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|
(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \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 Instantiate
open Environ
open Evd
open Proof_type
open Refiner
open Proof_trees
open Logic
open Reductionops
open Tacmach
open Evar_refiner
open Rawterm
open Tacexpr
(* if lname_typ is [xn,An;..;x1,A1] and l is a list of terms,
gives [x1:A1]..[xn:An]c' such that c converts to ([x1:A1]..[xn:An]c' l) *)
let abstract_scheme env c l lname_typ =
List.fold_left2
(fun t (locc,a) (na,_,ta) ->
if occur_meta ta then error "cannot find a type for the generalisation"
else if occur_meta a then lambda_name env (na,ta,t)
else lambda_name env (na,ta,subst_term_occ locc a t))
c
(List.rev l)
lname_typ
let abstract_list_all env sigma typ c l =
let ctxt,_ = decomp_n_prod env sigma (List.length l) typ in
let p = abstract_scheme env c (List.map (function a -> [],a) l) ctxt in
try
if is_conv_leq env sigma (Typing.type_of env sigma p) typ then p
else error "abstract_list_all"
with UserError _ ->
raise (RefinerError (CannotGeneralize typ))
(* Generator of metavariables *)
let meta_ctr = ref 0;;
let new_meta () = incr meta_ctr;!meta_ctr;;
(* replaces a mapping of existentials into a mapping of metas.
Problem if an evar appears in the type of another one (pops anomaly) *)
let exist_to_meta sigma (emap, c) =
let metamap = ref [] in
let change_exist evar =
let ty = nf_betaiota (nf_evar emap (existential_type emap evar)) in
let n = new_meta() in
metamap := (n, ty) :: !metamap;
mkMeta n in
let rec replace c =
match kind_of_term c with
Evar (k,_ as ev) when not (Evd.in_dom sigma k) -> change_exist ev
| _ -> map_constr replace c in
(!metamap, replace c)
type 'a freelisted = {
rebus : 'a;
freemetas : Intset.t }
type clbinding =
| Cltyp of constr freelisted
| Clval of constr freelisted * constr freelisted
type 'a clausenv = {
templval : constr freelisted;
templtyp : constr freelisted;
namenv : identifier Intmap.t;
env : clbinding Intmap.t;
hook : 'a }
let applyHead n c wc =
let rec apprec n c cty wc =
if n = 0 then
(wc,c)
else
match kind_of_term (w_whd_betadeltaiota wc cty) with
| Prod (_,c1,c2) ->
let evar = Evarutil.new_evar_in_sign (w_env wc) in
let (evar_n, _) = destEvar evar in
(compose
(apprec (n-1) (applist(c,[evar])) (subst1 evar c2))
(w_Declare evar_n c1))
wc
| _ -> error "Apply_Head_Then"
in
apprec n c (w_type_of wc c) wc
let mimick_evar hdc nargs sp wc =
let evd = Evd.map wc.sigma sp in
let wc' = extract_decl sp wc in
let (wc'', c) = applyHead nargs hdc wc' in
if wc'==wc''
then w_Define sp c wc
else
let wc''' = restore_decl sp evd wc'' in
w_Define sp c {it = wc.it ; sigma = wc'''.sigma}
(* (w_Focusing_THEN sp
(applyHead nargs hdc)
(fun c wc -> w_Define sp c wc)) wc *)
(* Unification à l'ordre 0 de m et n: [unify_0 mc wc m n] renvoie deux listes:
metasubst:(int*constr)list récolte les instances des (Meta k)
evarsubst:(constr*constr)list récolte les instances des (Const "?k")
Attention : pas d'unification entre les différences instances d'une
même meta ou evar, il peut rester des doublons *)
(* Unification order: *)
