client.rs

							warn!("   Native result {:?}", native_result);
							warn!("   Wasm result {:?}", wasm_result);
							telemetry!(SUBSTRATE_INFO; "block.execute.consensus_failure";
								"hash" => ?hash,
								"origin" => ?origin,
								"header" => ?header
							);
							wasm_result
						}),
					}
				};
				let (_, storage_update, changes_update) = self.executor.call_at_state::<_, _, _, NeverNativeValue, fn() -> _>(
					transaction_state,
					&mut overlay,
					"Core_execute_block",
					&<Block as BlockT>::new(import_headers.pre().clone(), body.unwrap_or_default()).encode(),
					match origin {
						BlockOrigin::NetworkInitialSync => get_execution_manager(self.execution_strategies().syncing),
						_ => get_execution_manager(self.execution_strategies().importing),
					},
					None,
					NeverOffchainExt::new(),
				)?;

				overlay.commit_prospective();

				let (top, children) = overlay.into_committed();
				let children = children.map(|(sk, it)| (sk, it.collect())).collect();
				if import_headers.post().state_root() != &storage_update.1 {
					return Err(error::Error::InvalidStateRoot);
				}

				Ok((Some(storage_update.0), Some(changes_update), Some((top.collect(), children))))
			},
			None => Ok((None, None, None))
		}
	}

	fn apply_finality_with_block_hash(
		&self,
		operation: &mut ClientImportOperation<Block, Blake2Hasher, B>,
		block: Block::Hash,
		justification: Option<Justification>,
		best_block: Block::Hash,
		notify: bool,
	) -> error::Result<()> {
		// find tree route from last finalized to given block.
		let last_finalized = self.backend.blockchain().last_finalized()?;

		if block == last_finalized {
			warn!("Possible safety violation: attempted to re-finalize last finalized block {:?} ", last_finalized);
			return Ok(());
		}

		let route_from_finalized = crate::blockchain::tree_route(
			self.backend.blockchain(),
			BlockId::Hash(last_finalized),
			BlockId::Hash(block),
		)?;

		if let Some(retracted) = route_from_finalized.retracted().get(0) {
			warn!("Safety violation: attempted to revert finalized block {:?} which is not in the \
				same chain as last finalized {:?}", retracted, last_finalized);

			return Err(error::Error::NotInFinalizedChain);
		}

		let route_from_best = crate::blockchain::tree_route(
			self.backend.blockchain(),
			BlockId::Hash(best_block),
			BlockId::Hash(block),
		)?;

		// if the block is not a direct ancestor of the current best chain,
		// then some other block is the common ancestor.
		if route_from_best.common_block().hash != block {
			// NOTE: we're setting the finalized block as best block, this might
			// be slightly innacurate since we might have a "better" block
			// further along this chain, but since best chain selection logic is
			// pluggable we cannot make a better choice here. usages that need
			// an accurate "best" block need to go through `SelectChain`
			// instead.
			operation.op.mark_head(BlockId::Hash(block))?;
		}

		let enacted = route_from_finalized.enacted();
		assert!(enacted.len() > 0);
		for finalize_new in &enacted[..enacted.len() - 1] {
			operation.op.mark_finalized(BlockId::Hash(finalize_new.hash), None)?;
		}

		assert_eq!(enacted.last().map(|e| e.hash), Some(block));
		operation.op.mark_finalized(BlockId::Hash(block), justification)?;

		if notify {
			// sometimes when syncing, tons of blocks can be finalized at once.
			// we'll send notifications spuriously in that case.
			const MAX_TO_NOTIFY: usize = 256;
			let enacted = route_from_finalized.enacted();
			let start = enacted.len() - ::std::cmp::min(enacted.len(), MAX_TO_NOTIFY);
			for finalized in &enacted[start..] {
				operation.notify_finalized.push(finalized.hash);
			}
		}

