(* Title: Pure/logic.ML
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Author: Makarius
Abstract syntax operations of the Pure meta-logic.
*)
signature LOGIC =
sig
val all_const: typ -> term
val all: term -> term -> term
val dependent_all_name: string * term -> term -> term
val is_all: term -> bool
val dest_all: term -> (string * typ) * term
val list_all: (string * typ) list * term -> term
val all_constraint: (string -> typ option) -> string * string -> term -> term
val dependent_all_constraint: (string -> typ option) -> string * string -> term -> term
val mk_equals: term * term -> term
val dest_equals: term -> term * term
val implies: term
val mk_implies: term * term -> term
val dest_implies: term -> term * term
val list_implies: term list * term -> term
val strip_imp_prems: term -> term list
val strip_imp_concl: term -> term
val strip_prems: int * term list * term -> term list * term
val count_prems: term -> int
val nth_prem: int * term -> term
val close_term: (string * term) list -> term -> term
val close_prop: (string * term) list -> term list -> term -> term
val close_prop_constraint: (string -> typ option) ->
(string * string) list -> term list -> term -> term
val true_prop: term
val conjunction: term
val mk_conjunction: term * term -> term
val mk_conjunction_list: term list -> term
val mk_conjunction_balanced: term list -> term
val dest_conjunction: term -> term * term
val dest_conjunction_list: term -> term list
val dest_conjunction_balanced: int -> term -> term list
val dest_conjunctions: term -> term list
val strip_horn: term -> term list * term
val mk_type: typ -> term
val dest_type: term -> typ
val type_map: (term -> term) -> typ -> typ
val const_of_class: class -> string
val class_of_const: string -> class
val mk_of_class: typ * class -> term
val dest_of_class: term -> typ * class
val mk_of_sort: typ * sort -> term list
val name_classrel: string * string -> string
val mk_classrel: class * class -> term
val dest_classrel: term -> class * class
val name_arities: arity -> string list
val name_arity: string * sort list * class -> string
val mk_arities: arity -> term list
val dest_arity: term -> string * sort list * class
val unconstrainT: sort list -> term ->
((typ -> typ) * ((typ * class) * term) list * (typ * class) list) * term
val protectC: term
val protect: term -> term
val unprotect: term -> term
val mk_term: term -> term
val dest_term: term -> term
val occs: term * term -> bool
val close_form: term -> term
val combound: term * int * int -> term
val rlist_abs: (string * typ) list * term -> term
val incr_tvar_same: int -> typ Same.operation
val incr_tvar: int -> typ -> typ
val incr_indexes_same: string list * typ list * int -> term Same.operation
val incr_indexes: string list * typ list * int -> term -> term
val lift_abs: int -> term -> term -> term
val lift_all: int -> term -> term -> term
val strip_assums_hyp: term -> term list
val strip_assums_concl: term -> term
val strip_params: term -> (string * typ) list
val has_meta_prems: term -> bool
val flatten_params: int -> term -> term
val list_rename_params: string list -> term -> term
val assum_pairs: int * term -> (term * term) list
val assum_problems: int * term -> (term -> term) * term list * term
val varifyT_global: typ -> typ
val unvarifyT_global: typ -> typ
val varify_types_global: term -> term
val unvarify_types_global: term -> term
