Source file uState.ml
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open CErrors
open Util
open Names
open Univ
open Sorts
open UVars
module UnivFlex = UnivFlex
type universes_entry =
| Monomorphic_entry of Univ.ContextSet.t
| Polymorphic_entry of UVars.UContext.t
module UNameMap = Id.Map
type uinfo = {
uname : Id.t option;
uloc : Loc.t option;
}
open Quality
let sort_inconsistency ?explain cst l r =
let explain = Option.map (fun p -> UGraph.Other p) explain in
raise (UGraph.UniverseInconsistency (None, (cst, l, r, explain)))
module QState : sig
type t
type elt = QVar.t
val empty : t
val union : fail:(t -> Quality.t -> Quality.t -> t) -> t -> t -> t
val add : check_fresh:bool -> named:bool -> elt -> t -> t
val repr : elt -> t -> Quality.t
val unify_quality : fail:(unit -> t) -> Conversion.conv_pb -> Quality.t -> Quality.t -> t -> t
val is_above_prop : elt -> t -> bool
val undefined : t -> QVar.Set.t
val collapse : t -> t
val pr : (QVar.t -> Pp.t) -> t -> Pp.t
val of_set : QVar.Set.t -> t
end =
struct
module QSet = QVar.Set
module QMap = QVar.Map
type t = {
named : QSet.t;
(** Named variables, may not be set to another *)
qmap : Quality.t option QMap.t;
above : QSet.t;
(** Set of quality variables known to be either in Prop or Type.
If q ∈ above then it must map to None in qmap. *)
}
type elt = QVar.t
let empty = { named = QSet.empty; qmap = QMap.empty; above = QSet.empty }
let rec repr q m = match QMap.find q m.qmap with
| None -> QVar q
| Some (QVar q) -> repr q m
| Some (QConstant _ as q) -> q
| exception Not_found ->
QVar q
let is_above_prop q m = QSet.mem q m.above
let set q qv m =
let q = repr q m in
let q = match q with QVar q -> q | QConstant _ -> assert false in
let qv = match qv with QVar qv -> repr qv m | (QConstant _ as qv) -> qv in
match q, qv with
| q, QVar qv ->
if QVar.equal q qv then Some m
else
if QSet.mem q m.named then None
else
let above =
if QSet.mem q m.above then QSet.add qv (QSet.remove q m.above)
else m.above
in
Some { named = m.named; qmap = QMap.add q (Some (QVar qv)) m.qmap; above }
| q, (QConstant qc as qv) ->
if qc == QSProp && QSet.mem q m.above then None
else if QSet.mem q m.named then None
else
Some { named = m.named; qmap = QMap.add q (Some qv) m.qmap; above = QSet.remove q m.above }
let set_above_prop q m =
let q = repr q m in
let q = match q with QVar q -> q | QConstant _ -> assert false in
if QSet.mem q m.named then None
else Some { named = m.named; qmap = m.qmap; above = QSet.add q m.above }
let unify_quality ~fail c q1 q2 local = match q1, q2 with
| QConstant QType, QConstant QType
| QConstant QProp, QConstant QProp
| QConstant QSProp, QConstant QSProp -> local
| QConstant QProp, QVar q when c == Conversion.CUMUL ->
begin match set_above_prop q local with
| Some local -> local
| None -> fail ()
end
| QVar qv1, QVar qv2 -> begin match set qv1 q2 local with
| Some local -> local
| None -> match set qv2 q1 local with
| Some local -> local
| None -> fail ()
end
| QVar q, (QConstant (QType | QProp | QSProp) as qv)
| (QConstant (QType | QProp | QSProp) as qv), QVar q ->
begin match set q qv local with
| Some local -> local
| None -> fail ()
end
| (QConstant QType, QConstant (QProp | QSProp)) -> fail ()
| (QConstant QProp, QConstant QType) ->
begin match c with
| CONV -> fail ()
| CUMUL -> local
end
| (QConstant QSProp, QConstant (QType | QProp)) -> fail ()
| (QConstant QProp, QConstant QSProp) -> fail ()
let nf_quality m = function
| QConstant _ as q -> q
| QVar q -> repr q m
let union ~fail s1 s2 =
let = ref [] in
let qmap = QMap.union (fun qk q1 q2 ->
match q1, q2 with
| Some q, None | None, Some q -> Some (Some q)
| None, None -> Some None
| Some q1, Some q2 ->
let () = if not (Quality.equal q1 q2) then extra := (q1,q2) :: !extra in
Some (Some q1))
s1.qmap s2.qmap
in
let = !extra in
let filter q = match QMap.find q qmap with
| None -> true
| Some _ -> false
| exception Not_found -> false
in
let above = QSet.filter filter @@ QSet.union s1.above s2.above in
let s = { named = QSet.union s1.named s2.named; qmap; above } in
List.fold_left (fun s (q1,q2) ->
let q1 = nf_quality s q1 and q2 = nf_quality s q2 in
unify_quality ~fail:(fun () -> fail s q1 q2) CONV q1 q2 s)
s
extra
let add ~check_fresh ~named q m =
if check_fresh then assert (not (QMap.mem q m.qmap));
{ named = if named then QSet.add q m.named else m.named;
qmap = QMap.add q None m.qmap;
above = m.above }
let of_set qs =
