hoopl-3.10.2.2: A library to support dataflow analysis and optimization

Safe HaskellSafe
LanguageHaskell2010

Compiler.Hoopl.Internals

Contents

Synopsis

Shapes

data O Source #

Used at the type level to indicate an "open" structure with a unique, unnamed control-flow edge flowing in or out. Fallthrough and concatenation are permitted at an open point.

Instances

IfThenElseable O Source # 

Methods

mkIfThenElse :: HooplNode n => (Label -> Label -> AGraph n O C) -> AGraph n O O -> AGraph n O O -> AGraph n O O Source #

type Fact O f Source # 
type Fact O f = f
type IndexedCO O _a b Source # 
type IndexedCO O _a b = b

data C Source #

Used at the type level to indicate a "closed" structure which supports control transfer only through the use of named labels---no "fallthrough" is permitted. The number of control-flow edges is unconstrained.

Instances

IfThenElseable C Source # 

Methods

mkIfThenElse :: HooplNode n => (Label -> Label -> AGraph n O C) -> AGraph n O C -> AGraph n O C -> AGraph n O C Source #

NonLocal n => LabelsPtr (n e C) Source # 

Methods

targetLabels :: n e C -> [Label] Source #

type Fact C f Source # 
type Fact C f = FactBase f
type IndexedCO C a _b Source # 
type IndexedCO C a _b = a

data MaybeO ex t where Source #

Maybe type indexed by open/closed

Constructors

JustO :: t -> MaybeO O t 
NothingO :: MaybeO C t 

Instances

Functor (MaybeO ex) Source # 

Methods

fmap :: (a -> b) -> MaybeO ex a -> MaybeO ex b #

(<$) :: a -> MaybeO ex b -> MaybeO ex a #

data MaybeC ex t where Source #

Maybe type indexed by closed/open

Constructors

JustC :: t -> MaybeC C t 
NothingC :: MaybeC O t 

Instances

Functor (MaybeC ex) Source # 

Methods

fmap :: (a -> b) -> MaybeC ex a -> MaybeC ex b #

(<$) :: a -> MaybeC ex b -> MaybeC ex a #

type family IndexedCO ex a b :: * Source #

Either type indexed by closed/open using type families

Instances

type IndexedCO C a _b Source # 
type IndexedCO C a _b = a
type IndexedCO O _a b Source # 
type IndexedCO O _a b = b

data Shape ex where Source #

Dynamic shape value

Constructors

Closed :: Shape C 
Open :: Shape O 

Blocks

data Block n e x where Source #

A sequence of nodes. May be any of four shapes (OO, OC, CO, CC). Open at the entry means single entry, mutatis mutandis for exit. A closedclosed block is a basic/ block and can't be extended further. Clients should avoid manipulating blocks and should stick to either nodes or graphs.

Constructors

BlockCO :: n C O -> Block n O O -> Block n C O 
BlockCC :: n C O -> Block n O O -> n O C -> Block n C C 
BlockOC :: Block n O O -> n O C -> Block n O C 
BNil :: Block n O O 
BMiddle :: n O O -> Block n O O 
BCat :: Block n O O -> Block n O O -> Block n O O 
BSnoc :: Block n O O -> n O O -> Block n O O 
BCons :: n O O -> Block n O O -> Block n O O 

Instances

Predicates on Blocks

Constructing blocks

blockCons :: n O O -> Block n O x -> Block n O x Source #

blockSnoc :: Block n e O -> n O O -> Block n e O Source #

blockJoinHead :: n C O -> Block n O x -> Block n C x Source #

blockJoinTail :: Block n e O -> n O C -> Block n e C Source #

blockJoin :: n C O -> Block n O O -> n O C -> Block n C C Source #

blockJoinAny :: (MaybeC e (n C O), Block n O O, MaybeC x (n O C)) -> Block n e x Source #

Convert a list of nodes to a block. The entry and exit node must or must not be present depending on the shape of the block.

