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printclambda.ml
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printclambda.ml
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(**************************************************************************)
(* *)
(* OCaml *)
(* *)
(* Xavier Leroy, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 1996 Institut National de Recherche en Informatique et *)
(* en Automatique. *)
(* *)
(* All rights reserved. This file is distributed under the terms of *)
(* the GNU Lesser General Public License version 2.1, with the *)
(* special exception on linking described in the file LICENSE. *)
(* *)
(**************************************************************************)
open Format
open Asttypes
open Clambda
module V = Backend_var
module VP = Backend_var.With_provenance
let mutable_flag = function
| Mutable-> "[mut]"
| Immutable -> ""
let value_kind =
let open Lambda in
function
| Pgenval -> ""
| Pintval -> ":int"
| Pfloatval -> ":float"
| Pboxedintval Pnativeint -> ":nativeint"
| Pboxedintval Pint32 -> ":int32"
| Pboxedintval Pint64 -> ":int64"
let rec structured_constant ppf = function
| Uconst_float x -> fprintf ppf "%F" x
| Uconst_int32 x -> fprintf ppf "%ldl" x
| Uconst_int64 x -> fprintf ppf "%LdL" x
| Uconst_nativeint x -> fprintf ppf "%ndn" x
| Uconst_block (tag, l) ->
fprintf ppf "block(%i" tag;
List.iter (fun u -> fprintf ppf ",%a" uconstant u) l;
fprintf ppf ")"
| Uconst_float_array [] ->
fprintf ppf "floatarray()"
| Uconst_float_array (f1 :: fl) ->
fprintf ppf "floatarray(%F" f1;
List.iter (fun f -> fprintf ppf ",%F" f) fl;
fprintf ppf ")"
| Uconst_string s -> fprintf ppf "%S" s
| Uconst_closure(clos, sym, fv) ->
let funs ppf =
List.iter (fprintf ppf "@ %a" one_fun) in
let sconsts ppf scl =
List.iter (fun sc -> fprintf ppf "@ %a" uconstant sc) scl in
fprintf ppf "@[<2>(const_closure%a %s@ %a)@]" funs clos sym sconsts fv
and one_fun ppf f =
let idents ppf =
List.iter
(fun (x, k) ->
fprintf ppf "@ %a%a"
VP.print x
Printlambda.value_kind k
)
in
fprintf ppf "(fun@ %s%s@ %d@ @[<2>%a@]@ @[<2>%a@])"
f.label (value_kind f.return) f.arity idents f.params lam f.body
and phantom_defining_expr ppf = function
| Uphantom_const const -> uconstant ppf const
| Uphantom_var var -> Ident.print ppf var
| Uphantom_offset_var { var; offset_in_words; } ->
Format.fprintf ppf "%a+(%d)" Backend_var.print var offset_in_words
| Uphantom_read_field { var; field; } ->
Format.fprintf ppf "%a[%d]" Backend_var.print var field
| Uphantom_read_symbol_field { sym; field; } ->
Format.fprintf ppf "%s[%d]" sym field
| Uphantom_block { tag; fields; } ->
Format.fprintf ppf "[%d: " tag;
List.iter (fun field ->
Format.fprintf ppf "%a; " Backend_var.print field)
fields;
Format.fprintf ppf "]"
and phantom_defining_expr_opt ppf = function
| None -> Format.fprintf ppf "DEAD"
| Some expr -> phantom_defining_expr ppf expr
and uconstant ppf = function
| Uconst_ref (s, Some c) ->
fprintf ppf "%S=%a" s structured_constant c
| Uconst_ref (s, None) -> fprintf ppf "%S"s
| Uconst_int i -> fprintf ppf "%i" i
and lam ppf = function
| Uvar id ->
V.print ppf id
| Uconst c -> uconstant ppf c
| Udirect_apply(f, largs, _) ->
let lams ppf largs =
List.iter (fun l -> fprintf ppf "@ %a" lam l) largs in
fprintf ppf "@[<2>(apply*@ %s %a)@]" f lams largs
| Ugeneric_apply(lfun, largs, _) ->
let lams ppf largs =
List.iter (fun l -> fprintf ppf "@ %a" lam l) largs in
fprintf ppf "@[<2>(apply@ %a%a)@]" lam lfun lams largs
| Uclosure(clos, fv) ->
let funs ppf =
List.iter (fprintf ppf "@ @[<2>%a@]" one_fun) in
let lams ppf =
List.iter (fprintf ppf "@ %a" lam) in
fprintf ppf "@[<2>(closure@ %a %a)@]" funs clos lams fv
| Uoffset(l,i) -> fprintf ppf "@[<2>(offset %a %d)@]" lam l i
| Ulet(mut, kind, id, arg, body) ->
let rec letbody ul = match ul with
| Ulet(mut, kind, id, arg, body) ->
fprintf ppf "@ @[<2>%a%s%s@ %a@]"
VP.print id
(mutable_flag mut) (value_kind kind) lam arg;
letbody body
| _ -> ul in
