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|
-- |
-- Copyright : (c) Sam Truzjan 2013
-- License : BSD3
-- Maintainer : pxqr.sta@gmail.com
-- Stability : experimental
-- Portability : portable
--
-- Every node maintains a routing table of known good nodes. The
-- nodes in the routing table are used as starting points for
-- queries in the DHT. Nodes from the routing table are returned in
-- response to queries from other nodes.
--
-- For more info see:
-- <http://www.bittorrent.org/beps/bep_0005.html#routing-table>
--
{-# LANGUAGE CPP #-}
{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE BangPatterns #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE ViewPatterns #-}
{-# LANGUAGE TypeOperators #-}
{-# LANGUAGE DeriveGeneric #-}
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE GADTs #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE StandaloneDeriving, FlexibleContexts, MultiParamTypeClasses, FlexibleInstances #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module Network.DHT.Routing
{-
( -- * BucketList
BucketList
, Info(..)
-- * Attributes
, BucketCount
, defaultBucketCount
, BucketSize
, defaultBucketSize
, NodeCount
-- * Query
, Network.DHT.Routing.null
, Network.DHT.Routing.full
, thisId
, shape
, Network.DHT.Routing.size
, Network.DHT.Routing.depth
, compatibleNodeId
-- * Lookup
, K
, defaultK
, TableKey (..)
, kclosest
-- * Construction
, Network.DHT.Routing.nullTable
, Event(..)
, CheckPing(..)
, Network.DHT.Routing.insert
-- * Conversion
, Network.DHT.Routing.TableEntry
, Network.DHT.Routing.toList
-- * Routing
, Timestamp
, getTimestamp
) -} where
import Control.Applicative as A
import Control.Arrow
import Control.Monad
import Data.Function
import Data.Functor.Identity
import Data.List as L hiding (insert)
import Data.Maybe
import Data.Monoid
import Data.Wrapper.PSQ as PSQ
import Data.Serialize as S hiding (Result, Done)
import qualified Data.Sequence as Seq
import Data.Time
import Data.Time.Clock.POSIX
import Data.Word
import GHC.Generics
import Text.PrettyPrint as PP hiding ((<>))
import Text.PrettyPrint.HughesPJClass (pPrint,Pretty)
import qualified Data.ByteString as BS
import Data.Bits
import Data.Ord
import Data.Reflection
import Network.Address
import Data.Typeable
import Data.Coerce
-- | Last time the node was responding to our queries.
--
-- Not all nodes that we learn about are equal. Some are \"good\" and
-- some are not. Many nodes using the DHT are able to send queries
-- and receive responses, but are not able to respond to queries
-- from other nodes. It is important that each node's routing table
-- must contain only known good nodes. A good node is a node has
-- responded to one of our queries within the last 15 minutes. A
-- node is also good if it has ever responded to one of our queries
-- and has sent us a query within the last 15 minutes. After 15
-- minutes of inactivity, a node becomes questionable. Nodes become
-- bad when they fail to respond to multiple queries in a row. Nodes
-- that we know are good are given priority over nodes with unknown
-- status.
--
type Timestamp = POSIXTime
getTimestamp :: IO Timestamp
getTimestamp = do
utcTime <- getCurrentTime
return $ utcTimeToPOSIXSeconds utcTime
{-----------------------------------------------------------------------
Bucket
-----------------------------------------------------------------------}
--
-- When a k-bucket is full and a new node is discovered for that
-- k-bucket, the least recently seen node in the k-bucket is
-- PINGed. If the node is found to be still alive, the new node is
-- place in a secondary list, a replacement cache. The replacement
-- cache is used only if a node in the k-bucket stops responding. In
-- other words: new nodes are used only when older nodes disappear.