{ named = QSet.empty; qmap = QMap.bind (fun _ -> None) qs; above = QSet.empty }
let undefined m =
let m = QMap.filter (fun _ v -> Option.is_empty v) m.qmap in
QMap.domain m
let collapse m =
let map q v = match v with
| None -> if QSet.mem q m.named then None else Some (QConstant QType)
| Some _ -> v
in
{ named = m.named; qmap = QMap.mapi map m.qmap; above = QSet.empty }
let pr prqvar { qmap; above; named } =
let open Pp in
let prbody u = function
| None ->
if QSet.mem u above then str " >= Prop"
else if QSet.mem u named then
str " (internal name " ++ QVar.raw_pr u ++ str ")"
else mt ()
| Some q ->
let q = Quality.pr prqvar q in
str " := " ++ q
in
h (prlist_with_sep fnl (fun (u, v) -> prqvar u ++ prbody u v) (QMap.bindings qmap))
end
module UPairSet = UnivMinim.UPairSet
type univ_names = UnivNames.universe_binders * (uinfo QVar.Map.t * uinfo Level.Map.t)
type t =
{ names : univ_names; (** Printing/location information *)
local : ContextSet.t; (** The local graph of universes (variables and constraints) *)
seff_univs : Level.Set.t; (** Local universes used through private constants *)
univ_variables : UnivFlex.t;
(** The local universes that are unification variables *)
sort_variables : QState.t;
(** Local quality variables. *)
universes : UGraph.t; (** The current graph extended with the local constraints *)
initial_universes : UGraph.t; (** The graph at the creation of the evar_map *)
minim_extra : UnivMinim.extra;
}
let empty =
{ names = UnivNames.empty_binders, (QVar.Map.empty, Level.Map.empty);
local = ContextSet.empty;
seff_univs = Level.Set.empty;
univ_variables = UnivFlex.empty;
sort_variables = QState.empty;
universes = UGraph.initial_universes;
initial_universes = UGraph.initial_universes;
minim_extra = UnivMinim.empty_extra; }
let make ~lbound univs =
{ empty with
universes = univs;
initial_universes = univs }
let is_empty uctx =
ContextSet.is_empty uctx.local &&
UnivFlex.is_empty uctx.univ_variables
let id_of_level uctx l =
try (Level.Map.find l (snd (snd uctx.names))).uname
with Not_found -> None
let id_of_qvar uctx l =
try (QVar.Map.find l (fst (snd uctx.names))).uname
with Not_found -> None
let qualid_of_qvar_names (bind, (qrev,_)) l =
try Some (Libnames.qualid_of_ident (Option.get (QVar.Map.find l qrev).uname))
with Not_found | Option.IsNone ->
None
let qualid_of_level_names (bind, (_,urev)) l =
try Some (Libnames.qualid_of_ident (Option.get (Level.Map.find l urev).uname))
with Not_found | Option.IsNone ->
UnivNames.qualid_of_level bind l
let qualid_of_level uctx l = qualid_of_level_names uctx.names l
let pr_uctx_qvar_names names l =
match qualid_of_qvar_names names l with
| Some qid -> Libnames.pr_qualid qid
| None -> QVar.raw_pr l
let pr_uctx_level_names names l =
match qualid_of_level_names names l with
| Some qid -> Libnames.pr_qualid qid
| None -> Level.raw_pr l
let pr_uctx_level uctx l = pr_uctx_level_names uctx.names l
let pr_uctx_qvar uctx l = pr_uctx_qvar_names uctx.names l
let merge_constraints uctx cstrs g =
try UGraph.merge_constraints cstrs g
with UGraph.UniverseInconsistency (_, i) ->
let printers = (pr_uctx_qvar uctx, pr_uctx_level uctx) in
raise (UGraph.UniverseInconsistency (Some printers, i))
let uname_union s t =
if s == t then s
else
UNameMap.merge (fun k l r ->
match l, r with
| Some _, _ -> l
| _, _ -> r) s t
let names_union ((qbind,ubind),(qrev,urev)) ((qbind',ubind'),(qrev',urev')) =
let qbind = uname_union qbind qbind'
and ubind = uname_union ubind ubind'
and qrev = QVar.Map.union (fun _ l _ -> Some l) qrev qrev'
and urev = Level.Map.lunion urev urev' in
((qbind,ubind),(qrev,urev))
let union uctx uctx' =
if uctx == uctx' then uctx
else if is_empty uctx' then uctx
else
let local = ContextSet.union uctx.local uctx'.local in
let seff = Level.Set.union uctx.seff_univs uctx'.seff_univs in
let names = names_union uctx.names uctx'.names in
let newus = Level.Set.diff (ContextSet.levels uctx'.local)
(ContextSet.levels uctx.local) in
let newus = Level.Set.diff newus (UnivFlex.domain uctx.univ_variables) in
let = UnivMinim.extra_union uctx.minim_extra uctx'.minim_extra in
let declarenew g =
Level.Set.fold (fun u g -> UGraph.add_universe u ~lbound:UGraph.Bound.Set ~strict:false g) newus g
in
let fail_union s q1 q2 =
if UGraph.type_in_type uctx.universes then s
else CErrors.user_err
Pp.(str "Could not merge universe contexts: could not unify" ++ spc() ++
Quality.raw_pr q1 ++ strbrk " and " ++ Quality.raw_pr q2 ++ str ".")