(* Left to right: unifies first argument and then the other arguments *)
let unify_l2r x = List.rev x
(* Right to left: unifies last argument and then the other arguments *)
let unify_r2l x = x
let sort_eqns = unify_r2l
let unify_0 cv_pb wc m n =
let env = w_env wc
and sigma = w_Underlying wc in
let trivial_unify pb substn m n =
if (not(occur_meta m)) & is_fconv pb env sigma m n then substn
else error_cannot_unify (m,n) in
let rec unirec_rec pb ((metasubst,evarsubst) as substn) m n =
let cM = Evarutil.whd_castappevar sigma m
and cN = Evarutil.whd_castappevar sigma n in
match (kind_of_term cM,kind_of_term cN) with
| Meta k1, Meta k2 ->
if k1 < k2 then (k1,cN)::metasubst,evarsubst
else if k1 = k2 then substn
else (k2,cM)::metasubst,evarsubst
| Meta k, _ -> (k,cN)::metasubst,evarsubst
| _, Meta k -> (k,cM)::metasubst,evarsubst
| Evar _, _ -> metasubst,((cM,cN)::evarsubst)
| _, Evar _ -> metasubst,((cN,cM)::evarsubst)
| Lambda (_,t1,c1), Lambda (_,t2,c2) ->
unirec_rec CONV (unirec_rec CONV substn t1 t2) c1 c2
| Prod (_,t1,c1), Prod (_,t2,c2) ->
unirec_rec pb (unirec_rec CONV substn t1 t2) c1 c2
| LetIn (_,b,_,c), _ -> unirec_rec pb substn (subst1 b c) cN
| _, LetIn (_,b,_,c) -> unirec_rec pb substn cM (subst1 b c)
| App (f1,l1), App (f2,l2) ->
let len1 = Array.length l1
and len2 = Array.length l2 in
let (f1,l1,f2,l2) =
if len1 = len2 then (f1,l1,f2,l2)
else if len1 < len2 then
let extras,restl2 = array_chop (len2-len1) l2 in
(f1, l1, appvect (f2,extras), restl2)
else
let extras,restl1 = array_chop (len1-len2) l1 in
(appvect (f1,extras), restl1, f2, l2) in
(try
array_fold_left2 (unirec_rec CONV)
(unirec_rec CONV substn f1 f2) l1 l2
with ex when catchable_exception ex ->
trivial_unify pb substn cM cN)
| Case (_,p1,c1,cl1), Case (_,p2,c2,cl2) ->
array_fold_left2 (unirec_rec CONV)
(unirec_rec CONV (unirec_rec CONV substn p1 p2) c1 c2) cl1 cl2
| _ -> trivial_unify pb substn cM cN
in
if (not(occur_meta m)) & is_fconv cv_pb env sigma m n then
([],[])
else
let (mc,ec) = unirec_rec cv_pb ([],[]) m n in
(sort_eqns mc, sort_eqns ec)
(* Unification
*
* Procedure:
* (1) The function [unify mc wc M N] produces two lists:
* (a) a list of bindings Meta->RHS
* (b) a list of bindings EVAR->RHS
*
* The Meta->RHS bindings cannot themselves contain
* meta-vars, so they get applied eagerly to the other
* bindings. This may or may not close off all RHSs of
* the EVARs. For each EVAR whose RHS is closed off,
* we can just apply it, and go on. For each which
* is not closed off, we need to do a mimick step -
* in general, we have something like:
*
* ?X == (c e1 e2 ... ei[Meta(k)] ... en)
*
* so we need to do a mimick step, converting ?X
* into
*
* ?X -> (c ?z1 ... ?zn)
*
* of the proper types. Then, we can decompose the
* equation into
*
* ?z1 --> e1
* ...
* ?zi --> ei[Meta(k)]
* ...
* ?zn --> en
*
* and keep on going. Whenever we find that a R.H.S.
* is closed, we can, as before, apply the constraint
* directly. Whenever we find an equation of the form:
*
* ?z -> Meta(n)
*
* we can reverse the equation, put it into our metavar
* substitution, and keep going.
