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+(* Title: compute.ML
+ Author: Christoph Traut, Lars Noschinski, TU Muenchen
+ Modified: Joshua Chen, University of Innsbruck
+
+This is a method for rewriting computational equalities that supports subterm
+selection based on patterns.
+
+This code has been slightly modified from the original at HOL/Library/compute.ML
+to incorporate automatic discharge of type-theoretic side conditions.
+
+Comment from the original code follows:
+
+The patterns accepted by compute are of the following form:
+ <atom> ::= <term> | "concl" | "asm" | "for" "(" <names> ")"
+ <pattern> ::= (in <atom> | at <atom>) [<pattern>]
+ <args> ::= [<pattern>] ("to" <term>) <thms>
+
+This syntax was clearly inspired by Gonthier's and Tassi's language of
+patterns but has diverged significantly during its development.
+
+We also allow introduction of identifiers for bound variables,
+which can then be used to match arbitrary subterms inside abstractions.
+*)
+
+infix 1 then_pconv;
+infix 0 else_pconv;
+
+signature COMPUTE =
+sig
+ type patconv = Proof.context -> Type.tyenv * (string * term) list -> cconv
+ val then_pconv: patconv * patconv -> patconv
+ val else_pconv: patconv * patconv -> patconv
+ val abs_pconv: patconv -> string option * typ -> patconv (*XXX*)
+ val fun_pconv: patconv -> patconv
+ val arg_pconv: patconv -> patconv
+ val imp_pconv: patconv -> patconv
+ val params_pconv: patconv -> patconv
+ val forall_pconv: patconv -> string option * typ option -> patconv
+ val all_pconv: patconv
+ val for_pconv: patconv -> (string option * typ option) list -> patconv
+ val concl_pconv: patconv -> patconv
+ val asm_pconv: patconv -> patconv
+ val asms_pconv: patconv -> patconv
+ val judgment_pconv: patconv -> patconv
+ val in_pconv: patconv -> patconv
+ val match_pconv: patconv -> term * (string option * typ) list -> patconv
+ val comps_pconv: term option -> thm list -> patconv
+
+ datatype ('a, 'b) pattern = At | In | Term of 'a | Concl | Asm | For of 'b list
+
+ val mk_hole: int -> typ -> term
+
+ val compute_conv: Proof.context
+ -> (term * (string * typ) list, string * typ option) pattern list * term option
+ -> thm list
+ -> conv
+end
+
+structure Compute : COMPUTE =
+struct
+
+datatype ('a, 'b) pattern = At | In | Term of 'a | Concl | Asm | For of 'b list
+
+exception NO_TO_MATCH
+
+val holeN = Name.internal "_hole"
+
+fun prep_meta_eq ctxt = Simplifier.mksimps ctxt #> map Drule.zero_var_indexes
+
+
+(* holes *)
+
+fun mk_hole i T = Var ((holeN, i), T)
+
+fun is_hole (Var ((name, _), _)) = (name = holeN)
+ | is_hole _ = false
+
+fun is_hole_const (Const (\<^const_name>\<open>compute_hole\<close>, _)) = true
+ | is_hole_const _ = false
+
+val hole_syntax =
+ let
+ (* Modified variant of Term.replace_hole *)
+ fun replace_hole Ts (Const (\<^const_name>\<open>compute_hole\<close>, T)) i =
+ (list_comb (mk_hole i (Ts ---> T), map_range Bound (length Ts)), i + 1)
+ | replace_hole Ts (Abs (x, T, t)) i =
+ let val (t', i') = replace_hole (T :: Ts) t i
+ in (Abs (x, T, t'), i') end
+ | replace_hole Ts (t $ u) i =
+ let
+ val (t', i') = replace_hole Ts t i
+ val (u', i'') = replace_hole Ts u i'
+ in (t' $ u', i'') end
+ | replace_hole _ a i = (a, i)
+ fun prep_holes ts = #1 (fold_map (replace_hole []) ts 1)
