package Math::BigFloat; # # Mike grinned. 'Two down, infinity to go' - Mike Nostrus in 'Before and After' # # The following hash values are used internally: # sign : "+", "-", "+inf", "-inf", or "NaN" if not a number # _m : mantissa ($LIB thingy) # _es : sign of _e # _e : exponent ($LIB thingy) # _a : accuracy # _p : precision use 5.006001; use strict; use warnings; use Carp qw< carp croak >; use Scalar::Util qw< blessed >; use Math::BigInt qw< >; our $VERSION = '1.999839'; $VERSION =~ tr/_//d; require Exporter; our @ISA = qw/Math::BigInt/; our @EXPORT_OK = qw/bpi/; # $_trap_inf/$_trap_nan are internal and should never be accessed from outside our ($AUTOLOAD, $accuracy, $precision, $div_scale, $round_mode, $rnd_mode, $upgrade, $downgrade, $_trap_nan, $_trap_inf); use overload # overload key: with_assign '+' => sub { $_[0] -> copy() -> badd($_[1]); }, '-' => sub { my $c = $_[0] -> copy(); $_[2] ? $c -> bneg() -> badd($_[1]) : $c -> bsub($_[1]); }, '*' => sub { $_[0] -> copy() -> bmul($_[1]); }, '/' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bdiv($_[0]) : $_[0] -> copy() -> bdiv($_[1]); }, '%' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bmod($_[0]) : $_[0] -> copy() -> bmod($_[1]); }, '**' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bpow($_[0]) : $_[0] -> copy() -> bpow($_[1]); }, '<<' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> blsft($_[0]) : $_[0] -> copy() -> blsft($_[1]); }, '>>' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> brsft($_[0]) : $_[0] -> copy() -> brsft($_[1]); }, # overload key: assign '+=' => sub { $_[0] -> badd($_[1]); }, '-=' => sub { $_[0] -> bsub($_[1]); }, '*=' => sub { $_[0] -> bmul($_[1]); }, '/=' => sub { scalar $_[0] -> bdiv($_[1]); }, '%=' => sub { $_[0] -> bmod($_[1]); }, '**=' => sub { $_[0] -> bpow($_[1]); }, '<<=' => sub { $_[0] -> blsft($_[1]); }, '>>=' => sub { $_[0] -> brsft($_[1]); }, # 'x=' => sub { }, # '.=' => sub { }, # overload key: num_comparison '<' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> blt($_[0]) : $_[0] -> blt($_[1]); }, '<=' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> ble($_[0]) : $_[0] -> ble($_[1]); }, '>' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bgt($_[0]) : $_[0] -> bgt($_[1]); }, '>=' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bge($_[0]) : $_[0] -> bge($_[1]); }, '==' => sub { $_[0] -> beq($_[1]); }, '!=' => sub { $_[0] -> bne($_[1]); }, # overload key: 3way_comparison '<=>' => sub { my $cmp = $_[0] -> bcmp($_[1]); defined($cmp) && $_[2] ? -$cmp : $cmp; }, 'cmp' => sub { $_[2] ? "$_[1]" cmp $_[0] -> bstr() : $_[0] -> bstr() cmp "$_[1]"; }, # overload key: str_comparison # 'lt' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bstrlt($_[0]) # : $_[0] -> bstrlt($_[1]); }, # # 'le' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bstrle($_[0]) # : $_[0] -> bstrle($_[1]); }, # # 'gt' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bstrgt($_[0]) # : $_[0] -> bstrgt($_[1]); }, # # 'ge' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bstrge($_[0]) # : $_[0] -> bstrge($_[1]); }, # # 'eq' => sub { $_[0] -> bstreq($_[1]); }, # # 'ne' => sub { $_[0] -> bstrne($_[1]); }, # overload key: binary '&' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> band($_[0]) : $_[0] -> copy() -> band($_[1]); }, '&=' => sub { $_[0] -> band($_[1]); }, '|' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bior($_[0]) : $_[0] -> copy() -> bior($_[1]); }, '|=' => sub { $_[0] -> bior($_[1]); }, '^' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> bxor($_[0]) : $_[0] -> copy() -> bxor($_[1]); }, '^=' => sub { $_[0] -> bxor($_[1]); }, # '&.' => sub { }, # '&.=' => sub { }, # '|.' => sub { }, # '|.=' => sub { }, # '^.' => sub { }, # '^.=' => sub { }, # overload key: unary 'neg' => sub { $_[0] -> copy() -> bneg(); }, # '!' => sub { }, '~' => sub { $_[0] -> copy() -> bnot(); }, # '~.' => sub { }, # overload key: mutators '++' => sub { $_[0] -> binc() }, '--' => sub { $_[0] -> bdec() }, # overload key: func 'atan2' => sub { $_[2] ? ref($_[0]) -> new($_[1]) -> batan2($_[0]) : $_[0] -> copy() -> batan2($_[1]); }, 'cos' => sub { $_[0] -> copy() -> bcos(); }, 'sin' => sub { $_[0] -> copy() -> bsin(); }, 'exp' => sub { $_[0] -> copy() -> bexp($_[1]); }, 'abs' => sub { $_[0] -> copy() -> babs(); }, 'log' => sub { $_[0] -> copy() -> blog(); }, 'sqrt' => sub { $_[0] -> copy() -> bsqrt(); }, 'int' => sub { $_[0] -> copy() -> bint(); }, # overload key: conversion 'bool' => sub { $_[0] -> is_zero() ? '' : 1; }, '""' => sub { $_[0] -> bstr(); }, '0+' => sub { $_[0] -> numify(); }, '=' => sub { $_[0] -> copy(); }, ; ############################################################################## # global constants, flags and assorted stuff # the following are public, but their usage is not recommended. Use the # accessor methods instead. # class constants, use Class->constant_name() to access # one of 'even', 'odd', '+inf', '-inf', 'zero', 'trunc' or 'common' $round_mode = 'even'; $accuracy = undef; $precision = undef; $div_scale = 40; $upgrade = undef; $downgrade = undef; # the package we are using for our private parts, defaults to: # Math::BigInt->config('lib') my $LIB = 'Math::BigInt::Calc'; # are NaNs ok? (otherwise it dies when encountering an NaN) set w/ config() $_trap_nan = 0; # the same for infinity $_trap_inf = 0; # constant for easier life my $nan = 'NaN'; my $IMPORT = 0; # was import() called yet? used to make require work # some digits of accuracy for blog(undef, 10); which we use in blog() for speed my $LOG_10 = '2.3025850929940456840179914546843642076011014886287729760333279009675726097'; my $LOG_10_A = length($LOG_10)-1; # ditto for log(2) my $LOG_2 = '0.6931471805599453094172321214581765680755001343602552541206800094933936220'; my $LOG_2_A = length($LOG_2)-1; my $HALF = '0.5'; # made into an object if nec. ############################################################################## # the old code had $rnd_mode, so we need to support it, too sub TIESCALAR { my ($class) = @_; bless \$round_mode, $class; } sub FETCH { return $round_mode; } sub STORE { $rnd_mode = $_[0]->round_mode($_[1]); } BEGIN { # when someone sets $rnd_mode, we catch this and check the value to see # whether it is valid or not. $rnd_mode = 'even'; tie $rnd_mode, 'Math::BigFloat'; *as_number = \&as_int; } sub DESTROY { # going through AUTOLOAD for every DESTROY is costly, avoid it by empty sub } sub AUTOLOAD { # make fxxx and bxxx both work by selectively mapping fxxx() to MBF::bxxx() my $name = $AUTOLOAD; $name =~ s/(.*):://; # split package my $c = $1 || __PACKAGE__; no strict 'refs'; $c->import() if $IMPORT == 0; if (!_method_alias($name)) { if (!defined $name) { # delayed load of Carp and avoid recursion croak("$c: Can't call a method without name"); } if (!_method_hand_up($name)) { # delayed load of Carp and avoid recursion croak("Can't call $c\-\>$name, not a valid method"); } # try one level up, but subst. bxxx() for fxxx() since MBI only got # bxxx() $name =~ s/^f/b/; return &{"Math::BigInt"."::$name"}(@_); } my $bname = $name; $bname =~ s/^f/b/; $c .= "::$name"; *{$c} = \&{$bname}; &{$c}; # uses @_ } ############################################################################## { # valid method aliases for AUTOLOAD my %methods = map { $_ => 1 } qw / fadd fsub fmul fdiv fround ffround fsqrt fmod fstr fsstr fpow fnorm fint facmp fcmp fzero fnan finf finc fdec ffac fneg fceil ffloor frsft flsft fone flog froot fexp /; # valid methods that can be handed up (for AUTOLOAD) my %hand_ups = map { $_ => 1 } qw / is_nan is_inf is_negative is_positive is_pos is_neg accuracy precision div_scale round_mode fabs fnot objectify upgrade downgrade bone binf bnan bzero bsub /; sub _method_alias { exists $methods{$_[0]||''}; } sub _method_hand_up { exists $hand_ups{$_[0]||''}; } } sub isa { my ($self, $class) = @_; return if $class =~ /^Math::BigInt/; # we aren't one of these UNIVERSAL::isa($self, $class); } sub config { # return (later set?) configuration data as hash ref my $class = shift || 'Math::BigFloat'; # Getter/accessor. if (@_ == 1 && ref($_[0]) ne 'HASH') { my $param = shift; return $class if $param eq 'class'; return $LIB if $param eq 'with'; return $class->SUPER::config($param); } # Setter. my $cfg = $class->SUPER::config(@_); # now we need only to override the ones that are different from our parent $cfg->{class} = $class; $cfg->{with} = $LIB; $cfg; } ############################################################################### # Constructor methods ############################################################################### sub new { # Create a new Math::BigFloat object from a string or another bigfloat # object. # _e: exponent # _m: mantissa # sign => ("+", "-", "+inf", "-inf", or "NaN") my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Make "require" work. $class -> import() if $IMPORT == 0; # Although this use has been discouraged for more than 10 years, people # apparently still use it, so we still support it. return $class -> bzero() unless @_; my ($wanted, @r) = @_; if (!defined($wanted)) { #if (warnings::enabled("uninitialized")) { # warnings::warn("uninitialized", # "Use of uninitialized value in new()"); #} return $class -> bzero(@r); } if (!ref($wanted) && $wanted eq "") { #if (warnings::enabled("numeric")) { # warnings::warn("numeric", # q|Argument "" isn't numeric in new()|); #} #return $class -> bzero(@r); return $class -> bnan(@r); } # Initialize a new object. $self = bless {}, $class unless $selfref; # Math::BigFloat or subclass if (defined(blessed($wanted)) && $wanted -> isa($class)) { # Don't copy the accuracy and precision, because a new object should get # them from the global configuration. $self -> {sign} = $wanted -> {sign}; $self -> {_m} = $LIB -> _copy($wanted -> {_m}); $self -> {_es} = $wanted -> {_es}; $self -> {_e} = $LIB -> _copy($wanted -> {_e}); $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $self; } # Shortcut for Math::BigInt and its subclasses. This should be improved. if (defined(blessed($wanted))) { if ($wanted -> isa('Math::BigInt')) { $self->{sign} = $wanted -> {sign}; $self->{_m} = $LIB -> _copy($wanted -> {value}); $self->{_es} = '+'; $self->{_e} = $LIB -> _zero(); return $self -> bnorm(); } if ($wanted -> can("as_number")) { $self->{sign} = $wanted -> sign(); $self->{_m} = $wanted -> as_number() -> {value}; $self->{_es} = '+'; $self->{_e} = $LIB -> _zero(); return $self -> bnorm(); } } # Shortcut for simple forms like '123' that have no trailing zeros. Trailing # zeros would require a non-zero exponent. if ($wanted =~ / ^ \s* # optional leading whitespace ( [+-]? ) # optional sign 0* # optional leading zeros ( [1-9] (?: [0-9]* [1-9] )? ) # significand \s* # optional trailing whitespace $ /x) { return $downgrade -> new($1 . $2) if defined $downgrade; $self->{sign} = $1 || '+'; $self->{_m} = $LIB -> _new($2); $self->{_es} = '+'; $self->{_e} = $LIB -> _zero(); $self = $self->round(@r) unless @r >= 2 && !defined $r[0] && !defined $r[1]; return $self; } # Handle Infs. if ($wanted =~ / ^ \s* ( [+-]? ) inf (?: inity )? \s* \z /ix) { my $sgn = $1 || '+'; return $class -> binf($sgn, @r); } # Handle explicit NaNs (not the ones returned due to invalid input). if ($wanted =~ / ^ \s* ( [+-]? ) nan \s* \z /ix) { return $class -> bnan(@r); } my @parts; if ( # Handle hexadecimal numbers. We auto-detect hexadecimal numbers if they # have a "0x", "0X", "x", or "X" prefix, cf. CORE::oct(). $wanted =~ /^\s*[+-]?0?[Xx]/ and @parts = $class -> _hex_str_to_flt_lib_parts($wanted) or # Handle octal numbers. We auto-detect octal numbers if they have a # "0o", "0O", "o", "O" prefix, cf. CORE::oct(). $wanted =~ /^\s*[+-]?0?[Oo]/ and @parts = $class -> _oct_str_to_flt_lib_parts($wanted) or # Handle binary numbers. We auto-detect binary numbers if they have a # "0b", "0B", "b", or "B" prefix, cf. CORE::oct(). $wanted =~ /^\s*[+-]?0?[Bb]/ and @parts = $class -> _bin_str_to_flt_lib_parts($wanted) or # At this point, what is left are decimal numbers that aren't handled # above and octal floating point numbers that don't have any of the # "0o", "0O", "o", or "O" prefixes. First see if it is a decimal number. @parts = $class -> _dec_str_to_flt_lib_parts($wanted) or # See if it is an octal floating point number. The extra check is # included because _oct_str_to_flt_lib_parts() accepts octal numbers # that don't have a prefix (this is needed to make it work with, e.g., # from_oct() that don't require a prefix). However, Perl requires a # prefix for octal floating point literals. For example, "1p+0" is not # valid, but "01p+0" and "0__1p+0" are. $wanted =~ /^\s*[+-]?0_*\d/ and @parts = $class -> _oct_str_to_flt_lib_parts($wanted)) { ($self->{sign}, $self->{_m}, $self->{_es}, $self->{_e}) = @parts; $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self; } # If we get here, the value is neither a valid decimal, binary, octal, or # hexadecimal number. It is not an explicit Inf or a NaN either. return $class -> bnan(@r); } sub from_dec { my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('from_dec'); my $str = shift; my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; if (my @parts = $class -> _dec_str_to_flt_lib_parts($str)) { ($self->{sign}, $self->{_m}, $self->{_es}, $self->{_e}) = @parts; $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self; } return $self -> bnan(@r); } sub from_hex { my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('from_hex'); my $str = shift; my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; if (my @parts = $class -> _hex_str_to_flt_lib_parts($str)) { ($self->{sign}, $self->{_m}, $self->{_es}, $self->{_e}) = @parts; $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self; } return $self -> bnan(@r); } sub from_oct { my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('from_oct'); my $str = shift; my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; if (my @parts = $class -> _oct_str_to_flt_lib_parts($str)) { ($self->{sign}, $self->{_m}, $self->{_es}, $self->{_e}) = @parts; $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self; } return $self -> bnan(@r); } sub from_bin { my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('from_bin'); my $str = shift; my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; if (my @parts = $class -> _bin_str_to_flt_lib_parts($str)) { ($self->{sign}, $self->{_m}, $self->{_es}, $self->{_e}) = @parts; $self = $self->round(@r) unless @r >= 2 && !defined($r[0]) && !defined($r[1]); return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self; } return $self -> bnan(@r); } sub from_ieee754 { my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('from_ieee754'); my $in = shift; # input string (or raw bytes) my $format = shift; # format ("binary32", "decimal64" etc.) my $enc; # significand encoding (applies only to decimal) my $k; # storage width in bits my $b; # base my @r = @_; # rounding parameters, if any if ($format =~ /^binary(\d+)\z/) { $k = $1; $b = 2; } elsif ($format =~ /^decimal(\d+)(dpd|bcd)?\z/) { $k = $1; $b = 10; $enc = $2 || 'dpd'; # default is dencely-packed decimals (DPD) } elsif ($format eq 'half') { $k = 16; $b = 2; } elsif ($format eq 'single') { $k = 32; $b = 2; } elsif ($format eq 'double') { $k = 64; $b = 2; } elsif ($format eq 'quadruple') { $k = 128; $b = 2; } elsif ($format eq 'octuple') { $k = 256; $b = 2; } elsif ($format eq 'sexdecuple') { $k = 512; $b = 2; } if ($b == 2) { # Get the parameters for this format. my $p; # precision (in bits) my $t; # number of bits in significand my $w; # number of bits in exponent if ($k == 16) { # binary16 (half-precision) $p = 11; $t = 10; $w = 5; } elsif ($k == 32) { # binary32 (single-precision) $p = 24; $t = 23; $w = 8; } elsif ($k == 64) { # binary64 (double-precision) $p = 53; $t = 52; $w = 11; } else { # binaryN (quadruple-precision and above) if ($k < 128 || $k != 32 * sprintf('%.0f', $k / 32)) { croak "Number of bits must be 16, 32, 64, or >= 128 and", " a multiple of 32"; } $p = $k - sprintf('%.0f', 4 * log($k) / log(2)) + 13; $t = $p - 1; $w = $k - $t - 1; } # The maximum exponent, minimum exponent, and exponent bias. my $emax = Math::BigFloat -> new(2) -> bpow($w - 1) -> bdec(); my $emin = 1 - $emax; my $bias = $emax; # Undefined input. unless (defined $in) { carp("Input is undefined"); return $self -> bzero(@r); } # Make sure input string is a string of zeros and ones. my $len = CORE::length $in; if (8 * $len == $k) { # bytes $in = unpack "B*", $in; } elsif (4 * $len == $k) { # hexadecimal if ($in =~ /([^\da-f])/i) { croak "Illegal hexadecimal digit '$1'"; } $in = unpack "B*", pack "H*", $in; } elsif ($len == $k) { # bits if ($in =~ /([^01])/) { croak "Illegal binary digit '$1'"; } } else { croak "Unknown input -- $in"; } # Split bit string into sign, exponent, and mantissa/significand. my $sign = substr($in, 0, 1) eq '1' ? '-' : '+'; my $expo = $class -> from_bin(substr($in, 1, $w)); my $mant = $class -> from_bin(substr($in, $w + 1)); my $x; $expo = $expo -> bsub($bias); # subtract bias if ($expo < $emin) { # zero and subnormals if ($mant == 0) { # zero $x = $class -> bzero(); } else { # subnormals # compute (1/$b)**(N) rather than ($b)**(-N) $x = $class -> new("0.5"); # 1/$b $x = $x -> bpow($bias + $t - 1) -> bmul($mant); $x = $x -> bneg() if $sign eq '-'; } } elsif ($expo > $emax) { # inf and nan if ($mant == 0) { # inf $x = $class -> binf($sign); } else { # nan $x = $class -> bnan(@r); } } else { # normals $mant = $class -> new(2) -> bpow($t) -> badd($mant); if ($expo < $t) { # compute (1/$b)**(N) rather than ($b)**(-N) $x = $class -> new("0.5"); # 1/$b $x = $x -> bpow($t - $expo) -> bmul($mant); } else { $x = $class -> new(2); $x = $x -> bpow($expo - $t) -> bmul($mant); } $x = $x -> bneg() if $sign eq '-'; } if ($selfref) { $self -> {sign} = $x -> {sign}; $self -> {_m} = $x -> {_m}; $self -> {_es} = $x -> {_es}; $self -> {_e} = $x -> {_e}; } else { $self = $x; } return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self -> is_int(); return $self -> round(@r); } croak("The format '$format' is not yet supported."); } sub bzero { # create/assign '+0' # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; $self->import() if $IMPORT == 0; # make require work # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('bzero'); # Get the rounding parameters, if any. my @r = @_; return $downgrade -> bzero(@r) if defined $downgrade; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; $self -> {sign} = '+'; $self -> {_m} = $LIB -> _zero(); $self -> {_es} = '+'; $self -> {_e} = $LIB -> _zero(); # If rounding parameters are given as arguments, use them. If no rounding # parameters are given, and if called as a class method initialize the new # instance with the class variables. #return $self -> round(@r); # this should work, but doesnt; fixme! if (@r) { croak "can't specify both accuracy and precision" if @r >= 2 && defined($r[0]) && defined($r[1]); $self->{_a} = $r[0]; $self->{_p} = $r[1]; } else { unless($selfref) { $self->{_a} = $class -> accuracy(); $self->{_p} = $class -> precision(); } } return $self; } sub bone { # Create or assign '+1' (or -1 if given sign '-'). # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; $self->import() if $IMPORT == 0; # make require work # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('bone'); return $downgrade -> bone(@_) if defined $downgrade; # Get the sign. my $sign = '+'; # default is to return +1 if (defined($_[0]) && $_[0] =~ /^\s*([+-])\s*$/) { $sign = $1; shift; } # Get the rounding parameters, if any. my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; $self -> {sign} = $sign; $self -> {_m} = $LIB -> _one(); $self -> {_es} = '+'; $self -> {_e} = $LIB -> _zero(); # If rounding parameters are given as arguments, use them. If no rounding # parameters are given, and if called as a class method initialize the new # instance with the class variables. #return $self -> round(@r); # this should work, but doesnt; fixme! if (@r) { croak "can't specify both accuracy and precision" if @r >= 2 && defined($r[0]) && defined($r[1]); $self->{_a} = $_[0]; $self->{_p} = $_[1]; } else { unless($selfref) { $self->{_a} = $class -> accuracy(); $self->{_p} = $class -> precision(); } } return $self; } sub binf { # create/assign a '+inf' or '-inf' # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; { no strict 'refs'; if (${"${class}::_trap_inf"}) { croak("Tried to create +-inf in $class->binf()"); } } $self->import() if $IMPORT == 0; # make require work # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('binf'); return $downgrade -> binf(@_) if $downgrade; # Get the sign. my $sign = '+'; # default is to return positive infinity if (defined($_[0]) && $_[0] =~ /^\s*([+-])(inf|$)/i) { $sign = $1; shift; } # Get the rounding parameters, if any. my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; $self -> {sign} = $sign . 