11

I am trying to write a C++ template function that will throw a runtime exception on integer overflow in casts between different integral types, with different widths, and possible signed/unsigned mismatch. For these purposes I'm not concerned with casting from floating-point types to integral types, nor other object-to-object conversions. I'd like to do this without having to write lots of special case code. This is what I currently have:

template< typename T, typename R > void safe_cast( const T& source, R& result )
{
    // get the maximum safe value of type R
    R rMax = (R) ~0;
    if ( rMax < 0 ) // R is a signed type
    {
        // assume that we're on an 8-bit twos-compliment machine
        rMax = ~( 0x80 << ( ( sizeof( R ) - 1 ) * 8 ) );
    }

    if ( ( source & rMax  ) != source )
    {
        throw new IntegerOverflowException( source );
    }

    result = static_cast<R>( source );
}

Is this correct and efficient?

EDIT: For various reasons stl isn't available, so I can't use std::numeric_limits, and anything from Boost is right out.

3
  • But you could copy the code you need from numeric_limits into your own templated helper. Assign everything to uint64 (or whatever the maximum allowable size is) and do comparisons within that type. – Drew Hoskins Jun 15 '09 at 22:54
  • 1
    That might work, but one really needs to be aware of the licensing terms when copying code like this. Besides potentially violating the terms, one could inadvertently "infect" their code, as is the case with the GPL. Make sure both licenses are compatible before doing this sort of thing. The usual "I am not a lawyer" disclaimer applies. – Void Jun 15 '09 at 23:22
  • What are the various reasons you can't use the STL? – GManNickG Aug 28 '09 at 20:28

10 Answers 10

5

Have you tried SafeInt? It's a cross platform template that will do integer overflow checks for a variety of integer types. It's available on github

12

You can get the minimum and maximum safe values (and a whole lot of other information) for any fundamental type in a much more elegant way using the std::numeric_limits template, e.g. std::numeric_limits<T>::max(). You'll need to include <limits>.

Reference: http://www.cplusplus.com/reference/std/limits/numeric_limits/

2
  • this edit 7 years later made me change my upvote to a downvote. Because the presented example added by @jpo38 does not work. Example pair: From=int, To=unsigned. source==-1. – Johannes Schaub - litb Feb 22 '17 at 17:56
  • Actually, I saw that and fixed that in my code since I edited this post. But forgot to update the edit...sorry. I now throw if static_cast<From>(static_cast<To>( source ) ) != source (basically, if some information were lost by the cast...this works great. Somehow similar to what Tim proposes below. No reference to max/min wish fails when moving from signed to unsigned and the way around. – jpo38 Feb 22 '17 at 19:41
11

Is boost an option? If so, try boost::numeric_cast<>. It appears to provide the characteristics you're looking for.

8

I think these work now, regardless of whether you use two's complement or not. Please test extensively before you use it. They give the following results. Each line gives one assertion failure (just change them into exceptions as you please)

/* unsigned -> signed, overflow */
safe_cast<short>(UINT_MAX);

/* unsigned -> unsigned, overflow */
safe_cast<unsigned char>(ULONG_MAX);

/* signed -> unsigned, overflow */
safe_cast<unsigned long>(-1);

/* signed -> signed, overflow */
safe_cast<signed char>(INT_MAX);

/* always works (no check done) */
safe_cast<long>(INT_MAX);

// giving these assertion failures results
(type)f <= (type)is_signed<To>::v_max
f <= (To)-1
f >= 0
f >= is_signed<To>::v_min && f <= is_signed<To>::v_max

Implementation. First some utilities to check for integer ranks (types with higher ranks will be able to contain values of types with lower rank, given the same sign. And some promotion tools, to be able to figure out a common, safe type (this will never yield a signed type if an unsigned type is involved, if the signed type won't be able to store all values of the unsigned one).

