module mod_matrix_manager use mod_global_variables, only: dp, ir, ic use mod_equilibrium_params, only: k2, k3 use mod_logging, only: logger, str use mod_settings, only: settings_t use mod_background, only: background_t use mod_physics, only: physics_t use mod_grid, only: grid_t use mod_matrix_elements, only: matrix_elements_t use mod_state_vector, only: sv_rho1, sv_v1, sv_v2, sv_v3, sv_T1, sv_a1, sv_a2, sv_a3 implicit none interface module subroutine add_bmatrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_bmatrix_terms module subroutine add_regular_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_regular_matrix_terms module subroutine add_flow_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_flow_matrix_terms module subroutine add_resistive_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_resistive_matrix_terms module subroutine add_heatloss_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_heatloss_matrix_terms module subroutine add_conduction_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_conduction_matrix_terms module subroutine add_viscosity_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_viscosity_matrix_terms module subroutine add_hall_matrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_hall_matrix_terms module subroutine add_hall_bmatrix_terms( & x, elements, settings, grid, background, physics & ) real(dp), intent(in) :: x type(matrix_elements_t), intent(inout) :: elements type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics end subroutine add_hall_bmatrix_terms end interface private public :: build_matrices contains subroutine build_matrices(matrix_B, matrix_A, settings, grid, background, physics) use mod_global_variables, only: n_gauss, gaussian_weights use mod_matrix_structure, only: matrix_t use mod_build_quadblock, only: add_to_quadblock use mod_boundary_manager, only: apply_boundary_conditions use mod_matrix_elements, only: new_matrix_elements !> the B-matrix type(matrix_t), intent(inout) :: matrix_B !> the A-matrix type(matrix_t), intent(inout) :: matrix_A !> the settings object type(settings_t), intent(in) :: settings type(grid_t), intent(in) :: grid type(background_t), intent(in) :: background type(physics_t), intent(in) :: physics !> quadblock for the A-matrix complex(dp), allocatable :: quadblock_A(:, :) !> quadblock for the B-matrix complex(dp), allocatable :: quadblock_B(:, :) !> left side of current interval real(dp) :: x_left !> right side of current interval real(dp) :: x_right !> current position in the Gaussian grid real(dp) :: x_gauss !> current weight real(dp) :: weight type(matrix_elements_t) :: elements_A, elements_B integer :: i, j, k, l, idx1, idx2 integer :: quadblock_idx, gauss_idx, dim_quadblock logical :: has_flow, has_resistivity, has_cooling, has_heating, has_conduction logical :: has_viscosity, has_hall has_flow = settings%physics%flow%is_enabled() has_resistivity = settings%physics%resistivity%is_enabled() has_cooling = settings%physics%cooling%is_enabled() has_heating = settings%physics%heating%is_enabled() has_conduction = settings%physics%conduction%is_enabled() has_viscosity = settings%physics%viscosity%is_enabled() has_hall = settings%physics%hall%is_enabled() dim_quadblock = settings%dims%get_dim_quadblock() allocate(quadblock_A(dim_quadblock, dim_quadblock)) allocate(quadblock_B, mold=quadblock_A) ! used to shift the quadblock along the main diagonal quadblock_idx = 0 do i = 1, settings%grid%get_gridpts() - 1 ! reset quadblocks quadblock_A = (0.0d0, 0.0d0) quadblock_B = (0.0d0, 0.0d0) ! get interval boundaries x_left = grid%base_grid(i) x_right = grid%base_grid(i + 1) ! loop over Gaussian points to calculate integral do j = 1, n_gauss ! current grid index of Gaussian grid gauss_idx = (i - 1) * n_gauss + j x_gauss = grid%gaussian_grid(gauss_idx) weight = gaussian_weights(j) elements_A = new_matrix_elements(settings%state_vector) elements_B = new_matrix_elements(settings%state_vector) ! get matrix elements call add_bmatrix_terms( & x_gauss, elements_B, settings, grid, background, physics & ) call add_regular_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_flow) call add_flow_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_resistivity) call add_resistive_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_cooling .or. has_heating) call add_heatloss_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_conduction) call add_conduction_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_viscosity) call add_viscosity_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) if (has_hall) then call add_hall_matrix_terms( & x_gauss, elements_A, settings, grid, background, physics & ) call add_hall_bmatrix_terms( & x_gauss, elements_B, settings, grid, background, physics & ) end if call add_to_quadblock( & quadblock_A, elements_A, x_gauss, x_left, x_right, weight, settings%dims & ) call elements_A%delete() call add_to_quadblock( & quadblock_B, elements_B, x_gauss, x_left, x_right, weight, settings%dims & ) call elements_B%delete() end do ! dx from integral quadblock_B = quadblock_B * (x_right - x_left) quadblock_A = quadblock_A * (x_right - x_left) ! fill matrices !> @note The quadblock is shifted along the main (tri)diagonal. !! We add `dim_subblock` instead of `dim_quadblock` to the indices, !! due to overlapping of the bottom-right part of the quadblock with the !! top-left part of the next grid interval. @endnote do k = 1, dim_quadblock do l = 1, dim_quadblock idx1 = k + quadblock_idx idx2 = l + quadblock_idx call matrix_B%add_element(row=idx1, column=idx2, element=quadblock_B(k, l)) call matrix_A%add_element(row=idx1, column=idx2, element=quadblock_A(k, l)) end do end do quadblock_idx = quadblock_idx + settings%dims%get_dim_subblock() end do deallocate(quadblock_A, quadblock_B) call apply_boundary_conditions( & matrix_A, matrix_B, settings, grid, background, physics & ) end subroutine build_matrices end module mod_matrix_manager