_content/talks/2013/advconc.slide - website - Git at Google

 Advanced Go Concurrency Patterns

 Sameer Ajmani
 Google
 http://profiles.google.com/ajmani
 @Sajma
 http://golang.org

 * Video

 This talk was presented at Google I/O in May 2013.

 .link https://www.youtube.com/watch?v=QDDwwePbDtw Watch the talk on YouTube

 * Get ready

 .image advconc/gopherswim.jpg 400 400

 * Go supports concurrency

 In the language and runtime, not a library.

 This changes how you structure your programs.

 * Goroutines and Channels

 Goroutines are independently executing functions in the same address space.

    go f()
    go g(1, 2)

 Channels are typed values that allow goroutines to synchronize and exchange information.

   c := make(chan int)
   go func() { c <- 3 }()
   n := <-c

 For more on the basics, watch [[http://go.dev/talks/2012/concurrency.slide#1][Go Concurrency Patterns (Pike, 2012)]].

 * Example: ping-pong

 .play advconc/pingpong/pingpong.go /STARTMAIN1/,/STOPMAIN1/

 * Deadlock detection

 .play advconc/pingpongdeadlock/pingpongdeadlock.go /STARTMAIN1/,/STOPMAIN1/

 * Panic dumps the stacks

 .play advconc/pingpongpanic/pingpongpanic.go /STARTMAIN1/,/STOPMAIN1/

 * It's easy to go, but how to stop?

 Long-lived programs need to clean up.

 Let's look at how to write programs that handle communication, periodic events, and cancellation.

 The core is Go's `select` statement: like a `switch`, but the decision is made based on the ability to communicate.

   select {
   case xc <- x:
       // sent x on xc
   case y := <-yc:
       // received y from yc
   }

 * Example: feed reader

 My favorite feed reader disappeared.  I need a new one.

 Why not write one?

 Where do we start?

 * Find an RSS client

 Searching [[http://godoc.org][godoc.org]] for *"rss"* turns up several hits, including one that provides:

   // Fetch fetches Items for uri and returns the time when the next
   // fetch should be attempted.  On failure, Fetch returns an error.
   func Fetch(uri string) (items []Item, next time.Time, err error)

   type Item struct{
       Title, Channel, GUID string // a subset of RSS fields
   }

 But I want a stream:

   <-chan Item

 And I want multiple subscriptions.

 * Here's what we have

   type Fetcher interface {
       Fetch() (items []Item, next time.Time, err error)
   }

   func Fetch(domain string) Fetcher {...} // fetches Items from domain

 * Here's what we want

   type Subscription interface {
       Updates() <-chan Item // stream of Items
       Close() error         // shuts down the stream
   }

   func Subscribe(fetcher Fetcher) Subscription {...} // converts Fetches to a stream

   func Merge(subs ...Subscription) Subscription {...} // merges several streams

 * Example

 .play advconc/fakemain/fakemain.go /func main/,/^}/

 * Subscribe

 `Subscribe` creates a new `Subscription` that repeatedly fetches items until `Close` is called.

   func Subscribe(fetcher Fetcher) Subscription {
       s := &sub{
           fetcher: fetcher,
           updates: make(chan Item), // for Updates
       }
       go s.loop()
       return s
   }

   // sub implements the Subscription interface.
   type sub struct {
       fetcher Fetcher   // fetches items
       updates chan Item // delivers items to the user
   }

   // loop fetches items using s.fetcher and sends them
   // on s.updates.  loop exits when s.Close is called.
   func (s *sub) loop() {...}

 * Implementing Subscription

 To implement the `Subscription` interface, define `Updates` and `Close`.

 .code advconc/fakemain/fakemain.go /func.* Updates/,/^}/

   func (s *sub) Close() error {
       // TODO: make loop exit
       // TODO: find out about any error
       return err
   }

 * What does loop do?