-- | Timestamp - last time this node is pinged.
type NodeEntry ni = Binding ni Timestamp
-- | Maximum number of 'NodeInfo's stored in a bucket. Most clients
-- use this value.
defaultBucketSize :: Int
defaultBucketSize = 8
data QueueMethods m elem fifo = QueueMethods
{ pushBack :: elem -> fifo -> m fifo
, popFront :: fifo -> m (Maybe elem, fifo)
, emptyQueue :: m fifo
}
{-
fromQ :: Functor m =>
( a -> b )
-> ( b -> a )
-> QueueMethods m elem a
-> QueueMethods m elem b
fromQ embed project QueueMethods{..} =
QueueMethods { pushBack = \e -> fmap embed . pushBack e . project
, popFront = fmap (second embed) . popFront . project
, emptyQueue = fmap embed emptyQueue
}
-}
seqQ :: QueueMethods Identity ni (Seq.Seq ni)
seqQ = QueueMethods
{ pushBack = \e fifo -> pure (fifo Seq.|> e)
, popFront = \fifo -> case Seq.viewl fifo of
e Seq.:< fifo' -> pure (Just e, fifo')
Seq.EmptyL -> pure (Nothing, Seq.empty)
, emptyQueue = pure Seq.empty
}
type BucketQueue ni = Seq.Seq ni
bucketQ :: QueueMethods Identity ni (BucketQueue ni)
bucketQ = seqQ
newtype Compare a = Compare (a -> a -> Ordering)
contramapC :: (b -> a) -> Compare a -> Compare b
contramapC f (Compare cmp) = Compare $ \a b -> cmp (f a) (f b)
newtype Ordered' s a = Ordered a
deriving (Show)
-- | Hack to avoid UndecidableInstances
newtype Shrink a = Shrink a
deriving (Show)
type Ordered s a = Ordered' s (Shrink a)
instance Reifies s (Compare a) => Eq (Ordered' s (Shrink a)) where
a == b = (compare a b == EQ)
instance Reifies s (Compare a) => Ord (Ordered' s (Shrink a)) where
compare a b = cmp (coerce a) (coerce b)
where Compare cmp = reflect (Proxy :: Proxy s)
-- | Bucket is also limited in its length — thus it's called k-bucket.
-- When bucket becomes full, we should split it in two lists by
-- current span bit. Span bit is defined by depth in the routing
-- table tree. Size of the bucket should be choosen such that it's
-- very unlikely that all nodes in bucket fail within an hour of
-- each other.
data Bucket s ni = Bucket
{ bktNodes :: !(PSQ (Ordered s ni) Timestamp) -- current routing nodes
, bktQ :: !(BucketQueue (Timestamp,ni)) -- replacements pending time-outs
} deriving (Generic)
deriving instance Show ni => Show (Bucket s ni)
bucketCompare :: forall p ni s. Reifies s (Compare ni) => p (Bucket s ni) -> Compare ni
bucketCompare _ = reflect (Proxy :: Proxy s)
mapBucket :: Reifies t (Compare ni) => (a -> ni) -> Bucket s a -> Bucket t ni
mapBucket f (Bucket ns q) = Bucket (PSQ.fromList $ map (\(ni :-> tm) -> (f' ni :-> tm)) $ PSQ.toList ns)
(fmap (second f) q)
where f' = coerce . f . coerce
#if 0
{-
getGenericNode :: ( Serialize (NodeId)
, Serialize ip
, Serialize u
) => Get (NodeInfo)
getGenericNode = do
nid <- get
naddr <- get
u <- get
return NodeInfo
{ nodeId = nid
, nodeAddr = naddr
, nodeAnnotation = u
}
putGenericNode :: ( Serialize (NodeId)
, Serialize ip
, Serialize u
) => NodeInfo -> Put
putGenericNode (NodeInfo nid naddr u) = do
put nid
put naddr
put u
instance (Eq ip, Ord (NodeId), Serialize (NodeId), Serialize ip, Serialize u) => Serialize (Bucket) where
get = Bucket . psqFromPairList <$> getListOf ( (,) <$> getGenericNode <*> get ) <*> pure (runIdentity $ emptyQueue bucketQ)
put = putListOf (\(ni,stamp) -> putGenericNode ni >> put stamp) . psqToPairList . bktNodes
-}
#endif
psqFromPairList :: (Ord p, Ord k) => [(k, p)] -> OrdPSQ k p ()
psqFromPairList xs = PSQ.fromList $ map (\(a,b) -> a :-> b) xs
psqToPairList :: OrdPSQ t t1 () -> [(t, t1)]
psqToPairList psq = map (\(a :-> b) -> (a,b)) $ PSQ.toList psq
-- | Update interval, in seconds.
