{-# LANGUAGE BangPatterns #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE UndecidableInstances #-} module GHC.Cmm.Expr ( CmmExpr(..), cmmExprType, cmmExprWidth, cmmExprAlignment, maybeInvertCmmExpr , CmmReg(..), cmmRegType, cmmRegWidth , CmmLit(..), cmmLitType , AlignmentSpec(..) -- TODO: Remove: , LocalReg(..), localRegType , GlobalReg(..), isArgReg, globalRegType , spReg, hpReg, spLimReg, hpLimReg, nodeReg , currentTSOReg, currentNurseryReg, hpAllocReg, cccsReg , node, baseReg , VGcPtr(..) , DefinerOfRegs, UserOfRegs , foldRegsDefd, foldRegsUsed , foldLocalRegsDefd, foldLocalRegsUsed , RegSet, LocalRegSet, GlobalRegSet , emptyRegSet, elemRegSet, extendRegSet, deleteFromRegSet, mkRegSet , plusRegSet, minusRegSet, timesRegSet, sizeRegSet, nullRegSet , regSetToList , isTrivialCmmExpr , hasNoGlobalRegs , isLit , isComparisonExpr , Area(..) , module GHC.Cmm.MachOp , module GHC.Cmm.Type ) where import GHC.Prelude import GHC.Platform import GHC.Cmm.BlockId import GHC.Cmm.CLabel import GHC.Cmm.MachOp import GHC.Cmm.Type import GHC.Cmm.Reg import GHC.Utils.Panic (panic) import GHC.Utils.Outputable import Data.Maybe import Data.Set (Set) import qualified Data.Set as Set import Numeric ( fromRat ) import GHC.Types.Basic (Alignment, mkAlignment, alignmentOf) ----------------------------------------------------------------------------- -- CmmExpr -- An expression. Expressions have no side effects. ----------------------------------------------------------------------------- data CmmExpr = CmmLit !CmmLit -- Literal | CmmLoad !CmmExpr !CmmType !AlignmentSpec -- Read memory location | CmmReg !CmmReg -- Contents of register | CmmMachOp MachOp [CmmExpr] -- Machine operation (+, -, *, etc.) | CmmStackSlot Area {-# UNPACK #-} !Int -- Addressing expression of a stack slot -- See Note [CmmStackSlot aliasing] | CmmRegOff !CmmReg !Int -- CmmRegOff reg i -- ** is shorthand only, meaning ** -- CmmMachOp (MO_Add rep) [x, CmmLit (CmmInt (fromIntegral i) rep)] -- where rep = typeWidth (cmmRegType reg) deriving Show instance Eq CmmExpr where -- Equality ignores the types CmmLit l1 == CmmLit l2 = l1==l2 CmmLoad e1 _ _ == CmmLoad e2 _ _ = e1==e2 CmmReg r1 == CmmReg r2 = r1==r2 CmmRegOff r1 i1 == CmmRegOff r2 i2 = r1==r2 && i1==i2 CmmMachOp op1 es1 == CmmMachOp op2 es2 = op1==op2 && es1==es2 CmmStackSlot a1 i1 == CmmStackSlot a2 i2 = a1==a2 && i1==i2 _e1 == _e2 = False instance OutputableP Platform CmmExpr where pdoc = pprExpr data AlignmentSpec = NaturallyAligned | Unaligned deriving (Eq, Ord, Show) -- | A stack area is either the stack slot where a variable is spilled -- or the stack space where function arguments and results are passed. data Area = Old -- See Note [Old Area] | Young {-# UNPACK #-} !BlockId -- Invariant: must be a continuation BlockId -- See Note [Continuation BlockIds] in GHC.Cmm.Node. deriving (Eq, Ord, Show) instance Outputable Area where ppr e = pprArea e pprArea :: Area -> SDoc pprArea Old = text "old" pprArea (Young id) = hcat [ text "young<", ppr id, text ">" ] {- Note [Old Area] ~~~~~~~~~~~~~~~~~~ There is a single call area 'Old', allocated at the extreme old end of the stack frame (ie just younger than the return address) which holds: * incoming (overflow) parameters, * outgoing (overflow) parameter to tail calls, * outgoing (overflow) result values * the update frame (if any) Its size is the max of all these requirements. On entry, the stack pointer will point to the youngest incoming parameter, which is not necessarily at the young end of the Old area. End of note -} {- Note [CmmStackSlot aliasing] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When do two CmmStackSlots