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|
(************************************************************************)
(* * The Coq Proof Assistant / The Coq Development Team *)
(* v * INRIA, CNRS and contributors - Copyright 1999-2018 *)
(* <O___,, * (see CREDITS file for the list of authors) *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(* * (see LICENSE file for the text of the license) *)
(************************************************************************)
open CErrors
open Util
open Names
open Cic
open Term
open Reduction
open Type_errors
open Declarations
open Environ
open Univ
let inductive_of_constructor = fst
let index_of_constructor = snd
let ith_constructor_of_inductive ind i = (ind,i)
type mind_specif = mutual_inductive_body * one_inductive_body
(* raise Not_found if not an inductive type *)
let lookup_mind_specif env (kn,tyi) =
let mib = lookup_mind kn env in
if tyi >= Array.length mib.mind_packets then
user_err Pp.(str "Inductive.lookup_mind_specif: invalid inductive index");
(mib, mib.mind_packets.(tyi))
let find_rectype env c =
let (t, l) = decompose_app (whd_all env c) in
match t with
| Ind ind -> (ind, l)
| _ -> raise Not_found
let find_inductive env c =
let (t, l) = decompose_app (whd_all env c) in
match t with
| Ind (ind,_)
when (fst (lookup_mind_specif env ind)).mind_finite != CoFinite -> (ind, l)
| _ -> raise Not_found
let find_coinductive env c =
let (t, l) = decompose_app (whd_all env c) in
match t with
| Ind (ind,_)
when (fst (lookup_mind_specif env ind)).mind_finite == CoFinite -> (ind, l)
| _ -> raise Not_found
let inductive_params (mib,_) = mib.mind_nparams
(** Polymorphic inductives *)
let inductive_is_polymorphic mib =
match mib.mind_universes with
| Monomorphic_ind _ -> false
| Polymorphic_ind ctx -> true
| Cumulative_ind cumi -> true
let inductive_is_cumulative mib =
match mib.mind_universes with
| Monomorphic_ind _ -> false
| Polymorphic_ind ctx -> false
| Cumulative_ind cumi -> true
(************************************************************************)
(* Build the substitution that replaces Rels by the appropriate *)
(* inductives *)
let ind_subst mind mib u =
let ntypes = mib.mind_ntypes in
let make_Ik k = Ind ((mind,ntypes-k-1),u) in
List.init ntypes make_Ik
(* Instantiate inductives in constructor type *)
let constructor_instantiate mind u mib c =
let s = ind_subst mind mib u in
substl s (subst_instance_constr u c)
let instantiate_params full t u args sign =
let fail () =
anomaly ~label:"instantiate_params" (Pp.str "type, ctxt and args mismatch.") in
let (rem_args, subs, ty) =
fold_rel_context
(fun decl (largs,subs,ty) ->
match (decl, largs, ty) with
| (LocalAssum _, a::args, Prod(_,_,t)) -> (args, a::subs, t)
| (LocalDef (_,b,_),_,LetIn(_,_,_,t)) ->
(largs, (substl subs (subst_instance_constr u b))::subs, t)
| (_,[],_) -> if full then fail() else ([], subs, ty)
| _ -> fail ())
sign
~init:(args,[],t)
in
if rem_args <> [] then fail();
substl subs ty
let full_inductive_instantiate mib u params sign =
let dummy = Prop Null in
let t = mkArity (Term.subst_instance_context u sign,dummy) in
fst (destArity (instantiate_params true t u params mib.mind_params_ctxt))
let full_constructor_instantiate ((mind,_),u,(mib,_),params) t =
let inst_ind = constructor_instantiate mind u mib t in
instantiate_params true inst_ind u params mib.mind_params_ctxt
(************************************************************************)
(************************************************************************)
(* Functions to build standard types related to inductive *)
(*
Computing the actual sort of an applied or partially applied inductive type:
I_i: forall uniformparams:utyps, forall otherparams:otyps, Type(a)
uniformargs : utyps
otherargs : otyps
I_1:forall ...,s_1;...I_n:forall ...,s_n |- sort(C_kj(uniformargs)) = s_kj
s'_k = max(..s_kj..)
merge(..s'_k..) = ..s''_k..
