//========= Copyright � 1996-2005, Valve Corporation, All rights reserved. ============// // // Purpose: // // $NoKeywords: $ //=============================================================================// #ifndef DISPCOLL_COMMON_H #define DISPCOLL_COMMON_H #pragma once #include "trace.h" #include "builddisp.h" #include "bitvec.h" #ifdef ENGINE_DLL #include "../engine/zone.h" #endif #ifdef ENGINE_DLL template class CDispVector : public CUtlVector > { }; #else template class CDispVector : public CUtlVector > { }; #define HUNK_ALLOC_CREDIT_( _x_ ) #endif FORWARD_DECLARE_HANDLE( memhandle_t ); #define DISPCOLL_TREETRI_SIZE MAX_DISPTRIS #define DISPCOLL_DIST_EPSILON 0.03125f #define DISPCOLL_ROOTNODE_INDEX 0 #define DISPCOLL_INVALID_TRI -1 #define DISPCOLL_INVALID_FRAC -99999.9f #define DISPCOLL_NORMAL_UNDEF 0xffff extern double g_flDispCollSweepTimer; extern double g_flDispCollIntersectTimer; extern double g_flDispCollInCallTimer; struct RayDispOutput_t { short ndxVerts[4]; // 3 verts and a pad float u, v; // the u, v paramters (edgeU = v1 - v0, edgeV = v2 - v0) float dist; // intersection distance }; // Assumptions: // Max patch is 17x17, therefore 9 bits needed to represent a triangle index // //============================================================================= // Displacement Collision Triangle class CDispCollTri { struct index_t { union { struct { unsigned short uiVert:9; unsigned short uiMin:2; unsigned short uiMax:2; } m_Index; unsigned short m_IndexDummy; }; }; index_t m_TriData[3]; public: unsigned short m_ucSignBits:3; // Plane test. unsigned short m_ucPlaneType:3; // Axial test? unsigned short m_uiFlags:7; // Uses 7-bits - maybe look into merging it with something? Vector m_vecNormal; // Triangle normal (plane normal). float m_flDist; // Triangle plane dist. // Creation. CDispCollTri(); void Init( void ); void CalcPlane( CDispVector &m_aVerts ); void FindMinMax( CDispVector &m_aVerts ); // Triangle data. inline void SetVert( int iPos, int iVert ) { Assert( ( iPos >= 0 ) && ( iPos < 3 ) ); Assert( ( iVert >= 0 ) && ( iVert < ( 1 << 9 ) ) ); m_TriData[iPos].m_Index.uiVert = iVert; } inline int GetVert( int iPos ) const { Assert( ( iPos >= 0 ) && ( iPos < 3 ) ); return m_TriData[iPos].m_Index.uiVert; } inline void SetMin( int iAxis, int iMin ) { Assert( ( iAxis >= 0 ) && ( iAxis < 3 ) ); Assert( ( iMin >= 0 ) && ( iMin < 3 ) ); m_TriData[iAxis].m_Index.uiMin = iMin; } inline int GetMin( int iAxis ) const { Assert( ( iAxis >= 0 ) && ( iAxis < 3 ) ); return m_TriData[iAxis].m_Index.uiMin; } inline void SetMax( int iAxis, int iMax ) { Assert( ( iAxis >= 0 ) && ( iAxis < 3 ) ); Assert( ( iMax >= 0 ) && ( iMax < 3 ) ); m_TriData[iAxis].m_Index.uiMax = iMax; } inline int GetMax( int iAxis ) const { Assert( ( iAxis >= 0 ) && ( iAxis < 3 ) ); return m_TriData[iAxis].m_Index.uiMax; } }; //============================================================================= // Helper class CDispCollHelper { public: float m_flStartFrac; float m_flEndFrac; Vector m_vecImpactNormal; float m_flImpactDist; }; //============================================================================= // Cache #pragma pack(1) class CDispCollTriCache { public: unsigned short m_iCrossX[3]; unsigned short m_iCrossY[3]; unsigned short m_iCrossZ[3]; }; #pragma pack() #include "mathlib/ssemath.h" class CDispCollNode { public: FourVectors m_mins; FourVectors m_maxs; }; class CDispCollLeaf { public: short m_tris[2]; }; // a power 4 displacement can have 341 nodes, pad out to 344 for 16-byte alignment const int MAX_DISP_AABB_NODES = 341; const int MAX_AABB_LIST = 344; struct rayleaflist_t { FourVectors rayStart; FourVectors rayExtents; FourVectors invDelta; int nodeList[MAX_AABB_LIST]; int