I'm trying to initialize an iterator to NULL, but it's not working. Can anyone help me?
If a pointer can be initialized with null, why can't we do that for an iterator?
vector<int> bob;
vector<int>::iterator it=NULL;
I want to initialize an iterator in a class constructor so that at the time of creation of an object of the class, the iterator should be set to NULL (default).
No, in general you cannot initialize an iterator with NULL. The iterator requirements do not require an iterator to be assignable or initializable from either an integer type or std::nullptr_t, the possible types that NULL can have.
There is no point in trying to do that. It is simply not needed. But since you have not explained why you would try to do that, I can't really make any further suggestions.
Regarding your further questions in the comments: You can value-initialize every forward iterator:
vector<int>::iterator it{}; // value-initialized
Since C++14 you are guaranteed that comparing iterators of the same type constructed in this way compare equal.
All container iterators are forward iterators.
The best equivalent to NULL or null_ptr for an iterator is the container::end() value. It likewise does not point to a valid element of the container. So, instead of testing the predicate (i == null_ptr), test (i == v.end()), and initialize as auto i = v.end();.
You can't initialize the iterator until after you have a container. But that is not a problem in practice because an iterator makes no sense without a container it refers to.
If you have complicated code that uses iterators, and you want to isolate that code in a function, you will have to pass two iterators to the function: the current or beginning iterator, and the end iterator. This is what the STL does.
An iterator is initialized when created.
You can null check its _Ptr member:
vector<int>::iterator p;
if (p._Ptr == NULL) ...
(using clang & dinkumware)
Related
Suppose I have a std::list myList and an iterator myIt that I am using to point to some element of the list.
Now I make a shallow copy copiedList of myList (so I can reorder it). Similarly I can make a copy copiedIt of myIt, however it still references myList instead of copiedList, meaning I cannot sensibly compare it against copiedList.end(), as I may have modified that list.
Is there a (standard) way to reseat copiedIt to reference copiedList instead? This should be semantically valid, as long as I have not made any changes to the copy.
My current solution is to use the original iterator to std::find the pointed-to element in the copy of the list, but while that works and causes no problems, it seems unelegant.
You can use std::next and std::distance, like this:
template <class Container>
typename Container::iterator reseat(typename Container::iterator it, const Container &source, Container &target)
{
return std::next(target.begin(), std::distance(source.begin(), it));
}
In prose: find the distance of it from the beginning of its container, and take an iterator to the same-distant element in the new container.
This could easily be generalised to allow source and target to be of different types. With slightly more work, generalisation to constant iterators is also possible.
How do you copy the list? If you'd iterate the first list and kept inserting the items individually, you'd get the iterator at each step: http://www.cplusplus.com/reference/list/list/insert/
This is because list::insert returns an iterator that points to the first of the newly inserted elements.
I have a doubt regarding the generic algorithm copy in C++.
To copy from destination container ret and source container bottom,
copy(bottom.begin(), bottom.end(), back_inserter(ret));
works but
copy(bottom.begin(), bottom.end(), ret.end());
does not. Do these two statements have different implications?
Check what the statements do – there is no magic involved. In particular, copy is (essentially) just a loop. Simplified:
template <typename I>
void copy(I begin, I end, I target) {
while (begin != end)
*target++ = *begin++;
}
And back_inserter really does what the name says.
So in effect, without theback_inserter you do not expand the target container, you just write past its end: iterators don’t change their underlying container. The back_inserter function, on the other hand, creates a specialised iterator which does hold a reference to its original container and calls push_back when you dereference and assign to it.
In the first one you are giving copy a method of inserting, and from what container to insert from.
In the second one you are only giving a pointer to the end of the container.
Both return iterators, but...
ret.end() returns an iterator pointing to the end of the
container. It can be decremented, but not incremented (since it
already points to the end of the sequence), and it cannot be
dereferenced unless it is decremented (again, because it points
to one past the end of the sequence).
back_inserter(ret) is a function which returns
a back_insertion_iterator, which is a very special type of
"iterator" (category OutputIterator): it's incrementation
functions are no-ops, dereferencing it returns *this, and
assigning a value type to it calls push_back on the owning
container. (In other words, it's not an iterator at all, except
for the C++ standard; but it presents the interface of one to do
something very different.)
the issue is I want to initialize a multiset iterator to some value, to be able to check later if there was some successful assignment to my iterator or not. Now without this initialization in some cycle of my program I get there some trash and all crashes.