/* ranks */
template<typename> struct int_rank;
#define RANK(T, I) template<> struct int_rank<T> \
    { static int const value = I; }

RANK(char, 1); RANK(unsigned char, 1); RANK(signed char, 1); 
RANK(short, 2); RANK(unsigned short, 2);
RANK(int, 3); RANK(unsigned int, 3);
RANK(long, 4); RANK(unsigned long, 4);
#undef RANK

/* usual arith. conversions for ints (pre-condition: A, B differ) */
template<int> struct uac_at;
template<> struct uac_at<1> { typedef int type; };
template<> struct uac_at<2> { typedef unsigned int type; };
template<> struct uac_at<3> { typedef long type; };
template<> struct uac_at<4> { typedef unsigned long type; };

template<typename A, typename B>
struct uac_type { 
    static char (&f(int))[1];
    static char (&f(unsigned int))[2];
    static char (&f(long))[3];
    static char (&f(unsigned long))[4];
    typedef typename uac_at<sizeof f(0 ? A() : B())>::type type; 
};

/* signed games */
template<typename> struct is_signed { static bool const value = false; };
#define SG(X, TT) template<> struct is_signed<X> { \
    static bool const value = true;                \
    static X const v_min = TT##_MIN;               \
    static X const v_max = TT##_MAX;               \
}

SG(signed char, SCHAR); 
SG(short, SHRT); 
SG(int, INT); 
SG(long, LONG); 
#undef SG

template<> struct is_signed<char> { 
    static bool const value = (CHAR_MIN < 0); 
    static char const v_min = CHAR_MIN; // just in case it's signed...
    static char const v_max = CHAR_MAX;
};

The conversion templates make use of them, to figure out for each case when what needs to be done or not done.

template<typename To, typename From, 
         bool to_signed = is_signed<To>::value, 
         bool from_signed = is_signed<From>::value,
         bool rank_fine = (int_rank<To>::value >= int_rank<From>::value)>
struct do_conv;

/* these conversions never overflow, like int -> int, 
 * or  int -> long. */
template<typename To, typename From, bool Sign>
struct do_conv<To, From, Sign, Sign, true> {
    static To call(From f) {
        return (To)f; 
    }
};

template<typename To, typename From>
struct do_conv<To, From, false, false, false> {
    static To call(From f) {
        assert(f <= (To)-1);
        return (To)f;
    }
};

template<typename To, typename From>
struct do_conv<To, From, false, true, true> {
    typedef typename uac_type<To, From>::type type;
    static To call(From f) {
        /* no need to check whether To's positive range will
         * store From's positive range: Because the rank is
         * fine, and To is unsigned. 
         * Fixes GCC warning "comparison is always true" */
        assert(f >= 0);
        return (To)f;
    }
};

template<typename To, typename From>
struct do_conv<To, From, false, true, false> {
    typedef typename uac_type<To, From>::type type;
    static To call(From f) {
        assert(f >= 0 && (type)f <= (type)(To)-1);
        return (To)f;
    }
};

template<typename To, typename From, bool Rank>
struct do_conv<To, From, true, false, Rank> {
    typedef typename uac_type<To, From>::type type;
    static To call(From f) {
        assert((type)f <= (type)is_signed<To>::v_max);
        return (To)f;
    }
};

template<typename To, typename From>
struct do_conv<To, From, true, true, false> {
    static To call(From f) {
        assert(f >= is_signed<To>::v_min && f <= is_signed<To>::v_max);
        return (To)f;
    }
};

template<typename To, typename From>
To safe_cast(From f) { return do_conv<To, From>::call(f); }
3

How about:

template< typename T, typename R > void safe_cast( const T& source, R& result )
{
    R temp = static_cast<R>( source );
    if (static_cast<T> (temp) != source
        || ( temp < 0 && source > 0)
        || ( temp > 0 && source < 0))
    {
        throw IntegerOverflowException( source );
    }
    result = temp;
}

Then you're just checking if the casting worked. Make sure you get back what you started with, and that the sign didn't flip.

EDIT: Since the comment below got messed up, here it is, formatted:

int myint (-1);
safe_cast( myint, mychar );
safe_cast( mychar, myuchar ); // Exception is thrown here
safe_cast( myuchar, myint );

The cast from int to char works fine. The cast from char to unsigned char throws an exception (as it should). I don't see a problem here.

