#region Translated by Jose Antonio De Santiago-Castillo. //Translated by Jose Antonio De Santiago-Castillo. //E-mail:JAntonioDeSantiago@gmail.com //Website: www.DotNumerics.com // //Fortran to C# Translation. //Translated by: //F2CSharp Version 0.72 (Dicember 7, 2009) //Code Optimizations: , assignment operator, for-loop: array indexes // #endregion using System; using DotNumerics.FortranLibrary; namespace DotNumerics.Optimization.LBFGSB { public class ACTIVE { #region Variables const double ZERO = 0.0E0; #endregion public ACTIVE() { } /// /// is an integer array of dimension n. /// On entry iwhere is unspecified. /// On exit iwhere(i)=-1 if x(i) has no bounds /// 3 if l(i)=u(i) /// 0 otherwise. /// In cauchy, iwhere is given finer gradations. /// /// /// * * * /// public void Run(int N, double[] L, int offset_l, double[] U, int offset_u, int[] NBD, int offset_nbd, ref double[] X, int offset_x, ref int[] IWHERE, int offset_iwhere , int IPRINT, ref bool PRJCTD, ref bool CNSTND, ref bool BOXED) { #region Variables int NBDD = 0; int I = 0; #endregion #region Array Index Correction int o_l = -1 + offset_l; int o_u = -1 + offset_u; int o_nbd = -1 + offset_nbd; int o_x = -1 + offset_x; int o_iwhere = -1 + offset_iwhere; #endregion #region Prolog // c ************ // c // c Subroutine active // c // c This subroutine initializes iwhere and projects the initial x to // c the feasible set if necessary. // c // c iwhere is an integer array of dimension n. // c On entry iwhere is unspecified. // c On exit iwhere(i)=-1 if x(i) has no bounds // c 3 if l(i)=u(i) // c 0 otherwise. // c In cauchy, iwhere is given finer gradations. // c // c // c * * * // c // c NEOS, November 1994. (Latest revision June 1996.) // c Optimization Technology Center. // c Argonne National Laboratory and Northwestern University. // c Written by // c Ciyou Zhu // c in collaboration with R.H. Byrd, P. Lu-Chen and J. Nocedal. // c // c // c ************ // c Initialize nbdd, prjctd, cnstnd and boxed. #endregion #region Body NBDD = 0; PRJCTD = false; CNSTND = false; BOXED = true; // c Project the initial x to the easible set if necessary. for (I = 1; I <= N; I++) { if (NBD[I + o_nbd] > 0) { if (NBD[I + o_nbd] <= 2 && X[I + o_x] <= L[I + o_l]) { if (X[I + o_x] < L[I + o_l]) { PRJCTD = true; X[I + o_x] = L[I + o_l]; } NBDD += 1; } else { if (NBD[I + o_nbd] >= 2 && X[I + o_x] >= U[I + o_u]) { if (X[I + o_x] > U[I + o_u]) { PRJCTD = true; X[I + o_x] = U[I + o_u]; } NBDD += 1; } } } } // c Initialize iwhere and assign values to cnstnd and boxed. for (I = 1; I <= N; I++) { if (NBD[I + o_nbd] != 2) BOXED = false; if (NBD[I + o_nbd] == 0) { // c this variable is always free IWHERE[I + o_iwhere] = - 1; // c otherwise set x(i)=mid(x(i), u(i), l(i)). } else { CNSTND = true; if (NBD[I + o_nbd] == 2 && U[I + o_u] - L[I + o_l] <= ZERO) { // c this variable is always fixed IWHERE[I + o_iwhere] = 3; } else { IWHERE[I + o_iwhere] = 0; } } } if (IPRINT >= 0) { if (PRJCTD) ;//ERROR-ERRORWRITE(6,*)'The initial X is infeasible. Restart with its projection.' if (!CNSTND) ;//ERROR-ERRORWRITE(6,*)'This problem is unconstrained.' } if (IPRINT > 0) ;//ERROR-ERRORWRITE(6,1001)NBDD return; #endregion } } // c======================= The end of active ============================= }