Wraps array of TRef and adds methods for convenience.
A TPriorityQueue
contains values of type A
that an Ordering
is defined
on.
A TPriorityQueue
contains values of type A
that an Ordering
is defined
on. Unlike a TQueue
, take
returns the highest priority value (the value
that is first in the specified ordering) as opposed to the first value
offered to the queue. The ordering that elements with the same priority will
be taken from the queue is not guaranteed.
A TReentrantLock
is a reentrant read/write lock.
A TReentrantLock
is a reentrant read/write lock. Multiple readers may all
concurrently acquire read locks. Only one writer is allowed to acquire a
write lock at any given time. Read locks may be upgraded into write locks.
A fiber that has a write lock may acquire other write locks or read locks.
The two primary methods of this structure are readLock
, which acquires a
read lock in a managed context, and writeLock
, which acquires a write lock
in a managed context.
Although located in the STM package, there is no need for locks within STM transactions. However, this lock can be quite useful in effectful code, to provide consistent read/write access to mutable state; and being in STM allows this structure to be composed into more complicated concurrent structures that are consumed from effectful code.
A TSemaphore
is a semaphore that can be composed transactionally.
A TSemaphore
is a semaphore that can be composed transactionally. Because
of the extremely high performance of ZIO's implementation of software
transactional memory TSemaphore
can support both controlling access to
some resource on a standalone basis as well as composing with other STM
data structures to solve more advanced concurrency problems.
For basic use cases, the most idiomatic way to work with a semaphore is to
use the withPermit
operator, which acquires a permit before executing
some ZIO
effect and release the permit immediately afterward. The permit
is guaranteed to be released immediately after the effect completes
execution, whether by success, failure, or interruption. Attempting to
acquire a permit when a sufficient number of permits are not available will
semantically block until permits become available without blocking any
underlying operating system threads. If you want to acquire more than one
permit at a time you can use withPermits
, which allows specifying a
number of permits to acquire. You can also use withPermitManaged
or
withPermitsManaged
to acquire and release permits within the context of
a managed effect for composing with other resources.
For more advanced concurrency problems you can use the acquire
and
release
operators directly, or their variants acquireN
and releaseN
,
all of which return STM transactions. Thus, they can be composed to form
larger STM transactions, for example acquiring permits from two different
semaphores transactionally and later releasing them transactionally to
safely synchronize on access to two different mutable variables.
Transactional set implemented on top of TMap.
STM[E, A]
represents an effect that can be performed transactionally,
resulting in a failure E
or a value A
.
STM[E, A]
represents an effect that can be performed transactionally,
resulting in a failure E
or a value A
.
def transfer(receiver: TRef[Int], sender: TRef[Int], much: Int): UIO[Int] = STM.atomically { for { balance <- sender.get _ <- STM.check(balance >= much) _ <- receiver.update(_ + much) _ <- sender.update(_ - much) newAmnt <- receiver.get } yield newAmnt } val action: UIO[Int] = for { t <- STM.atomically(TRef.make(0).zip(TRef.make(20000))) (receiver, sender) = t balance <- transfer(receiver, sender, 1000) } yield balance
Software Transactional Memory is a technique which allows composition of arbitrary atomic operations. It is the software analog of transactions in database systems.
The API is lifted directly from the Haskell package Control.Concurrent.STM although the implementation does not resemble the Haskell one at all. http://hackage.haskell.org/package/stm-2.5.0.0/docs/Control-Concurrent-STM.html
STM in Haskell was introduced in: Composable memory transactions, by Tim Harris, Simon Marlow, Simon Peyton Jones, and Maurice Herlihy, in ACM Conference on Principles and Practice of Parallel Programming 2005. https://www.microsoft.com/en-us/research/publication/composable-memory-transactions/
See also: Lock Free Data Structures using STMs in Haskell, by Anthony Discolo, Tim Harris, Simon Marlow, Simon Peyton Jones, Satnam Singh) FLOPS 2006: Eighth International Symposium on Functional and Logic Programming, Fuji Susono, JAPAN, April 2006 https://www.microsoft.com/en-us/research/publication/lock-free-data-structures-using-stms-in-haskell/
A ZTRef[EA, EB, A, B]
is a polymorphic, purely functional description of a
mutable reference that can be modified as part of a transactional effect.
A ZTRef[EA, EB, A, B]
is a polymorphic, purely functional description of a
mutable reference that can be modified as part of a transactional effect. The
fundamental operations of a ZTRef
are set
and get
. set
takes a value
of type A
and transactionally sets the reference to a new value, potentially
failing with an error of type EA
. get
gets the current value of the reference
and returns a value of type B
, potentially failing with an error of type EB
.
When the error and value types of the ZTRef
are unified, that is, it is a
ZTRef[E, E, A, A]
, the ZTRef
also supports atomic modify
and update
operations. All operations are guaranteed to be executed transactionally.
NOTE: While ZTRef
provides the transactional equivalent of a mutable reference,
the value inside the ZTRef
should be immutable. For performance reasons ZTRef
is implemented in terms of compare and swap operations rather than synchronization.
These operations are not safe for mutable values that do not support concurrent
access.