Math::NV - compare the NV values that perl assigns with C and MPFR
use Math::NV qw(:all); $bool = is_eq('1e-298'); $bool = is_eq_mpfr('1e-298'); # iff Math::MPFR is available If $bool is true, this suggests there is quite possibly no bug in the assignment of the specified value. If $bool is false, this implies that at least one of perl && C (wrt is_eq) or mpfr (wrt is_eq_mpfr) suffer a bug in assigning the specified value. IME, it's perl that's usually wrong - though I've struck buggy assignments with C. I've not yet found a case where mpfr assigns incorrectly - and I firmly expect that I won't ever find such a bug with that library. All mpfr values are assigned with a rounding mode of "to nearest, ties to even". (This could be made configurable if requested.)
$bool = is_eq($str); Returns true if the value perl assigns to an NV from the string $str is equal to the value C assigns to the C type specified by $Config{nvtype} from the same string. Else returns false - which implies that either perl or C is buggy in its assignment of that value. (Or they could both be buggy.) When is_eq() returns false, the 2 differing values are by default printed to STDOUT (in hex). To disable this behaviour set $Math::NV::no_warn to 2. $ternary = is_inexact($str); # requires mpfr-3.1.6 If $ternary is 0, then the value specified by $str is exactly representable by an NV. If $ternary is less than 0, then the value specified by $str is not exactly representable by an NV, and the nearest NV (ties to even) is less than the value that the string specifies. If $ternary is greater than 0, then the value specified by $str is not exactly representable by an NV, and the nearest NV (ties to even) is greater than the value that the string specifies. $bool = is_eq_mpfr($str); Returns true if the value perl assigns from the string $str is equal to the value mpfr assigns from the same string. If the string represents a subnormal value then the mpfr value is subnormalised before the comparison is made. When is_eq_mpfr() returns false, the 2 differing values are by default printed to STDOUT (in hex). To disable this behaviour set $Math::NV::no_warn to 2. $nv = nv($str); # scalar context ($nv, $iv) = nv($str); # list context On perls whose NV is a C "double", assigns to $nv the value that the C standard library function strtod($str) assigns. On perls whose NV is a C "long double", assigns to $nv the value that the C standard library function strtold($str) assigns. On perls whose NV is a C "__float128", assigns to $nv the value that the C standard library function strtofloat128($str) assigns. In list context, also returns the number of characters that were unparsed (ignored). Generally you'll want $str to be a string - eg the string "2.3", rather than the NV 2.3. Failure to adhere to this will result in a warning - though you can disable this warning by setting $Math::NV::no_warn to 1. $nv = set_C($str); Uses the standard C library's strtod() or strtold() or strtoflt128(), depending upon which of those three is correct for perl's floating point type. Expect the returned value to be the same as that returned by nv(). $nv = set_mpfr($str); Uses Math::MPFR to assign the value specified by $str to the NV $nv. Rounding is to nearest, ties to even. If the string represents a subnormal value, then the value held by the Math::MPFR object is subnormalized before being returned in $nv. $hex = nv_mpfr($str, [$bits]); # Returns a hex dump of the NV, # not the actual NV. Again, values will be subnormalized if appropriate. If $bits is not specified, it will be set to the value returned by mant_dig() - which is the appropriate value for the current perl that is being run. Valid values for $bits are 53 (double), 64 (80-bit extended precision long double), 113 (128-bit quad long double or __float128). To signify the double-double type, set $bits to either 106 or 2098. (While the double-double has only 106 mantissa bits, it can encapsulate precisions up to 2098 bits for some values. It makes no difference whether you specify 106 or 2098 - just go with the number you consider to be the more appropriate or easiest to memorise.) Any values other than 53, 64, 106, 113, or 2098 will cause an error. Uses the mpfr library to assign the value represented by $str as a double or long double or double-double or __float128 (as determined by the value of $bits). It then returns a hex dump of the bytes that make up that C data type. For example, nv_mpfr('1e+127', 53) returns 5a4d8ba7f519c84f. This is the same as will be returned by unpack("H*", pack("d>", 1e+127)) if the assignment of 1e+127 to a double has been done correctly. For the double-double, the returned scalar is a reference to a list that contains 2 elements - the hex dump of the most significant double, and the hex dump of the least siginificant double. For all other types, the returned scalar contains the hex dump of the given