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|
(************************************************************************)
(* * The Coq Proof Assistant / The Coq Development Team *)
(* v * INRIA, CNRS and contributors - Copyright 1999-2018 *)
(* <O___,, * (see CREDITS file for the list of authors) *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(* * (see LICENSE file for the text of the license) *)
(************************************************************************)
(* This file is (C) Copyright 2006-2015 Microsoft Corporation and Inria. *)
open Util
open Names
open Evd
open Term
open Constr
open Termops
open Printer
open Locusops
open Ltac_plugin
open Tacmach
open Refiner
open Libnames
open Ssrmatching_plugin
open Ssrmatching
open Ssrast
open Ssrprinters
module RelDecl = Context.Rel.Declaration
module NamedDecl = Context.Named.Declaration
(* Defining grammar rules with "xx" in it automatically declares keywords too,
* we thus save the lexer to restore it at the end of the file *)
let frozen_lexer = CLexer.get_keyword_state () ;;
let errorstrm x = CErrors.user_err ~hdr:"ssreflect" x
let allocc = Some(false,[])
(** Bound assumption argument *)
(* The Ltac API does have a type for assumptions but it is level-dependent *)
(* and therefore impractical to use for complex arguments, so we substitute *)
(* our own to have a uniform representation. Also, we refuse to intern *)
(* idents that match global/section constants, since this would lead to *)
(* fragile Ltac scripts. *)
let hyp_id (SsrHyp (_, id)) = id
let hyp_err ?loc msg id =
CErrors.user_err ?loc ~hdr:"ssrhyp" Pp.(str msg ++ Id.print id)
let not_section_id id = not (Termops.is_section_variable id)
let hyps_ids = List.map hyp_id
let rec check_hyps_uniq ids = function
| SsrHyp (loc, id) :: _ when List.mem id ids ->
hyp_err ?loc "Duplicate assumption " id
| SsrHyp (_, id) :: hyps -> check_hyps_uniq (id :: ids) hyps
| [] -> ()
let check_hyp_exists hyps (SsrHyp(_, id)) =
try ignore(Context.Named.lookup id hyps)
with Not_found -> errorstrm Pp.(str"No assumption is named " ++ Id.print id)
let test_hypname_exists hyps id =
try ignore(Context.Named.lookup id hyps); true
with Not_found -> false
let hoik f = function Hyp x -> f x | Id x -> f x
let hoi_id = hoik hyp_id
let mk_hint tac = false, [Some tac]
let mk_orhint tacs = true, tacs
let nullhint = true, []
let nohint = false, []
type 'a tac_a = (goal * 'a) sigma -> (goal * 'a) list sigma
let push_ctx a gl = re_sig (sig_it gl, a) (project gl)
let push_ctxs a gl =
re_sig (List.map (fun x -> x,a) (sig_it gl)) (project gl)
let pull_ctx gl = let g, a = sig_it gl in re_sig g (project gl), a
let pull_ctxs gl = let g, a = List.split (sig_it gl) in re_sig g (project gl), a
let with_ctx f gl =
let gl, ctx = pull_ctx gl in
let rc, ctx = f ctx in
rc, push_ctx ctx gl
let without_ctx f gl =
let gl, _ctx = pull_ctx gl in
f gl
let tac_ctx t gl =
let gl, a = pull_ctx gl in
let gl = t gl in
push_ctxs a gl
let tclTHEN_ia t1 t2 gl =
let gal = t1 gl in
let goals, sigma = sig_it gal, project gal in
let _, opened, sigma =
List.fold_left (fun (i,opened,sigma) g ->
let gl = t2 i (re_sig g sigma) in
i+1, sig_it gl :: opened, project gl)
(1,[],sigma) goals in
re_sig (List.flatten (List.rev opened)) sigma
let tclTHEN_a t1 t2 gl = tclTHEN_ia t1 (fun _ -> t2) gl
let tclTHENS_a t1 tl gl = tclTHEN_ia t1
(fun i -> List.nth tl (i-1)) gl
let rec tclTHENLIST_a = function
| [] -> tac_ctx tclIDTAC
| t1::tacl -> tclTHEN_a t1 (tclTHENLIST_a tacl)
(* like tclTHEN_i but passes to the tac "i of n" and not just i *)
let tclTHEN_i_max tac taci gl =
let maxi = ref 0 in
tclTHEN_ia (tclTHEN_ia tac (fun i -> maxi := max i !maxi; tac_ctx tclIDTAC))
(fun i gl -> taci i !maxi gl) gl
let tac_on_all gl tac =
let goals = sig_it gl in
let opened, sigma =
List.fold_left (fun (opened,sigma) g ->
let gl = tac (re_sig g sigma) in
sig_it gl :: opened, project gl)
([],project gl) goals in
re_sig (List.flatten (List.rev opened)) sigma
(* Used to thread data between intro patterns at run time *)
type tac_ctx = {
tmp_ids : (Id.t * Name.t ref) list;
wild_ids : Id.t list;
delayed_clears : Id.t list;
}
let new_ctx () =
{ tmp_ids = []; wild_ids = []; delayed_clears = [] }
let with_fresh_ctx t gl =
let gl = push_ctx (new_ctx()) gl in
let gl = t gl in
fst (pull_ctxs gl)
open Genarg
open Stdarg
open Pp
let errorstrm x = CErrors.user_err ~hdr:"ssreflect" x
let anomaly s = CErrors.anomaly (str s)
(* Tentative patch from util.ml *)
let array_fold_right_from n f v a =
let rec fold n =
if n >= Array.length v then a else f v.(n) (fold (succ n))
in
fold n
let array_app_tl v l =
if Array.length v = 0 then invalid_arg "array_app_tl";
array_fold_right_from 1 (fun e l -> e::l) v l
let array_list_of_tl v =
if Array.length v = 0 then invalid_arg "array_list_of_tl";
array_fold_right_from 1 (fun e l -> e::l) v []
(* end patch *)
let option_assert_get o msg =
match o with
| None -> CErrors.anomaly msg
| Some x -> x
(** Constructors for rawconstr *)
open Glob_term
open Globnames
open Misctypes
open Decl_kinds
let mkRHole = DAst.make @@ GHole (Evar_kinds.InternalHole, IntroAnonymous, None)
let rec mkRHoles n = if n > 0 then mkRHole :: mkRHoles (n - 1) else []
let rec isRHoles cl = match cl with
| [] -> true
| c :: l -> match DAst.get c with GHole _ -> isRHoles l | _ -> false
let mkRApp f args = if args = [] then f else DAst.make @@ GApp (f, args)
let mkRVar id = DAst.make @@ GRef (VarRef id,None)
let mkRltacVar id = DAst.make @@ GVar (id)
let mkRCast rc rt = DAst.make @@ GCast (rc, CastConv rt)
let mkRType = DAst.make @@ GSort (GType [])
let mkRProp = DAst.make @@ GSort (GProp)
let mkRArrow rt1 rt2 = DAst.make @@ GProd (Anonymous, Explicit, rt1, rt2)
let mkRConstruct c = DAst.make @@ GRef (ConstructRef c,None)
let mkRInd mind = DAst.make @@ GRef (IndRef mind,None)
let mkRLambda n s t = DAst.make @@ GLambda (n, Explicit, s, t)
let rec mkRnat n =
if n <= 0 then DAst.make @@ GRef (Coqlib.glob_O, None) else
mkRApp (DAst.make @@ GRef (Coqlib.glob_S, None)) [mkRnat (n - 1)]
let glob_constr ist genv = function
| _, Some ce ->
let vars = Id.Map.fold (fun x _ accu -> Id.Set.add x accu) ist.Tacinterp.lfun Id.Set.empty in
let ltacvars = {
Constrintern.empty_ltac_sign with Constrintern.ltac_vars = vars } in
Constrintern.intern_gen Pretyping.WithoutTypeConstraint ~ltacvars genv Evd.(from_env genv) ce
| rc, None -> rc
let pf_intern_term ist gl (_, c) = glob_constr ist (pf_env gl) c
let intern_term ist env (_, c) = glob_constr ist env c
(* Estimate a bound on the number of arguments of a raw constr. *)
(* This is not perfect, because the unifier may fail to *)
(* typecheck the partial application, so we use a minimum of 5. *)
(* Also, we don't handle delayed or iterated coercions to *)
(* FUNCLASS, which is probably just as well since these can *)
(* lead to infinite arities. *)
let splay_open_constr gl (sigma, c) =
let env = pf_env gl in let t = Retyping.get_type_of env sigma c in
Reductionops.splay_prod env sigma t
let isAppInd env sigma c =
let c = Reductionops.clos_whd_flags CClosure.all env sigma c in
