consul/agent/structs/config_entry_discoverychain.go

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package structs
import (
"encoding/json"
"fmt"
"math"
"net/http"
"regexp"
"sort"
"strconv"
"strings"
"time"
"github.com/hashicorp/go-bexpr"
"github.com/mitchellh/copystructure"
"github.com/mitchellh/hashstructure"
"github.com/hashicorp/consul/acl"
"github.com/hashicorp/consul/agent/cache"
"github.com/hashicorp/consul/lib"
"github.com/hashicorp/consul/lib/maps"
)
const (
// Names of Envoy's LB policies
LBPolicyMaglev = "maglev"
LBPolicyRingHash = "ring_hash"
LBPolicyRandom = "random"
LBPolicyLeastRequest = "least_request"
LBPolicyRoundRobin = "round_robin"
// Names of Envoy's LB policies
HashPolicyCookie = "cookie"
HashPolicyHeader = "header"
HashPolicyQueryParam = "query_parameter"
)
2020-09-02 21:49:03 +00:00
var (
validLBPolicies = map[string]bool{
"": true,
LBPolicyRandom: true,
LBPolicyRoundRobin: true,
LBPolicyLeastRequest: true,
LBPolicyRingHash: true,
LBPolicyMaglev: true,
}
validHashPolicies = map[string]bool{
HashPolicyHeader: true,
HashPolicyCookie: true,
HashPolicyQueryParam: true,
}
)
// ServiceRouterConfigEntry defines L7 (e.g. http) routing rules for a named
// service exposed in Connect.
//
// This config entry represents the topmost part of the discovery chain. Only
// one router config will be used per resolved discovery chain and is not
// otherwise discovered recursively (unlike splitter and resolver config
// entries).
//
// Router config entries will be restricted to only services that define their
// protocol as http-based (in centralized configuration).
type ServiceRouterConfigEntry struct {
Kind string
Name string
// Routes is the list of routes to consider when processing L7 requests.
// The first rule to match in the list is terminal and stops further
// evaluation.
//
// Traffic that fails to match any of the provided routes will be routed to
// the default service.
Routes []ServiceRoute
Meta map[string]string `json:",omitempty"`
acl.EnterpriseMeta `hcl:",squash" mapstructure:",squash"`
RaftIndex
}
func (e *ServiceRouterConfigEntry) GetKind() string {
return ServiceRouter
}
func (e *ServiceRouterConfigEntry) GetName() string {
if e == nil {
return ""
}
return e.Name
}
func (e *ServiceRouterConfigEntry) GetMeta() map[string]string {
if e == nil {
return nil
}
return e.Meta
}
func (e *ServiceRouterConfigEntry) Normalize() error {
if e == nil {
return fmt.Errorf("config entry is nil")
}
e.Kind = ServiceRouter
e.EnterpriseMeta.Normalize()
for _, route := range e.Routes {
if route.Match == nil || route.Match.HTTP == nil {
continue
}
httpMatch := route.Match.HTTP
for j := 0; j < len(httpMatch.Methods); j++ {
httpMatch.Methods[j] = strings.ToUpper(httpMatch.Methods[j])
}
if route.Destination != nil && route.Destination.Namespace == "" {
route.Destination.Namespace = e.EnterpriseMeta.NamespaceOrEmpty()
}
if route.Destination != nil && route.Destination.Partition == "" {
route.Destination.Partition = e.EnterpriseMeta.PartitionOrEmpty()
}
}
return nil
}
func (e *ServiceRouterConfigEntry) Validate() error {
if e.Name == "" {
return fmt.Errorf("Name is required")
}
if err := validateConfigEntryMeta(e.Meta); err != nil {
return err
}
// Technically you can have no explicit routes at all where just the
// catch-all is configured for you, but at that point maybe you should just
// delete it so it will default?
for i, route := range e.Routes {
eligibleForPrefixRewrite := false
if route.Match != nil && route.Match.HTTP != nil {
pathParts := 0
if route.Match.HTTP.PathExact != "" {
eligibleForPrefixRewrite = true
pathParts++
if !strings.HasPrefix(route.Match.HTTP.PathExact, "/") {
return fmt.Errorf("Route[%d] PathExact doesn't start with '/': %q", i, route.Match.HTTP.PathExact)
}
}
if route.Match.HTTP.PathPrefix != "" {
eligibleForPrefixRewrite = true
pathParts++
if !strings.HasPrefix(route.Match.HTTP.PathPrefix, "/") {
return fmt.Errorf("Route[%d] PathPrefix doesn't start with '/': %q", i, route.Match.HTTP.PathPrefix)
}
}
if route.Match.HTTP.PathRegex != "" {
pathParts++
}
if pathParts > 1 {
return fmt.Errorf("Route[%d] should only contain at most one of PathExact, PathPrefix, or PathRegex", i)
}
for j, hdr := range route.Match.HTTP.Header {
if hdr.Name == "" {
return fmt.Errorf("Route[%d] Header[%d] missing required Name field", i, j)
}
hdrParts := 0
if hdr.Present {
hdrParts++
}
if hdr.Exact != "" {
hdrParts++
}
if hdr.Regex != "" {
hdrParts++
}
if hdr.Prefix != "" {
hdrParts++
}
if hdr.Suffix != "" {
hdrParts++
}
if hdrParts != 1 {
return fmt.Errorf("Route[%d] Header[%d] should only contain one of Present, Exact, Prefix, Suffix, or Regex", i, j)
}
}
for j, qm := range route.Match.HTTP.QueryParam {
if qm.Name == "" {
return fmt.Errorf("Route[%d] QueryParam[%d] missing required Name field", i, j)
}
qmParts := 0
if qm.Present {
qmParts++
}
if qm.Exact != "" {
qmParts++
}
if qm.Regex != "" {
qmParts++
}
if qmParts != 1 {
return fmt.Errorf("Route[%d] QueryParam[%d] should only contain one of Present, Exact, or Regex", i, j)
}
}
if len(route.Match.HTTP.Methods) > 0 {
found := make(map[string]struct{})
for _, m := range route.Match.HTTP.Methods {
if !isValidHTTPMethod(m) {
return fmt.Errorf("Route[%d] Methods contains an invalid method %q", i, m)
}
if _, ok := found[m]; ok {
return fmt.Errorf("Route[%d] Methods contains %q more than once", i, m)
}
found[m] = struct{}{}
}
}
}
if route.Destination != nil {
if route.Destination.PrefixRewrite != "" && !eligibleForPrefixRewrite {
return fmt.Errorf("Route[%d] cannot make use of PrefixRewrite without configuring either PathExact or PathPrefix", i)
}
for _, r := range route.Destination.RetryOn {
if !isValidRetryCondition(r) {
return fmt.Errorf("Route[%d] contains an invalid retry condition: %q", i, r)
}
}
}
}
return nil
}
func isValidHTTPMethod(method string) bool {
switch method {
case http.MethodGet,
http.MethodHead,
http.MethodPost,
http.MethodPut,
http.MethodPatch,
http.MethodDelete,
http.MethodConnect,
http.MethodOptions,
http.MethodTrace:
return true
default:
return false
}
}
func isValidRetryCondition(retryOn string) bool {
switch retryOn {
case "5xx",
"gateway-error",
"reset",
"connect-failure",
"envoy-ratelimited",
"retriable-4xx",
"refused-stream",
"cancelled",
"deadline-exceeded",
"internal",
"resource-exhausted",
"unavailable":
return true
default:
return false
}
}
func (e *ServiceRouterConfigEntry) CanRead(authz acl.Authorizer) error {
return canReadDiscoveryChain(e, authz)
}
func (e *ServiceRouterConfigEntry) CanWrite(authz acl.Authorizer) error {
return canWriteDiscoveryChain(e, authz)
}
func (e *ServiceRouterConfigEntry) GetRaftIndex() *RaftIndex {
if e == nil {
return &RaftIndex{}
}
return &e.RaftIndex
}
func (e *ServiceRouterConfigEntry) ListRelatedServices() []ServiceID {
found := make(map[ServiceID]struct{})
// We always inject a default catch-all route to the same service as the router.