2
  • o, The compiler will spit warnings when one of the two types is unsigned and the other is not (comparison is always false due to limited range of data type in g++) when comparing with 0, but it will not throw and data will be lost: If you use your cast from -1 (int) to -1 (char) to 0xFF (unsigned char) back to int you will not get -1. The cast is not 'safe' as the values get changed in the way. – David Rodríguez - dribeas Jun 16 '09 at 5:42
  • ah, I had tested with a different compiler. The warnings refer to "temp < 0" when temp is unsigned, which is ok. It shouldn't throw at this point, and no data is lost. I tested what you suggest, i.e.: int myint (-1); safe_cast( myint, mychar ); safe_cast( mychar, myuchar ); // Exception is thrown here safe_cast( myuchar, myint ); The cast from int to char works fine. The cast from char to unsigned char throws an exception (as it should). I don't see a problem here. – Tim Jun 16 '09 at 14:11
2

Consider Safe Numerics at https://www.boost.org/doc/libs/1_71_0/libs/safe_numerics/doc/html/index.html http://rrsd.com/blincubator.com/bi_library/safe-numerics

This library provides drop-in replacements for all C primitive integer types. C operations which result erroneous results - including casting are trapped when detected.

0
2

It's been over a decade since this question was posted, and I wanted a solution that was self contained and used modern C++ (std::optional, constexpr, type_traits). Here is what I wrote:

/// Cast integer of type "From" to integer of type "To", as long as it fits. If it doesn't
/// fit, return std::nullopt.
template<typename To, typename From>
constexpr std::optional<To> IntegerCast(From from) {
    static_assert(std::is_integral_v<From>, "IntegerCast only supports integers");
    static_assert(std::is_integral_v<To>, "IntegerCast only supports integers");
    static_assert(!std::is_same_v<To, bool>, "IntegerCast only supports integers");
    static_assert(!std::is_same_v<From, bool>, "IntegerCast only supports integers");

    constexpr bool fromSigned = std::is_signed_v<From>;
    constexpr bool toSigned = std::is_signed_v<To>;
    constexpr bool bothSigned = fromSigned && toSigned;
    constexpr bool bothUnsigned = !fromSigned && !toSigned;

    constexpr From fromMax = std::numeric_limits<From>::max();
    constexpr From fromMin = std::numeric_limits<From>::min();
    constexpr To toMax = std::numeric_limits<To>::max();
    constexpr To toMin = std::numeric_limits<To>::min();

    if constexpr (bothUnsigned) {
        using Widen = std::conditional_t<(sizeof(From) > sizeof(To)), From, To>;
        if (from > Widen(toMax)) {
            return std::nullopt;
        } else {
            return To(from);
        }
    } else if constexpr (bothSigned) {
        using Widen = std::conditional_t<(sizeof(From) > sizeof(To)), From, To>;
        if (from > Widen(toMax)) {
            return std::nullopt;
        } else if (from < Widen(toMin)) {
            return std::nullopt;
        } else {
            return To(from);
        }
    } else if constexpr (fromSigned && !toSigned) {
        using Widen =
                std::make_unsigned_t<std::conditional_t<(sizeof(From) > sizeof(To)), From, To>>;
        if (from < 0) {
            return std::nullopt;
        } else if (from > Widen(toMax)) {
            return std::nullopt;
        } else {
            return To(from);
        }
    } else if constexpr (!fromSigned && toSigned) {
        using Widen =
                std::make_unsigned_t<std::conditional_t<(sizeof(From) > sizeof(To)), From, To>>;
        if (from > Widen(toMax)) {
            return std::nullopt;
        } else {
            return To(from);
        }
    }
}