delta :: NominalDiffTime
delta = 15 * 60
-- | Should maintain a set of stable long running nodes.
--
-- Note: pings are triggerd only when a bucket is full.
updateBucketForInbound curTime info bucket
-- Just update timestamp if a node is already in bucket.
--
-- Note PingResult events should only occur for nodes we requested a ping for,
-- and those will always already be in the routing queue and will get their
-- timestamp updated here, since 'TryInsert' is called on every inbound packet,
-- including ping results.
| already_have
= pure ( [], map_ns $ PSQ.insertWith max (coerce info) curTime )
-- bucket is good, but not full => we can insert a new node
| PSQ.size (bktNodes bucket) < defaultBucketSize
= pure ( [], map_ns $ PSQ.insert (coerce info) curTime )
-- If there are any questionable nodes in the bucket have not been
-- seen in the last 15 minutes, the least recently seen node is
-- pinged. If any nodes in the bucket are known to have become bad,
-- then one is replaced by the new node in the next insertBucket
-- iteration.
| not (L.null stales)
= pure ( stales
, bucket { -- Update timestamps so that we don't redundantly ping.
bktNodes = updateStamps curTime (coerce stales) $ bktNodes bucket
-- Update queue with the pending NodeInfo in case of ping fail.
, bktQ = runIdentity $ pushBack bucketQ (curTime,info) $ bktQ bucket } )
-- When the bucket is full of good nodes, the new node is simply discarded.
-- We must return 'A.empty' here to ensure that bucket splitting happens
-- inside 'modifyBucket'.
| otherwise = A.empty
where
-- We (take 1) to keep a 1-to-1 correspondence between pending pings and
-- waiting nodes in the bktQ. This way, we don't have to worry about what
-- to do with failed pings for which there is no ready replacements.
stales = -- One stale:
do (n :-> t) <- maybeToList $ PSQ.findMin (bktNodes bucket)
guard (t < curTime - delta)
return $ coerce n
-- All stale:
-- map key \$ PSQ.atMost (curTime - delta) $ bktNodes bucket
already_have = maybe False (const True) $ PSQ.lookup (coerce info) (bktNodes bucket)
map_ns f = bucket { bktNodes = f (bktNodes bucket) }
-- map_q f = bucket { bktQ = runIdentity \$ f (bktQ bucket) }
updateBucketForPingResult bad_node got_response bucket
= pure ( map (,Nothing) forgotten
++ map (second Just) replacements
, Bucket (foldr replace
(bktNodes bucket)
replacements)
popped
)
where
(top, popped) = runIdentity $ popFront bucketQ (bktQ bucket)
replacements | got_response = [] -- Timestamp was already updated by TryInsert.
| Just info <- top = do
-- Insert only if there's a removal.
