3189 lines
96 KiB
OCaml
3189 lines
96 KiB
OCaml
(***********************************************************************)
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(* *)
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(* OCaml *)
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(* *)
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(* Xavier Leroy, projet Cristal, INRIA Rocquencourt *)
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(* *)
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(* Copyright 1996 Institut National de Recherche en Informatique et *)
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(* en Automatique. All rights reserved. This file is distributed *)
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(* under the terms of the Q Public License version 1.0. *)
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(* *)
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(***********************************************************************)
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(* Compilation of pattern matching *)
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open Misc
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open Asttypes
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open Types
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open Typedtree
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open Lambda
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open Parmatch
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open Printf
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let dbg = false
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(* See Peyton-Jones, ``The Implementation of functional programming
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languages'', chapter 5. *)
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(*
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Well, it was true at the beginning of the world.
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Now, see Lefessant-Maranget ``Optimizing Pattern-Matching'' ICFP'2001
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*)
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(*
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Many functions on the various data structures of the algorithm :
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- Pattern matrices.
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- Default environments: mapping from matrices to exit numbers.
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- Contexts: matrices whose column are partitioned into
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left and right.
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- Jump summaries: mapping from exit numbers to contexts
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*)
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let string_of_lam lam =
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Printlambda.lambda Format.str_formatter lam ;
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Format.flush_str_formatter ()
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type matrix = pattern list list
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let add_omega_column pss = List.map (fun ps -> omega::ps) pss
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type ctx = {left:pattern list ; right:pattern list}
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let pretty_ctx ctx =
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List.iter
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(fun {left=left ; right=right} ->
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prerr_string "LEFT:" ;
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pretty_line left ;
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prerr_string " RIGHT:" ;
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pretty_line right ;
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prerr_endline "")
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ctx
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let le_ctx c1 c2 =
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le_pats c1.left c2.left &&
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le_pats c1.right c2.right
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let lshift {left=left ; right=right} = match right with
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| x::xs -> {left=x::left ; right=xs}
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| _ -> assert false
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let lforget {left=left ; right=right} = match right with
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| x::xs -> {left=omega::left ; right=xs}
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| _ -> assert false
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let rec small_enough n = function
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| [] -> true
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| _::rem ->
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if n <= 0 then false
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else small_enough (n-1) rem
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let ctx_lshift ctx =
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if small_enough 31 ctx then
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List.map lshift ctx
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else (* Context pruning *) begin
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get_mins le_ctx (List.map lforget ctx)
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end
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let rshift {left=left ; right=right} = match left with
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| p::ps -> {left=ps ; right=p::right}
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| _ -> assert false
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let ctx_rshift ctx = List.map rshift ctx
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let rec nchars n ps =
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if n <= 0 then [],ps
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else match ps with
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| p::rem ->
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let chars, cdrs = nchars (n-1) rem in
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p::chars,cdrs
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| _ -> assert false
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let rshift_num n {left=left ; right=right} =
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let shifted,left = nchars n left in
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{left=left ; right = shifted@right}
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let ctx_rshift_num n ctx = List.map (rshift_num n) ctx
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(* Recombination of contexts (eg: (_,_)::p1::p2::rem -> (p1,p2)::rem)
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All mutable fields are replaced by '_', since side-effects in
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guards can alter these fields *)
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let combine {left=left ; right=right} = match left with
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| p::ps -> {left=ps ; right=set_args_erase_mutable p right}
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| _ -> assert false
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let ctx_combine ctx = List.map combine ctx
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let ncols = function
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| [] -> 0
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| ps::_ -> List.length ps
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exception NoMatch
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exception OrPat
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let filter_matrix matcher pss =
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let rec filter_rec = function
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| (p::ps)::rem ->
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begin match p.pat_desc with
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| Tpat_alias (p,_,_) ->
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filter_rec ((p::ps)::rem)
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| Tpat_var _ ->
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filter_rec ((omega::ps)::rem)
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| _ ->
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begin
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let rem = filter_rec rem in
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try
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matcher p ps::rem
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with
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| NoMatch -> rem
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| OrPat ->
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match p.pat_desc with
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| Tpat_or (p1,p2,_) -> filter_rec [(p1::ps) ;(p2::ps)]@rem
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| _ -> assert false
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end
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end
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| [] -> []
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| _ ->
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pretty_matrix pss ;
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fatal_error "Matching.filter_matrix" in
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filter_rec pss
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let make_default matcher env =
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let rec make_rec = function
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| [] -> []
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| ([[]],i)::_ -> [[[]],i]
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| (pss,i)::rem ->
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let rem = make_rec rem in
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match filter_matrix matcher pss with
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| [] -> rem
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| ([]::_) -> ([[]],i)::rem
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| pss -> (pss,i)::rem in
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make_rec env
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let ctx_matcher p =
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let p = normalize_pat p in
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match p.pat_desc with
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| Tpat_construct (_, cstr,omegas) ->
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begin match cstr.cstr_tag with
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| Cstr_extension _ ->
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let nargs = List.length omegas in
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(fun q rem -> match q.pat_desc with
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| Tpat_construct (_, cstr',args)
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when List.length args = nargs ->
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p,args @ rem
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| Tpat_any -> p,omegas @ rem
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| _ -> raise NoMatch)
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| _ ->
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(fun q rem -> match q.pat_desc with
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| Tpat_construct (_, cstr',args)
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when cstr.cstr_tag=cstr'.cstr_tag ->
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p,args @ rem
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| Tpat_any -> p,omegas @ rem
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| _ -> raise NoMatch)
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end
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| Tpat_constant cst ->
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(fun q rem -> match q.pat_desc with
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| Tpat_constant cst' when const_compare cst cst' = 0 ->
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p,rem
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| Tpat_any -> p,rem
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| _ -> raise NoMatch)
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| Tpat_variant (lab,Some omega,_) ->
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(fun q rem -> match q.pat_desc with
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| Tpat_variant (lab',Some arg,_) when lab=lab' ->
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p,arg::rem
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| Tpat_any -> p,omega::rem
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| _ -> raise NoMatch)
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| Tpat_variant (lab,None,_) ->
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(fun q rem -> match q.pat_desc with
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| Tpat_variant (lab',None,_) when lab=lab' ->
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p,rem
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| Tpat_any -> p,rem
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| _ -> raise NoMatch)
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| Tpat_array omegas ->
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let len = List.length omegas in
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(fun q rem -> match q.pat_desc with
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| Tpat_array args when List.length args=len ->
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p,args @ rem
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| Tpat_any -> p, omegas @ rem
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| _ -> raise NoMatch)
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| Tpat_tuple omegas ->
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(fun q rem -> match q.pat_desc with
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| Tpat_tuple args -> p,args @ rem
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| _ -> p, omegas @ rem)
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| Tpat_record (l,_) -> (* Records are normalized *)
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(fun q rem -> match q.pat_desc with
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| Tpat_record (l',_) ->
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let l' = all_record_args l' in
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p, List.fold_right (fun (_, _,p) r -> p::r) l' rem
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| _ -> p,List.fold_right (fun (_, _,p) r -> p::r) l rem)
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| Tpat_lazy omega ->
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(fun q rem -> match q.pat_desc with
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| Tpat_lazy arg -> p, (arg::rem)
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| _ -> p, (omega::rem))
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| _ -> fatal_error "Matching.ctx_matcher"
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let filter_ctx q ctx =
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let matcher = ctx_matcher q in
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let rec filter_rec = function
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| ({right=p::ps} as l)::rem ->
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begin match p.pat_desc with
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| Tpat_or (p1,p2,_) ->
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filter_rec ({l with right=p1::ps}::{l with right=p2::ps}::rem)
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| Tpat_alias (p,_,_) ->
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filter_rec ({l with right=p::ps}::rem)
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| Tpat_var _ ->
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filter_rec ({l with right=omega::ps}::rem)
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| _ ->
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begin let rem = filter_rec rem in
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try
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let to_left, right = matcher p ps in
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{left=to_left::l.left ; right=right}::rem
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with
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| NoMatch -> rem
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end
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end
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| [] -> []
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| _ -> fatal_error "Matching.filter_ctx" in
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filter_rec ctx
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let select_columns pss ctx =
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let n = ncols pss in
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List.fold_right
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(fun ps r ->
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List.fold_right
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(fun {left=left ; right=right} r ->
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let transfert, right = nchars n right in
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try
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{left = lubs transfert ps @ left ; right=right}::r
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with
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| Empty -> r)
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ctx r)
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pss []
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let ctx_lub p ctx =
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List.fold_right
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(fun {left=left ; right=right} r ->
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match right with
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| q::rem ->
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begin try
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{left=left ; right = lub p q::rem}::r
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with
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| Empty -> r
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end
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| _ -> fatal_error "Matching.ctx_lub")
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ctx []
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let ctx_match ctx pss =
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List.exists
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(fun {right=qs} ->
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List.exists
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(fun ps -> compats qs ps)
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pss)
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ctx
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type jumps = (int * ctx list) list
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let pretty_jumps (env : jumps) = match env with
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| [] -> ()
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| _ ->
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List.iter
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(fun (i,ctx) ->
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Printf.fprintf stderr "jump for %d\n" i ;
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pretty_ctx ctx)
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env
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let rec jumps_extract i = function
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| [] -> [],[]
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| (j,pss) as x::rem as all ->
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if i=j then pss,rem
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else if j < i then [],all
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else
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let r,rem = jumps_extract i rem in
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r,(x::rem)
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let rec jumps_remove i = function
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| [] -> []
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| (j,_)::rem when i=j -> rem
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| x::rem -> x::jumps_remove i rem
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let jumps_empty = []
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and jumps_is_empty = function
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| [] -> true
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| _ -> false
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let jumps_singleton i = function
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| [] -> []
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| ctx -> [i,ctx]
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let jumps_add i pss jumps = match pss with
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| [] -> jumps
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| _ ->
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let rec add = function
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| [] -> [i,pss]
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| (j,qss) as x::rem as all ->
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if j > i then x::add rem
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else if j < i then (i,pss)::all
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else (i,(get_mins le_ctx (pss@qss)))::rem in
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add jumps
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let rec jumps_union (env1:(int*ctx list)list) env2 = match env1,env2 with
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| [],_ -> env2
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| _,[] -> env1
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| ((i1,pss1) as x1::rem1), ((i2,pss2) as x2::rem2) ->
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if i1=i2 then
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(i1,get_mins le_ctx (pss1@pss2))::jumps_union rem1 rem2
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else if i1 > i2 then
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x1::jumps_union rem1 env2
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else
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x2::jumps_union env1 rem2
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let rec merge = function
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| env1::env2::rem -> jumps_union env1 env2::merge rem
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| envs -> envs
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let rec jumps_unions envs = match envs with
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| [] -> []
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| [env] -> env
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| _ -> jumps_unions (merge envs)
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let jumps_map f env =
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List.map
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(fun (i,pss) -> i,f pss)
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env
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(* Pattern matching before any compilation *)
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type pattern_matching =
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{ mutable cases : (pattern list * lambda) list;
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args : (lambda * let_kind) list ;
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default : (matrix * int) list}
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(* Pattern matching after application of both the or-pat rule and the
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mixture rule *)
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type pm_or_compiled =
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{body : pattern_matching ;
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handlers : (matrix * int * Ident.t list * pattern_matching) list ;
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or_matrix : matrix ; }
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type pm_half_compiled =
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| PmOr of pm_or_compiled
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| PmVar of pm_var_compiled
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| Pm of pattern_matching
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and pm_var_compiled =
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{inside : pm_half_compiled ; var_arg : lambda ; }
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type pm_half_compiled_info =
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{me : pm_half_compiled ;
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matrix : matrix ;
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top_default : (matrix * int) list ; }
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let pretty_cases cases =
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List.iter
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(fun ((ps),l) ->
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List.iter
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(fun p ->
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Parmatch.top_pretty Format.str_formatter p ;
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prerr_string " " ;
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prerr_string (Format.flush_str_formatter ()))
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ps ;
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(*
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prerr_string " -> " ;
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Printlambda.lambda Format.str_formatter l ;
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prerr_string (Format.flush_str_formatter ()) ;
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*)
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prerr_endline "")
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cases
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let pretty_def def =
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prerr_endline "+++++ Defaults +++++" ;
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List.iter
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(fun (pss,i) ->
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Printf.fprintf stderr "Matrix for %d\n" i ;
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pretty_matrix pss)
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def ;
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prerr_endline "+++++++++++++++++++++"
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let pretty_pm pm = pretty_cases pm.cases
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let rec pretty_precompiled = function
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| Pm pm ->
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prerr_endline "++++ PM ++++" ;
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pretty_pm pm
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| PmVar x ->
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prerr_endline "++++ VAR ++++" ;
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pretty_precompiled x.inside
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| PmOr x ->
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prerr_endline "++++ OR ++++" ;
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pretty_pm x.body ;
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pretty_matrix x.or_matrix ;
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List.iter
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(fun (_,i,_,pm) ->
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eprintf "++ Handler %d ++\n" i ;
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pretty_pm pm)
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x.handlers
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let pretty_precompiled_res first nexts =
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pretty_precompiled first ;
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List.iter
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(fun (e, pmh) ->
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eprintf "** DEFAULT %d **\n" e ;
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pretty_precompiled pmh)
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nexts
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(* Identifing some semantically equivalent lambda-expressions,
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Our goal here is also to
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find alpha-equivalent (simple) terms *)
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(* However, as shown by PR#6359 such sharing may hinders the
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lambda-code invariant that all bound idents are unique,
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when switchs are compiled to test sequences.
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The definitive fix is the systematic introduction of exit/catch
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in case action sharing is present.
