c--------------------------------------------------------------------- c--------------------------------------------------------------------- subroutine blts ( ldmx, ldmy, ldmz, > nx, ny, nz, k, > omega, > v, tv, > ldz, ldy, ldx, d, > ist, iend, jst, jend, > nx0, ny0 ) c--------------------------------------------------------------------- c--------------------------------------------------------------------- c--------------------------------------------------------------------- c c compute the regular-sparse, block lower triangular solution: c c v <-- ( L-inv ) * v c c--------------------------------------------------------------------- implicit none c--------------------------------------------------------------------- c input parameters c--------------------------------------------------------------------- integer ldmx, ldmy, ldmz integer nx, ny, nz integer k double precision omega c--------------------------------------------------------------------- c To improve cache performance, second two dimensions padded by 1 c for even number sizes only. Only needed in v. c--------------------------------------------------------------------- double precision v( 5, ldmx/2*2+1, ldmy/2*2+1, *), > tv( 5, ldmx/2*2+1, ldmy), > ldz( 5, 5, ldmx/2*2+1, ldmy), > ldy( 5, 5, ldmx/2*2+1, ldmy), > ldx( 5, 5, ldmx/2*2+1, ldmy), > d( 5, 5, ldmx/2*2+1, ldmy) integer ist, iend integer jst, jend integer nx0, ny0 c--------------------------------------------------------------------- c local variables c--------------------------------------------------------------------- integer i, j, m double precision tmp, tmp1 double precision tmat(5,5) do j = jst, jend do i = ist, iend do m = 1, 5 tv( m, i, j ) = v( m, i, j, k ) > - omega * ( ldz( m, 1, i, j ) * v( 1, i, j, k-1 ) > + ldz( m, 2, i, j ) * v( 2, i, j, k-1 ) > + ldz( m, 3, i, j ) * v( 3, i, j, k-1 ) > + ldz( m, 4, i, j ) * v( 4, i, j, k-1 ) > + ldz( m, 5, i, j ) * v( 5, i, j, k-1 ) ) end do end do end do do j=jst,jend do i = ist, iend do m = 1, 5 tv( m, i, j ) = tv( m, i, j ) > - omega * ( ldy( m, 1, i, j ) * v( 1, i, j-1, k ) > + ldx( m, 1, i, j ) * v( 1, i-1, j, k ) > + ldy( m, 2, i, j ) * v( 2, i, j-1, k ) > + ldx( m, 2, i, j ) * v( 2, i-1, j, k ) > + ldy( m, 3, i, j ) * v( 3, i, j-1, k ) > + ldx( m, 3, i, j ) * v( 3, i-1, j, k ) > + ldy( m, 4, i, j ) * v( 4, i, j-1, k ) > + ldx( m, 4, i, j ) * v( 4, i-1, j, k ) > + ldy( m, 5, i, j ) * v( 5, i, j-1, k ) > + ldx( m, 5, i, j ) * v( 5, i-1, j, k ) ) end do c--------------------------------------------------------------------- c diagonal block inversion c c forward elimination c--------------------------------------------------------------------- do m = 1, 5 tmat( m, 1 ) = d( m, 1, i, j ) tmat( m, 2 ) = d( m, 2, i, j ) tmat( m, 3 ) = d( m, 3, i, j ) tmat( m, 4 ) = d( m, 4, i, j ) tmat( m, 5 ) = d( m, 5, i, j ) end do tmp1 = 1.0d+00 / tmat( 1, 1 ) tmp = tmp1 * tmat( 2, 1 ) tmat( 2, 2 ) = tmat( 2, 2 ) > - tmp * tmat( 1, 2 ) tmat( 2, 3 ) = tmat( 2, 3 ) > - tmp * tmat( 1, 3 ) tmat( 2, 4 ) = tmat( 2, 4 ) > - tmp * tmat( 1, 4 ) tmat( 2, 5 ) = tmat( 2, 5 ) > - tmp * tmat( 