In pseudocode I'd think about it like that:
multiset<whateverclassA,whateverclassB>::const_iterator init_me = NULL;
...//if succesfull, something is assigned to init_me iterator
if (init_me != NULL)
//do something
however it is not a usual pointer, so simple NULL doesn't suffice probably.
Any help appreciated!
Use std::multiset::end. This is also the value that will be returned by algorithms like std::multiset::find if the value could not be found:
multiset<whateverclassA,whateverclassB>::const_iterator
init_me = your_multiset.end();
/* ... */
if (init_me != your_multiset.end())
//do something
The variable init_me is an object instance, and NULL is a pointer. A non-pointer instance can not be compared to a pointer.
What you should to is set init_me to another iterator that means "no iterator", like end, and compare against that.
If the multiset in question always exists and is determined at the time you declare init_me (i.e. there is only one possible multiset that the iterator can point into), you could use mymultiset.end() as a marker.
(Note that this iterator does not point to the last element of a container, but to the "end", i.e. it is a special value. That's what makes it useful for flagging purposes. Be careful to only check other iterators against mymultiset.end(), not dereference it. Dereferencing end() or past-the-end iterators is undefined behaviour.)
I have a collection of elements in a std::vector that are sorted in a descending order starting from the first element. I have to use a vector because I need to have the elements in a contiguous chunk of memory. And I have a collection holding many instances of vectors with the described characteristics (always sorted in a descending order).
Now, sometimes, when I find out that I have too many elements in the greater collection (the one that holds these vectors), I discard the smallest elements from these vectors some way similar to this pseudo-code:
grand_collection: collection that holds these vectors
T: type argument of my vector
C: the type that is a member of T, that participates in the < comparison (this is what sorts data before they hit any of the vectors).
std::map<C, std::pair<T::const_reverse_iterator, std::vector<T>&>> what_to_delete;
iterate(it = grand_collection.begin() -> grand_collection.end())
{
iterate(vect_rit = it->rbegin() -> it->rend())
{
// ...
what_to_delete <- (vect_rit->C, pair(vect_rit, *it))
if (what_to_delete.size() > threshold)
what_to_delete.erase(what_to_delete.begin());
// ...
}
}
Now, after running this code, in what_to_delete I have a collection of iterators pointing to the original vectors that I want to remove from these vectors (overall smallest values). Remember, the original vectors are sorted before they hit this code, which means that for any what_to_delete[0 - n] there is no way that an iterator on position n - m would point to an element further from the beginning of the same vector than n, where m > 0.
When erasing elements from the original vectors, I have to convert a reverse_iterator to iterator. To do this, I rely on C++11's §24.4.1/1:
The relationship between reverse_iterator and iterator is
&*(reverse_iterator(i)) == &*(i- 1)
Which means that to delete a vect_rit, I use:
vector.erase(--vect_rit.base());
Now, according to C++11 standard §23.3.6.5/3:
iterator erase(const_iterator position); Effects: Invalidates
iterators and references at or after the point of the erase.
How does this work with reverse_iterators? Are reverse_iterators internally implemented with a reference to a vector's real beginning (vector[0]) and transforming that vect_rit to a classic iterator so then erasing would be safe? Or does reverse_iterator use rbegin() (which is vector[vector.size()]) as a reference point and deleting anything that is further from vector's 0-index would still invalidate my reverse iterator?
Edit:
Looks like reverse_iterator uses rbegin() as its reference point. Erasing elements the way I described was giving me errors about a non-deferenceable iterator after the first element was deleted. Whereas when storing classic iterators (converting to const_iterator) while inserting to what_to_delete worked correctly.
Now, for future reference, does The Standard specify what should be treated as a reference point in case of a random-access reverse_iterator? Or this is an implementation detail?
Thanks!
