Some "xlink", "href", lemma.Con.lemma_uri ]
in
(B.b_object (P.Mi(lemma_attrs,lemma.Con.lemma_name)))::row
- | Con.Term t ->
- if is_first then
+ | Con.Term (b,t) ->
+ if is_first || (not b) then
(term2pres t)::row
else (B.b_object (P.Mi([],"?")))::row
| Con.ArgProof _
(List.fold_right (make_arg_for_apply false) tl [])
| _ -> assert false
-let get_name = function
+let get_name ?(default="_") = function
| Some s -> s
- | None -> "_"
+ | None -> default
let add_xref id = function
| B.Text (attrs, t) -> B.Text (((Some "helm", "xref", id) :: attrs), t)
| _ -> assert false (* TODO, add_xref is meaningful for all boxes *)
-let rec justification term2pres p =
- if ((p.Con.proof_conclude.Con.conclude_method = "Exact") or
- ((p.Con.proof_context = []) &
- (p.Con.proof_apply_context = []) &
- (p.Con.proof_conclude.Con.conclude_method = "Apply"))) then
+let rec justification ~for_rewriting_step ~ignore_atoms term2pres p =
+ if p.Con.proof_conclude.Con.conclude_method = "Exact" &&
+ ignore_atoms
+ then
+ [], None
+ else if
+ (p.Con.proof_conclude.Con.conclude_method = "Exact" && not ignore_atoms) ||
+ (p.Con.proof_context = [] &&
+ p.Con.proof_apply_context = [] &&
+ p.Con.proof_conclude.Con.conclude_method = "Apply")
+ then
let pres_args =
- make_args_for_apply term2pres p.Con.proof_conclude.Con.conclude_args in
- B.H([],
- (B.b_kw "by")::B.b_space::
- B.Text([],"(")::pres_args@[B.Text([],")")]), None
- else (B.b_kw "by"),
- Some (B.b_toggle [B.b_kw "proof";proof2pres true term2pres p])
+ make_args_for_apply term2pres p.Con.proof_conclude.Con.conclude_args
+ in
+ [B.H([],
+ (if for_rewriting_step then (B.b_kw "exact") else (B.b_kw "by"))::
+ B.b_space::
+ B.Text([],"(")::pres_args@[B.Text([],")")])], None
+ else
+ [B.H([],
+ if for_rewriting_step then
+ [B.b_kw "proof"]
+ else
+ [B.b_kw "by"; B.b_space; B.b_kw "proof"]
+ )],
+ Some (B.b_toggle [B.b_kw "proof";B.indent (proof2pres true term2pres p)])
and proof2pres ?skip_initial_lambdas is_top_down term2pres p =
- let rec proof2pres ?(skip_initial_lambdas_internal=false) is_top_down p omit_dot =
- prerr_endline p.Con.proof_conclude.Con.conclude_method;
+ let rec proof2pres ?skip_initial_lambdas_internal is_top_down p in_bu_conversion =
let indent =
let is_decl e =
(match e with
| Some t -> Some (term2pres t)) in
let body =
let presconclude =
- conclude2pres ~skip_initial_lambdas_internal is_top_down p.Con.proof_conclude indent omit_conclusion
- omit_dot in
+ conclude2pres
+ ?skip_initial_lambdas_internal:
+ (match skip_initial_lambdas_internal with
+ Some (`Later s) -> Some (`Now s)
+ | _ -> None)
+ is_top_down p.Con.proof_name p.Con.proof_conclude indent
+ omit_conclusion in_bu_conversion in
let presacontext =
acontext2pres
- (p.Con.proof_conclude.Con.conclude_method = "BU_Conversion")
- p.Con.proof_apply_context
- presconclude indent
+ (if p.Con.proof_conclude.Con.conclude_method = "BU_Conversion" then
+ is_top_down
+ else
+ false)
+ p.Con.proof_apply_context
+ presconclude indent
(p.Con.proof_conclude.Con.conclude_method = "BU_Conversion")
in
context2pres
- (if skip_initial_lambdas_internal then [] else p.Con.proof_context)
+ (match skip_initial_lambdas_internal with
+ Some (`Now n) -> snd (HExtlib.split_nth "CP 1" n p.Con.proof_context)
+ | _ -> p.Con.proof_context)
presacontext
in
+(*
