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- // Copyright (C) 2005, 2006 International Business Machines and others.
- // All Rights Reserved.
- // This code is published under the Eclipse Public License.
- //
- // $Id: MittelmannDistCntrlNeumB.cpp 2005 2011-06-06 12:55:16Z stefan $
- //
- // Authors: Carl Laird, Andreas Waechter IBM 2004-11-05
- #include "MittelmannDistCntrlNeumB.hpp"
- #ifdef HAVE_CASSERT
- # include <cassert>
- #else
- # ifdef HAVE_ASSERT_H
- # include <assert.h>
- # else
- # error "don't have header file for assert"
- # endif
- #endif
- using namespace Ipopt;
- /* Constructor. */
- MittelmannDistCntrlNeumBBase::MittelmannDistCntrlNeumBBase()
- :
- y_d_(NULL)
- {}
- MittelmannDistCntrlNeumBBase::~MittelmannDistCntrlNeumBBase()
- {
- delete [] y_d_;
- }
- void
- MittelmannDistCntrlNeumBBase::SetBaseParameters(Index N, Number lb_y, Number ub_y,
- Number lb_u, Number ub_u,
- Number b_0j, Number b_1j,
- Number b_i0, Number b_i1,
- Number u_init)
- {
- N_ = N;
- h_ = 1./(N+1);
- hh_ = h_*h_;
- lb_y_ = lb_y;
- ub_y_ = ub_y;
- lb_u_ = lb_u;
- ub_u_ = ub_u;
- b_0j_ = b_0j;
- b_1j_ = b_1j;
- b_i0_ = b_i0;
- b_i1_ = b_i1;
- u_init_ = u_init;
- // Initialize the target profile variables
- delete [] y_d_;
- y_d_ = new Number[(N_+2)*(N_+2)];
- for (Index j=0; j<= N_+1; j++) {
- for (Index i=0; i<= N_+1; i++) {
- y_d_[y_index(i,j)] = y_d_cont(x1_grid(i),x2_grid(j));
- }
- }
- }
- bool MittelmannDistCntrlNeumBBase::get_nlp_info(
- Index& n, Index& m, Index& nnz_jac_g,
- Index& nnz_h_lag, IndexStyleEnum& index_style)
- {
- // We for each of the N_+2 times N_+2 mesh points we have the value
- // of the functions y, and for each N_ times N_ interior mesh points
- // we have values for u
- n = (N_+2)*(N_+2) + N_*N_;
- // For each of the N_ times N_ interior mesh points we have the
- // discretized PDE, and we have one constriant for each boundary
- // point (except for the corners)
- m = N_*N_ + 4*N_;
- // y(i,j), y(i-1,j), y(i+1,j), y(i,j-1), y(i,j+1), u(i,j) for each
- // of the N_*N_ discretized PDEs, and for the Neumann boundary
- // conditions
- nnz_jac_g = 6*N_*N_ + 8*N_;
- // diagonal entry for each dydy, dudu, dydu in the interior
- nnz_h_lag = 0;
- if (!fint_cont_dydy_alwayszero() || !d_cont_dydy_alwayszero()) {
- nnz_h_lag += N_*N_;
- }
- if (!fint_cont_dudu_alwayszero() || !d_cont_dudu_alwayszero()) {
- nnz_h_lag += N_*N_;
- }
- if (!fint_cont_dydu_alwayszero() || !d_cont_dydu_alwayszero()) {
- nnz_h_lag += N_*N_;
- }
- // We use the C indexing style for row/col entries (corresponding to
- // the C notation, starting at 0)
- index_style = C_STYLE;
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::get_bounds_info(Index n, Number* x_l, Number* x_u,
- Index m, Number* g_l, Number* g_u)
- {
- // Set overall bounds on the variables
- for (Index i=0; i<=N_+1; i++) {
- for (Index j=0; j<=N_+1; j++) {
- Index iy = y_index(i,j);
- x_l[iy] = lb_y_;
- x_u[iy] = ub_y_;
- }
- }
- for (Index i=1; i<=N_; i++) {
- for (Index j=1; j<=N_; j++) {
- Index iu = u_index(i,j);
- x_l[iu] = lb_u_;
- x_u[iu] = ub_u_;
- }
- }
- // There is no information for the y's at the corner points, so just
- // take those variables out
- x_l[y_index(0,0)] = x_u[y_index(0,0)] = 0.;
- x_l[y_index(0,N_+1)] = x_u[y_index(0,N_+1)] = 0.;
- x_l[y_index(N_+1,0)] = x_u[y_index(N_+1,0)] = 0.;
- x_l[y_index(N_+1,N_+1)] = x_u[y_index(N_+1,N_+1)] = 0.;
- // all discretized PDE constraints have right hand side zero
- for (Index i=0; i<m; i++) {
- g_l[i] = 0.;
- g_u[i] = 0.;
- }
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::get_starting_point(Index n, bool init_x, Number* x,
- bool init_z, Number* z_L, Number* z_U,
- Index m, bool init_lambda,
- Number* lambda)
- {
- // Here, we assume we only have starting values for x, if you code
- // your own NLP, you can provide starting values for the others if
- // you wish.
