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|
// -*- C++ -*-
//=============================================================================
/**
* @file Truncate.h
*
* $Id$
*
* @author Steve Huston <shuston@riverace.com>
* @author Ossama Othman <ossama_othman at symantec dot com>
* @author Russell Mora <russell_mora at symantec dot com>
*/
//=============================================================================
#ifndef ACE_TRUNCATE_H
#define ACE_TRUNCATE_H
#include /**/ "ace/pre.h"
#include "ace/config-all.h"
#if !defined (ACE_LACKS_PRAGMA_ONCE)
# pragma once
#endif /* ACE_LACKS_PRAGMA_ONCE */
#include "ace/Global_Macros.h"
#include "ace/If_Then_Else.h"
#include "ace/Numeric_Limits.h"
#if defined (__BORLANDC__) && __BORLANDC__ <= 0x582
# include "ace/Basic_Types.h"
#endif /* __BORLANDC__ <= 0x582 */
ACE_BEGIN_VERSIONED_NAMESPACE_DECL
namespace ACE_Utils
{
#if !defined (__BORLANDC__) || __BORLANDC__ > 0x582
template<typename T> struct Sign_Check;
// Specialize the unsigned signed cases.
template<> struct Sign_Check<unsigned char> { ACE_STATIC_CONSTANT (bool, is_signed = 0); };
template<> struct Sign_Check<unsigned short> { ACE_STATIC_CONSTANT (bool, is_signed = 0); };
template<> struct Sign_Check<unsigned int> { ACE_STATIC_CONSTANT (bool, is_signed = 0); };
template<> struct Sign_Check<unsigned long> { ACE_STATIC_CONSTANT (bool, is_signed = 0); };
#ifndef ACE_LACKS_LONGLONG_T
# ifdef __GNUC__
// Silence g++ "-pedantic" warnings regarding use of "long long"
// type.
__extension__
# endif /* __GNUC__ */
template<> struct Sign_Check<unsigned long long> { ACE_STATIC_CONSTANT (bool, is_signed = 0); };
#endif /* !ACE_LACKS_LONGLONG_T */
// Specialize the signed cases.
template<> struct Sign_Check<signed char> { ACE_STATIC_CONSTANT (bool, is_signed = 1); };
template<> struct Sign_Check<signed short> { ACE_STATIC_CONSTANT (bool, is_signed = 1); };
template<> struct Sign_Check<signed int> { ACE_STATIC_CONSTANT (bool, is_signed = 1); };
template<> struct Sign_Check<signed long> { ACE_STATIC_CONSTANT (bool, is_signed = 1); };
#ifndef ACE_LACKS_LONGLONG_T
# ifdef __GNUC__
// Silence g++ "-pedantic" warnings regarding use of "long long"
// type.
__extension__
# endif /* __GNUC__ */
template<> struct Sign_Check<signed long long> { ACE_STATIC_CONSTANT (bool, is_signed = 1); };
#endif /* !ACE_LACKS_LONGLONG_T */
// -----------------------------------------------------
/**
* @struct To_Unsigned
*
* @brief Retrieve unsigned counterpart to given type or value.
*
* Retrieve unsigned counterpart to given type or value.
*/
template<typename T> struct To_Unsigned;
template<>
struct To_Unsigned<unsigned char>
{
typedef unsigned char unsigned_type;
unsigned_type operator() (unsigned_type x) { return x; }
};
template<>
struct To_Unsigned<unsigned short>
{
typedef unsigned short unsigned_type;
unsigned_type operator() (unsigned_type x) { return x; }
};
template<>
struct To_Unsigned<unsigned int>
{
typedef unsigned int unsigned_type;
unsigned_type operator() (unsigned_type x) { return x; }
};
template<>
struct To_Unsigned<unsigned long>
{
typedef unsigned long unsigned_type;
unsigned_type operator() (unsigned_type x) { return x; }
};
#ifndef ACE_LACKS_LONGLONG_T
# ifdef __GNUC__
// Silence g++ "-pedantic" warnings regarding use of "long long"
// type.
