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In the C++ standard it says of floating literals:

If the scaled value is not in the range of representable values for its type, the program is ill-formed.

The scaled value is the significant part multiplied by 10 ^ exponent part.

Under x86-64:

  • float is a single-precision IEEE-754
  • double is a double-precision IEEE-754
  • long double is an 80-bit extended precision IEEE-754

In this context, what is the range of repsentable values for each of these three types? Where is this documented? or how is it calculated?

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Under x86-64, FP arithmetic is done with SSE, and therefore long double is 64 bits. –  MSalters Mar 2 '13 at 14:59
@MSalters: Can you clear this up here: stackoverflow.com/questions/15176290/… –  Andrew Tomazos Mar 2 '13 at 15:46
@MSalters: Cleared up now: Under the System V (Linux) x86-64 ABI, long double is 80 bits and implemented with the FPU (and not SSE). On Windows long double is defined as 64-bit. So it is different depending on the OS. –  Andrew Tomazos Mar 2 '13 at 16:07
@AndrewTomazos it's depending on the compiler. GCC on Windows can also support 80-bit long double –  Lưu Vĩnh Phúc Jun 1 at 10:34

3 Answers 3

up vote 2 down vote accepted

The answer (if you're on a machine with IEEE floating point) is in float.h. FLT_MAX, DBL_MAX and LDBL_MAX. On a system with full IEEE support, something around 3.4e+38, 1.8E+308 and 1.2E4932. (The exact values may vary, and may be expressed differently, depending on how the compiler does its input and rounding. g++, for example, defines them to be compiler built-ins.)


WRT your question (since neither I nor the other responders actually answered it): the range of representable values is [-type_MAX...type], where type is one of FLT, DBL, or LDBL.

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If you know the number of exponent bits and mantissa bits, then based on the IEEE-754 format, one can establish that the maximum absolute representable value is:

2^(2^(E-1)-1)) * (1 + (2^M-1)/2^M)

The minimum absolute value (not including zero or denormals) is:

  • For single-precision, E is 8, M is 23.
  • For double-precision, E is 11, M is 52.
  • For extended-precision, I'm not sure. If you're referring to the 80-bit precision of the x87 FPU, then so far as I can tell, it's not's IEEE-754 compliant...
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If E is a number of bits for the exponent, there is a 2^ missing in your formula, isn't there? –  Pascal Cuoq Mar 2 '13 at 13:27
@PascalCuoq: yes, you're right. Thanks! –  Oliver Charlesworth Mar 2 '13 at 13:28

The C++ standard library includes std::numeric_limits for this purpose. You can use:

std::numeric_limits<long double>::min()
std::numeric_limits<long double>::max()

to get the range of values a given floating point type supports. You can also use std::numeric_limits<T>::digits() to get the number of radix digits for each type.

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Only if your architecture and compiler supports full IEEE. (Microsoft compilers, for example, don't.) Of course, the information returned by these functions is probably more useful to you than some theoretical value. (But it's not sure. Although std::numeric_limits<long double>::max() will return the same as for double with Microsoft compilers, actual computation will use true IEEE long double for most intermediate values.) –  James Kanze Mar 2 '13 at 13:42
Also, beware of the signification of std::numeric_limits<T>::min(). For floating point types, it is the smallest value greater than zero that can be represented. The range of representable values is -std::numeric_limits<double>::max()...std::numeric_limits<double>::max(). –  James Kanze Mar 2 '13 at 13:48
@JamesKanze: C++11 introduced the lowest() function for range computation, but I am not sure how well supported it is in current compoiles –  talonmies Mar 2 '13 at 14:03
Yes. I was aware of some discussion about this; the fact that numeric_limits::min() had different semantics according to the type didn't really please some people. (On the other hand, it did correspond to the historical use, e.g. INT_MIN vs. DBL_MIN.) –  James Kanze Mar 2 '13 at 16:05

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