2088 lines
73 KiB
OCaml
2088 lines
73 KiB
OCaml
(***********************************************************************)
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(* *)
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(* Objective Caml *)
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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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(* $Id$ *)
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(* Translation from closed lambda to C-- *)
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open Misc
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open Arch
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open Asttypes
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open Primitive
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open Types
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open Lambda
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open Clambda
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open Cmm
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(* Local binding of complex expressions *)
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let bind name arg fn =
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match arg with
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Cvar _ | Cconst_int _ | Cconst_natint _ | Cconst_symbol _
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| Cconst_pointer _ | Cconst_natpointer _ -> fn arg
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| _ -> let id = Ident.create name in Clet(id, arg, fn (Cvar id))
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let bind_nonvar name arg fn =
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match arg with
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Cconst_int _ | Cconst_natint _ | Cconst_symbol _
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| Cconst_pointer _ | Cconst_natpointer _ -> fn arg
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| _ -> let id = Ident.create name in Clet(id, arg, fn (Cvar id))
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(* Block headers. Meaning of the tag field: see stdlib/obj.ml *)
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let float_tag = Cconst_int Obj.double_tag
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let floatarray_tag = Cconst_int Obj.double_array_tag
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let block_header tag sz =
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Nativeint.add (Nativeint.shift_left (Nativeint.of_int sz) 10)
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(Nativeint.of_int tag)
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let closure_header sz = block_header Obj.closure_tag sz
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let infix_header ofs = block_header Obj.infix_tag ofs
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let float_header = block_header Obj.double_tag (size_float / size_addr)
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let floatarray_header len =
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block_header Obj.double_array_tag (len * size_float / size_addr)
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let string_header len =
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block_header Obj.string_tag ((len + size_addr) / size_addr)
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let boxedint32_header = block_header Obj.custom_tag 2
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let boxedint64_header = block_header Obj.custom_tag (1 + 8 / size_addr)
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let boxedintnat_header = block_header Obj.custom_tag 2
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let alloc_block_header tag sz = Cconst_natint(block_header tag sz)
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let alloc_float_header = Cconst_natint(float_header)
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let alloc_floatarray_header len = Cconst_natint(floatarray_header len)
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let alloc_closure_header sz = Cconst_natint(closure_header sz)
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let alloc_infix_header ofs = Cconst_natint(infix_header ofs)
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let alloc_boxedint32_header = Cconst_natint(boxedint32_header)
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let alloc_boxedint64_header = Cconst_natint(boxedint64_header)
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let alloc_boxedintnat_header = Cconst_natint(boxedintnat_header)
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(* Integers *)
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let max_repr_int = max_int asr 1
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let min_repr_int = min_int asr 1
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let int_const n =
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if n <= max_repr_int && n >= min_repr_int
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then Cconst_int((n lsl 1) + 1)
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else Cconst_natint
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(Nativeint.add (Nativeint.shift_left (Nativeint.of_int n) 1) 1n)
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let add_const c n =
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if n = 0 then c else Cop(Caddi, [c; Cconst_int n])
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let incr_int = function
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Cconst_int n when n < max_int -> Cconst_int(n+1)
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| Cop(Caddi, [c; Cconst_int n]) when n < max_int -> add_const c (n + 1)
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| c -> add_const c 1
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let decr_int = function
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Cconst_int n when n > min_int -> Cconst_int(n-1)
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| Cop(Caddi, [c; Cconst_int n]) when n > min_int -> add_const c (n - 1)
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| c -> add_const c (-1)
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let add_int c1 c2 =
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match (c1, c2) with
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(Cop(Caddi, [c1; Cconst_int n1]),
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Cop(Caddi, [c2; Cconst_int n2])) when no_overflow_add n1 n2 ->
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add_const (Cop(Caddi, [c1; c2])) (n1 + n2)
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| (Cop(Caddi, [c1; Cconst_int n1]), c2) ->
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add_const (Cop(Caddi, [c1; c2])) n1
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| (c1, Cop(Caddi, [c2; Cconst_int n2])) ->
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add_const (Cop(Caddi, [c1; c2])) n2
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| (Cconst_int _, _) ->
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Cop(Caddi, [c2; c1])
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| (_, _) ->
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Cop(Caddi, [c1; c2])
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let sub_int c1 c2 =
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match (c1, c2) with
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(Cop(Caddi, [c1; Cconst_int n1]),
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Cop(Caddi, [c2; Cconst_int n2])) when no_overflow_sub n1 n2 ->
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add_const (Cop(Csubi, [c1; c2])) (n1 - n2)
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| (Cop(Caddi, [c1; Cconst_int n1]), c2) ->
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add_const (Cop(Csubi, [c1; c2])) n1
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| (c1, Cop(Caddi, [c2; Cconst_int n2])) when n2 <> min_int ->
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add_const (Cop(Csubi, [c1; c2])) (-n2)
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| (c1, Cconst_int n) when n <> min_int ->
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add_const c1 (-n)
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| (c1, c2) ->
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Cop(Csubi, [c1; c2])
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let mul_int c1 c2 =
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match (c1, c2) with
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(Cconst_int 0, _) -> c1
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| (Cconst_int 1, _) -> c2
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| (_, Cconst_int 0) -> c2
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| (_, Cconst_int 1) -> c1
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| (_, _) -> Cop(Cmuli, [c1; c2])
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let tag_int = function
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Cconst_int n -> int_const n
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| c -> Cop(Caddi, [Cop(Clsl, [c; Cconst_int 1]); Cconst_int 1])
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let force_tag_int = function
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Cconst_int n -> int_const n
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| c -> Cop(Cor, [Cop(Clsl, [c; Cconst_int 1]); Cconst_int 1])
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let untag_int = function
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Cconst_int n -> Cconst_int(n asr 1)
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| Cop(Caddi, [Cop(Clsl, [c; Cconst_int 1]); Cconst_int 1]) -> c
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| Cop(Cor, [Cop(Casr, [c; Cconst_int n]); Cconst_int 1])
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when n > 0 && n < size_int * 8 ->
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Cop(Casr, [c; Cconst_int (n+1)])
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| Cop(Cor, [Cop(Clsr, [c; Cconst_int n]); Cconst_int 1])
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when n > 0 && n < size_int * 8 ->
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Cop(Clsr, [c; Cconst_int (n+1)])
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| Cop(Cor, [c; Cconst_int 1]) -> Cop(Casr, [c; Cconst_int 1])
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| c -> Cop(Casr, [c; Cconst_int 1])
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let lsl_int c1 c2 =
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match (c1, c2) with
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(Cop(Clsl, [c; Cconst_int n1]), Cconst_int n2)
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when n1 > 0 && n2 > 0 && n1 + n2 < size_int * 8 ->
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Cop(Clsl, [c; Cconst_int (n1 + n2)])
