=head1 Terms
Symbolic Algebra in Pure Perl: terms.
See user manual L</NAME>.
A term represents a product of: variables, coefficents, divisors,
square roots, exponentials, and logs.
PhilipRBrenan@yahoo.com, 2004, Perl License.
package Math::Algebra::Symbols::Term;
$VERSION=1.21;
use Carp;
use Math::BigInt;
#HashUtil use Hash::Util qw(lock_hash);
use Scalar::Util qw(weaken);
=head2 Constructors
=head3 new
Constructor
sub new
{bless {c=>1, d=>1, i=>0, v=>{}, sqrt=>undef, divide=>undef, exp=>undef, log=>undef};
}
=head3 newFromString
New from String
sub newFromString($)
{my ($a) = @_;
return $zero unless $a;
my $A = $a;
for(;$A =~ /(\d+)\.(\d+)/;)
{my $i = $1;
my $j = $2;
my $l = '0' x length($j);
# carp "Replacing $i.$j with $i$j\/1$l in $A";
$A =~ s/$i\.$j/$i$j\/1$l/;
}
if ($A =~ /^\s*([+-])?(\d+)?(?:\/(\d+))?(i)?(?:\*)?(.*)$/)
{my $c = '';
$c = '-'.$c if $1 and $1 eq '-';
$c .= $2 if $2;
$c = '1' if $c eq '';
$c = '-1' if $c eq '-';
my $d = '';
$d = $3 if $3;
$d = 1 if $d eq '';
my $i = 0;
$i = 1 if $4;
my $z = new()->c($c)->d($d)->i($i);
my $b = $5;
for (;$b =~ /^([a-z]+)(?:\*\*)?(\d+)?(?:\*)?(.*)$/i;)
{$b = $3;
$z->{v}{$1} = $2 if defined($2);
$z->{v}{$1} = 1 unless defined($2);
}
croak "Cannot parse: $a" if $A eq $b;
croak "Cannot parse: $b in $a" if $b;
return $z->z;
}
croak "Unable to parse $a";
}
=head3 n
Short name for L</newFromString>
sub n($)
{newFromString($_[0]);
}
=head3 newFromStrings
New from Strings
sub newFromStrings(@)
{return $zero->clone() unless scalar(@_);
map {newFromString($_)} @_;
}
=head3 gcd
Greatest Common Divisor.
sub gcd($$)
{my $x = abs($_[0]);
my $y = abs($_[1]);
return 1 if $x == 1 or $y == 1;
my ($a, $b) = ($x, $y); $a = $y, $b = $x if $y < $a;
for(my $r;;)
{$r = $b % $a;
return $a if $r == 0;
($a, $b) = ($r, $a);
}
}
=head3 lcm
Least common multiple.
sub lcm($$)
{my $x = abs($_[0]);
my $y = abs($_[1]);
return $x*$y if $x == 1 or $y == 1;
$x*$y / gcd($x, $y);
}
=head3 isTerm
Confirm type
sub isTerm($) {1};
=head3 intCheck
Integer check
sub intCheck($$)
{my ($i, $m) = @_;
return $i if $i == 1;
$i =~ /^[\+\-]?\d+/ or die "Integer required for $m not $i";
return Math::BigInt->new($i) if $i > 10_000_000;
$i;
}
=head3 c
Coefficient
sub c($;$)
{my ($t) = @_;
return $t->{c} unless @_ > 1;
$t->{c} = ($_[1] == 1 ? $_[1] : intCheck($_[1], 'c'));
$t;
}
=head3 d
Divisor
sub d($;$)
{my ($t) = @_;
return $t->{d} unless @_ > 1;
$t->{d} = ($_[1] == 1 ? $_[1] : intCheck($_[1], 'd'));
$t;
}
=head3 timesInt
Multiply term by integer
sub timesInt($$)
{my ($t) = @_;
my $m = ($_[1] ? $_[1] : intCheck($_[1], 'times'));
$t->{c} *= $m;
if ($t->{d} > 1)
{my $g = gcd($t->{c}, $t->{d});
if ($g > 1)
{$t->{d} /= $g;
$t->{c} /= $g;
}
}
$t;
}
=head3 divideInt
Divide term by integer
sub divideInt($$)
{my ($t) = @_;
my $d = ($_[1] == 1 ? $_[1] : intCheck($_[1], 'divide'));
$d != 0 or die "Cannot divide by zero";
$t->{d} *= abs($d);
my $g = gcd($t->{d}, $t->{c});
if ($g > 1)
{$t->{d} /= $g;
$t->{c} /= $g;
}
$t->{c} = - $t->{c} if $d < 0;
$t;
}
=head3 negate
Negate term
sub negate($)
{my ($t) = @_;
$t->{c} = -$t->{c};
$t;
}
=head3 isZero
Zero?
sub isZero($)
{my ($t) = @_;
exists $t->{z} or die "Testing unfinalized term";
$t->{id} == $zero->{id};
}
=head3 notZero
Not Zero?
sub notZero($) {return !isZero($_[0])}
=head3 isOne
One?
sub isOne($)
{my ($t) = @_;
exists $t->{z} or die "Testing unfinalized term";
$t->{id} == $one->{id};
}
=head3 notOne
Not One?
sub notOne($) {return !isOne($_[0])}
=head3 isMinusOne
Minus One?
sub isMinusOne($)
{my ($t) = @_;
exists $t->{z} or die "Testing unfinalized term";
$t->{id} == $mOne->{id};
}
=head3 notMinusOne
Not Minus One?
sub notMinusOne($) {return !isMinusOne($_[0])}
=head3 i
Get/Set i - sqrt(-1)
sub i($;$)
{my ($t) = @_;
return $t->{i} unless(@_) > 1;
my $i = ($_[1] == 1 ? $_[1] : intCheck($_[1], 'i'));
my $i4 = $i % 4;
$t->{i} = $i % 2;
$t->{c} = -$t->{c} if $i4 == 2 or $i4 == 3;
$t;
}
=head3 iby
i by power: multiply a term by a power of i
sub iby($$)
{my ($t, $p) = @_;
$t->i($p+$t->{i});
$t;
}
=head3 Divide
Get/Set divide by.
sub Divide($;$)
{my ($t, $d) = @_;
return $t->{divide} unless @_ > 1;
$t->{divide} = $d;
$t;
}
=head3 removeDivide
Remove divide
sub removeDivide($)
{my ($t) = @_;
my $z = $t->clone;
delete $z->{divide};
$z->z;
}
=head3 Sqrt
Get/Set square root.
sub Sqrt($;$)
{my ($t, $s) = @_;
return $t->{sqrt} unless @_ > 1;
$t->{sqrt} = $s;
$t;
}
=head3 removeSqrt
Remove square root.
sub removeSqrt($)
{my ($t) = @_;
my $z = $t->clone;
delete $z->{sqrt};
$z->z;
}
=head3 Exp
Get/Set exp
sub Exp($;$)
{my ($t, $e) = @_;
return $t->{exp} unless @_ > 1;
$t->{exp} = $e;
$t;
}
=head3 Log
# Get/Set log
sub Log($$)
{my ($t, $l) = @_;
return $t->{log} unless @_ > 1;
$t->{log} = $l;
$t;
}
=head3 vp
Get/Set variable power.
