FILE: C:\Program Files (x86)\Plesk\perl\lib\bigfloat.pm

--
package bigfloat;

use strict;
use warnings;

use Carp qw< carp croak >;

our $VERSION = '0.67';

use Exporter;
our @ISA            = qw( Exporter );
our @EXPORT_OK      = qw( PI e bpi bexp hex oct );
our @EXPORT         = qw( inf NaN );

use overload;

my $obj_class = "Math::BigFloat";

##############################################################################

sub accuracy {
    my $self = shift;
    $obj_class -> accuracy(@_);
}

sub precision {
    my $self = shift;
    $obj_class -> precision(@_);
}

sub round_mode {
    my $self = shift;
    $obj_class -> round_mode(@_);
}

sub div_scale {
    my $self = shift;
    $obj_class -> div_scale(@_);
}

sub upgrade {
    my $self = shift;
    $obj_class -> upgrade(@_);
}

sub downgrade {
    my $self = shift;
    $obj_class -> downgrade(@_);
}

sub in_effect {
    my $level = shift || 0;
    my $hinthash = (caller($level))[10];
    $hinthash->{bigfloat};
}

sub _float_constant {
    my $str = shift;

    # See if we can convert the input string to a string using a normalized form
    # consisting of the significand as a signed integer, the character "e", and
    # the exponent as a signed integer, e.g., "+0e+0", "+314e-2", and "-1e+3".

    my $nstr;

    if (
        # See if it is an octal number. An octal number like '0377' is also
        # accepted by the functions parsing decimal and hexadecimal numbers, so
        # handle octal numbers before decimal and hexadecimal numbers.

        $str =~ /^0(?:[Oo]|_*[0-7])/ and
        $nstr = Math::BigInt -> oct_str_to_dec_flt_str($str)

          or

        # See if it is decimal number.

        $nstr = Math::BigInt -> dec_str_to_dec_flt_str($str)

          or

        # See if it is a hexadecimal number. Every hexadecimal number has a
        # prefix, but the functions parsing numbers don't require it, so check
        # to see if it actually is a hexadecimal number.

        $str =~ /^0[Xx]/ and
        $nstr = Math::BigInt -> hex_str_to_dec_flt_str($str)

          or

        # See if it is a binary numbers. Every binary number has a prefix, but
        # the functions parsing numbers don't require it, so check to see if it
        # actually is a binary number.

        $str =~ /^0[Bb]/ and
        $nstr = Math::BigInt -> bin_str_to_dec_flt_str($str))
    {
        return $obj_class -> new($nstr);
    }

    # If we get here, there is a bug in the code above this point.

    warn "Internal error: unable to handle literal constant '$str'.",
      " This is a bug, so please report this to the module author.";
    return $obj_class -> bnan();
}

#############################################################################
# the following two routines are for "use bigfloat qw/hex oct/;":

use constant LEXICAL => $] > 5.009004;

# Internal function with the same semantics as CORE::hex(). This function is
# not used directly, but rather by other front-end functions.

sub _hex_core {
    my $str = shift;

    # Strip off, clean, and parse as much as we can from the beginning.

    my $x;
    if ($str =~ s/ ^ ( 0? [xX] )? ( [0-9a-fA-F]* ( _ [0-9a-fA-F]+ )* ) //x) {
        my $chrs = $2;
        $chrs =~ tr/_//d;
        $chrs = '0' unless CORE::length $chrs;
        $x = $obj_class -> from_hex($chrs);
    } else {
        $x = $obj_class -> bzero();
    }

    # Warn about trailing garbage.

    if (CORE::length($str)) {
        require Carp;
        Carp::carp(sprintf("Illegal hexadecimal digit '%s' ignored",
                           substr($str, 0, 1)));
    }

    return $x;
}

# Internal function with the same semantics as CORE::oct(). This function is
# not used directly, but rather by other front-end functions.

sub _oct_core {
    my $str = shift;

    $str =~ s/^\s*//;

    # Hexadecimal input.

    return _hex_core($str) if $str =~ /^0?[xX]/;

    my $x;

    # Binary input.

    if ($str =~ /^0?[bB]/) {

        # Strip off, clean, and parse as much as we can from the beginning.

        if ($str =~ s/ ^ ( 0? [bB] )? ( [01]* ( _ [01]+ )* ) //x) {
            my $chrs = $2;
            $chrs =~ tr/_//d;
            $chrs = '0' unless CORE::length $chrs;
            $x = $obj_class -> from_bin($chrs);
        }

