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Suppose that I have an integer variable in a class, and this variable may be concurrently modified by other threads. Writes are protected by a mutex. Do I need to protect reads too? I've heard that there are some hardware architectures on which, if one thread modifies a variable, and another thread reads it, then the read result will be garbage; in this case I do need to protect reads. I've never seen such architectures though.

This question assumes that a single transaction only consists of updating a single integer variable so I'm not worried about the states of any other variables that might also be involved in a transaction.

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Dupe of stackoverflow.com/questions/1087771/… among many others –  anon Aug 29 '09 at 10:02
I don't think that specific one is a duplicate of this, but it has been asked before, I think –  1800 INFORMATION Aug 29 '09 at 10:07
Whoops you are right - there were so many to choose from I guess I got confused. –  anon Aug 29 '09 at 10:11
There's also the issue of memory barriers: If one thread writes to the variable, does the other thread see that change at all? (This can be an issue if the two threads access the memory through different processor caches.) –  sbi Aug 29 '09 at 14:22
Neil, that's Java, which has a different memory model. –  Hongli Aug 29 '09 at 16:54

12 Answers 12

up vote 24 down vote accepted

atomic read
As said before, it's platform dependent. On x86, the value must be aligned on a 4 byte boundary. Generally for most platforms, the read must execute in a single CPU instruction.

optimizer caching
The optimizer doesn't know you are reading a value modified by a different thread. declaring the value volatile helps with that: the optimizer will issue a memory read / write for every access, instead of trying to keep the value cached in a register.

CPU cache
Still, you might read a stale value, since on modern architectures you have multiple cores with individual cache that is not kept in sync automatically. You need a read memory barrier, usually a platform-specific instruction.

On Wintel, thread synchronization functions will automatically add a full memory barrier, or you can use the InterlockedXxxx functions.

MSDN: Memory and Synchronization issues, MemoryBarrier Macro

[edit] please also see drhirsch's comments.

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+1 because of memory barrier/CPU Cache mention as well as optimizer caching, which no one else here seems to acknowledge. –  paercebal Aug 29 '09 at 21:28
-1 for being completly wrong on the CPU cache issue. Google up MESI protocol. Memory barriers are for weak ordering load/store instructions (on x86 usually streaming mmx), which is a completly different topic. –  hirschhornsalz Sep 7 '09 at 10:46
(1) Yes. There is no multiprocessor architecture without cache coherency, simply because it is required. There are other protocols than MESI, but this is the most widespread. (2) You seem to confuse reordering of instructions, reordering of memory operations and concurrent access to the same data. This is all different. On most architectures instructions and the corresponding memory operations are not coupled, the processor may reorder memory operations within certain limits for effiency (out of order architecture). One of the rare counterexamples is the Intel Atom. –  hirschhornsalz Sep 8 '09 at 0:51
But this usually doesn't concern the programmer, unless you use instructions which have "weak memory ordering". You need assembler instructions or intrinsics to use these, so if you are using a high level language you will never have to use memory barriers. So far this has absolutly nothing to do with multiprocessors and their cache. If now two processors access the same data, which resides in one of the processors caches, the hardware makes sure, that both of the processors get the very same data, which may be even transferred from one processors cache to the other. –  hirschhornsalz Sep 8 '09 at 1:03
The "reordering of instructions" isn't really relevant in that case, this is a local optimization a processor can do. If you don't use synchronization and have a write operation in one of your processors the result is simply undefined. - The MSDN is really not the right place to look up lowlevel instructions, better check Intels or AMDs manuals or whatever you are using. –  hirschhornsalz Sep 8 '09 at 21:25

You ask a question about reading a variable and later you talk about updating a variable, which implies a read-modify-write operation.

Assuming you really mean the former, the read is safe if it is an atomic operation. For almost all architectures this is true for integers.

There are a few (and rare) exceptions:

  • The read is misaligned, for example accessing a 4-byte int at an odd address. Usually you need to force the compiler with special attributes to do some misalignment.
  • The size of an int is bigger than the natural size of instructions, for example using 16 bit ints on a 8 bit architecture.
  • Some architectures have an artificially limited bus width. I only know of very old and outdated ones, like a 386sx or a 68008.
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Note that even if the read is atomic, it may still be a stale value from the current threads CPU's cache. –  peterchen Aug 29 '09 at 16:58
No. Read about the MESI protcol. Cache coherency for normal read/write operations is always guaranteed and transparent to the software. –  hirschhornsalz Sep 7 '09 at 10:48
@drhirsch: Are you absolutely certain that no CPU exists that requires explicit cache control in the machine code? Because I am pretty sure I have read about such. –  Zan Lynx Sep 8 '09 at 14:50
@drhirsch: Ahah! "Not so MIPS systems, where many MIPS cores have caches with no extra "coherence" hardware of any kind." - embedded.com/design/opensource/208800056?_requestid=187872 –  Zan Lynx Sep 8 '09 at 14:53
This arcticle talkes about I/O caches in single processor systems regarding to DMA access. This has nothing to do with CPU cache coherency in multiprocessor systems. Do you understand the difference? –  hirschhornsalz Sep 8 '09 at 21:15

I'd recommend not to rely on any compiler or architecture in this case.
Whenever you have a mix of readers and writers (as opposed to just readers or just writers) you'd better sync them all. Imagine your code running an artificial heart of someone, you don't really want it to read wrong values, and surely you don't want a power plant in your city go 'boooom' because someone decided not to use that mutex. Save yourself a night-sleep in a long run, sync 'em.
If you only have one thread reading -- you're good to go with just that one mutex, however if you're planning for multiple readers and multiple writers you'd need a sophisticated piece of code to sync that. A nice implementation of read/write lock that would also be 'fair' is yet to be seen by me.