*
* The most efficient mimick possible is, for each
* Meta-var remaining in the term, to declare a
* new EVAR of the same type. This is supposedly
* determinable from the clausale form context -
* we look up the metavar, take its type there,
* and apply the metavar substitution to it, to
* close it off. But this might not always work,
* since other metavars might also need to be resolved. *)
let rec w_Unify cv_pb m n wc =
let (mc',ec') = unify_0 cv_pb wc m n in
w_resrec mc' ec' wc
and w_resrec metas evars wc =
match evars with
| [] -> (wc,metas)
| (lhs,rhs) :: t ->
match kind_of_term rhs with
| Meta k -> w_resrec ((k,lhs)::metas) t wc
| krhs ->
match kind_of_term lhs with
| Evar (evn,_) ->
if w_defined_evar wc evn then
let (wc',metas') = w_Unify CONV rhs lhs wc in
w_resrec (metas@metas') t wc'
else
(try
w_resrec metas t (w_Define evn rhs wc)
with ex when catchable_exception ex ->
(match krhs with
| App (f,cl) when isConst f ->
let wc' = mimick_evar f (Array.length cl) evn wc in
w_resrec metas evars wc'
| _ -> error "w_Unify"))
| _ -> anomaly "w_resrec"
(* [unifyTerms] et [unify] ne semble pas gérer les Meta, en
particulier ne semblent pas vérifier que des instances différentes
d'une même Meta sont compatibles. D'ailleurs le "fst" jette les metas
provenant de w_Unify. (Utilisé seulement dans prolog.ml) *)
(* let unifyTerms m n = walking (fun wc -> fst (w_Unify CONV m n [] wc)) *)
let unifyTerms m n gls =
tclIDTAC {it = gls.it;
sigma = (get_gc (fst (w_Unify CONV m n (Refiner.project_with_focus gls))))}
let unify m gls =
let n = pf_concl gls in unifyTerms m n gls
(* collects all metavar occurences, in left-to-right order, preserving
* repetitions and all. *)
let collect_metas c =
let rec collrec acc c =
match kind_of_term c with
| Meta mv -> mv::acc
| _ -> fold_constr collrec acc c
in
List.rev (collrec [] c)
let metavars_of c =
let rec collrec acc c =
match kind_of_term c with
| Meta mv -> Intset.add mv acc
| _ -> fold_constr collrec acc c
in
collrec Intset.empty c
let mk_freelisted c =
{ rebus = c; freemetas = metavars_of c }
(* [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 =
try
(match Intmap.find mv1 clenv.env with
| Clval (b,_) ->
Intset.mem mv0 b.freemetas || intset_exists menrec b.freemetas
| Cltyp _ -> false)
with Not_found ->
false
in
menrec
(* Creates a new clause-environment, whose template has a given
* type, CTY. This is not all that useful, since not very often
* does one know the type of the clause - one usually only has
* a clause which one wants to backchain thru. *)
let mk_clenv wc cty =
let mv = new_meta () in
let cty_fls = mk_freelisted cty in
{ templval = mk_freelisted (mkMeta mv);
templtyp = cty_fls;
namenv = Intmap.empty;
env = Intmap.add mv (Cltyp cty_fls) Intmap.empty ;
hook = wc }
let clenv_environments bound c =
let rec clrec (ne,e,metas) n c =
match n, kind_of_term c with
| (Some 0, _) -> (ne, e, List.rev metas, c)
| (n, Cast (c,_)) -> clrec (ne,e,metas) n c
| (n, Prod (na,c1,c2)) ->
let mv = new_meta () in
let dep = dependent (mkRel 1) c2 in
let ne' =
if dep then
match na with
| Anonymous -> ne
| Name id ->
if intmap_in_dom mv ne then begin
warning ("Cannot put metavar "^(string_of_int mv)^
" in name-environment twice");
ne
end else
Intmap.add mv id ne
else
ne
in
let e' = Intmap.add mv (Cltyp (mk_freelisted c1)) e in
clrec (ne',e', (mkMeta mv)::metas) (option_app ((+) (-1)) n)
(if dep then (subst1 (mkMeta mv) c2) else c2)
| (n, LetIn (na,b,_,c)) ->
clrec (ne,e,metas) (option_app ((+) (-1)) n) (subst1 b c)
| (n, _) -> (ne, e, List.rev metas, c)
in
clrec (Intmap.empty,Intmap.empty,[]) bound c
let mk_clenv_from_n wc n (c,cty) =
let (namenv,env,args,concl) = clenv_environments n cty in
{ templval = mk_freelisted (match args with [] -> c | _ -> applist (c,args));
templtyp = mk_freelisted concl;
namenv = namenv;
env = env;
hook = wc }
let mk_clenv_from wc = mk_clenv_from_n wc None
let map_fl f cfl = { cfl with rebus=f cfl.rebus }
let map_clb f = function
| Cltyp cfl -> Cltyp (map_fl f cfl)
| Clval (cfl1,cfl2) -> Clval (map_fl f cfl1,map_fl f cfl2)
