(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* if errors = [] then anomaly (str "try_find_f") else iraise (List.last errors) | h::t -> try f h with UserError _ | TypeError _ | PretypeError _ | PatternMatchingError _ as e -> let e = CErrors.push e in aux (e::errors) t in aux [] l let force_name = let nx = Name default_dependent_ident in function Anonymous -> nx | na -> na (************************************************************************) (* Pattern-matching compilation (Cases) *) (************************************************************************) (************************************************************************) (* Configuration, errors and warnings *) open Pp let msg_may_need_inversion () = strbrk "Found a matching with no clauses on a term unknown to have an empty inductive type." (* Utils *) let make_anonymous_patvars n = List.make n (CAst.make @@ PatVar Anonymous) (* 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 relocate_rel n1 n2 k j = if Int.equal j (n1 + k) then n2+k else j let rec relocate_index sigma n1 n2 k t = match EConstr.kind sigma t with | Rel j when Int.equal j (n1 + k) -> mkRel (n2+k) | Rel j when j < n1+k -> t | Rel j when j > n1+k -> t | _ -> EConstr.map_with_binders sigma succ (relocate_index sigma n1 n2) k t (**********************************************************************) (* Structures used in compiling pattern-matching *) type 'a rhs = { rhs_env : env; rhs_vars : Id.t list; avoid_ids : Id.t list; it : 'a option} type 'a equation = { patterns : cases_pattern list; rhs : 'a rhs; alias_stack : Name.t list; eqn_loc : Loc.t option; used : bool ref } type 'a matrix = 'a equation list (* 1st argument of IsInd is the original ind before extracting the summary *) type tomatch_type = | IsInd of types * inductive_type * Name.t list | NotInd of constr option * types (* spiwack: The first argument of [Pushed] is [true] for initial Pushed and [false] otherwise. Used to decide whether the term being matched on must be aliased in the variable case (only initial Pushed need to be aliased). The first argument of [Alias] is [true] if the alias was introduced by an initial pushed and [false] otherwise.*) type tomatch_status = | Pushed of (bool*((constr * tomatch_type) * int list * Name.t)) | Alias of (bool*(Name.t * constr * (constr * types))) | NonDepAlias | Abstract of int * rel_declaration type tomatch_stack = tomatch_status list (* We keep a constr for aliases and a cases_pattern for error message *) type pattern_history = | Top | MakeConstructor of constructor * 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 feed_history arg = function | Continuation (n, l, h) when n>=1 -> Continuation (n-1, arg :: l, h) | Continuation (n, _, _) -> anomaly (str "Bad number of expected remaining patterns: " ++ int n) | Result _ -> anomaly (Pp.str "Exhausted pattern history") (* This is for non exhaustive error message *) let rec glob_pattern_of_partial_history args2 = function | Continuation (n, args1, h) -> let args3 = make_anonymous_patvars (n - (List.length args2)) in build_glob_pattern (List.rev_append args1 (args2@args3)) h | Result pl -> pl and build_glob_pattern args = function | Top -> args | MakeConstructor (pci, rh) -> glob_pattern_of_partial_history [CAst.make @@ PatCstr (pci, args, Anonymous)] rh let complete_history = glob_pattern_of_partial_history [] (* This is to build glued pattern-matching history and alias bodies *) let pop_history_pattern = function | Continuation (0, l, Top) -> Result (List.rev l) | Continuation (0, l, MakeConstructor (pci, rh)) -> feed_history (CAst.make @@ PatCstr (pci,List.rev l,Anonymous)) rh | _ -> anomaly (Pp.str "Constructor not yet filled with its arguments") let pop_history h = feed_history (CAst.make @@ PatVar Anonymous) h (* Builds a continuation expecting [n] arguments and building [ci] applied to this [n] arguments *) let push_history_pattern n pci cont = Continuation (n, [], MakeConstructor (pci, cont)) (* A pattern-matching problem has the following form: env, evd |- match terms_to_tomatch return pred with mat end where terms_to_match is some sequence of "instructions" (t1 ... tp) 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; in Pushed ((c,tm),deps,na), [c] is the reference to the term (which is a Rel or an initial term), [tm] is its type (telling whether we know if it is an inductive type or not), [deps] is the list of terms to abstract before matching on [c] (these are rels too) - "Abstract" instructions mean that an abstraction has to be inserted in the current branch to build (this means a pattern has been detected dependent in another one and a generalization is necessary to ensure well-typing) Abstract instructions extend the [env] in which the other instructions are typed - "Alias" instructions mean 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) - "NonDepAlias" instructions mean the completion of a matching over a term to match as for Alias but without inserting this alias because there is no dependency in it 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 'a pattern_matching_problem = { env : env; evdref : evar_map ref; pred : constr; tomatch : tomatch_stack; history : pattern_continuation; mat : 'a matrix; caseloc : Loc.t option; casestyle : case_style; typing_function: type_constraint -> env -> evar_map ref -> 'a option -> 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 | { CAst.v = PatVar _ } :: l -> find_row_ind l | { CAst.v = PatCstr(c,_,_) ; loc } :: _ -> Some (loc,c) let inductive_template evdref env tmloc ind = let indu = evd_comb1 (Evd.fresh_inductive_instance env) evdref ind in let arsign = inductive_alldecls_env env indu in let indu = on_snd EInstance.make indu in let hole_source i = match tmloc with | Some loc -> Loc.tag ~loc @@ Evar_kinds.TomatchTypeParameter (ind,i) | None -> Loc.tag @@ Evar_kinds.TomatchTypeParameter (ind,i) in let (_,evarl,_) = List.fold_right (fun decl (subst,evarl,n) -> match decl with | LocalAssum (na,ty) -> let ty = EConstr.of_constr ty in let ty' = substl subst ty in let e = e_new_evar env evdref ~src:(hole_source n) ty' in (e::subst,e::evarl,n+1) | LocalDef (na,b,ty) -> let b = EConstr.of_constr b in (substl subst b::subst,evarl,n+1)) arsign ([],[],1) in applist (mkIndU indu,List.rev evarl) let try_find_ind env sigma typ realnames = let (IndType(indf,realargs) as ind) = find_rectype env sigma typ in let names = match realnames with | Some names -> names | None -> let ind = fst (fst (dest_ind_family indf)) in List.make (inductive_nrealdecls ind) Anonymous in IsInd (typ,ind,names) let inh_coerce_to_ind evdref env loc ty tyi = let sigma = !evdref in let expected_typ = inductive_template evdref env loc tyi in (* Try to refine the type with inductive information coming from the constructor and renounce if not able to give more information *) (* devrait être indifférent d'exiger leq ou pas puisque pour un inductif cela doit être égal *) if not (e_cumul env evdref expected_typ ty) then evdref := sigma let binding_vars_of_inductive sigma = function | NotInd _ -> [] | IsInd (_,IndType(_,realargs),_) -> List.filter (isRel sigma) realargs let extract_inductive_data env sigma decl = match decl with | LocalAssum (_,t) -> let tmtyp = try try_find_ind env sigma t None with Not_found -> NotInd (None,t) in let tmtypvars = binding_vars_of_inductive sigma tmtyp in (tmtyp,tmtypvars) | LocalDef (_,_,t) -> (NotInd (None, t), []) let unify_tomatch_with_patterns evdref env loc typ pats realnames = match find_row_ind pats with | None -> NotInd (None,typ) | Some (_,(ind,_)) -> inh_coerce_to_ind evdref env loc typ ind; try try_find_ind env !evdref typ realnames with Not_found -> NotInd (None,typ) let find_tomatch_tycon evdref env loc = function (* Try if some 'in I ...' is present and can be used as a constraint *) | Some (_,(ind,realnal)) -> mk_tycon (inductive_template evdref env loc ind),Some (List.rev realnal) | None -> empty_tycon,None let coerce_row typing_fun evdref env pats (tomatch,(_,indopt)) = let loc = loc_of_glob_constr tomatch in let tycon,realnames = find_tomatch_tycon evdref env loc indopt in let j = typing_fun tycon env evdref tomatch in let evd, j = Coercion.inh_coerce_to_base ?loc:(loc_of_glob_constr tomatch) env !evdref j in evdref := evd; let typ = nf_evar !evdref j.uj_type in let t = try try_find_ind env !evdref typ realnames with Not_found -> unify_tomatch_with_patterns evdref env loc typ pats realnames in (j.uj_val,t) let coerce_to_indtype typing_fun evdref 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 evdref env) matx' tomatchl (************************************************************************) (* Utils *) let mkExistential env ?(src=(Loc.tag Evar_kinds.InternalHole)) evdref = let e, u = e_new_type_evar env evdref univ_flexible_alg ~src:src in e let evd_comb2 f evdref x y = let (evd',y) = f !evdref x y in evdref := evd'; y let adjust_tomatch_to_pattern pb ((current,typ),deps,dep) = (* 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,names = match typ with IsInd(t,_,names) -> t,Some names | NotInd(_,t) -> t,None in let tmtyp = try try_find_ind pb.env !(pb.evdref) typ names with Not_found -> NotInd (None,typ) in match tmtyp with | NotInd (None,typ) -> let tm1 = List.map (fun eqn -> List.hd eqn.patterns) pb.mat in (match find_row_ind tm1 with | None -> (current,tmtyp) | Some (_,(ind,_)) -> let indt = inductive_template pb.evdref pb.env None ind in let current = if List.is_empty deps && isEvar !(pb.evdref) typ then (* Don't insert coercions if dependent; only solve evars *) let _ = e_cumul pb.env pb.evdref indt typ in current else (evd_comb2 (Coercion.inh_conv_coerce_to true pb.env) pb.evdref (make_judge current typ) indt).uj_val in let sigma = !