open Printf
module PP = Pahole_parser
-module SC = Struct_classify
+module MM = Minimizer
+
+let rec uniq ?(cmp = Pervasives.compare) = function
+ [] -> []
+ | [x] -> [x]
+ | x :: y :: xs when cmp x y = 0 ->
+ uniq (x :: xs)
+ | x :: y :: xs ->
+ x :: uniq (y :: xs)
+
+let sort_uniq ?cmp xs =
+ let xs = List.sort ?cmp xs in
+ let xs = uniq ?cmp xs in
+ xs
(* We don't care about locations when generating code, so it's
* useful to just have a single global _loc.
| x :: xs ->
List.fold_left (fun xs x -> <:sig_item< $xs$ $x$ >>) x xs
+let concat_exprs exprs =
+ match exprs with
+ | [] -> assert false
+ | x :: xs ->
+ List.fold_left (fun xs x -> <:expr< $xs$ ; $x$ >>) x xs
+
let concat_record_fields fields =
match fields with
- | [] -> assert false
- | f :: fs ->
- List.fold_left (fun fs f -> <:ctyp< $fs$ ; $f$ >>) f fs
+ | [] -> assert false
+ | f :: fs ->
+ List.fold_left (fun fs f -> <:ctyp< $fs$ ; $f$ >>) f fs
let concat_record_bindings rbs =
match rbs with
- | [] -> assert false
- | rb :: rbs ->
- List.fold_left (fun rbs rb -> <:rec_binding< $rbs$ ; $rb$ >>) rb rbs
+ | [] -> assert false
+ | rb :: rbs ->
+ List.fold_left (fun rbs rb -> <:rec_binding< $rbs$ ; $rb$ >>) rb rbs
+
+let concat_bindings bs =
+ match bs with
+ | [] -> assert false
+ | b :: bs ->
+ List.fold_left (fun bs b -> <:binding< $bs$ and $b$ >>) b bs
+
+let concat_sum_types ts =
+ match ts with
+ | [] -> assert false
+ | t :: ts ->
+ List.fold_left (fun ts t -> <:ctyp< $ts$ | $t$ >>) t ts
let build_record rbs =
Ast.ExRec (_loc, rbs, Ast.ExNil _loc)
Ast.ExTup (_loc,
List.fold_left (fun xs x -> Ast.ExCom (_loc, x, xs)) x xs)
+let build_tuple_from_patts patts =
+ match patts with
+ | [] | [_] -> assert false
+ | x :: xs ->
+ Ast.PaTup (_loc,
+ List.fold_left (fun xs x -> Ast.PaCom (_loc, x, xs)) x xs)
+
+(* Helper functions to store things in a fixed-length tuple very efficiently.
+ * Note that the tuple length must be >= 2.
+ *)
+type tuple = string list
+
+let tuple_create fields : tuple = fields
+
+(* Generates 'let _, _, resultpatt, _ = tupleexpr in body'. *)
+let tuple_generate_extract fields field resultpatt tupleexpr body =
+ let patts = List.map (
+ fun name -> if name = field then resultpatt else <:patt< _ >>
+ ) fields in
+ let result = build_tuple_from_patts patts in
+ <:expr< let $result$ = $tupleexpr$ in $body$ >>
+
+(* Generates '(fieldexpr1, fieldexpr2, ...)'. *)
+let tuple_generate_construct fieldexprs =
+ build_tuple_from_exprs fieldexprs
+
+type code = Ast.str_item * Ast.sig_item
+
let ocaml_type_of_field_type = function
- | PP.FInteger -> <:ctyp< int64 >>
- | PP.FString _ -> <:ctyp< string >>
- | PP.FStructPointer _ | PP.FVoidPointer
- | PP.FAnonListHeadPointer | PP.FListHeadPointer _ ->
+ | PP.FInteger, true -> <:ctyp< int64 >>
+ | PP.FInteger, false -> <:ctyp< int64 option >>
+ | PP.FString _, true -> <:ctyp< string >>
+ | PP.FString _, false -> <:ctyp< string option >>
+ | PP.FStructPointer _, true | PP.FVoidPointer, true
+ | PP.FAnonListHeadPointer, true | PP.FListHeadPointer _, true ->
