View Source Logging
Erlang provides a standard API for logging through Logger
, which is part of
the Kernel application. Logger consists of the API for issuing log events, and a
customizable backend where log handlers, filters and formatters can be plugged
in.
By default, the Kernel application installs one log handler at system start.
This handler is named default
. It receives and processes standard log events
produced by the Erlang runtime system, standard behaviours and different
Erlang/OTP applications. The log events are by default written to the terminal.
You can also configure the system so that the default handler prints log events
to a single file, or to a set of wrap logs via disk_log
.
By configuration, you can also modify or disable the default handler, replace it by a custom handler, and install additional handlers.
Overview
A log event consists of a log level, the message to be logged, and metadata.
The Logger backend forwards log events from the API, first through a set of primary filters, then through a set of secondary filters attached to each log handler. The secondary filters are in the following named handler filters.
Each filter set consists of a log level check, followed by zero or more filter functions.
The following figure shows a conceptual overview of Logger. The figure shows two log handlers, but any number of handlers can be installed.
---
title: Conceptual Overview
---
flowchart TD
DB[(Config DB)]
API ---> ML[Module Level <hr> Global Level <hr> Global Filters]
API -.Update configuration.-> DB
ML -.-> DB
ML ---> HL1[Hander Level <hr> Handler Filter]
ML ---> HL2[Hander Level <hr> Handler Filter]
HL1 ---> HC1[Handler Callback]
HL2 ---> HC2[Handler Callback]
HL1 -.-> DB
HL2 -.-> DB
subgraph Legend
direction LR
start1[ ] -->|Log event flow| stop1[ ]
style start1 height:0px;
style stop1 height:0px;
start2[ ] -.->|Look up configuration| stop2[ ]
style start2 height:0px;
style stop2 height:0px;
end
Log levels are expressed as atoms. Internally in Logger, the atoms are mapped to integer values, and a log event passes the log level check if the integer value of its log level is less than or equal to the currently configured log level. That is, the check passes if the event is equally or more severe than the configured level. See section Log Level for a listing and description of all log levels.
The primary log level can be overridden by a log level configured per module. This is to, for instance, allow more verbose logging from a specific part of the system.
Filter functions can be used for more sophisticated filtering than the log level check provides. A filter function can stop or pass a log event, based on any of the event's contents. It can also modify all parts of the log event. See section Filters for more details.
If a log event passes through all primary filters and all handler filters for a specific handler, Logger forwards the event to the handler callback. The handler formats and prints the event to its destination. See section Handlers for more details.
Everything up to and including the call to the handler callbacks is executed on the client process, that is, the process where the log event was issued. It is up to the handler implementation if other processes are involved or not.
The handlers are called in sequence, and the order is not defined.
Logger API
The API for logging consists of a set of macros, and a set
of functions on the form logger:Level/1,2,3
, which are all shortcuts for
logger:log(Level,Arg1[,Arg2[,Arg3]])
.
The macros are defined in logger.hrl
, which is included in a module with the
directive
-include_lib("kernel/include/logger.hrl").
The difference between using the macros and the exported functions is that macros add location (originator) information to the metadata, and performs lazy evaluation by wrapping the logger call in a case statement, so it is only evaluated if the log level of the event passes the primary log level check.
Log Level
The log level indicates the severity of a event. In accordance with the Syslog protocol, RFC 5424, eight log levels can be specified. The following table lists all possible log levels by name (atom), integer value, and description:
Level | Integer | Description |
---|---|---|
emergency | 0 | system is unusable |
alert | 1 | action must be taken immediately |
critical | 2 | critical conditions |
error | 3 | error conditions |
warning | 4 | warning conditions |
notice | 5 | normal but significant conditions |
info | 6 | informational messages |
debug | 7 | debug-level messages |
Table: Log Levels
Notice that the integer value is only used internally in Logger. In the API, you
must always use the atom. To compare the severity of two log levels, use
logger:compare_levels/2
.
Log Message
The log message contains the information to be logged. The message can consist of a format string and arguments (given as two separate parameters in the Logger API), a string or a report.
Example, format string and arguments:
logger:error("The file does not exist: ~ts",[Filename])
Example, string:
logger:notice("Something strange happened!")
