module C = Cic
module I = CicInspect
-module D = Deannotate
module S = CicSubstitution
module TC = CicTypeChecker
module Un = CicUniv
module Pp = CicPp
module PEH = ProofEngineHelpers
module HEL = HExtlib
+module DTI = DoubleTypeInference
module Cl = ProceduralClassify
module T = ProceduralTypes
module Cn = ProceduralConversion
+module H = ProceduralHelpers
type status = {
sorts : (C.id, A.sort_kind) Hashtbl.t;
max_depth: int option;
depth: int;
context: C.context;
- intros: string list
+ intros: string option list;
+ clears: string list;
+ clears_note: string;
+ case: int list;
+ skip_thm_and_qed : bool;
}
(* helpers ******************************************************************)
-let cic = D.deannotate_term
-
let split2_last l1 l2 =
try
let n = pred (List.length l1) in
let before2, after2 = HEL.split_nth n l2 in
before1, before2, List.hd after1, List.hd after2
with Invalid_argument _ -> failwith "A2P.split2_last"
-
+
let string_of_head = function
| C.ASort _ -> "sort"
| C.AConst _ -> "const"
let add st entry intro =
{st with context = entry :: st.context; intros = intro :: st.intros}
+let push st = {st with case = 1 :: st.case}
+
+let inc st =
+ {st with case = match st.case with
+ | [] -> assert false
+ | hd :: tl -> succ hd :: tl
+ }
+
+let case st str =
+ let case = String.concat "." (List.rev_map string_of_int st.case) in
+ Printf.sprintf "case %s: %s" case str
+
let test_depth st =
try
let msg = Printf.sprintf "Depth %u: " st.depth in
| C.ARel _ -> true
| _ -> false
else false
-(*
-let get_ind_name uri tno xcno =
-try
- let ts = match E.get_obj Un.empty_ugraph uri with
- | C.InductiveDefinition (ts, _, _,_), _ -> ts
- | _ -> assert false
- in
- let tname, cs = match List.nth ts tno with
- | (name, _, _, cs) -> name, cs
- in
- match xcno with
- | None -> tname
- | Some cno -> fst (List.nth cs (pred cno))
-with Invalid_argument _ -> failwith "A2P.get_ind_name"
-*)
+
let get_inner_types st v =
try
let id = Ut.id_of_annterm v in
*)
let get_type msg st bo =
try
- let ty, _ = TC.type_of_aux' [] st.context (cic bo) Un.empty_ugraph in
+ let ty, _ = TC.type_of_aux' [] st.context (H.cic bo) Un.empty_ugraph in
ty
with e -> failwith (msg ^ ": " ^ Printexc.to_string e)
| _ :: tl -> aux tl
in
aux st.context
-
+
+let get_ind_names uri tno =
+try
+ let ts = match E.get_obj Un.empty_ugraph uri with
+ | C.InductiveDefinition (ts, _, _, _), _ -> ts
+ | _ -> assert false
+ in
+ match List.nth ts tno with
+ | (_, _, _, cs) -> List.map fst cs
+with Invalid_argument _ -> failwith "A2P.get_ind_names"
+
(* proof construction *******************************************************)
-let unused_premise = "UNUSED"
+let used_premise = C.Name "USED"
let mk_exp_args hd tl classes synth =
let meta id = C.AImplicit (id, None) in
let args = aux args in
if args = [] then hd else C.AAppl ("", hd :: args)
+let mk_convert st ?name sty ety note =
+ let e = Cn.hole "" in
+ let csty, cety = H.cic sty, H.cic ety in
+ let _note = Printf.sprintf "%s\nSINTH: %s\nEXP: %s"
+ note (Pp.ppterm csty) (Pp.ppterm cety)
+ in
+ assert (Ut.is_sober csty);
+ assert (Ut.is_sober cety);
+ if Ut.alpha_equivalence csty cety then [(* T.Note note *)] else
+ let sty, ety = H.acic_bc st.context sty, H.acic_bc st.context ety in
+ match name with
+ | None -> [T.Change (sty, ety, None, e, ""(*note*))]
+ | Some (id, i) ->
+ begin match get_entry st id with
+ | C.Def _ -> assert false (* [T.ClearBody (id, note)] *)
+ | C.Decl _ -> [T.Change (ety, sty, Some (id, Some id), e, "" (* note *))]
+ end
+
let convert st ?name v =
match get_inner_types st v with
- | None -> []
- | Some (sty, ety) ->
- let e = Cn.mk_pattern 0 (T.mk_arel 1 "") in
- let csty, cety = cic sty, cic ety in
