(* *)
(***************************************************************************)
+let p_mtr a b = Mpresentation.Mtr(a,b)
+let p_mtd a b = Mpresentation.Mtd(a,b)
+let p_mtable a b = Mpresentation.Mtable(a,b)
+let p_mtext a b = Mpresentation.Mtext(a,b)
+let p_mi a b = Mpresentation.Mi(a,b)
+let p_mo a b = Mpresentation.Mo(a,b)
+let p_mrow a b = Mpresentation.Mrow(a,b)
+let p_mphantom a b = Mpresentation.Mphantom(a,b)
+
+
let rec split n l =
if n = 0 then [],l
else let l1,l2 =
let is_big_general countterm p =
let maxsize = Cexpr2pres.maxsize in
- let module Con = Cic2content in
+ let module Con = Content in
let rec countp current_size p =
if current_size > maxsize then current_size
else
if current_size > maxsize then maxsize
else
(match e with
- Con.Declaration d ->
+ `Declaration d ->
(match d.Con.dec_name with
Some s -> current_size + 4 + (String.length s)
| None -> prerr_endline "NO NAME!!"; assert false)
- | Con.Hypothesis h ->
+ | `Hypothesis h ->
(match h.Con.dec_name with
Some s -> current_size + 4 + (String.length s)
| None -> prerr_endline "NO NAME!!"; assert false)
- | Con.Proof p -> countp current_size p
- | Con.Definition d ->
+ | `Proof p -> countp current_size p
+ | `Definition d ->
(match d.Con.def_name with
Some s ->
let c1 = (current_size + 4 + (String.length s)) in
(countterm c1 d.Con.def_term)
| None ->
prerr_endline "NO NAME!!"; assert false)
- | Con.Joint ho -> maxsize + 1) (* we assume is big *)
+ | `Joint ho -> maxsize + 1) (* we assume is big *)
and
countapplycontext current_size ac =
List.fold_left countp current_size ac
(match prem.Con.premise_binder with
Some s -> current_size + (String.length s)
| None -> current_size + 7)
+ | Con.Lemma lemma ->
+ current_size + (String.length lemma.Con.lemma_name)
| Con.Term t -> countterm current_size t
| Con.ArgProof p -> countp current_size p
| Con.ArgMethod s -> (maxsize + 1)) in
let is_big = is_big_general (Cexpr2pres.countterm)
;;
-let make_row items concl =
+let get_xref =
+ let module Con = Content in
+ function
+ `Declaration d
+ | `Hypothesis d -> d.Con.dec_id
+ | `Proof p -> p.Con.proof_id
+ | `Definition d -> d.Con.def_id
+ | `Joint jo -> jo.Con.joint_id
+;;
+
+let make_row ?(attrs=[]) items concl =
let module P = Mpresentation in
(match concl with
P.Mtable _ -> (* big! *)
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
+ P.Mtable (attrs@[None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
[P.Mtr([],[P.Mtd ([],P.Mrow([],items))]);
P.Mtr ([],[P.Mtd ([],P.indented concl)])])
| _ -> (* small *)
- P.Mrow([],items@[P.Mspace([("width","0.1cm")]);concl]))
+ P.Mrow(attrs,items@[P.Mspace([None,"width","0.1cm"]);concl]))
;;
-let make_concl verb concl =
+let make_concl ?(attrs=[]) verb concl =
let module P = Mpresentation in
(match concl with
P.Mtable _ -> (* big! *)
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr([],[P.Mtd ([],P.Mtext([("mathcolor","Red")],verb))]);
+ P.Mtable (attrs@[None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr([],[P.Mtd ([],P.Mtext([None,"mathcolor","Red"],verb))]);
P.Mtr ([],[P.Mtd ([],P.indented concl)])])
| _ -> (* small *)
- P.Mrow([],
- [P.Mtext([("mathcolor","Red")],verb);
- P.Mspace([("width","0.1cm")]);
+ P.Mrow(attrs,
+ [P.Mtext([None,"mathcolor","Red"],verb);
+ P.Mspace([None,"width","0.1cm"]);
concl]))
;;
let make_args_for_apply term2pres args =
- let module Con = Cic2content in
+ let module Con = Content in
let module P = Mpresentation in
- let rec make_arg_for_apply is_first arg row =
- (match arg with
+ let make_arg_for_apply is_first arg row =
+ let res =
+ match arg with
Con.Aux n -> assert false
| Con.Premise prem ->
let name =
None -> "previous"
| Some s -> s) in
P.Mi([],name)::row
+ | Con.Lemma lemma ->
+ P.Mi([],lemma.Con.lemma_name)::row
| Con.Term t ->
if is_first then
(term2pres t)::row
- else P.Mspace([("width","0.1cm")])::P.Mi([],"_")::row
+ else P.Mi([],"_")::row
| Con.ArgProof _
| Con.ArgMethod _ ->
- P.Mspace([("width","0.1cm")])::P.Mi([],"_")::row) in
- match args with
- hd::tl ->
