G4ErrorSymMatrix Class Reference

#include <G4ErrorSymMatrix.hh>

Data Structures
class	G4ErrorSymMatrix_row
class	G4ErrorSymMatrix_row_const

Public Member Functions
G4ErrorSymMatrix	apply (G4double(*f)(G4double, G4int, G4int)) const
void	assign (const G4ErrorMatrix &m2)
void	assign (const G4ErrorSymMatrix &m2)
G4double	determinant () const
G4double &	fast (G4int row, G4int col)
const G4double &	fast (G4int row, G4int col) const
	G4ErrorSymMatrix ()
	G4ErrorSymMatrix (const G4ErrorSymMatrix &m1)
	G4ErrorSymMatrix (G4ErrorSymMatrix &&)=default
	G4ErrorSymMatrix (G4int p)
	G4ErrorSymMatrix (G4int p, G4int)
G4ErrorSymMatrix	inverse (G4int &ifail) const
void	invert (G4int &ifail)
void	invertBunchKaufman (G4int &ifail)
void	invertCholesky5 (G4int &ifail)
void	invertCholesky6 (G4int &ifail)
void	invertHaywood4 (G4int &ifail)
void	invertHaywood5 (G4int &ifail)
void	invertHaywood6 (G4int &ifail)
G4int	num_col () const
G4int	num_row () const
G4double &	operator() (G4int row, G4int col)
const G4double &	operator() (G4int row, G4int col) const
G4ErrorSymMatrix &	operator*= (G4double t)
G4ErrorSymMatrix &	operator+= (const G4ErrorSymMatrix &m2)
G4ErrorSymMatrix	operator- () const
G4ErrorSymMatrix &	operator-= (const G4ErrorSymMatrix &m2)
G4ErrorSymMatrix &	operator/= (G4double t)
G4ErrorSymMatrix &	operator= (const G4ErrorSymMatrix &m2)
G4ErrorSymMatrix &	operator= (G4ErrorSymMatrix &&)=default
G4ErrorSymMatrix_row	operator[] (G4int)
G4ErrorSymMatrix_row_const	operator[] (G4int) const
G4ErrorSymMatrix	similarity (const G4ErrorMatrix &m1) const
G4ErrorSymMatrix	similarity (const G4ErrorSymMatrix &m1) const
G4ErrorSymMatrix	similarityT (const G4ErrorMatrix &m1) const
G4ErrorSymMatrix	sub (G4int min_row, G4int max_row)
G4ErrorSymMatrix	sub (G4int min_row, G4int max_row) const
void	sub (G4int row, const G4ErrorSymMatrix &m1)
G4ErrorSymMatrix	T () const
G4double	trace () const
virtual	~G4ErrorSymMatrix ()

Protected Member Functions
G4int	num_size () const

Private Member Functions
void	invert4 (G4int &ifail)
void	invert5 (G4int &ifail)
void	invert6 (G4int &ifail)

Private Attributes
std::vector< G4double >	m
G4int	nrow
G4int	size

Static Private Attributes
static G4ThreadLocal G4double	adjustment5x5 = 0.0
static G4ThreadLocal G4double	adjustment6x6 = 0.0
static const G4double	CHOLESKY_CREEP_5x5 = .005
static const G4double	CHOLESKY_CREEP_6x6 = .002
static const G4double	CHOLESKY_THRESHOLD_5x5 = .5
static const G4double	CHOLESKY_THRESHOLD_6x6 = .2
static G4ThreadLocal G4double	posDefFraction5x5 = 1.0
static G4ThreadLocal G4double	posDefFraction6x6 = 1.0

Friends
G4double	condition (const G4ErrorSymMatrix &m)
void	diag_step (G4ErrorSymMatrix *t, G4ErrorMatrix *u, G4int begin, G4int end)
void	diag_step (G4ErrorSymMatrix *t, G4int begin, G4int end)
G4ErrorMatrix	diagonalize (G4ErrorSymMatrix *s)
class	G4ErrorMatrix
class	G4ErrorSymMatrix_row
class	G4ErrorSymMatrix_row_const
void	house_with_update2 (G4ErrorSymMatrix *a, G4ErrorMatrix *v, G4int row, G4int col)
G4ErrorMatrix	operator* (const G4ErrorMatrix &m1, const G4ErrorSymMatrix &m2)
G4ErrorMatrix	operator* (const G4ErrorSymMatrix &m1, const G4ErrorMatrix &m2)
G4ErrorMatrix	operator* (const G4ErrorSymMatrix &m1, const G4ErrorSymMatrix &m2)
G4ErrorSymMatrix	operator+ (const G4ErrorSymMatrix &m1, const G4ErrorSymMatrix &m2)
G4ErrorSymMatrix	operator- (const G4ErrorSymMatrix &m1, const G4ErrorSymMatrix &m2)
void	tridiagonal (G4ErrorSymMatrix *a, G4ErrorMatrix *hsm)

Detailed Description

Definition at line 43 of file G4ErrorSymMatrix.hh.

Constructor & Destructor Documentation

G4ErrorSymMatrix() [1/5]

G4ErrorSymMatrix::G4ErrorSymMatrix ( )

inline

G4ErrorSymMatrix() [2/5]

G4ErrorSymMatrix::G4ErrorSymMatrix ( G4int  p )

explicit

Definition at line 75 of file G4ErrorSymMatrix.cc.

  : m(p * (p + 1) / 2)
  , nrow(p)
{
  size = nrow * (nrow + 1) / 2;
  m.assign(size, 0);
}

References m, nrow, and size.

G4ErrorSymMatrix() [3/5]

G4ErrorSymMatrix::G4ErrorSymMatrix	(	G4int	p,
		G4int	init
	)

Definition at line 83 of file G4ErrorSymMatrix.cc.

  : m(p * (p + 1) / 2)
  , nrow(p)
{
  size = nrow * (nrow + 1) / 2;
 
  m.assign(size, 0);
  switch(init)
  {
    case 0:
      break;
 
    case 1:
    {
      G4ErrorMatrixIter a = m.begin();
      for(G4int i = 1; i <= nrow; i++)
      {
        *a = 1.0;
        a += (i + 1);
      }
      break;
    }
    default:
      G4ErrorMatrix::error("G4ErrorSymMatrix: initialization must be 0 or 1.");
  }
}

References G4ErrorMatrix::error(), m, nrow, and size.

G4ErrorSymMatrix() [4/5]

G4ErrorSymMatrix::G4ErrorSymMatrix

(

const G4ErrorSymMatrix &

m1

)

Definition at line 116 of file G4ErrorSymMatrix.cc.

  : m(mat1.size)
  , nrow(mat1.nrow)
  , size(mat1.size)
{
  m = mat1.m;
}

References m.

G4ErrorSymMatrix() [5/5]

G4ErrorSymMatrix::G4ErrorSymMatrix ( G4ErrorSymMatrix &&  )

default

~G4ErrorSymMatrix()

G4ErrorSymMatrix::~G4ErrorSymMatrix ( )

virtual

Definition at line 114 of file G4ErrorSymMatrix.cc.

{}

Member Function Documentation

apply()

G4ErrorSymMatrix G4ErrorSymMatrix::apply

(

G4double(*)(G4double, G4int, G4int)

f

)

const

Definition at line 592 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(num_row());
  G4ErrorMatrixConstIter a = m.begin();
  G4ErrorMatrixIter b      = mret.m.begin();
  for(G4int ir = 1; ir <= num_row(); ir++)
  {
    for(G4int ic = 1; ic <= ir; ic++)
    {
      *(b++) = (*f)(*(a++), ir, ic);
    }
  }
  return mret;
}

References m, and num_row().

assign() [1/2]

void G4ErrorSymMatrix::assign

(

const G4ErrorMatrix &

m2

)

Definition at line 608 of file G4ErrorSymMatrix.cc.

{
  if(mat1.nrow != nrow)
  {
    nrow = mat1.nrow;
    size = nrow * (nrow + 1) / 2;
    m.resize(size);
  }
  G4ErrorMatrixConstIter a = mat1.m.begin();
  G4ErrorMatrixIter b      = m.begin();
  for(G4int r = 1; r <= nrow; r++)
  {
    G4ErrorMatrixConstIter d = a;
    for(G4int c = 1; c <= r; c++)
    {
      *(b++) = *(d++);
    }
    a += nrow;
  }
}

References G4ErrorMatrix::m, m, G4ErrorMatrix::nrow, nrow, and size.

assign() [2/2]

void G4ErrorSymMatrix::assign

(

const G4ErrorSymMatrix &

m2

)

determinant()

G4double G4ErrorSymMatrix::determinant

(

)

const

Definition at line 841 of file G4ErrorSymMatrix.cc.

{
  static const G4int max_array = 20;
 
  // ir must point to an array which is ***1 longer than*** nrow
 
  static std::vector<G4int> ir_vec(max_array + 1);
  if(ir_vec.size() <= static_cast<unsigned int>(nrow))
  {
    ir_vec.resize(nrow + 1);
  }
  G4int* ir = &ir_vec[0];
 
  G4double det;
  G4ErrorMatrix mt(*this);
  G4int i = mt.dfact_matrix(det, ir);
  if(i == 0)
  {
    return det;
  }
  return 0.0;
}

References G4ErrorMatrix::dfact_matrix(), and nrow.

fast() [1/2]

G4double & G4ErrorSymMatrix::fast	(	G4int	row,
		G4int	col
	)

fast() [2/2]

const G4double & G4ErrorSymMatrix::fast	(	G4int	row,
		G4int	col
	)		const

inverse()

G4ErrorSymMatrix G4ErrorSymMatrix::inverse ( G4int &  ifail ) const

inline

invert()

void G4ErrorSymMatrix::invert

(

G4int &

ifail

)

Definition at line 724 of file G4ErrorSymMatrix.cc.

{
  ifail = 0;
 
  switch(nrow)
  {
    case 3:
    {
      G4double det, temp;
      G4double t1, t2, t3;
      G4double c11, c12, c13, c22, c23, c33;
      c11 = (*(m.begin() + 2)) * (*(m.begin() + 5)) -
            (*(m.begin() + 4)) * (*(m.begin() + 4));
      c12 = (*(m.begin() + 4)) * (*(m.begin() + 3)) -
            (*(m.begin() + 1)) * (*(m.begin() + 5));
      c13 = (*(m.begin() + 1)) * (*(m.begin() + 4)) -
            (*(m.begin() + 2)) * (*(m.begin() + 3));
      c22 = (*(m.begin() + 5)) * (*m.begin()) -
            (*(m.begin() + 3)) * (*(m.begin() + 3));
      c23 = (*(m.begin() + 3)) * (*(m.begin() + 1)) -
            (*(m.begin() + 4)) * (*m.begin());
      c33 = (*m.begin()) * (*(m.begin() + 2)) -
            (*(m.begin() + 1)) * (*(m.begin() + 1));
      t1 = std::fabs(*m.begin());
      t2 = std::fabs(*(m.begin() + 1));
      t3 = std::fabs(*(m.begin() + 3));
      if(t1 >= t2)
      {
        if(t3 >= t1)
        {
          temp = *(m.begin() + 3);
          det  = c23 * c12 - c22 * c13;
        }
        else
        {
          temp = *m.begin();
          det  = c22 * c33 - c23 * c23;
        }
      }
      else if(t3 >= t2)
      {
        temp = *(m.begin() + 3);
        det  = c23 * c12 - c22 * c13;
      }
      else
      {
        temp = *(m.begin() + 1);
        det  = c13 * c23 - c12 * c33;
      }
      if(det == 0)
      {
        ifail = 1;
        return;
      }
      {
        G4double ss          = temp / det;
        G4ErrorMatrixIter mq = m.begin();
        *(mq++)              = ss * c11;
        *(mq++)              = ss * c12;
        *(mq++)              = ss * c22;
        *(mq++)              = ss * c13;
        *(mq++)              = ss * c23;
        *(mq)                = ss * c33;
      }
    }
    break;
    case 2:
    {
      G4double det, temp, ss;
      det = (*m.begin()) * (*(m.begin() + 2)) -
            (*(m.begin() + 1)) * (*(m.begin() + 1));
      if(det == 0)
      {
        ifail = 1;
        return;
      }
      ss = 1.0 / det;
      *(m.begin() + 1) *= -ss;
      temp             = ss * (*(m.begin() + 2));
      *(m.begin() + 2) = ss * (*m.begin());
      *m.begin()       = temp;
      break;
    }
    case 1:
    {
      if((*m.begin()) == 0)
      {
        ifail = 1;
        return;
      }
      *m.begin() = 1.0 / (*m.begin());
      break;
    }
    case 5:
    {
      invert5(ifail);
      return;
    }
    case 6:
    {
      invert6(ifail);
      return;
    }
    case 4:
    {
      invert4(ifail);
      return;
    }
    default:
    {
      invertBunchKaufman(ifail);
      return;
    }
  }
  return;  // inversion successful
}

References invert4(), invert5(), invert6(), invertBunchKaufman(), m, and nrow.

invert4()

void G4ErrorSymMatrix::invert4 ( G4int &  ifail )

private

Definition at line 2328 of file G4ErrorSymMatrix.cc.

