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|
(* -*- compile-command: "make -C ../.. bin/coqtop.byte" -*- *)
(************************************************************************)
(* 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: subtac_cases.ml 12194 2009-06-17 16:38:09Z msozeau $ *)
open Cases
open Util
open Names
open Nameops
open Term
open Termops
open Declarations
open Inductiveops
open Environ
open Sign
open Reductionops
open Typeops
open Type_errors
open Rawterm
open Retyping
open Pretype_errors
open Evarutil
open Evarconv
open Subtac_utils
(************************************************************************)
(* Pattern-matching compilation (Cases) *)
(************************************************************************)
(************************************************************************)
(* Configuration, errors and warnings *)
open Pp
let mssg_may_need_inversion () =
str "Found a matching with no clauses on a term unknown to have an empty inductive type"
(* Utils *)
let make_anonymous_patvars =
list_tabulate (fun _ -> PatVar (dummy_loc,Anonymous))
(* Environment management *)
let push_rels vars env = List.fold_right push_rel vars env
let push_rel_defs =
List.fold_right (fun (x,d,t) e -> push_rel (x,Some d,t) e)
(* We have x1:t1...xn:tn,xi':ti,y1..yk |- c and re-generalize
over xi:ti to get x1:t1...xn:tn,xi':ti,y1..yk |- c[xi:=xi'] *)
let regeneralize_rel i k j = if j = i+k then k else if j < i+k then j else j
let rec regeneralize_index i k t = match kind_of_term t with
| Rel j when j = i+k -> mkRel (k+1)
| Rel j when j < i+k -> t
| Rel j when j > i+k -> t
| _ -> map_constr_with_binders succ (regeneralize_index i) k t
type alias_constr =
| DepAlias
| NonDepAlias
let mkSpecialLetInJudge j (na,(deppat,nondeppat,d,t)) =
{ uj_val =
(match d with
| DepAlias -> mkLetIn (na,deppat,t,j.uj_val)
| NonDepAlias ->
if (not (dependent (mkRel 1) j.uj_type))
or (* A leaf: *) isRel deppat
then
(* The body of pat is not needed to type j - see *)
(* insert_aliases - and both deppat and nondeppat have the *)
(* same type, then one can freely substitute one by the other *)
subst1 nondeppat j.uj_val
else
(* The body of pat is not needed to type j but its value *)
(* is dependent in the type of j; our choice is to *)
(* enforce this dependency *)
mkLetIn (na,deppat,t,j.uj_val));
uj_type = subst1 deppat j.uj_type }
(**********************************************************************)
(* Structures used in compiling pattern-matching *)
type rhs =
{ rhs_env : env;
avoid_ids : identifier list;
it : rawconstr;
}
type equation =
{ patterns : cases_pattern list;
rhs : rhs;
alias_stack : name list;
eqn_loc : loc;
used : bool ref }
type matrix = equation list
(* 1st argument of IsInd is the original ind before extracting the summary *)
type tomatch_type =
| IsInd of types * inductive_type
| NotInd of constr option * types
type tomatch_status =
| Pushed of ((constr * tomatch_type) * int list)
| Alias of (constr * constr * alias_constr * constr)
| Abstract of rel_declaration
type tomatch_stack = tomatch_status list
(* The type [predicate_signature] types the terms to match and the rhs:
- [PrLetIn (names,dep,pred)] types a pushed term ([Pushed]),
if dep<>Anonymous, the term is dependent, let n=|names|, if
n<>0 then the type of the pushed term is necessarily an
inductive with n real arguments. Otherwise, it may be
non inductive, or inductive without real arguments, or inductive
originating from a subterm in which case real args are not dependent;
it accounts for n+1 binders if dep or n binders if not dep
- [PrProd] types abstracted term ([Abstract]); it accounts for one binder
- [PrCcl] types the right-hand-side
- Aliases [Alias] have no trace in [predicate_signature]
*)
type predicate_signature =
| PrLetIn of (name list * name) * predicate_signature
| PrProd of predicate_signature
| PrCcl of constr
(* We keep a constr for aliases and a cases_pattern for error message *)
type alias_builder =
| AliasLeaf
| AliasConstructor of constructor
type pattern_history =
| Top
| MakeAlias of alias_builder * pattern_continuation
and pattern_continuation =
| Continuation of int * cases_pattern list * pattern_history
| Result of cases_pattern list
let start_history n = Continuation (n, [], Top)
let initial_history = function Continuation (_,[],Top) -> true | _ -> false
let feed_history arg = function
| Continuation (n, l, h) when n>=1 ->
Continuation (n-1, arg :: l, h)
| Continuation (n, _, _) ->
anomaly ("Bad number of expected remaining patterns: "^(string_of_int n))
| Result _ ->
anomaly "Exhausted pattern history"
(* This is for non exhaustive error message *)
let rec rawpattern_of_partial_history args2 = function
| Continuation (n, args1, h) ->
let args3 = make_anonymous_patvars (n - (List.length args2)) in
build_rawpattern (List.rev_append args1 (args2@args3)) h
| Result pl -> pl
and build_rawpattern args = function
| Top -> args
| MakeAlias (AliasLeaf, rh) ->
assert (args = []);
rawpattern_of_partial_history [PatVar (dummy_loc, Anonymous)] rh
| MakeAlias (AliasConstructor pci, rh) ->
rawpattern_of_partial_history
[PatCstr (dummy_loc, pci, args, Anonymous)] rh
let complete_history = rawpattern_of_partial_history []
(* This is to build glued pattern-matching history and alias bodies *)
let rec simplify_history = function
| Continuation (0, l, Top) -> Result (List.rev l)
| Continuation (0, l, MakeAlias (f, rh)) ->
let pargs = List.rev l in
let pat = match f with
| AliasConstructor pci ->
PatCstr (dummy_loc,pci,pargs,Anonymous)
| AliasLeaf ->
assert (l = []);
PatVar (dummy_loc, Anonymous) in
feed_history pat rh
| h -> h
(* Builds a continuation expecting [n] arguments and building [ci] applied
to this [n] arguments *)
let push_history_pattern n current cont =
Continuation (n, [], MakeAlias (current, cont))
(* A pattern-matching problem has the following form:
env, isevars |- <pred> Cases tomatch of mat end
where tomatch is some sequence of "instructions" (t1 ... tn)
and mat is some matrix
(p11 ... p1n -> rhs1)
( ... )
(pm1 ... pmn -> rhsm)
Terms to match: there are 3 kinds of instructions
- "Pushed" terms to match are typed in [env]; these are usually just
Rel(n) except for the initial terms given by user and typed in [env]
- "Abstract" instructions means an abstraction has to be inserted in the
current branch to build (this means a pattern has been detected dependent
in another one and generalisation is necessary to ensure well-typing)
- "Alias" instructions means an alias has to be inserted (this alias
is usually removed at the end, except when its type is not the
same as the type of the matched term from which it comes -
typically because the inductive types are "real" parameters)
Right-hand-sides:
They consist of a raw term to type in an environment specific to the
clause they belong to: the names of declarations are those of the
variables present in the patterns. Therefore, they come with their
own [rhs_env] (actually it is the same as [env] except for the names
of variables).
