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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open Util
open Names
open Nameops
open Term
open Termops
open Sign
open Environ
open Libnames
open Mod_subst
(* The kinds of existential variable *)
type obligation_definition_status = Define of bool | Expand
type hole_kind =
| ImplicitArg of global_reference * (int * identifier option) * bool
| BinderType of name
| QuestionMark of obligation_definition_status
| CasesType
| InternalHole
| TomatchTypeParameter of inductive * int
| GoalEvar
| ImpossibleCase
| MatchingVar of bool * identifier
(* The type of mappings for existential variables *)
type evar = existential_key
let string_of_existential evk = "?" ^ string_of_int evk
let existential_of_int evk = evk
type evar_body =
| Evar_empty
| Evar_defined of constr
type evar_info = {
evar_concl : constr;
evar_hyps : named_context_val;
evar_body : evar_body;
evar_filter : bool list;
evar_source : hole_kind located;
evar_extra : Store.t }
let make_evar hyps ccl = {
evar_concl = ccl;
evar_hyps = hyps;
evar_body = Evar_empty;
evar_filter = List.map (fun _ -> true) (named_context_of_val hyps);
evar_source = (dummy_loc,InternalHole);
evar_extra = Store.empty
}
let evar_concl evi = evi.evar_concl
let evar_hyps evi = evi.evar_hyps
let evar_context evi = named_context_of_val evi.evar_hyps
let evar_body evi = evi.evar_body
let evar_filter evi = evi.evar_filter
let evar_unfiltered_env evi = Global.env_of_context evi.evar_hyps
let evar_filtered_context evi =
snd (list_filter2 (fun b c -> b) (evar_filter evi,evar_context evi))
let evar_env evi =
List.fold_right push_named (evar_filtered_context evi)
(reset_context (Global.env()))
let eq_evar_info ei1 ei2 =
ei1 == ei2 ||
eq_constr ei1.evar_concl ei2.evar_concl &&
eq_named_context_val (ei1.evar_hyps) (ei2.evar_hyps) &&
ei1.evar_body = ei2.evar_body
(* spiwack: Revised hierarchy :
- ExistentialMap ( Maps of existential_keys )
- EvarInfoMap ( .t = evar_info ExistentialMap.t * evar_info ExistentialMap )
- EvarMap ( .t = EvarInfoMap.t * sort_constraints )
- evar_map (exported)
*)
module ExistentialMap = Intmap
module ExistentialSet = Intset
(* This exception is raised by *.existential_value *)
exception NotInstantiatedEvar
module EvarInfoMap = struct
type t = evar_info ExistentialMap.t * evar_info ExistentialMap.t
let empty = ExistentialMap.empty, ExistentialMap.empty
let is_empty (def,undef) =
(ExistentialMap.is_empty def, ExistentialMap.is_empty undef)
let to_list (def,undef) =
(* Workaround for change in Map.fold behavior in ocaml 3.08.4 *)
let l = ref [] in
ExistentialMap.iter (fun evk x -> l := (evk,x)::!l) def;
ExistentialMap.iter (fun evk x -> l := (evk,x)::!l) undef;
!l
let undefined_list (def,undef) =
(* Order is important: needs ocaml >= 3.08.4 from which "fold" is a
"fold_left" *)
ExistentialMap.fold (fun evk evi l -> (evk,evi)::l) undef []
let undefined_evars (def,undef) = (ExistentialMap.empty,undef)
let find (def,undef) k =
try ExistentialMap.find k def
with Not_found -> ExistentialMap.find k undef
let find_undefined (def,undef) k = ExistentialMap.find k undef
let remove (def,undef) k =
(ExistentialMap.remove k def,ExistentialMap.remove k undef)
let mem (def,undef) k =