{
  ifail = 0;
 
  // Find all NECESSARY 2x2 dets:  (14 of them)
 
  G4double Det2_12_01 = m[A10] * m[A21] - m[A11] * m[A20];
  G4double Det2_12_02 = m[A10] * m[A22] - m[A12] * m[A20];
  G4double Det2_12_12 = m[A11] * m[A22] - m[A12] * m[A21];
  G4double Det2_13_01 = m[A10] * m[A31] - m[A11] * m[A30];
  G4double Det2_13_02 = m[A10] * m[A32] - m[A12] * m[A30];
  G4double Det2_13_03 = m[A10] * m[A33] - m[A13] * m[A30];
  G4double Det2_13_12 = m[A11] * m[A32] - m[A12] * m[A31];
  G4double Det2_13_13 = m[A11] * m[A33] - m[A13] * m[A31];
  G4double Det2_23_01 = m[A20] * m[A31] - m[A21] * m[A30];
  G4double Det2_23_02 = m[A20] * m[A32] - m[A22] * m[A30];
  G4double Det2_23_03 = m[A20] * m[A33] - m[A23] * m[A30];
  G4double Det2_23_12 = m[A21] * m[A32] - m[A22] * m[A31];
  G4double Det2_23_13 = m[A21] * m[A33] - m[A23] * m[A31];
  G4double Det2_23_23 = m[A22] * m[A33] - m[A23] * m[A32];
 
  // Find all NECESSARY 3x3 dets:   (10 of them)
 
  G4double Det3_012_012 =
    m[A00] * Det2_12_12 - m[A01] * Det2_12_02 + m[A02] * Det2_12_01;
  G4double Det3_013_012 =
    m[A00] * Det2_13_12 - m[A01] * Det2_13_02 + m[A02] * Det2_13_01;
  G4double Det3_013_013 =
    m[A00] * Det2_13_13 - m[A01] * Det2_13_03 + m[A03] * Det2_13_01;
  G4double Det3_023_012 =
    m[A00] * Det2_23_12 - m[A01] * Det2_23_02 + m[A02] * Det2_23_01;
  G4double Det3_023_013 =
    m[A00] * Det2_23_13 - m[A01] * Det2_23_03 + m[A03] * Det2_23_01;
  G4double Det3_023_023 =
    m[A00] * Det2_23_23 - m[A02] * Det2_23_03 + m[A03] * Det2_23_02;
  G4double Det3_123_012 =
    m[A10] * Det2_23_12 - m[A11] * Det2_23_02 + m[A12] * Det2_23_01;
  G4double Det3_123_013 =
    m[A10] * Det2_23_13 - m[A11] * Det2_23_03 + m[A13] * Det2_23_01;
  G4double Det3_123_023 =
    m[A10] * Det2_23_23 - m[A12] * Det2_23_03 + m[A13] * Det2_23_02;
  G4double Det3_123_123 =
    m[A11] * Det2_23_23 - m[A12] * Det2_23_13 + m[A13] * Det2_23_12;
 
  // Find the 4x4 det:
 
  G4double det = m[A00] * Det3_123_123 - m[A01] * Det3_123_023 +
                 m[A02] * Det3_123_013 - m[A03] * Det3_123_012;
 
  if(det == 0)
  {
    ifail = 1;
    return;
  }
 
  G4double oneOverDet = 1.0 / det;
  G4double mn1OverDet = -oneOverDet;
 
  m[A00] = Det3_123_123 * oneOverDet;
  m[A01] = Det3_123_023 * mn1OverDet;
  m[A02] = Det3_123_013 * oneOverDet;
  m[A03] = Det3_123_012 * mn1OverDet;
 
  m[A11] = Det3_023_023 * oneOverDet;
  m[A12] = Det3_023_013 * mn1OverDet;
  m[A13] = Det3_023_012 * oneOverDet;
 
  m[A22] = Det3_013_013 * oneOverDet;
  m[A23] = Det3_013_012 * mn1OverDet;
 
  m[A33] = Det3_012_012 * oneOverDet;
 
  return;
}

References A00, A01, A02, A03, A10, A11, A12, A13, A20, A21, A22, A23, A30, A31, A32, A33, and m.

Referenced by invert(), and invertHaywood4().

invert5()

void G4ErrorSymMatrix::invert5 ( G4int &  ifail )

private

Definition at line 1390 of file G4ErrorSymMatrix.cc.

{
  if(posDefFraction5x5 >= CHOLESKY_THRESHOLD_5x5)
  {
    invertCholesky5(ifail);
    posDefFraction5x5 = .9 * posDefFraction5x5 + .1 * (1 - ifail);
    if(ifail != 0)  // Cholesky failed -- invert using Haywood
    {
      invertHaywood5(ifail);
    }
  }
  else
  {
    if(posDefFraction5x5 + adjustment5x5 >= CHOLESKY_THRESHOLD_5x5)
    {
      invertCholesky5(ifail);
      posDefFraction5x5 = .9 * posDefFraction5x5 + .1 * (1 - ifail);
      if(ifail != 0)  // Cholesky failed -- invert using Haywood
      {
        invertHaywood5(ifail);
        adjustment5x5 = 0;
      }
    }
    else
    {
      invertHaywood5(ifail);
      adjustment5x5 += CHOLESKY_CREEP_5x5;
    }
  }
  return;
}

References adjustment5x5, CHOLESKY_CREEP_5x5, CHOLESKY_THRESHOLD_5x5, invertCholesky5(), invertHaywood5(), and posDefFraction5x5.

Referenced by invert().

invert6()

void G4ErrorSymMatrix::invert6 ( G4int &  ifail )

private

Definition at line 1422 of file G4ErrorSymMatrix.cc.

{
  if(posDefFraction6x6 >= CHOLESKY_THRESHOLD_6x6)
  {
    invertCholesky6(ifail);
    posDefFraction6x6 = .9 * posDefFraction6x6 + .1 * (1 - ifail);
    if(ifail != 0)  // Cholesky failed -- invert using Haywood
    {
      invertHaywood6(ifail);
    }
  }
  else
  {
    if(posDefFraction6x6 + adjustment6x6 >= CHOLESKY_THRESHOLD_6x6)
    {
      invertCholesky6(ifail);
      posDefFraction6x6 = .9 * posDefFraction6x6 + .1 * (1 - ifail);
      if(ifail != 0)  // Cholesky failed -- invert using Haywood
      {
        invertHaywood6(ifail);
        adjustment6x6 = 0;
      }
    }
    else
    {
      invertHaywood6(ifail);
      adjustment6x6 += CHOLESKY_CREEP_6x6;
    }
  }
  return;
}

References adjustment6x6, CHOLESKY_CREEP_6x6, CHOLESKY_THRESHOLD_6x6, invertCholesky6(), invertHaywood6(), and posDefFraction6x6.

Referenced by invert().

invertBunchKaufman()

void G4ErrorSymMatrix::invertBunchKaufman

(

G4int &

ifail

)

Definition at line 874 of file G4ErrorSymMatrix.cc.

{
  // Bunch-Kaufman diagonal pivoting method
  // It is decribed in J.R. Bunch, L. Kaufman (1977).
  // "Some Stable Methods for Calculating Inertia and Solving Symmetric
  // Linear Systems", Math. Comp. 31, p. 162-179. or in Gene H. Golub,
  // Charles F. van Loan, "Matrix Computations" (the second edition
  // has a bug.) and implemented in "lapack"
  // Mario Stanke, 09/97
 
  G4int i, j, k, ss;
  G4int pivrow;
 
  // Establish the two working-space arrays needed:  x and piv are
  // used as pointers to arrays of doubles and ints respectively, each
  // of length nrow.  We do not want to reallocate each time through
  // unless the size needs to grow.  We do not want to leak memory, even
  // by having a new without a delete that is only done once.
 
  static const G4int max_array                     = 25;
  static G4ThreadLocal std::vector<G4double>* xvec = 0;
  if(!xvec)
    xvec = new std::vector<G4double>(max_array);
  static G4ThreadLocal std::vector<G4int>* pivv = 0;
  if(!pivv)
    pivv = new std::vector<G4int>(max_array);
  typedef std::vector<G4int>::iterator pivIter;
  if(xvec->size() < static_cast<unsigned int>(nrow))
    xvec->resize(nrow);
  if(pivv->size() < static_cast<unsigned int>(nrow))
    pivv->resize(nrow);
  // Note - resize should do  nothing if the size is already larger than nrow,
  //        but on VC++ there are indications that it does so we check.
  // Note - the data elements in a vector are guaranteed to be contiguous,
  //        so x[i] and piv[i] are optimally fast.
  G4ErrorMatrixIter x = xvec->begin();
  // x[i] is used as helper storage, needs to have at least size nrow.
  pivIter piv = pivv->begin();
  // piv[i] is used to store details of exchanges
 
  G4double temp1, temp2;
  G4ErrorMatrixIter ip, mjj, iq;
  G4double lambda, sigma;
  const G4double alpha   = .6404;  // = (1+sqrt(17))/8
  const G4double epsilon = 32 * DBL_EPSILON;
  // whenever a sum of two doubles is below or equal to epsilon
  // it is set to zero.
  // this constant could be set to zero but then the algorithm
  // doesn't neccessarily detect that a matrix is singular
 
  for(i = 0; i < nrow; i++)
  {
    piv[i] = i + 1;
  }
 
  ifail = 0;
 
  // compute the factorization P*A*P^T = L * D * L^T
  // L is unit lower triangular, D is direct sum of 1x1 and 2x2 matrices
  // L and D^-1 are stored in A = *this, P is stored in piv[]
 
  for(j = 1; j < nrow; j += ss)  // main loop over columns
  {
    mjj    = m.begin() + j * (j - 1) / 2 + j - 1;
    lambda = 0;  // compute lambda = max of A(j+1:n,j)
    pivrow = j + 1;
    ip     = m.begin() + (j + 1) * j / 2 + j - 1;
    for(i = j + 1; i <= nrow; ip += i++)
    {
      if(std::fabs(*ip) > lambda)
      {
        lambda = std::fabs(*ip);
        pivrow = i;
      }
    }
    if(lambda == 0)
    {
      if(*mjj == 0)
      {
        ifail = 1;
        return;
      }
      ss   = 1;
      *mjj = 1. / *mjj;
    }
    else
    {
      if(std::fabs(*mjj) >= lambda * alpha)
      {
        ss     = 1;
        pivrow = j;
      }
      else
      {
        sigma = 0;  // compute sigma = max A(pivrow, j:pivrow-1)
        ip    = m.begin() + pivrow * (pivrow - 1) / 2 + j - 1;
        for(k = j; k < pivrow; k++)
        {
          if(std::fabs(*ip) > sigma)
            sigma = std::fabs(*ip);
          ip++;
        }
        if(sigma * std::fabs(*mjj) >= alpha * lambda * lambda)
        {
          ss     = 1;
          pivrow = j;
        }
        else if(std::fabs(*(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow -
                            1)) >= alpha * sigma)
        {
          ss = 1;
        }
        else
        {
          ss = 2;
        }
      }
      if(pivrow == j)  // no permutation neccessary
      {
        piv[j - 1] = pivrow;
        if(*mjj == 0)
        {
          ifail = 1;
          return;
        }
        temp2 = *mjj = 1. / *mjj;  // invert D(j,j)
 
        // update A(j+1:n, j+1,n)
        for(i = j + 1; i <= nrow; i++)
        {
          temp1 = *(m.begin() + i * (i - 1) / 2 + j - 1) * temp2;
          ip    = m.begin() + i * (i - 1) / 2 + j;
          for(k = j + 1; k <= i; k++)
          {
            *ip -= temp1 * *(m.begin() + k * (k - 1) / 2 + j - 1);
            if(std::fabs(*ip) <= epsilon)
            {
              *ip = 0;
            }
            ip++;
          }
        }
        // update L
        ip = m.begin() + (j + 1) * j / 2 + j - 1;
        for(i = j + 1; i <= nrow; ip += i++)
        {
          *ip *= temp2;
        }
      }
      else if(ss == 1)  // 1x1 pivot
      {
        piv[j - 1] = pivrow;
 
        // interchange rows and columns j and pivrow in
        // submatrix (j:n,j:n)
        ip = m.begin() + pivrow * (pivrow - 1) / 2 + j;
        for(i = j + 1; i < pivrow; i++, ip++)
        {
          temp1 = *(m.begin() + i * (i - 1) / 2 + j - 1);
          *(m.begin() + i * (i - 1) / 2 + j - 1) = *ip;
          *ip                                    = temp1;
        }
        temp1 = *mjj;
        *mjj  = *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1);
        *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1) = temp1;
        ip = m.begin() + (pivrow + 1) * pivrow / 2 + j - 1;
        iq = ip + pivrow - j;
        for(i = pivrow + 1; i <= nrow; ip += i, iq += i++)
        {
          temp1 = *iq;
          *iq   = *ip;
          *ip   = temp1;
        }
 
        if(*mjj == 0)
        {
          ifail = 1;
          return;
        }
        temp2 = *mjj = 1. / *mjj;  // invert D(j,j)
 
        // update A(j+1:n, j+1:n)
        for(i = j + 1; i <= nrow; i++)
        {
          temp1 = *(m.begin() + i * (i - 1) / 2 + j - 1) * temp2;
          ip    = m.begin() + i * (i - 1) / 2 + j;
          for(k = j + 1; k <= i; k++)
          {
            *ip -= temp1 * *(m.begin() + k * (k - 1) / 2 + j - 1);
            if(std::fabs(*ip) <= epsilon)
            {
              *ip = 0;
            }
            ip++;
          }
        }
        // update L
        ip = m.begin() + (j + 1) * j / 2 + j - 1;
        for(i = j + 1; i <= nrow; ip += i++)
        {
          *ip *= temp2;
        }
      }
      else  // ss=2, ie use a 2x2 pivot
      {
        piv[j - 1] = -pivrow;
        piv[j]     = 0;  // that means this is the second row of a 2x2 pivot
 
        if(j + 1 != pivrow)
        {
          // interchange rows and columns j+1 and pivrow in
          // submatrix (j:n,j:n)
          ip = m.begin() + pivrow * (pivrow - 1) / 2 + j + 1;
          for(i = j + 2; i < pivrow; i++, ip++)
          {
            temp1 = *(m.begin() + i * (i - 1) / 2 + j);
            *(m.begin() + i * (i - 1) / 2 + j) = *ip;
            *ip                                = temp1;
          }
          temp1 = *(mjj + j + 1);
          *(mjj + j + 1) =
            *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1);
          *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1) = temp1;
          temp1                                                 = *(mjj + j);
          *(mjj + j) = *(m.begin() + pivrow * (pivrow - 1) / 2 + j - 1);
          *(m.begin() + pivrow * (pivrow - 1) / 2 + j - 1) = temp1;
          ip = m.begin() + (pivrow + 1) * pivrow / 2 + j;
          iq = ip + pivrow - (j + 1);
          for(i = pivrow + 1; i <= nrow; ip += i, iq += i++)
          {
            temp1 = *iq;
            *iq   = *ip;
            *ip   = temp1;
          }
        }
        // invert D(j:j+1,j:j+1)
        temp2 = *mjj * *(mjj + j + 1) - *(mjj + j) * *(mjj + j);
        if(temp2 == 0)
        {
          G4Exception("G4ErrorSymMatrix::bunch_invert()",
                      "GEANT4e-Notification", JustWarning,
                      "Error in pivot choice!");
        }
        temp2 = 1. / temp2;
 