val varify_global: term -> term
val unvarify_global: term -> term
val get_goal: term -> int -> term
val goal_params: term -> int -> term * term list
val prems_of_goal: term -> int -> term list
val concl_of_goal: term -> int -> term
end;
structure Logic : LOGIC =
struct
(*** Abstract syntax operations on the meta-connectives ***)
(** all **)
fun all_const T = Const ("Pure.all", (T --> propT) --> propT);
fun all v t = all_const (Term.fastype_of v) $ lambda v t;
fun dependent_all_name (x, v) t =
let
val x' = if x = "" then Term.term_name v else x;
val T = Term.fastype_of v;
val t' = Term.abstract_over (v, t);
in if Term.is_dependent t' then all_const T $ Abs (x', T, t') else t end;
fun is_all (Const ("Pure.all", _) $ Abs _) = true
| is_all _ = false;
fun dest_all (Const ("Pure.all", _) $ Abs (abs as (_, T, _))) =
let val (x, b) = Term.dest_abs abs (*potentially slow*)
in ((x, T), b) end
| dest_all t = raise TERM ("dest_all", [t]);
fun list_all ([], t) = t
| list_all ((a, T) :: vars, t) = all_const T $ Abs (a, T, list_all (vars, t));
(* operations before type-inference *)
local
fun abs_body default_type z tm =
let
fun abs lev (Abs (x, T, b)) = Abs (x, T, abs (lev + 1) b)
| abs lev (t $ u) = abs lev t $ abs lev u
| abs lev (a as Free (x, T)) =
if x = z then
Type.constraint (the_default dummyT (default_type x))
(Type.constraint T (Bound lev))
else a
| abs _ a = a;
in abs 0 (Term.incr_boundvars 1 tm) end;
in
fun all_constraint default_type (y, z) t =
all_const dummyT $ Abs (y, dummyT, abs_body default_type z t);
fun dependent_all_constraint default_type (y, z) t =
let val t' = abs_body default_type z t
in if Term.is_dependent t' then all_const dummyT $ Abs (y, dummyT, t') else t end;
end;
(** equality **)
fun mk_equals (t, u) =
let val T = Term.fastype_of t
in Const ("Pure.eq", T --> T --> propT) $ t $ u end;
fun dest_equals (Const ("Pure.eq", _) $ t $ u) = (t, u)
| dest_equals t = raise TERM ("dest_equals", [t]);
(** implies **)
val implies = Const ("Pure.imp", propT --> propT --> propT);
fun mk_implies (A, B) = implies $ A $ B;
fun dest_implies (Const ("Pure.imp", _) $ A $ B) = (A, B)
| dest_implies A = raise TERM ("dest_implies", [A]);
(** nested implications **)
(* [A1,...,An], B goes to A1==>...An==>B *)
fun list_implies ([], B) = B
| list_implies (A::As, B) = implies $ A $ list_implies(As,B);
(* A1==>...An==>B goes to [A1,...,An], where B is not an implication *)
fun strip_imp_prems (Const("Pure.imp", _) $ A $ B) = A :: strip_imp_prems B
| strip_imp_prems _ = [];
(* A1==>...An==>B goes to B, where B is not an implication *)
fun strip_imp_concl (Const("Pure.imp", _) $ A $ B) = strip_imp_concl B
| strip_imp_concl A = A : term;
(*Strip and return premises: (i, [], A1==>...Ai==>B)
goes to ([Ai, A(i-1),...,A1] , B) (REVERSED)
if i<0 or else i too big then raises TERM*)
fun strip_prems (0, As, B) = (As, B)
| strip_prems (i, As, Const("Pure.imp", _) $ A $ B) =
strip_prems (i-1, A::As, B)
| strip_prems (_, As, A) = raise TERM("strip_prems", A::As);
(*Count premises -- quicker than (length o strip_prems) *)
fun count_prems (Const ("Pure.imp", _) $ _ $ B) = 1 + count_prems B
| count_prems _ = 0;
(*Select Ai from A1 ==>...Ai==>B*)
fun nth_prem (1, Const ("Pure.imp", _) $ A $ _) = A
| nth_prem (i, Const ("Pure.imp", _) $ _ $ B) = nth_prem (i - 1, B)
| nth_prem (_, A) = raise TERM ("nth_prem", [A]);