ExistentialMap.mem k def || ExistentialMap.mem k undef
let fold (def,undef) f a =
ExistentialMap.fold f def (ExistentialMap.fold f undef a)
let fold_undefined (def,undef) f a =
ExistentialMap.fold f undef a
let exists_undefined (def,undef) f =
ExistentialMap.fold (fun k v b -> b || f k v) undef false
let add (def,undef) evk newinfo =
if newinfo.evar_body = Evar_empty then
(def,ExistentialMap.add evk newinfo undef)
else
(ExistentialMap.add evk newinfo def,undef)
let add_undefined (def,undef) evk newinfo =
assert (newinfo.evar_body = Evar_empty);
(def,ExistentialMap.add evk newinfo undef)
let map f (def,undef) = (ExistentialMap.map f def, ExistentialMap.map f undef)
let define (def,undef) evk body =
let oldinfo =
try ExistentialMap.find evk undef
with Not_found -> anomaly "Evd.define: cannot define undeclared evar" in
let newinfo =
{ oldinfo with
evar_body = Evar_defined body } in
match oldinfo.evar_body with
| Evar_empty ->
(ExistentialMap.add evk newinfo def,ExistentialMap.remove evk undef)
| _ ->
anomaly "Evd.define: cannot define an evar twice"
let is_evar = mem
let is_defined (def,undef) evk = ExistentialMap.mem evk def
let is_undefined (def,undef) evk = ExistentialMap.mem evk undef
(*******************************************************************)
(* Formerly Instantiate module *)
let is_id_inst inst =
let is_id (id,c) = match kind_of_term c with
| Var id' -> id = id'
| _ -> false
in
List.for_all is_id inst
(* Vérifier que les instances des let-in sont compatibles ?? *)
let instantiate_sign_including_let sign args =
let rec instrec = function
| ((id,b,_) :: sign, c::args) -> (id,c) :: (instrec (sign,args))
| ([],[]) -> []
| ([],_) | (_,[]) ->
anomaly "Signature and its instance do not match"
in
instrec (sign,args)
let instantiate_evar sign c args =
let inst = instantiate_sign_including_let sign args in
if is_id_inst inst then
c
else
replace_vars inst c
(* Existentials. *)
let existential_type sigma (n,args) =
let info =
try find sigma n
with Not_found ->
anomaly ("Evar "^(string_of_existential n)^" was not declared") in
let hyps = evar_filtered_context info in
instantiate_evar hyps info.evar_concl (Array.to_list args)
let existential_value sigma (n,args) =
let info = find sigma n in
let hyps = evar_filtered_context info in
match evar_body info with
| Evar_defined c ->
instantiate_evar hyps c (Array.to_list args)
| Evar_empty ->
raise NotInstantiatedEvar
let existential_opt_value sigma ev =
try Some (existential_value sigma ev)
with NotInstantiatedEvar -> None
end
(*******************************************************************)
(* Constraints for sort variables *)
(*******************************************************************)
type sort_var = Univ.universe
type sort_constraint =
| DefinedSort of sorts (* instantiated sort var *)
| SortVar of sort_var list * sort_var list (* (leq,geq) *)
| EqSort of sort_var
module UniverseMap =
Map.Make (struct type t = Univ.universe let compare = compare end)
type sort_constraints = sort_constraint UniverseMap.t
let rec canonical_find u scstr =
match UniverseMap.find u scstr with
EqSort u' -> canonical_find u' scstr
| c -> (u,c)
let whd_sort_var scstr t =
match kind_of_term t with
Sort(Type u) ->
(try
match canonical_find u scstr with