A report, which is either a map or a key-value list, is the preferred way to log using Logger as it makes it possible for different backends to filter and format the log event as it needs to.
Example, report:
?LOG_ERROR(#{ user => joe, filename => Filename, reason => enoent })
Reports can be accompanied by a report callback specified in the log event's metadata. The report callback is a convenience function that the formatter can use to convert the report to a format string and arguments, or directly to a string. The formatter can also use its own conversion function, if no callback is provided, or if a customized formatting is desired.
The report callback must be a fun with one or two arguments. If it takes one argument, this is the report itself, and the fun returns a format string and arguments:
fun((logger:report()) -> {io:format(),[term()]})
If it takes two arguments, the first is the report, and the second is a map containing extra data that allows direct conversion to a string:
fun((logger:report(),logger:report_cb_config()) -> unicode:chardata())
The fun must obey the depth
and chars_limit
parameters provided in the
second argument, as the formatter cannot do anything useful of these parameters
with the returned string. The extra data also contains a field named
single_line
, indicating if the printed log message may contain line breaks or
not. This variant is used when the formatting of the report depends on the size
or single line parameters.
Example, report, and metadata with report callback:
logger:debug(#{got => connection_request, id => Id, state => State},
#{report_cb => fun(R) -> {"~p",[R]} end})
The log message can also be provided through a fun for lazy evaluation. The fun is only evaluated if the primary log level check passes, and is therefore recommended if it is expensive to generate the message. The lazy fun must return a string, a report, or a tuple with format string and arguments.
Metadata
Metadata contains additional data associated with a log message. Logger inserts some metadata fields by default, and the client can add custom metadata in three different ways:
Set primary metadata - Primary metadata applies is the base metadata given to all log events. At startup it can be set using the kernel configuration parameter logger_metadata. At run-time it can be set and updated using
logger:set_primary_config/1
andlogger:update_primary_config/1
respectively.Set process metadata - Process metadata is set and updated with
logger:set_process_metadata/1
andlogger:update_process_metadata/1
, respectively. This metadata applies to the process on which these calls are made, and Logger adds the metadata to all log events issued on that process.Add metadata to a specific log event - Metadata associated with one specific log event is given as the last parameter to the log macro or Logger API function when the event is issued. For example:
?LOG_ERROR("Connection closed",#{context => server})
See the description of the logger:metadata/0
type for information about
which default keys Logger inserts, and how the different metadata maps are
merged.
Filters
Filters can be primary, or attached to a specific handler. Logger calls the primary filters first, and if they all pass, it calls the handler filters for each handler. Logger calls the handler callback only if all filters attached to the handler in question also pass.
A filter is defined as:
{FilterFun, Extra}
where FilterFun
is a function of arity 2, and Extra
is any term. When
applying the filter, Logger calls the function with the log event as the first
argument, and the value of Extra
as the second argument. See
logger:filter/0
for type definitions.
The filter function can return stop
, ignore
or the (possibly modified) log
event.
If stop
is returned, the log event is immediately discarded. If the filter is
primary, no handler filters or callbacks are called. If it is a handler filter,
the corresponding handler callback is not called, but the log event is forwarded
to filters attached to the next handler, if any.
If the log event is returned, the next filter function is called with the returned value as the first argument. That is, if a filter function modifies the log event, the next filter function receives the modified event. The value returned from the last filter function is the value that the handler callback receives.
If the filter function returns ignore
, it means that it did not recognize the
log event, and thus leaves to other filters to decide the event's destiny.
The configuration option filter_default
specifies the behaviour if all filter
functions return ignore
, or if no filters exist. filter_default
is by
default set to log
, meaning that if all existing filters ignore a log event,
Logger forwards the event to the handler callback. If filter_default
is set to
stop
, Logger discards such events.
Primary filters are added with logger:add_primary_filter/2
and removed with
logger:remove_primary_filter/1
. They can also be added at system start via the
Kernel configuration parameter logger
.
Handler filters are added with logger:add_handler_filter/3
and removed with
logger:remove_handler_filter/2
. They can also be specified directly in the
configuration when adding a handler with logger:add_handler/3
or via the
Kernel configuration parameter logger
.
To see which filters are currently installed in the system, use
logger:get_config/0
, or logger:get_primary_config/0
and
logger:get_handler_config/1
. Filters are listed in the order they are applied,
that is, the first filter in the list is applied first, and so on.
