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safemath.h
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safemath.h
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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
// See the LICENSE file in the project root for more information.
// ---------------------------------------------------------------------------
// safemath.h
//
// overflow checking infrastructure
// ---------------------------------------------------------------------------
#ifndef SAFEMATH_H_
#define SAFEMATH_H_
// This file is included from several places outside the CLR, so we can't
// pull in files like DebugMacros.h. However, we assume that the standard
// clrtypes (UINT32 etc.) are defined.
#include "debugmacrosext.h"
#ifndef _ASSERTE_SAFEMATH
#ifdef _ASSERTE
// Use _ASSERTE if we have it (should always be the case in the CLR)
#define _ASSERTE_SAFEMATH _ASSERTE
#else
// Otherwise (eg. we're being used from a tool like SOS) there isn't much
// we can rely on that is available everywhere. In
// several other tools we just take the recourse of disabling asserts,
// we'll do the same here.
// Ideally we'd have a collection of common utilities available evererywhere.
#define _ASSERTE_SAFEMATH(a)
#endif
#endif
#include "static_assert.h"
#ifdef PAL_STDCPP_COMPAT
#include <type_traits>
#else
#include "clr_std/type_traits"
#endif
//==================================================================
// Semantics: if val can be represented as the exact same value
// when cast to Dst type, then FitsIn<Dst>(val) will return true;
// otherwise FitsIn returns false.
//
// Dst and Src must both be integral types.
//
// It's important to note that most of the conditionals in this
// function are based on static type information and as such will
// be optimized away. In particular, the case where the signs are
// identical will result in no code branches.
#ifdef _PREFAST_
#pragma warning(push)
#pragma warning(disable:6326) // PREfast warning: Potential comparison of a constant with another constant
#endif // _PREFAST_
template <typename Dst, typename Src>
inline bool FitsIn(Src val)
{
#ifdef _MSC_VER
static_assert_no_msg(!__is_class(Dst));
static_assert_no_msg(!__is_class(Src));
#endif
if (std::is_signed<Src>::value == std::is_signed<Dst>::value)
{ // Src and Dst are equally signed
if (sizeof(Src) <= sizeof(Dst))
{ // No truncation is possible
return true;
}
else
{ // Truncation is possible, requiring runtime check
return val == (Src)((Dst)val);
}
}
else if (std::is_signed<Src>::value)
{ // Src is signed, Dst is unsigned
#ifdef __GNUC__
// Workaround for GCC warning: "comparison is always
// false due to limited range of data type."
if (!(val == 0 || val > 0))
#else
if (val < 0)
#endif
{ // A negative number cannot be represented by an unsigned type
return false;
}
else
{
if (sizeof(Src) <= sizeof(Dst))
{ // No truncation is possible
return true;
}
else
{ // Truncation is possible, requiring runtime check
return val == (Src)((Dst)val);
}
}
}
else
{ // Src is unsigned, Dst is signed
if (sizeof(Src) < sizeof(Dst))
{ // No truncation is possible. Note that Src is strictly
// smaller than Dst.
return true;
}
else
{ // Truncation is possible, requiring runtime check
#ifdef __GNUC__
// Workaround for GCC warning: "comparison is always
// true due to limited range of data type." If in fact
// Dst were unsigned we'd never execute this code
// anyway.
return ((Dst)val > 0 || (Dst)val == 0) &&
#else
return ((Dst)val >= 0) &&
#endif
(val == (Src)((Dst)val));
}
}
}
// Requires that Dst is an integral type, and that DstMin and DstMax are the
// minimum and maximum values of that type, respectively. Returns "true" iff
// "val" can be represented in the range [DstMin..DstMax] (allowing loss of precision, but
// not truncation).
template <INT64 DstMin, UINT64 DstMax>
inline bool FloatFitsInIntType(float val)
{
float DstMinF = static_cast<float>(DstMin);
float DstMaxF = static_cast<float>(DstMax);
return DstMinF <= val && val <= DstMaxF;
}
template <INT64 DstMin, UINT64 DstMax>
inline bool DoubleFitsInIntType(double val)
{
double DstMinD = static_cast<double>(DstMin);
double DstMaxD = static_cast<double>(DstMax);
return DstMinD <= val && val <= DstMaxD;
}
#ifdef _PREFAST_
#pragma warning(pop)
#endif //_PREFAST_
#define ovadd_lt(a, b, rhs) (((a) + (b) < (rhs) ) && ((a) + (b) >= (a)))
#define ovadd_le(a, b, rhs) (((a) + (b) <= (rhs) ) && ((a) + (b) >= (a)))
#define ovadd_gt(a, b, rhs) (((a) + (b) > (rhs) ) || ((a) + (b) < (a)))
#define ovadd_ge(a, b, rhs) (((a) + (b) >= (rhs) ) || ((a) + (b) < (a)))
#define ovadd3_gt(a, b, c, rhs) (((a) + (b) + (c) > (rhs)) || ((a) + (b) < (a)) || ((a) + (b) + (c) < (c)))
//-----------------------------------------------------------------------------
//
// Liberally lifted from the Office example on MSDN and modified.
