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Could you give an example where static_assert(...) 'C++0x' would solve the problem in hand elegantly?

I am familiar with run-time assert(...). When should I prefer static_assert(...) over regular assert(...)?

Also, in boost there is something called BOOST_STATIC_ASSERT, is it the same as static_assert(...)?

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SEE ALSO: BOOST_MPL_ASSERT, BOOST_MPL_ASSERT_NOT, BOOST_MPL_ASSERT_MSG, BOOST_MPL_ASSERT_RELATION [boost.org/doc/libs/1_40_0/libs/mpl/doc/refmanual/asserts.html] for more options. _MSG is especially nice once you figure out how to use it. –  KitsuneYMG Oct 30 '09 at 19:24

6 Answers 6

up vote 25 down vote accepted

Off the top of my head...

#include "SomeLibrary.h"

static_assert(SomeLibrary::Version > 2, 
         "Old versions of SomeLibrary are missing the foo functionality.  Cannot proceed!");

class UsingSomeLibrary {
   // ...
};

Assuming that SomeLibrary::Version is declared as a static const, rather than being #defined (as one would expect in a C++ library).

Contrast with having to actually compile SomeLibrary and your code, link everything, and run the executable only then to find out that you spent 30 minutes compiling an incompatible version of SomeLibrary.

@Arak, in response to your comment: yes, you can have static_assert just sitting out wherever, from the look of it:

class Foo
{
    public: 
        static const int bar = 3;
};

static_assert(Foo::bar > 4, "Foo::bar is too small :(");

int main()
{ 
    return Foo::bar;
}
$ g++ --std=c++0x a.cpp
a.cpp:7: error: static assertion failed: "Foo::bar is too small :("
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I am little confused, can you put static_assert in a non-execution context? It seems a very nice example :) –  AraK Oct 30 '09 at 3:53
1  
Yeah, static asserts as they stand are usually implemented as creating an object that's only defined if the predicate is true. This would just make a global. –  GManNickG Oct 30 '09 at 3:58
    
i'm not sure this qualifies as answering the original question in it's entirety, but nice demonstration –  Matt Joiner Oct 30 '09 at 7:10
    
This answer doesn't provide any details on what's the difference between assert from <cassert> and static_assert –  dZkF9RWJT6wN8ux Jan 16 '13 at 15:23
2  
@monocoder: See the paragraph starting with "Contrast with...". In short: assert checks its condition at runtime, and static_assert checks its condition at compilation. So if the condition you're asserting is known at compile time, use static_assert. If the condition won't be known until the program runs, use assert. –  Mike DeSimone May 3 '13 at 4:50

Static assert is used to make assertions at compile time. When the static assertion fails, the program simply doesn't compile. This is useful in different situations, like, for example, if you implement some functionality by code that critically depends on unsigned int object having exactly 32 bits. You can put a static assert like this

static_assert(sizeof(unsigned int) * CHAR_BIT == 32);

in your code. On another platform, with differently sized unsigned int type the compilation will fail, thus drawing attention of the developer to the problematic portion of the code and advising them to re-implement or re-inspect it.

For another example, you might want to pass some integral value as a void * pointer to a function (a hack, but useful at times) and you want to make sure that the integral value will fit into the pointer

int i;

static_assert(sizeof(void *) >= sizeof i);
foo((void *) i);

You might want to asset that char type is signed

static_assert(CHAR_MIN < 0);

or that integral division with negative values rounds towards zero

static_assert(-5 / 2 == -2);

And so on.

Run-time assertions in many cases can be used instead of static assertions, but run-time assertions only work at run-time and only when control passes over the assertion. For this reason a failing run-time assertion may lay dormant, undetected for extended periods of time.

Of course, the expression in static assertion has to be a compile-time constant. It can't be a run-time value. For run-time values you have no other choice but use the ordinary assert.

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This is a nice answer for sure, I hope you know that you got my +1 :) –  AraK Oct 30 '09 at 15:35
1  
Isn't static_assert REQUIRED to have a string literal as a second parameter? –  Trevor Hickey Dec 19 '13 at 16:56
    
@Trevor Hickey: Yes, it is. But I wasn't trying to refer to static_assert from C++11 specifically. My static_assert above is just some abstract implementation of static assertion. (I personally use something like that in C code). My answer is intended to be about general purpose of static assertions and their difference from run-time assertions. –  AndreyT Dec 20 '13 at 1:40

I use it to ensure my assumptions about compiler behaviour, headers, libs and even my own code are correct. For example here I verify that the struct has been correctly packed to the expected size.

struct LogicalBlockAddress
{
#pragma pack(push, 1)
    Uint32 logicalBlockNumber;
    Uint16 partitionReferenceNumber;
#pragma pack(pop)
};
BOOST_STATIC_ASSERT(sizeof(LogicalBlockAddress) == 6);

In a class wrapping stdio.h's fseek(), I have taken some shortcuts with enum Origin and check that those shortcuts align with the constants defined by stdio.h

uint64_t BasicFile::seek(int64_t offset, enum Origin origin)
{
    BOOST_STATIC_ASSERT(SEEK_SET == Origin::SET);

You should prefer static_assert over assert when the behaviour is defined at compile time, and not at runtime, such as the examples I've given above. An example where this is not the case would include parameter and return code checking.

BOOST_STATIC_ASSERT is a pre-C++0x macro that generates illegal code if the condition is not satisfied. The intentions are the same, albeit static_assert is standardised and may provide better compiler diagnostics.

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BOOST_STATIC_ASSERT is a cross platform wrapper for static_assert functionality.

Currently I am using static_assert in order to enforce "Concepts" on a class.

example:

template <typename T, typename U>
struct Type
{
  BOOST_STATIC_ASSERT(boost::is_base_of<T, Interface>::value);
  BOOST_STATIC_ASSERT(std::numeric_limits<U>::is_integer);
  /* ... more code ... */
};

This will cause a compile time error if any of the above conditions are not met.

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Now that C++11 is out (and has been out for a while), static_assert should be supported by the more recent versions of all the major compilers. For those of us who can't wait for C++14 (which hopefully will contain template constraints), this is a very useful application of static_assert. –  Collin Jun 14 '13 at 21:42

One use of static_assert might be to ensure that a structure (that is an interface with the outside world, such as a network or file) is exactly the size that you expect. This would catch cases where somebody adds or modifies a member from the structure without realising the consequences. The static_assert would pick it up and alert the user.

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This doesn't directly answers the original question, but makes an interesting study into how to enforce these compile time checks prior to C++11.

Chapter 2 (Section 2.1) of Modern C++ Design by Andrei Alexanderscu implements this idea of Compile-time assertions like this

template<int> struct CompileTimeError;
template<> struct CompileTimeError<true> {};

#define STATIC_CHECK(expr, msg) \
{ CompileTimeError<((expr) != 0)> ERROR_##msg; (void)ERROR_##msg; } 

Compare the macro STATIC_CHECK() and static_assert()

STATIC_CHECK(0, COMPILATION_FAILED);
static_assert(0, "compilation failed");
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