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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) *)
(************************************************************************)
(* $Id$ *)
open Names
open Constr
type tag = int
val accu_tag : tag
val type_atom_tag : tag
val max_atom_tag : tag
val proj_tag : tag
val fix_app_tag : tag
val switch_tag : tag
val cofix_tag : tag
val cofix_evaluated_tag : tag
val last_variant_tag : tag
type structured_constant =
| Const_sort of Sorts.t
| Const_ind of inductive
| Const_proj of Constant.t
| Const_b0 of tag
| Const_bn of tag * structured_constant array
| Const_univ_level of Univ.Level.t
val pp_struct_const : structured_constant -> Pp.t
type reloc_table = (tag * int) array
type annot_switch =
{ci : case_info; rtbl : reloc_table; tailcall : bool; max_stack_size : int}
val eq_structured_constant : structured_constant -> structured_constant -> bool
val hash_structured_constant : structured_constant -> int
val eq_annot_switch : annot_switch -> annot_switch -> bool
val hash_annot_switch : annot_switch -> int
module Label :
sig
type t = int
val no : t
val create : unit -> t
val reset_label_counter : unit -> unit
end
type instruction =
| Klabel of Label.t
| Kacc of int (** accu = sp[n] *)
| Kenvacc of int (** accu = coq_env[n] *)
| Koffsetclosure of int (** accu = &coq_env[n] *)
| Kpush (** sp = accu :: sp *)
| Kpop of int (** sp = skipn n sp *)
| Kpush_retaddr of Label.t (** sp = pc :: coq_env :: coq_extra_args :: sp ; coq_extra_args = 0 *)
| Kapply of int (** number of arguments (arguments on top of stack) *)
| Kappterm of int * int (** number of arguments, slot size *)
| Kreturn of int (** slot size *)
| Kjump
| Krestart
| Kgrab of int (** number of arguments *)
| Kgrabrec of int (** rec arg *)
| Kclosure of Label.t * int (** label, number of free variables *)
| Kclosurerec of int * int * Label.t array * Label.t array
(** nb fv, init, lbl types, lbl bodies *)
| Kclosurecofix of int * int * Label.t array * Label.t array
(** nb fv, init, lbl types, lbl bodies *)
| Kgetglobal of Constant.t
| Kconst of structured_constant
| Kmakeblock of (* size: *) int * tag (** allocate an ocaml block. Index 0
** is accu, all others are popped from
** the top of the stack *)
| Kmakeprod
| Kmakeswitchblock of Label.t * Label.t * annot_switch * int
| Kswitch of Label.t array * Label.t array (** consts,blocks *)
| Kpushfields of int
| Kfield of int (** accu = accu[n] *)
| Ksetfield of int (** accu[n] = sp[0] ; sp = pop sp *)
| Kstop
| Ksequence of bytecodes * bytecodes
| Kproj of int * Constant.t (** index of the projected argument,
name of projection *)
| Kensurestackcapacity of int
(** spiwack: instructions concerning integers *)
| Kbranch of Label.t (** jump to label, is it needed ? *)
| Kaddint31 (** adds the int31 in the accu
and the one ontop of the stack *)
| Kaddcint31 (** makes the sum and keeps the carry *)
| Kaddcarrycint31 (** sum +1, keeps the carry *)
| Ksubint31 (** subtraction modulo *)
| Ksubcint31 (** subtraction, keeps the carry *)
| Ksubcarrycint31 (** subtraction -1, keeps the carry *)
| Kmulint31 (** multiplication modulo *)
| Kmulcint31 (** multiplication, result in two
int31, for exact computation *)
| Kdiv21int31 (** divides a double size integer
(represented by an int31 in the
accumulator and one on the top of
the stack) by an int31. The result
is a pair of the quotient and the
rest.
If the divisor is 0, it returns
0. *)
| Kdivint31 (** euclidian division (returns a pair
quotient,rest) *)
| Kaddmuldivint31 (** generic operation for shifting and
cycling. Takes 3 int31 i j and s,
and returns x*2^s+y/(2^(31-s) *)
| Kcompareint31 (** unsigned comparison of int31
cf COMPAREINT31 in
kernel/byterun/coq_interp.c
for more info *)
| Khead0int31 (** Give the numbers of 0 in head of a in31*)
| Ktail0int31 (** Give the numbers of 0 in tail of a in31
ie low bits *)
| Kisconst of Label.t (** conditional jump *)
| Kareconst of int*Label.t (** conditional jump *)
| Kcompint31 (** dynamic compilation of int31 *)
| Kdecompint31 (** dynamix decompilation of int31 *)
| Klorint31 (** bitwise operations: or and xor *)
| Klandint31
| Klxorint31
and bytecodes = instruction list
type fv_elem =
FVnamed of Id.t
| FVrel of int
| FVuniv_var of int
| FVevar of Evar.t
type fv = fv_elem array
(** spiwack: this exception is expected to be raised by function expecting
closed terms. *)
exception NotClosed
module FvMap : Map.S with type key = fv_elem
(*spiwack: both type have been moved from Cbytegen because I needed them
for the retroknowledge *)
type vm_env = {
size : int; (** length of the list [n] *)
fv_rev : fv_elem list; (** [fvn; ... ;fv1] *)
fv_fwd : int FvMap.t; (** reverse mapping *)
}
type comp_env = {
nb_uni_stack : int ; (** number of universes on the stack *)
nb_stack : int; (** number of variables on the stack *)
in_stack : int list; (** position in the stack *)
nb_rec : int; (** number of mutually recursive functions *)
(** (= nbr) *)
pos_rec : instruction list; (** instruction d'acces pour les variables *)
(** de point fix ou de cofix *)
offset : int;
in_env : vm_env ref (** the variables that are accessed *)
}
val pp_bytecodes : bytecodes -> Pp.t
val pp_fv_elem : fv_elem -> Pp.t
|