Provided by: libalgorithm-lbfgs-perl_0.16-1build1_amd64 bug

NAME

       Algorithm::LBFGS - Perl extension for L-BFGS

SYNOPSIS

         use Algorithm::LBFGS;

         # create an L-BFGS optimizer
         my $o = Algorithm::LBFGS->new;

         # f(x) = (x1 - 1)^2 + (x2 + 2)^2
         # grad f(x) = (2 * (x1 - 1), 2 * (x2 + 2));
         my $eval_cb = sub {
             my $x = shift;
             my $f = ($x->[0] - 1) * ($x->[0] - 1) + ($x->[1] + 2) * ($x->[1] + 2);
             my $g = [ 2 * ($x->[0] - 1), 2 * ($x->[1] + 2) ];
             return ($f, $g);
         };

         my $x0 = [0.0, 0.0]; # initial point
         my $x = $o->fmin($eval_cb, $x0); # $x is supposed to be [ 1, -2 ];

DESCRIPTION

       L-BFGS (Limited-memory Broyden-Fletcher-Goldfarb-Shanno) is a quasi-Newton method for
       unconstrained optimization. This method is especially efficient on problems involving a
       large number of variables.

       Generally, it solves a problem described as following:

         min f(x), x = (x1, x2, ..., xn)

       Jorge Nocedal wrote a Fortran 77 version of this algorithm.

       <http://www.ece.northwestern.edu/~nocedal/lbfgs.html>

       And, Naoaki Okazaki rewrote it in pure C (liblbfgs).

       <http://www.chokkan.org/software/liblbfgs/index.html>

       This module is a Perl port of Naoaki Okazaki's C version.

   new
       "new" creates a L-BFGS optimizer with given parameters.

         my $o1 = new Algorithm::LBFGS(m => 5);
         my $o2 = new Algorithm::LBFGS(m => 3, eps => 1e-6);
         my $o3 = new Algorithm::LBFGS;

       If no parameter is specified explicitly, their default values are used.

       The parameter can be changed after the creation of the optimizer by "set_param". Also,
       they can be queryed by "get_param".

       Please refer to the "List of Parameters" for details about parameters.

   get_param
       Query the value of a parameter.

          my $o = Algorithm::LBFGS->new;
          print $o->get_param('epsilon'); # 1e-5

   set_param
       Change the values of one or several parameters.

          my $o = Algorithm::LBFGS->new;
          $o->set_param(epsilon => 1e-6, m => 7);

   fmin
       The prototype of "fmin" is like

         x = fmin(evaluation_cb, x0, progress_cb, user_data)

       As the name says, it finds a vector x which minimize the function f(x).

       "evaluation_cb" is a ref to the evaluation callback subroutine, "x0" is the initial point
       of the optimization algorithm, "progress_cb" (optional) is a ref to the progress callback
       subroutine, and "user_data" (optional) is a piece of extra data that client program want
       to pass to both "evaluation_cb" and "progress_cb".

       Client program can use "get_status" to find if any problem occured during the optimization
       after their calling "fmin". When the status is "LBFGS_OK", the returning value "x" (array
       ref) contains the optimized variables, otherwise, there may be some problems occured and
       the value in the returning "x" is undefined.

       evaluation_cb

       The ref to the evaluation callback subroutine.

       The evaluation callback subroutine is supposed to calculate the function value and
       gradient vector at a specified point "x". It is called automatically by "fmin" when an
       evaluation is needed.

       The client program need to make sure their evaluation callback subroutine has a prototype
       like

         (f, g) = evaluation_cb(x, step, user_data)

       "x" (array ref) is the current values of variables, "step" is the current step of the line
       search routine, "user_data" is the extra user data specified when calling "fmin".

       The evaluation callback subroutine is supposed to return both the function value "f" and
       the gradient vector "g" (array ref) at current "x".

       x0

       The initial point of the optimization algorithm.  The final result may depend on your
       choice of "x0".

       NOTE: The content of "x0" will be modified after calling "fmin".  When the algorithm
       terminates successfully, the content of "x0" will be replaced by the optimized variables,
       otherwise, the content of "x0" is undefined.

       progress_cb

       The ref to the progress callback subroutine.

