module N = Alpha
type status = {
+ i: string; (* item name *)
n: string; (* reference name *)
s: int list; (* scope *)
+ c: C.context (* context for kernel calls *)
}
(* internal functions *******************************************************)
let malformed s =
X.error ("engine: malformed term: " ^ s)
+let missing s =
+ X.log ("engine: missing macro for " ^ s)
+
(* generic term processing *)
-let proc_sort is = function
+let mk_ptr st name =
+ if G.is_global_id name then P.sprintf "%s.%s" st.i name else ""
+
+let get_macro s =
+ let rec aux = function
+ | [] -> "", G.nan
+ | (r, m, a) :: _ when r = s -> m, a
+ | _ :: tl -> aux tl
+ in
+ aux !G.macro
+
+let get_head = function
+ | C.Const c :: ts ->
+ let s, _ = K.resolve_reference c in
+ let macro, arity = get_macro s in
+ if arity = L.length ts then Some (macro, ts) else begin missing s; None end
+ | _ -> None
+
+let proc_sort st is = function
| C.Prop -> T.Macro "PROP" :: is
| C.Type [`Type, u] -> T.Macro "TYPE" :: T.arg (U.string_of_uri u) :: is
| C.Type [`CProp, u] -> T.Macro "CROP" :: T.arg (U.string_of_uri u) :: is
| C.Type _ -> malformed "T1"
-let rec proc_term is c = function
+let rec proc_term st is = function
| C.Appl []
| C.Meta _
| C.Implicit _ -> malformed "T2"
| C.Rel m ->
- let name = K.resolve_lref c m in
- T.Macro "LREF" :: T.arg name :: T.free name :: is
+ let name = K.resolve_lref st.c m in
+ T.Macro "LREF" :: T.arg name :: T.free (mk_ptr st name) :: is
| C.Appl ts ->
- let riss = L.rev_map (proc_term [] c) ts in
- T.Macro "APPL" :: T.mk_rev_args riss is
+ let macro, ts = match get_head ts with
+ | Some (macro, ts) -> macro, ts
+ | None -> "APPL", ts
+ in
+ let riss = L.rev_map (proc_term st []) ts in
+ T.Macro macro :: T.mk_rev_args riss is
| C.Prod (s, w, t) ->
- let is_w = proc_term [] c w in
- let is_t = proc_term is (K.add_dec s w c) t in
- T.Macro "PROD" :: T.arg s :: T.Group is_w :: is_t
+ let is_w = proc_term st [] w in
+ let is_t = proc_term {st with c=K.add_dec s w st.c} is t in
+ T.Macro "PROD" :: T.arg s :: T.free (mk_ptr st s) :: T.Group is_w :: is_t
| C.Lambda (s, w, t) ->
- let is_w = proc_term [] c w in
- let is_t = proc_term is (K.add_dec s w c) t in
- T.Macro "ABST" :: T.arg s :: T.Group is_w :: is_t
+ let is_w = proc_term st [] w in
+ let is_t = proc_term {st with c=K.add_dec s w st.c} is t in
+ T.Macro "ABST" :: T.arg s :: T.free (mk_ptr st s) :: T.Group is_w :: is_t
| C.LetIn (s, w, v, t) ->
- let is_w = proc_term [] c w in
- let is_v = proc_term [] c v in
- let is_t = proc_term is (K.add_def s w v c) t in
- T.Macro "ABBR" :: T.arg s :: T.Group is_w :: T.Group is_v :: is_t
+ let is_w = proc_term st [] w in
+ let is_v = proc_term st [] v in
+ let is_t = proc_term {st with c=K.add_def s w v st.c} is t in
+ T.Macro "ABBR" :: T.arg s :: T.free (mk_ptr st s) :: T.Group is_w :: T.Group is_v :: is_t
| C.Sort s ->
- proc_sort is s
- | C.Const (R.Ref (u, r)) ->
- let ss = K.segments_of_uri u in
- let _, _, _, _, obj = E.get_checked_obj G.status u in
- let ss, name = K.name_of_reference ss (obj, r) in
- T.Macro "GREF" :: T.arg name :: T.free (X.rev_map_concat X.id "." "type" ss) :: is
+ proc_sort st is s
+ | C.Const c ->
+ let s, name = K.resolve_reference c in
+ T.Macro "GREF" :: T.arg name :: T.free s :: is
| C.Match (w, u, v, ts) ->
- let is_w = proc_term [] c (C.Const w) in
- let is_u = proc_term [] c u in
- let is_v = proc_term [] c v in
- let riss = L.rev_map (proc_term [] c) ts in
+ let is_w = proc_term st [] (C.Const w) in
+ let is_u = proc_term st [] u in
+ let is_v = proc_term st [] v in
+ let riss = L.rev_map (proc_term st []) ts in
T.Macro "CASE" :: T.Group is_w :: T.Group is_u :: T.Group is_v :: T.mk_rev_args riss is
-let proc_term is c t = try proc_term is c t with
+let proc_term st is t = try proc_term st is t with
| E.ObjectNotFound _
| Invalid_argument "List.nth"
| Failure "nth"
(* proof processing *)
-let typeof c = function
+let typeof st = function
| C.Appl [t]
- | t -> K.whd_typeof c t
