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1209 lines
38 KiB
1209 lines
38 KiB
package overload;
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sub nil {}
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sub OVERLOAD {
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$package = shift;
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my %arg = @_;
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my ($sub, $fb);
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$ {$package . "::OVERLOAD"}{dummy}++; # Register with magic by touching.
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*{$package . "::()"} = \&nil; # Make it findable via fetchmethod.
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for (keys %arg) {
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if ($_ eq 'fallback') {
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$fb = $arg{$_};
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} else {
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$sub = $arg{$_};
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if (not ref $sub and $sub !~ /::/) {
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$ {$package . "::(" . $_} = $sub;
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$sub = \&nil;
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}
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#print STDERR "Setting `$ {'package'}::\cO$_' to \\&`$sub'.\n";
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*{$package . "::(" . $_} = \&{ $sub };
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}
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}
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${$package . "::()"} = $fb; # Make it findable too (fallback only).
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}
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sub import {
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$package = (caller())[0];
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# *{$package . "::OVERLOAD"} = \&OVERLOAD;
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shift;
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$package->overload::OVERLOAD(@_);
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}
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sub unimport {
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$package = (caller())[0];
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${$package . "::OVERLOAD"}{dummy}++; # Upgrade the table
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shift;
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for (@_) {
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if ($_ eq 'fallback') {
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undef $ {$package . "::()"};
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} else {
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delete $ {$package . "::"}{"(" . $_};
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}
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}
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}
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sub Overloaded {
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my $package = shift;
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$package = ref $package if ref $package;
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$package->can('()');
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}
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sub ov_method {
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my $globref = shift;
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return undef unless $globref;
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my $sub = \&{*$globref};
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return $sub if $sub ne \&nil;
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return shift->can($ {*$globref});
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}
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sub OverloadedStringify {
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my $package = shift;
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$package = ref $package if ref $package;
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#$package->can('(""')
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ov_method mycan($package, '(""'), $package
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or ov_method mycan($package, '(0+'), $package
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or ov_method mycan($package, '(bool'), $package
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or ov_method mycan($package, '(nomethod'), $package;
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}
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sub Method {
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my $package = shift;
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$package = ref $package if ref $package;
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#my $meth = $package->can('(' . shift);
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ov_method mycan($package, '(' . shift), $package;
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#return $meth if $meth ne \&nil;
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#return $ {*{$meth}};
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}
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sub AddrRef {
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my $package = ref $_[0];
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return "$_[0]" unless $package;
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bless $_[0], overload::Fake; # Non-overloaded package
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my $str = "$_[0]";
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bless $_[0], $package; # Back
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$package . substr $str, index $str, '=';
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}
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sub StrVal {
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(OverloadedStringify($_[0])) ?
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(AddrRef(shift)) :
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"$_[0]";
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}
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sub mycan { # Real can would leave stubs.
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my ($package, $meth) = @_;
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return \*{$package . "::$meth"} if defined &{$package . "::$meth"};
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my $p;
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foreach $p (@{$package . "::ISA"}) {
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my $out = mycan($p, $meth);
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return $out if $out;
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}
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return undef;
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}
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%constants = (
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'integer' => 0x1000,
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'float' => 0x2000,
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'binary' => 0x4000,
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'q' => 0x8000,
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'qr' => 0x10000,
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);
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%ops = ( with_assign => "+ - * / % ** << >> x .",
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assign => "+= -= *= /= %= **= <<= >>= x= .=",
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str_comparison => "< <= > >= == !=",
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'3way_comparison'=> "<=> cmp",
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num_comparison => "lt le gt ge eq ne",
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binary => "& | ^",
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unary => "neg ! ~",
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mutators => '++ --',
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func => "atan2 cos sin exp abs log sqrt",
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conversion => 'bool "" 0+',
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special => 'nomethod fallback =');
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sub constant {
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# Arguments: what, sub
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while (@_) {
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$^H{$_[0]} = $_[1];
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$^H |= $constants{$_[0]} | 0x20000;
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shift, shift;
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}
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}
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sub remove_constant {
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# Arguments: what, sub
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while (@_) {
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delete $^H{$_[0]};
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$^H &= ~ $constants{$_[0]};
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shift, shift;
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}
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}
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1;
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__END__
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=head1 NAME
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overload - Package for overloading perl operations
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=head1 SYNOPSIS
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package SomeThing;
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use overload
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'+' => \&myadd,
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'-' => \&mysub;
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# etc
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...
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package main;
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$a = new SomeThing 57;
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$b=5+$a;
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...
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if (overload::Overloaded $b) {...}
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...
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$strval = overload::StrVal $b;
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=head1 DESCRIPTION
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=head2 Declaration of overloaded functions
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The compilation directive
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package Number;
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use overload
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"+" => \&add,
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"*=" => "muas";
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declares function Number::add() for addition, and method muas() in
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the "class" C<Number> (or one of its base classes)
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for the assignment form C<*=> of multiplication.
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Arguments of this directive come in (key, value) pairs. Legal values
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are values legal inside a C<&{ ... }> call, so the name of a
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subroutine, a reference to a subroutine, or an anonymous subroutine
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will all work. Note that values specified as strings are
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interpreted as methods, not subroutines. Legal keys are listed below.
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The subroutine C<add> will be called to execute C<$a+$b> if $a
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is a reference to an object blessed into the package C<Number>, or if $a is
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not an object from a package with defined mathemagic addition, but $b is a
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reference to a C<Number>. It can also be called in other situations, like
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C<$a+=7>, or C<$a++>. See L<MAGIC AUTOGENERATION>. (Mathemagical
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methods refer to methods triggered by an overloaded mathematical
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operator.)
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Since overloading respects inheritance via the @ISA hierarchy, the
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above declaration would also trigger overloading of C<+> and C<*=> in
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all the packages which inherit from C<Number>.