+let body = B.V([],[B.b_kw ("(*<<" ^ p.Con.proof_conclude.Con.conclude_method ^ (if is_top_down then "(TD)" else "(NTD)") ^ "*)"); body; B.b_kw "(*>>*)"]) in
+*)
match p.Con.proof_name with
None -> body
| Some name ->
let concl =
make_concl ~attrs:[ Some "helm", "xref", p.Con.proof_id ]
"proof of" ac in
- B.b_toggle [ concl; body ]
+ B.b_toggle [ B.H ([], [concl; B.skip ; B.Text([],"(");
+ B.Object ([], P.Mi ([],name));
+ B.Text([],")") ]) ; body ]
in
B.indent action
term])
and acontext2pres is_top_down ac continuation indent in_bu_conversion =
- List.fold_right
- (fun p continuation ->
- let hd =
- if indent then
- B.indent (proof2pres is_top_down p in_bu_conversion)
- else
- proof2pres is_top_down p in_bu_conversion
+ let rec aux =
+ function
+ [] -> continuation
+ | p::tl ->
+ let continuation = aux tl in
+ (* Applicative context get flattened and the "body" of a BU_Conversion
+ is put in the applicative context. Thus two different situations
+ are possible:
+ {method = "BU_Conversion"; applicative_context=[p1; ...; pn]}
+ {method = xxx; applicative_context =
+ [ p1; ...; pn; {method="BU_Conversion"} ; p_{n+1}; ... ; pm ]}
+ In both situations only pn must be processed in in_bu_conversion
+ mode
+ *)
+ let in_bu_conversion =
+ match tl with
+ [] -> in_bu_conversion
+ | p::_ -> p.Con.proof_conclude.Con.conclude_method = "BU_Conversion"
in
+ let hd = proof2pres is_top_down p in_bu_conversion in
+ let hd = if indent then B.indent hd else hd in
B.V([Some "helm","xref",p.Con.proof_id],
- [B.H([Some "helm","xref","ace_"^p.Con.proof_id],[hd]);
- continuation])) ac continuation
+ [B.H([Some "helm","xref","ace_"^p.Con.proof_id],[hd]);
+ continuation])
+ in aux ac
- and conclude2pres ?skip_initial_lambdas_internal is_top_down conclude indent omit_conclusion omit_dot =
+ and conclude2pres ?skip_initial_lambdas_internal is_top_down name conclude indent omit_conclusion in_bu_conversion =
let tconclude_body =
match conclude.Con.conclude_conclusion with
Some t (*when not omit_conclusion or
if conclude.Con.conclude_method = "BU_Conversion" then
B.b_hv []
(make_concl "that is equivalent to" concl ::
- if is_top_down then [B.b_space ; B.Text([],"done.")] else [])
+ if is_top_down then [B.b_space ; B.b_kw "done";
+ B.Text([],".")] else [B.Text([],".")])
else if conclude.Con.conclude_method = "FalseInd" then
(* false ind is in charge to add the conclusion *)
falseind conclude
else
+ let prequel =
+ if
+ (not is_top_down) &&
+ conclude.Con.conclude_method = "Intros+LetTac"
+ then
+ let name = get_name name in
+ [B.V ([],
+ [ B.H([],
+ let expected =
+ (match conclude.Con.conclude_conclusion with
+ None -> B.Text([],"NO EXPECTED!!!")
+ | Some c -> term2pres c)
+ in
+ [make_concl "we need to prove" expected;
+ B.skip;
+ B.Text([],"(");
+ B.Object ([], P.Mi ([],name));
+ B.Text([],")");
+ B.Text ([],".")
+ ])])]
+ else
+ [] in
let conclude_body =
- conclude_aux ?skip_initial_lambdas_internal conclude in
+ conclude_aux ?skip_initial_lambdas_internal is_top_down conclude in
let ann_concl =
if conclude.Con.conclude_method = "Intros+LetTac"
|| conclude.Con.conclude_method = "ByInduction"
|| conclude.Con.conclude_method = "TD_Conversion"
+ || conclude.Con.conclude_method = "Eq_chain"
then
B.Text([],"")
- else if omit_conclusion then B.Text([],"done.")
