vendor/github.com/inconshreveable/log15/doc.go - gddo - Git at Google

 /*
 Package log15 provides an opinionated, simple toolkit for best-practice logging that is
 both human and machine readable. It is modeled after the standard library's io and net/http
 packages.

 This package enforces you to only log key/value pairs. Keys must be strings. Values may be
 any type that you like. The default output format is logfmt, but you may also choose to use
 JSON instead if that suits you. Here's how you log:

     log.Info("page accessed", "path", r.URL.Path, "user_id", user.id)

 This will output a line that looks like:

      lvl=info t=2014-05-02T16:07:23-0700 msg="page accessed" path=/org/71/profile user_id=9

 Getting Started

 To get started, you'll want to import the library:

     import log "github.com/inconshreveable/log15"


 Now you're ready to start logging:

     func main() {
         log.Info("Program starting", "args", os.Args())
     }


 Convention

 Because recording a human-meaningful message is common and good practice, the first argument to every
 logging method is the value to the *implicit* key 'msg'.

 Additionally, the level you choose for a message will be automatically added with the key 'lvl', and so
 will the current timestamp with key 't'.

 You may supply any additional context as a set of key/value pairs to the logging function. log15 allows
 you to favor terseness, ordering, and speed over safety. This is a reasonable tradeoff for
 logging functions. You don't need to explicitly state keys/values, log15 understands that they alternate
 in the variadic argument list:

     log.Warn("size out of bounds", "low", lowBound, "high", highBound, "val", val)

 If you really do favor your type-safety, you may choose to pass a log.Ctx instead:

     log.Warn("size out of bounds", log.Ctx{"low": lowBound, "high": highBound, "val": val})


 Context loggers

 Frequently, you want to add context to a logger so that you can track actions associated with it. An http
 request is a good example. You can easily create new loggers that have context that is automatically included
 with each log line:

     requestlogger := log.New("path", r.URL.Path)

     // later
     requestlogger.Debug("db txn commit", "duration", txnTimer.Finish())

 This will output a log line that includes the path context that is attached to the logger:

     lvl=dbug t=2014-05-02T16:07:23-0700 path=/repo/12/add_hook msg="db txn commit" duration=0.12


 Handlers

 The Handler interface defines where log lines are printed to and how they are formated. Handler is a
 single interface that is inspired by net/http's handler interface:

     type Handler interface {
         Log(r *Record) error
     }


 Handlers can filter records, format them, or dispatch to multiple other Handlers.
 This package implements a number of Handlers for common logging patterns that are
 easily composed to create flexible, custom logging structures.

 Here's an example handler that prints logfmt output to Stdout:

     handler := log.StreamHandler(os.Stdout, log.LogfmtFormat())

 Here's an example handler that defers to two other handlers. One handler only prints records
 from the rpc package in logfmt to standard out. The other prints records at Error level
 or above in JSON formatted output to the file /var/log/service.json

     handler := log.MultiHandler(
         log.LvlFilterHandler(log.LvlError, log.Must.FileHandler("/var/log/service.json", log.JsonFormat())),
         log.MatchFilterHandler("pkg", "app/rpc" log.StdoutHandler())
     )

 Logging File Names and Line Numbers

 This package implements three Handlers that add debugging information to the
 context, CallerFileHandler, CallerFuncHandler and CallerStackHandler. Here's
 an example that adds the source file and line number of each logging call to
 the context.

     h := log.CallerFileHandler(log.StdoutHandler)
     log.Root().SetHandler(h)
     ...
     log.Error("open file", "err", err)

 This will output a line that looks like:

     lvl=eror t=2014-05-02T16:07:23-0700 msg="open file" err="file not found" caller=data.go:42

 Here's an example that logs the call stack rather than just the call site.

     h := log.CallerStackHandler("%+v", log.StdoutHandler)
     log.Root().SetHandler(h)
     ...
     log.Error("open file", "err", err)

 This will output a line that looks like:

     lvl=eror t=2014-05-02T16:07:23-0700 msg="open file" err="file not found" stack="[pkg/data.go:42 pkg/cmd/main.go]"

 The "%+v" format instructs the handler to include the path of the source file
 relative to the compile time GOPATH. The github.com/go-stack/stack package
 documents the full list of formatting verbs and modifiers available.

