\input texinfo @c -*-texinfo-*- @c %**start of header @setfilename mpfr.info @settitle MPFR 2002 @synindex tp fn @iftex @afourpaper @end iftex @comment %**end of header @ifinfo @format START-INFO-DIR-ENTRY * mpfr: (mpfr.info). Multiple Precision Floating-Point Reliable Library. END-INFO-DIR-ENTRY @end format @end ifinfo @c smallbook @iftex @finalout @end iftex @c Note: the edition number is listed in *three* places; please update @c all three. Also, update the month and year where appropriate. @c ==> Update edition number for settitle and subtitle, and in the @c ==> following paragraph; update date, too. @ifinfo This file documents MPFR, a library for reliable multiple precision floating-point arithmetic Copyright (C) 1999-2001, Free Software Foundation. Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. @ignore Permission is granted to process this file through TeX and print the results, provided the printed document carries copying permission notice identical to this one except for the removal of this paragraph (this paragraph not being relevant to the printed manual). @end ignore Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. @end ifinfo @setchapternewpage on @titlepage @c use the new format for titles @title MPFR @subtitle The Multiple Precision Floating-Point Reliable Library @subtitle Edition 2002 @subtitle November 2001 @author the MPFR team, LORIA/INRIA Lorraine @c Include the Distribution inside the titlepage so @c that headings are turned off. @tex \global\parindent=0pt \global\parskip=8pt \global\baselineskip=13pt @end tex @page @vskip 0pt plus 1filll Copyright @copyright{} 1999-2001 Free Software Foundation @sp 2 Published by the Free Software Foundation @* 59 Temple Place - Suite 330 @* Boston, MA 02111-1307, USA @* Permission is granted to make and distribute verbatim copies of this manual provided the copyright notice and this permission notice are preserved on all copies. Permission is granted to copy and distribute modified versions of this manual under the conditions for verbatim copying, provided that the entire resulting derived work is distributed under the terms of a permission notice identical to this one. Permission is granted to copy and distribute translations of this manual into another language, under the above conditions for modified versions, except that this permission notice may be stated in a translation approved by the Foundation. @end titlepage @headings double @ifinfo @node Top, Copying, (dir), (dir) @top MPFR This manual documents how to install and use the Multiple Precision Floating-Point Reliable Library, version 2002 @end ifinfo @menu * Copying:: GMP Copying Conditions (LGPL). * Introduction to MPFR:: Brief introduction to MPFR. * Installing MPFR:: How to configure and compile the MPFR library. * MPFR Basics:: What every MPFR user should now. * Reporting Bugs:: How to usefully report bugs. * Floating-point Functions:: Functions for arithmetic on floats. * Contributors:: * References:: * Concept Index:: * Function Index:: @end menu @node Copying, Introduction to MPFR, Top, Top @comment node-name, next, previous, up @unnumbered MPFR Copying Conditions @cindex Copying conditions @cindex Conditions for copying MPFR This library is @dfn{free}; this means that everyone is free to use it and free to redistribute it on a free basis. The library is not in the public domain; it is copyrighted and there are restrictions on its distribution, but these restrictions are designed to permit everything that a good cooperating citizen would want to do. What is not allowed is to try to prevent others from further sharing any version of this library that they might get from you.@refill Specifically, we want to make sure that you have the right to give away copies of the library, that you receive source code or else can get it if you want it, that you can change this library or use pieces of it in new free programs, and that you know you can do these things.@refill To make sure that everyone has such rights, we have to forbid you to deprive anyone else of these rights. For example, if you distribute copies of the MPFR library, you must give the recipients all the rights that you have. You must make sure that they, too, receive or can get the source code. And you must tell them their rights.@refill Also, for our own protection, we must make certain that everyone finds out that there is no warranty for the MPFR library. If it is modified by someone else and passed on, we want their recipients to know that what they have is not what we distributed, so that any problems introduced by others will not reflect on our reputation.@refill The precise conditions of the license for the MPFR library are found in the Library General Public License that accompany the source code. See the file COPYING.@refill @node Introduction to MPFR, Installing MPFR, Copying, Top @comment node-name, next, previous, up @chapter Introduction to MPFR MPFR is a portable library written in C for arbitrary precision arithmetic on reliable floating-point numbers. It is based on the GNU MP library. It aims to extend the class of floating-point numbers provided by the GNU MP library by @dfn{reliable} floating-point numbers. It may replace the GNU MP floating-point numbers in a future release. The main differences with the @code{mpf} class are: @itemize @bullet @item the @code{mpfr} code is portable, i.e. the result of any operation does not depend (or should not) on the machine word size @code{mp_bits_per_limb} (32 or 64 on most machines); @item the precision in bits can be set exactly to any valid value for each variable (including very small precision); @item @code{mpfr} provides the four rounding modes from the IEEE 754 standard. @end itemize In particular, with a precision of 53 bits, @code{mpfr} should be able to exactly reproduce all computations with double-precision machine floating-point numbers (@code{double} type in C), except the range of values is much wider (the exponent has at least 32 bits instead of 11). This version of MPFR is released under the GNU Lesser General Public License. It is permitted to link MPFR to non-free programs, as long as when distributing them the MPFR source code and a means to re-link with a modified MPFR is provided. @section How to use this Manual Everyone should read @ref{MPFR Basics}. If you need to install the library yourself, you need to read @ref{Installing MPFR}, too. The rest of the manual can be used for later reference, although it is probably a good idea to glance through it. @node Installing MPFR, Reporting Bugs, Introduction to MPFR, Top @comment node-name, next, previous, up @chapter Installing MPFR @cindex Installation To build MPFR, you first have to install GNU MP (version 3.0 or higher) on your computer. You need a C compiler, preferably GCC, but