consul/agent/xds/rbac.go

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package xds
import (
"fmt"
"sort"
"strings"
envoy_listener_v3 "github.com/envoyproxy/go-control-plane/envoy/config/listener/v3"
envoy_rbac_v3 "github.com/envoyproxy/go-control-plane/envoy/config/rbac/v3"
envoy_route_v3 "github.com/envoyproxy/go-control-plane/envoy/config/route/v3"
2023-01-06 17:13:40 +00:00
envoy_http_header_to_meta_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/http/header_to_metadata/v3"
envoy_http_rbac_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/http/rbac/v3"
envoy_http_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/http_connection_manager/v3"
envoy_network_rbac_v3 "github.com/envoyproxy/go-control-plane/envoy/extensions/filters/network/rbac/v3"
envoy_matcher_v3 "github.com/envoyproxy/go-control-plane/envoy/type/matcher/v3"
"github.com/hashicorp/consul/agent/connect"
"github.com/hashicorp/consul/agent/structs"
Protobuf Refactoring for Multi-Module Cleanliness (#16302) Protobuf Refactoring for Multi-Module Cleanliness This commit includes the following: Moves all packages that were within proto/ to proto/private Rewrites imports to account for the packages being moved Adds in buf.work.yaml to enable buf workspaces Names the proto-public buf module so that we can override the Go package imports within proto/buf.yaml Bumps the buf version dependency to 1.14.0 (I was trying out the version to see if it would get around an issue - it didn't but it also doesn't break things and it seemed best to keep up with the toolchain changes) Why: In the future we will need to consume other protobuf dependencies such as the Google HTTP annotations for openapi generation or grpc-gateway usage. There were some recent changes to have our own ratelimiting annotations. The two combined were not working when I was trying to use them together (attempting to rebase another branch) Buf workspaces should be the solution to the problem Buf workspaces means that each module will have generated Go code that embeds proto file names relative to the proto dir and not the top level repo root. This resulted in proto file name conflicts in the Go global protobuf type registry. The solution to that was to add in a private/ directory into the path within the proto/ directory. That then required rewriting all the imports. Is this safe? AFAICT yes The gRPC wire protocol doesn't seem to care about the proto file names (although the Go grpc code does tack on the proto file name as Metadata in the ServiceDesc) Other than imports, there were no changes to any generated code as a result of this.
2023-02-17 21:14:46 +00:00
"github.com/hashicorp/consul/proto/private/pbpeering"
)
func makeRBACNetworkFilter(
intentions structs.Intentions,
intentionDefaultAllow bool,
localInfo rbacLocalInfo,
peerTrustBundles []*pbpeering.PeeringTrustBundle,
) (*envoy_listener_v3.Filter, error) {
rules := makeRBACRules(intentions, intentionDefaultAllow, localInfo, false, peerTrustBundles)
cfg := &envoy_network_rbac_v3.RBAC{
StatPrefix: "connect_authz",
Rules: rules,
}
return makeFilter("envoy.filters.network.rbac", cfg)
}
func makeRBACHTTPFilter(
intentions structs.Intentions,
intentionDefaultAllow bool,
localInfo rbacLocalInfo,
peerTrustBundles []*pbpeering.PeeringTrustBundle,
) (*envoy_http_v3.HttpFilter, error) {
rules := makeRBACRules(intentions, intentionDefaultAllow, localInfo, true, peerTrustBundles)
cfg := &envoy_http_rbac_v3.RBAC{
Rules: rules,
}
return makeEnvoyHTTPFilter("envoy.filters.http.rbac", cfg)
}
func intentionListToIntermediateRBACForm(
intentions structs.Intentions,
localInfo rbacLocalInfo,
isHTTP bool,
trustBundlesByPeer map[string]*pbpeering.PeeringTrustBundle,
) []*rbacIntention {
sort.Sort(structs.IntentionPrecedenceSorter(intentions))
// Omit any lower-precedence intentions that share the same source.
