Server IP : 85.214.239.14 / Your IP : 3.138.113.44 Web Server : Apache/2.4.62 (Debian) System : Linux h2886529.stratoserver.net 4.9.0 #1 SMP Tue Jan 9 19:45:01 MSK 2024 x86_64 User : www-data ( 33) PHP Version : 7.4.18 Disable Function : pcntl_alarm,pcntl_fork,pcntl_waitpid,pcntl_wait,pcntl_wifexited,pcntl_wifstopped,pcntl_wifsignaled,pcntl_wifcontinued,pcntl_wexitstatus,pcntl_wtermsig,pcntl_wstopsig,pcntl_signal,pcntl_signal_get_handler,pcntl_signal_dispatch,pcntl_get_last_error,pcntl_strerror,pcntl_sigprocmask,pcntl_sigwaitinfo,pcntl_sigtimedwait,pcntl_exec,pcntl_getpriority,pcntl_setpriority,pcntl_async_signals,pcntl_unshare, MySQL : OFF | cURL : OFF | WGET : ON | Perl : ON | Python : ON | Sudo : ON | Pkexec : OFF Directory : /proc/self/root/proc/2/cwd/proc/3/cwd/proc/self/root/lib/python3.5/logging/ |
Upload File : |
# Copyright 2001-2016 by Vinay Sajip. All Rights Reserved. # # Permission to use, copy, modify, and distribute this software and its # documentation for any purpose and without fee is hereby granted, # provided that the above copyright notice appear in all copies and that # both that copyright notice and this permission notice appear in # supporting documentation, and that the name of Vinay Sajip # not be used in advertising or publicity pertaining to distribution # of the software without specific, written prior permission. # VINAY SAJIP DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING # ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL # VINAY SAJIP BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR # ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER # IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT # OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. """ Additional handlers for the logging package for Python. The core package is based on PEP 282 and comments thereto in comp.lang.python. Copyright (C) 2001-2016 Vinay Sajip. All Rights Reserved. To use, simply 'import logging.handlers' and log away! """ import logging, socket, os, pickle, struct, time, re from stat import ST_DEV, ST_INO, ST_MTIME import queue try: import threading except ImportError: #pragma: no cover threading = None # # Some constants... # DEFAULT_TCP_LOGGING_PORT = 9020 DEFAULT_UDP_LOGGING_PORT = 9021 DEFAULT_HTTP_LOGGING_PORT = 9022 DEFAULT_SOAP_LOGGING_PORT = 9023 SYSLOG_UDP_PORT = 514 SYSLOG_TCP_PORT = 514 _MIDNIGHT = 24 * 60 * 60 # number of seconds in a day class BaseRotatingHandler(logging.FileHandler): """ Base class for handlers that rotate log files at a certain point. Not meant to be instantiated directly. Instead, use RotatingFileHandler or TimedRotatingFileHandler. """ def __init__(self, filename, mode, encoding=None, delay=False): """ Use the specified filename for streamed logging """ logging.FileHandler.__init__(self, filename, mode, encoding, delay) self.mode = mode self.encoding = encoding self.namer = None self.rotator = None def emit(self, record): """ Emit a record. Output the record to the file, catering for rollover as described in doRollover(). """ try: if self.shouldRollover(record): self.doRollover() logging.FileHandler.emit(self, record) except Exception: self.handleError(record) def rotation_filename(self, default_name): """ Modify the filename of a log file when rotating. This is provided so that a custom filename can be provided. The default implementation calls the 'namer' attribute of the handler, if it's callable, passing the default name to it. If the attribute isn't callable (the default is None), the name is returned unchanged. :param default_name: The default name for the log file. """ if not callable(self.namer): result = default_name else: result = self.namer(default_name) return result def rotate(self, source, dest): """ When rotating, rotate the current log. The default implementation calls the 'rotator' attribute of the handler, if it's callable, passing the source and dest arguments to it. If the attribute isn't callable (the default is None), the source is simply renamed to the destination. :param source: The source filename. This is normally the base filename, e.g. 'test.log' :param dest: The destination filename. This is normally what the source is rotated to, e.g. 'test.log.1'. """ if not callable(self.rotator): # Issue 18940: A file may not have been created if delay is True. if os.path.exists(source): os.rename(source, dest) else: self.rotator(source, dest) class RotatingFileHandler(BaseRotatingHandler): """ Handler for logging to a set of files, which switches from one file to the next when the current file reaches a certain size. """ def __init__(self, filename, mode='a', maxBytes=0, backupCount=0, encoding=None, delay=False): """ Open the specified file and use it as the stream for logging. By default, the file grows indefinitely. You can specify particular values of maxBytes and backupCount to allow the file to rollover at a predetermined size. Rollover occurs whenever the current log file is nearly maxBytes in length. If backupCount is >= 1, the system will successively create new files with the same pathname as the base file, but with extensions ".1", ".2" etc. appended to it. For example, with a backupCount of 5 and a base file name of "app.log", you would get "app.log", "app.log.1", "app.log.2", ... through to "app.log.5". The file being written to is always "app.log" - when it gets filled up, it is closed and renamed to "app.log.1", and if files "app.log.1", "app.log.2" etc. exist, then they are renamed to "app.log.2", "app.log.3" etc. respectively. If maxBytes is zero, rollover never occurs. """ # If rotation/rollover is wanted, it doesn't make sense to use another # mode. If for example 'w' were specified, then if there were multiple # runs of the calling application, the logs from previous runs would be # lost if the 'w' is respected, because the log file would be truncated # on each run. if maxBytes > 0: mode = 'a' BaseRotatingHandler.