- else B.b_hv []
- ((if not is_top_down || omit_dot then [make_concl "we proved" concl; B.Text([],if not is_top_down then "(previous)" else "")] else [B.Text([],"done")]) @ if not omit_dot then [B.Text([],".")] else [])
+ else if omit_conclusion then
+ B.H([], [B.b_kw "done" ; B.Text([],".") ])
+ else
+ B.b_hv []
+ ((if not is_top_down || in_bu_conversion then
+ (make_concl "we proved" concl) ::
+ if not is_top_down then
+ let name = get_name ~default:"previous" name in
+ [B.b_space; B.Text([],"(" ^ name ^ ")")]
+ else []
+ else [B.b_kw "done"]
+ ) @ if not in_bu_conversion then [B.Text([],".")] else [])
in
- B.V ([], [conclude_body; ann_concl])
- | _ -> conclude_aux ?skip_initial_lambdas_internal conclude
+ B.V ([], prequel @ [conclude_body; ann_concl])
+ | _ -> conclude_aux ?skip_initial_lambdas_internal is_top_down conclude
in
if indent then
B.indent (B.H ([Some "helm", "xref", conclude.Con.conclude_id],
else
B.H ([Some "helm", "xref", conclude.Con.conclude_id],[tconclude_body])
- and conclude_aux ?skip_initial_lambdas_internal conclude =
+ and conclude_aux ?skip_initial_lambdas_internal is_top_down conclude =
if conclude.Con.conclude_method = "TD_Conversion" then
let expected =
(match conclude.Con.conclude_conclusion with
B.V
([],
[make_concl "we need to prove" expected;
- make_concl "or equivalently" synth;
- B.Text([],".");
+ B.H ([],[make_concl "or equivalently" synth; B.Text([],".")]);
proof2pres true subproof false])
else if conclude.Con.conclude_method = "BU_Conversion" then
assert false
else if conclude.Con.conclude_method = "Exact" then
let arg =
(match conclude.Con.conclude_args with
- [Con.Term t] -> term2pres t
+ [Con.Term (b,t)] -> assert (not b);term2pres t
| [Con.Premise p] ->
(match p.Con.premise_binder with
| None -> assert false; (* unnamed hypothesis ??? *)
(match conclude.Con.conclude_conclusion with
None ->
B.b_h [] [B.b_kw "by"; B.b_space; arg]
- | Some c -> let conclusion = term2pres c in
+ | Some c ->
B.b_h [] [B.b_kw "by"; B.b_space; arg]
)
else if conclude.Con.conclude_method = "Intros+LetTac" then
(match conclude.Con.conclude_args with
- [Con.ArgProof p] -> proof2pres ?skip_initial_lambdas_internal true p false
+ [Con.ArgProof p] ->
+ (match conclude.Con.conclude_args with
+ [Con.ArgProof p] ->
+ proof2pres ?skip_initial_lambdas_internal true p false
+ | _ -> assert false)
| _ -> assert false)
(* OLD CODE
let conclusion =
andind conclude
else if (conclude.Con.conclude_method = "FalseInd") then
falseind conclude
- else if (conclude.Con.conclude_method = "Rewrite") then
+ else if conclude.Con.conclude_method = "RewriteLR"
+ || conclude.Con.conclude_method = "RewriteRL" then
let justif1,justif2 =
(match (List.nth conclude.Con.conclude_args 6) with
- Con.ArgProof p -> justification term2pres p
+ Con.ArgProof p ->
+ justification ~for_rewriting_step:true ~ignore_atoms:true
+ term2pres p
| _ -> assert false) in
+ let justif =
+ match justif2 with
+ None -> justif1
+ | Some j -> [j]
+ in
+ let index_term1, index_term2 =
+ if conclude.Con.conclude_method = "RewriteLR" then 2,5 else 5,2
+ in
let term1 =
- (match List.nth conclude.Con.conclude_args 2 with
- Con.Term t -> term2pres t
+ (match List.nth conclude.Con.conclude_args index_term1 with
+ Con.Term (_,t) -> term2pres t
| _ -> assert false) in
let term2 =
- (match List.nth conclude.Con.conclude_args 5 with
- Con.Term t -> term2pres t
+ (match List.nth conclude.Con.conclude_args index_term2 with
+ Con.Term (_,t) -> term2pres t
| _ -> assert false) in
+ let justif =
+ match justif with
+ [] -> []
+ | _ ->
+ justif @
+ [B.V([],
+ [B.b_kw "we proved (" ;
+ term1 ;
+ B.b_kw "=" ;
+ term2; B.b_kw ") (equality)."])]
