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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open CErrors
open Util
open Names
open Nameops
open Term
open Vars
open Environ
(* module RelDecl = Context.Rel.Declaration *)
module NamedDecl = Context.Named.Declaration
(** Generic filters *)
module Filter :
sig
type t
val equal : t -> t -> bool
val identity : t
val filter_list : t -> 'a list -> 'a list
val filter_array : t -> 'a array -> 'a array
val extend : int -> t -> t
val compose : t -> t -> t
val apply_subfilter : t -> bool list -> t
val restrict_upon : t -> int -> (int -> bool) -> t option
val map_along : (bool -> 'a -> bool) -> t -> 'a list -> t
val make : bool list -> t
val repr : t -> bool list option
end =
struct
type t = bool list option
(** We guarantee through the interface that if a filter is [Some _] then it
contains at least one [false] somewhere. *)
let identity = None
let rec equal l1 l2 = match l1, l2 with
| [], [] -> true
| h1 :: l1, h2 :: l2 ->
(if h1 then h2 else not h2) && equal l1 l2
| _ -> false
let equal l1 l2 = match l1, l2 with
| None, None -> true
| Some _, None | None, Some _ -> false
| Some l1, Some l2 -> equal l1 l2
let rec is_identity = function
| [] -> true
| true :: l -> is_identity l
| false :: _ -> false
let normalize f = if is_identity f then None else Some f
let filter_list f l = match f with
| None -> l
| Some f -> CList.filter_with f l
let filter_array f v = match f with
| None -> v
| Some f -> CArray.filter_with f v
let rec extend n l =
if n = 0 then l
else extend (pred n) (true :: l)
let extend n = function
| None -> None
| Some f -> Some (extend n f)
let compose f1 f2 = match f1 with
| None -> f2
| Some f1 ->
match f2 with
| None -> None
| Some f2 -> normalize (CList.filter_with f1 f2)
let apply_subfilter_array filter subfilter =
(** In both cases we statically know that the argument will contain at
least one [false] *)
match filter with
| None -> Some (Array.to_list subfilter)
| Some f ->
let len = Array.length subfilter in
let fold b (i, ans) =
if b then
let () = assert (0 <= i) in
(pred i, Array.unsafe_get subfilter i :: ans)
else
(i, false :: ans)
in
Some (snd (List.fold_right fold f (pred len, [])))
let apply_subfilter filter subfilter =
apply_subfilter_array filter (Array.of_list subfilter)
let restrict_upon f len p =
let newfilter = Array.init len p in
if Array.for_all (fun id -> id) newfilter then None
else
Some (apply_subfilter_array f newfilter)
let map_along f flt l =
let ans = match flt with
| None -> List.map (fun x -> f true x) l
| Some flt -> List.map2 f flt l
in
normalize ans
let make l = normalize l
let repr f = f
end
(* The kinds of existential variables are now defined in [Evar_kinds] *)
(* The type of mappings for existential variables *)
module Dummy = struct end
module Store = Store.Make(Dummy)
type evar = Term.existential_key
let string_of_existential evk = "?X" ^ string_of_int (Evar.repr 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 : Filter.t;
evar_source : Evar_kinds.t Loc.located;
evar_candidates : constr list option; (* if not None, list of allowed instances *)
evar_extra : Store.t }
let make_evar hyps ccl = {
evar_concl = ccl;
evar_hyps = hyps;
evar_body = Evar_empty;
evar_filter = Filter.identity;
evar_source = Loc.tag @@ Evar_kinds.InternalHole;
evar_candidates = None;
evar_extra = Store.empty
}
let instance_mismatch () =
anomaly (Pp.str "Signature and its instance do not match.")
