Doc/lib/libmpz.tex - platform/external/python/cpython2 - Gitiles

 \section{\module{mpz} ---
          GNU arbitrary magnitude integers}

 \declaremodule{builtin}{mpz}
 \modulesynopsis{Interface to the GNU MP library for arbitrary
 precision arithmetic.}


 This is an optional module.  It is only available when Python is
 configured to include it, which requires that the GNU MP software is
 installed.
 \index{MP, GNU library}
 \index{arbitrary precision integers}
 \index{integer!arbitrary precision}

 This module implements the interface to part of the GNU MP library,
 which defines arbitrary precision integer and rational number
 arithmetic routines.  Only the interfaces to the \emph{integer}
 (\function{mpz_*()}) routines are provided. If not stated
 otherwise, the description in the GNU MP documentation can be applied.

 Support for rational numbers\index{rational numbers} can be
 implemented in Python.  For an example, see the
 \module{Rat}\withsubitem{(demo module)}{\ttindex{Rat}} module, provided as
 \file{Demos/classes/Rat.py} in the Python source distribution.

 In general, \dfn{mpz}-numbers can be used just like other standard
 Python numbers, e.g., you can use the built-in operators like \code{+},
 \code{*}, etc., as well as the standard built-in functions like
 \function{abs()}, \function{int()}, \ldots, \function{divmod()},
 \function{pow()}.  \strong{Please note:} the \emph{bitwise-xor}
 operation has been implemented as a bunch of \emph{and}s,
 \emph{invert}s and \emph{or}s, because the library lacks an
 \cfunction{mpz_xor()} function, and I didn't need one.

 You create an mpz-number by calling the function \function{mpz()} (see
 below for an exact description). An mpz-number is printed like this:
 \code{mpz(\var{value})}.


 \begin{funcdesc}{mpz}{value}
   Create a new mpz-number. \var{value} can be an integer, a long,
   another mpz-number, or even a string. If it is a string, it is
   interpreted as an array of radix-256 digits, least significant digit
   first, resulting in a positive number. See also the \method{binary()}
   method, described below.
 \end{funcdesc}

 \begin{datadesc}{MPZType}
   The type of the objects returned by \function{mpz()} and most other
   functions in this module.
 \end{datadesc}


 A number of \emph{extra} functions are defined in this module. Non
 mpz-arguments are converted to mpz-values first, and the functions
 return mpz-numbers.

 \begin{funcdesc}{powm}{base, exponent, modulus}
   Return \code{pow(\var{base}, \var{exponent}) \%{} \var{modulus}}. If
   \code{\var{exponent} == 0}, return \code{mpz(1)}. In contrast to the
   \C{} library function, this version can handle negative exponents.
 \end{funcdesc}

 \begin{funcdesc}{gcd}{op1, op2}
   Return the greatest common divisor of \var{op1} and \var{op2}.
 \end{funcdesc}

 \begin{funcdesc}{gcdext}{a, b}
   Return a tuple \code{(\var{g}, \var{s}, \var{t})}, such that
   \code{\var{a}*\var{s} + \var{b}*\var{t} == \var{g} == gcd(\var{a}, \var{b})}.
 \end{funcdesc}

 \begin{funcdesc}{sqrt}{op}
   Return the square root of \var{op}. The result is rounded towards zero.
 \end{funcdesc}

 \begin{funcdesc}{sqrtrem}{op}
   Return a tuple \code{(\var{root}, \var{remainder})}, such that
   \code{\var{root}*\var{root} + \var{remainder} == \var{op}}.
 \end{funcdesc}

 \begin{funcdesc}{divm}{numerator, denominator, modulus}
   Returns a number \var{q} such that
   \code{\var{q} * \var{denominator} \%{} \var{modulus} ==
   \var{numerator}}.  One could also implement this function in Python,
   using \function{gcdext()}.
 \end{funcdesc}

 An mpz-number has one method:

 \begin{methoddesc}[mpz]{binary}{}
   Convert this mpz-number to a binary string, where the number has been
   stored as an array of radix-256 digits, least significant digit first.

