Turbine

Turbine is a dataflow processing library built on Clojure's core.async. Turbine is designed for workloads that require complex flows (meaning a branched DAG) and possibly multiple processors. As such it's not a distributed framework: it's a library built to run on a single machine and take advantage of all available cores.

This is not a production system, and isn't designed to compete with any existing frameworks. The closest project to it that I've seen are Matz's streem, which is a DSL for asynchronous stream processing, and dask, which is a dataflow framework for Python. Read the "Motivation" section for more details on what turbine does differently and why I think it's useful. I do need to mention a couple of things first:

1. This is a hobby project, and as such I do have a roadmap of things I'd like to add, but I don't really have anything that resembles a timetable. This is being built in my "spare time" which amounts to a few hours a week because toddlers.

2. This project is incomplete. There is critical functionality missing that I need to implement before release. However, what's here in the repository is functional.

Quick Start

It's probably a good idea to read the whole README, but this will get you started messing around if you're a hands-on learner.

In the project root, fire up a REPL and issue the following require:

user=> (require '[turbine.demos :refer :all])
nil

This loads five functions into the namespace that build sample topologies for interactive use, each of which demonstrates properties of a route in the library: scatter-demo, splatter-demo, select-demo, union-demo, and gather-demo.

All of the functions take zero arguments and returns a function that feeds the topology.

user=> (def scatter-in (scatter-demo))
#'user/scatter-in

So scatter-in is a function that can be called like so.

user=> (scatter-in "Hi there")
true
Hi there!
Hi there!!

All of the functions returned by the demos take a single string except the function returned by splatter-demo, which takes a vector of strings.

The topology specifiers can be seen by source-ing the demo functions.

Motivation

Suppose you have a CSV file that's too big for memory - like 20G or something like that - and you need to perform some transformations on it that will break it into a couple of files. What's the best tool for this work? Well, you can't load it into memory, which means that whatever intermediate stage you have between the initial file and the final files needs to be carefully considered. The first thing I personally reach for when faced with a data processing task is the command line - Unix / Linux command line programs are super fast because they're written in C, and they're built to be chained together with the pipe, which sends data through one line at a time, so memory isn't usually an issue (sort is a counter example). The issue with that is you can't branch a pipe. You'll be stuck scanning that big file twice to get what you want. Moreover, all of those tools are single core. Even if your task could be processed asynchronously, the command line won't be much help.

Turbine processes data one record at a time, but does so asynchronously, and is thus able to leverage all available processing cores to the extent that the processing task allows. Transformations are expressed as operations on collections - map, filter, etc., so there's no boilerplate looping required. It also grants full flexibility in building the processing flow - branches, conditional branches, and branch convergences are all available. It can take data from and write data to multiple sources. That's because at its core turbine is a stream processor.

Stream Processing Semantics

Stream processing frameworks / libraries express stream operations in one of two ways, which I call function-oriented and sequence-oriented.

Function-oriented semantics build a directed graph, with each node being a function and each edge being a stream connecting the nodes. Data flows though the edges into each node, which process the data and pass it down the graph. Examples of this approach are Storm, Kafka Streams (the Processor API), and Onyx.

Sequence-oriented semantics treat the stream as an infinite lazy collection, and use operations like map and filter to express transformations. Under the hood, these operations are composed when possible and converted to a directed graph, usually done with a "builder" or "context"-like object. Examples of this approach are Spark Streaming, Flink, and Kafka Streams (the high-level DSL).

Each approach has it's tradeoffs: function-oriented semantics allow fine-tuned flow control and provide a very natural way of expressing the computation, but doesn't compose operations for you when available and advanced flow controls introduce complexity (in the Rich Hickey sense). Collection-oriented semantics are much more concise and automajestically compose operations, but substantially limit flow control.

Turbine combines the expressive power of collection-oriented operations with the advanced flow control and natural representation of function-oriented semantics.

Core Concepts

There are two core concepts to turbine: channels and routes. Channels transport messages through the routes, transforming them along the way with transducers. Routes transfer messages between channels according to the route type without altering the messages. This is important; in many function-oriented systems (Onyx is an exception), the nodes of the graph are charged with transforming and routing the data, requiring the transformation nodes to be substantially more aware of the overall graph structure than they need to be. By separating the message transformations from the flow control and making routes first-class citizens, the resulting directed graph has routes as nodes, and channels as edges, with the data transformations pushed into the edges. I call this route-oriented semantics.