let evar_concl evi = evi.evar_concl
let evar_filter evi = evi.evar_filter
let evar_body evi = evi.evar_body
let evar_context evi = named_context_of_val evi.evar_hyps
let evar_filtered_context evi =
Filter.filter_list (evar_filter evi) (evar_context evi)
let evar_hyps evi = evi.evar_hyps
let evar_filtered_hyps evi = match Filter.repr (evar_filter evi) with
| None -> evar_hyps evi
| Some filter ->
let rec make_hyps filter ctxt = match filter, ctxt with
| [], [] -> empty_named_context_val
| false :: filter, _ :: ctxt -> make_hyps filter ctxt
| true :: filter, decl :: ctxt ->
let hyps = make_hyps filter ctxt in
push_named_context_val decl hyps
| _ -> instance_mismatch ()
in
make_hyps filter (evar_context evi)
let evar_env evi = Global.env_of_context evi.evar_hyps
let evar_filtered_env evi = match Filter.repr (evar_filter evi) with
| None -> evar_env evi
| Some filter ->
let rec make_env filter ctxt = match filter, ctxt with
| [], [] -> reset_context (Global.env ())
| false :: filter, _ :: ctxt -> make_env filter ctxt
| true :: filter, decl :: ctxt ->
let env = make_env filter ctxt in
push_named decl env
| _ -> instance_mismatch ()
in
make_env filter (evar_context evi)
let map_evar_body f = function
| Evar_empty -> Evar_empty
| Evar_defined d -> Evar_defined (f d)
let map_evar_info f evi =
{evi with
evar_body = map_evar_body f evi.evar_body;
evar_hyps = map_named_val f evi.evar_hyps;
evar_concl = f evi.evar_concl;
evar_candidates = Option.map (List.map f) evi.evar_candidates }
(* This exception is raised by *.existential_value *)
exception NotInstantiatedEvar
(* Note: let-in contributes to the instance *)
let evar_instance_array test_id info args =
let len = Array.length args in
let rec instrec filter ctxt i = match filter, ctxt with
| [], [] ->
if Int.equal i len then []
else instance_mismatch ()
| false :: filter, _ :: ctxt ->
instrec filter ctxt i
| true :: filter, d :: ctxt ->
if i < len then
let c = Array.unsafe_get args i in
if test_id d c then instrec filter ctxt (succ i)
else (NamedDecl.get_id d, c) :: instrec filter ctxt (succ i)
else instance_mismatch ()
| _ -> instance_mismatch ()
in
match Filter.repr (evar_filter info) with
| None ->
let map i d =
if (i < len) then
let c = Array.unsafe_get args i in
if test_id d c then None else Some (NamedDecl.get_id d, c)
else instance_mismatch ()
in
List.map_filter_i map (evar_context info)
| Some filter ->
instrec filter (evar_context info) 0
let make_evar_instance_array info args =
evar_instance_array (NamedDecl.get_id %> isVarId) info args
let instantiate_evar_array info c args =
let inst = make_evar_instance_array info args in
match inst with
| [] -> c
| _ -> replace_vars inst c
type evar_universe_context = UState.t
type 'a in_evar_universe_context = 'a * evar_universe_context
let empty_evar_universe_context = UState.empty
let union_evar_universe_context = UState.union
let evar_universe_context_set = UState.context_set
let evar_universe_context_constraints = UState.constraints
let evar_context_universe_context = UState.context
let evar_universe_context_of = UState.of_context_set
let evar_universe_context_subst = UState.subst
let add_constraints_context = UState.add_constraints
let add_universe_constraints_context = UState.add_universe_constraints
let constrain_variables = UState.constrain_variables
let evar_universe_context_of_binders = UState.of_binders
(*******************************************************************)
(* Metamaps *)
(*******************************************************************)
(* Constraints for existential variables *)
(*******************************************************************)
type 'a freelisted = {
rebus : 'a;
freemetas : Int.Set.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 -> Int.Set.add mv acc
| _ -> Term.fold_constr collrec acc c
in
collrec Int.Set.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 | Conv
let eq_instance_constraint c1 c2 = c1 == c2
(* 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.t * constr freelisted
| Clval of Name.t * (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 = Int.Set
module Metamap = Int.Map
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
module EvMap = Evar.Map
module EvNames :
sig
type t
val empty : t
val add_name_undefined : Id.t option -> Evar.t -> evar_info -> t -> t
val remove_name_defined : Evar.t -> t -> t
val rename : Evar.t -> Id.t -> t -> t
