I need to calculate an array (writeArray) using another array (readArray) but the problem is the index mapping is not the same between arrays (Value at index x of writeArray must be calculated with value at index y of readArray) so it's not very cache friendly.

However I can either choose if the loop browses readArray sequentially or writeArray sequentially.

So here is a simplified code :

int *readArray = new int[ARRAY_SIZE];       // Array to read
int *writeArray = new int[ARRAY_SIZE];      // Array to write
int *refArray = new int[ARRAY_SIZE];        // Index mapping between read and write, could be also array of pointers instead indexes

// Code not showed here : Initialization of readArray with values, writeArray with zeroes and refArray with random indexes for mapping between readArray and writeArray (values of indexes between 0 and ARRAY_SIZE - 1)

// Version 1: Random read (browse writeArray/refArray sequentially)
for (int n = 0; n < ARRAY_SIZE; ++n) {
    writeArray[n] = readArray[refArray[n]];

// Version 2: Random write (browse readArray/refArray sequentially)
for (int n = 0; n < ARRAY_SIZE; ++n) {
    writeArray[refArray[n]] = readArray[n];

I was thinking that cache read misses was more slower than write misses (because CPU needs to wait before reading complete if the next instruction depends of read data but for writing it doesn't need to wait for processing the next instruction) but with profiling it's seems that version 1 is faster than version 2 (version 2 is about 50% more slower than version 1).

I tried also this :

// Version 3: Same as version 2 but without polluting cache
for (int n = 0; n < ARRAY_SIZE; ++n) {
    _mm_stream_si32(&writeArray[refArray[n]], readArray[n]);

Because I don't need to read values of writeArray so there is no reason to pollute the cache with written values but this version is more more slower than other versions (6700% more slower than version 1).

Why write miss is slower than read miss ? Why bypassing cache for writing is more slower than using it even if we don't read these written data after ?

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  • I'm no expert in this area, but I'll bet it has something to do with pipelining. – Barmar Mar 12 '15 at 14:44
  • 3
    If you machine is OOO, then a read miss doesn't block other instructions that doesn't depend on this data. In this case, read misses occur very densely and are serviced in a pipelined fashion. Write misses are different, write misses usually have to be serviced first before anything can proceed to prevent read-before-write. – user3528438 Mar 12 '15 at 14:52
  • @user3528438 which sounds like a design decision. The write has to flush all reads, then do the write and "finish". The read can pipeline. You could reverse this (reads flush all writes, and read immediately, writes pipeline), but pipelining both is hard. And probably reading is more common than writing? Or feels like it should be faster. – Yakk - Adam Nevraumont Mar 12 '15 at 14:55
  • @Yakk I don't think you fully understand why I mentioned OOO. Cache missed are serviced in the same way for read- and write- misses. Multiple write misses can not happen because the existing miss stalls the machine so there's nothing to be pipelined. But when the machine is OOO, read-miss doesn't immediately cause a stall, then next read-miss can occur while current is being serviced. – user3528438 Mar 12 '15 at 15:21
  • @user3528438 I was treating OOO as "general out of order", not "the dominate out of order pattern". If you made read misses stall, and write misses not stall, in an OOO system you would maintain memory coherency as far as I can tell? Now, that would be a pretty useless machine, optimized for code that writes more than it reads, which is a strange beast. – Yakk - Adam Nevraumont Mar 12 '15 at 15:26

Let's start with the last version - what you did is use streaming stores for non sequential (not a stream) access pattern. You're randomly accessing integers, which means you're doing partial writes (int sized) into full cache lines. On normal writes this shouldn't matter, since the core pulls the line into cache, and simply modifies the necessary chunk (which will later be followed by writing it back when you need the storage for something else), but since you ask it to avoid caching, you actually have to do this partial merge in memory which is very expensive and blocking. Streaming stores are useful only when you're guaranteed to modify the full line (for e.g. by going over the array sequentially).

As for the 2nd version - your assumption is correct, if there was data dependency through the loads you would have had to wait for them, but there is no real dependency chain here. You only have a set of loads with a 2-level dependency, but no interdependency between them to cause any serialization across iterations (i.e. iteration n==2 and n==3 may start even before n==1 gets the first load done). Effectively, assuming your CPU can sustain N outstanding accesses (depending on the sizes and cache levels involved), you'll launch the first N references to refArray in parallel (assuming the index calculation is fast), followed by the first N references to readArray, and then the next batch and so on.

Now, since there's no data dependency, it becomes a question of bandwidth. In that case, generally speaking, loads are much easier for the processor due to their out-of-order nature - you can launch them in parallel and out of order, once you know the address (which only depends on the fast index calculation). Stores, on the other hand, need to be observed in program order (to retain memory consistency), which almost serializes them (there are some possible CPU tricks there, depending on your exact micro-architecture, but it won't change the big picture).

Edit: Another constraint added in version 2 (which I believe is even more critical), is memory disambiguation. The processor has to calculate the loads and stores addresses, in order to know if there's any collision (we know there isn't, but the processor doesn't...). If a load depends on a store, it has to be blocked, in case the new data has to be forwarded. Now, since loads are launched in an OOO machine early, it becomes vital to know the addresses for all the stores as early as possible to avoid collisions (or worse - speculations that fail and cause mass flushes)

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  • Thank you, so if I understand well, in this case, for random read example, prefetching could not optimize because the CPU doesn't wait unless the cache is full, is that correct ? Is it possible to avoid write stall by an instruction if we know that write doesn't affect memory we are reading ? – Johnmph Mar 12 '15 at 18:43
  • I'm not sure I follow the prefetching question, but prefetching can cut latency when you're not bandwidth constrained. In this case, since you have plenty of iterations for the OOO to run ahead through, I doubt it's going to be useful. As for avoiding the stalls, that depends on your micro architecture, but maybe using different offsets along the page for each array would help (it's also going to avoid cache set collisions which we didn't mention) – Leeor Mar 12 '15 at 20:22

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