(pb.evdref) in (current,try_find_ind pb.env sigma indt names)) | _ -> (current,tmtyp) let type_of_tomatch = function | IsInd (t,_,_) -> t | NotInd (_,t) -> t let map_tomatch_type f = function | IsInd (t,ind,names) -> IsInd (f t,map_inductive_type f ind,names) | NotInd (c,t) -> NotInd (Option.map f c, f t) let liftn_tomatch_type n depth = map_tomatch_type (Vars.liftn n depth) let lift_tomatch_type n = liftn_tomatch_type n 1 (**********************************************************************) (* Utilities on patterns *) let current_pattern eqn = match eqn.patterns with | pat::_ -> pat | [] -> anomaly (Pp.str "Empty list of patterns") let alias_of_pat = CAst.with_val (function | PatVar name -> name | PatCstr(_,_,name) -> name ) 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 (Pp.str "Empty list of patterns") let push_current_pattern (cur,ty) eqn = match eqn.patterns with | pat::pats -> let rhs_env = push_rel (LocalDef (alias_of_pat pat,cur,ty)) eqn.rhs.rhs_env in { eqn with rhs = { eqn.rhs with rhs_env = rhs_env }; patterns = pats } | [] -> anomaly (Pp.str "Empty list of patterns") (* spiwack: like [push_current_pattern] but does not introduce an alias in rhs_env. Aliasing binders are only useful for variables at the root of a pattern matching problem (initial push), so we distinguish the cases. *) let push_noalias_current_pattern eqn = match eqn.patterns with | _::pats -> { eqn with patterns = pats } | [] -> anomaly (Pp.str "push_noalias_current_pattern: 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, LocalAssum _ :: decls) -> pat :: adjust_local_defs ?loc (pats,decls) | (pats, LocalDef _ :: decls) -> (CAst.make ?loc @@ PatVar Anonymous) :: adjust_local_defs ?loc (pats,decls) | [], [] -> [] | _ -> raise NotAdjustable let check_and_adjust_constructor env ind cstrs = function | { CAst.v = PatVar _ } as pat -> pat | { CAst.v = PatCstr (((_,i) as cstr),args,alias) ; loc } as pat -> (* Check it is constructor of the right type *) let ind' = inductive_of_constructor cstr in if eq_ind 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 Int.equal (List.length args) nb_args_constr then pat else try let args' = adjust_local_defs ?loc (args, List.rev ci.cs_args) in CAst.make ?loc @@ PatCstr (cstr, args', alias) with NotAdjustable -> error_wrong_numarg_constructor ?loc env cstr nb_args_constr else (* Try to insert a coercion *) try Coercion.inh_pattern_coerce_to ?loc env pat ind' ind with Not_found -> error_bad_constructor ?loc env cstr ind let check_all_variables env sigma typ mat = List.iter (fun eqn -> match current_pattern eqn with | { CAst.v = PatVar id } -> () | { CAst.v = PatCstr (cstr_sp,_,_); loc } -> error_bad_pattern ?loc env sigma cstr_sp typ) mat let check_unused_pattern env eqn = if not !(eqn.used) then raise_pattern_matching_error ?loc:eqn.eqn_loc (env, Evd.empty, UnusedClause eqn.patterns) let set_used_pattern eqn = eqn.used := true let extract_rhs pb = match pb.mat with | [] -> user_err ~hdr:"build_leaf" (msg_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 -> Id.List.mem id rhs.rhs_vars let is_dep_patt_in eqn = function | { CAst.v = PatVar name } -> Flags.is_program_mode () || occur_in_rhs name eqn.rhs | { CAst.v = PatCstr _ } -> true let mk_dep_patt_row (pats,_,eqn) = List.map (is_dep_patt_in eqn) pats let dependencies_in_pure_rhs nargs eqns = if List.is_empty eqns then List.make nargs (not (Flags.is_program_mode ())) (* Only "_" patts *) else let deps_rows = List.map mk_dep_patt_row eqns in let deps_columns = matrix_transpose deps_rows in List.map (List.exists (fun x -> x)) deps_columns let dependent_decl sigma a = function | LocalAssum (na,t) -> dependent sigma a t | LocalDef (na,c,t) -> dependent sigma a t || dependent sigma a c let rec dep_in_tomatch sigma n = function | (Pushed _ | Alias _ | NonDepAlias) :: l -> dep_in_tomatch sigma n l | Abstract (_,d) :: l -> dependent_decl sigma (mkRel n) d || dep_in_tomatch sigma (n+1) l | [] -> false let dependencies_in_rhs sigma nargs current tms eqns = match EConstr.kind sigma current with | Rel n when dep_in_tomatch sigma n tms -> List.make nargs true | _ -> dependencies_in_pure_rhs nargs eqns (* Computing the matrix of dependencies *) (* [find_dependency_list tmi [d(i+1);...;dn]] computes in which declarations [d(i+1);...;dn] the term [tmi] is dependent in. [find_dependencies_signature (used1,...,usedn) ((tm1,d1),...,(tmn,dn))] returns [(deps1,...,depsn)] where [depsi] is a subset of tm(i+1),..,tmn denoting in which of the d(i+1)...dn, the term tmi is dependent. *) let rec find_dependency_list sigma tmblock = function | [] -> [] | (used,tdeps,tm,d)::rest -> let deps = find_dependency_list sigma tmblock rest in if used && List.exists (fun x -> dependent_decl sigma x d) tmblock then match EConstr.kind sigma tm with | Rel n -> List.add_set Int.equal n (List.union Int.equal deps tdeps) | _ -> List.union Int.equal deps tdeps else deps let find_dependencies sigma is_dep_or_cstr_in_rhs (tm,(_,tmtypleaves),d) nextlist = let deps = find_dependency_list sigma (tm::tmtypleaves) nextlist in if is_dep_or_cstr_in_rhs || not (List.is_empty deps) then ((true ,deps,tm,d)::nextlist) else ((false,[] ,tm,d)::nextlist) let find_dependencies_signature sigma deps_in_rhs typs = let l = List.fold_right2 (find_dependencies sigma) deps_in_rhs typs [] in List.map (fun (_,deps,_,_) -> deps) l (* Assume we had terms t1..tq to match in a context xp:Tp,...,x1:T1 |- and xn:Tn has just been regeneralized into x:Tn so that the terms to match are now to be considered in the context xp:Tp,...,x1:T1,x:Tn |-. [relocate_index_tomatch n 1 tomatch] updates t1..tq so that former references to xn1 are now references to x. Note that t1..tq are already adjusted to the context xp:Tp,...,x1:T1,x:Tn |-. [relocate_index_tomatch 1 n tomatch] will go the way back. *) let relocate_index_tomatch sigma n1 n2 = let rec genrec depth = function | [] -> [] | Pushed (b,((c,tm),l,na)) :: rest -> let c = relocate_index sigma n1 n2 depth c in let tm = map_tomatch_type (relocate_index sigma n1 n2 depth) tm in let l = List.map (relocate_rel n1 n2 depth) l in Pushed (b,((c,tm),l,na)) :: genrec depth rest | Alias (initial,(na,c,d)) :: rest -> (* [c] is out of relocation scope *) Alias (initial,(na,c,map_pair (relocate_index sigma n1 n2 depth) d)) :: genrec depth rest | NonDepAlias :: rest -> NonDepAlias :: genrec depth rest | Abstract (i,d) :: rest -> let i = relocate_rel n1 n2 depth i in Abstract (i, RelDecl.map_constr (fun c -> relocate_index sigma n1 n2 depth c) d) :: genrec (depth+1) rest in genrec 0 (* [replace_tomatch n c tomatch] replaces [Rel n] by [c] in [tomatch] *) let rec replace_term sigma n c k t = if isRel sigma t && Int.equal (destRel sigma t) (n + k) then Vars.lift k c else EConstr.map_with_binders sigma succ (replace_term sigma n c) k t let length_of_tomatch_type_sign na t = let l = match na with | Anonymous -> 0 | Name _ -> 1 in match t with | NotInd _ -> l | IsInd (_, _, names) -> List.length names + l let replace_tomatch sigma n c = let rec replrec depth = function | [] -> [] | Pushed (initial,((b,tm),l,na)) :: rest -> let b = replace_term sigma n c depth b in let tm = map_tomatch_type (replace_term sigma n c depth) tm in List.iter (fun i -> if Int.equal i (n + depth) then anomaly (Pp.str "replace_tomatch")) l; Pushed (initial,((b,tm),l,na)) :: replrec depth rest | Alias (initial,(na,b,d)) :: rest -> (* [b] is out of replacement scope *) Alias (initial,(na,b,map_pair (replace_term sigma n c depth) d)) :: replrec depth rest | NonDepAlias :: rest -> NonDepAlias :: replrec depth rest | Abstract (i,d) :: rest -> Abstract (i, RelDecl.map_constr (fun t -> replace_term sigma n c depth t) d) :: replrec (depth+1) rest in replrec 0 (* [liftn_tomatch_stack]: a 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 pushed terms to match must be lifted by n (knowing that [Abstract] introduces a binder in the list of pushed terms to match). *) let rec liftn_tomatch_stack n depth = function | [] -> [] | Pushed (initial,((c,tm),l,na))::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 Alias (initial,(na,liftn n depth c,map_pair (liftn n depth) d)) ::(liftn_tomatch_stack n depth rest) | NonDepAlias :: rest -> NonDepAlias :: liftn_tomatch_stack n depth rest | Abstract (i,d)::rest -> let i = if i 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 The exact names here are not important for typing (because they are put in pb.env and not in the rhs.rhs_env of branches. However, whether a name is Anonymous or not may have an effect on whether a generalization is done or not. *) 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 sigma sign eqns = let names1 = List.make (Context.Rel.length sign) Anonymous in (* If any, we prefer names used in pats, from top to bottom *) let names2,aliasname = List.fold_right (fun (pats,pat_alias,eqn) (names,aliasname) -> (merge_names alias_of_pat pats names, merge_name (fun x -> x) pat_alias aliasname)) eqns (names1,Anonymous) 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 Id.equal l eqn.rhs.avoid_ids) [] eqns in let names3,_ = List.fold_left2 (fun (l,avoid) d na -> let na = merge_name (fun (LocalAssum (na,t) | LocalDef (na,_,t)) -> Name (next_name_away (named_hd env sigma t na) avoid)) d na in (na::l,(out_name na)::avoid)) ([],allvars) (List.rev sign) names2 in names3,aliasname (*****************************************************************) (* Recovering names for variables pushed to the rhs' environment *) (* We just factorized a match over a matrix of equations *) (* "C xi1 .. xin as xi" as a single match over "C y1 .. yn as y" *) (* We now replace the names y1 .. yn y by the actual names *) (* xi1 .. xin xi to be found in the i-th clause of the matrix *) let recover_initial_subpattern_names = List.map2 RelDecl.set_name let recover_and_adjust_alias_names names sign = let rec aux = function | [],[] -> [] | x::names, LocalAssum (_,t)::sign -> (x, LocalAssum (alias_of_pat x,t)) :: aux (names,sign) | names, (LocalDef (na,_,_) as decl)::sign -> (CAst.make @@ PatVar na, decl) :: aux (names,sign) | _ -> assert false in List.split (aux (names,sign)) let push_rels_eqn sign eqn = {eqn with rhs = {eqn.rhs with rhs_env = push_rel_context sign eqn.rhs.rhs_env} } let push_rels_eqn_with_names sign eqn = let subpats = List.rev (List.firstn (List.length sign) eqn.patterns) in let subpatnames = List.map alias_of_pat subpats in let sign = recover_initial_subpattern_names subpatnames sign in push_rels_eqn sign eqn let push_generalized_decl_eqn env n decl eqn = match RelDecl.get_name decl with | Anonymous -> push_rels_eqn [decl] eqn | Name _ -> push_rels_eqn [RelDecl.set_name (RelDecl.get_name (Environ.lookup_rel n eqn.rhs.rhs_env)) decl] eqn let drop_alias_eqn eqn = { eqn with alias_stack = List.tl eqn.alias_stack } let push_alias_eqn alias eqn = let aliasname = List.hd eqn.alias_stack in let eqn = drop_alias_eqn eqn in let alias = RelDecl.set_name aliasname alias in push_rels_eqn [alias] eqn (**********************************************************************) (* Functions to deal with elimination predicate *) (* 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)]psi and it has to 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) => ... end" or a "psi(yk)", with psi extracting xij from uik, should be inserted somewhere in Ti. - If T is undefined, an easy solution is to insert a "match z with (Ci xi1..xipi) => ... end" 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 *) (* Propagation of user-provided predicate through compilation steps *) let rec map_predicate f k ccl = function | [] -> f k ccl | Pushed (_,((_,tm),_,na)) :: rest -> let k' = length_of_tomatch_type_sign na tm in map_predicate f (k+k') ccl rest | (Alias _ | NonDepAlias) :: rest -> map_predicate f k ccl rest | Abstract _ :: rest -> map_predicate f (k+1) ccl rest let noccur_predicate_between sigma n = map_predicate (noccur_between sigma n) let liftn_predicate n = map_predicate (liftn n) let lift_predicate n = liftn_predicate n 1 let regeneralize_index_predicate sigma n = map_predicate (relocate_index sigma n 1) 0 let substnl_predicate sigma = map_predicate (substnl sigma) (* This is parallel bindings *) let subst_predicate (subst,copt) ccl tms = let sigma = match copt with | None -> subst | Some c -> c::subst in substnl_predicate sigma 0 ccl tms let specialize_predicate_var (cur,typ,dep) env tms ccl = let c = match dep with | Anonymous -> None | Name _ -> Some cur in let l = match typ with | IsInd (_, IndType (_, _), []) -> [] | IsInd (_, IndType (indf, realargs), names) -> let arsign,_ = get_arity env indf in let arsign = List.map EConstr.of_rel_decl arsign in subst_of_rel_context_instance arsign realargs | NotInd _ -> [] in subst_predicate (l,c) ccl tms (*****************************************************************************) (* 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 sigma (names,na) ny d tms ccl = let () = match na with | Anonymous -> anomaly (Pp.str "Undetected dependency") | _ -> () in let p = List.length names + 1 in let ccl = lift_predicate 1 ccl tms in regeneralize_index_predicate sigma (ny+p+1) ccl tms (*****************************************************************************) (* We just matched over cur:ind(realargs) in the following matching problem *) (* *) (* env |- match cur tms return ccl with ... end *) (* *) (* and we want to build the predicate corresponding to the individual *) (* matching over cur *) (* *) (* pred = fun X:realargstyps x:ind(X)] PI tms.ccl *) (* *) (* where pred is computed by abstract_predicate and PI tms.ccl by *) (* extract_predicate *) (*****************************************************************************) let rec extract_predicate ccl = function | (Alias _ | NonDepAlias)::tms -> (* substitution already done in build_branch *) extract_predicate ccl tms | Abstract (i,d)::tms -> mkProd_wo_LetIn d (extract_predicate ccl tms) | Pushed (_,((cur,NotInd _),_,na))::tms -> begin match na with | Anonymous -> extract_predicate ccl tms | Name _ -> let tms = lift_tomatch_stack 1 tms in let pred = extract_predicate ccl tms in subst1 cur pred end | Pushed (_,((cur,IsInd (_,IndType(_,realargs),_)),_,na))::tms -> let realargs = List.rev realargs in let k, nrealargs = match na with | Anonymous -> 0, realargs | Name _ -> 1, (cur :: realargs) in let tms = lift_tomatch_stack (List.length realargs + k) tms in let pred = extract_predicate ccl tms in substl nrealargs pred | [] -> ccl let abstract_predicate env sigma indf cur realargs (names,na) tms ccl = let sign = make_arity_signature env sigma true indf in (* n is the number of real args + 1 (+ possible let-ins in sign) *) let n = List.length sign in (* Before abstracting we generalize over cur and on those realargs *) (* that are rels, consistently with the specialization made in *) (* build_branch *) let tms = List.fold_right2 (fun par arg tomatch -> match EConstr.kind sigma par with | Rel i -> relocate_index_tomatch sigma (i+n) (destRel sigma arg) tomatch | _ -> tomatch) (realargs@[cur]) (Context.Rel.to_extended_list EConstr.mkRel 0 sign) (lift_tomatch_stack n tms) in (* Pred is already dependent in the current term to match (if *) (* (na<>Anonymous) and its realargs; we just need to adjust it to *) (* full sign if dep in cur is not taken into account *) let ccl = match na with | Anonymous -> lift_predicate 1 ccl tms | Name _ -> ccl in let pred = extract_predicate ccl tms in (* Build the predicate properly speaking *) let sign = List.map2 set_name (na::names) sign in it_mkLambda_or_LetIn_name env sigma pred sign (* [expand_arg] is used by [specialize_predicate] if Yk denotes [Xk;xk] or [Xk], it replaces gamma, x1...xn, x1...xk Yk+1...Yn |- pred by gamma, x1...xn, x1...xk-1 [Xk;xk] Yk+1...Yn |- pred (if dep) or by gamma, x1...xn, x1...xk-1 [Xk] Yk+1...Yn |- pred (if not dep) *) let expand_arg tms (p,ccl) ((_,t),_,na) = let k = length_of_tomatch_type_sign na t in (p+k,liftn_predicate (k-1) (p+1) ccl tms) let use_unit_judge evd = let j, ctx = coq_unit_judge () in let evd' = Evd.merge_context_set Evd.univ_flexible_alg evd ctx in evd', j let add_assert_false_case pb tomatch = let pats = List.map (fun _ -> CAst.make @@ PatVar Anonymous) tomatch in let aliasnames = List.map_filter (function Alias _ | NonDepAlias -> Some Anonymous | _ -> None) tomatch in [ { patterns = pats; rhs = { rhs_env = pb.env; rhs_vars = []; avoid_ids = []; it = None }; alias_stack = Anonymous::aliasnames; eqn_loc = None; used = ref false } ] let adjust_impossible_cases pb pred tomatch submat = match submat with | [] -> (** FIXME: This breaks if using evar-insensitive primitives. In particular, this means that the Evd.define below may redefine an already defined evar. See e.g. first definition of test for bug #3388. *) let pred = EConstr.Unsafe.to_constr pred in begin match kind_of_term pred with | Evar (evk,_) when snd (evar_source evk !(pb.evdref)) == Evar_kinds.ImpossibleCase -> if not (Evd.is_defined !(pb.evdref) evk) then begin let evd, default = use_unit_judge !(pb.evdref) in pb.evdref := Evd.define evk (EConstr.Unsafe.to_constr default.uj_type) evd end; add_assert_false_case pb tomatch | _ -> submat end | _ -> submat (*****************************************************************************) (* Let pred = PI [X;x:I(X)]. PI tms. P be a typing predicate for the *) (* following pattern-matching problem: *) (* *) (* Gamma |- match Pushed(c:I(V)) as x in I(X), tms return pred with...end *) (* *) (* where the branch with constructor Ci:(x1:T1)...(xn:Tn)->I(realargsi) *) (* is considered. Assume each Ti is some Ii(argsi) with Ti:PI Ui. sort_i *) (* We let subst = X:=realargsi;x:=Ci(x1,...,xn) and replace pred by *) (* *) (* pred' = PI [X1:Ui;x1:I1(X1)]...[Xn:Un;xn:In(Xn)]. (PI tms. P)[subst] *) (* *) (* s.t. the following well-typed sub-pattern-matching problem is obtained *) (* *) (* Gamma,x'1..x'n |- *) (* match *) (* Pushed(x'1) as x1 in I(X1), *) (* .., *) (* Pushed(x'n) as xn in I(Xn), *) (* tms *) (* return pred' *) (* with .. end *) (* *) (*****************************************************************************) let specialize_predicate newtomatchs (names,depna) arsign cs tms ccl = (* Assume some gamma st: gamma |- PI [X,x:I(X)]. PI tms. ccl *) let nrealargs = List.length names in let l = match depna with Anonymous -> 0 | Name _ -> 1 in let k = nrealargs + l in (* We adjust pred st: gamma, x1..xn |- PI [X,x:I(X)]. PI tms. ccl' *) (* so that x can later be instantiated by Ci(x1..xn) *) (* and X by the realargs for Ci *) let n = cs.cs_nargs in let ccl' = liftn_predicate n (k+1) ccl tms in (* We prepare the substitution of X and x:I(X) *) let realargsi = if not (Int.equal nrealargs 0) then CVars.subst_of_rel_context_instance arsign (Array.to_list cs.cs_concl_realargs) else [] in let realargsi = List.map EConstr.of_constr realargsi in let copti = match depna with | Anonymous -> None | Name _ -> Some (EConstr.of_constr (build_dependent_constructor cs)) in (* The substituends realargsi, copti are all defined in gamma, x1...xn *) (* We need _parallel_ bindings to get gamma, x1...xn |- PI tms. ccl'' *) (* Note: applying the substitution in tms is not important (is it sure?) *) let ccl'' = whd_betaiota Evd.empty (subst_predicate (realargsi, copti) ccl' tms) in (* We adjust ccl st: gamma, x'1..x'n, x1..xn, tms |- ccl'' *) let ccl''' = liftn_predicate n (n+1) ccl'' tms in (* We finally get gamma,x'1..x'n,x |- [X1;x1:I(X1)]..