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moby--moby/libnetwork/network.go
Sebastiaan van Stijn e34ab5200d
fix formatting of "nolint" tags for go1.19
The correct formatting for machine-readable comments is;

    //<some alphanumeric identifier>:<options>[,<option>...][ // comment]

Which basically means:

- MUST NOT have a space before `<identifier>` (e.g. `nolint`)
- Identified MUST be alphanumeric
- MUST be followed by a colon
- MUST be followed by at least one `<option>`
- Optionally additional `<options>` (comma-separated)
- Optionally followed by a comment

Any other format will not be considered a machine-readable comment by `gofmt`,
and thus formatted as a regular comment. Note that this also means that a
`//nolint` (without anything after it) is considered invalid, same for `//#nosec`
(starts with a `#`).

Signed-off-by: Sebastiaan van Stijn <github@gone.nl>
(cherry picked from commit 4f08346686)
Signed-off-by: Sebastiaan van Stijn <github@gone.nl>
2022-07-15 13:45:13 +02:00

2258 lines
58 KiB
Go

package libnetwork
import (
"encoding/json"
"fmt"
"net"
"runtime"
"strings"
"sync"
"time"
"github.com/docker/docker/libnetwork/config"
"github.com/docker/docker/libnetwork/datastore"
"github.com/docker/docker/libnetwork/driverapi"
"github.com/docker/docker/libnetwork/etchosts"
"github.com/docker/docker/libnetwork/internal/setmatrix"
"github.com/docker/docker/libnetwork/ipamapi"
"github.com/docker/docker/libnetwork/netlabel"
"github.com/docker/docker/libnetwork/netutils"
"github.com/docker/docker/libnetwork/networkdb"
"github.com/docker/docker/libnetwork/options"
"github.com/docker/docker/libnetwork/types"
"github.com/docker/docker/pkg/stringid"
"github.com/sirupsen/logrus"
)
// A Network represents a logical connectivity zone that containers may
// join using the Link method. A Network is managed by a specific driver.
type Network interface {
// Name returns a user chosen name for this network.
Name() string
// ID returns a system generated id for this network.
ID() string
// Type returns the type of network, which corresponds to its managing driver.
Type() string
// CreateEndpoint creates a new endpoint to this network symbolically identified by the
// specified unique name. The options parameter carries driver specific options.
CreateEndpoint(name string, options ...EndpointOption) (Endpoint, error)
// Delete the network.
Delete(options ...NetworkDeleteOption) error
// Endpoints returns the list of Endpoint(s) in this network.
Endpoints() []Endpoint
// WalkEndpoints uses the provided function to walk the Endpoints.
WalkEndpoints(walker EndpointWalker)
// EndpointByName returns the Endpoint which has the passed name. If not found, the error ErrNoSuchEndpoint is returned.
EndpointByName(name string) (Endpoint, error)
// EndpointByID returns the Endpoint which has the passed id. If not found, the error ErrNoSuchEndpoint is returned.
EndpointByID(id string) (Endpoint, error)
// Info returns certain operational data belonging to this network.
Info() NetworkInfo
}
// NetworkInfo returns some configuration and operational information about the network
type NetworkInfo interface {
IpamConfig() (string, map[string]string, []*IpamConf, []*IpamConf)
IpamInfo() ([]*IpamInfo, []*IpamInfo)
DriverOptions() map[string]string
Scope() string
IPv6Enabled() bool
Internal() bool
Attachable() bool
Ingress() bool
ConfigFrom() string
ConfigOnly() bool
Labels() map[string]string
Dynamic() bool
Created() time.Time
// Peers returns a slice of PeerInfo structures which has the information about the peer
// nodes participating in the same overlay network. This is currently the per-network
// gossip cluster. For non-dynamic overlay networks and bridge networks it returns an
// empty slice
Peers() []networkdb.PeerInfo
// Services returns a map of services keyed by the service name with the details
// of all the tasks that belong to the service. Applicable only in swarm mode.
Services() map[string]ServiceInfo
}
// EndpointWalker is a client provided function which will be used to walk the Endpoints.
// When the function returns true, the walk will stop.
type EndpointWalker func(ep Endpoint) bool
// ipInfo is the reverse mapping from IP to service name to serve the PTR query.
// extResolver is set if an external server resolves a service name to this IP.
// It's an indication to defer PTR queries also to that external server.
type ipInfo struct {
name string
serviceID string
extResolver bool
}
// svcMapEntry is the body of the element into the svcMap
// The ip is a string because the SetMatrix does not accept non hashable values
type svcMapEntry struct {
ip string
serviceID string
}
type svcInfo struct {
svcMap setmatrix.SetMatrix
svcIPv6Map setmatrix.SetMatrix
ipMap setmatrix.SetMatrix
service map[string][]servicePorts
}
// backing container or host's info
type serviceTarget struct {
name string
ip net.IP
port uint16
}
type servicePorts struct {
portName string
proto string
target []serviceTarget
}
type networkDBTable struct {
name string
objType driverapi.ObjectType
}
// IpamConf contains all the ipam related configurations for a network
type IpamConf struct {
// PreferredPool is the master address pool for containers and network interfaces.
PreferredPool string
// SubPool is a subset of the master pool. If specified,
// this becomes the container pool.
SubPool string
// Gateway is the preferred Network Gateway address (optional).
Gateway string
// AuxAddresses contains auxiliary addresses for network driver. Must be within the master pool.
// libnetwork will reserve them if they fall into the container pool.
AuxAddresses map[string]string
}
// Validate checks whether the configuration is valid
func (c *IpamConf) Validate() error {
if c.Gateway != "" && nil == net.ParseIP(c.Gateway) {
return types.BadRequestErrorf("invalid gateway address %s in Ipam configuration", c.Gateway)
}
return nil
}
// IpamInfo contains all the ipam related operational info for a network
type IpamInfo struct {
PoolID string
Meta map[string]string
driverapi.IPAMData
}
// MarshalJSON encodes IpamInfo into json message
func (i *IpamInfo) MarshalJSON() ([]byte, error) {
m := map[string]interface{}{
"PoolID": i.PoolID,
}
v, err := json.Marshal(&i.IPAMData)
if err != nil {
return nil, err
}
m["IPAMData"] = string(v)
if i.Meta != nil {
m["Meta"] = i.Meta
}
return json.Marshal(m)
}
// UnmarshalJSON decodes json message into PoolData
func (i *IpamInfo) UnmarshalJSON(data []byte) error {
var (
m map[string]interface{}
err error
)
if err = json.Unmarshal(data, &m); err != nil {
return err
}
i.PoolID = m["PoolID"].(string)
if v, ok := m["Meta"]; ok {
b, _ := json.Marshal(v)
if err = json.Unmarshal(b, &i.Meta); err != nil {
return err
}
}
if v, ok := m["IPAMData"]; ok {
if err = json.Unmarshal([]byte(v.(string)), &i.IPAMData); err != nil {
return err
}
}
return nil
}
type network struct {
ctrlr *controller
name string
networkType string
id string
created time.Time
scope string // network data scope
labels map[string]string
ipamType string