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=head2 Calling Conventions for Binary Operations
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The functions specified in the C<use overload ...> directive are called
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with three (in one particular case with four, see L<Last Resort>)
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arguments. If the corresponding operation is binary, then the first
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two arguments are the two arguments of the operation. However, due to
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general object calling conventions, the first argument should always be
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an object in the package, so in the situation of C<7+$a>, the
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order of the arguments is interchanged. It probably does not matter
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when implementing the addition method, but whether the arguments
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are reversed is vital to the subtraction method. The method can
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query this information by examining the third argument, which can take
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three different values:
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=over 7
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=item FALSE
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the order of arguments is as in the current operation.
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=item TRUE
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the arguments are reversed.
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=item C<undef>
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the current operation is an assignment variant (as in
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C<$a+=7>), but the usual function is called instead. This additional
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information can be used to generate some optimizations. Compare
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L<Calling Conventions for Mutators>.
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=back
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=head2 Calling Conventions for Unary Operations
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Unary operation are considered binary operations with the second
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argument being C<undef>. Thus the functions that overloads C<{"++"}>
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is called with arguments C<($a,undef,'')> when $a++ is executed.
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=head2 Calling Conventions for Mutators
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Two types of mutators have different calling conventions:
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=over
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=item C<++> and C<-->
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The routines which implement these operators are expected to actually
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I<mutate> their arguments. So, assuming that $obj is a reference to a
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number,
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sub incr { my $n = $ {$_[0]}; ++$n; $_[0] = bless \$n}
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is an appropriate implementation of overloaded C<++>. Note that
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sub incr { ++$ {$_[0]} ; shift }
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is OK if used with preincrement and with postincrement. (In the case
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of postincrement a copying will be performed, see L<Copy Constructor>.)
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=item C<x=> and other assignment versions
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There is nothing special about these methods. They may change the
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value of their arguments, and may leave it as is. The result is going
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to be assigned to the value in the left-hand-side if different from
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this value.
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This allows for the same method to be used as overloaded C<+=> and
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C<+>. Note that this is I<allowed>, but not recommended, since by the
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semantic of L<"Fallback"> Perl will call the method for C<+> anyway,
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if C<+=> is not overloaded.
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=back
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B<Warning.> Due to the presense of assignment versions of operations,
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routines which may be called in assignment context may create
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self-referential structures. Currently Perl will not free self-referential
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structures until cycles are C<explicitly> broken. You may get problems
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when traversing your structures too.
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Say,
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use overload '+' => sub { bless [ \$_[0], \$_[1] ] };
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is asking for trouble, since for code C<$obj += $foo> the subroutine
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is called as C<$obj = add($obj, $foo, undef)>, or C<$obj = [\$obj,
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\$foo]>. If using such a subroutine is an important optimization, one
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can overload C<+=> explicitly by a non-"optimized" version, or switch
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to non-optimized version if C<not defined $_[2]> (see
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L<Calling Conventions for Binary Operations>).
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Even if no I<explicit> assignment-variants of operators are present in
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the script, they may be generated by the optimizer. Say, C<",$obj,"> or
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C<',' . $obj . ','> may be both optimized to
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my $tmp = ',' . $obj; $tmp .= ',';
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=head2 Overloadable Operations
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The following symbols can be specified in C<use overload> directive:
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=over 5
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=item * I<Arithmetic operations>
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"+", "+=", "-", "-=", "*", "*=", "/", "/=", "%", "%=",
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"**", "**=", "<<", "<<=", ">>", ">>=", "x", "x=", ".", ".=",
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For these operations a substituted non-assignment variant can be called if
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the assignment variant is not available. Methods for operations "C<+>",
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"C<->", "C<+=>", and "C<-=>" can be called to automatically generate
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increment and decrement methods. The operation "C<->" can be used to
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autogenerate missing methods for unary minus or C<abs>.
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See L<"MAGIC AUTOGENERATION">, L<"Calling Conventions for Mutators"> and
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L<"Calling Conventions for Binary Operations">) for details of these
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substitutions.
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=item * I<Comparison operations>
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"<", "<=", ">", ">=", "==", "!=", "<=>",
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"lt", "le", "gt", "ge", "eq", "ne", "cmp",
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If the corresponding "spaceship" variant is available, it can be
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used to substitute for the missing operation. During C<sort>ing
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arrays, C<cmp> is used to compare values subject to C<use overload>.
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=item * I<Bit operations>
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"&", "^", "|", "neg", "!", "~",
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"C<neg>" stands for unary minus. If the method for C<neg> is not
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specified, it can be autogenerated using the method for
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subtraction. If the method for "C<!>" is not specified, it can be
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autogenerated using the methods for "C<bool>", or "C<\"\">", or "C<0+>".
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=item * I<Increment and decrement>
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"++", "--",
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If undefined, addition and subtraction methods can be
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used instead. These operations are called both in prefix and
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postfix form.
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=item * I<Transcendental functions>
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"atan2", "cos", "sin", "exp", "abs", "log", "sqrt",
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If C<abs> is unavailable, it can be autogenerated using methods
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for "E<lt>" or "E<lt>=E<gt>" combined with either unary minus or subtraction.
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=item * I<Boolean, string and numeric conversion>
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"bool", "\"\"", "0+",
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If one or two of these operations are unavailable, the remaining ones can
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be used instead. C<bool> is used in the flow control operators
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(like C<while>) and for the ternary "C<?:>" operation. These functions can
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return any arbitrary Perl value. If the corresponding operation for this value
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is overloaded too, that operation will be called again with this value.
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=item * I<Special>
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"nomethod", "fallback", "=",
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see L<SPECIAL SYMBOLS FOR C<use overload>>.
