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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
open Pp
open Util
open Names
open Nameops
open Term
open Libnames
open Termops
open Declarations
open Inductive
open Environ
open Closure
open Reductionops
open Cbv
open Rawterm
(* Errors *)
type reduction_tactic_error =
InvalidAbstraction of env * constr * (env * Type_errors.type_error)
exception ReductionTacticError of reduction_tactic_error
(* Evaluable reference *)
exception Elimconst
exception Redelimination
let is_evaluable env = function
| EvalConstRef kn ->
is_transparent (ConstKey kn) &&
let cb = Environ.lookup_constant kn env in
cb.const_body <> None & not cb.const_opaque
| EvalVarRef id ->
is_transparent (VarKey id) &&
let (_,value,_) = Environ.lookup_named id env in
value <> None
let value_of_evaluable_ref env = function
| EvalConstRef con -> constant_value env con
| EvalVarRef id -> Option.get (pi2 (lookup_named id env))
let constr_of_evaluable_ref = function
| EvalConstRef con -> mkConst con
| EvalVarRef id -> mkVar id
type evaluable_reference =
| EvalConst of constant
| EvalVar of identifier
| EvalRel of int
| EvalEvar of existential
let mkEvalRef = function
| EvalConst cst -> mkConst cst
| EvalVar id -> mkVar id
| EvalRel n -> mkRel n
| EvalEvar ev -> mkEvar ev
let isEvalRef env c = match kind_of_term c with
| Const sp -> is_evaluable env (EvalConstRef sp)
| Var id -> is_evaluable env (EvalVarRef id)
| Rel _ | Evar _ -> true
| _ -> false
let destEvalRef c = match kind_of_term c with
| Const cst -> EvalConst cst
| Var id -> EvalVar id
| Rel n -> EvalRel n
| Evar ev -> EvalEvar ev
| _ -> anomaly "Not an unfoldable reference"
let reference_opt_value sigma env = function
| EvalConst cst -> constant_opt_value env cst
| EvalVar id ->
let (_,v,_) = lookup_named id env in
v
| EvalRel n ->
let (_,v,_) = lookup_rel n env in
Option.map (lift n) v
| EvalEvar ev -> Evd.existential_opt_value sigma ev
exception NotEvaluable
let reference_value sigma env c =
match reference_opt_value sigma env c with
| None -> raise NotEvaluable
| Some d -> d
(************************************************************************)
(* Reduction of constants hiding a fixpoint (e.g. for "simpl" tactic). *)
(* One reuses the name of the function after reduction of the fixpoint *)
type constant_evaluation =
| EliminationFix of int * int * (int * (int * constr) list * int)
| EliminationMutualFix of
int * evaluable_reference *
((int*evaluable_reference) option array *
(int * (int * constr) list * int))
| EliminationCases of int
| NotAnElimination
(* We use a cache registered as a global table *)
module CstOrdered =
struct
type t = constant
let compare = Pervasives.compare
end
module Cstmap = Map.Make(CstOrdered)
let eval_table = ref Cstmap.empty
type frozen = (int * constant_evaluation) Cstmap.t
let init () =
eval_table := Cstmap.empty
let freeze () =
!eval_table
let unfreeze ct =
eval_table := ct
let _ =
Summary.declare_summary "evaluation"
{ Summary.freeze_function = freeze;
Summary.unfreeze_function = unfreeze;
Summary.init_function = init;
Summary.survive_module = false;
Summary.survive_section = false }
(* Check that c is an "elimination constant"
either [xn:An]..[x1:A1](<P>Case (Rel i) of f1..fk end g1 ..gp)
or [xn:An]..[x1:A1](Fix(f|t) (Rel i1) ..(Rel ip))
with i1..ip distinct variables not occuring in t
In the second case, keep relevenant information ([i1,Ai1;..;ip,Aip],n)
in order to compute an equivalent of Fix(f|t)[xi<-ai] as
[yip:Bip]..[yi1:Bi1](F bn..b1)
== [yip:Bip]..[yi1:Bi1](Fix(f|t)[xi<-ai] (Rel p)..(Rel 1))
with bj=aj if j<>ik and bj=(Rel c) and Bic=Aic[xn..xic-1 <- an..aic-1]
*)
let check_fix_reversibility labs args ((lv,i),(_,tys,bds)) =
let n = List.length labs in
