NAG CL Interface
e04mfc (lp_​solve)

1 Purpose

e04mfc solves general linear programming problems. It is not intended for large sparse problems.

2 Specification

#include <nag.h>
void  e04mfc (Integer n, Integer nclin, const double a[], Integer tda, const double bl[], const double bu[], const double cvec[], double x[], double *objf, Nag_E04_Opt *options, Nag_Comm *comm, NagError *fail)
The function may be called by the names: e04mfc, nag_opt_lp_solve or nag_opt_lp.

3 Description

e04mfc is designed to solve linear programming (LP) problems of the form
minimize x R n cT x   subject to   l x A x u ,  
where c is an n element vector and A is an m lin by n matrix.
The function allows the linear objective function to be omitted in which case a feasible point (FP) for the set of constraints is sought.
The constraints involving A are called the general constraints. Note that upper and lower bounds are specified for all the variables and for all the general constraints. An equality constraint can be specified by setting l i = u i . If certain bounds are not present, the associated elements of l or u can be set to special values that will be treated as - or + . (See the description of the optional parameter options.inf_bound in Section 12.2).
You must supply an initial estimate of the solution.
Details about the algorithm are described in Section 11, but it is not necessary to read this more advanced section before using e04mfc.

4 References

Gill P E, Hammarling S, Murray W, Saunders M A and Wright M H (1986) Users' guide for LSSOL (Version 1.0) Report SOL 86-1 Department of Operations Research, Stanford University
Gill P E and Murray W (1978) Numerically stable methods for quadratic programming Math. Programming 14 349–372
Gill P E, Murray W, Saunders M A and Wright M H (1984) Procedures for optimization problems with a mixture of bounds and general linear constraints ACM Trans. Math. Software 10 282–298
Gill P E, Murray W, Saunders M A and Wright M H (1989) A practical anti-cycling procedure for linearly constrained optimization Math. Programming 45 437–474
Gill P E, Murray W, Saunders M A and Wright M H (1991) Inertia-controlling methods for general quadratic programming SIAM Rev. 33 1–36
Gill P E, Murray W and Wright M H (1991) Numerical Linear Algebra and Optimization (Volume 1) Addison Wesley, Redwood City, California.

5 Arguments

1: n Integer Input
On entry: n , the number of variables.
Constraint: n>0 .
2: nclin Integer Input
On entry: m lin , the number of general linear constraints.
Constraint: nclin0 .
3: a[nclin×tda] const double Input
Note: the i,jth element of the matrix A is stored in a[i-1×tda+j-1].
On entry: the i th row of a must contain the coefficients of the i th general linear constraint (the i th row of A ), for i=1,2,, m lin .
If nclin=0 then the array a is not referenced.
4: tda Integer Input
On entry: the stride separating matrix column elements in the array a.
Constraint: if nclin>0 , tdan
5: bl[n+nclin] const double Input
6: bu[n+nclin] const double Input
On entry: bl must contain the lower bounds and bu the upper bounds, for all the constraints in the following order. The first n elements of each array must contain the bounds on the variables, and the next m lin elements the bounds for the general linear constraints (if any). To specify a nonexistent lower bound (i.e., l j = - ), set bl[j-1] -options.inf_bound , and to specify a nonexistent upper bound (i.e., u j = + ), set bu[j-1] options.inf_bound; here options.inf_bound is the value of the optional parameter options.inf_bound, whose default value is 10 20 (see Section 12.2). To specify the j th constraint as an equality, set bl[j-1] = bu[j-1] = β , say, where β < options.inf_bound.
Constraint: bl[j-1] bu[j-1] , for j=1,2,,n+nclin-1.
7: cvec[n] const double Input
On entry: the coefficients of the objective function when the problem is of type options.prob=Nag_LP. The problem type is specified by the optional parameter options.prob (see Section 12.2) and the values options.prob=Nag_LP or Nag_FP represent linear programming problem and feasible point problem respectively. options.prob=Nag_LP is the default problem type for e04mfc.
If the problem type options.prob=Nag_FP is specified then cvec is not referenced and a NULL pointer may be given.
8: x[n] double Input/Output
On entry: an initial estimate of the solution.
On exit: the point at which e04mfc terminated. If fail.code=NE_NOERROR , NW_SOLN_NOT_UNIQUE or NW_NOT_FEASIBLE, x contains an estimate of the solution.
9: objf double * Output
On exit: the value of the objective function at x if x is feasible, or the sum of infeasibilities at x otherwise. If the problem is of type options.prob=Nag_FP and x is feasible, objf is set to zero.
10: options Nag_E04_Opt * Input/Output
On entry/exit: a pointer to a structure of type Nag_E04_Opt whose members are optional parameters for e04mfc. These structure members offer the means of adjusting some of the argument values of the algorithm and on output will supply further details of the results. A description of the members of options is given below in Section 12.2. Some of the results returned in options can be used by e04mfc to perform a ‘warm start’ if it is re-entered (see the member options.start in Section 12.2).
If any of these optional parameters are required, then the structure options should be declared and initialized by a call to e04xxc immediately before being supplied as an argument to e04mfc.
11: comm Nag_Comm * Input/Output
Note: comm is a NAG defined type (see Section 3.1.1 in the Introduction to the NAG Library CL Interface).
On entry/exit: structure containing pointers for user communication with an optional user-defined printing function. See Section 12.3.1 for details. If you do not need to make use of this communication feature then the null pointer NAGCOMM_NULL may be used in the call to e04mfc.
12: fail NagError * Input/Output
The NAG error argument (see Section 7 in the Introduction to the NAG Library CL Interface).