value. The enticement to use this function in preference to nv()/set_C is twofold: 1) mpfr reliably sets floating point values correctly (whereas C is more likely to suffer bugs); 2) nv_mpfr() can provide hex dumps for any of the four data types (double, long double, double-double and __float128), whereas nv() returns only the value for whichever data type is specified by $Config{nvtype}. Note, however, that for nv_mpfr() to return the hex form of the __float128 type, the mpfr library (as used by Math::MPFR) needs to have been built using the configure option --enable-float128, and this configure option is only available with mpfr-4.0.0 or later - and is not available for all architectures. As is the case with nv(), you'll generally want $str to be a string. For example, specify the string "2.3", rather than the NV 2.3. Failure to adhere to this will result in a warning - though you can disable this warning by setting $Math::NV::no_warn to 1. $nv_type = nv_type(); Returns "double", "long double", or "__float128" depending upon the way perl has been configured. The expectation is that it returns the same as $Config{nvtype}. (Please file a bug report if you find otherwise.) $digits = mant_dig(); Returns the number of bits the NV mantissa contains. This is normally 53 if nv_type() is double. For nv_type() of 'long double' it can be either 64 (extended precision long double), 113 (quad long double) or 106 (IBM double-double). For nv_type() of '__float128', mant_dig() will return 113. This function returns no other than one of those 4 values. IOW, expect mant_dig() to return the value of the float.h macro DBL_MANT_DIG, LDBL_MANT_DIG, or FLT128_MANT_DIG depending upon whichever is appropriate for perl's configuration. ($mantissa, $exponent, $precision) = ld2binary($nv); Uses code taken from tests/tset_ld.c in the mpfr library source and returns a base 2 representation of the value contained in the NV $nv - irrespective of whether the NV type ($Config{nvtype}) is double, long double or __float128. $mantissa is the mantissa (significand). $exponent is the exponent. $precision is the precision (in bits) of the mantissa - trailing zero bits are not counted. For example: @x = ld2binary(2 ** 45); will, upon investigation of the contents of @x, reveal that the mantissa is 0.1, the exponent is 46, and the precision is 1. ($mantissa, $exponent, $precision) = ld_str2binary($str); As for ld2binary, except that the argument is a string, not an NV: @x = ld_str2binary('35184372088832'); produces same result as doing: @x = ld2binary(2 ** 45); $nv = bin2val($mantissa, $exponent, $precision); Takes the return values of ld_str2binary() or ld2binary() and returns the original NV. (Doesn't work if the original NV is an inf or a nan.) Cprintf($fmt, $nv); Uses C's printf() function to format the NV $nv, according to the formatting specified by the string $fmt. $string = Csprintf($fmt, $nv, $buffer_size); Uses C's sprintf() function to format the NV $nv, according to the formatting specified by the string $fmt - and returns the result to $string. It's the responsibility of the caller to ensure that $buffer_size specifies a large enough number of characters to accommodate C's sprintf formatting of $nv. $ternary = cmp_2($str1, $str2); The main purpose here is to be able to determine (eg) whether: 0x1.7ap4 == 0b0.10111101e5 or: 0x1.6a09e667f3bcc908p+0 == 0xb.504f333f9de6484p-3 The 2 args begin with an (optional) + or - sign, followed by (case-insensitive) '0b', '0x', 'nan' or 'inf'. That is, they must match: /^(\-|\+)?0b|^(\-|\+)?0x|^(\-|\+)?nan|^(\-|\+)?inf/i The spaceship operator (<=>) is then used to compare the numeric values of the two strings, the result of which is returned. A negative return indicates that $str1 < $str2; a positive return indicates that $str1 > $str2; a return of zero indicates that $str1 == $str2; a return of undef indicates that $str1 and/or $str2 is a NaN. The values of the 2 args are calculated to their full precisions, even if either/both of those precisions exceed the precision of perl's floating point type (NV).
$Math::NV::no_warn Initially set to 0 - which means that if either nv(), nv_mpfr(), is_eq() or is_eq_mpfr() are handed an argument that is not a string, then a warning will be emitted. To disable this warning, simply set this variable to 1. Set to 2 to disable output of the 2 non-matching values when is_eq() or is_eq_mpfr() return false. Set to 3 to disable both of the above warnings.
This program is free software; you may redistribute it and/or modify it under the same terms as Perl itself. Copyright 2013-16, 2018-22 Sisyphus
Sisyphus <sisyphus at(@) cpan dot (.) org>
To install Math::NV, copy and paste the appropriate command in to your terminal.
cpanm
cpanm Math::NV
CPAN shell
perl -MCPAN -e shell install Math::NV
For more information on module installation, please visit the detailed CPAN module installation guide.