Source code for redis.client

from itertools import chain
import copy
import datetime
import hashlib
import re
import threading
import time
import warnings
from redis.commands import (CoreCommands, RedisModuleCommands,
                            SentinelCommands, list_or_args)
from redis.connection import (ConnectionPool, UnixDomainSocketConnection,
from redis.lock import Lock
from redis.exceptions import (
from redis.utils import safe_str, str_if_bytes


def timestamp_to_datetime(response):
    "Converts a unix timestamp to a Python datetime object"
    if not response:
        return None
        response = int(response)
    except ValueError:
        return None
    return datetime.datetime.fromtimestamp(response)

def string_keys_to_dict(key_string, callback):
    return dict.fromkeys(key_string.split(), callback)

class CaseInsensitiveDict(dict):
    "Case insensitive dict implementation. Assumes string keys only."

    def __init__(self, data):
        for k, v in data.items():
            self[k.upper()] = v

    def __contains__(self, k):
        return super().__contains__(k.upper())

    def __delitem__(self, k):

    def __getitem__(self, k):
        return super().__getitem__(k.upper())

    def get(self, k, default=None):
        return super().get(k.upper(), default)

    def __setitem__(self, k, v):
        super().__setitem__(k.upper(), v)

    def update(self, data):
        data = CaseInsensitiveDict(data)

def parse_debug_object(response):
    "Parse the results of Redis's DEBUG OBJECT command into a Python dict"
    # The 'type' of the object is the first item in the response, but isn't
    # prefixed with a name
    response = str_if_bytes(response)
    response = 'type:' + response
    response = dict(kv.split(':') for kv in response.split())

    # parse some expected int values from the string response
    # note: this cmd isn't spec'd so these may not appear in all redis versions
    int_fields = ('refcount', 'serializedlength', 'lru', 'lru_seconds_idle')
    for field in int_fields:
        if field in response:
            response[field] = int(response[field])

    return response

def parse_object(response, infotype):
    "Parse the results of an OBJECT command"
    if infotype in ('idletime', 'refcount'):
        return int_or_none(response)
    return response

def parse_info(response):
    "Parse the result of Redis's INFO command into a Python dict"
    info = {}
    response = str_if_bytes(response)

    def get_value(value):
        if ',' not in value or '=' not in value:
                if '.' in value:
                    return float(value)
                    return int(value)
            except ValueError:
                return value
            sub_dict = {}
            for item in value.split(','):
                k, v = item.rsplit('=', 1)
                sub_dict[k] = get_value(v)
            return sub_dict

    for line in response.splitlines():
        if line and not line.startswith('#'):
            if line.find(':') != -1:
                # Split, the info fields keys and values.
                # Note that the value may contain ':'. but the 'host:'
                # pseudo-command is the only case where the key contains ':'
                key, value = line.split(':', 1)
                if key == 'cmdstat_host':
                    key, value = line.rsplit(':', 1)

                if key == 'module':
                    # Hardcode a list for key 'modules' since there could be
                    # multiple lines that started with 'module'
                    info.setdefault('modules', []).append(get_value(value))
                    info[key] = get_value(value)
                # if the line isn't splittable, append it to the "__raw__" key
                info.setdefault('__raw__', []).append(line)

    return info

def parse_memory_stats(response, **kwargs):
    "Parse the results of MEMORY STATS"
    stats = pairs_to_dict(response,
    for key, value in stats.items():
        if key.startswith('db.'):
            stats[key] = pairs_to_dict(value,
    return stats

    'can-failover-its-master': int,
    'config-epoch': int,
    'down-after-milliseconds': int,
    'failover-timeout': int,
    'info-refresh': int,
    'last-hello-message': int,
    'last-ok-ping-reply': int,
    'last-ping-reply': int,
    'last-ping-sent': int,
    'master-link-down-time': int,
    'master-port': int,
    'num-other-sentinels': int,
    'num-slaves': int,
    'o-down-time': int,
    'pending-commands': int,
    'parallel-syncs': int,
    'port': int,
    'quorum': int,
    'role-reported-time': int,
    's-down-time': int,
    'slave-priority': int,
    'slave-repl-offset': int,
    'voted-leader-epoch': int

def parse_sentinel_state(item):
    result = pairs_to_dict_typed(item, SENTINEL_STATE_TYPES)
    flags = set(result['flags'].split(','))
    for name, flag in (('is_master', 'master'), ('is_slave', 'slave'),
                       ('is_sdown', 's_down'), ('is_odown', 'o_down'),
                       ('is_sentinel', 'sentinel'),
                       ('is_disconnected', 'disconnected'),
                       ('is_master_down', 'master_down')):
        result[name] = flag in flags
    return result

def parse_sentinel_master(response):
    return parse_sentinel_state(map(str_if_bytes, response))

def parse_sentinel_masters(response):
    result = {}
    for item in response:
        state = parse_sentinel_state(map(str_if_bytes, item))
        result[state['name']] = state
    return result

def parse_sentinel_slaves_and_sentinels(response):
    return [parse_sentinel_state(map(str_if_bytes, item)) for item in response]

def parse_sentinel_get_master(response):
    return response and (response[0], int(response[1])) or None

def pairs_to_dict(response, decode_keys=False, decode_string_values=False):
    "Create a dict given a list of key/value pairs"
    if response is None:
        return {}
    if decode_keys or decode_string_values:
        # the iter form is faster, but I don't know how to make that work
        # with a str_if_bytes() map
        keys = response[::2]
        if decode_keys:
            keys = map(str_if_bytes, keys)
        values = response[1::2]
        if decode_string_values:
            values = map(str_if_bytes, values)
        return dict(zip(keys, values))
        it = iter(response)
        return dict(zip(it, it))

def pairs_to_dict_typed(response, type_info):
    it = iter(response)
    result = {}
    for key, value in zip(it, it):
        if key in type_info:
                value = type_info[key](value)
            except Exception:
                # if for some reason the value can't be coerced, just use
                # the string value
        result[key] = value
    return result

def zset_score_pairs(response, **options):
    If ``withscores`` is specified in the options, return the response as
    a list of (value, score) pairs
    if not response or not options.get('withscores'):
        return response
    score_cast_func = options.get('score_cast_func', float)
    it = iter(response)
    return list(zip(it, map(score_cast_func, it)))

def sort_return_tuples(response, **options):
    If ``groups`` is specified, return the response as a list of
    n-element tuples with n being the value found in options['groups']
    if not response or not options.get('groups'):
        return response
    n = options['groups']
    return list(zip(*[response[i::n] for i in range(n)]))

def int_or_none(response):
    if response is None:
        return None
    return int(response)

def parse_stream_list(response):
    if response is None:
        return None
    data = []
    for r in response:
        if r is not None:
            data.append((r[0], pairs_to_dict(r[1])))
            data.append((None, None))
    return data

