mirror of
https://github.com/nillerusr/source-engine.git
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349 lines
9.1 KiB
C++
349 lines
9.1 KiB
C++
//========= Copyright Valve Corporation, All rights reserved. ============//
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//
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// Purpose:
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//
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// $NoKeywords: $
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//=============================================================================//
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#include "stdafx.h"
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#include "IEditorTexture.h"
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#include "MapFace.h"
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#include "clipcode.h"
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// memdbgon must be the last include file in a .cpp file!!!
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#include "tier0/memdbgon.h"
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static float g_vert[MAX_CLIPVERT][VERTEXSIZE];
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static int g_outCount;
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// Quick and dirty sutherland Hodgman clipper
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// Clip polygon to decal in texture space
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// JAY: This code is lame, change it later. It does way too much work per frame
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// It can be made to recursively call the clipping code and only copy the vertex list once
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int Inside( float *vert, int edge )
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{
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switch( edge ) {
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case 0: // left
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if ( vert[3] > 0.0 )
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return 1;
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return 0;
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case 1: // right
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if ( vert[3] < 1.0 )
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return 1;
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return 0;
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case 2: // top
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if ( vert[4] > 0.0 )
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return 1;
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return 0;
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case 3:
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if ( vert[4] < 1.0 )
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return 1;
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return 0;
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}
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return 0;
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}
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void Intersect( float *one, float *two, int edge, float *out )
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{
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float t;
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// t is the parameter of the line between one and two clipped to the edge
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// or the fraction of the clipped point between one & two
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// vert[3] is u
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// vert[4] is v
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// vert[0], vert[1], vert[2] is X, Y, Z
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if ( edge < 2 ) {
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if ( edge == 0 ) { // left
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t = ( (one[3] - 0) / (one[3] - two[3]) );
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out[3] = 0;
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}
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else { // right
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t = ( (one[3] - 1) / (one[3] - two[3]) );
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out[3] = 1;
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}
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out[4] = one[4] + (two[4] - one[4]) * t;
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}
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else {
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if ( edge == 2 ) { // top
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t = ( (one[4] - 0) / (one[4] - two[4]) );
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out[4] = 0;
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}
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else { // bottom
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t = ( (one[4] - 1) / (one[4] - two[4]) );
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out[4] = 1;
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}
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out[3] = one[3] + (two[3] - one[3]) * t;
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}
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out[0] = one[0] + (two[0] - one[0]) * t;
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out[1] = one[1] + (two[1] - one[1]) * t;
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out[2] = one[2] + (two[2] - one[2]) * t;
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}
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//-----------------------------------------------------------------------------
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// Purpose:
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// Input : *vert -
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// vertCount -
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// *out -
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// outSize -
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// edge -
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// Output : int
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//-----------------------------------------------------------------------------
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int SHClip( float *vert, int vertCount, float *out, int outSize, int edge )
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{
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int j, outCount;
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float *s, *p;
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outCount = 0;
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s = &vert[ (vertCount-1) * VERTEXSIZE ];
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for ( j = 0; j < vertCount; j++ ) {
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p = &vert[ j * VERTEXSIZE ];
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if ( Inside( p, edge ) ) {
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if ( Inside( s, edge ) ) {
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// Add a vertex and advance out to next vertex
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memcpy( out, p, sizeof(float)*VERTEXSIZE );
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outCount++;
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out += VERTEXSIZE;
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}
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else {
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Intersect( s, p, edge, out );
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out += VERTEXSIZE;
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outCount++;
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memcpy( out, p, sizeof(float)*VERTEXSIZE );
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outCount++;
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out += VERTEXSIZE;
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}
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}
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else {
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if ( Inside( s, edge ) ) {
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Intersect( p, s, edge, out );
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out += VERTEXSIZE;
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outCount++;
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}
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}
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if (outCount >= outSize)
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{
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Assert(FALSE);
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break;
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}
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s = p;
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}
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return outCount;
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}
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#define SIN_45_DEGREES ( 0.70710678118654752440084436210485f )
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// The world coordinate system is right handed with Z up.
