The rules for iterator invalidation are specific to a container.
Now invalidation may have 2 meanings with a vector:
- Invalidation = point outside of the range defined by [begin,end]
- Invalidation = point to a different object from the original one
As you can see, the second is much more strict:
std::vector<int>::iterator it = myVector.begin(); // it points to 0
myVector.erase(it); // it points to 1
myVector.erase(it); // it == myVector.end()
In this case, it is 'valid' in that it is always in the inclusive range [begin,end] and so can be safely used for any operation on myVector. On the other hand the expression (*it) keeps changing: first it returns 0, then 1, then it has undefined behavior...
In general, people will rather speak about the 2nd requirement, and invalidating an iterator simply means that (*it) may not produce the same result as before.
Now that this is said, there are several ways to invalidate an iterator on a Vector (in fact, it's the less stable structure of the STL).
During additions of elements:
- This may trigger a reallocation (1) if myVector.size() == myVector.capacity(), since checking this is error-prone, we usually consider that any addition will invalidate the iterators
- If you want to be 'picky' and knows that the reallocation is not triggered, then you still have to worry about
insert. Inserting an element invalidates the iterators pointing to this current position and all subsequent ones since the elements are shifted one step towards the end of the vector.
During removal of elements:
- There is no reallocation, even if the buffer is now much bigger than needed. It is possible to force this though, using the shrink to fit idiom (2).
- All iterators pointing past the element removed are invalidated. Especially, the previous 'end' iterator is now beyond the [begin,end] range and cannot be used safely within STL algorithms for example.
(1) The internal structure of a std::vector is an array of T, this is due for compatibility with the C-programs (using &myVector.front() as the address of the array) and because it guarantees contiguity and a minimum space overhead (ie, the amount of space taken by the vector own data vs the amount of space occupied by an object)
At any moment, you can know how many objects a vector can hold using .capacity() method.
When you want to insert an object and the vector does not have the necessary capacity, a call to the .reserve(size_t) method is triggered. This method, if the number of items required is superior to the current capacity, triggers a reallocation.
The vector then allocates a new array of elements (its size is generally 2*n+1 where n is the current capacity), copies the elements of the current array to the new array, discards the current array.
Because it discards the current array, your iterators are invalidated as vector iterators are generally simple pointers (for efficiency).
Note that if the iterators were implemented as: a reference to the vector + a count, and dereferencing was actually *(&m_vector.front() + n) reallocation would not invalidate them... but they would be less efficient.
(2) Shrink to fit: Warning, this triggers a COPY of the elements and invalidates iterators.
// myVector has 10 elements, but myVector.capacity() == 1000
It first creates a temporary vector, which will allocate only as much memory as is needed (with a minimum depending on the library), and copy the elements of myVector. Then the swap operation exchange the buffers from myVector and this copy, and thus myVector now hols a buffer with the minimum amount of memory necessary. At the end of the operation the temporary is destroyed and the memory it holds released.