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I just noticed a question asking what recursive data types ("self-referential types") would be good for in C++ and I was tempted to boldly claim

It's the only way to construct data structures (more precisely containers) that can accept arbitrary large data collections without using continuous memory areas.

That is, if you had no random-access arrays, you would require some means of references (logically) to a type within that type (obviously, instead of having a MyClass* next member you could say void* next but that would still point to a MyClass object or a derived type).

However, I am careful with absolute statements -- just because I couldn't think of something doesn't mean it's not possible, so am I overlooking something? Are there data structures that are neither organised using mechanisms similar to linked lists / trees nor using continuous sequences exclusively?

Note: This is tagged both and as I'd be interested specifically in the C++ language but also in theoretical aspects.

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+1 for this question which made me seriously think.... and I'm still thinking, and wondering. –  Nawaz Aug 24 '12 at 16:43
@Nawaz: I'm still waiting for some halfwit to remove the language-agnostic tag without reading the question :) –  bitmask Aug 24 '12 at 16:51
tbh idk if i get what you mean , but what about std::deque –  NoSenseEtAl Aug 27 '12 at 14:10

5 Answers 5

up vote 4 down vote accepted

It's the only way to construct data structures (more precisely containers) that can accept arbitrary large data collections without using continuous memory areas.

After contemplating for a while, this statement seems be correct. It is self-evident, in fact.

Suppose I've a collection of elements in a non-contiguous memory. Also suppose that I'm currently at element e. Now the question is, how would I know the next element in the collection? Is there any way?

Given an element e from a collection, there are only two ways to compute the location of the next element:

  • If I assume that it is at offset sizeof(e) irrespective of what e is, then it means that the next element starts where the current element ends. But then this implies that the collection is in a contiguous memory, which is forbidden in this discussion.

  • The element e itself tells us the location of the next element. It may store the address itself, or an offset. Either way, it is using the concept of self-reference, which too is forbidden in this discussion.

As I see it, the underlying idea of both of these approaches is exactly same: they both implement self-reference. The only difference is that in the former, the self-reference is implemented implicitly, using sizeof(e) as offset. This implicit self-reference is supported by the language itself, and implemented by the compiler. In the latter, it is explicit, everything is done by the programmer himself, as now the offset (or pointer) is stored in the element itself.

Hence, I don't see any third approach to implement self-reference. If not self-reference, then what terminology would one use to describe the computation of the location of the next element to an element e.

So my conclusion is, your statement is absolutely correct.

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Now I'm biased to accept your glorious assertions that I'm correct. I'll give it a day to see if somebody is able to contradict us. :) –  bitmask Aug 24 '12 at 17:22
@bitmask: Edited with my explanation. –  Nawaz Aug 24 '12 at 17:41
This is not entirely true, only on the premise of the usual memory model. If you have, you could, for example use a transactional memory approach where a pointer has to be combined with a generation to actually access the data. For a slightly more realistic option consider a file backed data structure where you memory map only one block, and you move to the next element by remapping a different section of the file (i.e. the next element is in the exact same location in memory after the file is remapped). The problem is that the question is ill-posed. –  David Rodríguez - dribeas Aug 24 '12 at 17:46
@user315052 A linked list is not searchable any more than an array is searchable. It is simple a collection, and so is a tree. You can treat the elements (or parts of them) as key for search algorithms, or you can choose not to do so. –  delnan Aug 24 '12 at 18:05
@user315052 I do not understand your objection, quite possibly because I am not smart enough for this kind of abstract thought. What I do feel is that algorithms operating over a data structure should not matter to this question since they do not change the way the data structure is defined -- e.g. a tree is a tree regardless of whether we use it as search tree or just as XML document. –  delnan Aug 24 '12 at 18:17

The problem is that the dynamic allocator itself is managing contiguous storage. Think about the "tape" used for a Turing Machine, or the Von Neumann architecture. So to seriously consider the problem, you would likely need to develop a new computing model and new computer architecture.

If you think disregarding the contiguous memory of the underlying machine is okay, I am sure a number of solutions are possible. The first that comes to my mind is that each node of the container is marked with an identifier that has no relation to its position in memory. Then, to find the associated node, all of memory is scanned until the identifier is found. This isn't even particularly inefficient if given enough computing elements in a parallel machine.

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Ah, good point. But the data-structure programmer doesn't have to be aware that RAM is really just a huge array. With continuous memory I was referring to continuous memory that is used as such! –  bitmask Aug 24 '12 at 17:02
@bitmask: From that point of view, the programmer doesn't have to know how an array is actually implemented, as long as the index operator does what it advertises to do. –  jxh Aug 24 '12 at 17:04
While this is true, I think that the distinction between memory usage of linked lists and arrays is sufficient to provide an interesting puzzle, even if all data structures merely map to a continuous memory backing. –  Maz Aug 24 '12 at 17:06
@bitmask: I added a hypothetical data structure. –  jxh Aug 24 '12 at 17:31

Here's a sketch of a proof.

Given that a program must be of finite size, all types defined within the program must contain only finitely many members and reference only finitely many other types. The same holds for any program entrypoint and for any objects defined before program initialisation.

