{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE LambdaCase #-}
{-# LANGUAGE RecordWildCards #-}
{-# LANGUAGE TupleSections #-}

{-# OPTIONS -Wall #-}
{-# OPTIONS -Werror=incomplete-patterns #-}

-- |
-- Module     : Network.DFINITY.RadixTree
-- Copyright  : 2018 DFINITY Stiftung
-- License    : GPL-3
-- Maintainer : Enzo Haussecker <enzo@dfinity.org>
-- Stability  : Stable
--
-- A generic data integrity layer.
module Network.DFINITY.RadixTree (

   -- ** Class
     RadixDatabase(..)

   -- ** Types
   , RadixError(..)
   , RadixRoot
   , RadixTree

   -- ** Create
   , createRadixTree
   , subtreeRadixTree

   -- ** Insert
   , insertRadixTree

   -- ** Delete
   , deleteRadixTree

   -- ** Merkleize
   , merkleizeRadixTree

   -- ** Query
   , lookupRadixTree
   , lookupMerkleizedRadixTree
   , lookupNonMerkleizedRadixTree

   -- ** Test
   , isEmptyRadixTree
   , isValidRadixRoot

   -- ** Stream
   , sourceMerkleizedRadixTree
   , sinkMerkleizedRadixTree

   -- ** Debug
   , contentsRadixTree
   , contentsMerkleizedRadixTree
   , contentsNonMerkleizedRadixTree
   , printRadixTree
   , printMerkleizedRadixTree
   , printNonMerkleizedRadixTree

   ) where

import Codec.Serialise (deserialise, deserialiseOrFail)
import Control.Concurrent (forkIO, killThread)
import Control.Concurrent.BoundedChan (BoundedChan, readChan, tryWriteChan)
import Control.Concurrent.MVar (modifyMVar_, newMVar, readMVar)
import Control.Exception (throw)
import Control.Monad (foldM, forM_, forever, void, when)
import Control.Monad.IO.Class (MonadIO(..))
import Control.Monad.Trans.Resource (MonadResource, ResourceT, allocate, release)
import Crypto.Hash.SHA256 (hash)
import Data.BloomFilter as Bloom (elem, insert, insertList)
import Data.Bool (bool)
import Data.ByteString.Char8 as Byte (ByteString, take)
import Data.ByteString.Lazy (fromStrict)
import Data.ByteString.Short (fromShort, toShort)
import Data.Conduit (ConduitM, await, yield)
import Data.Default.Class (def)
import Data.List as List (delete, foldl', null)
import Data.List.NonEmpty (NonEmpty(..), fromList)
import Data.LruCache as LRU (empty, insert, lookup)
import Data.Map.Strict as Map ((!), delete, empty, insert, keys, lookup, member, null, singleton)
import Data.Maybe (fromJust, isJust, isNothing, listToMaybe)
import Data.Tuple (swap)
import Database.LevelDB (DB)

import Network.DFINITY.RadixTree.Bits
import Network.DFINITY.RadixTree.Bloom
import Network.DFINITY.RadixTree.Lenses
import Network.DFINITY.RadixTree.Memory
import Network.DFINITY.RadixTree.Types
import Network.DFINITY.RadixTree.Utilities

-- |
-- Create a radix tree.
createRadixTree
   :: RadixDatabase m database
   => Int -- ^ Bloom filter size in bits.
   -> Int -- ^ LRU cache size in items.
   -> Maybe RadixRoot -- ^ Previous state root.
   -> database -- ^ Database.
   -> m (RadixTree database)
{-# SPECIALISE createRadixTree
   :: Int
   -> Int
   -> Maybe RadixRoot
   -> DB
   -> ResourceT IO (RadixTree DB) #-}
createRadixTree bloomSize cacheSize checkpoint database
   | bloomSize <= 0 = throw $ InvalidArgument "invalid Bloom filter size"
   | cacheSize <= 0 = throw $ InvalidArgument "invalid LRU cache size"
   | otherwise = do
      (root, cache') <-
         case checkpoint of
            Nothing -> storeCold def cache database
            Just root -> do
               result <- loadCold root cache database
               case snd <$> result of
                  Nothing -> throw $ StateRootDoesNotExist root
                  Just cache' -> pure (root, cache')
      pure $ RadixTree bloom bloomSize Map.empty cache' cacheSize root database 0 root
      where
      bloom = emptyRadixBloom bloomSize
      cache = LRU.empty cacheSize