Channels

Channels are literally core.async channels. To specify a channel in the directed graph (henceforth referred to as a topology), use a vector of the following form:

[chan-alias transducer optional]

chan-alias is a topology-local alias for the channel. For almost all of the routes, the outbound channels are fully defined. The alias is used to select the inbound channel for routes further "down" the topology.

transducer is the transducer to attach to the channel. This is where the collection-oriented semantics enter; a transducer is the essence of a collection operation without the actual collection. This makes them exceptionally easy to test since there are no framework components to mock and no restrictions regarding the shape or type of the messages. Just use eduction on some example messages and you have all of your business logic directly at your disposal for testing, with no need for additional abstractions. The transducer is optional; if it's omitted, the "pass-through" transducer (map identity) is attached when the topology is created.

Since transducers are composable, each channel's transformations can be represented as a single transducer, greatly simplifying topology specification as well as testing.

optional is used for certain routes that select the output channel based on some criteria. Currently the only route that uses this is select. I'll defer discussing this value until the routes have been introduced.

Here are a couple of examples:

;; Appends an exclamation point to the value.
[:exc1 (map #(str % "!"))]

;; Filters two-vector values if the second is less than the first 
;; and selects the second value.
[:alert-val (comp (filter (fn [[x y]] (< y x)))
                  (map (fn [[x y]] y)))]

;; Flattens vector messages into a stream of single elements.
[:flattener cat]

Before moving on I'd like to point out a critical detail when dealing with stateful transducers. When defining a stateful transducer, it's best practice to create a function that returns the transducer with defn rather than def-ing it directly (just like most of the transducers in clojure.core). Doing so ensures that if the transducer-generator is used in multiple parts of the topology the state remains independent. The reason is that transducer states are typically (though not necessarily) volatile, which is not thread-safe like an atom.

Routes

Routes are the switchpoints that transfer messages between channels asynchronously. There are three fundamental routes (with no embedded logic), and a few more I consider to be "composite" routes. A composite route can be emulated with a fundamental route and certain transducers on the output channels. For reasons related to both performance and conceptual separation of concerns it can sometimes make more sense to embed the logic in the route.

This library has three fundamental routes and three composite routes already implemented.

There are also three special routes for inputs, sinks, and reductions. They're pretty easy.

Currently these are the only routes available, but I do plan on implementing a means of adding custom routes.

Scatter

The scatter route is a fundamental route that takes a single inbound message and clones it into one or more outbound channels. It's specified as follows:

[:scatter in-chan-alias [out-chan-specifier1 out-chan-specifier2 ...]]

Here in-chan-alias is the topology-local alias of the inbound channel, and out-chan-specifier 1 and 2 are full channel specifiers with transducers (defined in the previous section). Here's a concrete example:

[:scatter :in-chan1 [[:exc1 (map #(str % "!"))]
                     [:exc2 (map #(str % "!!"))]]]

This specifier scatters any values on :in-chan onto two outbound channels, one of which appends a single exclamation mark and the other of which appends two. Exciting.

And doubly exciting.

Union

The union route is another implemented fundamental route. It takes messages from multiple channels and merges them onto a single outbound channel. It's specified as follows:

[:union [in-alias1 in-alias2 ...] out-chan-specifier]

Here in-alias 1 and 2 are input channel aliases, and out-chan-specifier is a single full channel specifier. Here's an example:

[:union [:exc1 :exc2] [:really-exc (map #(str % "!!"))]]

The union reads from :exc1 and :exc2, "funneling" their messages into a single channel which appends two more exclamation points. So if :exc 1 and 2 come from the scatter example above, you'll see messages coming out the other end with three and four exclamation points.

Gather

The gather route reads from multiple input channels and concatenates their messages into a vector that gets passed to a single output channel. This route will block until all of the input channels produce values, which makes it a dangerous route to put into a topology; it can plug the whole thing up. For batch-type jobs this isn't a concern, but if there's a possibility of data loss for a streaming job it can cause trouble unless all of the input channels are sourced from the same input (imagine using scatter on three separate channels and unifying them later). Here's what it will look like syntactically:

[:gather [in-alias1 in-alias2 ...] out-chan-specifier]

Here in-alias 1 and 2 are the aliases for input channels, and out-chan-specifier is the specifier for the output channel.