'inf'; $self -> {_m} = $LIB -> _zero(); $self -> {_es} = '+'; $self -> {_e} = $LIB -> _zero(); # If rounding parameters are given as arguments, use them. If no rounding # parameters are given, and if called as a class method initialize the new # instance with the class variables. #return $self -> round(@r); # this should work, but doesnt; fixme! if (@r) { croak "can't specify both accuracy and precision" if @r >= 2 && defined($r[0]) && defined($r[1]); $self->{_a} = $r[0]; $self->{_p} = $r[1]; } else { unless($selfref) { $self->{_a} = $class -> accuracy(); $self->{_p} = $class -> precision(); } } return $self; } sub bnan { # create/assign a 'NaN' # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; { no strict 'refs'; if (${"${class}::_trap_nan"}) { croak("Tried to create NaN in $class->bnan()"); } } $self->import() if $IMPORT == 0; # make require work # Don't modify constant (read-only) objects. return $self if $selfref && $self->modify('bnan'); return $downgrade -> bnan(@_) if defined $downgrade; # Get the rounding parameters, if any. my @r = @_; # If called as a class method, initialize a new object. $self = bless {}, $class unless $selfref; $self -> {sign} = $nan; $self -> {_m} = $LIB -> _zero(); $self -> {_es} = '+'; $self -> {_e} = $LIB -> _zero(); # If rounding parameters are given as arguments, use them. If no rounding # parameters are given, and if called as a class method initialize the new # instance with the class variables. #return $self -> round(@r); # this should work, but doesnt; fixme! if (@r) { croak "can't specify both accuracy and precision" if @r >= 2 && defined($r[0]) && defined($r[1]); $self->{_a} = $r[0]; $self->{_p} = $r[1]; } else { unless($selfref) { $self->{_a} = $class -> accuracy(); $self->{_p} = $class -> precision(); } } return $self; } sub bpi { # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } # Called as Argument list # --------- ------------- # Math::BigFloat->bpi() ("Math::BigFloat") # Math::BigFloat->bpi(10) ("Math::BigFloat", 10) # $x->bpi() ($x) # $x->bpi(10) ($x, 10) # Math::BigFloat::bpi() () # Math::BigFloat::bpi(10) (10) # # In ambiguous cases, we favour the OO-style, so the following case # # $n = Math::BigFloat->new("10"); # $x = Math::BigFloat->bpi($n); # # which gives an argument list with the single element $n, is resolved as # # $n->bpi(); my $self = shift; my $selfref = ref $self; my $class = $selfref || $self; my @r = @_; # rounding paramters if ($selfref) { # bpi() called as an instance method return $self if $self -> modify('bpi'); } else { # bpi() called as a class method $self = bless {}, $class; # initialize new instance } ($self, @r) = $self -> _find_round_parameters(@r); # The accuracy, i.e., the number of digits. Pi has one digit before the # dot, so a precision of 4 digits is equivalent to an accuracy of 5 digits. my $n = defined $r[0] ? $r[0] : defined $r[1] ? 1 - $r[1] : $self -> div_scale(); my $rmode = defined $r[2] ? $r[2] : $self -> round_mode(); my $pi; if ($n <= 1000) { # 75 x 14 = 1050 digits my $all_digits = < '+', _m => $LIB -> _new($digits), _es => '-', _e => $LIB -> _new($n - 1), }, $class; } else { # For large accuracy, the arctan formulas become very inefficient with # Math::BigFloat, so use Brent-Salamin (aka AGM or Gauss-Legendre). # Use a few more digits in the intermediate computations. $n += 8; $HALF = $class -> new($HALF) unless ref($HALF); my ($an, $bn, $tn, $pn) = ($class -> bone, $HALF -> copy() -> bsqrt($n), $HALF -> copy() -> bmul($HALF), $class -> bone); while ($pn < $n) { my $prev_an = $an -> copy(); $an = $an -> badd($bn) -> bmul($HALF, $n); $bn = $bn -> bmul($prev_an) -> bsqrt($n); $prev_an = $prev_an -> bsub($an); $tn = $tn -> bsub($pn * $prev_an * $prev_an); $pn = $pn -> badd($pn); } $an = $an -> badd($bn); $an = $an -> bmul($an, $n) -> bdiv(4 * $tn, $n); $an = $an -> round(@r); $pi = $an; } if (defined $r[0]) { $pi -> accuracy($r[0]); } elsif (defined $r[1]) { $pi -> precision($r[1]); } for my $key (qw/ sign _m _es _e _a _p /) { $self -> {$key} = $pi -> {$key}; } return $downgrade -> new($self -> bdstr(), @r) if defined($downgrade) && $self->is_int(); return $self; } sub copy { my ($x, $class); if (ref($_[0])) { # $y = $x -> copy() $x = shift; $class = ref($x); } else { # $y = Math::BigInt -> copy($y) $class = shift; $x = shift; } carp "Rounding is not supported for ", (caller(0))[3], "()" if @_; my $copy = bless {}, $class; $copy->{sign} = $x->{sign}; $copy->{_es} = $x->{_es}; $copy->{_m} = $LIB->_copy($x->{_m}); $copy->{_e} = $LIB->_copy($x->{_e}); $copy->{_a} = $x->{_a} if exists $x->{_a}; $copy->{_p} = $x->{_p} if exists $x->{_p}; return $copy; } sub as_int { # return copy as a bigint representation of this Math::BigFloat number my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x -> copy() if $x -> isa("Math::BigInt"); # disable upgrading and downgrading require Math::BigInt; my $upg = Math::BigInt -> upgrade(); my $dng = Math::BigInt -> downgrade(); Math::BigInt -> upgrade(undef); Math::BigInt -> downgrade(undef); my $y; if ($x -> is_inf()) { $y = Math::BigInt -> binf($x->sign()); } elsif ($x -> is_nan()) { $y = Math::BigInt -> bnan(); } else { $y = $LIB->_copy($x->{_m}); if ($x->{_es} eq '-') { # < 0 $y = $LIB->_rsft($y, $x->{_e}, 10); } elsif (! $LIB->_is_zero($x->{_e})) { # > 0 $y = $LIB->_lsft($y, $x->{_e}, 10); } $y = Math::BigInt->new($x->{sign} . $LIB->_str($y)); } # reset upgrading and downgrading Math::BigInt -> upgrade($upg); Math::BigInt -> downgrade($dng); return $y; } sub as_float { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x -> copy() if $x -> isa("Math::BigFloat"); # disable upgrading and downgrading require Math::BigFloat; my $upg = Math::BigFloat -> upgrade(); my $dng = Math::BigFloat -> downgrade(); Math::BigFloat -> upgrade(undef); Math::BigFloat -> downgrade(undef); my $y = Math::BigFloat -> new($x); # reset upgrading and downgrading Math::BigFloat -> upgrade($upg); Math::BigFloat -> downgrade($dng); return $y; } ############################################################################### # Boolean methods ############################################################################### sub is_zero { # return true if arg (BFLOAT or num_str) is zero my (undef, $x) = ref($_[0]) ? (undef, @_) : objectify(1, @_); ($x->{sign} eq '+' && $LIB->_is_zero($x->{_m})) ? 1 : 0; } sub is_one { # return true if arg (BFLOAT or num_str) is +1 or -1 if signis given my (undef, $x, $sign) = ref($_[0]) ? (undef, @_) : objectify(1, @_); $sign = '+' if !defined $sign || $sign ne '-'; ($x->{sign} eq $sign && $LIB->_is_zero($x->{_e}) && $LIB->_is_one($x->{_m})) ? 1 : 0; } sub is_odd { # return true if arg (BFLOAT or num_str) is odd or false if even my (undef, $x) = ref($_[0]) ? (undef, @_) : objectify(1, @_); (($x->{sign} =~ /^[+-]$/) && # NaN & +-inf aren't ($LIB->_is_zero($x->{_e})) && ($LIB->_is_odd($x->{_m}))) ? 1 : 0; } sub is_even { # return true if arg (BINT or num_str) is even or false if odd my (undef, $x) = ref($_[0]) ? (undef, @_) : objectify(1, @_); (($x->{sign} =~ /^[+-]$/) && # NaN & +-inf aren't ($x->{_es} eq '+') && # 123.45 isn't ($LIB->_is_even($x->{_m}))) ? 1 : 0; # but 1200 is } sub is_int { # return true if arg (BFLOAT or num_str) is an integer my (undef, $x) = ref($_[0]) ? (undef, @_) : objectify(1, @_); (($x->{sign} =~ /^[+-]$/) && # NaN and +-inf aren't ($x->{_es} eq '+')) ? 1 : 0; # 1e-1 => no integer } ############################################################################### # Comparison methods ############################################################################### sub bcmp { # Compares 2 values. Returns one of undef, <0, =0, >0. (suitable for sort) # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Handle all 'nan' cases. return if ($x->{sign} eq $nan) || ($y->{sign} eq $nan); # Handle all '+inf' and '-inf' cases. return 0 if ($x->{sign} eq '+inf' && $y->{sign} eq '+inf' || $x->{sign} eq '-inf' && $y->{sign} eq '-inf'); return +1 if $x->{sign} eq '+inf'; # x = +inf and y < +inf return -1 if $x->{sign} eq '-inf'; # x = -inf and y > -inf return -1 if $y->{sign} eq '+inf'; # x < +inf and y = +inf return +1 if $y->{sign} eq '-inf'; # x > -inf and y = -inf # Handle all cases with opposite signs. return +1 if $x->{sign} eq '+' && $y->{sign} eq '-'; # also does 0 <=> -y return -1 if $x->{sign} eq '-' && $y->{sign} eq '+'; # also does -x <=> 0 # Handle all remaining zero cases. my $xz = $x->is_zero(); my $yz = $y->is_zero(); return 0 if $xz && $yz; # 0 <=> 0 return -1 if $xz && $y->{sign} eq '+'; # 0 <=> +y return +1 if $yz && $x->{sign} eq '+'; # +x <=> 0 # Both arguments are now finite, non-zero numbers with the same sign. my $cmp; # The next step is to compare the exponents, but since each mantissa is an # integer of arbitrary value, the exponents must be normalized by the length # of the mantissas before we can compare them. my $mxl = $LIB->_len($x->{_m}); my $myl = $LIB->_len($y->{_m}); # If the mantissas have the same length, there is no point in normalizing # the exponents by the length of the mantissas, so treat that as a special # case. if ($mxl == $myl) { # First handle the two cases where the exponents have different signs. if ($x->{_es} eq '+' && $y->{_es} eq '-') { $cmp = +1; } elsif ($x->{_es} eq '-' && $y->{_es} eq '+') { $cmp = -1; } # Then handle the case where the exponents have the same sign. else { $cmp = $LIB->_acmp($x->{_e}, $y->{_e}); $cmp = -$cmp if $x->{_es} eq '-'; } # Adjust for the sign, which is the same for x and y, and bail out if # we're done. $cmp = -$cmp if $x->{sign} eq '-'; # 124 > 123, but -124 < -123 return $cmp if $cmp; } # We must normalize each exponent by the length of the corresponding # mantissa. Life is a lot easier if we first make both exponents # non-negative. We do this by adding the same positive value to both # exponent. This is safe, because when comparing the exponents, only the # relative difference is important. my $ex; my $ey; if ($x->{_es} eq '+') { # If the exponent of x is >= 0 and the exponent of y is >= 0, there is # no need to do anything special. if ($y->{_es} eq '+') { $ex = $LIB->_copy($x->{_e}); $ey = $LIB->_copy($y->{_e}); } # If the exponent of x is >= 0 and the exponent of y is < 0, add the # absolute value of the exponent of y to both. else { $ex = $LIB->_copy($x->{_e}); $ex = $LIB->_add($ex, $y->{_e}); # ex + |ey| $ey = $LIB->_zero(); # -ex + |ey| = 0 } } else { # If the exponent of x is < 0 and the exponent of y is >= 0, add the # absolute value of the exponent of x to both. if ($y->{_es} eq '+') { $ex = $LIB->_zero(); # -ex + |ex| = 0 $ey = $LIB->_copy($y->{_e}); $ey = $LIB->_add($ey, $x->{_e}); # ey + |ex| } # If the exponent of x is < 0 and the exponent of y is < 0, add the # absolute values of both exponents to both exponents. else { $ex = $LIB->_copy($y->{_e}); # -ex + |ey| + |ex| = |ey| $ey = $LIB->_copy($x->{_e}); # -ey + |ex| + |ey| = |ex| } } # Now we can normalize the exponents by adding lengths of the mantissas. $ex = $LIB->_add($ex, $LIB->_new($mxl)); $ey = $LIB->_add($ey, $LIB->_new($myl)); # We're done if the exponents are different. $cmp = $LIB->_acmp($ex, $ey); $cmp = -$cmp if $x->{sign} eq '-'; # 124 > 123, but -124 < -123 return $cmp if $cmp; # Compare the mantissas, but first normalize them by padding the shorter # mantissa with zeros (shift left) until it has the same length as the # longer mantissa. my $mx = $x->{_m}; my $my = $y->{_m}; if ($mxl > $myl) { $my = $LIB->_lsft($LIB->_copy($my), $LIB->_new($mxl - $myl), 10); } elsif ($mxl < $myl) { $mx = $LIB->_lsft($LIB->_copy($mx), $LIB->_new($myl - $mxl), 10); } $cmp = $LIB->_acmp($mx, $my); $cmp = -$cmp if $x->{sign} eq '-'; # 124 > 123, but -124 < -123 return $cmp; } sub bacmp { # Compares 2 values, ignoring their signs. # Returns one of undef, <0, =0, >0. (suitable for sort) # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # handle +-inf and NaN's if ($x->{sign} !~ /^[+-]$/ || $y->{sign} !~ /^[+-]$/) { return if (($x->{sign} eq $nan) || ($y->{sign} eq $nan)); return 0 if ($x->is_inf() && $y->is_inf()); return 1 if ($x->is_inf() && !$y->is_inf()); return -1; } # shortcut my $xz = $x->is_zero(); my $yz = $y->is_zero(); return 0 if $xz && $yz; # 0 <=> 0 return -1 if $xz && !$yz; # 0 <=> +y return 1 if $yz && !$xz; # +x <=> 0 # adjust so that exponents are equal my $lxm = $LIB->_len($x->{_m}); my $lym = $LIB->_len($y->{_m}); my ($xes, $yes) = (1, 1); $xes = -1 if $x->{_es} ne '+'; $yes = -1 if $y->{_es} ne '+'; # the numify somewhat limits our length, but makes it much faster my $lx = $lxm + $xes * $LIB->_num($x->{_e}); my $ly = $lym + $yes * $LIB->_num($y->{_e}); my $l = $lx - $ly; return $l <=> 0 if $l != 0; # lengths (corrected by exponent) are equal # so make mantissa equal-length by padding with zero (shift left) my $diff = $lxm - $lym; my $xm = $x->{_m}; # not yet copy it my $ym = $y->{_m}; if ($diff > 0) { $ym = $LIB->_copy($y->{_m}); $ym = $LIB->_lsft($ym, $LIB->_new($diff), 10); } elsif ($diff < 0) { $xm = $LIB->_copy($x->{_m}); $xm = $LIB->_lsft($xm, $LIB->_new(-$diff), 10); } $LIB->_acmp($xm, $ym); } ############################################################################### # Arithmetic methods ############################################################################### sub bneg { # (BINT or num_str) return BINT # negate number or make a negated number from string my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); return $x if $x->modify('bneg'); return $x -> bnan(@r) if $x -> is_nan(); # For +0 do not negate (to have always normalized +0). $x->{sign} =~ tr/+-/-+/ unless $x->{sign} eq '+' && $LIB->_is_zero($x->{_m}); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf() || $x -> is_nan()); return $x -> round(@r); } sub bnorm { # bnorm() can't support rounding, because bround() and bfround() call # bnorm(), which would recurse indefinitely. # adjust m and e so that m is smallest possible my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # inf, nan etc if ($x->{sign} !~ /^[+-]$/) { return $downgrade -> new($x) if defined $downgrade; return $x; } my $zeros = $LIB->_zeros($x->{_m}); # correct for trailing zeros if ($zeros != 0) { my $z = $LIB->_new($zeros); $x->{_m} = $LIB->_rsft($x->{_m}, $z, 10); if ($x->{_es} eq '-') { if ($LIB->_acmp($x->{_e}, $z) >= 0) { $x->{_e} = $LIB->_sub($x->{_e}, $z); $x->{_es} = '+' if $LIB->_is_zero($x->{_e}); } else { $x->{_e} = $LIB->_sub($LIB->_copy($z), $x->{_e}); $x->{_es} = '+'; } } else { $x->{_e} = $LIB->_add($x->{_e}, $z); } } else { # $x can only be 0Ey if there are no trailing zeros ('0' has 0 trailing # zeros). So, for something like 0Ey, set y to 0, and -0 => +0 if ($LIB->_is_zero($x->{_m})) { $x->{sign} = '+'; $x->{_es} = '+'; $x->{_e} = $LIB->_zero(); } } return $downgrade -> new($x) if defined($downgrade) && $x->is_int(); return $x; } sub binc { # increment arg by one my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('binc'); # Inf and NaN return $x -> bnan(@r) if $x -> is_nan(); return $x -> binf($x->{sign}, @r) if $x -> is_inf(); # Non-integer if ($x->{_es} eq '-') { return $x->badd($class->bone(), @r); } # If the exponent is non-zero, convert the internal representation, so that, # e.g., 12e+3 becomes 12000e+0 and we can easily increment the mantissa. if (!$LIB->_is_zero($x->{_e})) { $x->{_m} = $LIB->_lsft($x->{_m}, $x->{_e}, 10); # 1e2 => 100 $x->{_e} = $LIB->_zero(); # normalize $x->{_es} = '+'; # we know that the last digit of $x will be '1' or '9', depending on the # sign } # now $x->{_e} == 0 if ($x->{sign} eq '+') { $x->{_m} = $LIB->_inc($x->{_m}); return $x->bnorm()->bround(@r); } elsif ($x->{sign} eq '-') { $x->{_m} = $LIB->_dec($x->{_m}); $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # -1 +1 => -0 => +0 return $x->bnorm()->bround(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; } sub bdec { # decrement arg by one my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bdec'); # Inf and NaN return $x -> bnan(@r) if $x -> is_nan(); return $x -> binf($x->{sign}, @r) if $x -> is_inf(); # Non-integer if ($x->{_es} eq '-') { return $x->badd($class->bone('-'), @r); } # If the exponent is non-zero, convert the internal representation, so that, # e.g., 12e+3 becomes 12000e+0 and we can easily increment the mantissa. if (!$LIB->_is_zero($x->{_e})) { $x->{_m} = $LIB->_lsft($x->{_m}, $x->{_e}, 10); # 1e2 => 100 $x->{_e} = $LIB->_zero(); # normalize $x->{_es} = '+'; } # now $x->{_e} == 0 my $zero = $x->is_zero(); if (($x->{sign} eq '-') || $zero) { # x <= 0 $x->{_m} = $LIB->_inc($x->{_m}); $x->{sign} = '-' if $zero; # 0 => 1 => -1 $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # -1 +1 => -0 => +0 return $x->bnorm()->round(@r); } elsif ($x->{sign} eq '+') { # x > 0 $x->{_m} = $LIB->_dec($x->{_m}); return $x->bnorm()->round(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x -> round(@r); } sub badd { # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x->modify('badd'); # inf and NaN handling if ($x->{sign} !~ /^[+-]$/ || $y->{sign} !~ /^[+-]$/) { # $x is NaN and/or $y is NaN if ($x->{sign} eq $nan || $y->{sign} eq $nan) { $x = $x->bnan(); } # $x is Inf and $y is Inf elsif ($x->{sign} =~ /^[+-]inf$/ && $y->{sign} =~ /^[+-]inf$/) { # +Inf + +Inf or -Inf + -Inf => same, rest is NaN $x = $x->bnan() if $x->{sign} ne $y->{sign}; } # +-inf + something => +-inf; something +-inf => +-inf elsif ($y->{sign} =~ /^[+-]inf$/) { $x->{sign} = $y->{sign}; } return $downgrade -> new($x -> bdstr(), @r) if defined $downgrade; return $x -> round(@r); } return $upgrade->badd($x, $y, @r) if defined $upgrade; $r[3] = $y; # no push! # for speed: no add for $x + 0 if ($y->is_zero()) { $x = $x->round(@r); } # for speed: no add for 0 + $y elsif ($x->is_zero()) { # make copy, clobbering up x (modify in place!) $x->{_e} = $LIB->_copy($y->{_e}); $x->{_es} = $y->{_es}; $x->{_m} = $LIB->_copy($y->{_m}); $x->{sign} = $y->{sign} || $nan; $x = $x->round(@r); } # both $x and $y are non-zero else { # take lower of the two e's and adapt m1 to it to match m2 my $e = $y->{_e}; $e = $LIB->_zero() if !defined $e; # if no BFLOAT? $e = $LIB->_copy($e); # make copy (didn't do it yet) my $es; ($e, $es) = $LIB -> _ssub($e, $y->{_es} || '+', $x->{_e}, $x->{_es}); my $add = $LIB->_copy($y->{_m}); if ($es eq '-') { # < 0 $x->{_m} = $LIB->_lsft($x->{_m}, $e, 10); ($x->{_e}, $x->{_es}) = $LIB -> _sadd($x->{_e}, $x->{_es}, $e, $es); } elsif (!