-- |
-- Create a radix tree from a radix tree.
subtreeRadixTree
   :: RadixDatabase m database
   => RadixRoot -- ^ State root.
   -> RadixTree database -- ^ Radix tree.
   -> m (RadixTree database)
{-# SPECIALISE subtreeRadixTree
   :: RadixRoot
   -> RadixTree DB
   -> ResourceT IO (RadixTree DB) #-}
subtreeRadixTree root RadixTree {..} = do
   result <- loadCold root cache _radixDatabase
   case result of
      Nothing -> throw $ StateRootDoesNotExist root
      _ -> pure $ RadixTree bloom _radixBloomSize Map.empty cache _radixCacheSize root _radixDatabase 0 root
      where
      bloom = emptyRadixBloom _radixBloomSize
      cache = LRU.empty _radixCacheSize

-- |
-- Check if a radix tree is empty.
isEmptyRadixTree
   :: RadixTree database -- ^ Radix tree.
   -> Bool
{-# INLINABLE isEmptyRadixTree #-}
isEmptyRadixTree = (==) defaultRoot . _radixRoot

-- |
-- Check if a state root is valid.
isValidRadixRoot
   :: RadixDatabase m database
   => RadixRoot -- ^ State root.
   -> RadixTree database -- ^ Radix tree.
   -> m Bool
{-# SPECIALISE isValidRadixRoot
   :: RadixRoot
   -> RadixTree DB
   -> ResourceT IO Bool #-}
isValidRadixRoot root RadixTree {..} =
   isJust <$> load _radixDatabase key
   where
   key = fromShort root

-- |
-- Search for a value in a radix tree.
searchRadixTree
   :: RadixDatabase m database
   => Bool -- ^ Overwrite state root?
   -> (RadixTree database -> m (Maybe (RadixNode, RadixCache))) -- ^ Loading strategy.
   -> ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Either RadixError RadixSearchResult)
{-# SPECIALISE searchRadixTree
   :: Bool
   -> (RadixTree DB -> ResourceT IO (Maybe (RadixNode, RadixCache)))
   -> ByteString
   -> RadixTree DB
   -> ResourceT IO (Either RadixError RadixSearchResult) #-}
searchRadixTree flag strategy = \ key tree@RadixTree {..} -> do
   let key' = toBits key
   let tree' = tree `bool` setRoot _radixCheckpoint tree $ flag
   loop Nothing [] [] [] key' tree' where
   loop implicit roots nodes prefixes key tree@RadixTree {..} = do
      -- Load the root node.
      result <- strategy tree
      case result of
         Nothing -> pure $ Left $ StateRootDoesNotExist _radixRoot
         Just (node@RadixNode {..}, cache') -> do
            -- Calculate the prefix and overflow.
            let bits = maybe id (:) implicit $ maybe [] toBits _radixPrefix
            let prefix = matchBits bits key
            let n = length prefix
            let overflow = drop n bits
            -- Update the accumulators.
            let roots' = _radixRoot:roots
            let nodes' = node:nodes
            let prefixes' = prefix:prefixes
            let key' = drop n key
            -- Check the termination criteria.
            let residue = not $ List.null overflow
            let bit = head key'
            let child = bool _radixLeft _radixRight bit
            if List.null key' || residue || isNothing child
            then pure $ Right (fromList roots', fromList nodes', fromList prefixes', overflow, key', cache')
            else do
               -- Recurse.
               let root' = fromJust child
               let tree' = setCache cache' $ setRoot root' tree
               let implicit' = Just bit
               loop implicit' roots' nodes' prefixes' key' tree'

-- |
-- Search for a value in a Merkleized radix tree.
searchMerkleizedRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Either RadixError RadixSearchResult)
{-# SPECIALISE searchMerkleizedRadixTree
   :: ByteString
   -> RadixTree DB
   -> ResourceT IO (Either RadixError RadixSearchResult) #-}
searchMerkleizedRadixTree =
   searchRadixTree True $ \ RadixTree {..} ->
      loadCold _radixRoot _radixCache _radixDatabase

-- |
-- Search for a value in a non-Merkleized radix tree.
searchNonMerkleizedRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Either RadixError RadixSearchResult)
{-# SPECIALISE searchNonMerkleizedRadixTree
   :: ByteString
   -> RadixTree DB
   -> ResourceT IO (Either RadixError RadixSearchResult) #-}
searchNonMerkleizedRadixTree =
   searchRadixTree False $ \ RadixTree {..} ->
      loadHot _radixRoot _radixBuffer _radixCache _radixDatabase

