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/*
* Copyright 2013-2020 Software Radio Systems Limited
*
* This file is part of srsLTE.
*
* srsLTE is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as
* published by the Free Software Foundation, either version 3 of
* the License, or (at your option) any later version.
*
* srsLTE is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#ifndef SRSLTE_FSM_H
#define SRSLTE_FSM_H
#include "srslte/common/logmap.h"
#include "type_utils.h"
#include <cstdio>
#include <limits>
#include <memory>
#include <tuple>
namespace srslte {
//! Transition Type
template <typename NextState>
struct to_state {
using next_state = NextState;
};
template <typename... NextStates>
struct to_states {
template <typename ChosenState>
to_states(to_state<ChosenState>) : state_idx(get_type_index<ChosenState, NextStates...>())
{}
template <typename State>
bool is() const
{
return get_type_index<State, NextStates...>() == state_idx;
}
size_t get_type_idx() const { return state_idx; }
size_t state_idx;
};
//! Return for when there is no state transition
struct same_state {};
//! Forward declaration
template <typename Derived>
class fsm_t;
namespace fsm_details {
//! Visitor to get a state's name string
struct state_name_visitor {
template <typename State>
void operator()(State&& s)
{
name = get_type_name(s);
}
std::string name = "invalid";
};
//! Visitor to convert a to_state<States...> back to a single state
template <typename FSM, typename PrevState>
struct to_state_visitor {
to_state_visitor(FSM* f_, PrevState* p_) : f(f_), p(p_) {}
template <typename State>
void operator()();
FSM* f;
PrevState* p;
};
//! Visitor to call current state enter method for a given FSM
template <typename FSM>
struct enter_visitor {
explicit enter_visitor(FSM* f_) : f(f_) {}
template <typename State>
void operator()(State&& s);
FSM* f;
};
//! Helper metafunctions
template <typename FSM, typename State>
using enable_if_fsm_state = typename std::enable_if<FSM::template can_hold_state<State>()>::type;
template <typename FSM, typename State>
using disable_if_fsm_state = typename std::enable_if<not FSM::template can_hold_state<State>()>::type;
template <typename FSM>
constexpr bool is_fsm()
{
return std::is_base_of<fsm_t<FSM>, FSM>::value;
}
template <typename FSM>
constexpr typename std::enable_if<is_fsm<FSM>(), bool>::type is_subfsm()
{
return FSM::is_nested;
}
template <typename FSM>
constexpr typename std::enable_if<not is_fsm<FSM>(), bool>::type is_subfsm()
{
return false;
}
template <typename FSM>
using enable_if_subfsm = typename std::enable_if<is_subfsm<FSM>()>::type;
template <typename FSM>
using disable_if_subfsm = typename std::enable_if<not is_subfsm<FSM>()>::type;
struct fsm_helper {
//! Metafunction to determine if FSM can hold given State type
template <typename FSM>
using fsm_state_list_type = decltype(std::declval<typename FSM::derived_view>().states);
//! Call FSM/State enter method
template <typename FSM, typename State>
static enable_if_subfsm<State> call_enter(FSM* f, State* s)
{
using init_type = typename fsm_state_list_type<State>::init_state_t;
// set default FSM type
s->derived()->states.template transit<init_type>();
// call FSM enter function
f->enter(*s);
// call initial substate enter
fsm_details::enter_visitor<typename State::derived_view> visitor{s->derived()};
srslte::visit(visitor, s->derived()->states);
}
template <typename FSM, typename State, typename... Args>
static disable_if_subfsm<State> call_enter(FSM* f, State* s)
{
f->enter(*s);
}
//! Stayed in same state
template <typename FSM, typename PrevState>
static void handle_state_change(FSM* f, same_state* s, PrevState* p)
{
// do nothing
}
template <typename FSM, typename PrevState>
static void handle_state_change(FSM* f, to_state<same_state>* s, PrevState* p)
{
// do nothing
}
//! TargetState is type-erased (a choice). Apply its stored type to the fsm current state
template <typename FSM, typename... Args, typename PrevState>
static void handle_state_change(FSM* f, to_states<Args...>* s, PrevState* p)
{
to_state_visitor<FSM, PrevState> visitor{f, p};
srslte::static_visit(visitor, *s);
}
//! Simple state transition in FSM (no same_state of entry in nested FSM)
template <typename FSM, typename State, typename PrevState>
static auto handle_state_change(FSM* f, to_state<State>* s, PrevState* p) -> enable_if_fsm_state<FSM, State>
{
static_assert(not std::is_same<State, PrevState>::value, "State cannot transition to itself.\n");
f->exit(f->states.template get_unchecked<PrevState>());
f->states.template transit<State>();
f->log_h->info("FSM \"%s\": Detected transition \"%s\" -> \"%s\"",
get_type_name<typename FSM::derived_t>().c_str(),
get_type_name<PrevState>().c_str(),
get_type_name<State>().c_str());
call_enter(f, &f->states.template get_unchecked<State>());
}
//! State not present in current FSM. Attempt state transition in parent FSM in the case of NestedFSM
template <typename FSM, typename State, typename PrevState>
static auto handle_state_change(FSM* f, to_state<State>* s, PrevState* p) -> disable_if_fsm_state<FSM, State>
{
static_assert(FSM::is_nested, "State is not present in the FSM list of valid states");
f->exit(f->states.template get_unchecked<PrevState>());
handle_state_change(f->parent_fsm()->derived(), s, static_cast<typename FSM::derived_t*>(f));
}
//! Trigger Event, that will result in a state transition
template <typename FSM, typename Event>
struct trigger_visitor {
trigger_visitor(FSM* f_, Event&& ev_) : f(f_), ev(std::forward<Event>(ev_)) {}
/**
* @brief Trigger visitor callback for the current state.