let nargs = List.length args in
if nargs > n then raise Elimconst;
let nbfix = Array.length bds in
let li =
List.map
(function d -> match kind_of_term d with
| Rel k ->
if
array_for_all (noccurn k) tys
&& array_for_all (noccurn (k+nbfix)) bds
then
(k, List.nth labs (k-1))
else
raise Elimconst
| _ ->
raise Elimconst) args
in
if not (list_distinct (List.map fst li)) then
raise Elimconst;
let k = lv.(i) in
if k < nargs then
(* Such an optimisation would need eta-expansion
let p = destRel (List.nth args k) in
EliminationFix (n-p+1,(nbfix,li,n))
*)
EliminationFix (n,nargs,(nbfix,li,n))
else
EliminationFix (n-nargs+k+1,nargs,(nbfix,li,n))
(* Heuristic to look if global names are associated to other
components of a mutual fixpoint *)
let invert_name labs l na0 env sigma ref = function
| Name id ->
let minfxargs = List.length l in
if na0 <> Name id then
let refi = match ref with
| EvalRel _ | EvalEvar _ -> None
| EvalVar id' -> Some (EvalVar id)
| EvalConst kn ->
let (mp,dp,_) = repr_con kn in
Some (EvalConst (make_con mp dp (label_of_id id))) in
match refi with
| None -> None
| Some ref ->
try match reference_opt_value sigma env ref with
| None -> None
| Some c ->
let labs',ccl = decompose_lam c in
let _, l' = whd_betalet_stack sigma ccl in
let labs' = List.map snd labs' in
if labs' = labs & l = l' then Some (minfxargs,ref)
else None
with Not_found (* Undefined ref *) -> None
else Some (minfxargs,ref)
| Anonymous -> None (* Actually, should not occur *)
(* [compute_consteval_direct] expand all constant in a whole, but
[compute_consteval_mutual_fix] only one by one, until finding the
last one before the Fix if the latter is mutually defined *)
let compute_consteval_direct sigma env ref =
let rec srec env n labs c =
let c',l = whd_betadelta_stack env sigma c in
match kind_of_term c' with
| Lambda (id,t,g) when l=[] ->
srec (push_rel (id,None,t) env) (n+1) (t::labs) g
| Fix fix ->
(try check_fix_reversibility labs l fix
with Elimconst -> NotAnElimination)
| Case (_,_,d,_) when isRel d -> EliminationCases n
| _ -> NotAnElimination
in
match reference_opt_value sigma env ref with
| None -> NotAnElimination
| Some c -> srec env 0 [] c
let compute_consteval_mutual_fix sigma env ref =
let rec srec env minarg labs ref c =
let c',l = whd_betalet_stack sigma c in
let nargs = List.length l in
match kind_of_term c' with
| Lambda (na,t,g) when l=[] ->
srec (push_rel (na,None,t) env) (minarg+1) (t::labs) ref g
| Fix ((lv,i),(names,_,_)) ->
(* Last known constant wrapping Fix is ref = [labs](Fix l) *)
(match compute_consteval_direct sigma env ref with
| NotAnElimination -> (*Above const was eliminable but this not!*)
NotAnElimination
| EliminationFix (minarg',minfxargs,infos) ->
let refs =
Array.map
(invert_name labs l names.(i) env sigma ref) names in
let new_minarg = max (minarg'+minarg-nargs) minarg' in
EliminationMutualFix (new_minarg,ref,(refs,infos))
| _ -> assert false)
| _ when isEvalRef env c' ->
(* Forget all \'s and args and do as if we had started with c' *)
let ref = destEvalRef c' in
(match reference_opt_value sigma env ref with
| None -> anomaly "Should have been trapped by compute_direct"
| Some c -> srec env (minarg-nargs) [] ref c)
| _ -> (* Should not occur *) NotAnElimination
in
match reference_opt_value sigma env ref with
| None -> (* Should not occur *) NotAnElimination
| Some c -> srec env 0 [] ref c
let compute_consteval sigma env ref =
match compute_consteval_direct sigma env ref with
| EliminationFix (_,_,(nbfix,_,_)) when nbfix <> 1 ->
compute_consteval_mutual_fix sigma env ref
| elim -> elim
let reference_eval sigma env = function
| EvalConst cst as ref ->
(try
Cstmap.find cst !eval_table
with Not_found -> begin
let v = compute_consteval sigma env ref in