		Ok(())
	}

	fn notify_finalized(
		&self,
		notify_finalized: Vec<Block::Hash>,
	) -> error::Result<()> {
		let mut sinks = self.finality_notification_sinks.lock();

		for finalized_hash in notify_finalized {
			let header = self.header(&BlockId::Hash(finalized_hash))?
				.expect("header already known to exist in DB because it is indicated in the tree route; qed");

			telemetry!(SUBSTRATE_INFO; "notify.finalized";
				"height" => format!("{}", header.number()),
				"best" => ?finalized_hash,
			);

			let notification = FinalityNotification {
				header,
				hash: finalized_hash,
			};

			sinks.retain(|sink| sink.unbounded_send(notification.clone()).is_ok());
		}

		Ok(())
	}

	fn notify_imported(
		&self,
		notify_import: (
			Block::Hash, BlockOrigin,
			Block::Header,
			bool,
			Option<(
				Vec<(Vec<u8>, Option<Vec<u8>>)>,
				Vec<(Vec<u8>, Vec<(Vec<u8>, Option<Vec<u8>>)>)>,
				)
			>),
	) -> error::Result<()> {
		let (hash, origin, header, is_new_best, storage_changes) = notify_import;

		if let Some(storage_changes) = storage_changes {
			// TODO [ToDr] How to handle re-orgs? Should we re-emit all storage changes?
			self.storage_notifications.lock()
				.trigger(
					&hash,
					storage_changes.0.into_iter(),
					storage_changes.1.into_iter().map(|(sk, v)| (sk, v.into_iter())),
				);
		}

		let notification = BlockImportNotification::<Block> {
			hash,
			origin,
			header,
			is_new_best,
		};

		self.import_notification_sinks.lock()
			.retain(|sink| sink.unbounded_send(notification.clone()).is_ok());

		Ok(())
	}

	/// Apply auxiliary data insertion into an operation.
	pub fn apply_aux<
		'a,
		'b: 'a,
		'c: 'a,
		I: IntoIterator<Item=&'a(&'c [u8], &'c [u8])>,
		D: IntoIterator<Item=&'a &'b [u8]>,
	>(
		&self,
		operation: &mut ClientImportOperation<Block, Blake2Hasher, B>,
		insert: I,
		delete: D
	) -> error::Result<()> {
		operation.op.insert_aux(
			insert.into_iter()
				.map(|(k, v)| (k.to_vec(), Some(v.to_vec())))
				.chain(delete.into_iter().map(|k| (k.to_vec(), None)))
		)
	}

	/// Mark all blocks up to given as finalized in operation. If a
	/// justification is provided it is stored with the given finalized
	/// block (any other finalized blocks are left unjustified).
	///
	/// If the block being finalized is on a different fork from the current
	/// best block the finalized block is set as best, this might be slightly
	/// innacurate (i.e. outdated), usages that require determining an accurate
	/// best block should use `SelectChain` instead of the client.
	pub fn apply_finality(
		&self,
		operation: &mut ClientImportOperation<Block, Blake2Hasher, B>,
		id: BlockId<Block>,
		justification: Option<Justification>,
		notify: bool,
	) -> error::Result<()> {
		let last_best = self.backend.blockchain().info().best_hash;
		let to_finalize_hash = self.backend.blockchain().expect_block_hash_from_id(&id)?;
		self.apply_finality_with_block_hash(operation, to_finalize_hash, justification, last_best, notify)
	}

	/// Finalize a block. This will implicitly finalize all blocks up to it and
	/// fire finality notifications.
	///
	/// If the block being finalized is on a different fork from the current
	/// best block the finalized block is set as best, this might be slightly
	/// innacurate (i.e. outdated), usages that require determining an accurate
	/// best block should use `SelectChain` instead of the client.
	///
	/// Pass a flag to indicate whether finality notifications should be propagated.
	/// This is usually tied to some synchronization state, where we don't send notifications
	/// while performing major synchronization work.
	pub fn finalize_block(&self, id: BlockId<Block>, justification: Option<Justification>, notify: bool) -> error::Result<()> {
		self.lock_import_and_run(|operation| {
			let last_best = self.backend.blockchain().info().best_hash;
			let to_finalize_hash = self.backend.blockchain().expect_block_hash_from_id(&id)?;
			self.apply_finality_with_block_hash(operation, to_finalize_hash, justification, last_best, notify)
		})
	}

	/// Attempts to revert the chain by `n` blocks. Returns the number of blocks that were
	/// successfully reverted.
	pub fn revert(&self, n: NumberFor<Block>) -> error::Result<NumberFor<Block>> {
		Ok(self.backend.revert(n)?)
	}

	/// Get blockchain info.
	pub fn info(&self) -> ClientInfo<Block> {
		let info = self.backend.blockchain().info();
		ClientInfo {
			chain: info,
		}
	}