6 Error Indicators and Warnings

If one of NE_INT_ARG_LT, NE_2_INT_ARG_LT, NE_OPT_NOT_INIT, NE_BAD_PARAM, NE_INVALID_INT_RANGE_1, NE_INVALID_INT_RANGE_2, NE_INVALID_REAL_RANGE_FF, NE_INVALID_REAL_RANGE_F, NE_CVEC_NULL, NE_WARM_START, NE_BOUND, NE_BOUND_LCON, NE_STATE_VAL and NE_ALLOC_FAIL occurs, no values will have been assigned to objf, or to options.ax and options.lambda. x and options.state will be unchanged.
NE_2_INT_ARG_LT
On entry, tda=value while n=value . These arguments must satisfy tdan .
NE_ALLOC_FAIL
Dynamic memory allocation failed.
NE_BAD_PARAM
On entry, argument options.print_level had an illegal value.
On entry, argument options.prob had an illegal value.
On entry, argument options.start had an illegal value.
NE_BOUND
The lower bound for variable value (array element bl[value] ) is greater than the upper bound.
NE_BOUND_LCON
The lower bound for linear constraint value (array element bl[value] ) is greater than the upper bound.
NE_CVEC_NULL
options.prob=value but argument cvec= NULL.
NE_INT_ARG_LT
On entry, n=value.
Constraint: n1.
On entry, nclin=value.
Constraint: nclin0.
NE_INVALID_INT_RANGE_1
Value value given to options.fcheck not valid. Correct range is options.fcheck1 .
Value value given to options.max_iter not valid. Correct range is options.max_iter0 .
NE_INVALID_INT_RANGE_2
Value value given to options.reset_ftol not valid. Correct range is 0 < options.reset_ftol < 10000000 .
NE_INVALID_REAL_RANGE_F
Value value given to options.ftol not valid. Correct range is options.ftol>0.0 .
Value value given to options.inf_bound not valid. Correct range is options.inf_bound>0.0 .
Value value given to options.inf_step not valid. Correct range is options.inf_step>0.0 .
NE_INVALID_REAL_RANGE_FF
Value value given to options.crash_tol not valid. Correct range is 0.0 options.crash_tol 1.0 .
NE_NOT_APPEND_FILE
Cannot open file string for appending.
NE_NOT_CLOSE_FILE
Cannot close file string .
NE_OPT_NOT_INIT
options structure not initialized.
NE_STATE_VAL
options.state[value] is out of range. options.state[value] = value.
NE_UNBOUNDED
Solution appears to be unbounded.
This value of fail.code implies that a step as large as options.inf_step would have to be taken in order to continue the algorithm. This situation can occur only when the problem is of type options.prob=Nag_LP and at least one variable has no upper or lower bound.
NE_WARM_START
options.start=Nag_Warm but pointer options.state= NULL.
NE_WRITE_ERROR
Error occurred when writing to file string .
NW_NOT_FEASIBLE
No feasible point was found for the linear constraints.
It was not possible to satisfy all the constraints to within the feasibility tolerance. In this case, the constraint violations at the final x will reveal a value of the tolerance for which a feasible point will exist – for example, if the feasibility tolerance for each violated constraint exceeds its Residual at the final point. You should check that there are no constraint redundancies. If the data for the constraints are accurate only to the absolute precision σ , you should ensure that the value of the optional parameter options.ftol is greater than σ . For example, if all elements of A are of order unity and are accurate only to three decimal places, the optional parameter options.ftol should be at least 10 -3 .
NW_OVERFLOW_WARN
Serious ill-conditioning in the working set after adding constraint value. Overflow may occur in subsequent iterations.
If overflow occurs preceded by this warning then serious ill-conditioning has probably occurred in the working set when adding a constraint. It may be possible to avoid the difficulty by increasing the magnitude of the optional parameter options.ftol and re-running the program. If the message recurs even after this change, the offending linearly dependent constraint j must be removed from the problem.
NW_SOLN_NOT_UNIQUE
Optimal solution is not unique.
x is a weak local minimum (the projected gradient is negligible, the Lagrange multipliers are optimal but there is a small multiplier). This means that the solution x is not unique.
NW_TOO_MANY_ITER
The maximum number of iterations, value, have been performed.
The value of the optional parameter options.max_iter may be too small. If the method appears to be making progress (e.g., the objective function is being satisfactorily reduced), increase the value of options.max_iter and rerun e04mfc (possibly using the options.start=Nag_Warm facility to specify the initial working set).

7 Accuracy

e04mfc implements a numerically stable active set strategy and returns solutions that are as accurate as the condition of the problem warrants on the machine.

8 Parallelism and Performance

e04mfc is not threaded in any implementation.

9 Further Comments

Sensible scaling of the problem is likely to reduce the number of iterations required and make the problem less sensitive to perturbations in the data, thus improving the condition of the problem. In the absence of better information it is usually sensible to make the Euclidean lengths of each constraint of comparable magnitude. See the E04 Chapter Introduction and Gill et al. (1986) for further information and advice.

