arch/posix/core/posix_core.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2017 Oticon A/S
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * Here is where things actually happen for the POSIX arch
  *
  * We isolate all functions here, to ensure they can be compiled as
  * independently as possible to the remainder of Zephyr to avoid name clashes
  * as Zephyr does provide functions with the same names as the POSIX threads
  * functions
  */
 /**
  * Principle of operation:
  *
  * The Zephyr OS and its app run as a set of native pthreads.
  * The Zephyr OS only sees one of this thread executing at a time.
  * Which is running is controlled using {cond|mtx}_threads and
  * currently_allowed_thread.
  *
  * The main part of the execution of each thread will occur in a fully
  * synchronous and deterministic manner, and only when commanded by the Zephyr
  * kernel.
  * But the creation of a thread will spawn a new pthread whose start
  * is asynchronous to the rest, until synchronized in posix_wait_until_allowed()
  * below.
  * Similarly aborting and canceling threads execute a tail in a quite
  * asynchronous manner.
  *
  * This implementation is meant to be portable in between POSIX systems.
  * A table (threads_table) is used to abstract the native pthreads.
  * And index in this table is used to identify threads in the IF to the kernel.
  *
  */

 #define POSIX_ARCH_DEBUG_PRINTS 0

 #include <pthread.h>
 #include <stdbool.h>
 #include <stdlib.h>
 #include <string.h>

 #include "posix_core.h"
 #include "posix_arch_internal.h"
 #include <zephyr/arch/posix/posix_soc_if.h>
 #include "kernel_internal.h"
 #include <zephyr/kernel_structs.h>
 #include "ksched.h"
 #include "kswap.h"

 #define PREFIX     "POSIX arch core: "
 #define ERPREFIX   PREFIX"error on "
 #define NO_MEM_ERR PREFIX"Can't allocate memory\n"

 #if POSIX_ARCH_DEBUG_PRINTS
 #define PC_DEBUG(fmt, ...) posix_print_trace(PREFIX fmt, __VA_ARGS__)
 #else
 #define PC_DEBUG(...)
 #endif

 #define PC_ALLOC_CHUNK_SIZE 64
 #define PC_REUSE_ABORTED_ENTRIES 0
 /* tests/kernel/threads/scheduling/schedule_api fails when setting
  * PC_REUSE_ABORTED_ENTRIES => don't set it by now
  */

 static int threads_table_size;
 struct threads_table_el {
 	enum {NOTUSED = 0, USED, ABORTING, ABORTED, FAILED} state;
 	bool running;     /* Is this the currently running thread */
 	pthread_t thread; /* Actual pthread_t as returned by native kernel */
 	int thead_cnt; /* For debugging: Unique, consecutive, thread number */
 	/* Pointer to the status kept in the Zephyr thread stack */
 	posix_thread_status_t *t_status;
 };

 static struct threads_table_el *threads_table;

 static int thread_create_count; /* For debugging. Thread creation counter */

 /*
  * Conditional variable to block/awake all threads during swaps()
  * (we only need 1 mutex and 1 cond variable for all threads)
  */
 static pthread_cond_t cond_threads = PTHREAD_COND_INITIALIZER;
 /* Mutex for the conditional variable posix_core_cond_threads */
 static pthread_mutex_t mtx_threads = PTHREAD_MUTEX_INITIALIZER;
 /* Token which tells which process is allowed to run now */
 static int currently_allowed_thread;

 static bool terminate; /* Are we terminating the program == cleaning up */

 static void posix_wait_until_allowed(int this_th_nbr);
 static void *posix_thread_starter(void *arg);
 static void posix_preexit_cleanup(void);

 /**
  * Helper function, run by a thread is being aborted
  */
 static void abort_tail(int this_th_nbr)
 {
 	PC_DEBUG("Thread [%i] %i: %s: Aborting (exiting) (rel mut)\n",
 		threads_table[this_th_nbr].thead_cnt,
 		this_th_nbr,
 		__func__);

 	threads_table[this_th_nbr].running = false;
 	threads_table[this_th_nbr].state = ABORTED;
 	posix_preexit_cleanup();
 	pthread_exit(NULL);
 }

 /**
  *  Helper function to block this thread until it is allowed again
  *  (somebody calls posix_let_run() with this thread number
  *
  * Note that we go out of this function (the while loop below)
  * with the mutex locked by this particular thread.
  * In normal circumstances, the mutex is only unlocked internally in
  * pthread_cond_wait() while waiting for cond_threads to be signaled
  */
 static void posix_wait_until_allowed(int this_th_nbr)
 {
 	threads_table[this_th_nbr].running = false;