<:ctyp< Virt_mem_mmap.addr >>
+ | PP.FStructPointer _, false | PP.FVoidPointer, false
+ | PP.FAnonListHeadPointer, false | PP.FListHeadPointer _, false ->
+ <:ctyp< Virt_mem_mmap.addr option >>
let generate_types xs =
- let strs = List.map (
- fun (struct_name, sflist, cflist) ->
- let sflist = List.map (
- fun { SC.sf_name = name; sf_fields = fields } ->
- if fields <> [] then (
- let fields = List.map (
- fun { PP.field_name = name; PP.field_type = t } ->
- let t = ocaml_type_of_field_type t in
- <:ctyp< $lid:name$ : $t$ >>
- ) fields in
- let fields = concat_record_fields fields in
-
- <:str_item<
- type $lid:name$ = { $fields$ }
- >>
- ) else
- <:str_item< type $lid:name$ = unit >>
- ) sflist in
- let sflist = concat_str_items sflist in
-
- let cflist = List.map (
- fun { SC.cf_name = name; cf_fields = fields } ->
- if fields <> [] then (
- let fields = List.map (
- fun { PP.field_name = name; PP.field_type = t } ->
- let t = ocaml_type_of_field_type t in
- <:ctyp< $lid:name$ : $t$ >>
- ) fields in
- let fields = concat_record_fields fields in
-
- <:str_item<
- type $lid:name$ = { $fields$ }
- >>
- ) else
- <:str_item< type $lid:name$ = unit >>
- ) cflist in
- let cflist = concat_str_items cflist in
+ let types = List.map (
+ fun (struct_name, all_fields) ->
+ let fields = List.map (
+ fun (name, (typ, always_available)) ->
+ match typ with
+ | PP.FListHeadPointer _ ->
+ (* A list head turns into three fields, the pointer,
+ * the offset within current struct, and the adjustment
+ * (offset within destination struct).
+ *)
+ let t = ocaml_type_of_field_type (typ, always_available) in
+ [ <:ctyp< $lid:struct_name^"_"^name$ : $t$ >>;
+ <:ctyp< $lid:struct_name^"_"^name^"_offset"$ : int >>;
+ <:ctyp< $lid:struct_name^"_"^name^"_adjustment"$ : int >> ]
+ | _ ->
+ let t = ocaml_type_of_field_type (typ, always_available) in
+ [ <:ctyp< $lid:struct_name^"_"^name$ : $t$ >> ]
+ ) all_fields in
+ let fields = List.concat fields in
+ let fields = concat_record_fields fields in
<:str_item<
- type ('a, 'b) $lid:struct_name$ = {
- $lid:struct_name^"_shape"$ : 'a;
- $lid:struct_name^"_content"$ : 'b;
- }
- $sflist$
- $cflist$
+ type $lid:struct_name$ = { $fields$ }
+ >>,
+ <:sig_item<
+ type $lid:struct_name$ = { $fields$ }
>>
) xs in
- let sigs =
+ (* Generate a sum-type which can use to store any type of kernel
+ * structure, ie. Task_struct | Net_device | ...
+ *)
+ let types = types @ [
+ let constrs =
+ List.map (
+ fun (struct_name, _) ->
+ let struct_name_uc = String.capitalize struct_name in
+ <:ctyp< $uid:struct_name_uc$ of $lid:struct_name$ >>
+ ) xs in
+ let constrs = concat_sum_types constrs in
+ <:str_item<
+ type kernel_struct = $constrs$
+ >>,
+ <:sig_item<
+ type kernel_struct = $constrs$
+ >>
+ ] in
+
+ let strs, sigs = List.split types in
+ concat_str_items strs, concat_sig_items sigs
+
+let generate_offsets xs =
+ (* Only need to generate the offset_of_* functions for fields
+ * which are cross-referenced from another field. Which
+ * ones are those?