+ in
(*
B.V ([],
B.H ([],[
B.b_space; term2;
B.b_space; justif1])::
match justif2 with None -> [] | Some j -> [B.indent j])
-*) B.V([], [justif1 ; B.H([],[B.b_kw "we proved (" ; term2 ; B.b_kw "=" ; term1; B.b_kw ") (previous)."]); B.b_kw "by _"])
+*)
+ B.V([], justif @ [B.b_kw "by _"])
else if conclude.Con.conclude_method = "Eq_chain" then
let justification p =
- if skip_initial_lambdas <> None (* cheating *) then
- [B.b_kw "by _"]
- else
- let j1,j2 = justification term2pres p in
- j1 :: B.b_space :: (match j2 with Some j -> [j] | None -> [])
+ let j1,j2 =
+ justification ~for_rewriting_step:true ~ignore_atoms:false term2pres p
+ in
+ j1, match j2 with Some j -> [j] | None -> []
in
let rec aux args =
match args with
| [] -> []
- | (Con.ArgProof p)::(Con.Term t)::tl ->
- B.HOV(RenderingAttrs.indent_attributes `BoxML,([B.b_kw
- "=";B.b_space;term2pres t;B.b_space]@justification p@
- (if tl <> [] then [B.Text ([],".")] else [])))::(aux tl)
+ | (Con.ArgProof p)::(Con.Term (_,t))::tl ->
+ let justif1,justif2 = justification p in
+ B.HOV(RenderingAttrs.indent_attributes `BoxML,([B.b_kw
+ "=";B.b_space;term2pres t;B.b_space]@justif1@
+ (if tl <> [] then [B.Text ([],".")] else [B.b_space; B.b_kw "done" ; B.Text([],".")])@
+ justif2))::(aux tl)
| _ -> assert false
in
let hd =
match List.hd conclude.Con.conclude_args with
- | Con.Term t -> t
+ | Con.Term (_,t) -> t
| _ -> assert false
in
- B.HOV([],[B.Text ([],"conclude");B.b_space;term2pres hd; (* B.b_space; *)
- B.V ([],aux (List.tl conclude.Con.conclude_args))])
+ if is_top_down then
+ B.HOV([],
+ [B.b_kw "conclude";B.b_space;term2pres hd;
+ B.V ([],aux (List.tl conclude.Con.conclude_args))])
+ else
+ B.HOV([],
+ [B.b_kw "obtain";B.b_space;B.b_kw "FIXMEXX"; B.b_space;term2pres hd;
+ B.V ([],aux (List.tl conclude.Con.conclude_args))])
else if conclude.Con.conclude_method = "Apply" then
let pres_args =
make_args_for_apply term2pres conclude.Con.conclude_args in
Con.Aux n -> B.b_kw ("aux " ^ n)
| Con.Premise prem -> B.b_kw "premise"
| Con.Lemma lemma -> B.b_kw "lemma"
- | Con.Term t -> term2pres t
+ | Con.Term (_,t) -> term2pres t
| Con.ArgProof p -> proof2pres true p false
| Con.ArgMethod s -> B.b_kw "method"
Con.Aux n -> B.b_kw "an aux???"
| Con.Premise prem ->
(match prem.Con.premise_binder with
- None -> B.b_kw "the previous result"
+ None -> B.b_kw "previous"
| Some n -> B.Object ([], P.Mi([],n)))
| Con.Lemma lemma -> B.Object ([], P.Mi([],lemma.Con.lemma_name))
- | Con.Term t ->
+ | Con.Term (_,t) ->
term2pres t
| Con.ArgProof p -> B.b_kw "a proof???"
| Con.ArgMethod s -> B.b_kw "a method???")
Con.Aux n -> B.b_kw "an aux???"
| Con.Premise prem ->
(match prem.Con.premise_binder with
- None -> B.b_kw "the previous result"
+ None -> B.b_kw "previous"
| Some n -> B.Object ([], P.Mi([],n)))
| Con.Lemma lemma -> B.Object ([], P.Mi([],lemma.Con.lemma_name))
- | Con.Term t ->
+ | Con.Term (_,t) ->
term2pres t
| Con.ArgProof p -> B.b_kw "a proof???"