 Custom Handlers

 The Handler interface is so simple that it's also trivial to write your own. Let's create an
 example handler which tries to write to one handler, but if that fails it falls back to
 writing to another handler and includes the error that it encountered when trying to write
 to the primary. This might be useful when trying to log over a network socket, but if that
 fails you want to log those records to a file on disk.

     type BackupHandler struct {
         Primary Handler
         Secondary Handler
     }

     func (h *BackupHandler) Log (r *Record) error {
         err := h.Primary.Log(r)
         if err != nil {
             r.Ctx = append(ctx, "primary_err", err)
             return h.Secondary.Log(r)
         }
         return nil
     }

 This pattern is so useful that a generic version that handles an arbitrary number of Handlers
 is included as part of this library called FailoverHandler.

 Logging Expensive Operations

 Sometimes, you want to log values that are extremely expensive to compute, but you don't want to pay
 the price of computing them if you haven't turned up your logging level to a high level of detail.

 This package provides a simple type to annotate a logging operation that you want to be evaluated
 lazily, just when it is about to be logged, so that it would not be evaluated if an upstream Handler
 filters it out. Just wrap any function which takes no arguments with the log.Lazy type. For example:

     func factorRSAKey() (factors []int) {
         // return the factors of a very large number
     }

     log.Debug("factors", log.Lazy{factorRSAKey})

 If this message is not logged for any reason (like logging at the Error level), then
 factorRSAKey is never evaluated.

 Dynamic context values

 The same log.Lazy mechanism can be used to attach context to a logger which you want to be
 evaluated when the message is logged, but not when the logger is created. For example, let's imagine
 a game where you have Player objects:

     type Player struct {
         name string
         alive bool
         log.Logger
     }

 You always want to log a player's name and whether they're alive or dead, so when you create the player
 object, you might do:

     p := &Player{name: name, alive: true}
     p.Logger = log.New("name", p.name, "alive", p.alive)

 Only now, even after a player has died, the logger will still report they are alive because the logging
 context is evaluated when the logger was created. By using the Lazy wrapper, we can defer the evaluation
 of whether the player is alive or not to each log message, so that the log records will reflect the player's
 current state no matter when the log message is written:

     p := &Player{name: name, alive: true}
     isAlive := func() bool { return p.alive }
     player.Logger = log.New("name", p.name, "alive", log.Lazy{isAlive})

 Terminal Format

 If log15 detects that stdout is a terminal, it will configure the default
 handler for it (which is log.StdoutHandler) to use TerminalFormat. This format
 logs records nicely for your terminal, including color-coded output based
 on log level.

 Error Handling

 Becasuse log15 allows you to step around the type system, there are a few ways you can specify
 invalid arguments to the logging functions. You could, for example, wrap something that is not
 a zero-argument function with log.Lazy or pass a context key that is not a string. Since logging libraries
 are typically the mechanism by which errors are reported, it would be onerous for the logging functions
 to return errors. Instead, log15 handles errors by making these guarantees to you:

 - Any log record containing an error will still be printed with the error explained to you as part of the log record.

 - Any log record containing an error will include the context key LOG15_ERROR, enabling you to easily
 (and if you like, automatically) detect if any of your logging calls are passing bad values.

 Understanding this, you might wonder why the Handler interface can return an error value in its Log method. Handlers
 are encouraged to return errors only if they fail to write their log records out to an external source like if the
 syslog daemon is not responding. This allows the construction of useful handlers which cope with those failures
 like the FailoverHandler.

 Library Use

 log15 is intended to be useful for library authors as a way to provide configurable logging to
 users of their library. Best practice for use in a library is to always disable all output for your logger
 by default and to provide a public Logger instance that consumers of your library can configure. Like so:

     package yourlib

     import "github.com/inconshreveable/log15"

     var Log = log.New()

     func init() {
         Log.SetHandler(log.DiscardHandler())
     }

 Users of your library may then enable it if they like:

     import "github.com/inconshreveable/log15"
     import "example.com/yourlib"

     func main() {
         handler := // custom handler setup
         yourlib.Log.SetHandler(handler)
     }

 Best practices attaching logger context

 The ability to attach context to a logger is a powerful one. Where should you do it and why?
 I favor embedding a Logger directly into any persistent object in my application and adding
 unique, tracing context keys to it. For instance, imagine I am writing a web browser:

     type Tab struct {
         url string
         render *RenderingContext
         // ...