in
{ names;
local = local;
seff_univs = seff;
univ_variables =
UnivFlex.biased_union uctx.univ_variables uctx'.univ_variables;
sort_variables = QState.union ~fail:fail_union uctx.sort_variables uctx'.sort_variables;
initial_universes = declarenew uctx.initial_universes;
universes =
(if local == uctx.local then uctx.universes
else
let cstrsr = ContextSet.constraints uctx'.local in
merge_constraints uctx cstrsr (declarenew uctx.universes));
minim_extra = extra}
let context_set uctx = uctx.local
let sort_context_set uctx =
let us, csts = uctx.local in
(QState.undefined uctx.sort_variables, us), csts
let constraints uctx = snd uctx.local
let compute_instance_binders (qrev,urev) inst =
let qinst, uinst = Instance.to_array inst in
let qmap = function
| QVar q ->
begin try Name (Option.get (QVar.Map.find q qrev).uname)
with Option.IsNone | Not_found -> Anonymous
end
| QConstant _ -> assert false
in
let umap lvl =
try Name (Option.get (Level.Map.find lvl urev).uname)
with Option.IsNone | Not_found -> Anonymous
in
Array.map qmap qinst, Array.map umap uinst
let context uctx =
let qvars = QState.undefined uctx.sort_variables in
UContext.of_context_set (compute_instance_binders (snd uctx.names)) qvars uctx.local
type named_universes_entry = universes_entry * UnivNames.universe_binders
let univ_entry ~poly uctx =
let (binders, _) = uctx.names in
let entry =
if poly then Polymorphic_entry (context uctx)
else Monomorphic_entry (context_set uctx) in
entry, binders
let of_context_set ((qs,us),csts) =
let sort_variables = QState.of_set qs in
{ empty with
local = (us,csts);
sort_variables;}
type universe_opt_subst = UnivFlex.t
let subst uctx = uctx.univ_variables
let ugraph uctx = uctx.universes
let initial_graph uctx = uctx.initial_universes
let is_algebraic l uctx = UnivFlex.is_algebraic l uctx.univ_variables
let of_names (ubind,(revqbind,revubind)) =
let revqbind = QVar.Map.map (fun id -> { uname = Some id; uloc = None }) revqbind in
let revubind = Level.Map.map (fun id -> { uname = Some id; uloc = None }) revubind in
{empty with names = (ubind,(revqbind,revubind))}
let universe_of_name uctx s =
UNameMap.find s (snd (fst uctx.names))
let quality_of_name uctx s =
Id.Map.find s (fst (fst uctx.names))
let name_level level id uctx =
let ((qbind,ubind),(qrev,urev)) = uctx.names in
assert(not(Id.Map.mem id ubind));
let ubind = Id.Map.add id level ubind in
let urev = Level.Map.add level { uname = Some id; uloc = None } urev in
{ uctx with names = ((qbind,ubind),(qrev,urev)) }
let universe_binders uctx =
let named, _ = uctx.names in
named
let nf_qvar uctx q = QState.repr q uctx.sort_variables
let instantiate_variable l (b : Universe.t) v =
v := UnivFlex.define l b !v
exception UniversesDiffer
let { Goptions.get = weak_constraints } =
Goptions.declare_bool_option_and_ref
~key:["Cumulativity";"Weak";"Constraints"]
~value:true
()
let level_inconsistency cst l r =
let mk u = Sorts.sort_of_univ @@ Universe.make u in
raise (UGraph.UniverseInconsistency (None, (cst, mk l, mk r, None)))
let nf_universe uctx u =
UnivSubst.(subst_univs_universe (UnivFlex.normalize_univ_variable uctx.univ_variables)) u
let nf_level uctx u =
UnivSubst.(level_subst_of (UnivFlex.normalize_univ_variable uctx.univ_variables)) u
let nf_instance uctx u = Instance.subst_fn (nf_qvar uctx, nf_level uctx) u
let nf_quality uctx q = Quality.subst (nf_qvar uctx) q
let nf_sort uctx s =
let normalize u = nf_universe uctx u in
let qnormalize q = QState.repr q uctx.sort_variables in
Sorts.subst_fn (qnormalize, normalize) s
let nf_relevance uctx r = match r with
| Relevant | Irrelevant -> r
| RelevanceVar q ->
match nf_qvar uctx q with
| QConstant QSProp -> Sorts.Irrelevant
| QConstant QProp | QConstant QType -> Sorts.Relevant
| QVar q' ->
if QState.is_above_prop q' uctx.sort_variables then Relevant
else if QVar.equal q q' then r
else Sorts.RelevanceVar q'
let nf_universes uctx c =
let lsubst = uctx.univ_variables in
let nf_univ u = UnivFlex.normalize_univ_variable lsubst u in
let rec self () c = match Constr.kind c with
| Evar (evk, args) ->
let args' = SList.Smart.map (self ()) args in
if args == args' then c else Constr.mkEvar (evk, args')
| _ -> UnivSubst.map_universes_opt_subst_with_binders ignore self (nf_qvar uctx) nf_univ () c
in
self () c
type small_universe = USet | UProp | USProp
let is_uset = function USet -> true | UProp | USProp -> false
type sort_classification =
| USmall of small_universe
| ULevel of Level.t
| UMax of Universe.t * Level.Set.t
| UAlgebraic of Universe.t
let classify s = match s with
| Prop -> USmall UProp
| SProp -> USmall USProp
| Set -> USmall USet
| Type u | QSort (_, u) ->
if Universe.is_levels u then match Universe.level u with
| None -> UMax (u, Universe.levels u)
| Some u -> ULevel u
else UAlgebraic u
type local = {
local_cst : Constraints.t;
local_above_prop : Level.Set.t;
local_weak : UPairSet.t;
local_sorts : QState.t;
}
let add_local cst local =
{ local with local_cst = Constraints.add cst local.local_cst }
let enforce_leq_up u v local =
{ local with local_cst = UnivSubst.enforce_leq u (Universe.make v) local.local_cst }
