Theory T
theory T
imports Modal0
begin
axiomatization where
lstar0: "|L>" and
lstar1: "$G |L> $H ⟹ []P, $G |L> P, $H" and
lstar2: "$G |L> $H ⟹ P, $G |L> $H" and
rstar0: "|R>" and
rstar1: "$G |R> $H ⟹ <>P, $G |R> P, $H" and
rstar2: "$G |R> $H ⟹ P, $G |R> $H" and
boxR:
"⟦$E |L> $E'; $F |R> $F'; $G |R> $G';
$E' ⊢ $F', P, $G'⟧ ⟹ $E ⊢ $F, []P, $G" and
boxL: "$E, P, $F ⊢ $G ⟹ $E, []P, $F ⊢ $G" and
diaR: "$E ⊢ $F, P, $G ⟹ $E ⊢ $F, <>P, $G" and
diaL:
"⟦$E |L> $E'; $F |L> $F'; $G |R> $G';
$E', P, $F'⊢ $G'⟧ ⟹ $E, <>P, $F ⊢ $G"
ML ‹
structure T_Prover = Modal_ProverFun
(
val rewrite_rls = @{thms rewrite_rls}
val safe_rls = @{thms safe_rls}
val unsafe_rls = @{thms unsafe_rls} @ [@{thm boxR}, @{thm diaL}]
val bound_rls = @{thms bound_rls} @ [@{thm boxL}, @{thm diaR}]
val aside_rls = [@{thm lstar0}, @{thm lstar1}, @{thm lstar2}, @{thm rstar0},
@{thm rstar1}, @{thm rstar2}]
)
›
method_setup T_solve = ‹Scan.succeed (fn ctxt => SIMPLE_METHOD (T_Prover.solve_tac ctxt 2))›
lemma "⊢ []P ⟶ P" by T_solve
lemma "⊢ [](P ⟶ Q) ⟶ ([]P ⟶ []Q)" by T_solve
lemma "⊢ (P --< Q) ⟶ []P ⟶ []Q" by T_solve
lemma "⊢ P ⟶ <>P" by T_solve
lemma "⊢ [](P ∧ Q) ⟷ []P ∧ []Q" by T_solve
lemma "⊢ <>(P ∨ Q) ⟷ <>P ∨ <>Q" by T_solve
lemma "⊢ [](P ⟷ Q) ⟷ (P >-< Q)" by T_solve
lemma "⊢ <>(P ⟶ Q) ⟷ ([]P ⟶ <>Q)" by T_solve
lemma "⊢ []P ⟷ ¬ <>(¬ P)" by T_solve
lemma "⊢ [](¬ P) ⟷ ¬ <>P" by T_solve
lemma "⊢ ¬ []P ⟷ <>(¬ P)" by T_solve
lemma "⊢ [][]P ⟷ ¬ <><>(¬ P)" by T_solve
lemma "⊢ ¬ <>(P ∨ Q) ⟷ ¬ <>P ∧ ¬ <>Q" by T_solve
lemma "⊢ []P ∨ []Q ⟶ [](P ∨ Q)" by T_solve
lemma "⊢ <>(P ∧ Q) ⟶ <>P ∧ <>Q" by T_solve
lemma "⊢ [](P ∨ Q) ⟶ []P ∨ <>Q" by T_solve
lemma "⊢ <>P ∧ []Q ⟶ <>(P ∧ Q)" by T_solve
lemma "⊢ [](P ∨ Q) ⟶ <>P ∨ []Q" by T_solve
lemma "⊢ <>(P ⟶ (Q ∧ R)) ⟶ ([]P ⟶ <>Q) ∧ ([]P ⟶ <>R)" by T_solve
lemma "⊢ (P --< Q) ∧ (Q --< R ) ⟶ (P --< R)" by T_solve
lemma "⊢ []P ⟶ <>Q ⟶ <>(P ∧ Q)" by T_solve
end