_ <- maybeToList $ PSQ.lookup (coerce bad_node) (bktNodes bucket)
return (bad_node, info)
| otherwise = []
forgotten | got_response = maybeToList $ fmap snd top
replace (bad_node, (tm, info)) =
PSQ.insert (coerce info) tm
. PSQ.delete (coerce bad_node)
updateStamps :: Ord ni => Timestamp -> [ni] -> PSQ ni Timestamp -> PSQ ni Timestamp
updateStamps curTime stales nodes = foldl' (\q n -> PSQ.insert n curTime q) nodes stales
type BitIx = Word
partitionQ :: Monad f => QueueMethods f elem b -> (elem -> Bool) -> b -> f (b, b)
partitionQ imp test q0 = do
pass0 <- emptyQueue imp
fail0 <- emptyQueue imp
let flipfix a b f = fix f a b
flipfix q0 (pass0,fail0) $ \rec q qs -> do
(mb,q') <- popFront imp q
case mb of
Nothing -> return qs
Just e -> do qs' <- select (pushBack imp e) qs
rec q' qs'
where
select :: Functor f => (b -> f b) -> (b, b) -> f (b, b)
select f = if test e then \(a,b) -> flip (,) b <$> f a
else \(a,b) -> (,) a <$> f b
split :: -- ( Eq ip , Ord (NodeId) , FiniteBits (NodeId)) =>
forall ni s. ( Reifies s (Compare ni) ) =>
(ni -> Word -> Bool)
-> BitIx -> Bucket s ni -> (Bucket s ni, Bucket s ni)
split testNodeIdBit i b = (Bucket ns qs, Bucket ms rs)
where
(ns,ms) = (PSQ.fromList *** PSQ.fromList) . partition (spanBit . coerce . key) . PSQ.toList $ bktNodes b
(qs,rs) = runIdentity $ partitionQ bucketQ (spanBit . snd) $ bktQ b
spanBit :: ni -> Bool
spanBit entry = testNodeIdBit entry i
{-----------------------------------------------------------------------
-- BucketList
-----------------------------------------------------------------------}
defaultBucketCount :: Int
defaultBucketCount = 20
data Info ni nid = Info
{ myBuckets :: BucketList ni
, myNodeId :: nid
, myAddress :: SockAddr
}
deriving Generic
deriving instance (Eq ni, Eq nid) => Eq (Info ni nid)
deriving instance (Show ni, Show nid) => Show (Info ni nid)
-- instance (Eq ip, Serialize ip) => Serialize (Info ip)
-- | The routing table covers the entire 'NodeId' space from 0 to 2 ^
-- 160. The routing table is subdivided into 'Bucket's that each cover
-- a portion of the space. An empty table has one bucket with an ID
-- space range of @min = 0, max = 2 ^ 160@. When a node with ID \"N\"
-- is inserted into the table, it is placed within the bucket that has
-- @min <= N < max@. An empty table has only one bucket so any node
-- must fit within it. Each bucket can only hold 'K' nodes, currently
-- eight, before becoming 'Full'. When a bucket is full of known good
-- nodes, no more nodes may be added unless our own 'NodeId' falls
-- within the range of the 'Bucket'. In that case, the bucket is
-- replaced by two new buckets each with half the range of the old
-- bucket and the nodes from the old bucket are distributed among the
-- two new ones. For a new table with only one bucket, the full bucket
-- is always split into two new buckets covering the ranges @0..2 ^
-- 159@ and @2 ^ 159..2 ^ 160@.
--
data BucketList ni = forall s. Reifies s (Compare ni) =>
BucketList { thisNode :: !ni
, bktCount :: !Int
-- | Non-empty list of buckets.
, buckets :: [Bucket s ni]
}
mapTable :: (b -> t) -> (t -> b) -> BucketList t -> BucketList b
mapTable g f tbl@(BucketList self n bkts) = reify (contramapC g $ bucketCompare bkts)
$ \p -> BucketList
{ thisNode = f self
, bktCount = n
, buckets = map (resolve p . mapBucket f) bkts
}
where
resolve :: Proxy s -> Bucket s ni -> Bucket s ni
resolve = const id
instance (Eq ni) => Eq (BucketList ni) where
(==) = (==) `on` Network.DHT.Routing.toList
#if 0
instance Serialize NominalDiffTime where
put = putWord32be . fromIntegral . fromEnum
get = (toEnum . fromIntegral) <$> getWord32be
#endif
deriving instance (Show ni) => Show (BucketList ni)
#if 0
-- | Normally, routing table should be saved between invocations of
-- the client software. Note that you don't need to store /this/
-- 'NodeId' since it is already included in routing table.