- assert(init_x == true);
- assert(init_z == false);
- assert(init_lambda == false);
- // set all y's to the perfect match with y_d
- for (Index i=0; i<= N_+1; i++) {
- for (Index j=0; j<= N_+1; j++) {
- x[y_index(i,j)] = y_d_[y_index(i,j)];
- //x[y_index(i,j)] += h_*x1_grid(i) + 2*h_*x2_grid(j);
- }
- }
- // Set the initial (constant) value for the u's
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- x[u_index(i,j)] = u_init_;
- //x[u_index(i,j)] -= h_*x1_grid(i) + 2*h_*x2_grid(j);
- }
- }
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::get_scaling_parameters(Number& obj_scaling,
- bool& use_x_scaling,
- Index n, Number* x_scaling,
- bool& use_g_scaling,
- Index m, Number* g_scaling)
- {
- obj_scaling = 1./hh_;
- use_x_scaling = false;
- use_g_scaling = false;
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::eval_f(Index n, const Number* x,
- bool new_x, Number& obj_value)
- {
- // return the value of the objective function
- obj_value = 0.;
- for (Index i=1; i<=N_; i++) {
- for (Index j=1; j<= N_; j++) {
- Index iy = y_index(i,j);
- Index iu = u_index(i,j);
- obj_value += fint_cont(x1_grid(i), x2_grid(j), x[iy], x[iu]);
- }
- }
- obj_value *= hh_;
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::eval_grad_f(Index n, const Number* x, bool new_x, Number* grad_f)
- {
- // return the gradient of the objective function grad_{x} f(x)
- // The values are zero for variables on the boundary
- for (Index i=0; i<= N_+1; i++) {
- grad_f[y_index(i,0)] = 0.;
- }
- for (Index i=0; i<= N_+1; i++) {
- grad_f[y_index(i,N_+1)] = 0.;
- }
- for (Index j=1; j<= N_; j++) {
- grad_f[y_index(0,j)] = 0.;
- }
- for (Index j=1; j<= N_; j++) {
- grad_f[y_index(N_+1,j)] = 0.;
- }
- // now let's take care of the nonzero values
- for (Index i=1; i<=N_; i++) {
- for (Index j=1; j<= N_; j++) {
- Index iy = y_index(i,j);
- Index iu = u_index(i,j);
- grad_f[iy] = hh_*fint_cont_dy(x1_grid(i), x2_grid(j), x[iy], x[iu]);
- grad_f[iu] = hh_*fint_cont_du(x1_grid(i), x2_grid(j), x[iy], x[iu]);
- }
- }
- return true;
- }
- bool MittelmannDistCntrlNeumBBase::eval_g(Index n, const Number* x, bool new_x,
- Index m, Number* g)
- {
- // return the value of the constraints: g(x)
- // compute the discretized PDE for each interior grid point
- for (Index i=1; i<=N_; i++) {
- for (Index j=1; j<=N_; j++) {
- Number val;
- // Start with the discretized Laplacian operator
- val = 4.* x[y_index(i,j)]
- - x[y_index(i-1,j)] - x[y_index(i+1,j)]
- - x[y_index(i,j-1)] - x[y_index(i,j+1)];
- // Add the forcing term (including the step size here)
- val += hh_*d_cont(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- g[pde_index(i,j)] = val;
- }
- }
- Index ig = N_*N_;
- // set up the Neumann boundary conditions
- for (Index i=1; i<= N_; i++) {
- g[ig] = x[y_index(i,0)] - (1.-h_*b_i0_)*x[y_index(i,1)];
- ig++;
- }
- for (Index i=1; i<= N_; i++) {
- g[ig] = x[y_index(i,N_+1)] - (1.-h_*b_i1_)*x[y_index(i,N_)];
- ig++;
- }
- for (Index j=1; j<= N_; j++) {
- g[ig] = x[y_index(0,j)] - (1.-h_*b_0j_)*x[y_index(1,j)];
- ig++;
- }
- for (Index j=1; j<= N_; j++) {
