I have a multi-threaded application, which heavily uses std::cout for logging without any locking. In such a case, how can I 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?

  • 8
    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, 2013 at 22:23
  • 2
    std::cout is already thread-safe. Do you mean you want the actual chunks of text to be serialized per flush?
    – GManNickG
    Feb 5, 2013 at 22:38
  • 8
    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, 2013 at 22:48
  • 5
    However, the standard says: "[ Note: Users must still synchronize concurrent use of these objects and streams by multiple threads if they wish to avoid interleaved characters. — end note ]"
    – xmllmx
    Feb 5, 2013 at 22:49
  • 5
    @xmllmx: Which goes back to what I said: it's already thread-safe, do you want to further serialize the display of characters per-flush?
    – GManNickG
    Feb 5, 2013 at 22:55

11 Answers 11


While I can't be sure this applies to every compiler / version of std libs but in the code-base I'm using std::cout::operator<<() it is already thread-safe.

I'm assuming that what you're 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 shore \n
jumped over 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 can't be garbled because they are already fully formed, plus its also a better practice to fully form your strings anyway before dispatching them.

  • 7
    I think it's important to note that you're referring just to a specific implementation. Which one, and where does it guarantee thread-safety? I haven't looked myself yet, but I doubt that any recent C++ standard guarantees operator<<(std::ostream&, const std::string&) to be atomic. If there are no guarantees, then the implementation might still write the string out in chunks on some implementations, interleaving data from different threads.
    – MvG
    Mar 10, 2016 at 13:11
  • 2
    it's garanteed for std::cout (not std::ofstream in general). Jul 26, 2016 at 1:14
  • 4
    It's worse than that. I'm using Xcode (on OS X) and seeing character-by-character interleaving, making messages nearly unreadable. A mutex-protected wrapper for cout is probably the best way to go. Aug 19, 2016 at 6:27

Since C++20, you can use std::osyncstream wrapper:


  std::osyncstream bout(std::cout); // synchronized wrapper for std::cout
  bout << "Hello, ";
  bout << "World!";
  bout << std::endl; // flush is noted, but not yet performed
  bout << "and more!\n";
} // characters are transferred and std::cout is flushed

It provides the guarantee that all output made to the same final destination buffer (std::cout in the examples above) will be free of data races and will not be interleaved or garbled in any way, as long as every write to the that final destination buffer is made through (possibly different) instances of std::basic_osyncstream.

Alternatively, you can use a temporary:

std::osyncstream(std::cout) << "Hello, " << "World!" << '\n';
  • I don't think those options are available to me, I'm using Qt Creator version 4.13.2, based on Qt 5.15.1 Clang 11.0 Apple 64 bit. I don't see the header.
    – SPlatten
    Oct 14, 2020 at 17:44
  • Do I need to declare std::osyncstream bout(std::cout) only once for all cpp files or it is fine to declare it again in each cpp?
    – gil123
    Jan 7, 2021 at 16:57
  • 1
    I'm getting fatal error: syncstream: No such file or directory, is there a way to get the header file?
    – harry
    Feb 16, 2021 at 11:06
  • 2
    @csisy No. That just means that it won't be UB to use std::cout from multiple threads. You can still get the "wrong" output. E.g. if thread A does std::cout << "A: " << 0 << " "; and thread B does std::cout << "B: " << 1 << " "; you can get output like A: B: 0 1. That's "safe" but also probably not what you want. But replacing std::cout with std::osyncstream(std::cout) in both guarantees you get either A: 0 B: 1 or B: 1 A: 0.
    – HTNW
    Sep 6, 2021 at 17:57
  • 1
    @lilezek You generally do not want an osyncstream per thread. You want an osyncstream per logical message that should not be interrupted by another thread's text.
    – HTNW
    Sep 6, 2021 at 18:00

Note: This answer is pre-C++20 so it does not use std::osyncstream with its separate buffering, but uses a lock instead.