	/// Get block status.
	pub fn block_status(&self, id: &BlockId<Block>) -> error::Result<BlockStatus> {
		// this can probably be implemented more efficiently
		if let BlockId::Hash(ref h) = id {
			if self.importing_block.read().as_ref().map_or(false, |importing| h == importing) {
				return Ok(BlockStatus::Queued);
			}
		}
		let hash_and_number = match id.clone() {
			BlockId::Hash(hash) => self.backend.blockchain().number(hash)?.map(|n| (hash, n)),
			BlockId::Number(n) => self.backend.blockchain().hash(n)?.map(|hash| (hash, n)),
		};
		match hash_and_number {
			Some((hash, number)) => {
				if self.backend.have_state_at(&hash, number) {
					Ok(BlockStatus::InChainWithState)
				} else {
					Ok(BlockStatus::InChainPruned)
				}
			}
			None => Ok(BlockStatus::Unknown),
		}
	}

	/// Get block header by id.
	pub fn header(&self, id: &BlockId<Block>) -> error::Result<Option<<Block as BlockT>::Header>> {
		self.backend.blockchain().header(*id)
	}

	/// Get block body by id.
	pub fn body(&self, id: &BlockId<Block>) -> error::Result<Option<Vec<<Block as BlockT>::Extrinsic>>> {
		self.backend.blockchain().body(*id)
	}

	/// Get block justification set by id.
	pub fn justification(&self, id: &BlockId<Block>) -> error::Result<Option<Justification>> {
		self.backend.blockchain().justification(*id)
	}

	/// Get full block by id.
	pub fn block(&self, id: &BlockId<Block>)
		-> error::Result<Option<SignedBlock<Block>>>
	{
		Ok(match (self.header(id)?, self.body(id)?, self.justification(id)?) {
			(Some(header), Some(extrinsics), justification) =>
				Some(SignedBlock { block: Block::new(header, extrinsics), justification }),
			_ => None,
		})
	}

	/// Gets the uncles of the block with `target_hash` going back `max_generation` ancestors.
	pub fn uncles(&self, target_hash: Block::Hash, max_generation: NumberFor<Block>) -> error::Result<Vec<Block::Hash>> {
		let load_header = |id: Block::Hash| -> error::Result<Block::Header> {
			match self.backend.blockchain().header(BlockId::Hash(id))? {
				Some(hdr) => Ok(hdr),
				None => Err(Error::UnknownBlock(format!("Unknown block {:?}", id))),
			}
		};

		let genesis_hash = self.backend.blockchain().info().genesis_hash;
		if genesis_hash == target_hash { return Ok(Vec::new()); }

		let mut current_hash = target_hash;
		let mut current = load_header(current_hash)?;
		let mut ancestor_hash = *current.parent_hash();
		let mut ancestor = load_header(ancestor_hash)?;
		let mut uncles = Vec::new();

		for _generation in 0..max_generation.saturated_into() {
			let children = self.backend.blockchain().children(ancestor_hash)?;
			uncles.extend(children.into_iter().filter(|h| h != &current_hash));
			current_hash = ancestor_hash;
			if genesis_hash == current_hash { break; }
			current = ancestor;
			ancestor_hash = *current.parent_hash();
			ancestor = load_header(ancestor_hash)?;
		}

		Ok(uncles)
	}

	fn changes_trie_config(&self) -> Result<Option<ChangesTrieConfiguration>, Error> {
		Ok(self.backend.state_at(BlockId::Number(self.backend.blockchain().info().best_number))?
			.storage(well_known_keys::CHANGES_TRIE_CONFIG)
			.map_err(|e| error::Error::from_state(Box::new(e)))?
			.and_then(|c| Decode::decode(&mut &*c).ok()))
	}

	/// Prepare in-memory header that is used in execution environment.
	fn prepare_environment_block(&self, parent: &BlockId<Block>) -> error::Result<Block::Header> {
		let parent_header = self.backend.blockchain().expect_header(*parent)?;
		Ok(<<Block as BlockT>::Header as HeaderT>::new(
			self.backend.blockchain().expect_block_number_from_id(parent)? + One::one(),
			Default::default(),
			Default::default(),
			parent_header.hash(),
			Default::default(),
		))
	}
}

impl<B, E, Block, RA> ChainHeaderBackend<Block> for Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	E: CallExecutor<Block, Blake2Hasher> + Send + Sync,
	Block: BlockT<Hash=H256>,
	RA: Send + Sync
{
	fn header(&self, id: BlockId<Block>) -> error::Result<Option<Block::Header>> {
		self.backend.blockchain().header(id)
	}

	fn info(&self) -> blockchain::Info<Block> {
		self.backend.blockchain().info()
	}

	fn status(&self, id: BlockId<Block>) -> error::Result<blockchain::BlockStatus> {
		self.backend.blockchain().status(id)
	}

