heptagon/main/compiler.ml

(**************************************************************************)
(*                                                                        *)
(*  Heptagon                                                              *)
(*                                                                        *)
(*  Author : Marc Pouzet                                                  *)
(*  Organization : Demons, LRI, University of Paris-Sud, Orsay            *)
(*                                                                        *)
(**************************************************************************)
(* $Id$ *)

open Location
open Misc
open Global

let lexical_error err loc =
  Printf.eprintf "%aIllegal character.\n" output_location loc;
  raise Error

let syntax_error loc =
  Printf.eprintf "%aSyntax error.\n" output_location loc;
  raise Error

let language_error lang =
  Printf.eprintf "Unknown language: %s.\n" lang

let parse parsing_fun lexing_fun lexbuf =
  try
    parsing_fun lexing_fun lexbuf
  with
    | Lexer.Lexical_error(err, pos1, pos2) ->
        lexical_error err (Loc(pos1, pos2))
    | Parsing.Parse_error ->
        let pos1 = Lexing.lexeme_start lexbuf
        and pos2 = Lexing.lexeme_end lexbuf in
        let l = Loc(pos1,pos2) in
        syntax_error l

let comment s = Printf.printf "** %s done **\n" s; flush stdout

let build_path suf =
  match !target_path with
    | None -> suf
    | Some path -> Filename.concat path suf

let clean_dir dir =
  if Sys.file_exists dir && Sys.is_directory dir
  then begin
    let rm_file_in_dir fn = Sys.remove (Filename.concat dir fn) in
    Array.iter rm_file_in_dir (Sys.readdir dir);
  end else Unix.mkdir dir 0o740;
  dir

(** Generation of a dataflow target *)
let dataflow_target filename p target_languages =
  let rec one_target = function
 (*   | "z3z" :: others ->
        let dirname = build_path (filename ^ "_z3z") in
        let dir = clean_dir dirname in
        let p = Dynamic_system.program p in
        if !verbose then
          comment "Translation into dynamic system (Z/3Z equations)";
        Sigali.Printer.print dir p;
        one_target others *)
    | ("vhdl_df" | "vhdl") :: others ->
        let dirname = build_path (filename ^ "_vhdl") in
        let dir = clean_dir dirname in
        let vhdl = Mls2vhdl.translate (Filename.basename filename) p in
        Vhdl.print dir vhdl;
        one_target others
    | unknown_lg :: others -> unknown_lg :: one_target others
    | [] -> [] in
  one_target target_languages

(** Generation of a sequential target *)
let sequential_target filename o target_languages =
  let rec one_target = function
    | "c-old" :: others ->
        let dirname = build_path (filename ^ "_c-old") in
        let dir = clean_dir dirname in
        C_old.print o dir;
          one_target others 
    | "java" :: others ->
        let dirname = build_path filename in
        let dir = clean_dir dirname in
        Java.print dir o;
        one_target others
    | "c" :: others ->
        let dirname = build_path (filename ^ "_c") in
        let dir = clean_dir dirname in
        let c_ast = Cgen.translate filename o in
        C.output dir c_ast;
        one_target others
    | "caml" :: others -> Caml.print filename o; one_target others
    | unknown_lg :: others -> unknown_lg :: one_target others
    | [] -> [] in
  one_target target_languages

(** Whole translation. *)
let targets filename df obc target_languages =
  let target_languages = dataflow_target filename df target_languages in
  let target_languages = sequential_target filename obc target_languages in
  match target_languages with
    | [] -> ()
    | target :: _ -> language_error target

let parse_implementation lexbuf =
  parse Parser.program Lexer.token lexbuf

let parse_interface lexbuf =
  parse Parser.interface Lexer.token lexbuf

let interface modname filename =
  (* input and output files *)
  let source_name = filename ^ ".epi"
  and obj_interf_name = filename ^ ".epci" in

  let ic = open_in source_name
  and itc = open_out_bin obj_interf_name in
  let close_all_files () =
    close_in ic;
    close_out itc in

  try
    Location.initialize source_name ic;
    Modules.initialize modname;
    Initial.initialize ();

    (* Parsing of the file *)
    let lexbuf = Lexing.from_channel ic in
    let l = parse_interface lexbuf in

    (* Convert the parse tree to Heptagon AST *)
    let l = Scoping.translate_interface l in