10 Example

This example is a portfolio investment problem taken from Gill et al. (1991). The objective function to be minimized is
- 5 x 1 - 2 x 3  
subject to the bounds
x 1 -75 x 2 -1000 x 3 -25  
and the general constraints
20 x 1 + 2 x 2 + 100 x 3 = - 0 18 x 1 + 3 x 2 + 102 x 3 -600 15 x 1 - 1 2 x 2 - 25 x 3 - 0 -5 x 1 + 3 2 x 2 - 25 x 3 -500 -5 x 1 - 1 2 x 2 + 75 x 3 -1000  
The initial point, which is feasible, is
x 0 = 10.0,20.0,100.0 T .  
The solution is
x * = 75.0,-250.0,-10.0 T .  
Three general constraints are active at the solution, the bound constraints are all inactive.
The options structure is declared and initialized by e04xxc, a value is assigned directly to option options.inf_bound and e04mfc is then called. On successful return two further options are read from a data file by use of e04xyc and the problem is re-run. The memory freeing function e04xzc is used to free the memory assigned to the pointers in the options structure. You must not use the standard C function free() for this purpose.

10.1 Program Text

Program Text (e04mfce.c)

10.2 Program Data

Program Options (e04mfce.opt)

10.3 Program Results

Program Results (e04mfce.r)

11 Further Description

This section gives a detailed description of the algorithm used in e04mfc. This, and possibly the next section, Section 12, may be omitted if the more sophisticated features of the algorithm and software are not currently of interest.

11.1 Overview

e04mfc is based on an inertia-controlling method due to Gill and Murray (1978) and is described in detail by Gill et al. (1991). Here the main features of the method are summarised. Where possible, explicit reference is made to the names of variables that are arguments of e04mfc or appear in the printed output. e04mfc has two phases: finding an initial feasible point by minimizing the sum of infeasibilities (the feasibility phase), and minimizing the linear objective function within the feasible region (the optimality phase). The computations in both phases are performed by the same functions. The two-phase nature of the algorithm is reflected by changing the function being minimized from the sum of infeasibilities to the linear objective function. The feasibility phase does not perform the standard simplex method (i.e., it does not necessarily find a vertex), except in the LP case when m lin n . Once any iterate is feasible, all subsequent iterates remain feasible.
In general, an iterative process is required to solve a linear program. (For simplicity, we shall always consider a typical iteration and avoid reference to the index of the iteration.) Each new iterate x ¯ is defined by
x ¯ = x + α p , (1)
where the steplength α is a non-negative scalar, and p is called the search direction.
At each point x , a working set of constraints is defined to be a linearly independent subset of the constraints that are satisfied ‘exactly’ (to within the tolerance defined by the optional parameter options.ftol; see Section 12.2). The working set is the current prediction of the constraints that hold with equality at a solution of an LP problem. The search direction is constructed so that the constraints in the working set remain unaltered for any value of the step length. For a bound constraint in the working set, this property is achieved by setting the corresponding component of the search direction to zero. Thus, the associated variable is fixed and the specification of the working set induces a partition of x into fixed and free variables. During a given iteration, the fixed variables are effectively removed from the problem; since the relevant components of the search direction are zero, the columns of A corresponding to fixed variables may be ignored.
Let m w denote the number of general constraints in the working set and let n fx denote the number of variables fixed at one of their bounds ( m w and n fx are the quantities Lin and Bnd in the printed output from e04mfc). Similarly, let n fr n fr = n - n fx denote the number of free variables. At every iteration, the variables are re-ordered so that the last n fx variables are fixed, with all other relevant vectors and matrices ordered accordingly.

11.2 Definition of the Search Direction

Let A fr denote the m w by n fr sub-matrix of general constraints in the working set corresponding to the free variables, and let p fr denote the search direction with respect to the free variables only. The general constraints in the working set will be unaltered by any move along p if
A fr p fr = 0 . (2)
In order to compute p fr , the TQ factorization of A fr is used:
A fr Q fr = 0 T , (3)
where T is a nonsingular m w by m w upper triangular matrix (i.e., t ij = 0 if i>j ), and the nonsingular n fr by n fr matrix Q fr is the product of orthogonal transformations (see Gill et al. (1984)). If the columns of Q fr are partitioned so that
Q fr = Z Y ,  
where Y is n fr × m w , then the n z n z = n fr - m w columns of Z form a basis for the null space of A fr . Let n r be an integer such that 0 n r n z , and let Z r denote a matrix whose n r columns are a subset of the columns of Z . (The integer n r is the quantity Nrz in the printed output from e04mfc. In many cases, Z r will include all the columns of Z .) The direction p fr will satisfy (2) if
p fr = Z r p r , (4)
where p r is any n r -vector.