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*)
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module StoreExp =
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Switch.Store
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(struct
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type t = lambda
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type key = lambda
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let make_key = Lambda.make_key
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end)
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let make_exit i = Lstaticraise (i,[])
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(* Introduce a catch, if worth it *)
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let make_catch d k = match d with
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| Lstaticraise (_,[]) -> k d
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| _ ->
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let e = next_raise_count () in
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Lstaticcatch (k (make_exit e),(e,[]),d)
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(* Introduce a catch, if worth it, delayed version *)
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let rec as_simple_exit = function
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| Lstaticraise (i,[]) -> Some i
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| Llet (Alias,_,_,e) -> as_simple_exit e
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| _ -> None
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|
|
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let make_catch_delayed handler = match as_simple_exit handler with
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| Some i -> i,(fun act -> act)
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| None ->
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let i = next_raise_count () in
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(*
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Printf.eprintf "SHARE LAMBDA: %i\n%s\n" i (string_of_lam handler);
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*)
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i,
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(fun body -> match body with
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| Lstaticraise (j,_) ->
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if i=j then handler else body
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| _ -> Lstaticcatch (body,(i,[]),handler))
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|
|
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let raw_action l =
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match make_key l with | Some l -> l | None -> l
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let tr_raw act = match make_key act with
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| Some act -> act
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| None -> raise Exit
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let same_actions = function
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| [] -> None
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| [_,act] -> Some act
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| (_,act0) :: rem ->
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try
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let raw_act0 = tr_raw act0 in
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let rec s_rec = function
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| [] -> Some act0
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| (_,act)::rem ->
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if raw_act0 = tr_raw act then
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s_rec rem
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else
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None in
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s_rec rem
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with
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| Exit -> None
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(* Test for swapping two clauses *)
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let up_ok_action act1 act2 =
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try
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let raw1 = tr_raw act1
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and raw2 = tr_raw act2 in
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raw1 = raw2
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with
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| Exit -> false
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|
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(* Nothing is kown about exception/extension patterns,
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because of potential rebind *)
|
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let rec exc_inside p = match p.pat_desc with
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| Tpat_construct (_,{cstr_tag=Cstr_extension _},_) -> true
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| Tpat_any|Tpat_constant _|Tpat_var _
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| Tpat_construct (_,_,[])
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| Tpat_variant (_,None,_)
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-> false
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| Tpat_construct (_,_,ps)
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| Tpat_tuple ps
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| Tpat_array ps
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-> exc_insides ps
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| Tpat_variant (_, Some q,_)
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| Tpat_alias (q,_,_)
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| Tpat_lazy q
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-> exc_inside q
|
|
| Tpat_record (lps,_) ->
|
|
List.exists (fun (_,_,p) -> exc_inside p) lps
|
|
| Tpat_or (p1,p2,_) -> exc_inside p1 || exc_inside p2
|
|
|
|
and exc_insides ps = List.exists exc_inside ps
|
|
|
|
let up_ok (ps,act_p) l =
|
|
if exc_insides ps then match l with [] -> true | _::_ -> false
|
|
else
|
|
List.for_all
|
|
(fun (qs,act_q) ->
|
|
up_ok_action act_p act_q ||
|
|
not (Parmatch.compats ps qs))
|
|
l
|
|
|
|
|
|
(*
|
|
Simplify fonction normalize the first column of the match
|
|
- records are expanded so that they posses all fields
|
|
- aliases are removed and replaced by bindings in actions.
|
|
However or-patterns are simplified differently,
|
|
- aliases are not removed
|
|
- or patterns (_|p) are changed into _
|
|
*)
|
|
|
|
exception Var of pattern
|
|
|
|
let simplify_or p =
|
|
let rec simpl_rec p = match p with
|
|
| {pat_desc = Tpat_any|Tpat_var _} -> raise (Var p)
|
|
| {pat_desc = Tpat_alias (q,id,s)} ->
|
|
begin try
|
|
{p with pat_desc = Tpat_alias (simpl_rec q,id,s)}
|
|
with
|
|
| Var q -> raise (Var {p with pat_desc = Tpat_alias (q,id,s)})
|
|
end
|
|
| {pat_desc = Tpat_or (p1,p2,o)} ->
|
|
let q1 = simpl_rec p1 in
|
|
begin try
|
|
let q2 = simpl_rec p2 in
|
|
{p with pat_desc = Tpat_or (q1, q2, o)}
|
|
with
|
|
| Var q2 -> raise (Var {p with pat_desc = Tpat_or (q1, q2, o)})
|
|
end
|
|
| {pat_desc = Tpat_record (lbls,closed)} ->
|
|
let all_lbls = all_record_args lbls in
|
|
{p with pat_desc=Tpat_record (all_lbls, closed)}
|
|
| _ -> p in
|
|
try
|
|
simpl_rec p
|
|
with
|
|
| Var p -> p
|
|
|
|
let simplify_cases args cls = match args with
|
|
| [] -> assert false
|
|
| (arg,_)::_ ->
|
|
let rec simplify = function
|
|
| [] -> []
|
|
| ((pat :: patl, action) as cl) :: rem ->
|
|
begin match pat.pat_desc with
|
|
| Tpat_var (id, _) ->
|
|
(omega :: patl, bind Alias id arg action) ::
|
|
simplify rem
|
|
| Tpat_any ->
|
|
cl :: simplify rem
|
|
| Tpat_alias(p, id,_) ->
|
|
simplify ((p :: patl, bind Alias id arg action) :: rem)
|
|
| Tpat_record ([],_) ->
|
|
(omega :: patl, action)::
|
|
simplify rem
|
|
| Tpat_record (lbls, closed) ->
|
|
let all_lbls = all_record_args lbls in
|
|
let full_pat =
|
|
{pat with pat_desc=Tpat_record (all_lbls, closed)} in
|
|
(full_pat::patl,action)::
|
|
simplify rem
|
|
| Tpat_or _ ->
|
|
let pat_simple = simplify_or pat in
|
|
begin match pat_simple.pat_desc with
|
|
| Tpat_or _ ->
|
|
(pat_simple :: patl, action) ::
|
|
simplify rem
|
|
| _ ->
|
|
simplify ((pat_simple::patl,action) :: rem)
|
|
end
|
|
| _ -> cl :: simplify rem
|
|
end
|
|
| _ -> assert false in
|
|
|
|
simplify cls
|
|
|
|
|
|
|
|
(* Once matchings are simplified one easily finds
|
|
their nature *)
|
|
|
|
let rec what_is_cases cases = match cases with
|
|
| ({pat_desc=Tpat_any} :: _, _) :: rem -> what_is_cases rem
|
|
| (({pat_desc=(Tpat_var _|Tpat_or (_,_,_)|Tpat_alias (_,_,_))}::_),_)::_
|
|
-> assert false (* applies to simplified matchings only *)
|
|
| (p::_,_)::_ -> p
|
|
| [] -> omega
|
|
| _ -> assert false
|
|
|
|
|
|
|
|
(* A few operation on default environments *)
|
|
let as_matrix cases = get_mins le_pats (List.map (fun (ps,_) -> ps) cases)
|
|
|
|
(* For extension matching, record no imformation in matrix *)
|
|
let as_matrix_omega cases =
|
|
get_mins le_pats
|
|
(List.map
|
|
(fun (ps,_) ->
|
|
match ps with
|
|
| [] -> assert false
|
|
| _::ps -> omega::ps)
|
|
cases)
|
|
|
|
let cons_default matrix raise_num default =
|
|
match matrix with
|
|
| [] -> default
|
|
| _ -> (matrix,raise_num)::default
|
|
|
|
let default_compat p def =
|
|
List.fold_right
|
|
(fun (pss,i) r ->
|
|
let qss =
|
|
List.fold_right
|
|
(fun qs r -> match qs with
|
|
| q::rem when Parmatch.compat p q -> rem::r
|
|
| _ -> r)
|
|
pss [] in
|
|
match qss with
|
|
| [] -> r
|
|
| _ -> (qss,i)::r)
|
|
def []
|
|
|
|
(* Or-pattern expansion, variables are a complication w.r.t. the article *)
|
|
let rec extract_vars r p = match p.pat_desc with
|
|
| Tpat_var (id, _) -> IdentSet.add id r
|
|
| Tpat_alias (p, id,_ ) ->
|
|
extract_vars (IdentSet.add id r) p
|
|
| Tpat_tuple pats ->
|
|
List.fold_left extract_vars r pats
|
|
| Tpat_record (lpats,_) ->
|
|
List.fold_left
|
|
(fun r (_, _, p) -> extract_vars r p)
|
|
r lpats
|
|
| Tpat_construct (_, _, pats) ->
|
|
List.fold_left extract_vars r pats
|
|
| Tpat_array pats ->
|
|
List.fold_left extract_vars r pats
|
|
| Tpat_variant (_,Some p, _) -> extract_vars r p
|
|
| Tpat_lazy p -> extract_vars r p
|
|
| Tpat_or (p,_,_) -> extract_vars r p
|
|
| Tpat_constant _|Tpat_any|Tpat_variant (_,None,_) -> r
|
|
|
|
exception Cannot_flatten
|
|
|
|
let mk_alpha_env arg aliases ids =
|
|
List.map
|
|
(fun id -> id,
|
|
if List.mem id aliases then
|
|
match arg with
|
|
| Some v -> v
|
|
| _ -> raise Cannot_flatten
|
|
else
|
|
Ident.create (Ident.name id))
|
|
ids
|
|
|
|
let rec explode_or_pat arg patl mk_action rem vars aliases = function
|
|
| {pat_desc = Tpat_or (p1,p2,_)} ->
|
|
explode_or_pat
|
|
arg patl mk_action
|
|
(explode_or_pat arg patl mk_action rem vars aliases p2)
|
|
vars aliases p1
|
|
| {pat_desc = Tpat_alias (p,id, _)} ->
|
|
explode_or_pat arg patl mk_action rem vars (id::aliases) p
|
|
| {pat_desc = Tpat_var (x, _)} ->
|
|
let env = mk_alpha_env arg (x::aliases) vars in
|
|
(omega::patl,mk_action (List.map snd env))::rem
|
|
| p ->
|
|
let env = mk_alpha_env arg aliases vars in
|
|
(alpha_pat env p::patl,mk_action (List.map snd env))::rem
|
|
|
|
let pm_free_variables {cases=cases} =
|
|
List.fold_right
|
|
(fun (_,act) r -> IdentSet.union (free_variables act) r)
|
|
cases IdentSet.empty
|
|
|
|
|
|
(* Basic grouping predicates *)
|
|
let pat_as_constr = function
|
|
| {pat_desc=Tpat_construct (_, cstr,_)} -> cstr
|
|
| _ -> fatal_error "Matching.pat_as_constr"
|
|
|
|
let group_constant = function
|
|
| {pat_desc= Tpat_constant _} -> true
|
|
| _ -> false
|
|
|
|
and group_constructor = function
|
|
| {pat_desc = Tpat_construct (_,_,_)} -> true
|
|
| _ -> false
|
|
|
|
and group_variant = function
|
|
| {pat_desc = Tpat_variant (_, _, _)} -> true
|
|
| _ -> false
|
|
|
|
and group_var = function
|
|
| {pat_desc=Tpat_any} -> true
|
|
| _ -> false
|
|
|
|
and group_tuple = function
|
|
| {pat_desc = (Tpat_tuple _|Tpat_any)} -> true
|
|
| _ -> false
|
|
|
|
and group_record = function
|
|
| {pat_desc = (Tpat_record _|Tpat_any)} -> true
|
|
| _ -> false
|
|
|
|
and group_array = function
|
|
| {pat_desc=Tpat_array _} -> true
|
|
| _ -> false
|
|
|
|
and group_lazy = function
|
|
| {pat_desc = Tpat_lazy _} -> true
|
|
| _ -> false
|
|
|
|
let get_group p = match p.pat_desc with
|
|
| Tpat_any -> group_var
|
|
| Tpat_constant _ -> group_constant
|
|
| Tpat_construct _ -> group_constructor
|
|
| Tpat_tuple _ -> group_tuple
|
|
| Tpat_record _ -> group_record
|
|
| Tpat_array _ -> group_array
|
|
| Tpat_variant (_,_,_) -> group_variant
|
|
| Tpat_lazy _ -> group_lazy
|
|
| _ -> fatal_error "Matching.get_group"
|
|
|
|
|
|
|
|
let is_or p = match p.pat_desc with
|
|
| Tpat_or _ -> true
|
|
| _ -> false
|
|
|
|
(* Conditions for appending to the Or matrix *)
|
|
let conda p q = not (compat p q)
|
|
and condb act ps qs = not (is_guarded act) && Parmatch.le_pats qs ps
|
|
|
|
let or_ok p ps l =
|
|
List.for_all
|
|
(function
|
|
| ({pat_desc=Tpat_or _} as q::qs,act) ->
|
|
conda p q || condb act ps qs
|
|
| _ -> true)
|
|
l
|
|
|
|
(* Insert or append a pattern in the Or matrix *)
|
|
|
|
let equiv_pat p q = le_pat p q && le_pat q p
|
|
|
|
let rec get_equiv p l = match l with
|
|
| (q::_,_) as cl::rem ->
|
|
if equiv_pat p q then
|
|
let others,rem = get_equiv p rem in
|
|
cl::others,rem
|
|
else
|
|
[],l
|
|
| _ -> [],l
|
|
|
|
|
|
let insert_or_append p ps act ors no =
|
|
let rec attempt seen = function
|
|
| (q::qs,act_q) as cl::rem ->
|
|
if is_or q then begin
|
|
if compat p q then
|
|
if
|
|
IdentSet.is_empty (extract_vars IdentSet.empty p) &&
|
|
IdentSet.is_empty (extract_vars IdentSet.empty q) &&
|
|
equiv_pat p q
|
|
then (* attempt insert, for equivalent orpats with no variables *)
|
|
let _, not_e = get_equiv q rem in
|
|
if
|
|
or_ok p ps not_e && (* check append condition for head of O *)
|
|
List.for_all (* check insert condition for tail of O *)
|
|
(fun cl -> match cl with
|
|
| (q::_,_) -> not (compat p q)
|
|
| _ -> assert false)
|
|
seen
|
|
then (* insert *)
|
|
List.rev_append seen ((p::ps,act)::cl::rem), no
|
|
else (* fail to insert or append *)
|
|
ors,(p::ps,act)::no
|
|
else if condb act_q ps qs then (* check condition (b) for append *)
|
|
attempt (cl::seen) rem
|
|
else
|
|
ors,(p::ps,act)::no
|
|
else (* p # q, go on with append/insert *)
|
|
attempt (cl::seen) rem
|
|
end else (* q is not a or-pat, go on with append/insert *)
|
|
attempt (cl::seen) rem
|
|
| _ -> (* [] in fact *)
|
|
(p::ps,act)::ors,no in (* success in appending *)
|
|
attempt [] ors
|
|
|
|
(* Reconstruct default information from half_compiled pm list *)
|
|
|
|
let rec rebuild_matrix pmh = match pmh with
|
|
| Pm pm -> as_matrix pm.cases
|
|
| PmOr {or_matrix=m} -> m
|
|
| PmVar x -> add_omega_column (rebuild_matrix x.inside)
|
|
|
|
let rec rebuild_default nexts def = match nexts with
|
|
| [] -> def
|
|
| (e, pmh)::rem ->
|
|
(add_omega_column (rebuild_matrix pmh), e)::
|
|
rebuild_default rem def
|
|
|
|
let rebuild_nexts arg nexts k =
|
|
List.fold_right
|
|
(fun (e, pm) k -> (e, PmVar {inside=pm ; var_arg=arg})::k)
|
|
nexts k
|
|
|
|
|
|
(*
|
|
Split a matching.
|
|
Splitting is first directed by or-patterns, then by
|
|
tests (e.g. constructors)/variable transitions.
|
|
|
|
The approach is greedy, every split function attempt to
|
|
raise rows as much as possible in the top matrix,
|
|
then splitting applies again to the remaining rows.
|
|
|
|
Some precompilation of or-patterns and
|
|
variable pattern occurs. Mostly this means that bindings
|
|
are performed now, being replaced by let-bindings
|
|
in actions (cf. simplify_cases).
|
|
|
|
Additionally, if the match argument is a variable, matchings whose
|
|
first column is made of variables only are splitted further
|
|
(cf. precompile_var).