On get: returns the power of a variable, or zero if the variable is not
present in the term.
On set: Sets the power of a variable. If the power is zero, removes the
variable from the term. =cut
sub vp($$;$)
{my ($t, $v) = @_;
# $v =~ /^[a-z]+$/i or die "Bad variable name $v";
return exists($t->{v}{$v}) ? $t->{v}{$v} : 0 if @_ == 2;
my $p = ($_[2] == 1 ? $_[2] : intCheck($_[2], 'vp'));
$t->{v}{$v} = $p if $p;
delete $t->{v}{$v} unless $p;
$t;
}
=head3 v
Get all variables mentioned in the term. Variables to power zero
should have been removed by L</vp>.
sub v($)
{my ($t) = @_;
return keys %{$t->{v}};
}
=head3 clone
Clone a term. The existing term must be finalized, see L</z>: the new
term will not be finalized, allowing modifications to be made to it.
sub clone($)
{my ($t) = @_;
$t->{z} or die "Attempt to clone unfinalized term";
my $c = bless {%$t};
$c->{v} = {%{$t->{v}}};
delete @$c{qw(id s z)};
$c;
}
=head3 split
Split a term into its components
sub split($)
{my ($t) = @_;
my $c = $t->clone;
my @c = @$c{qw(sqrt divide exp log)};
@$c{qw(sqrt divide exp log)} = ((undef()) x 4);
(t=>$c, s=>$c[0], d=>$c[1], e=>$c[2], l=>$c[3]);
}
=head3 signature
Sign the term. Used to optimize addition.
Fix the problem of adding different logs
sub signature($)
{my ($t) = @_;
my $s = '';
$s .= sprintf("%010d", $t->{v}{$_}) . $_ for keys %{$t->{v}};
$s .= '(divide'. $t->{divide} .')' if defined($t->{divide});
$s .= '(sqrt'. $t->{sqrt} .')' if defined($t->{sqrt});
$s .= '(exp'. $t->{exp} .')' if defined($t->{exp});
$s .= '(log'. $t->{log} .')' if defined($t->{log});
$s .= 'i' if $t->{i} == 1;
$s = '1' if $s eq '';
$s;
}
=head3 getSignature
Get the signature of a term
sub getSignature($)
{my ($t) = @_;
exists $t->{z} ? $t->{z} : die "Attempt to get signature of unfinalized term";
}
=head3 add
Add two finalized terms, return result in new term or undef.
sub add($$)
{my ($a, $b) = @_;
$a->{z} and $b->{z} or
die "Attempt to add unfinalized terms";
return undef unless $a->{z} eq $b->{z};
return $a->clone->timesInt(2)->z if $a == $b;
my $z = $a->clone;
my $c = $a->{c} * $b->{d}
+ $b->{c} * $a->{d};
my $d = $a->{d} * $b->{d};
return $zero if $c == 0;
$z->c($c)->d(1)->divideInt($d)->z;
}
=head3 subtract
Subtract two finalized terms, return result in new term or undef.
sub subtract($$)
{my ($a, $b) = @_;
$a->{z} and $b->{z} or
die "Attempt to subtract unfinalized terms";
return $zero if $a == $b;
return $a if $b == $zero;
return $b->clone->negate->z if $a == $zero;
return undef unless $a->{z} eq $b->{z};
my $z = $a->clone;
my $c = $a->{c} * $b->{d}
- $b->{c} * $a->{d};
my $d = $a->{d} * $b->{d};
$z->c($c)->d(1)->divideInt($d)->z;
}
=head3 multiply
Multiply two finalized terms, return the result in a new term or undef
sub multiply($$)
{my ($a, $b) = @_;
$a->{z} and $b->{z} or
die "Attempt to multiply unfinalized terms";
# Check
return undef if
(defined($a->{divide}) and defined($b->{divide})) or
(defined($a->{sqrt} ) and defined($b->{sqrt})) or
(defined($a->{exp} ) and defined($b->{exp})) or
(defined($a->{log} ) and defined($b->{log}));
# cdi
my $c = $a->{c} * $b->{c};
my $d = $a->{d} * $b->{d};
my $i = $a->{i} + $b->{i};
$c = -$c, $i = 0 if $i == 2;
my $z = $a->clone->c($c)->d(1)->divideInt($d)->i($i);
# v
# for my $v($b->v)
# {$z->vp($v, $z->vp($v)+$b->vp($v));
# }
for my $v(keys(%{$b->{v}}))
{$z->vp($v, (exists($z->{v}{$v}) ? $z->{v}{$v} : 0)+$b->{v}{$v});
}
# Divide, sqrt, exp, log
$z->{divide} = $b->{divide} unless defined($a->{divide});
$z->{sqrt} = $b->{sqrt} unless defined($a->{sqrt});
$z->{exp} = $b->{exp} unless defined($a->{exp});
$z->{log} = $b->{log} unless defined($a->{log});
# Result
$z->z;
}
=head3 divide2
Divide two finalized terms, return the result in a new term or undef
sub divide2($$)
{my ($a, $b) = @_;
$a->{z} and $b->{z} or
die "Attempt to divide unfinalized terms";
# Check
return undef if
(defined($b->{divide}) and (!defined($a->{divide}) or $a->{divide}->id != $b->{divide}->id));
return undef if
(defined($b->{sqrt} ) and (!defined($a->{sqrt} ) or $a->{sqrt} ->id != $b->{sqrt} ->id));
return undef if
(defined($b->{exp} ) and (!defined($a->{exp} ) or $a->{exp} ->id != $b->{exp} ->id));
return undef if
(defined($b->{log} ) and (!defined($a->{log} ) or $a->{log} ->id != $b->{log} ->id));
# cdi
my $c = $a->{c} * $b->{d};
my $d = $a->{d} * $b->{c};
my $i = $a->{i} - $b->{i};
$c = -$c, $i = 1 if $i == -1;
my $g = gcd($c, $d);
$c /= $g;
$d /= $g;
my $z = $a->clone->c($c)->d(1)->divideInt($d)->i($i);
# v
for my $v($b->v)
{$z->vp($v, $z->vp($v)-$b->vp($v));
}
# Sqrt, divide, exp, log
delete $z->{divide} if defined($a->{divide}) and defined($b->{divide});
delete $z->{sqrt } if defined($a->{sqrt }) and defined($b->{sqrt });
delete $z->{exp } if defined($a->{exp }) and defined($b->{exp });
delete $z->{log } if defined($a->{log }) and defined($b->{log });
# Result
$z->z;
}
=head3 invert
Invert a term