def pairs_to_dict_with_str_keys(response):
    return pairs_to_dict(response, decode_keys=True)

def parse_list_of_dicts(response):
    return list(map(pairs_to_dict_with_str_keys, response))

def parse_xclaim(response, **options):
    if options.get('parse_justid', False):
        return response
    return parse_stream_list(response)

def parse_xautoclaim(response, **options):
    if options.get('parse_justid', False):
        return response[1]
    return parse_stream_list(response[1])

def parse_xinfo_stream(response, **options):
    data = pairs_to_dict(response, decode_keys=True)
    if not options.get('full', False):
        first = data['first-entry']
        if first is not None:
            data['first-entry'] = (first[0], pairs_to_dict(first[1]))
        last = data['last-entry']
        if last is not None:
            data['last-entry'] = (last[0], pairs_to_dict(last[1]))
        data['entries'] = {
            _id: pairs_to_dict(entry)
            for _id, entry in data['entries']
        data['groups'] = [
            pairs_to_dict(group, decode_keys=True)
            for group in data['groups']
    return data

def parse_xread(response):
    if response is None:
        return []
    return [[r[0], parse_stream_list(r[1])] for r in response]

def parse_xpending(response, **options):
    if options.get('parse_detail', False):
        return parse_xpending_range(response)
    consumers = [{'name': n, 'pending': int(p)} for n, p in response[3] or []]
    return {
        'pending': response[0],
        'min': response[1],
        'max': response[2],
        'consumers': consumers

def parse_xpending_range(response):
    k = ('message_id', 'consumer', 'time_since_delivered', 'times_delivered')
    return [dict(zip(k, r)) for r in response]

def float_or_none(response):
    if response is None:
        return None
    return float(response)

def bool_ok(response):
    return str_if_bytes(response) == 'OK'

def parse_zadd(response, **options):
    if response is None:
        return None
    if options.get('as_score'):
        return float(response)
    return int(response)

def parse_client_list(response, **options):
    clients = []
    for c in str_if_bytes(response).splitlines():
        # Values might contain '='
        clients.append(dict(pair.split('=', 1) for pair in c.split(' ')))
    return clients

def parse_config_get(response, **options):
    response = [str_if_bytes(i) if i is not None else None for i in response]
    return response and pairs_to_dict(response) or {}

def parse_scan(response, **options):
    cursor, r = response
    return int(cursor), r

def parse_hscan(response, **options):
    cursor, r = response
    return int(cursor), r and pairs_to_dict(r) or {}

def parse_zscan(response, **options):
    score_cast_func = options.get('score_cast_func', float)
    cursor, r = response
    it = iter(r)
    return int(cursor), list(zip(it, map(score_cast_func, it)))

def parse_zmscore(response, **options):
    # zmscore: list of scores (double precision floating point number) or nil
    return [float(score) if score is not None else None for score in response]

def parse_slowlog_get(response, **options):
    space = ' ' if options.get('decode_responses', False) else b' '

    def parse_item(item):
        result = {
            'id': item[0],
            'start_time': int(item[1]),
            'duration': int(item[2]),
        # Redis Enterprise injects another entry at index [3], which has
        # the complexity info (i.e. the value N in case the command has
        # an O(N) complexity) instead of the command.
        if isinstance(item[3], list):
            result['command'] = space.join(item[3])
            result['complexity'] = item[3]
            result['command'] = space.join(item[4])
        return result
    return [parse_item(item) for item in response]

def parse_stralgo(response, **options):
    Parse the response from `STRALGO` command.
    Without modifiers the returned value is string.
    When LEN is given the command returns the length of the result
    (i.e integer).
    When IDX is given the command returns a dictionary with the LCS
    length and all the ranges in both the strings, start and end
    offset for each string, where there are matches.
    When WITHMATCHLEN is given, each array representing a match will
    also have the length of the match at the beginning of the array.
    if options.get('len', False):
        return int(response)
    if options.get('idx', False):
        if options.get('withmatchlen', False):
            matches = [[(int(match[-1]))] + list(map(tuple, match[:-1]))
                       for match in response[1]]
            matches = [list(map(tuple, match))
                       for match in response[1]]
        return {
            str_if_bytes(response[0]): matches,
            str_if_bytes(response[2]): int(response[3])
    return str_if_bytes(response)

def parse_cluster_info(response, **options):
    response = str_if_bytes(response)
    return dict(line.split(':') for line in response.splitlines() if line)

def _parse_node_line(line):
    line_items = line.split(' ')
    node_id, addr, flags, master_id, ping, pong, epoch, \
        connected = line.split(' ')[:8]
    slots = [sl.split('-') for sl in line_items[8:]]
    node_dict = {
        'node_id': node_id,
        'flags': flags,
        'master_id': master_id,
        'last_ping_sent': ping,
        'last_pong_rcvd': pong,
        'epoch': epoch,
        'slots': slots,
        'connected': True if connected == 'connected' else False
    return addr, node_dict

def parse_cluster_nodes(response, **options):
    raw_lines = str_if_bytes(response).splitlines()
    return dict(_parse_node_line(line) for line in raw_lines)

def parse_geosearch_generic(response, **options):
    Parse the response of 'GEOSEARCH', GEORADIUS' and 'GEORADIUSBYMEMBER'
    commands according to 'withdist', 'withhash' and 'withcoord' labels.
    if options['store'] or options['store_dist']:
        # `store` and `store_dist` cant be combined
        # with other command arguments.
        # relevant to 'GEORADIUS' and 'GEORADIUSBYMEMBER'
        return response

    if type(response) != list:
        response_list = [response]
        response_list = response

    if not options['withdist'] and not options['withcoord'] \
            and not options['withhash']:
        # just a bunch of places
        return response_list

    cast = {
        'withdist': float,
        'withcoord': lambda ll: (float(ll[0]), float(ll[1])),
        'withhash': int

    # zip all output results with each casting function to get
    # the properly native Python value.
    f = [lambda x: x]
    f += [cast[o] for o in ['withdist', 'withhash', 'withcoord'] if options[o]]
    return [
        list(map(lambda fv: fv[0](fv[1]), zip(f, r))) for r in response_list

def parse_pubsub_numsub(response, **options):
    return list(zip(response[0::2], response[1::2]))

def parse_client_kill(response, **options):
    if isinstance(response, int):
        return response
    return str_if_bytes(response) == 'OK'

def parse_acl_getuser(response, **options):
    if response is None:
        return None
    data = pairs_to_dict(response, decode_keys=True)

    # convert everything but user-defined data in 'keys' to native strings
    data['flags'] = list(map(str_if_bytes, data['flags']))
    data['passwords'] = list(map(str_if_bytes, data['passwords']))
    data['commands'] = str_if_bytes(data['commands'])