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=back
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See L<"Fallback"> for an explanation of when a missing method can be
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autogenerated.
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A computer-readable form of the above table is available in the hash
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%overload::ops, with values being space-separated lists of names:
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with_assign => '+ - * / % ** << >> x .',
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assign => '+= -= *= /= %= **= <<= >>= x= .=',
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str_comparison => '< <= > >= == !=',
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'3way_comparison'=> '<=> cmp',
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num_comparison => 'lt le gt ge eq ne',
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binary => '& | ^',
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unary => 'neg ! ~',
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mutators => '++ --',
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func => 'atan2 cos sin exp abs log sqrt',
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conversion => 'bool "" 0+',
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special => 'nomethod fallback ='
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=head2 Inheritance and overloading
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Inheritance interacts with overloading in two ways.
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=over
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=item Strings as values of C<use overload> directive
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If C<value> in
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use overload key => value;
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is a string, it is interpreted as a method name.
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=item Overloading of an operation is inherited by derived classes
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Any class derived from an overloaded class is also overloaded. The
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set of overloaded methods is the union of overloaded methods of all
|
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the ancestors. If some method is overloaded in several ancestor, then
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which description will be used is decided by the usual inheritance
|
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rules:
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If C<A> inherits from C<B> and C<C> (in this order), C<B> overloads
|
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C<+> with C<\&D::plus_sub>, and C<C> overloads C<+> by C<"plus_meth">,
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then the subroutine C<D::plus_sub> will be called to implement
|
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operation C<+> for an object in package C<A>.
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=back
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Note that since the value of the C<fallback> key is not a subroutine,
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its inheritance is not governed by the above rules. In the current
|
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implementation, the value of C<fallback> in the first overloaded
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ancestor is used, but this is accidental and subject to change.
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|
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=head1 SPECIAL SYMBOLS FOR C<use overload>
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Three keys are recognized by Perl that are not covered by the above
|
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description.
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=head2 Last Resort
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|
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C<"nomethod"> should be followed by a reference to a function of four
|
|
parameters. If defined, it is called when the overloading mechanism
|
|
cannot find a method for some operation. The first three arguments of
|
|
this function coincide with the arguments for the corresponding method if
|
|
it were found, the fourth argument is the symbol
|
|
corresponding to the missing method. If several methods are tried,
|
|
the last one is used. Say, C<1-$a> can be equivalent to
|
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|
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&nomethodMethod($a,1,1,"-")
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|
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if the pair C<"nomethod" =E<gt> "nomethodMethod"> was specified in the
|
|
C<use overload> directive.
|
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|
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If some operation cannot be resolved, and there is no function
|
|
assigned to C<"nomethod">, then an exception will be raised via die()--
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|
unless C<"fallback"> was specified as a key in C<use overload> directive.
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|
|
|
=head2 Fallback
|
|
|
|
The key C<"fallback"> governs what to do if a method for a particular
|
|
operation is not found. Three different cases are possible depending on
|
|
the value of C<"fallback">:
|
|
|
|
=over 16
|
|
|
|
=item * C<undef>
|
|
|
|
Perl tries to use a
|
|
substituted method (see L<MAGIC AUTOGENERATION>). If this fails, it
|
|
then tries to calls C<"nomethod"> value; if missing, an exception
|
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will be raised.
|
|
|
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=item * TRUE
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|
|
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The same as for the C<undef> value, but no exception is raised. Instead,
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|
it silently reverts to what it would have done were there no C<use overload>
|
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present.
|
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|
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=item * defined, but FALSE
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|
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No autogeneration is tried. Perl tries to call
|
|
C<"nomethod"> value, and if this is missing, raises an exception.
|
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|
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=back
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|
|
|
B<Note.> C<"fallback"> inheritance via @ISA is not carved in stone
|
|
yet, see L<"Inheritance and overloading">.
|
|
|
|
=head2 Copy Constructor
|
|
|
|
The value for C<"="> is a reference to a function with three
|
|
arguments, i.e., it looks like the other values in C<use
|
|
overload>. However, it does not overload the Perl assignment
|
|
operator. This would go against Camel hair.
|
|
|
|
This operation is called in the situations when a mutator is applied
|
|
to a reference that shares its object with some other reference, such
|
|
as
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|
|
$a=$b;
|
|
++$a;
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|
|
To make this change $a and not change $b, a copy of C<$$a> is made,
|
|
and $a is assigned a reference to this new object. This operation is
|
|
done during execution of the C<++$a>, and not during the assignment,
|
|
(so before the increment C<$$a> coincides with C<$$b>). This is only
|
|
done if C<++> is expressed via a method for C<'++'> or C<'+='> (or
|
|
C<nomethod>). Note that if this operation is expressed via C<'+'>
|
|
a nonmutator, i.e., as in
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|
|
$a=$b;
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|
$a=$a+1;
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|
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then C<$a> does not reference a new copy of C<$$a>, since $$a does not
|
|
appear as lvalue when the above code is executed.