let subst_clenv f sub clenv =
{ templval = map_fl (subst_mps sub) clenv.templval;
templtyp = map_fl (subst_mps sub) clenv.templtyp;
namenv = clenv.namenv;
env = Intmap.map (map_clb (subst_mps sub)) clenv.env;
hook = f sub clenv.hook }
let connect_clenv wc clenv =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
namenv = clenv.namenv;
env = clenv.env;
hook = wc }
(* Changes the head of a clenv with (templ,templty) *)
let clenv_change_head (templ,templty) clenv =
{ templval = mk_freelisted templ;
templtyp = mk_freelisted templty;
namenv = clenv.namenv;
env = clenv.env;
hook = clenv.hook }
let mk_clenv_hnf_constr_type_of wc t =
mk_clenv_from wc (t,w_hnf_constr wc (w_type_of wc t))
let mk_clenv_rename_from wc (c,t) =
mk_clenv_from wc (c,rename_bound_var (w_env wc) [] t)
let mk_clenv_rename_from_n wc n (c,t) =
mk_clenv_from_n wc n (c,rename_bound_var (w_env wc) [] t)
let mk_clenv_rename_type_of wc t =
mk_clenv_from wc (t,rename_bound_var (w_env wc) [] (w_type_of wc t))
let mk_clenv_rename_hnf_constr_type_of wc t =
mk_clenv_from wc
(t,rename_bound_var (w_env wc) [] (w_hnf_constr wc (w_type_of wc t)))
let mk_clenv_type_of wc t = mk_clenv_from wc (t,w_type_of wc t)
let clenv_assign mv rhs clenv =
let rhs_fls = mk_freelisted rhs in
if intset_exists (mentions clenv mv) rhs_fls.freemetas then
error "clenv__assign: circularity in unification";
try
(match Intmap.find mv clenv.env with
| Clval (fls,ty) ->
if not (eq_constr fls.rebus rhs) then
try
(* Streams are lazy, force evaluation of id to catch Not_found*)
let id = Intmap.find mv clenv.namenv in
errorlabstrm "clenv_assign"
(str "An incompatible instantiation has already been found for " ++
pr_id id)
with Not_found ->
anomaly "clenv_assign: non dependent metavar already assigned"
else
clenv
| Cltyp bty ->
{ templval = clenv.templval;
templtyp = clenv.templtyp;
namenv = clenv.namenv;
env = Intmap.add mv (Clval (rhs_fls,bty)) clenv.env;
hook = clenv.hook })
with Not_found ->
error "clenv_assign"
let clenv_val_of clenv mv =
let rec valrec mv =
try
(match Intmap.find mv clenv.env with
| Cltyp _ -> mkMeta mv
| Clval(b,_) ->
instance (List.map (fun mv' -> (mv',valrec mv'))
(Intset.elements b.freemetas)) b.rebus)
with Not_found ->
mkMeta mv
in
valrec mv
let clenv_instance clenv b =
let c_sigma =
List.map
(fun mv -> (mv,clenv_val_of clenv mv)) (Intset.elements b.freemetas)
in
instance c_sigma b.rebus
let clenv_instance_term clenv c =
clenv_instance clenv (mk_freelisted c)
(* This function put casts around metavariables whose type could not be
* infered by the refiner, that is head of applications, predicates and
* subject of Cases.
* Does check that the casted type is closed. Anyway, the refiner would
* fail in this case... *)
let clenv_cast_meta clenv =
let rec crec u =
match kind_of_term u with
| App _ | Case _ -> crec_hd u
| Cast (c,_) when isMeta c -> u
| _ -> map_constr crec u
and crec_hd u =
match kind_of_term (strip_outer_cast u) with
| Meta mv ->
(try
match Intmap.find mv clenv.env with
| Cltyp b ->
let b' = clenv_instance clenv b in
if occur_meta b' then u else mkCast (mkMeta mv, b')
| Clval(_) -> u
with Not_found ->
u)
| App(f,args) -> mkApp (crec_hd f, Array.map crec args)
| Case(ci,p,c,br) ->
mkCase (ci, crec_hd p, crec_hd c, Array.map crec br)
| _ -> u
in
crec
(* [clenv_pose (na,mv,cty) clenv]
* returns a new clausenv which has added to it the metavar MV,
* with type CTY. the name NA, if it is not ANONYMOUS, will
* be entered into the name-map, as a way of accessing the new
* metavar. *)
let clenv_pose (na,mv,cty) clenv =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
env = Intmap.add mv (Cltyp (mk_freelisted cty)) clenv.env;
namenv = (match na with
| Anonymous -> clenv.namenv
| Name id -> Intmap.add mv id clenv.namenv);
hook = clenv.hook }
let clenv_defined clenv mv =
match Intmap.find mv clenv.env with
| Clval _ -> true
| Cltyp _ -> false
let clenv_value clenv mv =
match Intmap.find mv clenv.env with
| Clval(b,_) -> b
| Cltyp _ -> failwith "clenv_value"
let clenv_type clenv mv =