--------------------------------------------------------------------
Gamma |- I_i uniformargs otherargs : phi(s''_i)
where
- if p=0, phi() = Prop
- if p=1, phi(s) = s
- if p<>1, phi(s) = sup(Set,s)
Remark: Set (predicative) is encoded as Type(0)
*)
let sort_as_univ = function
| Type u -> u
| Prop Null -> Univ.type0m_univ
| Prop Pos -> Univ.type0_univ
(* cons_subst add the mapping [u |-> su] in subst if [u] is not *)
(* in the domain or add [u |-> sup x su] if [u] is already mapped *)
(* to [x]. *)
let cons_subst u su subst =
try
Univ.LMap.add u (Univ.sup (Univ.LMap.find u subst) su) subst
with Not_found -> Univ.LMap.add u su subst
(* remember_subst updates the mapping [u |-> x] by [u |-> sup x u] *)
(* if it is presents and returns the substitution unchanged if not.*)
let remember_subst u subst =
try
let su = Universe.make u in
Univ.LMap.add u (Univ.sup (Univ.LMap.find u subst) su) subst
with Not_found -> subst
(* Bind expected levels of parameters to actual levels *)
(* Propagate the new levels in the signature *)
let make_subst env =
let rec make subst = function
| LocalDef _ :: sign, exp, args ->
make subst (sign, exp, args)
| d::sign, None::exp, args ->
let args = match args with _::args -> args | [] -> [] in
make subst (sign, exp, args)
| d::sign, Some u::exp, a::args ->
(* We recover the level of the argument, but we don't change the *)
(* level in the corresponding type in the arity; this level in the *)
(* arity is a global level which, at typing time, will be enforce *)
(* to be greater than the level of the argument; this is probably *)
(* a useless extra constraint *)
let s = sort_as_univ (snd (dest_arity env a)) in
make (cons_subst u s subst) (sign, exp, args)
| LocalAssum (na,t) :: sign, Some u::exp, [] ->
(* No more argument here: we add the remaining universes to the *)
(* substitution (when [u] is distinct from all other universes in the *)
(* template, it is identity substitution otherwise (ie. when u is *)
(* already in the domain of the substitution) [remember_subst] will *)
(* update its image [x] by [sup x u] in order not to forget the *)
(* dependency in [u] that remains to be fullfilled. *)
make (remember_subst u subst) (sign, exp, [])
| sign, [], _ ->
(* Uniform parameters are exhausted *)
subst
| [], _, _ ->
assert false
in
make Univ.LMap.empty
let instantiate_universes env ctx ar argsorts =
let args = Array.to_list argsorts in
let subst = make_subst env (ctx,ar.template_param_levels,args) in
let level = Univ.subst_univs_universe (Univ.make_subst subst) ar.template_level in
let ty =
(* Singleton type not containing types are interpretable in Prop *)
if Univ.is_type0m_univ level then Prop Null
(* Non singleton type not containing types are interpretable in Set *)
else if Univ.is_type0_univ level then Prop Pos
(* This is a Type with constraints *)
else Type level
in
(ctx, ty)
(* Type of an inductive type *)
let type_of_inductive_gen env ((mib,mip),u) paramtyps =
match mip.mind_arity with
| RegularArity a ->
if not (inductive_is_polymorphic mib) then a.mind_user_arity
else subst_instance_constr u a.mind_user_arity
| TemplateArity ar ->
let ctx = List.rev mip.mind_arity_ctxt in
let ctx,s = instantiate_universes env ctx ar paramtyps in
mkArity (List.rev ctx,s)
let type_of_inductive_knowing_parameters env mip args =
type_of_inductive_gen env mip args
(* Type of a (non applied) inductive type *)
let type_of_inductive env mip =
type_of_inductive_knowing_parameters env mip [||]
(* The max of an array of universes *)
let cumulate_constructor_univ u = function
| Prop Null -> u
| Prop Pos -> Univ.sup Univ.type0_univ u
| Type u' -> Univ.sup u u'
let max_inductive_sort =
Array.fold_left cumulate_constructor_univ Univ.type0m_univ
(************************************************************************)
(* Type of a constructor *)
let type_of_constructor_subst cstr u (mib,mip) =
let ind = inductive_of_constructor cstr in
let specif = mip.mind_user_lc in
let i = index_of_constructor cstr in
let nconstr = Array.length mip.mind_consnames in
if i > nconstr then user_err Pp.(str "Not enough constructors in the type.");
constructor_instantiate (fst ind) u mib specif.(i-1)
let type_of_constructor_gen (cstr,u) (mib,mip as mspec) =
type_of_constructor_subst cstr u mspec
let type_of_constructor cstru mspec =
type_of_constructor_gen cstru mspec
let arities_of_specif (kn,u) (mib,mip) =
let specif = mip.mind_nf_lc in
Array.map (constructor_instantiate kn u mib) specif
(************************************************************************)
let error_elim_expln kp ki =
match kp,ki with
| (InType | InSet), InProp -> NonInformativeToInformative
| InType, InSet -> StrongEliminationOnNonSmallType (* if Set impredicative *)
| _ -> WrongArity
(* Type of case predicates *)
(* Get type of inductive, with parameters instantiated *)
let inductive_sort_family mip =
match mip.mind_arity with
| RegularArity s -> family_of_sort s.mind_sort
| TemplateArity _ -> InType
let mind_arity mip =
mip.mind_arity_ctxt, inductive_sort_family mip
let get_instantiated_arity (ind,u) (mib,mip) params =
let sign, s = mind_arity mip in
full_inductive_instantiate mib u params sign, s