- make_arg_for_apply true hd
- (List.fold_right (make_arg_for_apply false) tl [])
- | _ -> assert false;;
+ P.Mi([],"_")::row
+ in
+ if is_first then res else P.smallskip::res
+ in
+ match args with
+ hd::tl ->
+ make_arg_for_apply true hd
+ (List.fold_right (make_arg_for_apply false) tl [])
+ | _ -> assert false
+;;
let rec justification term2pres p =
- let module Con = Cic2content in
+ let module Con = Content in
let module P = Mpresentation in
if ((p.Con.proof_conclude.Con.conclude_method = "Exact") or
((p.Con.proof_context = []) &
let pres_args =
make_args_for_apply term2pres p.Con.proof_conclude.Con.conclude_args in
P.Mrow([],
- P.Mtext([("mathcolor","Red")],"by")::P.Mspace([("width","0.1cm")])::
+ P.Mtext([None,"mathcolor","Red"],"by")::P.Mspace([None,"width","0.1cm"])::
P.Mo([],"(")::pres_args@[P.Mo([],")")])
else proof2pres term2pres p
and proof2pres term2pres p =
let rec proof2pres p =
- let module Con = Cic2content in
+ let module Con = Content in
let module P = Mpresentation in
let indent =
let is_decl e =
(match e with
- Con.Declaration _
- | Con.Hypothesis _ -> true
+ `Declaration _
+ | `Hypothesis _ -> true
| _ -> false) in
((List.filter is_decl p.Con.proof_context) != []) in
+ let omit_conclusion = (not indent) && (p.Con.proof_context != []) in
let concl =
(match p.Con.proof_conclude.Con.conclude_conclusion with
None -> None
| Some t -> Some (term2pres t)) in
let body =
- let presconclude = conclude2pres p.Con.proof_conclude indent in
+ let presconclude =
+ conclude2pres p.Con.proof_conclude indent omit_conclusion in
let presacontext =
acontext2pres p.Con.proof_apply_context presconclude indent in
context2pres p.Con.proof_context presacontext in
-(*
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- (context2pres_old p.Con.proof_context)@
- (acontext2pres_old p.Con.proof_apply_context indent)@
- [conclude2pres_old p.Con.proof_conclude indent]) in *)
match p.Con.proof_name with
None -> body
| Some name ->
- let ac =
- (match concl with
- None -> P.Mtext([],"NO PROOF!!!")
- | Some c -> c) in
let action =
- P.Maction([("actiontype","toggle")],
- [(make_concl "proof of" ac);
- body]) in
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
+ match concl with
+ None -> body
+(*
+ P.Maction
+ ([None,"actiontype","toggle" ; None,"selection","1"],
+ [P.Mtext [] "proof" ; body])
+*)
+ | Some ac ->
+ P.Maction
+ ([None,"actiontype","toggle" ; None,"selection","1"],
+ [(make_concl ~attrs:[Some "helm", "xref", p.Con.proof_id]
+ "proof of" ac); body])
+ in
+ P.Mtable ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
[P.Mtr ([],[P.Mtd ([],P.Mfenced([],[P.Mtext ([],name)]))]);
P.Mtr ([],[P.Mtd ([], P.indented action)])])
+(*
+ P.Mtable ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left";Some "helm", "xref", p.Con.proof_id],
+ [P.Mtr ([],[P.Mtd ([],P.Mfenced([],[P.Mtext ([],name)]))]);
+ P.Mtr ([],[P.Mtd ([], P.indented action)])]) *)
and context2pres c continuation =
+ (* we generate a subtable for each context element, for selection
+ purposes
+ The table generated by the head-element does not have an xref;
+ the whole context-proof is already selectable *)
let module P = Mpresentation in
- List.fold_right
- (fun ce continuation ->
- P.Mtable([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr([],[P.Mtd ([],ce2pres ce)]);
- P.Mtr([],[P.Mtd ([], continuation)])])) c continuation
-
- and context2pres_old c =
- let module P = Mpresentation in
- List.map
- (function ce -> P.Mtr ([], [P.Mtd ([], ce2pres ce)])) c
-
+ match c with
+ [] -> continuation
+ | hd::tl ->
+ let continuation' =
+ List.fold_right
+ (fun ce continuation ->
+ let xref = get_xref ce in
+ P.Mtable([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"; Some "helm", "xref", xref ],
+ [P.Mtr([Some "helm", "xref", "ce_"^xref],[P.Mtd ([],ce2pres ce)]);
+ P.Mtr([],[P.Mtd ([], continuation)])])) tl continuation in
+ let hd_xref= get_xref hd in
+ P.Mtable([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr([Some "helm", "xref", "ce_"^hd_xref],