_, DefinedSort s -> mkSort s
| _ -> t
with Not_found -> t)
| _ -> t
let rec set_impredicative u s scstr =
match UniverseMap.find u scstr with
| DefinedSort s' ->
if family_of_sort s = family_of_sort s' then scstr
else failwith "sort constraint inconsistency"
| EqSort u' ->
UniverseMap.add u (DefinedSort s) (set_impredicative u' s scstr)
| SortVar(_,ul) ->
(* also set sorts lower than u as impredicative *)
UniverseMap.add u (DefinedSort s)
(List.fold_left (fun g u' -> set_impredicative u' s g) scstr ul)
let rec set_predicative u s scstr =
match UniverseMap.find u scstr with
| DefinedSort s' ->
if family_of_sort s = family_of_sort s' then scstr
else failwith "sort constraint inconsistency"
| EqSort u' ->
UniverseMap.add u (DefinedSort s) (set_predicative u' s scstr)
| SortVar(ul,_) ->
UniverseMap.add u (DefinedSort s)
(List.fold_left (fun g u' -> set_impredicative u' s g) scstr ul)
let var_of_sort = function
Type u -> u
| _ -> assert false
let is_sort_var s scstr =
match s with
Type u ->
(try
match canonical_find u scstr with
_, DefinedSort _ -> false
| _ -> true
with Not_found -> false)
| _ -> false
let new_sort_var cstr =
let u = Termops.new_univ() in
(u, UniverseMap.add u (SortVar([],[])) cstr)
let set_leq_sort (u1,(leq1,geq1)) (u2,(leq2,geq2)) scstr =
let rec search_rec (is_b, betw, not_betw) u1 =
if List.mem u1 betw then (true, betw, not_betw)
else if List.mem u1 not_betw then (is_b, betw, not_betw)
else if u1 = u2 then (true, u1::betw,not_betw) else
match UniverseMap.find u1 scstr with
EqSort u1' -> search_rec (is_b,betw,not_betw) u1'
| SortVar(leq,_) ->
let (is_b',betw',not_betw') =
List.fold_left search_rec (false,betw,not_betw) leq in
if is_b' then (true, u1::betw', not_betw')
else (false, betw', not_betw')
| DefinedSort _ -> (false,betw,u1::not_betw) in
let (is_betw,betw,_) = search_rec (false, [], []) u1 in
if is_betw then
UniverseMap.add u1 (SortVar(leq1@leq2,geq1@geq2))
(List.fold_left
(fun g u -> UniverseMap.add u (EqSort u1) g) scstr betw)
else
UniverseMap.add u1 (SortVar(u2::leq1,geq1))
(UniverseMap.add u2 (SortVar(leq2, u1::geq2)) scstr)
let set_leq s1 s2 scstr =
let u1 = var_of_sort s1 in
let u2 = var_of_sort s2 in
let (cu1,c1) = canonical_find u1 scstr in
let (cu2,c2) = canonical_find u2 scstr in
if cu1=cu2 then scstr
else
match c1,c2 with
(EqSort _, _ | _, EqSort _) -> assert false
| SortVar(leq1,geq1), SortVar(leq2,geq2) ->
set_leq_sort (cu1,(leq1,geq1)) (cu2,(leq2,geq2)) scstr
| _, DefinedSort(Prop _ as s) -> set_impredicative u1 s scstr
| _, DefinedSort(Type _) -> scstr
| DefinedSort(Type _ as s), _ -> set_predicative u2 s scstr
| DefinedSort(Prop _), _ -> scstr
let set_sort_variable s1 s2 scstr =
let u = var_of_sort s1 in
match s2 with
Prop _ -> set_impredicative u s2 scstr
| Type _ -> set_predicative u s2 scstr
let pr_sort_cstrs g =
let l = UniverseMap.fold (fun u c l -> (u,c)::l) g [] in
str "SORT CONSTRAINTS:" ++ fnl() ++
prlist_with_sep fnl (fun (u,c) ->
match c with
EqSort u' -> Univ.pr_uni u ++ str" == " ++ Univ.pr_uni u'
| DefinedSort s -> Univ.pr_uni u ++ str " := " ++ print_sort s
| SortVar(leq,geq) ->
str"[" ++ hov 0 (prlist_with_sep spc Univ.pr_uni geq) ++
str"] <= "++ Univ.pr_uni u ++ brk(0,0) ++ str"<= [" ++
