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'\"
'\" Copyright (c) 1993 The Regents of the University of California.
'\" Copyright (c) 1994-1996 Sun Microsystems, Inc.
'\"
'\" See the file "license.terms" for information on usage and redistribution
'\" of this file, and for a DISCLAIMER OF ALL WARRANTIES.
'\" 
.so man.macros
.TH if n "" Tcl "Tcl Built-In Commands"
.BS
'\" Note:  do not modify the .SH NAME line immediately below!
.SH NAME
if \- Execute scripts conditionally
.SH SYNOPSIS
\fBif \fIexpr1 \fR?\fBthen\fR? \fIbody1 \fBelseif \fIexpr2 \fR?\fBthen\fR? \fIbody2\fR \fBelseif\fR ... ?\fBelse\fR? ?\fIbodyN\fR?
.BE

.SH DESCRIPTION
.PP
The \fIif\fR command evaluates \fIexpr1\fR as an expression (in the
same way that \fBexpr\fR evaluates its argument).  The value of the
expression must be a boolean
(a numeric value, where 0 is false and
anything is true, or a string value such as \fBtrue\fR or \fByes\fR
for true and \fBfalse\fR or \fBno\fR for false);
if it is true then \fIbody1\fR is executed by passing it to the
Tcl interpreter.
Otherwise \fIexpr2\fR is evaluated as an expression and if it is true
then \fBbody2\fR is executed, and so on.
If none of the expressions evaluates to true then \fIbodyN\fR is
executed.
The \fBthen\fR and \fBelse\fR arguments are optional
.QW "noise words"
to make the command easier to read.
There may be any number of \fBelseif\fR clauses, including zero.
\fIBodyN\fR may also be omitted as long as \fBelse\fR is omitted too.
The return value from the command is the result of the body script
that was executed, or an empty string
if none of the expressions was non-zero and there was no \fIbodyN\fR.
.SH EXAMPLES
.PP
A simple conditional:
.PP
.CS
\fBif\fR {$vbl == 1} { puts "vbl is one" }
.CE
.PP
With an \fBelse\fR-clause:
.PP
.CS
\fBif\fR {$vbl == 1} {
    puts "vbl is one"
} \fBelse\fR {
    puts "vbl is not one"
}
.CE
.PP
With an \fBelseif\fR-clause too:
.PP
.CS
\fBif\fR {$vbl == 1} {
    puts "vbl is one"
} \fBelseif\fR {$vbl == 2} {
    puts "vbl is two"
} \fBelse\fR {
    puts "vbl is not one or two"
}
.CE
.PP
Remember, expressions can be multi-line, but in that case it can be a
good idea to use the optional \fBthen\fR keyword for clarity:
.PP
.CS
\fBif\fR {
    $vbl == 1
    || $vbl == 2
    || $vbl == 3
} \fBthen\fR {
    puts "vbl is one, two or three"
}
.CE
.SH "SEE ALSO"
expr(n), for(n), foreach(n)
.SH KEYWORDS
boolean, conditional, else, false, if, true
'\" Local Variables:
'\" mode: nroff
'\" End:
generated by cgit v0.12 at 2024-08-24 22:18:01 (GMT)
our logging needs are simple, then use the above examples to incorporate logging into your own scripts, and if you run into problems or don't understand something, please post a question on the comp.lang.python Usenet group (available at https://groups.google.com/group/comp.lang.python) and you should receive help before too long. Still here? You can carry on reading the next few sections, which provide a slightly more advanced/in-depth tutorial than the basic one above. After that, you can take a look at the :ref:`logging-cookbook`. .. _logging-advanced-tutorial: Advanced Logging Tutorial ------------------------- The logging library takes a modular approach and offers several categories of components: loggers, handlers, filters, and formatters. * Loggers expose the interface that application code directly uses. * Handlers send the log records (created by loggers) to the appropriate destination. * Filters provide a finer grained facility for determining which log records to output. * Formatters specify the layout of log records in the final output. Log event information is passed between loggers, handlers, filters and formatters in a :class:`LogRecord` instance. Logging is performed by calling methods on instances of the :class:`Logger` class (hereafter called :dfn:`loggers`). Each instance has a name, and they are conceptually arranged in a namespace hierarchy using dots (periods) as separators. For example, a logger named 'scan' is the parent of loggers 'scan.text', 'scan.html' and 'scan.pdf'. Logger names can be anything you want, and indicate the area of an application in which a logged message originates. A good convention to use when naming loggers is to use a module-level logger, in each module which uses logging, named as follows:: logger = logging.getLogger(__name__) This means that logger names track the package/module hierarchy, and it's intuitively obvious where events are logged just from the logger name. The root of the hierarchy of loggers is called the root logger. That's the logger used by the functions :func:`debug`, :func:`info`, :func:`warning`, :func:`error` and :func:`critical`, which just call the same-named method of the root logger. The functions and the methods have the same signatures. The root logger's name is printed as 'root' in the logged output. It is, of course, possible to log messages to different destinations. Support is included in the package for writing log messages to files, HTTP GET/POST locations, email via SMTP, generic sockets, queues, or OS-specific logging mechanisms such as syslog or the Windows NT event