foam-extend4.1-coherent-io/applications/solvers/equationReaderDemo/initializeSourceFields.H

    // Initializing the scalarFields
    forAll(sfA, cellIndex)
    {
        scalar cellValue(scalar(cellIndex) / 100000);
        sfA[cellIndex] = 10 + cellValue;
        sfB[cellIndex] = 20 + cellValue;
        sfC[cellIndex] = 30 + cellValue;
    }

    // Initializing the volScalarFields
    label globalI(0);
    forAll(vsfA.internalField(), cellIndex)
    {
        scalar cellValue(scalar(globalI) / 100000);
        vsfA.internalField()[cellIndex] = 40 + cellValue;
        vsfB.internalField()[cellIndex] = 50 + cellValue;
        vsfC.internalField()[cellIndex] = 60 + cellValue;
        globalI++;
    }
    forAll(vsfA.boundaryField(), geoIndex)
    {
        forAll(vsfA.boundaryField()[geoIndex], cellIndex)
        {
            scalar cellValue(scalar(globalI) / 100000);
            vsfA.boundaryField()[geoIndex][cellIndex] = 40 + cellValue;
            vsfB.boundaryField()[geoIndex][cellIndex] = 50 + cellValue;
            vsfC.boundaryField()[geoIndex][cellIndex] = 60 + cellValue;
            globalI++;
        }
    }

    // Initializing the vectorFields
    forAll(vfA, cellIndex)
    {
        scalar cellValue(scalar(cellIndex) / 100000);
        vfA[cellIndex] = vector
        (
            1000 + cellValue,
            1000 + cellValue,
            1000 + cellValue
        );
        vfB[cellIndex] = vector
        (
            2000 + cellValue,
            -2000 - cellValue,
            2000 + cellValue
        );
        vfC[cellIndex] = vector
        (
            3000 + cellValue,
            3000 + cellValue,
            -3000 - cellValue
        );
    }

    // Initializing the volVectorFields
    globalI = 0;
    forAll(vvfA.internalField(), cellIndex)
    {
        scalar cellValue(scalar(globalI) / 100000);
        vvfA.internalField()[cellIndex] = vector
        (
            4000 + cellValue,
            4000 + cellValue,
            4000 + cellValue
        );
        vvfB.internalField()[cellIndex] = vector
        (
            5000 + cellValue,
            -5000 - cellValue,
            5000 + cellValue
        );
        vvfC.internalField()[cellIndex] = vector
        (
            6000 + cellValue,
            6000 + cellValue,
            -6000 - cellValue
        );
        globalI++;
    }
    forAll(vvfA.boundaryField(), geoIndex)
    {
        forAll(vvfA.boundaryField()[geoIndex], cellIndex)
        {
            scalar cellValue(scalar(globalI) / 100000);
            vvfA.boundaryField()[geoIndex][cellIndex] = vector
            (
                4000 + cellValue,
                4000 + cellValue,
                4000 + cellValue
            );
            vvfB.boundaryField()[geoIndex][cellIndex] = vector
            (
                5000 + cellValue,
                -5000 - cellValue,
                5000 + cellValue
            );
            vvfC.boundaryField()[geoIndex][cellIndex] = vector
            (
                6000 + cellValue,
                6000 + cellValue,
                -6000 - cellValue
            );
            globalI++;
        }
    }

    // Initializing the tensorFields
    forAll(tfA, cellIndex)
    {
        scalar cellValue(scalar(cellIndex) / 100000);
        scalar tA(cellValue + 100000);
        scalar tB(cellValue + 200000);
        scalar tC(cellValue + 300000);
        tfA[cellIndex] = tensor
        (
            tA, -tA, tA,
            -tA, tA, -tA,
            tA, -tA, tA
        );
        tfB[cellIndex] = tensor
        (
            tB, tB, -tB,
            tB, -tB, tB,
            -tB, tB, -tB
        );
        tfC[cellIndex] = tensor
        (
            tC, tC, -tC,
            -tC, tC, tC,
            -tC, -tC, tC
        );
    }