+ *)
+ let fields =
+ List.concat (
+ List.map (
+ fun (_, (_, all_fields)) ->
+ List.filter_map (
+ function
+ | (_,
+ (PP.FListHeadPointer
+ ((Some (struct_name, field_name)) as f),
+ _)) ->
+ f
+ | _ ->
+ None
+ ) all_fields
+ ) xs
+ ) in
+
+ let fields = sort_uniq fields in
+
+ let strs =
List.map (
- fun (struct_name, _, _) ->
- <:sig_item<
- type ('a, 'b) $lid:struct_name$
- >>
+ fun (struct_name, field_name) ->
+ let kernels, _ =
+ try List.assoc struct_name xs
+ with Not_found ->
+ failwith (
+ sprintf "generate_offsets: structure %s not found. This is probably a list_head-related bug."
+ struct_name
+ ) in
+ (* Find the offset of this field in each kernel version. *)
+ let offsets =
+ List.filter_map (
+ fun ({ PP.kernel_version = version },
+ { PP.struct_fields = fields }) ->
+ try
+ let field =
+ List.find (fun { PP.field_name = name } -> field_name = name)
+ fields in
+ let offset = field.PP.field_offset in
+ Some (version, offset)
+ with Not_found -> None
+ ) kernels in
+
+ if offsets = [] then
+ failwith (
+ sprintf "generate_offsets: field %s.%s not found in any kernel. This is probably a list_head-related bug."
+ struct_name field_name
+ );
+
+ (* Generate a map of kernel version to offset. *)
+ let map = List.fold_left (
+ fun map (version, offset) ->
+ <:expr< StringMap.add $str:version$ $`int:offset$ $map$ >>
+ ) <:expr< StringMap.empty >> offsets in
+
+ let code =
+ <:str_item<
+ let $lid:"offset_of_"^struct_name^"_"^field_name$ =
+ let map = $map$ in
+ fun kernel_version -> StringMap.find kernel_version map
+ >> in
+ code
+ ) fields in
+
+ let strs = concat_str_items strs in
+
+ strs, <:sig_item< >>
+
+let generate_parsers xs =
+ let strs =
+ List.map (
+ fun (struct_name, (all_fields, palist)) ->
+ let palist =
+ List.map (
+ fun { MM.pa_name = pa_name } ->
+ <:str_item<
+ let $lid:pa_name$ kernel_version bits = $str:pa_name$
+ >>
+ ) palist in
+ concat_str_items palist
) xs in
- concat_str_items strs, concat_sig_items sigs
+ let strs = concat_str_items strs in
+
+ (* The shared parser functions.
+ *
+ * We could include bitmatch statements directly in here, but
+ * what happens is that the macros get expanded here, resulting
+ * in (even more) unreadable generated code. So instead just
+ * do a textual substitution later by post-processing the
+ * generated files. Not type-safe, but we can't have
+ * everything.