        // this quotient is guaranteed to exist by the choice
        // of the pivot
 
        temp1          = *mjj;
        *mjj           = *(mjj + j + 1) * temp2;
        *(mjj + j + 1) = temp1 * temp2;
        *(mjj + j)     = -*(mjj + j) * temp2;
 
        if(j < nrow - 1)  // otherwise do nothing
        {
          // update A(j+2:n, j+2:n)
          for(i = j + 2; i <= nrow; i++)
          {
            ip    = m.begin() + i * (i - 1) / 2 + j - 1;
            temp1 = *ip * *mjj + *(ip + 1) * *(mjj + j);
            if(std::fabs(temp1) <= epsilon)
            {
              temp1 = 0;
            }
            temp2 = *ip * *(mjj + j) + *(ip + 1) * *(mjj + j + 1);
            if(std::fabs(temp2) <= epsilon)
            {
              temp2 = 0;
            }
            for(k = j + 2; k <= i; k++)
            {
              ip = m.begin() + i * (i - 1) / 2 + k - 1;
              iq = m.begin() + k * (k - 1) / 2 + j - 1;
              *ip -= temp1 * *iq + temp2 * *(iq + 1);
              if(std::fabs(*ip) <= epsilon)
              {
                *ip = 0;
              }
            }
          }
          // update L
          for(i = j + 2; i <= nrow; i++)
          {
            ip    = m.begin() + i * (i - 1) / 2 + j - 1;
            temp1 = *ip * *mjj + *(ip + 1) * *(mjj + j);
            if(std::fabs(temp1) <= epsilon)
            {
              temp1 = 0;
            }
            *(ip + 1) = *ip * *(mjj + j) + *(ip + 1) * *(mjj + j + 1);
            if(std::fabs(*(ip + 1)) <= epsilon)
            {
              *(ip + 1) = 0;
            }
            *ip = temp1;
          }
        }
      }
    }
  }  // end of main loop over columns
 
  if(j == nrow)  // the the last pivot is 1x1
  {
    mjj = m.begin() + j * (j - 1) / 2 + j - 1;
    if(*mjj == 0)
    {
      ifail = 1;
      return;
    }
    else
    {
      *mjj = 1. / *mjj;
    }
  }  // end of last pivot code
 
  // computing the inverse from the factorization
 
  for(j = nrow; j >= 1; j -= ss)  // loop over columns
  {
    mjj = m.begin() + j * (j - 1) / 2 + j - 1;
    if(piv[j - 1] > 0)  // 1x1 pivot, compute column j of inverse
    {
      ss = 1;
      if(j < nrow)
      {
        ip = m.begin() + (j + 1) * j / 2 + j - 1;
        for(i = 0; i < nrow - j; ip += 1 + j + i++)
        {
          x[i] = *ip;
        }
        for(i = j + 1; i <= nrow; i++)
        {
          temp2 = 0;
          ip    = m.begin() + i * (i - 1) / 2 + j;
          for(k = 0; k <= i - j - 1; k++)
          {
            temp2 += *ip++ * x[k];
          }
          for(ip += i - 1; k < nrow - j; ip += 1 + j + k++)
          {
            temp2 += *ip * x[k];
          }
          *(m.begin() + i * (i - 1) / 2 + j - 1) = -temp2;
        }
        temp2 = 0;
        ip    = m.begin() + (j + 1) * j / 2 + j - 1;
        for(k = 0; k < nrow - j; ip += 1 + j + k++)
        {
          temp2 += x[k] * *ip;
        }
        *mjj -= temp2;
      }
    }
    else  // 2x2 pivot, compute columns j and j-1 of the inverse
    {
      if(piv[j - 1] != 0)
      {
        std::ostringstream message;
        message << "Error in pivot: " << piv[j - 1];
        G4Exception("G4ErrorSymMatrix::invertBunchKaufman()",
                    "GEANT4e-Notification", JustWarning, message);
      }
      ss = 2;
      if(j < nrow)
      {
        ip = m.begin() + (j + 1) * j / 2 + j - 1;
        for(i = 0; i < nrow - j; ip += 1 + j + i++)
        {
          x[i] = *ip;
        }
        for(i = j + 1; i <= nrow; i++)
        {
          temp2 = 0;
          ip    = m.begin() + i * (i - 1) / 2 + j;
          for(k = 0; k <= i - j - 1; k++)
          {
            temp2 += *ip++ * x[k];
          }
          for(ip += i - 1; k < nrow - j; ip += 1 + j + k++)
          {
            temp2 += *ip * x[k];
          }
          *(m.begin() + i * (i - 1) / 2 + j - 1) = -temp2;
        }
        temp2 = 0;
        ip    = m.begin() + (j + 1) * j / 2 + j - 1;
        for(k = 0; k < nrow - j; ip += 1 + j + k++)
        {
          temp2 += x[k] * *ip;
        }
        *mjj -= temp2;
        temp2 = 0;
        ip    = m.begin() + (j + 1) * j / 2 + j - 2;
        for(i = j + 1; i <= nrow; ip += i++)
        {
          temp2 += *ip * *(ip + 1);
        }
        *(mjj - 1) -= temp2;
        ip = m.begin() + (j + 1) * j / 2 + j - 2;
        for(i = 0; i < nrow - j; ip += 1 + j + i++)
        {
          x[i] = *ip;
        }
        for(i = j + 1; i <= nrow; i++)
        {
          temp2 = 0;
          ip    = m.begin() + i * (i - 1) / 2 + j;
          for(k = 0; k <= i - j - 1; k++)
          {
            temp2 += *ip++ * x[k];
          }
          for(ip += i - 1; k < nrow - j; ip += 1 + j + k++)
          {
            temp2 += *ip * x[k];
          }
          *(m.begin() + i * (i - 1) / 2 + j - 2) = -temp2;
        }
        temp2 = 0;
        ip    = m.begin() + (j + 1) * j / 2 + j - 2;
        for(k = 0; k < nrow - j; ip += 1 + j + k++)
        {
          temp2 += x[k] * *ip;
        }
        *(mjj - j) -= temp2;
      }
    }
 
    // interchange rows and columns j and piv[j-1]
    // or rows and columns j and -piv[j-2]
 
    pivrow = (piv[j - 1] == 0) ? -piv[j - 2] : piv[j - 1];
    ip     = m.begin() + pivrow * (pivrow - 1) / 2 + j;
    for(i = j + 1; i < pivrow; i++, ip++)
    {
      temp1 = *(m.begin() + i * (i - 1) / 2 + j - 1);
      *(m.begin() + i * (i - 1) / 2 + j - 1) = *ip;
      *ip                                    = temp1;
    }
    temp1 = *mjj;
    *mjj  = *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1);
    *(m.begin() + pivrow * (pivrow - 1) / 2 + pivrow - 1) = temp1;
    if(ss == 2)
    {
      temp1      = *(mjj - 1);
      *(mjj - 1) = *(m.begin() + pivrow * (pivrow - 1) / 2 + j - 2);
      *(m.begin() + pivrow * (pivrow - 1) / 2 + j - 2) = temp1;
    }
 
    ip = m.begin() + (pivrow + 1) * pivrow / 2 + j - 1;  // &A(i,j)
    iq = ip + pivrow - j;
    for(i = pivrow + 1; i <= nrow; ip += i, iq += i++)
    {
      temp1 = *iq;
      *iq   = *ip;
      *ip   = temp1;
    }
  }  // end of loop over columns (in computing inverse from factorization)
 
  return;  // inversion successful
}

References alpha, DBL_EPSILON, epsilon(), G4Exception(), G4ThreadLocal, JustWarning, G4InuclParticleNames::lambda, m, and nrow.

Referenced by invert().

invertCholesky5()

void G4ErrorSymMatrix::invertCholesky5

(

G4int &

ifail

)

Definition at line 2023 of file G4ErrorSymMatrix.cc.

{
  // Invert by
  //
  // a) decomposing M = G*G^T with G lower triangular
  //    (if M is not positive definite this will fail, leaving this unchanged)
  // b) inverting G to form H
  // c) multiplying H^T * H to get M^-1.
  //
  // If the matrix is pos. def. it is inverted and 1 is returned.
  // If the matrix is not pos. def. it remains unaltered and 0 is returned.
 
  G4double h10;  // below-diagonal elements of H
  G4double h20, h21;
  G4double h30, h31, h32;
  G4double h40, h41, h42, h43;
 
  G4double h00, h11, h22, h33, h44;  // 1/diagonal elements of G =
                                     // diagonal elements of H
 
  G4double g10;  // below-diagonal elements of G
  G4double g20, g21;
  G4double g30, g31, g32;
  G4double g40, g41, g42, g43;
 
  ifail = 1;  // We start by assuing we won't succeed...
 
  // Form G -- compute diagonal members of H directly rather than of G
  //-------
 
  // Scale first column by 1/sqrt(A00)
 
  h00 = m[A00];
  if(h00 <= 0)
  {
    return;
  }
  h00 = 1.0 / std::sqrt(h00);
 
  g10 = m[A10] * h00;
  g20 = m[A20] * h00;
  g30 = m[A30] * h00;
  g40 = m[A40] * h00;
 
  // Form G11 (actually, just h11)
 
  h11 = m[A11] - (g10 * g10);
  if(h11 <= 0)
  {
    return;
  }
  h11 = 1.0 / std::sqrt(h11);
 
  // Subtract inter-column column dot products from rest of column 1 and
  // scale to get column 1 of G
 
  g21 = (m[A21] - (g10 * g20)) * h11;
  g31 = (m[A31] - (g10 * g30)) * h11;
  g41 = (m[A41] - (g10 * g40)) * h11;
 
  // Form G22 (actually, just h22)
 
  h22 = m[A22] - (g20 * g20) - (g21 * g21);
  if(h22 <= 0)
  {
    return;
  }
  h22 = 1.0 / std::sqrt(h22);
 
  // Subtract inter-column column dot products from rest of column 2 and
  // scale to get column 2 of G
 
  g32 = (m[A32] - (g20 * g30) - (g21 * g31)) * h22;
  g42 = (m[A42] - (g20 * g40) - (g21 * g41)) * h22;
 
  // Form G33 (actually, just h33)
 
  h33 = m[A33] - (g30 * g30) - (g31 * g31) - (g32 * g32);
  if(h33 <= 0)
  {
    return;
  }
  h33 = 1.0 / std::sqrt(h33);
 
  // Subtract inter-column column dot product from A43 and scale to get G43
 
  g43 = (m[A43] - (g30 * g40) - (g31 * g41) - (g32 * g42)) * h33;
 
  // Finally form h44 - if this is possible inversion succeeds
 
  h44 = m[A44] - (g40 * g40) - (g41 * g41) - (g42 * g42) - (g43 * g43);
  if(h44 <= 0)
  {
    return;
  }
  h44 = 1.0 / std::sqrt(h44);
 
  // Form H = 1/G -- diagonal members of H are already correct
  //-------------
 
  // The order here is dictated by speed considerations
 
  h43 = -h33 * g43 * h44;
  h32 = -h22 * g32 * h33;
  h42 = -h22 * (g32 * h43 + g42 * h44);
  h21 = -h11 * g21 * h22;
  h31 = -h11 * (g21 * h32 + g31 * h33);
  h41 = -h11 * (g21 * h42 + g31 * h43 + g41 * h44);
  h10 = -h00 * g10 * h11;
  h20 = -h00 * (g10 * h21 + g20 * h22);
  h30 = -h00 * (g10 * h31 + g20 * h32 + g30 * h33);
  h40 = -h00 * (g10 * h41 + g20 * h42 + g30 * h43 + g40 * h44);
 
  // Change this to its inverse = H^T*H
  //------------------------------------
 
  m[A00] = h00 * h00 + h10 * h10 + h20 * h20 + h30 * h30 + h40 * h40;
  m[A01] = h10 * h11 + h20 * h21 + h30 * h31 + h40 * h41;
  m[A11] = h11 * h11 + h21 * h21 + h31 * h31 + h41 * h41;
  m[A02] = h20 * h22 + h30 * h32 + h40 * h42;
  m[A12] = h21 * h22 + h31 * h32 + h41 * h42;
  m[A22] = h22 * h22 + h32 * h32 + h42 * h42;
  m[A03] = h30 * h33 + h40 * h43;
  m[A13] = h31 * h33 + h41 * h43;
  m[A23] = h32 * h33 + h42 * h43;
  m[A33] = h33 * h33 + h43 * h43;
  m[A04] = h40 * h44;
  m[A14] = h41 * h44;
  m[A24] = h42 * h44;
  m[A34] = h43 * h44;
  m[A44] = h44 * h44;
 
  ifail = 0;
  return;
}

References A00, A01, A02, A03, A04, A10, A11, A12, A13, A14, A20, A21, A22, A23, A24, A30, A31, A32, A33, A34, A40, A41, A42, A43, A44, and m.

Referenced by invert5().

invertCholesky6()

void G4ErrorSymMatrix::invertCholesky6

(

G4int &

ifail

)

Definition at line 2159 of file G4ErrorSymMatrix.cc.

{
  // Invert by
  //
  // a) decomposing M = G*G^T with G lower triangular
  //    (if M is not positive definite this will fail, leaving this unchanged)
  // b) inverting G to form H
  // c) multiplying H^T * H to get M^-1.
  //
  // If the matrix is pos. def. it is inverted and 1 is returned.
  // If the matrix is not pos. def. it remains unaltered and 0 is returned.
 
  G4double h10;  // below-diagonal elements of H
  G4double h20, h21;
  G4double h30, h31, h32;
  G4double h40, h41, h42, h43;
  G4double h50, h51, h52, h53, h54;
 
  G4double h00, h11, h22, h33, h44, h55;  // 1/diagonal elements of G =
                                          // diagonal elements of H
 
  G4double g10;  // below-diagonal elements of G
  G4double g20, g21;
  G4double g30, g31, g32;
  G4double g40, g41, g42, g43;
  G4double g50, g51, g52, g53, g54;
 
  ifail = 1;  // We start by assuing we won't succeed...
 