*)
type pattern_matching_problem =
{ env : env;
isevars : Evd.evar_defs ref;
pred : predicate_signature option;
tomatch : tomatch_stack;
history : pattern_continuation;
mat : matrix;
caseloc : loc;
casestyle: case_style;
typing_function: type_constraint -> env -> rawconstr -> unsafe_judgment }
(*--------------------------------------------------------------------------*
* A few functions to infer the inductive type from the patterns instead of *
* checking that the patterns correspond to the ind. type of the *
* destructurated object. Allows type inference of examples like *
* match n with O => true | _ => false end *
* match x in I with C => true | _ => false end *
*--------------------------------------------------------------------------*)
(* Computing the inductive type from the matrix of patterns *)
(* We use the "in I" clause to coerce the terms to match and otherwise
use the constructor to know in which type is the matching problem
Note that insertion of coercions inside nested patterns is done
each time the matrix is expanded *)
let rec find_row_ind = function
[] -> None
| PatVar _ :: l -> find_row_ind l
| PatCstr(loc,c,_,_) :: _ -> Some (loc,c)
let inductive_template isevars env tmloc ind =
let arsign = get_full_arity_sign env ind in
let hole_source = match tmloc with
| Some loc -> fun i -> (loc, Evd.TomatchTypeParameter (ind,i))
| None -> fun _ -> (dummy_loc, Evd.InternalHole) in
let (_,evarl,_) =
List.fold_right
(fun (na,b,ty) (subst,evarl,n) ->
match b with
| None ->
let ty' = substl subst ty in
let e = e_new_evar isevars env ~src:(hole_source n) ty' in
(e::subst,e::evarl,n+1)
| Some b ->
(b::subst,evarl,n+1))
arsign ([],[],1) in
applist (mkInd ind,List.rev evarl)
(************************************************************************)
(* Utils *)
let mkExistential env ?(src=(dummy_loc,Evd.InternalHole)) isevars =
e_new_evar isevars env ~src:src (new_Type ())
let evd_comb2 f isevars x y =
let (evd',y) = f !isevars x y in
isevars := evd';
y
module Cases_F(Coercion : Coercion.S) : S = struct
let inh_coerce_to_ind isevars env ty tyi =
let expected_typ = inductive_template isevars env None tyi in
(* devrait être indifférent d'exiger leq ou pas puisque pour
un inductif cela doit être égal *)
let _ = e_cumul env isevars expected_typ ty in ()
let unify_tomatch_with_patterns isevars env loc typ pats =
match find_row_ind pats with
| None -> NotInd (None,typ)
| Some (_,(ind,_)) ->
inh_coerce_to_ind isevars env typ ind;
try IsInd (typ,find_rectype env (Evd.evars_of !isevars) typ)
with Not_found -> NotInd (None,typ)
let find_tomatch_tycon isevars env loc = function
(* Try if some 'in I ...' is present and can be used as a constraint *)
| Some (_,ind,_,_) -> mk_tycon (inductive_template isevars env loc ind)
| None -> empty_tycon
let coerce_row typing_fun isevars env pats (tomatch,(_,indopt)) =
let loc = Some (loc_of_rawconstr tomatch) in
let tycon = find_tomatch_tycon isevars env loc indopt in
let j = typing_fun tycon env tomatch in
let evd, j = Coercion.inh_coerce_to_base (loc_of_rawconstr tomatch) env !isevars j in
isevars := evd;
let typ = nf_evar (Evd.evars_of !isevars) j.uj_type in
let t =
try IsInd (typ,find_rectype env (Evd.evars_of !isevars) typ)
with Not_found ->
unify_tomatch_with_patterns isevars env loc typ pats in
(j.uj_val,t)
let coerce_to_indtype typing_fun isevars env matx tomatchl =
let pats = List.map (fun r -> r.patterns) matx in
let matx' = match matrix_transpose pats with
| [] -> List.map (fun _ -> []) tomatchl (* no patterns at all *)
| m -> m in
List.map2 (coerce_row typing_fun isevars env) matx' tomatchl
let adjust_tomatch_to_pattern pb ((current,typ),deps) =
(* Ideally, we could find a common inductive type to which both the
term to match and the patterns coerce *)
(* In practice, we coerce the term to match if it is not already an
inductive type and it is not dependent; moreover, we use only
the first pattern type and forget about the others *)
let typ = match typ with IsInd (t,_) -> t | NotInd (_,t) -> t in
let typ =
try IsInd (typ,find_rectype pb.env (Evd.evars_of !(pb.isevars)) typ)
with Not_found -> NotInd (None,typ) in
let tomatch = ((current,typ),deps) in
match typ with
| NotInd (None,typ) ->
let tm1 = List.map (fun eqn -> List.hd eqn.patterns) pb.mat in
(match find_row_ind tm1 with
| None -> tomatch
| Some (_,(ind,_)) ->
let indt = inductive_template pb.isevars pb.env None ind in
let current =
if deps = [] & isEvar typ then
(* Don't insert coercions if dependent; only solve evars *)
let _ = e_cumul pb.env pb.isevars indt typ in
current
else
(evd_comb2 (Coercion.inh_conv_coerce_to dummy_loc pb.env)
pb.isevars (make_judge current typ) (mk_tycon_type indt)).uj_val in
let sigma = Evd.evars_of !(pb.isevars) in
let typ = IsInd (indt,find_rectype pb.env sigma indt) in
((current,typ),deps))
| _ -> tomatch
(* extract some ind from [t], possibly coercing from constructors in [tm] *)
let to_mutind env isevars tm c t =
(* match c with
| Some body -> *) NotInd (c,t)
(* | None -> unify_tomatch_with_patterns isevars env t tm*)
let type_of_tomatch = function
| IsInd (t,_) -> t
| NotInd (_,t) -> t
let mkDeclTomatch na = function
| IsInd (t,_) -> (na,None,t)
| NotInd (c,t) -> (na,c,t)
let map_tomatch_type f = function
| IsInd (t,ind) -> IsInd (f t,map_inductive_type f ind)
| NotInd (c,t) -> NotInd (Option.map f c, f t)
let liftn_tomatch_type n depth = map_tomatch_type (liftn n depth)
let lift_tomatch_type n = liftn_tomatch_type n 1
let lift_tomatch n ((current,typ),info) =
((lift n current,lift_tomatch_type n typ),info)
(**********************************************************************)
(* Utilities on patterns *)
let current_pattern eqn =
match eqn.patterns with
| pat::_ -> pat
| [] -> anomaly "Empty list of patterns"
let alias_of_pat = function
| PatVar (_,name) -> name
| PatCstr(_,_,_,name) -> name
let unalias_pat = function
| PatVar (c,name) as p ->
if name = Anonymous then p else PatVar (c,Anonymous)
| PatCstr(a,b,c,name) as p ->
if name = Anonymous then p else PatCstr (a,b,c,Anonymous)
let remove_current_pattern eqn =
match eqn.patterns with
| pat::pats ->
{ eqn with
patterns = pats;
alias_stack = alias_of_pat pat :: eqn.alias_stack }
| [] -> anomaly "Empty list of patterns"
let prepend_pattern tms eqn = {eqn with patterns = tms@eqn.patterns }
(**********************************************************************)
(* Well-formedness tests *)
(* Partial check on patterns *)
exception NotAdjustable
let rec adjust_local_defs loc = function
| (pat :: pats, (_,None,_) :: decls) ->
pat :: adjust_local_defs loc (pats,decls)
| (pats, (_,Some _,_) :: decls) ->
PatVar (loc, Anonymous) :: adjust_local_defs loc (pats,decls)
| [], [] -> []
| _ -> raise NotAdjustable
let check_and_adjust_constructor env ind cstrs = function
| PatVar _ as pat -> pat
| PatCstr (loc,((_,i) as cstr),args,alias) as pat ->
(* Check it is constructor of the right type *)
let ind' = inductive_of_constructor cstr in
if Closure.mind_equiv env ind' ind then
(* Check the constructor has the right number of args *)
let ci = cstrs.(i-1) in
let nb_args_constr = ci.cs_nargs in
if List.length args = nb_args_constr then pat
else
try
let args' = adjust_local_defs loc (args, List.rev ci.cs_args)
in PatCstr (loc, cstr, args', alias)
with NotAdjustable ->
error_wrong_numarg_constructor_loc loc (Global.env())
cstr nb_args_constr
else
(* Try to insert a coercion *)
try
Coercion.inh_pattern_coerce_to loc pat ind' ind
with Not_found ->
error_bad_constructor_loc loc cstr ind
let check_all_variables typ mat =
List.iter
(fun eqn -> match current_pattern eqn with
| PatVar (_,id) -> ()
| PatCstr (loc,cstr_sp,_,_) ->
error_bad_pattern_loc loc cstr_sp typ)
mat
let check_unused_pattern env eqn =
if not !(eqn.used) then
raise_pattern_matching_error
(eqn.eqn_loc, env, UnusedClause eqn.patterns)
let set_used_pattern eqn = eqn.used := true
let extract_rhs pb =
match pb.mat with
| [] -> errorlabstrm "build_leaf" (mssg_may_need_inversion())
| eqn::_ ->
set_used_pattern eqn;
eqn.rhs
(**********************************************************************)
(* Functions to deal with matrix factorization *)
let occur_in_rhs na rhs =
match na with
| Anonymous -> false
| Name id -> occur_rawconstr id rhs.it
let is_dep_patt eqn = function
| PatVar (_,name) -> occur_in_rhs name eqn.rhs
| PatCstr _ -> true
let dependencies_in_rhs nargs eqns =
if eqns = [] then list_tabulate (fun _ -> false) nargs (* Only "_" patts *)
else
let deps = List.map (fun (tms,eqn) -> List.map (is_dep_patt eqn) tms) eqns in
let columns = matrix_transpose deps in
List.map (List.exists ((=) true)) columns
let dependent_decl a = function
| (na,None,t) -> dependent a t
| (na,Some c,t) -> dependent a t || dependent a c
(* Computing the matrix of dependencies *)
(* We are in context d1...dn |- and [find_dependencies k 1 nextlist]
computes for declaration [k+1] in which of declarations in
[nextlist] (which corresponds to d(k+2)...dn) it depends;
declarations are expressed by index, e.g. in dependency list
[n-2;1], [1] points to [dn] and [n-2] to [d3] *)
let rec find_dependency_list k n = function
| [] -> []
| (used,tdeps,d)::rest ->
let deps = find_dependency_list k (n+1) rest in
if used && dependent_decl (mkRel n) d
then list_add_set (List.length rest + 1) (list_union deps tdeps)
else deps
let find_dependencies is_dep_or_cstr_in_rhs d (k,nextlist) =
let deps = find_dependency_list k 1 nextlist in
if is_dep_or_cstr_in_rhs || deps <> []
then (k-1,(true ,deps,d)::nextlist)
else (k-1,(false,[] ,d)::nextlist)
let find_dependencies_signature deps_in_rhs typs =
let k = List.length deps_in_rhs in
let _,l = List.fold_right2 find_dependencies deps_in_rhs typs (k,[]) in
List.map (fun (_,deps,_) -> deps) l
(******)
(* A Pushed term to match has just been substituted by some
constructor t = (ci x1...xn) and the terms x1 ... xn have been added to
match
- all terms to match and to push (dependent on t by definition)
must have (Rel depth) substituted by t and Rel's>depth lifted by n
- all pushed terms to match (non dependent on t by definition) must
be lifted by n
We start with depth=1
*)
let regeneralize_index_tomatch n =
let rec genrec depth = function
| [] -> []
| Pushed ((c,tm),l)::rest ->
let c = regeneralize_index n depth c in
let tm = map_tomatch_type (regeneralize_index n depth) tm in
let l = List.map (regeneralize_rel n depth) l in
Pushed ((c,tm),l)::(genrec depth rest)
| Alias (c1,c2,d,t)::rest ->
Alias (regeneralize_index n depth c1,c2,d,t)::(genrec depth rest)
| Abstract d::rest ->
Abstract (map_rel_declaration (regeneralize_index n depth) d)
::(genrec (depth+1) rest) in
genrec 0
let rec replace_term n c k t =
if t = mkRel (n+k) then lift k c
else map_constr_with_binders succ (replace_term n c) k t
let replace_tomatch n c =
let rec replrec depth = function
| [] -> []
| Pushed ((b,tm),l)::rest ->
let b = replace_term n c depth b in
let tm = map_tomatch_type (replace_term n c depth) tm in
List.iter (fun i -> if i=n+depth then anomaly "replace_tomatch") l;
Pushed ((b,tm),l)::(replrec depth rest)
| Alias (c1,c2,d,t)::rest ->
Alias (replace_term n c depth c1,c2,d,t)::(replrec depth rest)
| Abstract d::rest ->
Abstract (map_rel_declaration (replace_term n c depth) d)
::(replrec (depth+1) rest) in
replrec 0
let liftn_rel_declaration n k = map_rel_declaration (liftn n k)
let substnl_rel_declaration sigma k = map_rel_declaration (substnl sigma k)
let rec liftn_tomatch_stack n depth = function
| [] -> []
| Pushed ((c,tm),l)::rest ->
let c = liftn n depth c in
let tm = liftn_tomatch_type n depth tm in
let l = List.map (fun i -> if i<depth then i else i+n) l in
Pushed ((c,tm),l)::(liftn_tomatch_stack n depth rest)
| Alias (c1,c2,d,t)::rest ->
Alias (liftn n depth c1,liftn n depth c2,d,liftn n depth t)
::(liftn_tomatch_stack n depth rest)
| Abstract d::rest ->
Abstract (map_rel_declaration (liftn n depth) d)
::(liftn_tomatch_stack n (depth+1) rest)
let lift_tomatch_stack n = liftn_tomatch_stack n 1
(* if [current] has type [I(p1...pn u1...um)] and we consider the case
of constructor [ci] of type [I(p1...pn u'1...u'm)], then the
default variable [name] is expected to have which type?