sub invert($)
{my ($t) = @_;
$t->{z} or die "Attempt to invert unfinalized term";
# Check
return undef if
$t->{divide} or
$t->{sqrt} or
$t->{exp} or
$t->{log};
# cdi
my ($c, $d, $i) = ($t->{c}, $t->{d}, $t->{i});
$c = -$c if $i;
my $z = clone($t)->c($d)->d(1)->divideInt($c)->i($i);
# v
for my $v($z->v)
{$z->vp($v, $z->vp($v));
}
# Result
$z->z;
}
=head3 power
Take power of term
sub power($$)
{my ($a, $b) = @_;
$a->{z} and $b->{z} or die "Attempt to take power of unfinalized term";
# Check
return $one if $a == $one or $b == $zero;
return undef if
$a->{divide} or
$a->{sqrt} or
$a->{exp} or
$a->{log};
return undef if
$b->{d} != 1 or
$b->{i} == 1 or
$b->{divide} or
$b->{sqrt} or
$b->{exp} or
$b->{log};
# cdi
my ($c, $d, $i) = ($a->{c}, $a->{d}, $a->{i});
my $p = $b->{c};
if ($p < 0)
{$a = invert($a);
return undef unless $a;
$p = -$p;
return $a if $p == 1;
}
my $z = $a->clone->z;
$z = $z->multiply($a) for (2..$p);
$i *= $p;
$z = $z->clone->i($i);
# v
# for my $v($z->v)
# {$z->vp($v, $p*$z->vp($v));
# }
# Result
$z->z;
}
=head3 sqrt2
Square root of a term
sub sqrt2($)
{my ($t) = @_;
$t->{z} or die "Attempt to sqrt unfinalized term";
# Check
return undef if $t->{i} or
$t->{divide} or
$t->{sqrt} or
$t->{exp} or
$t->{log};
# cd
my ($c, $d, $i) = ($t->{c}, $t->{d}, 0);
$c = -$c, $i = 1 if $c < 0;
my $c2 = sqrt($c); return undef unless $c2*$c2 == $c;
my $d2 = sqrt($d); return undef unless $d2*$d2 == $d;
my $z = clone($t)->c($c2)->d($d2)->i($i);
# v
for my $v($t->v)
{my $p = $z->vp($v);
return undef unless $p % 2 == 0;
$z->vp($v, $p/2);
}
# Result
$z->z;
}
=head3 exp2
Exponential of a term
sub exp2($)
{my ($t) = @_;
$t->{z} or die "Attempt to use unfinalized term in exp";
return $one if $t == $zero;
return undef if $t->{divide} or
$t->{sqrt} or
$t->{exp} or
$t->{log};
return undef unless $t->{i} == 1;
return undef unless $t->{d} == 1 or
$t->{d} == 2 or
$t->{d} == 4;
return undef unless scalar(keys(%{$t->{v}})) == 1 and
exists($t->{v}{pi}) and
$t->{v}{pi} == 1;
my $c = $t->{c};
my $d = $t->{d};
$c *= 2 if $d == 1;
$c %= 4;
return $one if $c == 0;
return $i if $c == 1;
return $mOne if $c == 2;
return $mI if $c == 3;
}
=head3 sin2
Sine of a term
sub sin2($)
{my ($t) = @_;
$t->{z} or die "Attempt to use unfinalized term in sin";
return $zero if $t == $zero;
return undef if $t->{divide} or
$t->{sqrt} or
$t->{exp} or
$t->{log};
return undef unless $t->{i} == 0;
return undef unless scalar(keys(%{$t->{v}})) == 1;
return undef unless exists($t->{v}{pi});
return undef unless $t->{v}{pi} == 1;
my $c = $t->{c};
my $d = $t->{d};
return undef unless $d== 1 or $d == 2 or $d == 3 or $d == 6;
$c *= 6 if $d == 1;
$c *= 3 if $d == 2;
$c *= 2 if $d == 3;
$c = $c % 12;
return $zero if $c == 0;
return $half if $c == 1;
return undef if $c == 2;
return $one if $c == 3;
return undef if $c == 4;
return $half if $c == 5;
return $zero if $c == 6;
return $mHalf if $c == 7;
return $undef if $c == 8;
return $mOne if $c == 9;
return $undef if $c == 10;
return $mHalf if $c == 11;
return $zero if $c == 12;
}
=head3 cos2
Cosine of a term
sub cos2($)
{my ($t) = @_;
$t->{z} or die "Attempt to use unfinalized term in cos";
return $one if $t == $zero;
return undef if $t->{divide} or
$t->{sqrt} or
$t->{exp} or
$t->{log};
return undef unless $t->{i} == 0;
return undef unless scalar(keys(%{$t->{v}})) == 1;
return undef unless exists($t->{v}{pi});
return undef unless $t->{v}{pi} == 1;
my $c = $t->{c};
my $d = $t->{d};
return undef unless $d== 1 or $d == 2 or $d == 3 or $d == 6;
$c *= 6 if $d == 1;
$c *= 3 if $d == 2;
$c *= 2 if $d == 3;
$c = $c % 12;
return $half if $c == 10;
return $undef if $c == 11;
return $one if $c == 12;
return $one if $c == 0;
return undef if $c == 1;
return $half if $c == 2;
return $zero if $c == 3;
return $mHalf if $c == 4;
return $undef if $c == 5;
return $mOne if $c == 6;
return $undef if $c == 7;
return $mHalf if $c == 8;
return $zero if $c == 9;
}
=head3 log2
Log of a term
sub log2($)
{my ($a) = @_;
$a->{z} or die "Attempt to use unfinalized term in log";
return $zero if $a == $one;
return undef;
}
=head3 id
Get Id of a term
sub id($)
{my ($t) = @_;
$t->{id} or die "Term $t not yet finalized";
$t->{id};
}
=head3 zz
# Check term finalized
sub zz($)
{my ($t) = @_;
$t->{z} or die "Term $t not yet finalized";
$t;
}
=head3 z
Finalize creation of the term. Once a term has been finalized, it
becomes readonly, which allows optimization to be performed. =cut
my $lock = 0; # Hash locking
my $z = 0; # Term counter
my %z; # Terms finalized
sub z($)
{my ($t) = @_;
!exists($t->{z}) or die "Already finalized this term";
my $p = $t->print;
return $z{$p} if defined($z{$p});
$z{$p} = $t;
weaken($z{$p}); # Greatly reduces memory usage
$t->{s} = $p;
$t->{z} = $t->signature;
$t->{id} = ++$z;
#HashUtil lock_hash(%{$t->{v}}) if $lock;
#HashUtil lock_hash %$t if $lock;
$t;
}
#sub DESTROY($)
