NAME

Math::Symbolic - Symbolic calculations

SYNOPSIS

use Math::Symbolic;

my $tree = Math::Symbolic->new_from_string('2*3^2');

DESCRIPTION

Math::Symbolic is intended to offer symbolic calculation capabilities to the Perl programmer without using external (and commercial) libraries and/or applications.

Unless, however, some interested and knowledgable developers turn up to participate in the development, the library will be severely limited by my experience in the area. Symbolic calculations are an active field of research in CS.

There are several ways to construct Math::Symbolic trees. There are no actual Math::Symbolic objects, but rather trees of objects of subclasses of Math::Symbolic. The most general but unfortunately also the least intuitive way of constructing trees is to use the constructors of the Math::Symbolic::Operator, Math::Symbolic::Variable, and Math::Symbolic::Constant classes to create (nested) objects of the corresponding types.

Furthermore, you may use the overloaded interface to apply the standard Perl operators (and functions, see "OVERLOADED OPERATORS") to existing Math::Symbolic trees and standard Perl expressions.

Possibly the most convenient way of constructing Math::Symbolic trees is using the builtin parser to generate trees from expressions such as '2 * x^5'. You may use the Math::Symbolic->parse_from_string() class method for this.

Of course, you may combine the overloaded interface with the parser to generate trees with Perl code such as "$term * 5 * 'sin(omega*t+phi)'" which will create a tree of the existing tree $term times 5 times the sine of the vars omega times t plus phi.

EXPORT

None by default, but you may choose to have the following constants exported to your namespace using the standard Exporter semantics. There are two export tags: :all and :constants. :all will export all constants and the parse_from_string subroutine.

Constants for transcendetal numbers:
  EULER (2.7182...)
  PI    (3.14159...)
  
Constants representing operator types: (First letter indicates arity)
(These evaluate to the same numbers that are returned by the type()
 method of Math::Symbolic::Operator objects.)
  B_SUM
  B_DIFFERENCE
  B_PRODUCT
  B_DIVISION
  B_LOG
  B_EXP
  U_MINUS
  U_P_DERIVATIVE (partial derivative)
  U_T_DERIVATIVE (total derivative)
  U_SINE
  U_COSINE
  U_TANGENT
  U_COTANGENT
  U_ARCSINE
  U_ARCCOSINE
  U_ARCTANGENT
  U_ARCCOTANGENT
  U_SINE_H
  U_COSINE_H
  U_AREASINE_H
  U_AREACOSINE_H
  
Constants representing Math::Symbolic term types:
(These evaluate to the same numbers that are returned by the term_type()
 methods.)
  T_OPERATOR
  T_CONSTANT
  T_VARIABLE

Subroutines:
  parse_from_string (returns Math::Symbolic tree)

CLASS DATA

The package variable $Parser will contain a Parse::RecDescent object that is used to parse strings at runtime.

SUBROUTINES

parse_from_string

This subroutine takes a string as argument and parses it using a Parse::RecDescent parser taken from the package variable $Math::Symbolic::Parser. It generates a Math::Symbolic tree from the string and returns that tree.

The string may contain any identifiers matching /[a-zA-Z][a-zA-Z0-9_]*/ which will be parsed as variables of the corresponding name.

Please refer to Math::Symbolic::Parser for more information.

EXAMPLES

This example demonstrates variable and operator creation using object prototypes as well as partial derivatives and the various ways of applying derivatives and simplifying terms. This is an old example demonstrating the worse parts of the interface. To be replaced soon.

use Math::Symbolic qw/:all/;

my $var = Math::Symbolic::Variable->new();
my $a = $var->new('a' => 2);
my $b = $var->new('b' => 3);
my $c = $var->new('c' => 4);

print "Vars: a=" . $a->value() .
           " b=" . $b->value() .
           " c=" . $c->value() .
           " (Values are optional)\n\n";

my $op    = Math::Symbolic::Operator->new();
my $add1  = $op->new('+', $a, $c);
my $mult1 = $op->new('*', $a, $b);
my $div1  = $op->new('/', $add1, $mult1);

print "Expression: (a+c)/(a*b)\n\n";

print "prefix notation and evaluation:\n";
print $div1->to_string('prefix') . " = " . $div1->value() . "\n\n";

print "Now, we derive this partially to a: (prefix again)\n";

my $n_tree = $op->new( {
  type => U_P_DERIVATIVE,
  operands => [$div1, $a],
} );
print $n_tree->to_string('prefix') . " = " . $n_tree->value() . "\n\n";
	
print "Now, we apply the derivative to the term: (infix)\n";
my $derived = $n_tree->apply_derivatives();
print "$derived = " . $derived->value() . "\n\n";

print "Finally, we simplify the derived term as much as possible:\n";
my $simplified = $derived->simplify();
print "$simplified = " . $derived->value() . "\n\n";

OVERLOADED OPERATORS

Since version 0.102, several arithmetic operators have been overloaded.

That means you can do most arithmetic with Math::Symbolic trees just as if they were plain Perl scalars.

The following operators are currently overloaded to produce valid Math::Symbolic trees when applied to an expression involving at least one Math::Symbolic object:

+, -, *, /, **, sqrt, log, exp, sin, cos

Furthermore, some contexts have been overloaded with particular behaviour: '""' (stringification context) has been overloaded to produce the string representation of the object. '0+' (numerical context) has been overloaded to produce the value of the object. 'bool' (boolean context) has been overloaded to produce the value of the object.

AUTHOR

Steffen Mueller, <symbolic-module at steffen-mueller dot net>

New versions of this module can be found on http://steffen-mueller.net or CPAN.

SEE ALSO

Math::Symbolic::ExportConstants Math::Symbolic::AuxFunctions

Math::Symbolic::Base Math::Symbolic::Operator Math::Symbolic::Constant Math::Symbolic::Variable

Math::Symbolic::Derivative

Math::Symbolic::Parser Math::Symbolic::Compiler