instance (Eq ip, Serialize ip, Ord (NodeId), Serialize (NodeId), Serialize u) => Serialize (BucketList)
#endif
-- | Shape of the table.
instance Pretty (BucketList ni) where
pPrint t
| bucketCount < 6 = hcat $ punctuate ", " $ L.map PP.int ss
| otherwise = brackets $
PP.int (L.sum ss) <> " nodes, " <>
PP.int bucketCount <> " buckets"
where
bucketCount = L.length ss
ss = shape t
-- | Empty table with specified /spine/ node id.
--
-- XXX: The comparison function argument is awkward here.
nullTable :: (ni -> ni -> Ordering) -> ni -> Int -> BucketList ni
nullTable cmp ni n =
reify (Compare cmp)
$ \p -> BucketList
ni
(bucketCount (pred n))
[Bucket (empty p) (runIdentity $ emptyQueue bucketQ)]
where
bucketCount x = max 0 (min 159 x)
empty :: Proxy s -> PSQ (p s ni) t
empty = const $ PSQ.empty
#if 0
-- | Test if table is empty. In this case DHT should start
-- bootstrapping process until table becomes 'full'.
null :: BucketList -> Bool
null (Tip _ _ b) = PSQ.null $ bktNodes b
null _ = False
-- | Test if table have maximum number of nodes. No more nodes can be
-- 'insert'ed, except old ones becomes bad.
full :: BucketList -> Bool
full (Tip _ n _) = n == 0
full (Zero t b) = PSQ.size (bktNodes b) == defaultBucketSize && full t
full (One b t) = PSQ.size (bktNodes b) == defaultBucketSize && full t
-- | Get the /spine/ node id.
thisId :: BucketList -> NodeId
thisId (Tip nid _ _) = nid
thisId (Zero table _) = thisId table
thisId (One _ table) = thisId table
-- | Number of nodes in a bucket or a table.
type NodeCount = Int
#endif
-- | Internally, routing table is similar to list of buckets or a
-- /matrix/ of nodes. This function returns the shape of the matrix.
shape :: BucketList ni -> [Int]
shape (BucketList _ _ tbl) = map (PSQ.size . bktNodes) tbl
#if 0
-- | Get number of nodes in the table.
size :: BucketList -> NodeCount
size = L.sum . shape
-- | Get number of buckets in the table.
depth :: BucketList -> BucketCount
depth = L.length . shape
#endif
lookupBucket :: forall ni nid x.
( FiniteBits nid
, Ord nid
) => (ni -> nid) -> nid -> (forall s. [Bucket s ni] -> x) -> BucketList ni -> x
lookupBucket nodeId nid kont (BucketList self _ bkts) = kont $ go 0 [] bkts
where
d = nid `xor` nodeId self
go :: Word -> [Bucket s ni] -> [Bucket s ni] -> [Bucket s ni]
go i bs (bucket : buckets)
| testIdBit d i = go (succ i) (bucket:bs) buckets
| otherwise = bucket : buckets ++ bs
go _ bs [] = bs
compatibleNodeId :: forall ni nid.
