pthread: was genau macht "joinable" und was macht "detached"?

[schorsch_76]

...
Ich vermute, viele wird es hier nicht geben, die sich mit der Materie tatsächlich auskennen und einen sicheren Beispielcode posten können, auch wenn ich es gehofft hatte...

HaWe: Ich mache das seit 20 Jahren in C++. Jeden Tag. Hier zeige ich dir die Richtung die gangbar ist, aber ich werde dir nicht dein Projekt schreiben.

[HaWe]

HaWe: Ich mache das seit 20 Jahren in C++. Jeden Tag. Hier zeige ich dir die Richtung die gangbar ist, aber ich werde dir nicht dein Projekt schreiben.

a ja, danke, aber die "Richtung" ist mir doch klar...
(gedacht war es ja für das Community Projekt RP6-Nachfolger, da wäre also Mitarbeit mit "echtem Code" auch für alle anderen sehr nützlich...)

(PS, edit: irgendwie "hinwurschteln" kann ich es ntl, die Frage ist nur, wie man es richtig und möglichst failsafe macht)

[schorsch_76]

Ich kann heut Abend ein kleines Sample schreiben

EDIT:
Das mit dem Subprozess kann sicher auch nach einem wegbrechen des ttys wieder starten. Wenn der tty einfach nicht mehr zu öffnen ist, dann wird auch das nichts werden.

Um das Arduino Protokol wieder zu syncen, muss halt das Protokoll "syncbar" sein. Der Arduino hat ja nichts davon mitbekommen.

Wie schaut denn das Protokoll aus?

[HaWe]

Ich kann heut Abend ein kleines Sample schreiben

EDIT:
Das mit dem Subprozess kann sicher auch nach einem wegbrechen des ttys wieder starten. Wenn der tty einfach nicht mehr zu öffnen ist, dann wird auch das nichts werden.

Um das Arduino Protokol wieder zu syncen, muss halt das Protokoll "syncbar" sein. Der Arduino hat ja nichts davon mitbekommen.

Wie schaut denn das Protokoll aus?

dankeschön!
das Arduino-Prog iat hier: https://www.roboternetz.de/community...l=1#post652616

- - - Aktualisiert - - -

dankeschön!
das Arduino-Prog iat hier: https://www.roboternetz.de/community...l=1#post652616

meine grobe Idee war (der heart beat ist noch nicht ausformuliert, nur der thread kill):

Code:

void* WATCHER_thr(void*)           // very high priority:  thread watcher  
{ 
   while(_TASKS_ACTIVE_) {               

    // to do: UART_HEARTBEAT auswerten!

    if (!UART_HEARTBEAT) {  // delays sind nur grobe Ideen, als yield für andere threads!
       pthread_kill(thread2, SIGKILL); // does not erase handle!
       delay(10);  // zusätzlich weitere Wartebedingung für kill?

       pthread_join(thread2, NULL);  // join, erase handle
       delay(10);

       serialClose( Serial);  // close UART, fd=Serial
       delay(10);
       Serial = serialOpen (uart, UARTclock);    // re-open Serial
       delay(1);
  
       pthread_create(&thread2, NULL, UART_thr, NULL);    // restart UART by medium   
       param.sched_priority = 40;
       pthread_setschedparam(thread2, SCHED_RR, &param); 

       delay(10);
    }
     
    delay(100);  // long yield

   }         
   return NULL;
}

// andere treads siehe Link oben!

//==================================================================
//==================================================================
 
int main() {
    
    // threads    
    pthread_t  thread0, thread1, thread2;
    struct     sched_param  param;
    
    printf("starting ..."); printf("\n");   
    
    // open UART Serial com port    
    Serial = serialOpen (uart, UARTclock);       
        

    // start multithreading  
    pthread_create(&thread0, NULL, WATCHER_thr, NULL);     // very high priority: thread watcher 
    param.sched_priority = 80;
    pthread_setschedparam(thread0, SCHED_RR, &param);
    
    pthread_create(&thread1, NULL, KBD_thr, NULL);     // low priority: keyboard monitor 
    param.sched_priority = 40;
    pthread_setschedparam(thread1, SCHED_RR, &param);
   
    pthread_create(&thread2, NULL, UART_thr, NULL);    // medium  priority: UART
    param.sched_priority = 40;
    pthread_setschedparam(thread2, SCHED_RR, &param);    
     
    
    while(_TASKS_ACTIVE_) { delay(10); }
     
    // wait for threads to join before exiting
    pthread_join(thread1, NULL);
    pthread_join(thread2, NULL);
    pthread_join(thread3, NULL);
   
    serialClose( Serial);
    exit(0);
}

[schorsch_76]

Hier ist mein fork() Sample. Es forkt und überwacht einen Subprozess. Ich habe auch einen tty_dummy für den string gebastelt der dein Protokoll nachahmt bzw. parst. Er sollte so auch wieder auf syncronisieren können (tty_dummy). Der Trick hier ist "find('\n')" und wenn der regex nicht matcht, das wegzuwerfen.