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| (_, _) ->
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Cop(Clsl, [c1; c2])
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let ignore_low_bit_int = function
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Cop(Caddi, [(Cop(Clsl, [_; Cconst_int 1]) as c); Cconst_int 1]) -> c
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| Cop(Cor, [c; Cconst_int 1]) -> c
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| c -> c
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let is_nonzero_constant = function
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Cconst_int n -> n <> 0
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| Cconst_natint n -> n <> 0n
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| _ -> false
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let safe_divmod op c1 c2 dbg =
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if !Clflags.fast || is_nonzero_constant c2 then
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Cop(op, [c1; c2])
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else
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bind "divisor" c2 (fun c2 ->
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Cifthenelse(c2,
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Cop(op, [c1; c2]),
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Cop(Craise dbg,
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[Cconst_symbol "caml_bucket_Division_by_zero"])))
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(* Bool *)
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let test_bool = function
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Cop(Caddi, [Cop(Clsl, [c; Cconst_int 1]); Cconst_int 1]) -> c
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| Cop(Clsl, [c; Cconst_int 1]) -> c
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| c -> Cop(Ccmpi Cne, [c; Cconst_int 1])
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(* Float *)
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let box_float c = Cop(Calloc, [alloc_float_header; c])
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let rec unbox_float = function
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Cop(Calloc, [header; c]) -> c
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| Clet(id, exp, body) -> Clet(id, exp, unbox_float body)
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| Cifthenelse(cond, e1, e2) ->
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Cifthenelse(cond, unbox_float e1, unbox_float e2)
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| Csequence(e1, e2) -> Csequence(e1, unbox_float e2)
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| Cswitch(e, tbl, el) -> Cswitch(e, tbl, Array.map unbox_float el)
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| Ccatch(n, ids, e1, e2) -> Ccatch(n, ids, unbox_float e1, unbox_float e2)
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| Ctrywith(e1, id, e2) -> Ctrywith(unbox_float e1, id, unbox_float e2)
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| c -> Cop(Cload Double_u, [c])
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(* Complex *)
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let box_complex c_re c_im =
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Cop(Calloc, [alloc_floatarray_header 2; c_re; c_im])
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let complex_re c = Cop(Cload Double_u, [c])
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let complex_im c = Cop(Cload Double_u,
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[Cop(Cadda, [c; Cconst_int size_float])])
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(* Unit *)
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let return_unit c = Csequence(c, Cconst_pointer 1)
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let rec remove_unit = function
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Cconst_pointer 1 -> Ctuple []
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| Csequence(c, Cconst_pointer 1) -> c
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| Csequence(c1, c2) ->
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Csequence(c1, remove_unit c2)
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| Cifthenelse(cond, ifso, ifnot) ->
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Cifthenelse(cond, remove_unit ifso, remove_unit ifnot)
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| Cswitch(sel, index, cases) ->
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Cswitch(sel, index, Array.map remove_unit cases)
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| Ccatch(io, ids, body, handler) ->
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Ccatch(io, ids, remove_unit body, remove_unit handler)
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| Ctrywith(body, exn, handler) ->
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Ctrywith(remove_unit body, exn, remove_unit handler)
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| Clet(id, c1, c2) ->
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Clet(id, c1, remove_unit c2)
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| Cop(Capply (mty, dbg), args) ->
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Cop(Capply (typ_void, dbg), args)
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| Cop(Cextcall(proc, mty, alloc, dbg), args) ->
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Cop(Cextcall(proc, typ_void, alloc, dbg), args)
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| Cexit (_,_) as c -> c
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| Ctuple [] as c -> c
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| c -> Csequence(c, Ctuple [])
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(* Access to block fields *)
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let field_address ptr n =
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if n = 0
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then ptr
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else Cop(Cadda, [ptr; Cconst_int(n * size_addr)])
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let get_field ptr n =
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Cop(Cload Word, [field_address ptr n])
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let set_field ptr n newval =
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Cop(Cstore Word, [field_address ptr n; newval])
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let header ptr =
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Cop(Cload Word, [Cop(Cadda, [ptr; Cconst_int(-size_int)])])
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let tag_offset =
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if big_endian then -1 else -size_int
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let get_tag ptr =
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if Proc.word_addressed then (* If byte loads are slow *)
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Cop(Cand, [header ptr; Cconst_int 255])
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else (* If byte loads are efficient *)
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Cop(Cload Byte_unsigned,
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[Cop(Cadda, [ptr; Cconst_int(tag_offset)])])
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let get_size ptr =
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Cop(Clsr, [header ptr; Cconst_int 10])
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(* Array indexing *)
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let log2_size_addr = Misc.log2 size_addr
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let log2_size_float = Misc.log2 size_float
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let wordsize_shift = 9
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let numfloat_shift = 9 + log2_size_float - log2_size_addr
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let is_addr_array_hdr hdr =
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Cop(Ccmpi Cne, [Cop(Cand, [hdr; Cconst_int 255]); floatarray_tag])
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let is_addr_array_ptr ptr =
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Cop(Ccmpi Cne, [get_tag ptr; floatarray_tag])
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let addr_array_length hdr = Cop(Clsr, [hdr; Cconst_int wordsize_shift])
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let float_array_length hdr = Cop(Clsr, [hdr; Cconst_int numfloat_shift])
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let lsl_const c n =
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Cop(Clsl, [c; Cconst_int n])
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let array_indexing log2size ptr ofs =
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match ofs with
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Cconst_int n ->
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let i = n asr 1 in
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if i = 0 then ptr else Cop(Cadda, [ptr; Cconst_int(i lsl log2size)])
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| Cop(Caddi, [Cop(Clsl, [c; Cconst_int 1]); Cconst_int 1]) ->
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Cop(Cadda, [ptr; lsl_const c log2size])
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| Cop(Caddi, [c; Cconst_int n]) ->
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Cop(Cadda, [Cop(Cadda, [ptr; lsl_const c (log2size - 1)]);
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Cconst_int((n-1) lsl (log2size - 1))])
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| _ ->
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Cop(Cadda, [Cop(Cadda, [ptr; lsl_const ofs (log2size - 1)]);
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Cconst_int((-1) lsl (log2size - 1))])
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let addr_array_ref arr ofs =
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Cop(Cload Word, [array_indexing log2_size_addr arr ofs])
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let unboxed_float_array_ref arr ofs =
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Cop(Cload Double_u, [array_indexing log2_size_float arr ofs])
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let float_array_ref arr ofs =
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box_float(unboxed_float_array_ref arr ofs)
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let addr_array_set arr ofs newval =
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Cop(Cextcall("caml_modify", typ_void, false, Debuginfo.none),
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[array_indexing log2_size_addr arr ofs; newval])
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let int_array_set arr ofs newval =
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Cop(Cstore Word, [array_indexing log2_size_addr arr ofs; newval])
