def test_get_prefix_nodes():
    trie = Trie(PersistentDB(KeyValueStorageInMemory()))
    prefix = 'abcd'
    prefix_nibbles = bin_to_nibbles(to_string(prefix))
    key1 = prefix + '1'
    key2 = prefix + '2'
    key3 = prefix + '3'
    trie.update(key1.encode(), rlp_encode(['v1']))
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles)
    # The last node should be a leaf since only 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_LEAF

    # The queried key is larger than prefix, results in blank node
    last_node_ = trie._get_last_node_for_prfx(
        trie.root_node, bin_to_nibbles(to_string(prefix + '5')))
    assert last_node_ == BLANK_NODE

    trie.update(key2.encode(), rlp_encode(['v2']))
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles)
    # The last node should be an extension since more than 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION

    trie.update(key3.encode(), rlp_encode(['v3']))
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles)
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION

    last_node_key = without_terminator(unpack_to_nibbles(last_node[0]))
    # Key for the fetched prefix nodes (ignore last nibble) is same as prefix nibbles
    assert last_node_key[:-1] == prefix_nibbles

    # The extension node is correctly decoded.
    decoded_extension = trie._decode_to_node(last_node[1])
    assert decoded_extension[1] == [b' ', rlp_encode(['v1'])]
    assert decoded_extension[2] == [b' ', rlp_encode(['v2'])]
    assert decoded_extension[3] == [b' ', rlp_encode(['v3'])]
def test_get_prefix_nodes():
    trie = Trie(PersistentDB(KeyValueStorageInMemory()))
    prefix = 'abcd'
    prefix_nibbles = bin_to_nibbles(prefix)
    key1 = prefix + '1'
    key2 = prefix + '2'
    key3 = prefix + '3'
    trie.update(key1.encode(), rlp_encode(['v1']))
    seen_prefix = []
    last_node = trie._get_last_node_for_prfx(trie.root_node,
                                             prefix_nibbles,
                                             seen_prfx=seen_prefix)
    # The last node should be a leaf since only 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_LEAF
    # Seen prefix matches the prefix exactly
    assert seen_prefix == []

    # The queried key is larger than prefix, results in blank node
    last_node_ = trie._get_last_node_for_prfx(trie.root_node,
                                              bin_to_nibbles(prefix + '5'), [])
    assert last_node_ == BLANK_NODE

    seen_prefix = []
    trie.update(key2.encode(), rlp_encode(['v2']))
    last_node = trie._get_last_node_for_prfx(trie.root_node,
                                             prefix_nibbles,
                                             seen_prfx=seen_prefix)
    # The last node should be an extension since more than 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert seen_prefix == []

    seen_prefix = []
    trie.update(key3.encode(), rlp_encode(['v3']))
    last_node = trie._get_last_node_for_prfx(trie.root_node,
                                             prefix_nibbles,
                                             seen_prfx=seen_prefix)
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert seen_prefix == []

    last_node_key = without_terminator(unpack_to_nibbles(last_node[0]))
    # Key for the fetched prefix nodes (ignore last nibble) is same as prefix nibbles
    assert last_node_key[:-1] == prefix_nibbles

    # The extension node is correctly decoded.
    decoded_extension = trie._decode_to_node(last_node[1])
    assert decoded_extension[1] == [b' ', rlp_encode(['v1'])]
    assert decoded_extension[2] == [b' ', rlp_encode(['v2'])]
    assert decoded_extension[3] == [b' ', rlp_encode(['v3'])]

    # Add keys with extended prefix
    extended_prefix = '1'
    key4 = prefix + extended_prefix + '85'
    trie.update(key4.encode(), rlp_encode(['v11']))
    key5 = prefix + extended_prefix + '96'
    trie.update(key5.encode(), rlp_encode(['v12']))
    seen_prefix = []
    new_prefix_nibbs = bin_to_nibbles(prefix + extended_prefix)
    last_node = trie._get_last_node_for_prfx(trie.root_node,
                                             new_prefix_nibbs,
                                             seen_prfx=seen_prefix)

    assert trie._get_node_type(last_node) == NODE_TYPE_BRANCH
    assert new_prefix_nibbs == seen_prefix
    assert seen_prefix == bin_to_nibbles(prefix + '1')