(*strip a proof state (Horn clause):
B1 ==> ... Bn ==> C goes to ([B1, ..., Bn], C) *)
fun strip_horn A = (strip_imp_prems A, strip_imp_concl A);
(* close -- omit vacuous quantifiers *)
val close_term = fold_rev Term.dependent_lambda_name;
fun close_prop xs As B =
fold_rev dependent_all_name xs (list_implies (As, B));
fun close_prop_constraint default_type xs As B =
fold_rev (dependent_all_constraint default_type) xs (list_implies (As, B));
(** conjunction **)
val true_prop = all_const propT $ Abs ("dummy", propT, mk_implies (Bound 0, Bound 0));
val conjunction = Const ("Pure.conjunction", propT --> propT --> propT);
(*A &&& B*)
fun mk_conjunction (A, B) = conjunction $ A $ B;
(*A &&& B &&& C -- improper*)
fun mk_conjunction_list [] = true_prop
| mk_conjunction_list ts = foldr1 mk_conjunction ts;
(*(A &&& B) &&& (C &&& D) -- balanced*)
fun mk_conjunction_balanced [] = true_prop
| mk_conjunction_balanced ts = Balanced_Tree.make mk_conjunction ts;
(*A &&& B*)
fun dest_conjunction (Const ("Pure.conjunction", _) $ A $ B) = (A, B)
| dest_conjunction t = raise TERM ("dest_conjunction", [t]);
(*A &&& B &&& C -- improper*)
fun dest_conjunction_list t =
(case try dest_conjunction t of
NONE => [t]
| SOME (A, B) => A :: dest_conjunction_list B);
(*(A &&& B) &&& (C &&& D) -- balanced*)
fun dest_conjunction_balanced 0 _ = []
| dest_conjunction_balanced n t = Balanced_Tree.dest dest_conjunction n t;
(*((A &&& B) &&& C) &&& D &&& E -- flat*)
fun dest_conjunctions t =
(case try dest_conjunction t of
NONE => [t]
| SOME (A, B) => dest_conjunctions A @ dest_conjunctions B);
(** types as terms **)
fun mk_type ty = Const ("Pure.type", Term.itselfT ty);
fun dest_type (Const ("Pure.type", Type ("itself", [ty]))) = ty
| dest_type t = raise TERM ("dest_type", [t]);
fun type_map f = dest_type o f o mk_type;
(** type classes **)
(* const names *)
val classN = "_class";
val const_of_class = suffix classN;
fun class_of_const c = unsuffix classN c
handle Fail _ => raise TERM ("class_of_const: bad name " ^ quote c, []);
(* class/sort membership *)
fun mk_of_class (ty, c) =
Const (const_of_class c, Term.itselfT ty --> propT) $ mk_type ty;
fun dest_of_class (Const (c_class, _) $ ty) = (dest_type ty, class_of_const c_class)
| dest_of_class t = raise TERM ("dest_of_class", [t]);
fun mk_of_sort (ty, S) = map (fn c => mk_of_class (ty, c)) S;
(* class relations *)
fun name_classrel (c1, c2) =
Long_Name.base_name c1 ^ "_" ^ Long_Name.base_name c2;
fun mk_classrel (c1, c2) = mk_of_class (Term.aT [c1], c2);
fun dest_classrel tm =
(case dest_of_class tm of
(TVar (_, [c1]), c2) => (c1, c2)
| _ => raise TERM ("dest_classrel", [tm]));
(* type arities *)
fun name_arities (t, _, S) =
let val b = Long_Name.base_name t
in S |> map (fn c => Long_Name.base_name c ^ "_" ^ b) end;
fun name_arity (t, dom, c) = hd (name_arities (t, dom, [c]));
fun mk_arities (t, Ss, S) =
let val T = Type (t, ListPair.map TFree (Name.invent Name.context Name.aT (length Ss), Ss))
in map (fn c => mk_of_class (T, c)) S end;
fun dest_arity tm =
let
fun err () = raise TERM ("dest_arity", [tm]);
val (ty, c) = dest_of_class tm;
val (t, tvars) =
(case ty of
Type (t, tys) => (t, map dest_TVar tys handle TYPE _ => err ())
| _ => err ());
val Ss =
if has_duplicates (eq_fst (op =)) tvars then err ()
else map snd tvars;
in (t, Ss, c) end;
(* internalized sort constraints *)