eval_table := Cstmap.add cst v !eval_table;
v
end)
| ref -> compute_consteval sigma env ref
let rev_firstn_liftn fn ln =
let rec rfprec p res l =
if p = 0 then
res
else
match l with
| [] -> invalid_arg "Reduction.rev_firstn_liftn"
| a::rest -> rfprec (p-1) ((lift ln a)::res) rest
in
rfprec fn []
(* If f is bound to EliminationFix (n',infos), then n' is the minimal
number of args for starting the reduction and infos is
(nbfix,[(yi1,Ti1);...;(yip,Tip)],n) indicating that f converts
to some [y1:T1,...,yn:Tn](Fix(..) yip .. yi1) where we can remark that
yij = Rel(n+1-j)
f is applied to largs and we need for recursive calls to build the function
g := [xp:Tip',...,x1:Ti1'](f a1 ... an)
s.t. (g u1 ... up) reduces to (Fix(..) u1 ... up)
This is made possible by setting
a_k:=z_j if k=i_j
a_k:=y_k otherwise
The type Tij' is Tij[yn..yi(j-1)..y1 <- ai(j-1)..a1]
*)
let x = Name (id_of_string "x")
let make_elim_fun (names,(nbfix,lv,n)) largs =
let lu = list_firstn n (list_of_stack largs) in
let p = List.length lv in
let lyi = List.map fst lv in
let la =
list_map_i (fun q aq ->
(* k from the comment is q+1 *)
try mkRel (p+1-(list_index (n-q) lyi))
with Not_found -> aq)
0 (List.map (lift p) lu)
in
fun i ->
match names.(i) with
| None -> None
| Some (minargs,ref) ->
let body = applistc (mkEvalRef ref) la in
let g =
list_fold_left_i (fun q (* j from comment is n+1-q *) c (ij,tij) ->
let subst = List.map (lift (-q)) (list_firstn (n-ij) la) in
let tij' = substl (List.rev subst) tij in
mkLambda (x,tij',c)) 1 body (List.rev lv)
in Some (minargs,g)
(* [f] is convertible to [Fix(recindices,bodynum),bodyvect)]:
do so that the reduction uses this extra information *)
let dummy = mkProp
let vfx = id_of_string"_expanded_fix_"
let vfun = id_of_string"_elimminator_function_"
(* Mark every occurrence of substituted vars (associated to a function)
as a problem variable: an evar that can be instantiated either by
vfx (expanded fixpoint) or vfun (named function). *)
let substl_with_function subst constr =
let cnt = ref 0 in
let evd = ref Evd.empty in
let minargs = ref Intmap.empty in
let v = Array.of_list subst in
let rec subst_total k c =
match kind_of_term c with
Rel i when k<i ->
if i <= k + Array.length v then
match v.(i-k-1) with
| (fx,Some(min,ref)) ->
decr cnt;
evd := Evd.add !evd !cnt
(Evd.make_evar
(val_of_named_context
[(vfx,None,dummy);(vfun,None,dummy)])
dummy);
minargs := Intmap.add !cnt min !minargs;
lift k (mkEvar(!cnt,[|fx;ref|]))
| (fx,None) -> lift k fx
else mkRel (i - Array.length v)
| _ ->
map_constr_with_binders succ subst_total k c in
let c = subst_total 0 constr in
(c,!evd,!minargs)
exception Partial
(* each problem variable that cannot be made totally applied even by
reduction is solved by the expanded fix term. *)
let solve_arity_problem env sigma fxminargs c =
let evm = ref sigma in
let set_fix i = evm := Evd.define i (mkVar vfx) !evm in
let rec check strict c =
let c' = whd_betaiotazeta sigma c in
let (h,rcargs) = decompose_app c' in
match kind_of_term h with
Evar(i,_) when Intmap.mem i fxminargs && not (Evd.is_defined !evm i) ->
let minargs = Intmap.find i fxminargs in
if List.length rcargs < minargs then
if strict then set_fix i
else raise Partial;
List.iter (check strict) rcargs
| (Var _|Const _) when isEvalRef env h ->
(match reference_opt_value sigma env (destEvalRef h) with
Some h' ->
let bak = !evm in
(try List.iter (check false) rcargs
with Partial ->
evm := bak;
check strict (applist(h',rcargs)))
| None -> List.iter (check strict) rcargs)
| _ -> iter_constr (check strict) c' in
check true c;
!evm
let substl_checking_arity env subst c =
(* we initialize the problem: *)
let body,sigma,minargs = substl_with_function subst c in
(* we collect arity constraints *)