__init__(self, filename, mode, encoding, delay) self.maxBytes = maxBytes self.backupCount = backupCount def doRollover(self): """ Do a rollover, as described in __init__(). """ if self.stream: self.stream.close() self.stream = None if self.backupCount > 0: for i in range(self.backupCount - 1, 0, -1): sfn = self.rotation_filename("%s.%d" % (self.baseFilename, i)) dfn = self.rotation_filename("%s.%d" % (self.baseFilename, i + 1)) if os.path.exists(sfn): if os.path.exists(dfn): os.remove(dfn) os.rename(sfn, dfn) dfn = self.rotation_filename(self.baseFilename + ".1") if os.path.exists(dfn): os.remove(dfn) self.rotate(self.baseFilename, dfn) if not self.delay: self.stream = self._open() def shouldRollover(self, record): """ Determine if rollover should occur. Basically, see if the supplied record would cause the file to exceed the size limit we have. """ if self.stream is None: # delay was set... self.stream = self._open() if self.maxBytes > 0: # are we rolling over? msg = "%s\n" % self.format(record) self.stream.seek(0, 2) #due to non-posix-compliant Windows feature if self.stream.tell() + len(msg) >= self.maxBytes: return 1 return 0 class TimedRotatingFileHandler(BaseRotatingHandler): """ Handler for logging to a file, rotating the log file at certain timed intervals. If backupCount is > 0, when rollover is done, no more than backupCount files are kept - the oldest ones are deleted. """ def __init__(self, filename, when='h', interval=1, backupCount=0, encoding=None, delay=False, utc=False, atTime=None): BaseRotatingHandler.__init__(self, filename, 'a', encoding, delay) self.when = when.upper() self.backupCount = backupCount self.utc = utc self.atTime = atTime # Calculate the real rollover interval, which is just the number of # seconds between rollovers. Also set the filename suffix used when # a rollover occurs. Current 'when' events supported: # S - Seconds # M - Minutes # H - Hours # D - Days # midnight - roll over at midnight # W{0-6} - roll over on a certain day; 0 - Monday # # Case of the 'when' specifier is not important; lower or upper case # will work. if self.when == 'S': self.interval = 1 # one second self.suffix = "%Y-%m-%d_%H-%M-%S" self.extMatch = r"^\d{4}-\d{2}-\d{2}_\d{2}-\d{2}-\d{2}(\.\w+)?$" elif self.when == 'M': self.interval = 60 # one minute self.suffix = "%Y-%m-%d_%H-%M" self.extMatch = r"^\d{4}-\d{2}-\d{2}_\d{2}-\d{2}(\.\w+)?$" elif self.when == 'H': self.interval = 60 * 60 # one hour self.suffix = "%Y-%m-%d_%H" self.extMatch = r"^\d{4}-\d{2}-\d{2}_\d{2}(\.\w+)?$" elif self.when == 'D' or self.when == 'MIDNIGHT': self.interval = 60 * 60 * 24 # one day self.suffix = "%Y-%m-%d" self.extMatch = r"^\d{4}-\d{2}-\d{2}(\.\w+)?$" elif self.when.startswith('W'): self.interval = 60 * 60 * 24 * 7 # one week if len(self.when) != 2: raise ValueError("You must specify a day for weekly rollover from 0 to 6 (0 is Monday): %s" % self.when) if self.when[1] < '0' or self.when[1] > '6': raise ValueError("Invalid day specified for weekly rollover: %s" % self.when) self.dayOfWeek = int(self.when[1]) self.suffix = "%Y-%m-%d" self.extMatch = r"^\d{4}-\d{2}-\d{2}(\.\w+)?$" else: raise ValueError("Invalid rollover interval specified: %s" % self.when) self.extMatch = re.compile(self.extMatch, re.ASCII) self.interval = self.interval * interval # multiply by units requested if os.path.exists(filename): t = os.stat(filename)[ST_MTIME] else: t = int(time.time()) self.rolloverAt = self.computeRollover(t) def computeRollover(self, currentTime): """ Work out the rollover time based on the specified time. """ result = currentTime + self.interval # If we are rolling over at midnight or weekly, then the interval is already known. # What we need to figure out is WHEN the next interval is. In other words, # if you are rolling over at midnight, then your base interval is 1 day, # but you want to start that one day clock at midnight, not now. So, we # have to fudge the rolloverAt value in order to trigger the first rollover # at the right time. After that, the regular interval will take care of # the rest. Note that this code doesn't care about leap seconds. :) if self.when == 'MIDNIGHT' or self.when.startswith('W'): # This could be done with less code, but I wanted it to be clear if self.utc: t = time.gmtime(currentTime) else: t = time.localtime(currentTime) currentHour = t[3] currentMinute = t[4] currentSecond = t[5] currentDay = t[6] # r is the number of seconds left between now and the next rotation if self.atTime is None: rotate_ts = _MIDNIGHT else: rotate_ts = ((self.atTime.hour * 60 + self.atTime.minute)*60 + self.atTime.second) r = rotate_ts - ((currentHour * 60 + currentMinute) * 60 + currentSecond) if r < 0: # Rotate time is before the current time (for example when # self.rotateAt is 13:45 and it now 14:15), rotation is # tomorrow. r += _MIDNIGHT currentDay = (currentDay + 1) % 7 result = currentTime + r # If we are rolling over on a certain day, add in the number of days until # the next rollover, but offset by 1 since we just calculated the time # until the next