Provided by: libmath-mpfr-perl_4.28-1build2_amd64
NAME
Math::MPFR - perl interface to the MPFR (floating point) library.
DEPENDENCIES
This module needs the MPFR and GMP C libraries. (Install the GMP library first as it is a pre-requisite for MPFR.) The GMP library is available from https://gmplib.org The MPFR library is available from https://www.mpfr.org/ Documentation for current mpfr functions can be found at: www.mpfr.org/mpfr-current/mpfr.html#Function-and-Type-Index
DESCRIPTION
A bigfloat module utilising the MPFR library. Basically this module simply wraps the 'mpfr' floating point functions provided by that library. Operator overloading is also available. The following documentation heavily plagiarises the mpfr documentation. See also the Math::MPFR test suite for some examples of usage.
SYNOPSIS
use Math::MPFR qw(:mpfr); # '@' can be used to separate mantissa from exponent. For bases # that are <= 10, 'e' or 'E' can also be used. # Use single quotes for string assignment if you're using '@' as # the separator. If you must use double quotes, you'll have to # escape the '@'. my $str = '.123542@2'; # mantissa = (.)123452 # exponent = 2 #Alternatively: # my $str = ".123542\@2"; # or: # my $str = '12.3542'; # or: # my $str = '1.23542e1'; # or: # my $str = '1.23542E1'; my $base = 10; my $rnd = MPFR_RNDZ; # See 'ROUNDING MODE' # Create an Math::MPFR object that holds an initial # value of $str (in base $base) and has the default # precision. $bn1 is the number. $nok will either be 0 # indicating that the string was a valid number string, or # -1, indicating that the string contained at least one # invalid numeric character. # See 'COMBINED INITIALISATION AND ASSIGNMENT', below. my ($bn1, $nok) = Rmpfr_init_set_str($str, $base, $rnd); # Or use the new() constructor - also documented below # in 'COMBINED INITIALISATION AND ASSIGNMENT'. # my $bn1 = Math::MPFR->new($str); # Create another Math::MPFR object with precision # of 100 bits and an initial value of NaN. my $bn2 = Rmpfr_init2(100); # Assign the value -2314.451 to $bn1. Rmpfr_set_d($bn2, -2314.451, MPFR_RNDN); # Create another Math::MPFR object that holds # an initial value of NaN and has the default precision. my $bn3 = Rmpfr_init(); # Or using instead the new() constructor: # my $bn3 = Math::MPFR->new(); # Perform some operations ... see 'FUNCTIONS' below. # see 'OPERATOR OVERLOADING' below for docs re # operator overloading . . # print out the value held by $bn1 (in octal): print Rmpfr_get_str($bn1, 8, 0, $rnd), "\n"; # print out the value held by $bn1 (in decimal): print Rmpfr_get_str($bn1, 10, 0, $rnd), "\n"; # or just make use of overloading : print $bn1, "\n"; # is base 10, and uses 'e' rather than '@'. # print out the value held by $bn1 (in base 16) using the # 'TRmpfr_out_str' function. (No newline is printed - unless # it's supplied as the optional fifth arg. See the # 'TRmpfr_out_str' documentation below.) TRmpfr_out_str(*stdout, 16, 0, $bn1, $rnd);
ROUNDING MODE
One of 4 values: GMP_RNDN (numeric value = 0): Round to nearest. GMP_RNDZ (numeric value = 1): Round towards zero. GMP_RNDU (numeric value = 2): Round towards +infinity. GMP_RNDD (numeric value = 3): Round towards -infinity. With the release of mpfr-3.0.0, the same rounding values are renamed to: MPFR_RNDN (numeric value = 0): Round to nearest. MPFR_RNDZ (numeric value = 1): Round towards zero. MPFR_RNDU (numeric value = 2): Round towards +infinity. MPFR_RNDD (numeric value = 3): Round towards -infinity. You can use either the "GMP_*" or the "MPFR_*" renditions. Also available are: mpfr-3.0.0 and later: MPFR_RNDA (numeric value = 4): Round away from zero. mpfr-4.0.0 and later: MPFR_RNDF (numeric value = 5): Faithful rounding. These last two rounding modes will cause a fatal error if the mpfr library against which Math::MPFR has been built is not sufficiently recent. MPFR_RNDF is experimental - the computed value is either that corresponding to MPFR_RNDD or that corresponding to MPFR_RNDU. In particular when those values are identical, i.e., when the result of the corresponding operation is exactly representable, that exact result is returned. Thus, the computed result can take at most two possible values, and in absence of underflow/overflow, the corresponding error is strictly less than one ulp (unit in the last place) of that result and of the exact result. For MPFR_RNDF, the returned value and the inexact flag are unspecified, the divide-by-zero flag is as with other roundings, and the underflow and overflow flags match what would be obtained in the case the computed value is the same as with MPFR_RNDD or MPFR_RNDU. The results may not be reproducible, and it may not work with all functions. Please report bugs. MPFR_RNDN (the 'round to nearest' mode) works as in the IEEE P754 standard: in case the number to be rounded lies exactly in the middle of two representable numbers, it is rounded to the one with the least significant bit set to zero. For example, the number 5, which is represented by (101) in binary, is rounded to (100)=4 with a precision of two bits, and not to (110)=6. This rule avoids the "drift" phenomenon mentioned by Knuth in volume 2 of The Art of Computer Programming (section 4.2.2, pages 221-222). Most Math::MPFR functions take as first argument the destination variable, as second and following arguments the input variables, as last argument a rounding mode, and have a return value of type 'int'. If this value is zero, it usually means that the value stored in the destination variable is the exact result of the corresponding mathematical function. If the returned value is positive (resp. negative), it usually means the value stored in the destination variable is greater (resp. lower) than the exact result. For example with the 'GMP_RNDU' rounding mode, the returned value is usually positive, except when the result is exact, in which case it is zero. In the case of an infinite result, it is considered as inexact when it was obtained by overflow, and exact otherwise. A NaN result (Not-a-Number) always corresponds to an inexact return value. See also the Rmpfr_round_nearest_away() function in the ROUNDING MODE FUNCTIONS section for the mode "round to nearest, ties away from zero".
MEMORY MANAGEMENT
Objects are created with new() or with the Rmpfr_init* functions. All of these functions return an object that has been blessed into the package Math::MPFR. They will therefore be automatically cleaned up by the DESTROY() function whenever they go out of scope. For each Rmpfr_init* function there is a corresponding function called Rmpfr_init*_nobless which returns an unblessed object. If you create Math::MPFR objects using the '_nobless' versions, it will then be up to you to clean up the memory associated with these objects by calling Rmpfr_clear($op) for each object, or Rmpfr_clears($op1, $op2, ....). Alternatively such objects will be cleaned up when the script ends. Because these objects have not been blessed into the Math::MPFR package, the overloaded operators will not work with them.
MIXING GMP OBJECTS WITH MPFR OBJECTS
Some of the Math::MPFR functions below take as arguments one or more of the GMP types mpz (integer), mpq (rational) and mpf (floating point). (Such functions are marked as taking mpz/mpq/mpf arguments.) For these functions to work you need to have loaded either: 1) Math::GMP from CPAN. (This module provides access to mpz objects only - NOT mpf and mpq objects.) AND/OR 2) Math::GMPz (for mpz types), Math::GMPq (for mpq types) and Math::GMPf (for mpf types). You may also be able to use objects from the GMP module that ships with the GMP sources. I get occasional segfaults when I try to do that, so I've stopped recommending it - and don't support the practice.
PASSING __float128 VALUES
There are 3 ways to pass __float128 values to/from Math::MPFR. Option 1) is the preferred option: 1) Build perl (5.21.4 or later) with -Dusequadmath; build the mpfr-4.0.0 (or later) library with the configure option --enable-float128. Then build Math::MPFR in the usual way. If the build process does not then result in a Math::MPFR module that supports the __float128 NV try providing the "F128=1" arg to the Makefile.PL (which will define the symbol MPFR_WANT_FLOAT128): perl Makefile.PL F128=1 (And please file a bug report, because the aim is that you should not need to specify F128=1 here.) Then you can pass your perl's __float128 NV values directly to/from Math::MPFR using: Rmpfr_set_float128() or Rmpfr_set_NV() and Rmpfr_get_float128() or Rmpfr_get_NV() This will also mean that overloaded operations that receive an NV will evaluate that (__float128) NV to its full precision. And assigning the NV as Math::MPFR->new($NV) will also work as intended. NOTE: If you have built perl with -Dusequadmath, but the mpfr library was not built with float128 support , then both Rmpfr_set_NV() and Rmpfr_get_NV() will still set/get __float128 values. Also, overloaded operations that receive an NV will still evaluate that (__float128) NV to its full precision. It's only Rmpfr_set_float128() and Rmpfr_get_float128() that will not be available. 2) On a perl that was not built with -Dusequadmath, install Math::Float128, build the mpfr-4.0.0 (or later) library with the configure option --enable-float128, and build Math::MPFR by providing the "F128=1" arg to the Makefile.pl: perl Makefile.PL F128=1 Then you can pass the values of the Math::Float128 objects to and from Math::MPFR objects using: Rmpfr_set_FLOAT128() and Rmpfr_get_FLOAT128() 3) Convert the __float128 values to a string and pass them to and from Math::MPFR using: Rmpfr_strtofr()/Rmpfr_set_str() and Rmpfr_get_str()
PASSING _Decimal64 & _Decimal128 VALUES
Install Math::Decimal64 and/or Math::Decimal128 and build the mpfr library (version 3.1.0 or later for _Decimal64, version 4.1.0 or later for _Decimal128) with the --enable-decimal-float option. The Math::MPFR build process should detect the _Decimal64/_Decimal128 availability and include or exclude the support accordingly. If the auto-detection fails to detect the availability, you can override it by providing the "D64=1" and/or "D128=1" arg to the the Makefile.PL (either of which will define MPFR_WANT_DECIMAL_FLOATS): perl Makefile.PL D64=1 D128=1 You can then pass _Decimal64/_Decimal128 values between Math::MPFR and Math::Decimal64/Math::Decimal128 using: Rmpfr_set_DECIMAL64() and Rmpfr_get_DECIMAL64() Rmpfr_set_DECIMAL128() and Rmpfr_get_DECIMAL128() NOTE: It is allowable to pass any or all of "D64=1", "D128=1" and "F128=1" args to the Makefile.PL. To force the removal of _Decimal64/Decimal128 support in Math::MPFR, simply provide "D64=0" and/or "D128=0" as arguments to the Makefile.PL: perl Makefile.PL D64=0 D128=0
FUNCTIONS
These next 3 functions are demonstrated above (in SYNOPSIS): $rop = Rmpfr_init(); $rop = Rmpfr_init2($p); $str = Rmpfr_get_str($op, $base, $digits, $rnd); # mpfr version >= 4.1.0 ? 1 < $base < 63 || -37 < $base < -1 # : 1 < $base < 63 The third argument to Rmpfr_get_str() specifies the number of digits required to be output in the mantissa. (Trailing zeroes are removed.) If $digits is 0, the number of digits of the mantissa is chosen large enough so that re-reading the printed value with the same precision, assuming both output and input use rounding to nearest, will recover the original value of $op. The following functions are generally wrappers around an mpfr function of the same name. eg. Rmpfr_swap() is a wrapper around mpfr_swap(). "$rop", "$op1", "$op2", etc. are Math::MPFR objects - the return value of one of the Rmpfr_init* functions. They are in fact references to mpfr structures. The "$op" variables are the operands and "$rop" is the variable that stores the result of the operation. Generally, $rop, $op1, $op2, etc. can be the same perl variable referencing the same mpfr structure, though often they will be distinct perl variables referencing distinct mpfr structures. Eg something like Rmpfr_add($r1, $r1, $r1, $rnd), where $r1 *is* the same reference to the same mpfr structure, would add $r1 to itself and store the result in $r1. Alternatively, you could (courtesy of operator overloading) simply code it as $r1 += $r1 (or even as $r *= 2). Otoh, Rmpfr_add($r1, $r2, $r3, $rnd), where each of the arguments is a different reference to a different mpfr structure would add $r2 to $r3 and store the result in $r1. Alternatively it could be coded as $r1 = $r2 + $r3. "$inex" is a signed integer value (IV) returned by many of the mpfr functions. $inex == 0 indicates that the function's result was exact; $inex < 0 indicates that the function's result was rounded to a value that is less than the exact result; $inex > 0 indicates that the function's result was rounded to a a value that is greater than the exact result. "$ui" means any integer that will fit into a C 'unsigned long int', "$si" means any integer that will fit into a C 'signed long int'. "$uj" means any integer that will fit into a C 'uintmax_t'. Don't use any of these functions unless your perl's UV is at least as big as a 'uintmax_t'. "$sj" means any integer that will fit into a C 'intmax_t'. Don't use any of these functions unless your perl's IV is at least as big as an 'intmax_t'. "$double" is a C double and "$float" is a C float ... but both will be represented in Perl as an NV. "$ld" means a long double. Don't use these functions if the precision of your Perl's NV is less than the precision of a 'long double'. "$f128" means a __float128. Don't use these functions unless your Perl's NV is a __float128 && mpfr has been configured with '--enable-float128'. (Note that versions of mpfr prior to 4.0.0 cannot be configured with '--enable-float128'.) "$bool" means a value (usually a 'signed long int') in which the only interest is whether it evaluates as false or true. "$str" simply means a string of symbols that represent a number, eg '1234567890987654321234567E7' or 'zsa34760sdfgq123r5@11'. Valid bases for MPFR numbers are 2 to 62. "$rnd" is simply one of the 5 rounding mode values (discussed above). "$p" is the (signed int) value for precision. ############## ROUNDING MODE FUNCTIONS Rmpfr_set_default_rounding_mode($rnd); Sets the