svcID := NewServiceID(e.Name, &e.EnterpriseMeta)
found[svcID] = struct{}{}
for _, route := range e.Routes {
if route.Destination != nil {
destID := NewServiceID(defaultIfEmpty(route.Destination.Service, e.Name), route.Destination.GetEnterpriseMeta(&e.EnterpriseMeta))
if destID != svcID {
found[destID] = struct{}{}
}
}
}
if len(found) == 0 {
return nil
}
out := make([]ServiceID, 0, len(found))
for svc := range found {
out = append(out, svc)
}
sort.Slice(out, func(i, j int) bool {
return out[i].EnterpriseMeta.LessThan(&out[j].EnterpriseMeta) ||
out[i].ID < out[j].ID
})
return out
}
func (e *ServiceRouterConfigEntry) GetEnterpriseMeta() *acl.EnterpriseMeta {
if e == nil {
return nil
}
return &e.EnterpriseMeta
}
// ServiceRoute is a single routing rule that routes traffic to the destination
// when the match criteria applies.
type ServiceRoute struct {
Match *ServiceRouteMatch `json:",omitempty"`
Destination *ServiceRouteDestination `json:",omitempty"`
}
// ServiceRouteMatch is a set of criteria that can match incoming L7 requests.
type ServiceRouteMatch struct {
HTTP *ServiceRouteHTTPMatch `json:",omitempty"`
// If we have non-http match criteria for other protocols in the future
// (gRPC, redis, etc) they can go here.
}
func (m *ServiceRouteMatch) IsEmpty() bool {
return m.HTTP == nil || m.HTTP.IsEmpty()
}
// ServiceRouteHTTPMatch is a set of http-specific match criteria.
type ServiceRouteHTTPMatch struct {
PathExact string `json:",omitempty" alias:"path_exact"`
PathPrefix string `json:",omitempty" alias:"path_prefix"`
PathRegex string `json:",omitempty" alias:"path_regex"`
Header []ServiceRouteHTTPMatchHeader `json:",omitempty"`
QueryParam []ServiceRouteHTTPMatchQueryParam `json:",omitempty" alias:"query_param"`
Methods []string `json:",omitempty"`
}
func (m *ServiceRouteHTTPMatch) IsEmpty() bool {
return m.PathExact == "" &&
m.PathPrefix == "" &&
m.PathRegex == "" &&
len(m.Header) == 0 &&
len(m.QueryParam) == 0 &&
len(m.Methods) == 0
}
type ServiceRouteHTTPMatchHeader struct {
Name string
Present bool `json:",omitempty"`
Exact string `json:",omitempty"`
Prefix string `json:",omitempty"`
Suffix string `json:",omitempty"`
Regex string `json:",omitempty"`
Invert bool `json:",omitempty"`
}
type ServiceRouteHTTPMatchQueryParam struct {
Name string
Present bool `json:",omitempty"`
Exact string `json:",omitempty"`
Regex string `json:",omitempty"`
}
// ServiceRouteDestination describes how to proxy the actual matching request
// to a service.
type ServiceRouteDestination struct {
// Service is the service to resolve instead of the default service. If
// empty then the default discovery chain service name is used.
Service string `json:",omitempty"`
// ServiceSubset is a named subset of the given service to resolve instead
// of one defined as that service's DefaultSubset. If empty the default
// subset is used.
//
// If this field is specified then this route is ineligible for further
// splitting.
ServiceSubset string `json:",omitempty" alias:"service_subset"`
// Namespace is the namespace to resolve the service from instead of the
// current namespace. If empty the current namespace is assumed.
//
// If this field is specified then this route is ineligible for further
// splitting.
Namespace string `json:",omitempty"`
// Partition is the partition to resolve the service from instead of the
// current partition. If empty the current partition is assumed.
//
// If this field is specified then this route is ineligible for further
// splitting.
Partition string `json:",omitempty"`
// PrefixRewrite allows for the proxied request to have its matching path
// prefix modified before being sent to the destination. Described more
// below in the envoy implementation section.
PrefixRewrite string `json:",omitempty" alias:"prefix_rewrite"`
// RequestTimeout is the total amount of time permitted for the entire
// downstream request (and retries) to be processed.
RequestTimeout time.Duration `json:",omitempty" alias:"request_timeout"`
// IdleTimeout is The total amount of time permitted for the request stream
// to be idle
IdleTimeout time.Duration `json:",omitempty" alias:"idle_timeout"`
// NumRetries is the number of times to retry the request when a retryable
// result occurs. This seems fairly proxy agnostic.
NumRetries uint32 `json:",omitempty" alias:"num_retries"`
// RetryOnConnectFailure allows for connection failure errors to trigger a
// retry. This should be expressible in other proxies as it's just a layer
// 4 failure bubbling up to layer 7.
RetryOnConnectFailure bool `json:",omitempty" alias:"retry_on_connect_failure"`
// RetryOn allows setting envoy specific conditions when a request should
// be automatically retried.
RetryOn []string `json:",omitempty" alias:"retry_on"`
// RetryOnStatusCodes is a flat list of http response status codes that are
// eligible for retry. This again should be feasible in any reasonable proxy.
RetryOnStatusCodes []uint32 `json:",omitempty" alias:"retry_on_status_codes"`
// Allow HTTP header manipulation to be configured.
RequestHeaders *HTTPHeaderModifiers `json:",omitempty" alias:"request_headers"`
ResponseHeaders *HTTPHeaderModifiers `json:",omitempty" alias:"response_headers"`
}
func (e *ServiceRouteDestination) MarshalJSON() ([]byte, error) {
type Alias ServiceRouteDestination
exported := &struct {
RequestTimeout string `json:",omitempty"`
IdleTimeout string `json:",omitempty"`
*Alias
}{
RequestTimeout: e.RequestTimeout.String(),
IdleTimeout: e.IdleTimeout.String(),
Alias: (*Alias)(e),
}
if e.RequestTimeout == 0 {
exported.RequestTimeout = ""
}
if e.IdleTimeout == 0 {
exported.IdleTimeout = ""
}
return json.Marshal(exported)
}
func (e *ServiceRouteDestination) UnmarshalJSON(data []byte) error {
type Alias ServiceRouteDestination
aux := &struct {
RequestTimeout string
IdleTimeout string
*Alias
}{
Alias: (*Alias)(e),
}
if err := lib.UnmarshalJSON(data, &aux); err != nil {
return err
}
var err error
if aux.RequestTimeout != "" {
if e.RequestTimeout, err = time.ParseDuration(aux.RequestTimeout); err != nil {
return err
}
}
if aux.IdleTimeout != "" {
if e.IdleTimeout, err = time.ParseDuration(aux.IdleTimeout); err != nil {
return err
}
}
return nil
}
func (d *ServiceRouteDestination) HasRetryFeatures() bool {
return d.NumRetries > 0 || d.RetryOnConnectFailure || len(d.RetryOnStatusCodes) > 0 || len(d.RetryOn) > 0
}
// ServiceSplitterConfigEntry defines how incoming requests are split across
// different subsets of a single service (like during staged canary rollouts),
// or perhaps across different services (like during a v2 rewrite or other type
// of codebase migration).
