mirror of
https://github.com/nillerusr/source-engine.git
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293 lines
8.2 KiB
C++
293 lines
8.2 KiB
C++
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//========= Copyright Valve Corporation, All rights reserved. ============//
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//
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// Purpose: A little helper class that computes a spline patch
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//
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// $Workfile: $
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// $Date: $
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//
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//-----------------------------------------------------------------------------
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// $Log: $
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//
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// $NoKeywords: $
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//=============================================================================//
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#include "cbase.h"
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#include "splinepatch.h"
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#include "mathlib/vmatrix.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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//-----------------------------------------------------------------------------
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// Catmull rom blend weights
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//-----------------------------------------------------------------------------
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static VMatrix s_CatmullRom( -0.5, 1.5, -1.5, 0.5,
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1, -2.5, 2, -0.5,
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-0.5, 0, 0.5, 0,
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0, 1, 0, 0 );
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//-----------------------------------------------------------------------------
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// The last argument represents the number of float channels in addition to position
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//-----------------------------------------------------------------------------
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CSplinePatch::CSplinePatch( ) : m_ChannelCount(0),
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m_Width(0), m_Height(0), m_ppPositions(0), m_LinearFactor(1.0f)
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{
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}
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CSplinePatch::~CSplinePatch()
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{
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}
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//-----------------------------------------------------------------------------
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// Initialize the spline patch
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//-----------------------------------------------------------------------------
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void CSplinePatch::Init( int w, int h, int extraChannels )
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{
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assert( extraChannels < MAX_CHANNELS );
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m_ChannelCount = extraChannels;
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m_Width = w;
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m_Height = h;
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m_LinearFactor = 1.0f;
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}
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//-----------------------------------------------------------------------------
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// 0 = linear, 1 = spliney!
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//-----------------------------------------------------------------------------
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void CSplinePatch::SetLinearBlend( float factor )
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{
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m_LinearFactor = factor;
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}
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//-----------------------------------------------------------------------------
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// Hooks the patch up to externally controlled data...
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//-----------------------------------------------------------------------------
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void CSplinePatch::SetControlPositions( Vector const** pPositions )
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{
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m_ppPositions = pPositions;
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}
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void CSplinePatch::SetChannelData( int channel, float* pChannel )
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{
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m_pChannel[channel] = pChannel;
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}
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static inline void ComputeIndex( int i, int maxval, int* idx )
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{
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if (i == 0)
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{
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idx[0] = 0; idx[1] = 0; idx[2] = 1;
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idx[3] = (maxval > 2) ? 2 : 1;
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}
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else
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{
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idx[0] = i-1; idx[1] = i;
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if (i >= maxval - 1)
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{
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idx[2] = i; idx[3] = i;
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}
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else
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{
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idx[2] = i+1;
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if (i >= maxval - 2)
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idx[3] = i+1;
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else
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idx[3]= i+2;
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}
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}
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}
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//-----------------------------------------------------------------------------
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// Computes indices of the samples to read for this interpolation
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//-----------------------------------------------------------------------------
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void CSplinePatch::ComputeIndices( )
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{
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int s[4];
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int t[4];
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ComputeIndex( m_is, m_Width, s );
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ComputeIndex( m_it, m_Height, t );
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int base = t[0] * m_Width;
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m_SampleIndices[0][0] = base + s[0];
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m_SampleIndices[1][0] = base + s[1];
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m_SampleIndices[2][0] = base + s[2];
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m_SampleIndices[3][0] = base + s[3];
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base = t[1] * m_Width;
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m_SampleIndices[0][1] = base + s[0];
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m_SampleIndices[1][1] = base + s[1];
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m_SampleIndices[2][1] = base + s[2];
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m_SampleIndices[3][1] = base + s[3];
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base = t[2] * m_Width;
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m_SampleIndices[0][2] = base + s[0];
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m_SampleIndices[1][2] = base + s[1];
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m_SampleIndices[2][2] = base + s[2];
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m_SampleIndices[3][2] = base + s[3];
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base = t[3] * m_Width;
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m_SampleIndices[0][3] = base + s[0];
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m_SampleIndices[1][3] = base + s[1];
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m_SampleIndices[2][3] = base + s[2];
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m_SampleIndices[3][3] = base + s[3];
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}
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//-----------------------------------------------------------------------------
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// Call this before querying the patch for data at (s,t)
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//-----------------------------------------------------------------------------
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void CSplinePatch::SetupPatchQuery( float s, float t )
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{
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m_is = (int)s;
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m_it = (int)t;
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if( m_is >= m_Width )
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{
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m_is = m_Width - 1;
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m_fs = 1.0f;
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}
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else
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{
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m_fs = s - m_is;
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}
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if( m_it >= m_Height )
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{
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m_it = m_Height - 1;
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m_ft = 1.0f;
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}
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else
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{
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m_ft = t - m_it;
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}
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ComputeIndices( );
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// The patch equation is:
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// px = S * M * Gx * M^T * T^T
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// py = S * M * Gy * M^T * T^T
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// pz = S * M * Gz * M^T * T^T
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// where S = [s^3 s^2 s 1], T = [t^3 t^2 t 1]
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// M is the patch type matrix, in my case I'm using a catmull-rom
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// G is the array of control points. rows have constant t
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// We're gonna cache off S * M and M^T * T^T...