let elim_sorts (_,mip) = mip.mind_kelim
let extended_rel_list n hyps =
let rec reln l p = function
| LocalAssum _ :: hyps -> reln (Rel (n+p) :: l) (p+1) hyps
| LocalDef _ :: hyps -> reln l (p+1) hyps
| [] -> l
in
reln [] 1 hyps
let build_dependent_inductive ind (_,mip) params =
let realargs,_ = List.chop mip.mind_nrealdecls mip.mind_arity_ctxt in
applist
(Ind ind,
List.map (lift mip.mind_nrealdecls) params
@ extended_rel_list 0 realargs)
(* This exception is local *)
exception LocalArity of (sorts_family * sorts_family * arity_error) option
let check_allowed_sort ksort specif =
if not (List.exists ((=) ksort) (elim_sorts specif)) then
let s = inductive_sort_family (snd specif) in
raise (LocalArity (Some(ksort,s,error_elim_expln ksort s)))
let is_correct_arity env c (p,pj) ind specif params =
let arsign,_ = get_instantiated_arity ind specif params in
let rec srec env pt ar =
let pt' = whd_all env pt in
match pt', ar with
| Prod (na1,a1,t), LocalAssum (_,a1')::ar' ->
(try conv env a1 a1'
with NotConvertible -> raise (LocalArity None));
srec (push_rel (LocalAssum (na1,a1)) env) t ar'
| Prod (na1,a1,a2), [] -> (* whnf of t was not needed here! *)
let env' = push_rel (LocalAssum (na1,a1)) env in
let ksort = match (whd_all env' a2) with
| Sort s -> family_of_sort s
| _ -> raise (LocalArity None) in
let dep_ind = build_dependent_inductive ind specif params in
(try conv env a1 dep_ind
with NotConvertible -> raise (LocalArity None));
check_allowed_sort ksort specif;
true
| Sort s', [] ->
check_allowed_sort (family_of_sort s') specif;
false
| _, (LocalDef _ as d)::ar' ->
srec (push_rel d env) (lift 1 pt') ar'
| _ ->
raise (LocalArity None)
in
try srec env pj (List.rev arsign)
with LocalArity kinds ->
error_elim_arity env ind (elim_sorts specif) c (p,pj) kinds
(************************************************************************)
(* Type of case branches *)
(* [p] is the predicate, [i] is the constructor number (starting from 0),
and [cty] is the type of the constructor (params not instantiated) *)
let build_branches_type (ind,u) (_,mip as specif) params dep p =
let build_one_branch i cty =
let typi = full_constructor_instantiate (ind,u,specif,params) cty in
let (args,ccl) = decompose_prod_assum typi in
let nargs = rel_context_length args in
let (_,allargs) = decompose_app ccl in
let (lparams,vargs) = List.chop (inductive_params specif) allargs in
let cargs =
if dep then
let cstr = ith_constructor_of_inductive ind (i+1) in
let dep_cstr =
applist (Construct (cstr,u),lparams@extended_rel_list 0 args) in
vargs @ [dep_cstr]
else
vargs in
let base = beta_appvect (lift nargs p) (Array.of_list cargs) in
it_mkProd_or_LetIn base args in
Array.mapi build_one_branch mip.mind_nf_lc
(* [p] is the predicate, [c] is the match object, [realargs] is the
list of real args of the inductive type *)
let build_case_type dep p c realargs =
let args = if dep then realargs@[c] else realargs in
beta_appvect p (Array.of_list args)
let type_case_branches env (pind,largs) (p,pj) c =
let specif = lookup_mind_specif env (fst pind) in
let nparams = inductive_params specif in
let (params,realargs) = List.chop nparams largs in
let dep = is_correct_arity env c (p,pj) pind specif params in
let lc = build_branches_type pind specif params dep p in
let ty = build_case_type dep p c realargs in
(lc, ty)
(************************************************************************)
(* Checking the case annotation is relevant *)
let check_case_info env indsp ci =
let (mib,mip) = lookup_mind_specif env indsp in
if
not (eq_ind_chk indsp ci.ci_ind) ||
(mib.mind_nparams <> ci.ci_npar) ||
(mip.mind_consnrealdecls <> ci.ci_cstr_ndecls) ||
(mip.mind_consnrealargs <> ci.ci_cstr_nargs)
then raise (TypeError(env,WrongCaseInfo(indsp,ci)))
(************************************************************************)
(************************************************************************)
(* Guard conditions for fix and cofix-points *)
(* Check if t is a subterm of Rel n, and gives its specification,
assuming lst already gives index of
subterms with corresponding specifications of recursive arguments *)
(* A powerful notion of subterm *)
(* To each inductive definition corresponds an array describing the
structure of recursive arguments for each constructor, we call it
the recursive spec of the type (it has type recargs vect). For
checking the guard, we start from the decreasing argument (Rel n)
with its recursive spec. During checking the guardness condition,
we collect patterns variables corresponding to subterms of n, each
of them with its recursive spec. They are organised in a list lst
of type (int * recargs) list which is sorted with respect to the
first argument.
*)
(*************************************************************)
(* Environment annotated with marks on recursive arguments *)
(* tells whether it is a strict or loose subterm *)
type size = Large | Strict
(* merging information *)
let size_glb s1 s2 =
match s1,s2 with
Strict, Strict -> Strict
| _ -> Large
(* possible specifications for a term:
- Not_subterm: when the size of a term is not related to the
recursive argument of the fixpoint
