Skip to content

saucam/util

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Twitter Util

Build status Codecov Project status Gitter Maven Central

A bunch of idiomatic, small, general purpose tools.

See the Scaladoc here.

Status

This project is used in production at Twitter (and many other organizations), and is being actively developed and maintained.

Releases

Releases are done on an approximately monthly schedule. While semver is not followed, the changelogs are detailed and include sections on public API breaks and changes in runtime behavior.

Contributing

The master branch of this repository contains the latest stable release of Util, and weekly snapshots are published to the develop branch. In general pull requests should be submitted against develop. See CONTRIBUTING.md for more details about how to contribute.

Using in your project

An example SBT dependency string for the util-collection tools would look like this:

val collUtils = "com.twitter" %% "util-collection" % "18.11.0"

Units

Time

import com.twitter.conversions.time._

val duration1 = 1.second
val duration2 = 2.minutes
duration1.inMillis // => 1000L

Space

import com.twitter.conversions.storage._
val amount = 8.megabytes
amount.inBytes // => 8388608L
amount.inKilobytes // => 8192L

Futures

A Non-actor re-implementation of Scala Futures.

import com.twitter.conversions.time._
import com.twitter.util.{Await, Future, Promise}

val f = new Promise[Int]
val g = f.map { result => result + 1 }
f.setValue(1)
Await.result(g, 1.second) // => this blocks for the futures result (and eventually returns 2)

// Another option:
g.onSuccess { result =>
  println(result) // => prints "2"
}

// Using for expressions:
val xFuture = Future(1)
val yFuture = Future(2)

for {
  x <- xFuture
  y <- yFuture
} {
  println(x + y) // => prints "3"
}

Collections

LruMap

The LruMap is an LRU with a maximum size passed in. If the map is full it expires items in FIFO order. Reading a value will move an item to the top of the stack.

import com.twitter.util.LruMap

val map = new LruMap[String, String](15) // this is of type mutable.Map[String, String]

Object Pool

The pool order is FIFO.

A pool of constants

import scala.collection.mutable
import com.twitter.util.{Await, SimplePool}

val queue = new mutable.Queue[Int] ++ List(1, 2, 3)
val pool = new SimplePool(queue)

// Note that the pool returns Futures, it doesn't block on exhaustion.
assert(Await.result(pool.reserve()) == 1)
pool.reserve().onSuccess { item =>
  println(item) // prints "2"
}

A pool of dynamically created objects

Here is a pool of even-number generators. It stores 4 numbers at a time:

import com.twitter.util.{Future, FactoryPool}

val pool = new FactoryPool[Int](4) {
  var count = 0
  def makeItem() = { count += 1; Future(count) }
  def isHealthy(i: Int) = i % 2 == 0
}

It checks the health when you successfully reserve an object (i.e., when the Future yields).

Hashing

util-hashing is a collection of hash functions and hashing distributors (eg. ketama).

To use one of the available hash functions:

import com.twitter.hashing.KeyHasher

KeyHasher.FNV1_32.hashKey("string".getBytes)

Available hash functions are:

FNV1_32
FNV1A_32
FNV1_64
FNV1A_64
KETAMA
CRC32_ITU
HSIEH

To use KetamaDistributor:

import com.twitter.hashing.{KetamaDistributor, KetamaNode, KeyHasher}

val nodes = List(KetamaNode("host:port", 1 /* weight */, "foo" /* handle */))
val distributor = new KetamaDistributor(nodes, 1 /* num reps */)
distributor.nodeForHash("abc".##) // => client

Logging

util-logging is a small wrapper around Java's built-in logging to make it more Scala-friendly.

Using

To access logging, you can usually just use:

import com.twitter.logging.Logger
private val log = Logger.get(getClass)

This creates a Logger object that uses the current class or object's package name as the logging node, so class "com.example.foo.Lamp" will log to node com.example.foo (generally showing "foo" as the name in the logfile). You can also get a logger explicitly by name:

private val log = Logger.get("com.example.foo")

Logger objects wrap everything useful from java.util.logging.Logger, as well as adding some convenience methods:

// log a string with sprintf conversion:
log.info("Starting compaction on zone %d...", zoneId)

try {
  ...
} catch {
  // log an exception backtrace with the message:
  case e: IOException =>
    log.error(e, "I/O exception: %s", e.getMessage)
}

Each of the log levels (from "fatal" to "trace") has these two convenience methods. You may also use log directly:

import com.twitter.logging.Level
log(Level.DEBUG, "Logging %s at debug level.", name)

An advantage to using sprintf ("%s", etc) conversion, as opposed to:

log(Level.DEBUG, s"Logging $name at debug level.")

is that Java & Scala perform string concatenation at runtime, even if nothing will be logged because the log file isn't writing debug messages right now. With sprintf parameters, the arguments are just bundled up and passed directly to the logging level before formatting. If no log message would be written to any file or device, then no formatting is done and the arguments are thrown away. That makes it very inexpensive to include verbose debug logging which can be turned off without recompiling and re-deploying.