// http://msdn.microsoft.com/library/en-us/dncode/html/secure01142004.asp
//
// Modified to track an overflow bit instead of throwing exceptions. In most
// cases the Visual C++ optimizer (Whidbey beta1 - v14.00.40607) is able to
// optimize the bool away completely.
// Note that using a sentinal value (IntMax for example) to represent overflow
// actually results in poorer code-gen.
//
// This has also been simplified significantly to remove functionality we
// don't currently want (division, implicit conversions, many additional operators etc.)
//
// Example:
// unsafe: UINT32 bufSize = headerSize + elementCount * sizeof(void*);
// becomes:
// S_UINT32 bufSize = S_UINT32(headerSize) + S_UINT32(elementCount) *
// S_UINT32( sizeof(void*) );
// if( bufSize.IsOverflow() ) { <overflow-error> }
// else { use bufSize.Value() }
// or:
// UINT32 tmp, bufSize;
// if( !ClrSafeInt<UINT32>::multiply( elementCount, sizeof(void*), tmp ) ||
// !ClrSafeInt<UINT32>::addition( tmp, headerSize, bufSize ) )
// { <overflow-error> }
// else { use bufSize }
//
//-----------------------------------------------------------------------------
// TODO: Any way to prevent unintended instantiations? This is only designed to
// work with unsigned integral types (signed types will work but we probably
// don't need signed support).
template<typename T> class ClrSafeInt
{
public:
// Default constructor - 0 value by default
ClrSafeInt() :
m_value(0),
m_overflow(false)
COMMA_INDEBUG( m_checkedOverflow( false ) )
{
}
// Value constructor
// This is explicit because otherwise it would be harder to
// differentiate between checked and unchecked usage of an operator.
// I.e. si + x + y vs. si + ( x + y )
//
// Set the m_checkedOverflow bit to true since this is being initialized
// with a constant value and we know that it is valid. A scenario in
// which this is useful is when an overflow causes a fallback value to
// be used:
// if (val.IsOverflow())
// val = ClrSafeInt<T>(some_value);
explicit ClrSafeInt( T v ) :
m_value(v),
m_overflow(false)
COMMA_INDEBUG( m_checkedOverflow( true ) )
{
}
template <typename U>
explicit ClrSafeInt(U u) :
m_value(0),
m_overflow(false)
COMMA_INDEBUG( m_checkedOverflow( false ) )
{
if (!FitsIn<T>(u))
{
m_overflow = true;
}
else
{
m_value = (T)u;
}
}
template <typename U>
ClrSafeInt(ClrSafeInt<U> u) :
m_value(0),
m_overflow(false)
COMMA_INDEBUG( m_checkedOverflow( false ) )
{
if (u.IsOverflow() || !FitsIn<T>(u.Value()))
{
m_overflow = true;
}
else
{
m_value = (T)u.Value();
}
}
// Note: compiler-generated copy constructor and assignment operator
// are correct for our purposes.
// Note: The MS compiler will sometimes silently perform value-destroying
// conversions when calling the operators below.
// Eg. "ClrSafeInt<unsigned> s(0); s += int(-1);" will result in s
// having the value 0xffffffff without generating a compile-time warning.
// Narrowing conversions are generally level 4 warnings so may or may not
// be visible.
//
// In the original SafeInt class, all operators have an
// additional overload that takes an arbitrary type U and then safe
// conversions are performed (resulting in overflow whenever the value
// cannot be preserved).
// We could do the same thing, but currently don't because:
// - we don't believe there are common cases where this would result in a
// security hole.
// - the extra complexity isn't worth the benefits
// - it would prevent compiler warnings in the cases we do get warnings for.
// true if there has been an overflow leading up to the creation of this
// value, false otherwise.
// Note that in debug builds we track whether our client called this,
// so we should not be calling this method ourselves from within this class.
inline bool IsOverflow() const
{
INDEBUG( m_checkedOverflow = true; )
return m_overflow;
}
// Get the value of this integer.
