kc3-lang/gnulib/tests/test-mtx.c

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  Date : 2023-01-01T01:14:21
  

  maint: run 'make update-copyright'
  

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• tests/test-mtx.c

• /* Test of locking in multithreaded situations.
     Copyright (C) 2005, 2008-2023 Free Software Foundation, Inc.
  
     This program is free software: you can redistribute it and/or modify
     it under the terms of the GNU General Public License as published by
     the Free Software Foundation, either version 3 of the License, or
     (at your option) any later version.
  
     This program is distributed in the hope that it will be useful,
     but WITHOUT ANY WARRANTY; without even the implied warranty of
     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
     GNU General Public License for more details.
  
     You should have received a copy of the GNU General Public License
     along with this program.  If not, see <https://www.gnu.org/licenses/>.  */
  
  /* Written by Bruno Haible <bruno@clisp.org>, 2005.  */
  
  #include <config.h>
  
  /* Whether to enable locking.
     Uncomment this to get a test program without locking, to verify that
     it crashes.  */
  #define ENABLE_LOCKING 1
  
  /* Which tests to perform.
     Uncomment some of these, to verify that all tests crash if no locking
     is enabled.  */
  #define DO_TEST_LOCK 1
  #define DO_TEST_RECURSIVE_LOCK 1
  #define DO_TEST_ONCE 1
  
  /* Whether to help the scheduler through explicit thrd_yield().
     Uncomment this to see if the operating system has a fair scheduler.  */
  #define EXPLICIT_YIELD 1
  
  /* Whether to print debugging messages.  */
  #define ENABLE_DEBUGGING 0
  
  /* Number of simultaneous threads.  */
  #define THREAD_COUNT 10
  
  /* Number of operations performed in each thread.
     This is quite high, because with a smaller count, say 5000, we often get
     an "OK" result even without ENABLE_LOCKING (on Linux/x86).  */
  #define REPEAT_COUNT 50000
  
  #include <threads.h>
  #include <stdint.h>
  #include <stdio.h>
  #include <stdlib.h>
  #include <string.h>
  
  #include "glthread/lock.h"
  
  #if HAVE_DECL_ALARM
  # include <signal.h>
  # include <unistd.h>
  #endif
  
  #include "macros.h"
  #include "atomic-int-isoc.h"
  
  #if ENABLE_DEBUGGING
  # define dbgprintf printf
  #else
  # define dbgprintf if (0) printf
  #endif
  
  #if EXPLICIT_YIELD
  # define yield() thrd_yield ()
  #else
  # define yield()
  #endif
  
  /* Returns a reference to the current thread as a pointer, for debugging.  */
  #if defined __MVS__
    /* On IBM z/OS, pthread_t is a struct with an 8-byte '__' field.
       The first three bytes of this field appear to uniquely identify a
       pthread_t, though not necessarily representing a pointer.  */
  # define thrd_current_pointer() (*((void **) thrd_current ().__))
  #elif defined __sun
    /* On Solaris, thrd_t is merely an 'unsigned int'.  */
  # define thrd_current_pointer() ((void *) (uintptr_t) thrd_current ())
  #else
  # define thrd_current_pointer() ((void *) thrd_current ())
  #endif
  
  #define ACCOUNT_COUNT 4
  
  static int account[ACCOUNT_COUNT];
  
  static int
  random_account (void)
  {
    return ((unsigned int) rand () >> 3) % ACCOUNT_COUNT;
  }
  
  static void
  check_accounts (void)
  {
    int i, sum;
  
    sum = 0;
    for (i = 0; i < ACCOUNT_COUNT; i++)
      sum += account[i];
    if (sum != ACCOUNT_COUNT * 1000)
      abort ();
  }
  