    # split 'commands' into separate 'categories' and 'commands' lists
    commands, categories = [], []
    for command in data['commands'].split(' '):
        if '@' in command:

    data['commands'] = commands
    data['categories'] = categories
    data['enabled'] = 'on' in data['flags']
    return data

def parse_acl_log(response, **options):
    if response is None:
        return None
    if isinstance(response, list):
        data = []
        for log in response:
            log_data = pairs_to_dict(log, True, True)
            client_info = log_data.get('client-info', '')
            log_data["client-info"] = parse_client_info(client_info)

            # float() is lossy comparing to the "double" in C
            log_data["age-seconds"] = float(log_data["age-seconds"])
        data = bool_ok(response)
    return data

def parse_client_info(value):
    Parsing client-info in ACL Log in following format.
    "key1=value1 key2=value2 key3=value3"
    client_info = {}
    infos = str_if_bytes(value).split(" ")
    for info in infos:
        key, value = info.split("=")
        client_info[key] = value

    # Those fields are defined as int in networking.c
    for int_key in {"id", "age", "idle", "db", "sub", "psub",
                    "multi", "qbuf", "qbuf-free", "obl",
                    "argv-mem", "oll", "omem", "tot-mem"}:
        client_info[int_key] = int(client_info[int_key])
    return client_info

def parse_module_result(response):
    if isinstance(response, ModuleError):
        raise response
    return True

def parse_set_result(response, **options):
    Handle SET result since GET argument is available since Redis 6.2.
    Parsing SET result into:
    - BOOL
    - String when GET argument is used
    if options.get('get'):
        # Redis will return a getCommand result.
        # See `setGenericCommand` in t_string.c
        return response
    return response and str_if_bytes(response) == 'OK'