// Must only be called when IsOverflow()==false. If this is called
// on overflow we'll assert in Debug and return 0 in release.
inline T Value() const
{
_ASSERTE_SAFEMATH( m_checkedOverflow ); // Ensure our caller first checked the overflow bit
_ASSERTE_SAFEMATH( !m_overflow );
return m_value;
}
// force the value into the overflow state.
inline void SetOverflow()
{
INDEBUG( this->m_checkedOverflow = false; )
this->m_overflow = true;
// incase someone manages to call Value in release mode - should be optimized out
this->m_value = 0;
}
//
// OPERATORS
//
// Addition and multiplication. Only permitted when both sides are explicitly
// wrapped inside of a ClrSafeInt and when the types match exactly.
// If we permitted a RHS of type 'T', then there would be differences
// in correctness between mathematically equivalent expressions such as
// "si + x + y" and "si + ( x + y )". Unfortunately, not permitting this
// makes expressions involving constants tedius and ugly since the constants
// must be wrapped in ClrSafeInt instances. If we become confident that
// our tools (PreFast) will catch all integer overflows, then we can probably
// safely add this.
inline ClrSafeInt<T> operator +(ClrSafeInt<T> rhs) const
{
ClrSafeInt<T> result; // value is initialized to 0
if( this->m_overflow ||
rhs.m_overflow ||
!addition( this->m_value, rhs.m_value, result.m_value ) )
{
result.m_overflow = true;
}
return result;
}
inline ClrSafeInt<T> operator -(ClrSafeInt<T> rhs) const
{
ClrSafeInt<T> result; // value is initialized to 0
if( this->m_overflow ||
rhs.m_overflow ||
!subtraction( this->m_value, rhs.m_value, result.m_value ) )
{
result.m_overflow = true;
}
return result;
}
inline ClrSafeInt<T> operator *(ClrSafeInt<T> rhs) const
{
ClrSafeInt<T> result; // value is initialized to 0
if( this->m_overflow ||
rhs.m_overflow ||
!multiply( this->m_value, rhs.m_value, result.m_value ) )
{
result.m_overflow = true;
}
return result;
}
// Accumulation operators
// Here it's ok to have versions that take a value of type 'T', however we still
// don't allow any mixed-type operations.
inline ClrSafeInt<T>& operator +=(ClrSafeInt<T> rhs)
{
INDEBUG( this->m_checkedOverflow = false; )
if( this->m_overflow ||
rhs.m_overflow ||
!ClrSafeInt<T>::addition( this->m_value, rhs.m_value, this->m_value ) )
{
this->SetOverflow();
}
return *this;
}
inline ClrSafeInt<T>& operator +=(T rhs)
{
INDEBUG( this->m_checkedOverflow = false; )
if( this->m_overflow ||
!ClrSafeInt<T>::addition( this->m_value, rhs, this->m_value ) )
{
this->SetOverflow();
}
return *this;
}
inline ClrSafeInt<T>& operator *=(ClrSafeInt<T> rhs)
{
INDEBUG( this->m_checkedOverflow = false; )
if( this->m_overflow ||
rhs.m_overflow ||
!ClrSafeInt<T>::multiply( this->m_value, rhs.m_value, this->m_value ) )
{
this->SetOverflow();
}
return *this;
}
inline ClrSafeInt<T>& operator *=(T rhs)
{
INDEBUG( this->m_checkedOverflow = false; )
if( this->m_overflow ||
!ClrSafeInt<T>::multiply( this->m_value, rhs, this->m_value ) )
{
this->SetOverflow();
}
return *this;
}
//
// STATIC HELPER METHODS
//these compile down to something as efficient as macros and allow run-time testing
//of type by the developer
//
template <typename U> static bool IsSigned(U)
{
return std::is_signed<U>::value;
}
static bool IsSigned()
{
return std::is_signed<T>::value;
}
static bool IsMixedSign(T lhs, T rhs)
{
return ((lhs ^ rhs) < 0);
}
static unsigned char BitCount(){return (sizeof(T)*8);}
static bool Is64Bit(){return sizeof(T) == 8;}
static bool Is32Bit(){return sizeof(T) == 4;}
static bool Is16Bit(){return sizeof(T) == 2;}
static bool Is8Bit(){return sizeof(T) == 1;}
//both of the following should optimize away
static T MaxInt()
{
if(IsSigned())
{
return (T)~((T)1 << (BitCount()-1));
}
//else
return (T)(~(T)0);
}
static T MinInt()
{
if(IsSigned())
{
return (T)((T)1 << (BitCount()-1));
}
else
{
return ((T)0);
}
}
// Align a value up to the nearest boundary, which must be a power of 2
inline void AlignUp( T alignment )
{
_ASSERTE_SAFEMATH( IsPowerOf2( alignment ) );
*this += (alignment - 1);
if( !this->m_overflow )
{
m_value &= ~(alignment - 1);
}
}
//
// Arithmetic implementation functions
//
//note - this looks complex, but most of the conditionals
//are constant and optimize away
//for example, a signed 64-bit check collapses to:
/*
if(lhs == 0 || rhs == 0)
return 0;
if(MaxInt()/+lhs < +rhs)
{
//overflow
throw SafeIntException(ERROR_ARITHMETIC_OVERFLOW);
}
//ok
return lhs * rhs;
Which ought to inline nicely
*/
// Returns true if safe, false for overflow.
