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569 lines
22 KiB
Plaintext
569 lines
22 KiB
Plaintext
[section:fp_facets Facets for Floating-Point Infinities and NaNs]
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[import ../../example/nonfinite_facet_sstream.cpp]
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[h4 Synopsis]
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namespace boost{ namespace math
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{
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// Values for flags.
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const int legacy;
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const int signed_zero;
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const int trap_infinity;
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const int trap_nan;
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template<
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class CharType,
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class OutputIterator = std::ostreambuf_iterator<CharType>
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>
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class nonfinite_num_put : public std::num_put<CharType, OutputIterator>
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{
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public:
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explicit nonfinite_num_put(int flags = 0);
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};
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template<
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class CharType,
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class InputIterator = std::istreambuf_iterator<CharType>
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>
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class nonfinite_num_get : public std::num_get<CharType, InputIterator>
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{
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public:
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explicit nonfinite_num_get(int flags = 0); // legacy, sign_zero ...
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};
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}} // namespace boost namespace math
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To use these facets
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#include <boost\math\special_functions\nonfinite_num_facets.hpp>
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[section:facets_intro Introduction]
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[h5 The Problem]
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The C++98 standard does not specify how ['infinity] and ['NaN] are represented in text streams.
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As a result, different platforms use different string representations.
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This can cause undefined behavior when text files are moved between different platforms.
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Some platforms cannot even input parse their own output!
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So 'route-tripping' or loopback of output to input is not possible.
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For instance, the following test fails with MSVC:
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stringstream ss;
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double inf = numeric_limits<double>::infinity();
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double r;
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ss << inf; // Write out.
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ss >> r; // Read back in.
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cout << "infinity output was " << inf << endl; // 1.#INF
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cout << "infinity input was " << r << endl; // 1
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assert(inf == y); // Fails!
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[h5 The Solution]
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The facets `nonfinite_num_put` and `nonfinite_num_get`
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format and parse all floating-point numbers,
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including `infinity` and `NaN`, in a consistent and portable manner.
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The following test succeeds with MSVC.
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[nonfinite_facets_sstream_1]
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[tip To add two facets, `nonfinite_num_put` and `nonfinite_num_get`,
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you may have to add one at a time, using a temporary locale.
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Or you can create a new locale in one step
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`std::locale new_locale(std::locale(std::locale(std::locale(), new boost::math::nonfinite_num_put<char>), new boost::math::nonfinite_num_get<char>));`
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and, for example, use it to imbue an input and output stringstream.
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]
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[tip To just change an input or output stream, you can concisely write
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`cout.imbue (std::locale(std::locale(), new boost::math::nonfinite_num_put<char>));`
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or
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`cin.imbue (std::locale(std::locale(), new boost::math::nonfinite_num_get<char>));`
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]
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[nonfinite_facets_sstream_2]
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[h4 C++0X standard for output of infinity and NaN]
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[@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2011/n3242.pdf C++0X (final) draft standard]
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does not explicitly specify the representation (and input) of nonfinite values,
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leaving it implementation-defined.
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So without some specific action, input and output of nonfinite values is not portable.
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[h4 C99 standard for output of infinity and NaN]
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The [@http://www.open-std.org/JTC1/SC22/WG14/www/docs/n1256.pdf C99 standard]
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[*does] specify how infinity and NaN
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are formatted by printf and similar output functions,
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and parsed by scanf and similar input functions.
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The following string representations are used:
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[table C99 Representation of Infinity and NaN
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[[number] [string]]
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[[Positive infinity]["inf" or "infinity"]]
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[[Positive NaN]["nan" or "nan(...)"]]
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[[Negative infinity]["-inf" or "-infinity"]]
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[[Negative NaN]["-nan" or "-nan(...)"]]
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]
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So following C99 provides a sensible 'standard' way
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of handling input and output of nonfinites in C++,
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and this implementation follows most of these formats.
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[h5 Signaling NaNs]
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A particular type of NaN is the signaling NaN.
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The usual mechanism of signaling is by raising a floating-point exception.
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Signaling NaNs are defined by
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[@http://en.wikipedia.org/wiki/IEEE_floating-point_standard IEEE 754-2008].
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Floating-point values with layout ['s]111 1111 1['a]xx xxxx xxxx xxxx xxxx xxxx
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where ['s] is the sign, ['x] is the payload, and bit ['a] determines the type of NaN.
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If bit ['a] = 1, it is a quiet NaN.
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If bit ['a] is zero and the payload ['x] is nonzero, then it is a signaling NaN.