[docs]class Redis(RedisModuleCommands, CoreCommands, SentinelCommands, object): """ Implementation of the Redis protocol. This abstract class provides a Python interface to all Redis commands and an implementation of the Redis protocol. Pipelines derive from this, implementing how the commands are sent and received to the Redis server. Based on configuration, an instance will either use a ConnectionPool, or Connection object to talk to redis. """ RESPONSE_CALLBACKS = { **string_keys_to_dict( 'AUTH COPY EXPIRE EXPIREAT PEXPIRE PEXPIREAT ' 'HEXISTS HMSET LMOVE BLMOVE MOVE ' 'MSETNX PERSIST PSETEX RENAMENX SISMEMBER SMOVE SETEX SETNX', bool ), **string_keys_to_dict( 'BITCOUNT BITPOS DECRBY DEL EXISTS GEOADD GETBIT HDEL HLEN ' 'HSTRLEN INCRBY LINSERT LLEN LPUSHX PFADD PFCOUNT RPUSHX SADD ' 'SCARD SDIFFSTORE SETBIT SETRANGE SINTERSTORE SREM STRLEN ' 'SUNIONSTORE UNLINK XACK XDEL XLEN XTRIM ZCARD ZLEXCOUNT ZREM ' 'ZREMRANGEBYLEX ZREMRANGEBYRANK ZREMRANGEBYSCORE', int ), **string_keys_to_dict( 'INCRBYFLOAT HINCRBYFLOAT', float ), **string_keys_to_dict( # these return OK, or int if redis-server is >=1.3.4 'LPUSH RPUSH', lambda r: isinstance(r, int) and r or str_if_bytes(r) == 'OK' ), **string_keys_to_dict('SORT', sort_return_tuples), **string_keys_to_dict('ZSCORE ZINCRBY GEODIST', float_or_none), **string_keys_to_dict( 'FLUSHALL FLUSHDB LSET LTRIM MSET PFMERGE READONLY READWRITE ' 'RENAME SAVE SELECT SHUTDOWN SLAVEOF SWAPDB WATCH UNWATCH ', bool_ok ), **string_keys_to_dict('BLPOP BRPOP', lambda r: r and tuple(r) or None), **string_keys_to_dict( 'SDIFF SINTER SMEMBERS SUNION', lambda r: r and set(r) or set() ), **string_keys_to_dict( 'ZPOPMAX ZPOPMIN ZINTER ZDIFF ZUNION ZRANGE ZRANGEBYSCORE ' 'ZREVRANGE ZREVRANGEBYSCORE', zset_score_pairs ), **string_keys_to_dict('BZPOPMIN BZPOPMAX', \ lambda r: r and (r[0], r[1], float(r[2])) or None), **string_keys_to_dict('ZRANK ZREVRANK', int_or_none), **string_keys_to_dict('XREVRANGE XRANGE', parse_stream_list), **string_keys_to_dict('XREAD XREADGROUP', parse_xread), **string_keys_to_dict('BGREWRITEAOF BGSAVE', lambda r: True), 'ACL CAT': lambda r: list(map(str_if_bytes, r)), 'ACL DELUSER': int, 'ACL GENPASS': str_if_bytes, 'ACL GETUSER': parse_acl_getuser, 'ACL HELP': lambda r: list(map(str_if_bytes, r)), 'ACL LIST': lambda r: list(map(str_if_bytes, r)), 'ACL LOAD': bool_ok, 'ACL LOG': parse_acl_log, 'ACL SAVE': bool_ok, 'ACL SETUSER': bool_ok, 'ACL USERS': lambda r: list(map(str_if_bytes, r)), 'ACL WHOAMI': str_if_bytes, 'CLIENT GETNAME': str_if_bytes, 'CLIENT ID': int, 'CLIENT KILL': parse_client_kill, 'CLIENT LIST': parse_client_list, 'CLIENT INFO': parse_client_info, 'CLIENT SETNAME': bool_ok, 'CLIENT UNBLOCK': lambda r: r and int(r) == 1 or False, 'CLIENT PAUSE': bool_ok, 'CLIENT GETREDIR': int, 'CLIENT TRACKINGINFO': lambda r: list(map(str_if_bytes, r)), 'CLUSTER ADDSLOTS': bool_ok, 'CLUSTER COUNT-FAILURE-REPORTS': lambda x: int(x), 'CLUSTER COUNTKEYSINSLOT': lambda x: int(x), 'CLUSTER DELSLOTS': bool_ok, 'CLUSTER FAILOVER': bool_ok, 'CLUSTER FORGET': bool_ok, 'CLUSTER INFO': parse_cluster_info, 'CLUSTER KEYSLOT': lambda x: int(x), 'CLUSTER MEET': bool_ok, 'CLUSTER NODES': parse_cluster_nodes, 'CLUSTER REPLICATE': bool_ok, 'CLUSTER RESET': bool_ok, 'CLUSTER SAVECONFIG': bool_ok, 'CLUSTER SET-CONFIG-EPOCH': bool_ok, 'CLUSTER SETSLOT': bool_ok, 'CLUSTER SLAVES': parse_cluster_nodes, 'COMMAND COUNT': int, 'CONFIG GET': parse_config_get, 'CONFIG RESETSTAT': bool_ok, 'CONFIG SET': bool_ok, 'DEBUG OBJECT': parse_debug_object, 'GEOHASH': lambda r: list(map(str_if_bytes, r)), 'GEOPOS': lambda r: list(map(lambda ll: (float(ll[0]), float(ll[1])) if ll is not None else None, r)), 'GEOSEARCH': parse_geosearch_generic, 'GEORADIUS': parse_geosearch_generic, 'GEORADIUSBYMEMBER': parse_geosearch_generic, 'HGETALL': lambda r: r and pairs_to_dict(r) or {}, 'HSCAN': parse_hscan, 'INFO': parse_info, 'LASTSAVE': timestamp_to_datetime, 'MEMORY PURGE': bool_ok, 'MEMORY STATS': parse_memory_stats, 'MEMORY USAGE': int_or_none, 'MODULE LOAD': parse_module_result, 'MODULE UNLOAD': parse_module_result, 'MODULE LIST': lambda r: [pairs_to_dict(m) for m in r], 'OBJECT': parse_object, 'PING': lambda r: str_if_bytes(r) == 'PONG', 'QUIT': bool_ok, 'STRALGO': parse_stralgo, 'PUBSUB NUMSUB': parse_pubsub_numsub, 'RANDOMKEY': lambda r: r and r or None, 'SCAN': parse_scan, 'SCRIPT EXISTS': lambda r: list(map(bool, r)), 'SCRIPT FLUSH': bool_ok, 'SCRIPT KILL': bool_ok, 'SCRIPT LOAD': str_if_bytes, 'SENTINEL CKQUORUM': bool_ok, 'SENTINEL FAILOVER': bool_ok, 'SENTINEL FLUSHCONFIG': bool_ok, 'SENTINEL GET-MASTER-ADDR-BY-NAME': parse_sentinel_get_master, 'SENTINEL MASTER': parse_sentinel_master, 'SENTINEL MASTERS': parse_sentinel_masters, 'SENTINEL MONITOR': bool_ok, 'SENTINEL RESET': bool_ok, 'SENTINEL REMOVE': bool_ok, 'SENTINEL SENTINELS': parse_sentinel_slaves_and_sentinels, 'SENTINEL SET': bool_ok, 'SENTINEL SLAVES': parse_sentinel_slaves_and_sentinels, 'SET': parse_set_result, 'SLOWLOG GET': parse_slowlog_get, 'SLOWLOG LEN': int, 'SLOWLOG RESET': bool_ok, 'SSCAN': parse_scan, 'TIME': lambda x: (int(x[0]), int(x[1])), 'XCLAIM': parse_xclaim, 'XAUTOCLAIM': parse_xautoclaim, 'XGROUP CREATE': bool_ok, 'XGROUP DELCONSUMER': int, 'XGROUP DESTROY': bool, 'XGROUP SETID': bool_ok, 'XINFO CONSUMERS': parse_list_of_dicts, 'XINFO GROUPS': parse_list_of_dicts, 'XINFO STREAM': parse_xinfo_stream, 'XPENDING': parse_xpending, 'ZADD': parse_zadd, 'ZSCAN': parse_zscan, 'ZMSCORE': parse_zmscore, }
[docs] @classmethod def from_url(cls, url, **kwargs): """ Return a Redis client object configured from the given URL For example:: redis://[[username]:[password]]@localhost:6379/0 rediss://[[username]:[password]]@localhost:6379/0 unix://[[username]:[password]]@/path/to/socket.sock?db=0 Three URL schemes are supported: - `redis://` creates a TCP socket connection. See more at: <> - `rediss://` creates a SSL wrapped TCP socket connection. See more at: <> - ``unix://``: creates a Unix Domain Socket connection. The username, password, hostname, path and all querystring values are passed through urllib.parse.unquote in order to replace any percent-encoded values with their corresponding characters. There are several ways to specify a database number. The first value found will be used: 1. A ``db`` querystring option, e.g. redis://localhost?db=0 2. If using the redis:// or rediss:// schemes, the path argument of the url, e.g. redis://localhost/0 3. A ``db`` keyword argument to this function. If none of these options are specified, the default db=0 is used. All querystring options are cast to their appropriate Python types. Boolean arguments can be specified with string values "True"/"False" or "Yes"/"No". Values that cannot be properly cast cause a ``ValueError`` to be raised. Once parsed, the querystring arguments and keyword arguments are passed to the ``ConnectionPool``'s class initializer. In the case of conflicting arguments, querystring arguments always win. """ connection_pool = ConnectionPool.from_url(url, **kwargs) return cls(connection_pool=connection_pool)
