(***********************************************************************) (* *) (* 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. *) (* *) (***********************************************************************) (* $Id$ *) (* Elimination of useless Llet(Alias) bindings. Also transform let-bound references into variables. *) open Asttypes open Lambda (* To transform let-bound references into variables *) exception Real_reference let rec eliminate_ref id = function Lvar v as lam -> if Ident.same v id then raise Real_reference else lam | Lconst cst as lam -> lam | Lapply(e1, el) -> Lapply(eliminate_ref id e1, List.map (eliminate_ref id) el) | Lfunction(kind, params, body) as lam -> if IdentSet.mem id (free_variables lam) then raise Real_reference else lam | Llet(str, v, e1, e2) -> Llet(str, v, eliminate_ref id e1, eliminate_ref id e2) | Lletrec(idel, e2) -> Lletrec(List.map (fun (v, e) -> (v, eliminate_ref id e)) idel, eliminate_ref id e2) | Lprim(Pfield 0, [Lvar v]) when Ident.same v id -> Lvar id | Lprim(Psetfield(0, _), [Lvar v; e]) when Ident.same v id -> Lassign(id, eliminate_ref id e) | Lprim(Poffsetref delta, [Lvar v]) when Ident.same v id -> Lassign(id, Lprim(Poffsetint delta, [Lvar id])) | Lprim(p, el) -> Lprim(p, List.map (eliminate_ref id) el) | Lswitch(e, sw) -> Lswitch(eliminate_ref id e, {sw_numconsts = sw.sw_numconsts; sw_consts = List.map (fun (n, e) -> (n, eliminate_ref id e)) sw.sw_consts; sw_numblocks = sw.sw_numblocks; sw_blocks = List.map (fun (n, e) -> (n, eliminate_ref id e)) sw.sw_blocks; sw_failaction = match sw.sw_failaction with | None -> None | Some l -> Some (eliminate_ref id l)}) | Lstaticraise (i,args) -> Lstaticraise (i,List.map (eliminate_ref id) args) | Lstaticcatch(e1, i, e2) -> Lstaticcatch(eliminate_ref id e1, i, eliminate_ref id e2) | Ltrywith(e1, v, e2) -> Ltrywith(eliminate_ref id e1, v, eliminate_ref id e2) | Lifthenelse(e1, e2, e3) -> Lifthenelse(eliminate_ref id e1, eliminate_ref id e2, eliminate_ref id e3) | Lsequence(e1, e2) -> Lsequence(eliminate_ref id e1, eliminate_ref id e2) | Lwhile(e1, e2) -> Lwhile(eliminate_ref id e1, eliminate_ref id e2) | Lfor(v, e1, e2, dir, e3) -> Lfor(v, eliminate_ref id e1, eliminate_ref id e2, dir, eliminate_ref id e3) | Lassign(v, e) -> Lassign(v, eliminate_ref id e) | Lsend(m, o, el) -> Lsend(eliminate_ref id m, eliminate_ref id o, List.map (eliminate_ref id) el) | Levent(l, ev) -> Levent(eliminate_ref id l, ev) | Lifused(v, e) -> Lifused(v, eliminate_ref id e) (* Simplification of exits *) let simplify_exits lam = (* Count occurrences of (exit n ...) statements *) let exits = Hashtbl.create 17 in let count_exit i = try !(Hashtbl.find exits i) with | Not_found -> 0 and incr_exit i = try incr (Hashtbl.find exits i) with | Not_found -> Hashtbl.add exits i (ref 1) in let rec count = function | (Lvar _| Lconst _) -> () | Lapply(l1, ll) -> count l1; List.iter count ll | Lfunction(kind, params, l) -> count l | Llet(str, v, l1, l2) -> count l2; count l1 | Lletrec(bindings, body) -> List.iter (fun (v, l) -> count l) bindings; count body | Lprim(p, ll) -> List.iter count ll | Lswitch(l, sw) -> count_default sw ; count l; List.iter (fun (_, l) -> count l) sw.sw_consts; List.iter (fun (_, l) -> count l) sw.sw_blocks | Lstaticraise (i,ls) -> incr_exit i ; List.iter count ls | Lstaticcatch (l1,(i,[]),Lstaticraise (j,[])) -> (* i will be replaced by j in l1, so each occurence of i in l1 increases j's ref count *) count l1 ; let ic = count_exit i in begin try let r = Hashtbl.find exits j in r := !r + ic with | Not_found -> Hashtbl.add exits j (ref ic) end | Lstaticcatch(l1, (i,_), l2) -> count l1; (* If l1 does not contain (exit i), l2 will be removed, so don't count its exits *) if count_exit i > 0 then count l2 | Ltrywith(l1, v, l2) -> count l1; count l2 | Lifthenelse(l1, l2, l3) -> count l1; count l2; count l3 | Lsequence(l1, l2) -> count l1; count l2 | Lwhile(l1, l2) -> count l1; count l2 | Lfor(_, l1, l2, dir, l3) -> count l1; count l2; count l3 | Lassign(v, l) -> (* Lalias-bound variables are never assigned, so don't increase v's refcount *) count