-------------------------------------------------------------------------------- -- Copyright 2001-2012, Daan Leijen, Bastiaan Heeren, Jurriaan Hage. This file -- is distributed under the terms of the BSD3 License. For more information, -- see the file "LICENSE.txt", which is included in the distribution. -------------------------------------------------------------------------------- -- $Id: Inline.hs 291 2012-11-08 11:27:33Z heere112 $ module Lvm.Asm.Inline (asmInline) where import Data.Maybe import Lvm.Asm.Data import Lvm.Asm.Occur ( asmOccur ) import Lvm.Common.Id import Lvm.Common.IdMap {--------------------------------------------------------------- Inline environment maps identifiers to their definition ---------------------------------------------------------------} type Env = IdMap Expr removeIds :: [Id] -> IdMap a -> IdMap a removeIds = flip (foldr deleteMap) {--------------------------------------------------------------- asmInline ---------------------------------------------------------------} asmInline :: AsmModule -> AsmModule asmInline = fmap inlineTop . asmOccur inlineTop :: Top -> Top inlineTop (Top params expr) = Top params (inlineExpr emptyMap expr) inlineExpr :: Env -> Expr -> Expr inlineExpr env expr = case expr of -- dead variable Let _ (Note (Occur Never) _) e2 -> inlineExpr env e2 -- once Let x (Note (Occur Once) e1) e2 -> let e1' = inlineExpr env e1 -- de-annotate in inlineExpr (extendMap x e1' env) e2 -- trivial, inline everywhere Let x e1 e2 | trivial e1 -> let e1' = inlineExpr env (deAnnotate e1) in inlineExpr (extendMap x e1' env) e2 Eval x e1 e2 | whnfTrivial e1 -> let e1' = inlineExpr env (deAnnotate e1) in inlineExpr (extendMap x e1' env) e2 -- inline-able let! binding? Eval x (Note (Occur Once) e1) e2 -> let e1' = inlineExpr env e1 -- de-annotate in if firstuse x e2 -- firstuse is true, we can inline immediately then let env' = extendMap x (Eval x e1' (Ap x [])) env -- NOTE: should we use a fresh id? in inlineExpr env' e2 else let e2' = inlineExpr env e2 in if firstuse x e2' -- firstuse became true after inlining! re-inline this definition again (is this too expensive?) then let env' = extendMap x (Eval x e1' (Ap x [])) emptyMap -- NOTE: should we use a fresh id? in inlineExpr env' e2' -- otherwise, don't inline this definition else Eval x (Note (Occur Once) e1') e2' -- basic cases Let x e1 e2 -> let env' = deleteMap x env in Let x (inlineExpr env e1) (inlineExpr env' e2) Eval x e1 e2 -> let env' = deleteMap x env in Eval x (inlineExpr env e1) (inlineExpr env' e2) LetRec bs e -> let (bs',env') = inlineBinds env bs in LetRec bs' (inlineExpr env' e) Match x alts -> case lookupMap x env of Just e -> -- trivial inlining of a let! binding leads to this configuration. -- a case-of-known transformation would actually remove this match. Eval x (Note (Occur Once) e) (Match x (inlineAlts env alts)) Nothing -> Match x (inlineAlts env alts) Ap x [] -> fromMaybe (Ap x []) (lookupMap x env) Ap x args -> let args0 = inlineExprs env args in case lookupMap x env of Just e -> case e of Ap id1 args1 -> Ap id1 (args1 ++ args0) -- flatten applications Eval id1 e1 (Ap id2 []) | id1==id2 -- special case for the strict inliner -> Eval id1 e1 (Ap id1 args0) _ -> Let x e (Ap x args) -- don't inline! Nothing -> Ap x args0 Con con args -> Con (inlineCon env con) (inlineExprs env args) Prim x args -> Prim x (inlineExprs env args) Lit _ -> expr Note note e -> Note note (inlineExpr env e) inlineCon :: Env -> Con Expr -> Con Expr inlineCon env con = case con of ConTag tag arity -> ConTag (inlineExpr env tag) arity _ -> con inlineExprs :: Env -> [Expr] -> [Expr] inlineExprs env exprs = [inlineExpr env expr | expr <- exprs] inlineBinds :: Env -> [(Id,Expr)] -> ([(Id,Expr)],Env) inlineBinds env binds = let env' = removeIds (map fst binds) env in ([(x,inlineExpr env' e) | (x,e) <- binds], env') inlineAlts :: Env -> [Alt] -> [Alt] inlineAlts env alts = [inlineAlt env alt | alt <- alts] inlineAlt :: IdMap Expr -> Alt -> Alt inlineAlt env (Alt pat expr) = Alt pat (inlineExpr (removeIds (patIds pat) env) expr) where patIds (PatVar x) = [x] patIds (PatCon _ xs) = xs patIds (PatLit _) = [] {--------------------------------------------------------------- deAnnotate ---------------------------------------------------------------} deAnnotate :: Expr -> Expr deAnnotate expr = case expr of Note _ e -> deAnnotate e _ -> expr {--------------------------------------------------------------- trivial ---------------------------------------------------------------} trivial :: Expr -> Bool trivial expr = case expr of Note _ e -> trivial e Ap _ [] -> True Con (ConId _) [] -> True Lit _ -> True _ -> False whnfTrivial :: Expr -> Bool whnfTrivial expr = case expr of Note _ e -> whnfTrivial e Con (ConId _) [] -> True Lit _ -> True _ -> False {--------------------------------------------------------------- firstuse ---------------------------------------------------------------} firstuse :: Id -> Expr -> Bool firstuse x = first x False firsts :: Id -> Bool -> [Expr] -> Bool firsts = foldl . first first :: Id -> Bool -> Expr -> Bool first x c expr = case expr of LetRec bs e -> firsts x c (map snd bs ++ [e]) Let _ e1 e2 -> firsts x c [e1,e2] Eval _ e1 _ -> first x False e1 Match _ _ -> False Prim _ args -> firsts x False args Ap y args | null args && y == x -> True | not (null args) -> firsts x c (Ap y [] : args) Con _ args -> firsts x c args Note _ e -> first x c e _ -> c