For convenience, the following built-in filters exist:
logger_filters:domain/2
- Provides a way of filtering log events based on adomain
field inMetadata
.logger_filters:level/2
- Provides a way of filtering log events based on the log level.logger_filters:progress/2
- Stops or allows progress reports fromsupervisor
andapplication_controller
.logger_filters:remote_gl/2
- Stops or allows log events originating from a process that has its group leader on a remote node.
Handlers
A handler is defined as a module exporting at least the following callback function:
log(LogEvent, Config) -> term()
This function is called when a log event has passed through all primary filters, and all handler filters attached to the handler in question. The function call is executed on the client process, and it is up to the handler implementation if other processes are involved or not.
Logger allows adding multiple instances of a handler callback. That is, if a callback module implementation allows it, you can add multiple handler instances using the same callback module. The different instances are identified by unique handler identities.
In addition to the mandatory callback function log/2
, a handler module can
export the optional callback functions adding_handler/1
, changing_config/3
,
filter_config/1
, and removing_handler/1
. See logger_handler
for more
information about these function.
The following built-in handlers exist:
logger_std_h
- This is the default handler used by OTP. Multiple instances can be started, and each instance will write log events to a given destination, terminal or file.logger_disk_log_h
- This handler behaves much likelogger_std_h
, except it usesdisk_log
as its destination.error_logger
- This handler is provided for backwards compatibility only. It is not started by default, but will be automatically started the first time anerror_logger
event handler is added witherror_logger:add_report_handler/1,2
.The old
error_logger
event handlers in STDLIB and SASL still exist, but they are not added by Erlang/OTP 21.0 or later.
Formatters
A formatter can be used by the handler implementation to do the final formatting
of a log event, before printing to the handler's destination. The handler
callback receives the formatter information as part of the handler
configuration, which is passed as the second argument to
HModule:log/2
.
The formatter information consist of a formatter module, FModule
and its
configuration, FConfig
. FModule
must export the following function, which
can be called by the handler:
format(LogEvent,FConfig)
-> FormattedLogEntry
The formatter information for a handler is set as a part of its configuration
when the handler is added. It can also be changed during runtime with
logger:set_handler_config(HandlerId,formatter,{Module,FConfig})
,
which overwrites the current formatter information, or with
logger:update_formatter_config/2,3
,
which only modifies the formatter configuration.
If the formatter module exports the optional callback function
check_config(FConfig)
, Logger calls
this function when the formatter information is set or modified, to verify the
validity of the formatter configuration.
If no formatter information is specified for a handler, Logger uses
logger_formatter
as default. See the logger_formatter
manual page for more
information about this module.
Configuration
At system start, Logger is configured through Kernel configuration parameters. The parameters that apply to Logger are described in section Kernel Configuration Parameters. Examples are found in section Configuration Examples.
During runtime, Logger configuration is changed via API functions. See section
Configuration API Functions in the logger
manual page.
Primary Logger Configuration
Logger API functions that apply to the primary Logger configuration are:
get_primary_config/0
set_primary_config/1,2
update_primary_config/1
add_primary_filter/2
remove_primary_filter/1
The primary Logger configuration is a map with the following keys:
level =
t:logger:level/0`` | all | none
- Specifies the primary log level, that is, log event that are equally or more severe than this level, are forwarded to the primary filters. Less severe log events are immediately discarded.See section Log Level for a listing and description of possible log levels.
The initial value of this option is set by the Kernel configuration parameter
logger_level
. It is changed during runtime withlogger:set_primary_config(level,Level)
.Defaults to
notice
.filters = [{FilterId,Filter}]
- Specifies the primary filters.FilterId = ``t:logger:filter_id/0
Filter = ``t:logger:filter/0
The initial value of this option is set by the Kernel configuration parameter
logger
. During runtime, primary filters are added and removed withlogger:add_primary_filter/2
andlogger:remove_primary_filter/1
, respectively.See section Filters for more detailed information.
Defaults to
[]
.filter_default = log | stop
- Specifies what happens to a log event if all filters returnignore
, or if no filters exist.See section Filters for more information about how this option is used.
Defaults to
log
.metadata =
metadata()
- The primary metadata to be used for all log calls.See section Metadata for more information about how this option is used.