intentions = removeSameSourceIntentions(intentions)
rbacIxns := make([]*rbacIntention, 0, len(intentions))
for _, ixn := range intentions {
// trustBundle is only applicable to imported services
trustBundle, ok := trustBundlesByPeer[ixn.SourcePeer]
if ixn.SourcePeer != "" && !ok {
// If the intention defines a source peer, we expect to
// see a trust bundle. Otherwise the config snapshot may
// not have yet received the bundles and we fail silently
continue
}
rixn := intentionToIntermediateRBACForm(ixn, localInfo, isHTTP, trustBundle)
rbacIxns = append(rbacIxns, rixn)
}
return rbacIxns
}
func removeSourcePrecedence(rbacIxns []*rbacIntention, intentionDefaultAction intentionAction, localInfo rbacLocalInfo) []*rbacIntention {
if len(rbacIxns) == 0 {
return nil
}
// Remove source precedence:
//
// First walk backwards and add each intention to all subsequent statements
// (via AND NOT $x).
//
// If it is L4 and has the same action as the default intention action then
// mark the rule itself for erasure.
numRetained := 0
for i := len(rbacIxns) - 1; i >= 0; i-- {
for j := i + 1; j < len(rbacIxns); j++ {
if rbacIxns[j].Skip {
continue
}
// [i] is the intention candidate that we are distributing
// [j] is the thing to maybe NOT [i] from
if ixnSourceMatches(rbacIxns[i].Source, rbacIxns[j].Source) {
rbacIxns[j].NotSources = append(rbacIxns[j].NotSources, rbacIxns[i].Source)
}
}
if rbacIxns[i].Action == intentionDefaultAction {
// Lower precedence intentions that match the default intention
// action are skipped, since they're handled by the default
// catch-all.
rbacIxns[i].Skip = true // mark for deletion
} else {
numRetained++
}
}
// At this point precedence doesn't matter for the source element.
// Remove skipped intentions and also compute the final Principals for each
// intention.
out := make([]*rbacIntention, 0, numRetained)
for _, rixn := range rbacIxns {
if rixn.Skip {
continue
}
rixn.ComputedPrincipal = rixn.FlattenPrincipal(localInfo)
out = append(out, rixn)
}
return out
}
func removeIntentionPrecedence(rbacIxns []*rbacIntention, intentionDefaultAction intentionAction, localInfo rbacLocalInfo) []*rbacIntention {
// Remove source precedence. After this completes precedence doesn't matter
// between any two intentions.
rbacIxns = removeSourcePrecedence(rbacIxns, intentionDefaultAction, localInfo)
numRetained := 0
for _, rbacIxn := range rbacIxns {
// Remove permission precedence. After this completes precedence
// doesn't matter between any two permissions on this intention.
rbacIxn.Permissions = removePermissionPrecedence(rbacIxn.Permissions, intentionDefaultAction)
if rbacIxn.Action == intentionActionLayer7 && len(rbacIxn.Permissions) == 0 {
// All of the permissions must have had the default action type and
// were removed. Mark this for removal below.
rbacIxn.Skip = true
} else {
numRetained++
}
}
if numRetained == len(rbacIxns) {
return rbacIxns
}
// We previously used the absence of permissions (above) as a signal to
// mark the entire intention for removal. Now do the deletions.
out := make([]*rbacIntention, 0, numRetained)
for _, rixn := range rbacIxns {
if !rixn.Skip {
out = append(out, rixn)
}
}
return out
}
func removePermissionPrecedence(perms []*rbacPermission, intentionDefaultAction intentionAction) []*rbacPermission {
if len(perms) == 0 {
return nil
}
// First walk backwards and add each permission to all subsequent
// statements (via AND NOT $x).
