source-engine/public/nmatrix.h

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
// $NoKeywords: $
//=============================================================================//

#ifndef NMATRIX_H
#define NMATRIX_H
#ifdef _WIN32
#pragma once
#endif


#include <assert.h>
#include "nvector.h"


#define NMatrixMN NMatrix<M,N>


template<int M, int N>
class NMatrix
{
public:

						NMatrixMN() {}
	
	static NMatrixMN	SetupNMatrixNull();					// Return a matrix of all zeros.
	static NMatrixMN	SetupNMatrixIdentity();				// Return an identity matrix.

	NMatrixMN const&	operator=( NMatrixMN const &other );

	NMatrixMN			operator+( NMatrixMN const &v ) const;
	NMatrixMN const&	operator+=( NMatrixMN const &v );

	NMatrixMN			operator-() const;
	NMatrixMN			operator-( NMatrixMN const &v ) const;

	// Multiplies the column vector on the right-hand side.
	NVector<M>			operator*( NVector<N> const &v ) const;

	// Can't get the compiler to work with a real MxN * NxR matrix multiply...
	NMatrix<M,M>		operator*( NMatrix<N,M> const &b ) const;

	NMatrixMN			operator*( float val ) const;
	
	bool				InverseGeneral( NMatrixMN &mInverse ) const;
	NMatrix<N,M>		Transpose() const;


public:

	float				m[M][N];
};


// Return the matrix generated by multiplying a column vector 'a' by row vector 'b'.
template<int N>
inline NMatrix<N,N> OuterProduct( NVectorN const &a, NVectorN const &b )
{
	NMatrix<N,N> ret;

	for( int i=0; i < N; i++ )
		for( int j=0; j < N; j++ )
			ret.m[i][j] = a.v[i] * b.v[j];

	return ret;
}


// -------------------------------------------------------------------------------- //
// NMatrix inlines.
// -------------------------------------------------------------------------------- //

template<int M, int N>
inline NMatrixMN NMatrixMN::SetupNMatrixNull()
{
	NMatrix ret;
	memset( ret.m, 0, sizeof(float)*M*N );
	return ret;
}


template<int M, int N>
inline NMatrixMN NMatrixMN::SetupNMatrixIdentity()
{
	assert( M == N );	// Identity matrices must be square.

	NMatrix ret;
	memset( ret.m, 0, sizeof(float)*M*N );
	for( int i=0; i < N; i++ )
		ret.m[i][i] = 1;
	return ret;
}


template<int M, int N>
inline NMatrixMN const &NMatrixMN::operator=( NMatrixMN const &v )
{
	memcpy( m, v.m, sizeof(float)*M*N );
	return *this;
}


template<int M, int N>
inline NMatrixMN NMatrixMN::operator+( NMatrixMN const &v ) const
{
	NMatrixMN ret;
	for( int i=0; i < M; i++ )
		for( int j=0; j < N; j++ )
			ret.m[i][j] = m[i][j] + v.m[i][j];

	return ret;
}


template<int M, int N>
inline NMatrixMN const &NMatrixMN::operator+=( NMatrixMN const &v )
{
	for( int i=0; i < M; i++ )
		for( int j=0; j < N; j++ )
			m[i][j] += v.m[i][j];

	return *this;
}


template<int M, int N>
inline NMatrixMN NMatrixMN::operator-() const
{
	NMatrixMN ret;
	
	for( int i=0; i < M*N; i++ )
		((float*)ret.m)[i] = -((float*)m)[i];
	
	return ret;
}


template<int M, int N>
inline NMatrixMN NMatrixMN::operator-( NMatrixMN const &v ) const
{
	NMatrixMN ret;
	for( int i=0; i < M; i++ )
		for( int j=0; j < N; j++ )
			ret.m[i][j] = m[i][j] - v.m[i][j];
	return ret;
}


template<int M, int N>
inline NVector<M> NMatrixMN::operator*( NVectorN const &v ) const
{
	NVectorN ret;

	for( int i=0; i < M; i++ )
	{
		ret.v[i] = 0;

		for( int j=0; j < N; j++ )
			ret.v[i] += m[i][j] * v.v[j];
	}
	
	return ret;
}


template<int M, int N>
inline NMatrix<M,M> NMatrixMN::operator*( NMatrix<N,M> const &b ) const
{
	NMatrix<M,M> ret;