+ in
+ Context.proof_map (Syntax_Phases.term_check 101 "hole_expansion" (K prep_holes))
+ #> Proof_Context.set_mode Proof_Context.mode_pattern
+ end
+
+
+(* pattern conversions *)
+
+type patconv = Proof.context -> Type.tyenv * (string * term) list -> cterm -> thm
+
+fun (cv1 then_pconv cv2) ctxt tytenv ct = (cv1 ctxt tytenv then_conv cv2 ctxt tytenv) ct
+
+fun (cv1 else_pconv cv2) ctxt tytenv ct = (cv1 ctxt tytenv else_conv cv2 ctxt tytenv) ct
+
+fun raw_abs_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ Abs _ => CConv.abs_cconv (fn (x, ctxt') => cv x ctxt' tytenv) ctxt ct
+ | t => raise TERM ("raw_abs_pconv", [t])
+
+fun raw_fun_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ _ $ _ => CConv.fun_cconv (cv ctxt tytenv) ct
+ | t => raise TERM ("raw_fun_pconv", [t])
+
+fun raw_arg_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ _ $ _ => CConv.arg_cconv (cv ctxt tytenv) ct
+ | t => raise TERM ("raw_arg_pconv", [t])
+
+fun abs_pconv cv (s,T) ctxt (tyenv, ts) ct =
+ let val u = Thm.term_of ct
+ in
+ case try (fastype_of #> dest_funT) u of
+ NONE => raise TERM ("abs_pconv: no function type", [u])
+ | SOME (U, _) =>
+ let
+ val tyenv' =
+ if T = dummyT then tyenv
+ else Sign.typ_match (Proof_Context.theory_of ctxt) (T, U) tyenv
+ val eta_expand_cconv =
+ case u of
+ Abs _=> Thm.reflexive
+ | _ => CConv.rewr_cconv @{thm eta_expand}
+ fun add_ident NONE _ l = l
+ | add_ident (SOME name) ct l = (name, Thm.term_of ct) :: l
+ val abs_cv = CConv.abs_cconv (fn (ct, ctxt) => cv ctxt (tyenv', add_ident s ct ts)) ctxt
+ in (eta_expand_cconv then_conv abs_cv) ct end
+ handle Pattern.MATCH => raise TYPE ("abs_pconv: types don't match", [T,U], [u])
+ end
+
+fun fun_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ _ $ _ => CConv.fun_cconv (cv ctxt tytenv) ct
+ | Abs (_, T, _ $ Bound 0) => abs_pconv (fun_pconv cv) (NONE, T) ctxt tytenv ct
+ | t => raise TERM ("fun_pconv", [t])
+
+local
+
+fun arg_pconv_gen cv0 cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ _ $ _ => cv0 (cv ctxt tytenv) ct
+ | Abs (_, T, _ $ Bound 0) => abs_pconv (arg_pconv_gen cv0 cv) (NONE, T) ctxt tytenv ct
+ | t => raise TERM ("arg_pconv_gen", [t])
+
+in
+
+fun arg_pconv ctxt = arg_pconv_gen CConv.arg_cconv ctxt
+fun imp_pconv ctxt = arg_pconv_gen (CConv.concl_cconv 1) ctxt
+
+end
+
+(* Move to B in !!x_1 ... x_n. B. Do not eta-expand *)
+fun params_pconv cv ctxt tytenv ct =
+ let val pconv =
+ case Thm.term_of ct of
+ Const (\<^const_name>\<open>Pure.all\<close>, _) $ Abs _ => (raw_arg_pconv o raw_abs_pconv) (fn _ => params_pconv cv)
+ | Const (\<^const_name>\<open>Pure.all\<close>, _) => raw_arg_pconv (params_pconv cv)
+ | _ => cv
+ in pconv ctxt tytenv ct end
+
+fun forall_pconv cv ident ctxt tytenv ct =
+ case Thm.term_of ct of
+ Const (\<^const_name>\<open>Pure.all\<close>, T) $ _ =>
+ let
+ val def_U = T |> dest_funT |> fst |> dest_funT |> fst
+ val ident' = apsnd (the_default (def_U)) ident
+ in arg_pconv (abs_pconv cv ident') ctxt tytenv ct end
+ | t => raise TERM ("forall_pconv", [t])
+
+fun all_pconv _ _ = Thm.reflexive
+
+fun for_pconv cv idents ctxt tytenv ct =
+ let
+ fun f rev_idents (Const (\<^const_name>\<open>Pure.all\<close>, _) $ t) =
+ let val (rev_idents', cv') = f rev_idents (case t of Abs (_,_,u) => u | _ => t)
