are only at the end of the child list`
			`bool emptyChild = false;`
			`for (size_t i=0; i<num; i++) {`
			`emptyChild \|= (children[i] == NodeRef::emptyNode);`
			`assert(emptyChild == (children[i] == NodeRef::emptyNode));`
			`}`
			`#endif`
Add Embree thirdparty library 2020-12-19 14:50:20 +01:00			`AABBNode_t* node = ref.getAABBNode();`
			`for (size_t i=0; i<num; i++) node->setRef(i,children[i]);`

			`if (unlikely(precord.alloc_barrier))`
			`{`
			`PrimRef* begin = &prims[precord.prims.begin()];`
			`PrimRef* end = &prims[precord.prims.end()]; // FIXME: extended end for spatial split builder!!!!!`
			`size_t bytes = (size_t)end - (size_t)begin;`
			`allocator->addBlock(begin,bytes);`
			`}`

			`return ref;`
			`}`

			`FastAllocator* const allocator;`
			`PrimRef* const prims;`
			`};`

			`/! Clears the node. /`
			`__forceinline void clear() {`
			`lower_x = lower_y = lower_z = pos_inf;`
			`upper_x = upper_y = upper_z = neg_inf;`
			`BaseNode_t<NodeRef,N>::clear();`
			`}`

			`/! Sets bounding box and ID of child. /`
			`__forceinline void setRef(size_t i, const NodeRef& ref) {`
			`assert(i < N);`
			`children[i] = ref;`
			`}`

			`/! Sets bounding box of child. /`
			`__forceinline void setBounds(size_t i, const BBox3fa& bounds)`
			`{`
			`assert(i < N);`
			`lower_x[i] = bounds.lower.x; lower_y[i] = bounds.lower.y; lower_z[i] = bounds.lower.z;`
			`upper_x[i] = bounds.upper.x; upper_y[i] = bounds.upper.y; upper_z[i] = bounds.upper.z;`
			`}`

			`/! Sets bounding box and ID of child. /`
			`__forceinline void set(size_t i, const NodeRef& ref, const BBox3fa& bounds) {`
			`setBounds(i,bounds);`
			`children[i] = ref;`
			`}`

			`/! Returns bounds of node. /`
			`__forceinline BBox3fa bounds() const {`
			`const Vec3fa lower(reduce_min(lower_x),reduce_min(lower_y),reduce_min(lower_z));`
			`const Vec3fa upper(reduce_max(upper_x),reduce_max(upper_y),reduce_max(upper_z));`
			`return BBox3fa(lower,upper);`
			`}`

			`/! Returns bounds of specified child. /`
			`__forceinline BBox3fa bounds(size_t i) const`
			`{`
			`assert(i < N);`
			`const Vec3fa lower(lower_x[i],lower_y[i],lower_z[i]);`
			`const Vec3fa upper(upper_x[i],upper_y[i],upper_z[i]);`
			`return BBox3fa(lower,upper);`
			`}`

			`/! Returns extent of bounds of specified child. /`
			`__forceinline Vec3fa extend(size_t i) const {`
			`return bounds(i).size();`
			`}`

			`/! Returns bounds of all children (implemented later as specializations) /`
			`__forceinline void bounds(BBox<vfloat4>& bounds0, BBox<vfloat4>& bounds1, BBox<vfloat4>& bounds2, BBox<vfloat4>& bounds3) const;`

			`/! swap two children of the node /`
			`__forceinline void swap(size_t i, size_t j)`
			`{`
			`assert(i<N && j<N);`
			`std::swap(children[i],children[j]);`
			`std::swap(lower_x[i],lower_x[j]);`
			`std::swap(lower_y[i],lower_y[j]);`
			`std::swap(lower_z[i],lower_z[j]);`
			`std::swap(upper_x[i],upper_x[j]);`
			`std::swap(upper_y[i],upper_y[j]);`
			`std::swap(upper_z[i],upper_z[j]);`
			`}`

			`/! swap the children of two nodes /`
			`__forceinline static void swap(AABBNode_t* a, size_t i, AABBNode_t* b, size_t j)`
			`{`
			`assert(i<N && j<N);`
			`std::swap(a->children[i],b->children[j]);`
			`std::swap(a->lower_x[i],b->lower_x[j]);`
			`std::swap(a->lower_y[i],b->lower_y[j]);`
			`std::swap(a->lower_z[i],b->lower_z[j]);`
			`std::swap(a->upper_x[i],b->upper_x[j]);`
			`std::swap(a->upper_y[i],b->upper_y[j]);`
			`std::swap(a->upper_z[i],b->upper_z[j]);`
			`}`

			`/! compacts a node (moves empty children to the end) /`
			`__forceinline static void compact(AABBNode_t* a)`
			`{`
			`/* find right most filled node */`
			`ssize_t j=N;`
			`for (j=j-1; j>=0; j--)`
			`if (a->child(j) != NodeRef::emptyNode)`
			`break;`

			`/* replace empty nodes with filled nodes */`
			`for (ssize_t i=0; i<j; i++) {`
			`if (a->child(i) == NodeRef::emptyNode) {`
			`a->swap(i,j);`
			`for (j=j-1; j>i; j--)`
			`if (a->child(j) != NodeRef::emptyNode)`
			`break;`
			`}`
			`}`
			`}`

			`/! Returns reference to specified child /`
			`__forceinline NodeRef& child(size_t i) { assert(i<N); return children[i]; }`
			`__forceinline const NodeRef& child(size_t i) const { assert(i<N); return children[i]; }`

			`/! output operator /`
			`friend embree_ostream operator<<(embree_ostream o, const AABBNode_t& n)`
			`{`
			`o << "AABBNode { " << embree_endl;`
			`o << " lower_x " << n.lower_x << embree_endl;`
			`o << " upper_x " << n.upper_x << embree_endl;`
			`o << " lower_y " << n.lower_y << embree_endl;`
			`o << " upper_y " << n.upper_y << embree_endl;`
			`o << " lower_z " << n.lower_z << embree_endl;`
			`o << " upper_z " << n.upper_z << embree_endl;`
			`o << " children = ";`
			`for (size_t i=0; i<N; i++) o << n.children[i] << " ";`
			`o << embree_endl;`
			`o << "}" << embree_endl;`
			`return o;`
			`}`

			`public:`
			`vfloat<N> lower_x; //!< X dimension of lower bounds of all N children.`
			`vfloat<N> upper_x; //!< X dimension of upper bounds of all N children.`
			`vfloat<N> lower_y; //!< Y dimension of lower bounds of all N children.`
			`vfloat<N> upper_y; //!< Y dimension of upper bounds of all N children.`
			`vfloat<N> lower_z; //!< Z dimension of lower bounds of all N children.`
			`vfloat<N> upper_z; //!< Z dimension of upper bounds of all N children.`
			`};`

			`template<>`
			`__forceinline void AABBNode_t<NodeRefPtr<4>,4>::bounds(BBox<vfloat4>& bounds0, BBox<vfloat4>& bounds1, BBox<vfloat4>& bounds2, BBox<vfloat4>& bounds3) const {`
			`transpose(lower_x,lower_y,lower_z,vfloat4(zero),bounds0.lower,bounds1.lower,bounds2.lower,bounds3.lower);`
			`transpose(upper_x,upper_y,upper_z,vfloat4(zero),bounds0.upper,bounds1.upper,bounds2.upper,bounds3.upper);`
			`}`
			`}`