Counter Strike : Global Offensive Source Code
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//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
// $NoKeywords: $
//=============================================================================//
#include "vrad.h"
#include "VRAD_DispColl.h"
#include "DispColl_Common.h"
#include "radial.h"
#include "CollisionUtils.h"
#include "tier0\dbg.h"
#define SAMPLE_BBOX_SLOP 5.0f
#define TRIEDGE_EPSILON 0.001f
float g_flMaxDispSampleSize = 512.0f;
static FileHandle_t pDispFile = FILESYSTEM_INVALID_HANDLE;
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
CVRADDispColl::CVRADDispColl()
{
m_iParent = -1;
m_flSampleRadius2 = 0.0f;
m_flPatchSampleRadius2 = 0.0f;
m_flSampleWidth = 0.0f;
m_flSampleHeight = 0.0f;
m_aLuxelCoords.Purge();
m_aVertNormals.Purge();
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
CVRADDispColl::~CVRADDispColl()
{
m_aLuxelCoords.Purge();
m_aVertNormals.Purge();
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
bool CVRADDispColl::Create( CCoreDispInfo *pDisp )
{
// Base class create.
if( !CDispCollTree::Create( pDisp ) )
return false;
// Allocate VRad specific memory.
m_aLuxelCoords.SetSize( GetSize() );
m_aVertNormals.SetSize( GetSize() );
// VRad specific base surface data.
CCoreDispSurface *pSurf = pDisp->GetSurface();
m_iParent = pSurf->GetHandle();
// VRad specific displacement surface data.
for ( int iVert = 0; iVert < m_aVerts.Count(); ++iVert )
{
pDisp->GetNormal( iVert, m_aVertNormals[iVert] );
pDisp->GetLuxelCoord( 0, iVert, m_aLuxelCoords[iVert] );
}
// Re-calculate the lightmap size (in uv) so that the luxels give
// a better world-space uniform approx. due to the non-linear nature
// of the displacement surface in uv-space
dface_t *pFace = &g_pFaces[m_iParent];
if( pFace )
{
CalcSampleRadius2AndBox( pFace );
}
return true;
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
void CVRADDispColl::CalcSampleRadius2AndBox( dface_t *pFace )
{
// Get the luxel sample size.
texinfo_t *pTexInfo = &texinfo[pFace->texinfo];
Assert ( pTexInfo );
if ( !pTexInfo )
return;
// Todo: Width = Height now, should change all the code to look at one value.
Vector vecTmp( pTexInfo->lightmapVecsLuxelsPerWorldUnits[0][0],
pTexInfo->lightmapVecsLuxelsPerWorldUnits[0][1],
pTexInfo->lightmapVecsLuxelsPerWorldUnits[0][2] );
float flWidth = 1.0f / VectorLength( vecTmp );
float flHeight = flWidth;
// Save off the sample width and height.
m_flSampleWidth = flWidth;
m_flSampleHeight = flHeight;
// Calculate the sample radius squared.
float flSampleRadius = sqrt( ( ( flWidth * flWidth ) + ( flHeight * flHeight ) ) ); // * 2.2f;//RADIALDIST2; // AV - Removing the 2.2 scalar since 1.0 works better with CS:GO
if ( flSampleRadius > g_flMaxDispSampleSize )
{
flSampleRadius = g_flMaxDispSampleSize;
}
m_flSampleRadius2 = flSampleRadius * flSampleRadius;
// Calculate the patch radius - the max sample edge length * the number of luxels per edge "chop."
float flSampleSize = max( m_flSampleWidth, m_flSampleHeight );
float flPatchSampleRadius = flSampleSize * dispchop * ( g_bLargeDispSampleRadius ? 2.2f : 1.0f ); // AV - Removing the 2.2 scalar since 1.0 works better with CS:GO. TS - It fixes lighting artefacts in maps with many small displacements.
if ( flPatchSampleRadius > g_MaxDispPatchRadius )
{
flPatchSampleRadius = g_MaxDispPatchRadius;
Warning( "Patch Sample Radius Clamped!\n" );
}
m_flPatchSampleRadius2 = flPatchSampleRadius * flPatchSampleRadius;
}
//-----------------------------------------------------------------------------
// Purpose: Get the min/max of the displacement surface.
//-----------------------------------------------------------------------------
void CVRADDispColl::GetSurfaceMinMax( Vector &boxMin, Vector &boxMax )
{
// Initialize the minimum and maximum box
boxMin = m_aVerts[0];
boxMax = m_aVerts[0];
for( int i = 1; i < m_aVerts.Count(); i++ )
{
if( m_aVerts[i].x < boxMin.x ) { boxMin.x = m_aVerts[i].x; }
if( m_aVerts[i].y < boxMin.y ) { boxMin.y = m_aVerts[i].y; }
if( m_aVerts[i].z < boxMin.z ) { boxMin.z = m_aVerts[i].z; }
if( m_aVerts[i].x > boxMax.x ) { boxMax.x = m_aVerts[i].x; }
if( m_aVerts[i].y > boxMax.y ) { boxMax.y = m_aVerts[i].y; }
if( m_aVerts[i].z > boxMax.z ) { boxMax.z = m_aVerts[i].z; }
}
}
//-----------------------------------------------------------------------------
// Purpose: Find the minor projection axes based on the given normal.