Defaults to
#{}
.
Handler Configuration
Logger API functions that apply to handler configuration are:
get_handler_config/0,1
set_handler_config/2,3
update_handler_config/2,3
add_handler_filter/3
remove_handler_filter/2
update_formatter_config/2,3
The configuration for a handler is a map with the following keys:
id = ``t:logger_handler:id/0
- Automatically inserted by Logger. The value is the same as theHandlerId
specified when adding the handler, and it cannot be changed.module = module()
- Automatically inserted by Logger. The value is the same as theModule
specified when adding the handler, and it cannot be changed.level = ``t:logger:level/0`` | all | none
- Specifies the log level for the handler, that is, log events that are equally or more severe than this level, are forwarded to the handler filters for this handler.See section Log Level for a listing and description of possible log levels.
The log level is specified when adding the handler, or changed during runtime with, for instance,
logger:set_handler_config(HandlerId,level,Level)
.Defaults to
all
.filters = [{FilterId,Filter}]
- Specifies the handler filters.FilterId = ``t:logger:filter_id/0
Filter = ``t:logger:filter/0
Handler filters are specified when adding the handler, or added or removed during runtime with
logger:add_handler_filter/3
andlogger:remove_handler_filter/2
, respectively.See Filters for more detailed information.
Defaults to
[]
.filter_default = log | stop
- Specifies what happens to a log event if all filters returnignore
, or if no filters exist.See section Filters for more information about how this option is used.
Defaults to
log
.formatter = {FormatterModule,FormatterConfig}
- Specifies a formatter that the handler can use for converting the log event term to a printable string.FormatterModule = module()
FormatterConfig = ``t:logger:formatter_config/0
The formatter information is specified when adding the handler. The formatter configuration can be changed during runtime with
logger:update_formatter_config/2,3
, or the complete formatter information can be overwritten with, for instance,logger:set_handler_config/3
.See section Formatters for more detailed information.
Defaults to
{logger_formatter,DefaultFormatterConfig}
. See thelogger_formatter
manual page for information about this formatter and its default configuration.config = term()
- Handler specific configuration, that is, configuration data related to a specific handler implementation.The configuration for the built-in handlers is described in the
logger_std_h
andlogger_disk_log_h
manual pages.
Notice that level
and filters
are obeyed by Logger itself before forwarding
the log events to each handler, while formatter
and all handler specific
options are left to the handler implementation.
Kernel Configuration Parameters
The following Kernel configuration parameters apply to Logger:
logger = [Config]
- Specifies the configuration for Logger, except the primary log level, which is specified withlogger_level
, and the compatibility with SASL Error Logging, which is specified withlogger_sasl_compatible
.With this parameter, you can modify or disable the default handler, add custom handlers and primary logger filters, set log levels per module, and modify the proxy configuration.
Config
is any (zero or more) of the following:{handler, default, undefined}
- Disables the default handler. This allows another application to add its own default handler.Only one entry of this type is allowed.
{handler, HandlerId, Module, HandlerConfig}
- IfHandlerId
isdefault
, then this entry modifies the default handler, equivalent to callinglogger:remove_handler(default)
followed by
logger:add_handler(default, Module, HandlerConfig)
For all other values of
HandlerId
, this entry adds a new handler, equivalent to callinglogger:add_handler(HandlerId, Module, HandlerConfig)
Multiple entries of this type are allowed.
{filters, FilterDefault, [Filter]}
- Adds the specified primary filters.FilterDefault = log | stop
Filter = {FilterId, {FilterFun, FilterConfig}}
Equivalent to calling
logger:add_primary_filter(FilterId, {FilterFun, FilterConfig})
for each
Filter
.FilterDefault
specifies the behaviour if all primary filters returnignore
, see section Filters.Only one entry of this type is allowed.
{module_level, Level, [Module]}
- Sets module log level for the given modules. Equivalent to callinglogger:set_module_level(Module, Level)
for each
Module
.Multiple entries of this type are allowed.
{proxy, ProxyConfig}
- Sets the proxy configuration, equivalent to callinglogger:set_proxy_config(ProxyConfig)
Only one entry of this type is allowed.