    Interface.Type.main l;
    Modules.write itc;
    if !print_types then Interface.Printer.print stdout;
    close_all_files ()
  with
    | x -> close_all_files (); raise x

let do_pass f d p pp enabled =
  if enabled
  then
    let r = f p in
    if !verbose
    then begin
      comment d;
      pp r;
    end;
    r
  else p

let do_silent_pass f d p enabled =
  if enabled
  then begin
    let r = f p in
    if !verbose then comment d; r
  end
  else p

let compile modname filename =
  (* input and output files *)
  let source_name = filename ^ ".ept"
  and obj_interf_name = filename ^ ".epci"
  and mls_name = filename ^ ".mls"
  and mls_norm_name = filename ^ "_norm.mls"
  and obc_name = filename ^ ".obc"
  and ml_name = filename ^ ".ml" in

  let ic = open_in source_name
  and itc = open_out_bin obj_interf_name
  and mlsc = open_out mls_name
  and mlsnc = open_out mls_norm_name
  and obc = open_out obc_name
  and mlc = open_out ml_name in

  let close_all_files () =
    close_in ic;
    close_out itc;
    close_out mlsc;
    close_out obc;
    close_out mlc in

  try
    Location.initialize source_name ic;
    Modules.initialize modname;
    Initial.initialize ();

    let pp = Printer.print stdout in

    (* Parsing of the file *)
    let lexbuf = Lexing.from_channel ic in
    let p = parse_implementation lexbuf in

    (* Convert the parse tree to Heptagon AST *)
    let p = Scoping.translate_program p in
    if !verbose
    then begin
      comment "Parsing";
      pp p
    end;

(*   Misc.reset_symbol (); *)

    (* Typing *)
    let p = do_pass Typing.program "Typing" p pp true in

    (* Linear typing *)
    let p = do_pass Linear_typing.program "Linear Typing" p pp (not !no_mem_alloc) in

    if !print_types then Interface.Printer.print stdout;
    Modules.write itc;

    (* Causality check *)
    let p =
	do_silent_pass Causality.program "Causality check" p true in

    (* Initialization check *)
    let p =
      do_silent_pass Initialization.program "Initialization check" p !init in

    (* Mark nodes to be inlined *)
(*      let to_inline = List.map Misc.mk_longname !nodes_to_inline in
      let p = Inline.mark_calls_to to_inline p in
      let p = match !node_to_flatten with
      | None -> p
      | Some nn -> Inline.flatten nn p in
      if !verbose then comment "Inlining pre-pass";*)

    (* Inline marked nodes *)
(*      let p = do_pass Inline.program "Inlining" p pp true in  *)

   (* Automata memory sharing *)
    let p = do_pass Automata_mem.program "Automata memory sharing" p pp (not !no_mem_alloc) in

    (* Completion of partial definitions *)
    let p = do_pass Completion.program "Completion" p pp true in

    (* Automata *)
    let p = do_pass Automata.program "Automata" p pp true in

    (* Present *)
    let p = do_pass Present.program "Present" p pp true in

    (* Shared variables (last) *)
    let p = do_pass Last.program "Last" p pp true in

    (* Reset *)
    let reset_prog = if !use_new_reset_encoding then Reset_new.program else Reset.program in
    let p = do_pass reset_prog "Reset" p pp true in

    (* Every *)
    let p = do_pass Every.program "Every" p pp true in

    (* Merge and translate the heptagon program into the *)
    (* clocked data-flow language mini-ls *)
    let pp = Minils.Printer.print stdout in

    let p = Merge.program p in
    if !verbose then comment "Translation into clocked equations";
    Minils.Printer.print mlsc p;

    (* Annotation of expressions with their clock *)
    let p = Clocking.program p in

    (* Mls2dot.program "" p; *)

    (** Start of data-flow optimizations *)
    (* Normalization to maximize opportunities *)
    let p = do_pass Normalize.program "Normalization" p pp true in

    (* Back-end causality check. Only useful to check that *)
    (* we did not make any mistake during code generation *)
    let p =
      do_silent_pass Dfcausality.program "Post-pass causality check" p true in

    (* Check that the dataflow code is well initialized *)
    (*
      let p =
      do_silent_pass Init.program "Post-pass initialization check" p true in
    *)

    let sigali = List.mem "z3z" !target_languages in

    (* Boolean translation of enumerated values *)
  (*  let p =
      do_pass
        Boolean.program "Boolean transformation" p pp (!boolean or sigali) in
  *)

    (* Normalization to maximize opportunities *)
    let p = do_pass Normalize.program "Normalization" p pp true in