It comes with a test suite in GoogleTest

TEST(IntegerCast, Basics) {
    constexpr uint64_t large64 = 10000000000000000000ull;
    static_assert(IntegerCast<uint8_t>(large64) == std::nullopt);
    static_assert(IntegerCast<uint16_t>(large64) == std::nullopt);
    static_assert(IntegerCast<uint32_t>(large64) == std::nullopt);
    static_assert(IntegerCast<uint64_t>(large64) == 10000000000000000000ull);
    static_assert(IntegerCast<int8_t>(large64) == std::nullopt);
    static_assert(IntegerCast<int16_t>(large64) == std::nullopt);
    static_assert(IntegerCast<int32_t>(large64) == std::nullopt);
    static_assert(IntegerCast<int64_t>(large64) == std::nullopt);

    constexpr int64_t largeNegative64 = -5000000000000000000;
    static_assert(IntegerCast<uint8_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<uint16_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<uint32_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<uint64_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<int8_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<int16_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<int32_t>(largeNegative64) == std::nullopt);
    static_assert(IntegerCast<int64_t>(largeNegative64) == -5000000000000000000);

    constexpr uint64_t small64 = 1;
    static_assert(IntegerCast<uint8_t>(small64) == 1);
    static_assert(IntegerCast<uint16_t>(small64) == 1);
    static_assert(IntegerCast<uint32_t>(small64) == 1);
    static_assert(IntegerCast<uint64_t>(small64) == 1);
    static_assert(IntegerCast<int8_t>(small64) == 1);
    static_assert(IntegerCast<int16_t>(small64) == 1);
    static_assert(IntegerCast<int32_t>(small64) == 1);
    static_assert(IntegerCast<int64_t>(small64) == 1);

    constexpr int64_t smallNegative64 = -1;
    static_assert(IntegerCast<uint8_t>(smallNegative64) == std::nullopt);
    static_assert(IntegerCast<uint16_t>(smallNegative64) == std::nullopt);
    static_assert(IntegerCast<uint32_t>(smallNegative64) == std::nullopt);
    static_assert(IntegerCast<uint64_t>(smallNegative64) == std::nullopt);
    static_assert(IntegerCast<int8_t>(smallNegative64) == -1);
    static_assert(IntegerCast<int16_t>(smallNegative64) == -1);
    static_assert(IntegerCast<int32_t>(smallNegative64) == -1);
    static_assert(IntegerCast<int64_t>(smallNegative64) == -1);
}

TEST(IntegerCast, Boundaries) {
    constexpr uint8_t maxUnsigned8 = 255;
    static_assert(IntegerCast<uint8_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<uint16_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<uint32_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<uint64_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<int8_t>(maxUnsigned8) == std::nullopt);
    static_assert(IntegerCast<int16_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<int32_t>(maxUnsigned8) == 255);
    static_assert(IntegerCast<int64_t>(maxUnsigned8) == 255);

    constexpr uint8_t minUnisigned8 = 0;
    static_assert(IntegerCast<uint8_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<uint16_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<uint32_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<uint64_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<int8_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<int16_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<int32_t>(minUnisigned8) == 0);
    static_assert(IntegerCast<int64_t>(minUnisigned8) == 0);

    constexpr int8_t maxSigned8 = 127;
    static_assert(IntegerCast<uint8_t>(maxSigned8) == 127);
    static_assert(IntegerCast<uint16_t>(maxSigned8) == 127);
    static_assert(IntegerCast<uint32_t>(maxSigned8) == 127);
    static_assert(IntegerCast<uint64_t>(maxSigned8) == 127);
    static_assert(IntegerCast<int8_t>(maxSigned8) == 127);
    static_assert(IntegerCast<int16_t>(maxSigned8) == 127);
    static_assert(IntegerCast<int32_t>(maxSigned8) == 127);
    static_assert(IntegerCast<int64_t>(maxSigned8) == 127);

    constexpr int8_t minSigned8 = -128;
    static_assert(IntegerCast<uint8_t>(minSigned8) == std::nullopt);
    static_assert(IntegerCast<uint16_t>(minSigned8) == std::nullopt);
    static_assert(IntegerCast<uint32_t>(minSigned8) == std::nullopt);
    static_assert(IntegerCast<uint64_t>(minSigned8) == std::nullopt);
    static_assert(IntegerCast<int8_t>(minSigned8) == -128);
    static_assert(IntegerCast<int16_t>(minSigned8) == -128);
    static_assert(IntegerCast<int32_t>(minSigned8) == -128);
    static_assert(IntegerCast<int64_t>(minSigned8) == -128);
}