11.3 The Main Iteration

Let Q denote the n by n matrix
Q = Q fr I fx ,  
where I fx is the identity matrix of order n fx . Let g q denote the transformed gradient
g q = Q T c  
and let the vector of first n r elements of g q be denoted by g r . The quantity g r is known as the reduced gradient of cT x . If the reduced gradient is zero, x is a constrained stationary point in the subspace defined by Z . During the feasibility phase, the reduced gradient will usually be zero only at a vertex (although it may be zero at non-vertices in the presence of constraint dependencies). During the optimality phase, a zero reduced gradient implies that x minimizes the linear objective when the constraints in the working set are treated as equalities. At a constrained stationary point, Lagrange multipliers λ c and λ b for the general and bound constraints are defined from the equations
AfrT λ c = g fr  and  λ b = g fx - AfxT λ c . (5)
Given a positive constant δ of the order of the machine precision, a Lagrange multiplier λ j corresponding to an inequality constraint in the working set is said to be optimal if λ j δ when the associated constraint is at its upper bound, or if λ j -δ when the associated constraint is at its lower bound. If a multiplier is non-optimal, the objective function (either the true objective or the sum of infeasibilities) can be reduced by deleting the corresponding constraint (with index Jdel; see Section 12.3) from the working set.
If optimal multipliers occur during the feasibility phase and the sum of infeasibilities is nonzero, there is no feasible point, and e04mfc will continue until the minimum value of the sum of infeasibilities has been found. At this point, the Lagrange multiplier λ j corresponding to an inequality constraint in the working set will be such that - 1+δ λ j δ when the associated constraint is at its upper bound, and -δ λ j 1+δ when the associated constraint is at its lower bound. Lagrange multipliers for equality constraints will satisfy λ j 1 + δ .
If the reduced gradient is not zero, Lagrange multipliers need not be computed and the nonzero elements of the search direction p are given by Z r p r . The choice of step length is influenced by the need to maintain feasibility with respect to the satisfied constraints.
Each change in the working set leads to a simple change to A fr : if the status of a general constraint changes, a row of A fr is altered; if a bound constraint enters or leaves the working set, a column of A fr changes. Explicit representations are recurred of the matrices T and Q fr and of vectors QT g , and QT c .
One of the most important features of e04mfc is its control of the conditioning of the working set, whose nearness to linear dependence is estimated by the ratio of the largest to smallest diagonal elements of the TQ factor T (the printed value Cond T; see Section 12.3). In constructing the initial working set, constraints are excluded that would result in a large value of Cond T.
e04mfc includes a rigorous procedure that prevents the possibility of cycling at a point where the active constraints are nearly linearly dependent (see Gill et al. (1989)). The main feature of the anti-cycling procedure is that the feasibility tolerance is increased slightly at the start of every iteration. This not only allows a positive step to be taken at every iteration, but also provides, whenever possible, a choice of constraints to be added to the working set. Let α m denote the maximum step at which x + α m p does not violate any constraint by more than its feasibility tolerance. All constraints at a distance α α α m along p from the current point are then viewed as acceptable candidates for inclusion in the working set. The constraint whose normal makes the largest angle with the search direction is added to the working set.

11.4 Choosing the Initial Working Set

Let Z be partitioned as Z = Z r Z a . A working set for which Z r defines the null space can be obtained by including the rows of ZaT as ‘artificial constraints’. Minimization of the objective function then proceeds within the subspace defined by Z r , as described in Section 11.2.
The artificially augmented working set is given by
A ¯ fr = ZaT A fr , (6)
so that p fr will satisfy A fr p fr = 0 and ZaT p fr = 0 . By definition of the TQ factorization, A ¯ fr automatically satisfies the following:
A¯FRQFR= ZAT AFR QFR= ZAT AFR ZR ZA Y = 0 T¯ ,  
where
T ¯ = I 0 0 T ,  
and hence the TQ factorization of (6) is available trivially from T and Q fr without additional expense.
The matrix Z a is not kept fixed, since its role is purely to define an appropriate null space; the TQ factorization can therefore be updated in the normal fashion as the iterations proceed. No work is required to ‘delete’ the artificial constraints associated with Z a when ZrT g fr = 0 , since this simply involves repartitioning Q fr . The ‘artificial’ multiplier vector associated with the rows of ZaT is equal to ZaT g fr , and the multipliers corresponding to the rows of the ‘true’ working set are the multipliers that would be obtained if the artificial constraints were not present. If an artificial constraint is ‘deleted’ from the working set, an A appears alongside the entry in the Jdel column of the printed output (see Section 12.3).
The number of columns in Z a and Z r and the Euclidean norm of ZrT g fr , appear in the printed output as Nart, Nrz and Norm Gz (see Section 12.3).
Under some circumstances, a different type of artificial constraint is used when solving a linear program. Although the algorithm of e04mfc does not usually perform simplex steps (in the traditional sense), there is one exception: a linear program with fewer general constraints than variables (i.e., m lin n ). (Use of the simplex method in this situation leads to savings in storage.) At the starting point, the ‘natural’ working set (the set of constraints exactly or nearly satisfied at the starting point) is augmented with a suitable number of ‘temporary’ bounds, each of which has the effect of temporarily fixing a variable at its current value. In subsequent iterations, a temporary bound is treated as a standard constraint until it is deleted from the working set, in which case it is never added again. If a temporary bound is ‘deleted’ from the working set, an F (for ‘Fixed’) appears alongside the entry in the Jdel column of the printed output (see Section 12.3).

12 Optional Parameters

A number of optional input and output arguments to e04mfc are available through the structure argument options, type Nag_E04_Opt. An argument may be selected by assigning an appropriate value to the relevant structure member; those arguments not selected will be assigned default values. If no use is to be made of any of the optional parameters you should use the NAG defined null pointer, E04_DEFAULT, in place of options when calling e04mfc; the default settings will then be used for all arguments.
Before assigning values to options directly the structure must be initialized by a call to the function e04xxc. Values may then be assigned to the structure members in the normal C manner.
After return from e04mfc, the options structure may only be re-used for future calls of e04mfc if the dimensions of the new problem are the same. Otherwise, the structure must be cleared by a call of e04xzc) and re-initialized by a call of e04xxc before future calls. Failure to do this will result in unpredictable behaviour.
Option settings may also be read from a file using the function e04xyc in which case initialization of the options structure will be performed automatically if not already done. Any subsequent direct assignment to the options structure must not be preceded by initialization.
If assignment of functions and memory to pointers in the options structure is required, this must be done directly in the calling program; they cannot be assigned using e04xyc.