See section Configuration Examples for examples using the
logger
parameter for system configuration.logger_metadata = map()
- Specifies the primary metadata. See thekernel(6)
manual page for more information about this parameter.logger_level = Level
- Specifies the primary log level. See thekernel(6)
manual page for more information about this parameter.logger_sasl_compatible = true | false
- Specifies Logger's compatibility with SASL Error Logging. See thekernel(6)
manual page for more information about this parameter.
Configuration Examples
The value of the Kernel configuration parameter logger
is a list of tuples. It
is possible to write the term on the command line when starting an erlang node,
but as the term grows, a better approach is to use the system configuration
file. See the config(4)
manual page for more information about
this file.
Each of the following examples shows a simple system configuration file that configures Logger according to the description.
Modify the default handler to print to a file instead of
standard_io
:
[{kernel,
[{logger,
[{handler, default, logger_std_h, % {handler, HandlerId, Module,
#{config => #{file => "log/erlang.log"}}} % Config}
]}]}].
Modify the default handler to print each log event as a single line:
[{kernel,
[{logger,
[{handler, default, logger_std_h,
#{formatter => {logger_formatter, #{single_line => true}}}}
]}]}].
Modify the default handler to print the pid of the logging process for each log event:
[{kernel,
[{logger,
[{handler, default, logger_std_h,
#{formatter => {logger_formatter,
#{template => [time," ",pid," ",msg,"\n"]}}}}
]}]}].
Modify the default handler to only print errors and more severe log events to "log/erlang.log", and add another handler to print all log events to "log/debug.log".
[{kernel,
[{logger,
[{handler, default, logger_std_h,
#{level => error,
config => #{file => "log/erlang.log"}}},
{handler, info, logger_std_h,
#{level => debug,
config => #{file => "log/debug.log"}}}
]}]}].
Backwards Compatibility with error_logger
Logger provides backwards compatibility with error_logger
in the following
ways:
API for Logging - The
error_logger
API still exists, but should only be used by legacy code. It will be removed in a later release.Calls to
error_logger:error_report/1,2
,error_logger:error_msg/1,2
, and corresponding functions for warning and info messages, are all forwarded to Logger as calls tologger:log(Level,Report,Metadata)
.Level = error | warning | info
and is taken from the function name.Report
contains the actual log message, andMetadata
contains additional information which can be used for creating backwards compatible events for legacyerror_logger
event handlers, see section Legacy Event Handlers.Output Format - To get log events on the same format as produced by
error_logger_tty_h
anderror_logger_file_h
, use the default formatter,logger_formatter
, with configuration parameterlegacy_header
set totrue
. This is the default configuration of thedefault
handler started by Kernel.Default Format of Log Events from OTP - By default, all log events originating from within OTP, except the former so called "SASL reports", look the same as before.
SASL Reports
By SASL reports we mean supervisor reports, crash reports and progress reports.Prior to Erlang/OTP 21.0, these reports were only logged when the SASL application was running, and they were printed through SASL's own event handlers
sasl_report_tty_h
andsasl_report_file_h
.The destination of these log events was configured by SASL configuration parameters.
Due to the specific event handlers, the output format slightly differed from other log events.
As of Erlang/OTP 21.0, the concept of SASL reports is removed, meaning that the default behaviour is as follows:
- Supervisor reports, crash reports, and progress reports are no longer connected to the SASL application.
- Supervisor reports and crash reports are issued as
error
level log events, and are logged through the default handler started by Kernel. - Progress reports are issued as
info
level log events, and since the default primary log level isnotice
, these are not logged by default. To enable printing of progress reports, set the primary log level toinfo
. - The output format is the same for all log events.
If the old behaviour is preferred, the Kernel configuration parameter
logger_sasl_compatible
can be set totrue
. The SASL configuration parameters can then be used as before, and the SASL reports will only be printed if the SASL application is running, through a second log handler namedsasl
.All SASL reports have a metadata field
domain
which is set to[otp,sasl]
. This field can be used by filters to stop or allow the log events.See section SASL User's Guide for more information about the old SASL error logging functionality.
Legacy Event Handlers
To use event handlers written forerror_logger
, just add your event handler witherror_logger:add_report_handler/1,2.
This automatically starts the error logger event manager, and adds
error_logger
as a handler to Logger, with the following configuration:#{level => info, filter_default => log, filters => []}.