Rem: [current] is [(Rel i)] except perhaps for initial terms to match *)
(************************************************************************)
(* Some heuristics to get names for variables pushed in pb environment *)
(* Typical requirement:
[match y with (S (S x)) => x | x => x end] should be compiled into
[match y with O => y | (S n) => match n with O => y | (S x) => x end end]
and [match y with (S (S n)) => n | n => n end] into
[match y with O => y | (S n0) => match n0 with O => y | (S n) => n end end]
i.e. user names should be preserved and created names should not
interfere with user names *)
let merge_name get_name obj = function
| Anonymous -> get_name obj
| na -> na
let merge_names get_name = List.map2 (merge_name get_name)
let get_names env sign eqns =
let names1 = list_tabulate (fun _ -> Anonymous) (List.length sign) in
(* If any, we prefer names used in pats, from top to bottom *)
let names2 =
List.fold_right
(fun (pats,eqn) names -> merge_names alias_of_pat pats names)
eqns names1 in
(* Otherwise, we take names from the parameters of the constructor but
avoiding conflicts with user ids *)
let allvars =
List.fold_left (fun l (_,eqn) -> list_union l eqn.rhs.avoid_ids) [] eqns in
let names4,_ =
List.fold_left2
(fun (l,avoid) d na ->
let na =
merge_name
(fun (na,_,t) -> Name (next_name_away (named_hd env t na) avoid))
d na
in
(na::l,(out_name na)::avoid))
([],allvars) (List.rev sign) names2 in
names4
(************************************************************************)
(* Recovering names for variables pushed to the rhs' environment *)
let recover_alias_names get_name = List.map2 (fun x (_,c,t) ->(get_name x,c,t))
let all_name sign = List.map (fun (n, b, t) -> let n = match n with Name _ -> n | Anonymous -> Name (id_of_string "Anonymous") in
(n, b, t)) sign
let push_rels_eqn sign eqn =
let sign = all_name sign in
{eqn with rhs = {eqn.rhs with rhs_env = push_rels sign eqn.rhs.rhs_env; } }
let push_rels_eqn_with_names sign eqn =
let pats = List.rev (list_firstn (List.length sign) eqn.patterns) in
let sign = recover_alias_names alias_of_pat pats sign in
push_rels_eqn sign eqn
let build_aliases_context env sigma names allpats pats =
(* pats is the list of bodies to push as an alias *)
(* They all are defined in env and we turn them into a sign *)
(* cuts in sign need to be done in allpats *)
let rec insert env sign1 sign2 n newallpats oldallpats = function
| (deppat,_,_,_)::pats, Anonymous::names when not (isRel deppat) ->
(* Anonymous leaves must be considered named and treated in the *)
(* next clause because they may occur in implicit arguments *)
insert env sign1 sign2
n newallpats (List.map List.tl oldallpats) (pats,names)
| (deppat,nondeppat,d,t)::pats, na::names ->
let nondeppat = lift n nondeppat in
let deppat = lift n deppat in
let newallpats =
List.map2 (fun l1 l2 -> List.hd l2::l1) newallpats oldallpats in
let oldallpats = List.map List.tl oldallpats in
let decl = (na,Some deppat,t) in
let a = (deppat,nondeppat,d,t) in
insert (push_rel decl env) (decl::sign1) ((na,a)::sign2) (n+1)
newallpats oldallpats (pats,names)
| [], [] -> newallpats, sign1, sign2, env
| _ -> anomaly "Inconsistent alias and name lists" in
let allpats = List.map (fun x -> [x]) allpats
in insert env [] [] 0 (List.map (fun _ -> []) allpats) allpats (pats, names)
let insert_aliases_eqn sign eqnnames alias_rest eqn =
let thissign = List.map2 (fun na (_,c,t) -> (na,c,t)) eqnnames sign in
push_rels_eqn thissign { eqn with alias_stack = alias_rest; }
let insert_aliases env sigma alias eqns =
(* Là, y a une faiblesse, si un alias est utilisé dans un cas par *)
(* défaut présent mais inutile, ce qui est le cas général, l'alias *)
(* est introduit même s'il n'est pas utilisé dans les cas réguliers *)
let eqnsnames = List.map (fun eqn -> List.hd eqn.alias_stack) eqns in
let alias_rests = List.map (fun eqn -> List.tl eqn.alias_stack) eqns in
(* names2 takes the meet of all needed aliases *)
let names2 =
List.fold_right (merge_name (fun x -> x)) eqnsnames Anonymous in
(* Only needed aliases are kept by build_aliases_context *)
let eqnsnames, sign1, sign2, env =
build_aliases_context env sigma [names2] eqnsnames [alias] in
let eqns = list_map3 (insert_aliases_eqn sign1) eqnsnames alias_rests eqns in
sign2, env, eqns
(**********************************************************************)
(* Functions to deal with elimination predicate *)
exception Occur
let noccur_between_without_evar n m term =
let rec occur_rec n c = match kind_of_term c with
| Rel p -> if n<=p && p<n+m then raise Occur
| Evar (_,cl) -> ()
| _ -> iter_constr_with_binders succ occur_rec n c
in
try occur_rec n term; true with Occur -> false
(* Inferring the predicate *)
let prepare_unif_pb typ cs =
let n = List.length (assums_of_rel_context cs.cs_args) in
(* We may need to invert ci if its parameters occur in typ *)
let typ' =
if noccur_between_without_evar 1 n typ then lift (-n) typ
else (* TODO4-1 *)
error "Unable to infer return clause of this pattern-matching problem" in
let args = extended_rel_list (-n) cs.cs_args in
let ci = applist (mkConstruct cs.cs_cstr, cs.cs_params@args) in
(* This is the problem: finding P s.t. cs_args |- (P realargs ci) = typ' *)
(Array.map (lift (-n)) cs.cs_concl_realargs, ci, typ')
(* Infering the predicate *)
(*
The problem to solve is the following:
We match Gamma |- t : I(u01..u0q) against the following constructors:
Gamma, x11...x1p1 |- C1(x11..x1p1) : I(u11..u1q)
...
Gamma, xn1...xnpn |- Cn(xn1..xnp1) : I(un1..unq)
Assume the types in the branches are the following
Gamma, x11...x1p1 |- branch1 : T1
...
Gamma, xn1...xnpn |- branchn : Tn
Assume the type of the global case expression is Gamma |- T
The predicate has the form phi = [y1..yq][z:I(y1..yq)]? and must satisfy
the following n+1 equations:
Gamma, x11...x1p1 |- (phi u11..u1q (C1 x11..x1p1)) = T1
...
Gamma, xn1...xnpn |- (phi un1..unq (Cn xn1..xnpn)) = Tn
Gamma |- (phi u01..u0q t) = T
Some hints:
- Clearly, if xij occurs in Ti, then, a "match z with (Ci xi1..xipi) => ..."
should be inserted somewhere in Ti.
- If T is undefined, an easy solution is to insert a "match z with (Ci
xi1..xipi) => ..." in front of each Ti
- Otherwise, T1..Tn and T must be step by step unified, if some of them
diverge, then try to replace the diverging subterm by one of y1..yq or z.