	fn number(&self, hash: Block::Hash) -> error::Result<Option<<<Block as BlockT>::Header as HeaderT>::Number>> {
		self.backend.blockchain().number(hash)
	}

	fn hash(&self, number: NumberFor<Block>) -> error::Result<Option<Block::Hash>> {
		self.backend.blockchain().hash(number)
	}
}

impl<B, E, Block, RA> ProvideCache<Block> for Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	Block: BlockT<Hash=H256>,
{
	fn cache(&self) -> Option<Arc<dyn Cache<Block>>> {
		self.backend.blockchain().cache()
	}
}

impl<B, E, Block, RA> ProvideRuntimeApi for Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	E: CallExecutor<Block, Blake2Hasher> + Clone + Send + Sync,
	Block: BlockT<Hash=H256>,
	RA: ConstructRuntimeApi<Block, Self>
{
	type Api = <RA as ConstructRuntimeApi<Block, Self>>::RuntimeApi;

	fn runtime_api<'a>(&'a self) -> ApiRef<'a, Self::Api> {
		RA::construct_runtime_api(self)
	}
}

impl<B, E, Block, RA> CallRuntimeAt<Block> for Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	E: CallExecutor<Block, Blake2Hasher> + Clone + Send + Sync,
	Block: BlockT<Hash=H256>,
{
	fn call_api_at<
		'a,
		R: Encode + Decode + PartialEq,
		NC: FnOnce() -> result::Result<R, &'static str> + UnwindSafe,
		C: CoreApi<Block>,
	>(
		&self,
		core_api: &C,
		at: &BlockId<Block>,
		function: &'static str,
		args: Vec<u8>,
		changes: &RefCell<OverlayedChanges>,
		initialize_block: InitializeBlock<'a, Block>,
		native_call: Option<NC>,
		context: ExecutionContext,
		recorder: &Option<Rc<RefCell<ProofRecorder<Block>>>>,
	) -> error::Result<NativeOrEncoded<R>> {
		let manager = match context {
			ExecutionContext::BlockConstruction =>
				self.execution_strategies.block_construction.get_manager(),
			ExecutionContext::Syncing =>
				self.execution_strategies.syncing.get_manager(),
			ExecutionContext::Importing =>
				self.execution_strategies.importing.get_manager(),
			ExecutionContext::OffchainWorker(_) =>
				self.execution_strategies.offchain_worker.get_manager(),
			ExecutionContext::Other =>
				self.execution_strategies.other.get_manager(),
		};

		let mut offchain_extensions = match context {
			ExecutionContext::OffchainWorker(ext) => Some(ext),
			_ => None,
		};

		self.executor.contextual_call::<_, _, fn(_,_) -> _,_,_>(
			|| core_api.initialize_block(at, &self.prepare_environment_block(at)?),
			at,
			function,
			&args,
			changes,
			initialize_block,
			manager,
			native_call,
			offchain_extensions.as_mut(),
			recorder,
		)
	}

	fn runtime_version_at(&self, at: &BlockId<Block>) -> error::Result<RuntimeVersion> {
		self.runtime_version_at(at)
	}
}

impl<'a, B, E, Block, RA> consensus::BlockImport<Block> for &'a Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	E: CallExecutor<Block, Blake2Hasher> + Clone + Send + Sync,
	Block: BlockT<Hash=H256>,
{
	type Error = ConsensusError;

	/// Import a checked and validated block. If a justification is provided in
	/// `BlockImportParams` then `finalized` *must* be true.
	fn import_block(
		&mut self,
		import_block: BlockImportParams<Block>,
		new_cache: HashMap<CacheKeyId, Vec<u8>>,
	) -> Result<ImportResult, Self::Error> {
		self.lock_import_and_run(|operation| {
			self.apply_block(operation, import_block, new_cache)
		}).map_err(|e| ConsensusError::ClientImport(e.to_string()).into())
	}

	/// Check block preconditions.
	fn check_block(
		&mut self,
		hash: Block::Hash,
		parent_hash: Block::Hash,
	) -> Result<ImportResult, Self::Error> {
		match self.block_status(&BlockId::Hash(parent_hash))
			.map_err(|e| ConsensusError::ClientImport(e.to_string()))?
		{
			BlockStatus::InChainWithState | BlockStatus::Queued => {},
			BlockStatus::Unknown | BlockStatus::InChainPruned => return Ok(ImportResult::UnknownParent),
			BlockStatus::KnownBad => return Ok(ImportResult::KnownBad),
		}

		match self.block_status(&BlockId::Hash(hash))
			.map_err(|e| ConsensusError::ClientImport(e.to_string()))?
		{
			BlockStatus::InChainWithState | BlockStatus::Queued => return Ok(ImportResult::AlreadyInChain),
			BlockStatus::Unknown | BlockStatus::InChainPruned => {},
			BlockStatus::KnownBad => return Ok(ImportResult::KnownBad),
		}