   The mpz-number must have a value greater than or equal to zero,
   otherwise \exception{ValueError} will be raised.
 \end{methoddesc}
	\section{\module{mpz} ---
	GNU arbitrary magnitude integers}

	\declaremodule{builtin}{mpz}
	\modulesynopsis{Interface to the GNU MP library for arbitrary
	precision arithmetic.}


	This is an optional module. It is only available when Python is
	configured to include it, which requires that the GNU MP software is
	installed.
	\index{MP, GNU library}
	\index{arbitrary precision integers}
	\index{integer!arbitrary precision}

	This module implements the interface to part of the GNU MP library,
	which defines arbitrary precision integer and rational number
	arithmetic routines. Only the interfaces to the \emph{integer}
	(\function{mpz_*()}) routines are provided. If not stated
	otherwise, the description in the GNU MP documentation can be applied.

	Support for rational numbers\index{rational numbers} can be
	implemented in Python. For an example, see the
	\module{Rat}\withsubitem{(demo module)}{\ttindex{Rat}} module, provided as
	\file{Demos/classes/Rat.py} in the Python source distribution.

	In general, \dfn{mpz}-numbers can be used just like other standard
	Python numbers, e.g., you can use the built-in operators like \code{+},
	\code{*}, etc., as well as the standard built-in functions like
	\function{abs()}, \function{int()}, \ldots, \function{divmod()},
	\function{pow()}. \strong{Please note:} the \emph{bitwise-xor}
	operation has been implemented as a bunch of \emph{and}s,
	\emph{invert}s and \emph{or}s, because the library lacks an
	\cfunction{mpz_xor()} function, and I didn't need one.

	You create an mpz-number by calling the function \function{mpz()} (see
	below for an exact description). An mpz-number is printed like this:
	\code{mpz(\var{value})}.


	\begin{funcdesc}{mpz}{value}
	Create a new mpz-number. \var{value} can be an integer, a long,
	another mpz-number, or even a string. If it is a string, it is
	interpreted as an array of radix-256 digits, least significant digit
	first, resulting in a positive number. See also the \method{binary()}
	method, described below.
	\end{funcdesc}

	\begin{datadesc}{MPZType}
	The type of the objects returned by \function{mpz()} and most other
	functions in this module.
	\end{datadesc}


	A number of \emph{extra} functions are defined in this module. Non
	mpz-arguments are converted to mpz-values first, and the functions
	return mpz-numbers.

	\begin{funcdesc}{powm}{base, exponent, modulus}
	Return \code{pow(\var{base}, \var{exponent}) \%{} \var{modulus}}. If
	\code{\var{exponent} == 0}, return \code{mpz(1)}. In contrast to the
	\C{} library function, this version can handle negative exponents.
	\end{funcdesc}

	\begin{funcdesc}{gcd}{op1, op2}
	Return the greatest common divisor of \var{op1} and \var{op2}.
	\end{funcdesc}

	\begin{funcdesc}{gcdext}{a, b}
	Return a tuple \code{(\var{g}, \var{s}, \var{t})}, such that
	\code{\var{a}\var{s} + \var{b}\var{t} == \var{g} == gcd(\var{a}, \var{b})}.
	\end{funcdesc}

	\begin{funcdesc}{sqrt}{op}
	Return the square root of \var{op}. The result is rounded towards zero.
	\end{funcdesc}

	\begin{funcdesc}{sqrtrem}{op}
	Return a tuple \code{(\var{root}, \var{remainder})}, such that
	\code{\var{root}*\var{root} + \var{remainder} == \var{op}}.
	\end{funcdesc}

	\begin{funcdesc}{divm}{numerator, denominator, modulus}
	Returns a number \var{q} such that
	\code{\var{q} * \var{denominator} \%{} \var{modulus} ==
	\var{numerator}}. One could also implement this function in Python,
	using \function{gcdext()}.
	\end{funcdesc}

	An mpz-number has one method:

	\begin{methoddesc}[mpz]{binary}{}
	Convert this mpz-number to a binary string, where the number has been
	stored as an array of radix-256 digits, least significant digit first.

	The mpz-number must have a value greater than or equal to zero,
	otherwise \exception{ValueError} will be raised.
	\end{methoddesc}