//
// This config entry represents the next hop of the discovery chain after
// routing. If no splitter config is defined the chain assumes 100% of traffic
// goes to the default service and discovery continues on to the resolution
// hop.
//
// Splitter configs are recursively collected while walking the discovery
// chain.
//
// Splitter config entries will be restricted to only services that define
// their protocol as http-based (in centralized configuration).
type ServiceSplitterConfigEntry struct {
Kind string
Name string
// Splits is the configurations for the details of the traffic splitting.
//
// The sum of weights across all splits must add up to 100.
//
// If the split is within epsilon of 100 then the remainder is attributed
// to the FIRST split.
Splits []ServiceSplit
Meta map[string]string `json:",omitempty"`
acl.EnterpriseMeta `hcl:",squash" mapstructure:",squash"`
RaftIndex
}
func (e *ServiceSplitterConfigEntry) GetKind() string {
return ServiceSplitter
}
func (e *ServiceSplitterConfigEntry) GetName() string {
if e == nil {
return ""
}
return e.Name
}
func (e *ServiceSplitterConfigEntry) GetMeta() map[string]string {
if e == nil {
return nil
}
return e.Meta
}
func (e *ServiceSplitterConfigEntry) Normalize() error {
if e == nil {
return fmt.Errorf("config entry is nil")
}
e.Kind = ServiceSplitter
// This slightly massages inputs to enforce that the smallest representable
// weight is 1/10000 or .01%
e.EnterpriseMeta.Normalize()
if len(e.Splits) > 0 {
for i, split := range e.Splits {
if split.Namespace == "" {
split.Namespace = e.EnterpriseMeta.NamespaceOrDefault()
}
e.Splits[i].Weight = NormalizeServiceSplitWeight(split.Weight)
}
}
return nil
}
func NormalizeServiceSplitWeight(weight float32) float32 {
weightScaled := scaleWeight(weight)
return float32(weightScaled) / 100.0
}
func (e *ServiceSplitterConfigEntry) Validate() error {
if e.Name == "" {
return fmt.Errorf("Name is required")
}
if len(e.Splits) == 0 {
return fmt.Errorf("no splits configured")
}
if err := validateConfigEntryMeta(e.Meta); err != nil {
return err
}
const maxScaledWeight = 100 * 100
copyAsKey := func(s ServiceSplit) ServiceSplit {
s.Weight = 0
return s
}
// Make sure we didn't refer to the same thing twice.
found := make(map[ServiceSplit]struct{})
for _, split := range e.Splits {
splitKey := copyAsKey(split)
if splitKey.Service == "" {
splitKey.Service = e.Name
}
if _, ok := found[splitKey]; ok {
return fmt.Errorf(
"split destination occurs more than once: service=%q, subset=%q, namespace=%q, partition=%q",
splitKey.Service, splitKey.ServiceSubset, splitKey.Namespace, splitKey.Partition,
)
}
found[splitKey] = struct{}{}
}
sumScaled := 0
for _, split := range e.Splits {
sumScaled += scaleWeight(split.Weight)
}
if sumScaled != maxScaledWeight {
return fmt.Errorf("the sum of all split weights must be 100, not %f", float32(sumScaled)/100)
}
return nil
}
// scaleWeight assumes the input is a value between 0 and 100 representing
// shares out of a percentile range. The function will convert to a unit
// representing 0.01% units in the same manner as you may convert $0.98 to 98
// cents.
func scaleWeight(v float32) int {
return int(math.Round(float64(v * 100.0)))
}
func (e *ServiceSplitterConfigEntry) CanRead(authz acl.Authorizer) error {
return canReadDiscoveryChain(e, authz)
}
func (e *ServiceSplitterConfigEntry) CanWrite(authz acl.Authorizer) error {
return canWriteDiscoveryChain(e, authz)
}
func (e *ServiceSplitterConfigEntry) GetRaftIndex() *RaftIndex {
if e == nil {
return &RaftIndex{}
}
return &e.RaftIndex
}
func (e *ServiceSplitterConfigEntry) GetEnterpriseMeta() *acl.EnterpriseMeta {
if e == nil {
return nil
}
return &e.EnterpriseMeta
}
func (e *ServiceSplitterConfigEntry) ListRelatedServices() []ServiceID {
found := make(map[ServiceID]struct{})
svcID := NewServiceID(e.Name, &e.EnterpriseMeta)
for _, split := range e.Splits {
splitID := NewServiceID(defaultIfEmpty(split.Service, e.Name), split.GetEnterpriseMeta(&e.EnterpriseMeta))
if splitID != svcID {
found[splitID] = struct{}{}
}
}
if len(found) == 0 {
return nil
}
out := make([]ServiceID, 0, len(found))
for svc := range found {
out = append(out, svc)
}
sort.Slice(out, func(i, j int) bool {
return out[i].EnterpriseMeta.LessThan(&out[j].EnterpriseMeta) ||
out[i].ID < out[j].ID
})
return out
}
// ServiceSplit defines how much traffic to send to which set of service
// instances during a traffic split.
type ServiceSplit struct {
// A value between 0 and 100 reflecting what portion of traffic should be
// directed to this split.
//
// The smallest representable weight is 1/10000 or .01%
//
// If the split is within epsilon of 100 then the remainder is attributed
// to the FIRST split.
Weight float32
// Service is the service to resolve instead of the default (optional).
Service string `json:",omitempty"`
// ServiceSubset is a named subset of the given service to resolve instead
// of one defined as that service's DefaultSubset. If empty the default
// subset is used (optional).
//
// If this field is specified then this route is ineligible for further
// splitting.
ServiceSubset string `json:",omitempty" alias:"service_subset"`
// Namespace is the namespace to resolve the service from instead of the
// current namespace. If empty the current namespace is assumed (optional).
//
// If this field is specified then this route is ineligible for further
// splitting.
Namespace string `json:",omitempty"`
// Partition is the partition to resolve the service from instead of the
// current partition. If empty the current partition is assumed (optional).
//
// If this field is specified then this route is ineligible for further
// splitting.
Partition string `json:",omitempty"`
// NOTE: Any configuration added to Splits that needs to be passed to the
// proxy needs special handling MergeParent below.
// Allow HTTP header manipulation to be configured.
RequestHeaders *HTTPHeaderModifiers `json:",omitempty" alias:"request_headers"`
ResponseHeaders *HTTPHeaderModifiers `json:",omitempty" alias:"response_headers"`
}
// MergeParent is called by the discovery chain compiler when a split directs to
// another splitter. We refer to the first ServiceSplit as the parent and the
// ServiceSplits of the second splitter as its children. The parent ends up
// "flattened" by the compiler, i.e. replaced with its children recursively with
// the weights modified as necessary.
//
// Since the parent is never included in the output, any request processing
// config attached to it (e.g. header manipulation) would be lost and not take
// affect when splitters direct to other splitters. To avoid that, we define a
// MergeParent operation which is called by the compiler on each child split
// during flattening. It must merge any request processing configuration from
// the passed parent into the child such that the end result is equivalent to a
// request first passing through the parent and then the child. Response
// handling must occur as if the request first passed through the through the
// child to the parent.