day starts. There are three cases: # Case 1) The day to rollover is today; in this case, do nothing # Case 2) The day to rollover is further in the interval (i.e., today is # day 2 (Wednesday) and rollover is on day 6 (Sunday). Days to # next rollover is simply 6 - 2 - 1, or 3. # Case 3) The day to rollover is behind us in the interval (i.e., today # is day 5 (Saturday) and rollover is on day 3 (Thursday). # Days to rollover is 6 - 5 + 3, or 4. In this case, it's the # number of days left in the current week (1) plus the number # of days in the next week until the rollover day (3). # The calculations described in 2) and 3) above need to have a day added. # This is because the above time calculation takes us to midnight on this # day, i.e. the start of the next day. if self.when.startswith('W'): day = currentDay # 0 is Monday if day != self.dayOfWeek: if day < self.dayOfWeek: daysToWait = self.dayOfWeek - day else: daysToWait = 6 - day + self.dayOfWeek + 1 newRolloverAt = result + (daysToWait * (60 * 60 * 24)) if not self.utc: dstNow = t[-1] dstAtRollover = time.localtime(newRolloverAt)[-1] if dstNow != dstAtRollover: if not dstNow: # DST kicks in before next rollover, so we need to deduct an hour addend = -3600 else: # DST bows out before next rollover, so we need to add an hour addend = 3600 newRolloverAt += addend result = newRolloverAt return result def shouldRollover(self, record): """ Determine if rollover should occur. record is not used, as we are just comparing times, but it is needed so the method signatures are the same """ t = int(time.time()) if t >= self.rolloverAt: return 1 return 0 def getFilesToDelete(self): """ Determine the files to delete when rolling over. More specific than the earlier method, which just used glob.glob(). """ dirName, baseName = os.path.split(self.baseFilename) fileNames = os.listdir(dirName) result = [] prefix = baseName + "." plen = len(prefix) for fileName in fileNames: if fileName[:plen] == prefix: suffix = fileName[plen:] if self.extMatch.match(suffix): result.append(os.path.join(dirName, fileName)) result.sort() if len(result) < self.backupCount: result = [] else: result = result[:len(result) - self.backupCount] return result def doRollover(self): """ do a rollover; in this case, a date/time stamp is appended to the filename when the rollover happens. However, you want the file to be named for the start of the interval, not the current time. If there is a backup count, then we have to get a list of matching filenames, sort them and remove the one with the oldest suffix. """ if self.stream: self.stream.close() self.stream = None # get the time that this sequence started at and make it a TimeTuple currentTime = int(time.time()) dstNow = time.localtime(currentTime)[-1] t = self.rolloverAt - self.interval if self.utc: timeTuple = time.gmtime(t) else: timeTuple = time.localtime(t) dstThen = timeTuple[-1] if dstNow != dstThen: if dstNow: addend = 3600 else: addend = -3600 timeTuple = time.localtime(t + addend) dfn = self.rotation_filename(self.baseFilename + "." + time.strftime(self.suffix, timeTuple)) if os.path.exists(dfn): os.remove(dfn) self.rotate(self.baseFilename, dfn) if self.backupCount > 0: for s in self.getFilesToDelete(): os.remove(s) if not self.delay: self.stream = self._open() newRolloverAt = self.computeRollover(currentTime) while newRolloverAt <= currentTime: newRolloverAt = newRolloverAt + self.interval #If DST changes and midnight or weekly rollover, adjust for this. if (self.when == 'MIDNIGHT' or self.when.startswith('W')) and not self.utc: dstAtRollover = time.localtime(newRolloverAt)[-1] if dstNow != dstAtRollover: if not dstNow: # DST kicks in before next rollover, so we need to deduct an hour addend = -3600 else: # DST bows out before next rollover, so we need to add an hour addend = 3600 newRolloverAt += addend self.rolloverAt = newRolloverAt class WatchedFileHandler(logging.FileHandler): """ A handler for logging to a file, which watches the file to see if it has changed while in use. This can happen because of usage of programs such as newsyslog and logrotate which perform log file rotation. This handler, intended for use under Unix, watches the file to see if it has changed since the last emit. (A file has changed if its device or inode have changed.) If it has changed, the old file stream is closed, and the file opened to get a new stream. This handler is not appropriate for use under Windows, because under Windows open files cannot be moved or renamed - logging opens the files with exclusive locks - and so there is no need for such a handler. Furthermore, ST_INO is not supported under Windows; stat always returns zero for this value. This handler is based on a suggestion and patch by Chad J. Schroeder. """ def __init__(self, filename, mode='a', encoding=None, delay=False): logging.FileHandler.