( Serialize nid, FiniteBits nid) =>
(ni -> nid) -> BucketList ni -> IO nid
compatibleNodeId nodeId tbl = genBucketSample prefix br
where
br = bucketRange (L.length (shape tbl) - 1) True
nodeIdSize = finiteBitSize (undefined :: nid) `div` 8
bs = BS.pack $ take nodeIdSize $ tablePrefix (testIdBit . nodeId) tbl ++ repeat 0
prefix = either error id $ S.decode bs
tablePrefix :: (ni -> Word -> Bool) -> BucketList ni -> [Word8]
tablePrefix testbit = map (packByte . take 8 . (++repeat False))
. chunksOf 8
. tableBits testbit
where
packByte = foldl1' (.|.) . zipWith bitmask [7,6 .. 0]
bitmask ix True = bit ix
bitmask _ _ = 0
tableBits :: (ni -> Word -> Bool) -> BucketList ni -> [Bool]
tableBits testbit (BucketList self _ bkts) =
zipWith const (map (testbit self) [0..])
bkts
chunksOf :: Int -> [e] -> [[e]]
chunksOf i ls = map (take i) (build (splitter ls)) where
splitter :: [e] -> ([e] -> a -> a) -> a -> a
splitter [] _ n = n
splitter l c n = l `c` splitter (drop i l) c n
build :: ((a -> [a] -> [a]) -> [a] -> [a]) -> [a]
build g = g (:) []
-- | Count of closest nodes in find_node reply.
type K = Int
-- | Default 'K' is equal to 'defaultBucketSize'.
defaultK :: K
defaultK = 8
#if 0
class TableKey dht k where
toNodeId :: k -> NodeId
instance TableKey dht (NodeId) where
toNodeId = id
#endif
-- | In Kademlia, the distance metric is XOR and the result is
-- interpreted as an unsigned integer.
newtype NodeDistance nodeid = NodeDistance nodeid
deriving (Eq, Ord)
-- | distance(A,B) = |A xor B| Smaller values are closer.
distance :: Bits nid => nid -> nid -> NodeDistance nid
distance a b = NodeDistance $ xor a b
-- | Order by closeness: nearest nodes first.
rank :: ( FiniteBits nid
, Ord nid
) => (x -> nid) -> nid -> [x] -> [x]
rank f nid = L.sortBy (comparing (distance nid . f))
-- | Get a list of /K/ closest nodes using XOR metric. Used in
-- 'find_node' and 'get_peers' queries.
kclosest :: ( FiniteBits nid
, Ord nid
) => (ni -> nid) -> Int -> nid -> BucketList ni -> [ni]
kclosest nodeId k nid tbl = take k $ rank nodeId nid (L.concat bucket)
++ rank nodeId nid (L.concat everyone)
where
(bucket,everyone) =
L.splitAt 1
. lookupBucket nodeId nid (L.map (coerce . L.map PSQ.key . PSQ.toList . bktNodes))
$ tbl
{-----------------------------------------------------------------------
-- Routing
-----------------------------------------------------------------------}
splitTip :: -- ( Eq ip , Ord (NodeId) , FiniteBits (NodeId)) =>
( Reifies s (Compare ni) ) =>
(ni -> Word -> Bool)
-> ni -> Int -> BitIx -> Bucket s ni -> [ Bucket s ni ]
splitTip testNodeBit ni n i bucket
| testNodeBit ni i = [zeros , ones ]
| otherwise = [ones , zeros ]
where
(ones, zeros) = split testNodeBit i bucket
-- | Used in each query.
--
-- TODO: Kademlia non-empty subtrees should should split if they have less than
-- k nodes in them. Which subtrees I mean is illustrated in Fig 1. of Kademlia
-- paper. The rule requiring additional splits is in section 2.4.
modifyBucket
:: -- ( Eq ip , Ord (NodeId) , FiniteBits (NodeId)) =>
forall ni nid xs.
