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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Xml_datatype
open Vernacexpr
open Constrexpr
open Names
open Misctypes
open Bigint
open Decl_kinds
open Extend
open Libnames
let unlock loc =
let start, stop = Loc.unloc loc in
(string_of_int start, string_of_int stop)
let xmlNoop = (* almost noop *)
PCData ""
let xmlWithLoc loc ename attr xml =
let start, stop = unlock loc in
Element(ename, [ "begin", start; "end", stop ] @ attr, xml)
let get_fst_attr_in_xml_list attr xml_list =
let attrs_list =
List.map (function
| Element (_, attrs, _) -> (List.filter (fun (a,_) -> a = attr) attrs)
| _ -> [])
xml_list in
match List.flatten attrs_list with
| [] -> (attr, "")
| l -> (List.hd l)
let backstep_loc xmllist =
let start_att = get_fst_attr_in_xml_list "begin" xmllist in
let stop_att = get_fst_attr_in_xml_list "end" (List.rev xmllist) in
[start_att ; stop_att]
let compare_begin_att xml1 xml2 =
let att1 = get_fst_attr_in_xml_list "begin" [xml1] in
let att2 = get_fst_attr_in_xml_list "begin" [xml2] in
match att1, att2 with
| (_, s1), (_, s2) when s1 == "" || s2 == "" -> 0
| (_, s1), (_, s2) when int_of_string s1 > int_of_string s2 -> 1
| (_, s1), (_, s2) when int_of_string s1 < int_of_string s2 -> -1
| _ -> 0
let xmlBeginSection loc name = xmlWithLoc loc "beginsection" ["name", name] []
let xmlEndSegment loc name = xmlWithLoc loc "endsegment" ["name", name] []
let xmlThm typ name loc xml =
xmlWithLoc loc "theorem" ["type", typ; "name", name] xml
let xmlDef typ name loc xml =
xmlWithLoc loc "definition" ["type", typ; "name", name] xml
let xmlNotation attr name loc xml =
xmlWithLoc loc "notation" (("name", name) :: attr) xml
let xmlReservedNotation attr name loc =
xmlWithLoc loc "reservednotation" (("name", name) :: attr) []
let xmlCst name ?(attr=[]) loc =
xmlWithLoc loc "constant" (("name", name) :: attr) []
let xmlOperator name ?(attr=[]) ?(pprules=[]) loc =
xmlWithLoc loc "operator"
(("name", name) :: List.map (fun (a,b) -> "format"^a,b) pprules @ attr) []
let xmlApply loc ?(attr=[]) xml = xmlWithLoc loc "apply" attr xml
let xmlToken loc ?(attr=[]) xml = xmlWithLoc loc "token" attr xml
let xmlTyped xml = Element("typed", (backstep_loc xml), xml)
let xmlReturn ?(attr=[]) xml = Element("return", attr, xml)
let xmlCase xml = Element("case", [], xml)
let xmlScrutinee ?(attr=[]) xml = Element("scrutinee", attr, xml)
let xmlWith xml = Element("with", [], xml)
let xmlAssign id xml = Element("assign", ["target",string_of_id id], [xml])
let xmlInductive kind loc xml = xmlWithLoc loc "inductive" ["kind",kind] xml
let xmlCoFixpoint xml = Element("cofixpoint", [], xml)
let xmlFixpoint xml = Element("fixpoint", [], xml)
let xmlCheck loc xml = xmlWithLoc loc "check" [] xml
let xmlAssumption kind loc xml = xmlWithLoc loc "assumption" ["kind",kind] xml
let xmlComment loc xml = xmlWithLoc loc "comment" [] xml
let xmlCanonicalStructure attr loc = xmlWithLoc loc "canonicalstructure" attr []
let xmlQed ?(attr=[]) loc = xmlWithLoc loc "qed" attr []
let xmlPatvar id loc = xmlWithLoc loc "patvar" ["id", id] []
let xmlReference ref =
let name = Libnames.string_of_reference ref in
