metaforce/Runtime/Collision/CCollidableOBBTree.cpp

575 lines
26 KiB
C++

#include "Runtime/Collision/CCollidableOBBTree.hpp"
#include <array>
#include "Runtime/Collision/CCollisionInfoList.hpp"
#include "Runtime/Collision/CInternalRayCastStructure.hpp"
#include "Runtime/Collision/CMaterialFilter.hpp"
#include "Runtime/Collision/CollisionUtil.hpp"
namespace metaforce {
CCollidableOBBTree::CCollidableOBBTree(const COBBTree* tree, const metaforce::CMaterialList& material)
: CCollisionPrimitive(material), x10_tree(tree) {}
bool CCollidableOBBTree::LineIntersectsLeaf(const COBBTree::CLeafData& leaf, CRayCastInfo& info) const {
bool ret = false;
u16 intersectIdx = 0;
for (size_t i = 0; i < leaf.GetSurfaceVector().size(); ++i) {
u16 surfIdx = leaf.GetSurfaceVector()[i];
CCollisionSurface surface = x10_tree->GetSurface(surfIdx);
CMaterialList matList = GetMaterial();
matList.Add(surface.GetSurfaceFlags());
if (info.GetMaterialFilter().Passes(matList)) {
if (CollisionUtil::RayTriangleIntersection(info.GetRay().start, info.GetRay().dir, surface.GetVerts(),
info.Magnitude())) {
intersectIdx = surfIdx;
ret = true;
}
}
}
if (ret) {
CCollisionSurface surf = x10_tree->GetSurface(intersectIdx);
info.Plane() = surf.GetPlane();
info.Material() = CMaterialList(surf.GetSurfaceFlags());
}
return ret;
}
bool CCollidableOBBTree::LineIntersectsOBBTree(const COBBTree::CNode& n0, const COBBTree::CNode& n1,
CRayCastInfo& info) const {
bool ret = false;
float t0, t1;
bool intersects0 = false;
bool intersects1 = false;
if (CollisionUtil::LineIntersectsOBBox(n0.GetOBB(), info.GetRay(), t0) && t0 < info.GetMagnitude())
intersects0 = true;
if (CollisionUtil::LineIntersectsOBBox(n1.GetOBB(), info.GetRay(), t1) && t1 < info.GetMagnitude())
intersects1 = true;
if (intersects0 && intersects1) {
if (t0 < t1) {
if (n0.IsLeaf() ? LineIntersectsLeaf(n0.GetLeafData(), info)
: LineIntersectsOBBTree(n0.GetLeft(), n0.GetRight(), info)) {
if (info.GetMagnitude() < t1)
return true;
ret = true;
}
if (n1.IsLeaf()) {
if (LineIntersectsLeaf(n1.GetLeafData(), info))
return true;
} else {
if (LineIntersectsOBBTree(n1.GetLeft(), n1.GetRight(), info))
return true;
}
} else {
if (n1.IsLeaf() ? LineIntersectsLeaf(n1.GetLeafData(), info)
: LineIntersectsOBBTree(n1.GetLeft(), n1.GetRight(), info)) {
if (info.GetMagnitude() < t0)
return true;
ret = true;
}
if (n0.IsLeaf()) {
if (LineIntersectsLeaf(n0.GetLeafData(), info))
return true;
} else {
if (LineIntersectsOBBTree(n0.GetLeft(), n0.GetRight(), info))
return true;
}
}
} else if (intersects0) {
return n0.IsLeaf() ? LineIntersectsLeaf(n0.GetLeafData(), info)
: LineIntersectsOBBTree(n0.GetLeft(), n0.GetRight(), info);
} else if (intersects1) {
return n1.IsLeaf() ? LineIntersectsLeaf(n1.GetLeafData(), info)
: LineIntersectsOBBTree(n1.GetLeft(), n1.GetRight(), info);
}
return ret;
}
bool CCollidableOBBTree::LineIntersectsOBBTree(const COBBTree::CNode& node, CRayCastInfo& info) const {
float t;
bool ret = false;
if (CollisionUtil::LineIntersectsOBBox(node.GetOBB(), info.GetRay(), t) && t < info.GetMagnitude()) {
if (node.IsLeaf()) {
if (LineIntersectsLeaf(node.GetLeafData(), info))
ret = true;
} else {
if (LineIntersectsOBBTree(node.GetLeft(), node.GetRight(), info))
ret = true;
}
const_cast<COBBTree::CNode&>(node).SetHit(true);
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return ret;
}
CRayCastResult CCollidableOBBTree::LineIntersectsTree(const zeus::CMRay& ray, const CMaterialFilter& filter,
float maxTime, const zeus::CTransform& xf) const {
zeus::CMRay useRay = ray.getInvUnscaledTransformRay(xf);
CRayCastInfo info(useRay, filter, maxTime);
if (LineIntersectsOBBTree(x10_tree->GetRoot(), info)) {
zeus::CPlane xfPlane = TransformPlane(info.GetPlane(), xf);
return CRayCastResult(info.GetMagnitude(), ray.start + info.GetMagnitude() * ray.dir, xfPlane, info.GetMaterial());
} else {
return {};
}
}
zeus::CPlane CCollidableOBBTree::TransformPlane(const zeus::CPlane& pl, const zeus::CTransform& xf) {