log. Destinations are served by :dfn:`handler` classes. You can create your own log destination class if you have special requirements not met by any of the built-in handler classes. By default, no destination is set for any logging messages. You can specify a destination (such as console or file) by using :func:`basicConfig` as in the tutorial examples. If you call the functions :func:`debug`, :func:`info`, :func:`warning`, :func:`error` and :func:`critical`, they will check to see if no destination is set; and if one is not set, they will set a destination of the console (``sys.stderr``) and a default format for the displayed message before delegating to the root logger to do the actual message output. The default format set by :func:`basicConfig` for messages is:: severity:logger name:message You can change this by passing a format string to :func:`basicConfig` with the *format* keyword argument. For all options regarding how a format string is constructed, see :ref:`formatter-objects`. Logging Flow ^^^^^^^^^^^^ The flow of log event information in loggers and handlers is illustrated in the following diagram. .. image:: logging_flow.png Loggers ^^^^^^^ :class:`Logger` objects have a threefold job. First, they expose several methods to application code so that applications can log messages at runtime. Second, logger objects determine which log messages to act upon based upon severity (the default filtering facility) or filter objects. Third, logger objects pass along relevant log messages to all interested log handlers. The most widely used methods on logger objects fall into two categories: configuration and message sending. These are the most common configuration methods: * :meth:`Logger.setLevel` specifies the lowest-severity log message a logger will handle, where debug is the lowest built-in severity level and critical is the highest built-in severity. For example, if the severity level is INFO, the logger will handle only INFO, WARNING, ERROR, and CRITICAL messages and will ignore DEBUG messages. * :meth:`Logger.addHandler` and :meth:`Logger.removeHandler` add and remove handler objects from the logger object. Handlers are covered in more detail in :ref:`handler-basic`. * :meth:`Logger.addFilter` and :meth:`Logger.removeFilter` add and remove filter objects from the logger object. Filters are covered in more detail in :ref:`filter`. You don't need to always call these methods on every logger you create. See the last two paragraphs in this section. With the logger object configured, the following methods create log messages: * :meth:`Logger.debug`, :meth:`Logger.info`, :meth:`Logger.warning`, :meth:`Logger.error`, and :meth:`Logger.critical` all create log records with a message and a level that corresponds to their respective method names. The message is actually a format string, which may contain the standard string substitution syntax of ``%s``, ``%d``, ``%f``, and so on. The rest of their arguments is a list of objects that correspond with the substitution fields in the message. With regard to ``**kwargs``, the logging methods care only about a keyword of ``exc_info`` and use it to determine whether to log exception information. * :meth:`Logger.exception` creates a log message similar to :meth:`Logger.error`. The difference is that :meth:`Logger.exception` dumps a stack trace along with it. Call this method only from an exception handler. * :meth:`Logger.log` takes a log level as an explicit argument. This is a little more verbose for logging messages than using the log level convenience methods listed above, but this is how to log at custom log levels. :func:`getLogger` returns a reference to a logger instance with the specified name if it is provided, or ``root`` if not. The names are period-separated hierarchical structures. Multiple calls to :func:`getLogger` with the same name will return a reference to the same logger object. Loggers that are further down in the hierarchical list are children of loggers higher up in the list. For example, given a logger with a name of ``foo``, loggers with names of ``foo.bar``, ``foo.bar.baz``, and ``foo.bam`` are all descendants of ``foo``. Loggers have a concept of *effective level*. If a level is not explicitly set on a logger, the level of its parent is used instead as its effective level. If the parent has no explicit level set, *its* parent is examined, and so on - all ancestors are searched until an explicitly set level is found. The root logger always has an explicit level set (``WARNING`` by default). When deciding whether to process an event, the effective level of the logger is used to determine whether the event is passed to the logger's handlers. Child loggers propagate messages up to the handlers associated with their ancestor loggers. Because of this, it is unnecessary to define and configure handlers for all the loggers an application uses. It is sufficient to configure handlers for a top-level logger and create child loggers as needed. (You can, however, turn off propagation by setting the *propagate* attribute of a logger to *False*.) .. _handler-basic: Handlers ^^^^^^^^ :class:`~logging.Handler` objects