default rounding mode to $rnd (where $rnd can be one of MPFR_RNDN, MPFR_RNDU, MPFR_RNDZ, MPFR_RNDD and MPFR_RNDA. Note that MPFR_RNDA is available only if Math::MPFR has been built against mpfr-3.0.0 or later. The default rounding mode is to nearest initially (MPFR_RNDN). The default rounding mode is the rounding mode that is used in in overloaded operations. $si = Rmpfr_get_default_rounding_mode(); Returns to $si the numeric value (0, 1, 2, 3 or 4) of the current default rounding mode. This will initially be 0. $inex = Rmpfr_prec_round($rop, $p, $rnd); Rounds $rop according to $rnd with precision $p, which may be different from that of $rop. If $p is greater or equal to the precision of $rop, then new space is allocated for the mantissa, and it is filled with zeroes. Otherwise, the mantissa is rounded to precision $p with the given direction. In both cases, the precision of $rop is changed to $p. The precision $p can be any integer between RMPFR_PREC_MIN and RMPFR_PREC_MAX. $inex = Rmpfr_round_nearest_away(\&function, $rop, @input_args); This is a perl implementation (and not a wrapping) of the mpfr_round_nearest_away macro introduced in mpfr-4.0.0. You can use this function so long as Math::MPFR has been built against mpfr-3.0.0 or later. This rounding is defined in the same way as MPFR_RNDN, except in case of tie, where the value away from zero is returned. The first arg is a reference to the perl subroutine you wish to call, and the remaining args are the args that the subroutine usually takes (minus the rounding arg). For example: $inex = Rmpfr_round_nearest_away(\&Rmpfr_add, $rop, $op1, $op2); $inex = Rmpfr_round_nearest_away(\&Rmpfr_strtofr, $rop, '1e-200', 10); $inex = Rmpfr_round_nearest_away(\&Rmpfr_prec_round, $rop, $prec); The "function" being called must be one that returns the ternary int (-ve for "less than", 0 for "exact", and +ve for "greater than"). Unlike the more efficient rndna(), this function requires that Rmpfr_get_emin() is greater than Rmpfr_get_emin_min(). If you're not concerned about correct rounding (nearest away) of the value +/- 0.25 * (2 ** Rmpfr_get_emin()) then you can instead use the rndna function (immediately below). $inex = rndna(\&function, $rop, @input_args); A more efficient version of the (above) Rmpfr_round_nearest_away function. However, it will not correctly deal with the value +/- 0.25 * (2 ** Rmpfr_get_emin()). Unlike Rmpfr_round_nearest_away(), this function allows that Rmpfr_get_emin() == Rmpfr_get_emin_min(). ############## INITIALIZATION A variable should be initialized once only. First read the section 'MEMORY MANAGEMENT' (above). Rmpfr_set_default_prec($p); Set the default precision to be *exactly* $p bits. The precision of a variable means the number of bits used to store its mantissa. All subsequent calls to 'mpfr_init' will use this precision, but previously initialized variables are unaffected. This default precision is set to 53 bits initially. The precision can be any integer between RMPFR_PREC_MIN and RMPFR_PREC_MAX. $ui = Rmpfr_get_default_prec(); Returns the default MPFR precision in bits. $rop = Math::MPFR->new(); $rop = Math::MPFR::new(); $rop = new Math::MPFR(); $rop = Rmpfr_init(); $rop = Rmpfr_init_nobless(); Initialize $rop, and set its value to NaN. The precision of $rop is the default precision, which can be changed by a call to 'Rmpfr_set_default_prec'. $rop = Rmpfr_init2($p); $rop = Rmpfr_init2_nobless($p); Initialize $rop, set its precision to be *exactly* $p bits, and set its value to NaN. To change the precision of a variable which has already been initialized, use 'Rmpfr_set_prec' instead. The precision $p can be any integer between RMPFR_PREC_MIN and RMPFR_PREC_MAX. @rops = Rmpfr_inits($how_many); @rops = Rmpfr_inits_nobless($how_many); Returns an array of $how_many Math::MPFR objects - initialized, with a value of NaN, and with default precision. (These functions do not wrap mpfr_inits.) @rops = Rmpfr_inits2($p, $how_many); @rops = Rmpfr_inits2_nobless($p, $how_many); Returns an array of $how_many Math::MPFR objects - initialized, with a value of NaN, and with precision of $p. (These functions do not wrap mpfr_inits2.) Rmpfr_set_prec($op, $p); Reset the precision of $op to be *exactly* $p bits. The previous value stored in $op is lost. The precision $p can be any integer between RMPFR_PREC_MIN and RMPFR_PREC_MAX. If you want to keep the previous value stored in $op, use 'Rmpfr_prec_round' instead. $si = Rmpfr_get_prec($op); Return to $si the precision actually used for assignments of $op, i.e. the number of bits used to store its mantissa. Rmpfr_set_prec_raw($rop, $p); Reset the precision of $rop to be *exactly* $p bits. The only difference with 'mpfr_set_prec' is that $p is assumed to be small enough so that the mantissa fits into the current allocated memory space for $rop. Otherwise an error will occur. $min_prec = Rmpfr_min_prec($op); (This function is implemented only when Math::MPFR is built against mpfr-3.0.0 or later. The mpfr_min_prec function was not present in earlier versions of mpfr.) $min_prec is set to the minimal number of bits required to store the significand of $op, and 0 for special values, including 0. (Warning: the returned value can be less than RMPFR_PREC_MIN.) $minimum_precision = RMPFR_PREC_MIN; $maximum_precision = RMPFR_PREC_MAX; Returns the minimum/maximum precision for Math::MPFR objects allowed by the mpfr library being used. ########## ASSIGNMENT $inex = Rmpfr_set($rop, $op, $rnd); $inex = Rmpfr_set_ui($rop, $ui, $rnd); $inex = Rmpfr_set_si($rop, $si, $rnd); $inex = Rmpfr_set_sj($rop, $sj, $rnd); $inex = Rmpfr_set_uj($rop, $uj, $rnd); $inex = Rmpfr_set_IV($rop, $iv, $rnd); # $iv is $Config{ivtype} $inex = Rmpfr_set_d ($rop, $double, $rnd); $inex = Rmpfr_set_ld($rop, $ld, $rnd); # long double $inex = Rmpfr_set_NV($rop, $nv, $rnd); # $nv is $Config{nvtype} $inex = Rmpfr_set_LD($rop, $LD, $rnd); # $LD is a Math::LongDouble # object $inex = Rmpfr_set_z($rop, $z, $rnd); # $z is a mpz object. $inex = Rmpfr_set_q($rop, $q, $rnd); # $q is a mpq object. $inex = Rmpfr_set_f($rop, $f, $rnd); # $f is a mpf object. $inex = Rmpfr_set_flt($rop, $float, $rnd);# mpfr-3.0.0 and later only $inex = Rmpfr_set_float128($rop, $f128, $rnd);# nvtype is __float128 # && mpfr-4.0.0 or later # && mpfr lib built with # --enable-float128. $inex = Rmpfr_set_DECIMAL64($rop, $D64, $rnd);# mpfr-3.1.0 or later && # mpfr lib built with # --enable-decimal-float # $D64 is a # Math::Decimal64 object $inex = Rmpfr_set_DECIMAL128($rop, $D128, $rnd);# mpfr-3.1.0 or later && # mpfr lib built with # --enable-decimal-float. # $D128 is a # Math::Decimal128 object $inex = Rmpfr_set_FLOAT128($rop, $F128, $rnd);# mpfr-4.0.0 and later # && mpfr lib built with # --enable-float128. # $F128 is a # Math::Float128 object. Set the value of $rop from 2nd arg, rounded to the precision of $rop towards the given direction $rnd. Please note that even a 'long int' may have to be rounded if the destination precision is less than the machine word width. The return value is zero when $rop==2nd arg, positive when $rop>2nd arg, and negative when $rop<2nd arg. For 'mpfr_set_d', be careful that the input number $double may not be exactly representable as a double-precision number (this happens for 0.1 for instance), in which case it is first rounded by the C compiler to a double-precision number, and then only to a mpfr floating-point number. NOTE: 1) Rmpfr_set_IV requires that $iv has it's IOK flag set, and Rmpfr_set_NV requires that $nv has its NOK flag set. Otherwise these functions will croak. Best to first check IOK_flag($iv) or NOK_flag($nv), both of which will return a non-zero value if and only if the flag in question is set. 2) Rmpfr_set_IV also handles unsigned (UV) arguments. $inex = Rmpfr_set_ui_2exp($rop, $ui, $exp, $rnd); $inex = Rmpfr_set_si_2exp($rop, $si, $exp, $rnd); $inex = Rmpfr_set_uj_2exp($rop, $sj, $exp, $rnd); $inex = Rmpfr_set_sj_2exp($rop, $sj, $exp, $rnd); $inex = Rmpfr_set_z_2exp($rop, $z, $exp, $rnd); # mpfr-3.0.0 & later only Set the value of $rop from the 2nd arg multiplied by two to the power $exp, rounded towards the given direction $rnd. Note that the input 0 is converted to +0. ($z is a GMP mpz object.) $inex = Rmpfr_set_str($rop, $str, $base, $rnd); Set $rop to the value of $str in base $base (0,2..36 or, if Math::MPFR has been built against mpfr-3.0.0 or later, (0,2..62), rounded in direction $rnd to the precision of $rop. The exponent is read in decimal. This function returns 0 if the entire string is a valid number in base $base. Otherwise it returns -1. If -1 is returned: 1) the non-numeric flag (which was initialised to 0) will be incremented. You can query/clear/reset the value of the flag with (resp.) nnumflag()/clear_nnum()/set_nnum() - all of which are documented below (in "MISCELLANEOUS"); 2) A warning will be emitted if $Math::MPFR::NNW is set to 1 (default is 0). If $base is zero, the base is set according to the following rules: if the string starts with '0b' or '0B' the base is set to 2; if the string starts with '0x' or '0X' the base is set to 16; otherwise the base is set to 10. The following exponent symbols can be used: '@' - can be used for any base; 'e' or 'E' - can be used only with bases <= 10; 'p' or 'P' - can be used to introduce binary exponents with hexadecimal or binary strings. See the MPFR library documentation for more details. See also 'Rmpfr_inp_str' (below). Because of the special significance of the '@' symbol in perl, make sure you assign to strings using single quotes, not double quotes, when using '@' as the exponent marker. If you must use double quotes (which is hard to believe) then you need to escape the '@'. ie the following two assignments are equivalent: Rmpfr_set_str($rop, '.1234@-5', 10, GMP_RNDN); Rmpfr_set_str($rop, ".1234\@-5", 10, GMP_RNDN); But the following assignment won't do what you want: Rmpfr_set_str($rop, ".1234@-5", 10, GMP_RNDN); $inex = Rmpfr_strtofr($rop, $str, $base, $rnd); Read a floating point number from a string $str in base $base, rounded in the direction $rnd. If successful, the result is stored in $rop. If $str doesn't start with a valid number then $rop is set to zero. Parsing follows the standard C 'strtod' function with some extensions. Case is ignored. After optional leading whitespace, one has a subject sequence consisting of an optional sign ('+' or '-'), and either numeric data or special data. The subject sequence is defined as the longest initial subsequence of the input string, starting with the first non-whitespace character, that is of the expected form. The form of numeric data is a non-empty sequence of significand digits with an optional decimal point, and an optional exponent consisting of an exponent prefix followed by an optional sign and a non-empty sequence of decimal digits. A significand digit is either a decimal digit or a Latin letter (62 possible characters), with 'a' = 10, 'b' = 11, ..., 'z' = 36; its value must be strictly less than the base. The decimal point can be either the one defined by the current locale or the period (the first one is accepted for consistency with the C standard and the practice, the second one is accepted to allow the programmer to provide MPFR numbers from strings in a way that does not depend on the current locale). The exponent prefix can be 'e' or 'E' for bases up to 10, or '@' in any base; it indicates a multiplication by a power of the base. In bases 2 and 16, the exponent prefix can also be 'p' or 'P', in which case it introduces a binary exponent: it indicates a multiplication by a power of 2 (there is a difference only for base 16). The value of an exponent is always written in base 10. In base 2, the significand can start with '0b' or '0B', and in base 16, it can start with '0x' or '0X'. If the argument $base is 0, then the base is automatically detected as follows. If the significand starts with '0b' or '0B', base 2 is assumed. If the significand starts with '0x' or '0X', base 16 is assumed. Otherwise base 10 is assumed. Other allowable values for $base are 2 to 62. Note: The exponent must contain at least a digit. Otherwise the possible exponent prefix and sign are not part of the number (which ends with the significand). Similarly, if '0b', '0B', '0x' or '0X' is not followed by a binary/hexadecimal digit, then the subject sequence stops at the character '0'. Special data (for infinities and NaN) can be '@inf@' or '@nan@(n-char-sequence)', and if BASE <= 16, it can also be 'infinity', 'inf', 'nan' or 'nan(n-char-sequence)', all case insensitive. A 'n-char-sequence' is a non-empty string containing only digits, Latin letters and the underscore (0, 1, 2, ..., 9, a, b, ..., z, A, B, ..., Z, _). Note: one has an optional sign for all data, even NaN. The function returns a usual ternary value. Rmpfr_set_str_binary($rop, $str); Removed in Math-MPFR-3.30. Should have been removed long ago. Set $rop to the value of the binary number in $str, which has to be of the form +/-xxxx.xxxxxxEyy. The exponent is read in decimal, but is interpreted as the power of two to be multiplied by the mantissa. The mantissa length of $str has to be less or equal to the precision of $rop, otherwise an error occurs. If $str starts with 'N', it is interpreted as NaN (Not-a-Number); if it starts with 'I' after the sign, it is interpreted as infinity, with the corresponding sign. Rmpfr_set_inf($rop, $si); Rmpfr_set_nan($rop); Rmpfr_set_zero($rop, $si); # mpfr-3.0.0 and later only. Set the variable $rop to infinity or NaN (Not-a-Number) or zero respectively. In 'Rmpfr_set_inf' and 'Rmpfr_set_zero', the sign of $rop is positive if 2nd arg >= 0. Else the sign is negative. Rmpfr_swap($op1, $op2); Swap the values $op1 and $op2 efficiently. Warning: the precisions are exchanged too; in case the precisions are different, 'mpfr_swap' is thus not equivalent to three 'mpfr_set' calls using a third auxiliary variable. ################################################ COMBINED INITIALIZATION AND ASSIGNMENT NOTE: Do NOT use these functions if $rop has already been initialised. Use the Rmpfr_set* functions in the section 'ASSIGNMENT' (above). First read the section 'MEMORY MANAGEMENT' (above). $rop = Math::MPFR->new($arg); $rop = Math::MPFR::new($arg); $rop = new Math::MPFR($arg); Returns a Math::MPFR object with the value of $arg, rounded in the default rounding direction, with default precision. $arg can be either a number (signed integer, unsigned integer, signed fraction or unsigned fraction), a string that represents a numeric value, or an object (of type Math::GMPf, Math::GMPq, Math::GMPz, orMath::GMP) If $arg is a string, an optional additional argument that specifies the base of the number can be supplied to new(). Legal values for base are 0 and 2 to 62. If $arg is a string and no additional argument is supplied, the base will be deduced. See 'Rmpfr_set_str' above for an explanation of how that deduction is done. NOTE: If $arg is *both* an NV (floating point value) and PV (string), then the value specified by the PV (string) will be used. This is probably what you want (less likely so with perl-5.18.4 and earlier). However, there's no guaranteed way for the new() function to correctly tell and it's best to avoid passing such values, or to explicitly use the value you want by doing an Rmpfr_init() followed by the appropriate 'Rmpfr_set_*' function documented in the previous section. Or, if such exists, you could instead call the appropriate 'Rmpfr_init_set_*' function documented immediately below. Note that these functions (below) return a list of 2 values. ($rop, $inex) = Rmpfr_init_set ($op, $rnd); ($rop, $inex) = Rmpfr_init_set_nobless($op, $rnd); ($rop, $inex) = Rmpfr_init_set_ui ($ui, $rnd); ($rop, $inex) = Rmpfr_init_set_ui_nobless($ui, $rnd); ($rop, $inex) = Rmpfr_init_set_si ($si, $rnd); ($rop, $inex) = Rmpfr_init_set_si_nobless($si, $rnd); ($rop, $inex) = Rmpfr_init_set_d ($double, $rnd); ($rop, $inex) = Rmpfr_init_set_d_nobless($double, $rnd); ($rop, $inex) = Rmpfr_init_set_ld ($longdouble, $rnd); ($rop, $inex) = Rmpfr_init_set_ld_nobless($longdouble, $rnd); ($rop, $inex) = Rmpfr_init_set_float128 ($float128, $rnd); ($rop, $inex) = Rmpfr_init_set_float128_nobless($float128, $rnd); ($rop, $inex) = Rmpfr_init_set_f ($f, $rnd);# $f is a mpf object ($rop, $inex) = Rmpfr_init_set_f_nobless($f, $rnd);# $f is a mpf object ($rop, $inex) = Rmpfr_init_set_z ($z, $rnd);# $z is a mpz object ($rop, $inex) = Rmpfr_init_set_z_nobless($z, $rnd);# $z is a mpz object ($rop, $inex) = Rmpfr_init_set_q ($q, $rnd);# $q is a mpq object ($rop, $inex) = Rmpfr_init_set_q_nobless($q, $rnd);# $q is a mpq object ($rop, $inex) = Rmpfr_init_set_IV ($IV,$rnd);# $IV is $Config{ivtype} ($rop, $inex) = Rmpfr_init_set_IV_nobless($IV,$rnd);# $IV is $Config{ivtype} ($rop, $inex) = Rmpfr_init_set_NV ($NV,$rnd);# $NV is $Config{nvtype} ($rop, $inex) = Rmpfr_init_set_NV_nobless($NV,$rnd);# $NV is $Config{nvtype} Initialize $rop and set its value from the 1st arg, rounded to direction $rnd. The precision of $rop will be taken from the active default precision, as set by 'Rmpfr_set_default_prec'. ($rop, $si) = Rmpfr_init_set_str($str, $base, $rnd); ($rop, $si) = Rmpfr_init_set_str_nobless($str, $base, $rnd); Initialize $rop and set its value from $str in base $base, rounded to direction $rnd. If $str was a valid number, then $si will be set to 0. Else it will be set to -1. If $si is -1 : 1) the non-numeric flag (which was initialised to 0) will be incremented. You can query/clear/reset the value of the flag with (resp.) nnumflag()/clear_nnum()/set_nnum() - all of which are documented below (in "MISCELLANEOUS"); 2) A warning will be emitted if $Math::MPFR::NNW is set to 1 (default is 0). See 'Rmpfr_set_str' (above) and 'Rmpfr_inp_str' (below). ########## CONVERSION $str = Rmpfr_get_str($op, $base, $digits, $rnd); Returns a string of the form, eg, '8.3456712@2' which means '834.56712'. The third argument to Rmpfr_get_str() specifies the number of digits required to be output in the mantissa. (Trailing zeroes are removed.) If $digits is 0, the number of digits of the mantissa is chosen large enough so that re-reading the printed value with the same precision, assuming both output and input use rounding to nearest, will recover the original value of $op. $str will be set to 'Nan', '-Inf' or 'Inf' whenever $op is (respectively) a NaN, a negative infinity or a positive infinity. ($str, $si) = Rmpfr_deref2($op, $base, $digits, $rnd); Returns the mantissa to $str (as a string of digits, prefixed with a minus sign if $op is negative), and returns the exponent to $si. There's an implicit decimal point to the left of the first digit in $str. The third argument to Rmpfr_deref2() specifies the number of digits required to be output in the mantissa. If $digits is 0, the number of digits of the mantissa is chosen large enough so that re-reading the printed value with the same precision, assuming both output and input use rounding to nearest, will recover the original value of $op. Unlike Rmpfr_get_str() and Rmpfr_integer_string(), $str will be set to '@NaN@', '-@Inf@' or '@Inf@' whenever $op is (respectively) a NaN, a negative infinity or a positive infinity, as those are the strings that the mpfr library assigns. $str = Rmpfr_integer_string($op, $base, $rnd); Returns the truncated integer value of $op as a string. (No exponent is returned). For example, if $op contains the value 2.3145679e2, $str will be set to "231". $str will be set to 'Nan', '-Inf' or 'Inf' whenever $op is (respectively) a NaN, a negative infinity or a positive infinity. (This function is mainly to provide a simple means of getting 'sj' and 'uj' values on a 64-bit perl where the MPFR library does not support mpfr_get_uj and mpfr_get_sj functions - which may happen, for example, with libraries built with Microsoft Compilers.) $bool = Rmpfr_fits_ushort_p($op, $rnd); # fits in unsigned short $bool = Rmpfr_fits_sshort_p($op, $rnd); # fits in signed short $bool = Rmpfr_fits_uint_p($op, $rnd); # fits in unsigned int $bool = Rmpfr_fits_sint_p($op, $rnd); # fits in signed int $bool = Rmpfr_fits_ulong_p($op, $rnd); # fits in unsigned long $bool = Rmpfr_fits_slong_p($op, $rnd); # fits in signed long $bool = Rmpfr_fits_uintmax_p($op, $rnd); # fits in uintmax_t $bool = Rmpfr_fits_intmax_p($op, $rnd); # fits in intmax_t $bool = Rmpfr_fits_IV_p($op, $rnd); # fits in perl IV or UV Return non-zero if $op would fit in the respective data type, when rounded to an integer in the direction $rnd. $ui = Rmpfr_get_ui($op, $rnd); $si = Rmpfr_get_si($op, $rnd); $sj = Rmpfr_get_sj($op, $rnd); $uj = Rmpfr_get_uj($op, $rnd); $IV = Rmpfr_get_IV($op, $rnd); # $IV is $Config{ivtype} Convert $op to an 'unsigned long long', a 'signed long', a 'signed long long', an 'unsigned long long' or an 'IV' - after rounding it with respect to $rnd. If $op is NaN, the result is undefined. If $op is too big for the return type, it returns the maximum or the minimum of the corresponding C type, depending on the direction of the overflow. The flag erange is then also set. $double = Rmpfr_get_d($op, $rnd); $ld = Rmpfr_get_ld($op, $rnd); $f128 = Rmpfr_get_float128($op, $rnd);# nvtype is __float128 # && mpfr-4.0.0 or later # && mpfr lib built with # --enable-float128. $NV = Rmpfr_get_NV($op, $rnd); # double/long double/__float128 $float = Rmpfr_get_flt($op, $rnd); # mpfr-3.0.0 and later Rmpfr_get_LD($LD, $op, $rnd); # $LD is a Math::LongDouble object. Rmpfr_get_DECIMAL64($d64, $op, $rnd); # mpfr-3.1.0 or later && # mpfr lib built with # --enable-decimal-float # && D64=1 arg given to # Makefile.PL. $D64 is a # Math::Decimal64 object Rmpfr_get_FLOAT128($F128, $op, $rnd);# mpfr-4.0.0 and later && # mpfr library built with # --enable-float128. # $F128 is a Math::Float128 # object. Convert $op to a 'double', a 'long double', a __float128, an 'NV', a float, a Math::LongDouble object, a Math::Decimal64 object, or a Math::Float128 object using the rounding mode $rnd. $double = Rmpfr_get_d1($op); Convert $op to a double, using the default MPFR rounding mode (see function 'mpfr_set_default_rounding_mode'). $si = Rmpfr_get_z_exp($z, $op); # $z is a mpz object $si = Rmpfr_get_z_2exp($z, $op); # $z is a mpz object (Identical functions. Use either - 'get_z_exp' might one day be removed.) Puts the mantissa of $rop into $z, and returns the exponent $si such that $rop == $z * (2 ** $ui). $inex = Rmpfr_get_z($z, $op, $rnd); # $z is a mpz object. Convert $op to an mpz object ($z), after rounding it with respect to RND. If built against mpfr-3.0.0 or later, return the usual ternary value. (The function returns undef when using mpfr-2.x.x.) Croak with appropriate error message if $op is NaN or Inf. $inex = Rmpfr_get_f ($f, $op, $rnd); # $f is a Math::GMPf object. Convert $op to a 'mpf_t', after rounding it with respect to $rnd. When built against mpfr-3.0.0 or later, this function returns the usual ternary value. When built against earlier versions of mpfr, return zero if no error occurred. Croak with appropriate error message if $op is NaN or Inf. Rmpfr_get_q ($q, $op); # $q is a Math::GMPq object. Convert $op to a rational value. $q will be set to the exact value contained in $op - hence no need for a rounding argument. Croak with appropriate error message if $op is NaN or Inf. $d = Rmpfr_get_d_2exp ($exp, $op, $rnd); # $d is NV (double) $d = Rmpfr_get_ld_2exp ($exp, $op, $rnd); # $d is NV (long double) Set $exp and $d such that 0.5<=abs($d)<1 and $d times 2 raised to $exp equals $op rounded to double (resp. long double) precision, using the given rounding mode. If $op is zero, then a zero of the same sign (or an unsigned zero, if the implementation does not have signed zeros) is returned, and $exp is set to 0. If $op is NaN or an infinity, then the corresponding double precision (resp. long-double precision) value is returned, and $exp is undefined. $inex = Rmpfr_frexp($si, $rop, $op, $rnd); # mpfr-3.1.0 and later only Set $si and $rop such that 0.5<=abs($rop)<1 and $rop * (2 ** $si) equals $op rounded to the precision of $rop, using the given rounding mode. If $op is zero, then $rop is set to zero (of the same sign) and $exp is set to 0. If $op is NaN or an infinity, then $rop is set to the same value and the value of $exp is meaningless (and should be ignored). $ui1 = Rmpfr_get_str_ndigits($ui2, $ui3); # new with mpfr-4.1.0 Note: $ui2 must be in the range 2..62 (inclusive). Return the minimal integer $ui1 such that any number of precision $ui3 bits, when output with $ui1 digits in radix $ui2 with rounding to nearest, can be recovered exactly when read again, still with rounding to nearest. More precisely, we have $ui1 = 1 + ceil($ui3 * log(2) / log($ui2)), with $ui3 decremented by 1 if $ui2 is a power of 2. This function wraps mpfr_get_str_ndigits if mpfr version is 4.1.0 or later. Otherwise it calls Rmpfr_get_str_ndigits_alt, which does not require mpfr-4.1.0. $ui1 = Rmpfr_get_str_ndigits_alt($ui2, $ui3); Provided as a fallback (though it can also be called separately) for Rmpfr_get_str_ndigits when mpfr version is older than 4.1.0. Unlike Rmpfr_get_str_ndigits, this function does not require that $ui2 is in the range 2..62. ########## ARITHMETIC $inex = Rmpfr_add($rop, $op1, $op2, $rnd); $inex = Rmpfr_add_ui($rop, $op, $ui, $rnd); $inex = Rmpfr_add_si($rop, $op, $si1, $rnd); $inex = Rmpfr_add_d($rop, $op, $double, $rnd); $inex = Rmpfr_add_z($rop, $op, $z, $rnd); # $z is a mpz object. $inex = Rmpfr_add_q($rop, $op, $q, $rnd); # $q is a mpq object. Set $rop to 2nd arg + 3rd arg rounded in the direction $rnd. The return value is zero if $rop is exactly 2nd arg + 3rd arg, positive if $rop is larger than 2nd arg + 3rd arg, and negative if $rop is smaller than 2nd arg + 3rd arg. $inex = Rmpfr_sum($rop, \@ops, scalar(@ops), $rnd); @ops is an array consisting entirely of Math::MPFR objects. Set $rop to the sum of all members of @ops, rounded in the direction $rnd. $si is zero when the computed value is the exact value, and non-zero when this cannot be guaranteed, without giving the direction of the error as the other functions do. $inex = Rmpfr_sub($rop, $op1, $op2, $rnd); $inex = Rmpfr_sub_ui($rop, $op, $ui, $rnd); $inex = Rmpfr_sub_z($rop, $op, $z, $rnd); # $z is a mpz object. $inex = Rmpfr_z_sub($rop, $z, $op, $rnd); # mpfr-3.1.0 and later only $inex = Rmpfr_sub_q($rop, $op, $q, $rnd); # $q is a mpq object. $inex = Rmpfr_ui_sub($rop, $ui, $op, $rnd); $inex = Rmpfr_si_sub($rop, $si1, $op, $rnd); $inex = Rmpfr_sub_si($rop, $op, $si1, $rnd); $inex = Rmpfr_sub_d($rop, $op, $double, $rnd); $inex = Rmpfr_d_sub($rop, $double, $op, $rnd); Set $rop to 2nd arg - 3rd arg rounded in the direction $rnd. The return value is zero if $rop is exactly 2nd arg - 3rd arg, positive if $rop is larger than 2nd arg - 3rd arg, and negative if $rop is smaller than 2nd arg - 3rd arg. $inex = Rmpfr_mul($rop, $op1, $op2, $rnd); $inex = Rmpfr_mul_ui($rop, $op, $ui, $rnd); $inex = Rmpfr_mul_si($rop, $op, $si1, $rnd); $inex = Rmpfr_mul_d($rop, $op, $double, $rnd); $inex = Rmpfr_mul_z($rop, $op, $z, $rnd); # $z is a mpz object. $inex = Rmpfr_mul_q($rop, $op, $q, $rnd); # $q is a mpq object. Set $rop to 2nd arg * 3rd arg rounded in the direction $rnd. Return 0 if the result is exact, a positive value if $rop is greater than 2nd arg times 3rd arg, a negative value otherwise. $inex = Rmpfr_div($rop, $op1, $op2, $rnd); $inex = Rmpfr_div_ui($rop, $op, $ui, $rnd); $inex = Rmpfr_ui_div($rop, $ui, $op, $rnd); $inex = Rmpfr_div_si($rop, $op, $si1, $rnd); $inex = Rmpfr_si_div($rop, $si1, $op, $rnd); $inex = Rmpfr_div_d($rop, $op, $double, $rnd); $inex = Rmpfr_d_div($rop, $double, $op, $rnd); $inex = Rmpfr_div_z($rop, $op, $z, $rnd); # $z is a mpz object. $inex = Rmpfr_z_div($rop, $z, $op, $rnd); # $z is a mpz object. $inex = Rmpfr_div_q($rop, $op, $q, $rnd); # $q is a mpq object. $inex = Rmpfr_q_div($rop, $q, $op, $rnd); # $q is a mpq object. NOTE: The mpfr library does not provide mpfr_z_div and mpfr_q_div functions. Set $rop to 2nd arg / 3rd arg rounded in the direction $rnd. These functions return 0 if the division is exact, a positive value when $rop is larger than 2nd arg divided by 3rd arg, and a negative value otherwise. q_add_fr($q1, $q2, $op); # $q1, $q2 are mpq objects Set $q1 to the exact rational value of $q2 + $op q_sub_fr($q1, $q2, $op); # $q1, $q2 are mpq objects Set $q1 to the exact rational