zeus::CVector3f normal = xf.rotate(pl.normal());
return zeus::CPlane(normal, (xf * (pl.normal() * pl.d())).dot(normal));
}
bool CCollidableOBBTree::SphereCollideWithLeafMoving(const COBBTree::CLeafData& leaf, const zeus::CTransform& xf,
const zeus::CSphere& sphere, const CMaterialList& matList,
const CMaterialFilter& filter, const zeus::CVector3f& dir,
double& dOut, CCollisionInfo& infoOut) const {
bool ret = false;
zeus::CAABox aabb(sphere.position - sphere.radius, sphere.position + sphere.radius);
zeus::CAABox moveAABB = aabb;
zeus::CVector3f moveVec = float(dOut) * dir;
moveAABB.accumulateBounds(aabb.max + moveVec);
moveAABB.accumulateBounds(aabb.min + moveVec);
zeus::CVector3f center = moveAABB.center();
zeus::CVector3f extent = moveAABB.extents();
for (u16 triIdx : leaf.GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(triIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat)) {
if (CollisionUtil::TriBoxOverlap(center, extent, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2))) {
const_cast<CCollidableOBBTree&>(*this).x1c_hits += 1;
zeus::CVector3f surfNormal = surf.GetNormal();
if ((sphere.position + moveVec - surf.GetVert(0)).dot(surfNormal) <= sphere.radius) {
const float mag = (sphere.radius - (sphere.position - surf.GetVert(0)).dot(surfNormal)) / dir.dot(surfNormal);
const zeus::CVector3f intersectPoint = sphere.position + mag * dir;
const std::array<bool, 3> outsideEdges{
(intersectPoint - surf.GetVert(0)).dot((surf.GetVert(1) - surf.GetVert(0)).cross(surfNormal)) < 0.f,
(intersectPoint - surf.GetVert(1)).dot((surf.GetVert(2) - surf.GetVert(1)).cross(surfNormal)) < 0.f,
(intersectPoint - surf.GetVert(2)).dot((surf.GetVert(0) - surf.GetVert(2)).cross(surfNormal)) < 0.f,
};
if (mag >= 0.f && !outsideEdges[0] && !outsideEdges[1] && !outsideEdges[2] && mag < dOut) {
infoOut = CCollisionInfo(intersectPoint - sphere.radius * surfNormal, matList, triMat, surfNormal);
dOut = mag;
ret = true;
}
const bool intersects = (sphere.position - surf.GetVert(0)).dot(surfNormal) <= sphere.radius;
std::array<bool, 3> testVert{true, true, true};
const u16* edgeIndices = x10_tree->GetTriangleEdgeIndices(triIdx);
for (int k = 0; k < 3; ++k) {
if (intersects || outsideEdges[k]) {
u16 edgeIdx = edgeIndices[k];
if (CMetroidAreaCollider::g_DupPrimitiveCheckCount != CMetroidAreaCollider::g_DupEdgeList[edgeIdx]) {
CMetroidAreaCollider::g_DupEdgeList[edgeIdx] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMaterialList edgeMat(x10_tree->GetEdgeMaterial(edgeIdx));
if (!edgeMat.HasMaterial(EMaterialTypes::NoEdgeCollision)) {
int nextIdx = (k + 1) % 3;
zeus::CVector3f edgeVec = surf.GetVert(nextIdx) - surf.GetVert(k);
float edgeVecMag = edgeVec.magnitude();
edgeVec *= zeus::CVector3f(1.f / edgeVecMag);
float dirDotEdge = dir.dot(edgeVec);
zeus::CVector3f edgeRej = dir - dirDotEdge * edgeVec;
float edgeRejMagSq = edgeRej.magSquared();
zeus::CVector3f vertToSphere = sphere.position - surf.GetVert(k);
float vtsDotEdge = vertToSphere.dot(edgeVec);
zeus::CVector3f vtsRej = vertToSphere - vtsDotEdge * edgeVec;
if (edgeRejMagSq > 0.f) {
const float tmp = 2.f * vtsRej.dot(edgeRej);
const float tmp2 =
4.f * edgeRejMagSq * (vtsRej.magSquared() - sphere.radius * sphere.radius) - tmp * tmp;
if (tmp2 >= 0.f) {
const float mag2 = 0.5f / edgeRejMagSq * (-tmp - std::sqrt(tmp2));
if (mag2 >= 0.f) {
const float t = mag2 * dirDotEdge + vtsDotEdge;
if (t >= 0.f && t <= edgeVecMag && mag2 < dOut) {
zeus::CVector3f point = surf.GetVert(k) + t * edgeVec;
infoOut = CCollisionInfo(point, matList, edgeMat,
(sphere.position + mag2 * dir - point).normalized());
dOut = mag2;
ret = true;
testVert[k] = false;
testVert[nextIdx] = false;
} else if (t < -sphere.radius && dirDotEdge <= 0.f) {
testVert[k] = false;
} else if (t > edgeVecMag + sphere.radius && dirDotEdge >= 0.0) {
testVert[nextIdx] = false;
}
}
} else {
testVert[k] = false;
testVert[nextIdx] = false;
}
}
}