hov 0 (prlist_with_sep spc Univ.pr_uni leq) ++ str"]")
l
module EvarMap = struct
type t = EvarInfoMap.t * sort_constraints
let empty = EvarInfoMap.empty, UniverseMap.empty
let add (sigma,sm) k v = (EvarInfoMap.add sigma k v, sm)
let add_undefined (sigma,sm) k v = (EvarInfoMap.add_undefined sigma k v, sm)
let find (sigma,_) = EvarInfoMap.find sigma
let find_undefined (sigma,_) = EvarInfoMap.find_undefined sigma
let remove (sigma,sm) k = (EvarInfoMap.remove sigma k, sm)
let mem (sigma,_) = EvarInfoMap.mem sigma
let to_list (sigma,_) = EvarInfoMap.to_list sigma
let undefined_list (sigma,_) = EvarInfoMap.undefined_list sigma
let undefined_evars (sigma,sm) = (EvarInfoMap.undefined_evars sigma, sm)
let fold (sigma,_) = EvarInfoMap.fold sigma
let fold_undefined (sigma,_) = EvarInfoMap.fold_undefined sigma
let define (sigma,sm) k v = (EvarInfoMap.define sigma k v, sm)
let is_evar (sigma,_) = EvarInfoMap.is_evar sigma
let is_defined (sigma,_) = EvarInfoMap.is_defined sigma
let is_undefined (sigma,_) = EvarInfoMap.is_undefined sigma
let existential_value (sigma,_) = EvarInfoMap.existential_value sigma
let existential_type (sigma,_) = EvarInfoMap.existential_type sigma
let existential_opt_value (sigma,_) = EvarInfoMap.existential_opt_value sigma
let progress_evar_map (sigma1,sm1 as x) (sigma2,sm2 as y) = not (x == y) &&
(EvarInfoMap.exists_undefined sigma1
(fun k v -> assert (v.evar_body = Evar_empty);
EvarInfoMap.is_defined sigma2 k)
|| not (UniverseMap.equal (=) sm1 sm2))
let merge e e' = fold e' (fun n v sigma -> add sigma n v) e
end
(*******************************************************************)
(* Metamaps *)
(*******************************************************************)
(* Constraints for existential variables *)
(*******************************************************************)
type 'a freelisted = {
rebus : 'a;
freemetas : Intset.t }
(* Collects all metavars appearing in a constr *)
let metavars_of c =
let rec collrec acc c =
match kind_of_term c with
| Meta mv -> Intset.add mv acc
| _ -> fold_constr collrec acc c
in
collrec Intset.empty c
let mk_freelisted c =
{ rebus = c; freemetas = metavars_of c }
let map_fl f cfl = { cfl with rebus=f cfl.rebus }
(* Status of an instance found by unification wrt to the meta it solves:
- a supertype of the meta (e.g. the solution to ?X <= T is a supertype of ?X)
- a subtype of the meta (e.g. the solution to T <= ?X is a supertype of ?X)
- a term that can be eta-expanded n times while still being a solution
(e.g. the solution [P] to [?X u v = P u v] can be eta-expanded twice)
*)
type instance_constraint =
IsSuperType | IsSubType | ConvUpToEta of int | UserGiven
(* Status of the unification of the type of an instance against the type of
the meta it instantiates:
- CoerceToType means that the unification of types has not been done
and that a coercion can still be inserted: the meta should not be
substituted freely (this happens for instance given via the
"with" binding clause).
- TypeProcessed means that the information obtainable from the
unification of types has been extracted.
- TypeNotProcessed means that the unification of types has not been
done but it is known that no coercion may be inserted: the meta
can be substituted freely.