alias? - T[old+N] aliases with U[young(L)+M] for all T, U, L, N and M - T[old+N] aliases with U[old+M] only if the areas actually overlap Or more informally, different Areas may overlap with each other. An alternative semantics, that we previously had, was that different Areas do not overlap. The problem that lead to redefining the semantics of stack areas is described below. e.g. if we had x = Sp[old + 8] y = Sp[old + 16] Sp[young(L) + 8] = L Sp[young(L) + 16] = y Sp[young(L) + 24] = x call f() returns to L if areas semantically do not overlap, then we might optimise this to Sp[young(L) + 8] = L Sp[young(L) + 16] = Sp[old + 8] Sp[young(L) + 24] = Sp[old + 16] call f() returns to L and now young(L) cannot be allocated at the same place as old, and we are doomed to use more stack. - old+8 conflicts with young(L)+8 - old+16 conflicts with young(L)+16 and young(L)+8 so young(L)+8 == old+24 and we get Sp[-8] = L Sp[-16] = Sp[8] Sp[-24] = Sp[0] Sp -= 24 call f() returns to L However, if areas are defined to be "possibly overlapping" in the semantics, then we cannot commute any loads/stores of old with young(L), and we will be able to re-use both old+8 and old+16 for young(L). x = Sp[8] y = Sp[0] Sp[8] = L Sp[0] = y Sp[-8] = x Sp = Sp - 8 call f() returns to L Now, the assignments of y go away, x = Sp[8] Sp[8] = L Sp[-8] = x Sp = Sp - 8 call f() returns to L -} data CmmLit = CmmInt !Integer !Width -- Interpretation: the 2's complement representation of the value -- is truncated to the specified size. This is easier than trying -- to keep the value within range, because we don't know whether -- it will be used as a signed or unsigned value (the CmmType doesn't -- distinguish between signed & unsigned). | CmmFloat Rational !Width | CmmVec [CmmLit] -- Vector literal | CmmLabel CLabel -- Address of label | CmmLabelOff CLabel !Int -- Address of label + byte offset -- Due to limitations in the C backend, the following -- MUST ONLY be used inside the info table indicated by label2 -- (label2 must be the info label), and label1 must be an -- SRT, a slow entrypoint or a large bitmap (see the Mangler) -- Don't use it at all unless tablesNextToCode. -- It is also used inside the NCG during when generating -- position-independent code. | CmmLabelDiffOff CLabel CLabel !Int !Width -- label1 - label2 + offset -- In an expression, the width just has the effect of MO_SS_Conv -- from wordWidth to the desired width. -- -- In a static literal, the supported Widths depend on the -- architecture: wordWidth is supported on all -- architectures. Additionally W32 is supported on x86_64 when -- using the small memory model. | CmmBlock {-# UNPACK #-} !BlockId -- Code label -- Invariant: must be a continuation BlockId -- See Note [Continuation BlockIds] in GHC.Cmm.Node. | CmmHighStackMark -- A late-bound constant that stands for the max -- #bytes of stack space used during a procedure. -- During the stack-layout pass, CmmHighStackMark -- is replaced by a CmmInt for the actual number -- of bytes used deriving (Eq, Show) instance OutputableP Platform CmmLit where pdoc = pprLit instance Outputable CmmLit where ppr (CmmInt n w) = text "CmmInt" <+> ppr n <+> ppr w ppr (CmmFloat n w) = text "CmmFloat" <+> text (show n) <+> ppr w ppr (CmmVec xs) = text "CmmVec" <+> ppr xs ppr (CmmLabel _) = text "CmmLabel" ppr (CmmLabelOff _ _) = text "CmmLabelOff" ppr (CmmLabelDiffOff _ _ _ _) = text "CmmLabelDiffOff" ppr (CmmBlock blk) = text "CmmBlock" <+> ppr blk ppr CmmHighStackMark = text "CmmHighStackMark" cmmExprType :: Platform -> CmmExpr -> CmmType cmmExprType platform = \case (CmmLit lit) -> cmmLitType platform lit (CmmLoad _ rep _) -> rep (CmmReg