+ [P.Mtd ([],ce2pres hd)]);
+ P.Mtr([],[P.Mtd ([], continuation')])])
+
and ce2pres =
let module P = Mpresentation in
- let module Con = Cic2content in
+ let module Con = Content in
function
- Con.Declaration d ->
+ `Declaration d ->
(match d.Con.dec_name with
Some s ->
let ty = term2pres d.Con.dec_type in
P.Mrow ([],
- [P.Mtext([("mathcolor","Red")],"Assume");
- P.Mspace([("width","0.1cm")]);
+ [P.Mtext([None,"mathcolor","Red"],"Assume");
+ P.Mspace([None,"width","0.1cm"]);
P.Mi([],s);
P.Mtext([],":");
ty])
| None ->
prerr_endline "NO NAME!!"; assert false)
- | Con.Hypothesis h ->
+ | `Hypothesis h ->
(match h.Con.dec_name with
Some s ->
let ty = term2pres h.Con.dec_type in
P.Mrow ([],
- [P.Mtext([("mathcolor","Red")],"Suppose");
- P.Mspace([("width","0.1cm")]);
- P.Mtext([],"(");
+ [P.Mtext([None,"mathcolor","Red"],"Suppose");
+ P.Mspace([None,"width","0.1cm"]);
+ P.Mo([],"(");
P.Mi ([],s);
- P.Mtext([],")");
- P.Mspace([("width","0.1cm")]);
+ P.Mo([],")");
+ P.Mspace([None,"width","0.1cm"]);
ty])
| None ->
prerr_endline "NO NAME!!"; assert false)
- | Con.Proof p -> proof2pres p
- | Con.Definition d ->
+ | `Proof p ->
+ proof2pres p
+ | `Definition d ->
(match d.Con.def_name with
Some s ->
let term = term2pres d.Con.def_term in
term])
| None ->
prerr_endline "NO NAME!!"; assert false)
- | Con.Joint ho ->
+ | `Joint ho ->
P.Mtext ([],"jointdef")
and acontext2pres ac continuation indent =
+ let module Con = Content in
let module P = Mpresentation in
List.fold_right
(fun p continuation ->
P.indented (proof2pres p)
else
proof2pres p in
- P.Mtable([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr([],[P.Mtd ([],hd)]);
+ P.Mtable([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"; Some "helm","xref",p.Con.proof_id],
+ [P.Mtr([Some "helm","xref","ace_"^p.Con.proof_id],[P.Mtd ([],hd)]);
P.Mtr([],[P.Mtd ([], continuation)])])) ac continuation
- and acontext2pres_old ac indent =
+ and conclude2pres conclude indent omit_conclusion =
+ let module Con = Content in
let module P = Mpresentation in
- List.map
- (function p ->
- if indent then
- P.Mtr ([], [P.Mtd ([], P.indented (proof2pres p))])
- else
- P.Mtr ([],
- [P.Mtd ([], proof2pres p)])) ac
-
- and conclude2pres conclude indent =
- let module P = Mpresentation in
- if indent then
- P.indented (conclude_aux conclude)
+ let tconclude_body =
+ match conclude.Con.conclude_conclusion with
+ Some t when
+ not omit_conclusion or
+ (* CSC: I ignore the omit_conclusion flag in this case. *)
+ (* CSC: Is this the correct behaviour? In the stylesheets *)
+ (* CSC: we simply generated nothing (i.e. the output type *)
+ (* CSC: of the function should become an option. *)
+ conclude.Con.conclude_method = "BU_Conversion" ->
+ let concl = (term2pres t) in
+ if conclude.Con.conclude_method = "BU_Conversion" then
+ make_concl "that is equivalent to" concl
+ else if conclude.Con.conclude_method = "FalseInd" then
+ (* false ind is in charge to add the conclusion *)
+ falseind conclude
+ else
+ let conclude_body = conclude_aux conclude in
+ let ann_concl =
+ if conclude.Con.conclude_method = "TD_Conversion" then
+ make_concl "that is equivalent to" concl
+ else make_concl "we conclude" concl in
+ P.Mtable ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr ([],[P.Mtd ([],conclude_body)]);
+ P.Mtr ([],[P.Mtd ([],ann_concl)])])
+ | _ -> conclude_aux conclude in
+ if indent then
+ P.indented (P.Mrow ([Some "helm", "xref", conclude.Con.conclude_id],
+ [tconclude_body]))
else
- conclude_aux conclude
+ P.Mrow ([Some "helm", "xref", conclude.Con.conclude_id],[tconclude_body])
- and conclude2pres_old conclude indent =
- let module P = Mpresentation in
- if indent then
- P.Mtr ([], [P.Mtd ([], P.indented (conclude_aux conclude))])
- else
- P.Mtr ([],
- [P.Mtd ([], conclude_aux conclude)])
and conclude_aux conclude =
- let module Con = Cic2content in
+ let module Con = Content in
let module P = Mpresentation in
if conclude.Con.conclude_method = "TD_Conversion" then
let expected =
None -> P.Mtext([],"NO SYNTH!!!")