let sigma' = solve_arity_problem env sigma minargs body in
(* we propagate the constraints: solved problems are substituted;
the other ones are replaced by the function symbol *)
let rec nf_fix c =
match kind_of_term c with
Evar(i,[|fx;f|] as ev) when Intmap.mem i minargs ->
(match Evd.existential_opt_value sigma' ev with
Some c' -> c'
| None -> f)
| _ -> map_constr nf_fix c in
nf_fix body
let contract_fix_use_function env sigma f
((recindices,bodynum),(_names,_types,bodies as typedbodies)) =
let nbodies = Array.length recindices in
let make_Fi j = (mkFix((recindices,j),typedbodies), f j) in
let lbodies = list_tabulate make_Fi nbodies in
substl_checking_arity env (List.rev lbodies) (nf_beta sigma bodies.(bodynum))
let reduce_fix_use_function env sigma f whfun fix stack =
match fix_recarg fix stack with
| None -> NotReducible
| Some (recargnum,recarg) ->
let (recarg'hd,_ as recarg') =
if isRel recarg then
(* The recarg cannot be a local def, no worry about the right env *)
(recarg, empty_stack)
else
whfun (recarg, empty_stack) in
let stack' = stack_assign stack recargnum (app_stack recarg') in
(match kind_of_term recarg'hd with
| Construct _ ->
Reduced (contract_fix_use_function env sigma f fix,stack')
| _ -> NotReducible)
let contract_cofix_use_function env sigma f
(bodynum,(_names,_,bodies as typedbodies)) =
let nbodies = Array.length bodies in
let make_Fi j = (mkCoFix(j,typedbodies), f j) in
let subbodies = list_tabulate make_Fi nbodies in
substl_checking_arity env (List.rev subbodies)
(nf_beta sigma bodies.(bodynum))
let reduce_mind_case_use_function func env sigma mia =
match kind_of_term mia.mconstr with
| Construct(ind_sp,i) ->
let real_cargs = list_skipn mia.mci.ci_npar mia.mcargs in
applist (mia.mlf.(i-1), real_cargs)
| CoFix (bodynum,(names,_,_) as cofix) ->
let build_cofix_name =
if isConst func then
let (mp,dp,_) = repr_con (destConst func) in
let minargs = List.length mia.mcargs in
fun i ->
if i = bodynum then Some (minargs,func)
else match names.(i) with
| Anonymous -> None
| Name id ->
(* In case of a call to another component of a block of
mutual inductive, try to reuse the global name if
the block was indeed initially built as a global
definition *)
let kn = make_con mp dp (label_of_id id) in
try match constant_opt_value env kn with
| None -> None
(* TODO: check kn is correct *)
| Some _ -> Some (minargs,mkConst kn)
with Not_found -> None
else
fun _ -> None in
let cofix_def =
contract_cofix_use_function env sigma build_cofix_name cofix in
mkCase (mia.mci, mia.mP, applist(cofix_def,mia.mcargs), mia.mlf)
| _ -> assert false
let special_red_case env sigma whfun (ci, p, c, lf) =
let rec redrec s =
let (constr, cargs) = whfun s in
if isEvalRef env constr then
let ref = destEvalRef constr in
match reference_opt_value sigma env ref with
| None -> raise Redelimination
| Some gvalue ->
if reducible_mind_case gvalue then
reduce_mind_case_use_function constr env sigma
{mP=p; mconstr=gvalue; mcargs=list_of_stack cargs;
mci=ci; mlf=lf}
else
redrec (gvalue, cargs)
else
if reducible_mind_case constr then
reduce_mind_case
{mP=p; mconstr=constr; mcargs=list_of_stack cargs;
mci=ci; mlf=lf}
else
raise Redelimination
in
redrec (c, empty_stack)
(* [red_elim_const] contracts iota/fix/cofix redexes hidden behind
constants by keeping the name of the constants in the recursive calls;
it fails if no redex is around *)
let rec red_elim_const env sigma ref largs =
match reference_eval sigma env ref with
| EliminationCases n when stack_args_size largs >= n ->
let c = reference_value sigma env ref in
let c', lrest = whd_betadelta_state env sigma (c,largs) in
let whfun = whd_simpl_state env sigma in
(special_red_case env sigma whfun (destCase c'), lrest)
| EliminationFix (min,minfxargs,infos) when stack_args_size largs >=min ->