let c, _ = decompose_app_vect sigma c in
EConstr.isInd sigma c
(** Generic argument-based globbing/typing utilities *)
let interp_refine ist gl rc =
let constrvars = Tacinterp.extract_ltac_constr_values ist (pf_env gl) in
let vars = { Glob_ops.empty_lvar with
Ltac_pretype.ltac_constrs = constrvars; ltac_genargs = ist.Tacinterp.lfun
} in
let kind = Pretyping.OfType (pf_concl gl) in
let flags = {
Pretyping.use_typeclasses = true;
solve_unification_constraints = true;
use_hook = None;
fail_evar = false;
expand_evars = true }
in
let sigma, c = Pretyping.understand_ltac flags (pf_env gl) (project gl) vars kind rc in
(* ppdebug(lazy(str"sigma@interp_refine=" ++ pr_evar_map None sigma)); *)
ppdebug(lazy(str"c@interp_refine=" ++ Printer.pr_econstr_env (pf_env gl) sigma c));
(sigma, (sigma, c))
let interp_open_constr ist gl gc =
let (sigma, (c, _)) = Tacinterp.interp_open_constr_with_bindings ist (pf_env gl) (project gl) (gc, Misctypes.NoBindings) in
(project gl, (sigma, c))
let interp_term ist gl (_, c) = snd (interp_open_constr ist gl c)
let of_ftactic ftac gl =
let r = ref None in
let tac = Ftactic.run ftac (fun ans -> r := Some ans; Proofview.tclUNIT ()) in
let tac = Proofview.V82.of_tactic tac in
let { sigma = sigma } = tac gl in
let ans = match !r with
| None -> assert false (** If the tactic failed we should not reach this point *)
| Some ans -> ans
in
(sigma, ans)
let interp_wit wit ist gl x =
let globarg = in_gen (glbwit wit) x in
let arg = Tacinterp.interp_genarg ist globarg in
let (sigma, arg) = of_ftactic arg gl in
sigma, Tacinterp.Value.cast (topwit wit) arg
let interp_hyp ist gl (SsrHyp (loc, id)) =
let s, id' = interp_wit wit_var ist gl CAst.(make ?loc id) in
if not_section_id id' then s, SsrHyp (loc, id') else
hyp_err ?loc "Can't clear section hypothesis " id'
let interp_hyps ist gl ghyps =
let hyps = List.map snd (List.map (interp_hyp ist gl) ghyps) in
check_hyps_uniq [] hyps; Tacmach.project gl, hyps
(* Old terms *)
let mk_term k c = k, (mkRHole, Some c)
let mk_lterm c = mk_term xNoFlag c
(* New terms *)
let mk_ast_closure_term a t = {
annotation = a;
body = t;
interp_env = None;
glob_env = None;
}
let glob_ast_closure_term (ist : Genintern.glob_sign) t =
{ t with glob_env = Some ist }
let subst_ast_closure_term (_s : Mod_subst.substitution) t =
(* _s makes sense only for glob constr *)
t
let interp_ast_closure_term (ist : Geninterp.interp_sign) (gl : 'goal Evd.sigma) t =
(* gl is only useful if we want to interp *now*, later we have
* a potentially different gl.sigma *)
Tacmach.project gl, { t with interp_env = Some ist }
let ssrterm_of_ast_closure_term { body; annotation } =
let c = match annotation with
| `Parens -> xInParens
| `At -> xWithAt
| _ -> xNoFlag in
mk_term c body
let ssrdgens_of_parsed_dgens = function
| [], clr -> { dgens = []; gens = []; clr }
| [gens], clr -> { dgens = []; gens; clr }
| [dgens;gens], clr -> { dgens; gens; clr }
| _ -> assert false
let nbargs_open_constr gl oc =
let pl, _ = splay_open_constr gl oc in List.length pl
let pf_nbargs gl c = nbargs_open_constr gl (project gl, c)
let internal_names = ref []
let add_internal_name pt = internal_names := pt :: !internal_names
let is_internal_name s = List.exists (fun p -> p s) !internal_names
let tmp_tag = "_the_"
let tmp_post = "_tmp_"
let mk_tmp_id i =
Id.of_string (Printf.sprintf "%s%s%s" tmp_tag (CString.ordinal i) tmp_post)
let new_tmp_id ctx =
let id = mk_tmp_id (1 + List.length ctx.tmp_ids) in
let orig = ref Anonymous in
(id, orig), { ctx with tmp_ids = (id, orig) :: ctx.tmp_ids }
;;
let mk_internal_id s =
let s' = Printf.sprintf "_%s_" s in
let s' = String.map (fun c -> if c = ' ' then '_' else c) s' in
add_internal_name ((=) s'); Id.of_string s'
let same_prefix s t n =
let rec loop i = i = n || s.[i] = t.[i] && loop (i + 1) in loop 0
let skip_digits s =
let n = String.length s in
let rec loop i = if i < n && is_digit s.[i] then loop (i + 1) else i in loop
let mk_tagged_id t i = Id.of_string (Printf.sprintf "%s%d_" t i)
let is_tagged t s =
let n = String.length s - 1 and m = String.length t in
m < n && s.[n] = '_' && same_prefix s t m && skip_digits s m = n
let evar_tag = "_evar_"
let _ = add_internal_name (is_tagged evar_tag)
let mk_evar_name n = Name (mk_tagged_id evar_tag n)
let ssr_anon_hyp = "Hyp"
let wildcard_tag = "_the_"
let wildcard_post = "_wildcard_"
let mk_wildcard_id i =
Id.of_string (Printf.sprintf "%s%s%s" wildcard_tag (CString.ordinal i) wildcard_post)
let has_wildcard_tag s =
let n = String.length s in let m = String.length wildcard_tag in
let m' = String.length wildcard_post in
n < m + m' + 2 && same_prefix s wildcard_tag m &&
String.sub s (n - m') m' = wildcard_post &&
skip_digits s m = n - m' - 2
let _ = add_internal_name has_wildcard_tag
let new_wild_id ctx =
let i = 1 + List.length ctx.wild_ids in
let id = mk_wildcard_id i in
id, { ctx with wild_ids = id :: ctx.wild_ids }
let discharged_tag = "_discharged_"
let mk_discharged_id id =
Id.of_string (Printf.sprintf "%s%s_" discharged_tag (Id.to_string id))
let has_discharged_tag s =
let m = String.length discharged_tag and n = String.length s - 1 in
m < n && s.[n] = '_' && same_prefix s discharged_tag m
let _ = add_internal_name has_discharged_tag
let is_discharged_id id = has_discharged_tag (Id.to_string id)
let max_suffix m (t, j0 as tj0) id =
let s = Id.to_string id in let n = String.length s - 1 in
let dn = String.length t - 1 - n in let i0 = j0 - dn in
if not (i0 >= m && s.[n] = '_' && same_prefix s t m) then tj0 else
let rec loop i =
if i < i0 && s.[i] = '0' then loop (i + 1) else
if (if i < i0 then skip_digits s i = n else le_s_t i) then s, i else tj0
and le_s_t i =
let ds = s.[i] and dt = t.[i + dn] in
if ds = dt then i = n || le_s_t (i + 1) else
dt < ds && skip_digits s i = n in
loop m
let mk_anon_id t gl_ids =
let m, si0, id0 =
let s = ref (Printf.sprintf "_%s_" t) in
if is_internal_name !s then s := "_" ^ !s;
let n = String.length !s - 1 in
let rec loop i j =
let d = !s.[i] in if not (is_digit d) then i + 1, j else
loop (i - 1) (if d = '0' then j else i) in
let m, j = loop (n - 1) n in m, (!s, j), Id.of_string !s in
if not (List.mem id0 gl_ids) then id0 else
let s, i = List.fold_left (max_suffix m) si0 gl_ids in
let open Bytes in
let s = of_string s in
let n = length s - 1 in
let rec loop i =
if get s i = '9' then (set s i '0'; loop (i - 1)) else
if i < m then (set s n '0'; set s m '1'; cat s (of_string "_")) else
(set s i (Char.chr (Char.code (get s i) + 1)); s) in
Id.of_bytes (loop (n - 1))
let convert_concl_no_check t = Tactics.convert_concl_no_check t Term.DEFAULTcast
let convert_concl t = Tactics.convert_concl t Term.DEFAULTcast
let rename_hd_prod orig_name_ref gl =
match EConstr.kind (project gl) (pf_concl gl) with
| Term.Prod(_,src,tgt) ->
Proofview.V82.of_tactic (convert_concl_no_check (EConstr.mkProd (!orig_name_ref,src,tgt))) gl
| _ -> CErrors.anomaly (str "gentac creates no product")
(* Reduction that preserves the Prod/Let spine of the "in" tactical. *)
let inc_safe n = if n = 0 then n else n + 1
let rec safe_depth s c = match EConstr.kind s c with