- The main problem is what to do when an existential variables is encountered
let prepare_unif_pb typ cs =
let n = cs.cs_nargs in
let _,p = decompose_prod_n n typ in
let ci = build_dependent_constructor cs in
(* This is the problem: finding P s.t. cs_args |- (P realargs ci) = p *)
(n, cs.cs_concl_realargs, ci, p)
let eq_operator_lift k (n,n') = function
| OpRel p, OpRel p' when p > k & p' > k ->
if p < k+n or p' < k+n' then false else p - n = p' - n'
| op, op' -> op = op'
let rec transpose_args n =
if n=0 then []
else
(Array.map (fun l -> List.hd l) lv)::
(transpose_args (m-1) (Array.init (fun l -> List.tl l)))
let shift_operator k = function OpLambda _ | OpProd _ -> k+1 | _ -> k
let reloc_operator (k,n) = function OpRel p when p > k ->
let rec unify_clauses k pv =
let pv'= Array.map (fun (n,sign,_,p) -> n,splay_constr (whd_betaiotaevar (push_rels (List.rev sign) env) (Evd.evars_of isevars)) p) pv in
let n1,op1 = let (n1,(op1,args1)) = pv'.(0) in n1,op1 in
if Array.for_all (fun (ni,(opi,_)) -> eq_operator_lift k (n1,ni) (op1,opi)) pv'
then
let argvl = transpose_args (List.length args1) pv' in
let k' = shift_operator k op1 in
let argl = List.map (unify_clauses k') argvl in
gather_constr (reloc_operator (k,n1) op1) argl
*)
let abstract_conclusion typ cs =
let n = List.length (assums_of_rel_context cs.cs_args) in
let (sign,p) = decompose_prod_n n typ in
lam_it p sign
let infer_predicate loc env isevars typs cstrs indf =
(* Il faudra substituer les isevars a un certain moment *)
if Array.length cstrs = 0 then (* "TODO4-3" *)
error "Inference of annotation for empty inductive types not implemented"
else
(* Empiric normalization: p may depend in a irrelevant way on args of the*)
(* cstr as in [c:{_:Alpha & Beta}] match c with (existS a b)=>(a,b) end *)
let typs =
Array.map (local_strong whd_beta (Evd.evars_of !isevars)) typs
in
let eqns = array_map2 prepare_unif_pb typs cstrs in
(* First strategy: no dependencies at all *)
(*
let (mis,_) = dest_ind_family indf in
let (cclargs,_,typn) = eqns.(mis_nconstr mis -1) in
*)
let (sign,_) = get_arity env indf in
let mtyp =
if array_exists is_Type typs then
(* Heuristic to avoid comparison between non-variables algebric univs*)
new_Type ()
else
mkExistential env ~src:(loc, Evd.CasesType) isevars
in
if array_for_all (fun (_,_,typ) -> e_cumul env isevars typ mtyp) eqns
then
(* Non dependent case -> turn it into a (dummy) dependent one *)
let sign = (Anonymous,None,build_dependent_inductive env indf)::sign in
let pred = it_mkLambda_or_LetIn (lift (List.length sign) mtyp) sign in
(true,pred) (* true = dependent -- par défaut *)
else
(*
let s = get_sort_of env (evars_of isevars) typs.(0) in
let predpred = it_mkLambda_or_LetIn (mkSort s) sign in
let caseinfo = make_default_case_info mis in
let brs = array_map2 abstract_conclusion typs cstrs in
let predbody = mkCase (caseinfo, (nf_betaiota predpred), mkRel 1, brs) in
let pred = it_mkLambda_or_LetIn (lift (List.length sign) mtyp) sign in
*)
(* "TODO4-2" *)
(* We skip parameters *)
let cis =
Array.map
(fun cs ->
applist (mkConstruct cs.cs_cstr, extended_rel_list 0 cs.cs_args))
cstrs in
let ct = array_map2 (fun ci (_,_,t) -> (ci,t)) cis eqns in
raise_pattern_matching_error (loc,env, CannotInferPredicate ct)
(*
(true,pred)
*)
(* Propagation of user-provided predicate through compilation steps *)
let rec map_predicate f k = function
| PrCcl ccl -> PrCcl (f k ccl)
| PrProd pred ->
PrProd (map_predicate f (k+1) pred)
| PrLetIn ((names,dep as tm),pred) ->
let k' = List.length names + (if dep<>Anonymous then 1 else 0) in
PrLetIn (tm, map_predicate f (k+k') pred)
let rec noccurn_predicate k = function
| PrCcl ccl -> noccurn k ccl
| PrProd pred -> noccurn_predicate (k+1) pred
| PrLetIn ((names,dep),pred) ->
let k' = List.length names + (if dep<>Anonymous then 1 else 0) in
noccurn_predicate (k+k') pred
let liftn_predicate n = map_predicate (liftn n)
let lift_predicate n = liftn_predicate n 1
let regeneralize_index_predicate n = map_predicate (regeneralize_index n) 0
let substnl_predicate sigma = map_predicate (substnl sigma)
(* This is parallel bindings *)
let subst_predicate (args,copt) pred =
let sigma = match copt with
| None -> List.rev args
| Some c -> c::(List.rev args) in
substnl_predicate sigma 0 pred
let specialize_predicate_var (cur,typ) = function
| PrProd _ | PrCcl _ ->
anomaly "specialize_predicate_var: a pattern-variable must be pushed"
| PrLetIn (([],dep),pred) ->
subst_predicate ([],if dep<>Anonymous then Some cur else None) pred
| PrLetIn ((_,dep),pred) ->
(match typ with
| IsInd (_,IndType (_,realargs)) ->
subst_predicate (realargs,if dep<>Anonymous then Some cur else None) pred
| _ -> anomaly "specialize_predicate_var")
let ungeneralize_predicate = function
| PrLetIn _ | PrCcl _ -> anomaly "ungeneralize_predicate: expects a product"
| PrProd pred -> pred
(*****************************************************************************)
(* We have pred = [X:=realargs;x:=c]P typed in Gamma1, x:I(realargs), Gamma2 *)
(* and we want to abstract P over y:t(x) typed in the same context to get *)
(* *)
(* pred' = [X:=realargs;x':=c](y':t(x'))P[y:=y'] *)
(* *)
(* We first need to lift t(x) s.t. it is typed in Gamma, X:=rargs, x' *)
(* then we have to replace x by x' in t(x) and y by y' in P *)
(*****************************************************************************)
let generalize_predicate ny d = function
| PrLetIn ((names,dep as tm),pred) ->
if dep=Anonymous then anomaly "Undetected dependency";
let p = List.length names + 1 in
let pred = lift_predicate 1 pred in
let pred = regeneralize_index_predicate (ny+p+1) pred in
PrLetIn (tm, PrProd pred)
| PrProd _ | PrCcl _ ->
anomaly "generalize_predicate: expects a non trivial pattern"
let rec extract_predicate l = function
| pred, Alias (deppat,nondeppat,_,_)::tms ->
let tms' = match kind_of_term nondeppat with
| Rel i -> replace_tomatch i deppat tms
| _ -> (* initial terms are not dependent *) tms in
extract_predicate l (pred,tms')
| PrProd pred, Abstract d'::tms ->
let d' = map_rel_declaration (lift (List.length l)) d' in
substl l (mkProd_or_LetIn d' (extract_predicate [] (pred,tms)))
| PrLetIn (([],dep),pred), Pushed ((cur,_),_)::tms ->
extract_predicate (if dep<>Anonymous then cur::l else l) (pred,tms)
| PrLetIn ((_,dep),pred), Pushed ((cur,IsInd (_,(IndType(_,realargs)))),_)::tms ->
let l = List.rev realargs@l in
extract_predicate (if dep<>Anonymous then cur::l else l) (pred,tms)
| PrCcl ccl, [] ->
substl l ccl
| _ -> anomaly"extract_predicate: predicate inconsistent with terms to match"
let abstract_predicate env sigma indf cur tms = function
| (PrProd _ | PrCcl _) -> anomaly "abstract_predicate: must be some LetIn"
| PrLetIn ((names,dep),pred) ->
let sign = make_arity_signature env true indf in
(* n is the number of real args + 1 *)
let n = List.length sign in
let tms = lift_tomatch_stack n tms in
let tms =
match kind_of_term cur with
| Rel i -> regeneralize_index_tomatch (i+n) tms
| _ -> (* Initial case *) tms in
(* Depending on whether the predicate is dependent or not, and has real
args or not, we lift it to make room for [sign] *)
(* Even if not intrinsically dep, we move the predicate into a dep one *)
let sign,k =
if names = [] & n <> 1 then
(* Real args were not considered *)
(if dep<>Anonymous then
((let (_,c,t) = List.hd sign in (dep,c,t)::List.tl sign),n-1)
else
(sign,n))
else
(* Real args are OK *)
(List.map2 (fun na (_,c,t) -> (na,c,t)) (dep::names) sign,
if dep<>Anonymous then 0 else 1) in
let pred = lift_predicate k pred in
let pred = extract_predicate [] (pred,tms) in
(true, it_mkLambda_or_LetIn_name env pred sign)
let rec known_dependent = function
| None -> false
| Some (PrLetIn ((_,dep),_)) -> dep<>Anonymous
| Some (PrCcl _) -> false
| Some (PrProd _) ->
anomaly "known_dependent: can only be used when patterns remain"
(* [expand_arg] is used by [specialize_predicate]
it replaces gamma, x1...xn, x1...xk |- pred
by gamma, x1...xn, x1...xk-1 |- [X=realargs,xk=xk]pred (if dep) or
by gamma, x1...xn, x1...xk-1 |- [X=realargs]pred (if not dep) *)
let expand_arg n alreadydep (na,t) deps (k,pred) =
(* current can occur in pred even if the original problem is not dependent *)
let dep =
if alreadydep<>Anonymous then alreadydep
else if deps = [] && noccurn_predicate 1 pred then Anonymous
else Name (id_of_string "x") in
let pred = if dep<>Anonymous then pred else lift_predicate (-1) pred in
(* There is no dependency in realargs for subpattern *)
(k-1, PrLetIn (([],dep), pred))
(*****************************************************************************)
(* pred = [X:=realargs;x:=c]P types the following problem: *)
(* *)
(* Gamma |- match Pushed(c:I(realargs)) rest with...end: pred *)
(* *)
(* where the branch with constructor Ci:(x1:T1)...(xn:Tn)->I(realargsi) *)
(* is considered. Assume each Ti is some Ii(argsi). *)
(* We let e=Ci(x1,...,xn) and replace pred by *)
(* *)
(* pred' = [X1:=rargs1,x1:=x1']...[Xn:=rargsn,xn:=xn'](P[X:=realargsi;x:=e]) *)
(* *)
(* s.t Gamma,x1'..xn' |- match Pushed(x1')..Pushed(xn') rest with..end :pred'*)
(* *)
(*****************************************************************************)
let specialize_predicate tomatchs deps cs = function
| (PrProd _ | PrCcl _) ->
anomaly "specialize_predicate: a matched pattern must be pushed"
| PrLetIn ((names,isdep),pred) ->
(* Assume some gamma st: gamma, (X,x:=realargs,copt) |- pred *)
let nrealargs = List.length names in
let k = nrealargs + (if isdep<>Anonymous then 1 else 0) in
(* We adjust pred st: gamma, x1..xn, (X,x:=realargs,copt) |- pred' *)
let n = cs.cs_nargs in
let pred' = liftn_predicate n (k+1) pred in
let argsi = if nrealargs <> 0 then Array.to_list cs.cs_concl_realargs else [] in
