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Is there a specific data structure that a deque in the C++ STL is supposed to implement, or is a deque just this vague notion of an array growable from both the front and the back, to be implemented however the implementation chooses?

I used to always assume a deque was a circular buffer, but I was recently reading a C++ reference here, and it sounds like a deque is some kind of array of arrays. It doesn't seem like it's a plain old circular buffer. Is it a gap buffer, then, or some other variant of growable array, or is it just implementation-dependent?


It seems the general consensus is that a deque is a data structure such that:

  • the time to insert or remove an element should be constant at beginning or end of the list and at most linear elsewhere. If we interpret this to mean true constant time and not amortized constant time, as someone comments, this seems challenging. Some have argued that we should not interpret this to mean non-amortized constant time.
  • "A deque requires that any insertion shall keep any reference to a member element valid. It's OK for iterators to be invalidated, but the members themselves must stay in the same place in memory." As someone comments: This is easy enough by just copying the members to somewhere on the heap and storing T* in the data structure under the hood.
  • "Inserting a single element either at the beginning or end of a deque always takes constant time and causes a single call to a constructor of T." The single constructor of T will also be achieved if the data structure stores T* under the hood.
  • The data structure must have random access.

It seems no one knows how to get a combination of the 1st and 4th conditions if we take the first condition to be "non-amortized constant time". A linked list achieves 1) but not 4), whereas a typical circular buffer achieves 4) but not 1). I think I have an implementation that fulfills both below. Comments?

We start with an implementation someone else suggested: we allocate an array and start placing elements from the middle, leaving space in both the front and back. In this implementation, we keep track of how many elements there are from the center in both the front and back directions, call those values F and B. Then, let's augment this data structure with an auxiliary array that is twice the size of the original array (so now we're wasting a ton of space, but no change in asymptotic complexity). We will also fill this auxiliary array from its middle and give it similar values F' and B'. The strategy is this: every time we add one element to the primary array in a given direction, if F > F' or B > B' (depending on the direction), up to two values are copied from the primary array to the auxiliary array until F' catches up with F (or B' with B). So an insert operation involves putting 1 element into the primary array and copying up to 2 from the primary to the auxiliary, but it's still O(1). When the primary array becomes full, we free the primary array, make the auxiliary array the primary array, and make another auxiliary array that's yet 2 times bigger. This new auxiliary array starts out with F' = B' = 0 and having nothing copied to it (so the resize op is O(1) if a heap allocation is O(1) complexity). Since the auxiliary copies 2 elements for every element added to the primary and the primary starts out at most half-full, it is impossible for the auxiliary to not have caught up with the primary by the time the primary runs out of space again. Deletions likewise just need to remove 1 element from the primary and either 0 or 1 from the auxiliary. So, assuming heap allocations are O(1), this implementation fulfills condition 1). We make the array be of T* and use new whenever inserting to fulfill conditions 2) and 3). Finally, 4) is fulfilled because we are using an array structure and can easily implement O(1) access.

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You might be interested in reading this question I asked a while ago. – Mehrdad Dec 24 '11 at 23:23
it's not a circular buffer in any sense – Lightness Races in Orbit Dec 24 '11 at 23:34
Gap buffers are inefficient for deques. – Pubby Dec 24 '11 at 23:46
@TomalakGeret'kal, there's nothing wrong with using circular buffers. They are quite a reasonable implementation in fact. In you look at the comment thread at Pubby's answer, you can see a lot of argument. It appears some people are convinced in must be a simple linked list, with non-random access. It would be good to get more people to look at this. – Aaron McDaid Dec 25 '11 at 3:51
Doh! The following sentences in N3242 are relevant, and give me pause for thought (i.e. I might have been wrong). "An insertion at either end of the deque invalidates all the iterators to the deque, but has no effect on the validity of references to elements of the deque." and "Inserting a single element either at the beginning or end of a deque always takes constant time and causes a single call to a constructor of T." – Aaron McDaid Dec 25 '11 at 4:03
up vote 3 down vote accepted

(Making this answer a community-wiki. Please get stuck in.)

First things first: A deque requires that any insertion to the front or back shall keep any reference to a member element valid. It's OK for iterators to be invalidated, but the members themselves must stay in the same place in memory. This is easy enough by just copying the members to somewhere on the heap and storing T* in the data structure under the hood. See this other StackOverflow question " About deque<T>'s extra indirection "

(vector doesn't guarantee to preserve either iterators or references, whereas list preserves both).

So let's just take this 'indirection' for granted and look at the rest of the problem. The interesting bit is the time to insert or remove from the beginning or end of the list. At first, it looks like a deque could trivially be implemented with a vector, perhaps by interpreting it as a circular buffer.