//
// If it has the same action as the default intention action then mark the
// permission itself for erasure.
numRetained := 0
for i := len(perms) - 1; i >= 0; i-- {
for j := i + 1; j < len(perms); j++ {
if perms[j].Skip {
continue
}
// [i] is the permission candidate that we are distributing
// [j] is the thing to maybe NOT [i] from
perms[j].NotPerms = append(
perms[j].NotPerms,
perms[i].Perm,
)
}
if perms[i].Action == intentionDefaultAction {
// Lower precedence permissions that match the default intention
// action are skipped, since they're handled by the default
// catch-all.
perms[i].Skip = true // mark for deletion
} else {
numRetained++
}
}
// Remove skipped permissions and also compute the final Permissions for each item.
out := make([]*rbacPermission, 0, numRetained)
for _, perm := range perms {
if perm.Skip {
continue
}
perm.ComputedPermission = perm.Flatten()
out = append(out, perm)
}
return out
}
func intentionToIntermediateRBACForm(
ixn *structs.Intention,
localInfo rbacLocalInfo,
isHTTP bool,
bundle *pbpeering.PeeringTrustBundle,
) *rbacIntention {
rixn := &rbacIntention{
Source: rbacService{
ServiceName: ixn.SourceServiceName(),
Peer: ixn.SourcePeer,
TrustDomain: localInfo.trustDomain,
},
Precedence: ixn.Precedence,
}
// imported services will have addition metadata used to override SpiffeID creation
if bundle != nil {
rixn.Source.ExportedPartition = bundle.ExportedPartition
rixn.Source.TrustDomain = bundle.TrustDomain
}
if len(ixn.Permissions) > 0 {
if isHTTP {
rixn.Action = intentionActionLayer7
rixn.Permissions = make([]*rbacPermission, 0, len(ixn.Permissions))
for _, perm := range ixn.Permissions {
rixn.Permissions = append(rixn.Permissions, &rbacPermission{
Definition: perm,
Action: intentionActionFromString(perm.Action),
Perm: convertPermission(perm),
})
}
} else {
// In case L7 intentions slip through to here, treat them as deny intentions.
rixn.Action = intentionActionDeny
}
} else {
rixn.Action = intentionActionFromString(ixn.Action)
}
return rixn
}
type intentionAction int
const (
intentionActionDeny intentionAction = iota
intentionActionAllow
intentionActionLayer7
)
func intentionActionFromBool(v bool) intentionAction {
if v {
return intentionActionAllow
} else {
return intentionActionDeny
}
}
func intentionActionFromString(s structs.IntentionAction) intentionAction {
if s == structs.IntentionActionAllow {
return intentionActionAllow
}
return intentionActionDeny
}
type rbacService struct {
structs.ServiceName
// Peer, ExportedPartition, and TrustDomain are
// only applicable to imported services and are
// used to override SPIFFEID fields.
Peer string
ExportedPartition string
TrustDomain string
}
type rbacIntention struct {
Source rbacService
NotSources []rbacService
Action intentionAction
Permissions []*rbacPermission
Precedence int
// Skip is field used to indicate that this intention can be deleted in the
// final pass. Items marked as true should generally not escape the method
// that marked them.
Skip bool
ComputedPrincipal *envoy_rbac_v3.Principal
}
func (r *rbacIntention) FlattenPrincipal(localInfo rbacLocalInfo) *envoy_rbac_v3.Principal {
if !localInfo.expectXFCC {
return r.flattenPrincipalFromCert()
} else if r.Source.Peer == "" {
// NOTE: ixnSourceMatches should enforce that all of Source and NotSources
// are peered or not-peered, so we only need to look at the Source element.
return r.flattenPrincipalFromCert() // intention is not relevant to peering
}
// If this intention is an L7 peered one, then it is exclusively resolvable
// using XFCC, rather than the TLS SAN field.
fromXFCC := r.flattenPrincipalFromXFCC()
// Use of the XFCC one is gated on coming directly from our own gateways.