1, 5 ) tv( 2, i, j ) = tv( 2, i, j ) > - tv( 1, i, j ) * tmp tmp = tmp1 * tmat( 3, 1 ) tmat( 3, 2 ) = tmat( 3, 2 ) > - tmp * tmat( 1, 2 ) tmat( 3, 3 ) = tmat( 3, 3 ) > - tmp * tmat( 1, 3 ) tmat( 3, 4 ) = tmat( 3, 4 ) > - tmp * tmat( 1, 4 ) tmat( 3, 5 ) = tmat( 3, 5 ) > - tmp * tmat( 1, 5 ) tv( 3, i, j ) = tv( 3, i, j ) > - tv( 1, i, j ) * tmp tmp = tmp1 * tmat( 4, 1 ) tmat( 4, 2 ) = tmat( 4, 2 ) > - tmp * tmat( 1, 2 ) tmat( 4, 3 ) = tmat( 4, 3 ) > - tmp * tmat( 1, 3 ) tmat( 4, 4 ) = tmat( 4, 4 ) > - tmp * tmat( 1, 4 ) tmat( 4, 5 ) = tmat( 4, 5 ) > - tmp * tmat( 1, 5 ) tv( 4, i, j ) = tv( 4, i, j ) > - tv( 1, i, j ) * tmp tmp = tmp1 * tmat( 5, 1 ) tmat( 5, 2 ) = tmat( 5, 2 ) > - tmp * tmat( 1, 2 ) tmat( 5, 3 ) = tmat( 5, 3 ) > - tmp * tmat( 1, 3 ) tmat( 5, 4 ) = tmat( 5, 4 ) > - tmp * tmat( 1, 4 ) tmat( 5, 5 ) = tmat( 5, 5 ) > - tmp * tmat( 1, 5 ) tv( 5, i, j ) = tv( 5, i, j ) > - tv( 1, i, j ) * tmp tmp1 = 1.0d+00 / tmat( 2, 2 ) tmp = tmp1 * tmat( 3, 2 ) tmat( 3, 3 ) = tmat( 3, 3 ) > - tmp * tmat( 2, 3 ) tmat( 3, 4 ) = tmat( 3, 4 ) > - tmp * tmat( 2, 4 ) tmat( 3, 5 ) = tmat( 3, 5 ) > - tmp * tmat( 2, 5 ) tv( 3, i, j ) = tv( 3, i, j ) > - tv( 2, i, j ) * tmp tmp = tmp1 * tmat( 4, 2 ) tmat( 4, 3 ) = tmat( 4, 3 ) > - tmp * tmat( 2, 3 ) tmat( 4, 4 ) = tmat( 4, 4 ) > - tmp * tmat( 2, 4 ) tmat( 4, 5 ) = tmat( 4, 5 ) > - tmp * tmat( 2, 5 ) tv( 4, i, j ) = tv( 4, i, j ) > - tv( 2, i, j ) * tmp tmp = tmp1 * tmat( 5, 2 ) tmat( 5, 3 ) = tmat( 5, 3 ) > - tmp * tmat( 2, 3 ) tmat( 5, 4 ) = tmat( 5, 4 ) > - tmp * tmat( 2, 4 ) tmat( 5, 5 ) = tmat( 5, 5 ) > - tmp * tmat( 2, 5 ) tv( 5, i, j ) = tv( 5, i, j ) > - tv( 2, i, j ) * tmp tmp1 = 1.0d+00 / tmat( 3, 3 ) tmp = tmp1 * tmat( 4, 3 ) tmat( 4, 4 ) = tmat( 4, 4 ) > - tmp * tmat( 3, 4 ) tmat( 4, 5 ) = tmat( 4, 5 ) > - tmp * tmat( 3, 5 ) tv( 4, i, j ) = tv( 4, i, j ) > - tv( 3, i, j ) * tmp tmp = tmp1 * tmat( 5, 3 ) tmat( 5, 4 ) = tmat( 5, 4 ) > - tmp * tmat( 3, 4 ) tmat( 5, 5 ) = tmat( 5, 5 ) > - tmp * tmat( 3, 5 ) tv( 5, i, j ) = tv( 5, i, j ) > - tv( 3, i, j ) * tmp tmp1 = 1.0d+00 / tmat( 4, 4 ) tmp = tmp1 * tmat( 5, 4 ) tmat( 5, 5 ) = tmat( 5, 5 ) > - tmp * tmat( 4, 5 ) tv( 5, i, j ) = tv( 5, i, j ) > - tv( 4, i, j ) * tmp c--------------------------------------------------------------------- c back substitution c--------------------------------------------------------------------- v( 5, i, j, k ) = tv( 5, i, j ) > / tmat( 5, 5 ) tv( 4, i, j ) = tv( 4, i, j ) > - tmat( 4, 5 ) * v( 5, i, j, k ) v( 4, i, j, k ) = tv( 4, i, j ) > / tmat( 4, 4 ) tv( 3, i, j ) = tv( 3, i, j ) > - tmat( 3, 4 ) * v( 4, i, j, k ) > - tmat( 3, 5 ) * v( 5, i, j, k ) v( 3, i, j, k ) = tv( 3, i, j ) > / tmat( 3, 3 ) tv( 2, i, j ) = tv( 2, i, j ) > - tmat( 2, 3 ) * v( 3, i, j, k ) > - tmat( 2, 4 ) * v( 4, i, j, k ) > - tmat( 2, 5 ) * v( 5, i, j, k ) v( 2, i, j, k ) = tv( 2, i, j ) > / tmat( 2, 2 ) tv( 1, i, j ) = tv( 1, i, j ) > - tmat( 1, 2 ) * v( 2, i, j, k ) > - tmat( 1, 3 ) * v( 3, i, j, k ) > - tmat( 1, 4 ) * v( 4, i, j, k ) > - tmat( 1, 5 ) * v( 5, i, j, k ) v( 1, i, j, k ) = tv( 1, i, j ) > / tmat( 1, 1 ) enddo enddo return end