Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Asking this question with C# tag, but if it is possible, it should be possible in any language.

Is it possible to implement a doubly linked list using Interlocked operations to provide no-wait locking? I would want to insert, add and remove, and clear without waiting.

share|improve this question
lock free and wait free are different.... lock free means some threads can make progress, wait free means all threads can make process. –  user997112 Mar 16 at 2:45
add comment

8 Answers

up vote 10 down vote accepted

A simple google search will reveal many lock-free doubly linked list papers.

However, they are based on atomic CAS (compare and swap).

I don't know how atomic the operations in C# are, but according to this website


C# operations are only guaranteed to be atomic for reading and writing a 32bit field. No mention of CAS.

share|improve this answer
C# (.NET) absolutely has an atomic Compare-and-Swap. It is called Interlocked.CompareExchange. msdn.microsoft.com/en-us/library/… –  Cheeso May 11 '09 at 20:12
@ Cheeso, then in that case, its possible. –  Unknown May 11 '09 at 20:37
It could be used to implement a multi-threaded user-interface - no more single UI Thread. –  luvieere Nov 5 '09 at 13:14
@luvieere: The vast majority of the time there is absolutely no need for a multi-threaded UI. Using a single thread simplifies things greatly and the added complexity of using multiple UI threads is simply not worth it. –  Ed S. Mar 2 '12 at 17:50
add comment

Yes it's possible, here's my implementation of an STL-like Lock-Free Doubly-Linked List in C++.

Sample code that spawns threads to randomly perform ops on a list

It requires only a 32-bit compare-and-swap to operate on full 32-bit memory addresses without any ABA issues. This list is only possible because of a strong lock-free memory manager.

Check out the benchmarks on page 12. Performance of the list scales linearly with the number of threads as contention increases. The algorithm supports parallelism for disjoint accesses, so as the list size increases contention can decrease.

My implementation should actually run faster than the algorithm in the paper as I use a O(1) lookup table instead of a O(log n) set in the memory reclamation function. It runs on x86 compiling with VS2010. The memory manager may need a few more barriers for architectures with weak memory models.

share|improve this answer
A+ for good research. –  Andres Jaan Tack Nov 21 '11 at 18:23
Your links are broken. –  user Jun 30 '13 at 13:56
can you take a look at this question: stackoverflow.com/q/19609417/2279977 , pls –  MohammadRB Oct 27 '13 at 6:06
add comment

Here is a paper which discribes a lock free doublly linked list.

We present an efficient and practical lock-free implementation of a concurrent deque that is disjoint-parallel accessible and uses atomic primitives which are available in modern computer systems. Previously known lock-free algorithms of deques are either based on non-available atomic synchronization primitives, only implement a subset of the functionality, or are not designed for disjoint accesses. Our algorithm is based on a doubly linked list, and only requires single-word compare-and-swap...

Ross Bencina has some really good links I just found with numerious papers and source code excamples for "Some notes on lock-free and wait-free algorithms".

share|improve this answer
I believe however, AFAIK, ALL doubly-linked lists (and indeed, it might even be all singly-linked lists) require GC. –  user82238 Oct 6 '09 at 15:21
I believe Valois' 1995 singly-linked list does not require GC - I need to read the paper though. –  user82238 Oct 21 '09 at 8:54
The Valois paper uses reference counting to ensure lock free memory management. The reference count represents the number of global pointers to the node. Additionally each thread keeps a hazard list of pointers to nodes it is currently using. If a thread wants to remove a pointer from its hazard list which has a reference count of 0, it has to scan the hazard lists of all other threads to see if anyone is still using it, and only delete it of no one is. There are some tricks involved in safely scanning the hazard lists without taking any locks. –  JanKanis May 27 '13 at 13:47
add comment

I don't believe this is possible, since you're having to set multiple references in one shot, and the interlocked operations are limited in their power.

For example, take the add operation - if you're inserting node B between A and C, you need to set B->next, B->prev, A->next, and C->prev in one atomic operation. Interlocked can't handle that. Presetting B's elements doesn't even help, because another thread could decide to do an insert while you're preparing "B".

I'd focus more on getting the locking as fine-grained as possible in this case, not trying to eliminate it.

share|improve this answer
"getting the locking as fine-grained as possible" - that could make it slower, as the cost of taking out many short locks may be more significant than the avoided waiting time, depending on the macro-behaviour of the application. –  Daniel Earwicker May 11 '09 at 20:34
Good point, Earwicker. Profiling would be of benefit here –  Reed Copsey May 11 '09 at 21:12
This answer is incorrect. Doubly linked lists have been implemented. The key is that the back pointer isn't always up to date and so when you traverse backwards, you have to do some extra work. –  user82238 Oct 6 '09 at 15:20
I don't think @BlankXavier gets the question... –  John Gietzen Oct 6 '09 at 15:30
I don't think @JohnGietzen gets the question. The OP wants to know if it's possible to implement a wait free doubly linked list. It is. The back pointer cannot be trusted, so extra work is done when walking the list backward, but that's not waiting. The data structure has very similar performance characteristics to a "real" doubly linked list. But of course low-lock data structures can often be slower than their much simpler locking counterparts - that's why you need to profile first, and verify that the locking is actually the bottleneck. –  Eloff Apr 7 '10 at 18:38
show 7 more comments

Read the footnote - they plan to pull ConcurrentLinkedList from 4.0 prior to the final release of VS2010

share|improve this answer
add comment

FWIW, .NET 4.0 is adding a ConcurrentLinkedList, a threadsafe doubly linked list in the System.Collections.Concurrent namespace. You can read the documentation or the blog post describing it.

share|improve this answer
Threadsafe by no means means lock-free. –  user82238 Oct 6 '09 at 15:23
add comment

Well you haven't actually asked how to do it. But, provided you can do an atomic CAS in c# it's entirely possible.

In fact I'm just working through an implementation of a doubly linked wait free list in C++ right now.

Here is paper describing it. http://www.cse.chalmers.se/~tsigas/papers/Haakan-Thesis.pdf

And a presentation that may also provide you some clues. http://www.ida.liu.se/~chrke/courses/MULTI/slides/Lock-Free_DoublyLinkedList.pdf

share|improve this answer
add comment

I would say that the answer is a very deeply qualified "yes, it is possible, but hard". To implement what you're asking for, you'd basically need something that would compile the operations together to ensure no collisions; as such, it would be very hard to create a general implementation for that purpose, and it would still have some significant limitations. It would probably be simpler to create a specific implementation tailored to the precise needs, and even then, it wouldn't be "simple" by any means.

share|improve this answer
"something that would compile the operations together to ensure no collisions" - what does that mean? –  Daniel Earwicker May 11 '09 at 20:32
Think of it like how modern CPUs utilize multiple execution units on one core to achieve high instruction throughput; the interactions of the instructions with the execution units is checked to be non-interdependent, and the microinstructions are interleaved so as to preserve any order-dependent operations. It's fundamentally a compilation operation. –  Paul Sonier May 11 '09 at 21:00
This is a pretty much a non-issue as most languages supply some sort of "memory barrier" that disallows both the compiler and the CPU from moving read/write operations beyond it, so you can make sure it doesn't rearrange the operations in a way that invalidates you're code. (Its why the volatile keyword in c/c++ was invented, though volatile only ensures this against other volatile variables, hence the introduction of memory barriers). –  Grant Peters Jun 23 '09 at 14:36
There are better methods than the method suggested here. I don't think anyone has tried doing this - it seems basically to be a form of serialisation, not unlike a multiple-reader/single-writer lock. –  user82238 Oct 6 '09 at 15:24
add comment

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.