示例#1
0
void Foam::DILUPreconditioner::calcReciprocalD
(
    scalarField& rD,
    const lduMatrix& matrix
)
{
    scalar* __restrict__ rDPtr = rD.begin();

    const label* const __restrict__ uPtr =
        matrix.lduAddr().upperAddr().begin();
    const label* const __restrict__ lPtr =
        matrix.lduAddr().lowerAddr().begin();

    const scalar* const __restrict__ upperPtr = matrix.upper().begin();
    const scalar* const __restrict__ lowerPtr = matrix.lower().begin();

    register label nFaces = matrix.upper().size();
    for (register label face=0; face<nFaces; face++)
    {
        rDPtr[uPtr[face]] -= upperPtr[face]*lowerPtr[face]/rDPtr[lPtr[face]];
    }


    // Calculate the reciprocal of the preconditioned diagonal
    register label nCells = rD.size();

    for (register label cell=0; cell<nCells; cell++)
    {
        rDPtr[cell] = 1.0/rDPtr[cell];
    }
}
示例#2
0
// add by NUDT Exercise Group-RXG: begin
Foam::iluSmoother::iluSmoother
(
    const word& fieldName,
    const lduMatrix& matrix,
    const FieldField<Field, scalar>& coupleBouCoeffs,
    const FieldField<Field, scalar>& coupleIntCoeffs,
    const lduInterfaceFieldPtrsList& interfaces
)
:
    lduSmoother
    (
        fieldName,
        matrix,
        coupleBouCoeffs,
        coupleIntCoeffs,
        interfaces
    ),
    precon_
    (
        matrix,
        coupleBouCoeffs,
        coupleIntCoeffs,
        interfaces
    ),
    xCorr_(matrix.lduAddr().size()),
    residual_(matrix.lduAddr().size())
{}
void Foam::DILUPreconditioner::calcReciprocalD
(
    scalarField& rD,
    const lduMatrix& matrix
)
{
    scalar* __restrict__ rDPtr = rD.begin();

    const label* const __restrict__ uPtr = matrix.lduAddr().upperAddr().begin();
    const label* const __restrict__ lPtr = matrix.lduAddr().lowerAddr().begin();

    const scalar* const __restrict__ upperPtr = matrix.upper().begin();
    const scalar* const __restrict__ lowerPtr = matrix.lower().begin();

    label nFaces = matrix.upper().size();
    for (label face=0; face<nFaces; face++)
    {
        Pout<< "Adapting diagonal for cell:" << uPtr[face]
            << " contributions from cell " << lPtr[face]
            << " from " << rDPtr[uPtr[face]];

        rDPtr[uPtr[face]] -= upperPtr[face]*lowerPtr[face]/rDPtr[lPtr[face]];

        Pout<< " to " << rDPtr[uPtr[face]] << endl;
    }


    // Calculate the reciprocal of the preconditioned diagonal
    label nCells = rD.size();

    for (label cell=0; cell<nCells; cell++)
    {
        rDPtr[cell] = 1.0/rDPtr[cell];
    }
}
Foam::symGaussSeidelPrecon::symGaussSeidelPrecon
(
    const lduMatrix& matrix,
    const FieldField<Field, scalar>& coupleBouCoeffs,
    const FieldField<Field, scalar>& coupleIntCoeffs,
    const lduInterfaceFieldPtrsList& interfaces,
    const dictionary& dict
)
:
    lduPreconditioner
    (
        matrix,
        coupleBouCoeffs,
        coupleIntCoeffs,
        interfaces
    ),
    mBouCoeffs_(coupleBouCoeffs.size()),
    bPrime_(matrix.lduAddr().size())
{
    forAll(mBouCoeffs_, i)
    {
        if (interfaces_.set(i))
        {
            mBouCoeffs_.set(i, -coupleBouCoeffs_[i]);
        }
    }
}
void Foam::coupledGaussSeidelPrecon::reverseSweepTranspose
(
    const lduMatrix& matrix,
    scalarField& x,
    scalarField& bPrime
) const
{
    const scalarField& diag = matrix.diag();
    const scalarField& lower = matrix.lower();
    const scalarField& upper = matrix.upper();

