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(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015     *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(* Author: Jean-Christophe Filliâtre as part of the rebuilding of Coq
   around a purely functional abstract type-checker, Aug 1999 *)
(* Cleaning and lightening of the kernel by Bruno Barras, Nov 2001 *)
(* Flag for predicativity of Set by Hugo Herbelin in Oct 2003 *)
(* Support for virtual machine by Benjamin Grégoire in Oct 2004 *)
(* Support for retroknowledge by Arnaud Spiwack in May 2007 *)
(* Support for assumption dependencies by Arnaud Spiwack in May 2007 *)

(* Miscellaneous maintenance by Bruno Barras, Hugo Herbelin, Jean-Marc
   Notin, Matthieu Sozeau *)

(* This file defines the type of environments on which the
   type-checker works, together with simple related functions *)

open Errors
open Util
open Names
open Term
open Context
open Vars
open Declarations
open Pre_env

(* The type of environments. *)

type named_context_val = Pre_env.named_context_val

type env = Pre_env.env

let pre_env env = env
let env_of_pre_env env = env
let oracle env = env.env_conv_oracle
let set_oracle env o = { env with env_conv_oracle = o }

let empty_named_context_val = empty_named_context_val

let empty_env = empty_env

let engagement env = env.env_stratification.env_engagement

let is_impredicative_set env = 
  match fst (engagement env) with
  | ImpredicativeSet -> true
  | _ -> false

let type_in_type env =
  match snd (engagement env) with
  | TypeInType -> true
  | _ -> false

let universes env = env.env_stratification.env_universes
let named_context env = env.env_named_context
let named_context_val env = env.env_named_context,env.env_named_vals
let rel_context env = env.env_rel_context
let opaque_tables env = env.indirect_pterms
let set_opaque_tables env indirect_pterms = { env with indirect_pterms }

let empty_context env =
  match env.env_rel_context, env.env_named_context with
  | [], [] -> true
  | _ -> false

(* Rel context *)
let lookup_rel n env =
  lookup_rel n env.env_rel_context

let evaluable_rel n env =
  match lookup_rel n env with
  | (_,Some _,_) -> true
  | _ -> false

let nb_rel env = env.env_nb_rel

let push_rel = push_rel

let push_rel_context ctxt x = Context.fold_rel_context push_rel ctxt ~init:x

let push_rec_types (lna,typarray,_) env =
  let ctxt = Array.map2_i (fun i na t -> (na, None, lift i t)) lna typarray in
  Array.fold_left (fun e assum -> push_rel assum e) env ctxt

let fold_rel_context f env ~init =
  let rec fold_right env =
    match env.env_rel_context with
    | [] -> init
    | rd::rc ->
	let env =
	  { env with
	    env_rel_context = rc;
	    env_rel_val = List.tl env.env_rel_val;
	    env_nb_rel = env.env_nb_rel - 1 } in
	f env rd (fold_right env)
  in fold_right env

(* Named context *)

let named_context_of_val = fst
let named_vals_of_val = snd

(* [map_named_val f ctxt] apply [f] to the body and the type of
   each declarations.
   *** /!\ ***   [f t] should be convertible with t *)
let map_named_val f (ctxt,ctxtv) =
  let rec map ctx = match ctx with
  | [] -> []
  | (id, body, typ) :: rem ->
    let body' = Option.smartmap f body in
    let typ' = f typ in
    let rem' = map rem in
    if body' == body && typ' == typ && rem' == rem then ctx
    else (id, body', typ') :: rem'
  in
  (map ctxt, ctxtv)

let empty_named_context = empty_named_context

let push_named = push_named
let push_named_context = List.fold_right push_named
let push_named_context_val = push_named_context_val

let val_of_named_context ctxt =
  List.fold_right push_named_context_val ctxt empty_named_context_val


let lookup_named id env = Context.lookup_named id env.env_named_context
let lookup_named_val id (ctxt,_) = Context.lookup_named id ctxt

let eq_named_context_val c1 c2 =
   c1 == c2 || named_context_equal (named_context_of_val c1) (named_context_of_val c2)