[Xn;xn:I(Xn)]pred'''*) snd (List.fold_left (expand_arg tms) (1,ccl''') newtomatchs) let find_predicate loc env evdref p current (IndType (indf,realargs)) dep tms = let pred = abstract_predicate env !evdref indf current realargs dep tms p in (pred, whd_betaiota !evdref (applist (pred, realargs@[current]))) (* Take into account that a type has been discovered to be inductive, leading to more dependencies in the predicate if the type has indices *) let adjust_predicate_from_tomatch tomatch (current,typ as ct) pb = let ((_,oldtyp),deps,na) = tomatch in match typ, oldtyp with | IsInd (_,_,names), NotInd _ -> let k = match na with | Anonymous -> 1 | Name _ -> 2 in let n = List.length names in { pb with pred = liftn_predicate n k pb.pred pb.tomatch }, (ct,List.map (fun i -> if i >= k then i+n else i) deps,na) | _ -> pb, (ct,deps,na) (* Remove commutative cuts that turn out to be non-dependent after some evars have been instantiated *) let rec ungeneralize sigma n ng body = match EConstr.kind sigma body with | Lambda (_,_,c) when Int.equal ng 0 -> subst1 (mkRel n) c | Lambda (na,t,c) -> (* We traverse an inner generalization *) mkLambda (na,t,ungeneralize sigma (n+1) (ng-1) c) | LetIn (na,b,t,c) -> (* We traverse an alias *) mkLetIn (na,b,t,ungeneralize sigma (n+1) ng c) | Case (ci,p,c,brs) -> (* We traverse a split *) let p = let sign,p = decompose_lam_assum sigma p in let sign2,p = decompose_prod_n_assum sigma ng p in let p = prod_applist sigma p [mkRel (n+List.length sign+ng)] in it_mkLambda_or_LetIn (it_mkProd_or_LetIn p sign2) sign in mkCase (ci,p,c,Array.map2 (fun q c -> let sign,b = decompose_lam_n_decls sigma q c in it_mkLambda_or_LetIn (ungeneralize sigma (n+q) ng b) sign) ci.ci_cstr_ndecls brs) | App (f,args) -> (* We traverse an inner generalization *) assert (isCase sigma f); mkApp (ungeneralize sigma n (ng+Array.length args) f,args) | _ -> assert false let ungeneralize_branch sigma n k (sign,body) cs = (sign,ungeneralize sigma (n+cs.cs_nargs) k body) let rec is_dependent_generalization sigma ng body = match EConstr.kind sigma body with | Lambda (_,_,c) when Int.equal ng 0 -> not (noccurn sigma 1 c) | Lambda (na,t,c) -> (* We traverse an inner generalization *) is_dependent_generalization sigma (ng-1) c | LetIn (na,b,t,c) -> (* We traverse an alias *) is_dependent_generalization sigma ng c | Case (ci,p,c,brs) -> (* We traverse a split *) Array.exists2 (fun q c -> let _,b = decompose_lam_n_decls sigma q c in is_dependent_generalization sigma ng b) ci.ci_cstr_ndecls brs | App (g,args) -> (* We traverse an inner generalization *) assert (isCase sigma g); is_dependent_generalization sigma (ng+Array.length args) g | _ -> assert false let is_dependent_branch sigma k (_,br) = is_dependent_generalization sigma k br let postprocess_dependencies evd tocheck brs tomatch pred deps cs = let rec aux k brs tomatch pred tocheck deps = match deps, tomatch with | [], _ -> brs,tomatch,pred,[] | n::deps, Abstract (i,d) :: tomatch -> let d = map_constr (fun c -> nf_evar evd c) d in let is_d = match d with LocalAssum _ -> false | LocalDef _ -> true in if is_d || List.exists (fun c -> dependent_decl evd (lift k c) d) tocheck && Array.exists (is_dependent_branch evd k) brs then (* Dependency in the current term to match and its dependencies is real *) let brs,tomatch,pred,inst = aux (k+1) brs tomatch pred (mkRel n::tocheck) deps in let inst = match d with | LocalAssum _ -> mkRel n :: inst | _ -> inst in brs, Abstract (i,d) :: tomatch, pred, inst else (* Finally, no dependency remains, so, we can replace the generalized *) (* terms by its actual value in both the remaining terms to match and *) (* the bodies of the Case *) let pred = lift_predicate (-1) pred tomatch in let tomatch = relocate_index_tomatch evd 1 (n+1) tomatch in let tomatch = lift_tomatch_stack (-1) tomatch in let brs = Array.map2 (ungeneralize_branch evd n k) brs cs in aux k brs tomatch pred tocheck deps | _ -> assert false in aux 0 brs tomatch pred tocheck deps (************************************************************************) (* Sorting equations by constructor *) let rec irrefutable env = function | { CAst.v = PatVar name } -> true | { CAst.v = PatCstr (cstr,args,_) } -> let ind = inductive_of_constructor cstr in let (_,mip) = Inductive.lookup_mind_specif env ind in let one_constr = Int.equal (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.make (Array.length cstrs) [] in let only_default = ref None 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 | { CAst.v = PatVar name } -> (* This is a default clause that we expand *) for i=1 to Array.length cstrs do let args = make_anonymous_patvars cstrs.(i-1).cs_nargs in brs.(i-1) <- (args, name, rest) :: brs.(i-1) done; if !only_default == None then only_default := Some true | { CAst.v = PatCstr (((_,i)),args,name) ; loc } -> (* This is a regular clause *) only_default := Some false; brs.(i-1) <- (args, name, rest) :: brs.(i-1)) mat () in (brs,Option.default false !only_default) (************************************************************************) (* Here starts the pattern-matching compilation algorithm *) (* Abstracting over dependent subterms to match *) let rec generalize_problem names pb = function | [] -> pb, [] | i::l -> let pb',deps = generalize_problem names pb l in let d = map_constr (lift i) (lookup_rel i pb.env) in begin match d with | LocalDef (Anonymous,_,_) -> pb', deps | _ -> (* for better rendering *) let d = RelDecl.map_type (fun c -> whd_betaiota !(pb.evdref) c) d in let tomatch = lift_tomatch_stack 1 pb'.tomatch in let tomatch = relocate_index_tomatch !(pb.evdref) (i+1) 1 tomatch in { pb' with tomatch = Abstract (i,d) :: tomatch; pred = generalize_predicate !(pb'.evdref) names i d pb'.tomatch pb'.pred }, i::deps end (* No more patterns: typing the right-hand side of equations *) let build_leaf pb = let rhs = extract_rhs pb in let j = pb.typing_function (mk_tycon pb.pred) rhs.rhs_env pb.evdref rhs.it in j_nf_evar !(pb.evdref) j (* Build the sub-pattern-matching problem for a given branch "C x1..xn as x" *) (* spiwack: the [initial] argument keeps track whether the branch is a toplevel branch ([true]) or a deep one ([false]). *) let build_branch initial current realargs deps (realnames,curname) pb arsign eqns const_info = (* We remember that we descend through constructor C *) let history = push_history_pattern const_info.cs_nargs (fst const_info.cs_cstr) pb.history in (* We prepare the matching on x1:T1 .. xn:Tn using some heuristic to *) (* build the name x1..xn from the names present in the equations *) (* that had matched constructor C *) let cs_args = const_info.cs_args in let cs_args = List.map (fun d -> map_rel_decl EConstr.of_constr d) cs_args in let names,aliasname = get_names pb.env !(pb.evdref) cs_args eqns in let typs = List.map2 RelDecl.set_name names cs_args in (* Beta-iota-normalize types to better compatibility of refine with 8.4 behavior *) (* This is a bit too strong I think, in the sense that what we would *) (* really like is to have beta-iota reduction only at the positions where *) (* parameters are substituted *) let typs = List.map (map_type (nf_betaiota !(pb.evdref))) typs in (* We build the matrix obtained by expanding the matching on *) (* "C x1..xn as x" followed by a residual matching on eqn into *) (* a matching on "x1 .. xn eqn" *) let submat = List.map (fun (tms,_,eqn) -> prepend_pattern tms eqn) eqns in (* We adjust the terms to match in the context they will be once the *) (* context [x1:T1,..,xn:Tn] will have been pushed on the current env *) let typs' = List.map_i (fun i d -> (mkRel i, map_constr (lift i) d)) 1 typs in let extenv = push_rel_context typs pb.env in let typs' = List.map (fun (c,d) -> (c,extract_inductive_data extenv !(pb.evdref) d,d)) typs' in (* We compute over which of x(i+1)..xn and x matching on xi will need a *) (* generalization *) let dep_sign = find_dependencies_signature !(pb.evdref) (dependencies_in_rhs !(pb.evdref) const_info.cs_nargs current pb.tomatch 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 = EConstr.of_constr (build_dependent_constructor const_info) in (* Current context Gamma has the form Gamma1;cur:I(realargs);Gamma2 *) (* We go from Gamma |- PI tms. pred to *) (* Gamma;x1..xn;curalias:I(x1..xn) |- PI tms'. pred' *) (* where, in tms and pred, those realargs that are vars are *) (* replaced by the corresponding xi and cur replaced by curalias *) let cirealargs = Array.map_to_list EConstr.of_constr const_info.cs_concl_realargs in (* Do the specialization for terms to match *) let tomatch = List.fold_right2 (fun par arg tomatch -> match EConstr.kind !(pb.evdref) par with | Rel i -> replace_tomatch !(pb.evdref) (i+const_info.cs_nargs) arg tomatch | _ -> tomatch) (current::realargs) (ci::cirealargs) (lift_tomatch_stack const_info.cs_nargs pb.tomatch) in let pred_is_not_dep = noccur_predicate_between !(pb.evdref) 1 (List.length realnames + 1) pb.pred tomatch in let typs' = List.map2 (fun (tm, (tmtyp,_), decl) deps -> let na = RelDecl.get_name decl in let na = match curname, na with | Name _, Anonymous -> curname | Name _, Name _ -> na | Anonymous, _ -> if List.is_empty deps && pred_is_not_dep then Anonymous else force_name na in ((tm,tmtyp),deps,na)) typs' (List.rev dep_sign) in (* Do the specialization for the predicate *) let pred = specialize_predicate typs' (realnames,curname) arsign const_info tomatch pb.pred in let currents = List.map (fun x -> Pushed (false,x)) typs' in let alias = match aliasname with | Anonymous -> NonDepAlias | Name _ -> let cur_alias = lift const_info.cs_nargs current in let ind = mkApp ( applist (mkIndU (inductive_of_constructor (fst const_info.cs_cstr), EInstance.make (snd const_info.cs_cstr)), List.map (EConstr.of_constr %> lift const_info.cs_nargs) const_info.cs_params), Array.map EConstr.of_constr const_info.cs_concl_realargs) in Alias (initial,(aliasname,cur_alias,(ci,ind))) in let tomatch = List.rev_append (alias :: currents) tomatch in let submat = adjust_impossible_cases pb pred tomatch submat in let () = match submat with | [] -> raise_pattern_matching_error (pb.env, Evd.empty, NonExhaustive (complete_history history)) | _ -> () in typs, { pb with env = extenv; tomatch = tomatch; pred = pred; history = history; mat = List.map (push_rels_eqn_with_names typs) submat } (********************************************************************** INVARIANT: pb = { env, pred, tomatch, mat, ...