 - periodically call `Fetch`
 - send fetched items on the `Updates` channel
 - exit when `Close` is called, reporting any error

 * Naive Implementation

 # Not quite enough room for this; retry after format change:
 # .play advconc/naivemain/naivemain.go /naiveSub\) loop/,/^}/
 # also on subsequent slides.

 .play advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE /
 .code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/

 * Bug 1: unsynchronized access to s.closed/s.err

 .code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsync
 .code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/ HLsync

 * Race Detector

   go run -race naivemain.go

 # original is 400x1500
 .image advconc/race.png 150 562
 .play advconc/naivemain/naivemain.go /STARTNAIVE /,/s.err/ HLsync
 .code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/ HLsync

 * Bug 2: time.Sleep may keep loop running

 .code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsleep

 * Bug 3: loop may block forever on s.updates

 .code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsend

 * Solution

 Change the body of `loop` to a `select` with three cases:

 - `Close` was called
 - it's time to call `Fetch`
 - send an item on `s.updates`

 * Structure: for-select loop

 `loop` runs in its own goroutine.

 `select` lets `loop` avoid blocking indefinitely in any one state.

   func (s *sub) loop() {
       ... declare mutable state ...
       for {
           ... set up channels for cases ...
           select {
           case <-c1:
               ... read/write state ...
           case c2 <- x:
               ... read/write state ...
           case y := <-c3:
               ... read/write state ...
           }
       }
   }

 The cases interact via local state in `loop`.

 * Case 1: Close

 `Close` communicates with `loop` via `s.closing`.

   type sub struct {
       closing chan chan error
   }

 The service (`loop`) listens for requests on its channel (`s.closing`).

 The client (`Close`) sends a request on `s.closing`: _exit_and_reply_with_the_error_

 In this case, the only thing in the request is the _reply_channel_.

 * Case 1: Close

 `Close` asks loop to exit and waits for a response.

 .code advconc/fakemain/fakemain.go /\*sub\) Close/,/^}/ HLchan

 `loop` handles `Close` by replying with the `Fetch` error and exiting.

 .code advconc/fakemain/fakemain.go /STARTCLOSEONLY /,/STOPCLOSEONLY / HLchan

 * Case 2: Fetch

 Schedule the next `Fetch` after some delay.

 .code advconc/fakemain/fakemain.go /STARTFETCHONLY /,/STOPFETCHONLY /

 * Case 3: Send

 Send the fetched items, one at a time.

 	var pending []Item // appended by fetch; consumed by send
 	for {
 		select {
 		case s.updates <- pending[0]:
 			pending = pending[1:]
 		}
 	}

 Whoops. This crashes.

 .image advconc/gopherswrench.jpg 200 337

 * Select and nil channels

 Sends and receives on nil channels block.

 Select never selects a blocking case.

 .play advconc/nilselect/nilselect.go /func main/,/^}/

 * Case 3: Send (fixed)

 Enable send only when pending is non-empty.

 .code advconc/fakemain/fakemain.go /STARTSENDONLY /,/STOPSENDONLY / HLupdates

 * Select

 Put the three cases together:

 .code advconc/fakemain/fakemain.go /STARTSELECT /,/STOPSELECT /

 The cases interact via `err`, `next`, and `pending`.

 No locks, no condition variables, no callbacks.

 * Bugs fixed

 - Bug 1: unsynchronized access to `s.closed` and `s.err`
 - Bug 2: `time.Sleep` may keep loop running
 - Bug 3: `loop` may block forever sending on `s.updates`

 .code advconc/fakemain/fakemain.go /STARTSELECT /,/STOPSELECT / HLcases

 * We can improve loop further

 * Issue: Fetch may return duplicates

 .code advconc/fakemain/fakemain.go /STARTFETCHVARS /,/STOPFETCHVARS / HLfetch
 .code advconc/fakemain/fakemain.go /STARTFETCHCASE /,/STOPFETCHCASE / HLfetch

 * Fix: Filter items before adding to pending

 .code advconc/fakemain/fakemain.go /STARTSEEN /,/STOPSEEN / HLseen
 .code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLdupe

 * Issue: Pending queue grows without bound

 .code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLdupe

 * Fix: Disable fetch case when too much pending

   const maxPending = 10

 .code advconc/fakemain/fakemain.go /STARTCAP /,/STOPCAP / HLcap

 Could instead drop older items from the head of `pending`.