fun unconstrainT shyps prop =
let
val present = rev ((fold_types o fold_atyps_sorts) (insert (eq_fst op =)) prop []);
val extra = fold (Sorts.remove_sort o #2) present shyps;
val n = length present;
val (names1, names2) = Name.invent Name.context Name.aT (n + length extra) |> chop n;
val present_map =
map2 (fn (T, S) => fn a => (T, TVar ((a, 0), S))) present names1;
val constraints_map =
map2 (fn (_, S) => fn a => (S, TVar ((a, 0), S))) present names1 @
map2 (fn S => fn a => (S, TVar ((a, 0), S))) extra names2;
fun atyp_map T =
(case AList.lookup (op =) present_map T of
SOME U => U
| NONE =>
(case AList.lookup (op =) constraints_map (Type.sort_of_atyp T) of
SOME U => U
| NONE => raise TYPE ("Dangling type variable", [T], [])));
val constraints =
maps (fn (_, T as TVar (ai, S)) =>
map (fn c => ((T, c), mk_of_class (TVar (ai, []), c))) S)
constraints_map;
val outer_constraints =
maps (fn (T, S) => map (pair T) S)
(present @ map (fn S => (TFree ("'dummy", S), S)) extra);
val prop' =
prop
|> (Term.map_types o Term.map_atyps) (Type.strip_sorts o atyp_map)
|> curry list_implies (map snd constraints);
in ((atyp_map, constraints, outer_constraints), prop') end;
(** protected propositions and embedded terms **)
val protectC = Const ("Pure.prop", propT --> propT);
fun protect t = protectC $ t;
fun unprotect (Const ("Pure.prop", _) $ t) = t
| unprotect t = raise TERM ("unprotect", [t]);
fun mk_term t = Const ("Pure.term", Term.fastype_of t --> propT) $ t;
fun dest_term (Const ("Pure.term", _) $ t) = t
| dest_term t = raise TERM ("dest_term", [t]);
(*** Low-level term operations ***)
(*Does t occur in u? Or is alpha-convertible to u?
The term t must contain no loose bound variables*)
fun occs (t, u) = exists_subterm (fn s => t aconv s) u;
(*Close up a formula over all free variables by quantification*)
fun close_form A = fold (all o Free) (Term.add_frees A []) A;
(*** Specialized operations for resolution... ***)
(*computes t(Bound(n+k-1),...,Bound(n)) *)
fun combound (t, n, k) =
if k>0 then combound (t,n+1,k-1) $ (Bound n) else t;
(* ([xn,...,x1], t) ======> (x1,...,xn)t *)
fun rlist_abs ([], body) = body
| rlist_abs ((a,T)::pairs, body) = rlist_abs(pairs, Abs(a, T, body));
fun incr_tvar_same 0 = Same.same
| incr_tvar_same k = Term_Subst.map_atypsT_same
(fn TVar ((a, i), S) => TVar ((a, i + k), S)
| _ => raise Same.SAME);
fun incr_tvar k T = incr_tvar_same k T handle Same.SAME => T;
(*For all variables in the term, increment indexnames and lift over the Us
result is ?Gidx(B.(lev+n-1),...,B.lev) where lev is abstraction level *)
fun incr_indexes_same ([], [], 0) = Same.same
| incr_indexes_same (fixed, Ts, k) =
let
val n = length Ts;
val incrT = incr_tvar_same k;
fun incr lev (Var ((x, i), T)) =
combound (Var ((x, i + k), Ts ---> Same.commit incrT T), lev, n)
| incr lev (Free (x, T)) =
if member (op =) fixed x then
combound (Free (x, Ts ---> Same.commit incrT T), lev, n)
else Free (x, incrT T)
| incr lev (Abs (x, T, body)) =
(Abs (x, incrT T, incr (lev + 1) body handle Same.SAME => body)
handle Same.SAME => Abs (x, T, incr (lev + 1) body))
| incr lev (t $ u) =
(incr lev t $ (incr lev u handle Same.SAME => u)
handle Same.SAME => t $ incr lev u)
| incr _ (Const (c, T)) = Const (c, incrT T)
| incr _ (Bound _) = raise Same.SAME;
in incr 0 end;
fun incr_indexes arg t = incr_indexes_same arg t handle Same.SAME => t;
