#ifndef SPOT_TGBA_TGBA_HH
# define SPOT_TGBA_TGBA_HH
#include "state.hh"
#include "succiter.hh"
#include "bdddict.hh"
namespace spot
{
/// \brief A Transition-based Generalized Büchi Automaton.
///
/// The acronym TGBA (Transition-based Generalized Büchi Automaton)
/// was coined by Dimitra Giannakopoulou and Flavio Lerda
/// in "From States to Transitions: Improving Translation of LTL
/// Formulae to Büchi Automata". (FORTE'02)
///
/// TGBAs are transition-based, meanings their labels are put
/// on arcs, not on nodes. They use Generalized Büchi acceptance
/// conditions: there are several accepting sets (of
/// transitions), and a path can be accepted only if it traverse
/// at least one transition of each set infinitely often.
///
/// Browsing such automaton can be achieved using two functions.
/// \c get_init_state, and \c succ_iter. The former returns
/// the initial state while the latter allows to explore the
/// successor states of any state.
///
/// Note that although this is a transition-based automata,
/// we never represent transitions! Transition informations are
/// obtained by querying the iterator over the successors of
/// a state.
class tgba
{
protected:
tgba();
virtual ~tgba();
public:
/// \brief Get the initial state of the automaton.
///
/// The state has been allocated with \c new. It is the
/// responsability of the caller to \c delete it when no
/// longer needed.
virtual state* get_init_state() const = 0;
/// \brief Get an iterator over the successors of \a local_state.
///
/// The iterator has been allocated with \c new. It is the
/// responsability of the caller to \c delete it when no
/// longer needed.
///
/// During synchornized products, additional informations are
/// passed about the entire product and its state. Recall that
/// products can be nested, forming a tree of spot::tgba where
/// most values are computed on demand. \a global_automaton
/// designate the root spot::tgba, and \a global_state its
/// state. This two objects can be used by succ_iter() to
/// restrict the set of successors to compute.
///
/// \param local_state The state whose successors are to be explored.
/// This pointer is not adopted in any way by \c succ_iter, and
/// it is still the caller's responsability to delete it when
/// appropriate (this can be done during the lifetime of
/// the iterator).
/// \param global_state In a product, the state of the global
/// product automaton. Otherwise, 0. Like \a locale_state,
/// \a global_state is not adopted by \c succ_iter.
/// \param global_automaton In a product, the state of the global
/// product automaton. Otherwise, 0.
virtual tgba_succ_iterator*
succ_iter(const state* local_state,
const state* global_state = 0,
const tgba* global_automaton = 0) const = 0;
/// \brief Get a formula that must hold whatever successor is taken.
///
/// \return A formula which must be verified for all successors
/// of \a state.
///
/// This can be as simple as \c bddtrue, or more completely
/// the disjunction of the condition of all successors. This
/// is used as an hint by \c succ_iter() to reduce the number
/// of successor to compute in a product.
///
/// Sub classes should implement compute_support_conditions(),
/// this function is just a wrapper that will cache the
/// last return value for efficiency.
bdd support_conditions(const state* state) const;
/// \brief Get the conjunctions of variables tested by
/// the outgoing transitions of \a state.
///
/// All variables tested by outgoing transitions must be
/// returned. This is mandatory.
///
/// This is used as an hint by some \c succ_iter() to reduce the
/// number of successor to compute in a product.
///
/// Sub classes should implement compute_support_variables(),
/// this function is just a wrapper that will cache the
/// last return value for efficiency.
bdd support_variables(const state* state) const;
/// \brief Get the dictionary associated to the automaton.
///
/// State are represented as BDDs. The dictionary allows
/// to map BDD variables back to formulae, and vice versa.
/// This is useful when dealing with several automata (which
/// may use the same BDD variable for different formula),
/// or simply when printing.
virtual bdd_dict* get_dict() const = 0;
/// \brief Format the state as a string for printing.
///
/// This formating is the responsability of the automata
/// who owns the state.
virtual std::string format_state(const state* state) const = 0;
/// \brief Return the set of all accepting conditions used
/// by this automaton.
///
/// The goal of the emptiness check is to ensure that
/// a strongly connected component walks through each
/// of these acceptiong conditions. I.e., the union
/// of the acceptiong conditions of all transition in
/// the SCC should be equal to the result of this function.
virtual bdd all_accepting_conditions() const = 0;
/// \brief Return the conjuction of all negated accepting
/// variables.
///
/// For instance if the automaton uses variables `Acc[a]`,
/// `Acc[b]` and `Acc[c]` to describe accepting sets,
/// this function should return `!Acc[a]\&!Acc[b]\&!Acc[c]`.
///
/// This is useful when making products: each operand's condition
/// set should be augmented with the neg_accepting_conditions() of
/// the other operand.
virtual bdd neg_accepting_conditions() const = 0;
protected:
/// Do the actual computation of tgba::support_conditions().
virtual bdd compute_support_conditions(const state* state) const = 0;
/// Do the actual computation of tgba::support_variables().
virtual bdd compute_support_variables(const state* state) const = 0;
private:
mutable const state* last_support_conditions_input_;
mutable bdd last_support_conditions_output_;
mutable const state* last_support_variables_input_;
mutable bdd last_support_variables_output_;
};
}
#endif // SPOT_TGBA_TGBA_HH