llvm-project/libcxxabi/test/guard_test_basic.pass.cpp

156 lines
3.9 KiB
C++

//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// UNSUPPORTED: c++98, c++03
#define TESTING_CXA_GUARD
#include "../src/cxa_guard_impl.h"
#include <cassert>
using namespace __cxxabiv1;
template <class GuardType, class Impl>
struct Tests {
private:
Tests() : g{}, impl(&g) {}
GuardType g;
Impl impl;
uint8_t first_byte() {
uint8_t first;
std::memcpy(&first, &g, 1);
return first;
}
void reset() { g = {}; }
public:
// Test the post conditions on cxa_guard_acquire, cxa_guard_abort, and
// cxa_guard_release. Specifically, that they leave the first byte with
// the value 0 or 1 as specified by the ARM or Itanium specification.
static void test() {
Tests tests;
tests.test_acquire();
tests.test_abort();
tests.test_release();
}
void test_acquire() {
{
reset();
assert(first_byte() == 0);
assert(impl.cxa_guard_acquire() == INIT_IS_PENDING);
assert(first_byte() == 0);
}
{
reset();
assert(first_byte() == 0);
assert(impl.cxa_guard_acquire() == INIT_IS_PENDING);
impl.cxa_guard_release();
assert(first_byte() == 1);
assert(impl.cxa_guard_acquire() == INIT_IS_DONE);
}
}
void test_release() {
{
reset();
assert(first_byte() == 0);
assert(impl.cxa_guard_acquire() == INIT_IS_PENDING);
assert(first_byte() == 0);
impl.cxa_guard_release();
assert(first_byte() == 1);
}
}
void test_abort() {
{
reset();
assert(first_byte() == 0);
assert(impl.cxa_guard_acquire() == INIT_IS_PENDING);
assert(first_byte() == 0);
impl.cxa_guard_abort();
assert(first_byte() == 0);
assert(impl.cxa_guard_acquire() == INIT_IS_PENDING);
assert(first_byte() == 0);
}
}
};
struct NopMutex {
bool lock() {
assert(!is_locked);
is_locked = true;
return false;
}
bool unlock() {
assert(is_locked);
is_locked = false;
return false;
}
private:
bool is_locked = false;
};
NopMutex global_nop_mutex = {};
struct NopCondVar {
bool broadcast() { return false; }
bool wait(NopMutex&) { return false; }
};
NopCondVar global_nop_cond = {};
void NopFutexWait(int*, int) { assert(false); }
void NopFutexWake(int*) { assert(false); }
uint32_t MockGetThreadID() { return 0; }
int main() {
{
#if defined(_LIBCXXABI_HAS_NO_THREADS)
static_assert(CurrentImplementation == Implementation::NoThreads, "");
static_assert(
std::is_same<SelectedImplementation, InitByteNoThreads>::value, "");
#else
static_assert(CurrentImplementation == Implementation::GlobalLock, "");
static_assert(
std::is_same<
SelectedImplementation,
InitByteGlobalMutex<LibcppMutex, LibcppCondVar,
GlobalStatic<LibcppMutex>::instance,
GlobalStatic<LibcppCondVar>::instance>>::value,
"");
#endif
}
{
#if defined(__APPLE__) || defined(__linux__)
assert(PlatformThreadID);
#endif
if (PlatformSupportsThreadID()) {
assert(PlatformThreadID() != 0);
assert(PlatformThreadID() == PlatformThreadID());
}
}
{
Tests<uint32_t, InitByteNoThreads>::test();
Tests<uint64_t, InitByteNoThreads>::test();
}
{
using MutexImpl =
InitByteGlobalMutex<NopMutex, NopCondVar, global_nop_mutex,
global_nop_cond, MockGetThreadID>;
Tests<uint32_t, MutexImpl>::test();
Tests<uint64_t, MutexImpl>::test();
}
{
using FutexImpl =
InitByteFutex<&NopFutexWait, &NopFutexWake, &MockGetThreadID>;
Tests<uint32_t, FutexImpl>::test();
Tests<uint64_t, FutexImpl>::test();
}
}