(***********************************************************************) (* *) (* Objective Caml *) (* *) (* Xavier Leroy, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* en Automatique. All rights reserved. This file is distributed *) (* under the terms of the Q Public License version 1.0. *) (* *) (***********************************************************************) (* $Id$ *) open Misc open Path open Asttypes type primitive = Pidentity | Pignore (* Globals *) | Pgetglobal of Ident.t | Psetglobal of Ident.t (* Operations on heap blocks *) | Pmakeblock of int * mutable_flag | Pfield of int | Psetfield of int * bool | Pfloatfield of int | Psetfloatfield of int | Pduprecord of Types.record_representation * int (* External call *) | Pccall of Primitive.description (* Exceptions *) | Praise (* Boolean operations *) | Psequand | Psequor | Pnot (* Integer operations *) | Pnegint | Paddint | Psubint | Pmulint | Pdivint | Pmodint | Pandint | Porint | Pxorint | Plslint | Plsrint | Pasrint | Pintcomp of comparison | Poffsetint of int | Poffsetref of int (* Float operations *) | Pintoffloat | Pfloatofint | Pnegfloat | Pabsfloat | Paddfloat | Psubfloat | Pmulfloat | Pdivfloat | Pfloatcomp of comparison (* String operations *) | Pstringlength | Pstringrefu | Pstringsetu | Pstringrefs | Pstringsets (* Array operations *) | Pmakearray of array_kind | Parraylength of array_kind | Parrayrefu of array_kind | Parraysetu of array_kind | Parrayrefs of array_kind | Parraysets of array_kind (* Test if the argument is a block or an immediate integer *) | Pisint (* Test if the (integer) argument is outside an interval *) | Pisout (* Bitvect operations *) | Pbittest (* Operations on boxed integers (Nativeint.t, Int32.t, Int64.t) *) | Pbintofint of boxed_integer | Pintofbint of boxed_integer | Pcvtbint of boxed_integer (*source*) * boxed_integer (*destination*) | Pnegbint of boxed_integer | Paddbint of boxed_integer | Psubbint of boxed_integer | Pmulbint of boxed_integer | Pdivbint of boxed_integer | Pmodbint of boxed_integer | Pandbint of boxed_integer | Porbint of boxed_integer | Pxorbint of boxed_integer | Plslbint of boxed_integer | Plsrbint of boxed_integer | Pasrbint of boxed_integer | Pbintcomp of boxed_integer * comparison (* Operations on big arrays *) | Pbigarrayref of int * bigarray_kind * bigarray_layout | Pbigarrayset of int * bigarray_kind * bigarray_layout and comparison = Ceq | Cneq | Clt | Cgt | Cle | Cge and array_kind = Pgenarray | Paddrarray | Pintarray | Pfloatarray and boxed_integer = Pnativeint | Pint32 | Pint64 and bigarray_kind = Pbigarray_unknown | Pbigarray_float32 | Pbigarray_float64 | Pbigarray_sint8 | Pbigarray_uint8 | Pbigarray_sint16 | Pbigarray_uint16 | Pbigarray_int32 | Pbigarray_int64 | Pbigarray_caml_int | Pbigarray_native_int | Pbigarray_complex32 | Pbigarray_complex64 and bigarray_layout = Pbigarray_unknown_layout | Pbigarray_c_layout | Pbigarray_fortran_layout type structured_constant = Const_base of constant | Const_pointer of int | Const_block of int * structured_constant list | Const_float_array of string list | Const_immstring of string type function_kind = Curried | Tupled type let_kind = Strict | Alias | StrictOpt | Variable type meth_kind = Self | Public | Cached type shared_code = (int * int) list type lambda = Lvar of Ident.t | Lconst of structured_constant | Lapply of lambda * lambda list * Location.t | Lfunction of function_kind * Ident.t list * lambda | Llet of let_kind * Ident.t * lambda * lambda | Lletrec of (Ident.t * lambda) list * lambda | Lprim of primitive * lambda list | Lswitch of lambda * lambda_switch | Lstaticraise of int * lambda list | Lstaticcatch of lambda * (int * Ident.t list) * lambda | Ltrywith of lambda * Ident.t * lambda | Lifthenelse of lambda * lambda * lambda | Lsequence of lambda * lambda | Lwhile of lambda * lambda | Lfor of Ident.t * lambda * lambda * direction_flag * lambda | Lassign of Ident.t * lambda | Lsend of meth_kind * lambda * lambda * lambda list | Levent of lambda * lambda_event | Lifused of Ident.t * lambda