|
|
|
|
*)
|
|
|
|
|
|
let rec split_or argo cls args def =
|
|
|
|
let cls = simplify_cases args cls in
|
|
|
|
let rec do_split before ors no = function
|
|
| [] ->
|
|
cons_next
|
|
(List.rev before) (List.rev ors) (List.rev no)
|
|
| ((p::ps,act) as cl)::rem ->
|
|
if up_ok cl no then
|
|
if is_or p then
|
|
let ors, no = insert_or_append p ps act ors no in
|
|
do_split before ors no rem
|
|
else begin
|
|
if up_ok cl ors then
|
|
do_split (cl::before) ors no rem
|
|
else if or_ok p ps ors then
|
|
do_split before (cl::ors) no rem
|
|
else
|
|
do_split before ors (cl::no) rem
|
|
end
|
|
else
|
|
do_split before ors (cl::no) rem
|
|
| _ -> assert false
|
|
|
|
and cons_next yes yesor = function
|
|
| [] ->
|
|
precompile_or argo yes yesor args def []
|
|
| rem ->
|
|
let {me=next ; matrix=matrix ; top_default=def},nexts =
|
|
do_split [] [] [] rem in
|
|
let idef = next_raise_count () in
|
|
precompile_or
|
|
argo yes yesor args
|
|
(cons_default matrix idef def)
|
|
((idef,next)::nexts) in
|
|
|
|
do_split [] [] [] cls
|
|
|
|
(* Ultra-naive spliting, close to semantics, used for extension,
|
|
as potential rebind prevents any kind of optimisation *)
|
|
|
|
and split_naive cls args def k =
|
|
|
|
let rec split_exc cstr0 yes = function
|
|
| [] ->
|
|
let yes = List.rev yes in
|
|
{ me = Pm {cases=yes; args=args; default=def;} ;
|
|
matrix = as_matrix_omega yes ;
|
|
top_default=def},
|
|
k
|
|
| (p::_,_ as cl)::rem ->
|
|
if group_constructor p then
|
|
let cstr = pat_as_constr p in
|
|
if cstr = cstr0 then split_exc cstr0 (cl::yes) rem
|
|
else
|
|
let yes = List.rev yes in
|
|
let {me=next ; matrix=matrix ; top_default=def}, nexts =
|
|
split_exc cstr [cl] rem in
|
|
let idef = next_raise_count () in
|
|
let def = cons_default matrix idef def in
|
|
{ me = Pm {cases=yes; args=args; default=def} ;
|
|
matrix = as_matrix_omega yes ;
|
|
top_default = def; },
|
|
(idef,next)::nexts
|
|
else
|
|
let yes = List.rev yes in
|
|
let {me=next ; matrix=matrix ; top_default=def}, nexts =
|
|
split_noexc [cl] rem in
|
|
let idef = next_raise_count () in
|
|
let def = cons_default matrix idef def in
|
|
{ me = Pm {cases=yes; args=args; default=def} ;
|
|
matrix = as_matrix_omega yes ;
|
|
top_default = def; },
|
|
(idef,next)::nexts
|
|
| _ -> assert false
|
|
|
|
and split_noexc yes = function
|
|
| [] -> precompile_var args (List.rev yes) def k
|
|
| (p::_,_ as cl)::rem ->
|
|
if group_constructor p then
|
|
let yes= List.rev yes in
|
|
let {me=next; matrix=matrix; top_default=def;},nexts =
|
|
split_exc (pat_as_constr p) [cl] rem in
|
|
let idef = next_raise_count () in
|
|
precompile_var
|
|
args yes
|
|
(cons_default matrix idef def)
|
|
((idef,next)::nexts)
|
|
else split_noexc (cl::yes) rem
|
|
| _ -> assert false in
|
|
|
|
match cls with
|
|
| [] -> assert false
|
|
| (p::_,_ as cl)::rem ->
|
|
if group_constructor p then
|
|
split_exc (pat_as_constr p) [cl] rem
|
|
else
|
|
split_noexc [cl] rem
|
|
| _ -> assert false
|
|
|
|
and split_constr cls args def k =
|
|
let ex_pat = what_is_cases cls in
|
|
match ex_pat.pat_desc with
|
|
| Tpat_any -> precompile_var args cls def k
|
|
| Tpat_construct (_,{cstr_tag=Cstr_extension _},_) ->
|
|
split_naive cls args def k
|
|
| _ ->
|
|
|
|
let group = get_group ex_pat in
|
|
|
|
let rec split_ex yes no = function
|
|
| [] ->
|
|
let yes = List.rev yes and no = List.rev no in
|
|
begin match no with
|
|
| [] ->
|
|
{me = Pm {cases=yes ; args=args ; default=def} ;
|
|
matrix = as_matrix yes ;
|
|
top_default = def},
|
|
k
|
|
| cl::rem ->
|
|
begin match yes with
|
|
| [] ->
|
|
(* Could not success in raising up a constr matching up *)
|
|
split_noex [cl] [] rem
|
|
| _ ->
|
|
let {me=next ; matrix=matrix ; top_default=def}, nexts =
|
|
split_noex [cl] [] rem in
|
|
let idef = next_raise_count () in
|
|
let def = cons_default matrix idef def in
|
|
{me = Pm {cases=yes ; args=args ; default=def} ;
|
|
matrix = as_matrix yes ;
|
|
top_default = def },
|
|
(idef, next)::nexts
|
|
end
|
|
end
|
|
| (p::_,_) as cl::rem ->
|
|
if group p && up_ok cl no then
|
|
split_ex (cl::yes) no rem
|
|
else
|
|
split_ex yes (cl::no) rem
|
|
| _ -> assert false
|
|
|
|
and split_noex yes no = function
|
|
| [] ->
|
|
let yes = List.rev yes and no = List.rev no in
|
|
begin match no with
|
|
| [] -> precompile_var args yes def k
|
|
| cl::rem ->
|
|
let {me=next ; matrix=matrix ; top_default=def}, nexts =
|
|
split_ex [cl] [] rem in
|
|
let idef = next_raise_count () in
|
|
precompile_var
|
|
args yes
|
|
(cons_default matrix idef def)
|
|
((idef,next)::nexts)
|
|
end
|
|
| [ps,_ as cl]
|
|
when List.for_all group_var ps && yes <> [] ->
|
|
(* This enables an extra division in some frequent case :
|
|
last row is made of variables only *)
|
|
split_noex yes (cl::no) []
|
|
| (p::_,_) as cl::rem ->
|
|
if not (group p) && up_ok cl no then
|
|
split_noex (cl::yes) no rem
|
|
else
|
|
split_noex yes (cl::no) rem
|
|
| _ -> assert false in
|
|
|
|
match cls with
|
|
| ((p::_,_) as cl)::rem ->
|
|
if group p then split_ex [cl] [] rem
|
|
else split_noex [cl] [] rem
|
|
| _ -> assert false
|
|
|
|
and precompile_var args cls def k = match args with
|
|
| [] -> assert false
|
|
| _::((Lvar v as av,_) as arg)::rargs ->
|
|
begin match cls with
|
|
| [ps,_] -> (* as splitted as it can *)
|
|
dont_precompile_var args cls def k
|
|
| _ ->
|
|
(* Precompile *)
|
|
let var_cls =
|
|
List.map
|
|
(fun (ps,act) -> match ps with
|
|
| _::ps -> ps,act | _ -> assert false)
|
|
cls
|
|
and var_def = make_default (fun _ rem -> rem) def in
|
|
let {me=first ; matrix=matrix}, nexts =
|
|
split_or (Some v) var_cls (arg::rargs) var_def in
|
|
|
|
(* Compute top information *)
|
|
match nexts with
|
|
| [] -> (* If you need *)
|
|
dont_precompile_var args cls def k
|
|
| _ ->
|
|
let rfirst =
|
|
{me = PmVar {inside=first ; var_arg = av} ;
|
|
matrix = add_omega_column matrix ;
|
|
top_default = rebuild_default nexts def ; }
|
|
and rnexts = rebuild_nexts av nexts k in
|
|
rfirst, rnexts
|
|
end
|
|
| _ ->
|
|
dont_precompile_var args cls def k
|
|
|
|
and dont_precompile_var args cls def k =
|
|
{me = Pm {cases = cls ; args = args ; default = def } ;
|
|
matrix=as_matrix cls ;
|
|
top_default=def},k
|
|
|
|
and is_exc p = match p.pat_desc with
|
|
| Tpat_or (p1,p2,_) -> is_exc p1 || is_exc p2
|
|
| Tpat_alias (p,v,_) -> is_exc p
|
|
| Tpat_construct (_,{cstr_tag=Cstr_extension _},_) -> true
|
|
| _ -> false
|
|
|
|
and precompile_or argo cls ors args def k = match ors with
|
|
| [] -> split_constr cls args def k
|
|
| _ ->
|
|
let rec do_cases = function
|
|
| ({pat_desc=Tpat_or _} as orp::patl, action)::rem ->
|
|
let do_opt = not (is_exc orp) in
|
|
let others,rem =
|
|
if do_opt then get_equiv orp rem
|
|
else [],rem in
|
|
let orpm =
|
|
{cases =
|
|
(patl, action)::
|
|
List.map
|
|
(function
|
|
| (_::ps,action) -> ps,action
|
|
| _ -> assert false)
|
|
others ;
|
|
args = (match args with _::r -> r | _ -> assert false) ;
|
|
default = default_compat (if do_opt then orp else omega) def} in
|
|
let vars =
|
|
IdentSet.elements
|
|
(IdentSet.inter
|
|
(extract_vars IdentSet.empty orp)
|
|
(pm_free_variables orpm)) in
|
|
let or_num = next_raise_count () in
|
|
let new_patl = Parmatch.omega_list patl in
|
|
|
|
let mk_new_action vs =
|
|
Lstaticraise
|
|
(or_num, List.map (fun v -> Lvar v) vs) in
|
|
|
|
let do_optrec,body,handlers = do_cases rem in
|
|
do_opt && do_optrec,
|
|
explode_or_pat
|
|
argo new_patl mk_new_action body vars [] orp,
|
|
let mat = if do_opt then [[orp]] else [[omega]] in
|
|
((mat, or_num, vars , orpm):: handlers)
|
|
| cl::rem ->
|
|
let b,new_ord,new_to_catch = do_cases rem in
|
|
b,cl::new_ord,new_to_catch
|
|
| [] -> true,[],[] in
|
|
|
|
let do_opt,end_body, handlers = do_cases ors in
|
|
let matrix = (if do_opt then as_matrix else as_matrix_omega) (cls@ors)
|
|
and body = {cases=cls@end_body ; args=args ; default=def} in
|
|
{me = PmOr {body=body ; handlers=handlers ; or_matrix=matrix} ;
|
|
matrix=matrix ;
|
|
top_default=def},
|
|
k
|
|
|
|
let split_precompile argo pm =
|
|
let {me=next}, nexts = split_or argo pm.cases pm.args pm.default in
|
|
if dbg && (nexts <> [] || (match next with PmOr _ -> true | _ -> false))
|
|
then begin
|
|
prerr_endline "** SPLIT **" ;
|
|
pretty_pm pm ;
|
|
pretty_precompiled_res next nexts
|
|
end ;
|
|
next, nexts
|
|
|
|
|
|
(* General divide functions *)
|
|
|
|
let add_line patl_action pm = pm.cases <- patl_action :: pm.cases; pm
|
|
|
|
type cell =
|
|
{pm : pattern_matching ;
|
|
ctx : ctx list ;
|
|
pat : pattern}
|
|
|
|
let add make_matching_fun division eq_key key patl_action args =
|
|
try
|
|
let (_,cell) = List.find (fun (k,_) -> eq_key key k) division in
|
|
cell.pm.cases <- patl_action :: cell.pm.cases;
|
|
division
|
|
with Not_found ->
|
|
let cell = make_matching_fun args in
|
|
cell.pm.cases <- [patl_action] ;
|
|
(key, cell) :: division
|
|
|
|
|
|
let divide make eq_key get_key get_args ctx pm =
|
|
|
|
let rec divide_rec = function
|
|
| (p::patl,action) :: rem ->
|
|
let this_match = divide_rec rem in
|
|
add
|
|
(make p pm.default ctx)
|
|
this_match eq_key (get_key p) (get_args p patl,action) pm.args
|
|
| _ -> [] in
|
|
|
|
divide_rec pm.cases
|
|
|
|
|
|
let divide_line make_ctx make get_args pat ctx pm =
|
|
let rec divide_rec = function
|
|
| (p::patl,action) :: rem ->
|
|
let this_match = divide_rec rem in
|
|
add_line (get_args p patl, action) this_match
|
|
| _ -> make pm.default pm.args in
|
|
|
|
{pm = divide_rec pm.cases ;
|
|
ctx=make_ctx ctx ;
|
|
pat=pat}
|
|
|
|
|
|
|
|
(* Then come various functions,
|
|
There is one set of functions per matching style
|
|
(constants, constructors etc.)
|
|
|
|
- matcher function are arguments to make_default (for defaukt handlers)
|
|
They may raise NoMatch or OrPat and perform the full
|
|
matching (selection + arguments).
|
|
|
|
|
|
- get_args and get_key are for the compiled matrices, note that
|
|
selection and geting arguments are separed.
|
|
|
|
- make_ _matching combines the previous functions for produicing
|
|
new ``pattern_matching'' records.