-- |
-- Insert a key and value into a radix tree.
insertRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> m (RadixTree database)
{-# SPECIALISE insertRadixTree
   :: ByteString
   -> ByteString
   -> RadixTree DB
   -> ResourceT IO (RadixTree DB) #-}
insertRadixTree key value tree =
   if isEmptyRadixTree tree
   then pure $ initializeRadixTree key value tree
   else searchNonMerkleizedRadixTree key tree >>= \ case
      Left err -> throw err
      Right result@(_, _, _, [], [], _) ->
         pure $ insertRadixTreeAt result value tree
      Right result@(_, _, _, [], _, _) ->
         pure $ insertRadixTreeAfter result value tree
      Right result@(_, _, _, _, [], _) ->
         pure $ insertRadixTreeBefore result value tree
      Right result ->
         pure $ insertRadixTreeBetween result value tree

-- TODO (enzo): Documentation.
initializeRadixTree
   :: ByteString -- ^ Key.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE initializeRadixTree #-}
initializeRadixTree key value tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setNonce nonce $ setRoot root tree
   where
   prefix = createPrefix $ toBits key
   node = setPrefix prefix $ Just value `setLeaf` def
   root = createRootFromNonce _radixNonce
   bloom = Bloom.insert root _radixBloom
   nonce = _radixNonce + 1
   buffer = storeHot root node _radixBuffer

-- TODO (enzo): Documentation.
insertRadixTreeAt
   :: RadixSearchResult -- ^ Search result.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE insertRadixTreeAt #-}
insertRadixTreeAt (_:|roots, node:|nodes, prefix:|_, _, _, cache) value tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   node' = Just value `setLeaf` node
   root' = createRootFromNonce _radixNonce
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root':roots
   buffer = merkleSpoof root' parent $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 1
   state = bool _radixRoot root' $ isNothing parent

-- TODO (enzo): Documentation.
insertRadixTreeAfter
   :: RadixSearchResult -- ^ Search result.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE insertRadixTreeAfter #-}
insertRadixTreeAfter (_:|roots, node:|nodes, prefix:|_, _, keyOverflow, cache) value tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   prefix' = createPrefix $ drop 1 keyOverflow
   node' = setPrefix prefix' $ Just value `setLeaf` def
   root' = createRootFromNonce _radixNonce
   node'' = test `setChild` Just root' $ node
   root'' = createRootFromNonce $ _radixNonce + 1
   test = head keyOverflow
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root'':root':roots
   buffer = merkleSpoof root'' parent $ storeHot root'' node'' $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 2
   state = bool _radixRoot root'' $ isNothing parent

-- TODO (enzo): Documentation.
insertRadixTreeBefore
   :: RadixSearchResult -- ^ Search result.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE insertRadixTreeBefore #-}
insertRadixTreeBefore (_:|roots, node:|nodes, prefix:|_, prefixOverflow, _, cache) value tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   prefix' = createPrefix $ drop 1 prefixOverflow
   node' = setPrefix prefix' node
   root' = createRootFromNonce _radixNonce
   prefix'' = createPrefix $ drop 1 prefix `bool` prefix $ isNothing parent
   node'' = setPrefix prefix'' $ test `setChild` Just root' $ Just value `setLeaf` def
   root'' = createRootFromNonce $ _radixNonce + 1
   test = head prefixOverflow
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root'':root':roots
   buffer = merkleSpoof root'' parent $ storeHot root'' node'' $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 2
   state = bool _radixRoot root'' $ isNothing parent

-- TODO (enzo): Documentation.
insertRadixTreeBetween
   :: RadixSearchResult -- ^ Search result.
   -> ByteString -- ^ Value.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE insertRadixTreeBetween #-}
insertRadixTreeBetween (_:|roots, node:|nodes, prefix:|_, prefixOverflow, keyOverflow, cache) value tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   prefix' = createPrefix $ drop 1 keyOverflow
   node' = setPrefix prefix' $ Just value `setLeaf` def
   root' = createRootFromNonce _radixNonce
   prefix'' = createPrefix $ drop 1 prefixOverflow
   node'' = setPrefix prefix'' node
   root'' = createRootFromNonce $ _radixNonce + 1
   prefix''' = createPrefix $ drop 1 prefix `bool` prefix $ isNothing parent
   node''' = setPrefix prefix''' $ setChildren children def
   root''' = createRootFromNonce $ _radixNonce + 2
   test = head keyOverflow
   children = bool id swap test (Just root', Just root'')
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root''':root'':root':roots
   buffer = merkleSpoof root''' parent $ storeHot root''' node''' $ storeHot root'' node'' $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 3
   state = bool _radixRoot root''' $ isNothing parent