are responsible for dispatching the appropriate log messages (based on the log messages' severity) to the handler's specified destination. :class:`Logger` objects can add zero or more handler objects to themselves with an :meth:`~Logger.addHandler` method. As an example scenario, an application may want to send all log messages to a log file, all log messages of error or higher to stdout, and all messages of critical to an email address. This scenario requires three individual handlers where each handler is responsible for sending messages of a specific severity to a specific location. The standard library includes quite a few handler types (see :ref:`useful-handlers`); the tutorials use mainly :class:`StreamHandler` and :class:`FileHandler` in its examples. There are very few methods in a handler for application developers to concern themselves with. The only handler methods that seem relevant for application developers who are using the built-in handler objects (that is, not creating custom handlers) are the following configuration methods: * The :meth:`~Handler.setLevel` method, just as in logger objects, specifies the lowest severity that will be dispatched to the appropriate destination. Why are there two :func:`setLevel` methods? The level set in the logger determines which severity of messages it will pass to its handlers. The level set in each handler determines which messages that handler will send on. * :meth:`~Handler.setFormatter` selects a Formatter object for this handler to use. * :meth:`~Handler.addFilter` and :meth:`~Handler.removeFilter` respectively configure and deconfigure filter objects on handlers. Application code should not directly instantiate and use instances of :class:`Handler`. Instead, the :class:`Handler` class is a base class that defines the interface that all handlers should have and establishes some default behavior that child classes can use (or override). Formatters ^^^^^^^^^^ Formatter objects configure the final order, structure, and contents of the log message. Unlike the base :class:`logging.Handler` class, application code may instantiate formatter classes, although you could likely subclass the formatter if your application needs special behavior. The constructor takes three optional arguments -- a message format string, a date format string and a style indicator. .. method:: logging.Formatter.__init__(fmt=None, datefmt=None, style='%') If there is no message format string, the default is to use the raw message. If there is no date format string, the default date format is:: %Y-%m-%d %H:%M:%S with the milliseconds tacked on at the end. The ``style`` is one of `%`, '{' or '$'. If one of these is not specified, then '%' will be used. If the ``style`` is '%', the message format string uses ``%(<dictionary key>)s`` styled string substitution; the possible keys are documented in :ref:`logrecord-attributes`. If the style is '{', the message format string is assumed to be compatible with :meth:`str.format` (using keyword arguments), while if the style is '$' then the message format string should conform to what is expected by :meth:`string.Template.substitute`. .. versionchanged:: 3.2 Added the ``style`` parameter. The following message format string will log the time in a human-readable format, the severity of the message, and the contents of the message, in that order:: '%(asctime)s - %(levelname)s - %(message)s' Formatters use a user-configurable function to convert the creation time of a record to a tuple. By default, :func:`time.localtime` is used; to change this for a particular formatter instance, set the ``converter`` attribute of the instance to a function with the same signature as :func:`time.localtime` or :func:`time.gmtime`. To change it for all formatters, for example if you want all logging times to be shown in GMT, set the ``converter`` attribute in the Formatter class (to ``time.gmtime`` for GMT display). Configuring Logging ^^^^^^^^^^^^^^^^^^^ .. currentmodule:: logging.config Programmers can configure logging in three ways: 1. Creating loggers, handlers, and formatters explicitly using Python code that calls the configuration methods listed above. 2. Creating a logging config file and reading it using the :func:`fileConfig` function. 3. Creating a dictionary of configuration information and passing it to the :func:`dictConfig` function. For the reference documentation on the last two options, see :ref:`logging-config-api`. The following example configures a very simple logger, a console handler, and a simple formatter using Python code:: import logging # create logger logger = logging.getLogger('simple_example') logger.setLevel(logging.DEBUG) # create console handler and set level to debug ch = logging.StreamHandler() ch.setLevel(logging.DEBUG) # create formatter formatter = logging.Formatter('%(asctime)s - %(name)s - %(levelname)s - %(message)s') # add formatter to ch ch.setFormatter(formatter) # add ch to logger logger.addHandler(ch) # 'application' code logger.debug('debug message') logger.info('info message') logger.warn('warn message') logger.error('error