*)
type instance_typing_status =
CoerceToType | TypeNotProcessed | TypeProcessed
(* Status of an instance together with the status of its type unification *)
type instance_status = instance_constraint * instance_typing_status
(* Clausal environments *)
type clbinding =
| Cltyp of name * constr freelisted
| Clval of name * (constr freelisted * instance_status) * constr freelisted
let map_clb f = function
| Cltyp (na,cfl) -> Cltyp (na,map_fl f cfl)
| Clval (na,(cfl1,pb),cfl2) -> Clval (na,(map_fl f cfl1,pb),map_fl f cfl2)
(* name of defined is erased (but it is pretty-printed) *)
let clb_name = function
Cltyp(na,_) -> (na,false)
| Clval (na,_,_) -> (na,true)
(***********************)
module Metaset = Intset
let meta_exists p s = Metaset.fold (fun x b -> b || (p x)) s false
module Metamap = Intmap
let metamap_to_list m =
Metamap.fold (fun n v l -> (n,v)::l) m []
(*************************)
(* Unification state *)
type conv_pb = Reduction.conv_pb
type evar_constraint = conv_pb * Environ.env * constr * constr
type evar_map =
{ evars : EvarMap.t;
conv_pbs : evar_constraint list;
last_mods : ExistentialSet.t;
metas : clbinding Metamap.t }
(*** Lifting primitive from EvarMap. ***)
(* HH: The progress tactical now uses this function. *)
let progress_evar_map d1 d2 =
EvarMap.progress_evar_map d1.evars d2.evars
(* spiwack: tentative. It might very well not be the semantics we want
for merging evar_map *)
let merge d1 d2 = {
evars = EvarMap.merge d1.evars d2.evars ;
conv_pbs = List.rev_append d1.conv_pbs d2.conv_pbs ;
last_mods = ExistentialSet.union d1.last_mods d2.last_mods ;
metas = Metamap.fold (fun k m r -> Metamap.add k m r) d2.metas d1.metas
}
let add d e i = { d with evars=EvarMap.add d.evars e i }
let remove d e = { d with evars=EvarMap.remove d.evars e }
let find d e = EvarMap.find d.evars e
let find_undefined d e = EvarMap.find_undefined d.evars e
let mem d e = EvarMap.mem d.evars e
(* spiwack: this function loses information from the original evar_map
it might be an idea not to export it. *)
let to_list d = EvarMap.to_list d.evars
let undefined_list d = EvarMap.undefined_list d.evars
let undefined_evars d = { d with evars=EvarMap.undefined_evars d.evars }
(* spiwack: not clear what folding over an evar_map, for now we shall
simply fold over the inner evar_map. *)
let fold f d a = EvarMap.fold d.evars f a
let fold_undefined f d a = EvarMap.fold_undefined d.evars f a
let is_evar d e = EvarMap.is_evar d.evars e
let is_defined d e = EvarMap.is_defined d.evars e
let is_undefined d e = EvarMap.is_undefined d.evars e
let existential_value d e = EvarMap.existential_value d.evars e
let existential_type d e = EvarMap.existential_type d.evars e
let existential_opt_value d e = EvarMap.existential_opt_value d.evars e
(*** /Lifting... ***)
(* evar_map are considered empty disregarding histories *)
let is_empty d =
d.evars = EvarMap.empty &&
d.conv_pbs = [] &&
Metamap.is_empty d.metas
let subst_named_context_val s = map_named_val (subst_mps s)