-- |
-- Delete a value from a radix tree.
deleteRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (RadixTree database)
{-# SPECIALISE deleteRadixTree
   :: ByteString
   -> RadixTree DB
   -> ResourceT IO (RadixTree DB) #-}
deleteRadixTree key tree@RadixTree {..} =
   if isEmptyRadixTree tree
   then pure tree
   else searchNonMerkleizedRadixTree key tree >>= \ case
      Left err -> throw err
      Right result@(_, nodes, prefix:|_, [], [], cache) ->
         case nodes of
            -- No children and no parent.
            RadixNode _ Nothing Nothing _:|[] ->
               pure $ deleteRadixTreeNoChildrenNoParent result tree
            -- No children and parent with leaf.
            RadixNode _ Nothing Nothing _:|parent:_ | isJust $ getLeaf parent ->
               pure $ deleteRadixTreeNoChildrenParentWithLeaf result tree
            -- No children and parent without leaf.
            RadixNode _ Nothing Nothing _:|parent:_ -> do
               let test = not $ head prefix
               let root = fromJust $ getChild test parent
               loadHot root _radixBuffer cache _radixDatabase >>= \ case
                  Nothing -> throw $ StateRootDoesNotExist root
                  Just (node, cache') ->
                     pure $ deleteRadixTreeNoChildrenParentWithoutLeaf result node cache' test tree
            -- One left child.
            RadixNode _ child Nothing _:|_ | isJust child -> do
               let test = False
               let root = fromJust child
               loadHot root _radixBuffer cache _radixDatabase >>= \ case
                  Nothing -> throw $ StateRootDoesNotExist root
                  Just (node, cache') ->
                     pure $ deleteRadixTreeOneChild result node cache' test tree
            -- One right child.
            RadixNode _ Nothing child _:|_ | isJust child -> do
               let test = True
               let root = fromJust child
               loadHot root _radixBuffer cache _radixDatabase >>= \ case
                  Nothing -> throw $ StateRootDoesNotExist root
                  Just (node, cache') ->
                     pure $ deleteRadixTreeOneChild result node cache' test tree
            -- Two children.
            _ -> pure $ deleteRadixTreeTwoChildren result tree
      Right _ -> pure tree

-- TODO (enzo): Documentation.
deleteRadixTreeNoChildrenNoParent
   :: RadixSearchResult -- ^ Search result.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE deleteRadixTreeNoChildrenNoParent #-}
deleteRadixTreeNoChildrenNoParent (_, _, _, _, _, cache) tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setRoot state tree
   where
   bloom = Bloom.insert defaultRoot _radixBloom
   buffer = storeHot defaultRoot def _radixBuffer
   state = defaultRoot

-- TODO (enzo): Documentation.
deleteRadixTreeNoChildrenParentWithLeaf
   :: RadixSearchResult -- ^ Search result.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE deleteRadixTreeNoChildrenParentWithLeaf #-}
deleteRadixTreeNoChildrenParentWithLeaf (_:|_:roots, _:|node:nodes, prefix:|prefixes, _, _, cache) tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   node' = setChild test Nothing node
   root' = createRootFromNonce _radixNonce
   test = head prefix
   parent = listToMaybe $ zip3 roots nodes $ map head prefixes
   bloom = flip insertList _radixBloom $ root':roots
   buffer = merkleSpoof root' parent $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 1
   state = bool _radixRoot root' $ isNothing parent
deleteRadixTreeNoChildrenParentWithLeaf _ _ =
   throw $ InvalidArgument "unknown parent"