__extension__
# endif /* __GNUC__ */
template<>
struct To_Unsigned<unsigned long long>
{
typedef unsigned long long unsigned_type;
unsigned_type operator() (unsigned_type x) { return x; }
};
#endif /* !ACE_LACKS_LONGLONG_T */
// ----------------
template<>
struct To_Unsigned<signed char>
{
typedef signed char signed_type;
typedef unsigned char unsigned_type;
unsigned_type operator() (signed_type x)
{
return static_cast<unsigned_type> (x);
}
};
template<>
struct To_Unsigned<signed short>
{
typedef signed short signed_type;
typedef unsigned short unsigned_type;
unsigned_type operator() (signed_type x)
{
return static_cast<unsigned_type> (x);
}
};
template<>
struct To_Unsigned<signed int>
{
typedef signed int signed_type;
typedef unsigned int unsigned_type;
unsigned_type operator() (signed_type x)
{
return static_cast<unsigned_type> (x);
}
};
template<>
struct To_Unsigned<signed long>
{
typedef signed long signed_type;
typedef unsigned long unsigned_type;
unsigned_type operator() (signed_type x)
{
return static_cast<unsigned_type> (x);
}
};
#ifndef ACE_LACKS_LONGLONG_T
# ifdef __GNUC__
// Silence g++ "-pedantic" warnings regarding use of "long long"
// type.
__extension__
# endif /* __GNUC__ */
template<>
struct To_Unsigned<signed long long>
{
typedef signed long long signed_type;
typedef unsigned long long unsigned_type;
unsigned_type operator() (signed_type x)
{
return static_cast<unsigned_type> (x);
}
};
#endif /* !ACE_LACKS_LONGLONG_T */
// -----------------------------------------------------
/**
* @struct Safe_Comparator
*
* @brief Conservative comparison of types that may not be safely
* promoted and/or converted to each other.
*
* The comparison operations provided by this structure perform
* negative value checking when necessary to prevent wrap-around
* when explicitly casting to an unsigned type.
*
* @internal This structure is not meant for general use.
*/
template<typename LEFT,
typename RIGHT,
bool IS_LEFT_SIGNED,
bool IS_RIGHT_SIGNED> struct Safe_Comparator;
// LEFT: signed, RIGHT: unsigned
template<typename LEFT, typename RIGHT>
struct Safe_Comparator<LEFT, RIGHT, true, false>
{
static bool greater_than (LEFT lhs, RIGHT rhs)
{
// Prevent wrap-around when casting to unsigned.
if (lhs < 0)
return false; // since rhs is always positive
else
{
// Implicit promotion of unsigned LEFT and RIGHT types here.
return To_Unsigned<LEFT>() (lhs) > rhs;
}
}
};
// LEFT: unsigned, RIGHT: signed
template<typename LEFT, typename RIGHT>
struct Safe_Comparator<LEFT, RIGHT, false, true>
{
static bool greater_than (LEFT lhs, RIGHT rhs)
{
// Prevent wrap-around when casting to unsigned.
if (rhs < 0)
return true; // since lhs is always positive
else
{
// Implicit promotion of unsigned LEFT and RIGHT types here.
return lhs > To_Unsigned<RIGHT>() (rhs);
}
}
};
// LEFT: unsigned, RIGHT: unsigned
template<typename LEFT, typename RIGHT>
struct Safe_Comparator<LEFT, RIGHT, false, false>
{
static bool greater_than (LEFT lhs, RIGHT rhs)
{
// Implicit promotion of unsigned LEFT and RIGHT types here.
return lhs > rhs;
}
};
// LEFT: signed, RIGHT: signed
template<typename LEFT, typename RIGHT>
struct Safe_Comparator<LEFT, RIGHT, true, true>
{
static bool greater_than (LEFT lhs, RIGHT rhs)
{
// Implicit promotion of signed LEFT and RIGHT types here.
return lhs > rhs;
}
};
// -----------------------------------------------------
/**
* @struct Fast_Comparator
*
* @brief Quick comparison of types that can be safely promoted
* and/or converted to each other.
*
* The comparison operations provided by this structure perform no
* negative value checking, meaning it is not applicable to all
* types. Check the value of the @c USABLE enumerator to determine
* if it applies to the types in question.