| LetIn (Name x, _, _, c') when is_discharged_id x -> safe_depth s c' + 1
| LetIn (_, _, _, c') | Prod (_, _, c') -> inc_safe (safe_depth s c')
| _ -> 0
let red_safe (r : Reductionops.reduction_function) e s c0 =
let rec red_to e c n = match EConstr.kind s c with
| Prod (x, t, c') when n > 0 ->
let t' = r e s t in let e' = EConstr.push_rel (RelDecl.LocalAssum (x, t')) e in
EConstr.mkProd (x, t', red_to e' c' (n - 1))
| LetIn (x, b, t, c') when n > 0 ->
let t' = r e s t in let e' = EConstr.push_rel (RelDecl.LocalAssum (x, t')) e in
EConstr.mkLetIn (x, r e s b, t', red_to e' c' (n - 1))
| _ -> r e s c in
red_to e c0 (safe_depth s c0)
let is_id_constr sigma c = match EConstr.kind sigma c with
| Lambda(_,_,c) when EConstr.isRel sigma c -> 1 = EConstr.destRel sigma c
| _ -> false
let red_product_skip_id env sigma c = match EConstr.kind sigma c with
| App(hd,args) when Array.length args = 1 && is_id_constr sigma hd -> args.(0)
| _ -> try Tacred.red_product env sigma c with _ -> c
let ssrevaltac ist gtac = Tacinterp.tactic_of_value ist gtac
(** Open term to lambda-term coercion *)(* {{{ ************************************)
(* This operation takes a goal gl and an open term (sigma, t), and *)
(* returns a term t' where all the new evars in sigma are abstracted *)
(* with the mkAbs argument, i.e., for mkAbs = mkLambda then there is *)
(* some duplicate-free array args of evars of sigma such that the *)
(* term mkApp (t', args) is convertible to t. *)
(* This makes a useful shorthand for local definitions in proofs, *)
(* i.e., pose succ := _ + 1 means pose succ := fun n : nat => n + 1, *)
(* and, in context of the the 4CT library, pose mid := maps id means *)
(* pose mid := fun d : detaSet => @maps d d (@id (datum d)) *)
(* Note that this facility does not extend to set, which tries *)
(* instead to fill holes by matching a goal subterm. *)
(* The argument to "have" et al. uses product abstraction, e.g. *)
(* have Hmid: forall s, (maps id s) = s. *)
(* stands for *)
(* have Hmid: forall (d : dataSet) (s : seq d), (maps id s) = s. *)
(* We also use this feature for rewrite rules, so that, e.g., *)
(* rewrite: (plus_assoc _ 3). *)
(* will execute as *)
(* rewrite (fun n => plus_assoc n 3) *)
(* i.e., it will rewrite some subterm .. + (3 + ..) to .. + 3 + ... *)
(* The convention is also used for the argument of the congr tactic, *)
(* e.g., congr (x + _ * 1). *)
(* Replace new evars with lambda variables, retaining local dependencies *)
(* but stripping global ones. We use the variable names to encode the *)
(* the number of dependencies, so that the transformation is reversible. *)
let env_size env = List.length (Environ.named_context env)
let pf_concl gl = EConstr.Unsafe.to_constr (pf_concl gl)
let pf_get_hyp gl x = EConstr.Unsafe.to_named_decl (pf_get_hyp gl x)
let pf_e_type_of gl t =
let sigma, env, it = project gl, pf_env gl, sig_it gl in
let sigma, ty = Typing.type_of env sigma t in
re_sig it sigma, ty
let nf_evar sigma t =
EConstr.Unsafe.to_constr (Evarutil.nf_evar sigma (EConstr.of_constr t))
let pf_abs_evars2 gl rigid (sigma, c0) =
let c0 = EConstr.to_constr sigma c0 in
let sigma0, ucst = project gl, Evd.evar_universe_context sigma in
let nenv = env_size (pf_env gl) in
let abs_evar n k =
let evi = Evd.find sigma k in
let dc = CList.firstn n (evar_filtered_context evi) in
let abs_dc c = function
| NamedDecl.LocalDef (x,b,t) -> mkNamedLetIn x b t (mkArrow t c)
| NamedDecl.LocalAssum (x,t) -> mkNamedProd x t c in
let t = Context.Named.fold_inside abs_dc ~init:evi.evar_concl dc in
nf_evar sigma t in
let rec put evlist c = match Constr.kind c with
| Evar (k, a) ->
if List.mem_assoc k evlist || Evd.mem sigma0 k || List.mem k rigid then evlist else
let n = max 0 (Array.length a - nenv) in
let t = abs_evar n k in (k, (n, t)) :: put evlist t
| _ -> Constr.fold put evlist c in
let evlist = put [] c0 in
if evlist = [] then 0, EConstr.of_constr c0,[], ucst else
let rec lookup k i = function
| [] -> 0, 0
| (k', (n, _)) :: evl -> if k = k' then i, n else lookup k (i + 1) evl in
let rec get i c = match Constr.kind c with
| Evar (ev, a) ->
let j, n = lookup ev i evlist in
if j = 0 then Constr.map (get i) c else if n = 0 then mkRel j else
mkApp (mkRel j, Array.init n (fun k -> get i a.(n - 1 - k)))
| _ -> Constr.map_with_binders ((+) 1) get i c in
let rec loop c i = function
| (_, (n, t)) :: evl ->
loop (mkLambda (mk_evar_name n, get (i - 1) t, c)) (i - 1) evl
| [] -> c in
List.length evlist, EConstr.of_constr (loop (get 1 c0) 1 evlist), List.map fst evlist, ucst
let pf_abs_evars gl t = pf_abs_evars2 gl [] t
(* As before but if (?i : T(?j)) and (?j : P : Prop), then the lambda for i
* looks like (fun evar_i : (forall pi : P. T(pi))) thanks to "loopP" and all
* occurrences of evar_i are replaced by (evar_i evar_j) thanks to "app".
*
* If P can be solved by ssrautoprop (that defaults to trivial), then
* the corresponding lambda looks like (fun evar_i : T(c)) where c is
* the solution found by ssrautoprop.
*)
let ssrautoprop_tac = ref (fun gl -> assert false)
(* Thanks to Arnaud Spiwack for this snippet *)
let call_on_evar tac e s =
let { it = gs ; sigma = s } =
tac { it = e ; sigma = s; } in
gs, s
open Pp
let pp _ = () (* FIXME *)
module Intset = Evar.Set
let pf_abs_evars_pirrel gl (sigma, c0) =
pp(lazy(str"==PF_ABS_EVARS_PIRREL=="));
pp(lazy(str"c0= " ++ Printer.pr_constr_env (pf_env gl) sigma c0));
let sigma0 = project gl in
let c0 = nf_evar sigma0 (nf_evar sigma c0) in
let nenv = env_size (pf_env gl) in
let abs_evar n k =
let evi = Evd.find sigma k in
let dc = CList.firstn n (evar_filtered_context evi) in
let abs_dc c = function
| NamedDecl.LocalDef (x,b,t) -> mkNamedLetIn x b t (mkArrow t c)
| NamedDecl.LocalAssum (x,t) -> mkNamedProd x t c in
let t = Context.Named.fold_inside abs_dc ~init:evi.evar_concl dc in
nf_evar sigma0 (nf_evar sigma t) in
let rec put evlist c = match Constr.kind c with
| Evar (k, a) ->
if List.mem_assoc k evlist || Evd.mem sigma0 k then evlist else
let n = max 0 (Array.length a - nenv) in
let k_ty =
Retyping.get_sort_family_of
(pf_env gl) sigma (EConstr.of_constr (Evd.evar_concl (Evd.find sigma k))) in
let is_prop = k_ty = InProp in
let t = abs_evar n k in (k, (n, t, is_prop)) :: put evlist t
| _ -> Constr.fold put evlist c in
let evlist = put [] c0 in
if evlist = [] then 0, c0 else
let pr_constr t = Printer.pr_econstr_env (pf_env gl) sigma (Reductionops.nf_beta (pf_env gl) (project gl) (EConstr.of_constr t)) in
pp(lazy(str"evlist=" ++ pr_list (fun () -> str";")
(fun (k,_) -> Evar.print k) evlist));
let evplist =
let depev = List.fold_left (fun evs (_,(_,t,_)) ->
let t = EConstr.of_constr t in
Intset.union evs (Evarutil.undefined_evars_of_term sigma t)) Intset.empty evlist in
List.filter (fun (i,(_,_,b)) -> b && Intset.mem i depev) evlist in
let evlist, evplist, sigma =
if evplist = [] then evlist, [], sigma else
List.fold_left (fun (ev, evp, sigma) (i, (_,t,_) as p) ->
try
let ng, sigma = call_on_evar !ssrautoprop_tac i sigma in
if (ng <> []) then errorstrm (str "Should we tell the user?");