 	PC_DEBUG("Thread [%i] %i: %s: Waiting to be allowed to run (rel mut)\n",
 		threads_table[this_th_nbr].thead_cnt,
 		this_th_nbr,
 		__func__);

 	while (this_th_nbr != currently_allowed_thread) {
 		pthread_cond_wait(&cond_threads, &mtx_threads);

 		if (threads_table &&
 		    (threads_table[this_th_nbr].state == ABORTING)) {
 			abort_tail(this_th_nbr);
 		}
 	}

 	threads_table[this_th_nbr].running = true;

 	PC_DEBUG("Thread [%i] %i: %s(): I'm allowed to run! (hav mut)\n",
 		threads_table[this_th_nbr].thead_cnt,
 		this_th_nbr,
 		__func__);
 }


 /**
  * Helper function to let the thread <next_allowed_th> run
  * Note: posix_let_run() can only be called with the mutex locked
  */
 static void posix_let_run(int next_allowed_th)
 {
 	PC_DEBUG("%s: We let thread [%i] %i run\n",
 		__func__,
 		threads_table[next_allowed_th].thead_cnt,
 		next_allowed_th);


 	currently_allowed_thread = next_allowed_th;

 	/*
 	 * We let all threads know one is able to run now (it may even be us
 	 * again if fancied)
 	 * Note that as we hold the mutex, they are going to be blocked until
 	 * we reach our own posix_wait_until_allowed() while loop
 	 */
 	PC_SAFE_CALL(pthread_cond_broadcast(&cond_threads));
 }


 static void posix_preexit_cleanup(void)
 {
 	/*
 	 * Release the mutex so the next allowed thread can run
 	 */
 	PC_SAFE_CALL(pthread_mutex_unlock(&mtx_threads));

 	/* We detach ourselves so nobody needs to join to us */
 	pthread_detach(pthread_self());
 }


 /**
  * Let the ready thread run and block this thread until it is allowed again
  *
  * called from arch_swap() which does the picking from the kernel structures
  */
 void posix_swap(int next_allowed_thread_nbr, int this_th_nbr)
 {
 	posix_let_run(next_allowed_thread_nbr);

 	if (threads_table[this_th_nbr].state == ABORTING) {
 		PC_DEBUG("Thread [%i] %i: %s: Aborting curr.\n",
 			threads_table[this_th_nbr].thead_cnt,
 			this_th_nbr,
 			__func__);
 		abort_tail(this_th_nbr);
 	} else {
 		posix_wait_until_allowed(this_th_nbr);
 	}
 }

 /**
  * Let the ready thread (main) run, and exit this thread (init)
  *
  * Called from arch_switch_to_main_thread() which does the picking from the
  * kernel structures
  *
  * Note that we could have just done a swap(), but that would have left the
  * init thread lingering. Instead here we exit the init thread after enabling
  * the new one
  */
 void posix_main_thread_start(int next_allowed_thread_nbr)
 {
 	posix_let_run(next_allowed_thread_nbr);
 	PC_DEBUG("%s: Init thread dying now (rel mut)\n",
 		__func__);
 	posix_preexit_cleanup();
 	pthread_exit(NULL);
 }

 /**
  * Handler called when any thread is cancelled or exits
  */
 static void posix_cleanup_handler(void *arg)
 {
 	/*
 	 * If we are not terminating, this is just an aborted thread,
 	 * and the mutex was already released
 	 * Otherwise, release the mutex so other threads which may be
 	 * caught waiting for it could terminate
 	 */

 	if (!terminate) {
 		return;
 	}

 #if POSIX_ARCH_DEBUG_PRINTS
 	posix_thread_status_t *ptr = (posix_thread_status_t *) arg;

 	PC_DEBUG("Thread %i: %s: Canceling (rel mut)\n",
 		ptr->thread_idx,
 		__func__);
 #endif


 	PC_SAFE_CALL(pthread_mutex_unlock(&mtx_threads));

 	/* We detach ourselves so nobody needs to join to us */
 	pthread_detach(pthread_self());
 }

 /**
  * Helper function to start a Zephyr thread as a POSIX thread:
  *  It will block the thread until a arch_swap() is called for it
  *
  * Spawned from posix_new_thread() below
  */
 static void *posix_thread_starter(void *arg)
 {
 	int thread_idx = (intptr_t)arg;

 	PC_DEBUG("Thread [%i] %i: %s: Starting\n",
 		threads_table[thread_idx].thead_cnt,
 		thread_idx,
 		__func__);

 	/*
 	 * We block until all other running threads reach the while loop
 	 * in posix_wait_until_allowed() and they release the mutex
 	 */
 	PC_SAFE_CALL(pthread_mutex_lock(&mtx_threads));