Here's an example of what this looks like:

[:gather [:exc1 :exc2] [:cat-strings (map (fn [[l r]] (str l r)))]]

If exc 1 and 2 are the outputs of the scatter route above, this route will take messages with one and two exclamation points and concatenate the two strings into a single string. This exact scenario is an instance when the gather route would be safe; if you're scattering directly onto two channels then you're guaranteed to get them both into the gather route in the same order, though not necessarily at the same time (if one of the gather's input channels has a more computationally intensive transducer than the other). So there will be some blocking, but not infinite blocking.

Select

The select route is a composite route that receives messages from a single inbound channel and uses a selector function to determine which outbound channels receive it. It's somewhat similar to a multimethod dispatch, except there can be multiple outbound channels selected (and there's no hierarchy or any of that ... maybe it's not that similar). There really isn't a good theoretical reason I can think of to prohibit the number of matching outbound channels. Here's what a select route specifier looks like

[:select in-chan-alias 
         [out-chan-specifier-and-selector1 
          out-chan-specifier-and-selector2 ...] 
        selector-fn]

The selector values are attached to the outbound channel specifiers, so those have the form

[chan-alias xform selector-value]

NOTE: A transducer must be specified for channel specifiers on this route. (map identity) cannot be automatically injected here at the moment. This is subject to change.

The selector value is matched against the value returned by applying the dispatch function to the message. Here's an example:

[:select :ints [[:evens (map inc) 0]
                [:odds  (map inc) 1]] 
         (fn [x] (mod x 2))]

This takes an inbound integer message and routes it to the :evens channel if the number is even, and the :odds if the number is odd.

Note that this can be implemented with a scatter route by attaching filter transducers to each of the outbound channels, which makes it a composite route according to the vocabulary I made up.

NOTE In a future version the selector-value argument of the outbound channel specifier could be optional if by default the selector-fn values can be hashed to select the outbound channel.

Splatter

The splatter route is a composite route that receives vector messages and "splats" each element of the vector onto an output channel.

[:splatter in-chan-alias [out-chan-specifier1 out-chan-specifier2 ... ]]

Where the output channel specifiers are the standard ones seen in the fundamental routes. Here's an example specification:

[:splatter :vector-in [[:exc1 (map #(str % "!"))]
                       [:exc2 (map #(str % "!!"))]]]

This takes a vector of strings coming from vector-in, putting the first element onto exc1 and the second onto exc2.

["Hi" "there"]    ;; Input to the above splatter route. 
"Hi!" 
"there!!" ;; Output to the above splatter route.

This route is a composite route because it can be implemented by using scatter and map transducers that select each element of the vector. If there are more elements in the input vector than there are output channels then the vector is truncated. If there are more output channels than elements in the input vector then only channels corresponding to those elements are written to.

Spread

The spread route is a special case of select that takes the value on the inbound channel and places it onto one of the outbound channels. It selects the outbound channel based on a round robin scheduler. This route can be used to distribute computational workload amongst independent threads of execution.

[:spread in-chan-alias [out-chan-specifier1 out-chan-specifier2 ...]]

The outbound channel specifiers are normal specifiers.

[:spread :in1 [[:out-chan-1 (map some-slow-function)]
               [:out-chan-2 (map some-slow-function)]]]

This takes values from :in1 and alternates between :out-chan-1 and :out-chan-2, which is good because I get the impression that the outbound transducers have a pretty slow function attached to them.

In

The in specifier defines an input, creating an alias and defining any transducers on the channel.

[:in in-chan-alias in-xform]

As an example, the following input increments any values passed into the topology for this channel.

[:in :integers-in (map inc)]

I'll discuss this a little later, but the number of in routes determines the number of input functions returned when the topology is built.

Collect

The collect specifier is built specifically for batch processing. It acts as a reducer, holding the accumulator until the topology is closed before sending it downstream.

[:collect in-chan-alias out-chan-specifier reducer-fn initial-accumulator]

Here there are two additional elements beyond the input alias and the output specifier: the reducer function and initial accumulator. The reducer function is literally a reducer: it takes two arguments, and accumulator and a new value. Examples of reducers:

(fn [a v] (+ a v)) ;; Sum.
(fn [a v] (assoc v (inc (a v 0)))) ;; Count by key.
(fn [a v] (max a v)) ;; Max value.
(fn [a v] (min a v)) ;; Min value.