Die Funktion die im Subprozess aufgerufen wird, öffnet dann den tty und spricht mit dem Master nur über die pipes. Die tty_dummy() ist nur ein ungetestetes Skelett. Auf Arduino Seite würde ich das auch so ähnlich machen.

Das ganze wurde auf meinem Debianrechner getestet.

Das Testprogram zeigt:

Code:

./restarttest                                                                                             
Started worker: 5433
Slave got command: 14
Got data from worker 4
Slave got command: 11
Got data from worker 3
Slave got command: 11
Got data from worker 3
Slave got command: 11
Got data from worker 3
Slave got command: 11
Got data from worker 2
Slave got command: 13
worker abort
Terminate worker: 5433
Started worker: 5434
Slave got command: 12
Got data from worker 1
Slave got command: 13
Got data from worker 1
Slave got command: 16
Got data from worker 3
Slave got command: 16
Got data from worker 3
Slave got command: 16
...

Code:

/******************************************************************************
			   DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
					   Version 2, December 2004
	 

	Copyright (C) 2019 Georg Gast <georg@schorsch-tech.de>

	Everyone is permitted to copy and distribute verbatim or modified
	copies of this license document, and changing it is allowed as long
	as the name is changed.
	 

			   DO WHAT THE FUCK YOU WANT TO PUBLIC LICENSE
	  TERMS AND CONDITIONS FOR COPYING, DISTRIBUTION AND MODIFICATION

	 0. You just DO WHAT THE FUCK YOU WANT TO.
******************************************************************************/

/******************************************************************************
	Sample for Roboternetz.de:
	pthread: was genau macht "joinable" und was macht "detached"?
	https://www.roboternetz.de/community...macht-detached
	

	Compile with:
	-------------
	g++ --std=c++11 restart.cpp -o restart

	Explanation:
	------------
	This program creates a master process and forks a child process. These
	two processes are connected by pipes. Just use plain POSIX.
	

	+--------------------+
	| Master             |
	+--------------------+
	   |               ^
	   v               |
	+--------------------+
	| worker             |
	+--------------------+
	

	They exchange random integer bytes.
	

	The master sends to the child random commands. If it does not get a response
	within 100 millisec it sends SIGKILL to the worker that it can not prevent
	from termination. After the worker is reaped, close the old pipes, create
	new pipes and forks a new worker.

	The worker starts to sleep, if its rng generates a 6, if it gets a 7
	it calls std::abort(). In any other case it sends it to the master.
	but just if SIMULATE_FAIL is 1.
	

	The child rng uses this distribution scheme:
	std::normal_distribution<>  dis(3,2);
		-2
		-1 *
		 0 ***
		 1 *****
		 2 ********
		 3 **********
		 4 ********
		 5 ******
		 6 ***
		 7 *
		 8
		

	Comments:
	---------
	If we need to send more data than PIPE_BUF (linux 64 bit 64kb, 32bit 4kb)
	through the pipes, we need to use select(),poll() or epoll() and create a
	multiplexed application then we could make sure the while loop in the
	read_loop/write_loop can be avoided. It would also make an application
	more expandable.

	see: man 7 pipe
	
	boost::asio would also be a nice solution to this problem and make it
	platform independent.
	