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
  • 2
    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. Feb 6, 2013 at 21:51
  • 1
    @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, 2013 at 21:58
  • 2
    @MvG: He's not using a macro, he's using the comma operator. Regardless, this can be simplified. Replace cout with an object that buffers until it receives a '\n', and then locks, dumps the entire buffer to cout, and unlocks, all at once. Jul 13, 2017 at 1:01
  • 1
    @MooingDuck: I was mentioning macro because the same pattern (the one with the comma in it) would be repeated all over the place. The buffer then flush whole lines approach makes sense if single line atomicity is all you need, but e.g. a multi-line stack trace interleaved with other stuff can be quite confusing, so that's not always the best approach.
    – MvG
    Jul 13, 2017 at 2:14
  • 1
    @MvG As you know, C++20 brings osyncstream which is similar to your synchronized_ostream wrapper. Would you mind updating your answer to reflect that?
    – L. F.
    Mar 25, 2019 at 12:58

I really like the trick from Nicolás given in this question of creating a temporary object and putting the protection code on the destructor.

/** Thread safe cout class
  * Exemple of use:
  *    PrintThread{} << "Hello world!" << std::endl;
class PrintThread: public std::ostringstream
    PrintThread() = default;

        std::lock_guard<std::mutex> guard(_mutexPrint);
        std::cout << this->str();

    static std::mutex _mutexPrint;

std::mutex PrintThread::_mutexPrint{};

You can then use it as a regular std::cout, from any thread:

PrintThread{} << "my_val=" << val << std::endl;

The object collect data as a regular ostringstream. As soon the coma is reached, the object is destroyed and flush all collected information.

  • I wonder if you could do class PrintThreadType {}; PrintThreadType& getPrintThread() {static PrintThreadType a; return a;} PrintThreadType& PrintThread = getPrintThread(); in a header to sidestep odr? Probably doesn't work. Jul 13, 2017 at 1:06
  • 3
    You gotta be careful with this idea. Destructors in C++ should not be allowed to throw exceptions. By default, in C++11 (and, I presume, beyond), if an exception propagates out of a destructor, it will call std::terminate. Nov 6, 2017 at 0:30
  • What does this last line do? std::mutex PrintThread::_mutexPrint{};
    – Ari
    May 28, 2020 at 16:59
  • @Ari, _mutexPrint is a static variable (common to all instance of PrintThread) (See: en.cppreference.com/w/cpp/language/static), the {} is just one of the many syntax to initialise an object (since C++11) (See: en.cppreference.com/w/cpp/language/value_initialization). So the last line initialise the static variable once. May 28, 2020 at 21:51
  • 2
    @KefSchecter, if this is really an issue in practice, I guess one could try to wrap the destructor code in some try {} catch(...) {} to silent the error instead of terminating. But this is indeed a limitation of this method. Aug 6, 2020 at 8:41

Along the lines of the answer suggested by Conchylicultor, but without inheriting from std::ostringstream:

EDIT: Fixed return type for the overloaded operator and added overload for std::endl.

EDIT 1: I have extended this into a simple header-only library for logging / debugging multi-threaded programs.

#include <iostream>
#include <mutex>
#include <thread>
#include <vector>    
#include <chrono>

static std::mutex mtx_cout;

// Asynchronous output
struct acout
        std::unique_lock<std::mutex> lk;


        template<typename T>
        acout& operator<<(const T& _t)
            std::cout << _t;
            return *this;

        acout& operator<<(std::ostream& (*fp)(std::ostream&))
            std::cout << fp;
            return *this;

int main(void)

    std::vector<std::thread> workers_cout;
    std::vector<std::thread> workers_acout;

    size_t worker(0);
    size_t threads(5);

    std::cout << "With std::cout:" << std::endl;

    for (size_t i = 0; i < threads; ++i)
            std::cout << "\tThis is worker " << ++worker << " in thread "
                      << std::this_thread::get_id() << std::endl;
    for (auto& w : workers_cout)

    worker = 0;


    std::cout << "\nWith acout():" << std::endl;

    for (size_t i = 0; i < threads; ++i)
            acout() << "\tThis is worker " << ++worker << " in thread "
                    << std::this_thread::get_id() << std::endl;
    for (auto& w : workers_acout)

    return 0;