12.1 Optional Parameter Checklist and Default Values

For easy reference, the following list shows the members of options which are valid for e04mfc together with their default values where relevant. The number ε is a generic notation for machine precision (see X02AJC).
Nag_ProblemType prob Nag_LP
Nag_Start start Nag_Cold
Boolean list Nag_TRUE
Nag_PrintType print_level Nag_Soln_Iter
char outfile[512] stdout
void (*print_fun)() NULL
Integer max_iter max50, 5 n+nclin
double crash_tol 0.01
double ftol ε
double optim_tol ε 0.8
Integer reset_ftol 10000
Integer fcheck 50
double inf_bound 10 20
double inf_step maxoptions.inf_bound, 10 20
Integer *state size n+nclin
double *ax size nclin
double *lambda size n+nclin
Integer iter

12.2 Description of the Optional Parameters

prob – Nag_ProblemType Default =Nag_LP
On entry: specifies the problem type. The following are the two possible values of options.prob and the size of the array cvec that is required to define the objective function:
Nag_FP cvec not accessed;
Nag_LP cvec[n] required;
Nag_FP denotes a feasible point problem and Nag_LP a linear programming problem.
Constraint: options.prob=Nag_FP or Nag_LP.
start – Nag_Start Default =Nag_Cold
On entry: specifies how the initial working set is chosen. With options.start=Nag_Cold, e04mfc chooses the initial working set based on the values of the variables and constraints at the initial point. Broadly speaking, the initial working set will include equality constraints and bounds or inequality constraints that violate or ‘nearly’ satisfy their bounds (to within options.crash_tol; see below).
With options.start=Nag_Warm, you must provide a valid definition of every element of the array pointer options.state (see below for the definition of this member of options). e04mfc will override your specification of options.state if necessary, so that a poor choice of the working set will not cause a fatal error. options.start=Nag_Warm will be advantageous if a good estimate of the initial working set is available – for example, when e04mfc is called repeatedly to solve related problems.
Constraint: options.start=Nag_Cold or Nag_Warm.
list – Nag_Boolean Default =Nag_TRUE
On entry: if options.list=Nag_TRUE the argument settings in the call to e04mfc will be printed.
print_level – Nag_PrintType Default =Nag_Soln_Iter
On entry: the level of results printout produced by e04mfc. The following values are available:
Nag_NoPrint No output.
Nag_Soln The final solution.
Nag_Iter One line of output for each iteration.
Nag_Iter_Long A longer line of output for each iteration with more information (line exceeds 80 characters).
Nag_Soln_Iter The final solution and one line of output for each iteration.
Nag_Soln_Iter_Long The final solution and one long line of output for each iteration (line exceeds 80 characters).
Nag_Soln_Iter_Const As Nag_Soln_Iter_Long with the Lagrange multipliers, the variables x , the constraint values Ax and the constraint status also printed at each iteration.
Nag_Soln_Iter_Full As Nag_Soln_Iter_Const with the diagonal elements of the upper triangular matrix T associated with the TQ factorization 3 of the working set.
Details of each level of results printout are described in Section 12.3.
Constraint: options.print_level=Nag_NoPrint, Nag_Soln, Nag_Iter, Nag_Soln_Iter, Nag_Iter_Long, Nag_Soln_Iter_Long, Nag_Soln_Iter_Const or Nag_Soln_Iter_Full.
outfile – const char[512] Default = stdout
On entry: the name of the file to which results should be printed. If options.outfile[0] = ' \0 ' then the stdout stream is used.
print_fun – pointer to function Default = NULL
On entry: printing function defined by you; the prototype of options.print_fun is
void (*print_fun)(const Nag_Search_State *st, Nag_Comm *comm);
See Section 12.3.1 below for further details.
max_iter – Integer Default = max50, 5 n+nclin
On entry: options.max_iter specifies the maximum number of iterations to be performed by e04mfc.
If you wish to check that a call to e04mfc is correct before attempting to solve the problem in full then options.max_iter may be set to 0. No iterations will then be performed but the initialization stages prior to the first iteration will be processed and a listing of argument settings output if options.list=Nag_TRUE (the default setting).
Constraint: options.max_iter0 .
crash_tol – double Default =0.01
On entry: options.crash_tol is used in conjunction with the optional parameter options.start. When options.start has the default setting, i.e., options.start=Nag_Cold, e04mfc selects an initial working set. The initial working set will include bounds or general inequality constraints that lie within options.crash_tol of their bounds. In particular, a constraint of the form ajT x l will be included in the initial working set if ajT x-l options.crash_tol × 1 + l .
Constraint: 0.0 options.crash_tol 1.0 .
ftol – double Default = ε
On entry: options.ftol defines the maximum acceptable violation in each constraint at a ‘feasible’ point. For example, if the variables and the coefficients in the general constraints are of order unity, and the latter are correct to about 6 decimal digits, it would be appropriate to specify options.ftol as 10 -6 .
e04mfc attempts to find a feasible solution before optimizing the objective function. If the sum of infeasibilities cannot be reduced to zero, e04mfc finds the minimum value of the sum. Let Sinf be the corresponding sum of infeasibilities. If Sinf is quite small, it may be appropriate to raise options.ftol by a factor of 10 or 100. Otherwise, some error in the data should be suspected.
Note that a ‘feasible solution’ is a solution that satisfies the current constraints to within the tolerance options.ftol.
Constraint: options.ftol>0.0 .
optim_tol – double ε 0.8
On entry: options.optim_tol defines the tolerance used to determine whether the bounds and generated constraints have the correct sign for the solution to be judged optimal.
Constraint: options.optim_tolε .
reset_ftol – Integer Default =10000
On entry: this option is part of an anti-cycling procedure designed to guarantee progress even on highly degenerate problems.
The strategy is to force a positive step at every iteration, at the expense of violating the constraints by a small amount. Suppose that the value of the optional parameter options.ftol is δ . Over a period of options.reset_ftol iterations, the feasibility tolerance actually used by e04mfc increases from 0.5 δ to δ (in steps of 0.5 δ / options.reset_ftol).