message') logger.critical('critical message') Running this module from the command line produces the following output:: $ python simple_logging_module.py 2005-03-19 15:10:26,618 - simple_example - DEBUG - debug message 2005-03-19 15:10:26,620 - simple_example - INFO - info message 2005-03-19 15:10:26,695 - simple_example - WARNING - warn message 2005-03-19 15:10:26,697 - simple_example - ERROR - error message 2005-03-19 15:10:26,773 - simple_example - CRITICAL - critical message The following Python module creates a logger, handler, and formatter nearly identical to those in the example listed above, with the only difference being the names of the objects:: import logging import logging.config logging.config.fileConfig('logging.conf') # create logger logger = logging.getLogger('simpleExample') # 'application' code logger.debug('debug message') logger.info('info message') logger.warn('warn message') logger.error('error message') logger.critical('critical message') Here is the logging.conf file:: [loggers] keys=root,simpleExample [handlers] keys=consoleHandler [formatters] keys=simpleFormatter [logger_root] level=DEBUG handlers=consoleHandler [logger_simpleExample] level=DEBUG handlers=consoleHandler qualname=simpleExample propagate=0 [handler_consoleHandler] class=StreamHandler level=DEBUG formatter=simpleFormatter args=(sys.stdout,) [formatter_simpleFormatter] format=%(asctime)s - %(name)s - %(levelname)s - %(message)s datefmt= The output is nearly identical to that of the non-config-file-based example:: $ python simple_logging_config.py 2005-03-19 15:38:55,977 - simpleExample - DEBUG - debug message 2005-03-19 15:38:55,979 - simpleExample - INFO - info message 2005-03-19 15:38:56,054 - simpleExample - WARNING - warn message 2005-03-19 15:38:56,055 - simpleExample - ERROR - error message 2005-03-19 15:38:56,130 - simpleExample - CRITICAL - critical message You can see that the config file approach has a few advantages over the Python code approach, mainly separation of configuration and code and the ability of noncoders to easily modify the logging properties. .. warning:: The :func:`fileConfig` function takes a default parameter, ``disable_existing_loggers``, which defaults to ``True`` for reasons of backward compatibility. This may or may not be what you want, since it will cause any loggers existing before the :func:`fileConfig` call to be disabled unless they (or an ancestor) are explicitly named in the configuration. Please refer to the reference documentation for more information, and specify ``False`` for this parameter if you wish. The dictionary passed to :func:`dictConfig` can also specify a Boolean value with key ``disable_existing_loggers``, which if not specified explicitly in the dictionary also defaults to being interpreted as ``True``. This leads to the logger-disabling behaviour described above, which may not be what you want - in which case, provide the key explicitly with a value of ``False``. .. currentmodule:: logging Note that the class names referenced in config files need to be either relative to the logging module, or absolute values which can be resolved using normal import mechanisms. Thus, you could use either :class:`~logging.handlers.WatchedFileHandler` (relative to the logging module) or ``mypackage.mymodule.MyHandler`` (for a class defined in package ``mypackage`` and module ``mymodule``, where ``mypackage`` is available on the Python import path). In Python 3.2, a new means of configuring logging has been introduced, using dictionaries to hold configuration information. This provides a superset of the functionality of the config-file-based approach outlined above, and is the recommended configuration method for new applications and deployments. Because a Python dictionary is used to hold configuration information, and since you can populate that dictionary using different means, you have more options for configuration. For example, you can use a configuration file in JSON format, or, if you have access to YAML processing functionality, a file in YAML format, to populate the configuration dictionary. Or, of course, you can construct the dictionary in Python code, receive it in pickled form over a socket, or use whatever approach makes sense for your application. Here's an example of the same configuration as above, in YAML format for the new dictionary-based approach:: version: 1 formatters: simple: format: '%(asctime)s - %(name)s - %(levelname)s - %(message)s' handlers: console: class: logging.StreamHandler level: DEBUG formatter: simple stream: ext://sys.stdout loggers: simpleExample: level: DEBUG handlers: [console] propagate: no root: level: DEBUG handlers: [console] For more information about logging using a dictionary, see :ref:`logging-config-api`. What happens if no configuration is provided ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ If no logging configuration is provided, it is possible to have a situation where a logging event needs to be output, but no handlers can be found to output the event. The behaviour of the logging package in these circumstances is dependent on the Python version. For versions of Python