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let float_array_set arr ofs newval =
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Cop(Cstore Double_u, [array_indexing log2_size_float arr ofs; newval])
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(* String length *)
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let string_length exp =
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bind "str" exp (fun str ->
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let tmp_var = Ident.create "tmp" in
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Clet(tmp_var,
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Cop(Csubi,
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[Cop(Clsl,
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[Cop(Clsr, [header str; Cconst_int 10]);
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Cconst_int log2_size_addr]);
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Cconst_int 1]),
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Cop(Csubi,
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[Cvar tmp_var;
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Cop(Cload Byte_unsigned,
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[Cop(Cadda, [str; Cvar tmp_var])])])))
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(* Message sending *)
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let lookup_tag obj tag =
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bind "tag" tag (fun tag ->
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Cop(Cextcall("caml_get_public_method", typ_addr, false, Debuginfo.none),
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[obj; tag]))
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let lookup_label obj lab =
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bind "lab" lab (fun lab ->
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let table = Cop (Cload Word, [obj]) in
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addr_array_ref table lab)
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let call_cached_method obj tag cache pos args dbg =
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let arity = List.length args in
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let cache = array_indexing log2_size_addr cache pos in
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Compilenv.need_send_fun arity;
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Cop(Capply (typ_addr, dbg),
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Cconst_symbol("caml_send" ^ string_of_int arity) ::
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obj :: tag :: cache :: args)
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(* Allocation *)
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let make_alloc_generic set_fn tag wordsize args =
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if wordsize <= Config.max_young_wosize then
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Cop(Calloc, Cconst_natint(block_header tag wordsize) :: args)
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else begin
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let id = Ident.create "alloc" in
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let rec fill_fields idx = function
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[] -> Cvar id
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| e1::el -> Csequence(set_fn (Cvar id) (Cconst_int idx) e1,
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fill_fields (idx + 2) el) in
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Clet(id,
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Cop(Cextcall("caml_alloc", typ_addr, true, Debuginfo.none),
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[Cconst_int wordsize; Cconst_int tag]),
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fill_fields 1 args)
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end
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let make_alloc tag args =
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make_alloc_generic addr_array_set tag (List.length args) args
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let make_float_alloc tag args =
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make_alloc_generic float_array_set tag
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(List.length args * size_float / size_addr) args
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(* To compile "let rec" over values *)
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let fundecls_size fundecls =
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let sz = ref (-1) in
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List.iter
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(fun (label, arity, params, body) ->
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sz := !sz + 1 + (if arity = 1 then 2 else 3))
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fundecls;
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!sz
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type rhs_kind =
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| RHS_block of int
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| RHS_nonrec
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;;
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let rec expr_size = function
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| Uclosure(fundecls, clos_vars) ->
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RHS_block (fundecls_size fundecls + List.length clos_vars)
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| Ulet(id, exp, body) ->
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expr_size body
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| Uletrec(bindings, body) ->
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expr_size body
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| Uprim(Pmakeblock(tag, mut), args, _) ->
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RHS_block (List.length args)
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| Uprim(Pmakearray(Paddrarray | Pintarray), args, _) ->
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RHS_block (List.length args)
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| Usequence(exp, exp') ->
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expr_size exp'
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| _ -> RHS_nonrec
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(* Record application and currying functions *)
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let apply_function n =
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Compilenv.need_apply_fun n; "caml_apply" ^ string_of_int n
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let curry_function n =
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Compilenv.need_curry_fun n;
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if n >= 0
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then "caml_curry" ^ string_of_int n
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else "caml_tuplify" ^ string_of_int (-n)
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(* Comparisons *)
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let transl_comparison = function
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Lambda.Ceq -> Ceq
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| Lambda.Cneq -> Cne
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| Lambda.Cge -> Cge
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| Lambda.Cgt -> Cgt
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| Lambda.Cle -> Cle
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| Lambda.Clt -> Clt
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(* Translate structured constants *)
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let const_label = ref 0
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let new_const_label () =
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incr const_label;
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!const_label
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let new_const_symbol () =
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incr const_label;
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Compilenv.make_symbol (Some (string_of_int !const_label))
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let structured_constants = ref ([] : (string * structured_constant) list)
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let transl_constant = function
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Const_base(Const_int n) ->
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int_const n
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| Const_base(Const_char c) ->
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Cconst_int(((Char.code c) lsl 1) + 1)
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| Const_pointer n ->
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if n <= max_repr_int && n >= min_repr_int
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then Cconst_pointer((n lsl 1) + 1)
|
|
else Cconst_natpointer
|
|
(Nativeint.add (Nativeint.shift_left (Nativeint.of_int n) 1) 1n)
|
|
| cst ->
|
|
let lbl = new_const_symbol() in
|
|
structured_constants := (lbl, cst) :: !structured_constants;
|
|
Cconst_symbol lbl
|
|
|
|
(* Translate constant closures *)
|
|
|
|
let constant_closures =
|
|
ref ([] : (string * (string * int * Ident.t list * ulambda) list) list)
|
|
|
|
(* Boxed integers *)
|
|
|
|
let box_int_constant bi n =
|
|
match bi with
|
|
Pnativeint -> Const_base(Const_nativeint n)
|
|
| Pint32 -> Const_base(Const_int32 (Nativeint.to_int32 n))
|
|
| Pint64 -> Const_base(Const_int64 (Int64.of_nativeint n))
|
|
|
|
let operations_boxed_int bi =
|
|
match bi with
|
|
Pnativeint -> "caml_nativeint_ops"
|
|
| Pint32 -> "caml_int32_ops"
|
|
| Pint64 -> "caml_int64_ops"
|
|
|
|
let alloc_header_boxed_int bi =
|
|
match bi with
|
|
Pnativeint -> alloc_boxedintnat_header
|
|
| Pint32 -> alloc_boxedint32_header
|
|
| Pint64 -> alloc_boxedint64_header
|
|
|
|
let box_int bi arg =
|
|
match arg with
|
|
Cconst_int n ->
|
|
transl_constant (box_int_constant bi (Nativeint.of_int n))
|
|
| Cconst_natint n ->
|
|
transl_constant (box_int_constant bi n)
|
|
| _ ->
|
|
let arg' =
|
|
if bi = Pint32 && size_int = 8 && big_endian
|
|
then Cop(Clsl, [arg; Cconst_int 32])
|
|
else arg in
|
|
Cop(Calloc, [alloc_header_boxed_int bi;
|
|
Cconst_symbol(operations_boxed_int bi);
|
|
arg'])
|
|
|
|
let rec unbox_int bi arg =
|
|
match arg with
|
|
Cop(Calloc, [hdr; ops; Cop(Clsl, [contents; Cconst_int 32])])
|
|
when bi = Pint32 && size_int = 8 && big_endian ->
|
|
(* Force sign-extension of low 32 bits *)
|
|
Cop(Casr, [Cop(Clsl, [contents; Cconst_int 32]); Cconst_int 32])
|
|
| Cop(Calloc, [hdr; ops; contents])
|
|
when bi = Pint32 && size_int = 8 && not big_endian ->
|
|
(* Force sign-extension of low 32 bits *)
|
|
Cop(Casr, [Cop(Clsl, [contents; Cconst_int 32]); Cconst_int 32])
|
|
| Cop(Calloc, [hdr; ops; contents]) ->