blockAppend :: Block n e O -> Block n O x -> Block n e x Source #

Deconstructing blocks

firstNode :: Block n C x -> n C O Source #

lastNode :: Block n x C -> n O C Source #

endNodes :: Block n C C -> (n C O, n O C) Source #

blockSplitHead :: Block n C x -> (n C O, Block n O x) Source #

blockSplitTail :: Block n e C -> (Block n e O, n O C) Source #

blockSplit :: Block n C C -> (n C O, Block n O O, n O C) Source #

Split a closed block into its entry node, open middle block, and exit node.

blockSplitAny :: Block n e x -> (MaybeC e (n C O), Block n O O, MaybeC x (n O C)) Source #

Modifying blocks

replaceFirstNode :: Block n C x -> n C O -> Block n C x Source #

replaceLastNode :: Block n x C -> n O C -> Block n x C Source #

Converting to and from lists

blockToList :: Block n O O -> [n O O] Source #

Maps and folds

mapBlock :: (forall e x. n e x -> n' e x) -> Block n e x -> Block n' e x Source #

map a function over the nodes of a Block

mapBlock' :: (forall e x. n e x -> n' e x) -> Block n e x -> Block n' e x Source #

A strict mapBlock

mapBlock3' :: forall n n' e x. (n C O -> n' C O, n O O -> n' O O, n O C -> n' O C) -> Block n e x -> Block n' e x Source #

map over a block, with different functions to apply to first nodes, middle nodes and last nodes respectively. The map is strict.

foldBlockNodesF :: forall n a. (forall e x. n e x -> a -> a) -> forall e x. Block n e x -> IndexedCO e a a -> IndexedCO x a a Source #

foldBlockNodesF3 :: forall n a b c. (n C O -> a -> b, n O O -> b -> b, n O C -> b -> c) -> forall e x. Block n e x -> IndexedCO e a b -> IndexedCO x c b Source #

Fold a function over every node in a block, forward or backward. The fold function must be polymorphic in the shape of the nodes.

foldBlockNodesB :: forall n a. (forall e x. n e x -> a -> a) -> forall e x. Block n e x -> IndexedCO x a a -> IndexedCO e a a Source #

foldBlockNodesB3 :: forall n a b c. (n C O -> b -> c, n O O -> b -> b, n O C -> a -> b) -> forall e x. Block n e x -> IndexedCO x a b -> IndexedCO e c b Source #

Biasing

frontBiasBlock :: Block n e x -> Block n e x Source #

A block is "front biased" if the left child of every concatenation operation is a node, not a general block; a front-biased block is analogous to an ordinary list. If a block is front-biased, then its nodes can be traversed from front to back without general recusion; tail recursion suffices. Not all shapes can be front-biased; a closed/open block is inherently back-biased.

backBiasBlock :: Block n e x -> Block n e x Source #

A block is "back biased" if the right child of every concatenation operation is a node, not a general block; a back-biased block is analogous to a snoc-list. If a block is back-biased, then its nodes can be traversed from back to back without general recusion; tail recursion suffices. Not all shapes can be back-biased; an open/closed block is inherently front-biased.

Body

type Body n = LabelMap (Block n C C) Source #

A (possibly empty) collection of closed/closed blocks

type Body' block n = LabelMap (block n C C) Source #

Body abstracted over block

emptyBody :: Body' block n Source #

bodyList :: Body' block n -> [(Label, block n C C)] Source #

addBlock :: NonLocal thing => thing C C -> LabelMap (thing C C) -> LabelMap (thing C C) Source #

bodyUnion :: forall a. LabelMap a -> LabelMap a -> LabelMap a Source #

Graph

type Graph = Graph' Block Source #

A control-flow graph, which may take any of four shapes (O/O, OC, CO, C/C). A graph open at the entry has a single, distinguished, anonymous entry point; if a graph is closed at the entry, its entry point(s) are supplied by a context.

data Graph' block n e x where Source #

Graph' is abstracted over the block type, so that we can build graphs of annotated blocks for example (Compiler.Hoopl.Dataflow needs this).