| Con.ArgMethod s -> B.b_kw "a method???") in
(make_concl "we proceed by induction on" arg) in
let to_prove =
- (make_concl "to prove" proof_conclusion) in
- B.V ([], induction_on::to_prove:: B.Text([],".")::(make_cases args_for_cases))
+ B.H ([], [make_concl "to prove" proof_conclusion ; B.Text([],".")]) in
+ B.V ([], induction_on::to_prove::(make_cases args_for_cases))
and make_cases l = List.map make_case l
| _ -> assert false in
let hyps = List.map make_hyp indhyps in
text::hyps) in
- (* let acontext =
- acontext2pres_old p.Con.proof_apply_context true in *)
let body =
- conclude2pres true p.Con.proof_conclude true true false in
+ conclude2pres true p.Con.proof_name p.Con.proof_conclude true true false in
let presacontext =
let acontext_id =
match p.Con.proof_apply_context with
p.Con.proof_apply_context body true
(p.Con.proof_conclude.Con.conclude_method = "BU_Conversion")
]) in
- B.V ([], pattern::induction_hypothesis@[asubconcl;B.Text([],".");presacontext])
+ B.V ([], pattern::induction_hypothesis@[B.H ([],[asubconcl;B.Text([],".")]);presacontext])
| _ -> assert false
and falseind conclude =
[ B.Object ([], P.Mi([],lemma.Con.lemma_name)); B.skip;
B.b_kw "is contradictory, hence" ]
| _ -> assert false) in
- (* let body = proof2pres {proof with Con.proof_context = tl} false in *)
make_row arg proof_conclusion
and andind conclude =
B.Text([],")");
B.skip;
term2pres hyp2.Con.dec_type]) in
- (* let body = proof2pres {proof with Con.proof_context = tl} false in *)
- let body= conclude2pres false proof.Con.proof_conclude false true false in
+ let body =
+ conclude2pres false proof.Con.proof_name proof.Con.proof_conclude
+ false true false in
let presacontext =
acontext2pres false proof.Con.proof_apply_context body false false
in
B.Text([],")");
B.skip;
term2pres hyp.Con.dec_type]) in
- (* let body = proof2pres {proof with Con.proof_context = tl} false in *)
- let body= conclude2pres false proof.Con.proof_conclude false true false in
+ let body =
+ conclude2pres false proof.Con.proof_name proof.Con.proof_conclude
+ false true false in
let presacontext =
acontext2pres false proof.Con.proof_apply_context body false false
in
| _ -> assert false
in
- proof2pres ?skip_initial_lambdas_internal:skip_initial_lambdas is_top_down p false
+ proof2pres
+ ?skip_initial_lambdas_internal:
+ (match skip_initial_lambdas with
+ None -> Some (`Later 0) (* we already printed theorem: *)
+ | Some n -> Some (`Later n))
+ is_top_down p false
exception ToDo
(B.b_hv [Some "helm", "xref", id]
((B.b_toggle [
B.b_h [] [B.b_text [] "{...}"; B.b_space];
- B.b_hv [] (List.map
+ B.b_hv [] (HExtlib.list_concat ~sep:[B.b_text [] ";"; B.b_space]
+ (List.map (fun x -> [x])
+ (List.map
(function
| None ->
B.b_h []
(match dec_name with
None -> "_"
| Some n -> n));
- B.b_text [] ":";
+ B.b_text [] ":"; B.b_space;
term2pres ty ]
| Some (`Definition d) ->
let
None -> "_"
| Some n -> n)) ;
B.b_text [] (Utf8Macro.unicode_of_tex "\\Assign");
+ B.b_space;
term2pres bo]
| Some (`Proof p) ->
let proof_name = p.Content.proof_name in
None -> "_"
| Some n -> n)) ;
B.b_text [] (Utf8Macro.unicode_of_tex "\\Assign");
+ B.b_space;
proof2pres true term2pres p])
- (List.rev context)) ] ::
+ (List.rev context)))) ] ::
[ B.b_h []
- [ B.b_text [] (Utf8Macro.unicode_of_tex "\\vdash");
+ [ B.b_space;
+ B.b_text [] (Utf8Macro.unicode_of_tex "\\vdash");
+ B.b_space;
B.b_object (p_mi [] (string_of_int n)) ;
B.b_text [] ":" ;
+ B.b_space;
term2pres ty ]])))
let metasenv2pres term2pres = function
match kind with
| `Recursive _ -> "Recursive definition"
| `CoRecursive -> "CoRecursive definition"
- | `Inductive _ -> "Inductive definition"
- | `CoInductive _ -> "CoInductive definition"
+ | `Inductive i ->
+ "Inductive definition with "^string_of_int i^" fixed parameter(s)"
+ | `CoInductive i ->
+ "Co-Inductive definition with "^string_of_int i^" fixed parameter(s)"
in
B.b_h [] (B.b_kw kind :: params2pres params)
[Some "helm","xref","id"]
([ B.b_h [] (B.b_kw ("theorem " ^ name) ::
params2pres params @ [B.b_kw ":"]);
- B.indent (term2pres thesis) ; B.b_kw "." ] @
+ B.H ([],[B.indent (term2pres thesis) ; B.b_kw "." ])] @
metasenv2pres term2pres metasenv @
[proof ; B.b_kw "qed."])
| `Def (_, ty, `Definition body) ->
content2pres ?skip_initial_lambdas ?skip_thm_and_qed
(fun ?(prec=90) annterm ->
let ast, ids_to_uris =
- TermAcicContent.ast_of_acic ids_to_inner_sorts annterm
+ TermAcicContent.ast_of_acic ~output_type:`Term ids_to_inner_sorts annterm
in
CicNotationPres.box_of_mpres
(CicNotationPres.render ids_to_uris ~prec