In the question you have already quoted exactly what the standard says a reverse_iterator is:
The relationship between reverse_iterator and iterator is &*(reverse_iterator(i)) == &*(i- 1)
Remember that a reverse_iterator is just an 'adaptor' on top of the underlying iterator (reverse_iterator::current). The 'reference point', as you put it, for a reverse_iterator is that wrapped iterator, current. All operations on the reverse_iterator really occur on that underlying iterator. You can obtain that iterator using the reverse_iterator::base() function.
If you erase --vect_rit.base(), you are in effect erasing --current, so current will be invalidated.
As a side note, the expression --vect_rit.base() might not always compile. If the iterator is actually just a raw pointer (as might be the case for a vector), then vect_rit.base() returns an rvalue (a prvalue in C++11 terms), so the pre-decrement operator won't work on it since that operator needs a modifiable lvalue. See "Item 28: Understand how to use a reverse_iterator's base iterator" in "Effective STL" by Scott Meyers. (an early version of the item can be found online in "Guideline 3" of http://www.drdobbs.com/three-guidelines-for-effective-iterator/184401406).
You can use the even uglier expression, (++vect_rit).base(), to avoid that problem. Or since you're dealing with a vector and random access iterators: vect_rit.base() - 1
Either way, vect_rit is invalidated by the erase because vect_rit.current is invalidated.
However, remember that vector::erase() returns a valid iterator to the new location of the element that followed the one that was just erased. You can use that to 're-synchronize' vect_rit:
vect_rit = vector_type::reverse_iterator( vector.erase(vect_rit.base() - 1));
From a standardese point of view (and I'll admit, I'm not an expert on the standard): From §24.5.1.1:
namespace std {
template <class Iterator>
class reverse_iterator ...
{
...
Iterator base() const; // explicit
...
protected:
Iterator current;
...
};
}
And from §24.5.1.3.3:
Iterator base() const; // explicit
Returns: current.
Thus it seems to me that so long as you don't erase anything in the vector before what one of your reverse_iterators points to, said reverse_iterator should remain valid.
Of course, given your description, there is one catch: if you have two contiguous elements in your vector that you end up wanting to delete, the fact that you vector.erase(--vector_rit.base()) means that you've invalidated the reverse_iterator "pointing" to the immediately preceeding element, and so your next vector.erase(...) is undefined behavior.
Just in case that's clear as mud, let me say that differently:
std::vector<T> v=...;
...
// it_1 and it_2 are contiguous
std::vector<T>::reverse_iterator it_1=v.rend();
std::vector<T>::reverse_iterator it_2=it_1;
--it_2;
// Erase everything after it_1's pointee:
// convert from reverse_iterator to iterator
std::vector<T>::iterator tmp_it=it_1.base();
// but that points one too far in, so decrement;
--tmp_it;
// of course, now tmp_it points at it_2's base:
assert(tmp_it == it_2.base());
// perform erasure
v.erase(tmp_it); // invalidates all iterators pointing at or past *tmp_it
// (like, say it_2.base()...)
// now delete it_2's pointee:
std::vector<T>::iterator tmp_it_2=it_2.base(); // note, invalid iterator!
// undefined behavior:
--tmp_it_2;
v.erase(tmp_it_2);
In practice, I suspect that you'll run into two possible implementations: more commonly, the underlying iterator will be little more than a (suitably wrapped) raw pointer, and so everything will work perfectly happily. Less commonly, the iterator might actually try to track invalidations/perform bounds checking (didn't Dinkumware STL do such things when compiled in debug mode at one point?), and just might yell at you.
The reverse_iterator, just like the normal iterator, points to a certain position in the vector. Implementation details are irrelevant, but if you must know, they both are (in a typical implementation) just plain old pointers inside. The difference is the direction. The reverse iterator has its + and - reversed w.r.t. the regular iterator (and also ++ and --, > and < etc).
This is interesting to know, but doesn't really imply an answer to the main question.
If you read the language carefully, it says:
Invalidates iterators and references at or after the point of the erase.
References do not have a built-in sense of direction. Hence, the language clearly refers to the container's own sense of direction. Positions after the point of the erase are those with higher indices. Hence, the iterator's direction is irrelevant here.