} tomatch = list of Pushed (c:T), Abstract (na:T), Alias (c:T) or NonDepAlias all terms and types in Pushed, Abstract and Alias are relative to env enriched by the Abstract coming before *) (**********************************************************************) (* Main compiling descent *) let rec compile pb = match pb.tomatch with | Pushed cur :: rest -> match_current { pb with tomatch = rest } cur | Alias (initial,x) :: rest -> compile_alias initial pb x rest | NonDepAlias :: rest -> compile_non_dep_alias pb rest | Abstract (i,d) :: rest -> compile_generalization pb i d rest | [] -> build_leaf pb (* Case splitting *) and match_current pb (initial,tomatch) = let tm = adjust_tomatch_to_pattern pb tomatch in let pb,tomatch = adjust_predicate_from_tomatch tomatch tm pb in let ((current,typ),deps,dep) = tomatch in match typ with | NotInd (_,typ) -> check_all_variables pb.env !(pb.evdref) typ pb.mat; compile_all_variables initial tomatch pb | IsInd (_,(IndType(indf,realargs) as indt),names) -> let mind,_ = dest_ind_family indf in let mind = Tacred.check_privacy pb.env mind in let cstrs = get_constructors pb.env indf in let arsign, _ = get_arity pb.env indf in let eqns,onlydflt = group_equations pb (fst mind) current cstrs pb.mat in let no_cstr = Int.equal (Array.length cstrs) 0 in if (not no_cstr || not (List.is_empty pb.mat)) && onlydflt then compile_all_variables initial tomatch pb else (* We generalize over terms depending on current term to match *) let pb,deps = generalize_problem (names,dep) pb deps in (* We compile branches *) let brvals = Array.map2 (compile_branch initial current realargs (names,dep) deps pb arsign) eqns cstrs in (* We build the (elementary) case analysis *) let depstocheck = current::binding_vars_of_inductive !(pb.evdref) typ in let brvals,tomatch,pred,inst = postprocess_dependencies !(pb.evdref) depstocheck brvals pb.tomatch pb.pred deps cstrs in let brvals = Array.map (fun (sign,body) -> it_mkLambda_or_LetIn body sign) brvals in let (pred,typ) = find_predicate pb.caseloc pb.env pb.evdref pred current indt (names,dep) tomatch in let ci = make_case_info pb.env (fst mind) pb.casestyle in let pred = nf_betaiota !(pb.evdref) pred in let case = make_case_or_project pb.env !(pb.evdref) indf ci pred current brvals in Typing.check_allowed_sort pb.env !(pb.evdref) mind current pred; { uj_val = applist (case, inst); uj_type = prod_applist !(pb.evdref) typ inst } (* Building the sub-problem when all patterns are variables. Case where [current] is an intially pushed term. *) and shift_problem ((current,t),_,na) pb = let ty = type_of_tomatch t in let tomatch = lift_tomatch_stack 1 pb.tomatch in let pred = specialize_predicate_var (current,t,na) pb.env pb.tomatch pb.pred in let pb = { pb with env = push_rel (LocalDef (na,current,ty)) pb.env; tomatch = tomatch; pred = lift_predicate 1 pred tomatch; history = pop_history pb.history; mat = List.map (push_current_pattern (current,ty)) pb.mat } in let j = compile pb in { uj_val = subst1 current j.uj_val; uj_type = subst1 current j.uj_type } (* Building the sub-problem when all patterns are variables, non-initial case. Variables which appear as subterms of constructor are already introduced in the context, we avoid creating aliases to themselves by treating this case specially. *) and pop_problem ((current,t),_,na) pb = let pred = specialize_predicate_var (current,t,na) pb.env pb.tomatch pb.pred in let pb = { pb with pred = pred; history = pop_history pb.history; mat = List.map push_noalias_current_pattern pb.mat } in compile pb (* Building the sub-problem when all patterns are variables. *) and compile_all_variables initial cur pb = if initial then shift_problem cur pb else pop_problem cur pb (* Building the sub-problem when all patterns are variables *) and compile_branch initial current realargs names deps pb arsign eqns cstr = let sign, pb = build_branch initial current realargs deps names pb arsign eqns cstr in sign, (compile pb).uj_val (* Abstract over a declaration before continuing splitting *) and compile_generalization pb i d rest = let pb = { pb with env = push_rel d pb.env; tomatch = rest; mat = List.map (push_generalized_decl_eqn pb.env i d) pb.mat } in let j = compile pb in { uj_val = mkLambda_or_LetIn d j.uj_val; uj_type = mkProd_wo_LetIn d j.uj_type } (* spiwack: the [initial] argument keeps track whether the alias has been introduced by a toplevel branch ([true]) or a deep one ([false]). *) and compile_alias initial pb (na,orig,(expanded,expanded_typ)) rest = let f c t = let alias = LocalDef (na,c,t) in let pb = { pb with env = push_rel alias pb.env; tomatch = lift_tomatch_stack 1 rest; pred = lift_predicate 1 pb.pred pb.tomatch; history = pop_history_pattern pb.history; mat = List.map (push_alias_eqn alias) pb.mat } in let j = compile pb in let sigma = !(pb.evdref) in { uj_val = if isRel sigma c || isVar sigma c || count_occurrences sigma (mkRel 1) j.uj_val <= 1 then subst1 c j.uj_val else mkLetIn (na,c,t,j.uj_val); uj_type = subst1 c j.uj_type } in (* spiwack: when an alias appears on a deep branch, its non-expanded form is automatically a variable of the same name. We avoid introducing such superfluous aliases so that refines are elegant. *) let just_pop () = let pb = { pb with tomatch = rest; history = pop_history_pattern pb.history; mat = List.map drop_alias_eqn pb.mat } in compile pb in let sigma = !(pb.evdref) in (* If the "match" was orginally over a variable, as in "match x with O => true | n => n end", we give preference to non-expansion in the default clause (i.e. "match x with O => true | n => n end" rather than "match x with O => true | S p => S p end"; computationally, this avoids reallocating constructors in cbv evaluation; the drawback is that it might duplicate the instances of the term to match when the corresponding variable is substituted by a non-evaluated expression *) if not (Flags.is_program_mode ()) && (isRel sigma orig || isVar sigma orig) then (* Try to compile first using non expanded alias *) try if initial then f orig (Retyping.get_type_of pb.env sigma orig) else just_pop () with e when precatchable_exception e -> (* Try then to compile using expanded alias *) (* Could be needed in case of dependent return clause *) pb.evdref := sigma; f expanded expanded_typ else (* Try to compile first using expanded alias *) try f expanded expanded_typ with e when precatchable_exception e -> (* Try then to compile using non expanded alias *) (* Could be needed in case of a recursive call which requires to be on a variable for size reasons *) pb.evdref := sigma; if initial then f orig (Retyping.get_type_of pb.env !(pb.evdref) orig) else just_pop () (* Remember that a non-trivial pattern has been consumed *) and compile_non_dep_alias pb rest = let pb = { pb with tomatch = rest; history = pop_history_pattern pb.history; mat = List.map drop_alias_eqn pb.mat } in compile pb (* 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 initial_lpat,initial_rhs = lpat,rhs in let initial_rhs = rhs in let rhs = { rhs_env = env; rhs_vars = free_glob_vars initial_rhs; avoid_ids = ids@(ids_of_named_context (named_context env)); it = Some initial_rhs } in { patterns = initial_lpat; alias_stack = []; eqn_loc = loc; used = ref false; rhs = rhs } in List.map build_eqn eqns (***************** Building an inversion predicate ************************) (* Let "match t1 in I1 u11..u1n_1 ... tm in Im um1..umn_m with ... end : T" be a pattern-matching problem. We assume that each uij can be decomposed under the form pij(vij1..vijq_ij) where pij(aij1..aijq_ij) is a pattern depending on some variables aijk and the vijk are instances of these variables. We also assume that each ti has the form of a pattern qi(wi1..wiq_i) where qi(bi1..biq_i) is a pattern depending on some variables bik and the wik are instances of these variables (in practice, there is no reason that ti is already constructed and the qi will be degenerated). We then look for a type U(..a1jk..b1 .. ..amjk..bm) so that T = U(..v1jk..t1 .. ..vmjk..tm). This a higher-order matching problem with a priori different solutions (one of them if T itself!). We finally invert the uij and the ti and build the return clause phi(x11..x1n_1y1..xm1..xmn_mym) = match x11..x1n_1 y1 .. xm1..xmn_m ym with | p11..p1n_1 q1 .. pm1..pmn_m qm => U(..a1jk..b1 .. ..amjk..bm) | _ .. _ _ .. _ .. _ _ => True end so that "phi(u11..u1n_1t1..um1..umn_mtm) = T" (note that the clause returning True never happens and any inhabited type can be put instead). *) let adjust_to_extended_env_and_remove_deps env extenv sigma subst t = let n = Context.Rel.length (rel_context env) in let n' = Context.Rel.length (rel_context extenv) in (* We first remove the bindings that are dependently typed (they are difficult to manage and it is not sure these are so useful in practice); Notes: - [subst] is made of pairs [(id,u)] where id is a name in [extenv] and [u] a term typed in [env]; - [subst0] is made of items [(p,u,(u,ty))] where [ty] is the type of [u] and both are adjusted to [extenv] while [p] is the index of [id] in [extenv] (after expansion of the aliases) *) let map (x, u) = (* d1 ... dn dn+1 ... dn'-p+1 ... dn' *) (* \--env-/ (= x:ty) *) (* \--------------extenv------------/ *) let (p, _, _) = lookup_rel_id x (rel_context extenv) in let rec traverse_local_defs p = match lookup_rel p extenv with | LocalDef (_,c,_) -> assert (isRel sigma c); traverse_local_defs (p + destRel sigma c) | LocalAssum _ -> p in let p = traverse_local_defs p in let u = lift (n' - n) u in try