//
// MergeDefaults leaves both s and parent unchanged and returns a deep copy to
// avoid confusing issues where config changes after being compiled.
func (s *ServiceSplit) MergeParent(parent *ServiceSplit) (*ServiceSplit, error) {
if s == nil && parent == nil {
return nil, nil
}
var err error
var copy ServiceSplit
if s == nil {
copy = *parent
copy.RequestHeaders, err = parent.RequestHeaders.Clone()
if err != nil {
return nil, err
}
copy.ResponseHeaders, err = parent.ResponseHeaders.Clone()
if err != nil {
return nil, err
}
return &copy, nil
} else {
copy = *s
}
var parentReq *HTTPHeaderModifiers
if parent != nil {
parentReq = parent.RequestHeaders
}
// Merge any request handling from parent _unless_ it's overridden by us.
copy.RequestHeaders, err = MergeHTTPHeaderModifiers(parentReq, s.RequestHeaders)
if err != nil {
return nil, err
}
var parentResp *HTTPHeaderModifiers
if parent != nil {
parentResp = parent.ResponseHeaders
}
// Merge any response handling. Note that we allow parent to override this
// time since responses flow the other way so the unflattened behavior would
// be that the parent processing happens _after_ ours potentially overriding
// it.
copy.ResponseHeaders, err = MergeHTTPHeaderModifiers(s.ResponseHeaders, parentResp)
if err != nil {
return nil, err
}
return &copy, nil
}
// ServiceResolverConfigEntry defines which instances of a service should
// satisfy discovery requests for a given named service.
//
// This config entry represents the next hop of the discovery chain after
// splitting. If no resolver config is defined the chain assumes 100% of
// traffic goes to the healthy instances of the default service in the current
// datacenter+namespace and discovery terminates.
//
// Resolver configs are recursively collected while walking the chain.
//
// Resolver config entries will be valid for services defined with any protocol
// (in centralized configuration).
type ServiceResolverConfigEntry struct {
Kind string
Name string
// DefaultSubset is the subset to use when no explicit subset is
// requested. If empty the unnamed subset is used.
DefaultSubset string `json:",omitempty" alias:"default_subset"`
// Subsets is a map of subset name to subset definition for all
// usable named subsets of this service. The map key is the name
// of the subset and all names must be valid DNS subdomain elements
// so they can be used in SNI FQDN headers for the Connect Gateways
// feature.
//
// This may be empty, in which case only the unnamed default subset
// will be usable.
Subsets map[string]ServiceResolverSubset `json:",omitempty"`
// Redirect is a service/subset/datacenter/namespace to resolve
// instead of the requested service (optional).
//
// When configured, all occurrences of this resolver in any discovery
// chain evaluation will be substituted for the supplied redirect
// EXCEPT when the redirect has already been applied.
//
// When substituting the supplied redirect into the discovery chain
// all other fields beside Kind/Name/Redirect will be ignored.
Redirect *ServiceResolverRedirect `json:",omitempty"`
// Failover controls when and how to reroute traffic to an alternate pool
// of service instances.
//
// The map is keyed by the service subset it applies to, and the special
// string "*" is a wildcard that applies to any subset not otherwise
// specified here.
Failover map[string]ServiceResolverFailover `json:",omitempty"`
// ConnectTimeout is the timeout for establishing new network connections
// to this service.
ConnectTimeout time.Duration `json:",omitempty" alias:"connect_timeout"`
// RequestTimeout is the timeout for an HTTP request to complete before
// the connection is automatically terminated. If unspecified, defaults
// to 15 seconds.
RequestTimeout time.Duration `json:",omitempty" alias:"request_timeout"`
2020-08-23 00:05:09 +00:00
// LoadBalancer determines the load balancing policy and configuration for services
// issuing requests to this upstream service.
LoadBalancer *LoadBalancer `json:",omitempty" alias:"load_balancer"`
2020-08-23 00:05:09 +00:00
Meta map[string]string `json:",omitempty"`
acl.EnterpriseMeta `hcl:",squash" mapstructure:",squash"`
RaftIndex
}
func (e *ServiceResolverConfigEntry) RelatedPeers() []string {
peers := make(map[string]struct{})
if r := e.Redirect; r != nil && r.Peer != "" {
peers[r.Peer] = struct{}{}
}
if e.Failover != nil {
for _, f := range e.Failover {
for _, t := range f.Targets {
if t.Peer != "" {
peers[t.Peer] = struct{}{}
}
}
}
}
return maps.SliceOfKeys(peers)
}
func (e *ServiceResolverConfigEntry) MarshalJSON() ([]byte, error) {
type Alias ServiceResolverConfigEntry
exported := &struct {
ConnectTimeout string `json:",omitempty"`
RequestTimeout string `json:",omitempty"`
*Alias
}{
ConnectTimeout: e.ConnectTimeout.String(),
RequestTimeout: e.RequestTimeout.String(),
Alias: (*Alias)(e),
}
if e.ConnectTimeout == 0 {
exported.ConnectTimeout = ""
}
if e.RequestTimeout == 0 {
exported.RequestTimeout = ""
}
return json.Marshal(exported)
}
func (e *ServiceResolverConfigEntry) UnmarshalJSON(data []byte) error {
type Alias ServiceResolverConfigEntry
aux := &struct {
ConnectTimeout string
RequestTimeout string
*Alias
}{
Alias: (*Alias)(e),
}
if err := lib.UnmarshalJSON(data, &aux); err != nil {
return err
}
var err error
if aux.ConnectTimeout != "" {
if e.ConnectTimeout, err = time.ParseDuration(aux.ConnectTimeout); err != nil {
return err
}
}
if aux.RequestTimeout != "" {
if e.RequestTimeout, err = time.ParseDuration(aux.RequestTimeout); err != nil {
return err
}
}
return nil
}
func (e *ServiceResolverConfigEntry) SubsetExists(name string) bool {
if name == "" {
return true
}
if len(e.Subsets) == 0 {
return false
}
_, ok := e.Subsets[name]
return ok
}
func (e *ServiceResolverConfigEntry) IsDefault() bool {
return e.DefaultSubset == "" &&
len(e.Subsets) == 0 &&
e.Redirect == nil &&
len(e.Failover) == 0 &&
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e.ConnectTimeout == 0 &&
e.RequestTimeout == 0 &&
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e.LoadBalancer == nil
}
func (e *ServiceResolverConfigEntry) GetKind() string {
return ServiceResolver
}
func (e *ServiceResolverConfigEntry) GetName() string {
if e == nil {
return ""
}
return e.Name
}
func (e *ServiceResolverConfigEntry) GetMeta() map[string]string {
if e == nil {
return nil
}
return e.Meta
}
func (e *ServiceResolverConfigEntry) Normalize() error {
if e == nil {
return fmt.Errorf("config entry is nil")
}
e.Kind = ServiceResolver
e.EnterpriseMeta.Normalize()
return nil
}
func (e *ServiceResolverConfigEntry) Validate() error {
if e.Name == "" {
return fmt.Errorf("Name is required")
}
if err := validateConfigEntryMeta(e.Meta); err != nil {
return err
}
if len(e.Subsets) > 0 {
for name, subset := range e.Subsets {
if name == "" {
return fmt.Errorf("Subset defined with empty name")
}
if err := validateServiceSubset(name); err != nil {
return fmt.Errorf("Subset %q is invalid: %v", name, err)
}
if subset.Filter != "" {
if _, err := bexpr.CreateEvaluator(subset.Filter, nil); err != nil {
return fmt.Errorf("Filter for subset %q is not a valid expression: %v", name, err)
}
}
}
}
isSubset := func(subset string) bool {
if len(e.Subsets) > 0 {
_, ok := e.Subsets[subset]
return ok
}
return false
}
if e.DefaultSubset != "" && !isSubset(e.DefaultSubset) {
return fmt.Errorf("DefaultSubset %q is not a valid subset", e.DefaultSubset)
}
if e.Redirect != nil {
if !e.InDefaultPartition() && e.Redirect.Datacenter != "" {
return fmt.Errorf("Cross-datacenter redirect is only supported in the default partition")
}
if acl.PartitionOrDefault(e.Redirect.Partition) != e.PartitionOrDefault() && e.Redirect.Datacenter != "" {
return fmt.Errorf("Cross-datacenter and cross-partition redirect is not supported")
}
r := e.Redirect
if err := r.ValidateEnterprise(); err != nil {
return fmt.Errorf("Redirect: %s", err.Error())
}
if len(e.Failover) > 0 {
return fmt.Errorf("Redirect and Failover cannot both be set")
}
// TODO(rb): prevent subsets and default subsets from being defined?