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Although there has been theoretical interest in the ability of a signaling NaN
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to raise an exception, for example to prevent use of an uninitialised variable,
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in practice there appears to be no useful application of signaling NaNs for
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most current processors.
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[@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2011/n3242.pdf C++0X 18.3.2.2]
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still specifies a (implementation-defined) representation for signaling NaN,
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and `static constexpr bool has_signaling_NaN`
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a method of checking if a floating-point type has a representation for signaling NaN.
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But in practice, most platforms treat signaling NaNs in the same as quiet NaNs.
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So, for example, they are represented by "nan" on output in
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[@http://www.open-std.org/JTC1/SC22/WG14/www/docs/n1256.pdf C99] format,
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and output as `1.#QNAN` by Microsoft compilers.
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[note The C99 standard does not distinguish
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between the quiet NaN and signaling NaN values.
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A quiet NaN propagates through almost every arithmetic operation
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without raising a floating-point exception;
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a signaling NaN generally raises a floating-point exception
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when occurring as an arithmetic operand.
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C99 specification does not define the behavior of signaling NaNs.
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NaNs created by IEC 60559 operations are always quiet.
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Therefore this implementation follows C99, and treats the signaling NaN bit
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as just a part of the NaN payload field.
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So this implementation does not distinguish between the two classes of NaN.]
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[note An implementation may give zero and non-numeric values (such as infinities and NaNs)
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a sign or may leave them unsigned. Wherever such values are unsigned,
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any requirement in the C99 Standard to retrieve the sign shall produce an unspecified sign,
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and any requirement to set the sign shall be ignored.
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This might apply to user-defined types, but in practice built-in floating-point
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types `float`, `double` and `long double` have well-behaved signs.]
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The numbers can be of type `float`, `double` and `long double`.
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An optional + sign can be used with positive numbers (controlled by ios manipulator `showpos`).
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The function `printf` and similar C++ functions use standard formatting flags
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to put all lower or all upper case
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(controlled by `std::ios` manipulator `uppercase` and `lowercase`).
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The function `scanf` and similar input functions are case-insensitive.
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The dots in `nan(...)` stand for an arbitrary string.
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The meaning of that string is implementation dependent.
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It can be used to convey extra information about the NaN, from the 'payload'.
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A particular value of the payload might be used to indicate a ['missing value], for example.
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This library uses the string representations specified by the C99 standard.
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An example of an implementation that optionally includes the NaN payload information is at
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[@http://publib.boulder.ibm.com/infocenter/zos/v1r10/index.jsp?topic=/com.ibm.zos.r10.bpxbd00/fprints.htm AIX NaN fprintf].
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That implementation specifies for Binary Floating Point NANs:
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* A NaN ordinal sequence is a left-parenthesis character '(',
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followed by a digit sequence representing
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an integer n, where 1 <= n <= INT_MAX-1,
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followed by a right-parenthesis character ')'.
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* The integer value, n, is determined by the fraction bits of the NaN argument value as follows:
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* For a signalling NaN value, NaN fraction bits are reversed (left to right)
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to produce bits (right to left) of an even integer value, 2*n.
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Then formatted output functions produce a (signalling) NaN ordinal sequence
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corresponding to the integer value n.
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* For a quiet NaN value, NaN fraction bits are reversed (left to right)
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to produce bits (right to left) of an odd integer value, 2*n-1.
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Then formatted output functions produce a (quiet) NaN ordinal sequence
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corresponding to the integer value n.
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[warning This implementation does not (yet) provide output of, or access to, the NaN payload.]
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[endsect] [/section:intro Introduction]
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[section:reference Reference]
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[h5 The Facet `nonfinite_num_put`]
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template<
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class CharType, class OutputIterator = std::ostreambuf_iterator<CharType>
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>
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class nonfinite_num_put;
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The `class nonfinite_num_put<CharType, OutputIterator>`
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is derived from `std::num_put<CharType, OutputIterator>`.
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Thus it is a facet that formats numbers.
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The first template argument is the character type of the formatted strings,
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usually `char` or `wchar_t`.
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The second template argument is the type of iterator used to write the strings.
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It is required to be an output iterator.
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Usually the default `std::ostreambuf_iterator` is used.
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The public interface of the class consists of a single constructor only:
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nonfinite_num_put(int flags = 0);
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The flags argument (effectively optional because a default of ` no_flags` is provided)
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is discussed below.
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The class template `nonfinite_num_put` is defined in the
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header `boost/math/nonfinite_num_facets.hpp`
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and lives in the namespace `boost::math`.