The initial accumulator is ... the initial value of the accumulator.

Here's a concrete example:

[:collect :integers-in [:max-integer-out] ; <- (map identity is implicit now).
          (fn [a v] (max a v)) 0]

This route reads the integers from the :integers-in channel and accumulates the maximum value. The important thing to understand about this route is that it holds onto the accumulator until the topology is closed. Once the topology is closed with close-topology, the value of the accumulator (a in the function above) is passed to the :max-integer-out channel to the rest of the topology.

Sink

The sink specifier defines an "output" function whose return value isn't used (meaning it's used purely for side effects). I'll discuss the importance of sinks in the next section.

[:sink in-chan-alias sink-fn]

Here's an example of a very simple sink.

[:sink :exc1 println]

This takes all values put onto the exc1 channel and "sinks" them to stdout.

The topology-wide rule regarding sinks is that any channels in the topology that aren't being ingested into a route must go into a sink. If this isn't done, the channel's buffers will fill up and the topology will freeze when the internal core.async puts can't complete.

On a final note, it's worth mentioning that the scatter and union routes already have primitives in core.async as tap/mult and alt/alts, this library just wraps them into a data structure.

Topologies

There are differences between turbine's treatment of the topology graphs and other stream processing frameworks. They all stem from this:

A topology is a collection of functions that send data through the DAG and return no value.

Most stream processing frameworks (plus Kafka streams) treat the topology as this other entity that gets built through some context or builder, and then submitted to a cluster manager, or started by the context. This hard-wires the sources into the topology graphs, making them closed systems. Moreover, they're single-purpose systems because that context/builder is also mutable (Onyx and Storm's Clojure DSL are the exception here, they define the topology as a data structure - turbine does as well. I sense a common thread ....). Mutable operations don't compose as well as immutable ones.

Turbine doesn't bother wiring in the sources at all. For stream sources we can use stdin, a socket, or a Kafka topic; for batch sources we can use a file. Ther input sources shouldn't be complected with the processing itself (naturally this is the rationale behind the existence of transducers - reducing functions don't actually need to know they're attached to a collection). Instead, turbine defines the topology as the functions that feed it. These functions each take a single value and return nothing, which makes them the same kind of function sink expects. This makes turbine topologies composable, just like transducers. Define the topology in pieces and use the entry point functions as sink operators when you want to stick them together. Another advantage is that turbine doesn't require special "connectors" to plug a source into the topology - just use the entry points like any other function.

To make a topology, use the make-topology function

(def entry-points (make-topology topology-specifier))

entry-points is a vector of functions that put values onto the channels specified by the in specifiers (in the same order they were specified). Assuming entry-points has only one element, the topology is executed as follows:

((first entry-points) new-message)

This leaves it to the user to wire the topology to the source. For example, this function could be used as a callback, be placed in a go-loop, or dropped into another topology.

I do have plans for making make-topology return the function directly when there's only one entry point into the topology for convenience.

In addition to creating topologies, turbine also has a function for closing them. This will close all of the async channels and flush routes that maintain state (when they're implemented). The function is called - and this will shock you - close-topology. Pass it all of the input functions to the topology you want to close and it does the rest. To close the above topology, simply call

(close-topology entry-points)

Under the hood close-topology passes a sentinel value to the input functions, directing them to close their downstream async channels. The routes have logic to listen to when the input channels close, and they in turn close their output channels. This ensures all of the channels flush their in-flight values before they close the downstream processors because the nil that a closed channel returns only gets pulled after the queue is empty.

Helpers

One common pattern I use (see this piece of code) is to :spread some expensive computation across multiple channels (which run in separate threads), then :union them together. If I want to :spread onto a variable number of cores, I'd need to use something like a for comprehension to make that happen. To make this more convenient, I created a macro/function pair that does just that: clone-channel creates a vector of distinct channel specifiers and suppresses evaluation of the transducer function until after the cloning is done, and clone-kw clones a keyword into a vector of keywords. The keywords produced by clone-kw are created the same way as the aliases in clone-channel, so the function and macro are meant to complement one another. Use them like this:

(require '[turbine.core :refer [make-topology clone-channel clone-kw]])

(make-topology
  [[:in :in1]
   [:spread :in1 (clone-channel 5 :compute (map inc))]
   [:union (clone-kw 5 :compute) [:out]]
   [:sink :out println]])

;; Equivalent topology.
(make-topology
  [[:in :in1]
   [:spread :in1 [[:compute0 (map inc)]
                  [:compute1 (map inc)]
                  [:compute2 (map inc)]
                  [:compute3 (map inc)]
                  [:compute4 (map inc)]]]
   [:union [:compute0
            :compute1
            :compute2
            :compute3
            :compute4]
            [:out]]
   [:sink :out println]])

Examples

Here are some topology examples for each of the routes. Each of these is implemented in the turbine.demos namespace.