    const labelList& upperAddr = matrix.lduAddr().upperAddr();
    const labelList& ownStartAddr = matrix.lduAddr().ownerStartAddr();

    const label nRows = x.size();
    label fStart, fEnd;

    for (register label rowI = nRows - 1; rowI >= 0; rowI--)
    {
        // lRow is equal to rowI
        scalar& curX = x[rowI];

        // Grab the accumulated neighbour side
        curX = bPrime[rowI];

        // Start and end of this row
        fStart = ownStartAddr[rowI];
        fEnd = ownStartAddr[rowI + 1];

        // Accumulate the owner product side
        for (register label curCoeff = fStart; curCoeff < fEnd; curCoeff++)
        {
            // Transpose multiplication.  HJ, 19/Jan/2009
            curX -= lower[curCoeff]*x[upperAddr[curCoeff]];
        }

        // Finish current x
        curX /= diag[rowI];

        // Distribute the neighbour side using current x
        for (register label curCoeff = fStart; curCoeff < fEnd; curCoeff++)
        {
            // Transpose multiplication.  HJ, 19/Jan/2009
            bPrime[upperAddr[curCoeff]] -= upper[curCoeff]*curX;
        }
    }
}
示例#6
0
Foam::amgPrecon::amgPrecon
(
    const lduMatrix& matrix,
    const FieldField<Field, scalar>& coupleBouCoeffs,
    const FieldField<Field, scalar>& coupleIntCoeffs,
    const lduInterfaceFieldPtrsList& interfaceFields,
    const dictionary& dict
)
:
    lduPreconditioner
    (
        matrix,
        coupleBouCoeffs,
        coupleIntCoeffs,
        interfaceFields
    ),
    cycle_(amgCycle::cycleNames_.read(dict.lookup("cycle"))),
    nPreSweeps_(readLabel(dict.lookup("nPreSweeps"))),
    nPostSweeps_(readLabel(dict.lookup("nPostSweeps"))),
    nMaxLevels_(readLabel(dict.lookup("nMaxLevels"))),
    scale_(dict.lookup("scale")),
    amgPtr_
    (
        new amgCycle
        (
            autoPtr<amgLevel>
            (
                new fineAmgLevel
                (
                    matrix,
                    coupleBouCoeffs,
                    coupleIntCoeffs,
                    interfaceFields,
                    dict,
                    dict.lookup("policy"),
                    readLabel(dict.lookup("groupSize")),
                    readLabel(dict.lookup("minCoarseEqns")),
                    dict.lookup("smoother")
                )
            )
        )
    ),
    xBuffer_(matrix.lduAddr().size())
{
    // Make coarse levels
    amgPtr_->makeCoarseLevels(nMaxLevels_);
}
Foam::symGaussSeidelPrecon::symGaussSeidelPrecon
(
    const lduMatrix& matrix,
    const FieldField<Field, scalar>& coupleBouCoeffs,
    const FieldField<Field, scalar>& coupleIntCoeffs,
    const lduInterfaceFieldPtrsList& interfaces
)
:
    lduPreconditioner
    (
        matrix,
        coupleBouCoeffs,
        coupleIntCoeffs,
        interfaces
    ),
    bPrime_(matrix.lduAddr().size())
{}
示例#8
0
Foam::procLduMatrix::procLduMatrix
(
    const lduMatrix& ldum,
    const FieldField<Field, scalar>& interfaceCoeffs,
    const lduInterfaceFieldPtrsList& interfaces
)
:
    upperAddr_(ldum.lduAddr().upperAddr()),
    lowerAddr_(ldum.lduAddr().lowerAddr()),
    diag_(ldum.diag()),
    upper_(ldum.upper()),
    lower_(ldum.lower())
{
    label nInterfaces = 0;

    forAll(interfaces, i)
    {
        if (interfaces.set(i))
        {
            nInterfaces++;
        }
    }

    interfaces_.setSize(nInterfaces);

    nInterfaces = 0;

    forAll(interfaces, i)
    {
        if (interfaces.set(i))
        {
            interfaces_.set
            (
                nInterfaces++,
                new procLduInterface
                (
                    interfaces[i],
                    interfaceCoeffs[i]
                )
            );
        }
    }