|
|
contents
|
|
| Clet(id, exp, body) -> Clet(id, exp, unbox_int bi body)
|
|
| Cifthenelse(cond, e1, e2) ->
|
|
Cifthenelse(cond, unbox_int bi e1, unbox_int bi e2)
|
|
| Csequence(e1, e2) -> Csequence(e1, unbox_int bi e2)
|
|
| Cswitch(e, tbl, el) -> Cswitch(e, tbl, Array.map (unbox_int bi) el)
|
|
| Ccatch(n, ids, e1, e2) -> Ccatch(n, ids, unbox_int bi e1, unbox_int bi e2)
|
|
| Ctrywith(e1, id, e2) -> Ctrywith(unbox_int bi e1, id, unbox_int bi e2)
|
|
| _ ->
|
|
Cop(Cload(if bi = Pint32 then Thirtytwo_signed else Word),
|
|
[Cop(Cadda, [arg; Cconst_int size_addr])])
|
|
|
|
let make_unsigned_int bi arg =
|
|
if bi = Pint32 && size_int = 8
|
|
then Cop(Cand, [arg; Cconst_natint 0xFFFFFFFFn])
|
|
else arg
|
|
|
|
(* Big arrays *)
|
|
|
|
let bigarray_elt_size = function
|
|
Pbigarray_unknown -> assert false
|
|
| Pbigarray_float32 -> 4
|
|
| Pbigarray_float64 -> 8
|
|
| Pbigarray_sint8 -> 1
|
|
| Pbigarray_uint8 -> 1
|
|
| Pbigarray_sint16 -> 2
|
|
| Pbigarray_uint16 -> 2
|
|
| Pbigarray_int32 -> 4
|
|
| Pbigarray_int64 -> 8
|
|
| Pbigarray_caml_int -> size_int
|
|
| Pbigarray_native_int -> size_int
|
|
| Pbigarray_complex32 -> 8
|
|
| Pbigarray_complex64 -> 16
|
|
|
|
let bigarray_indexing unsafe elt_kind layout b args dbg =
|
|
let check_bound a1 a2 k =
|
|
if unsafe then k else Csequence(Cop(Ccheckbound dbg, [a1;a2]), k) in
|
|
let rec ba_indexing dim_ofs delta_ofs = function
|
|
[] -> assert false
|
|
| [arg] ->
|
|
bind "idx" (untag_int arg)
|
|
(fun idx ->
|
|
check_bound (Cop(Cload Word,[field_address b dim_ofs])) idx idx)
|
|
| arg1 :: argl ->
|
|
let rem = ba_indexing (dim_ofs + delta_ofs) delta_ofs argl in
|
|
bind "idx" (untag_int arg1)
|
|
(fun idx ->
|
|
bind "bound" (Cop(Cload Word, [field_address b dim_ofs]))
|
|
(fun bound ->
|
|
check_bound bound idx (add_int (mul_int rem bound) idx))) in
|
|
let offset =
|
|
match layout with
|
|
Pbigarray_unknown_layout ->
|
|
assert false
|
|
| Pbigarray_c_layout ->
|
|
ba_indexing (4 + List.length args) (-1) (List.rev args)
|
|
| Pbigarray_fortran_layout ->
|
|
ba_indexing 5 1 (List.map (fun idx -> sub_int idx (Cconst_int 2)) args)
|
|
and elt_size =
|
|
bigarray_elt_size elt_kind in
|
|
let byte_offset =
|
|
if elt_size = 1
|
|
then offset
|
|
else Cop(Clsl, [offset; Cconst_int(log2 elt_size)]) in
|
|
Cop(Cadda, [Cop(Cload Word, [field_address b 1]); byte_offset])
|
|
|
|
let bigarray_word_kind = function
|
|
Pbigarray_unknown -> assert false
|
|
| Pbigarray_float32 -> Single
|
|
| Pbigarray_float64 -> Double
|
|
| Pbigarray_sint8 -> Byte_signed
|
|
| Pbigarray_uint8 -> Byte_unsigned
|
|
| Pbigarray_sint16 -> Sixteen_signed
|
|
| Pbigarray_uint16 -> Sixteen_unsigned
|
|
| Pbigarray_int32 -> Thirtytwo_signed
|
|
| Pbigarray_int64 -> Word
|
|
| Pbigarray_caml_int -> Word
|
|
| Pbigarray_native_int -> Word
|
|
| Pbigarray_complex32 -> Single
|
|
| Pbigarray_complex64 -> Double
|
|
|
|
let bigarray_get unsafe elt_kind layout b args dbg =
|
|
match elt_kind with
|
|
Pbigarray_complex32 | Pbigarray_complex64 ->
|
|
let kind = bigarray_word_kind elt_kind in
|
|
let sz = bigarray_elt_size elt_kind / 2 in
|
|
bind "addr" (bigarray_indexing unsafe elt_kind layout b args dbg) (fun addr ->
|
|
box_complex
|
|
(Cop(Cload kind, [addr]))
|
|
(Cop(Cload kind, [Cop(Cadda, [addr; Cconst_int sz])])))
|
|
| _ ->
|
|
Cop(Cload (bigarray_word_kind elt_kind),
|
|
[bigarray_indexing unsafe elt_kind layout b args dbg])
|
|
|
|
let bigarray_set unsafe elt_kind layout b args newval dbg =
|
|
match elt_kind with
|
|
Pbigarray_complex32 | Pbigarray_complex64 ->
|
|
let kind = bigarray_word_kind elt_kind in
|
|
let sz = bigarray_elt_size elt_kind / 2 in
|
|
bind "newval" newval (fun newv ->
|
|
bind "addr" (bigarray_indexing unsafe elt_kind layout b args dbg) (fun addr ->
|
|
Csequence(
|
|
Cop(Cstore kind, [addr; complex_re newv]),
|
|
Cop(Cstore kind,
|
|
[Cop(Cadda, [addr; Cconst_int sz]); complex_im newv]))))
|
|
| _ ->
|
|
Cop(Cstore (bigarray_word_kind elt_kind),
|
|
[bigarray_indexing unsafe elt_kind layout b args dbg; newval])
|
|
|
|
(* Simplification of some primitives into C calls *)
|
|
|
|
let default_prim name =
|
|
{ prim_name = name; prim_arity = 0 (*ignored*);
|
|
prim_alloc = true; prim_native_name = ""; prim_native_float = false }
|
|
|
|
let simplif_primitive_32bits = function
|
|
Pbintofint Pint64 -> Pccall (default_prim "caml_int64_of_int")
|
|
| Pintofbint Pint64 -> Pccall (default_prim "caml_int64_to_int")
|
|
| Pcvtbint(Pint32, Pint64) -> Pccall (default_prim "caml_int64_of_int32")
|
|
| Pcvtbint(Pint64, Pint32) -> Pccall (default_prim "caml_int64_to_int32")
|
|
| Pcvtbint(Pnativeint, Pint64) ->
|
|
Pccall (default_prim "caml_int64_of_nativeint")
|
|
| Pcvtbint(Pint64, Pnativeint) ->
|
|
Pccall (default_prim "caml_int64_to_nativeint")
|
|
| Pnegbint Pint64 -> Pccall (default_prim "caml_int64_neg")
|
|
| Paddbint Pint64 -> Pccall (default_prim "caml_int64_add")
|
|
| Psubbint Pint64 -> Pccall (default_prim "caml_int64_sub")
|
|
| Pmulbint Pint64 -> Pccall (default_prim "caml_int64_mul")
|
|
| Pdivbint Pint64 -> Pccall (default_prim "caml_int64_div")
|
|
| Pmodbint Pint64 -> Pccall (default_prim "caml_int64_mod")
|
|
| Pandbint Pint64 -> Pccall (default_prim "caml_int64_and")
|
|
| Porbint Pint64 -> Pccall (default_prim "caml_int64_or")
|
|
| Pxorbint Pint64 -> Pccall (default_prim "caml_int64_xor")
|
|
| Plslbint Pint64 -> Pccall (default_prim "caml_int64_shift_left")
|
|
| Plsrbint Pint64 -> Pccall (default_prim "caml_int64_shift_right_unsigned")
|
|
| Pasrbint Pint64 -> Pccall (default_prim "caml_int64_shift_right")
|
|
| Pbintcomp(Pint64, Lambda.Ceq) -> Pccall (default_prim "caml_equal")
|
|
| Pbintcomp(Pint64, Lambda.Cneq) -> Pccall (default_prim "caml_notequal")
|
|
| Pbintcomp(Pint64, Lambda.Clt) -> Pccall (default_prim "caml_lessthan")
|
|
| Pbintcomp(Pint64, Lambda.Cgt) -> Pccall (default_prim "caml_greaterthan")
|
|
| Pbintcomp(Pint64, Lambda.Cle) -> Pccall (default_prim "caml_lessequal")
|
|
| Pbintcomp(Pint64, Lambda.Cge) -> Pccall (default_prim "caml_greaterequal")
|
|
| Pbigarrayref(unsafe, n, Pbigarray_int64, layout) ->
|
|
Pccall (default_prim ("caml_ba_get_" ^ string_of_int n))
|
|
| Pbigarrayset(unsafe, n, Pbigarray_int64, layout) ->
|
|
Pccall (default_prim ("caml_ba_set_" ^ string_of_int n))
|
|
| p -> p
|
|
|
|
let simplif_primitive p =
|
|
match p with
|
|
| Pduprecord _ ->
|
|
Pccall (default_prim "caml_obj_dup")
|
|
| Pbigarrayref(unsafe, n, Pbigarray_unknown, layout) ->
|
|
Pccall (default_prim ("caml_ba_get_" ^ string_of_int n))
|
|
| Pbigarrayset(unsafe, n, Pbigarray_unknown, layout) ->
|
|
Pccall (default_prim ("caml_ba_set_" ^ string_of_int n))
|
|
| Pbigarrayref(unsafe, n, kind, Pbigarray_unknown_layout) ->
|
|
Pccall (default_prim ("caml_ba_get_" ^ string_of_int n))
|
|
| Pbigarrayset(unsafe, n, kind, Pbigarray_unknown_layout) ->
|
|
Pccall (default_prim ("caml_ba_set_" ^ string_of_int n))
|
|
| p ->
|
|
if size_int = 8 then p else simplif_primitive_32bits p
|
|
|
|
(* Build switchers both for constants and blocks *)
|
|
|
|
(* constants first *)
|
|
|
|
let transl_isout h arg = tag_int (Cop(Ccmpa Clt, [h ; arg]))
|
|
|
|
exception Found of int
|
|
|
|
let make_switch_gen arg cases acts =
|
|
let lcases = Array.length cases in
|
|
let new_cases = Array.create lcases 0 in
|
|
let store = Switch.mk_store (=) in
|
|
|
|
for i = 0 to Array.length cases-1 do
|
|
let act = cases.(i) in
|
|
let new_act = store.Switch.act_store act in
|
|
new_cases.(i) <- new_act
|
|
done ;
|
|
Cswitch
|
|
(arg, new_cases,
|
|
Array.map
|
|
(fun n -> acts.(n))
|
|
(store.Switch.act_get ()))
|
|
|
|
|
|
(* Then for blocks *)
|
|
|
|
module SArgBlocks =
|
|
struct
|
|
type primitive = operation
|
|
|
|
let eqint = Ccmpi Ceq
|
|
let neint = Ccmpi Cne
|
|
let leint = Ccmpi Cle
|
|
let ltint = Ccmpi Clt
|
|
let geint = Ccmpi Cge
|
|
let gtint = Ccmpi Cgt
|
|
|
|
type act = expression
|
|
|
|
let default = Cexit (0,[])
|
|
let make_prim p args = Cop (p,args)
|
|
let make_offset arg n = add_const arg n
|
|
let make_isout h arg = Cop (Ccmpa Clt, [h ; arg])
|
|
let make_isin h arg = Cop (Ccmpa Cge, [h ; arg])
|
|
let make_if cond ifso ifnot = Cifthenelse (cond, ifso, ifnot)
|
|
let make_switch arg cases actions =
|
|
make_switch_gen arg cases actions
|
|
let bind arg body = bind "switcher" arg body
|
|
|
|
end
|
|
|
|
module SwitcherBlocks = Switch.Make(SArgBlocks)
|
|
|
|
(* Auxiliary functions for optimizing "let" of boxed numbers (floats and
|
|
boxed integers *)
|
|
|
|
type unboxed_number_kind =
|
|
No_unboxing
|
|
| Boxed_float
|
|
| Boxed_integer of boxed_integer
|
|
|
|
let is_unboxed_number = function
|
|
Uconst(Const_base(Const_float f)) ->
|
|
Boxed_float
|
|
| Uprim(p, _, _) ->
|
|
begin match simplif_primitive p with
|
|
Pccall p -> if p.prim_native_float then Boxed_float else No_unboxing
|
|
| Pfloatfield _ -> Boxed_float
|
|
| Pfloatofint -> Boxed_float
|
|
| Pnegfloat -> Boxed_float
|
|
| Pabsfloat -> Boxed_float
|
|
| Paddfloat -> Boxed_float
|
|
| Psubfloat -> Boxed_float
|
|
| Pmulfloat -> Boxed_float
|
|
| Pdivfloat -> Boxed_float
|
|
| Parrayrefu Pfloatarray -> Boxed_float
|
|
| Parrayrefs Pfloatarray -> Boxed_float
|
|
| Pbintofint bi -> Boxed_integer bi
|
|
| Pcvtbint(src, dst) -> Boxed_integer dst
|
|
| Pnegbint bi -> Boxed_integer bi
|
|
| Paddbint bi -> Boxed_integer bi
|
|
| Psubbint bi -> Boxed_integer bi
|
|
| Pmulbint bi -> Boxed_integer bi
|
|
| Pdivbint bi -> Boxed_integer bi
|
|
| Pmodbint bi -> Boxed_integer bi
|
|
| Pandbint bi -> Boxed_integer bi
|
|
| Porbint bi -> Boxed_integer bi
|
|
| Pxorbint bi -> Boxed_integer bi
|
|
| Plslbint bi -> Boxed_integer bi
|
|
| Plsrbint bi -> Boxed_integer bi
|
|
| Pasrbint bi -> Boxed_integer bi
|
|
| Pbigarrayref(_, _, (Pbigarray_float32 | Pbigarray_float64), _) ->
|
|
Boxed_float
|
|
| Pbigarrayref(_, _, Pbigarray_int32, _) -> Boxed_integer Pint32
|
|
| Pbigarrayref(_, _, Pbigarray_int64, _) -> Boxed_integer Pint64
|
|
| Pbigarrayref(_, _, Pbigarray_native_int, _) -> Boxed_integer Pnativeint
|
|
| _ -> No_unboxing
|
|
end
|
|
| _ -> No_unboxing
|
|
|
|
let subst_boxed_number unbox_fn boxed_id unboxed_id exp =
|
|
let need_boxed = ref false in
|
|
let assigned = ref false in
|
|
let rec subst = function
|
|
Cvar id as e ->
|
|
if Ident.same id boxed_id then need_boxed := true; e
|
|
| Clet(id, arg, body) -> Clet(id, subst arg, subst body)
|
|
| Cassign(id, arg) ->
|
|
if Ident.same id boxed_id then begin
|
|
assigned := true;
|
|
Cassign(unboxed_id, subst(unbox_fn arg))
|
|
end else
|
|
Cassign(id, subst arg)
|
|
| Ctuple argv -> Ctuple(List.map subst argv)
|
|
| Cop(Cload _, [Cvar id]) as e ->
|
|
if Ident.same id boxed_id then Cvar unboxed_id else e
|
|
| Cop(Cload _, [Cop(Cadda, [Cvar id; _])]) as e ->
|
|
if Ident.same id boxed_id then Cvar unboxed_id else e
|
|
| Cop(op, argv) -> Cop(op, List.map subst argv)
|
|
| Csequence(e1, e2) -> Csequence(subst e1, subst e2)
|
|
| Cifthenelse(e1, e2, e3) -> Cifthenelse(subst e1, subst e2, subst e3)
|
|
| Cswitch(arg, index, cases) ->
|
|
Cswitch(subst arg, index, Array.map subst cases)
|
|
| Cloop e -> Cloop(subst e)
|
|