any reasonable compiler should work. And you need a standard Unix @samp{make} program, plus some other standard Unix utility programs. Here are the steps needed to install the library on Unix systems: @enumerate @item In most cases, @samp{./configure --with-gmp=/usr/local/gmp} should work, where the directory @samp{/usr/local/gmp} is where you have installed GNU MP. When you install GNU MP, you have to copy the files @samp{config.h}, @samp{gmp-impl.h}, @samp{gmp-mparam.h} and @samp{longlong.h} from the GNU MP source directory to @samp{/usr/local/gmp/include}; these additional files are needed by MPFR. An alternative way is @samp{./configure --with-gmp-include=dir1 --with-gmp-lib=dir2}, where @samp{dir1} contains the GNU MP header files, and @samp{dir2} the GNU MP library files. If you get error messages, your machine might not be supported. If you want to compile in a separate object directory, cd to that directory, and prefix the configure command with the path to the MPFR source directory. Not all @samp{make} programs have the necessary features to support this. In particular, SunOS and Solaris @samp{make} have bugs that make them unable to build from a separate object directory. Use GNU @samp{make} instead. Also, the generated makefiles use some pattern matching rules that are not supported by all @samp{make} programs. Again, use GNU @samp{make} instead. @item @samp{make} This will compile MPFR, and create a library archive file @file{libmpfr.a} in the working directory. @item @samp{make check} This will make sure MPFR was built correctly. If you get error messages, please report this to @samp{mpfr@@loria.fr}. (@xref{Reporting Bugs}, for information on what to include in useful bug reports.) @item @samp{make install} This will copy the files @file{mpfr.h} and @file{mpf2mpfr.h}, and @file{libmpfr.a}, to the directories @file{/usr/local/include} and @file{/usr/local/lib} respectively (or if you passed the @samp{--prefix} option to @file{configure}, to the directory given as argument to @samp{--prefix}). @end enumerate There are some other useful make targets: @itemize @bullet @item @samp{mpfr.dvi} or @samp{dvi} Create a DVI version of the manual, in @file{mpfr.dvi}. @c and a set of info files, in @file{mpfr.info}, @file{mpfr.info-1}, @file{mpfr.info-2}, etc. @item @samp{mpfr.ps} Create a Postscript version of the manual, in @file{mpfr.ps}. @c @item @c @samp{html} @c Create a HTML version of the manual, in @file{mpfr.html}. @item @samp{clean} Delete all object files and archive files, but not the configuration files. @item @samp{distclean} Delete all files not included in the distribution. @item @samp{uninstall} Delete all files copied by @samp{make install}. @end itemize @section Known Build Problems MPFR suffers from all bugs from the GNU MP library, plus many many more. Please report other problems to @samp{mpfr@@loria.fr}. @xref{Reporting Bugs}. Some bug fixes are available on the MPFR web page @samp{http://www.mpfr.org}. @node Reporting Bugs, MPFR Basics, Installing MPFR, Top @comment node-name, next, previous, up @chapter Reporting Bugs @cindex Reporting bugs If you think you have found a bug in the MPFR library, first have a look on the MPFR web page @samp{http://www.mpfr.org/}: perhaps this bug is already known, in which case you will find a workaround for it. Otherwise, please investigate and report it. We have made this library available to you, and it is not to ask too much from you, to ask you to report the bugs that you find. There are a few things you should think about when you put your bug report together. You have to send us a test case that makes it possible for us to reproduce the bug. Include instructions on how to run the test case. You also have to explain what is wrong; if you get a crash, or if the results printed are incorrect and in that case, in what way. Please include compiler version information in your bug report. This can be extracted using @samp{what `which cc`}, or, if you're using gcc, @samp{gcc -v}. Also, include the output from @samp{uname -a}. If your bug report is good, we will do our best to help you to get a corrected version of the library; if the bug report is poor, we won't do anything about it (aside of chiding you to send better bug reports). Send your bug report to: @samp{mpfr@@loria.fr}. If you think something in this manual is unclear, or downright incorrect, or if the language needs to be improved, please send a note to the same address. @node MPFR Basics, Floating-point Functions, Reporting Bugs, Top @comment node-name, next, previous, up @chapter MPFR Basics @cindex @file{mpfr.h} All declarations needed to use MPFR are collected in the include file @file{mpfr.h}. It is designed to work with both C and C++ compilers. You should include that file in any program using the MPFR library: @code{#include "mpfr.h"} @section Nomenclature and Types @cindex Floating-point number @tindex @code{mpfr_t} @noindent @dfn{Floating-point number} or @dfn{Float} for short, is an arbitrary precision mantissa with a limited precision exponent. The C data type for such objects is @code{mpfr_t}. A floating-point number can have three special values: Not-a-Number (NaN) or plus or minus Infinity. NaN represents a value which cannot be represented in the floating-point format, like 0 divided by 0, or Infinity minus Infinity. @cindex Precision @tindex @code{mp_prec_t} @noindent The @dfn{Precision} is the number of bits used to represent the mantissa of a floating-point number; the corresponding C data type is @code{mp_prec_t}. The precision can be any integer between @code{MPFR_PREC_MIN} and @code{MPFR_PREC_MAX}. In the current implementation, @code{MPFR_PREC_MIN} is equal to 2 and @code{MPFR_PREC_MAX} is equal to @code{ULONG_MAX}. @cindex Rounding Mode @tindex @code{mp_rnd_t} @noindent The @dfn{rounding mode} specifies the way to round the result of a floating-point operation, in case the exact result can not be represented exactly in the destination mantissa; the corresponding C data type is @code{mp_rnd_t}. @cindex Limb @c @tindex @code{mp_limb_t} @noindent A @dfn{limb} means the part of a multi-precision number that fits in a single word. (We chose this word because a limb of the human body is analogous to a digit, only larger, and containing several digits.) Normally a limb contains 32 or 64 bits. The C data type for a limb is @code{mp_limb_t}. @section Function Classes There is only one class of functions in the MPFR library: @enumerate @item Functions for floating-point arithmetic, with names beginning with @code{mpfr_}. The associated type is @code{mpfr_t}. There are about 50 functions is this class. @end enumerate @section MPFR Variable Conventions As a general rule, all MPFR functions expect output arguments before input arguments. This notation is based on an