let i, j = Loc.unloc (Libnames.loc_of_reference ref) in
let b, e = string_of_int i, string_of_int j in
Element("reference",["name", name; "begin", b; "end", e] ,[])
let xmlRequire loc ?(attr=[]) xml = xmlWithLoc loc "require" attr xml
let xmlImport loc ?(attr=[]) xml = xmlWithLoc loc "import" attr xml
let xmlAddLoadPath loc ?(attr=[]) xml = xmlWithLoc loc "addloadpath" attr xml
let xmlRemoveLoadPath loc ?(attr=[]) = xmlWithLoc loc "removeloadpath" attr
let xmlAddMLPath loc ?(attr=[]) = xmlWithLoc loc "addmlpath" attr
let xmlExtend loc xml = xmlWithLoc loc "extend" [] xml
let xmlScope loc action ?(attr=[]) name xml =
xmlWithLoc loc "scope" (["name",name;"action",action] @ attr) xml
let xmlProofMode loc name = xmlWithLoc loc "proofmode" ["name",name] []
let xmlProof loc xml = xmlWithLoc loc "proof" [] xml
let xmlRawTactic name rtac =
Element("rawtactic", ["name",name],
[PCData (Pp.string_of_ppcmds (Pptactic.pr_raw_tactic rtac))])
let xmlSectionSubsetDescr name ssd =
Element("sectionsubsetdescr",["name",name],
[PCData (Proof_using.to_string ssd)])
let xmlDeclareMLModule loc s =
xmlWithLoc loc "declarexmlmodule" []
(List.map (fun x -> Element("path",["value",x],[])) s)
(* tactics *)
let xmlLtac loc xml = xmlWithLoc loc "ltac" [] xml
(* toplevel commands *)
let xmlGallina loc xml = xmlWithLoc loc "gallina" [] xml
let xmlTODO loc x =
xmlWithLoc loc "todo" [] [PCData (Pp.string_of_ppcmds (Ppvernac.pr_vernac x))]
let string_of_name n =
match n with
| Anonymous -> "_"
| Name id -> Id.to_string id
let string_of_glob_sort s =
match s with
| GProp -> "Prop"
| GSet -> "Set"
| GType _ -> "Type"
let string_of_cast_sort c =
match c with
| CastConv _ -> "CastConv"
| CastVM _ -> "CastVM"
| CastNative _ -> "CastNative"
| CastCoerce -> "CastCoerce"
let string_of_case_style s =
match s with
| LetStyle -> "Let"
| IfStyle -> "If"
| LetPatternStyle -> "LetPattern"
| MatchStyle -> "Match"
| RegularStyle -> "Regular"
let attribute_of_syntax_modifier sm =
match sm with
| SetItemLevel (sl, NumLevel n) ->
List.map (fun s -> ("itemlevel", s)) sl @ ["level", string_of_int n]
| SetItemLevel (sl, NextLevel) ->
List.map (fun s -> ("itemlevel", s)) sl @ ["level", "next"]
| SetLevel i -> ["level", string_of_int i]
| SetAssoc a ->
begin match a with
| NonA -> ["",""]
| RightA -> ["associativity", "right"]
| LeftA -> ["associativity", "left"]
end
| SetEntryType (s, _) -> ["entrytype", s]
| SetOnlyParsing v -> ["compat", Flags.pr_version v]
| SetFormat (system, (loc, s)) ->
let start, stop = unlock loc in
["format-"^system, s; "begin", start; "end", stop]
let string_of_assumption_kind l a many =
match l, a, many with
| (Discharge, Logical, true) -> "Hypotheses"
| (Discharge, Logical, false) -> "Hypothesis"
| (Discharge, Definitional, true) -> "Variables"
| (Discharge, Definitional, false) -> "Variable"
| (Global, Logical, true) -> "Axioms"
| (Global, Logical, false) -> "Axiom"
| (Global, Definitional, true) -> "Parameters"
| (Global, Definitional, false) -> "Parameter"
| (Local, Logical, true) -> "Local Axioms"
| (Local, Logical, false) -> "Local Axiom"
| (Local, Definitional, true) -> "Local Parameters"
| (Local, Definitional, false) -> "Local Parameter"