  // Form G -- compute diagonal members of H directly rather than of G
  //-------
 
  // Scale first column by 1/sqrt(A00)
 
  h00 = m[A00];
  if(h00 <= 0)
  {
    return;
  }
  h00 = 1.0 / std::sqrt(h00);
 
  g10 = m[A10] * h00;
  g20 = m[A20] * h00;
  g30 = m[A30] * h00;
  g40 = m[A40] * h00;
  g50 = m[A50] * h00;
 
  // Form G11 (actually, just h11)
 
  h11 = m[A11] - (g10 * g10);
  if(h11 <= 0)
  {
    return;
  }
  h11 = 1.0 / std::sqrt(h11);
 
  // Subtract inter-column column dot products from rest of column 1 and
  // scale to get column 1 of G
 
  g21 = (m[A21] - (g10 * g20)) * h11;
  g31 = (m[A31] - (g10 * g30)) * h11;
  g41 = (m[A41] - (g10 * g40)) * h11;
  g51 = (m[A51] - (g10 * g50)) * h11;
 
  // Form G22 (actually, just h22)
 
  h22 = m[A22] - (g20 * g20) - (g21 * g21);
  if(h22 <= 0)
  {
    return;
  }
  h22 = 1.0 / std::sqrt(h22);
 
  // Subtract inter-column column dot products from rest of column 2 and
  // scale to get column 2 of G
 
  g32 = (m[A32] - (g20 * g30) - (g21 * g31)) * h22;
  g42 = (m[A42] - (g20 * g40) - (g21 * g41)) * h22;
  g52 = (m[A52] - (g20 * g50) - (g21 * g51)) * h22;
 
  // Form G33 (actually, just h33)
 
  h33 = m[A33] - (g30 * g30) - (g31 * g31) - (g32 * g32);
  if(h33 <= 0)
  {
    return;
  }
  h33 = 1.0 / std::sqrt(h33);
 
  // Subtract inter-column column dot products from rest of column 3 and
  // scale to get column 3 of G
 
  g43 = (m[A43] - (g30 * g40) - (g31 * g41) - (g32 * g42)) * h33;
  g53 = (m[A53] - (g30 * g50) - (g31 * g51) - (g32 * g52)) * h33;
 
  // Form G44 (actually, just h44)
 
  h44 = m[A44] - (g40 * g40) - (g41 * g41) - (g42 * g42) - (g43 * g43);
  if(h44 <= 0)
  {
    return;
  }
  h44 = 1.0 / std::sqrt(h44);
 
  // Subtract inter-column column dot product from M54 and scale to get G54
 
  g54 = (m[A54] - (g40 * g50) - (g41 * g51) - (g42 * g52) - (g43 * g53)) * h44;
 
  // Finally form h55 - if this is possible inversion succeeds
 
  h55 = m[A55] - (g50 * g50) - (g51 * g51) - (g52 * g52) - (g53 * g53) -
        (g54 * g54);
  if(h55 <= 0)
  {
    return;
  }
  h55 = 1.0 / std::sqrt(h55);
 
  // Form H = 1/G -- diagonal members of H are already correct
  //-------------
 
  // The order here is dictated by speed considerations
 
  h54 = -h44 * g54 * h55;
  h43 = -h33 * g43 * h44;
  h53 = -h33 * (g43 * h54 + g53 * h55);
  h32 = -h22 * g32 * h33;
  h42 = -h22 * (g32 * h43 + g42 * h44);
  h52 = -h22 * (g32 * h53 + g42 * h54 + g52 * h55);
  h21 = -h11 * g21 * h22;
  h31 = -h11 * (g21 * h32 + g31 * h33);
  h41 = -h11 * (g21 * h42 + g31 * h43 + g41 * h44);
  h51 = -h11 * (g21 * h52 + g31 * h53 + g41 * h54 + g51 * h55);
  h10 = -h00 * g10 * h11;
  h20 = -h00 * (g10 * h21 + g20 * h22);
  h30 = -h00 * (g10 * h31 + g20 * h32 + g30 * h33);
  h40 = -h00 * (g10 * h41 + g20 * h42 + g30 * h43 + g40 * h44);
  h50 = -h00 * (g10 * h51 + g20 * h52 + g30 * h53 + g40 * h54 + g50 * h55);
 
  // Change this to its inverse = H^T*H
  //------------------------------------
 
  m[A00] =
    h00 * h00 + h10 * h10 + h20 * h20 + h30 * h30 + h40 * h40 + h50 * h50;
  m[A01] = h10 * h11 + h20 * h21 + h30 * h31 + h40 * h41 + h50 * h51;
  m[A11] = h11 * h11 + h21 * h21 + h31 * h31 + h41 * h41 + h51 * h51;
  m[A02] = h20 * h22 + h30 * h32 + h40 * h42 + h50 * h52;
  m[A12] = h21 * h22 + h31 * h32 + h41 * h42 + h51 * h52;
  m[A22] = h22 * h22 + h32 * h32 + h42 * h42 + h52 * h52;
  m[A03] = h30 * h33 + h40 * h43 + h50 * h53;
  m[A13] = h31 * h33 + h41 * h43 + h51 * h53;
  m[A23] = h32 * h33 + h42 * h43 + h52 * h53;
  m[A33] = h33 * h33 + h43 * h43 + h53 * h53;
  m[A04] = h40 * h44 + h50 * h54;
  m[A14] = h41 * h44 + h51 * h54;
  m[A24] = h42 * h44 + h52 * h54;
  m[A34] = h43 * h44 + h53 * h54;
  m[A44] = h44 * h44 + h54 * h54;
  m[A05] = h50 * h55;
  m[A15] = h51 * h55;
  m[A25] = h52 * h55;
  m[A35] = h53 * h55;
  m[A45] = h54 * h55;
  m[A55] = h55 * h55;
 
  ifail = 0;
  return;
}

References A00, A01, A02, A03, A04, A05, A10, A11, A12, A13, A14, A15, A20, A21, A22, A23, A24, A25, A30, A31, A32, A33, A34, A35, A40, A41, A42, A43, A44, A45, A50, A51, A52, A53, A54, A55, and m.

Referenced by invert6().

invertHaywood4()

void G4ErrorSymMatrix::invertHaywood4

(

G4int &

ifail

)

Definition at line 2403 of file G4ErrorSymMatrix.cc.

{
  invert4(ifail);  // For the 4x4 case, the method we use for invert is already
                   // the Haywood method.
}

References invert4().

invertHaywood5()

void G4ErrorSymMatrix::invertHaywood5

(

G4int &

ifail

)

Definition at line 1454 of file G4ErrorSymMatrix.cc.

{
  ifail = 0;
 
  // Find all NECESSARY 2x2 dets:  (25 of them)
 
  G4double Det2_23_01 = m[A20] * m[A31] - m[A21] * m[A30];
  G4double Det2_23_02 = m[A20] * m[A32] - m[A22] * m[A30];
  G4double Det2_23_03 = m[A20] * m[A33] - m[A23] * m[A30];
  G4double Det2_23_12 = m[A21] * m[A32] - m[A22] * m[A31];
  G4double Det2_23_13 = m[A21] * m[A33] - m[A23] * m[A31];
  G4double Det2_23_23 = m[A22] * m[A33] - m[A23] * m[A32];
  G4double Det2_24_01 = m[A20] * m[A41] - m[A21] * m[A40];
  G4double Det2_24_02 = m[A20] * m[A42] - m[A22] * m[A40];
  G4double Det2_24_03 = m[A20] * m[A43] - m[A23] * m[A40];
  G4double Det2_24_04 = m[A20] * m[A44] - m[A24] * m[A40];
  G4double Det2_24_12 = m[A21] * m[A42] - m[A22] * m[A41];
  G4double Det2_24_13 = m[A21] * m[A43] - m[A23] * m[A41];
  G4double Det2_24_14 = m[A21] * m[A44] - m[A24] * m[A41];
  G4double Det2_24_23 = m[A22] * m[A43] - m[A23] * m[A42];
  G4double Det2_24_24 = m[A22] * m[A44] - m[A24] * m[A42];
  G4double Det2_34_01 = m[A30] * m[A41] - m[A31] * m[A40];
  G4double Det2_34_02 = m[A30] * m[A42] - m[A32] * m[A40];
  G4double Det2_34_03 = m[A30] * m[A43] - m[A33] * m[A40];
  G4double Det2_34_04 = m[A30] * m[A44] - m[A34] * m[A40];
  G4double Det2_34_12 = m[A31] * m[A42] - m[A32] * m[A41];
  G4double Det2_34_13 = m[A31] * m[A43] - m[A33] * m[A41];
  G4double Det2_34_14 = m[A31] * m[A44] - m[A34] * m[A41];
  G4double Det2_34_23 = m[A32] * m[A43] - m[A33] * m[A42];
  G4double Det2_34_24 = m[A32] * m[A44] - m[A34] * m[A42];
  G4double Det2_34_34 = m[A33] * m[A44] - m[A34] * m[A43];
 
  // Find all NECESSARY 3x3 dets:   (30 of them)
 
  G4double Det3_123_012 =
    m[A10] * Det2_23_12 - m[A11] * Det2_23_02 + m[A12] * Det2_23_01;
  G4double Det3_123_013 =
    m[A10] * Det2_23_13 - m[A11] * Det2_23_03 + m[A13] * Det2_23_01;
  G4double Det3_123_023 =
    m[A10] * Det2_23_23 - m[A12] * Det2_23_03 + m[A13] * Det2_23_02;
  G4double Det3_123_123 =
    m[A11] * Det2_23_23 - m[A12] * Det2_23_13 + m[A13] * Det2_23_12;
  G4double Det3_124_012 =
    m[A10] * Det2_24_12 - m[A11] * Det2_24_02 + m[A12] * Det2_24_01;
  G4double Det3_124_013 =
    m[A10] * Det2_24_13 - m[A11] * Det2_24_03 + m[A13] * Det2_24_01;
  G4double Det3_124_014 =
    m[A10] * Det2_24_14 - m[A11] * Det2_24_04 + m[A14] * Det2_24_01;
  G4double Det3_124_023 =
    m[A10] * Det2_24_23 - m[A12] * Det2_24_03 + m[A13] * Det2_24_02;
  G4double Det3_124_024 =
    m[A10] * Det2_24_24 - m[A12] * Det2_24_04 + m[A14] * Det2_24_02;
  G4double Det3_124_123 =
    m[A11] * Det2_24_23 - m[A12] * Det2_24_13 + m[A13] * Det2_24_12;
  G4double Det3_124_124 =
    m[A11] * Det2_24_24 - m[A12] * Det2_24_14 + m[A14] * Det2_24_12;
  G4double Det3_134_012 =
    m[A10] * Det2_34_12 - m[A11] * Det2_34_02 + m[A12] * Det2_34_01;
  G4double Det3_134_013 =
    m[A10] * Det2_34_13 - m[A11] * Det2_34_03 + m[A13] * Det2_34_01;
  G4double Det3_134_014 =
    m[A10] * Det2_34_14 - m[A11] * Det2_34_04 + m[A14] * Det2_34_01;
  G4double Det3_134_023 =
    m[A10] * Det2_34_23 - m[A12] * Det2_34_03 + m[A13] * Det2_34_02;
  G4double Det3_134_024 =
    m[A10] * Det2_34_24 - m[A12] * Det2_34_04 + m[A14] * Det2_34_02;
  G4double Det3_134_034 =
    m[A10] * Det2_34_34 - m[A13] * Det2_34_04 + m[A14] * Det2_34_03;
  G4double Det3_134_123 =
    m[A11] * Det2_34_23 - m[A12] * Det2_34_13 + m[A13] * Det2_34_12;
  G4double Det3_134_124 =
    m[A11] * Det2_34_24 - m[A12] * Det2_34_14 + m[A14] * Det2_34_12;
  G4double Det3_134_134 =
    m[A11] * Det2_34_34 - m[A13] * Det2_34_14 + m[A14] * Det2_34_13;
  G4double Det3_234_012 =
    m[A20] * Det2_34_12 - m[A21] * Det2_34_02 + m[A22] * Det2_34_01;
  G4double Det3_234_013 =
    m[A20] * Det2_34_13 - m[A21] * Det2_34_03 + m[A23] * Det2_34_01;
  G4double Det3_234_014 =
    m[A20] * Det2_34_14 - m[A21] * Det2_34_04 + m[A24] * Det2_34_01;
  G4double Det3_234_023 =
    m[A20] * Det2_34_23 - m[A22] * Det2_34_03 + m[A23] * Det2_34_02;
  G4double Det3_234_024 =
    m[A20] * Det2_34_24 - m[A22] * Det2_34_04 + m[A24] * Det2_34_02;
  G4double Det3_234_034 =
    m[A20] * Det2_34_34 - m[A23] * Det2_34_04 + m[A24] * Det2_34_03;
  G4double Det3_234_123 =
    m[A21] * Det2_34_23 - m[A22] * Det2_34_13 + m[A23] * Det2_34_12;
  G4double Det3_234_124 =
    m[A21] * Det2_34_24 - m[A22] * Det2_34_14 + m[A24] * Det2_34_12;
  G4double Det3_234_134 =
    m[A21] * Det2_34_34 - m[A23] * Det2_34_14 + m[A24] * Det2_34_13;
  G4double Det3_234_234 =
    m[A22] * Det2_34_34 - m[A23] * Det2_34_24 + m[A24] * Det2_34_23;
 
  // Find all NECESSARY 4x4 dets:   (15 of them)
 