gwIDPattern := makeSpiffeMeshGatewayPattern(localInfo.trustDomain, localInfo.partition)
return andPrincipals([]*envoy_rbac_v3.Principal{
authenticatedPatternPrincipal(gwIDPattern),
fromXFCC,
})
}
func (r *rbacIntention) flattenPrincipalFromCert() *envoy_rbac_v3.Principal {
r.NotSources = simplifyNotSourceSlice(r.NotSources)
if len(r.NotSources) == 0 {
return idPrincipal(r.Source)
}
andIDs := make([]*envoy_rbac_v3.Principal, 0, len(r.NotSources)+1)
andIDs = append(andIDs, idPrincipal(r.Source))
for _, src := range r.NotSources {
andIDs = append(andIDs, notPrincipal(
idPrincipal(src),
))
}
return andPrincipals(andIDs)
}
func (r *rbacIntention) flattenPrincipalFromXFCC() *envoy_rbac_v3.Principal {
r.NotSources = simplifyNotSourceSlice(r.NotSources)
if len(r.NotSources) == 0 {
return xfccPrincipal(r.Source)
}
andIDs := make([]*envoy_rbac_v3.Principal, 0, len(r.NotSources)+1)
andIDs = append(andIDs, xfccPrincipal(r.Source))
for _, src := range r.NotSources {
andIDs = append(andIDs, notPrincipal(
xfccPrincipal(src),
))
}
return andPrincipals(andIDs)
}
type rbacPermission struct {
Definition *structs.IntentionPermission
Action intentionAction
Perm *envoy_rbac_v3.Permission
NotPerms []*envoy_rbac_v3.Permission
// Skip is field used to indicate that this permission can be deleted in
// the final pass. Items marked as true should generally not escape the
// method that marked them.
Skip bool
ComputedPermission *envoy_rbac_v3.Permission
}
func (p *rbacPermission) Flatten() *envoy_rbac_v3.Permission {
if len(p.NotPerms) == 0 {
return p.Perm
}
parts := make([]*envoy_rbac_v3.Permission, 0, len(p.NotPerms)+1)
parts = append(parts, p.Perm)
for _, notPerm := range p.NotPerms {
parts = append(parts, notPermission(notPerm))
}
return andPermissions(parts)
}
// simplifyNotSourceSlice will collapse NotSources elements together if any element is
// a subset of another.
// For example "default/web" is a subset of "default/*" because it is covered by the wildcard.
func simplifyNotSourceSlice(notSources []rbacService) []rbacService {
if len(notSources) <= 1 {
return notSources
}
// Sort, keeping the least wildcarded elements first.
// More specific elements have a higher precedence over more wildcarded elements.
sort.SliceStable(notSources, func(i, j int) bool {
return countWild(notSources[i]) < countWild(notSources[j])
})
keep := make([]rbacService, 0, len(notSources))
for i := 0; i < len(notSources); i++ {
si := notSources[i]
remove := false
for j := i + 1; j < len(notSources); j++ {
sj := notSources[j]
if ixnSourceMatches(si, sj) {
remove = true
break
}
}
if !remove {
keep = append(keep, si)
}
}
return keep
}
type rbacLocalInfo struct {
trustDomain string
datacenter string
partition string
expectXFCC bool
}
// makeRBACRules translates Consul intentions into RBAC Policies for Envoy.
//
// Consul lets you define up to 9 different kinds of intentions that apply at
// different levels of precedence (this is limited to 4 if not using Consul
// Enterprise). Each intention in this flat list (sorted by precedence) can either
// be an allow rule or a deny rule. Heres a concrete example of this at work:
//
// intern/trusted-app => billing/payment-svc : ALLOW (prec=9)
// intern/* => billing/payment-svc : DENY (prec=8)
// */* => billing/payment-svc : ALLOW (prec=7)
// ::: ACL default policy ::: : DENY (prec=N/A)
//
// In contrast, Envoy lets you either configure a filter to be based on an
// allow-list or a deny-list based on the action attribute of the RBAC rules
// struct.