let get_constraint = function
| Conversion.CONV -> Eq
| Conversion.CUMUL -> Le
let unify_quality univs c s1 s2 l =
let fail () = if UGraph.type_in_type univs then l.local_sorts
else sort_inconsistency (get_constraint c) s1 s2
in
{ l with
local_sorts = QState.unify_quality ~fail
c (Sorts.quality s1) (Sorts.quality s2) l.local_sorts;
}
let process_universe_constraints uctx cstrs =
let open UnivSubst in
let open UnivProblem in
let univs = uctx.universes in
let vars = ref uctx.univ_variables in
let normalize u = UnivFlex.normalize_univ_variable !vars u in
let qnormalize sorts q = QState.repr q sorts in
let normalize_sort sorts s =
Sorts.subst_fn ((qnormalize sorts), subst_univs_universe normalize) s
in
let nf_constraint sorts = function
| QLeq (a, b) -> QLeq (Quality.subst (qnormalize sorts) a, Quality.subst (qnormalize sorts) b)
| QEq (a, b) -> QEq (Quality.subst (qnormalize sorts) a, Quality.subst (qnormalize sorts) b)
| ULub (u, v) -> ULub (level_subst_of normalize u, level_subst_of normalize v)
| UWeak (u, v) -> UWeak (level_subst_of normalize u, level_subst_of normalize v)
| UEq (u, v) -> UEq (normalize_sort sorts u, normalize_sort sorts v)
| ULe (u, v) -> ULe (normalize_sort sorts u, normalize_sort sorts v)
in
let is_local l = UnivFlex.mem l !vars in
let equalize_small l s local =
let ls = match l with
| USProp -> sprop
| UProp -> prop
| USet -> set
in
if UGraph.check_eq_sort univs ls s then local
else if is_uset l then match classify s with
| USmall _ -> sort_inconsistency Eq set s
| ULevel r ->
if is_local r then
let () = instantiate_variable r Universe.type0 vars in
add_local (Level.set, Eq, r) local
else
sort_inconsistency Eq set s
| UMax (u, _)| UAlgebraic u ->
if univ_level_mem Level.set u then
let inst = univ_level_rem Level.set u u in
enforce_leq_up inst Level.set local
else
sort_inconsistency Eq ls s
else sort_inconsistency Eq ls s
in
let equalize_variables fo l' r' local =
if Level.equal l' r' then local
else
let () =
if is_local l' then
instantiate_variable l' (Universe.make r') vars
else if is_local r' then
instantiate_variable r' (Universe.make l') vars
else if not (UnivProblem.check_eq_level univs l' r') then
if Level.is_set l' || Level.is_set r' then
level_inconsistency Eq l' r'
else if fo then
raise UniversesDiffer
in
add_local (l', Eq, r') local
in
let equalize_algebraic l ru local =
let alg = UnivFlex.is_algebraic l uctx.univ_variables in
let inst = univ_level_rem l ru ru in
if alg && not (Level.Set.mem l (Universe.levels inst)) then
let () = instantiate_variable l inst vars in
local
else
if univ_level_mem l ru then
enforce_leq_up inst l local
else sort_inconsistency Eq (sort_of_univ (Universe.make l)) (sort_of_univ ru)
in
let equalize_universes l r local = match classify l, classify r with
| USmall l', (USmall _ | ULevel _ | UMax _ | UAlgebraic _) ->
equalize_small l' r local
| (ULevel _ | UMax _ | UAlgebraic _), USmall r' ->
equalize_small r' l local
| ULevel l', ULevel r' ->
equalize_variables false l' r' local
| ULevel l', (UAlgebraic r | UMax (r, _)) | (UAlgebraic r | UMax (r, _)), ULevel l' ->
equalize_algebraic l' r local
| (UAlgebraic _ | UMax _), (UAlgebraic _ | UMax _) ->
if UGraph.check_eq_sort univs l r then local
else sort_inconsistency Eq l r
in
let unify_universes cst local =
let cst = nf_constraint local.local_sorts cst in
if UnivProblem.is_trivial cst then local
else match cst with
| QEq (a, b) ->
let mk q = Sorts.make q Universe.type0 in
unify_quality univs CONV (mk a) (mk b) local
| QLeq (a, b) ->
let mk q = Sorts.make q Universe.type0 in
unify_quality univs CUMUL (mk a) (mk b) local
| ULe (l, r) ->
let local = unify_quality univs CUMUL l r local in
let l = normalize_sort local.local_sorts l in
let r = normalize_sort local.local_sorts r in
begin match classify r with
| UAlgebraic _ | UMax _ ->
if UGraph.check_leq_sort univs l r then local
else
sort_inconsistency Le l r
~explain:(Pp.str "(cannot handle algebraic on the right)")
| USmall r' ->
if UGraph.type_in_type univs then local
else begin match classify l with
| UAlgebraic _ ->
sort_inconsistency Le l r
| USmall l' ->
if UGraph.check_leq_sort univs l r then local
else sort_inconsistency Le l r
| ULevel l' ->
if is_uset r' && is_local l' then
let () = instantiate_variable l' Universe.type0 vars in
add_local (l', Eq, Level.set) local
else
sort_inconsistency Le l r
| UMax (_, levels) ->
if is_uset r' then
let fold l' local =
let l = sort_of_univ @@ Universe.make l' in
if Level.is_set l' || is_local l' then
equalize_variables false l' Level.set local
else sort_inconsistency Le l r
in
Level.Set.fold fold levels local
else
sort_inconsistency Le l r
end
| ULevel r' ->
match classify l with
| USmall UProp ->
{ local with local_above_prop = Level.Set.add r' local.local_above_prop }
| USmall USProp ->
if UGraph.type_in_type univs then local
else sort_inconsistency Le l r
| USmall USet ->
add_local (Level.set, Le, r') local
| ULevel l' ->
add_local (l', Le, r') local
| UAlgebraic l ->
enforce_leq_up l r' local
| UMax (_, l) ->
Univ.Level.Set.fold (fun l' accu -> add_local (l', Le, r') accu) l local