List.filter (fun (j,_) -> j <> i) ev, evp, sigma
with _ -> ev, p::evp, sigma) (evlist, [], sigma) (List.rev evplist) in
let c0 = nf_evar sigma c0 in
let evlist =
List.map (fun (x,(y,t,z)) -> x,(y,nf_evar sigma t,z)) evlist in
let evplist =
List.map (fun (x,(y,t,z)) -> x,(y,nf_evar sigma t,z)) evplist in
pp(lazy(str"c0= " ++ pr_constr c0));
let rec lookup k i = function
| [] -> 0, 0
| (k', (n,_,_)) :: evl -> if k = k' then i,n else lookup k (i + 1) evl in
let rec get evlist i c = match Constr.kind c with
| Evar (ev, a) ->
let j, n = lookup ev i evlist in
if j = 0 then Constr.map (get evlist i) c else if n = 0 then mkRel j else
mkApp (mkRel j, Array.init n (fun k -> get evlist i a.(n - 1 - k)))
| _ -> Constr.map_with_binders ((+) 1) (get evlist) i c in
let rec app extra_args i c = match decompose_app c with
| hd, args when isRel hd && destRel hd = i ->
let j = destRel hd in
mkApp (mkRel j, Array.of_list (List.map (Vars.lift (i-1)) extra_args @ args))
| _ -> Constr.map_with_binders ((+) 1) (app extra_args) i c in
let rec loopP evlist c i = function
| (_, (n, t, _)) :: evl ->
let t = get evlist (i - 1) t in
let n = Name (Id.of_string (ssr_anon_hyp ^ string_of_int n)) in
loopP evlist (mkProd (n, t, c)) (i - 1) evl
| [] -> c in
let rec loop c i = function
| (_, (n, t, _)) :: evl ->
let evs = Evarutil.undefined_evars_of_term sigma (EConstr.of_constr t) in
let t_evplist = List.filter (fun (k,_) -> Intset.mem k evs) evplist in
let t = loopP t_evplist (get t_evplist 1 t) 1 t_evplist in
let t = get evlist (i - 1) t in
let extra_args =
List.map (fun (k,_) -> mkRel (fst (lookup k i evlist)))
(List.rev t_evplist) in
let c = if extra_args = [] then c else app extra_args 1 c in
loop (mkLambda (mk_evar_name n, t, c)) (i - 1) evl
| [] -> c in
let res = loop (get evlist 1 c0) 1 evlist in
pp(lazy(str"res= " ++ pr_constr res));
List.length evlist, res
(* Strip all non-essential dependencies from an abstracted term, generating *)
(* standard names for the abstracted holes. *)
let nb_evar_deps = function
| Name id ->
let s = Id.to_string id in
if not (is_tagged evar_tag s) then 0 else
let m = String.length evar_tag in
(try int_of_string (String.sub s m (String.length s - 1 - m)) with _ -> 0)
| _ -> 0
let pf_type_id gl t = Id.of_string (Namegen.hdchar (pf_env gl) (project gl) t)
let pfe_type_of gl t =
let sigma, ty = pf_type_of gl t in
re_sig (sig_it gl) sigma, ty
let pf_type_of gl t =
let sigma, ty = pf_type_of gl (EConstr.of_constr t) in
re_sig (sig_it gl) sigma, EConstr.Unsafe.to_constr ty
let pf_abs_cterm gl n c0 =
if n <= 0 then c0 else
let c0 = EConstr.Unsafe.to_constr c0 in
let noargs = [|0|] in
let eva = Array.make n noargs in
let rec strip i c = match Constr.kind c with
| App (f, a) when isRel f ->
let j = i - destRel f in
if j >= n || eva.(j) = noargs then mkApp (f, Array.map (strip i) a) else
let dp = eva.(j) in
let nd = Array.length dp - 1 in
let mkarg k = strip i a.(if k < nd then dp.(k + 1) - j else k + dp.(0)) in
mkApp (f, Array.init (Array.length a - dp.(0)) mkarg)
| _ -> Constr.map_with_binders ((+) 1) strip i c in
let rec strip_ndeps j i c = match Constr.kind c with
| Prod (x, t, c1) when i < j ->
let dl, c2 = strip_ndeps j (i + 1) c1 in
if Vars.noccurn 1 c2 then dl, Vars.lift (-1) c2 else
i :: dl, mkProd (x, strip i t, c2)
| LetIn (x, b, t, c1) when i < j ->
let _, _, c1' = destProd c1 in
let dl, c2 = strip_ndeps j (i + 1) c1' in
if Vars.noccurn 1 c2 then dl, Vars.lift (-1) c2 else
i :: dl, mkLetIn (x, strip i b, strip i t, c2)
| _ -> [], strip i c in
let rec strip_evars i c = match Constr.kind c with
| Lambda (x, t1, c1) when i < n ->
let na = nb_evar_deps x in
let dl, t2 = strip_ndeps (i + na) i t1 in
let na' = List.length dl in
eva.(i) <- Array.of_list (na - na' :: dl);
let x' =
if na' = 0 then Name (pf_type_id gl (EConstr.of_constr t2)) else mk_evar_name na' in
mkLambda (x', t2, strip_evars (i + 1) c1)
(* if noccurn 1 c2 then lift (-1) c2 else
mkLambda (Name (pf_type_id gl t2), t2, c2) *)
| _ -> strip i c in
EConstr.of_constr (strip_evars 0 c0)
(* }}} *)
let pf_merge_uc uc gl =
re_sig (sig_it gl) (Evd.merge_universe_context (Refiner.project gl) uc)
let pf_merge_uc_of sigma gl =
let ucst = Evd.evar_universe_context sigma in
pf_merge_uc ucst gl
let rec constr_name sigma c = match EConstr.kind sigma c with
| Var id -> Name id
| Cast (c', _, _) -> constr_name sigma c'
| Const (cn,_) -> Name (Label.to_id (Constant.label cn))
| App (c', _) -> constr_name sigma c'
| _ -> Anonymous
let pf_mkprod gl c ?(name=constr_name (project gl) c) cl =
let gl, t = pfe_type_of gl c in
if name <> Anonymous || EConstr.Vars.noccurn (project gl) 1 cl then gl, EConstr.mkProd (name, t, cl) else
gl, EConstr.mkProd (Name (pf_type_id gl t), t, cl)
let pf_abs_prod name gl c cl = pf_mkprod gl c ~name (Termops.subst_term (project gl) c cl)
(** look up a name in the ssreflect internals module *)
let ssrdirpath = DirPath.make [Id.of_string "ssreflect"]
let ssrqid name = Libnames.make_qualid ssrdirpath (Id.of_string name)
let ssrtopqid name = Libnames.qualid_of_ident (Id.of_string name)
let locate_reference qid =
Smartlocate.global_of_extended_global (Nametab.locate_extended qid)
let mkSsrRef name =
try locate_reference (ssrqid name) with Not_found ->
try locate_reference (ssrtopqid name) with Not_found ->
CErrors.user_err (Pp.str "Small scale reflection library not loaded")
let mkSsrRRef name = (DAst.make @@ GRef (mkSsrRef name,None)), None
let mkSsrConst name env sigma =
EConstr.fresh_global env sigma (mkSsrRef name)
let pf_mkSsrConst name gl =
let sigma, env, it = project gl, pf_env gl, sig_it gl in
let (sigma, t) = mkSsrConst name env sigma in
t, re_sig it sigma
let pf_fresh_global name gl =
let sigma, env, it = project gl, pf_env gl, sig_it gl in
let sigma,t = Evd.fresh_global env sigma name in
t, re_sig it sigma
let mkProt t c gl =
let prot, gl = pf_mkSsrConst "protect_term" gl in
EConstr.mkApp (prot, [|t; c|]), gl
let mkEtaApp c n imin =
let open EConstr in
if n = 0 then c else
let nargs, mkarg =
if n < 0 then -n, (fun i -> mkRel (imin + i)) else
let imax = imin + n - 1 in n, (fun i -> mkRel (imax - i)) in
mkApp (c, Array.init nargs mkarg)
let mkRefl t c gl =
let sigma = project gl in
let (sigma, refl) = EConstr.fresh_global (pf_env gl) sigma Coqlib.((build_coq_eq_data()).refl) in
EConstr.mkApp (refl, [|t; c|]), { gl with sigma }
let discharge_hyp (id', (id, mode)) gl =
let cl' = Vars.subst_var id (pf_concl gl) in
match pf_get_hyp gl id, mode with
| NamedDecl.LocalAssum (_, t), _ | NamedDecl.LocalDef (_, _, t), "(" ->
Proofview.V82.of_tactic (Tactics.apply_type ~typecheck:true (EConstr.of_constr (mkProd (Name id', t, cl')))
[EConstr.of_constr (mkVar id)]) gl
| NamedDecl.LocalDef (_, v, t), _ ->
Proofview.V82.of_tactic
(convert_concl (EConstr.of_constr (mkLetIn (Name id', v, t, cl')))) gl
(* wildcard names *)
let clear_wilds wilds gl =
Proofview.V82.of_tactic (Tactics.clear (List.filter (fun id -> List.mem id wilds) (pf_ids_of_hyps gl))) gl
let clear_with_wilds wilds clr0 gl =
let extend_clr clr nd =
let id = NamedDecl.get_id nd in
if List.mem id clr || not (List.mem id wilds) then clr else