 * Issue: Loop blocks on Fetch

 .code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLfetch

 * Fix: Run Fetch asynchronously

 Add a new `select` case for `fetchDone`.

   type fetchResult struct{ fetched []Item; next time.Time; err error }

 .code advconc/fakemain/fakemain.go /STARTFETCHDONE /,/STOPFETCHDONE / HLfetch
 .code advconc/fakemain/fakemain.go /STARTFETCHIF /,/STOPFETCHIF / HLfetch
 .code advconc/fakemain/fakemain.go /STARTFETCHASYNC /,/STOPFETCHASYNC / HLfetch

 * Implemented Subscribe

 Responsive. Cleans up. Easy to read and change.

 Three techniques:

 - `for-select` loop
 - service channel, reply channels (`chan`chan`error`)
 - `nil` channels in `select` cases

 More details online, including `Merge`.

 .image advconc/gopherhat.jpg 200 158

 * Conclusion

 Concurrent programming can be tricky.

 Go makes it easier:

 - channels convey data, timer events, cancellation signals
 - goroutines serialize access to local mutable state
 - stack traces & deadlock detector
 - race detector

 .image advconc/race.png 200 750

 * Links

 Go Concurrency Patterns (2012)

 .link http://go.dev/talks/2012/concurrency.slide

 Concurrency is not parallelism

 .link http://golang.org/s/concurrency-is-not-parallelism

 Share memory by communicating

 .link http://golang.org/doc/codewalk/sharemem

 Go Tour (learn Go in your browser)

 .link http://tour.golang.org
	Advanced Go Concurrency Patterns

	Sameer Ajmani
	Google
	http://profiles.google.com/ajmani
	@Sajma
	http://golang.org

	* Video

	This talk was presented at Google I/O in May 2013.

	.link https://www.youtube.com/watch?v=QDDwwePbDtw Watch the talk on YouTube

	* Get ready

	.image advconc/gopherswim.jpg 400 400

	* Go supports concurrency

	In the language and runtime, not a library.

	This changes how you structure your programs.

	* Goroutines and Channels

	Goroutines are independently executing functions in the same address space.

	go f()
	go g(1, 2)

	Channels are typed values that allow goroutines to synchronize and exchange information.

	c := make(chan int)
	go func() { c <- 3 }()
	n := <-c

	For more on the basics, watch [[http://go.dev/talks/2012/concurrency.slide#1][Go Concurrency Patterns (Pike, 2012)]].

	* Example: ping-pong

	.play advconc/pingpong/pingpong.go /STARTMAIN1/,/STOPMAIN1/

	* Deadlock detection

	.play advconc/pingpongdeadlock/pingpongdeadlock.go /STARTMAIN1/,/STOPMAIN1/

	* Panic dumps the stacks

	.play advconc/pingpongpanic/pingpongpanic.go /STARTMAIN1/,/STOPMAIN1/

	* It's easy to go, but how to stop?

	Long-lived programs need to clean up.

	Let's look at how to write programs that handle communication, periodic events, and cancellation.

	The core is Go's `select` statement: like a `switch`, but the decision is made based on the ability to communicate.

	select {
	case xc <- x:
	// sent x on xc
	case y := <-yc:
	// received y from yc
	}

	* Example: feed reader

	My favorite feed reader disappeared. I need a new one.

	Why not write one?

	Where do we start?

	* Find an RSS client

	Searching [[http://godoc.org][godoc.org]] for "rss" turns up several hits, including one that provides:

	// Fetch fetches Items for uri and returns the time when the next
	// fetch should be attempted. On failure, Fetch returns an error.
	func Fetch(uri string) (items []Item, next time.Time, err error)

	type Item struct{
	Title, Channel, GUID string // a subset of RSS fields
	}

	But I want a stream:

	<-chan Item

	And I want multiple subscriptions.