        # Warn about trailing garbage.

        if (CORE::length($str)) {
            require Carp;
            Carp::carp(sprintf("Illegal binary digit '%s' ignored",
                               substr($str, 0, 1)));
        }

        return $x;
    }

    # Octal input. Strip off, clean, and parse as much as we can from the
    # beginning.

    if ($str =~ s/ ^ ( 0? [oO] )? ( [0-7]* ( _ [0-7]+ )* ) //x) {
        my $chrs = $2;
        $chrs =~ tr/_//d;
        $chrs = '0' unless CORE::length $chrs;
        $x = $obj_class -> from_oct($chrs);
    }

    # Warn about trailing garbage. CORE::oct() only warns about 8 and 9, but it
    # is more helpful to warn about all invalid digits.

    if (CORE::length($str)) {
        require Carp;
        Carp::carp(sprintf("Illegal octal digit '%s' ignored",
                           substr($str, 0, 1)));
    }

    return $x;
}

{
    my $proto = LEXICAL ? '_' : ';$';
    eval '
sub hex(' . $proto . ') {' . <<'.';
    my $str = @_ ? $_[0] : $_;
    _hex_core($str);
}
.

    eval '
sub oct(' . $proto . ') {' . <<'.';
    my $str = @_ ? $_[0] : $_;
    _oct_core($str);
}
.
}

#############################################################################
# the following two routines are for Perl 5.9.4 or later and are lexical

my ($prev_oct, $prev_hex, $overridden);

if (LEXICAL) { eval <<'.' }
sub _hex(_) {
    my $hh = (caller 0)[10];
    return $$hh{bigfloat} ? bigfloat::_hex_core($_[0])
         : $$hh{bigrat} ? bigrat::_hex_core($_[0])
         : $$hh{bigint} ? bigint::_hex_core($_[0])
         : $prev_hex    ? &$prev_hex($_[0])
         : CORE::hex($_[0]);
}

sub _oct(_) {
    my $hh = (caller 0)[10];
    return $$hh{bigfloat} ? bigfloat::_oct_core($_[0])
         : $$hh{bigrat} ? bigrat::_oct_core($_[0])
         : $$hh{bigint} ? bigint::_oct_core($_[0])
         : $prev_oct    ? &$prev_oct($_[0])
         : CORE::oct($_[0]);
}
.

sub _override {
    return if $overridden;
    $prev_oct = *CORE::GLOBAL::oct{CODE};
    $prev_hex = *CORE::GLOBAL::hex{CODE};
    no warnings 'redefine';
    *CORE::GLOBAL::oct = \&_oct;
    *CORE::GLOBAL::hex = \&_hex;
    $overridden = 1;
}

sub unimport {
    delete $^H{bigfloat};       # no longer in effect
    overload::remove_constant('binary', '', 'float', '', 'integer');
}

sub import {
    my $class = shift;

    $^H{bigfloat} = 1;          # we are in effect
    delete $^H{bigint};
    delete $^H{bigrat};

    # for newer Perls always override hex() and oct() with a lexical version:
    if (LEXICAL) {
        _override();
    }

    my @import = ();
    my @a = ();                         # unrecognized arguments
    my $ver;                            # version?

    while (@_) {
        my $param = shift;

        # Accuracy.

        if ($param =~ /^a(ccuracy)?$/) {
            push @import, 'accuracy', shift();
            next;
        }

        # Precision.

        if ($param =~ /^p(recision)?$/) {
            push @import, 'precision', shift();
            next;
        }

        # Rounding mode.

        if ($param eq 'round_mode') {
            push @import, 'round_mode', shift();
            next;
        }

        # Backend library.

        if ($param =~ /^(l|lib|try|only)$/) {
            push @import, $param eq 'l' ? 'lib' : $param;
            push @import, shift() if @_;
            next;
        }

        if ($param =~ /^(v|version)$/) {
            $ver = 1;
            next;
        }

        if ($param =~ /^(t|trace)$/) {
            $obj_class .= "::Trace";
            eval "require $obj_class";
            die $@ if $@;
            next;
        }

        if ($param =~ /^(PI|e|bexp|bpi|hex|oct)\z/) {
            push @a, $param;
            next;
        }

        croak("Unknown option '$param'");
    }

    eval "require $obj_class";
    die $@ if $@;
    $obj_class -> import(@import);

    if ($ver) {
        printf "%-31s v%s\n", $class, $class -> VERSION();
        printf " lib => %-23s v%s\n",
          $obj_class -> config("lib"), $obj_class -> config("lib_version");
        printf "%-31s v%s\n", $obj_class, $obj_class -> VERSION();
        exit;
    }

    $class -> export_to_level(1, $class, @a);   # export inf, NaN, etc.

    overload::constant

        # This takes care each number written as decimal integer and within the
        # range of what perl can represent as an integer, e.g., "314", but not
        # "3141592653589793238462643383279502884197169399375105820974944592307".

        integer => sub {
            #printf "Value '%s' handled by the 'integer' sub.\n", $_[0];
            my $str = shift;
            return $obj_class -> new($str);
        },

