[project @ 2001-02-20 11:04:42 by simonmar]

[ghc-hetmet.git] / ghc / compiler / main / DriverState.hs

-----------------------------------------------------------------------------
-- $Id: DriverState.hs,v 1.27 2001/02/20 11:04:42 simonmar Exp $
--
-- Settings for the driver
--
-- (c) The University of Glasgow 2000
--
-----------------------------------------------------------------------------

module DriverState where

#include "HsVersions.h"

import CmStaticInfo
import CmdLineOpts
import DriverUtil
import Util
import Config
import Exception
import IOExts
#ifdef mingw32_TARGET_OS
import TmpFiles ( newTempName )
import Directory ( removeFile )
#endif
import Panic

import List
import Char  
import Monad

-----------------------------------------------------------------------------
-- non-configured things

cHaskell1Version = "5" -- i.e., Haskell 98

-----------------------------------------------------------------------------
-- Global compilation flags

-- location of compiler-related files
GLOBAL_VAR(v_TopDir,  clibdir, String)

-- Cpp-related flags
v_Hs_source_cpp_opts = global
        [ "-D__HASKELL1__="++cHaskell1Version
        , "-D__GLASGOW_HASKELL__="++cProjectVersionInt                          
        , "-D__HASKELL98__"
        , "-D__CONCURRENT_HASKELL__"
        ]
{-# NOINLINE v_Hs_source_cpp_opts #-}

-- Keep output from intermediate phases
GLOBAL_VAR(v_Keep_hi_diffs,             False,          Bool)
GLOBAL_VAR(v_Keep_hc_files,             False,          Bool)
GLOBAL_VAR(v_Keep_s_files,              False,          Bool)
GLOBAL_VAR(v_Keep_raw_s_files,          False,          Bool)
GLOBAL_VAR(v_Keep_tmp_files,            False,          Bool)

-- Misc
GLOBAL_VAR(v_Scale_sizes_by,            1.0,            Double)
GLOBAL_VAR(v_Dry_run,                   False,          Bool)
GLOBAL_VAR(v_Static,                    True,           Bool)
GLOBAL_VAR(v_NoHsMain,                  False,          Bool)
GLOBAL_VAR(v_Recomp,                    True,           Bool)
GLOBAL_VAR(v_Collect_ghc_timing,        False,          Bool)
GLOBAL_VAR(v_Do_asm_mangling,           True,           Bool)
GLOBAL_VAR(v_Excess_precision,          False,          Bool)

-----------------------------------------------------------------------------
-- Splitting object files (for libraries)

GLOBAL_VAR(v_Split_object_files,        False,          Bool)
GLOBAL_VAR(v_Split_prefix,              "",             String)
GLOBAL_VAR(v_N_split_files,             0,              Int)
        
can_split :: Bool
can_split =  prefixMatch "i386"    cTARGETPLATFORM
          || prefixMatch "alpha"   cTARGETPLATFORM
          || prefixMatch "hppa"    cTARGETPLATFORM
          || prefixMatch "m68k"    cTARGETPLATFORM
          || prefixMatch "mips"    cTARGETPLATFORM
          || prefixMatch "powerpc" cTARGETPLATFORM
          || prefixMatch "rs6000"  cTARGETPLATFORM
          || prefixMatch "sparc"   cTARGETPLATFORM

-----------------------------------------------------------------------------
-- Compiler output options

defaultHscLang
  | cGhcWithNativeCodeGen == "YES" && 
        (prefixMatch "i386" cTARGETPLATFORM ||
         prefixMatch "sparc" cTARGETPLATFORM)   =  HscAsm
  | otherwise                                   =  HscC

GLOBAL_VAR(v_Output_dir,  Nothing, Maybe String)
GLOBAL_VAR(v_Object_suf,  Nothing, Maybe String)
GLOBAL_VAR(v_Output_file, Nothing, Maybe String)
GLOBAL_VAR(v_Output_hi,   Nothing, Maybe String)

GLOBAL_VAR(v_Ld_inputs, [],      [String])

odir_ify :: String -> IO String
odir_ify f = do
  odir_opt <- readIORef v_Output_dir
  case odir_opt of
        Nothing -> return f
        Just d  -> return (newdir d f)

osuf_ify :: String -> IO String
osuf_ify f = do
  osuf_opt <- readIORef v_Object_suf
  case osuf_opt of
        Nothing -> return f
        Just s  -> return (newsuf s f)