reg) -> cmmRegType platform reg (CmmMachOp op args) -> machOpResultType platform op (map (cmmExprType platform) args) (CmmRegOff reg _) -> cmmRegType platform reg (CmmStackSlot _ _) -> bWord platform -- an address -- Careful though: what is stored at the stack slot may be bigger than -- an address cmmLitType :: Platform -> CmmLit -> CmmType cmmLitType platform = \case (CmmInt _ width) -> cmmBits width (CmmFloat _ width) -> cmmFloat width (CmmVec []) -> panic "cmmLitType: CmmVec []" (CmmVec (l:ls)) -> let ty = cmmLitType platform l in if all (`cmmEqType` ty) (map (cmmLitType platform) ls) then cmmVec (1+length ls) ty else panic "cmmLitType: CmmVec" (CmmLabel lbl) -> cmmLabelType platform lbl (CmmLabelOff lbl _) -> cmmLabelType platform lbl (CmmLabelDiffOff _ _ _ width) -> cmmBits width (CmmBlock _) -> bWord platform (CmmHighStackMark) -> bWord platform cmmLabelType :: Platform -> CLabel -> CmmType cmmLabelType platform lbl | isGcPtrLabel lbl = gcWord platform | otherwise = bWord platform cmmExprWidth :: Platform -> CmmExpr -> Width cmmExprWidth platform e = typeWidth (cmmExprType platform e) -- | Returns an alignment in bytes of a CmmExpr when it's a statically -- known integer constant, otherwise returns an alignment of 1 byte. -- The caller is responsible for using with a sensible CmmExpr -- argument. cmmExprAlignment :: CmmExpr -> Alignment cmmExprAlignment (CmmLit (CmmInt intOff _)) = alignmentOf (fromInteger intOff) cmmExprAlignment _ = mkAlignment 1 -------- --- Negation for conditional branches maybeInvertCmmExpr :: CmmExpr -> Maybe CmmExpr maybeInvertCmmExpr (CmmMachOp op args) = do op' <- maybeInvertComparison op return (CmmMachOp op' args) maybeInvertCmmExpr _ = Nothing --------------------------------------------------- -- CmmExpr predicates --------------------------------------------------- isTrivialCmmExpr :: CmmExpr -> Bool isTrivialCmmExpr (CmmLoad _ _ _) = False isTrivialCmmExpr (CmmMachOp _ _) = False isTrivialCmmExpr (CmmLit _) = True isTrivialCmmExpr (CmmReg _) = True isTrivialCmmExpr (CmmRegOff _ _) = True isTrivialCmmExpr (CmmStackSlot _ _) = panic "isTrivialCmmExpr CmmStackSlot" hasNoGlobalRegs :: CmmExpr -> Bool hasNoGlobalRegs (CmmLoad e _ _) = hasNoGlobalRegs e hasNoGlobalRegs (CmmMachOp _ es) = all hasNoGlobalRegs es hasNoGlobalRegs (CmmLit _) = True hasNoGlobalRegs (CmmReg (CmmLocal _)) = True hasNoGlobalRegs (CmmRegOff (CmmLocal _) _) = True hasNoGlobalRegs _ = False isLit :: CmmExpr -> Bool isLit (CmmLit _) = True isLit _ = False isComparisonExpr :: CmmExpr -> Bool isComparisonExpr (CmmMachOp op _) = isComparisonMachOp op isComparisonExpr _ = False ----------------------------------------------------------------------------- -- Register-use information for expressions and other types ----------------------------------------------------------------------------- -- | Sets of registers -- These are used for dataflow facts, and a common operation is taking -- the union of two RegSets and then asking whether the union is the -- same as one of the inputs. UniqSet isn't good here, because -- sizeUniqSet is O(n) whereas Set.size is O(1), so we use ordinary -- Sets. type RegSet r = Set r type LocalRegSet = RegSet LocalReg type GlobalRegSet = RegSet GlobalReg emptyRegSet :: RegSet r nullRegSet :: RegSet r -> Bool elemRegSet :: Ord r => r -> RegSet r -> Bool extendRegSet :: Ord r => RegSet r -> r -> RegSet r deleteFromRegSet :: Ord r => RegSet r -> r -> RegSet r mkRegSet :: Ord r => [r] -> RegSet r minusRegSet, plusRegSet, timesRegSet :: Ord r => RegSet r -> RegSet r -> RegSet r sizeRegSet :: RegSet r -> Int regSetToList :: RegSet r -> [r] emptyRegSet = Set.empty nullRegSet = Set.null