| Ccatch(nfail, ids, e1, e2) -> Ccatch(nfail, ids, subst e1, subst e2)
|
|
| Cexit (nfail, el) -> Cexit (nfail, List.map subst el)
|
|
| Ctrywith(e1, id, e2) -> Ctrywith(subst e1, id, subst e2)
|
|
| e -> e in
|
|
let res = subst exp in
|
|
(res, !need_boxed, !assigned)
|
|
|
|
(* Translate an expression *)
|
|
|
|
let functions = (Queue.create() : (string * Ident.t list * ulambda) Queue.t)
|
|
|
|
let rec transl = function
|
|
Uvar id ->
|
|
Cvar id
|
|
| Uconst sc ->
|
|
transl_constant sc
|
|
| Uclosure(fundecls, []) ->
|
|
let lbl = new_const_symbol() in
|
|
constant_closures := (lbl, fundecls) :: !constant_closures;
|
|
List.iter
|
|
(fun (label, arity, params, body) ->
|
|
Queue.add (label, params, body) functions)
|
|
fundecls;
|
|
Cconst_symbol lbl
|
|
| Uclosure(fundecls, clos_vars) ->
|
|
let block_size =
|
|
fundecls_size fundecls + List.length clos_vars in
|
|
let rec transl_fundecls pos = function
|
|
[] ->
|
|
List.map transl clos_vars
|
|
| (label, arity, params, body) :: rem ->
|
|
Queue.add (label, params, body) functions;
|
|
let header =
|
|
if pos = 0
|
|
then alloc_closure_header block_size
|
|
else alloc_infix_header pos in
|
|
if arity = 1 then
|
|
header ::
|
|
Cconst_symbol label ::
|
|
int_const 1 ::
|
|
transl_fundecls (pos + 3) rem
|
|
else
|
|
header ::
|
|
Cconst_symbol(curry_function arity) ::
|
|
int_const arity ::
|
|
Cconst_symbol label ::
|
|
transl_fundecls (pos + 4) rem in
|
|
Cop(Calloc, transl_fundecls 0 fundecls)
|
|
| Uoffset(arg, offset) ->
|
|
field_address (transl arg) offset
|
|
| Udirect_apply(lbl, args, dbg) ->
|
|
Cop(Capply(typ_addr, dbg), Cconst_symbol lbl :: List.map transl args)
|
|
| Ugeneric_apply(clos, [arg], dbg) ->
|
|
bind "fun" (transl clos) (fun clos ->
|
|
Cop(Capply(typ_addr, dbg), [get_field clos 0; transl arg; clos]))
|
|
| Ugeneric_apply(clos, args, dbg) ->
|
|
let arity = List.length args in
|
|
let cargs = Cconst_symbol(apply_function arity) ::
|
|
List.map transl (args @ [clos]) in
|
|
Cop(Capply(typ_addr, dbg), cargs)
|
|
| Usend(kind, met, obj, args, dbg) ->
|
|
let call_met obj args clos =
|
|
if args = [] then
|
|
Cop(Capply(typ_addr, dbg), [get_field clos 0;obj;clos])
|
|
else
|
|
let arity = List.length args + 1 in
|
|
let cargs = Cconst_symbol(apply_function arity) :: obj ::
|
|
(List.map transl args) @ [clos] in
|
|
Cop(Capply(typ_addr, dbg), cargs)
|
|
in
|
|
bind "obj" (transl obj) (fun obj ->
|
|
match kind, args with
|
|
Self, _ ->
|
|
bind "met" (lookup_label obj (transl met)) (call_met obj args)
|
|
| Cached, cache :: pos :: args ->
|
|
call_cached_method obj (transl met) (transl cache) (transl pos)
|
|
(List.map transl args) dbg
|
|
| _ ->
|
|
bind "met" (lookup_tag obj (transl met)) (call_met obj args))
|
|
| Ulet(id, exp, body) ->
|
|
begin match is_unboxed_number exp with
|
|
No_unboxing ->
|
|
Clet(id, transl exp, transl body)
|
|
| Boxed_float ->
|
|
transl_unbox_let box_float unbox_float transl_unbox_float
|
|
id exp body
|
|
| Boxed_integer bi ->
|
|
transl_unbox_let (box_int bi) (unbox_int bi) (transl_unbox_int bi)
|
|
id exp body
|
|
end
|
|
| Uletrec(bindings, body) ->
|
|
transl_letrec bindings (transl body)
|
|
|
|
(* Primitives *)
|
|
| Uprim(prim, args, dbg) ->
|
|
begin match (simplif_primitive prim, args) with
|
|
(Pgetglobal id, []) ->
|
|
Cconst_symbol (Ident.name id)
|
|
| (Pmakeblock(tag, mut), []) ->
|
|
transl_constant(Const_block(tag, []))
|
|
| (Pmakeblock(tag, mut), args) ->
|
|
make_alloc tag (List.map transl args)
|
|
| (Pccall prim, args) ->
|
|
if prim.prim_native_float then
|
|
box_float
|
|
(Cop(Cextcall(prim.prim_native_name, typ_float, false, dbg),
|
|
List.map transl_unbox_float args))
|
|
else
|
|
Cop(Cextcall(Primitive.native_name prim, typ_addr, prim.prim_alloc, dbg),
|
|
List.map transl args)
|
|
| (Pmakearray kind, []) ->
|
|
transl_constant(Const_block(0, []))
|
|
| (Pmakearray kind, args) ->
|
|
begin match kind with
|
|
Pgenarray ->
|
|
Cop(Cextcall("caml_make_array", typ_addr, true, Debuginfo.none),
|
|
[make_alloc 0 (List.map transl args)])
|
|
| Paddrarray | Pintarray ->
|
|
make_alloc 0 (List.map transl args)
|
|
| Pfloatarray ->
|
|
make_float_alloc Obj.double_array_tag
|
|
(List.map transl_unbox_float args)
|
|
end
|
|
| (Pbigarrayref(unsafe, num_dims, elt_kind, layout), arg1 :: argl) ->
|
|
let elt =
|
|
bigarray_get unsafe elt_kind layout
|
|
(transl arg1) (List.map transl argl) dbg in
|
|
begin match elt_kind with
|
|
Pbigarray_float32 | Pbigarray_float64 -> box_float elt
|
|
| Pbigarray_complex32 | Pbigarray_complex64 -> elt
|
|
| Pbigarray_int32 -> box_int Pint32 elt
|
|
| Pbigarray_int64 -> box_int Pint64 elt
|
|
| Pbigarray_native_int -> box_int Pnativeint elt
|
|
| Pbigarray_caml_int -> force_tag_int elt
|
|
| _ -> tag_int elt
|
|
end
|
|
| (Pbigarrayset(unsafe, num_dims, elt_kind, layout), arg1 :: argl) ->
|
|
let (argidx, argnewval) = split_last argl in
|
|
return_unit(bigarray_set unsafe elt_kind layout
|
|
(transl arg1)
|
|
(List.map transl argidx)
|
|
(match elt_kind with
|
|
Pbigarray_float32 | Pbigarray_float64 ->
|
|
transl_unbox_float argnewval
|
|
| Pbigarray_complex32 | Pbigarray_complex64 -> transl argnewval
|
|
| Pbigarray_int32 -> transl_unbox_int Pint32 argnewval
|
|
| Pbigarray_int64 -> transl_unbox_int Pint64 argnewval
|
|
| Pbigarray_native_int -> transl_unbox_int Pnativeint argnewval
|
|
| _ -> untag_int (transl argnewval))
|
|
dbg)
|
|
| (p, [arg]) ->
|
|
transl_prim_1 p arg dbg
|
|
| (p, [arg1; arg2]) ->
|
|
transl_prim_2 p arg1 arg2 dbg
|
|
| (p, [arg1; arg2; arg3]) ->
|
|
transl_prim_3 p arg1 arg2 arg3 dbg
|
|
| (_, _) ->
|
|
fatal_error "Cmmgen.transl:prim"
|
|
end
|
|
|
|
(* Control structures *)
|
|
| Uswitch(arg, s) ->
|
|
(* As in the bytecode interpreter, only matching against constants
|
|
can be checked *)
|
|
if Array.length s.us_index_blocks = 0 then
|
|
Cswitch
|
|
(untag_int (transl arg),
|
|
s.us_index_consts,
|
|
Array.map transl s.us_actions_consts)
|
|
else if Array.length s.us_index_consts = 0 then
|
|
transl_switch (get_tag (transl arg))
|
|
s.us_index_blocks s.us_actions_blocks
|
|
else
|
|
bind "switch" (transl arg) (fun arg ->
|
|
Cifthenelse(
|
|
Cop(Cand, [arg; Cconst_int 1]),
|
|
transl_switch
|
|
(untag_int arg) s.us_index_consts s.us_actions_consts,
|
|
transl_switch
|
|
(get_tag arg) s.us_index_blocks s.us_actions_blocks))
|
|
| Ustaticfail (nfail, args) ->
|
|
Cexit (nfail, List.map transl args)
|
|
| Ucatch(nfail, [], body, handler) ->
|
|
make_catch nfail (transl body) (transl handler)
|
|
| Ucatch(nfail, ids, body, handler) ->
|
|
Ccatch(nfail, ids, transl body, transl handler)
|
|
| Utrywith(body, exn, handler) ->
|
|
Ctrywith(transl body, exn, transl handler)
|
|
| Uifthenelse(Uprim(Pnot, [arg], _), ifso, ifnot) ->
|
|
transl (Uifthenelse(arg, ifnot, ifso))
|
|
| Uifthenelse(cond, ifso, Ustaticfail (nfail, [])) ->
|
|
exit_if_false cond (transl ifso) nfail
|
|
| Uifthenelse(cond, Ustaticfail (nfail, []), ifnot) ->
|
|
exit_if_true cond nfail (transl ifnot)
|
|
| Uifthenelse(Uprim(Psequand, _, _) as cond, ifso, ifnot) ->
|
|
let raise_num = next_raise_count () in
|
|
make_catch
|
|
raise_num
|
|
(exit_if_false cond (transl ifso) raise_num)
|
|
(transl ifnot)
|
|
| Uifthenelse(Uprim(Psequor, _, _) as cond, ifso, ifnot) ->
|
|
let raise_num = next_raise_count () in
|
|
make_catch
|
|
raise_num
|
|
(exit_if_true cond raise_num (transl ifnot))
|
|
(transl ifso)
|
|
| Uifthenelse (Uifthenelse (cond, condso, condnot), ifso, ifnot) ->
|
|
let num_true = next_raise_count () in
|
|
make_catch
|
|
num_true
|
|
(make_catch2
|
|
(fun shared_false ->
|
|
Cifthenelse
|
|
(test_bool (transl cond),
|
|
exit_if_true condso num_true shared_false,
|
|
exit_if_true condnot num_true shared_false))
|
|
(transl ifnot))
|
|
(transl ifso)
|
|
| Uifthenelse(cond, ifso, ifnot) ->
|
|
Cifthenelse(test_bool(transl cond), transl ifso, transl ifnot)
|
|
| Usequence(exp1, exp2) ->
|
|
Csequence(remove_unit(transl exp1), transl exp2)
|
|
| Uwhile(cond, body) ->
|
|
let raise_num = next_raise_count () in
|
|
return_unit
|
|
(Ccatch
|
|
(raise_num, [],
|
|
Cloop(exit_if_false cond (remove_unit(transl body)) raise_num),
|
|
Ctuple []))
|
|
| Ufor(id, low, high, dir, body) ->
|
|
let tst = match dir with Upto -> Cgt | Downto -> Clt in
|
|
let inc = match dir with Upto -> Caddi | Downto -> Csubi in
|
|
let raise_num = next_raise_count () in
|
|
let id_prev = Ident.rename id in
|
|
return_unit
|
|
(Clet
|
|
(id, transl low,
|
|
bind_nonvar "bound" (transl high) (fun high ->
|
|
Ccatch
|
|
(raise_num, [],
|
|
Cifthenelse
|
|
(Cop(Ccmpi tst, [Cvar id; high]), Cexit (raise_num, []),
|
|
Cloop
|
|
(Csequence
|
|
(remove_unit(transl body),
|
|
Clet(id_prev, Cvar id,
|
|
Csequence
|
|
(Cassign(id,
|
|
Cop(inc, [Cvar id; Cconst_int 2])),
|
|
Cifthenelse
|
|
(Cop(Ccmpi Ceq, [Cvar id_prev; high]),
|
|
Cexit (raise_num,[]), Ctuple [])))))),
|
|
Ctuple []))))
|
|
| Uassign(id, exp) ->
|
|
return_unit(Cassign(id, transl exp))
|
|
|
|
and transl_prim_1 p arg dbg =
|
|
match p with
|
|
(* Generic operations *)
|
|
Pidentity ->
|
|
transl arg
|
|
| Pignore ->
|
|
return_unit(remove_unit (transl arg))
|
|
(* Heap operations *)
|
|
| Pfield n ->
|
|
get_field (transl arg) n
|
|
| Pfloatfield n ->
|
|
let ptr = transl arg in
|
|
box_float(
|
|
Cop(Cload Double_u,
|
|
[if n = 0 then ptr
|
|
else Cop(Cadda, [ptr; Cconst_int(n * size_float)])]))
|
|
(* Exceptions *)
|
|
| Praise ->
|
|
Cop(Craise dbg, [transl arg])
|
|
(* Integer operations *)
|
|
| Pnegint ->
|
|
Cop(Csubi, [Cconst_int 2; transl arg])
|
|
| Poffsetint n ->
|
|
if no_overflow_lsl n then
|
|
add_const (transl arg) (n lsl 1)
|
|
else
|
|
transl_prim_2 Paddint arg (Uconst (Const_base(Const_int n))) Debuginfo.none
|
|
| Poffsetref n ->
|
|
return_unit
|
|
(bind "ref" (transl arg) (fun arg ->
|
|
Cop(Cstore Word,
|
|
[arg; add_const (Cop(Cload Word, [arg])) (n lsl 1)])))
|
|
(* Floating-point operations *)
|
|
| Pfloatofint ->
|
|
box_float(Cop(Cfloatofint, [untag_int(transl arg)]))
|
|
| Pintoffloat ->
|
|
tag_int(Cop(Cintoffloat, [transl_unbox_float arg]))
|
|
| Pnegfloat ->
|
|
box_float(Cop(Cnegf, [transl_unbox_float arg]))
|
|
| Pabsfloat ->
|
|
box_float(Cop(Cabsf, [transl_unbox_float arg]))
|
|
(* String operations *)
|
|
| Pstringlength ->
|
|
tag_int(string_length (transl arg))
|
|
(* Array operations *)
|
|
| Parraylength kind ->
|
|
begin match kind with
|
|
Pgenarray ->
|
|
let len =
|
|
if wordsize_shift = numfloat_shift then
|
|
Cop(Clsr, [header(transl arg); Cconst_int wordsize_shift])
|
|
else
|
|
bind "header" (header(transl arg)) (fun hdr ->
|
|
Cifthenelse(is_addr_array_hdr hdr,
|
|
Cop(Clsr, [hdr; Cconst_int wordsize_shift]),
|
|
Cop(Clsr, [hdr; Cconst_int numfloat_shift]))) in
|
|
Cop(Cor, [len; Cconst_int 1])
|
|
| Paddrarray | Pintarray ->
|
|
Cop(Cor, [addr_array_length(header(transl arg)); Cconst_int 1])
|
|
| Pfloatarray ->
|
|
Cop(Cor, [float_array_length(header(transl arg)); Cconst_int 1])
|
|
end
|
|
(* Boolean operations *)
|
|
| Pnot ->
|
|
Cop(Csubi, [Cconst_int 4; transl arg]) (* 1 -> 3, 3 -> 1 *)
|
|
(* Test integer/block *)
|
|
| Pisint ->
|
|
tag_int(Cop(Cand, [transl arg; Cconst_int 1]))
|
|
(* Boxed integers *)