def __init__(self, host='localhost', port=6379, db=0, password=None, socket_timeout=None, socket_connect_timeout=None, socket_keepalive=None, socket_keepalive_options=None, connection_pool=None, unix_socket_path=None, encoding='utf-8', encoding_errors='strict', charset=None, errors=None, decode_responses=False, retry_on_timeout=False, ssl=False, ssl_keyfile=None, ssl_certfile=None, ssl_cert_reqs='required', ssl_ca_certs=None, ssl_check_hostname=False, max_connections=None, single_connection_client=False, health_check_interval=0, client_name=None, username=None, retry=None): """ Initialize a new Redis client. To specify a retry policy, first set `retry_on_timeout` to `True` then set `retry` to a valid `Retry` object """ if not connection_pool: if charset is not None: warnings.warn(DeprecationWarning( '"charset" is deprecated. Use "encoding" instead')) encoding = charset if errors is not None: warnings.warn(DeprecationWarning( '"errors" is deprecated. Use "encoding_errors" instead')) encoding_errors = errors kwargs = { 'db': db, 'username': username, 'password': password, 'socket_timeout': socket_timeout, 'encoding': encoding, 'encoding_errors': encoding_errors, 'decode_responses': decode_responses, 'retry_on_timeout': retry_on_timeout, 'retry': copy.deepcopy(retry), 'max_connections': max_connections, 'health_check_interval': health_check_interval, 'client_name': client_name } # based on input, setup appropriate connection args if unix_socket_path is not None: kwargs.update({ 'path': unix_socket_path, 'connection_class': UnixDomainSocketConnection }) else: # TCP specific options kwargs.update({ 'host': host, 'port': port, 'socket_connect_timeout': socket_connect_timeout, 'socket_keepalive': socket_keepalive, 'socket_keepalive_options': socket_keepalive_options, }) if ssl: kwargs.update({ 'connection_class': SSLConnection, 'ssl_keyfile': ssl_keyfile, 'ssl_certfile': ssl_certfile, 'ssl_cert_reqs': ssl_cert_reqs, 'ssl_ca_certs': ssl_ca_certs, 'ssl_check_hostname': ssl_check_hostname, }) connection_pool = ConnectionPool(**kwargs) self.connection_pool = connection_pool self.connection = None if single_connection_client: self.connection = self.connection_pool.get_connection('_') self.response_callbacks = CaseInsensitiveDict( self.__class__.RESPONSE_CALLBACKS) def __repr__(self): return "%s<%s>" % (type(self).__name__, repr(self.connection_pool))
[docs] def set_response_callback(self, command, callback): "Set a custom Response Callback" self.response_callbacks[command] = callback
[docs] def load_external_module(self, funcname, func, ): """ This function can be used to add externally defined redis modules, and their namespaces to the redis client. funcname - A string containing the name of the function to create func - The function, being added to this class. ex: Assume that one has a custom redis module named foomod that creates command named 'foo.dothing' and 'foo.anotherthing' in redis. To load function functions into this namespace: from redis import Redis from foomodule import F r = Redis() r.load_external_module("foo", F)'your', 'arguments') For a concrete example see the reimport of the redisjson module in tests/ """ setattr(self, funcname, func)
[docs] def pipeline(self, transaction=True, shard_hint=None): """ Return a new pipeline object that can queue multiple commands for later execution. ``transaction`` indicates whether all commands should be executed atomically. Apart from making a group of operations atomic, pipelines are useful for reducing the back-and-forth overhead between the client and server. """ return Pipeline( self.connection_pool, self.response_callbacks, transaction, shard_hint)
[docs] def transaction(self, func, *watches, **kwargs): """ Convenience method for executing the callable `func` as a transaction while watching all keys specified in `watches`. The 'func' callable should expect a single argument which is a Pipeline object. """ shard_hint = kwargs.pop('shard_hint', None) value_from_callable = kwargs.pop('value_from_callable', False) watch_delay = kwargs.pop('watch_delay', None) with self.pipeline(True, shard_hint) as pipe: while True: try: if watches:*watches) func_value = func(pipe) exec_value = pipe.execute() return func_value if value_from_callable else exec_value except WatchError: if watch_delay is not None and watch_delay > 0: time.sleep(watch_delay) continue
[docs] def lock(self, name, timeout=None, sleep=0.1, blocking_timeout=None, lock_class=None, thread_local=True): """ Return a new Lock object using key ``name`` that mimics the behavior of threading.Lock. If specified, ``timeout`` indicates a maximum life for the lock. By default, it will remain locked until release() is called. ``sleep`` indicates the amount of time to sleep per loop iteration when the lock is in blocking mode and another client is currently holding the lock. ``blocking_timeout`` indicates the maximum amount of time in seconds to spend trying to acquire the lock. A value of ``None`` indicates continue trying forever. ``blocking_timeout`` can be specified as a float or integer, both representing the number of seconds to wait. ``lock_class`` forces the specified lock implementation. ``thread_local`` indicates whether the lock token is placed in thread-local storage. By default, the token is placed in thread local storage so that a thread only sees its token, not a token set by another thread. Consider the following timeline: time: 0, thread-1 acquires `my-lock`, with a timeout of 5 seconds. thread-1 sets the token to "abc" time: 1, thread-2 blocks trying to acquire `my-lock` using the Lock instance. time: 5, thread-1 has not yet completed. redis expires the lock key. time: 5, thread-2 acquired `my-lock` now that it's available. thread-2 sets the token to "xyz" time: 6, thread-1 finishes its work and calls release(). if the token is *not* stored in thread local storage, then thread-1 would see the token value as "xyz" and would be able to successfully release the thread-2's lock. In some use cases it's necessary to disable thread local storage. For example, if you have code where one thread acquires a lock and passes that lock instance to a worker thread to release later. If thread local storage isn't disabled in this case, the worker thread won't see the token set by the thread that acquired the lock. Our assumption is that these cases aren't common and as such default to using thread local storage. """ if lock_class is None: lock_class = Lock return lock_class(self, name, timeout=timeout, sleep=sleep, blocking_timeout=blocking_timeout, thread_local=thread_local)
[docs] def pubsub(self, **kwargs): """ Return a Publish/Subscribe object. With this object, you can subscribe to channels and listen for messages that get published to them. """ return PubSub(self.connection_pool, **kwargs)
def monitor(self): return Monitor(self.connection_pool) def client(self): return self.__class__(connection_pool=self.connection_pool, single_connection_client=True) def __enter__(self): return self def __exit__(self, exc_type, exc_value, traceback): self.close() def __del__(self): self.close() def close(self): conn = self.connection if conn: self.connection = None self.connection_pool.release(conn) def _send_command_parse_response(self, conn, command_name, *args, **options): """ Send a command and parse the response """ conn.send_command(*args) return self.parse_response(conn, command_name, **options) def _disconnect_raise(self, conn, error): """ Close the connection and raise an exception if retry_on_timeout is not set or the error is not a TimeoutError """ conn.disconnect() if not (conn.retry_on_timeout and isinstance(error, TimeoutError)): raise error # COMMAND EXECUTION AND PROTOCOL PARSING
[docs] def execute_command(self, *args, **options): "Execute a command and return a parsed response" pool = self.connection_pool command_name = args[0] conn = self.connection or pool.get_connection(command_name, **options) try: return conn.retry.call_with_retry( lambda: self._send_command_parse_response(conn, command_name, *args, **options), lambda error: self._disconnect_raise(conn, error)) finally: if not self.connection: pool.release(conn)
[docs] def parse_response(self, connection, command_name, **options): "Parses a response from the Redis server" try: response = connection.read_response() except ResponseError: if EMPTY_RESPONSE in options: return options[EMPTY_RESPONSE] raise if command_name in self.response_callbacks: return self.response_callbacks[command_name](response, **options) return response