value of $q2 - $op q_mul_fr($q1, $q2, $op); # $q1, $q2 are mpq objects Set $q1 to the exact rational value of $q2 * $op q_div_fr($q1, $q2, $op); # $q1, $q2 are mpq objects Set $q1 to the exact rational value of $q2 / $op $si = Rmpfr_sqr($rop, $op, $rnd); Set $rop to the square of $op, rounded in direction $rnd. $inex = Rmpfr_sqrt($rop, $op, $rnd); $inex = Rmpfr_sqrt_ui($rop, $ui, $rnd); Set $rop to the square root of the 2nd arg rounded in the direction $rnd. Set $rop to NaN if 2nd arg is negative. Return 0 if the operation is exact, a non-zero value otherwise. $inex = Rmpfr_rec_sqrt($rop, $op, $rnd); Set $rop to $op ** (-1 / 2) rounded in the direction $rnd. Set $rop to +Inf if $op is 0, and 0 if $op is +Inf. Set $rop to NaN if $op is less than zero. $inex = Rmpfr_rec_root($rop, $op, $ui, $rnd); NOTE: There is no such mpfr function as mpfr_rec_root. This function originally provided as a perl implementation by Vincent Lefevre - and rewritten by sisyphus as an XSub. (See https://sympa.inria.fr/sympa/arc/mpfr/2016-12/msg00032.html) Set $rop to $op ** (-1 / $ui) rounded in the direction $rnd. May not correctly handle overflow or underflow. $inex = Rmpfr_cbrt($rop, $op, $rnd); Set $rop to the cubic root of $op, rounded in the direction $rnd. $inex = Rmpfr_root($rop, $op, $ui $rnd); Deprecated in mpfr-4.0.0 - use Rmpfr_rootn_ui with mpfr-4 and later. This function will croak with "deprecation" warning if Math::MPFR has been built against mpfr-4.x.x or later. Set $rop to the $ui'th root of $op, rounded in the direction $rnd. Return 0 if the operation is exact, a non-zero value otherwise. $inex = Rmpfr_rootn_ui($rop, $op, $ui $rnd); # mpfr-4.0.0 and later Same as Rmpfr_root except that $rop is set to +0 (instead of -0) when $op is -0 and $ui is even. This function (and Rmpfr_cbrt) agree with the rootn function of the IEEE 754-2008 standard (Section 9.2). $inex = Rmpfr_pow_ui($rop, $op, $ui, $rnd); $inex = Rmpfr_pow_uj($rop, $op, $uj, $rnd); $inex = Rmpfr_pow_si($rop, $op, $si, $rnd); $inex = Rmpfr_pow_sj($rop, $op, $sj, $rnd); $inex = Rmpfr_pown($rop, $op, $sj, $rnd); # same as Rmpfr_pow_sj $inex = Rmpfr_ui_pow_ui($rop, $ui, $ui, $rnd); $inex = Rmpfr_ui_pow($rop, $ui, $op, $rnd); $inex = Rmpfr_pow ($rop, $op1, $op2, $rnd); $inex = Rmpfr_pow_z ($rop, $op, $z, $rnd); # $z is a mpz object $inex = Rmpfr_pow_IV($rop, $op, $IV, $rnd); # $IV is $Config{ivtype} Set $rop to 2nd arg raised to 3rd arg, rounded to the direction $rnd with the precision of $rop. Return zero if the result is exact, a positive value when the result is greater than 2nd arg to the power 3rd arg, and a negative value when it is smaller. See the MPFR documentation for documentation regarding special cases (ie when nan or signed inf/zero values are involved). $inex = Rmpfr_powr($rop, $op1, $op2, $rnd); Corresponds to the 'powr' function from IEEE 754: $rop = exp($op2 * log($op1)) rounded to the direction $rnd with the precision of $rop. $inex = Rmpfr_compound_si($rop, $op, $si, $rnd); $rop = ($op + 1) ** $si, rounded according to $rnd, to the precision of $rop. When $si is 0 and $op is NaN or is >= -1, $rop is set to 1. $inex = Rmpfr_neg($rop, $op, $rnd); Set $rop to -$op rounded in the direction $rnd. Just changes the sign if $rop and $op are the same variable. $si = Rmpfr_abs($rop, $op, $rnd); Set $rop to the absolute value of $op, rounded in the direction $rnd. Return 0 if the result is exact, a positive value if $rop is larger than the absolute value of $op, and a negative value otherwise. $inex = Rmpfr_dim($rop, $op1, $op2, $rnd); Set $rop to the positive difference of $op1 and $op2, i.e., $op1 - $op2 rounded in the direction $rnd if $op1 > $op2, and +0 otherwise. $rop is set to NaN when $op1 or $op2 is NaN. $inex = Rmpfr_mul_2exp($rop, $op, $ui, $rnd); $inex = Rmpfr_mul_2ui($rop, $op, $ui, $rnd); $inex = Rmpfr_mul_2si($rop, $op, $si, $rnd); Set $rop to 2nd arg times 2 raised to 3rd arg rounded to the direction $rnd. Just increases the exponent by 3rd arg when $rop and 2nd arg are identical. Return zero when $rop = 2nd arg, a positive value when $rop > 2nd arg, and a negative value when $rop < 2nd arg. Note: The 'Rmpfr_mul_2exp' function is defined for compatibility reasons; you should use 'Rmpfr_mul_2ui' (or 'Rmpfr_mul_2si') instead. $inex = Rmpfr_div_2exp($rop, $op, $ui, $rnd); $inex = Rmpfr_div_2ui($rop, $op, $ui, $rnd); $inex = Rmpfr_div_2si($rop, $op, $si, $rnd); Set $rop to 2nd arg divided by 2 raised to 3rd arg rounded to the direction $rnd. Just decreases the exponent by 3rd arg when $rop and 2nd arg are identical. Return zero when $rop = 2nd arg, a positive value when $rop > 2nd arg, and a negative value when $rop < 2nd arg. Note: The 'Rmpfr_div_2exp' function is defined for compatibility reasons; you should use 'Rmpfr_div_2ui' (or 'Rmpfr_div_2si') instead. ########## COMPARISON $si = Rmpfr_cmp($op1, $op2); $si = Rmpfr_cmpabs($op1, $op2); $si = Rmpfr_cmpabs_ui($op, $ui); # requires mpfr-4.1.0 and later $si = Rmpfr_cmp_ui($op, $ui); $si = Rmpfr_cmp_si($op, $si); $si = Rmpfr_cmp_d($op, $double); $si = Rmpfr_cmp_ld($op, $ld); # long double $si = Rmpfr_cmp_float128($op, $float128); # __float128 $si = Rmpfr_cmp_z($op, $z); # $z is a mpz object $si = Rmpfr_cmp_q($op, $q); # $q is a mpq object $si = Rmpfr_cmp_f($op, $f); # $f is a mpf object $si = Rmpfr_cmp_IV($op, $iv); # $iv is $Config{ivtype} $si = Rmpfr_cmp_NV($op, $nv); # $nv is $Config{nvtype} Compare 1st and 2nd args. In the case of 'Rmpfr_cmpabs()' and 'Rmpfr_cmpabs_ui' compare the absolute values of the 2 args. Return a positive value if 1st arg > 2nd arg, zero if 1st arg = 2nd arg, and a negative value if 1st arg < 2nd arg. Both args are considered to their full own precision, which may differ. In case 1st and 2nd args are of same sign but different, the absolute value returned is one plus the absolute difference of their exponents. If one of the operands is NaN (Not-a-Number), return zero and set the erange flag. NOTE: 1) Rmpfr_cmp_IV() requires that the 2nd argument has its IOK flag set, and Rmpfr_cmp_NV() requires that the 2nd argument has its NOK flag set. Otherwise these functions croak. Suggestion: first check the status of the flag using IOK_flag($iv) or NOK_flag($nv),which return a non-zero value if and only if the flag in question is set. 2) Rmpfr_cmp_IV handles both signed and unsigned IV args. $si = fr_cmp_q_rounded($op, $q, $rnd); # $q is a mpq object Convert $q to an mpfr object of current default precision, rounded in accordance with the value specified by $rnd. Then compare $op with this mpfr object, according to the rules specified for Rmpfr_cmp (above). $bool = Rmpfr_total_order_p($op1, $op2); # new with mpfr-4.1.0 This function implements the totalOrder predicate from IEEE 754-2008, where -NaN < -Inf < negative finite numbers < -0 < +0 < positive finite numbers < +Inf < +NaN. It returns a non-zero value (true) when X is smaller than or equal to Y for this order relation, and zero (false) otherwise. Contrary to 'Rmpfr_cmp($x, $y)', which returns a ternary value, 'Rmpfr_total_order_p' returns a binary value (zero or non-zero). In particular, 'Rmpfr_total_order_p($x, $x)' returns true, 'Rmpfr_total_order_p(-0, +0)' returns true and 'Rmpfr_total_order_p(+0, -0)' returns false. The sign bit of NaN also matters. This function falls back to our own implementation if the mpfr version is older than 4.1.0 (because, in that case, mpfr_total_order_p is unavailable). $si = Rmpfr_cmp_ui_2exp($op, $ui, $si); $si = Rmpfr_cmp_si_2exp($op, $si, $si); Compare 1st arg and 2nd arg multiplied by two to the power 3rd arg. $bool = Rmpfr_eq($op1, $op2, $ui); The mpfr library function mpfr_eq may change in future releases of the mpfr library (post 2.4.0). If that happens, the change will also be reflected in Rmpfr_eq. Return non-zero if the first $ui bits of $op1 and $op2 are equal, zero otherwise. I.e., tests if $op1 and $op2 are approximately equal. $bool = Rmpfr_nan_p($op); Return non-zero if $op is Not-a-Number (NaN), zero otherwise. $bool = Rmpfr_inf_p($op); Return non-zero if $op is plus or minus infinity, zero otherwise. $bool = Rmpfr_number_p($op); Return non-zero if $op is an ordinary number, i.e. neither Not-a-Number nor plus or minus infinity. $bool = Rmpfr_zero_p($op); Return non-zero if $op is zero. Else return 0. $bool = Rmpfr_regular_p($op); # mpfr-3.0.0 and later only Return non-zero if $op is a regular number (i.e. neither NaN, nor an infinity nor zero). Return zero otherwise. Rmpfr_reldiff($rop, $op1, $op2, $rnd); Compute the relative difference between $op1 and $op2 and store the result in $rop. This function does not guarantee the exact rounding on the relative difference; it just computes abs($op1-$op2)/$op1, using the rounding mode $rnd for all operations. $si = Rmpfr_sgn($op); Return a positive value if op > 0, zero if $op = 0, and a negative value if $op < 0. Its result is not specified when $op is NaN (Not-a-Number). $bool = Rmpfr_greater_p($op1, $op2); Return non-zero if $op1 > $op2, zero otherwise. $bool = Rmpfr_greaterequal_p($op1, $op2); Return non-zero if $op1 >= $op2, zero otherwise. $bool = Rmpfr_less_p($op1, $op2); Return non-zero if $op1 < $op2, zero otherwise. $bool = Rmpfr_lessequal_p($op1, $op2); Return non-zero if $op1 <= $op2, zero otherwise. $bool = Rmpfr_lessgreater_p($op1, $op2); Return non-zero if $op1 < $op2 or $op1 > $op2 (i.e. neither $op1, nor $op2 is NaN, and $op1 <> $op2), zero otherwise (i.e. $op1 and/or $op2 are NaN, or $op1 = $op2). $bool = Rmpfr_equal_p($op1, $op2); Return non-zero if $op1 = $op2, zero otherwise (i.e. $op1 and/or $op2 are NaN, or $op1 <> $op2). $bool = Rmpfr_unordered_p($op1, $op2); Return non-zero if $op1 or $op2 is a NaN (i.e. they cannot be compared), zero otherwise. ####### SPECIAL $inex = Rmpfr_log($rop, $op, $rnd); $inex = Rmpfr_log_ui($rop, $ui, $rnd); # mpfr-4.0.0 & later only $inex = Rmpfr_log2($rop, $op, $rnd); $inex = Rmpfr_log10($rop, $op, $rnd); Set $rop to the natural logarithm of $op, the natural logarithm of $ui, log2($op) or log10($op), respectively, rounded in the direction $rnd. $inex = Rmpfr_exp($rop, $op, $rnd); $inex = Rmpfr_exp2($rop, $op, $rnd); $inex = Rmpfr_exp10($rop, $op, $rnd); Set rop to the exponential of op, to 2 power of op or to 10 power of op, respectively, rounded in the direction rnd. $inex = Rmpfr_sin($rop $op, $rnd); $inex = Rmpfr_cos($rop, $op, $rnd); $inex = Rmpfr_tan($rop, $op, $rnd); Set $rop to the sine/cosine/tangent respectively of $op, rounded to the direction $rnd with the precision of $rop. Return 0 if the result is exact (this occurs in fact only when $op is 0 i.e. the sine is 0, the cosine is 1, and the tangent is 0). Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. $si = Rmpfr_sin_cos($rop1, $rop2, $op, $rnd); Set simultaneously $rop1 to the sine of $op and $rop2 to the cosine of $op, rounded to the direction $rnd with their corresponding precisions. Return 0 if both results are exact. $inex = Rmpfr_cosu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_sinu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_tanu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only Set $rop to the cosine (resp. sine and tangent) of $op multiplied by 2*Pi and divided by $ui. For example, if $ui equals 360, one gets the cosine (resp. sine and tangent) for $op in degrees. For 'Rmpfr_cosu', when $op multiplied by 2 and divided by $ui is a half-integer, the result is +0, following IEEE 754-2019 (cosPi), so that the function is even. For 'Rmpfr_sinu', when $op multiplied by 2 and divided by $ui is an integer, the result is zero with the same sign as $op, following IEEE 754-2019 (sinPi), so that the function is odd. Similarly, the function 'Rmpfr_tanu' follows IEEE 754-2019 (tanPi). $inex = Rmpfr_acosu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_asinu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_atanu($rop, $op, $ui, $rnd); # mpfr-4.2.0 and later only Set $rop to X multiplied by $ui and divided by 2*Pi, where X is the arc-cosine (resp. arc-sine and arc-tangent) of $op. For example, if $ui equals 360, mpfr_acosu yields the arc-cosine in degrees. $inex = Rmpfr_cospi($rop, $op, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_sinpi($rop, $op, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_tanpi($rop, $op, $rnd); # mpfr-4.2.0 and later only Set $rop to the cosine (resp. sine and tangent) of $op multiplied by Pi. See the description of 'Rmpfr_sinu', 'Rmpfr_cosu' and 'Rmpfr_tanu' for special values. $inex = Rmpfr_acospi($rop, $op, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_asinpi($rop, $op, $rnd); # mpfr-4.2.0 and later only $inex = Rmpfr_atanpi($rop, $op, $rnd); # mpfr-4.2.0 and later only $rop = acos($op)/Pi, resp. asin($op)/Pi and atan($op)/Pi. $inex = Rmpfr_sinh_cosh($rop1, $rop2, $op, $rnd); Set simultaneously $rop1 to the hyperbolic sine of $op and $rop2 to the hyperbolic cosine of $op, rounded in the direction $rnd with the corresponding precision of $rop1 and $rop2 which must be different variables. Return 0 if both results are exact. $inex = Rmpfr_acos($rop, $op, $rnd); $inex = Rmpfr_asin($rop, $op, $rnd); $inex = Rmpfr_atan($rop, $op, $rnd); Set $rop to the arc-cosine, arc-sine or arc-tangent of $op, rounded to the direction $rnd with the precision of $rop. Return 0 if the result is exact. Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. $inex = Rmpfr_atan2($rop, $op1, $op2, $rnd); Set $rop to the tangent of $op1/$op2, rounded to the direction $rnd with the precision of $rop. Return 0 if the result is exact. Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. See the MPFR documentation for details regarding special cases. $inex = Rmpfr_atan2u($rop, $op1, $op2, $ui, $rnd); Same as taking the Rmpfr_atan2() result and multiplying it by $ui/(2*Pi). $inex = Rmpfr_atan2pi($rop, $op1, $op2, $rnd); Same as Rmpfr_atan2u() with $ui = 2. $inex = Rmpfr_cosh($rop, $op, $rnd); $inex = Rmpfr_sinh($rop, $op, $rnd); $inex = Rmpfr_tanh($rop, $op, $rnd); Set $rop to the hyperbolic cosine/hyperbolic sine/hyperbolic tangent respectively of $op, rounded to the direction $rnd with the precision of $rop. Return 0 if the result is exact (this occurs in fact only when $op is 0 i.e. the result is 1). Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. $inex = Rmpfr_acosh($rop, $op, $rnd); $inex = Rmpfr_asinh($rop, $op, $rnd); $inex = Rmpfr_atanh($rop, $op, $rnd); Set $rop to the inverse hyperbolic cosine, sine or tangent of $op, rounded to the direction $rnd with the precision of $rop. Return 0 if the result is exact. $inex = Rmpfr_sec ($rop, $op, $rnd); $inex = Rmpfr_csc ($rop, $op, $rnd); $inex = Rmpfr_cot ($rop, $op, $rnd); Set $rop to the secant of $op, cosecant of $op, cotangent of $op, rounded in the direction RND. Return 0 if the result is exact. Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. $inex = Rmpfr_sech ($rop, $op, $rnd); $inex = Rmpfr_csch ($rop, $op, $rnd); $inex = Rmpfr_coth ($rop, $op, $rnd); Set $rop to the hyperbolic secant of $op, cosecant of $op, cotangent of $op, rounded in the direction RND. Return 0 if the result is exact. Return a negative value if the result is less than the actual value. Return a positive result if the return is greater than the actual value. $inex = Rmpfr_fac_ui($rop, $ui, $rnd); Set $rop to the factorial of $ui, rounded to the direction $rnd with the precision of $rop. $inex = Rmpfr_log1p ($rop, $op, $rnd); $inex = Rmpfr_log2p1 ($rop, $op, $rnd); $inex = Rmpfr_log10p1($rop, $op, $rnd); In Rmpfr_log1p set $rop = log( $op + 1). In Rmpfr_log2p1 set $rop = log2( $op + 1). In Rmpfr_log10p1 set $rop = log10($op + 1). In all three cases, round the result in the direction $rnd to the precision of $rop. $inex = Rmpfr_expm1 ($rop, $op, $rnd); $inex = Rmpfr_exp2m1 ($rop, $op, $rnd); $inex = Rmpfr_exp10m1($rop, $op, $rnd); In Rmpfr_expm1, set $rop to the exponential of $op followed by a subtraction of 1. $rop = (e ** $op) - 1. In Rmpfr_exp2p1, set $rop = (2 ** $op) - 1. In Rmpfr_exp10p1, set $rop = (10 ** $op) - 1. For all three, the result is rounded to the direction $rnd with the precision of $rop. $inex = Rmpfr_fma($rop, $op1, $op2, $op3, $rnd); Set $rop to $op1 * $op2 + $op3, rounded to the direction $rnd. $inex = Rmpfr_fmma($rop, $op1, $op2, $op3, $op4, $rnd); NOTE: Needs mpfr-4.0.0 or later Set $rop to $op1 * $op2 + $op3 * $op4, rounded to the direction $rnd. $inex = Rmpfr_fms($rop, $op1, $op2, $op3, $rnd); Set $rop to $op1 * $op2 - $op3, rounded to the direction $rnd. $inex = Rmpfr_fmms($rop, $op1, $op2, $op3, $op4, $rnd); NOTE: Needs mpfr-4.0.0 or later Set $rop to $op1 * $op2 - $op3 * $op4, rounded to the direction $rnd. $inex = Rmpfr_agm($rop, $op1, $op2, $rnd); Set $rop to the arithmetic-geometric mean of $op1 and $op2, rounded to the direction $rnd with the precision of $rop. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_hypot ($rop, $op1, $op2, $rnd); Set $rop to the Euclidean norm of $op1 and $op2, i.e. the square root of the sum of the squares of $op1 and $op2, rounded in the direction $rnd. Special values are currently handled as described in Section F.9.4.3 of the ISO C99 standard, for the hypot function (note this may change in future versions): If $op1 or $op2 is an infinity, then plus infinity is returned in $rop, even if the other number is NaN. $inex = Rmpfr_ai($rop, $op, $rnd); # mpfr-3.0.0 and later only Set $rop to the value of the Airy function Ai on $op, rounded in the direction $rnd. When $op is NaN, $rop is always set to NaN. When $op is +Inf or -Inf, $rop is +0. The current implementation is not intended to be used with large arguments. It works with $op typically smaller than 500. For larger arguments, other methods should be used and will be implemented soon. $inex = Rmpfr_const_log2($rop, $rnd); Set $rop to the logarithm of 2 rounded to the direction $rnd with the precision of $rop. This function stores the computed value to avoid another calculation if a lower or equal precision is requested. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_const_pi($rop, $rnd); Set $rop to the value of Pi rounded to the direction $rnd with the precision of $rop. This function uses the Borwein, Borwein, Plouffe formula which directly gives the expansion of Pi in base 16. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_const_euler($rop, $rnd); Set $rop to the value of Euler's constant 0.577... rounded to the direction $rnd with the precision of $rop. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. inex = Rmpfr_const_catalan($rop, $rnd); Set $rop to the value of Catalan's constant 0.915... rounded to the direction $rnd with the precision of $rop. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. Rmpfr_free_cache(); Free the cache used by the functions computing constants if needed (currently 'mpfr_const_log2', 'mpfr_const_pi' and 'mpfr_const_euler'). Rmpfr_free_cache2($ui); # mpfr-4.0.0 and later only Free various caches and pools used by MPFR internally, as specified by $ui, which is a set of flags: a) those local to the current thread if flag MPFR_FREE_LOCAL_CACHE is set; b) those shared by all threads if flag MPFR_FREE_GLOBAL_CACHE is set. The other bits of $ui are currently ignored and are reserved for future use; they should be zero. Note: Rmpfr_free_cache2(MPFR_FREE_LOCAL_CACHE|MPFR_FREE_GLOBAL_CACHE) is currently equivalent to mpfr_free_cache(). Rmpfr_free_pool() # mpfr-4.0.0 and later only Free the pools used by mpfr internally. Note: This function is automatically called after the thread-local caches are freed (with mpfr_free_cache or mpfr_free_cache2). $inex = Rmpfr_beta($rop, $op1, $op2, $rnd); # mpfr-4.0.0 & # later only Set $rop to the beta function at $op1, $op2, rounded according to $rnd. $inex = Rmpfr_gamma($rop, $op, $rnd); $inex = Rmpfr_lngamma($rop, $op, $rnd); Set $rop to the value of the Gamma function on $op (and, respectively, its natural logarithm) rounded to the direction $rnd. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. 'Rmpfr_gamma' sets $rop to NaN when $op is negative. $inex = Rmpfr_gamma_inc($rop, $op1, $op2, $rnd); # mpfr-4.0.0 & # later only Set $rop to the value of the incomplete Gamma function on $op1 and $op2, rounded in the direction $rnd. When $op2 is zero and $op1 is a negative value, $rop is set to NaN. Note: the current implementation is slow for large values of $rop and $op, in which case some internal overflow might also occur. ($signp, $si) = Rmpfr_lgamma ($rop, $op, $rnd); Set $rop to the value of the logarithm of the absolute value of the Gamma function on $op, rounded in the direction $rnd. The sign (1 or -1) of Gamma($op) is returned in $signp. When $op is an infinity or a non-positive integer, +Inf is returned. When $op is NaN, -Inf or a negative integer, $signp is undefined, and when $op is 0, $signp is the sign of the zero. $inex = Rmpfr_digamma ($rop, $op, $rnd); # mpfr-3.0.0 and later only Set $rop to the value of the Digamma (sometimes also called Psi) function on $op, rounded in the direction $rnd. When $op is a negative integer, set $rop to NaN. $inex = Rmpfr_zeta($rop, $op, $rnd); $inex = Rmpfr_zeta_ui($rop, $ul, $rnd); Set $rop to the value of the Riemann Zeta function on 2nd arg, rounded to the direction $rnd. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_erf($rop, $op, $rnd); Set $rop to the value of the error function on $op, rounded to the direction $rnd. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_erfc($rop, $op, $rnd); Set $rop to the complementary error function on $op, rounded to the direction $rnd. Return zero if $rop is exact, a positive value if $rop is larger than the exact value, or a negative value if $rop is less than the exact value. $inex = Rmpfr_j0 ($rop, $op, $rnd); $inex = Rmpfr_j1 ($rop, $op, $rnd); $inex = Rmpfr_jn ($rop, $si2, $op, $rnd); Set $rop to the value of the first order Bessel function of order 0, 1 and $si2 on $op, rounded in the direction $rnd. When $op is NaN, $rop is always set to NaN. When $op is plus or minus Infinity, $rop is set to +0. When $op is zero, and $si2 is not zero, $rop is +0 or -0 depending on the parity and sign of $si2, and the sign of $op. $inex = Rmpfr_y0 ($rop, $op, $rnd); $inex = Rmpfr_y1 ($rop, $op, $rnd); $inex = Rmpfr_yn ($rop, $si2, $op, $rnd); Set $rop to the value of the second order Bessel function of order 0, 1 and $si2 on $op, rounded in the direction $rnd. When $op is NaN or negative, $rop is always set to NaN. When $op is +Inf, $rop is +0. When $op is zero, $rop is +Inf or -Inf depending on the parity and sign of $si2. $inex = Rmpfr_eint ($rop, $op, $rnd) Set $rop to the exponential integral of $op, rounded in the direction $rnd. See the MPFR documentation for details. As of mpfr-4.0.0 Rmpfr_eint() returns the value of the E1/eint1 function for negative input. (With previous versions of mpfr NaN was returned for negative argument.) $inex = Rmpfr_li2 ($rop, $op, $rnd); Set $rop to real part of the dilogarithm of $op, rounded in the direction $rnd. The dilogarithm function is defined here as the integral of -log(1-t)/t from 0 to x. $inex = Rmpfr_dot ($rop, \@op1, \@op2, $ui, $rnd); # mpfr-4.1.0 & # later only Set $rop to the dot product of elements of @op1 by those of @op2, whose common size is $ui (== scalar @op1), correctly rounded in the direction $rnd. This function is experimental, and does not yet handle intermediate overflows and underflows. ############# I-O FUNCTIONS $ui = Rmpfr_out_str([$prefix,] $op, $base, $digits, $round [, $suffix]); BEST TO USE TRmpfr_out_str INSTEAD Output $op to STDOUT, as a string of digits in base $base, rounded in direction $round. $base may be in the range 2 to 62 (or -36..-2, 2 .. 62 if Math::MPFR has been built against mpfr-4.1.0 or later). Print $digits significant digits exactly, or if $digits is 0, enough digits so that $op can be read back exactly (see Rmpfr_get_str). In addition to the significant digits, a decimal point at the right of the first digit and a trailing exponent in base 10, in the form 'eNNN', are printed If $base is greater than 10, '@' will be used instead of 'e' as exponent delimiter. The optional arguments, $prefix and $suffix, are strings that will be prepended/appended to the mpfr_out_str output. Return the number of bytes written (not counting those contained in $suffix and $prefix), or if an error occurred, return 0. (Note that none, one or both of $prefix and $suffix can be supplied.) $ui = TRmpfr_out_str([$prefix,] $stream, $base, $digits, $op, $round [, $suffix]); As for Rmpfr_out_str, except that there's the capability to print to somewhere other than STDOUT. Note that the order of the args is different (to match the order of the mpfr_out_str args). To print to STDERR: TRmpfr_out_str(*stderr, $base, $digits, $op, $round); To print to an open filehandle (let's call it $fh): TRmpfr_out_str(\*$fh, $base, $digits, $op, $round); $ui = Rmpfr_inp_str($rop, $base, $round); BEST TO USE TRmpfr_inp_str INSTEAD. Input a string in base $base from STDIN, rounded in direction $round, and put the read float in $rop. The string is of the form 'M@N' or, if the base is 10 or less, alternatively 'MeN' or 'MEN', or, if the base is 16, alternatively 'MpB' or 'MPB'. 'M' is the mantissa in the specified base, 'N' is the exponent written in decimal for the specified base, and in base 16, 'B' is the binary exponent written in decimal (i.e. it indicates the power of 2 by which the mantissa is to be scaled). The argument $base may be in the range 2 to 62. Special values can be read as follows (the case does not matter): '@NaN@', '@Inf@', '+@Inf@' and '-@Inf@', possibly followed by other characters; if the base is smaller or equal to 16, the following strings are accepted too: 'NaN', 'Inf', '+Inf' and '-Inf'. Return the number of bytes read, or if non-numeric characters were encountered in the input, return 0. If 0 is returned: 1) the non-numeric flag (which was initialised to 0) will be incremented. You can query/clear/reset the value of the flag with (resp.) nnumflag()/clear_nnum()/set_nnum() - all of which are documented below; 2) A warning will be emitted if $Math::MPFR::NNW is set to 1 (default is 0). $ui = TRmpfr_inp_str($rop, $stream, $base, $round); As for Rmpfr_inp_str, except that there's the capability to read from somewhere other than STDIN. To read from STDIN: TRmpfr_inp_str($rop, *stdin, $base, $round); To read from an open filehandle (let's call it $fh): TRmpfr_inp_str($rop, \*$fh, $base, $round); Rmpfr_dump($op); Output "$op\n" on stdout in base 2. As with 'Rmpfr_print_binary' the exponent is in base 10. $si = Rmpfr_fpif_export ($stream, $op); # Needs mpfr-4.0.0 $si = Rmpfr_fpif_export ($op, $stream); # Needs mpfr-4.0.0 Note: These function are experimental and their interface might change in future versions of mpfr. Export/import the number $op to/from the stream $stream in a floating-point interchange format. In particular one can export on a 32-bit computer and import on a 64-bit computer, or export on a little-endian computer and import on a big-endian computer. The precision of OP is stored too. The import function fails if the precision (which is read from the stream) is greater than MPFR_PREC_MAX. Return 0 if the export/import was successful. ########## EXCEPTIONS $inex = Rmpfr_subnormalize ($op, $si, $rnd); This function rounds $op emulating subnormal number arithmetic. See the MPFR documentation for mpfr_subnormalize at: www.mpfr.org/mpfr-current/mpfr.html#Function-and-Type-Index $si = Rmpfr_get_emin(); $si = Rmpfr_get_emax(); Return to $si the (current) smallest and largest exponents allowed for a floating-point variable. $si = Rmpfr_get_emin_min(); $si = Rmpfr_get_emin_max(); $si = Rmpfr_get_emax_min(); $si = Rmpfr_get_emax_max(); Return to $si the minimum and maximum of the smallest and largest exponents allowed for 'mpfr_set_emin' and 'mpfr_set_emax'. These values are implementation dependent $bool = Rmpfr_set_emin($si); $bool = Rmpfr_set_emax($si); Set the smallest and largest exponents allowed for a floating-point variable. Return a non-zero value when $si is not in the range of exponents accepted by the implementation (in that case the smallest or largest exponent is not changed), and zero otherwise. If the user changes the exponent range, it is her/his responsibility to check that all current floating-point variables are in the new allowed range (for example using 'Rmpfr_check_range', otherwise the subsequent behaviour will be undefined, in