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I need a fast way to obtain the float with a given bit-pattern (provided as int32_t). Of course, the compiler should optimise the whole construction away. Simple conversion does a cast and reinterpret_cast<> is not allowed ...

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Use a union ... – Marc Glisse Feb 13 '13 at 13:52
Why is reinterpret_cast not allowed? See blogs.msdn.com/b/oldnewthing/archive/2013/02/06/10391383.aspx – John Zwinck Feb 13 '13 at 13:54
@JohnZwinck reinterpret_cast<> on the pointer types is allowed, but that does require a memory location. won't work with variable in register – Walter Feb 13 '13 at 13:56
Also, memcopy(). – Alexey Frunze Feb 13 '13 at 14:02
@PeteBecker: I'm pretty sure that I have managed in the past to persuade GCC to break your code. But not necessarily when int32value is a parameter, IIRC the breakage I had was that the strict aliasing violation resulted in the source not getting initialized. – Steve Jessop Feb 13 '13 at 14:05
up vote 5 down vote accepted

It's not reliable that the compiler will optimize this away, but it avoids UB provided that the value supplied really is a representation of a float (that is, it's the right size and its bit pattern doesn't hold a trap representation of float). GCC is at least sometimes capable of optimizing it away:

float convert(int32_t inputvalue) {
    float f;
    std::memcpy(&f, &inputvalue, sizeof(f));
    return f;

If the optimization is an important part of the question then the official answer is that there is no way to guarantee that an unknown compiler will make a given optimization. But this one is harder to optimize than most. It relies on the compiler "understanding" what memcpy does, which is a bigger ask than "understanding" what a pointer cast does.

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+1 Used this successfully, with both VC 2010 and gcc 4.6 optimizing this into a simple load of the 32-bit memory into a floating point register. I even saw this getting optimized better than the union-approach, at least for the reverse float-to-int case (which made VC use an additional roundtrip from memory over float register to int register for the union-approach, probably due to the float assignment). In fact memcpy may seem like a heavy thing, but for such simple operands the compiler really knows what to do. – Christian Rau Feb 13 '13 at 14:27

The only fully portable method is to memcpy via a buffer:

static_assert(sizeof(float) == sizeof(int32_t), "!!");
char buf[sizeof(float)];
memcpy(buf, &i, sizeof(buf));
memcpy(&f, buf, sizeof(buf));

Usually the buffer can be elided:

static_assert(sizeof(float) == sizeof(int32_t), "!!");
memcpy(&f, &i, sizeof(float));
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What is "usually"? – Marc Glisse Feb 13 '13 at 14:17
@MarcGlisse direct memcpy (not via a buffer) is only defined where the source and destination have the same type (3.9p3), but it's difficult to see how a compiler could fail to interpret direct memcpy as intended. – ecatmur Feb 13 '13 at 14:38
@ecatmur What makes you say that? Whether you pass through the intermediate buffer or not, the required semantics are exactly the same. (Both are "undefined behavior", because the bit pattern in the source might correspond to a trapping value in the destination type, but you are guaranteed to get the same bit pattern.) – James Kanze Feb 13 '13 at 14:47
@JamesKanze 3.9p2 gives copy into a buffer and back to the original object; 3.9p3 direct copy between objects of the same type. I can see how to infer that copy into a buffer and to an object of different type is defined, but not for direct copy. – ecatmur Feb 13 '13 at 15:06
@ecatmur Except that §3.9/2 explicitly says that the results are defined only if the buffer is copied back into an object of the same type. The two paragraphs basically make the same guarantee, the first for indirect copies, and the second for direct copies. The standard cannot guarantee more, because some legal representations of values of one type will be trapping representations in another type. – James Kanze Feb 13 '13 at 15:19

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