+ *)
+ let subs = Hashtbl.create 13 in
+ List.iter (
+ fun (struct_name, (all_fields, palist)) ->
+ List.iter (
+ fun ({ MM.pa_name = pa_name;
+ pa_endian = endian; pa_structure = structure }) ->
+ (* Generate the code to match this structure. *)
+ let endian =
+ match endian with
+ | Bitstring.LittleEndian -> "littleendian"
+ | Bitstring.BigEndian -> "bigendian"
+ | _ -> assert false in
+ let patterns =
+ String.concat ";\n " (
+ List.map (
+ function
+ | { PP.field_name = field_name;
+ field_type = PP.FInteger;
+ field_offset = offset;
+ field_size = size } ->
+ (* 'zero+' is a hack to force the type to int64. *)
+ sprintf "%s : zero+%d : offset(%d), %s"
+ field_name (size*8) (offset*8) endian
+
+ | { PP.field_name = field_name;
+ field_type = (PP.FStructPointer _
+ | PP.FVoidPointer
+ | PP.FAnonListHeadPointer
+ | PP.FListHeadPointer _);
+ field_offset = offset;
+ field_size = size } ->
+ sprintf "%s : zero+%d : offset(%d), %s"
+ field_name (size*8) (offset*8) endian
+
+ | { PP.field_name = field_name;
+ field_type = PP.FString width;
+ field_offset = offset;
+ field_size = size } ->
+ sprintf "%s : %d : offset(%d), string"
+ field_name (width*8) (offset*8)
+ ) structure.PP.struct_fields
+ ) in
+
+ let assignments =
+ List.map (
+ fun (field_name, (field_type, always_available)) ->
+ if always_available then (
+ (* Go and look up the field offset in the correct kernel. *)
+ let { PP.field_offset = offset } =
+ List.find (fun { PP.field_name = name } ->
+ field_name = name)
+ structure.PP.struct_fields in
+
+ (* Generate assignment code. List_heads are treated
+ * specially because they have an implicit adjustment.
+ *)
+ match field_type with
+ | PP.FListHeadPointer None ->
+ sprintf "%s_%s = %s;
+ %s_%s_offset = %d;
+ %s_%s_adjustment = %d"
+ struct_name field_name field_name
+ struct_name field_name offset
+ struct_name field_name offset
+
+ | PP.FListHeadPointer (Some (other_struct_name,
+ other_field_name)) ->
+ (* A reference to a field in another structure. We don't
+ * know the offset until runtime, so we have to call
+ * offset_of_<struct>_<field> to find it.
+ *)
+ sprintf "%s_%s = %s;
+ %s_%s_offset = %d;
+ %s_%s_adjustment = offset_of_%s_%s kernel_version"
+ struct_name field_name field_name
+ struct_name field_name offset (* in this struct *)
+ struct_name field_name (* ... & in other struct*)
+ other_struct_name other_field_name
+
+ | _ ->
+ sprintf "%s_%s = %s" struct_name field_name field_name
+ ) else (
+ (* Field is optional. Is it available in this kernel
+ * version? If so, get its offset, else throw Not_found.
+ *)
+ try
+ let { PP.field_offset = offset } =
+ List.find (fun { PP.field_name = name } ->
+ field_name = name)
+ structure.PP.struct_fields in
+
+ (* Generate assignment code. List_heads are treated
+ * specially because they have an implicit adjustment.
+ *)
+ match field_type with
+ | PP.FListHeadPointer None ->
+ sprintf "%s_%s = Some %s;
+ %s_%s_offset = %d;
+ %s_%s_adjustment = %d"
+ struct_name field_name field_name
+ struct_name field_name offset
+ struct_name field_name offset
+
+ | PP.FListHeadPointer (Some (other_struct_name,
+ other_field_name)) ->
+ (* A reference to a field in another structure. We
+ * don't know the offset until runtime, so we have
+ * to call offset_of_<struct>_<field> to find it.