-----------------------------------------------------------------------------
-- Hi Files

GLOBAL_VAR(v_Hi_on_stdout,      False,  Bool)
GLOBAL_VAR(v_Hi_suf,            "hi",   String)

-----------------------------------------------------------------------------
-- Compiler optimisation options

GLOBAL_VAR(v_OptLevel, 0, Int)

setOptLevel :: String -> IO ()
setOptLevel ""              = do { writeIORef v_OptLevel 1 }
setOptLevel "not"           = writeIORef v_OptLevel 0
setOptLevel [c] | isDigit c = do
   let level = ord c - ord '0'
   writeIORef v_OptLevel level
setOptLevel s = unknownFlagErr ("-O"++s)

GLOBAL_VAR(v_minus_o2_for_C,            False, Bool)
GLOBAL_VAR(v_MaxSimplifierIterations,   4,     Int)
GLOBAL_VAR(v_StgStats,                  False, Bool)
GLOBAL_VAR(v_UsageSPInf,                False, Bool)  -- Off by default
GLOBAL_VAR(v_Strictness,                True,  Bool)
GLOBAL_VAR(v_CPR,                       True,  Bool)
GLOBAL_VAR(v_CSE,                       True,  Bool)

-- these are the static flags you get without -O.
hsc_minusNoO_flags =
       [ 
        "-fignore-interface-pragmas",
        "-fomit-interface-pragmas",
        "-flet-no-escape"
        ]

-- these are the static flags you get when -O is on.
hsc_minusO_flags =
  [ 
        "-ffoldr-build-on",
        "-fdo-eta-reduction",
        "-fdo-lambda-eta-expansion",
        "-fcase-merge",
        "-flet-to-case",
        "-flet-no-escape"
   ]

hsc_minusO2_flags = hsc_minusO_flags    -- for now

getStaticOptimisationFlags 0 = hsc_minusNoO_flags
getStaticOptimisationFlags 1 = hsc_minusO_flags
getStaticOptimisationFlags n = hsc_minusO2_flags

buildCoreToDo :: IO [CoreToDo]
buildCoreToDo = do
   opt_level  <- readIORef v_OptLevel
   max_iter   <- readIORef v_MaxSimplifierIterations
   usageSP    <- readIORef v_UsageSPInf
   strictness <- readIORef v_Strictness
   cpr        <- readIORef v_CPR
   cse        <- readIORef v_CSE

   if opt_level == 0 then return
      [
        CoreDoSimplify (isAmongSimpl [
            MaxSimplifierIterations max_iter
        ])
      ]

    else {- opt_level >= 1 -} return [ 

        -- initial simplify: mk specialiser happy: minimum effort please
        CoreDoSimplify (isAmongSimpl [
            SimplInlinePhase 0,
                        -- Don't inline anything till full laziness has bitten
                        -- In particular, inlining wrappers inhibits floating
                        -- e.g. ...(case f x of ...)...
                        --  ==> ...(case (case x of I# x# -> fw x#) of ...)...
                        --  ==> ...(case x of I# x# -> case fw x# of ...)...
                        -- and now the redex (f x) isn't floatable any more
            DontApplyRules,
                        -- Similarly, don't apply any rules until after full 
                        -- laziness.  Notably, list fusion can prevent floating.
            NoCaseOfCase,
                        -- Don't do case-of-case transformations.
                        -- This makes full laziness work better
            MaxSimplifierIterations max_iter
        ]),

        -- Specialisation is best done before full laziness
        -- so that overloaded functions have all their dictionary lambdas manifest
        CoreDoSpecialising,

        CoreDoFloatOutwards False{-not full-},
        CoreDoFloatInwards,

        CoreDoSimplify (isAmongSimpl [
           SimplInlinePhase 1,
                -- Want to run with inline phase 1 after the specialiser to give
                -- maximum chance for fusion to work before we inline build/augment
                -- in phase 2.  This made a difference in 'ansi' where an 
                -- overloaded function wasn't inlined till too late.
           MaxSimplifierIterations max_iter
        ]),

        -- infer usage information here in case we need it later.
        -- (add more of these where you need them --KSW 1999-04)
        if usageSP then CoreDoUSPInf else CoreDoNothing,