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|
|
If the copy constructor is required during the execution of some mutator,
|
|
but a method for C<'='> was not specified, it can be autogenerated as a
|
|
string copy if the object is a plain scalar.
|
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|
|
=over 5
|
|
|
|
=item B<Example>
|
|
|
|
The actually executed code for
|
|
|
|
$a=$b;
|
|
Something else which does not modify $a or $b....
|
|
++$a;
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|
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may be
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|
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$a=$b;
|
|
Something else which does not modify $a or $b....
|
|
$a = $a->clone(undef,"");
|
|
$a->incr(undef,"");
|
|
|
|
if $b was mathemagical, and C<'++'> was overloaded with C<\&incr>,
|
|
C<'='> was overloaded with C<\&clone>.
|
|
|
|
=back
|
|
|
|
Same behaviour is triggered by C<$b = $a++>, which is consider a synonym for
|
|
C<$b = $a; ++$a>.
|
|
|
|
=head1 MAGIC AUTOGENERATION
|
|
|
|
If a method for an operation is not found, and the value for C<"fallback"> is
|
|
TRUE or undefined, Perl tries to autogenerate a substitute method for
|
|
the missing operation based on the defined operations. Autogenerated method
|
|
substitutions are possible for the following operations:
|
|
|
|
=over 16
|
|
|
|
=item I<Assignment forms of arithmetic operations>
|
|
|
|
C<$a+=$b> can use the method for C<"+"> if the method for C<"+=">
|
|
is not defined.
|
|
|
|
=item I<Conversion operations>
|
|
|
|
String, numeric, and boolean conversion are calculated in terms of one
|
|
another if not all of them are defined.
|
|
|
|
=item I<Increment and decrement>
|
|
|
|
The C<++$a> operation can be expressed in terms of C<$a+=1> or C<$a+1>,
|
|
and C<$a--> in terms of C<$a-=1> and C<$a-1>.
|
|
|
|
=item C<abs($a)>
|
|
|
|
can be expressed in terms of C<$aE<lt>0> and C<-$a> (or C<0-$a>).
|
|
|
|
=item I<Unary minus>
|
|
|
|
can be expressed in terms of subtraction.
|
|
|
|
=item I<Negation>
|
|
|
|
C<!> and C<not> can be expressed in terms of boolean conversion, or
|
|
string or numerical conversion.
|
|
|
|
=item I<Concatenation>
|
|
|
|
can be expressed in terms of string conversion.
|
|
|
|
=item I<Comparison operations>
|
|
|
|
can be expressed in terms of its "spaceship" counterpart: either
|
|
C<E<lt>=E<gt>> or C<cmp>:
|
|
|
|
<, >, <=, >=, ==, != in terms of <=>
|
|
lt, gt, le, ge, eq, ne in terms of cmp
|
|
|
|
=item I<Copy operator>
|
|
|
|
can be expressed in terms of an assignment to the dereferenced value, if this
|
|
value is a scalar and not a reference.
|
|
|
|
=back
|
|
|
|
=head1 Losing overloading
|
|
|
|
The restriction for the comparison operation is that even if, for example,
|
|
`C<cmp>' should return a blessed reference, the autogenerated `C<lt>'
|
|
function will produce only a standard logical value based on the
|
|
numerical value of the result of `C<cmp>'. In particular, a working
|
|
numeric conversion is needed in this case (possibly expressed in terms of
|
|
other conversions).
|
|
|
|
Similarly, C<.=> and C<x=> operators lose their mathemagical properties
|
|
if the string conversion substitution is applied.
|
|
|
|
When you chop() a mathemagical object it is promoted to a string and its
|
|
mathemagical properties are lost. The same can happen with other
|
|
operations as well.
|
|
|
|
=head1 Run-time Overloading
|
|
|
|
Since all C<use> directives are executed at compile-time, the only way to
|
|
change overloading during run-time is to
|
|
|
|
eval 'use overload "+" => \&addmethod';
|
|
|
|
You can also use
|
|
|
|
eval 'no overload "+", "--", "<="';
|
|
|
|
though the use of these constructs during run-time is questionable.
|
|
|
|
=head1 Public functions
|
|
|
|
Package C<overload.pm> provides the following public functions:
|
|
|
|
=over 5
|
|
|
|
=item overload::StrVal(arg)
|
|
|
|
Gives string value of C<arg> as in absence of stringify overloading.
|
|
|
|
=item overload::Overloaded(arg)
|
|
|
|
Returns true if C<arg> is subject to overloading of some operations.
|
|
|
|
=item overload::Method(obj,op)
|
|
|
|
Returns C<undef> or a reference to the method that implements C<op>.
|
|
|
|
=back
|
|
|
|
=head1 Overloading constants
|
|
|
|
For some application Perl parser mangles constants too much. It is possible
|
|
to hook into this process via overload::constant() and overload::remove_constant()
|
|
functions.
|
|
|
|
These functions take a hash as an argument. The recognized keys of this hash
|
|
are
|
|
|
|
=over 8
|
|
|
|
=item integer
|
|
|
|
to overload integer constants,
|
|
|
|
=item float
|
|
|
|
to overload floating point constants,
|
|
|
|
=item binary
|
|
|
|
to overload octal and hexadecimal constants,
|
|
|
|
=item q
|
|
|
|
to overload C<q>-quoted strings, constant pieces of C<qq>- and C<qx>-quoted
|
|
strings and here-documents,
|
|
|
|
=item qr
|
|
|
|
to overload constant pieces of regular expressions.
|
|
|
|
=back
|
|
|
|
The corresponding values are references to functions which take three arguments:
|
|
the first one is the I<initial> string form of the constant, the second one
|
|
is how Perl interprets this constant, the third one is how the constant is used.
|
|
Note that the initial string form does not
|
|
contain string delimiters, and has backslashes in backslash-delimiter
|
|
combinations stripped (thus the value of delimiter is not relevant for
|
|
processing of this string). The return value of this function is how this
|
|
constant is going to be interpreted by Perl. The third argument is undefined
|
|
unless for overloaded C<q>- and C<qr>- constants, it is C<q> in single-quote
|
|
context (comes from strings, regular expressions, and single-quote HERE
|
|
documents), it is C<tr> for arguments of C<tr>/C<y> operators,
|
|
it is C<s> for right-hand side of C<s>-operator, and it is C<qq> otherwise.
|
|
|
|
Since an expression C<"ab$cd,,"> is just a shortcut for C<'ab' . $cd . ',,'>,
|
|
it is expected that overloaded constant strings are equipped with reasonable
|
|
overloaded catenation operator, otherwise absurd results will result.