Constructors

GNil :: Graph' block n O O 
GUnit :: block n O O -> Graph' block n O O 
GMany :: MaybeO e (block n O C) -> Body' block n -> MaybeO x (block n C O) -> Graph' block n e x 

class NonLocal thing where Source #

Gives access to the anchor points for nonlocal edges as well as the edges themselves

Minimal complete definition

entryLabel, successors

Methods

entryLabel :: thing C x -> Label Source #

successors :: thing e C -> [Label] Source #

Instances

Constructing graphs

blockGraph :: NonLocal n => Block n e x -> Graph n e x Source #

gUnitOO :: block n O O -> Graph' block n O O Source #

gUnitOC :: block n O C -> Graph' block n O C Source #

gUnitCO :: block n C O -> Graph' block n C O Source #

gUnitCC :: NonLocal (block n) => block n C C -> Graph' block n C C Source #

catGraphNodeOC :: NonLocal n => Graph n e O -> n O C -> Graph n e C Source #

catGraphNodeOO :: Graph n e O -> n O O -> Graph n e O Source #

catNodeCOGraph :: NonLocal n => n C O -> Graph n O x -> Graph n C x Source #

catNodeOOGraph :: n O O -> Graph n O x -> Graph n O x Source #

Splicing graphs

splice :: forall block n e a x. NonLocal (block n) => (forall e x. block n e O -> block n O x -> block n e x) -> Graph' block n e a -> Graph' block n a x -> Graph' block n e x Source #

gSplice :: NonLocal n => Graph n e a -> Graph n a x -> Graph n e x Source #

Maps

mapGraph :: (forall e x. n e x -> n' e x) -> Graph n e x -> Graph n' e x Source #

Maps over all nodes in a graph.

mapGraphBlocks :: forall block n block' n' e x. (forall e x. block n e x -> block' n' e x) -> Graph' block n e x -> Graph' block' n' e x Source #

Function mapGraphBlocks enables a change of representation of blocks, nodes, or both. It lifts a polymorphic block transform into a polymorphic graph transform. When the block representation stabilizes, a similar function should be provided for blocks.

Folds

foldGraphNodes :: forall n a. (forall e x. n e x -> a -> a) -> forall e x. Graph n e x -> a -> a Source #

Fold a function over every node in a graph. The fold function must be polymorphic in the shape of the nodes.

Extracting Labels

labelsDefined :: forall block n e x. NonLocal (block n) => Graph' block n e x -> LabelSet Source #

labelsUsed :: forall block n e x. NonLocal (block n) => Graph' block n e x -> LabelSet Source #

Depth-first traversals

postorder_dfs :: NonLocal (block n) => Graph' block n O x -> [block n C C] Source #

Traversal: postorder_dfs returns a list of blocks reachable from the entry of enterable graph. The entry and exit are *not* included. The list has the following property:

Say a "back reference" exists if one of a block's control-flow successors precedes it in the output list

Then there are as few back references as possible

The output is suitable for use in a forward dataflow problem. For a backward problem, simply reverse the list. (postorder_dfs is sufficiently tricky to implement that one doesn't want to try and maintain both forward and backward versions.)

postorder_dfs_from :: (NonLocal block, LabelsPtr b) => LabelMap (block C C) -> b -> [block C C] Source #

postorder_dfs_from_except :: forall block e. (NonLocal block, LabelsPtr e) => LabelMap (block C C) -> e -> LabelSet -> [block C C] Source #

preorder_dfs :: NonLocal (block n) => Graph' block n O x -> [block n C C] Source #

preorder_dfs_from_except :: forall block e. (NonLocal block, LabelsPtr e) => LabelMap (block C C) -> e -> LabelSet -> [block C C] Source #