		Ok(ImportResult::imported())
	}
}

impl<B, E, Block, RA> consensus::BlockImport<Block> for Client<B, E, Block, RA> where
	B: backend::Backend<Block, Blake2Hasher>,
	E: CallExecutor<Block, Blake2Hasher> + Clone + Send + Sync,
	Block: BlockT<Hash=H256>,
{
	type Error = ConsensusError;

	fn import_block(
		&mut self,
		import_block: BlockImportParams<Block>,
		new_cache: HashMap<CacheKeyId, Vec<u8>>,
	) -> Result<ImportResult, Self::Error> {
		(&*self).import_block(import_block, new_cache)
	}

	fn check_block(
		&mut self,
		hash: Block::Hash,
		parent_hash: Block::Hash,
	) -> Result<ImportResult, Self::Error> {
		(&*self).check_block(hash, parent_hash)
	}
}

impl<B, E, Block, RA> BlockchainEvents<Block> for Client<B, E, Block, RA>
where
	E: CallExecutor<Block, Blake2Hasher>,
	Block: BlockT<Hash=H256>,
{
	/// Get block import event stream.
	fn import_notification_stream(&self) -> ImportNotifications<Block> {
		let (sink, stream) = mpsc::unbounded();
		self.import_notification_sinks.lock().push(sink);
		stream
	}

	fn finality_notification_stream(&self) -> FinalityNotifications<Block> {
		let (sink, stream) = mpsc::unbounded();
		self.finality_notification_sinks.lock().push(sink);
		stream
	}

	/// Get storage changes event stream.
	fn storage_changes_notification_stream(
		&self,
		filter_keys: Option<&[StorageKey]>,
		child_filter_keys: Option<&[(StorageKey, Option<Vec<StorageKey>>)]>,
	) -> error::Result<StorageEventStream<Block::Hash>> {
		Ok(self.storage_notifications.lock().listen(filter_keys, child_filter_keys))
	}
}

/// Implement Longest Chain Select implementation
/// where 'longest' is defined as the highest number of blocks
pub struct LongestChain<B, Block> {
	backend: Arc<B>,
	_phantom: PhantomData<Block>
}

impl<B, Block> Clone for LongestChain<B, Block> {
	fn clone(&self) -> Self {
		let backend = self.backend.clone();
		LongestChain {
			backend,
			_phantom: Default::default()
		}
	}
}

impl<B, Block> LongestChain<B, Block>
where
	B: backend::Backend<Block, Blake2Hasher>,
	Block: BlockT<Hash=H256>,
{
	/// Instantiate a new LongestChain for Backend B
	pub fn new(backend: Arc<B>) -> Self {
		LongestChain {
			backend,
			_phantom: Default::default()
		}
	}

	fn best_block_header(&self) -> error::Result<<Block as BlockT>::Header> {
		let info = self.backend.blockchain().info();
		let best_hash = self.best_containing(info.best_hash, None)?
			.unwrap_or(info.best_hash);

		Ok(self.backend.blockchain().header(BlockId::Hash(best_hash))?
			.expect("given block hash was fetched from block in db; qed"))
	}

	/// Get the most recent block hash of the best (longest) chains
	/// that contain block with the given `target_hash`.
	///
	/// The search space is always limited to blocks which are in the finalized
	/// chain or descendents of it.
	///
	/// If `maybe_max_block_number` is `Some(max_block_number)`
	/// the search is limited to block `numbers <= max_block_number`.
	/// in other words as if there were no blocks greater `max_block_number`.
	/// Returns `Ok(None)` if `target_hash` is not found in search space.
	/// TODO: document time complexity of this, see [#1444](https://github.com/paritytech/substrate/issues/1444)
	fn best_containing(
		&self,
		target_hash: Block::Hash,
		maybe_max_number: Option<NumberFor<Block>>
	) -> error::Result<Option<Block::Hash>> {
		let target_header = {
			match self.backend.blockchain().header(BlockId::Hash(target_hash))? {
				Some(x) => x,
				// target not in blockchain
				None => { return Ok(None); },
			}
		};