val reassign_name_defined : Evar.t -> Evar.t -> t -> t
val ident : Evar.t -> t -> Id.t option
val key : Id.t -> t -> Evar.t
end =
struct
type t = Id.t EvMap.t * existential_key Idmap.t
let empty = (EvMap.empty, Idmap.empty)
let add_name_newly_undefined id evk evi (evtoid, idtoev as names) =
match id with
| None -> names
| Some id ->
if Idmap.mem id idtoev then
user_err (str "Already an existential evar of name " ++ pr_id id);
(EvMap.add evk id evtoid, Idmap.add id evk idtoev)
let add_name_undefined naming evk evi (evtoid,idtoev as evar_names) =
if EvMap.mem evk evtoid then
evar_names
else
add_name_newly_undefined naming evk evi evar_names
let remove_name_defined evk (evtoid, idtoev as names) =
let id = try Some (EvMap.find evk evtoid) with Not_found -> None in
match id with
| None -> names
| Some id -> (EvMap.remove evk evtoid, Idmap.remove id idtoev)
let rename evk id (evtoid, idtoev) =
let id' = try Some (EvMap.find evk evtoid) with Not_found -> None in
match id' with
| None -> (EvMap.add evk id evtoid, Idmap.add id evk idtoev)
| Some id' ->
if Idmap.mem id idtoev then anomaly (str "Evar name already in use.");
(EvMap.update evk id evtoid (* overwrite old name *), Idmap.add id evk (Idmap.remove id' idtoev))
let reassign_name_defined evk evk' (evtoid, idtoev as names) =
let id = try Some (EvMap.find evk evtoid) with Not_found -> None in
match id with
| None -> names (** evk' must not be defined *)
| Some id ->
(EvMap.add evk' id (EvMap.remove evk evtoid),
Idmap.add id evk' (Idmap.remove id idtoev))
let ident evk (evtoid, _) =
try Some (EvMap.find evk evtoid) with Not_found -> None
let key id (_, idtoev) =
Idmap.find id idtoev
end
type evar_map = {
(** Existential variables *)
defn_evars : evar_info EvMap.t;
undf_evars : evar_info EvMap.t;
evar_names : EvNames.t;
(** Universes *)
universes : evar_universe_context;
(** Conversion problems *)
conv_pbs : evar_constraint list;
last_mods : Evar.Set.t;
(** Metas *)
metas : clbinding Metamap.t;
(** Interactive proofs *)
effects : Safe_typing.private_constants;
future_goals : Evar.t list; (** list of newly created evars, to be
eventually turned into goals if not solved.*)
principal_future_goal : Evar.t option; (** if [Some e], [e] must be
contained
[future_goals]. The evar
[e] will inherit
properties (now: the
name) of the evar which
will be instantiated with
a term containing [e]. *)
extras : Store.t;
}
(*** Lifting primitive from Evar.Map. ***)
let rename evk id evd =
{ evd with evar_names = EvNames.rename evk id evd.evar_names }
let add_with_name ?name d e i = match i.evar_body with
| Evar_empty ->
let evar_names = EvNames.add_name_undefined name e i d.evar_names in
{ d with undf_evars = EvMap.add e i d.undf_evars; evar_names }
| Evar_defined _ ->
let evar_names = EvNames.remove_name_defined e d.evar_names in
{ d with defn_evars = EvMap.add e i d.defn_evars; evar_names }
let add d e i = add_with_name d e i
(** New evars *)
let evar_counter_summary_name = "evar counter"
(* Generator of existential names *)
let new_untyped_evar =
let evar_ctr = Summary.ref 0 ~name:evar_counter_summary_name in
fun () -> incr evar_ctr; Evar.unsafe_of_int !evar_ctr
let new_evar evd ?name evi =
let evk = new_untyped_evar () in
let evd = add_with_name evd ?name evk evi in
(evd, evk)
let remove d e =
let undf_evars = EvMap.remove e d.undf_evars in
let defn_evars = EvMap.remove e d.defn_evars in
let principal_future_goal = match d.principal_future_goal with
| None -> None
| Some e' -> if Evar.equal e e' then None else d.principal_future_goal
in
let future_goals = List.filter (fun e' -> not (Evar.equal e e')) d.future_goals in
{ d with undf_evars; defn_evars; principal_future_goal; future_goals }
let find d e =
try EvMap.find e d.undf_evars
with Not_found -> EvMap.find e d.defn_evars
let find_undefined d e = EvMap.find e d.undf_evars
let mem d e = EvMap.mem e d.undf_evars || EvMap.mem e d.defn_evars
let undefined_map d = d.undf_evars
let drop_all_defined d = { d with defn_evars = EvMap.empty }
(* 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 =
EvMap.fold f d.defn_evars (EvMap.fold f d.undf_evars a)
let fold_undefined f d a = EvMap.fold f d.undf_evars a
let raw_map f d =
let f evk info =
let ans = f evk info in
let () = match info.evar_body, ans.evar_body with
| Evar_defined _, Evar_empty
| Evar_empty, Evar_defined _ ->
anomaly (str "Unrespectful mapping function.")