//
// On the surface it would seem that the configuration model of Consul
// intentions is incompatible with that of Envoys RBAC engine. For any given
// destination service Consuls model requires evaluating a list of rules and
// short circuiting later rules once an earlier rule matches. After a rule is
// found to match then we decide if it is allow/deny. Envoy on the other hand
// requires the rules to express all conditions to allow access or all conditions
// to deny access.
//
// Despite the surface incompatibility it is possible to marry these two
// models. For clarity Ill rewrite the earlier example intentions in an
// abbreviated form:
//
// A : ALLOW
// B : DENY
// C : ALLOW
// <default> : DENY
//
// 1. Given that the overall intention default is set to deny, we start by
// choosing to build an allow-list in Envoy (this is also the variant that I find
// easier to think about).
// 2. Next we traverse the list in precedence order (top down) and any DENY
// intentions are combined with later intentions using logical operations.
// 3. Now that all of the intentions result in the same action (allow) we have
// successfully removed precedence and we can express this in as a set of Envoy
// RBAC policies.
//
// After this the earlier A/B/C/default list becomes:
//
// A : ALLOW
// C AND NOT(B) : ALLOW
// <default> : DENY
//
// Which really is just an allow-list of [A, C AND NOT(B)]
func makeRBACRules(
intentions structs.Intentions,
intentionDefaultAllow bool,
localInfo rbacLocalInfo,
isHTTP bool,
peerTrustBundles []*pbpeering.PeeringTrustBundle,
) *envoy_rbac_v3.RBAC {
// TODO(banks,rb): Implement revocation list checking?
// TODO(peering): mkeeler asked that these maps come from proxycfg instead of
// being constructed in xds to save memory allocation and gc pressure. Low priority.
trustBundlesByPeer := make(map[string]*pbpeering.PeeringTrustBundle, len(peerTrustBundles))
for _, ptb := range peerTrustBundles {
trustBundlesByPeer[ptb.PeerName] = ptb
}
if isHTTP && len(peerTrustBundles) > 0 {
for _, ixn := range intentions {
if ixn.SourcePeer != "" {
localInfo.expectXFCC = true
break
}
}
}
// First build up just the basic principal matches.
rbacIxns := intentionListToIntermediateRBACForm(intentions, localInfo, isHTTP, trustBundlesByPeer)
// Normalize: if we are in default-deny then all intentions must be allows and vice versa
intentionDefaultAction := intentionActionFromBool(intentionDefaultAllow)
var rbacAction envoy_rbac_v3.RBAC_Action
if intentionDefaultAllow {
// The RBAC policies deny access to principals. The rest is allowed.
// This is block-list style access control.
rbacAction = envoy_rbac_v3.RBAC_DENY
} else {
// The RBAC policies grant access to principals. The rest is denied.
// This is safe-list style access control. This is the default type.
rbacAction = envoy_rbac_v3.RBAC_ALLOW
}
// Remove source and permissions precedence.
