package Math::BigRat;
-require 5.005_03;
+# anythig older is untested, and unlikely to work
+use 5.006;
use strict;
use Math::BigFloat;
@ISA = qw(Math::BigFloat);
-$VERSION = '0.15';
+$VERSION = '0.21';
use overload; # inherit overload from Math::BigFloat
$self->{_d} = $MBI->_copy( $f->{_m} );
# calculate the difference between nE and dE
- # XXX TODO: check that exponent() makes a copy to avoid copy()
- my $diff_e = $nf->exponent()->copy()->bsub( $f->exponent);
+ my $diff_e = $nf->exponent()->bsub( $f->exponent);
if ($diff_e->is_negative())
{
# < 0: mul d with it
$self->{sign} = '+'; # no sign => '+'
$self->{_n} = undef;
$self->{_d} = undef;
- if ($n =~ /^([+-]?)0*(\d+)\z/) # first part ok?
+ if ($n =~ /^([+-]?)0*([0-9]+)\z/) # first part ok?
{
$self->{sign} = $1 || '+'; # no sign => '+'
$self->{_n} = $MBI->_new($2 || 0);
}
- if ($d =~ /^([+-]?)0*(\d+)\z/) # second part ok?
+ if ($d =~ /^([+-]?)0*([0-9]+)\z/) # second part ok?
{
$self->{sign} =~ tr/+-/-+/ if ($1 || '') eq '-'; # negate if second part neg.
$self->{_d} = $MBI->_new($2 || 0);
else
{
# for simple forms, use $MBI directly
- if ($n =~ /^([+-]?)0*(\d+)\z/)
+ if ($n =~ /^([+-]?)0*([0-9]+)\z/)
{
$self->{sign} = $1 || '+';
$self->{_n} = $MBI->_new($2 || 0);
# return (later set?) configuration data as hash ref
my $class = shift || 'Math::BigRat';
+ if (@_ == 1 && ref($_[0]) ne 'HASH')
+ {
+ my $cfg = $class->SUPER::config();
+ return $cfg->{$_[0]};
+ }
+
my $cfg = $class->SUPER::config(@_);
# now we need only to override the ones that are different from our parent
my ($self,$x) = ref($_[0]) ? (undef,$_[0]) : objectify(1,@_);
# Both parts must be objects of whatever we are using today.
- # Second check because Calc.pm has ARRAY res as unblessed objects.
- if (ref($x->{_n}) ne $MBI && ref($x->{_n}) ne 'ARRAY')
+ if ( my $c = $MBI->_check($x->{_n}) )
{
- require Carp; Carp::croak ("n is not $MBI but (".ref($x->{_n}).') in bnorm()');
+ require Carp; Carp::croak ("n did not pass the self-check ($c) in bnorm()");
}
- if (ref($x->{_d}) ne $MBI && ref($x->{_d}) ne 'ARRAY')
+ if ( my $c = $MBI->_check($x->{_d}) )
{
- require Carp; Carp::croak ("d is not $MBI but (".ref($x->{_d}).') in bnorm()');
+ require Carp; Carp::croak ("d did not pass the self-check ($c) in bnorm()");
}
# no normalize for NaN, inf etc.
$x->_new_from_float( $x->_as_float()->blog(Math::BigFloat->new("$y"),@r) );
}
+sub bexp
+ {
+ # set up parameters
+ my ($self,$x,$y,$a,$p,$r) = (ref($_[0]),@_);
+
+ # objectify is costly, so avoid it
+ if ((!ref($_[0])) || (ref($_[0]) ne ref($_[1])))
+ {
+ ($self,$x,$y,$a,$p,$r) = objectify(2,$class,@_);
+ }
+
+ return $x->binf() if $x->{sign} eq '+inf';
+ return $x->bzero() if $x->{sign} eq '-inf';
+
+ # we need to limit the accuracy to protect against overflow
+ my $fallback = 0;
+ my ($scale,@params);
+ ($x,@params) = $x->_find_round_parameters($a,$p,$r);
+
+ # also takes care of the "error in _find_round_parameters?" case
+ return $x if $x->{sign} eq 'NaN';
+
+ # no rounding at all, so must use fallback
+ if (scalar @params == 0)
+ {
+ # simulate old behaviour
+ $params[0] = $self->div_scale(); # and round to it as accuracy
+ $params[1] = undef; # P = undef
+ $scale = $params[0]+4; # at least four more for proper round
+ $params[2] = $r; # round mode by caller or undef
+ $fallback = 1; # to clear a/p afterwards
+ }
+ else
+ {
+ # the 4 below is empirical, and there might be cases where it's not enough...
