src/third_party/llvm-project/lldb/packages/Python/lldbsuite/test/functionalities/thread/break_after_join/main.cpp - cobalt - Git at Google

 //===-- main.cpp ------------------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 // This test is intended to create a situation in which one thread will exit
 // while a breakpoint is being handled in another thread.  This may not always
 // happen because it's possible that the exiting thread will exit before the
 // breakpoint is hit.  The test case should be flexible enough to treat that
 // as success.

 #include "pseudo_barrier.h"
 #include <chrono>
 #include <thread>

 volatile int g_test = 0;

 // A barrier to synchronize all the threads.
 pseudo_barrier_t g_barrier1;

 // A barrier to keep the threads from exiting until after the breakpoint has
 // been passed.
 pseudo_barrier_t g_barrier2;

 void *
 break_thread_func ()
 {
     // Wait until all the threads are running
     pseudo_barrier_wait(g_barrier1);

     // Wait for the join thread to join
     std::this_thread::sleep_for(std::chrono::microseconds(50));

     // Do something
     g_test++;       // Set breakpoint here

     // Synchronize after the breakpoint
     pseudo_barrier_wait(g_barrier2);

     // Return
     return NULL;
 }

 void *
 wait_thread_func ()
 {
     // Wait until the entire first group of threads is running
     pseudo_barrier_wait(g_barrier1);

     // Wait until the breakpoint has been passed
     pseudo_barrier_wait(g_barrier2);

     // Return
     return NULL;
 }

 void *
 join_thread_func (void *input)
 {
     std::thread *thread_to_join = (std::thread *)input;

     // Sync up with the rest of the threads.
     pseudo_barrier_wait(g_barrier1);

     // Join the other thread
     thread_to_join->join();

     // Return
     return NULL;
 }

 int main ()
 {
     // The first barrier waits for the non-joining threads to start.
     // This thread will also participate in that barrier.
     // The idea here is to guarantee that the joining thread will be
     // last in the internal list maintained by the debugger.
     pseudo_barrier_init(g_barrier1, 5);

     // The second barrier keeps the waiting threads around until the breakpoint
     // has been passed.
     pseudo_barrier_init(g_barrier2, 4);

     // Create a thread to hit the breakpoint
     std::thread thread_1(break_thread_func);

     // Create more threads to slow the debugger down during processing.
     std::thread thread_2(wait_thread_func);
     std::thread thread_3(wait_thread_func);
     std::thread thread_4(wait_thread_func);

     // Create a thread to join the breakpoint thread
     std::thread thread_5(join_thread_func, &thread_1);

     // Wait for the threads to finish
     thread_5.join();  // implies thread_1 is already finished
     thread_4.join();
     thread_3.join();
     thread_2.join();

     return 0;
 }
	//===-- main.cpp ------------------------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	// This test is intended to create a situation in which one thread will exit
	// while a breakpoint is being handled in another thread. This may not always
	// happen because it's possible that the exiting thread will exit before the
	// breakpoint is hit. The test case should be flexible enough to treat that
	// as success.

	#include "pseudo_barrier.h"
	#include <chrono>
	#include <thread>

	volatile int g_test = 0;

	// A barrier to synchronize all the threads.
	pseudo_barrier_t g_barrier1;

	// A barrier to keep the threads from exiting until after the breakpoint has
	// been passed.
	pseudo_barrier_t g_barrier2;

	void *
	break_thread_func ()
	{
	// Wait until all the threads are running
	pseudo_barrier_wait(g_barrier1);

	// Wait for the join thread to join
	std::this_thread::sleep_for(std::chrono::microseconds(50));

	// Do something
	g_test++; // Set breakpoint here

	// Synchronize after the breakpoint
	pseudo_barrier_wait(g_barrier2);

	// Return
	return NULL;
	}

	void *
	wait_thread_func ()
	{
	// Wait until the entire first group of threads is running
	pseudo_barrier_wait(g_barrier1);

	// Wait until the breakpoint has been passed
	pseudo_barrier_wait(g_barrier2);

	// Return
	return NULL;
	}

	void *
	join_thread_func (void *input)
	{
	std::thread thread_to_join = (std::thread )input;

	// Sync up with the rest of the threads.
	pseudo_barrier_wait(g_barrier1);

	// Join the other thread
	thread_to_join->join();

	// Return
	return NULL;
	}

	int main ()
	{
	// The first barrier waits for the non-joining threads to start.
	// This thread will also participate in that barrier.
	// The idea here is to guarantee that the joining thread will be
	// last in the internal list maintained by the debugger.
	pseudo_barrier_init(g_barrier1, 5);

	// The second barrier keeps the waiting threads around until the breakpoint
	// has been passed.
	pseudo_barrier_init(g_barrier2, 4);

	// Create a thread to hit the breakpoint
	std::thread thread_1(break_thread_func);

	// Create more threads to slow the debugger down during processing.
	std::thread thread_2(wait_thread_func);
	std::thread thread_3(wait_thread_func);
	std::thread thread_4(wait_thread_func);

	// Create a thread to join the breakpoint thread
	std::thread thread_5(join_thread_func, &thread_1);

	// Wait for the threads to finish
	thread_5.join(); // implies thread_1 is already finished
	thread_4.join();
	thread_3.join();
	thread_2.join();

	return 0;
	}