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Unlike the C++ Standard facet `std::num_put`, the facet `nonfinite_num_put`
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formats `infinity` and `NaN` in a consistent and portable manner.
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It uses the following string representations:
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[table
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[[Number][String]]
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[[Positive infinity][inf]]
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[[Positive NaN][nan]]
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[[Negative infinity][-inf]]
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[[Negative NaN][-nan]]
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]
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The numbers can be of type `float`, `double` and `long double`.
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The strings can be in all lower case or all upper case.
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An optional + sign can be used with positive numbers.
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This can be controlled with the `uppercase`, `lowercase`, `showpos` and `noshowpos` manipulators.
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Formatting of integers, boolean values and finite floating-point numbers is simply delegated to the normal `std::num_put`.
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[h5 Facet `nonfinite_num_get`]
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template<class CharType, class InputIterator = std::istreambuf_iterator<CharType> > class nonfinite_num_get;
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The class `nonfinite_num_get<CharType, InputIterator>` is derived from `std::num_get<CharType, IntputIterator>`.
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Thus it is a facet that parses strings that represent numbers.
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The first template argument is the character type of the strings,
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usually `char` or `wchar_t`.
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The second template argument is the type of iterator used to read the strings.
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It is required to be an input iterator. Usually the default is used.
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The public interface of the class consists of a single constructor only:
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nonfinite_num_get(int flags = 0);
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The flags argument is discussed below.
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The `class template nonfinite_num_get` is defined
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in the header `boost/math/nonfinite_num_facets.hpp`
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and lives in the `namespace boost::math`.
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Unlike the facet `std::num_get`, the facet `nonfinite_num_get` parses strings
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that represent `infinity` and `NaN` in a consistent and portable manner.
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It recognizes precisely the string representations specified by the C99 standard:
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[table
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[[Number][String]]
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[[Positive infinity][inf, infinity]]
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[[Positive NaN][nan, nan(...)]]
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[[Negative infinity][-inf, -infinity]]
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[[Negative NaN][-nan, -nan(...)]]
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]
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The numbers can be of type `float`, `double` and `long double`.
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The facet is case-insensitive. An optional + sign can be used with positive numbers.
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The dots in nan(...) stand for an arbitrary string usually containing the ['NaN payload].
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Parsing of strings that represent integers, boolean values
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and finite floating-point numbers is delegated to `std::num_get`.
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When the facet parses a string that represents `infinity` on a platform that lacks infinity,
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then the fail bit of the stream is set.
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When the facet parses a string that represents `NaN` on a platform that lacks NaN,
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then the fail bit of the stream is set.
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[h4 Flags]
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The constructors for `nonfinite_num_put` and `nonfinite_num_get`
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take an optional bit flags argument.
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There are four different bit flags:
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* legacy
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* signed_zero
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* trap_infinity
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* trap_nan
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The flags can be combined with the OR `operator|`.
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The flags are defined in the header `boost/math/nonfinite_num_facets.hpp`
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and live in the `namespace boost::math`.
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[h5 legacy]
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The legacy flag has no effect with the output facet `nonfinite_num_put`.
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If the legacy flag is used with the `nonfinite_num_get` input facet,
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then the facet will recognize all the following string representations of `infinity` and `NaN`:
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[table
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[[Number][String]]
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[[Positive infinity][inf, infinity, one#inf]]
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[[Positive NaN][nan, nan(...), nanq, nans, qnan, snan, one#ind, one#qnan, one#snan]]
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[[Negative infinity][-inf, -infinity, -one#inf]]
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[[Negative NaN][-nan, -nan(...), -nanq, -nans, -qnan, -snan, -one#ind, - one#qnan, -one#snan]]
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]
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* The numbers can be of type `float`, `double` and `long double`.
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* The facet is case-insensitive.
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* An optional `+` sign can be used with the positive values.
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* The dots in `nan(...)` stand for an arbitrary string.
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* `one` stands for any string that `std::num_get` parses as the number `1`,
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typically "1.#INF", "1.QNAN" but also "000001.#INF"...
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The list includes a number of non-standard string representations of infinity and NaN
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that are used by various existing implementations of the C++ standard library,
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and also string representations used by other programming languages.
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[h5 signed_zero]
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If the `signed_zero` flag is used with `nonfinite_num_put`,
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then the facet will always distinguish between positive and negative zero.
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It will format positive zero as "0" or "+0" and negative zero as "-0".