if r.isEmpty() {
return fmt.Errorf("Redirect is empty")
}
switch {
case r.SamenessGroup != "" && r.ServiceSubset != "":
return fmt.Errorf("Redirect.SamenessGroup cannot be set with Redirect.ServiceSubset")
case r.SamenessGroup != "" && r.Partition != "":
return fmt.Errorf("Redirect.Partition cannot be set with Redirect.SamenessGroup")
case r.SamenessGroup != "" && r.Datacenter != "":
return fmt.Errorf("Redirect.SamenessGroup cannot be set with Redirect.Datacenter")
case r.Peer != "" && r.ServiceSubset != "":
return fmt.Errorf("Redirect.Peer cannot be set with Redirect.ServiceSubset")
case r.Peer != "" && r.Partition != "":
return fmt.Errorf("Redirect.Partition cannot be set with Redirect.Peer")
case r.Peer != "" && r.Datacenter != "":
return fmt.Errorf("Redirect.Peer cannot be set with Redirect.Datacenter")
case r.Service == "":
if r.ServiceSubset != "" {
return fmt.Errorf("Redirect.ServiceSubset defined without Redirect.Service")
}
if r.Namespace != "" {
return fmt.Errorf("Redirect.Namespace defined without Redirect.Service")
}
if r.Partition != "" {
return fmt.Errorf("Redirect.Partition defined without Redirect.Service")
}
if r.Peer != "" {
return fmt.Errorf("Redirect.Peer defined without Redirect.Service")
}
case r.ServiceSubset != "" && (r.Service == "" || r.Service == e.Name):
if !isSubset(r.ServiceSubset) {
return fmt.Errorf("Redirect.ServiceSubset %q is not a valid subset of %q", r.ServiceSubset, e.Name)
}
}
}
if len(e.Failover) > 0 {
for subset, f := range e.Failover {
if !e.InDefaultPartition() && len(f.Datacenters) != 0 {
return fmt.Errorf("Cross-datacenter failover is only supported in the default partition")
}
errorPrefix := fmt.Sprintf("Bad Failover[%q]: ", subset)
if err := f.ValidateEnterprise(); err != nil {
return fmt.Errorf(errorPrefix + err.Error())
}
if subset != "*" && !isSubset(subset) {
return fmt.Errorf(errorPrefix + "not a valid subset subset")
}
if f.isEmpty() {
return fmt.Errorf(errorPrefix + "one of Service, ServiceSubset, Namespace, Targets, SamenessGroup, or Datacenters is required")
}
if err := f.Policy.ValidateEnterprise(); err != nil {
return fmt.Errorf("Bad Failover[%q]: %s", subset, err)
}
if !f.Policy.isValid() {
return fmt.Errorf("Bad Failover[%q]: Policy must be one of '', 'default', or 'order-by-locality'", subset)
}
if f.ServiceSubset != "" {
if f.Service == "" || f.Service == e.Name {
if !isSubset(f.ServiceSubset) {
return fmt.Errorf("%sServiceSubset %q is not a valid subset of %q", errorPrefix, f.ServiceSubset, f.Service)
}
}
}
if f.SamenessGroup != "" {
switch {
case len(f.Datacenters) > 0:
return fmt.Errorf("Bad Failover[%q]: SamenessGroup cannot be set with Datacenters", subset)
case f.ServiceSubset != "":
return fmt.Errorf("Bad Failover[%q]: SamenessGroup cannot be set with ServiceSubset", subset)
case len(f.Targets) > 0:
return fmt.Errorf("Bad Failover[%q]: SamenessGroup cannot be set with Targets", subset)
}
}
if len(f.Datacenters) != 0 && len(f.Targets) != 0 {
return fmt.Errorf("Bad Failover[%q]: Targets cannot be set with Datacenters", subset)
}
if f.ServiceSubset != "" && len(f.Targets) != 0 {
return fmt.Errorf("Bad Failover[%q]: Targets cannot be set with ServiceSubset", subset)
}
if f.Service != "" && len(f.Targets) != 0 {
return fmt.Errorf("Bad Failover[%q]: Targets cannot be set with Service", subset)
}
for i, target := range f.Targets {
errorPrefix := fmt.Sprintf("Bad Failover[%q].Targets[%d]: ", subset, i)
if err := target.ValidateEnterprise(); err != nil {
return fmt.Errorf(errorPrefix + err.Error())
}
switch {
case target.Peer != "" && target.ServiceSubset != "":
return fmt.Errorf(errorPrefix + "Peer cannot be set with ServiceSubset")
case target.Peer != "" && target.Partition != "":
return fmt.Errorf(errorPrefix + "Partition cannot be set with Peer")
case target.Peer != "" && target.Datacenter != "":
return fmt.Errorf(errorPrefix + "Peer cannot be set with Datacenter")
case target.Partition != "" && target.Datacenter != "":
return fmt.Errorf(errorPrefix + "Partition cannot be set with Datacenter")
case target.ServiceSubset != "" && (target.Service == "" || target.Service == e.Name):
if !isSubset(target.ServiceSubset) {
return fmt.Errorf("%sServiceSubset %q is not a valid subset of %q", errorPrefix, target.ServiceSubset, e.Name)
}
}
}
for _, dc := range f.Datacenters {
if dc == "" {
return fmt.Errorf("Bad Failover[%q].Datacenters: found empty datacenter", subset)
}
}
}
}
if e.ConnectTimeout < 0 {
return fmt.Errorf("Bad ConnectTimeout '%s', must be >= 0", e.ConnectTimeout)
}
if e.RequestTimeout < 0 {
return fmt.Errorf("Bad RequestTimeout '%s', must be >= 0", e.RequestTimeout)
}
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if e.LoadBalancer != nil {
lb := e.LoadBalancer
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if ok := validLBPolicies[lb.Policy]; !ok {
return fmt.Errorf("Bad LoadBalancer policy: %q is not supported", lb.Policy)
}
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if lb.Policy != LBPolicyRingHash && lb.RingHashConfig != nil {
return fmt.Errorf("Bad LoadBalancer configuration. "+
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"RingHashConfig specified for incompatible load balancing policy %q", lb.Policy)
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}
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if lb.Policy != LBPolicyLeastRequest && lb.LeastRequestConfig != nil {
return fmt.Errorf("Bad LoadBalancer configuration. "+
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"LeastRequestConfig specified for incompatible load balancing policy %q", lb.Policy)
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}
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if !lb.IsHashBased() && len(lb.HashPolicies) > 0 {
return fmt.Errorf("Bad LoadBalancer configuration: "+
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"HashPolicies specified for non-hash-based Policy: %q", lb.Policy)
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}
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for i, hp := range lb.HashPolicies {
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if ok := validHashPolicies[hp.Field]; hp.Field != "" && !ok {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: %q is not a supported field", i, hp.Field)
}
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if hp.SourceIP && hp.Field != "" {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: "+
"A single hash policy cannot hash both a source address and a %q", i, hp.Field)
}
if hp.SourceIP && hp.FieldValue != "" {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: "+