+ | t -> K.whd_typeof st.c t
-let init () = {
- n = ""; s = [1]
+let init i = {
+ i = i;
+ n = ""; s = [1]; c = [];
}
-let push st n = {
+let push st n = {st with
n = n; s = 1 :: st.s;
}
-let next st = {
+let next st f = {st with
+ c = f st.c;
n = ""; s = match st.s with [] -> failwith "hd" | i :: tl -> succ i :: tl
}
let mk_open st ris =
if st.n = "" then ris else
- T.free (scope st) :: T.free st.n :: T.arg st.n :: T.Macro "OPEN" :: ris
+ T.free (scope st) :: T.free (mk_ptr st st.n) :: T.arg st.n :: T.Macro "OPEN" :: ris
-let mk_dec kind w s ris =
+let mk_dec st kind w s ris =
let w = if !G.no_types then [] else w in
- T.Group w :: T.free s :: T.arg s :: T.Macro kind :: ris
+ T.Group w :: T.free (mk_ptr st s) :: T.arg s :: T.Macro kind :: ris
-let mk_inferred st c t ris =
- let u = typeof c t in
- let is_u = proc_term [] c u in
- mk_dec "DECL" is_u st.n ris
+let mk_inferred st t ris =
+ let u = typeof st t in
+ let is_u = proc_term st [] u in
+ mk_dec st "DECL" is_u st.n ris
-let rec proc_proof st ris c t = match t with
+let rec proc_proof st ris t = match t with
| C.Appl []
| C.Meta _
| C.Implicit _
| C.Sort _
| C.Prod _ -> malformed "P1"
| C.Const _
- | C.Rel _ -> proc_proof st ris c (C.Appl [t])
+ | C.Rel _ -> proc_proof st ris (C.Appl [t])
| C.Lambda (s, w, t) ->
- let is_w = proc_term [] c w in
+ let is_w = proc_term st [] w in
let ris = mk_open st ris in
- proc_proof (next st) (mk_dec "PRIM" is_w s ris) (K.add_dec s w c) t
+ proc_proof (next st (K.add_dec s w)) (mk_dec st "PRIM" is_w s ris) t
| C.Appl (t0 :: ts) ->
- let rts = X.rev_neg_filter (K.not_prop2 c) [t0] ts in
- let ris = T.Macro "STEP" :: mk_inferred st c t ris in
- let tts = L.rev_map (proc_term [] c) rts in
+ let rts = X.rev_neg_filter (K.not_prop2 st.c) [t0] ts in
+ let ris = T.Macro "STEP" :: mk_inferred st t ris in
+ let tts = L.rev_map (proc_term st []) rts in
mk_exit st (T.rev_mk_args tts ris)
| C.Match (w, u, v, ts) ->
- let rts = X.rev_neg_filter (K.not_prop2 c) [v] ts in
- let ris = T.Macro "DEST" :: mk_inferred st c t ris in
- let tts = L.rev_map (proc_term [] c) rts in
+ let rts = X.rev_neg_filter (K.not_prop2 st.c) [v] ts in
+ let ris = T.Macro "DEST" :: mk_inferred st t ris in
+ let tts = L.rev_map (proc_term st []) rts in
mk_exit st (T.rev_mk_args tts ris)
| C.LetIn (s, w, v, t) ->
- let is_w = proc_term [] c w in
+ let is_w = proc_term st [] w in
let ris = mk_open st ris in
- if K.not_prop1 c w then
- let is_v = proc_term [] c v in
- let ris = T.Group is_v :: T.Macro "BODY" :: mk_dec "DECL" is_w s ris in
- proc_proof (next st) ris (K.add_def s w v c) t
+ if K.not_prop1 st.c w then
+ let is_v = proc_term st [] v in
+ let ris = T.Group is_v :: T.Macro "BODY" :: mk_dec st "DECL" is_w s ris in
+ proc_proof (next st (K.add_def s w v)) ris t
else
- let ris_v = proc_proof (push st s) ris c v in
- proc_proof (next st) ris_v (K.add_def s w v c) t
+ let ris_v = proc_proof (push st s) ris v in
+ proc_proof (next st (K.add_def s w v)) ris_v t
-let proc_proof rs c t = try proc_proof (init ()) rs c t with
+let proc_proof st rs t = try proc_proof st rs t with
| E.ObjectNotFound _
| Invalid_argument "List.nth"
| Failure "nth"
let note = T.Note "This file was automatically generated by MaTeX: do not edit"
let proc_item item s ss t =
+ let st = init ss in
let tt = N.process_top_term s t in (* alpha-conversion *)
let is = [T.Macro "end"; T.arg item] in
- note :: T.Macro "begin" :: T.arg item :: T.arg s :: T.free ss :: proc_term is [] tt
+ note :: T.Macro "begin" :: T.arg item :: T.arg s :: T.free ss :: proc_term st is tt
let proc_top_proof s ss t =
+ let st = init ss in
let t0 = A.process_top_term s t in (* anticipation *)
let tt = N.process_top_term s t0 in (* alpha-conversion *)
let ris = [T.free ss; T.arg s; T.arg "proof"; T.Macro "begin"; note] in
- L.rev (T.arg "proof" :: T.Macro "end" :: proc_proof ris [] tt)
+ L.rev (T.arg "proof" :: T.Macro "end" :: proc_proof st ris tt)
let open_out_tex s =
let fname = s ^ T.file_ext in