StrictRedis = Redis class Monitor: """ Monitor is useful for handling the MONITOR command to the redis server. next_command() method returns one command from monitor listen() method yields commands from monitor. """ monitor_re = re.compile(r'\[(\d+) (.*)\] (.*)') command_re = re.compile(r'"(.*?)(?<!\\)"') def __init__(self, connection_pool): self.connection_pool = connection_pool self.connection = self.connection_pool.get_connection('MONITOR') def __enter__(self): self.connection.send_command('MONITOR') # check that monitor returns 'OK', but don't return it to user response = self.connection.read_response() if not bool_ok(response): raise RedisError('MONITOR failed: %s' % response) return self def __exit__(self, *args): self.connection.disconnect() self.connection_pool.release(self.connection) def next_command(self): "Parse the response from a monitor command" response = self.connection.read_response() if isinstance(response, bytes): response = self.connection.encoder.decode(response, force=True) command_time, command_data = response.split(' ', 1) m = self.monitor_re.match(command_data) db_id, client_info, command = m.groups() command = ' '.join(self.command_re.findall(command)) # Redis escapes double quotes because each piece of the command # string is surrounded by double quotes. We don't have that # requirement so remove the escaping and leave the quote. command = command.replace('\\"', '"') if client_info == 'lua': client_address = 'lua' client_port = '' client_type = 'lua' elif client_info.startswith('unix'): client_address = 'unix' client_port = client_info[5:] client_type = 'unix' else: # use rsplit as ipv6 addresses contain colons client_address, client_port = client_info.rsplit(':', 1) client_type = 'tcp' return { 'time': float(command_time), 'db': int(db_id), 'client_address': client_address, 'client_port': client_port, 'client_type': client_type, 'command': command } def listen(self): "Listen for commands coming to the server." while True: yield self.next_command() class PubSub: """ PubSub provides publish, subscribe and listen support to Redis channels. After subscribing to one or more channels, the listen() method will block until a message arrives on one of the subscribed channels. That message will be returned and it's safe to start listening again. """ PUBLISH_MESSAGE_TYPES = ('message', 'pmessage') UNSUBSCRIBE_MESSAGE_TYPES = ('unsubscribe', 'punsubscribe') HEALTH_CHECK_MESSAGE = 'redis-py-health-check' def __init__(self, connection_pool, shard_hint=None, ignore_subscribe_messages=False): self.connection_pool = connection_pool self.shard_hint = shard_hint self.ignore_subscribe_messages = ignore_subscribe_messages self.connection = None # we need to know the encoding options for this connection in order # to lookup channel and pattern names for callback handlers. self.encoder = self.connection_pool.get_encoder() if self.encoder.decode_responses: self.health_check_response = ['pong', self.HEALTH_CHECK_MESSAGE] else: self.health_check_response = [ b'pong', self.encoder.encode(self.HEALTH_CHECK_MESSAGE) ] self.reset() def __enter__(self): return self def __exit__(self, exc_type, exc_value, traceback): self.reset() def __del__(self): try: # if this object went out of scope prior to shutting down # subscriptions, close the connection manually before # returning it to the connection pool self.reset() except Exception: pass def reset(self): if self.connection: self.connection.disconnect() self.connection.clear_connect_callbacks() self.connection_pool.release(self.connection) self.connection = None self.channels = {} self.pending_unsubscribe_channels = set() self.patterns = {} self.pending_unsubscribe_patterns = set() def close(self): self.reset() def on_connect(self, connection): "Re-subscribe to any channels and patterns previously subscribed to" # NOTE: for python3, we can't pass bytestrings as keyword arguments # so we need to decode channel/pattern names back to unicode strings # before passing them to [p]subscribe. self.pending_unsubscribe_channels.clear() self.pending_unsubscribe_patterns.clear() if self.channels: channels = {} for k, v in self.channels.items(): channels[self.encoder.decode(k, force=True)] = v self.subscribe(**channels) if self.patterns: patterns = {} for k, v in self.patterns.items(): patterns[self.encoder.decode(k, force=True)] = v self.psubscribe(**patterns) @property def subscribed(self): "Indicates if there are subscriptions to any channels or patterns" return bool(self.channels or self.patterns) def execute_command(self, *args): "Execute a publish/subscribe command" # NOTE: don't parse the response in this function -- it could pull a # legitimate message off the stack if the connection is already # subscribed to one or more channels if self.connection is None: self.connection = self.connection_pool.get_connection( 'pubsub', self.shard_hint ) # register a callback that re-subscribes to any channels we # were listening to when we were disconnected self.connection.register_connect_callback(self.on_connect) connection = self.connection kwargs = {'check_health': not self.subscribed} self._execute(connection, connection.send_command, *args, **kwargs) def _disconnect_raise_connect(self, conn, error): """ Close the connection and raise an exception if retry_on_timeout is not set or the error is not a TimeoutError. Otherwise, try to reconnect """ conn.disconnect() if not (conn.retry_on_timeout and isinstance(error, TimeoutError)): raise error conn.connect() def _execute(self, conn, command, *args, **kwargs): """ Connect manually upon disconnection. If the Redis server is down, this will fail and raise a ConnectionError as desired. After reconnection, the ``on_connect`` callback should have been called by the # connection to resubscribe us to any channels and patterns we were previously listening to """ return conn.retry.call_with_retry( lambda: command(*args, **kwargs), lambda error: self._disconnect_raise_connect(conn, error)) def parse_response(self, block=True, timeout=0): """Parse the response from a publish/subscribe command""" conn = self.connection if conn is None: raise RuntimeError( 'pubsub connection not set: ' 'did you forget to call subscribe() or psubscribe()?') self.check_health() if( not block and not self._execute(conn, conn.can_read, timeout=timeout) ): return None response = self._execute(conn, conn.read_response) if conn.health_check_interval and \ response == self.health_check_response: # ignore the health check message as user might not expect it return None return response def check_health(self): conn = self.connection if conn is None: raise RuntimeError( 'pubsub connection not set: ' 'did you forget to call subscribe() or psubscribe()?') if conn.health_check_interval and time.time() > conn.next_health_check: conn.send_command('PING', self.HEALTH_CHECK_MESSAGE, check_health=False) def _normalize_keys(self, data): """ normalize channel/pattern names to be either bytes or strings based on whether responses are automatically decoded. this saves us from coercing the value for each message coming in. """ encode = self.encoder.encode decode = self.encoder.decode return {decode(encode(k)): v for k, v in data.items()} def psubscribe(self, *args, **kwargs): """ Subscribe to channel patterns. Patterns supplied as keyword arguments expect a pattern name as the key and a callable as the value. A pattern's callable will be invoked automatically when a message is received on that pattern rather than producing a message via ``listen()``. """ if args: args = list_or_args(args[0], args[1:]) new_patterns = dict.fromkeys(args) new_patterns.update(kwargs) ret_val = self.execute_command('PSUBSCRIBE', *new_patterns.keys()) # update the patterns dict AFTER we send the command. we don't want to # subscribe twice to these patterns, once for the command and again # for the reconnection. new_patterns = self._normalize_keys(new_patterns) self.patterns.update(new_patterns) self.pending_unsubscribe_patterns.difference_update(new_patterns) return ret_val def punsubscribe(self, *args): """ Unsubscribe from the supplied patterns. If empty, unsubscribe from all patterns. """ if args: args = list_or_args(args[0], args[1:]) patterns = self._normalize_keys(dict.fromkeys(args)) else: patterns = self.patterns