-- TODO (enzo): Documentation.
deleteRadixTreeNoChildrenParentWithoutLeaf
   :: RadixSearchResult -- ^ Search result.
   -> RadixNode -- ^ Radix node.
   -> RadixCache -- ^ Radix cache.
   -> Bool -- ^ Lineage.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE deleteRadixTreeNoChildrenParentWithoutLeaf #-}
deleteRadixTreeNoChildrenParentWithoutLeaf (_:|_:roots, _:|_:nodes, _:|prefixes, _, _, _) node@RadixNode {..} cache test tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   prefix' = createPrefix $ drop 1 bits `bool` bits $ isNothing parent
   node' = setPrefix prefix' node
   root' = createRootFromNonce _radixNonce
   bits = head prefixes ++ test:maybe [] toBits _radixPrefix
   parent = listToMaybe $ zip3 roots nodes $ map head prefixes
   bloom = flip insertList _radixBloom $ root':roots
   buffer = merkleSpoof root' parent $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 1
   state = bool _radixRoot root' $ isNothing parent
deleteRadixTreeNoChildrenParentWithoutLeaf _ _ _ _ _ =
   throw $ InvalidArgument "unknown parent"

-- TODO (enzo): Documentation.
deleteRadixTreeOneChild
   :: RadixSearchResult -- ^ Search result.
   -> RadixNode -- ^ Radix node.
   -> RadixCache -- ^ Radix cache.
   -> Bool -- ^ Lineage.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE deleteRadixTreeOneChild #-}
deleteRadixTreeOneChild (_:|roots, _:|nodes, prefix:|_, _, _, _) node@RadixNode {..} cache test tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   prefix' = createPrefix $ drop 1 bits `bool` bits $ isNothing parent
   node' = setPrefix prefix' node
   root' = createRootFromNonce _radixNonce
   bits = prefix ++ test:maybe [] toBits _radixPrefix
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root':roots
   buffer = merkleSpoof root' parent $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 1
   state = bool _radixRoot root' $ isNothing parent

-- TODO (enzo): Documentation.
deleteRadixTreeTwoChildren
   :: RadixSearchResult -- ^ Search result.
   -> RadixTree database -- ^ Radix tree.
   -> RadixTree database
{-# INLINABLE deleteRadixTreeTwoChildren #-}
deleteRadixTreeTwoChildren (_:|roots, node:|nodes, prefix:|_, _, _, cache) tree@RadixTree {..} =
   seq bloom $ setBloom bloom $ setBuffer buffer $ setCache cache $ setNonce nonce $ setRoot state tree
   where
   node' = setLeaf Nothing node
   root' = createRootFromNonce _radixNonce
   parent = listToMaybe $ zip3 roots nodes prefix
   bloom = flip insertList _radixBloom $ root':roots
   buffer = merkleSpoof root' parent $ storeHot root' node' _radixBuffer
   nonce = _radixNonce + 1
   state = bool _radixRoot root' $ isNothing parent

-- |
-- Lookup a value in a radix tree.
lookupRadixTree'
   :: RadixDatabase m database
   => (ByteString -> RadixTree database -> m (Either RadixError RadixSearchResult)) -- ^ Search algorithm.
   -> ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Maybe (ByteString, RadixTree database))
{-# SPECIALISE lookupRadixTree'
   :: (ByteString -> RadixTree DB -> ResourceT IO (Either RadixError RadixSearchResult))
   -> ByteString
   -> RadixTree DB
   -> ResourceT IO (Maybe (ByteString, RadixTree DB)) #-}
lookupRadixTree' search key tree = do
   found <- search key tree
   case found of
      Left err -> throw err
      Right (_, RadixNode {..}:|_, _, prefixOverflow, keyOverflow, cache') ->
         if not $ List.null prefixOverflow && List.null keyOverflow
         then pure Nothing
         else pure $ do
            value <- _radixLeaf
            let tree' = setCache cache' tree
            pure (value, tree')

-- |
-- A convenient alias for `lookupNonMerkleizedRadixTree`.
lookupRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Maybe (ByteString, RadixTree database))
{-# SPECIALISE lookupRadixTree
   :: ByteString
   -> RadixTree DB
   -> ResourceT IO (Maybe (ByteString, RadixTree DB)) #-}
lookupRadixTree = lookupNonMerkleizedRadixTree

-- |
-- Lookup a value in a Merkleized radix tree.
lookupMerkleizedRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Maybe (ByteString, RadixTree database))
{-# DEPRECATED lookupMerkleizedRadixTree "The function is will be removed in the next release. Please use 'lookupRadixTree' instead." #-}
lookupMerkleizedRadixTree = lookupRadixTree' searchMerkleizedRadixTree