ipamOptions map[string]string
addrSpace string
ipamV4Config []*IpamConf
ipamV6Config []*IpamConf
ipamV4Info []*IpamInfo
ipamV6Info []*IpamInfo
enableIPv6 bool
postIPv6 bool
epCnt *endpointCnt
generic options.Generic
dbIndex uint64
dbExists bool
persist bool
drvOnce *sync.Once
resolverOnce sync.Once
resolver []Resolver
internal bool
attachable bool
inDelete bool
ingress bool
driverTables []networkDBTable
dynamic bool
configOnly bool
configFrom string
loadBalancerIP net.IP
loadBalancerMode string
sync.Mutex
}
const (
loadBalancerModeNAT = "NAT"
loadBalancerModeDSR = "DSR"
loadBalancerModeDefault = loadBalancerModeNAT
)
func (n *network) Name() string {
n.Lock()
defer n.Unlock()
return n.name
}
func (n *network) ID() string {
n.Lock()
defer n.Unlock()
return n.id
}
func (n *network) Created() time.Time {
n.Lock()
defer n.Unlock()
return n.created
}
func (n *network) Type() string {
n.Lock()
defer n.Unlock()
return n.networkType
}
func (n *network) Key() []string {
n.Lock()
defer n.Unlock()
return []string{datastore.NetworkKeyPrefix, n.id}
}
func (n *network) KeyPrefix() []string {
return []string{datastore.NetworkKeyPrefix}
}
func (n *network) Value() []byte {
n.Lock()
defer n.Unlock()
b, err := json.Marshal(n)
if err != nil {
return nil
}
return b
}
func (n *network) SetValue(value []byte) error {
return json.Unmarshal(value, n)
}
func (n *network) Index() uint64 {
n.Lock()
defer n.Unlock()
return n.dbIndex
}
func (n *network) SetIndex(index uint64) {
n.Lock()
n.dbIndex = index
n.dbExists = true
n.Unlock()
}
func (n *network) Exists() bool {
n.Lock()
defer n.Unlock()
return n.dbExists
}
func (n *network) Skip() bool {
n.Lock()
defer n.Unlock()
return !n.persist
}
func (n *network) New() datastore.KVObject {
n.Lock()
defer n.Unlock()
return &network{
ctrlr: n.ctrlr,
drvOnce: &sync.Once{},
scope: n.scope,
}
}
// CopyTo deep copies to the destination IpamConfig
func (c *IpamConf) CopyTo(dstC *IpamConf) error {
dstC.PreferredPool = c.PreferredPool
dstC.SubPool = c.SubPool
dstC.Gateway = c.Gateway
if c.AuxAddresses != nil {
dstC.AuxAddresses = make(map[string]string, len(c.AuxAddresses))
for k, v := range c.AuxAddresses {
dstC.AuxAddresses[k] = v
}
}
return nil
}
// CopyTo deep copies to the destination IpamInfo
func (i *IpamInfo) CopyTo(dstI *IpamInfo) error {
dstI.PoolID = i.PoolID
if i.Meta != nil {
dstI.Meta = make(map[string]string)
for k, v := range i.Meta {
dstI.Meta[k] = v
}
}
dstI.AddressSpace = i.AddressSpace
dstI.Pool = types.GetIPNetCopy(i.Pool)
dstI.Gateway = types.GetIPNetCopy(i.Gateway)
if i.AuxAddresses != nil {
dstI.AuxAddresses = make(map[string]*net.IPNet)
for k, v := range i.AuxAddresses {
dstI.AuxAddresses[k] = types.GetIPNetCopy(v)
}
}
return nil
}
func (n *network) validateConfiguration() error {
if n.configOnly {
// Only supports network specific configurations.
// Network operator configurations are not supported.
if n.ingress || n.internal || n.attachable || n.scope != "" {
return types.ForbiddenErrorf("configuration network can only contain network " +
"specific fields. Network operator fields like " +
"[ ingress | internal | attachable | scope ] are not supported.")
}
}
if n.configFrom != "" {
if n.configOnly {
return types.ForbiddenErrorf("a configuration network cannot depend on another configuration network")
}
if n.ipamType != "" &&
n.ipamType != defaultIpamForNetworkType(n.networkType) ||
n.enableIPv6 ||
len(n.labels) > 0 || len(n.ipamOptions) > 0 ||
len(n.ipamV4Config) > 0 || len(n.ipamV6Config) > 0 {
return types.ForbiddenErrorf("user specified configurations are not supported if the network depends on a configuration network")
}
if len(n.generic) > 0 {
if data, ok := n.generic[netlabel.GenericData]; ok {
var (
driverOptions map[string]string
opts interface{}
)
switch t := data.(type) {
case map[string]interface{}, map[string]string:
opts = t
}
ba, err := json.Marshal(opts)
if err != nil {
return fmt.Errorf("failed to validate network configuration: %v", err)
}
if err := json.Unmarshal(ba, &driverOptions); err != nil {
return fmt.Errorf("failed to validate network configuration: %v", err)
}
if len(driverOptions) > 0 {
return types.ForbiddenErrorf("network driver options are not supported if the network depends on a configuration network")
}
}
}
}
return nil
}
// applyConfigurationTo applies network specific configurations.
func (n *network) applyConfigurationTo(to *network) error {
to.enableIPv6 = n.enableIPv6
if len(n.labels) > 0 {
to.labels = make(map[string]string, len(n.labels))
for k, v := range n.labels {
if _, ok := to.labels[k]; !ok {
to.labels[k] = v
}
}
}
if len(n.ipamType) != 0 {
to.ipamType = n.ipamType
}
if len(n.ipamOptions) > 0 {
to.ipamOptions = make(map[string]string, len(n.ipamOptions))
for k, v := range n.ipamOptions {
if _, ok := to.ipamOptions[k]; !ok {
to.ipamOptions[k] = v
}
}
}
if len(n.ipamV4Config) > 0 {
to.ipamV4Config = make([]*IpamConf, 0, len(n.ipamV4Config))
to.ipamV4Config = append(to.ipamV4Config, n.ipamV4Config...)
}
if len(n.ipamV6Config) > 0 {
to.ipamV6Config = make([]*IpamConf, 0, len(n.ipamV6Config))
to.ipamV6Config = append(to.ipamV6Config, n.ipamV6Config...)
}
if len(n.generic) > 0 {
to.generic = options.Generic{}
for k, v := range n.generic {
to.generic[k] = v
}
}
return nil
}
func (n *network) CopyTo(o datastore.KVObject) error {
n.Lock()
defer n.Unlock()
dstN := o.(*network)
dstN.name = n.name
dstN.id = n.id
dstN.created = n.created
dstN.networkType = n.networkType
dstN.scope = n.scope
dstN.dynamic = n.dynamic
dstN.ipamType = n.ipamType
dstN.enableIPv6 = n.enableIPv6
dstN.persist = n.persist
dstN.postIPv6 = n.postIPv6
dstN.dbIndex = n.dbIndex
dstN.dbExists = n.dbExists
dstN.drvOnce = n.drvOnce
dstN.internal = n.internal
dstN.attachable = n.attachable
dstN.inDelete = n.inDelete
dstN.ingress = n.ingress
dstN.configOnly = n.configOnly
dstN.configFrom = n.configFrom
dstN.loadBalancerIP = n.loadBalancerIP
dstN.loadBalancerMode = n.loadBalancerMode
// copy labels
if dstN.labels == nil {
dstN.labels = make(map[string]string, len(n.labels))
}
for k, v := range n.labels {
dstN.labels[k] = v
}
if n.ipamOptions != nil {
dstN.ipamOptions = make(map[string]string, len(n.ipamOptions))
for k, v := range n.ipamOptions {
dstN.ipamOptions[k] = v
}
}
for _, v4conf := range n.ipamV4Config {
dstV4Conf := &IpamConf{}
if err := v4conf.CopyTo(dstV4Conf); err != nil {
return err
}
dstN.ipamV4Config = append(dstN.ipamV4Config, dstV4Conf)
}
for _, v4info := range n.ipamV4Info {
dstV4Info := &IpamInfo{}
if err := v4info.CopyTo(dstV4Info); err != nil {
return err
}
dstN.ipamV4Info = append(dstN.ipamV4Info, dstV4Info)
}
for _, v6conf := range n.ipamV6Config {
dstV6Conf := &IpamConf{}
if err := v6conf.CopyTo(dstV6Conf); err != nil {
return err
}
dstN.ipamV6Config = append(dstN.ipamV6Config, dstV6Conf)
}
for _, v6info := range n.ipamV6Info {
dstV6Info := &IpamInfo{}
if err := v6info.CopyTo(dstV6Info); err != nil {
return err
}
dstN.ipamV6Info = append(dstN.ipamV6Info, dstV6Info)
}
dstN.generic = options.Generic{}
for k, v := range n.generic {
dstN.generic[k] = v
}
return nil