let vars = Termops.global_vars_set_of_decl (pf_env gl) (project gl) nd in
let occurs id' = Id.Set.mem id' vars in
if List.exists occurs clr then id :: clr else clr in
Proofview.V82.of_tactic (Tactics.clear (Context.Named.fold_inside extend_clr ~init:clr0 (Tacmach.pf_hyps gl))) gl
let clear_wilds_and_tmp_and_delayed_ids gl =
let _, ctx = pull_ctx gl in
tac_ctx
(tclTHEN
(clear_with_wilds ctx.wild_ids ctx.delayed_clears)
(clear_wilds (List.map fst ctx.tmp_ids @ ctx.wild_ids))) gl
let rec is_name_in_ipats name = function
| IPatClear clr :: tl ->
List.exists (function SsrHyp(_,id) -> id = name) clr
|| is_name_in_ipats name tl
| IPatId id :: tl -> id = name || is_name_in_ipats name tl
| (IPatCase l | IPatDispatch l) :: tl -> List.exists (is_name_in_ipats name) l || is_name_in_ipats name tl
| _ :: tl -> is_name_in_ipats name tl
| [] -> false
let view_error s gv =
errorstrm (str ("Cannot " ^ s ^ " view ") ++ pr_term gv)
open Locus
(****************************** tactics ***********************************)
let rewritetac dir c =
(* Due to the new optional arg ?tac, application shouldn't be too partial *)
Proofview.V82.of_tactic begin
Equality.general_rewrite (dir = L2R) AllOccurrences true false c
end
(**********************`:********* hooks ************************************)
type name_hint = (int * EConstr.types array) option ref
let pf_abs_ssrterm ?(resolve_typeclasses=false) ist gl t =
let sigma, ct as t = interp_term ist gl t in
let sigma, _ as t =
let env = pf_env gl in
if not resolve_typeclasses then t
else
let sigma = Typeclasses.resolve_typeclasses ~fail:false env sigma in
sigma, Evarutil.nf_evar sigma ct in
let n, c, abstracted_away, ucst = pf_abs_evars gl t in
List.fold_left Evd.remove sigma abstracted_away, pf_abs_cterm gl n c, ucst, n
let top_id = mk_internal_id "top assumption"
let ssr_n_tac seed n gl =
let name = if n = -1 then seed else ("ssr" ^ seed ^ string_of_int n) in
let fail msg = CErrors.user_err (Pp.str msg) in
let tacname =
try Tacenv.locate_tactic (Libnames.qualid_of_ident (Id.of_string name))
with Not_found -> try Tacenv.locate_tactic (ssrqid name)
with Not_found ->
if n = -1 then fail "The ssreflect library was not loaded"
else fail ("The tactic "^name^" was not found") in
let tacexpr = Loc.tag @@ Tacexpr.Reference (ArgArg (Loc.tag @@ tacname)) in
Proofview.V82.of_tactic (Tacinterp.eval_tactic (Tacexpr.TacArg tacexpr)) gl
let donetac n gl = ssr_n_tac "done" n gl
open Constrexpr
open Util
(** Constructors for constr_expr *)
let mkCProp loc = CAst.make ?loc @@ CSort GProp
let mkCType loc = CAst.make ?loc @@ CSort (GType [])
let mkCVar ?loc id = CAst.make ?loc @@ CRef (CAst.make ?loc @@ Ident id, None)
let rec mkCHoles ?loc n =
if n <= 0 then [] else (CAst.make ?loc @@ CHole (None, IntroAnonymous, None)) :: mkCHoles ?loc (n - 1)
let mkCHole loc = CAst.make ?loc @@ CHole (None, IntroAnonymous, None)
let mkCLambda ?loc name ty t = CAst.make ?loc @@
CLambdaN ([CLocalAssum([CAst.make ?loc name], Default Explicit, ty)], t)
let mkCArrow ?loc ty t = CAst.make ?loc @@
CProdN ([CLocalAssum([CAst.make Anonymous], Default Explicit, ty)], t)
let mkCCast ?loc t ty = CAst.make ?loc @@ CCast (t, CastConv ty)
let rec isCHoles = function { CAst.v = CHole _ } :: cl -> isCHoles cl | cl -> cl = []
let rec isCxHoles = function ({ CAst.v = CHole _ }, None) :: ch -> isCxHoles ch | _ -> false
let pf_interp_ty ?(resolve_typeclasses=false) ist gl ty =
let n_binders = ref 0 in
let ty = match ty with
| a, (t, None) ->
let rec force_type ty = DAst.(map (function
| GProd (x, k, s, t) -> incr n_binders; GProd (x, k, s, force_type t)
| GLetIn (x, v, oty, t) -> incr n_binders; GLetIn (x, v, oty, force_type t)
| _ -> DAst.get (mkRCast ty mkRType))) ty in
a, (force_type t, None)
| _, (_, Some ty) ->
let rec force_type ty = CAst.(map (function
| CProdN (abs, t) ->
n_binders := !n_binders + List.length (List.flatten (List.map (function CLocalAssum (nal,_,_) -> nal | CLocalDef (na,_,_) -> [na] | CLocalPattern _ -> (* We count a 'pat for 1; TO BE CHECKED *) [CAst.make Name.Anonymous]) abs));
CProdN (abs, force_type t)
| CLetIn (n, v, oty, t) -> incr n_binders; CLetIn (n, v, oty, force_type t)
| _ -> (mkCCast ty (mkCType None)).v)) ty in
mk_term ' ' (force_type ty) in
let strip_cast (sigma, t) =
let rec aux t = match EConstr.kind_of_type sigma t with
| CastType (t, ty) when !n_binders = 0 && EConstr.isSort sigma ty -> t
| ProdType(n,s,t) -> decr n_binders; EConstr.mkProd (n, s, aux t)
| LetInType(n,v,ty,t) -> decr n_binders; EConstr.mkLetIn (n, v, ty, aux t)
| _ -> anomaly "pf_interp_ty: ssr Type cast deleted by typecheck" in
sigma, aux t in
let sigma, cty as ty = strip_cast (interp_term ist gl ty) in
let ty =
let env = pf_env gl in
if not resolve_typeclasses then ty
else
let sigma = Typeclasses.resolve_typeclasses ~fail:false env sigma in
sigma, Evarutil.nf_evar sigma cty in
let n, c, _, ucst = pf_abs_evars gl ty in
let lam_c = pf_abs_cterm gl n c in
let ctx, c = EConstr.decompose_lam_n_assum sigma n lam_c in
n, EConstr.it_mkProd_or_LetIn c ctx, lam_c, ucst
;;
(* TASSI: given (c : ty), generates (c ??? : ty[???/...]) with m evars *)
exception NotEnoughProducts
let saturate ?(beta=false) ?(bi_types=false) env sigma c ?(ty=Retyping.get_type_of env sigma c) m
=
let rec loop ty args sigma n =
if n = 0 then
let args = List.rev args in
(if beta then Reductionops.whd_beta sigma else fun x -> x)
(EConstr.mkApp (c, Array.of_list (List.map snd args))), ty, args, sigma
else match EConstr.kind_of_type sigma ty with
| ProdType (_, src, tgt) ->
let sigma = create_evar_defs sigma in
let (sigma, x) =
Evarutil.new_evar env sigma
(if bi_types then Reductionops.nf_betaiota env sigma src else src) in
loop (EConstr.Vars.subst1 x tgt) ((m - n,x) :: args) sigma (n-1)
| CastType (t, _) -> loop t args sigma n
| LetInType (_, v, _, t) -> loop (EConstr.Vars.subst1 v t) args sigma n
| SortType _ -> assert false
| AtomicType _ ->
let ty = (* FIXME *)
(Reductionops.whd_all env sigma) ty in
match EConstr.kind_of_type sigma ty with
| ProdType _ -> loop ty args sigma n
| _ -> raise NotEnoughProducts
in
loop ty [] sigma m
let pf_saturate ?beta ?bi_types gl c ?ty m =
let env, sigma, si = pf_env gl, project gl, sig_it gl in
let t, ty, args, sigma = saturate ?beta ?bi_types env sigma c ?ty m in
t, ty, args, re_sig si sigma
let pf_partial_solution gl t evl =
let sigma, g = project gl, sig_it gl in
let sigma = Goal.V82.partial_solution sigma g t in
re_sig (List.map (fun x -> (fst (EConstr.destEvar sigma x))) evl) sigma
let dependent_apply_error =
try CErrors.user_err (Pp.str "Could not fill dependent hole in \"apply\"")
with err -> err
(* TASSI: Sometimes Coq's apply fails. According to my experience it may be
* related to goals that are products and with beta redexes. In that case it
* guesses the wrong number of implicit arguments for your lemma. What follows
* is just like apply, but with a user-provided number n of implicits.
*
* Refine.refine function that handles type classes and evars but fails to
* handle "dependently typed higher order evars".