 	/*
 	 * The program may have been finished before this thread ever got to run
 	 */
 	/* LCOV_EXCL_START */ /* See Note1 */
 	if (!threads_table) {
 		posix_cleanup_handler(arg);
 		pthread_exit(NULL);
 	}
 	/* LCOV_EXCL_STOP */

 	pthread_cleanup_push(posix_cleanup_handler, arg);

 	PC_DEBUG("Thread [%i] %i: %s: After start mutex (hav mut)\n",
 		threads_table[thread_idx].thead_cnt,
 		thread_idx,
 		__func__);

 	/*
 	 * The thread would try to execute immediately, so we block it
 	 * until allowed
 	 */
 	posix_wait_until_allowed(thread_idx);

 	posix_new_thread_pre_start();

 	posix_thread_status_t *ptr = threads_table[thread_idx].t_status;

 	z_thread_entry(ptr->entry_point, ptr->arg1, ptr->arg2, ptr->arg3);

 	/*
 	 * We only reach this point if the thread actually returns which should
 	 * not happen. But we handle it gracefully just in case
 	 */
 	/* LCOV_EXCL_START */
 	posix_print_trace(PREFIX"Thread [%i] %i [%lu] ended!?!\n",
 			threads_table[thread_idx].thead_cnt,
 			thread_idx,
 			pthread_self());


 	threads_table[thread_idx].running = false;
 	threads_table[thread_idx].state = FAILED;

 	pthread_cleanup_pop(1);

 	return NULL;
 	/* LCOV_EXCL_STOP */
 }

 /**
  * Return the first free entry index in the threads table
  */
 static int ttable_get_empty_slot(void)
 {

 	for (int i = 0; i < threads_table_size; i++) {
 		if ((threads_table[i].state == NOTUSED)
 			|| (PC_REUSE_ABORTED_ENTRIES
 			&& (threads_table[i].state == ABORTED))) {
 			return i;
 		}
 	}

 	/*
 	 * else, we run out table without finding an index
 	 * => we expand the table
 	 */

 	threads_table = realloc(threads_table,
 				(threads_table_size + PC_ALLOC_CHUNK_SIZE)
 				* sizeof(struct threads_table_el));
 	if (threads_table == NULL) { /* LCOV_EXCL_BR_LINE */
 		posix_print_error_and_exit(NO_MEM_ERR); /* LCOV_EXCL_LINE */
 	}

 	/* Clear new piece of table */
 	(void)memset(&threads_table[threads_table_size], 0,
 		     PC_ALLOC_CHUNK_SIZE * sizeof(struct threads_table_el));

 	threads_table_size += PC_ALLOC_CHUNK_SIZE;

 	/* The first newly created entry is good: */
 	return threads_table_size - PC_ALLOC_CHUNK_SIZE;
 }

 /**
  * Called from arch_new_thread(),
  * Create a new POSIX thread for the new Zephyr thread.
  * arch_new_thread() picks from the kernel structures what it is that we need
  * to call with what parameters
  */
 void posix_new_thread(posix_thread_status_t *ptr)
 {
 	int t_slot;

 	t_slot = ttable_get_empty_slot();
 	threads_table[t_slot].state = USED;
 	threads_table[t_slot].running = false;
 	threads_table[t_slot].thead_cnt = thread_create_count++;
 	threads_table[t_slot].t_status = ptr;
 	ptr->thread_idx = t_slot;

 	PC_SAFE_CALL(pthread_create(&threads_table[t_slot].thread,
 				  NULL,
 				  posix_thread_starter,
 				  (void *)(intptr_t)t_slot));

 	PC_DEBUG("%s created thread [%i] %i [%lu]\n",
 		__func__,
 		threads_table[t_slot].thead_cnt,
 		t_slot,
 		threads_table[t_slot].thread);

 }

 /**
  * Called from zephyr_wrapper()
  * prepare whatever needs to be prepared to be able to start threads
  */
 void posix_init_multithreading(void)
 {
 	thread_create_count = 0;

 	currently_allowed_thread = -1;

 	threads_table = calloc(PC_ALLOC_CHUNK_SIZE,
 				sizeof(struct threads_table_el));
 	if (threads_table == NULL) { /* LCOV_EXCL_BR_LINE */
 		posix_print_error_and_exit(NO_MEM_ERR); /* LCOV_EXCL_LINE */
 	}

 	threads_table_size = PC_ALLOC_CHUNK_SIZE;