|
|
Similarly, negative numbers are considered as negations of positive constants.
|
|
|
|
Note that it is probably meaningless to call the functions overload::constant()
|
|
and overload::remove_constant() from anywhere but import() and unimport() methods.
|
|
From these methods they may be called as
|
|
|
|
sub import {
|
|
shift;
|
|
return unless @_;
|
|
die "unknown import: @_" unless @_ == 1 and $_[0] eq ':constant';
|
|
overload::constant integer => sub {Math::BigInt->new(shift)};
|
|
}
|
|
|
|
B<BUGS> Currently overloaded-ness of constants does not propagate
|
|
into C<eval '...'>.
|
|
|
|
=head1 IMPLEMENTATION
|
|
|
|
What follows is subject to change RSN.
|
|
|
|
The table of methods for all operations is cached in magic for the
|
|
symbol table hash for the package. The cache is invalidated during
|
|
processing of C<use overload>, C<no overload>, new function
|
|
definitions, and changes in @ISA. However, this invalidation remains
|
|
unprocessed until the next C<bless>ing into the package. Hence if you
|
|
want to change overloading structure dynamically, you'll need an
|
|
additional (fake) C<bless>ing to update the table.
|
|
|
|
(Every SVish thing has a magic queue, and magic is an entry in that
|
|
queue. This is how a single variable may participate in multiple
|
|
forms of magic simultaneously. For instance, environment variables
|
|
regularly have two forms at once: their %ENV magic and their taint
|
|
magic. However, the magic which implements overloading is applied to
|
|
the stashes, which are rarely used directly, thus should not slow down
|
|
Perl.)
|
|
|
|
If an object belongs to a package using overload, it carries a special
|
|
flag. Thus the only speed penalty during arithmetic operations without
|
|
overloading is the checking of this flag.
|
|
|
|
In fact, if C<use overload> is not present, there is almost no overhead
|
|
for overloadable operations, so most programs should not suffer
|
|
measurable performance penalties. A considerable effort was made to
|
|
minimize the overhead when overload is used in some package, but the
|
|
arguments in question do not belong to packages using overload. When
|
|
in doubt, test your speed with C<use overload> and without it. So far
|
|
there have been no reports of substantial speed degradation if Perl is
|
|
compiled with optimization turned on.
|
|
|
|
There is no size penalty for data if overload is not used. The only
|
|
size penalty if overload is used in some package is that I<all> the
|
|
packages acquire a magic during the next C<bless>ing into the
|
|
package. This magic is three-words-long for packages without
|
|
overloading, and carries the cache table if the package is overloaded.
|
|
|
|
Copying (C<$a=$b>) is shallow; however, a one-level-deep copying is
|
|
carried out before any operation that can imply an assignment to the
|
|
object $a (or $b) refers to, like C<$a++>. You can override this
|
|
behavior by defining your own copy constructor (see L<"Copy Constructor">).
|
|
|
|
It is expected that arguments to methods that are not explicitly supposed
|
|
to be changed are constant (but this is not enforced).
|
|
|
|
=head1 Metaphor clash
|
|
|
|
One may wonder why the semantic of overloaded C<=> is so counter intuitive.
|
|
If it I<looks> counter intuitive to you, you are subject to a metaphor
|
|
clash.
|
|
|
|
Here is a Perl object metaphor:
|
|
|
|
I< object is a reference to blessed data>
|
|
|
|
and an arithmetic metaphor:
|
|
|
|
I< object is a thing by itself>.
|
|
|
|
The I<main> problem of overloading C<=> is the fact that these metaphors
|
|
imply different actions on the assignment C<$a = $b> if $a and $b are
|
|
objects. Perl-think implies that $a becomes a reference to whatever
|
|
$b was referencing. Arithmetic-think implies that the value of "object"
|
|
$a is changed to become the value of the object $b, preserving the fact
|
|
that $a and $b are separate entities.
|
|
|
|
The difference is not relevant in the absence of mutators. After
|
|
a Perl-way assignment an operation which mutates the data referenced by $a
|
|
would change the data referenced by $b too. Effectively, after
|
|
C<$a = $b> values of $a and $b become I<indistinguishable>.
|
|
|
|
On the other hand, anyone who has used algebraic notation knows the
|
|
expressive power of the arithmetic metaphor. Overloading works hard
|
|
to enable this metaphor while preserving the Perlian way as far as
|
|
possible. Since it is not not possible to freely mix two contradicting
|
|
metaphors, overloading allows the arithmetic way to write things I<as
|
|
far as all the mutators are called via overloaded access only>. The
|
|
way it is done is described in L<Copy Constructor>.
|
|
|
|
If some mutator methods are directly applied to the overloaded values,
|
|
one may need to I<explicitly unlink> other values which references the
|
|
same value:
|
|
|
|
$a = new Data 23;
|
|
...
|
|
$b = $a; # $b is "linked" to $a
|
|
...
|
|
$a = $a->clone; # Unlink $b from $a
|
|
$a->increment_by(4);
|
|
|
|
Note that overloaded access makes this transparent:
|
|
|
|
$a = new Data 23;
|
|
$b = $a; # $b is "linked" to $a
|
|
$a += 4; # would unlink $b automagically
|
|
|
|
However, it would not make
|
|
|
|
$a = new Data 23;
|
|
$a = 4; # Now $a is a plain 4, not 'Data'
|
|
|
|
preserve "objectness" of $a. But Perl I<has> a way to make assignments
|
|
to an object do whatever you want. It is just not the overload, but
|
|
tie()ing interface (see L<perlfunc/tie>). Adding a FETCH() method
|
|
which returns the object itself, and STORE() method which changes the
|
|
value of the object, one can reproduce the arithmetic metaphor in its
|
|
completeness, at least for variables which were tie()d from the start.