| _ -> ()
in
ans
in
let defn_evars = EvMap.smartmapi f d.defn_evars in
let undf_evars = EvMap.smartmapi f d.undf_evars in
{ d with defn_evars; undf_evars; }
let raw_map_undefined f d =
let f evk info =
let ans = f evk info in
let () = match ans.evar_body with
| Evar_defined _ ->
anomaly (str "Unrespectful mapping function.")
| _ -> ()
in
ans
in
{ d with undf_evars = EvMap.smartmapi f d.undf_evars; }
let is_evar = mem
let is_defined d e = EvMap.mem e d.defn_evars
let is_undefined d e = EvMap.mem e d.undf_evars
let existential_value d (n, args) =
let info = find d n in
match evar_body info with
| Evar_defined c ->
instantiate_evar_array info c args
| Evar_empty ->
raise NotInstantiatedEvar
let existential_opt_value d ev =
try Some (existential_value d ev)
with NotInstantiatedEvar -> None
let existential_type d (n, args) =
let info =
try find d n
with Not_found ->
anomaly (str "Evar " ++ str (string_of_existential n) ++ str " was not declared.") in
instantiate_evar_array info info.evar_concl args
let add_constraints d c =
{ d with universes = add_constraints_context d.universes c }
let add_universe_constraints d c =
{ d with universes = add_universe_constraints_context d.universes c }
(*** /Lifting... ***)
(* evar_map are considered empty disregarding histories *)
let is_empty d =
EvMap.is_empty d.defn_evars &&
EvMap.is_empty d.undf_evars &&
List.is_empty d.conv_pbs &&
Metamap.is_empty d.metas
let cmap f evd =
{ evd with
metas = Metamap.map (map_clb f) evd.metas;
defn_evars = EvMap.map (map_evar_info f) evd.defn_evars;
undf_evars = EvMap.map (map_evar_info f) evd.undf_evars
}
(* spiwack: deprecated *)
let create_evar_defs sigma = { sigma with
conv_pbs=[]; last_mods=Evar.Set.empty; metas=Metamap.empty }
let empty = {
defn_evars = EvMap.empty;
undf_evars = EvMap.empty;
universes = empty_evar_universe_context;
conv_pbs = [];
last_mods = Evar.Set.empty;
metas = Metamap.empty;
effects = Safe_typing.empty_private_constants;
evar_names = EvNames.empty; (* id<->key for undefined evars *)
future_goals = [];
principal_future_goal = None;
extras = Store.empty;
}
let from_env e =
{ empty with universes = UState.make (Environ.universes e) }
let from_ctx ctx = { empty with universes = ctx }
let has_undefined evd = not (EvMap.is_empty evd.undf_evars)
let evars_reset_evd ?(with_conv_pbs=false) ?(with_univs=true) evd d =
let conv_pbs = if with_conv_pbs then evd.conv_pbs else d.conv_pbs in
let last_mods = if with_conv_pbs then evd.last_mods else d.last_mods in
let universes =
if not with_univs then evd.universes
else union_evar_universe_context evd.universes d.universes
in
{ evd with
metas = d.metas;
last_mods; conv_pbs; universes }
let merge_universe_context evd uctx' =
{ evd with universes = union_evar_universe_context evd.universes uctx' }
let set_universe_context evd uctx' =
{ evd with universes = uctx' }
let add_conv_pb ?(tail=false) pb d =
(** MS: we have duplicates here, why? *)
if tail then {d with conv_pbs = d.conv_pbs @ [pb]}
else {d with conv_pbs = pb::d.conv_pbs}
let evar_source evk d = (find d evk).evar_source
let evar_ident evk evd = EvNames.ident evk evd.evar_names
let evar_key id evd = EvNames.key id evd.evar_names
let restricted = Store.field ()
let define_aux ?dorestrict def undef evk body =
let oldinfo =
try EvMap.find evk undef
with Not_found ->
if EvMap.mem evk def then
anomaly ~label:"Evd.define" (Pp.str "cannot define an evar twice.")