KademliaSpace nid ni
-> nid -> (forall s. Reifies s (Compare ni) => Bucket s ni -> Maybe (xs, Bucket s ni)) -> BucketList ni -> Maybe (xs,BucketList ni)
modifyBucket space nid f (BucketList self n bkts)
= second (BucketList self n) <$> go (0 :: BitIx) bkts
where
d = kademliaXor space nid (kademliaLocation space self)
-- go :: BitIx -> [Bucket s ni] -> Maybe (xs, [Bucket s ni])
go !i (bucket : buckets@(_:_))
| kademliaTestBit space d i = second (bucket :) <$> go (succ i) buckets
| otherwise = second (: buckets) <$> f bucket
go !i [bucket]
| (n == 0) = second (: []) <$> f bucket
| otherwise = second (: []) <$> f bucket
<|> go i (splitTip (kademliaTestBit space . kademliaLocation space) self n i bucket)
-- | Triggering event for atomic table update
data Event ni = TryInsert { foreignNode :: ni }
| PingResult { foreignNode :: ni , ponged :: Bool }
#if 0
deriving instance Eq (NodeId) => Eq (Event)
deriving instance ( Show ip
, Show (NodeId)
, Show u
) => Show (Event)
#endif
eventId :: (ni -> nid) -> Event ni -> nid
eventId nodeId (TryInsert ni) = nodeId ni
eventId nodeId (PingResult ni _) = nodeId ni
-- | Actions requested by atomic table update
data CheckPing ni = CheckPing [ni]
#if 0
deriving instance Eq (NodeId) => Eq (CheckPing)
deriving instance ( Show ip
, Show (NodeId)
, Show u
) => Show (CheckPing)
#endif
-- | Call on every inbound packet (including requested ping results).
-- Returns a triple (was_inserted, to_ping, tbl') where
--
-- [ /was_inserted/ ] True if the node was added to the routing table.
--
-- [ /to_ping/ ] A list of nodes to ping and then run 'updateForPingResult'.
-- This will be empty if /was_inserted/, but a non-inserted node
-- may be added to a replacement queue and will be inserted if
-- one of the items in this list time out.
--
-- [ /tbl'/ ] The updated routing 'BucketList'.
--
updateForInbound ::
KademliaSpace nid ni
-> Timestamp -> ni -> BucketList ni -> (Bool, [ni], BucketList ni)
updateForInbound space tm ni tbl@(BucketList _ _ bkts) =
maybe (False, [],tbl) (\(ps,tbl') -> (True, ps, tbl'))
$ modifyBucket space
(kademliaLocation space ni)
(updateBucketForInbound tm ni)
tbl
-- | Update the routing table with the results of a ping.
--
-- Each (a,(tm,b)) in the returned list indicates that the node /a/ was deleted from the
-- routing table and the node /b/, with timestamp /tm/, has taken its place.
updateForPingResult ::
KademliaSpace nid ni
-> ni -- ^ The pinged node.
-> Bool -- ^ True if we got a reply, False if it timed out.
-> BucketList ni -- ^ The routing table.
-> ( [(ni,Maybe (Timestamp, ni))], BucketList ni )
updateForPingResult space ni got_reply tbl =
fromMaybe ([],tbl)
$ modifyBucket space
(kademliaLocation space ni)
(updateBucketForPingResult ni got_reply)
tbl
{-----------------------------------------------------------------------
-- Conversion
-----------------------------------------------------------------------}
type TableEntry ni = (ni, Timestamp)
tableEntry :: NodeEntry ni -> TableEntry ni
tableEntry (a :-> b) = (a, b)
toList :: BucketList ni -> [[TableEntry ni]]
toList (BucketList _ _ bkts) = coerce $ L.map (L.map tableEntry . PSQ.toList . bktNodes) bkts
data KademliaSpace nid ni = KademliaSpace
{ -- | Given a node record (probably including IP address), yields a
-- kademlia xor-metric location.
kademliaLocation :: ni -> nid
-- | Used when comparing locations. This is similar to
-- 'Data.Bits.testBit' except that the ordering of bits is reversed, so
-- that 0 is the most significant bit.
, kademliaTestBit :: nid -> Word -> Bool
-- | The Kademlia xor-metric.
, kademliaXor :: nid -> nid -> nid
}
contramapKS f ks = ks
{ kademliaLocation = kademliaLocation ks . f
}
|