+ *)
+ sprintf "%s_%s = Some %s;
+ %s_%s_offset = %d;
+ %s_%s_adjustment = offset_of_%s_%s kernel_version"
+ struct_name field_name field_name
+ struct_name field_name offset(*in this struct *)
+ struct_name field_name (*... & in other struct*)
+ other_struct_name other_field_name
+
+ | _ ->
+ sprintf "%s_%s = Some %s"
+ struct_name field_name field_name
+ with
+ Not_found ->
+ (* Field is not available in this kernel version. *)
+ match field_type with
+ | PP.FListHeadPointer _ ->
+ sprintf "%s_%s = None;
+ %s_%s_offset = -1;
+ %s_%s_adjustment = -1"
+ struct_name field_name
+ struct_name field_name
+ struct_name field_name
+ | _ ->
+ sprintf "%s_%s = None" struct_name field_name
+ )
+ ) all_fields in
+
+ let assignments = String.concat ";\n " assignments in
+
+ let code =
+ sprintf "
+ bitmatch bits with
+ | { %s } ->
+ { %s }
+ | { _ } ->
+ raise (ParseError (%S, %S, match_err))"
+ patterns assignments
+ struct_name pa_name in
+
+ Hashtbl.add subs pa_name code
+ ) palist;
+ ) xs;
+
+ (strs, <:sig_item< >>), subs
+
+let generate_version_maps xs =
+ (* size_of_<struct> kernel_version *)
+ let strs = List.map (
+ fun (struct_name, (kernels, _)) ->
+ let map =
+ List.fold_right (
+ fun ({ PP.kernel_version = version },
+ { PP.struct_total_size = size }) map ->
+ <:expr<
+ StringMap.add $str:version$ $`int:size$ $map$
+ >>
+ ) kernels <:expr< StringMap.empty >> in
+
+ <:str_item<
+ let $lid:"size_of_"^struct_name$ =
+ let map = $map$ in
+ fun kernel_version ->
+ try StringMap.find kernel_version map
+ with Not_found ->
+ unknown_kernel_version kernel_version $str:struct_name$
+ >>
+ ) xs in
+
+ (* parser_of_<struct> kernel_version *)
+ let strs = strs @ List.map (
+ fun (struct_name, (kernels, pahash)) ->
+ let map =
+ List.fold_right (
+ fun ({ PP.kernel_version = version }, _) map ->
+ let { MM.pa_name = pa_name } = Hashtbl.find pahash version in
+ <:expr<
+ StringMap.add $str:version$ $lid:pa_name$ $map$
+ >>
+ ) kernels <:expr< StringMap.empty >> in
+
+ <:str_item<
+ let $lid:"parser_of_"^struct_name$ =
+ let map = $map$ in
+ fun kernel_version ->
+ try StringMap.find kernel_version map
+ with Not_found ->
+ unknown_kernel_version kernel_version $str:struct_name$
+ >>
+ ) xs in
+
+ concat_str_items strs, <:sig_item< >>
+
+let generate_followers names xs =
+ (* A follower function for every structure. *)
+ let bindings = List.map (
+ fun (struct_name, all_fields) ->
+ let followers = List.fold_right (
+ fun (name, (typ, always_available)) rest ->
+ let is_shape_field =
+ match typ with
+ | PP.FListHeadPointer None -> true
+ | PP.FListHeadPointer (Some (struct_name, _))
+ | PP.FStructPointer struct_name
+ when List.mem struct_name names -> true
+ | _ -> false in
+ if not is_shape_field then rest
+ else (
+ let dest_struct_name =
+ match typ with
+ | PP.FListHeadPointer None -> struct_name
+ | PP.FListHeadPointer (Some (struct_name, _)) -> struct_name
+ | PP.FStructPointer struct_name -> struct_name
+ | _ -> assert false in
+
+ let body =
+ match typ with
+ | PP.FListHeadPointer _ ->
+ <:expr<
+ if debug then
+ eprintf "%s_follower: %s: list_head pointing at a %s\n"
+ $str:struct_name$ $str:name$ $str:dest_struct_name$;
+
+ (* For list head pointers, add the address of the base
+ * of this virtual structure to the map, then adjust
+ * the pointer.
+ *)
+ let offset = data.$lid:struct_name^"_"^name^"_offset"$
+ and adj = data.$lid:struct_name^"_"^name^"_adjustment"$ in
+
+ if debug then
+ eprintf "%s_follower: %s: offset=%d adjustment=%d\n"
+ $str:struct_name$ $str:name$ offset adj;
+
+ let offset = Int64.of_int offset
+ and adj = Int64.of_int adj in
+
+ (* 'addr' is base of the virtual struct, but when
+ * adding it to the map make sure we don't splat
+ * the real structure (can happen if offset=adj).
+ *)
+ let map =
+ if offset <> adj then (
+ let addr = Int64.sub (Int64.add addr offset) adj in
+ AddrMap.add addr ($str:dest_struct_name$, None) map
+ ) else map in
+
+ (* 'dest_addr' is the destination address of
+ * this pointer. It needs the usual list_head
+ * adjustment applied.