class LabelsPtr l where Source #

Minimal complete definition

targetLabels

Methods

targetLabels :: l -> [Label] Source #

Instances

data Label Source #

Instances

data LabelSet Source #

Instances

data LabelMap v Source #

Instances

Functor LabelMap Source # 

Methods

fmap :: (a -> b) -> LabelMap a -> LabelMap b #

(<$) :: a -> LabelMap b -> LabelMap a #

Foldable LabelMap Source # 

Methods

fold :: Monoid m => LabelMap m -> m #

foldMap :: Monoid m => (a -> m) -> LabelMap a -> m #

foldr :: (a -> b -> b) -> b -> LabelMap a -> b #

foldr' :: (a -> b -> b) -> b -> LabelMap a -> b #

foldl :: (b -> a -> b) -> b -> LabelMap a -> b #

foldl' :: (b -> a -> b) -> b -> LabelMap a -> b #

foldr1 :: (a -> a -> a) -> LabelMap a -> a #

foldl1 :: (a -> a -> a) -> LabelMap a -> a #

toList :: LabelMap a -> [a] #

null :: LabelMap a -> Bool #

length :: LabelMap a -> Int #

elem :: Eq a => a -> LabelMap a -> Bool #

maximum :: Ord a => LabelMap a -> a #

minimum :: Ord a => LabelMap a -> a #

sum :: Num a => LabelMap a -> a #

product :: Num a => LabelMap a -> a #

Traversable LabelMap Source # 

Methods

traverse :: Applicative f => (a -> f b) -> LabelMap a -> f (LabelMap b) #

sequenceA :: Applicative f => LabelMap (f a) -> f (LabelMap a) #

mapM :: Monad m => (a -> m b) -> LabelMap a -> m (LabelMap b) #

sequence :: Monad m => LabelMap (m a) -> m (LabelMap a) #

IsMap LabelMap Source # 

Associated Types

type KeyOf (LabelMap :: * -> *) :: * Source #

Methods

mapNull :: LabelMap a -> Bool Source #

mapSize :: LabelMap a -> Int Source #

mapMember :: KeyOf LabelMap -> LabelMap a -> Bool Source #

mapLookup :: KeyOf LabelMap -> LabelMap a -> Maybe a Source #

mapFindWithDefault :: a -> KeyOf LabelMap -> LabelMap a -> a Source #

mapEmpty :: LabelMap a Source #

mapSingleton :: KeyOf LabelMap -> a -> LabelMap a Source #

mapInsert :: KeyOf LabelMap -> a -> LabelMap a -> LabelMap a Source #

mapInsertWith :: (a -> a -> a) -> KeyOf LabelMap -> a -> LabelMap a -> LabelMap a Source #

mapDelete :: KeyOf LabelMap -> LabelMap a -> LabelMap a Source #

mapUnion :: LabelMap a -> LabelMap a -> LabelMap a Source #

mapUnionWithKey :: (KeyOf LabelMap -> a -> a -> a) -> LabelMap a -> LabelMap a -> LabelMap a Source #

mapDifference :: LabelMap a -> LabelMap a -> LabelMap a Source #

mapIntersection :: LabelMap a -> LabelMap a -> LabelMap a Source #

mapIsSubmapOf :: Eq a => LabelMap a -> LabelMap a -> Bool Source #

mapMap :: (a -> b) -> LabelMap a -> LabelMap b Source #

mapMapWithKey :: (KeyOf LabelMap -> a -> b) -> LabelMap a -> LabelMap b Source #

mapFold :: (a -> b -> b) -> b -> LabelMap a -> b Source #

mapFoldWithKey :: (KeyOf LabelMap -> a -> b -> b) -> b -> LabelMap a -> b Source #

