4coder/non-source/test_data/lots_of_files/safeint.h

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/***
*safeint.h - SafeInt class and free-standing functions used to prevent arithmetic overflows
*
* Copyright (c) Microsoft Corporation. All rights reserved.
*
*Purpose:
*
* The SafeInt class is designed to have as low an overhead as possible
* while still ensuring that all integer operations are conducted safely.
* Nearly every operator has been overloaded, with a very few exceptions.
*
* A usability-safety trade-off has been made to help ensure safety. This
* requires that every operation return either a SafeInt or a bool. If we
* allowed an operator to return a base integer type T, then the following
* can happen:
*
* char i = SafeInt<char>(32) * 2 + SafeInt<char>(16) * 4;
*
* The * operators take precedence, get overloaded, return a char, and then
* you have:
*
* char i = (char)64 + (char)64; //overflow!
*
* This situation would mean that safety would depend on usage, which isn't
* acceptable.
*
* One key operator that is missing is an implicit cast to type T. The reason for
* this is that if there is an implicit cast operator, then we end up with
* an ambiguous compile-time precedence. Because of this amiguity, there
* are two methods that are provided:
*
* Casting operators for every native integer type
*
* SafeInt::Ptr() - returns the address of the internal integer
*
* The SafeInt class should be used in any circumstances where ensuring
* integrity of the calculations is more important than performance. See Performance
* Notes below for additional information.
*
* Many of the conditionals will optimize out or be inlined for a release
* build (especially with /Ox), but it does have significantly more overhead,
* especially for signed numbers. If you do not _require_ negative numbers, use
* unsigned integer types - certain types of problems cannot occur, and this class
* performs most efficiently.
*
* Here's an example of when the class should ideally be used -
*
* void* AllocateMemForStructs(int StructSize, int HowMany)
* {
* SafeInt<unsigned long> s(StructSize);
*
* s *= HowMany;
*
* return malloc(s);
*
* }
*
* Here's when it should NOT be used:
*
* void foo()
* {
* int i;
*
* for(i = 0; i < 0xffff; i++)
* ....
* }
*
* Error handling - a SafeInt class will throw exceptions if something
* objectionable happens. The exceptions are SafeIntException classes,
* which contain an enum as a code.
*
* Typical usage might be:
*
* bool foo()
* {
* SafeInt<unsigned long> s; //note that s == 0 unless set
*
* try{
* s *= 23;
* ....
* }
* catch(SafeIntException err)
* {
* //handle errors here
* }
* }
*
* SafeInt accepts an error policy as an optional template parameter.
* We provide two error policy along with SafeInt: SafeIntErrorPolicy_SafeIntException, which
* throws SafeIntException in case of error, and SafeIntErrorPolicy_InvalidParameter, which
* calls _invalid_parameter to terminate the program.
*
* You can replace the error policy class with any class you like. This is accomplished by:
* 1) Create a class that has the following interface:
*
* struct YourSafeIntErrorPolicy
* {
* static __declspec(noreturn) void __stdcall SafeIntOnOverflow()
* {
* throw YourException( YourSafeIntArithmeticOverflowError );
* // or do something else which will terminate the program
* }
*
* static __declspec(noreturn) void __stdcall SafeIntOnDivZero()
* {
* throw YourException( YourSafeIntDivideByZeroError );
* // or do something else which will terminate the program
* }
* };
*
* Note that you don't have to throw C++ exceptions, you can throw Win32 exceptions, or do
* anything you like, just don't return from the call back into the code.
*
* 2) Either explicitly declare SafeInts like so:
* SafeInt< int, YourSafeIntErrorPolicy > si;
* or, before including SafeInt:
* #define _SAFEINT_DEFAULT_ERROR_POLICY ::YourSafeIntErrorPolicy
*
* Performance:
*
* Due to the highly nested nature of this class, you can expect relatively poor
* performance in unoptimized code. In tests of optimized code vs. correct inline checks
* in native code, this class has been found to take approximately 8% more CPU time (this varies),
* most of which is due to exception handling.
*
* Binary Operators:
*
* All of the binary operators have certain assumptions built into the class design.
* This is to ensure correctness. Notes on each class of operator follow:
*
* Arithmetic Operators (*,/,+,-,%)
* There are three possible variants:
* SafeInt< T, E > op SafeInt< T, E >
* SafeInt< T, E > op U
* U op SafeInt< T, E >
*
* The SafeInt< T, E > op SafeInt< U, E > variant is explicitly not supported, and if you try to do
* this the compiler with throw the following error:
*
* error C2593: 'operator *' is ambiguous
*
* This is because the arithmetic operators are required to return a SafeInt of some type.
* The compiler cannot know whether you'd prefer to get a type T or a type U returned. If
* you need to do this, you need to extract the value contained within one of the two using
* the casting operator. For example:
*
* SafeInt< T, E > t, result;
* SafeInt< U, E > u;
*
* result = t * (U)u;
*
* Comparison Operators:
*
* Because each of these operators return type bool, mixing SafeInts of differing types is
* allowed.
*
* Shift Operators:
*
* Shift operators always return the type on the left hand side of the operator. Mixed type
* operations are allowed because the return type is always known.
*
* Boolean Operators:
*
* Like comparison operators, these overloads always return type bool, and mixed-type SafeInts
* are allowed. Additionally, specific overloads exist for type bool on both sides of the
* operator.
*
* Binary Operators:
*
* Mixed-type operations are discouraged, however some provision has been made in order to
* enable things like:
*
* SafeInt<char> c = 2;
*
* if(c & 0x02)
* ...
*
* The "0x02" is actually an int, and it needs to work.
* In the case of binary operations on integers smaller than 32-bit, or of mixed type, corner
* cases do exist where you could get unexpected results. In any case where SafeInt returns a different
* result than the underlying operator, it will call _ASSERTE(). You should examine your code and cast things
* properly so that you are not programming with side effects.
*
* Comparison Operators and ANSI Conversions:
*
* The comparison operator behavior in this class varies from the ANSI definition.
