/************************************************************** ggt-head beg * * GGT: Generic Graphics Toolkit * * Original Authors: * Allen Bierbaum * * ----------------------------------------------------------------- * File: Matrix.h,v * Date modified: 2004/11/22 15:04:05 * Version: 1.39 * ----------------------------------------------------------------- * *********************************************************** ggt-head end */ /*************************************************************** ggt-cpr beg * * GGT: The Generic Graphics Toolkit * Copyright (C) 2001,2002 Allen Bierbaum * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * ************************************************************ ggt-cpr end */ #ifndef _GMTL_MATRIX_H_ #define _GMTL_MATRIX_H_ #include #include #include #include namespace gmtl { /** * State tracked NxM dimensional Matrix (ordered in memory by Column) * * Memory mapping: * * gmtl::Matrix stores its elements in column major order. * That is, it stores each column end-to-end in memory. * * Typically, for 3D transform matrices, the 3x3 rotation is * in the first three columns, while the translation is in the last column. * * This memory alignment is chosen for compatibility with the OpenGL graphics * API and others, which take matrices in this specific column major ordering * described above. * * See the interfaces for operator[r][c] and operator(r,c) for how to iterate * over columns and rows for a GMTL Matrix. * * NOTES on Matrix memory layout and [][] accessors: *
    *
  • gmtl Matrix memory is "column major" ordered, where columns are end * to end in memory, while a C/C++ Matrix accessed the same way * (using operator[][]) as a gmtl Matrix is "row major" ordered. * *
  • As a result, a gmtl matrix stores elements in memory transposed from * the equivelent matrix defined using an array in the C/C++ * language, assuming they are accessed the same way (see example). *
      *
    • Illustrative Example:
      * Given two flavors of matrix, C/C++, and gmtl:
      * float cmat[n][m]; and gmtl::Matrix mat;
      * Writing values into each, while accessing them the same:
      * cmat[row][col] = mat[row][col] = some_values[x];
      * Then reading values from the matrix array:
      * ((float*)cmat) and mat.getData()
      * Will yield pointers to memory containing matrices that are the transpose of each other. *
    *
  • In practice, the differences between GMTL and C/C++ defined matrices * all depends how you iterate over your matrix.
    * If gmtl is accessed mat[row][col] and C/C++ is accessed mat[col][row], then * memory-wise, these two will yield the same memory mapping (column major as described above), * thus, are equivelent and can both be used interchangably in many popular graphics APIs * such as OpenGL, DirectX, and others. * *
  • In C/C++ access of a matrix via mat[row][col] yields this memory mapping after using ((float*)mat) to return it:
    * 
     *    (0,0) (0,1) (0,2) (0,3)   <=== Contiguous memory arranged by row
 *    (1,0) (1,1) (1,2) (1,3)   <=== Contiguous
 *    (2,0) (2,1) (2,2) (2,3)   <=== Contiguous
 *    (3,0) (3,1) (3,2) (3,3)   <=== Contiguous
 *
 *  or linearly if you prefer:
 *    (0,0) (0,1) (0,2) (0,3) (1,0) (1,1) (1,2) (1,3) (2,0) (2,1) (2,2) (2,3) (3,0) (3,1) (3,2) (3,3)
 *
    * *
  • In gmtl, access of a matrix via mat[row][col] yields this memory mapping after using getData() to return it:
    * 
     *    (0,0) (0,1) (0,2) (0,3)
 *    (1,0) (1,1) (1,2) (1,3)
 *    (2,0) (2,1) (2,2) (2,3)
 *    (3,0) (3,1) (3,2) (3,3)
 *      ^     ^     ^     ^
 *    --1-----2-----3-----4---- Contiguous memory arranged by column
 *
 *  or linearly if you prefer:
 *    (0,0) (1,0) (2,0) (3,0) (0,1) (1,1) (2,1) (3,1) (0,2) (1,2) (2,2) (3,2) (0,3) (1,3) (2,3) (3,3)
 *
    *
