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I created a macro that conveniently builds lambda functions using which I can iterate through tensor objects in a library that I wrote. However, nesting these macros seemed to cause GCC to undergo an internal segmentation fault. Upon expanding the compiler's preprocessor output and going through some trial and error, I discovered that cause seems to be the use of decltype in the parameter list of a nested lambda function declared in the method of a class or struct. Below follows a minimal example using the standard library.

#include <iostream>
#include <type_traits>

template <class Iterator, class Func>
void for_each(const Iterator first, const Iterator last, Func func)
        for (Iterator it = first; it != last; ++it) {

template <class T>
class helper
        typedef typename T::size_type type;

template <class T>
class helper<T&>
        typedef typename T::size_type type;

template <class T>
class helper<T*>
        typedef typename T::size_type type;

struct bar
        struct foo
                typedef int size_type;
        } foo_;

        void test()
                int arr[] = { 1, 2, 3 };
                for_each(arr, arr + 3, [&](int i) {
                        ** XXX: The "typename ... type" segfaults g++!
                        for_each(arr, arr + 3, [&](typename helper<decltype(foo_)>::type j) {


int main()
        return 0;

Compiler Output:

$ g++ -Wall -std=c++0x nested_lambda.cpp
nested_lambda.cpp: In lambda function:
nested_lambda.cpp:42:56: internal compiler error: Segmentation fault
Please submit a full bug report,
with preprocessed source if appropriate.
See <file:///usr/share/doc/gcc-4.6/README.Bugs> for instructions.
Preprocessed source stored into /tmp/ccqYohFA.out file, please attach this to your bugreport.

I initially opted to use decltype because an object is passed to a macro, and I need to extract the object's type. From the object's type, (T, T&, or T*), I'd use a traits class to pull T::size_type. size_type would then be the type of the lambda function parameters.

How can I circumvent this issue without having to use a typedef to declare the type of the lambda function parameter in advance? If you can think of some other solution that could easily be implemented in a macro (i.e. copied and pasted repeatedly in the parameter list of a lambda function), that would work too.

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Have you, in fact, filed a full bug report as the compiler output requests? Often one benefit of filing a bug report is that the compiler engineers who read it will make a suggestion on how to work around the problem. It's difficult to know how to avoid it without knowing the compiler internals. – Brooks Moses Jan 27 '12 at 6:47
Why do you need typename at all here ? helper<decltype(foo_)>::type has no dependent types since you're not in a template. – J.N. Feb 22 '12 at 14:34
My bad, it is indeed unnecessary; I typed the keyword by habit. – void-pointer Mar 3 '12 at 12:27

As a very rough workaround for those who may be experiencing similar issues, the best standard solution I could come up with involved having the macro declare a typedef in advance, concatenating GUID-like prefix (I personally recommend _qki_zbeu26_w92b27bqy_r62zf91j2n_s0a02_) and __LINE__ to generate some warbled nonsense for the typedef name. With all luck, this name will not clash with any other definitions.

To ensure that the same __LINE__ gets concatenated even when the warbled name is used for the lambda function parameter types, the warbled name will need to be generated by a macro that is initially passed a macro parameter, as in the code sample below.

#define _foo_GUID \

#define _foo_MANGLE_IMPL2(a, b) \
    a ## b

#define _foo_MANGLE_IMPL(a, b) \
    _foo_MANGLE_IMPL2(a, b)

#define _foo_MANGLE(a) \
    _foo_MANGLE_IMPL(_foo_GUID, a)

When passing _foo_MANGLE(__LINE__) as a macro parameter, please ensure that there is an extra level of indirection so that _foo_MANGLE(__LINE__) gets evaluated before it is used.

share|improve this answer
Names beginning with two underscores (or a single underscore followed by a capital letter) are illegal for use in user code, as they're reserved for the implementation. – ildjarn Jan 27 '12 at 16:07
Thanks, I updated my answer so that the macro is standard-conforming. – void-pointer Jan 27 '12 at 21:56
Hm? There are still __GUID, __MANGLE_IMPL2, __MANGLE_IMPL, and __MANGLE -- all of these are illegal. Also (I didn't mention earlier) any name beginning with an underscore in global scope is reserved as well, so _qki_zbeu26_w92b27bqy_r62zf91j2n__s0a02__ is still a problem. – ildjarn Jan 27 '12 at 21:57
Fair enough, as long as it's not used to declare real symbols in global scope, since they'll begin with _q. (Also, again, names beginning with a single underscore followed by a capital letter are reserved regardless of scope, so _GUID etc. are still no-go.) – ildjarn Jan 27 '12 at 22:04
@void-pointer: see in the C++11 standard – Chris Dodd Apr 1 '12 at 19:54
up vote 0 down vote accepted

This bug is currently being addressed, and I think that it should be fixed soon.

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