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Imagine that you're reading the variable in one thread, that thread gets interrupted while reading and the variable is changed by a writing thread. Now what is the value of the read integer after the reading thread resumes?

Unless reading a variable is an atomic operation, in this case only takes a single (assembly) instruction, you can not ensure that the above situation can not happen. (The variable could be written to memory, and retrieving the value would take more than one instruction)

The consensus is that you should encapsulate/lock all writes individualy, while reads can be executed concurrently with (only) other reads

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Read does not need to take one clock cycle to be atomic. Your last part is unclear to me - I guess you mean "reads can be domne concurrently, but durign a write, other threads reading or writing must be locked" –  peterchen Aug 29 '09 at 17:07

Suppose that I have an integer variable in a class, and this variable may be concurrently modified by other threads. Writes are protected by a mutex. Do I need to protect reads too? I've heard that there are some hardware architectures on which, if one thread modifies a variable, and another thread reads it, then the read result will be garbage; in this case I do need to protect reads. I've never seen such architectures though.

In the general case, that is potentially every architecture. Every architecture has cases where reading concurrently with a write will result in garbage. However, almost every architecture also has exceptions to this rule.

It is common that word-sized variables are read and written atomically, so synchronization is not needed when reading or writing. The proper value will be written atomically as a single operation, and threads will read the current value as a single atomic operation as well, even if another thread is writing. So for integers, you're safe on most architectures. Some will extend this guarantee to a few other sizes as well, but that's obviously hardware-dependant.

For non-word-sized variables both reading and writing will typically be non-atomic, and will have to be synchronized by other means.

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If you don't use prevous value of this variable when write new, then:

  You can read and write integer variable without using mutex. It is because integer is base type in 32bit architecture and every modification/read of value is doing with one operation.

But, if you donig something such as increment:


  Then you need use mutex, because this construction is expanded to myvar = myvar + 1 and between read myvar and increment myvar, myvar can be modified. In that case you will get bad value.

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While it would probably be safe to read ints on 32 bit systems without synchronization. I would not risk it. While multiple concurrent reads are not a problem, I do not like writes to happen at the same time as reads.

I would recommend placing the reads in the Critical Section too and then stress test your application on multiple cores to see if this is causing too much contention. Finding concurrency bugs is a nightmare I prefer to avoid. What happens if in the future some one decides to change the int to a long long or a double, so they can hold larger numbers?

If you have a nice thread library like boost.thread or zthread then you should have read/writer locks. These would be ideal for your situation as they allow multiple reads while protecting writes.

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This may happen on 8 bit systems which use 16 bit integers.

If you want to avoid locking you can under suitable circumstances get away with reading multiple times, until you get two equal consecutive values. For example, I've used this approach to read the 64 bit clock on a 32 bit embedded target, where the clock tick was implemented as an interrupt routine. In that case reading three times suffices, because the clock can only tick once in the short time the reading routine runs.

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Both reading / writing to variables with concurrency must be protected by a critical section (not mutex). Unless you want to waste your whole day debugging.

Critical sections are platform-specific, I believe. On Win32, critical section is very efficient: when no interlocking occur, entering critical section is almost free and does not affect overall performance. When interlocking occur, it is still more efficient, than mutex, because it implements a series of checks before suspending the thread.

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In general, each machine instruction goes thru several hardware stages when executing. As most current CPUs are multi-core or hyper-threaded, that means that reading a variable may start it moving thru the instruction pipeline, but it doesn't stop another CPU core or hyper-thread from concurrently executing a store instruction to the same address. The two concurrently executing instructions, read and store, might "cross paths", meaning that the read will receive the old value just before the new value is stored.
To resume: you do need the mutex for both read and writes.

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If a variable is marked with the volatile keyword then the read/write becomes atomic but this has many, many other implications in terms of what the compiler does and how it behaves and shouldn't just be used for this purpose.

Read up on what volatile does before you blindly start using it: http://msdn.microsoft.com/en-us/library/12a04hfd(VS.80).aspx

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volatile doesn't mean "atomic". It's compiler dependant what volatile really means, today most compilers treat it as "don't do clever optimization tricks to this variable" –  nos Aug 29 '09 at 10:29
The standard specifies 'volatile' as meaning that the variable may change or be accessed out of the thread's control, so it should never be cached in a register or similar. A variable marked volatile will always be read and written directly to main memory. However, it says nothing about synchronization. –  jalf Aug 29 '09 at 13:12
@jalf: I believe a variable marked "volatile" must be read exactly once any time the C code indicates a read, even if it would be more efficient to read the variable zero times, or more times; and written exactly once any time the code indicates a write, even if it might be more efficient to write it more (e.g. a=!b; might be most efficient as "a=0; if (!b) a=1;" but that would not be permitted if a is volatile. Is that still the current meaning? –  supercat Aug 17 '10 at 15:16

Depends on your platform. Most modern platforms offer atomic operations for integers: Windows has InterlockedIncrement, InterlockedDecrement, InterlockedCompareExchange, etc. These operations are usually supported by the underlying hardware (read: the CPU) and they are usually cheaper than using a critical section or other synchronization mechanisms.

See MSDN: InterlockedCompareExchange

I believe Linux (and modern Unix variants) support similar operations in the pthreads package but I don't claim to be an expert there.

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this does not answer the OP's question –  NomeN Aug 29 '09 at 11:12

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