    (* Mls2dot.program "normalized_" p; *)

    let p =
      do_pass Deadcode.program "Deadcode removal" p pp !deadcode in

    (* Automata minimization *)
    let p = do_pass Tommls.program "Automata minimization" p pp !tomato in

    (* Common sub-expression elimination *)
    let p =
      do_pass Cmse.program "Common sub-expression elimination" p pp !cse in

    (* Removing intermediate equations *)
    let p =
      do_pass Intermediate.program "Intermediate-equations removal"
        p pp !intermediate in

    Mls2dot.program "optimized_" p;

    (* Splitting *)
    let p = do_pass Splitting.program "Splitting" p pp (not !no_mem_alloc) in

    (* Scheduling *)
    let scheduler = if !use_interf_scheduler then Schedule_interf.program else Schedule.program in
    let p = do_pass scheduler "Scheduling" p pp true in

    (* Memory allocation *)
    Interference.world.Interference.node_is_scheduled <- true;
    let p = do_pass Memalloc.program 
      "Interference graph building and Memory Allocation" p pp (not !no_mem_alloc) in

    (* Parametrized functions instantiation *)
    let p = do_pass Callgraph.program 
      "Parametrized functions instantiation" p pp true in

    Minils.Printer.print mlsnc p;

    (* Producing Object-based code *)
    let o = Translate.program p in
    if !verbose then comment "Translation into Object-based code";
    Obc.Printer.print obc o;

    let pp = Obc.Printer.print stdout in
      if !verbose then pp o;

    (* Translation into dataflow and sequential languages *)
    targets filename p o !target_languages;

    close_all_files ();

  with x -> close_all_files (); raise x
Initial commit 2010-06-15 10:49:03 +02:00			`(**************************************************************************)`
			`(* *)`
			`(* Heptagon *)`
			`(* *)`
			`(* Author : Marc Pouzet *)`
			`(* Organization : Demons, LRI, University of Paris-Sud, Orsay *)`
			`(* *)`
			`(**************************************************************************)`
			`(* $Id$ *)`

			`open Location`
			`open Misc`
			`open Global`

			`let lexical_error err loc =`
			`Printf.eprintf "%aIllegal character.\n" output_location loc;`
			`raise Error`

			`let syntax_error loc =`
			`Printf.eprintf "%aSyntax error.\n" output_location loc;`
			`raise Error`

			`let language_error lang =`
			`Printf.eprintf "Unknown language: %s.\n" lang`

			`let parse parsing_fun lexing_fun lexbuf =`
			`try`
			`parsing_fun lexing_fun lexbuf`
			`with`
			`\| Lexer.Lexical_error(err, pos1, pos2) ->`
			`lexical_error err (Loc(pos1, pos2))`
			`\| Parsing.Parse_error ->`
			`let pos1 = Lexing.lexeme_start lexbuf`
			`and pos2 = Lexing.lexeme_end lexbuf in`
			`let l = Loc(pos1,pos2) in`
			`syntax_error l`

			`let comment s = Printf.printf " %s done \n" s; flush stdout`

			`let build_path suf =`
			`match !target_path with`
			`\| None -> suf`
			`\| Some path -> Filename.concat path suf`

			`let clean_dir dir =`
			`if Sys.file_exists dir && Sys.is_directory dir`
			`then begin`
			`let rm_file_in_dir fn = Sys.remove (Filename.concat dir fn) in`
			`Array.iter rm_file_in_dir (Sys.readdir dir);`
			`end else Unix.mkdir dir 0o740;`
			`dir`

			`(** Generation of a dataflow target *)`
			`let dataflow_target filename p target_languages =`
			`let rec one_target = function`
			`(* \| "z3z" :: others ->`
			`let dirname = build_path (filename ^ "_z3z") in`
			`let dir = clean_dir dirname in`
			`let p = Dynamic_system.program p in`
			`if !verbose then`
			`comment "Translation into dynamic system (Z/3Z equations)";`
			`Sigali.Printer.print dir p;`
			`one_target others *)`
			`\| ("vhdl_df" \| "vhdl") :: others ->`
			`let dirname = build_path (filename ^ "_vhdl") in`
			`let dir = clean_dir dirname in`
			`let vhdl = Mls2vhdl.translate (Filename.basename filename) p in`
			`Vhdl.print dir vhdl;`
			`one_target others`
			`\| unknown_lg :: others -> unknown_lg :: one_target others`
			`\| [] -> [] in`
			`one_target target_languages`