In the absence of contiguous arrays (which are the product of a type with a runtime natural number and are therefore unconstrained in size), all types must be arrived at through the composition of types as above; derivation of types (pointer-to-pointer-to-A) is still constrained by the size of the program. There are no facilities other than contiguous arrays to compose a runtime value with a type.

This is a little contentious; if e.g. mappings are considered primitive then one can approximate an array with a map whose keys are the natural numbers. Of course, any implementation of a map must use self-referential data structures (B-trees) or contiguous arrays (hash tables).

Next, if the types are non-recursive then any chain of types (A references B references C...) must terminate, and can be of no greater length than the number of types defined in the program. Thus the total size of data referenceable by the program is limited to the product of the sizes of each type multiplied by the number of names defined in the program (in its entrypoint and static data).

This holds even if functions are recursive (which strictly speaking breaks the prohibition on recursive types, since functions are types); the amount of data immediately visible at any one point in the program is still limited to the product of the sizes of each type multiplied by the number of names visible at that point.

An exception to this is if you store a "container" in a stack of recursive function calls; however such a program would not be able to traverse its data at random without unwinding the stack and having to reread data, which is something of a disqualification.

Finally, if it is possible to create types dynamically the above proof does not hold; we could for example create a Lisp-style list structure where each cell is of a distinct type: cons<4>('h', cons<3>('e', cons<2>('l', cons<1>('l', cons<0>('o', nil))))). This is not possible in most static-typed languages, although it is possible in some dynamic languages e.g. Python.

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You're basically paraphrasing the core idea in König's lemma. At first I thought you were dead on, but if we allow continuous arrays, your assertion that we need recursive types would still hold which is obviously false. I believe this breaks your proof. Unfortunately -- it was elegant. –  bitmask Aug 24 '12 at 17:31
@bitmask I think I've rescued it, want to take another look? –  ecatmur Aug 24 '12 at 18:04

The statement is not correct. The simple counter example is std::deque in C++. The basic data structure (for the language-agnostic part) is a contiguous array of pointers to arrays of data. The actual data is stored in ropes (non-contiguous blocks), that are chained through a contiguous array.

This might be bordering your requirements, depending on what without using continuous memory areas mean. I am using the interpretation that the stored data is not contiguous, but this data structure depends on having arrays for the intermediate layer.

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Doesn't that still use continuous memory areas to store an arbitrarily large amount of data? Since either the array of arrays needs contain more arrays, or one of it's element arrays needs to gain more elements. Either way, you still use continuous memory areas. –  Maz Aug 24 '12 at 16:50
I will not be convinced with this answer if I take "without using continuous memory" part seriously to the extent that avoids using any array. –  Nawaz Aug 24 '12 at 16:52
If you ask me, this doesn't qualify. You are still using continuous storage. Obviously, I can store some intermediate type (that contains just one or any number of actual data objects) in the continuous sequence to avoid storing the data directly. –  bitmask Aug 24 '12 at 16:53
@bitmask: The problem is that your question is ill-posed. In some languages, even self referencing types are implemented in terms of arrays (i.e. the list interface can be implemented as an array). Now if what you want is strictly that, then a recursive template is a solution, since technically each instantiation of the template is a different type, the template refers to itself, but none of the types is self referencing. I am tempted to close as Not a question, as it is not clear what you really want to achieve –  David Rodríguez - dribeas Aug 24 '12 at 17:19
@bitmask: Also note the final question: Are there data structures that are neither organised using mechanisms similar to linked lists / trees nor using continuous sequences exclusively? ==> std::deque –  David Rodríguez - dribeas Aug 24 '12 at 17:21

I think a better phrasing would be:

It's the only way to construct data structures (more precisely containers) that can accept 
arbitrary large data collections without using memory areas of determinable address.

What I mean is that normal arrays use addr(idx)=idx*size+inital_addr to get the memory address of an element. However, if you change that to something like addr(idx)=idx*idx*size+initial_addr then the elements of the data structure are not stored in continuous memory areas, rather, there are large gaps between where elements are stored. Thus, it is not continuous memory.

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But you would still use continuous memory. It' just that you choose not to make use of most elements. You just waste memory intentionally -- if I understand you correctly. –  bitmask Aug 24 '12 at 17:10
No, you're not wasting memory. Let's say I'm the kernel, so I have access to all system memory. I could have an data structure, storing data in the above pattern. Then, when I map memory to user-level processes, I map the gaps in between the elements that I am using to user-mode memory. –  Maz Aug 24 '12 at 17:14
Ah, I see. Well then your memory still looks like continuous for the user. I can access addr(0), addr(1), addr(2), and so forth. What the kernel does with that is none of my concern (as far as this question is concerned). –  bitmask Aug 24 '12 at 17:18
I'm saying that the kernel is the sample program, but this still works for user-mode programs. Let's say the memory allocator (in user-mode) wants to store some data in a data structure. Then, whenever malloc() is called, it returns memory from in between elements of the data structure. In this case the memory doesn't look continuous to the program, and it doesn't matter, since malloc() results don't need to be continuous, so long as the pointer returned is continuous for the requested size. –  Maz Aug 24 '12 at 17:22

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