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moby--moby/libnetwork/service_windows.go

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package libnetwork
import (
"net"
"github.com/Microsoft/hcsshim"
"github.com/sirupsen/logrus"
)
type policyLists struct {
ilb *hcsshim.PolicyList
elb *hcsshim.PolicyList
}
var lbPolicylistMap = make(map[*loadBalancer]*policyLists)
func (n *network) addLBBackend(ip net.IP, lb *loadBalancer) {
if len(lb.vip) == 0 {
return
}
vip := lb.vip
ingressPorts := lb.service.ingressPorts
lb.Lock()
defer lb.Unlock()
//find the load balancer IP for the network.
var sourceVIP string
for _, e := range n.Endpoints() {
epInfo := e.Info()
if epInfo == nil {
continue
}
if epInfo.LoadBalancer() {
sourceVIP = epInfo.Iface().Address().IP.String()
break
}
}
if sourceVIP == "" {
logrus.Errorf("Failed to find load balancer IP for network %s", n.Name())
return
}
var endpoints []hcsshim.HNSEndpoint
for eid, be := range lb.backEnds {
if be.disabled {
continue
}
//Call HNS to get back ID (GUID) corresponding to the endpoint.
hnsEndpoint, err := hcsshim.GetHNSEndpointByName(eid)
if err != nil {
logrus.Errorf("Failed to find HNS ID for endpoint %v: %v", eid, err)
return
}
endpoints = append(endpoints, *hnsEndpoint)
}
if policies, ok := lbPolicylistMap[lb]; ok {
if policies.ilb != nil {
policies.ilb.Delete()
policies.ilb = nil
}
if policies.elb != nil {
policies.elb.Delete()
policies.elb = nil
}
delete(lbPolicylistMap, lb)
}
ilbPolicy, err := hcsshim.AddLoadBalancer(endpoints, true, sourceVIP, vip.String(), 0, 0, 0)
if err != nil {
logrus.Errorf("Failed to add ILB policy for service %s (%s) with endpoints %v using load balancer IP %s on network %s: %v",
lb.service.name, vip.String(), endpoints, sourceVIP, n.Name(), err)
return
}
lbPolicylistMap[lb] = &policyLists{
ilb: ilbPolicy,
}
publishedPorts := make(map[uint32]uint32)
for i, port := range ingressPorts {
protocol := uint16(6)
// Skip already published port
if publishedPorts[port.PublishedPort] == port.TargetPort {
continue
}
if port.Protocol == ProtocolUDP {
protocol = 17
}
// check if already has udp matching to add wild card publishing
for j := i + 1; j < len(ingressPorts); j++ {
if ingressPorts[j].TargetPort == port.TargetPort &&
ingressPorts[j].PublishedPort == port.PublishedPort {
protocol = 0
}
}
publishedPorts[port.PublishedPort] = port.TargetPort
lbPolicylistMap[lb].elb, err = hcsshim.AddLoadBalancer(endpoints, false, sourceVIP, "", protocol, uint16(port.TargetPort), uint16(port.PublishedPort))
if err != nil {
logrus.Errorf("Failed to add ELB policy for service %s (ip:%s target port:%v published port:%v) with endpoints %v using load balancer IP %s on network %s: %v",
lb.service.name, vip.String(), uint16(port.TargetPort), uint16(port.PublishedPort), endpoints, sourceVIP, n.Name(), err)
return
}
}
}
func (n *network) rmLBBackend(ip net.IP, lb *loadBalancer, rmService bool, fullRemove bool) {
if len(lb.vip) == 0 {
return
}
if numEnabledBackends(lb) > 0 {
// Reprogram HNS (actually VFP) with the existing backends.