| (Global, Conjectural, _) -> "Conjecture"
| ((Discharge | Local), Conjectural, _) -> assert false
let rec pp_bindlist bl =
let tlist =
List.flatten
(List.map
(fun (loc_names, _, e) ->
let names =
(List.map
(fun (loc, name) ->
xmlCst (string_of_name name) loc) loc_names) in
match e with
| CHole _ -> names
| _ -> names @ [pp_expr e])
bl) in
match tlist with
| [e] -> e
| l -> xmlTyped l
and pp_decl_notation ((_, s), ce, sc) = (* don't know what it is for now *)
Element ("decl_notation", ["name", s], [pp_expr ce])
and pp_local_binder lb = (* don't know what it is for now *)
match lb with
| LocalRawDef ((_, nam), ce) ->
let attrs = ["name", string_of_name nam] in
pp_expr ~attr:attrs ce
| LocalRawAssum (namll, _, ce) ->
let ppl =
List.map (fun (loc, nam) -> (xmlCst (string_of_name nam) loc)) namll in
xmlTyped (ppl @ [pp_expr ce])
and pp_local_decl_expr lde = (* don't know what it is for now *)
match lde with
| AssumExpr (_, ce) -> pp_expr ce
| DefExpr (_, ce, _) -> pp_expr ce
and pp_inductive_expr ((_, ((l, id),_)), lbl, ceo, _, cl_or_rdexpr) =
(* inductive_expr *)
let b,e = Loc.unloc l in
let location = ["begin", string_of_int b; "end", string_of_int e] in
[Element ("lident", ["name", Id.to_string id] @ location, [])] @ (* inductive name *)
begin match cl_or_rdexpr with
| Constructors coel -> List.map (fun (_, (_, ce)) -> pp_expr ce) coel
| RecordDecl (_, ldewwwl) ->
List.map (fun (((_, x), _), _) -> pp_local_decl_expr x) ldewwwl
end @
begin match ceo with (* don't know what it is for now *)
| Some ce -> [pp_expr ce]
| None -> []
end @
(List.map pp_local_binder lbl)
and pp_recursion_order_expr optid roe = (* don't know what it is for now *)
let attrs =
match optid with
| None -> []
| Some (loc, id) ->
let start, stop = unlock loc in
["begin", start; "end", stop ; "name", Id.to_string id] in
let kind, expr =
match roe with
| CStructRec -> "struct", []
| CWfRec e -> "rec", [pp_expr e]
| CMeasureRec (e, None) -> "mesrec", [pp_expr e]
| CMeasureRec (e, Some rel) -> "mesrec", [pp_expr e] @ [pp_expr rel] in
Element ("recursion_order", ["kind", kind] @ attrs, expr)
and pp_fixpoint_expr (((loc, id), pl), (optid, roe), lbl, ce, ceo) =
(* fixpoint_expr *)
let start, stop = unlock loc in
let id = Id.to_string id in
[Element ("lident", ["begin", start; "end", stop ; "name", id], [])] @
(* fixpoint name *)
[pp_recursion_order_expr optid roe] @
(List.map pp_local_binder lbl) @
[pp_expr ce] @
begin match ceo with (* don't know what it is for now *)
| Some ce -> [pp_expr ce]
| None -> []
end
and pp_cofixpoint_expr (((loc, id), pl), lbl, ce, ceo) = (* cofixpoint_expr *)
(* Nota: it is like fixpoint_expr without (optid, roe)
* so could be merged if there is no more differences *)
let start, stop = unlock loc in
let id = Id.to_string id in
[Element ("lident", ["begin", start; "end", stop ; "name", id], [])] @
(* cofixpoint name *)
(List.map pp_local_binder lbl) @
[pp_expr ce] @
begin match ceo with (* don't know what it is for now *)
| Some ce -> [pp_expr ce]
| None -> []
end
and pp_lident (loc, id) = xmlCst (Id.to_string id) loc
and pp_simple_binder (idl, ce) = List.map pp_lident idl @ [pp_expr ce]
