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concurrency.go
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concurrency.go
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package lo
import (
"context"
"sync"
"time"
)
type synchronize struct {
locker sync.Locker
}
func (s *synchronize) Do(cb func()) {
s.locker.Lock()
Try0(cb)
s.locker.Unlock()
}
// Synchronize wraps the underlying callback in a mutex. It receives an optional mutex.
func Synchronize(opt ...sync.Locker) *synchronize {
if len(opt) > 1 {
panic("unexpected arguments")
} else if len(opt) == 0 {
opt = append(opt, &sync.Mutex{})
}
return &synchronize{
locker: opt[0],
}
}
// Async executes a function in a goroutine and returns the result in a channel.
func Async[A any](f func() A) <-chan A {
ch := make(chan A, 1)
go func() {
ch <- f()
}()
return ch
}
// Async0 executes a function in a goroutine and returns a channel set once the function finishes.
func Async0(f func()) <-chan struct{} {
ch := make(chan struct{}, 1)
go func() {
f()
ch <- struct{}{}
}()
return ch
}
// Async1 is an alias to Async.
func Async1[A any](f func() A) <-chan A {
return Async(f)
}
// Async2 has the same behavior as Async, but returns the 2 results as a tuple inside the channel.
func Async2[A, B any](f func() (A, B)) <-chan Tuple2[A, B] {
ch := make(chan Tuple2[A, B], 1)
go func() {
ch <- T2(f())
}()
return ch
}
// Async3 has the same behavior as Async, but returns the 3 results as a tuple inside the channel.
func Async3[A, B, C any](f func() (A, B, C)) <-chan Tuple3[A, B, C] {
ch := make(chan Tuple3[A, B, C], 1)
go func() {
ch <- T3(f())
}()
return ch
}
// Async4 has the same behavior as Async, but returns the 4 results as a tuple inside the channel.
func Async4[A, B, C, D any](f func() (A, B, C, D)) <-chan Tuple4[A, B, C, D] {
ch := make(chan Tuple4[A, B, C, D], 1)
go func() {
ch <- T4(f())
}()
return ch
}
// Async5 has the same behavior as Async, but returns the 5 results as a tuple inside the channel.
func Async5[A, B, C, D, E any](f func() (A, B, C, D, E)) <-chan Tuple5[A, B, C, D, E] {
ch := make(chan Tuple5[A, B, C, D, E], 1)
go func() {
ch <- T5(f())
}()
return ch
}
// Async6 has the same behavior as Async, but returns the 6 results as a tuple inside the channel.
func Async6[A, B, C, D, E, F any](f func() (A, B, C, D, E, F)) <-chan Tuple6[A, B, C, D, E, F] {
ch := make(chan Tuple6[A, B, C, D, E, F], 1)
go func() {
ch <- T6(f())
}()
return ch
}
// WaitFor runs periodically until a condition is validated.
func WaitFor(condition func(i int) bool, timeout time.Duration, heartbeatDelay time.Duration) (totalIterations int, elapsed time.Duration, conditionFound bool) {
conditionWithContext := func(_ context.Context, currentIteration int) bool {
return condition(currentIteration)
}
return WaitForWithContext(context.Background(), conditionWithContext, timeout, heartbeatDelay)
}
// WaitForWithContext runs periodically until a condition is validated or context is canceled.
func WaitForWithContext(ctx context.Context, condition func(ctx context.Context, currentIteration int) bool, timeout time.Duration, heartbeatDelay time.Duration) (totalIterations int, elapsed time.Duration, conditionFound bool) {
start := time.Now()
if ctx.Err() != nil {
return totalIterations, time.Since(start), false
}
ctx, cleanCtx := context.WithTimeout(ctx, timeout)
ticker := time.NewTicker(heartbeatDelay)
defer func() {
cleanCtx()
ticker.Stop()
}()
for {
select {
case <-ctx.Done():
return totalIterations, time.Since(start), false
case <-ticker.C:
totalIterations++
if condition(ctx, totalIterations-1) {
return totalIterations, time.Since(start), true
}
}
}
}