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The string representation of positive zero can be controlled
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with the `showpos` and `noshowpos` manipulators.
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The `signed_zero flag` has no effect with the input facet `nonfinite_num_get`.
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The input facet `nonfinite_num_get` always parses "0" and "+0"
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as positive zero and "-0" as negative zero,
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as do most implementations of `std::num_get`.
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[note If the `signed_zero` flag is not set (the default), then a negative zero value
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will be displayed on output in whatever way the platform normally handles it.
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For most platforms, this it will format positive zero as "0" or "+0" and negative zero as "-0".
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But setting the `signed_zero` flag may be more portable.]
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[tip A negative zero value can be portably produced using the changesign function
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`(changesign)(static_cast<ValType>(0))` where `ValType` is `float`, `double` or `long double`,
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or a User-Defined floating-point type (UDT) provided that this UDT has a sign
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and that the changesign function is implemented.]
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[h5 trap_infinity]
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If the `trap_infinity` flag is used with `nonfinite_num_put`,
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then the facet will throw an exception of type `std::ios_base::failure`
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when an attempt is made to format positive or negative infinity.
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If the facet is called from a stream insertion operator,
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then the stream will catch that exception and set either its `fail bit` or its `bad bit`.
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Which bit is set is platform dependent.
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If the `trap_infinity` flag is used with `nonfinite_num_get`,
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then the facet will set the `fail bit` of the stream when an attempt is made
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to parse a string that represents positive or negative infinity.
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(See Design Rationale below for a discussion of this inconsistency.)
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[h5 trap_nan]
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Same as `trap_infinity`, but positive and negative NaN are trapped instead.
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[endsect] [/section:reference Reference]
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[section:examples Examples]
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[h5 Simple example with std::stringstreams]
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[nonfinite_facets_sstream_1]
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[nonfinite_facets_sstream_2]
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[h5 Use with lexical_cast]
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[note From Boost 1.48, lexical_cast no longer uses stringstreams internally,
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and is now able to handle infinities and NaNs natively on most platforms.]
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Without using a new locale that contains the nonfinite facets,
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previous versions of `lexical_cast` using stringstream were not portable
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(and often failed) if nonfinite values are found.
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[nonfinite_facets_sstream_1]
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Although other examples imbue individual streams with the new locale,
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for the streams constructed inside lexical_cast,
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it was necesary to assign to a global locale.
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locale::global(new_locale);
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`lexical_cast` then works as expected, even with infinity and NaNs.
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double x = boost::lexical_cast<double>("inf");
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assert(x == std::numeric:limits<double>::infinity());
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string s = boost::lexical_cast<string>(numeric_limits<double>::infinity());
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assert(s == "inf");
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[warning If you use stringstream inside your functions,
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you may still need to use a global locale to handle nonfinites correctly.
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Or you need to imbue your stringstream with suitable get and put facets.]
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[warning You should be aware that the C++ specification does not explicitly require
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that input from decimal digits strings converts with rounding to the
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nearest representable floating-point binary value.
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(In contrast, decimal digits read by the compiler,
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for example by an assignment like `double d = 1.234567890123456789`,
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are guaranteed to assign the nearest representable value to double d).
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This implies that, no matter how many decimal digits you provide,
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there is a potential uncertainty of 1 least significant bit in the resulting binary value.]
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See [@http://en.wikipedia.org/wiki/Floating_point#Representable_numbers.2C_conversion_and_rounding conversion and rounding]
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for more information on ['nearest representable] and ['rounding] and
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[@http://www.exploringbinary.com/ Exploring Binary] for much detail on input and round-tripping difficulties.
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Most iostream libraries do in fact achieve the desirable
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['nearest representable floating-point binary value] for all values of input.
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However one popular STL library does not quite achieve this for 64-bit doubles. See
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[@http://connect.microsoft.com/VisualStudio/feedback/details/98770/decimal-digit-string-input-to-double-may-be-1-bit-wrong
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Decimal digit string input to double may be 1 bit wrong] for the bizarre full details.
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If you are expecting to 'round-trip' `lexical_cast` or `serialization`,
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for example archiving and loading,
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and want to be [*absolutely certain that you will
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always get an exactly identical double value binary pattern],
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you should use the suggested 'workaround' below that is believed to work on all platforms.
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You should output using all potentially significant decimal digits,
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by setting stream precision to `std::numeric_limits<double>::max_digits10`,
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(or for the appropriate floating-point type, if not double)
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and crucially, [*require `scientific` format], not `fixed` or automatic (default), for example:
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double output_value = any value;
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std::stringstream s;
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s << setprecison(std::numeric_limits<double>::max_digits10) << scientific << output_value;
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s >> input_value;
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[h4 Use with serialization archives]
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It is vital that the same locale is used
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when an archive is saved and when it is loaded.