}
示例#9
0
void Foam::GaussSeidelSmoother::smooth
(
    const word& fieldName_,
    scalarField& psi,
    const lduMatrix& matrix_,
    const scalarField& source,
    const FieldField<Field, scalar>& interfaceBouCoeffs_,
    const lduInterfaceFieldPtrsList& interfaces_,
    const direction cmpt,
    const label nSweeps
)
{
    register scalar*  psiPtr = psi.begin();

    register const label nCells = psi.size();

    scalarField bPrime(nCells);
    register scalar*  bPrimePtr = bPrime.begin();

    register const scalar* const  diagPtr = matrix_.diag().begin();
    register const scalar* const  upperPtr =
        matrix_.upper().begin();
    register const scalar* const  lowerPtr =
        matrix_.lower().begin();

    register const label* const  uPtr =
        matrix_.lduAddr().upperAddr().begin();

    register const label* const  ownStartPtr =
        matrix_.lduAddr().ownerStartAddr().begin();


    // Parallel boundary initialisation.  The parallel boundary is treated
    // as an effective jacobi interface in the boundary.
    // Note: there is a change of sign in the coupled
    // interface update.  The reason for this is that the
    // internal coefficients are all located at the l.h.s. of
    // the matrix whereas the "implicit" coefficients on the
    // coupled boundaries are all created as if the
    // coefficient contribution is of a source-kind (i.e. they
    // have a sign as if they are on the r.h.s. of the matrix.
    // To compensate for this, it is necessary to turn the
    // sign of the contribution.

    FieldField<Field, scalar> mBouCoeffs(interfaceBouCoeffs_.size());

    forAll(mBouCoeffs, patchi)
    {
        if (interfaces_.set(patchi))
        {
            mBouCoeffs.set(patchi, -interfaceBouCoeffs_[patchi]);
        }
    }

    for (label sweep=0; sweep<nSweeps; sweep++)
    {
        bPrime = source;

        matrix_.initMatrixInterfaces
        (
            mBouCoeffs,
            interfaces_,
            psi,
            bPrime,
            cmpt
        );

        matrix_.updateMatrixInterfaces
        (
            mBouCoeffs,
            interfaces_,
            psi,
            bPrime,
            cmpt
        );

        register scalar curPsi;
        register label fStart;
        register label fEnd = ownStartPtr[0];

        for (register label cellI=0; cellI<nCells; cellI++)
        {
            // Start and end of this row
            fStart = fEnd;
            fEnd = ownStartPtr[cellI + 1];

            // Get the accumulated neighbour side
            curPsi = bPrimePtr[cellI];

            // Accumulate the owner product side
            for (register label curFace=fStart; curFace<fEnd; curFace++)
            {
                curPsi -= upperPtr[curFace]*psiPtr[uPtr[curFace]];
            }

            // Finish current psi
            curPsi /= diagPtr[cellI];