match Intmap.find mv clenv.env with
| Cltyp b -> b
| Clval(_,b) -> b
let clenv_template clenv = clenv.templval
let clenv_template_type clenv = clenv.templtyp
let clenv_instance_value clenv mv =
clenv_instance clenv (clenv_value clenv mv)
let clenv_instance_type clenv mv =
clenv_instance clenv (clenv_type clenv mv)
let clenv_instance_template clenv =
clenv_instance clenv (clenv_template clenv)
let clenv_instance_template_type clenv =
clenv_instance clenv (clenv_template_type clenv)
let clenv_wtactic wt clenv =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
namenv = clenv.namenv;
env = clenv.env;
hook = wt clenv.hook }
let clenv_type_of ce c =
let metamap =
List.map
(function
| (n,Clval(_,typ)) -> (n,typ.rebus)
| (n,Cltyp typ) -> (n,typ.rebus))
(intmap_to_list ce.env)
in
Retyping.get_type_of_with_meta (w_env ce.hook) (w_Underlying ce.hook) metamap c
let clenv_instance_type_of ce c =
clenv_instance ce (mk_freelisted (clenv_type_of ce c))
(* [clenv_merge b metas evars clenv] merges common instances in metas
or in evars, possibly generating new unification problems; if [b]
is true, unification of types of metas is required *)
let clenv_merge with_types metas evars clenv =
let ty_metas = ref [] in
let ty_evars = ref [] in
let rec clenv_resrec metas evars clenv =
match (evars,metas) with
| ([], []) -> clenv
| ((lhs,rhs)::t, metas) ->
(match kind_of_term rhs with
| Meta k -> clenv_resrec ((k,lhs)::metas) t clenv
| krhs ->
(match kind_of_term lhs with
| Evar (evn,_) ->
if w_defined_evar clenv.hook evn then
let (metas',evars') = unify_0 CONV clenv.hook rhs lhs in
clenv_resrec (metas'@metas) (evars'@t) clenv
else begin
let rhs' =
if occur_meta rhs then subst_meta metas rhs else rhs
in
if occur_evar evn rhs' then error "w_Unify";
try
clenv_resrec metas t
(clenv_wtactic (w_Define evn rhs') clenv)
with ex when catchable_exception ex ->
(match krhs with
| App (f,cl) when isConst f or isConstruct f ->
clenv_resrec metas evars
(clenv_wtactic
(mimick_evar f (Array.length cl) evn)
clenv)
| _ -> error "w_Unify")
end
| _ -> anomaly "clenv_resrec"))
| ([], (mv,n)::t) ->
if clenv_defined clenv mv then
let (metas',evars') =
unify_0 CONV clenv.hook (clenv_value clenv mv).rebus n in
clenv_resrec (metas'@t) evars' clenv
else
begin
if with_types (* or occur_meta mvty *) then
(let mvty = clenv_instance_type clenv mv in
try
let nty = clenv_type_of clenv
(clenv_instance clenv (mk_freelisted n)) in
let (mc,ec) = unify_0 CUMUL clenv.hook nty mvty in
ty_metas := mc @ !ty_metas;
ty_evars := ec @ !ty_evars
with e when Logic.catchable_exception e -> ());
clenv_resrec t [] (clenv_assign mv n clenv)
end in
(* merge constraints *)
let clenv' = clenv_resrec metas evars clenv in
if with_types then
(* merge constraints about types: if they fail, don't worry *)
try clenv_resrec !ty_metas !ty_evars clenv'
with e when Logic.catchable_exception e -> clenv'
else clenv'
(* [clenv_unify M N clenv]
performs a unification of M and N, generating a bunch of
unification constraints in the process. These constraints
are processed, one-by-one - they may either generate new
bindings, or, if there is already a binding, new unifications,
which themselves generate new constraints. This continues
until we get failure, or we run out of constraints.
[clenv_typed_unify M N clenv] expects in addition that expected
types of metavars are unifiable with the types of their instances *)
let clenv_unify_core_0 with_types cv_pb m n clenv =
let (mc,ec) = unify_0 cv_pb clenv.hook m n in
clenv_merge with_types mc ec clenv
let clenv_unify_0 = clenv_unify_core_0 false
let clenv_typed_unify = clenv_unify_core_0 true
(* takes a substitution s, an open term op and a closed term cl
try to find a subterm of cl which matches op, if op is just a Meta
FAIL because we cannot find a binding *)
let iter_fail f a =
let n = Array.length a in
let rec ffail i =
if i = n then error "iter_fail"
else
try f a.(i)
with ex when catchable_exception ex -> ffail (i+1)
in ffail 0
(* Tries to find an instance of term [cl] in term [op].