  G4double Det4_0123_0123 = m[A00] * Det3_123_123 - m[A01] * Det3_123_023 +
                            m[A02] * Det3_123_013 - m[A03] * Det3_123_012;
  G4double Det4_0124_0123 = m[A00] * Det3_124_123 - m[A01] * Det3_124_023 +
                            m[A02] * Det3_124_013 - m[A03] * Det3_124_012;
  G4double Det4_0124_0124 = m[A00] * Det3_124_124 - m[A01] * Det3_124_024 +
                            m[A02] * Det3_124_014 - m[A04] * Det3_124_012;
  G4double Det4_0134_0123 = m[A00] * Det3_134_123 - m[A01] * Det3_134_023 +
                            m[A02] * Det3_134_013 - m[A03] * Det3_134_012;
  G4double Det4_0134_0124 = m[A00] * Det3_134_124 - m[A01] * Det3_134_024 +
                            m[A02] * Det3_134_014 - m[A04] * Det3_134_012;
  G4double Det4_0134_0134 = m[A00] * Det3_134_134 - m[A01] * Det3_134_034 +
                            m[A03] * Det3_134_014 - m[A04] * Det3_134_013;
  G4double Det4_0234_0123 = m[A00] * Det3_234_123 - m[A01] * Det3_234_023 +
                            m[A02] * Det3_234_013 - m[A03] * Det3_234_012;
  G4double Det4_0234_0124 = m[A00] * Det3_234_124 - m[A01] * Det3_234_024 +
                            m[A02] * Det3_234_014 - m[A04] * Det3_234_012;
  G4double Det4_0234_0134 = m[A00] * Det3_234_134 - m[A01] * Det3_234_034 +
                            m[A03] * Det3_234_014 - m[A04] * Det3_234_013;
  G4double Det4_0234_0234 = m[A00] * Det3_234_234 - m[A02] * Det3_234_034 +
                            m[A03] * Det3_234_024 - m[A04] * Det3_234_023;
  G4double Det4_1234_0123 = m[A10] * Det3_234_123 - m[A11] * Det3_234_023 +
                            m[A12] * Det3_234_013 - m[A13] * Det3_234_012;
  G4double Det4_1234_0124 = m[A10] * Det3_234_124 - m[A11] * Det3_234_024 +
                            m[A12] * Det3_234_014 - m[A14] * Det3_234_012;
  G4double Det4_1234_0134 = m[A10] * Det3_234_134 - m[A11] * Det3_234_034 +
                            m[A13] * Det3_234_014 - m[A14] * Det3_234_013;
  G4double Det4_1234_0234 = m[A10] * Det3_234_234 - m[A12] * Det3_234_034 +
                            m[A13] * Det3_234_024 - m[A14] * Det3_234_023;
  G4double Det4_1234_1234 = m[A11] * Det3_234_234 - m[A12] * Det3_234_134 +
                            m[A13] * Det3_234_124 - m[A14] * Det3_234_123;
 
  // Find the 5x5 det:
 
  G4double det = m[A00] * Det4_1234_1234 - m[A01] * Det4_1234_0234 +
                 m[A02] * Det4_1234_0134 - m[A03] * Det4_1234_0124 +
                 m[A04] * Det4_1234_0123;
 
  if(det == 0)
  {
    ifail = 1;
    return;
  }
 
  G4double oneOverDet = 1.0 / det;
  G4double mn1OverDet = -oneOverDet;
 
  m[A00] = Det4_1234_1234 * oneOverDet;
  m[A01] = Det4_1234_0234 * mn1OverDet;
  m[A02] = Det4_1234_0134 * oneOverDet;
  m[A03] = Det4_1234_0124 * mn1OverDet;
  m[A04] = Det4_1234_0123 * oneOverDet;
 
  m[A11] = Det4_0234_0234 * oneOverDet;
  m[A12] = Det4_0234_0134 * mn1OverDet;
  m[A13] = Det4_0234_0124 * oneOverDet;
  m[A14] = Det4_0234_0123 * mn1OverDet;
 
  m[A22] = Det4_0134_0134 * oneOverDet;
  m[A23] = Det4_0134_0124 * mn1OverDet;
  m[A24] = Det4_0134_0123 * oneOverDet;
 
  m[A33] = Det4_0124_0124 * oneOverDet;
  m[A34] = Det4_0124_0123 * mn1OverDet;
 
  m[A44] = Det4_0123_0123 * oneOverDet;
 
  return;
}

References A00, A01, A02, A03, A04, A10, A11, A12, A13, A14, A20, A21, A22, A23, A24, A30, A31, A32, A33, A34, A40, A41, A42, A43, A44, and m.

Referenced by invert5().

invertHaywood6()

void G4ErrorSymMatrix::invertHaywood6

(

G4int &

ifail

)

Definition at line 1620 of file G4ErrorSymMatrix.cc.

{
  ifail = 0;
 
  // Find all NECESSARY 2x2 dets:  (39 of them)
 
  G4double Det2_34_01 = m[A30] * m[A41] - m[A31] * m[A40];
  G4double Det2_34_02 = m[A30] * m[A42] - m[A32] * m[A40];
  G4double Det2_34_03 = m[A30] * m[A43] - m[A33] * m[A40];
  G4double Det2_34_04 = m[A30] * m[A44] - m[A34] * m[A40];
  G4double Det2_34_12 = m[A31] * m[A42] - m[A32] * m[A41];
  G4double Det2_34_13 = m[A31] * m[A43] - m[A33] * m[A41];
  G4double Det2_34_14 = m[A31] * m[A44] - m[A34] * m[A41];
  G4double Det2_34_23 = m[A32] * m[A43] - m[A33] * m[A42];
  G4double Det2_34_24 = m[A32] * m[A44] - m[A34] * m[A42];
  G4double Det2_34_34 = m[A33] * m[A44] - m[A34] * m[A43];
  G4double Det2_35_01 = m[A30] * m[A51] - m[A31] * m[A50];
  G4double Det2_35_02 = m[A30] * m[A52] - m[A32] * m[A50];
  G4double Det2_35_03 = m[A30] * m[A53] - m[A33] * m[A50];
  G4double Det2_35_04 = m[A30] * m[A54] - m[A34] * m[A50];
  G4double Det2_35_05 = m[A30] * m[A55] - m[A35] * m[A50];
  G4double Det2_35_12 = m[A31] * m[A52] - m[A32] * m[A51];
  G4double Det2_35_13 = m[A31] * m[A53] - m[A33] * m[A51];
  G4double Det2_35_14 = m[A31] * m[A54] - m[A34] * m[A51];
  G4double Det2_35_15 = m[A31] * m[A55] - m[A35] * m[A51];
  G4double Det2_35_23 = m[A32] * m[A53] - m[A33] * m[A52];
  G4double Det2_35_24 = m[A32] * m[A54] - m[A34] * m[A52];
  G4double Det2_35_25 = m[A32] * m[A55] - m[A35] * m[A52];
  G4double Det2_35_34 = m[A33] * m[A54] - m[A34] * m[A53];
  G4double Det2_35_35 = m[A33] * m[A55] - m[A35] * m[A53];
  G4double Det2_45_01 = m[A40] * m[A51] - m[A41] * m[A50];
  G4double Det2_45_02 = m[A40] * m[A52] - m[A42] * m[A50];
  G4double Det2_45_03 = m[A40] * m[A53] - m[A43] * m[A50];
  G4double Det2_45_04 = m[A40] * m[A54] - m[A44] * m[A50];
  G4double Det2_45_05 = m[A40] * m[A55] - m[A45] * m[A50];
  G4double Det2_45_12 = m[A41] * m[A52] - m[A42] * m[A51];
  G4double Det2_45_13 = m[A41] * m[A53] - m[A43] * m[A51];
  G4double Det2_45_14 = m[A41] * m[A54] - m[A44] * m[A51];
  G4double Det2_45_15 = m[A41] * m[A55] - m[A45] * m[A51];
  G4double Det2_45_23 = m[A42] * m[A53] - m[A43] * m[A52];
  G4double Det2_45_24 = m[A42] * m[A54] - m[A44] * m[A52];
  G4double Det2_45_25 = m[A42] * m[A55] - m[A45] * m[A52];
  G4double Det2_45_34 = m[A43] * m[A54] - m[A44] * m[A53];
  G4double Det2_45_35 = m[A43] * m[A55] - m[A45] * m[A53];
  G4double Det2_45_45 = m[A44] * m[A55] - m[A45] * m[A54];
 
  // Find all NECESSARY 3x3 dets:  (65 of them)
 
  G4double Det3_234_012 =
    m[A20] * Det2_34_12 - m[A21] * Det2_34_02 + m[A22] * Det2_34_01;
  G4double Det3_234_013 =
    m[A20] * Det2_34_13 - m[A21] * Det2_34_03 + m[A23] * Det2_34_01;
  G4double Det3_234_014 =
    m[A20] * Det2_34_14 - m[A21] * Det2_34_04 + m[A24] * Det2_34_01;
  G4double Det3_234_023 =
    m[A20] * Det2_34_23 - m[A22] * Det2_34_03 + m[A23] * Det2_34_02;
  G4double Det3_234_024 =
    m[A20] * Det2_34_24 - m[A22] * Det2_34_04 + m[A24] * Det2_34_02;
  G4double Det3_234_034 =
    m[A20] * Det2_34_34 - m[A23] * Det2_34_04 + m[A24] * Det2_34_03;
  G4double Det3_234_123 =
    m[A21] * Det2_34_23 - m[A22] * Det2_34_13 + m[A23] * Det2_34_12;
  G4double Det3_234_124 =
    m[A21] * Det2_34_24 - m[A22] * Det2_34_14 + m[A24] * Det2_34_12;
  G4double Det3_234_134 =
    m[A21] * Det2_34_34 - m[A23] * Det2_34_14 + m[A24] * Det2_34_13;
  G4double Det3_234_234 =
    m[A22] * Det2_34_34 - m[A23] * Det2_34_24 + m[A24] * Det2_34_23;
  G4double Det3_235_012 =
    m[A20] * Det2_35_12 - m[A21] * Det2_35_02 + m[A22] * Det2_35_01;
  G4double Det3_235_013 =
    m[A20] * Det2_35_13 - m[A21] * Det2_35_03 + m[A23] * Det2_35_01;
  G4double Det3_235_014 =
    m[A20] * Det2_35_14 - m[A21] * Det2_35_04 + m[A24] * Det2_35_01;
  G4double Det3_235_015 =
    m[A20] * Det2_35_15 - m[A21] * Det2_35_05 + m[A25] * Det2_35_01;
  G4double Det3_235_023 =
    m[A20] * Det2_35_23 - m[A22] * Det2_35_03 + m[A23] * Det2_35_02;
  G4double Det3_235_024 =
    m[A20] * Det2_35_24 - m[A22] * Det2_35_04 + m[A24] * Det2_35_02;
  G4double Det3_235_025 =
    m[A20] * Det2_35_25 - m[A22] * Det2_35_05 + m[A25] * Det2_35_02;
  G4double Det3_235_034 =
    m[A20] * Det2_35_34 - m[A23] * Det2_35_04 + m[A24] * Det2_35_03;
  G4double Det3_235_035 =
    m[A20] * Det2_35_35 - m[A23] * Det2_35_05 + m[A25] * Det2_35_03;
  G4double Det3_235_123 =
    m[A21] * Det2_35_23 - m[A22] * Det2_35_13 + m[A23] * Det2_35_12;
  G4double Det3_235_124 =
    m[A21] * Det2_35_24 - m[A22] * Det2_35_14 + m[A24] * Det2_35_12;
  G4double Det3_235_125 =
    m[A21] * Det2_35_25 - m[A22] * Det2_35_15 + m[A25] * Det2_35_12;
  G4double Det3_235_134 =
    m[A21] * Det2_35_34 - m[A23] * Det2_35_14 + m[A24] * Det2_35_13;
  G4double Det3_235_135 =
    m[A21] * Det2_35_35 - m[A23] * Det2_35_15 + m[A25] * Det2_35_13;
  G4double Det3_235_234 =
    m[A22] * Det2_35_34 - m[A23] * Det2_35_24 + m[A24] * Det2_35_23;
  G4double Det3_235_235 =
    m[A22] * Det2_35_35 - m[A23] * Det2_35_25 + m[A25] * Det2_35_23;
  G4double Det3_245_012 =
    m[A20] * Det2_45_12 - m[A21] * Det2_45_02 + m[A22] * Det2_45_01;
  G4double Det3_245_013 =
    m[A20] * Det2_45_13 - m[A21] * Det2_45_03 + m[A23] * Det2_45_01;
  G4double Det3_245_014 =
    m[A20] * Det2_45_14 - m[A21] * Det2_45_04 + m[A24] * Det2_45_01;
  G4double Det3_245_015 =
    m[A20] * Det2_45_15 - m[A21] * Det2_45_05 + m[A25] * Det2_45_01;
  G4double Det3_245_023 =
    m[A20] * Det2_45_23 - m[A22] * Det2_45_03 + m[A23] * Det2_45_02;
  G4double Det3_245_024 =
    m[A20] * Det2_45_24 - m[A22] * Det2_45_04 + m[A24] * Det2_45_02;
  G4double Det3_245_025 =
    m[A20] * Det2_45_25 - m[A22] * Det2_45_05 + m[A25] * Det2_45_02;
  G4double Det3_245_034 =
    m[A20] * Det2_45_34 - m[A23] * Det2_45_04 + m[A24] * Det2_45_03;
  G4double Det3_245_035 =
    m[A20] * Det2_45_35 - m[A23] * Det2_45_05 + m[A25] * Det2_45_03;
  G4double Det3_245_045 =
    m[A20] * Det2_45_45 - m[A24] * Det2_45_05 + m[A25] * Det2_45_04;
  G4double Det3_245_123 =
    m[A21] * Det2_45_23 - m[A22] * Det2_45_13 + m[A23] * Det2_45_12;
  G4double Det3_245_124 =
    m[A21] * Det2_45_24 - m[A22] * Det2_45_14 + m[A24] * Det2_45_12;
  G4double Det3_245_125 =
    m[A21] * Det2_45_25 - m[A22] * Det2_45_15 + m[A25] * Det2_45_12;
  G4double Det3_245_134 =
    m[A21] * Det2_45_34 - m[A23] * Det2_45_14 + m[A24] * Det2_45_13;
  G4double Det3_245_135 =
    m[A21] * Det2_45_35 - m[A23] * Det2_45_15 + m[A25] * Det2_45_13;
  G4double Det3_245_145 =
    m[A21] * Det2_45_45 - m[A24] * Det2_45_15 + m[A25] * Det2_45_14;
  G4double Det3_245_234 =
    m[A22] * Det2_45_34 - m[A23] * Det2_45_24 + m[A24] * Det2_45_23;
  G4double Det3_245_235 =
    m[A22] * Det2_45_35 - m[A23] * Det2_45_25 + m[A25] * Det2_45_23;
  G4double Det3_245_245 =
    m[A22] * Det2_45_45 - m[A24] * Det2_45_25 + m[A25] * Det2_45_24;
  G4double Det3_345_012 =
    m[A30] * Det2_45_12 - m[A31] * Det2_45_02 + m[A32] * Det2_45_01;
  G4double Det3_345_013 =
    m[A30] * Det2_45_13 - m[A31] * Det2_45_03 + m[A33] * Det2_45_01;
  G4double Det3_345_014 =
    m[A30] * Det2_45_14 - m[A31] * Det2_45_04 + m[A34] * Det2_45_01;
  G4double Det3_345_015 =
    m[A30] * Det2_45_15 - m[A31] * Det2_45_05 + m[A35] * Det2_45_01;
  G4double Det3_345_023 =
    m[A30] * Det2_45_23 - m[A32] * Det2_45_03 + m[A33] * Det2_45_02;
  G4double Det3_345_024 =
    m[A30] * Det2_45_24 - m[A32] * Det2_45_04 + m[A34] * Det2_45_02;
  G4double Det3_345_025 =
    m[A30] * Det2_45_25 - m[A32] * Det2_45_05 + m[A35] * Det2_45_02;
  G4double Det3_345_034 =
    m[A30] * Det2_45_34 - m[A33] * Det2_45_04 + m[A34] * Det2_45_03;
  G4double Det3_345_035 =
    m[A30] * Det2_45_35 - m[A33] * Det2_45_05 + m[A35] * Det2_45_03;
  G4double Det3_345_045 =
    m[A30] * Det2_45_45 - m[A34] * Det2_45_05 + m[A35] * Det2_45_04;
  G4double Det3_345_123 =
    m[A31] * Det2_45_23 - m[A32] * Det2_45_13 + m[A33] * Det2_45_12;
  G4double Det3_345_124 =
    m[A31] * Det2_45_24 - m[A32] * Det2_45_14 + m[A34] * Det2_45_12;
  G4double Det3_345_125 =
    m[A31] * Det2_45_25 - m[A32] * Det2_45_15 + m[A35] * Det2_45_12;
  G4double Det3_345_134 =
    m[A31] * Det2_45_34 - m[A33] * Det2_45_14 + m[A34] * Det2_45_13;
  G4double Det3_345_135 =
    m[A31] * Det2_45_35 - m[A33] * Det2_45_15 + m[A35] * Det2_45_13;
  G4double Det3_345_145 =
    m[A31] * Det2_45_45 - m[A34] * Det2_45_15 + m[A35] * Det2_45_14;
  G4double Det3_345_234 =
    m[A32] * Det2_45_34 - m[A33] * Det2_45_24 + m[A34] * Det2_45_23;
  G4double Det3_345_235 =
    m[A32] * Det2_45_35 - m[A33] * Det2_45_25 + m[A35] * Det2_45_23;
  G4double Det3_345_245 =
    m[A32] * Det2_45_45 - m[A34] * Det2_45_25 + m[A35] * Det2_45_24;
  G4double Det3_345_345 =
    m[A33] * Det2_45_45 - m[A34] * Det2_45_35 + m[A35] * Det2_45_34;
 