__init__(self, filename, mode, encoding, delay) self.dev, self.ino = -1, -1 self._statstream() def _statstream(self): if self.stream: sres = os.fstat(self.stream.fileno()) self.dev, self.ino = sres[ST_DEV], sres[ST_INO] def emit(self, record): """ Emit a record. First check if the underlying file has changed, and if it has, close the old stream and reopen the file to get the current stream. """ # Reduce the chance of race conditions by stat'ing by path only # once and then fstat'ing our new fd if we opened a new log stream. # See issue #14632: Thanks to John Mulligan for the problem report # and patch. try: # stat the file by path, checking for existence sres = os.stat(self.baseFilename) except FileNotFoundError: sres = None # compare file system stat with that of our stream file handle if not sres or sres[ST_DEV] != self.dev or sres[ST_INO] != self.ino: if self.stream is not None: # we have an open file handle, clean it up self.stream.flush() self.stream.close() self.stream = None # See Issue #21742: _open () might fail. # open a new file handle and get new stat info from that fd self.stream = self._open() self._statstream() logging.FileHandler.emit(self, record) class SocketHandler(logging.Handler): """ A handler class which writes logging records, in pickle format, to a streaming socket. The socket is kept open across logging calls. If the peer resets it, an attempt is made to reconnect on the next call. The pickle which is sent is that of the LogRecord's attribute dictionary (__dict__), so that the receiver does not need to have the logging module installed in order to process the logging event. To unpickle the record at the receiving end into a LogRecord, use the makeLogRecord function. """ def __init__(self, host, port): """ Initializes the handler with a specific host address and port. When the attribute *closeOnError* is set to True - if a socket error occurs, the socket is silently closed and then reopened on the next logging call. """ logging.Handler.__init__(self) self.host = host self.port = port if port is None: self.address = host else: self.address = (host, port) self.sock = None self.closeOnError = False self.retryTime = None # # Exponential backoff parameters. # self.retryStart = 1.0 self.retryMax = 30.0 self.retryFactor = 2.0 def makeSocket(self, timeout=1): """ A factory method which allows subclasses to define the precise type of socket they want. """ if self.port is not None: result = socket.create_connection(self.address, timeout=timeout) else: result = socket.socket(socket.AF_UNIX, socket.SOCK_STREAM) result.settimeout(timeout) try: result.connect(self.address) except OSError: result.close() # Issue 19182 raise return result def createSocket(self): """ Try to create a socket, using an exponential backoff with a max retry time. Thanks to Robert Olson for the original patch (SF #815911) which has been slightly refactored. """ now = time.time() # Either retryTime is None, in which case this # is the first time back after a disconnect, or # we've waited long enough. if self.retryTime is None: attempt = True else: attempt = (now >= self.retryTime) if attempt: try: self.sock = self.makeSocket() self.retryTime = None # next time, no delay before trying except OSError: #Creation failed, so set the retry time and return. if self.retryTime is None: self.retryPeriod = self.retryStart else: self.retryPeriod = self.retryPeriod * self.retryFactor if self.retryPeriod > self.retryMax: self.retryPeriod = self.retryMax self.retryTime = now + self.retryPeriod def send(self, s): """ Send a pickled string to the socket. This function allows for partial sends which can happen when the network is busy. """ if self.sock is None: self.createSocket() #self.sock can be None either because we haven't reached the retry #time yet, or because we have reached the retry time and retried, #but are still unable to connect. if self.sock: try: self.sock.sendall(s) except OSError: #pragma: no cover self.sock.close() self.sock = None # so we can call createSocket next time def makePickle(self, record): """ Pickles the record in binary format with a length prefix, and returns it ready for transmission across the socket. """ ei = record.exc_info if ei: # just to get traceback text into record.exc_text ... dummy = self.format(record) # See issue #14436: If msg or args are objects, they may not be # available on the receiving end. So we convert the msg % args # to a string, save it as msg and zap the args. d = dict(record.__dict__) d['msg'] = record.getMessage() d['args'] = None d['exc_info'] = None # Issue #25685: delete 'message' if present: redundant with 'msg' d.pop('message', None) s = pickle.dumps(d, 1) slen = struct.pack(">L", len(s)) return slen + s def handleError(self, record): """ Handle an error during logging. An error has occurred during logging. Most likely cause - connection lost. Close the socket so that we can retry on the next event. """ if self.closeOnError and self.sock: self.sock.close() self.sock = None #try to reconnect next time else: logging.Handler.handleError(self, record) def emit(self, record): """ Emit a record. Pickles the record and writes it to the socket in binary format. If there is an error with the socket, silently drop the packet. If there was a problem with the socket, re-establishes the socket. """ try: s = self.makePickle(record) self.send(s) except Exception: self.handleError(record) def close(self): """ Closes the socket. """ self.acquire() try: sock = self.sock if sock: self.sock = None sock.close() logging.Handler.close(self) finally: self.release() class DatagramHandler(SocketHandler): """ A handler class which writes logging records, in pickle format, to a datagram socket. The pickle which is sent is that of the LogRecord's attribute dictionary (__dict__), so that the receiver does not need to have the logging module installed in order to process the logging event. To unpickle the record at the receiving end into a LogRecord, use the makeLogRecord function. """ def __init__(self, host, port): """ Initializes the handler with a specific host address and port. """ SocketHandler.