Multi-Threading

Base.Threads.@threads — Macro

  1. Threads.@threads [schedule] for ... end

A macro to parallelize a for loop to run with multiple threads. Splits the iteration space among multiple tasks and runs those tasks on threads according to a scheduling policy. A barrier is placed at the end of the loop which waits for all tasks to finish execution.

The schedule argument can be used to request a particular scheduling policy. The only currently supported value is :static, which creates one task per thread and divides the iterations equally among them. Specifying :static is an error if used from inside another @threads loop or from a thread other than 1.

The default schedule (used when no schedule argument is present) is subject to change.

Julia 1.5

The schedule argument is available as of Julia 1.5.

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Base.Threads.@spawn — Macro

  1. Threads.@spawn expr

Create and run a Task on any available thread. To wait for the task to finish, call wait on the result of this macro, or call fetch to wait and then obtain its return value.

Values can be interpolated into @spawn via $, which copies the value directly into the constructed underlying closure. This allows you to insert the value of a variable, isolating the aysnchronous code from changes to the variable’s value in the current task.

Note

See the manual chapter on threading for important caveats.

Julia 1.3

This macro is available as of Julia 1.3.

Julia 1.4

Interpolating values via $ is available as of Julia 1.4.

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Base.Threads.threadid — Function

  1. Threads.threadid()

Get the ID number of the current thread of execution. The master thread has ID 1.

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Base.Threads.nthreads — Function

  1. Threads.nthreads()

Get the number of threads available to the Julia process. This is the inclusive upper bound on threadid().

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Synchronization

Base.Threads.Condition — Type

  1. Threads.Condition([lock])

A thread-safe version of Base.Condition.

To call wait or notify on a Threads.Condition, you must first call lock on it. When wait is called, the lock is atomically released during blocking, and will be reacquired before wait returns. Therefore idiomatic use of a Threads.Condition c looks like the following:

  1. lock(c)
  2. try
  3.     while !thing_we_are_waiting_for
  4.         wait(c)
  5.     end
  6. finally
  7.     unlock(c)
  8. end

Julia 1.2

This functionality requires at least Julia 1.2.

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Base.Event — Type

  1. Event()

Create a level-triggered event source. Tasks that call wait on an Event are suspended and queued until notify is called on the Event. After notify is called, the Event remains in a signaled state and tasks will no longer block when waiting for it.

Julia 1.1

This functionality requires at least Julia 1.1.

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See also Synchronization.

Atomic operations

Warning

The API for atomic operations has not yet been finalized and is likely to change.

Base.Threads.Atomic — Type

  1. Threads.Atomic{T}

Holds a reference to an object of type T, ensuring that it is only accessed atomically, i.e. in a thread-safe manner.

Only certain “simple” types can be used atomically, namely the primitive boolean, integer, and float-point types. These are Bool, Int8Int128, UInt8UInt128, and Float16Float64.

New atomic objects can be created from a non-atomic values; if none is specified, the atomic object is initialized with zero.

Atomic objects can be accessed using the [] notation:

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> x[] = 1
  5. 1
  7. julia> x[]
  8. 1

Atomic operations use an atomic_ prefix, such as atomic_add!, atomic_xchg!, etc.

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Base.Threads.atomic_cas! — Function

  1. Threads.atomic_cas!(x::Atomic{T}, cmp::T, newval::T) where T

Atomically compare-and-set x

Atomically compares the value in x with cmp. If equal, write newval to x. Otherwise, leaves x unmodified. Returns the old value in x. By comparing the returned value to cmp (via ===) one knows whether x was modified and now holds the new value newval.

For further details, see LLVM’s cmpxchg instruction.

This function can be used to implement transactional semantics. Before the transaction, one records the value in x. After the transaction, the new value is stored only if x has not been modified in the mean time.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_cas!(x, 4, 2);
  6. julia> x
  7. Base.Threads.Atomic{Int64}(3)
  9. julia> Threads.atomic_cas!(x, 3, 2);
  11. julia> x
  12. Base.Threads.Atomic{Int64}(2)

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Base.Threads.atomic_xchg! — Function

  1. Threads.atomic_xchg!(x::Atomic{T}, newval::T) where T

Atomically exchange the value in x

Atomically exchanges the value in x with newval. Returns the old value.

For further details, see LLVM’s atomicrmw xchg instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_xchg!(x, 2)
  5. 3
  7. julia> x[]
  8. 2

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Base.Threads.atomic_add! — Function

  1. Threads.atomic_add!(x::Atomic{T}, val::T) where T <: ArithmeticTypes

Atomically add val to x

Performs x[] += val atomically. Returns the old value. Not defined for Atomic{Bool}.