*
* @internal This structure is not meant for general use.
*/
template<typename LEFT, typename RIGHT>
struct Fast_Comparator
{
ACE_STATIC_CONSTANT (
bool,
USE_LEFT = ((sizeof (LEFT) > sizeof (RIGHT)
&& (Sign_Check<LEFT>::is_signed == 1
|| Sign_Check<RIGHT>::is_signed == 0))
// The following is basically the case where LEFT
// and RIGHT are the same integral type.
|| (sizeof (LEFT) == sizeof (RIGHT)
// Can't portably do
// Sign_Check<LEFT>::is_signed ==
// Sign_Check<RIGHT>::is_signed,
// i.e. comparison of anonymous enumerations,
// without triggering a compiler diagnostic
// so expand the comparison.
&& ((Sign_Check<LEFT>::is_signed == 1
&& Sign_Check<RIGHT>::is_signed == 1)
|| (Sign_Check<LEFT>::is_signed == 0
&& Sign_Check<RIGHT>::is_signed == 0)))));
ACE_STATIC_CONSTANT (
bool,
USE_RIGHT = (sizeof (RIGHT) > sizeof (LEFT)
&& (Sign_Check<RIGHT>::is_signed == 1
|| Sign_Check<LEFT>::is_signed == 0)));
ACE_STATIC_CONSTANT (bool, USABLE = (USE_LEFT || USE_RIGHT));
typedef typename ACE::If_Then_Else<
USE_LEFT,
LEFT,
typename ACE::If_Then_Else<
USE_RIGHT,
RIGHT,
void>::result_type>::result_type promote_type;
static bool greater_than (LEFT lhs, RIGHT rhs)
{
// The explicit cast is assumed to change the type of rhs without
// changing its value.
return
(static_cast<promote_type> (lhs) > static_cast<promote_type> (rhs));
}
};
// -----------------------------------------------------
/**
* @struct Comparator
*
* @brief Structure that provides optimal comparison operation for
* given types.
*
* The comparison operations provided by this structure are chosen
* at compile time based on the signs and sizes of types being
* compared.
* @par
* Comparisons of values with the same sign or those with types that
* can be promoted safely are done quickly, without any range
* checking.
* @par
* Comparisons of values of different types that cannot be safely
* promoted incur an additional check for a negative value to allow
* the compiler to perform the appropriate implicit unsigned type
* promotion.
*
* @note In general, the operations found in this structure should
* not be used to work around compiler diagnostics regarding
* comparison of signed and unsigned types. Verify that your
* types are correct before relying on those operations.
*
* @internal This structure is not meant for general use.
*/
template<typename LEFT, typename RIGHT>
struct Comparator
{
typedef typename ACE::If_Then_Else<
Fast_Comparator<LEFT, RIGHT>::USABLE,
Fast_Comparator<LEFT, RIGHT>,
Safe_Comparator<LEFT,
RIGHT,
Sign_Check<LEFT>::is_signed,
Sign_Check<RIGHT>::is_signed> >::result_type comp_type;
};
// -----------------------------------------------------
/**
* @struct Truncator
*
* @brief Truncate value of type @c FROM to value of type @c TO.
*
* Truncate a value of type @c FROM to value of type @c TO, if the
* value is larger than the maximum of value of type @c TO.
*/
template<typename FROM, typename TO>
struct Truncator
{
ACE_STATIC_CONSTANT (
bool,
// max FROM always greater than max TO
MAX_FROM_GT_MAX_TO = (sizeof(FROM) > sizeof (TO)
|| (sizeof(FROM) == sizeof (TO)
&& Sign_Check<FROM>::is_signed == 0)));
typedef typename ACE::If_Then_Else<
MAX_FROM_GT_MAX_TO,
FROM,
TO>::result_type comp_to_type;
// Take advantage of knowledge that we're casting a positive value
// to a type large enough to hold it so that we can bypass
// negative value checks at compile-time. Otherwise fallback on
// the safer comparison.
typedef typename ACE::If_Then_Else<
MAX_FROM_GT_MAX_TO,
Fast_Comparator<FROM, comp_to_type>,
typename Comparator<FROM, comp_to_type>::comp_type>::result_type comparator;
/// Truncate a value of type @c FROM to value of type @c TO, if
/// the value is larger than the maximum of value of type @c TO.