__init__(self, host, port) self.closeOnError = False def makeSocket(self): """ The factory method of SocketHandler is here overridden to create a UDP socket (SOCK_DGRAM). """ if self.port is None: family = socket.AF_UNIX else: family = socket.AF_INET s = socket.socket(family, socket.SOCK_DGRAM) return s def send(self, s): """ Send a pickled string to a socket. This function no longer allows for partial sends which can happen when the network is busy - UDP does not guarantee delivery and can deliver packets out of sequence. """ if self.sock is None: self.createSocket() self.sock.sendto(s, self.address) class SysLogHandler(logging.Handler): """ A handler class which sends formatted logging records to a syslog server. Based on Sam Rushing's syslog module: http://www.nightmare.com/squirl/python-ext/misc/syslog.py Contributed by Nicolas Untz (after which minor refactoring changes have been made). """ # from <linux/sys/syslog.h>: # ====================================================================== # priorities/facilities are encoded into a single 32-bit quantity, where # the bottom 3 bits are the priority (0-7) and the top 28 bits are the # facility (0-big number). Both the priorities and the facilities map # roughly one-to-one to strings in the syslogd(8) source code. This # mapping is included in this file. # # priorities (these are ordered) LOG_EMERG = 0 # system is unusable LOG_ALERT = 1 # action must be taken immediately LOG_CRIT = 2 # critical conditions LOG_ERR = 3 # error conditions LOG_WARNING = 4 # warning conditions LOG_NOTICE = 5 # normal but significant condition LOG_INFO = 6 # informational LOG_DEBUG = 7 # debug-level messages # facility codes LOG_KERN = 0 # kernel messages LOG_USER = 1 # random user-level messages LOG_MAIL = 2 # mail system LOG_DAEMON = 3 # system daemons LOG_AUTH = 4 # security/authorization messages LOG_SYSLOG = 5 # messages generated internally by syslogd LOG_LPR = 6 # line printer subsystem LOG_NEWS = 7 # network news subsystem LOG_UUCP = 8 # UUCP subsystem LOG_CRON = 9 # clock daemon LOG_AUTHPRIV = 10 # security/authorization messages (private) LOG_FTP = 11 # FTP daemon # other codes through 15 reserved for system use LOG_LOCAL0 = 16 # reserved for local use LOG_LOCAL1 = 17 # reserved for local use LOG_LOCAL2 = 18 # reserved for local use LOG_LOCAL3 = 19 # reserved for local use LOG_LOCAL4 = 20 # reserved for local use LOG_LOCAL5 = 21 # reserved for local use LOG_LOCAL6 = 22 # reserved for local use LOG_LOCAL7 = 23 # reserved for local use priority_names = { "alert": LOG_ALERT, "crit": LOG_CRIT, "critical": LOG_CRIT, "debug": LOG_DEBUG, "emerg": LOG_EMERG, "err": LOG_ERR, "error": LOG_ERR, # DEPRECATED "info": LOG_INFO, "notice": LOG_NOTICE, "panic": LOG_EMERG, # DEPRECATED "warn": LOG_WARNING, # DEPRECATED "warning": LOG_WARNING, } facility_names = { "auth": LOG_AUTH, "authpriv": LOG_AUTHPRIV, "cron": LOG_CRON, "daemon": LOG_DAEMON, "ftp": LOG_FTP, "kern": LOG_KERN, "lpr": LOG_LPR, "mail": LOG_MAIL, "news": LOG_NEWS, "security": LOG_AUTH, # DEPRECATED "syslog": LOG_SYSLOG, "user": LOG_USER, "uucp": LOG_UUCP, "local0": LOG_LOCAL0, "local1": LOG_LOCAL1, "local2": LOG_LOCAL2, "local3": LOG_LOCAL3, "local4": LOG_LOCAL4, "local5": LOG_LOCAL5, "local6": LOG_LOCAL6, "local7": LOG_LOCAL7, } #The map below appears to be trivially lowercasing the key. However, #there's more to it than meets the eye - in some locales, lowercasing #gives unexpected results. See SF #1524081: in the Turkish locale, #"INFO".lower() != "info" priority_map = { "DEBUG" : "debug", "INFO" : "info", "WARNING" : "warning", "ERROR" : "error", "CRITICAL" : "critical" } def __init__(self, address=('localhost', SYSLOG_UDP_PORT), facility=LOG_USER, socktype=None): """ Initialize a handler. If address is specified as a string, a UNIX socket is used. To log to a local syslogd, "SysLogHandler(address="/dev/log")" can be used. If facility is not specified, LOG_USER is used. If socktype is specified as socket.SOCK_DGRAM or socket.SOCK_STREAM, that specific socket type will be used. For Unix sockets, you can also specify a socktype of None, in which case socket.SOCK_DGRAM will be used, falling back to socket.SOCK_STREAM. """ logging.Handler.__init__(self) self.address = address self.facility = facility self.socktype = socktype if isinstance(address, str): self.unixsocket = True self._connect_unixsocket(address) else: self.unixsocket = False if socktype is None: socktype = socket.SOCK_DGRAM self.socket = socket.socket(socket.AF_INET, socktype) if socktype == socket.SOCK_STREAM: self.socket.connect(address) self.socktype = socktype self.formatter = None def _connect_unixsocket(self, address): use_socktype = self.socktype if use_socktype is None: use_socktype = socket.SOCK_DGRAM self.socket = socket.socket(socket.AF_UNIX, use_socktype) try: self.socket.connect(address) # it worked, so set self.socktype to the used type self.socktype = use_socktype except OSError: self.socket.close() if self.socktype is not None: # user didn't specify falling back, so fail raise use_socktype = socket.SOCK_STREAM self.socket = socket.socket(socket.AF_UNIX, use_socktype) try: self.socket.connect(address) # it worked, so set self.socktype to the used type self.socktype = use_socktype except OSError: self.socket.close() raise def encodePriority(self, facility, priority): """ Encode the facility and priority. You can pass in strings or integers - if strings are passed, the facility_names and priority_names mapping dictionaries are used to convert