Unifies [cl] to every subterm of [op] until it finds a match.
Fails if no match is found *)
let unify_to_subterm clause (op,cl) =
let rec matchrec cl =
let cl = strip_outer_cast cl in
(try
if closed0 cl
then clenv_unify_0 CONV op cl clause,cl
else error "Bound 1"
with ex when catchable_exception ex ->
(match kind_of_term cl with
| App (f,args) ->
let n = Array.length args in
assert (n>0);
let c1 = mkApp (f,Array.sub args 0 (n-1)) in
let c2 = args.(n-1) in
(try
matchrec c1
with ex when catchable_exception ex ->
matchrec c2)
| Case(_,_,c,lf) -> (* does not search in the predicate *)
(try
matchrec c
with ex when catchable_exception ex ->
iter_fail matchrec lf)
| LetIn(_,c1,_,c2) ->
(try
matchrec c1
with ex when catchable_exception ex ->
matchrec c2)
| Fix(_,(_,types,terms)) ->
(try
iter_fail matchrec types
with ex when catchable_exception ex ->
iter_fail matchrec terms)
| CoFix(_,(_,types,terms)) ->
(try
iter_fail matchrec types
with ex when catchable_exception ex ->
iter_fail matchrec terms)
| Prod (_,t,c) ->
(try
matchrec t
with ex when catchable_exception ex ->
matchrec c)
| Lambda (_,t,c) ->
(try
matchrec t
with ex when catchable_exception ex ->
matchrec c)
| _ -> error "Match_subterm"))
in
if isMeta op then error "Match_subterm";
matchrec cl
(* Possibly gives K-terms in case the operator does not contain
a meta : BUG ?? *)
let unify_to_subterm_list allow_K clause oplist t =
List.fold_right
(fun op (clause,l) ->
if occur_meta op then
let (clause',cl) =
(try
unify_to_subterm clause (strip_outer_cast op,t)
with e when catchable_exception e ->
if allow_K then (clause,op) else raise e)
in
(clause',cl::l)
else
(clause,op::l))
oplist
(clause,[])
let secondOrderAbstraction allow_K typ (p, oplist) clause =
let env = w_env clause.hook in
let sigma = w_Underlying clause.hook in
let (clause',cllist) = unify_to_subterm_list allow_K clause oplist typ in
let typp = clenv_instance_type clause' p in
let pred = abstract_list_all env sigma typp typ cllist in
clenv_unify_0 CONV (mkMeta p) pred clause'
let clenv_unify2 allow_K cv_pb ty1 ty2 clause =
let c1, oplist1 = whd_stack ty1 in
let c2, oplist2 = whd_stack ty2 in
match kind_of_term c1, kind_of_term c2 with
| Meta p1, _ ->
(* Find the predicate *)
let clause' =
secondOrderAbstraction allow_K ty2 (p1,oplist1) clause in
(* Resume first order unification *)
clenv_unify_0 cv_pb (clenv_instance_term clause' ty1) ty2 clause'
| _, Meta p2 ->
(* Find the predicate *)
let clause' =
secondOrderAbstraction allow_K ty1 (p2, oplist2) clause in
(* Resume first order unification *)
clenv_unify_0 cv_pb ty1 (clenv_instance_term clause' ty2) clause'
| _ -> error "clenv_unify2"
(* The unique unification algorithm works like this: If the pattern is
flexible, and the goal has a lambda-abstraction at the head, then
we do a first-order unification.
If the pattern is not flexible, then we do a first-order
unification, too.
If the pattern is flexible, and the goal doesn't have a
lambda-abstraction head, then we second-order unification. *)
(* We decide here if first-order or second-order unif is used for Apply *)
(* We apply a term of type (ai:Ai)C and try to solve a goal C' *)
(* The type C is in clenv.templtyp.rebus with a lot of Meta to solve *)
(* 3-4-99 [HH] New fo/so choice heuristic :
In case we have to unify (Meta(1) args) with ([x:A]t args')
we first try second-order unification and if it fails first-order.