  
  /* ------------------- Test normal (non-recursive) locks ------------------- */
  
  /* Test normal locks by having several bank accounts and several threads
     which shuffle around money between the accounts and another thread
     checking that all the money is still there.  */
  
  static mtx_t my_lock;
  
  static int
  lock_mutator_thread (void *arg)
  {
    int repeat;
  
    for (repeat = REPEAT_COUNT; repeat > 0; repeat--)
      {
        int i1, i2, value;
  
        dbgprintf ("Mutator %p before lock\n", thrd_current_pointer ());
        ASSERT (mtx_lock (&my_lock) == thrd_success);
        dbgprintf ("Mutator %p after  lock\n", thrd_current_pointer ());
  
        i1 = random_account ();
        i2 = random_account ();
        value = ((unsigned int) rand () >> 3) % 10;
        account[i1] += value;
        account[i2] -= value;
  
        dbgprintf ("Mutator %p before unlock\n", thrd_current_pointer ());
        ASSERT (mtx_unlock (&my_lock) == thrd_success);
        dbgprintf ("Mutator %p after  unlock\n", thrd_current_pointer ());
  
        dbgprintf ("Mutator %p before check lock\n", thrd_current_pointer ());
        ASSERT (mtx_lock (&my_lock) == thrd_success);
        check_accounts ();
        ASSERT (mtx_unlock (&my_lock) == thrd_success);
        dbgprintf ("Mutator %p after  check unlock\n", thrd_current_pointer ());
  
        yield ();
      }
  
    dbgprintf ("Mutator %p dying.\n", thrd_current_pointer ());
    return 0;
  }
  
  static struct atomic_int lock_checker_done;
  
  static int
  lock_checker_thread (void *arg)
  {
    while (get_atomic_int_value (&lock_checker_done) == 0)
      {
        dbgprintf ("Checker %p before check lock\n", thrd_current_pointer ());
        ASSERT (mtx_lock (&my_lock) == thrd_success);
        check_accounts ();
        ASSERT (mtx_unlock (&my_lock) == thrd_success);
        dbgprintf ("Checker %p after  check unlock\n", thrd_current_pointer ());
  
        yield ();
      }
  
    dbgprintf ("Checker %p dying.\n", thrd_current_pointer ());
    return 0;
  }
  
  static void
  test_mtx_plain (void)
  {
    int i;
    thrd_t checkerthread;
    thrd_t threads[THREAD_COUNT];
  
    /* Initialization.  */
    for (i = 0; i < ACCOUNT_COUNT; i++)
      account[i] = 1000;
    init_atomic_int (&lock_checker_done);
    set_atomic_int_value (&lock_checker_done, 0);
  
    /* Spawn the threads.  */
    ASSERT (thrd_create (&checkerthread, lock_checker_thread, NULL)
            == thrd_success);
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_create (&threads[i], lock_mutator_thread, NULL)
              == thrd_success);
  
    /* Wait for the threads to terminate.  */
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_join (threads[i], NULL) == thrd_success);
    set_atomic_int_value (&lock_checker_done, 1);
    ASSERT (thrd_join (checkerthread, NULL) == thrd_success);
    check_accounts ();
  }
  
  
  /* -------------------------- Test recursive locks -------------------------- */
  
  /* Test recursive locks by having several bank accounts and several threads
     which shuffle around money between the accounts (recursively) and another
     thread checking that all the money is still there.  */
  
  static mtx_t my_reclock;
  
  static void
  recshuffle (void)
  {
    int i1, i2, value;
  
    dbgprintf ("Mutator %p before lock\n", thrd_current_pointer ());
    ASSERT (mtx_lock (&my_reclock) == thrd_success);
    dbgprintf ("Mutator %p after  lock\n", thrd_current_pointer ());
  
    i1 = random_account ();
    i2 = random_account ();
    value = ((unsigned int) rand () >> 3) % 10;
    account[i1] += value;
    account[i2] -= value;
  
    /* Recursive with probability 0.5.  */
    if (((unsigned int) rand () >> 3) % 2)
      recshuffle ();
  
    dbgprintf ("Mutator %p before unlock\n", thrd_current_pointer ());
    ASSERT (mtx_unlock (&my_reclock) == thrd_success);
    dbgprintf ("Mutator %p after  unlock\n", thrd_current_pointer ());
  }
  
  static int
  reclock_mutator_thread (void *arg)
  {
    int repeat;
  
    for (repeat = REPEAT_COUNT; repeat > 0; repeat--)
      {
        recshuffle ();
  