+ $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined
+ }
+
+ return $x->bone(@params) if $x->is_zero();
+
+ # See the comments in Math::BigFloat on how this algorithm works.
+ # Basically we calculate A and B (where B is faculty(N)) so that A/B = e
+
+ my $x_org = $x->copy();
+ if ($scale <= 75)
+ {
+ # set $x directly from a cached string form
+ $x->{_n} = $MBI->_new("90933395208605785401971970164779391644753259799242");
+ $x->{_d} = $MBI->_new("33452526613163807108170062053440751665152000000000");
+ $x->{sign} = '+';
+ }
+ else
+ {
+ # compute A and B so that e = A / B.
+
+ # After some terms we end up with this, so we use it as a starting point:
+ my $A = $MBI->_new("90933395208605785401971970164779391644753259799242");
+ my $F = $MBI->_new(42); my $step = 42;
+
+ # Compute how many steps we need to take to get $A and $B sufficiently big
+ my $steps = Math::BigFloat::_len_to_steps($scale - 4);
+# print STDERR "# Doing $steps steps for ", $scale-4, " digits\n";
+ while ($step++ <= $steps)
+ {
+ # calculate $a * $f + 1
+ $A = $MBI->_mul($A, $F);
+ $A = $MBI->_inc($A);
+ # increment f
+ $F = $MBI->_inc($F);
+ }
+ # compute $B as factorial of $steps (this is faster than doing it manually)
+ my $B = $MBI->_fac($MBI->_new($steps));
+
+# print "A ", $MBI->_str($A), "\nB ", $MBI->_str($B), "\n";
+
+ $x->{_n} = $A;
+ $x->{_d} = $B;
+ $x->{sign} = '+';
+ }
+
+ # $x contains now an estimate of e, with some surplus digits, so we can round
+ if (!$x_org->is_one())
+ {
+ # raise $x to the wanted power and round it in one step:
+ $x->bpow($x_org, @params);
+ }
+ else
+ {
+ # else just round the already computed result
+ delete $x->{_a}; delete $x->{_p};
+ # shortcut to not run through _find_round_parameters again
+ if (defined $params[0])
+ {
+ $x->bround($params[0],$params[2]); # then round accordingly
+ }
+ else
+ {
+ $x->bfround($params[1],$params[2]); # then round accordingly
+ }
+ }
+ if ($fallback)
+ {
+ # clear a/p after round, since user did not request it
+ delete $x->{_a}; delete $x->{_p};
+ }
+
+ $x;
+ }
+
+sub bnok
+ {
+ # set up parameters
+ my ($self,$x,$y,@r) = (ref($_[0]),@_);
+
+ # objectify is costly, so avoid it
+ if ((!ref($_[0])) || (ref($_[0]) ne ref($_[1])))
+ {
+ ($self,$x,$y,@r) = objectify(2,$class,@_);
+ }
+
+ # do it with floats
+ $x->_new_from_float( $x->_as_float()->bnok(Math::BigFloat->new("$y"),@r) );
+ }
+
sub _float_from_part
{
my $x = shift;
{
my ($self,$x) = ref($_[0]) ? (undef,$_[0]) : objectify(1,@_);
- return Math::BigInt->new($x) if $x->{sign} !~ /^[+-]$/; # NaN, inf etc
+ # NaN, inf etc
+ return Math::BigInt->new($x->{sign}) if $x->{sign} !~ /^[+-]$/;
my $u = Math::BigInt->bzero();
$u->{sign} = $x->{sign};
$s . $MBI->_as_hex($x->{_n});
}
+sub as_oct
+ {
+ my ($self,$x) = ref($_[0]) ? (undef,$_[0]) : objectify(1,@_);
+
+ return $x unless $x->is_int();
+
+ my $s = $x->{sign}; $s = '' if $s eq '+';
+ $s . $MBI->_as_oct($x->{_n});
+ }
+
+##############################################################################
+
+sub from_hex
+ {
+ my $class = shift;
+
+ $class->new(@_);
+ }
+
+sub from_bin
+ {
+ my $class = shift;
+
+ $class->new(@_);