 	PC_SAFE_CALL(pthread_mutex_lock(&mtx_threads));
 }

 /**
  * Free any allocated memory by the posix core and clean up.
  * Note that this function cannot be called from a SW thread
  * (the CPU is assumed halted. Otherwise we will cancel ourselves)
  *
  * This function cannot guarantee the threads will be cancelled before the HW
  * thread exists. The only way to do that, would be  to wait for each of them in
  * a join (without detaching them, but that could lead to locks in some
  * convoluted cases. As a call to this function can come from an ASSERT or other
  * error termination, we better do not assume things are working fine.
  * => we prefer the supposed memory leak report from valgrind, and ensure we
  * will not hang
  *
  */
 void posix_core_clean_up(void)
 {

 	if (!threads_table) { /* LCOV_EXCL_BR_LINE */
 		return; /* LCOV_EXCL_LINE */
 	}

 	terminate = true;

 	for (int i = 0; i < threads_table_size; i++) {
 		if (threads_table[i].state != USED) {
 			continue;
 		}

 		/* LCOV_EXCL_START */
 		if (pthread_cancel(threads_table[i].thread)) {
 			posix_print_warning(
 				PREFIX"cleanup: could not stop thread %i\n",
 				i);
 		}
 		/* LCOV_EXCL_STOP */
 	}

 	free(threads_table);
 	threads_table = NULL;
 }


 void posix_abort_thread(int thread_idx)
 {
 	if (threads_table[thread_idx].state != USED) { /* LCOV_EXCL_BR_LINE */
 		/* The thread may have been already aborted before */
 		return; /* LCOV_EXCL_LINE */
 	}

 	PC_DEBUG("Aborting not scheduled thread [%i] %i\n",
 		threads_table[thread_idx].thead_cnt,
 		thread_idx);

 	threads_table[thread_idx].state = ABORTING;
 	/*
 	 * Note: the native thread will linger in RAM until it catches the
 	 * mutex or awakes on the condition.
 	 * Note that even if we would pthread_cancel() the thread here, that
 	 * would be the case, but with a pthread_cancel() the mutex state would
 	 * be uncontrolled
 	 */
 }


 #if defined(CONFIG_ARCH_HAS_THREAD_ABORT)
 void z_impl_k_thread_abort(k_tid_t thread)
 {
 	unsigned int key;
 	int thread_idx;

 	posix_thread_status_t *tstatus =
 					(posix_thread_status_t *)
 					thread->callee_saved.thread_status;

 	thread_idx = tstatus->thread_idx;

 	key = irq_lock();

 	if (_current == thread) {
 		if (tstatus->aborted == 0) { /* LCOV_EXCL_BR_LINE */
 			tstatus->aborted = 1;
 		} else {
 			posix_print_warning(/* LCOV_EXCL_LINE */
 				PREFIX"The kernel is trying to abort and swap "
 				"out of an already aborted thread %i. This "
 				"should NOT have happened\n",
 				thread_idx);
 		}
 		threads_table[thread_idx].state = ABORTING;
 		PC_DEBUG("Thread [%i] %i: %s Marked myself "
 			"as aborting\n",
 			threads_table[thread_idx].thead_cnt,
 			thread_idx,
 			__func__);
 	}

 	z_thread_abort(thread);

 	if (tstatus->aborted == 0) {
 		PC_DEBUG("%s aborting now [%i] %i\n",
 			__func__,
 			threads_table[thread_idx].thead_cnt,
 			thread_idx);

 		tstatus->aborted = 1;
 		posix_abort_thread(thread_idx);
 	} else {
 		PC_DEBUG("%s ignoring re_abort of [%i] "
 			"%i\n",
 			__func__,
 			threads_table[thread_idx].thead_cnt,
 			thread_idx);
 	}

 	/* The abort handler might have altered the ready queue. */
 	z_reschedule_irqlock(key);
 }
 #endif


