#ifndef SIMGRID_SIMIX_BLOCKING_SIMCALL_HPP
#define SIMGRID_SIMIX_BLOCKING_SIMCALL_HPP
-#include <iostream>
-
#include <exception>
+#include <functional>
+#include <future>
+#include <utility>
#include <xbt/sysdep.h>
-#include <future>
-
#include <xbt/future.hpp>
#include <simgrid/kernel/future.hpp>
#include <simgrid/simix.h>
namespace simgrid {
namespace simix {
-XBT_PUBLIC(void) unblock(smx_process_t process);
+XBT_PUBLIC(void) unblock(smx_actor_t process);
-/** Execute some code in kernel mode and wakes up the process when
+/** Execute some code in kernel mode and wakes up the actor when
* the result is available.
*
- * The code given is executed in SimGrid kernel and expected to return
- * a `simgrid::kernel::Future`. The current process is resumed whenever
- * the Future becomes ready and gets the value or exception of the future:
+ * It is given a callback which is executed in the SimGrid kernel and
+ * returns a `simgrid::kernel::Future<T>`. The kernel blocks the actor
+ * until the Future is ready and:
+ *
+ * - either returns the value wrapped in the future to the actor;
*
- * This can be used to implement blocking calls in without adding new simcalls.
- * One downside of this approach is that we don't have any semantic on what
- * the process is waiting. This might be a problem for the model-checker and
- * we'll have to device a way to make it work.
+ * - or raises the exception stored in the future in the actor.
*
- * @param code Kernel code returning a `simgrid::kernel::Future<T>`
- * @return Value of the kernel future
- * @exception Exception from the kernel future
+ * This can be used to implement blocking calls without adding new simcalls.
+ * One downside of this approach is that we don't have any semantic on what
+ * the actor is waiting. This might be a problem for the model-checker and
+ * we'll have to devise a way to make it work.
+ *
+ * @param code Kernel code returning a `simgrid::kernel::Future<T>`
+ * @return Value of the kernel future
+ * @exception Exception from the kernel future
*/
template<class F>
-auto blocking_simcall(F code) -> decltype(code().get())
+auto kernelSync(F code) -> decltype(code().get())
{
typedef decltype(code().get()) T;
if (SIMIX_is_maestro())
xbt_die("Can't execute blocking call in kernel mode");
- smx_process_t self = SIMIX_process_self();
+ smx_actor_t self = SIMIX_process_self();
simgrid::xbt::Result<T> result;
simcall_run_blocking([&result, self, &code]{
try {
auto future = code();
- future.then([&result, self](simgrid::kernel::Future<T> value) {
+ future.then_([&result, self](simgrid::kernel::Future<T> value) {
simgrid::xbt::setPromise(result, value);
simgrid::simix::unblock(self);
});
}
/** A blocking (`wait()`-based) future for SIMIX processes */
+// TODO, .wait_for()
+// TODO, .wait_until()
+// TODO, SharedFuture
+// TODO, simgrid::simix::when_all - wait for all future to be ready (this one is simple!)
+// TODO, simgrid::simix::when_any - wait for any future to be ready
template <class T>
class Future {
public:
bool valid() const { return future_.valid(); }
T get()
{
- if (!valid())
+ if (not valid())
throw std::future_error(std::future_errc::no_state);
- smx_process_t self = SIMIX_process_self();
+ smx_actor_t self = SIMIX_process_self();
simgrid::xbt::Result<T> result;
simcall_run_blocking([this, &result, self]{
try {
// When the kernel future is ready...
- this->future_.then([this, &result, self](simgrid::kernel::Future<T> value) {
+ this->future_.then_([&result, self](simgrid::kernel::Future<T> value) {
// ... wake up the process with the result of the kernel future.
simgrid::xbt::setPromise(result, value);
simgrid::simix::unblock(self);
});
return result.get();
}
- // TODO, wait()
- // TODO, wait_for()
- // TODO, wait_until()
+ bool is_ready() const
+ {
+ if (not valid())
+ throw std::future_error(std::future_errc::no_state);
+ return future_.is_ready();
+ }
+ void wait()
+ {
+ // The future is ready! We don't have to wait:
+ if (this->is_ready())
+ return;
+ // The future is not ready. We have to delegate to the SimGrid kernel:
+ std::exception_ptr exception;
+ smx_actor_t self = SIMIX_process_self();
+ simcall_run_blocking([this, &exception, self]{
+ try {
+ // When the kernel future is ready...
+ this->future_.then_([this, self](simgrid::kernel::Future<T> value) {
+ // ...store it the simix kernel and wake up.
+ this->future_ = std::move(value);
+ simgrid::simix::unblock(self);
+ });
+ }
+ catch (...) {
+ exception = std::current_exception();
+ simgrid::simix::unblock(self);
+ }
+ });
+ }
private:
// We wrap an event-based kernel future:
simgrid::kernel::Future<T> future_;
/** Start some asynchronous work
*
* @param code SimGrid kernel code which returns a simgrid::kernel::Future
- * @return User future
+ * @return Actor future
*/
template<class F>
-auto asynchronous_simcall(F code)
+auto kernelAsync(F code)
-> Future<decltype(code().get())>
{
typedef decltype(code().get()) T;
- // Execute the code in the kernel and get the kernel simcall:
+ // Execute the code in the kernel and get the kernel future:
simgrid::kernel::Future<T> future =
- simgrid::simix::kernel(std::move(code));
+ simgrid::simix::kernelImmediate(std::move(code));
- // Wrap tyhe kernel simcall in a user simcall:
+ // Wrap the kernel future in a actor future:
return simgrid::simix::Future<T>(std::move(future));
}