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pigweed / pigweed / pigweed / 9618d8a770149043adf88005f7d102d4e1f6ac35 / . / pw_sync / binary_semaphore_facade_test.cc
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// Copyright 2020 The Pigweed Authors
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not
// use this file except in compliance with the License. You may obtain a copy of
// the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations under
// the License.
#include <chrono>
#include "gtest/gtest.h"
#include "pw_chrono/system_clock.h"
#include "pw_sync/binary_semaphore.h"
using pw::chrono::SystemClock;
namespace pw::sync {
namespace {
extern "C" {
// Functions defined in binary_semaphore_facade_test_c.c which call the API
// from C.
void pw_sync_BinarySemaphore_CallRelease(pw_sync_BinarySemaphore* semaphore);
void pw_sync_BinarySemaphore_CallAcquire(pw_sync_BinarySemaphore* semaphore);
bool pw_sync_BinarySemaphore_CallTryAcquire(pw_sync_BinarySemaphore* semaphore);
bool pw_sync_BinarySemaphore_CallTryAcquireFor(
pw_sync_BinarySemaphore* semaphore,
pw_chrono_SystemClock_TickCount for_at_least);
bool pw_sync_BinarySemaphore_CallTryAcquireUntil(
pw_sync_BinarySemaphore* semaphore,
pw_chrono_SystemClock_TimePoint until_at_least);
ptrdiff_t pw_sync_BinarySemaphore_CallMax(void);
} // extern "C"
static constexpr auto kArbitraryDuration = std::chrono::milliseconds(42);
// We can't control the SystemClock's period configuration, so just in case
// duration cannot be accurately expressed in integer ticks, round the
// duration w/ duration_cast.
static constexpr auto kRoundedArbitraryDuration =
std::chrono::duration_cast<SystemClock::duration>(kArbitraryDuration);
static constexpr pw_chrono_SystemClock_TickCount kRoundedArbitraryDurationInC =
kRoundedArbitraryDuration.count();
TEST(BinarySemaphore, EmptyInitialState) {
BinarySemaphore semaphore;
EXPECT_FALSE(semaphore.try_acquire());
}
// TODO(pwbug/291): Add real concurrency tests once we have pw::thread.
TEST(BinarySemaphore, Release) {
BinarySemaphore semaphore;
semaphore.release();
semaphore.release();
semaphore.acquire();
// Ensure it fails when empty.
EXPECT_FALSE(semaphore.try_acquire());
}
BinarySemaphore empty_initial_semaphore;
TEST(BinarySemaphore, EmptyInitialStateStatic) {
EXPECT_FALSE(empty_initial_semaphore.try_acquire());
}
BinarySemaphore release_semaphore;
TEST(BinarySemaphore, ReleaseStatic) {
release_semaphore.release();
release_semaphore.release();
release_semaphore.acquire();
// Ensure it fails when empty.
EXPECT_FALSE(release_semaphore.try_acquire());
}
TEST(BinarySemaphore, TryAcquireFor) {
BinarySemaphore semaphore;
semaphore.release();
SystemClock::time_point before = SystemClock::now();
EXPECT_TRUE(semaphore.try_acquire_for(kRoundedArbitraryDuration));
SystemClock::duration time_elapsed = SystemClock::now() - before;
EXPECT_LT(time_elapsed, kRoundedArbitraryDuration);
// Ensure it blocks and fails when empty.
before = SystemClock::now();
EXPECT_FALSE(semaphore.try_acquire_for(kRoundedArbitraryDuration));
time_elapsed = SystemClock::now() - before;
EXPECT_GE(time_elapsed, kRoundedArbitraryDuration);
}
TEST(BinarySemaphore, TryAcquireUntil) {
BinarySemaphore semaphore;
semaphore.release();
const SystemClock::time_point deadline =
SystemClock::now() + kRoundedArbitraryDuration;
EXPECT_TRUE(semaphore.try_acquire_until(deadline));
EXPECT_LT(SystemClock::now(), deadline);
// Ensure it blocks and fails when empty.
EXPECT_FALSE(semaphore.try_acquire_until(deadline));
EXPECT_GE(SystemClock::now(), deadline);
}
TEST(BinarySemaphore, EmptyInitialStateInC) {
BinarySemaphore semaphore;
EXPECT_FALSE(pw_sync_BinarySemaphore_CallTryAcquire(&semaphore));
}
TEST(BinarySemaphore, ReleaseInC) {
BinarySemaphore semaphore;
pw_sync_BinarySemaphore_CallRelease(&semaphore);
pw_sync_BinarySemaphore_CallRelease(&semaphore);
pw_sync_BinarySemaphore_CallAcquire(&semaphore);
// Ensure it fails when empty.
EXPECT_FALSE(pw_sync_BinarySemaphore_CallTryAcquire(&semaphore));
}
TEST(BinarySemaphore, TryAcquireForInC) {
BinarySemaphore semaphore;
pw_sync_BinarySemaphore_CallRelease(&semaphore);
pw_chrono_SystemClock_TimePoint before = pw_chrono_SystemClock_Now();
ASSERT_TRUE(pw_sync_BinarySemaphore_CallTryAcquireFor(
&semaphore, kRoundedArbitraryDurationInC));
pw_chrono_SystemClock_TickCount time_elapsed =
pw_chrono_SystemClock_Now().ticks_since_epoch - before.ticks_since_epoch;
EXPECT_LT(time_elapsed, kRoundedArbitraryDurationInC);
// Ensure it blocks and fails when empty.
before = pw_chrono_SystemClock_Now();
EXPECT_FALSE(pw_sync_BinarySemaphore_CallTryAcquireFor(
&semaphore, kRoundedArbitraryDurationInC));
time_elapsed =
pw_chrono_SystemClock_Now().ticks_since_epoch - before.ticks_since_epoch;
EXPECT_GE(time_elapsed, kRoundedArbitraryDurationInC);
}
TEST(BinarySemaphore, TryAcquireUntilInC) {
BinarySemaphore semaphore;
pw_sync_BinarySemaphore_CallRelease(&semaphore);
pw_chrono_SystemClock_TimePoint deadline;
deadline.ticks_since_epoch = pw_chrono_SystemClock_Now().ticks_since_epoch +
kRoundedArbitraryDurationInC;
ASSERT_TRUE(
pw_sync_BinarySemaphore_CallTryAcquireUntil(&semaphore, deadline));
EXPECT_LT(pw_chrono_SystemClock_Now().ticks_since_epoch,
deadline.ticks_since_epoch);
// Ensure it blocks and fails when empty.
EXPECT_FALSE(
pw_sync_BinarySemaphore_CallTryAcquireUntil(&semaphore, deadline));
EXPECT_GE(pw_chrono_SystemClock_Now().ticks_since_epoch,
deadline.ticks_since_epoch);
}
TEST(BinarySemaphore, MaxInC) {
EXPECT_EQ(BinarySemaphore::max(), pw_sync_BinarySemaphore_Max());
}
} // namespace
} // namespace pw::sync