	The regex in the tty_dummy could be optimized to detect automaticly how
	many ix=xxx are received.
******************************************************************************/

// if SIMULATE_FAIL is 1, the child simulates random failing
// if SIMULATE_FAIL is 0, the child should run forever
#define SIMULATE_FAIL 1

// std c++
#include <cassert>
#include <chrono> // clock
#include <cmath>  // std::round
#include <functional>
#include <iostream>
#include <memory> // shared_ptr for FDHandle
#include <random>
#include <regex>
#include <string>
#include <thread> // sleep_for
#include <tuple>

// abort and runtime_error
#include <exception>
#include <stdexcept>

// linux + posix
#include <sys/ioctl.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/wait.h>

#include <fcntl.h>
#include <limits.h> // PIPE_BUF
#include <signal.h>
#include <unistd.h>

// make sure we always close the fd (we MUST ensure
// no fd leak as the process is very long running)
using FDHandle = std::shared_ptr<void>;
FDHandle MakeFDHandle(int fd)
{
	return FDHandle(reinterpret_cast<void *>(fd), [fd](void *) {
		if (fd >= 0)
		{
			close(fd);
		}
	});
}
inline int GetFD(FDHandle handle)
{
	size_t p = reinterpret_cast<size_t>(handle.get());

	return static_cast<int>(p);
}

// chrono helper
using clk = std::chrono::system_clock;
using timepoint_t = clk::time_point;

inline timepoint_t now() { return clk::now(); }

// blocking write until we wrote all data
size_t write_loop(FDHandle fd, const void *buffer, size_t len)
{
	assert(fd.get() != nullptr && GetFD(fd) >= 0);
	assert(buffer != nullptr);
	assert(len > 0);
	assert(len < PIPE_BUF &&
		   "Because in case we got a signal and interrupt the write, we must "
		   "be able to get the data into the pipe");

	ssize_t wrote_bytes = 0;
	size_t total_wrote = 0;

	while (total_wrote < len)
	{
		int f = GetFD(fd);
		while ((wrote_bytes =
					write(GetFD(fd),
						  reinterpret_cast<const char *>(buffer) + total_wrote,
						  len - total_wrote)) < 0 &&
			   errno == EINTR)
			;

		// EOF
		if (wrote_bytes == 0)
		{
			throw std::runtime_error("write_loop EOF");
		}
		else if (wrote_bytes < 0)
		{
			perror("write()");
			throw std::runtime_error("write() failed");
		}

		total_wrote += wrote_bytes;
	}
	assert(total_wrote == len);

	return total_wrote;
}

// blocking read until we get some data
int read_loop(FDHandle fd, void *buffer, size_t len)
{
	assert(fd.get() != nullptr && GetFD(fd) >= 0);
	assert(buffer != nullptr);
	assert(len > 0);

	int read_bytes;
	while ((read_bytes = read(GetFD(fd), buffer, len)) < 0 && errno == EINTR)
		;

	// EOF
	if (read_bytes == 0)
	{
		throw std::runtime_error("read_loop EOF");
	}
	else if (read_bytes < 0)
	{
		perror("read()");
		throw std::runtime_error("read() failed");
	}
	assert(read_bytes > 0);

	return read_bytes;
}

// peek into the pipe and get the available bytes
int get_avail_bytes(FDHandle fd)
{
	assert(fd.get() != nullptr && GetFD(fd) >= 0);

	int avail_bytes = 0;
	if (ioctl(GetFD(fd), FIONREAD, &avail_bytes) != 0)
	{
		perror("ioctl()");
		throw std::runtime_error("ioctl() failed");
	}
	return avail_bytes;
}

// start the worker and give back the FDHandles to and from the worker
std::tuple<pid_t, FDHandle /* rfd */, FDHandle /* wfd*/>
start_worker(std::function<int(FDHandle rfd, FDHandle wfd)> fo)
{
	assert(static_cast<bool>(fo) == true && "Function object must be valid");

	int master_to_worker[2];
	int worker_to_master[2];
	if (pipe(master_to_worker) != 0)
	{
		perror("pipe() master_to_worker");
		exit(EXIT_FAILURE);
	}
	if (pipe(worker_to_master) != 0)
	{
		perror("pipe() worker_to_master");
		exit(EXIT_FAILURE);
	}

	pid_t PID = fork();
	switch (pid)
	{
			// fork failed:
		case -1:
			perror("fork()");
			exit(EXIT_FAILURE);

			// child
		case 0:
		{
			// as the child we should close the not needed fds
			close(master_to_worker[1]);
			close(worker_to_master[0]);

			exit(fo(MakeFDHandle(master_to_worker[0]),
					MakeFDHandle(worker_to_master[1])));
		}

		// master
		default:
		{
			// as a master we should close the not needed fds
			close(master_to_worker[0]);
			close(worker_to_master[1]);

			return std::make_tuple(pid, MakeFDHandle(worker_to_master[0]),
								   MakeFDHandle(master_to_worker[1]));
		}
	}