        CoreDoSimplify (isAmongSimpl [
                -- Need inline-phase2 here so that build/augment get 
                -- inlined.  I found that spectral/hartel/genfft lost some useful
                -- strictness in the function sumcode' if augment is not inlined
                -- before strictness analysis runs
           SimplInlinePhase 2,
           MaxSimplifierIterations max_iter
        ]),

        CoreDoSimplify (isAmongSimpl [
           MaxSimplifierIterations 2
                -- No -finline-phase: allow all Ids to be inlined now
                -- This gets foldr inlined before strictness analysis
        ]),

        if strictness then CoreDoStrictness else CoreDoNothing,
        if cpr        then CoreDoCPResult   else CoreDoNothing,
        CoreDoWorkerWrapper,
        CoreDoGlomBinds,

        CoreDoSimplify (isAmongSimpl [
           MaxSimplifierIterations max_iter
                -- No -finline-phase: allow all Ids to be inlined now
        ]),

        CoreDoFloatOutwards False{-not full-},
                -- nofib/spectral/hartel/wang doubles in speed if you
                -- do full laziness late in the day.  It only happens
                -- after fusion and other stuff, so the early pass doesn't
                -- catch it.  For the record, the redex is 
                --        f_el22 (f_el21 r_midblock)


-- Leave out lambda lifting for now
--        "-fsimplify", -- Tidy up results of full laziness
--          "[", 
--                "-fmax-simplifier-iterations2",
--          "]",
--        "-ffloat-outwards-full",      

        -- We want CSE to follow the final full-laziness pass, because it may
        -- succeed in commoning up things floated out by full laziness.
        -- CSE used to rely on the no-shadowing invariant, but it doesn't any more

        if cse then CoreCSE else CoreDoNothing,

        CoreDoFloatInwards,

-- Case-liberation for -O2.  This should be after
-- strictness analysis and the simplification which follows it.

        if opt_level >= 2 then
           CoreLiberateCase
        else
           CoreDoNothing,

        -- Final clean-up simplification:
        CoreDoSimplify (isAmongSimpl [
          MaxSimplifierIterations max_iter
                -- No -finline-phase: allow all Ids to be inlined now
        ])
     ]

buildStgToDo :: IO [ StgToDo ]
buildStgToDo = do
  stg_stats <- readIORef v_StgStats
  let flags1 | stg_stats = [ D_stg_stats ]
             | otherwise = [ ]

        -- STG passes
  ways_ <- readIORef v_Ways
  let flags2 | WayProf `elem` ways_ = StgDoMassageForProfiling : flags1
             | otherwise            = flags1

  return flags2

-----------------------------------------------------------------------------
-- Paths & Libraries

split_marker = ':'   -- not configurable (ToDo)

v_Import_paths, v_Include_paths, v_Library_paths :: IORef [String]
GLOBAL_VAR(v_Import_paths,  ["."], [String])
GLOBAL_VAR(v_Include_paths, ["."], [String])
GLOBAL_VAR(v_Library_paths, [],  [String])

GLOBAL_VAR(v_Cmdline_libraries,   [], [String])

addToDirList :: IORef [String] -> String -> IO ()
addToDirList ref path
  = do paths <- readIORef ref
       writeIORef ref (paths ++ split split_marker path)

-----------------------------------------------------------------------------
-- Packages

GLOBAL_VAR(v_Path_package_config, error "path_package_config", String)

-- package list is maintained in dependency order
GLOBAL_VAR(v_Packages, ("std":"rts":"gmp":[]), [String])

addPackage :: String -> IO ()
addPackage package
  = do pkg_details <- readIORef v_Package_details
       case lookupPkg package pkg_details of
          Nothing -> throwDyn (OtherError ("unknown package name: " ++ package))
          Just details -> do
            ps <- readIORef v_Packages
            unless (package `elem` ps) $ do
                mapM_ addPackage (package_deps details)
                ps <- readIORef v_Packages
                writeIORef v_Packages (package:ps)

getPackageImportPath   :: IO [String]
getPackageImportPath = do
  ps <- getPackageInfo
  return (nub (concat (map import_dirs ps)))

getPackageIncludePath   :: IO [String]
getPackageIncludePath = do
  ps <- getPackageInfo
  return (nub (filter (not.null) (concatMap include_dirs ps)))

