A templated class can capture its own this pointer in a lambda:

template <typename T>
class Foo {
    void foo(void) {}
    auto getCallableFoo(void) {
      return [this]() { this->foo(); };

This and all other Foo examples can be tested using the following code:

int main()
  Foo<int> f;
  auto callable = f.getCallableFoo();

However, if instead an init-capture is used, this no longer works with GCC:

    auto getCallableFoo(void) {
      return [ptr = this]() { ptr->foo(); };

Error message (from GCC 5.1):

error: ‘Foo<T>::getCallableFoo()::<lambda()>::__ptr’ has incomplete type

Clang 3.7 appears to compile and run this code without error. (I'm actually using a version compiled from source from before 3.7 was released, but I don't expect this has broken since then.)

Init-capture is supposed to behave like assignment to auto, but the following code appears to work without error in GCC:

// New method in Foo:
auto getPtr(void) {
  return this;

// Usage:
auto ptr = f.getPtr();

So why isn't the ptr value able to capture this in GCC? Is this a bug?

One other consideration is that, according to CppReference, this is treated as a separate syntactical case from every other capture-list type. So that may be one hint toward why GCC treats these cases differently. But it is not clear to me what (if any) special handling is done for this special case, or why it's a special case at all.

EDIT: It appears that this does work:

return [ptr = static_cast<decltype(this)>(this)]() { ptr->foo(); };

This makes no sense to me, because decltype (unlike auto) infers exactly the type of its argument, so the static_cast shouldn't actually be affecting anything.

EDITS 2,3,4: Here's a complete list of expressions that I've tried with both compilers, with comments indicating which compiler(s) accept each expression:

[this]() { this->foo(); };        // Both: work
[ptr = this]() { ptr->foo(); };   // GCC fails
[ptr = static_cast<decltype(this)>(this)]() { ptr->foo(); };   // Both: works (!!!)
[ptr(this)]() { ptr->foo(); };   // GCC fails
[ptr{this}]() { ptr->foo(); };   // GCC works (!!!!!!!!), Clang doesn't work (infers initializer list)
[ptr = {this}]() { ptr->foo(); };   // Both: fail (infers initializer list)
[ptr = &*this]() { ptr->foo(); };  // Both: work
[ptr = &*(this)]() { ptr->foo(); };  // Both: work

For [ptr{this}], my version of Clang (a pre-release 3.7) warns that the interpretation will change; currently it infers an initializer list, but presumably later versions will (or already do) infer the type of this in accordance with the new auto rules from N3922.

It shocks me that GCC permits [ptr{this}] but not [ptr(this)]. I have no explanation for this.

  • Interesting. Note that changing it to [ptr = static_cast<const Foo<T>* const>(this)] works for me under GCC 4.9.3 (once foo and getCallableFoo are declared as const, as they should be). – Yuushi Jan 20 '16 at 0:56
  • @Yuushi Hm. I'd like this to work inside of a macro, BIND_MEMBER_TO_THIS, that simply binds an arbitrary member function to the object's this pointer. I'd like to implement the macro using a more generic BIND_MEMBER_TO_OBJ_PTR macro, which would init-capture a pointer, but for now I'm working around the (apparent) bug by simply rewriting the entire lambda using [this] instead of making use of the other macro. As for foo and getCallableFoo, I'm trying to be as generic as possible here--foo() could be either const or non-const. – Kyle Strand Jan 20 '16 at 1:04
  • Note of course that the macro can't include a cast except by using decltype. Aaaaaaand....it appears that static_cast<decltype(this)>(this), as silly as it looks, does indeed work. I'll add that to the question. – Kyle Strand Jan 20 '16 at 1:06
  • 1
    Does the same bug appear if you use a simple braced-initialiser instead of =? i.e. [ptr(this)]() { ... } – paddy Jan 20 '16 at 1:08
  • 2
    Amusingly it appears that [ptr = &*this] works... – Revolver_Ocelot Jan 20 '16 at 1:18

It's a bug.

This is a bug. I've submitted a GCC bug report for this problem. It has now been fixed in GCC's trunk.


As noted by Revolver_Ocelot, &* appears to force g++ to perform the correct type-deduction. My current workaround (which is inside a macro taking some pointer expression that might be this) is therefore to capture [ptr = &*(ptr_expr)].

Why did this happen?

As noted above, GCC's Jason Merrill has fixed this in GCC's trunk. He comments that the this pointer requires special handling in lambda captures; specifically, it is treated as though it were not a dependent type. Previously, this special handling applied to [this] but not to [ptr = this].

  • 1
    If you are taking arbitrary pointers, I'd use unary + rather than &*. – T.C. Jan 21 '16 at 21:36
  • @T.C. Any particular reason why? I don't really understand what meaning unary + would typically have when applied to pointers, but &* fairly obviously means "dereference then take the address again." – Kyle Strand Jan 21 '16 at 21:52
  • 1
    Unary + does nothing. &* is UB on null pointers. – T.C. Jan 21 '16 at 21:53
  • @T.C. Ah. That makes complete sense, but if it's a null pointer, I've got UB anyway because the lambda calls a function using ptr->. – Kyle Strand Jan 21 '16 at 21:56

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