l | Lsend(m, o, ll) -> List.iter count (m::o::ll) | Levent(l, _) -> count l | Lifused(v, l) -> count l and count_default sw = match sw.sw_failaction with | None -> () | Some al -> let nconsts = List.length sw.sw_consts and nblocks = List.length sw.sw_blocks in if nconsts < sw.sw_numconsts && nblocks < sw.sw_numblocks then begin (* default action will occur twice in native code *) count al ; count al end else begin (* default action will occur once *) assert (nconsts < sw.sw_numconsts || nblocks < sw.sw_numblocks) ; count al end in count lam; (* Second pass simplify ``catch body with (i ...) handler'' - if (exit i ...) does not occur in body, suppress catch - if (exit i ...) occurs exactly once in body, substitute it with handler - If handler is a single variable, replace (exit i ..) with it Note: In ``catch body with (i x1 .. xn) handler'' Substituted expression is let y1 = x1 and ... yn = xn in handler[x1 <- y1 ; ... ; xn <- yn] For the sake of preserving the uniqueness of bound variables. (No alpha conversion of ``handler'' is presently needed, since substitution of several ``(exit i ...)'' occurs only when ``handler'' is a variable.) *) let subst = Hashtbl.create 17 in let rec simplif = function | (Lvar _|Lconst _) as l -> l | Lapply(l1, ll) -> Lapply(simplif l1, List.map simplif ll) | Lfunction(kind, params, l) -> Lfunction(kind, params, simplif l) | Llet(kind, v, l1, l2) -> Llet(kind, v, simplif l1, simplif l2) | Lletrec(bindings, body) -> Lletrec(List.map (fun (v, l) -> (v, simplif l)) bindings, simplif body) | Lprim(p, ll) -> Lprim(p, List.map simplif ll) | Lswitch(l, sw) -> let new_l = simplif l and new_consts = List.map (fun (n, e) -> (n, simplif e)) sw.sw_consts and new_blocks = List.map (fun (n, e) -> (n, simplif e)) sw.sw_blocks and new_fail = match sw.sw_failaction with | None -> None | Some l -> Some (simplif l) in Lswitch (new_l, {sw with sw_consts = new_consts ; sw_blocks = new_blocks; sw_failaction = new_fail}) | Lstaticraise (i,[]) as l -> begin try let _,handler = Hashtbl.find subst i in handler with | Not_found -> l end | Lstaticraise (i,ls) as l -> let ls = List.map simplif ls in begin try let xs,handler = Hashtbl.find subst i in let ys = List.map Ident.rename xs in let env = List.fold_right2 (fun x y t -> Ident.add x (Lvar y) t) xs ys Ident.empty in List.fold_right2 (fun y l r -> Llet (Alias, y, l, r)) ys ls (Lambda.subst_lambda env handler) with | Not_found -> l end | Lstaticcatch (l1,(i,[]),(Lstaticraise (j,[]) as l2)) -> Hashtbl.add subst i ([],simplif l2) ; simplif l1 | Lstaticcatch (l1,(i,xs), (Lvar _ as l2)) -> begin match count_exit i with | 0 -> simplif l1 | _ -> Hashtbl.add subst i (xs,l2) ; simplif l1 end | Lstaticcatch (l1,(i,xs),l2) -> begin match count_exit i with | 0 -> simplif l1 | 1 -> Hashtbl.add subst i (xs,simplif l2) ; simplif l1 | _ -> Lstaticcatch (simplif l1, (i,xs), simplif l2) end | Ltrywith(l1, v, l2) -> Ltrywith(simplif l1, v, simplif l2) | Lifthenelse(l1, l2, l3) -> Lifthenelse(simplif l1, simplif l2, simplif l3) | Lsequence(l1, l2) -> Lsequence(simplif l1, simplif l2) | Lwhile(l1, l2) -> Lwhile(simplif l1, simplif l2) | Lfor(v, l1, l2, dir, l3) -> Lfor(v, simplif l1, simplif l2, dir, simplif l3) | Lassign(v, l) -> Lassign(v, simplif l) | Lsend(m, o, ll) -> Lsend(simplif m, simplif o, List.map simplif ll) | Levent(l, ev) -> Levent(simplif l, ev) | Lifused(v, l) -> Lifused (v,simplif l) in simplif lam (* Simplification of lets *) let simplify_lets lam = (* First pass: count the occurrences of all identifiers *) let occ = Hashtbl.create 83 in let count_var v = try !