       The progress callback subroutine is called by "fmin" at the end of each iteration, with
       information of current iteration. It is very useful for a client program to monitor the
       optimization progress.

       The client program need to make sure their progress callback subroutine has a prototype
       like

         s = progress_cb(x, g, fx, xnorm, gnorm, step, k, ls, user_data)

       "x" (array ref) is the current values of variables. "g" (array ref) is the current
       gradient vector. "fx" is the current function value. "xnorm" and "gnorm" is the L2 norm of
       "x" and "g". "step" is the line-search step used for this iteration. "k" is the iteration
       count. "ls" is the number of evaluations in this iteration. "user_data" is the extra user
       data specified when calling "fmin".

       The progress callback subroutine is supposed to return an indicating value "s" for "fmin"
       to decide whether the optimization should continue or stop. "fmin" continues to the next
       iteration when "s=0", otherwise, it terminates with status code "LBFGSERR_CANCELED".

       The client program can also pass string values to "progress_cb", which means it want to
       use a predefined progress callback subroutine. There are two predefined progress callback
       subroutines, 'verbose' and 'logging'.  'verbose' just prints out all information of each
       iteration, while 'logging' logs the same information in an array ref provided by
       "user_data".

         ...

         # print out the iterations
         fmin($eval_cb, $x0, 'verbose');

         # log iterations information in the array ref $log
         my $log = [];

         fmin($eval_cb, $x0, 'logging', $log);

         use Data::Dumper;
         print Dumper $log;

       user_data

       The extra user data. It will be sent to both "evaluation_cb" and "progress_cb".

   get_status
       Get the status of previous call of "fmin".

         ...
         $o->fmin(...);

         # check the status
         if ($o->get_status eq 'LBFGS_OK') {
            ...
         }

         # print the status out
         print $o->get_status;

       The status code is a string, which could be one of those in the "List of Status Codes".

   status_ok
       This is a shortcut of saying "get_status" eq "LBFGS_OK".

         ...

         if ($o->fmin(...), $o->status_ok) {
             ...
         }

   List of Parameters
       m

       The number of corrections to approximate the inverse hessian matrix.

       The L-BFGS algorithm stores the computation results of previous "m" iterations to
       approximate the inverse hessian matrix of the current iteration. This parameter controls
       the size of the limited memories (corrections). The default value is 6. Values less than 3
       are not recommended. Large values will result in excessive computing time.

       epsilon

       Epsilon for convergence test.

       This parameter determines the accuracy with which the solution is to be found. A
       minimization terminates when

         ||grad f(x)|| < epsilon * max(1, ||x||)

       where ||.|| denotes the Euclidean (L2) norm. The default value is 1e-5.

       max_iterations

       The maximum number of iterations.

       The L-BFGS algorithm terminates an optimization process with "LBFGSERR_MAXIMUMITERATION"
       status code when the iteration count exceedes this parameter. Setting this parameter to
       zero continues an optimization process until a convergence or error. The default value is
       0.

       max_linesearch

       The maximum number of trials for the line search.

       This parameter controls the number of function and gradients evaluations per iteration for
       the line search routine. The default value is 20.

       min_step

       The minimum step of the line search routine.

       The default value is 1e-20. This value need not be modified unless the exponents are too
       large for the machine being used, or unless the problem is extremely badly scaled (in
       which case the exponents should be increased).

       max_step

       The maximum step of the line search.

       The default value is 1e+20. This value need not be modified unless the exponents are too
       large for the machine being used, or unless the problem is extremely badly scaled (in
       which case the exponents should be increased).

       ftol

       A parameter to control the accuracy of the line search routine.

       The default value is 1e-4. This parameter should be greater than zero and smaller than
       0.5.

       gtol

       A parameter to control the accuracy of the line search routine.

       The default value is 0.9. If the function and gradient evaluations are inexpensive with
       respect to the cost of the iteration (which is sometimes the case when solving very large
       problems) it may be advantageous to set this parameter to a small value. A typical small
       value is 0.1. This parameter shuold be greater than the ftol parameter (1e-4) and smaller
       than 1.0.

       xtol

       The machine precision for floating-point values.