and lambda_switch = { sw_numconsts: int; sw_consts: (int * lambda) list; sw_numblocks: int; sw_blocks: (int * lambda) list; sw_failaction : lambda option} and lambda_event = { lev_loc: Location.t; lev_kind: lambda_event_kind; lev_repr: int ref option; lev_env: Env.summary } and lambda_event_kind = Lev_before | Lev_after of Types.type_expr | Lev_function let const_unit = Const_pointer 0 let lambda_unit = Lconst const_unit let rec same l1 l2 = match (l1, l2) with | Lvar v1, Lvar v2 -> Ident.same v1 v2 | Lconst c1, Lconst c2 -> c1 = c2 | Lapply(a1, bl1, _), Lapply(a2, bl2, _) -> same a1 a2 && samelist same bl1 bl2 | Lfunction(k1, idl1, a1), Lfunction(k2, idl2, a2) -> k1 = k2 && samelist Ident.same idl1 idl2 && same a1 a2 | Llet(k1, id1, a1, b1), Llet(k2, id2, a2, b2) -> k1 = k2 && Ident.same id1 id2 && same a1 a2 && same b1 b2 | Lletrec (bl1, a1), Lletrec (bl2, a2) -> samelist samebinding bl1 bl2 && same a1 a2 | Lprim(p1, al1), Lprim(p2, al2) -> p1 = p2 && samelist same al1 al2 | Lswitch(a1, s1), Lswitch(a2, s2) -> same a1 a2 && sameswitch s1 s2 | Lstaticraise(n1, al1), Lstaticraise(n2, al2) -> n1 = n2 && samelist same al1 al2 | Lstaticcatch(a1, (n1, idl1), b1), Lstaticcatch(a2, (n2, idl2), b2) -> same a1 a2 && n1 = n2 && samelist Ident.same idl1 idl2 && same b1 b2 | Ltrywith(a1, id1, b1), Ltrywith(a2, id2, b2) -> same a1 a2 && Ident.same id1 id2 && same b1 b2 | Lifthenelse(a1, b1, c1), Lifthenelse(a2, b2, c2) -> same a1 a2 && same b1 b2 && same c1 c2 | Lsequence(a1, b1), Lsequence(a2, b2) -> same a1 a2 && same b1 b2 | Lwhile(a1, b1), Lwhile(a2, b2) -> same a1 a2 && same b1 b2 | Lfor(id1, a1, b1, df1, c1), Lfor(id2, a2, b2, df2, c2) -> Ident.same id1 id2 && same a1 a2 && same b1 b2 && df1 = df2 && same c1 c2 | Lassign(id1, a1), Lassign(id2, a2) -> Ident.same id1 id2 && same a1 a2 | Lsend(k1, a1, b1, cl1), Lsend(k2, a2, b2, cl2) -> k1 = k2 && same a1 a2 && same b1 b2 && samelist same cl1 cl2 | Levent(a1, ev1), Levent(a2, ev2) -> same a1 a2 && ev1.lev_loc = ev2.lev_loc | Lifused(id1, a1), Lifused(id2, a2) -> Ident.same id1 id2 && same a1 a2 | _, _ -> false and samebinding (id1, c1) (id2, c2) = Ident.same id1 id2 && same c1 c2 and sameswitch sw1 sw2 = let samecase (n1, a1) (n2, a2) = n1 = n2 && same a1 a2 in sw1.sw_numconsts = sw2.sw_numconsts && sw1.sw_numblocks = sw2.sw_numblocks && samelist samecase sw1.sw_consts sw2.sw_consts && samelist samecase sw1.sw_blocks sw2.sw_blocks && (match (sw1.sw_failaction, sw2.sw_failaction) with | (None, None) -> true | (Some a1, Some a2) -> same a1 a2 | _ -> false) let name_lambda arg fn = match arg with Lvar id -> fn id | _ -> let id = Ident.create "let" in Llet(Strict, id, arg, fn id) let name_lambda_list args fn = let rec name_list names = function [] -> fn (List.rev names) | (Lvar id as arg) :: rem -> name_list (arg :: names) rem | arg :: rem -> let id = Ident.create "let" in Llet(Strict, id, arg, name_list (Lvar id :: names) rem) in name_list [] args let rec iter f = function Lvar _ | Lconst _ -> () | Lapply(fn, args, _) -> f fn; List.iter f args | Lfunction(kind, params, body) -> f body | Llet(str, id, arg, body) -> f arg; f body | Lletrec(decl, body) -> f body; List.iter (fun (id, exp) -> f exp) decl | Lprim(p, args) -> List.iter f args | Lswitch(arg, sw) -> f arg; List.iter (fun (key, case) -> f case) sw.sw_consts; List.iter (fun (key, case) -> f case) sw.sw_blocks; begin match sw.sw_failaction with | None -> () | Some l -> f l end | Lstaticraise (_,args) -> List.iter f args | Lstaticcatch(e1, (_,vars), e2) -> f e1; f e2 | Ltrywith(e1, exn, e2) -> f e1; f e2 | Lifthenelse(e1, e2, e3) -> f e1; f e2; f e3 | Lsequence(e1, e2) -> f e1; f e2 | Lwhile(e1, e2) -> f e1; f e2 | Lfor(v, e1, e2, dir, e3) -> f e1; f e2; f e3 | Lassign(id, e) -> f e | Lsend (k, met, obj, args) -> List.iter f (met::obj::args) | Levent (lam, evt) -> f lam | Lifused (v, e) -> f e module IdentSet = Set.Make(struct type t = Ident.t let compare = compare end) let free_ids get l = let fv = ref IdentSet.empty in let rec free l = iter free l; fv := List.fold_right IdentSet.add (get