In probing the conditions of this question, a problem arose, exemplified by the code below.

#include <iostream>
#include <thread>
#include <chrono>
#include <stdexcept>
#include <cxxabi.h>

using namespace std;

// mocking external library call stuck in a strictly user-land infinite loop
int buggy_function_simulation()
    // cout << "In buggy function" << endl; // (1)
    int counter = 0;
    while (true)
        if ( ++counter == 1000000 ) { counter = 0; }
    return 0;

int main(int argc, char **argv) {
    cout << "Hello, world!" << endl;

    auto lambda = []() {
        pthread_setcanceltype( PTHREAD_CANCEL_ASYNCHRONOUS, nullptr );
        // cout << "ID: "<<pthread_self() <<endl; // (2)
            cout << "ID: "<<pthread_self() <<endl; // (3)
        catch ( abi::__forced_unwind& )
            cout << "thread cancelled!" << endl; // (4)

    std::thread th(lambda);

    pthread_t id = th.native_handle();
    cout << id << endl;

    cout << "cancelling ID: "<< id << endl;


    cout << "cancelled: "<< id << endl;

    return 0;

Compiling and running results in an abort:

$ g++ -g -Og -std=c++11 -pthread -o test test.cpp -lpthread
$ ./test
Hello, world!
ID: 139841296869120
cancelling ID: 139841296869120
terminate called without an active exception
Aborted (core dumped)

Note that the diagnostic output (4) does not appear.

If I comment out (3) and uncomment (2), the result is:

$ ./test
Hello, world!
ID: 139933357348608
cancelling ID: 139933357348608
cancelled: 139933357348608

Again, the output at (4) does not appear (why?), but the abort has been obviated.

If, alternately, I retain (3), leave (2) commented out, and uncomment (1), the result is finally as expected:

$ ./test
Hello, world!
ID: 139998901511936
In buggy function
cancelling ID: 139998901511936
thread cancelled!
cancelled: 139998901511936

So, the questions are:

  • what is the reason for the "terminate called without an active exception" abort in the first case?
  • why is the catch block not activated in the second case?
  • why did uncommenting (1) in the third case make such a difference?

For completeness, here is the stack trace from gdb for the first case:

Program terminated with signal SIGABRT, Aborted.
#0  __GI_raise (sig=sig@entry=6) at ../sysdeps/unix/sysv/linux/raise.c:51
51      ../sysdeps/unix/sysv/linux/raise.c: No such file or directory.
[Current thread is 1 (Thread 0x7f5d9b49a700 (LWP 12130))]
(gdb) where
#0  __GI_raise (sig=sig@entry=6) at ../sysdeps/unix/sysv/linux/raise.c:51
#1  0x00007f5d9b879801 in __GI_abort () at abort.c:79
#2  0x00007f5d9bece957 in ?? () from /usr/lib/x86_64-linux-gnu/libstdc++.so.6
#3  0x00007f5d9bed4ab6 in ?? () from /usr/lib/x86_64-linux-gnu/libstdc++.so.6
#4  0x00007f5d9bed4af1 in std::terminate() () from /usr/lib/x86_64-linux-gnu/libstdc++.so.6
#5  0x00007f5d9bed44ba in __gxx_personality_v0 () from /usr/lib/x86_64-linux-gnu/libstdc++.so.6
#6  0x00007f5d9bc3a708 in ?? () from /lib/x86_64-linux-gnu/libgcc_s.so.1
#7  0x00007f5d9bc3acfc in _Unwind_ForcedUnwind () from /lib/x86_64-linux-gnu/libgcc_s.so.1
#8  0x00007f5d9c1dbf10 in __GI___pthread_unwind (buf=<optimized out>) at unwind.c:121
#9  0x00007f5d9c1d0d42 in __do_cancel () at ./pthreadP.h:297
#10 sigcancel_handler (sig=<optimized out>, si=0x7f5d9b499bb0, ctx=<optimized out>) at nptl-init.c:215
#11 <signal handler called>
#12 buggy_function_simulation () at test.cpp:15
#13 0x0000558865838227 in <lambda()>::operator() (__closure=<optimized out>) at test.cpp:29
#14 std::__invoke_impl<void, main(int, char**)::<lambda()> > (__f=...) at /usr/include/c++/7/bits/invoke.h:60
#15 std::__invoke<main(int, char**)::<lambda()> > (__fn=...) at /usr/include/c++/7/bits/invoke.h:95
#16 std::thread::_Invoker<std::tuple<main(int, char**)::<lambda()> > >::_M_invoke<0> (this=<optimized out>)
    at /usr/include/c++/7/thread:234
#17 std::thread::_Invoker<std::tuple<main(int, char**)::<lambda()> > >::operator() (this=<optimized out>)
    at /usr/include/c++/7/thread:243
#18 std::thread::_State_impl<std::thread::_Invoker<std::tuple<main(int, char**)::<lambda()> > > >::_M_run(void) (
    this=<optimized out>) at /usr/include/c++/7/thread:186
#19 0x00007f5d9beff66f in ?? () from /usr/lib/x86_64-linux-gnu/libstdc++.so.6
#20 0x00007f5d9c1d26db in start_thread (arg=0x7f5d9b49a700) at pthread_create.c:463
#21 0x00007f5d9b95a88f in clone () at ../sysdeps/unix/sysv/linux/x86_64/clone.S:95
  • 1
    Maybe the reason is that the function invoked by std::thread must not terminate with an (uncaught) exception? – j6t Nov 28 '19 at 7:55
  • The reported error apparently says the opposite, that throw() was called without an (active) exception to throw - which caused std::terminate() to be invoked instead. The implementation of pthread_cancel() in Linux involves throwing an exception of type abi::__forced_unwind, which must not be swallowed in a catch block. – arayq2 Nov 28 '19 at 8:28
  • it looks like even with PTHREAD_CANCEL_ASYNCHRONOUS your thread needs a cancelation point – Alexander Nov 28 '19 at 8:41
  • The point is what to do when a cancellation point is not available. The use case is a thread stuck in a third-party computational library - an infinite loop due to a terminating threshold condition not being met, with no external calls - that needs to be killed off. – arayq2 Nov 29 '19 at 8:00
  • 1
    @TedLyngmo: Diverge was too strong a term for me to use. I really meant non-converging, implying an infinite execution. I would expect any decent numerical method library to detect overflow or underflow. – jxh Dec 3 '19 at 23:46