analogy with the assignment operator. MPFR allows you to use the same variable for both input and output in the same expression. For example, the main function for floating-point multiplication, @code{mpfr_mul}, can be used like this: @code{mpfr_mul (x, x, x, rnd_mode)}. This computes the square of @var{x} with rounding mode @code{rnd_mode} and puts the result back in @var{x}. Before you can assign to an MPFR variable, you need to initialize it by calling one of the special initialization functions. When you're done with a variable, you need to clear it out, using one of the functions for that purpose. A variable should only be initialized once, or at least cleared out between each initialization. After a variable has been initialized, it may be assigned to any number of times. For efficiency reasons, avoid to initialize and clear out a variable in loops. Instead, initialize it before entering the loop, and clear it out after the loop has exited. You don't need to be concerned about allocating additional space for MPFR variables, since any variable has a mantissa of fixed size. Hence unless you change its precision, or clear and reinitialize it, a floating-point variable will have the same allocated space during all its life. @section Compatibility with MPF A header file @file{mpf2mpfr.h} is included in the distribution of MPFR for compatibility with the GNU MP class MPF. After inserting the following two lines after the @code{#include "gmp.h"} line, @code{#include "mpfr.h"} @code{#include "mpf2mpfr.h"} any program written for MPF can be linked directly with MPFR without any changes. All operations are then performed with the default MPFR rounding mode, which can be reset with @code{mpfr_set_default_rounding_mode}. @deftypevr {Global Variable} {mp_rnd_t} __gmp_default_rounding_mode The default rounding mode (to nearest initially). @end deftypevr @section Getting the Latest Version of MPFR The latest version of MPFR is available from @file{http://www.mpfr.org/}. @node Floating-point Functions, Contributors, MPFR Basics, Top @comment node-name, next, previous, up @chapter Floating-point Functions @cindex Floating-point functions @cindex Float functions The floating-point functions expect arguments of type @code{mpfr_t}. The MPFR floating-point functions have an interface that is similar to the GNU MP integer functions. The function prefix for floating-point operations is @code{mpfr_}. There is one significant characteristic of floating-point numbers that has motivated a difference between this function class and other MPFR function classes: the inherent inexactness of floating-point arithmetic. The user has to specify the precision of each variable. A computation that assigns a variable will take place with the precision of the assigned variable; the cost of that computation should not depend from the precision of variables used as input on average. @cindex User-defined precision The precision of a calculation is defined as follows: Compute the requested operation exactly (with ``infinite precision''), and round the result to the destination variable precision with the given rounding mode. Even if the user has asked for a very high precision, MP will not calculate with superfluous digits. For example, if two low-precision numbers of nearly equal magnitude are added, the precision of the result will be limited to what is required to represent the result accurately. The MPFR floating-point functions are intended to be a smooth extension of the IEEE P754 arithmetic. The results obtained on one computer should not differ from the results obtained on a computer with a different word size. @menu * Rounding Modes:: * Exceptions:: * Initializing Floats:: * Assigning Floats:: * Simultaneous Float Init & Assign:: * Converting Floats:: * Float Arithmetic:: * Float Comparison:: * I/O of Floats:: * Miscellaneous Float Functions:: @end menu @node Rounding Modes, Exceptions, Floating-point Functions, Floating-point Functions @cindex Rounding modes @section Rounding Modes The following four rounding modes are supported: @itemize @bullet @item @code{GMP_RNDN}: round to nearest @item @code{GMP_RNDZ}: round towards zero @item @code{GMP_RNDU}: round towards plus infinity @item @code{GMP_RNDD}: round towards minus infinity @end itemize The @samp{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 @dfn{drift} phenomenon mentioned by Knuth in volume 2 of The Art of Computer Programming (section 4.2.2, pages 221-222). Most 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 @code{int}. If this value is zero, it 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 means the value stored in the destination variable is greater (resp. lower) than the exact result. For example with the @code{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. @deftypefun void mpfr_set_default_rounding_mode (mp_rnd_t @var{rnd}) Sets the default rounding mode to @var{rnd}. The default rounding mode is to nearest initially. @end deftypefun @deftypefun int mpfr_round (mpfr_t @var{x}, mp_rnd_t @var{rnd}, mp_prec_t @var{prec}) Rounds @var{x} according to @var{rnd} with precision @var{prec}, which may be different from that of @var{x}. If @var{prec} is greater or equal to the precision of @var{x}, then new space is allocated for the mantissa, and it is filled with zeroes. Otherwise, the mantissa is rounded to precision @var{prec} with the given direction. In both cases, the precision of @var{x} is changed to @var{prec}. The returned value is zero when the result is exact, positive when it is greater than the original value of @var{x}, and negative when it is smaller. The precision @var{prec} can be any integer between @code{MPFR_PREC_MIN} and @code{MPFR_PREC_MAX}. @end deftypefun @c @deftypefun void mpfr_set_machine_rnd_mode (mp_rnd_t @var{rnd}) @c Set the machine rounding mode to @var{rnd}. @c This function is useful for debugging purpose, but @c also as a common interface to all different ways of setting the @c rounding mode, which unfortunately differ from one operating system to @c another one. @c @end deftypefun @deftypefun {char *} mpfr_print_rnd_mode (mp_rnd_t @var{rnd}) Returns the input string (GMP_RNDD, GMP_RNDU, GMP_RNDN, GMP_RNDZ) corresponding to the rounding mode @var{rnd}. @end deftypefun @node Exceptions, Initializing Floats, Rounding Modes, Floating-point Functions @comment node-name, next, previous, up @section Exceptions @deftypefun mp_exp_t mpfr_get_emin (void) @deftypefunx mp_exp_t mpfr_get_emax (void) Return the (current) smallest and largest exponents allowed for a floating-point variable. @end deftypefun @deftypefun int mpfr_set_emin (mp_exp_t @var{exp}) @deftypefunx int mpfr_set_emax (mp_exp_t @var{exp}) Set the smallest and largest exponents allowed for a floating-point variable. Return a non-zero value when @var{exp} is not in the range 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 @code{mpfr_check_range}, otherwise the subsequent behaviour will be undefined, in the sense of the ISO C standard. @end deftypefun @deftypefun int mpfr_check_range (mpfr_t @var{x}, mp_rnd_t @var{rnd}) Return zero if the exponent of @var{x} is in the current allowed range (see @code{mpfr_get_emin} and @code{mpfr_get_emax}), otherwise reset @var{x} according to the current floating-point system and the rounding mode @var{rnd}, and return a positive value if the rounded result is larger than the original one, a negative value otherwise (the result cannot be exact in that case). @end deftypefun @deftypefun void mpfr_clear_underflow (void) @deftypefunx void mpfr_clear_overflow (void) @deftypefunx void mpfr_clear_nanflag (void) @deftypefunx void mpfr_clear_inexflag (void) Clear the underflow, overflow, invalid, and inexact flags. @end deftypefun @deftypefun void mpfr_clear_flags (void) Clear all global flags (underflow, overflow, inexact, invalid). @end deftypefun @deftypefun int mpfr_underflow_p (void) @deftypefunx int mpfr_overflow_p (void) @deftypefunx int mpfr_nanflag_p (void) @deftypefunx int mpfr_inexflag_p (void) Return the corresponding (underflow, overflow, invalid, inexact) flag, which is non-zero iff the flag is set. @end deftypefun @node Initializing Floats, Assigning Floats, Exceptions, Floating-point Functions @comment node-name, next, previous, up @section Initialization and Assignment Functions @deftypefun void mpfr_set_default_prec (mp_prec_t @var{prec}) Set the default precision to be @strong{exactly} @var{prec} bits. The precision of a variable means the number of bits used to store its mantissa. All subsequent calls to @code{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 @code{MPFR_PREC_MIN} and @code{MPFR_PREC_MAX}. @end deftypefun @deftypefun mp_prec_t mpfr_get_default_prec () Returns the default MPFR precision in bits. @end deftypefun An @code{mpfr_t} object must be initialized before storing the first value in it. The functions @code{mpfr_init} and @code{mpfr_init2} are used for that purpose. @deftypefun void mpfr_init (mpfr_t @var{x}) Initialize @var{x}, and set its value to zero. Normally, a variable should be initialized once only or at least be cleared, using @code{mpfr_clear}, between initializations. The precision of @var{x} is the default precision, which can be changed by a call to @code{mpfr_set_default_prec}. @end deftypefun @deftypefun void mpfr_init2 (mpfr_t @var{x}, mp_prec_t @var{prec}) Initialize @var{x}, set its precision to be @strong{exactly} @var{prec} bits, and set its value to zero. Normally, a variable should be initialized once only or at least be cleared, using @code{mpfr_clear}, between initializations. To change the precision of a variable which has already been initialized, use @code{mpfr_set_prec} instead. The precision @var{prec} can be any integer between @code{MPFR_PREC_MIN} and @code{MPFR_PREC_MAX}. @end deftypefun @deftypefun void mpfr_clear (mpfr_t @var{x}) Free the space occupied by @var{x}. Make sure to call this function for all @code{mpfr_t} variables when you are done with them. @end deftypefun @need 2000 Here is an example on how to initialize floating-point variables: @example @{ mpfr_t x, y; mpfr_init (x); /* use default precision */ mpfr_init2 (y, 256); /* precision @emph{exactly} 256 bits */ @dots{} /* Unless the program is about to exit, do ... */ mpfr_clear (x); mpfr_clear (y); @} @end example The following two functions are useful for changing the precision during a calculation. A typical use would be for adjusting the precision gradually in iterative algorithms like Newton-Raphson, making the computation precision closely match the actual accurate part of the numbers. @deftypefun int mpfr_set_prec (mpfr_t @var{x}, mp_prec_t @var{prec}) Reset the precision of @var{x} to be @strong{exactly} @var{prec} bits. The previous value stored in @var{x} is lost. It is equivalent to a call to @code{mpfr_clear(x)} followed by a call to @code{mpfr_init2(x, prec)}, but more efficient as no allocation is done in case the current allocated space for the mantissa of @var{x} is enough. The precision @var{prec} can be any integer between @code{MPFR_PREC_MIN} and @code{MPFR_PREC_MAX}. In case you want to keep the previous value stored in @var{x}, use @code{mpfr_round} instead. @end deftypefun @deftypefun mp_prec_t mpfr_get_prec (mpfr_t @var{x}) Return the precision actually used for assignments of @var{x}, i.e. the number of bits used to store its mantissa. @end deftypefun @deftypefun void mpfr_set_prec_raw (mpfr_t @var{x}, unsigned long int @var{p}) Reset the precision of @var{x} to be @strong{exactly} @var{prec} bits. The only difference with @code{mpfr_set_prec} is that @var{p} is assumed to be small enough so that the mantissa fits into the current allocated memory space for @var{x}. Otherwise an error will occur. @end deftypefun @node Assigning Floats, Simultaneous Float Init & Assign, Initializing Floats, Floating-point Functions @comment node-name, next, previous, up @subsection Assignment Functions @cindex Float assignment functions These functions assign new values to already initialized floats (@pxref{Initializing Floats}). @deftypefun int mpfr_set (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_set_ui (mpfr_t @var{rop}, unsigned long int @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_set_si (mpfr_t @var{rop}, long int @var{op}, mp_rnd_t @var{rnd} @deftypefunx int mpfr_set_d (mpfr_t @var{rop}, double @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_set_z (mpfr_t @var{rop}, mpz_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_set_q (mpfr_t @var{rop}, mpq_t @var{op}, mp_rnd_t @var{rnd}) Set the value of @var{rop} from @var{op}, rounded to the precision of @var{rop} towards the given direction @var{rnd}. Please note that even a @code{long int} may have to be rounded, if the destination precision is less than the machine word width. The return value is zero when @var{rop}=@var{op}, positive when @var{rop}>@var{op}, and negative when @var{rop}<@var{op}. For @code{mpfr_set_d}, be careful that the input number @var{op} 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. @end deftypefun @deftypefun int mpfr_set_str (mpfr_t @var{x}, char *@var{s}, int @var{base}, mp_rnd_t @var{rnd}) Set @var{x} to the value of the string @var{s} in base @var{base}, rounded in direction @var{rnd} to the precision of @var{x}. The exponent is read in decimal. This function returns 0 if the entire string up to the final '\0' is a valid number in base @var{base}, and @minus{}1 otherwise. @end deftypefun @deftypefun void mpfr_set_str_raw (mpfr_t @var{x}, char *@var{s}) Set @var{x} to the value of the binary number in string @var{s}, 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 @var{s} has to be less or equal to the precision of @var{x}, otherwise an error occurs. If @var{s} starts with @code{N}, it is interpreted as NaN (Not-a-Number); if it starts with @code{I} after the sign, it is interpreted as infinity, with the corresponding sign. @end deftypefun @deftypefun int mpfr_set_f (mpfr_t @var{x}, mpf_t @var{y}, mp_rnd_t @var{rnd}) Set @var{x} to the GNU MP floating-point number @var{y}, rounded with the @var{rnd} mode and the precision of @var{x}. The returned value is zero when @var{x}=@var{y}, positive when @var{x}>@var{y}, and negative when @var{x}<@var{y}. @end deftypefun @deftypefun void mpfr_swap (mpfr_t @var{x}, mpfr_t @var{y}) Swap the values @var{x} and @var{y} efficiently. Warning: the precisions are exchanged too; in case the precisions are different, @code{mpfr_swap} is thus not equivalent to three @code{mpfr_set} calls using a third auxiliary variable. @end deftypefun @node Simultaneous Float Init & Assign, Converting Floats, Assigning Floats, Floating-point Functions @comment node-name, next, previous, up @subsection Combined Initialization and Assignment Functions @cindex Initialization and assignment functions @deftypefn Macro int mpfr_init_set (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_ui (mpfr_t @var{rop}, unsigned long int @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_si (mpfr_t @var{rop}, signed long int @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_d (mpfr_t @var{rop}, double @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_f (mpfr_t @var{rop}, double @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_z (mpfr_t @var{rop}, mpz_t @var{op}, mp_rnd_t @var{rnd}) @deftypefnx Macro int mpfr_init_set_q (mpfr_t @var{rop}, mpq_t @var{op}, mp_rnd_t @var{rnd}) Initialize @var{rop} and set its value from @var{op}, rounded to direction @var{rnd}. The precision of @var{rop} will be taken from the active default precision, as set by @code{mpfr_set_default_prec}. The return value if zero if @var{rop}=@var{op}, positive if @var{rop}>@var{op}, and negative when @var{rop}<@var{op}. @end deftypefn @deftypefun int mpfr_init_set_str (mpfr_t @var{x}, char *@var{s}, int @var{base}, mp_rnd_t @var{rnd}) Initialize @var{x} and sets its value from the string @var{s} in base @var{base}, rounded to direction @var{rnd}. See @code{mpfr_set_str}. @end deftypefun @node Converting Floats, Float Arithmetic, Simultaneous Float Init & Assign, Floating-point Functions @comment node-name, next, previous, up @section Conversion Functions @cindex Conversion functions @deftypefun double mpfr_get_d (mpfr_t @var{op}) Convert @var{op} to a double, using the current @emph{machine} rounding mode. @end deftypefun @deftypefun {char *} mpfr_get_str (char *@var{str}, mp_exp_t *@var{expptr}, int @var{base}, size_t @var{n_digits}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Convert @var{op} to a string of digits in base @var{base}, with rounding in direction @var{rnd}. The base may vary from 2 to 36. Generate exactly @var{n_digits} significant digits. If @var{n_digits} is 0, it prints the maximum possible number of digits giving an exact rounding in the given base @var{base} with the direction @var{rnd}. In other words, if @var{op} was the exact rounding of a real number in direction @var{rnd}, then the printed value is also an exact rounding in base @var{base} of that real number with the same precision. An error occurs when one is unable to determine the leading digit, which can happen especially if the precision of @var{op} is small. If @var{str} is NULL, space for the mantissa is allocated using the default allocation function, and a pointer to the string is returned. In that case, the user should her/himself free the corresponding memory with @code{(*_mp_free_func)(s, strlen(s) + 1)}. If @var{str} is not NULL, it should point to a block of storage large enough for the mantissa, i.e., @var{n_digits} + 2. The two extra bytes are for a possible minus sign, and for the terminating null character. The exponent is written through the pointer @var{expptr}. If @var{n_digits} is 0, note that the space requirements for @var{str} in this case will be impossible for the user to predetermine. Therefore, one needs to pass NULL for the string argument whenever @var{n_digits} is 0. The generated string is a fraction, with an implicit radix point immediately to the left of the first digit. For example, the number 3.1416 would be returned as "31416" in the string and 1 written at @var{expptr}. @end deftypefun @node Float Arithmetic, Float Comparison, Converting Floats, Floating-point Functions @comment node-name, next, previous, up @section Basic Arithmetic Functions @cindex Float arithmetic functions @cindex Arithmetic functions @deftypefun int mpfr_add (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_add_ui (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_add_z (mpfr_t @var{rop}, mpfr_t @var{op1}, mpz_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_add_q (mpfr_t @var{rop}, mpfr_t @var{op1}, mpq_t @var{op2}, mp_rnd_t @var{rnd}) @ifinfo Set @var{rop} to @var{op1} + @var{op2} rounded in the direction @var{rnd}. @end ifinfo @iftex @tex Set @var{rop} to $@var{op1} + @var{op2}$ rounded in the direction @var{rnd}. @end tex @end iftex The return value is zero if @var{rop} is exactly @var{op1} + @var{op2}, positive if @var{rop} is larger than @var{op1} + @var{op2}, and negative if @var{rop} is smaller than @var{op1} + @var{op2}. @end deftypefun @deftypefun int mpfr_sub (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_ui_sub (mpfr_t @var{rop}, unsigned long int @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sub_ui (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sub_z (mpfr_t @var{rop}, mpfr_t @var{op1}, mpz_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sub_q (mpfr_t @var{rop}, mpfr_t @var{op1}, mpq_t @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1} @minus{} @var{op2} rounded in the direction @var{rnd}. The return value is zero if @var{rop} is exactly @var{op1} @minus{} @var{op2}, positive if @var{rop} is larger than @var{op1} @minus{} @var{op2}, and negative if @var{rop} is smaller than @var{op1} @minus{} @var{op2}. @end deftypefun @deftypefun int mpfr_mul (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_mul_ui (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_mul_z (mpfr_t @var{rop}, mpfr_t @var{op1}, mpz_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_mul_q (mpfr_t @var{rop}, mpfr_t @var{op1}, mpq_t @var{op2}, mp_rnd_t @var{rnd}) @ifinfo Set @var{rop} to @var{op1} times @var{op2} rounded in the direction @var{rnd}. @end ifinfo @iftex @tex Set @var{rop} to $@var{op1} \times @var{op2}$ rounded in the direction @var{rnd}. @end tex @end iftex Return 0 if the result is exact, a positive