"A FieldValue cannot be specified when hashing SourceIP", i)
}
if hp.Field != "" && hp.FieldValue == "" {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: Field %q was specified without a FieldValue", i, hp.Field)
}
if hp.FieldValue != "" && hp.Field == "" {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: FieldValue requires a Field to apply to", i)
}
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if hp.CookieConfig != nil {
if hp.Field != HashPolicyCookie {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: cookie_config provided for %q", i, hp.Field)
}
if hp.CookieConfig.Session && hp.CookieConfig.TTL != 0*time.Second {
return fmt.Errorf("Bad LoadBalancer HashPolicy[%d]: a session cookie cannot have an associated TTL", i)
}
}
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}
}
return nil
}
func (e *ServiceResolverConfigEntry) CanRead(authz acl.Authorizer) error {
return canReadDiscoveryChain(e, authz)
}
func (e *ServiceResolverConfigEntry) CanWrite(authz acl.Authorizer) error {
return canWriteDiscoveryChain(e, authz)
}
func (e *ServiceResolverConfigEntry) GetRaftIndex() *RaftIndex {
if e == nil {
return &RaftIndex{}
}
return &e.RaftIndex
}
func (e *ServiceResolverConfigEntry) GetEnterpriseMeta() *acl.EnterpriseMeta {
if e == nil {
return nil
}
return &e.EnterpriseMeta
}
func (e *ServiceResolverConfigEntry) ListRelatedServices() []ServiceID {
found := make(map[ServiceID]struct{})
svcID := NewServiceID(e.Name, &e.EnterpriseMeta)
if e.Redirect != nil {
redirectID := NewServiceID(defaultIfEmpty(e.Redirect.Service, e.Name), e.Redirect.GetEnterpriseMeta(&e.EnterpriseMeta))
if redirectID != svcID {
found[redirectID] = struct{}{}
}
}
if len(e.Failover) > 0 {
for _, failover := range e.Failover {
if len(failover.Targets) == 0 {
failoverID := NewServiceID(defaultIfEmpty(failover.Service, e.Name), failover.GetEnterpriseMeta(&e.EnterpriseMeta))
if failoverID != svcID {
found[failoverID] = struct{}{}
}
continue
}
for _, target := range failover.Targets {
// We can't know about related services on cluster peers.
if target.Peer != "" {
continue
}
failoverID := NewServiceID(defaultIfEmpty(target.Service, e.Name), target.GetEnterpriseMeta(failover.GetEnterpriseMeta(&e.EnterpriseMeta)))
if failoverID != svcID {
found[failoverID] = struct{}{}
}
}
}
}
if len(found) == 0 {
return nil
}
out := make([]ServiceID, 0, len(found))
for svc := range found {
out = append(out, svc)
}
sort.Slice(out, func(i, j int) bool {
return out[i].EnterpriseMeta.LessThan(&out[j].EnterpriseMeta) ||
out[i].ID < out[j].ID
})
return out
}
// ServiceResolverSubset defines a way to select a portion of the Consul
// catalog during service discovery. Anything that affects the ultimate catalog
// query performed OR post-processing on the results of that sort of query
// should be defined here.
type ServiceResolverSubset struct {
// Filter specifies the go-bexpr filter expression to be used for selecting
// instances of the requested service.
Filter string `json:",omitempty"`
// OnlyPassing - Specifies the behavior of the resolver's health check
// filtering. If this is set to false, the results will include instances
// with checks in the passing as well as the warning states. If this is set
// to true, only instances with checks in the passing state will be
// returned. (behaves identically to the similarly named field on prepared
// queries).
OnlyPassing bool `json:",omitempty" alias:"only_passing"`
}
type ServiceResolverRedirect struct {
// Service is a service to resolve instead of the current service
// (optional).
Service string `json:",omitempty"`
// ServiceSubset is a named subset of the given service to resolve instead
// of one defined as that service's DefaultSubset If empty the default
// subset is used (optional).
//
// If this is specified at least one of Service, Datacenter, or Namespace
// should be configured.
ServiceSubset string `json:",omitempty" alias:"service_subset"`
// Namespace is the namespace to resolve the service from instead of the
// current one (optional).
Namespace string `json:",omitempty"`
// Partition is the partition to resolve the service from instead of the
// current one (optional).
Partition string `json:",omitempty"`
// Datacenter is the datacenter to resolve the service from instead of the
// current one (optional).
Datacenter string `json:",omitempty"`
// Peer is the name of the cluster peer to resolve the service from instead
// of the current one (optional).
Peer string `json:",omitempty"`
// SamenessGroup is the name of the sameness group to resolve the service from instead
// of the local partition.
SamenessGroup string `json:",omitempty"`
}
func (r *ServiceResolverRedirect) ToDiscoveryTargetOpts() DiscoveryTargetOpts {
return DiscoveryTargetOpts{
Service: r.Service,
ServiceSubset: r.ServiceSubset,
Namespace: r.Namespace,
Partition: r.Partition,
Datacenter: r.Datacenter,
Peer: r.Peer,
}
}
func (r *ServiceResolverRedirect) isEmpty() bool {
return r.Service == "" &&
r.ServiceSubset == "" &&
r.Namespace == "" &&
r.Partition == "" &&
r.Datacenter == "" &&
r.Peer == "" &&
r.SamenessGroup == ""
}
// There are some restrictions on what is allowed in here:
//
// - Service, ServiceSubset, Namespace, Datacenters, and Targets cannot all be
// empty at once. When Targets is defined, the other fields should not be
// populated.
type ServiceResolverFailover struct {
// Service is the service to resolve instead of the default as the failover
// group of instances (optional).
//
// This is a DESTINATION during failover.
Service string `json:",omitempty"`
// ServiceSubset is the named subset of the requested service to resolve as
// the failover group of instances. If empty the default subset for the
// requested service is used (optional).
//
// This is a DESTINATION during failover.
ServiceSubset string `json:",omitempty" alias:"service_subset"`
// Namespace is the namespace to resolve the requested service from to form
// the failover group of instances. If empty the current namespace is used
// (optional).
//
// This is a DESTINATION during failover.
Namespace string `json:",omitempty"`
// Datacenters is a fixed list of datacenters to try. We never try a
// datacenter multiple times, so those are subtracted from this list before
// proceeding.
//
// This is a DESTINATION during failover.
Datacenters []string `json:",omitempty"`
// Targets specifies a fixed list of failover targets to try. We never try a
// target multiple times, so those are subtracted from this list before
// proceeding.
//
// This is a DESTINATION during failover.
