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Is there a portable and safe way to interpret the bit-pattern made by a boost::uint16_t as a boost::int16_t? I have a uint16_t, which I know represents a signed 16-bit integer encoded as little-endian. I need to do some signed arithmetic on this value, so is there anyway to convince the compiler that it already is a signed value?

If I a not mistaken, a static_cast<int16_t> would convert the value, perhaps changing its bit-pattern.

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reinterpret_cast< int16_t& >( uint16_value ); should work anywhere, even though is implementation defined. –  K-ballo Sep 18 '11 at 20:52
How did the signed value get into the uint? Normally, the way to convert it to signed is to revert that operation. –  jalf Sep 18 '11 at 21:23
@jalf The signed value comes from serialized data stored in a file. I use the unsigned type because I need to do extensive bitwise operations on 2-byte words. –  Viktor Dahl Sep 18 '11 at 21:25

6 Answers 6

If you are looking for something different than a cast, then copy its memory representation to that of a boost::int16_t since its what it represents to begin with.

Edit: If you have to make it work on a big endian machine, simply copy the bytes backwards. Use std::copy and std::reverse.

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You mean something in the manner of a memcpy? That sound like it would work. –  Viktor Dahl Sep 18 '11 at 20:49
@Viktor Dahl: Indeed, memcpy would do. Or the fancy std::copy is there as well. –  K-ballo Sep 18 '11 at 20:50
It won't work on a big endian machine. –  David Hammen Sep 18 '11 at 21:26
as I and David Hammen stated in our answers, this memcpy could go wrong if target system is big-endian. other than that there is no difference in results between copying memory or just casting it away. just when you cast there is no accual code generated to cast but when you use memcpy it consumes some time. –  Ali.S Sep 18 '11 at 21:27
@Gajet: Except that casting is undefined behavior and memcpying isn't. Also, most casts include code generation, only reinterpret_cast doesn't. –  K-ballo Sep 18 '11 at 21:30

Mask off all but the sign bit, store that in a signed int, then set the sign using the sign bit.

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Only correct answer here so far. Note that you will probably have to handle INT_MIN as a special case, since the natural way to write this will end up doing -1 * 0 == 0 for that case. –  Nemo Sep 18 '11 at 21:10
Not correct. This only works if the target machine is little endian. –  David Hammen Sep 18 '11 at 21:11
@David: You are completely wrong, and also very confused about what "big-endian" actually means. You cannot tell just by shifting and masking integers whether a system is big-endian. (Nor should you try. Unless you are serializing data for transport, you never care whether the system is big- or little- endian.) –  Nemo Sep 18 '11 at 21:13
How do you "mask off the sign bit" of an unsigned integer? It doesn't have a sign bit. And signed integers are not required to be represented in two's complement (or one's complement, or any other specific representation, making it impossible to talk about a signed integer's "sign bit" in a portable manner as well) –  jalf Sep 18 '11 at 21:15
@jalf: By "sign bit" he means "high bit". The suggestion is to mask off the high bit (but remember it), copy the resulting number to an int16_t, then multiply by -1 if the high bit was set. This does not depend on signed integers being two's complement. –  Nemo Sep 18 '11 at 21:18

I guess *(boost::int16_t*)(&signedvalue) would work, unless your system architecture is not little-endian by default. endian ness will change behavior since after above operation cpu will treat signed value as a architecture specific boost::int16_t value (meaning if your architecture is big endian it'll go wrong).

