| |
Boost Numeric Conversion LibraryHeader boost/numeric/conversion/converter.hpp |
namespace boost { namespace numeric {
template<class T,
class S,
class Traits, = conversion_traits<T,S>
class OverflowHandler = def_overflow_handler,
class Float2IntRounder = Trunc< typename Traits::source_type >,
class RawConverter = raw_converter<Traits>,
class UserRangeChecker = UseInternalRangeChecker
>
struct converter
{
typedef Traits traits ;
typedef typename Traits::source_type source_type ;
typedef typename Traits::argument_type argument_type ;
typedef typename Traits::result_type result_type ;
static result_type convert ( argument_type s ) ;
result_type operator() ( argument_type s ) const ;
// Internal member functions:
static range_check_result out_of_range ( argument_type s ) ;
static void validate_range ( argument_type s ) ;
static result_type low_level_convert ( argument_type s ) ;
static source_type nearbyint ( argument_type s ) ;
} ;
} } // namespace numeric, boost
boost::numeric::converter<> is a
Unary Function Object
encapsulating the code to perform a numeric conversion with the direction and properties specified
by the Traits template parameter. It can optionally take some
policies
which can be used to customize its behavior. The Traits parameter is not a policy but
the parameter that defines the conversion.
| T | The Numeric Type which is the Target of the conversion. |
| S | The Numeric Type which is the Source of the conversion. |
Traits |
This must be a conversion traits class with the interface of boost::numeric::conversion_traits |
OverflowHandler |
Stateless Policy called to administrate the result of the
range checking. It is a Function Object which receives the result of out_of_range()
and is called inside the validate_range() static member function
exposed by the converter. |
Float2IntRounder |
Stateless Policy which specifies the rounding mode used for
float to integral conversions. It supplies the nearbyint() static member function exposed
by the converter. |
RawConverter |
Stateless Policy which is used to perform the actual conversion.
It supplies the low_level_convert() static member function
exposed by the converter. |
UserRangeChecker |
Special and Optional Stateless Policy which can be used to override
the internal range checking logic. If given, supplies alternative code for the out_of_range() and validate_range() static member functions exposed by the converter. |
static result_type converter<>::convert ( argument_type s ) ; //
throw
This static member function converts an rvalue of type source_type to an rvalue of type target_type.
If the conversion requires it, it performs a range checking before the conversion and passes the result of the check to the overflow handler policy (the default policy throws an exception if out-of-range is detected)
The implementation of this function is actually built from the policies and is basically as follows:result_type converter<>::convert ( argument_type s ) { validate_range(s); // Implemented by the internal range checking logic // (which also calls the OverflowHandler policy) // or externally supplied by the UserRangeChecker policy. s = nearbyint(s); // Externally supplied by the Float2IntRounder policy. // NOTE: This is actually called only for float to int conversions. return low_level_convert(s); // Externally supplied by the RawConverter policy. }"converter<>::operator() const" just calls
convert()
static range_check_result numeric_converter<>::out_of_range (
argument_type s ) ;
This internal static member function determines if the value 's' can be represented by the target type without overflow.
It does not determine if the conversion is exact; that is, it does not detect inexact conversions, only out-of-range conversions (see the Definitions for further details).
The return value is of enum typeboost::numeric::range_check_result
The actual code for the range checking logic is optimized for the combined properties of the source and target types. For example, a non-subranged conversion (i.e: int->float), requires no range checking, so out_of_range() returns cInRange directly. See the following table for more details.
If the user supplied a UserRangeChecker policy, is this policy which implements this function, so the implementation is user defined, although it is expected to perform the same conceptual check and return the appropriate result.
static void numeric_converter<>::validate_range ( argument_type
s ) ; // no throw
This internal static member function calls
out_of_range(s), and passes the result to theOverflowHandlerpolicy class
For those Target/Source combinations which don't require range checking, this is an empty inline function.
If the user supplied a UserRangeChecker policy, is this policy which implements this function, so the implementation is user defined, although it is expected to perform the same action as the default. In particular, it is expected to pass the result of the check to the overflow handler.
static result_type numeric_converter<>::low_level_convert (
argument_type s ) ;
This internal static member function performs the actual conversion.
This function is externally supplied by theRawConverterpolicy class.
static source_type converter<>::nearbyint (
argument_type s ) ;
This internal static member function, which is only used for float to int conversions, returns an integer value of floating-point type according to some rounding direction.
This function is externally supplied by theFloat2IntRounderpolicy class which encapsulates the specific rounding mode.
Internal Member Functions: These static member functions
build the actual conversion code used by convert(). The user does
not have to call these if calling convert(), since convert() calls them infernally,
but they can be called separately for specific needs.
The Following table summarizes the internal range checking logic performed
for each combination of the properties of Source and Target.
LowestT/HighestT denotes the highest and lowest values of the Target type, respectively.
S(n) is short for "static_cast<S>(n)" (S denotes the Source
type).
"NONE" indicates that for this case there is no range checking.
int_to_int |--> sig_to_sig |--> subranged |--> ( s >= S(LowestT) ) && ( s <= S(HighestT) )
| |--> not subranged |--> NONE
|
|--> unsig_to_unsig |--> subranged |--> ( s >= S(LowestT) ) && ( s <= S(HighestT) )
| |--> not subranged |--> NONE
|
|--> sig_to_unsig |--> pos subranged |--> ( s >= S(0) ) && ( s <= S(HighestT) )
| |--> not pos subranged |--> ( s >= S(0) )
|
|--> unsig_to_sig |--> subranged |--> ( s <= S(HighestT) )
| |--> not subranged |--> NONE
int_to_float |--> NONE
float_to_int |--> round_to_zero |--> ( s > S(LowestT)-S(1) ) && ( s < S(HighestT)+S(1) )
|--> round_to_even_nearest |--> ( s >= S(LowestT)-S(0.5) ) && ( s < S(HighestT)+S(0.5) )
|--> round_to_infinity |--> ( s > S(LowestT)-S(1) ) && ( s <= S(HighestT) )
|--> round_to_neg_infinity |--> ( s >= S(LowestT) ) && ( s < S(HighestT)+S(1) )
float_to_float |--> subranged |--> ( s >= S(LowestT) ) && ( s <= S(HighestT) )
|--> not subranged |--> NONE
#include <boost/numeric/conversion/converter.hpp>
int main() {
typedef boost::numeric::converter<int,doublegt; Double2Int ;
int x = Double2Int::convert(2.0);
assert ( x == 2 );
int y = Double2Int()(3.14); // As a function object.
assert ( y == 3 ) ; // The default rounding is trunc.
try
{
double m = boost::numeric::bounds<double>::highest();
int z = Double2Int::convert(m); // By default throws positive_overflow()
}
catch ( boost::numeric::positive_overflow const& )
{
}
return 0;
}
Back to Numeric Conversion library index
Revised 16 May 2005
© Copyright Fernando Luis Cacciola Carballal, 2004
Use, modification, and distribution are subject to the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at www.boost.org/LICENSE_1_0.txt)