Is there any way to check if an iterator (whether it is from a vector, a list, a deque...) is (still) dereferenceable, i.e. has not been invalidated?
I have been using try-catch, but is there a more direct way to do this?
Example: (which doesn't work)
list<int> l;
for (i = 1; i<10; i++) {
l.push_back(i * 10);
}
itd = l.begin();
itd++;
if (something) {
l.erase(itd);
}
/* now, in other place.. check if it points to somewhere meaningful */
if (itd != l.end())
{
// blablabla
}
I assume you mean "is an iterator valid," that it hasn't been invalidated due to changes to the container (e.g., inserting/erasing to/from a vector). In that case, no, you cannot determine if an iterator is (safely) dereferencable.
As jdehaan said, if the iterator wasn't invalidated and points into a container, you can check by comparing it to container.end().
Note, however, that if the iterator is singular -- because it wasn't initialized or it became invalid after a mutating operation on the container (vector's iterators are invalidated when you increase the vector's capacity, for example) -- the only operation that you are allowed to perform on it is assignment. In other words, you can't check whether an iterator is singular or not.
std::vector<int>::iterator iter = vec.begin();
vec.resize(vec.capacity() + 1);
// iter is now singular, you may only perform assignment on it,
// there is no way in general to determine whether it is singular or not
Non-portable answer: Yes - in Visual Studio
Visual Studio's STL iterators have a "debugging" mode which do exactly this. You wouldn't want to enable this in ship builds (there is overhead) but useful in checked builds.
Read about it on VC10 here (this system can and in fact does change every release, so find the docs specific to your version).
Edit Also, I should add: debug iterators in visual studio are designed to immediately explode when you use them (instead undefined behavior); not to allow "querying" of their state.
Usually you test it by checking if it is different from the end(), like
if (it != container.end())
{
// then dereference
}
Moreover using exception handling for replacing logic is bad in terms of design and performance. Your question is very good and it is definitively worth a replacement in your code. Exception handling like the names says shall only be used for rare unexpected issues.
Is there any way to check if a iterator (whether it is from a vector, a list, a deque...) is (still) dereferencable, i.e has not been invalidated ?
No, there isn't. Instead you need to control access to the container while your iterator exists, for example:
Your thread should not modify the container (invalidating the iterator) while it is still using an instantiated iterator for that container
If there's a risk that other threads might modify the container while your thread is iterating, then in order to make this scenario thread-safe your thread must acquire some kind of lock on the container (so that it prevents other threads from modifying the container while it's using an iterator)
Work-arounds like catching an exception won't work.
This is a specific instance of the more general problem, "can I test/detect whether a pointer is valid?", the answer to which is typically "no, you can't test for it: instead you have to manage all memory allocations and deletions in order to know whether any given pointer is still valid".
Trying and catching is not safe, you will not, or at least seldom throw if your iterator is "out of bounds".
what alemjerus say, an iterator can always be dereferenced. No matter what uglyness lies beneath. It is quite possible to iterate into other areas of memory and write to other areas that might keep other objects. I have been looking at code, watching variables change for no particular reason. That is a bug that is really hard to detect.
Also it is wise to remember that inserting and removing elements might potentially invalidate all references, pointers and iterators.
My best advice would be to keep you iterators under control, and always keep an "end" iterator at hand to be able to test if you are at the "end of the line" so to speak.
In some of the STL containers, the current iterator becomes invalid when you erase the current value of the iterator. This happens because the erase operation changes the internal memory structure of the container and increment operator on existing iterator points to an undefined locations.
When you do the following, iterator is incementented before it is passed to erase function.
if (something) l.erase(itd++);
Is there any way to check if an iterator is dereferencable
Yes, with gcc debugging containers available as GNU extensions. For std::list you can use __gnu_debug::list instead. The following code will abort as soon as invalid iterator is attempted to be used. As debugging containers impose extra overhead they are intended only when debugging.