value if @var{rop}>@var{op1}*@var{op2}, a negative value otherwise. @end deftypefun Division is undefined if the divisor is zero, and passing a zero divisor to the divide functions will make these functions intentionally divide by zero. This gives the user the possibility to handle arithmetic exceptions in these functions in the same manner as other arithmetic exceptions. @deftypefun int mpfr_div (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_ui_div (mpfr_t @var{rop}, unsigned long int @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_div_ui (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_div_z (mpfr_t @var{rop}, mpfr_t @var{op1}, mpz_t @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_div_q (mpfr_t @var{rop}, mpfr_t @var{op1}, mpq_t @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1}/@var{op2} rounded in the direction @var{rnd}. These functions return 0 if the division is exact, a positive value when @var{rop} is larger than @var{op1} divided by @var{op2}, and a negative value otherwise. @end deftypefun @deftypefun int mpfr_sqrt (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sqrt_ui (mpfr_t @var{rop}, unsigned long int @var{op}, mp_rnd_t @var{rnd}) @ifinfo Set @var{rop} to the square root of @var{op} rounded in the direction @var{rnd}. @end ifinfo @iftex @tex Set @var{rop} to $\sqrt{@var{op}}$ rounded in the direction @var{rnd}. @end tex @end iftex Set @var{rop} to NaN if @var{op} is negative. Return 0 if the operation is exact, a non-zero value otherwise. @end deftypefun @deftypefun int mpfr_pow_ui (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_ui_pow_ui (mpfr_t @var{rop}, unsigned long int @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1} raised to @var{op2}. The computation is done by binary exponentiation. Return 0 if the result is exact, a non-zero value otherwise (but the sign of the return value has no meaning). @end deftypefun @deftypefun int mpfr_ui_pow (mpfr_t @var{rop}, unsigned long int @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1} raised to @var{op2}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return zero iff the result is exact, a positive value when the result is greater than @var{op1} to the power @var{op2}, and a negative value when it is smaller. @end deftypefun @deftypefun int mpfr_pow_si (mpfr_t @var{rop}, mpfr_t @var{op1}, long int @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1} raised to the power @var{op2}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return zero iff the result is exact. @end deftypefun @deftypefun int mpfr_pow (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{op1} raised to the power @var{op2}, rounded to the direction @var{rnd} with the precision of @var{rop}. If @var{op1} is negative then @var{rop} is set to NaN, even if @var{op2} is an integer. Return zero iff the result is exact. @end deftypefun @deftypefun int mpfr_neg (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to @minus{}@var{op} rounded in the direction @var{rnd}. Just changes the sign if @var{rop} and @var{op} are the same variable. @end deftypefun @deftypefun int mpfr_abs (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the absolute value of @var{op}, rounded in the direction @var{rnd}. Return 0 if the result is exact, a positive value if @var{rop} is larger than the absolute value of @var{op}, and a negative value otherwise. @end deftypefun @deftypefun int mpfr_mul_2exp (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @ifinfo Set @var{rop} to @var{op1} times 2 raised to @var{op2} @end ifinfo @iftex @tex Set @var{rop} to $@var{op1} \times 2^{op2}$ @end tex @end iftex rounded to the direction @var{rnd}. Just increases the exponent by @var{op2} when @var{rop} and @var{op1} are identical. Return zero when @var{rop}=@var{op1}, a positive value when @var{rop}>@var{op1}, and a negative value when @var{rop}<@var{op1}. @end deftypefun @deftypefun int mpfr_div_2exp (mpfr_t @var{rop}, mpfr_t @var{op1}, unsigned long int @var{op2}, mp_rnd_t @var{rnd}) @ifinfo Set @var{rop} to @var{op1} divided by 2 raised to @var{op2} @end ifinfo @iftex @tex Set @var{rop} to $@var{op1}/2^{op2}$ @end tex @end iftex rounded to the direction @var{rnd}. Just decreases the exponent by @var{op2} when @var{rop} and @var{op1} are identical. Return zero when @var{rop}=@var{op1}, a positive value when @var{rop}>@var{op1}, and a negative value when @var{rop}<@var{op1}. @end deftypefun @node Float Comparison, I/O of Floats, Float Arithmetic, Floating-point Functions @comment node-name, next, previous, up @section Comparison Functions @cindex Float comparisons functions @cindex Comparison functions @deftypefun int mpfr_cmp (mpfr_t @var{op1}, mpfr_t @var{op2}) @deftypefunx int mpfr_cmp_ui (mpfr_t @var{op1}, unsigned long int @var{op2}) @deftypefunx int mpfr_cmp_si (mpfr_t @var{op1}, signed long int @var{op2}) @ifinfo Compare @var{op1} and @var{op2}. Return a positive value if @var{op1} > @var{op2}, zero if @var{op1} = @var{op2}, and a negative value if @var{op1} < @var{op2}. @end ifinfo @iftex @tex Compare @var{op1} and @var{op2}. Return a positive value if $@var{op1} > @var{op2}$, zero if $@var{op1} = @var{op2}$, and a negative value if $@var{op1} < @var{op2}$. @end tex @end iftex Both @var{op1} and @var{op2} are considered to their full own precision, which may differ. In case @var{op1} and @var{op2} are of same sign but different, the absolute value returned is one plus the absolute difference of their exponents. In case one of the operands is NaN (Not-a-Number), it returns 1, even if both are NaN. @end deftypefun @deftypefun int mpfr_cmp_ui_2exp (mpfr_t @var{op1}, unsigned long int @var{op2}, int @var{e}) @deftypefunx int mpfr_cmp_si_2exp (mpfr_t @var{op1}, long int @var{op2}, int @var{e}) Compare @var{op1} and @var{op2} multiplied by two to the power @var{e}. @end deftypefun @deftypefun int mpfr_eq (mpfr_t @var{op1}, mpfr_t @var{op2}, unsigned long int op3) Return non-zero if the first @var{op3} bits of @var{op1} and @var{op2} are equal, zero otherwise. I.e., tests if @var{op1} and @var{op2} are approximately equal. @end deftypefun @deftypefun int mpfr_nan_p (mpfr_t @var{op}) Return non-zero if @var{op} is Not-a-Number (NaN), zero otherwise. @end deftypefun @deftypefun int mpfr_inf_p (mpfr_t @var{op}) Return non-zero if @var{op} is plus or minus infinity, zero otherwise. @end deftypefun @deftypefun int mpfr_number_p (mpfr_t @var{op}) Return non-zero if @var{op} is an ordinary number, i.e. neither Not-a-Number nor plus or minus infinity. @end deftypefun @deftypefun void mpfr_reldiff (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) Compute the relative difference between @var{op1} and @var{op2} and store the result in @var{rop}. This function does not guarantee the exact rounding on the relative difference; it just