}
}
}
const auto vertIndices = x10_tree->GetTriangleVertexIndices(triIdx);
for (int k = 0; k < 3; ++k) {
const u16 vertIdx = vertIndices[k];
if (testVert[k]) {
if (CMetroidAreaCollider::g_DupPrimitiveCheckCount != CMetroidAreaCollider::g_DupVertexList[vertIdx]) {
CMetroidAreaCollider::g_DupVertexList[vertIdx] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
double d = dOut;
if (CollisionUtil::RaySphereIntersection_Double(zeus::CSphere(surf.GetVert(k), sphere.radius),
sphere.position, dir, d) &&
d >= 0.0) {
infoOut = CCollisionInfo(surf.GetVert(k), matList, x10_tree->GetVertMaterial(vertIdx),
(sphere.position + dir * d - surf.GetVert(k)).normalized());
dOut = d;
ret = true;
}
}
} else {
CMetroidAreaCollider::g_DupVertexList[vertIdx] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
}
}
}
} else {
const u16* edgeIndices = x10_tree->GetTriangleEdgeIndices(triIdx);
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[0]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[1]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[2]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
const auto vertIndices = x10_tree->GetTriangleVertexIndices(triIdx);
CMetroidAreaCollider::g_DupVertexList[vertIndices[0]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupVertexList[vertIndices[1]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupVertexList[vertIndices[2]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
}
}
}
return ret;
}
bool CCollidableOBBTree::SphereCollisionMoving(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CSphere& sphere, const zeus::COBBox& obb,
const CMaterialList& material, const CMaterialFilter& filter,
const zeus::CVector3f& dir, double& dOut, CCollisionInfo& info) const {
bool ret = false;
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
if (SphereCollideWithLeafMoving(node.GetLeafData(), xf, sphere, material, filter, dir, dOut, info))
ret = true;
} else {
if (SphereCollisionMoving(node.GetLeft(), xf, sphere, obb, material, filter, dir, dOut, info))
ret = true;
if (SphereCollisionMoving(node.GetRight(), xf, sphere, obb, material, filter, dir, dOut, info))
ret = true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return ret;
}
bool CCollidableOBBTree::AABoxCollideWithLeafMoving(const COBBTree::CLeafData& leaf, const zeus::CTransform& xf,
const zeus::CAABox& aabb, const CMaterialList& matList,
const CMaterialFilter& filter,
const CMovingAABoxComponents& components,
const zeus::CVector3f& dir, double& dOut,
CCollisionInfo& infoOut) const {
bool ret = false;
zeus::CAABox movedAABB = components.x6e8_aabb;
zeus::CVector3f moveVec = float(dOut) * dir;
movedAABB.accumulateBounds(aabb.min + moveVec);
movedAABB.accumulateBounds(aabb.max + moveVec);
zeus::CVector3f center = movedAABB.center();
zeus::CVector3f extent = movedAABB.extents();
zeus::CVector3f normal, point;
for (u16 triIdx : leaf.GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(triIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat)) {
if (CollisionUtil::TriBoxOverlap(center, extent, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2))) {
const_cast<CCollidableOBBTree&>(*this).x1c_hits += 1;
const auto vertIndices = x10_tree->GetTriangleVertexIndices(triIdx);
double d = dOut;
if (CMetroidAreaCollider::MovingAABoxCollisionCheck_BoxVertexTri(surf, aabb, components.x6c4_vertIdxs, dir, d,
normal, point) &&
d < dOut) {
ret = true;
infoOut = CCollisionInfo(point, matList, triMat, normal);
dOut = d;
}
for (int k = 0; k < 3; ++k) {
u16 vertIdx = vertIndices[k];
const zeus::CVector3f& vtx = surf.GetVert(k);
if (CMetroidAreaCollider::g_DupPrimitiveCheckCount != CMetroidAreaCollider::g_DupVertexList[vertIdx]) {
CMetroidAreaCollider::g_DupVertexList[vertIdx] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
if (movedAABB.pointInside(vtx)) {
d = dOut;
if (CMetroidAreaCollider::MovingAABoxCollisionCheck_TriVertexBox(vtx, aabb, dir, d, normal, point) &&
d < dOut) {