| Some c -> (term2pres c)) in
P.Mtable
- ([("align","baseline 1");("equalrows","false");("columnalign","left")],
+ ([None,"align","baseline 1"; None,"equalrows","false"; None,"columnalign","left"],
[P.Mtr([],[P.Mtd([],make_concl "we must prove" expected)]);
P.Mtr([],[P.Mtd([],make_concl "or equivalently" synth)]);
P.Mtr([],[P.Mtd([],proof2pres subproof)])])
else if conclude.Con.conclude_method = "BU_Conversion" then
- let conclusion =
- (match conclude.Con.conclude_conclusion with
- None -> P.Mtext([],"NO Conclusion!!!")
- | Some c -> term2pres c) in
- make_concl "that is equivalent to" conclusion
+ assert false
else if conclude.Con.conclude_method = "Exact" then
- let conclusion =
- (match conclude.Con.conclude_conclusion with
- None -> P.Mtext([],"NO Conclusion!!!")
- | Some c -> term2pres c) in
let arg =
(match conclude.Con.conclude_args with
[Con.Term t] -> term2pres t
| _ -> assert false) in
- make_row
- [arg;P.Mspace([("width","0.1cm")]);P.Mtext([],"proves")] conclusion
+ (match conclude.Con.conclude_conclusion with
+ None ->
+ p_mrow []
+ [p_mtext [None, "mathcolor", "red"] "Consider" ; P.smallskip; arg]
+ | Some c -> let conclusion = term2pres c in
+ make_row
+ [arg; P.Mspace([None,"width","0.1cm"]);P.Mtext([],"proves")]
+ conclusion
+ )
else if conclude.Con.conclude_method = "Intros+LetTac" then
+ (match conclude.Con.conclude_args with
+ [Con.ArgProof p] -> proof2pres p
+ | _ -> assert false)
+(* OLD CODE
let conclusion =
(match conclude.Con.conclude_conclusion with
None -> P.Mtext([],"NO Conclusion!!!")
(match conclude.Con.conclude_args with
[Con.ArgProof p] ->
P.Mtable
- ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
[P.Mtr([],[P.Mtd([],proof2pres p)]);
P.Mtr([],[P.Mtd([],
- (make_concl "we proved *" conclusion))])]);
+ (make_concl "we proved 1" conclusion))])]);
| _ -> assert false)
+*)
+ else if (conclude.Con.conclude_method = "Case") then
+ case conclude
else if (conclude.Con.conclude_method = "ByInduction") then
byinduction conclude
+ else if (conclude.Con.conclude_method = "Exists") then
+ exists conclude
+ else if (conclude.Con.conclude_method = "AndInd") then
+ andind conclude
+ else if (conclude.Con.conclude_method = "FalseInd") then
+ falseind conclude
else if (conclude.Con.conclude_method = "Rewrite") then
let justif =
(match (List.nth conclude.Con.conclude_args 6) with
let term2 =
(match List.nth conclude.Con.conclude_args 5 with
Con.Term t -> term2pres t
- | _ -> assert false) in
- let conclusion =
- (match conclude.Con.conclude_conclusion with
- None -> P.Mtext([],"NO Conclusion!!!")