At certain stages the following ‘resetting procedure’ is used to remove constraint infeasibilities. First, all variables whose upper or lower bounds are in the working set are moved exactly onto their bounds. A count is kept of the number of nontrivial adjustments made. If the count is positive, iterative refinement is used to give variables that satisfy the working set to (essentially) machine precision. Finally, the current feasibility tolerance is reinitialized to 0.5 δ .
If a problem requires more than options.reset_ftol iterations, the resetting procedure is invoked and a new cycle of options.reset_ftol iterations is started. (The decision to resume the feasibility phase or optimality phase is based on comparing any constraint infeasibilities with δ .)
The resetting procedure is also invoked when e04mfc reaches an apparently optimal, infeasible or unbounded solution, unless this situation has already occurred twice. If any nontrivial adjustments are made, iterations are continued.
Constraint: 0 < options.reset_ftol < 10000000 .
fcheck – Integer Default =50
On entry: every options.fcheck iterations, a numerical test is made to see if the current solution x satisfies the constraints in the working set. If the largest residual of the constraints in the working set is judged to be too large, the current working set is re-factorized and the variables are recomputed to satisfy the constraints more accurately.
Constraint: options.fcheck1 .
inf_bound – double Default = 10 20
On entry: options.inf_bound defines the ‘infinite’ bound in the definition of the problem constraints. Any upper bound greater than or equal to options.inf_bound will be regarded as + (and similarly for a lower bound less than or equal to -options.inf_bound ).
Constraint: options.inf_bound>0.0 .
inf_step – double Default = maxoptions.inf_bound, 10 20
On entry: options.inf_step specifies the magnitude of the change in variables that will be considered a step to an unbounded solution. (Note that an unbounded solution can occur only when the problem is of type options.prob=Nag_LP). If the change in x during an iteration would exceed the value of options.inf_step, the objective function is considered to be unbounded below in the feasible region.
Constraint: options.inf_step>0.0 .
state – Integer * Default memory = n + nclin
On entry: options.state need not be set if the default option of options.start=Nag_Cold is used as n+nclin values of memory will be automatically allocated by e04mfc.
If the option options.start=Nag_Warm has been chosen, options.state must point to a minimum of n+nclin elements of memory. This memory will already be available if the options structure has been used in a previous call to e04mfc from the calling program, using the same values of n and nclin and options.start=Nag_Cold. If a previous call has not been made sufficient memory must be allocated to options.state by you.
When a warm start is chosen options.state should specify the desired status of the constraints at the start of the feasibility phase. More precisely, the first n elements of options.state refer to the upper and lower bounds on the variables, and the next m lin elements refer to the general linear constraints (if any). Possible values for options.state[j-1] are as follows:
options.state[j-1] Meaning
0 The corresponding constraint should not be in the initial working set.
1 The constraint should be in the initial working set at its lower bound.
2 The constraint should be in the initial working set at its upper bound.
3 The constraint should be in the initial working set as an equality. This value should only be specified if bl[j-1] = bu[j-1] . The values 1, 2 or 3 all have the same effect when bl[j-1] = bu[j-1] .
The values -2 , -1 and 4 are also acceptable but will be reset to zero by the function. In particular, if e04mfc has been called previously with the same values of n and nclin, options.state already contains satisfactory information. (See also the description of the optional parameter options.start). The function also adjusts (if necessary) the values supplied in x to be consistent with the values supplied in options.state.
On exit: if e04mfc exits with fail.code=NE_NOERROR , NW_SOLN_NOT_UNIQUE or NW_NOT_FEASIBLE, the values in options.state indicate the status of the constraints in the working set at the solution. Otherwise, options.state indicates the composition of the working set at the final iterate. The significance of each possible value of options.state[j-1] is as follows:
options.state[j-1] Meaning
-2 The constraint violates its lower bound by more than the feasibility tolerance.
-1 The constraint violates its upper bound by more than the feasibility tolerance.
- 0 The constraint is satisfied to within the feasibility tolerance, but is not in the working set.
- 1 This inequality constraint is included in the working set at its lower bound.
- 2 This inequality constraint is included in the working set at its upper bound.
- 3 This constraint is included in the working set as an equality. This value of options.state can occur only when bl[j-1] = bu[j-1] .
- 4 This corresponds to optimality being declared with x[j-1] being temporarily fixed at its current value. This value of options.state can only occur when fail.code=NW_SOLN_NOT_UNIQUE .
ax – double * Default memory =nclin
On entry: nclin values of memory will be automatically allocated by e04mfc and this is the recommended method of use of options.ax. However you may supply memory from the calling program.
On exit: if nclin>0 , options.ax points to the final values of the linear constraints Ax .
lambda – double * Default memory = n + nclin
On entry: n+nclin values of memory will be automatically allocated by e04mfc and this is the recommended method of use of options.lambda. However you may supply memory from the calling program.
On exit: the values of the Lagrange multipliers for each constraint with respect to the current working set. The first n elements contain the multipliers for the bound constraints on the variables, and the next m lin elements contain the multipliers for the general linear constraints (if any). If options.state[j-1] = 0 (i.e., constraint j is not in the working set), options.lambda[j-1] is zero. If x is optimal, options.lambda[j-1] should be non-negative if options.state[j-1] = 1 , non-positive if options.state[j-1] = 2 and zero if options.state[j-1] = 4 .
iter – Integer 
On exit: the total number of iterations performed in the feasibility phase and (if appropriate) the optimality phase.