* * State Tracking: * * The idea of a state-tracked matrix is that if we track the information * as it is stored into the matrix, then other operations could make more optimal * descisions based on the known state. A good example is in matrix invertion, * a reletively costly operation for matrices. However, if we know the matrix state * is (i.e.) ORTHOGONAL, then inversion becomes a simple transpose operation. * There are also optimizations with multiplication, as well as other. * * One side effect of this state tracking is that EVERY MATRIC FUNCTION NEEDS TO * TRACK STATE. This means that anyone writing custom methods, or extentions to * gmtl, will need to pay close attention to matrix state. * * To facilitate state tracking in extensions, we've provided the function * gmtl::combineMatrixStates() to help in determining state based on two * combined matrices. * @see Matrix44f * @see Matrix44d * @ingroup Types */ template class Matrix { public: // This is a hack to work around a bug with GCC 3.3 on Mac OS X where // boost::is_polymorphic returns a false positive. The details can be // found in the Boost.Python FAQ: // http://www.boost.org/libs/python/doc/v2/faq.html#macosx #if defined(__MACH__) && defined(__APPLE_CC__) && defined(__GNUC__) && \ __GNUC__ == 3 && __GNUC_MINOR__ == 3 bool dummy_; #endif /** use this to declare single value types of the same type as this matrix. */ typedef DATA_TYPE DataType; enum Params { Rows = ROWS, Cols = COLS }; /** Helper class for Matrix op[]. * This class encapsulates the row that the user is accessing * and implements a new op[] that passes the column to use */ class RowAccessor { public: typedef DATA_TYPE DataType; RowAccessor(Matrix* mat, const unsigned row) : mMat(mat), mRow(row) { gmtlASSERT(row < ROWS); gmtlASSERT(NULL != mat); } DATA_TYPE& operator[](const unsigned column) { gmtlASSERT(column < COLS); return (*mMat)(mRow,column); } Matrix* mMat; unsigned mRow; /** The row being accessed */ }; /** Helper class for Matrix op[] const. * This class encapsulates the row that the user is accessing * and implements a new op[] that passes the column to use */ class ConstRowAccessor { public: typedef DATA_TYPE DataType; ConstRowAccessor( const Matrix* mat, const unsigned row ) : mMat( mat ), mRow( row ) { gmtlASSERT( row < ROWS ); gmtlASSERT( NULL != mat ); } const DATA_TYPE& operator[](const unsigned column) const { gmtlASSERT(column < COLS); return (*mMat)(mRow,column); } const Matrix* mMat; unsigned mRow; /** The row being accessed */ }; /** describes the xforms that this matrix has been through. */ enum XformState { // identity matrix. IDENTITY = 1, // only translation, can simply negate that column TRANS = 2, // able to tranpose to get the inverse. only rotation component is set ORTHOGONAL = 4, // orthogonal, and normalized axes. //ORTHONORMAL = 8, // leaves the homogeneous coordinate unchanged - that is, in which the last column is (0,0,0,s). // can include rotation, uniform scale, and translation, but no shearing or nonuniform scaling // This can optionally be combined with the NON_UNISCALE state to indicate there is also non-uniform scale AFFINE = 16, // AFFINE matrix with non-uniform scale, a matrix cannot // have this state without also having AFFINE (must be or'd together). NON_UNISCALE = 32, // fully set matrix containing more information than the above, or state is unknown, // or unclassifiable in terms of the above. FULL = 64, // error bit XFORM_ERROR = 128 }; /** Default Constructor (Identity constructor) */ Matrix() { /** @todo mp */ for (unsigned int r = 0; r < ROWS; ++r) { for (unsigned int c = 0; c < COLS; ++c) { this->operator()( r, c ) = (DATA_TYPE)0.0; } } /** @todo mp */ for (unsigned int x = 0; x < Math::Min( COLS, ROWS ); ++x) { this->operator()( x, x ) = (DATA_TYPE)1.0; } /** @todo Set initial state to IDENTITY and test other stuff */ mState = IDENTITY; } /** copy constructor */ Matrix( const Matrix& matrix ) { this->set( matrix.getData() ); mState = matrix.mState; } /** element wise setter for 2x2. * @note variable names specify the row,column number to put the data into * @todo needs mp!! */ void set( DATA_TYPE v00, DATA_TYPE v01, DATA_TYPE v10, DATA_TYPE v11 ) { GMTL_STATIC_ASSERT( (ROWS == 2 && COLS == 2), Set_called_when_Matrix_not_of_size_2_2 ); mData[0] = v00; mData[1] = v10; mData[2] = v01; mData[3] = v11; mState = FULL; } /** element wise setter for 2x3. * @todo needs mp!! */ void set( DATA_TYPE v00, DATA_TYPE v01, DATA_TYPE v02, DATA_TYPE v10, DATA_TYPE v11, DATA_TYPE v12 ) { GMTL_STATIC_ASSERT( (ROWS == 2 && COLS == 3), Set_called_when_Matrix_not_of_size_2_3 ); mData[0] = v00; mData[1] = v10; mData[2] = v01; mData[3] = v11; mData[4] = v02; mData[5] = v12; mState = FULL; } /** element wise setter for 3x3. * @todo needs mp!! */ void set( DATA_TYPE v00, DATA_TYPE v01, DATA_TYPE v02, DATA_TYPE