*
* Refiner.refiner that does not handle metas with a non ground type but works
* with dependently typed higher order metas. *)
let applyn ~with_evars ?beta ?(with_shelve=false) n t gl =
if with_evars then
let refine gl =
let t, ty, args, gl = pf_saturate ?beta ~bi_types:true gl t n in
(* pp(lazy(str"sigma@saturate=" ++ pr_evar_map None (project gl))); *)
let gl = pf_unify_HO gl ty (Tacmach.pf_concl gl) in
let gs = CList.map_filter (fun (_, e) ->
if EConstr.isEvar (project gl) e then Some e else None)
args in
pf_partial_solution gl t gs
in
Proofview.(V82.of_tactic
(tclTHEN (V82.tactic refine)
(if with_shelve then shelve_unifiable else tclUNIT ()))) gl
else
let t, gl = if n = 0 then t, gl else
let sigma, si = project gl, sig_it gl in
let rec loop sigma bo args = function (* saturate with metas *)
| 0 -> EConstr.mkApp (t, Array.of_list (List.rev args)), re_sig si sigma
| n -> match EConstr.kind sigma bo with
| Lambda (_, ty, bo) ->
if not (EConstr.Vars.closed0 sigma ty) then
raise dependent_apply_error;
let m = Evarutil.new_meta () in
loop (meta_declare m (EConstr.Unsafe.to_constr ty) sigma) bo ((EConstr.mkMeta m)::args) (n-1)
| _ -> assert false
in loop sigma t [] n in
pp(lazy(str"Refiner.refiner " ++ Printer.pr_econstr_env (pf_env gl) (project gl) t));
Tacmach.refine_no_check t gl
let refine_with ?(first_goes_last=false) ?beta ?(with_evars=true) oc gl =
let rec mkRels = function 1 -> [] | n -> mkRel n :: mkRels (n-1) in
let uct = Evd.evar_universe_context (fst oc) in
let n, oc = pf_abs_evars_pirrel gl (fst oc, EConstr.Unsafe.to_constr (snd oc)) in
let gl = pf_unsafe_merge_uc uct gl in
let oc = if not first_goes_last || n <= 1 then oc else
let l, c = decompose_lam oc in
if not (List.for_all_i (fun i (_,t) -> Vars.closedn ~-i t) (1-n) l) then oc else
compose_lam (let xs,y = List.chop (n-1) l in y @ xs)
(mkApp (compose_lam l c, Array.of_list (mkRel 1 :: mkRels n)))
in
pp(lazy(str"after: " ++ Printer.pr_constr_env (pf_env gl) (project gl) oc));
try applyn ~with_evars ~with_shelve:true ?beta n (EConstr.of_constr oc) gl
with e when CErrors.noncritical e -> raise dependent_apply_error
(** Profiling *)(* {{{ *************************************************************)
type profiler = {
profile : 'a 'b. ('a -> 'b) -> 'a -> 'b;
reset : unit -> unit;
print : unit -> unit }
let profile_now = ref false
let something_profiled = ref false
let profilers = ref []
let add_profiler f = profilers := f :: !profilers;;
let _ =
Goptions.declare_bool_option
{ Goptions.optname = "ssreflect profiling";
Goptions.optkey = ["SsrProfiling"];
Goptions.optread = (fun _ -> !profile_now);
Goptions.optdepr = false;
Goptions.optwrite = (fun b ->
Ssrmatching.profile b;
profile_now := b;
if b then List.iter (fun f -> f.reset ()) !profilers;
if not b then List.iter (fun f -> f.print ()) !profilers) }
let () =
let prof_total =
let init = ref 0.0 in {
profile = (fun f x -> assert false);
reset = (fun () -> init := Unix.gettimeofday ());
print = (fun () -> if !something_profiled then
prerr_endline
(Printf.sprintf "!! %-39s %10d %9.4f %9.4f %9.4f"
"total" 0 (Unix.gettimeofday() -. !init) 0.0 0.0)) } in
let prof_legenda = {
profile = (fun f x -> assert false);
reset = (fun () -> ());
print = (fun () -> if !something_profiled then begin
prerr_endline
(Printf.sprintf "!! %39s ---------- --------- --------- ---------"
(String.make 39 '-'));
prerr_endline
(Printf.sprintf "!! %-39s %10s %9s %9s %9s"
"function" "#calls" "total" "max" "average") end) } in
add_profiler prof_legenda;
add_profiler prof_total
;;
let mk_profiler s =
let total, calls, max = ref 0.0, ref 0, ref 0.0 in
let reset () = total := 0.0; calls := 0; max := 0.0 in
let profile f x =
if not !profile_now then f x else
let before = Unix.gettimeofday () in
try
incr calls;
let res = f x in
let after = Unix.gettimeofday () in
let delta = after -. before in
total := !total +. delta;
if delta > !max then max := delta;
res
with exc ->
let after = Unix.gettimeofday () in
let delta = after -. before in
total := !total +. delta;
if delta > !max then max := delta;
raise exc in
let print () =
if !calls <> 0 then begin
something_profiled := true;
prerr_endline
(Printf.sprintf "!! %-39s %10d %9.4f %9.4f %9.4f"
s !calls !total !max (!total /. (float_of_int !calls))) end in
let prof = { profile = profile; reset = reset; print = print } in
add_profiler prof;
prof
;;
(* }}} *)
(* We wipe out all the keywords generated by the grammar rules we defined. *)
(* The user is supposed to Require Import ssreflect or Require ssreflect *)
(* and Import ssreflect.SsrSyntax to obtain these keywords and as a *)
(* consequence the extended ssreflect grammar. *)
let () = CLexer.set_keyword_state frozen_lexer ;;
(** Basic tactics *)
let rec fst_prod red tac = Proofview.Goal.nf_enter begin fun gl ->
let concl = Proofview.Goal.concl gl in
match EConstr.kind (Proofview.Goal.sigma gl) concl with
| Prod (id,_,tgt) | LetIn(id,_,_,tgt) -> tac id
| _ -> if red then Tacticals.New.tclZEROMSG (str"No product even after head-reduction.")
else Tacticals.New.tclTHEN Tactics.hnf_in_concl (fst_prod true tac)
end
let introid ?(orig=ref Anonymous) name = tclTHEN (fun gl ->
let g, env = Tacmach.pf_concl gl, pf_env gl in
let sigma = project gl in
match EConstr.kind sigma g with
| App (hd, _) when EConstr.isLambda sigma hd ->
Proofview.V82.of_tactic (convert_concl_no_check (Reductionops.whd_beta sigma g)) gl
| _ -> tclIDTAC gl)
(Proofview.V82.of_tactic
(fst_prod false (fun id -> orig := id; Tactics.intro_mustbe_force name)))
;;
let anontac decl gl =
let id = match RelDecl.get_name decl with
| Name id ->
if is_discharged_id id then id else mk_anon_id (Id.to_string id) (Tacmach.pf_ids_of_hyps gl)
| _ -> mk_anon_id ssr_anon_hyp (Tacmach.pf_ids_of_hyps gl) in
introid id gl
let rec intro_anon gl =
try anontac (List.hd (fst (EConstr.decompose_prod_n_assum (project gl) 1 (Tacmach.pf_concl gl)))) gl
with err0 -> try tclTHEN (Proofview.V82.of_tactic Tactics.red_in_concl) intro_anon gl with e when CErrors.noncritical e -> raise err0
(* with _ -> CErrors.error "No product even after reduction" *)
let is_pf_var sigma c =
EConstr.isVar sigma c && not_section_id (EConstr.destVar sigma c)
let hyp_of_var sigma v = SsrHyp (Loc.tag @@ EConstr.destVar sigma v)
let interp_clr sigma = function
| Some clr, (k, c)
when (k = xNoFlag || k = xWithAt) && is_pf_var sigma c ->
hyp_of_var sigma c :: clr
| Some clr, _ -> clr
| None, _ -> []
(** Basic tacticals *)
(** Multipliers *)(* {{{ ***********************************************************)
(* tactical *)
let tclID tac = tac
let tclDOTRY n tac =
if n <= 0 then tclIDTAC else
let rec loop i gl =
if i = n then tclTRY tac gl else
tclTRY (tclTHEN tac (loop (i + 1))) gl in
loop 1
let tclDO n tac =
let prefix i = str"At iteration " ++ int i ++ str": " in
let tac_err_at i gl =
try tac gl
with
| CErrors.UserError (l, s) as e ->
let _, info = CErrors.push e in
let e' = CErrors.UserError (l, prefix i ++ s) in
Util.iraise (e', info)
| Ploc.Exc(loc, CErrors.UserError (l, s)) ->
raise (Ploc.Exc(loc, CErrors.UserError (l, prefix i ++ s))) in
let rec loop i gl =
if i = n then tac_err_at i gl else
(tclTHEN (tac_err_at i) (loop (i + 1))) gl in