self.pending_unsubscribe_patterns.update(patterns) return self.execute_command('PUNSUBSCRIBE', *args) def subscribe(self, *args, **kwargs): """ Subscribe to channels. Channels supplied as keyword arguments expect a channel name as the key and a callable as the value. A channel's callable will be invoked automatically when a message is received on that channel rather than producing a message via ``listen()`` or ``get_message()``. """ if args: args = list_or_args(args[0], args[1:]) new_channels = dict.fromkeys(args) new_channels.update(kwargs) ret_val = self.execute_command('SUBSCRIBE', *new_channels.keys()) # update the channels dict AFTER we send the command. we don't want to # subscribe twice to these channels, once for the command and again # for the reconnection. new_channels = self._normalize_keys(new_channels) self.channels.update(new_channels) self.pending_unsubscribe_channels.difference_update(new_channels) return ret_val def unsubscribe(self, *args): """ Unsubscribe from the supplied channels. If empty, unsubscribe from all channels """ if args: args = list_or_args(args[0], args[1:]) channels = self._normalize_keys(dict.fromkeys(args)) else: channels = self.channels self.pending_unsubscribe_channels.update(channels) return self.execute_command('UNSUBSCRIBE', *args) def listen(self): "Listen for messages on channels this client has been subscribed to" while self.subscribed: response = self.handle_message(self.parse_response(block=True)) if response is not None: yield response def get_message(self, ignore_subscribe_messages=False, timeout=0): """ Get the next message if one is available, otherwise None. If timeout is specified, the system will wait for `timeout` seconds before returning. Timeout should be specified as a floating point number. """ response = self.parse_response(block=False, timeout=timeout) if response: return self.handle_message(response, ignore_subscribe_messages) return None def ping(self, message=None): """ Ping the Redis server """ message = '' if message is None else message return self.execute_command('PING', message) def handle_message(self, response, ignore_subscribe_messages=False): """ Parses a pub/sub message. If the channel or pattern was subscribed to with a message handler, the handler is invoked instead of a parsed message being returned. """ message_type = str_if_bytes(response[0]) if message_type == 'pmessage': message = { 'type': message_type, 'pattern': response[1], 'channel': response[2], 'data': response[3] } elif message_type == 'pong': message = { 'type': message_type, 'pattern': None, 'channel': None, 'data': response[1] } else: message = { 'type': message_type, 'pattern': None, 'channel': response[1], 'data': response[2] } # if this is an unsubscribe message, remove it from memory if message_type in self.UNSUBSCRIBE_MESSAGE_TYPES: if message_type == 'punsubscribe': pattern = response[1] if pattern in self.pending_unsubscribe_patterns: self.pending_unsubscribe_patterns.remove(pattern) self.patterns.pop(pattern, None) else: channel = response[1] if channel in self.pending_unsubscribe_channels: self.pending_unsubscribe_channels.remove(channel) self.channels.pop(channel, None) if message_type in self.PUBLISH_MESSAGE_TYPES: # if there's a message handler, invoke it if message_type == 'pmessage': handler = self.patterns.get(message['pattern'], None) else: handler = self.channels.get(message['channel'], None) if handler: handler(message) return None elif message_type != 'pong': # this is a subscribe/unsubscribe message. ignore if we don't # want them if ignore_subscribe_messages or self.ignore_subscribe_messages: return None return message def run_in_thread(self, sleep_time=0, daemon=False, exception_handler=None): for channel, handler in self.channels.items(): if handler is None: raise PubSubError("Channel: '%s' has no handler registered" % channel) for pattern, handler in self.patterns.items(): if handler is None: raise PubSubError("Pattern: '%s' has no handler registered" % pattern) thread = PubSubWorkerThread( self, sleep_time, daemon=daemon, exception_handler=exception_handler ) thread.start() return thread class PubSubWorkerThread(threading.Thread): def __init__(self, pubsub, sleep_time, daemon=False, exception_handler=None): super().__init__() self.daemon = daemon self.pubsub = pubsub self.sleep_time = sleep_time self.exception_handler = exception_handler self._running = threading.Event() def run(self): if self._running.is_set(): return self._running.set() pubsub = self.pubsub sleep_time = self.sleep_time while self._running.is_set(): try: pubsub.get_message(ignore_subscribe_messages=True, timeout=sleep_time) except BaseException as e: if self.exception_handler is None: raise self.exception_handler(e, pubsub, self) pubsub.close() def stop(self): # trip the flag so the run loop exits. the run loop will # close the pubsub connection, which disconnects the socket # and returns the connection to the pool. self._running.clear() class Pipeline(Redis): """ Pipelines provide a way to transmit multiple commands to the Redis server in one transmission. This is convenient for batch processing, such as saving all the values in a list to Redis. All commands executed within a pipeline are wrapped with MULTI and EXEC calls. This guarantees all commands executed in the pipeline will be executed atomically. Any command raising an exception does *not* halt the execution of subsequent commands in the pipeline. Instead, the exception is caught and its instance is placed into the response list returned by execute(). Code iterating over the response list should be able to deal with an instance of an exception as a potential value. In general, these will be ResponseError exceptions, such as those raised when issuing a command on a key of a different datatype. """ UNWATCH_COMMANDS = {'DISCARD', 'EXEC', 'UNWATCH'} def __init__(self, connection_pool, response_callbacks, transaction, shard_hint): self.connection_pool = connection_pool self.connection = None self.response_callbacks = response_callbacks self.transaction = transaction self.shard_hint = shard_hint self.watching = False self.reset() def __enter__(self): return self def __exit__(self, exc_type, exc_value, traceback): self.reset() def __del__(self): try: self.reset() except Exception: pass def __len__(self): return len(self.command_stack) def __bool__(self): "Pipeline instances should always evaluate to True" return True def reset(self): self.command_stack = [] self.scripts = set() # make sure to reset the connection state in the event that we were # watching something if self.watching and self.connection: try: # call this manually since our unwatch or # immediate_execute_command methods can call reset() self.connection.send_command('UNWATCH') self.connection.read_response() except ConnectionError: # disconnect will also remove any previous WATCHes self.connection.disconnect() # clean up the other instance attributes self.watching = False self.explicit_transaction = False # we can safely return the connection to the pool here since we're # sure we're no longer WATCHing anything if self.connection: self.connection_pool.release(self.connection) self.connection = None def multi(self): """ Start a transactional block of the pipeline after WATCH commands are issued. End the transactional block with `execute`. """ if self.explicit_transaction: raise RedisError('Cannot issue nested calls to MULTI') if self.command_stack: raise RedisError('Commands without an initial WATCH have already ' 'been issued') self.explicit_transaction = True def execute_command(self, *args, **kwargs): if (self.watching or args[0] == 'WATCH') and \ not self.explicit_transaction: return self.immediate_execute_command(*args, **kwargs) return self.pipeline_execute_command(*args, **kwargs) def _disconnect_reset_raise(self, conn, error): """ Close the connection, reset watching state and raise an exception if we were watching, retry_on_timeout is not set, or the error