v10, DATA_TYPE v11, DATA_TYPE v12, DATA_TYPE v20, DATA_TYPE v21, DATA_TYPE v22) { GMTL_STATIC_ASSERT( (ROWS == 3 && COLS == 3), Set_called_when_Matrix_not_of_size_3_3 ); mData[0] = v00; mData[1] = v10; mData[2] = v20; mData[3] = v01; mData[4] = v11; mData[5] = v21; mData[6] = v02; mData[7] = v12; mData[8] = v22; mState = FULL; } /** element wise setter for 3x4. * @todo needs mp!! currently no way for a 4x3, .... */ void set( DATA_TYPE v00, DATA_TYPE v01, DATA_TYPE v02, DATA_TYPE v03, DATA_TYPE v10, DATA_TYPE v11, DATA_TYPE v12, DATA_TYPE v13, DATA_TYPE v20, DATA_TYPE v21, DATA_TYPE v22, DATA_TYPE v23) { GMTL_STATIC_ASSERT( (ROWS == 3 && COLS == 4), Set_called_when_Matrix_not_of_size_3_4 ); mData[0] = v00; mData[1] = v10; mData[2] = v20; mData[3] = v01; mData[4] = v11; mData[5] = v21; mData[6] = v02; mData[7] = v12; mData[8] = v22; // right row mData[9] = v03; mData[10] = v13; mData[11] = v23; mState = FULL; } /** element wise setter for 4x4. * @todo needs mp!! currently no way for a 4x3, .... */ void set( DATA_TYPE v00, DATA_TYPE v01, DATA_TYPE v02, DATA_TYPE v03, DATA_TYPE v10, DATA_TYPE v11, DATA_TYPE v12, DATA_TYPE v13, DATA_TYPE v20, DATA_TYPE v21, DATA_TYPE v22, DATA_TYPE v23, DATA_TYPE v30, DATA_TYPE v31, DATA_TYPE v32, DATA_TYPE v33 ) { GMTL_STATIC_ASSERT( (ROWS == 4 && COLS == 4), Set_called_when_Matrix_not_of_size_4_4 ); mData[0] = v00; mData[1] = v10; mData[2] = v20; mData[4] = v01; mData[5] = v11; mData[6] = v21; mData[8] = v02; mData[9] = v12; mData[10] = v22; // right row mData[12] = v03; mData[13] = v13; mData[14] = v23; // bottom row mData[3] = v30; mData[7] = v31; mData[11] = v32; mData[15] = v33; mState = FULL; } /** comma operator * @todo implement this! */ //void operator,()( DATA_TYPE b ) {} /** set the matrix to the given data. * This function is useful to copy matrix data from another math library. * *

"Example (to a matrix using an external math library):"

* \code * pfMatrix other_matrix; * other_matrix.setRot( 90, 1, 0, 0 ); * * gmtl::Matrix44f mat; * mat.set( other_matrix.getFloatPtr() ); * \endcode * * WARNING: this isn't really safe, size and datatype are not enforced by * the compiler. * @pre data is in the native format of the gmtl::Matrix class, if not, * then you might be able to use the setTranspose function. * @pre i.e. in a 4x4 data[0-3] is the 1st column, data[4-7] is 2nd, etc... */ void set( const DATA_TYPE* data ) { /** @todo mp */ for (unsigned int x = 0; x < ROWS * COLS; ++x) mData[x] = data[x]; mState = FULL; } /** set the matrix to the transpose of the given data. * normally set() takes raw matrix data in column by column order, * this function allows you to pass in row by row data. * * Normally you'll use this function if you want to use a float array * to init the matrix (see code example). * *

"Example (to set a [15 -4 20] translation using float array):"

* \code * float data[] = { 1, 0, 0, 15, * 0, 1, 0, -4, * 0, 0, 1, 20, * 0, 0, 0, 1 }; * gmtl::Matrix44f mat; * mat.setTranspose( data ); * \endcode * * WARNING: this isn't really safe, size and datatype are not enforced by * the compiler. * @pre ptr is in the transpose of the native format of the Matrix class * @pre i.e. in a 4x4 data[0-3] is the 1st row, data[4-7] is 2nd, etc... */ void setTranspose( const DATA_TYPE* data ) { /** @todo metaprog */ for (unsigned int r = 0; r < ROWS; ++r) for (unsigned int c = 0; c < COLS; ++c) this->operator()( r, c ) = data[(r * COLS) + c]; mState = FULL; } /** access [row, col] in the matrix * WARNING: If you set data in the matrix (using this interface), * you are required to set mState * appropriately, failure to do so will result in incorrect * calculations by other functions in GMTL. If you are unsure * about how to set mState, set it to FULL and you will be sure * to get the correct result at the cost of some performance. */ DATA_TYPE& operator()( const unsigned row, const unsigned column ) { gmtlASSERT( (row < ROWS) && (column < COLS) ); return mData[column*ROWS + row]; } /** access [row, col] in the matrix (const version) */ const DATA_TYPE& operator()( const unsigned row, const unsigned column ) const { gmtlASSERT( (row < ROWS) && (column < COLS) ); return mData[column*ROWS + row]; } /** bracket operator * WARNING: If you set data in the matrix (using this interface), * you are required to set mState * appropriately, failure to do so will result in incorrect * calculations by other functions in GMTL. If you are unsure * about how to set mState, set it to FULL and you will be sure * to get the correct result at the cost of some performance. */ RowAccessor operator[]( const unsigned row ) { return RowAccessor(this, row); } /** bracket operator (const version) */ ConstRowAccessor operator[]( const unsigned row ) const { return ConstRowAccessor( this, row ); } /* // bracket operator const DATA_TYPE& operator[]( const unsigned i ) const { gmtlASSERT( i < (ROWS*COLS) ); return mData[i]; } */ /** Gets a DATA_TYPE pointer to the matrix data. * @return Returns a pointer to the head of the matrix data. */ const DATA_TYPE* getData() const { return (DATA_TYPE*)mData; } bool isError() { return mState & XFORM_ERROR; } void setError() { mState |= XFORM_ERROR; } void setState(int state) { mState = state; } public: /** Column major. In other words {Column1, Column2, Column3, Column4} in memory * access element mData[column][row] * WARNING: If you set data in the matrix (using this interface), * you are required to set mState appropriately, * failure to do so will result in incorrect * calculations by other functions in GMTL. If you are unsure * about how to set mState, set it to FULL and you will be sure * to get the correct result at the cost of some performance. */ DATA_TYPE mData[COLS*ROWS]; /** describes what xforms are in this matrix */ int mState; }; typedef Matrix Matrix22f; typedef Matrix Matrix22d; typedef Matrix Matrix23f; typedef Matrix Matrix23d; typedef Matrix Matrix33f; typedef Matrix Matrix33d; typedef Matrix Matrix34f; typedef Matrix Matrix34d; typedef Matrix Matrix44f; typedef Matrix Matrix44d; /** 32bit floating point 2x2 identity matrix */ const Matrix22f MAT_IDENTITY22F = Matrix22f(); /** 64bit floating point 2x2 identity matrix */ const Matrix22d MAT_IDENTITY22D = Matrix22d(); /** 32bit floating point 2x2 identity matrix */ const Matrix23f MAT_IDENTITY23F = Matrix23f(); /** 64bit floating point 2x2 identity matrix */ const Matrix23d MAT_IDENTITY23D = Matrix23d(); /** 32bit floating point 3x3 identity matrix */ const Matrix33f MAT_IDENTITY33F = Matrix33f(); /** 64bit floating point 3x3 identity matrix */ const Matrix33d MAT_IDENTITY33D = Matrix33d(); /** 32bit floating point 3x4 identity matrix */ const Matrix34f MAT_IDENTITY34F = Matrix34f(); /** 64bit floating point 3x4 identity matrix */ const Matrix34d MAT_IDENTITY34D = Matrix34d(); /** 32bit floating point 4x4 identity matrix */ const Matrix44f MAT_IDENTITY44F = Matrix44f(); /** 64bit floating point 4x4 identity matrix */ const Matrix44d MAT_IDENTITY44D = Matrix44d(); /** utility function for use by matrix operations. * given two matrices, when combined with set(..) or xform(..) types of operations, * compute what matrixstate will the resulting matrix have? */ inline int combineMatrixStates( int state1, int state2 ) { switch (state1) { case Matrix44f::IDENTITY: switch (state2) { case Matrix44f::XFORM_ERROR: return state2; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; default: return state2; } case Matrix44f::TRANS: switch (state2) { case Matrix44f::IDENTITY: return state1; case Matrix44f::ORTHOGONAL: return Matrix44f::AFFINE; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; default: return state2; } case Matrix44f::ORTHOGONAL: switch (state2) { case Matrix44f::IDENTITY: return state1; case Matrix44f::TRANS: return Matrix44f::AFFINE; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; default: return state2; } case Matrix44f::AFFINE: switch (state2) { case Matrix44f::IDENTITY: case Matrix44f::TRANS: case Matrix44f::ORTHOGONAL: return state1; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; case Matrix44f::AFFINE | Matrix44f::NON_UNISCALE: default: return state2; } case Matrix44f::AFFINE | Matrix44f::NON_UNISCALE: switch (state2) { case Matrix44f::IDENTITY: case Matrix44f::TRANS: case Matrix44f::ORTHOGONAL: case Matrix44f::AFFINE: return state1; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; default: return state2; } case Matrix44f::FULL: switch (state2) { case Matrix44f::XFORM_ERROR: return state2; case Matrix44f::NON_UNISCALE: return Matrix44f::XFORM_ERROR; default: return state1; } break; default: return Matrix44f::XFORM_ERROR; } } } // end namespace gmtl #endif