//-----------------------------------------------------------------------------
void CVRADDispColl::GetMinorAxes( Vector const &vecNormal, int &nAxis0, int &nAxis1 )
{
nAxis0 = 0;
nAxis1 = 1;
if( FloatMakePositive( vecNormal.x ) > FloatMakePositive( vecNormal.y ) )
{
if( FloatMakePositive( vecNormal.x ) > FloatMakePositive( vecNormal.z ) )
{
nAxis0 = 1;
nAxis1 = 2;
}
}
else
{
if( FloatMakePositive( vecNormal.y ) > FloatMakePositive( vecNormal.z ) )
{
nAxis0 = 0;
nAxis1 = 2;
}
}
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void CVRADDispColl::BaseFacePlaneToDispUV( Vector const &vecPlanePt, Vector2D &dispUV )
{
PointInQuadToBarycentric( m_vecSurfPoints[0], m_vecSurfPoints[3], m_vecSurfPoints[2], m_vecSurfPoints[1], vecPlanePt, dispUV );
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void CVRADDispColl::DispUVToSurfPoint( Vector2D const &dispUV, Vector &vecPoint, float flPushEps )
{
// Check to see that the point is on the surface.
if ( dispUV.x < 0.0f || dispUV.x > 1.0f || dispUV.y < 0.0f || dispUV.y > 1.0f )
return;
// Get the displacement power.
int nWidth = ( ( 1 << m_nPower ) + 1 );
int nHeight = nWidth;
// Scale the U, V coordinates to the displacement grid size.
float flU = dispUV.x * static_cast<float>( nWidth - 1.000001f );
float flV = dispUV.y * static_cast<float>( nHeight - 1.000001f );
// Find the base U, V.
int nSnapU = static_cast<int>( flU );
int nSnapV = static_cast<int>( flV );
// Use this to get the triangle orientation.
bool bOdd = ( ( ( nSnapV * nWidth ) + nSnapU ) % 2 == 1 );
// Top Left to Bottom Right
if( bOdd )
{
DispUVToSurf_TriTLToBR( vecPoint, flPushEps, flU, flV, nSnapU, nSnapV, nWidth, nHeight );
}
// Bottom Left to Top Right
else
{
DispUVToSurf_TriBLToTR( vecPoint, flPushEps, flU, flV, nSnapU, nSnapV, nWidth, nHeight );
}
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
void CVRADDispColl::DispUVToSurf_TriTLToBR( Vector &vecPoint, float flPushEps,
float flU, float flV, int nSnapU, int nSnapV,
int nWidth, int nHeight )
{
int nNextU = nSnapU + 1;
int nNextV = nSnapV + 1;
if ( nNextU == nWidth) { --nNextU; }
if ( nNextV == nHeight ) { --nNextV; }
float flFracU = flU - static_cast<float>( nSnapU );
float flFracV = flV - static_cast<float>( nSnapV );
if( ( flFracU + flFracV ) >= ( 1.0f + TRIEDGE_EPSILON ) )
{
int nIndices[3];
nIndices[0] = nNextV * nWidth + nSnapU;
nIndices[1] = nNextV * nWidth + nNextU;
nIndices[2] = nSnapV * nWidth + nNextU;
Vector edgeU = m_aVerts[nIndices[0]] - m_aVerts[nIndices[1]];
Vector edgeV = m_aVerts[nIndices[2]] - m_aVerts[nIndices[1]];
vecPoint = m_aVerts[nIndices[1]] + edgeU * ( 1.0f - flFracU ) + edgeV * ( 1.0f - flFracV );
if ( flPushEps != 0.0f )
{
Vector vecNormal;
vecNormal = CrossProduct( edgeU, edgeV );
VectorNormalize( vecNormal );
vecPoint += ( vecNormal * flPushEps );
}
}
else
{
int nIndices[3];
nIndices[0] = nSnapV * nWidth + nSnapU;
nIndices[1] = nNextV * nWidth + nSnapU;
nIndices[2] = nSnapV * nWidth + nNextU;
Vector edgeU = m_aVerts[nIndices[2]] - m_aVerts[nIndices[0]];
Vector edgeV = m_aVerts[nIndices[1]] - m_aVerts[nIndices[0]];
vecPoint = m_aVerts[nIndices[0]] + edgeU * flFracU + edgeV * flFracV;
if ( flPushEps != 0.0f )
{
Vector vecNormal;
vecNormal = CrossProduct( edgeU, edgeV );
VectorNormalize( vecNormal );
vecPoint += ( vecNormal * flPushEps );
}
}
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
void CVRADDispColl::DispUVToSurf_TriBLToTR( Vector &vecPoint, float flPushEps,
float flU, float flV, int nSnapU, int nSnapV,
int nWidth, int nHeight )
{
int nNextU = nSnapU + 1;
int nNextV = nSnapV + 1;