(* A local const is evaluable if it is defined  *)

let named_type id env =
  let (_,_,t) = lookup_named id env in t

let named_body id env =
  let (_,b,_) = lookup_named id env in b

let evaluable_named id env =
  match named_body id env with
  | Some _      -> true
  | _          -> false

let reset_with_named_context (ctxt,ctxtv) env =
  { env with
    env_named_context = ctxt;
    env_named_vals = ctxtv;
    env_rel_context = empty_rel_context;
    env_rel_val = [];
    env_nb_rel = 0 }

let reset_context = reset_with_named_context empty_named_context_val

let pop_rel_context n env =
  let ctxt = env.env_rel_context in
  { env with
    env_rel_context = List.skipn n ctxt;
    env_nb_rel = env.env_nb_rel - n }

let fold_named_context f env ~init =
  let rec fold_right env =
    match env.env_named_context with
    | [] -> init
    | d::ctxt ->
	let env =
	  reset_with_named_context (ctxt,List.tl env.env_named_vals) env in
	f env d (fold_right env)
  in fold_right env

let fold_named_context_reverse f ~init env =
  Context.fold_named_context_reverse f ~init:init (named_context env)


(* Universe constraints *)

let map_universes f env =
  let s = env.env_stratification in
    { env with env_stratification =
	 { s with env_universes = f s.env_universes } }
				     
let add_constraints c env =
  if Univ.Constraint.is_empty c then env
  else map_universes (Univ.merge_constraints c) env

let check_constraints c env =
  Univ.check_constraints c env.env_stratification.env_universes

let push_constraints_to_env (_,univs) env =
  add_constraints univs env

let add_universes strict ctx g =
  let g = Array.fold_left
	    (* Be lenient, module typing reintroduces universes and constraints due to includes *)
	    (fun g v -> try Univ.add_universe v strict g with Univ.AlreadyDeclared -> g)
	    g (Univ.Instance.to_array (Univ.UContext.instance ctx))
  in
    Univ.merge_constraints (Univ.UContext.constraints ctx) g
			   
let push_context ?(strict=false) ctx env =
  map_universes (add_universes strict ctx) env

let add_universes_set strict ctx g =
  let g = Univ.LSet.fold
	    (fun v g -> try Univ.add_universe v strict g with Univ.AlreadyDeclared -> g)
	    (Univ.ContextSet.levels ctx) g
  in Univ.merge_constraints (Univ.ContextSet.constraints ctx) g

let push_context_set ?(strict=false) ctx env =
  map_universes (add_universes_set strict ctx) env

let set_engagement c env = (* Unsafe *)
  { env with env_stratification =
    { env.env_stratification with env_engagement = c } }

(* Global constants *)

let lookup_constant = lookup_constant

let no_link_info = NotLinked

let add_constant_key kn cb linkinfo env =
  let new_constants =
    Cmap_env.add kn (cb,(ref linkinfo, ref None)) env.env_globals.env_constants in
  let new_globals =
    { env.env_globals with
	env_constants = new_constants } in
  { env with env_globals = new_globals }

let add_constant kn cb env =
  add_constant_key kn cb no_link_info env

let constraints_of cb u =
  let univs = cb.const_universes in
    Univ.subst_instance_constraints u (Univ.UContext.constraints univs)

let map_regular_arity f = function
  | RegularArity a as ar -> 
    let a' = f a in 
      if a' == a then ar else RegularArity a'
  | TemplateArity _ -> assert false

(* constant_type gives the type of a constant *)
let constant_type env (kn,u) =
  let cb = lookup_constant kn env in
    if cb.const_polymorphic then
      let csts = constraints_of cb u in
	(map_regular_arity (subst_instance_constr u) cb.const_type, csts)
    else cb.const_type, Univ.Constraint.empty

let constant_context env kn =
  let cb = lookup_constant kn env in
    if cb.const_polymorphic then cb.const_universes
    else Univ.UContext.empty