CMaterialList vertMat(x10_tree->GetVertMaterial(vertIdx));
ret = true;
infoOut = CCollisionInfo(point, matList, vertMat, normal);
dOut = d;
}
}
}
}
const u16* edgeIndices = x10_tree->GetTriangleEdgeIndices(triIdx);
for (int k = 0; k < 3; ++k) {
u16 edgeIdx = edgeIndices[k];
if (CMetroidAreaCollider::g_DupPrimitiveCheckCount != CMetroidAreaCollider::g_DupEdgeList[edgeIdx]) {
CMetroidAreaCollider::g_DupEdgeList[edgeIdx] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMaterialList edgeMat(x10_tree->GetEdgeMaterial(edgeIdx));
if (!edgeMat.HasMaterial(EMaterialTypes::NoEdgeCollision)) {
d = dOut;
if (CMetroidAreaCollider::MovingAABoxCollisionCheck_Edge(surf.GetVert(k), surf.GetVert((k + 1) % 3),
components.x0_edges, dir, d, normal, point) &&
d < dOut) {
ret = true;
infoOut = CCollisionInfo(point, matList, edgeMat, normal);
dOut = d;
}
}
}
}
} else {
const u16* edgeIndices = x10_tree->GetTriangleEdgeIndices(triIdx);
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[0]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[1]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupEdgeList[edgeIndices[2]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
const auto vertIndices = x10_tree->GetTriangleVertexIndices(triIdx);
CMetroidAreaCollider::g_DupVertexList[vertIndices[0]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupVertexList[vertIndices[1]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
CMetroidAreaCollider::g_DupVertexList[vertIndices[2]] = CMetroidAreaCollider::g_DupPrimitiveCheckCount;
}
}
}
return ret;
}
bool CCollidableOBBTree::AABoxCollisionMoving(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CAABox& aabb, const zeus::COBBox& obb,
const CMaterialList& material, const CMaterialFilter& filter,
const CMovingAABoxComponents& components, const zeus::CVector3f& dir,
double& dOut, CCollisionInfo& info) const {
bool ret = false;
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
if (AABoxCollideWithLeafMoving(node.GetLeafData(), xf, aabb, material, filter, components, dir, dOut, info))
ret = true;
} else {
if (AABoxCollisionMoving(node.GetLeft(), xf, aabb, obb, material, filter, components, dir, dOut, info))
ret = true;
if (AABoxCollisionMoving(node.GetRight(), xf, aabb, obb, material, filter, components, dir, dOut, info))
ret = true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return ret;
}
bool CCollidableOBBTree::SphereCollisionBoolean(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CSphere& sphere, const zeus::COBBox& obb,
const CMaterialFilter& filter) const {
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
for (u16 surfIdx : node.GetLeafData().GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(surfIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat) &&
CollisionUtil::TriSphereOverlap(sphere, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2)))
return true;
}
} else {
if (SphereCollisionBoolean(node.GetLeft(), xf, sphere, obb, filter))
return true;
if (SphereCollisionBoolean(node.GetRight(), xf, sphere, obb, filter))
return true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return false;
}
bool CCollidableOBBTree::AABoxCollisionBoolean(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CAABox& aabb, const zeus::COBBox& obb,
const CMaterialFilter& filter) const {
zeus::CVector3f center = aabb.center();
zeus::CVector3f extent = aabb.extents();
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
for (u16 surfIdx : node.GetLeafData().GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(surfIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat) &&
CollisionUtil::TriBoxOverlap(center, extent, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2)))
return true;
}
} else {
if (AABoxCollisionBoolean(node.GetLeft(), xf, aabb, obb, filter))
return true;
if (AABoxCollisionBoolean(node.GetRight(), xf, aabb, obb, filter))
return true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return false;
}