and pp_cases_pattern_expr cpe =
match cpe with
| CPatAlias (loc, cpe, id) ->
xmlApply loc
(xmlOperator "alias" ~attr:["name", string_of_id id] loc ::
[pp_cases_pattern_expr cpe])
| CPatCstr (loc, ref, cpel1, cpel2) ->
xmlApply loc
(xmlOperator "reference"
~attr:["name", Libnames.string_of_reference ref] loc ::
[Element ("impargs", [], (List.map pp_cases_pattern_expr cpel1));
Element ("args", [], (List.map pp_cases_pattern_expr cpel2))])
| CPatAtom (loc, optr) ->
let attrs = match optr with
| None -> []
| Some r -> ["name", Libnames.string_of_reference r] in
xmlApply loc (xmlOperator "atom" ~attr:attrs loc :: [])
| CPatOr (loc, cpel) ->
xmlApply loc (xmlOperator "or" loc :: List.map pp_cases_pattern_expr cpel)
| CPatNotation (loc, n, (subst_constr, subst_rec), cpel) ->
xmlApply loc
(xmlOperator "notation" loc ::
[xmlOperator n loc;
Element ("subst", [],
[Element ("subterms", [],
List.map pp_cases_pattern_expr subst_constr);
Element ("recsubterms", [],
List.map
(fun (cpel) ->
Element ("recsubterm", [],
List.map pp_cases_pattern_expr cpel))
subst_rec)]);
Element ("args", [], (List.map pp_cases_pattern_expr cpel))])
| CPatPrim (loc, tok) -> pp_token loc tok
| CPatRecord (loc, rcl) ->
xmlApply loc
(xmlOperator "record" loc ::
List.map (fun (r, cpe) ->
Element ("field",
["reference", Libnames.string_of_reference r],
[pp_cases_pattern_expr cpe]))
rcl)
| CPatDelimiters (loc, delim, cpe) ->
xmlApply loc
(xmlOperator "delimiter" ~attr:["name", delim] loc ::
[pp_cases_pattern_expr cpe])
and pp_case_expr (e, (name, pat)) =
match name, pat with
| None, None -> xmlScrutinee [pp_expr e]
| Some (loc, name), None ->
let start, stop= unlock loc in
xmlScrutinee ~attr:["name", string_of_name name;
"begin", start; "end", stop] [pp_expr e]
| Some (loc, name), Some p ->
let start, stop= unlock loc in
xmlScrutinee ~attr:["name", string_of_name name;
"begin", start; "end", stop]
[Element ("in", [], [pp_cases_pattern_expr p]) ; pp_expr e]
| None, Some p ->
xmlScrutinee [Element ("in", [], [pp_cases_pattern_expr p]) ; pp_expr e]
and pp_branch_expr_list bel =
xmlWith
(List.map
(fun (_, cpel, e) ->
let ppcepl =
List.map pp_cases_pattern_expr (List.flatten (List.map snd cpel)) in
let ppe = [pp_expr e] in
xmlCase (ppcepl @ ppe))
bel)
and pp_token loc tok =
let tokstr =
match tok with
| String s -> PCData s
| Numeral n -> PCData (to_string n) in
xmlToken loc [tokstr]
and pp_local_binder_list lbl =
let l = (List.map pp_local_binder lbl) in
Element ("recurse", (backstep_loc l), l)
and pp_const_expr_list cel =
let l = List.map pp_expr cel in
Element ("recurse", (backstep_loc l), l)
and pp_expr ?(attr=[]) e =
match e with
| CRef (r, _) ->
xmlCst ~attr
(Libnames.string_of_reference r) (Libnames.loc_of_reference r)
| CProdN (loc, bl, e) ->
xmlApply loc
(xmlOperator "forall" loc :: [pp_bindlist bl] @ [pp_expr e])
| CApp (loc, (_, hd), args) ->
xmlApply ~attr loc (pp_expr hd :: List.map (fun (e,_) -> pp_expr e) args)
| CAppExpl (loc, (_, r, _), args) ->
xmlApply ~attr loc
(xmlCst (Libnames.string_of_reference r)
(Libnames.loc_of_reference r) :: List.map pp_expr args)
| CNotation (loc, notation, ([],[],[])) ->
xmlOperator notation loc