computes abs(@var{op1}@minus{}@var{op2})/@var{op1}, using the rounding mode @var{rnd} for all operations. @end deftypefun @deftypefun int mpfr_sgn (mpfr_t @var{op}) Return a positive value if @var{op} > 0, zero if @var{op} = 0, and a negative value if @var{op} < 0. Its result is not specified when @var{op} is NaN (Not-a-Number). @end deftypefun @section Special Functions @cindex Special functions @deftypefun int mpfr_log (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the natural logarithm of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return zero when the result is exact (this occurs in fact only when @var{op} is 0, 1, or +infinity) and a non-zero value otherwise (except for rounding to nearest, the sign of the return value is that of @var{rop}-log(@var{op}). @end deftypefun @deftypefun int mpfr_exp (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the exponential of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return zero when the result is exact (this occurs in fact only when @var{op} is -infinity, 0, or +infinity), a positive value when the result is greater than the exponential of @var{op}, and a negative value when it is smaller. @end deftypefun @deftypefun int mpfr_exp2 (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to 2 power of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return zero iff the result is exact (this occurs in fact only when @var{op} is -infinity, 0, or +infinity), a positive value when the result is greater than the exponential of @var{op}, and a negative value when it is smaller. @end deftypefun @deftypefun int mpfr_cos (mpfr_t @var{cop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sin (mpfr_t @var{sop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_tan (mpfr_t @var{top}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{cop} to the cosine of @var{op}, @var{sop} to the sine of @var{op}, @var{top} to the tangent of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 0 i.e. the sine is 0, the cosine is 1, and the tangent is 0). @end deftypefun @deftypefun int mpfr_cosh (mpfr_t @var{cop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_sinh (mpfr_t @var{sop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_tanh (mpfr_t @var{top}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{cop} to the hyperbolic cosine of @var{op}, @var{sop} to the hyperbolic sine of @var{op}, @var{top} to the hyperbolic tangent of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 0 i.e. the result is 1). @end deftypefun @deftypefun int mpfr_acosh (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_asinh (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_atanh (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the inverse hyperbolic cosine, sine or tangent of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact. @end deftypefun @deftypefun int mpfr_fac_ui (mpfr_t @var{rop}, unsigned long int @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the factorial of the unsigned long int @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact. @end deftypefun @deftypefun int mpfr_log1p (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the logarithm of one plus @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 0 i.e. the result is 0). @end deftypefun @deftypefun int mpfr_expm1 (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the exponential of @var{op} minus one, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 0 i.e. the result is 0). @end deftypefun @deftypefun int mpfr_log2 (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_log10 (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the log[t] (t=2 or 10)(log x / log t) of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 1 i.e. the result is 0). @end deftypefun @deftypefun int mpfr_fma (mpfr_t @var{rop}, mpfr_t @var{opx},mpfr_t @var{opy},mpfr_t @var{opz}, mp_rnd_t @var{rnd}) Set @var{rop} to @var{opx} * @var{opy} + @var{opz}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact, a positive value if @var{rop} is larger than @var{opx} * @var{opy} + @var{opz}, and a negative value otherwise. @end deftypefun @deftypefun void mpfr_agm (mpfr_t @var{rop}, mpfr_t @var{op1}, mpfr_t @var{op2}, mp_rnd_t @var{rnd}) Set @var{rop} to the arithmetic-geometric mean of @var{op1} and @var{op2}, rounded to the direction @var{rnd} with the precision of @var{rop}. @end deftypefun @deftypefun int mpfr_asin (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) @deftypefunx int mpfr_atan (mpfr_t @var{rop}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Set @var{rop} to the arc-sine or arc-tangent of @var{op}, rounded to the direction @var{rnd} with the precision of @var{rop}. Return 0 iff the result is exact (this occurs in fact only when @var{op} is 0 i.e. the result is 0). @end deftypefun @deftypefun void mpfr_const_log2 (mpfr_t @var{rop}, mp_rnd_t @var{rnd}) Set @var{rop} to the logarithm of 2 rounded to the direction @var{rnd} with the precision of @var{rop}. This function stores the computed value to avoid another calculation if a lower or equal precision is requested. @end deftypefun @deftypefun void mpfr_const_pi (mpfr_t @var{rop}, mp_rnd_t @var{rnd}) Set @var{rop} to the value of Pi rounded to the direction @var{rnd} with the precision of @var{rop}. This function uses the Borwein, Borwein, Plouffe formula which directly gives the expansion of Pi in base 16. @end deftypefun @deftypefun void mpfr_const_euler (mpfr_t @var{rop}, mp_rnd_t @var{rnd}) Set @var{rop} to the value of Euler's constant 0.577... rounded to the direction @var{rnd} with the precision of @var{rop}. @end deftypefun @node I/O of Floats, Miscellaneous Float Functions, Float Comparison, Floating-point Functions @comment node-name, next, previous, up @section Input and Output Functions @cindex Float input and output functions @cindex Input functions @cindex Output functions @cindex I/O functions Functions that perform input from a standard input/output stream, and functions that output to a standard input/output stream. Passing a NULL pointer for a @var{stream} argument to any of these functions will make them read from @code{stdin} and write to @code{stdout}, respectively. When using any of these functions, it is a good idea to include @file{stdio.h} before @file{mpfr.h}, since that will allow @file{mpfr.h} to define prototypes for these functions. @deftypefun size_t mpfr_out_str (FILE *@var{stream}, int @var{base}, size_t @var{n_digits}, mpfr_t @var{op}, mp_rnd_t @var{rnd}) Output @var{op} on stdio stream @var{stream}, as a string of digits in base @var{base}, rounded to direction @var{rnd}. The base may vary from 2 to 36. Print at most @var{n_digits} significant digits, or if @var{n_digits} is 0, the maximum number of digits accurately representable by @var{op}. In addition to the significant