- | Some c -> term2pres c) in
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr ([],[P.Mtd ([],P.Mrow([],[
- P.Mtext([("mathcolor","Red")],"rewrite");
- P.Mspace([("width","0.1cm")]);term1;
- P.Mspace([("width","0.1cm")]);
- P.Mtext([("mathcolor","Red")],"with");
- P.Mspace([("width","0.1cm")]);term2]))]);
- P.Mtr ([],[P.Mtd ([],P.indented justif)]);
- P.Mtr ([],[P.Mtd ([],make_concl "we proved" conclusion)])])
+ | _ -> assert false) in
+ P.Mtable ([None,"align","baseline 1";None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr ([],[P.Mtd ([],P.Mrow([],[
+ P.Mtext([None,"mathcolor","Red"],"rewrite");
+ P.Mspace([None,"width","0.1cm"]);term1;
+ P.Mspace([None,"width","0.1cm"]);
+ P.Mtext([None,"mathcolor","Red"],"with");
+ P.Mspace([None,"width","0.1cm"]);term2]))]);
+ P.Mtr ([],[P.Mtd ([],P.indented justif)])]);
else if conclude.Con.conclude_method = "Apply" then
let pres_args =
- make_args_for_apply term2pres conclude.Con.conclude_args in
- let by =
- P.Mrow([],
- P.Mtext([("mathcolor","Red")],"by")::P.Mspace([("width","0.1cm")])::
- P.Mo([],"(")::pres_args@[P.Mo([],")")]) in
- match conclude.Con.conclude_conclusion with
- None -> P.Mrow([],[P.Mtext([],"QUA");by])
- | Some t ->
- let concl = (term2pres t) in
- let ann_concl = make_concl "we proved" concl in
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr ([],[P.Mtd ([],by)]);
- P.Mtr ([],[P.Mtd ([],ann_concl)])])
- else let body =
+ make_args_for_apply term2pres conclude.Con.conclude_args in
+ P.Mrow([],
+ P.Mtext([None,"mathcolor","Red"],"by")::
+ P.Mspace([None,"width","0.1cm"])::
+ P.Mo([],"(")::pres_args@[P.Mo([],")")])
+ else
P.Mtable
- ([("align","baseline 1");("equalrows","false");("columnalign","left")],
+ ([None,"align","baseline 1"; None,"equalrows","false"; None,"columnalign","left"],
[P.Mtr ([],[P.Mtd ([],P.Mtext([],"Apply method" ^ conclude.Con.conclude_method ^ " to"))]);
P.Mtr ([],
[P.Mtd ([],
(P.indented
(P.Mtable
- ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- args2pres conclude.Con.conclude_args))))])]) in
- match conclude.Con.conclude_conclusion with
- None -> body
- | Some t ->
- let concl = (term2pres t) in
- let ann_concl = make_concl "we proved" concl in
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
- [P.Mtr ([],[P.Mtd ([],body)]);
- P.Mtr ([],[P.Mtd ([],ann_concl)])])
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ args2pres conclude.Con.conclude_args))))])])
and args2pres l =
let module P = Mpresentation in
and arg2pres =
let module P = Mpresentation in
- let module Con = Cic2content in
+ let module Con = Content in
function
Con.Aux n ->
- P.Mtext ([],"aux " ^ string_of_int n)
+ P.Mtext ([],"aux " ^ n)
| Con.Premise prem ->
P.Mtext ([],"premise")
+ | Con.Lemma lemma ->
+ P.Mtext ([],"lemma")
| Con.Term t ->
term2pres t
| Con.ArgProof p ->
| Con.ArgMethod s ->
P.Mtext ([],"method")
+ and case conclude =
+ let module P = Mpresentation in
+ let module Con = Content in
+ let proof_conclusion =
+ (match conclude.Con.conclude_conclusion with
+ None -> P.Mtext([],"No conclusion???")
+ | Some t -> term2pres t) in
+ let arg,args_for_cases =
+ (match conclude.Con.conclude_args with
+ Con.Aux(_)::Con.Aux(_)::Con.Term(_)::arg::tl ->
+ arg,tl
+ | _ -> assert false) in
+ let case_on =
+ let case_arg =
+ (match arg with
+ Con.Aux n ->
+ P.Mtext ([],"an aux???")
+ | Con.Premise prem ->
+ (match prem.Con.premise_binder with
+ None -> P.Mtext ([],"the previous result")
+ | Some n -> P.Mi([],n))
+ | Con.Lemma lemma -> P.Mi([],lemma.Con.lemma_name)
+ | Con.Term t ->
+ term2pres t
+ | Con.ArgProof p ->
+ P.Mtext ([],"a proof???")
+ | Con.ArgMethod s ->
+ P.Mtext ([],"a method???")) in
+ (make_concl "we proceede by cases on" case_arg) in
+ let to_prove =
+ (make_concl "to prove" proof_conclusion) in
+ P.Mtable
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ P.Mtr ([],[P.Mtd ([],case_on)])::
+ P.Mtr ([],[P.Mtd ([],to_prove)])::
+ (make_cases args_for_cases))
+
and byinduction conclude =
let module P = Mpresentation in
- let module Con = Cic2content in
+ let module Con = Content in
let proof_conclusion =
(match conclude.Con.conclude_conclusion with
None -> P.Mtext([],"No conclusion???")