* As an example, consider the following:
*
* unsigned int l = 0xffffffff;
* char c = -1;
*
* if(c == l)
* printf("Why is -1 equal to 4 billion???\n");
*
* The problem here is that c gets cast to an int, now has a value of 0xffffffff, and then gets
* cast again to an unsigned int, losing the true value. This behavior is despite the fact that
* an __int64 exists, and the following code will yield a different (and intuitively correct)
* answer:
*
* if((__int64)c == (__int64)l))
* printf("Why is -1 equal to 4 billion???\n");
* else
* printf("Why doesn't the compiler upcast to 64-bits when needed?\n");
*
* Note that combinations with smaller integers won't display the problem - if you
* changed "unsigned int" above to "unsigned short", you'd get the right answer.
*
* If you prefer to retain the ANSI standard behavior insert, before including safeint.h:
*
* #define _SAFEINT_ANSI_CONVERSIONS 1
*
* into your source. Behavior differences occur in the following cases:
* 8, 16, and 32-bit signed int, unsigned 32-bit int
* any signed int, unsigned 64-bit int
* Note - the signed int must be negative to show the problem
*
****/
#pragma once
#include <crtdefs.h>
#include <crtdbg.h>
#if !defined (_SAFEINT_DEFAULT_ERROR_POLICY)
#define _SAFEINT_DEFAULT_ERROR_POLICY SafeIntErrorPolicy_SafeIntException
#endif /* !defined (_SAFEINT_DEFAULT_ERROR_POLICY) */
#if !defined (_SAFEINT_SHIFT_ASSERT)
#define _SAFEINT_SHIFT_ASSERT(x) _ASSERTE(x)
#endif /* !defined (_SAFEINT_SHIFT_ASSERT) */
#if !defined (_SAFEINT_BINARY_ASSERT)
#define _SAFEINT_BINARY_ASSERT(x) _ASSERTE(x)
#endif /* !defined (_SAFEINT_BINARY_ASSERT) */
#if !defined (_SAFEINT_EXCEPTION_ASSERT)
#define _SAFEINT_EXCEPTION_ASSERT()
#endif /* !defined (_SAFEINT_EXCEPTION_ASSERT) */
// by default, SafeInt will accept negation of an unsigned int;
// if you wish to disable it or assert, you can define the following
// macro to be a static assert or a runtime assert
#if !defined (_SAFEINT_UNSIGNED_NEGATION_BEHAVIOR)
#define _SAFEINT_UNSIGNED_NEGATION_BEHAVIOR()
#endif /* !defined (_SAFEINT_UNSIGNED_NEGATION_BEHAVIOR) */
// See above "Comparison Operators and ANSI Conversions" for an explanation
// of _SAFEINT_USE_ANSI_CONVERSIONS
#if !defined (_SAFEINT_USE_ANSI_CONVERSIONS)
#define _SAFEINT_USE_ANSI_CONVERSIONS 0
#endif /* !defined (_SAFEINT_USE_ANSI_CONVERSIONS) */
#pragma pack(push, _CRT_PACKING)
namespace msl
{
namespace utilities
{
enum SafeIntError
{
SafeIntNoError = 0,
SafeIntArithmeticOverflow,
SafeIntDivideByZero
};
} // namespace utilities
} // namespace msl
#include "safeint_internal.h"
namespace msl
{
namespace utilities
{
class SafeIntException
{
public:
SafeIntException() { m_code = SafeIntNoError; }
SafeIntException( SafeIntError code )
{
m_code = code;
}
SafeIntError m_code;
};
struct SafeIntErrorPolicy_SafeIntException
{
static __declspec(noreturn) void SafeIntOnOverflow()
{
_SAFEINT_EXCEPTION_ASSERT();
throw SafeIntException( SafeIntArithmeticOverflow );
}
static __declspec(noreturn) void SafeIntOnDivZero()
{
_SAFEINT_EXCEPTION_ASSERT();
throw SafeIntException( SafeIntDivideByZero );
}
};
struct SafeIntErrorPolicy_InvalidParameter
{
static __declspec(noreturn) void SafeIntOnOverflow()
{
_SAFEINT_EXCEPTION_ASSERT();
_CRT_SECURE_INVALID_PARAMETER("SafeInt Arithmetic Overflow");
}
static __declspec(noreturn) void SafeIntOnDivZero()
{
_SAFEINT_EXCEPTION_ASSERT();
_CRT_SECURE_INVALID_PARAMETER("SafeInt Divide By Zero");
}
};
// Free-standing functions that can be used where you only need to check one operation
// non-class helper function so that you can check for a cast's validity
// and handle errors how you like
template < typename T, typename U >
inline bool SafeCast( const T From, U& To ) throw()
{
return (details::SafeCastHelper< U, T,
details::SafeIntErrorPolicy_NoThrow >::Cast( From, To ) == SafeIntNoError);
}
template < typename T, typename U >
inline bool SafeEquals( const T t, const U u ) throw()
{
return details::EqualityTest< T, U >::IsEquals( t, u );
}
template < typename T, typename U >
inline bool SafeNotEquals( const T t, const U u ) throw()
{
return !details::EqualityTest< T, U >::IsEquals( t, u );
}
template < typename T, typename U >
inline bool SafeGreaterThan( const T t, const U u ) throw()
{
return details::GreaterThanTest< T, U >::GreaterThan( t, u );
}
template < typename T, typename U >
inline bool SafeGreaterThanEquals( const T t, const U u ) throw()
{
return !details::GreaterThanTest< U, T >::GreaterThan( u, t );
}
template < typename T, typename U >
inline bool SafeLessThan( const T t, const U u ) throw()
{
return details::GreaterThanTest< U, T >::GreaterThan( u, t );
}
template < typename T, typename U >
inline bool SafeLessThanEquals( const T t, const U u ) throw()
{
return !details::GreaterThanTest< T, U >::GreaterThan( t, u );
}
template < typename T, typename U >
inline bool SafeModulus( const T& t, const U& u, T& result ) throw()
{
return ( details::ModulusHelper< T, U, details::SafeIntErrorPolicy_NoThrow >::Modulus( t, u, result ) == SafeIntNoError );
}
template < typename T, typename U >
inline bool SafeMultiply( T t, U u, T& result ) throw()
{
return ( details::MultiplicationHelper< T, U,
details::SafeIntErrorPolicy_NoThrow >::Multiply( t, u, result ) == SafeIntNoError );
}
template < typename T, typename U >
inline bool SafeDivide( T t, U u, T& result ) throw()
{
return ( details::DivisionHelper< T, U,
details::SafeIntErrorPolicy_NoThrow >::Divide( t, u, result ) == SafeIntNoError );
}
template < typename T, typename U >
inline bool SafeAdd( T t, U u, T& result ) throw()
{
return ( details::AdditionHelper< T, U,
details::SafeIntErrorPolicy_NoThrow >::Addition( t, u, result ) == SafeIntNoError );
}
template < typename T, typename U >
inline bool SafeSubtract( T t, U u, T& result ) throw()
{
return ( details::SubtractionHelper< T, U,
details::SafeIntErrorPolicy_NoThrow >::Subtract( t, u, result ) == SafeIntNoError );
}
// SafeInt class
template < typename T, typename E = _SAFEINT_DEFAULT_ERROR_POLICY >
class SafeInt
{
public:
SafeInt() throw()
{
static_assert( details::NumericType< T >::isInt , "SafeInt<T>: T needs to be an integer type" );
