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load_balancer.go
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load_balancer.go
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// Copyright (c) 2019 The Gnet Authors. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package gnet
import (
"hash/crc32"
"net"
"github.com/panjf2000/gnet/v2/internal/bs"
)
// LoadBalancing represents the type of load-balancing algorithm.
type LoadBalancing int
const (
// RoundRobin assigns the next accepted connection to the event-loop by polling event-loop list.
RoundRobin LoadBalancing = iota
// LeastConnections assigns the next accepted connection to the event-loop that is
// serving the least number of active connections at the current time.
LeastConnections
// SourceAddrHash assigns the next accepted connection to the event-loop by hashing the remote address.
SourceAddrHash
)
type (
// loadBalancer is an interface which manipulates the event-loop set.
loadBalancer interface {
register(*eventloop)
next(net.Addr) *eventloop
index(int) *eventloop
iterate(func(int, *eventloop) bool)
len() int
}
// baseLoadBalancer with base lb.
baseLoadBalancer struct {
eventLoops []*eventloop
size int
}
// roundRobinLoadBalancer with Round-Robin algorithm.
roundRobinLoadBalancer struct {
baseLoadBalancer
nextIndex uint64
}
// leastConnectionsLoadBalancer with Least-Connections algorithm.
leastConnectionsLoadBalancer struct {
baseLoadBalancer
}
// sourceAddrHashLoadBalancer with Hash algorithm.
sourceAddrHashLoadBalancer struct {
baseLoadBalancer
}
)
// ==================================== Implementation of base load-balancer ====================================
// register adds a new eventloop into load-balancer.
func (lb *baseLoadBalancer) register(el *eventloop) {
el.idx = lb.size
lb.eventLoops = append(lb.eventLoops, el)
lb.size++
}
// index returns the eligible eventloop by index.
func (lb *baseLoadBalancer) index(i int) *eventloop {
if i >= lb.size {
return nil
}
return lb.eventLoops[i]
}
// iterate iterates all the eventloops.
func (lb *baseLoadBalancer) iterate(f func(int, *eventloop) bool) {
for i, el := range lb.eventLoops {
if !f(i, el) {
break
}
}
}
// len returns the length of event-loop list.
func (lb *baseLoadBalancer) len() int {
return lb.size
}
// ==================================== Implementation of Round-Robin load-balancer ====================================
// next returns the eligible event-loop based on Round-Robin algorithm.
func (lb *roundRobinLoadBalancer) next(_ net.Addr) (el *eventloop) {
el = lb.eventLoops[lb.nextIndex%uint64(lb.size)]
lb.nextIndex++
return
}
// ================================= Implementation of Least-Connections load-balancer =================================
func (lb *leastConnectionsLoadBalancer) next(_ net.Addr) (el *eventloop) {
el = lb.eventLoops[0]
minN := el.countConn()
for _, v := range lb.eventLoops[1:] {
if n := v.countConn(); n < minN {
minN = n
el = v
}
}
return
}
// ======================================= Implementation of Hash load-balancer ========================================
// hash converts a string to a unique hash code.
func (*sourceAddrHashLoadBalancer) hash(s string) int {
v := int(crc32.ChecksumIEEE(bs.StringToBytes(s)))
if v >= 0 {
return v
}
return -v
}
// next returns the eligible event-loop by taking the remainder of a hash code as the index of event-loop list.
func (lb *sourceAddrHashLoadBalancer) next(netAddr net.Addr) *eventloop {
hashCode := lb.hash(netAddr.String())
return lb.eventLoops[hashCode%lb.size]
}