12.3 Description of Printed Output

The level of printed output can be controlled with the structure members options.list and options.print_level (see Section 12.2). If options.list=Nag_TRUE then the argument values to e04mfc are listed, whereas the printout of results is governed by the value of options.print_level. The default of options.print_level=Nag_Soln_Iter provides a single line of output at each iteration and the final result. This section describes all of the possible levels of results printout available from e04mfc.
The convention for numbering the constraints in the iteration results is that indices 1 to n refer to the bounds on the variables, and indices n+1 to n + m lin refer to the general constraints. When the status of a constraint changes, the index of the constraint is printed, along with the designation L (lower bound), U (upper bound), E (equality), F (temporarily fixed variable) or A (artificial constraint).
When options.print_level=Nag_Iter or Nag_Soln_Iter the following line of output is produced on completion of each iteration.
Itn the iteration count.
Jdel the index of the constraint deleted from the working set. If Jdel is zero, no constraint was deleted.
Jadd the index of the constraint added to the working set. If Jadd is zero, no constraint was added.
Step the step taken along the computed search direction. If a constraint is added during the current iteration (i.e., Jadd is positive), Step will be the step to the nearest constraint. During the optimality phase, the step can be greater than 1 only if the reduced Hessian is not positive definite.
Ninf the number of violated constraints (infeasibilities). This will be zero during the optimality phase.
Sinf/Obj the value of the current objective function. If x is not feasible, Sinf gives a weighted sum of the magnitudes of constraint violations. If x is feasible, Obj is the value of the objective function. The output line for the final iteration of the feasibility phase (i.e., the first iteration for which Ninf is zero) will give the value of the true objective at the first feasible point.
During the optimality phase, the value of the objective function will be non-increasing. During the feasibility phase, the number of constraint infeasibilities will not increase until either a feasible point is found, or the optimality of the multipliers implies that no feasible point exists. Once optimal multipliers are obtained, the number of infeasibilities can increase, but the sum of infeasibilities will either remain constant or be reduced until the minimum sum of infeasibilities is found.
Bnd the number of simple bound constraints in the current working set.
Lin the number of general linear constraints in the current working set.
Nart the number of artificial constraints in the working set, i.e., the number of columns of Z a (see Section 11). At the start of the optimality phase, Nart provides an estimate of the number of non-positive eigenvalues in the reduced Hessian.
Nrz is the number of columns of Z r (see Section 11). Nrz is the dimension of the subspace in which the objective function is currently being minimized. The value of Nrz is the number of variables minus the number of constraints in the working set; i.e., Nrz = n - Bnd + Lin + Nart .
The value of n z , the number of columns of Z (see Section 11) can be calculated as n z = n - Bnd+Lin . A zero value of n z implies that x lies at a vertex of the feasible region.
Norm Gz ZrT g fr , the Euclidean norm of the reduced gradient with respect to Z r . During the optimality phase, this norm will be approximately zero after a unit step.
If options.print_level=Nag_Iter_Long, Nag_Soln_Iter_Long, Nag_Soln_Iter_Const or Nag_Soln_Iter_Full the line of printout is extended to give the following information. (Note this longer line extends over more than 80 characters).
NOpt is the number of non-optimal Lagrange multipliers at the current point. NOpt is not printed if the current x is infeasible or no multipliers have been calculated. At a minimizer, NOpt will be zero.
Min LM is the value of the Lagrange multiplier associated with the deleted constraint. If Min LM is negative, a lower bound constraint has been deleted; if Min LM is positive, an upper bound constraint has been deleted. If no multipliers are calculated during a given iteration, Min LM will be zero.
Cond T is a lower bound on the condition number of the working set.
When options.print_level=Nag_Soln_Iter_Const or Nag_Soln_Iter_Full more detailed results are given at each iteration. For the setting options.print_level=Nag_Soln_Iter_Const additional values output are:
Value of x the value of x currently held in x.
State the current value of options.state associated with x .
Value of Ax the value of Ax currently held in options.ax.
State the current value of options.state associated with Ax .
Also printed are the Lagrange Multipliers for the bound constraints, linear constraints and artificial constraints.
If options.print_level=Nag_Soln_Iter_Full then the diagonal of T and Z r are also output at each iteration.
When options.print_level=Nag_Soln, Nag_Soln_Iter, Nag_Soln_Iter_Const or Nag_Soln_Iter_Full the final printout from e04mfc includes a listing of the status of every variable and constraint. The following describes the printout for each variable.
Varbl the name (V) and index j , for j=1,2,,n, of the variable.
State the state of the variable (FR if neither bound is in the working set, EQ if a fixed variable, LL if on its lower bound, UL if on its upper bound, TF if temporarily fixed at its current value). If Value lies outside the upper or lower bounds by more than the feasibility tolerance, State will be ++ or -- respectively.
Value the value of the variable at the final iteration.
Lower bound the lower bound specified for the variable. (None indicates that bl[j-1] -options.inf_bound .)
Upper bound the upper bound specified for the variable. (None indicates that bu[j-1] options.inf_bound.)
Lagr mult the value of the Lagrange multiplier for the associated bound constraint. This will be zero if State is FR. If x is optimal, the multiplier should be non-negative if State is LL, and non-positive if State is UL.
Residual the difference between the variable Value and the nearer of its bounds bl[j-1] and bu[j-1] .
The meaning of the printout for general constraints is the same as that given above for variables, with ‘variable’ replaced by ‘constraint’, and with the following change in the heading:
LCon the name (L) and index j , for j=1,2,, m lin of the constraint.