- Subterm: when the term is a subterm of the recursive argument
the wf_paths argument specifies which subterms are recursive
- Dead_code: when the term has been built by elimination over an
empty type
*)
type subterm_spec =
Subterm of (size * wf_paths)
| Dead_code
| Not_subterm
let eq_wf_paths = Rtree.equal eq_recarg
let inter_recarg r1 r2 = match r1, r2 with
| Norec, Norec -> Some r1
| Mrec i1, Mrec i2
| Imbr i1, Imbr i2
| Mrec i1, Imbr i2 -> if Names.eq_ind_chk i1 i2 then Some r1 else None
| Imbr i1, Mrec i2 -> if Names.eq_ind_chk i1 i2 then Some r2 else None
| _ -> None
let inter_wf_paths = Rtree.inter eq_recarg inter_recarg Norec
let incl_wf_paths = Rtree.incl eq_recarg inter_recarg Norec
let spec_of_tree t =
if eq_wf_paths t mk_norec
then Not_subterm
else Subterm (Strict, t)
let inter_spec s1 s2 =
match s1, s2 with
| _, Dead_code -> s1
| Dead_code, _ -> s2
| Not_subterm, _ -> s1
| _, Not_subterm -> s2
| Subterm (a1,t1), Subterm (a2,t2) ->
Subterm (size_glb a1 a2, inter_wf_paths t1 t2)
let subterm_spec_glb =
Array.fold_left inter_spec Dead_code
type guard_env =
{ env : env;
(* dB of last fixpoint *)
rel_min : int;
(* dB of variables denoting subterms *)
genv : subterm_spec Lazy.t list;
}
let make_renv env recarg tree =
{ env = env;
rel_min = recarg+2; (* recarg = 0 ==> Rel 1 -> recarg; Rel 2 -> fix *)
genv = [Lazy.from_val(Subterm(Large,tree))] }
let push_var renv (x,ty,spec) =
{ env = push_rel (LocalAssum (x,ty)) renv.env;
rel_min = renv.rel_min+1;
genv = spec:: renv.genv }
let assign_var_spec renv (i,spec) =
{ renv with genv = List.assign renv.genv (i-1) spec }
let push_var_renv renv (x,ty) =
push_var renv (x,ty,Lazy.from_val Not_subterm)
(* Fetch recursive information about a variable p *)
let subterm_var p renv =
try Lazy.force (List.nth renv.genv (p-1))
with Failure _ | Invalid_argument _ -> Not_subterm
let push_ctxt_renv renv ctxt =
let n = rel_context_length ctxt in
{ env = push_rel_context ctxt renv.env;
rel_min = renv.rel_min+n;
genv = iterate (fun ge -> Lazy.from_val Not_subterm::ge) n renv.genv }
let push_fix_renv renv (_,v,_ as recdef) =
let n = Array.length v in
{ env = push_rec_types recdef renv.env;
rel_min = renv.rel_min+n;
genv = iterate (fun ge -> Lazy.from_val Not_subterm::ge) n renv.genv }
(* Definition and manipulation of the stack *)
type stack_element = |SClosure of guard_env*constr |SArg of subterm_spec Lazy.t
let push_stack_closures renv l stack =
List.fold_right (fun h b -> (SClosure (renv,h))::b) l stack
let push_stack_args l stack =
List.fold_right (fun h b -> (SArg h)::b) l stack
(******************************)
(* Computing the recursive subterms of a term (propagation of size
information through Cases). *)
(*
c is a branch of an inductive definition corresponding to the spec
lrec. mind_recvec is the recursive spec of the inductive
definition of the decreasing argument n.
case_branches_specif renv lrec lc will pass the lambdas
of c corresponding to pattern variables and collect possibly new
subterms variables and returns the bodies of the branches with the
correct envs and decreasing args.
*)
let lookup_subterms env ind =
let (_,mip) = lookup_mind_specif env ind in
mip.mind_recargs
let match_inductive ind ra =
match ra with
| (Mrec i | Imbr i) -> eq_ind_chk ind i
| Norec -> false
(* In {match c as z in ci y_s return P with |C_i x_s => t end}
[branches_specif renv c_spec ci] returns an array of x_s specs knowing
c_spec. *)
let branches_specif renv c_spec ci =
let car =
(* We fetch the regular tree associated to the inductive of the match.
This is just to get the number of constructors (and constructor
arities) that fit the match branches without forcing c_spec.
Note that c_spec might be more precise than [v] below, because of
nested inductive types. *)
let (_,mip) = lookup_mind_specif renv.env ci.ci_ind in
let v = dest_subterms mip.mind_recargs in
Array.map List.length v in
Array.mapi
(fun i nca -> (* i+1-th cstructor has arity nca *)
let lvra = lazy
(match Lazy.force c_spec with
Subterm (_,t) when match_inductive ci.ci_ind (dest_recarg t) ->
let vra = Array.of_list (dest_subterms t).(i) in
assert (nca = Array.length vra);
Array.map spec_of_tree vra
| Dead_code -> Array.make nca Dead_code
| _ -> Array.make nca Not_subterm) in
List.init nca (fun j -> lazy (Lazy.force lvra).(j)))
car
let check_inductive_codomain env p =
let absctx, ar = dest_lam_assum env p in
let env = push_rel_context absctx env in
let arctx, s = dest_prod_assum env ar in
let env = push_rel_context arctx env in
let i,l' = decompose_app (whd_all env s) in
match i with Ind _ -> true | _ -> false
(* The following functions are almost duplicated from indtypes.ml, except
that they carry here a poorer environment (containing less information). *)
let ienv_push_var (env, lra) (x,a,ra) =
(push_rel (LocalAssum (x,a)) env, (Norec,ra)::lra)
let ienv_push_inductive (env, ra_env) ((mind,u),lpar) =
let mib = Environ.lookup_mind mind env in
let ntypes = mib.mind_ntypes in
let push_ind specif env =
let decl = LocalAssum (Anonymous,
hnf_prod_applist env (type_of_inductive env ((mib,specif),u)) lpar) in
push_rel decl env
in
let env = Array.fold_right push_ind mib.mind_packets env in