|
|
| Pbintofint bi ->
|
|
box_int bi (untag_int (transl arg))
|
|
| Pintofbint bi ->
|
|
force_tag_int (transl_unbox_int bi arg)
|
|
| Pcvtbint(bi1, bi2) ->
|
|
box_int bi2 (transl_unbox_int bi1 arg)
|
|
| Pnegbint bi ->
|
|
box_int bi (Cop(Csubi, [Cconst_int 0; transl_unbox_int bi arg]))
|
|
| _ ->
|
|
fatal_error "Cmmgen.transl_prim_1"
|
|
|
|
and transl_prim_2 p arg1 arg2 dbg =
|
|
match p with
|
|
(* Heap operations *)
|
|
Psetfield(n, ptr) ->
|
|
if ptr then
|
|
return_unit(Cop(Cextcall("caml_modify", typ_void, false, Debuginfo.none),
|
|
[field_address (transl arg1) n; transl arg2]))
|
|
else
|
|
return_unit(set_field (transl arg1) n (transl arg2))
|
|
| Psetfloatfield n ->
|
|
let ptr = transl arg1 in
|
|
return_unit(
|
|
Cop(Cstore Double_u,
|
|
[if n = 0 then ptr
|
|
else Cop(Cadda, [ptr; Cconst_int(n * size_float)]);
|
|
transl_unbox_float arg2]))
|
|
|
|
(* Boolean operations *)
|
|
| Psequand ->
|
|
Cifthenelse(test_bool(transl arg1), transl arg2, Cconst_int 1)
|
|
(* let id = Ident.create "res1" in
|
|
Clet(id, transl arg1,
|
|
Cifthenelse(test_bool(Cvar id), transl arg2, Cvar id)) *)
|
|
| Psequor ->
|
|
Cifthenelse(test_bool(transl arg1), Cconst_int 3, transl arg2)
|
|
|
|
(* Integer operations *)
|
|
| Paddint ->
|
|
decr_int(add_int (transl arg1) (transl arg2))
|
|
| Psubint ->
|
|
incr_int(sub_int (transl arg1) (transl arg2))
|
|
| Pmulint ->
|
|
incr_int(Cop(Cmuli, [decr_int(transl arg1); untag_int(transl arg2)]))
|
|
| Pdivint ->
|
|
tag_int(safe_divmod Cdivi (untag_int(transl arg1)) (untag_int(transl arg2)) dbg)
|
|
| Pmodint ->
|
|
tag_int(safe_divmod Cmodi (untag_int(transl arg1)) (untag_int(transl arg2)) dbg)
|
|
| Pandint ->
|
|
Cop(Cand, [transl arg1; transl arg2])
|
|
| Porint ->
|
|
Cop(Cor, [transl arg1; transl arg2])
|
|
| Pxorint ->
|
|
Cop(Cor, [Cop(Cxor, [ignore_low_bit_int(transl arg1);
|
|
ignore_low_bit_int(transl arg2)]);
|
|
Cconst_int 1])
|
|
| Plslint ->
|
|
incr_int(lsl_int (decr_int(transl arg1)) (untag_int(transl arg2)))
|
|
| Plsrint ->
|
|
Cop(Cor, [Cop(Clsr, [transl arg1; untag_int(transl arg2)]);
|
|
Cconst_int 1])
|
|
| Pasrint ->
|
|
Cop(Cor, [Cop(Casr, [transl arg1; untag_int(transl arg2)]);
|
|
Cconst_int 1])
|
|
| Pintcomp cmp ->
|
|
tag_int(Cop(Ccmpi(transl_comparison cmp), [transl arg1; transl arg2]))
|
|
| Pisout ->
|
|
transl_isout (transl arg1) (transl arg2)
|
|
(* Float operations *)
|
|
| Paddfloat ->
|
|
box_float(Cop(Caddf,
|
|
[transl_unbox_float arg1; transl_unbox_float arg2]))
|
|
| Psubfloat ->
|
|
box_float(Cop(Csubf,
|
|
[transl_unbox_float arg1; transl_unbox_float arg2]))
|
|
| Pmulfloat ->
|
|
box_float(Cop(Cmulf,
|
|
[transl_unbox_float arg1; transl_unbox_float arg2]))
|
|
| Pdivfloat ->
|
|
box_float(Cop(Cdivf,
|
|
[transl_unbox_float arg1; transl_unbox_float arg2]))
|
|
| Pfloatcomp cmp ->
|
|
tag_int(Cop(Ccmpf(transl_comparison cmp),
|
|
[transl_unbox_float arg1; transl_unbox_float arg2]))
|
|
|
|
(* String operations *)
|
|
| Pstringrefu ->
|
|
tag_int(Cop(Cload Byte_unsigned,
|
|
[add_int (transl arg1) (untag_int(transl arg2))]))
|
|
| Pstringrefs ->
|
|
tag_int
|
|
(bind "str" (transl arg1) (fun str ->
|
|
bind "index" (untag_int (transl arg2)) (fun idx ->
|
|
Csequence(
|
|
Cop(Ccheckbound dbg, [string_length str; idx]),
|
|
Cop(Cload Byte_unsigned, [add_int str idx])))))
|
|
|
|
(* Array operations *)
|
|
| Parrayrefu kind ->
|
|
begin match kind with
|
|
Pgenarray ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
Cifthenelse(is_addr_array_ptr arr,
|
|
addr_array_ref arr idx,
|
|
float_array_ref arr idx)))
|
|
| Paddrarray | Pintarray ->
|
|
addr_array_ref (transl arg1) (transl arg2)
|
|
| Pfloatarray ->
|
|
float_array_ref (transl arg1) (transl arg2)
|
|
end
|
|
| Parrayrefs kind ->
|
|
begin match kind with
|
|
Pgenarray ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
bind "header" (header arr) (fun hdr ->
|
|
Cifthenelse(is_addr_array_hdr hdr,
|
|
Csequence(Cop(Ccheckbound dbg, [addr_array_length hdr; idx]),
|
|
addr_array_ref arr idx),
|
|
Csequence(Cop(Ccheckbound dbg, [float_array_length hdr; idx]),
|
|
float_array_ref arr idx)))))
|
|
| Paddrarray | Pintarray ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Csequence(Cop(Ccheckbound dbg, [addr_array_length(header arr); idx]),
|
|
addr_array_ref arr idx)))
|
|
| Pfloatarray ->
|
|
box_float(
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Csequence(Cop(Ccheckbound dbg,
|
|
[float_array_length(header arr); idx]),
|
|
unboxed_float_array_ref arr idx))))
|
|
end
|
|
|
|
(* Operations on bitvects *)
|
|
| Pbittest ->
|
|
bind "index" (untag_int(transl arg2)) (fun idx ->
|
|
tag_int(
|
|
Cop(Cand, [Cop(Clsr, [Cop(Cload Byte_unsigned,
|
|
[add_int (transl arg1)
|
|
(Cop(Clsr, [idx; Cconst_int 3]))]);
|
|
Cop(Cand, [idx; Cconst_int 7])]);
|
|
Cconst_int 1])))
|
|
|
|
(* Boxed integers *)
|
|
| Paddbint bi ->
|
|
box_int bi (Cop(Caddi,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Psubbint bi ->
|
|
box_int bi (Cop(Csubi,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Pmulbint bi ->
|
|
box_int bi (Cop(Cmuli,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Pdivbint bi ->
|
|
box_int bi (safe_divmod Cdivi
|
|
(transl_unbox_int bi arg1) (transl_unbox_int bi arg2)
|
|
dbg)
|
|
| Pmodbint bi ->
|
|
box_int bi (safe_divmod Cmodi
|
|
(transl_unbox_int bi arg1) (transl_unbox_int bi arg2)
|
|
dbg)
|
|
| Pandbint bi ->
|
|
box_int bi (Cop(Cand,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Porbint bi ->
|
|
box_int bi (Cop(Cor,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Pxorbint bi ->
|
|
box_int bi (Cop(Cxor,
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| Plslbint bi ->
|
|
box_int bi (Cop(Clsl,
|
|
[transl_unbox_int bi arg1; untag_int(transl arg2)]))
|
|
| Plsrbint bi ->
|
|
box_int bi (Cop(Clsr,
|
|
[make_unsigned_int bi (transl_unbox_int bi arg1);
|
|
untag_int(transl arg2)]))
|
|
| Pasrbint bi ->
|
|
box_int bi (Cop(Casr,
|
|
[transl_unbox_int bi arg1; untag_int(transl arg2)]))
|
|
| Pbintcomp(bi, cmp) ->
|
|
tag_int (Cop(Ccmpi(transl_comparison cmp),
|
|
[transl_unbox_int bi arg1; transl_unbox_int bi arg2]))
|
|
| _ ->
|
|
fatal_error "Cmmgen.transl_prim_2"
|
|
|
|
and transl_prim_3 p arg1 arg2 arg3 dbg =
|
|
match p with
|
|
(* String operations *)
|
|
Pstringsetu ->
|
|
return_unit(Cop(Cstore Byte_unsigned,
|
|
[add_int (transl arg1) (untag_int(transl arg2));
|
|
untag_int(transl arg3)]))
|
|
| Pstringsets ->
|
|
return_unit
|
|
(bind "str" (transl arg1) (fun str ->
|
|
bind "index" (untag_int (transl arg2)) (fun idx ->
|
|
Csequence(
|
|
Cop(Ccheckbound dbg, [string_length str; idx]),
|
|
Cop(Cstore Byte_unsigned,
|
|
[add_int str idx; untag_int(transl arg3)])))))
|
|
|
|
(* Array operations *)
|
|
| Parraysetu kind ->
|
|
return_unit(begin match kind with
|
|
Pgenarray ->
|
|
bind "newval" (transl arg3) (fun newval ->
|
|
bind "index" (transl arg2) (fun index ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Cifthenelse(is_addr_array_ptr arr,
|
|
addr_array_set arr index newval,
|
|
float_array_set arr index (unbox_float newval)))))
|
|
| Paddrarray ->
|
|
addr_array_set (transl arg1) (transl arg2) (transl arg3)
|
|
| Pintarray ->
|
|
int_array_set (transl arg1) (transl arg2) (transl arg3)
|
|
| Pfloatarray ->
|
|
float_array_set (transl arg1) (transl arg2) (transl_unbox_float arg3)
|
|
end)
|
|
| Parraysets kind ->
|
|
return_unit(begin match kind with
|
|
Pgenarray ->
|
|
bind "newval" (transl arg3) (fun newval ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
bind "header" (header arr) (fun hdr ->
|
|
Cifthenelse(is_addr_array_hdr hdr,
|
|
Csequence(Cop(Ccheckbound dbg, [addr_array_length hdr; idx]),
|
|
addr_array_set arr idx newval),
|
|
Csequence(Cop(Ccheckbound dbg, [float_array_length hdr; idx]),
|
|
float_array_set arr idx
|
|
(unbox_float newval)))))))
|
|
| Paddrarray ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Csequence(Cop(Ccheckbound dbg, [addr_array_length(header arr); idx]),
|
|
addr_array_set arr idx (transl arg3))))
|
|
| Pintarray ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Csequence(Cop(Ccheckbound dbg, [addr_array_length(header arr); idx]),
|
|
int_array_set arr idx (transl arg3))))
|
|
| Pfloatarray ->
|
|
bind "index" (transl arg2) (fun idx ->
|
|
bind "arr" (transl arg1) (fun arr ->
|
|
Csequence(Cop(Ccheckbound dbg, [float_array_length(header arr);idx]),
|
|
float_array_set arr idx (transl_unbox_float arg3))))
|
|
end)
|
|
| _ ->
|
|
fatal_error "Cmmgen.transl_prim_3"
|
|
|
|
and transl_unbox_float = function
|
|
Uconst(Const_base(Const_float f)) -> Cconst_float f
|
|
| exp -> unbox_float(transl exp)
|
|
|
|
and transl_unbox_int bi = function
|
|
Uconst(Const_base(Const_int32 n)) ->
|
|
Cconst_natint (Nativeint.of_int32 n)
|
|
| Uconst(Const_base(Const_nativeint n)) ->
|
|
Cconst_natint n
|
|
| Uconst(Const_base(Const_int64 n)) ->
|
|
assert (size_int = 8); Cconst_natint (Int64.to_nativeint n)
|
|
| Uprim(Pbintofint bi', [Uconst(Const_base(Const_int i))], _) when bi = bi' ->
|
|
Cconst_int i
|
|
| exp -> unbox_int bi (transl exp)
|
|
|
|
and transl_unbox_let box_fn unbox_fn transl_unbox_fn id exp body =
|
|
let unboxed_id = Ident.create (Ident.name id) in
|
|
let trbody1 = transl body in
|
|
let (trbody2, need_boxed, is_assigned) =
|
|
subst_boxed_number unbox_fn id unboxed_id trbody1 in
|
|
if need_boxed && is_assigned then
|
|
Clet(id, transl exp, trbody1)
|
|
else
|
|
Clet(unboxed_id, transl_unbox_fn exp,
|
|
if need_boxed
|
|
then Clet(id, box_fn(Cvar unboxed_id), trbody2)
|
|
else trbody2)
|
|
|
|
and make_catch ncatch body handler = match body with
|
|
| Cexit (nexit,[]) when nexit=ncatch -> handler
|
|
| _ -> Ccatch (ncatch, [], body, handler)
|
|
|
|
and make_catch2 mk_body handler = match handler with
|
|
| Cexit (_,[])|Ctuple []|Cconst_int _|Cconst_pointer _ ->
|
|
mk_body handler
|
|
| _ ->
|
|
let nfail = next_raise_count () in
|
|
make_catch
|
|
nfail
|
|
(mk_body (Cexit (nfail,[])))
|
|
handler
|
|
|
|
and exit_if_true cond nfail otherwise =
|
|
match cond with
|
|
| Uconst (Const_pointer 0) -> otherwise
|
|
| Uconst (Const_pointer 1) -> Cexit (nfail,[])
|
|
| Uprim(Psequor, [arg1; arg2], _) ->
|
|
exit_if_true arg1 nfail (exit_if_true arg2 nfail otherwise)
|
|
| Uprim(Psequand, _, _) ->
|
|
begin match otherwise with
|
|
| Cexit (raise_num,[]) ->
|
|
exit_if_false cond (Cexit (nfail,[])) raise_num
|
|
| _ ->
|
|
let raise_num = next_raise_count () in
|
|
make_catch
|
|
raise_num
|
|
(exit_if_false cond (Cexit (nfail,[])) raise_num)
|
|
otherwise
|
|
end
|
|
| Uprim(Pnot, [arg], _) ->
|
|
exit_if_false arg otherwise nfail
|
|
| Uifthenelse (cond, ifso, ifnot) ->
|
|
make_catch2
|
|
(fun shared ->
|
|
Cifthenelse
|
|
(test_bool (transl cond),
|
|
exit_if_true ifso nfail shared,
|
|
exit_if_true ifnot nfail shared))
|
|
otherwise
|
|
| _ ->
|
|
Cifthenelse(test_bool(transl cond), Cexit (nfail, []), otherwise)
|
|
|
|
and exit_if_false cond otherwise nfail =
|
|
match cond with
|
|
| Uconst (Const_pointer 0) -> Cexit (nfail,[])
|
|
| Uconst (Const_pointer 1) -> otherwise
|
|
| Uprim(Psequand, [arg1; arg2], _) ->
|
|
exit_if_false arg1 (exit_if_false arg2 otherwise nfail) nfail