m_int = 0;
}
// Having a constructor for every type of int
// avoids having the compiler evade our checks when doing implicit casts -
// e.g., SafeInt<char> s = 0x7fffffff;
SafeInt( const T& i ) throw()
{
static_assert( details::NumericType< T >::isInt , "SafeInt<T>: T needs to be an integer type" );
//always safe
m_int = i;
}
// provide explicit boolean converter
SafeInt( bool b ) throw()
{
static_assert( details::NumericType< T >::isInt , "SafeInt<T>: T needs to be an integer type" );
m_int = b ? 1 : 0;
}
template < typename U >
SafeInt(const SafeInt< U, E >& u)
{
static_assert( details::NumericType< T >::isInt , "SafeInt<T>: T needs to be an integer type" );
*this = SafeInt< T, E >( (U)u );
}
template < typename U >
SafeInt( const U& i )
{
static_assert( details::NumericType< T >::isInt , "SafeInt<T>: T needs to be an integer type" );
// SafeCast will throw exceptions if i won't fit in type T
details::SafeCastHelper< T, U, E >::Cast( i, m_int );
}
// now start overloading operators
// assignment operator
// constructors exist for all int types and will ensure safety
template < typename U >
SafeInt< T, E >& operator =( const U& rhs )
{
// use constructor to test size
// constructor is optimized to do minimal checking based
// on whether T can contain U
// note - do not change this
*this = SafeInt< T, E >( rhs );
return *this;
}
SafeInt< T, E >& operator =( const T& rhs ) throw()
{
m_int = rhs;
return *this;
}
template < typename U >
SafeInt< T, E >& operator =( const SafeInt< U, E >& rhs )
{
details::SafeCastHelper< T, U, E >::Cast( rhs.Ref(), m_int );
return *this;
}
SafeInt< T, E >& operator =( const SafeInt< T, E >& rhs ) throw()
{
m_int = rhs.m_int;
return *this;
}
// Casting operators
operator bool() const throw()
{
return !!m_int;
}
operator char() const
{
char val;
details::SafeCastHelper< char, T, E >::Cast( m_int, val );
return val;
}
operator signed char() const
{
signed char val;
details::SafeCastHelper< signed char, T, E >::Cast( m_int, val );
return val;
}
operator unsigned char() const
{
unsigned char val;
details::SafeCastHelper< unsigned char, T, E >::Cast( m_int, val );
return val;
}
operator __int16() const
{
__int16 val;
details::SafeCastHelper< __int16, T, E >::Cast( m_int, val );
return val;
}
operator unsigned __int16() const
{
unsigned __int16 val;
details::SafeCastHelper< unsigned __int16, T, E >::Cast( m_int, val );
return val;
}
operator __int32() const
{
__int32 val;
details::SafeCastHelper< __int32, T, E >::Cast( m_int, val );
return val;
}
operator unsigned __int32() const
{
unsigned __int32 val;
details::SafeCastHelper< unsigned __int32, T, E >::Cast( m_int, val );
return val;
}
// The compiler knows that int == __int32
// but not that long == __int32
operator long() const
{
long val;
details::SafeCastHelper< long, T, E >::Cast( m_int, val );
return val;
}
operator unsigned long() const
{
unsigned long val;
details::SafeCastHelper< unsigned long, T, E >::Cast( m_int, val );
return val;
}
operator __int64() const
{
__int64 val;
details::SafeCastHelper< __int64, T, E >::Cast( m_int, val );
return val;
}
operator unsigned __int64() const
{
unsigned __int64 val;
details::SafeCastHelper< unsigned __int64, T, E >::Cast( m_int, val );
return val;
}
#if _NATIVE_WCHAR_T_DEFINED
operator wchar_t() const
{
unsigned __int16 val;
details::SafeCastHelper< unsigned __int16, T, E >::Cast( m_int, val );
return val;
}
#endif /* _NATIVE_WCHAR_T_DEFINED */
// If you need a pointer to the data
// this could be dangerous, but allows you to correctly pass
// instances of this class to APIs that take a pointer to an integer
// also see overloaded address-of operator below
T* Ptr() throw() { return &m_int; }
const T* Ptr() const throw() { return &m_int; }
const T& Ref() const throw() { return m_int; }
// Unary operators
bool operator !() const throw() { return (!m_int) ? true : false; }
// operator + (unary)
// note - normally, the '+' and '-' operators will upcast to a signed int
// for T < 32 bits. This class changes behavior to preserve type
const SafeInt< T, E >& operator +() const throw() { return *this; };
//unary -
SafeInt< T, E > operator -() const
{
// Note - unsigned still performs the bitwise manipulation
// will warn at level 2 or higher if the value is 32-bit or larger
T tmp;
details::NegationHelper< T, E, details::IntTraits< T >::isSigned >::Negative( m_int, tmp );
return SafeInt< T, E >( tmp );
}
// prefix increment operator
SafeInt< T, E >& operator ++()
{
if( m_int != details::IntTraits< T >::maxInt )
{
++m_int;
return *this;
}
E::SafeIntOnOverflow();
}
// prefix decrement operator
SafeInt< T, E >& operator --()
{
if( m_int != details::IntTraits< T >::minInt )
{
--m_int;
return *this;
}
E::SafeIntOnOverflow();
}
// note that postfix operators have inherently worse perf
// characteristics
// postfix increment operator
SafeInt< T, E > operator ++( int ) // dummy arg to comply with spec
{
if( m_int != details::IntTraits< T >::maxInt )
{
SafeInt< T, E > tmp( m_int );
m_int++;
return tmp;
}
E::SafeIntOnOverflow();
}
// postfix decrement operator
SafeInt< T, E > operator --( int ) // dummy arg to comply with spec
{
if( m_int != details::IntTraits< T >::minInt )
{
SafeInt< T, E > tmp( m_int );
m_int--;
return tmp;
}
E::SafeIntOnOverflow();
}
// One's complement
// Note - this operator will normally change size to an int
// cast in return improves perf and maintains type
SafeInt< T, E > operator ~() const throw() { return SafeInt< T, E >( (T)~m_int ); }
// Binary operators
//
// arithmetic binary operators
// % modulus
// * multiplication
// / division
// + addition
// - subtraction
//
// For each of the arithmetic operators, you will need to
// use them as follows:
//
// SafeInt<char> c = 2;
// SafeInt<int> i = 3;
//
// SafeInt<int> i2 = i op (char)c;
// OR
// SafeInt<char> i2 = (int)i op c;
//
// The base problem is that if the lhs and rhs inputs are different SafeInt types
// it is not possible in this implementation to determine what type of SafeInt
// should be returned. You have to let the class know which of the two inputs
// need to be the return type by forcing the other value to the base integer type.