* @description tries to find an fsm::trigger method in case the current state is a nested fsm. If it does not
* find it, searches for a react(current_state&, event) method at the current level
* Stores True in "result" if state changed. False otherwise
*/
template <typename CurrentState>
disable_if_subfsm<CurrentState> operator()(CurrentState& s)
{
result = call_react(s);
}
template <typename CurrentState>
enable_if_subfsm<CurrentState> operator()(CurrentState& s)
{
// Enter here for SubFSMs
result = s.trigger(std::forward<Event>(ev));
if (not result) {
result = call_react(s);
}
}
template <typename State>
using enable_if_react = decltype(std::declval<FSM>().react(std::declval<State&>(), std::declval<Event&&>()),
bool());
//! In case there is a react method
template <typename State>
auto call_react(State& s) -> decltype(std::declval<FSM>().react(s, std::declval<Event&&>()), bool())
{
auto target_state = f->react(s, std::forward<Event>(ev));
fsm_helper::handle_state_change(f, &target_state, &s);
return true;
}
bool call_react(...)
{
f->log_fsm_activity(
"FSM \"%s\": Unhandled event caught: \"%s\"\n", get_type_name<FSM>().c_str(), get_type_name<Event>().c_str());
return false;
}
FSM* f;
Event ev;
bool result = false;
};
};
template <typename FSM, typename PrevState>
template <typename State>
void to_state_visitor<FSM, PrevState>::operator()()
{
to_state<State> t;
fsm_helper::handle_state_change(f, &t, p);
}
template <typename FSM>
template <typename State>
void enter_visitor<FSM>::operator()(State&& s)
{
fsm_helper::call_enter(f, &s);
}
} // namespace fsm_details
//! Gets the typename currently stored in the choice_t
template <typename... Args>
std::string get_type_name(const srslte::to_states<Args...>& t)
{
fsm_details::state_name_visitor v{};
srslte::visit(v, t);
return v.name;
}
template <typename Derived, typename ParentFSM>
class nested_fsm_t;
//! CRTP Class for all non-nested FSMs
template <typename Derived>
class fsm_t
{
protected:
using base_t = fsm_t<Derived>;
template <typename SubFSM>
using subfsm_t = nested_fsm_t<SubFSM, Derived>;
//! get access to derived protected members from the base
class derived_view : public Derived
{
public:
using derived_t = Derived;
using derived_t::base_t::enter;
using derived_t::base_t::exit;
// propagate user fsm methods
using Derived::enter;
using Derived::exit;
using Derived::react;
using Derived::states;
};
public:
static const bool is_nested = false;
template <typename NextState>
using to_state = srslte::to_state<NextState>;
template <typename... NextStates>
using to_states = srslte::to_states<NextStates...>;
//! Struct used to store FSM states
template <typename... States>
struct state_list : public std::tuple<States...> {
using tuple_base_t = std::tuple<States...>;
using init_state_t = typename std::decay<decltype(std::get<0>(std::declval<tuple_base_t>()))>::type;
template <typename... Args>
state_list(fsm_t<Derived>* f, Args&&... args) : tuple_base_t(std::forward<Args>(args)...)