12.3.1 Output of results via a user-defined printing function

You may also specify your own print function for output of iteration results and the final solution by use of the options.print_fun function pointer, which has prototype
void (*print_fun)(const Nag_Search_State *st, Nag_Comm *comm);
The rest of this section can be skipped if you wish to use the default printing facilities.
When a user-defined function is assigned to options.print_fun this will be called in preference to the internal print function of e04mfc. Calls to the user-defined function are again controlled by means of the options.print_level member. Information is provided through st and comm, the two structure arguments to options.print_fun.
If commit_prt = Nag_TRUE then the results from the last iteration of e04mfc are set in the following members of st:
firstNag_Boolean
Nag_TRUE on the first call to options.print_fun.
iterInteger
The number of iterations performed.
nInteger
The number of variables.
nclinInteger
The number of linear constraints.
jdelInteger
Index of constraint deleted.
jaddInteger
Index of constraint added.
stepdouble
The step taken along the current search direction.
ninfInteger
The number of infeasibilities.
fdouble
The value of the current objective function.
bndInteger
Number of bound constraints in the working set.
linInteger
Number of general linear constraints in the working set.
nartInteger
Number of artificial constraints in the working set.
nrzInteger
Number of columns of Z r .
norm_gzdouble
Euclidean norm of the reduced gradient, ZrT g fr .
noptInteger
Number of non-optimal Lagrange multipliers.
min_lmdouble
Value of the Lagrange multiplier associated with the deleted constraint.
condtdouble
A lower bound on the condition number of the working set.
xdouble *
x points to the n memory locations holding the current point x .
axdouble *
options.ax points to the nclin memory locations holding the current values Ax .
stateInteger *
options.state points to the n+nclin memory locations holding the status of the variables and general linear constraints. See Section 12.2 for a description of the possible status values.
tdouble *
The upper triangular matrix T with stlin columns. Matrix element i,j is held in stt[ i-1 * sttdt + j-1 ] .
tdtInteger
The trailing dimension for stt.
If commnew_lm = Nag_TRUE then the Lagrange multipliers have been updated and the following members are set:
kxInteger *
Indices of the bound constraints with associated multipliers. Value of stkx[i-1] is the index of the constraint with multiplier stlambda[i-1] , for i=1,2,,stbnd.
kactiveInteger *
Indices of the linear constraints with associated multipliers. Value of stkactive[i-1] is the index of the constraint with multiplier stlambda[stbnd+i-1] , for i=1,2,,stlin.
lambdadouble *
The multipliers for the constraints in the working set. options.lambda[i-1] , for i=1,2,,stbnd hold the multipliers for the bound constraints while the multipliers for the linear constraints are held at indices i-1 = stbnd , , stbnd + stlin .
gqdouble *
stgq[i-1] , for i=1,2,,stnart hold the multipliers for the artificial constraints.
The following members of st are also relevant and apply when commit_prt or commnew_lm is Nag_TRUE.
refactorNag_Boolean
Nag_TRUE if iterative refinement performed. See Section 11.3 and optional parameter options.reset_ftol.
jmaxInteger
If strefactor = Nag_TRUE then stjmax holds the index of the constraint with the maximum violation.
errmaxdouble
If strefactor = Nag_TRUE then sterrmax holds the value of the maximum violation.
movedNag_Boolean
Nag_TRUE if some variables moved to their bounds. See the optional parameter options.reset_ftol.
nmovedInteger
If stmoved = Nag_TRUE then stnmoved holds the number of variables which were moved to their bounds.
rowerrNag_Boolean
Nag_TRUE if some constraints are not satisfied to within options.ftol.
feasibleNag_Boolean
Nag_TRUE when a feasible point has been found.
If commsol_prt = Nag_TRUE then the final result from e04mfc is available and the following members of st are set:
iterInteger
The number of iterations performed.
nInteger
The number of variables.
nclinInteger
The number of linear constraints.
xdouble *
x points to the n memory locations holding the final point x .
fdouble *
The final objective function value or, if x is not feasible, the sum of infeasibilities. If the problem is of type options.prob=Nag_FP and x is feasible then stf is set to zero.
axdouble *
options.ax points to the nclin memory locations holding the final values Ax .
stateInteger *
ststate points to the n+nclin memory locations holding the final status of the variables and general linear constraints. See Section 12.2 for a description of the possible status values.
lambdadouble *
stlambda points to the n+nclin final values of the Lagrange multipliers.
bldouble *
bl points to the n+nclin lower bound values.
budouble *
bu points to the n+nclin upper bound values.
endstateNag_EndState
The state of termination of e04mfc. Possible values of stendstate and their correspondence to the exit value of fail.code are:
Value of stendstate Value of fail.code
Nag_Feasible and Nag_Optimal NE_NOERROR
Nag_Weakmin NW_SOLN_NOT_UNIQUE
Nag_Unbounded NE_UNBOUNDED
Nag_Infeasible NW_NOT_FEASIBLE
Nag_Too_Many_Iter NW_TOO_MANY_ITER
The relevant members of the structure comm are:
it_prtNag_Boolean
Will be Nag_TRUE when the print function is called with the result of the current iteration.
sol_prtNag_Boolean
Will be Nag_TRUE when the print function is called with the final result.
new_lmNag_Boolean
Will be Nag_TRUE when the Lagrange multipliers have been updated.
userdouble
iuserInteger
pPointer 
Pointers for communication of user information. If used they must be allocated memory either before entry to e04mfc or during a call to options.print_fun. The type Pointer will be void * with a C compiler that defines void *.