        dbgprintf ("Mutator %p before check lock\n", thrd_current_pointer ());
        ASSERT (mtx_lock (&my_reclock) == thrd_success);
        check_accounts ();
        ASSERT (mtx_unlock (&my_reclock) == thrd_success);
        dbgprintf ("Mutator %p after  check unlock\n", thrd_current_pointer ());
  
        yield ();
      }
  
    dbgprintf ("Mutator %p dying.\n", thrd_current_pointer ());
    return 0;
  }
  
  static struct atomic_int reclock_checker_done;
  
  static int
  reclock_checker_thread (void *arg)
  {
    while (get_atomic_int_value (&reclock_checker_done) == 0)
      {
        dbgprintf ("Checker %p before check lock\n", thrd_current_pointer ());
        ASSERT (mtx_lock (&my_reclock) == thrd_success);
        check_accounts ();
        ASSERT (mtx_unlock (&my_reclock) == thrd_success);
        dbgprintf ("Checker %p after  check unlock\n", thrd_current_pointer ());
  
        yield ();
      }
  
    dbgprintf ("Checker %p dying.\n", thrd_current_pointer ());
    return 0;
  }
  
  static void
  test_mtx_recursive (void)
  {
    int i;
    thrd_t checkerthread;
    thrd_t threads[THREAD_COUNT];
  
    /* Initialization.  */
    for (i = 0; i < ACCOUNT_COUNT; i++)
      account[i] = 1000;
    init_atomic_int (&reclock_checker_done);
    set_atomic_int_value (&reclock_checker_done, 0);
  
    /* Spawn the threads.  */
    ASSERT (thrd_create (&checkerthread, reclock_checker_thread, NULL)
            == thrd_success);
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_create (&threads[i], reclock_mutator_thread, NULL)
              == thrd_success);
  
    /* Wait for the threads to terminate.  */
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_join (threads[i], NULL) == thrd_success);
    set_atomic_int_value (&reclock_checker_done, 1);
    ASSERT (thrd_join (checkerthread, NULL) == thrd_success);
    check_accounts ();
  }
  
  
  /* ------------------------ Test once-only execution ------------------------ */
  
  /* Test once-only execution by having several threads attempt to grab a
     once-only task simultaneously (triggered by releasing a read-write lock).  */
  
  static once_flag fresh_once = ONCE_FLAG_INIT;
  static int ready[THREAD_COUNT];
  static mtx_t ready_lock[THREAD_COUNT];
  #if ENABLE_LOCKING
  static gl_rwlock_t fire_signal[REPEAT_COUNT];
  #else
  static volatile int fire_signal_state;
  #endif
  static once_flag once_control;
  static int performed;
  static mtx_t performed_lock;
  
  static void
  once_execute (void)
  {
    ASSERT (mtx_lock (&performed_lock) == thrd_success);
    performed++;
    ASSERT (mtx_unlock (&performed_lock) == thrd_success);
  }
  
  static int
  once_contender_thread (void *arg)
  {
    int id = (int) (intptr_t) arg;
    int repeat;
  
    for (repeat = 0; repeat <= REPEAT_COUNT; repeat++)
      {
        /* Tell the main thread that we're ready.  */
        ASSERT (mtx_lock (&ready_lock[id]) == thrd_success);
        ready[id] = 1;
        ASSERT (mtx_unlock (&ready_lock[id]) == thrd_success);
  
        if (repeat == REPEAT_COUNT)
          break;
  
        dbgprintf ("Contender %p waiting for signal for round %d\n",
                   thrd_current_pointer (), repeat);
  #if ENABLE_LOCKING
        /* Wait for the signal to go.  */
        gl_rwlock_rdlock (fire_signal[repeat]);
        /* And don't hinder the others (if the scheduler is unfair).  */
        gl_rwlock_unlock (fire_signal[repeat]);
  #else
        /* Wait for the signal to go.  */
        while (fire_signal_state <= repeat)
          yield ();
  #endif
        dbgprintf ("Contender %p got the     signal for round %d\n",
                   thrd_current_pointer (), repeat);
  
        /* Contend for execution.  */
        call_once (&once_control, once_execute);
      }
  
    return 0;
  }
  
  static void
  test_once (void)
  {
    int i, repeat;
    thrd_t threads[THREAD_COUNT];
  