	* Here's what we have

	type Fetcher interface {
	Fetch() (items []Item, next time.Time, err error)
	}

	func Fetch(domain string) Fetcher {...} // fetches Items from domain

	* Here's what we want

	type Subscription interface {
	Updates() <-chan Item // stream of Items
	Close() error // shuts down the stream
	}

	func Subscribe(fetcher Fetcher) Subscription {...} // converts Fetches to a stream

	func Merge(subs ...Subscription) Subscription {...} // merges several streams

	* Example

	.play advconc/fakemain/fakemain.go /func main/,/^}/

	* Subscribe

	`Subscribe` creates a new `Subscription` that repeatedly fetches items until `Close` is called.

	func Subscribe(fetcher Fetcher) Subscription {
	s := &sub{
	fetcher: fetcher,
	updates: make(chan Item), // for Updates
	}
	go s.loop()
	return s
	}

	// sub implements the Subscription interface.
	type sub struct {
	fetcher Fetcher // fetches items
	updates chan Item // delivers items to the user
	}

	// loop fetches items using s.fetcher and sends them
	// on s.updates. loop exits when s.Close is called.
	func (s *sub) loop() {...}

	* Implementing Subscription

	To implement the `Subscription` interface, define `Updates` and `Close`.

	.code advconc/fakemain/fakemain.go /func.* Updates/,/^}/

	func (s *sub) Close() error {
	// TODO: make loop exit
	// TODO: find out about any error
	return err
	}

	* What does loop do?

	- periodically call `Fetch`
	- send fetched items on the `Updates` channel
	- exit when `Close` is called, reporting any error

	* Naive Implementation

	# Not quite enough room for this; retry after format change:
	# .play advconc/naivemain/naivemain.go /naiveSub\) loop/,/^}/
	# also on subsequent slides.

	.play advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE /
	.code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/

	* Bug 1: unsynchronized access to s.closed/s.err

	.code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsync
	.code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/ HLsync

	* Race Detector

	go run -race naivemain.go

	# original is 400x1500
	.image advconc/race.png 150 562
	.play advconc/naivemain/naivemain.go /STARTNAIVE /,/s.err/ HLsync
	.code advconc/naivemain/naivemain.go /naiveSub\) Close/,/^}/ HLsync

	* Bug 2: time.Sleep may keep loop running

	.code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsleep

	* Bug 3: loop may block forever on s.updates

	.code advconc/naivemain/naivemain.go /STARTNAIVE /,/STOPNAIVE / HLsend

	* Solution

	Change the body of `loop` to a `select` with three cases:

	- `Close` was called
	- it's time to call `Fetch`
	- send an item on `s.updates`

	* Structure: for-select loop

	`loop` runs in its own goroutine.

	`select` lets `loop` avoid blocking indefinitely in any one state.

	func (s *sub) loop() {
	... declare mutable state ...
	for {
	... set up channels for cases ...
	select {
	case <-c1:
	... read/write state ...
	case c2 <- x:
	... read/write state ...
	case y := <-c3:
	... read/write state ...
	}
	}
	}

	The cases interact via local state in `loop`.

	* Case 1: Close

	`Close` communicates with `loop` via `s.closing`.

	type sub struct {
	closing chan chan error
	}

	The service (`loop`) listens for requests on its channel (`s.closing`).

	The client (`Close`) sends a request on `s.closing`: _exit_and_reply_with_the_error_

	In this case, the only thing in the request is the _reply_channel_.

	* Case 1: Close

	`Close` asks loop to exit and waits for a response.

	.code advconc/fakemain/fakemain.go /\*sub\) Close/,/^}/ HLchan

	`loop` handles `Close` by replying with the `Fetch` error and exiting.