# {my ($t) = @_;
# delete $z{$t->{s}} if defined($t) and exists $t->{s};
# }
sub lockHashes()
{my ($l) = @_;
#HashUtil for my $t(values %z)
#HashUtil {lock_hash(%{$t->{v}});
#HashUtil lock_hash %$t;
#HashUtil }
$lock = 1;
}
=head3 print
Print
sub print($)
{my ($t) = @_;
return $t->{s} if defined($t->{s});
my @k = keys %{$t->{v}};
my $v = $t->{v};
my $s = '';
$s .= $t->{c};
$s .= '/'.$t->{d} if $t->{d} != 1;
$s .= '*i' if $t->{i} == 1;
$s .= '*$'.$_ for grep {$v->{$_} == 1} @k;
$s .= '/$'.$_ for grep {$v->{$_} == -1} @k;
$s .= '*$'.$_.'**'. $v->{$_} for grep {$v->{$_} > 1} @k;
$s .= '/$'.$_.'**'.-$v->{$_} for grep {$v->{$_} < -1} @k;
$s .= '/('. $t->{divide} .')' if $t->{divide};
$s .= '*sqrt('. $t->{sqrt} .')' if $t->{sqrt};
$s .= '*exp('. $t->{exp} .')' if $t->{exp};
$s .= '*log('. $t->{log} .')' if $t->{log};
$s;
}
=head3 constants
Useful constants
$zero = new()->c(0)->z; sub zero () {$zero}
$one = new()->z; sub one () {$one}
$two = new()->c(2)->z; sub two () {$two}
$mOne = new()->c(-1)->z; sub mOne () {$mOne}
$i = new()->i(1)->z; sub pI () {$pI}
$mI = new()->c(-1)->i(1)->z; sub mI () {$mI}
$half = new()->c( 1)->d(2)->z; sub half () {$half}
$mHalf = new()->c(-1)->d(2)->z; sub mHalf() {$mHalf}
$pi = new()->vp('pi', 1)->z; sub pi () {$pi}
=head2 import
Export L</newFromStrings> to calling package with a name specifed by the
caller, or as B<term()> by default. =cut
sub import
{my %P = (program=>@_);
my %p; $p{lc()} = $P{$_} for(keys(%P));
#_______________________________________________________________________
# New symbols term constructor - export to calling package.
#_______________________________________________________________________
my $s = "pack"."age XXXX;\n". <<'END';
no warnings 'redefine';
sub NNNN
{return SSSSnewFromStrings(@_);
}
use warnings 'redefine';
END
#_______________________________________________________________________
# Export to calling package.
#_______________________________________________________________________
my $name = 'term';
$name = $p{term} if exists($p{term});
my ($main) = caller();
my $pack = __PACKAGE__.'::';
$s=~ s/XXXX/$main/g;
$s=~ s/NNNN/$name/g;
$s=~ s/SSSS/$pack/g;
eval($s);
#_______________________________________________________________________
# Check options supplied by user
#_______________________________________________________________________
delete @p{qw(program terms)};
croak "Unknown option(s) for ". __PACKAGE__ .": ". join(' ', keys(%p))."\n\n". <<'END' if keys(%p);
Valid options are:
terms=>'name' Desired name of the constructor routine for creating
new terms. The default is 'term'.
END
}
=head2 Operators
=head3 Operator Overloads
Operator Overloads
use overload
'+' =>\&add3,
'-' =>\&negate3,
'*' =>\&multiply3,
'/' =>\÷3,
'**' =>\&power3,
'==' =>\&equals3,
'sqrt' =>\&sqrt3,
'exp' =>\&exp3,
'log' =>\&log3,
'sin' =>\&sin3,
'cos' =>\&cos3,
'""' =>\&print3,
fallback=>1;
=head3 add3
Add operator.
sub add3
{my ($a, $b) = @_;
$b = newFromString("$b") unless ref($b) eq __PACKAGE__;
$a->{z} and $b->{z} or die "Add using unfinalized terms";
$a->add($b);
}
=head3 negate3
Negate operator.
sub negate3
{my ($a, $b, $c) = @_;
if (defined($b))
{$b = newFromString("$b") unless ref($b) eq __PACKAGE__;
$a->{z} and $b->{z} or die "Negate using unfinalized terms";
return $b->subtract($a) if $c;
return $a->subtract($b) unless $c;
}
else
{$a->{z} or die "Negate single unfinalized terms";
return $a->negate;
}
}
=head3 multiply3
Multiply operator.
sub multiply3
{my ($a, $b) = @_;
$b = newFromString("$b") unless ref($b) eq __PACKAGE__;
$a->{z} and $b->{z} or die "Multiply using unfinalized terms";
$a->multiply($b);
}
=head3 divide3
Divide operator.
sub divide3
{my ($a, $b, $c) = @_;
$b = newFromString("$b") unless ref($b) eq __PACKAGE__;
$a->{z} and $b->{z} or die "Divide using unfinalized terms";
return $b->divide2($a) if $c;
return $a->divide2($b) unless $c;
}
=head3 power3
Power operator.
sub power3
{my ($a, $b) = @_;
$b = newFromString("$b") unless ref($b) eq __PACKAGE__;
$a->{z} and $b->{z} or die "Power using unfinalized terms";
$a->power($b);
}
=head3 equals3
Equals operator.
sub equals3
{my ($a, $b) = @_;
if (ref($b) eq __PACKAGE__)
{$a->{z} and $b->{z} or die "Equals using unfinalized terms";
return $a->{id} == $b->{id};
}
else
{$a->{z} or die "Equals using unfinalized terms";
return $a->print eq "$b";
}
}
=head3 print3
Print operator.
sub print3
{my ($a) = @_;
$a->{z} or die "Print of unfinalized term";
$a->print();
}
=head3 sqrt3
Square root operator.
sub sqrt3
{my ($a) = @_;
$a->{z} or die "Sqrt of unfinalized term";
$a->sqrt2();
}
=head3 exp3
Exponential operator.
sub exp3
{my ($a) = @_;
$a->{z} or die "Exp of unfinalized term";
$a->exp2();
}
=head3 sin3
Sine operator.
sub sin3
{my ($a) = @_;
$a->{z} or die "Sin of unfinalized term";
$a->sin2();
}
=head3 cos3
Cosine operator.
sub cos3
{my ($a) = @_;
$a->{z} or die "Cos of unfinalized term";
$a->cos2();
}
=head3 log3
Log operator.