 /*
  * Notes about coverage:
  *
  * Note1:
  *
  * This condition will only be triggered in very unlikely cases
  * (once every few full regression runs).
  * It is therefore excluded from the coverage report to avoid confusing
  * developers.
  *
  * Background: This arch creates a pthread as soon as the Zephyr kernel creates
  * a Zephyr thread. A pthread creation is an asynchronous process handled by the
  * host kernel.
  *
  * This architecture normally keeps only 1 thread executing at a time.
  * But part of the pre-initialization during creation of a new thread
  * and some cleanup at the tail of the thread termination are executed
  * in parallel to other threads.
  * That is, the execution of those code paths is a bit indeterministic.
  *
  * Only when the Zephyr kernel attempts to swap to a new thread does this
  * architecture need to wait until its pthread is ready and initialized
  * (has reached posix_wait_until_allowed())
  *
  * In some cases (tests) threads are created which are never actually needed
  * (typically the idle thread). That means the test may finish before this
  * thread's underlying pthread has reached posix_wait_until_allowed().
  *
  * In this unlikely cases the initialization or cleanup of the thread follows
  * non-typical code paths.
  * This code paths are there to ensure things work always, no matter
  * the load of the host. Without them, very rare & mysterious segfault crashes
  * would occur.
  * But as they are very atypical and only triggered with some host loads,
  * they will be covered in the coverage reports only rarely.
  *
  * Note2:
  *
  * Some other code will never or only very rarely trigger and is therefore
  * excluded with LCOV_EXCL_LINE
  *
  */
	/*
	* Copyright (c) 2017 Oticon A/S
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* Here is where things actually happen for the POSIX arch
	*
	* We isolate all functions here, to ensure they can be compiled as
	* independently as possible to the remainder of Zephyr to avoid name clashes
	* as Zephyr does provide functions with the same names as the POSIX threads
	* functions
	*/
	/**
	* Principle of operation:
	*
	* The Zephyr OS and its app run as a set of native pthreads.
	* The Zephyr OS only sees one of this thread executing at a time.
	* Which is running is controlled using {cond\|mtx}_threads and
	* currently_allowed_thread.
	*
	* The main part of the execution of each thread will occur in a fully
	* synchronous and deterministic manner, and only when commanded by the Zephyr
	* kernel.
	* But the creation of a thread will spawn a new pthread whose start
	* is asynchronous to the rest, until synchronized in posix_wait_until_allowed()
	* below.
	* Similarly aborting and canceling threads execute a tail in a quite
	* asynchronous manner.
	*
	* This implementation is meant to be portable in between POSIX systems.
	* A table (threads_table) is used to abstract the native pthreads.
	* And index in this table is used to identify threads in the IF to the kernel.
	*
	*/

	#define POSIX_ARCH_DEBUG_PRINTS 0

	#include <pthread.h>
	#include <stdbool.h>
	#include <stdlib.h>
	#include <string.h>

	#include "posix_core.h"
	#include "posix_arch_internal.h"
	#include <zephyr/arch/posix/posix_soc_if.h>
	#include "kernel_internal.h"
	#include <zephyr/kernel_structs.h>
	#include "ksched.h"
	#include "kswap.h"

	#define PREFIX "POSIX arch core: "
	#define ERPREFIX PREFIX"error on "
	#define NO_MEM_ERR PREFIX"Can't allocate memory\n"

	#if POSIX_ARCH_DEBUG_PRINTS
	#define PC_DEBUG(fmt, ...) posix_print_trace(PREFIX fmt, __VA_ARGS__)
	#else
	#define PC_DEBUG(...)
	#endif

	#define PC_ALLOC_CHUNK_SIZE 64
	#define PC_REUSE_ABORTED_ENTRIES 0
	/* tests/kernel/threads/scheduling/schedule_api fails when setting
	* PC_REUSE_ABORTED_ENTRIES => don't set it by now
	*/

	static int threads_table_size;
	struct threads_table_el {
	enum {NOTUSED = 0, USED, ABORTING, ABORTED, FAILED} state;
	bool running; /* Is this the currently running thread */
	pthread_t thread; /* Actual pthread_t as returned by native kernel */
	int thead_cnt; /* For debugging: Unique, consecutive, thread number */
	/* Pointer to the status kept in the Zephyr thread stack */
	posix_thread_status_t *t_status;
	};

	static struct threads_table_el *threads_table;

	static int thread_create_count; /* For debugging. Thread creation counter */

	/*
	* Conditional variable to block/awake all threads during swaps()
	* (we only need 1 mutex and 1 cond variable for all threads)
	*/
	static pthread_cond_t cond_threads = PTHREAD_COND_INITIALIZER;
	/* Mutex for the conditional variable posix_core_cond_threads */
	static pthread_mutex_t mtx_threads = PTHREAD_MUTEX_INITIALIZER;
	/* Token which tells which process is allowed to run now */
	static int currently_allowed_thread;

	static bool terminate; /* Are we terminating the program == cleaning up */

	static void posix_wait_until_allowed(int this_th_nbr);
	static void posix_thread_starter(void arg);
	static void posix_preexit_cleanup(void);

	/**
	* Helper function, run by a thread is being aborted
	*/
	static void abort_tail(int this_th_nbr)
	{
	PC_DEBUG("Thread [%i] %i: %s: Aborting (exiting) (rel mut)\n",
	threads_table[this_th_nbr].thead_cnt,
	this_th_nbr,
	__func__);

	threads_table[this_th_nbr].running = false;
	threads_table[this_th_nbr].state = ABORTED;
	posix_preexit_cleanup();
	pthread_exit(NULL);
	}

	/**
	* Helper function to block this thread until it is allowed again
	* (somebody calls posix_let_run() with this thread number
	*
	* Note that we go out of this function (the while loop below)
	* with the mutex locked by this particular thread.
	* In normal circumstances, the mutex is only unlocked internally in
	* pthread_cond_wait() while waiting for cond_threads to be signaled
	*/
	static void posix_wait_until_allowed(int this_th_nbr)
	{
	threads_table[this_th_nbr].running = false;