//
// Note - as per feedback from Scott Meyers, I'm exploring how to get around this.
// 3.0 update - I'm still thinking about this. It can be done with template metaprogramming,
// but it is tricky, and there's a perf vs. correctness tradeoff where the right answer
// is situational.
//
// The case of:
//
// SafeInt< T, E > i, j, k;
// i = j op k;
//
// works just fine and no unboxing is needed because the return type is not ambiguous.
// Modulus
// Modulus has some convenient properties -
// first, the magnitude of the return can never be
// larger than the lhs operand, and it must be the same sign
// as well. It does, however, suffer from the same promotion
// problems as comparisons, division and other operations
template < typename U >
SafeInt< T, E > operator %( U rhs ) const
{
T result;
details::ModulusHelper< T, U, E >::Modulus( m_int, rhs, result );
return SafeInt< T, E >( result );
}
SafeInt< T, E > operator %( SafeInt< T, E > rhs ) const
{
T result;
details::ModulusHelper< T, T, E >::Modulus( m_int, rhs, result );
return SafeInt< T, E >( result );
}
// Modulus assignment
template < typename U >
SafeInt< T, E >& operator %=( U rhs )
{
details::ModulusHelper< T, U, E >::Modulus( m_int, rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator %=( SafeInt< U, E > rhs )
{
details::ModulusHelper< T, U, E >::Modulus( m_int, (U)rhs, m_int );
return *this;
}
// Multiplication
template < typename U >
SafeInt< T, E > operator *( U rhs ) const
{
T ret( 0 );
details::MultiplicationHelper< T, U, E >::Multiply( m_int, rhs, ret );
return SafeInt< T, E >( ret );
}
SafeInt< T, E > operator *( SafeInt< T, E > rhs ) const
{
T ret( 0 );
details::MultiplicationHelper< T, T, E >::Multiply( m_int, (T)rhs, ret );
return SafeInt< T, E >( ret );
}
// Multiplication assignment
SafeInt< T, E >& operator *=( SafeInt< T, E > rhs )
{
details::MultiplicationHelper< T, T, E >::Multiply( m_int, (T)rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator *=( U rhs )
{
details::MultiplicationHelper< T, U, E >::Multiply( m_int, rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator *=( SafeInt< U, E > rhs )
{
details::MultiplicationHelper< T, U, E >::Multiply( m_int, rhs.Ref(), m_int );
return *this;
}
// Division
template < typename U >
SafeInt< T, E > operator /( U rhs ) const
{
T ret( 0 );
details::DivisionHelper< T, U, E >::Divide( m_int, rhs, ret );
return SafeInt< T, E >( ret );
}
SafeInt< T, E > operator /( SafeInt< T, E > rhs ) const
{
T ret( 0 );
details::DivisionHelper< T, T, E >::Divide( m_int, (T)rhs, ret );
return SafeInt< T, E >( ret );
}
// Division assignment
SafeInt< T, E >& operator /=( SafeInt< T, E > i )
{
details::DivisionHelper< T, T, E >::Divide( m_int, (T)i, m_int );
return *this;
}
template < typename U > SafeInt< T, E >& operator /=( U i )
{
details::DivisionHelper< T, U, E >::Divide( m_int, i, m_int );
return *this;
}
template < typename U > SafeInt< T, E >& operator /=( SafeInt< U, E > i )
{
details::DivisionHelper< T, U, E >::Divide( m_int, (U)i, m_int );
return *this;
}
// For addition and subtraction
// Addition
SafeInt< T, E > operator +( SafeInt< T, E > rhs ) const
{
T ret( 0 );
details::AdditionHelper< T, T, E >::Addition( m_int, (T)rhs, ret );
return SafeInt< T, E >( ret );
}
template < typename U >
SafeInt< T, E > operator +( U rhs ) const
{
T ret( 0 );
details::AdditionHelper< T, U, E >::Addition( m_int, rhs, ret );
return SafeInt< T, E >( ret );
}
//addition assignment
SafeInt< T, E >& operator +=( SafeInt< T, E > rhs )
{
details::AdditionHelper< T, T, E >::Addition( m_int, (T)rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator +=( U rhs )
{
details::AdditionHelper< T, U, E >::Addition( m_int, rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator +=( SafeInt< U, E > rhs )
{
details::AdditionHelper< T, U, E >::Addition( m_int, (U)rhs, m_int );
return *this;
}
// Subtraction
template < typename U >
SafeInt< T, E > operator -( U rhs ) const
{
T ret( 0 );
details::SubtractionHelper< T, U, E >::Subtract( m_int, rhs, ret );
return SafeInt< T, E >( ret );
}
SafeInt< T, E > operator -(SafeInt< T, E > rhs) const
{
T ret( 0 );
details::SubtractionHelper< T, T, E >::Subtract( m_int, (T)rhs, ret );
return SafeInt< T, E >( ret );
}
// Subtraction assignment
SafeInt< T, E >& operator -=( SafeInt< T, E > rhs )
{
details::SubtractionHelper< T, T, E >::Subtract( m_int, (T)rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator -=( U rhs )
{
details::SubtractionHelper< T, U, E >::Subtract( m_int, rhs, m_int );
return *this;
}
template < typename U >
SafeInt< T, E >& operator -=( SafeInt< U, E > rhs )
{
details::SubtractionHelper< T, U, E >::Subtract( m_int, (U)rhs, m_int );
return *this;
}
// Comparison operators
// Additional overloads defined outside the class
// to allow for cases where the SafeInt is the rhs value
// Less than
template < typename U >
bool operator <( U rhs ) const throw()
{
return details::GreaterThanTest< U, T >::GreaterThan( rhs, m_int );
}
bool operator <( SafeInt< T, E > rhs ) const throw()
{
return m_int < (T)rhs;
}
// Greater than or eq.