- if Ut.alpha_equivalence csty cety then [] else
- match name with
- | None -> [T.Change (sty, ety, None, e, "")]
- | Some (id, i) ->
- begin match get_entry st id with
- | C.Def _ -> [T.ClearBody (id, "")]
- | C.Decl w ->
- let w = S.lift i w in
- if Ut.alpha_equivalence csty w then []
- else
- [T.Note (Pp.ppterm csty); T.Note (Pp.ppterm w);
- T.Change (sty, ety, Some (id, id), e, "")]
- end
-
+ | None -> [(*T.Note "NORMAL: NO INNER TYPES"*)]
+ | Some (sty, ety) -> mk_convert st ?name sty ety "NORMAL"
+
+let convert_elim st ?name t v pattern =
+ match t, get_inner_types st t, get_inner_types st v with
+ | _, None, _
+ | _, _, None -> [(* T.Note "ELIM: NO INNER TYPES"*)]
+ | C.AAppl (_, hd :: tl), Some (tsty, _), Some (vsty, _) ->
+ let where = List.hd (List.rev tl) in
+ let cty = Cn.elim_inferred_type
+ st.context (H.cic vsty) (H.cic where) (H.cic hd) (H.cic pattern)
+ in
+ mk_convert st ?name (Cn.fake_annotate "" st.context cty) tsty "ELIM"
+ | _, Some _, Some _ -> assert false
+
let get_intro = function
- | C.Anonymous -> unused_premise
- | C.Name s -> s
-
-let mk_intros st script =
- if st.intros = [] then script else
- let count = List.length st.intros in
- T.Intros (Some count, List.rev st.intros, "") :: script
+ | C.Anonymous -> None
+ | C.Name s -> Some s
+
+let mk_intros st what script =
+ let intros st script =
+ if st.intros = [] then script else
+ let count = List.length st.intros in
+ T.Intros (Some count, List.rev st.intros, "") :: script
+ in
+ let clears st script =
+ if true (* st.clears = [] *) then script else T.Clear (st.clears, st.clears_note) :: script
+ in
+ intros st (clears st (convert st what @ script))
let mk_arg st = function
| C.ARel (_, _, i, name) as what -> convert st ~name:(name, i) what
| _ -> []
-let mk_fwd_rewrite st dtext name tl direction =
+let mk_fwd_rewrite st dtext name tl direction t =
assert (List.length tl = 6);
let what, where, predicate = List.nth tl 5, List.nth tl 3, List.nth tl 2 in
let e = Cn.mk_pattern 1 predicate in
match where with
- | C.ARel (_, _, _, premise) ->
- let script = mk_arg st what in
+ | C.ARel (_, _, i, premise) as v ->
let where = Some (premise, name) in
- T.Rewrite (direction, what, where, e, dtext) :: script
+(* let _script = convert_elim st ~name:(premise, i) t v e in *)
+ let script = mk_arg st what @ mk_arg st v (* @ script *) in
+ let st = {st with context = Cn.clear st.context premise} in
+ st, T.Rewrite (direction, what, where, e, dtext) :: script
| _ -> assert false
-let mk_rewrite st dtext what qs tl direction =
+let mk_rewrite st dtext where qs tl direction t =
assert (List.length tl = 5);
let predicate = List.nth tl 2 in
let e = Cn.mk_pattern 1 predicate in
- [T.Rewrite (direction, what, None, e, dtext); T.Branch (qs, "")]
+ let script = [] (* convert_elim st t t e *) in
+ script @ [T.Rewrite (direction, where, None, e, dtext); T.Branch (qs, "")]
let rec proc_lambda st name v t =
- let entry = Some (name, C.Decl (cic v)) in
+ let dno = DTI.does_not_occur 1 (H.cic t) in
+ let dno = dno && match get_inner_types st t with
+ | None -> false
+ | Some (it, et) ->
+ DTI.does_not_occur 1 (H.cic it) && DTI.does_not_occur 1 (H.cic et)
+ in
+ let name = match dno, name with
+ | true, _ -> C.Anonymous
+ | false, C.Anonymous -> H.mk_fresh_name st.context used_premise
+ | false, name -> name
+ in
+ let entry = Some (name, C.Decl (H.cic v)) in
let intro = get_intro name in
proc_proof (add st entry intro) t
let intro = get_intro name in
let proceed, dtext = test_depth st in
let script = if proceed then
- let hyp, rqv = match get_inner_types st v with
+ let st, hyp, rqv = match get_inner_types st v with
| Some (ity, _) ->
- let rqv = match v with