$LIB->_is_zero($e)) { # > 0 $add = $LIB->_lsft($add, $e, 10); } # else: both e are the same, so just leave them if ($x->{sign} eq $y->{sign}) { $x->{_m} = $LIB->_add($x->{_m}, $add); } else { ($x->{_m}, $x->{sign}) = $LIB -> _sadd($x->{_m}, $x->{sign}, $add, $y->{sign}); } # delete trailing zeros, then round $x = $x->bnorm()->round(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; # rounding already done above } sub bsub { # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x -> modify('bsub'); if ($y -> is_zero()) { $x = $x -> round(@r); } else { # To correctly handle the special case $x -> bsub($x), we note the sign # of $x, then flip the sign of $y, and if the sign of $x changed too, # then we know that $x and $y are the same object. my $xsign = $x -> {sign}; $y -> {sign} =~ tr/+-/-+/; # does nothing for NaN if ($xsign ne $x -> {sign}) { # special case of $x -> bsub($x) results in 0 if ($xsign =~ /^[+-]$/) { $x = $x -> bzero(@r); } else { $x = $x -> bnan(); # NaN, -inf, +inf } return $downgrade -> new($x -> bdstr(), @r) if defined $downgrade; return $x -> round(@r); } $x = $x -> badd($y, @r); # badd does not leave internal zeros $y -> {sign} =~ tr/+-/-+/; # reset $y (does nothing for NaN) } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); $x; # already rounded by badd() or no rounding } sub bmul { # multiply two numbers # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x->modify('bmul'); return $x->bnan(@r) if ($x->{sign} eq $nan) || ($y->{sign} eq $nan); # inf handling if (($x->{sign} =~ /^[+-]inf$/) || ($y->{sign} =~ /^[+-]inf$/)) { return $x->bnan(@r) if $x->is_zero() || $y->is_zero(); # result will always be +-inf: # +inf * +/+inf => +inf, -inf * -/-inf => +inf # +inf * -/-inf => -inf, -inf * +/+inf => -inf return $x->binf(@r) if ($x->{sign} =~ /^\+/ && $y->{sign} =~ /^\+/); return $x->binf(@r) if ($x->{sign} =~ /^-/ && $y->{sign} =~ /^-/); return $x->binf('-', @r); } return $upgrade->bmul($x, $y, @r) if defined $upgrade; # aEb * cEd = (a*c)E(b+d) $x->{_m} = $LIB->_mul($x->{_m}, $y->{_m}); ($x->{_e}, $x->{_es}) = $LIB -> _sadd($x->{_e}, $x->{_es}, $y->{_e}, $y->{_es}); $r[3] = $y; # no push! # adjust sign: $x->{sign} = $x->{sign} ne $y->{sign} ? '-' : '+'; $x = $x->bnorm->round(@r); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } sub bmuladd { # multiply two numbers and add the third to the result # set up parameters my ($class, $x, $y, $z, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) && ref($_[1]) eq ref($_[2]) ? (ref($_[0]), @_) : objectify(3, @_); return $x if $x->modify('bmuladd'); return $x->bnan(@r) if (($x->{sign} eq $nan) || ($y->{sign} eq $nan) || ($z->{sign} eq $nan)); # inf handling if (($x->{sign} =~ /^[+-]inf$/) || ($y->{sign} =~ /^[+-]inf$/)) { return $x->bnan(@r) if $x->is_zero() || $y->is_zero(); # result will always be +-inf: # +inf * +/+inf => +inf, -inf * -/-inf => +inf # +inf * -/-inf => -inf, -inf * +/+inf => -inf return $x->binf(@r) if ($x->{sign} =~ /^\+/ && $y->{sign} =~ /^\+/); return $x->binf(@r) if ($x->{sign} =~ /^-/ && $y->{sign} =~ /^-/); return $x->binf('-', @r); } # aEb * cEd = (a*c)E(b+d) $x->{_m} = $LIB->_mul($x->{_m}, $y->{_m}); ($x->{_e}, $x->{_es}) = $LIB -> _sadd($x->{_e}, $x->{_es}, $y->{_e}, $y->{_es}); $r[3] = $y; # no push! # adjust sign: $x->{sign} = $x->{sign} ne $y->{sign} ? '-' : '+'; # z=inf handling (z=NaN handled above) if ($z->{sign} =~ /^[+-]inf$/) { $x->{sign} = $z->{sign}; return $downgrade -> new($x -> bdstr(), @r) if defined $downgrade; return $x -> round(@r); } # take lower of the two e's and adapt m1 to it to match m2 my $e = $z->{_e}; $e = $LIB->_zero() if !defined $e; # if no BFLOAT? $e = $LIB->_copy($e); # make copy (didn't do it yet) my $es; ($e, $es) = $LIB -> _ssub($e, $z->{_es} || '+', $x->{_e}, $x->{_es}); my $add = $LIB->_copy($z->{_m}); if ($es eq '-') # < 0 { $x->{_m} = $LIB->_lsft($x->{_m}, $e, 10); ($x->{_e}, $x->{_es}) = $LIB -> _sadd($x->{_e}, $x->{_es}, $e, $es); } elsif (!$LIB->_is_zero($e)) # > 0 { $add = $LIB->_lsft($add, $e, 10); } # else: both e are the same, so just leave them if ($x->{sign} eq $z->{sign}) { # add $x->{_m} = $LIB->_add($x->{_m}, $add); } else { ($x->{_m}, $x->{sign}) = $LIB -> _sadd($x->{_m}, $x->{sign}, $add, $z->{sign}); } # delete trailing zeros, then round $x = $x->bnorm()->round(@r); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } sub bdiv { # (dividend: BFLOAT or num_str, divisor: BFLOAT or num_str) return # (BFLOAT, BFLOAT) (quo, rem) or BFLOAT (only quo) # set up parameters my ($class, $x, $y, @r) = (ref($_[0]), @_); # objectify is costly, so avoid it if ((!ref($_[0])) || (ref($_[0]) ne ref($_[1]))) { ($class, $x, $y, @r) = objectify(2, @_); } return $x if $x->modify('bdiv'); my $wantarray = wantarray; # call only once # At least one argument is NaN. This is handled the same way as in # Math::BigInt -> bdiv(). if ($x -> is_nan() || $y -> is_nan()) { return $wantarray ? ($x -> bnan(@r), $class -> bnan(@r)) : $x -> bnan(@r); } # Divide by zero and modulo zero. This is handled the same way as in # Math::BigInt -> bdiv(). See the comment in the code for Math::BigInt -> # bdiv() for further details. if ($y -> is_zero()) { my ($quo, $rem); if ($wantarray) { $rem = $x -> copy() -> round(@r); $rem = $downgrade -> new($rem, @r) if defined($downgrade) && $rem -> is_int(); } if ($x -> is_zero()) { $quo = $x -> bnan(@r); } else { $quo = $x -> binf($x -> {sign}, @r); } return $wantarray ? ($quo, $rem) : $quo; } # Numerator (dividend) is +/-inf. This is handled the same way as in # Math::BigInt -> bdiv(). See the comment in the code for Math::BigInt -> # bdiv() for further details. if ($x -> is_inf()) { my ($quo, $rem); $rem = $class -> bnan(@r) if $wantarray; if ($y -> is_inf()) { $quo = $x -> bnan(@r); } else { my $sign = $x -> bcmp(0) == $y -> bcmp(0) ? '+' : '-'; $quo = $x -> binf($sign, @r); } return $wantarray ? ($quo, $rem) : $quo; } # Denominator (divisor) is +/-inf. This is handled the same way as in # Math::BigInt -> bdiv(), with one exception: In scalar context, # Math::BigFloat does true division (although rounded), not floored division # (F-division), so a finite number divided by +/-inf is always zero. See the # comment in the code for Math::BigInt -> bdiv() for further details. if ($y -> is_inf()) { my ($quo, $rem); if ($wantarray) { if ($x -> is_zero() || $x -> bcmp(0) == $y -> bcmp(0)) { $rem = $x -> copy() -> round(@r); $rem = $downgrade -> new($rem, @r) if defined($downgrade) && $rem -> is_int(); $quo = $x -> bzero(@r); } else { $rem = $class -> binf($y -> {sign}, @r); $quo = $x -> bone('-', @r); } return ($quo, $rem); } else { if ($y -> is_inf()) { if ($x -> is_nan() || $x -> is_inf()) { return $x -> bnan(@r); } else { return $x -> bzero(@r); } } } } # At this point, both the numerator and denominator are finite numbers, and # the denominator (divisor) is non-zero. # x == 0? if ($x->is_zero()) { my ($quo, $rem); $quo = $x->round(@r); $quo = $downgrade -> new($quo, @r) if defined($downgrade) && $quo -> is_int(); if ($wantarray) { $rem = $class -> bzero(@r); return $quo, $rem; } return $quo; } # Division might return a value that we can not represent exactly, so # upgrade, if upgrading is enabled. return $upgrade -> bdiv($x, $y, @r) if defined($upgrade) && !wantarray && !$LIB -> _is_one($y -> {_m}); # we need to limit the accuracy to protect against overflow my $fallback = 0; my (@params, $scale); ($x, @params) = $x->_find_round_parameters($r[0], $r[1], $r[2], $y); return $x -> round(@r) if $x->is_nan(); # error in _find_round_parameters? # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } my $rem; $rem = $class -> bzero() if wantarray; $y = $class->new($y) unless $y->isa('Math::BigFloat'); my $lx = $LIB -> _len($x->{_m}); my $ly = $LIB -> _len($y->{_m}); $scale = $lx if $lx > $scale; $scale = $ly if $ly > $scale; my $diff = $ly - $lx; $scale += $diff if $diff > 0; # if lx << ly, but not if ly << lx! # check that $y is not 1 nor -1 and cache the result: my $y_not_one = !($LIB->_is_zero($y->{_e}) && $LIB->_is_one($y->{_m})); # flipping the sign of $y will also flip the sign of $x for the special # case of $x->bsub($x); so we can catch it below: my $xsign = $x->{sign}; $y->{sign} =~ tr/+-/-+/; if ($xsign ne $x->{sign}) { # special case of $x /= $x results in 1 $x = $x->bone(); # "fixes" also sign of $y, since $x is $y } else { # correct $y's sign again $y->{sign} =~ tr/+-/-+/; # continue with normal div code: # make copy of $x in case of list context for later remainder # calculation if (wantarray && $y_not_one) { $rem = $x->copy(); } $x->{sign} = $x->{sign} ne $y->sign() ? '-' : '+'; # check for / +-1 (+/- 1E0) if ($y_not_one) { # promote Math::BigInt and its subclasses (except when already a # Math::BigFloat) $y = $class->new($y) unless $y->isa('Math::BigFloat'); # calculate the result to $scale digits and then round it # a * 10 ** b / c * 10 ** d => a/c * 10 ** (b-d) $x->{_m} = $LIB->_lsft($x->{_m}, $LIB->_new($scale), 10); $x->{_m} = $LIB->_div($x->{_m}, $y->{_m}); # a/c # correct exponent of $x ($x->{_e}, $x->{_es}) = $LIB -> _ssub($x->{_e}, $x->{_es}, $y->{_e}, $y->{_es}); # correct for 10**scale ($x->{_e}, $x->{_es}) = $LIB -> _ssub($x->{_e}, $x->{_es}, $LIB->_new($scale), '+'); $x = $x->bnorm(); # remove trailing 0's } } # end else $x != $y # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x->{_a} = undef; # clear before round $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x->{_p} = undef; # clear before round $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } if (wantarray) { if ($y_not_one) { $x = $x -> bfloor(); $rem = $rem->bmod($y, @params); # copy already done } if ($fallback) { # clear a/p after round, since user did not request it $rem->{_a} = undef; $rem->{_p} = undef; } $x = $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); $rem = $downgrade -> new($rem -> bdstr(), @r) if defined($downgrade) && $rem -> is_int(); return ($x, $rem); } $x = $downgrade -> new($x, @r) if defined($downgrade) && $x -> is_int(); $x; # rounding already done above } sub bmod { # (dividend: BFLOAT or num_str, divisor: BFLOAT or num_str) return remainder # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x->modify('bmod'); # At least one argument is NaN. This is handled the same way as in # Math::BigInt -> bmod(). return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); # Modulo zero. This is handled the same way as in Math::BigInt -> bmod(). if ($y -> is_zero()) { return $x -> round(@r); } # Numerator (dividend) is +/-inf. This is handled the same way as in # Math::BigInt -> bmod(). if ($x -> is_inf()) { return $x -> bnan(@r); } # Denominator (divisor) is +/-inf. This is handled the same way as in # Math::BigInt -> bmod(). if ($y -> is_inf()) { if ($x -> is_zero() || $x -> bcmp(0) == $y -> bcmp(0)) { return $x -> round(@r); } else { return $x -> binf($y -> sign(), @r); } } return $x->bzero(@r) if $x->is_zero() || ($x->is_int() && # check that $y == +1 or $y == -1: ($LIB->_is_zero($y->{_e}) && $LIB->_is_one($y->{_m}))); my $cmp = $x->bacmp($y); # equal or $x < $y? if ($cmp == 0) { # $x == $y => result 0 return $x -> bzero(@r); } # only $y of the operands negative? my $neg = $x->{sign} ne $y->{sign} ? 1 : 0; $x->{sign} = $y->{sign}; # calc sign first if ($cmp < 0 && $neg == 0) { # $x < $y => result $x return $x -> round(@r); } my $ym = $LIB->_copy($y->{_m}); # 2e1 => 20 $ym = $LIB->_lsft($ym, $y->{_e}, 10) if $y->{_es} eq '+' && !$LIB->_is_zero($y->{_e}); # if $y has digits after dot my $shifty = 0; # correct _e of $x by this if ($y->{_es} eq '-') # has digits after dot { # 123 % 2.5 => 1230 % 25 => 5 => 0.5 $shifty = $LIB->_num($y->{_e}); # no more digits after dot # 123 => 1230, $y->{_m} is already 25 $x->{_m} = $LIB->_lsft($x->{_m}, $y->{_e}, 10); } # $ym is now mantissa of $y based on exponent 0 my $shiftx = 0; # correct _e of $x by this if ($x->{_es} eq '-') # has digits after dot { # 123.4 % 20 => 1234 % 200 $shiftx = $LIB->_num($x->{_e}); # no more digits after dot $ym = $LIB->_lsft($ym, $x->{_e}, 10); # 123 => 1230 } # 123e1 % 20 => 1230 % 20 if ($x->{_es} eq '+' && !$LIB->_is_zero($x->{_e})) { $x->{_m} = $LIB->_lsft($x->{_m}, $x->{_e}, 10); # es => '+' here } $x->{_e} = $LIB->_new($shiftx); $x->{_es} = '+'; $x->{_es} = '-' if $shiftx != 0 || $shifty != 0; $x->{_e} = $LIB->_add($x->{_e}, $LIB->_new($shifty)) if $shifty != 0; # now mantissas are equalized, exponent of $x is adjusted, so calc result $x->{_m} = $LIB->_mod($x->{_m}, $ym); $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # fix sign for -0 $x = $x->bnorm(); # if one of them negative => correct in place if ($neg != 0 && ! $x -> is_zero()) { my $r = $y - $x; $x->{_m} = $r->{_m}; $x->{_e} = $r->{_e}; $x->{_es} = $r->{_es}; $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # fix sign for -0 $x = $x->bnorm(); } $x = $x->round($r[0], $r[1], $r[2], $y); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } sub bmodpow { # takes a very large number to a very large exponent in a given very # large modulus, quickly, thanks to binary exponentiation. Supports # negative exponents. my ($class, $num, $exp, $mod, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) && ref($_[1]) eq ref($_[2]) ? (ref($_[0]), @_) : objectify(3, @_); return $num if $num->modify('bmodpow'); return $num -> bnan(@r) if $mod->is_nan() || $exp->is_nan() || $mod->is_nan(); # check modulus for valid values return $num->bnan(@r) if $mod->{sign} ne '+' || $mod->is_zero(); # check exponent for valid values if ($exp->{sign} =~ /\w/) { # i.e., if it's NaN, +inf, or -inf... return $num->bnan(@r); } $num = $num->bmodinv($mod, @r) if $exp->{sign} eq '-'; # check num for valid values (also NaN if there was no inverse but $exp < 0) return $num->bnan(@r) if $num->{sign} !~ /^[+-]$/; # $mod is positive, sign on $exp is ignored, result also positive # XXX TODO: speed it up when all three numbers are integers $num = $num->bpow($exp)->bmod($mod); return $downgrade -> new($num -> bdstr(), @r) if defined($downgrade) && ($num->is_int() || $num->is_inf() || $num->is_nan()); return $num -> round(@r); } sub bpow { # (BFLOAT or num_str, BFLOAT or num_str) return BFLOAT # compute power of two numbers, second arg is used as integer # modifies first argument # set up parameters my ($class, $x, $y, $a, $p, $r) = (ref($_[0]), @_); # objectify is costly, so avoid it if ((!ref($_[0])) || (ref($_[0]) ne ref($_[1]))) { ($class, $x, $y, $a, $p, $r) = objectify(2, @_); } return $x if $x -> modify('bpow'); # $x and/or $y is a NaN return $x -> bnan() if $x -> is_nan() || $y -> is_nan(); # $x and/or $y is a +/-Inf if ($x -> is_inf("-")) { return $x -> bzero() if $y -> is_negative(); return $x -> bnan() if $y -> is_zero(); return $x if $y -> is_odd(); return $x -> bneg(); } elsif ($x -> is_inf("+")) { return $x -> bzero() if $y -> is_negative(); return $x -> bnan() if $y -> is_zero(); return $x; } elsif ($y -> is_inf("-")) { return $x -> bnan() if $x -> is_one("-"); return $x -> binf("+") if $x > -1 && $x < 1; return $x -> bone() if $x -> is_one("+"); return $x -> bzero(); } elsif ($y -> is_inf("+")) { return $x -> bnan() if $x -> is_one("-"); return $x -> bzero() if $x > -1 && $x < 1; return $x -> bone() if $x -> is_one("+"); return $x -> binf("+"); } if ($x -> is_zero()) { return $x -> bone() if $y -> is_zero(); return $x -> binf() if $y -> is_negative(); return $x; } # We don't support complex numbers, so upgrade or return NaN. if ($x -> is_negative() && !$y -> is_int()) { return $upgrade -> bpow($x, $y, $a, $p, $r) if defined $upgrade; return $x -> bnan(); } if ($x -> is_one("+") || $y -> is_one()) { return $x; } if ($x -> is_one("-")) { return $x if $y -> is_odd(); return $x -> bneg(); } return $x -> _pow($y, $a, $p, $r) if !$y -> is_int(); my $y1 = $y -> as_int()->{value}; # make MBI part my $new_sign = '+'; $new_sign = $LIB -> _is_odd($y1) ? '-' : '+' if $x->{sign} ne '+'; # calculate $x->{_m} ** $y and $x->{_e} * $y separately (faster) $x->{_m} = $LIB -> _pow($x->{_m}, $y1); $x->{_e} = $LIB -> _mul($x->{_e}, $y1); $x->{sign} = $new_sign; $x = $x -> bnorm(); # x ** (-y) = 1 / (x ** y) if ($y->{sign} eq '-') { # modify $x in place! my $z = $x -> copy(); $x = $x -> bone(); # round in one go (might ignore y's A!) return scalar $x -> bdiv($z, $a, $p, $r); } $x = $x -> round($a, $p, $r, $y); return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } sub blog { # Return the logarithm of the operand. If a second operand is defined, that # value is used as the base, otherwise the base is assumed to be Euler's # constant. my ($class, $x, $base, @r); # Only objectify the base if it is defined, since an undefined base, as in # $x->blog() or $x->blog(undef) signals that the base is Euler's number = # 2.718281828... if (!ref($_[0]) && $_[0] =~ /^[A-Za-z]|::/) { # E.g., Math::BigFloat->blog(256, 2) ($class, $x, $base, @r) = defined $_[2] ? objectify(2, @_) : objectify(1, @_); } else { # E.g., $x->blog(2) or the deprecated Math::BigFloat::blog(256, 2) ($class, $x, $base, @r) = defined $_[1] ? objectify(2, @_) : objectify(1, @_); } return $x if $x->modify('blog'); # Handle all exception cases and all trivial cases. I have used Wolfram # Alpha (http://www.wolframalpha.com) as the reference for these cases. return $x -> bnan(@r) if $x -> is_nan(); if (defined $base) { $base = $class -> new($base) unless defined(blessed($base)) && $base -> isa($class); if ($base -> is_nan() || $base -> is_one()) { return $x -> bnan(@r); } elsif ($base -> is_inf() || $base -> is_zero()) { return $x -> bnan(@r) if $x -> is_inf() || $x -> is_zero(); return $x -> bzero(@r); } elsif ($base -> is_negative()) { # -inf < base < 0 return $x -> bzero(@r) if $x -> is_one(); # x = 1 return $x -> bone('+', @r) if $x == $base; # x = base # we can't handle these cases, so upgrade, if we can return $upgrade -> blog($x, $base, @r) if defined $upgrade; return $x -> bnan(@r); } return $x -> bone(@r) if $x == $base; # 0 < base && 0 < x < inf } if ($x -> is_inf()) { # x = +/-inf my $sign = defined($base) && $base < 1 ? '-' : '+'; return $x -> binf($sign, @r); } elsif ($x -> is_neg()) { # -inf < x < 0 return $upgrade -> blog($x, $base, @r) if defined $upgrade; return $x -> bnan(@r); } elsif ($x -> is_one()) { # x = 1 return $x -> bzero(@r); } elsif ($x -> is_zero()) { # x = 0 my $sign = defined($base) && $base < 1 ? '+' : '-'; return $x -> binf($sign, @r); } # we need to limit the accuracy to protect against overflow my $fallback = 0; my ($scale, @params); ($x, @params) = $x->_find_round_parameters(@r); # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->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[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; my $done = 0; # If both $x and $base are integers, try to calculate an integer result # first. This is very fast, and if the exact result was found, we are done. if (defined($base) && $base -> is_int() && $x -> is_int()) { my $x_lib = $LIB -> _new($x -> bdstr()); my $b_lib = $LIB -> _new($base -> bdstr()); ($x_lib, my $exact) = $LIB -> _log_int($x_lib, $b_lib); if ($exact) { $x->{_m} = $x_lib; $x->{_e} = $LIB -> _zero(); $x = $x -> bnorm(); $done = 1; } } # If the integer result was not accurate, compute the natural logarithm # log($x) (using reduction by 10 and possibly also by 2), and if a # different base was requested, convert the result with log($x)/log($base). unless ($done) { $x = $x -> _log_10($scale); if (defined $base) { # log_b(x) = ln(x) / ln(b), so compute ln(b) my $base_log_e = $base -> copy() -> _log_10($scale); $x = $x -> bdiv($base_log_e, $scale); } } # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x -> bround($params[0], $params[2]); # then round accordingly } else { $x = $x -> bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; } sub bexp { # Calculate e ** X (Euler's number to the power of X) my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bexp'); return $x->bnan(@r) if $x -> is_nan(); return $x->binf(@r) if $x->{sign} eq '+inf'; return $x->bzero(@r) 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(@r); # error in _find_round_parameters? return $x->bnan(@r) if $x->{sign} eq 'NaN'; # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->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[2]; # 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 $x->is_zero(); if (!