bool CCollidableOBBTree::SphereCollideWithLeaf(const COBBTree::CLeafData& leaf, const zeus::CTransform& xf,
const zeus::CSphere& sphere, const CMaterialList& material,
const CMaterialFilter& filter, CCollisionInfoList& infoList) const {
bool ret = false;
zeus::CVector3f point, normal;
for (u16 surfIdx : leaf.GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(surfIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat)) {
const_cast<CCollidableOBBTree&>(*this).x1c_hits += 1;
if (CollisionUtil::TriSphereIntersection(sphere, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2), point,
normal)) {
CCollisionInfo collision(point, material, triMat, normal);
infoList.Add(collision, false);
ret = true;
}
}
}
return ret;
}
bool CCollidableOBBTree::SphereCollision(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CSphere& sphere, const zeus::COBBox& obb,
const CMaterialList& material, const CMaterialFilter& filter,
CCollisionInfoList& infoList) const {
bool ret = false;
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
if (SphereCollideWithLeaf(node.GetLeafData(), xf, sphere, material, filter, infoList))
ret = true;
} else {
if (SphereCollision(node.GetLeft(), xf, sphere, obb, material, filter, infoList))
ret = true;
if (SphereCollision(node.GetRight(), xf, sphere, obb, material, filter, infoList))
ret = true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return ret;
}
bool CCollidableOBBTree::AABoxCollideWithLeaf(const COBBTree::CLeafData& leaf, const zeus::CTransform& xf,
const zeus::CAABox& aabb, const CMaterialList& material,
const CMaterialFilter& filter, const std::array<zeus::CPlane, 6>& planes,
CCollisionInfoList& infoList) const {
bool ret = false;
zeus::CVector3f center = aabb.center();
zeus::CVector3f extent = aabb.extents();
for (u16 surfIdx : leaf.GetSurfaceVector()) {
CCollisionSurface surf = x10_tree->GetTransformedSurface(surfIdx, xf);
CMaterialList triMat = GetMaterial();
triMat.Add(CMaterialList(surf.GetSurfaceFlags()));
if (filter.Passes(triMat) &&
CollisionUtil::TriBoxOverlap(center, extent, surf.GetVert(0), surf.GetVert(1), surf.GetVert(2))) {
zeus::CAABox newAABB = zeus::CAABox();
const_cast<CCollidableOBBTree&>(*this).x1c_hits += 1;
if (CMetroidAreaCollider::ConvexPolyCollision(planes, surf.GetVerts(), newAABB)) {
zeus::CPlane plane = surf.GetPlane();
CCollisionInfo collision(newAABB, triMat, material, plane.normal(), -plane.normal());
infoList.Add(collision, false);
ret = true;
}
}
}
return ret;
}
bool CCollidableOBBTree::AABoxCollision(const COBBTree::CNode& node, const zeus::CTransform& xf,
const zeus::CAABox& aabb, const zeus::COBBox& obb,
const CMaterialList& material, const CMaterialFilter& filter,
const std::array<zeus::CPlane, 6>& planes, CCollisionInfoList& infoList) const {
bool ret = false;
const_cast<CCollidableOBBTree&>(*this).x14_tries += 1;
if (obb.OBBIntersectsBox(node.GetOBB())) {
const_cast<COBBTree::CNode&>(node).SetHit(true);
if (node.IsLeaf()) {
if (AABoxCollideWithLeaf(node.GetLeafData(), xf, aabb, material, filter, planes, infoList))
ret = true;
} else {
if (AABoxCollision(node.GetLeft(), xf, aabb, obb, material, filter, planes, infoList))
ret = true;
if (AABoxCollision(node.GetRight(), xf, aabb, obb, material, filter, planes, infoList))
ret = true;
}
} else {
const_cast<CCollidableOBBTree&>(*this).x18_misses += 1;
}
return ret;
}
FourCC CCollidableOBBTree::GetPrimType() const { return SBIG('OBBT'); }
CRayCastResult CCollidableOBBTree::CastRayInternal(const CInternalRayCastStructure& rayCast) const {
return LineIntersectsTree(rayCast.GetRay(), rayCast.GetFilter(), rayCast.GetMaxTime(), rayCast.GetTransform());
}
zeus::CAABox CCollidableOBBTree::CalculateAABox(const zeus::CTransform& xf) const {
return zeus::COBBox::FromAABox(x10_tree->CalculateLocalAABox(), xf).calculateAABox();
}
zeus::CAABox CCollidableOBBTree::CalculateLocalAABox() const { return x10_tree->CalculateLocalAABox(); }
} // namespace metaforce