Before, second-order was used if the type of Meta(1) and [x:A]t was
convertible and first-order otherwise. But if failed if e.g. the type of
Meta(1) had meta-variables in it. *)
let clenv_unify allow_K cv_pb ty1 ty2 clenv =
let hd1,l1 = whd_stack ty1 in
let hd2,l2 = whd_stack ty2 in
match kind_of_term hd1, l1<>[], kind_of_term hd2, l2<>[] with
(* Pattern case *)
| (Meta _, true, Lambda _, _ | Lambda _, _, Meta _, true)
when List.length l1 = List.length l2 ->
(try
clenv_typed_unify cv_pb ty1 ty2 clenv
with ex when catchable_exception ex ->
try
clenv_unify2 allow_K cv_pb ty1 ty2 clenv
with ex when catchable_exception ex ->
error "Cannot solve a second-order unification problem")
(* Second order case *)
| (Meta _, true, _, _ | _, _, Meta _, true) ->
(try
clenv_unify2 allow_K cv_pb ty1 ty2 clenv
with ex when catchable_exception ex ->
try
clenv_typed_unify cv_pb ty1 ty2 clenv
with ex when catchable_exception ex ->
error "Cannot solve a second-order unification problem")
(* General case: try first order *)
| _ -> clenv_unify_0 cv_pb ty1 ty2 clenv
(* [clenv_bchain 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. *)
let clenv_bchain mv subclenv clenv =
(* Add the metavars of [subclenv] to [clenv], with their name-environment *)
let clenv' =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
namenv =
List.fold_left (fun ne (mv,id) ->
if clenv_defined subclenv mv then
ne
else if intmap_in_dom mv ne then begin
warning ("Cannot put metavar "^(string_of_int mv)^
" in name-environment twice");
ne
end else
Intmap.add mv id ne)
clenv.namenv (intmap_to_list subclenv.namenv);
env = List.fold_left (fun m (n,v) -> Intmap.add n v m)
clenv.env (intmap_to_list subclenv.env);
hook = clenv.hook }
in
(* unify the type of the template of [subclenv] with the type of [mv] *)
let clenv'' =
clenv_unify true CUMUL
(clenv_instance clenv' (clenv_template_type subclenv))
(clenv_instance_type clenv' mv)
clenv'
in
(* assign the metavar *)
let clenv''' =
clenv_assign mv (clenv_instance clenv' (clenv_template subclenv)) clenv''
in
clenv'''
(* swaps the "hooks" in [clenv1] and [clenv2], so we can then use
backchain to hook them together *)
let clenv_swap clenv1 clenv2 =
let clenv1' = { templval = clenv1.templval;
templtyp = clenv1.templtyp;
namenv = clenv1.namenv;
env = clenv1.env;
hook = clenv2.hook}
and clenv2' = { templval = clenv2.templval;
templtyp = clenv2.templtyp;
namenv = clenv2.namenv;
env = clenv2.env;
hook = clenv1.hook}
in
(clenv1',clenv2')
let clenv_fchain mv nextclenv clenv =
let (clenv',nextclenv') = clenv_swap clenv nextclenv in
clenv_bchain mv clenv' nextclenv'
let clenv_refine kONT clenv gls =
tclTHEN
(kONT clenv.hook)
(refine (clenv_instance_template clenv)) gls
let clenv_refine_cast kONT clenv gls =
tclTHEN
(kONT clenv.hook)
(refine (clenv_cast_meta clenv (clenv_instance_template clenv)))
gls
(* [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 clenv mv =
match Intmap.find mv clenv.env with
| Clval(_,b) -> b.freemetas
| Cltyp b -> b.freemetas
let clenv_template_metavars clenv = clenv.templval.freemetas
(* [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_ *)
let dependent_metas clenv mvs conclmetas =
List.fold_right
(fun mv deps ->
Intset.union deps (clenv_metavars clenv mv))
mvs conclmetas
let clenv_dependent hyps_only clenv =
let mvs = collect_metas (clenv_instance_template clenv) in
let ctyp_mvs = metavars_of (clenv_instance_template_type clenv) in
let deps = dependent_metas clenv mvs ctyp_mvs in
List.filter
(fun mv -> Intset.mem mv deps && not (hyps_only && Intset.mem mv ctyp_mvs))
mvs
let clenv_missing c = clenv_dependent true c
(* [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_instance_template clenv) in
let ctyp_mvs = metavars_of (clenv_instance_template_type clenv) in
let deps = dependent_metas clenv mvs ctyp_mvs in