        -- includes are in reverse dependency order (i.e. rts first)
getPackageCIncludes   :: IO [String]
getPackageCIncludes = do
  ps <- getPackageInfo
  return (reverse (nub (filter (not.null) (concatMap c_includes ps))))

getPackageLibraryPath  :: IO [String]
getPackageLibraryPath = do
  ps <- getPackageInfo
  return (nub (concat (map library_dirs ps)))

getPackageLibraries    :: IO [String]
getPackageLibraries = do
  ps <- getPackageInfo
  tag <- readIORef v_Build_tag
  let suffix = if null tag then "" else '_':tag
  return (concat (
        map (\p -> map (++suffix) (hs_libraries p) ++ extra_libraries p) ps
     ))

getPackageExtraGhcOpts :: IO [String]
getPackageExtraGhcOpts = do
  ps <- getPackageInfo
  return (concatMap extra_ghc_opts ps)

getPackageExtraCcOpts  :: IO [String]
getPackageExtraCcOpts = do
  ps <- getPackageInfo
  return (concatMap extra_cc_opts ps)

getPackageExtraLdOpts  :: IO [String]
getPackageExtraLdOpts = do
  ps <- getPackageInfo
  return (concatMap extra_ld_opts ps)

getPackageInfo :: IO [Package]
getPackageInfo = do
  ps <- readIORef v_Packages
  getPackageDetails ps

getPackageDetails :: [String] -> IO [Package]
getPackageDetails ps = do
  pkg_details <- readIORef v_Package_details
  return [ pkg | p <- ps, Just pkg <- [ lookupPkg p pkg_details ] ]

GLOBAL_VAR(v_Package_details, (error "package_details"), [Package])

lookupPkg :: String -> [Package] -> Maybe Package
lookupPkg nm ps
   = case [p | p <- ps, name p == nm] of
        []    -> Nothing
        (p:_) -> Just p
-----------------------------------------------------------------------------
-- Ways

-- The central concept of a "way" is that all objects in a given
-- program must be compiled in the same "way".  Certain options change
-- parameters of the virtual machine, eg. profiling adds an extra word
-- to the object header, so profiling objects cannot be linked with
-- non-profiling objects.

-- After parsing the command-line options, we determine which "way" we
-- are building - this might be a combination way, eg. profiling+ticky-ticky.

-- We then find the "build-tag" associated with this way, and this
-- becomes the suffix used to find .hi files and libraries used in
-- this compilation.

GLOBAL_VAR(v_Build_tag, "", String)

data WayName
  = WayProf
  | WayUnreg
  | WayTicky
  | WayPar
  | WayGran
  | WaySMP
  | WayDebug
  | WayUser_a
  | WayUser_b
  | WayUser_c
  | WayUser_d
  | WayUser_e
  | WayUser_f
  | WayUser_g
  | WayUser_h
  | WayUser_i
  | WayUser_j
  | WayUser_k
  | WayUser_l
  | WayUser_m
  | WayUser_n
  | WayUser_o
  | WayUser_A
  | WayUser_B
  deriving (Eq,Ord)

GLOBAL_VAR(v_Ways, [] ,[WayName])

allowed_combination way = way `elem` combs
  where  -- the sub-lists must be ordered according to WayName, 
         -- because findBuildTag sorts them
    combs                = [ [WayProf,WayUnreg], [WayProf,WaySMP] ]

findBuildTag :: IO [String]  -- new options
findBuildTag = do
  way_names <- readIORef v_Ways
  case sort way_names of
     []  -> do  writeIORef v_Build_tag ""
                return []

     [w] -> do let details = lkupWay w
               writeIORef v_Build_tag (wayTag details)
               return (wayOpts details)

     ws  -> if not (allowed_combination ws)
                then throwDyn (OtherError $
                                "combination not supported: "  ++
                                foldr1 (\a b -> a ++ '/':b) 
                                (map (wayName . lkupWay) ws))
                else let stuff = map lkupWay ws
                         tag   = concat (map wayTag stuff)
                         flags = map wayOpts stuff
                     in do
                     writeIORef v_Build_tag tag
                     return (concat flags)

lkupWay w = 
   case lookup w way_details of
        Nothing -> error "findBuildTag"
        Just details -> details

data Way = Way {
  wayTag   :: String,
  wayName  :: String,
  wayOpts  :: [String]
  }

way_details :: [ (WayName, Way) ]
way_details =
  [ (WayProf, Way  "p" "Profiling"  
        [ "-fscc-profiling"
        , "-DPROFILING"
        , "-optc-DPROFILING"
        , "-fvia-C" ]),