	// just to silence compiler warning: we never reach this point
	return std::make_tuple(pid, MakeFDHandle(-1), MakeFDHandle(-1));
}

void kill_worker(pid_t &worker)
{
	if (worker <= 0)
	{
		return;
	}

	// SIGKILL _CAN NOT_ be prohibited by the worker. It kills in any case
	// the worker (if we have the right to send it this signal)
	std::cout << "Terminate worker: " << worker << std::endl;
	if (kill(worker, SIGKILL) != 0)
	{
		perror("kill()");
		exit(EXIT_FAILURE);
	}

	// Just wait for this worker and reap the child process (prevent zombie
	// process)
	if (waitpid(worker, NULL, 0) != worker)
	{
		perror("waitpid()");
		exit(EXIT_FAILURE);
	}

	worker = 0;
}

// signal handler for master
// here we can just use very limited number of functions
// see man signal
int selfpipe[2];
void onsignal(int signal)
{
	switch (signal)
	{
		case SIGTERM:
		case SIGQUIT:
			write(selfpipe[1], " ", 1);
			break;

		case SIGCHLD:
			break;
		default:
			break;
	}
}

// master function. It should not fail or hang.
int master(std::function<int(FDHandle rfd, FDHandle wfd)> worker_fo)
{
	assert(static_cast<bool>(worker_fo) == true &&
		   "Function object must be valid");

	// install sighandler for SIGTERM, SIGQUIT, SIGCHLD
	// with self pipe trick.
	if (pipe2(selfpipe, O_NONBLOCK) != 0)
	{
		perror("pipe() selfpipe");
		exit(EXIT_FAILURE);
	}
	auto rd_selfpipe = MakeFDHandle(selfpipe[0]);
	auto wr_selfpipe = MakeFDHandle(selfpipe[1]);
	signal(SIGCHLD, &onsignal);
	signal(SIGTERM, &onsignal);
	signal(SIGQUIT, &onsignal);

	// make sure master and worker dont share the same rng sequence
	std::random_device rd;
	std::mt19937 gen(rd());
	std::uniform_int_distribution<> dis(11, 16);

	auto last_bytes_read_at = now();
	pid_t worker = 0;

	FDHandle rfd;
	FDHandle wfd;

	bool run = true;
	while (run)
	{
		// start the worker
		if (worker == 0)
		{
			std::tie(worker, rfd, wfd) = start_worker(worker_fo);
			last_bytes_read_at = now();
			std::cout << "Started worker: " << worker << std::endl;
		}

		// generate a pseudo command
		int cmd = dis(gen);
		int wrote_bytes = write_loop(wfd, &cmd, sizeof(int));
		assert(wrote_bytes == sizeof(int));

		// check if the worker has wrote some data
		int avail_bytes = 0;
		while (avail_bytes == 0 &&
			   now() - last_bytes_read_at < std::chrono::milliseconds(100))
		{
			avail_bytes = get_avail_bytes(rfd);
			if (avail_bytes == 0)
			{
				std::this_thread::sleep_for(std::chrono::milliseconds(10));
			}
		}

		// check if worker failed
		if (avail_bytes == 0)
		{
			kill_worker(worker);
			continue;
		}

		// got data from the worker
		int data;
		int read_bytes = read_loop(rfd, &data, sizeof(int));
		assert(read_bytes > 0);

		std::cout << "Got data from worker " << data << std::endl;
		last_bytes_read_at = now();

		// check self pipe and reset run flag
		if (get_avail_bytes(rd_selfpipe) > 0)
		{
			run = false;
		}
	}

	// kill the worker, the pipes get closed by the handles
	kill_worker(worker);

	return EXIT_SUCCESS;
}

int failing_worker(FDHandle rfd, FDHandle wfd)
{
	// worker dont get a signal handler as we want to manipulate it by the user
	assert(rfd.get() != nullptr && GetFD(rfd) >= 0);
	assert(wfd.get() != nullptr && GetFD(wfd) >= 0);

	// make sure master and worker dont share the same sequence
	std::random_device rd;
	std::mt19937 gen(rd());
	std::normal_distribution<> dis(3, 2);

	/*
		-2
		-1 *
		 0 ***
		 1 *****
		 2 ********
		 3 **********
		 4 ********
		 5 ******
		 6 ***
		 7 *
		 8
	*/
	while (1)
	{
		// read our command from the master
		int cmd;
		int read_bytes = read_loop(rfd, &cmd, sizeof(cmd));

		assert(read_bytes > 0);
		std::cout << "Slave got command: " << cmd << std::endl;