    /* Initialize all variables.  */
    for (i = 0; i < THREAD_COUNT; i++)
      {
        ready[i] = 0;
        ASSERT (mtx_init (&ready_lock[i], mtx_plain) == thrd_success);
      }
  #if ENABLE_LOCKING
    for (i = 0; i < REPEAT_COUNT; i++)
      gl_rwlock_init (fire_signal[i]);
  #else
    fire_signal_state = 0;
  #endif
  
  #if ENABLE_LOCKING
    /* Block all fire_signals.  */
    for (i = REPEAT_COUNT-1; i >= 0; i--)
      gl_rwlock_wrlock (fire_signal[i]);
  #endif
  
    /* Spawn the threads.  */
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_create (&threads[i],
                           once_contender_thread, (void *) (intptr_t) i)
              == thrd_success);
  
    for (repeat = 0; repeat <= REPEAT_COUNT; repeat++)
      {
        /* Wait until every thread is ready.  */
        dbgprintf ("Main thread before synchronizing for round %d\n", repeat);
        for (;;)
          {
            int ready_count = 0;
            for (i = 0; i < THREAD_COUNT; i++)
              {
                ASSERT (mtx_lock (&ready_lock[i]) == thrd_success);
                ready_count += ready[i];
                ASSERT (mtx_unlock (&ready_lock[i]) == thrd_success);
              }
            if (ready_count == THREAD_COUNT)
              break;
            yield ();
          }
        dbgprintf ("Main thread after  synchronizing for round %d\n", repeat);
  
        if (repeat > 0)
          {
            /* Check that exactly one thread executed the once_execute()
               function.  */
            if (performed != 1)
              abort ();
          }
  
        if (repeat == REPEAT_COUNT)
          break;
  
        /* Preparation for the next round: Initialize once_control.  */
        memcpy (&once_control, &fresh_once, sizeof (once_flag));
  
        /* Preparation for the next round: Reset the performed counter.  */
        performed = 0;
  
        /* Preparation for the next round: Reset the ready flags.  */
        for (i = 0; i < THREAD_COUNT; i++)
          {
            ASSERT (mtx_lock (&ready_lock[i]) == thrd_success);
            ready[i] = 0;
            ASSERT (mtx_unlock (&ready_lock[i]) == thrd_success);
          }
  
        /* Signal all threads simultaneously.  */
        dbgprintf ("Main thread giving signal for round %d\n", repeat);
  #if ENABLE_LOCKING
        gl_rwlock_unlock (fire_signal[repeat]);
  #else
        fire_signal_state = repeat + 1;
  #endif
      }
  
    /* Wait for the threads to terminate.  */
    for (i = 0; i < THREAD_COUNT; i++)
      ASSERT (thrd_join (threads[i], NULL) == thrd_success);
  }
  
  
  /* -------------------------------------------------------------------------- */
  
  int
  main ()
  {
  #if HAVE_DECL_ALARM
    /* Declare failure if test takes too long, by using default abort
       caused by SIGALRM.  */
    int alarm_value = 600;
    signal (SIGALRM, SIG_DFL);
    alarm (alarm_value);
  #endif
  
    ASSERT (mtx_init (&my_lock, mtx_plain) == thrd_success);
    ASSERT (mtx_init (&my_reclock, mtx_plain | mtx_recursive) == thrd_success);
    ASSERT (mtx_init (&performed_lock, mtx_plain) == thrd_success);
  
  #if DO_TEST_LOCK
    printf ("Starting test_mtx_plain ..."); fflush (stdout);
    test_mtx_plain ();
    printf (" OK\n"); fflush (stdout);
  #endif
  #if DO_TEST_RECURSIVE_LOCK
    printf ("Starting test_mtx_recursive ..."); fflush (stdout);
    test_mtx_recursive ();
    printf (" OK\n"); fflush (stdout);
  #endif
  #if DO_TEST_ONCE
    printf ("Starting test_once ..."); fflush (stdout);
    test_once ();
    printf (" OK\n"); fflush (stdout);
  #endif
  
    return 0;
  }
  

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