let subst_evar_info s evi =
let subst_evb = function Evar_empty -> Evar_empty
| Evar_defined c -> Evar_defined (subst_mps s c) in
{ evi with
evar_concl = subst_mps s evi.evar_concl;
evar_hyps = subst_named_context_val s evi.evar_hyps;
evar_body = subst_evb evi.evar_body }
let subst_evar_defs_light sub evd =
assert (UniverseMap.is_empty (snd evd.evars));
assert (evd.conv_pbs = []);
{ evd with
metas = Metamap.map (map_clb (subst_mps sub)) evd.metas;
evars = EvarInfoMap.map (subst_evar_info sub) (fst evd.evars), (snd evd.evars)
}
let subst_evar_map = subst_evar_defs_light
(* spiwack: deprecated *)
let create_evar_defs sigma = { sigma with
conv_pbs=[]; last_mods=ExistentialSet.empty; metas=Metamap.empty }
(* spiwack: tentatively deprecated *)
let create_goal_evar_defs sigma = { sigma with
(* conv_pbs=[]; last_mods=ExistentialSet.empty; metas=Metamap.empty } *)
metas=Metamap.empty }
let empty = {
evars=EvarMap.empty;
conv_pbs=[];
last_mods = ExistentialSet.empty;
metas=Metamap.empty
}
let evars_reset_evd evd d = {d with evars = evd.evars}
let add_conv_pb pb d = {d with conv_pbs = pb::d.conv_pbs}
let evar_source evk d = (EvarMap.find d.evars evk).evar_source
(* define the existential of section path sp as the constr body *)
let define evk body evd =
{ evd with
evars = EvarMap.define evd.evars evk body;
last_mods =
match evd.conv_pbs with
| [] -> evd.last_mods
| _ -> ExistentialSet.add evk evd.last_mods }
let evar_declare hyps evk ty ?(src=(dummy_loc,InternalHole)) ?filter evd =
let filter =
if filter = None then
List.map (fun _ -> true) (named_context_of_val hyps)
else
(let filter = Option.get filter in
assert (List.length filter = List.length (named_context_of_val hyps));
filter)
in
{ evd with
evars = EvarMap.add_undefined evd.evars evk
{evar_hyps = hyps;
evar_concl = ty;
evar_body = Evar_empty;
evar_filter = filter;
evar_source = src;
evar_extra = Store.empty } }
let is_defined_evar evd (evk,_) = EvarMap.is_defined evd.evars evk
(* Does k corresponds to an (un)defined existential ? *)
let is_undefined_evar evd c = match kind_of_term c with
| Evar ev -> not (is_defined_evar evd ev)
| _ -> false
(* extracts conversion problems that satisfy predicate p *)
(* Note: conv_pbs not satisying p are stored back in reverse order *)
let extract_conv_pbs evd p =
let (pbs,pbs1) =
List.fold_left
(fun (pbs,pbs1) pb ->
if p pb then
(pb::pbs,pbs1)
else
(pbs,pb::pbs1))
([],[])
evd.conv_pbs
in
{evd with conv_pbs = pbs1; last_mods = ExistentialSet.empty},
pbs
let extract_changed_conv_pbs evd p =
extract_conv_pbs evd (p evd.last_mods)
let extract_all_conv_pbs evd =
extract_conv_pbs evd (fun _ -> true)
(* spiwack: should it be replaced by Evd.merge? *)
let evar_merge evd evars =
{ evd with evars = EvarMap.merge evd.evars evars.evars }
let evar_list evd c =
let rec evrec acc c =
match kind_of_term c with
| Evar (evk, _ as ev) when mem evd evk -> ev :: acc
| _ -> fold_constr evrec acc c in
evrec [] c
(**********************************************************)
(* Sort variables *)