if ( nNextU == nWidth) { --nNextU; }
if ( nNextV == nHeight ) { --nNextV; }
float flFracU = flU - static_cast<float>( nSnapU );
float flFracV = flV - static_cast<float>( nSnapV );
if( flFracU < flFracV )
{
int nIndices[3];
nIndices[0] = nSnapV * nWidth + nSnapU;
nIndices[1] = nNextV * nWidth + nSnapU;
nIndices[2] = nNextV * nWidth + nNextU;
Vector edgeU = m_aVerts[nIndices[2]] - m_aVerts[nIndices[1]];
Vector edgeV = m_aVerts[nIndices[0]] - m_aVerts[nIndices[1]];
vecPoint = m_aVerts[nIndices[1]] + edgeU * flFracU + edgeV * ( 1.0f - flFracV );
if ( flPushEps != 0.0f )
{
Vector vecNormal;
vecNormal = CrossProduct( edgeV, edgeU );
VectorNormalize( vecNormal );
vecPoint += ( vecNormal * flPushEps );
}
}
else
{
int nIndices[3];
nIndices[0] = nSnapV * nWidth + nSnapU;
nIndices[1] = nNextV * nWidth + nNextU;
nIndices[2] = nSnapV * nWidth + nNextU;
Vector edgeU = m_aVerts[nIndices[0]] - m_aVerts[nIndices[2]];
Vector edgeV = m_aVerts[nIndices[1]] - m_aVerts[nIndices[2]];
vecPoint = m_aVerts[nIndices[2]] + edgeU * ( 1.0f - flFracU ) + edgeV * flFracV;
if ( flPushEps != 0.0f )
{
Vector vecNormal;
vecNormal = CrossProduct( edgeV, edgeU );
VectorNormalize( vecNormal );
vecPoint += ( vecNormal * flPushEps );
}
}
}
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
void CVRADDispColl::DispUVToSurfNormal( Vector2D const &dispUV, Vector &vecNormal )
{
// Check to see that the point is on the surface.
if ( dispUV.x < 0.0f || dispUV.x > 1.0f || dispUV.y < 0.0f || dispUV.y > 1.0f )
return;
// Get the displacement power.
int nWidth = ( ( 1 << m_nPower ) + 1 );
int nHeight = nWidth;
// Scale the U, V coordinates to the displacement grid size.
float flU = dispUV.x * static_cast<float>( nWidth - 1.000001f );
float flV = dispUV.y * static_cast<float>( nHeight - 1.000001f );
// Find the base U, V.
int nSnapU = static_cast<int>( flU );
int nSnapV = static_cast<int>( flV );
int nNextU = nSnapU + 1;
int nNextV = nSnapV + 1;
if ( nNextU == nWidth) { --nNextU; }
if ( nNextV == nHeight ) { --nNextV; }
float flFracU = flU - static_cast<float>( nSnapU );
float flFracV = flV - static_cast<float>( nSnapV );
// Get the four normals "around" the "spot"
int iQuad[VRAD_QUAD_SIZE];
iQuad[0] = ( nSnapV * nWidth ) + nSnapU;
iQuad[1] = ( nNextV * nWidth ) + nSnapU;
iQuad[2] = ( nNextV * nWidth ) + nNextU;
iQuad[3] = ( nSnapV * nWidth ) + nNextU;
// Find the blended normal (bi-linear).
Vector vecTmpNormals[2], vecBlendedNormals[2], vecDispNormals[4];
for ( int iVert = 0; iVert < VRAD_QUAD_SIZE; ++iVert )
{
GetVertNormal( iQuad[iVert], vecDispNormals[iVert] );
}
vecTmpNormals[0] = vecDispNormals[0] * ( 1.0f - flFracU );
vecTmpNormals[1] = vecDispNormals[3] * flFracU;
vecBlendedNormals[0] = vecTmpNormals[0] + vecTmpNormals[1];
VectorNormalize( vecBlendedNormals[0] );
vecTmpNormals[0] = vecDispNormals[1] * ( 1.0f - flFracU );
vecTmpNormals[1] = vecDispNormals[2] * flFracU;
vecBlendedNormals[1] = vecTmpNormals[0] + vecTmpNormals[1];
VectorNormalize( vecBlendedNormals[1] );
vecTmpNormals[0] = vecBlendedNormals[0] * ( 1.0f - flFracV );
vecTmpNormals[1] = vecBlendedNormals[1] * flFracV;
vecNormal = vecTmpNormals[0] + vecTmpNormals[1];
VectorNormalize( vecNormal );
}
//-----------------------------------------------------------------------------
// Purpose:
// Output : float
//-----------------------------------------------------------------------------
float CVRADDispColl::CreateParentPatches( void )
{
// Save the total surface area of the displacement.
float flTotalArea = 0.0f;
// Get the number of displacement subdivisions.