			`(** Generation of a sequential target *)`
			`let sequential_target filename o target_languages =`
			`let rec one_target = function`
			`\| "c-old" :: others ->`
			`let dirname = build_path (filename ^ "_c-old") in`
			`let dir = clean_dir dirname in`
			`C_old.print o dir;`
			`one_target others`
			`\| "java" :: others ->`
			`let dirname = build_path filename in`
			`let dir = clean_dir dirname in`
			`Java.print dir o;`
			`one_target others`
			`\| "c" :: others ->`
			`let dirname = build_path (filename ^ "_c") in`
			`let dir = clean_dir dirname in`
			`let c_ast = Cgen.translate filename o in`
			`C.output dir c_ast;`
			`one_target others`
			`\| "caml" :: others -> Caml.print filename o; one_target others`
			`\| unknown_lg :: others -> unknown_lg :: one_target others`
			`\| [] -> [] in`
			`one_target target_languages`

			`(** Whole translation. *)`
			`let targets filename df obc target_languages =`
			`let target_languages = dataflow_target filename df target_languages in`
			`let target_languages = sequential_target filename obc target_languages in`
			`match target_languages with`
			`\| [] -> ()`
			`\| target :: _ -> language_error target`

			`let parse_implementation lexbuf =`
			`parse Parser.program Lexer.token lexbuf`

			`let parse_interface lexbuf =`
			`parse Parser.interface Lexer.token lexbuf`

			`let interface modname filename =`
			`(* input and output files *)`
			`let source_name = filename ^ ".epi"`
			`and obj_interf_name = filename ^ ".epci" in`

			`let ic = open_in source_name`
			`and itc = open_out_bin obj_interf_name in`
			`let close_all_files () =`
			`close_in ic;`
			`close_out itc in`

			`try`
			`Location.initialize source_name ic;`
			`Modules.initialize modname;`
			`Initial.initialize ();`

			`(* Parsing of the file *)`
			`let lexbuf = Lexing.from_channel ic in`
			`let l = parse_interface lexbuf in`

			`(* Convert the parse tree to Heptagon AST *)`
			`let l = Scoping.translate_interface l in`

			`Interface.Type.main l;`
			`Modules.write itc;`
			`if !print_types then Interface.Printer.print stdout;`
			`close_all_files ()`
			`with`
			`\| x -> close_all_files (); raise x`

			`let do_pass f d p pp enabled =`
			`if enabled`
			`then`
			`let r = f p in`
			`if !verbose`
			`then begin`
			`comment d;`
			`pp r;`
			`end;`
			`r`
			`else p`

			`let do_silent_pass f d p enabled =`
			`if enabled`
			`then begin`
			`let r = f p in`
			`if !verbose then comment d; r`
			`end`
			`else p`

			`let compile modname filename =`
			`(* input and output files *)`
			`let source_name = filename ^ ".ept"`
			`and obj_interf_name = filename ^ ".epci"`
			`and mls_name = filename ^ ".mls"`
			`and mls_norm_name = filename ^ "_norm.mls"`
			`and obc_name = filename ^ ".obc"`
			`and ml_name = filename ^ ".ml" in`

			`let ic = open_in source_name`
			`and itc = open_out_bin obj_interf_name`
			`and mlsc = open_out mls_name`
			`and mlsnc = open_out mls_norm_name`
			`and obc = open_out obc_name`
			`and mlc = open_out ml_name in`

			`let close_all_files () =`
			`close_in ic;`
			`close_out itc;`
			`close_out mlsc;`
			`close_out obc;`
			`close_out mlc in`

			`try`
			`Location.initialize source_name ic;`
			`Modules.initialize modname;`
			`Initial.initialize ();`

			`let pp = Printer.print stdout in`

			`(* Parsing of the file *)`
			`let lexbuf = Lexing.from_channel ic in`
			`let p = parse_implementation lexbuf in`

			`(* Convert the parse tree to Heptagon AST *)`
			`let p = Scoping.translate_program p in`
			`if !verbose`
			`then begin`
			`comment "Parsing";`
			`pp p`
			`end;`

			`(* Misc.reset_symbol (); *)`

			`(* Typing *)`
			`let p = do_pass Typing.program "Typing" p pp true in`

			`(* Linear typing *)`
			`let p = do_pass Linear_typing.program "Linear Typing" p pp (not !no_mem_alloc) in`

			`if !print_types then Interface.Printer.print stdout;`
			`Modules.write itc;`

			`(* Causality check *)`
			`let p =`
			`do_silent_pass Causality.program "Causality check" p true in`

			`(* Initialization check *)`
			`let p =`
			`do_silent_pass Initialization.program "Initialization check" p !init in`