Some (p, u, expand_vars_in_term extenv sigma u) (* pedrot: does this really happen to raise [Failure _]? *) with Failure _ -> None in let subst0 = List.map_filter map subst in let t0 = lift (n' - n) t in (subst0, t0) let push_binder d (k,env,subst) = (k+1,push_rel d env,List.map (fun (na,u,d) -> (na,lift 1 u,d)) subst) let rec list_assoc_in_triple x = function [] -> raise Not_found | (a, b, _)::l -> if Int.equal a x then b else list_assoc_in_triple x l (* Let vijk and ti be a set of dependent terms and T a type, all * defined in some environment env. The vijk and ti are supposed to be * instances for variables aijk and bi. * * [abstract_tycon Gamma0 Sigma subst T Gamma] looks for U(..v1jk..t1 .. ..vmjk..tm) * defined in some extended context * "Gamma0, ..a1jk:V1jk.. b1:W1 .. ..amjk:Vmjk.. bm:Wm" * such that env |- T = U(..v1jk..t1 .. ..vmjk..tm). To not commit to * a particular solution, we replace each subterm t in T that unifies with * a subset u1..ul of the vijk and ti by a special evar * ?id(x=t;c1:=c1,..,cl=cl) defined in context Gamma0,x,c1,...,cl |- ?id * (where the c1..cl are the aijk and bi matching the u1..ul), and * similarly for each ti. *) let abstract_tycon ?loc env evdref subst tycon extenv t = let t = nf_betaiota !evdref t in (* it helps in some cases to remove K-redex*) let src = match EConstr.kind !evdref t with | Evar (evk,_) -> (Loc.tag ?loc @@ Evar_kinds.SubEvar evk) | _ -> (Loc.tag ?loc @@ Evar_kinds.CasesType true) in let subst0,t0 = adjust_to_extended_env_and_remove_deps env extenv !evdref subst t in (* We traverse the type T of the original problem Xi looking for subterms that match the non-constructor part of the constraints (this part is in subst); these subterms are the "good" subterms and we replace them by an evar that may depend (and only depend) on the corresponding convertible subterms of the substitution *) let rec aux (k,env,subst as x) t = match EConstr.kind !evdref t with | Rel n when is_local_def (lookup_rel n env) -> t | Evar ev -> let ty = get_type_of env !evdref t in let ty = Evarutil.evd_comb1 (refresh_universes (Some false) env) evdref ty in let inst = List.map_i (fun i _ -> try list_assoc_in_triple i subst0 with Not_found -> mkRel i) 1 (rel_context env) in let ev' = e_new_evar env evdref ~src ty in begin match solve_simple_eqn (evar_conv_x full_transparent_state) env !evdref (None,ev,substl inst ev') with | Success evd -> evdref := evd | UnifFailure _ -> assert false end; ev' | _ -> let good = List.filter (fun (_,u,_) -> is_conv_leq env !evdref t u) subst in match good with | [] -> map_constr_with_full_binders !evdref push_binder aux x t | (_, _, u) :: _ -> (* u is in extenv *) let vl = List.map pi1 good in let ty = let ty = get_type_of env !evdref t in Evarutil.evd_comb1 (refresh_universes (Some false) env) evdref ty in let ty = lift (-k) (aux x ty) in let depvl = free_rels !evdref ty in let inst = List.map_i (fun i _ -> if Int.List.mem i vl then u else mkRel i) 1 (rel_context extenv) in let rel_filter = List.map (fun a -> not (isRel !evdref a) || dependent !evdref a u || Int.Set.mem (destRel !evdref a) depvl) inst in let named_filter = List.map (fun d -> local_occur_var !evdref (NamedDecl.get_id d) u) (named_context extenv) in let filter = Filter.make (rel_filter @ named_filter) in let candidates = u :: List.map mkRel vl in let ev = e_new_evar extenv evdref ~src ~filter ~candidates ty in lift k ev in aux (0,extenv,subst0) t0 let build_tycon ?loc env tycon_env s subst tycon extenv evdref t = let t,tt = match t with | None -> (* This is the situation we are building a return predicate and we are in an impossible branch *) let n = Context.Rel.length (rel_context env) in let n' = Context.Rel.length (rel_context tycon_env) in let impossible_case_type, u = e_new_type_evar (reset_context env) evdref univ_flexible_alg ~src:(Loc.tag ?loc Evar_kinds.ImpossibleCase) in (lift (n'-n) impossible_case_type, mkSort u) | Some t -> let t = abstract_tycon ?loc tycon_env evdref subst tycon extenv t in let evd,tt = Typing.type_of extenv !evdref t in evdref := evd; (t,tt) in let b = e_cumul env evdref tt (mkSort s) (* side effect *) in if not b then anomaly (Pp.str "Build_tycon: should be a type"); { uj_val = t; uj_type = tt } (* For a multiple pattern-matching problem Xi on t1..tn with return * type T, [build_inversion_problem Gamma Sigma (t1..tn) T] builds a return * predicate for Xi that is itself made by an auxiliary * pattern-matching problem of which the first clause reveals the * pattern structure of the constraints on the inductive types of the t1..tn, * and the second clause is a wildcard clause for catching the * impossible cases. See above "Building an inversion predicate" for * further explanations *) let build_inversion_problem loc env sigma tms t = let make_patvar t (subst,avoid) = let id = next_name_away (named_hd env sigma t Anonymous) avoid in CAst.make @@ PatVar (Name id), ((id,t)::subst, id::avoid) in let rec reveal_pattern t (subst,avoid as acc) = match EConstr.kind sigma (whd_all env sigma t) with | Construct (cstr,u) -> CAst.make (PatCstr (cstr,[],Anonymous)), acc | App (f,v) when isConstruct sigma f -> let cstr,u = destConstruct sigma f in let n = constructor_nrealargs_env env cstr in let l = List.lastn n (Array.to_list v) in let l,acc = List.fold_map' reveal_pattern l acc in CAst.make (PatCstr (cstr,l,Anonymous)), acc | _ -> make_patvar t acc in let rec aux n env acc_sign tms acc = match tms with | [] -> [], acc_sign, acc | (t, IsInd (_,IndType(indf,realargs),_)) :: tms -> let patl,acc = List.fold_map' reveal_pattern realargs acc in let pat,acc = make_patvar t acc in let indf' = lift_inductive_family n indf in let sign = make_arity_signature env sigma true indf' in let patl = pat :: List.rev patl in let patl,sign = recover_and_adjust_alias_names patl sign in let p = List.length patl in let env' = push_rel_context sign env in let patl',acc_sign,acc = aux (n+p) env' (sign@acc_sign) tms acc in List.rev_append patl patl',acc_sign,acc | (t, NotInd (bo,typ)) :: tms -> let pat,acc = make_patvar t acc in let d = LocalAssum (alias_of_pat pat,typ) in let patl,acc_sign,acc = aux (n+1) (push_rel d env) (d::acc_sign) tms acc in pat::patl,acc_sign,acc in let avoid0 = ids_of_context env in (* [patl] is a list of patterns revealing the substructure of constructors present in the constraints on the type of the multiple terms t1..tn that are matched in the original problem; [subst] is the substitution of the free pattern variables in [patl] that returns the non-constructor parts of the constraints. Especially, if the ti has type I ui1..uin_i, and the patterns associated to ti are pi1..pin_i, then subst(pij) is uij; the substitution is useful to recognize which subterms of the whole type T of the original problem have to be abstracted *) let patl,sign,(subst,avoid) = aux 0 env [] tms ([],avoid0) in let n = List.length sign in let decls = List.map_i (fun i d -> (mkRel i, map_constr (lift i) d)) 1 sign in let pb_env = push_rel_context sign env in let decls = List.map (fun (c,d) -> (c,extract_inductive_data pb_env sigma d,d)) decls in let decls = List.rev decls in let dep_sign = find_dependencies_signature sigma (List.make n true) decls in let sub_tms = List.map2 (fun deps (tm, (tmtyp,_), decl) -> let na = if List.is_empty deps then Anonymous else force_name (RelDecl.get_name decl) in Pushed (true,((tm,tmtyp),deps,na))) dep_sign decls in let subst = List.map (fun (na,t) -> (na,lift n t)) subst in (* [main_eqn] is the main clause of the auxiliary pattern-matching that serves as skeleton for the return type: [patl] is the substructure of constructors extracted from the list of constraints on the inductive types of the multiple terms matched in the original pattern-matching problem Xi *) let main_eqn = { patterns = patl; alias_stack = []; eqn_loc = None; used = ref false; rhs = { rhs_env = pb_env; (* we assume all vars are used; in practice we discard dependent vars so that the field rhs_vars is normally not used *) rhs_vars = List.map fst subst; avoid_ids = avoid; it = Some (lift n t) } } in (* [catch_all] is a catch-all default clause of the auxiliary pattern-matching, if needed: it will catch the clauses of the original pattern-matching problem Xi whose type constraints are incompatible with the constraints on the inductive types of the multiple terms matched in Xi *) let catch_all_eqn = if List.for_all (irrefutable env) patl then (* No need for a catch all clause *) [] else [ { patterns = List.map (fun _ -> CAst.make @@ PatVar Anonymous) patl; alias_stack = []; eqn_loc = None; used = ref false; rhs = { rhs_env = pb_env; rhs_vars = []; avoid_ids = avoid0; it = None } } ] in (* [pb] is the auxiliary pattern-matching serving as skeleton for the return type of the original problem Xi *) let s' = Retyping.get_sort_of env sigma t in let sigma, s = Evd.new_sort_variable univ_flexible_alg sigma in let sigma = Evd.set_leq_sort env sigma s' s in let evdref = ref sigma in let pb = { env = pb_env; evdref = evdref; pred = (*ty *) mkSort s; tomatch = sub_tms; history = start_history n; mat = main_eqn :: catch_all_eqn; caseloc = loc; casestyle = RegularStyle; typing_function = build_tycon ?loc env pb_env s subst} in let pred = (compile pb).uj_val in (!evdref,pred) (* Here, [pred] is assumed to be in the context built from all *) (* realargs and terms to match *) let build_initial_predicate arsign pred = let rec buildrec n pred tmnames = function | [] -> List.rev tmnames,pred | (decl::realdecls)::lnames -> let na = RelDecl.get_name decl in let n' = n + List.length realdecls in buildrec (n'+1) pred (force_name na::tmnames) lnames | _ -> assert false in buildrec 0 pred [] (List.rev arsign) let extract_arity_signature ?