fprintf ppf "@[<2>(let@ @[<hv 1>(@[<2>%a%s%s@ %a@]"
VP.print id (mutable_flag mut)
(value_kind kind) lam arg;
let expr = letbody body in
fprintf ppf ")@]@ %a)@]" lam expr
| Uphantom_let (id, defining_expr, body) ->
let rec letbody ul = match ul with
| Uphantom_let (id, defining_expr, body) ->
fprintf ppf "@ @[<2>%a@ %a@]"
Backend_var.With_provenance.print id
phantom_defining_expr_opt defining_expr;
letbody body
| _ -> ul in
fprintf ppf "@[<2>(phantom_let@ @[<hv 1>(@[<2>%a@ %a@]"
Backend_var.With_provenance.print id
phantom_defining_expr_opt defining_expr;
let expr = letbody body in
fprintf ppf ")@]@ %a)@]" lam expr
| Uprim(prim, largs, _) ->
let lams ppf largs =
List.iter (fun l -> fprintf ppf "@ %a" lam l) largs in
fprintf ppf "@[<2>(%a%a)@]"
Printclambda_primitives.primitive prim lams largs
| Uswitch(larg, sw, _dbg) ->
let print_case tag index i ppf =
for j = 0 to Array.length index - 1 do
if index.(j) = i then fprintf ppf "case %s %i:" tag j
done in
let print_cases tag index cases ppf =
for i = 0 to Array.length cases - 1 do
fprintf ppf "@ @[<2>%t@ %a@]"
(print_case tag index i) sequence cases.(i)
done in
let switch ppf sw =
print_cases "int" sw.us_index_consts sw.us_actions_consts ppf ;
print_cases "tag" sw.us_index_blocks sw.us_actions_blocks ppf in
fprintf ppf
"@[<v 0>@[<2>(switch@ %a@ @]%a)@]"
lam larg switch sw
| Ustringswitch(larg,sw,d) ->
let switch ppf sw =
let spc = ref false in
List.iter
(fun (s,l) ->
if !spc then fprintf ppf "@ " else spc := true;
fprintf ppf "@[<hv 1>case \"%s\":@ %a@]"
(String.escaped s) lam l)
sw ;
begin match d with
| Some d ->
if !spc then fprintf ppf "@ " else spc := true;
fprintf ppf "@[<hv 1>default:@ %a@]" lam d
| None -> ()
end in
fprintf ppf
"@[<1>(switch %a@ @[<v 0>%a@])@]" lam larg switch sw
| Ustaticfail (i, ls) ->
let lams ppf largs =
List.iter (fun l -> fprintf ppf "@ %a" lam l) largs in
fprintf ppf "@[<2>(exit@ %d%a)@]" i lams ls;
| Ucatch(i, vars, lbody, lhandler) ->
fprintf ppf "@[<2>(catch@ %a@;<1 -1>with (%d%a)@ %a)@]"
lam lbody i
(fun ppf vars ->
List.iter
(fun (x, k) ->
fprintf ppf " %a%a"
VP.print x
Printlambda.value_kind k
)
vars
)
vars
lam lhandler
| Utrywith(lbody, param, lhandler) ->
fprintf ppf "@[<2>(try@ %a@;<1 -1>with %a@ %a)@]"
lam lbody VP.print param lam lhandler
| Uifthenelse(lcond, lif, lelse) ->
fprintf ppf "@[<2>(if@ %a@ %a@ %a)@]" lam lcond lam lif lam lelse
| Usequence(l1, l2) ->
fprintf ppf "@[<2>(seq@ %a@ %a)@]" lam l1 sequence l2
| Uwhile(lcond, lbody) ->
fprintf ppf "@[<2>(while@ %a@ %a)@]" lam lcond lam lbody
| Ufor(param, lo, hi, dir, body) ->
fprintf ppf "@[<2>(for %a@ %a@ %s@ %a@ %a)@]"
VP.print param lam lo
(match dir with Upto -> "to" | Downto -> "downto")
lam hi lam body
| Uassign(id, expr) ->
fprintf ppf "@[<2>(assign@ %a@ %a)@]" V.print id lam expr
| Usend (k, met, obj, largs, _) ->
let args ppf largs =
List.iter (fun l -> fprintf ppf "@ %a" lam l) largs in
let kind =
if k = Lambda.Self then "self"
else if k = Lambda.Cached then "cache"
else "" in
fprintf ppf "@[<2>(send%s@ %a@ %a%a)@]" kind lam obj lam met args largs
| Uunreachable ->
fprintf ppf "unreachable"
and sequence ppf ulam = match ulam with
| Usequence(l1, l2) ->
fprintf ppf "%a@ %a" sequence l1 sequence l2
| _ -> lam ppf ulam
let clambda ppf ulam =
fprintf ppf "%a@." lam ulam
let rec approx ppf = function
Value_closure(fundesc, a) ->
Format.fprintf ppf "@[<2>function %s@ arity %i"
fundesc.fun_label fundesc.fun_arity;
if fundesc.fun_closed then begin
Format.fprintf ppf "@ (closed)"
end;
if fundesc.fun_inline <> None then begin
Format.fprintf ppf "@ (inline)"
end;
Format.fprintf ppf "@ -> @ %a@]" approx a
| Value_tuple a ->
let tuple ppf a =
for i = 0 to Array.length a - 1 do
if i > 0 then Format.fprintf ppf ";@ ";
Format.fprintf ppf "%i: %a" i approx a.(i)
done in
Format.fprintf ppf "@[<hov 1>(%a)@]" tuple a
| Value_unknown ->
Format.fprintf ppf "_"
| Value_const c ->
fprintf ppf "@[const(%a)@]" uconstant c
| Value_global_field (s, i) ->
fprintf ppf "@[global(%s,%i)@]" s i