type const_evaluation_result = NoBody | Opaque | IsProj

exception NotEvaluableConst of const_evaluation_result

let constant_value env (kn,u) =
  let cb = lookup_constant kn env in
    if cb.const_proj = None then
      match cb.const_body with
      | Def l_body -> 
	if cb.const_polymorphic then
	  let csts = constraints_of cb u in
	    (subst_instance_constr u (Mod_subst.force_constr l_body), csts)
	else Mod_subst.force_constr l_body, Univ.Constraint.empty
      | OpaqueDef _ -> raise (NotEvaluableConst Opaque)
      | Undef _ -> raise (NotEvaluableConst NoBody)
    else raise (NotEvaluableConst IsProj)

let constant_opt_value env cst =
  try Some (constant_value env cst)
  with NotEvaluableConst _ -> None

let constant_value_and_type env (kn, u) =
  let cb = lookup_constant kn env in
    if cb.const_polymorphic then
      let cst = constraints_of cb u in
      let b' = match cb.const_body with
	| Def l_body -> Some (subst_instance_constr u (Mod_subst.force_constr l_body))
	| OpaqueDef _ -> None
	| Undef _ -> None
      in
	b', map_regular_arity (subst_instance_constr u) cb.const_type, cst
    else 
      let b' = match cb.const_body with
	| Def l_body -> Some (Mod_subst.force_constr l_body)
	| OpaqueDef _ -> None
	| Undef _ -> None
      in b', cb.const_type, Univ.Constraint.empty

(* These functions should be called under the invariant that [env] 
   already contains the constraints corresponding to the constant 
   application. *)

(* constant_type gives the type of a constant *)
let constant_type_in env (kn,u) =
  let cb = lookup_constant kn env in
    if cb.const_polymorphic then
      map_regular_arity (subst_instance_constr u) cb.const_type
    else cb.const_type

let constant_value_in env (kn,u) =
  let cb = lookup_constant kn env in
  match cb.const_body with
    | Def l_body -> 
      let b = Mod_subst.force_constr l_body in
	subst_instance_constr u b
    | OpaqueDef _ -> raise (NotEvaluableConst Opaque)
    | Undef _ -> raise (NotEvaluableConst NoBody)

let constant_opt_value_in env cst =
  try Some (constant_value_in env cst)
  with NotEvaluableConst _ -> None

(* A global const is evaluable if it is defined and not opaque *)
let evaluable_constant kn env =
  let cb = lookup_constant kn env in
    match cb.const_body with
    | Def _ -> true
    | OpaqueDef _ -> false
    | Undef _ -> false

let polymorphic_constant cst env =
  (lookup_constant cst env).const_polymorphic

let polymorphic_pconstant (cst,u) env =
  if Univ.Instance.is_empty u then false
  else polymorphic_constant cst env

let template_polymorphic_constant cst env =
  match (lookup_constant cst env).const_type with 
  | TemplateArity _ -> true
  | RegularArity _ -> false

let template_polymorphic_pconstant (cst,u) env =
  if not (Univ.Instance.is_empty u) then false
  else template_polymorphic_constant cst env

let lookup_projection cst env =
  match (lookup_constant (Projection.constant cst) env).const_proj with 
  | Some pb -> pb
  | None -> anomaly (Pp.str "lookup_projection: constant is not a projection")

let is_projection cst env =
  match (lookup_constant cst env).const_proj with 
  | Some _ -> true
  | None -> false

(* Mutual Inductives *)
let lookup_mind = lookup_mind

let polymorphic_ind (mind,i) env =
  (lookup_mind mind env).mind_polymorphic

let polymorphic_pind (ind,u) env =
  if Univ.Instance.is_empty u then false
  else polymorphic_ind ind env

let template_polymorphic_ind (mind,i) env =
  match (lookup_mind mind env).mind_packets.(i).mind_arity with 
  | TemplateArity _ -> true
  | RegularArity _ -> false

let template_polymorphic_pind (ind,u) env =
  if not (Univ.Instance.is_empty u) then false
  else template_polymorphic_ind ind env
  
let add_mind_key kn mind_key env =
  let new_inds = Mindmap_env.add kn mind_key env.env_globals.env_inductives in
  let new_globals =
    { env.env_globals with
	env_inductives = new_inds } in
  { env with env_globals = new_globals }

let add_mind kn mib env =
  let li = ref no_link_info in add_mind_key kn (mib, li) env