  // Find all NECESSARY 4x4 dets:  (55 of them)
 
  G4double Det4_1234_0123 = m[A10] * Det3_234_123 - m[A11] * Det3_234_023 +
                            m[A12] * Det3_234_013 - m[A13] * Det3_234_012;
  G4double Det4_1234_0124 = m[A10] * Det3_234_124 - m[A11] * Det3_234_024 +
                            m[A12] * Det3_234_014 - m[A14] * Det3_234_012;
  G4double Det4_1234_0134 = m[A10] * Det3_234_134 - m[A11] * Det3_234_034 +
                            m[A13] * Det3_234_014 - m[A14] * Det3_234_013;
  G4double Det4_1234_0234 = m[A10] * Det3_234_234 - m[A12] * Det3_234_034 +
                            m[A13] * Det3_234_024 - m[A14] * Det3_234_023;
  G4double Det4_1234_1234 = m[A11] * Det3_234_234 - m[A12] * Det3_234_134 +
                            m[A13] * Det3_234_124 - m[A14] * Det3_234_123;
  G4double Det4_1235_0123 = m[A10] * Det3_235_123 - m[A11] * Det3_235_023 +
                            m[A12] * Det3_235_013 - m[A13] * Det3_235_012;
  G4double Det4_1235_0124 = m[A10] * Det3_235_124 - m[A11] * Det3_235_024 +
                            m[A12] * Det3_235_014 - m[A14] * Det3_235_012;
  G4double Det4_1235_0125 = m[A10] * Det3_235_125 - m[A11] * Det3_235_025 +
                            m[A12] * Det3_235_015 - m[A15] * Det3_235_012;
  G4double Det4_1235_0134 = m[A10] * Det3_235_134 - m[A11] * Det3_235_034 +
                            m[A13] * Det3_235_014 - m[A14] * Det3_235_013;
  G4double Det4_1235_0135 = m[A10] * Det3_235_135 - m[A11] * Det3_235_035 +
                            m[A13] * Det3_235_015 - m[A15] * Det3_235_013;
  G4double Det4_1235_0234 = m[A10] * Det3_235_234 - m[A12] * Det3_235_034 +
                            m[A13] * Det3_235_024 - m[A14] * Det3_235_023;
  G4double Det4_1235_0235 = m[A10] * Det3_235_235 - m[A12] * Det3_235_035 +
                            m[A13] * Det3_235_025 - m[A15] * Det3_235_023;
  G4double Det4_1235_1234 = m[A11] * Det3_235_234 - m[A12] * Det3_235_134 +
                            m[A13] * Det3_235_124 - m[A14] * Det3_235_123;
  G4double Det4_1235_1235 = m[A11] * Det3_235_235 - m[A12] * Det3_235_135 +
                            m[A13] * Det3_235_125 - m[A15] * Det3_235_123;
  G4double Det4_1245_0123 = m[A10] * Det3_245_123 - m[A11] * Det3_245_023 +
                            m[A12] * Det3_245_013 - m[A13] * Det3_245_012;
  G4double Det4_1245_0124 = m[A10] * Det3_245_124 - m[A11] * Det3_245_024 +
                            m[A12] * Det3_245_014 - m[A14] * Det3_245_012;
  G4double Det4_1245_0125 = m[A10] * Det3_245_125 - m[A11] * Det3_245_025 +
                            m[A12] * Det3_245_015 - m[A15] * Det3_245_012;
  G4double Det4_1245_0134 = m[A10] * Det3_245_134 - m[A11] * Det3_245_034 +
                            m[A13] * Det3_245_014 - m[A14] * Det3_245_013;
  G4double Det4_1245_0135 = m[A10] * Det3_245_135 - m[A11] * Det3_245_035 +
                            m[A13] * Det3_245_015 - m[A15] * Det3_245_013;
  G4double Det4_1245_0145 = m[A10] * Det3_245_145 - m[A11] * Det3_245_045 +
                            m[A14] * Det3_245_015 - m[A15] * Det3_245_014;
  G4double Det4_1245_0234 = m[A10] * Det3_245_234 - m[A12] * Det3_245_034 +
                            m[A13] * Det3_245_024 - m[A14] * Det3_245_023;
  G4double Det4_1245_0235 = m[A10] * Det3_245_235 - m[A12] * Det3_245_035 +
                            m[A13] * Det3_245_025 - m[A15] * Det3_245_023;
  G4double Det4_1245_0245 = m[A10] * Det3_245_245 - m[A12] * Det3_245_045 +
                            m[A14] * Det3_245_025 - m[A15] * Det3_245_024;
  G4double Det4_1245_1234 = m[A11] * Det3_245_234 - m[A12] * Det3_245_134 +
                            m[A13] * Det3_245_124 - m[A14] * Det3_245_123;
  G4double Det4_1245_1235 = m[A11] * Det3_245_235 - m[A12] * Det3_245_135 +
                            m[A13] * Det3_245_125 - m[A15] * Det3_245_123;
  G4double Det4_1245_1245 = m[A11] * Det3_245_245 - m[A12] * Det3_245_145 +
                            m[A14] * Det3_245_125 - m[A15] * Det3_245_124;
  G4double Det4_1345_0123 = m[A10] * Det3_345_123 - m[A11] * Det3_345_023 +
                            m[A12] * Det3_345_013 - m[A13] * Det3_345_012;
  G4double Det4_1345_0124 = m[A10] * Det3_345_124 - m[A11] * Det3_345_024 +
                            m[A12] * Det3_345_014 - m[A14] * Det3_345_012;
  G4double Det4_1345_0125 = m[A10] * Det3_345_125 - m[A11] * Det3_345_025 +
                            m[A12] * Det3_345_015 - m[A15] * Det3_345_012;
  G4double Det4_1345_0134 = m[A10] * Det3_345_134 - m[A11] * Det3_345_034 +
                            m[A13] * Det3_345_014 - m[A14] * Det3_345_013;
  G4double Det4_1345_0135 = m[A10] * Det3_345_135 - m[A11] * Det3_345_035 +
                            m[A13] * Det3_345_015 - m[A15] * Det3_345_013;
  G4double Det4_1345_0145 = m[A10] * Det3_345_145 - m[A11] * Det3_345_045 +
                            m[A14] * Det3_345_015 - m[A15] * Det3_345_014;
  G4double Det4_1345_0234 = m[A10] * Det3_345_234 - m[A12] * Det3_345_034 +
                            m[A13] * Det3_345_024 - m[A14] * Det3_345_023;
  G4double Det4_1345_0235 = m[A10] * Det3_345_235 - m[A12] * Det3_345_035 +
                            m[A13] * Det3_345_025 - m[A15] * Det3_345_023;
  G4double Det4_1345_0245 = m[A10] * Det3_345_245 - m[A12] * Det3_345_045 +
                            m[A14] * Det3_345_025 - m[A15] * Det3_345_024;
  G4double Det4_1345_0345 = m[A10] * Det3_345_345 - m[A13] * Det3_345_045 +
                            m[A14] * Det3_345_035 - m[A15] * Det3_345_034;
  G4double Det4_1345_1234 = m[A11] * Det3_345_234 - m[A12] * Det3_345_134 +
                            m[A13] * Det3_345_124 - m[A14] * Det3_345_123;
  G4double Det4_1345_1235 = m[A11] * Det3_345_235 - m[A12] * Det3_345_135 +
                            m[A13] * Det3_345_125 - m[A15] * Det3_345_123;
  G4double Det4_1345_1245 = m[A11] * Det3_345_245 - m[A12] * Det3_345_145 +
                            m[A14] * Det3_345_125 - m[A15] * Det3_345_124;
  G4double Det4_1345_1345 = m[A11] * Det3_345_345 - m[A13] * Det3_345_145 +
                            m[A14] * Det3_345_135 - m[A15] * Det3_345_134;
  G4double Det4_2345_0123 = m[A20] * Det3_345_123 - m[A21] * Det3_345_023 +
                            m[A22] * Det3_345_013 - m[A23] * Det3_345_012;
  G4double Det4_2345_0124 = m[A20] * Det3_345_124 - m[A21] * Det3_345_024 +
                            m[A22] * Det3_345_014 - m[A24] * Det3_345_012;
  G4double Det4_2345_0125 = m[A20] * Det3_345_125 - m[A21] * Det3_345_025 +
                            m[A22] * Det3_345_015 - m[A25] * Det3_345_012;
  G4double Det4_2345_0134 = m[A20] * Det3_345_134 - m[A21] * Det3_345_034 +
                            m[A23] * Det3_345_014 - m[A24] * Det3_345_013;
  G4double Det4_2345_0135 = m[A20] * Det3_345_135 - m[A21] * Det3_345_035 +
                            m[A23] * Det3_345_015 - m[A25] * Det3_345_013;
  G4double Det4_2345_0145 = m[A20] * Det3_345_145 - m[A21] * Det3_345_045 +
                            m[A24] * Det3_345_015 - m[A25] * Det3_345_014;
  G4double Det4_2345_0234 = m[A20] * Det3_345_234 - m[A22] * Det3_345_034 +
                            m[A23] * Det3_345_024 - m[A24] * Det3_345_023;
  G4double Det4_2345_0235 = m[A20] * Det3_345_235 - m[A22] * Det3_345_035 +
                            m[A23] * Det3_345_025 - m[A25] * Det3_345_023;
  G4double Det4_2345_0245 = m[A20] * Det3_345_245 - m[A22] * Det3_345_045 +
                            m[A24] * Det3_345_025 - m[A25] * Det3_345_024;
  G4double Det4_2345_0345 = m[A20] * Det3_345_345 - m[A23] * Det3_345_045 +
                            m[A24] * Det3_345_035 - m[A25] * Det3_345_034;
  G4double Det4_2345_1234 = m[A21] * Det3_345_234 - m[A22] * Det3_345_134 +
                            m[A23] * Det3_345_124 - m[A24] * Det3_345_123;
  G4double Det4_2345_1235 = m[A21] * Det3_345_235 - m[A22] * Det3_345_135 +
                            m[A23] * Det3_345_125 - m[A25] * Det3_345_123;
  G4double Det4_2345_1245 = m[A21] * Det3_345_245 - m[A22] * Det3_345_145 +
                            m[A24] * Det3_345_125 - m[A25] * Det3_345_124;
  G4double Det4_2345_1345 = m[A21] * Det3_345_345 - m[A23] * Det3_345_145 +
                            m[A24] * Det3_345_135 - m[A25] * Det3_345_134;
  G4double Det4_2345_2345 = m[A22] * Det3_345_345 - m[A23] * Det3_345_245 +
                            m[A24] * Det3_345_235 - m[A25] * Det3_345_234;
 
  // Find all NECESSARY 5x5 dets:  (19 of them)
 