Note
This handler ignores events that do not originate from the
error_logger
API, or from within OTP. This means that if your code uses the Logger API for logging, then your log events will be discarded by this handler.The handler is not overload protected.
Error Handling
Logger does, to a certain extent, check its input data before forwarding a log event to filters and handlers. It does, however, not evaluate report callbacks, or check the validity of format strings and arguments. This means that all filters and handlers must be careful when formatting the data of a log event, making sure that it does not crash due to bad input data or faulty callbacks.
If a filter or handler still crashes, Logger will remove the filter or handler in question from the configuration, and print a short error message to the terminal. A debug event containing the crash reason and other details is also issued.
See section Log Message for more information about report callbacks and valid forms of log messages.
Example: Add a handler to log info events to file
When starting an Erlang node, the default behaviour is that all log events on
level notice
or more severe, are logged to the terminal via the default
handler. To also log info events, you can either change the primary log level to
info
:
1> logger:set_primary_config(level, info).
ok
or set the level for one or a few modules only:
2> logger:set_module_level(mymodule, info).
ok
This allows info events to pass through to the default handler, and be printed to the terminal as well. If there are many info events, it can be useful to print these to a file instead.
First, set the log level of the default handler to notice
, preventing it from
printing info events to the terminal:
3> logger:set_handler_config(default, level, notice).
ok
Then, add a new handler which prints to file. You can use the handler module
logger_std_h
, and configure it to log to file:
4> Config = #{config => #{file => "./info.log"}, level => info}.
#{config => #{file => "./info.log"},level => info}
5> logger:add_handler(myhandler, logger_std_h, Config).
ok
Since filter_default
defaults to log
, this handler now receives all log
events. If you want info events only in the file, you must add a filter to stop
all non-info events. The built-in filter logger_filters:level/2
can do this:
6> logger:add_handler_filter(myhandler, stop_non_info,
{fun logger_filters:level/2, {stop, neq, info}}).
ok
See section Filters for more information about the
filters and the filter_default
configuration parameter.
Example: Implement a handler
logger_handler
describes the callback functions that can be implemented for
a Logger handler.
A handler callback module must export:
log(Log, Config)
It can optionally also export some, or all, of the following:
adding_handler(Config)
removing_handler(Config)
changing_config(SetOrUpdate, OldConfig, NewConfig)
filter_config(Config)
When a handler is added, by for example a call to
logger:add_handler(Id, HModule, Config)
, Logger
first calls HModule:adding_handler(Config)
. If this function returns
{ok,Config1}
, Logger writes Config1
to the configuration database, and the
logger:add_handler/3
call returns. After this, the handler is installed and
must be ready to receive log events as calls to HModule:log/2
.
A handler can be removed by calling
logger:remove_handler(Id)
. Logger calls
HModule:removing_handler(Config)
, and removes the handler's configuration from
the configuration database.
When logger:set_handler_config/2,3
or
logger:update_handler_config/2,3
is
called, Logger calls
HModule:changing_config(SetOrUpdate, OldConfig, NewConfig)
. If this function
returns {ok,NewConfig1}
, Logger writes NewConfig1
to the configuration
database.
When logger:get_config/0
or
logger:get_handler_config/0,1
is called,
Logger calls HModule:filter_config(Config)
. This function must return the
handler configuration where internal data is removed.
A simple handler that prints to the terminal can be implemented as follows:
-module(myhandler1).
-export([log/2]).
log(LogEvent, #{formatter := {FModule, FConfig}}) ->
io:put_chars(FModule:format(LogEvent, FConfig)).
Notice that the above handler does not have any overload protection, and all log events are printed directly from the client process.
For information and examples of overload protection, please refer to section
Protecting the Handler from Overload,
and the implementation of logger_std_h
and
logger_disk_log_h
.
The following is a simpler example of a handler which logs to a file through one single process:
-module(myhandler2).
-export([adding_handler/1, removing_handler/1, log/2]).
