function [residuals,JJacobian] = linear_perfect_foresight_problem(y, dynamicjacobian, Y0, YT, ... exo_simul, params, steady_state, maximum_lag, T, ny, i_cols, ... i_cols_J1, i_cols_1, i_cols_T, i_cols_j, i_cols_0, i_cols_J0, jendo, jexog) % Computes the residuals and the Jacobian matrix for a linear perfect foresight problem over T periods. % % INPUTS % ... % % OUTPUTS % ... % % ALGORITHM % ... % % SPECIAL REQUIREMENTS % None. % Copyright © 2015-2020 Dynare Team % % This file is part of Dynare. % % Dynare is free software: you can redistribute it and/or modify % it under the terms of the GNU General Public License as published by % the Free Software Foundation, either version 3 of the License, or % (at your option) any later version. % % Dynare is distributed in the hope that it will be useful, % but WITHOUT ANY WARRANTY; without even the implied warranty of % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the % GNU General Public License for more details. % % You should have received a copy of the GNU General Public License % along with Dynare. If not, see . YY = [Y0; y; YT]; residuals = zeros(T*ny,1); z = zeros(columns(dynamicjacobian), 1); if nargout == 2 iJacobian = cell(T,1); end i_rows = 1:ny; i_cols_J = i_cols; offset = 0; for it = maximum_lag+(1:T) z(jendo) = YY(i_cols); z(jexog) = transpose(exo_simul(it,:)); residuals(i_rows) = dynamicjacobian*z; if nargout == 2 if T==1 && it==maximum_lag+1 [rows, cols, vals] = find(dynamicjacobian(:,i_cols_0)); if size(dynamicjacobian, 1) == 1 % find() will return row vectors in this case rows = rows'; cols = cols'; vals = vals'; end iJacobian{1} = [rows, i_cols_J0(cols), vals]; elseif it == maximum_lag+1 [rows,cols,vals] = find(dynamicjacobian(:,i_cols_1)); if size(dynamicjacobian, 1) == 1 % find() will return row vectors in this case rows = rows'; cols = cols'; vals = vals'; end iJacobian{1} = [offset+rows, i_cols_J1(cols), vals]; elseif it == maximum_lag+T [rows,cols,vals] = find(dynamicjacobian(:,i_cols_T)); if size(dynamicjacobian, 1) == 1 % find() will return row vectors in this case rows = rows'; cols = cols'; vals = vals'; end iJacobian{T} = [offset+rows, i_cols_J(i_cols_T(cols)), vals]; else [rows,cols,vals] = find(dynamicjacobian(:,i_cols_j)); if size(dynamicjacobian, 1) == 1 % find() will return row vectors in this case rows = rows'; cols = cols'; vals = vals'; end iJacobian{it-maximum_lag} = [offset+rows, i_cols_J(cols), vals]; i_cols_J = i_cols_J + ny; end offset = offset + ny; end i_rows = i_rows + ny; i_cols = i_cols + ny; end if nargout == 2 iJacobian = cat(1,iJacobian{:}); JJacobian = sparse(iJacobian(:,1), iJacobian(:,2), iJacobian(:,3), T*ny, T*ny); end