       This parameter must be a positive value set by a client program to estimate the machine
       precision. The line search routine will terminate with the status code
       ("LBFGSERR_ROUNDING_ERROR") if the relative width of the interval of uncertainty is less
       than this parameter.

       orthantwise_c

       Coeefficient for the L1 norm of variables.

       This parameter should be set to zero for standard minimization problems.  Setting this
       parameter to a positive value minimizes the objective function f(x) combined with the L1
       norm |x| of the variables, f(x) + c|x|.  This parameter is the coeefficient for the |x|,
       i.e., c. As the L1 norm |x| is not differentiable at zero, the module modify function and
       gradient evaluations from a client program suitably; a client program thus have only to
       return the function value f(x) and gradients grad f(x) as usual. The default value is
       zero.

   List of Status Codes
       LBFGS_OK

       No error occured.

       LBFGSERR_UNKNOWNERROR

       Unknown error.

       LBFGSERR_LOGICERROR

       Logic error.

       LBFGSERR_OUTOFMEMORY

       Insufficient memory.

       LBFGSERR_CANCELED

       The minimization process has been canceled.

       LBFGSERR_INVALID_N

       Invalid number of variables specified.

       LBFGSERR_INVALID_N_SSE

       Invalid number of variables (for SSE) specified.

       LBFGSERR_INVALID_MINSTEP

       Invalid parameter "max_step" specified.

       LBFGSERR_INVALID_MAXSTEP

       Invalid parameter "max_step" specified.

       LBFGSERR_INVALID_FTOL

       Invalid parameter "ftol" specified.

       LBFGSERR_INVALID_GTOL

       Invalid parameter "gtol" specified.

       LBFGSERR_INVALID_XTOL

       Invalid parameter "xtol" specified.

       LBFGSERR_INVALID_MAXLINESEARCH

       Invalid parameter "max_linesearch" specified.

       LBFGSERR_INVALID_ORTHANTWISE

       Invalid parameter "orthantwise_c" specified.

       LBFGSERR_OUTOFINTERVAL

       The line-search step went out of the interval of uncertainty.

       LBFGSERR_INCORRECT_TMINMAX

       A logic error occurred; alternatively, the interval of uncertainty became too small.

       LBFGSERR_ROUNDING_ERROR

       A rounding error occurred; alternatively, no line-search step satisfies the sufficient
       decrease and curvature conditions.

       LBFGSERR_MINIMUMSTEP

       The line-search step became smaller than "min_step".

       LBFGSERR_MAXIMUMSTEP

       The line-search step became larger than "max_step".

       LBFGSERR_MAXIMUMLINESEARCH

       The line-search routine reaches the maximum number of evaluations.

       LBFGSERR_MAXIMUMITERATION

       The algorithm routine reaches the maximum number of iterations.

       LBFGSERR_WIDTHTOOSMALL

       Relative width of the interval of uncertainty is at most "xtol".

       LBFGSERR_INVALIDPARAMETERS

       A logic error (negative line-search step) occurred.

       LBFGSERR_INCREASEGRADIENT

       The current search direction increases the objective function value.

SEE ALSO

       PDL, PDL::Opt::NonLinear

AUTHOR

       Laye Suen, <laye@cpan.org>

COPYRIGHT AND LICENSE

       Copyright (C) 1990, Jorge Nocedal

       Copyright (C) 2007, Naoaki Okazaki

       Copyright (C) 2008, Laye Suen

       This library is distributed under the term of the MIT license.

       <http://opensource.org/licenses/mit-license.php>

REFERENCE

        J. Nocedal. Updating Quasi-Newton Matrices with Limited Storage (1980) , Mathematics of
       Computation 35, pp. 773-782.
        D.C. Liu and J. Nocedal. On the Limited Memory Method for Large Scale Optimization
       (1989), Mathematical Programming B, 45, 3, pp. 503-528.
        Jorge Nocedal's Fortran 77 implementation,
       <http://www.ece.northwestern.edu/~nocedal/lbfgs.html>
        Naoaki Okazaki's C implementation (liblbfgs),
       <http://www.chokkan.org/software/liblbfgs/index.html>