-- |
-- Lookup a value in a non-Merkleized radix tree.
lookupNonMerkleizedRadixTree
   :: RadixDatabase m database
   => ByteString -- ^ Key.
   -> RadixTree database -- ^ Radix tree.
   -> m (Maybe (ByteString, RadixTree database))
{-# SPECIALISE lookupNonMerkleizedRadixTree
   :: ByteString
   -> RadixTree DB
   -> ResourceT IO (Maybe (ByteString, RadixTree DB)) #-}
lookupNonMerkleizedRadixTree = lookupRadixTree' searchNonMerkleizedRadixTree

-- |
-- Mask a node in a Merkleized radix tree.
merkleSpoof
   :: RadixRoot -- ^ State root.
   -> Maybe (RadixRoot, RadixNode, Bool) -- ^ Parent.
   -> RadixBuffer -- ^ Buffer.
   -> RadixBuffer
{-# INLINABLE merkleSpoof #-}
merkleSpoof mask = \ case
   Nothing -> id
   Just (root, node, test) ->
      storeHot root $ test `setChild` Just mask $ node

-- |
-- Merkleize a radix tree. This will flush the buffer to disk.
merkleizeRadixTree
   :: RadixDatabase m database
   => RadixTree database-- ^ Radix tree.
   -> m (RadixRoot, RadixTree database)
{-# SPECIALISE merkleizeRadixTree
   :: RadixTree DB
   -> ResourceT IO (RadixRoot, RadixTree DB) #-}
merkleizeRadixTree RadixTree {..} = do
   (root, cache) <- loop _radixRoot _radixCache
   let tree = RadixTree bloom _radixBloomSize Map.empty cache _radixCacheSize root _radixDatabase 0 root
   pure (root, tree)
   where
   bloom = emptyRadixBloom _radixBloomSize
   loop root cache =
      if not $ Bloom.elem root _radixBloom
      then pure (root, cache)
      else do
         -- Load the root node.
         result <- loadHot root _radixBuffer cache _radixDatabase
         case result of
            Nothing -> throw $ StateRootDoesNotExist root
            Just (node@RadixNode {..}, cache') ->
               case (_radixLeft, _radixRight) of
                  -- No children.
                  (Nothing, Nothing) ->
                     storeCold node cache' _radixDatabase
                  -- One left child.
                  (Just child, Nothing) -> do
                     (root', cache'') <- loop child cache'
                     let node' = False `setChild` Just root' $ node
                     storeCold node' cache'' _radixDatabase
                  -- One right child.
                  (Nothing, Just child) -> do
                     (root', cache'') <- loop child cache'
                     let node' = True `setChild` Just root' $ node
                     storeCold node' cache'' _radixDatabase
                  -- Two children.
                  (Just left, Just right) -> do
                     (root', cache'') <- loop left cache'
                     (root'', cache''') <- loop right cache''
                     let node' = setChildren (Just root', Just root'') node
                     storeCold node' cache''' _radixDatabase

-- |
-- Create a conduit from a Merkleized radix tree.
sourceMerkleizedRadixTree
   :: MonadResource m
   => RadixDatabase (ConduitM () ByteString m) database
   => [Bool] -- ^ Bit mask.
   -> Int -- ^ LRU cache size in items.
   -> BoundedChan RadixRoot -- ^ Terminal state root producer.
   -> RadixTree database -- ^ Radix tree.
   -> ConduitM () ByteString m ()
{-# SPECIALISE sourceMerkleizedRadixTree
   :: [Bool]
   -> Int
   -> BoundedChan RadixRoot
   -> RadixTree DB
   -> ConduitM () ByteString (ResourceT IO) () #-}
sourceMerkleizedRadixTree mask cacheSize chan
   | cacheSize <= 0 = throw $ InvalidArgument "invalid LRU cache size"
   | otherwise = \ tree -> do
      cache <- liftIO $ newMVar $ LRU.empty cacheSize
      (,) action _ <- flip allocate killThread $ forkIO $ forever $ do
         root <- readChan chan
         modifyMVar_ cache $ pure . LRU.insert root ()
      loop cache tree []
      release action
      where
      loop cache tree@RadixTree {..} roots = do
         seen <- liftIO $ readMVar cache
         let roots' = _radixCheckpoint:roots
         if flip any roots' $ isJust . flip LRU.lookup seen
         then pure ()
         else do
            let key = fromShort _radixCheckpoint
            result <- load _radixDatabase key
            case result of
               Nothing -> pure ()
               Just bytes -> do
                  let RadixNode {..} = deserialise $ fromStrict bytes
                  let success = all id $ zipWith (==) mask $ toBits $ fromShort _radixCheckpoint
                  when success $ yield bytes
                  forM_ [_radixLeft, _radixRight] $ \ case
                     Nothing -> pure ()
                     Just root -> loop cache `flip` roots' $ setCheckpoint root tree