+ *)
+ let dest_addr = Int64.sub dest_addr adj in
+
+ if debug then
+ eprintf "%s_follower: %s: dest_addr=%Lx\n"
+ $str:struct_name$ $str:name$ dest_addr;
+
+ let map =
+ $lid:dest_struct_name^"_follower"$
+ debug kernel_version load map dest_addr in
+ map
+ >>
+
+ | PP.FStructPointer _ ->
+ <:expr<
+ if debug then
+ eprintf "%s_follower: %s: is a struct pointer pointing to a %s; dest_addr=%Lx\n"
+ $str:struct_name$ $str:name$
+ $str:dest_struct_name$ dest_addr;
+
+ let map =
+ $lid:dest_struct_name^"_follower"$
+ debug kernel_version load map dest_addr in
+ map
+ >>
+
+ | _ -> assert false in
+
+ if always_available then
+ <:expr<
+ let dest_addr = data.$lid:struct_name^"_"^name$ in
+ let map = $body$ in
+ $rest$
+ >>
+ else
+ <:expr<
+ let map =
+ match data.$lid:struct_name^"_"^name$ with
+ | None -> map
+ | Some dest_addr -> $body$ in
+ $rest$
+ >>
+ )
+ ) all_fields <:expr< map >> in
+
+ let struct_name_uc = String.capitalize struct_name in
+
+ <:binding<
+ $lid:struct_name^"_follower"$ debug kernel_version load map addr =
+ if debug then
+ eprintf "%s_follower: addr = %Lx\n" $str:struct_name$ addr;
+ if addr <> 0L && not (AddrMap.mem addr map) then (
+ let parser_ = $lid:"parser_of_"^struct_name$ kernel_version in
+ let total_size = $lid:"size_of_"^struct_name$ kernel_version in
+ let bits = load $str:struct_name$ addr total_size in
+ let data = parser_ kernel_version bits in
+ let map = AddrMap.add
+ addr ($str:struct_name$,
+ Some (total_size, bits, $uid:struct_name_uc$ data))
+ map in
+ $followers$
+ )
+ else map
+ >>
+ ) xs in
+ let bindings = concat_bindings bindings in
+ let strs = <:str_item< let rec $bindings$ >> in
+
+ (* Function signatures for the interface. *)
+ let sigs = List.map (
+ fun (struct_name, _) ->
+ <:sig_item<
+ val $lid:struct_name^"_follower"$ :
+ bool -> kernel_version -> load_fn -> addrmap -> Virt_mem_mmap.addr ->
+ addrmap
+ >>
+ ) xs in
+ let sigs = concat_sig_items sigs in
+
+ strs, sigs
+
+let output_interf ~output_file types offsets parsers version_maps followers =
+ (* Some standard code that appears at the top and bottom
+ * of the interface file.
+ *)
+ let prologue =
+ <:sig_item<
+ module AddrMap : sig
+ type key = Virt_mem_mmap.addr
+ type 'a t = 'a Map.Make(Int64).t
+ val empty : 'a t
+ val is_empty : 'a t -> bool
+ val add : key -> 'a -> 'a t -> 'a t
+ val find : key -> 'a t -> 'a
+ val remove : key -> 'a t -> 'a t
+ val mem : key -> 'a t -> bool
+ val iter : (key -> 'a -> unit) -> 'a t -> unit
+ val map : ('a -> 'b) -> 'a t -> 'b t
+ val mapi : (key -> 'a -> 'b) -> 'a t -> 'b t
+ val fold : (key -> 'a -> 'b -> 'b) -> 'a t -> 'b -> 'b
+ val compare : ('a -> 'a -> int) -> 'a t -> 'a t -> int
+ val equal : ('a -> 'a -> bool) -> 'a t -> 'a t -> bool
+ end ;;
+ exception ParseError of string * string * string ;;
+
+ type kernel_version = string
+
+ type load_fn =
+ string -> Virt_mem_mmap.addr -> int -> Bitstring.bitstring
+ >>
+ and addrmap =
+ <:sig_item<
+ type addrmap =
+ (string * (int * Bitstring.bitstring * kernel_struct) option)
+ AddrMap.t
+ >> in
+
+ let sigs =
+ concat_sig_items [ prologue;
+ types;
+ addrmap;
+ offsets;
+ parsers;
+ version_maps;
+ followers ] in
+ Printers.OCaml.print_interf ~output_file sigs;
+
+ ignore (Sys.command (sprintf "wc -l %s" (Filename.quote output_file)))
+
+(* Finally generate the output files. *)
+let re_subst = Pcre.regexp "^(.*)\"(\\w+_parser_\\d+)\"(.*)$"
+
+let output_implem ~output_file types offsets parsers parser_subs
+ version_maps followers =
+ (* Some standard code that appears at the top and bottom
+ * of the implementation file.