n.addLBBackend(ip, lb)
} else {
lb.Lock()
defer lb.Unlock()
logrus.Debugf("No more backends for service %s (ip:%s). Removing all policies", lb.service.name, lb.vip.String())
if policyLists, ok := lbPolicylistMap[lb]; ok {
if policyLists.ilb != nil {
policyLists.ilb.Delete()
policyLists.ilb = nil
}
if policyLists.elb != nil {
policyLists.elb.Delete()
policyLists.elb = nil
}
delete(lbPolicylistMap, lb)
} else {
logrus.Errorf("Failed to find policies for service %s (%s)", lb.service.name, lb.vip.String())
}
}
}
Gracefully remove LB endpoints from services This patch attempts to allow endpoints to complete servicing connections while being removed from a service. The change adds a flag to the endpoint.deleteServiceInfoFromCluster() method to indicate whether this removal should fully remove connectivity through the load balancer to the endpoint or should just disable directing further connections to the endpoint. If the flag is 'false', then the load balancer assigns a weight of 0 to the endpoint but does not remove it as a linux load balancing destination. It does remove the endpoint as a docker load balancing endpoint but tracks it in a special map of "disabled-but-not- destroyed" load balancing endpoints. This allows traffic to continue flowing, at least under Linux. If the flag is 'true', then the code removes the endpoint entirely as a load balancing destination. The sandbox.DisableService() method invokes deleteServiceInfoFromCluster() with the flag sent to 'false', while the endpoint.sbLeave() method invokes it with the flag set to 'true' to complete the removal on endpoint finalization. Renaming the endpoint invokes deleteServiceInfoFromCluster() with the flag set to 'true' because renaming attempts to completely remove and then re-add each endpoint service entry. The controller.rmServiceBinding() method, which carries out the operation, similarly gets a new flag for whether to fully remove the endpoint. If the flag is false, it does the job of moving the endpoint from the load balancing set to the 'disabled' set. It then removes or de-weights the entry in the OS load balancing table via network.rmLBBackend(). It removes the service entirely via said method ONLY IF there are no more live or disabled load balancing endpoints. Similarly network.addLBBackend() requires slight tweaking to properly manage the disabled set. Finally, this change requires propagating the status of disabled service endpoints via the networkDB. Accordingly, the patch includes both code to generate and handle service update messages. It also augments the service structure with a ServiceDisabled boolean to convey whether an endpoint should ultimately be removed or just disabled. This, naturally, required a rebuild of the protocol buffer code as well. Signed-off-by: Chris Telfer <ctelfer@docker.com>
2018-02-14 17:04:23 -05:00
func numEnabledBackends(lb *loadBalancer) int {
nEnabled := 0
for _, be := range lb.backEnds {
if !be.disabled {
nEnabled++
}
}
return nEnabled
}
Add endpoint load-balancing mode This is the heart of the scalability change for services in libnetwork. The present routing mesh adds load-balancing rules for a network to every container connected to the network. This newer approach creates a load-balancing endpoint per network per node. For every service on a network, libnetwork assigns the VIP of the service to the endpoint's interface as an alias. This endpoint must have a unique IP address in order to route return traffic to it. Traffic destined for a service's VIP arrives at the load-balancing endpoint on the VIP and from there, Linux load balances it among backend destinations while SNATing said traffic to the endpoint's unique IP address. The net result of this scheme is that each node in a swarm need only have one set of load balancing state per service instead of one per container on the node. This scheme is very similar to how services currently operate on Windows nodes in libnetwork. It (as with Windows nodes) costs the use of extra IP addresses in a network (one per node) and an extra network hop in the stack, although, always in the stack local to the container. In order to prevent existing deployments from suddenly failing if they failed to allocate sufficient address space to include per-node load-balancing endpoint IP addresses, this patch preserves the existing functionality and activates the new functionality on a per-network basis depending on whether the network has a load-balancing endpoint. Eventually, moby should always set this option when creating new networks and should only omit it for networks created as part of a swarm that are not marked to use endpoint load balancing. This patch also normalizes the code to treat "load" and "balancer" as two separate words from the perspectives of variable/function naming. This means that the 'b' in "balancer" must be capitalized. Signed-off-by: Chris Telfer <ctelfer@docker.com>
2018-04-10 12:34:41 -04:00
func (sb *sandbox) populateLoadBalancers(ep *endpoint) {
}
func arrangeIngressFilterRule() {
}