int nInterval = GetWidth();
Vector vecPoints[4];
vecPoints[0].Init( m_aVerts[0].x, m_aVerts[0].y, m_aVerts[0].z );
vecPoints[1].Init( m_aVerts[(nInterval*(nInterval-1))].x, m_aVerts[(nInterval*(nInterval-1))].y, m_aVerts[(nInterval*(nInterval-1))].z );
vecPoints[2].Init( m_aVerts[((nInterval*nInterval)-1)].x, m_aVerts[((nInterval*nInterval)-1)].y, m_aVerts[((nInterval*nInterval)-1)].z );
vecPoints[3].Init( m_aVerts[(nInterval-1)].x, m_aVerts[(nInterval-1)].y, m_aVerts[(nInterval-1)].z );
// Create and initialize the patch.
int iPatch = g_Patches.AddToTail();
if ( iPatch == g_Patches.InvalidIndex() )
return flTotalArea;
// Keep track of the area of the patches.
float flArea = 0.0f;
if ( !InitParentPatch( iPatch, vecPoints, flArea ) )
{
g_Patches.Remove( iPatch );
flArea = 0.0f;
}
// Return the displacement area.
return flArea;
}
//-----------------------------------------------------------------------------
// Purpose:
// Input : iParentPatch -
// nLevel -
//-----------------------------------------------------------------------------
void CVRADDispColl::CreateChildPatchesFromRoot( int iParentPatch, int *pChildPatch )
{
// Initialize the child patch indices.
pChildPatch[0] = g_Patches.InvalidIndex();
pChildPatch[1] = g_Patches.InvalidIndex();
// Get the number of displacement subdivisions.
int nInterval = GetWidth();
// Get the parent patch.
CPatch *pParentPatch = &g_Patches[iParentPatch];
if ( !pParentPatch )
return;
// Split along the longest edge.
Vector vecEdges[4];
vecEdges[0] = pParentPatch->winding->p[1] - pParentPatch->winding->p[0];
vecEdges[1] = pParentPatch->winding->p[2] - pParentPatch->winding->p[1];
vecEdges[2] = pParentPatch->winding->p[3] - pParentPatch->winding->p[2];
vecEdges[3] = pParentPatch->winding->p[3] - pParentPatch->winding->p[0];
// Should the patch be subdivided - check the area.
float flMaxLength = max( m_flSampleWidth, m_flSampleHeight );
float flMinEdgeLength = flMaxLength * dispchop;
// Find the longest edge.
float flEdgeLength = 0.0f;
int iLongEdge = -1;
for ( int iEdge = 0; iEdge < 4; ++iEdge )
{
float flLength = vecEdges[iEdge].Length();
if ( flEdgeLength < flLength )
{
flEdgeLength = vecEdges[iEdge].Length();
iLongEdge = iEdge;
}
}
// Small enough already, return.
if ( flEdgeLength < flMinEdgeLength )
return;
// Test area as well so we don't allow slivers.
float flMinArea = ( dispchop * flMaxLength ) * ( dispchop * flMaxLength );
Vector vecNormal = vecEdges[3].Cross( vecEdges[0] );
float flTestArea = VectorNormalize( vecNormal );
if ( flTestArea < flMinArea )
return;
// Get the points for the first triangle.
int iPoints[3];
Vector vecPoints[3];
float flArea;
iPoints[0] = ( nInterval * nInterval ) - 1;
iPoints[1] = 0;
iPoints[2] = nInterval * ( nInterval - 1 );
for ( int iPoint = 0; iPoint < 3; ++iPoint )
{
VectorCopy( m_aVerts[iPoints[iPoint]], vecPoints[iPoint] );
}
// Create and initialize the patch.
pChildPatch[0] = g_Patches.AddToTail();
if ( pChildPatch[0] == g_Patches.InvalidIndex() )
return;
if ( !InitPatch( pChildPatch[0], iParentPatch, 0, vecPoints, iPoints, flArea ) )
{
g_Patches.Remove( pChildPatch[0] );
pChildPatch[0] = g_Patches.InvalidIndex();
return;
}
// Get the points for the second triangle.
iPoints[0] = 0;
iPoints[1] = ( nInterval * nInterval ) - 1;
iPoints[2] = nInterval - 1;
for ( int iPoint = 0; iPoint < 3; ++iPoint )
{
VectorCopy( m_aVerts[iPoints[iPoint]], vecPoints[iPoint] );
}
// Create and initialize the patch.
pChildPatch[1] = g_Patches.AddToTail();
if ( pChildPatch[1] == g_Patches.InvalidIndex() )
{
g_Patches.Remove( pChildPatch[0] );
pChildPatch[0] = g_Patches.InvalidIndex();
return;
}
if ( !InitPatch( pChildPatch[1], iParentPatch, 1, vecPoints, iPoints, flArea ) )
{
g_Patches.Remove( pChildPatch[0] );
pChildPatch[0] = g_Patches.InvalidIndex();
g_Patches.Remove( pChildPatch[1] );
pChildPatch[1] = g_Patches.InvalidIndex();
return;
}
}
//-----------------------------------------------------------------------------
// Purpose:
// Input : flMinArea -
// Output : float
//-----------------------------------------------------------------------------
void CVRADDispColl::CreateChildPatches( int iParentPatch, int nLevel )
{
// Get the parent patch.