loop 1
let tclMULT = function
| 0, May -> tclREPEAT
| 1, May -> tclTRY
| n, May -> tclDOTRY n
| 0, Must -> tclAT_LEAST_ONCE
| n, Must when n > 1 -> tclDO n
| _ -> tclID
let old_cleartac clr = check_hyps_uniq [] clr; Proofview.V82.of_tactic (Tactics.clear (hyps_ids clr))
let cleartac clr = check_hyps_uniq [] clr; Tactics.clear (hyps_ids clr)
(* }}} *)
(** Generalize tactic *)
(* XXX the k of the redex should percolate out *)
let pf_interp_gen_aux gl to_ind ((oclr, occ), t) =
let pat = interp_cpattern gl t None in (* UGLY API *)
let cl, env, sigma = Tacmach.pf_concl gl, pf_env gl, project gl in
let (c, ucst), cl =
try fill_occ_pattern ~raise_NoMatch:true env sigma (EConstr.Unsafe.to_constr cl) pat occ 1
with NoMatch -> redex_of_pattern env pat, (EConstr.Unsafe.to_constr cl) in
let gl = pf_merge_uc ucst gl in
let c = EConstr.of_constr c in
let cl = EConstr.of_constr cl in
let clr = interp_clr sigma (oclr, (tag_of_cpattern t, c)) in
if not(occur_existential sigma c) then
if tag_of_cpattern t = xWithAt then
if not (EConstr.isVar sigma c) then
errorstrm (str "@ can be used with variables only")
else match Tacmach.pf_get_hyp gl (EConstr.destVar sigma c) with
| NamedDecl.LocalAssum _ -> errorstrm (str "@ can be used with let-ins only")
| NamedDecl.LocalDef (name, b, ty) -> true, pat, EConstr.mkLetIn (Name name,b,ty,cl),c,clr,ucst,gl
else let gl, ccl = pf_mkprod gl c cl in false, pat, ccl, c, clr,ucst,gl
else if to_ind && occ = None then
let nv, p, _, ucst' = pf_abs_evars gl (fst pat, c) in
let ucst = UState.union ucst ucst' in
if nv = 0 then anomaly "occur_existential but no evars" else
let gl, pty = pfe_type_of gl p in
false, pat, EConstr.mkProd (constr_name (project gl) c, pty, Tacmach.pf_concl gl), p, clr,ucst,gl
else CErrors.user_err ?loc:(loc_of_cpattern t) (str "generalized term didn't match")
let apply_type x xs = Proofview.V82.of_tactic (Tactics.apply_type ~typecheck:true x xs)
let genclrtac cl cs clr =
let tclmyORELSE tac1 tac2 gl =
try tac1 gl
with e when CErrors.noncritical e -> tac2 e gl in
(* apply_type may give a type error, but the useful message is
* the one of clear. You type "move: x" and you get
* "x is used in hyp H" instead of
* "The term H has type T x but is expected to have type T x0". *)
tclTHEN
(tclmyORELSE
(apply_type cl cs)
(fun type_err gl ->
tclTHEN
(tclTHEN (Proofview.V82.of_tactic (Tactics.elim_type (EConstr.of_constr
(Universes.constr_of_global @@ Coqlib.build_coq_False ())))) (old_cleartac clr))
(fun gl -> raise type_err)
gl))
(old_cleartac clr)
let gentac gen gl =
(* ppdebug(lazy(str"sigma@gentac=" ++ pr_evar_map None (project gl))); *)
let conv, _, cl, c, clr, ucst,gl = pf_interp_gen_aux gl false gen in
ppdebug(lazy(str"c@gentac=" ++ pr_econstr_env (pf_env gl) (project gl) c));
let gl = pf_merge_uc ucst gl in
if conv
then tclTHEN (Proofview.V82.of_tactic (convert_concl cl)) (old_cleartac clr) gl
else genclrtac cl [c] clr gl
let genstac (gens, clr) =
tclTHENLIST (old_cleartac clr :: List.rev_map gentac gens)
let gen_tmp_ids
?(ist=Geninterp.({ lfun = Id.Map.empty; extra = Tacinterp.TacStore.empty })) gl
=
let gl, ctx = pull_ctx gl in
push_ctxs ctx
(tclTHENLIST
(List.map (fun (id,orig_ref) ->
tclTHEN
(gentac ((None,Some(false,[])),cpattern_of_id id))
(rename_hd_prod orig_ref))
ctx.tmp_ids) gl)
;;
let pf_interp_gen gl to_ind gen =
let _, _, a, b, c, ucst,gl = pf_interp_gen_aux gl to_ind gen in
a, b ,c, pf_merge_uc ucst gl
(* TASSI: This version of unprotects inlines the unfold tactic definition,
* since we don't want to wipe out let-ins, and it seems there is no flag
* to change that behaviour in the standard unfold code *)
let unprotecttac gl =
let c, gl = pf_mkSsrConst "protect_term" gl in
let prot, _ = EConstr.destConst (project gl) c in
Tacticals.onClause (fun idopt ->
let hyploc = Option.map (fun id -> id, InHyp) idopt in
Proofview.V82.of_tactic (Tactics.reduct_option
(Reductionops.clos_norm_flags
(CClosure.RedFlags.mkflags
[CClosure.RedFlags.fBETA;
CClosure.RedFlags.fCONST prot;
CClosure.RedFlags.fMATCH;
CClosure.RedFlags.fFIX;
CClosure.RedFlags.fCOFIX]), DEFAULTcast) hyploc))
allHypsAndConcl gl
let is_protect hd env sigma =
let _, protectC = mkSsrConst "protect_term" env sigma in
EConstr.eq_constr_nounivs sigma hd protectC
let abs_wgen keep_let f gen (gl,args,c) =
let sigma, env = project gl, pf_env gl in
let evar_closed t p =
if occur_existential sigma t then
CErrors.user_err ?loc:(loc_of_cpattern p) ~hdr:"ssreflect"
(pr_constr_pat (EConstr.Unsafe.to_constr t) ++
str" contains holes and matches no subterm of the goal") in
match gen with
| _, Some ((x, mode), None) when mode = "@" || (mode = " " && keep_let) ->
let x = hoi_id x in
let decl = Tacmach.pf_get_hyp gl x in
gl,
(if NamedDecl.is_local_def decl then args else EConstr.mkVar x :: args),
EConstr.mkProd_or_LetIn (decl |> NamedDecl.to_rel_decl |> RelDecl.set_name (Name (f x)))
(EConstr.Vars.subst_var x c)
| _, Some ((x, _), None) ->
let x = hoi_id x in
gl, EConstr.mkVar x :: args, EConstr.mkProd (Name (f x),Tacmach.pf_get_hyp_typ gl x, EConstr.Vars.subst_var x c)
| _, Some ((x, "@"), Some p) ->
let x = hoi_id x in
let cp = interp_cpattern gl p None in
let (t, ucst), c =
try fill_occ_pattern ~raise_NoMatch:true env sigma (EConstr.Unsafe.to_constr c) cp None 1
with NoMatch -> redex_of_pattern env cp, (EConstr.Unsafe.to_constr c) in
let c = EConstr.of_constr c in
let t = EConstr.of_constr t in
evar_closed t p;
let ut = red_product_skip_id env sigma t in
let gl, ty = pfe_type_of gl t in
pf_merge_uc ucst gl, args, EConstr.mkLetIn(Name (f x), ut, ty, c)
| _, Some ((x, _), Some p) ->
let x = hoi_id x in
let cp = interp_cpattern gl p None in
let (t, ucst), c =
try fill_occ_pattern ~raise_NoMatch:true env sigma (EConstr.Unsafe.to_constr c) cp None 1
with NoMatch -> redex_of_pattern env cp, (EConstr.Unsafe.to_constr c) in
let c = EConstr.of_constr c in
let t = EConstr.of_constr t in
evar_closed t p;
let gl, ty = pfe_type_of gl t in
pf_merge_uc ucst gl, t :: args, EConstr.mkProd(Name (f x), ty, c)
| _ -> gl, args, c
let clr_of_wgen gen clrs = match gen with
| clr, Some ((x, _), None) ->
let x = hoi_id x in
old_cleartac clr :: old_cleartac [SsrHyp(Loc.tag x)] :: clrs
| clr, _ -> old_cleartac clr :: clrs
let reduct_in_concl t = Tactics.reduct_in_concl (t, DEFAULTcast)
let unfold cl =
let module R = Reductionops in let module F = CClosure.RedFlags in
reduct_in_concl (R.clos_norm_flags (F.mkflags
(List.map (fun c -> F.fCONST (fst (destConst (EConstr.Unsafe.to_constr c)))) cl @
[F.fBETA; F.fMATCH; F.fFIX; F.fCOFIX])))
open Proofview
open Notations
let tacSIGMA = Goal.enter_one begin fun g ->
let k = Goal.goal g in
let sigma = Goal.sigma g in
tclUNIT (Tacmach.re_sig k sigma)
end
let tclINTERP_AST_CLOSURE_TERM_AS_CONSTR c =
tclINDEPENDENTL begin tacSIGMA >>= fun gl ->
let old_ssrterm = mkRHole, Some c.Ssrast.body in
let ist =
option_assert_get c.Ssrast.interp_env
Pp.(str "tclINTERP_AST_CLOSURE_TERM_AS_CONSTR: term with no ist") in
let sigma, t =
interp_wit Stdarg.wit_constr ist gl old_ssrterm in
Unsafe.tclEVARS sigma <*>
tclUNIT t
end
let tacREDUCE_TO_QUANTIFIED_IND ty =
tacSIGMA >>= fun gl ->
tclUNIT (Tacmach.pf_reduce_to_quantified_ind gl ty)