let new_sort_variable ({ evars = (sigma,sm) } as d)=
let (u,scstr) = new_sort_var sm in
(Type u,{ d with evars = (sigma,scstr) } )
let is_sort_variable {evars=(_,sm)} s =
is_sort_var s sm
let whd_sort_variable {evars=(_,sm)} t = whd_sort_var sm t
let set_leq_sort_variable ({evars=(sigma,sm)}as d) u1 u2 =
{ d with evars = (sigma, set_leq u1 u2 sm) }
let define_sort_variable ({evars=(sigma,sm)}as d) u s =
{ d with evars = (sigma, set_sort_variable u s sm) }
let pr_sort_constraints {evars=(_,sm)} = pr_sort_cstrs sm
(**********************************************************)
(* Accessing metas *)
let meta_list evd = metamap_to_list evd.metas
let find_meta evd mv = Metamap.find mv evd.metas
let undefined_metas evd =
List.sort Pervasives.compare (map_succeed (function
| (n,Clval(_,_,typ)) -> failwith ""
| (n,Cltyp (_,typ)) -> n)
(meta_list evd))
let metas_of evd =
List.map (function
| (n,Clval(_,_,typ)) -> (n,typ.rebus)
| (n,Cltyp (_,typ)) -> (n,typ.rebus))
(meta_list evd)
let map_metas_fvalue f evd =
{ evd with metas =
Metamap.map
(function
| Clval(id,(c,s),typ) -> Clval(id,(mk_freelisted (f c.rebus),s),typ)
| x -> x) evd.metas }
let meta_opt_fvalue evd mv =
match Metamap.find mv evd.metas with
| Clval(_,b,_) -> Some b
| Cltyp _ -> None
let meta_defined evd mv =
match Metamap.find mv evd.metas with
| Clval _ -> true
| Cltyp _ -> false
let try_meta_fvalue evd mv =
match Metamap.find mv evd.metas with
| Clval(_,b,_) -> b
| Cltyp _ -> raise Not_found
let meta_fvalue evd mv =
try try_meta_fvalue evd mv
with Not_found -> anomaly "meta_fvalue: meta has no value"
let meta_value evd mv =
(fst (try_meta_fvalue evd mv)).rebus
let meta_ftype evd mv =
match Metamap.find mv evd.metas with
| Cltyp (_,b) -> b
| Clval(_,_,b) -> b
let meta_type evd mv = (meta_ftype evd mv).rebus
let meta_declare mv v ?(name=Anonymous) evd =
{ evd with metas = Metamap.add mv (Cltyp(name,mk_freelisted v)) evd.metas }
let meta_assign mv (v,pb) evd =
match Metamap.find mv evd.metas with
| Cltyp(na,ty) ->
{ evd with
metas = Metamap.add mv (Clval(na,(mk_freelisted v,pb),ty)) evd.metas }
| _ -> anomaly "meta_assign: already defined"
let meta_reassign mv (v,pb) evd =
match Metamap.find mv evd.metas with
| Clval(na,_,ty) ->
{ evd with
metas = Metamap.add mv (Clval(na,(mk_freelisted v,pb),ty)) evd.metas }
| _ -> anomaly "meta_reassign: not yet defined"
(* If the meta is defined then forget its name *)
let meta_name evd mv =
try fst (clb_name (Metamap.find mv evd.metas)) with Not_found -> Anonymous
let meta_with_name evd id =
let na = Name id in
let (mvl,mvnodef) =
Metamap.fold
(fun n clb (l1,l2 as l) ->
let (na',def) = clb_name clb in
if na = na' then if def then (n::l1,l2) else (n::l1,n::l2)
else l)
evd.metas ([],[]) in
match mvnodef, mvl with
| _,[] ->
errorlabstrm "Evd.meta_with_name"
(str"No such bound variable " ++ pr_id id ++ str".")
| ([n],_|_,[n]) ->
n
| _ ->
errorlabstrm "Evd.meta_with_name"
(str "Binder name \"" ++ pr_id id ++
strbrk "\" occurs more than once in clause.")