  G4double Det5_01234_01234 =
    m[A00] * Det4_1234_1234 - m[A01] * Det4_1234_0234 +
    m[A02] * Det4_1234_0134 - m[A03] * Det4_1234_0124 + m[A04] * Det4_1234_0123;
  G4double Det5_01235_01234 =
    m[A00] * Det4_1235_1234 - m[A01] * Det4_1235_0234 +
    m[A02] * Det4_1235_0134 - m[A03] * Det4_1235_0124 + m[A04] * Det4_1235_0123;
  G4double Det5_01235_01235 =
    m[A00] * Det4_1235_1235 - m[A01] * Det4_1235_0235 +
    m[A02] * Det4_1235_0135 - m[A03] * Det4_1235_0125 + m[A05] * Det4_1235_0123;
  G4double Det5_01245_01234 =
    m[A00] * Det4_1245_1234 - m[A01] * Det4_1245_0234 +
    m[A02] * Det4_1245_0134 - m[A03] * Det4_1245_0124 + m[A04] * Det4_1245_0123;
  G4double Det5_01245_01235 =
    m[A00] * Det4_1245_1235 - m[A01] * Det4_1245_0235 +
    m[A02] * Det4_1245_0135 - m[A03] * Det4_1245_0125 + m[A05] * Det4_1245_0123;
  G4double Det5_01245_01245 =
    m[A00] * Det4_1245_1245 - m[A01] * Det4_1245_0245 +
    m[A02] * Det4_1245_0145 - m[A04] * Det4_1245_0125 + m[A05] * Det4_1245_0124;
  G4double Det5_01345_01234 =
    m[A00] * Det4_1345_1234 - m[A01] * Det4_1345_0234 +
    m[A02] * Det4_1345_0134 - m[A03] * Det4_1345_0124 + m[A04] * Det4_1345_0123;
  G4double Det5_01345_01235 =
    m[A00] * Det4_1345_1235 - m[A01] * Det4_1345_0235 +
    m[A02] * Det4_1345_0135 - m[A03] * Det4_1345_0125 + m[A05] * Det4_1345_0123;
  G4double Det5_01345_01245 =
    m[A00] * Det4_1345_1245 - m[A01] * Det4_1345_0245 +
    m[A02] * Det4_1345_0145 - m[A04] * Det4_1345_0125 + m[A05] * Det4_1345_0124;
  G4double Det5_01345_01345 =
    m[A00] * Det4_1345_1345 - m[A01] * Det4_1345_0345 +
    m[A03] * Det4_1345_0145 - m[A04] * Det4_1345_0135 + m[A05] * Det4_1345_0134;
  G4double Det5_02345_01234 =
    m[A00] * Det4_2345_1234 - m[A01] * Det4_2345_0234 +
    m[A02] * Det4_2345_0134 - m[A03] * Det4_2345_0124 + m[A04] * Det4_2345_0123;
  G4double Det5_02345_01235 =
    m[A00] * Det4_2345_1235 - m[A01] * Det4_2345_0235 +
    m[A02] * Det4_2345_0135 - m[A03] * Det4_2345_0125 + m[A05] * Det4_2345_0123;
  G4double Det5_02345_01245 =
    m[A00] * Det4_2345_1245 - m[A01] * Det4_2345_0245 +
    m[A02] * Det4_2345_0145 - m[A04] * Det4_2345_0125 + m[A05] * Det4_2345_0124;
  G4double Det5_02345_01345 =
    m[A00] * Det4_2345_1345 - m[A01] * Det4_2345_0345 +
    m[A03] * Det4_2345_0145 - m[A04] * Det4_2345_0135 + m[A05] * Det4_2345_0134;
  G4double Det5_02345_02345 =
    m[A00] * Det4_2345_2345 - m[A02] * Det4_2345_0345 +
    m[A03] * Det4_2345_0245 - m[A04] * Det4_2345_0235 + m[A05] * Det4_2345_0234;
  G4double Det5_12345_01234 =
    m[A10] * Det4_2345_1234 - m[A11] * Det4_2345_0234 +
    m[A12] * Det4_2345_0134 - m[A13] * Det4_2345_0124 + m[A14] * Det4_2345_0123;
  G4double Det5_12345_01235 =
    m[A10] * Det4_2345_1235 - m[A11] * Det4_2345_0235 +
    m[A12] * Det4_2345_0135 - m[A13] * Det4_2345_0125 + m[A15] * Det4_2345_0123;
  G4double Det5_12345_01245 =
    m[A10] * Det4_2345_1245 - m[A11] * Det4_2345_0245 +
    m[A12] * Det4_2345_0145 - m[A14] * Det4_2345_0125 + m[A15] * Det4_2345_0124;
  G4double Det5_12345_01345 =
    m[A10] * Det4_2345_1345 - m[A11] * Det4_2345_0345 +
    m[A13] * Det4_2345_0145 - m[A14] * Det4_2345_0135 + m[A15] * Det4_2345_0134;
  G4double Det5_12345_02345 =
    m[A10] * Det4_2345_2345 - m[A12] * Det4_2345_0345 +
    m[A13] * Det4_2345_0245 - m[A14] * Det4_2345_0235 + m[A15] * Det4_2345_0234;
  G4double Det5_12345_12345 =
    m[A11] * Det4_2345_2345 - m[A12] * Det4_2345_1345 +
    m[A13] * Det4_2345_1245 - m[A14] * Det4_2345_1235 + m[A15] * Det4_2345_1234;
 
  // Find the determinant
 
  G4double det = m[A00] * Det5_12345_12345 - m[A01] * Det5_12345_02345 +
                 m[A02] * Det5_12345_01345 - m[A03] * Det5_12345_01245 +
                 m[A04] * Det5_12345_01235 - m[A05] * Det5_12345_01234;
 
  if(det == 0)
  {
    ifail = 1;
    return;
  }
 
  G4double oneOverDet = 1.0 / det;
  G4double mn1OverDet = -oneOverDet;
 
  m[A00] = Det5_12345_12345 * oneOverDet;
  m[A01] = Det5_12345_02345 * mn1OverDet;
  m[A02] = Det5_12345_01345 * oneOverDet;
  m[A03] = Det5_12345_01245 * mn1OverDet;
  m[A04] = Det5_12345_01235 * oneOverDet;
  m[A05] = Det5_12345_01234 * mn1OverDet;
 
  m[A11] = Det5_02345_02345 * oneOverDet;
  m[A12] = Det5_02345_01345 * mn1OverDet;
  m[A13] = Det5_02345_01245 * oneOverDet;
  m[A14] = Det5_02345_01235 * mn1OverDet;
  m[A15] = Det5_02345_01234 * oneOverDet;
 
  m[A22] = Det5_01345_01345 * oneOverDet;
  m[A23] = Det5_01345_01245 * mn1OverDet;
  m[A24] = Det5_01345_01235 * oneOverDet;
  m[A25] = Det5_01345_01234 * mn1OverDet;
 
  m[A33] = Det5_01245_01245 * oneOverDet;
  m[A34] = Det5_01245_01235 * mn1OverDet;
  m[A35] = Det5_01245_01234 * oneOverDet;
 
  m[A44] = Det5_01235_01235 * oneOverDet;
  m[A45] = Det5_01235_01234 * mn1OverDet;
 
  m[A55] = Det5_01234_01234 * oneOverDet;
 
  return;
}

References A00, A01, A02, A03, A04, A05, A10, A11, A12, A13, A14, A15, A20, A21, A22, A23, A24, A25, A30, A31, A32, A33, A34, A35, A40, A41, A42, A43, A44, A45, A50, A51, A52, A53, A54, A55, and m.

Referenced by invert6().

num_col()

G4int G4ErrorSymMatrix::num_col ( ) const

inline

Referenced by operator+(), G4ErrorMatrix::operator+=(), operator+=(), operator-(), G4ErrorMatrix::operator-=(), operator-=(), operator<<(), and similarity().

num_row()

G4int G4ErrorSymMatrix::num_row ( ) const

inline

Referenced by apply(), dsum(), operator+(), G4ErrorMatrix::operator+=(), operator+=(), operator-(), G4ErrorMatrix::operator-=(), operator-=(), operator<<(), similarity(), similarityT(), and sub().

num_size()

G4int G4ErrorSymMatrix::num_size ( ) const

inlineprotected

Referenced by operator-().

operator()() [1/2]

G4double & G4ErrorSymMatrix::operator()	(	G4int	row,
		G4int	col
	)

operator()() [2/2]

const G4double & G4ErrorSymMatrix::operator()	(	G4int	row,
		G4int	col
	)		const

operator*=()

G4ErrorSymMatrix & G4ErrorSymMatrix::operator*=

(

G4double

t

)

Definition at line 508 of file G4ErrorSymMatrix.cc.

{
  SIMPLE_UOP(*=)
  return (*this);
}

References SIMPLE_UOP.

operator+=()

G4ErrorSymMatrix & G4ErrorSymMatrix::operator+=

(

const G4ErrorSymMatrix &

m2

)

Definition at line 462 of file G4ErrorSymMatrix.cc.

{
  CHK_DIM_2(num_row(), mat2.num_row(), num_col(), mat2.num_col(), +=);
  SIMPLE_BOP(+=)
  return (*this);
}

References CHK_DIM_2, num_col(), num_row(), and SIMPLE_BOP.

operator-()

G4ErrorSymMatrix G4ErrorSymMatrix::operator-

(

)

const

Definition at line 209 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mat2(nrow);
  G4ErrorMatrixConstIter a = m.begin();
  G4ErrorMatrixIter b      = mat2.m.begin();
  G4ErrorMatrixConstIter e = m.begin() + num_size();
  for(; a < e; a++, b++)
  {
    (*b) = -(*a);
  }
  return mat2;
}

References m, nrow, and num_size().

operator-=()

G4ErrorSymMatrix & G4ErrorSymMatrix::operator-=

(

const G4ErrorSymMatrix &

m2

)

Definition at line 495 of file G4ErrorSymMatrix.cc.

{
  CHK_DIM_2(num_row(), mat2.num_row(), num_col(), mat2.num_col(), -=);
  SIMPLE_BOP(-=)
  return (*this);
}

References CHK_DIM_2, num_col(), num_row(), and SIMPLE_BOP.

operator/=()

G4ErrorSymMatrix & G4ErrorSymMatrix::operator/=

(

G4double

t

)

Definition at line 502 of file G4ErrorSymMatrix.cc.

{
  SIMPLE_UOP(/=)
  return (*this);
}

References SIMPLE_UOP.

operator=() [1/2]

G4ErrorSymMatrix & G4ErrorSymMatrix::operator=

(

const G4ErrorSymMatrix &

m2

)

Definition at line 546 of file G4ErrorSymMatrix.cc.

{
  if(&mat1 == this)
  {
    return *this;
  }
  if(mat1.nrow != nrow)
  {
    nrow = mat1.nrow;
    size = mat1.size;
    m.resize(size);
  }
  m = mat1.m;
  return (*this);
}

References m, nrow, and size.

operator=() [2/2]

G4ErrorSymMatrix & G4ErrorSymMatrix::operator= ( G4ErrorSymMatrix &&  )

default

operator[]() [1/2]

G4ErrorSymMatrix_row G4ErrorSymMatrix::operator[] ( G4int  )

inline

operator[]() [2/2]

G4ErrorSymMatrix_row_const G4ErrorSymMatrix::operator[] ( G4int  ) const

inline

similarity() [1/2]

G4ErrorSymMatrix G4ErrorSymMatrix::similarity

(

const G4ErrorMatrix &

m1

)

const

Definition at line 629 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(mat1.num_row());
  G4ErrorMatrix temp = mat1 * (*this);
 
  // If mat1*(*this) has correct dimensions, then so will the mat1.T
  // multiplication. So there is no need to check dimensions again.
 
  G4int n                  = mat1.num_col();
  G4ErrorMatrixIter mr     = mret.m.begin();
  G4ErrorMatrixIter tempr1 = temp.m.begin();
  for(G4int r = 1; r <= mret.num_row(); r++)
  {
    G4ErrorMatrixConstIter m1c1 = mat1.m.begin();
    for(G4int c = 1; c <= r; c++)
    {
      G4double tmp                = 0.0;
      G4ErrorMatrixIter tempri    = tempr1;
      G4ErrorMatrixConstIter m1ci = m1c1;
      for(G4int i = 1; i <= mat1.num_col(); i++)
      {
        tmp += (*(tempri++)) * (*(m1ci++));
      }
      *(mr++) = tmp;
      m1c1 += n;
    }
    tempr1 += n;
  }
  return mret;
}

References G4ErrorMatrix::m, m, CLHEP::detail::n, G4ErrorMatrix::num_col(), G4ErrorMatrix::num_row(), and num_row().