sub log3
{my ($a) = @_;
$a->{z} or die "Log of unfinalized term";
$a->log2();
}
=head2 test
Tests
sub test()
{my ($a, $b, $c);
# lockHashes();
$a = n(0); $a == $zero or die "100";
$a = n(1); $a == $one or die "101";
$a = n(2); $a == $two or die "102";
$b = n(3); $b == 3 or die "103";
$c = $a+$a; $c == 4 or die "104";
$c = $a+$b; $c == 5 or die "105";
$c = $a+$b+$a+$b; $c == 10 or die "106";
$c = $a+1; $c == 3 or die "107";
$c = $a+2; $c == 4 or die "108";
$c = $b-1; $c == 2 or die "109";
$c = $b-2; $c == 1 or die "110";
$c = $b-9; $c == -6 or die "111";
$c = $a/2; $c == $one or die "112";
$c = $a/4; $c == '1/2' or die "113";
$c = $a*2/2; $c == $two or die "114";
$c = $a*2/4; $c == $one or die "115";
$c = $a**2; $c == 4 or die "116";
$c = $a**10; $c == 1024 or die "117";
$c = sqrt($a**2); $c == $a or die "118";
$d = n(-1); $d == -1 or die "119";
$c = sqrt($d); $c == '1*i' or die "120";
$d = n(4); $d == 4 or die "121";
$c = sqrt($d); $c == 2 or die "122";
$c = n('x*y2')/n('a*b2'); $c == '1*$x/$a*$y**2/$b**2' or die "122";
$a = n('x'); $a == '1*$x' or die "21";
$b = n('2*x**2'); $b == '2*$x**2' or die "22";
$c = $a+$a; $c == '2*$x' or die "23";
$c = $a+$a+$a; $c == '3*$x' or die "24";
$c = $a-$a; $c == $zero or die "25";
$c = $a-$a-$a; $c == '-1*$x' or die "26";
$c = $a*$b; $c == '2*$x**3' or die "27";
$c = $a*$b*$a*$b; $c == '4*$x**6' or die "28";
$c = $b/$a; $c == '2*$x' or die "29";
$c = $a**2/$b;
$c == '1/2' or die "29";
$c = sqrt($a**4/($b/2)); $c == $a or die "29";
$a = sin($zero); $a == -0 or die "301";
$a = sin($pi/6); $a == $half or die "302";
$a = sin($pi/2); $a == 1 or die "303";
$a = sin(5*$pi/6); $a == $half or die "304";
$a = sin(120*$pi/120); $a == $zero or die "305";
$a = sin(7*$pi/6); $a == -$half or die "306";
$a = sin(3*$pi/2); $a == -1 or die "307";
$a = sin(110*$pi/ 60); $a == '-1/2' or die "308";
$a = sin(2*$pi); $a == $zero or die "309";
$a = sin(-$zero); $a == $zero or die "311";
$a = sin(-$pi/6); $a == -$half or die "312";
$a = sin(-$pi/2); $a == -$one or die "313";
$a = sin(-5*$pi/6); $a == -$half or die "314";
$a = sin(-120*$pi/120); $a == -$zero or die "315";
$a = sin(-7*$pi/6); $a == $half or die "316";
$a = sin(-3*$pi/2); $a == $one or die "317";
$a = sin(-110*$pi/ 60); $a == $half or die "318";
$a = sin(-2*$pi); $a == $zero or die "319";
$a = cos($zero); $a == $one or die "321";
$a = cos($pi/3); $a == $half or die "322";
$a = cos($pi/2); $a == $zero or die "323";
$a = cos(4*$pi/6); $a == -$half or die "324";
$a = cos(120*$pi/120); $a == -$one or die "325";
$a = cos(8*$pi/6); $a == -$half or die "326";
$a = cos(3*$pi/2); $a == $zero or die "327";
$a = cos(100*$pi/ 60); $a == $half or die "328";
$a = cos(2*$pi); $a == $one or die "329";
$a = cos(-$zero); $a == $one or die "331";
$a = cos(-$pi/3); $a == +$half or die "332";
$a = cos(-$pi/2); $a == $zero or die "333";
$a = cos(-4*$pi/6); $a == -$half or die "334";
$a = cos(-120*$pi/120); $a == -$one or die "335";
$a = cos(-8*$pi/6); $a == -$half or die "336";
$a = cos(-3*$pi/2); $a == $zero or die "337";
$a = cos(-100*$pi/ 60); $a == $half or die "338";
$a = cos(-2*$pi); $a == $one or die "339";
$a = exp($zero); $a == $one or die "340";
$a = exp($i*$pi/2); $a == $i or die "341";
$a = exp($i*$pi); $a == -$one or die "342";
$a = exp(3*$i*$pi/2); $a == -$i or die "343";
$a = exp(4*$i*$pi/2); $a == $one or die "344";
}
test unless caller;
#_______________________________________________________________________
# Package installed successfully
#_______________________________________________________________________
1;
__DATA__
#______________________________________________________________________
# User guide.
#______________________________________________________________________
=head1 NAME
Math::Algebra::Symbols - Symbolic Algebra in Pure Perl.
User guide.
=head1 SYNOPSIS
Example symbols.pl
#!perl -w -I..
#______________________________________________________________________
# Symbolic algebra.
# Perl License.
# PhilipRBrenan@yahoo.com, 2004.
#______________________________________________________________________
use Math::Algebra::Symbols hyper=>1;
use Test::Simple tests=>5;
($n, $x, $y) = symbols(qw(n x y));
$a += ($x**8 - 1)/($x-1);
$b += sin($x)**2 + cos($x)**2;
$c += (sin($n*$x) + cos($n*$x))->d->d->d->d / (sin($n*$x)+cos($n*$x));
$d = tanh($x+$y) == (tanh($x)+tanh($y))/(1+tanh($x)*tanh($y));
($e,$f) = @{($x**2 eq 5*$x-6) > $x};
print "$a\n$b\n$c\n$d\n$e,$f\n";
ok("$a" eq '$x+$x**2+$x**3+$x**4+$x**5+$x**6+$x**7+1');
ok("$b" eq '1');
ok("$c" eq '$n**4');
ok("$d" eq '1');
ok("$e,$f" eq '2,3');
=head1 DESCRIPTION
This package supplies a set of functions and operators to manipulate
operator expressions algebraically using the familiar Perl syntax.
These expressions are constructed
from L</Symbols>, L</Operators>, and L</Functions>, and processed via
L</Methods>. For examples, see: L</Examples>.
=head2 Symbols
Symbols are created with the exported B<symbols()> constructor routine:
Example t/constants.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: constants.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>1;
my ($x, $y, $i, $o, $pi) = symbols(qw(x y i 1 pi));
ok( "$x $y $i $o $pi" eq '$x $y i 1 $pi' );
The B<symbols()> routine constructs references to symbolic variables and
symbolic constants from a list of names and integer constants.
The special symbol B<i> is recognized as the square root of B<-1>.
The special symbol B<pi> is recognized as the smallest positive real
that satisfies:
Example t/ipi.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: constants.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($i, $pi) = symbols(qw(i pi));
ok( exp($i*$pi) == -1 );
ok( exp($i*$pi) <=> '-1' );
=head3 Constructor Routine Name
If you wish to use a different name for the constructor routine, say
B<S>:
Example t/ipi2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: constants.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols symbols=>'S';
use Test::Simple tests=>2;
my ($i, $pi) = S(qw(i pi));
ok( exp($i*$pi) == -1 );
ok( exp($i*$pi) <=> '-1' );
=head3 Big Integers
Symbols automatically uses big integers if needed.