| CNotation (loc, notation, (args, cell, lbll)) ->
let fmts = Notation.find_notation_extra_printing_rules notation in
let oper = xmlOperator notation loc ~pprules:fmts in
let cels = List.map pp_const_expr_list cell in
let lbls = List.map pp_local_binder_list lbll in
let args = List.map pp_expr args in
xmlApply loc (oper :: (List.sort compare_begin_att (args @ cels @ lbls)))
| CSort(loc, s) ->
xmlOperator (string_of_glob_sort s) loc
| CDelimiters (loc, scope, ce) ->
xmlApply loc (xmlOperator "delimiter" ~attr:["name", scope] loc ::
[pp_expr ce])
| CPrim (loc, tok) -> pp_token loc tok
| CGeneralization (loc, kind, _, e) ->
let kind= match kind with
| Explicit -> "explicit"
| Implicit -> "implicit" in
xmlApply loc
(xmlOperator "generalization" ~attr:["kind", kind] loc :: [pp_expr e])
| CCast (loc, e, tc) ->
begin match tc with
| CastConv t | CastVM t |CastNative t ->
xmlApply loc
(xmlOperator ":" loc ~attr:["kind", (string_of_cast_sort tc)] ::
[pp_expr e; pp_expr t])
| CastCoerce ->
xmlApply loc
(xmlOperator ":" loc ~attr:["kind", "CastCoerce"] ::
[pp_expr e])
end
| CEvar (loc, ek, cel) ->
let ppcel = List.map (fun (id,e) -> xmlAssign id (pp_expr e)) cel in
xmlApply loc
(xmlOperator "evar" loc ~attr:["id", string_of_id ek] ::
ppcel)
| CPatVar (loc, id) -> xmlPatvar (string_of_id id) loc
| CHole (loc, _, _, _) -> xmlCst ~attr "_" loc
| CIf (loc, test, (_, ret), th, el) ->
let return = match ret with
| None -> []
| Some r -> [xmlReturn [pp_expr r]] in
xmlApply loc
(xmlOperator "if" loc ::
return @ [pp_expr th] @ [pp_expr el])
| CLetTuple (loc, names, (_, ret), value, body) ->
let return = match ret with
| None -> []
| Some r -> [xmlReturn [pp_expr r]] in
xmlApply loc
(xmlOperator "lettuple" loc ::
return @
(List.map (fun (loc, var) -> xmlCst (string_of_name var) loc) names) @
[pp_expr value; pp_expr body])
| CCases (loc, sty, ret, cel, bel) ->
let return = match ret with
| None -> []
| Some r -> [xmlReturn [pp_expr r]] in
xmlApply loc
(xmlOperator "match" loc ~attr:["style", (string_of_case_style sty)] ::
(return @
[Element ("scrutinees", [], List.map pp_case_expr cel)] @
[pp_branch_expr_list bel]))
| CRecord (_, _, _) -> assert false
| CLetIn (loc, (varloc, var), value, body) ->
xmlApply loc
(xmlOperator "let" loc ::
[xmlCst (string_of_name var) varloc; pp_expr value; pp_expr body])
| CLambdaN (loc, bl, e) ->
xmlApply loc
(xmlOperator "lambda" loc :: [pp_bindlist bl] @ [pp_expr e])
| CCoFix (_, _, _) -> assert false
| CFix (loc, lid, fel) ->
xmlApply loc
(xmlOperator "fix" loc ::
List.flatten (List.map
(fun (a,b,cl,c,d) -> pp_fixpoint_expr ((a,None),b,cl,c,Some d))
fel))
let pp_comment (c) =
match c with
| CommentConstr e -> [pp_expr e]
| CommentString s -> [Element ("string", [], [PCData s])]
| CommentInt i -> [PCData (string_of_int i)]
let rec tmpp v loc =
match v with
(* Control *)
| VernacLoad (verbose,f) ->
xmlWithLoc loc "load" ["verbose",string_of_bool verbose;"file",f] []
| VernacTime l ->
xmlApply loc (Element("time",[],[]) ::
List.map (fun(loc,e) ->tmpp e loc) l)
| VernacRedirect (s, l) ->
xmlApply loc (Element("redirect",["path", s],[]) ::
List.map (fun(loc,e) ->tmpp e loc) l)
| VernacTimeout (s,e) ->