+ let st, rqv = match v with
| C.AAppl (_, hd :: tl) when is_fwd_rewrite_right hd tl ->
- mk_fwd_rewrite st dtext intro tl true
+ mk_fwd_rewrite st dtext intro tl true v
| C.AAppl (_, hd :: tl) when is_fwd_rewrite_left hd tl ->
- mk_fwd_rewrite st dtext intro tl false
+ mk_fwd_rewrite st dtext intro tl false v
| v ->
let qs = [proc_proof (next st) v; [T.Id ""]] in
- [T.Branch (qs, ""); T.Cut (intro, ity, dtext)]
+ let ity = H.acic_bc st.context ity in
+ st, [T.Branch (qs, ""); T.Cut (intro, ity, dtext)]
in
- C.Decl (cic ity), rqv
+ st, C.Decl (H.cic ity), rqv
| None ->
- C.Def (cic v, None), [T.LetIn (intro, v, dtext)]
+ st, C.Def (H.cic v, None), [T.LetIn (intro, v, dtext)]
in
let entry = Some (name, hyp) in
let qt = proc_proof (next (add st entry intro)) t in
else
[T.Apply (what, dtext)]
in
- mk_intros st script
+ mk_intros st what script
and proc_rel st what =
let _, dtext = test_depth st in
let text = "assumption" in
let script = [T.Apply (what, dtext ^ text)] in
- mk_intros st script
+ mk_intros st what script
and proc_mutconstruct st what =
let _, dtext = test_depth st in
let script = [T.Apply (what, dtext)] in
- mk_intros st script
+ mk_intros st what script
and proc_appl st what hd tl =
let proceed, dtext = test_depth st in
let script = if proceed then
let ty = get_type "TC2" st hd in
- let (classes, rc) as h = Cl.classify st.context ty in
+ let classes, rc = Cl.classify st.context ty in
let goal_arity = match get_inner_types st what with
| None -> 0
- | Some (ity, _) -> snd (PEH.split_with_whd (st.context, cic ity))
+ | Some (ity, _) -> snd (PEH.split_with_whd (st.context, H.cic ity))
in
- let argsno = List.length classes in
- let decurry = argsno - List.length tl in
+ let parsno, argsno = List.length classes, List.length tl in
+ let decurry = parsno - argsno in
let diff = goal_arity - decurry in
- if diff < 0 then failwith (Printf.sprintf "NOT TOTAL: %i %s |--- %s" diff (Pp.ppcontext st.context) (Pp.ppterm (cic hd)));
+ if diff < 0 then failwith (Printf.sprintf "NOT TOTAL: %i %s |--- %s" diff (Pp.ppcontext st.context) (Pp.ppterm (H.cic hd)));
let rec mk_synth a n =
if n < 0 then a else mk_synth (I.S.add n a) (pred n)
in
let synth = mk_synth I.S.empty decurry in
- let text = "" (* Printf.sprintf "%u %s" argsno (Cl.to_string h) *) in
- let script = List.rev (mk_arg st hd) @ convert st what in
+ let text = "" (* Printf.sprintf "%u %s" parsno (Cl.to_string h) *) in
+ let script = List.rev (mk_arg st hd) in
match rc with
- | Some (i, j) ->
+ | Some (i, j, uri, tyno) ->
let classes, tl, _, where = split2_last classes tl in
let script = List.rev (mk_arg st where) @ script in
let synth = I.S.add 1 synth in
- let qs = proc_bkd_proofs (next st) synth classes tl in
+ let names = get_ind_names uri tyno in
+ let qs = proc_bkd_proofs (next st) synth names classes tl in
if is_rewrite_right hd then
- script @ mk_rewrite st dtext where qs tl false
+ script @ mk_rewrite st dtext where qs tl false what
else if is_rewrite_left hd then
- script @ mk_rewrite st dtext where qs tl true
+ script @ mk_rewrite st dtext where qs tl true what
else
- let predicate = List.nth tl (argsno - i) in
- let e = Cn.mk_pattern 0 (T.mk_arel 1 "") (* j predicate *) in
+ let predicate = List.nth tl (parsno - i) in
+ let e = Cn.mk_pattern j predicate in
let using = Some hd in
- script @
+ (* convert_elim st what what e @ *) script @
[T.Elim (where, using, e, dtext ^ text); T.Branch (qs, "")]
| None ->
- let qs = proc_bkd_proofs (next st) synth classes tl in
+ let qs = proc_bkd_proofs (next st) synth [] classes tl in
let hd = mk_exp_args hd tl classes synth in
script @ [T.Apply (hd, dtext ^ text); T.Branch (qs, "")]
else
[T.Apply (what, dtext)]
