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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
open Pp
open Util
open Names
open Nameops
open Term
open Termops
open Sign
open Environ
open Evd
open Reduction
open Reductionops
open Rawterm
open Pattern
open Tacred
open Pretype_errors
open Evarutil
open Unification
open Mod_subst
open Coercion.Default
(* Abbreviations *)
let pf_env gls = Global.env_of_context gls.it.evar_hyps
let pf_type_of gls c = Typing.type_of (pf_env gls) gls.sigma c
let pf_hnf_constr gls c = hnf_constr (pf_env gls) gls.sigma c
let pf_concl gl = gl.it.evar_concl
(******************************************************************)
(* Clausal environments *)
type clausenv = {
env : env;
evd : evar_defs;
templval : constr freelisted;
templtyp : constr freelisted }
let cl_env ce = ce.env
let cl_sigma ce = evars_of ce.evd
let subst_clenv sub clenv =
{ templval = map_fl (subst_mps sub) clenv.templval;
templtyp = map_fl (subst_mps sub) clenv.templtyp;
evd = subst_evar_defs_light sub clenv.evd;
env = clenv.env }
let clenv_nf_meta clenv c = nf_meta clenv.evd c
let clenv_term clenv c = meta_instance clenv.evd c
let clenv_meta_type clenv mv = Typing.meta_type clenv.evd mv
let clenv_value clenv = meta_instance clenv.evd clenv.templval
let clenv_type clenv = meta_instance clenv.evd clenv.templtyp
let clenv_hnf_constr ce t = hnf_constr (cl_env ce) (cl_sigma ce) t
let clenv_get_type_of ce c =
Retyping.get_type_of_with_meta (cl_env ce) (cl_sigma ce) (metas_of ce.evd) c
exception NotExtensibleClause
let clenv_push_prod cl =
let typ = whd_betadeltaiota (cl_env cl) (cl_sigma cl) (clenv_type cl) in
let rec clrec typ = match kind_of_term typ with
| Cast (t,_,_) -> clrec t
| Prod (na,t,u) ->
let mv = new_meta () in
let dep = dependent (mkRel 1) u in
let na' = if dep then na else Anonymous in
let e' = meta_declare mv t ~name:na' cl.evd in
let concl = if dep then subst1 (mkMeta mv) u else u in
let def = applist (cl.templval.rebus,[mkMeta mv]) in
{ templval = mk_freelisted def;
templtyp = mk_freelisted concl;
evd = e';
env = cl.env }
| _ -> raise NotExtensibleClause
in clrec typ
(* Instantiate the first [bound] products of [t] with metas (all products if
[bound] is [None]; unfold local defs *)
let clenv_environments evd bound t =
let rec clrec (e,metas) n t =
match n, kind_of_term t with
| (Some 0, _) -> (e, List.rev metas, t)
| (n, Cast (t,_,_)) -> clrec (e,metas) n t
| (n, Prod (na,t1,t2)) ->
let mv = new_meta () in
let dep = dependent (mkRel 1) t2 in
let na' = if dep then na else Anonymous in
let e' = meta_declare mv t1 ~name:na' e in
clrec (e', (mkMeta mv)::metas) (Option.map ((+) (-1)) n)
(if dep then (subst1 (mkMeta mv) t2) else t2)
| (n, LetIn (na,b,_,t)) -> clrec (e,metas) n (subst1 b t)
| (n, _) -> (e, List.rev metas, t)
in
clrec (evd,[]) bound t
(* Instantiate the first [bound] products of [t] with evars (all products if
[bound] is [None]; unfold local defs *)
let clenv_environments_evars env evd bound t =
let rec clrec (e,ts) n t =
match n, kind_of_term t with
| (Some 0, _) -> (e, List.rev ts, t)
| (n, Cast (t,_,_)) -> clrec (e,ts) n t
| (n, Prod (na,t1,t2)) ->
let e',constr = Evarutil.new_evar e env t1 in
let dep = dependent (mkRel 1) t2 in
clrec (e', constr::ts) (Option.map ((+) (-1)) n)
(if dep then (subst1 constr t2) else t2)
| (n, LetIn (na,b,_,t)) -> clrec (e,ts) n (subst1 b t)
| (n, _) -> (e, List.rev ts, t)
in
clrec (evd,[]) bound t
let clenv_conv_leq env sigma t c bound =
let ty = Retyping.get_type_of env sigma c in
let evd = Evd.create_goal_evar_defs sigma in
let evars,args,_ = clenv_environments_evars env evd (Some bound) ty in
let evars = Evarconv.the_conv_x_leq env t (applist (c,args)) evars in
let evars,_ = Evarconv.consider_remaining_unif_problems env evars in
let args = List.map (whd_evar (Evd.evars_of evars)) args in
check_evars env sigma evars (applist (c,args));
args
let mk_clenv_from_env environ sigma n (c,cty) =
let evd = create_goal_evar_defs sigma in
let (env,args,concl) = clenv_environments evd n cty in
{ templval = mk_freelisted (match args with [] -> c | _ -> applist (c,args));
templtyp = mk_freelisted concl;
evd = env;
env = environ }
