#define SIMGRID_SIMIX_HPP
#include <simgrid/simix.h>
-#include <xbt/functional.hpp>
#include <xbt/promise.hpp>
#include <xbt/signal.hpp>
-#include <xbt/utility.hpp>
-#include <boost/heap/fibonacci_heap.hpp>
#include <string>
#include <unordered_map>
-XBT_PUBLIC void simcall_run_kernel(std::function<void()> const& code, simgrid::mc::SimcallInspector* t);
-XBT_PUBLIC void simcall_run_blocking(std::function<void()> const& code, simgrid::mc::SimcallInspector* t);
+XBT_PUBLIC void simcall_run_kernel(std::function<void()> const& code,
+ simgrid::kernel::actor::SimcallObserver* observer);
+XBT_PUBLIC void simcall_run_blocking(std::function<void()> const& code,
+ simgrid::kernel::actor::SimcallObserver* observer);
namespace simgrid {
namespace kernel {
* you may need to wait for that mutex to be unlocked by its current owner.
* Potentially blocking simcall must be issued using simcall_blocking(), right below in this file.
*/
-template <class F> typename std::result_of_t<F()> simcall(F&& code, mc::SimcallInspector* t = nullptr)
+template <class F> typename std::result_of_t<F()> simcall(F&& code, SimcallObserver* observer = nullptr)
{
// If we are in the maestro, we take the fast path and execute the
// code directly without simcall marshalling/unmarshalling/dispatch:
// conveniently handles the success/failure value for us.
using R = typename std::result_of_t<F()>;
simgrid::xbt::Result<R> result;
- simcall_run_kernel([&result, &code] { simgrid::xbt::fulfill_promise(result, std::forward<F>(code)); }, t);
+ simcall_run_kernel([&result, &code] { simgrid::xbt::fulfill_promise(result, std::forward<F>(code)); }, observer);
return result.get();
}
* This is very similar to simcall() right above, but the calling actor will not get rescheduled until
* actor->simcall_answer() is called explicitly.
*
- * Since the return value does not come from the lambda directly, its type cannot be guessed automatically and must
- * be provided as template parameter.
- *
* This is meant for blocking actions. For example, locking a mutex is a blocking simcall.
* First it's a simcall because that's obviously a modification of the world. Then, that's a blocking simcall because if
* the mutex happens not to be free, the actor is added to a queue of actors in the mutex. Every mutex->unlock() takes
* right away with actor->simcall_answer() once the mutex is marked as locked.
*
* If your code never calls actor->simcall_answer() itself, the actor will never return from its simcall.
+ *
+ * The return value is obtained from observer->get_result() if it exists. Otherwise void is returned.
*/
-template <class R, class F> R simcall_blocking(F&& code, mc::SimcallInspector* t = nullptr)
+template <class F> void simcall_blocking(F&& code, SimcallObserver* observer = nullptr)
{
- // If we are in the maestro, we take the fast path and execute the
- // code directly without simcall marshalling/unmarshalling/dispatch:
- if (SIMIX_is_maestro())
- return std::forward<F>(code)();
+ xbt_assert(not SIMIX_is_maestro(), "Cannot execute blocking call in kernel mode");
- // If we are in the application, pass the code to the maestro which
- // executes it for us and reports the result. We use a std::future which
+ // Pass the code to the maestro which executes it for us and reports the result. We use a std::future which
// conveniently handles the success/failure value for us.
- simgrid::xbt::Result<R> result;
- simcall_run_blocking([&result, &code] { simgrid::xbt::fulfill_promise(result, std::forward<F>(code)); }, t);
- return result.get();
+ simgrid::xbt::Result<void> result;
+ simcall_run_blocking([&result, &code] { simgrid::xbt::fulfill_promise(result, std::forward<F>(code)); }, observer);
+ result.get(); // rethrow stored exception if any
+}
+
+template <class F, class Observer>
+auto simcall_blocking(F&& code, Observer* observer) -> decltype(observer->get_result())
+{
+ simcall_blocking(std::forward<F>(code), static_cast<SimcallObserver*>(observer));
+ return observer->get_result();
}
} // namespace actor
} // namespace kernel
namespace simgrid {
namespace simix {
-inline auto& simix_timers() // avoid static initialization order fiasco
-{
- using TimerQelt = std::pair<double, Timer*>;
- static boost::heap::fibonacci_heap<TimerQelt, boost::heap::compare<xbt::HeapComparator<TimerQelt>>> value;
- return value;
-}
-
-/** @brief Timer datatype */
-class Timer {
- double date = 0.0;
-
-public:
- std::remove_reference_t<decltype(simix_timers())>::handle_type handle_;
-
- Timer(double date, simgrid::xbt::Task<void()>&& callback) : date(date), callback(std::move(callback)) {}
-
- simgrid::xbt::Task<void()> callback;
- double get_date() const { return date; }
- void remove();
-
- template <class F> static inline Timer* set(double date, F callback)
- {
- return set(date, simgrid::xbt::Task<void()>(std::move(callback)));
- }
+XBT_PUBLIC void unblock(smx_actor_t process);
- static Timer* set(double date, simgrid::xbt::Task<void()>&& callback);
- static double next() { return simix_timers().empty() ? -1.0 : simix_timers().top().first; }
-};
+// In MC mode, the application sends these pointers to the MC
+xbt_dynar_t simix_global_get_actors_addr();
+xbt_dynar_t simix_global_get_dead_actors_addr();
} // namespace simix
} // namespace simgrid