	.code advconc/fakemain/fakemain.go /STARTCLOSEONLY /,/STOPCLOSEONLY / HLchan

	* Case 2: Fetch

	Schedule the next `Fetch` after some delay.

	.code advconc/fakemain/fakemain.go /STARTFETCHONLY /,/STOPFETCHONLY /

	* Case 3: Send

	Send the fetched items, one at a time.

	var pending []Item // appended by fetch; consumed by send
	for {
	select {
	case s.updates <- pending[0]:
	pending = pending[1:]
	}
	}

	Whoops. This crashes.

	.image advconc/gopherswrench.jpg 200 337

	* Select and nil channels

	Sends and receives on nil channels block.

	Select never selects a blocking case.

	.play advconc/nilselect/nilselect.go /func main/,/^}/

	* Case 3: Send (fixed)

	Enable send only when pending is non-empty.

	.code advconc/fakemain/fakemain.go /STARTSENDONLY /,/STOPSENDONLY / HLupdates

	* Select

	Put the three cases together:

	.code advconc/fakemain/fakemain.go /STARTSELECT /,/STOPSELECT /

	The cases interact via `err`, `next`, and `pending`.

	No locks, no condition variables, no callbacks.

	* Bugs fixed

	- Bug 1: unsynchronized access to `s.closed` and `s.err`
	- Bug 2: `time.Sleep` may keep loop running
	- Bug 3: `loop` may block forever sending on `s.updates`

	.code advconc/fakemain/fakemain.go /STARTSELECT /,/STOPSELECT / HLcases

	* We can improve loop further

	* Issue: Fetch may return duplicates

	.code advconc/fakemain/fakemain.go /STARTFETCHVARS /,/STOPFETCHVARS / HLfetch
	.code advconc/fakemain/fakemain.go /STARTFETCHCASE /,/STOPFETCHCASE / HLfetch

	* Fix: Filter items before adding to pending

	.code advconc/fakemain/fakemain.go /STARTSEEN /,/STOPSEEN / HLseen
	.code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLdupe

	* Issue: Pending queue grows without bound

	.code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLdupe

	* Fix: Disable fetch case when too much pending

	const maxPending = 10

	.code advconc/fakemain/fakemain.go /STARTCAP /,/STOPCAP / HLcap

	Could instead drop older items from the head of `pending`.

	* Issue: Loop blocks on Fetch

	.code advconc/fakemain/fakemain.go /STARTDEDUPE /,/STOPDEDUPE / HLfetch

	* Fix: Run Fetch asynchronously

	Add a new `select` case for `fetchDone`.

	type fetchResult struct{ fetched []Item; next time.Time; err error }

	.code advconc/fakemain/fakemain.go /STARTFETCHDONE /,/STOPFETCHDONE / HLfetch
	.code advconc/fakemain/fakemain.go /STARTFETCHIF /,/STOPFETCHIF / HLfetch
	.code advconc/fakemain/fakemain.go /STARTFETCHASYNC /,/STOPFETCHASYNC / HLfetch

	* Implemented Subscribe

	Responsive. Cleans up. Easy to read and change.

	Three techniques:

	- `for-select` loop
	- service channel, reply channels (`chan`chan`error`)
	- `nil` channels in `select` cases

	More details online, including `Merge`.

	.image advconc/gopherhat.jpg 200 158

	* Conclusion

	Concurrent programming can be tricky.

	Go makes it easier:

	- channels convey data, timer events, cancellation signals
	- goroutines serialize access to local mutable state
	- stack traces & deadlock detector
	- race detector

	.image advconc/race.png 200 750

	* Links

	Go Concurrency Patterns (2012)

	.link http://go.dev/talks/2012/concurrency.slide

	Concurrency is not parallelism

	.link http://golang.org/s/concurrency-is-not-parallelism

	Share memory by communicating

	.link http://golang.org/doc/codewalk/sharemem

	Go Tour (learn Go in your browser)

	.link http://tour.golang.org