Erlang Run-Time System Application (ERTS)

Reference Manual

Version 11.2.2.15

Table of Contents

atomics

Module

atomics

Module Summary

Atomic Functions

Since

Module atomics was introduced in OTP 21.2.

Description

This module provides a set of functions to do atomic operations towards mutable atomic variables. The implementation utilizes only atomic hardware instructions without any software level locking, which makes it very efficient for concurrent access. The atomics are organized into arrays with the following semantics:

  • Atomics are 64 bit integers.

  • Atomics can be represented as either signed or unsigned.

  • Atomics wrap around at overflow and underflow operations.

  • All operations guarantee atomicity. No intermediate results can be seen. The result of one mutation can only be the input to one following mutation.

  • All atomic operations are mutually ordered. If atomic B is updated after atomic A, then that is how it will appear to any concurrent readers. No one can read the new value of B and then read the old value of A.

  • Indexes into atomic arrays are one-based. An atomic array of arity N contains N atomics with index from 1 to N.

Data Types

Identifies an atomic array returned from new/2.

new(Arity, Opts) -> atomics_ref()
OTP 21.2

Types

Arity = integer() >= 1
Opts = [Opt]
Opt = {signed, boolean()}

Create a new array of Arity number of atomics. All atomics in the array are initially set to zero.

Argument Opts is a list of the following possible options:

{signed, boolean()}

Indicate if the elements of the array will be treated as signed or unsigned integers. Default is true (signed).

The integer interval for signed atomics are from -(1 bsl 63) to (1 bsl 63)-1 and for unsigned atomics from 0 to (1 bsl 64)-1.

Atomics are not tied to the current process and are automatically garbage collected when they are no longer referenced.

put(Ref, Ix, Value) -> ok
OTP 21.2

Types

Ix = Value = integer()

Set atomic to Value.

get(Ref, Ix) -> integer()
OTP 21.2

Types

Ix = integer()

Read atomic value.

add(Ref, Ix, Incr) -> ok
OTP 21.2

Types

Ix = Incr = integer()

Add Incr to atomic.

add_get(Ref, Ix, Incr) -> integer()
OTP 21.2

Types

Ix = Incr = integer()

Atomic addition and return of the result.

sub(Ref, Ix, Decr) -> ok
OTP 21.2

Types

Ix = Decr = integer()

Subtract Decr from atomic.

sub_get(Ref, Ix, Decr) -> integer()
OTP 21.2

Types

Ix = Decr = integer()

Atomic subtraction and return of the result.

exchange(Ref, Ix, Desired) -> integer()
OTP 21.2

Types

Ix = Desired = integer()

Atomically replaces the value of the atomic with Desired and returns the value it held previously.

compare_exchange(Ref, Ix, Expected, Desired) -> ok | integer()
OTP 21.2

Types

Ix = Expected = Desired = integer()

Atomically compares the atomic with Expected, and if those are equal, set atomic to Desired. Returns ok if Desired was written. Returns the actual atomic value if not equal to Expected.

info(Ref) -> Info
OTP 21.2

Types

Info =
    #{size := Size, max := Max, min := Min, memory := Memory}
Size = integer() >= 0
Max = Min = integer()
Memory = integer() >= 0

Return information about an atomic array in a map. The map has the following keys:

size

The number of atomics in the array.

max

The highest possible value an atomic in this array can hold.

min

The lowest possible value an atomic in this array can hold.

memory

Approximate memory consumption for the array in bytes.