	for( int myRow=0; myRow < M; myRow++ )
	{
		for( int otherCol=0; otherCol < M; otherCol++ )
		{
			ret[myRow][otherCol] = 0;
			for( int i=0; i < N; i++ )
				ret[myRow][otherCol] += a.m[myRow][i] * b.m[i][otherCol];
		}
	}

	return ret;
}


template<int M, int N>
inline NMatrixMN NMatrixMN::operator*( float val ) const
{
	NMatrixMN ret;

	for( int i=0; i < N*M; i++ )
		((float*)ret.m)[i] = ((float*)m)[i] * val;

	return ret;
}


template<int M, int N>
bool NMatrixMN::InverseGeneral( NMatrixMN &mInverse ) const
{
	int iRow, i, j, iTemp, iTest;
	float mul, fTest, fLargest;
	float mat[N][2*N];
	int rowMap[N], iLargest;
	float *pOut, *pRow, *pScaleRow;

	
	// Can only invert square matrices.
	if( M != N )
	{
		assert( !"Tried to invert a non-square matrix" );
		return false;
	}


	// How it's done.
	// AX = I
	// A = this
	// X = the matrix we're looking for
	// I = identity

	// Setup AI
	for(i=0; i < N; i++)
	{
		const float *pIn = m[i];
		pOut = mat[i];

		for(j=0; j < N; j++)
		{
			pOut[j] = pIn[j];
		}

		for(j=N; j < 2*N; j++)
			pOut[j] = 0;
		
		pOut[i+N] = 1.0f;

		rowMap[i] = i;
	}

	// Use row operations to get to reduced row-echelon form using these rules:
	// 1. Multiply or divide a row by a nonzero number.
	// 2. Add a multiple of one row to another.
	// 3. Interchange two rows.

	for(iRow=0; iRow < N; iRow++)
	{
		// Find the row with the largest element in this column.
		fLargest = 0.001f;
		iLargest = -1;
		for(iTest=iRow; iTest < N; iTest++)
		{
			fTest = (float)fabs(mat[rowMap[iTest]][iRow]);
			if(fTest > fLargest)
			{
				iLargest = iTest;
				fLargest = fTest;
			}
		}

		// They're all too small.. sorry.
		if(iLargest == -1)
		{
			return false;
		}

		// Swap the rows.
		iTemp = rowMap[iLargest];
		rowMap[iLargest] = rowMap[iRow];
		rowMap[iRow] = iTemp;

		pRow = mat[rowMap[iRow]];

		// Divide this row by the element.
		mul = 1.0f / pRow[iRow];
		for(j=0; j < 2*N; j++)
			pRow[j] *= mul;

		pRow[iRow] = 1.0f; // Preserve accuracy...
		
		// Eliminate this element from the other rows using operation 2.
		for(i=0; i < N; i++)
		{
			if(i == iRow)
				continue;

			pScaleRow = mat[rowMap[i]];
		
			// Multiply this row by -(iRow*the element).
			mul = -pScaleRow[iRow];
			for(j=0; j < 2*N; j++)
			{
				pScaleRow[j] += pRow[j] * mul;
			}

			pScaleRow[iRow] = 0.0f; // Preserve accuracy...
		}
	}

	// The inverse is on the right side of AX now (the identity is on the left).
	for(i=0; i < N; i++)
	{
		const float *pIn = mat[rowMap[i]] + N;
		pOut = mInverse.m[i];

		for(j=0; j < N; j++)
		{
			pOut[j] = pIn[j];
		}
	}

	return true;
}


template<int M, int N>
inline NMatrix<N,M> NMatrixMN::Transpose() const
{
	NMatrix<N,M> ret;
	
	for( int i=0; i < M; i++ )
		for( int j=0; j < N; j++ )
			ret.m[j][i] = m[i][j];
	
	return ret;
}

#endif // NMATRIX_H
1 5 years ago			`//========= Copyright Valve Corporation, All rights reserved. ============//`
			`//`
			`// Purpose:`
			`//`
			`// $NoKeywords: $`
			`//=============================================================================//`

			`#ifndef NMATRIX_H`
			`#define NMATRIX_H`
			`#ifdef _WIN32`
			`#pragma once`
			`#endif`