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a) what has this to do with endianness? b) this is undefined behaviour. –  Kerrek SB Sep 18 '11 at 20:55
c) this only works if sizeof(int) == sizeof(int16_t) which hasn't been true on most common architectures for years. –  Chris Lutz Sep 18 '11 at 21:02
@Kerrek: Strictly speaking this is UB. Practically speaking, it is not. That idiom is very far widespread. A compiler vendor that invoked the erase_the_hard_driver() function in response would find itself losing customers right and left. So they do just what it says to do, and they do not optimize it away. –  David Hammen Sep 18 '11 at 21:07
@Chris: I think he meant *(int16_t)(&unsigned_value). –  David Hammen Sep 18 '11 at 21:07
@Chris,@kerrek: edited my answer, david was right. it's not undefined behavior, it's just may cause unexpected results if you are not sure about target platform. –  Ali.S Sep 18 '11 at 21:13

To avoid controversy over *(int16_t)(&input_value), I changed the last statement in the code block to memcpy and added *(int16_t)(&input_value) as an addendum. (It as the other way around).

On a big endian machine you will need to do a byte swap and then interpret as a signed integer:

if (big_endian()) {
  input_value = (uint16_t)((input_value & 0xff00u) >> 8) |
                (uint16_t)((input_value & 0x00ffu) << 8);
int16_t signed_value;
std::memcpy (&signed_value, &input_value, sizeof(int16_t));

On most computers you can change the call to memcpy to signed_value = *(int16_t)(&input_value);. This is, strictly speaking, undefined behavior. It is also an extremely widely used idiom. Almost all compilers do the "right thing" with this statement. But, as is always the case with extensions to the language, YMMV.

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@Nemo: The code inside the if is the standard implementation of ntohs and htons on a little endian machine. This code most certainly does do something: It swaps the bytes. The problem is that we can't use either ntohs and htons here because the incoming value is not network order. It is little endian instead. –  David Hammen Sep 18 '11 at 21:15
@nemo that code above is changing endianness correctly, and it's needed if system is big-endian. also the cast there is not undefined behavior. since we know sizeof(int16_t) == sizeof(uint16_t)! –  Ali.S Sep 18 '11 at 21:16
@Nemo: I did note that the OP might have to use a memcpy. It is dubious that he would. Find a compiler that does not accept this idiom. It's use is far too widespread for compilers to do anything but accept it. –  David Hammen Sep 18 '11 at 21:18
@Nemo: The value is known to represent "a signed 16-bit integer encoded as little-endian". In other words, a 16 bit signed integer sent over a network connection without bothering to convert to network order and received as a 16 bit unsigned integer. Lots of people ignore network order nowadays given the preponderance of little endian machines. Byte swapping most certainly is necessary when the recipient of that value is a big endian machine. –  David Hammen Sep 18 '11 at 21:21
@David: Sorry, I missed that detail in the question. Removing my other comments. –  Nemo Sep 18 '11 at 21:22

As a different tack, the best way to maximize (but not ensure) portability is to store those signed 16 bit integers as signed 16 bit integers in network order rather than as unsigned 16 bit integers in little endian order. This puts the burden on the target machine to be able to translate those 16 bit network order signed integers to 16 bit signed integers in the native form to the target. Not every machine supports this capability, but most machines that can connect to a network do. After all, that file has to get to the target machine by some mechanism, so the odds are pretty good that it will understand network order.

On the other hand, if you are zapping that binary file to some embedded machine via some proprietary serial interface, the answer to the portability question is the same answer you'll get when you tell your doctor "it hurts when I do this."

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Just use the static cast. Changing the bit pattern happens to be exactly what you want, if you happen to be on a platform that defines them differently.

reinterpret_cast, or any equivalent pointer cast, is undefined (not implementation defined). That means the compiler is free to do nasty things like cache the undefined form in a register and miss the update. Besides, if you were on a platform where the bit patterns were different then bypassing the conversion would leave you with garbage (just like pretending a float is an int and adding 1 to it.)

More info is at Signed to unsigned conversion in C - is it always safe? but the summary C, in a roundabout way, defines the static cast (ordinary C cast actually) as exactly what you get by treating the bits the same on x86 (which uses two's complement.)

Don't play chicken with the compiler (this always worked on this compiler so surely they won't break everybody's code by changing it). History has proven you wrong.

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