			`(* Mark nodes to be inlined *)`
			`(* let to_inline = List.map Misc.mk_longname !nodes_to_inline in`
			`let p = Inline.mark_calls_to to_inline p in`
			`let p = match !node_to_flatten with`
			`\| None -> p`
			`\| Some nn -> Inline.flatten nn p in`
			`if !verbose then comment "Inlining pre-pass";*)`

			`(* Inline marked nodes *)`
			`(* let p = do_pass Inline.program "Inlining" p pp true in *)`

			`(* Automata memory sharing *)`
			`let p = do_pass Automata_mem.program "Automata memory sharing" p pp (not !no_mem_alloc) in`

			`(* Completion of partial definitions *)`
			`let p = do_pass Completion.program "Completion" p pp true in`

			`(* Automata *)`
			`let p = do_pass Automata.program "Automata" p pp true in`

			`(* Present *)`
			`let p = do_pass Present.program "Present" p pp true in`

			`(* Shared variables (last) *)`
			`let p = do_pass Last.program "Last" p pp true in`

			`(* Reset *)`
			`let reset_prog = if !use_new_reset_encoding then Reset_new.program else Reset.program in`
			`let p = do_pass reset_prog "Reset" p pp true in`

			`(* Every *)`
			`let p = do_pass Every.program "Every" p pp true in`

			`(* Merge and translate the heptagon program into the *)`
			`(* clocked data-flow language mini-ls *)`
			`let pp = Minils.Printer.print stdout in`

			`let p = Merge.program p in`
			`if !verbose then comment "Translation into clocked equations";`
			`Minils.Printer.print mlsc p;`

			`(* Annotation of expressions with their clock *)`
			`let p = Clocking.program p in`

			`(* Mls2dot.program "" p; *)`

			`(** Start of data-flow optimizations *)`
			`(* Normalization to maximize opportunities *)`
			`let p = do_pass Normalize.program "Normalization" p pp true in`

			`(* Back-end causality check. Only useful to check that *)`
			`(* we did not make any mistake during code generation *)`
			`let p =`
			`do_silent_pass Dfcausality.program "Post-pass causality check" p true in`

			`(* Check that the dataflow code is well initialized *)`
			`(*`
			`let p =`
			`do_silent_pass Init.program "Post-pass initialization check" p true in`
			`*)`

			`let sigali = List.mem "z3z" !target_languages in`

			`(* Boolean translation of enumerated values *)`
			`(* let p =`
			`do_pass`
			`Boolean.program "Boolean transformation" p pp (!boolean or sigali) in`
			`*)`

			`(* Normalization to maximize opportunities *)`
			`let p = do_pass Normalize.program "Normalization" p pp true in`

			`(* Mls2dot.program "normalized_" p; *)`

			`let p =`
			`do_pass Deadcode.program "Deadcode removal" p pp !deadcode in`

			`(* Automata minimization *)`
			`let p = do_pass Tommls.program "Automata minimization" p pp !tomato in`

			`(* Common sub-expression elimination *)`
			`let p =`
			`do_pass Cmse.program "Common sub-expression elimination" p pp !cse in`

			`(* Removing intermediate equations *)`
			`let p =`
			`do_pass Intermediate.program "Intermediate-equations removal"`
			`p pp !intermediate in`

			`Mls2dot.program "optimized_" p;`

			`(* Splitting *)`
			`let p = do_pass Splitting.program "Splitting" p pp (not !no_mem_alloc) in`

			`(* Scheduling *)`
			`let scheduler = if !use_interf_scheduler then Schedule_interf.program else Schedule.program in`
			`let p = do_pass scheduler "Scheduling" p pp true in`

			`(* Memory allocation *)`
			`Interference.world.Interference.node_is_scheduled <- true;`
			`let p = do_pass Memalloc.program`
			`"Interference graph building and Memory Allocation" p pp (not !no_mem_alloc) in`

			`(* Parametrized functions instantiation *)`
			`let p = do_pass Callgraph.program`
			`"Parametrized functions instantiation" p pp true in`

			`Minils.Printer.print mlsnc p;`

			`(* Producing Object-based code *)`
			`let o = Translate.program p in`
			`if !verbose then comment "Translation into Object-based code";`
			`Obc.Printer.print obc o;`

			`let pp = Obc.Printer.print stdout in`
			`if !verbose then pp o;`

			`(* Translation into dataflow and sequential languages *)`
			`targets filename p o !target_languages;`

			`close_all_files ();`

			`with x -> close_all_files (); raise x`