Example t/bigInt.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: bigInt.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>1;
my $z = symbols('1234567890987654321/1234567890987654321');
ok( eval $z eq '1');
=head2 Operators
L</Symbols> can be combined with L</Operators> to create symbolic expressions:
=head3 Arithmetic operators
=head4 Arithmetic Operators: B<+> B<-> B<*> B</> B<**>
Example t/x2y2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplification.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $y) = symbols(qw(x y));
ok( ($x**2-$y**2)/($x-$y) == $x+$y );
ok( ($x**2-$y**2)/($x-$y) != $x-$y );
ok( ($x**2-$y**2)/($x-$y) <=> '$x+$y' );
The operators: B<+=> B<-=> B<*=> B</=> are overloaded to work
symbolically rather than numerically. If you need numeric results, you
can always B<eval()> the resulting symbolic expression.
=head4 Square root Operator: B<sqrt>
Example t/ix.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: sqrt(-1).
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x, $i) = symbols(qw(x i));
ok( sqrt(-$x**2) == $i*$x );
ok( sqrt(-$x**2) <=> 'i*$x' );
The square root is represented by the symbol B<i>, which allows complex
expressions to be processed by Math::Complex.
=head4 Exponential Operator: B<exp>
Example t/expd.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: exp.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x, $i) = symbols(qw(x i));
ok( exp($x)->d($x) == exp($x) );
ok( exp($x)->d($x) <=> 'exp($x)' );
The exponential operator.
=head4 Logarithm Operator: B<log>
Example t/logExp.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: log: need better example.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>1;
my ($x) = symbols(qw(x));
ok( log($x) <=> 'log($x)' );
Logarithm to base B<e>.
Note: the above result is only true for x > 0. B<Symbols> does not include domain and range
specifications of the functions it uses.
=head4 Sine and Cosine Operators: B<sin> and B<cos>
Example t/sinCos.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplification.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x) = symbols(qw(x));
ok( sin($x)**2 + cos($x)**2 == 1 );
ok( sin($x)**2 + cos($x)**2 != 0 );
ok( sin($x)**2 + cos($x)**2 <=> '1' );
This famous trigonometric identity is not preprogrammed into B<Symbols>
as it is in commercial products.
Instead: an expression for B<sin()> is constructed using the complex
exponential: L</exp>, said expression is algebraically multiplied out to
prove the identity. The proof steps involve large intermediate
expressions in each step, as yet I have not provided a means to neatly
lay out these intermediate steps and thus provide a more compelling
demonstration of the ability of B<Symbols> to verify such statements
from first principles.
=head3 Relational operators
=head4 Relational operators: B<==>, B<!=>
Example t/x2y2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplification.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $y) = symbols(qw(x y));
ok( ($x**2-$y**2)/($x-$y) == $x+$y );
ok( ($x**2-$y**2)/($x-$y) != $x-$y );
ok( ($x**2-$y**2)/($x-$y) <=> '$x+$y' );
The relational equality operator B<==> compares two symbolic expressions
and returns TRUE(1) or FALSE(0) accordingly. B<!=> produces the opposite
result.
=head4 Relational operator: B<eq>
Example t/eq.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: solving.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $v, $t) = symbols(qw(x v t));
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) == $v*$t );
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) != $v+$t );
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) <=> '$v*$t' );
The relational operator B<eq> is a synonym for the minus B<-> operator,
with the expectation that later on the L<solve()|/Solving equations>
function will be used to simplify and rearrange the equation. You may
prefer to use B<eq> instead of B<-> to enhance readability, there is no
functional difference.
=head3 Complex operators
=head4 Complex operators: the B<dot> operator: B<^>
Example t/dot.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: dot operator. Note the low priority
# of the ^ operator.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($a, $b, $i) = symbols(qw(a b i));
ok( (($a+$i*$b)^($a-$i*$b)) == $a**2-$b**2 );
ok( (($a+$i*$b)^($a-$i*$b)) != $a**2+$b**2 );
ok( (($a+$i*$b)^($a-$i*$b)) <=> '$a**2-$b**2' );
Note the use of brackets: The B<^> operator has low priority.
The B<^> operator treats its left hand and right hand arguments as
complex numbers, which in turn are regarded as two dimensional vectors
to which the vector dot product is applied.
=head4 Complex operators: the B<cross> operator: B<x>
Example t/cross.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: cross operator.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $i) = symbols(qw(x i));
ok( $i*$x x $x == $x**2 );
ok( $i*$x x $x != $x**3 );
ok( $i*$x x $x <=> '$x**2' );
The B<x> operator treats its left hand and right hand arguments as
complex numbers, which in turn are regarded as two dimensional vectors
defining the sides of a parallelogram. The B<x> operator returns the
area of this parallelogram.
Note the space before the B<x>, otherwise Perl is unable to disambiguate
the expression correctly.
=head4 Complex operators: the B<conjugate> operator: B<~>
Example t/conjugate.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: dot operator. Note the low priority
# of the ^ operator.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $y, $i) = symbols(qw(x y i));
ok( ~($x+$i*$y) == $x-$i*$y );
ok( ~($x-$i*$y) == $x+$i*$y );
ok( (($x+$i*$y)^($x-$i*$y)) <=> '$x**2-$y**2' );
The B<~> operator returns the complex conjugate of its right hand side.
=head4 Complex operators: the B<modulus> operator: B<abs>
Example t/abs.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: dot operator. Note the low priority
# of the ^ operator.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $i) = symbols(qw(x i));
ok( abs($x+$i*$x) == sqrt(2*$x**2) );
ok( abs($x+$i*$x) != sqrt(2*$x**3) );
ok( abs($x+$i*$x) <=> 'sqrt(2*$x**2)' );
The B<abs> operator returns the modulus (length) of its right hand side.
=head4 Complex operators: the B<unit> operator: B<!>
Example t/unit.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: unit operator.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>4;
my ($i) = symbols(qw(i));
ok( !$i == $i );
ok( !$i <=> 'i' );
ok( !($i+1) <=> '1/(sqrt(2))+i/(sqrt(2))' );
ok( !($i-1) <=> '-1/(sqrt(2))+i/(sqrt(2))' );
The B<!> operator returns a complex number of unit length pointing in
the same direction as its right hand side.
=head3 Equation Manipulation Operators
=head4 Equation Manipulation Operators: B<Simplify> operator: B<+=>
Example t/simplify.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplify.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x) = symbols(qw(x));
ok( ($x**8 - 1)/($x-1) == $x+$x**2+$x**3+$x**4+$x**5+$x**6+$x**7+1 );
ok( ($x**8 - 1)/($x-1) <=> '$x+$x**2+$x**3+$x**4+$x**5+$x**6+$x**7+1' );
The simplify operator B<+=> is a synonym for the
L<simplify()|/"simplifying_equations:_simplify()"> method, if and only
if, the target on the left hand side initially has a value of undef.
