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In the Boost 1.5.1 source under smart_ptr\detail\atomic_count_win32.hpp is a neat little atomic reference counter boost::detail::atomic_count.

on line 48, they do a cast I'm curious about:

class atomic_count

// ...

operator long() const
    return static_cast<long const volatile &>( value_ );

long value_;

Why is the counter value cast to a-reference-to-a-volatile-constant-long (long const volatile&)?

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What is the type of value_? –  Matt Kline Dec 3 '12 at 20:06
@slavik262: It's a regular (non-CV-qualified) long. –  ruakh Dec 3 '12 at 20:12
what strike me more are the earlier versions –  UmNyobe Dec 3 '12 at 20:16
@Paul in general for this kind of things put a link to the code. –  UmNyobe Dec 3 '12 at 20:22

2 Answers 2

up vote 5 down vote accepted

MSVC provides a now-deprecated extension on volatile variables, giving them acquire and release semantics (memory ordering guarantees, with respect to multithreaded programming.)

This cast "enables" this extension on the variable, giving it read-acquire semantics (to match any release-writes that may also occur). Again, this is, non-standard. In C++11 code you should use std::atomic<>.

They need this because boost::shared_ptr gives guarantees of correctness for shared_ptr<T> in multithreaded (shared) use; this is their implementation of a lock-free counter.

(Also, this is only half the story: while this extension may provide the needed ordering and visibility guarantees, it does not guarantee atomicity. On Win32 this is guaranteed implicitly by the platforms it runs on: aligned word-sized integer reads and writes are atomic per the platform.)

To nip it in the bud before it starts: without this extension volatile is not useful for multithreaded programming. Don't even try. This extension is deprecated, so you should really avoid it if you can.

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On x86 platforms, for aligned values of native width, this is known to be sufficient.

The problem they're trying to avoid is this:

  1. The variable has the hex value 0000FFFF.

  2. Thread A starts to read the value and gets the 0000xxxx part.

  3. Thread B increments the value from 0000FFFF to 00010000.

  4. Thread A finishes reading the value, getting the xxxx0000 part that it hadn't read yet.

  5. Thread A has now read a value of 00000000!

This is called word tearing. However, it is known that this doesn't happen for aligned types of native width on x86. So a mere cast through volatile (which is known to avoid problematic compiler optimizations) is all that is needed.

Note that this is not some general truth. This just happens to be a property of the platform. This isn't portable code.

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i have to admit one thing dave, I dont understand "sufficient." –  UmNyobe Dec 3 '12 at 20:18
I mean that it is known that nothing more aggressive (such as inline assembly or a compiler intrinsic) is needed. (I updated the answer with some details.) –  David Schwartz Dec 3 '12 at 20:22
Atomicity is only half the requirements, you also need to address ordering and visibility. For that you either need implicit guarantees from the platform (like x86 being a strongly-ordered platform) or memory fences, which MSVC provides on volatile as an extension, hence the cast. By the way, your answer is confusing (which UmNyobe is alluding to) because you say "sufficient" and "all that is needed" without ever stating the goal ("atomicity"). –  GManNickG Dec 3 '12 at 20:45
+1 for the explanation of word tearing –  PaulH Dec 3 '12 at 20:54

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