the sense of the ISO C standard. $inex = Rmpfr_check_range($op, $si, $rnd); This function assumes that $op is the correctly rounded value of some real value X in the direction $rnd and some extended exponent range, and that $si is the corresponding ternary value. Thus $si is negative if $op is smaller than X, positive if $op is larger than X, and zero if $op equals X. This function modifies $op if needed to be in the current range of acceptable values. It generates an underflow or an overflow if the exponent of $op is outside the current allowed range; the value of $si may be used to avoid a double rounding. This function returns zero if the new value of $op equals the exact one X, a positive value if that new value is larger than X, and a negative value if it is smaller than X. Note that unlike most functions, the new result $op is compared to the (unknown) exact one X, not the input value $op, i.e., the ternary value is propagated. Note: If $op is an infinity and $inex is different from zero (i.e., if the rounded result is an inexact infinity), then the overflow flag is set. Rmpfr_set_underflow(); Rmpfr_set_overflow(); Rmpfr_set_nanflag(); Rmpfr_set_inexflag(); Rmpfr_set_erangeflag(); Rmpfr_set_divby0(); # mpfr-3.1.0 and later only Rmpfr_clear_underflow(); Rmpfr_clear_overflow(); Rmpfr_clear_nanflag(); Rmpfr_clear_inexflag(); Rmpfr_clear_erangeflag(); Rmpfr_clear_divby0(); # mpfr-3.1.0 and later only Set/clear the underflow, overflow, invalid, inexact, erange and divide-by-zero flags. Rmpfr_clear_flags(); Clear all global flags (underflow, overflow, inexact, invalid, erange and divide-by-zero). $bool = Rmpfr_underflow_p(); $bool = Rmpfr_overflow_p(); $bool = Rmpfr_nanflag_p(); $bool = Rmpfr_inexflag_p(); $bool = Rmpfr_erangeflag_p(); $bool = Rmpfr_divby0_p(); # mpfr-3.1.0 and later only Return the corresponding (underflow, overflow, invalid, inexact, erange, divide-by-zero) flag, which is non-zero if the flag is set. Rmpfr_flags_clear($mask); # needs mpfr-4.0.0 or later Rmpfr_flags_set($mask); # needs mpfr-4.0.0 or later $mask2 = Rmpfr_flags_test($mask); # needs mpfr-4.0.0 or later $mask = Rmpfr_flags_save(); # needs mpfr-4.0.0 or later Rmpfr_flags_restore($mask1, $mask2); # needs mpfr-4.0.0 or later $mask is an integer value resulting from OR'ing (or adding) any of the following constants together: MPFR_FLAGS_UNDERFLOW MPFR_FLAGS_OVERFLOW MPFR_FLAGS_NAN MPFR_FLAGS_INEXACT MPFR_FLAGS_ERANGE MPFR_FLAGS_DIVBY0 MPFR_FLAGS_ALL MPFR_FLAGS_ALL is the same as all of those constants OR'ed (added) together. Examples: Clear the divby0 and nan flags, without affecting the status of any other flags: Rmpfr_flags_clear(MPFR_FLAGS_DIVBY0|MPFR_FLAGS_NAN); Set the underflow and erange flags, without affecting the status of any other flags: Rmpfr_flags_set(MPFR_FLAGS_UNDERFLOW|MPFR_FLAGS_ERANGE); Test the status of specific flags, ignoring all other flags. This particular example will set $mask to the value of MPFR_FLAGS_NAN if the nan flag is set - else $mask will be set to zero: $mask = Rmpfr_flags_test(MPFR_FLAGS_UNDERFLOW); Return all flags: $mask = Rmpfr_flags_save(); Equivalently, this can be done with: $mask = Rmpfr_flags_test(MPFR_FLAGS_ALL); Set flags specified in $mask2 to the state specified in $mask1, For this example, the overflow flag will be set && the nan flag will be cleared. The underflow flag will remain untouched. $mask1 = MPFR_FLAGS_UNDERFLOW | MPFR_FLAGS_OVERFLOW; $mask2 = MPFR_FLAGS_OVERFLOW | MPFR_FLAGS_NAN; Rmpfr_flags_restore($mask1, $mask2); ############# MISCELLANEOUS $str = doubletoa($double [, $x]); # Available only when # $Config{nvsize} == 8. # Else use nvtoa(). Sets $str to the value of $double. $str will appear in standard decimal format such that the condition ($str == $double) is true. The grisu3 algorithm used by this function, whilst very quick, will fail for about 0.5% of values. When this happens doubletoa will (by default) fall back to using nvtoa() - which is slower, but reliable. Alternatively, providing a second argument to doubletoa (any scalar will do) will ensure that it falls back to returning sprintf("%.17g", $double).This will be an accurate return, and it will be quicker than the nvtoa() fallback, but it often provides more digits than are necessary. Whenever doubletoa reverts to a fallback routine, $Math::MPFR::doubletoa_fallback (which is initially set to 0) will be incremented. This feature can be disabled by providing the FB=0 argument to the 'perl Makefile.PL' step of the Math::MPFR build. $str = nvtoa($NV); # Available irrespective of $Config{nvsize} # and $Config{nvtype} Sets $str to the value of $NV. $str will appear in standard decimal format, containing the *minimum* number of digits such that the condition ($str == $NV) is true. NOTE 1: Except for perls whose nvtype is __float128: 1) perl versions prior to 5.30.0 are buggy in their assignment of values to the NV; 2) perl versions from 5.30.0 on that don't define $Config{d_strtod} (or respectively $Config{d_strtold} for -Duselongdouble builds) are also buggy in their assignment of values to the NV. The nvtoa() function looks only at the value that was passed to it - which, with such buggy perls, may differ from the intended value by a few ULPs. On these buggy perls, the bug can be avoided by assigning with atonv() - which requires mpfr-3.1.6 or later. NOTE 2: Be wary of values assigned by perl to double-double NVs, as such assignments may also be buggy, irrespective of the perl version. Again, with these perls, assign using atonv() - which requires mpfr-3.1.6 or later. With double-double NVs, nvtoa() currently requires mpfr-4.0.0 or later. $str = mpfrtoa($op, $uv); # $uv is optional (new in 4.24), and will # be set to zero if not provided. As for nvtoa(), except that mpfrtoa() instead takes a Math::MPFR object as its argument. Sets $str to the value of $op. $str will appear in standard decimal format, containing the *minimum* number of digits such that the condition ($str == $op) is true. If provided, $uv sets the minimum precision below which the value will be deemed subnormal. For example, if $uv is given as 53, then any Math::MPFR object ($op) with precision less than 53 bits will be treated as subnormal. (This can have an effect on the no. of significant mantissa digits returned.) If $uv is not provided, it is assigned a value of 0 - ie no Math::MPFR objects will be treated as subnormal (because precision is never less than 0). $str = anytoa($op [, $bits]); For example, you want to know what nvtoa(sqrt 3) would return on a perl whose nvtype is the 113-bit precision __float128 (or IEEE-754 128-bit long double) but you don't have access to such a perl. You can do: my $bits = 113; my $op = Rmpfr_init2($bits); Rmpfr_set_ui($op, 3, MPFR_RNDN); $op = sqrt($op); print anytoa($op); # alternatively: # print anytoa($op, $bits); We allow the second arg solely for back-compatibility. This also allows one to provide a second arg to anytoa() that differs in value to the precision of $op, though it's not clear to me that this is in any way useful. Similarly, changing $bits to 53, or 64, or 2098 will provide the same as nvtoa(sqrt 3) for (respectively) the 53-bit precision double , the 64-bit extended precision long double, and the double-double. $bits must be either 53, 64, 113 or 2098 (and the same goes for the precision of $op). When anytoa() is called with only the one argument ($op), or with a 2nd argument that is equivalent to the precision of $op, then the value returned will be the same as returned by mpfrtoa($op) unless: 1) $op holds a finite value that is of such magnitude that the specified nvtype will turn it into (+ or -) Inf; or 2) $op holds a finite non-zero value that is so close to zero that the specified nvtype will either round it to zero or denormalize it; or 3) the precision of $op is 2098 bits. $mask = nvtoa_test($str, $arg, $debug); # $debug can be omitted. $arg can be either an NV or a Math::MPFR object. If $arg is an NV, then $str is the string returned by nvtoa($arg). Else $str is the string returned by mpfrtoa($arg). The nvtoa_test function checks that $str is the correct string for the given $arg. $mask is initially set to zero. If $str assigns to $arg (as it should) then $mask set to 1. Also, we chop the least significant digit off the mantissa of a copy of $str, and add 2 to $mask if this chopped $str assigns to a value less than $arg. Also, we increment the least significant mantissa digit of this chopped copy of $str, and add 4 to $mask if this chopped-and-incremented $str assigns to a value greater than $arg. Also, we check that the mantissa portion of $str contains no unwelcome trailing zeroes. $mask is then returned. If all is correct, it's value will be 15. If the value of the returned $mask is not 15, then we can determine which part(s) of the test has failed by examining $mask's four lowest bits. If a third (debug) arg is provided and is TRUE, then some debug info is provided during the running of nvtoa_test(). For inf, nan, and zero, we do only the initial test and return 15 if that test has passed, or 0 if that test has failed. (The other 3 tests don't really apply.) $str = numtoa($sv); As for nvtoa() but prints out UVs and IVs in integer format. (If UV-precision is greater than NV-precision then nvtoa() output can lose precision as it prints out UVs and IVs in floating point format.) $double = atodouble($str); # Needs mpfr-3.1.6 or later Sets $double to the value of the double that's represented by the string $str. If $Config{nvtype} is double, it therefore returns the same value as atonv. See atonv() below. $NV = atonv($str); # Needs mpfr-3.1.6 or later Sets $NV to the NV value represented by the string $str. If $str expresses a base 2 value, begin it with '0b' or '0B'. If $str expresses a base 16 value, begin it with '0x' or '0X. For example: atonv('0x0.89p5'), atonv('0x0.112@2'), atonv('17.125') and atonv('0b0.10001001e5') all return 17.125. NOTE: ORIGINALLY TOOK 2 ARGUMENTS - NOW TAKES ONLY 1, as of Math-MPFR-4.07. $sv = atonum($str); # Needs mpfr-3.1.6 or later If $str numifies to an IV, return that IV. Else return the NV that is returned by atonv($str). $ret = decimalize($op [, $anything]); # 2nd (optional) arg # can be any scalar. If no second argument is provided, return an exact base 10 string representation of the value held in $op. Else, instead return the number of decimal digits (not counting leading zeros) contained in the significand of that "exact base 10 representation", as estimated by decimalize(). This value could be one greater than the actual number of those significand digits. If a second arg is supplied && $op is Inf or NaN or Zero, then the returned value will be zero. NOTE: https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/ explains that the maximum number of significant digits returned for a double precision value will be 767: 1074 + floor(log10(2**53-1) / 2**1074))+1 = 767 $bool = check_exact_decimal($str, $op); Can be used to verify the string returned by decimalize(). Return 1 if $str is an exact decimal representation of the value held in $op. Else return 0. $MPFR_version = Rmpfr_get_version(); Returns the version of the MPFR library (eg 4.0.2) being used by Math::MPFR. $GMP_version = Math::MPFR::gmp_v(); Returns the version of the gmp library (eg. 4.1.3) being used by the mpfr library that's being used by Math::MPFR. The function is not exportable. $ui = MPFR_VERSION; An integer whose value is dependent upon the 'major', 'minor' and 'patchlevel' values of the MPFR library against which Math::MPFR was built. This value is from the mpfr.h that was in use when the compilation of Math::MPFR took place. $ui = MPFR_VERSION_MAJOR; The 'x' in the 'x.y.z' of the MPFR library version. This value is from the mpfr.h that was in use when the compilation of Math::MPFR took place. $ui = MPFR_VERSION_MINOR; The 'y' in the 'x.y.z' of the MPFR library version. This value is from the mpfr.h that was in use when the compilation of Math::MPFR took place. $ui = MPFR_VERSION_PATCHLEVEL; The 'z' in the 'x.y.z' of the MPFR library version. This value is from the mpfr.h that was in use when the compilation of Math::MPFR took place. $string = MPFR_VERSION_STRING; $string is set to the version of the MPFR library (eg 2.1.0) against which Math::MPFR was built. This value is from the mpfr.h that was in use when the compilation of Math::MPFR took place. $ui = MPFR_VERSION_NUM($major, $minor, $patchlevel); Returns the value for MPFR_VERSION for "MPFR-$major.$minor.$patchlevel". $str = Rmpfr_get_patches(); Return a string containing the ids of the patches applied to the MPFR library (contents of the 'PATCHES' file), separated by spaces. Note: If the program has been compiled with an older MPFR version and is dynamically linked with a new MPFR library version, the ids of the patches applied to the old (compile-time) MPFR version are not available (however this information should not have much interest in general). $bool = Rmpfr_buildopt_tls_p(); # mpfr-3.0.0 and later only Return a non-zero value if mpfr was compiled as thread safe using compiler-level Thread Local Storage (that is mpfr was built with the '--enable-thread-safe' configure option), else return zero. $bool = Rmpfr_buildopt_decimal_p(); # mpfr-3.0.0 and later only Return a non-zero value if mpfr was compiled with decimal float support (that is mpfr was built with the '--enable-decimal-float' configure option), return zero otherwise. $bool = Rmpfr_buildopt_float128_p(); # mpfr-4.0.0 and later only Return a non-zero value if mpfr was compiled with __float128 support (that is mpfr was built with the '--enable-decimal-float' configure option), return zero otherwise. $bool = Rmpfr_buildopt_gmpinternals_p(); # mpfr-3.1.0 and later only Return a non-zero value if mpfr was compiled with gmp internals (that is, mpfr was built with either '--with-gmp-build' or '--enable-gmp-internals' configure option), return zero otherwise. $bool = Rmpfr_buildopt_sharedcache_p(); # mpfr-4.0.0 and later only Return a non-zero value if MPFR was compiled so that all threads share the same cache for the one MPFR constant, like `mpfr_const_pi' or `mpfr_const_log2' (that is, MPFR was built with the `--enable-shared-cache' configure option), return zero otherwise. $str = Rmpfr_buildopt_tune_case(); # mpfr-3.1.0 and later only Return a string saying which thresholds file has been used at compile time. This file is normally selected from the processor type. If "make tune" has been used, then it will return "src/mparam.h". Otherwise it will say which official mparam.h file has been used. $inex = Rmpfr_rint($rop, $op, $rnd); $inex = Rmpfr_ceil($rop, $op); $inex = Rmpfr_floor($rop, $op); $inex = Rmpfr_round($rop, $op); $inex = Rmpfr_roundeven($rop, $op); # mpfr-4.0.0 and later only $inex = Rmpfr_trunc($rop, $op); Set $rop to $op rounded to an integer. 