         Logger
     }

     func NewTab(url string) *Tab {
         return &Tab {
             // ...
             url: url,

             Logger: log.New("url", url),
         }
     }

 When a new tab is created, I assign a logger to it with the url of
 the tab as context so it can easily be traced through the logs.
 Now, whenever we perform any operation with the tab, we'll log with its
 embedded logger and it will include the tab title automatically:

     tab.Debug("moved position", "idx", tab.idx)

 There's only one problem. What if the tab url changes? We could
 use log.Lazy to make sure the current url is always written, but that
 would mean that we couldn't trace a tab's full lifetime through our
 logs after the user navigate to a new URL.

 Instead, think about what values to attach to your loggers the
 same way you think about what to use as a key in a SQL database schema.
 If it's possible to use a natural key that is unique for the lifetime of the
 object, do so. But otherwise, log15's ext package has a handy RandId
 function to let you generate what you might call "surrogate keys"
 They're just random hex identifiers to use for tracing. Back to our
 Tab example, we would prefer to set up our Logger like so:

         import logext "github.com/inconshreveable/log15/ext"

         t := &Tab {
             // ...
             url: url,
         }

         t.Logger = log.New("id", logext.RandId(8), "url", log.Lazy{t.getUrl})
         return t

 Now we'll have a unique traceable identifier even across loading new urls, but
 we'll still be able to see the tab's current url in the log messages.

 Must

 For all Handler functions which can return an error, there is a version of that
 function which will return no error but panics on failure. They are all available
 on the Must object. For example:

     log.Must.FileHandler("/path", log.JsonFormat)
     log.Must.NetHandler("tcp", ":1234", log.JsonFormat)

 Inspiration and Credit

 All of the following excellent projects inspired the design of this library:

 code.google.com/p/log4go

 github.com/op/go-logging

 github.com/technoweenie/grohl

 github.com/Sirupsen/logrus

 github.com/kr/logfmt

 github.com/spacemonkeygo/spacelog

 golang's stdlib, notably io and net/http

 The Name

 https://xkcd.com/927/

 */
 package log15
	/*
	Package log15 provides an opinionated, simple toolkit for best-practice logging that is
	both human and machine readable. It is modeled after the standard library's io and net/http
	packages.

	This package enforces you to only log key/value pairs. Keys must be strings. Values may be
	any type that you like. The default output format is logfmt, but you may also choose to use
	JSON instead if that suits you. Here's how you log:

	log.Info("page accessed", "path", r.URL.Path, "user_id", user.id)

	This will output a line that looks like:

	lvl=info t=2014-05-02T16:07:23-0700 msg="page accessed" path=/org/71/profile user_id=9

	Getting Started

	To get started, you'll want to import the library:

	import log "github.com/inconshreveable/log15"


	Now you're ready to start logging:

	func main() {
	log.Info("Program starting", "args", os.Args())
	}


	Convention

	Because recording a human-meaningful message is common and good practice, the first argument to every
	logging method is the value to the implicit key 'msg'.

	Additionally, the level you choose for a message will be automatically added with the key 'lvl', and so
	will the current timestamp with key 't'.

	You may supply any additional context as a set of key/value pairs to the logging function. log15 allows
	you to favor terseness, ordering, and speed over safety. This is a reasonable tradeoff for
	logging functions. You don't need to explicitly state keys/values, log15 understands that they alternate
	in the variadic argument list:

	log.Warn("size out of bounds", "low", lowBound, "high", highBound, "val", val)

	If you really do favor your type-safety, you may choose to pass a log.Ctx instead:

	log.Warn("size out of bounds", log.Ctx{"low": lowBound, "high": highBound, "val": val})


	Context loggers

	Frequently, you want to add context to a logger so that you can track actions associated with it. An http
	request is a good example. You can easily create new loggers that have context that is automatically included
	with each log line:

	requestlogger := log.New("path", r.URL.Path)

	// later
	requestlogger.Debug("db txn commit", "duration", txnTimer.Finish())

	This will output a log line that includes the path context that is attached to the logger:

	lvl=dbug t=2014-05-02T16:07:23-0700 path=/repo/12/add_hook msg="db txn commit" duration=0.12


	Handlers

	The Handler interface defines where log lines are printed to and how they are formated. Handler is a
	single interface that is inspired by net/http's handler interface:

	type Handler interface {
	Log(r *Record) error
	}


	Handlers can filter records, format them, or dispatch to multiple other Handlers.
	This package implements a number of Handlers for common logging patterns that are
	easily composed to create flexible, custom logging structures.