xmlApply loc (Element("timeout",["val",string_of_int s],[]) ::
[tmpp e loc])
| VernacFail e -> xmlApply loc (Element("fail",[],[]) :: [tmpp e loc])
| VernacError _ -> xmlWithLoc loc "error" [] []
(* Syntax *)
| VernacTacticNotation _ as x ->
xmlLtac loc [PCData (Pp.string_of_ppcmds (Ppvernac.pr_vernac x))]
| VernacSyntaxExtension (_, ((_, name), sml)) ->
let attrs = List.flatten (List.map attribute_of_syntax_modifier sml) in
xmlReservedNotation attrs name loc
| VernacOpenCloseScope (_,(true,name)) -> xmlScope loc "open" name []
| VernacOpenCloseScope (_,(false,name)) -> xmlScope loc "close" name []
| VernacDelimiters (name,Some tag) ->
xmlScope loc "delimit" name ~attr:["delimiter",tag] []
| VernacDelimiters (name,None) ->
xmlScope loc "undelimit" name ~attr:[] []
| VernacBindScope (name,l) ->
xmlScope loc "bind" name
(List.map (function
| ByNotation(loc,name,None) -> xmlNotation [] name loc []
| ByNotation(loc,name,Some d) ->
xmlNotation ["delimiter",d] name loc []
| AN ref -> xmlReference ref) l)
| VernacInfix (_,((_,name),sml),ce,sn) ->
let attrs = List.flatten (List.map attribute_of_syntax_modifier sml) in
let sc_attr =
match sn with
| Some scope -> ["scope", scope]
| None -> [] in
xmlNotation (sc_attr @ attrs) name loc [pp_expr ce]
| VernacNotation (_, ce, (lstr, sml), sn) ->
let name = snd lstr in
let attrs = List.flatten (List.map attribute_of_syntax_modifier sml) in
let sc_attr =
match sn with
| Some scope -> ["scope", scope]
| None -> [] in
xmlNotation (sc_attr @ attrs) name loc [pp_expr ce]
| VernacNotationAddFormat _ as x -> xmlTODO loc x
| VernacUniverse _
| VernacConstraint _
| VernacPolymorphic (_, _) as x -> xmlTODO loc x
(* Gallina *)
| VernacDefinition (ldk, ((_,id),_), de) ->
let l, dk =
match ldk with
| Some l, dk -> (l, dk)
| None, dk -> (Global, dk) in (* Like in ppvernac.ml, l 585 *)
let e =
match de with
| ProveBody (_, ce) -> ce
| DefineBody (_, Some _, ce, None) -> ce
| DefineBody (_, None , ce, None) -> ce
| DefineBody (_, Some _, ce, Some _) -> ce
| DefineBody (_, None , ce, Some _) -> ce in
let str_dk = Kindops.string_of_definition_kind (l, false, dk) in
let str_id = Id.to_string id in
(xmlDef str_dk str_id loc [pp_expr e])
| VernacStartTheoremProof (tk, [ Some ((_,id),_), ([], statement, None) ], b) ->
let str_tk = Kindops.string_of_theorem_kind tk in
let str_id = Id.to_string id in
(xmlThm str_tk str_id loc [pp_expr statement])
| VernacStartTheoremProof _ as x -> xmlTODO loc x
| VernacEndProof pe ->
begin
match pe with
| Admitted -> xmlQed loc
| Proved (_, Some ((_, id), Some tk)) ->
let nam = Id.to_string id in
let typ = Kindops.string_of_theorem_kind tk in
xmlQed ~attr:["name", nam; "type", typ] loc
| Proved (_, Some ((_, id), None)) ->
let nam = Id.to_string id in
xmlQed ~attr:["name", nam] loc
| Proved _ -> xmlQed loc
end
| VernacExactProof _ as x -> xmlTODO loc x
| VernacAssumption ((l, a), _, sbwcl) ->
let binders = List.map (fun (_, (id, c)) -> (List.map fst id, c)) sbwcl in
let many =
List.length (List.flatten (List.map fst binders)) > 1 in
let exprs =
List.flatten (List.map pp_simple_binder binders) in
let l = match l with Some x -> x | None -> Decl_kinds.Global in