'Rmpfr_ceil' rounds to the next higher representable integer, 'Rmpfr_floor' to the next lower, 'Rmpfr_round' to the nearest representable integer, rounding halfway cases away from zero, 'Rmpfr_roundeven' to the nearest representable integer, rounding halfway cases with the even- rounding rule and 'Rmpfr_trunc' to the representable integer towards zero. 'Rmpfr_rint' behaves like one of these four functions, depending on the rounding mode. Further to its usual meaning, $inex is 0 when $op is an integer representable in $rop, 1 or -1 when $op is an integer that is not representable in $rop, 2 or -2 when $op is not an integer. $inex = Rmpfr_rint_ceil($rop, $op, $rnd); $inex = Rmpfr_rint_floor($rop, $op, $rnd); $inex = Rmpfr_rint_round($rop, $op, $rnd); $inex = Rmpfr_rint_roundeven($rop, $op, $rnd); # mpfr-4.0.0 & later $inex = Rmpfr_rint_trunc($rop, $op, $rnd); Set $rop to $op rounded to an integer. 'Rmpfr_rint_ceil' rounds to the next higher or equal integer, 'Rmpfr_rint_floor' to the next lower or equal integer, 'Rmpfr_rint_round' to the nearest integer, rounding halfway cases away from zero, 'Rmpfr_rint_roundeven' to the nearest integer,rounding halfway cases to the nearest even integer and 'Rmpfr_rint_trunc' to the next integer towards zero. If the result is not representable, it is rounded in the direction $rnd. $inex = Rmpfr_frac($rop, $op, $round); Set $rop to the fractional part of $op, having the same sign as $op, rounded in the direction $round (unlike in 'mpfr_rint', $round affects only how the exact fractional part is rounded, not how the fractional part is generated). $inex = Rmpfr_modf ($rop1, $rop2, $op, $rnd); Set simultaneously $rop1 to the integral part of $op and $rop2 to the fractional part of $op, rounded in the direction RND with the corresponding precision of $rop1 and $rop2 (equivalent to 'Rmpfr_trunc($rop1, $op, $rnd)' and 'Rmpfr_frac($rop1, $op, $rnd)'). The variables $rop1 and $rop2 must be different. Return 0 if both results are exact. $inex = Rmpfr_remainder($rop, $op1, $op2, $rnd); $inex = Rmpfr_fmod($rop, $op1, $op2, $rnd); ($si2, $si) = Rmpfr_remquo ($rop, $op1, $op2, $rnd); ($si2, $si) = Rmpfr_fmodquo ($rop, $op1, $op2, $rnd); # mpfr-4.0.0 & # later only Set $rop to the value of $op - N*$op2, rounded according to the direction $rnd, where N is the integer quotient of $op1 divided by $op2, defined as follows: N is rounded toward zero for 'Rmpfr_fmod' and 'Rmpfr_fmodquo', and to the nearest integer (ties rounded to even) for 'mpfr_remainder' and 'mpfr_remquo'. Special values are handled as described in Section F.9.7.1 of the ISO C99 standard: If $op1 is infinite or $op2 is zero, $rop is NaN. If $op2 is infinite and $op1 is finite, $rop is $op1 rounded to the precision of $rop. If $rop is zero, it has the sign of $op1. The return value is the ternary value corresponding to $rop. Additionally, 'Rmpfr_remquo' and 'Rmpfr_fmodquo store the low significant bits from the quotient in $si2 (more precisely the number of bits in a 'long' minus one), with the sign of $op1 divided by $op2 (except if those low bits are all zero, in which case zero is returned). Note that $op1 may be so large in magnitude relative to $op2 that an exact representation of the quotient is not practical. 'Rmpfr_remainder' and Rmpfr_remquo' functions are useful for additive argument reduction. $inex = Rmpfr_fmod_ui($rop, $op1, $ui, $rnd); As for Rmpfr_fmod(), above, except that the 3rd arg is an unsigned long int instead of a Math::MPFR object. This function was introduced in mpfr-4.2.0-dev, but is implemented (suboptimally) in Math::MPFR built against older versions of the mpfr library. $bool = Rmpfr_integer_p($op); Return non-zero if $op is an integer. Rmpfr_nexttoward($op1, $op2); If $op1 or $op2 is NaN, set $op1 to NaN. Otherwise, if $op1 is different from $op2, replace $op1 by the next floating-point number (with the precision of $op1 and the current exponent range) in the direction of $op2, if there is one (the infinite values are seen as the smallest and largest floating-point numbers). If the result is zero, it keeps the same sign. No underflow or overflow is generated. Rmpfr_nextabove($op1); Equivalent to 'mpfr_nexttoward' where $op2 is plus infinity. Rmpfr_nextbelow($op1); Equivalent to 'mpfr_nexttoward' where $op2 is minus infinity. $inex = Rmpfr_min($rop, $op1, $op2, $round); Set $rop to the minimum of $op1 and $op2. If $op1 and $op2 are both NaN, then $rop is set to NaN. If $op1 or $op2 is NaN, then $rop is set to the numeric value. If $op1 and $op2 are zeros of different signs, then $rop is set to -0. $inex = Rmpfr_max($rop, $op1, $op2, $round); Set $rop to the maximum of $op1 and $op2. If $op1 and $op2 are both NaN, then $rop is set to NaN. If $op1 or $op2 is NaN, then $rop is set to the numeric value. If $op1 and $op2 are zeros of different signs, then $rop is set to +0. $IV = Math::MPFR::nnumflag(); # not exported Returns the value of the non-numeric flag. This flag is initialized to zero, but incremented by 1 whenever the a string containing non-numeric characters is passed to an mpfr function. The value of the flag therefore tells us how many times such strings were passed to mpfr functions . The flag can be reset to 0 by running clear_nnum(). $IV = Math::MPFR::nok_pokflag(); # not exported Returns the value of the nok_pok flag. This flag is initialized to zero, but incremented by 1 whenever a scalar that is both a float (NOK) and string (POK) is passed to new() or to an overloaded operator. The value of the flag therefore tells us how many times such events occurred . The flag can be reset to 0 by running clear_nok_pok(). Math::MPFR::set_nnum($IV); # not exported Resets the global non-numeric flag to the value specified by $IV. Math::MPFR::set_nok_pok($IV); # not exported Resets the nok_pok flag to the value specified by $IV. Math::MPFR::clear_nnum(); # not exported Resets the global non-numeric flag to 0.(Essentially the same as running set_nnum(0).) Math::MPFR::clear_nok_pok(); # not exported Resets the nok_pok flag to 0.(Essentially the same as running set_nok_pok(0).) $bytes = Math::MPFR::bytes($val, $bits); (The semantics for calling this function have changed as of Math-MPFR-4.13.) $val must either be a string (eg '1.613e-45', '2.3', '0x17.8') or a Math::MPFR object. $bits must be one of 53, 64, 2098 or 113. $bytes will be set to the hex representation of $val. If $bits is 53, $bytes will display the byte structure (in hex) of the standard 8-byte double, $val. If $bits is 64, the structure returned will be that of $val as an extended precision 10-byte long double. If $bits is 2098, the structure returned will be that of $val as the 16-byte IBM doubledouble. If $bits is 113, the structure returned will be that of $val as the quad precision 16-byte IEEE long double (or __float128, which is identical in byte structure). eg: bytes('1.3', 53) returns 3ff4cccccccccccd bytes('1.3', 64) returns 3fffa666666666666666 bytes('1.3', 2098) returns 3ff4cccccccccccdbc8999999999999a bytes('1.3', 113) returns 3fff4ccccccccccccccccccccccccccd If $val is a Math::MPFR object, its precision must be $bits. For many architectures and mpfr configurations, the structures for all 4 allowed values of $bits will be accessible. In some cases, however, $bits values of 64 and/or 113 might throw a fatal error (with diagnostic message stating that the requested byte structure is not currently available). $si = IOK_flag($sv); # $sv is a perl scalar variable. $si = NOK_flag($sv); $si = POK_flag($sv); Return 0 if $sv's IOK/NOK/POK flag is unset. Else return 1. If the IsUV flag is set, then IOK_flag() returns 2, thereby indicating that both the IOK and IsUV flags are set (and that the integer value held by $sv should therefore be treated as unsigned). ############## RANDOM NUMBERS Rmpfr_urandomb(@r, $state); Each member of @r is a Math::MPFR object. $state is a reference to a gmp_randstate_t structure. Set each member of @r to a uniformly distributed random float in the interval 0 <= $_ < 1. Before using this function you must first create $state by calling one of the 4 Rmpfr_randinit functions, then seed $state by calling one of the 2 Rmpfr_randseed functions. The memory associated with $state will be freed automatically when $state goes out of scope. Rmpfr_random2($rop, $si, $ui); # not implemented in # mpfr-3.0.0 and later Attempting to use this function when Math::MPFR has been built against mpfr-3.0.0 (or later) will cause the program to die, with an appropriate error message. Generate a random float of at most abs($si) limbs, with long strings of zeros and ones in the binary representation. The exponent of the number is in the interval -$ui to $ui. This function is useful for testing functions and algorithms, since this kind of random numbers have proven to be more likely to trigger corner-case bugs. Negative random numbers are generated when $si is negative. $si = Rmpfr_urandom ($rop, $state, $rnd); # mpfr-3.0.0 and # later only Generate a uniformly distributed random float. The floating-point number $rop can be seen as if a random real number is generated according to the continuous uniform distribution on the interval[0, 1] and then rounded in the direction RND. Before using this function you must first create $state by calling one of the Rmpfr_randinit functions (below), then seed $state by calling one of the Rmpfr_randseed functions. $si = Rmpfr_grandom($rop1, $rop2, $state, $rnd); Available only with mpfr-3.1.x. (Was deprecated in 4.0.0.) Use Rmpfr_nrandom() if Rmpfr_grandom() is unavailable. This function will croak with an appropriate message if Math::MPFR is built against an mpfr version other than 3.1.x. Generate two random floats according to a standard normal gaussian distribution. The floating-point numbers $rop1 and $rop2 can be seen as if a random real number were generated according to the standard normal gaussian distribution and then rounded in the direction $rnd. Before using this function you must first create $state by calling one of the Rmpfr_randinit functions (below), then seed $state by calling one of the Rmpfr_randseed functions. $si = Rmpfr_nrandom ($rop, $state, $rnd); # mpfr-4.0.0 and # later only Generate a random floating-point number according to a standard normal Gaussian distribution (with mean zero and variance one). The floating-point number $rop can be seen as if a random real number were generated according to the standard normal Gaussian distribution and then rounded in the direction $rnd. This function is more efficient than Rmpfr_grandom. $si = Rmpfr_erandom($rop, $state, $rnd); # mpfr-4.0.0 and # later only Generate one random floating-point number according to an exponential distribution, with mean one. Other characteristics are identical to 'Rmpfr_nrandom'. $state = Rmpfr_randinit_default(); Initialise $state with a default algorithm. This will be a compromise between speed and randomness, and is recommended for applications with no special requirements. $state = Rmpfr_randinit_mt(); Initialize state for a Mersenne Twister algorithm. This algorithm is fast and has good randomness properties. $state = Rmpfr_randinit_lc_2exp($a, $c, $m2exp); This function is not tested in the test suite. Use with caution - I often select values here that cause Rmpf_urandomb() to behave non-randomly. Initialise $state with a linear congruential algorithm: X = ($a * X + $c) % 2 ** $m2exp The low bits in X are not very random - for this reason only the high half of each X is actually used. $c and $m2exp are both unsigned longs. $a can be any one of Math::GMP, or Math::GMPz objects. Or it can be a string. If it is a string of hex digits it must be prefixed with either OX or Ox. If it is a string of octal digits it must be prefixed with 'O'. Else it is assumed to be a decimal integer. No other bases are allowed. $state = Rmpfr_randinit_lc_2exp_size($ui); Initialise state as per Rmpfr_randinit_lc_2exp. The values for $a, $c and $m2exp are selected from a table, chosen so that $ui bits (or more) of each X will be used. Rmpfr_randseed($state, $seed); $state is a reference to a gmp_randstate_t structure (the return value of one of the Rmpfr_randinit functions). $seed is the seed. It can be any one of Math::GMP, or Math::GMPz objects. Or it can be a string of digits. If it is a string of hex digits it must be prefixed with either OX or Ox. If it is a string of octal digits it must be prefixed with 'O'. Else it is assumed to be a decimal integer. No other bases are allowed. Rmpfr_randseed_ui($state, $ui); $state is a reference to a gmp_randstate_t structure (the return value of one of the Rmpfr_randinit functions). $ui is the seed. ######### INTERNALS $bool = Rmpfr_can_round($op, $ui, $rnd1, $rnd2, $p); Assuming $op is an approximation of an unknown number X in direction $rnd1 with error at most two to the power E(b)-$ui where E(b) is the exponent of $op, returns 1 if one is able to round exactly X to precision $p with direction $rnd2, and 0 otherwise. This function *does not modify* its arguments. $str = Rmpfr_print_rnd_mode($rnd); Return a string ("MPFR_RNDD", "MPFR_RNDU", "MPFR_RNDN", "MPFR_RNDZ", "MPFR_RNDA") corresponding to the rounding mode $rnd, or return undef if $rnd is an invalid rounding mode. $si = Rmpfr_get_exp($op); Return to $si the exponent of $op. The behavior for nan, infinity or zero is undefined. $si = Rmpfr_set_exp($op, $si); Set the exponent of $op if $si is in the current exponent range, and return 0 (even if $op is not a non-zero ordinary number); otherwise, return