(* Lifting functions from subgoal and increment:
lift_abs operates on terms
lift_all operates on propositions *)
fun lift_abs inc =
let
fun lift Ts (Const ("Pure.imp", _) $ _ $ B) t = lift Ts B t
| lift Ts (Const ("Pure.all", _) $ Abs (a, T, B)) t = Abs (a, T, lift (T :: Ts) B t)
| lift Ts _ t = incr_indexes ([], rev Ts, inc) t;
in lift [] end;
fun lift_all inc =
let
fun lift Ts ((c as Const ("Pure.imp", _)) $ A $ B) t = c $ A $ lift Ts B t
| lift Ts ((c as Const ("Pure.all", _)) $ Abs (a, T, B)) t = c $ Abs (a, T, lift (T :: Ts) B t)
| lift Ts _ t = incr_indexes ([], rev Ts, inc) t;
in lift [] end;
(*Strips assumptions in goal, yielding list of hypotheses. *)
fun strip_assums_hyp B =
let
fun strip Hs (Const ("Pure.imp", _) $ H $ B) = strip (H :: Hs) B
| strip Hs (Const ("Pure.all", _) $ Abs (a, T, t)) =
strip (map (incr_boundvars 1) Hs) t
| strip Hs B = rev Hs
in strip [] B end;
(*Strips assumptions in goal, yielding conclusion. *)
fun strip_assums_concl (Const("Pure.imp", _) $ H $ B) = strip_assums_concl B
| strip_assums_concl (Const("Pure.all", _) $ Abs (a, T, t)) = strip_assums_concl t
| strip_assums_concl B = B;
(*Make a list of all the parameters in a subgoal, even if nested*)
fun strip_params (Const("Pure.imp", _) $ H $ B) = strip_params B
| strip_params (Const("Pure.all", _) $ Abs (a, T, t)) = (a, T) :: strip_params t
| strip_params B = [];
(*test for nested meta connectives in prems*)
val has_meta_prems =
let
fun is_meta (Const ("Pure.eq", _) $ _ $ _) = true
| is_meta (Const ("Pure.imp", _) $ _ $ _) = true
| is_meta (Const ("Pure.all", _) $ _) = true
| is_meta _ = false;
fun ex_meta (Const ("Pure.imp", _) $ A $ B) = is_meta A orelse ex_meta B
| ex_meta (Const ("Pure.all", _) $ Abs (_, _, B)) = ex_meta B
| ex_meta _ = false;
in ex_meta end;
(*Removes the parameters from a subgoal and renumber bvars in hypotheses,
where j is the total number of parameters (precomputed)
If n>0 then deletes assumption n. *)
fun remove_params j n A =
if j=0 andalso n<=0 then A (*nothing left to do...*)
else case A of
Const("Pure.imp", _) $ H $ B =>
if n=1 then (remove_params j (n-1) B)
else implies $ (incr_boundvars j H) $ (remove_params j (n-1) B)
| Const("Pure.all",_)$Abs(a,T,t) => remove_params (j-1) n t
| _ => if n>0 then raise TERM("remove_params", [A])
else A;
(*Move all parameters to the front of the subgoal, renaming them apart;
if n>0 then deletes assumption n. *)
fun flatten_params n A =
let val params = strip_params A;
val vars = ListPair.zip (Name.variant_list [] (map #1 params),
map #2 params)
in list_all (vars, remove_params (length vars) n A) end;
(*Makes parameters in a goal have the names supplied by the list cs.*)
fun list_rename_params cs (Const ("Pure.imp", _) $ A $ B) =
implies $ A $ list_rename_params cs B
| list_rename_params (c :: cs) ((a as Const ("Pure.all", _)) $ Abs (_, T, t)) =
a $ Abs (c, T, list_rename_params cs t)
| list_rename_params cs B = B;
(*** Treatment of "assume", "erule", etc. ***)
(*Strips assumptions in goal yielding
HS = [Hn,...,H1], params = [xm,...,x1], and B,
where x1...xm are the parameters. This version (21.1.2005) REQUIRES
the the parameters to be flattened, but it allows erule to work on
assumptions of the form !!x. phi. Any !! after the outermost string
will be regarded as belonging to the conclusion, and left untouched.
Used ONLY by assum_pairs.