    # traverse to the next node
    remaining_key4_nibbs = bin_to_nibbles(key4)[len(seen_prefix):]
    remaining_key5_nibbs = bin_to_nibbles(key5)[len(seen_prefix):]
    next_nibble = remaining_key4_nibbs[0] if remaining_key4_nibbs[
        0] > remaining_key5_nibbs[0] else remaining_key5_nibbs[0]
    next_node = trie._decode_to_node(last_node[next_nibble])

    assert trie._get_node_type(next_node) == NODE_TYPE_BRANCH

    # The 8th index should lead to a node with key '5', key4 ended in '85'
    assert trie._get_node_type(next_node[8]) == NODE_TYPE_LEAF
    assert without_terminator(unpack_to_nibbles(
        next_node[8][0])) == bin_to_nibbles('5')

    # The 9th index should lead to a node with key '6', key5 ended in '96'
    assert trie._get_node_type(next_node[9]) == NODE_TYPE_LEAF
    assert without_terminator(unpack_to_nibbles(
        next_node[9][0])) == bin_to_nibbles('6')

    prefix_1 = prefix + 'efgh'
    prefix_1_nibbles = bin_to_nibbles(prefix_1)
    key1 = prefix_1 + '1'
    key2 = prefix_1 + '2'
    key3 = prefix_1 + '3'

    trie.update(key1.encode(), rlp_encode(['v1']))
    trie.update(key2.encode(), rlp_encode(['v1']))
    trie.update(key3.encode(), rlp_encode(['v1']))

    seen_prefix = []
    last_node = trie._get_last_node_for_prfx(trie.root_node,
                                             prefix_1_nibbles,
                                             seen_prfx=seen_prefix)
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert len(seen_prefix) > 0
    assert starts_with(prefix_1_nibbles, seen_prefix)
Beispiel #3
0
class PruningState(State):
    """
    This class is used to store the
    committed root hash of the trie in the db.
    The committed root hash is only updated once a batch gets written to the
    ledger. It might happen that a few batches are in 3 phase commit and the
    node crashes. Now when the node restarts, it restores the db from the
    committed root hash and all entries for uncommitted batches will be
    ignored
    """

    # SOME KEY THAT DOES NOT COLLIDE WITH ANY STATE VARIABLE'S NAME
    rootHashKey = b'\x88\xc8\x88 \x9a\xa7\x89\x1b'

    def __init__(self, keyValueStorage: KeyValueStorage):
        self._kv = keyValueStorage
        if self.rootHashKey in self._kv:
            rootHash = bytes(self._kv.get(self.rootHashKey))
        else:
            rootHash = BLANK_ROOT
            self._kv.put(self.rootHashKey, BLANK_ROOT)
        self._trie = Trie(PersistentDB(self._kv), rootHash)

    @property
    def head(self):
        # The current head of the state, if the state is a merkle tree then
        # head is the root
        return self._trie.root_node

    @property
    def committedHead(self):
        # The committed head of the state, if the state is a merkle tree then
        # head is the root
        return self._hash_to_node(self.committedHeadHash)

    def get_head_by_hash(self, root_hash):
        # return node of a merkle tree by given hash
        return self._hash_to_node(root_hash)

    def _hash_to_node(self, node_hash):
        if node_hash == BLANK_ROOT:
            return BLANK_NODE
        return self._trie._decode_to_node(node_hash)

    def set(self, key: bytes, value: bytes):
        self._trie.update(key, rlp_encode([value]))

    def get(self, key: bytes, isCommitted: bool = True) -> Optional[bytes]:
        if not isCommitted:
            val = self._trie.get(key)
        else:
            val = self._trie._get(self.committedHead,
                                  bin_to_nibbles(to_string(key)))
        if val:
            return self.get_decoded(val)

    def get_for_root_hash(self, root_hash, key: bytes) -> Optional[bytes]:
        root = self._hash_to_node(root_hash)
        val = self._trie._get(root, bin_to_nibbles(to_string(key)))
        if val:
            return self.get_decoded(val)

    def get_all_leaves_for_root_hash(self, root_hash):
        node = self._hash_to_node(root_hash)
        leaves = self._trie.to_dict(node)
        return leaves

    def remove(self, key: bytes):
        self._trie.delete(key)

    def commit(self, rootHash=None, rootNode=None):
        if rootNode:
            rootHash = self._trie._encode_node(rootNode)
        elif rootHash and isHex(rootHash):
            if isinstance(rootHash, str):
                rootHash = rootHash.encode()
            rootHash = unhexlify(rootHash)
        elif rootHash:
            rootHash = rootHash
        else:
            rootHash = self.headHash
        self._kv.put(self.rootHashKey, rootHash)

    def revertToHead(self, headHash=None):
        head = self._hash_to_node(headHash)
        self._trie.replace_root_hash(self._trie.root_node, head)