|
|
| Uprim(Psequor, _, _) ->
|
|
begin match otherwise with
|
|
| Cexit (raise_num,[]) ->
|
|
exit_if_true cond raise_num (Cexit (nfail,[]))
|
|
| _ ->
|
|
let raise_num = next_raise_count () in
|
|
make_catch
|
|
raise_num
|
|
(exit_if_true cond raise_num (Cexit (nfail,[])))
|
|
otherwise
|
|
end
|
|
| Uprim(Pnot, [arg], _) ->
|
|
exit_if_true arg nfail otherwise
|
|
| Uifthenelse (cond, ifso, ifnot) ->
|
|
make_catch2
|
|
(fun shared ->
|
|
Cifthenelse
|
|
(test_bool (transl cond),
|
|
exit_if_false ifso shared nfail,
|
|
exit_if_false ifnot shared nfail))
|
|
otherwise
|
|
| _ ->
|
|
Cifthenelse(test_bool(transl cond), otherwise, Cexit (nfail, []))
|
|
|
|
and transl_switch arg index cases = match Array.length cases with
|
|
| 0 -> fatal_error "Cmmgen.transl_switch"
|
|
| 1 -> transl cases.(0)
|
|
| _ ->
|
|
let n_index = Array.length index in
|
|
let actions = Array.map transl cases in
|
|
|
|
let inters = ref []
|
|
and this_high = ref (n_index-1)
|
|
and this_low = ref (n_index-1)
|
|
and this_act = ref index.(n_index-1) in
|
|
for i = n_index-2 downto 0 do
|
|
let act = index.(i) in
|
|
if act = !this_act then
|
|
decr this_low
|
|
else begin
|
|
inters := (!this_low, !this_high, !this_act) :: !inters ;
|
|
this_high := i ;
|
|
this_low := i ;
|
|
this_act := act
|
|
end
|
|
done ;
|
|
inters := (0, !this_high, !this_act) :: !inters ;
|
|
bind "switcher" arg
|
|
(fun a ->
|
|
SwitcherBlocks.zyva
|
|
(0,n_index-1)
|
|
(fun i -> Cconst_int i)
|
|
a
|
|
(Array.of_list !inters) actions)
|
|
|
|
and transl_letrec bindings cont =
|
|
let bsz = List.map (fun (id, exp) -> (id, exp, expr_size exp)) bindings in
|
|
let rec init_blocks = function
|
|
| [] -> fill_nonrec bsz
|
|
| (id, exp, RHS_block sz) :: rem ->
|
|
Clet(id, Cop(Cextcall("caml_alloc_dummy", typ_addr, true, Debuginfo.none),
|
|
[int_const sz]),
|
|
init_blocks rem)
|
|
| (id, exp, RHS_nonrec) :: rem ->
|
|
Clet (id, Cconst_int 0, init_blocks rem)
|
|
and fill_nonrec = function
|
|
| [] -> fill_blocks bsz
|
|
| (id, exp, RHS_block sz) :: rem -> fill_nonrec rem
|
|
| (id, exp, RHS_nonrec) :: rem ->
|
|
Clet (id, transl exp, fill_nonrec rem)
|
|
and fill_blocks = function
|
|
| [] -> cont
|
|
| (id, exp, RHS_block _) :: rem ->
|
|
Csequence(Cop(Cextcall("caml_update_dummy", typ_void, false, Debuginfo.none),
|
|
[Cvar id; transl exp]),
|
|
fill_blocks rem)
|
|
| (id, exp, RHS_nonrec) :: rem ->
|
|
fill_blocks rem
|
|
in init_blocks bsz
|
|
|
|
(* Translate a function definition *)
|
|
|
|
let transl_function lbl params body =
|
|
Cfunction {fun_name = lbl;
|
|
fun_args = List.map (fun id -> (id, typ_addr)) params;
|
|
fun_body = transl body;
|
|
fun_fast = !Clflags.optimize_for_speed}
|
|
|
|
(* Translate all function definitions *)
|
|
|
|
module StringSet =
|
|
Set.Make(struct
|
|
type t = string
|
|
let compare = compare
|
|
end)
|
|
|
|
let rec transl_all_functions already_translated cont =
|
|
try
|
|
let (lbl, params, body) = Queue.take functions in
|
|
if StringSet.mem lbl already_translated then
|
|
transl_all_functions already_translated cont
|
|
else begin
|
|
transl_all_functions (StringSet.add lbl already_translated)
|
|
(transl_function lbl params body :: cont)
|
|
end
|
|
with Queue.Empty ->
|
|
cont
|
|
|
|
(* Emit structured constants *)
|
|
|
|
let immstrings = Hashtbl.create 17
|
|
|
|
let rec emit_constant symb cst cont =
|
|
match cst with
|
|
Const_base(Const_float s) ->
|
|
Cint(float_header) :: Cdefine_symbol symb :: Cdouble s :: cont
|
|
| Const_base(Const_string s) | Const_immstring s ->
|
|
Cint(string_header (String.length s)) ::
|
|
Cdefine_symbol symb ::
|
|
emit_string_constant s cont
|
|
| Const_base(Const_int32 n) ->
|
|
Cint(boxedint32_header) :: Cdefine_symbol symb ::
|
|
emit_boxed_int32_constant n cont
|
|
| Const_base(Const_int64 n) ->
|
|
Cint(boxedint64_header) :: Cdefine_symbol symb ::
|
|
emit_boxed_int64_constant n cont
|
|
| Const_base(Const_nativeint n) ->
|
|
Cint(boxedintnat_header) :: Cdefine_symbol symb ::
|
|
emit_boxed_nativeint_constant n cont
|
|
| Const_block(tag, fields) ->
|
|
let (emit_fields, cont1) = emit_constant_fields fields cont in
|
|
Cint(block_header tag (List.length fields)) ::
|
|
Cdefine_symbol symb ::
|
|
emit_fields @ cont1
|
|
| Const_float_array(fields) ->
|
|
Cint(floatarray_header (List.length fields)) ::
|
|
Cdefine_symbol symb ::
|
|
Misc.map_end (fun f -> Cdouble f) fields cont
|
|
| _ -> fatal_error "gencmm.emit_constant"
|
|
|
|
and emit_constant_fields fields cont =
|
|
match fields with
|
|
[] -> ([], cont)
|
|
| f1 :: fl ->
|
|
let (data1, cont1) = emit_constant_field f1 cont in
|
|
let (datal, contl) = emit_constant_fields fl cont1 in
|
|
(data1 :: datal, contl)
|
|
|
|
and emit_constant_field field cont =
|
|
match field with
|
|
Const_base(Const_int n) ->
|
|
(Cint(Nativeint.add (Nativeint.shift_left (Nativeint.of_int n) 1) 1n),
|
|
cont)
|
|
| Const_base(Const_char c) ->
|
|
(Cint(Nativeint.of_int(((Char.code c) lsl 1) + 1)), cont)
|
|
| Const_base(Const_float s) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(float_header) :: Cdefine_label lbl :: Cdouble s :: cont)
|
|
| Const_base(Const_string s) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(string_header (String.length s)) :: Cdefine_label lbl ::
|
|
emit_string_constant s cont)
|
|
| Const_immstring s ->
|
|
begin try
|
|
(Clabel_address (Hashtbl.find immstrings s), cont)
|
|
with Not_found ->
|
|
let lbl = new_const_label() in
|
|
Hashtbl.add immstrings s lbl;
|
|
(Clabel_address lbl,
|
|
Cint(string_header (String.length s)) :: Cdefine_label lbl ::
|
|
emit_string_constant s cont)
|
|
end
|
|
| Const_base(Const_int32 n) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(boxedint32_header) :: Cdefine_label lbl ::
|
|
emit_boxed_int32_constant n cont)
|
|
| Const_base(Const_int64 n) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(boxedint64_header) :: Cdefine_label lbl ::
|
|
emit_boxed_int64_constant n cont)
|
|
| Const_base(Const_nativeint n) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(boxedintnat_header) :: Cdefine_label lbl ::
|
|
emit_boxed_nativeint_constant n cont)
|
|
| Const_pointer n ->
|
|
(Cint(Nativeint.add (Nativeint.shift_left (Nativeint.of_int n) 1) 1n),
|
|
cont)
|
|
| Const_block(tag, fields) ->
|
|
let lbl = new_const_label() in
|
|
let (emit_fields, cont1) = emit_constant_fields fields cont in
|
|
(Clabel_address lbl,
|
|
Cint(block_header tag (List.length fields)) :: Cdefine_label lbl ::
|
|
emit_fields @ cont1)
|
|
| Const_float_array(fields) ->
|
|
let lbl = new_const_label() in
|
|
(Clabel_address lbl,
|
|
Cint(floatarray_header (List.length fields)) :: Cdefine_label lbl ::
|
|
Misc.map_end (fun f -> Cdouble f) fields cont)
|
|
|
|
and emit_string_constant s cont =
|
|
let n = size_int - 1 - (String.length s) mod size_int in
|
|
Cstring s :: Cskip n :: Cint8 n :: cont
|
|
|
|
and emit_boxed_int32_constant n cont =
|
|
let n = Nativeint.of_int32 n in
|
|
if size_int = 8 then
|
|
Csymbol_address("caml_int32_ops") :: Cint32 n :: Cint32 0n :: cont
|
|
else
|
|
Csymbol_address("caml_int32_ops") :: Cint n :: cont
|
|
|
|
and emit_boxed_nativeint_constant n cont =
|
|
Csymbol_address("caml_nativeint_ops") :: Cint n :: cont
|
|
|
|
and emit_boxed_int64_constant n cont =
|
|
let lo = Int64.to_nativeint n in
|
|
if size_int = 8 then
|
|
Csymbol_address("caml_int64_ops") :: Cint lo :: cont
|
|
else begin
|
|
let hi = Int64.to_nativeint (Int64.shift_right n 32) in
|
|
if big_endian then
|
|
Csymbol_address("caml_int64_ops") :: Cint hi :: Cint lo :: cont
|
|
else
|
|
Csymbol_address("caml_int64_ops") :: Cint lo :: Cint hi :: cont
|
|
end
|
|
|
|
(* Emit constant closures *)
|
|
|
|
let emit_constant_closure symb fundecls cont =
|
|
match fundecls with
|
|
[] -> assert false
|
|
| (label, arity, params, body) :: remainder ->
|
|
let rec emit_others pos = function
|
|
[] -> cont
|
|
| (label, arity, params, body) :: rem ->
|
|
if arity = 1 then
|
|
Cint(infix_header pos) ::
|
|
Csymbol_address label ::
|
|
Cint 3n ::
|
|
emit_others (pos + 3) rem
|
|
else
|
|
Cint(infix_header pos) ::
|
|
Csymbol_address(curry_function arity) ::
|
|
Cint(Nativeint.of_int (arity lsl 1 + 1)) ::
|
|
Csymbol_address label ::
|
|
emit_others (pos + 4) rem in
|
|
Cint(closure_header (fundecls_size fundecls)) ::
|
|
Cdefine_symbol symb ::
|
|
if arity = 1 then
|
|
Csymbol_address label ::
|
|
Cint 3n ::
|
|
emit_others 3 remainder
|
|
else
|
|
Csymbol_address(curry_function arity) ::
|
|
Cint(Nativeint.of_int (arity lsl 1 + 1)) ::
|
|
Csymbol_address label ::
|
|
emit_others 4 remainder
|
|
|
|
(* Emit all structured constants *)
|
|
|
|
let emit_all_constants cont =
|
|
let c = ref cont in
|
|
List.iter
|
|
(fun (lbl, cst) -> c := Cdata(emit_constant lbl cst []) :: !c)
|
|
!structured_constants;
|
|
structured_constants := [];
|
|
Hashtbl.clear immstrings; (* PR#3979 *)
|
|
List.iter
|
|
(fun (symb, fundecls) ->
|
|
c := Cdata(emit_constant_closure symb fundecls []) :: !c)
|
|
!constant_closures;
|
|
constant_closures := [];
|
|
!c
|
|
|
|
(* Translate a compilation unit *)
|
|
|
|
let compunit size ulam =
|
|
let glob = Compilenv.make_symbol None in
|
|
let init_code = transl ulam in
|
|
let c1 = [Cfunction {fun_name = Compilenv.make_symbol (Some "entry");
|
|
fun_args = [];
|
|
fun_body = init_code; fun_fast = false}] in
|
|
let c2 = transl_all_functions StringSet.empty c1 in
|
|
let c3 = emit_all_constants c2 in
|
|
Cdata [Cint(block_header 0 size);
|
|
Cglobal_symbol glob;
|
|
Cdefine_symbol glob;
|
|
Cskip(size * size_addr)] :: c3
|
|
|
|
(*
|
|
CAMLprim value caml_cache_public_method (value meths, value tag, value *cache)
|
|
{
|
|
int li = 3, hi = Field(meths,0), mi;
|
|
while (li < hi) { // no need to check the 1st time
|
|
mi = ((li+hi) >> 1) | 1;
|
|
if (tag < Field(meths,mi)) hi = mi-2;
|
|
else li = mi;
|
|
}
|
|
*cache = (li-3)*sizeof(value)+1;
|
|
return Field (meths, li-1);
|
|
}
|
|
*)
|
|
|
|
let cache_public_method meths tag cache =
|
|
let raise_num = next_raise_count () in
|
|
let li = Ident.create "li" and hi = Ident.create "hi"
|
|
and mi = Ident.create "mi" and tagged = Ident.create "tagged" in
|
|
Clet (
|
|
li, Cconst_int 3,
|
|
Clet (
|
|
hi, Cop(Cload Word, [meths]),
|
|
Csequence(
|
|
Ccatch
|
|
(raise_num, [],
|
|
Cloop
|
|
(Clet(
|
|
mi,
|
|
Cop(Cor,
|
|
[Cop(Clsr, [Cop(Caddi, [Cvar li; Cvar hi]); Cconst_int 1]);
|
|
Cconst_int 1]),
|
|
Csequence(
|
|
Cifthenelse
|
|
(Cop (Ccmpi Clt,
|
|
[tag;
|
|
Cop(Cload Word,
|
|
[Cop(Cadda,
|
|
[meths; lsl_const (Cvar mi) log2_size_addr])])]),
|
|
Cassign(hi, Cop(Csubi, [Cvar mi; Cconst_int 2])),
|
|
Cassign(li, Cvar mi)),
|
|
Cifthenelse
|
|
(Cop(Ccmpi Cge, [Cvar li; Cvar hi]), Cexit (raise_num, []),
|
|
Ctuple [])))),
|
|
Ctuple []),
|
|
Clet (
|
|
tagged, Cop(Cadda, [lsl_const (Cvar li) log2_size_addr;
|
|
Cconst_int(1 - 3 * size_addr)]),
|
|
Csequence(Cop (Cstore Word, [cache; Cvar tagged]),
|
|
Cvar tagged)))))
|
|
|
|
(* Generate an application function:
|
|
(defun caml_applyN (a1 ... aN clos)
|
|
(if (= clos.arity N)
|
|
(app clos.direct a1 ... aN clos)
|
|
(let (clos1 (app clos.code a1 clos)
|
|
clos2 (app clos1.code a2 clos)
|
|
...