them to integers. """ if isinstance(facility, str): facility = self.facility_names[facility] if isinstance(priority, str): priority = self.priority_names[priority] return (facility << 3) | priority def close (self): """ Closes the socket. """ self.acquire() try: self.socket.close() logging.Handler.close(self) finally: self.release() def mapPriority(self, levelName): """ Map a logging level name to a key in the priority_names map. This is useful in two scenarios: when custom levels are being used, and in the case where you can't do a straightforward mapping by lowercasing the logging level name because of locale- specific issues (see SF #1524081). """ return self.priority_map.get(levelName, "warning") ident = '' # prepended to all messages append_nul = True # some old syslog daemons expect a NUL terminator def emit(self, record): """ Emit a record. The record is formatted, and then sent to the syslog server. If exception information is present, it is NOT sent to the server. """ try: msg = self.format(record) if self.ident: msg = self.ident + msg if self.append_nul: msg += '\000' # We need to convert record level to lowercase, maybe this will # change in the future. prio = '<%d>' % self.encodePriority(self.facility, self.mapPriority(record.levelname)) prio = prio.encode('utf-8') # Message is a string. Convert to bytes as required by RFC 5424 msg = msg.encode('utf-8') msg = prio + msg if self.unixsocket: try: self.socket.send(msg) except OSError: self.socket.close() self._connect_unixsocket(self.address) self.socket.send(msg) elif self.socktype == socket.SOCK_DGRAM: self.socket.sendto(msg, self.address) else: self.socket.sendall(msg) except Exception: self.handleError(record) class SMTPHandler(logging.Handler): """ A handler class which sends an SMTP email for each logging event. """ def __init__(self, mailhost, fromaddr, toaddrs, subject, credentials=None, secure=None, timeout=5.0): """ Initialize the handler. Initialize the instance with the from and to addresses and subject line of the email. To specify a non-standard SMTP port, use the (host, port) tuple format for the mailhost argument. To specify authentication credentials, supply a (username, password) tuple for the credentials argument. To specify the use of a secure protocol (TLS), pass in a tuple for the secure argument. This will only be used when authentication credentials are supplied. The tuple will be either an empty tuple, or a single-value tuple with the name of a keyfile, or a 2-value tuple with the names of the keyfile and certificate file. (This tuple is passed to the `starttls` method). A timeout in seconds can be specified for the SMTP connection (the default is one second). """ logging.Handler.__init__(self) if isinstance(mailhost, (list, tuple)): self.mailhost, self.mailport = mailhost else: self.mailhost, self.mailport = mailhost, None if isinstance(credentials, (list, tuple)): self.username, self.password = credentials else: self.username = None self.fromaddr = fromaddr if isinstance(toaddrs, str): toaddrs = [toaddrs] self.toaddrs = toaddrs self.subject = subject self.secure = secure self.timeout = timeout def getSubject(self, record): """ Determine the subject for the email. If you want to specify a subject line which is record-dependent, override this method. """ return self.subject def emit(self, record): """ Emit a record. Format the record and send it to the specified addressees. """ try: import smtplib from email.message import EmailMessage import email.utils port = self.mailport if not port: port = smtplib.SMTP_PORT smtp = smtplib.SMTP(self.mailhost, port, timeout=self.timeout) msg = EmailMessage() msg['From'] = self.fromaddr msg['To'] = ','.join(self.toaddrs) msg['Subject'] = self.getSubject(record) msg['Date'] = email.utils.localtime() msg.set_content(self.format(record)) if self.username: if self.secure is not None: smtp.ehlo() smtp.starttls(*self.secure) smtp.ehlo() smtp.login(self.username, self.password) smtp.send_message(msg) smtp.quit() except Exception: self.handleError(record) class NTEventLogHandler(logging.Handler): """ A handler class which sends events to the NT Event Log. Adds a registry entry for the specified application name. If no dllname is provided, win32service.pyd (which contains some basic message placeholders) is used. Note that use of these placeholders will make your event logs big, as the entire message source is held in the log. If you want slimmer logs, you have to pass in the name of your own DLL which contains the message definitions you want to use in the event log. """ def __init__(self, appname, dllname=None, logtype="Application"): logging.Handler.__init__(self) try: import win32evtlogutil, win32evtlog self.appname = appname self._welu = win32evtlogutil if not dllname: dllname = os.path.split(self._welu.