template < typename U >
bool operator >=( U rhs ) const throw()
{
return !details::GreaterThanTest< U, T >::GreaterThan( rhs, m_int );
}
bool operator >=( SafeInt< T, E > rhs ) const throw()
{
return m_int >= (T)rhs;
}
// Greater than
template < typename U >
bool operator >( U rhs ) const throw()
{
return details::GreaterThanTest< T, U >::GreaterThan( m_int, rhs );
}
bool operator >( SafeInt< T, E > rhs ) const throw()
{
return m_int > (T)rhs;
}
// Less than or eq.
template < typename U >
bool operator <=( U rhs ) const throw()
{
return !details::GreaterThanTest< T, U >::GreaterThan( m_int, rhs );
}
bool operator <=( SafeInt< T, E > rhs ) const throw()
{
return m_int <= (T)rhs;
}
// Equality
template < typename U >
bool operator ==( U rhs ) const throw()
{
return details::EqualityTest< T, U >::IsEquals( m_int, rhs );
}
// Need an explicit override for type bool
bool operator ==( bool rhs ) const throw()
{
return ( m_int == 0 ? false : true ) == rhs;
}
bool operator ==( SafeInt< T, E > rhs ) const throw() { return m_int == (T)rhs; }
// != operators
template < typename U >
bool operator !=( U rhs ) const throw()
{
return !details::EqualityTest< T, U >::IsEquals( m_int, rhs );
}
bool operator !=( bool b ) const throw()
{
return ( m_int == 0 ? false : true ) != b;
}
bool operator !=( SafeInt< T, E > rhs ) const throw() { return m_int != (T)rhs; }
// Shift operators
// Note - shift operators ALWAYS return the same type as the lhs
// specific version for SafeInt< T, E > not needed -
// code path is exactly the same as for SafeInt< U, E > as rhs
// Left shift
// Also, shifting > bitcount is undefined - trap in debug (check _SAFEINT_SHIFT_ASSERT)
template < typename U >
SafeInt< T, E > operator <<( U bits ) const throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || bits >= 0 );
_SAFEINT_SHIFT_ASSERT( bits < (int)details::IntTraits< T >::bitCount );
return SafeInt< T, E >( (T)( m_int << bits ) );
}
template < typename U >
SafeInt< T, E > operator <<( SafeInt< U, E > bits ) const throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || (U)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( (U)bits < (int)details::IntTraits< T >::bitCount );
return SafeInt< T, E >( (T)( m_int << (U)bits ) );
}
// Left shift assignment
template < typename U >
SafeInt< T, E >& operator <<=( U bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || bits >= 0 );
_SAFEINT_SHIFT_ASSERT( bits < (int)details::IntTraits< T >::bitCount );
m_int <<= bits;
return *this;
}
template < typename U >
SafeInt< T, E >& operator <<=( SafeInt< U, E > bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || (U)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( (U)bits < (int)details::IntTraits< T >::bitCount );
m_int <<= (U)bits;
return *this;
}
// Right shift
template < typename U >
SafeInt< T, E > operator >>( U bits ) const throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || bits >= 0 );
_SAFEINT_SHIFT_ASSERT( bits < (int)details::IntTraits< T >::bitCount );
return SafeInt< T, E >( (T)( m_int >> bits ) );
}
template < typename U >
SafeInt< T, E > operator >>( SafeInt< U, E > bits ) const throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || (U)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( bits < (int)details::IntTraits< T >::bitCount );
return SafeInt< T, E >( (T)(m_int >> (U)bits) );
}
// Right shift assignment
template < typename U >
SafeInt< T, E >& operator >>=( U bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || bits >= 0 );
_SAFEINT_SHIFT_ASSERT( bits < (int)details::IntTraits< T >::bitCount );
m_int >>= bits;
return *this;
}
template < typename U >
SafeInt< T, E >& operator >>=( SafeInt< U, E > bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< U >::isSigned || (U)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( (U)bits < (int)details::IntTraits< T >::bitCount );
m_int >>= (U)bits;
return *this;
}
// Bitwise operators
// This only makes sense if we're dealing with the same type and size
// demand a type T, or something that fits into a type T
// Bitwise &
SafeInt< T, E > operator &( SafeInt< T, E > rhs ) const throw()
{
return SafeInt< T, E >( m_int & (T)rhs );
}
template < typename U >
SafeInt< T, E > operator &( U rhs ) const throw()
{
// we want to avoid setting bits by surprise
// consider the case of lhs = int, value = 0xffffffff
// rhs = char, value = 0xff
//
// programmer intent is to get only the lower 8 bits
