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After performing a mathematical operation, for say, multiplying two integers, is it possible to access the overflow flag register in a CPU with C++ ? If not what are other fast ways to check for an overflow ?

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    Check this stackoverflow.com/questions/199333/…
    – acrilige
    Commented Jan 16, 2013 at 12:52
  • @acrilige thanks ,, that answers the second part of my question, any idea on how to check for the overflow AFTER performing the calculations ? Commented Jan 16, 2013 at 12:56
  • For obvious reasons it is impossible to directly access the overflow flag register in a standard, portable way. However, you can determine if an operation will overflow with a little work, and there are ways to check this or detect overflows in a non-standard non-portable way. Commented Jan 16, 2013 at 12:57
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    Why can't you check for overflow before calculations?
    – acrilige
    Commented Jan 16, 2013 at 12:58
  • Divide the result by the multiplicand. If you don't get the multiplier back then it overflowed. Commented Jan 16, 2013 at 13:30

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No, generally it's impossible. Some CPUs don't even have such a flag (e.g. MIPS).

The link provided in one of the comments will give you ideas on how you can do overflow checks.

Remember that in C and C++ signed integer overflows cause undefined behavior and legally you cannot perform overflow checks after the fact. You either need to use unsigned arithmetic or do the checks before arithmetic operations.

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I recommend this reading in every appropriate case. From Optimizing software in C++ -

Integer overflow is another security problem. The official C standard says that the behavior of signed integers in case of overflow is "undefined". This allows the compiler to ignore overflow or assume that it doesn't occur. In the case of the Gnu compiler, the assumption that signed integer overflow doesn't occur has the unfortunate consequence that it allows the compiler to optimize away an overflow check. There are a number of possible remedies against this problem: (1) check for overflow before it occurs, (2) use unsigned integers - they are guaranteed to wrap around, (3) trap integer overflow with the option -ftrapv, but this is extremely inefficient, (4) get a compiler warning for such optimizations with option -Wstrict-overflow=2, or (5) make the overflow behavior well-defined with option -fwrapv or -fno-strict-overflow.

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You'd have to do the operation and check the overflow bit in inline assembly. You could do that and jump to a label on overflow, or (more generally but less efficiently) set a variable if it overflowed.

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    It's odd to me no one else mentioned this option. While inline assembly isn't strictly c++, it's absolutely a viable option for anyone who's asking this question. There is of course, the limitation that it won't compile for all architectures, but that's up to the OP to decide if that is important or not. Commented Jul 15, 2021 at 13:23
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This is probably not what you want to do for two reasons:

  1. not every CPU has an overflow flag
  2. using C++ there is actually no way to access the overflow flag

the overflow checking tips that people have posted before might be useful.

if you really want to very write fast code that multiplies two integers and checks the overflow flag, you will have to use assembly. if you want some examples for x86, then do ask

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No. Best approach to check in advance as here

If not what are other fast ways to check for an overflow ?

If you need to test after operation you can use floating point representation (double precision) - every 32-bit integer can be represented exactly as floating point number. If all of the machines you target support IEEE (which is probably the case if you don't have to consider mainframes), you can just do the operations, then use isfinite or isinf on the results. Fast (in terms of programmer's efforts) way is: The IEEE Standard for Floating-Point Arithmetic (IEEE 754) defines five exceptions, each of which returns a default value and has a corresponding status flag that (except in certain cases of underflow) is raised when the exception occurs. The five possible exceptions are:

  • Invalid operation: mathematically undefined, e.g., the square root of a negative number. By default, returns qNaN.
  • Division by zero: an operation on finite operands gives an exact infinite result, e.g., 1/0 or log(0). By default, returns ±infinity.
  • Overflow: a result is too large to be represented correctly (i.e., its exponent with an unbounded exponent range would be larger than emax). By default, returns ±infinity for the round-to-nearest modes (and follows the rounding rules for the directed rounding modes).
  • Underflow: a result is very small (outside the normal range) and is inexact. By default, returns a subnormal or zero (following the rounding rules).
  • Inexact: the exact (i.e., unrounded) result is not representable exactly. By default, returns the correctly rounded result.
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    Note that this question is tagged integer-overflow and is about signed-integer overflow. Not FP overflow to +-Inf. You can access FP flags via fenv: en.cppreference.com/w/c/numeric/fenv. fetestexcept(FE_OVERFLOW) checks the FP overflow flag. (Only works right if you use #pragma STDC FENV_ACCESS ON or command line options for some compilers. en.cppreference.com/w/c/numeric/fenv/fetestexcept has an example.) Commented Apr 12, 2020 at 18:42
  • I see - every integer can be represent as floating point number and there is no other fast ways. Except checking in advance.
    – Vlad
    Commented Apr 12, 2020 at 22:11
  • double can represent every int32_t but not every int64_t. So yes, you could check the range of a double before converting back to int. That's hardly efficient so IDK what your point is. Some machines will have an 80-bit or wider long double that can represent every int64_t, but many C++ implementations only have 64-bit FP. Also, FP overflow is irrelevant to this problem (unless you do multiple multiplies that actually produce FP overflow). Commented Apr 12, 2020 at 22:19
  • floating point number with double precision is limited by 10^308. More than 10^64. IEEE 754 is about single and double precision.
    – Vlad
    Commented Apr 12, 2020 at 22:26
  • Yes that's the highest finite double, but the first non-representable integer-valued double is 2^53 + 1 because it has a 53-bit mantissa. en.wikipedia.org/wiki/Double-precision_floating-point_format. A 64-bit double can represent some numbers other than possible values of int64_t, therefore by the pigeonhole principle there must be some values of int64_t that don't have a double bit pattern to represent them. See Which is the first integer that an IEEE 754 float is incapable of representing exactly? Commented Apr 12, 2020 at 22:34

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