|
|
closN-1 (app closN-2.code aN-1 closN-2))
|
|
(app closN-1.code aN closN-1))))
|
|
*)
|
|
|
|
let apply_function_body arity =
|
|
let arg = Array.create arity (Ident.create "arg") in
|
|
for i = 1 to arity - 1 do arg.(i) <- Ident.create "arg" done;
|
|
let clos = Ident.create "clos" in
|
|
let rec app_fun clos n =
|
|
if n = arity-1 then
|
|
Cop(Capply(typ_addr, Debuginfo.none),
|
|
[get_field (Cvar clos) 0; Cvar arg.(n); Cvar clos])
|
|
else begin
|
|
let newclos = Ident.create "clos" in
|
|
Clet(newclos,
|
|
Cop(Capply(typ_addr, Debuginfo.none),
|
|
[get_field (Cvar clos) 0; Cvar arg.(n); Cvar clos]),
|
|
app_fun newclos (n+1))
|
|
end in
|
|
let args = Array.to_list arg in
|
|
let all_args = args @ [clos] in
|
|
(args, clos,
|
|
if arity = 1 then app_fun clos 0 else
|
|
Cifthenelse(
|
|
Cop(Ccmpi Ceq, [get_field (Cvar clos) 1; int_const arity]),
|
|
Cop(Capply(typ_addr, Debuginfo.none),
|
|
get_field (Cvar clos) 2 :: List.map (fun s -> Cvar s) all_args),
|
|
app_fun clos 0))
|
|
|
|
let send_function arity =
|
|
let (args, clos', body) = apply_function_body (1+arity) in
|
|
let cache = Ident.create "cache"
|
|
and obj = List.hd args
|
|
and tag = Ident.create "tag" in
|
|
let clos =
|
|
let cache = Cvar cache and obj = Cvar obj and tag = Cvar tag in
|
|
let meths = Ident.create "meths" and cached = Ident.create "cached" in
|
|
let real = Ident.create "real" in
|
|
let mask = get_field (Cvar meths) 1 in
|
|
let cached_pos = Cvar cached in
|
|
let tag_pos = Cop(Cadda, [Cop (Cadda, [cached_pos; Cvar meths]);
|
|
Cconst_int(3*size_addr-1)]) in
|
|
let tag' = Cop(Cload Word, [tag_pos]) in
|
|
Clet (
|
|
meths, Cop(Cload Word, [obj]),
|
|
Clet (
|
|
cached, Cop(Cand, [Cop(Cload Word, [cache]); mask]),
|
|
Clet (
|
|
real,
|
|
Cifthenelse(Cop(Ccmpa Cne, [tag'; tag]),
|
|
cache_public_method (Cvar meths) tag cache,
|
|
cached_pos),
|
|
Cop(Cload Word, [Cop(Cadda, [Cop (Cadda, [Cvar real; Cvar meths]);
|
|
Cconst_int(2*size_addr-1)])]))))
|
|
|
|
in
|
|
let body = Clet(clos', clos, body) in
|
|
let fun_args =
|
|
[obj, typ_addr; tag, typ_int; cache, typ_addr]
|
|
@ List.map (fun id -> (id, typ_addr)) (List.tl args) in
|
|
Cfunction
|
|
{fun_name = "caml_send" ^ string_of_int arity;
|
|
fun_args = fun_args;
|
|
fun_body = body;
|
|
fun_fast = true}
|
|
|
|
let apply_function arity =
|
|
let (args, clos, body) = apply_function_body arity in
|
|
let all_args = args @ [clos] in
|
|
Cfunction
|
|
{fun_name = "caml_apply" ^ string_of_int arity;
|
|
fun_args = List.map (fun id -> (id, typ_addr)) all_args;
|
|
fun_body = body;
|
|
fun_fast = true}
|
|
|
|
(* Generate tuplifying functions:
|
|
(defun caml_tuplifyN (arg clos)
|
|
(app clos.direct #0(arg) ... #N-1(arg) clos)) *)
|
|
|
|
let tuplify_function arity =
|
|
let arg = Ident.create "arg" in
|
|
let clos = Ident.create "clos" in
|
|
let rec access_components i =
|
|
if i >= arity
|
|
then []
|
|
else get_field (Cvar arg) i :: access_components(i+1) in
|
|
Cfunction
|
|
{fun_name = "caml_tuplify" ^ string_of_int arity;
|
|
fun_args = [arg, typ_addr; clos, typ_addr];
|
|
fun_body =
|
|
Cop(Capply(typ_addr, Debuginfo.none),
|
|
get_field (Cvar clos) 2 :: access_components 0 @ [Cvar clos]);
|
|
fun_fast = true}
|
|
|
|
(* Generate currying functions:
|
|
(defun caml_curryN (arg clos)
|
|
(alloc HDR caml_curryN_1 arg clos))
|
|
(defun caml_curryN_1 (arg clos)
|
|
(alloc HDR caml_curryN_2 arg clos))
|
|
...
|
|
(defun caml_curryN_N-1 (arg clos)
|
|
(let (closN-2 clos.cdr
|
|
closN-3 closN-2.cdr
|
|
...
|
|
clos1 clos2.cdr
|
|
clos clos1.cdr)
|
|
(app clos.direct
|
|
clos1.car clos2.car ... closN-2.car clos.car arg clos))) *)
|
|
|
|
let final_curry_function arity =
|
|
let last_arg = Ident.create "arg" in
|
|
let last_clos = Ident.create "clos" in
|
|
let rec curry_fun args clos n =
|
|
if n = 0 then
|
|
Cop(Capply(typ_addr, Debuginfo.none),
|
|
get_field (Cvar clos) 2 ::
|
|
args @ [Cvar last_arg; Cvar clos])
|
|
else begin
|
|
let newclos = Ident.create "clos" in
|
|
Clet(newclos,
|
|
get_field (Cvar clos) 3,
|
|
curry_fun (get_field (Cvar clos) 2 :: args) newclos (n-1))
|
|
end in
|
|
Cfunction
|
|
{fun_name = "caml_curry" ^ string_of_int arity ^
|
|
"_" ^ string_of_int (arity-1);
|
|
fun_args = [last_arg, typ_addr; last_clos, typ_addr];
|
|
fun_body = curry_fun [] last_clos (arity-1);
|
|
fun_fast = true}
|
|
|
|
let rec intermediate_curry_functions arity num =
|
|
if num = arity - 1 then
|
|
[final_curry_function arity]
|
|
else begin
|
|
let name1 = "caml_curry" ^ string_of_int arity in
|
|
let name2 = if num = 0 then name1 else name1 ^ "_" ^ string_of_int num in
|
|
let arg = Ident.create "arg" and clos = Ident.create "clos" in
|
|
Cfunction
|
|
{fun_name = name2;
|
|
fun_args = [arg, typ_addr; clos, typ_addr];
|
|
fun_body = Cop(Calloc,
|
|
[alloc_closure_header 4;
|
|
Cconst_symbol(name1 ^ "_" ^ string_of_int (num+1));
|
|
int_const 1; Cvar arg; Cvar clos]);
|
|
fun_fast = true}
|
|
:: intermediate_curry_functions arity (num+1)
|
|
end
|
|
|
|
let curry_function arity =
|
|
if arity >= 0
|
|
then intermediate_curry_functions arity 0
|
|
else [tuplify_function (-arity)]
|
|
|
|
|
|
module IntSet = Set.Make(
|
|
struct
|
|
type t = int
|
|
let compare = compare
|
|
end)
|
|
|
|
let default_apply = IntSet.add 2 (IntSet.add 3 IntSet.empty)
|
|
(* These apply funs are always present in the main program because
|
|
the run-time system needs them (cf. asmrun/<arch>.S) . *)
|
|
|
|
let generic_functions shared units =
|
|
let (apply,send,curry) =
|
|
List.fold_left
|
|
(fun (apply,send,curry) ui ->
|
|
List.fold_right IntSet.add ui.Compilenv.ui_apply_fun apply,
|
|
List.fold_right IntSet.add ui.Compilenv.ui_send_fun send,
|
|
List.fold_right IntSet.add ui.Compilenv.ui_curry_fun curry)
|
|
(IntSet.empty,IntSet.empty,IntSet.empty)
|
|
units in
|
|
let apply = if shared then apply else IntSet.union apply default_apply in
|
|
let accu = IntSet.fold (fun n accu -> apply_function n :: accu) apply [] in
|
|
let accu = IntSet.fold (fun n accu -> send_function n :: accu) send accu in
|
|
IntSet.fold (fun n accu -> curry_function n @ accu) curry accu
|
|
|
|
(* Generate the entry point *)
|
|
|
|
let entry_point namelist =
|
|
let incr_global_inited =
|
|
Cop(Cstore Word,
|
|
[Cconst_symbol "caml_globals_inited";
|
|
Cop(Caddi, [Cop(Cload Word, [Cconst_symbol "caml_globals_inited"]);
|
|
Cconst_int 1])]) in
|
|
let body =
|
|
List.fold_right
|
|
(fun name next ->
|
|
let entry_sym = Compilenv.make_symbol ~unitname:name (Some "entry") in
|
|
Csequence(Cop(Capply(typ_void, Debuginfo.none),
|
|
[Cconst_symbol entry_sym]),
|
|
Csequence(incr_global_inited, next)))
|
|
namelist (Cconst_int 1) in
|
|
Cfunction {fun_name = "caml_program";
|
|
fun_args = [];
|
|
fun_body = body;
|
|
fun_fast = false}
|
|
|
|
(* Generate the table of globals *)
|
|
|
|
let cint_zero = Cint 0n
|
|
|
|
let global_table namelist =
|
|
let mksym name =
|
|
Csymbol_address (Compilenv.make_symbol ~unitname:name None)
|
|
in
|
|
Cdata(Cglobal_symbol "caml_globals" ::
|
|
Cdefine_symbol "caml_globals" ::
|
|
List.map mksym namelist @
|
|
[cint_zero])
|
|
|
|
let reference_symbols namelist =
|
|
let mksym name = Csymbol_address name in
|
|
Cdata(List.map mksym namelist)
|
|
|
|
let global_data name v =
|
|
Cdata(Cglobal_symbol name ::
|
|
emit_constant name
|
|
(Const_base (Const_string (Marshal.to_string v []))) [])
|
|
|
|
let globals_map v = global_data "caml_globals_map" v
|
|
|
|
(* Generate the master table of frame descriptors *)
|
|
|
|
let frame_table namelist =
|
|
let mksym name =
|
|
Csymbol_address (Compilenv.make_symbol ~unitname:name (Some "frametable"))
|
|
in
|
|
Cdata(Cglobal_symbol "caml_frametable" ::
|
|
Cdefine_symbol "caml_frametable" ::
|
|
List.map mksym namelist
|
|
@ [cint_zero])
|
|
|
|
(* Generate the table of module data and code segments *)
|
|
|
|
let segment_table namelist symbol begname endname =
|
|
let addsyms name lst =
|
|
Csymbol_address (Compilenv.make_symbol ~unitname:name (Some begname)) ::
|
|
Csymbol_address (Compilenv.make_symbol ~unitname:name (Some endname)) ::
|
|
lst
|
|
in
|
|
Cdata(Cglobal_symbol symbol ::
|
|
Cdefine_symbol symbol ::
|
|
List.fold_right addsyms namelist [cint_zero])
|
|
|
|
let data_segment_table namelist =
|
|
segment_table namelist "caml_data_segments" "data_begin" "data_end"
|
|
|
|
let code_segment_table namelist =
|
|
segment_table namelist "caml_code_segments" "code_begin" "code_end"
|
|
|
|
(* Initialize a predefined exception *)
|
|
|
|
let predef_exception name =
|
|
let bucketname = "caml_bucket_" ^ name in
|
|
let symname = "caml_exn_" ^ name in
|
|
Cdata(Cglobal_symbol symname ::
|
|
emit_constant symname (Const_block(0,[Const_base(Const_string name)]))
|
|
[ Cglobal_symbol bucketname;
|
|
Cint(block_header 0 1);
|
|
Cdefine_symbol bucketname;
|
|
Csymbol_address symname ])
|
|
|
|
(* Header for a plugin *)
|
|
|
|
let mapflat f l = List.flatten (List.map f l)
|
|
|
|
type dynunit = {
|
|
name: string;
|
|
crc: Digest.t;
|
|
imports_cmi: (string * Digest.t) list;
|
|
imports_cmx: (string * Digest.t) list;
|
|
defines: string list;
|
|
}
|
|
|
|
type dynheader = {
|
|
magic: string;
|
|
units: dynunit list;
|
|
}
|
|
|
|
let dyn_magic_number = "Caml2007D001"
|
|
|
|
let plugin_header units =
|
|
let mk (ui,crc) =
|
|
{ name = ui.Compilenv.ui_name;
|
|
crc = crc;
|
|
imports_cmi = ui.Compilenv.ui_imports_cmi;
|
|
imports_cmx = ui.Compilenv.ui_imports_cmx;
|
|
defines = ui.Compilenv.ui_defines
|
|
} in
|
|
global_data "caml_plugin_header"
|
|
{ magic = dyn_magic_number; units = List.map mk units }
|