maxIndex; }; //============================================================================= // // Displacement Collision Tree Data // class CDispCollTree { public: // Creation/Destruction. CDispCollTree(); ~CDispCollTree(); virtual bool Create( CCoreDispInfo *pDisp ); // Raycasts. // NOTE: These assume you've precalculated invDelta as well as culled to the bounds of this disp bool AABBTree_Ray( const Ray_t &ray, const Vector &invDelta, CBaseTrace *pTrace, bool bSide = true ); bool AABBTree_Ray( const Ray_t &ray, const Vector &invDelta, RayDispOutput_t &output ); // NOTE: Lower perf helper function, should not be used in the game runtime bool AABBTree_Ray( const Ray_t &ray, RayDispOutput_t &output ); // Hull Sweeps. // NOTE: These assume you've precalculated invDelta as well as culled to the bounds of this disp bool AABBTree_SweepAABB( const Ray_t &ray, const Vector &invDelta, CBaseTrace *pTrace ); // Hull Intersection. bool AABBTree_IntersectAABB( const Vector &absMins, const Vector &absMaxs ); // Point/Box vs. Bounds. bool PointInBounds( Vector const &vecBoxCenter, Vector const &vecBoxMin, Vector const &vecBoxMax, bool bPoint ); // Utility. inline void SetPower( int power ) { m_nPower = power; } inline int GetPower( void ) { return m_nPower; } inline int GetFlags( void ) { return m_nFlags; } inline void SetFlags( int nFlags ) { m_nFlags = nFlags; } inline bool CheckFlags( int nFlags ) { return ( ( nFlags & GetFlags() ) != 0 ) ? true : false; } inline int GetTexinfoFlags( void ) { return m_nTexinfoFlags; } inline void SetTexinfoFlags( int nFlags ) { m_nTexinfoFlags = nFlags; } inline int GetWidth( void ) { return ( ( 1 << m_nPower ) + 1 ); } inline int GetHeight( void ) { return ( ( 1 << m_nPower ) + 1 ); } inline int GetSize( void ) { return ( ( 1 << m_nPower ) + 1 ) * ( ( 1 << m_nPower ) + 1 ); } inline int GetTriSize( void ) { return ( ( 1 << m_nPower ) * ( 1 << m_nPower ) * 2 ); } // inline void SetTriFlags( short iTri, unsigned short nFlags ) { m_aTris[iTri].m_uiFlags = nFlags; } inline void GetStabDirection( Vector &vecDir ) { vecDir = m_vecStabDir; } inline void GetBounds( Vector &vecBoxMin, Vector &vecBoxMax ) { vecBoxMin = m_mins; vecBoxMax = m_maxs; } inline int GetContents( void ) { return m_nContents; } inline void SetSurfaceProps( int iProp, short nSurfProp ) { Assert( ( iProp >= 0 ) && ( iProp < 4 ) ); m_nSurfaceProps[iProp] = nSurfProp; } inline short GetSurfaceProps( int iProp ) { return m_nSurfaceProps[iProp]; } inline unsigned int GetMemorySize( void ) { return m_nSize; } inline unsigned int GetCacheMemorySize( void ) { return ( m_aTrisCache.Count() * sizeof(CDispCollTriCache) + m_aEdgePlanes.Count() * sizeof(Vector) ); } inline bool IsCached( void ) { return m_aTrisCache.Count() == m_aTris.Count(); } void GetVirtualMeshList( struct virtualmeshlist_t *pList ); int AABBTree_GetTrisInSphere( const Vector ¢er, float radius, unsigned short *pIndexOut, int indexMax ); public: inline int Nodes_GetChild( int iNode, int nDirection ); inline int Nodes_CalcCount( int nPower ); inline int Nodes_GetParent( int iNode ); inline int Nodes_GetLevel( int iNode ); inline int Nodes_GetIndexFromComponents( int x, int y ); void LockCache(); void UnlockCache(); void Cache( void ); void Uncache() { m_aTrisCache.Purge(); m_aEdgePlanes.Purge(); } #ifdef ENGINE_DLL // Data manager methods static size_t EstimatedSize( CDispCollTree *pTree ) { return pTree->GetCacheMemorySize(); } static CDispCollTree *CreateResource( CDispCollTree *pTree ) { // Created ahead of time return pTree; } bool GetData() { return IsCached(); } size_t Size() { return GetCacheMemorySize(); } void DestroyResource() { Uncache(); m_hCache = NULL; } #endif protected: bool AABBTree_Create( CCoreDispInfo *pDisp ); void AABBTree_CopyDispData( CCoreDispInfo *pDisp ); void