a non-zero value. $si = Rmpfr_signbit ($op); Return a non-zero value if $op has its sign bit set (i.e. if it is negative, -0, or a NaN whose representation has its sign bit set). $si2 = Rmpfr_setsign ($rop, $op, $si, $rnd); Set the value of $rop from $op, rounded towards the given direction $rnd, then set/clear its sign bit if $si is true/false (even when $op is a NaN). $si = Rmpfr_copysign ($rop, $op1, $op2, $rnd); Set the value of $rop from $op1, rounded towards the given direction $rnd, then set its sign bit to that of $op2 (even when $op1 or $op2 is a NaN). This function is equivalent to: Rmpfr_setsign ($rop, $op1, Rmpfr_signbit ($op2), $rnd)'. #################### OPERATOR OVERLOADING Overloading works with numbers, strings (bases 2, 10, and 16 only - see step '4.' below) and Math::MPFR objects. Overloaded operations are performed using the current "default rounding mode" (which you can determine using the 'Rmpfr_get_default_rounding_mode' function, and change using the 'Rmpfr_set_default_rounding_mode' function). Be aware that when you use overloading with a string operand, the overload subroutine converts that string operand to a Math::MPFR object with *current default precision*, and using the *current default rounding mode*. Note that any comparison using the spaceship operator ( <=> ) will return undef if either/both of the operands is a NaN. All comparisons ( < <= > >= == != <=> ) involving one or more NaNs will set the erange flag. For the purposes of the overloaded 'not', '!' and 'bool' operators, a "false" Math::MPFR object is one whose value is either 0 (including -0) or NaN. (A "true" Math::MPFR object is, of course, simply one that is not "false".) The following operators are overloaded: + - * / ** sqrt (Return object has default precision) += -= *= /= **= ++ -- (Precision remains unchanged) < <= > >= == != <=> ! bool abs atan2 cos sin log exp (Return object has default precision) int (On perl 5.8+ only, NA on perl 5.6. The return object has default precision) "" (Interpolates the value of the Math::MPFR object to a decimal string) << >> <<= >>= (These just increase/decrease the exponent by the value of the given "shift" argument) = (The copy has the same precision as the copied object.) NOTE: Making use of the '=' overloading is not recommended unless you understand its caveats. See 'perldoc overload' and read it thoroughly, including the documentation regarding 'copy constructors'. Furthermore, all overloaded comparisons ( < <= > >= == != <=> ) between Math::MPFR and Math::GMPz objects or between Math::MPFR and Math::GMPq objects are permitted. Some additional cross-class overloading is also allowed. Let $M be a Math::MPFR object, and $G be any one of a Math::GMPz, Math::GMPq or Math::GMPf object. Then it is now permissible to do: $M + $G; $M += $G; $M - $G; $M -= $G; $M * $G; $M *= $G; $M / $G; $M /= $G; $M ** $G; $M **= $G; If you have version 0.35 (or later) of Math::GMPz, Math::GMPq and Math::GMPf, it is also permissible to do: $G + $M; $G - $M; $G * $M; $G / $M; $G ** $M; Again, each of those operations returns a Math::MPFR object containing the result of the operation. Each operation is conducted using current default rounding mode. NOTE: In overloading a ** (power) operation that involves a Math::GMPq object, it is necessary to convert the Math::GMPq object to an mpfr_t (the type of value encapsulated in the Math::MPFR object). This conversion is done using current default precision and current default rounding mode. The following is still NOT ALLOWED, and will cause a fatal error: $G += $M; $G -= $M; $G *= $M; $G /= $M; $G **= $M; In those situations where the overload subroutine operates on 2 perl variables, then obviously one of those perl variables is a Math::MPFR object. To determine the value of the other variable the subroutine works through the following steps (in order), using the first value it finds, or croaking if it gets to step 6: 1. If the variable is a UV then that value is used. The variable is considered to be a UV if the IOK and IsUV flags are set. 2. If the variable is an IV, then that value is used. The variable is considered to be an IV if the IOK flag is set. 3. If the variable is a string (ie the POK flag is set) then the value of that string is used. If the POK flag is set, but the string is not a valid number, the subroutine croaks with an appropriate error message. If the string starts with '0b' or '0B' it is regarded as a base 2 number. If it starts with '0x' or '0X' it is regarded as a base 16 number. Otherwise it is regarded as a base 10 number. The value is then handed to a temporary Math::MPFR object that has current default precision. Any rounding required will be done in accordance with current default rounding mode. See "STRING OVERLOADING ANOMALY" (below) for an example of possible anomalies regarding string overloading. 4. If the variable is an NV (floating point value) then that value is used. The variable is considered to be an NV if the NOK flag is set. Note therefore, that if the variable is both an NV (NOK flag set) and PV (POK flag also set) then the string value in the PV slot will be used. This is probably, but not necessarily, what you want, and it's recommended not to pass such values to the overloaded operators. 5. If the variable is a Math::MPFR, Math::GMPz, Math::GMPf, or Math::GMPq object then the value of that object is used. If the particular operation does not accept a Math::GMP* object, then the operation dies with an appropriate error message if such an object is received. 6. If none of the above is true, then the second variable is deemed to be of an invalid type. The operation croaks with an appropriate error message. ##################### STRING OVERLOADING ANOMALY An example, when $Config{ivsize} == 8, default precision <= 63, default rounding mode is either MPFR_RNDN, MPFR_RNDU or MPFR_RNDA : my $f = Math::MPFR->new(2 ** 64); # 0x1p+64 my $i = 18446744073709551615; # 1 less than 2 ** 64 print ($f <=> $i ); # prints 1 print ($f <=> "$i"); # prints 0 If you want an integer string in an overloaded expression to be evaluated to its full (arbitrary) precision, then convert it to a Math::GMPz object first: print ($f <=> Math::GMPz->new("$i")); # prints 1 See t/anomaly.t in the test suite for further examples. ##################### FORMATTED OUTPUT NOTE: When using the 'P' (precision) type specifier, instead of providing $prec to the 'P' specifier, it's now advisable to provide prec_cast($prec). The 'P' specifier expects an mp_prec_t but, prior to 3.18, we could pass it only an IV. This didn't work on at least some big-endian machines if the size of the IV was greater than the size of the mp_prec_t. The Math::MPFR::Prec package (which is part of this distribution) exists solely to provide the prec_cast sub. And the prec_cast sub's return value should be passed *only* to the 'P' type specifier. Nothing else will understand it. Passing it to something other than the 'P' specifier may produce a garbage result - might even cause a segfault. prec_cast($prec); Ensures that the 'P' type specifier will provide correct results. In Math::MPFR versions prior to 3.18 we could do only (eg) : Rmpfr_printf("%Pu\n", Rmpfr_get_prec($op)); But that didn't work correctly for all architectures. As of 3.18, that can be rewritten as: Rmpfr_printf("%Pu\n", prec_cast(Rmpfr_get_prec($op))); which should work on all architectures. Rmpfr_printf($format_string, [$rnd,] $var); This function (unlike the MPFR counterpart) is limited to taking 2 or 3 arguments - the format string, optionally a rounding argument, and the variable to be formatted. That is, you can currently printf only one variable at a time. If there's no variable to be formatted, just add a '0' as the final argument. ie this will work fine: Rmpfr_printf("hello world\n", 0); NOTE: The rounding argument $rnd can be provided *only* if $var is a Math::MPFR object. To do otherwise is a fatal error. See the mpfr documentation for details re the formatting options: http://www.mpfr.org/mpfr-current/mpfr.html#Formatted-Output-Functions Rmpfr_fprintf($fh, $format_string, [$rnd,] $var); This function (unlike the MPFR counterpart) is limited to taking 3 or 4 arguments - the filehandle, the format string, optionally a rounding argument, and the variable to be formatted. That is, you can printf only one variable at a time. If there's no variable to be formatted, just add a '0' as the final argument. ie this will work fine: Rmpfr_fprintf($fh, "hello world\n", 0); NOTE: The rounding argument $rnd can be provided *only* if $var is a Math::MPFR object. To do otherwise is a fatal error. See the mpfr documentation for details re the formatting options: http://www.mpfr.org/mpfr-current/mpfr.html#Formatted-Output-Functions Rmpfr_sprintf($buffer, $format_string, [$rnd,] $var, $buflen); This function (unlike the MPFR counterpart) is limited to taking 4 or 5 arguments - the buffer, the format string, optionally a rounding argument, the variable to be formatted and the size of the buffer ($buflen) into which the result will be written. $buflen must specify a size (characters) that is at least large enough to accommodate the formatted string (including the terminating NULL). The formatted string will be placed in $buffer. If there's no variable to be formatted, just insert a '0' as the value for $var. ie this will work fine: Rmpfr_sprintf($buffer, "hello world", 0, $buflen); NOTE: The rounding argument $rnd can be provided *only* if $var is a Math::MPFR object. To do otherwise is a fatal error. See the mpfr documentation for details re the formatting options: http://www.mpfr.org/mpfr-current/mpfr.html#Formatted-Output-Functions Rmpfr_snprintf($buffer, $bytes, $format_string, [$rnd,] $var, $buflen); This function (unlike the MPFR counterpart) is limited to taking 5 or 6 arguments - the buffer, the number of bytes to be written, the format string, optionally a rounding argument, the variable to be formatted and the size of the buffer ($buflen). $buflen must specify a size (characters) that is at least large enough to accommodate the formatted string (including the terminating NULL). The formatted string will be placed in $buffer. If there's no variable to be formatted, just insert a '0' as the value for $arg. ie this will work fine: Rmpfr_snprintf($buffer, 12, "hello world", 0, $buflen); NOTE: The rounding argument $rnd can be provided *only* if $var is a Math::MPFR object. To do otherwise is a fatal error. See the mpfr documentation for further details: http://www.mpfr.org/mpfr-current/mpfr.html#Formatted-Output-Functions ##################### BASE CONVERSIONS $DBL_DIG = MPFR_DBL_DIG; # Will be undef if float.h doesn't define # DBL_DIG. $LDBL_DIG = MPFR_LDBL_DIG; # Will be undef if float.h doesn't define # LDBL_DIG. $FLT128_DIG = MPFR_FLT128_DIG; # Will be undef if quadmath.h has not # been loaded, or quadmath.h does not # define FLT128_DIG . $min_prec = mpfr_min_inter_prec($orig_base, $orig_prec, $to_base); NOTE: $min_prec can be (very rarely) off by one if $orig_prec is in the millions, or if either $orig_base or $to_base are outside of the range 2..64. Example 1: Let's say we have some base 10 integers comprising 16 base 10 digits, and we want to represent those numbers in base 2 (binary). What is the minimum required number of bits, such that it can be guaranteed that converting the base 2 representations back to base 10 will result in the original 16 digit representations ? We can calculate that minimum required precision with: $min_prec = mpfr_min_inter_prec($orig_base, $orig_prec, $to_base); In this example case that becomes: $min_prec = mpfr_min_inter_prec(10, 16, 2); which will set $min_prec to 55. That is, so long as our base 2 representations provide at least 55 bits, we can pass 16-digit, base 10, integer values to them, and be assured of retrieving the original base 10 representation when we convert the base 2 representations back to base 10. Sure ... not all 16-digit values require 55 bits, but there are some that do ... and there are none that require more than 55 bits. Example 2: $min_prec = mpfr_min_inter_prec(2, 53, 10); $min_prec is set to 17. This tells us that a base 10 representation of a 53-bit integer needs to comprise at least 17 digits if we are to be assured that assigning that base 10 representation to a 53-bit integer will result in a 53-bit integer that is identical to the first. Otherwise, there is no such assurance. $max_prec = mpfr_max_orig_prec ($orig_base, $to_base, $to_prec); NOTE: $max_prec can be (very rarely) off by one if $to_prec is in the millions, or if either $orig_base or $to_base are outside of the range 2..64. For example: To determine the maximum significant number of base 10 digits that can be specified, when assigning to a 53-bit double. We have: $max_len = mpfr_max_orig_len($orig_base, $to_base, $to_prec); For this example that becomes: $max_len = mpfr_max_orig_len(10, 2, 53); which will set $max_len to 15. That is, so long as our base 10 integer consists of no more than 15 significant digits, we can assign it to a 53-bit double and be assured of retrieving the original value upon converting that double back to a 15-digit base 10 representation. Otherwise, there is no such assurance. It is to be expected that mpfr_max_orig_len(10, 2, 53) == DBL_DIG and mpfr_max_orig_len(10, 2, 113) == FLT128_DIG and mpfr_max_orig_len(10, 2, $long_double_prec) == LDBL_DIG (where $long_double_prec is the precision, in bits, of the the C 'long double' type - usually either 53 or 64 or 113.) #####################
TODO
Look at wrapping mpfr_mp_memory_cleanup, mp_set_memory_functions
BUGS
You can get segfaults if you pass the wrong type of argument to the functions - so if you get a segfault, the first thing to do is to check that the argument types you have supplied are appropriate.
ACKNOWLEDGEMENTS
Thanks to Vincent Lefevre for providing corrections to errors and omissions, and suggesting improvements (which were duly put in place).
LICENSE
This program is free software; you may redistribute it and/or modify it under the same terms as Perl itself. Copyright 2006-2024 Sisyphus
AUTHOR
Sisyphus <sisyphus at(@) cpan dot (.) org>