else
anomaly ~label:"Evd.define" (Pp.str "cannot define undeclared evar.")
in
let () = assert (oldinfo.evar_body == Evar_empty) in
let evar_extra = match dorestrict with
| Some evk' -> Store.set oldinfo.evar_extra restricted evk'
| None -> oldinfo.evar_extra in
let newinfo = { oldinfo with evar_body = Evar_defined body; evar_extra } in
EvMap.add evk newinfo def, EvMap.remove evk undef
(* define the existential of section path sp as the constr body *)
let define evk body evd =
let (defn_evars, undf_evars) = define_aux evd.defn_evars evd.undf_evars evk body in
let last_mods = match evd.conv_pbs with
| [] -> evd.last_mods
| _ -> Evar.Set.add evk evd.last_mods
in
let evar_names = EvNames.remove_name_defined evk evd.evar_names in
{ evd with defn_evars; undf_evars; last_mods; evar_names }
let is_restricted_evar evi =
Store.get evi.evar_extra restricted
let restrict evk filter ?candidates ?src evd =
let evk' = new_untyped_evar () in
let evar_info = EvMap.find evk evd.undf_evars in
let evar_info' =
{ evar_info with evar_filter = filter;
evar_candidates = candidates;
evar_source = (match src with None -> evar_info.evar_source | Some src -> src) } in
let last_mods = match evd.conv_pbs with
| [] -> evd.last_mods
| _ -> Evar.Set.add evk evd.last_mods in
let evar_names = EvNames.reassign_name_defined evk evk' evd.evar_names in
let ctxt = Filter.filter_list filter (evar_context evar_info) in
let id_inst = Array.map_of_list (NamedDecl.get_id %> mkVar) ctxt in
let body = mkEvar(evk',id_inst) in
let (defn_evars, undf_evars) = define_aux ~dorestrict:evk' evd.defn_evars evd.undf_evars evk body in
{ evd with undf_evars = EvMap.add evk' evar_info' undf_evars;
defn_evars; last_mods; evar_names }, evk'
let downcast evk ccl evd =
let evar_info = EvMap.find evk evd.undf_evars in
let evar_info' = { evar_info with evar_concl = ccl } in
{ evd with undf_evars = EvMap.add evk evar_info' evd.undf_evars }
(* 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 = Evar.Set.empty},
pbs
let extract_changed_conv_pbs evd p =
extract_conv_pbs evd (fun pb -> p evd.last_mods pb)
let extract_all_conv_pbs evd =
extract_conv_pbs evd (fun _ -> true)
let loc_of_conv_pb evd (pbty,env,t1,t2) =
match kind_of_term (fst (decompose_app t1)) with
| Evar (evk1,_) -> fst (evar_source evk1 evd)
| _ ->
match kind_of_term (fst (decompose_app t2)) with
| Evar (evk2,_) -> fst (evar_source evk2 evd)
| _ -> None
(** The following functions return the set of evars immediately
contained in the object *)
(* excluding defined evars *)
let evars_of_term c =
let rec evrec acc c =
match kind_of_term c with
| Evar (n, l) -> Evar.Set.add n (Array.fold_left evrec acc l)
| _ -> Term.fold_constr evrec acc c
in
evrec Evar.Set.empty c
let evars_of_named_context nc =
Context.Named.fold_outside
(NamedDecl.fold_constr (fun constr s -> Evar.Set.union s (evars_of_term constr)))
nc
~init:Evar.Set.empty
let evars_of_filtered_evar_info evi =
Evar.Set.union (evars_of_term evi.evar_concl)
(Evar.Set.union
(match evi.evar_body with
| Evar_empty -> Evar.Set.empty
| Evar_defined b -> evars_of_term b)
(evars_of_named_context (evar_filtered_context evi)))
(**********************************************************)
(* Sort variables *)
type rigid = UState.rigid =
| UnivRigid
| UnivFlexible of bool (** Is substitution by an algebraic ok? *)
let univ_rigid = UnivRigid
let univ_flexible = UnivFlexible false