With std::cout:
        This is worker 1 in thread 139911511856896
        This is worker  This is worker 3 in thread 139911495071488
        This is worker 4 in thread 139911486678784
2 in thread     This is worker 5 in thread 139911503464192139911478286080

With acout():
        This is worker 1 in thread 139911478286080
        This is worker 2 in thread 139911486678784
        This is worker 3 in thread 139911495071488
        This is worker 4 in thread 139911503464192
        This is worker 5 in thread 139911511856896
  • 2
    @vallismortis Done. I hope you find it useful.
    – cantordust
    Nov 14, 2018 at 23:42

For fast debugging c++11 applications and avoid interleaved output I just write small functions like these:

#include <mutex>
mutex m_screen;
void msg(char const * const message);
void msg(char const * const message)
  cout << message << endl;

I use these types of functions for outputs and if numeric values are needed I just use something like this:

void msgInt(char const * const message, int const &value);
void msgInt(char const * const message, int const &value)
  cout << message << " = " << value << endl;

This is easy and works fine to me, but I don't really know if it is technically correct. So I would be glad to hear your opinions.

Well, I didn't read this:

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

I'm sorry. However I hope it helps somebody.

  • 8
    This code isn't safe, because cout can throw an exception and then your mutex never gets unlocked. You should use std::lock_guard with the mutex to ensure the mutex will get released no matter what when you're done with it. Nov 6, 2017 at 5:26

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 its original streambuffer (a.k.a. Decorator Pattern).

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:

template<typename integer_type>
std::string hex(integer_type v)
    /* Notes:
    1. using showbase would still not show the 0x for a zero
    2. using (v + 0) 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.

  • Aren't the contents of lines written to a common buffer first? If so, the line-buffered print is not thread-safe at all!
    – duleshi
    Oct 26, 2015 at 6:52
  • I'm not sure what you mean, as I said on the first level, each thread has its own buffer, so there's no common buffer. On the second level, there is indeed a common buffer, but that buffer "has to use a lock" as I wrote above. Both is thread-safe to me. Oct 26, 2015 at 6:56
  • Sorry for not reading through. My habit is to read the first few sentences and look at the code samples, and I didn't find any locks there. I tend to treat the beginning or ending as a summary. And I think answers fit for a quick glance is really great.
    – duleshi
    Oct 26, 2015 at 7:13
  • @UlrichEckhardt Is template <integer_type> what you mean? The code is valid as is, but it doesn't make much sense ;)
    – L. F.
    Feb 11, 2019 at 9:58

I know its an old question, but it helped me a lot with my problem. I created an utility class based on this post answers and I'd like to share my result.

Considering we use C++11 or latter C++ versions, this class provides print and println functions to compose strings before calling the standard output stream and avoid concurrency problems. These are variadic functions which use templates to print different data types.

You can check its use in a producer-consumer problem on my github: https://github.com/eloiluiz/threadsBar

So, here is my code:

class Console {
    Console() = default;

    inline static void innerPrint(std::ostream &stream) {}

    template<typename Head, typename... Tail>
    inline static void innerPrint(std::ostream &stream, Head const head, Tail const ...tail) {
        stream << head;
        innerPrint(stream, tail...);

    template<typename Head, typename... Tail>
    inline static void print(Head const head, Tail const ...tail) {
        // Create a stream buffer
        std::stringbuf buffer;
        std::ostream stream(&buffer);
        // Feed input parameters to the stream object
        innerPrint(stream, head, tail...);
        // Print into console and flush
        std::cout << buffer.str();

    template<typename Head, typename... Tail>
    inline static void println(Head const head, Tail const ...tail) {
        print(head, tail..., "\n");

