//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============// // // Purpose: This module defines the CPowerInfo class, which contains a // whole bunch of precalculated data for each displacement power. // It holds data that indicates how to tesselate, how to access // neighbor displacements, etc. // // $NoKeywords: $ //=============================================================================// #ifndef DISP_POWERINFO_H #define DISP_POWERINFO_H #ifdef _WIN32 #pragma once #endif #include "disp_vertindex.h" #include "bspfile.h" #define NUM_POWERINFOS (MAX_MAP_DISP_POWER+1) struct DispNodeInfo_t { enum { // Indicates if any children at all have triangles CHILDREN_HAVE_TRIANGLES = 0x1 }; // Indicates which tesselation indices are associated with a node unsigned short m_FirstTesselationIndex; unsigned char m_Count; unsigned char m_Flags; Vector m_mins; // AABB for node triangles Vector m_maxs; }; // ------------------------------------------------------------------------ // // CTesselateWindings are used to tell what order a node needs to visit // vertices while tesselating. // ------------------------------------------------------------------------ // class CTesselateVert { public: CTesselateVert( CVertIndex const &index, int iNode ); CVertIndex m_Index; short m_iNode; // Which node this vert is a part of (-1 on left, right, up, and down). }; class CTesselateWinding { public: CTesselateVert *m_Verts; short m_nVerts; // (includes the last vert) }; class CVertDependency { public: // Returns false if there is no dependency stored here. bool IsValid() { return m_iVert.x != -1; } public: // The vert index is in the same power as the source displacement. // It is also wrapped, so for example, on the middle of the right edge // of a 3x3, it will have a dependency on the 3x3's root node (1,1), and it // will have another (1,1) entry that references a neighbor. CVertIndex m_iVert; // This is -1 if the vert exists inside the source displacement. // It is one of the NEIGHBOREDGE_ codes above if it reaches into a neighbor. short m_iNeighbor; }; // Precalculated data about displacement vertices. class CVertInfo { public: CVertInfo(); // These are the vertices that this vertex depends on (vertices that must be // active for this vert to exist). CVertDependency m_Dependencies[2]; // These are the vertices that have this vert in their m_Dependencies. enum { NUM_REVERSE_DEPENDENCIES=4 }; CVertDependency m_ReverseDependencies[NUM_REVERSE_DEPENDENCIES]; short m_iNodeLevel; // -1 if this is not a node. Otherwise, the recursion level // of this node (root node = 1). CVertIndex m_iParent; // x=-1 if this is a not a node or if it's the root node. }; class CTwoUShorts { public: unsigned short m_Values[2]; }; class CFourVerts { public: CVertIndex m_Verts[4]; }; // Used for referencing triangles in the fully-tesselated displacement by index. class CTriInfo { public: unsigned short m_Indices[3]; }; // Precalculated data for displacements of a certain power. class CPowerInfo { public: CPowerInfo( CVertInfo *pVertInfo, CFourVerts *pSideVerts, CFourVerts *pChildVerts, CFourVerts *pSideVertCorners, CTwoUShorts *pErrorEdges, CTriInfo *pTriInfos ); int GetPower() const { return m_Power; } int GetSideLength() const { return m_SideLength; } const CVertIndex& GetRootNode() const { return m_RootNode; } int GetMidPoint() const { return m_MidPoint; } // Half the edge length. // Get at the tri list. int GetNumTriInfos() const { return m_nTriInfos; } const CTriInfo* GetTriInfo( int i ) const { return &m_pTriInfos[i]; } // Get the number of vertices in a displacement of this power. int GetNumVerts() const { return m_MaxVerts; } // Return a corner point index. Indexed by the CORNER_ defines. const CVertIndex& GetCornerPointIndex( int iCorner ) const; public: CVertInfo *m_pVertInfo; CFourVerts *m_pSideVerts; // The 4 side verts for each node. CFourVerts *m_pChildVerts; // The 4 children for each node. CFourVerts *m_pSideVertCorners; CTwoUShorts *m_pErrorEdges; // These are the edges // that are used to measure the screenspace // error with respect to each vert. CTriInfo *m_pTriInfos; int m_nTriInfos; int m_Power; CVertIndex m_RootNode; int m_SideLength; int m_SideLengthM1; // Side length minus 1. int m_MidPoint; // Side length / 2. int m_MaxVerts; // m_SideLength * m_SideLength int m_NodeCount; // total # of nodes, including children // Precalculated increments if you're using a bit vector to represent nodes. // Starting at level 0 of the tree, this stores the increment between the nodes at this // level. Vectors holding node data are stored in preorder traversal, and these // increments tell the number of elements between nodes at each level. int m_NodeIndexIncrements[MAX_MAP_DISP_POWER]; CVertIndex m_EdgeStartVerts[4]; CVertIndex m_EdgeIncrements[4]; CVertIndex m_NeighborStartVerts[4][4]; // [side][orientation] CVertIndex m_NeighborIncrements[4][4]; // [side][orientation] private: friend void InitPowerInfo( CPowerInfo *pInfo, int iMaxPower ); CVertIndex m_CornerPointIndices[4]; }; // ----------------------------------------------------------------------------- // // Globals. // ----------------------------------------------------------------------------- // // Indexed by the TWINDING_ enums. extern CTesselateWinding g_TWinding; // ----------------------------------------------------------------------------- // // Functions. // ----------------------------------------------------------------------------- // // Valid indices are MIN_MAP_DISP_POWER through (and including) MAX_MAP_DISP_POWER. const CPowerInfo* GetPowerInfo( int iPower ); #endif // DISP_POWERINFO_H