let univ_flexible_alg = UnivFlexible true
let evar_universe_context d = d.universes
let universe_context_set d = UState.context_set d.universes
let universe_context ~names ~extensible evd =
UState.universe_context ~names ~extensible evd.universes
let check_univ_decl evd decl = UState.check_univ_decl evd.universes decl
let restrict_universe_context evd vars =
{ evd with universes = UState.restrict evd.universes vars }
let universe_subst evd =
UState.subst evd.universes
let merge_context_set ?loc ?(sideff=false) rigid evd ctx' =
{evd with universes = UState.merge ?loc sideff rigid evd.universes ctx'}
let merge_universe_subst evd subst =
{evd with universes = UState.merge_subst evd.universes subst }
let with_context_set ?loc rigid d (a, ctx) =
(merge_context_set ?loc rigid d ctx, a)
let new_univ_level_variable ?loc ?name rigid evd =
let uctx', u = UState.new_univ_variable ?loc rigid name evd.universes in
({evd with universes = uctx'}, u)
let new_univ_variable ?loc ?name rigid evd =
let uctx', u = UState.new_univ_variable ?loc rigid name evd.universes in
({evd with universes = uctx'}, Univ.Universe.make u)
let new_sort_variable ?loc ?name rigid d =
let (d', u) = new_univ_variable ?loc rigid ?name d in
(d', Type u)
let add_global_univ d u =
{ d with universes = UState.add_global_univ d.universes u }
let make_flexible_variable evd ~algebraic u =
{ evd with universes =
UState.make_flexible_variable evd.universes ~algebraic u }
let make_evar_universe_context e l =
let uctx = UState.make (Environ.universes e) in
match l with
| None -> uctx
| Some us ->
List.fold_left
(fun uctx (loc,id) ->
fst (UState.new_univ_variable ?loc univ_rigid (Some (Id.to_string id)) uctx))
uctx us
(****************************************)
(* Operations on constants *)
(****************************************)
let fresh_sort_in_family ?loc ?(rigid=univ_flexible) env evd s =
with_context_set ?loc rigid evd (Universes.fresh_sort_in_family env s)
let fresh_constant_instance ?loc env evd c =
with_context_set ?loc univ_flexible evd (Universes.fresh_constant_instance env c)
let fresh_inductive_instance ?loc env evd i =
with_context_set ?loc univ_flexible evd (Universes.fresh_inductive_instance env i)
let fresh_constructor_instance ?loc env evd c =
with_context_set ?loc univ_flexible evd (Universes.fresh_constructor_instance env c)
let fresh_global ?loc ?(rigid=univ_flexible) ?names env evd gr =
with_context_set ?loc rigid evd (Universes.fresh_global_instance ?names env gr)
let whd_sort_variable evd t = t
let is_sort_variable evd s = UState.is_sort_variable evd.universes s
let is_flexible_level evd l =
let uctx = evd.universes in
Univ.LMap.mem l (UState.subst uctx)
let is_eq_sort s1 s2 =
if Sorts.equal s1 s2 then None
else
let u1 = univ_of_sort s1
and u2 = univ_of_sort s2 in
if Univ.Universe.equal u1 u2 then None
else Some (u1, u2)
(* Precondition: l is not defined in the substitution *)
let universe_rigidity evd l =
let uctx = evd.universes in
if Univ.LSet.mem l (Univ.ContextSet.levels (UState.context_set uctx)) then
UnivFlexible (Univ.LSet.mem l (UState.algebraics uctx))
else UnivRigid
let normalize_universe evd =
let vars = ref (UState.subst evd.universes) in
let normalize = Universes.normalize_universe_opt_subst vars in
normalize
let normalize_universe_instance evd l =
let vars = ref (UState.subst evd.universes) in
let normalize = Univ.level_subst_of (Universes.normalize_univ_variable_opt_subst vars) in