}
func (n *network) DataScope() string {
s := n.Scope()
// All swarm scope networks have local datascope
if s == datastore.SwarmScope {
s = datastore.LocalScope
}
return s
}
func (n *network) getEpCnt() *endpointCnt {
n.Lock()
defer n.Unlock()
return n.epCnt
}
// TODO : Can be made much more generic with the help of reflection (but has some golang limitations)
func (n *network) MarshalJSON() ([]byte, error) {
netMap := make(map[string]interface{})
netMap["name"] = n.name
netMap["id"] = n.id
netMap["created"] = n.created
netMap["networkType"] = n.networkType
netMap["scope"] = n.scope
netMap["labels"] = n.labels
netMap["ipamType"] = n.ipamType
netMap["ipamOptions"] = n.ipamOptions
netMap["addrSpace"] = n.addrSpace
netMap["enableIPv6"] = n.enableIPv6
if n.generic != nil {
netMap["generic"] = n.generic
}
netMap["persist"] = n.persist
netMap["postIPv6"] = n.postIPv6
if len(n.ipamV4Config) > 0 {
ics, err := json.Marshal(n.ipamV4Config)
if err != nil {
return nil, err
}
netMap["ipamV4Config"] = string(ics)
}
if len(n.ipamV4Info) > 0 {
iis, err := json.Marshal(n.ipamV4Info)
if err != nil {
return nil, err
}
netMap["ipamV4Info"] = string(iis)
}
if len(n.ipamV6Config) > 0 {
ics, err := json.Marshal(n.ipamV6Config)
if err != nil {
return nil, err
}
netMap["ipamV6Config"] = string(ics)
}
if len(n.ipamV6Info) > 0 {
iis, err := json.Marshal(n.ipamV6Info)
if err != nil {
return nil, err
}
netMap["ipamV6Info"] = string(iis)
}
netMap["internal"] = n.internal
netMap["attachable"] = n.attachable
netMap["inDelete"] = n.inDelete
netMap["ingress"] = n.ingress
netMap["configOnly"] = n.configOnly
netMap["configFrom"] = n.configFrom
netMap["loadBalancerIP"] = n.loadBalancerIP
netMap["loadBalancerMode"] = n.loadBalancerMode
return json.Marshal(netMap)
}
// TODO : Can be made much more generic with the help of reflection (but has some golang limitations)
func (n *network) UnmarshalJSON(b []byte) (err error) {
var netMap map[string]interface{}
if err := json.Unmarshal(b, &netMap); err != nil {
return err
}
n.name = netMap["name"].(string)
n.id = netMap["id"].(string)
// "created" is not available in older versions
if v, ok := netMap["created"]; ok {
// n.created is time.Time but marshalled as string
if err = n.created.UnmarshalText([]byte(v.(string))); err != nil {
logrus.Warnf("failed to unmarshal creation time %v: %v", v, err)
n.created = time.Time{}
}
}
n.networkType = netMap["networkType"].(string)
n.enableIPv6 = netMap["enableIPv6"].(bool)
// if we weren't unmarshaling to netMap we could simply set n.labels
// unfortunately, we can't because map[string]interface{} != map[string]string
if labels, ok := netMap["labels"].(map[string]interface{}); ok {
n.labels = make(map[string]string, len(labels))
for label, value := range labels {
n.labels[label] = value.(string)
}
}
if v, ok := netMap["ipamOptions"]; ok {
if iOpts, ok := v.(map[string]interface{}); ok {
n.ipamOptions = make(map[string]string, len(iOpts))
for k, v := range iOpts {
n.ipamOptions[k] = v.(string)
}
}
}
if v, ok := netMap["generic"]; ok {
n.generic = v.(map[string]interface{})
// Restore opts in their map[string]string form
if v, ok := n.generic[netlabel.GenericData]; ok {
var lmap map[string]string
ba, err := json.Marshal(v)
if err != nil {
return err
}
if err := json.Unmarshal(ba, &lmap); err != nil {
return err
}
n.generic[netlabel.GenericData] = lmap
}
}
if v, ok := netMap["persist"]; ok {
n.persist = v.(bool)
}
if v, ok := netMap["postIPv6"]; ok {
n.postIPv6 = v.(bool)
}
if v, ok := netMap["ipamType"]; ok {
n.ipamType = v.(string)
} else {
n.ipamType = ipamapi.DefaultIPAM
}
if v, ok := netMap["addrSpace"]; ok {
n.addrSpace = v.(string)
}
if v, ok := netMap["ipamV4Config"]; ok {
if err := json.Unmarshal([]byte(v.(string)), &n.ipamV4Config); err != nil {
return err
}
}
if v, ok := netMap["ipamV4Info"]; ok {
if err := json.Unmarshal([]byte(v.(string)), &n.ipamV4Info); err != nil {
return err
}
}
if v, ok := netMap["ipamV6Config"]; ok {
if err := json.Unmarshal([]byte(v.(string)), &n.ipamV6Config); err != nil {
return err
}
}
if v, ok := netMap["ipamV6Info"]; ok {
if err := json.Unmarshal([]byte(v.(string)), &n.ipamV6Info); err != nil {
return err
}
}
if v, ok := netMap["internal"]; ok {
n.internal = v.(bool)
}
if v, ok := netMap["attachable"]; ok {
n.attachable = v.(bool)
}
if s, ok := netMap["scope"]; ok {
n.scope = s.(string)
}
if v, ok := netMap["inDelete"]; ok {
n.inDelete = v.(bool)
}
if v, ok := netMap["ingress"]; ok {
n.ingress = v.(bool)
}
if v, ok := netMap["configOnly"]; ok {
n.configOnly = v.(bool)
}
if v, ok := netMap["configFrom"]; ok {
n.configFrom = v.(string)
}
if v, ok := netMap["loadBalancerIP"]; ok {
n.loadBalancerIP = net.ParseIP(v.(string))
}
n.loadBalancerMode = loadBalancerModeDefault
if v, ok := netMap["loadBalancerMode"]; ok {
n.loadBalancerMode = v.(string)
}
// Reconcile old networks with the recently added `--ipv6` flag
if !n.enableIPv6 {
n.enableIPv6 = len(n.ipamV6Info) > 0
}
return nil
}
// NetworkOption is an option setter function type used to pass various options to
// NewNetwork method. The various setter functions of type NetworkOption are
// provided by libnetwork, they look like NetworkOptionXXXX(...)
type NetworkOption func(n *network)
// NetworkOptionGeneric function returns an option setter for a Generic option defined
// in a Dictionary of Key-Value pair
func NetworkOptionGeneric(generic map[string]interface{}) NetworkOption {
return func(n *network) {
if n.generic == nil {
n.generic = make(map[string]interface{})
}
if val, ok := generic[netlabel.EnableIPv6]; ok {
n.enableIPv6 = val.(bool)
}
if val, ok := generic[netlabel.Internal]; ok {
n.internal = val.(bool)
}
for k, v := range generic {
n.generic[k] = v
}
}
}
// NetworkOptionIngress returns an option setter to indicate if a network is
// an ingress network.
func NetworkOptionIngress(ingress bool) NetworkOption {
return func(n *network) {
n.ingress = ingress
}
}
// NetworkOptionPersist returns an option setter to set persistence policy for a network
func NetworkOptionPersist(persist bool) NetworkOption {
return func(n *network) {
n.persist = persist
}
}
// NetworkOptionEnableIPv6 returns an option setter to explicitly configure IPv6
func NetworkOptionEnableIPv6(enableIPv6 bool) NetworkOption {
return func(n *network) {
if n.generic == nil {
n.generic = make(map[string]interface{})
}
n.enableIPv6 = enableIPv6
n.generic[netlabel.EnableIPv6] = enableIPv6
}
}
// NetworkOptionInternalNetwork returns an option setter to config the network
// to be internal which disables default gateway service
func NetworkOptionInternalNetwork() NetworkOption {
return func(n *network) {
if n.generic == nil {
n.generic = make(map[string]interface{})
}
n.internal = true
n.generic[netlabel.Internal] = true
}
}
// NetworkOptionAttachable returns an option setter to set attachable for a network
func NetworkOptionAttachable(attachable bool) NetworkOption {
return func(n *network) {
n.attachable = attachable
}
}
// NetworkOptionScope returns an option setter to overwrite the network's scope.