// normal behavior is to upcast both sides to an int
// which then sign extends rhs, setting all the bits
// If you land in the assert, this is because the bitwise operator
// was causing unexpected behavior. Fix is to properly cast your inputs
// so that it works like you meant, not unexpectedly
return SafeInt< T, E >( details::BinaryAndHelper< T, U >::And( m_int, rhs ) );
}
// Bitwise & assignment
SafeInt< T, E >& operator &=( SafeInt< T, E > rhs ) throw()
{
m_int &= (T)rhs;
return *this;
}
template < typename U >
SafeInt< T, E >& operator &=( U rhs ) throw()
{
m_int = details::BinaryAndHelper< T, U >::And( m_int, rhs );
return *this;
}
template < typename U >
SafeInt< T, E >& operator &=( SafeInt< U, E > rhs ) throw()
{
m_int = details::BinaryAndHelper< T, U >::And( m_int, (U)rhs );
return *this;
}
// XOR
SafeInt< T, E > operator ^( SafeInt< T, E > rhs ) const throw()
{
return SafeInt< T, E >( (T)( m_int ^ (T)rhs ) );
}
template < typename U >
SafeInt< T, E > operator ^( U rhs ) const throw()
{
// If you land in the assert, this is because the bitwise operator
// was causing unexpected behavior. Fix is to properly cast your inputs
// so that it works like you meant, not unexpectedly
return SafeInt< T, E >( details::BinaryXorHelper< T, U >::Xor( m_int, rhs ) );
}
// XOR assignment
SafeInt< T, E >& operator ^=( SafeInt< T, E > rhs ) throw()
{
m_int ^= (T)rhs;
return *this;
}
template < typename U >
SafeInt< T, E >& operator ^=( U rhs ) throw()
{
m_int = details::BinaryXorHelper< T, U >::Xor( m_int, rhs );
return *this;
}
template < typename U >
SafeInt< T, E >& operator ^=( SafeInt< U, E > rhs ) throw()
{
m_int = details::BinaryXorHelper< T, U >::Xor( m_int, (U)rhs );
return *this;
}
// bitwise OR
SafeInt< T, E > operator |( SafeInt< T, E > rhs ) const throw()
{
return SafeInt< T, E >( (T)( m_int | (T)rhs ) );
}
template < typename U >
SafeInt< T, E > operator |( U rhs ) const throw()
{
return SafeInt< T, E >( details::BinaryOrHelper< T, U >::Or( m_int, rhs ) );
}
// bitwise OR assignment
SafeInt< T, E >& operator |=( SafeInt< T, E > rhs ) throw()
{
m_int |= (T)rhs;
return *this;
}
template < typename U >
SafeInt< T, E >& operator |=( U rhs ) throw()
{
m_int = details::BinaryOrHelper< T, U >::Or( m_int, rhs );
return *this;
}
template < typename U >
SafeInt< T, E >& operator |=( SafeInt< U, E > rhs ) throw()
{
m_int = details::BinaryOrHelper< T, U >::Or( m_int, (U)rhs );
return *this;
}
// Miscellaneous helper functions
SafeInt< T, E > Min( SafeInt< T, E > test, SafeInt< T, E > floor = SafeInt< T, E >( details::IntTraits< T >::minInt ) ) const throw()
{
T tmp = test < m_int ? test : m_int;
return tmp < floor ? floor : tmp;
}
SafeInt< T, E > Max( SafeInt< T, E > test, SafeInt< T, E > upper = SafeInt< T, E >( details::IntTraits< T >::maxInt ) ) const throw()
{
T tmp = test > m_int ? test : m_int;
return tmp > upper ? upper : tmp;
}
void Swap( SafeInt< T, E >& with ) throw()
{
T temp( m_int );
m_int = with.m_int;
with.m_int = temp;
}
template < int bits >
const SafeInt< T, E >& Align()
{
// Zero is always aligned
if( m_int == 0 )
return *this;
// We don't support aligning negative numbers at this time
// Can't align unsigned numbers on bitCount (e.g., 8 bits = 256, unsigned char max = 255)
// or signed numbers on bitCount-1 (e.g., 7 bits = 128, signed char max = 127).
// Also makes no sense to try to align on negative or no bits.
_SAFEINT_SHIFT_ASSERT( ( ( details::IntTraits<T>::isSigned && bits < (int)details::IntTraits< T >::bitCount - 1 )
|| ( !details::IntTraits<T>::isSigned && bits < (int)details::IntTraits< T >::bitCount ) ) &&
bits >= 0 && ( !details::IntTraits<T>::isSigned || m_int > 0 ) );
const T AlignValue = ( (T)1 << bits ) - 1;
m_int = ( m_int + AlignValue ) & ~AlignValue;
if( m_int <= 0 )
E::SafeIntOnOverflow();
return *this;
}
// Commonly needed alignments:
const SafeInt< T, E >& Align2() { return Align< 1 >(); }
const SafeInt< T, E >& Align4() { return Align< 2 >(); }
const SafeInt< T, E >& Align8() { return Align< 3 >(); }
const SafeInt< T, E >& Align16() { return Align< 4 >(); }
const SafeInt< T, E >& Align32() { return Align< 5 >(); }
const SafeInt< T, E >& Align64() { return Align< 6 >(); }
private:
T m_int;
};
// Externally defined functions for the case of U op SafeInt< T, E >
template < typename T, typename U, typename E >
bool operator <( U lhs, SafeInt< T, E > rhs ) throw()
{
return details::GreaterThanTest< T, U >::GreaterThan( (T)rhs, lhs );