Referenced by G4ErrorSurfaceTrajState::BuildErrorMatrix(), G4ErrorFreeTrajState::G4ErrorFreeTrajState(), and G4ErrorFreeTrajState::PropagateError().

similarity() [2/2]

G4ErrorSymMatrix G4ErrorSymMatrix::similarity

(

const G4ErrorSymMatrix &

m1

)

const

Definition at line 660 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(mat1.num_row());
  G4ErrorMatrix temp       = mat1 * (*this);
  G4int n                  = mat1.num_col();
  G4ErrorMatrixIter mr     = mret.m.begin();
  G4ErrorMatrixIter tempr1 = temp.m.begin();
  for(G4int r = 1; r <= mret.num_row(); r++)
  {
    G4ErrorMatrixConstIter m1c1 = mat1.m.begin();
    G4int c;
    for(c = 1; c <= r; c++)
    {
      G4double tmp                = 0.0;
      G4ErrorMatrixIter tempri    = tempr1;
      G4ErrorMatrixConstIter m1ci = m1c1;
      G4int i;
      for(i = 1; i < c; i++)
      {
        tmp += (*(tempri++)) * (*(m1ci++));
      }
      for(i = c; i <= mat1.num_col(); i++)
      {
        tmp += (*(tempri++)) * (*(m1ci));
        m1ci += i;
      }
      *(mr++) = tmp;
      m1c1 += c;
    }
    tempr1 += n;
  }
  return mret;
}

References G4ErrorMatrix::m, m, CLHEP::detail::n, num_col(), and num_row().

similarityT()

G4ErrorSymMatrix G4ErrorSymMatrix::similarityT

(

const G4ErrorMatrix &

m1

)

const

Definition at line 695 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(mat1.num_col());
  G4ErrorMatrix temp       = (*this) * mat1;
  G4int n                  = mat1.num_col();
  G4ErrorMatrixIter mrc    = mret.m.begin();
  G4ErrorMatrixIter temp1r = temp.m.begin();
  for(G4int r = 1; r <= mret.num_row(); r++)
  {
    G4ErrorMatrixConstIter m11c = mat1.m.begin();
    for(G4int c = 1; c <= r; c++)
    {
      G4double tmp                = 0.0;
      G4ErrorMatrixIter tempir    = temp1r;
      G4ErrorMatrixConstIter m1ic = m11c;
      for(G4int i = 1; i <= mat1.num_row(); i++)
      {
        tmp += (*(tempir)) * (*(m1ic));
        tempir += n;
        m1ic += n;
      }
      *(mrc++) = tmp;
      m11c++;
    }
    temp1r++;
  }
  return mret;
}

References G4ErrorMatrix::m, m, CLHEP::detail::n, G4ErrorMatrix::num_col(), G4ErrorMatrix::num_row(), and num_row().

sub() [1/3]

G4ErrorSymMatrix G4ErrorSymMatrix::sub	(	G4int	min_row,
		G4int	max_row
	)

Definition at line 151 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(max_row - min_row + 1);
  if(max_row > num_row())
  {
    G4ErrorMatrix::error("G4ErrorSymMatrix::sub: Index out of range");
  }
  G4ErrorMatrixIter a  = mret.m.begin();
  G4ErrorMatrixIter b1 = m.begin() + (min_row + 2) * (min_row - 1) / 2;
  for(G4int irow = 1; irow <= mret.num_row(); irow++)
  {
    G4ErrorMatrixIter b = b1;
    for(G4int icol = 1; icol <= irow; icol++)
    {
      *(a++) = *(b++);
    }
    b1 += irow + min_row - 1;
  }
  return mret;
}

References G4ErrorMatrix::error(), m, and num_row().

sub() [2/3]

G4ErrorSymMatrix G4ErrorSymMatrix::sub	(	G4int	min_row,
		G4int	max_row
	)		const

Definition at line 130 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(max_row - min_row + 1);
  if(max_row > num_row())
  {
    G4ErrorMatrix::error("G4ErrorSymMatrix::sub: Index out of range");
  }
  G4ErrorMatrixIter a       = mret.m.begin();
  G4ErrorMatrixConstIter b1 = m.begin() + (min_row + 2) * (min_row - 1) / 2;
  for(G4int irow = 1; irow <= mret.num_row(); irow++)
  {
    G4ErrorMatrixConstIter b = b1;
    for(G4int icol = 1; icol <= irow; icol++)
    {
      *(a++) = *(b++);
    }
    b1 += irow + min_row - 1;
  }
  return mret;
}

References G4ErrorMatrix::error(), m, and num_row().

Referenced by dsum().

sub() [3/3]

void G4ErrorSymMatrix::sub	(	G4int	row,
		const G4ErrorSymMatrix &	m1
	)

Definition at line 172 of file G4ErrorSymMatrix.cc.

{
  if(row < 1 || row + mat1.num_row() - 1 > num_row())
  {
    G4ErrorMatrix::error("G4ErrorSymMatrix::sub: Index out of range");
  }
  G4ErrorMatrixConstIter a = mat1.m.begin();
  G4ErrorMatrixIter b1     = m.begin() + (row + 2) * (row - 1) / 2;
  for(G4int irow = 1; irow <= mat1.num_row(); irow++)
  {
    G4ErrorMatrixIter b = b1;
    for(G4int icol = 1; icol <= irow; icol++)
    {
      *(b++) = *(a++);
    }
    b1 += irow + row - 1;
  }
}

References G4ErrorMatrix::error(), m, and num_row().

T()

G4ErrorSymMatrix G4ErrorSymMatrix::T

(

)

const

Referenced by G4ErrorFreeTrajState::PropagateError().

trace()

G4double G4ErrorSymMatrix::trace

(

)

const

Definition at line 864 of file G4ErrorSymMatrix.cc.

{
  G4double t = 0.0;
  for(G4int i = 0; i < nrow; i++)
  {
    t += *(m.begin() + (i + 3) * i / 2);
  }
  return t;
}

References m, and nrow.

Friends And Related Function Documentation

condition

G4double condition ( const G4ErrorSymMatrix &  m )

friend

diag_step [1/2]

void diag_step ( G4ErrorSymMatrix *  t, G4ErrorMatrix *  u, G4int  begin, G4int  end  )

friend

diag_step [2/2]

void diag_step ( G4ErrorSymMatrix *  t, G4int  begin, G4int  end  )

friend

diagonalize

G4ErrorMatrix diagonalize ( G4ErrorSymMatrix *  s )

friend

G4ErrorMatrix

friend class G4ErrorMatrix

friend

Definition at line 194 of file G4ErrorSymMatrix.hh.

G4ErrorSymMatrix_row

friend class G4ErrorSymMatrix_row

friend

Definition at line 192 of file G4ErrorSymMatrix.hh.

G4ErrorSymMatrix_row_const

friend class G4ErrorSymMatrix_row_const

friend

Definition at line 193 of file G4ErrorSymMatrix.hh.

house_with_update2

void house_with_update2 ( G4ErrorSymMatrix *  a, G4ErrorMatrix *  v, G4int  row, G4int  col  )

friend

operator* [1/3]

G4ErrorMatrix operator* ( const G4ErrorMatrix &  m1, const G4ErrorSymMatrix &  m2  )

friend

Definition at line 302 of file G4ErrorSymMatrix.cc.

{
  G4ErrorMatrix mret(mat1.num_row(), mat2.num_col());
  CHK_DIM_1(mat1.num_col(), mat2.num_row(), *);
  G4ErrorMatrixConstIter mit1, mit2, sp, snp;  // mit2=0
  G4double temp;
  G4ErrorMatrixIter mir = mret.m.begin();
  for(mit1 = mat1.m.begin();
      mit1 < mat1.m.begin() + mat1.num_row() * mat1.num_col(); mit1 = mit2)
  {
    snp = mat2.m.begin();
    for(int step = 1; step <= mat2.num_row(); ++step)
    {
      mit2 = mit1;
      sp   = snp;
      snp += step;
      temp = 0;
      while(sp < snp)  // Loop checking, 06.08.2015, G.Cosmo
      {
        temp += *(sp++) * (*(mit2++));
      }
      if(step < mat2.num_row())
      {  // only if we aren't on the last row
        sp += step - 1;
        for(int stept = step + 1; stept <= mat2.num_row(); stept++)
        {
          temp += *sp * (*(mit2++));
          if(stept < mat2.num_row())
            sp += stept;
        }
      }  // if(step
      *(mir++) = temp;
    }  // for(step
  }    // for(mit1
  return mret;
}

operator* [2/3]

G4ErrorMatrix operator* ( const G4ErrorSymMatrix &  m1, const G4ErrorMatrix &  m2  )

friend

Definition at line 339 of file G4ErrorSymMatrix.cc.

{
  G4ErrorMatrix mret(mat1.num_row(), mat2.num_col());
  CHK_DIM_1(mat1.num_col(), mat2.num_row(), *);
  G4int step, stept;
  G4ErrorMatrixConstIter mit1, mit2, sp, snp;
  G4double temp;
  G4ErrorMatrixIter mir = mret.m.begin();
  for(step = 1, snp = mat1.m.begin(); step <= mat1.num_row(); snp += step++)
  {
    for(mit1 = mat2.m.begin(); mit1 < mat2.m.begin() + mat2.num_col(); mit1++)
    {
      mit2 = mit1;
      sp   = snp;
      temp = 0;
      while(sp < snp + step)  // Loop checking, 06.08.2015, G.Cosmo
      {
        temp += *mit2 * (*(sp++));
        mit2 += mat2.num_col();
      }
      sp += step - 1;
      for(stept = step + 1; stept <= mat1.num_row(); stept++)
      {
        temp += *mit2 * (*sp);
        mit2 += mat2.num_col();
        sp += stept;
      }
      *(mir++) = temp;
    }
  }
  return mret;
}

operator* [3/3]

G4ErrorMatrix operator* ( const G4ErrorSymMatrix &  m1, const G4ErrorSymMatrix &  m2  )

friend

Definition at line 372 of file G4ErrorSymMatrix.cc.

{
  G4ErrorMatrix mret(mat1.num_row(), mat1.num_row());
  CHK_DIM_1(mat1.num_col(), mat2.num_row(), *);
  G4int step1, stept1, step2, stept2;
  G4ErrorMatrixConstIter snp1, sp1, snp2, sp2;
  G4double temp;
  G4ErrorMatrixIter mr = mret.m.begin();
  for(step1 = 1, snp1 = mat1.m.begin(); step1 <= mat1.num_row();
      snp1 += step1++)
  {
    for(step2 = 1, snp2 = mat2.m.begin(); step2 <= mat2.num_row();)
    {
      sp1 = snp1;
      sp2 = snp2;
      snp2 += step2;
      temp = 0;
      if(step1 < step2)
      {
        while(sp1 < snp1 + step1)  // Loop checking, 06.08.2015, G.Cosmo
        {
          temp += (*(sp1++)) * (*(sp2++));
        }
        sp1 += step1 - 1;
        for(stept1 = step1 + 1; stept1 != step2 + 1; sp1 += stept1++)
        {
          temp += (*sp1) * (*(sp2++));
        }
        sp2 += step2 - 1;
        for(stept2 = ++step2; stept2 <= mat2.num_row();
            sp1 += stept1++, sp2 += stept2++)
        {
          temp += (*sp1) * (*sp2);
        }
      }
      else
      {
        while(sp2 < snp2)  // Loop checking, 06.08.2015, G.Cosmo
        {
          temp += (*(sp1++)) * (*(sp2++));
        }
        sp2 += step2 - 1;
        for(stept2 = ++step2; stept2 != step1 + 1; sp2 += stept2++)
        {
          temp += (*(sp1++)) * (*sp2);
        }
        sp1 += step1 - 1;
        for(stept1 = step1 + 1; stept1 <= mat1.num_row();
            sp1 += stept1++, sp2 += stept2++)
        {
          temp += (*sp1) * (*sp2);
        }
      }
      *(mr++) = temp;
    }
  }
  return mret;
}

operator+

G4ErrorSymMatrix operator+ ( const G4ErrorSymMatrix &  m1, const G4ErrorSymMatrix &  m2  )

friend

Definition at line 238 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(mat1.nrow);
  CHK_DIM_1(mat1.nrow, mat2.nrow, +);
  SIMPLE_TOP(+)
  return mret;
}

operator-

G4ErrorSymMatrix operator- ( const G4ErrorSymMatrix &  m1, const G4ErrorSymMatrix &  m2  )

friend

Definition at line 267 of file G4ErrorSymMatrix.cc.

{
  G4ErrorSymMatrix mret(mat1.num_row());
  CHK_DIM_1(mat1.num_row(), mat2.num_row(), -);
  SIMPLE_TOP(-)
  return mret;
}

tridiagonal

void tridiagonal ( G4ErrorSymMatrix *  a, G4ErrorMatrix *  hsm  )

friend

Field Documentation

adjustment5x5

G4ThreadLocal G4double G4ErrorSymMatrix::adjustment5x5 = 0.0

staticprivate

Definition at line 225 of file G4ErrorSymMatrix.hh.

Referenced by invert5().

adjustment6x6

G4ThreadLocal G4double G4ErrorSymMatrix::adjustment6x6 = 0.0

staticprivate

Definition at line 230 of file G4ErrorSymMatrix.hh.

Referenced by invert6().

CHOLESKY_CREEP_5x5

const G4double G4ErrorSymMatrix::CHOLESKY_CREEP_5x5 = .005

staticprivate

Definition at line 227 of file G4ErrorSymMatrix.hh.

Referenced by invert5().

CHOLESKY_CREEP_6x6

const G4double G4ErrorSymMatrix::CHOLESKY_CREEP_6x6 = .002

staticprivate

Definition at line 232 of file G4ErrorSymMatrix.hh.

Referenced by invert6().

CHOLESKY_THRESHOLD_5x5

const G4double G4ErrorSymMatrix::CHOLESKY_THRESHOLD_5x5 = .5

staticprivate

Definition at line 226 of file G4ErrorSymMatrix.hh.

Referenced by invert5().

CHOLESKY_THRESHOLD_6x6

const G4double G4ErrorSymMatrix::CHOLESKY_THRESHOLD_6x6 = .2

staticprivate

Definition at line 231 of file G4ErrorSymMatrix.hh.

Referenced by invert6().

m

std::vector<G4double> G4ErrorSymMatrix::m

private

Definition at line 219 of file G4ErrorSymMatrix.hh.

Referenced by apply(), assign(), G4ErrorMatrix::G4ErrorMatrix(), G4ErrorSymMatrix(), invert(), invert4(), invertBunchKaufman(), invertCholesky5(), invertCholesky6(), invertHaywood5(), invertHaywood6(), G4ErrorMatrix::operator+=(), operator-(), G4ErrorMatrix::operator-=(), G4ErrorMatrix::operator=(), operator=(), similarity(), similarityT(), sub(), and trace().

nrow

G4int G4ErrorSymMatrix::nrow

private

Definition at line 221 of file G4ErrorSymMatrix.hh.

Referenced by assign(), determinant(), G4ErrorSymMatrix(), invert(), invertBunchKaufman(), operator-(), G4ErrorMatrix::operator=(), operator=(), and trace().

posDefFraction5x5

G4ThreadLocal G4double G4ErrorSymMatrix::posDefFraction5x5 = 1.0

staticprivate

Definition at line 224 of file G4ErrorSymMatrix.hh.

Referenced by invert5().

posDefFraction6x6

G4ThreadLocal G4double G4ErrorSymMatrix::posDefFraction6x6 = 1.0

staticprivate

Definition at line 229 of file G4ErrorSymMatrix.hh.

Referenced by invert6().

size

G4int G4ErrorSymMatrix::size

private

Definition at line 222 of file G4ErrorSymMatrix.hh.

Referenced by assign(), G4ErrorSymMatrix(), and operator=().

---

The documentation for this class was generated from the following files:

• source/error_propagation/include/G4ErrorSymMatrix.hh
• source/error_propagation/src/G4ErrorSymMatrix.cc