l) !fv; match l with Lfunction(kind, params, body) -> List.iter (fun param -> fv := IdentSet.remove param !fv) params | Llet(str, id, arg, body) -> fv := IdentSet.remove id !fv | Lletrec(decl, body) -> List.iter (fun (id, exp) -> fv := IdentSet.remove id !fv) decl | Lstaticcatch(e1, (_,vars), e2) -> List.iter (fun id -> fv := IdentSet.remove id !fv) vars | Ltrywith(e1, exn, e2) -> fv := IdentSet.remove exn !fv | Lfor(v, e1, e2, dir, e3) -> fv := IdentSet.remove v !fv | Lassign(id, e) -> fv := IdentSet.add id !fv | Lvar _ | Lconst _ | Lapply _ | Lprim _ | Lswitch _ | Lstaticraise _ | Lifthenelse _ | Lsequence _ | Lwhile _ | Lsend _ | Levent _ | Lifused _ -> () in free l; !fv let free_variables l = free_ids (function Lvar id -> [id] | _ -> []) l let free_methods l = free_ids (function Lsend(Self, Lvar meth, obj, _) -> [meth] | _ -> []) l (* Check if an action has a "when" guard *) let raise_count = ref 0 let next_raise_count () = incr raise_count ; !raise_count (* Anticipated staticraise, for guards *) let staticfail = Lstaticraise (0,[]) let rec is_guarded = function | Lifthenelse( cond, body, Lstaticraise (0,[])) -> true | Llet(str, id, lam, body) -> is_guarded body | Levent(lam, ev) -> is_guarded lam | _ -> false let rec patch_guarded patch = function | Lifthenelse (cond, body, Lstaticraise (0,[])) -> Lifthenelse (cond, body, patch) | Llet(str, id, lam, body) -> Llet (str, id, lam, patch_guarded patch body) | Levent(lam, ev) -> Levent (patch_guarded patch lam, ev) | _ -> fatal_error "Lambda.patch_guarded" (* Translate an access path *) let rec transl_path = function Pident id -> if Ident.global id then Lprim(Pgetglobal id, []) else Lvar id | Pdot(p, s, pos) -> Lprim(Pfield pos, [transl_path p]) | Papply(p1, p2) -> fatal_error "Lambda.transl_path" (* Compile a sequence of expressions *) let rec make_sequence fn = function [] -> lambda_unit | [x] -> fn x | x::rem -> let lam = fn x in Lsequence(lam, make_sequence fn rem) (* Apply a substitution to a lambda-term. Assumes that the bound variables of the lambda-term do not belong to the domain of the substitution. Assumes that the image of the substitution is out of reach of the bound variables of the lambda-term (no capture). *) let subst_lambda s lam = let rec subst = function Lvar id as l -> begin try Ident.find_same id s with Not_found -> l end | Lconst sc as l -> l | Lapply(fn, args, loc) -> Lapply(subst fn, List.map subst args, loc) | Lfunction(kind, params, body) -> Lfunction(kind, params, subst body) | Llet(str, id, arg, body) -> Llet(str, id, subst arg, subst body) | Lletrec(decl, body) -> Lletrec(List.map subst_decl decl, subst body) | Lprim(p, args) -> Lprim(p, List.map subst args) | Lswitch(arg, sw) -> Lswitch(subst arg, {sw with sw_consts = List.map subst_case sw.sw_consts; sw_blocks = List.map subst_case sw.sw_blocks; sw_failaction = match sw.sw_failaction with | None -> None | Some l -> Some (subst l)}) | Lstaticraise (i,args) -> Lstaticraise (i, List.map subst args) | Lstaticcatch(e1, io, e2) -> Lstaticcatch(subst e1, io, subst e2) | Ltrywith(e1, exn, e2) -> Ltrywith(subst e1, exn, subst e2) | Lifthenelse(e1, e2, e3) -> Lifthenelse(subst e1, subst e2, subst e3) | Lsequence(e1, e2) -> Lsequence(subst e1, subst e2) | Lwhile(e1, e2) -> Lwhile(subst e1, subst e2) | Lfor(v, e1, e2, dir, e3) -> Lfor(v, subst e1, subst e2, dir, subst e3) | Lassign(id, e) -> Lassign(id, subst e) | Lsend (k, met, obj, args) -> Lsend (k, subst met, subst obj, List.map subst args) | Levent (lam, evt) -> Levent (subst lam, evt) | Lifused (v, e) -> Lifused (v, subst e) and subst_decl (id, exp) = (id, subst exp) and subst_case (key, case) = (key, subst case) in subst lam (* To let-bind expressions to variables *) let bind str var exp body = match exp with Lvar var' when Ident.same var var' -> body | _ -> Llet(str, var, exp, body) and commute_comparison = function | Ceq -> Ceq| Cneq -> Cneq | Clt -> Cgt | Cle -> Cge | Cgt -> Clt | Cge -> Cle and negate_comparison = function | Ceq -> Cneq| Cneq -> Ceq | Clt -> Cge | Cle -> Cgt | Cgt -> Cle | Cge -> Clt