BUT A deque must satisfy "Inserting a single element either at the beginning or end of a deque always takes constant time and causes a single call to a constructor of T."

Thanks to the indirection we've already mentioned, it's easy to ensure there is just one constructor call, but the challenge is to guarantee constant time. It would be easy if we could just use constant amortized time, which would allow the simple vector implementation, but it must be constant (non-amortized) time.

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I've changed this answer quite a lot. It's a community wiki now, and I don't claim to have all the answer any more! I'm primarily focused on just clarifying the problem. – Aaron McDaid Dec 25 '11 at 4:42
The versions of the draft that required constant time push also required constant time operator[]. Even ignoring the issue of invalidating references, I think that constraint is a challenging problem. – Hurkyl Dec 25 '11 at 4:43
If operator[] (and other non-random operations) could be linear, then a standard linked-list would be the answer. I can't find the relevant sentence in the draft I'm looking at, so I don't know if operator[] is amortized or not. (I'd be surprised if it wasn't constant) – Aaron McDaid Dec 25 '11 at 4:52
@Hurkyl, this is the closest I've found in N3242 " deque is a sequence container that, like a vector (23.3.6), supports random access iterators " (my emphasis) – Aaron McDaid Dec 25 '11 at 4:54
In the versions I looked at there was a table, with the comment "An implementation shall provide these operations for all container types shown ... so as to take amortized constant time". (And the other one I read said the same thing, but without the word 'amortized') In the version I saved, this was "Table 71: Optional sequence operations" in subsubsection 23.1.1 - Sequences [lib.sequence.reqmts] in the Container Requirements subsection. – Hurkyl Dec 25 '11 at 5:03

It's implementation specific. All a deque requires is constant time insertion/deletion at the start/end, and at most linear elsewhere. Elements are not required to be contiguous.

Most implementations use an unrolled linked list.

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@BentFX Yeah, that was confusing. Reworded it. – Pubby Dec 24 '11 at 23:33
The restrictions are a lot more specific. Especially a deque is required to have random access iterators. Insertion and deletion at the begin/end don't need to be efficient, they need to be constant time and at most linear time at other positions. – pmr Dec 24 '11 at 23:57
@pmr: It is. And I consider it a bug now. The requirement of a random access iterator is incompatible with the requirement of absolute O(1) time for inserts and deletes to either end. Not even vector accomplishes this feat. Maybe some brilliant computer scientist knows how to create a data structure that can satisfy these two requirements. But I don't know of such a data structure. – Omnifarious Dec 25 '11 at 0:36
@Omnifarious: It's completely possible to have constant-time insertion/deletion at either end while keeping it random-access. Just leave extra space in the beginning as well as the end. See the question I asked a while ago (link above). We had an entire discussion about this, which the poster deleted because he thought it wasn't possible. It's completely possible -- it just wastes a bit more space (which doesn't really matter anyway). – Mehrdad Dec 25 '11 at 3:01
@Mehrdad: The standard is intended to apply to all environments. That's why so much is left unspecified or undefined. There is a distinction between absolute constant time, and amortized constant time. The standard makes this distinction in some places, most notably (AFAIK) ::std::vector explicitly specifies that push_back is amortized constant time. So if that's what they mean, that's what they should say. The point is for the language to be precise and unambiguous, not to make sense for 'most' environments. – Omnifarious Dec 25 '11 at 7:57

A deque is typically implemented as a dynamic array of arrays of T.

 (a) (b) (c) (d)
 +-+ +-+ +-+ +-+
 | | | | | | | |
 +-+ +-+ +-+ +-+
  ^   ^   ^   ^
  |   |   |   |
| 1 | 8 | 8 | 3 | (reference)

The arrays (a), (b), (c) and (d) are generally of fixed capacity, and the inner arrays (b) and (c) are necessarily full. (a) and (d) are not full, which gives O(1) insertion at both ends.

Imagining that we do a lot of push_front, (a) will fill up, when it's full and an insertion is performed we first need to allocate a new array, then grow the (reference) vector and push the pointer to the new array at the front.

This implementation trivially provides:

  • Random Access
  • Reference Preservation on push at both ends
  • Insertion in the middle that is proportional to min(distance(begin, it), distance(it, end)) (the Standard is slightly more stringent that what you required)

However it fails the requirement of amortized O(1) growth. Because the arrays have fixed capacity whenever the (reference) vector needs to grow, we have O(N/capacity) pointer copies. Because pointers are trivially copied, a single memcpy call is possible, so in practice this is mostly constant... but this is insufficient to pass with flying colors.