Targets []ServiceResolverFailoverTarget `json:",omitempty"`
// Policy specifies the exact mechanism used for failover.
Policy *ServiceResolverFailoverPolicy `json:",omitempty"`
// SamenessGroup specifies the sameness group to failover to.
SamenessGroup string `json:",omitempty"`
}
type ServiceResolverFailoverPolicy struct {
// Mode specifies the type of failover that will be performed. Valid values are
// "default", "" (equivalent to "default") and "order-by-locality".
Mode string `json:",omitempty"`
}
func (f *ServiceResolverFailover) ToDiscoveryTargetOpts() DiscoveryTargetOpts {
return DiscoveryTargetOpts{
Service: f.Service,
ServiceSubset: f.ServiceSubset,
Namespace: f.Namespace,
}
}
func (f *ServiceResolverFailover) isEmpty() bool {
return f.Service == "" &&
f.ServiceSubset == "" &&
f.Namespace == "" &&
len(f.Datacenters) == 0 &&
len(f.Targets) == 0 &&
f.SamenessGroup == ""
}
func (fp *ServiceResolverFailoverPolicy) isValid() bool {
if fp == nil {
return true
}
switch fp.Mode {
case "":
case "default":
case "order-by-locality":
default:
return false
}
return true
}
type ServiceResolverFailoverTarget struct {
// Service specifies the name of the service to try during failover.
Service string `json:",omitempty"`
// ServiceSubset specifies the service subset to try during failover.
ServiceSubset string `json:",omitempty" alias:"service_subset"`
// Partition specifies the partition to try during failover.
Partition string `json:",omitempty"`
// Namespace specifies the namespace to try during failover.
Namespace string `json:",omitempty"`
// Datacenter specifies the datacenter to try during failover.
Datacenter string `json:",omitempty"`
// Peer specifies the name of the cluster peer to try during failover.
Peer string `json:",omitempty"`
}
func (t *ServiceResolverFailoverTarget) ToDiscoveryTargetOpts() DiscoveryTargetOpts {
return DiscoveryTargetOpts{
Service: t.Service,
ServiceSubset: t.ServiceSubset,
Namespace: t.Namespace,
Partition: t.Partition,
Datacenter: t.Datacenter,
Peer: t.Peer,
}
}
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// LoadBalancer determines the load balancing policy and configuration for services
// issuing requests to this upstream service.
type LoadBalancer struct {
// Policy is the load balancing policy used to select a host
Policy string `json:",omitempty"`
// RingHashConfig contains configuration for the "ring_hash" policy type
RingHashConfig *RingHashConfig `json:",omitempty" alias:"ring_hash_config"`
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// LeastRequestConfig contains configuration for the "least_request" policy type
LeastRequestConfig *LeastRequestConfig `json:",omitempty" alias:"least_request_config"`
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// HashPolicies is a list of hash policies to use for hashing load balancing algorithms.
// Hash policies are evaluated individually and combined such that identical lists
// result in the same hash.
// If no hash policies are present, or none are successfully evaluated,
// then a random backend host will be selected.
HashPolicies []HashPolicy `json:",omitempty" alias:"hash_policies"`
}
// RingHashConfig contains configuration for the "ring_hash" policy type
type RingHashConfig struct {
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// MinimumRingSize determines the minimum number of entries in the hash ring
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MinimumRingSize uint64 `json:",omitempty" alias:"minimum_ring_size"`
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// MaximumRingSize determines the maximum number of entries in the hash ring
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MaximumRingSize uint64 `json:",omitempty" alias:"maximum_ring_size"`
}
// LeastRequestConfig contains configuration for the "least_request" policy type
type LeastRequestConfig struct {
// ChoiceCount determines the number of random healthy hosts from which to select the one with the least requests.
ChoiceCount uint32 `json:",omitempty" alias:"choice_count"`
}
// HashPolicy defines which attributes will be hashed by hash-based LB algorithms
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type HashPolicy struct {
// Field is the attribute type to hash on.
// Must be one of "header","cookie", or "query_parameter".
// Cannot be specified along with SourceIP.
Field string `json:",omitempty"`
// FieldValue is the value to hash.
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// ie. header name, cookie name, URL query parameter name
// Cannot be specified along with SourceIP.
FieldValue string `json:",omitempty" alias:"field_value"`
// CookieConfig contains configuration for the "cookie" hash policy type.
CookieConfig *CookieConfig `json:",omitempty" alias:"cookie_config"`
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// SourceIP determines whether the hash should be of the source IP rather than of a field and field value.
// Cannot be specified along with Field or FieldValue.
SourceIP bool `json:",omitempty" alias:"source_ip"`
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// Terminal will short circuit the computation of the hash when multiple hash policies are present.
// If a hash is computed when a Terminal policy is evaluated,
// then that hash will be used and subsequent hash policies will be ignored.
Terminal bool `json:",omitempty"`
}
// CookieConfig contains configuration for the "cookie" hash policy type.
// This is specified to have Envoy generate a cookie for a client on its first request.
type CookieConfig struct {
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// Generates a session cookie with no expiration.
Session bool `json:",omitempty"`
// TTL for generated cookies. Cannot be specified for session cookies.
TTL time.Duration `json:",omitempty"`
// The path to set for the cookie
Path string `json:",omitempty"`
}
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func (lb *LoadBalancer) IsHashBased() bool {
if lb == nil {
return false
}
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switch lb.Policy {
case LBPolicyMaglev, LBPolicyRingHash:
return true
default:
return false
}
}
type discoveryChainConfigEntry interface {
ConfigEntry
// ListRelatedServices returns a list of other names of services referenced
// in this config entry.
ListRelatedServices() []ServiceID
}
func canReadDiscoveryChain(entry discoveryChainConfigEntry, authz acl.Authorizer) error {
var authzContext acl.AuthorizerContext
entry.GetEnterpriseMeta().FillAuthzContext(&authzContext)
return authz.ToAllowAuthorizer().ServiceReadAllowed(entry.GetName(), &authzContext)
}
func canWriteDiscoveryChain(entry discoveryChainConfigEntry, authz acl.Authorizer) error {
entryID := NewServiceID(entry.GetName(), entry.GetEnterpriseMeta())
var authzContext acl.AuthorizerContext
entryID.FillAuthzContext(&authzContext)
name := entry.GetName()
if err := authz.ToAllowAuthorizer().ServiceWriteAllowed(name, &authzContext); err != nil {
return err
}
for _, svc := range entry.ListRelatedServices() {
if entryID == svc {
continue
}
svc.FillAuthzContext(&authzContext)
// You only need read on related services to redirect traffic flow for
// your own service.
if err := authz.ToAllowAuthorizer().ServiceReadAllowed(svc.ID, &authzContext); err != nil {
return err
}
}
return nil
}
// DiscoveryChainRequest is used when requesting the discovery chain for a
// service.
type DiscoveryChainRequest struct {
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
2019-08-02 03:03:34 +00:00
Name string
EvaluateInDatacenter string
EvaluateInNamespace string
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EvaluateInPartition string
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
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// OverrideMeshGateway allows for the mesh gateway setting to be overridden
// for any resolver in the compiled chain.
OverrideMeshGateway MeshGatewayConfig
// OverrideProtocol allows for the final protocol for the chain to be
// altered.
//
// - If the chain ordinarily would be TCP and an L7 protocol is passed here
// the chain will not include Routers or Splitters.