TO operator() (FROM val)
{
return
(comparator::greater_than (val, ACE_Numeric_Limits<TO>::max ())
? ACE_Numeric_Limits<TO>::max ()
: static_cast<TO> (val));
}
};
// Partial specialization for the case where the types are the same.
// No truncation is necessary.
template<typename T>
struct Truncator<T, T>
{
T operator() (T val)
{
return val;
}
};
// -----------------------------------------------------
/**
* @struct Noop_Truncator
*
* @brief No-op truncation.
*
* This structure/functor performs no truncation since it assumes
* that @c sizeof(FROM) @c < @c sizeof(TO), meaning that
* @c numeric_limits<FROM>::max() @c < @c numeric_limits<TO>::max().
*/
template<typename FROM, typename TO>
struct Noop_Truncator
{
TO operator() (FROM val)
{
return static_cast<TO> (val);
}
};
// -----------------------------------------------------
/**
* @class Truncate
*
* @brief Helper function to truncate an integral value to the
* maximum value of the given type.
*
* Very useful since ACE methods return @c int very often and
* the value's source is often a different-size integral
* type, such as @c size_t. This function hides the
* truncation logic and resolves compiler diagnostics.
*
* @internal Internal use only.
*/
template<typename TO, typename FROM>
inline TO Truncate (FROM val)
{
// If the size of FROM is less than the size of TO, "val" will
// never be greater than the maximum "TO" value, so there is no
// need to attempt to truncate.
typedef typename ACE::If_Then_Else<
(sizeof (FROM) < sizeof (TO)),
Noop_Truncator<FROM, TO>,
Truncator<FROM, TO> >::result_type truncator;
return truncator() (val);
}
#else
// Borland can't handle the template meta-programming above so
// provide explicit specializations for a few types. More will be
// added if necessary.
/**
* @deprecated Borland ACE_Utils::Truncator<> specializations should
* be removed.
*/
template<typename FROM, typename TO> struct Truncator;
//----------------------------------------------------------
// sizeof(FROM) > sizeof(TO)
//----------------------------------------------------------
template<>
struct ACE_Export Truncator<ACE_INT32, ACE_INT8>
{
ACE_INT8 operator() (ACE_INT32 val)
{
return
(val > ACE_Numeric_Limits<ACE_INT8>::max ()
? ACE_Numeric_Limits<ACE_INT8>::max ()
: static_cast<ACE_INT8> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_UINT32, ACE_UINT8>
{
ACE_UINT8 operator() (ACE_UINT32 val)
{
return
(val > static_cast<ACE_UINT32> (ACE_Numeric_Limits<ACE_UINT8>::max ())
? ACE_Numeric_Limits<ACE_UINT8>::max ()
: static_cast<ACE_UINT8> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_INT32, ACE_UINT8>
{
ACE_UINT8 operator() (ACE_INT32 val)
{
return
(val > static_cast<ACE_INT32> (ACE_Numeric_Limits<ACE_UINT8>::max ())
? ACE_Numeric_Limits<ACE_UINT8>::max ()
: static_cast<ACE_UINT8> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_UINT32, ACE_INT8>
{
ACE_INT8 operator() (ACE_UINT32 val)
{
return
(val > static_cast<ACE_UINT32> (ACE_Numeric_Limits<ACE_INT8>::max ())
? ACE_Numeric_Limits<ACE_INT8>::max ()
: static_cast<ACE_INT8> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_INT64, ACE_INT32>
{
ACE_INT32 operator() (ACE_INT64 val)
{
return
(val > ACE_Numeric_Limits<ACE_INT32>::max ()
? ACE_Numeric_Limits<ACE_INT32>::max ()
: static_cast<ACE_INT32> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_INT64, ACE_UINT32>
{
ACE_UINT32 operator() (ACE_INT64 val)
{
return
(val > static_cast<ACE_INT64> (ACE_Numeric_Limits<ACE_UINT32>::max ())