	Here's an example handler that prints logfmt output to Stdout:

	handler := log.StreamHandler(os.Stdout, log.LogfmtFormat())

	Here's an example handler that defers to two other handlers. One handler only prints records
	from the rpc package in logfmt to standard out. The other prints records at Error level
	or above in JSON formatted output to the file /var/log/service.json

	handler := log.MultiHandler(
	log.LvlFilterHandler(log.LvlError, log.Must.FileHandler("/var/log/service.json", log.JsonFormat())),
	log.MatchFilterHandler("pkg", "app/rpc" log.StdoutHandler())
	)

	Logging File Names and Line Numbers

	This package implements three Handlers that add debugging information to the
	context, CallerFileHandler, CallerFuncHandler and CallerStackHandler. Here's
	an example that adds the source file and line number of each logging call to
	the context.

	h := log.CallerFileHandler(log.StdoutHandler)
	log.Root().SetHandler(h)
	...
	log.Error("open file", "err", err)

	This will output a line that looks like:

	lvl=eror t=2014-05-02T16:07:23-0700 msg="open file" err="file not found" caller=data.go:42

	Here's an example that logs the call stack rather than just the call site.

	h := log.CallerStackHandler("%+v", log.StdoutHandler)
	log.Root().SetHandler(h)
	...
	log.Error("open file", "err", err)

	This will output a line that looks like:

	lvl=eror t=2014-05-02T16:07:23-0700 msg="open file" err="file not found" stack="[pkg/data.go:42 pkg/cmd/main.go]"

	The "%+v" format instructs the handler to include the path of the source file
	relative to the compile time GOPATH. The github.com/go-stack/stack package
	documents the full list of formatting verbs and modifiers available.

	Custom Handlers

	The Handler interface is so simple that it's also trivial to write your own. Let's create an
	example handler which tries to write to one handler, but if that fails it falls back to
	writing to another handler and includes the error that it encountered when trying to write
	to the primary. This might be useful when trying to log over a network socket, but if that
	fails you want to log those records to a file on disk.

	type BackupHandler struct {
	Primary Handler
	Secondary Handler
	}

	func (h BackupHandler) Log (r Record) error {
	err := h.Primary.Log(r)
	if err != nil {
	r.Ctx = append(ctx, "primary_err", err)
	return h.Secondary.Log(r)
	}
	return nil
	}

	This pattern is so useful that a generic version that handles an arbitrary number of Handlers
	is included as part of this library called FailoverHandler.

	Logging Expensive Operations

	Sometimes, you want to log values that are extremely expensive to compute, but you don't want to pay
	the price of computing them if you haven't turned up your logging level to a high level of detail.

	This package provides a simple type to annotate a logging operation that you want to be evaluated
	lazily, just when it is about to be logged, so that it would not be evaluated if an upstream Handler
	filters it out. Just wrap any function which takes no arguments with the log.Lazy type. For example:

	func factorRSAKey() (factors []int) {
	// return the factors of a very large number
	}

	log.Debug("factors", log.Lazy{factorRSAKey})

	If this message is not logged for any reason (like logging at the Error level), then
	factorRSAKey is never evaluated.

	Dynamic context values

	The same log.Lazy mechanism can be used to attach context to a logger which you want to be
	evaluated when the message is logged, but not when the logger is created. For example, let's imagine
	a game where you have Player objects:

	type Player struct {
	name string
	alive bool
	log.Logger
	}

	You always want to log a player's name and whether they're alive or dead, so when you create the player
	object, you might do:

	p := &Player{name: name, alive: true}
	p.Logger = log.New("name", p.name, "alive", p.alive)

	Only now, even after a player has died, the logger will still report they are alive because the logging
	context is evaluated when the logger was created. By using the Lazy wrapper, we can defer the evaluation
	of whether the player is alive or not to each log message, so that the log records will reflect the player's
	current state no matter when the log message is written:

	p := &Player{name: name, alive: true}
	isAlive := func() bool { return p.alive }
	player.Logger = log.New("name", p.name, "alive", log.Lazy{isAlive})

	Terminal Format

	If log15 detects that stdout is a terminal, it will configure the default
	handler for it (which is log.StdoutHandler) to use TerminalFormat. This format
	logs records nicely for your terminal, including color-coded output based
	on log level.