// By default the network's scope is set to the network driver's datascope.
func NetworkOptionScope(scope string) NetworkOption {
return func(n *network) {
n.scope = scope
}
}
// NetworkOptionIpam function returns an option setter for the ipam configuration for this network
func NetworkOptionIpam(ipamDriver string, addrSpace string, ipV4 []*IpamConf, ipV6 []*IpamConf, opts map[string]string) NetworkOption {
return func(n *network) {
if ipamDriver != "" {
n.ipamType = ipamDriver
if ipamDriver == ipamapi.DefaultIPAM {
n.ipamType = defaultIpamForNetworkType(n.Type())
}
}
n.ipamOptions = opts
n.addrSpace = addrSpace
n.ipamV4Config = ipV4
n.ipamV6Config = ipV6
}
}
// NetworkOptionLBEndpoint function returns an option setter for the configuration of the load balancer endpoint for this network
func NetworkOptionLBEndpoint(ip net.IP) NetworkOption {
return func(n *network) {
n.loadBalancerIP = ip
}
}
// NetworkOptionDriverOpts function returns an option setter for any driver parameter described by a map
func NetworkOptionDriverOpts(opts map[string]string) NetworkOption {
return func(n *network) {
if n.generic == nil {
n.generic = make(map[string]interface{})
}
if opts == nil {
opts = make(map[string]string)
}
// Store the options
n.generic[netlabel.GenericData] = opts
}
}
// NetworkOptionLabels function returns an option setter for labels specific to a network
func NetworkOptionLabels(labels map[string]string) NetworkOption {
return func(n *network) {
n.labels = labels
}
}
// NetworkOptionDynamic function returns an option setter for dynamic option for a network
func NetworkOptionDynamic() NetworkOption {
return func(n *network) {
n.dynamic = true
}
}
// NetworkOptionDeferIPv6Alloc instructs the network to defer the IPV6 address allocation until after the endpoint has been created
// It is being provided to support the specific docker daemon flags where user can deterministically assign an IPv6 address
// to a container as combination of fixed-cidr-v6 + mac-address
// TODO: Remove this option setter once we support endpoint ipam options
func NetworkOptionDeferIPv6Alloc(enable bool) NetworkOption {
return func(n *network) {
n.postIPv6 = enable
}
}
// NetworkOptionConfigOnly tells controller this network is
// a configuration only network. It serves as a configuration
// for other networks.
func NetworkOptionConfigOnly() NetworkOption {
return func(n *network) {
n.configOnly = true
}
}
// NetworkOptionConfigFrom tells controller to pick the
// network configuration from a configuration only network
func NetworkOptionConfigFrom(name string) NetworkOption {
return func(n *network) {
n.configFrom = name
}
}
func (n *network) processOptions(options ...NetworkOption) {
for _, opt := range options {
if opt != nil {
opt(n)
}
}
}
type networkDeleteParams struct {
rmLBEndpoint bool
}
// NetworkDeleteOption is a type for optional parameters to pass to the
// network.Delete() function.
type NetworkDeleteOption func(p *networkDeleteParams)
// NetworkDeleteOptionRemoveLB informs a network.Delete() operation that should
// remove the load balancer endpoint for this network. Note that the Delete()
// method will automatically remove a load balancing endpoint for most networks
// when the network is otherwise empty. However, this does not occur for some
// networks. In particular, networks marked as ingress (which are supposed to
// be more permanent than other overlay networks) won't automatically remove
// the LB endpoint on Delete(). This method allows for explicit removal of
// such networks provided there are no other endpoints present in the network.
// If the network still has non-LB endpoints present, Delete() will not
// remove the LB endpoint and will return an error.
func NetworkDeleteOptionRemoveLB(p *networkDeleteParams) {
p.rmLBEndpoint = true
}
func (n *network) resolveDriver(name string, load bool) (driverapi.Driver, *driverapi.Capability, error) {
c := n.getController()
// Check if a driver for the specified network type is available
d, cap := c.drvRegistry.Driver(name)
if d == nil {
if load {
err := c.loadDriver(name)
if err != nil {
return nil, nil, err
}
d, cap = c.drvRegistry.Driver(name)
if d == nil {
return nil, nil, fmt.Errorf("could not resolve driver %s in registry", name)
}
} else {
// don't fail if driver loading is not required
return nil, nil, nil
}
}
return d, cap, nil
}
func (n *network) driverIsMultihost() bool {
_, cap, err := n.resolveDriver(n.networkType, true)
if err != nil {
return false
}
return cap.ConnectivityScope == datastore.GlobalScope
}
func (n *network) driver(load bool) (driverapi.Driver, error) {
d, cap, err := n.resolveDriver(n.networkType, load)
if err != nil {
return nil, err
}
n.Lock()
// If load is not required, driver, cap and err may all be nil
if n.scope == "" && cap != nil {
n.scope = cap.DataScope
}
if n.dynamic {
// If the network is dynamic, then it is swarm
// scoped regardless of the backing driver.
n.scope = datastore.SwarmScope
}
n.Unlock()
return d, nil
}
func (n *network) Delete(options ...NetworkDeleteOption) error {
var params networkDeleteParams
for _, opt := range options {
opt(&params)
}
return n.delete(false, params.rmLBEndpoint)
}
// This function gets called in 3 ways:
// - Delete() -- (false, false)
// remove if endpoint count == 0 or endpoint count == 1 and
// there is a load balancer IP
// - Delete(libnetwork.NetworkDeleteOptionRemoveLB) -- (false, true)
// remove load balancer and network if endpoint count == 1
// - controller.networkCleanup() -- (true, true)
// remove the network no matter what
func (n *network) delete(force bool, rmLBEndpoint bool) error {
n.Lock()
c := n.ctrlr
name := n.name
id := n.id
n.Unlock()
c.networkLocker.Lock(id)
defer c.networkLocker.Unlock(id) //nolint:errcheck
n, err := c.getNetworkFromStore(id)
if err != nil {
return &UnknownNetworkError{name: name, id: id}
}
// Only remove ingress on force removal or explicit LB endpoint removal
if n.ingress && !force && !rmLBEndpoint {
return &ActiveEndpointsError{name: n.name, id: n.id}
}
// Check that the network is empty
var emptyCount uint64
if n.hasLoadBalancerEndpoint() {
emptyCount = 1
}
if !force && n.getEpCnt().EndpointCnt() > emptyCount {
if n.configOnly {
return types.ForbiddenErrorf("configuration network %q is in use", n.Name())
}
return &ActiveEndpointsError{name: n.name, id: n.id}
}
if n.hasLoadBalancerEndpoint() {
// If we got to this point, then the following must hold:
// * force is true OR endpoint count == 1
if err := n.deleteLoadBalancerSandbox(); err != nil {
if !force {
return err
}
// continue deletion when force is true even on error
logrus.Warnf("Error deleting load balancer sandbox: %v", err)
}
// Reload the network from the store to update the epcnt.
n, err = c.getNetworkFromStore(id)
if err != nil {
return &UnknownNetworkError{name: name, id: id}
}
}
// Up to this point, errors that we returned were recoverable.
// From here on, any errors leave us in an inconsistent state.
// This is unfortunate, but there isn't a safe way to
// reconstitute a load-balancer endpoint after removing it.
