X-Git-Url: http://info.iut-bm.univ-fcomte.fr/pub/gitweb/simgrid.git/blobdiff_plain/6e16b58747eec5f035a6ffd4f5344d277dd1e753..ae4b6cc2c552e112d81d613060466b16f474dc67:/include/simgrid/simix/blocking_simcall.hpp diff --git a/include/simgrid/simix/blocking_simcall.hpp b/include/simgrid/simix/blocking_simcall.hpp index 59f688cab0..5389d8fce5 100644 --- a/include/simgrid/simix/blocking_simcall.hpp +++ b/include/simgrid/simix/blocking_simcall.hpp @@ -7,14 +7,13 @@ #ifndef SIMGRID_SIMIX_BLOCKING_SIMCALL_HPP #define SIMGRID_SIMIX_BLOCKING_SIMCALL_HPP -#include - #include +#include +#include +#include #include -#include - #include #include #include @@ -27,24 +26,28 @@ namespace simix { XBT_PUBLIC(void) unblock(smx_process_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`. The kernel blocks the actor + * until the Future is ready and: + * + * - either returns the value wrapped in the future to the actor; + * + * - or raises the exception stored in the future in 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. + * 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` - * @return Value of the kernel future - * @exception Exception from the kernel future + * @param code Kernel code returning a `simgrid::kernel::Future` + * @return Value of the kernel future + * @exception Exception from the kernel future */ template -auto blocking_simcall(F code) -> decltype(code().get()) +auto kernelSync(F code) -> decltype(code().get()) { typedef decltype(code().get()) T; if (SIMIX_is_maestro()) @@ -56,7 +59,7 @@ auto blocking_simcall(F code) -> decltype(code().get()) simcall_run_blocking([&result, self, &code]{ try { auto future = code(); - future.then([&result, self](simgrid::kernel::Future value) { + future.then_([&result, self](simgrid::kernel::Future value) { simgrid::xbt::setPromise(result, value); simgrid::simix::unblock(self); }); @@ -70,6 +73,11 @@ auto blocking_simcall(F code) -> decltype(code().get()) } /** 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 Future { public: @@ -86,7 +94,7 @@ public: simcall_run_blocking([this, &result, self]{ try { // When the kernel future is ready... - this->future_.then([this, &result, self](simgrid::kernel::Future value) { + this->future_.then_([this, &result, self](simgrid::kernel::Future value) { // ... wake up the process with the result of the kernel future. simgrid::xbt::setPromise(result, value); simgrid::simix::unblock(self); @@ -99,9 +107,35 @@ public: }); return result.get(); } - // TODO, wait() - // TODO, wait_for() - // TODO, wait_until() + bool is_ready() const + { + if (!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_process_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 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 future_; @@ -110,19 +144,19 @@ private: /** Start some asynchronous work * * @param code SimGrid kernel code which returns a simgrid::kernel::Future - * @return User future + * @return Actor future */ template -auto asynchronous_simcall(F code) +auto kernelAsync(F code) -> Future { 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 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(std::move(future)); }