end
| ULub (l, r) ->
equalize_variables true l r local
| UWeak (l, r) ->
if weak_constraints ()
then { local with local_weak = UPairSet.add (l, r) local.local_weak }
else local
| UEq (l, r) ->
let local = unify_quality univs CONV l r local in
let l = normalize_sort local.local_sorts l in
let r = normalize_sort local.local_sorts r in
equalize_universes l r local
in
let unify_universes cst local =
if not (UGraph.type_in_type univs) then unify_universes cst local
else try unify_universes cst local with UGraph.UniverseInconsistency _ -> local
in
let local = {
local_cst = Constraints.empty;
local_weak = uctx.minim_extra.UnivMinim.weak_constraints;
local_above_prop = uctx.minim_extra.UnivMinim.above_prop;
local_sorts = uctx.sort_variables;
} in
let local = UnivProblem.Set.fold unify_universes cstrs local in
let = { UnivMinim.above_prop = local.local_above_prop; UnivMinim.weak_constraints = local.local_weak } in
!vars, extra, local.local_cst, local.local_sorts
let add_universe_constraints uctx cstrs =
let univs, local = uctx.local in
let vars, , local', sorts = process_universe_constraints uctx cstrs in
{ uctx with
local = (univs, Constraints.union local local');
univ_variables = vars;
universes = merge_constraints uctx local' uctx.universes;
sort_variables = sorts;
minim_extra = extra; }
let problem_of_constraints cstrs =
Constraints.fold (fun (l,d,r) acc ->
let l = Universe.make l and r = sort_of_univ @@ Universe.make r in
let cstr' = let open UnivProblem in
match d with
| Lt ->
ULe (sort_of_univ @@ Universe.super l, r)
| Le -> ULe (sort_of_univ l, r)
| Eq -> UEq (sort_of_univ l, r)
in UnivProblem.Set.add cstr' acc)
cstrs UnivProblem.Set.empty
let add_constraints uctx cstrs =
let cstrs = problem_of_constraints cstrs in
add_universe_constraints uctx cstrs
let add_quconstraints uctx (qcstrs,ucstrs) =
let cstrs = problem_of_constraints ucstrs in
let cstrs = QConstraints.fold (fun (l,d,r) cstrs ->
match d with
| Equal -> UnivProblem.Set.add (QEq (l,r)) cstrs
| Leq -> UnivProblem.Set.add (QLeq (l,r)) cstrs)
qcstrs cstrs
in
add_universe_constraints uctx cstrs
let check_qconstraints uctx csts =
Sorts.QConstraints.for_all (fun (l,k,r) ->
let l = nf_quality uctx l in
let r = nf_quality uctx r in
if Quality.equal l r then true
else match l,k,r with
| _, Equal, _ -> false
| QConstant QProp, Leq, QConstant QType -> true
| QConstant QProp, Leq, QVar q -> QState.is_above_prop q uctx.sort_variables
| _, Leq, _ -> false)
csts
let check_universe_constraint uctx (c:UnivProblem.t) =
match c with
| QEq (a,b) ->
let a = nf_quality uctx a in
let b = nf_quality uctx b in
Quality.equal a b
| QLeq (a,b) ->
let a = nf_quality uctx a in
let b = nf_quality uctx b in
if Quality.equal a b then true
else begin match a, b with
| QConstant QProp, QConstant QType -> true
| QConstant QProp, QVar q -> QState.is_above_prop q uctx.sort_variables
| _ -> false
end
| ULe (u,v) -> UGraph.check_leq_sort uctx.universes u v
| UEq (u,v) -> UGraph.check_eq_sort uctx.universes u v
| ULub (u,v) -> UGraph.check_eq_level uctx.universes u v
| UWeak _ -> true
let check_universe_constraints uctx csts =
UnivProblem.Set.for_all (check_universe_constraint uctx) csts
let constrain_variables diff uctx =
let local, vars = UnivFlex.constrain_variables diff uctx.univ_variables uctx.local in
{ uctx with local; univ_variables = vars }
type ('a, 'b, 'c) gen_universe_decl = {
univdecl_qualities : 'a;
univdecl_extensible_qualities : bool;
univdecl_instance : 'b;
univdecl_extensible_instance : bool;
univdecl_constraints : 'c;
univdecl_extensible_constraints : bool }
type universe_decl =
(QVar.t list, Level.t list, Constraints.t) gen_universe_decl
let default_univ_decl =
{ univdecl_qualities = [];
univdecl_extensible_qualities = true;
univdecl_instance = [];
univdecl_extensible_instance = true;
univdecl_constraints = Constraints.empty;
univdecl_extensible_constraints = true }
let pr_error_unbound_universes quals univs names =
let open Pp in
let nqs = QVar.Set.cardinal quals in
let prqvar q =
let info = QVar.Map.find_opt q (fst (snd names)) in
h (pr_uctx_qvar_names names q ++ (match info with
| None | Some {uloc=None} -> mt ()
| Some {uloc=Some loc} -> spc() ++ str"(" ++ Loc.pr loc ++ str")"))
in
let nus = Level.Set.cardinal univs in
let prlev u =
let info = Level.Map.find_opt u (snd (snd names)) in
h (pr_uctx_level_names names u ++ (match info with
| None | Some {uloc=None} -> mt ()
| Some {uloc=Some loc} -> spc() ++ str"(" ++ Loc.pr loc ++ str")"))
in
let ppqs = if nqs > 0 then
str (if nqs = 1 then "Quality" else "Qualities") ++ spc () ++
prlist_with_sep spc prqvar (QVar.Set.elements quals)
else mt()
in
let ppus = if nus > 0 then
let universe_s = CString.plural nus "universe" in
let universe_s = if nqs = 0 then CString.capitalize_ascii universe_s else universe_s in
str universe_s ++ spc () ++
prlist_with_sep spc prlev (Level.Set.elements univs)
else mt()
in
(hv 0
(ppqs ++
(if nqs > 0 && nus > 0 then strbrk " and " else mt()) ++
ppus ++
spc () ++ str (CString.conjugate_verb_to_be (nus + nqs)) ++ str" unbound."))