|
|
*)
|
|
|
|
|
|
|
|
let rec matcher_const cst p rem = match p.pat_desc with
|
|
| Tpat_or (p1,p2,_) ->
|
|
begin try
|
|
matcher_const cst p1 rem with
|
|
| NoMatch -> matcher_const cst p2 rem
|
|
end
|
|
| Tpat_constant c1 when const_compare c1 cst = 0 -> rem
|
|
| Tpat_any -> rem
|
|
| _ -> raise NoMatch
|
|
|
|
let get_key_constant caller = function
|
|
| {pat_desc= Tpat_constant cst} -> cst
|
|
| p ->
|
|
prerr_endline ("BAD: "^caller) ;
|
|
pretty_pat p ;
|
|
assert false
|
|
|
|
let get_args_constant _ rem = rem
|
|
|
|
let make_constant_matching p def ctx = function
|
|
[] -> fatal_error "Matching.make_constant_matching"
|
|
| (_ :: argl) ->
|
|
let def =
|
|
make_default
|
|
(matcher_const (get_key_constant "make" p)) def
|
|
and ctx =
|
|
filter_ctx p ctx in
|
|
{pm = {cases = []; args = argl ; default = def} ;
|
|
ctx = ctx ;
|
|
pat = normalize_pat p}
|
|
|
|
|
|
|
|
|
|
let divide_constant ctx m =
|
|
divide
|
|
make_constant_matching
|
|
(fun c d -> const_compare c d = 0) (get_key_constant "divide")
|
|
get_args_constant
|
|
ctx m
|
|
|
|
(* Matching against a constructor *)
|
|
|
|
|
|
let make_field_args binding_kind arg first_pos last_pos argl =
|
|
let rec make_args pos =
|
|
if pos > last_pos
|
|
then argl
|
|
else (Lprim(Pfield pos, [arg]), binding_kind) :: make_args (pos + 1)
|
|
in make_args first_pos
|
|
|
|
let get_key_constr = function
|
|
| {pat_desc=Tpat_construct (_, cstr,_)} -> cstr.cstr_tag
|
|
| _ -> assert false
|
|
|
|
let get_args_constr p rem = match p with
|
|
| {pat_desc=Tpat_construct (_, _, args)} -> args @ rem
|
|
| _ -> assert false
|
|
|
|
let matcher_constr cstr = match cstr.cstr_arity with
|
|
| 0 ->
|
|
let rec matcher_rec q rem = match q.pat_desc with
|
|
| Tpat_or (p1,p2,_) ->
|
|
begin
|
|
try
|
|
matcher_rec p1 rem
|
|
with
|
|
| NoMatch -> matcher_rec p2 rem
|
|
end
|
|
| Tpat_construct (_, cstr1, []) when cstr.cstr_tag = cstr1.cstr_tag ->
|
|
rem
|
|
| Tpat_any -> rem
|
|
| _ -> raise NoMatch in
|
|
matcher_rec
|
|
| 1 ->
|
|
let rec matcher_rec q rem = match q.pat_desc with
|
|
| Tpat_or (p1,p2,_) ->
|
|
let r1 = try Some (matcher_rec p1 rem) with NoMatch -> None
|
|
and r2 = try Some (matcher_rec p2 rem) with NoMatch -> None in
|
|
begin match r1,r2 with
|
|
| None, None -> raise NoMatch
|
|
| Some r1, None -> r1
|
|
| None, Some r2 -> r2
|
|
| Some (a1::rem1), Some (a2::_) ->
|
|
{a1 with
|
|
pat_loc = Location.none ;
|
|
pat_desc = Tpat_or (a1, a2, None)}::
|
|
rem
|
|
| _, _ -> assert false
|
|
end
|
|
| Tpat_construct (_, cstr1, [arg])
|
|
when cstr.cstr_tag = cstr1.cstr_tag -> arg::rem
|
|
| Tpat_any -> omega::rem
|
|
| _ -> raise NoMatch in
|
|
matcher_rec
|
|
| _ ->
|
|
fun q rem -> match q.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_construct (_, cstr1, args)
|
|
when cstr.cstr_tag = cstr1.cstr_tag -> args @ rem
|
|
| Tpat_any -> Parmatch.omegas cstr.cstr_arity @ rem
|
|
| _ -> raise NoMatch
|
|
|
|
let make_constr_matching p def ctx = function
|
|
[] -> fatal_error "Matching.make_constr_matching"
|
|
| ((arg, mut) :: argl) ->
|
|
let cstr = pat_as_constr p in
|
|
let newargs =
|
|
if cstr.cstr_inlined <> None then
|
|
(arg, Alias) :: argl
|
|
else match cstr.cstr_tag with
|
|
Cstr_constant _ | Cstr_block _ ->
|
|
make_field_args Alias arg 0 (cstr.cstr_arity - 1) argl
|
|
| Cstr_extension _ ->
|
|
make_field_args Alias arg 1 cstr.cstr_arity argl in
|
|
{pm=
|
|
{cases = []; args = newargs;
|
|
default = make_default (matcher_constr cstr) def} ;
|
|
ctx = filter_ctx p ctx ;
|
|
pat=normalize_pat p}
|
|
|
|
|
|
let divide_constructor ctx pm =
|
|
divide
|
|
make_constr_matching
|
|
(=) get_key_constr get_args_constr
|
|
ctx pm
|
|
|
|
(* Matching against a variant *)
|
|
|
|
let rec matcher_variant_const lab p rem = match p.pat_desc with
|
|
| Tpat_or (p1, p2, _) ->
|
|
begin
|
|
try
|
|
matcher_variant_const lab p1 rem
|
|
with
|
|
| NoMatch -> matcher_variant_const lab p2 rem
|
|
end
|
|
| Tpat_variant (lab1,_,_) when lab1=lab -> rem
|
|
| Tpat_any -> rem
|
|
| _ -> raise NoMatch
|
|
|
|
|
|
let make_variant_matching_constant p lab def ctx = function
|
|
[] -> fatal_error "Matching.make_variant_matching_constant"
|
|
| ((arg, mut) :: argl) ->
|
|
let def = make_default (matcher_variant_const lab) def
|
|
and ctx = filter_ctx p ctx in
|
|
{pm={ cases = []; args = argl ; default=def} ;
|
|
ctx=ctx ;
|
|
pat = normalize_pat p}
|
|
|
|
let matcher_variant_nonconst lab p rem = match p.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_variant (lab1,Some arg,_) when lab1=lab -> arg::rem
|
|
| Tpat_any -> omega::rem
|
|
| _ -> raise NoMatch
|
|
|
|
|
|
let make_variant_matching_nonconst p lab def ctx = function
|
|
[] -> fatal_error "Matching.make_variant_matching_nonconst"
|
|
| ((arg, mut) :: argl) ->
|
|
let def = make_default (matcher_variant_nonconst lab) def
|
|
and ctx = filter_ctx p ctx in
|
|
{pm=
|
|
{cases = []; args = (Lprim(Pfield 1, [arg]), Alias) :: argl;
|
|
default=def} ;
|
|
ctx=ctx ;
|
|
pat = normalize_pat p}
|
|
|
|
let divide_variant row ctx {cases = cl; args = al; default=def} =
|
|
let row = Btype.row_repr row in
|
|
let rec divide = function
|
|
({pat_desc = Tpat_variant(lab, pato, _)} as p:: patl, action) :: rem ->
|
|
let variants = divide rem in
|
|
if try Btype.row_field_repr (List.assoc lab row.row_fields) = Rabsent
|
|
with Not_found -> true
|
|
then
|
|
variants
|
|
else begin
|
|
let tag = Btype.hash_variant lab in
|
|
match pato with
|
|
None ->
|
|
add (make_variant_matching_constant p lab def ctx) variants
|
|
(=) (Cstr_constant tag) (patl, action) al
|
|
| Some pat ->
|
|
add (make_variant_matching_nonconst p lab def ctx) variants
|
|
(=) (Cstr_block tag) (pat :: patl, action) al
|
|
end
|
|
| cl -> []
|
|
in
|
|
divide cl
|
|
|
|
(*
|
|
Three ``no-test'' cases
|
|
*)
|
|
|
|
(* Matching against a variable *)
|
|
|
|
let get_args_var _ rem = rem
|
|
|
|
|
|
let make_var_matching def = function
|
|
| [] -> fatal_error "Matching.make_var_matching"
|
|
| _::argl ->
|
|
{cases=[] ;
|
|
args = argl ;
|
|
default= make_default get_args_var def}
|
|
|
|
let divide_var ctx pm =
|
|
divide_line ctx_lshift make_var_matching get_args_var omega ctx pm
|
|
|
|
(* Matching and forcing a lazy value *)
|
|
|
|
let get_arg_lazy p rem = match p with
|
|
| {pat_desc = Tpat_any} -> omega :: rem
|
|
| {pat_desc = Tpat_lazy arg} -> arg :: rem
|
|
| _ -> assert false
|
|
|
|
let matcher_lazy p rem = match p.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_var _ -> get_arg_lazy omega rem
|
|
| _ -> get_arg_lazy p rem
|
|
|
|
(* Inlining the tag tests before calling the primitive that works on
|
|
lazy blocks. This is alse used in translcore.ml.
|
|
No call other than Obj.tag when the value has been forced before.
|
|
*)
|
|
|
|
let prim_obj_tag =
|
|
Primitive.simple ~name:"caml_obj_tag" ~arity:1 ~alloc:false
|
|
|
|
let get_mod_field modname field =
|
|
lazy (
|
|
try
|
|
let mod_ident = Ident.create_persistent modname in
|
|
let env = Env.open_pers_signature modname Env.initial_safe_string in
|
|
let p = try
|
|
match Env.lookup_value (Longident.Lident field) env with
|
|
| (Path.Pdot(_,_,i), _) -> i
|
|
| _ -> fatal_error ("Primitive "^modname^"."^field^" not found.")
|
|
with Not_found ->
|
|
fatal_error ("Primitive "^modname^"."^field^" not found.")
|
|
in
|
|
Lprim(Pfield p, [Lprim(Pgetglobal mod_ident, [])])
|
|
with Not_found -> fatal_error ("Module "^modname^" unavailable.")
|
|
)
|
|
|
|
let code_force_lazy_block =
|
|
get_mod_field "CamlinternalLazy" "force_lazy_block"
|
|
;;
|
|
|
|
(* inline_lazy_force inlines the beginning of the code of Lazy.force. When
|
|
the value argument is tagged as:
|
|
- forward, take field 0
|
|
- lazy, call the primitive that forces (without testing again the tag)
|
|
- anything else, return it
|
|
|
|
Using Lswitch below relies on the fact that the GC does not shortcut
|
|
Forward(val_out_of_heap).
|
|
*)
|
|
|
|
let inline_lazy_force_cond arg loc =
|
|
let idarg = Ident.create "lzarg" in
|
|
let varg = Lvar idarg in
|
|
let tag = Ident.create "tag" in
|
|
let force_fun = Lazy.force code_force_lazy_block in
|
|
Llet(Strict, idarg, arg,
|
|
Llet(Alias, tag, Lprim(Pccall prim_obj_tag, [varg]),
|
|
Lifthenelse(
|
|
(* if (tag == Obj.forward_tag) then varg.(0) else ... *)
|
|
Lprim(Pintcomp Ceq,
|
|
[Lvar tag; Lconst(Const_base(Const_int Obj.forward_tag))]),
|
|
Lprim(Pfield 0, [varg]),
|
|
Lifthenelse(
|
|
(* ... if (tag == Obj.lazy_tag) then Lazy.force varg else ... *)
|
|
Lprim(Pintcomp Ceq,
|
|
[Lvar tag; Lconst(Const_base(Const_int Obj.lazy_tag))]),
|
|
Lapply{ap_should_be_tailcall=false;
|
|
ap_loc=loc;
|
|
ap_func=force_fun;
|
|
ap_args=[varg];
|
|
ap_inlined=Default_inline},
|
|
(* ... arg *)
|
|
varg))))
|
|
|
|
let inline_lazy_force_switch arg loc =
|
|
let idarg = Ident.create "lzarg" in
|
|
let varg = Lvar idarg in
|
|
let force_fun = Lazy.force code_force_lazy_block in
|
|
Llet(Strict, idarg, arg,
|
|
Lifthenelse(
|
|
Lprim(Pisint, [varg]), varg,
|
|
(Lswitch
|
|
(varg,
|
|
{ sw_numconsts = 0; sw_consts = [];
|
|
sw_numblocks = 256; (* PR#6033 - tag ranges from 0 to 255 *)
|
|
sw_blocks =
|
|
[ (Obj.forward_tag, Lprim(Pfield 0, [varg]));
|
|
(Obj.lazy_tag,
|
|
Lapply{ap_should_be_tailcall=false;
|
|
ap_loc=loc;
|
|
ap_func=force_fun;
|
|
ap_args=[varg];
|
|
ap_inlined=Default_inline}) ];
|
|
sw_failaction = Some varg } ))))
|
|
|
|
let inline_lazy_force arg loc =
|
|
if !Clflags.native_code then
|
|
(* Lswitch generates compact and efficient native code *)
|
|
inline_lazy_force_switch arg loc
|
|
else
|
|
(* generating bytecode: Lswitch would generate too many rather big
|
|
tables (~ 250 elts); conditionals are better *)
|
|
inline_lazy_force_cond arg loc
|
|
|
|
let make_lazy_matching def = function
|
|
[] -> fatal_error "Matching.make_lazy_matching"
|
|
| (arg,mut) :: argl ->
|
|
{ cases = [];
|
|
args =
|
|
(inline_lazy_force arg Location.none, Strict) :: argl;
|
|
default = make_default matcher_lazy def }
|
|
|
|
let divide_lazy p ctx pm =
|
|
divide_line
|
|
(filter_ctx p)
|
|
make_lazy_matching
|
|
get_arg_lazy
|
|
p ctx pm
|
|
|
|
(* Matching against a tuple pattern *)
|
|
|
|
|
|
let get_args_tuple arity p rem = match p with
|
|
| {pat_desc = Tpat_any} -> omegas arity @ rem
|
|
| {pat_desc = Tpat_tuple args} ->
|
|
args @ rem
|
|
| _ -> assert false
|
|
|
|
let matcher_tuple arity p rem = match p.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_var _ -> get_args_tuple arity omega rem
|
|
| _ -> get_args_tuple arity p rem
|
|
|
|
let make_tuple_matching arity def = function
|
|
[] -> fatal_error "Matching.make_tuple_matching"
|
|
| (arg, mut) :: argl ->
|
|
let rec make_args pos =
|
|
if pos >= arity
|
|
then argl
|
|
else (Lprim(Pfield pos, [arg]), Alias) :: make_args (pos + 1) in
|
|
{cases = []; args = make_args 0 ;
|
|
default=make_default (matcher_tuple arity) def}
|
|
|
|
|
|
let divide_tuple arity p ctx pm =
|
|
divide_line
|
|
(filter_ctx p)
|
|
(make_tuple_matching arity)
|
|
(get_args_tuple arity) p ctx pm
|
|
|
|
(* Matching against a record pattern *)
|
|
|
|
|
|
let record_matching_line num_fields lbl_pat_list =
|
|
let patv = Array.make num_fields omega in
|
|
List.iter (fun (_, lbl, pat) -> patv.(lbl.lbl_pos) <- pat) lbl_pat_list;
|
|
Array.to_list patv
|
|
|
|
let get_args_record num_fields p rem = match p with
|
|
| {pat_desc=Tpat_any} ->
|
|
record_matching_line num_fields [] @ rem
|
|
| {pat_desc=Tpat_record (lbl_pat_list,_)} ->
|
|
record_matching_line num_fields lbl_pat_list @ rem
|
|
| _ -> assert false
|
|
|
|
let matcher_record num_fields p rem = match p.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_var _ -> get_args_record num_fields omega rem
|
|
| _ -> get_args_record num_fields p rem
|
|
|
|
let make_record_matching all_labels def = function
|
|
[] -> fatal_error "Matching.make_record_matching"
|
|
| ((arg, mut) :: argl) ->
|
|
let rec make_args pos =
|
|
if pos >= Array.length all_labels then argl else begin
|
|
let lbl = all_labels.(pos) in
|
|
let access =
|
|
match lbl.lbl_repres with
|
|
Record_regular | Record_inlined _ -> Pfield lbl.lbl_pos
|
|
| Record_float -> Pfloatfield lbl.lbl_pos
|
|
| Record_extension -> Pfield (lbl.lbl_pos + 1)
|
|
in
|
|
let str =
|
|
match lbl.lbl_mut with
|
|
Immutable -> Alias
|
|
| Mutable -> StrictOpt in
|
|
(Lprim(access, [arg]), str) :: make_args(pos + 1)
|
|
end in
|
|
let nfields = Array.length all_labels in
|
|
let def= make_default (matcher_record nfields) def in
|
|
{cases = []; args = make_args 0 ; default = def}
|
|
|
|
|
|
let divide_record all_labels p ctx pm =
|
|
let get_args = get_args_record (Array.length all_labels) in
|
|
divide_line
|
|
(filter_ctx p)
|
|
(make_record_matching all_labels)
|
|
get_args
|
|
p ctx pm
|
|
|
|
(* Matching against an array pattern *)
|
|
|
|
let get_key_array = function
|
|
| {pat_desc=Tpat_array patl} -> List.length patl
|
|
| _ -> assert false
|
|
|
|
let get_args_array p rem = match p with
|
|
| {pat_desc=Tpat_array patl} -> patl@rem
|
|
| _ -> assert false
|
|
|
|
let matcher_array len p rem = match p.pat_desc with
|
|
| Tpat_or (_,_,_) -> raise OrPat
|
|
| Tpat_array args when List.length args=len -> args @ rem
|
|
| Tpat_any -> Parmatch.omegas len @ rem
|
|
| _ -> raise NoMatch
|
|
|
|
let make_array_matching kind p def ctx = function
|
|
| [] -> fatal_error "Matching.make_array_matching"
|
|
| ((arg, mut) :: argl) ->
|
|
let len = get_key_array p in
|
|
let rec make_args pos =
|
|
if pos >= len
|
|
then argl
|
|
else (Lprim(Parrayrefu kind, [arg; Lconst(Const_base(Const_int pos))]),
|
|
StrictOpt) :: make_args (pos + 1) in
|
|
let def = make_default (matcher_array len) def
|
|
and ctx = filter_ctx p ctx in
|
|
{pm={cases = []; args = make_args 0 ; default = def} ;
|
|
ctx=ctx ;
|
|
pat = normalize_pat p}
|
|
|
|
let divide_array kind ctx pm =
|
|
divide
|
|
(make_array_matching kind)
|
|
(=) get_key_array get_args_array ctx pm
|
|
|
|
|
|
(*
|
|
Specific string test sequence
|
|
Will be called by the bytecode compiler, from bytegen.ml.