let rc = Array.mapi (fun j t -> (Imbr (mind,j),t)) (Rtree.mk_rec_calls ntypes) in
let lra_ind = Array.rev_to_list rc in
let ra_env = List.map (fun (r,t) -> (r,Rtree.lift ntypes t)) ra_env in
(env, lra_ind @ ra_env)
let rec ienv_decompose_prod (env,_ as ienv) n c =
if Int.equal n 0 then (ienv,c) else
let c' = whd_all env c in
match c' with
Prod(na,a,b) ->
let ienv' = ienv_push_var ienv (na,a,mk_norec) in
ienv_decompose_prod ienv' (n-1) b
| _ -> assert false
let lambda_implicit_lift n a =
let level = Level.make (DirPath.make [Id.of_string "implicit"]) 0 in
let implicit_sort = Sort (Type (Universe.make level)) in
let lambda_implicit a = Lambda (Anonymous, implicit_sort, a) in
iterate lambda_implicit n (lift n a)
let abstract_mind_lc ntyps npars lc =
if Int.equal npars 0 then
lc
else
let make_abs =
List.init ntyps
(function i -> lambda_implicit_lift npars (Rel (i+1)))
in
Array.map (substl make_abs) lc
(* [get_recargs_approx env tree ind args] builds an approximation of the recargs
tree for ind, knowing args. The argument tree is used to know when candidate
nested types should be traversed, pruning the tree otherwise. This code is very
close to check_positive in indtypes.ml, but does no positivy check and does not
compute the number of recursive arguments. *)
let get_recargs_approx env tree ind args =
let rec build_recargs (env, ra_env as ienv) tree c =
let x,largs = decompose_app (whd_all env c) in
match x with
| Prod (na,b,d) ->
assert (List.is_empty largs);
build_recargs (ienv_push_var ienv (na, b, mk_norec)) tree d
| Rel k ->
(* Free variables are allowed and assigned Norec *)
(try snd (List.nth ra_env (k-1))
with Failure _ | Invalid_argument _ -> mk_norec)
| Ind ind_kn ->
(* When the inferred tree allows it, we consider that we have a potential
nested inductive type *)
begin match dest_recarg tree with
| Imbr kn' | Mrec kn' when eq_ind_chk (fst ind_kn) kn' ->
build_recargs_nested ienv tree (ind_kn, largs)
| _ -> mk_norec
end
| err ->
mk_norec
and build_recargs_nested (env,ra_env as ienv) tree (((mind,i),u), largs) =
(* If the infered tree already disallows recursion, no need to go further *)
if eq_wf_paths tree mk_norec then tree
else
let mib = Environ.lookup_mind mind env in
let auxnpar = mib.mind_nparams_rec in
let nonrecpar = mib.mind_nparams - auxnpar in
let (lpar,_) = List.chop auxnpar largs in
let auxntyp = mib.mind_ntypes in
(* Extends the environment with a variable corresponding to
the inductive def *)
let (env',_ as ienv') = ienv_push_inductive ienv ((mind,u),lpar) in
(* Parameters expressed in env' *)
let lpar' = List.map (lift auxntyp) lpar in
(* In case of mutual inductive types, we use the recargs tree which was
computed statically. This is fine because nested inductive types with
mutually recursive containers are not supported. *)
let trees =
if Int.equal auxntyp 1 then [|dest_subterms tree|]
else Array.map (fun mip -> dest_subterms mip.mind_recargs) mib.mind_packets
in
let mk_irecargs j specif =
(* The nested inductive type with parameters removed *)
let auxlcvect = abstract_mind_lc auxntyp auxnpar specif.mind_nf_lc in
let paths = Array.mapi
(fun k c ->
let c' = hnf_prod_applist env' c lpar' in
(* skip non-recursive parameters *)
let (ienv',c') = ienv_decompose_prod ienv' nonrecpar c' in
build_recargs_constructors ienv' trees.(j).(k) c')
auxlcvect
in
mk_paths (Imbr (mind,j)) paths
in
let irecargs = Array.mapi mk_irecargs mib.mind_packets in
(Rtree.mk_rec irecargs).(i)
and build_recargs_constructors ienv trees c =
let rec recargs_constr_rec (env,ra_env as ienv) trees lrec c =
let x,largs = decompose_app (whd_all env c) in
match x with
| Prod (na,b,d) ->
let () = assert (List.is_empty largs) in
let recarg = build_recargs ienv (List.hd trees) b in
let ienv' = ienv_push_var ienv (na,b,mk_norec) in
recargs_constr_rec ienv' (List.tl trees) (recarg::lrec) d
| hd ->
List.rev lrec
in
recargs_constr_rec ienv trees [] c
in
(* starting with ra_env = [] seems safe because any unbounded Rel will be
assigned Norec *)
build_recargs_nested (env,[]) tree (ind, args)
(* [restrict_spec env spec p] restricts the size information in spec to what is
allowed to flow through a match with predicate p in environment env. *)
let restrict_spec env spec p =
if spec = Not_subterm then spec
else let absctx, ar = dest_lam_assum env p in
(* Optimization: if the predicate is not dependent, no restriction is needed
and we avoid building the recargs tree. *)
if noccur_with_meta 1 (rel_context_length absctx) ar then spec
else
let env = push_rel_context absctx env in
let arctx, s = dest_prod_assum env ar in
let env = push_rel_context arctx env in
let i,args = decompose_app (whd_all env s) in
match i with
| Ind i ->
begin match spec with
| Dead_code -> spec
| Subterm(st,tree) ->
let recargs = get_recargs_approx env tree i args in
let recargs = inter_wf_paths tree recargs in
Subterm(st,recargs)
| _ -> assert false
end
| _ -> Not_subterm
(* [subterm_specif renv t] computes the recursive structure of [t] and
compare its size with the size of the initial recursive argument of
the fixpoint we are checking. [renv] collects such information
about variables.