$x->isa('Math::BigFloat')) { $x = Math::BigFloat->new($x); $class = ref($x); } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. # Temporarily disable downgrading my $dng = Math::BigFloat -> downgrade(); Math::BigFloat -> downgrade(undef); my $x_org = $x->copy(); # We use the following Taylor series: # x x^2 x^3 x^4 # e = 1 + --- + --- + --- + --- ... # 1! 2! 3! 4! # The difference for each term is X and N, which would result in: # 2 copy, 2 mul, 2 add, 1 inc, 1 div operations per term # But it is faster to compute exp(1) and then raising it to the # given power, esp. if $x is really big and an integer because: # * The numerator is always 1, making the computation faster # * the series converges faster in the case of x == 1 # * We can also easily check when we have reached our limit: when the # term to be added is smaller than "1E$scale", we can stop - f.i. # scale == 5, and we have 1/40320, then we stop since 1/40320 < 1E-5. # * we can compute the *exact* result by simulating bigrat math: # 1 1 gcd(3, 4) = 1 1*24 + 1*6 5 # - + - = ---------- = -- # 6 24 6*24 24 # We do not compute the gcd() here, but simple do: # 1 1 1*24 + 1*6 30 # - + - = --------- = -- # 6 24 6*24 144 # In general: # a c a*d + c*b and note that c is always 1 and d = (b*f) # - + - = --------- # b d b*d # This leads to: which can be reduced by b to: # a 1 a*b*f + b a*f + 1 # - + - = --------- = ------- # b b*f b*b*f b*f # The first terms in the series are: # 1 1 1 1 1 1 1 1 13700 # -- + -- + -- + -- + -- + --- + --- + ---- = ----- # 1 1 2 6 24 120 720 5040 5040 # Note that we cannot simply reduce 13700/5040 to 685/252, but must keep # the numerator and the denominator! if ($scale <= 75) { # set $x directly from a cached string form $x->{_m} = $LIB->_new("2718281828459045235360287471352662497757" . "2470936999595749669676277240766303535476"); $x->{sign} = '+'; $x->{_es} = '-'; $x->{_e} = $LIB->_new(79); } 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 = $LIB->_new("9093339520860578540197197" . "0164779391644753259799242"); my $F = $LIB->_new(42); my $step = 42; # Compute how many steps we need to take to get $A and $B sufficiently # big my $steps = _len_to_steps($scale - 4); # print STDERR "# Doing $steps steps for ", $scale-4, " digits\n"; while ($step++ <= $steps) { # calculate $a * $f + 1 $A = $LIB->_mul($A, $F); $A = $LIB->_inc($A); # increment f $F = $LIB->_inc($F); } # Compute $B as factorial of $steps (this is faster than doing it # manually) my $B = $LIB->_fac($LIB->_new($steps)); # print "A ", $LIB->_str($A), "\nB ", $LIB->_str($B), "\n"; # compute A/B with $scale digits in the result (truncate, not round) $A = $LIB->_lsft($A, $LIB->_new($scale), 10); $A = $LIB->_div($A, $B); $x->{_m} = $A; $x->{sign} = '+'; $x->{_es} = '-'; $x->{_e} = $LIB->_new($scale); } # $x contains now an estimate of e, with some surplus digits, so we can # round if (!$x_org->is_one()) { # Reduce size of fractional part, followup with integer power of two. my $lshift = 0; while ($lshift < 30 && $x_org->bacmp(2 << $lshift) > 0) { $lshift++; } # Raise $x to the wanted power and round it. if ($lshift == 0) { $x = $x->bpow($x_org, @params); } else { my($mul, $rescale) = (1 << $lshift, $scale+1+$lshift); $x = $x -> bpow(scalar $x_org->bdiv($mul, $rescale), $rescale) -> bpow($mul, @params); } } else { # else just round the already computed result $x->{_a} = undef; $x->{_p} = undef; # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # Restore globals $$abr = $ab; $$pbr = $pb; # Restore downgrading. Math::BigFloat -> downgrade($dng); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); $x; } sub bnok { # Calculate n over k (binomial coefficient or "choose" function) as integer. # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x if $x->modify('bnok'); return $x->bnan() if $x->is_nan() || $y->is_nan(); return $x->bnan() if (($x->is_finite() && !$x->is_int()) || ($y->is_finite() && !$y->is_int())); my $xint = Math::BigInt -> new($x -> bsstr()); my $yint = Math::BigInt -> new($y -> bsstr()); $xint = $xint -> bnok($yint); return $xint if defined $downgrade; my $xflt = Math::BigFloat -> new($xint); $x->{_m} = $xflt->{_m}; $x->{_e} = $xflt->{_e}; $x->{_es} = $xflt->{_es}; $x->{sign} = $xflt->{sign}; return $x; } sub bsin { # Calculate a sinus of x. my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # taylor: x^3 x^5 x^7 x^9 # sin = x - --- + --- - --- + --- ... # 3! 5! 7! 9! return $x if $x->modify('bsin'); return $x -> bzero(@r) if $x->is_zero(); return $x -> bnan(@r) if $x->is_nan() || $x->is_inf(); # we need to limit the accuracy to protect against overflow my $fallback = 0; my ($scale, @params); ($x, @params) = $x->_find_round_parameters(@r); # error in _find_round_parameters? return $x->bnan(@r) if $x->is_nan(); # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $params[1] = undef; # disable P $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; my $over = $x * $x; # X ^ 2 my $x2 = $over->copy(); # X ^ 2; difference between terms $over = $over->bmul($x); # X ^ 3 as starting value my $sign = 1; # start with -= my $below = $class->new(6); my $factorial = $class->new(4); $x->{_a} = undef; $x->{_p} = undef; my $limit = $class->new("1E-". ($scale-1)); while (1) { # we calculate the next term, and add it to the last # when the next term is below our limit, it won't affect the outcome # anymore, so we stop: my $next = $over->copy()->bdiv($below, $scale); last if $next->bacmp($limit) <= 0; if ($sign == 0) { $x = $x->badd($next); } else { $x = $x->bsub($next); } $sign = 1-$sign; # alternate # calculate things for the next term $over = $over->bmul($x2); # $x*$x $below = $below->bmul($factorial); # n*(n+1) $factorial = $factorial->binc(); $below = $below -> bmul($factorial); # n*(n+1) $factorial = $factorial->binc(); } # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); $x; } sub bcos { # Calculate a cosinus of x. my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # Taylor: x^2 x^4 x^6 x^8 # cos = 1 - --- + --- - --- + --- ... # 2! 4! 6! 8! # we need to limit the accuracy to protect against overflow my $fallback = 0; my ($scale, @params); ($x, @params) = $x->_find_round_parameters(@r); # constant object or error in _find_round_parameters? return $x if $x->modify('bcos') || $x->is_nan(); return $x->bnan() if $x->is_inf(); return $x->bone(@r) if $x->is_zero(); # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $params[1] = undef; # disable P $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; my $over = $x * $x; # X ^ 2 my $x2 = $over->copy(); # X ^ 2; difference between terms my $sign = 1; # start with -= my $below = $class->new(2); my $factorial = $class->new(3); $x = $x->bone(); $x->{_a} = undef; $x->{_p} = undef; my $limit = $class->new("1E-". ($scale-1)); #my $steps = 0; while (3 < 5) { # we calculate the next term, and add it to the last # when the next term is below our limit, it won't affect the outcome # anymore, so we stop: my $next = $over->copy()->bdiv($below, $scale); last if $next->bacmp($limit) <= 0; if ($sign == 0) { $x = $x->badd($next); } else { $x = $x->bsub($next); } $sign = 1-$sign; # alternate # calculate things for the next term $over = $over->bmul($x2); # $x*$x $below = $below->bmul($factorial); # n*(n+1) $factorial = $factorial -> binc(); $below = $below->bmul($factorial); # n*(n+1) $factorial = $factorial -> binc(); } # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); $x; } sub batan { # Calculate a arcus tangens of x. my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # taylor: x^3 x^5 x^7 x^9 # atan = x - --- + --- - --- + --- ... # 3 5 7 9 return $x if $x->modify('batan'); return $x -> bnan(@r) if $x->is_nan(); # We need to limit the accuracy to protect against overflow. my $fallback = 0; my ($scale, @params); ($x, @params) = $x->_find_round_parameters(@r); # Error in _find_round_parameters? return $x -> bnan(@r) if $x->is_nan(); if ($x->{sign} =~ /^[+-]inf\z/) { # +inf result is PI/2 # -inf result is -PI/2 # calculate PI/2 my $pi = $class->bpi(@r); # modify $x in place $x->{_m} = $pi->{_m}; $x->{_e} = $pi->{_e}; $x->{_es} = $pi->{_es}; # -y => -PI/2, +y => PI/2 $x->{sign} = substr($x->{sign}, 0, 1); # "+inf" => "+" $x -> {_m} = $LIB->_div($x->{_m}, $LIB->_new(2)); return $x; } return $x->bzero(@r) if $x->is_zero(); # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $params[1] = undef; # disable P $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # 1 or -1 => PI/4 # inlined is_one() && is_one('-') if ($LIB->_is_one($x->{_m}) && $LIB->_is_zero($x->{_e})) { my $pi = $class->bpi($scale - 3); # modify $x in place $x->{_m} = $pi->{_m}; $x->{_e} = $pi->{_e}; $x->{_es} = $pi->{_es}; # leave the sign of $x alone (+1 => +PI/4, -1 => -PI/4) $x->{_m} = $LIB->_div($x->{_m}, $LIB->_new(4)); return $x; } # This series is only valid if -1 < x < 1, so for other x we need to # calculate PI/2 - atan(1/x): my $pi = undef; if ($x->bacmp($x->copy()->bone) >= 0) { # calculate PI/2 $pi = $class->bpi($scale - 3); $pi->{_m} = $LIB->_div($pi->{_m}, $LIB->_new(2)); # calculate 1/$x: my $x_copy = $x->copy(); # modify $x in place $x = $x->bone(); $x = $x->bdiv($x_copy, $scale); } my $fmul = 1; foreach (0 .. int($scale / 20)) { $fmul *= 2; $x = $x->bdiv($x->copy()->bmul($x)->binc()->bsqrt($scale + 4)->binc(), $scale + 4); } # When user set globals, they would interfere with our calculation, so # disable them and later re-enable them. no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # We also need to disable any set A or P on $x (_find_round_parameters # took them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; my $over = $x * $x; # X ^ 2 my $x2 = $over->copy(); # X ^ 2; difference between terms $over = $over->bmul($x); # X ^ 3 as starting value my $sign = 1; # start with -= my $below = $class->new(3); my $two = $class->new(2); $x->{_a} = undef; $x->{_p} = undef; my $limit = $class->new("1E-". ($scale-1)); #my $steps = 0; while (1) { # We calculate the next term, and add it to the last. When the next # term is below our limit, it won't affect the outcome anymore, so we # stop: my $next = $over->copy()->bdiv($below, $scale); last if $next->bacmp($limit) <= 0; if ($sign == 0) { $x = $x->badd($next); } else { $x = $x->bsub($next); } $sign = 1-$sign; # alternatex # calculate things for the next term $over = $over->bmul($x2); # $x*$x $below = $below->badd($two); # n += 2 } $x = $x->bmul($fmul); if (defined $pi) { my $x_copy = $x->copy(); # modify $x in place $x->{_m} = $pi->{_m}; $x->{_e} = $pi->{_e}; $x->{_es} = $pi->{_es}; # PI/2 - $x $x = $x->bsub($x_copy); } # Shortcut to not run through _find_round_parameters again. if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # Clear a/p after round, since user did not request it. $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf()); $x; } sub batan2 { # $y -> batan2($x) returns the arcus tangens of $y / $x. # Set up parameters. my ($class, $y, $x, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); # Quick exit if $y is read-only. return $y if $y -> modify('batan2'); # Handle all NaN cases. return $y -> bnan() if $x->{sign} eq $nan || $y->{sign} eq $nan; # We need to limit the accuracy to protect against overflow. my $fallback = 0; my ($scale, @params); ($y, @params) = $y -> _find_round_parameters(@r); # Error in _find_round_parameters? return $y if $y->is_nan(); # No rounding at all, so must use fallback. if (scalar @params == 0) { # Simulate old behaviour $params[0] = $class -> div_scale(); # and round to it as accuracy $params[1] = undef; # disable P $scale = $params[0] + 4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough ... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } if ($x -> is_inf("+")) { # x = inf if ($y -> is_inf("+")) { # y = inf $y = $y -> bpi($scale) -> bmul("0.25"); # pi/4 } elsif ($y -> is_inf("-")) { # y = -inf $y = $y -> bpi($scale) -> bmul("-0.25"); # -pi/4 } else { # -inf < y < inf return $y -> bzero(@r); # 0 } } elsif ($x -> is_inf("-")) { # x = -inf if ($y -> is_inf("+")) { # y = inf $y = $y -> bpi($scale) -> bmul("0.75"); # 3/4 pi } elsif ($y -> is_inf("-")) { # y = -inf $y = $y -> bpi($scale) -> bmul("-0.75"); # -3/4 pi } elsif ($y >= 0) { # y >= 0 $y = $y -> bpi($scale); # pi } else { # y < 0 $y = $y -> bpi($scale) -> bneg(); # -pi } } elsif ($x > 0) { # 0 < x < inf if ($y -> is_inf("+")) { # y = inf $y = $y -> bpi($scale) -> bmul("0.5"); # pi/2 } elsif ($y -> is_inf("-")) { # y = -inf $y = $y -> bpi($scale) -> bmul("-0.5"); # -pi/2 } else { # -inf < y < inf $y = $y -> bdiv($x, $scale) -> batan($scale); # atan(y/x) } } elsif ($x < 0) { # -inf < x < 0 my $pi = $class -> bpi($scale); if ($y >= 0) { # y >= 0 $y = $y -> bdiv($x, $scale) -> batan() # atan(y/x) + pi -> badd($pi); } else { # y < 0 $y = $y -> bdiv($x, $scale) -> batan() # atan(y/x) - pi -> bsub($pi); } } else { # x = 0 if ($y > 0) { # y > 0 $y = $y -> bpi($scale) -> bmul("0.5"); # pi/2 } elsif ($y < 0) { # y < 0 $y = $y -> bpi($scale) -> bmul("-0.5"); # -pi/2 } else { # y = 0 return $y -> bzero(@r); # 0 } } $y = $y -> round(@r); if ($fallback) { $y->{_a} = undef; $y->{_p} = undef; } return $y; } sub bsqrt { # calculate square root my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bsqrt'); # Handle trivial cases. return $x -> bnan(@r) if $x->is_nan(); return $x -> binf("+", @r) if $x->{sign} eq '+inf'; return $x -> round(@r) if $x->is_zero() || $x->is_one(); # We don't support complex numbers. if ($x -> is_neg()) { return $upgrade -> bsqrt($x, @r) if defined($upgrade); return $x -> bnan(@r); } # we need to limit the accuracy to protect against overflow my $fallback = 0; my (@params, $scale); ($x, @params) = $x->_find_round_parameters(@r); # error in _find_round_parameters? return $x -> bnan(@r) if $x->is_nan(); # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; my $i = $LIB->_copy($x->{_m}); $i = $LIB->_lsft($i, $x->{_e}, 10) unless $LIB->_is_zero($x->{_e}); my $xas = Math::BigInt->bzero(); $xas->{value} = $i; my $gs = $xas->copy()->bsqrt(); # some guess if (($x->{_es} ne '-') # guess can't be accurate if there are # digits after the dot && ($xas->bacmp($gs * $gs) == 0)) # guess hit the nail on the head? { # exact result, copy result over to keep $x $x->{_m} = $gs->{value}; $x->{_e} = $LIB->_zero(); $x->{_es} = '+'; $x = $x->bnorm(); # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # re-enable A and P, upgrade is taken care of by "local" ${"$class\::accuracy"} = $ab; ${"$class\::precision"} = $pb; return $x; } # sqrt(2) = 1.4 because sqrt(2*100) = 1.4*10; so we can increase the # accuracy of the result by multiplying the input by 100 and then divide the # integer result of sqrt(input) by 10. Rounding afterwards returns the real # result. # The following steps will transform 123.456 (in $x) into 123456 (in $y1) my $y1 = $LIB->_copy($x->{_m}); my $length = $LIB->_len($y1); # Now calculate how many digits the result of sqrt(y1) would have my $digits = int($length / 2); # But we need at least $scale digits, so calculate how many are missing my $shift = $scale - $digits; # This happens if the input had enough digits # (we take care of integer guesses above) $shift = 0 if $shift < 0; # Multiply in steps of 100, by shifting left two times the "missing" digits my $s2 = $shift * 2; # We now make sure that $y1 has the same odd or even number of digits than # $x had. So when _e of $x is odd, we must shift $y1 by one digit left, # because we always must multiply by steps of 100 (sqrt(100) is 10) and not # steps of 10. The length of $x does not count, since an even or odd number # of digits before the dot is not changed by adding an even number of digits # after the dot (the result is still odd or even digits long). $s2++ if $LIB->_is_odd($x->{_e}); $y1 = $LIB->_lsft($y1, $LIB->_new($s2), 10); # now take the square root and truncate to integer $y1 = $LIB->_sqrt($y1); # By "shifting" $y1 right (by creating a negative _e) we calculate the final # result, which is than later rounded to the desired scale. # calculate how many zeros $x had after the '.' (or before it, depending # on sign of $dat, the result should have half as many: my $dat = $LIB->_num($x->{_e}); $dat = -$dat if $x->{_es} eq '-'; $dat += $length; if ($dat > 0) { # no zeros after the dot (e.g. 1.23, 0.49 etc) # preserve half as many digits before the dot than the input had # (but round this "up") $dat = int(($dat+1)/2); } else { $dat = int(($dat)/2); } $dat -= $LIB->_len($y1); if ($dat < 0) { $dat = abs($dat); $x->{_e} = $LIB->_new($dat); $x->{_es} = '-'; } else { $x->{_e} = $LIB->_new($dat); $x->{_es} = '+'; } $x->{_m} = $y1; $x = $x->bnorm(); # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf()); $x; } sub broot { # calculate $y'th root of $x # set up parameters my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x->modify('broot'); # Handle trivial cases. return $x -> bnan(@r) if $x->is_nan() || $y->is_nan(); if ($x -> is_neg()) { # -27 ** (1/3) = -3 return $x -> broot($y -> copy() -> bneg(), @r) -> bneg() if $x -> is_int() && $y -> is_int() && $y -> is_neg(); return $upgrade -> broot($x, $y, @r) if defined $upgrade; return $x -> bnan(@r); } # NaN handling: $x ** 1/0, x or y NaN, or y inf/-inf or y == 0 return $x->bnan() if $x->{sign} !~ /^\+/ || $y->is_zero() || $y->{sign} !~ /^\+$/; return $x if $x->is_zero() || $x->is_one() || $x->is_inf() || $y->is_one(); # we need to limit the accuracy to protect against overflow my $fallback = 0; my (@params, $scale); ($x, @params) = $x->_find_round_parameters(@r); return $x if $x->is_nan(); # error in _find_round_parameters? # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; # remember sign and make $x positive, since -4 ** (1/2) => -2 my $sign = 0; $sign = 1 if $x->{sign} eq '-'; $x->{sign} = '+'; my $is_two = 0; if ($y->isa('Math::BigFloat')) { $is_two = $y->{sign} eq '+' && $LIB->_is_two($y->{_m}) && $LIB->_is_zero($y->{_e}); } else { $is_two = $y == 2; } # normal square root if $y == 2: if ($is_two) { $x = $x->bsqrt($scale+4); } elsif ($y->is_one('-')) { # $x ** -1 => 1/$x my $u = $class->bone()->bdiv($x, $scale); # copy private parts over $x->{_m} = $u->{_m}; $x->{_e} = $u->{_e}; $x->{_es} = $u->{_es}; } else { # calculate the broot() as integer result first, and if it fits, return # it rightaway (but only if $x and $y are integer): my $done = 0; # not yet if ($y->is_int() && $x->is_int()) { my $i = $LIB->_copy($x->{_m}); $i = $LIB->_lsft($i, $x->{_e}, 10) unless $LIB->_is_zero($x->{_e}); my $int = Math::BigInt->bzero(); $int->{value} = $i; $int = $int->broot($y->as_number()); # if ($exact) if ($int->copy()->bpow($y) == $x) { # found result, return it $x->{_m} = $int->{value}; $x->{_e} = $LIB->_zero(); $x->{_es} = '+'; $x = $x->bnorm(); $done = 1; } } if ($done == 0) { my $u = $class->bone()->bdiv($y, $scale+4); $u->{_a} = undef; $u->{_p} = undef; $x = $x->bpow($u, $scale+4); # el cheapo } } $x = $x->bneg() if $sign == 1; # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf()); $x; } sub bfac { # (BFLOAT or num_str, BFLOAT or num_str) return BFLOAT # compute factorial number, modifies first argument # set up parameters my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # inf => inf return $x if $x->modify('bfac'); return $x -> bnan(@r) if $x->is_nan() || $x->is_inf("-"); return $x -> binf("+", @r) if $x->is_inf("+"); return $x -> bone(@r) if $x->is_zero() || $x->is_one(); if ($x -> is_neg() || !