mapFilter :: (a -> Bool) -> LabelMap a -> LabelMap a Source #

mapElems :: LabelMap a -> [a] Source #

mapKeys :: LabelMap a -> [KeyOf LabelMap] Source #

mapToList :: LabelMap a -> [(KeyOf LabelMap, a)] Source #

mapFromList :: [(KeyOf LabelMap, a)] -> LabelMap a Source #

mapFromListWith :: (a -> a -> a) -> [(KeyOf LabelMap, a)] -> LabelMap a Source #

Eq v => Eq (LabelMap v) Source # 

Methods

(==) :: LabelMap v -> LabelMap v -> Bool #

(/=) :: LabelMap v -> LabelMap v -> Bool #

Ord v => Ord (LabelMap v) Source # 

Methods

compare :: LabelMap v -> LabelMap v -> Ordering #

(<) :: LabelMap v -> LabelMap v -> Bool #

(<=) :: LabelMap v -> LabelMap v -> Bool #

(>) :: LabelMap v -> LabelMap v -> Bool #

(>=) :: LabelMap v -> LabelMap v -> Bool #

max :: LabelMap v -> LabelMap v -> LabelMap v #

min :: LabelMap v -> LabelMap v -> LabelMap v #

Show v => Show (LabelMap v) Source # 

Methods

showsPrec :: Int -> LabelMap v -> ShowS #

show :: LabelMap v -> String #

showList :: [LabelMap v] -> ShowS #

type KeyOf LabelMap Source # 

data DataflowLattice a Source #

A transfer function might want to use the logging flag to control debugging, as in for example, it updates just one element in a big finite map. We don't want Hoopl to show the whole fact, and only the transfer function knows exactly what changed.

Constructors

DataflowLattice 

Fields

type JoinFun a = Label -> OldFact a -> NewFact a -> (ChangeFlag, a) Source #

newtype OldFact a Source #

Constructors

OldFact a 

newtype NewFact a Source #

Constructors

NewFact a 

type family Fact x f :: * Source #

Instances

type Fact C f Source # 
type Fact C f = FactBase f
type Fact O f Source # 
type Fact O f = f

mkFactBase :: forall f. DataflowLattice f -> [(Label, f)] -> FactBase f Source #

mkFactBase creates a FactBase from a list of (Label, fact) pairs. If the same label appears more than once, the relevant facts are joined.

data FwdPass m n f Source #

Constructors

FwdPass 

newtype FwdTransfer n f Source #

Constructors

FwdTransfer3 

Fields

mkFTransfer :: (forall e x. n e x -> f -> Fact x f) -> FwdTransfer n f Source #

mkFTransfer3 :: (n C O -> f -> f) -> (n O O -> f -> f) -> (n O C -> f -> FactBase f) -> FwdTransfer n f Source #

newtype FwdRewrite m n f Source #

Constructors

FwdRewrite3 

Fields

mkFRewrite :: FuelMonad m => (forall e x. n e x -> f -> m (Maybe (Graph n e x))) -> FwdRewrite m n f Source #

Functions passed to mkFRewrite should not be aware of the fuel supply. The result returned by mkFRewrite respects fuel.

mkFRewrite3 :: forall m n f. FuelMonad m => (n C O -> f -> m (Maybe (Graph n C O))) -> (n O O -> f -> m (Maybe (Graph n O O))) -> (n O C -> f -> m (Maybe (Graph n O C))) -> FwdRewrite m n f Source #

Functions passed to mkFRewrite3 should not be aware of the fuel supply. The result returned by mkFRewrite3 respects fuel.

wrapFR Source #

Arguments

:: (forall e x. (n e x -> f -> m (Maybe (Graph n e x, FwdRewrite m n f))) -> n' e x -> f' -> m' (Maybe (Graph n' e x, FwdRewrite m' n' f')))

This argument may assume that any function passed to it respects fuel, and it must return a result that respects fuel.

-> FwdRewrite m n f 
-> FwdRewrite m' n' f' 

wrapFR2 Source #

Arguments

:: (forall e x. (n1 e x -> f1 -> m1 (Maybe (Graph n1 e x, FwdRewrite m1 n1 f1))) -> (n2 e x -> f2 -> m2 (Maybe (Graph n2 e x, FwdRewrite m2 n2 f2))) -> n3 e x -> f3 -> m3 (Maybe (Graph n3 e x, FwdRewrite m3 n3 f3)))

This argument may assume that any function passed to it respects fuel, and it must return a result that respects fuel.