|
|
The strategy is first dichotomic search (we perform 3-way tests
|
|
with compare_string), then sequence of equality tests
|
|
when there are less then T=strings_test_threshold static strings to match.
|
|
|
|
Increasing T entails (slightly) less code, decreasing T
|
|
(slightly) favors runtime speed.
|
|
T=8 looks a decent tradeoff.
|
|
*)
|
|
|
|
(* Utilities *)
|
|
|
|
let strings_test_threshold = 8
|
|
|
|
let prim_string_notequal =
|
|
Pccall(Primitive.simple
|
|
~name:"caml_string_notequal"
|
|
~arity:2
|
|
~alloc:false)
|
|
|
|
let prim_string_compare =
|
|
Pccall(Primitive.simple
|
|
~name:"caml_string_compare"
|
|
~arity:2
|
|
~alloc:false)
|
|
|
|
let bind_sw arg k = match arg with
|
|
| Lvar _ -> k arg
|
|
| _ ->
|
|
let id = Ident.create "switch" in
|
|
Llet (Strict,id,arg,k (Lvar id))
|
|
|
|
|
|
(* Sequential equality tests *)
|
|
|
|
let make_string_test_sequence arg sw d =
|
|
let d,sw = match d with
|
|
| None ->
|
|
begin match sw with
|
|
| (_,d)::sw -> d,sw
|
|
| [] -> assert false
|
|
end
|
|
| Some d -> d,sw in
|
|
bind_sw arg
|
|
(fun arg ->
|
|
List.fold_right
|
|
(fun (s,lam) k ->
|
|
Lifthenelse
|
|
(Lprim
|
|
(prim_string_notequal,
|
|
[arg; Lconst (Const_immstring s)]),
|
|
k,lam))
|
|
sw d)
|
|
|
|
let rec split k xs = match xs with
|
|
| [] -> assert false
|
|
| x0::xs ->
|
|
if k <= 1 then [],x0,xs
|
|
else
|
|
let xs,y0,ys = split (k-2) xs in
|
|
x0::xs,y0,ys
|
|
|
|
let zero_lam = Lconst (Const_base (Const_int 0))
|
|
|
|
let tree_way_test arg lt eq gt =
|
|
Lifthenelse
|
|
(Lprim (Pintcomp Clt,[arg;zero_lam]),lt,
|
|
Lifthenelse(Lprim (Pintcomp Clt,[zero_lam;arg]),gt,eq))
|
|
|
|
(* Dichotomic tree *)
|
|
|
|
|
|
let rec do_make_string_test_tree arg sw delta d =
|
|
let len = List.length sw in
|
|
if len <= strings_test_threshold+delta then
|
|
make_string_test_sequence arg sw d
|
|
else
|
|
let lt,(s,act),gt = split len sw in
|
|
bind_sw
|
|
(Lprim
|
|
(prim_string_compare,
|
|
[arg; Lconst (Const_immstring s)];))
|
|
(fun r ->
|
|
tree_way_test r
|
|
(do_make_string_test_tree arg lt delta d)
|
|
act
|
|
(do_make_string_test_tree arg gt delta d))
|
|
|
|
(* Entry point *)
|
|
let expand_stringswitch arg sw d = match d with
|
|
| None ->
|
|
bind_sw arg
|
|
(fun arg -> do_make_string_test_tree arg sw 0 None)
|
|
| Some e ->
|
|
bind_sw arg
|
|
(fun arg ->
|
|
make_catch e
|
|
(fun d -> do_make_string_test_tree arg sw 1 (Some d)))
|
|
|
|
(**********************)
|
|
(* Generic test trees *)
|
|
(**********************)
|
|
|
|
(* Sharing *)
|
|
|
|
(* Add handler, if shared *)
|
|
let handle_shared () =
|
|
let hs = ref (fun x -> x) in
|
|
let handle_shared act = match act with
|
|
| Switch.Single act -> act
|
|
| Switch.Shared act ->
|
|
let i,h = make_catch_delayed act in
|
|
let ohs = !hs in
|
|
hs := (fun act -> h (ohs act)) ;
|
|
make_exit i in
|
|
hs,handle_shared
|
|
|
|
|
|
let share_actions_tree sw d =
|
|
let store = StoreExp.mk_store () in
|
|
(* Default action is always shared *)
|
|
let d =
|
|
match d with
|
|
| None -> None
|
|
| Some d -> Some (store.Switch.act_store_shared d) in
|
|
(* Store all other actions *)
|
|
let sw =
|
|
List.map (fun (cst,act) -> cst,store.Switch.act_store act) sw in
|
|
|
|
(* Retrieve all actions, includint potentiel default *)
|
|
let acts = store.Switch.act_get_shared () in
|
|
|
|
(* Array of actual actions *)
|
|
let hs,handle_shared = handle_shared () in
|
|
let acts = Array.map handle_shared acts in
|
|
|
|
(* Recontruct default and switch list *)
|
|
let d = match d with
|
|
| None -> None
|
|
| Some d -> Some (acts.(d)) in
|
|
let sw = List.map (fun (cst,j) -> cst,acts.(j)) sw in
|
|
!hs,sw,d
|
|
|
|
(* Note: dichotomic search requires sorted input with no duplicates *)
|
|
let rec uniq_lambda_list sw = match sw with
|
|
| []|[_] -> sw
|
|
| (c1,_ as p1)::((c2,_)::sw2 as sw1) ->
|
|
if const_compare c1 c2 = 0 then uniq_lambda_list (p1::sw2)
|
|
else p1::uniq_lambda_list sw1
|
|
|
|
let sort_lambda_list l =
|
|
let l =
|
|
List.stable_sort (fun (x,_) (y,_) -> const_compare x y) l in
|
|
uniq_lambda_list l
|
|
|
|
let rec cut n l =
|
|
if n = 0 then [],l
|
|
else match l with
|
|
[] -> raise (Invalid_argument "cut")
|
|
| a::l -> let l1,l2 = cut (n-1) l in a::l1, l2
|
|
|
|
let rec do_tests_fail fail tst arg = function
|
|
| [] -> fail
|
|
| (c, act)::rem ->
|
|
Lifthenelse
|
|
(Lprim (tst, [arg ; Lconst (Const_base c)]),
|
|
do_tests_fail fail tst arg rem,
|
|
act)
|
|
|
|
let rec do_tests_nofail tst arg = function
|
|
| [] -> fatal_error "Matching.do_tests_nofail"
|
|
| [_,act] -> act
|
|
| (c,act)::rem ->
|
|
Lifthenelse
|
|
(Lprim (tst, [arg ; Lconst (Const_base c)]),
|
|
do_tests_nofail tst arg rem,
|
|
act)
|
|
|
|
let make_test_sequence fail tst lt_tst arg const_lambda_list =
|
|
let const_lambda_list = sort_lambda_list const_lambda_list in
|
|
let hs,const_lambda_list,fail =
|
|
share_actions_tree const_lambda_list fail in
|
|
|
|
let rec make_test_sequence const_lambda_list =
|
|
if List.length const_lambda_list >= 4 && lt_tst <> Pignore then
|
|
split_sequence const_lambda_list
|
|
else match fail with
|
|
| None -> do_tests_nofail tst arg const_lambda_list
|
|
| Some fail -> do_tests_fail fail tst arg const_lambda_list
|
|
|
|
and split_sequence const_lambda_list =
|
|
let list1, list2 =
|
|
cut (List.length const_lambda_list / 2) const_lambda_list in
|
|
Lifthenelse(Lprim(lt_tst,[arg; Lconst(Const_base (fst(List.hd list2)))]),
|
|
make_test_sequence list1, make_test_sequence list2)
|
|
in
|
|
hs (make_test_sequence const_lambda_list)
|
|
|
|
|
|
module SArg = struct
|
|
type primitive = Lambda.primitive
|
|
|
|
let eqint = Pintcomp Ceq
|
|
let neint = Pintcomp Cneq
|
|
let leint = Pintcomp Cle
|
|
let ltint = Pintcomp Clt
|
|
let geint = Pintcomp Cge
|
|
let gtint = Pintcomp Cgt
|
|
|
|
type act = Lambda.lambda
|
|
|
|
let make_prim p args = Lprim (p,args)
|
|
let make_offset arg n = match n with
|
|
| 0 -> arg
|
|
| _ -> Lprim (Poffsetint n,[arg])
|
|
|
|
let bind arg body =
|
|
let newvar,newarg = match arg with
|
|
| Lvar v -> v,arg
|
|
| _ ->
|
|
let newvar = Ident.create "switcher" in
|
|
newvar,Lvar newvar in
|
|
bind Alias newvar arg (body newarg)
|
|
let make_const i = Lconst (Const_base (Const_int i))
|
|
let make_isout h arg = Lprim (Pisout, [h ; arg])
|
|
let make_isin h arg = Lprim (Pnot,[make_isout h arg])
|
|
let make_if cond ifso ifnot = Lifthenelse (cond, ifso, ifnot)
|
|
let make_switch arg cases acts =
|
|
let l = ref [] in
|
|
for i = Array.length cases-1 downto 0 do
|
|
l := (i,acts.(cases.(i))) :: !l
|
|
done ;
|
|
Lswitch(arg,
|
|
{sw_numconsts = Array.length cases ; sw_consts = !l ;
|
|
sw_numblocks = 0 ; sw_blocks = [] ;
|
|
sw_failaction = None})
|
|
let make_catch = make_catch_delayed
|
|
let make_exit = make_exit
|
|
|
|
end
|
|
|
|
(* Action sharing for Lswitch argument *)
|
|
let share_actions_sw sw =
|
|
(* Attempt sharing on all actions *)
|
|
let store = StoreExp.mk_store () in
|
|
let fail = match sw.sw_failaction with
|
|
| None -> None
|
|
| Some fail ->
|
|
(* Fail is translated to exit, whatever happens *)
|
|
Some (store.Switch.act_store_shared fail) in
|
|
let consts =
|
|
List.map
|
|
(fun (i,e) -> i,store.Switch.act_store e)
|
|
sw.sw_consts
|
|
and blocks =
|
|
List.map
|
|
(fun (i,e) -> i,store.Switch.act_store e)
|
|
sw.sw_blocks in
|
|
let acts = store.Switch.act_get_shared () in
|
|
let hs,handle_shared = handle_shared () in
|
|
let acts = Array.map handle_shared acts in
|
|
let fail = match fail with
|
|
| None -> None
|
|
| Some fail -> Some (acts.(fail)) in
|
|
!hs,
|
|
{ sw with
|
|
sw_consts = List.map (fun (i,j) -> i,acts.(j)) consts ;
|
|
sw_blocks = List.map (fun (i,j) -> i,acts.(j)) blocks ;
|
|
sw_failaction = fail; }
|
|
|
|
(* Reintroduce fail action in switch argument,
|
|
for the sake of avoiding carrying over huge switches *)
|
|
|
|
let reintroduce_fail sw = match sw.sw_failaction with
|
|
| None ->
|
|
let t = Hashtbl.create 17 in
|
|
let seen (_,l) = match as_simple_exit l with
|
|
| Some i ->
|
|
let old = try Hashtbl.find t i with Not_found -> 0 in
|
|
Hashtbl.replace t i (old+1)
|
|
| None -> () in
|
|
List.iter seen sw.sw_consts ;
|
|
List.iter seen sw.sw_blocks ;
|
|
let i_max = ref (-1)
|
|
and max = ref (-1) in
|
|
Hashtbl.iter
|
|
(fun i c ->
|
|
if c > !max then begin
|
|
i_max := i ;
|
|
max := c
|
|
end) t ;
|
|
if !max >= 3 then
|
|
let default = !i_max in
|
|
let remove =
|
|
List.filter
|
|
(fun (_,lam) -> match as_simple_exit lam with
|
|
| Some j -> j <> default
|
|
| None -> true) in
|
|
{sw with
|
|
sw_consts = remove sw.sw_consts ;
|
|
sw_blocks = remove sw.sw_blocks ;
|
|
sw_failaction = Some (make_exit default)}
|
|
else sw
|
|
| Some _ -> sw
|
|
|
|
|
|
module Switcher = Switch.Make(SArg)
|
|
open Switch
|
|
|
|
let rec last def = function
|
|
| [] -> def
|
|
| [x,_] -> x
|
|
| _::rem -> last def rem
|
|
|
|
let get_edges low high l = match l with
|
|
| [] -> low, high
|
|
| (x,_)::_ -> x, last high l
|
|
|
|
|
|
let as_interval_canfail fail low high l =
|
|
let store = StoreExp.mk_store () in
|
|
|
|
let do_store tag act =
|
|
|
|
let i = store.act_store act in
|
|
(*
|
|
eprintf "STORE [%s] %i %s\n" tag i (string_of_lam act) ;
|
|
*)
|
|
i in
|
|
|
|
let rec nofail_rec cur_low cur_high cur_act = function
|
|
| [] ->
|
|
if cur_high = high then
|
|
[cur_low,cur_high,cur_act]
|
|
else
|
|
[(cur_low,cur_high,cur_act) ; (cur_high+1,high, 0)]
|
|
| ((i,act_i)::rem) as all ->
|
|
let act_index = do_store "NO" act_i in
|
|
if cur_high+1= i then
|
|
if act_index=cur_act then
|
|
nofail_rec cur_low i cur_act rem
|
|
else if act_index=0 then
|
|
(cur_low,i-1, cur_act)::fail_rec i i rem
|
|
else
|
|
(cur_low, i-1, cur_act)::nofail_rec i i act_index rem
|
|
else if act_index = 0 then
|
|
(cur_low, cur_high, cur_act)::
|
|
fail_rec (cur_high+1) (cur_high+1) all
|
|
else
|
|
(cur_low, cur_high, cur_act)::
|
|
(cur_high+1,i-1,0)::
|
|
nofail_rec i i act_index rem
|
|
|
|
and fail_rec cur_low cur_high = function
|
|
| [] -> [(cur_low, cur_high, 0)]
|
|
| (i,act_i)::rem ->
|
|
let index = do_store "YES" act_i in
|
|
if index=0 then fail_rec cur_low i rem
|
|
else
|
|
(cur_low,i-1,0)::
|
|
nofail_rec i i index rem in
|
|
|
|
let init_rec = function
|
|
| [] -> [low,high,0]
|
|
| (i,act_i)::rem ->
|
|
let index = do_store "INIT" act_i in
|
|
if index=0 then
|
|
fail_rec low i rem
|
|
else
|
|
if low < i then
|
|
(low,i-1,0)::nofail_rec i i index rem
|
|
else
|
|
nofail_rec i i index rem in
|
|
|
|
assert (do_store "FAIL" fail = 0) ; (* fail has action index 0 *)
|
|
let r = init_rec l in
|
|
Array.of_list r, store
|
|
|
|
let as_interval_nofail l =
|
|
let store = StoreExp.mk_store () in
|
|
|
|
let rec i_rec cur_low cur_high cur_act = function
|
|
| [] ->
|
|
[cur_low, cur_high, cur_act]
|
|
| (i,act)::rem ->
|
|
let act_index = store.act_store act in
|
|
if act_index = cur_act then
|
|
i_rec cur_low i cur_act rem
|
|
else
|
|
(cur_low, cur_high, cur_act)::
|
|
i_rec i i act_index rem in
|
|
let inters = match l with
|
|
| (i,act)::rem ->
|
|
let act_index = store.act_store act in
|
|
i_rec i i act_index rem
|
|
| _ -> assert false in
|
|
|
|
Array.of_list inters, store
|
|
|
|
|
|
let sort_int_lambda_list l =
|
|
List.sort
|
|
(fun (i1,_) (i2,_) ->
|
|
if i1 < i2 then -1
|
|
else if i2 < i1 then 1
|
|
else 0)
|
|
l
|
|
|
|
let as_interval fail low high l =
|
|
let l = sort_int_lambda_list l in
|
|
get_edges low high l,
|
|
(match fail with
|
|
| None -> as_interval_nofail l
|
|
| Some act -> as_interval_canfail act low high l)
|
|
|
|
let call_switcher fail arg low high int_lambda_list =
|
|
let edges, (cases, actions) =
