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I came accross a strange segfault. The cause actually led me to a bug, but I still don't understand why a segmentation fault is caused here... The code is:

#include <memory>
int main(int argc, char **arv)
{
    int *i = new int;
    std::unique_ptr<int> u1(i);
    std::unique_ptr<int> u2;
    u1 = std::move(u2); // line 7
    std::shared_ptr<int> s1(i); // line 8
    std::shared_ptr<int> s2;
    s2 = s1;
}

I compile with g++ 4.6 and -std=c++0x and get a segfault.

If I change line 7 to u2 = std::move(u1); (that was the bug) it disappears. If I change line 8 to std::shared_ptr<int> s1(new int(3)); (which of course I don't want) it also disappears. If I remove from line 8 on also no segfault.

So no harm done, but I don't understand why there should be a segfault. As far as I understand,
in line 7 an empty pointer is assigned to u1. No reset(), no end of scope. Nevertheless i seems to be invalid from there on. Is that intented? That means one has to be very very careful when moving a pointer because another object could be destroyed!

What do you think? How do I protect myself from this?

Thanks, Steffen

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2 Answers 2

up vote 9 down vote accepted

Your line 8 is wrong: Once you capture i in the unique_ptr, you must not again give it to some other ownership-taking object! Every owner will attempt to delete *i, which is wrong.

Instead, you should create the shared pointer from the unique pointer:

std::shared_ptr<int> s1(std::move(u2));

(Also, you have u1 and u2 the wrong way round.)

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what bothers me is that I can do it with not even a warning when compiling with -pedantic -Wall -Wextra. Is the answer really just "Don't!"? –  steffen May 10 '12 at 13:24
2  
@steffen: Indeed, the answer is "Don't". There's no protection against int * p = new int; do_crazy_stuff(p); be_insane(p); take_ownership(p);. The compiler can't really know what you're going to do with the pointer. –  Kerrek SB May 10 '12 at 13:34
    
True... thanks for the de-delusion :) –  steffen May 10 '12 at 16:48

This line:

u1 = std::move(u2);

Makes the previous pointer stored by u1 to be deleted. Therefore, your i pointer gets freed. Creating a shared_ptr holding the free'd pointer is undefined behaviour.

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yeah. I figured that. See my comment to Kerrek: no warning whatsoever. The compiler let's my hurt myself here! –  steffen May 10 '12 at 13:26
    
There's nothing wrong with assigning the unique pointers either way. A default-constructed unique pointer is null, and assignment properly disposes of the old resource. The line u1 = std::move(u2); deletes *i, and then both u1 and u2 are null. –  Kerrek SB May 10 '12 at 13:35
    
@KerrekSB I never said there was something wrong with assigning a unique_ptr. The way OP is doing it, the pointer held by u1 is free'd after move-assigning u2. The problem is that he creates a shared_ptr to the(already free'd) pointer. Steffen, the compiler has no ability to know what does shared/unique_ptr do what the pointers they store. –  mfontanini May 10 '12 at 13:53
    
yeah I guess I overestimated to power of the compiler ;) thanks for putting me on the ground. –  steffen May 10 '12 at 16:46

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