For further details, see LLVM’s atomicrmw add instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_add!(x, 2)
  5. 3
  7. julia> x[]
  8. 5

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Base.Threads.atomic_sub! — Function

  1. Threads.atomic_sub!(x::Atomic{T}, val::T) where T <: ArithmeticTypes

Atomically subtract val from x

Performs x[] -= val atomically. Returns the old value. Not defined for Atomic{Bool}.

For further details, see LLVM’s atomicrmw sub instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_sub!(x, 2)
  5. 3
  7. julia> x[]
  8. 1

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Base.Threads.atomic_and! — Function

  1. Threads.atomic_and!(x::Atomic{T}, val::T) where T

Atomically bitwise-and x with val

Performs x[] &= val atomically. Returns the old value.

For further details, see LLVM’s atomicrmw and instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_and!(x, 2)
  5. 3
  7. julia> x[]
  8. 2

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Base.Threads.atomic_nand! — Function

  1. Threads.atomic_nand!(x::Atomic{T}, val::T) where T

Atomically bitwise-nand (not-and) x with val

Performs x[] = ~(x[] & val) atomically. Returns the old value.

For further details, see LLVM’s atomicrmw nand instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(3)
  2. Base.Threads.Atomic{Int64}(3)
  4. julia> Threads.atomic_nand!(x, 2)
  5. 3
  7. julia> x[]
  8. -3

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Base.Threads.atomic_or! — Function

  1. Threads.atomic_or!(x::Atomic{T}, val::T) where T

Atomically bitwise-or x with val

Performs x[] |= val atomically. Returns the old value.

For further details, see LLVM’s atomicrmw or instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(5)
  2. Base.Threads.Atomic{Int64}(5)
  4. julia> Threads.atomic_or!(x, 7)
  5. 5
  7. julia> x[]
  8. 7

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Base.Threads.atomic_xor! — Function

  1. Threads.atomic_xor!(x::Atomic{T}, val::T) where T

Atomically bitwise-xor (exclusive-or) x with val

Performs x[] $= val atomically. Returns the old value.

For further details, see LLVM’s atomicrmw xor instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(5)
  2. Base.Threads.Atomic{Int64}(5)
  4. julia> Threads.atomic_xor!(x, 7)
  5. 5
  7. julia> x[]
  8. 2

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Base.Threads.atomic_max! — Function

  1. Threads.atomic_max!(x::Atomic{T}, val::T) where T

Atomically store the maximum of x and val in x

Performs x[] = max(x[], val) atomically. Returns the old value.

For further details, see LLVM’s atomicrmw max instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(5)
  2. Base.Threads.Atomic{Int64}(5)
  4. julia> Threads.atomic_max!(x, 7)
  5. 5
  7. julia> x[]
  8. 7

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Base.Threads.atomic_min! — Function

  1. Threads.atomic_min!(x::Atomic{T}, val::T) where T

Atomically store the minimum of x and val in x

Performs x[] = min(x[], val) atomically. Returns the old value.

For further details, see LLVM’s atomicrmw min instruction.

Examples

  1. julia> x = Threads.Atomic{Int}(7)
  2. Base.Threads.Atomic{Int64}(7)
  4. julia> Threads.atomic_min!(x, 5)
  5. 7
  7. julia> x[]
  8. 5

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Base.Threads.atomic_fence — Function

  1. Threads.atomic_fence()

Insert a sequential-consistency memory fence

Inserts a memory fence with sequentially-consistent ordering semantics. There are algorithms where this is needed, i.e. where an acquire/release ordering is insufficient.

This is likely a very expensive operation. Given that all other atomic operations in Julia already have acquire/release semantics, explicit fences should not be necessary in most cases.

For further details, see LLVM’s fence instruction.

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ccall using a threadpool (Experimental)

Base.@threadcall — Macro

  1. @threadcall((cfunc, clib), rettype, (argtypes...), argvals...)

The @threadcall macro is called in the same way as ccall but does the work in a different thread. This is useful when you want to call a blocking C function without causing the main julia thread to become blocked. Concurrency is limited by size of the libuv thread pool, which defaults to 4 threads but can be increased by setting the UV_THREADPOOL_SIZE environment variable and restarting the julia process.

Note that the called function should never call back into Julia.

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Low-level synchronization primitives

These building blocks are used to create the regular synchronization objects.

Base.Threads.SpinLock — Type

  1. SpinLock()

Create a non-reentrant, test-and-test-and-set spin lock. Recursive use will result in a deadlock. This kind of lock should only be used around code that takes little time to execute and does not block (e.g. perform I/O). In general, ReentrantLock should be used instead.

Each lock must be matched with an unlock.

Test-and-test-and-set spin locks are quickest up to about 30ish contending threads. If you have more contention than that, different synchronization approaches should be considered.

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