$x -> is_int()) { return $upgrade -> bfac($x, @r) if defined($upgrade); return $x -> bnan(@r); } if (! $LIB->_is_zero($x->{_e})) { $x->{_m} = $LIB->_lsft($x->{_m}, $x->{_e}, 10); # change 12e1 to 120e0 $x->{_e} = $LIB->_zero(); # normalize $x->{_es} = '+'; } $x->{_m} = $LIB->_fac($x->{_m}); # calculate factorial $x = $x->bnorm()->round(@r); # norm again and round result return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf()); $x; } sub bdfac { # compute double factorial # set up parameters my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bdfac'); return $x -> bnan(@r) if $x->is_nan() || $x->is_inf("-"); return $x -> binf("+", @r) if $x->is_inf("+"); if ($x <= -2 || !$x -> is_int()) { return $upgrade -> bdfac($x, @r) if defined($upgrade); return $x -> bnan(@r); } return $x->bone() if $x <= 1; croak("bdfac() requires a newer version of the $LIB library.") unless $LIB->can('_dfac'); if (! $LIB->_is_zero($x->{_e})) { $x->{_m} = $LIB->_lsft($x->{_m}, $x->{_e}, 10); # change 12e1 to 120e0 $x->{_e} = $LIB->_zero(); # normalize $x->{_es} = '+'; } $x->{_m} = $LIB->_dfac($x->{_m}); # calculate factorial $x = $x->bnorm()->round(@r); # norm again and round result return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; } sub btfac { # compute triple factorial # set up parameters my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('btfac'); return $x -> bnan(@r) if $x->is_nan() || $x->is_inf("-"); return $x -> binf("+", @r) if $x->is_inf("+"); if ($x <= -3 || !$x -> is_int()) { return $upgrade -> btfac($x, @r) if defined($upgrade); return $x -> bnan(@r); } my $k = $class -> new("3"); return $x->bnan(@r) if $x <= -$k; my $one = $class -> bone(); return $x->bone(@r) if $x <= $one; my $f = $x -> copy(); while ($f -> bsub($k) > $one) { $x = $x -> bmul($f); } $x = $x->round(@r); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; } sub bmfac { my ($class, $x, $k, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x->modify('bmfac'); return $x -> bnan(@r) if $x->is_nan() || $x->is_inf("-") || !$k->is_pos(); return $x -> binf("+", @r) if $x->is_inf("+"); if ($x <= -$k || !$x -> is_int() || ($k -> is_finite() && !$k -> is_int())) { return $upgrade -> bmfac($x, $k, @r) if defined($upgrade); return $x -> bnan(@r); } my $one = $class -> bone(); return $x->bone(@r) if $x <= $one; my $f = $x -> copy(); while ($f -> bsub($k) > $one) { $x = $x -> bmul($f); } $x = $x->round(@r); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && $x -> is_int(); return $x; } sub blsft { # shift left by $y (multiply by $b ** $y) # set up parameters my ($class, $x, $y, $b, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) && ref($_[1]) eq ref($_[2]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x -> modify('blsft'); return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); $b = 2 if !defined $b; $b = $class -> new($b) unless ref($b) && $b -> isa($class); return $x -> bnan(@r) if $b -> is_nan(); # There needs to be more checking for special cases here. Fixme! # shift by a negative amount? return $x -> brsft($y -> copy() -> babs(), $b) if $y -> {sign} =~ /^-/; $x = $x -> bmul($b -> bpow($y), $r[0], $r[1], $r[2], $y); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf() || $x -> is_nan()); return $x; } sub brsft { # shift right by $y (divide $b ** $y) # set up parameters my ($class, $x, $y, $b, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) && ref($_[1]) eq ref($_[2]) ? (ref($_[0]), @_) : objectify(2, @_); return $x if $x -> modify('brsft'); return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); # There needs to be more checking for special cases here. Fixme! $b = 2 if !defined $b; $b = $class -> new($b) unless ref($b) && $b -> isa($class); return $x -> bnan(@r) if $b -> is_nan(); # shift by a negative amount? return $x -> blsft($y -> copy() -> babs(), $b) if $y -> {sign} =~ /^-/; # call bdiv() $x = $x -> bdiv($b -> bpow($y), $r[0], $r[1], $r[2], $y); return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade) && ($x -> is_int() || $x -> is_inf() || $x -> is_nan()); return $x; } ############################################################################### # Bitwise methods ############################################################################### sub band { my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return if $x -> modify('band'); return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); my $xint = $x -> as_int(); # to Math::BigInt my $yint = $y -> as_int(); # to Math::BigInt $xint = $xint -> band($yint); return $xint -> round(@r) if defined $downgrade; my $xflt = $class -> new($xint); # back to Math::BigFloat $x -> {sign} = $xflt -> {sign}; $x -> {_m} = $xflt -> {_m}; $x -> {_es} = $xflt -> {_es}; $x -> {_e} = $xflt -> {_e}; return $x -> round(@r); } sub bior { my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return if $x -> modify('bior'); return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); my $xint = $x -> as_int(); # to Math::BigInt my $yint = $y -> as_int(); # to Math::BigInt $xint = $xint -> bior($yint); return $xint -> round(@r) if defined $downgrade; my $xflt = $class -> new($xint); # back to Math::BigFloat $x -> {sign} = $xflt -> {sign}; $x -> {_m} = $xflt -> {_m}; $x -> {_es} = $xflt -> {_es}; $x -> {_e} = $xflt -> {_e}; return $x -> round(@r); } sub bxor { my ($class, $x, $y, @r) = ref($_[0]) && ref($_[0]) eq ref($_[1]) ? (ref($_[0]), @_) : objectify(2, @_); return if $x -> modify('bxor'); return $x -> bnan(@r) if $x -> is_nan() || $y -> is_nan(); my $xint = $x -> as_int(); # to Math::BigInt my $yint = $y -> as_int(); # to Math::BigInt $xint = $xint -> bxor($yint); return $xint -> round(@r) if defined $downgrade; my $xflt = $class -> new($xint); # back to Math::BigFloat $x -> {sign} = $xflt -> {sign}; $x -> {_m} = $xflt -> {_m}; $x -> {_es} = $xflt -> {_es}; $x -> {_e} = $xflt -> {_e}; return $x -> round(@r); } sub bnot { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return if $x -> modify('bnot'); return $x -> bnan(@r) if $x -> is_nan(); my $xint = $x -> as_int(); # to Math::BigInt $xint = $xint -> bnot(); return $xint -> round(@r) if defined $downgrade; my $xflt = $class -> new($xint); # back to Math::BigFloat $x -> {sign} = $xflt -> {sign}; $x -> {_m} = $xflt -> {_m}; $x -> {_es} = $xflt -> {_es}; $x -> {_e} = $xflt -> {_e}; return $x -> round(@r); } ############################################################################### # Rounding methods ############################################################################### sub bround { # accuracy: preserve $N digits, and overwrite the rest with 0's my ($class, $x, @a) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); if (($a[0] || 0) < 0) { croak('bround() needs positive accuracy'); } return $x if $x->modify('bround'); my ($scale, $mode) = $x->_scale_a(@a); if (!defined $scale) { # no-op return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # Scale is now either $x->{_a}, $accuracy, or the input argument. Test # whether $x already has lower accuracy, do nothing in this case but do # round if the accuracy is the same, since a math operation might want to # round a number with A=5 to 5 digits afterwards again if (defined $x->{_a} && $x->{_a} < $scale) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # scale < 0 makes no sense # scale == 0 => keep all digits # never round a +-inf, NaN if ($scale <= 0 || $x->{sign} !~ /^[+-]$/) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # 1: never round a 0 # 2: if we should keep more digits than the mantissa has, do nothing if ($x->is_zero() || $LIB->_len($x->{_m}) <= $scale) { $x->{_a} = $scale if !defined $x->{_a} || $x->{_a} > $scale; return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # pass sign to bround for '+inf' and '-inf' rounding modes my $m = bless { sign => $x->{sign}, value => $x->{_m} }, 'Math::BigInt'; $m = $m->bround($scale, $mode); # round mantissa $x->{_m} = $m->{value}; # get our mantissa back $x->{_a} = $scale; # remember rounding $x->{_p} = undef; # and clear P # bnorm() downgrades if necessary, so no need to check whether to downgrade. $x->bnorm(); # del trailing zeros gen. by bround() } sub bfround { # precision: round to the $Nth digit left (+$n) or right (-$n) from the '.' # $n == 0 means round to integer # expects and returns normalized numbers! my ($class, $x, @p) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bfround'); # no-op my ($scale, $mode) = $x->_scale_p(@p); if (!defined $scale) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # never round a 0, +-inf, NaN if ($x->is_zero()) { $x->{_p} = $scale if !defined $x->{_p} || $x->{_p} < $scale; # -3 < -2 return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } if ($x->{sign} !~ /^[+-]$/) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # don't round if x already has lower precision if (defined $x->{_p} && $x->{_p} < 0 && $scale < $x->{_p}) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } $x->{_p} = $scale; # remember round in any case $x->{_a} = undef; # and clear A if ($scale < 0) { # round right from the '.' if ($x->{_es} eq '+') { # e >= 0 => nothing to round return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } $scale = -$scale; # positive for simplicity my $len = $LIB->_len($x->{_m}); # length of mantissa # the following poses a restriction on _e, but if _e is bigger than a # scalar, you got other problems (memory etc) anyway my $dad = -(0+ ($x->{_es}.$LIB->_num($x->{_e}))); # digits after dot my $zad = 0; # zeros after dot $zad = $dad - $len if (-$dad < -$len); # for 0.00..00xxx style # print "scale $scale dad $dad zad $zad len $len\n"; # number bsstr len zad dad # 0.123 123e-3 3 0 3 # 0.0123 123e-4 3 1 4 # 0.001 1e-3 1 2 3 # 1.23 123e-2 3 0 2 # 1.2345 12345e-4 5 0 4 # do not round after/right of the $dad if ($scale > $dad) { # 0.123, scale >= 3 => exit return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # round to zero if rounding inside the $zad, but not for last zero like: # 0.0065, scale -2, round last '0' with following '65' (scale == zad # case) if ($scale < $zad) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x->bzero(); } if ($scale == $zad) { # for 0.006, scale -3 and trunc $scale = -$len; } else { # adjust round-point to be inside mantissa if ($zad != 0) { $scale = $scale-$zad; } else { my $dbd = $len - $dad; $dbd = 0 if $dbd < 0; # digits before dot $scale = $dbd+$scale; } } } else { # round left from the '.' # 123 => 100 means length(123) = 3 - $scale (2) => 1 my $dbt = $LIB->_len($x->{_m}); # digits before dot my $dbd = $dbt + ($x->{_es} . $LIB->_num($x->{_e})); # should be the same, so treat it as this $scale = 1 if $scale == 0; # shortcut if already integer if ($scale == 1 && $dbt <= $dbd) { return $downgrade -> new($x) if defined($downgrade) && ($x->is_int() || $x->is_inf() || $x->is_nan()); return $x; } # maximum digits before dot ++$dbd; if ($scale > $dbd) { # not enough digits before dot, so round to zero return $downgrade -> new($x) if defined($downgrade); return $x->bzero; } elsif ($scale == $dbd) { # maximum $scale = -$dbt; } else { $scale = $dbd - $scale; } } # pass sign to bround for rounding modes '+inf' and '-inf' my $m = bless { sign => $x->{sign}, value => $x->{_m} }, 'Math::BigInt'; $m = $m->bround($scale, $mode); $x->{_m} = $m->{value}; # get our mantissa back # bnorm() downgrades if necessary, so no need to check whether to downgrade. $x->bnorm(); } sub bfloor { # round towards minus infinity my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bfloor'); return $x -> bnan(@r) if $x -> is_nan(); if ($x->{sign} =~ /^[+-]$/) { # if $x has digits after dot, remove them if ($x->{_es} eq '-') { $x->{_m} = $LIB->_rsft($x->{_m}, $x->{_e}, 10); $x->{_e} = $LIB->_zero(); $x->{_es} = '+'; # increment if negative $x->{_m} = $LIB->_inc($x->{_m}) if $x->{sign} eq '-'; } $x = $x->round(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade); return $x; } sub bceil { # round towards plus infinity my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bceil'); return $x -> bnan(@r) if $x -> is_nan(); # if $x has digits after dot, remove them if ($x->{sign} =~ /^[+-]$/) { if ($x->{_es} eq '-') { $x->{_m} = $LIB->_rsft($x->{_m}, $x->{_e}, 10); $x->{_e} = $LIB->_zero(); $x->{_es} = '+'; if ($x->{sign} eq '+') { $x->{_m} = $LIB->_inc($x->{_m}); # increment if positive } else { $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # avoid -0 } } $x = $x->round(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade); return $x; } sub bint { # round towards zero my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); return $x if $x->modify('bint'); return $x -> bnan(@r) if $x -> is_nan(); if ($x->{sign} =~ /^[+-]$/) { # if $x has digits after the decimal point if ($x->{_es} eq '-') { $x->{_m} = $LIB->_rsft($x->{_m}, $x->{_e}, 10); # remove frac part $x->{_e} = $LIB->_zero(); # truncate/normalize $x->{_es} = '+'; # abs e $x->{sign} = '+' if $LIB->_is_zero($x->{_m}); # avoid -0 } $x = $x->round(@r); } return $downgrade -> new($x -> bdstr(), @r) if defined($downgrade); return $x; } ############################################################################### # Other mathematical methods ############################################################################### sub bgcd { # (BINT or num_str, BINT or num_str) return BINT # does not modify arguments, but returns new object # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my ($class, @args) = objectify(0, @_); my $x = shift @args; $x = ref($x) && $x -> isa($class) ? $x -> copy() : $class -> new($x); return $class->bnan() unless $x -> is_int(); while (@args) { my $y = shift @args; $y = $class->new($y) unless ref($y) && $y -> isa($class); return $class->bnan() unless $y -> is_int(); # greatest common divisor while (! $y->is_zero()) { ($x, $y) = ($y->copy(), $x->copy()->bmod($y)); } last if $x -> is_one(); } $x = $x -> babs(); return $downgrade -> new($x) if defined $downgrade && $x->is_int(); return $x; } sub blcm { # (BFLOAT or num_str, BFLOAT or num_str) return BFLOAT # does not modify arguments, but returns new object # Least Common Multiple # Class::method(...) -> Class->method(...) unless (@_ && (defined(blessed($_[0])) && $_[0] -> isa(__PACKAGE__) || $_[0] =~ /^[a-z]\w*(?:::[a-z]\w*)*$/i)) { #carp "Using ", (caller(0))[3], "() as a function is deprecated;", # " use is as a method instead"; unshift @_, __PACKAGE__; } my ($class, @args) = objectify(0, @_); my $x = shift @args; $x = ref($x) && $x -> isa($class) ? $x -> copy() : $class -> new($x); return $class->bnan() if $x->{sign} !~ /^[+-]$/; # x NaN? while (@args) { my $y = shift @args; $y = $class -> new($y) unless ref($y) && $y -> isa($class); return $x->bnan() unless $y -> is_int(); my $gcd = $x -> bgcd($y); $x = $x -> bdiv($gcd) -> bmul($y); } $x = $x -> babs(); return $downgrade -> new($x) if defined $downgrade && $x->is_int(); return $x; } ############################################################################### # Object property methods ############################################################################### sub length { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return 1 if $LIB->_is_zero($x->{_m}); my $len = $LIB->_len($x->{_m}); $len += $LIB->_num($x->{_e}) if $x->{_es} eq '+'; if (wantarray()) { my $t = 0; $t = $LIB->_num($x->{_e}) if $x->{_es} eq '-'; return ($len, $t); } $len; } sub mantissa { # return a copy of the mantissa my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # The following line causes a lot of noise in the test suits for # the Math-BigRat and bignum distributions. Fixme! #carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x -> bnan(@r) if $x -> is_nan(); if ($x->{sign} !~ /^[+-]$/) { my $s = $x->{sign}; $s =~ s/^\+//; return Math::BigInt->new($s, undef, undef); # -inf, +inf => +inf } my $m = Math::BigInt->new($LIB->_str($x->{_m}), undef, undef); $m = $m->bneg() if $x->{sign} eq '-'; $m; } sub exponent { # return a copy of the exponent my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); # The following line causes a lot of noise in the test suits for # the Math-BigRat and bignum distributions. Fixme! #carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x -> bnan(@r) if $x -> is_nan(); if ($x->{sign} !~ /^[+-]$/) { my $s = $x->{sign}; $s =~ s/^[+-]//; return Math::BigInt->new($s, undef, undef); # -inf, +inf => +inf } Math::BigInt->new($x->{_es} . $LIB->_str($x->{_e}), undef, undef); } sub parts { # return a copy of both the exponent and the mantissa my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; if ($x->{sign} !