(* Lookup of section variables *)

let lookup_constant_variables c env =
  let cmap = lookup_constant c env in
  Context.vars_of_named_context cmap.const_hyps

let lookup_inductive_variables (kn,i) env =
  let mis = lookup_mind kn env in
  Context.vars_of_named_context mis.mind_hyps

let lookup_constructor_variables (ind,_) env =
  lookup_inductive_variables ind env

(* Returns the list of global variables in a term *)

let vars_of_global env constr =
  match kind_of_term constr with
      Var id -> Id.Set.singleton id
    | Const (kn, _) -> lookup_constant_variables kn env
    | Ind (ind, _) -> lookup_inductive_variables ind env
    | Construct (cstr, _) -> lookup_constructor_variables cstr env
    (** FIXME: is Proj missing? *)
    | _ -> raise Not_found

let global_vars_set env constr =
  let rec filtrec acc c =
    let acc =
      match kind_of_term c with
      | Var _ | Const _ | Ind _ | Construct _ ->
	  Id.Set.union (vars_of_global env c) acc
      | _ ->
	  acc in
    fold_constr filtrec acc c
  in
    filtrec Id.Set.empty constr


(* [keep_hyps env ids] keeps the part of the section context of [env] which
   contains the variables of the set [ids], and recursively the variables
   contained in the types of the needed variables. *)

let really_needed env needed =
  Context.fold_named_context_reverse
    (fun need (id,copt,t) ->
      if Id.Set.mem id need then
        let globc =
          match copt with
            | None -> Id.Set.empty
            | Some c -> global_vars_set env c in
        Id.Set.union
          (global_vars_set env t)
          (Id.Set.union globc need)
      else need)
    ~init:needed
    (named_context env)

let keep_hyps env needed =
  let really_needed = really_needed env needed in
  Context.fold_named_context
    (fun (id,_,_ as d) nsign ->
      if Id.Set.mem id really_needed then add_named_decl d nsign
      else nsign)
    (named_context env)
    ~init:empty_named_context

(* Modules *)

let add_modtype mtb env =
  let mp = mtb.mod_mp in
  let new_modtypes = MPmap.add mp mtb env.env_globals.env_modtypes in
  let new_globals = { env.env_globals with env_modtypes = new_modtypes } in
  { env with env_globals = new_globals }

let shallow_add_module mb env =
  let mp = mb.mod_mp in
  let new_mods = MPmap.add mp mb env.env_globals.env_modules in
  let new_globals = { env.env_globals with env_modules = new_mods } in
  { env with env_globals = new_globals }

let lookup_module mp env =
    MPmap.find mp env.env_globals.env_modules


let lookup_modtype mp env = 
  MPmap.find mp env.env_globals.env_modtypes

(*s Judgments. *)

type unsafe_judgment = {
  uj_val : constr;
  uj_type : types }

let make_judge v tj =
  { uj_val = v;
    uj_type = tj }

let j_val j = j.uj_val
let j_type j = j.uj_type

type unsafe_type_judgment = {
  utj_val : constr;
  utj_type : sorts }

(*s Compilation of global declaration *)

let compile_constant_body = Cbytegen.compile_constant_body false

exception Hyp_not_found

let apply_to_hyp (ctxt,vals) id f =
  let rec aux rtail ctxt vals =
    match ctxt, vals with
    | (idc,c,ct as d)::ctxt, v::vals ->
	if Id.equal idc id then
	  (f ctxt d rtail)::ctxt, v::vals
	else
	  let ctxt',vals' = aux (d::rtail) ctxt vals in
	  d::ctxt', v::vals'
    | [],[] -> raise Hyp_not_found
    | _, _ -> assert false
  in aux [] ctxt vals

let apply_to_hyp_and_dependent_on (ctxt,vals) id f g =
  let rec aux ctxt vals =
    match ctxt,vals with
    | (idc,c,ct as d)::ctxt, v::vals ->
	if Id.equal idc id then
	  let sign = ctxt,vals in
	  push_named_context_val (f d sign) sign
	else
	  let (ctxt,vals as sign) = aux ctxt vals in
	  push_named_context_val (g d sign) sign
    | [],[] -> raise Hyp_not_found
    | _,_ -> assert false
  in aux ctxt vals

let insert_after_hyp (ctxt,vals) id d check =
  let rec aux ctxt vals =
    match  ctxt, vals with
    | (idc,c,ct)::ctxt', v::vals' ->
	if Id.equal idc id then begin
	  check ctxt;
	  push_named_context_val d (ctxt,vals)
	end else
	  let ctxt,vals = aux ctxt vals in
	  d::ctxt, v::vals
    | [],[] -> raise Hyp_not_found
    | _, _ -> assert false
  in aux ctxt vals