let mk_clenv_from_n gls n (c,cty) =
mk_clenv_from_env (Global.env_of_context gls.it.evar_hyps) gls.sigma n (c, cty)
let mk_clenv_from gls = mk_clenv_from_n gls None
let mk_clenv_rename_from_n gls n (c,t) =
mk_clenv_from_n gls n (c,rename_bound_var (pf_env gls) [] t)
let mk_clenv_type_of gls t = mk_clenv_from gls (t,pf_type_of gls t)
(******************************************************************)
(* [mentions clenv mv0 mv1] is true if mv1 is defined and mentions
* mv0, or if one of the free vars on mv1's freelist mentions
* mv0 *)
let mentions clenv mv0 =
let rec menrec mv1 =
mv0 = mv1 ||
let mlist =
try match meta_opt_fvalue clenv.evd mv1 with
| Some (b,_) -> b.freemetas
| None -> Metaset.empty
with Not_found -> Metaset.empty in
meta_exists menrec mlist
in menrec
let clenv_defined clenv mv = meta_defined clenv.evd mv
let error_incompatible_inst clenv mv =
let na = meta_name clenv.evd mv in
match na with
Name id ->
errorlabstrm "clenv_assign"
(str "An incompatible instantiation has already been found for " ++
pr_id id)
| _ ->
anomaly "clenv_assign: non dependent metavar already assigned"
(* TODO: replace by clenv_unify (mkMeta mv) rhs ? *)
let clenv_assign mv rhs clenv =
let rhs_fls = mk_freelisted rhs in
if meta_exists (mentions clenv mv) rhs_fls.freemetas then
error "clenv_assign: circularity in unification";
try
if meta_defined clenv.evd mv then
if not (eq_constr (fst (meta_fvalue clenv.evd mv)).rebus rhs) then
error_incompatible_inst clenv mv
else
clenv
else
let st = (ConvUpToEta 0,TypeNotProcessed) in
{clenv with evd = meta_assign mv (rhs_fls.rebus,st) clenv.evd}
with Not_found ->
error "clenv_assign: undefined meta"
let clenv_wtactic f clenv = {clenv with evd = f clenv.evd }
(* [clenv_dependent hyps_only clenv]
* returns a list of the metavars which appear in the template of clenv,
* and which are dependent, This is computed by taking the metavars in cval,
* in right-to-left order, and collecting the metavars which appear
* in their types, and adding in all the metavars appearing in the
* type of clenv.
* If [hyps_only] then metavariables occurring in the type are _excluded_ *)
(* [clenv_metavars clenv mv]
* returns a list of the metavars which appear in the type of
* the metavar mv. The list is unordered. *)
let clenv_metavars evd mv =
(mk_freelisted (meta_instance evd (meta_ftype evd mv))).freemetas
let dependent_metas clenv mvs conclmetas =
List.fold_right
(fun mv deps ->
Metaset.union deps (clenv_metavars clenv.evd mv))
mvs conclmetas
let duplicated_metas c =
let rec collrec (one,more as acc) c =
match kind_of_term c with
| Meta mv -> if List.mem mv one then (one,mv::more) else (mv::one,more)
| _ -> fold_constr collrec acc c
in
snd (collrec ([],[]) c)
let clenv_dependent hyps_only clenv =
let mvs = undefined_metas clenv.evd in
let ctyp_mvs = (mk_freelisted (clenv_type clenv)).freemetas in
let deps = dependent_metas clenv mvs ctyp_mvs in
let nonlinear = duplicated_metas (clenv_value clenv) in
(* Make the assumption that duplicated metas have internal dependencies *)
List.filter
(fun mv -> (Metaset.mem mv deps &&
not (hyps_only && Metaset.mem mv ctyp_mvs))
or List.mem mv nonlinear)
mvs
let clenv_missing ce = clenv_dependent true ce
(******************************************************************)
let clenv_unify allow_K ?(flags=default_unify_flags) cv_pb t1 t2 clenv =
{ clenv with
evd = w_unify allow_K ~flags:flags clenv.env cv_pb t1 t2 clenv.evd }
let clenv_unify_meta_types ?(flags=default_unify_flags) clenv =
{ clenv with evd = w_unify_meta_types ~flags:flags clenv.env clenv.evd }
let clenv_unique_resolver allow_K ?(flags=default_unify_flags) clenv gl =
if isMeta (fst (whd_stack clenv.templtyp.rebus)) then
clenv_unify allow_K CUMUL ~flags:flags (clenv_type clenv) (pf_concl gl)
(clenv_unify_meta_types ~flags:flags clenv)
else
clenv_unify allow_K CUMUL ~flags:flags
(meta_reducible_instance clenv.evd clenv.templtyp) (pf_concl gl) clenv
(* [clenv_pose_metas_as_evars clenv dep_mvs]
* For each dependent evar in the clause-env which does not have a value,
* pose a value for it by constructing a fresh evar. We do this in
* left-to-right order, so that every evar's type is always closed w.r.t.