	Error Handling

	Becasuse log15 allows you to step around the type system, there are a few ways you can specify
	invalid arguments to the logging functions. You could, for example, wrap something that is not
	a zero-argument function with log.Lazy or pass a context key that is not a string. Since logging libraries
	are typically the mechanism by which errors are reported, it would be onerous for the logging functions
	to return errors. Instead, log15 handles errors by making these guarantees to you:

	- Any log record containing an error will still be printed with the error explained to you as part of the log record.

	- Any log record containing an error will include the context key LOG15_ERROR, enabling you to easily
	(and if you like, automatically) detect if any of your logging calls are passing bad values.

	Understanding this, you might wonder why the Handler interface can return an error value in its Log method. Handlers
	are encouraged to return errors only if they fail to write their log records out to an external source like if the
	syslog daemon is not responding. This allows the construction of useful handlers which cope with those failures
	like the FailoverHandler.

	Library Use

	log15 is intended to be useful for library authors as a way to provide configurable logging to
	users of their library. Best practice for use in a library is to always disable all output for your logger
	by default and to provide a public Logger instance that consumers of your library can configure. Like so:

	package yourlib

	import "github.com/inconshreveable/log15"

	var Log = log.New()

	func init() {
	Log.SetHandler(log.DiscardHandler())
	}

	Users of your library may then enable it if they like:

	import "github.com/inconshreveable/log15"
	import "example.com/yourlib"

	func main() {
	handler := // custom handler setup
	yourlib.Log.SetHandler(handler)
	}

	Best practices attaching logger context

	The ability to attach context to a logger is a powerful one. Where should you do it and why?
	I favor embedding a Logger directly into any persistent object in my application and adding
	unique, tracing context keys to it. For instance, imagine I am writing a web browser:

	type Tab struct {
	url string
	render *RenderingContext
	// ...

	Logger
	}

	func NewTab(url string) *Tab {
	return &Tab {
	// ...
	url: url,

	Logger: log.New("url", url),
	}
	}

	When a new tab is created, I assign a logger to it with the url of
	the tab as context so it can easily be traced through the logs.
	Now, whenever we perform any operation with the tab, we'll log with its
	embedded logger and it will include the tab title automatically:

	tab.Debug("moved position", "idx", tab.idx)

	There's only one problem. What if the tab url changes? We could
	use log.Lazy to make sure the current url is always written, but that
	would mean that we couldn't trace a tab's full lifetime through our
	logs after the user navigate to a new URL.

	Instead, think about what values to attach to your loggers the
	same way you think about what to use as a key in a SQL database schema.
	If it's possible to use a natural key that is unique for the lifetime of the
	object, do so. But otherwise, log15's ext package has a handy RandId
	function to let you generate what you might call "surrogate keys"
	They're just random hex identifiers to use for tracing. Back to our
	Tab example, we would prefer to set up our Logger like so:

	import logext "github.com/inconshreveable/log15/ext"

	t := &Tab {
	// ...
	url: url,
	}

	t.Logger = log.New("id", logext.RandId(8), "url", log.Lazy{t.getUrl})
	return t

	Now we'll have a unique traceable identifier even across loading new urls, but
	we'll still be able to see the tab's current url in the log messages.

	Must

	For all Handler functions which can return an error, there is a version of that
	function which will return no error but panics on failure. They are all available
	on the Must object. For example:

	log.Must.FileHandler("/path", log.JsonFormat)
	log.Must.NetHandler("tcp", ":1234", log.JsonFormat)

	Inspiration and Credit

	All of the following excellent projects inspired the design of this library:

	code.google.com/p/log4go

	github.com/op/go-logging

	github.com/technoweenie/grohl

	github.com/Sirupsen/logrus

	github.com/kr/logfmt

	github.com/spacemonkeygo/spacelog

	golang's stdlib, notably io and net/http

	The Name

	https://xkcd.com/927/

	*/
	package log15