}
template < typename T, typename U, typename E >
bool operator <( SafeInt< U, E > lhs, SafeInt< T, E > rhs ) throw()
{
return details::GreaterThanTest< T, U >::GreaterThan( (T)rhs, (U)lhs );
}
// Greater than
template < typename T, typename U, typename E >
bool operator >( U lhs, SafeInt< T, E > rhs ) throw()
{
return details::GreaterThanTest< U, T >::GreaterThan( lhs, (T)rhs );
}
template < typename T, typename U, typename E >
bool operator >( SafeInt< T, E > lhs, SafeInt< U, E > rhs ) throw()
{
return details::GreaterThanTest< T, U >::GreaterThan( (T)lhs, (U)rhs );
}
// Greater than or equal
template < typename T, typename U, typename E >
bool operator >=( U lhs, SafeInt< T, E > rhs ) throw()
{
return !details::GreaterThanTest< T, U >::GreaterThan( (T)rhs, lhs );
}
template < typename T, typename U, typename E >
bool operator >=( SafeInt< T, E > lhs, SafeInt< U, E > rhs ) throw()
{
return !details::GreaterThanTest< U, T >::GreaterThan( (U)rhs, (T)lhs );
}
// Less than or equal
template < typename T, typename U, typename E >
bool operator <=( U lhs, SafeInt< T, E > rhs ) throw()
{
return !details::GreaterThanTest< U, T >::GreaterThan( lhs, (T)rhs );
}
template < typename T, typename U, typename E >
bool operator <=( SafeInt< T, E > lhs, SafeInt< U, E > rhs ) throw()
{
return !details::GreaterThanTest< T, U >::GreaterThan( (T)lhs, (U)rhs );
}
// equality
// explicit overload for bool
template < typename T, typename E >
bool operator ==( bool lhs, SafeInt< T, E > rhs ) throw()
{
return lhs == ( (T)rhs == 0 ? false : true );
}
template < typename T, typename U, typename E >
bool operator ==( U lhs, SafeInt< T, E > rhs ) throw()
{
return details::EqualityTest< T, U >::IsEquals((T)rhs, lhs);
}
template < typename T, typename U, typename E >
bool operator ==( SafeInt< T, E > lhs, SafeInt< U, E > rhs ) throw()
{
return details::EqualityTest< T, U >::IsEquals( (T)lhs, (U)rhs );
}
//not equals
template < typename T, typename U, typename E >
bool operator !=( U lhs, SafeInt< T, E > rhs ) throw()
{
return !details::EqualityTest< T, U >::IsEquals( rhs, lhs );
}
template < typename T, typename E >
bool operator !=( bool lhs, SafeInt< T, E > rhs ) throw()
{
return ( (T)rhs == 0 ? false : true ) != lhs;
}
template < typename T, typename U, typename E >
bool operator !=( SafeInt< T, E > lhs, SafeInt< U, E > rhs ) throw()
{
return !details::EqualityTest< T, U >::IsEquals( lhs, rhs );
}
// Modulus
template < typename T, typename U, typename E >
SafeInt< T, E > operator %( U lhs, SafeInt< T, E > rhs )
{
// Value of return depends on sign of lhs
// This one may not be safe - bounds check in constructor
// if lhs is negative and rhs is unsigned, this will throw an exception.
// Fast-track the simple case
// same size and same sign
#pragma warning(suppress:4127 6326)
if( sizeof(T) == sizeof(U) && details::IntTraits< T >::isSigned == details::IntTraits< U >::isSigned )
{
if( rhs != 0 )
{
if( details::IntTraits< T >::isSigned && (T)rhs == -1 )
return 0;
return SafeInt< T, E >( (T)( lhs % (T)rhs ) );
}
E::SafeIntOnDivZero();
}
return SafeInt< T, E >( ( SafeInt< U, E >( lhs ) % (T)rhs ) );
}
// Multiplication
template < typename T, typename U, typename E >
SafeInt< T, E > operator *( U lhs, SafeInt< T, E > rhs )
{
T ret( 0 );
details::MultiplicationHelper< T, U, E >::Multiply( (T)rhs, lhs, ret );
return SafeInt< T, E >(ret);
}
// Division
template < typename T, typename U, typename E > SafeInt< T, E > operator /( U lhs, SafeInt< T, E > rhs )
{
#pragma warning(push)
#pragma warning(disable: 4127 4146 4307 4310 6326)
// Corner case - has to be handled seperately
if( details::DivisionMethod< U, T >::method == details::DivisionState_UnsignedSigned )
{
if( (T)rhs > 0 )
return SafeInt< T, E >( lhs/(T)rhs );
// Now rhs is either negative, or zero
if( (T)rhs != 0 )
{
if( sizeof( U ) >= 4 && sizeof( T ) <= sizeof( U ) )
{
// Problem case - normal casting behavior changes meaning
// flip rhs to positive
// any operator casts now do the right thing
U tmp;
if( sizeof(T) == 4 )
tmp = lhs/(U)(unsigned __int32)( -(T)rhs );
else
tmp = lhs/(U)( -(T)rhs );
if( tmp <= details::IntTraits< T >::maxInt )
return SafeInt< T, E >( -( (T)tmp ) );
// Corner case
// Note - this warning happens because we're not using partial
// template specialization in this case. For any real cases where
// this block isn't optimized out, the warning won't be present.