-- |
-- Create a Merkleized radix tree from a conduit.
sinkMerkleizedRadixTree
   :: MonadResource m
   => RadixDatabase (ConduitM ByteString () m) database
   => RadixRoot -- ^ Target state root.
   -> BoundedChan RadixRoot -- ^ Terminal state root consumer.
   -> RadixTree database -- ^ Radix tree.
   -> ConduitM ByteString () m (Either [RadixRoot] (RadixTree database))
{-# SPECIALISE sinkMerkleizedRadixTree
   :: RadixRoot
   -> BoundedChan RadixRoot
   -> RadixTree DB
   -> ConduitM ByteString () (ResourceT IO) (Either [RadixRoot] (RadixTree DB)) #-}
sinkMerkleizedRadixTree checkpoint chan tree@RadixTree {..} =
   loop1 Map.empty $ singleton checkpoint Nothing where
   loop1 = \ buffer want ->
      if Map.null want
      then pure $ Right $ setCheckpoint checkpoint $ setRoot checkpoint tree
      else await >>= \ case
         Nothing -> pure $ Left $ keys want
         Just bytes ->
            case deserialiseOrFail $ fromStrict bytes of
               Right RadixNode {..} -> do
                  let key = Byte.take 20 $ hash bytes
                  let root = toShort key
                  let wanted = member root want
                  exists <- if wanted
                     then pure False
                     else isJust <$> load _radixDatabase key
                  if exists
                  then loop1 buffer $ Map.delete root want
                  else do
                     children <- foldM step [] $ maybe id (:) _radixLeft $ maybe id (:) _radixRight []
                     let buffer' = Map.insert root (key, bytes, children) buffer
                     if not wanted
                     then loop1 buffer' want
                     else loop3 buffer' `uncurry` loop2 buffer' (want, []) root
               _ -> loop1 buffer want
      where
      step accum root = do
         valid <- isValidRadixRoot root tree
         if valid
         then pure accum
         else pure $ root:accum
   loop2 buffer accum@(want, candidates) root =
      case Map.lookup root buffer of
         Nothing -> accum
         Just (key, bytes, []) -> (want, (root, key, bytes):candidates)
         Just (_, _, children) ->
            let want' = foldr step want children
            in foldl' (loop2 buffer) (want', candidates) children
      where
      step = flip Map.insert $ Just root
   loop3 buffer want = \ case
      [] -> loop1 buffer want
      (root, key, bytes):candidates -> do
         store _radixDatabase key bytes
         let buffer' = Map.delete root buffer
         case want ! root of
            Nothing -> do
               let want' = Map.delete root want
               loop1 buffer' want'
            Just root' -> do
               let want' = Map.delete root want
               let (key', bytes', siblings') = buffer ! root'
               let children' = List.delete root siblings'
               if List.null children'
               then loop3 buffer' want' $ (root', key', bytes'):candidates
               else do
                  let buffer'' = Map.insert root' (key', bytes', children') buffer'
                  liftIO $ void $ tryWriteChan chan root
                  loop3 buffer'' want' candidates

-- |
-- Get the contents of a radix tree.
contentsRadixTree'
   :: RadixDatabase m database
   => Bool -- ^ Overwrite state root?
   -> (RadixTree database -> m (Maybe (RadixNode, RadixCache))) -- ^ Loading strategy.
   -> RadixTree database -- ^ Radix tree.
   -> m [(ByteString, ByteString)]
{-# SPECIALISE contentsRadixTree'
   :: Bool
   -> (RadixTree DB -> ResourceT IO (Maybe (RadixNode, RadixCache)))
   -> RadixTree DB
   -> ResourceT IO [(ByteString, ByteString)] #-}
contentsRadixTree' flag strategy = \ tree@RadixTree {..} -> do
   let tree' = tree `bool` setRoot _radixCheckpoint tree $ flag
   loop tree' [] [] where
   loop tree@RadixTree {..} prefix accum = do
      result <- strategy tree
      case fst <$> result of
         Nothing -> throw $ StateRootDoesNotExist _radixRoot
         Just RadixNode {..} -> do
            let prefix' = prefix ++ maybe [] toBits _radixPrefix
            let key = fromBits prefix'
            let accum' = maybe accum (\ value -> (key, value):accum) _radixLeaf
            let children = [(,False) <$> _radixLeft, (,True) <$> _radixRight]
            flip foldM accum' `flip` children $ \ accum'' -> \ case
               Nothing -> pure accum''
               Just (root, test) -> do
                  let tree' = setRoot root tree
                  let prefix'' = prefix' ++ [test]
                  loop tree' prefix'' accum''