CPatch *pParentPatch = &g_Patches[iParentPatch];
if ( !pParentPatch )
return;
// The root face is a quad - special case.
if ( pParentPatch->winding->numpoints == 4 )
{
int iChildPatch[2];
CreateChildPatchesFromRoot( iParentPatch, iChildPatch );
if ( iChildPatch[0] != g_Patches.InvalidIndex() && iChildPatch[1] != g_Patches.InvalidIndex() )
{
CreateChildPatches( iChildPatch[0], 0 );
CreateChildPatches( iChildPatch[1], 0 );
}
return;
}
// Calculate the the area of the patch (triangle!).
Assert( pParentPatch->winding->numpoints == 3 );
if ( pParentPatch->winding->numpoints != 3 )
return;
// Should the patch be subdivided - check the area.
float flMaxLength = max( m_flSampleWidth, m_flSampleHeight );
float flMinEdgeLength = flMaxLength * dispchop;
// Split along the longest edge.
Vector vecEdges[3];
vecEdges[0] = pParentPatch->winding->p[1] - pParentPatch->winding->p[0];
vecEdges[1] = pParentPatch->winding->p[2] - pParentPatch->winding->p[0];
vecEdges[2] = pParentPatch->winding->p[2] - pParentPatch->winding->p[1];
// Find the longest edge.
float flEdgeLength = 0.0f;
int iLongEdge = -1;
for ( int iEdge = 0; iEdge < 3; ++iEdge )
{
if ( flEdgeLength < vecEdges[iEdge].Length() )
{
flEdgeLength = vecEdges[iEdge].Length();
iLongEdge = iEdge;
}
}
// Small enough already, return.
if ( flEdgeLength < flMinEdgeLength )
return;
// Test area as well so we don't allow slivers.
float flMinArea = ( dispchop * flMaxLength ) * ( dispchop * flMaxLength ) * 0.5f;
Vector vecNormal = vecEdges[1].Cross( vecEdges[0] );
float flTestArea = VectorNormalize( vecNormal );
flTestArea *= 0.5f;
if ( flTestArea < flMinArea )
return;
// Check to see if any more displacement verts exist - go to subdivision if not.
if ( nLevel >= ( m_nPower * 2 ) )
{
CreateChildPatchesSub( iParentPatch );
return;
}
int nChildIndices[2][3];
int nNewIndex = ( pParentPatch->indices[1] + pParentPatch->indices[0] ) / 2;
nChildIndices[0][0] = pParentPatch->indices[2];
nChildIndices[0][1] = pParentPatch->indices[0];
nChildIndices[0][2] = nNewIndex;
nChildIndices[1][0] = pParentPatch->indices[1];
nChildIndices[1][1] = pParentPatch->indices[2];
nChildIndices[1][2] = nNewIndex;
Vector vecChildPoints[2][3];
for ( int iTri = 0; iTri < 2; ++iTri )
{
for ( int iPoint = 0; iPoint < 3; ++iPoint )
{
VectorCopy( m_aVerts[nChildIndices[iTri][iPoint]], vecChildPoints[iTri][iPoint] );
}
}
// Create and initialize the children patches.
int iChildPatch[2] = { -1, -1 };
for ( int iChild = 0; iChild < 2; ++iChild )
{
iChildPatch[iChild] = g_Patches.AddToTail();
float flArea = 0.0f;
if ( !InitPatch( iChildPatch[iChild], iParentPatch, iChild, vecChildPoints[iChild], nChildIndices[iChild], flArea ) )
{
if ( iChild == 0 )
{
pParentPatch->child1 = g_Patches.InvalidIndex();
g_Patches.Remove( iChildPatch[iChild] );
break;
}
else
{
pParentPatch->child1 = g_Patches.InvalidIndex();
pParentPatch->child2 = g_Patches.InvalidIndex();
g_Patches.Remove( iChildPatch[iChild] );
g_Patches.Remove( iChildPatch[0] );
}
}
}
// Continue creating children patches.
int nNewLevel = ++nLevel;
CreateChildPatches( iChildPatch[0], nNewLevel );
CreateChildPatches( iChildPatch[1], nNewLevel );
}
//-----------------------------------------------------------------------------
// Purpose:
// Input : flMinArea -
// Output : float
//-----------------------------------------------------------------------------
void CVRADDispColl::CreateChildPatchesSub( int iParentPatch )
{
// Get the parent patch.
CPatch *pParentPatch = &g_Patches[iParentPatch];
if ( !pParentPatch )
return;
// Calculate the the area of the patch (triangle!).
Assert( pParentPatch->winding->numpoints == 3 );
if ( pParentPatch->winding->numpoints != 3 )
return;
// Should the patch be subdivided - check the area.
float flMaxLength = max( m_flSampleWidth, m_flSampleHeight );
float flMinEdgeLength = flMaxLength * dispchop;
// Split along the longest edge.