    # Proofs are always generated over committed state
    def generate_state_proof(self,
                             key: bytes,
                             root=None,
                             serialize=False,
                             get_value=False):
        return self._trie.generate_state_proof(key,
                                               root,
                                               serialize,
                                               get_value=get_value)

    def generate_state_proof_for_keys_with_prefix(self,
                                                  key_prfx,
                                                  root=None,
                                                  serialize=False,
                                                  get_value=False):
        return self._trie.generate_state_proof_for_keys_with_prefix(
            key_prfx, root, serialize, get_value=get_value)

    @staticmethod
    def verify_state_proof(root, key, value, proof_nodes, serialized=False):
        encoded_key, encoded_value = PruningState.encode_kv_for_verification(
            key, value)
        return Trie.verify_spv_proof(root, encoded_key, encoded_value,
                                     proof_nodes, serialized)

    @staticmethod
    def verify_state_proof_multi(root,
                                 key_values,
                                 proof_nodes,
                                 serialized=False):
        encoded_key_values = dict(
            PruningState.encode_kv_for_verification(k, v)
            for k, v in key_values.items())
        return Trie.verify_spv_proof_multi(root, encoded_key_values,
                                           proof_nodes, serialized)

    @staticmethod
    def encode_kv_for_verification(key, value):
        encoded_key = key.encode() if isinstance(key, str) else key
        encoded_value = rlp_encode([value]) if value is not None else b''
        return encoded_key, encoded_value

    @property
    def as_dict(self):
        d = self._trie.to_dict()
        return {k: self.get_decoded(v) for k, v in d.items()}

    @property
    def headHash(self):
        """
        The hash of the current head of the state, if the state is a merkle
        tree then hash of the root
        :return:
        """
        return self._trie.root_hash

    @property
    def committedHeadHash(self):
        return self._kv.get(self.rootHashKey)

    @property
    def closed(self):
        return not self._kv or self._kv.closed

    @property
    def isEmpty(self):
        return self._kv and self.committedHeadHash == BLANK_ROOT

    def close(self):
        if self._kv:
            self._kv.close()
            self._kv = None

    @staticmethod
    def get_decoded(encoded):
        return rlp_decode(encoded)[0]
class PruningState(State):
    """
    This class is used to store the
    committed root hash of the trie in the db.
    The committed root hash is only updated once a batch gets written to the
    ledger. It might happen that a few batches are in 3 phase commit and the
    node crashes. Now when the node restarts, it restores the db from the
    committed root hash and all entries for uncommitted batches will be
    ignored
    """

    # SOME KEY THAT DOES NOT COLLIDE WITH ANY STATE VARIABLE'S NAME
    rootHashKey = b'\x88\xc8\x88 \x9a\xa7\x89\x1b'

    def __init__(self, keyValueStorage: KeyValueStorage):
        self._kv = keyValueStorage
        if self.rootHashKey in self._kv:
            rootHash = bytes(self._kv.get(self.rootHashKey))
        else:
            rootHash = BLANK_ROOT
            self._kv.put(self.rootHashKey, BLANK_ROOT)
        self._trie = Trie(
            PersistentDB(self._kv),
            rootHash)

    @property
    def head(self):
        # The current head of the state, if the state is a merkle tree then
        # head is the root
        return self._trie.root_node

    @property
    def committedHead(self):
        # The committed head of the state, if the state is a merkle tree then
        # head is the root
        return self._hash_to_node(self.committedHeadHash)

    def get_head_by_hash(self, root_hash):
        # return node of a merkle tree by given hash
        return self._hash_to_node(root_hash)

    def _hash_to_node(self, node_hash):
        if node_hash == BLANK_ROOT:
            return BLANK_NODE
        return self._trie._decode_to_node(node_hash)

    def set(self, key: bytes, value: bytes):
        self._trie.update(key, rlp_encode([value]))

    def get(self, key: bytes, isCommitted: bool = True) -> Optional[bytes]:
        if not isCommitted:
            val = self._trie.get(key)
        else:
            val = self._trie._get(self.committedHead,
                                  bin_to_nibbles(to_string(key)))
        if val:
            return self.get_decoded(val)