elemRegSet = Set.member extendRegSet = flip Set.insert deleteFromRegSet = flip Set.delete mkRegSet = Set.fromList minusRegSet = Set.difference plusRegSet = Set.union timesRegSet = Set.intersection sizeRegSet = Set.size regSetToList = Set.toList class Ord r => UserOfRegs r a where foldRegsUsed :: Platform -> (b -> r -> b) -> b -> a -> b foldLocalRegsUsed :: UserOfRegs LocalReg a => Platform -> (b -> LocalReg -> b) -> b -> a -> b foldLocalRegsUsed = foldRegsUsed class Ord r => DefinerOfRegs r a where foldRegsDefd :: Platform -> (b -> r -> b) -> b -> a -> b foldLocalRegsDefd :: DefinerOfRegs LocalReg a => Platform -> (b -> LocalReg -> b) -> b -> a -> b foldLocalRegsDefd = foldRegsDefd instance UserOfRegs LocalReg CmmReg where foldRegsUsed _ f z (CmmLocal reg) = f z reg foldRegsUsed _ _ z (CmmGlobal _) = z instance DefinerOfRegs LocalReg CmmReg where foldRegsDefd _ f z (CmmLocal reg) = f z reg foldRegsDefd _ _ z (CmmGlobal _) = z instance UserOfRegs GlobalReg CmmReg where {-# INLINEABLE foldRegsUsed #-} foldRegsUsed _ _ z (CmmLocal _) = z foldRegsUsed _ f z (CmmGlobal reg) = f z reg instance DefinerOfRegs GlobalReg CmmReg where foldRegsDefd _ _ z (CmmLocal _) = z foldRegsDefd _ f z (CmmGlobal reg) = f z reg instance Ord r => UserOfRegs r r where foldRegsUsed _ f z r = f z r instance Ord r => DefinerOfRegs r r where foldRegsDefd _ f z r = f z r instance (Ord r, UserOfRegs r CmmReg) => UserOfRegs r CmmExpr where -- The (Ord r) in the context is necessary here -- See Note [Recursive superclasses] in GHC.Tc.TyCl.Instance {-# INLINEABLE foldRegsUsed #-} foldRegsUsed platform f !z e = expr z e where expr z (CmmLit _) = z expr z (CmmLoad addr _ _) = foldRegsUsed platform f z addr expr z (CmmReg r) = foldRegsUsed platform f z r expr z (CmmMachOp _ exprs) = foldRegsUsed platform f z exprs expr z (CmmRegOff r _) = foldRegsUsed platform f z r expr z (CmmStackSlot _ _) = z instance UserOfRegs r a => UserOfRegs r [a] where foldRegsUsed platform f set as = foldl' (foldRegsUsed platform f) set as {-# INLINABLE foldRegsUsed #-} instance DefinerOfRegs r a => DefinerOfRegs r [a] where foldRegsDefd platform f set as = foldl' (foldRegsDefd platform f) set as {-# INLINABLE foldRegsDefd #-} -- -------------------------------------------------------------------------- -- Pretty-printing expressions -- -------------------------------------------------------------------------- pprExpr :: Platform -> CmmExpr -> SDoc pprExpr platform e = case e of CmmRegOff reg i -> pprExpr platform (CmmMachOp (MO_Add rep) [CmmReg reg, CmmLit (CmmInt (fromIntegral i) rep)]) where rep = typeWidth (cmmRegType platform reg) CmmLit lit -> pprLit platform lit _other -> pprExpr1 platform e -- Here's the precedence table from GHC.Cmm.Parser: -- %nonassoc '>=' '>' '<=' '<' '!=' '==' -- %left '|' -- %left '^' -- %left '&' -- %left '>>' '<<' -- %left '-' '+' -- %left '/' '*' '%' -- %right '~' -- We just cope with the common operators for now, the rest will get -- a default conservative behaviour. -- %nonassoc '>=' '>' '<=' '<' '!=' '==' pprExpr1, pprExpr7, pprExpr8 :: Platform -> CmmExpr -> SDoc pprExpr1 platform (CmmMachOp op [x,y]) | Just doc <- infixMachOp1 op = pprExpr7 platform x <+> doc <+> pprExpr7 platform y pprExpr1 platform e = pprExpr7 platform e infixMachOp1, infixMachOp7, infixMachOp8 :: MachOp -> Maybe SDoc infixMachOp1 (MO_Eq _) = Just (text "==") infixMachOp1 (MO_Ne _) = Just (text "!