Vector vecEdges[3];
vecEdges[0] = pParentPatch->winding->p[1] - pParentPatch->winding->p[0];
vecEdges[1] = pParentPatch->winding->p[2] - pParentPatch->winding->p[0];
vecEdges[2] = pParentPatch->winding->p[2] - pParentPatch->winding->p[1];
// Find the longest edge.
float flEdgeLength = 0.0f;
int iLongEdge = -1;
for ( int iEdge = 0; iEdge < 3; ++iEdge )
{
if ( flEdgeLength < vecEdges[iEdge].Length() )
{
flEdgeLength = vecEdges[iEdge].Length();
iLongEdge = iEdge;
}
}
// Small enough already, return.
if ( flEdgeLength < flMinEdgeLength )
return;
// Test area as well so we don't allow slivers.
float flMinArea = ( dispchop * flMaxLength ) * ( dispchop * flMaxLength ) * 0.5f;
Vector vecNormal = vecEdges[1].Cross( vecEdges[0] );
float flTestArea = VectorNormalize( vecNormal );
flTestArea *= 0.5f;
if ( flTestArea < flMinArea )
return;
// Create children patchs - 2 of them.
Vector vecChildPoints[2][3];
switch ( iLongEdge )
{
case 0:
{
vecChildPoints[0][0] = pParentPatch->winding->p[0];
vecChildPoints[0][1] = ( pParentPatch->winding->p[0] + pParentPatch->winding->p[1] ) * 0.5f;
vecChildPoints[0][2] = pParentPatch->winding->p[2];
vecChildPoints[1][0] = ( pParentPatch->winding->p[0] + pParentPatch->winding->p[1] ) * 0.5f;
vecChildPoints[1][1] = pParentPatch->winding->p[1];
vecChildPoints[1][2] = pParentPatch->winding->p[2];
break;
}
case 1:
{
vecChildPoints[0][0] = pParentPatch->winding->p[0];
vecChildPoints[0][1] = pParentPatch->winding->p[1];
vecChildPoints[0][2] = ( pParentPatch->winding->p[1] + pParentPatch->winding->p[2] ) * 0.5f;
vecChildPoints[1][0] = ( pParentPatch->winding->p[1] + pParentPatch->winding->p[2] ) * 0.5f;
vecChildPoints[1][1] = pParentPatch->winding->p[2];
vecChildPoints[1][2] = pParentPatch->winding->p[0];
break;
}
case 2:
{
vecChildPoints[0][0] = pParentPatch->winding->p[0];
vecChildPoints[0][1] = pParentPatch->winding->p[1];
vecChildPoints[0][2] = ( pParentPatch->winding->p[0] + pParentPatch->winding->p[2] ) * 0.5f;
vecChildPoints[1][0] = ( pParentPatch->winding->p[0] + pParentPatch->winding->p[2] ) * 0.5f;
vecChildPoints[1][1] = pParentPatch->winding->p[1];
vecChildPoints[1][2] = pParentPatch->winding->p[2];
break;
}
}
// Create and initialize the children patches.
int iChildPatch[2] = { 0, 0 };
int nChildIndices[3] = { -1, -1, -1 };
for ( int iChild = 0; iChild < 2; ++iChild )
{
iChildPatch[iChild] = g_Patches.AddToTail();
float flArea = 0.0f;
if ( !InitPatch( iChildPatch[iChild], iParentPatch, iChild, vecChildPoints[iChild], nChildIndices, flArea ) )
{
if ( iChild == 0 )
{
pParentPatch->child1 = g_Patches.InvalidIndex();
g_Patches.Remove( iChildPatch[iChild] );
break;
}
else
{
pParentPatch->child1 = g_Patches.InvalidIndex();
pParentPatch->child2 = g_Patches.InvalidIndex();
g_Patches.Remove( iChildPatch[iChild] );
g_Patches.Remove( iChildPatch[0] );
}
}
}
// Continue creating children patches.
CreateChildPatchesSub( iChildPatch[0] );
CreateChildPatchesSub( iChildPatch[1] );
}
int PlaneTypeForNormal (Vector& normal)
{
vec_t ax, ay, az;
// NOTE: should these have an epsilon around 1.0?
if (normal[0] == 1.0 || normal[0] == -1.0)
return PLANE_X;
if (normal[1] == 1.0 || normal[1] == -1.0)
return PLANE_Y;
if (normal[2] == 1.0 || normal[2] == -1.0)
return PLANE_Z;
ax = fabs(normal[0]);
ay = fabs(normal[1]);
az = fabs(normal[2]);
if (ax >= ay && ax >= az)
return PLANE_ANYX;
if (ay >= ax && ay >= az)
return PLANE_ANYY;
return PLANE_ANYZ;
}
//-----------------------------------------------------------------------------
// Purpose:
// Input : iPatch -
// iParentPatch -
// iChild -
// *pPoints -
// *pIndices -
// &flArea -
// Output : Returns true on success, false on failure.
//-----------------------------------------------------------------------------
bool CVRADDispColl::InitParentPatch( int iPatch, Vector *pPoints, float &flArea )
{
// Get the current patch.