#include <debug/list>
int main() {
__gnu_debug::list<int> l;
for (int i = 1; i < 10; i++) {
l.push_back(i * 10);
}
auto itd = l.begin();
itd++;
l.erase(itd);
/* now, in other place.. check if itd points to somewhere meaningful */
if (itd != l.end()) {
// blablabla
}
}
$ ./a.out
/usr/include/c++/7/debug/safe_iterator.h:552:
Error: attempt to compare a singular iterator to a past-the-end iterator.
Objects involved in the operation:
iterator "lhs" # 0x0x7ffda4c57fc0 {
type = __gnu_debug::_Safe_iterator<std::_List_iterator<int>, std::__debug::list<int, std::allocator<int> > > (mutable iterator);
state = singular;
references sequence with type 'std::__debug::list<int, std::allocator<int> >' # 0x0x7ffda4c57ff0
}
iterator "rhs" # 0x0x7ffda4c580c0 {
type = __gnu_debug::_Safe_iterator<std::_List_iterator<int>, std::__debug::list<int, std::allocator<int> > > (mutable iterator);
state = past-the-end;
references sequence with type 'std::__debug::list<int, std::allocator<int> >' # 0x0x7ffda4c57ff0
}
Aborted (core dumped)
The type of the parameters of the erase function of any std container (as you have listed in your question, i.e. whether it is from a vector, a list, a deque...) is always iterator of this container only.
This function uses the first given iterator to exclude from the container the element that this iterator points at and even those that follow. Some containers erase only one element for one iterator, and some other containers erase all elements followed by one iterator (including the element pointed by this iterator) to the end of the container. If the erase function receives two iterators, then the two elements, pointed by each iterator, are erased from the container and all the rest between them are erased from the container as well, but the point is that every iterator that is passed to the erase function of any std container becomes invalid! Also:
Each iterator that was pointing at some element that has been erased from the container becomes invalid, but it doesn't pass the end of the container!
This means that an iterator that was pointing at some element that has been erased from the container cannot be compared to container.end().
This iterator is invalid, and so it is not dereferencable, i.e. you cannot use neither the * nor -> operators, it is also not incrementable, i.e. you cannot use the ++ operator, and it is also not decrementable, i.e. you cannot use the -- operator.
It is also not comparable!!! I.E. you cannot even use neither == nor != operators
Actually you cannot use any operator that is declared and defined in the std iterator.
You cannot do anything with this iterator, like null pointer.
Doing something with an invalid iterator immediately stops the program and even causes the program to crash and an assertion dialog window appears. There is no way to continue program no matter what options you choose, what buttons you click. You just can terminate the program and the process by clicking the Abort button.
You don't do anything else with an invalid iterator, unless you can either set it to the begin of the container, or just ignore it.
But before you decide what to do with an iterator, first you must know if this iterator is either invalid or not, if you call the erase function of the container you are using.
I have made by myself a function that checks, tests, knows and returns true whether a given iterator is either invalid or not. You can use the memcpy function to get the state of any object, item, structure, class and etc, and of course we always use the memset function at first to either clear or empty a new buffer, structure, class or any object or item:
bool IsNull(list<int>::iterator& i) //In your example, you have used list<int>, but if your container is not list, then you have to change this parameter to the type of the container you are using, if it is either a vector or deque, and also the type of the element inside the container if necessary.
{
byte buffer[sizeof(i)];
memset(buffer, 0, sizeof(i));
memcpy(buffer, &i, sizeof(i));
return *buffer == 0; //I found that the size of any iterator is 12 bytes long. I also found that if the first byte of the iterator that I copy to the buffer is zero, then the iterator is invalid. Otherwise it is valid. I like to call invalid iterators also as "null iterators".
}
I have already tested this function before I posted it there and found that this function is working for me.
I very hope that I have fully answered your question and also helped you very much!
There is a way, but is ugly... you can use the std::distance function
#include <algorithms>
using namespace std
auto distance_to_iter = distance(container.begin(), your_iter);
auto distance_to_end = distance(container.begin(),container.end());
bool is_your_iter_still_valid = distance_to_iter != distance_to_end;
use erase with increment :
if (something) l.erase(itd++);
so you can test the validity of the iterator.
if (iterator != container.end()) {
iterator is dereferencable !
}
If your iterator doesnt equal container.end(), and is not dereferencable, youre doing something wrong.