(* To be used in Logic.clear_hyps *)
let remove_hyps ids check_context check_value (ctxt, vals) =
  let rec remove_hyps ctxt vals = match ctxt, vals with
  | [], [] -> [], []
  | d :: rctxt, (nid, v) :: rvals ->
    let (id, _, _) = d in
    let ans = remove_hyps rctxt rvals in
    if Id.Set.mem id ids then ans
    else
      let (rctxt', rvals') = ans in
      let d' = check_context d in
      let v' = check_value v in
      if d == d' && v == v' && rctxt == rctxt' && rvals == rvals' then
        ctxt, vals
      else (d' :: rctxt', (nid, v') :: rvals')
  | _ -> assert false
  in
  remove_hyps ctxt vals

(*spiwack: the following functions assemble the pieces of the retroknowledge
   note that the "consistent" register function is available in the module
   Safetyping, Environ only synchronizes the proactive and the reactive parts*)

open Retroknowledge

(* lifting of the "get" functions works also for "mem"*)
let retroknowledge f env =
  f env.retroknowledge

let registered env field =
    retroknowledge mem env field

let register_one env field entry =
  { env with retroknowledge = Retroknowledge.add_field env.retroknowledge field entry }

(* [register env field entry] may register several fields when needed *)
let register env field entry =
  match field with
    | KInt31 (grp, Int31Type) ->
        let i31c = match kind_of_term entry with
                     | Ind i31t -> mkConstructUi (i31t, 1)
		     | _ -> anomaly ~label:"Environ.register" (Pp.str "should be an inductive type")
	in
        register_one (register_one env (KInt31 (grp,Int31Constructor)) i31c) field entry
    | field -> register_one env field entry

(* the Environ.register function syncrhonizes the proactive and reactive
   retroknowledge. *)
let dispatch =

  (* subfunction used for static decompilation of int31 (after a vm_compute,
     see pretyping/vnorm.ml for more information) *)
  let constr_of_int31 =
    let nth_digit_plus_one i n = (* calculates the nth (starting with 0)
                                    digit of i and adds 1 to it
                                    (nth_digit_plus_one 1 3 = 2) *)
      if Int.equal (i land (1 lsl n)) 0 then
        1
      else
        2
    in
      fun ind -> fun digit_ind -> fun tag ->
	let array_of_int i =
	  Array.init 31 (fun n -> mkConstruct
			   (digit_ind, nth_digit_plus_one i (30-n)))
	in
	  mkApp(mkConstruct(ind, 1), array_of_int tag)
  in

  (* subfunction which dispatches the compiling information of an
     int31 operation which has a specific vm instruction (associates
     it to the name of the coq definition in the reactive retroknowledge) *)
  let int31_op n op prim kn =
    { empty_reactive_info with
      vm_compiling = Some (Cbytegen.op_compilation n op kn);
      native_compiling = Some (Nativelambda.compile_prim prim (Univ.out_punivs kn));
    }
  in