|
|
|
|
(Note that a workaround for a bug may be needed, see L<"BUGS">.)
|
|
|
|
=head1 Cookbook
|
|
|
|
Please add examples to what follows!
|
|
|
|
=head2 Two-face scalars
|
|
|
|
Put this in F<two_face.pm> in your Perl library directory:
|
|
|
|
package two_face; # Scalars with separate string and
|
|
# numeric values.
|
|
sub new { my $p = shift; bless [@_], $p }
|
|
use overload '""' => \&str, '0+' => \&num, fallback => 1;
|
|
sub num {shift->[1]}
|
|
sub str {shift->[0]}
|
|
|
|
Use it as follows:
|
|
|
|
require two_face;
|
|
my $seven = new two_face ("vii", 7);
|
|
printf "seven=$seven, seven=%d, eight=%d\n", $seven, $seven+1;
|
|
print "seven contains `i'\n" if $seven =~ /i/;
|
|
|
|
(The second line creates a scalar which has both a string value, and a
|
|
numeric value.) This prints:
|
|
|
|
seven=vii, seven=7, eight=8
|
|
seven contains `i'
|
|
|
|
=head2 Symbolic calculator
|
|
|
|
Put this in F<symbolic.pm> in your Perl library directory:
|
|
|
|
package symbolic; # Primitive symbolic calculator
|
|
use overload nomethod => \&wrap;
|
|
|
|
sub new { shift; bless ['n', @_] }
|
|
sub wrap {
|
|
my ($obj, $other, $inv, $meth) = @_;
|
|
($obj, $other) = ($other, $obj) if $inv;
|
|
bless [$meth, $obj, $other];
|
|
}
|
|
|
|
This module is very unusual as overloaded modules go: it does not
|
|
provide any usual overloaded operators, instead it provides the L<Last
|
|
Resort> operator C<nomethod>. In this example the corresponding
|
|
subroutine returns an object which encapsulates operations done over
|
|
the objects: C<new symbolic 3> contains C<['n', 3]>, C<2 + new
|
|
symbolic 3> contains C<['+', 2, ['n', 3]]>.
|
|
|
|
Here is an example of the script which "calculates" the side of
|
|
circumscribed octagon using the above package:
|
|
|
|
require symbolic;
|
|
my $iter = 1; # 2**($iter+2) = 8
|
|
my $side = new symbolic 1;
|
|
my $cnt = $iter;
|
|
|
|
while ($cnt--) {
|
|
$side = (sqrt(1 + $side**2) - 1)/$side;
|
|
}
|
|
print "OK\n";
|
|
|
|
The value of $side is
|
|
|
|
['/', ['-', ['sqrt', ['+', 1, ['**', ['n', 1], 2]],
|
|
undef], 1], ['n', 1]]
|
|
|
|
Note that while we obtained this value using a nice little script,
|
|
there is no simple way to I<use> this value. In fact this value may
|
|
be inspected in debugger (see L<perldebug>), but ony if
|
|
C<bareStringify> B<O>ption is set, and not via C<p> command.
|
|
|
|
If one attempts to print this value, then the overloaded operator
|
|
C<""> will be called, which will call C<nomethod> operator. The
|
|
result of this operator will be stringified again, but this result is
|
|
again of type C<symbolic>, which will lead to an infinite loop.
|
|
|
|
Add a pretty-printer method to the module F<symbolic.pm>:
|
|
|
|
sub pretty {
|
|
my ($meth, $a, $b) = @{+shift};
|
|
$a = 'u' unless defined $a;
|
|
$b = 'u' unless defined $b;
|
|
$a = $a->pretty if ref $a;
|
|
$b = $b->pretty if ref $b;
|
|
"[$meth $a $b]";
|
|
}
|
|
|
|
Now one can finish the script by
|
|
|
|
print "side = ", $side->pretty, "\n";
|
|
|
|
The method C<pretty> is doing object-to-string conversion, so it
|
|
is natural to overload the operator C<""> using this method. However,
|
|
inside such a method it is not necessary to pretty-print the
|
|
I<components> $a and $b of an object. In the above subroutine
|
|
C<"[$meth $a $b]"> is a catenation of some strings and components $a
|
|
and $b. If these components use overloading, the catenation operator
|
|
will look for an overloaded operator C<.>, if not present, it will
|
|
look for an overloaded operator C<"">. Thus it is enough to use
|
|
|
|
use overload nomethod => \&wrap, '""' => \&str;
|
|
sub str {
|
|
my ($meth, $a, $b) = @{+shift};
|
|
$a = 'u' unless defined $a;
|
|
$b = 'u' unless defined $b;
|
|
"[$meth $a $b]";
|
|
}
|
|
|
|
Now one can change the last line of the script to
|
|
|
|
print "side = $side\n";
|
|
|
|
which outputs
|
|
|
|
side = [/ [- [sqrt [+ 1 [** [n 1 u] 2]] u] 1] [n 1 u]]
|
|
|
|
and one can inspect the value in debugger using all the possible
|
|
methods.
|
|
|
|
Something is is still amiss: consider the loop variable $cnt of the
|
|
script. It was a number, not an object. We cannot make this value of
|
|
type C<symbolic>, since then the loop will not terminate.
|
|
|
|
Indeed, to terminate the cycle, the $cnt should become false.
|
|
However, the operator C<bool> for checking falsity is overloaded (this
|
|
time via overloaded C<"">), and returns a long string, thus any object
|
|
of type C<symbolic> is true. To overcome this, we need a way to
|
|
compare an object to 0. In fact, it is easier to write a numeric
|
|
conversion routine.