List.filter (fun mv -> not (Intset.mem mv deps)) mvs
let clenv_constrain_dep_args hyps_only clause = function
| [] -> clause
| mlist ->
let occlist = clenv_dependent hyps_only clause in
if List.length occlist = List.length mlist then
List.fold_left2
(fun clenv k c -> clenv_unify true CONV (mkMeta k) c clenv)
clause occlist mlist
else
error ("Not the right number of missing arguments (expected "
^(string_of_int (List.length occlist))^")")
let clenv_constrain_missing_args mlist clause =
clenv_constrain_dep_args true clause mlist
let clenv_lookup_name clenv id =
match intmap_inv clenv.namenv id with
| [] ->
errorlabstrm "clenv_lookup_name"
(str"No such bound variable " ++ pr_id id)
| [n] ->
n
| _ ->
anomaly "clenv_lookup_name: a name occurs more than once in clause"
let clenv_match_args s clause =
let mvs = clenv_independent clause in
let rec matchrec clause = function
| [] -> clause
| (b,c)::t ->
let k =
match b with
| NamedHyp s ->
if List.mem_assoc b t then
errorlabstrm "clenv_match_args"
(str "The variable " ++ pr_id s ++
str " occurs more than once in binding")
else
clenv_lookup_name clause s
| AnonHyp n ->
if List.mem_assoc b t then errorlabstrm "clenv_match_args"
(str "The position " ++ int n ++
str " occurs more than once in binding");
try
List.nth mvs (n-1)
with (Failure _|Invalid_argument _) ->
errorlabstrm "clenv_match_args" (str "No such binder")
in
let k_typ = w_hnf_constr clause.hook (clenv_instance_type clause k)
and c_typ = w_hnf_constr clause.hook (w_type_of clause.hook c) in
matchrec
(clenv_assign k c (clenv_unify true CUMUL c_typ k_typ clause)) t
in
matchrec clause s
(* [clenv_pose_dependent_evars clenv]
* 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. *)
let clenv_pose_dependent_evars clenv =
let dep_mvs = clenv_dependent false clenv in
List.fold_left
(fun clenv mv ->
let evar = Evarutil.new_evar_in_sign (w_env clenv.hook) in
let (evar_n,_) = destEvar evar in
let tY = clenv_instance_type clenv mv in
let clenv' = clenv_wtactic (w_Declare evar_n tY) clenv in
clenv_assign mv evar clenv')
clenv
dep_mvs
let clenv_add_sign (id,sign) clenv =
{ templval = clenv.templval;
templtyp = clenv.templtyp;
namenv = clenv.namenv;
env = clenv.env;
hook = w_add_sign (id,sign) clenv.hook}
(***************************)
let clenv_unique_resolver allow_K clause gl =
clenv_unify allow_K CUMUL
(clenv_instance_template_type clause) (pf_concl gl) clause
let res_pf kONT clenv gls =
clenv_refine kONT (clenv_unique_resolver false clenv gls) gls
let res_pf_cast kONT clenv gls =
clenv_refine_cast kONT (clenv_unique_resolver false clenv gls) gls
let elim_res_pf kONT clenv gls =
clenv_refine_cast kONT (clenv_unique_resolver true clenv gls) gls
let e_res_pf kONT clenv gls =
clenv_refine kONT
(clenv_pose_dependent_evars (clenv_unique_resolver false clenv gls)) gls
(* Clausal environment for an application *)
let make_clenv_binding_gen n wc (c,t) = function
| ImplicitBindings largs ->
let clause = mk_clenv_from_n wc n (c,t) in
clenv_constrain_dep_args (n <> None) clause largs
| ExplicitBindings lbind ->
let clause = mk_clenv_rename_from_n wc n (c,t) in
clenv_match_args lbind clause
| NoBindings ->
mk_clenv_from_n wc n (c,t)
let make_clenv_binding_apply wc n = make_clenv_binding_gen (Some n) wc
let make_clenv_binding = make_clenv_binding_gen None
open Printer
let pr_clenv clenv =
let pr_name mv =
try
let id = Intmap.find mv clenv.namenv in
(str"[" ++ pr_id id ++ str"]")
with Not_found -> (mt ())
in
let pr_meta_binding = function
| (mv,Cltyp b) ->
hov 0 (int mv ++ pr_name mv ++ str " : " ++ prterm b.rebus ++ fnl ())
| (mv,Clval(b,_)) ->
hov 0 (int mv ++ pr_name mv ++ str " := " ++ prterm b.rebus ++ fnl ())
in
(str"TEMPL: " ++ prterm clenv.templval.rebus ++
str" : " ++ prterm clenv.templtyp.rebus ++ fnl () ++
(prlist pr_meta_binding (intmap_to_list clenv.env)))
|