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  1. Say I have a bitmap, and several threads (running on several CPUs) are setting bits on it. No synchronization is used, and no atomic operations. Also, no resets are done. To my understanding, when two threads are trying to set two bits on the same word, only one operation would eventually stick. The reason is that for a bit to be set, the whole word should be read and written back, and so when both reads are done at the same time, when writing back one operation would override the other. Is that correct?

  2. If the above is true, is it always so for byte operations as well? Namely, if a word is 2 bytes, and each thread tries to set a different byte to 1, will they too override each other when done concurrently, or do some systems support writing back the results to only a part of a word?

Reason for asking is trying to figure out how much space do I have to give up in order to omit synchronization in bit/byte/word-map operations.

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up vote 5 down vote accepted

In short, it's very CPU and compiler dependent.

Say you have a 32-bit value containing zero, and thread A wants to set bit 0 and thread B wants to set bit 1.

As you describe, these are read-modify-write operations, and the synchronization issue is 'what happens if they collide'.

The case you need to avoid is this:

A: Reads (gets 0)
B: Reads (also gets zero)
A: Logical-OR bit 0, result = 1
A: Writes 1
B: Logical-OR bit 1, result = 2
B: Writes 2 - oops, should have been 3

... when the correct result is this...

A: Reads (gets 0)
A: Logical-OR bit 0, result = 1
A: Writes 1
B: Reads (gets 1)
B: Logical-OR bit 1, result = 2
B: Writes 3 - correct

On some processors, the read-modify write will be three separate instructions, so you WILL need synchronization. On others, it will be a single atomic instruction. On multiple Core/CPU systems it will be a single instruction BUT other cores/CPUs may be able to access, so again you will need synchronization.

Doing it with bytes can be the same. In some processor memory architectures, you can only write a 32-bit memory value, so byte updates require a read-modify-write as before.

Update for X86 architecture (and windows, specifically)

Windows provides a set of atomic "Interlocked" operations on 32-bit values, including Logical OR. These could be a big help to you in avoiding critical sections. but beware, because as Raymond Chen points out, they don't solve everything. Keeping reading that post until you understand it!

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1  
The Interlocked* functions are actually quite equivalent to critical sections, at least until two threads try to enter a section at the same time, when a real kernel object (event IIRC) is created. Till then, Interlocked is use on any entrance. Also, note that Interlocked ops do impose some synchronization in an SMP environment, and are much heavier than a simple set. But thanks anyway for the elaborated answer! – eran Nov 10 '10 at 5:53

The specifics will be system-dependent, and possibly compiler-dependent. I imagine you might have to go all the way to a 32-bit integer before you are free from the effects you fear.

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I'm not even sure that 32 bits values are enough - are 32 bits operation atomic on all 64 bits architectures? – MSalters Nov 9 '10 at 12:26
    
Good point! .... – Ned Batchelder Nov 9 '10 at 12:34
    
@MSalters: 32 bit operations aren't necessarily atomic (in the sense we need) on all 32 bit architectures either. ARM permits non-coherent caches, so it really doesn't matter whether the op is atomic w.r.t the local CPU cache, it isn't atomic w.r.t main memory. – Steve Jessop Nov 9 '10 at 13:32
  1. I believe this is true, for the reasons you specified.

  2. The way I see it, if your bitmap is stored as a char[], and if your architecture is byte addressable (it's possible to read and write an individual byte in memory, without having to read an entire word), then the compiler may generate an atomic operation. Even so, it's completely implementation-defined, so you can't rely on it.

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I've presented the problem in a general way, but in practice, I'm aiming at the common x86 and x64 platforms. Are any of their variants byte addressable, or is it a feature of some exotic architectures? – eran Nov 9 '10 at 12:48
    
@eran - suggest you update your question with that detail... – Roddy Nov 9 '10 at 13:51

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