let copti = if isdep<>Anonymous then Some (build_dependent_constructor cs) else None in
(* The substituends argsi, copti are all defined in gamma, x1...xn *)
(* We need _parallel_ bindings to get gamma, x1...xn |- pred'' *)
let pred'' = subst_predicate (argsi, copti) pred' in
(* We adjust pred st: gamma, x1..xn, x1..xn |- pred'' *)
let pred''' = liftn_predicate n (n+1) pred'' in
(* We finally get gamma,x1..xn |- [X1,x1:=R1,x1]..[Xn,xn:=Rn,xn]pred'''*)
snd (List.fold_right2 (expand_arg n isdep) tomatchs deps (n,pred'''))
let find_predicate loc env isevars p typs cstrs current
(IndType (indf,realargs)) tms =
let (dep,pred) =
match p with
| Some p -> abstract_predicate env (Evd.evars_of !isevars) indf current tms p
| None -> infer_predicate loc env isevars typs cstrs indf in
let typ = whd_beta (Evd.evars_of !isevars) (applist (pred, realargs)) in
if dep then
(pred, whd_beta (Evd.evars_of !isevars) (applist (typ, [current])),
new_Type ())
else
(pred, typ, new_Type ())
(************************************************************************)
(* Sorting equations by constructor *)
type inversion_problem =
(* the discriminating arg in some Ind and its order in Ind *)
| Incompatible of int * (int * int)
| Constraints of (int * constr) list
let solve_constraints constr_info indt =
(* TODO *)
Constraints []
let rec irrefutable env = function
| PatVar (_,name) -> true
| PatCstr (_,cstr,args,_) ->
let ind = inductive_of_constructor cstr in
let (_,mip) = Inductive.lookup_mind_specif env ind in
let one_constr = Array.length mip.mind_user_lc = 1 in
one_constr & List.for_all (irrefutable env) args
let first_clause_irrefutable env = function
| eqn::mat -> List.for_all (irrefutable env) eqn.patterns
| _ -> false
let group_equations pb ind current cstrs mat =
let mat =
if first_clause_irrefutable pb.env mat then [List.hd mat] else mat in
let brs = Array.create (Array.length cstrs) [] in
let only_default = ref true in
let _ =
List.fold_right (* To be sure it's from bottom to top *)
(fun eqn () ->
let rest = remove_current_pattern eqn in
let pat = current_pattern eqn in
match check_and_adjust_constructor pb.env ind cstrs pat with
| PatVar (_,name) ->
(* This is a default clause that we expand *)
for i=1 to Array.length cstrs do
let n = cstrs.(i-1).cs_nargs in
let args = make_anonymous_patvars n in
brs.(i-1) <- (args, rest) :: brs.(i-1)
done
| PatCstr (loc,((_,i)),args,_) ->
(* This is a regular clause *)
only_default := false;
brs.(i-1) <- (args,rest) :: brs.(i-1)) mat () in
(brs,!only_default)
(************************************************************************)
(* Here starts the pattern-matching compilation algorithm *)
(* Abstracting over dependent subterms to match *)
let rec generalize_problem pb = function
| [] -> pb
| i::l ->
let d = map_rel_declaration (lift i) (Environ.lookup_rel i pb.env) in
let pb' = generalize_problem pb l in
let tomatch = lift_tomatch_stack 1 pb'.tomatch in
let tomatch = regeneralize_index_tomatch (i+1) tomatch in
{ pb with
tomatch = Abstract d :: tomatch;
pred = Option.map (generalize_predicate i d) pb'.pred }
(* No more patterns: typing the right-hand-side of equations *)
let build_leaf pb =
let rhs = extract_rhs pb in
let tycon = match pb.pred with
| None -> anomaly "Predicate not found"
| Some (PrCcl typ) -> mk_tycon typ
| Some _ -> anomaly "not all parameters of pred have been consumed" in
pb.typing_function tycon rhs.rhs_env rhs.it
(* Building the sub-problem when all patterns are variables *)
let shift_problem (current,t) pb =
{pb with
tomatch = Alias (current,current,NonDepAlias,type_of_tomatch t)::pb.tomatch;
pred = Option.map (specialize_predicate_var (current,t)) pb.pred;
history = push_history_pattern 0 AliasLeaf pb.history;
mat = List.map remove_current_pattern pb.mat }
(* Building the sub-pattern-matching problem for a given branch *)
let build_branch current deps pb eqns const_info =
(* We remember that we descend through a constructor *)
let alias_type =
if Array.length const_info.cs_concl_realargs = 0
& not (known_dependent pb.pred) & deps = []
then
NonDepAlias
else
DepAlias
in
let history =
push_history_pattern const_info.cs_nargs
(AliasConstructor const_info.cs_cstr)
pb.history in
(* We find matching clauses *)
let cs_args = (*assums_of_rel_context*) const_info.cs_args in
let names = get_names pb.env cs_args eqns in
let submat = List.map (fun (tms,eqn) -> prepend_pattern tms eqn) eqns in
if submat = [] then
raise_pattern_matching_error
(dummy_loc, pb.env, NonExhaustive (complete_history history));
let typs = List.map2 (fun (_,c,t) na -> (na,c,t)) cs_args names in
let _,typs',_ =
List.fold_right
(fun (na,c,t as d) (env,typs,tms) ->
let tm1 = List.map List.hd tms in
let tms = List.map List.tl tms in
(push_rel d env, (na,to_mutind env pb.isevars tm1 c t)::typs,tms))
typs (pb.env,[],List.map fst eqns) in
let dep_sign =
find_dependencies_signature
(dependencies_in_rhs const_info.cs_nargs eqns) (List.rev typs) in
(* The dependent term to subst in the types of the remaining UnPushed
terms is relative to the current context enriched by topushs *)
let ci = build_dependent_constructor const_info in
(* We replace [(mkRel 1)] by its expansion [ci] *)
(* and context "Gamma = Gamma1, current, Gamma2" by "Gamma;typs;curalias" *)
(* This is done in two steps : first from "Gamma |- tms" *)
(* into "Gamma; typs; curalias |- tms" *)
let tomatch = lift_tomatch_stack const_info.cs_nargs pb.tomatch in
let currents =
list_map2_i
(fun i (na,t) deps -> Pushed ((mkRel i, lift_tomatch_type i t), deps))
1 typs' (List.rev dep_sign) in
let sign = List.map (fun (na,t) -> mkDeclTomatch na t) typs' in
let ind =
appvect (
applist (mkInd (inductive_of_constructor const_info.cs_cstr),
List.map (lift const_info.cs_nargs) const_info.cs_params),
const_info.cs_concl_realargs) in
let cur_alias = lift (List.length sign) current in
let currents = Alias (ci,cur_alias,alias_type,ind) :: currents in
let env' = push_rels sign pb.env in
let pred' = Option.map (specialize_predicate (List.rev typs') dep_sign const_info) pb.pred in
sign,
{ pb with
env = env';
tomatch = List.rev_append currents tomatch;
pred = pred';
history = history;
mat = List.map (push_rels_eqn_with_names sign) submat }
(**********************************************************************
INVARIANT:
pb = { env, subst, tomatch, mat, ...}
tomatch = list of Pushed (c:T) or Abstract (na:T) or Alias (c:T)
"Pushed" terms and types are relative to env
"Abstract" types are relative to env enriched by the previous terms to match
*)
(**********************************************************************)
(* Main compiling descent *)
let rec compile pb =
match pb.tomatch with
| (Pushed cur)::rest -> match_current { pb with tomatch = rest } cur
| (Alias x)::rest -> compile_alias pb x rest
| (Abstract d)::rest -> compile_generalization pb d rest
| [] -> build_leaf pb
and match_current pb tomatch =
let ((current,typ as ct),deps) = adjust_tomatch_to_pattern pb tomatch in
match typ with
| NotInd (_,typ) ->
check_all_variables typ pb.mat;
compile (shift_problem ct pb)
| IsInd (_,(IndType(indf,realargs) as indt)) ->
let mind,_ = dest_ind_family indf in
let cstrs = get_constructors pb.env indf in
let eqns,onlydflt = group_equations pb mind current cstrs pb.mat in
if (Array.length cstrs <> 0 or pb.mat <> []) & onlydflt then
compile (shift_problem ct pb)
else
let _constraints = Array.map (solve_constraints indt) cstrs in
(* We generalize over terms depending on current term to match *)
let pb = generalize_problem pb deps in
(* We compile branches *)
let brs = array_map2 (compile_branch current deps pb) eqns cstrs in
(* We build the (elementary) case analysis *)
let brvals = Array.map (fun (v,_) -> v) brs in
let brtyps = Array.map (fun (_,t) -> t) brs in
let (pred,typ,s) =
find_predicate pb.caseloc pb.env pb.isevars
pb.pred brtyps cstrs current indt pb.tomatch in
let ci = make_case_info pb.env mind pb.casestyle in
let case = mkCase (ci,nf_betaiota Evd.empty pred,current,brvals) in
let inst = List.map mkRel deps in
{ uj_val = applist (case, inst);
uj_type = substl inst typ }
and compile_branch current deps pb eqn cstr =
let sign, pb = build_branch current deps pb eqn cstr in
let j = compile pb in
(it_mkLambda_or_LetIn j.uj_val sign, j.uj_type)
and compile_generalization pb d rest =
let pb =
{ pb with
env = push_rel d pb.env;
tomatch = rest;
pred = Option.map ungeneralize_predicate pb.pred;
mat = List.map (push_rels_eqn [d]) pb.mat } in
let j = compile pb in
{ uj_val = mkLambda_or_LetIn d j.uj_val;
uj_type = mkProd_or_LetIn d j.uj_type }
and compile_alias pb (deppat,nondeppat,d,t) rest =
let history = simplify_history pb.history in
let sign, newenv, mat =
insert_aliases pb.env (Evd.evars_of !(pb.isevars)) (deppat,nondeppat,d,t) pb.mat in
let n = List.length sign in
(* We had Gamma1; x:current; Gamma2 |- tomatch(x) and we rebind x to get *)
(* Gamma1; x:current; Gamma2; typs; x':=curalias |- tomatch(x') *)
let tomatch = lift_tomatch_stack n rest in
let tomatch = match kind_of_term nondeppat with
| Rel i ->
if n = 1 then regeneralize_index_tomatch (i+n) tomatch
else replace_tomatch i deppat tomatch
| _ -> (* initial terms are not dependent *) tomatch in
let pb =
{pb with
env = newenv;
tomatch = tomatch;
pred = Option.map (lift_predicate n) pb.pred;
history = history;
mat = mat } in
let j = compile pb in
List.fold_left mkSpecialLetInJudge j sign
(* pour les alias des initiaux, enrichir les env de ce qu'il faut et
substituer après par les initiaux *)
(**************************************************************************)
(* Preparation of the pattern-matching problem *)
(* builds the matrix of equations testing that each eqn has n patterns
* and linearizing the _ patterns.