Still, push_front and push_back are more efficient than for a vector (unless you are using MSVC implementation which is notoriously slow because of very small capacity for the arrays...)

Honestly, I know of no data structure, or data structure combination, that could satisfy both:

  • Random Access


  • O(1) insertion at both ends

I do know a few "near" matches:

  • Amortized O(1) insertion can be done with a dynamic array in which you write in the middle, this is incompatible with the "reference preservation" semantics of the deque
  • A B+ Tree can be adapted to provide an access by index instead of by key, the times are close to constants, but the complexity is O(log N) for access and insertion (with a small constant), it requires using Fenwick Trees in the intermediate level nodes.
  • Finger Trees can be adapted similarly, once again it's really O(log N) though.
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A deque<T> could be implemented correctly by using a vector<T*>. All the elements are copied onto the heap and the pointers stored in a vector. (More on the vector later).

Why T* instead of T? Because the standard requires that

"An insertion at either end of the deque invalidates all the iterators to the deque, but has no effect on the validity of references to elements of the deque."

(my emphasis). The T* helps to satisfy that. It also helps us to satisfy this:

"Inserting a single element either at the beginning or end of a deque always ..... causes a single call to a constructor of T."

Now for the (controversial) bit. Why use a vector to store the T*? It gives us random access, which is a good start. Let's forget about the complexity of vector for a moment and build up to this carefully:

The standard talks about "the number of operations on the contained objects.". For deque::push_front this is clearly 1 because exactly one T object is constructed and zero of the existing T objects are read or scanned in any way. This number, 1, is clearly a constant and is independent of the number of objects currently in the deque. This allows us to say that:

'For our deque::push_front, the number of operations on the contained objects (the Ts) is fixed and is independent of the number of objects already in the deque.'

Of course, the number of operations on the T* will not be so well-behaved. When the vector<T*> grows too big, it'll be realloced and many T*s will be copied around. So yes, the number of operations on the T* will vary wildly, but the number of operations on T will not be affected.

Why do we care about this distinction between counting operations on T and counting operations on T*? It's because the standard says:

All of the complexity requirements in this clause are stated solely in terms of the number of operations on the contained objects.

For the deque, the contained objects are the T, not the T*, meaning we can ignore any operation which copies (or reallocs) a T*.

I haven't said much about how a vector would behave in a deque. Perhaps we would interpret it as a circular buffer (with the vector always taking up its maximum capacity(), and then realloc everything into a bigger buffer when the vector is full. The details don't matter.

In the last few paragraphs, we have analyzed deque::push_front and the relationship between the number of objects in the deque already and the number of operations performed by push_front on contained T-objects. And we found they were independent of each other. As the standard mandates that complexity is in terms of operations-on-T, then we can say this has constant complexity.

Yes, the Operations-On-T*-Complexity is amortized (due to the vector), but we're only interested in the Operations-On-T-Complexity and this is constant (non-amortized).

Epilogue: the complexity of vector::push_back or vector::push_front is irrelevant in this implementation; those considerations involve operations on T* and hence is irrelevant.

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I disagree. The complexity of push_front is relevant, because the Standard precises the complexity in terms of N where N represents the number of elements in the sequence. Adding your level of indirection does not solve the issue that N pointers need be copied when doing a push_front... – Matthieu M. Dec 27 '11 at 16:50
@MatthieuM., in my answer, you'll see a sentence from the C++ standard that suggests that copying pointers is not a problem and doesn't count towards the complexity. Also, I did not add the indirection, others have noted that the deque is a two level structure - see this accepted answer stackoverflow.com/a/6292437/146041 This appears to a complex and subtle, and interesting(!), question. – Aaron McDaid Dec 28 '11 at 17:06
ah... interesting! Indeed if the complexity is defined in terms of the number of calls of the copy constructor, then there is none when pushing elements at the end with the traditional array of pointers implementations (whether they use blocks or simple pointers). Still, I find this somewhat cheating. Even though it means that the complexity does not vary depending on the complexity of T, it hides the fact that it varies depending on the number of elements... – Matthieu M. Dec 28 '11 at 17:54

My understanding of deque

It allocates 'n' empty contiguous objects from the heap as the first sub-array. The objects in it are added exactly once by the head pointer on insertion.

When the head pointer comes to the end of an array, it allocates/links a new non-contiguous sub-array and adds objects there.

They are removed exactly once by the tail pointer on extraction. When the tail pointer finishes a sub-array of objects, it moves on to the next linked sub-array, and deallocates the old.

The intermediate objects between the head and tail are never moved in memory by deque.

A random access first determines which sub-array has the object, then access it from it's relative offset with in the subarray.

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