CPatch *pPatch = &g_Patches[iPatch];
if ( !pPatch )
return false;
// Clear the patch data.
memset( pPatch, 0, sizeof( CPatch ) );
// This is a parent.
pPatch->ndxNext = g_FacePatches.Element( GetParentIndex() );
g_FacePatches[GetParentIndex()] = iPatch;
pPatch->faceNumber = GetParentIndex();
// Initialize parent and children indices.
pPatch->child1 = g_Patches.InvalidIndex();
pPatch->child2 = g_Patches.InvalidIndex();
pPatch->parent = g_Patches.InvalidIndex();
pPatch->ndxNextClusterChild = g_Patches.InvalidIndex();
pPatch->ndxNextParent = g_Patches.InvalidIndex();
pPatch->staticPropIdx = -1;
Vector vecEdges[2];
vecEdges[0] = pPoints[1] - pPoints[0];
vecEdges[1] = pPoints[3] - pPoints[0];
// Calculate the triangle normal and area.
Vector vecNormal = vecEdges[1].Cross( vecEdges[0] );
flArea = VectorNormalize( vecNormal );
// Initialize the patch scale.
pPatch->scale[0] = pPatch->scale[1] = 1.0f;
// Set the patch chop - minchop (that is what the minimum area is based on).
pPatch->chop = dispchop;
// Displacements are not sky!
pPatch->sky = false;
// Copy the winding.
Vector vecCenter( 0.0f, 0.0f, 0.0f );
pPatch->winding = AllocWinding( 4 );
pPatch->winding->numpoints = 4;
for ( int iPoint = 0; iPoint < 4; ++iPoint )
{
VectorCopy( pPoints[iPoint], pPatch->winding->p[iPoint] );
VectorAdd( pPoints[iPoint], vecCenter, vecCenter );
}
// Set the origin and normal.
VectorScale( vecCenter, ( 1.0f / 4.0f ), vecCenter );
VectorCopy( vecCenter, pPatch->origin );
VectorCopy( vecNormal, pPatch->normal );
// Create the plane.
pPatch->plane = new dplane_t;
if ( !pPatch->plane )
return false;
VectorCopy( vecNormal, pPatch->plane->normal );
pPatch->plane->dist = vecNormal.Dot( pPoints[0] );
pPatch->plane->type = PlaneTypeForNormal( pPatch->plane->normal );
pPatch->planeDist = pPatch->plane->dist;
// Set the area.
pPatch->area = flArea;
// Calculate the mins/maxs.
Vector vecMin( FLT_MAX, FLT_MAX, FLT_MAX );
Vector vecMax( FLT_MIN, FLT_MIN, FLT_MIN );
for ( int iPoint = 0; iPoint < 4; ++iPoint )
{
for ( int iAxis = 0; iAxis < 3; ++iAxis )
{
vecMin[iAxis] = min( vecMin[iAxis], pPoints[iPoint][iAxis] );
vecMax[iAxis] = max( vecMax[iAxis], pPoints[iPoint][iAxis] );
}
}
VectorCopy( vecMin, pPatch->mins );
VectorCopy( vecMax, pPatch->maxs );
VectorCopy( vecMin, pPatch->face_mins );
VectorCopy( vecMax, pPatch->face_maxs );
// Check for bumpmap.
dface_t *pFace = dfaces + pPatch->faceNumber;
texinfo_t *pTexInfo = &texinfo[pFace->texinfo];
pPatch->needsBumpmap = pTexInfo->flags & SURF_BUMPLIGHT ? true : false;
// Misc...
pPatch->m_IterationKey = 0;
// Calculate the base light, area, and reflectivity.
BaseLightForFace( &g_pFaces[pPatch->faceNumber], pPatch->baselight, &pPatch->basearea, pPatch->reflectivity );
return true;
}
//-----------------------------------------------------------------------------
// Purpose:
// Input : *pPatch -
// *pPoints -
// &vecNormal -
// flArea -
//-----------------------------------------------------------------------------
bool CVRADDispColl::InitPatch( int iPatch, int iParentPatch, int iChild, Vector *pPoints, int *pIndices, float &flArea )
{
// Get the current patch.
CPatch *pPatch = &g_Patches[iPatch];
if ( !pPatch )
return false;
// Clear the patch data.
memset( pPatch, 0, sizeof( CPatch ) );
pPatch->staticPropIdx = -1;
// Setup the parent if we are not the parent.
CPatch *pParentPatch = NULL;
if ( iParentPatch != g_Patches.InvalidIndex() )
{
// Get the parent patch.
pParentPatch = &g_Patches[iParentPatch];
if ( !pParentPatch )
return false;
}
// Attach the face to the correct lists.
if ( !pParentPatch )
{
// This is a parent.
pPatch->ndxNext = g_FacePatches.Element( GetParentIndex() );
g_FacePatches[GetParentIndex()] = iPatch;
pPatch->faceNumber = GetParentIndex();
}
else
{
pPatch->ndxNext = g_Patches.InvalidIndex();
pPatch->faceNumber = pParentPatch->faceNumber;
// Attach to the parent patch.
if ( iChild == 0 )
{
pParentPatch->child1 = iPatch;
}
else
{
pParentPatch->child2 = iPatch;
}
}
// Initialize parent and children indices.
pPatch->child1 = g_Patches.InvalidIndex();
pPatch->child2 = g_Patches.InvalidIndex();
pPatch->ndxNextClusterChild = g_Patches.InvalidIndex();
pPatch->ndxNextParent = g_Patches.InvalidIndex();
pPatch->parent = iParentPatch;
// Get triangle edges.