* Syntactic correctness has already been done in astterm *)
let matx_of_eqns env eqns =
let build_eqn (loc,ids,lpat,rhs) =
let rhs =
{ rhs_env = env;
avoid_ids = ids@(ids_of_named_context (named_context env));
it = rhs;
} in
{ patterns = lpat;
alias_stack = [];
eqn_loc = loc;
used = ref false;
rhs = rhs }
in List.map build_eqn eqns
(************************************************************************)
(* preparing the elimination predicate if any *)
let oldprepare_predicate_from_tycon loc dep env isevars tomatchs sign c =
let cook (n, l, env, signs) = function
| c,IsInd (_,IndType(indf,realargs)) ->
let indf' = lift_inductive_family n indf in
let sign = make_arity_signature env dep indf' in
let p = List.length realargs in
if dep then
(n + p + 1, c::(List.rev realargs)@l, push_rels sign env,sign::signs)
else
(n + p, (List.rev realargs)@l, push_rels sign env,sign::signs)
| c,NotInd _ ->
(n, l, env, []::signs) in
let n, allargs, env, signs = List.fold_left cook (0, [], env, []) tomatchs in
let names = List.rev (List.map (List.map pi1) signs) in
let allargs =
List.map (fun c -> lift n (nf_betadeltaiota env (Evd.evars_of !isevars) c)) allargs in
let rec build_skeleton env c =
(* Don't put into normal form, it has effects on the synthesis of evars *)
(* let c = whd_betadeltaiota env (evars_of isevars) c in *)
(* We turn all subterms possibly dependent into an evar with maximum ctxt*)
if isEvar c or List.exists (eq_constr c) allargs then
e_new_evar isevars env ~src:(loc, Evd.CasesType)
(Retyping.get_type_of env (Evd.evars_of !isevars) c)
else
map_constr_with_full_binders push_rel build_skeleton env c
in
names, build_skeleton env (lift n c)
(* Here, [pred] is assumed to be in the context built from all *)
(* realargs and terms to match *)
let build_initial_predicate isdep allnames pred =
let nar = List.fold_left (fun n names -> List.length names + n) 0 allnames in
let rec buildrec n pred = function
| [] -> PrCcl pred
| names::lnames ->
let names' = if isdep then List.tl names else names in
let n' = n + List.length names' in
let pred, p, user_p =
if isdep then
if dependent (mkRel (nar-n')) pred then pred, 1, 1
else liftn (-1) (nar-n') pred, 0, 1
else pred, 0, 0 in
let na =
if p=1 then
let na = List.hd names in
if na = Anonymous then
(* peut arriver en raison des evars *)
Name (id_of_string "x") (*Hum*)
else na
else Anonymous in
PrLetIn ((names',na), buildrec (n'+user_p) pred lnames)
in buildrec 0 pred allnames
let extract_arity_signature env0 tomatchl tmsign =
let get_one_sign n tm (na,t) =
match tm with
| NotInd (bo,typ) ->
(match t with
| None -> [na,Option.map (lift n) bo,lift n typ]
| Some (loc,_,_,_) ->
user_err_loc (loc,"",
str "Unexpected type annotation for a term of non inductive type"))
| IsInd (_,IndType(indf,realargs)) ->
let indf' = lift_inductive_family n indf in
let (ind,params) = dest_ind_family indf' in
let nrealargs = List.length realargs in
let realnal =
match t with
| Some (loc,ind',nparams,realnal) ->
if ind <> ind' then
user_err_loc (loc,"",str "Wrong inductive type");
if List.length params <> nparams
or nrealargs <> List.length realnal then
anomaly "Ill-formed 'in' clause in cases";
List.rev realnal
| None -> list_tabulate (fun _ -> Anonymous) nrealargs in
let arsign = fst (get_arity env0 indf') in
(na,None,build_dependent_inductive env0 indf')
::(List.map2 (fun x (_,c,t) ->(x,c,t)) realnal arsign) in
let rec buildrec n = function
| [],[] -> []
| (_,tm)::ltm, x::tmsign ->
let l = get_one_sign n tm x in
l :: buildrec (n + List.length l) (ltm,tmsign)
| _ -> assert false
in List.rev (buildrec 0 (tomatchl,tmsign))
let extract_arity_signatures env0 tomatchl tmsign =
let get_one_sign tm (na,t) =
match tm with
| NotInd (bo,typ) ->
(match t with
| None -> [na,bo,typ]
| Some (loc,_,_,_) ->
user_err_loc (loc,"",
str "Unexpected type annotation for a term of non inductive type"))
| IsInd (_,IndType(indf,realargs)) ->
let (ind,params) = dest_ind_family indf in
let nrealargs = List.length realargs in
let realnal =
match t with
| Some (loc,ind',nparams,realnal) ->
if ind <> ind' then
user_err_loc (loc,"",str "Wrong inductive type");
if List.length params <> nparams
or nrealargs <> List.length realnal then
anomaly "Ill-formed 'in' clause in cases";
List.rev realnal
| None -> list_tabulate (fun _ -> Anonymous) nrealargs in
let arsign = fst (get_arity env0 indf) in
(na,None,build_dependent_inductive env0 indf)
::(try List.map2 (fun x (_,c,t) ->(x,c,t)) realnal arsign with _ -> assert false) in
let rec buildrec = function
| [],[] -> []
| (_,tm)::ltm, x::tmsign ->
let l = get_one_sign tm x in
l :: buildrec (ltm,tmsign)
| _ -> assert false
in List.rev (buildrec (tomatchl,tmsign))
let inh_conv_coerce_to_tycon loc env isevars j tycon =
match tycon with
| Some p ->
let (evd',j) = Coercion.inh_conv_coerce_to loc env !isevars j p in
isevars := evd';
j
| None -> j
let out_ind = function IsInd (_, IndType(x, y)) -> (x, y) | _ -> assert(false)
let string_of_name name =
match name with
| Anonymous -> "anonymous"
| Name n -> string_of_id n
let id_of_name n = id_of_string (string_of_name n)
let make_prime_id name =
let str = string_of_name name in
id_of_string str, id_of_string (str ^ "'")
let prime avoid name =
let previd, id = make_prime_id name in
previd, next_ident_away_from id avoid
let make_prime avoid prevname =
let previd, id = prime !avoid prevname in
avoid := id :: !avoid;
previd, id
let eq_id avoid id =
let hid = id_of_string ("Heq_" ^ string_of_id id) in
let hid' = next_ident_away_from hid avoid in
hid'
let mk_eq typ x y = mkApp (Lazy.force eq_ind, [| typ; x ; y |])
let mk_eq_refl typ x = mkApp (Lazy.force eq_refl, [| typ; x |])
let hole = RHole (dummy_loc, Evd.QuestionMark (Evd.Define true))
let context_of_arsign l =
let (x, _) = List.fold_right
(fun c (x, n) ->
(lift_rel_context n c @ x, List.length c + n))
l ([], 0)
in x
let constr_of_pat env isevars arsign pat avoid =
let rec typ env (ty, realargs) pat avoid =
match pat with
| PatVar (l,name) ->
let name, avoid = match name with
Name n -> name, avoid
| Anonymous ->
let previd, id = prime avoid (Name (id_of_string "wildcard")) in
Name id, id :: avoid
in
PatVar (l, name), [name, None, ty] @ realargs, mkRel 1, ty, (List.map (fun x -> mkRel 1) realargs), 1, avoid
| PatCstr (l,((_, i) as cstr),args,alias) ->
let cind = inductive_of_constructor cstr in
let IndType (indf, _) = find_rectype env (Evd.evars_of !isevars) (lift (-(List.length realargs)) ty) in
let ind, params = dest_ind_family indf in
if ind <> cind then error_bad_constructor_loc l cstr ind;
let cstrs = get_constructors env indf in
let ci = cstrs.(i-1) in
let nb_args_constr = ci.cs_nargs in
assert(nb_args_constr = List.length args);
let patargs, args, sign, env, n, m, avoid =
List.fold_right2
(fun (na, c, t) ua (patargs, args, sign, env, n, m, avoid) ->
let pat', sign', arg', typ', argtypargs, n', avoid =
typ env (lift (n - m) t, []) ua avoid
in
let args' = arg' :: List.map (lift n') args in
let env' = push_rels sign' env in
(pat' :: patargs, args', sign' @ sign, env', n' + n, succ m, avoid))
ci.cs_args (List.rev args) ([], [], [], env, 0, 0, avoid)
in
let args = List.rev args in
let patargs = List.rev patargs in
let pat' = PatCstr (l, cstr, patargs, alias) in
let cstr = mkConstruct ci.cs_cstr in
let app = applistc cstr (List.map (lift (List.length sign)) params) in
let app = applistc app args in
let apptype = Retyping.get_type_of env (Evd.evars_of !isevars) app in
let IndType (indf, realargs) = find_rectype env (Evd.evars_of !isevars) apptype in
match alias with
Anonymous ->
pat', sign, app, apptype, realargs, n, avoid
| Name id ->
let sign = (alias, None, lift m ty) :: sign in
let avoid = id :: avoid in
let sign, i, avoid =
try
let env = push_rels sign env in
isevars := the_conv_x_leq (push_rels sign env) (lift (succ m) ty) (lift 1 apptype) !isevars;
let eq_t = mk_eq (lift (succ m) ty)
(mkRel 1) (* alias *)
(lift 1 app) (* aliased term *)
in
let neq = eq_id avoid id in
(Name neq, Some (mkRel 0), eq_t) :: sign, 2, neq :: avoid
with Reduction.NotConvertible -> sign, 1, avoid
in
(* Mark the equality as a hole *)
pat', sign, lift i app, lift i apptype, realargs, n + i, avoid
in
let pat', sign, patc, patty, args, z, avoid = typ env (pi3 (List.hd arsign), List.tl arsign) pat avoid in
pat', (sign, patc, (pi3 (List.hd arsign), args), pat'), avoid
(* shadows functional version *)
let eq_id avoid id =
let hid = id_of_string ("Heq_" ^ string_of_id id) in
let hid' = next_ident_away_from hid !avoid in
avoid := hid' :: !avoid;
hid'
let rels_of_patsign =
List.map (fun ((na, b, t) as x) ->
match b with
| Some t' when kind_of_term t' = Rel 0 -> (na, None, t)
| _ -> x)
let vars_of_ctx ctx =
let _, y =
List.fold_right (fun (na, b, t) (prev, vars) ->
match b with
| Some t' when kind_of_term t' = Rel 0 ->
prev,
(RApp (dummy_loc,
(RRef (dummy_loc, Lazy.force refl_ref)), [hole; RVar (dummy_loc, prev)])) :: vars
| _ ->
match na with
Anonymous -> raise (Invalid_argument "vars_of_ctx")
| Name n -> n, RVar (dummy_loc, n) :: vars)
ctx (id_of_string "vars_of_ctx_error", [])
in List.rev y
let rec is_included x y =
match x, y with
| PatVar _, _ -> true
| _, PatVar _ -> true
| PatCstr (l, (_, i), args, alias), PatCstr (l', (_, i'), args', alias') ->
if i = i' then List.for_all2 is_included args args'
else false
(* liftsign is the current pattern's complete signature length. Hence pats is already typed in its
full signature. However prevpatterns are in the original one signature per pattern form.