let meta_merge evd1 evd2 =
{evd2 with
metas = List.fold_left (fun m (n,v) -> Metamap.add n v m)
evd2.metas (metamap_to_list evd1.metas) }
type metabinding = metavariable * constr * instance_status
let retract_coercible_metas evd =
let mc,ml =
Metamap.fold (fun n v (mc,ml) ->
match v with
| Clval (na,(b,(UserGiven,CoerceToType as s)),typ) ->
(n,b.rebus,s)::mc, Metamap.add n (Cltyp (na,typ)) ml
| v ->
mc, Metamap.add n v ml)
evd.metas ([],Metamap.empty) in
mc, { evd with metas = ml }
let rec list_assoc_in_triple x = function
[] -> raise Not_found
| (a,b,_)::l -> if compare a x = 0 then b else list_assoc_in_triple x l
let subst_defined_metas bl c =
let rec substrec c = match kind_of_term c with
| Meta i -> substrec (list_assoc_in_triple i bl)
| _ -> map_constr substrec c
in try Some (substrec c) with Not_found -> None
(*******************************************************************)
type open_constr = evar_map * constr
(*******************************************************************)
(* The type constructor ['a sigma] adds an evar map to an object of
type ['a] *)
type 'a sigma = {
it : 'a ;
sigma : evar_map}
let sig_it x = x.it
let sig_sig x = x.sigma
(**********************************************************)
(* Failure explanation *)
type unsolvability_explanation = SeveralInstancesFound of int
(**********************************************************)
(* Pretty-printing *)
let pr_instance_status (sc,typ) =
begin match sc with
| IsSubType -> str " [or a subtype of it]"
| IsSuperType -> str " [or a supertype of it]"
| ConvUpToEta 0 -> mt ()
| UserGiven -> mt ()
| ConvUpToEta n -> str" [or an eta-expansion up to " ++ int n ++ str" of it]"
end ++
begin match typ with
| CoerceToType -> str " [up to coercion]"
| TypeNotProcessed -> mt ()
| TypeProcessed -> str " [type is checked]"
end
let pr_meta_map mmap =
let pr_name = function
Name id -> str"[" ++ pr_id id ++ str"]"
| _ -> mt() in
let pr_meta_binding = function
| (mv,Cltyp (na,b)) ->
hov 0
(pr_meta mv ++ pr_name na ++ str " : " ++
print_constr b.rebus ++ fnl ())
| (mv,Clval(na,(b,s),t)) ->
hov 0
(pr_meta mv ++ pr_name na ++ str " := " ++
print_constr b.rebus ++
str " : " ++ print_constr t.rebus ++
spc () ++ pr_instance_status s ++ fnl ())
in
prlist pr_meta_binding (metamap_to_list mmap)
let pr_decl ((id,b,_),ok) =
match b with
| None -> if ok then pr_id id else (str "{" ++ pr_id id ++ str "}")
| Some c -> str (if ok then "(" else "{") ++ pr_id id ++ str ":=" ++
print_constr c ++ str (if ok then ")" else "}")
let pr_evar_info evi =
let decls = List.combine (evar_context evi) (evar_filter evi) in
let phyps = prlist_with_sep pr_spc pr_decl (List.rev decls) in
let pty = print_constr evi.evar_concl in
let pb =
match evi.evar_body with
| Evar_empty -> mt ()
| Evar_defined c -> spc() ++ str"=> " ++ print_constr c
in
hov 2 (str"[" ++ phyps ++ spc () ++ str"|- " ++ pty ++ pb ++ str"]")
let pr_evar_map_t (evars,cstrs as sigma) =
let evs =
if evars = EvarInfoMap.empty then mt ()
else
str"EVARS:"++brk(0,1)++
h 0 (prlist_with_sep pr_fnl
(fun (ev,evi) ->
h 0 (str(string_of_existential ev)++str"=="++ pr_evar_info evi))
(EvarMap.to_list sigma))++fnl()
and cs =
if cstrs = UniverseMap.empty then mt ()
else pr_sort_cstrs cstrs++fnl()
in evs ++ cs
let pr_constraints pbs =
h 0
(prlist_with_sep pr_fnl (fun (pbty,_,t1,t2) ->
print_constr t1 ++ spc() ++
str (match pbty with
| Reduction.CONV -> "=="
| Reduction.CUMUL -> "<=") ++
spc() ++ print_constr t2) pbs)
let pr_evar_map evd =
let pp_evm =
if evd.evars = EvarMap.empty then mt() else
pr_evar_map_t evd.evars++fnl() in
let cstrs =
if evd.conv_pbs = [] then mt() else
str"CONSTRAINTS:"++brk(0,1)++pr_constraints evd.conv_pbs++fnl() in
let pp_met =
if evd.metas = Metamap.empty then mt() else
str"METAS:"++brk(0,1)++pr_meta_map evd.metas in
v 0 (pp_evm ++ cstrs ++ pp_met)
let pr_metaset metas =
str "[" ++ prlist_with_sep spc pr_meta (Metaset.elements metas) ++ str "]"
|