|
|
|
|
Here is the text of F<symbolic.pm> with such a routine added (and
|
|
slightly modified str()):
|
|
|
|
package symbolic; # Primitive symbolic calculator
|
|
use overload
|
|
nomethod => \&wrap, '""' => \&str, '0+' => \#
|
|
|
|
sub new { shift; bless ['n', @_] }
|
|
sub wrap {
|
|
my ($obj, $other, $inv, $meth) = @_;
|
|
($obj, $other) = ($other, $obj) if $inv;
|
|
bless [$meth, $obj, $other];
|
|
}
|
|
sub str {
|
|
my ($meth, $a, $b) = @{+shift};
|
|
$a = 'u' unless defined $a;
|
|
if (defined $b) {
|
|
"[$meth $a $b]";
|
|
} else {
|
|
"[$meth $a]";
|
|
}
|
|
}
|
|
my %subr = ( n => sub {$_[0]},
|
|
sqrt => sub {sqrt $_[0]},
|
|
'-' => sub {shift() - shift()},
|
|
'+' => sub {shift() + shift()},
|
|
'/' => sub {shift() / shift()},
|
|
'*' => sub {shift() * shift()},
|
|
'**' => sub {shift() ** shift()},
|
|
);
|
|
sub num {
|
|
my ($meth, $a, $b) = @{+shift};
|
|
my $subr = $subr{$meth}
|
|
or die "Do not know how to ($meth) in symbolic";
|
|
$a = $a->num if ref $a eq __PACKAGE__;
|
|
$b = $b->num if ref $b eq __PACKAGE__;
|
|
$subr->($a,$b);
|
|
}
|
|
|
|
All the work of numeric conversion is done in %subr and num(). Of
|
|
course, %subr is not complete, it contains only operators used in the
|
|
example below. Here is the extra-credit question: why do we need an
|
|
explicit recursion in num()? (Answer is at the end of this section.)
|
|
|
|
Use this module like this:
|
|
|
|
require symbolic;
|
|
my $iter = new symbolic 2; # 16-gon
|
|
my $side = new symbolic 1;
|
|
my $cnt = $iter;
|
|
|
|
while ($cnt) {
|
|
$cnt = $cnt - 1; # Mutator `--' not implemented
|
|
$side = (sqrt(1 + $side**2) - 1)/$side;
|
|
}
|
|
printf "%s=%f\n", $side, $side;
|
|
printf "pi=%f\n", $side*(2**($iter+2));
|
|
|
|
It prints (without so many line breaks)
|
|
|
|
[/ [- [sqrt [+ 1 [** [/ [- [sqrt [+ 1 [** [n 1] 2]]] 1]
|
|
[n 1]] 2]]] 1]
|
|
[/ [- [sqrt [+ 1 [** [n 1] 2]]] 1] [n 1]]]=0.198912
|
|
pi=3.182598
|
|
|
|
The above module is very primitive. It does not implement
|
|
mutator methods (C<++>, C<-=> and so on), does not do deep copying
|
|
(not required without mutators!), and implements only those arithmetic
|
|
operations which are used in the example.
|
|
|
|
To implement most arithmetic operations is easy, one should just use
|
|
the tables of operations, and change the code which fills %subr to
|
|
|
|
my %subr = ( 'n' => sub {$_[0]} );
|
|
foreach my $op (split " ", $overload::ops{with_assign}) {
|
|
$subr{$op} = $subr{"$op="} = eval "sub {shift() $op shift()}";
|
|
}
|
|
my @bins = qw(binary 3way_comparison num_comparison str_comparison);
|
|
foreach my $op (split " ", "@overload::ops{ @bins }") {
|
|
$subr{$op} = eval "sub {shift() $op shift()}";
|
|
}
|
|
foreach my $op (split " ", "@overload::ops{qw(unary func)}") {
|
|
print "defining `$op'\n";
|
|
$subr{$op} = eval "sub {$op shift()}";
|
|
}
|
|
|
|
Due to L<Calling Conventions for Mutators>, we do not need anything
|
|
special to make C<+=> and friends work, except filling C<+=> entry of
|
|
%subr, and defining a copy constructor (needed since Perl has no
|
|
way to know that the implementation of C<'+='> does not mutate
|
|
the argument, compare L<Copy Constructor>).
|
|
|
|
To implement a copy constructor, add C<'=' => \&cpy> to C<use overload>
|
|
line, and code (this code assumes that mutators change things one level
|
|
deep only, so recursive copying is not needed):
|
|
|
|
sub cpy {
|
|
my $self = shift;
|
|
bless [@$self], ref $self;
|
|
}
|
|
|
|
To make C<++> and C<--> work, we need to implement actual mutators,
|
|
either directly, or in C<nomethod>. We continue to do things inside
|
|
C<nomethod>, thus add
|
|
|
|
if ($meth eq '++' or $meth eq '--') {
|
|
@$obj = ($meth, (bless [@$obj]), 1); # Avoid circular reference
|
|
return $obj;
|
|
}
|
|
|
|
after the first line of wrap(). This is not a most effective
|
|
implementation, one may consider
|
|
|
|
sub inc { $_[0] = bless ['++', shift, 1]; }
|
|
|
|
instead.
|
|
|
|
As a final remark, note that one can fill %subr by
|
|
|
|
my %subr = ( 'n' => sub {$_[0]} );
|
|
foreach my $op (split " ", $overload::ops{with_assign}) {
|
|
$subr{$op} = $subr{"$op="} = eval "sub {shift() $op shift()}";
|
|
}
|
|
my @bins = qw(binary 3way_comparison num_comparison str_comparison);
|
|
foreach my $op (split " ", "@overload::ops{ @bins }") {
|
|
$subr{$op} = eval "sub {shift() $op shift()}";
|
|
}
|
|
foreach my $op (split " ", "@overload::ops{qw(unary func)}") {
|
|
$subr{$op} = eval "sub {$op shift()}";
|
|
}
|
|
$subr{'++'} = $subr{'+'};
|
|
$subr{'--'} = $subr{'-'};
|
|
|
|
This finishes implementation of a primitive symbolic calculator in
|
|
50 lines of Perl code. Since the numeric values of subexpressions
|
|
are not cached, the calculator is very slow.