digits, a decimal point at the right of the first digit and a trailing exponent, in the form @samp{eNNN}, are printed. If @var{base} is greater than 10, @samp{@@} will be used instead of @samp{e} as exponent delimiter. Return the number of bytes written, or if an error occurred, return 0. @end deftypefun @deftypefun size_t mpfr_inp_str (mpfr_t @var{rop}, FILE *@var{stream}, int @var{base}, mp_rnd_t @var{rnd}) Input a string in base @var{base} from stdio stream @var{stream}, rounded in direction @var{rnd}, and put the read float in @var{rop}. The string is of the form @samp{M@@N} or, if the base is 10 or less, alternatively @samp{MeN} or @samp{MEN}. @samp{M} is the mantissa and @samp{N} is the exponent. The mantissa is always in the specified base. The exponent is @c either in the specified base or, if @var{base} is negative, in decimal. The argument @var{base} may be in the range 2 to 36. @c , or @minus{}36 to @c @minus{}2. Negative values are used to specify that the exponent is in @c decimal. Unlike the corresponding @code{mpz} function, the base will not be determined from the leading characters of the string if @var{base} is 0. This is so that numbers like @samp{0.23} are not interpreted as octal. Return the number of bytes read, or if an error occurred, return 0. @end deftypefun @deftypefun void mpfr_print_binary (mpfr_t @var{float}) Output @var{float} on stdout in raw binary format (the exponent is in decimal, yet). The last bits from the least significant limb which do not belong to the mantissa are printed between square brackets; they should always be zero. @end deftypefun @c @deftypefun void mpfr_inp_raw (mpfr_t @var{float}, FILE *@var{stream}) @c Input from stdio stream @var{stream} in the format written by @c @code{mpfr_out_raw}, and put the result in @var{float}. @c @end deftypefun @node Miscellaneous Float Functions, , I/O of Floats, Floating-point Functions @comment node-name, next, previous, up @section Miscellaneous Functions @cindex Miscellaneous float functions @deftypefun void mpfr_ceil (mpfr_t @var{rop}, mpfr_t @var{op}) @deftypefunx void mpfr_floor (mpfr_t @var{rop}, mpfr_t @var{op}) @deftypefunx void mpfr_trunc (mpfr_t @var{rop}, mpfr_t @var{op}) Set @var{rop} to @var{op} rounded to an integer. @code{mpfr_ceil} rounds to the next higher integer, @code{mpfr_floor} to the next lower, and @code{mpfr_trunc} to the integer towards zero. @end deftypefun @deftypefun void mpfr_urandomb (mpfr_t @var{rop}, gmp_randstate_t @var{state}) Generate a uniformly distributed random float in the interval 0 <= X < 1. @end deftypefun @deftypefun void mpfr_random (mpfr_t @var{rop}) Put in @var{rop} a random float in the interval [0,1[. Random limbs are generated using the @code{random} system function. @end deftypefun @deftypefun void mpfr_random2 (mpfr_t @var{rop}, mp_size_t @var{max_size}, mp_exp_t @var{max_exp}) Generate a random float of at most @var{max_size} limbs, with long strings of zeros and ones in the binary representation. The exponent of the number is in the interval @minus{}@var{exp} to @var{exp}. 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 @var{max_size} is negative. @end deftypefun @c @deftypefun size_t mpfr_size (mpfr_t @var{op}) @c Return the size of @var{op} measured in number of limbs. If @var{op} is @c zero, the returned value will be zero. (@xref{Nomenclature}, for an @c explanation of the concept @dfn{limb}.) @c @c @strong{This function is obsolete. It will disappear from future MP @c releases.} @c @end deftypefun @section Internal Functions These functions were mainly designed for the implementation of @code{mpfr}, but may be useful for users too. You need to include @code{mpfr-impl.h} to use them. @deftypefun int mpfr_add_one_ulp (mpfr_t @var{x}, mp_rnd_t @var{rnd}) Add one unit in last place (ulp) to @var{x} if @var{x} is finite and positive, subtract one ulp if @var{x} is finite and negative; otherwise, @var{x} is not changed. The return value is zero unless an overflow occurs, in which case the @code{mpfr_add_one_ulp} function behaves like a conventional addition. @end deftypefun @deftypefun int mpfr_sub_one_ulp (mpfr_t @var{x}, mp_rnd_t @var{rnd}) Subtract one ulp to @var{x} if @var{x} is finite and positive, add one ulp if @var{x} is finite and negative; otherwise, @var{x} is not changed. The return value is zero unless an underflow occurs, in which case the @code{mpfr_sub_one_ulp} function behaves like a conventional subtraction. @end deftypefun @deftypefun int mpfr_can_round (mpfr_t @var{b}, mp_exp_t @var{err}, mp_rnd_t @var{rnd1}, mp_rnd_t @var{rnd2}, mp_prec_t @var{prec}) Assuming @var{b} is an approximation of an unknown number @var{x} in direction @var{rnd1} with error at most two to the power E(b)-@var{err} where E(b) is the exponent of @var{b}, returns 1 if one is able to round exactly @var{x} to precision @var{prec} with direction @var{rnd2}, and 0 otherwise. This function @strong{does not modify} its arguments. @end deftypefun @node Contributors, References, Floating-point Functions, Top @comment node-name, next, previous, up @unnumbered Contributors We would like to thank Jean-Michel Muller and Joris van der Hoeven for very fruitful discussions at the beginning of that project, Torbjorn Granlund and Kevin Ryde for their help about design issues and their suggestions for an easy integration into GNU MP, and Nathalie Revol for her careful reading of this documentation. Sylvie Boldo from ENS-Lyon, France, contributed the functions @code{mpfr_agm} and @code{mpfr_log}. Emmanuel Jeandel, from ENS-Lyon too, contributed the generic hypergeometric code in @code{generic.c}, as well as the @code{mpfr_exp3}, a first implementation of the sine and cosine, and improved versions of @code{mpfr_const_log2} and @code{mpfr_const_pi}. Mathieu Dutour contributed the functions @code{mpfr_atan} and @code{mpfr_asin}, David Daney contributed the hyperbolic and inverse hyperbolic functions, the base-2 exponential, and the factorial function. @node References, , Contributors, Top @comment node-name, next, previous, up @unnumbered References @itemize @bullet @item Torbjorn Granlund, "GNU MP: The GNU Multiple Precision Arithmetic Library", version 3.1, 2000. @item IEEE standard for binary floating-point arithmetic, Technical Report ANSI-IEEE Standard 754-1985, New York, 1985. Approved March 21, 1985: IEEE Standards Board; approved July 26, 1985: American National Standards Institute, 18 pages. @item Donald E. Knuth, "The Art of Computer Programming", vol 2, "Seminumerical Algorithms", 2nd edition, Addison-Wesley, 1981. @end itemize @node Concept Index, , , Top @comment node-name, next, previous, up @unnumbered Concept Index @printindex cp @node Function Index, , , Top @comment node-name, next, previous, up @unnumbered Function and Type Index @printindex fn @contents @bye