let inductive_arg,args_for_cases =
(match conclude.Con.conclude_args with
Con.Aux(n)::_::tl ->
- let l1,l2 = split n tl in
+ let l1,l2 = split (int_of_string n) tl in
let last_pos = (List.length l2)-1 in
List.nth l2 last_pos,l1
| _ -> assert false) in
(match prem.Con.premise_binder with
None -> P.Mtext ([],"the previous result")
| Some n -> P.Mi([],n))
+ | Con.Lemma lemma -> P.Mi([],lemma.Con.lemma_name)
| Con.Term t ->
term2pres t
| Con.ArgProof p ->
(make_concl "we proceede by induction on" arg) in
let to_prove =
(make_concl "to prove" proof_conclusion) in
- let we_proved =
- (make_concl "we proved" proof_conclusion) in
P.Mtable
- ([("align","baseline 1");("equalrows","false");("columnalign","left")],
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
P.Mtr ([],[P.Mtd ([],induction_on)])::
P.Mtr ([],[P.Mtd ([],to_prove)])::
- (make_cases args_for_cases) @
- [P.Mtr ([],[P.Mtd ([],we_proved)])])
-
+ (make_cases args_for_cases))
+
and make_cases args_for_cases =
let module P = Mpresentation in
List.map
and make_case =
let module P = Mpresentation in
- let module Con = Cic2content in
+ let module Con = Content in
function
Con.ArgProof p ->
let name =
let indhyps,args =
List.partition
(function
- Con.Hypothesis h -> h.Con.dec_inductive
+ `Hypothesis h -> h.Con.dec_inductive
| _ -> false) p.Con.proof_context in
let pattern_aux =
List.fold_right
(fun e p ->
let dec =
(match e with
- Con.Declaration h
- | Con.Hypothesis h ->
+ `Declaration h
+ | `Hypothesis h ->
let name =
(match h.Con.dec_name with
None -> "NO NAME???"
| Some n ->n) in
- [P.Mspace([("width","0.1cm")]);
+ [P.Mspace([None,"width","0.1cm"]);
P.Mi ([],name);
P.Mtext([],":");
(term2pres h.Con.dec_type)]
dec@p) args [] in
let pattern =
P.Mtr ([],[P.Mtd ([],P.Mrow([],
- P.Mtext([],"Case")::P.Mspace([("width","0.1cm")])::name::pattern_aux@
- [P.Mspace([("width","0.1cm")]);
+ P.Mtext([],"Case")::P.Mspace([None,"width","0.1cm"])::name::pattern_aux@
+ [P.Mspace([None,"width","0.1cm"]);
P.Mtext([],"->")]))]) in
let subconcl =
(match p.Con.proof_conclude.Con.conclude_conclusion with
| Some t -> term2pres t) in
let asubconcl =
P.Mtr([],[P.Mtd([],
- make_concl "the thesis becomes" subconcl)]) in
+ P.indented (make_concl "the thesis becomes" subconcl))]) in
let induction_hypothesis =
(match indhyps with
[] -> []
(P.Mtext([],"by induction hypothesis we know:")))]) in
let make_hyp =
function
- Con.Hypothesis h ->
+ `Hypothesis h ->
let name =
(match h.Con.dec_name with
None -> "no name"
| Some s -> s) in
P.indented (P.Mrow ([],
- [P.Mtext([],"(");
+ [P.Mo([],"(");
P.Mi ([],name);
- P.Mtext([],")");
- P.Mspace([("width","0.1cm")]);
+ P.Mo([],")");
+ P.Mspace([None,"width","0.1cm"]);
term2pres h.Con.dec_type]))
| _ -> assert false in
let hyps =
text::hyps) in
(* let acontext =
acontext2pres_old p.Con.proof_apply_context true in *)
- let body = conclude2pres p.Con.proof_conclude true in
+ let body = conclude2pres p.Con.proof_conclude true false in
let presacontext =
- acontext2pres p.Con.proof_apply_context body true in
- P.Mtable ([("align","baseline 1");("equalrows","false");
- ("columnalign","left")],
+ let acontext_id =
+ match p.Con.proof_apply_context with
+ [] -> p.Con.proof_conclude.Con.conclude_id
+ | {Con.proof_id = id}::_ -> id
+ in
+ P.Maction([None,"actiontype","toggle" ; None,"selection","1"],
+ [P.indented
+ (P.Mtext
+ ([None,"mathcolor","Red" ;
+ Some "helm", "xref", acontext_id],"Proof")) ;
+ acontext2pres p.Con.proof_apply_context body true]) in
+ P.Mtable ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
pattern::asubconcl::induction_hypothesis@
[P.Mtr([],[P.Mtd([],presacontext)])])
- | _ -> assert false in
+ | _ -> assert false
+
+ and falseind conclude =
+ let module P = Mpresentation in
+ let module Con = Content in
+ let proof_conclusion =
+ (match conclude.Con.conclude_conclusion with
+ None -> P.Mtext([],"No conclusion???")