let c = reference_value sigma env ref in
let d, lrest = whd_betadelta_state env sigma (c,largs) in
let f = make_elim_fun ([|Some (minfxargs,ref)|],infos) largs in
let whfun = whd_construct_state env sigma in
(match reduce_fix_use_function env sigma f whfun (destFix d) lrest with
| NotReducible -> raise Redelimination
| Reduced (c,rest) -> (nf_beta sigma c, rest))
| EliminationMutualFix (min,refgoal,refinfos)
when stack_args_size largs >= min ->
let rec descend ref args =
let c = reference_value sigma env ref in
if ref = refgoal then
(c,args)
else
let c', lrest = whd_betalet_state sigma (c,args) in
descend (destEvalRef c') lrest in
let (_, midargs as s) = descend ref largs in
let d, lrest = whd_betadelta_state env sigma s in
let f = make_elim_fun refinfos midargs in
let whfun = whd_construct_state env sigma in
(match reduce_fix_use_function env sigma f whfun (destFix d) lrest with
| NotReducible -> raise Redelimination
| Reduced (c,rest) -> (nf_beta sigma c, rest))
| _ -> raise Redelimination
(* reduce to whd normal form or to an applied constant that does not hide
a reducible iota/fix/cofix redex (the "simpl" tactic) *)
and whd_simpl_state env sigma s =
let rec redrec (x, stack as s) =
match kind_of_term x with
| Lambda (na,t,c) ->
(match decomp_stack stack with
| None -> s
| Some (a,rest) -> stacklam redrec [a] c rest)
| LetIn (n,b,t,c) -> stacklam redrec [b] c stack
| App (f,cl) -> redrec (f, append_stack cl stack)
| Cast (c,_,_) -> redrec (c, stack)
| Case (ci,p,c,lf) ->
(try
redrec (special_red_case env sigma redrec (ci,p,c,lf), stack)
with
Redelimination -> s)
| Fix fix ->
(try match reduce_fix (whd_construct_state env) sigma fix stack with
| Reduced s' -> redrec s'
| NotReducible -> s
with Redelimination -> s)
| _ when isEvalRef env x ->
let ref = destEvalRef x in
(try
redrec (red_elim_const env sigma ref stack)
with Redelimination ->
s)
| _ -> s
in
redrec s
(* reduce until finding an applied constructor or fail *)
and whd_construct_state env sigma s =
let (constr, cargs as s') = whd_simpl_state env sigma s in
if reducible_mind_case constr then s'
else if isEvalRef env constr then
let ref = destEvalRef constr in
match reference_opt_value sigma env ref with
| None -> raise Redelimination
| Some gvalue -> whd_construct_state env sigma (gvalue, cargs)
else
raise Redelimination
(************************************************************************)
(* Special Purpose Reduction Strategies *)
(* Red reduction tactic: one step of delta reduction + full
beta-iota-fix-cofix-zeta-cast at the head of the conclusion of a
sequence of products; fails if no delta redex is around
*)
let try_red_product env sigma c =
let simpfun = clos_norm_flags betaiotazeta env sigma in
let rec redrec env x =
match kind_of_term x with
| App (f,l) ->
(match kind_of_term f with
| Fix fix ->
let stack = append_stack l empty_stack in
(match fix_recarg fix stack with
| None -> raise Redelimination
| Some (recargnum,recarg) ->
let recarg' = redrec env recarg in
let stack' = stack_assign stack recargnum recarg' in
simpfun (app_stack (f,stack')))
| _ -> simpfun (appvect (redrec env f, l)))
| Cast (c,_,_) -> redrec env c
| Prod (x,a,b) -> mkProd (x, a, redrec (push_rel (x,None,a) env) b)
| LetIn (x,a,b,t) -> redrec env (subst1 a t)
| Case (ci,p,d,lf) -> simpfun (mkCase (ci,p,redrec env d,lf))
| _ when isEvalRef env x ->
(* TO DO: re-fold fixpoints after expansion *)
(* to get true one-step reductions *)
let ref = destEvalRef x in
(match reference_opt_value sigma env ref with
| None -> raise Redelimination
| Some c -> c)
| _ -> raise Redelimination
in redrec env c
let red_product env sigma c =
try try_red_product env sigma c
with Redelimination -> error "Not reducible."