exception UnboundUnivs of QVar.Set.t * Level.Set.t * univ_names
let error_unbound_universes qs us uctx = raise (UnboundUnivs (qs,us,uctx))
let _ = CErrors.register_handler (function
| UnboundUnivs (qs,us,uctx) -> Some (pr_error_unbound_universes qs us uctx)
| _ -> None)
let universe_context_inst decl qvars levels names =
let leftqs = List.fold_left (fun acc l -> QVar.Set.remove l acc) qvars decl.univdecl_qualities in
let leftus = List.fold_left (fun acc l -> Level.Set.remove l acc) levels decl.univdecl_instance in
let () =
let unboundqs = if decl.univdecl_extensible_qualities then QVar.Set.empty else leftqs in
let unboundus = if decl.univdecl_extensible_instance then Level.Set.empty else leftus in
if not (QVar.Set.is_empty unboundqs && Level.Set.is_empty unboundus)
then error_unbound_universes unboundqs unboundus names
in
let leftqs = UContext.sort_qualities
(Array.map_of_list (fun q -> Quality.QVar q) (QVar.Set.elements leftqs))
in
let leftus = UContext.sort_levels (Array.of_list (Level.Set.elements leftus)) in
let instq = Array.append
(Array.map_of_list (fun q -> Quality.QVar q) decl.univdecl_qualities)
leftqs
in
let instu = Array.append (Array.of_list decl.univdecl_instance) leftus in
let inst = Instance.of_array (instq,instu) in
inst
let check_universe_context_set ~prefix levels names =
let left =
List.fold_left (fun left l -> Level.Set.remove l left)
levels prefix
in
if not (Level.Set.is_empty left)
then error_unbound_universes QVar.Set.empty left names
let check_implication uctx cstrs cstrs' =
let gr = initial_graph uctx in
let grext = merge_constraints uctx cstrs gr in
let cstrs' = Constraints.filter (fun c -> not (UGraph.check_constraint grext c)) cstrs' in
if Constraints.is_empty cstrs' then ()
else CErrors.user_err
Pp.(str "Universe constraints are not implied by the ones declared: " ++
Constraints.pr (pr_uctx_level uctx) cstrs')
let check_mono_univ_decl uctx decl =
let () =
if not (List.is_empty decl.univdecl_qualities)
|| not (QVar.Set.is_empty (QState.undefined uctx.sort_variables))
then CErrors.user_err Pp.(str "Monomorphic declarations may not have sort variables.")
in
let levels, csts = uctx.local in
let () =
let prefix = decl.univdecl_instance in
if not decl.univdecl_extensible_instance
then check_universe_context_set ~prefix levels uctx.names
in
if decl.univdecl_extensible_constraints then uctx.local
else begin
check_implication uctx
decl.univdecl_constraints
csts;
levels, decl.univdecl_constraints
end
let check_poly_univ_decl uctx decl =
let levels, csts = uctx.local in
let qvars = QState.undefined uctx.sort_variables in
let inst = universe_context_inst decl qvars levels uctx.names in
let nas = compute_instance_binders (snd uctx.names) inst in
let csts = if decl.univdecl_extensible_constraints then csts
else begin
check_implication uctx
decl.univdecl_constraints
csts;
decl.univdecl_constraints
end
in
let uctx = UContext.make nas (inst, csts) in
uctx
let check_univ_decl ~poly uctx decl =
let (binders, _) = uctx.names in
let entry =
if poly then Polymorphic_entry (check_poly_univ_decl uctx decl)
else Monomorphic_entry (check_mono_univ_decl uctx decl) in
entry, binders
let is_bound l lbound = match lbound with
| UGraph.Bound.Prop -> false
| UGraph.Bound.Set -> Level.is_set l
let restrict_universe_context ?(lbound = UGraph.Bound.Set) (univs, csts) keep =
let removed = Level.Set.diff univs keep in
if Level.Set.is_empty removed then univs, csts
else
let allunivs = Constraints.fold (fun (u,_,v) all -> Level.Set.add u (Level.Set.add v all)) csts univs in
let g = UGraph.initial_universes in
let g = Level.Set.fold (fun v g -> if Level.is_set v then g else
UGraph.add_universe v ~lbound ~strict:false g) allunivs g in
let g = UGraph.merge_constraints csts g in
let allkept = Level.Set.union (UGraph.domain UGraph.initial_universes) (Level.Set.diff allunivs removed) in
let csts = UGraph.constraints_for ~kept:allkept g in
let csts = Constraints.filter (fun (l,d,r) -> not (is_bound l lbound && d == Le)) csts in
(Level.Set.inter univs keep, csts)
let restrict ?lbound uctx vars =
let vars = Level.Set.union vars uctx.seff_univs in
let vars = Id.Map.fold (fun na l vars -> Level.Set.add l vars)
(snd (fst uctx.names)) vars
in
let uctx' = restrict_universe_context ?lbound uctx.local vars in
{ uctx with local = uctx' }
let restrict_even_binders ?lbound uctx vars =
let vars = Level.Set.union vars uctx.seff_univs in
let uctx' = restrict_universe_context ?lbound uctx.local vars in
{ uctx with local = uctx' }
let restrict_constraints uctx csts =
let levels, _ = uctx.local in
let uctx' = { uctx with local = ContextSet.of_set levels; universes = uctx.initial_universes } in
add_constraints uctx' csts
type 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
(** ~sideff indicates that it is ok to redeclare a universe.