That message can be triggered if you throw from inside a function marked noexcept. All destructors are implicitly noexcept, so if the thread is running a destructor when the exception triggered by pthread_cancel is thrown, your program will terminate and you will get that message.

operator<< for std::cout is a formatted output operation, which constructs a sentry object, which is destructed on exit (see https://en.cppreference.com/w/cpp/named_req/FormattedOutputFunction). If the cancel comes while the destructor of the sentry object is being processed, this will thus terminate your application.

Do not use PTHREAD_CANCEL_ASYNCHRONOUS in C++. Even using pthread_cancel at all can be problematic due to the automatic rethrow from catch clauses.


pthread_cancel is a POSIX C function, intended to work with C code. It has two modes of operation: synchronous and asynchronous.

Synchronous use of pthread_cancel sets an internal flag on the target thread which is then check in certain functions marked as cancellation points in the POSIX documentation. If any of those functions are called by the target thread, then cancellation is triggered. On Linux this is done by raising a special exception using the C++ exception mechanism that cannot be caught and discarded. This triggers stack unwinding, calls C++ destructors, and runs code registered with pthread_cleanup_push. This is compatible with normal C++ code, assuming nothing tries to catch and discard the exception. If all catch blocks rethrow, then everything works as expected. If the cancellation starts inside a function marked noexcept (such as a destructor, which is noexcept by default), then the program will terminate.

Asynchronous use of pthread_cancel is different. This sends a special signal to the target thread which interrupts it at any arbitrary point and starts the stack unwinding process described above. This is much more dangerous, as the code may be in the middle of evaluating any arbitrary expression, so the state of the application's data is much less well defined.

If you use asynchronous cancellation with code that has been designed to support it, then this can be OK. It may be possible to make code async-cancel-safe through careful use of pthread_setcancelstate to disabled cancellation in specific regions, and use of pthread_cleanup_push to register cancellation cleanup handlers, but this cannot be done in all cases.

With synchronous cancellation, if a function declared noexcept does not call any cancellation point functions, then all is well. With asynchronous cancellation, all code is a potential cancellation point, so before entering any code that is marked noexcept, you must call pthread_setcancelstate to temporarily disable cancellation, otherwise if the cancellation signal is received while that function is running then terminate will be called due to the cancellation exception. As noted above, this includes all destructors which are not explicitly marked noexcept(false).

Consequently, any call to arbitrary C++ library code (which may therefore construct C++ objects with destructors) is a potential hazard when using asynchronous cancellation, and you must call pthread_setcancelstate to disable cancellation around any block of code which creates C++ objects with destructors, and/or calls into C++ library code out of your control (such as standard library functions).

| improve this answer | |
  • Are you saying there is no way to kill off a worker thread stuck in an infinite loop (e.g. an iterative "solver" routine, such as a bond yield calculation, unable for whatever reason to reach a terminating threshold condition without ever going through a cancellation point) without killing the entire program? – arayq2 Nov 28 '19 at 9:17
  • No, I am saying that you need to design your code to support cooperative cancellation rather than using pthread_cancel. C++20 adds std::stop_source and std::stop_token which can be used for this purpose, but you can do it yourself. The simplest method is to use std::atomic<bool> stop_requested, which is then checked in your loop. – Anthony Williams Nov 28 '19 at 9:21
  • The thread is stuck in an external library which we have no control over. Cancelling/killing threads running wayward third-party code is a very common real-life occurrence for which the standard bromide seems to be "design your code better!". If only we could. – arayq2 Nov 28 '19 at 9:25
  • If the code is designed to work with pthread_cancel, feel free to use it. Otherwise things won't work as expected anyway: globals will be left in an unspecified state, memory might be leaked, mutex locks unreleased, etc. – Anthony Williams Nov 28 '19 at 9:28
  • 2
    You could create a new process using a system call and then communicate with it using message passing instead of shared memory. That way you can kill it (almost) whenever you like and there is very little risk that doing so will affect your main process. – andrew.punnett Dec 5 '19 at 23:59

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.