[library Boost.NumericConversion [quickbook 1.4] [authors [Cacciola Carballal, Fernando Luis]] [copyright 2004-2007 Fernando Luis Cacciola Carballal] [category numerics] [id numeric_conversion] [dirname numeric_conversion] [purpose Optimized Policy-based Numeric Conversions ] [source-mode c++] [license 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]) ] ] [/ Macros will be used for links so we have a central place to change them ] [/ Cited Boost resources ] [def __MPL_INTEGRAL_CONSTANT__ [@../../../../mpl/doc/refmanual/integral-constant.html MPL's Integral Constant] ] [/ Other web resources ] [def __SGI_UNARY_FUNCTION__ [@http://www.sgi.com/tech/stl/UnaryFunction.html Unary Function Object]] [/ Icons ] [def __NOTE__ [$images/note.png]] [def __ALERT__ [$images/caution.png]] [def __DETAIL__ [$images/note.png]] [def __TIP__ [$images/tip.png]] [def __QUESTION_MARK__ [$images/question.png]] [def __SPACE__ [$images/space.png]] [def __GO_TO__ [$images/callouts/R.png]] [section Overview] The Boost Numeric Conversion library is a collection of tools to describe and perform conversions between values of different [link boost_numericconversion.definitions.numeric_types numeric types]. The library includes a special alternative for a subset of `std::numeric_limits<>`, the [link boost_numericconversion.bounds___traits_class bounds<>] traits class, which provides a consistent way to obtain the [link boost_numericconversion.definitions.range_and_precision boundary] values for the [link boost_numericconversion.definitions.range_and_precision range] of a numeric type. It also includes a set of [link boost_numericconversion.conversion_traits___traits_class trait classes] which describes the compile-time properties of a conversion from a source to a target numeric type. Both [link boost_numericconversion.definitions.c___arithmetic_types arithmetic] and [link boost_numericconversion.definitions.numeric_types user-defined numeric types] can be used. A policy-based [link boost_numericconversion.converter___function_object converter] object which uses `conversion_traits` to select an optimized implementation is supplied. Such implementation uses an optimal range checking code suitable for the source/target combination. * The converter's out-of-range behavior can be customized via an [link boost_numericconversion.numeric_converter_policy_classes.policy_overflowhandler OverflowHandler] policy. * For floating-point to integral conversions, the rounding mode can be selected via the [link boost_numericconversion.numeric_converter_policy_classes.policy_float2introunder Float2IntRounder] policy. * A custom low-level conversion routine (for UDTs for instance) can be passed via a [link boost_numericconversion.numeric_converter_policy_classes.policy_rawconverter RawConverter] policy. * The optimized automatic range-checking logic can be overridden via a [link boost_numericconversion.numeric_converter_policy_classes.policy_userrangechecker UserRangeChecker] policy. [endsect] [include definitions.qbk] [include converter.qbk] [include requirements.qbk] [include bounds.qbk] [include conversion_traits.qbk] [include converter_policies.qbk] [include numeric_cast.qbk] [section History and Acknowledgments] [heading Pre-formal review] * Kevlin Henney, with help from David Abrahams and Beman Dawes, originally contributed the previous version of `numeric_cast<>` which already presented the idea of a runtime range check. * Later, Eric Ford, Kevin Lynch and the author spotted some genericity problems with that `numeric_cast<>` which prevented it from being used in a generic layer of math functions. * An improved `numeric_cast<>` which properly handled all combinations of arithmetic types was presented. * David Abrahams and Beman Dawes acknowledged the need of an improved version of `numeric_cast<>` and supported the submission as originally laid out. Daryl Walker and Darin Adler made some important comments and proposed fixes to the original submission. * Special thanks go to Björn Karlsoon who helped the author considerably. Having found the problems with `numeric_cast<>` himself, he revised very carefully the original submission and spot a subtle bug in the range checking implementation. He also wrote part of this documentation and proof-read and corrected other parts. And most importantly: the features now presented here in this library evolved from the original submission as a result of the useful private communications between Björn and the author. [heading Post-formal review] * Guillaume Melquiond spoted some documentation and code issues, particularly about rounding conversions. * The following people contributed an important review of the design, documentation and c ode: Kevin Lynch, Thorsten Ottosen, Paul Bristow, Daryle Walker, Jhon Torjo, Eric Ford, Gennadiy Rozental. [endsect] [section Bibliography] * Standard Documents: # ISO/IEC 14882:98 (C++98 Standard) # ISO/IEC 9899:1999 (C99 Standard) # ISO/IEC 10967-1 (Language Independent Arithmetic (LIA), Part I, 1994) # ISO/IEC 2382-1:1993 (Information Technology - Vocabulary - Part I: Fundamental Terms) # ANSI/IEEE 754-1985 [and IEC 60559:1989] (Binary floating-point) # ANSI/IEEE 854-1988 (Radix Independent floating-point) # ANSI X3/TR-1-82 (Dictionary for Information Processing Systems) # ISO/IEC JTC1/SC22/WG14/N753 C9X Revision Proposal: LIA-1 Binding: Rationale * Papers: # David Goldberg What Every Computer Scientist Should Know About Floating-Point Arithmetic # Prof. William Kahan papers on floating-point. [endsect]