	PC_DEBUG("Thread [%i] %i: %s: Waiting to be allowed to run (rel mut)\n",
	threads_table[this_th_nbr].thead_cnt,
	this_th_nbr,
	__func__);

	while (this_th_nbr != currently_allowed_thread) {
	pthread_cond_wait(&cond_threads, &mtx_threads);

	if (threads_table &&
	(threads_table[this_th_nbr].state == ABORTING)) {
	abort_tail(this_th_nbr);
	}
	}

	threads_table[this_th_nbr].running = true;

	PC_DEBUG("Thread [%i] %i: %s(): I'm allowed to run! (hav mut)\n",
	threads_table[this_th_nbr].thead_cnt,
	this_th_nbr,
	__func__);
	}


	/**
	* Helper function to let the thread <next_allowed_th> run
	* Note: posix_let_run() can only be called with the mutex locked
	*/
	static void posix_let_run(int next_allowed_th)
	{
	PC_DEBUG("%s: We let thread [%i] %i run\n",
	__func__,
	threads_table[next_allowed_th].thead_cnt,
	next_allowed_th);


	currently_allowed_thread = next_allowed_th;

	/*
	* We let all threads know one is able to run now (it may even be us
	* again if fancied)
	* Note that as we hold the mutex, they are going to be blocked until
	* we reach our own posix_wait_until_allowed() while loop
	*/
	PC_SAFE_CALL(pthread_cond_broadcast(&cond_threads));
	}


	static void posix_preexit_cleanup(void)
	{
	/*
	* Release the mutex so the next allowed thread can run
	*/
	PC_SAFE_CALL(pthread_mutex_unlock(&mtx_threads));

	/* We detach ourselves so nobody needs to join to us */
	pthread_detach(pthread_self());
	}


	/**
	* Let the ready thread run and block this thread until it is allowed again
	*
	* called from arch_swap() which does the picking from the kernel structures
	*/
	void posix_swap(int next_allowed_thread_nbr, int this_th_nbr)
	{
	posix_let_run(next_allowed_thread_nbr);

	if (threads_table[this_th_nbr].state == ABORTING) {
	PC_DEBUG("Thread [%i] %i: %s: Aborting curr.\n",
	threads_table[this_th_nbr].thead_cnt,
	this_th_nbr,
	__func__);
	abort_tail(this_th_nbr);
	} else {
	posix_wait_until_allowed(this_th_nbr);
	}
	}

	/**
	* Let the ready thread (main) run, and exit this thread (init)
	*
	* Called from arch_switch_to_main_thread() which does the picking from the
	* kernel structures
	*
	* Note that we could have just done a swap(), but that would have left the
	* init thread lingering. Instead here we exit the init thread after enabling
	* the new one
	*/
	void posix_main_thread_start(int next_allowed_thread_nbr)
	{
	posix_let_run(next_allowed_thread_nbr);
	PC_DEBUG("%s: Init thread dying now (rel mut)\n",
	__func__);
	posix_preexit_cleanup();
	pthread_exit(NULL);
	}

	/**
	* Handler called when any thread is cancelled or exits
	*/
	static void posix_cleanup_handler(void *arg)
	{
	/*
	* If we are not terminating, this is just an aborted thread,
	* and the mutex was already released
	* Otherwise, release the mutex so other threads which may be
	* caught waiting for it could terminate
	*/

	if (!terminate) {
	return;
	}

	#if POSIX_ARCH_DEBUG_PRINTS
	posix_thread_status_t ptr = (posix_thread_status_t ) arg;

	PC_DEBUG("Thread %i: %s: Canceling (rel mut)\n",
	ptr->thread_idx,
	__func__);
	#endif


	PC_SAFE_CALL(pthread_mutex_unlock(&mtx_threads));

	/* We detach ourselves so nobody needs to join to us */
	pthread_detach(pthread_self());
	}

	/**
	* Helper function to start a Zephyr thread as a POSIX thread:
	* It will block the thread until a arch_swap() is called for it
	*
	* Spawned from posix_new_thread() below
	*/
	static void posix_thread_starter(void arg)
	{
	int thread_idx = (intptr_t)arg;

	PC_DEBUG("Thread [%i] %i: %s: Starting\n",
	threads_table[thread_idx].thead_cnt,
	thread_idx,
	__func__);

	/*
	* We block until all other running threads reach the while loop
	* in posix_wait_until_allowed() and they release the mutex
	*/
	PC_SAFE_CALL(pthread_mutex_lock(&mtx_threads));