+ in
+ case rev_idents' of
+ [] => ([], forall_pconv cv' (NONE, NONE))
+ | (x :: xs) => (xs, forall_pconv cv' x)
+ end
+ | f rev_idents _ = (rev_idents, cv)
+ in
+ case f (rev idents) (Thm.term_of ct) of
+ ([], cv') => cv' ctxt tytenv ct
+ | _ => raise CTERM ("for_pconv", [ct])
+ end
+
+fun concl_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ (Const (\<^const_name>\<open>Pure.imp\<close>, _) $ _) $ _ => imp_pconv (concl_pconv cv) ctxt tytenv ct
+ | _ => cv ctxt tytenv ct
+
+fun asm_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ (Const (\<^const_name>\<open>Pure.imp\<close>, _) $ _) $ _ => CConv.with_prems_cconv ~1 (cv ctxt tytenv) ct
+ | t => raise TERM ("asm_pconv", [t])
+
+fun asms_pconv cv ctxt tytenv ct =
+ case Thm.term_of ct of
+ (Const (\<^const_name>\<open>Pure.imp\<close>, _) $ _) $ _ =>
+ ((CConv.with_prems_cconv ~1 oo cv) else_pconv imp_pconv (asms_pconv cv)) ctxt tytenv ct
+ | t => raise TERM ("asms_pconv", [t])
+
+fun judgment_pconv cv ctxt tytenv ct =
+ if Object_Logic.is_judgment ctxt (Thm.term_of ct)
+ then arg_pconv cv ctxt tytenv ct
+ else cv ctxt tytenv ct
+
+fun in_pconv cv ctxt tytenv ct =
+ (cv else_pconv
+ raw_fun_pconv (in_pconv cv) else_pconv
+ raw_arg_pconv (in_pconv cv) else_pconv
+ raw_abs_pconv (fn _ => in_pconv cv))
+ ctxt tytenv ct
+
+fun replace_idents idents t =
+ let
+ fun subst ((n1, s)::ss) (t as Free (n2, _)) = if n1 = n2 then s else subst ss t
+ | subst _ t = t
+ in Term.map_aterms (subst idents) t end
+
+fun match_pconv cv (t,fixes) ctxt (tyenv, env_ts) ct =
+ let
+ val t' = replace_idents env_ts t
+ val thy = Proof_Context.theory_of ctxt
+ val u = Thm.term_of ct
+
+ fun descend_hole fixes (Abs (_, _, t)) =
+ (case descend_hole fixes t of
+ NONE => NONE
+ | SOME (fix :: fixes', pos) => SOME (fixes', abs_pconv pos fix)
+ | SOME ([], _) => raise Match (* less fixes than abstractions on path to hole *))
+ | descend_hole fixes (t as l $ r) =
+ let val (f, _) = strip_comb t
+ in
+ if is_hole f
+ then SOME (fixes, cv)
+ else
+ (case descend_hole fixes l of
+ SOME (fixes', pos) => SOME (fixes', fun_pconv pos)
+ | NONE =>
+ (case descend_hole fixes r of
+ SOME (fixes', pos) => SOME (fixes', arg_pconv pos)
+ | NONE => NONE))
+ end
+ | descend_hole fixes t =
+ if is_hole t then SOME (fixes, cv) else NONE
+
+ val to_hole = descend_hole (rev fixes) #> the_default ([], cv) #> snd
+ in
+ case try (Pattern.match thy (apply2 Logic.mk_term (t',u))) (tyenv, Vartab.empty) of
+ NONE => raise TERM ("match_pconv: Does not match pattern", [t, t',u])
+ | SOME (tyenv', _) => to_hole t ctxt (tyenv', env_ts) ct
+ end
+
+fun comps_pconv to thms ctxt (tyenv, env_ts) =
+ let
+ fun instantiate_normalize_env ctxt env thm =
+ let
+ val prop = Thm.prop_of thm
+ val norm_type = Envir.norm_type o Envir.type_env
+ val insts = Term.add_vars prop []
+ |> map (fn x as (s, T) =>
+ ((s, norm_type env T), Thm.cterm_of ctxt (Envir.norm_term env (Var x))))
+ val tyinsts = Term.add_tvars prop []
+ |> map (fn x => (x, Thm.ctyp_of ctxt (norm_type env (TVar x))))
+ in Drule.instantiate_normalize (tyinsts, insts) thm end
+
+ fun unify_with_rhs context to env thm =
+ let
+ val (_, rhs) = thm |> Thm.concl_of |> Logic.dest_equals
+ val env' = Pattern.unify context (Logic.mk_term to, Logic.mk_term rhs) env
