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I have a multi-threaded application, which heavily uses std::cout for logging without any locking. In such a case, how to easily add lock mechanism to make std::cout thread-safe?

I don't want to search for each occurrence of std::cout and add a line of locking code. That is too tedious.

Any better practice?

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This was actually one of the topics discussed and given an example for in this video. The usage of it comes at about 48 minutes in, and the implementation is a while before that, as there's an example for strings before it. –  chris Feb 5 '13 at 22:23
std::cout is already thread-safe. Do you mean you want the actual chunks of text to be serialized per flush? –  GManNickG Feb 5 '13 at 22:38
@GManNickG, really? Which page of the C++ standard provides that? –  xmllmx Feb 5 '13 at 22:39
See here, for example. –  GManNickG Feb 5 '13 at 22:46
Section 27.4.1: Concurrent access to a synchronized ( standard iostream object’s formatted and unformatted in- put ( and output ( functions or a standard C stream by multiple threads shall not result in a data race (1.10). –  John Schug Feb 5 '13 at 22:48

3 Answers 3

up vote 7 down vote accepted

I guess you could implement your own class which wraps cout and associates a mutex with it. The operator << of that new class would do three things:

  1. create a lock for the mutex, possibly blocking other threads
  2. do the output, i.e. do the operator << for the wrapped stream and the passed argument
  3. construct an instance of a different class, passing the lock to that

This different class would keep the lock and delegate operator << to the wrapped stream. The destructor of that second class would eventually destroy the lock and release the mutex.

So any output you write as a single statement, i.e. as a single sequence of << invocations, will be printed atomically as long as all your output goes through that object with the same mutex.

Let's call the two classes synchronized_ostream and locked_ostream. If sync_cout is an instance of synchronized_ostream which wraps std::cout, then the sequence

sync_cout << "Hello, " << name << "!" << std::endl;

would result in the following actions:

  1. synchronized_ostream::operator<< would aquire the lock
  2. synchronized_ostream::operator<< would delegate the printing of "Hello, " to cout
  3. operator<<(std::ostream&, const char*) would print "Hello, "
  4. synchronized_ostream::operator<< would construct a locked_ostream and pass the lock to that
  5. locked_ostream::operator<< would delegate the printing of name to cout
  6. operator<<(std::ostream&, std::string) would print the name
  7. The same delegation to cout happens for the exclamation point and the endline manipulator
  8. The locked_ostream temporary gets destructed, the lock is released
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This can be simplified a bit. Firstly, if any code doesn't play by the rules, it can still mess with cout, which means you must change any occurrence of cout. In that case, you can also replace it with (cout_lock(), cout), where cout_lock() is a scoped lock type specifically for syncing access to cout. This will create a temporary object living until the next line, while the result of the expression (A, B) is B due to the comma operator. I'd claim that this is less code, and you still can lock the mutex for more than a line, if you want. –  Ulrich Eckhardt Feb 6 '13 at 21:51
@doomster: explicitely maintaining a locked_ostream for more than a single expression would be possible with my setup as well, but your aproach is interesting as well. It does appear to be asking for a macro, though, which is a rather un-C++-ish way to deal with issues. Otherwise, always coding the lock will become tedious. –  MvG Feb 6 '13 at 21:58

A feasible solution uses a line-buffer for each thread. You might get interleaved lines, but not interleaved characters. If you attach that to thread-local storage, you also avoid lock contention issues. Then, when a line is full (or on flush, if you want), you write it to stdout. This last operation of course has to use a lock. You stuff all this into a streambuffer, which you put between std::cout and it's original streambuffer.

The problem this doesn't solve is things like format flags (e.g. hex/dec/oct for numbers), which can sometimes percolate between threads, because they are attached to the stream. It's nothing bad, assuming you're only logging and not using it for important data. It helps to just not format things specially. If you need hex output for certain numbers, try this:

std::string hex(integer_type v)
    /* Notes:
    1. using showbase would still not show the 0x for a zero
    2. using (v + 0) will converts an  unsigned char to a type
       that is recognized as integer instead of as character */
    std::stringstream s;
    s << "0x" << std::setfill('0') << std::hex
        << std::setw(2 * sizeof v) << (v + 0);
    return s.str();

Similar approaches work for other formats as well.

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While i cant be sure this applies to every compiler / version of std libs but in the code-base im using std::cout::operator<<() it is already thread-safe.

Im assuming that what your really trying to do it stop std::cout from mixing string when concatenating with the operator<< multiple time per string, across multiple threads.

The reason strings get garbled is because there is a "External" race on the operator<< this can lead to things like this happening.

//Thread 1
std::cout << "the quick brown fox " << "jumped over the lazy dog " << std::endl;

//Thread 2
std::cout << "my mother washes" << " seashells by the sea shore" << std::endl;

//Could just as easily print like this or any other crazy order.
my mother washes the quick brown fox seashells by the sea sure \n
jumped of the lazy dog \n

If that's the case there is a much simpler answer than making your own thread safe cout or implementing a lock to use with cout.

Simply compose your string before you pass it to cout

For example.

//There are other ways, but stringstream uses << just like cout.. 
std::stringstream msg;
msg << "Error:" << Err_num << ", " << ErrorString( Err_num ) << "\n"; 
std::cout << msg.str();

This way your stings cant be garbled because they are already fully formed, plus its also a better practice to fully form your strings anyway before dispatching them.

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