Univ.Instance.subst_fn normalize l
let normalize_sort evars s =
match s with
| Prop _ -> s
| Type u ->
let u' = normalize_universe evars u in
if u' == u then s else Type u'
(* FIXME inefficient *)
let set_eq_sort env d s1 s2 =
let s1 = normalize_sort d s1 and s2 = normalize_sort d s2 in
match is_eq_sort s1 s2 with
| None -> d
| Some (u1, u2) ->
if not (type_in_type env) then
add_universe_constraints d
(Universes.Constraints.singleton (u1,Universes.UEq,u2))
else
d
let has_lub evd u1 u2 =
if Univ.Universe.equal u1 u2 then evd
else add_universe_constraints evd
(Universes.Constraints.singleton (u1,Universes.ULub,u2))
let set_eq_level d u1 u2 =
add_constraints d (Univ.enforce_eq_level u1 u2 Univ.Constraint.empty)
let set_leq_level d u1 u2 =
add_constraints d (Univ.enforce_leq_level u1 u2 Univ.Constraint.empty)
let set_eq_instances ?(flex=false) d u1 u2 =
add_universe_constraints d
(Universes.enforce_eq_instances_univs flex u1 u2 Universes.Constraints.empty)
let set_leq_sort env evd s1 s2 =
let s1 = normalize_sort evd s1
and s2 = normalize_sort evd s2 in
match is_eq_sort s1 s2 with
| None -> evd
| Some (u1, u2) ->
if not (type_in_type env) then
add_universe_constraints evd (Universes.Constraints.singleton (u1,Universes.ULe,u2))
else evd
let check_eq evd s s' =
UGraph.check_eq (UState.ugraph evd.universes) s s'
let check_leq evd s s' =
UGraph.check_leq (UState.ugraph evd.universes) s s'
let normalize_evar_universe_context_variables = UState.normalize_variables
let abstract_undefined_variables = UState.abstract_undefined_variables
let fix_undefined_variables evd =
{ evd with universes = UState.fix_undefined_variables evd.universes }
let refresh_undefined_universes evd =
let uctx', subst = UState.refresh_undefined_univ_variables evd.universes in
let evd' = cmap (subst_univs_level_constr subst) {evd with universes = uctx'} in
evd', subst
let normalize_evar_universe_context = UState.normalize
let nf_univ_variables evd =
let subst, uctx' = normalize_evar_universe_context_variables evd.universes in
let evd' = {evd with universes = uctx'} in
evd', subst
let nf_constraints evd =
let subst, uctx' = normalize_evar_universe_context_variables evd.universes in
let uctx' = normalize_evar_universe_context uctx' in
{evd with universes = uctx'}
let universe_of_name evd s = UState.universe_of_name evd.universes s
let add_universe_name evd s l =
{ evd with universes = UState.add_universe_name evd.universes s l }
let universes evd = UState.ugraph evd.universes
let update_sigma_env evd env =
{ evd with universes = UState.update_sigma_env evd.universes env }
exception UniversesDiffer = UState.UniversesDiffer
(**********************************************************)
(* Side effects *)
let emit_side_effects eff evd =
{ evd with effects = Safe_typing.concat_private eff evd.effects;
universes = UState.emit_side_effects eff evd.universes }
let drop_side_effects evd =
{ evd with effects = Safe_typing.empty_private_constants; }
let eval_side_effects evd = evd.effects
(* Future goals *)
let declare_future_goal evk evd =
{ evd with future_goals = evk::evd.future_goals }
let declare_principal_goal evk evd =
match evd.principal_future_goal with
| None -> { evd with
future_goals = evk::evd.future_goals;
principal_future_goal=Some evk; }
| Some _ -> CErrors.user_err Pp.(str "Only one main subgoal per instantiation.")