The examples assume the following namespace declaration:

(ns my-ns
    (:require [turbine.routes :refer [make-topology]]))

Scatter

This topology takes a single value, scatters it onto two channels, one appending a single exclamation point, the other appending two.

(make-topology
  [[:in :in1]
   ;; Scatter clones the messages onto the output channels.
   [:scatter :in1 [[:exc1 (map #(str % "!"))]
                   [:exc2 (map #(str % "!!"))]]]
   [:sink :exc1 println]
   [:sink :exc2 println]]))

Splatter

This topology takes a vector input and uses splatter to append a single exclamation point to the first element and two exclamation points to the second.

(make-topology
  [[:in :in1]
   ;; Splatter takes a vector and "splats" it onto the output channels.
   [:splatter :in1 [[:exc1 (map #(str % "!"))]
                    [:exc2 (map #(str % "!!"))]]]
   [:sink :exc1 println]
   [:sink :exc2 println]])

Select

This topology takes a single value and uses select to append a single exclamation point to lower case words and two exclamation points to upper case words. As previously mentioned, this can be done with scatter and filter.

(make-topology
  [[:in :in1]
   ;; Outbound aliases in a select have an additional element, which is
   ;; matched against the value of the selector function applied to the 
   ;; inbound message.
   [:select :in1 [[:exc1 (map #(str % "!")) true]
                  [:exc2 (map #(str % "!!")) false]]
            ;; This selector function is boolean, but it doesn't have to be.
            (fn [x] (Character/isLowerCase (first x)))]
   [:sink :exc1 println]
   [:sink :exc2 println]])

Spread

This topology takes a single value and alternates between appending one and two exclamation points.

(make-topology
  [[:in :in1]
   [:spread :in1 [[:exc1 (map #(str % "!"))]
                  [:exc2 (map #(str % "!!"))]]]
   [:sink :exc1 println]
   [:sink :exc2 println]])

Union

This topology takes a single value and copies it, one with a single exclamation point and another with two. These are "flattened" onto the stream by the union route, so one input will result in two sinks.

This topology can also be built with a composition of map and cat using no routes whatsoever.

(make-topology
  [[:in :in1]
   [:scatter :in1 [[:exc1 (map #(str % "!"))]
                   [:exc2 (map #(str % "!!"))]]]
   [:union [:exc1 :exc2] [:ident]]
   [:sink :ident println]])

Collect

This topology reads integers, storing the maximum value. When the topology is closed, the maximum value is printed.

;; Doesn't do anything until close-topology is called.
(make-topology
  [[:in :in1]
   [:collect :in1 [:out]
             (fn [a v] (max a v)) 0]
   [:sink :out println]])

Contents

The package currently contains three namespaces: turbine.core, turbine.routes, turbine.demos. turbine.core contains the topology building machinery. turbine.routes is the meat of the library, containing all of the logic for establishing the routes. turbine.demos contains all of the topologies in the "Examples" section with functions to return the entry points. It's designed for interactive use in the REPL.

user=> (require '[turbine.demos :refer :all])
nil
user=> (require '[turbine.core :refer :all])
nil

user=> (def scatter-in (scatter-demo))
#'user/scatter-in

user=> (scatter-in "hello")
true
hello!
hello!!

user=> (def collect-in (collect-demo))
#'user/collect-in

user=> (collect-in 1)
true
user=> (collect-in 2)
true
user=> (collect-in -1)
true
user=> (close-topology [collect-in])
nil
2

Future Work

There are a number of things to do before an "official" release.

• Create a defroute macro or function for custom routing.
• Make transducers optional in the topology specification.
• Enable batch computation by writing a close-topology! function.
• Create join routes.
• Create a :collect route for batch aggregation.
• Create a streaming aggregation transducer?
• Create a command line tool that reads a turbine “script” and executes it against a file?