AABBTree_CreateLeafs( void ); void AABBTree_GenerateBoxes_r( int nodeIndex, Vector *pMins, Vector *pMaxs ); void AABBTree_CalcBounds( void ); int AABBTree_BuildTreeTrisInSphere_r( const Vector ¢er, float radius, int iNode, unsigned short *pIndexOut, unsigned short indexMax ); void AABBTree_TreeTrisRayTest( const Ray_t &ray, const Vector &vecInvDelta, int iNode, CBaseTrace *pTrace, bool bSide, CDispCollTri **pImpactTri ); void AABBTree_TreeTrisRayBarycentricTest( const Ray_t &ray, const Vector &vecInvDelta, int iNode, RayDispOutput_t &output, CDispCollTri **pImpactTri ); int FORCEINLINE BuildRayLeafList( int iNode, rayleaflist_t &list ); struct AABBTree_TreeTrisSweepTest_Args_t { AABBTree_TreeTrisSweepTest_Args_t( const Ray_t &ray, const Vector &vecInvDelta, const Vector &rayDir, CBaseTrace *pTrace ) : ray( ray ), vecInvDelta( vecInvDelta ), rayDir( rayDir ), pTrace( pTrace ) {} const Ray_t &ray; const Vector &vecInvDelta; const Vector &rayDir; CBaseTrace *pTrace; }; protected: void SweepAABBTriIntersect( const Ray_t &ray, const Vector &rayDir, int iTri, CDispCollTri *pTri, CBaseTrace *pTrace ); void Cache_Create( CDispCollTri *pTri, int iTri ); // Testing! bool Cache_EdgeCrossAxisX( const Vector &vecEdge, const Vector &vecOnEdge, const Vector &vecOffEdge, CDispCollTri *pTri, unsigned short &iPlane ); bool Cache_EdgeCrossAxisY( const Vector &vecEdge, const Vector &vecOnEdge, const Vector &vecOffEdge, CDispCollTri *pTri, unsigned short &iPlane ); bool Cache_EdgeCrossAxisZ( const Vector &vecEdge, const Vector &vecOnEdge, const Vector &vecOffEdge, CDispCollTri *pTri, unsigned short &iPlane ); inline bool FacePlane( const Ray_t &ray, const Vector &rayDir, CDispCollTri *pTri, CDispCollHelper *pHelper ); bool FORCEINLINE AxisPlanesXYZ( const Ray_t &ray, CDispCollTri *pTri, CDispCollHelper *pHelper ); inline bool EdgeCrossAxisX( const Ray_t &ray, unsigned short iPlane, CDispCollHelper *pHelper ); inline bool EdgeCrossAxisY( const Ray_t &ray, unsigned short iPlane, CDispCollHelper *pHelper ); inline bool EdgeCrossAxisZ( const Ray_t &ray, unsigned short iPlane, CDispCollHelper *pHelper ); bool ResolveRayPlaneIntersect( float flStart, float flEnd, const Vector &vecNormal, float flDist, CDispCollHelper *pHelper ); template bool FORCEINLINE TestOneAxisPlaneMin( const Ray_t &ray, CDispCollTri *pTri ); template bool FORCEINLINE TestOneAxisPlaneMax( const Ray_t &ray, CDispCollTri *pTri ); template bool EdgeCrossAxis( const Ray_t &ray, unsigned short iPlane, CDispCollHelper *pHelper ); // Utility inline void CalcClosestBoxPoint( const Vector &vecPlaneNormal, const Vector &vecBoxStart, const Vector &vecBoxExtents, Vector &vecBoxPoint ); inline void CalcClosestExtents( const Vector &vecPlaneNormal, const Vector &vecBoxExtents, Vector &vecBoxPoint ); int AddPlane( const Vector &vecNormal ); bool FORCEINLINE IsLeafNode(int iNode); public: Vector m_mins; // Bounding box of the displacement surface and base face int m_iCounter; Vector m_maxs; // Bounding box of the displacement surface and base face protected: int m_nContents; // The displacement surface "contents" (solid, etc...) #ifdef ENGINE_DLL memhandle_t m_hCache; #endif int m_nPower; // Size of the displacement ( 2^power + 1 ) uint16 m_nFlags; uint16 m_nTexinfoFlags; Vector m_vecSurfPoints[4]; // Base surface points. // Collision data. Vector m_vecStabDir; // Direction to stab for this displacement surface (is the base face normal) short m_nSurfaceProps[4]; // Surface properties (save off from texdata for impact responses) protected: CDispVector m_aVerts; // Displacement verts. CDispVector m_aTris; // Displacement triangles. CDispVector m_nodes; // Nodes. CDispVector m_leaves; // Leaves. // Cache CUtlVector m_aTrisCache; CUtlVector m_aEdgePlanes; CDispCollHelper m_Helper; unsigned