		// send a response to the master (or sleep or abort)
		int rnd = std::round(dis(gen));
#if SIMULATE_FAIL
		if (rnd == 6)
		{
			// sleep forever: simulate hang
			std::cout << "worker sleeping" << std::endl;
			std::this_thread::sleep_until(timepoint_t::max());
		}
		else if (rnd == 7)
		{
			// just die: abnormal program termination
			std::cout << "worker abort" << std::endl;
			std::abort();
		}
#endif

		// simulate a read from UART and give it to master
		int wrote = write_loop(wfd, &rnd, sizeof(rnd));
		assert(wrote > 0);
	}

	return EXIT_FAILURE;
}

// an example of the tty receiver on the pi
int tty_dummy(FDHandle rfd, FDHandle wfd)
{
	assert(rfd.get() != nullptr && GetFD(rfd) >= 0);
	assert(wfd.get() != nullptr && GetFD(wfd) >= 0);

	std::string rcv_buffer;
	while (1)
	{
		// read data from the master
		std::array<char, 256> tmp;
		const int read_bytes = read_loop(rfd, &tmp[0], tmp.size());
		for (int i = 0; i < read_bytes; ++i)
		{
			rcv_buffer += tmp[i];
		}

		// is there a /n
		auto pos = rcv_buffer.find('\n');
		if (pos != std::string::npos)
		{
			std::string line(rcv_buffer.begin(), rcv_buffer.begin() + pos);

			// remove the line from the rcv buffer
			rcv_buffer.erase(rcv_buffer.begin(), rcv_buffer.begin() + pos + 1);

			// math this:
			// §&i0=17628;&i1=1;&i2=17434;&i3=33;&i4=-444;&i5=5555;&i6=43690;
			std::regex ex(
				"^§&i0=([\\-0-9]++);&i1=([\\-0-9]+);&i2=([\\-0-9]+);&i3=([\\-0-"
				"9]+);&i4=([\\-0-9]+);&i5=([\\-0-9]+);&i6=([\\-0-9]+);$");
			std::smatch match;
			if (!std::regex_match(line, match, ex))
			{
				std::cerr << "Unmatched line: " << line << std::endl;
				continue;
			}

			std::cout << "Matched: ";
			for (int i = 0; i < 7; ++i)
			{
				std::cout << "i" << i << "=" << match[i].str() << std::endl;
			}
		}
	}
}

int main(int argc, char *argv[])
{
	try
	{
		// start the master function
		return master(&failing_worker);
	}
	catch (const std::exception &ex)
	{
		std::cerr << ex.what() << std::endl;
	}
	catch (...)
	{
		std::cerr << "Unknown exception" << std::endl;
	}
	return EXIT_FAILURE;
}

- - - Aktualisiert - - -

@HaWe:

man 3 pthread_kill

NOTES
Signal dispositions are process-wide: if a signal handler is installed, the handler will be invoked in the thread thread, but if the disposition of
the signal is "stop", "continue", or "terminate", this action will affect the whole process.

Das bedeutet, das du nicht den thread töten kannst. Du rufst nur "kill" auf im Kontext des thread thread.

- - - Aktualisiert - - -

Das hier zeigt es ganz gut:

http://openbook.rheinwerk-verlag.de/.../Kap10-011.htm

[HaWe]

@HaWe:

man 3 pthread_kill

Das bedeutet, das du nicht den thread töten kannst. Du rufst nur "kill" auf im Kontext des thread thread.

das verstehe ich nicht:
pthread_kill soll doch einen anderen thread killen - und du sagst, das tut es nicht?

[schorsch_76]

das verstehe ich nicht:
pthread_kill soll doch einen anderen thread killen - und du sagst, das tut es nicht?

Nein, das tut es nicht. Wenn du SIGKILL sendest, wird der ganze Prozess getötet. Das sagt die Dokumentaton zur API. man 3 pthread_kill. SIGKILL kann nicht geblockt werden.

[HaWe]

habe jetzt noch mal etwas genauer deinen Code studiert, aber nutzt du denn wirklich pthread? sieht irgendwie wie std::thread aus, das verwende ich aber ja gar nicht...

[schorsch_76]

Nein, ich nutze keinen Thread. Nur fork ()

- - - Aktualisiert - - -

Bzw sleep_for um zu schlafen. Das ist c++11