	/*
	* The program may have been finished before this thread ever got to run
	*/
	/* LCOV_EXCL_START / / See Note1 */
	if (!threads_table) {
	posix_cleanup_handler(arg);
	pthread_exit(NULL);
	}
	/* LCOV_EXCL_STOP */

	pthread_cleanup_push(posix_cleanup_handler, arg);

	PC_DEBUG("Thread [%i] %i: %s: After start mutex (hav mut)\n",
	threads_table[thread_idx].thead_cnt,
	thread_idx,
	__func__);

	/*
	* The thread would try to execute immediately, so we block it
	* until allowed
	*/
	posix_wait_until_allowed(thread_idx);

	posix_new_thread_pre_start();

	posix_thread_status_t *ptr = threads_table[thread_idx].t_status;

	z_thread_entry(ptr->entry_point, ptr->arg1, ptr->arg2, ptr->arg3);

	/*
	* We only reach this point if the thread actually returns which should
	* not happen. But we handle it gracefully just in case
	*/
	/* LCOV_EXCL_START */
	posix_print_trace(PREFIX"Thread [%i] %i [%lu] ended!?!\n",
	threads_table[thread_idx].thead_cnt,
	thread_idx,
	pthread_self());


	threads_table[thread_idx].running = false;
	threads_table[thread_idx].state = FAILED;

	pthread_cleanup_pop(1);

	return NULL;
	/* LCOV_EXCL_STOP */
	}

	/**
	* Return the first free entry index in the threads table
	*/
	static int ttable_get_empty_slot(void)
	{

	for (int i = 0; i < threads_table_size; i++) {
	if ((threads_table[i].state == NOTUSED)
	\|\| (PC_REUSE_ABORTED_ENTRIES
	&& (threads_table[i].state == ABORTED))) {
	return i;
	}
	}

	/*
	* else, we run out table without finding an index
	* => we expand the table
	*/

	threads_table = realloc(threads_table,
	(threads_table_size + PC_ALLOC_CHUNK_SIZE)
	* sizeof(struct threads_table_el));
	if (threads_table == NULL) { /* LCOV_EXCL_BR_LINE */
	posix_print_error_and_exit(NO_MEM_ERR); /* LCOV_EXCL_LINE */
	}

	/* Clear new piece of table */
	(void)memset(&threads_table[threads_table_size], 0,
	PC_ALLOC_CHUNK_SIZE * sizeof(struct threads_table_el));

	threads_table_size += PC_ALLOC_CHUNK_SIZE;

	/* The first newly created entry is good: */
	return threads_table_size - PC_ALLOC_CHUNK_SIZE;
	}

	/**
	* Called from arch_new_thread(),
	* Create a new POSIX thread for the new Zephyr thread.
	* arch_new_thread() picks from the kernel structures what it is that we need
	* to call with what parameters
	*/
	void posix_new_thread(posix_thread_status_t *ptr)
	{
	int t_slot;

	t_slot = ttable_get_empty_slot();
	threads_table[t_slot].state = USED;
	threads_table[t_slot].running = false;
	threads_table[t_slot].thead_cnt = thread_create_count++;
	threads_table[t_slot].t_status = ptr;
	ptr->thread_idx = t_slot;

	PC_SAFE_CALL(pthread_create(&threads_table[t_slot].thread,
	NULL,
	posix_thread_starter,
	(void *)(intptr_t)t_slot));

	PC_DEBUG("%s created thread [%i] %i [%lu]\n",
	__func__,
	threads_table[t_slot].thead_cnt,
	t_slot,
	threads_table[t_slot].thread);

	}

	/**
	* Called from zephyr_wrapper()
	* prepare whatever needs to be prepared to be able to start threads
	*/
	void posix_init_multithreading(void)
	{
	thread_create_count = 0;

	currently_allowed_thread = -1;

	threads_table = calloc(PC_ALLOC_CHUNK_SIZE,
	sizeof(struct threads_table_el));
	if (threads_table == NULL) { /* LCOV_EXCL_BR_LINE */
	posix_print_error_and_exit(NO_MEM_ERR); /* LCOV_EXCL_LINE */
	}

	threads_table_size = PC_ALLOC_CHUNK_SIZE;


	PC_SAFE_CALL(pthread_mutex_lock(&mtx_threads));
	}

	/**
	* Free any allocated memory by the posix core and clean up.
	* Note that this function cannot be called from a SW thread
	* (the CPU is assumed halted. Otherwise we will cancel ourselves)
	*
	* This function cannot guarantee the threads will be cancelled before the HW
	* thread exists. The only way to do that, would be to wait for each of them in
	* a join (without detaching them, but that could lead to locks in some
	* convoluted cases. As a call to this function can come from an ASSERT or other
	* error termination, we better do not assume things are working fine.
	* => we prefer the supposed memory leak report from valgrind, and ensure we
	* will not hang
	*
	*/
	void posix_core_clean_up(void)
	{

	if (!threads_table) { /* LCOV_EXCL_BR_LINE */
	return; /* LCOV_EXCL_LINE */
	}

	terminate = true;

	for (int i = 0; i < threads_table_size; i++) {
	if (threads_table[i].state != USED) {
	continue;
	}