-export([init/1, handle_call/3, handle_cast/2, terminate/2]).
adding_handler(Config) ->
MyConfig = maps:get(config,Config,#{file => "myhandler2.log"}),
{ok, Pid} = gen_server:start(?MODULE, MyConfig, []),
{ok, Config#{config => MyConfig#{pid => Pid}}}.
removing_handler(#{config := #{pid := Pid}}) ->
gen_server:stop(Pid).
log(LogEvent,#{config := #{pid := Pid}} = Config) ->
gen_server:cast(Pid, {log, LogEvent, Config}).
init(#{file := File}) ->
{ok, Fd} = file:open(File, [append, {encoding, utf8}]),
{ok, #{file => File, fd => Fd}}.
handle_call(_, _, State) ->
{reply, {error, bad_request}, State}.
handle_cast({log, LogEvent, Config}, #{fd := Fd} = State) ->
do_log(Fd, LogEvent, Config),
{noreply, State}.
terminate(_Reason, #{fd := Fd}) ->
_ = file:close(Fd),
ok.
do_log(Fd, LogEvent, #{formatter := {FModule, FConfig}}) ->
String = FModule:format(LogEvent, FConfig),
io:put_chars(Fd, String).
Protecting the Handler from Overload
The default handlers, logger_std_h
and logger_disk_log_h
, feature an
overload protection mechanism, which makes it possible for the handlers to
survive, and stay responsive, during periods of high load (when huge numbers of
incoming log requests must be handled). The mechanism works as follows:
Message Queue Length
The handler process keeps track of the length of its message queue and takes some form of action when the current length exceeds a configurable threshold. The purpose is to keep the handler in, or to as quickly as possible get the handler into, a state where it can keep up with the pace of incoming log events. The memory use of the handler must never grow larger and larger, since that will eventually cause the handler to crash. These three thresholds, with associated actions, exist:
sync_mode_qlen
- As long as the length of the message queue is lower than this value, all log events are handled asynchronously. This means that the client process sending the log event, by calling a log function in the Logger API, does not wait for a response from the handler but continues executing immediately after the event is sent. It is not affected by the time it takes the handler to print the event to the log device. If the message queue grows larger than this value, the handler starts handling log events synchronously instead, meaning that the client process sending the event must wait for a response. When the handler reduces the message queue to a level below thesync_mode_qlen
threshold, asynchronous operation is resumed. The switch from asynchronous to synchronous mode can slow down the logging tempo of one, or a few, busy senders, but cannot protect the handler sufficiently in a situation of many busy concurrent senders.Defaults to
10
messages.drop_mode_qlen
- When the message queue grows larger than this threshold, the handler switches to a mode in which it drops all new events that senders want to log. Dropping an event in this mode means that the call to the log function never results in a message being sent to the handler, but the function returns without taking any action. The handler keeps logging the events that are already in its message queue, and when the length of the message queue is reduced to a level below the threshold, synchronous or asynchronous mode is resumed. Notice that when the handler activates or deactivates drop mode, information about it is printed in the log.Defaults to
200
messages.flush_qlen
- If the length of the message queue grows larger than this threshold, a flush (delete) operation takes place. To flush events, the handler discards the messages in the message queue by receiving them in a loop without logging. Client processes waiting for a response from a synchronous log request receive a reply from the handler indicating that the request is dropped. The handler process increases its priority during the flush loop to make sure that no new events are received during the operation. Notice that after the flush operation is performed, the handler prints information in the log about how many events have been deleted.Defaults to
1000
messages.
For the overload protection algorithm to work properly, it is required that:
sync_mode_qlen =< drop_mode_qlen =< flush_qlen
and that:
drop_mode_qlen > 1
To disable certain modes, do the following:
- If
sync_mode_qlen
is set to0
, all log events are handled synchronously. That is, asynchronous logging is disabled. - If
sync_mode_qlen
is set to the same value asdrop_mode_qlen
, synchronous mode is disabled. That is, the handler always runs in asynchronous mode, unless dropping or flushing is invoked. - If
drop_mode_qlen
is set to the same value asflush_qlen
, drop mode is disabled and can never occur.
During high load scenarios, the length of the handler message queue rarely grows in a linear and predictable way. Instead, whenever the handler process is scheduled in, it can have an almost arbitrary number of messages waiting in the message queue. It is for this reason that the overload protection mechanism is focused on acting quickly, and quite drastically, such as immediately dropping or flushing messages, when a large queue length is detected.