    def get_for_root_hash(self, root_hash, key: bytes) -> Optional[bytes]:
        root = self._hash_to_node(root_hash)
        val = self._trie._get(root,
                              bin_to_nibbles(to_string(key)))
        if val:
            return self.get_decoded(val)

    def get_all_leaves_for_root_hash(self, root_hash):
        node = self._hash_to_node(root_hash)
        leaves = self._trie.to_dict(node)
        return leaves

    def remove(self, key: bytes):
        self._trie.delete(key)

    def commit(self, rootHash=None, rootNode=None):
        if rootNode:
            rootHash = self._trie._encode_node(rootNode)
        elif rootHash and isHex(rootHash):
            if isinstance(rootHash, str):
                rootHash = rootHash.encode()
            rootHash = unhexlify(rootHash)
        elif rootHash:
            rootHash = rootHash
        else:
            rootHash = self.headHash
        self._kv.put(self.rootHashKey, rootHash)

    def revertToHead(self, headHash=None):
        head = self._hash_to_node(headHash)
        self._trie.replace_root_hash(self._trie.root_node, head)

    # Proofs are always generated over committed state
    def generate_state_proof(self, key: bytes, root=None, serialize=False, get_value=False):
        return self._trie.generate_state_proof(key, root, serialize, get_value=get_value)

    def generate_state_proof_for_keys_with_prefix(self, key_prfx, root=None,
                                                  serialize=False, get_value=False):
        return self._trie.generate_state_proof_for_keys_with_prefix(key_prfx, root,
                                                                    serialize, get_value=get_value)

    @staticmethod
    def verify_state_proof(root, key, value, proof_nodes, serialized=False):
        encoded_key, encoded_value = PruningState.encode_kv_for_verification(key, value)
        return Trie.verify_spv_proof(root, encoded_key, encoded_value,
                                     proof_nodes, serialized)

    @staticmethod
    def verify_state_proof_multi(root, key_values, proof_nodes, serialized=False):
        encoded_key_values = dict(PruningState.encode_kv_for_verification(k, v) for k, v in key_values.items())
        return Trie.verify_spv_proof_multi(root, encoded_key_values, proof_nodes, serialized)

    @staticmethod
    def encode_kv_for_verification(key, value):
        encoded_key = key.encode() if isinstance(key, str) else key
        encoded_value = rlp_encode([value]) if value is not None else b''
        return encoded_key, encoded_value

    @property
    def as_dict(self):
        d = self._trie.to_dict()
        return {k: self.get_decoded(v) for k, v in d.items()}

    @property
    def headHash(self):
        """
        The hash of the current head of the state, if the state is a merkle
        tree then hash of the root
        :return:
        """
        return self._trie.root_hash

    @property
    def committedHeadHash(self):
        return self._kv.get(self.rootHashKey)

    @property
    def isEmpty(self):
        return self.committedHeadHash == BLANK_ROOT

    def close(self):
        if self._kv:
            self._kv.close()
            self._kv = None

    @staticmethod
    def get_decoded(encoded):
        return rlp_decode(encoded)[0]
def test_get_values_at_roots_in_memory():
    # Update key with different values but preserve root after each update
    # Check values of keys with different previous roots and check that they
    # are correct
    trie = Trie(PersistentDB(KeyValueStorageInMemory()))

    trie.update('k1'.encode(), rlp_encode(['v1']))
    # print state.root_hash.encode('hex')
    # print state.root_node

    val = trie.get('k1')
    print(rlp_decode(val))
    oldroot1 = trie.root_node
    old_root1_hash = trie.root_hash
    assert trie._decode_to_node(old_root1_hash) == oldroot1
    trie.update('k1'.encode(), rlp_encode(['v1a']))
    val = trie.get('k1')
    assert rlp_decode(val) == [b'v1a', ]