Admittedly this is very strange behavior: it arises due to the shortage
of over-rideable operators in Perl: in particular it arises due to the
shortage of over-rideable unary operators in Perl. Never-the-less: this
operator is useful as can be seen in the L<Synopsis|/"synopsis">, and
the desired pre-condition can always achieved by using B<my>.
=head4 Equation Manipulation Operators: B<Solve> operator: B<E<gt>>
Example t/solve2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplify.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($t) = symbols(qw(t));
my $rabbit = 10 + 5 * $t;
my $fox = 7 * $t * $t;
my ($a, $b) = @{($rabbit eq $fox) > $t};
ok( "$a" eq '1/14*sqrt(305)+5/14' );
ok( "$b" eq '-1/14*sqrt(305)+5/14' );
The solve operator B<E<gt>> is a synonym for the
L<solve()|/"Solving_equations:_solve()"> method.
The priority of B<E<gt>> is higher than that of B<eq>, so the brackets
around the equation to be solved are necessary until Perl provides a
mechanism for adjusting operator priority (cf. Algol 68).
If the equation is in a single variable, the single variable
may be named after the B<E<gt>> operator without the use of [...]:
use Math::Algebra::Symbols;
my $rabbit = 10 + 5 * $t;
my $fox = 7 * $t * $t;
my ($a, $b) = @{($rabbit eq $fox) > $t};
print "$a\n";
# 1/14*sqrt(305)+5/14
If there are multiple solutions, (as in the case of polynomials), B<E<gt>>
returns an array of symbolic expressions containing the solutions.
This example was provided by Mike Schilli m@perlmeister.com.
=head2 Functions
Perl operator overloading is very useful for producing compact
representations of algebraic expressions. Unfortunately there are only a
small number of operators that Perl allows to be overloaded. The
following functions are used to provide capabilities not easily expressed
via Perl operator overloading.
These functions may either be called as methods from symbols constructed
by the L</Symbols> construction routine, or they may be exported into
the user's namespace as described in L</EXPORT>.
=head3 Trigonometric and Hyperbolic functions
=head4 Trigonometric functions
Example t/sinCos2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: methods.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>1;
my ($x, $y) = symbols(qw(x y));
ok( (sin($x)**2 == (1-cos(2*$x))/2) );
The trigonometric functions B<cos>, B<sin>, B<tan>, B<sec>, B<csc>,
B<cot> are available, either as exports to the caller's name space, or
as methods.
=head4 Hyperbolic functions
Example t/tanh.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: methods.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols hyper=>1;
use Test::Simple tests=>1;
my ($x, $y) = symbols(qw(x y));
ok( tanh($x+$y)==(tanh($x)+tanh($y))/(1+tanh($x)*tanh($y)));
The hyperbolic functions B<cosh>, B<sinh>, B<tanh>, B<sech>, B<csch>,
B<coth> are available, either as exports to the caller's name space, or
as methods.
=head3 Complex functions
=head4 Complex functions: B<re> and B<im>
use Math::Algebra::Symbols complex=>1;
Example t/reIm.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: methods.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x, $i) = symbols(qw(x i));
ok( ($i*$x)->re <=> 0 );
ok( ($i*$x)->im <=> '$x' );
The B<re> and B<im> functions return an expression which represents the
real and imaginary parts of the expression, assuming that symbolic
variables represent real numbers.
=head4 Complex functions: B<dot> and B<cross>
Example t/dotCross.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: methods.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my $i = symbols(qw(i));
ok( ($i+1)->cross($i-1) <=> 2 );
ok( ($i+1)->dot ($i-1) <=> 0 );
The B<dot> and B<cross> operators are available as functions, either as
exports to the caller's name space, or as methods.
=head4 Complex functions: B<conjugate>, B<modulus> and B<unit>
Example t/conjugate2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: methods.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my $i = symbols(qw(i));
ok( ($i+1)->unit <=> '1/(sqrt(2))+i/(sqrt(2))' );
ok( ($i+1)->modulus <=> 'sqrt(2)' );
ok( ($i+1)->conjugate <=> '1-i' );
The B<conjugate>, B<abs> and B<unit> operators are available as
functions: B<conjugate>, B<modulus> and B<unit>, either as exports to
the caller's name space, or as methods. The confusion over the naming of:
the B<abs> operator being the same as the B<modulus> complex function;
arises over the limited set of Perl operator names available for
overloading.
=head2 Methods
=head3 Methods for manipulating Equations
=head4 Simplifying equations: B<simplify()>
Example t/simplify2.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplify.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x) = symbols(qw(x));
my $y = (($x**8 - 1)/($x-1))->simplify(); # Simplify method
my $z += ($x**8 - 1)/($x-1); # Simplify via +=
ok( "$y" eq '$x+$x**2+$x**3+$x**4+$x**5+$x**6+$x**7+1' );
ok( "$z" eq '$x+$x**2+$x**3+$x**4+$x**5+$x**6+$x**7+1' );
B<Simplify()> attempts to simplify an expression. There is no general
simplification algorithm: consequently simplifications are carried out
on ad hoc basis. You may not even agree that the proposed simplification
for a given expressions is indeed any simpler than the original. It is
for these reasons that simplification has to be explicitly requested
rather than being performed automagically.
At the moment, simplifications consist of polynomial division: when the
expression consists, in essence, of one polynomial divided by another,
an attempt is made to perform polynomial division, the result is
returned if there is no remainder.
The B<+=> operator may be used to simplify and assign an expression to a
Perl variable. Perl operator overloading precludes the use of B<=> in this
manner.
=head4 Substituting into equations: B<sub()>
Example t/sub.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: expression substitution for a variable.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>2;
my ($x, $y) = symbols(qw(x y));
my $e = 1+$x+$x**2/2+$x**3/6+$x**4/24+$x**5/120;
ok( $e->sub(x=>$y**2, z=>2) <=> '$y**2+1/2*$y**4+1/6*$y**6+1/24*$y**8+1/120*$y**10+1' );
ok( $e->sub(x=>1) <=> '163/60');
The B<sub()> function example on line B<#1> demonstrates replacing
variables with expressions. The replacement specified for B<z> has no
effect as B<z> is not present in this equation.
Line B<#2> demonstrates the resulting rational fraction that arises when
all the variables have been replaced by constants. This package does not
convert fractions to decimal expressions in case there is a loss of
accuracy, however:
my $e2 = $e->sub(x=>1);
$result = eval "$e2";
or similar will produce approximate results.