(dolift=true) env0 tomatchl tmsign = let lift = if dolift then lift else fun n t -> t in let get_one_sign n tm (na,t) = match tm with | NotInd (bo,typ) -> (match t with | None -> (match bo with | None -> [LocalAssum (na, lift n typ)] | Some b -> [LocalDef (na, lift n b, lift n typ)]) | Some (loc,_) -> user_err ?loc (str"Unexpected type annotation for a term of non inductive type.")) | IsInd (term,IndType(indf,realargs),_) -> let indf' = if dolift then lift_inductive_family n indf else indf in let ((ind,u),_) = dest_ind_family indf' in let nrealargs_ctxt = inductive_nrealdecls_env env0 ind in let arsign = fst (get_arity env0 indf') in let arsign = List.map (fun d -> map_rel_decl EConstr.of_constr d) arsign in let realnal = match t with | Some (loc,(ind',realnal)) -> if not (eq_ind ind ind') then user_err ?loc (str "Wrong inductive type."); if not (Int.equal nrealargs_ctxt (List.length realnal)) then anomaly (Pp.str "Ill-formed 'in' clause in cases"); List.rev realnal | None -> List.make nrealargs_ctxt Anonymous in LocalAssum (na, EConstr.of_constr (build_dependent_inductive env0 indf')) ::(List.map2 RelDecl.set_name 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 inh_conv_coerce_to_tycon ?loc env evdref j tycon = match tycon with | Some p -> let (evd',j) = Coercion.inh_conv_coerce_to ?loc true env !evdref j p in evdref := evd'; j | None -> j (* We put the tycon inside the arity signature, possibly discovering dependencies. *) let prepare_predicate_from_arsign_tycon env sigma loc tomatchs arsign c = let nar = List.fold_left (fun n sign -> Context.Rel.nhyps sign + n) 0 arsign in let subst, len = List.fold_right2 (fun (tm, tmtype) sign (subst, len) -> let signlen = List.length sign in match EConstr.kind sigma tm with | Rel n when dependent sigma tm c && Int.equal signlen 1 (* The term to match is not of a dependent type itself *) -> ((n, len) :: subst, len - signlen) | Rel n when signlen > 1 (* The term is of a dependent type, maybe some variable in its type appears in the tycon. *) -> (match tmtype with NotInd _ -> (subst, len - signlen) | IsInd (_, IndType(indf,realargs),_) -> let subst, len = List.fold_left (fun (subst, len) arg -> match EConstr.kind sigma arg with | Rel n when dependent sigma arg c -> ((n, len) :: subst, pred len) | _ -> (subst, pred len)) (subst, len) realargs in let subst = if dependent sigma tm c && List.for_all (isRel sigma) realargs then (n, len) :: subst else subst in (subst, pred len)) | _ -> (subst, len - signlen)) (List.rev tomatchs) arsign ([], nar) in let rec predicate lift c = match EConstr.kind sigma c with | Rel n when n > lift -> (try (* Make the predicate dependent on the matched variable *) let idx = Int.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)) | _ -> EConstr.map_with_binders sigma succ predicate lift c in assert (len == 0); let p = predicate 0 c in let env' = List.fold_right push_rel_context arsign env in try let sigma' = fst (Typing.type_of env' sigma p) in Some (sigma', p) with e when precatchable_exception e -> None (* 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: we try to specialize the * tycon to make the predicate if it is not closed. *) exception LocalOccur let noccur_with_meta sigma n m term = let rec occur_rec n c = match EConstr.kind sigma c with | Rel p -> if n<=p && p (match EConstr.kind sigma f with | Cast (c,_,_) when isMeta sigma c -> () | Meta _ -> () | _ -> EConstr.iter_with_binders sigma succ occur_rec n c) | Evar (_, _) -> () | _ -> EConstr.iter_with_binders sigma succ occur_rec n c in try (occur_rec n term; true) with LocalOccur -> false let prepare_predicate ?loc typing_fun env sigma tomatchs arsign tycon pred = let refresh_tycon sigma t = (** If we put the typing constraint in the term, it has to be refreshed to preserve the invariant that no algebraic universe can appear in the term. *) refresh_universes ~status:Evd.univ_flexible ~onlyalg:true (Some true) env sigma t in let preds = match pred, tycon with (* No return clause *) | None, Some t when not (noccur_with_meta sigma 0 max_int t) -> (* If the tycon is not closed w.r.t real variables, we try *) (* two different strategies *) (* First strategy: we abstract the tycon wrt to the dependencies *) let sigma, t = refresh_tycon sigma t in let p1 = prepare_predicate_from_arsign_tycon env sigma loc tomatchs arsign t in (* Second strategy: we build an "inversion" predicate *) let sigma2,pred2 = build_inversion_problem loc env sigma tomatchs t in (match p1 with | Some (sigma1,pred1) -> [sigma1, pred1; sigma2, pred2] | None -> [sigma2, pred2]) | None, _ -> (* No dependent type constraint, or no constraints at all: *) (* we use two strategies *) let sigma,t = match tycon with | Some t -> refresh_tycon sigma t | None -> let sigma = Sigma.Unsafe.of_evar_map sigma in let Sigma ((t, _), sigma, _) = new_type_evar env sigma univ_flexible_alg ~src:(Loc.tag ?loc @@ Evar_kinds.CasesType false) in let sigma = Sigma.to_evar_map sigma in sigma, t in (* First strategy: we build an "inversion" predicate *) let sigma1,pred1 = build_inversion_problem loc env sigma tomatchs t in (* Second strategy: we directly use the evar as a non dependent pred *) let pred2 = lift (List.length (List.flatten arsign)) t in [sigma1, pred1; sigma, pred2] (* Some type annotation *) | Some rtntyp, _ -> (* We extract the signature of the arity *) let envar = List.fold_right push_rel_context arsign env in let sigma, newt = new_sort_variable univ_flexible_alg sigma in let evdref = ref sigma in let predcclj = typing_fun (mk_tycon (mkSort newt)) envar evdref rtntyp in let sigma = !evdref in let predccl = nf_evar sigma predcclj.uj_val in [sigma, predccl] in List.map (fun (sigma,pred) -> let (nal,pred) = build_initial_predicate arsign pred in sigma,nal,pred) preds (** Program cases *) open Program let ($) f x = f x let string_of_name name = match name with | Anonymous -> "anonymous" | Name n -> Id.to_string 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 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_" ^ Id.to_string id) in let hid' = next_ident_away hid avoid in hid' let mk_eq evdref typ x y = papp evdref coq_eq_ind [| typ; x ; y |] let mk_eq_refl evdref typ x = papp evdref coq_eq_refl [| typ; x |] let mk_JMeq evdref typ x typ' y = papp evdref coq_JMeq_ind [| typ; x ; typ'; y |] let mk_JMeq_refl evdref typ x = papp evdref coq_JMeq_refl [| typ; x |] let hole = CAst.make @@ GHole (Evar_kinds.QuestionMark (Evar_kinds.Define false), Misctypes.IntroAnonymous, None) let constr_of_pat env evdref arsign pat avoid = let rec typ env (ty, realargs) pat avoid = let loc = pat.CAst.loc in match pat.CAst.v with | PatVar 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 ((CAst.make ?loc @@ PatVar name), [LocalAssum (name, ty)] @ realargs, mkRel 1, ty, (List.map (fun x -> mkRel 1) realargs), 1, avoid) | PatCstr (((_, i) as cstr),args,alias) -> let cind = inductive_of_constructor cstr in let IndType (indf, _) = try find_rectype env ( !evdref) (lift (-(List.length realargs)) ty) with Not_found -> error_case_not_inductive env !evdref {uj_val = ty; uj_type = Typing.unsafe_type_of env !evdref ty} in let (ind,u), params = dest_ind_family indf in let params = List.map EConstr.of_constr params in if not (eq_ind ind cind) then error_bad_constructor ?loc env cstr ind; let cstrs = get_constructors env indf in let ci = cstrs.(i-1) in let nb_args_constr = ci.cs_nargs in assert (Int.equal nb_args_constr (List.length args)); let patargs, args, sign, env, n, m, avoid = List.fold_right2 (fun decl ua (patargs, args, sign, env, n, m, avoid) -> let t = EConstr.of_constr (RelDecl.get_type decl) in let pat', sign', arg', typ', argtypargs, n', avoid = let liftt = liftn (List.length sign) (succ (List.length args)) t in typ env (substl args liftt, []) ua avoid in let args' = arg' :: List.map (lift n') args in let env' = push_rel_context 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' = CAst.make ?loc @@ PatCstr (cstr, patargs, alias) in let cstr = mkConstructU (on_snd EInstance.make ci.cs_cstr) in let app = applist (cstr, List.map (lift (List.length sign)) params) in let app = applist (app, args) in let apptype = Retyping.get_type_of env ( !evdref) app in let IndType (indf, realargs) = find_rectype env (!evdref) apptype in match alias with Anonymous -> pat', sign, app, apptype, realargs, n, avoid | Name id -> let sign = LocalAssum (alias, lift m ty) :: sign in let avoid = id :: avoid in let sign, i, avoid = try let env = push_rel_context sign env in evdref := the_conv_x_leq (push_rel_context sign env) (lift (succ m) ty) (lift 1 apptype) !evdref; let eq_t = mk_eq evdref (lift (succ m) ty) (mkRel 1) (* alias *) (lift 1 app) (* aliased term *) in let neq = eq_id avoid id in LocalDef (Name neq, 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 (RelDecl.get_type (List.hd arsign), List.tl arsign) pat avoid in pat', (sign, patc, (RelDecl.get_type (List.hd arsign), args), pat'), avoid (* shadows functional version *) let eq_id avoid id = let hid = Id.of_string ("Heq_" ^ Id.to_string id) in let hid' = next_ident_away hid !avoid in avoid := hid' :: !avoid; hid' let is_topvar sigma t = match EConstr.kind sigma t with | Rel 0 -> true | _ -> false let rels_of_patsign sigma = List.map (fun decl -> match decl with | LocalDef (na,t',t) when is_topvar sigma t' -> LocalAssum (na,t) | _ -> decl) let vars_of_ctx sigma ctx = let _, y = List.fold_right (fun decl (prev, vars) -> match decl with | LocalDef (na,t',t) when is_topvar sigma t' -> prev, (CAst.make @@ GApp ( (CAst.make @@ GRef (delayed_force coq_eq_refl_ref, None)), [hole; CAst.make @@ GVar prev])) :: vars | _ -> match RelDecl.get_name decl with Anonymous -> invalid_arg "vars_of_ctx" | Name n -> n, (CAst.make @@ GVar n) :: vars) ctx (Id.of_string "vars_of_ctx_error", []) in List.rev y let rec is_included x y = match CAst.