I have some code which uses an array of int (int[]) in a thread which is activated every second.

I use lock() from std::mutex to lock this array in this thread.

However I wonder if there is a way to create an atomic array (or vector) to avoid using a mutex? I tried a couple of ways, but the compiler always complains somehow?

I know there is a way to create an array of atomics but this is not the same.

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    what are the ways you tried and how exactly did the compiler complain? – largest_prime_is_463035818 Sep 6 '17 at 7:36
  • Possible duplicate of (preferably boost) lock-free array/vector/map/etc? – Robinson Sep 6 '17 at 7:45
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    BTW, atomic doesn't guaranty lock-free, so implementation can do thing similarly to mutex. – Jarod42 Sep 6 '17 at 7:45
  • @tobi303 I tried to make some combinations like this: std::atomic<int[]> myArray = {0,0,0}; or like this: std::atomic<int[10]> myArray; and so on. – rainbow Sep 6 '17 at 7:48
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    There are some very good CPPCON talks on lock-free programming and performance measuring. The short answer is don't bother unless the mutex version cannot meet the performance expectations of your users. If that's the case then in all likelihood it's your design that's wrong. An atomic store takes ~10 times as long as a non-atomic one. If you're doing a run of stores, you're better off holding a lock and doing them without atomics. – Richard Hodges Sep 6 '17 at 8:03

In practice, at the CPU level, there are instructions which can atomically update an int, and a good compiler will use these for std::atomic<int>. In contrast, there are are no instructions which can atomically update a vector of ints (for any architecture I am aware of), so there has got to be a mutex of some sort somewhere. You might as well let it be your mutex.

For future readers who haven't yet written code with the mutex:

You can't create a std::atomic of int[10], because that leads to a function which returns an array - and you can't have those. What you can do, is have a std::atomic<std::array<int,10>>

int main()
  std::atomic<std::array<int,10>> myArray;

Note that the compiler/library will create a mutex under the hood to make this atomic. Note further that this doesn't do what you want. It allows you to set the value of the whole array atomically.

It doesn't allow you to read the whole array, update one element, and write the whole array back atomically.

The reads and the writes will be individually atomic, but another thread can get in between the read and the write.

You need the mutex!

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    it might be worth mentioning that this array would be about as useful as a chocolate teapot. All you would be able to do is take copies of the entire array or replace the entire array from a copy. – Richard Hodges Sep 6 '17 at 8:06
  • Short and elegant explanation. Thank you. This is answer I looked for. – rainbow Sep 6 '17 at 8:20
  • cppref states "std::atomic may be instantiated with any TriviallyCopyable type T:" and afaik arrays are trivially copyable, or am I wrong? – largest_prime_is_463035818 Sep 6 '17 at 8:26
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    @RichardHodges : Yes, I wrote this before cycling to work. As I walked out the door, I realized that problem! – Martin Bonner supports Monica Sep 6 '17 at 8:33
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    @tobi303 : Hmm. According to cppreference, arrays of trivially copyable types are trivially copiable. That may mean there is an error in cppreference, or there is a defect in the standard. Requiring that the library allow you to instantiate std::atomic<int[10]> when there can be no way of obtaining the value (because operator T would have to return int[10]) is pointless. – Martin Bonner supports Monica Sep 6 '17 at 8:46

You can put arrays in atomics, but not directly. Like the other answer explain you can use std::array. I answered this question and explained how to do something similar for a struct.

Having said that and explained the technical viability, I have to tell you something else:


The power of atomic variables come from the fact that some processors can do their operations with one instruction. The C++ compiler will try to make your atomic operations happen in one instruction. If it fails, it'll initiate a bus lock, which is like a global lock of everything, until that array is updated. It's equivalent to a mutex that locks all your variables in your program. If you're concerned about performance, don't do that!

So for your case, a mutex is not a bad idea. At least you can control what is critical and improve performance.

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    bus lock: Do you have a cite for that? Surely creating a mutex under the hood is going to be much easier to implement (and much more performant). – Martin Bonner supports Monica Sep 6 '17 at 8:32
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    How can it be done? Easy. None of the member functions of std::atomic allow direct access to the underlying value, so give each std::atomic a mutex, lock the mutex at the start of each member function, release it at the end. I have a feeling that you may be mis-remembering how some architectures implement atomic operations on eg a word. – Martin Bonner supports Monica Sep 6 '17 at 8:43
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    @MartinBonner You may be right. But let me point out a very subtle point here: It's not about thread-safety as this is not what the program has to guarantee, and that's the problem. It's about atomicity and its semantic meaning. The definition of an atomic variable is: It's a variable with operations that can be either done or not done. It cannot be in any state in between. It's not about locking access to the variables. But again, I might be misremembering this, however, I would never do atomics for more than 16 bytes. – The Quantum Physicist Sep 6 '17 at 8:51
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    std::atomic<std::array<unsigned char, 256>> provides exactly that. Internally, there may be intermediate states - but they are unobservable by any C++ programme with defined behaviour. (And if the program has undefined behaviour, it becomes impossible to reason about.) – Martin Bonner supports Monica Sep 6 '17 at 8:55
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    I feel like "If it fails, it'll initiate a bus lock" isn't exactly true. Take a look at the signature of atomic::load: cplusplus.com/reference/atomic/atomic/load You can specify memory_order_xxx – KeksArmee Sep 12 '18 at 16:28

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