__file__) dllname = os.path.split(dllname[0]) dllname = os.path.join(dllname[0], r'win32service.pyd') self.dllname = dllname self.logtype = logtype self._welu.AddSourceToRegistry(appname, dllname, logtype) self.deftype = win32evtlog.EVENTLOG_ERROR_TYPE self.typemap = { logging.DEBUG : win32evtlog.EVENTLOG_INFORMATION_TYPE, logging.INFO : win32evtlog.EVENTLOG_INFORMATION_TYPE, logging.WARNING : win32evtlog.EVENTLOG_WARNING_TYPE, logging.ERROR : win32evtlog.EVENTLOG_ERROR_TYPE, logging.CRITICAL: win32evtlog.EVENTLOG_ERROR_TYPE, } except ImportError: print("The Python Win32 extensions for NT (service, event "\ "logging) appear not to be available.") self._welu = None def getMessageID(self, record): """ Return the message ID for the event record. If you are using your own messages, you could do this by having the msg passed to the logger being an ID rather than a formatting string. Then, in here, you could use a dictionary lookup to get the message ID. This version returns 1, which is the base message ID in win32service.pyd. """ return 1 def getEventCategory(self, record): """ Return the event category for the record. Override this if you want to specify your own categories. This version returns 0. """ return 0 def getEventType(self, record): """ Return the event type for the record. Override this if you want to specify your own types. This version does a mapping using the handler's typemap attribute, which is set up in __init__() to a dictionary which contains mappings for DEBUG, INFO, WARNING, ERROR and CRITICAL. If you are using your own levels you will either need to override this method or place a suitable dictionary in the handler's typemap attribute. """ return self.typemap.get(record.levelno, self.deftype) def emit(self, record): """ Emit a record. Determine the message ID, event category and event type. Then log the message in the NT event log. """ if self._welu: try: id = self.getMessageID(record) cat = self.getEventCategory(record) type = self.getEventType(record) msg = self.format(record) self._welu.ReportEvent(self.appname, id, cat, type, [msg]) except Exception: self.handleError(record) def close(self): """ Clean up this handler. You can remove the application name from the registry as a source of event log entries. However, if you do this, you will not be able to see the events as you intended in the Event Log Viewer - it needs to be able to access the registry to get the DLL name. """ #self._welu.RemoveSourceFromRegistry(self.appname, self.logtype) logging.Handler.close(self) class HTTPHandler(logging.Handler): """ A class which sends records to a Web server, using either GET or POST semantics. """ def __init__(self, host, url, method="GET", secure=False, credentials=None, context=None): """ Initialize the instance with the host, the request URL, and the method ("GET" or "POST") """ logging.Handler.__init__(self) method = method.upper() if method not in ["GET", "POST"]: raise ValueError("method must be GET or POST") if not secure and context is not None: raise ValueError("context parameter only makes sense " "with secure=True") self.host = host self.url = url self.method = method self.secure = secure self.credentials = credentials self.context = context def mapLogRecord(self, record): """ Default implementation of mapping the log record into a dict that is sent as the CGI data. Overwrite in your class. Contributed by Franz Glasner. """ return record.__dict__ def emit(self, record): """ Emit a record. Send the record to the Web server as a percent-encoded dictionary """ try: import http.client, urllib.parse host = self.host if self.secure: h = http.client.HTTPSConnection(host, context=self.context) else: h = http.client.HTTPConnection(host) url = self.url data = urllib.parse.urlencode(self.mapLogRecord(record)) if self.method == "GET": if (url.find('?') >= 0): sep = '&' else: sep = '?' url = url + "%c%s" % (sep, data) h.putrequest(self.method, url) # support multiple hosts on one IP address... # need to strip optional :port from host, if present i = host.find(":") if i >= 0: host = host[:i] h.putheader("Host", host) if self.method == "POST": h.putheader("Content-type", "application/x-www-form-urlencoded") h.putheader("Content-length", str(len(data))) if self.credentials: import base64 s = ('%s:%s' % self.credentials).encode('utf-8') s = 'Basic ' + base64.b64encode(s).strip().decode('ascii') h.putheader('Authorization', s) h.endheaders() if self.method == "POST": h.send(data.encode('utf-8')) h.getresponse() #can't do anything with the result except Exception: self.handleError(record) class BufferingHandler(logging.Handler): """ A handler class which buffers logging records in memory. Whenever each record is added to the buffer, a check is made to see if the buffer should be flushed. If it should, then flush() is expected to do what's needed. """ def __init__(self, capacity): """ Initialize the handler with the buffer size. """ logging.Handler.__init__(self) self.capacity = capacity self.buffer = [] def shouldFlush(self, record): """ Should the handler flush its buffer? Returns true if the buffer is up to capacity. This method can be overridden to implement custom flushing strategies. """ return (len(self.buffer) >= self.capacity) def emit(self, record): """ Emit a record. Append the record. If shouldFlush() tells us to, call flush() to process the buffer. """ self.buffer.append(record) if self.shouldFlush(record): self.flush() def flush(self): """ Override to implement custom flushing behaviour. This version just zaps the buffer to empty. """ self.acquire() try: self.buffer = [] finally: self.release() def close(self): """ Close the handler. This version just flushes and chains to the parent class' close(). """ try: self.flush() finally: logging.Handler.close(self) class MemoryHandler(BufferingHandler): """ A handler class which buffers logging records in memory, periodically flushing them to a target handler. Flushing occurs whenever the buffer is full, or when an event of a certain severity or greater is seen. """ def __init__(self, capacity, flushLevel=logging.ERROR, target=None): """ Initialize the handler with the buffer size, the level at which flushing should occur and an optional target. Note that without a target being set either here or via setTarget(), a MemoryHandler is no use to anyone! """ BufferingHandler.