    // Initializing the volTectorFields
    globalI = 0;
    forAll(vtfA.internalField(), cellIndex)
    {
        scalar cellValue(scalar(globalI) / 100000);
        scalar tA(cellValue + 400000);
        scalar tB(cellValue + 500000);
        scalar tC(cellValue + 600000);
        vtfA.internalField()[cellIndex] = tensor
        (
            tA, -tA, tA,
            -tA, tA, -tA,
            tA, -tA, tA
        );
        vtfB.internalField()[cellIndex] = tensor
        (
            tB, tB, -tB,
            tB, -tB, tB,
            -tB, tB, -tB
        );
        vtfC.internalField()[cellIndex] = tensor
        (
            tC, tC, -tC,
            -tC, tC, tC,
            -tC, -tC, tC
        );
        globalI++;
    }
    forAll(vtfA.boundaryField(), geoIndex)
    {
        forAll(vtfA.boundaryField()[geoIndex], cellIndex)
        {
            scalar cellValue(scalar(globalI) / 100000);
            scalar tA(cellValue + 400000);
            scalar tB(cellValue + 500000);
            scalar tC(cellValue + 600000);
            vtfA.boundaryField()[geoIndex][cellIndex] = tensor
            (
                tA, -tA, tA,
                -tA, tA, -tA,
                tA, -tA, tA
            );
            vtfB.boundaryField()[geoIndex][cellIndex] = tensor
            (
                tB, tB, -tB,
                tB, -tB, tB,
                -tB, tB, -tB
            );
            vtfC.boundaryField()[geoIndex][cellIndex] = tensor
            (
                tC, tC, -tC,
                -tC, tC, tC,
                -tC, -tC, tC
            );
            globalI++;
        }
    }
Imported new equationReader 2013-08-29 20:03:52 +00:00			`// Initializing the scalarFields`
			`forAll(sfA, cellIndex)`
			`{`
			`scalar cellValue(scalar(cellIndex) / 100000);`
			`sfA[cellIndex] = 10 + cellValue;`
			`sfB[cellIndex] = 20 + cellValue;`
			`sfC[cellIndex] = 30 + cellValue;`
			`}`

			`// Initializing the volScalarFields`
			`label globalI(0);`
			`forAll(vsfA.internalField(), cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`vsfA.internalField()[cellIndex] = 40 + cellValue;`
			`vsfB.internalField()[cellIndex] = 50 + cellValue;`
			`vsfC.internalField()[cellIndex] = 60 + cellValue;`
			`globalI++;`
			`}`
			`forAll(vsfA.boundaryField(), geoIndex)`
			`{`
			`forAll(vsfA.boundaryField()[geoIndex], cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`vsfA.boundaryField()[geoIndex][cellIndex] = 40 + cellValue;`
			`vsfB.boundaryField()[geoIndex][cellIndex] = 50 + cellValue;`
			`vsfC.boundaryField()[geoIndex][cellIndex] = 60 + cellValue;`
			`globalI++;`
			`}`
			`}`

			`// Initializing the vectorFields`
			`forAll(vfA, cellIndex)`
			`{`
			`scalar cellValue(scalar(cellIndex) / 100000);`
			`vfA[cellIndex] = vector`
			`(`
			`1000 + cellValue,`
			`1000 + cellValue,`
			`1000 + cellValue`
			`);`
			`vfB[cellIndex] = vector`
			`(`
			`2000 + cellValue,`
			`-2000 - cellValue,`
			`2000 + cellValue`
			`);`
			`vfC[cellIndex] = vector`
			`(`
			`3000 + cellValue,`
			`3000 + cellValue,`
			`-3000 - cellValue`
			`);`
			`}`