            // Distribute the neighbour side using current psi
            for (register label curFace=fStart; curFace<fEnd; curFace++)
            {
                bPrimePtr[uPtr[curFace]] -= lowerPtr[curFace]*curPsi;
            }

            psiPtr[cellI] = curPsi;
        }
    }
}
void Foam::symGaussSeidelSmoother::smooth
(
    const word& fieldName_,
    scalarField& psi,
    const lduMatrix& matrix_,
    const scalarField& source,
    const FieldField<Field, scalar>& interfaceBouCoeffs_,
    const lduInterfaceFieldPtrsList& interfaces_,
    const direction cmpt,
    const label nSweeps
)
{
    scalar* __restrict__ psiPtr = psi.begin();

    const label nCells = psi.size();

    scalarField bPrime(nCells);
    scalar* __restrict__ bPrimePtr = bPrime.begin();

    const scalar* const __restrict__ diagPtr = matrix_.diag().begin();
    const scalar* const __restrict__ upperPtr =
        matrix_.upper().begin();
    const scalar* const __restrict__ lowerPtr =
        matrix_.lower().begin();

    const label* const __restrict__ uPtr =
        matrix_.lduAddr().upperAddr().begin();

    const label* const __restrict__ ownStartPtr =
        matrix_.lduAddr().ownerStartAddr().begin();


    // Parallel boundary initialisation.  The parallel boundary is treated
    // as an effective jacobi interface in the boundary.
    // Note: there is a change of sign in the coupled
    // interface update.  The reason for this is that the
    // internal coefficients are all located at the l.h.s. of
    // the matrix whereas the "implicit" coefficients on the
    // coupled boundaries are all created as if the
    // coefficient contribution is of a source-kind (i.e. they
    // have a sign as if they are on the r.h.s. of the matrix.
    // To compensate for this, it is necessary to turn the
    // sign of the contribution.

    FieldField<Field, scalar>& mBouCoeffs =
        const_cast<FieldField<Field, scalar>&>
        (
            interfaceBouCoeffs_
        );

    forAll(mBouCoeffs, patchi)
    {
        if (interfaces_.set(patchi))
        {
            mBouCoeffs[patchi].negate();
        }
    }


    for (label sweep=0; sweep<nSweeps; sweep++)
    {
        bPrime = source;

        matrix_.initMatrixInterfaces
        (
            mBouCoeffs,
            interfaces_,
            psi,
            bPrime,
            cmpt
        );

        matrix_.updateMatrixInterfaces
        (
            mBouCoeffs,
            interfaces_,
            psi,
            bPrime,
            cmpt
        );

        scalar psii;
        label fStart;
        label fEnd = ownStartPtr[0];

        for (label celli=0; celli<nCells; celli++)
        {
            // Start and end of this row
            fStart = fEnd;
            fEnd = ownStartPtr[celli + 1];

            // Get the accumulated neighbour side
            psii = bPrimePtr[celli];

            // Accumulate the owner product side
            for (label facei=fStart; facei<fEnd; facei++)
            {
                psii -= upperPtr[facei]*psiPtr[uPtr[facei]];
            }

            // Finish current psi
            psii /= diagPtr[celli];

            // Distribute the neighbour side using current psi
            for (label facei=fStart; facei<fEnd; facei++)
            {
                bPrimePtr[uPtr[facei]] -= lowerPtr[facei]*psii;
            }

            psiPtr[celli] = psii;
        }

        fStart = ownStartPtr[nCells];

        for (label celli=nCells-1; celli>=0; celli--)
        {
            // Start and end of this row
            fEnd = fStart;
            fStart = ownStartPtr[celli];

            // Get the accumulated neighbour side
            psii = bPrimePtr[celli];

            // Accumulate the owner product side
            for (label facei=fStart; facei<fEnd; facei++)
            {
                psii -= upperPtr[facei]*psiPtr[uPtr[facei]];
            }

            // Finish psi for this cell
            psii /= diagPtr[celli];

            // Distribute the neighbour side using psi for this cell
            for (label facei=fStart; facei<fEnd; facei++)
            {
                bPrimePtr[uPtr[facei]] -= lowerPtr[facei]*psii;
            }

            psiPtr[celli] = psii;
        }
    }

    // Restore interfaceBouCoeffs_
    forAll(mBouCoeffs, patchi)
    {
        if (interfaces_.set(patchi))
        {
            mBouCoeffs[patchi].negate();
        }
    }
}