|
|
|
|
Here is the answer for the exercise: In the case of str(), we need no
|
|
explicit recursion since the overloaded C<.>-operator will fall back
|
|
to an existing overloaded operator C<"">. Overloaded arithmetic
|
|
operators I<do not> fall back to numeric conversion if C<fallback> is
|
|
not explicitly requested. Thus without an explicit recursion num()
|
|
would convert C<['+', $a, $b]> to C<$a + $b>, which would just rebuild
|
|
the argument of num().
|
|
|
|
If you wonder why defaults for conversion are different for str() and
|
|
num(), note how easy it was to write the symbolic calculator. This
|
|
simplicity is due to an appropriate choice of defaults. One extra
|
|
note: due to the explicit recursion num() is more fragile than sym():
|
|
we need to explicitly check for the type of $a and $b. If components
|
|
$a and $b happen to be of some related type, this may lead to problems.
|
|
|
|
=head2 I<Really> symbolic calculator
|
|
|
|
One may wonder why we call the above calculator symbolic. The reason
|
|
is that the actual calculation of the value of expression is postponed
|
|
until the value is I<used>.
|
|
|
|
To see it in action, add a method
|
|
|
|
sub STORE {
|
|
my $obj = shift;
|
|
$#$obj = 1;
|
|
@$obj->[0,1] = ('=', shift);
|
|
}
|
|
|
|
to the package C<symbolic>. After this change one can do
|
|
|
|
my $a = new symbolic 3;
|
|
my $b = new symbolic 4;
|
|
my $c = sqrt($a**2 + $b**2);
|
|
|
|
and the numeric value of $c becomes 5. However, after calling
|
|
|
|
$a->STORE(12); $b->STORE(5);
|
|
|
|
the numeric value of $c becomes 13. There is no doubt now that the module
|
|
symbolic provides a I<symbolic> calculator indeed.
|
|
|
|
To hide the rough edges under the hood, provide a tie()d interface to the
|
|
package C<symbolic> (compare with L<Metaphor clash>). Add methods
|
|
|
|
sub TIESCALAR { my $pack = shift; $pack->new(@_) }
|
|
sub FETCH { shift }
|
|
sub nop { } # Around a bug
|
|
|
|
(the bug is described in L<"BUGS">). One can use this new interface as
|
|
|
|
tie $a, 'symbolic', 3;
|
|
tie $b, 'symbolic', 4;
|
|
$a->nop; $b->nop; # Around a bug
|
|
|
|
my $c = sqrt($a**2 + $b**2);
|
|
|
|
Now numeric value of $c is 5. After C<$a = 12; $b = 5> the numeric value
|
|
of $c becomes 13. To insulate the user of the module add a method
|
|
|
|
sub vars { my $p = shift; tie($_, $p), $_->nop foreach @_; }
|
|
|
|
Now
|
|
|
|
my ($a, $b);
|
|
symbolic->vars($a, $b);
|
|
my $c = sqrt($a**2 + $b**2);
|
|
|
|
$a = 3; $b = 4;
|
|
printf "c5 %s=%f\n", $c, $c;
|
|
|
|
$a = 12; $b = 5;
|
|
printf "c13 %s=%f\n", $c, $c;
|
|
|
|
shows that the numeric value of $c follows changes to the values of $a
|
|
and $b.
|
|
|
|
=head1 AUTHOR
|
|
|
|
Ilya Zakharevich E<lt>F<[email protected]>E<gt>.
|
|
|
|
=head1 DIAGNOSTICS
|
|
|
|
When Perl is run with the B<-Do> switch or its equivalent, overloading
|
|
induces diagnostic messages.
|
|
|
|
Using the C<m> command of Perl debugger (see L<perldebug>) one can
|
|
deduce which operations are overloaded (and which ancestor triggers
|
|
this overloading). Say, if C<eq> is overloaded, then the method C<(eq>
|
|
is shown by debugger. The method C<()> corresponds to the C<fallback>
|
|
key (in fact a presence of this method shows that this package has
|
|
overloading enabled, and it is what is used by the C<Overloaded>
|
|
function of module C<overload>).
|
|
|
|
=head1 BUGS
|
|
|
|
Because it is used for overloading, the per-package hash %OVERLOAD now
|
|
has a special meaning in Perl. The symbol table is filled with names
|
|
looking like line-noise.
|
|
|
|
For the purpose of inheritance every overloaded package behaves as if
|
|
C<fallback> is present (possibly undefined). This may create
|
|
interesting effects if some package is not overloaded, but inherits
|
|
from two overloaded packages.
|
|
|
|
Relation between overloading and tie()ing is broken. Overloading is
|
|
triggered or not basing on the I<previous> class of tie()d value.
|
|
|
|
This happens because the presence of overloading is checked too early,
|
|
before any tie()d access is attempted. If the FETCH()ed class of the
|
|
tie()d value does not change, a simple workaround is to access the value
|
|
immediately after tie()ing, so that after this call the I<previous> class
|
|
coincides with the current one.
|
|
|
|
B<Needed:> a way to fix this without a speed penalty.
|
|
|
|
Barewords are not covered by overloaded string constants.
|
|
|
|
This document is confusing. There are grammos and misleading language
|
|
used in places. It would seem a total rewrite is needed.
|
|
|
|
=cut
|
|
|