    (WayTicky, Way  "t" "Ticky-ticky Profiling"  
        [ "-fticky-ticky"
        , "-DTICKY_TICKY"
        , "-optc-DTICKY_TICKY"
        , "-fvia-C" ]),

    (WayUnreg, Way  "u" "Unregisterised" 
        unregFlags ),

    (WayPar, Way  "mp" "Parallel" 
        [ "-fparallel"
        , "-D__PARALLEL_HASKELL__"
        , "-optc-DPAR"
        , "-package concurrent"
        , "-fvia-C" ]),

    (WayGran, Way  "mg" "Gransim" 
        [ "-fgransim"
        , "-D__GRANSIM__"
        , "-optc-DGRAN"
        , "-package concurrent"
        , "-fvia-C" ]),

    (WaySMP, Way  "s" "SMP"
        [ "-fsmp"
        , "-optc-pthread"
        , "-optl-pthread"
        , "-optc-DSMP"
        , "-fvia-C" ]),

    (WayUser_a,  Way  "a"  "User way 'a'"  ["$WAY_a_REAL_OPTS"]),       
    (WayUser_b,  Way  "b"  "User way 'b'"  ["$WAY_b_REAL_OPTS"]),       
    (WayUser_c,  Way  "c"  "User way 'c'"  ["$WAY_c_REAL_OPTS"]),       
    (WayUser_d,  Way  "d"  "User way 'd'"  ["$WAY_d_REAL_OPTS"]),       
    (WayUser_e,  Way  "e"  "User way 'e'"  ["$WAY_e_REAL_OPTS"]),       
    (WayUser_f,  Way  "f"  "User way 'f'"  ["$WAY_f_REAL_OPTS"]),       
    (WayUser_g,  Way  "g"  "User way 'g'"  ["$WAY_g_REAL_OPTS"]),       
    (WayUser_h,  Way  "h"  "User way 'h'"  ["$WAY_h_REAL_OPTS"]),       
    (WayUser_i,  Way  "i"  "User way 'i'"  ["$WAY_i_REAL_OPTS"]),       
    (WayUser_j,  Way  "j"  "User way 'j'"  ["$WAY_j_REAL_OPTS"]),       
    (WayUser_k,  Way  "k"  "User way 'k'"  ["$WAY_k_REAL_OPTS"]),       
    (WayUser_l,  Way  "l"  "User way 'l'"  ["$WAY_l_REAL_OPTS"]),       
    (WayUser_m,  Way  "m"  "User way 'm'"  ["$WAY_m_REAL_OPTS"]),       
    (WayUser_n,  Way  "n"  "User way 'n'"  ["$WAY_n_REAL_OPTS"]),       
    (WayUser_o,  Way  "o"  "User way 'o'"  ["$WAY_o_REAL_OPTS"]),       
    (WayUser_A,  Way  "A"  "User way 'A'"  ["$WAY_A_REAL_OPTS"]),       
    (WayUser_B,  Way  "B"  "User way 'B'"  ["$WAY_B_REAL_OPTS"]) 
  ]

unregFlags = 
   [ "-optc-DNO_REGS"
   , "-optc-DUSE_MINIINTERPRETER"
   , "-fno-asm-mangling"
   , "-funregisterised"
   , "-fvia-C" ]

-----------------------------------------------------------------------------
-- Programs for particular phases

GLOBAL_VAR(v_Pgm_L,   error "pgm_L", String)
GLOBAL_VAR(v_Pgm_P,   cRAWCPP,       String)
GLOBAL_VAR(v_Pgm_c,   cGCC,          String)
GLOBAL_VAR(v_Pgm_m,   error "pgm_m", String)
GLOBAL_VAR(v_Pgm_s,   error "pgm_s", String)
GLOBAL_VAR(v_Pgm_a,   cGCC,          String)
GLOBAL_VAR(v_Pgm_l,   cGCC,          String)
GLOBAL_VAR(v_Pgm_dll, cMkDLL,        String)

GLOBAL_VAR(v_Opt_dep,    [], [String])
GLOBAL_VAR(v_Anti_opt_C, [], [String])
GLOBAL_VAR(v_Opt_C,      [], [String])
GLOBAL_VAR(v_Opt_l,      [], [String])
GLOBAL_VAR(v_Opt_dll,    [], [String])

getStaticOpts :: IORef [String] -> IO [String]
getStaticOpts ref = readIORef ref >>= return . reverse