// Mark the network for deletion
n.inDelete = true
if err = c.updateToStore(n); err != nil {
return fmt.Errorf("error marking network %s (%s) for deletion: %v", n.Name(), n.ID(), err)
}
if n.ConfigFrom() != "" {
if t, err := c.getConfigNetwork(n.ConfigFrom()); err == nil {
if err := t.getEpCnt().DecEndpointCnt(); err != nil {
logrus.Warnf("Failed to update reference count for configuration network %q on removal of network %q: %v",
t.Name(), n.Name(), err)
}
} else {
logrus.Warnf("Could not find configuration network %q during removal of network %q", n.configFrom, n.Name())
}
}
if n.configOnly {
goto removeFromStore
}
n.ipamRelease()
if err = c.updateToStore(n); err != nil {
logrus.Warnf("Failed to update store after ipam release for network %s (%s): %v", n.Name(), n.ID(), err)
}
// We are about to delete the network. Leave the gossip
// cluster for the network to stop all incoming network
// specific gossip updates before cleaning up all the service
// bindings for the network. But cleanup service binding
// before deleting the network from the store since service
// bindings cleanup requires the network in the store.
n.cancelDriverWatches()
if err = n.leaveCluster(); err != nil {
logrus.Errorf("Failed leaving network %s from the agent cluster: %v", n.Name(), err)
}
// Cleanup the service discovery for this network
c.cleanupServiceDiscovery(n.ID())
// Cleanup the load balancer. On Windows this call is required
// to remove remote loadbalancers in VFP, and must be performed before
// dataplane network deletion.
if runtime.GOOS == "windows" {
c.cleanupServiceBindings(n.ID())
}
// Delete the network from the dataplane
if err = n.deleteNetwork(); err != nil {
if !force {
return err
}
logrus.Debugf("driver failed to delete stale network %s (%s): %v", n.Name(), n.ID(), err)
}
removeFromStore:
// deleteFromStore performs an atomic delete operation and the
// network.epCnt will help prevent any possible
// race between endpoint join and network delete
if err = c.deleteFromStore(n.getEpCnt()); err != nil {
if !force {
return fmt.Errorf("error deleting network endpoint count from store: %v", err)
}
logrus.Debugf("Error deleting endpoint count from store for stale network %s (%s) for deletion: %v", n.Name(), n.ID(), err)
}
if err = c.deleteFromStore(n); err != nil {
return fmt.Errorf("error deleting network from store: %v", err)
}
return nil
}
func (n *network) deleteNetwork() error {
d, err := n.driver(true)
if err != nil {
return fmt.Errorf("failed deleting network: %v", err)
}
if err := d.DeleteNetwork(n.ID()); err != nil {
// Forbidden Errors should be honored
if _, ok := err.(types.ForbiddenError); ok {
return err
}
if _, ok := err.(types.MaskableError); !ok {
logrus.Warnf("driver error deleting network %s : %v", n.name, err)
}
}
for _, resolver := range n.resolver {
resolver.Stop()
}
return nil
}
func (n *network) addEndpoint(ep *endpoint) error {
d, err := n.driver(true)
if err != nil {
return fmt.Errorf("failed to add endpoint: %v", err)
}
err = d.CreateEndpoint(n.id, ep.id, ep.Interface(), ep.generic)
if err != nil {
return types.InternalErrorf("failed to create endpoint %s on network %s: %v",
ep.Name(), n.Name(), err)
}
return nil
}
func (n *network) CreateEndpoint(name string, options ...EndpointOption) (Endpoint, error) {
var err error
if !config.IsValidName(name) {
return nil, ErrInvalidName(name)
}
if n.ConfigOnly() {
return nil, types.ForbiddenErrorf("cannot create endpoint on configuration-only network")
}
if _, err = n.EndpointByName(name); err == nil {
return nil, types.ForbiddenErrorf("endpoint with name %s already exists in network %s", name, n.Name())
}
n.ctrlr.networkLocker.Lock(n.id)
defer n.ctrlr.networkLocker.Unlock(n.id) //nolint:errcheck
return n.createEndpoint(name, options...)
}
func (n *network) createEndpoint(name string, options ...EndpointOption) (Endpoint, error) {
var err error
ep := &endpoint{name: name, generic: make(map[string]interface{}), iface: &endpointInterface{}}
ep.id = stringid.GenerateRandomID()
// Initialize ep.network with a possibly stale copy of n. We need this to get network from
// store. But once we get it from store we will have the most uptodate copy possibly.
ep.network = n
ep.network, err = ep.getNetworkFromStore()
if err != nil {
logrus.Errorf("failed to get network during CreateEndpoint: %v", err)
return nil, err
}
n = ep.network
ep.processOptions(options...)
for _, llIPNet := range ep.Iface().LinkLocalAddresses() {
if !llIPNet.IP.IsLinkLocalUnicast() {
return nil, types.BadRequestErrorf("invalid link local IP address: %v", llIPNet.IP)
}
}
if opt, ok := ep.generic[netlabel.MacAddress]; ok {
if mac, ok := opt.(net.HardwareAddr); ok {
ep.iface.mac = mac
}
}
ipam, capability, err := n.getController().getIPAMDriver(n.ipamType)
if err != nil {
return nil, err
}
if capability.RequiresMACAddress {
if ep.iface.mac == nil {
ep.iface.mac = netutils.GenerateRandomMAC()
}
if ep.ipamOptions == nil {
ep.ipamOptions = make(map[string]string)
}
ep.ipamOptions[netlabel.MacAddress] = ep.iface.mac.String()
}
if err = ep.assignAddress(ipam, true, n.enableIPv6 && !n.postIPv6); err != nil {
return nil, err
}
defer func() {
if err != nil {
ep.releaseAddress()
}
}()
if err = n.addEndpoint(ep); err != nil {
return nil, err
}
defer func() {
if err != nil {
if e := ep.deleteEndpoint(false); e != nil {
logrus.Warnf("cleaning up endpoint failed %s : %v", name, e)
}
}
}()
// We should perform updateToStore call right after addEndpoint
// in order to have iface properly configured
if err = n.getController().updateToStore(ep); err != nil {
return nil, err
}
defer func() {
if err != nil {
if e := n.getController().deleteFromStore(ep); e != nil {
logrus.Warnf("error rolling back endpoint %s from store: %v", name, e)
}
}
}()
if err = ep.assignAddress(ipam, false, n.enableIPv6 && n.postIPv6); err != nil {
return nil, err
}
// Watch for service records
n.getController().watchSvcRecord(ep)
defer func() {
if err != nil {
n.getController().unWatchSvcRecord(ep)
}
}()
// Increment endpoint count to indicate completion of endpoint addition
if err = n.getEpCnt().IncEndpointCnt(); err != nil {
return nil, err
}
return ep, nil
}
func (n *network) Endpoints() []Endpoint {
var list []Endpoint
endpoints, err := n.getEndpointsFromStore()
if err != nil {
logrus.Error(err)
}
for _, ep := range endpoints {
list = append(list, ep)
}
return list
}
func (n *network) WalkEndpoints(walker EndpointWalker) {
for _, e := range n.Endpoints() {
if walker(e) {
return
}
}
}
func (n *network) EndpointByName(name string) (Endpoint, error) {
if name == "" {
return nil, ErrInvalidName(name)
}
var e Endpoint
s := func(current Endpoint) bool {
if current.Name() == name {
e = current
return true
}
return false
}
n.WalkEndpoints(s)
if e == nil {
return nil, ErrNoSuchEndpoint(name)
}
return e, nil
}
func (n *network) EndpointByID(id string) (Endpoint, error) {
if id == "" {
return nil, ErrInvalidID(id)
}
ep, err := n.getEndpointFromStore(id)
if err != nil {
return nil, ErrNoSuchEndpoint(id)
}
return ep, nil
}
func (n *network) updateSvcRecord(ep *endpoint, localEps []*endpoint, isAdd bool) {
var ipv6 net.IP
epName := ep.Name()
if iface := ep.Iface(); iface != nil && iface.Address() != nil {
myAliases := ep.MyAliases()
if iface.AddressIPv6() != nil {
ipv6 = iface.AddressIPv6().IP
}
serviceID := ep.svcID
if serviceID == "" {
serviceID = ep.ID()
}
if isAdd {
// If anonymous endpoint has an alias use the first alias
// for ip->name mapping. Not having the reverse mapping
// breaks some apps
if ep.isAnonymous() {
if len(myAliases) > 0 {