__init__(self, capacity) self.flushLevel = flushLevel self.target = target def shouldFlush(self, record): """ Check for buffer full or a record at the flushLevel or higher. """ return (len(self.buffer) >= self.capacity) or \ (record.levelno >= self.flushLevel) def setTarget(self, target): """ Set the target handler for this handler. """ self.target = target def flush(self): """ For a MemoryHandler, flushing means just sending the buffered records to the target, if there is one. Override if you want different behaviour. The record buffer is also cleared by this operation. """ self.acquire() try: if self.target: for record in self.buffer: self.target.handle(record) self.buffer = [] finally: self.release() def close(self): """ Flush, set the target to None and lose the buffer. """ try: self.flush() finally: self.acquire() try: self.target = None BufferingHandler.close(self) finally: self.release() class QueueHandler(logging.Handler): """ This handler sends events to a queue. Typically, it would be used together with a multiprocessing Queue to centralise logging to file in one process (in a multi-process application), so as to avoid file write contention between processes. This code is new in Python 3.2, but this class can be copy pasted into user code for use with earlier Python versions. """ def __init__(self, queue): """ Initialise an instance, using the passed queue. """ logging.Handler.__init__(self) self.queue = queue def enqueue(self, record): """ Enqueue a record. The base implementation uses put_nowait. You may want to override this method if you want to use blocking, timeouts or custom queue implementations. """ self.queue.put_nowait(record) def prepare(self, record): """ Prepares a record for queuing. The object returned by this method is enqueued. The base implementation formats the record to merge the message and arguments, and removes unpickleable items from the record in-place. You might want to override this method if you want to convert the record to a dict or JSON string, or send a modified copy of the record while leaving the original intact. """ # The format operation gets traceback text into record.exc_text # (if there's exception data), and also puts the message into # record.message. We can then use this to replace the original # msg + args, as these might be unpickleable. We also zap the # exc_info attribute, as it's no longer needed and, if not None, # will typically not be pickleable. self.format(record) record.msg = record.message record.args = None record.exc_info = None return record def emit(self, record): """ Emit a record. Writes the LogRecord to the queue, preparing it for pickling first. """ try: self.enqueue(self.prepare(record)) except Exception: self.handleError(record) if threading: class QueueListener(object): """ This class implements an internal threaded listener which watches for LogRecords being added to a queue, removes them and passes them to a list of handlers for processing. """ _sentinel = None def __init__(self, queue, *handlers, respect_handler_level=False): """ Initialise an instance with the specified queue and handlers. """ self.queue = queue self.handlers = handlers self._thread = None self.respect_handler_level = respect_handler_level def dequeue(self, block): """ Dequeue a record and return it, optionally blocking. The base implementation uses get. You may want to override this method if you want to use timeouts or work with custom queue implementations. """ return self.queue.get(block) def start(self): """ Start the listener. This starts up a background thread to monitor the queue for LogRecords to process. """ self._thread = t = threading.Thread(target=self._monitor) t.daemon = True t.start() def prepare(self , record): """ Prepare a record for handling. This method just returns the passed-in record. You may want to override this method if you need to do any custom marshalling or manipulation of the record before passing it to the handlers. """ return record def handle(self, record): """ Handle a record. This just loops through the handlers offering them the record to handle. """ record = self.prepare(record) for handler in self.handlers: if not self.respect_handler_level: process = True else: process = record.levelno >= handler.level if process: handler.handle(record) def _monitor(self): """ Monitor the queue for records, and ask the handler to deal with them. This method runs on a separate, internal thread. The thread will terminate if it sees a sentinel object in the queue. """ q = self.queue has_task_done = hasattr(q, 'task_done') while True: try: record = self.dequeue(True) if record is self._sentinel: break self.handle(record) if has_task_done: q.task_done() except queue.Empty: break def enqueue_sentinel(self): """ This is used to enqueue the sentinel record. The base implementation uses put_nowait. You may want to override this method if you want to use timeouts or work with custom queue implementations. """ self.queue.put_nowait(self._sentinel) def stop(self): """ Stop the listener. This asks the thread to terminate, and then waits for it to do so. Note that if you don't call this before your application exits, there may be some records still left on the queue, which won't be processed. """ self.enqueue_sentinel() self._thread.join() self._thread = None