(*
(* This old version of hnf uses betadeltaiota instead of itself (resp
whd_construct_state) to reduce the argument of Case (resp Fix);
The new version uses the "simpl" strategy instead. For instance,
Variable n:nat.
Eval hnf in match (plus (S n) O) with S n => n | _ => O end.
returned
(fix plus (n m : nat) {struct n} : nat :=
match n with
| O => m
| S p => S (plus p m)
end) n 0
while the new version returns (plus n O)
*)
let whd_simpl_orelse_delta_but_fix_old env sigma c =
let whd_all = whd_betadeltaiota_state env sigma in
let rec redrec (x, stack as s) =
match kind_of_term x with
| Lambda (na,t,c) ->
(match decomp_stack stack with
| None -> s
| Some (a,rest) -> stacklam redrec [a] c rest)
| LetIn (n,b,t,c) -> stacklam redrec [b] c stack
| App (f,cl) -> redrec (f, append_stack cl stack)
| Cast (c,_,_) -> redrec (c, stack)
| Case (ci,p,d,lf) ->
(try
redrec (special_red_case env sigma whd_all (ci,p,d,lf), stack)
with Redelimination ->
s)
| Fix fix ->
(match reduce_fix whd_all fix stack with
| Reduced s' -> redrec s'
| NotReducible -> s)
| _ when isEvalRef env x ->
let ref = destEvalRef x in
(try
redrec (red_elim_const env sigma ref stack)
with Redelimination ->
match reference_opt_value sigma env ref with
| Some c ->
(match kind_of_term ((strip_lam c)) with
| CoFix _ | Fix _ -> s
| _ -> redrec (c, stack))
| None -> s)
| _ -> s
in app_stack (redrec (c, empty_stack))
*)
(* Same as [whd_simpl] but also reduces constants that do not hide a
reducible fix, but does this reduction of constants only until it
it immediately hides a non reducible fix or a cofix *)
let whd_simpl_orelse_delta_but_fix env sigma c =
let rec redrec s =
let (constr, stack as s') = whd_simpl_state env sigma s in
if isEvalRef env constr then
match reference_opt_value sigma env (destEvalRef constr) with
| Some c ->
(match kind_of_term ((strip_lam c)) with
| CoFix _ | Fix _ -> s'
| _ -> redrec (c, stack))
| None -> s'
else s'
in app_stack (redrec (c, empty_stack))
let hnf_constr = whd_simpl_orelse_delta_but_fix
(* The "simpl" reduction tactic *)
let whd_simpl env sigma c =
app_stack (whd_simpl_state env sigma (c, empty_stack))
let simpl env sigma c = strong whd_simpl env sigma c
let nf = simpl (* Compatibility *)
(* Reduction at specific subterms *)
let is_head c t =
match kind_of_term t with
| App (f,_) -> f = c
| _ -> false
let contextually byhead ((nowhere_except_in,locs),c) f env sigma t =
let maxocc = List.fold_right max locs 0 in
let pos = ref 1 in
let rec traverse (env,c as envc) t =
if nowhere_except_in & (!pos > maxocc) then t
else
if (not byhead & eq_constr c t) or (byhead & is_head c t) then
let ok =
if nowhere_except_in then List.mem !pos locs
else not (List.mem !pos locs) in
incr pos;
if ok then
f env sigma t
else if byhead then
(* find other occurrences of c in t; TODO: ensure left-to-right *)
let (f,l) = destApp t in
mkApp (f, array_map_left (traverse envc) l)
else
t
else
map_constr_with_binders_left_to_right
(fun d (env,c) -> (push_rel d env,lift 1 c))
traverse envc t
in
let t' = traverse (env,c) t in
if List.exists (fun o -> o >= !pos) locs then error_invalid_occurrence locs;
t'
(* linear bindings (following pretty-printer) of the value of name in c.