TEST(IntegerCast, SameSizeDifferentSign) {
    constexpr uint8_t above = 200;
    static_assert(IntegerCast<int8_t>(above) == std::nullopt);

    constexpr uint8_t withinUnsigned = 100;
    static_assert(IntegerCast<int8_t>(withinUnsigned) == 100);

    constexpr int8_t withinSigned = 100;
    static_assert(IntegerCast<uint8_t>(withinSigned) == 100);

    constexpr int8_t below = -100;
    static_assert(IntegerCast<uint8_t>(below) == std::nullopt);
}
1

Am I correct in assuming that in the case that R is signed you are trying to fill rMax with all 1s except for the last bit? If that's the case, then you should have 0x80 (1000 0000) instead of 0x10 (0001 0000).

Also it doesn't look like your function supports negative numbers for the source.

Edit:

Here is a slightly edited version that I've tested for converting from ints to chars:

template< typename T, typename R >
void safe_cast( const T& source, R& result )
{
    // get the maximum safe value of type R
    R rMax = (R) ~0;
    if ( rMax < 0 ) // R is a signed type
    {
        // assume that we're on an 8-bit twos-compliment machine
    rMax = ( 0x80 << ( ( sizeof( R ) - 1 ) * 8 ) );
    if(source >= 0)
        rMax = ~rMax;
    }

    if ( (source >= 0 && ( source & rMax  ) != source) || (source < 0 && (source & rMax) != rMax) )
    {
        throw new IntegerOverflowException( source );
    }

    result = static_cast<R>( source );
}

Edit: fixed error.

0

I must be missing something, but isn't this what you want?:

// using a more cast-like prototype, if I may:
template<class to, class from> inline
to safe_cast(from f)
{
   to t = static_cast<to>(f);
   if ( t != f ) throw whatever; // no new!
   return t;
}
6
  • No, if you use your cast from -1 (int) to -1 (char) to 0xFF (unsigned char) back to int you will not get -1. The cast is not 'safe' as the values get changed in the way. – David Rodríguez - dribeas Jun 16 '09 at 5:37
  • Hi Dribeas, I am sorry, I am not sure what you are saying. . safe_cast<char>(int(-1)) doesn't overflow, and returns fine . safe_cast<unsigned char>(char(-1)) changes sign (and value), and throws. hence the correct behavior. or, what are you saying? – sly Jun 16 '09 at 11:38
  • assuming char is signed, safe_cast<unsigned char>(char(-1)) will set t to UCHAR_MAX (probably 255). then if(t != f) will promote char to int, yielding to -1 and unsigned char to int, yielding 255, thus they are not equal. BUT doing safe_cast<unsigned int>(-1), it will set t to UINT_MAX, then the if will not promote anything, and convert the int to unsigned int (UAC), thus yielding UINT_MAX again, and wrongly thinking the cast succeeded. – Johannes Schaub - litb Jun 16 '09 at 16:24
  • I find that hard to believe; does C++ actually differ from C on this point? C99 makes perfectly clear that "When a value with integer type is converted to another integer type ... if the value can be represented by the new type, it is unchanged." Thus--in C--converting UCHAR_MAX to int in your example gives 255. – Stephen Canon Aug 28 '09 at 20:52
  • @stephentyrone, the same happens in my example. t is UCHAR_MAX, and when promoted to int it will be 255. What conversion do you refer to in particular? – Johannes Schaub - litb Aug 28 '09 at 21:11
0

I have a single header at sweet.hpp called conv.hpp. It will test the bounds for all integer types and also allows to and from string casts for integer.

short a = to<short>(1337);
std::string b = to<std::string>(a);
long c = to<long>(b);

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