If you prefer, there are also variants that take lazily evaluated parameters, and only evaluate them if logging is active at that level:

log.ifDebug(s"Login from $name at $date.")

The logging classes are done as an extension to the java.util.logging API, and so you can use the Java interface directly, if you want to. Each of the Java classes (Logger, Handler, Formatter) is just wrapped by a Scala class.

Configuring

In the Java style, log nodes are in a tree, with the root node being "" (the empty string). If a node has a filter level set, only log messages of that priority or higher are passed up to the parent. Handlers are attached to nodes for sending log messages to files or logging services, and may have formatters attached to them.

Logging levels are, in priority order of highest to lowest:

  • FATAL - the server is about to exit
  • CRITICAL - an event occurred that is bad enough to warrant paging someone
  • ERROR - a user-visible error occurred (though it may be limited in scope)
  • WARNING - a coder may want to be notified, but the error was probably not user-visible
  • INFO - normal informational messages
  • DEBUG - coder-level debugging information
  • TRACE - intensive debugging information

Each node may also optionally choose to not pass messages up to the parent node.

The LoggerFactory builder is used to configure individual log nodes, by filling in fields and calling the apply method. For example, to configure the root logger to filter at INFO level and write to a file:

import com.twitter.logging._

val factory = LoggerFactory(
  node = "",
  level = Some(Level.INFO),
  handlers = List(
    FileHandler(
      filename = "/var/log/example/example.log",
      rollPolicy = Policy.SigHup
    )
  )
)

val logger = factory()

As many LoggerFactorys can be configured as you want, so you can attach to several nodes if you like. To remove all previous configurations, use:

Logger.clearHandlers()

Handlers

  • QueueingHandler

    Queues log records and publishes them in another thread thereby enabling "async logging".

  • ConsoleHandler

    Logs to the console.

  • FileHandler

    Logs to a file, with an optional file rotation policy. The policies are:

    • Policy.Never - always use the same logfile (default)
    • Policy.Hourly - roll to a new logfile at the top of every hour
    • Policy.Daily - roll to a new logfile at midnight every night
    • Policy.Weekly(n) - roll to a new logfile at midnight on day N (0 = Sunday)
    • Policy.SigHup - reopen the logfile on SIGHUP (for logrotate and similar services)

    When a logfile is rolled, the current logfile is renamed to have the date (and hour, if rolling hourly) attached, and a new one is started. So, for example, test.log may become test-20080425.log, and test.log will be reopened as a new file.

  • SyslogHandler

    Log to a syslog server, by host and port.

  • ScribeHandler

    Log to a scribe server, by host, port, and category. Buffering and backoff can also be configured: You can specify how long to collect log lines before sending them in a single burst, the maximum burst size, and how long to backoff if the server seems to be offline.

  • ThrottledHandler

    Wraps another handler, tracking (and squelching) duplicate messages. If you use a format string like "Error %d at %s", the log messages will be de-duped based on the format string, even if they have different parameters.

Formatters

Handlers usually have a formatter attached to them, and these formatters generally just add a prefix containing the date, log level, and logger name.

  • Formatter

    A standard log prefix like "ERR [20080315-18:39:05.033] jobs: ", which can be configured to truncate log lines to a certain length, limit the lines of an exception stack trace, and use a special time zone.

    You can override the format string used to generate the prefix, also.

  • BareFormatterConfig

    No prefix at all. May be useful for logging info destined for scripts.

  • SyslogFormatterConfig

    A formatter required by the syslog protocol, with configurable syslog priority and date format.

Future interrupts

Method raise on Future (def raise(cause: Throwable)) raises the interrupt described by cause to the producer of this Future. Interrupt handlers are installed on a Promise using setInterruptHandler, which takes a partial function:

val p = new Promise[T]
p.setInterruptHandler {
  case exc: MyException =>
    // deal with interrupt..
}

Interrupts differ in semantics from cancellation in important ways: there can only be one interrupt handler per promise, and interrupts are only delivered if the promise is not yet complete.

Time and Duration

Like arithmetic on doubles, Time and Duration arithmetic is now free of overflows. Instead, they overflow to Top and Bottom values, which are analogous to positive and negative infinity.

Since the resolution of Time.now has been reduced (and is also more expensive due to its use of system time), a new Stopwatch API has been introduced in order to calculate durations of time.

It's used simply:

import com.twitter.util.{Duration, Stopwatch}
val elapsed: () => Duration = Stopwatch.start()

which is read by applying elapsed:

val duration: Duration = elapsed()

About

Wonderful reusable code from Twitter

Resources

License

Code of conduct

Stars

Watchers

Forks

Packages

No packages published

Languages

  • Scala 91.2%
  • Java 6.3%
  • Python 2.1%
  • Mako 0.2%
  • HTML 0.1%
  • Shell 0.1%