- g[ig] = x[y_index(N_+1,j)] - (1.-h_*b_1j_)*x[y_index(N_,j)];
- ig++;
- }
- DBG_ASSERT(ig==m);
- return true;
- }
- bool MittelmannDistCntrlNeumBBase::eval_jac_g(Index n, const Number* x, bool new_x,
- Index m, Index nele_jac, Index* iRow, Index *jCol,
- Number* values)
- {
- if (values == NULL) {
- // return the structure of the jacobian of the constraints
- // distretized PDEs
- Index ijac = 0;
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- Index ig = pde_index(i,j);
- // y(i,j)
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,j);
- ijac++;
- // y(i-1,j)
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i-1,j);
- ijac++;
- // y(i+1,j)
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i+1,j);
- ijac++;
- // y(i,j-1)
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,j-1);
- ijac++;
- // y(i,j+1)
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,j+1);
- ijac++;
- // u(i,j)
- iRow[ijac] = ig;
- jCol[ijac] = u_index(i,j);
- ijac++;
- }
- }
- Index ig = N_*N_;
- // set up the Neumann boundary conditions
- for (Index i=1; i<=N_; i++) {
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,0);
- ijac++;
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,1);
- ijac++;
- ig++;
- }
- for (Index i=1; i<=N_; i++) {
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,N_);
- ijac++;
- iRow[ijac] = ig;
- jCol[ijac] = y_index(i,N_+1);
- ijac++;
- ig++;
- }
- for (Index j=1; j<=N_; j++) {
- iRow[ijac] = ig;
- jCol[ijac] = y_index(0,j);
- ijac++;
- iRow[ijac] = ig;
- jCol[ijac] = y_index(1,j);
- ijac++;
- ig++;
- }
- for (Index j=1; j<=N_; j++) {
- iRow[ijac] = ig;
- jCol[ijac] = y_index(N_,j);
- ijac++;
- iRow[ijac] = ig;
- jCol[ijac] = y_index(N_+1,j);
- ijac++;
- ig++;
- }
- DBG_ASSERT(ijac==nele_jac);
- }
- else {
- // return the values of the jacobian of the constraints
- Index ijac = 0;
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- // y(i,j)
- values[ijac] = 4. + hh_*d_cont_dy(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ijac++;
- // y(i-1,j)
- values[ijac] = -1.;
- ijac++;
- // y(i+1,j)
- values[ijac] = -1.;
- ijac++;
- // y(1,j-1)
- values[ijac] = -1.;
- ijac++;
- // y(1,j+1)
- values[ijac] = -1.;
- ijac++;
- // y(i,j)
- values[ijac] = hh_*d_cont_du(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ijac++;
- }
- }
- for (Index i=1; i<=N_; i++) {
- values[ijac] = 1.;
- ijac++;
- values[ijac] = -1.+h_*b_i0_;
- ijac++;
- }
- for (Index i=1; i<=N_; i++) {
- values[ijac] = -1.+h_*b_i1_;
- ijac++;
- values[ijac] = 1.;
- ijac++;
- }
- for (Index j=1; j<=N_; j++) {
- values[ijac] = 1.;
- ijac++;
- values[ijac] = -1.+h_*b_0j_;
- ijac++;
- }
- for (Index j=1; j<=N_; j++) {
- values[ijac] = -1.+h_*b_1j_;
- ijac++;
- values[ijac] = 1.;
- ijac++;
- }
- DBG_ASSERT(ijac==nele_jac);
- }
- return true;
- }
- bool
- MittelmannDistCntrlNeumBBase::eval_h(Index n, const Number* x, bool new_x,
- Number obj_factor, Index m,
- const Number* lambda,
- bool new_lambda, Index nele_hess, Index* iRow,
- Index* jCol, Number* values)
- {
- if (values == NULL) {
- // return the structure. This is a symmetric matrix, fill the lower left
- // triangle only.