~ /^[+-]$/) { my $s = $x->{sign}; $s =~ s/^\+//; my $se = $s; $se =~ s/^-//; # +inf => inf and -inf, +inf => inf return ($class->new($s), $class->new($se)); } my $m = Math::BigInt->bzero(); $m->{value} = $LIB->_copy($x->{_m}); $m = $m->bneg() if $x->{sign} eq '-'; ($m, Math::BigInt->new($x->{_es} . $LIB->_num($x->{_e}))); } # Parts used for scientific notation with significand/mantissa and exponent as # integers. E.g., "12345.6789" is returned as "123456789" (mantissa) and "-4" # (exponent). sub sparts { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Not-a-number. if ($x -> is_nan()) { my $mant = $class -> bnan(); # mantissa return $mant unless wantarray; # scalar context my $expo = $class -> bnan(); # exponent return ($mant, $expo); # list context } # Infinity. if ($x -> is_inf()) { my $mant = $class -> binf($x->{sign}); # mantissa return $mant unless wantarray; # scalar context my $expo = $class -> binf('+'); # exponent return ($mant, $expo); # list context } # Finite number. my $mant = $class -> new($x); $mant->{_es} = '+'; $mant->{_e} = $LIB->_zero(); $mant = $downgrade -> new($mant) if defined $downgrade; return $mant unless wantarray; my $expo = $class -> new($x -> {_es} . $LIB->_str($x -> {_e})); $expo = $downgrade -> new($expo) if defined $downgrade; return ($mant, $expo); } # Parts used for normalized notation with significand/mantissa as either 0 or a # number in the semi-open interval [1,10). E.g., "12345.6789" is returned as # "1.23456789" and "4". sub nparts { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Not-a-number and Infinity. return $x -> sparts() if $x -> is_nan() || $x -> is_inf(); # Finite number. my ($mant, $expo) = $x -> sparts(); if ($mant -> bcmp(0)) { my ($ndigtot, $ndigfrac) = $mant -> length(); my $expo10adj = $ndigtot - $ndigfrac - 1; if ($expo10adj > 0) { # if mantissa is not an integer $mant = $mant -> brsft($expo10adj, 10); return $mant unless wantarray; $expo = $expo -> badd($expo10adj); return ($mant, $expo); } } return $mant unless wantarray; return ($mant, $expo); } # Parts used for engineering notation with significand/mantissa as either 0 or a # number in the semi-open interval [1,1000) and the exponent is a multiple of 3. # E.g., "12345.6789" is returned as "12.3456789" and "3". sub eparts { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Not-a-number and Infinity. return $x -> sparts() if $x -> is_nan() || $x -> is_inf(); # Finite number. my ($mant, $expo) = $x -> nparts(); my $c = $expo -> copy() -> bmod(3); $mant = $mant -> blsft($c, 10); return $mant unless wantarray; $expo = $expo -> bsub($c); return ($mant, $expo); } # Parts used for decimal notation, e.g., "12345.6789" is returned as "12345" # (integer part) and "0.6789" (fraction part). sub dparts { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Not-a-number. if ($x -> is_nan()) { my $int = $class -> bnan(); return $int unless wantarray; my $frc = $class -> bzero(); # or NaN? return ($int, $frc); } # Infinity. if ($x -> is_inf()) { my $int = $class -> binf($x->{sign}); return $int unless wantarray; my $frc = $class -> bzero(); return ($int, $frc); } # Finite number. my $int = $x -> copy(); my $frc; # If the input is an integer. if ($int->{_es} eq '+') { $frc = $class -> bzero(); } # If the input has a fraction part else { $int->{_m} = $LIB -> _rsft($int->{_m}, $int->{_e}, 10); $int->{_e} = $LIB -> _zero(); $int->{_es} = '+'; $int->{sign} = '+' if $LIB->_is_zero($int->{_m}); # avoid -0 return $int unless wantarray; $frc = $x -> copy() -> bsub($int); return ($int, $frc); } $int = $downgrade -> new($int) if defined $downgrade; return $int unless wantarray; return $int, $frc; } # Fractional parts with the numerator and denominator as integers. E.g., # "123.4375" is returned as "1975" and "16". sub fparts { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # NaN => NaN/NaN if ($x -> is_nan()) { return $class -> bnan() unless wantarray; return $class -> bnan(), $class -> bnan(); } # ±Inf => ±Inf/1 if ($x -> is_inf()) { my $numer = $class -> binf($x->{sign}); return $numer unless wantarray; my $denom = $class -> bone(); return $numer, $denom; } # Finite number. # If we get here, we know that the output is an integer. $class = $downgrade if defined $downgrade; my @flt_parts = ($x->{sign}, $x->{_m}, $x->{_es}, $x->{_e}); my @rat_parts = $class -> _flt_lib_parts_to_rat_lib_parts(@flt_parts); my $num = $class -> new($LIB -> _str($rat_parts[1])); my $den = $class -> new($LIB -> _str($rat_parts[2])); $num = $num -> bneg() if $rat_parts[0] eq "-"; return $num unless wantarray; return $num, $den; } # Given "123.4375", returns "1975", since "123.4375" is "1975/16". sub numerator { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $class -> bnan() if $x -> is_nan(); return $class -> binf($x -> sign()) if $x -> is_inf(); return $class -> bzero() if $x -> is_zero(); # If we get here, we know that the output is an integer. $class = $downgrade if defined $downgrade; if ($x -> {_es} eq '-') { # exponent < 0 my $numer_lib = $LIB -> _copy($x -> {_m}); my $denom_lib = $LIB -> _1ex($x -> {_e}); my $gcd_lib = $LIB -> _gcd($LIB -> _copy($numer_lib), $denom_lib); $numer_lib = $LIB -> _div($numer_lib, $gcd_lib); return $class -> new($x -> {sign} . $LIB -> _str($numer_lib)); } elsif (! $LIB -> _is_zero($x -> {_e})) { # exponent > 0 my $numer_lib = $LIB -> _copy($x -> {_m}); $numer_lib = $LIB -> _lsft($numer_lib, $x -> {_e}, 10); return $class -> new($x -> {sign} . $LIB -> _str($numer_lib)); } else { # exponent = 0 return $class -> new($x -> {sign} . $LIB -> _str($x -> {_m})); } } # Given "123.4375", returns "16", since "123.4375" is "1975/16". sub denominator { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $class -> bnan() if $x -> is_nan(); # If we get here, we know that the output is an integer. $class = $downgrade if defined $downgrade; if ($x -> {_es} eq '-') { # exponent < 0 my $numer_lib = $LIB -> _copy($x -> {_m}); my $denom_lib = $LIB -> _1ex($x -> {_e}); my $gcd_lib = $LIB -> _gcd($LIB -> _copy($numer_lib), $denom_lib); $denom_lib = $LIB -> _div($denom_lib, $gcd_lib); return $class -> new($LIB -> _str($denom_lib)); } else { # exponent >= 0 return $class -> bone(); } } ############################################################################### # String conversion methods ############################################################################### sub bstr { # (ref to BFLOAT or num_str) return num_str # Convert number from internal format to (non-scientific) string format. # internal format is always normalized (no leading zeros, "-0" => "+0") my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Finite number my $es = '0'; my $len = 1; my $cad = 0; my $dot = '.'; # $x is zero? my $not_zero = !($x->{sign} eq '+' && $LIB->_is_zero($x->{_m})); if ($not_zero) { $es = $LIB->_str($x->{_m}); $len = CORE::length($es); my $e = $LIB->_num($x->{_e}); $e = -$e if $x->{_es} eq '-'; if ($e < 0) { $dot = ''; # if _e is bigger than a scalar, the following will blow your memory if ($e <= -$len) { my $r = abs($e) - $len; $es = '0.'. ('0' x $r) . $es; $cad = -($len+$r); } else { substr($es, $e, 0) = '.'; $cad = $LIB->_num($x->{_e}); $cad = -$cad if $x->{_es} eq '-'; } } elsif ($e > 0) { # expand with zeros $es .= '0' x $e; $len += $e; $cad = 0; } } # if not zero $es = '-'.$es if $x->{sign} eq '-'; # if set accuracy or precision, pad with zeros on the right side if ((defined $x->{_a}) && ($not_zero)) { # 123400 => 6, 0.1234 => 4, 0.001234 => 4 my $zeros = $x->{_a} - $cad; # cad == 0 => 12340 $zeros = $x->{_a} - $len if $cad != $len; $es .= $dot.'0' x $zeros if $zeros > 0; } elsif ((($x->{_p} || 0) < 0)) { # 123400 => 6, 0.1234 => 4, 0.001234 => 6 my $zeros = -$x->{_p} + $cad; $es .= $dot.'0' x $zeros if $zeros > 0; } $es; } # Decimal notation, e.g., "12345.6789" (no exponent). sub bdstr { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> bdstr($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number my $mant = $LIB->_str($x->{_m}); my $esgn = $x->{_es}; my $eabs = $LIB -> _num($x->{_e}); my $uintmax = ~0; my $str = $mant; if ($esgn eq '+') { croak("The absolute value of the exponent is too large") if $eabs > $uintmax; $str .= "0" x $eabs; } else { my $mlen = CORE::length($mant); my $c = $mlen - $eabs; my $intmax = ($uintmax - 1) / 2; croak("The absolute value of the exponent is too large") if (1 - $c) > $intmax; $str = "0" x (1 - $c) . $str if $c <= 0; substr($str, -$eabs, 0) = '.'; } return $x->{sign} eq '-' ? '-' . $str : $str; } # Scientific notation with significand/mantissa and exponent as integers, e.g., # "12345.6789" is written as "123456789e-4". sub bsstr { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> bsstr($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number ($x->{sign} eq '-' ? '-' : '') . $LIB->_str($x->{_m}) . 'e' . $x->{_es} . $LIB->_str($x->{_e}); } # Normalized notation, e.g., "12345.6789" is written as "1.23456789e+4". sub bnstr { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> bnstr($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number my $str = $x->{sign} eq '-' ? '-' : ''; # Get the mantissa and the length of the mantissa. my $mant = $LIB->_str($x->{_m}); my $mantlen = CORE::length($mant); if ($mantlen == 1) { # Not decimal point when the mantissa has length one, i.e., return the # number 2 as the string "2", not "2.". $str .= $mant . 'e' . $x->{_es} . $LIB->_str($x->{_e}); } else { # Compute new exponent where the original exponent is adjusted by the # length of the mantissa minus one (because the decimal point is after # one digit). my ($eabs, $esgn) = $LIB -> _sadd($LIB -> _copy($x->{_e}), $x->{_es}, $LIB -> _new($mantlen - 1), "+"); substr $mant, 1, 0, "."; $str .= $mant . 'e' . $esgn . $LIB->_str($eabs); } return $str; } # Engineering notation, e.g., "12345.6789" is written as "12.3456789e+3". sub bestr { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> bestr($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number my $str = $x->{sign} eq '-' ? '-' : ''; # Get the mantissa, the length of the mantissa, and adjust the exponent by # the length of the mantissa minus 1 (because the dot is after one digit). my $mant = $LIB->_str($x->{_m}); my $mantlen = CORE::length($mant); my ($eabs, $esgn) = $LIB -> _sadd($LIB -> _copy($x->{_e}), $x->{_es}, $LIB -> _new($mantlen - 1), "+"); my $dotpos = 1; my $mod = $LIB -> _mod($LIB -> _copy($eabs), $LIB -> _new("3")); unless ($LIB -> _is_zero($mod)) { if ($esgn eq '+') { $eabs = $LIB -> _sub($eabs, $mod); $dotpos += $LIB -> _num($mod); } else { my $delta = $LIB -> _sub($LIB -> _new("3"), $mod); $eabs = $LIB -> _add($eabs, $delta); $dotpos += $LIB -> _num($delta); } } if ($dotpos < $mantlen) { substr $mant, $dotpos, 0, "."; } elsif ($dotpos > $mantlen) { $mant .= "0" x ($dotpos - $mantlen); } $str .= $mant . 'e' . $esgn . $LIB->_str($eabs); return $str; } # Fractional notation, e.g., "123.4375" is written as "1975/16". sub bfstr { my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), $_[0]) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> bfstr($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number my $str = $x->{sign} eq '-' ? '-' : ''; if ($x->{_es} eq '+') { $str .= $LIB -> _str($x->{_m}) . ("0" x $LIB -> _num($x->{_e})); } else { my @flt_parts = ($x->{sign}, $x->{_m}, $x->{_es}, $x->{_e}); my @rat_parts = $class -> _flt_lib_parts_to_rat_lib_parts(@flt_parts); $str = $LIB -> _str($rat_parts[1]) . "/" . $LIB -> _str($rat_parts[2]); $str = "-" . $str if $rat_parts[0] eq "-"; } return $str; } sub to_hex { # return number as hexadecimal string (only for integers defined) my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), $_[0]) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> to_hex($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number return '0' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in hex? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_to_hex($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub to_oct { # return number as octal digit string (only for integers defined) my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), $_[0]) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> to_hex($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number return '0' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in octal? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_to_oct($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub to_bin { # return number as binary digit string (only for integers defined) my ($class, $x, @r) = ref($_[0]) ? (ref($_[0]), $_[0]) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; # Inf and NaN if ($x->{sign} ne '+' && $x->{sign} ne '-') { return $x->{sign} unless $x->{sign} eq '+inf'; # -inf, NaN return 'inf'; # +inf } # Upgrade? return $upgrade -> to_hex($x, @r) if defined($upgrade) && !$x -> isa($class); # Finite number return '0' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in binary? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_to_bin($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub to_ieee754 { my ($class, $x, $format, @r) = ref($_[0]) ? (ref($_[0]), @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; my $enc; # significand encoding (applies only to decimal) my $k; # storage width in bits my $b; # base if ($format =~ /^binary(\d+)\z/) { $k = $1; $b = 2; } elsif ($format =~ /^decimal(\d+)(dpd|bcd)?\z/) { $k = $1; $b = 10; $enc = $2 || 'dpd'; # default is dencely-packed decimals (DPD) } elsif ($format eq 'half') { $k = 16; $b = 2; } elsif ($format eq 'single') { $k = 32; $b = 2; } elsif ($format eq 'double') { $k = 64; $b = 2; } elsif ($format eq 'quadruple') { $k = 128; $b = 2; } elsif ($format eq 'octuple') { $k = 256; $b = 2; } elsif ($format eq 'sexdecuple') { $k = 512; $b = 2; } if ($b == 2) { # Get the parameters for this format. my $p; # precision (in bits) my $t; # number of bits in significand my $w; # number of bits in exponent if ($k == 16) { # binary16 (half-precision) $p = 11; $t = 10; $w = 5; } elsif ($k == 32) { # binary32 (single-precision) $p = 24; $t = 23; $w = 8; } elsif ($k == 64) { # binary64 (double-precision) $p = 53; $t = 52; $w = 11; } else { # binaryN (quadruple-precition and above) if ($k < 128 || $k != 32 * sprintf('%.0f', $k / 32)) { croak "Number of bits must be 16, 32, 64, or >= 128 and", " a multiple of 32"; } $p = $k - sprintf('%.0f', 4 * log($k) / log(2)) + 13; $t = $p - 1; $w = $k - $t - 1; } # The maximum exponent, minimum exponent, and exponent bias. my $emax = $class -> new(2) -> bpow($w - 1) -> bdec(); my $emin = 1 - $emax; my $bias = $emax; # Get numerical sign, exponent, and mantissa/significand for bit # string. my $sign = 0; my $expo; my $mant; if ($x -> is_nan()) { # nan $sign = 1; $expo = $emax -> copy() -> binc(); $mant = $class -> new(2) -> bpow($t - 1); } elsif ($x -> is_inf()) { # inf $sign = 1 if $x -> is_neg(); $expo = $emax -> copy() -> binc(); $mant = $class -> bzero(); } elsif ($x -> is_zero()) { # zero $expo = $emin -> copy() -> bdec(); $mant = $class -> bzero(); } else { # normal and subnormal $sign = 1 if $x -> is_neg(); # Now we need to compute the mantissa and exponent in base $b. my $binv = $class -> new("0.5"); my $b = $class -> new(2); my $one = $class -> bone(); # We start off by initializing the exponent to zero and the # mantissa to the input value. Then we increase the mantissa and # decrease the exponent, or vice versa, until the mantissa is in # the desired range or we hit one of the limits for the exponent. $mant = $x -> copy() -> babs(); # We need to find the base 2 exponent. First make an estimate of # the base 2 exponent, before adjusting it below. We could skip # this estimation and go straight to the while-loops below, but the # loops are slow, especially when the final exponent is far from # zero and even more so if the number of digits is large. This # initial estimation speeds up the computation dramatically. # # log2($m * 10**$e) = log10($m + 10**$e) * log(10)/log(2) # = (log10($m) + $e) * log(10)/log(2) # = (log($m)/log(10) + $e) * log(10)/log(2) my ($m, $e) = $x -> nparts(); my $ms = $m -> numify(); my $es = $e -> numify(); my $expo_est = (log(abs($ms))/log(10) + $es) * log(10)/log(2); $expo_est = int($expo_est); # Limit the exponent. if ($expo_est > $emax) { $expo_est = $emax; } elsif ($expo_est < $emin) { $expo_est = $emin; } # Don't multiply by a number raised to a negative exponent. This # will cause a division, whose result is truncated to some fixed # number of digits. Instead, multiply by the inverse number raised # to a positive exponent. $expo = $class -> new($expo_est); if ($expo_est > 0) { $mant = $mant -> bmul($binv -> copy() -> bpow($expo)); } elsif ($expo_est < 0) { my $expo_abs = $expo -> copy() -> bneg(); $mant = $mant -> bmul($b -> copy() -> bpow($expo_abs)); } # Final adjustment of the estimate above. while ($mant >= $b && $expo <= $emax) { $mant = $mant -> bmul($binv); $expo = $expo -> binc(); } while ($mant < $one && $expo >= $emin) { $mant = $mant -> bmul($b); $expo = $expo -> bdec(); } # This is when the magnitude is larger than what can be represented # in this format. Encode as infinity. if ($expo > $emax) { $mant = $class -> bzero(); $expo = $emax -> copy() -> binc(); } # This is when the magnitude is so small that the number is encoded # as a subnormal number. # # If the magnitude is smaller than that of the smallest subnormal # number, and rounded downwards, it is encoded as zero. This works # transparently and does not need to be treated as a special case. # # If the number is between the largest subnormal number and the # smallest normal number, and the value is rounded upwards, the # value must be encoded as a normal number. This must be treated as # a special case. elsif ($expo < $emin) { # Scale up the mantissa (significand), and round to integer. my $const = $class -> new($b) -> bpow($t - 1); $mant = $mant -> bmul($const); $mant = $mant -> bfround(0); # If the mantissa overflowed, encode as the smallest normal # number. if ($mant == $const -> bmul($b)) { $mant = $mant -> bzero(); $expo = $expo -> binc(); } } # This is when the magnitude is within the range of what can be # encoded as a normal number. else { # Remove implicit leading bit, scale up the mantissa # (significand) to an integer, and round. $mant = $mant -> bdec(); my $const = $class -> new($b) -> bpow($t); $mant = $mant -> bmul($const) -> bfround(0); # If the mantissa overflowed, encode as the next larger value. # This works correctly also when the next larger value is # infinity. if ($mant == $const) { $mant = $mant -> bzero(); $expo = $expo -> binc(); } } } $expo = $expo -> badd($bias); # add bias my $signbit = "$sign"; my $mantbits = $mant -> to_bin(); $mantbits = ("0" x ($t - CORE::length($mantbits))) . $mantbits; my $expobits = $expo -> to_bin(); $expobits = ("0" x ($w - CORE::length($expobits))) . $expobits; my $bin = $signbit . $expobits . $mantbits; return pack "B*", $bin; } croak("The format '$format' is not yet supported."); } sub as_hex { # return number as hexadecimal string (only for integers defined) my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x->bstr() if $x->{sign} !~ /^[+-]$/; # inf, nan etc return '0x0' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in hex? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_as_hex($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub as_oct { # return number as octal digit string (only for integers defined) my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x->bstr() if $x->{sign} !~ /^[+-]$/; # inf, nan etc return '00' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in octal? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_as_oct($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub as_bin { # return number as binary digit string (only for integers defined) my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; return $x->bstr() if $x->{sign} !~ /^[+-]$/; # inf, nan etc return '0b0' if $x->is_zero(); return $nan if $x->{_es} ne '+'; # how to do 1e-1 in binary? my $z = $LIB->_copy($x->{_m}); if (! $LIB->_is_zero($x->{_e})) { # > 0 $z = $LIB->_lsft($z, $x->{_e}, 10); } my $str = $LIB->_as_bin($z); return $x->{sign} eq '-' ? "-$str" : $str; } sub numify { # Make a Perl scalar number from a Math::BigFloat object. my (undef, $x, @r) = ref($_[0]) ? (undef, @_) : objectify(1, @_); carp "Rounding is not supported for ", (caller(0))[3], "()" if @r; if ($x -> is_nan()) { require Math::Complex; my $inf = $Math::Complex::Inf; return $inf - $inf; } if ($x -> is_inf()) { require Math::Complex; my $inf = $Math::Complex::Inf; return $x -> is_negative() ? -$inf : $inf; } # Create a string and let Perl's atoi()/atof() handle the rest. return 0 + $x -> bnstr(); } ############################################################################### # Private methods and functions. ############################################################################### sub import { my $class = shift; $IMPORT++; # remember we did import() my @import = ('objectify'); my @a; # unrecognized arguments while (@_) { my $param = shift; # Enable overloading of constants. if ($param eq ':constant') { overload::constant integer => sub { $class -> new(shift); }, float => sub { $class -> new(shift); }, binary => sub { # E.g., a literal 0377 shall result in an object whose value # is decimal 255, but new("0377") returns decimal 377. return $class -> from_oct($_[0]) if $_[0] =~ /^0_*[0-7]/; $class -> new(shift); }; next; } # Upgrading. if ($param eq 'upgrade') { $class -> upgrade(shift); next; } # Downgrading. if ($param eq 'downgrade') { $class -> downgrade(shift); next; } # Accuracy. if ($param eq 'accuracy') { $class -> accuracy(shift); next; } # Precision. if ($param eq 'precision') { $class -> precision(shift); next; } # Rounding mode. if ($param eq 'round_mode') { $class -> round_mode(shift); next; } # Backend library. if ($param =~ /^(lib|try|only)\z/) { push @import, $param; push @import, shift() if @_; next; } if ($param eq 'with') { # alternative class for our private parts() # XXX: no longer supported # $LIB = shift() || 'Calc'; # carp "'with' is no longer supported, use 'lib', 'try', or 'only'"; shift; next; } # Unrecognized parameter. push @a, $param; } Math::BigInt -> import(@import); # find out which one was actually loaded $LIB = Math::BigInt -> config('lib'); $class->export_to_level(1, $class, @a); # export wanted functions } sub _len_to_steps { # Given D (digits in decimal), compute N so that N! (N factorial) is # at least D digits long. D should be at least 50. my $d = shift; # two constants for the Ramanujan estimate of ln(N!) my $lg2 = log(2 * 3.14159265) / 2; my $lg10 = log(10); # D = 50 => N => 42, so L = 40 and R = 50 my $l = 40; my $r = $d; # Otherwise this does not work under -Mbignum and we do not yet have "no # bignum;" :( $l = $l->numify if ref($l); $r = $r->numify if ref($r); $lg2 = $lg2->numify if ref($lg2); $lg10 = $lg10->numify if ref($lg10); # binary search for the right value (could this be written as the reverse of # lg(n!)