* metas.
* Node added 14/4/08 [HH]: before this date, evars were collected in
clenv_dependent by collect_metas in the fold_constr order which is
(almost) the left-to-right order of dependencies in term. However,
due to K-redexes, collect_metas was sometimes missing some metas.
The call to collect_metas has been replaced by a call to
undefined_metas, but then the order was the one of definition of
the metas (numbers in increasing order) which is _not_ the
dependency order when a clenv_fchain occurs (because clenv_fchain
plugs a term with a list of consecutive metas in place of a - a priori -
arbitrary metavariable belonging to another sequence of consecutive metas:
e.g., clenv_fchain may plug (H ?1 ?2) at the position ?6 of
(nat_ind ?3 ?4 ?5 ?6), leading to a dependency order 3<4<5<1<2).
To ensure the dependency order, we check that the type of each meta
to pose is already meta-free, otherwise we postpone the transformation,
hoping that no cycle may happen.
Another approach could have been to use decimal numbers for metas so that
in the example above, (H ?1 ?2) would have been renumbered (H ?6.1 ?6.2)
then making the numeric order match the dependency order.
*)
let clenv_pose_metas_as_evars clenv dep_mvs =
let rec fold clenv = function
| [] -> clenv
| mv::mvs ->
let ty = clenv_meta_type clenv mv in
(* Postpone the evar-ization if dependent on another meta *)
(* This assumes no cycle in the dependencies - is it correct ? *)
if occur_meta ty then fold clenv (mvs@[mv])
else
let (evd,evar) =
new_evar clenv.evd (cl_env clenv) ~src:(dummy_loc,GoalEvar) ty in
let clenv = clenv_assign mv evar {clenv with evd=evd} in
fold clenv mvs in
fold clenv dep_mvs
let evar_clenv_unique_resolver = clenv_unique_resolver
(******************************************************************)
let connect_clenv gls clenv =
{ clenv with
evd = evars_reset_evd gls.sigma clenv.evd;
env = Global.env_of_context gls.it.evar_hyps }
(* [clenv_fchain mv clenv clenv']
*
* Resolves the value of "mv" (which must be undefined) in clenv to be
* the template of clenv' be the value "c", applied to "n" fresh
* metavars, whose types are chosen by destructing "clf", which should
* be a clausale forme generated from the type of "c". The process of
* resolution can cause unification of already-existing metavars, and
* of the fresh ones which get created. This operation is a composite
* of operations which pose new metavars, perform unification on
* terms, and make bindings.
Otherwise said, from
[clenv] = [env;sigma;metas |- c:T]
[clenv'] = [env';sigma';metas' |- d:U]
[mv] = [mi] of type [Ti] in [metas]
then, if the unification of [Ti] and [U] produces map [rho], the
chaining is [env';sigma';rho'(metas),rho(metas') |- c:rho'(T)] for
[rho'] being [rho;mi:=d].
In particular, it assumes that [env'] and [sigma'] extend [env] and [sigma].