			`#include <assert.h>`
			`#include "nvector.h"`


			`#define NMatrixMN NMatrix<M,N>`


			`template<int M, int N>`
			`class NMatrix`
			`{`
			`public:`

			`NMatrixMN() {}`

			`static NMatrixMN SetupNMatrixNull(); // Return a matrix of all zeros.`
			`static NMatrixMN SetupNMatrixIdentity(); // Return an identity matrix.`

			`NMatrixMN const& operator=( NMatrixMN const &other );`

			`NMatrixMN operator+( NMatrixMN const &v ) const;`
			`NMatrixMN const& operator+=( NMatrixMN const &v );`

			`NMatrixMN operator-() const;`
			`NMatrixMN operator-( NMatrixMN const &v ) const;`

			`// Multiplies the column vector on the right-hand side.`
			`NVector<M> operator*( NVector<N> const &v ) const;`

			`// Can't get the compiler to work with a real MxN * NxR matrix multiply...`
			`NMatrix<M,M> operator*( NMatrix<N,M> const &b ) const;`

			`NMatrixMN operator*( float val ) const;`

			`bool InverseGeneral( NMatrixMN &mInverse ) const;`
			`NMatrix<N,M> Transpose() const;`


			`public:`

			`float m[M][N];`
			`};`



			`// Return the matrix generated by multiplying a column vector 'a' by row vector 'b'.`
			`template<int N>`
			`inline NMatrix<N,N> OuterProduct( NVectorN const &a, NVectorN const &b )`
			`{`
			`NMatrix<N,N> ret;`

			`for( int i=0; i < N; i++ )`
			`for( int j=0; j < N; j++ )`
			`ret.m[i][j] = a.v[i] * b.v[j];`

			`return ret;`
			`}`


			`// -------------------------------------------------------------------------------- //`
			`// NMatrix inlines.`
			`// -------------------------------------------------------------------------------- //`

			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::SetupNMatrixNull()`
			`{`
			`NMatrix ret;`
			`memset( ret.m, 0, sizeof(float)MN );`
			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::SetupNMatrixIdentity()`
			`{`
			`assert( M == N ); // Identity matrices must be square.`

			`NMatrix ret;`
			`memset( ret.m, 0, sizeof(float)MN );`
			`for( int i=0; i < N; i++ )`
			`ret.m[i][i] = 1;`
			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN const &NMatrixMN::operator=( NMatrixMN const &v )`
			`{`
			`memcpy( m, v.m, sizeof(float)MN );`
			`return *this;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::operator+( NMatrixMN const &v ) const`
			`{`
			`NMatrixMN ret;`
			`for( int i=0; i < M; i++ )`
			`for( int j=0; j < N; j++ )`
			`ret.m[i][j] = m[i][j] + v.m[i][j];`

			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN const &NMatrixMN::operator+=( NMatrixMN const &v )`
			`{`
			`for( int i=0; i < M; i++ )`
			`for( int j=0; j < N; j++ )`
			`m[i][j] += v.m[i][j];`

			`return *this;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::operator-() const`
			`{`
			`NMatrixMN ret;`

			`for( int i=0; i < M*N; i++ )`
			`((float)ret.m)[i] = -((float)m)[i];`

			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::operator-( NMatrixMN const &v ) const`
			`{`
			`NMatrixMN ret;`
			`for( int i=0; i < M; i++ )`
			`for( int j=0; j < N; j++ )`
			`ret.m[i][j] = m[i][j] - v.m[i][j];`
			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NVector<M> NMatrixMN::operator*( NVectorN const &v ) const`
			`{`
			`NVectorN ret;`

			`for( int i=0; i < M; i++ )`
			`{`
			`ret.v[i] = 0;`

			`for( int j=0; j < N; j++ )`
			`ret.v[i] += m[i][j] * v.v[j];`
			`}`

			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrix<M,M> NMatrixMN::operator*( NMatrix<N,M> const &b ) const`
			`{`
			`NMatrix<M,M> ret;`

			`for( int myRow=0; myRow < M; myRow++ )`
			`{`
			`for( int otherCol=0; otherCol < M; otherCol++ )`
			`{`
			`ret[myRow][otherCol] = 0;`
			`for( int i=0; i < N; i++ )`
			`ret[myRow][otherCol] += a.m[myRow][i] * b.m[i][otherCol];`
			`}`
			`}`