At the moment only variables can be replaced by expressions. Mike
Schilli, m@perlmeister.com, has proposed that substitutions for
expressions should also be allowed, as in:
$x/$y => $z
=head4 Solving equations: B<solve()>
Example t/solve1.t
#!perl -w
#______________________________________________________________________
# Symbolic algebra: examples: simplify.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests=>3;
my ($x, $v, $t) = symbols(qw(x v t));
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) == $v*$t );
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) != $v/$t );
ok( ($v eq $x / $t)->solve(qw(x in terms of v t)) <=> '$v*$t' );
B<solve()> assumes that the equation on the left hand side is equal to
zero, applies various simplifications, then attempts to rearrange the
equation to obtain an equation for the first variable in the parameter
list assuming that the other terms mentioned in the parameter list are
known constants. There may of course be other unknown free variables in
the equation to be solved: the proposed solution is automatically tested
against the original equation to check that the proposed solution
removes these variables, an error is reported via B<die()> if it does not.
Example t/solve.t
#!perl -w -I..
#______________________________________________________________________
# Symbolic algebra: quadratic equation.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::Simple tests => 2;
my ($x) = symbols(qw(x));
my $p = $x**2-5*$x+6; # Quadratic polynomial
my ($a, $b) = @{($p > $x )}; # Solve for x
print "x=$a,$b\n"; # Roots
ok($a == 2);
ok($b == 3);
If there are multiple solutions, (as in the case of polynomials), B<solve()>
returns an array of symbolic expressions containing the solutions.
=head3 Methods for performing Calculus
=head4 Differentiation: B<d()>
Example t/differentiation.t
#!perl -w -I..
#______________________________________________________________________
# Symbolic algebra.
# PhilipRBrenan@yahoo.com, 2004, Perl License.
#______________________________________________________________________
use Math::Algebra::Symbols;
use Test::More tests => 5;
$x = symbols(qw(x));
ok( sin($x) == sin($x)->d->d->d->d);
ok( cos($x) == cos($x)->d->d->d->d);
ok( exp($x) == exp($x)->d($x)->d('x')->d->d);
ok( (1/$x)->d == -1/$x**2);
ok( exp($x)->d->d->d->d <=> 'exp($x)' );
B<d()> differentiates the equation on the left hand side by the named
variable.
The variable to be differentiated by may be explicitly specified,
either as a string or as single symbol; or it may be heuristically
guessed as follows:
If the equation to be differentiated refers to only one symbol, then
that symbol is used. If several symbols are present in the equation, but
only one of B<t>, B<x>, B<y>, B<z> is present, then that variable is
used in honor of Newton, Leibnitz, Cauchy.
=head2 Example of Equation Solving: the focii of a hyperbola:
use Math::Algebra::Symbols;
my ($a, $b, $x, $y, $i, $o) = symbols(qw(a b x y i 1));
print
"Hyperbola: Constant difference between distances from focii to locus of y=1/x",
"\n Assume by symmetry the focii are on ",
"\n the line y=x: ", $f1 = $x + $i * $x,
"\n and equidistant from the origin: ", $f2 = -$f1,
"\n Choose a convenient point on y=1/x: ", $a = $o+$i,
"\n and a general point on y=1/x: ", $b = $y+$i/$y,
"\n Difference in distances from focii",
"\n From convenient point: ", $A = abs($a - $f2) - abs($a - $f1),
"\n From general point: ", $B = abs($b - $f2) + abs($b - $f1),
"\n\n Solving for x we get: x=", ($A - $B) > $x,
"\n (should be: sqrt(2))",
"\n Which is indeed constant, as was to be demonstrated\n";
This example demonstrates the power of symbolic processing by finding the
focii of the curve B<y=1/x>, and incidentally, demonstrating that this curve
is a hyperbola.
=head1 EXPORTS
use Math::Algebra::Symbols
symbols=>'S',
trig => 1,
hyper => 1,
complex=> 1;
=over
=item trig=>0
The default, do not export trigonometric functions.
=item trig=>1
Export trigonometric functions: B<tan>, B<sec>, B<csc>, B<cot> to the
caller's namespace. B<sin>, B<cos> are created by default by overloading
the existing Perl B<sin> and B<cos> operators.
=item B<trigonometric>
Alias of B<trig>
=item hyperbolic=>0
The default, do not export hyperbolic functions.
=item hyper=>1
Export hyperbolic functions: B<sinh>, B<cosh>, B<tanh>, B<sech>,
B<csch>, B<coth> to the caller's namespace.
=item B<hyperbolic>
Alias of B<hyper>
=item complex=>0
The default, do not export complex functions
=item complex=>1
Export complex functions: B<conjugate>, B<cross>, B<dot>, B<im>,
B<modulus>, B<re>, B<unit> to the caller's namespace.
=back
=head1 PACKAGES
The B<Symbols> packages manipulate a sum of products representation of
an algebraic equation. The B<Symbols> package is the user interface to
the functionality supplied by the B<Symbols::Sum> and B<Symbols::Term>
packages.
=head2 Math::Algebra::Symbols::Term
B<Symbols::Term> represents a product term. A product term consists of the
number B<1>, optionally multiplied by:
=over
=item Variables
any number of variables raised to integer powers,
=item Coefficient
An integer coefficient optionally divided by a positive integer divisor,
both represented as BigInts if necessary.
=item Sqrt
The sqrt of of any symbolic expression representable by the B<Symbols>
package, including minus one: represented as B<i>.
=item Reciprocal
The multiplicative inverse of any symbolic expression representable by
the B<Symbols> package: i.e. a B<SymbolsTerm> may be divided by any
symbolic expression representable by the B<Symbols> package.
=item Exp
The number B<e> raised to the power of any symbolic expression
representable by the B<Symbols> package.
=item Log
The logarithm to base B<e> of any symbolic expression representable by
the B<Symbols> package.
=back
Thus B<SymbolsTerm> can represent expressions like:
2/3*$x**2*$y**-3*exp($i*$pi)*sqrt($z**3) / $x
but not:
$x + $y
for which package B<Symbols::Sum> is required.
=head2 Math::Algebra::Symbols::Sum
B<Symbols::Sum> represents a sum of product terms supplied by
B<Symbols::Term> and thus behaves as a polynomial. Operations such as
equation solving and differentiation are applied at this level.
The main benefit of programming B<Symbols::Term> and B<Symbols::Sum> as two
separate but related packages is Object Oriented Polymorphism. I.e. both
packages need to multiply items together: each package has its own B<multiply> method,
with Perl method lookup selecting the appropriate one as required.
=head2 Math::Algebra::Symbols
Packaging the user functionality alone and separately in package
B<Symbols> allows the internal functions to be conveniently hidden from
user scripts.
=head1 AUTHOR
Philip R Brenan at B<philiprbrenan@yahoo.com>
=head2 Credits
=head3 Author
philiprbrenan@yahoo.com
=head3 Copyright
philiprbrenan@yahoo.com, 2004
=head3 License
Perl License.
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