(x.v, y.v) with | PatVar _, _ -> true | _, PatVar _ -> true | PatCstr ((_, i), args, alias), PatCstr ((_, i'), args', alias') -> if Int.equal i i' then List.for_all2 is_included args args' else false let lift_rel_context n l = map_rel_context_with_binders (liftn n) l (* 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 evdref 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 *) (papp evdref coq_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 sigma, conj = mk_coq_and !evdref c' in let sigma, neg = mk_coq_not sigma conj in let conj = it_mkProd_or_LetIn neg (lift_rel_context liftsign sign) in evdref := sigma; conj :: c) [] prevpatterns in match diffs with [] -> None | _ -> Some (let sigma, conj = mk_coq_and !evdref diffs in evdref := sigma; conj) let constrs_of_pats typing_fun env evdref 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 evdref 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 !evdref sign, lift n c, (s, List.map (lift n) args), p) :: pats, len + n)) ([], 0) pats in let ineqs = build_ineqs evdref prevpatterns pats signlen in let rhs_rels' = rels_of_patsign !evdref 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 -> [LocalAssum (Anonymous, ineqs)], lift 1 arity in let eqs_rels, arity = decompose_prod_n_assum !evdref neqs arity in eqs_rels @ neqs_rels @ rhs_rels', arity in let rhs_env = push_rel_context 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 _btype = evd_comb1 (Typing.type_of env) evdref bbody in let branch_name = Id.of_string ("program_branch_" ^ (string_of_int !i)) in let branch_decl = LocalDef (Name branch_name, lift !i bbody, lift !i btype) in let branch = let bref = CAst.make @@ GVar branch_name in match vars_of_ctx !evdref rhs_rels with [] -> bref | l -> CAst.make @@ GApp (bref, l) in let branch = match ineqs with Some _ -> CAst.make @@ GApp (branch, [ hole ]) | None -> branch in incr i; let rhs = { eqn.rhs with it = Some 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 sigma tomatchs tycon = let prev, ctx, names, tycon = List.fold_left (fun (prev, ctx, names, tycon) (c, t) -> let lenctx = List.length ctx in match EConstr.kind sigma c with Rel n -> (lift lenctx c, lift_tomatch_type lenctx t) :: prev, ctx, names, tycon | _ -> let tycon = Option.map (fun t -> subst_term sigma (lift 1 c) (lift 1 t)) tycon in let name = next_ident_away (Id.of_string "filtered_var") names in (mkRel 1, lift_tomatch_type (succ lenctx) t) :: lift_ctx 1 prev, LocalDef (Name name, lift lenctx c, lift lenctx $ type_of_tomatch t) :: ctx, name :: names, tycon) ([], [], [], tycon) tomatchs in List.rev prev, ctx, tycon let build_dependent_signature env evdref avoid tomatchs arsign = let avoid = ref avoid in let arsign = List.rev arsign in let allnames = List.rev_map (List.map RelDecl.get_name) 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 app_decl = List.hd arsign in (* The matched argument *) let appn = RelDecl.get_name app_decl in let appt = RelDecl.get_type app_decl in 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 decl -> let name = RelDecl.get_name decl in let t = RelDecl.get_type decl in let argt = Retyping.get_type_of env !evdref arg in let eq, refl_arg = if Reductionops.is_conv env !evdref argt t then (mk_eq evdref (lift (nargeqs + slift) argt) (mkRel (nargeqs + slift)) (lift (nargeqs + nar) arg), mk_eq_refl evdref argt arg) else (mk_JMeq evdref (lift (nargeqs + slift) t) (mkRel (nargeqs + slift)) (lift (nargeqs + nar) argt) (lift (nargeqs + nar) arg), mk_JMeq_refl evdref argt arg) in let previd, id = let name = match EConstr.kind !evdref arg with Rel n -> RelDecl.get_name (lookup_rel n env) | _ -> name in make_prime avoid name in (env, succ nargeqs, (LocalAssum (Name (eq_id avoid previd), eq)) :: argeqs, refl_arg :: refl_args, pred slift, RelDecl.set_name (Name id) decl :: argsign')) (env, neqs, [], [], slift, []) args argsign in let eq = mk_JMeq evdref (lift (nargeqs + slift) appt) (mkRel (nargeqs + slift)) (lift (nargeqs + nar) ty) (lift (nargeqs + nar) tm) in let refl_eq = mk_JMeq_refl evdref ty tm in let previd, id = make_prime avoid appn in ((LocalAssum (Name (eq_id avoid previd), eq) :: argeqs) :: eqs, succ nargeqs, refl_eq :: refl_args, pred slift, ((RelDecl.set_name (Name id) app_decl :: argsign') :: arsigns)) | _ -> (* Non dependent inductive or not inductive, just use a regular equality *) let decl = match arsign with [x] -> x | _ -> assert(false) in let name = RelDecl.get_name decl in let previd, id = make_prime avoid name in let arsign' = RelDecl.set_name (Name id) decl in let tomatch_ty = type_of_tomatch ty in let eq = mk_eq evdref (lift nar tomatch_ty) (mkRel slift) (lift nar tm) in ([LocalAssum (Name (eq_id avoid previd), eq)] :: eqs, succ neqs, (mk_eq_refl evdref tomatch_ty tm) :: refl_args, pred slift, (arsign' :: []) :: arsigns)) ([], 0, [], nar, []) tomatchs arsign in let arsign'' = List.rev arsign' in assert(Int.equal slift 0); (* we must have folded over all elements of the arity signature *) arsign'', allnames, nar, eqs, neqs, refls 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 compile_program_cases ?loc style (typing_function, evdref) tycon env (predopt, tomatchl, eqns) = let typing_fun tycon env = function | Some t -> typing_function tycon env evdref t | None -> Evarutil.evd_comb0 use_unit_judge evdref 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_function evdref env matx tomatchl in let tycon = valcon_of_tycon tycon in let tomatchs, tomatchs_lets, tycon' = abstract_tomatch env !evdref tomatchs tycon 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_signature ~dolift:false env tomatchs 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 evdref avoid tomatchs arsign in let tycon, arity = match tycon' with | None -> let ev = mkExistential env evdref in ev, ev | Some t -> let pred = match prepare_predicate_from_arsign_tycon env !evdref loc tomatchs sign t with | Some (evd, pred) -> evdref := evd; pred | None -> let nar = List.fold_left (fun n sign -> List.length sign + n) 0 sign in lift nar t in Option.get tycon, pred 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 evdref matx tomatchs sign neqs arity in let matx = List.rev matx in let _ = assert (Int.equal len (List.length lets)) in let env = push_rel_context 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 nal, pred = build_initial_predicate sign 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 out_tmt na = function NotInd (None,t) -> LocalAssum (na,t) | NotInd (Some b, t) -> LocalDef (na,b,t) | IsInd (typ,_,_) -> LocalAssum (na,typ) in let typs = List.map2 (fun na (tm,tmt) -> (tm,out_tmt na tmt)) nal tomatchs in let typs = List.map (fun (c,d) -> (c,extract_inductive_data env !evdref d,d)) typs in let dep_sign = find_dependencies_signature !evdref (List.make (List.length typs) true) typs in let typs' = List.map3 (fun (tm,tmt) deps na -> let deps = if not (isRel !evdref tm) then [] else deps in ((tm,tmt),deps,na)) tomatchs dep_sign nal in let initial_pushed = List.map (fun x -> Pushed (true,x)) typs' in let typing_function tycon env evdref = function | Some t -> typing_function tycon env evdref t | None -> evd_comb0 use_unit_judge evdref in let pb = { env = env; evdref = evdref; pred = pred; tomatch = initial_pushed; history = start_history (List.length initial_pushed); mat = matx; caseloc = loc; casestyle= style; typing_function = typing_function } in let j = compile pb in (* We check for unused patterns *) List.iter (check_unused_pattern env) matx; let body = it_mkLambda_or_LetIn (applist (j.uj_val, args)) lets in let j = { uj_val = it_mkLambda_or_LetIn body tomatchs_lets; uj_type = EConstr.of_constr (EConstr.to_constr !evdref tycon); } in j (**************************************************************************) (* Main entry of the matching compilation *) let compile_cases ?loc style (typing_fun, evdref) tycon env (predopt, tomatchl, eqns) = if predopt == None && Flags.is_program_mode () && Program.is_program_cases () then compile_program_cases ?loc style (typing_fun, evdref) tycon env (predopt, tomatchl, eqns) else (* 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 evdref env matx tomatchl in (* If an elimination predicate is provided, we check it is compatible with the type of arguments to match; if none is provided, we build alternative possible predicates *) let arsign = extract_arity_signature env tomatchs tomatchl in let preds = prepare_predicate ?loc typing_fun env !evdref tomatchs arsign tycon predopt in let compile_for_one_predicate (sigma,nal,pred) = (* 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 out_tmt na = function NotInd (None,t) -> LocalAssum (na,t) | NotInd (Some b,t) -> LocalDef (na,b,t) | IsInd (typ,_,_) -> LocalAssum (na,typ) in let typs = List.map2 (fun na (tm,tmt) -> (tm,out_tmt na tmt)) nal tomatchs in let typs = List.map (fun (c,d) -> (c,extract_inductive_data env sigma d,d)) typs in let dep_sign = find_dependencies_signature !evdref (List.make (List.length typs) true) typs in let typs' = List.map3 (fun (tm,tmt) deps na -> let deps = if not (isRel !evdref tm) then [] else deps in ((tm,tmt),deps,na)) tomatchs dep_sign nal in let initial_pushed = List.map (fun x -> Pushed (true,x)) typs' in (* A typing function that provides with a canonical term for absurd cases*) let typing_fun tycon env evdref = function | Some t -> typing_fun tycon env evdref t | None -> evd_comb0 use_unit_judge evdref in let myevdref = ref sigma in let pb = { env = env; evdref = myevdref; 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 coerce to the tycon (if an elim predicate was provided) *) let j = inh_conv_coerce_to_tycon ?loc env myevdref j tycon in evdref := !myevdref; j in (* Return the term compiled with the first possible elimination *) (* predicate for which the compilation succeeds *) let j = list_try_compile compile_for_one_predicate preds in (* We check for unused patterns *) List.iter (check_unused_pattern env) matx; j