|
|
as_interval fail low high int_lambda_list in
|
|
Switcher.zyva edges arg cases actions
|
|
|
|
|
|
let rec list_as_pat = function
|
|
| [] -> fatal_error "Matching.list_as_pat"
|
|
| [pat] -> pat
|
|
| pat::rem ->
|
|
{pat with pat_desc = Tpat_or (pat,list_as_pat rem,None)}
|
|
|
|
|
|
let complete_pats_constrs = function
|
|
| p::_ as pats ->
|
|
List.map
|
|
(pat_of_constr p)
|
|
(complete_constrs p (List.map get_key_constr pats))
|
|
| _ -> assert false
|
|
|
|
|
|
(*
|
|
Following two ``failaction'' function compute n, the trap handler
|
|
to jump to in case of failure of elementary tests
|
|
*)
|
|
|
|
let mk_failaction_neg partial ctx def = match partial with
|
|
| Partial ->
|
|
begin match def with
|
|
| (_,idef)::_ ->
|
|
Some (Lstaticraise (idef,[])),jumps_singleton idef ctx
|
|
| [] ->
|
|
(* Act as Total, this means
|
|
If no appropriate default matrix exists,
|
|
then this switch cannot fail *)
|
|
None, jumps_empty
|
|
end
|
|
| Total ->
|
|
None, jumps_empty
|
|
|
|
|
|
|
|
(* In line with the article and simpler than before *)
|
|
let mk_failaction_pos partial seen ctx defs =
|
|
if dbg then begin
|
|
prerr_endline "**POS**" ;
|
|
pretty_def defs ;
|
|
()
|
|
end ;
|
|
let rec scan_def env to_test defs = match to_test,defs with
|
|
| ([],_)|(_,[]) ->
|
|
List.fold_left
|
|
(fun (klist,jumps) (pats,i)->
|
|
let action = Lstaticraise (i,[]) in
|
|
let klist =
|
|
List.fold_right
|
|
(fun pat r -> (get_key_constr pat,action)::r)
|
|
pats klist
|
|
and jumps =
|
|
jumps_add i (ctx_lub (list_as_pat pats) ctx) jumps in
|
|
klist,jumps)
|
|
([],jumps_empty) env
|
|
| _,(pss,idef)::rem ->
|
|
let now, later =
|
|
List.partition
|
|
(fun (p,p_ctx) -> ctx_match p_ctx pss) to_test in
|
|
match now with
|
|
| [] -> scan_def env to_test rem
|
|
| _ -> scan_def ((List.map fst now,idef)::env) later rem in
|
|
|
|
let fail_pats = complete_pats_constrs seen in
|
|
if List.length fail_pats < 32 then begin
|
|
let fail,jmps =
|
|
scan_def
|
|
[]
|
|
(List.map
|
|
(fun pat -> pat, ctx_lub pat ctx)
|
|
fail_pats)
|
|
defs in
|
|
if dbg then begin
|
|
eprintf "POSITIVE JUMPS [%i]:\n" (List.length fail_pats);
|
|
pretty_jumps jmps
|
|
end ;
|
|
None,fail,jmps
|
|
end else begin (* Two many non-matched constructors -> reduced information *)
|
|
if dbg then eprintf "POS->NEG!!!\n%!" ;
|
|
let fail,jumps = mk_failaction_neg partial ctx defs in
|
|
if dbg then
|
|
eprintf "FAIL: %s\n"
|
|
(match fail with
|
|
| None -> "<none>"
|
|
| Some lam -> string_of_lam lam) ;
|
|
fail,[],jumps
|
|
end
|
|
|
|
let combine_constant arg cst partial ctx def
|
|
(const_lambda_list, total, pats) =
|
|
let fail, local_jumps =
|
|
mk_failaction_neg partial ctx def in
|
|
let lambda1 =
|
|
match cst with
|
|
| Const_int _ ->
|
|
let int_lambda_list =
|
|
List.map (function Const_int n, l -> n,l | _ -> assert false)
|
|
const_lambda_list in
|
|
call_switcher fail arg min_int max_int int_lambda_list
|
|
| Const_char _ ->
|
|
let int_lambda_list =
|
|
List.map (function Const_char c, l -> (Char.code c, l)
|
|
| _ -> assert false)
|
|
const_lambda_list in
|
|
call_switcher fail arg 0 255 int_lambda_list
|
|
| Const_string _ ->
|
|
(* Note as the bytecode compiler may resort to dichotmic search,
|
|
the clauses of strinswitch are sorted with duplicate removed.
|
|
This partly applies to the native code compiler, which requires
|
|
no duplicates *)
|
|
let const_lambda_list = sort_lambda_list const_lambda_list in
|
|
let sw =
|
|
List.map
|
|
(fun (c,act) -> match c with
|
|
| Const_string (s,_) -> s,act
|
|
| _ -> assert false)
|
|
const_lambda_list in
|
|
let hs,sw,fail = share_actions_tree sw fail in
|
|
hs (Lstringswitch (arg,sw,fail))
|
|
| Const_float _ ->
|
|
make_test_sequence
|
|
fail
|
|
(Pfloatcomp Cneq) (Pfloatcomp Clt)
|
|
arg const_lambda_list
|
|
| Const_int32 _ ->
|
|
make_test_sequence
|
|
fail
|
|
(Pbintcomp(Pint32, Cneq)) (Pbintcomp(Pint32, Clt))
|
|
arg const_lambda_list
|
|
| Const_int64 _ ->
|
|
make_test_sequence
|
|
fail
|
|
(Pbintcomp(Pint64, Cneq)) (Pbintcomp(Pint64, Clt))
|
|
arg const_lambda_list
|
|
| Const_nativeint _ ->
|
|
make_test_sequence
|
|
fail
|
|
(Pbintcomp(Pnativeint, Cneq)) (Pbintcomp(Pnativeint, Clt))
|
|
arg const_lambda_list
|
|
in lambda1,jumps_union local_jumps total
|
|
|
|
|
|
|
|
let split_cases tag_lambda_list =
|
|
let rec split_rec = function
|
|
[] -> ([], [])
|
|
| (cstr, act) :: rem ->
|
|
let (consts, nonconsts) = split_rec rem in
|
|
match cstr with
|
|
Cstr_constant n -> ((n, act) :: consts, nonconsts)
|
|
| Cstr_block n -> (consts, (n, act) :: nonconsts)
|
|
| _ -> assert false in
|
|
let const, nonconst = split_rec tag_lambda_list in
|
|
sort_int_lambda_list const,
|
|
sort_int_lambda_list nonconst
|
|
|
|
let split_extension_cases tag_lambda_list =
|
|
let rec split_rec = function
|
|
[] -> ([], [])
|
|
| (cstr, act) :: rem ->
|
|
let (consts, nonconsts) = split_rec rem in
|
|
match cstr with
|
|
Cstr_extension(path, true) -> ((path, act) :: consts, nonconsts)
|
|
| Cstr_extension(path, false) -> (consts, (path, act) :: nonconsts)
|
|
| _ -> assert false in
|
|
split_rec tag_lambda_list
|
|
|
|
|
|
let combine_constructor arg ex_pat cstr partial ctx def
|
|
(tag_lambda_list, total1, pats) =
|
|
if cstr.cstr_consts < 0 then begin
|
|
(* Special cases for extensions *)
|
|
let fail, local_jumps =
|
|
mk_failaction_neg partial ctx def in
|
|
let lambda1 =
|
|
let consts, nonconsts = split_extension_cases tag_lambda_list in
|
|
let default, consts, nonconsts =
|
|
match fail with
|
|
| None ->
|
|
begin match consts, nonconsts with
|
|
| _, (_, act)::rem -> act, consts, rem
|
|
| (_, act)::rem, _ -> act, rem, nonconsts
|
|
| _ -> assert false
|
|
end
|
|
| Some fail -> fail, consts, nonconsts in
|
|
let nonconst_lambda =
|
|
match nonconsts with
|
|
[] -> default
|
|
| _ ->
|
|
let tag = Ident.create "tag" in
|
|
let tests =
|
|
List.fold_right
|
|
(fun (path, act) rem ->
|
|
Lifthenelse(Lprim(Pintcomp Ceq,
|
|
[Lvar tag;
|
|
transl_path ex_pat.pat_env path]),
|
|
act, rem))
|
|
nonconsts
|
|
default
|
|
in
|
|
Llet(Alias, tag, Lprim(Pfield 0, [arg]), tests)
|
|
in
|
|
List.fold_right
|
|
(fun (path, act) rem ->
|
|
Lifthenelse(Lprim(Pintcomp Ceq,
|
|
[arg; transl_path ex_pat.pat_env path]),
|
|
act, rem))
|
|
consts
|
|
nonconst_lambda
|
|
in
|
|
lambda1, jumps_union local_jumps total1
|
|
end else begin
|
|
(* Regular concrete type *)
|
|
let ncases = List.length tag_lambda_list
|
|
and nconstrs = cstr.cstr_consts + cstr.cstr_nonconsts in
|
|
let sig_complete = ncases = nconstrs in
|
|
let fail_opt,fails,local_jumps =
|
|
if sig_complete then None,[],jumps_empty
|
|
else
|
|
mk_failaction_pos partial pats ctx def in
|
|
|
|
let tag_lambda_list = fails @ tag_lambda_list in
|
|
let (consts, nonconsts) = split_cases tag_lambda_list in
|
|
let lambda1 =
|
|
match fail_opt,same_actions tag_lambda_list with
|
|
| None,Some act -> act (* Identical actions, no failure *)
|
|
| _ ->
|
|
match
|
|
(cstr.cstr_consts, cstr.cstr_nonconsts, consts, nonconsts)
|
|
with
|
|
| (1, 1, [0, act1], [0, act2]) ->
|
|
(* Typically, match on lists, will avoid isint primitive in that
|
|
case *)
|
|
Lifthenelse(arg, act2, act1)
|
|
| (n,0,_,[]) -> (* The type defines constant constructors only *)
|
|
call_switcher fail_opt arg 0 (n-1) consts
|
|
| (n, _, _, _) ->
|
|
let act0 =
|
|
(* = Some act when all non-const constructors match to act *)
|
|
match fail_opt,nonconsts with
|
|
| Some a,[] -> Some a
|
|
| Some _,_ ->
|
|
if List.length nonconsts = cstr.cstr_nonconsts then
|
|
same_actions nonconsts
|
|
else None
|
|
| None,_ -> same_actions nonconsts in
|
|
match act0 with
|
|
| Some act ->
|
|
Lifthenelse
|
|
(Lprim (Pisint, [arg]),
|
|
call_switcher
|
|
fail_opt arg
|
|
0 (n-1) consts,
|
|
act)
|
|
(* Emit a switch, as bytecode implements this sophisticated instruction *)
|
|
| None ->
|
|
let sw =
|
|
{sw_numconsts = cstr.cstr_consts; sw_consts = consts;
|
|
sw_numblocks = cstr.cstr_nonconsts; sw_blocks = nonconsts;
|
|
sw_failaction = fail_opt} in
|
|
let hs,sw = share_actions_sw sw in
|
|
let sw = reintroduce_fail sw in
|
|
hs (Lswitch (arg,sw)) in
|
|
lambda1, jumps_union local_jumps total1
|
|
end
|
|
|
|
let make_test_sequence_variant_constant fail arg int_lambda_list =
|
|
let _, (cases, actions) =
|
|
as_interval fail min_int max_int int_lambda_list in
|
|
Switcher.test_sequence arg cases actions
|
|
|
|
let call_switcher_variant_constant fail arg int_lambda_list =
|
|
call_switcher fail arg min_int max_int int_lambda_list
|
|
|
|
|
|
let call_switcher_variant_constr fail arg int_lambda_list =
|
|
let v = Ident.create "variant" in
|
|
Llet(Alias, v, Lprim(Pfield 0, [arg]),
|
|
call_switcher
|
|
fail (Lvar v) min_int max_int int_lambda_list)
|
|
|
|
let combine_variant row arg partial ctx def (tag_lambda_list, total1, pats) =
|
|
let row = Btype.row_repr row in
|
|
let num_constr = ref 0 in
|
|
if row.row_closed then
|
|
List.iter
|
|
(fun (_, f) ->
|
|
match Btype.row_field_repr f with
|
|
Rabsent | Reither(true, _::_, _, _) -> ()
|
|
| _ -> incr num_constr)
|
|
row.row_fields
|
|
else
|
|
num_constr := max_int;
|
|
let test_int_or_block arg if_int if_block =
|
|
Lifthenelse(Lprim (Pisint, [arg]), if_int, if_block) in
|
|
let sig_complete = List.length tag_lambda_list = !num_constr
|
|
and one_action = same_actions tag_lambda_list in
|
|
let fail, local_jumps =
|
|
if
|
|
sig_complete || (match partial with Total -> true | _ -> false)
|
|
then
|
|
None, jumps_empty
|
|
else
|
|
mk_failaction_neg partial ctx def in
|
|
let (consts, nonconsts) = split_cases tag_lambda_list in
|
|
let lambda1 = match fail, one_action with
|
|
| None, Some act -> act
|
|
| _,_ ->
|
|
match (consts, nonconsts) with
|
|
| ([n, act1], [m, act2]) when fail=None ->
|
|
test_int_or_block arg act1 act2
|
|
| (_, []) -> (* One can compare integers and pointers *)
|
|
make_test_sequence_variant_constant fail arg consts
|
|
| ([], _) ->
|
|
let lam = call_switcher_variant_constr
|
|
fail arg nonconsts in
|
|
(* One must not dereference integers *)
|
|
begin match fail with
|
|
| None -> lam
|
|
| Some fail -> test_int_or_block arg fail lam
|
|
end
|
|
| (_, _) ->
|
|
let lam_const =
|
|
call_switcher_variant_constant
|
|
fail arg consts
|
|
and lam_nonconst =
|
|
call_switcher_variant_constr
|
|
fail arg nonconsts in
|
|
test_int_or_block arg lam_const lam_nonconst
|
|
in
|
|
lambda1, jumps_union local_jumps total1
|
|
|
|
|
|
let combine_array arg kind partial ctx def
|
|
(len_lambda_list, total1, pats) =
|
|
let fail, local_jumps = mk_failaction_neg partial ctx def in
|
|
let lambda1 =
|
|
let newvar = Ident.create "len" in
|
|
let switch =
|
|
call_switcher
|
|
fail (Lvar newvar)
|
|
0 max_int len_lambda_list in
|
|
bind
|
|
Alias newvar (Lprim(Parraylength kind, [arg])) switch in
|
|
lambda1, jumps_union local_jumps total1
|
|
|
|
(* Insertion of debugging events *)
|
|
|
|
let rec event_branch repr lam =
|
|
begin match lam, repr with
|
|
(_, None) ->
|
|
lam
|
|
| (Levent(lam', ev), Some r) ->
|
|
incr r;
|
|
Levent(lam', {lev_loc = ev.lev_loc;
|
|
lev_kind = ev.lev_kind;
|
|
lev_repr = repr;
|
|
lev_env = ev.lev_env})
|
|
| (Llet(str, id, lam, body), _) ->
|
|
Llet(str, id, lam, event_branch repr body)
|
|
| Lstaticraise _,_ -> lam
|
|
| (_, Some r) ->
|
|
Printlambda.lambda Format.str_formatter lam ;
|
|
fatal_error
|
|
("Matching.event_branch: "^Format.flush_str_formatter ())
|
|
end
|
|
|
|
|
|
(*
|
|
This exception is raised when the compiler cannot produce code
|
|
because control cannot reach the compiled clause,
|
|
|
|
Unused is raised initialy in compile_test.