Unless nasms<0, it can terminate the recursion early; that allows
erule to work on assumptions of the form P==>Q.*)
fun strip_assums_imp (0, Hs, B) = (Hs, B) (*recursion terminated by nasms*)
| strip_assums_imp (nasms, Hs, Const("Pure.imp", _) $ H $ B) =
strip_assums_imp (nasms-1, H::Hs, B)
| strip_assums_imp (_, Hs, B) = (Hs, B); (*recursion terminated by B*)
(*Strips OUTER parameters only.*)
fun strip_assums_all (params, Const("Pure.all",_)$Abs(a,T,t)) =
strip_assums_all ((a,T)::params, t)
| strip_assums_all (params, B) = (params, B);
(*Produces disagreement pairs, one for each assumption proof, in order.
A is the first premise of the lifted rule, and thus has the form
H1 ==> ... Hk ==> B and the pairs are (H1,B),...,(Hk,B).
nasms is the number of assumptions in the original subgoal, needed when B
has the form B1 ==> B2: it stops B1 from being taken as an assumption. *)
fun assum_pairs(nasms,A) =
let val (params, A') = strip_assums_all ([],A)
val (Hs,B) = strip_assums_imp (nasms,[],A')
fun abspar t = rlist_abs(params, t)
val D = abspar B
fun pairrev ([], pairs) = pairs
| pairrev (H::Hs, pairs) = pairrev(Hs, (abspar H, D) :: pairs)
in pairrev (Hs,[])
end;
fun assum_problems (nasms, A) =
let
val (params, A') = strip_assums_all ([], A)
val (Hs, B) = strip_assums_imp (nasms, [], A')
fun abspar t = rlist_abs (params, t)
in (abspar, rev Hs, B) end;
(* global schematic variables *)
fun bad_schematic xi = "Illegal schematic variable: " ^ quote (Term.string_of_vname xi);
fun bad_fixed x = "Illegal fixed variable: " ^ quote x;
fun varifyT_global_same ty = ty
|> Term_Subst.map_atypsT_same
(fn TFree (a, S) => TVar ((a, 0), S)
| TVar (ai, _) => raise TYPE (bad_schematic ai, [ty], []));
fun unvarifyT_global_same ty = ty
|> Term_Subst.map_atypsT_same
(fn TVar ((a, 0), S) => TFree (a, S)
| TVar (ai, _) => raise TYPE (bad_schematic ai, [ty], [])
| TFree (a, _) => raise TYPE (bad_fixed a, [ty], []));
val varifyT_global = Same.commit varifyT_global_same;
val unvarifyT_global = Same.commit unvarifyT_global_same;
fun varify_types_global tm = tm
|> Same.commit (Term_Subst.map_types_same varifyT_global_same)
handle TYPE (msg, _, _) => raise TERM (msg, [tm]);
fun unvarify_types_global tm = tm
|> Same.commit (Term_Subst.map_types_same unvarifyT_global_same)
handle TYPE (msg, _, _) => raise TERM (msg, [tm]);
fun varify_global tm = tm
|> Same.commit (Term_Subst.map_aterms_same
(fn Free (x, T) => Var ((x, 0), T)
| Var (xi, _) => raise TERM (bad_schematic xi, [tm])
| _ => raise Same.SAME))
|> varify_types_global;
fun unvarify_global tm = tm
|> Same.commit (Term_Subst.map_aterms_same
(fn Var ((x, 0), T) => Free (x, T)
| Var (xi, _) => raise TERM (bad_schematic xi, [tm])
| Free (x, _) => raise TERM (bad_fixed x, [tm])
| _ => raise Same.SAME))
|> unvarify_types_global;
(* goal states *)
fun get_goal st i =
nth_prem (i, st) handle TERM _ =>
error ("Subgoal number " ^ string_of_int i ^ " out of range (a total of " ^
string_of_int (count_prems st) ^ " subgoals)");
(*reverses parameters for substitution*)
fun goal_params st i =
let val gi = get_goal st i
val rfrees = map Free (Term.rename_wrt_term gi (strip_params gi))
in (gi, rfrees) end;
fun concl_of_goal st i =
let val (gi, rfrees) = goal_params st i
val B = strip_assums_concl gi
in subst_bounds (rfrees, B) end;
fun prems_of_goal st i =
let val (gi, rfrees) = goal_params st i
val As = strip_assums_hyp gi
in map (fn A => subst_bounds (rfrees, A)) As end;
end;