prior to 3.2, the behaviour is as follows: * If *logging.raiseExceptions* is *False* (production mode), the event is silently dropped. * If *logging.raiseExceptions* is *True* (development mode), a message 'No handlers could be found for logger X.Y.Z' is printed once. In Python 3.2 and later, the behaviour is as follows: * The event is output using a 'handler of last resort', stored in ``logging.lastResort``. This internal handler is not associated with any logger, and acts like a :class:`~logging.StreamHandler` which writes the event description message to the current value of ``sys.stderr`` (therefore respecting any redirections which may be in effect). No formatting is done on the message - just the bare event description message is printed. The handler's level is set to ``WARNING``, so all events at this and greater severities will be output. To obtain the pre-3.2 behaviour, ``logging.lastResort`` can be set to *None*. .. _library-config: Configuring Logging for a Library ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ When developing a library which uses logging, you should take care to document how the library uses logging - for example, the names of loggers used. Some consideration also needs to be given to its logging configuration. If the using application does not use logging, and library code makes logging calls, then (as described in the previous section) events of severity ``WARNING`` and greater will be printed to ``sys.stderr``. This is regarded as the best default behaviour. If for some reason you *don't* want these messages printed in the absence of any logging configuration, you can attach a do-nothing handler to the top-level logger for your library. This avoids the message being printed, since a handler will be always be found for the library's events: it just doesn't produce any output. If the library user configures logging for application use, presumably that configuration will add some handlers, and if levels are suitably configured then logging calls made in library code will send output to those handlers, as normal. A do-nothing handler is included in the logging package: :class:`~logging.NullHandler` (since Python 3.1). An instance of this handler could be added to the top-level logger of the logging namespace used by the library (*if* you want to prevent your library's logged events being output to ``sys.stderr`` in the absence of logging configuration). If all logging by a library *foo* is done using loggers with names matching 'foo.x', 'foo.x.y', etc. then the code:: import logging logging.getLogger('foo').addHandler(logging.NullHandler()) should have the desired effect. If an organisation produces a number of libraries, then the logger name specified can be 'orgname.foo' rather than just 'foo'. .. note:: It is strongly advised that you *do not add any handlers other than* :class:`~logging.NullHandler` *to your library's loggers*. This is because the configuration of handlers is the prerogative of the application developer who uses your library. The application developer knows their target audience and what handlers are most appropriate for their application: if you add handlers 'under the hood', you might well interfere with their ability to carry out unit tests and deliver logs which suit their requirements. Logging Levels -------------- The numeric values of logging levels are given in the following table. These are primarily of interest if you want to define your own levels, and need them to have specific values relative to the predefined levels. If you define a level with the same numeric value, it overwrites the predefined value; the predefined name is lost. +--------------+---------------+ | Level | Numeric value | +==============+===============+ | ``CRITICAL`` | 50 | +--------------+---------------+ | ``ERROR`` | 40 | +--------------+---------------+ | ``WARNING`` | 30 | +--------------+---------------+ | ``INFO`` | 20 | +--------------+---------------+ | ``DEBUG`` | 10 | +--------------+---------------+ | ``NOTSET`` | 0 | +--------------+---------------+ Levels can also be associated with loggers, being set either by the developer or through loading a saved logging configuration. When a logging method is called on a logger, the logger compares its own level with the level associated with the method call. If the logger's level is higher than the method call's, no logging message is actually generated. This is the basic mechanism controlling the verbosity of logging output. Logging messages are encoded as instances of the :class:`~logging.LogRecord` class. When a logger decides to actually log an event, a :class:`~logging.LogRecord` instance is created from the logging message. Logging messages are subjected to a dispatch mechanism through the use of :dfn:`handlers`, which are instances of subclasses of the :class:`Handler` class. Handlers are responsible for ensuring that a logged message (in the form of a :class:`LogRecord`) ends up in a particular location (or set of locations) which is useful for the target audience for that message (such as end users, support desk staff, system administrators, developers). Handlers