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Vector4D svec, tvec;
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float fs2 = m_fs * m_fs;
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svec[0] = fs2 * m_fs; svec[1] = fs2; svec[2] = m_fs; svec[3] = 1.0f;
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float ft2 = m_ft * m_ft;
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tvec[0] = ft2 * m_ft; tvec[1] = ft2; tvec[2] = m_ft; tvec[3] = 1.0f;
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// This sets up the catmull rom matrix based on the blend factor!!
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// we can go from linear to curvy!
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s_CatmullRom.Init( -0.5 * m_LinearFactor, 1.5 * m_LinearFactor, -1.5 * m_LinearFactor, 0.5 * m_LinearFactor,
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m_LinearFactor, -2.5 * m_LinearFactor, 2 * m_LinearFactor, -0.5 * m_LinearFactor,
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-0.5 * m_LinearFactor, -1 + m_LinearFactor, 1 - 0.5 * m_LinearFactor, 0,
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0, 1, 0, 0 );
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Vector4DMultiplyTranspose( s_CatmullRom, svec, m_SVec );
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Vector4DMultiplyTranspose( s_CatmullRom, tvec, m_TVec );
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}
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//-----------------------------------------------------------------------------
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// Gets the point and normal at (i,j) specified above
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//-----------------------------------------------------------------------------
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void CSplinePatch::GetPointAndNormal( Vector& position, Vector& normal ) const
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{
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// The patch equation is:
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// px = S * M * Gx * M^T * T^T
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// py = S * M * Gy * M^T * T^T
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// pz = S * M * Gz * M^T * T^T
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// where S = [s^3 s^2 s 1], T = [t^3 t^2 t 1]
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// M is the patch type matrix, in my case I'm using a catmull-rom
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// G is the array of control points. rows have constant t
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VMatrix controlPointsX, controlPointsY, controlPointsZ;
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for (int i = 0; i < 4; ++i)
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{
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for (int j = 0; j < 4; ++j)
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{
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int idx = m_SampleIndices[i][j];
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controlPointsX[i][j] = m_ppPositions[ idx ]->x;
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controlPointsY[i][j] = m_ppPositions[ idx ]->y;
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controlPointsZ[i][j] = m_ppPositions[ idx ]->z;
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}
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}
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Vector4D tmp;
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Vector4DMultiply( controlPointsX, m_TVec, tmp );
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position[0] = DotProduct4D( tmp, m_SVec );
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Vector4DMultiply( controlPointsY, m_TVec, tmp );
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position[1] = DotProduct4D( tmp, m_SVec );
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Vector4DMultiply( controlPointsZ, m_TVec, tmp );
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position[2] = DotProduct4D( tmp, m_SVec );
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// Normal computation
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float fs2 = m_fs * m_fs;
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float ft2 = m_ft * m_ft;
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Vector4D dsvec( 3.0f * fs2, 2.0f * m_fs, 1.0f, 0.0f );
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Vector4D dtvec( 3.0f * ft2, 2.0f * m_ft, 1.0f, 0.0f );
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Vector4DMultiplyTranspose( s_CatmullRom, dsvec, dsvec );
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Vector4DMultiplyTranspose( s_CatmullRom, dtvec, dtvec );
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Vector ds, dt;
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Vector4DMultiply( controlPointsX, m_TVec, tmp );
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ds[0] = DotProduct4D( tmp, dsvec );
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Vector4DMultiply( controlPointsY, m_TVec, tmp );
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ds[1] = DotProduct4D( tmp, dsvec );
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Vector4DMultiply( controlPointsZ, m_TVec, tmp );
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ds[2] = DotProduct4D( tmp, dsvec );
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Vector4DMultiply( controlPointsX, dtvec, tmp );
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dt[0] = DotProduct4D( tmp, m_SVec );
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Vector4DMultiply( controlPointsY, dtvec, tmp );
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dt[1] = DotProduct4D( tmp, m_SVec );
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Vector4DMultiply( controlPointsZ, dtvec, tmp );
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dt[2] = DotProduct4D( tmp, m_SVec );
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CrossProduct( ds, dt, normal );
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VectorNormalize( normal );
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}
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//-----------------------------------------------------------------------------
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// Gets at other channels
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//-----------------------------------------------------------------------------
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float CSplinePatch::GetChannel( int channel ) const
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{
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// The patch equation is:
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// px = S * M * Gx * M^T * T^T
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// py = S * M * Gy * M^T * T^T
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// pz = S * M * Gz * M^T * T^T
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// where S = [s^3 s^2 s 1], T = [t^3 t^2 t 1]
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// M is the patch type matrix, in my case I'm using a catmull-rom
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// G is the array of control points. rows have constant t
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assert( m_pChannel[channel] );
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VMatrix controlPoints;
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for (int i = 0; i < 4; ++i)
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{
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for (int j = 0; j < 4; ++j)
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{
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controlPoints[i][j] = m_pChannel[channel][ m_SampleIndices[i][j] ];
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}
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}
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Vector4D tmp;
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Vector4DMultiply( controlPoints, m_TVec, tmp );
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return DotProduct4D( tmp, m_SVec );
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}
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