+ handle Pattern.Unif => raise NO_TO_MATCH
+ in env' end
+
+ fun inst_thm_to _ (NONE, _) thm = thm
+ | inst_thm_to (ctxt : Proof.context) (SOME to, env) thm =
+ instantiate_normalize_env ctxt (unify_with_rhs (Context.Proof ctxt) to env thm) thm
+
+ fun inst_thm ctxt idents (to, tyenv) thm =
+ let
+ (* Replace any identifiers with their corresponding bound variables. *)
+ val maxidx = Term.maxidx_typs (map (snd o snd) (Vartab.dest tyenv)) 0
+ val env = Envir.Envir {maxidx = maxidx, tenv = Vartab.empty, tyenv = tyenv}
+ val maxidx = Envir.maxidx_of env |> fold Term.maxidx_term (the_list to)
+ val thm' = Thm.incr_indexes (maxidx + 1) thm
+ in SOME (inst_thm_to ctxt (Option.map (replace_idents idents) to, env) thm') end
+ handle NO_TO_MATCH => NONE
+
+ in CConv.rewrs_cconv (map_filter (inst_thm ctxt env_ts (to, tyenv)) thms) end
+
+fun compute_conv ctxt (pattern, to) thms ct =
+ let
+ fun apply_pat At = judgment_pconv
+ | apply_pat In = in_pconv
+ | apply_pat Asm = params_pconv o asms_pconv
+ | apply_pat Concl = params_pconv o concl_pconv
+ | apply_pat (For idents) = (fn cv => for_pconv cv (map (apfst SOME) idents))
+ | apply_pat (Term x) = (fn cv => match_pconv cv (apsnd (map (apfst SOME)) x))
+
+ val cv = fold_rev apply_pat pattern
+
+ fun distinct_prems th =
+ case Seq.pull (distinct_subgoals_tac th) of
+ NONE => th
+ | SOME (th', _) => th'
+
+ val compute = comps_pconv to (maps (prep_meta_eq ctxt) thms)
+ in cv compute ctxt (Vartab.empty, []) ct |> distinct_prems end
+
+fun compute_export_tac ctxt (pat, pat_ctxt) thms =
+ let
+ val export = case pat_ctxt of
+ NONE => I
+ | SOME inner => singleton (Proof_Context.export inner ctxt)
+ in CCONVERSION (export o compute_conv ctxt pat thms) end
+
+val _ =
+ Theory.setup
+ let
+ fun mk_fix s = (Binding.name s, NONE, NoSyn)
+
+ val raw_pattern : (string, binding * string option * mixfix) pattern list parser =
+ let
+ val sep = (Args.$$$ "at" >> K At) || (Args.$$$ "in" >> K In)
+ val atom = (Args.$$$ "asm" >> K Asm) ||
+ (Args.$$$ "concl" >> K Concl) ||
+ (Args.$$$ "for" |-- Args.parens (Scan.optional Parse.vars []) >> For) ||
+ (Parse.term >> Term)
+ val sep_atom = sep -- atom >> (fn (s,a) => [s,a])
+
+ fun append_default [] = [Concl, In]
+ | append_default (ps as Term _ :: _) = Concl :: In :: ps
+ | append_default [For x, In] = [For x, Concl, In]
+ | append_default (For x :: (ps as In :: Term _:: _)) = For x :: Concl :: ps
+ | append_default ps = ps
+
+ in Scan.repeats sep_atom >> (rev #> append_default) end
+
+ fun context_lift (scan : 'a parser) f = fn (context : Context.generic, toks) =>
+ let
+ val (r, toks') = scan toks
+ val (r', context') = Context.map_proof_result (fn ctxt => f ctxt r) context
+ in (r', (context', toks' : Token.T list)) end
+
+ fun read_fixes fixes ctxt =
+ let fun read_typ (b, rawT, mx) = (b, Option.map (Syntax.read_typ ctxt) rawT, mx)
+ in Proof_Context.add_fixes (map read_typ fixes) ctxt end
+
+ fun prep_pats ctxt (ps : (string, binding * string option * mixfix) pattern list) =
+ let
+ fun add_constrs ctxt n (Abs (x, T, t)) =
+ let
+ val (x', ctxt') = yield_singleton Proof_Context.add_fixes (mk_fix x) ctxt
+ in
+ (case add_constrs ctxt' (n+1) t of
+ NONE => NONE
+ | SOME ((ctxt'', n', xs), t') =>
+ let
+ val U = Type_Infer.mk_param n []