Also merges the universe context in the local constraint structures
and not only in the graph. *)
let merge ?loc ~sideff rigid uctx uctx' =
let levels = ContextSet.levels uctx' in
let local = ContextSet.append uctx' uctx.local in
let declare g =
Level.Set.fold (fun u g ->
try UGraph.add_universe ~lbound:UGraph.Bound.Set ~strict:false u g
with UGraph.AlreadyDeclared when sideff -> g)
levels g
in
let names =
let fold u accu =
let update = function
| None -> Some { uname = None; uloc = loc }
| Some info -> match info.uloc with
| None -> Some { info with uloc = loc }
| Some _ -> Some info
in
Level.Map.update u update accu
in
(fst uctx.names, (fst (snd uctx.names), Level.Set.fold fold levels (snd (snd uctx.names))))
in
let initial = declare uctx.initial_universes in
let univs = declare uctx.universes in
let universes = merge_constraints uctx (ContextSet.constraints uctx') univs in
let uctx =
match rigid with
| UnivRigid -> uctx
| UnivFlexible b ->
assert (not sideff);
let uvars' = UnivFlex.add_levels levels ~algebraic:b uctx.univ_variables in
{ uctx with univ_variables = uvars' }
in
{ uctx with names; local; universes;
initial_universes = initial }
let merge_sort_variables ?loc ~sideff uctx qvars =
let sort_variables =
QVar.Set.fold (fun qv qstate -> QState.add ~check_fresh:(not sideff) ~named:false qv qstate)
qvars
uctx.sort_variables
in
let names =
let fold u accu =
let update = function
| None -> Some { uname = None; uloc = loc }
| Some info -> match info.uloc with
| None -> Some { info with uloc = loc }
| Some _ -> Some info
in
QVar.Map.update u update accu
in
let qrev = QVar.Set.fold fold qvars (fst (snd uctx.names)) in
(fst uctx.names, (qrev, snd (snd uctx.names)))
in
{ uctx with sort_variables; names }
let merge_sort_context ?loc ~sideff rigid uctx ((qvars,levels),csts) =
let uctx = merge_sort_variables ?loc ~sideff uctx qvars in
merge ?loc ~sideff rigid uctx (levels,csts)
let demote_seff_univs univs uctx =
let seff = Level.Set.union uctx.seff_univs univs in
{ uctx with seff_univs = seff }
let demote_global_univs env uctx =
let env_ugraph = Environ.universes env in
let mem_univ u ugraph = match UGraph.check_declared_universes ugraph (Level.Set.singleton u) with
| () -> true
| exception (UGraph.UndeclaredLevel _) -> false
in
let mem_constraints (u, _, v as cst) ugraph =
mem_univ u ugraph && mem_univ v ugraph && UGraph.check_constraint ugraph cst
in
let filter_univs u = not (mem_univ u env_ugraph) in
let filter_constraints cst = not (mem_constraints cst env_ugraph) in
let (local_univs, local_constraints) = uctx.local in
let new_univs = Level.Set.filter filter_univs local_univs in
let new_constraints = Constraints.filter filter_constraints local_constraints in
{ uctx with local = (new_univs, new_constraints) }
let merge_seff uctx uctx' =
let levels = ContextSet.levels uctx' in
let declare g =
Level.Set.fold (fun u g ->
try UGraph.add_universe ~lbound:UGraph.Bound.Set ~strict:false u g
with UGraph.AlreadyDeclared -> g)
levels g
in
let initial_universes = declare uctx.initial_universes in
let univs = declare uctx.universes in
let universes = merge_constraints uctx (ContextSet.constraints uctx') univs in
{ uctx with universes; initial_universes }
let emit_side_effects eff u =
let uctx = Safe_typing.universes_of_private eff in
let u = demote_seff_univs (fst uctx) u in
merge_seff u uctx
let update_sigma_univs uctx univs =
let eunivs =
{ uctx with
initial_universes = univs;
universes = univs }
in
merge_seff eunivs eunivs.local
let add_qnames ?loc s l ((qnames,unames), (qnames_rev,unames_rev)) =
if Id.Map.mem s qnames
then user_err ?loc
Pp.(str "Quality " ++ Id.print s ++ str" already bound.");
((Id.Map.add s l qnames, unames),
(QVar.Map.add l { uname = Some s; uloc = loc } qnames_rev, unames_rev))
let add_names ?loc s l ((qnames,unames), (qnames_rev,unames_rev)) =
if UNameMap.mem s unames
then user_err ?loc
Pp.(str "Universe " ++ Id.print s ++ str" already bound.");
((qnames,UNameMap.add s l unames),
(qnames_rev, Level.Map.add l { uname = Some s; uloc = loc } unames_rev))
let add_qloc l loc (names, (qnames_rev,unames_rev) as orig) =
match loc with
| None -> orig
| Some _ -> (names, (QVar.Map.add l { uname = None; uloc = loc } qnames_rev, unames_rev))
let add_loc l loc (names, (qnames_rev,unames_rev) as orig) =
match loc with
| None -> orig
| Some _ -> (names, (qnames_rev, Level.Map.add l { uname = None; uloc = loc } unames_rev))
let add_universe ?loc name strict uctx u =
let lbound = UGraph.Bound.Set in
let initial_universes = UGraph.add_universe ~lbound ~strict u uctx.initial_universes in
let universes = UGraph.add_universe ~lbound ~strict u uctx.universes in
let local = ContextSet.add_universe u uctx.local in
let names =
match name with
| Some n -> add_names ?loc n u uctx.names
| None -> add_loc u loc uctx.names
in
{ uctx with names; local; initial_universes; universes }
let new_sort_variable ?loc ?name uctx =