*)
let build_ineqs prevpatterns pats liftsign =
let _tomatchs = List.length pats in
let diffs =
List.fold_left
(fun c eqnpats ->
let acc = List.fold_left2
(* ppat is the pattern we are discriminating against, curpat is the current one. *)
(fun acc (ppat_sign, ppat_c, (ppat_ty, ppat_tyargs), ppat)
(curpat_sign, curpat_c, (curpat_ty, curpat_tyargs), curpat) ->
match acc with
None -> None
| Some (sign, len, n, c) -> (* FixMe: do not work with ppat_args *)
if is_included curpat ppat then
(* Length of previous pattern's signature *)
let lens = List.length ppat_sign in
(* Accumulated length of previous pattern's signatures *)
let len' = lens + len in
let acc =
((* Jump over previous prevpat signs *)
lift_rel_context len ppat_sign @ sign,
len',
succ n, (* nth pattern *)
mkApp (Lazy.force eq_ind,
[| lift (len' + liftsign) curpat_ty;
liftn (len + liftsign) (succ lens) ppat_c ;
lift len' curpat_c |]) ::
List.map (lift lens (* Jump over this prevpat signature *)) c)
in Some acc
else None)
(Some ([], 0, 0, [])) eqnpats pats
in match acc with
None -> c
| Some (sign, len, _, c') ->
let conj = it_mkProd_or_LetIn (mk_not (mk_conj c'))
(lift_rel_context liftsign sign)
in
conj :: c)
[] prevpatterns
in match diffs with [] -> None
| _ -> Some (mk_conj diffs)
let subst_rel_context k ctx subst =
let (_, ctx') =
List.fold_right
(fun (n, b, t) (k, acc) ->
(succ k, (n, Option.map (substnl subst k) b, substnl subst k t) :: acc))
ctx (k, [])
in ctx'
let lift_rel_contextn n k sign =
let rec liftrec k = function
| (na,c,t)::sign ->
(na,Option.map (liftn n k) c,liftn n k t)::(liftrec (k-1) sign)
| [] -> []
in
liftrec (rel_context_length sign + k) sign
let constrs_of_pats typing_fun env isevars eqns tomatchs sign neqs arity =
let i = ref 0 in
let (x, y, z) =
List.fold_left
(fun (branches, eqns, prevpatterns) eqn ->
let _, newpatterns, pats =
List.fold_left2
(fun (idents, newpatterns, pats) pat arsign ->
let pat', cpat, idents = constr_of_pat env isevars arsign pat idents in
(idents, pat' :: newpatterns, cpat :: pats))
([], [], []) eqn.patterns sign
in
let newpatterns = List.rev newpatterns and opats = List.rev pats in
let rhs_rels, pats, signlen =
List.fold_left
(fun (renv, pats, n) (sign,c, (s, args), p) ->
(* Recombine signatures and terms of all of the row's patterns *)
let sign' = lift_rel_context n sign in
let len = List.length sign' in
(sign' @ renv,
(* lift to get outside of previous pattern's signatures. *)
(sign', liftn n (succ len) c, (s, List.map (liftn n (succ len)) args), p) :: pats,
len + n))
([], [], 0) opats in
let pats, _ = List.fold_left
(* lift to get outside of past patterns to get terms in the combined environment. *)
(fun (pats, n) (sign, c, (s, args), p) ->
let len = List.length sign in
((rels_of_patsign sign, lift n c, (s, List.map (lift n) args), p) :: pats, len + n))
([], 0) pats
in
let ineqs = build_ineqs prevpatterns pats signlen in
let rhs_rels' = rels_of_patsign rhs_rels in
let _signenv = push_rel_context rhs_rels' env in
let arity =
let args, nargs =
List.fold_right (fun (sign, c, (_, args), _) (allargs,n) ->
(args @ c :: allargs, List.length args + succ n))
pats ([], 0)
in
let args = List.rev args in
substl args (liftn signlen (succ nargs) arity)
in
let rhs_rels', tycon =
let neqs_rels, arity =
match ineqs with
| None -> [], arity
| Some ineqs ->
[Anonymous, None, ineqs], lift 1 arity
in
let eqs_rels, arity = decompose_prod_n_assum neqs arity in
eqs_rels @ neqs_rels @ rhs_rels', arity
in
let rhs_env = push_rels rhs_rels' env in
let j = typing_fun (mk_tycon tycon) rhs_env eqn.rhs.it in
let bbody = it_mkLambda_or_LetIn j.uj_val rhs_rels'
and btype = it_mkProd_or_LetIn j.uj_type rhs_rels' in
let branch_name = id_of_string ("branch_" ^ (string_of_int !i)) in
let branch_decl = (Name branch_name, Some (lift !i bbody), (lift !i btype)) in
let branch =
let bref = RVar (dummy_loc, branch_name) in
match vars_of_ctx rhs_rels with
[] -> bref
| l -> RApp (dummy_loc, bref, l)
in
let branch = match ineqs with
Some _ -> RApp (dummy_loc, branch, [ hole ])
| None -> branch
in
incr i;
let rhs = { eqn.rhs with it = branch } in
(branch_decl :: branches,
{ eqn with patterns = newpatterns; rhs = rhs } :: eqns,
opats :: prevpatterns))
([], [], []) eqns
in x, y
(* Builds the predicate. If the predicate is dependent, its context is
* made of 1+nrealargs assumptions for each matched term in an inductive
* type and 1 assumption for each term not _syntactically_ in an
* inductive type.
* Each matched terms are independently considered dependent or not.
* A type constraint but no annotation case: it is assumed non dependent.