fun rk value field ->
  (* subfunction which shortens the (very common) dispatch of operations *)
  let int31_op_from_const n op prim =
    match kind_of_term value with
      | Const kn ->  int31_op n op prim kn
      | _ -> anomaly ~label:"Environ.register" (Pp.str "should be a constant")
  in
  let int31_binop_from_const op prim = int31_op_from_const 2 op prim in
  let int31_unop_from_const op prim = int31_op_from_const 1 op prim in
  match field with
    | KInt31 (grp, Int31Type) ->
        let int31bit =
          (* invariant : the type of bits is registered, otherwise the function
             would raise Not_found. The invariant is enforced in safe_typing.ml *)
          match field with
          | KInt31 (grp, Int31Type) -> Retroknowledge.find rk (KInt31 (grp,Int31Bits))
          | _ -> anomaly ~label:"Environ.register"
              (Pp.str "add_int31_decompilation_from_type called with an abnormal field")
        in
        let i31bit_type =
          match kind_of_term int31bit with
          | Ind (i31bit_type,_) -> i31bit_type
          |  _ -> anomaly ~label:"Environ.register"
              (Pp.str "Int31Bits should be an inductive type")
        in
        let int31_decompilation =
          match kind_of_term value with
          | Ind (i31t,_) ->
              constr_of_int31 i31t i31bit_type
          | _ -> anomaly ~label:"Environ.register"
              (Pp.str "should be an inductive type")
        in
        { empty_reactive_info with
          vm_decompile_const = Some int31_decompilation;
          vm_before_match = Some Cbytegen.int31_escape_before_match;
          native_before_match = Some (Nativelambda.before_match_int31 i31bit_type);
        }
    | KInt31 (_, Int31Constructor) ->
        { empty_reactive_info with
          vm_constant_static = Some Cbytegen.compile_structured_int31;
          vm_constant_dynamic = Some Cbytegen.dynamic_int31_compilation;
          native_constant_static = Some Nativelambda.compile_static_int31;
          native_constant_dynamic = Some Nativelambda.compile_dynamic_int31;
        }
    | KInt31 (_, Int31Plus) -> int31_binop_from_const Cbytecodes.Kaddint31
							  Primitives.Int31add
    | KInt31 (_, Int31PlusC) -> int31_binop_from_const Cbytecodes.Kaddcint31
							   Primitives.Int31addc
    | KInt31 (_, Int31PlusCarryC) -> int31_binop_from_const Cbytecodes.Kaddcarrycint31
								Primitives.Int31addcarryc
    | KInt31 (_, Int31Minus) -> int31_binop_from_const Cbytecodes.Ksubint31
							   Primitives.Int31sub
    | KInt31 (_, Int31MinusC) -> int31_binop_from_const Cbytecodes.Ksubcint31
							    Primitives.Int31subc
    | KInt31 (_, Int31MinusCarryC) -> int31_binop_from_const
	                                Cbytecodes.Ksubcarrycint31 Primitives.Int31subcarryc
    | KInt31 (_, Int31Times) -> int31_binop_from_const Cbytecodes.Kmulint31
							   Primitives.Int31mul
    | KInt31 (_, Int31TimesC) -> int31_binop_from_const Cbytecodes.Kmulcint31
							   Primitives.Int31mulc
    | KInt31 (_, Int31Div21) -> int31_op_from_const 3 Cbytecodes.Kdiv21int31
                                                           Primitives.Int31div21
    | KInt31 (_, Int31Diveucl) -> int31_binop_from_const Cbytecodes.Kdivint31
							 Primitives.Int31diveucl
    | KInt31 (_, Int31AddMulDiv) -> int31_op_from_const 3 Cbytecodes.Kaddmuldivint31
                                                         Primitives.Int31addmuldiv
    | KInt31 (_, Int31Compare) -> int31_binop_from_const Cbytecodes.Kcompareint31
							     Primitives.Int31compare
    | KInt31 (_, Int31Head0) -> int31_unop_from_const Cbytecodes.Khead0int31
							  Primitives.Int31head0
    | KInt31 (_, Int31Tail0) -> int31_unop_from_const Cbytecodes.Ktail0int31
							  Primitives.Int31tail0
    | KInt31 (_, Int31Lor) -> int31_binop_from_const Cbytecodes.Klorint31
							 Primitives.Int31lor
    | KInt31 (_, Int31Land) -> int31_binop_from_const Cbytecodes.Klandint31
							  Primitives.Int31land
    | KInt31 (_, Int31Lxor) -> int31_binop_from_const Cbytecodes.Klxorint31
							  Primitives.Int31lxor
    | _ -> empty_reactive_info

let _ = Hook.set Retroknowledge.dispatch_hook dispatch