*)
let rec subterm_specif renv stack t =
(* maybe reduction is not always necessary! *)
let f,l = decompose_app (whd_all renv.env t) in
match f with
| Rel k -> subterm_var k renv
| Case (ci,p,c,lbr) ->
let stack' = push_stack_closures renv l stack in
let cases_spec =
branches_specif renv (lazy_subterm_specif renv [] c) ci
in
let stl =
Array.mapi (fun i br' ->
let stack_br = push_stack_args (cases_spec.(i)) stack' in
subterm_specif renv stack_br br')
lbr in
let spec = subterm_spec_glb stl in
restrict_spec renv.env spec p
| Fix ((recindxs,i),(_,typarray,bodies as recdef)) ->
(* when proving that the fixpoint f(x)=e is less than n, it is enough
to prove that e is less than n assuming f is less than n
furthermore when f is applied to a term which is strictly less than
n, one may assume that x itself is strictly less than n
*)
if not (check_inductive_codomain renv.env typarray.(i)) then Not_subterm
else
let (ctxt,clfix) = dest_prod renv.env typarray.(i) in
let oind =
let env' = push_rel_context ctxt renv.env in
try Some(fst(find_inductive env' clfix))
with Not_found -> None in
(match oind with
None -> Not_subterm (* happens if fix is polymorphic *)
| Some ind ->
let nbfix = Array.length typarray in
let recargs = lookup_subterms renv.env ind in
(* pushing the fixpoints *)
let renv' = push_fix_renv renv recdef in
let renv' =
(* Why Strict here ? To be general, it could also be
Large... *)
assign_var_spec renv'
(nbfix-i, lazy (Subterm(Strict,recargs))) in
let decrArg = recindxs.(i) in
let theBody = bodies.(i) in
let nbOfAbst = decrArg+1 in
let sign,strippedBody = decompose_lam_n_assum nbOfAbst theBody in
(* pushing the fix parameters *)
let stack' = push_stack_closures renv l stack in
let renv'' = push_ctxt_renv renv' sign in
let renv'' =
if List.length stack' < nbOfAbst then renv''
else
let decrArg = List.nth stack' decrArg in
let arg_spec = stack_element_specif decrArg in
assign_var_spec renv'' (1, arg_spec) in
subterm_specif renv'' [] strippedBody)
| Lambda (x,a,b) ->
assert (l=[]);
let spec,stack' = extract_stack renv a stack in
subterm_specif (push_var renv (x,a,spec)) stack' b
(* Metas and evars are considered OK *)
| (Meta _|Evar _) -> Dead_code
(* Other terms are not subterms *)
| _ -> Not_subterm
and lazy_subterm_specif renv stack t =
lazy (subterm_specif renv stack t)
and stack_element_specif = function
|SClosure (h_renv,h) -> lazy_subterm_specif h_renv [] h
|SArg x -> x
and extract_stack renv a = function
| [] -> Lazy.from_val Not_subterm , []
| h::t -> stack_element_specif h, t
(* Check size x is a correct size for recursive calls. *)
let check_is_subterm x tree =
match Lazy.force x with
| Subterm (Strict,tree') -> incl_wf_paths tree tree'
| Dead_code -> true
| _ -> false
(************************************************************************)
exception FixGuardError of env * guard_error
let error_illegal_rec_call renv fx (arg_renv,arg) =
let (_,le_vars,lt_vars) =
List.fold_left
(fun (i,le,lt) sbt ->
match Lazy.force sbt with
(Subterm(Strict,_) | Dead_code) -> (i+1, le, i::lt)
| (Subterm(Large,_)) -> (i+1, i::le, lt)
| _ -> (i+1, le ,lt))
(1,[],[]) renv.genv in
raise (FixGuardError (renv.env,
RecursionOnIllegalTerm(fx,(arg_renv.env, arg),
le_vars,lt_vars)))
let error_partial_apply renv fx =
raise (FixGuardError (renv.env,NotEnoughArgumentsForFixCall fx))
let filter_stack_domain env ci p stack =
let absctx, ar = dest_lam_assum env p in
(* Optimization: if the predicate is not dependent, no restriction is needed
and we avoid building the recargs tree. *)
if noccur_with_meta 1 (rel_context_length absctx) ar then stack
else let env = push_rel_context absctx env in
let rec filter_stack env ar stack =
let t = whd_all env ar in
match stack, t with
| elt :: stack', Prod (n,a,c0) ->
let d = LocalAssum (n,a) in
let ty, args = decompose_app (whd_all env a) in
let elt = match ty with
| Ind ind ->
let spec' = stack_element_specif elt in
(match (Lazy.force spec') with
| Not_subterm | Dead_code -> elt
| Subterm(s,path) ->
let recargs = get_recargs_approx env path ind args in
let path = inter_wf_paths path recargs in
SArg (lazy (Subterm(s,path))))
| _ -> (SArg (lazy Not_subterm))
in
elt :: filter_stack (push_rel d env) c0 stack'
| _,_ -> List.fold_right (fun _ l -> SArg (lazy Not_subterm) :: l) stack []
in
filter_stack env ar stack
(* Check if [def] is a guarded fixpoint body with decreasing arg.
