Next generation concurrency primitives for Clojure built on top of Project Loom
Project Loom is bringing first-class fibers to the JVM! Tapestry seeks to bring ergonomic clojure APIs for working with Loom.
Fibers behave similarly to OS level threads, but are much lighter weight to spawn, allowing potentially millions of them to exist.
Clojure already has the wonderful core.async and manifold libraries but writing maximally performant code in either requires the abstraction (channels, or promises) to leak all over your code (as you return channels or promise chains) to avoid blocking. Furthermore you frequently have to think about which executor will handle the blocking code.
Loom moves handling parking to the JVM runtime level making it possible for "blocking" code to be executed in a highly parallel fashion without the developer having to explicitly opt into the behavior. This is similar to how Golang and Haskell achieve their highly performant parallelism.
Some great further reading on the topic:
manifold
and core.async
the JVM executor is mostly analogous to the rust's concept of the Executor. In a language like
Rust, without a runtime, being explicit and "colorizing functions" makes sense, but with a
run-time we can do better.Tapestry is still pre-1.0. As the APIs in loom have stabilized so too has tapestry.
Tapestry is being used in production for several of Teknql's projects and has
more or less replaced both clojure.core/future
and manifold.deferred/future
.
It is the ambition of the project to eventually drop manifold entirely, at which point it will likely hit 1.0.
Add to your deps.edn:
teknql/tapestry {:mvn/version "0.4.2"}
Here is a demo of some of the basics.
(require '[tapestry.core :refer [fiber fiber-loop]])
;; Spawning a Fiber behaves very similarly to `future` in standard clojure, but
;; runs in a Loom Fiber and returns a tapestry.core.Fiber which implements IDeref.
@(fiber (+ 1 2 3 4))
;; => 10
;; Or, Like `core.async`'s `go-loop'
@(fiber-loop [i 0]
(if (= i 5)
(* 2 i)
(do (Thread/sleep 100)
(recur (inc i)))))
;; => 10, after aprox 500ms of sleeping
(require '[tapestry.core :refer [fiber interrupt! alive?]]')
(let [f (fiber (Thread/sleep 10000))]
(alive? f) ;; true
(interrupt! f)
(alive? f) ;; false
@f ;; Raises java.lang.InterruptedException))
Tapestry supports setting timeouts on fibers which will cause them to be
interrupted (with a java.lang.InterruptedException
) when the timeout is hit.
(require '[tapestry.core :refer [fiber timeout! alive?]]')
(let [f (fiber (Thread/sleep 10000))]
(timeout! f 100)
(alive? f) ;; true
(Thread/sleep 200)
(alive? f) ;; false
@f ;; Raises java.util.concurrent.TimeoutException))
You can also specify a default value
(require '[tapestry.core :refer [fiber timeout! alive?]]')
(let [f (fiber (Thread/sleep 10000))]
(timeout! f 100 :default)
@f ;; => :default))
You can use dynamic bindings to set a timeout on a bunch of fibers. Note that each fiber will have a timeout that starts from when the fiber was spawned.
(require '[tapestry.core :refer [fiber alive? with-timeout]]')
(with-timeout 100 ;; Accepts a duration or number of millis
(let [f (fiber (Thread/sleep 10000))]
@f ;; raises java.util.concurrent.TimeoutException
))
(require '[tapestry.core :refer [parallelly asyncly pfor]]
'[clj-http.client :as clj-http])
(def urls
["https://google.com"
"https://bing.com"
"https://yahoo.com"])
;; We can also run a function over a sequence, spawning a fiber for each item.
(->> urls
(parallelly clj-http/get))
;; We can using the built in `pfor` macro to evaluate a `for` expression in parallel. Note that unlike
;; clojure.core/for, this is not lazy.
(pfor [url urls]
(clj-http/get url))
;; Similalry, if we don't care about the order of items being maintained, and instead just want
;; to return results as quickly as possible
(doseq [resp (asyncly clj-http/get urls)]
(println "Got Response!" (:status resp)))
;; We can control max parallelism for fibers
(require '[tapestry.core :refer [parallelly fiber]])
;; Note that you can also use `with-max-parallelism` within a fiber body
;; which will limit parallelism of all newly spawned fibers. Consider the following
;; in which we process up to 3 orders simultaneously, and each order can process up to 2
;; tasks in parallel.
(defn process-order!
[order]
(with-max-parallelism 2
(let [internal-notification-success? (fiber (send-internal-notification! order))
shipping-success? (fiber (ship-order! order))
receipt-success? (fiber (send-receipt! order))]
{:is-notified @internal-notification-success?
:is-shipped @shipping-success?
:has-receipt @receipt-success?})))
(with-max-parallelism 3
(let [order-a-summary (process-order! order-a)
order-b-summary (process-order! order-b)
order-c-summary (process-order! order-c)
order-d-summary (process-order! order-d)]
{:a @order-a-summary
:b @order-b-summary
:c @order-c-summary
:d @order-d-summary})
;; You can also bound the parallelism of sequence processing functions by specifying
;; an optional bound:
(asyncly 3 clj-http/get urls)
(parallelly 3 clj-http/get urls)
(require '[manifold.stream :as s]
'[tick.alpha.api :as t]
'[tapestry.core :refer [periodically parallelly asyncly]])
;; tapestry.core/periodically behaves very similar to manfold's built in periodically,
;; but runs each task in a fiber. You can terminate it by closing the stream.
(let [count (atom 0)
generator (periodically (t/new-duration 1 :seconds) #(swap! count inc))]
(->> generator
(s/consume #(println "Count is now:" %)))
(Thread/sleep 5000)
(s/close! generator))
;; Also, `parallelly` and `asyncly` both suppport manifold streams, allowing you to describe parallel
;; execution pipelines
(->> (s/stream)
(paralelly 5 some-operation)
(asyncly 5 some-other-operation)
(s/consume #(println "Got Result" %)))
(let [counter (agent 0)]
(tapestry.core/send counter inc)
(await counter)
@a)
;; => 1
None at the moment
Add the following to your .clj-kondo/config.edn
{:lint-as {tapestry.core/fiber-loop clojure.core/loop
tapestry.core/pfor clojure.core/for}}
(parallelize ...)
macro to automatically re-write call graphsCan you improve this documentation? These fine people already did:
Ryan Schmukler, Gtoast & Odd Andreas SørsætherEdit on GitHub
cljdoc is a website building & hosting documentation for Clojure/Script libraries
× close