		if let Some(max_number) = maybe_max_number {
			// target outside search range
			if target_header.number() > &max_number {
				return Ok(None);
			}
		}

		let leaves = {
			// ensure no blocks are imported during this code block.
			// an import could trigger a reorg which could change the canonical chain.
			// we depend on the canonical chain staying the same during this code block.
			let _import_lock = self.backend.get_import_lock().lock();

			let info = self.backend.blockchain().info();

			let canon_hash = self.backend.blockchain().hash(*target_header.number())?
				.ok_or_else(|| error::Error::from(format!("failed to get hash for block number {}", target_header.number())))?;

			if canon_hash == target_hash {
				// if a `max_number` is given we try to fetch the block at the
				// given depth, if it doesn't exist or `max_number` is not
				// provided, we continue to search from all leaves below.
				if let Some(max_number) = maybe_max_number {
					if let Some(header) = self.backend.blockchain().hash(max_number)? {
						return Ok(Some(header));
					}
				}
			} else if info.finalized_number >= *target_header.number() {
				// header is on a dead fork.
				return Ok(None);
			}

			self.backend.blockchain().leaves()?
		};

		// for each chain. longest chain first. shortest last
		for leaf_hash in leaves {
			// start at the leaf
			let mut current_hash = leaf_hash;

			// if search is not restricted then the leaf is the best
			let mut best_hash = leaf_hash;

			// go backwards entering the search space
			// waiting until we are <= max_number
			if let Some(max_number) = maybe_max_number {
				loop {
					let current_header = self.backend.blockchain().header(BlockId::Hash(current_hash.clone()))?
						.ok_or_else(|| error::Error::from(format!("failed to get header for hash {}", current_hash)))?;

					if current_header.number() <= &max_number {
						best_hash = current_header.hash();
						break;
					}

					current_hash = *current_header.parent_hash();
				}
			}

			// go backwards through the chain (via parent links)
			loop {
				// until we find target
				if current_hash == target_hash {
					return Ok(Some(best_hash));
				}

				let current_header = self.backend.blockchain().header(BlockId::Hash(current_hash.clone()))?
					.ok_or_else(|| error::Error::from(format!("failed to get header for hash {}", current_hash)))?;

				// stop search in this chain once we go below the target's block number
				if current_header.number() < target_header.number() {
					break;
				}

				current_hash = *current_header.parent_hash();
			}
		}

		// header may be on a dead fork -- the only leaves that are considered are
		// those which can still be finalized.
		//
		// FIXME #1558 only issue this warning when not on a dead fork
		warn!(
			"Block {:?} exists in chain but not found when following all \
			leaves backwards. Number limit = {:?}",
			target_hash,
			maybe_max_number,
		);

		Ok(None)
	}

	fn leaves(&self) -> Result<Vec<<Block as BlockT>::Hash>, error::Error> {
		self.backend.blockchain().leaves()
	}
}

impl<B, Block> SelectChain<Block> for LongestChain<B, Block>
where
	B: backend::Backend<Block, Blake2Hasher>,
	Block: BlockT<Hash=H256>,
{

	fn leaves(&self) -> Result<Vec<<Block as BlockT>::Hash>, ConsensusError> {
		LongestChain::leaves(self)
			.map_err(|e| ConsensusError::ChainLookup(e.to_string()).into())
	}

	fn best_chain(&self)
		-> Result<<Block as BlockT>::Header, ConsensusError>
	{
		LongestChain::best_block_header(&self)
			.map_err(|e| ConsensusError::ChainLookup(e.to_string()).into())
	}

	fn finality_target(
		&self,
		target_hash: Block::Hash,
		maybe_max_number: Option<NumberFor<Block>>
	) -> Result<Option<Block::Hash>, ConsensusError> {
		LongestChain::best_containing(self, target_hash, maybe_max_number)
			.map_err(|e| ConsensusError::ChainLookup(e.to_string()).into())
	}
}

impl<B, E, Block, RA> BlockBody<Block> for Client<B, E, Block, RA>
	where
		B: backend::Backend<Block, Blake2Hasher>,
		E: CallExecutor<Block, Blake2Hasher>,
		Block: BlockT<Hash=H256>,
{
	fn block_body(&self, id: &BlockId<Block>) -> error::Result<Option<Vec<<Block as BlockT>::Extrinsic>>> {
		self.body(id)
	}
}