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//
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// ^ Z
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// |
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// |
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// |
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//X<----|
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// \
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// \
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// \ Y
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//-----------------------------------------------------------------------------
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// compute the decal basis based on surface normal, and preferred saxis
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//-----------------------------------------------------------------------------
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static void R_DecalComputeBasis( Vector const& surfaceNormal, Vector const* pSAxis,
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bool flipNormal, Vector* textureSpaceBasis )
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{
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// s, t, textureSpaceNormal (T cross S = textureSpaceNormal(N))
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// N
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// \
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// \
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// \
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// |---->S
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// |
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// |
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// |T
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// S = textureSpaceBasis[0]
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// T = textureSpaceBasis[1]
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// N = textureSpaceBasis[2]
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// Get the surface normal.
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textureSpaceBasis[2] = surfaceNormal;
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if (flipNormal)
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VectorNegate( textureSpaceBasis[2] );
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if (pSAxis)
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{
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// T = S cross N
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CrossProduct( *pSAxis, textureSpaceBasis[2], textureSpaceBasis[1] );
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// Name sure they aren't parallel or antiparallel
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// In that case, fall back to the normal algorithm.
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if ( DotProduct( textureSpaceBasis[1], textureSpaceBasis[1] ) > 1e-6 )
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{
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// S = N cross T
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CrossProduct( textureSpaceBasis[2], textureSpaceBasis[1], textureSpaceBasis[0] );
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VectorNormalize( textureSpaceBasis[0] );
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VectorNormalize( textureSpaceBasis[1] );
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return;
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}
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// Fall through to the standard algorithm for parallel or antiparallel
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}
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// floor/ceiling?
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if( fabs( surfaceNormal[2] ) > SIN_45_DEGREES )
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{
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textureSpaceBasis[0][0] = 1.0f;
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textureSpaceBasis[0][1] = 0.0f;
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textureSpaceBasis[0][2] = 0.0f;
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// T = S cross N
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CrossProduct( textureSpaceBasis[0], textureSpaceBasis[2], textureSpaceBasis[1] );
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// S = N cross T
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CrossProduct( textureSpaceBasis[2], textureSpaceBasis[1], textureSpaceBasis[0] );
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}
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// wall
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else
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{
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textureSpaceBasis[1][0] = 0.0f;
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textureSpaceBasis[1][1] = 0.0f;
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textureSpaceBasis[1][2] = -1.0f;
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// S = N cross T
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CrossProduct( textureSpaceBasis[2], textureSpaceBasis[1], textureSpaceBasis[0] );
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// T = S cross N
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CrossProduct( textureSpaceBasis[0], textureSpaceBasis[2], textureSpaceBasis[1] );
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}
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VectorNormalize( textureSpaceBasis[0] );
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VectorNormalize( textureSpaceBasis[1] );
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}
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//-----------------------------------------------------------------------------
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// Purpose: Clips a texture to a face. Used for decal application.
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// NOTE : HL and HL2 generate texcoords for decals differently!!!
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// Input : pFace -
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// pDecalTex -
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// org -
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// pOutPoints -
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// Output : Returns the number of points places in the pOutPoints array.
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//-----------------------------------------------------------------------------
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int CreateClippedPoly(CMapFace *pFace, IEditorTexture *pDecalTex, Vector& org, vec5_t *pOutPoints, int nOutSize)
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{
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float outvert[MAX_CLIPVERT][VERTEXSIZE];
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Assert(nOutSize <= MAX_CLIPVERT); // This code uses temp buffers of this size.
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/*#ifdef SDK_BUILD
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BUG: THIS IS THE HL1 VERSION! SWITCH BETWEEN THESE ALGORITHMS AT RUNTIME
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Vector vecOrg, vecSAxis, vecTAxis;
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// Copy the origin.
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vecOrg = org;
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// Get the U/V axes for this face.