is not a TimeoutError """ conn.disconnect() # if we were already watching a variable, the watch is no longer # valid since this connection has died. raise a WatchError, which # indicates the user should retry this transaction. if self.watching: self.reset() raise WatchError("A ConnectionError occurred on while " "watching one or more keys") # if retry_on_timeout is not set, or the error is not # a TimeoutError, raise it if not (conn.retry_on_timeout and isinstance(error, TimeoutError)): self.reset() raise def immediate_execute_command(self, *args, **options): """ Execute a command immediately, but don't auto-retry on a ConnectionError if we're already WATCHing a variable. Used when issuing WATCH or subsequent commands retrieving their values but before MULTI is called. """ command_name = args[0] conn = self.connection # if this is the first call, we need a connection if not conn: conn = self.connection_pool.get_connection(command_name, self.shard_hint) self.connection = conn return conn.retry.call_with_retry( lambda: self._send_command_parse_response(conn, command_name, *args, **options), lambda error: self._disconnect_reset_raise(conn, error)) def pipeline_execute_command(self, *args, **options): """ Stage a command to be executed when execute() is next called Returns the current Pipeline object back so commands can be chained together, such as: pipe = pipe.set('foo', 'bar').incr('baz').decr('bang') At some other point, you can then run: pipe.execute(), which will execute all commands queued in the pipe. """ self.command_stack.append((args, options)) return self def _execute_transaction(self, connection, commands, raise_on_error): cmds = chain([(('MULTI', ), {})], commands, [(('EXEC', ), {})]) all_cmds = connection.pack_commands([args for args, options in cmds if EMPTY_RESPONSE not in options]) connection.send_packed_command(all_cmds) errors = [] # parse off the response for MULTI # NOTE: we need to handle ResponseErrors here and continue # so that we read all the additional command messages from # the socket try: self.parse_response(connection, '_') except ResponseError as e: errors.append((0, e)) # and all the other commands for i, command in enumerate(commands): if EMPTY_RESPONSE in command[1]: errors.append((i, command[1][EMPTY_RESPONSE])) else: try: self.parse_response(connection, '_') except ResponseError as e: self.annotate_exception(e, i + 1, command[0]) errors.append((i, e)) # parse the EXEC. try: response = self.parse_response(connection, '_') except ExecAbortError: if errors: raise errors[0][1] raise # EXEC clears any watched keys self.watching = False if response is None: raise WatchError("Watched variable changed.") # put any parse errors into the response for i, e in errors: response.insert(i, e) if len(response) != len(commands): self.connection.disconnect() raise ResponseError("Wrong number of response items from " "pipeline execution") # find any errors in the response and raise if necessary if raise_on_error: self.raise_first_error(commands, response) # We have to run response callbacks manually data = [] for r, cmd in zip(response, commands): if not isinstance(r, Exception): args, options = cmd command_name = args[0] if command_name in self.response_callbacks: r = self.response_callbacks[command_name](r, **options) data.append(r) return data def _execute_pipeline(self, connection, commands, raise_on_error): # build up all commands into a single request to increase network perf all_cmds = connection.pack_commands([args for args, _ in commands]) connection.send_packed_command(all_cmds) response = [] for args, options in commands: try: response.append( self.parse_response(connection, args[0], **options)) except ResponseError as e: response.append(e) if raise_on_error: self.raise_first_error(commands, response) return response def raise_first_error(self, commands, response): for i, r in enumerate(response): if isinstance(r, ResponseError): self.annotate_exception(r, i + 1, commands[i][0]) raise r def annotate_exception(self, exception, number, command): cmd = ' '.join(map(safe_str, command)) msg = 'Command # %d (%s) of pipeline caused error: %s' % ( number, cmd, exception.args[0]) exception.args = (msg,) + exception.args[1:] def parse_response(self, connection, command_name, **options): result = Redis.parse_response( self, connection, command_name, **options) if command_name in self.UNWATCH_COMMANDS: self.watching = False elif command_name == 'WATCH': self.watching = True return result def load_scripts(self): # make sure all scripts that are about to be run on this pipeline exist scripts = list(self.scripts) immediate = self.immediate_execute_command shas = [s.sha for s in scripts] # we can't use the normal script_* methods because they would just # get buffered in the pipeline. exists = immediate('SCRIPT EXISTS', *shas) if not all(exists): for s, exist in zip(scripts, exists): if not exist: s.sha = immediate('SCRIPT LOAD', s.script) def _disconnect_raise_reset(self, conn, error): """ Close the connection, raise an exception if we were watching, and raise an exception if retry_on_timeout is not set, or the error is not a TimeoutError """ conn.disconnect() # if we were watching a variable, the watch is no longer valid # since this connection has died. raise a WatchError, which # indicates the user should retry this transaction. if self.watching: raise WatchError("A ConnectionError occurred on while " "watching one or more keys") # if retry_on_timeout is not set, or the error is not # a TimeoutError, raise it if not (conn.retry_on_timeout and isinstance(error, TimeoutError)): self.reset() raise def execute(self, raise_on_error=True): "Execute all the commands in the current pipeline" stack = self.command_stack if not stack and not self.watching: return [] if self.scripts: self.load_scripts() if self.transaction or self.explicit_transaction: execute = self._execute_transaction else: execute = self._execute_pipeline conn = self.connection if not conn: conn = self.connection_pool.get_connection('MULTI', self.shard_hint) # assign to self.connection so reset() releases the connection # back to the pool after we're done self.connection = conn try: return conn.retry.call_with_retry( lambda: execute(conn, stack, raise_on_error), lambda error: self._disconnect_raise_reset(conn, error)) finally: self.reset() def discard(self): """Flushes all previously queued commands See: """ self.execute_command("DISCARD") def watch(self, *names): "Watches the values at keys ``names``" if self.explicit_transaction: raise RedisError('Cannot issue a WATCH after a MULTI') return self.execute_command('WATCH', *names) def unwatch(self): "Unwatches all previously specified keys" return self.watching and self.execute_command('UNWATCH') or True class Script: "An executable Lua script object returned by ``register_script``" def __init__(self, registered_client, script): self.registered_client = registered_client self.script = script # Precalculate and store the SHA1 hex digest of the script. if isinstance(script, str): # We need the encoding from the client in order to generate an # accurate byte representation of the script encoder = registered_client.connection_pool.get_encoder() script = encoder.encode(script) self.sha = hashlib.sha1(script).hexdigest() def __call__(self, keys=[], args=[], client=None): "Execute the script, passing any required ``args``" if client is None: client = self.registered_client args = tuple(keys) + tuple(args) # make sure the Redis server knows about the script if isinstance(client, Pipeline): # Make sure the pipeline can register the script before executing. client.scripts.add(self) try: return client.evalsha(self.sha, len(keys), *args) except NoScriptError: # Maybe the client is pointed to a different server than the client # that created this instance? # Overwrite the sha just in case there was a discrepancy. self.sha = client.script_load(self.script) return client.evalsha(self.sha, len(keys), *args)