* n is the number of the next occurence of name.
* ol is the occurence list to find. *)
let substlin env evalref n (nowhere_except_in,locs) c =
let maxocc = List.fold_right max locs 0 in
let pos = ref n in
assert (List.for_all (fun x -> x >= 0) locs);
let value = value_of_evaluable_ref env evalref in
let term = constr_of_evaluable_ref evalref in
let rec substrec () c =
if nowhere_except_in & !pos > maxocc then c
else if c = term then
let ok =
if nowhere_except_in then List.mem !pos locs
else not (List.mem !pos locs) in
incr pos;
if ok then value else c
else
map_constr_with_binders_left_to_right
(fun _ () -> ())
substrec () c
in
let t' = substrec () c in
(!pos, t')
let string_of_evaluable_ref env = function
| EvalVarRef id -> string_of_id id
| EvalConstRef kn ->
string_of_qualid
(Nametab.shortest_qualid_of_global (vars_of_env env) (ConstRef kn))
let unfold env sigma name =
if is_evaluable env name then
clos_norm_flags (unfold_red name) env sigma
else
error (string_of_evaluable_ref env name^" is opaque.")
(* [unfoldoccs : (readable_constraints -> (int list * section_path) -> constr -> constr)]
* Unfolds the constant name in a term c following a list of occurrences occl.
* at the occurrences of occ_list. If occ_list is empty, unfold all occurences.
* Performs a betaiota reduction after unfolding. *)
let unfoldoccs env sigma ((nowhere_except_in,locs as plocs),name) c =
if locs = [] then if nowhere_except_in then c else unfold env sigma name c
else
let (nbocc,uc) = substlin env name 1 plocs c in
if nbocc = 1 then
error ((string_of_evaluable_ref env name)^" does not occur.");
let rest = List.filter (fun o -> o >= nbocc) locs in
if rest <> [] then error_invalid_occurrence rest;
nf_betaiota sigma uc
(* Unfold reduction tactic: *)
let unfoldn loccname env sigma c =
List.fold_left (fun c occname -> unfoldoccs env sigma occname c) c loccname
(* Re-folding constants tactics: refold com in term c *)
let fold_one_com com env sigma c =
let rcom =
try red_product env sigma com
with Redelimination -> error "Not reducible." in
(* Reason first on the beta-iota-zeta normal form of the constant as
unfold produces it, so that the "unfold f; fold f" configuration works
to refold fix expressions *)
let a = subst_term (clos_norm_flags unfold_side_red env sigma rcom) c in
if not (eq_constr a c) then
subst1 com a
else
(* Then reason on the non beta-iota-zeta form for compatibility -
even if it is probably a useless configuration *)
let a = subst_term rcom c in
subst1 com a
let fold_commands cl env sigma c =
List.fold_right (fun com -> fold_one_com com env sigma) (List.rev cl) c
(* call by value reduction functions *)
let cbv_norm_flags flags env sigma t =
cbv_norm (create_cbv_infos flags env sigma) t
let cbv_beta = cbv_norm_flags beta empty_env
let cbv_betaiota = cbv_norm_flags betaiota empty_env
let cbv_betadeltaiota env sigma = cbv_norm_flags betadeltaiota env sigma
let compute = cbv_betadeltaiota
(* Pattern *)
(* gives [na:ta]c' such that c converts to ([na:ta]c' a), abstracting only
* the specified occurrences. *)
let abstract_scheme env sigma (locc,a) c =
let ta = Retyping.get_type_of env sigma a in
let na = named_hd env ta Anonymous in
if occur_meta ta then error "Cannot find a type for the generalisation.";
if occur_meta a then
mkLambda (na,ta,c)
else
mkLambda (na,ta,subst_term_occ locc a c)
let pattern_occs loccs_trm env sigma c =
let abstr_trm = List.fold_right (abstract_scheme env sigma) loccs_trm c in
try
let _ = Typing.type_of env sigma abstr_trm in
applist(abstr_trm, List.map snd loccs_trm)
with Type_errors.TypeError (env',t) ->
raise (ReductionTacticError (InvalidAbstraction (env,abstr_trm,(env',t))))
(* Used in several tactics. *)
(* put t as t'=(x1:A1)..(xn:An)B with B an inductive definition of name name
return name, B and t' *)
let reduce_to_ind_gen allow_product env sigma t =
let rec elimrec env t l =
let t = hnf_constr env sigma t in
match kind_of_term (fst (decompose_app t)) with
| Ind ind-> (ind, it_mkProd_or_LetIn t l)
| Prod (n,ty,t') ->
if allow_product then
elimrec (push_rel (n,None,ty) env) t' ((n,None,ty)::l)
else
errorlabstrm "" (str"Not an inductive definition.")