impl<B, E, Block, RA> backend::AuxStore for Client<B, E, Block, RA>
	where
		B: backend::Backend<Block, Blake2Hasher>,
		E: CallExecutor<Block, Blake2Hasher>,
		Block: BlockT<Hash=H256>,
{
	/// Insert auxiliary data into key-value store.
	fn insert_aux<
		'a,
		'b: 'a,
		'c: 'a,
		I: IntoIterator<Item=&'a(&'c [u8], &'c [u8])>,
		D: IntoIterator<Item=&'a &'b [u8]>,
	>(&self, insert: I, delete: D) -> error::Result<()> {
		// Import is locked here because we may have other block import
		// operations that tries to set aux data. Note that for consensus
		// layer, one can always use atomic operations to make sure
		// import is only locked once.
		self.lock_import_and_run(|operation| {
			self.apply_aux(operation, insert, delete)
		})
	}
	/// Query auxiliary data from key-value store.
	fn get_aux(&self, key: &[u8]) -> error::Result<Option<Vec<u8>>> {
		crate::backend::AuxStore::get_aux(&*self.backend, key)
	}
}

/// Utility methods for the client.
pub mod utils {
	use super::*;
	use crate::{backend::Backend, blockchain, error};
	use primitives::H256;

	/// Returns a function for checking block ancestry, the returned function will
	/// return `true` if the given hash (second parameter) is a descendent of the
	/// base (first parameter). If the `current` parameter is defined, it should
	/// represent the current block `hash` and its `parent hash`, if given the
	/// function that's returned will assume that `hash` isn't part of the local DB
	/// yet, and all searches in the DB will instead reference the parent.
	pub fn is_descendent_of<'a, B, E, Block: BlockT<Hash=H256>, RA>(
		client: &'a Client<B, E, Block, RA>,
		current: Option<(&'a H256, &'a H256)>,
	) -> impl Fn(&H256, &H256) -> Result<bool, error::Error> + 'a
		where B: Backend<Block, Blake2Hasher>,
			  E: CallExecutor<Block, Blake2Hasher> + Send + Sync,
	{
		move |base, hash| {
			if base == hash { return Ok(false); }

			let mut hash = hash;
			if let Some((current_hash, current_parent_hash)) = current {
				if base == current_hash { return Ok(false); }
				if hash == current_hash {
					if base == current_parent_hash {
						return Ok(true);
					} else {
						hash = current_parent_hash;
					}
				}
			}

			let tree_route = blockchain::tree_route(
				#[allow(deprecated)]
				client.backend().blockchain(),
				BlockId::Hash(*hash),
				BlockId::Hash(*base),
			)?;

			Ok(tree_route.common_block().hash == *base)
		}
	}
}

#[cfg(test)]
pub(crate) mod tests {
	use std::collections::HashMap;
	use super::*;
	use primitives::blake2_256;
	use sr_primitives::DigestItem;
	use consensus::{BlockOrigin, SelectChain};
	use test_client::{
		prelude::*,
		client::backend::Backend as TestBackend,
		runtime::{self, Block, Transfer, RuntimeApi, TestAPI},
	};

	/// Returns tuple, consisting of:
	/// 1) test client pre-filled with blocks changing balances;
	/// 2) roots of changes tries for these blocks
	/// 3) test cases in form (begin, end, key, vec![(block, extrinsic)]) that are required to pass
	pub fn prepare_client_with_key_changes() -> (
		test_client::client::Client<test_client::Backend, test_client::Executor, Block, RuntimeApi>,
		Vec<H256>,
		Vec<(u64, u64, Vec<u8>, Vec<(u64, u32)>)>,
	) {
		// prepare block structure
		let blocks_transfers = vec![
			vec![(AccountKeyring::Alice, AccountKeyring::Dave), (AccountKeyring::Bob, AccountKeyring::Dave)],
			vec![(AccountKeyring::Charlie, AccountKeyring::Eve)],
			vec![],
			vec![(AccountKeyring::Alice, AccountKeyring::Dave)],
		];

		// prepare client ang import blocks
		let mut local_roots = Vec::new();
		let remote_client = TestClientBuilder::new().set_support_changes_trie(true).build();
		let mut nonces: HashMap<_, u64> = Default::default();
		for (i, block_transfers) in blocks_transfers.into_iter().enumerate() {
			let mut builder = remote_client.new_block(Default::default()).unwrap();
			for (from, to) in block_transfers {
				builder.push_transfer(Transfer {
					from: from.into(),
					to: to.into(),
					amount: 1,
					nonce: *nonces.entry(from).and_modify(|n| { *n = *n + 1 }).or_default(),
				}).unwrap();
			}
			remote_client.import(BlockOrigin::Own, builder.bake().unwrap()).unwrap();

			let header = remote_client.header(&BlockId::Number(i as u64 + 1)).unwrap().unwrap();
			let trie_root = header.digest().log(DigestItem::as_changes_trie_root)
				.map(|root| H256::from_slice(root.as_ref()))
				.unwrap();
			local_roots.push(trie_root);
		}