static bool multiply(T lhs, T rhs, T &result)
{
if(Is64Bit())
{
//fast track this one - and avoid DIV_0 below
if(lhs == 0 || rhs == 0)
{
result = 0;
return true;
}
//we're 64 bit - slow, but the only way to do it
if(IsSigned())
{
if(!IsMixedSign(lhs, rhs))
{
//both positive or both negative
//result will be positive, check for lhs * rhs > MaxInt
if(lhs > 0)
{
//both positive
if(MaxInt()/lhs < rhs)
{
//overflow
return false;
}
}
else
{
//both negative
//comparison gets tricky unless we force it to positive
//EXCEPT that -MinInt is undefined - can't be done
//And MinInt always has a greater magnitude than MaxInt
if(lhs == MinInt() || rhs == MinInt())
{
//overflow
return false;
}
#ifdef _MSC_VER
#pragma warning(push)
#pragma warning( disable : 4146 ) // unary minus applied to unsigned is still unsigned
#endif
if(MaxInt()/(-lhs) < (-rhs) )
{
//overflow
return false;
}
#ifdef _MSC_VER
#pragma warning(pop)
#endif
}
}
else
{
//mixed sign - this case is difficult
//test case is lhs * rhs < MinInt => overflow
//if lhs < 0 (implies rhs > 0),
//lhs < MinInt/rhs is the correct test
//else if lhs > 0
//rhs < MinInt/lhs is the correct test
//avoid dividing MinInt by a negative number,
//because MinInt/-1 is a corner case
if(lhs < 0)
{
if(lhs < MinInt()/rhs)
{
//overflow
return false;
}
}
else
{
if(rhs < MinInt()/lhs)
{
//overflow
return false;
}
}
}
//ok
result = lhs * rhs;
return true;
}
else
{
//unsigned, easy case
if(MaxInt()/lhs < rhs)
{
//overflow
return false;
}
//ok
result = lhs * rhs;
return true;
}
}
else if(Is32Bit())
{
//we're 32-bit
if(IsSigned())
{
INT64 tmp = (INT64)lhs * (INT64)rhs;
//upper 33 bits must be the same
//most common case is likely that both are positive - test first
if( (tmp & 0xffffffff80000000LL) == 0 ||
(tmp & 0xffffffff80000000LL) == 0xffffffff80000000LL)
{
//this is OK
result = (T)tmp;
return true;
}
//overflow
return false;
}
else
{
UINT64 tmp = (UINT64)lhs * (UINT64)rhs;
if (tmp & 0xffffffff00000000ULL) //overflow
{
//overflow
return false;
}
result = (T)tmp;
return true;
}
}
else if(Is16Bit())
{
//16-bit
if(IsSigned())
{
INT32 tmp = (INT32)lhs * (INT32)rhs;
//upper 17 bits must be the same
//most common case is likely that both are positive - test first
if( (tmp & 0xffff8000) == 0 || (tmp & 0xffff8000) == 0xffff8000)
{
//this is OK
result = (T)tmp;
return true;
}
//overflow
return false;
}
else
{
UINT32 tmp = (UINT32)lhs * (UINT32)rhs;
if (tmp & 0xffff0000) //overflow
{
return false;
}
result = (T)tmp;
return true;
}
}
else //8-bit
{
_ASSERTE_SAFEMATH(Is8Bit());
if(IsSigned())
{
INT16 tmp = (INT16)lhs * (INT16)rhs;
//upper 9 bits must be the same
//most common case is likely that both are positive - test first
if( (tmp & 0xff80) == 0 || (tmp & 0xff80) == 0xff80)
{
//this is OK
result = (T)tmp;
return true;
}
//overflow
return false;
}
else
{
UINT16 tmp = ((UINT16)lhs) * ((UINT16)rhs);
if (tmp & 0xff00) //overflow
{
return false;
}
result = (T)tmp;
return true;
}
}
}
// Returns true if safe, false on overflow
static inline bool addition(T lhs, T rhs, T &result)
{
if(IsSigned())
{
//test for +/- combo
if(!IsMixedSign(lhs, rhs))
{
//either two negatives, or 2 positives
#ifdef __GNUC__
// Workaround for GCC warning: "comparison is always
// false due to limited range of data type."
