// { dg-do run } // { dg-additional-options "-pthread" { target pthread } } // { dg-require-effective-target c++11 } // { dg-require-gthreads "" } // Copyright (C) 2010-2024 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library 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, or (at your option) // any later version. // This library 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 library; see the file COPYING3. If not see // . #include #include struct unreliable_lock { std::mutex m; std::unique_lock l; static int count; static int throw_on; static int lock_on; unreliable_lock() : l(m, std::defer_lock) { } ~unreliable_lock() { VERIFY( !l.owns_lock() ); } void lock() { if (count == throw_on) throw throw_on; ++count; l.lock(); } bool try_lock() { if (count == throw_on) throw throw_on; std::unique_lock l2(m, std::defer_lock); if (count == lock_on) l2.lock(); ++count; return l.try_lock(); } void unlock() { VERIFY( l.owns_lock() ); l.unlock(); } }; int unreliable_lock::count = 0; int unreliable_lock::throw_on = -1; int unreliable_lock::lock_on = -1; void test01() { unreliable_lock l1, l2, l3; std::mutex m1, m2, m3; try { unreliable_lock::count = 0; std::lock(l1, l2, l3); VERIFY( unreliable_lock::count == 3 ); l1.unlock(); l2.unlock(); l3.unlock(); } catch (...) { VERIFY( false ); } // Repeat with non-heterogeneous arguments try { unreliable_lock::count = 0; std::lock(l1, l2, l3, m1); VERIFY( unreliable_lock::count == 3 ); l1.unlock(); l2.unlock(); l3.unlock(); VERIFY( !m1.try_lock() ); // already locked m1.unlock(); } catch (...) { VERIFY( false ); } try { unreliable_lock::count = 0; std::lock(m1, l1, l2, l3); VERIFY( unreliable_lock::count == 3 ); VERIFY( !m1.try_lock() ); // already locked m1.unlock(); l1.unlock(); l2.unlock(); l3.unlock(); } catch (...) { VERIFY( false ); } try { unreliable_lock::count = 0; std::lock(l1, m1, l2, m2, l3, m3); VERIFY( unreliable_lock::count == 3 ); l1.unlock(); l2.unlock(); l3.unlock(); VERIFY( !m1.try_lock() ); // already locked VERIFY( !m2.try_lock() ); // already locked VERIFY( !m3.try_lock() ); // already locked m1.unlock(); m2.unlock(); m3.unlock(); } catch (...) { VERIFY( false ); } } void test02() { // test behaviour when a lock is already held try { unreliable_lock::lock_on = 1; while (unreliable_lock::lock_on < 3) { unreliable_lock::count = 0; unreliable_lock l1, l2, l3; std::lock(l1, l2, l3); VERIFY( unreliable_lock::count > 3 ); l1.unlock(); l2.unlock(); l3.unlock(); ++unreliable_lock::lock_on; } } catch (...) { VERIFY( false ); } // Repeat with non-heterogeneous arguments try { unreliable_lock::lock_on = 1; while (unreliable_lock::lock_on < 3) { unreliable_lock::count = 0; unreliable_lock l1, l2, l3; std::mutex m1; std::lock(l1, l2, l3, m1); VERIFY( unreliable_lock::count > 3 ); l1.unlock(); l2.unlock(); l3.unlock(); VERIFY( !m1.try_lock() ); // already locked m1.unlock(); ++unreliable_lock::lock_on; } } catch (...) { VERIFY( false ); } } void test03() { // test behaviour when an exception is thrown unreliable_lock::throw_on = 0; while (unreliable_lock::throw_on < 3) { unreliable_lock::count = 0; unreliable_lock l1, l2, l3; bool test = false; try { std::lock(l1, l2, l3); } catch (...) { test = true; } VERIFY( test ); ++unreliable_lock::throw_on; } // Repeat with non-heterogeneous arguments unreliable_lock::throw_on = 0; while (unreliable_lock::throw_on < 3) { unreliable_lock::count = 0; unreliable_lock l1, l2, l3; std::mutex m1; bool test = false; try { std::lock(l1, l2, l3, m1); } catch (...) { test = true; } VERIFY( test ); VERIFY( m1.try_lock() ); // m1 was not left locked by failed std::lock m1.unlock(); ++unreliable_lock::throw_on; } unreliable_lock::throw_on = 0; while (unreliable_lock::throw_on < 3) { unreliable_lock::count = 0; unreliable_lock l1, l2, l3; std::mutex m1; bool test = false; try { std::lock(m1, l1, l2, l3); } catch (...) { test = true; } VERIFY( test ); VERIFY( m1.try_lock() ); // m1 was not left locked by failed std::lock m1.unlock(); ++unreliable_lock::throw_on; } } int main() { test01(); test02(); test03(); return 0; }