+ }
+
+sub from_oct
+ {
+ my $class = shift;
+
+ my @parts;
+ for my $c (@_)
+ {
+ push @parts, Math::BigInt->from_oct($c);
+ }
+ $class->new ( @parts );
+ }
+
##############################################################################
# import
my $self = shift;
my $l = scalar @_;
my $lib = ''; my @a;
+ my $try = 'try';
for ( my $i = 0; $i < $l ; $i++)
{
$downgrade = $_[$i+1]; # or undef to disable
$i++;
}
- elsif ($_[$i] eq 'lib')
+ elsif ($_[$i] =~ /^(lib|try|only)\z/)
{
$lib = $_[$i+1] || ''; # default Calc
+ $try = $1; # lib, try or only
$i++;
}
elsif ($_[$i] eq 'with')
$lib = join(",", @c);
}
my @import = ('objectify');
- push @import, lib => $lib if $lib ne '';
+ push @import, $try => $lib if $lib ne '';
# MBI already loaded, so feed it our lib arguments
Math::BigInt->import( @import );
=head2 MATH LIBRARY
-Math with the numbers is done (by default) by a module called
-Math::BigInt::Calc. This is equivalent to saying:
-
- use Math::BigRat lib => 'Calc';
+You can change the underlying module that does the low-level
+math operations by using:
-You can change this by using:
+ use Math::BigRat try => 'GMP';
- use Math::BigRat lib => 'BitVect';
+Note: This needs Math::BigInt::GMP installed.
The following would first try to find Math::BigInt::Foo, then
Math::BigInt::Bar, and when this also fails, revert to Math::BigInt::Calc:
- use Math::BigRat lib => 'Foo,Math::BigInt::Bar';
+ use Math::BigRat try => 'Foo,Math::BigInt::Bar';
+
+If you want to get warned when the fallback occurs, replace "try" with
+"lib":
-Calc.pm uses as internal format an array of elements of some decimal base
-(usually 1e7, but this might be different for some systems) with the least
-significant digit first, while BitVect.pm uses a bit vector of base 2, most
-significant bit first. Other modules might use even different means of
-representing the numbers. See the respective module documentation for further
-details.
+ use Math::BigRat lib => 'Foo,Math::BigInt::Bar';
-Currently the following replacement libraries exist, search for them at CPAN:
+If you want the code to die instead, replace "try" with
+"only":
- Math::BigInt::BitVect
- Math::BigInt::GMP
- Math::BigInt::Pari
- Math::BigInt::FastCalc
+ use Math::BigRat only => 'Foo,Math::BigInt::Bar';
=head1 METHODS
-Any methods not listed here are dervied from Math::BigFloat (or
+Any methods not listed here are derived from Math::BigFloat (or
Math::BigInt), so make sure you check these two modules for further
information.
Return a list consisting of (signed) numerator and (unsigned) denominator as
BigInts.
-=head2 as_int()
+=head2 numify()
+
+ my $y = $x->numify();
+
+Returns the object as a scalar. This will lose some data if the object
+cannot be represented by a normal Perl scalar (integer or float), so
+use as_int() instead.
+
+This routine is automatically used whenever a scalar is required:
+
+ my $x = Math::BigRat->new('3/1');
+ @array = (1,2,3);
+ $y = $array[$x]; # set $y to 3
+
+=head2 as_int()/as_number()
$x = Math::BigRat->new('13/7');
print $x->as_int(),"\n"; # '1'
Returns the BigRat as binary string. Works only for integers.