|
|
|
|
compile_list (for compiling switch results) catch Unused
|
|
|
|
comp_match_handlers (for compililing splitted matches)
|
|
may reraise Unused
|
|
|
|
|
|
*)
|
|
|
|
exception Unused
|
|
|
|
let compile_list compile_fun division =
|
|
|
|
let rec c_rec totals = function
|
|
| [] -> [], jumps_unions totals, []
|
|
| (key, cell) :: rem ->
|
|
begin match cell.ctx with
|
|
| [] -> c_rec totals rem
|
|
| _ ->
|
|
try
|
|
let (lambda1, total1) = compile_fun cell.ctx cell.pm in
|
|
let c_rem, total, new_pats =
|
|
c_rec
|
|
(jumps_map ctx_combine total1::totals) rem in
|
|
((key,lambda1)::c_rem), total, (cell.pat::new_pats)
|
|
with
|
|
| Unused -> c_rec totals rem
|
|
end in
|
|
c_rec [] division
|
|
|
|
|
|
let compile_orhandlers compile_fun lambda1 total1 ctx to_catch =
|
|
let rec do_rec r total_r = function
|
|
| [] -> r,total_r
|
|
| (mat,i,vars,pm)::rem ->
|
|
begin try
|
|
let ctx = select_columns mat ctx in
|
|
let handler_i, total_i = compile_fun ctx pm in
|
|
match raw_action r with
|
|
| Lstaticraise (j,args) ->
|
|
if i=j then
|
|
List.fold_right2 (bind Alias) vars args handler_i,
|
|
jumps_map (ctx_rshift_num (ncols mat)) total_i
|
|
else
|
|
do_rec r total_r rem
|
|
| _ ->
|
|
do_rec
|
|
(Lstaticcatch (r,(i,vars), handler_i))
|
|
(jumps_union
|
|
(jumps_remove i total_r)
|
|
(jumps_map (ctx_rshift_num (ncols mat)) total_i))
|
|
rem
|
|
with
|
|
| Unused ->
|
|
do_rec (Lstaticcatch (r, (i,vars), lambda_unit)) total_r rem
|
|
end in
|
|
do_rec lambda1 total1 to_catch
|
|
|
|
|
|
let compile_test compile_fun partial divide combine ctx to_match =
|
|
let division = divide ctx to_match in
|
|
let c_div = compile_list compile_fun division in
|
|
match c_div with
|
|
| [],_,_ ->
|
|
begin match mk_failaction_neg partial ctx to_match.default with
|
|
| None,_ -> raise Unused
|
|
| Some l,total -> l,total
|
|
end
|
|
| _ ->
|
|
combine ctx to_match.default c_div
|
|
|
|
(* Attempt to avoid some useless bindings by lowering them *)
|
|
|
|
(* Approximation of v present in lam *)
|
|
let rec approx_present v = function
|
|
| Lconst _ -> false
|
|
| Lstaticraise (_,args) ->
|
|
List.exists (fun lam -> approx_present v lam) args
|
|
| Lprim (_,args) ->
|
|
List.exists (fun lam -> approx_present v lam) args
|
|
| Llet (Alias, _, l1, l2) ->
|
|
approx_present v l1 || approx_present v l2
|
|
| Lvar vv -> Ident.same v vv
|
|
| _ -> true
|
|
|
|
let rec lower_bind v arg lam = match lam with
|
|
| Lifthenelse (cond, ifso, ifnot) ->
|
|
let pcond = approx_present v cond
|
|
and pso = approx_present v ifso
|
|
and pnot = approx_present v ifnot in
|
|
begin match pcond, pso, pnot with
|
|
| false, false, false -> lam
|
|
| false, true, false ->
|
|
Lifthenelse (cond, lower_bind v arg ifso, ifnot)
|
|
| false, false, true ->
|
|
Lifthenelse (cond, ifso, lower_bind v arg ifnot)
|
|
| _,_,_ -> bind Alias v arg lam
|
|
end
|
|
| Lswitch (ls,({sw_consts=[i,act] ; sw_blocks = []} as sw))
|
|
when not (approx_present v ls) ->
|
|
Lswitch (ls, {sw with sw_consts = [i,lower_bind v arg act]})
|
|
| Lswitch (ls,({sw_consts=[] ; sw_blocks = [i,act]} as sw))
|
|
when not (approx_present v ls) ->
|
|
Lswitch (ls, {sw with sw_blocks = [i,lower_bind v arg act]})
|
|
| Llet (Alias, vv, lv, l) ->
|
|
if approx_present v lv then
|
|
bind Alias v arg lam
|
|
else
|
|
Llet (Alias, vv, lv, lower_bind v arg l)
|
|
| _ ->
|
|
bind Alias v arg lam
|
|
|
|
let bind_check str v arg lam = match str,arg with
|
|
| _, Lvar _ ->bind str v arg lam
|
|
| Alias,_ -> lower_bind v arg lam
|
|
| _,_ -> bind str v arg lam
|
|
|
|
let comp_exit ctx m = match m.default with
|
|
| (_,i)::_ -> Lstaticraise (i,[]), jumps_singleton i ctx
|
|
| _ -> fatal_error "Matching.comp_exit"
|
|
|
|
|
|
|
|
let rec comp_match_handlers comp_fun partial ctx arg first_match next_matchs =
|
|
match next_matchs with
|
|
| [] -> comp_fun partial ctx arg first_match
|
|
| rem ->
|
|
let rec c_rec body total_body = function
|
|
| [] -> body, total_body
|
|
(* Hum, -1 meant never taken
|
|
| (-1,pm)::rem -> c_rec body total_body rem *)
|
|
| (i,pm)::rem ->
|
|
let ctx_i,total_rem = jumps_extract i total_body in
|
|
begin match ctx_i with
|
|
| [] -> c_rec body total_body rem
|
|
| _ ->
|
|
try
|
|
let li,total_i =
|
|
comp_fun
|
|
(match rem with [] -> partial | _ -> Partial)
|
|
ctx_i arg pm in
|
|
c_rec
|
|
(Lstaticcatch (body,(i,[]),li))
|
|
(jumps_union total_i total_rem)
|
|
rem
|
|
with
|
|
| Unused ->
|
|
c_rec (Lstaticcatch (body,(i,[]),lambda_unit))
|
|
total_rem rem
|
|
end in
|
|
try
|
|
let first_lam,total = comp_fun Partial ctx arg first_match in
|
|
c_rec first_lam total rem
|
|
with Unused -> match next_matchs with
|
|
| [] -> raise Unused
|
|
| (_,x)::xs -> comp_match_handlers comp_fun partial ctx arg x xs
|
|
|
|
(* To find reasonable names for variables *)
|
|
|
|
let rec name_pattern default = function
|
|
(pat :: patl, action) :: rem ->
|
|
begin match pat.pat_desc with
|
|
Tpat_var (id, _) -> id
|
|
| Tpat_alias(p, id, _) -> id
|
|
| _ -> name_pattern default rem
|
|
end
|
|
| _ -> Ident.create default
|
|
|
|
let arg_to_var arg cls = match arg with
|
|
| Lvar v -> v,arg
|
|
| _ ->
|
|
let v = name_pattern "match" cls in
|
|
v,Lvar v
|
|
|
|
|
|
(*
|
|
The main compilation function.
|
|
Input:
|
|
repr=used for inserting debug events
|
|
partial=exhaustiveness information from Parmatch
|
|
ctx=a context
|
|
m=a pattern matching
|
|
|
|
Output: a lambda term, a jump summary {..., exit number -> context, .. }
|
|
*)
|
|
|
|
let rec compile_match repr partial ctx m = match m with
|
|
| { cases = [] } -> comp_exit ctx m
|
|
| { cases = ([], action) :: rem } ->
|
|
if is_guarded action then begin
|
|
let (lambda, total) =
|
|
compile_match None partial ctx { m with cases = rem } in
|
|
event_branch repr (patch_guarded lambda action), total
|
|
end else
|
|
(event_branch repr action, jumps_empty)
|
|
| { args = (arg, str)::argl } ->
|
|
let v,newarg = arg_to_var arg m.cases in
|
|
let first_match,rem =
|
|
split_precompile (Some v)
|
|
{ m with args = (newarg, Alias) :: argl } in
|
|
let (lam, total) =
|
|
comp_match_handlers
|
|
((if dbg then do_compile_matching_pr else do_compile_matching) repr)
|
|
partial ctx newarg first_match rem in
|
|
bind_check str v arg lam, total
|
|
| _ -> assert false
|
|
|
|
|
|
(* verbose version of do_compile_matching, for debug *)
|
|
|
|
and do_compile_matching_pr repr partial ctx arg x =
|
|
prerr_string "COMPILE: " ;
|
|
prerr_endline (match partial with Partial -> "Partial" | Total -> "Total") ;
|
|
prerr_endline "MATCH" ;
|
|
pretty_precompiled x ;
|
|
prerr_endline "CTX" ;
|
|
pretty_ctx ctx ;
|
|
let (_, jumps) as r = do_compile_matching repr partial ctx arg x in
|
|
prerr_endline "JUMPS" ;
|
|
pretty_jumps jumps ;
|
|
r
|
|
|
|
and do_compile_matching repr partial ctx arg pmh = match pmh with
|
|
| Pm pm ->
|
|
let pat = what_is_cases pm.cases in
|
|
begin match pat.pat_desc with
|
|
| Tpat_any ->
|
|
compile_no_test
|
|
divide_var ctx_rshift repr partial ctx pm
|
|
| Tpat_tuple patl ->
|
|
compile_no_test
|
|
(divide_tuple (List.length patl) (normalize_pat pat)) ctx_combine
|
|
repr partial ctx pm
|
|
| Tpat_record ((_, lbl,_)::_,_) ->
|
|
compile_no_test
|
|
(divide_record lbl.lbl_all (normalize_pat pat))
|
|
ctx_combine repr partial ctx pm
|
|
| Tpat_constant cst ->
|
|
compile_test
|
|
(compile_match repr partial) partial
|
|
divide_constant
|
|
(combine_constant arg cst partial)
|
|
ctx pm
|
|
| Tpat_construct (_, cstr, _) ->
|
|
compile_test
|
|
(compile_match repr partial) partial
|
|
divide_constructor (combine_constructor arg pat cstr partial)
|
|
ctx pm
|
|
| Tpat_array _ ->
|
|
let kind = Typeopt.array_pattern_kind pat in
|
|
compile_test (compile_match repr partial) partial
|
|
(divide_array kind) (combine_array arg kind partial)
|
|
ctx pm
|
|
| Tpat_lazy _ ->
|
|
compile_no_test
|
|
(divide_lazy (normalize_pat pat))
|
|
ctx_combine repr partial ctx pm
|
|
| Tpat_variant(lab, _, row) ->
|
|
compile_test (compile_match repr partial) partial
|
|
(divide_variant !row)
|
|
(combine_variant !row arg partial)
|
|
ctx pm
|
|
| _ -> assert false
|
|
end
|
|
| PmVar {inside=pmh ; var_arg=arg} ->
|
|
let lam, total =
|
|
do_compile_matching repr partial (ctx_lshift ctx) arg pmh in
|
|
lam, jumps_map ctx_rshift total
|
|
| PmOr {body=body ; handlers=handlers} ->
|
|
let lam, total = compile_match repr partial ctx body in
|
|
compile_orhandlers (compile_match repr partial) lam total ctx handlers
|
|
|
|
and compile_no_test divide up_ctx repr partial ctx to_match =
|
|
let {pm=this_match ; ctx=this_ctx } = divide ctx to_match in
|
|
let lambda,total = compile_match repr partial this_ctx this_match in
|
|
lambda, jumps_map up_ctx total
|
|
|
|
|
|
|
|
|
|
(* The entry points *)
|
|
|
|
(*
|
|
If there is a guard in a matching or a lazy pattern,
|
|
then set exhaustiveness info to Partial.
|
|
(because of side effects, assume the worst).
|
|
|
|
Notice that exhaustiveness information is trusted by the compiler,
|
|
that is, a match flagged as Total should not fail at runtime.
|
|
More specifically, for instance if match y with x::_ -> x uis flagged
|
|
total (as it happens during JoCaml compilation) then y cannot be []
|
|
at runtime. As a consequence, the static Total exhaustiveness information
|
|
have to to be downgraded to Partial, in the dubious cases where guards
|
|
or lazy pattern execute arbitrary code that may perform side effects
|
|
and change the subject values.
|
|
LM:
|
|
Lazy pattern was PR #5992, initial patch by lwp25.
|
|
I have generalized the patch, so as to also find mutable fields.
