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[sonar] Constify pointer and reference parameters in src/s4u/.
[simgrid.git]
/
include
/
simgrid
/
s4u
/
ConditionVariable.hpp
diff --git
a/include/simgrid/s4u/ConditionVariable.hpp
b/include/simgrid/s4u/ConditionVariable.hpp
index
946a2d5
..
8e84127
100644
(file)
--- a/
include/simgrid/s4u/ConditionVariable.hpp
+++ b/
include/simgrid/s4u/ConditionVariable.hpp
@@
-35,8
+35,8
@@
public:
ConditionVariable(ConditionVariable const&) = delete;
ConditionVariable& operator=(ConditionVariable const&) = delete;
ConditionVariable(ConditionVariable const&) = delete;
ConditionVariable& operator=(ConditionVariable const&) = delete;
- friend XBT_PUBLIC void intrusive_ptr_add_ref(
ConditionVariable
* cond);
- friend XBT_PUBLIC void intrusive_ptr_release(
ConditionVariable
* cond);
+ friend XBT_PUBLIC void intrusive_ptr_add_ref(
const ConditionVariable
* cond);
+ friend XBT_PUBLIC void intrusive_ptr_release(
const ConditionVariable
* cond);
#endif
static ConditionVariablePtr create();
#endif
static ConditionVariablePtr create();
@@
-44,8
+44,8
@@
public:
// Wait functions without time:
void wait(MutexPtr lock);
// Wait functions without time:
void wait(MutexPtr lock);
- void wait(
std::unique_lock<Mutex>
& lock);
- template <class P> void wait(
std::unique_lock<Mutex>
& lock, P pred)
+ void wait(
const std::unique_lock<Mutex>
& lock);
+ template <class P> void wait(
const std::unique_lock<Mutex>
& lock, P pred)
{
while (not pred())
wait(lock);
{
while (not pred())
wait(lock);
@@
-53,8
+53,8
@@
public:
// Wait function taking a plain double as time:
// Wait function taking a plain double as time:
- std::cv_status wait_until(
std::unique_lock<Mutex>
& lock, double timeout_time);
- std::cv_status wait_for(
std::unique_lock<Mutex>
& lock, double duration);
+ std::cv_status wait_until(
const std::unique_lock<Mutex>
& lock, double timeout_time);
+ std::cv_status wait_for(
const std::unique_lock<Mutex>
& lock, double duration);
template <class P> bool wait_until(std::unique_lock<Mutex> & lock, double timeout_time, P pred)
{
while (not pred())
template <class P> bool wait_until(std::unique_lock<Mutex> & lock, double timeout_time, P pred)
{
while (not pred())
@@
-62,7
+62,7
@@
public:
return pred();
return true;
}
return pred();
return true;
}
- template <class P> bool wait_for(
std::unique_lock<Mutex>
& lock, double duration, P pred)
+ template <class P> bool wait_for(
const std::unique_lock<Mutex>
& lock, double duration, P pred)
{
return this->wait_until(lock, SIMIX_get_clock() + duration, std::move(pred));
}
{
return this->wait_until(lock, SIMIX_get_clock() + duration, std::move(pred));
}
@@
-70,25
+70,25
@@
public:
// Wait function taking a C++ style time:
template <class Rep, class Period, class P>
// Wait function taking a C++ style time:
template <class Rep, class Period, class P>
- bool wait_for(
std::unique_lock<Mutex>
& lock, std::chrono::duration<Rep, Period> duration, P pred)
+ bool wait_for(
const std::unique_lock<Mutex>
& lock, std::chrono::duration<Rep, Period> duration, P pred)
{
auto seconds = std::chrono::duration_cast<SimulationClockDuration>(duration);
return this->wait_for(lock, seconds.count(), pred);
}
template <class Rep, class Period>
{
auto seconds = std::chrono::duration_cast<SimulationClockDuration>(duration);
return this->wait_for(lock, seconds.count(), pred);
}
template <class Rep, class Period>
- std::cv_status wait_for(
std::unique_lock<Mutex>
& lock, std::chrono::duration<Rep, Period> duration)
+ std::cv_status wait_for(
const std::unique_lock<Mutex>
& lock, std::chrono::duration<Rep, Period> duration)
{
auto seconds = std::chrono::duration_cast<SimulationClockDuration>(duration);
return this->wait_for(lock, seconds.count());
}
template <class Duration>
{
auto seconds = std::chrono::duration_cast<SimulationClockDuration>(duration);
return this->wait_for(lock, seconds.count());
}
template <class Duration>
- std::cv_status wait_until(
std::unique_lock<Mutex>
& lock, const SimulationTimePoint<Duration>& timeout_time)
+ std::cv_status wait_until(
const std::unique_lock<Mutex>
& lock, const SimulationTimePoint<Duration>& timeout_time)
{
auto timeout_native = std::chrono::time_point_cast<SimulationClockDuration>(timeout_time);
return this->wait_until(lock, timeout_native.time_since_epoch().count());
}
template <class Duration, class P>
{
auto timeout_native = std::chrono::time_point_cast<SimulationClockDuration>(timeout_time);
return this->wait_until(lock, timeout_native.time_since_epoch().count());
}
template <class Duration, class P>
- bool wait_until(
std::unique_lock<Mutex>
& lock, const SimulationTimePoint<Duration>& timeout_time, P pred)
+ bool wait_until(
const std::unique_lock<Mutex>
& lock, const SimulationTimePoint<Duration>& timeout_time, P pred)
{
auto timeout_native = std::chrono::time_point_cast<SimulationClockDuration>(timeout_time);
return this->wait_until(lock, timeout_native.time_since_epoch().count(), std::move(pred));
{
auto timeout_native = std::chrono::time_point_cast<SimulationClockDuration>(timeout_time);
return this->wait_until(lock, timeout_native.time_since_epoch().count(), std::move(pred));