The values of the previously listed thresholds can be specified by the user. This way, a handler can be configured to, for example, not drop or flush messages unless the message queue length of the handler process grows extremely large. Notice that large amounts of memory can be required for the node under such circumstances. Another example of user configuration is when, for performance reasons, the client processes must never be blocked by synchronous log requests. It is possible, perhaps, that dropping or flushing events is still acceptable, since it does not affect the performance of the client processes sending the log events.
A configuration example:
logger:add_handler(my_standard_h, logger_std_h,
#{config => #{file => "./system_info.log",
sync_mode_qlen => 100,
drop_mode_qlen => 1000,
flush_qlen => 2000}}).
Controlling Bursts of Log Requests
Large bursts of log events - many events received by the handler under a short period of time - can potentially cause problems, such as:
- Log files grow very large, very quickly.
- Circular logs wrap too quickly so that important data is overwritten.
- Write buffers grow large, which slows down file sync operations.
For this reason, both built-in handlers offer the possibility to specify the maximum number of events to be handled within a certain time frame. With this burst control feature enabled, the handler can avoid choking the log with massive amounts of printouts. The configuration parameters are:
burst_limit_enable
- Valuetrue
enables burst control andfalse
disables it.Defaults to
true
.burst_limit_max_count
- This is the maximum number of events to handle within aburst_limit_window_time
time frame. After the limit is reached, successive events are dropped until the end of the time frame.Defaults to
500
events.burst_limit_window_time
- See the previous description ofburst_limit_max_count
.Defaults to
1000
milliseconds.
A configuration example:
logger:add_handler(my_disk_log_h, logger_disk_log_h,
#{config => #{file => "./my_disk_log",
burst_limit_enable => true,
burst_limit_max_count => 20,
burst_limit_window_time => 500}}).
Terminating an Overloaded Handler
It is possible that a handler, even if it can successfully manage peaks of high load without crashing, can build up a large message queue, or use a large amount of memory. The overload protection mechanism includes an automatic termination and restart feature for the purpose of guaranteeing that a handler does not grow out of bounds. The feature is configured with the following parameters:
overload_kill_enable
- Valuetrue
enables the feature andfalse
disables it.Defaults to
false
.overload_kill_qlen
- This is the maximum allowed queue length. If the message queue grows larger than this, the handler process is terminated.Defaults to
20000
messages.overload_kill_mem_size
- This is the maximum memory size that the handler process is allowed to use. If the handler grows larger than this, the process is terminated.Defaults to
3000000
bytes.overload_kill_restart_after
- If the handler is terminated, it restarts automatically after a delay specified in milliseconds. The valueinfinity
prevents restarts.Defaults to
5000
milliseconds.
If the handler process is terminated because of overload, it prints information about it in the log. It also prints information about when a restart has taken place, and the handler is back in action.
Note
The sizes of the log events affect the memory needs of the handler. For information about how to limit the size of log events, see the
logger_formatter
manual page.
Logger Proxy
The Logger proxy is an Erlang process which is part of the Kernel application's
supervision tree. During startup, the proxy process registers itself as the
system_logger
, meaning that log events produced by the emulator are sent to
this process.
When a log event is issued on a process which has its group leader on a remote node, Logger automatically forwards the log event to the group leader's node. To achieve this, it first sends the log event as an Erlang message from the original client process to the proxy on the local node, and the proxy in turn forwards the event to the proxy on the remote node.
When receiving a log event, either from the emulator or from a remote node, the proxy calls the Logger API to log the event.
The proxy process is overload protected in the same way as described in section Protecting the Handler from Overload, but with the following default values:
#{sync_mode_qlen => 500,
drop_mode_qlen => 1000,
flush_qlen => 5000,
burst_limit_enable => false,
overload_kill_enable => false}
For log events from the emulator, synchronous message passing mode is not
applicable, since all messages are passed asynchronously by the emulator. Drop
mode is achieved by setting the system_logger
to undefined
, forcing the
emulator to drop events until it is set back to the proxy pid again.
The proxy uses erlang:send_nosuspend/2
when sending log events to a remote
node. If the message could not be sent without suspending the sender, it is
dropped. This is to avoid blocking the proxy process.
See Also
disk_log
, erlang
, error_logger
, logger
, logger_disk_log_h
,
logger_filters
, logger_formatter
, logger_std_h
,
sasl(6)