|
|
*)
|
|
|
|
let find_in_pat pred =
|
|
let rec find_rec p =
|
|
pred p.pat_desc ||
|
|
begin match p.pat_desc with
|
|
| Tpat_alias (p,_,_) | Tpat_variant (_,Some p,_) | Tpat_lazy p ->
|
|
find_rec p
|
|
| Tpat_tuple ps|Tpat_construct (_,_,ps) | Tpat_array ps ->
|
|
List.exists find_rec ps
|
|
| Tpat_record (lpats,_) ->
|
|
List.exists
|
|
(fun (_, _, p) -> find_rec p)
|
|
lpats
|
|
| Tpat_or (p,q,_) ->
|
|
find_rec p || find_rec q
|
|
| Tpat_constant _ | Tpat_var _
|
|
| Tpat_any | Tpat_variant (_,None,_) -> false
|
|
end in
|
|
find_rec
|
|
|
|
let is_lazy_pat = function
|
|
| Tpat_lazy _ -> true
|
|
| Tpat_alias _ | Tpat_variant _ | Tpat_record _
|
|
| Tpat_tuple _|Tpat_construct _ | Tpat_array _
|
|
| Tpat_or _ | Tpat_constant _ | Tpat_var _ | Tpat_any
|
|
-> false
|
|
|
|
let is_lazy p = find_in_pat is_lazy_pat p
|
|
|
|
let have_mutable_field p = match p with
|
|
| Tpat_record (lps,_) ->
|
|
List.exists
|
|
(fun (_,lbl,_) ->
|
|
match lbl.Types.lbl_mut with
|
|
| Mutable -> true
|
|
| Immutable -> false)
|
|
lps
|
|
| Tpat_alias _ | Tpat_variant _ | Tpat_lazy _
|
|
| Tpat_tuple _|Tpat_construct _ | Tpat_array _
|
|
| Tpat_or _
|
|
| Tpat_constant _ | Tpat_var _ | Tpat_any
|
|
-> false
|
|
|
|
let is_mutable p = find_in_pat have_mutable_field p
|
|
|
|
(* Downgrade Total when
|
|
1. Matching accesses some mutable fields;
|
|
2. And there are guards or lazy patterns.
|
|
*)
|
|
|
|
let check_partial is_mutable is_lazy pat_act_list = function
|
|
| Partial -> Partial
|
|
| Total ->
|
|
if
|
|
pat_act_list = [] || (* allow empty case list *)
|
|
List.exists
|
|
(fun (pats, lam) ->
|
|
is_mutable pats && (is_guarded lam || is_lazy pats))
|
|
pat_act_list
|
|
then Partial
|
|
else Total
|
|
|
|
let check_partial_list =
|
|
check_partial (List.exists is_mutable) (List.exists is_lazy)
|
|
let check_partial = check_partial is_mutable is_lazy
|
|
|
|
(* have toplevel handler when appropriate *)
|
|
|
|
let start_ctx n = [{left=[] ; right = omegas n}]
|
|
|
|
let check_total total lambda i handler_fun =
|
|
if jumps_is_empty total then
|
|
lambda
|
|
else begin
|
|
Lstaticcatch(lambda, (i,[]), handler_fun())
|
|
end
|
|
|
|
let compile_matching loc repr handler_fun arg pat_act_list partial =
|
|
let partial = check_partial pat_act_list partial in
|
|
match partial with
|
|
| Partial ->
|
|
let raise_num = next_raise_count () in
|
|
let pm =
|
|
{ cases = List.map (fun (pat, act) -> ([pat], act)) pat_act_list;
|
|
args = [arg, Strict] ;
|
|
default = [[[omega]],raise_num]} in
|
|
begin try
|
|
let (lambda, total) = compile_match repr partial (start_ctx 1) pm in
|
|
check_total total lambda raise_num handler_fun
|
|
with
|
|
| Unused -> assert false (* ; handler_fun() *)
|
|
end
|
|
| Total ->
|
|
let pm =
|
|
{ cases = List.map (fun (pat, act) -> ([pat], act)) pat_act_list;
|
|
args = [arg, Strict] ;
|
|
default = []} in
|
|
let (lambda, total) = compile_match repr partial (start_ctx 1) pm in
|
|
assert (jumps_is_empty total) ;
|
|
lambda
|
|
|
|
|
|
let partial_function loc () =
|
|
(* [Location.get_pos_info] is too expensive *)
|
|
let (fname, line, char) = Location.get_pos_info loc.Location.loc_start in
|
|
Lprim(Praise Raise_regular, [Lprim(Pmakeblock(0, Immutable),
|
|
[transl_normal_path Predef.path_match_failure;
|
|
Lconst(Const_block(0,
|
|
[Const_base(Const_string (fname, None));
|
|
Const_base(Const_int line);
|
|
Const_base(Const_int char)]))])])
|
|
|
|
let for_function loc repr param pat_act_list partial =
|
|
compile_matching loc repr (partial_function loc) param pat_act_list partial
|
|
|
|
(* In the following two cases, exhaustiveness info is not available! *)
|
|
let for_trywith param pat_act_list =
|
|
compile_matching Location.none None
|
|
(fun () -> Lprim(Praise Raise_reraise, [param]))
|
|
param pat_act_list Partial
|
|
|
|
let simple_for_let loc param pat body =
|
|
compile_matching loc None (partial_function loc) param [pat, body] Partial
|
|
|
|
|
|
(* Optimize binding of immediate tuples
|
|
|
|
The goal of the implementation of 'for_let' below, which replaces
|
|
'simple_for_let', is to avoid tuple allocation in cases such as
|
|
this one:
|
|
|
|
let (x,y) =
|
|
let foo = ... in
|
|
if foo then (1, 2) else (3,4)
|
|
in bar
|
|
|
|
The compiler easily optimizes the simple `let (x,y) = (1,2) in ...`
|
|
case (call to Matching.for_multiple_match from Translcore), but
|
|
didn't optimize situations where the rhs tuples are hidden under
|
|
a more complex context.
|
|
|
|
The idea comes from Alain Frisch which suggested and implemented
|
|
the following compilation method, based on Lassign:
|
|
|
|
let x = dummy in let y = dummy in
|
|
begin
|
|
let foo = ... in
|
|
if foo then
|
|
(let x1 = 1 in let y1 = 2 in x <- x1; y <- y1)
|
|
else
|
|
(let x2 = 3 in let y2 = 4 in x <- x2; y <- y2)
|
|
end;
|
|
bar
|
|
|
|
The current implementation from Gabriel Scherer uses Lstaticcatch /
|
|
Lstaticraise instead:
|
|
|
|
catch
|
|
let foo = ... in
|
|
if foo then
|
|
(let x1 = 1 in let y1 = 2 in exit x1 y1)
|
|
else
|
|
(let x2 = 3 in let y2 = 4 in exit x2 y2)
|
|
with x y ->
|
|
bar
|
|
|
|
The catch/exit is used to avoid duplication of the let body ('bar'
|
|
in the example), on 'if' branches for example; it is useless for
|
|
linear contexts such as 'let', but we don't need to be careful to
|
|
generate nice code because Simplif will remove such useless
|
|
catch/exit.
|
|
*)
|
|
|
|
let rec map_return f = function
|
|
| Llet (k, id, l1, l2) -> Llet (k, id, l1, map_return f l2)
|
|
| Lletrec (l1, l2) -> Lletrec (l1, map_return f l2)
|
|
| Lifthenelse (lcond, lthen, lelse) ->
|
|
Lifthenelse (lcond, map_return f lthen, map_return f lelse)
|
|
| Lsequence (l1, l2) -> Lsequence (l1, map_return f l2)
|
|
| Levent (l, ev) -> Levent (map_return f l, ev)
|
|
| Ltrywith (l1, id, l2) -> Ltrywith (map_return f l1, id, map_return f l2)
|
|
| Lstaticcatch (l1, b, l2) -> Lstaticcatch (map_return f l1, b, map_return f l2)
|
|
| Lstaticraise _ | Lprim(Praise _, _) as l -> l
|
|
| l -> f l
|
|
|
|
(* The 'opt' reference indicates if the optimization is worthy.
|
|
|
|
It is shared by the different calls to 'assign_pat' performed from
|
|
'map_return'. For example with the code
|
|
let (x, y) = if foo then z else (1,2)
|
|
the else-branch will activate the optimization for both branches.
|
|
|
|
That means that the optimization is activated if *there exists* an
|
|
interesting tuple in one hole of the let-rhs context. We could
|
|
choose to activate it only if *all* holes are interesting. We made
|
|
that choice because being optimistic is extremely cheap (one static
|
|
exit/catch overhead in the "wrong cases"), while being pessimistic
|
|
can be costly (one unnecessary tuple allocation).
|
|
*)
|
|
|
|
let assign_pat opt nraise catch_ids loc pat lam =
|
|
let rec collect acc pat lam = match pat.pat_desc, lam with
|
|
| Tpat_tuple patl, Lprim(Pmakeblock _, lams) ->
|
|
opt := true;
|
|
List.fold_left2 collect acc patl lams
|
|
| Tpat_tuple patl, Lconst(Const_block(_, scl)) ->
|
|
opt := true;
|
|
let collect_const acc pat sc = collect acc pat (Lconst sc) in
|
|
List.fold_left2 collect_const acc patl scl
|
|
| _ ->
|
|
(* pattern idents will be bound in staticcatch (let body), so we
|
|
refresh them here to guarantee binders uniqueness *)
|
|
let pat_ids = pat_bound_idents pat in
|
|
let fresh_ids = List.map (fun id -> id, Ident.rename id) pat_ids in
|
|
(fresh_ids, alpha_pat fresh_ids pat, lam) :: acc
|
|
in
|
|
|
|
(* sublets were accumulated by 'collect' with the leftmost tuple
|
|
pattern at the bottom of the list; to respect right-to-left
|
|
evaluation order for tuples, we must evaluate sublets
|
|
top-to-bottom. To preserve tail-rec, we will fold_left the
|
|
reversed list. *)
|
|
let rev_sublets = List.rev (collect [] pat lam) in
|
|
let exit =
|
|
(* build an Ident.tbl to avoid quadratic refreshing costs *)
|
|
let add t (id, fresh_id) = Ident.add id fresh_id t in
|
|
let add_ids acc (ids, _pat, _lam) = List.fold_left add acc ids in
|
|
let tbl = List.fold_left add_ids Ident.empty rev_sublets in
|
|
let fresh_var id = Lvar (Ident.find_same id tbl) in
|
|
Lstaticraise(nraise, List.map fresh_var catch_ids)
|
|
in
|
|
let push_sublet code (_ids, pat, lam) = simple_for_let loc lam pat code in
|
|
List.fold_left push_sublet exit rev_sublets
|
|
|
|
let for_let loc param pat body =
|
|
match pat.pat_desc with
|
|
| Tpat_any | Tpat_var _ ->
|
|
(* fast path *)
|
|
simple_for_let loc param pat body
|
|
| _ ->
|
|
let opt = ref false in
|
|
let nraise = next_raise_count () in
|
|
let catch_ids = pat_bound_idents pat in
|
|
let bind = map_return (assign_pat opt nraise catch_ids loc pat) param in
|
|
if !opt then Lstaticcatch(bind, (nraise, catch_ids), body)
|
|
else simple_for_let loc param pat body
|
|
|
|
(* Handling of tupled functions and matchings *)
|
|
|
|
(* Easy case since variables are available *)
|
|
let for_tupled_function loc paraml pats_act_list partial =
|
|
let partial = check_partial_list pats_act_list partial in
|
|
let raise_num = next_raise_count () in
|
|
let omegas = [List.map (fun _ -> omega) paraml] in
|
|
let pm =
|
|
{ cases = pats_act_list;
|
|
args = List.map (fun id -> (Lvar id, Strict)) paraml ;
|
|
default = [omegas,raise_num]
|
|
} in
|
|
try
|
|
let (lambda, total) = compile_match None partial
|
|
(start_ctx (List.length paraml)) pm in
|
|
check_total total lambda raise_num (partial_function loc)
|
|
with
|
|
| Unused -> partial_function loc ()
|
|
|
|
|
|
|
|
let flatten_pattern size p = match p.pat_desc with
|
|
| Tpat_tuple args -> args
|
|
| Tpat_any -> omegas size
|
|
| _ -> raise Cannot_flatten
|
|
|
|
let rec flatten_pat_line size p k = match p.pat_desc with
|
|
| Tpat_any -> omegas size::k
|
|
| Tpat_tuple args -> args::k
|
|
| Tpat_or (p1,p2,_) -> flatten_pat_line size p1 (flatten_pat_line size p2 k)
|
|
| Tpat_alias (p,_,_) -> (* Note: if this 'as' pat is here, then this is a
|
|
useless binding, solves PR #3780 *)
|
|
flatten_pat_line size p k
|
|
| _ -> fatal_error "Matching.flatten_pat_line"
|
|
|
|
let flatten_cases size cases =
|
|
List.map
|
|
(fun (ps,action) -> match ps with
|
|
| [p] -> flatten_pattern size p,action
|
|
| _ -> fatal_error "Matching.flatten_case")
|
|
cases
|
|
|
|
let flatten_matrix size pss =
|
|
List.fold_right
|
|
(fun ps r -> match ps with
|
|
| [p] -> flatten_pat_line size p r
|
|
| _ -> fatal_error "Matching.flatten_matrix")
|
|
pss []
|
|
|
|
let flatten_def size def =
|
|
List.map
|
|
(fun (pss,i) -> flatten_matrix size pss,i)
|
|
def
|
|
|
|
let flatten_pm size args pm =
|
|
{args = args ; cases = flatten_cases size pm.cases ;
|
|
default = flatten_def size pm.default}
|
|
|
|
|
|
let flatten_precompiled size args pmh = match pmh with
|
|
| Pm pm -> Pm (flatten_pm size args pm)
|
|
| PmOr {body=b ; handlers=hs ; or_matrix=m} ->
|
|
PmOr
|
|
{body=flatten_pm size args b ;
|
|
handlers=
|
|
List.map
|
|
(fun (mat,i,vars,pm) -> flatten_matrix size mat,i,vars,pm)
|
|
hs ;
|
|
or_matrix=flatten_matrix size m ;}
|
|
| PmVar _ -> assert false
|
|
|
|
(*
|
|
compiled_flattened is a ``comp_fun'' argument to comp_match_handlers.
|
|
Hence it needs a fourth argument, which it ignores
|
|
*)
|
|
|
|
let compile_flattened repr partial ctx _ pmh = match pmh with
|
|
| Pm pm -> compile_match repr partial ctx pm
|
|
| PmOr {body=b ; handlers=hs} ->
|
|
let lam, total = compile_match repr partial ctx b in
|
|
compile_orhandlers (compile_match repr partial) lam total ctx hs
|
|
| PmVar _ -> assert false
|
|
|
|
let do_for_multiple_match loc paraml pat_act_list partial =
|
|
let repr = None in
|
|
let partial = check_partial pat_act_list partial in
|
|
let raise_num,pm1 =
|
|
match partial with
|
|
| Partial ->
|
|
let raise_num = next_raise_count () in
|
|
raise_num,
|
|
{ cases = List.map (fun (pat, act) -> ([pat], act)) pat_act_list;
|
|
args = [Lprim(Pmakeblock(0, Immutable), paraml), Strict] ;
|
|
default = [[[omega]],raise_num] }
|
|
| _ ->
|
|
-1,
|
|
{ cases = List.map (fun (pat, act) -> ([pat], act)) pat_act_list;
|
|
args = [Lprim(Pmakeblock(0, Immutable), paraml), Strict] ;
|
|
default = [] } in
|
|
|
|
try
|
|
try
|
|
(* Once for checking that compilation is possible *)
|
|
let next, nexts = split_precompile None pm1 in
|
|
|
|
let size = List.length paraml
|
|
and idl = List.map (fun _ -> Ident.create "match") paraml in
|
|
let args = List.map (fun id -> Lvar id, Alias) idl in
|
|
|
|
let flat_next = flatten_precompiled size args next
|
|
and flat_nexts =
|
|
List.map
|
|
(fun (e,pm) -> e,flatten_precompiled size args pm)
|
|
nexts in
|
|
|
|
let lam, total =
|
|
comp_match_handlers
|
|
(compile_flattened repr)
|
|
partial (start_ctx size) () flat_next flat_nexts in
|
|
List.fold_right2 (bind Strict) idl paraml
|
|
(match partial with
|
|
| Partial ->
|
|
check_total total lam raise_num (partial_function loc)
|
|
| Total ->
|
|
assert (jumps_is_empty total) ;
|
|
lam)
|
|
with Cannot_flatten ->
|
|
let (lambda, total) = compile_match None partial (start_ctx 1) pm1 in
|
|
begin match partial with
|
|
| Partial ->
|
|
check_total total lambda raise_num (partial_function loc)
|
|
| Total ->
|
|
assert (jumps_is_empty total) ;
|
|
lambda
|
|
end
|
|
with Unused ->
|
|
assert false (* ; partial_function loc () *)
|
|
|
|
(* #PR4828: Believe it or not, the 'paraml' argument below
|
|
may not be side effect free. *)
|
|
|
|
let param_to_var param = match param with
|
|
| Lvar v -> v,None
|
|
| _ -> Ident.create "match",Some param
|
|
|
|
let bind_opt (v,eo) k = match eo with
|
|
| None -> k
|
|
| Some e -> Lambda.bind Strict v e k
|
|
|
|
let for_multiple_match loc paraml pat_act_list partial =
|
|
let v_paraml = List.map param_to_var paraml in
|
|
let paraml = List.map (fun (v,_) -> Lvar v) v_paraml in
|
|
List.fold_right bind_opt v_paraml
|
|
(do_for_multiple_match loc paraml pat_act_list partial)
|