let kind = string_of_assumption_kind l a many in
xmlAssumption kind loc exprs
| VernacInductive (_, _, iednll) ->
let kind =
let (_, _, _, k, _),_ = List.hd iednll in
begin
match k with
| Record -> "Record"
| Structure -> "Structure"
| Inductive_kw -> "Inductive"
| CoInductive -> "CoInductive"
| Class _ -> "Class"
| Variant -> "Variant"
end in
let exprs =
List.flatten (* should probably not be flattened *)
(List.map
(fun (ie, dnl) -> (pp_inductive_expr ie) @
(List.map pp_decl_notation dnl)) iednll) in
xmlInductive kind loc exprs
| VernacFixpoint (_, fednll) ->
let exprs =
List.flatten (* should probably not be flattened *)
(List.map
(fun (fe, dnl) -> (pp_fixpoint_expr fe) @
(List.map pp_decl_notation dnl)) fednll) in
xmlFixpoint exprs
| VernacCoFixpoint (_, cfednll) ->
(* Nota: it is like VernacFixpoint without so could be merged *)
let exprs =
List.flatten (* should probably not be flattened *)
(List.map
(fun (cfe, dnl) -> (pp_cofixpoint_expr cfe) @
(List.map pp_decl_notation dnl)) cfednll) in
xmlCoFixpoint exprs
| VernacScheme _ as x -> xmlTODO loc x
| VernacCombinedScheme _ as x -> xmlTODO loc x
(* Gallina extensions *)
| VernacBeginSection (_, id) -> xmlBeginSection loc (Id.to_string id)
| VernacEndSegment (_, id) -> xmlEndSegment loc (Id.to_string id)
| VernacNameSectionHypSet _ as x -> xmlTODO loc x
| VernacRequire (from, import, l) ->
let import = match import with
| None -> []
| Some true -> ["export","true"]
| Some false -> ["import","true"]
in
let from = match from with
| None -> []
| Some r -> ["from", Libnames.string_of_reference r]
in
xmlRequire loc ~attr:(from @ import) (List.map (fun ref ->
xmlReference ref) l)
| VernacImport (true,l) ->
xmlImport loc ~attr:["export","true"] (List.map (fun ref ->
xmlReference ref) l)
| VernacImport (false,l) ->
xmlImport loc (List.map (fun ref ->
xmlReference ref) l)
| VernacCanonical r ->
let attr =
match r with
| AN (Qualid (_, q)) -> ["qualid", string_of_qualid q]
| AN (Ident (_, id)) -> ["id", Id.to_string id]
| ByNotation (_, s, _) -> ["notation", s] in
xmlCanonicalStructure attr loc
| VernacCoercion _ as x -> xmlTODO loc x
| VernacIdentityCoercion _ as x -> xmlTODO loc x
(* Type classes *)
| VernacInstance _ as x -> xmlTODO loc x
| VernacContext _ as x -> xmlTODO loc x
| VernacDeclareInstances _ as x -> xmlTODO loc x
| VernacDeclareClass _ as x -> xmlTODO loc x
(* Modules and Module Types *)
| VernacDeclareModule _ as x -> xmlTODO loc x
| VernacDefineModule _ as x -> xmlTODO loc x
| VernacDeclareModuleType _ as x -> xmlTODO loc x
| VernacInclude _ as x -> xmlTODO loc x
(* Solving *)
| (VernacSolve _ | VernacSolveExistential _) as x ->
xmlLtac loc [PCData (Pp.string_of_ppcmds (Ppvernac.pr_vernac x))]
(* Auxiliary file and library management *)
| VernacAddLoadPath (recf,name,None) ->
xmlAddLoadPath loc ~attr:["rec",string_of_bool recf;"path",name] []
| VernacAddLoadPath (recf,name,Some dp) ->
xmlAddLoadPath loc ~attr:["rec",string_of_bool recf;"path",name]
[PCData (Names.DirPath.to_string dp)]
| VernacRemoveLoadPath name -> xmlRemoveLoadPath loc ~attr:["path",name] []
| VernacAddMLPath (recf,name) ->
xmlAddMLPath loc ~attr:["rec",string_of_bool recf;"path",name] []