if( tmp == (U)details::IntTraits< T >::maxInt + 1 )
return SafeInt< T, E >( details::IntTraits< T >::minInt );
E::SafeIntOnOverflow();
}
return SafeInt< T, E >(lhs/(T)rhs);
}
E::SafeIntOnDivZero();
} // method == DivisionState_UnsignedSigned
if( details::SafeIntCompare< T, U >::isBothSigned )
{
if( lhs == details::IntTraits< U >::minInt && (T)rhs == -1 )
{
// corner case of a corner case - lhs = min int, rhs = -1,
// but rhs is the return type, so in essence, we can return -lhs
// if rhs is a larger type than lhs
if( sizeof( U ) < sizeof( T ) )
{
return SafeInt< T, E >( (T)( -(T)details::IntTraits< U >::minInt ) );
}
// If rhs is smaller or the same size int, then -minInt won't work
E::SafeIntOnOverflow();
}
}
// Otherwise normal logic works with addition of bounds check when casting from U->T
U ret;
details::DivisionHelper< U, T, E >::Divide( lhs, (T)rhs, ret );
return SafeInt< T, E >( ret );
#pragma warning(pop)
}
// Addition
template < typename T, typename U, typename E >
SafeInt< T, E > operator +( U lhs, SafeInt< T, E > rhs )
{
T ret( 0 );
details::AdditionHelper< T, U, E >::Addition( (T)rhs, lhs, ret );
return SafeInt< T, E >( ret );
}
// Subtraction
template < typename T, typename U, typename E >
SafeInt< T, E > operator -( U lhs, SafeInt< T, E > rhs )
{
T ret( 0 );
details::SubtractionHelper< U, T, E, details::SubtractionMethod2< U, T >::method >::Subtract( lhs, rhs.Ref(), ret );
return SafeInt< T, E >( ret );
}
// Overrides designed to deal with cases where a SafeInt is assigned out
// to a normal int - this at least makes the last operation safe
// +=
template < typename T, typename U, typename E >
T& operator +=( T& lhs, SafeInt< U, E > rhs )
{
T ret( 0 );
details::AdditionHelper< T, U, E >::Addition( lhs, (U)rhs, ret );
lhs = ret;
return lhs;
}
template < typename T, typename U, typename E >
T& operator -=( T& lhs, SafeInt< U, E > rhs )
{
T ret( 0 );
details::SubtractionHelper< T, U, E >::Subtract( lhs, (U)rhs, ret );
lhs = ret;
return lhs;
}
template < typename T, typename U, typename E >
T& operator *=( T& lhs, SafeInt< U, E > rhs )
{
T ret( 0 );
details::MultiplicationHelper< T, U, E >::Multiply( lhs, (U)rhs, ret );
lhs = ret;
return lhs;
}
template < typename T, typename U, typename E >
T& operator /=( T& lhs, SafeInt< U, E > rhs )
{
T ret( 0 );
details::DivisionHelper< T, U, E >::Divide( lhs, (U)rhs, ret );
lhs = ret;
return lhs;
}
template < typename T, typename U, typename E >
T& operator %=( T& lhs, SafeInt< U, E > rhs )
{
T ret( 0 );
details::ModulusHelper< T, U, E >::Modulus( lhs, (U)rhs, ret );
lhs = ret;
return lhs;
}
template < typename T, typename U, typename E >
T& operator &=( T& lhs, SafeInt< U, E > rhs ) throw()
{
lhs = details::BinaryAndHelper< T, U >::And( lhs, (U)rhs );
return lhs;
}
template < typename T, typename U, typename E >
T& operator ^=( T& lhs, SafeInt< U, E > rhs ) throw()
{
lhs = details::BinaryXorHelper< T, U >::Xor( lhs, (U)rhs );
return lhs;
}
template < typename T, typename U, typename E >
T& operator |=( T& lhs, SafeInt< U, E > rhs ) throw()
{
lhs = details::BinaryOrHelper< T, U >::Or( lhs, (U)rhs );
return lhs;
}
template < typename T, typename U, typename E >
T& operator <<=( T& lhs, SafeInt< U, E > rhs ) throw()
{
lhs = (T)( SafeInt< T, E >( lhs ) << (U)rhs );
return lhs;
}
template < typename T, typename U, typename E >
T& operator >>=( T& lhs, SafeInt< U, E > rhs ) throw()
{
lhs = (T)( SafeInt< T, E >( lhs ) >> (U)rhs );
return lhs;
}
// Specific pointer overrides
// Note - this function makes no attempt to ensure
// that the resulting pointer is still in the buffer, only
// that no int overflows happened on the way to getting the new pointer
template < typename T, typename U, typename E >
T*& operator +=( T*& lhs, SafeInt< U, E > rhs )
{
// Cast the pointer to a number so we can do arithmetic
SafeInt< uintptr_t, E > ptr_val = reinterpret_cast< uintptr_t >( lhs );
// Check first that rhs is valid for the type of ptrdiff_t
// and that multiplying by sizeof( T ) doesn't overflow a ptrdiff_t
// Next, we need to add 2 SafeInts of different types, so unbox the ptr_diff
// Finally, cast the number back to a pointer of the correct type
lhs = reinterpret_cast< T* >( (uintptr_t)( ptr_val + (ptrdiff_t)( SafeInt< ptrdiff_t, E >( rhs ) * sizeof( T ) ) ) );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator -=( T*& lhs, SafeInt< U, E > rhs )
{
// Cast the pointer to a number so we can do arithmetic
SafeInt< size_t, E > ptr_val = reinterpret_cast< uintptr_t >( lhs );
// See above for comments
lhs = reinterpret_cast< T* >( (uintptr_t)( ptr_val - (ptrdiff_t)( SafeInt< ptrdiff_t, E >( rhs ) * sizeof( T ) ) ) );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator *=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator /=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator %=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator &=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator ^=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator |=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator <<=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
template < typename T, typename U, typename E >
T*& operator >>=( T* lhs, SafeInt< U, E > rhs )
{
static_assert( false, "SafeInt<T>: This operator explicitly not supported" );
return lhs;
}
// Shift operators
// NOTE - shift operators always return the type of the lhs argument
// Left shift
template < typename T, typename U, typename E >
SafeInt< U, E > operator <<( U lhs, SafeInt< T, E > bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< T >::isSigned || (T)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( (T)bits < (int)details::IntTraits< U >::bitCount );
return SafeInt< U, E >( (U)( lhs << (T)bits ) );
}
// Right shift
template < typename T, typename U, typename E >
SafeInt< U, E > operator >>( U lhs, SafeInt< T, E > bits ) throw()
{
_SAFEINT_SHIFT_ASSERT( !details::IntTraits< T >::isSigned || (T)bits >= 0 );
_SAFEINT_SHIFT_ASSERT( (T)bits < (int)details::IntTraits< U >::bitCount );
return SafeInt< U, E >( (U)( lhs >> (T)bits ) );
}
// Bitwise operators
// This only makes sense if we're dealing with the same type and size
// demand a type T, or something that fits into a type T.
// Bitwise &
template < typename T, typename U, typename E >
SafeInt< T, E > operator &( U lhs, SafeInt< T, E > rhs ) throw()
{
return SafeInt< T, E >( details::BinaryAndHelper< T, U >::And( (T)rhs, lhs ) );
}
// Bitwise XOR
template < typename T, typename U, typename E >
SafeInt< T, E > operator ^( U lhs, SafeInt< T, E > rhs ) throw()
{
return SafeInt< T, E >(details::BinaryXorHelper< T, U >::Xor( (T)rhs, lhs ) );
}
// Bitwise OR
template < typename T, typename U, typename E >
SafeInt< T, E > operator |( U lhs, SafeInt< T, E > rhs ) throw()
{
return SafeInt< T, E >( details::BinaryOrHelper< T, U >::Or( (T)rhs, lhs ) );
}
} // namespace utilities
} // namespace msl
#pragma pack(pop)