    # Already saved roots help in getting previous values
    oldval = trie.get_at(oldroot1, 'k1')
    assert rlp_decode(oldval) == [b'v1', ]
    oldroot1a = trie.root_node

    trie.update('k1'.encode(), rlp_encode([b'v1b']))
    val = trie.get('k1')
    assert rlp_decode(val) == [b'v1b']

    oldval = trie.get_at(oldroot1a, 'k1')
    assert rlp_decode(oldval) == [b'v1a', ]

    oldval = trie.get_at(oldroot1, 'k1')
    assert rlp_decode(oldval) == [b'v1', ]

    oldroot1b = trie.root_node

    trie.update('k1'.encode(), rlp_encode([b'v1c']))
    val = trie.get('k1')
    assert rlp_decode(val) == [b'v1c', ]

    oldval = trie.get_at(oldroot1b, 'k1')
    assert rlp_decode(oldval) == [b'v1b', ]

    oldval = trie.get_at(oldroot1a, 'k1')
    assert rlp_decode(oldval) == [b'v1a', ]

    oldval = trie.get_at(oldroot1, 'k1')
    assert rlp_decode(oldval) == [b'v1', ]

    oldroot1c = trie.root_node

    trie.delete('k1'.encode())
    assert trie.get('k1') == BLANK_NODE

    oldval = trie.get_at(oldroot1c, 'k1')
    assert rlp_decode(oldval) == [b'v1c', ]

    oldval = trie.get_at(oldroot1b, 'k1')
    assert rlp_decode(oldval) == [b'v1b', ]

    oldval = trie.get_at(oldroot1a, 'k1')
    assert rlp_decode(oldval) == [b'v1a', ]

    oldval = trie.get_at(oldroot1, 'k1')
    assert rlp_decode(oldval) == [b'v1', ]

    trie.root_node = oldroot1c
    val = trie.get('k1')
    assert rlp_decode(val) == [b'v1c', ]

    trie.root_node = oldroot1
    val = trie.get('k1')
    assert rlp_decode(val) == [b'v1', ]
Beispiel #6
0
class PruningState(State):
    # This class is used to store the
    # committed root hash of the trie in the db.
    # The committed root hash is only updated once a batch gets written to the
    # ledger. It might happen that a few batches are in 3 phase commit and the
    # node crashes. Now when the node restarts, it restores the db from the
    # committed root hash and all entries for uncommitted batches will be
    # ignored

    # some key that does not collide with any state variable's name
    rootHashKey = b'\x88\xc8\x88 \x9a\xa7\x89\x1b'

    def __init__(self, keyValueStorage: KeyValueStorage):
        self._kv = keyValueStorage
        if self.rootHashKey in self._kv:
            rootHash = bytes(self._kv.get(self.rootHashKey))
        else:
            rootHash = BLANK_ROOT
            self._kv.put(self.rootHashKey, BLANK_ROOT)
        self._trie = Trie(PersistentDB(self._kv), rootHash)

    @property
    def head(self):
        # The current head of the state, if the state is a merkle tree then
        # head is the root
        return self._trie.root_node

    @property
    def committedHead(self):
        # The committed head of the state, if the state is a merkle tree then
        # head is the root
        if self.committedHeadHash == BLANK_ROOT:
            return BLANK_NODE
        else:
            return self._trie._decode_to_node(self.committedHeadHash)

    def set(self, key: bytes, value: bytes):
        self._trie.update(key, rlp_encode([value]))

    def get(self, key: bytes, isCommitted: bool = True):
        if not isCommitted:
            val = self._trie.get(key)
        else:
            val = self._trie._get(self.committedHead,
                                  bin_to_nibbles(to_string(key)))
        if val:
            return rlp_decode(val)[0]

    def remove(self, key: bytes):
        self._trie.delete(key)

    def commit(self, rootHash=None, rootNode=None):
        if rootNode:
            rootHash = self._trie._encode_node(rootNode)
        elif rootHash and isHex(rootHash):
            if isinstance(rootHash, str):
                rootHash = rootHash.encode()
            rootHash = unhexlify(rootHash)
        elif rootHash:
            rootHash = rootHash
        else:
            rootHash = self.headHash
        self._kv.put(self.rootHashKey, rootHash)

    def revertToHead(self, headHash=None):
        if headHash != BLANK_ROOT:
            head = self._trie._decode_to_node(headHash)
        else:
            head = BLANK_NODE
        self._trie.replace_root_hash(self._trie.root_node, head)

    @property
    def as_dict(self):
        d = self._trie.to_dict()
        return {k: rlp_decode(v)[0] for k, v in d.items()}

    @property
    def headHash(self):
        """
        The hash of the current head of the state, if the state is a merkle
        tree then hash of the root
        :return:
        """
        return self._trie.root_hash

    @property
    def committedHeadHash(self):
        return self._kv.get(self.rootHashKey)