        # This takes care of each number written with a decimal point and/or
        # using floating point notation, e.g., "3.", "3.0", "3.14e+2" (decimal),
        # "0b1.101p+2" (binary), "03.14p+2" and "0o3.14p+2" (octal), and
        # "0x3.14p+2" (hexadecimal).

        float => sub {
            #printf "# Value '%s' handled by the 'float' sub.\n", $_[0];
            _float_constant(shift);
        },

        # Take care of each number written as an integer (no decimal point or
        # exponent) using binary, octal, or hexadecimal notation, e.g., "0b101"
        # (binary), "0314" and "0o314" (octal), and "0x314" (hexadecimal).

        binary => sub {
            #printf "# Value '%s' handled by the 'binary' sub.\n", $_[0];
            my $str = shift;
            return $obj_class -> new($str) if $str =~ /^0[XxBb]/;
            $obj_class -> from_oct($str);
        };
}

sub inf () { $obj_class -> binf(); }
sub NaN () { $obj_class -> bnan(); }

# This should depend on the current accuracy/precision. Fixme!
sub PI  () { $obj_class -> new('3.141592653589793238462643383279502884197'); }
sub e   () { $obj_class -> new('2.718281828459045235360287471352662497757'); }

sub bpi ($) {
    my $up = Math::BigFloat -> upgrade();   # get current upgrading, if any ...
    Math::BigFloat -> upgrade(undef);       # ... and disable

    my $x = Math::BigFloat -> bpi(@_);

    Math::BigFloat -> upgrade($up);         # reset the upgrading

    return $x;
}

sub bexp ($$) {
    my $up = Math::BigFloat -> upgrade();   # get current upgrading, if any ...
    Math::BigFloat -> upgrade(undef);       # ... and disable

    my $x = Math::BigFloat -> new(shift);
    $x -> bexp(@_);

    Math::BigFloat -> upgrade($up);         # reset the upgrading

    return $x;
}

1;

__END__

=pod

=head1 NAME

bigfloat - transparent big floating point number support for Perl

=head1 SYNOPSIS

    use bigfloat;

    $x = 2 + 4.5;                       # Math::BigFloat 6.5
    print 2 ** 512 * 0.1;               # Math::BigFloat 134...09.6
    print inf + 42;                     # Math::BigFloat inf
    print NaN * 7;                      # Math::BigFloat NaN
    print hex("0x1234567890123490");    # Perl v5.10.0 or later

    {
        no bigfloat;
        print 2 ** 256;                 # a normal Perl scalar now
    }

    # for older Perls, import into current package:
    use bigfloat qw/hex oct/;
    print hex("0x1234567890123490");
    print oct("01234567890123490");

=head1 DESCRIPTION

All numeric literals in the given scope are converted to Math::BigFloat objects.

All operators (including basic math operations) except the range operator C<..>
are overloaded.

So, the following:

    use bigfloat;
    $x = 1234;

creates a Math::BigFloat and stores a reference to in $x. This happens
transparently and behind your back, so to speak.

You can see this with the following:

    perl -Mbigfloat -le 'print ref(1234)'

Since numbers are actually objects, you can call all the usual methods from
Math::BigFloat on them. This even works to some extent on expressions:

    perl -Mbigfloat -le '$x = 1234; print $x->bdec()'
    perl -Mbigfloat -le 'print 1234->copy()->binc();'
    perl -Mbigfloat -le 'print 1234->copy()->binc->badd(6);'
    perl -Mbigfloat -le 'print +(1234)->copy()->binc()'

(Note that print doesn't do what you expect if the expression starts with
'(' hence the C<+>)

You can even chain the operations together as usual:

    perl -Mbigfloat -le 'print 1234->copy()->binc->badd(6);'
    1241

Please note the following does not work as expected (prints nothing), since
overloading of '..' is not yet possible in Perl (as of v5.8.0):

    perl -Mbigfloat -le 'for (1..2) { print ref($_); }'

=head2 Options

C recognizes some options that can be passed while loading it via via
C. The following options exist:

=over 4

=item a or accuracy

This sets the accuracy for all math operations. The argument must be greater
than or equal to zero. See Math::BigInt's bround() method for details.

    perl -Mbigfloat=a,50 -le 'print sqrt(20)'

Note that setting precision and accuracy at the same time is not possible.

=item p or precision

This sets the precision for all math operations. The argument can be any
integer. Negative values mean a fixed number of digits after the dot, while a
positive value rounds to this digit left from the dot. 0 means round to integer.
See Math::BigInt's bfround() method for details.

    perl -Mbigfloat=p,-50 -le 'print sqrt(20)'

Note that setting precision and accuracy at the same time is not possible.

=item t or trace

This enables a trace mode and is primarily for debugging.

=item l, lib, try, or only

Load a different math lib, see L
--