given [recpos], the decreasing arguments of each mutually defined
fixpoint. *)
let check_one_fix renv recpos trees def =
let nfi = Array.length recpos in
(* Checks if [t] only make valid recursive calls *)
let rec check_rec_call renv stack t =
(* if [t] does not make recursive calls, it is guarded: *)
if noccur_with_meta renv.rel_min nfi t then ()
else
let (f,l) = decompose_app (whd_betaiotazeta t) in
match f with
| Rel p ->
(* Test if [p] is a fixpoint (recursive call) *)
if renv.rel_min <= p && p < renv.rel_min+nfi then
begin
List.iter (check_rec_call renv []) l;
(* the position of the invoked fixpoint: *)
let glob = renv.rel_min+nfi-1-p in
(* the decreasing arg of the rec call: *)
let np = recpos.(glob) in
let stack' = push_stack_closures renv l stack in
if List.length stack' <= np then error_partial_apply renv glob
else
(* Retrieve the expected tree for the argument *)
(* Check the decreasing arg is smaller *)
let z = List.nth stack' np in
if not (check_is_subterm (stack_element_specif z) trees.(glob)) then
begin match z with
|SClosure (z,z') -> error_illegal_rec_call renv glob (z,z')
|SArg _ -> error_partial_apply renv glob
end
end
else
begin
match lookup_rel p renv.env with
| LocalAssum _ ->
List.iter (check_rec_call renv []) l
| LocalDef (_,c,_) ->
try List.iter (check_rec_call renv []) l
with FixGuardError _ ->
check_rec_call renv stack (applist(lift p c,l))
end
| Case (ci,p,c_0,lrest) ->
List.iter (check_rec_call renv []) (c_0::p::l);
(* compute the recarg information for the arguments of
each branch *)
let case_spec = branches_specif renv
(lazy_subterm_specif renv [] c_0) ci in
let stack' = push_stack_closures renv l stack in
let stack' = filter_stack_domain renv.env ci p stack' in
Array.iteri (fun k br' ->
let stack_br = push_stack_args case_spec.(k) stack' in
check_rec_call renv stack_br br') lrest
(* Enables to traverse Fixpoint definitions in a more intelligent
way, ie, the rule :
if - g = fix g (y1:T1)...(yp:Tp) {struct yp} := e &
- f is guarded with respect to the set of pattern variables S
in a1 ... am &
- f is guarded with respect to the set of pattern variables S
in T1 ... Tp &
- ap is a sub-term of the formal argument of f &
- f is guarded with respect to the set of pattern variables
S+{yp} in e
then f is guarded with respect to S in (g a1 ... am).
Eduardo 7/9/98 *)
| Fix ((recindxs,i),(_,typarray,bodies as recdef)) ->
List.iter (check_rec_call renv []) l;
Array.iter (check_rec_call renv []) typarray;
let decrArg = recindxs.(i) in
let renv' = push_fix_renv renv recdef in
let stack' = push_stack_closures renv l stack in
Array.iteri
(fun j body ->
if i=j && (List.length stack' > decrArg) then
let recArg = List.nth stack' decrArg in
let arg_sp = stack_element_specif recArg in
check_nested_fix_body renv' (decrArg+1) arg_sp body
else check_rec_call renv' [] body)
bodies
| Const (kn,u) ->
if evaluable_constant kn renv.env then
try List.iter (check_rec_call renv []) l
with (FixGuardError _ ) ->
let value = (applist(constant_value renv.env (kn,u), l)) in
check_rec_call renv stack value
else List.iter (check_rec_call renv []) l
| Lambda (x,a,b) ->
assert (l = []);
check_rec_call renv [] a ;
let spec, stack' = extract_stack renv a stack in
check_rec_call (push_var renv (x,a,spec)) stack' b
| Prod (x,a,b) ->
assert (l = [] && stack = []);
check_rec_call renv [] a;
check_rec_call (push_var_renv renv (x,a)) [] b
| CoFix (i,(_,typarray,bodies as recdef)) ->
List.iter (check_rec_call renv []) l;
Array.iter (check_rec_call renv []) typarray;
let renv' = push_fix_renv renv recdef in
Array.iter (check_rec_call renv' []) bodies
| (Ind _ | Construct _) ->
List.iter (check_rec_call renv []) l
| Proj (p, c) ->
List.iter (check_rec_call renv []) l;
check_rec_call renv [] c
| Var _ -> anomaly (Pp.str "Section variable in Coqchk!")
| Sort _ -> assert (l = [])
(* l is not checked because it is considered as the meta's context *)
| (Evar _ | Meta _) -> ()
| (App _ | LetIn _ | Cast _) -> assert false (* beta zeta reduction *)
and check_nested_fix_body renv decr recArgsDecrArg body =
if decr = 0 then
check_rec_call (assign_var_spec renv (1,recArgsDecrArg)) [] body
else
match body with
| Lambda (x,a,b) ->
check_rec_call renv [] a;
let renv' = push_var_renv renv (x,a) in
check_nested_fix_body renv' (decr-1) recArgsDecrArg b
| _ -> anomaly (Pp.str "Not enough abstractions in fix body.")
in
check_rec_call renv [] def
let inductive_of_mutfix env ((nvect,bodynum),(names,types,bodies as recdef)) =
let nbfix = Array.length bodies in
if nbfix = 0
|| Array.length nvect <> nbfix
|| Array.length types <> nbfix
|| Array.length names <> nbfix
|| bodynum < 0
|| bodynum >= nbfix
then anomaly (Pp.str "Ill-formed fix term.");
let fixenv = push_rec_types recdef env in
let raise_err env i err =
error_ill_formed_rec_body env err names i in
(* Check the i-th definition with recarg k *)
let find_ind i k def =
(* check fi does not appear in the k+1 first abstractions,
gives the type of the k+1-eme abstraction (must be an inductive) *)
let rec check_occur env n def =
match (whd_all env def) with
| Lambda (x,a,b) ->
if noccur_with_meta n nbfix a then
let env' = push_rel (LocalAssum (x,a)) env in
if n = k+1 then
(* get the inductive type of the fixpoint *)
let (mind, _) =
try find_inductive env a
with Not_found ->
raise_err env i (RecursionNotOnInductiveType a) in
(mind, (env', b))
else check_occur env' (n+1) b
else anomaly ~label:"check_one_fix" (Pp.str "Bad occurrence of recursive call.")
