ants/multipool_func.go

202 lines
5.7 KiB
Go

// MIT License
// Copyright (c) 2023 Andy Pan
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
package ants
import (
"errors"
"fmt"
"strings"
"sync/atomic"
"time"
)
// MultiPoolWithFunc consists of multiple pools, from which you will benefit the
// performance improvement on basis of the fine-grained locking that reduces
// the lock contention.
// MultiPoolWithFunc is a good fit for the scenario where you have a large number of
// tasks to submit, and you don't want the single pool to be the bottleneck.
type MultiPoolWithFunc struct {
pools []*PoolWithFunc
index uint32
state int32
lbs LoadBalancingStrategy
}
// NewMultiPoolWithFunc instantiates a MultiPoolWithFunc with a size of the pool list and a size
// per pool, and the load-balancing strategy.
func NewMultiPoolWithFunc(size, sizePerPool int, fn func(interface{}), lbs LoadBalancingStrategy, options ...Option) (*MultiPoolWithFunc, error) {
pools := make([]*PoolWithFunc, size)
for i := 0; i < size; i++ {
pool, err := NewPoolWithFunc(sizePerPool, fn, options...)
if err != nil {
return nil, err
}
pools[i] = pool
}
if lbs != RoundRobin && lbs != LeastTasks {
return nil, ErrInvalidLoadBalancingStrategy
}
return &MultiPoolWithFunc{pools: pools, lbs: lbs}, nil
}
func (mp *MultiPoolWithFunc) next(lbs LoadBalancingStrategy) (idx int) {
switch lbs {
case RoundRobin:
if idx = int((atomic.AddUint32(&mp.index, 1) - 1) % uint32(len(mp.pools))); idx == -1 {
idx = 0
}
return
case LeastTasks:
leastTasks := 1<<31 - 1
for i, pool := range mp.pools {
if n := pool.Running(); n < leastTasks {
leastTasks = n
idx = i
}
}
return
}
return -1
}
// Invoke submits a task to a pool selected by the load-balancing strategy.
func (mp *MultiPoolWithFunc) Invoke(args interface{}) (err error) {
if mp.IsClosed() {
return ErrPoolClosed
}
if err = mp.pools[mp.next(mp.lbs)].Invoke(args); err == nil {
return
}
if err == ErrPoolOverload && mp.lbs == RoundRobin {
return mp.pools[mp.next(LeastTasks)].Invoke(args)
}
return
}
// Running returns the number of the currently running workers across all pools.
func (mp *MultiPoolWithFunc) Running() (n int) {
for _, pool := range mp.pools {
n += pool.Running()
}
return
}
// RunningByIndex returns the number of the currently running workers in the specific pool.
func (mp *MultiPoolWithFunc) RunningByIndex(idx int) (int, error) {
if idx < 0 || idx >= len(mp.pools) {
return -1, ErrInvalidPoolIndex
}
return mp.pools[idx].Running(), nil
}
// Free returns the number of available workers across all pools.
func (mp *MultiPoolWithFunc) Free() (n int) {
for _, pool := range mp.pools {
n += pool.Free()
}
return
}
// FreeByIndex returns the number of available workers in the specific pool.
func (mp *MultiPoolWithFunc) FreeByIndex(idx int) (int, error) {
if idx < 0 || idx >= len(mp.pools) {
return -1, ErrInvalidPoolIndex
}
return mp.pools[idx].Free(), nil
}
// Waiting returns the number of the currently waiting tasks across all pools.
func (mp *MultiPoolWithFunc) Waiting() (n int) {
for _, pool := range mp.pools {
n += pool.Waiting()
}
return
}
// WaitingByIndex returns the number of the currently waiting tasks in the specific pool.
func (mp *MultiPoolWithFunc) WaitingByIndex(idx int) (int, error) {
if idx < 0 || idx >= len(mp.pools) {
return -1, ErrInvalidPoolIndex
}
return mp.pools[idx].Waiting(), nil
}
// Cap returns the capacity of this multi-pool.
func (mp *MultiPoolWithFunc) Cap() (n int) {
for _, pool := range mp.pools {
n += pool.Cap()
}
return
}
// Tune resizes each pool in multi-pool.
//
// Note that this method doesn't resize the overall
// capacity of multi-pool.
func (mp *MultiPoolWithFunc) Tune(size int) {
for _, pool := range mp.pools {
pool.Tune(size)
}
}
// IsClosed indicates whether the multi-pool is closed.
func (mp *MultiPoolWithFunc) IsClosed() bool {
return atomic.LoadInt32(&mp.state) == CLOSED
}
// ReleaseTimeout closes the multi-pool with a timeout,
// it waits all pools to be closed before timing out.
func (mp *MultiPoolWithFunc) ReleaseTimeout(timeout time.Duration) error {
if !atomic.CompareAndSwapInt32(&mp.state, OPENED, CLOSED) {
return ErrPoolClosed
}
var errStr strings.Builder
for i, pool := range mp.pools {
if err := pool.ReleaseTimeout(timeout); err != nil {
errStr.WriteString(fmt.Sprintf("pool %d: %v\n", i, err))
if i < len(mp.pools)-1 {
errStr.WriteString(" | ")
}
return err
}
}
if errStr.Len() == 0 {
return nil
}
return errors.New(errStr.String())
}
// Reboot reboots a released multi-pool.
func (mp *MultiPoolWithFunc) Reboot() {
if atomic.CompareAndSwapInt32(&mp.state, CLOSED, OPENED) {
atomic.StoreUint32(&mp.index, 0)
for _, pool := range mp.pools {
pool.Reboot()
}
}
}