Vector vecEdges[3];
vecEdges[0] = pPoints[1] - pPoints[0];
vecEdges[1] = pPoints[2] - pPoints[0];
vecEdges[2] = pPoints[2] - pPoints[1];
// Find the longest edge.
// float flEdgeLength = 0.0f;
// for ( int iEdge = 0; iEdge < 3; ++iEdge )
// {
// if ( flEdgeLength < vecEdges[iEdge].Length() )
// {
// flEdgeLength = vecEdges[iEdge].Length();
// }
// }
// Calculate the triangle normal and area.
Vector vecNormal = vecEdges[1].Cross( vecEdges[0] );
flArea = VectorNormalize( vecNormal );
flArea *= 0.5f;
// Initialize the patch scale.
pPatch->scale[0] = pPatch->scale[1] = 1.0f;
// Set the patch chop - minchop (that is what the minimum area is based on).
pPatch->chop = dispchop;
// Displacements are not sky!
pPatch->sky = false;
// Copy the winding.
Vector vecCenter( 0.0f, 0.0f, 0.0f );
pPatch->winding = AllocWinding( 3 );
pPatch->winding->numpoints = 3;
for ( int iPoint = 0; iPoint < 3; ++iPoint )
{
VectorCopy( pPoints[iPoint], pPatch->winding->p[iPoint] );
VectorAdd( pPoints[iPoint], vecCenter, vecCenter );
pPatch->indices[iPoint] = static_cast<short>( pIndices[iPoint] );
}
// Set the origin and normal.
VectorScale( vecCenter, ( 1.0f / 3.0f ), vecCenter );
VectorCopy( vecCenter, pPatch->origin );
VectorCopy( vecNormal, pPatch->normal );
// Create the plane.
pPatch->plane = new dplane_t;
if ( !pPatch->plane )
return false;
VectorCopy( vecNormal, pPatch->plane->normal );
pPatch->plane->dist = vecNormal.Dot( pPoints[0] );
pPatch->plane->type = PlaneTypeForNormal( pPatch->plane->normal );
pPatch->planeDist = pPatch->plane->dist;
// Set the area.
pPatch->area = flArea;
// Calculate the mins/maxs.
Vector vecMin( FLT_MAX, FLT_MAX, FLT_MAX );
Vector vecMax( FLT_MIN, FLT_MIN, FLT_MIN );
for ( int iPoint = 0; iPoint < 3; ++iPoint )
{
for ( int iAxis = 0; iAxis < 3; ++iAxis )
{
vecMin[iAxis] = min( vecMin[iAxis], pPoints[iPoint][iAxis] );
vecMax[iAxis] = max( vecMax[iAxis], pPoints[iPoint][iAxis] );
}
}
VectorCopy( vecMin, pPatch->mins );
VectorCopy( vecMax, pPatch->maxs );
if ( !pParentPatch )
{
VectorCopy( vecMin, pPatch->face_mins );
VectorCopy( vecMax, pPatch->face_maxs );
}
else
{
VectorCopy( pParentPatch->face_mins, pPatch->face_mins );
VectorCopy( pParentPatch->face_maxs, pPatch->face_maxs );
}
// Check for bumpmap.
dface_t *pFace = dfaces + pPatch->faceNumber;
texinfo_t *pTexInfo = &texinfo[pFace->texinfo];
pPatch->needsBumpmap = pTexInfo->flags & SURF_BUMPLIGHT ? true : false;
// Misc...
pPatch->m_IterationKey = 0;
// Get the base light for the face.
if ( !pParentPatch )
{
BaseLightForFace( &g_pFaces[pPatch->faceNumber], pPatch->baselight, &pPatch->basearea, pPatch->reflectivity );
}
else
{
VectorCopy( pParentPatch->baselight, pPatch->baselight );
pPatch->basearea = pParentPatch->basearea;
pPatch->reflectivity = pParentPatch->reflectivity;
}
return true;
}
void CVRADDispColl::AddPolysForRayTrace( void )
{
if ( !( m_nContents & MASK_OPAQUE ) )
return;
for ( int ndxTri = 0; ndxTri < m_aTris.Count(); ndxTri++ )
{
CDispCollTri *tri = m_aTris.Base() + ndxTri;
int v[3];
for ( int ndxv = 0; ndxv < 3; ndxv++ )
v[ndxv] = tri->GetVert(ndxv);
Vector fullCoverage;
fullCoverage.x = 1.0f;
g_RtEnv.AddTriangle( TRACE_ID_OPAQUE, m_aVerts[v[0]], m_aVerts[v[1]], m_aVerts[v[2]], fullCoverage );
}
}