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https://github.com/XTLS/Xray-core.git
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fa5d7a255b
* v5: Health Check & LeastLoad Strategy (rebased from 2c5a71490368500a982018a74a6d519c7e121816) Some changes will be necessary to integrate it into V2Ray * Update proto * parse duration conf with time.Parse() * moving health ping to observatory as a standalone component * moving health ping to observatory as a standalone component: auto generated file * add initialization for health ping * incorporate changes in router implementation * support principle target output * add v4 json support for BurstObservatory & fix balancer reference * update API command * remove cancelled API * return zero length value when observer is not found * remove duplicated targeted dispatch * adjust test with updated structure * bug fix for observer * fix strategy selector * fix strategy least load * Fix ticker usage ticker.Close does not close ticker.C * feat: Replace default Health Ping URL to HTTPS (#1991) * fix selectLeastLoad() returns wrong number of nodes (#2083) * Test: fix leastload strategy unit test * fix(router): panic caused by concurrent map read and write (#2678) * Clean up code --------- Co-authored-by: Jebbs <qjebbs@gmail.com> Co-authored-by: Shelikhoo <xiaokangwang@outlook.com> Co-authored-by: 世界 <i@sekai.icu> Co-authored-by: Bernd Eichelberger <46166740+4-FLOSS-Free-Libre-Open-Source-Software@users.noreply.github.com> Co-authored-by: 秋のかえで <autmaple@protonmail.com> Co-authored-by: Rinka <kujourinka@gmail.com>
180 lines
5 KiB
Go
180 lines
5 KiB
Go
package router
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import (
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"testing"
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)
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/*
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Split into multiple package, need to be tested separately
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func TestSelectLeastLoad(t *testing.T) {
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settings := &StrategyLeastLoadConfig{
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HealthCheck: &HealthPingConfig{
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SamplingCount: 10,
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},
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Expected: 1,
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MaxRTT: int64(time.Millisecond * time.Duration(800)),
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}
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strategy := NewLeastLoadStrategy(settings)
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// std 40
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strategy.PutResult("a", time.Millisecond*time.Duration(60))
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strategy.PutResult("a", time.Millisecond*time.Duration(140))
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strategy.PutResult("a", time.Millisecond*time.Duration(60))
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strategy.PutResult("a", time.Millisecond*time.Duration(140))
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// std 60
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strategy.PutResult("b", time.Millisecond*time.Duration(40))
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strategy.PutResult("b", time.Millisecond*time.Duration(160))
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strategy.PutResult("b", time.Millisecond*time.Duration(40))
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strategy.PutResult("b", time.Millisecond*time.Duration(160))
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// std 0, but >MaxRTT
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strategy.PutResult("c", time.Millisecond*time.Duration(1000))
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strategy.PutResult("c", time.Millisecond*time.Duration(1000))
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strategy.PutResult("c", time.Millisecond*time.Duration(1000))
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strategy.PutResult("c", time.Millisecond*time.Duration(1000))
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expected := "a"
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actual := strategy.SelectAndPick([]string{"a", "b", "c", "untested"})
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if actual != expected {
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t.Errorf("expected: %v, actual: %v", expected, actual)
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}
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}
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func TestSelectLeastLoadWithCost(t *testing.T) {
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settings := &StrategyLeastLoadConfig{
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HealthCheck: &HealthPingConfig{
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SamplingCount: 10,
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},
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Costs: []*StrategyWeight{
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{Match: "a", Value: 9},
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},
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Expected: 1,
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}
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strategy := NewLeastLoadStrategy(settings, nil)
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// std 40, std+c 120
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strategy.PutResult("a", time.Millisecond*time.Duration(60))
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strategy.PutResult("a", time.Millisecond*time.Duration(140))
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strategy.PutResult("a", time.Millisecond*time.Duration(60))
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strategy.PutResult("a", time.Millisecond*time.Duration(140))
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// std 60
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strategy.PutResult("b", time.Millisecond*time.Duration(40))
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strategy.PutResult("b", time.Millisecond*time.Duration(160))
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strategy.PutResult("b", time.Millisecond*time.Duration(40))
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strategy.PutResult("b", time.Millisecond*time.Duration(160))
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expected := "b"
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actual := strategy.SelectAndPick([]string{"a", "b", "untested"})
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if actual != expected {
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t.Errorf("expected: %v, actual: %v", expected, actual)
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}
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}
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*/
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func TestSelectLeastExpected(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: nil,
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Expected: 3,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 100},
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{Tag: "b", RTTDeviationCost: 200},
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{Tag: "c", RTTDeviationCost: 300},
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{Tag: "d", RTTDeviationCost: 350},
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}
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expected := 3
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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func TestSelectLeastExpected2(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: nil,
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Expected: 3,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 100},
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{Tag: "b", RTTDeviationCost: 200},
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}
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expected := 2
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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func TestSelectLeastExpectedAndBaselines(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: []int64{200, 300, 400},
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Expected: 3,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 100},
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{Tag: "b", RTTDeviationCost: 200},
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{Tag: "c", RTTDeviationCost: 250},
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{Tag: "d", RTTDeviationCost: 300},
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{Tag: "e", RTTDeviationCost: 310},
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}
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expected := 3
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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func TestSelectLeastExpectedAndBaselines2(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: []int64{200, 300, 400},
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Expected: 3,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 500},
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{Tag: "b", RTTDeviationCost: 600},
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{Tag: "c", RTTDeviationCost: 700},
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{Tag: "d", RTTDeviationCost: 800},
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{Tag: "e", RTTDeviationCost: 900},
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}
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expected := 3
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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func TestSelectLeastLoadBaselines(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: []int64{200, 400, 600},
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Expected: 0,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 100},
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{Tag: "b", RTTDeviationCost: 200},
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{Tag: "c", RTTDeviationCost: 300},
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}
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expected := 1
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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func TestSelectLeastLoadBaselinesNoQualified(t *testing.T) {
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strategy := &LeastLoadStrategy{
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settings: &StrategyLeastLoadConfig{
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Baselines: []int64{200, 400, 600},
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Expected: 0,
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},
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}
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nodes := []*node{
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{Tag: "a", RTTDeviationCost: 800},
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{Tag: "b", RTTDeviationCost: 1000},
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}
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expected := 0
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ns := strategy.selectLeastLoad(nodes)
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if len(ns) != expected {
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t.Errorf("expected: %v, actual: %v", expected, len(ns))
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}
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}
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