are passed :class:`LogRecord` instances intended for particular destinations. Each logger can have zero, one or more handlers associated with it (via the :meth:`~Logger.addHandler` method of :class:`Logger`). In addition to any handlers directly associated with a logger, *all handlers associated with all ancestors of the logger* are called to dispatch the message (unless the *propagate* flag for a logger is set to a false value, at which point the passing to ancestor handlers stops). Just as for loggers, handlers can have levels associated with them. A handler's level acts as a filter in the same way as a logger's level does. If a handler decides to actually dispatch an event, the :meth:`~Handler.emit` method is used to send the message to its destination. Most user-defined subclasses of :class:`Handler` will need to override this :meth:`~Handler.emit`. .. _custom-levels: Custom Levels ^^^^^^^^^^^^^ Defining your own levels is possible, but should not be necessary, as the existing levels have been chosen on the basis of practical experience. However, if you are convinced that you need custom levels, great care should be exercised when doing this, and it is possibly *a very bad idea to define custom levels if you are developing a library*. That's because if multiple library authors all define their own custom levels, there is a chance that the logging output from such multiple libraries used together will be difficult for the using developer to control and/or interpret, because a given numeric value might mean different things for different libraries. .. _useful-handlers: Useful Handlers --------------- In addition to the base :class:`Handler` class, many useful subclasses are provided: #. :class:`StreamHandler` instances send messages to streams (file-like objects). #. :class:`FileHandler` instances send messages to disk files. #. :class:`~handlers.BaseRotatingHandler` is the base class for handlers that rotate log files at a certain point. It is not meant to be instantiated directly. Instead, use :class:`~handlers.RotatingFileHandler` or :class:`~handlers.TimedRotatingFileHandler`. #. :class:`~handlers.RotatingFileHandler` instances send messages to disk files, with support for maximum log file sizes and log file rotation. #. :class:`~handlers.TimedRotatingFileHandler` instances send messages to disk files, rotating the log file at certain timed intervals. #. :class:`~handlers.SocketHandler` instances send messages to TCP/IP sockets. Since 3.4, Unix domain sockets are also supported. #. :class:`~handlers.DatagramHandler` instances send messages to UDP sockets. Since 3.4, Unix domain sockets are also supported. #. :class:`~handlers.SMTPHandler` instances send messages to a designated email address. #. :class:`~handlers.SysLogHandler` instances send messages to a Unix syslog daemon, possibly on a remote machine. #. :class:`~handlers.NTEventLogHandler` instances send messages to a Windows NT/2000/XP event log. #. :class:`~handlers.MemoryHandler` instances send messages to a buffer in memory, which is flushed whenever specific criteria are met. #. :class:`~handlers.HTTPHandler` instances send messages to an HTTP server using either ``GET`` or ``POST`` semantics. #. :class:`~handlers.WatchedFileHandler` instances watch the file they are logging to. If the file changes, it is closed and reopened using the file name. This handler is only useful on Unix-like systems; Windows does not support the underlying mechanism used. #. :class:`~handlers.QueueHandler` instances send messages to a queue, such as those implemented in the :mod:`queue` or :mod:`multiprocessing` modules. #. :class:`NullHandler` instances do nothing with error messages. They are used by library developers who want to use logging, but want to avoid the 'No handlers could be found for logger XXX' message which can be displayed if the library user has not configured logging. See :ref:`library-config` for more information. .. versionadded:: 3.1 The :class:`NullHandler` class. .. versionadded:: 3.2 The :class:`~handlers.QueueHandler` class. The :class:`NullHandler`, :class:`StreamHandler` and :class:`FileHandler` classes are defined in the core logging package. The other handlers are defined in a sub- module, :mod:`logging.handlers`. (There is also another sub-module, :mod:`logging.config`, for configuration functionality.) Logged messages are formatted for presentation through instances of the :class:`Formatter` class. They are initialized with a format string suitable for use with the % operator and a dictionary. For formatting multiple messages in a batch, instances of :class:`~handlers.BufferingFormatter` can be used. In addition to the format string (which is applied to each message in the batch), there is provision for header and trailer format strings. When filtering based on logger level and/or handler level is not enough, instances of :class:`Filter` can be added to both :class:`Logger` and :class:`Handler` instances (through their :meth:`~Handler.addFilter` method). Before deciding to process a message further, both loggers and handlers consult all their filters for