?) while ($r - $l > 1) { my $n = int(($r - $l) / 2) + $l; my $ramanujan = int(($n * log($n) - $n + log($n * (1 + 4*$n*(1+2*$n))) / 6 + $lg2) / $lg10); $ramanujan > $d ? $r = $n : $l = $n; } $l; } sub _log { # internal log function to calculate ln() based on Taylor series. # Modifies $x in place. my ($x, $scale) = @_; my $class = ref $x; # in case of $x == 1, result is 0 return $x -> bzero() if $x -> is_one(); # XXX TODO: rewrite this in a similar manner to bexp() # http://www.efunda.com/math/taylor_series/logarithmic.cfm?search_string=log # u = x-1, v = x+1 # _ _ # Taylor: | u 1 u^3 1 u^5 | # ln (x) = 2 | --- + - * --- + - * --- + ... | x > 0 # |_ v 3 v^3 5 v^5 _| # This takes much more steps to calculate the result and is thus not used # u = x-1 # _ _ # Taylor: | u 1 u^2 1 u^3 | # ln (x) = 2 | --- + - * --- + - * --- + ... | x > 1/2 # |_ x 2 x^2 3 x^3 _| # scale used in intermediate computations my $scaleup = $scale + 4; my ($v, $u, $numer, $denom, $factor, $f); $v = $x -> copy(); $v = $v -> binc(); # v = x+1 $x = $x -> bdec(); $u = $x -> copy(); # u = x-1; x = x-1 $x = $x -> bdiv($v, $scaleup); # first term: u/v $numer = $u -> copy(); # numerator $denom = $v -> copy(); # denominator $u = $u -> bmul($u); # u^2 $v = $v -> bmul($v); # v^2 $numer = $numer -> bmul($u); # u^3 $denom = $denom -> bmul($v); # v^3 $factor = $class -> new(3); $f = $class -> new(2); while (1) { my $next = $numer -> copy() -> bround($scaleup) -> bdiv($denom -> copy() -> bmul($factor) -> bround($scaleup), $scaleup); $next->{_a} = undef; $next->{_p} = undef; my $x_prev = $x -> copy(); $x = $x -> badd($next); last if $x -> bacmp($x_prev) == 0; # calculate things for the next term $numer = $numer -> bmul($u); $denom = $denom -> bmul($v); $factor = $factor -> badd($f); } $x = $x -> bmul($f); # $x *= 2 $x = $x -> bround($scale); } sub _log_10 { # Internal log function based on reducing input to the range of 0.1 .. 9.99 # and then "correcting" the result to the proper one. Modifies $x in place. my ($x, $scale) = @_; my $class = ref $x; # Taking blog() from numbers greater than 10 takes a *very long* time, so we # break the computation down into parts based on the observation that: # blog(X*Y) = blog(X) + blog(Y) # We set Y here to multiples of 10 so that $x becomes below 1 - the smaller # $x is the faster it gets. Since 2*$x takes about 10 times as # long, we make it faster by about a factor of 100 by dividing $x by 10. # The same observation is valid for numbers smaller than 0.1, e.g. computing # log(1) is fastest, and the further away we get from 1, the longer it # takes. So we also 'break' this down by multiplying $x with 10 and subtract # the log(10) afterwards to get the correct result. # To get $x even closer to 1, we also divide by 2 and then use log(2) to # correct for this. For instance if $x is 2.4, we use the formula: # blog(2.4 * 2) == blog(1.2) + blog(2) # and thus calculate only blog(1.2) and blog(2), which is faster in total # than calculating blog(2.4). # In addition, the values for blog(2) and blog(10) are cached. # Calculate the number of digits before the dot, i.e., 1 + floor(log10(x)): # x = 123 => dbd = 3 # x = 1.23 => dbd = 1 # x = 0.0123 => dbd = -1 # x = 0.000123 => dbd = -3 # etc. my $dbd = $LIB->_num($x->{_e}); $dbd = -$dbd if $x->{_es} eq '-'; $dbd += $LIB->_len($x->{_m}); # more than one digit (e.g. at least 10), but *not* exactly 10 to avoid # infinite recursion my $calc = 1; # do some calculation? # No upgrading or downgrading in the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; # disable the shortcut for 10, since we need log(10) and this would recurse # infinitely deep if ($x->{_es} eq '+' && # $x == 10 ($LIB->_is_one($x->{_e}) && $LIB->_is_one($x->{_m}))) { $dbd = 0; # disable shortcut # we can use the cached value in these cases if ($scale <= $LOG_10_A) { $x = $x->bzero(); $x = $x->badd($LOG_10); # modify $x in place $calc = 0; # no need to calc, but round } # if we can't use the shortcut, we continue normally } else { # disable the shortcut for 2, since we maybe have it cached if (($LIB->_is_zero($x->{_e}) && # $x == 2 $LIB->_is_two($x->{_m}))) { $dbd = 0; # disable shortcut # we can use the cached value in these cases if ($scale <= $LOG_2_A) { $x = $x->bzero(); $x = $x->badd($LOG_2); # modify $x in place $calc = 0; # no need to calc, but round } # if we can't use the shortcut, we continue normally } } # if $x = 0.1, we know the result must be 0-log(10) if ($calc != 0 && ($x->{_es} eq '-' && # $x == 0.1 ($LIB->_is_one($x->{_e}) && $LIB->_is_one($x->{_m})))) { $dbd = 0; # disable shortcut # we can use the cached value in these cases if ($scale <= $LOG_10_A) { $x = $x->bzero(); $x = $x->bsub($LOG_10); $calc = 0; # no need to calc, but round } } return $x if $calc == 0; # already have the result # default: these correction factors are undef and thus not used my $l_10; # value of ln(10) to A of $scale my $l_2; # value of ln(2) to A of $scale my $two = $class->new(2); # $x == 2 => 1, $x == 13 => 2, $x == 0.1 => 0, $x == 0.01 => -1 # so don't do this shortcut for 1 or 0 if (($dbd > 1) || ($dbd < 0)) { # convert our cached value to an object if not already (avoid doing this # at import() time, since not everybody needs this) $LOG_10 = $class->new($LOG_10, undef, undef) unless ref $LOG_10; # got more than one digit before the dot, or more than one zero after # the dot, so do: # log(123) == log(1.23) + log(10) * 2 # log(0.0123) == log(1.23) - log(10) * 2 if ($scale <= $LOG_10_A) { # use cached value $l_10 = $LOG_10->copy(); # copy for mul } else { # else: slower, compute and cache result # shorten the time to calculate log(10) based on the following: # log(1.25 * 8) = log(1.25) + log(8) # = log(1.25) + log(2) + log(2) + log(2) # first get $l_2 (and possible compute and cache log(2)) $LOG_2 = $class->new($LOG_2, undef, undef) unless ref $LOG_2; if ($scale <= $LOG_2_A) { # use cached value $l_2 = $LOG_2->copy(); # copy() for the mul below } else { # else: slower, compute and cache result $l_2 = $two->copy(); $l_2 = $l_2->_log($scale); # scale+4, actually $LOG_2 = $l_2->copy(); # cache the result for later # the copy() is for mul below $LOG_2_A = $scale; } # now calculate log(1.25): $l_10 = $class->new('1.25'); $l_10 = $l_10->_log($scale); # scale+4, actually # log(1.25) + log(2) + log(2) + log(2): $l_10 = $l_10->badd($l_2); $l_10 = $l_10->badd($l_2); $l_10 = $l_10->badd($l_2); $LOG_10 = $l_10->copy(); # cache the result for later # the copy() is for mul below $LOG_10_A = $scale; } $dbd-- if ($dbd > 1); # 20 => dbd=2, so make it dbd=1 $l_10 = $l_10->bmul($class->new($dbd)); # log(10) * (digits_before_dot-1) my $dbd_sign = '+'; if ($dbd < 0) { $dbd = -$dbd; $dbd_sign = '-'; } ($x->{_e}, $x->{_es}) = $LIB -> _ssub($x->{_e}, $x->{_es}, $LIB->_new($dbd), $dbd_sign); } # Now: 0.1 <= $x < 10 (and possible correction in l_10) ### Since $x in the range 0.5 .. 1.5 is MUCH faster, we do a repeated div ### or mul by 2 (maximum times 3, since x < 10 and x > 0.1) $HALF = $class->new($HALF) unless ref($HALF); my $twos = 0; # default: none (0 times) while ($x->bacmp($HALF) <= 0) { # X <= 0.5 $twos--; $x = $x->bmul($two); } while ($x->bacmp($two) >= 0) { # X >= 2 $twos++; $x = $x->bdiv($two, $scale+4); # keep all digits } $x = $x->bround($scale+4); # $twos > 0 => did mul 2, < 0 => did div 2 (but we never did both) # So calculate correction factor based on ln(2): if ($twos != 0) { $LOG_2 = $class->new($LOG_2, undef, undef) unless ref $LOG_2; if ($scale <= $LOG_2_A) { # use cached value $l_2 = $LOG_2->copy(); # copy() for the mul below } else { # else: slower, compute and cache result $l_2 = $two->copy(); $l_2 = $l_2->_log($scale); # scale+4, actually $LOG_2 = $l_2->copy(); # cache the result for later # the copy() is for mul below $LOG_2_A = $scale; } $l_2 = $l_2->bmul($twos); # * -2 => subtract, * 2 => add } else { undef $l_2; } $x = $x->_log($scale); # need to do the "normal" way $x = $x->badd($l_10) if defined $l_10; # correct it by ln(10) $x = $x->badd($l_2) if defined $l_2; # and maybe by ln(2) # all done, $x contains now the result $x; } sub _pow { # Calculate a power where $y is a non-integer, like 2 ** 0.3 my ($x, $y, @r) = @_; my $class = ref($x); # if $y == 0.5, it is sqrt($x) $HALF = $class->new($HALF) unless ref($HALF); return $x->bsqrt(@r, $y) if $y->bcmp($HALF) == 0; # Using: # a ** x == e ** (x * ln a) # u = y * ln x # _ _ # Taylor: | u u^2 u^3 | # x ** y = 1 + | --- + --- + ----- + ... | # |_ 1 1*2 1*2*3 _| # we need to limit the accuracy to protect against overflow my $fallback = 0; my ($scale, @params); ($x, @params) = $x->_find_round_parameters(@r); return $x if $x->is_nan(); # error in _find_round_parameters? # no rounding at all, so must use fallback if (scalar @params == 0) { # simulate old behaviour $params[0] = $class->div_scale(); # and round to it as accuracy $params[1] = undef; # disable P $scale = $params[0]+4; # at least four more for proper round $params[2] = $r[2]; # 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 is not # enough... $scale = abs($params[0] || $params[1]) + 4; # take whatever is defined } # when user set globals, they would interfere with our calculation, so # disable them and later re-enable them no strict 'refs'; my $abr = "$class\::accuracy"; my $ab = $$abr; $$abr = undef; my $pbr = "$class\::precision"; my $pb = $$pbr; $$pbr = undef; # we also need to disable any set A or P on $x (_find_round_parameters took # them already into account), since these would interfere, too $x->{_a} = undef; $x->{_p} = undef; # Disabling upgrading and downgrading is no longer necessary to avoid an # infinite recursion, but it avoids unnecessary upgrading and downgrading in # the intermediate computations. local $Math::BigInt::upgrade = undef; local $Math::BigFloat::downgrade = undef; my ($limit, $v, $u, $below, $factor, $next, $over); $u = $x->copy()->blog(undef, $scale)->bmul($y); my $do_invert = ($u->{sign} eq '-'); $u = $u->bneg() if $do_invert; $v = $class->bone(); # 1 $factor = $class->new(2); # 2 $x = $x->bone(); # first term: 1 $below = $v->copy(); $over = $u->copy(); $limit = $class->new("1E-". ($scale-1)); while (3 < 5) { # we calculate the next term, and add it to the last # when the next term is below our limit, it won't affect the outcome # anymore, so we stop: $next = $over->copy()->bdiv($below, $scale); last if $next->bacmp($limit) <= 0; $x = $x->badd($next); # calculate things for the next term $over *= $u; $below *= $factor; $factor = $factor->binc(); last if $x->{sign} !~ /^[-+]$/; } if ($do_invert) { my $x_copy = $x->copy(); $x = $x->bone->bdiv($x_copy, $scale); } # shortcut to not run through _find_round_parameters again if (defined $params[0]) { $x = $x->bround($params[0], $params[2]); # then round accordingly } else { $x = $x->bfround($params[1], $params[2]); # then round accordingly } if ($fallback) { # clear a/p after round, since user did not request it $x->{_a} = undef; $x->{_p} = undef; } # restore globals $$abr = $ab; $$pbr = $pb; $x; } # These functions are only provided for backwards compabibility so that old # version of Math::BigRat etc. don't complain about missing them. sub _e_add { my ($x, $y, $xs, $ys) = @_; return $LIB -> _sadd($x, $xs, $y, $ys); } sub _e_sub { my ($x, $y, $xs, $ys) = @_; return $LIB -> _ssub($x, $xs, $y, $ys); } 1; __END__ =pod =head1 NAME Math::BigFloat - arbitrary size floating point math package =head1 SYNOPSIS use Math::BigFloat; # Configuration methods (may be used as class methods and instance methods) Math::BigFloat->accuracy(); # get class accuracy Math::BigFloat->accuracy($n); # set class accuracy Math::BigFloat->precision(); # get class precision Math::BigFloat->precision($n); # set class precision Math::BigFloat->round_mode(); # get class rounding mode Math::BigFloat->round_mode($m); # set global round mode, must be one of # 'even', 'odd', '+inf', '-inf', 'zero', # 'trunc', or 'common' Math::BigFloat->config("lib"); # name of backend math library # Constructor methods (when the class methods below are used as instance # methods, the value is assigned the invocand) $x = Math::BigFloat->new($str); # defaults to 0 $x = Math::BigFloat->new('0x123'); # from hexadecimal $x = Math::BigFloat->new('0o377'); # from octal $x = Math::BigFloat->new('0b101'); # from binary $x = Math::BigFloat->from_hex('0xc.afep+3'); # from hex $x = Math::BigFloat->from_hex('cafe'); # ditto $x = Math::BigFloat->from_oct('1.3267p-4'); # from octal $x = Math::BigFloat->from_oct('01.3267p-4'); # ditto $x = Math::BigFloat->from_oct('0o1.3267p-4'); # ditto $x = Math::BigFloat->from_oct('0377'); # ditto $x = Math::BigFloat->from_bin('0b1.1001p-4'); # from binary $x = Math::BigFloat->from_bin('0101'); # ditto $x = Math::BigFloat->from_ieee754($b, "binary64"); # from IEEE-754 bytes $x = Math::BigFloat->bzero(); # create a +0 $x = Math::BigFloat->bone(); # create a +1 $x = Math::BigFloat->bone('-'); # create a -1 $x = Math::BigFloat->binf(); # create a +inf $x = Math::BigFloat->binf('-'); # create a -inf $x = Math::BigFloat->bnan(); # create a Not-A-Number $x = Math::BigFloat->bpi(); # returns pi $y = $x->copy(); # make a copy (unlike $y = $x) $y = $x->as_int(); # return as BigInt $y = $x->as_float(); # return as a Math::BigFloat $y = $x->as_rat(); # return as a Math::BigRat # Boolean methods (these don't modify the invocand) $x->is_zero(); # if $x is 0 $x->is_one(); # if $x is +1 $x->is_one("+"); # ditto $x->is_one("-"); # if $x is -1 $x->is_inf(); # if $x is +inf or -inf $x->is_inf("+"); # if $x is +inf $x->is_inf("-"); # if $x is -inf $x->is_nan(); # if $x is NaN $x->is_positive(); # if $x > 0 $x->is_pos(); # ditto $x->is_negative(); # if $x < 0 $x->is_neg(); # ditto $x->is_odd(); # if $x is odd $x->is_even(); # if $x is even $x->is_int(); # if $x is an integer # Comparison methods $x->bcmp($y); # compare numbers (undef, < 0, == 0, > 0) $x->bacmp($y); # compare absolutely (undef, < 0, == 0, > 0) $x->beq($y); # true if and only if $x == $y $x->bne($y); # true if and only if $x != $y $x->blt($y); # true if and only if $x < $y $x->ble($y); # true if and only if $x <= $y $x->bgt($y); # true if and only if $x > $y $x->bge($y); # true if and only if $x >= $y # Arithmetic methods $x->bneg(); # negation $x->babs(); # absolute value $x->bsgn(); # sign function (-1, 0, 1, or NaN) $x->bnorm(); # normalize (no-op) $x->binc(); # increment $x by 1 $x->bdec(); # decrement $x by 1 $x->badd($y); # addition (add $y to $x) $x->bsub($y); # subtraction (subtract $y from $x) $x->bmul($y); # multiplication (multiply $x by $y) $x->bmuladd($y,$z); # $x = $x * $y + $z $x->bdiv($y); # division (floored), set $x to quotient # return (quo,rem) or quo if scalar $x->btdiv($y); # division (truncated), set $x to quotient # return (quo,rem) or quo if scalar $x->bmod($y); # modulus (x % y) $x->btmod($y); # modulus (truncated) $x->bmodinv($mod); # modular multiplicative inverse $x->bmodpow($y,$mod); # modular exponentiation (($x ** $y) % $mod) $x->bpow($y); # power of arguments (x ** y) $x->blog(); # logarithm of $x to base e (Euler's number) $x->blog($base); # logarithm of $x to base $base (e.g., base 2) $x->bexp(); # calculate e ** $x where e is Euler's number $x->bnok($y); # x over y (binomial coefficient n over k) $x->bsin(); # sine $x->bcos(); # cosine $x->batan(); # inverse tangent $x->batan2($y); # two-argument inverse tangent $x->bsqrt(); # calculate square root $x->broot($y); # $y'th root of $x (e.g. $y == 3 => cubic root) $x->bfac(); # factorial of $x (1*2*3*4*..