+ *)
+ let prologue =
+ <:str_item<
+ open Printf ;;
+ module StringMap = Map.Make (String) ;;
+ module AddrMap = Map.Make (Int64) ;;
+ exception ParseError of string * string * string ;;
+
+ let match_err = "failed to match kernel structure"
+
+ let unknown_kernel_version version struct_name =
+ invalid_arg (sprintf "%s: unknown kernel version or
+struct %s is not supported in this kernel.
+Try a newer version of virt-mem, or if the guest is not from a
+supported Linux distribution, see this page about adding support:
+ http://et.redhat.com/~rjones/virt-mem/faq.html\n"
+ version struct_name)
+
+ type kernel_version = string
+ type load_fn = string -> Virt_mem_mmap.addr -> int -> Bitstring.bitstring
+
+ let zero = 0
+ >>
+ and addrmap =
+ <:str_item<
+ type addrmap =
+ (string * (int * Bitstring.bitstring * kernel_struct) option)
+ AddrMap.t
+ >> in
+
+ let strs =
+ concat_str_items [ prologue;
+ types;
+ addrmap;
+ offsets;
+ parsers;
+ version_maps;
+ followers ] in
+
+ (* Write the new implementation to .ml.new file. *)
+ let new_output_file = output_file ^ ".new" in
+ Printers.OCaml.print_implem ~output_file:new_output_file strs;
+
+ (* Substitute the parser bodies in the output file. *)
+ let ichan = open_in new_output_file in
+ let ochan = open_out output_file in
+
+ output_string ochan "\
+(* WARNING: This file and the corresponding mli (interface) are
+ * automatically generated by the extract/codegen/ program.
+ *
+ * Any edits you make to this file will be lost.
+ *
+ * To update this file from the latest kernel database, it is recommended
+ * that you do 'make update-kernel-structs'.
+ *)\n\n";
+
+ let rec loop () =
+ let line = input_line ichan in
+ let line =
+ if Pcre.pmatch ~rex:re_subst line then (
+ let subs = Pcre.exec ~rex:re_subst line in
+ let start = Pcre.get_substring subs 1 in
+ let template = Pcre.get_substring subs 2 in
+ let rest = Pcre.get_substring subs 3 in
+ let sub =
+ try Hashtbl.find parser_subs template
+ with Not_found -> assert false in
+ start ^ sub ^ rest
+ ) else line in
+ output_string ochan line; output_char ochan '\n';
+ loop ()
+ in
+ (try loop () with End_of_file -> ());
+
+ close_out ochan;
+ close_in ichan;
-let output_interf ~output_file types =
- let sigs = concat_sig_items [ types ] in
- Printers.OCaml.print_interf ~output_file sigs
+ Unix.unlink new_output_file;
-let output_implem ~output_file types =
- let strs = concat_str_items [ types ] in
- Printers.OCaml.print_implem ~output_file strs
+ ignore (Sys.command (sprintf "wc -l %s" (Filename.quote output_file)))