let future_goals evd = evd.future_goals
let principal_future_goal evd = evd.principal_future_goal
let reset_future_goals evd =
{ evd with future_goals = [] ; principal_future_goal=None }
let restore_future_goals evd gls pgl =
{ evd with future_goals = gls ; principal_future_goal = pgl }
(**********************************************************)
(* Accessing metas *)
(** We use this function to overcome OCaml compiler limitations and to prevent
the use of costly in-place modifications. *)
let set_metas evd metas = {
defn_evars = evd.defn_evars;
undf_evars = evd.undf_evars;
universes = evd.universes;
conv_pbs = evd.conv_pbs;
last_mods = evd.last_mods;
metas;
effects = evd.effects;
evar_names = evd.evar_names;
future_goals = evd.future_goals;
principal_future_goal = evd.principal_future_goal;
extras = evd.extras;
}
let meta_list evd = metamap_to_list evd.metas
let undefined_metas evd =
let filter = function
| (n,Clval(_,_,typ)) -> None
| (n,Cltyp (_,typ)) -> Some n
in
let m = List.map_filter filter (meta_list evd) in
List.sort Int.compare m
let map_metas_fvalue f evd =
let map = function
| Clval(id,(c,s),typ) -> Clval(id,(mk_freelisted (f c.rebus),s),typ)
| x -> x
in
set_metas evd (Metamap.smartmap map evd.metas)
let map_metas f evd =
let map cl = map_clb f cl in
set_metas evd (Metamap.smartmap map 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 ~label:"meta_fvalue" (Pp.str "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 =
let metas = Metamap.add mv (Cltyp(name,mk_freelisted v)) evd.metas in
set_metas evd metas
let meta_assign mv (v, pb) evd =
let modify _ = function
| Cltyp (na, ty) -> Clval (na, (mk_freelisted v, pb), ty)
| _ -> anomaly ~label:"meta_assign" (Pp.str "already defined.")
in
let metas = Metamap.modify mv modify evd.metas in
set_metas evd metas
let meta_reassign mv (v, pb) evd =
let modify _ = function
| Clval(na, _, ty) -> Clval (na, (mk_freelisted v, pb), ty)
| _ -> anomaly ~label:"meta_reassign" (Pp.str "not yet defined.")
in
let metas = Metamap.modify mv modify evd.metas in
set_metas evd metas
(* 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 clear_metas evd = {evd with metas = Metamap.empty}
let meta_merge ?(with_univs = true) evd1 evd2 =
let metas = Metamap.fold Metamap.add evd1.metas evd2.metas in
let universes =
if with_univs then union_evar_universe_context evd2.universes evd1.universes
else evd2.universes
in
{evd2 with universes; metas; }
type metabinding = metavariable * constr * instance_status
let retract_coercible_metas evd =
let mc = ref [] in
let map n v = match v with
| Clval (na, (b, (Conv, CoerceToType as s)), typ) ->
let () = mc := (n, b.rebus, s) :: !mc in
Cltyp (na, typ)
| v -> v
in
let metas = Metamap.smartmapi map evd.metas in
!mc, set_metas evd metas
let evar_source_of_meta mv evd =
match meta_name evd mv with
| Anonymous -> Loc.tag Evar_kinds.GoalEvar
| Name id -> Loc.tag @@ Evar_kinds.VarInstance id
let dependent_evar_ident ev evd =
let evi = find evd ev in
match evi.evar_source with
| (_,Evar_kinds.VarInstance id) -> id
| _ -> anomaly (str "Not an evar resulting of a dependent binding.")
(**********************************************************)
(* Extra data *)
let get_extra_data evd = evd.extras
let set_extra_data extras evd = { evd with extras }
(*******************************************************************)
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
let on_sig s f =
let sigma', v = f s.sigma in
{ s with sigma = sigma' }, v
(*******************************************************************)
(* The state monad with state an evar map. *)
module MonadR =
Monad.Make (struct
type +'a t = evar_map -> evar_map * 'a
let return a = fun s -> (s,a)
let (>>=) x f = fun s ->
let (s',a) = x s in
f a s'
let (>>) x y = fun s ->
let (s',()) = x s in
y s'
let map f x = fun s ->
on_snd f (x s)
end)
module Monad =
Monad.Make (struct
type +'a t = evar_map -> 'a * evar_map
let return a = fun s -> (a,s)
let (>>=) x f = fun s ->
let (a,s') = x s in
f a s'
let (>>) x y = fun s ->
let ((),s') = x s in
y s'
let map f x = fun s ->
on_fst f (x s)
end)
(**********************************************************)
(* Failure explanation *)
type unsolvability_explanation = SeveralInstancesFound of int
|