+ | Some t -> term2pres t) in
+ let case_arg =
+ (match conclude.Con.conclude_args with
+ [Con.Aux(n);_;case_arg] -> case_arg
+ | _ -> assert false;
+ (*
+ List.map (ContentPp.parg 0) conclude.Con.conclude_args;
+ assert false *)) in
+ let arg =
+ (match case_arg with
+ Con.Aux n -> assert false
+ | Con.Premise prem ->
+ (match prem.Con.premise_binder with
+ None -> [P.Mtext([],"Contradiction, hence")]
+ | Some n ->
+ [P.Mi([],n);P.smallskip;P.Mtext([],"is contradictory, hence")])
+ | Con.Lemma lemma ->
+ [P.Mi([],lemma.Con.lemma_name);P.smallskip;P.Mtext([],"is contradictory, hence")]
+ | _ -> assert false) in
+ (* let body = proof2pres {proof with Con.proof_context = tl} in *)
+ make_row arg proof_conclusion
+
+ and andind conclude =
+ let module P = Mpresentation in
+ let module Con = Content in
+ let proof_conclusion =
+ (match conclude.Con.conclude_conclusion with
+ None -> P.Mtext([],"No conclusion???")
+ | Some t -> term2pres t) in
+ let proof,case_arg =
+ (match conclude.Con.conclude_args with
+ [Con.Aux(n);_;Con.ArgProof proof;case_arg] -> proof,case_arg
+ | _ -> assert false;
+ (*
+ List.map (ContentPp.parg 0) conclude.Con.conclude_args;
+ assert false *)) in
+ let arg =
+ (match case_arg with
+ Con.Aux n -> assert false
+ | Con.Premise prem ->
+ (match prem.Con.premise_binder with
+ None -> []
+ | Some n -> [P.Mtext([],"by");P.smallskip;P.Mi([],n)])
+ | Con.Lemma lemma ->
+ [P.Mtext([],"by");P.smallskip;P.Mi([],lemma.Con.lemma_name)]
+ | _ -> assert false) in
+ match proof.Con.proof_context with
+ `Hypothesis hyp1::`Hypothesis hyp2::tl ->
+ let get_name hyp =
+ (match hyp.Con.dec_name with
+ None -> "_"
+ | Some s -> s) in
+ let preshyp1 =
+ P.Mrow ([],
+ [P.Mtext([],"(");
+ P.Mi([],get_name hyp1);
+ P.Mtext([],")");
+ P.smallskip;
+ term2pres hyp1.Con.dec_type]) in
+ let preshyp2 =
+ P.Mrow ([],
+ [P.Mtext([],"(");
+ P.Mi([],get_name hyp2);
+ P.Mtext([],")");
+ P.smallskip;
+ term2pres hyp2.Con.dec_type]) in
+ (* let body = proof2pres {proof with Con.proof_context = tl} in *)
+ let body = conclude2pres proof.Con.proof_conclude false true in
+ let presacontext =
+ acontext2pres proof.Con.proof_apply_context body false in
+ P.Mtable
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr ([],[P.Mtd ([],
+ P.Mrow([],arg@[P.smallskip;P.Mtext([],"we have")]))]);
+ P.Mtr ([],[P.Mtd ([],preshyp1)]);
+ P.Mtr ([],[P.Mtd ([],P.Mtext([],"and"))]);
+ P.Mtr ([],[P.Mtd ([],preshyp2)]);
+ P.Mtr ([],[P.Mtd ([],presacontext)])]);
+ | _ -> assert false
+
+ and exists conclude =
+ let module P = Mpresentation in
+ let module Con = Content in
+ let proof_conclusion =
+ (match conclude.Con.conclude_conclusion with
+ None -> P.Mtext([],"No conclusion???")