| VernacDeclareMLModule sl -> xmlDeclareMLModule loc sl
| VernacChdir _ as x -> xmlTODO loc x
(* State management *)
| VernacWriteState _ as x -> xmlTODO loc x
| VernacRestoreState _ as x -> xmlTODO loc x
(* Resetting *)
| VernacResetName _ as x -> xmlTODO loc x
| VernacResetInitial as x -> xmlTODO loc x
| VernacBack _ as x -> xmlTODO loc x
| VernacBackTo _ -> PCData "VernacBackTo"
(* Commands *)
| VernacDeclareTacticDefinition _ as x -> xmlTODO loc x
| VernacCreateHintDb _ as x -> xmlTODO loc x
| VernacRemoveHints _ as x -> xmlTODO loc x
| VernacHints _ as x -> xmlTODO loc x
| VernacSyntacticDefinition ((_, name), (idl, ce), _, _) ->
let name = Id.to_string name in
let attrs = List.map (fun id -> ("id", Id.to_string id)) idl in
xmlNotation attrs name loc [pp_expr ce]
| VernacDeclareImplicits _ as x -> xmlTODO loc x
| VernacArguments _ as x -> xmlTODO loc x
| VernacArgumentsScope _ as x -> xmlTODO loc x
| VernacReserve _ as x -> xmlTODO loc x
| VernacGeneralizable _ as x -> xmlTODO loc x
| VernacSetOpacity _ as x -> xmlTODO loc x
| VernacSetStrategy _ as x -> xmlTODO loc x
| VernacUnsetOption _ as x -> xmlTODO loc x
| VernacSetOption _ as x -> xmlTODO loc x
| VernacAddOption _ as x -> xmlTODO loc x
| VernacRemoveOption _ as x -> xmlTODO loc x
| VernacMemOption _ as x -> xmlTODO loc x
| VernacPrintOption _ as x -> xmlTODO loc x
| VernacCheckMayEval (_,_,e) -> xmlCheck loc [pp_expr e]
| VernacGlobalCheck _ as x -> xmlTODO loc x
| VernacDeclareReduction _ as x -> xmlTODO loc x
| VernacPrint _ as x -> xmlTODO loc x
| VernacSearch _ as x -> xmlTODO loc x
| VernacLocate _ as x -> xmlTODO loc x
| VernacRegister _ as x -> xmlTODO loc x
| VernacComments (cl) ->
xmlComment loc (List.flatten (List.map pp_comment cl))
| VernacNop as x -> xmlTODO loc x
(* Stm backdoor *)
| VernacStm _ as x -> xmlTODO loc x
(* Proof management *)
| VernacGoal _ as x -> xmlTODO loc x
| VernacAbort _ as x -> xmlTODO loc x
| VernacAbortAll -> PCData "VernacAbortAll"
| VernacRestart as x -> xmlTODO loc x
| VernacUndo _ as x -> xmlTODO loc x
| VernacUndoTo _ as x -> xmlTODO loc x
| VernacBacktrack _ as x -> xmlTODO loc x
| VernacFocus _ as x -> xmlTODO loc x
| VernacUnfocus as x -> xmlTODO loc x
| VernacUnfocused as x -> xmlTODO loc x
| VernacBullet _ as x -> xmlTODO loc x
| VernacSubproof _ as x -> xmlTODO loc x
| VernacEndSubproof as x -> xmlTODO loc x
| VernacShow _ as x -> xmlTODO loc x
| VernacCheckGuard as x -> xmlTODO loc x
| VernacProof (tac,using) ->
let tac = Option.map (xmlRawTactic "closingtactic") tac in
let using = Option.map (xmlSectionSubsetDescr "using") using in
xmlProof loc (Option.List.(cons tac (cons using [])))
| VernacProofMode name -> xmlProofMode loc name
(* Toplevel control *)
| VernacToplevelControl _ as x -> xmlTODO loc x
(* For extension *)
| VernacExtend _ as x ->
xmlExtend loc [PCData (Pp.string_of_ppcmds (Ppvernac.pr_vernac x))]
(* Flags *)
| VernacProgram e -> xmlApply loc (Element("program",[],[]) :: [tmpp e loc])
| VernacLocal (b,e) ->
xmlApply loc (Element("local",["flag",string_of_bool b],[]) ::
[tmpp e loc])
let tmpp v loc =
match tmpp v loc with
| Element("ltac",_,_) as x -> x
| xml -> xmlGallina loc [xml]
|