*)
let clenv_fchain ?(allow_K=true) ?(flags=default_unify_flags) mv clenv nextclenv =
(* Add the metavars of [nextclenv] to [clenv], with their name-environment *)
let clenv' =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
evd =
evar_merge (meta_merge clenv.evd nextclenv.evd) (evars_of clenv.evd);
env = nextclenv.env } in
(* unify the type of the template of [nextclenv] with the type of [mv] *)
let clenv'' =
clenv_unify allow_K ~flags:flags CUMUL
(clenv_term clenv' nextclenv.templtyp)
(clenv_meta_type clenv' mv)
clenv' in
(* assign the metavar *)
let clenv''' =
clenv_assign mv (clenv_term clenv' nextclenv.templval) clenv''
in
clenv'''
(***************************************************************)
(* Bindings *)
type arg_bindings = open_constr explicit_bindings
(* [clenv_independent clenv]
* returns a list of metavariables which appear in the term cval,
* and which are not dependent. That is, they do not appear in
* the types of other metavars which are in cval, nor in the type
* of cval, ctyp. *)
let clenv_independent clenv =
let mvs = collect_metas (clenv_value clenv) in
let ctyp_mvs = (mk_freelisted (clenv_type clenv)).freemetas in
let deps = dependent_metas clenv mvs ctyp_mvs in
List.filter (fun mv -> not (Metaset.mem mv deps)) mvs
let check_bindings bl =
match list_duplicates (List.map pi2 bl) with
| NamedHyp s :: _ ->
errorlabstrm ""
(str "The variable " ++ pr_id s ++
str " occurs more than once in binding list.");
| AnonHyp n :: _ ->
errorlabstrm ""
(str "The position " ++ int n ++
str " occurs more than once in binding list.")
| [] -> ()
let meta_of_binder clause loc mvs = function
| NamedHyp s -> meta_with_name clause.evd s
| AnonHyp n ->
try List.nth mvs (n-1)
with (Failure _|Invalid_argument _) ->
errorlabstrm "" (str "No such binder.")
let error_already_defined b =
match b with
| NamedHyp id ->
errorlabstrm ""
(str "Binder name \"" ++ pr_id id ++
str"\" already defined with incompatible value.")
| AnonHyp n ->
anomalylabstrm ""
(str "Position " ++ int n ++ str" already defined.")
let clenv_unify_binding_type clenv c t u =
if isMeta (fst (whd_stack u)) then
(* Not enough information to know if some subtyping is needed *)
CoerceToType, clenv, c
else
(* Enough information so as to try a coercion now *)
try
let evd,c = w_coerce_to_type (cl_env clenv) clenv.evd c t u in
TypeProcessed, { clenv with evd = evd }, c
with e when precatchable_exception e ->
TypeNotProcessed, clenv, c
let clenv_assign_binding clenv k (sigma,c) =
let k_typ = clenv_hnf_constr clenv (clenv_meta_type clenv k) in
let clenv' = { clenv with evd = evar_merge clenv.evd sigma} in
let c_typ = nf_betaiota (clenv_get_type_of clenv' c) in
let status,clenv'',c = clenv_unify_binding_type clenv' c c_typ k_typ in
{ clenv'' with evd = meta_assign k (c,(UserGiven,status)) clenv''.evd }
let clenv_match_args bl clenv =
if bl = [] then
clenv
else
let mvs = clenv_independent clenv in
check_bindings bl;
List.fold_left
(fun clenv (loc,b,(sigma,c as sc)) ->
let k = meta_of_binder clenv loc mvs b in
if meta_defined clenv.evd k then
if eq_constr (fst (meta_fvalue clenv.evd k)).rebus c then clenv
else error_already_defined b
else
clenv_assign_binding clenv k sc)
clenv bl
let clenv_constrain_last_binding c clenv =
let all_mvs = collect_metas clenv.templval.rebus in
let k =
try list_last all_mvs
with Failure _ -> anomaly "clenv_constrain_with_bindings" in
clenv_assign_binding clenv k (Evd.empty,c)
let clenv_constrain_dep_args hyps_only bl clenv =
if bl = [] then
clenv
else
let occlist = clenv_dependent hyps_only clenv in
if List.length occlist = List.length bl then
List.fold_left2 clenv_assign_binding clenv occlist bl
else
errorlabstrm ""
(strbrk "Not the right number of missing arguments (expected " ++
int (List.length occlist) ++ str ").")
(****************************************************************)
(* Clausal environment for an application *)
let make_clenv_binding_gen hyps_only n gls (c,t) = function
| ImplicitBindings largs ->
let clause = mk_clenv_from_n gls n (c,t) in
clenv_constrain_dep_args hyps_only largs clause
| ExplicitBindings lbind ->
let clause = mk_clenv_rename_from_n gls n (c,t) in
clenv_match_args lbind clause
| NoBindings ->
mk_clenv_from_n gls n (c,t)
let make_clenv_binding_apply gls n = make_clenv_binding_gen true n gls
let make_clenv_binding = make_clenv_binding_gen false None
(****************************************************************)
(* Pretty-print *)
let pr_clenv clenv =
h 0
(str"TEMPL: " ++ print_constr clenv.templval.rebus ++
str" : " ++ print_constr clenv.templtyp.rebus ++ fnl () ++
pr_evar_defs clenv.evd)
|