			`return ret;`
			`}`


			`template<int M, int N>`
			`inline NMatrixMN NMatrixMN::operator*( float val ) const`
			`{`
			`NMatrixMN ret;`

			`for( int i=0; i < N*M; i++ )`
			`((float)ret.m)[i] = ((float)m)[i] * val;`

			`return ret;`
			`}`


			`template<int M, int N>`
			`bool NMatrixMN::InverseGeneral( NMatrixMN &mInverse ) const`
			`{`
			`int iRow, i, j, iTemp, iTest;`
			`float mul, fTest, fLargest;`
			`float mat[N][2*N];`
			`int rowMap[N], iLargest;`
			`float pOut, pRow, *pScaleRow;`


			`// Can only invert square matrices.`
			`if( M != N )`
			`{`
			`assert( !"Tried to invert a non-square matrix" );`
			`return false;`
			`}`


			`// How it's done.`
			`// AX = I`
			`// A = this`
			`// X = the matrix we're looking for`
			`// I = identity`

			`// Setup AI`
			`for(i=0; i < N; i++)`
			`{`
			`const float *pIn = m[i];`
			`pOut = mat[i];`

			`for(j=0; j < N; j++)`
			`{`
			`pOut[j] = pIn[j];`
			`}`

			`for(j=N; j < 2*N; j++)`
			`pOut[j] = 0;`

			`pOut[i+N] = 1.0f;`

			`rowMap[i] = i;`
			`}`

			`// Use row operations to get to reduced row-echelon form using these rules:`
			`// 1. Multiply or divide a row by a nonzero number.`
			`// 2. Add a multiple of one row to another.`
			`// 3. Interchange two rows.`

			`for(iRow=0; iRow < N; iRow++)`
			`{`
			`// Find the row with the largest element in this column.`
			`fLargest = 0.001f;`
			`iLargest = -1;`
			`for(iTest=iRow; iTest < N; iTest++)`
			`{`
			`fTest = (float)fabs(mat[rowMap[iTest]][iRow]);`
			`if(fTest > fLargest)`
			`{`
			`iLargest = iTest;`
			`fLargest = fTest;`
			`}`
			`}`

			`// They're all too small.. sorry.`
			`if(iLargest == -1)`
			`{`
			`return false;`
			`}`

			`// Swap the rows.`
			`iTemp = rowMap[iLargest];`
			`rowMap[iLargest] = rowMap[iRow];`
			`rowMap[iRow] = iTemp;`

			`pRow = mat[rowMap[iRow]];`

			`// Divide this row by the element.`
			`mul = 1.0f / pRow[iRow];`
			`for(j=0; j < 2*N; j++)`
			`pRow[j] *= mul;`

			`pRow[iRow] = 1.0f; // Preserve accuracy...`

			`// Eliminate this element from the other rows using operation 2.`
			`for(i=0; i < N; i++)`
			`{`
			`if(i == iRow)`
			`continue;`

			`pScaleRow = mat[rowMap[i]];`

			`// Multiply this row by -(iRow*the element).`
			`mul = -pScaleRow[iRow];`
			`for(j=0; j < 2*N; j++)`
			`{`
			`pScaleRow[j] += pRow[j] * mul;`
			`}`

			`pScaleRow[iRow] = 0.0f; // Preserve accuracy...`
			`}`
			`}`

			`// The inverse is on the right side of AX now (the identity is on the left).`
			`for(i=0; i < N; i++)`
			`{`
			`const float *pIn = mat[rowMap[i]] + N;`
			`pOut = mInverse.m[i];`

			`for(j=0; j < N; j++)`
			`{`
			`pOut[j] = pIn[j];`
			`}`
			`}`

			`return true;`
			`}`


			`template<int M, int N>`
			`inline NMatrix<N,M> NMatrixMN::Transpose() const`
			`{`
			`NMatrix<N,M> ret;`

			`for( int i=0; i < M; i++ )`
			`for( int j=0; j < N; j++ )`
			`ret.m[j][i] = m[i][j];`

			`return ret;`
			`}`

			`#endif // NMATRIX_H`