permission. If any filter returns a false value, the message is not processed further. The basic :class:`Filter` functionality allows filtering by specific logger name. If this feature is used, messages sent to the named logger and its children are allowed through the filter, and all others dropped. .. _logging-exceptions: Exceptions raised during logging -------------------------------- The logging package is designed to swallow exceptions which occur while logging in production. This is so that errors which occur while handling logging events - such as logging misconfiguration, network or other similar errors - do not cause the application using logging to terminate prematurely. :class:`SystemExit` and :class:`KeyboardInterrupt` exceptions are never swallowed. Other exceptions which occur during the :meth:`~Handler.emit` method of a :class:`Handler` subclass are passed to its :meth:`~Handler.handleError` method. The default implementation of :meth:`~Handler.handleError` in :class:`Handler` checks to see if a module-level variable, :data:`raiseExceptions`, is set. If set, a traceback is printed to :data:`sys.stderr`. If not set, the exception is swallowed. .. note:: The default value of :data:`raiseExceptions` is ``True``. This is because during development, you typically want to be notified of any exceptions that occur. It's advised that you set :data:`raiseExceptions` to ``False`` for production usage. .. currentmodule:: logging .. _arbitrary-object-messages: Using arbitrary objects as messages ----------------------------------- In the preceding sections and examples, it has been assumed that the message passed when logging the event is a string. However, this is not the only possibility. You can pass an arbitrary object as a message, and its :meth:`~object.__str__` method will be called when the logging system needs to convert it to a string representation. In fact, if you want to, you can avoid computing a string representation altogether - for example, the :class:`~handlers.SocketHandler` emits an event by pickling it and sending it over the wire. Optimization ------------ Formatting of message arguments is deferred until it cannot be avoided. However, computing the arguments passed to the logging method can also be expensive, and you may want to avoid doing it if the logger will just throw away your event. To decide what to do, you can call the :meth:`~Logger.isEnabledFor` method which takes a level argument and returns true if the event would be created by the Logger for that level of call. You can write code like this:: if logger.isEnabledFor(logging.DEBUG): logger.debug('Message with %s, %s', expensive_func1(), expensive_func2()) so that if the logger's threshold is set above ``DEBUG``, the calls to :func:`expensive_func1` and :func:`expensive_func2` are never made. .. note:: In some cases, :meth:`~Logger.isEnabledFor` can itself be more expensive than you'd like (e.g. for deeply nested loggers where an explicit level is only set high up in the logger hierarchy). In such cases (or if you want to avoid calling a method in tight loops), you can cache the result of a call to :meth:`~Logger.isEnabledFor` in a local or instance variable, and use that instead of calling the method each time. Such a cached value would only need to be recomputed when the logging configuration changes dynamically while the application is running (which is not all that common). There are other optimizations which can be made for specific applications which need more precise control over what logging information is collected. Here's a list of things you can do to avoid processing during logging which you don't need: +-----------------------------------------------+----------------------------------------+ | What you don't want to collect | How to avoid collecting it | +===============================================+========================================+ | Information about where calls were made from. | Set ``logging._srcfile`` to ``None``. | | | This avoids calling | | | :func:`sys._getframe`, which may help | | | to speed up your code in environments | | | like PyPy (which can't speed up code | | | that uses :func:`sys._getframe`), if | | | and when PyPy supports Python 3.x. | +-----------------------------------------------+----------------------------------------+ | Threading information. | Set ``logging.logThreads`` to ``0``. | +-----------------------------------------------+----------------------------------------+ | Process information. | Set ``logging.logProcesses`` to ``0``. | +-----------------------------------------------+----------------------------------------+ Also note that the core logging module only includes the basic handlers. If you don't import :mod:`logging.handlers` and :mod:`logging.config`, they won't take up any memory. .. seealso:: Module :mod:`logging` API reference for the logging module. Module :mod:`logging.config` Configuration API for the logging module. Module :mod:`logging.handlers` Useful handlers included with the logging module. :ref:`A logging cookbook <logging-cookbook>`
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