[/ Copyright 2011 - 2020 John Maddock. Copyright 2013 - 2019 Paul A. Bristow. Copyright 2013 Christopher Kormanyos. Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt). ] [section:gmp_float gmp_float] `#include ` namespace boost{ namespace multiprecision{ template class gmp_float; typedef number > mpf_float_50; typedef number > mpf_float_100; typedef number > mpf_float_500; typedef number > mpf_float_1000; typedef number > mpf_float; }} // namespaces The `gmp_float` back-end is used in conjunction with `number` : it acts as a thin wrapper around the [gmp] `mpf_t` to provide an real-number type that is a drop-in replacement for the native C++ floating-point types, but with much greater precision. Type `gmp_float` can be used at fixed precision by specifying a non-zero `Digits10` template parameter, or at variable precision by setting the template argument to zero. The typedefs mpf_float_50, mpf_float_100, mpf_float_500, mpf_float_1000 provide arithmetic types at 50, 100, 500 and 1000 decimal digits precision respectively. The typedef mpf_float provides a variable precision type whose precision can be controlled via the `number`s member functions. [note This type only provides standard library and `numeric_limits` support when the precision is fixed at compile time.] As well as the usual conversions from arithmetic and string types, instances of `number >` are copy constructible and assignable from: * The [gmp] native types `mpf_t`, `mpz_t`, `mpq_t`. * The `number` wrappers around those types: `number >`, `number`, `number`. It's also possible to access the underlying `mpf_t` via the `data()` member function of `gmp_float`. Things you should know when using this type: * Default constructed `gmp_float`s have the value zero (this is the [gmp] library's default behavior). * No changes are made to the [gmp] library's global settings, so this type can be safely mixed with existing [gmp] code. * This backend supports rvalue-references and is move-aware, making instantiations of `number` on this backend move aware. * It is not possible to round-trip objects of this type to and from a string and get back exactly the same value. This appears to be a limitation of [gmp]. * Since the underlying [gmp] types have no notion of infinities or NaNs, care should be taken to avoid numeric overflow or division by zero. That latter will result in a std::overflow_error being thrown, while generating excessively large exponents may result in instability of the underlying [gmp] library (in testing, converting a number with an excessively large or small exponent to a string caused [gmp] to segfault). * This type can equally be used with [mpir] as the underlying implementation - indeed that is the recommended option on Win32. * Conversion from a string results in a `std::runtime_error` being thrown if the string can not be interpreted as a valid floating-point number. * Division by zero results in a `std::overflow_error` being thrown. [h5 [gmp] example:] [mpf_eg] [endsect]