n.addSvcRecords(ep.ID(), myAliases[0], serviceID, iface.Address().IP, ipv6, true, "updateSvcRecord")
}
} else {
n.addSvcRecords(ep.ID(), epName, serviceID, iface.Address().IP, ipv6, true, "updateSvcRecord")
}
for _, alias := range myAliases {
n.addSvcRecords(ep.ID(), alias, serviceID, iface.Address().IP, ipv6, false, "updateSvcRecord")
}
} else {
if ep.isAnonymous() {
if len(myAliases) > 0 {
n.deleteSvcRecords(ep.ID(), myAliases[0], serviceID, iface.Address().IP, ipv6, true, "updateSvcRecord")
}
} else {
n.deleteSvcRecords(ep.ID(), epName, serviceID, iface.Address().IP, ipv6, true, "updateSvcRecord")
}
for _, alias := range myAliases {
n.deleteSvcRecords(ep.ID(), alias, serviceID, iface.Address().IP, ipv6, false, "updateSvcRecord")
}
}
}
}
func addIPToName(ipMap setmatrix.SetMatrix, name, serviceID string, ip net.IP) {
reverseIP := netutils.ReverseIP(ip.String())
ipMap.Insert(reverseIP, ipInfo{
name: name,
serviceID: serviceID,
})
}
func delIPToName(ipMap setmatrix.SetMatrix, name, serviceID string, ip net.IP) {
reverseIP := netutils.ReverseIP(ip.String())
ipMap.Remove(reverseIP, ipInfo{
name: name,
serviceID: serviceID,
})
}
func addNameToIP(svcMap setmatrix.SetMatrix, name, serviceID string, epIP net.IP) {
// Since DNS name resolution is case-insensitive, Use the lower-case form
// of the name as the key into svcMap
lowerCaseName := strings.ToLower(name)
svcMap.Insert(lowerCaseName, svcMapEntry{
ip: epIP.String(),
serviceID: serviceID,
})
}
func delNameToIP(svcMap setmatrix.SetMatrix, name, serviceID string, epIP net.IP) {
lowerCaseName := strings.ToLower(name)
svcMap.Remove(lowerCaseName, svcMapEntry{
ip: epIP.String(),
serviceID: serviceID,
})
}
func (n *network) addSvcRecords(eID, name, serviceID string, epIP, epIPv6 net.IP, ipMapUpdate bool, method string) {
// Do not add service names for ingress network as this is a
// routing only network
if n.ingress {
return
}
networkID := n.ID()
logrus.Debugf("%s (%.7s).addSvcRecords(%s, %s, %s, %t) %s sid:%s", eID, networkID, name, epIP, epIPv6, ipMapUpdate, method, serviceID)
c := n.getController()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
sr = svcInfo{
svcMap: setmatrix.NewSetMatrix(),
svcIPv6Map: setmatrix.NewSetMatrix(),
ipMap: setmatrix.NewSetMatrix(),
}
c.svcRecords[networkID] = sr
}
if ipMapUpdate {
addIPToName(sr.ipMap, name, serviceID, epIP)
if epIPv6 != nil {
addIPToName(sr.ipMap, name, serviceID, epIPv6)
}
}
addNameToIP(sr.svcMap, name, serviceID, epIP)
if epIPv6 != nil {
addNameToIP(sr.svcIPv6Map, name, serviceID, epIPv6)
}
}
func (n *network) deleteSvcRecords(eID, name, serviceID string, epIP net.IP, epIPv6 net.IP, ipMapUpdate bool, method string) {
// Do not delete service names from ingress network as this is a
// routing only network
if n.ingress {
return
}
networkID := n.ID()
logrus.Debugf("%s (%.7s).deleteSvcRecords(%s, %s, %s, %t) %s sid:%s ", eID, networkID, name, epIP, epIPv6, ipMapUpdate, method, serviceID)
c := n.getController()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
return
}
if ipMapUpdate {
delIPToName(sr.ipMap, name, serviceID, epIP)
if epIPv6 != nil {
delIPToName(sr.ipMap, name, serviceID, epIPv6)
}
}
delNameToIP(sr.svcMap, name, serviceID, epIP)
if epIPv6 != nil {
delNameToIP(sr.svcIPv6Map, name, serviceID, epIPv6)
}
}
func (n *network) getSvcRecords(ep *endpoint) []etchosts.Record {
n.Lock()
defer n.Unlock()
if ep == nil {
return nil
}
var recs []etchosts.Record
epName := ep.Name()
n.ctrlr.Lock()
defer n.ctrlr.Unlock()
sr, ok := n.ctrlr.svcRecords[n.id]
if !ok || sr.svcMap == nil {
return nil
}
svcMapKeys := sr.svcMap.Keys()
// Loop on service names on this network
for _, k := range svcMapKeys {
if strings.Split(k, ".")[0] == epName {
continue
}
// Get all the IPs associated to this service
mapEntryList, ok := sr.svcMap.Get(k)
if !ok {
// The key got deleted
continue
}
if len(mapEntryList) == 0 {
logrus.Warnf("Found empty list of IP addresses for service %s on network %s (%s)", k, n.name, n.id)
continue
}
recs = append(recs, etchosts.Record{
Hosts: k,
IP: mapEntryList[0].(svcMapEntry).ip,
})
}
return recs
}
func (n *network) getController() *controller {
n.Lock()
defer n.Unlock()
return n.ctrlr
}
func (n *network) ipamAllocate() error {
if n.hasSpecialDriver() {
return nil
}
ipam, _, err := n.getController().getIPAMDriver(n.ipamType)
if err != nil {
return err
}
if n.addrSpace == "" {
if n.addrSpace, err = n.deriveAddressSpace(); err != nil {
return err
}
}
err = n.ipamAllocateVersion(4, ipam)
if err != nil {
return err
}
defer func() {
if err != nil {
n.ipamReleaseVersion(4, ipam)
}
}()
if !n.enableIPv6 {
return nil
}
err = n.ipamAllocateVersion(6, ipam)
return err
}
func (n *network) requestPoolHelper(ipam ipamapi.Ipam, addressSpace, preferredPool, subPool string, options map[string]string, v6 bool) (string, *net.IPNet, map[string]string, error) {
for {
poolID, pool, meta, err := ipam.RequestPool(addressSpace, preferredPool, subPool, options, v6)
if err != nil {
return "", nil, nil, err
}
// If the network belongs to global scope or the pool was
// explicitly chosen or it is invalid, do not perform the overlap check.
if n.Scope() == datastore.GlobalScope || preferredPool != "" || !types.IsIPNetValid(pool) {
return poolID, pool, meta, nil
}
// Check for overlap and if none found, we have found the right pool.
if _, err := netutils.FindAvailableNetwork([]*net.IPNet{pool}); err == nil {
return poolID, pool, meta, nil
}
// Pool obtained in this iteration is
// overlapping. Hold onto the pool and don't release
// it yet, because we don't want ipam to give us back
// the same pool over again. But make sure we still do
// a deferred release when we have either obtained a
// non-overlapping pool or ran out of pre-defined
// pools.
defer func() {
if err := ipam.ReleasePool(poolID); err != nil {
logrus.Warnf("Failed to release overlapping pool %s while returning from pool request helper for network %s", pool, n.Name())
}
}()
// If this is a preferred pool request and the network
// is local scope and there is an overlap, we fail the
// network creation right here. The pool will be
// released in the defer.
if preferredPool != "" {
return "", nil, nil, fmt.Errorf("requested subnet %s overlaps in the host", preferredPool)
}
}
}
func (n *network) ipamAllocateVersion(ipVer int, ipam ipamapi.Ipam) error {
var (
cfgList *[]*IpamConf
infoList *[]*IpamInfo
err error
)
switch ipVer {
case 4:
cfgList = &n.ipamV4Config
infoList = &n.ipamV4Info
case 6:
cfgList = &n.ipamV6Config
infoList = &n.ipamV6Info
default:
return types.InternalErrorf("incorrect ip version passed to ipam allocate: %d", ipVer)
}
if len(*cfgList) == 0 {
*cfgList = []*IpamConf{{}}
}
*infoList = make([]*IpamInfo, len(*cfgList))
logrus.Debugf("Allocating IPv%d pools for network %s (%s)", ipVer, n.Name(), n.ID())
for i, cfg := range *cfgList {
if err = cfg.Validate(); err != nil {
return err
}
d := &IpamInfo{}
(*infoList)[i] = d
d.AddressSpace = n.addrSpace
d.PoolID, d.Pool, d.Meta, err = n.requestPoolHelper(ipam, n.addrSpace, cfg.PreferredPool, cfg.SubPool, n.ipamOptions, ipVer == 6)
if err != nil {
return err
}
defer func() {
if err != nil {
if err := ipam.ReleasePool(d.PoolID); err != nil {
logrus.Warnf("Failed to release address pool %s after failure to create network %s (%s)", d.PoolID, n.Name(), n.ID())
}
}
}()
if gws, ok := d.Meta[netlabel.Gateway]; ok {
if d.Gateway, err = types.ParseCIDR(gws); err != nil {
return types.BadRequestErrorf("failed to parse gateway address (%v) returned by ipam driver: %v", gws, err)
}
}
// If user requested a specific gateway, libnetwork will allocate it
// irrespective of whether ipam driver returned a gateway already.