			`// Initializing the volVectorFields`
			`globalI = 0;`
			`forAll(vvfA.internalField(), cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`vvfA.internalField()[cellIndex] = vector`
			`(`
			`4000 + cellValue,`
			`4000 + cellValue,`
			`4000 + cellValue`
			`);`
			`vvfB.internalField()[cellIndex] = vector`
			`(`
			`5000 + cellValue,`
			`-5000 - cellValue,`
			`5000 + cellValue`
			`);`
			`vvfC.internalField()[cellIndex] = vector`
			`(`
			`6000 + cellValue,`
			`6000 + cellValue,`
			`-6000 - cellValue`
			`);`
			`globalI++;`
			`}`
			`forAll(vvfA.boundaryField(), geoIndex)`
			`{`
			`forAll(vvfA.boundaryField()[geoIndex], cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`vvfA.boundaryField()[geoIndex][cellIndex] = vector`
			`(`
			`4000 + cellValue,`
			`4000 + cellValue,`
			`4000 + cellValue`
			`);`
			`vvfB.boundaryField()[geoIndex][cellIndex] = vector`
			`(`
			`5000 + cellValue,`
			`-5000 - cellValue,`
			`5000 + cellValue`
			`);`
			`vvfC.boundaryField()[geoIndex][cellIndex] = vector`
			`(`
			`6000 + cellValue,`
			`6000 + cellValue,`
			`-6000 - cellValue`
			`);`
			`globalI++;`
			`}`
			`}`

			`// Initializing the tensorFields`
			`forAll(tfA, cellIndex)`
			`{`
			`scalar cellValue(scalar(cellIndex) / 100000);`
			`scalar tA(cellValue + 100000);`
			`scalar tB(cellValue + 200000);`
			`scalar tC(cellValue + 300000);`
			`tfA[cellIndex] = tensor`
			`(`
			`tA, -tA, tA,`
			`-tA, tA, -tA,`
			`tA, -tA, tA`
			`);`
			`tfB[cellIndex] = tensor`
			`(`
			`tB, tB, -tB,`
			`tB, -tB, tB,`
			`-tB, tB, -tB`
			`);`
			`tfC[cellIndex] = tensor`
			`(`
			`tC, tC, -tC,`
			`-tC, tC, tC,`
			`-tC, -tC, tC`
			`);`
			`}`

			`// Initializing the volTectorFields`
			`globalI = 0;`
			`forAll(vtfA.internalField(), cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`scalar tA(cellValue + 400000);`
			`scalar tB(cellValue + 500000);`
			`scalar tC(cellValue + 600000);`
			`vtfA.internalField()[cellIndex] = tensor`
			`(`
			`tA, -tA, tA,`
			`-tA, tA, -tA,`
			`tA, -tA, tA`
			`);`
			`vtfB.internalField()[cellIndex] = tensor`
			`(`
			`tB, tB, -tB,`
			`tB, -tB, tB,`
			`-tB, tB, -tB`
			`);`
			`vtfC.internalField()[cellIndex] = tensor`
			`(`
			`tC, tC, -tC,`
			`-tC, tC, tC,`
			`-tC, -tC, tC`
			`);`
			`globalI++;`
			`}`
			`forAll(vtfA.boundaryField(), geoIndex)`
			`{`
			`forAll(vtfA.boundaryField()[geoIndex], cellIndex)`
			`{`
			`scalar cellValue(scalar(globalI) / 100000);`
			`scalar tA(cellValue + 400000);`
			`scalar tB(cellValue + 500000);`
			`scalar tC(cellValue + 600000);`
			`vtfA.boundaryField()[geoIndex][cellIndex] = tensor`
			`(`
			`tA, -tA, tA,`
			`-tA, tA, -tA,`
			`tA, -tA, tA`
			`);`
			`vtfB.boundaryField()[geoIndex][cellIndex] = tensor`
			`(`
			`tB, tB, -tB,`
			`tB, -tB, tB,`
			`-tB, tB, -tB`
			`);`
			`vtfC.boundaryField()[geoIndex][cellIndex] = tensor`
			`(`
			`tC, tC, -tC,`
			`-tC, tC, tC,`
			`-tC, -tC, tC`
			`);`
			`globalI++;`
			`}`
			`}`