let q = UnivGen.new_sort_global () in
let sort_variables = QState.add ~check_fresh:false ~named:(Option.has_some name)
q uctx.sort_variables
in
let names = match name with
| Some n -> add_qnames ?loc n q uctx.names
| None -> add_qloc q loc uctx.names
in
{ uctx with sort_variables; names }, q
let new_univ_variable ?loc rigid name uctx =
let u = UnivGen.fresh_level () in
let uctx =
match rigid with
| UnivRigid -> uctx
| UnivFlexible algebraic ->
let univ_variables = UnivFlex.add u ~algebraic uctx.univ_variables in
{ uctx with univ_variables }
in
let uctx = add_universe ?loc name false uctx u in
uctx, u
let add_global_univ uctx u = add_universe None true uctx u
let make_with_initial_binders ~lbound univs binders =
let uctx = make ~lbound univs in
List.fold_left
(fun uctx { CAst.loc; v = id } ->
fst (new_univ_variable ?loc univ_rigid (Some id) uctx))
uctx binders
let from_env ?(binders=[]) env =
make_with_initial_binders ~lbound:UGraph.Bound.Set (Environ.universes env) binders
let make_nonalgebraic_variable uctx u =
{ uctx with univ_variables = UnivFlex.make_nonalgebraic_variable uctx.univ_variables u }
let make_flexible_nonalgebraic uctx =
{ uctx with univ_variables = UnivFlex.make_all_undefined_nonalgebraic uctx.univ_variables }
let subst_univs_context_with_def def usubst (uctx, cst) =
(Level.Set.diff uctx def, UnivSubst.subst_univs_constraints usubst cst)
let normalize_variables uctx =
let normalized_variables, def, subst =
UnivFlex.normalize_univ_variables uctx.univ_variables
in
let uctx_local = subst_univs_context_with_def def subst uctx.local in
let univs = UGraph.merge_constraints (snd uctx_local) uctx.initial_universes in
{ uctx with
local = uctx_local;
univ_variables = normalized_variables;
universes = univs }
let fix_undefined_variables uctx =
{ uctx with univ_variables = UnivFlex.fix_undefined_variables uctx.univ_variables }
let collapse_sort_variables uctx =
{ uctx with sort_variables = QState.collapse uctx.sort_variables }
let minimize ?(lbound = UGraph.Bound.Set) uctx =
let open UnivMinim in
let (vars', us') =
normalize_context_set ~lbound uctx.universes uctx.local uctx.univ_variables
uctx.minim_extra
in
if ContextSet.equal us' uctx.local then uctx
else
let universes = UGraph.merge_constraints (snd us') uctx.initial_universes in
{ names = uctx.names;
local = us';
seff_univs = uctx.seff_univs;
univ_variables = vars';
sort_variables = uctx.sort_variables;
universes = universes;
initial_universes = uctx.initial_universes;
minim_extra = UnivMinim.empty_extra; }
let universe_context_inst_decl decl qvars levels names =
let leftqs = List.fold_left (fun acc l -> QVar.Set.remove l acc) qvars decl.univdecl_qualities in
let leftus = List.fold_left (fun acc l -> Level.Set.remove l acc) levels decl.univdecl_instance in
let () =
let unboundqs = if decl.univdecl_extensible_qualities then QVar.Set.empty else leftqs in
let unboundus = if decl.univdecl_extensible_instance then Level.Set.empty else leftus in
if not (QVar.Set.is_empty unboundqs && Level.Set.is_empty unboundus)
then error_unbound_universes unboundqs unboundus names
in
let instq = Array.map_of_list (fun q -> Quality.QVar q) decl.univdecl_qualities in
let instu = Array.of_list decl.univdecl_instance in
let inst = Instance.of_array (instq,instu) in
inst
let check_univ_decl_rev uctx decl =
let levels, csts = uctx.local in
let qvars = QState.undefined uctx.sort_variables in
let inst = universe_context_inst_decl decl qvars levels uctx.names in
let nas = compute_instance_binders (snd uctx.names) inst in
let () =
check_implication uctx
csts
decl.univdecl_constraints
in
let uctx = fix_undefined_variables uctx in
let uctx, csts =
if decl.univdecl_extensible_constraints
then uctx, csts else restrict_constraints uctx decl.univdecl_constraints, decl.univdecl_constraints
in
let uctx' = UContext.make nas (inst, csts) in
uctx, uctx'
let check_uctx_impl ~fail uctx uctx' =
let levels, csts = uctx'.local in
let qvars_diff =
QVar.Set.diff
(QState.undefined uctx'.sort_variables)
(QState.undefined uctx.sort_variables)
in
let levels_diff = Level.Set.diff levels (fst uctx.local) in
let () = if not @@ (QVar.Set.is_empty qvars_diff && Level.Set.is_empty levels_diff) then
error_unbound_universes qvars_diff levels_diff uctx'.names
in
let () =
let grext = ugraph uctx in
let cstrs' = Constraints.filter (fun c -> not (UGraph.check_constraint grext c)) csts in
if Constraints.is_empty cstrs' then ()
else fail (Constraints.pr (pr_uctx_level uctx) cstrs')
in
()
let pr_weak prl {minim_extra={UnivMinim.weak_constraints=weak}} =
let open Pp in
prlist_with_sep fnl (fun (u,v) -> prl u ++ str " ~ " ++ prl v) (UPairSet.elements weak)
let pr_sort_opt_subst uctx = QState.pr (pr_uctx_qvar uctx) uctx.sort_variables
module Internal =
struct
let reboot env uctx =
let uctx_global = from_env env in
{ uctx_global with univ_variables = uctx.univ_variables; sort_variables = uctx.sort_variables }
end