int m_nSize; }; FORCEINLINE bool CDispCollTree::IsLeafNode(int iNode) { return iNode >= m_nodes.Count() ? true : false; } //----------------------------------------------------------------------------- // Purpose: get the child node index given the current node index and direction // of the child (1 of 4) // Input: iNode - current node index // nDirection - direction of the child ( [0...3] - SW, SE, NW, NE ) // Output: int - the index of the child node //----------------------------------------------------------------------------- inline int CDispCollTree::Nodes_GetChild( int iNode, int nDirection ) { // node range [0...m_NodeCount) Assert( iNode >= 0 ); Assert( iNode < m_nodes.Count() ); // ( node index * 4 ) + ( direction + 1 ) return ( ( iNode << 2 ) + ( nDirection + 1 ) ); } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- inline int CDispCollTree::Nodes_CalcCount( int nPower ) { Assert( nPower >= 1 ); Assert( nPower <= 4 ); return ( ( 1 << ( ( nPower + 1 ) << 1 ) ) / 3 ); } //----------------------------------------------------------------------------- // Purpose: get the parent node index given the current node // Input: iNode - current node index // Output: int - the index of the parent node //----------------------------------------------------------------------------- inline int CDispCollTree::Nodes_GetParent( int iNode ) { // node range [0...m_NodeCount) Assert( iNode >= 0 ); Assert( iNode < m_nodes.Count() ); // ( node index - 1 ) / 4 return ( ( iNode - 1 ) >> 2 ); } //----------------------------------------------------------------------------- // Purpose: // TODO: should make this a function - not a hardcoded set of statements!!! //----------------------------------------------------------------------------- inline int CDispCollTree::Nodes_GetLevel( int iNode ) { // node range [0...m_NodeCount) Assert( iNode >= 0 ); Assert( iNode < m_nodes.Count() ); // level = 2^n + 1 if ( iNode == 0 ) { return 1; } if ( iNode < 5 ) { return 2; } if ( iNode < 21 ) { return 3; } if ( iNode < 85 ) { return 4; } if ( iNode < 341 ) { return 5; } return -1; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- inline int CDispCollTree::Nodes_GetIndexFromComponents( int x, int y ) { int nIndex = 0; // Interleave bits from the x and y values to create the index int iShift; for( iShift = 0; x != 0; iShift += 2, x >>= 1 ) { nIndex |= ( x & 1 ) << iShift; } for( iShift = 1; y != 0; iShift += 2, y >>= 1 ) { nIndex |= ( y & 1 ) << iShift; } return nIndex; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- inline void CDispCollTree::CalcClosestBoxPoint( const Vector &vecPlaneNormal, const Vector &vecBoxStart, const Vector &vecBoxExtents, Vector &vecBoxPoint ) { vecBoxPoint = vecBoxStart; ( vecPlaneNormal[0] < 0.0f ) ? vecBoxPoint[0] += vecBoxExtents[0] : vecBoxPoint[0] -= vecBoxExtents[0]; ( vecPlaneNormal[1] < 0.0f ) ? vecBoxPoint[1] += vecBoxExtents[1] : vecBoxPoint[1] -= vecBoxExtents[1]; ( vecPlaneNormal[2] < 0.0f ) ? vecBoxPoint[2] += vecBoxExtents[2] : vecBoxPoint[2] -= vecBoxExtents[2]; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- inline void CDispCollTree::CalcClosestExtents( const Vector &vecPlaneNormal, const Vector &vecBoxExtents, Vector &vecBoxPoint ) { ( vecPlaneNormal[0] < 0.0f ) ? vecBoxPoint[0] = vecBoxExtents[0] : vecBoxPoint[0] = -vecBoxExtents[0]; ( vecPlaneNormal[1] < 0.0f ) ? vecBoxPoint[1] = vecBoxExtents[1] : vecBoxPoint[1] = -vecBoxExtents[1]; ( vecPlaneNormal[2] < 0.0f ) ? vecBoxPoint[2] = vecBoxExtents[2] : vecBoxPoint[2] = -vecBoxExtents[2]; } //============================================================================= // Global Helper Functions CDispCollTree *DispCollTrees_Alloc( int count ); void DispCollTrees_Free( CDispCollTree *pTrees ); #endif // DISPCOLL_COMMON_H