		// prepare test cases
		let alice = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Alice.into())).to_vec();
		let bob = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Bob.into())).to_vec();
		let charlie = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Charlie.into())).to_vec();
		let dave = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Dave.into())).to_vec();
		let eve = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Eve.into())).to_vec();
		let ferdie = blake2_256(&runtime::system::balance_of_key(AccountKeyring::Ferdie.into())).to_vec();
		let test_cases = vec![
			(1, 4, alice.clone(), vec![(4, 0), (1, 0)]),
			(1, 3, alice.clone(), vec![(1, 0)]),
			(2, 4, alice.clone(), vec![(4, 0)]),
			(2, 3, alice.clone(), vec![]),

			(1, 4, bob.clone(), vec![(1, 1)]),
			(1, 1, bob.clone(), vec![(1, 1)]),
			(2, 4, bob.clone(), vec![]),

			(1, 4, charlie.clone(), vec![(2, 0)]),

			(1, 4, dave.clone(), vec![(4, 0), (1, 1), (1, 0)]),
			(1, 1, dave.clone(), vec![(1, 1), (1, 0)]),
			(3, 4, dave.clone(), vec![(4, 0)]),

			(1, 4, eve.clone(), vec![(2, 0)]),
			(1, 1, eve.clone(), vec![]),
			(3, 4, eve.clone(), vec![]),

			(1, 4, ferdie.clone(), vec![]),
		];

		(remote_client, local_roots, test_cases)
	}

	#[test]
	fn client_initializes_from_genesis_ok() {
		let client = test_client::new();

		assert_eq!(
			client.runtime_api().balance_of(
				&BlockId::Number(client.info().chain.best_number),
				AccountKeyring::Alice.into()
			).unwrap(),
			1000
		);
		assert_eq!(
			client.runtime_api().balance_of(
				&BlockId::Number(client.info().chain.best_number),
				AccountKeyring::Ferdie.into()
			).unwrap(),
			0
		);
	}

	#[test]
	fn block_builder_works_with_no_transactions() {
		let client = test_client::new();

		let builder = client.new_block(Default::default()).unwrap();

		client.import(BlockOrigin::Own, builder.bake().unwrap()).unwrap();

		assert_eq!(client.info().chain.best_number, 1);
	}

	#[test]
	fn block_builder_works_with_transactions() {
		let client = test_client::new();

		let mut builder = client.new_block(Default::default()).unwrap();

		builder.push_transfer(Transfer {
			from: AccountKeyring::Alice.into(),
			to: AccountKeyring::Ferdie.into(),
			amount: 42,
			nonce: 0,
		}).unwrap();

		client.import(BlockOrigin::Own, builder.bake().unwrap()).unwrap();

		assert_eq!(client.info().chain.best_number, 1);
		assert_ne!(
			client.state_at(&BlockId::Number(1)).unwrap().pairs(),
			client.state_at(&BlockId::Number(0)).unwrap().pairs()
		);
		assert_eq!(
			client.runtime_api().balance_of(
				&BlockId::Number(client.info().chain.best_number),
				AccountKeyring::Alice.into()
			).unwrap(),
			958
		);
		assert_eq!(
			client.runtime_api().balance_of(
				&BlockId::Number(client.info().chain.best_number),
				AccountKeyring::Ferdie.into()
			).unwrap(),
			42
		);
	}

	#[test]
	fn block_builder_does_not_include_invalid() {
		let client = test_client::new();

		let mut builder = client.new_block(Default::default()).unwrap();

		builder.push_transfer(Transfer {
			from: AccountKeyring::Alice.into(),
			to: AccountKeyring::Ferdie.into(),
			amount: 42,
			nonce: 0,
		}).unwrap();

		assert!(builder.push_transfer(Transfer {
			from: AccountKeyring::Eve.into(),
			to: AccountKeyring::Alice.into(),
			amount: 42,
			nonce: 0,
		}).is_err());

		client.import(BlockOrigin::Own, builder.bake().unwrap()).unwrap();

		assert_eq!(client.info().chain.best_number, 1);
		assert_ne!(