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Otherwise, loading the archive may fail.
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By default, archives are saved and loaded with a classic C locale
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with a `boost::archive::codecvt_null` facet added.
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Normally you do not have to worry about that.
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The constructors for the archive classes, as a side-effect,
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imbue the stream with such a locale.
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However, if you want to use the
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facets `nonfinite_num_put` and `nonfinite_num_get` with archives,
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then you have to manage the locale manually.
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That is done by calling the archive constructor with the flag
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`boost::archive::no_codecvt`, thereby ensuring that the archive constructor
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will [*not imbue the stream with a new locale].
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The following code shows how to use `nonfinite_num_put` with a `text_oarchive`.
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locale default_locale(locale::classic(), new boost::archive::codecvt_null<char>);
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locale my_locale(default_locale, new nonfinite_num_put<char>);
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ofstream ofs("test.txt");
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ofs.imbue(my_locale);
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boost::archive::text_oarchive oa(ofs, no_codecvt);
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double x = numeric_limits<double>::infinity();
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oa & x;
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The same method works with `nonfinite_num_get` and `text_iarchive`.
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If you use the `nonfinite_num_put` with `trap_infinity`
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and/or `trap_nan` flag with a serialization archive,
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then you must set the exception mask of the stream.
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Serialization archives do not check the stream state.
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[h5 Other examples]
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[@../../example/nonfinite_facet_simple.cpp nonfinite_facet_simple.cpp]
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give some more simple demonstrations of the difference between using classic C locale
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and constructing a C99 infinty and NaN compliant locale for input and output.
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See [@../../example/nonfinite_facet_sstream.cpp nonfinite_facet_sstream.cpp]
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for this example of use with `std::stringstream`s.
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For an example of how to enforce the MSVC 'legacy'
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"1.#INF" and "1.#QNAN" representations of infinity and NaNs,
|
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for input and output,
|
|
see [@../../example/nonfinite_legacy.cpp nonfinite_legacy.cpp].
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Treatment of signaling NaN is demonstrated at
|
|
[@../../example/nonfinite_signaling_NaN.cpp]
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Example [@../../example/nonfinite_loopback_ok.cpp] shows loopback works OK.
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Example [@../../example/nonfinite_num_facet.cpp] shows output and re-input
|
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of various finite and nonfinite values.
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A simple example of trapping nonfinite output is at
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|
[@../../example/nonfinite_num_facet_trap.cpp nonfinite_num_facet_trap.cpp].
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|
A very basic example of using Boost.Archive is at
|
|
[@../../example/nonfinite_serialization_archives.cpp].
|
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|
|
A full demonstration of serialization by Francois Mauger is at
|
|
[@../../example/nonfinite_num_facet_serialization.cpp]
|
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[endsect] [/section:examples Examples]
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[section:portability Portability]
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This library uses the floating-point number classification and sign-bit from Boost.Math library,
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|
and should work on all platforms where that library works.
|
|
See the portability information for that library.
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[endsect] [/section:portability Portability]
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|
[section:rationale Design Rationale]
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|
* The flags are implemented as a const data member of the facet.
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Facets are reference counted, and locales can share facets.
|
|
Therefore changing the flags of a facet would have effects that are hard to predict.
|
|
An alternative design would be to implement the flags
|
|
using `std::ios_base::xalloc` and `std::ios_base::iword`.
|
|
Then one could safely modify the flags, and one could define manipulators that do so.
|
|
However, for that to work with dynamically linked libraries,
|
|
a `.cpp` file would have to be added to the library.
|
|
It was judged be more desirable to have a header-only library,
|
|
than to have mutable flags and manipulators.
|
|
|
|
* The facet `nonfinite_num_put` throws an exception when
|
|
the `trap_infinity` or `trap_nan` flag is set
|
|
and an attempt is made to format infinity or NaN.
|
|
It would be better if the facet set the `fail bit` of the stream.
|
|
However, facets derived from `std::num_put` do not have access to the stream state.
|
|
|
|
[endsect] [/section:rationale Design Rationale]
|
|
|
|
[endsect] [/section:fp_facets Facets for Floating-Point Infinities and NaNs]
|
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[/
|
|
Copyright Johan Rade and Paul A. Bristow 2011.
|
|
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).
|
|
]
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