    @property
    def isEmpty(self):
        return self.committedHeadHash == BLANK_ROOT

    def close(self):
        if self._kv:
            self._kv.close()
            self._kv = None
def test_get_prefix_nodes():
    trie = Trie(PersistentDB(KeyValueStorageInMemory()))
    prefix = 'abcd'
    prefix_nibbles = bin_to_nibbles(prefix)
    key1 = prefix + '1'
    key2 = prefix + '2'
    key3 = prefix + '3'
    trie.update(key1.encode(), rlp_encode(['v1']))
    seen_prefix = []
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles,
                                             seen_prfx=seen_prefix)
    # The last node should be a leaf since only 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_LEAF
    # Seen prefix matches the prefix exactly
    assert seen_prefix == []

    # The queried key is larger than prefix, results in blank node
    last_node_ = trie._get_last_node_for_prfx(trie.root_node,
                                              bin_to_nibbles(prefix + '5'), [])
    assert last_node_ == BLANK_NODE

    seen_prefix = []
    trie.update(key2.encode(), rlp_encode(['v2']))
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles,
                                             seen_prfx=seen_prefix)
    # The last node should be an extension since more than 1 key
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert seen_prefix == []

    seen_prefix = []
    trie.update(key3.encode(), rlp_encode(['v3']))
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_nibbles,
                                             seen_prfx=seen_prefix)
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert seen_prefix == []

    last_node_key = without_terminator(unpack_to_nibbles(last_node[0]))
    # Key for the fetched prefix nodes (ignore last nibble) is same as prefix nibbles
    assert last_node_key[:-1] == prefix_nibbles

    # The extension node is correctly decoded.
    decoded_extension = trie._decode_to_node(last_node[1])
    assert decoded_extension[1] == [b' ', rlp_encode(['v1'])]
    assert decoded_extension[2] == [b' ', rlp_encode(['v2'])]
    assert decoded_extension[3] == [b' ', rlp_encode(['v3'])]

    # Add keys with extended prefix
    extended_prefix = '1'
    key4 = prefix + extended_prefix + '85'
    trie.update(key4.encode(), rlp_encode(['v11']))
    key5 = prefix + extended_prefix + '96'
    trie.update(key5.encode(), rlp_encode(['v12']))
    seen_prefix = []
    new_prefix_nibbs = bin_to_nibbles(prefix + extended_prefix)
    last_node = trie._get_last_node_for_prfx(trie.root_node, new_prefix_nibbs,
                                             seen_prfx=seen_prefix)

    assert trie._get_node_type(last_node) == NODE_TYPE_BRANCH
    assert new_prefix_nibbs == seen_prefix
    assert seen_prefix == bin_to_nibbles(prefix + '1')

    # traverse to the next node
    remaining_key4_nibbs = bin_to_nibbles(key4)[len(seen_prefix):]
    remaining_key5_nibbs = bin_to_nibbles(key5)[len(seen_prefix):]
    next_nibble = remaining_key4_nibbs[0] if remaining_key4_nibbs[0] > remaining_key5_nibbs[0] else remaining_key5_nibbs[0]
    next_node = trie._decode_to_node(last_node[next_nibble])

    assert trie._get_node_type(next_node) == NODE_TYPE_BRANCH

    # The 8th index should lead to a node with key '5', key4 ended in '85'
    assert trie._get_node_type(next_node[8]) == NODE_TYPE_LEAF
    assert without_terminator(unpack_to_nibbles(next_node[8][0])) == bin_to_nibbles('5')

    # The 9th index should lead to a node with key '6', key5 ended in '96'
    assert trie._get_node_type(next_node[9]) == NODE_TYPE_LEAF
    assert without_terminator(unpack_to_nibbles(next_node[9][0])) == bin_to_nibbles('6')

    prefix_1 = prefix + 'efgh'
    prefix_1_nibbles = bin_to_nibbles(prefix_1)
    key1 = prefix_1 + '1'
    key2 = prefix_1 + '2'
    key3 = prefix_1 + '3'

    trie.update(key1.encode(), rlp_encode(['v1']))
    trie.update(key2.encode(), rlp_encode(['v1']))
    trie.update(key3.encode(), rlp_encode(['v1']))

    seen_prefix = []
    last_node = trie._get_last_node_for_prfx(trie.root_node, prefix_1_nibbles,
                                             seen_prfx=seen_prefix)
    assert trie._get_node_type(last_node) == NODE_TYPE_EXTENSION
    assert len(seen_prefix) > 0
    assert starts_with(prefix_1_nibbles, seen_prefix)