(Hashtbl.find occ v) with Not_found -> 0 and incr_var v = try incr(Hashtbl.find occ v) with Not_found -> Hashtbl.add occ v (ref 1) in let rec count = function | Lvar v -> incr_var v | Lconst cst -> () | Lapply(l1, ll) -> count l1; List.iter count ll | Lfunction(kind, params, l) -> count l | Llet(str, v, Lvar w, l2) when not !Clflags.debug -> (* v will be replaced by w in l2, so each occurrence of v in l2 increases w's refcount *) count l2; let vc = count_var v in begin try let r = Hashtbl.find occ w in r := !r + vc with Not_found -> Hashtbl.add occ w (ref vc) end | Llet(str, v, l1, l2) -> count l2; (* If v is unused, l1 will be removed, so don't count its variables *) if str = Strict || count_var v > 0 then count l1 | Lletrec(bindings, body) -> List.iter (fun (v, l) -> count l) bindings; count body | Lprim(p, ll) -> List.iter count ll | Lswitch(l, sw) -> count_default sw ; count l; List.iter (fun (_, l) -> count l) sw.sw_consts; List.iter (fun (_, l) -> count l) sw.sw_blocks | Lstaticraise (i,ls) -> List.iter count ls | Lstaticcatch(l1, (i,_), l2) -> count l1; count l2 | Ltrywith(l1, v, l2) -> count l1; count l2 | Lifthenelse(l1, l2, l3) -> count l1; count l2; count l3 | Lsequence(l1, l2) -> count l1; count l2 | Lwhile(l1, l2) -> count l1; count l2 | Lfor(_, l1, l2, dir, l3) -> count l1; count l2; count l3 | Lassign(v, l) -> (* Lalias-bound variables are never assigned, so don't increase v's refcount *) count l | Lsend(m, o, ll) -> List.iter count (m::o::ll) | Levent(l, _) -> count l | Lifused(v, l) -> if count_var v > 0 then count l and count_default sw = match sw.sw_failaction with | None -> () | Some al -> let nconsts = List.length sw.sw_consts and nblocks = List.length sw.sw_blocks in if nconsts < sw.sw_numconsts && nblocks < sw.sw_numblocks then begin (* default action will occur twice in native code *) count al ; count al end else begin (* default action will occur once *) assert (nconsts < sw.sw_numconsts || nblocks < sw.sw_numblocks) ; count al end in count lam; (* Second pass: remove Lalias bindings of unused variables, and substitute the bindings of variables used exactly once. *) let subst = Hashtbl.create 83 in let rec simplif = function Lvar v as l -> begin try Hashtbl.find subst v with Not_found -> l end | Lconst cst as l -> l | Lapply(l1, ll) -> Lapply(simplif l1, List.map simplif ll) | Lfunction(kind, params, l) -> Lfunction(kind, params, simplif l) | Llet(str, v, Lvar w, l2) when not !Clflags.debug -> Hashtbl.add subst v (simplif (Lvar w)); simplif l2 | Llet(Strict, v, Lprim(Pmakeblock(0, Mutable), [linit]), lbody) when not !Clflags.debug -> let slinit = simplif linit in let slbody = simplif lbody in begin try Llet(Variable, v, slinit, eliminate_ref v slbody) with Real_reference -> Llet(Strict, v, Lprim(Pmakeblock(0, Mutable), [slinit]), slbody) end | Llet(Alias, v, l1, l2) -> begin match count_var v with 0 -> simplif l2 | 1 when not !Clflags.debug -> Hashtbl.add subst v (simplif l1); simplif l2 | n -> Llet(Alias, v, simplif l1, simplif l2) end | Llet(StrictOpt, v, l1, l2) -> begin match count_var v with 0 -> simplif l2 | n -> Llet(Alias, v, simplif l1, simplif l2) end | Llet(kind, v, l1, l2) -> Llet(kind, v, simplif l1, simplif l2) | Lletrec(bindings, body) -> Lletrec(List.map (fun (v, l) -> (v, simplif l)) bindings, simplif body) | Lprim(p, ll) -> Lprim(p, List.map simplif ll) | Lswitch(l, sw) -> let new_l = simplif l and new_consts = List.map (fun (n, e) -> (n, simplif e)) sw.sw_consts and new_blocks = List.map (fun (n, e) -> (n, simplif e)) sw.sw_blocks and new_fail = match sw.sw_failaction with | None -> None | Some l -> Some (simplif l) in Lswitch (new_l, {sw with sw_consts = new_consts ; sw_blocks = new_blocks; sw_failaction = new_fail}) | Lstaticraise (i,ls) -> Lstaticraise (i, List.map simplif ls) | Lstaticcatch(l1, (i,args), l2) -> Lstaticcatch (simplif l1, (i,args), simplif l2) | Ltrywith(l1, v, l2) -> Ltrywith(simplif l1, v, simplif l2) | Lifthenelse(l1, l2, l3) -> Lifthenelse(simplif l1, simplif l2, simplif l3) | Lsequence(Lifused(v, l1), l2) -> if count_var v > 0 then Lsequence(simplif l1, simplif l2) else simplif l2 | Lsequence(l1, l2) -> Lsequence(simplif l1, simplif l2) | Lwhile(l1, l2) -> Lwhile(simplif l1, simplif l2) | Lfor(v, l1, l2, dir, l3) -> Lfor(v, simplif l1, simplif l2, dir, simplif l3) | Lassign(v, l) -> Lassign(v, simplif l) | Lsend(m, o, ll) -> Lsend(simplif m, simplif o, List.map simplif ll) | Levent(l, ev) -> Levent(simplif l, ev) | Lifused(v, l) -> if count_var v > 0 then simplif l else lambda_unit in simplif lam let simplify_lambda lam = simplify_lets (simplify_exits lam)