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vecSAxis = pFace->texture.UAxis;
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vecTAxis = pFace->texture.VAxis;
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float decalwidth = pDecalTex->GetWidth();
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float decalheight = pDecalTex->GetHeight();
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float scale = 1.0f;
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IEditorTexture *pFaceTex = pFace->GetTexture();
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float scalex = scale * (float)pFaceTex->GetWidth() / decalwidth;
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float scaley = scale * (float)pFaceTex->GetHeight() / decalheight;
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float u = DotProduct(vecSAxis, vecOrg);
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float v = DotProduct(vecTAxis, vecOrg);
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u -= decalwidth / 2;
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v -= decalheight / 2;
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u /= pFaceTex->GetWidth();
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v /= pFaceTex->GetHeight();
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// Generate texture coordinates for each vertex in decal s,t space
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Vector *pVertex = pFace->Points;
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float curU, curV;
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for (int j = 0; j < pFace->nPoints; j++, pVertex++)
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{
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// Copy X, Y, & Z
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g_vert[j][0] = pVertex[0][0];
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g_vert[j][1] = pVertex[0][1];
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g_vert[j][2] = pVertex[0][2];
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// Get u, v coordinates of vertex in DECAL SPACE
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curU = DotProduct(vecSAxis, *pVertex) / pFaceTex->GetWidth();
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curV = DotProduct(vecTAxis, *pVertex) / pFaceTex->GetHeight();
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// Generate U & V
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g_vert[j][3] = (curU - u) * scalex; // Decal relative texture coordinates
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g_vert[j][4] = (curV - v) * scaley;
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}
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#else */
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// THIS IS THE HL2 VERSION!
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float decalScale = pDecalTex->GetDecalScale();
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float decalWidth = pDecalTex->GetWidth();
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float decalHeight = pDecalTex->GetHeight();
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Vector textureSpaceBasis[3];
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R_DecalComputeBasis( pFace->plane.normal, NULL,
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false, textureSpaceBasis );
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float u = DotProduct(textureSpaceBasis[0], org);
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float v = DotProduct(textureSpaceBasis[1], org);
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// subtract the world space dist from the center of the
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// decal to the origin of the decal
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u -= decalWidth * decalScale / 2.0f;
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v -= decalHeight * decalScale / 2.0f;
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float scalex = 1.0f / ( decalScale * decalWidth );
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float scaley = 1.0f / ( decalScale * decalHeight );
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// Generate texture coordinates for each vertex in decal s,t space
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Vector *pVertex = pFace->Points;
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float curU, curV;
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for (int j = 0; j < pFace->nPoints; j++, pVertex++)
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{
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// Copy X, Y, & Z
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g_vert[j][0] = pVertex[0][0];
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g_vert[j][1] = pVertex[0][1];
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g_vert[j][2] = pVertex[0][2];
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// Get u, v coordinates of vertex in DECAL SPACE
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curU = DotProduct(textureSpaceBasis[0], *pVertex);
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curV = DotProduct(textureSpaceBasis[1], *pVertex);
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// Generate U & V
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g_vert[j][3] = (curU - u) * scalex; // Decal relative texture coordinates
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g_vert[j][4] = (curV - v) * scaley;
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}
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// #endif
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// Clip the polygon to the decal texture space
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// FIXME: Yes this realy copies the vertex list 4 times !!
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int nMaxVerts = min(nOutSize, MAX_CLIPVERT);
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g_outCount = SHClip( g_vert[0], pFace->nPoints, outvert[0], nMaxVerts, 0 ); // clip left
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g_outCount = SHClip( outvert[0], g_outCount, g_vert[0], nMaxVerts, 1 ); // clip right
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g_outCount = SHClip( g_vert[0], g_outCount, outvert[0], nMaxVerts, 2 ); // clip top
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g_outCount = SHClip( outvert[0], g_outCount, g_vert[0], nMaxVerts, 3 ); // clip bottom
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memcpy(pOutPoints, g_vert, sizeof(vec5_t) * g_outCount);
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return(g_outCount);
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}
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