in
- mk_intros st script
+ mk_intros st what script
and proc_other st what =
let text = Printf.sprintf "%s: %s" "UNEXPANDED" (string_of_head what) in
let script = [T.Note text] in
- mk_intros st script
-
-and proc_proof st = function
- | C.ALambda (_, name, w, t) -> proc_lambda st name w t
- | C.ALetIn (_, name, v, t) as what -> proc_letin st what name v t
- | C.ARel _ as what -> proc_rel st what
- | C.AMutConstruct _ as what -> proc_mutconstruct st what
- | C.AAppl (_, hd :: tl) as what -> proc_appl st what hd tl
- | what -> proc_other st what
-
-and proc_bkd_proofs st synth classes ts =
+ mk_intros st what script
+
+and proc_proof st t =
+ let f st =
+ let xtypes, note = match get_inner_types st t with
+ | Some (it, et) -> Some (H.cic it, H.cic et),
+ (Printf.sprintf "\nInferred: %s\nExpected: %s"
+ (Pp.ppterm (H.cic it)) (Pp.ppterm (H.cic et)))
+ | None -> None, "\nNo types"
+ in
+ let context, clears = Cn.get_clears st.context (H.cic t) xtypes in
+ let note = Pp.ppcontext st.context ^ note in
+ {st with context = context; clears = clears; clears_note = note; }
+ in
+ match t with
+ | C.ALambda (_, name, w, t) -> proc_lambda st name w t
+ | C.ALetIn (_, name, v, t) as what -> proc_letin (f st) what name v t
+ | C.ARel _ as what -> proc_rel (f st) what
+ | C.AMutConstruct _ as what -> proc_mutconstruct (f st) what
+ | C.AAppl (_, hd :: tl) as what -> proc_appl (f st) what hd tl
+ | what -> proc_other (f st) what
+
+and proc_bkd_proofs st synth names classes ts =
try
+ let get_note =
+ let names = ref (names, push st) in
+ fun f ->
+ match !names with
+ | [], st -> fun _ -> f st
+ | "" :: tl, st -> names := tl, st; fun _ -> f st
+ | hd :: tl, st ->
+ let note = case st hd in
+ names := tl, inc st;
+ fun b -> if b then T.Note note :: f st else f st
+ in
let _, dtext = test_depth st in
let aux (inv, _) v =
if I.overlaps synth inv then None else
- if I.S.is_empty inv then Some (proc_proof st v) else
- Some [T.Apply (v, dtext ^ "dependent")]
+ if I.S.is_empty inv then Some (get_note (fun st -> proc_proof st v)) else
+ Some (fun _ -> [T.Apply (v, dtext ^ "dependent")])
in
- List.rev (T.list_map2_filter aux classes ts)
+ let ps = T.list_map2_filter aux classes ts in
+ let b = List.length ps > 1 in
+ List.rev_map (fun f -> f b) ps
+
with Invalid_argument s -> failwith ("A2P.proc_bkd_proofs: " ^ s)
(* object costruction *******************************************************)
let proc_obj st = function
| C.AConstant (_, _, s, Some v, t, [], pars) when is_theorem pars ->
let ast = proc_proof st v in
- let count = T.count_steps 0 ast in
- let text = Printf.sprintf "tactics: %u" count in
- T.Theorem (s, t, text) :: ast @ [T.Qed ""]
+ let steps, nodes = T.count_steps 0 ast, T.count_nodes 0 ast in
+ let text = Printf.sprintf "tactics: %u\nnodes: %u" steps nodes in
+ if st.skip_thm_and_qed then ast
+ else T.Theorem (Some s, t, "") :: ast @ [T.Qed text]
| _ ->
failwith "not a theorem"
(* interface functions ******************************************************)
-let acic2procedural ~ids_to_inner_sorts ~ids_to_inner_types ?depth prefix aobj =
+let acic2procedural ~ids_to_inner_sorts ~ids_to_inner_types ?depth
+?(skip_thm_and_qed=false) prefix aobj =
let st = {
- sorts = ids_to_inner_sorts;
- types = ids_to_inner_types;
- prefix = prefix;
- max_depth = depth;
- depth = 0;
- context = [];
- intros = []
+ sorts = ids_to_inner_sorts;
+ types = ids_to_inner_types;
+ prefix = prefix;
+ max_depth = depth;
+ depth = 0;
+ context = [];
+ intros = [];
+ clears = [];
+ clears_note = "";
+ case = [];
+ skip_thm_and_qed = skip_thm_and_qed;
} in
HLog.debug "Procedural: level 2 transformation";
let steps = proc_obj st aobj in