| _ -> raise_err env i NotEnoughAbstractionInFixBody in
check_occur fixenv 1 def in
(* Do it on every fixpoint *)
let rv = Array.map2_i find_ind nvect bodies in
(Array.map fst rv, Array.map snd rv)
let check_fix env ((nvect,_),(names,_,bodies as _recdef) as fix) =
let (minds, rdef) = inductive_of_mutfix env fix in
let get_tree (kn,i) =
let mib = Environ.lookup_mind kn env in
mib.mind_packets.(i).mind_recargs
in
let trees = Array.map get_tree minds in
for i = 0 to Array.length bodies - 1 do
let (fenv,body) = rdef.(i) in
let renv = make_renv fenv nvect.(i) trees.(i) in
try check_one_fix renv nvect trees body
with FixGuardError (fixenv,err) ->
error_ill_formed_rec_body fixenv err names i
done
(*
let cfkey = CProfile.declare_profile "check_fix";;
let check_fix env fix = CProfile.profile3 cfkey check_fix env fix;;
*)
(************************************************************************)
(* Co-fixpoints. *)
exception CoFixGuardError of env * guard_error
let anomaly_ill_typed () =
anomaly ~label:"check_one_cofix" (Pp.str "too many arguments applied to constructor.")
let rec codomain_is_coind env c =
let b = whd_all env c in
match b with
| Prod (x,a,b) ->
codomain_is_coind (push_rel (LocalAssum (x,a)) env) b
| _ ->
(try find_coinductive env b
with Not_found ->
raise (CoFixGuardError (env, CodomainNotInductiveType b)))
let check_one_cofix env nbfix def deftype =
let rec check_rec_call env alreadygrd n tree vlra t =
if not (noccur_with_meta n nbfix t) then
let c,args = decompose_app (whd_all env t) in
match c with
| Rel p when n <= p && p < n+nbfix ->
(* recursive call: must be guarded and no nested recursive
call allowed *)
if not alreadygrd then
raise (CoFixGuardError (env,UnguardedRecursiveCall t))
else if not(List.for_all (noccur_with_meta n nbfix) args) then
raise (CoFixGuardError (env,NestedRecursiveOccurrences))
| Construct ((_,i as cstr_kn),u) ->
let lra = vlra.(i-1) in
let mI = inductive_of_constructor cstr_kn in
let (mib,mip) = lookup_mind_specif env mI in
let realargs = List.skipn mib.mind_nparams args in
let rec process_args_of_constr = function
| (t::lr), (rar::lrar) ->
if rar = mk_norec then
if noccur_with_meta n nbfix t
then process_args_of_constr (lr, lrar)
else raise (CoFixGuardError
(env,RecCallInNonRecArgOfConstructor t))
else begin
check_rec_call env true n rar (dest_subterms rar) t;
process_args_of_constr (lr, lrar)
end
| [],_ -> ()
| _ -> anomaly_ill_typed ()
in process_args_of_constr (realargs, lra)
| Lambda (x,a,b) ->
assert (args = []);
if noccur_with_meta n nbfix a then
let env' = push_rel (LocalAssum (x,a)) env in
check_rec_call env' alreadygrd (n+1) tree vlra b
else
raise (CoFixGuardError (env,RecCallInTypeOfAbstraction a))
| CoFix (j,(_,varit,vdefs as recdef)) ->
if List.for_all (noccur_with_meta n nbfix) args
then
if Array.for_all (noccur_with_meta n nbfix) varit then
let nbfix = Array.length vdefs in
let env' = push_rec_types recdef env in
(Array.iter (check_rec_call env' alreadygrd (n+nbfix) tree vlra) vdefs;
List.iter (check_rec_call env alreadygrd n tree vlra) args)
else
raise (CoFixGuardError (env,RecCallInTypeOfDef c))
else
raise (CoFixGuardError (env,UnguardedRecursiveCall c))
| Case (_,p,tm,vrest) ->
begin
let tree = match restrict_spec env (Subterm (Strict, tree)) p with
| Dead_code -> assert false
| Subterm (_, tree') -> tree'
| _ -> raise (CoFixGuardError (env, ReturnPredicateNotCoInductive c))
in
if (noccur_with_meta n nbfix p) then
if (noccur_with_meta n nbfix tm) then
if (List.for_all (noccur_with_meta n nbfix) args) then
let vlra = dest_subterms tree in
Array.iter (check_rec_call env alreadygrd n tree vlra) vrest
else
raise (CoFixGuardError (env,RecCallInCaseFun c))
else
raise (CoFixGuardError (env,RecCallInCaseArg c))
else
raise (CoFixGuardError (env,RecCallInCasePred c))
end
| Meta _ -> ()
| Evar _ ->
List.iter (check_rec_call env alreadygrd n tree vlra) args
| _ -> raise (CoFixGuardError (env,NotGuardedForm t)) in
let (mind, _) = codomain_is_coind env deftype in
let vlra = lookup_subterms env mind in
check_rec_call env false 1 vlra (dest_subterms vlra) def
(* The function which checks that the whole block of definitions
satisfies the guarded condition *)
let check_cofix env (bodynum,(names,types,bodies as recdef)) =
let nbfix = Array.length bodies in
for i = 0 to nbfix-1 do
let fixenv = push_rec_types recdef env in
try check_one_cofix fixenv nbfix bodies.(i) types.(i)
with CoFixGuardError (errenv,err) ->
error_ill_formed_rec_body errenv err names i
done
|