| _ ->
(* Last chance: we allow to bypass the Opaque flag (as it
was partially the case between V5.10 and V8.1 *)
let t' = whd_betadeltaiota env sigma t in
match kind_of_term (fst (decompose_app t')) with
| Ind ind-> (ind, it_mkProd_or_LetIn t' l)
| _ -> errorlabstrm "" (str"Not an inductive product.")
in
elimrec env t []
let reduce_to_quantified_ind x = reduce_to_ind_gen true x
let reduce_to_atomic_ind x = reduce_to_ind_gen false x
(* Reduce the weak-head redex [beta,iota/fix/cofix[all],cast,zeta,simpl/delta]
or raise [NotStepReducible] if not a weak-head redex *)
exception NotStepReducible
let one_step_reduce env sigma c =
let rec redrec (x, stack) =
match kind_of_term x with
| Lambda (n,t,c) ->
(match decomp_stack stack with
| None -> raise NotStepReducible
| Some (a,rest) -> (subst1 a c, rest))
| App (f,cl) -> redrec (f, append_stack cl stack)
| LetIn (_,f,_,cl) -> (subst1 f cl,stack)
| Cast (c,_,_) -> redrec (c,stack)
| Case (ci,p,c,lf) ->
(try
(special_red_case env sigma (whd_simpl_state env sigma)
(ci,p,c,lf), stack)
with Redelimination -> raise NotStepReducible)
| Fix fix ->
(match reduce_fix (whd_construct_state env) sigma fix stack with
| Reduced s' -> s'
| NotReducible -> raise NotStepReducible)
| _ when isEvalRef env x ->
let ref = destEvalRef x in
(try
red_elim_const env sigma ref stack
with Redelimination ->
match reference_opt_value sigma env ref with
| Some d -> d, stack
| None -> raise NotStepReducible)
| _ -> raise NotStepReducible
in
app_stack (redrec (c, empty_stack))
let isIndRef = function IndRef _ -> true | _ -> false
let reduce_to_ref_gen allow_product env sigma ref t =
if isIndRef ref then
let (mind,t) = reduce_to_ind_gen allow_product env sigma t in
if IndRef mind <> ref then
errorlabstrm "" (str "Cannot recognize a statement based on " ++
Nametab.pr_global_env Idset.empty ref ++ str".")
else
t
else
(* lazily reduces to match the head of [t] with the expected [ref] *)
let rec elimrec env t l =
let c, _ = Reductionops.whd_stack sigma t in
match kind_of_term c with
| Prod (n,ty,t') ->
if allow_product then
elimrec (push_rel (n,None,t) env) t' ((n,None,ty)::l)
else
errorlabstrm ""
(str "Cannot recognize an atomic statement based on " ++
Nametab.pr_global_env Idset.empty ref ++ str".")
| _ ->
try
if global_of_constr c = ref
then it_mkProd_or_LetIn t l
else raise Not_found
with Not_found ->
try
let t' = nf_betaiota sigma (one_step_reduce env sigma t) in
elimrec env t' l
with NotStepReducible ->
errorlabstrm ""
(str "Cannot recognize a statement based on " ++
Nametab.pr_global_env Idset.empty ref ++ str".")
in
elimrec env t []
let reduce_to_quantified_ref = reduce_to_ref_gen true
let reduce_to_atomic_ref = reduce_to_ref_gen false
|