$x) $x->blsft($n); # left shift $n places in base 2 $x->blsft($n,$b); # left shift $n places in base $b # returns (quo,rem) or quo (scalar context) $x->brsft($n); # right shift $n places in base 2 $x->brsft($n,$b); # right shift $n places in base $b # returns (quo,rem) or quo (scalar context) # Bitwise methods $x->band($y); # bitwise and $x->bior($y); # bitwise inclusive or $x->bxor($y); # bitwise exclusive or $x->bnot(); # bitwise not (two's complement) # Rounding methods $x->round($A,$P,$mode); # round to accuracy or precision using # rounding mode $mode $x->bround($n); # accuracy: preserve $n digits $x->bfround($n); # $n > 0: round to $nth digit left of dec. point # $n < 0: round to $nth digit right of dec. point $x->bfloor(); # round towards minus infinity $x->bceil(); # round towards plus infinity $x->bint(); # round towards zero # Other mathematical methods $x->bgcd($y); # greatest common divisor $x->blcm($y); # least common multiple # Object property methods (do not modify the invocand) $x->sign(); # the sign, either +, - or NaN $x->digit($n); # the nth digit, counting from the right $x->digit(-$n); # the nth digit, counting from the left $x->length(); # return number of digits in number ($xl,$f) = $x->length(); # length of number and length of fraction # part, latter is always 0 digits long # for Math::BigInt objects $x->mantissa(); # return (signed) mantissa as BigInt $x->exponent(); # return exponent as BigInt $x->parts(); # return (mantissa,exponent) as BigInt $x->sparts(); # mantissa and exponent (as integers) $x->nparts(); # mantissa and exponent (normalised) $x->eparts(); # mantissa and exponent (engineering notation) $x->dparts(); # integer and fraction part $x->fparts(); # numerator and denominator $x->numerator(); # numerator $x->denominator(); # denominator # Conversion methods (do not modify the invocand) $x->bstr(); # decimal notation, possibly zero padded $x->bsstr(); # string in scientific notation with integers $x->bnstr(); # string in normalized notation $x->bestr(); # string in engineering notation $x->bdstr(); # string in decimal notation $x->bfstr(); # string in fractional notation $x->as_hex(); # as signed hexadecimal string with prefixed 0x $x->as_bin(); # as signed binary string with prefixed 0b $x->as_oct(); # as signed octal string with prefixed 0 $x->to_ieee754($format); # to bytes encoded according to IEEE 754-2008 # Other conversion methods $x->numify(); # return as scalar (might overflow or underflow) =head1 DESCRIPTION Math::BigFloat provides support for arbitrary precision floating point. Overloading is also provided for Perl operators. All operators (including basic math operations) are overloaded if you declare your big floating point numbers as $x = Math::BigFloat -> new('12_3.456_789_123_456_789E-2'); Operations with overloaded operators preserve the arguments, which is exactly what you expect. =head2 Input Input values to these routines may be any scalar number or string that looks like a number. Anything that is accepted by Perl as a literal numeric constant should be accepted by this module. =over =item * Leading and trailing whitespace is ignored. =item * Leading zeros are ignored, except for floating point numbers with a binary exponent, in which case the number is interpreted as an octal floating point number. For example, "01.4p+0" gives 1.5, "00.4p+0" gives 0.5, but "0.4p+0" gives a NaN. And while "0377" gives 255, "0377p0" gives 255. =item * If the string has a "0x" or "0X" prefix, it is interpreted as a hexadecimal number. =item * If the string has a "0o" or "0O" prefix, it is interpreted as an octal number. A floating point literal with a "0" prefix is also interpreted as an octal number. =item * If the string has a "0b" or "0B" prefix, it is interpreted as a binary number. =item * Underline characters are allowed in the same way as they are allowed in literal numerical constants. =item * If the string can not be interpreted, NaN is returned. =item * For hexadecimal, octal, and binary floating point numbers, the exponent must be separated from the significand (mantissa) by the letter "p" or "P", not "e" or "E" as with decimal numbers. =back Some examples of valid string input Input string Resulting value 123 123 1.23e2 123 12300e-2 123 67_538_754 67538754 -4_5_6.7_8_9e+0_1_0 -4567890000000 0x13a 314 0x13ap0 314 0x1.3ap+8 314 0x0.00013ap+24 314 0x13a000p-12 314 0o472 314 0o1.164p+8 314 0o0.0001164p+20 314 0o1164000p-10 314 0472 472 Note! 01.164p+8 314 00.0001164p+20 314 01164000p-10 314 0b100111010 314 0b1.0011101p+8 314 0b0.00010011101p+12 314 0b100111010000p-3 314 0x1.921fb5p+1 3.14159262180328369140625e+0 0o1.2677025p1 2.71828174591064453125 01.2677025p1 2.71828174591064453125 0b1.1001p-4 9.765625e-2 =head2 Output Output values are usually Math::BigFloat objects. Boolean operators C, C, C, etc. return true or false. Comparison operators C and C) return -1, 0, 1, or undef. =head1 METHODS Math::BigFloat supports all methods that Math::BigInt supports, except it calculates non-integer results when possible. Please see L for a full description of each method. Below are just the most important differences: =head2 Configuration methods =over =item accuracy() $x->accuracy(5); # local for $x CLASS->accuracy(5); # global for all members of CLASS # Note: This also applies to new()! $A = $x->accuracy(); # read out accuracy that affects $x $A = CLASS->accuracy(); # read out global accuracy Set or get the global or local accuracy, aka how many significant digits the results have. If you set a global accuracy, then this also applies to new()! Warning! The accuracy I, e.g. once you created a number under the influence of C<< CLASS->accuracy($A) >>, all results from math operations with that number will also be rounded. In most cases, you should probably round the results explicitly using one of L, L or L or by passing the desired accuracy to the math operation as additional parameter: my $x = Math::BigInt->new(30000); my $y = Math::BigInt->new(7); print scalar $x->copy()->bdiv($y, 2); # print 4300 print scalar $x->copy()->bdiv($y)->bround(2); # print 4300 =item precision() $x->precision(-2); # local for $x, round at the second # digit right of the dot $x->precision(2); # ditto, round at the second digit # left of the dot CLASS->precision(5); # Global for all members of CLASS # This also applies to new()! CLASS->precision(-5); # ditto $P = CLASS->precision(); # read out global precision $P = $x->precision(); # read out precision that affects $x Note: You probably want to use L instead. With L you set the number of digits each result should have, with L you set the place where to round! =back =head2 Constructor methods =over =item from_hex() $x -> from_hex("0x1.921fb54442d18p+1"); $x = Math::BigFloat -> from_hex("0x1.921fb54442d18p+1"); Interpret input as a hexadecimal string.A prefix ("0x", "x", ignoring case) is optional. A single underscore character ("_") may be placed between any two digits. If the input is invalid, a NaN is returned. The exponent is in base 2 using decimal digits. If called as an instance method, the value is assigned to the invocand. =item from_oct() $x -> from_oct("1.3267p-4"); $x = Math::BigFloat -> from_oct("1.3267p-4"); Interpret input as an octal string. A single underscore character ("_") may be placed between any two digits. If the input is invalid, a NaN is returned. The exponent is in base 2 using decimal digits. If called as an instance method, the value is assigned to the invocand. =item from_bin() $x -> from_bin("0b1.1001p-4"); $x = Math::BigFloat -> from_bin("0b1.1001p-4"); Interpret input as a hexadecimal string. A prefix ("0b" or "b", ignoring case) is optional. A single underscore character ("_") may be placed between any two digits. If the input is invalid, a NaN is returned. The exponent is in base 2 using decimal digits. If called as an instance method, the value is assigned to the invocand. =item from_ieee754() Interpret the input as a value encoded as described in IEEE754-2008. The input can be given as a byte string, hex string or binary string. The input is assumed to be in big-endian byte-order. # both $dbl and $mbf are 3.141592... $bytes = "\x40\x09\x21\xfb\x54\x44\x2d\x18"; $dbl = unpack "d>", $bytes; $mbf = Math::BigFloat -> from_ieee754($bytes, "binary64"); =item bpi() print Math::BigFloat->bpi(100), "\n"; Calculate PI to N digits (including the 3 before the dot). The result is rounded according to the current rounding mode, which defaults to "even". This method was added in v1.87 of Math::BigInt (June 2007). =back =head2 Arithmetic methods =over =item bmuladd() $x->bmuladd($y,$z); Multiply $x by $y, and then add $z to the result. This method was added in v1.87 of Math::BigInt (June 2007). =item bdiv() $q = $x->bdiv($y); ($q, $r) = $x->bdiv($y); In scalar context, divides $x by $y and returns the result to the given or default accuracy/precision. In list context, does floored division (F-division), returning an integer $q and a remainder $r so that $x = $q * $y + $r. The remainer (modulo) is equal to what is returned by C<< $x->bmod($y) >>. =item bmod() $x->bmod($y); Returns $x modulo $y. When $x is finite, and $y is finite and non-zero, the result is identical to the remainder after floored division (F-division). If, in addition, both $x and $y are integers, the result is identical to the result from Perl's % operator. =item bexp() $x->bexp($accuracy); # calculate e ** X Calculates the expression C where C is Euler's number. This method was added in v1.82 of Math::BigInt (April 2007). =item 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 v1.84 of Math::BigInt (April 2007). =item bsin() my $x = Math::BigFloat->new(1); print $x->bsin(100), "\n"; Calculate the sinus of $x, modifying $x in place. This method was added in v1.87 of Math::BigInt (June 2007). =item bcos() my $x = Math::BigFloat->new(1); print $x->bcos(100), "\n"; Calculate the cosinus of $x, modifying $x in place. This method was added in v1.87 of Math::BigInt (June 2007). =item batan() my $x = Math::BigFloat->new(1); print $x->batan(100), "\n"; Calculate the arcus tanges of $x, modifying $x in place. See also L. This method was added in v1.87 of Math::BigInt (June 2007). =item batan2() my $y = Math::BigFloat->new(2); my $x = Math::BigFloat->new(3); print $y->batan2($x), "\n"; Calculate the arcus tanges of C<$y> divided by C<$x>, modifying $y in place. See also L. This method was added in v1.87 of Math::BigInt (June 2007). =item as_float() This method is called when Math::BigFloat encounters an object it doesn't know how to handle. For instance, assume $x is a Math::BigFloat, or subclass thereof, and $y is defined, but not a Math::BigFloat, or subclass thereof. If you do $x -> badd($y); $y needs to be converted into an object that $x can deal with. This is done by first checking if $y is something that $x might be upgraded to. If that is the case, no further attempts are made. The next is to see if $y supports the method C. The method C is expected to return either an object that has the same class as $x, a subclass thereof, or a string that Cnew()> can parse to create an object. In Math::BigFloat, C has the same effect as C. =item to_ieee754() Encodes the invocand as a byte string in the given format as specified in IEEE 754-2008. Note that the encoded value is the nearest possible representation of the value. This value might not be exactly the same as the value in the invocand. # $x = 3.1415926535897932385 $x = Math::BigFloat -> bpi(30); $b = $x -> to_ieee754("binary64"); # encode as 8 bytes $h = unpack "H*", $b; # "400921fb54442d18" # 3.141592653589793115997963... $y = Math::BigFloat -> from_ieee754($h, "binary64"); All binary formats in IEEE 754-2008 are accepted. For convenience, som aliases are recognized: "half" for "binary16", "single" for "binary32", "double" for "binary64", "quadruple" for "binary128", "octuple" for "binary256", and "sexdecuple" for "binary512". See also L. =back =head2 ACCURACY AND PRECISION See also: L. Math::BigFloat supports both precision (rounding to a certain place before or after the dot) and accuracy (rounding to a certain number of digits). For a full documentation, examples and tips on these topics please see the large section about rounding in L. Since things like C or C<1 / 3> must presented with a limited accuracy lest a operation consumes all resources, each operation produces no more than the requested number of digits. If there is no global precision or accuracy set, B the operation in question was not called with a requested precision or accuracy, B the input $x has no accuracy or precision set, then a fallback parameter will be used. For historical reasons, it is called C and can be accessed via: $d = Math::BigFloat->div_scale(); # query Math::BigFloat->div_scale($n); # set to $n digits The default value for C is 40. In case the result of one operation has more digits than specified, it is rounded. The rounding mode taken is either the default mode, or the one supplied to the operation after the I: $x = Math::BigFloat->new(2); Math::BigFloat->accuracy(5); # 5 digits max $y = $x->copy()->bdiv(3); # gives 0.66667 $y = $x->copy()->bdiv(3,6); # gives 0.666667 $y = $x->copy()->bdiv(3,6,undef,'odd'); # gives 0.666667 Math::BigFloat->round_mode('zero'); $y = $x->copy()->bdiv(3,6); # will also give 0.666667 Note that C<< Math::BigFloat->accuracy() >> and C<< Math::BigFloat->precision() >> set the global variables, and thus B newly created number will be subject to the global rounding B. This means that in the examples above, the C<3> as argument to C will also get an accuracy of B<5>. It is less confusing to either calculate the result fully, and afterwards round it explicitly, or use the additional parameters to the math functions like so: use Math::BigFloat; $x = Math::BigFloat->new(2); $y = $x->copy()->bdiv(3); print $y->bround(5),"\n"; # gives 0.66667 or use Math::BigFloat; $x = Math::BigFloat->new(2); $y = $x->copy()->bdiv(3,5); # gives 0.66667 print "$y\n"; =head2 Rounding =over =item bfround ( +$scale ) Rounds to the $scale'th place left from the '.', counting from the dot. The first digit is numbered 1. =item bfround ( -$scale ) Rounds to the $scale'th place right from the '.', counting from the dot. =item bfround ( 0 ) Rounds to an integer. =item bround ( +$scale ) Preserves accuracy to $scale digits from the left (aka significant digits) and pads the rest with zeros. If the number is between 1 and -1, the significant digits count from the first non-zero after the '.' =item bround ( -$scale ) and bround ( 0 ) These are effectively no-ops. =back All rounding functions take as a second parameter a rounding mode from one of the following: 'even', 'odd', '+inf', '-inf', 'zero', 'trunc' or 'common'. The default rounding mode is 'even'. By using C<< Math::BigFloat->round_mode($round_mode); >> you can get and set the default mode for subsequent rounding. The usage of C<$Math::BigFloat::$round_mode> is no longer supported. The second parameter to the round functions then overrides the default temporarily. The C function returns a BigInt from a Math::BigFloat. It uses 'trunc' as rounding mode to make it equivalent to: $x = 2.5; $y = int($x) + 2; You can override this by passing the desired rounding mode as parameter to C: $x = Math::BigFloat->new(2.5); $y = $x->as_number('odd'); # $y = 3 =head1 NUMERIC LITERALS After C all numeric literals in the given scope are converted to C objects. This conversion happens at compile time. For example, perl -MMath::BigFloat=:constant -le 'print 2e-150' prints the exact value of C<2e-150>. Note that without conversion of constants the expression C<2e-150> is calculated using Perl scalars, which leads to an inaccuracte result. Note that strings are not affected, so that use Math::BigFloat qw/:constant/; $y = "1234567890123456789012345678901234567890" + "123456789123456789"; does not give you what you expect. You need an explicit Math::BigFloat->new() around at least one of the operands. You should also quote large constants to prevent loss of precision: use Math::BigFloat; $x = Math::BigFloat->new("1234567889123456789123456789123456789"); Without the quotes Perl converts the large number to a floating point constant at compile time, and then converts the result to a Math::BigFloat object at runtime, which results in an inaccurate result. =head2 Hexadecimal, octal, and binary floating point literals Perl (and this module) accepts hexadecimal, octal, and binary floating point literals, but use them with care with Perl versions before v5.32.0, because some versions of Perl silently give the wrong result. Below are some examples of different ways to write the number decimal 314. Hexadecimal floating point literals: 0x1.3ap+8 0X1.3AP+8 0x1.3ap8 0X1.3AP8 0x13a0p-4 0X13A0P-4 Octal floating point literals (with "0" prefix): 01.164p+8 01.164P+8 01.164p8 01.164P8 011640p-4 011640P-4 Octal floating point literals (with "0o" prefix) (requires v5.34.0): 0o1.164p+8 0O1.164P+8 0o1.164p8 0O1.164P8 0o11640p-4 0O11640P-4 Binary floating point literals: 0b1.0011101p+8 0B1.0011101P+8 0b1.0011101p8 0B1.0011101P8 0b10011101000p-2 0B10011101000P-2 =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::BigFloat lib => "Calc"; You can change this by using: use Math::BigFloat lib => "GMP"; B: General purpose packages should not be explicit about the library to use; let the script author decide which is best. Note: The keyword 'lib' will warn when the requested library could not be loaded. To suppress the warning use 'try' instead: use Math::BigFloat try => "GMP"; If your script works with huge numbers and Calc is too slow for them, you can also for the loading of one of these libraries and if none of them can be used, the code will die: use Math::BigFloat only => "GMP,Pari"; 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::BigFloat lib => "Foo,Math::BigInt::Bar"; See the respective low-level library documentation for further details. See L for more details about using a different low-level library. =head2 Using Math::BigInt::Lite For backwards compatibility reasons it is still possible to request a different storage class for use with Math::BigFloat: use Math::BigFloat with => 'Math::BigInt::Lite'; However, this request is ignored, as the current code now uses the low-level math library for directly storing the number parts. =head1 EXPORTS C exports nothing by default, but can export the C method: use Math::BigFloat qw/bpi/; print bpi(10), "\n"; =head1 CAVEATS Do not try to be clever to insert some operations in between switching libraries: require Math::BigFloat; my $matter = Math::BigFloat->bone() + 4; # load BigInt and Calc Math::BigFloat->import( lib => 'Pari' ); # load Pari, too my $anti_matter = Math::BigFloat->bone()+4; # now use Pari This will create objects with numbers stored in two different backend libraries, and B will happen when you use these together: my $flash_and_bang = $matter + $anti_matter; # Don't do this! =over =item stringify, bstr() Both stringify and bstr() now drop the leading '+'. The old code would return '+1.23', the new returns '1.23'. See the documentation in L for reasoning and details. =item brsft() The following will probably not print what you expect: my $c = Math::BigFloat->new('3.14159'); print $c->brsft(3,10),"\n"; # prints 0.00314153.1415 It prints both quotient and remainder, since print calls C in list context. Also, C<< $c->brsft() >> will modify $c, so be careful. You probably want to use print scalar $c->copy()->brsft(3,10),"\n"; # or if you really want to modify $c print scalar $c->brsft(3,10),"\n"; instead. =item Modifying and = Beware of: $x = Math::BigFloat->new(5); $y = $x; It will not do what you think, e.g. making a copy of $x. Instead it just makes a second reference to the B object and stores it in $y. Thus anything that modifies $x will modify $y (except overloaded math operators), and vice versa. See L for details and how to avoid that. =item precision() vs. accuracy() A common pitfall is to use L when you want to round a result to a certain number of digits: use Math::BigFloat; Math::BigFloat->precision(4); # does not do what you # think it does my $x = Math::BigFloat->new(12345); # rounds $x to "12000"! print "$x\n"; # print "12000" my $y = Math::BigFloat->new(3); # rounds $y to "0"! print "$y\n"; # print "0" $z = $x / $y; # 12000 / 0 => NaN! print "$z\n"; print $z->precision(),"\n"; # 4 Replacing L with L is probably not what you want, either: use Math::BigFloat; Math::BigFloat->accuracy(4); # enables global rounding: my $x = Math::BigFloat->new(123456); # rounded immediately # to "12350" print "$x\n"; # print "123500" my $y = Math::BigFloat->new(3); # rounded to "3 print "$y\n"; # print "3" print $z = $x->copy()->bdiv($y),"\n"; # 41170 print $z->accuracy(),"\n"; # 4 What you want to use instead is: use Math::BigFloat; my $x = Math::BigFloat->new(123456); # no rounding print "$x\n"; # print "123456" my $y = Math::BigFloat->new(3); # no rounding print "$y\n"; # print "3" print $z = $x->copy()->bdiv($y,4),"\n"; # 41150 print $z->accuracy(),"\n"; # undef In addition to computing what you expected, the last example also does B "taint" the result with an accuracy or precision setting, which would influence any further operation. =back =head1 BUGS Please report any bugs or feature requests to C, or through the web interface at L (requires login). We will be notified, and then you'll automatically be notified of progress on your bug as I make changes. =head1 SUPPORT You can find documentation for this module with the perldoc command. perldoc Math::BigFloat You can also look for information at: =over 4 =item * GitHub L =item * RT: CPAN's request tracker L =item * MetaCPAN L =item * CPAN Testers Matrix L =back =head1 LICENSE This program is free software; you may redistribute it and/or modify it under the same terms as Perl itself. =head1 SEE ALSO L and L as well as the backends L, L, and L. The pragmas L, L and L. =head1 AUTHORS =over 4 =item * Mark Biggar, overloaded interface by Ilya Zakharevich, 1996-2001. =item * Completely rewritten by Tels L in 2001-2008. =item * Florian Ragwitz Eflora@cpan.orgE, 2010. =item * Peter John Acklam Epjacklam@gmail.comE, 2011-. =back =cut