? ACE_Numeric_Limits<ACE_UINT32>::max ()
: static_cast<ACE_UINT32> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_UINT64, ACE_UINT32>
{
ACE_UINT32 operator() (ACE_UINT64 val)
{
return
(val > static_cast<ACE_UINT64> (ACE_Numeric_Limits<ACE_UINT32>::max ())
? ACE_Numeric_Limits<ACE_UINT32>::max ()
: static_cast<ACE_UINT32> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_UINT64, ACE_INT32>
{
ACE_INT32 operator() (ACE_UINT64 val)
{
return
(val > static_cast<ACE_UINT64> (ACE_Numeric_Limits<ACE_INT32>::max ())
? ACE_Numeric_Limits<ACE_INT32>::max ()
: static_cast<ACE_INT32> (val));
}
};
//----------------------------------------------------------
// sizeof(FROM) == sizeof(TO)
//----------------------------------------------------------
template<>
struct ACE_Export Truncator<ACE_INT32, ACE_UINT32>
{
ACE_UINT32 operator() (ACE_INT32 val)
{
return static_cast<ACE_UINT32> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT32, ACE_INT32>
{
ACE_INT32 operator() (ACE_UINT32 val)
{
return
(val > static_cast<ACE_UINT32> (ACE_Numeric_Limits<ACE_INT32>::max ())
? ACE_Numeric_Limits<ACE_INT32>::max ()
: static_cast<ACE_INT32> (val));
}
};
template<>
struct ACE_Export Truncator<ACE_INT64, ACE_UINT64>
{
ACE_UINT64 operator() (ACE_INT64 val)
{
return static_cast<ACE_UINT64> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT64, ACE_INT64>
{
ACE_INT64 operator() (ACE_UINT64 val)
{
return
(val > static_cast<ACE_UINT64> (ACE_Numeric_Limits<ACE_INT64>::max ())
? ACE_Numeric_Limits<ACE_INT64>::max ()
: static_cast<ACE_INT64> (val));
}
};
//----------------------------------------------------------
// sizeof(FROM) < sizeof(TO)
//----------------------------------------------------------
template<>
struct ACE_Export Truncator<ACE_INT8, ACE_INT32>
{
ACE_INT32 operator() (ACE_INT8 val)
{
return static_cast<ACE_INT32> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT8, ACE_UINT32>
{
ACE_UINT32 operator() (ACE_UINT8 val)
{
return static_cast<ACE_UINT32> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT8, ACE_INT32>
{
ACE_INT32 operator() (ACE_UINT8 val)
{
return static_cast<ACE_INT32> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_INT8, ACE_UINT32>
{
ACE_UINT32 operator() (ACE_INT8 val)
{
return static_cast<ACE_UINT32> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_INT32, ACE_INT64>
{
ACE_INT64 operator() (ACE_INT32 val)
{
return static_cast<ACE_INT64> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_INT32, ACE_UINT64>
{
ACE_UINT64 operator() (ACE_INT32 val)
{
return static_cast<ACE_UINT64> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT32, ACE_UINT64>
{
ACE_UINT64 operator() (ACE_UINT32 val)
{
return static_cast<ACE_UINT64> (val);
}
};
template<>
struct ACE_Export Truncator<ACE_UINT32, ACE_INT64>
{
ACE_INT64 operator() (ACE_UINT32 val)
{
return static_cast<ACE_INT64> (val);
}
};
// Partial specialization for the case where the types are the same.
// No truncation is necessary.
template<typename T>
struct ACE_Export Truncator<T, T>
{
T operator() (T val)
{
return val;
}
};
// -------------------------------------
template<typename TO, typename FROM>
inline TO Truncate (FROM val)
{
typedef Truncator<FROM, TO> truncator;
return truncator() (val);
}
#endif /* !__BORLANDC__ || __BORLANDC__ > 0x582 */
} // namespace ACE_Utils
ACE_END_VERSIONED_NAMESPACE_DECL
#include /**/ "ace/post.h"
#endif /* ACE_TRUNCATE_H*/
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