-- |
-- A convenient alias for `contentsNonMerkleizedRadixTree`.
contentsRadixTree
   :: RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m [(ByteString, ByteString)]
{-# SPECIALISE contentsRadixTree
   :: RadixTree DB
   -> ResourceT IO [(ByteString, ByteString)] #-}
contentsRadixTree = contentsNonMerkleizedRadixTree

-- |
-- Get the contents of a Merkleized radix tree.
contentsMerkleizedRadixTree
   :: RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m [(ByteString, ByteString)]
{-# SPECIALISE contentsMerkleizedRadixTree
   :: RadixTree DB
   -> ResourceT IO [(ByteString, ByteString)] #-}
contentsMerkleizedRadixTree =
   contentsRadixTree' True $ \ RadixTree {..} ->
      loadCold _radixRoot _radixCache _radixDatabase

-- |
-- Get the contents of a non-Merkleized radix tree.
contentsNonMerkleizedRadixTree
   :: RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m [(ByteString, ByteString)]
{-# SPECIALISE contentsNonMerkleizedRadixTree
   :: RadixTree DB
   -> ResourceT IO [(ByteString, ByteString)] #-}
contentsNonMerkleizedRadixTree =
   contentsRadixTree' False $ \ RadixTree {..} ->
      loadHot _radixRoot _radixBuffer _radixCache _radixDatabase

-- |
-- Print a radix tree.
printRadixTree'
   :: MonadIO m
   => RadixDatabase m database
   => Bool -- ^ Overwrite state root?
   -> (RadixTree database -> m (Maybe (RadixNode, RadixCache))) -- ^ Loading strategy.
   -> RadixTree database -- ^ Radix tree.
   -> m ()
{-# SPECIALISE printRadixTree'
   :: Bool
   -> (RadixTree DB -> ResourceT IO (Maybe (RadixNode, RadixCache)))
   -> RadixTree DB
   -> ResourceT IO () #-}
printRadixTree' flag strategy = \ tree@RadixTree {..} -> do
   let tree' = tree `bool` setRoot _radixCheckpoint tree $ flag
   loop tree' 0 where
   loop tree@RadixTree {..} i = do
      result <- strategy tree
      case fst <$> result of
         Nothing -> throw $ StateRootDoesNotExist _radixRoot
         Just node@RadixNode {..} -> do
            let indent = (++) $ concat $ replicate i "|"
            liftIO $ putStrLn $ indent $ show node
            let j = i + 1
            forM_ [_radixLeft, _radixRight] $ \ case
               Nothing -> pure ()
               Just root -> setRoot root tree `loop` j

-- |
-- A convenient alias for `printNonMerkleizedRadixTree`.
printRadixTree
   :: MonadIO m
   => RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m ()
{-# SPECIALISE printRadixTree
   :: RadixTree DB
   -> ResourceT IO () #-}
printRadixTree = printNonMerkleizedRadixTree

-- |
-- Print a Merkleized radix tree.
printMerkleizedRadixTree
   :: MonadIO m
   => RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m ()
{-# SPECIALISE printMerkleizedRadixTree
   :: RadixTree DB
   -> ResourceT IO () #-}
printMerkleizedRadixTree =
   printRadixTree' True $ \ RadixTree {..} ->
      loadCold _radixRoot _radixCache _radixDatabase

-- |
-- Print a non-Merkleized radix tree.
printNonMerkleizedRadixTree
   :: MonadIO m
   => RadixDatabase m database
   => RadixTree database -- ^ Radix tree.
   -> m ()
{-# SPECIALISE printNonMerkleizedRadixTree
   :: RadixTree DB
   -> ResourceT IO () #-}
printNonMerkleizedRadixTree =
   printRadixTree' False $ \ RadixTree {..} ->
      loadHot _radixRoot _radixBuffer _radixCache _radixDatabase