- Index ihes=0;
- if (!fint_cont_dydy_alwayszero() || !d_cont_dydy_alwayszero()) {
- // First the diagonal entries for dydy
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- iRow[ihes] = y_index(i,j);
- jCol[ihes] = y_index(i,j);
- ihes++;
- }
- }
- }
- if (!fint_cont_dudu_alwayszero() || !d_cont_dudu_alwayszero()) {
- // Now the diagonal entries for dudu
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- iRow[ihes] = u_index(i,j);
- jCol[ihes] = u_index(i,j);
- ihes++;
- }
- }
- }
- if (!fint_cont_dydu_alwayszero() || !d_cont_dydu_alwayszero()) {
- // Now the diagonal entries for dydu
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- iRow[ihes] = y_index(i,j);
- jCol[ihes] = u_index(i,j);
- ihes++;
- }
- }
- }
- DBG_ASSERT(ihes==nele_hess);
- }
- else {
- // return the values
- Index ihes=0;
- Index ihes_store;
- // First the diagonal entries for dydy
- if (!fint_cont_dydy_alwayszero() || !d_cont_dydy_alwayszero()) {
- ihes_store = ihes;
- if (!fint_cont_dydy_alwayszero()) {
- // Contribution from the objective function
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] =
- obj_factor*hh_*fint_cont_dydy(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- else {
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] = 0.;
- ihes++;
- }
- }
- }
- if (!d_cont_dydy_alwayszero()) {
- ihes = ihes_store;
- // Contribution from the constraints
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] +=
- lambda[pde_index(i,j)]*hh_*d_cont_dydy(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- }
- // Finally the entries for dudu
- if (!fint_cont_dudu_alwayszero() || !d_cont_dudu_alwayszero()) {
- ihes_store = ihes;
- if (!fint_cont_dudu_alwayszero()) {
- // Contribution from the objective function
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] =
- obj_factor*hh_*fint_cont_dudu(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- else {
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] = 0.;
- ihes++;
- }
- }
- }
- if (!d_cont_dudu_alwayszero()) {
- ihes = ihes_store;
- // Contribution from the constraints
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] +=
- lambda[pde_index(i,j)]*hh_*d_cont_dudu(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- }
- // Now the entries for dydu
- if (!fint_cont_dydu_alwayszero() || !d_cont_dydu_alwayszero()) {
- ihes_store = ihes;
- if (!fint_cont_dydu_alwayszero()) {
- // Contribution from the objective function
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] =
- obj_factor*hh_*fint_cont_dydu(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- else {
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] = 0.;
- ihes++;
- }
- }
- }
- if (!d_cont_dydu_alwayszero()) {
- ihes = ihes_store;
- // Contribution from the constraints
- for (Index i=1; i<= N_; i++) {
- for (Index j=1; j<= N_; j++) {
- values[ihes] +=
- lambda[pde_index(i,j)]*hh_*d_cont_dydu(x1_grid(i), x2_grid(j),
- x[y_index(i,j)], x[u_index(i,j)]);
- ihes++;
- }
- }
- }
- }
- }
- return true;
- }
- void
- MittelmannDistCntrlNeumBBase::finalize_solution(SolverReturn status,
- Index n, const Number* x, const Number* z_L, const Number* z_U,
- Index m, const Number* g, const Number* lambda, Number obj_value,
- const IpoptData* ip_data,
- IpoptCalculatedQuantities* ip_cq)
- {
- /*
- FILE* fp = fopen("solution.txt", "w+");
- for (Index i=0; i<=N_+1; i++) {
- for (Index j=0; j<=N_+1; j++) {
- fprintf(fp, "y[%6d,%6d] = %15.8e\n", i, j, x[y_index(i,j)]);
- }
- }
- for (Index i=1; i<=N_; i++) {
- for (Index j=1; j<=N_; j++) {
- fprintf(fp, "u[%6d,%6d] = %15.8e\n", i, j ,x[u_index(i,j)]);
- }
- }
- fclose(fp);
- */
- }
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