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I recently finished fixing a bug in the following function, and the answer surprised me. I have the following function (written as it was before I found the bug):

    void Level::getItemsAt(vector<item::Item>& vect, const Point& pt)
    {
        vector<itemPtr>::iterator it; // itemPtr is a typedef for a std::tr1::shared_ptr<item::Item>
        for(it=items.begin(); it!=items.end(); ++it)
        {
            if((*it)->getPosition() == pt)
            {
                item::Item item(**it);
                items.erase(it);
                vect.push_back(item);
            }
        }
    }

This function finds all Item objects in the 'items' vector that has a certain position, removes them from 'items', and puts them in 'vect'. Later, a function named putItemsAt does the opposite, and adds items to 'items'. The first time through, getItemsAt works fine. After putItemsAt is called, though, the for loop in getItemsAt will run off the end of 'items'. 'it' will point at an invalid Item pointer, and getPosition() segfaults. On a hunch, I changed it!=items.end() to it<items.end(), and it worked. Can anyone tell me why? Looking around SO suggests it might involve erase invalidating the iterator, but it still doesn't make sense why it would work the first time through.

I'm also curious because I plan to change 'items' from a vector to a list, since list's erase is more efficient. I know I'd have to use != for a list, as it doesn't have a < operator. Would I run into the same problem using a list?

share|improve this question
up vote 10 down vote accepted

When you call erase(), that iterator becomes invalidated. Since that is your loop iterator, calling the '++' operator on it after invalidating it is undefined behavor. erase() returns a new valid iterator that points to the next item in the vector. You need to use that new iterator from that point onwards in your loop, ie:

void Level::getItemsAt(vector<item::Item>& vect, const Point& pt) 
{ 
    vector<itemPtr>::iterator it = items.begin();
    while( it != items.end() )
    {
        if( (*it)->getPosition() == pt )
        {
            item::Item item(**it);
            it = items.erase(it);
            vect.push_back(item);
        }
        else
            ++it;
    } 
} 
share|improve this answer
    
-1: The code you posted does nothing but replace the for loop with the while loop. It's still invalid. – Billy ONeal Jun 30 '10 at 20:22
    
@Billy: Not quite. He's corrected the erase statement. The statement "it = items.erase(it)" assigns a new, valid value to it. – Peter Ruderman Jun 30 '10 at 20:25
1  
@Peter: vect.push_back doesn't invalidate it because vect is a different vector than items. – Ken Bloom Jun 30 '10 at 20:31
    
@Ken: I misread the question. I've already corrected my comment. – Peter Ruderman Jun 30 '10 at 20:32
1  
@Max: Keep in mind that Billy's solution is not equivalent. remove_copy_if with a back_inserter and his ItemIsAtPoint predicate will push back item::Item objects onto vect if getPosition() == pt. However, the items that are copied into vect are not erased from items. – Daniel Trebbien Jun 30 '10 at 21:03

You're invoking undefined behavior. All the iterators to a vector are invalidated by the fact that you called erase on that vector. It's perfectly valid for an implementation to do whatever it wants.

When you call items.erase(it);, it is now invalid. To conform to the standard, you must now assume that it is dead.

You invoke undefined behavior by using that invalid iterator in the next call to vect.push_back.

You invoke undefined behavior again by using it as the tracking variable of your for loop.

You can make your code valid by using std::remove_copy_if.

class ItemIsAtPoint : std::unary_function<bool, item::Item>
{
    Point pt;
public:
    ItemIsAtPoint(const Point& inPt) : pt(inPt) {}
    bool operator()(const item::Item* input)
    {
        return input->GetPosition() == pt;
    }
};

void Level::getItemsAt(vector<item::Item>& vect, const Point& pt)
{
    std::size_t oldSize = items.size();
    std::remove_copy_if(items.begin(), items.end(), std::back_inserter(vect), 
        ItemIsAtPoint(pt));
    items.resize(vect.size() - (items.size() - oldSize));
}

You can make this a lot prettier if you are using boost::bind, but this works.

share|improve this answer
1  
When debugging, you should use your STL implementation's debug mode (both STLPort and GNU libstdc++ have a debug mode) which will put debug code in the iterators to raise big red flags (probably throw an exception) whenever you try to invalidly use an iterator that's been invalidated. – Ken Bloom Jun 30 '10 at 20:16
    
I guess I'm not making a connection here, but I need the function to remove elements from the vector. How does modifying an element in place help me do that? @Ken Bloom: I'm compiling with g++ and using its '-g' debug flag. Which others should I use? – Max Jun 30 '10 at 20:23
    
@Max: The code you posted does not remove elements from the vector. If you want to remove those, you should be using std::remove_if or std::remove_copy_if instead of handwritten loops. – Billy ONeal Jun 30 '10 at 20:25
    
@Billy: I meant he could make his code asymptotically faster than the code that he had already. When I look at your code, I notice that it's not doing quite the same thing that Max's code is doing. I don't have a his code for putItemsAt, but I think his version will end up with all of the modified items at the end of the list, and yours will end up with a modification in place. – Ken Bloom Jun 30 '10 at 20:27
1  
I don't know about passing the result of remove_copy_if to erase. The result of the remove_copy_if is an OutputIterator -- a back_inserter -- whereas the vector erase requires a vector iterator. – Daniel Trebbien Jun 30 '10 at 21:13

I'll go with Remy Lebeau's explanation about iterator invalidation, and just add that you can make your code valid and asymptotically faster (linear time, instead of quadratic time) by using a std::list instead of a std::vector. (std::list deletions only invalidate the iterator that was deleted, and insertions don't invalidate any iterators.)

You can also predictibly identify iterator invalidation while debugging by activating your STL implementation's debug mode. On GCC, you do with with the compiler flag -D_GLIBCXX_DEBUG (see some caveats there).

share|improve this answer
    
+1 for telling me about those flags. – Max Jul 1 '10 at 18:51

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