*)
let lift_ctx n ctx =
let ctx', _ =
List.fold_right (fun (c, t) (ctx, n') -> (liftn n n' c, liftn_tomatch_type n n' t) :: ctx, succ n') ctx ([], 0)
in ctx'
(* Turn matched terms into variables. *)
let abstract_tomatch env tomatchs =
let prev, ctx, names =
List.fold_left
(fun (prev, ctx, names) (c, t) ->
let lenctx = List.length ctx in
match kind_of_term c with
Rel n -> (lift lenctx c, lift_tomatch_type lenctx t) :: prev, ctx, names
| _ ->
let name = next_ident_away_from (id_of_string "filtered_var") names in
(mkRel 1, lift_tomatch_type (succ lenctx) t) :: lift_ctx 1 prev,
(Name name, Some (lift lenctx c), lift lenctx $ type_of_tomatch t) :: ctx,
name :: names)
([], [], []) tomatchs
in List.rev prev, ctx
let is_dependent_ind = function
IsInd (_, IndType (indf, args)) when List.length args > 0 -> true
| _ -> false
let build_dependent_signature env evars avoid tomatchs arsign =
let avoid = ref avoid in
let arsign = List.rev arsign in
let allnames = List.rev (List.map (List.map pi1) arsign) in
let nar = List.fold_left (fun n names -> List.length names + n) 0 allnames in
let eqs, neqs, refls, slift, arsign' =
List.fold_left2
(fun (eqs, neqs, refl_args, slift, arsigns) (tm, ty) arsign ->
(* The accumulator:
previous eqs,
number of previous eqs,
lift to get outside eqs and in the introduced variables ('as' and 'in'),
new arity signatures
*)
match ty with
IsInd (ty, IndType (indf, args)) when List.length args > 0 ->
(* Build the arity signature following the names in matched terms as much as possible *)
let argsign = List.tl arsign in (* arguments in inverse application order *)
let (appn, appb, appt) as _appsign = List.hd arsign in (* The matched argument *)
let argsign = List.rev argsign in (* arguments in application order *)
let env', nargeqs, argeqs, refl_args, slift, argsign' =
List.fold_left2
(fun (env, nargeqs, argeqs, refl_args, slift, argsign') arg (name, b, t) ->
let argt = Retyping.get_type_of env evars arg in
let eq, refl_arg =
if Reductionops.is_conv env evars argt t then
(mk_eq (lift (nargeqs + slift) argt)
(mkRel (nargeqs + slift))
(lift (nargeqs + nar) arg),
mk_eq_refl argt arg)
else
(mk_JMeq (lift (nargeqs + slift) t)
(mkRel (nargeqs + slift))
(lift (nargeqs + nar) argt)
(lift (nargeqs + nar) arg),
mk_JMeq_refl argt arg)
in
let previd, id =
let name =
match kind_of_term arg with
Rel n -> pi1 (Environ.lookup_rel n env)
| _ -> name
in
make_prime avoid name
in
(env, succ nargeqs,
(Name (eq_id avoid previd), None, eq) :: argeqs,
refl_arg :: refl_args,
pred slift,
(Name id, b, t) :: argsign'))
(env, 0, [], [], slift, []) args argsign
in
let eq = mk_JMeq
(lift (nargeqs + slift) appt)
(mkRel (nargeqs + slift))
(lift (nargeqs + nar) ty)
(lift (nargeqs + nar) tm)
in
let refl_eq = mk_JMeq_refl ty tm in
let previd, id = make_prime avoid appn in
(((Name (eq_id avoid previd), None, eq) :: argeqs) :: eqs,
succ nargeqs,
refl_eq :: refl_args,
pred slift,
(((Name id, appb, appt) :: argsign') :: arsigns))
| _ ->
(* Non dependent inductive or not inductive, just use a regular equality *)
let (name, b, typ) = match arsign with [x] -> x | _ -> assert(false) in
let previd, id = make_prime avoid name in
let arsign' = (Name id, b, typ) in
let tomatch_ty = type_of_tomatch ty in
let eq =
mk_eq (lift nar tomatch_ty)
(mkRel slift) (lift nar tm)
in
([(Name (eq_id avoid previd), None, eq)] :: eqs, succ neqs,
(mk_eq_refl tomatch_ty tm) :: refl_args,
pred slift, (arsign' :: []) :: arsigns))
([], 0, [], nar, []) tomatchs arsign
in
let arsign'' = List.rev arsign' in
assert(slift = 0); (* we must have folded over all elements of the arity signature *)
arsign'', allnames, nar, eqs, neqs, refls
(**************************************************************************)
(* Main entry of the matching compilation *)
let liftn_rel_context n k sign =
let rec liftrec k = function
| (na,c,t)::sign ->
(na,Option.map (liftn n k) c,liftn n k t)::(liftrec (k-1) sign)
| [] -> []
in
liftrec (k + rel_context_length sign) sign
let nf_evars_env evar_defs (env : env) : env =
let nf t = nf_isevar evar_defs t in
let env0 : env = reset_context env in
let f e (na, b, t) e' : env =
Environ.push_named (na, Option.map nf b, nf t) e'
in
let env' = Environ.fold_named_context f ~init:env0 env in
Environ.fold_rel_context (fun e (na, b, t) e' -> Environ.push_rel (na, Option.map nf b, nf t) e')
~init:env' env
(* We put the tycon inside the arity signature, possibly discovering dependencies. *)
let prepare_predicate_from_arsign_tycon loc env evm tomatchs arsign c =
let nar = List.fold_left (fun n sign -> List.length sign + n) 0 arsign in
let subst, len =
List.fold_left2 (fun (subst, len) (tm, tmtype) sign ->
let signlen = List.length sign in
match kind_of_term tm with
| Rel n when dependent tm c
&& signlen = 1 (* The term to match is not of a dependent type itself *) ->
((n, len) :: subst, len - signlen)
| Rel _ when not (dependent tm c)
&& signlen > 1 (* The term is of a dependent type but does not appear in
the tycon, maybe some variable in its type does. *) ->
(match tmtype with
NotInd _ -> (* len - signlen, subst*) assert false (* signlen > 1 *)
| IsInd (_, IndType(indf,realargs)) ->
List.fold_left
(fun (subst, len) arg ->
match kind_of_term arg with
| Rel n when dependent arg c ->
((n, len) :: subst, pred len)
| _ -> (subst, pred len))
(subst, len) realargs)
| _ -> (subst, len - signlen))
([], nar) tomatchs arsign
in
let rec predicate lift c =
match kind_of_term c with
| Rel n when n > lift ->
(try
(* Make the predicate dependent on the matched variable *)
let idx = List.assoc (n - lift) subst in
mkRel (idx + lift)
with Not_found ->
(* A variable that is not matched, lift over the arsign. *)
mkRel (n + nar))
| _ ->
map_constr_with_binders succ predicate lift c
in
try
(* The tycon may be ill-typed after abstraction. *)
let pred = predicate 0 c in
let env' = push_rel_context (context_of_arsign arsign) env in
ignore(Typing.sort_of env' evm pred); pred
with _ -> lift nar c
let prepare_predicate_from_rettyp loc typing_fun isevars env tomatchs sign tycon rtntyp =
(* We extract the signature of the arity *)
let arsign = extract_arity_signature env tomatchs sign in
let newenv = List.fold_right push_rels arsign env in
let allnames = List.rev (List.map (List.map pi1) arsign) in
match rtntyp with
| Some rtntyp ->
let predcclj = typing_fun (mk_tycon (new_Type ())) newenv rtntyp in
let predccl = (j_nf_isevar !isevars predcclj).uj_val in
Some (build_initial_predicate true allnames predccl)
| None ->
match valcon_of_tycon tycon with
| Some ty ->
let pred =
prepare_predicate_from_arsign_tycon loc env (Evd.evars_of !isevars) tomatchs arsign ty
in Some (build_initial_predicate true allnames pred)
| None -> None
let compile_cases loc style (typing_fun, isevars) (tycon : Evarutil.type_constraint) env (predopt, tomatchl, eqns) =
let typing_fun tycon env = typing_fun tycon env isevars in
(* We build the matrix of patterns and right-hand-side *)
let matx = matx_of_eqns env eqns in
(* We build the vector of terms to match consistently with the *)
(* constructors found in patterns *)
let tomatchs = coerce_to_indtype typing_fun isevars env matx tomatchl in
let _isdep = List.exists (fun (x, y) -> is_dependent_ind y) tomatchs in
if predopt = None then
let tomatchs, tomatchs_lets = abstract_tomatch env tomatchs in
let tomatchs_len = List.length tomatchs_lets in
let env = push_rel_context tomatchs_lets env in
let len = List.length eqns in
let sign, allnames, signlen, eqs, neqs, args =
(* The arity signature *)
let arsign = extract_arity_signatures env tomatchs (List.map snd tomatchl) in
(* Build the dependent arity signature, the equalities which makes
the first part of the predicate and their instantiations. *)
let avoid = [] in
build_dependent_signature env (Evd.evars_of !isevars) avoid tomatchs arsign
in
let tycon, arity =
match valcon_of_tycon tycon with
| None -> let ev = mkExistential env isevars in ev, ev
| Some t ->
t, prepare_predicate_from_arsign_tycon loc env (Evd.evars_of !isevars)
tomatchs sign (lift tomatchs_len t)
in
let neqs, arity =
let ctx = context_of_arsign eqs in
let neqs = List.length ctx in
neqs, it_mkProd_or_LetIn (lift neqs arity) ctx
in
let lets, matx =
(* Type the rhs under the assumption of equations *)
constrs_of_pats typing_fun env isevars matx tomatchs sign neqs arity
in
let matx = List.rev matx in
let _ = assert(len = List.length lets) in
let env = push_rels lets env in
let matx = List.map (fun eqn -> { eqn with rhs = { eqn.rhs with rhs_env = env } }) matx in
let tomatchs = List.map (fun (x, y) -> lift len x, lift_tomatch_type len y) tomatchs in
let args = List.rev_map (lift len) args in
let pred = liftn len (succ signlen) arity in
let pred = build_initial_predicate true allnames pred in
(* We push the initial terms to match and push their alias to rhs' envs *)
(* names of aliases will be recovered from patterns (hence Anonymous here) *)
let initial_pushed = List.map (fun tm -> Pushed (tm,[])) tomatchs in
let pb =
{ env = env;
isevars = isevars;
pred = Some pred;
tomatch = initial_pushed;
history = start_history (List.length initial_pushed);
mat = matx;
caseloc = loc;
casestyle= style;
typing_function = typing_fun } in
let j = compile pb in
(* We check for unused patterns *)
List.iter (check_unused_pattern env) matx;
let body = it_mkLambda_or_LetIn (applistc j.uj_val args) lets in
let j =
{ uj_val = it_mkLambda_or_LetIn body tomatchs_lets;
uj_type = nf_isevar !isevars tycon; }
in j
else
(* We build the elimination predicate if any and check its consistency *)
(* with the type of arguments to match *)
let tmsign = List.map snd tomatchl in
let pred = prepare_predicate_from_rettyp loc typing_fun isevars env tomatchs tmsign tycon predopt in
(* We push the initial terms to match and push their alias to rhs' envs *)
(* names of aliases will be recovered from patterns (hence Anonymous here) *)
let initial_pushed = List.map (fun tm -> Pushed (tm,[])) tomatchs in
let pb =
{ env = env;
isevars = isevars;
pred = pred;
tomatch = initial_pushed;
history = start_history (List.length initial_pushed);
mat = matx;
caseloc = loc;
casestyle= style;
typing_function = typing_fun } in
let j = compile pb in
(* We check for unused patterns *)
List.iter (check_unused_pattern env) matx;
inh_conv_coerce_to_tycon loc env isevars j tycon
end
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