+ val u = Type.constraint (U --> dummyT) (Abs (x, T, t'))
+ in SOME ((ctxt'', n', (x', U) :: xs), u) end)
+ end
+ | add_constrs ctxt n (l $ r) =
+ (case add_constrs ctxt n l of
+ SOME (c, l') => SOME (c, l' $ r)
+ | NONE =>
+ (case add_constrs ctxt n r of
+ SOME (c, r') => SOME (c, l $ r')
+ | NONE => NONE))
+ | add_constrs ctxt n t =
+ if is_hole_const t then SOME ((ctxt, n, []), t) else NONE
+
+ fun prep (Term s) (n, ctxt) =
+ let
+ val t = Syntax.parse_term ctxt s
+ val ((ctxt', n', bs), t') =
+ the_default ((ctxt, n, []), t) (add_constrs ctxt (n+1) t)
+ in (Term (t', bs), (n', ctxt')) end
+ | prep (For ss) (n, ctxt) =
+ let val (ns, ctxt') = read_fixes ss ctxt
+ in (For ns, (n, ctxt')) end
+ | prep At (n,ctxt) = (At, (n, ctxt))
+ | prep In (n,ctxt) = (In, (n, ctxt))
+ | prep Concl (n,ctxt) = (Concl, (n, ctxt))
+ | prep Asm (n,ctxt) = (Asm, (n, ctxt))
+
+ val (xs, (_, ctxt')) = fold_map prep ps (0, ctxt)
+
+ in (xs, ctxt') end
+
+ fun prep_args ctxt (((raw_pats, raw_to), raw_ths)) =
+ let
+
+ fun check_terms ctxt ps to =
+ let
+ fun safe_chop (0: int) xs = ([], xs)
+ | safe_chop n (x :: xs) = chop (n - 1) xs |>> cons x
+ | safe_chop _ _ = raise Match
+
+ fun reinsert_pat _ (Term (_, cs)) (t :: ts) =
+ let val (cs', ts') = safe_chop (length cs) ts
+ in (Term (t, map dest_Free cs'), ts') end
+ | reinsert_pat _ (Term _) [] = raise Match
+ | reinsert_pat ctxt (For ss) ts =
+ let val fixes = map (fn s => (s, Variable.default_type ctxt s)) ss
+ in (For fixes, ts) end
+ | reinsert_pat _ At ts = (At, ts)
+ | reinsert_pat _ In ts = (In, ts)
+ | reinsert_pat _ Concl ts = (Concl, ts)
+ | reinsert_pat _ Asm ts = (Asm, ts)
+
+ fun free_constr (s,T) = Type.constraint T (Free (s, dummyT))
+ fun mk_free_constrs (Term (t, cs)) = t :: map free_constr cs
+ | mk_free_constrs _ = []
+
+ val ts = maps mk_free_constrs ps @ the_list to
+ |> Syntax.check_terms (hole_syntax ctxt)
+ val ctxt' = fold Variable.declare_term ts ctxt
+ val (ps', (to', ts')) = fold_map (reinsert_pat ctxt') ps ts
+ ||> (fn xs => case to of NONE => (NONE, xs) | SOME _ => (SOME (hd xs), tl xs))
+ val _ = case ts' of (_ :: _) => raise Match | [] => ()
+ in ((ps', to'), ctxt') end
+
+ val (pats, ctxt') = prep_pats ctxt raw_pats
+
+ val ths = Attrib.eval_thms ctxt' raw_ths
+ val to = Option.map (Syntax.parse_term ctxt') raw_to
+
+ val ((pats', to'), ctxt'') = check_terms ctxt' pats to
+
+ in ((pats', ths, (to', ctxt)), ctxt'') end
+
+ val to_parser = Scan.option ((Args.$$$ "to") |-- Parse.term)
+
+ val subst_parser =
+ let val scan = raw_pattern -- to_parser -- Parse.thms1
+ in context_lift scan prep_args end
+
+ fun compute_export_ctac inputs inthms =
+ CONTEXT_TACTIC' (fn ctxt => compute_export_tac ctxt inputs inthms)
+ in
+ Method.setup \<^binding>\<open>cmp\<close> (subst_parser >>
+ (fn (pattern, inthms, (to, pat_ctxt)) => fn orig_ctxt => SIMPLE_METHOD'
+ (compute_export_tac orig_ctxt ((pattern, to), SOME pat_ctxt) inthms)))
+ "single-step rewriting, allowing subterm selection via patterns" #>
+ Method.setup \<^binding>\<open>comp\<close> (subst_parser >>
+ (fn (pattern, inthms, (to, pat_ctxt)) => K (CONTEXT_METHOD (
+ CHEADGOAL o SIDE_CONDS 0
+ (compute_export_ctac ((pattern, to), SOME pat_ctxt) inthms)))))
+ "single-step rewriting with auto-typechecking"
+ end
+end