let tacTYPEOF c = Goal.enter_one ~__LOC__ (fun g ->
let sigma, env = Goal.sigma g, Goal.env g in
let sigma, ty = Typing.type_of env sigma c in
Unsafe.tclEVARS sigma <*> tclUNIT ty)
(** This tactic creates a partial proof realizing the introduction rule, but
does not check anything. *)
let unsafe_intro env store decl b =
let open Context.Named.Declaration in
Refine.refine ~typecheck:false begin fun sigma ->
let ctx = Environ.named_context_val env in
let nctx = EConstr.push_named_context_val decl ctx in
let inst = List.map (get_id %> EConstr.mkVar) (Environ.named_context env) in
let ninst = EConstr.mkRel 1 :: inst in
let nb = EConstr.Vars.subst1 (EConstr.mkVar (get_id decl)) b in
let sigma, ev =
Evarutil.new_evar_instance nctx sigma nb ~principal:true ~store ninst in
sigma, EConstr.mkNamedLambda_or_LetIn decl ev
end
let set_decl_id id = let open Context in function
| Rel.Declaration.LocalAssum(name,ty) -> Named.Declaration.LocalAssum(id,ty)
| Rel.Declaration.LocalDef(name,ty,t) -> Named.Declaration.LocalDef(id,ty,t)
let rec decompose_assum env sigma orig_goal =
let open Context in
match EConstr.kind sigma orig_goal with
| Prod(name,ty,t) ->
Rel.Declaration.LocalAssum(name,ty), t, true
| LetIn(name,ty,t1,t2) -> Rel.Declaration.LocalDef(name, ty, t1), t2, true
| _ ->
let goal = Reductionops.whd_allnolet env sigma orig_goal in
match EConstr.kind sigma goal with
| Prod(name,ty,t) -> Rel.Declaration.LocalAssum(name,ty), t, false
| LetIn(name,ty,t1,t2) -> Rel.Declaration.LocalDef(name,ty,t1), t2, false
| App(hd,args) when EConstr.isLetIn sigma hd -> (* hack *)
let _,v,_,b = EConstr.destLetIn sigma hd in
let ctx, t, _ =
decompose_assum env sigma
(EConstr.mkApp (EConstr.Vars.subst1 v b, args)) in
ctx, t, false
| _ -> CErrors.user_err
Pp.(str "No assumption in " ++ Printer.pr_econstr_env env sigma goal)
let tclFULL_BETAIOTA = Goal.enter begin fun gl ->
let r, _ = Redexpr.reduction_of_red_expr (Goal.env gl)
Genredexpr.(Lazy {
rBeta=true; rMatch=true; rFix=true; rCofix=true;
rZeta=false; rDelta=false; rConst=[]}) in
Tactics.e_reduct_in_concl ~check:false (r,Constr.DEFAULTcast)
end
(** [intro id k] introduces the first premise (product or let-in) of the goal
under the name [id], reducing the head of the goal (using beta, iota, delta
but not zeta) if necessary. If [id] is None, a name is generated, that will
not be user accessible. If the goal does not start with a product or a
let-in even after reduction, it fails. In case of success, the original name
and final id are passed to the continuation [k] which gets evaluated. *)
let tclINTRO ~id ~conclusion:k = Goal.enter begin fun gl ->
let open Context in
let env, sigma, extra, g = Goal.(env gl, sigma gl, extra gl, concl gl) in
let decl, t, no_red = decompose_assum env sigma g in
let original_name = Rel.Declaration.get_name decl in
let already_used = Tacmach.New.pf_ids_of_hyps gl in
let id = match id, original_name with
| Some id, _ -> id
| _, Name id ->
if is_discharged_id id then id
else mk_anon_id (Id.to_string id) already_used
| _, _ ->
let ids = Tacmach.New.pf_ids_of_hyps gl in
mk_anon_id ssr_anon_hyp ids
in
if List.mem id already_used then
errorstrm Pp.(Id.print id ++ str" already used");
unsafe_intro env extra (set_decl_id id decl) t <*>
(if no_red then tclUNIT () else tclFULL_BETAIOTA) <*>
k ~orig_name:original_name ~new_name:id
end
let return ~orig_name:_ ~new_name:_ = tclUNIT ()
let tclINTRO_ID id = tclINTRO ~id:(Some id) ~conclusion:return
let tclINTRO_ANON = tclINTRO ~id:None ~conclusion:return
let tclRENAME_HD_PROD name = Goal.enter begin fun gl ->
let convert_concl_no_check t =
Tactics.convert_concl_no_check t Term.DEFAULTcast in
let concl = Goal.concl gl in
let sigma = Goal.sigma gl in
match EConstr.kind sigma concl with
| Prod(_,src,tgt) ->
convert_concl_no_check EConstr.(mkProd (name,src,tgt))
| _ -> CErrors.anomaly (Pp.str "rename_hd_prod: no head product")
end
let tcl0G tac =
numgoals >>= fun ng -> if ng = 0 then tclUNIT () else tac
let rec tclFIRSTa = function
| [] -> Tacticals.New.tclZEROMSG Pp.(str"No applicable tactic.")
| tac :: rest -> tclORELSE tac (fun _ -> tclFIRSTa rest)
let rec tclFIRSTi tac n =
if n < 0 then Tacticals.New.tclZEROMSG Pp.(str "tclFIRSTi")
else tclORELSE (tclFIRSTi tac (n-1)) (fun _ -> tac n)
let tacCONSTR_NAME ?name c =
match name with
| Some n -> tclUNIT n
| None ->
Goal.enter_one ~__LOC__ (fun g ->
let sigma = Goal.sigma g in
tclUNIT (constr_name sigma c))
let tacMKPROD c ?name cl =
tacTYPEOF c >>= fun t ->
tacCONSTR_NAME ?name c >>= fun name ->
Goal.enter_one ~__LOC__ begin fun g ->
let sigma, env = Goal.sigma g, Goal.env g in
if name <> Names.Name.Anonymous || EConstr.Vars.noccurn sigma 1 cl
then tclUNIT (EConstr.mkProd (name, t, cl))
else
let name = Names.Id.of_string (Namegen.hdchar env sigma t) in
tclUNIT (EConstr.mkProd (Names.Name.Name name, t, cl))
end
let tacINTERP_CPATTERN cp =
tacSIGMA >>= begin fun gl ->
tclUNIT (Ssrmatching.interp_cpattern gl cp None)
end
let tacUNIFY a b =
tacSIGMA >>= begin fun gl ->
let gl = Ssrmatching.pf_unify_HO gl a b in
Unsafe.tclEVARS (Tacmach.project gl)
end
let tclOPTION o d =
match o with
| None -> d >>= tclUNIT
| Some x -> tclUNIT x
let tacIS_INJECTION_CASE ?ty t = begin
tclOPTION ty (tacTYPEOF t) >>= fun ty ->
tacREDUCE_TO_QUANTIFIED_IND ty >>= fun ((mind,_),_) ->
tclUNIT (Globnames.eq_gr (Globnames.IndRef mind) (Coqlib.build_coq_eq ()))
end
let tclWITHTOP tac = Goal.enter begin fun gl ->
let top =
mk_anon_id "top_assumption" (Tacmach.New.pf_ids_of_hyps gl) in
tclINTRO_ID top <*>
tac (EConstr.mkVar top) <*>
Tactics.clear [top]
end
let tacMK_SSR_CONST name = Goal.enter_one ~__LOC__ begin fun g ->
let sigma, env = Goal.(sigma g, env g) in
let sigma, c = mkSsrConst name env sigma in
Unsafe.tclEVARS sigma <*>
tclUNIT c
end
module type StateType = sig
type state
val init : state
end
module MakeState(S : StateType) = struct
let state_field : S.state Proofview_monad.StateStore.field =
Proofview_monad.StateStore.field ()
(* FIXME: should not inject fresh_state, but initialize it at the beginning *)
let lift_upd_state upd s =
let open Proofview_monad.StateStore in
let old_state = Option.default S.init (get s state_field) in
upd old_state >>= fun new_state ->
tclUNIT (set s state_field new_state)
let tacUPDATE upd = Goal.enter begin fun gl ->
let s0 = Goal.state gl in
Goal.enter_one ~__LOC__ (fun _ -> lift_upd_state upd s0) >>= fun s ->
Unsafe.tclGETGOALS >>= fun gls ->
let gls = List.map (fun gs ->
let g = Proofview_monad.drop_state gs in
Proofview_monad.goal_with_state g s) gls in
Unsafe.tclSETGOALS gls
end
let tclGET k = Goal.enter begin fun gl ->
let open Proofview_monad.StateStore in
k (Option.default S.init (get (Goal.state gl) state_field))
end
let tclSET new_s =
let open Proofview_monad.StateStore in
Unsafe.tclGETGOALS >>= fun gls ->
let gls = List.map (fun gs ->
let g = Proofview_monad.drop_state gs in
let s = Proofview_monad.get_state gs in
Proofview_monad.goal_with_state g (set s state_field new_s)) gls in
Unsafe.tclSETGOALS gls
let get g =
Option.default S.init
(Proofview_monad.StateStore.get (Goal.state g) state_field)
end
(* vim: set filetype=ocaml foldmethod=marker: *)
|