-> FwdRewrite m1 n1 f1 
-> FwdRewrite m2 n2 f2 
-> FwdRewrite m3 n3 f3 

data BwdPass m n f Source #

Constructors

BwdPass 

newtype BwdTransfer n f Source #

Constructors

BwdTransfer3 

Fields

mkBTransfer :: (forall e x. n e x -> Fact x f -> f) -> BwdTransfer n f Source #

mkBTransfer3 :: (n C O -> f -> f) -> (n O O -> f -> f) -> (n O C -> FactBase f -> f) -> BwdTransfer n f Source #

wrapBR Source #

Arguments

:: (forall e x. Shape x -> (n e x -> Fact x f -> m (Maybe (Graph n e x, BwdRewrite m n f))) -> n' e x -> Fact x f' -> m' (Maybe (Graph n' e x, BwdRewrite m' n' f')))

This argument may assume that any function passed to it respects fuel, and it must return a result that respects fuel.

-> BwdRewrite m n f 
-> BwdRewrite m' n' f' 

wrapBR2 Source #

Arguments

:: (forall e x. Shape x -> (n1 e x -> Fact x f1 -> m1 (Maybe (Graph n1 e x, BwdRewrite m1 n1 f1))) -> (n2 e x -> Fact x f2 -> m2 (Maybe (Graph n2 e x, BwdRewrite m2 n2 f2))) -> n3 e x -> Fact x f3 -> m3 (Maybe (Graph n3 e x, BwdRewrite m3 n3 f3)))

This argument may assume that any function passed to it respects fuel, and it must return a result that respects fuel.

-> BwdRewrite m1 n1 f1 
-> BwdRewrite m2 n2 f2 
-> BwdRewrite m3 n3 f3 

newtype BwdRewrite m n f Source #

Constructors

BwdRewrite3 

Fields

mkBRewrite :: FuelMonad m => (forall e x. n e x -> Fact x f -> m (Maybe (Graph n e x))) -> BwdRewrite m n f Source #

Functions passed to mkBRewrite should not be aware of the fuel supply. The result returned by mkBRewrite respects fuel.

mkBRewrite3 :: forall m n f. FuelMonad m => (n C O -> f -> m (Maybe (Graph n C O))) -> (n O O -> f -> m (Maybe (Graph n O O))) -> (n O C -> FactBase f -> m (Maybe (Graph n O C))) -> BwdRewrite m n f Source #

Functions passed to mkBRewrite3 should not be aware of the fuel supply. The result returned by mkBRewrite3 respects fuel.

analyzeAndRewriteFwd :: forall m n f e x entries. (CheckpointMonad m, NonLocal n, LabelsPtr entries) => FwdPass m n f -> MaybeC e entries -> Graph n e x -> Fact e f -> m (Graph n e x, FactBase f, MaybeO x f) Source #

if the graph being analyzed is open at the entry, there must be no other entry point, or all goes horribly wrong...

analyzeAndRewriteBwd :: (CheckpointMonad m, NonLocal n, LabelsPtr entries) => BwdPass m n f -> MaybeC e entries -> Graph n e x -> Fact x f -> m (Graph n e x, FactBase f, MaybeO e f) Source #

if the graph being analyzed is open at the exit, I don't quite understand the implications of possible other exits

Respecting Fuel

A value of type FwdRewrite or BwdRewrite respects fuel if any function contained within the value satisfies the following properties:

  • When fuel is exhausted, it always returns Nothing.
  • When it returns Just g rw, it consumes exactly one unit of fuel, and new rewrite rw also respects fuel.

Provided that functions passed to mkFRewrite, mkFRewrite3, mkBRewrite, and mkBRewrite3 are not aware of the fuel supply, the results respect fuel.

It is an unchecked run-time error for the argument passed to wrapFR, wrapFR2, wrapBR, or warpBR2 to return a function that does not respect fuel.