if (!(rhs == 0 || rhs > 0))
#else
if(rhs < 0)
#endif // __GNUC__ else
{
//two negatives
if(lhs < (T)(MinInt() - rhs)) //remember rhs < 0
{
return false;
}
//ok
}
else
{
//two positives
if((T)(MaxInt() - lhs) < rhs)
{
return false;
}
//OK
}
}
//else overflow not possible
result = lhs + rhs;
return true;
}
else //unsigned
{
if((T)(MaxInt() - lhs) < rhs)
{
return false;
}
result = lhs + rhs;
return true;
}
}
// Returns true if safe, false on overflow
static inline bool subtraction(T lhs, T rhs, T& result)
{
T tmp = lhs - rhs;
if(IsSigned())
{
if(IsMixedSign(lhs, rhs)) //test for +/- combo
{
//mixed positive and negative
//two cases - +X - -Y => X + Y - check for overflow against MaxInt()
// -X - +Y - check for overflow against MinInt()
if(lhs >= 0) //first case
{
//test is X - -Y > MaxInt()
//equivalent to X > MaxInt() - |Y|
//Y == MinInt() creates special case
//Even 0 - MinInt() can't be done
//note that the special case collapses into the general case, due to the fact
//MaxInt() - MinInt() == -1, and lhs is non-negative
//OR tmp should be GTE lhs
// old test - leave in for clarity
//if(lhs > (T)(MaxInt() + rhs)) //remember that rhs is negative
if(tmp < lhs)
{
return false;
}
//fall through to return value
}
else
{
//second case
//test is -X - Y < MinInt()
//or -X < MinInt() + Y
//we do not have the same issues because abs(MinInt()) > MaxInt()
//tmp should be LTE lhs
//if(lhs < (T)(MinInt() + rhs)) // old test - leave in for clarity
if(tmp > lhs)
{
return false;
}
//fall through to return value
}
}
// else
//both negative, or both positive
//no possible overflow
result = tmp;
return true;
}
else
{
//easy unsigned case
if(lhs < rhs)
{
return false;
}
result = tmp;
return true;
}
}
private:
// Private helper functions
// Note that's it occasionally handy to call the arithmetic implementation
// functions above so we leave them public, even though we almost always use
// the operators instead.
// True if the specified value is a power of two.
static inline bool IsPowerOf2( T x )
{
// find the smallest power of 2 >= x
T testPow = 1;
while( testPow < x )
{
testPow = testPow << 1; // advance to next power of 2
if( testPow <= 0 )
{
return false; // overflow
}
}
return( testPow == x );
}
//
// Instance data
//
// The integer value this instance represents, or 0 if overflow.
T m_value;
// True if overflow has been reached. Once this is set, it cannot be cleared.
bool m_overflow;
// In debug builds we verify that our caller checked the overflow bit before
// accessing the value. This flag is cleared on initialization, and whenever
// m_value or m_overflow changes, and set only when IsOverflow
// is called.
INDEBUG( mutable bool m_checkedOverflow; )
};
// Allows creation of a ClrSafeInt corresponding to the type of the argument.
template <typename T>
ClrSafeInt<T> AsClrSafeInt(T t)
{
return ClrSafeInt<T>(t);
}
template <typename T>
ClrSafeInt<T> AsClrSafeInt(ClrSafeInt<T> t)
{
return t;
}
// Convenience safe-integer types. Currently these are the only types
// we are using ClrSafeInt with. We may want to add others.
// These type names are based on our standardized names in clrtypes.h
typedef ClrSafeInt<UINT8> S_UINT8;
typedef ClrSafeInt<UINT16> S_UINT16;
//typedef ClrSafeInt<UINT32> S_UINT32;
#define S_UINT32 ClrSafeInt<UINT32>
typedef ClrSafeInt<UINT64> S_UINT64;
typedef ClrSafeInt<SIZE_T> S_SIZE_T;
#endif // SAFEMATH_H_