=") infixMachOp1 (MO_Shl _) = Just (text "<<") infixMachOp1 (MO_U_Shr _) = Just (text ">>") infixMachOp1 (MO_U_Ge _) = Just (text ">=") infixMachOp1 (MO_U_Le _) = Just (text "<=") infixMachOp1 (MO_U_Gt _) = Just (char '>') infixMachOp1 (MO_U_Lt _) = Just (char '<') infixMachOp1 _ = Nothing -- %left '-' '+' pprExpr7 platform (CmmMachOp (MO_Add rep1) [x, CmmLit (CmmInt i rep2)]) | i < 0 = pprExpr7 platform (CmmMachOp (MO_Sub rep1) [x, CmmLit (CmmInt (negate i) rep2)]) pprExpr7 platform (CmmMachOp op [x,y]) | Just doc <- infixMachOp7 op = pprExpr7 platform x <+> doc <+> pprExpr8 platform y pprExpr7 platform e = pprExpr8 platform e infixMachOp7 (MO_Add _) = Just (char '+') infixMachOp7 (MO_Sub _) = Just (char '-') infixMachOp7 _ = Nothing -- %left '/' '*' '%' pprExpr8 platform (CmmMachOp op [x,y]) | Just doc <- infixMachOp8 op = pprExpr8 platform x <+> doc <+> pprExpr9 platform y pprExpr8 platform e = pprExpr9 platform e infixMachOp8 (MO_U_Quot _) = Just (char '/') infixMachOp8 (MO_Mul _) = Just (char '*') infixMachOp8 (MO_U_Rem _) = Just (char '%') infixMachOp8 _ = Nothing pprExpr9 :: Platform -> CmmExpr -> SDoc pprExpr9 platform e = case e of CmmLit lit -> pprLit1 platform lit CmmLoad expr rep align -> let align_mark = case align of NaturallyAligned -> empty Unaligned -> text "^" in ppr rep <> align_mark <> brackets (pdoc platform expr) CmmReg reg -> ppr reg CmmRegOff reg off -> parens (ppr reg <+> char '+' <+> int off) CmmStackSlot a off -> parens (ppr a <+> char '+' <+> int off) CmmMachOp mop args -> genMachOp platform mop args genMachOp :: Platform -> MachOp -> [CmmExpr] -> SDoc genMachOp platform mop args | Just doc <- infixMachOp mop = case args of -- dyadic [x,y] -> pprExpr9 platform x <+> doc <+> pprExpr9 platform y -- unary [x] -> doc <> pprExpr9 platform x _ -> pprTrace "GHC.Cmm.Expr.genMachOp: machop with strange number of args" (pprMachOp mop <+> parens (hcat $ punctuate comma (map (pprExpr platform) args))) empty | isJust (infixMachOp1 mop) || isJust (infixMachOp7 mop) || isJust (infixMachOp8 mop) = parens (pprExpr platform (CmmMachOp mop args)) | otherwise = char '%' <> ppr_op <> parens (commafy (map (pprExpr platform) args)) where ppr_op = text (map (\c -> if c == ' ' then '_' else c) (show mop)) -- replace spaces in (show mop) with underscores, -- -- Unsigned ops on the word size of the machine get nice symbols. -- All else get dumped in their ugly format. -- infixMachOp :: MachOp -> Maybe SDoc infixMachOp mop = case mop of MO_And _ -> Just $ char '&' MO_Or _ -> Just $ char '|' MO_Xor _ -> Just $ char '^' MO_Not _ -> Just $ char '~' MO_S_Neg _ -> Just $ char '-' -- there is no unsigned neg :) _ -> Nothing -- -------------------------------------------------------------------------- -- Pretty-printing literals -- -- To minimise line noise we adopt the convention that if the literal -- has the natural machine word size, we do not append the type -- -------------------------------------------------------------------------- pprLit :: Platform -> CmmLit -> SDoc pprLit platform lit = case lit of CmmInt i rep -> hcat [ (if i < 0 then parens else id)(integer i) , ppUnless (rep == wordWidth platform) $ space <> dcolon <+> ppr rep ] CmmFloat f rep -> hsep [ double (fromRat f), dcolon, ppr rep ] CmmVec lits -> char '<' <> commafy (map (pprLit platform) lits) <> char '>' CmmLabel clbl -> pdoc platform clbl CmmLabelOff clbl i -> pdoc platform clbl <> ppr_offset i CmmLabelDiffOff clbl1 clbl2 i _ -> pdoc platform clbl1 <> char '-' <> pdoc platform clbl2 <> ppr_offset i CmmBlock id -> ppr id CmmHighStackMark -> text "" pprLit1 :: Platform -> CmmLit -> SDoc pprLit1 platform lit@(CmmLabelOff {}) = parens (pprLit platform lit) pprLit1 platform lit = pprLit platform lit ppr_offset :: Int -> SDoc ppr_offset i | i==0 = empty | i>=0 = char '+' <> int i | otherwise = char '-' <> int (-i) commafy :: [SDoc] -> SDoc commafy xs = fsep $ punctuate comma xs