+ | Some t -> term2pres t) in
+ let proof =
+ (match conclude.Con.conclude_args with
+ [Con.Aux(n);_;Con.ArgProof proof;_] -> proof
+ | _ -> assert false;
+ (*
+ List.map (ContentPp.parg 0) conclude.Con.conclude_args;
+ assert false *)) in
+ match proof.Con.proof_context with
+ `Declaration decl::`Hypothesis hyp::tl
+ | `Hypothesis decl::`Hypothesis hyp::tl ->
+ let get_name decl =
+ (match decl.Con.dec_name with
+ None -> "_"
+ | Some s -> s) in
+ let presdecl =
+ P.Mrow ([],
+ [P.Mtext([None,"mathcolor","Red"],"let");
+ P.smallskip;
+ P.Mi([],get_name decl);
+ P.Mtext([],":"); term2pres decl.Con.dec_type]) in
+ let suchthat =
+ P.Mrow ([],
+ [P.Mtext([None,"mathcolor","Red"],"such that");
+ P.smallskip;
+ P.Mtext([],"(");
+ P.Mi([],get_name hyp);
+ P.Mtext([],")");
+ P.smallskip;
+ term2pres hyp.Con.dec_type]) in
+ (* let body = proof2pres {proof with Con.proof_context = tl} in *)
+ let body = conclude2pres proof.Con.proof_conclude false true in
+ let presacontext =
+ acontext2pres proof.Con.proof_apply_context body false in
+ P.Mtable
+ ([None,"align","baseline 1"; None,"equalrows","false";
+ None,"columnalign","left"],
+ [P.Mtr ([],[P.Mtd ([],presdecl)]);
+ P.Mtr ([],[P.Mtd ([],suchthat)]);
+ P.Mtr ([],[P.Mtd ([],presacontext)])]);
+ | _ -> assert false in
proof2pres p
;;
-(*
-let content2pres =
- proof2pres
- (function p -> Cexpr2pres.cexpr2pres_charcount (Content_expressions.acic2cexpr p))
-;; *)
+exception ToDo;;
+let content2pres term2pres (id,params,metasenv,obj) =
+ let module K = Content in
+ let module P = Mpresentation in
+ match obj with
+ `Def (K.Const,thesis,`Proof p) ->
+ p_mtable
+ [None,"align","baseline 1";
+ None,"equalrows","false";
+ None,"columnalign","left";
+ None,"helm:xref","id"]
+ ([p_mtr []
+ [p_mtd []
+ (p_mrow []
+ [p_mtext []
+ ("UNFINISHED PROOF" ^ id ^"(" ^
+ String.concat " ; " (List.map UriManager.string_of_uri params)^
+ ")")])] ;
+ p_mtr []
+ [p_mtd []
+ (p_mrow []
+ [p_mtext [] "THESIS:"])] ;
+ p_mtr []
+ [p_mtd []
+ (p_mrow []
+ [p_mphantom []
+ (p_mtext [] "__") ;
+ term2pres thesis])]] @
+ (match metasenv with
+ None -> []
+ | Some metasenv' ->
+ [p_mtr []
+ [p_mtd []
+ (* Conjectures are in their own table to make *)
+ (* diffing the DOM trees easier. *)
+ (p_mtable
+ [None,"align","baseline 1";
+ None,"equalrows","false";
+ None,"columnalign","left"]
+ ((p_mtr []
+ [p_mtd []
+ (p_mrow []
+ [p_mtext [] "CONJECTURES:"])])::
+ List.map
+ (function
+ (id,n,context,ty) ->
+ p_mtr []
+ [p_mtd []
+ (p_mrow [Some "helm", "xref", id]
+ (List.map
+ (function
+ None ->
+ p_mrow []
+ [ p_mi [] "_" ;
+ p_mo [] ":?" ;
+ p_mi [] "_"]
+ | Some (`Declaration d)
+ | Some (`Hypothesis d) ->
+ let
+ { K.dec_name = dec_name ;
+ K.dec_type = ty } = d
+ in
+ p_mrow []
+ [ p_mi []
+ (match dec_name with
+ None -> "_"
+ | Some n -> n) ;
+ p_mo [] ":" ;
+ term2pres ty]
+ | Some (`Definition d) ->
+ let
+ { K.def_name = def_name ;
+ K.def_term = bo } = d
+ in
+ p_mrow []
+ [ p_mi []
+ (match def_name with
+ None -> "_"
+ | Some n -> n) ;
+ p_mo [] ":=" ;
+ term2pres bo]
+ | Some (`Proof p) ->
+ let proof_name = p.K.proof_name in
+ p_mrow []
+ [ p_mi []
+ (match proof_name with
+ None -> "_"
+ | Some n -> n) ;
+ p_mo [] ":=" ;
+ proof2pres term2pres p]
+ ) (List.rev context) @
+ [ p_mo [] "|-" ] @
+ [ p_mi [] (string_of_int n) ;
+ p_mo [] ":" ;
+ term2pres ty ]
+ ))
+ ]
+ ) metasenv'
+ ))]]
+ ) @
+ [p_mtr []
+ [p_mtd []
+ (p_mrow []
+ [proof2pres term2pres p])]])
+ | _ -> raise ToDo
+;;
+let content2pres ~ids_to_inner_sorts =
+ content2pres
+ (function p ->
+ (Cexpr2pres.cexpr2pres_charcount
+ (Content_expressions.acic2cexpr ids_to_inner_sorts p)))
+;;