+=head2 as_oct()
+
+ $x = Math::BigRat->new('13');
+ print $x->as_oct(),"\n"; # '015'
+
+Returns the BigRat as octal string. Works only for integers.
+
+=head2 from_hex()/from_bin()/from_oct()
+
+ my $h = Math::BigRat->from_hex('0x10');
+ my $b = Math::BigRat->from_bin('0b10000000');
+ my $o = Math::BigRat->from_oct('020');
+
+Create a BigRat from an hexadecimal, binary or octal number
+in string form.
+
+=head2 length()
+
+ $len = $x->length();
+
+Return the length of $x in digitis for integer values.
+
+=head2 digit()
+
+ print Math::BigRat->new('123/1')->digit(1); # 1
+ print Math::BigRat->new('123/1')->digit(-1); # 3
+
+Return the N'ths digit from X when X is an integer value.
+
+=head2 bnorm()
+
+ $x->bnorm();
+
+Reduce the number to the shortest form. This routine is called
+automatically whenever it is needed.
+
=head2 bfac()
$x->bfac();
Works currently only for integers.
-=head2 blog()
-
-Is not yet implemented.
-
=head2 bround()/round()/bfround()
Are not yet implemented.
Set $x to the remainder of the division of $x by $y.
+=head2 bneg()
+
+ $x->bneg();
+
+Used to negate the object in-place.
+
=head2 is_one()
print "$x is 1\n" if $x->is_one();
Return true if $x is exactly zero, otherwise false.
-=head2 is_pos()
+=head2 is_pos()/is_positive()
print "$x is >= 0\n" if $x->is_positive();
C<is_positive()> is an alias for C<is_pos()>.
-=head2 is_neg()
+=head2 is_neg()/is_negative()
print "$x is < 0\n" if $x->is_negative();
Calculate the square root of $x.
-=head2 config
+=head2 broot()
+
+ $x->broot($n);
+
+Calculate the N'th root of $x.
+
+=head2 badd()/bmul()/bsub()/bdiv()/bdec()/binc()
+
+Please see the documentation in L<Math::BigInt>.
+
+=head2 copy()
+
+ my $z = $x->copy();
+
+Makes a deep copy of the object.
+
+Please see the documentation in L<Math::BigInt> for further details.
+
+=head2 bstr()/bsstr()
+
+ my $x = Math::BigInt->new('8/4');
+ print $x->bstr(),"\n"; # prints 1/2
+ print $x->bsstr(),"\n"; # prints 1/2
+
+Return a string representating this object.
+
+=head2 bacmp()/bcmp()
+
+Used to compare numbers.
+
+Please see the documentation in L<Math::BigInt> for further details.
+
+=head2 blsft()/brsft()
+
+Used to shift numbers left/right.
+
+Please see the documentation in L<Math::BigInt> for further details.
+
+=head2 bpow()
+
+ $x->bpow($y);
+
+Compute $x ** $y.
+
+Please see the documentation in L<Math::BigInt> for further details.
+
+=head2 bexp()
+
+ $x->bexp($accuracy); # calculate e ** X
+
+Calculates two integers A and B so that A/B is equal to C<e ** $x>, where C<e> is
+Euler's number.
+
+This method was added in v0.20 of Math::BigRat (May 2007).
+
+See also L<blog()>.
+
+=head2 bnok()
+
+ $x->bnok($y); # x over y (binomial coefficient n over k)
+
+Calculates the binomial coefficient n over k, also called the "choose"
+function. The result is equivalent to:
+
+ ( n ) n!
+ | - | = -------
+ ( k ) k!(n-k)!
+
+This method was added in v0.20 of Math::BigRat (May 2007).
+
+=head2 config()
use Data::Dumper;
undef
round_mode RW Global round mode
even
- div_scale RW Fallback acccuracy for div
+ div_scale RW Fallback accuracy for div
40
trap_nan RW Trap creation of NaN (undef = no)
undef
=head1 AUTHORS
-(C) by Tels L<http://bloodgate.com/> 2001 - 2005.
+(C) by Tels L<http://bloodgate.com/> 2001 - 2007.
=cut