// If none of the above is true, libnetwork will allocate one.
if cfg.Gateway != "" || d.Gateway == nil {
var gatewayOpts = map[string]string{
ipamapi.RequestAddressType: netlabel.Gateway,
}
if d.Gateway, _, err = ipam.RequestAddress(d.PoolID, net.ParseIP(cfg.Gateway), gatewayOpts); err != nil {
return types.InternalErrorf("failed to allocate gateway (%v): %v", cfg.Gateway, err)
}
}
// Auxiliary addresses must be part of the master address pool
// If they fall into the container addressable pool, libnetwork will reserve them
if cfg.AuxAddresses != nil {
var ip net.IP
d.IPAMData.AuxAddresses = make(map[string]*net.IPNet, len(cfg.AuxAddresses))
for k, v := range cfg.AuxAddresses {
if ip = net.ParseIP(v); ip == nil {
return types.BadRequestErrorf("non parsable secondary ip address (%s:%s) passed for network %s", k, v, n.Name())
}
if !d.Pool.Contains(ip) {
return types.ForbiddenErrorf("auxiliary address: (%s:%s) must belong to the master pool: %s", k, v, d.Pool)
}
// Attempt reservation in the container addressable pool, silent the error if address does not belong to that pool
if d.IPAMData.AuxAddresses[k], _, err = ipam.RequestAddress(d.PoolID, ip, nil); err != nil && err != ipamapi.ErrIPOutOfRange {
return types.InternalErrorf("failed to allocate secondary ip address (%s:%s): %v", k, v, err)
}
}
}
}
return nil
}
func (n *network) ipamRelease() {
if n.hasSpecialDriver() {
return
}
ipam, _, err := n.getController().getIPAMDriver(n.ipamType)
if err != nil {
logrus.Warnf("Failed to retrieve ipam driver to release address pool(s) on delete of network %s (%s): %v", n.Name(), n.ID(), err)
return
}
n.ipamReleaseVersion(4, ipam)
n.ipamReleaseVersion(6, ipam)
}
func (n *network) ipamReleaseVersion(ipVer int, ipam ipamapi.Ipam) {
var infoList *[]*IpamInfo
switch ipVer {
case 4:
infoList = &n.ipamV4Info
case 6:
infoList = &n.ipamV6Info
default:
logrus.Warnf("incorrect ip version passed to ipam release: %d", ipVer)
return
}
if len(*infoList) == 0 {
return
}
logrus.Debugf("releasing IPv%d pools from network %s (%s)", ipVer, n.Name(), n.ID())
for _, d := range *infoList {
if d.Gateway != nil {
if err := ipam.ReleaseAddress(d.PoolID, d.Gateway.IP); err != nil {
logrus.Warnf("Failed to release gateway ip address %s on delete of network %s (%s): %v", d.Gateway.IP, n.Name(), n.ID(), err)
}
}
if d.IPAMData.AuxAddresses != nil {
for k, nw := range d.IPAMData.AuxAddresses {
if d.Pool.Contains(nw.IP) {
if err := ipam.ReleaseAddress(d.PoolID, nw.IP); err != nil && err != ipamapi.ErrIPOutOfRange {
logrus.Warnf("Failed to release secondary ip address %s (%v) on delete of network %s (%s): %v", k, nw.IP, n.Name(), n.ID(), err)
}
}
}
}
if err := ipam.ReleasePool(d.PoolID); err != nil {
logrus.Warnf("Failed to release address pool %s on delete of network %s (%s): %v", d.PoolID, n.Name(), n.ID(), err)
}
}
*infoList = nil
}
func (n *network) getIPInfo(ipVer int) []*IpamInfo {
var info []*IpamInfo
switch ipVer {
case 4:
info = n.ipamV4Info
case 6:
info = n.ipamV6Info
default:
return nil
}
l := make([]*IpamInfo, 0, len(info))
n.Lock()
l = append(l, info...)
n.Unlock()
return l
}
func (n *network) getIPData(ipVer int) []driverapi.IPAMData {
var info []*IpamInfo
switch ipVer {
case 4:
info = n.ipamV4Info
case 6:
info = n.ipamV6Info
default:
return nil
}
l := make([]driverapi.IPAMData, 0, len(info))
n.Lock()
for _, d := range info {
l = append(l, d.IPAMData)
}
n.Unlock()
return l
}
func (n *network) deriveAddressSpace() (string, error) {
local, global, err := n.getController().drvRegistry.IPAMDefaultAddressSpaces(n.ipamType)
if err != nil {
return "", types.NotFoundErrorf("failed to get default address space: %v", err)
}
if n.DataScope() == datastore.GlobalScope {
return global, nil
}
return local, nil
}
func (n *network) Info() NetworkInfo {
return n
}
func (n *network) Peers() []networkdb.PeerInfo {
if !n.Dynamic() {
return []networkdb.PeerInfo{}
}
agent := n.getController().getAgent()
if agent == nil {
return []networkdb.PeerInfo{}
}
return agent.networkDB.Peers(n.ID())
}
func (n *network) DriverOptions() map[string]string {
n.Lock()
defer n.Unlock()
if n.generic != nil {
if m, ok := n.generic[netlabel.GenericData]; ok {
return m.(map[string]string)
}
}
return map[string]string{}
}
func (n *network) Scope() string {
n.Lock()
defer n.Unlock()
return n.scope
}
func (n *network) IpamConfig() (string, map[string]string, []*IpamConf, []*IpamConf) {
n.Lock()
defer n.Unlock()
v4L := make([]*IpamConf, len(n.ipamV4Config))
v6L := make([]*IpamConf, len(n.ipamV6Config))
for i, c := range n.ipamV4Config {
cc := &IpamConf{}
if err := c.CopyTo(cc); err != nil {
logrus.WithError(err).Error("Error copying ipam ipv4 config")
}
v4L[i] = cc
}
for i, c := range n.ipamV6Config {
cc := &IpamConf{}
if err := c.CopyTo(cc); err != nil {
logrus.WithError(err).Debug("Error copying ipam ipv6 config")
}
v6L[i] = cc
}
return n.ipamType, n.ipamOptions, v4L, v6L
}
func (n *network) IpamInfo() ([]*IpamInfo, []*IpamInfo) {
n.Lock()
defer n.Unlock()
v4Info := make([]*IpamInfo, len(n.ipamV4Info))
v6Info := make([]*IpamInfo, len(n.ipamV6Info))
for i, info := range n.ipamV4Info {
ic := &IpamInfo{}
if err := info.CopyTo(ic); err != nil {
logrus.WithError(err).Error("Error copying ipv4 ipam config")
}
v4Info[i] = ic
}
for i, info := range n.ipamV6Info {
ic := &IpamInfo{}
if err := info.CopyTo(ic); err != nil {
logrus.WithError(err).Error("Error copying ipv6 ipam config")
}
v6Info[i] = ic
}
return v4Info, v6Info
}
func (n *network) Internal() bool {
n.Lock()
defer n.Unlock()
return n.internal
}
func (n *network) Attachable() bool {
n.Lock()
defer n.Unlock()
return n.attachable
}
func (n *network) Ingress() bool {
n.Lock()
defer n.Unlock()
return n.ingress
}
func (n *network) Dynamic() bool {
n.Lock()
defer n.Unlock()
return n.dynamic
}
func (n *network) IPv6Enabled() bool {
n.Lock()
defer n.Unlock()
return n.enableIPv6
}
func (n *network) ConfigFrom() string {
n.Lock()
defer n.Unlock()
return n.configFrom
}
func (n *network) ConfigOnly() bool {
n.Lock()
defer n.Unlock()
return n.configOnly
}
func (n *network) Labels() map[string]string {
n.Lock()
defer n.Unlock()
var lbls = make(map[string]string, len(n.labels))
for k, v := range n.labels {
lbls[k] = v
}
return lbls
}
func (n *network) TableEventRegister(tableName string, objType driverapi.ObjectType) error {
if !driverapi.IsValidType(objType) {
return fmt.Errorf("invalid object type %v in registering table, %s", objType, tableName)
}
t := networkDBTable{
name: tableName,
objType: objType,
}
n.Lock()
defer n.Unlock()
n.driverTables = append(n.driverTables, t)
return nil
}
func (n *network) UpdateIpamConfig(ipV4Data []driverapi.IPAMData) {
ipamV4Config := make([]*IpamConf, len(ipV4Data))
for i, data := range ipV4Data {
ic := &IpamConf{}
ic.PreferredPool = data.Pool.String()
ic.Gateway = data.Gateway.IP.String()
ipamV4Config[i] = ic
}
n.Lock()
defer n.Unlock()
n.ipamV4Config = ipamV4Config
}
// Special drivers are ones which do not need to perform any network plumbing
func (n *network) hasSpecialDriver() bool {
return n.Type() == "host" || n.Type() == "null"
}
func (n *network) hasLoadBalancerEndpoint() bool {
return len(n.loadBalancerIP) != 0
}
func (n *network) ResolveName(req string, ipType int) ([]net.IP, bool) {
var ipv6Miss bool
c := n.getController()
networkID := n.ID()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
return nil, false
}
req = strings.TrimSuffix(req, ".")