{
if (not Derived::is_nested) {
// If Root FSM, call initial state enter method
fsm_details::fsm_helper::call_enter(f->derived(), &get_unchecked<init_state_t>());
}
}
template <typename State>
bool is() const
{
return type_idx<State>() == current_idx;
}
template <typename State>
State& get_unchecked()
{
return std::get<type_idx<State>()>(*this);
}
template <typename State>
const State& get_unchecked() const
{
return std::get<type_idx<State>()>(*this);
}
template <typename NextState>
void transit()
{
current_idx = type_idx<NextState>();
}
template <typename State>
constexpr static bool can_hold_type()
{
return srslte::type_list_contains<State, States...>();
}
template <typename State>
constexpr static size_t type_idx()
{
return get_type_index<State, States...>();
}
size_t get_type_idx() const { return current_idx; }
private:
size_t current_idx = 0;
};
explicit fsm_t(srslte::log_ref log_) : log_h(log_) {}
// Push Events to FSM
template <typename Ev>
bool trigger(Ev&& e)
{
fsm_details::fsm_helper::trigger_visitor<derived_view, Ev> visitor{derived(), std::forward<Ev>(e)};
srslte::visit(visitor, derived()->states);
return visitor.result;
}
template <typename State>
bool is_in_state() const
{
return derived()->states.template is<State>();
}
template <typename State>
const State* get_if_current_state() const
{
return is_in_state<State>() ? get_state<State>() : nullptr;
}
template <typename State>
State* get_state()
{
return &derived()->states.template get_unchecked<State>();
}
template <typename State>
const State* get_state() const
{
return &derived()->states.template get_unchecked<State>();
}
std::string current_state_name() const
{
fsm_details::state_name_visitor visitor{};
srslte::visit(visitor, derived()->states);
return visitor.name;
}
//! Static method to check if State belongs to the list of possible states
template <typename State>
constexpr static bool can_hold_state()
{
return fsm_details::fsm_helper::fsm_state_list_type<fsm_t<Derived> >::template can_hold_type<State>();
}
void set_fsm_event_log_level(srslte::LOG_LEVEL_ENUM e) { fsm_event_log_level = e; }
srslte::log_ref get_log() const { return log_h; }
protected:
friend struct fsm_details::fsm_helper;
// Access to CRTP derived class
derived_view* derived() { return static_cast<derived_view*>(this); }
const derived_view* derived() const { return static_cast<const derived_view*>(this); }
template <typename State>
void enter(State& s)
{
// do nothing by default
}
template <typename State>
void exit(State& s)
{
// do nothing by default
}
template <typename... Args>
void log_fsm_activity(const char* format, Args&&... args)
{
switch (fsm_event_log_level) {
case LOG_LEVEL_DEBUG:
log_h->debug(format, std::forward<Args>(args)...);
break;
case LOG_LEVEL_INFO:
log_h->info(format, std::forward<Args>(args)...);
break;
case LOG_LEVEL_WARNING:
log_h->warning(format, std::forward<Args>(args)...);
break;
case LOG_LEVEL_ERROR:
log_h->error(format, std::forward<Args>(args)...);
break;
default:
break;
}
}
srslte::log_ref log_h;
srslte::LOG_LEVEL_ENUM fsm_event_log_level = LOG_LEVEL_INFO;
};
template <typename Derived, typename ParentFSM>
class nested_fsm_t : public fsm_t<Derived>
{
public:
using base_t = nested_fsm_t<Derived, ParentFSM>;
using parent_t = ParentFSM;
static const bool is_nested = true;
explicit nested_fsm_t(ParentFSM* parent_fsm_) : fsm_t<Derived>(parent_fsm_->get_log()), fsm_ptr(parent_fsm_) {}
// Get pointer to outer FSM in case of HSM
const parent_t* parent_fsm() const { return fsm_ptr; }
parent_t* parent_fsm() { return fsm_ptr; }
protected:
using parent_fsm_t = ParentFSM;
using fsm_t<Derived>::enter;
using fsm_t<Derived>::exit;
ParentFSM* fsm_ptr = nullptr;
};
template <typename Proc>
struct proc_complete_ev {
proc_complete_ev(bool success_) : success(success_) {}
bool success;
};
// event
template <typename... Args>
struct proc_launch_ev {
std::tuple<Args...> args;
explicit proc_launch_ev(Args&&... args_) : args(std::forward<Args>(args_)...) {}
};
template <typename Derived, typename Result = std::true_type>
class proc_fsm_t : public fsm_t<Derived>
{
using fsm_type = Derived;
using fsm_t<Derived>::derived;
friend struct fsm_details::fsm_helper;
protected:
using fsm_t<Derived>::log_h;
using fsm_t<Derived>::enter;
using fsm_t<Derived>::exit;
template <typename State>
auto react(State&, srslte::proc_launch_ev<int*> e) -> srslte::same_state
{
log_h->warning("Unhandled event \"launch\" caught when procedure is already running\n");
return {};
}
public:
using base_t = proc_fsm_t<Derived, Result>;
using fsm_t<Derived>::trigger;
// events
struct reset_ev {};
// states
struct idle_st {};
struct complete_st {};
explicit proc_fsm_t(srslte::log_ref log_) : fsm_t<Derived>(log_) {}
bool is_running() const { return base_t::template is_in_state<idle_st>(); }
template <typename... Args>
void launch(Args&&... args)
{
trigger(proc_launch_ev<Args...>(std::forward<Args>(args)...));
}
protected:
void exit(idle_st& s)
{
launch_counter++;
log_h->info("Starting run no. %d\n", launch_counter);
}
void enter(complete_st& s) { trigger(reset_ev{}); }
auto react(complete_st& s, reset_ev ev) -> to_state<idle_st> { return {}; }
srslte::to_state<complete_st> set_success(Result&& r = {})
{
result = std::forward<Result>(r);
success = true;
return {};
}
srslte::to_state<complete_st> set_failure()
{
success = false;
return {};
}
bool is_success() const { return success; }
const Result& get_result() const
{
if (is_success()) {
return result;
}
throw bad_type_access{"in proc_fsm_t::get_result"};
}
private:
int launch_counter = 0;
bool success = false;
Result result;
};
} // namespace srslte
#endif // SRSLTE_FSM_H