This is how I manage thread safe operations on std::cout using a custom enum and macros:

enum SynchronisedOutput { IO_Lock, IO_Unlock };

inline std::ostream & operator<<(std::ostream & os, SynchronisedOutput so) {
  static std::mutex mutex;

  if (IO_Lock == so) mutex.lock();
  else if (IO_Unlock == so)

  return os;

#define sync_os(Os) (Os) << IO_Lock
#define sync_cout sync_os(std::cout)
#define sync_endl '\n' << IO_Unlock

This allow me to write things like:

sync_cout << "Hello, " << name << '!' << sync_endl;

in threads without racing issues.


I had a similar problem to yours. You can use the following class. This only supports outputting to std::cout, but if you need a general one let me know. In the code below, tsprint creates an inline temporary object of the class ThreadSafePrinter. If you want, you can change tsprint to cout if you have used cout instead of std::cout, so you won't have to replace any instances of cout but I do not recommend such a practice in general. It is much better to use a special output symbol for such debug lines starting from the beginning of the project anyway.

I like this solution as well: 1. In my solution all threads can continue inserting into their corresponding thread_local stringstream static-objects and then lock the mutex only when it is required to flush which is triggered in the destructor. This is expected to improve the efficiency by shortening the duration during which the mutex-lock is held. Maybe I can include a mechanism similar to the sync_endl solution mentioned in 1.

class ThreadSafePrinter
    static mutex m;
    static thread_local stringstream ss;
    ThreadSafePrinter() = default;
        lock_guard  lg(m);
        std::cout << ss.str();

    template<typename T>
    ThreadSafePrinter& operator << (const T& c)
        ss << c;
        return *this;

    // this is the type of std::cout
    typedef std::basic_ostream<char, std::char_traits<char> > CoutType;

    // this is the function signature of std::endl
    typedef CoutType& (*StandardEndLine)(CoutType&);

    // define an operator<< to take in std::endl
    ThreadSafePrinter& operator<<(StandardEndLine manip)
        return *this;
mutex ThreadSafePrinter::m;
thread_local stringstream ThreadSafePrinter::ss;
#define tsprint ThreadSafePrinter()

void main()
    tsprint << "asd ";
    tsprint << "dfg";
  • While the answer offers a workaround it is technically not a solution to the question. Considering the purpose of the proposed method, it should be clarified that the static and thread_local members must not be instantiated in the header file that defines the proposed class. (See stackoverflow.com/a/18861043/3434933) Nov 8, 2021 at 14:29
  • @PierreSchroeder Thank you for the feedback! Regarding your first point: yes this is a workaround like others' solutions on this page. To address the second part, I just copy-pasted the code from my main file (note that just below the class there is a main call), so it works in a single file. I assume anyone asking this type of advanced question would be able to know that they should not place the static object definitions inside header files. Of course, t does not mean that my assumption holds in general. Another point: my solutions keeps the lock shorter using the thread-local stringstream.
    – Eddie
    Nov 9, 2021 at 8:24

In addition to synchronisation this solution provides information about the thread from which the log was written.

DISCLAIMER: It's quite a naive way of syncing the logs, however it might be applicable for some small use cases for debugging.

thread_local int thread_id = -1;
std::atomic<int> thread_count;

struct CurrentThread {

  static void init() {
    if (thread_id == -1) {
      thread_id = thread_count++;

  friend std::ostream &operator<<(std::ostream &os, const CurrentThread &t) {
    os << "[Thread-" << thread_id << "] - ";
    return os;

CurrentThread current_thread;
std::mutex io_lock;
#ifdef DEBUG
#define LOG(x) {CurrentThread::init(); std::unique_lock<std::mutex> lk(io_lock); cout << current_thread << x << endl;}
#define LOG(x)

This can be used like this.

LOG(cout << "Waiting for some event");

And it will give log output

[Thread-1] - Entering critical section 
[Thread-2] - Waiting on mutex
[Thread-1] - Leaving critical section, unlocking the mutex

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