	/* LCOV_EXCL_START */
	if (pthread_cancel(threads_table[i].thread)) {
	posix_print_warning(
	PREFIX"cleanup: could not stop thread %i\n",
	i);
	}
	/* LCOV_EXCL_STOP */
	}

	free(threads_table);
	threads_table = NULL;
	}


	void posix_abort_thread(int thread_idx)
	{
	if (threads_table[thread_idx].state != USED) { /* LCOV_EXCL_BR_LINE */
	/* The thread may have been already aborted before */
	return; /* LCOV_EXCL_LINE */
	}

	PC_DEBUG("Aborting not scheduled thread [%i] %i\n",
	threads_table[thread_idx].thead_cnt,
	thread_idx);

	threads_table[thread_idx].state = ABORTING;
	/*
	* Note: the native thread will linger in RAM until it catches the
	* mutex or awakes on the condition.
	* Note that even if we would pthread_cancel() the thread here, that
	* would be the case, but with a pthread_cancel() the mutex state would
	* be uncontrolled
	*/
	}


	#if defined(CONFIG_ARCH_HAS_THREAD_ABORT)
	void z_impl_k_thread_abort(k_tid_t thread)
	{
	unsigned int key;
	int thread_idx;

	posix_thread_status_t *tstatus =
	(posix_thread_status_t *)
	thread->callee_saved.thread_status;

	thread_idx = tstatus->thread_idx;

	key = irq_lock();

	if (_current == thread) {
	if (tstatus->aborted == 0) { /* LCOV_EXCL_BR_LINE */
	tstatus->aborted = 1;
	} else {
	posix_print_warning(/* LCOV_EXCL_LINE */
	PREFIX"The kernel is trying to abort and swap "
	"out of an already aborted thread %i. This "
	"should NOT have happened\n",
	thread_idx);
	}
	threads_table[thread_idx].state = ABORTING;
	PC_DEBUG("Thread [%i] %i: %s Marked myself "
	"as aborting\n",
	threads_table[thread_idx].thead_cnt,
	thread_idx,
	__func__);
	}

	z_thread_abort(thread);

	if (tstatus->aborted == 0) {
	PC_DEBUG("%s aborting now [%i] %i\n",
	__func__,
	threads_table[thread_idx].thead_cnt,
	thread_idx);

	tstatus->aborted = 1;
	posix_abort_thread(thread_idx);
	} else {
	PC_DEBUG("%s ignoring re_abort of [%i] "
	"%i\n",
	__func__,
	threads_table[thread_idx].thead_cnt,
	thread_idx);
	}

	/* The abort handler might have altered the ready queue. */
	z_reschedule_irqlock(key);
	}
	#endif


	/*
	* Notes about coverage:
	*
	* Note1:
	*
	* This condition will only be triggered in very unlikely cases
	* (once every few full regression runs).
	* It is therefore excluded from the coverage report to avoid confusing
	* developers.
	*
	* Background: This arch creates a pthread as soon as the Zephyr kernel creates
	* a Zephyr thread. A pthread creation is an asynchronous process handled by the
	* host kernel.
	*
	* This architecture normally keeps only 1 thread executing at a time.
	* But part of the pre-initialization during creation of a new thread
	* and some cleanup at the tail of the thread termination are executed
	* in parallel to other threads.
	* That is, the execution of those code paths is a bit indeterministic.
	*
	* Only when the Zephyr kernel attempts to swap to a new thread does this
	* architecture need to wait until its pthread is ready and initialized
	* (has reached posix_wait_until_allowed())
	*
	* In some cases (tests) threads are created which are never actually needed
	* (typically the idle thread). That means the test may finish before this
	* thread's underlying pthread has reached posix_wait_until_allowed().
	*
	* In this unlikely cases the initialization or cleanup of the thread follows
	* non-typical code paths.
	* This code paths are there to ensure things work always, no matter
	* the load of the host. Without them, very rare & mysterious segfault crashes
	* would occur.
	* But as they are very atypical and only triggered with some host loads,
	* they will be covered in the coverage reports only rarely.
	*
	* Note2:
	*
	* Some other code will never or only very rarely trigger and is therefore
	* excluded with LCOV_EXCL_LINE
	*
	*/