//
// - If the chain ordinarily would be L7 and TCP is passed here the chain
// will not include Routers or Splitters.
OverrideProtocol string
// OverrideConnectTimeout allows for the ConnectTimeout setting to be
// overridden for any resolver in the compiled chain.
OverrideConnectTimeout time.Duration
Datacenter string // where to route the RPC
QueryOptions
}
func (r *DiscoveryChainRequest) RequestDatacenter() string {
return r.Datacenter
}
func (r *DiscoveryChainRequest) CacheInfo() cache.RequestInfo {
info := cache.RequestInfo{
Token: r.Token,
Datacenter: r.Datacenter,
MinIndex: r.MinQueryIndex,
Timeout: r.MaxQueryTime,
MaxAge: r.MaxAge,
MustRevalidate: r.MustRevalidate,
}
v, err := hashstructure.Hash(struct {
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
2019-08-02 03:03:34 +00:00
Name string
EvaluateInDatacenter string
EvaluateInNamespace string
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EvaluateInPartition string
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
2019-08-02 03:03:34 +00:00
OverrideMeshGateway MeshGatewayConfig
OverrideProtocol string
OverrideConnectTimeout time.Duration
Filter string
}{
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
2019-08-02 03:03:34 +00:00
Name: r.Name,
EvaluateInDatacenter: r.EvaluateInDatacenter,
EvaluateInNamespace: r.EvaluateInNamespace,
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EvaluateInPartition: r.EvaluateInPartition,
connect: reconcile how upstream configuration works with discovery chains (#6225) * connect: reconcile how upstream configuration works with discovery chains The following upstream config fields for connect sidecars sanely integrate into discovery chain resolution: - Destination Namespace/Datacenter: Compilation occurs locally but using different default values for namespaces and datacenters. The xDS clusters that are created are named as they normally would be. - Mesh Gateway Mode (single upstream): If set this value overrides any value computed for any resolver for the entire discovery chain. The xDS clusters that are created may be named differently (see below). - Mesh Gateway Mode (whole sidecar): If set this value overrides any value computed for any resolver for the entire discovery chain. If this is specifically overridden for a single upstream this value is ignored in that case. The xDS clusters that are created may be named differently (see below). - Protocol (in opaque config): If set this value overrides the value computed when evaluating the entire discovery chain. If the normal chain would be TCP or if this override is set to TCP then the result is that we explicitly disable L7 Routing and Splitting. The xDS clusters that are created may be named differently (see below). - Connect Timeout (in opaque config): If set this value overrides the value for any resolver in the entire discovery chain. The xDS clusters that are created may be named differently (see below). If any of the above overrides affect the actual result of compiling the discovery chain (i.e. "tcp" becomes "grpc" instead of being a no-op override to "tcp") then the relevant parameters are hashed and provided to the xDS layer as a prefix for use in naming the Clusters. This is to ensure that if one Upstream discovery chain has no overrides and tangentially needs a cluster named "api.default.XXX", and another Upstream does have overrides for "api.default.XXX" that they won't cross-pollinate against the operator's wishes. Fixes #6159
2019-08-02 03:03:34 +00:00
OverrideMeshGateway: r.OverrideMeshGateway,
OverrideProtocol: r.OverrideProtocol,
OverrideConnectTimeout: r.OverrideConnectTimeout,
Filter: r.QueryOptions.Filter,
}, nil)
if err == nil {
// If there is an error, we don't set the key. A blank key forces
// no cache for this request so the request is forwarded directly
// to the server.
info.Key = strconv.FormatUint(v, 10)
}
return info
}
type DiscoveryChainResponse struct {
Chain *CompiledDiscoveryChain
QueryMeta
}
type ConfigEntryGraphError struct {
// one of Message or Err should be set
Message string
Err error
}
func (e *ConfigEntryGraphError) Error() string {
if e.Err != nil {
return e.Err.Error()
}
return e.Message
}
var (
validServiceSubset = regexp.MustCompile(`^[a-z0-9]([a-z0-9-]*[a-z0-9])?$`)
serviceSubsetMaxLength = 63
)
// validateServiceSubset checks if the provided name can be used as an service
// subset. Because these are used in SNI headers they must a DNS label per
// RFC-1035/RFC-1123.
func validateServiceSubset(subset string) error {
if subset == "" || len(subset) > serviceSubsetMaxLength {
return fmt.Errorf("must be non-empty and 63 characters or fewer")
}
if !validServiceSubset.MatchString(subset) {
return fmt.Errorf("must be 63 characters or fewer, begin or end with lower case alphanumeric characters, and contain lower case alphanumeric characters or '-' in between")
}
return nil
}
func defaultIfEmpty(val, defaultVal string) string {
if val != "" {
return val
}
return defaultVal
}
func IsProtocolHTTPLike(protocol string) bool {
switch protocol {
case "http", "http2", "grpc":
return true
default:
return false
}
}
// HTTPHeaderModifiers is a set of rules for HTTP header modification that
// should be performed by proxies as the request passes through them. It can
// operate on either request or response headers depending on the context in
// which it is used.
type HTTPHeaderModifiers struct {
// Add is a set of name -> value pairs that should be appended to the request
// or response (i.e. allowing duplicates if the same header already exists).
Add map[string]string `json:",omitempty"`
// Set is a set of name -> value pairs that should be added to the request or
// response, overwriting any existing header values of the same name.
Set map[string]string `json:",omitempty"`
// Remove is the set of header names that should be stripped from the request
// or response.
Remove []string `json:",omitempty"`
}
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func (m *HTTPHeaderModifiers) IsZero() bool {
if m == nil {
return true
}
return len(m.Add) == 0 && len(m.Set) == 0 && len(m.Remove) == 0
}
func (m *HTTPHeaderModifiers) Validate(protocol string) error {
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if m.IsZero() {
return nil
}
if !IsProtocolHTTPLike(protocol) {
// Non nil but context is not an httpish protocol
return fmt.Errorf("only valid for http, http2 and grpc protocols")
}
return nil
}
// Clone returns a deep-copy of m unless m is nil
func (m *HTTPHeaderModifiers) Clone() (*HTTPHeaderModifiers, error) {
if m == nil {
return nil, nil
}
cpy, err := copystructure.Copy(m)
if err != nil {
return nil, err
}
m = cpy.(*HTTPHeaderModifiers)
return m, nil
}
// MergeHTTPHeaderModifiers takes a base HTTPHeaderModifiers and merges in field
// defined in overrides. Precedence is given to the overrides field if there is
// a collision. The resulting object is returned leaving both base and overrides
// unchanged. The `Add` field in override also replaces same-named keys of base
// since we have no way to express multiple adds to the same key. We could
// change that, but it makes the config syntax more complex for a huge edgecase.
func MergeHTTPHeaderModifiers(base, overrides *HTTPHeaderModifiers) (*HTTPHeaderModifiers, error) {
if base.IsZero() {
return overrides.Clone()
}
merged, err := base.Clone()
if err != nil {
return nil, err
}
if overrides.IsZero() {
return merged, nil
}
for k, v := range overrides.Add {
merged.Add[k] = v
}
for k, v := range overrides.Set {
merged.Set[k] = v
}
// Deduplicate removes.
removed := make(map[string]struct{})
for _, k := range merged.Remove {
removed[k] = struct{}{}
}
for _, k := range overrides.Remove {
if _, ok := removed[k]; !ok {
merged.Remove = append(merged.Remove, k)
}
}
return merged, nil
}