req = strings.ToLower(req)
ipSet, ok := sr.svcMap.Get(req)
if ipType == types.IPv6 {
// If the name resolved to v4 address then its a valid name in
// the docker network domain. If the network is not v6 enabled
// set ipv6Miss to filter the DNS query from going to external
// resolvers.
if ok && !n.enableIPv6 {
ipv6Miss = true
}
ipSet, ok = sr.svcIPv6Map.Get(req)
}
if ok && len(ipSet) > 0 {
// this map is to avoid IP duplicates, this can happen during a transition period where 2 services are using the same IP
noDup := make(map[string]bool)
var ipLocal []net.IP
for _, ip := range ipSet {
if _, dup := noDup[ip.(svcMapEntry).ip]; !dup {
noDup[ip.(svcMapEntry).ip] = true
ipLocal = append(ipLocal, net.ParseIP(ip.(svcMapEntry).ip))
}
}
return ipLocal, ok
}
return nil, ipv6Miss
}
func (n *network) HandleQueryResp(name string, ip net.IP) {
networkID := n.ID()
c := n.getController()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
return
}
ipStr := netutils.ReverseIP(ip.String())
// If an object with extResolver == true is already in the set this call will fail
// but anyway it means that has already been inserted before
if ok, _ := sr.ipMap.Contains(ipStr, ipInfo{name: name}); ok {
sr.ipMap.Remove(ipStr, ipInfo{name: name})
sr.ipMap.Insert(ipStr, ipInfo{name: name, extResolver: true})
}
}
func (n *network) ResolveIP(ip string) string {
networkID := n.ID()
c := n.getController()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
return ""
}
nwName := n.Name()
elemSet, ok := sr.ipMap.Get(ip)
if !ok || len(elemSet) == 0 {
return ""
}
// NOTE it is possible to have more than one element in the Set, this will happen
// because of interleave of different events from different sources (local container create vs
// network db notifications)
// In such cases the resolution will be based on the first element of the set, and can vary
// during the system stabilitation
elem, ok := elemSet[0].(ipInfo)
if !ok {
setStr, b := sr.ipMap.String(ip)
logrus.Errorf("expected set of ipInfo type for key %s set:%t %s", ip, b, setStr)
return ""
}
if elem.extResolver {
return ""
}
return elem.name + "." + nwName
}
func (n *network) ResolveService(name string) ([]*net.SRV, []net.IP) {
c := n.getController()
srv := []*net.SRV{}
ip := []net.IP{}
logrus.Debugf("Service name To resolve: %v", name)
// There are DNS implementations that allow SRV queries for names not in
// the format defined by RFC 2782. Hence specific validations checks are
// not done
parts := strings.Split(name, ".")
if len(parts) < 3 {
return nil, nil
}
portName := parts[0]
proto := parts[1]
svcName := strings.Join(parts[2:], ".")
networkID := n.ID()
c.Lock()
defer c.Unlock()
sr, ok := c.svcRecords[networkID]
if !ok {
return nil, nil
}
svcs, ok := sr.service[svcName]
if !ok {
return nil, nil
}
for _, svc := range svcs {
if svc.portName != portName {
continue
}
if svc.proto != proto {
continue
}
for _, t := range svc.target {
srv = append(srv,
&net.SRV{
Target: t.name,
Port: t.port,
})
ip = append(ip, t.ip)
}
}
return srv, ip
}
func (n *network) ExecFunc(f func()) error {
return types.NotImplementedErrorf("ExecFunc not supported by network")
}
func (n *network) NdotsSet() bool {
return false
}
// config-only network is looked up by name
func (c *controller) getConfigNetwork(name string) (*network, error) {
var n Network
s := func(current Network) bool {
if current.Info().ConfigOnly() && current.Name() == name {
n = current
return true
}
return false
}
c.WalkNetworks(s)
if n == nil {
return nil, types.NotFoundErrorf("configuration network %q not found", name)
}
return n.(*network), nil
}
func (n *network) lbSandboxName() string {
name := "lb-" + n.name
if n.ingress {
name = n.name + "-sbox"
}
return name
}
func (n *network) lbEndpointName() string {
return n.name + "-endpoint"
}
func (n *network) createLoadBalancerSandbox() (retErr error) {
sandboxName := n.lbSandboxName()
// Mark the sandbox to be a load balancer
sbOptions := []SandboxOption{OptionLoadBalancer(n.id)}
if n.ingress {
sbOptions = append(sbOptions, OptionIngress())
}
sb, err := n.ctrlr.NewSandbox(sandboxName, sbOptions...)
if err != nil {
return err
}
defer func() {
if retErr != nil {
if e := n.ctrlr.SandboxDestroy(sandboxName); e != nil {
logrus.Warnf("could not delete sandbox %s on failure on failure (%v): %v", sandboxName, retErr, e)
}
}
}()
endpointName := n.lbEndpointName()
epOptions := []EndpointOption{
CreateOptionIpam(n.loadBalancerIP, nil, nil, nil),
CreateOptionLoadBalancer(),
}
if n.hasLoadBalancerEndpoint() && !n.ingress {
// Mark LB endpoints as anonymous so they don't show up in DNS
epOptions = append(epOptions, CreateOptionAnonymous())
}
ep, err := n.createEndpoint(endpointName, epOptions...)
if err != nil {
return err
}
defer func() {
if retErr != nil {
if e := ep.Delete(true); e != nil {
logrus.Warnf("could not delete endpoint %s on failure on failure (%v): %v", endpointName, retErr, e)
}
}
}()
if err := ep.Join(sb, nil); err != nil {
return err
}
return sb.EnableService()
}
func (n *network) deleteLoadBalancerSandbox() error {
n.Lock()
c := n.ctrlr
name := n.name
n.Unlock()
sandboxName := n.lbSandboxName()
endpointName := n.lbEndpointName()
endpoint, err := n.EndpointByName(endpointName)
if err != nil {
logrus.Warnf("Failed to find load balancer endpoint %s on network %s: %v", endpointName, name, err)
} else {
info := endpoint.Info()
if info != nil {
sb := info.Sandbox()
if sb != nil {
if err := sb.DisableService(); err != nil {
logrus.Warnf("Failed to disable service on sandbox %s: %v", sandboxName, err)
// Ignore error and attempt to delete the load balancer endpoint
}
}
}
if err := endpoint.Delete(true); err != nil {
logrus.Warnf("Failed to delete endpoint %s (%s) in %s: %v", endpoint.Name(), endpoint.ID(), sandboxName, err)
// Ignore error and attempt to delete the sandbox.
}
}
if err := c.SandboxDestroy(sandboxName); err != nil {
return fmt.Errorf("Failed to delete %s sandbox: %v", sandboxName, err)
}
return nil
}