rbacIxns = removeIntentionPrecedence(rbacIxns, intentionDefaultAction, localInfo)
// For L4: we should generate one big Policy listing all Principals
// For L7: we should generate one Policy per Principal and list all of the Permissions
rbac := &envoy_rbac_v3.RBAC{
Action: rbacAction,
Policies: make(map[string]*envoy_rbac_v3.Policy),
}
var principalsL4 []*envoy_rbac_v3.Principal
for i, rbacIxn := range rbacIxns {
if rbacIxn.Action == intentionActionLayer7 {
if len(rbacIxn.Permissions) == 0 {
panic("invalid state: L7 intention has no permissions")
}
if !isHTTP {
panic("invalid state: L7 permissions present for TCP service")
}
// For L7: we should generate one Policy per Principal and list all of the Permissions
policy := &envoy_rbac_v3.Policy{
Principals: optimizePrincipals([]*envoy_rbac_v3.Principal{rbacIxn.ComputedPrincipal}),
Permissions: make([]*envoy_rbac_v3.Permission, 0, len(rbacIxn.Permissions)),
}
for _, perm := range rbacIxn.Permissions {
policy.Permissions = append(policy.Permissions, perm.ComputedPermission)
}
rbac.Policies[fmt.Sprintf("consul-intentions-layer7-%d", i)] = policy
} else {
// For L4: we should generate one big Policy listing all Principals
principalsL4 = append(principalsL4, rbacIxn.ComputedPrincipal)
}
}
if len(principalsL4) > 0 {
rbac.Policies["consul-intentions-layer4"] = &envoy_rbac_v3.Policy{
Principals: optimizePrincipals(principalsL4),
Permissions: []*envoy_rbac_v3.Permission{anyPermission()},
}
}
if len(rbac.Policies) == 0 {
rbac.Policies = nil
}
return rbac
}
func optimizePrincipals(orig []*envoy_rbac_v3.Principal) []*envoy_rbac_v3.Principal {
// If they are all ORs, then OR them together.
var orIds []*envoy_rbac_v3.Principal
for _, p := range orig {
or, ok := p.Identifier.(*envoy_rbac_v3.Principal_OrIds)
if !ok {
return orig
}
orIds = append(orIds, or.OrIds.Ids...)
}
return []*envoy_rbac_v3.Principal{orPrincipals(orIds)}
}
// removeSameSourceIntentions will iterate over intentions and remove any lower precedence
// intentions that share the same source. Intentions are sorted by descending precedence
// so once a source has been seen, additional intentions with the same source can be dropped.
//
// Example for the default/web service:
// input: [(backend/* -> default/web), (backend/* -> default/*)]
// output: [(backend/* -> default/web)]
//
// (backend/* -> default/*) was dropped because it is already known that any service
// in the backend namespace can target default/web.
func removeSameSourceIntentions(intentions structs.Intentions) structs.Intentions {
if len(intentions) < 2 {
return intentions
}
var (
out = make(structs.Intentions, 0, len(intentions))
changed = false
seenSource = make(map[structs.PeeredServiceName]struct{})
)
for _, ixn := range intentions {
psn := structs.PeeredServiceName{
ServiceName: ixn.SourceServiceName(),
Peer: ixn.SourcePeer,
}
if _, ok := seenSource[psn]; ok {
// A higher precedence intention already used this exact source
// definition with a different destination.
changed = true
continue
}
seenSource[psn] = struct{}{}
out = append(out, ixn)
}
if !changed {
return intentions
}
return out
}
// ixnSourceMatches determines if the 'tester' service name is matched by the
// 'against' service name via wildcard rules.
//
// For instance:
// - (web, api) => false, because these have no wildcards
// - (web, *) => true, because "all services" includes "web"
// - (default/web, default/*) => true, because "all services in the default NS" includes "default/web"
// - (default/*, */*) => true, "any service in any NS" includes "all services in the default NS"
// - (default/default/*, other/*/*) => false, "any service in "other" partition" does NOT include services in the default partition"
//
// Peer and partition must be exact names and cannot be compared with wildcards.
func ixnSourceMatches(tester, against rbacService) bool {
// We assume that we can't have the same intention twice before arriving
// here.
numWildTester := countWild(tester)
numWildAgainst := countWild(against)
if numWildTester == numWildAgainst {
return false
} else if numWildTester > numWildAgainst {
return false
}
matchesAP := tester.PartitionOrDefault() == against.PartitionOrDefault()
matchesPeer := tester.Peer == against.Peer
matchesNS := tester.NamespaceOrDefault() == against.NamespaceOrDefault() || against.NamespaceOrDefault() == structs.WildcardSpecifier
matchesName := tester.Name == against.Name || against.Name == structs.WildcardSpecifier
return matchesAP && matchesPeer && matchesNS && matchesName
}
// countWild counts the number of wildcard values in the given namespace and name.
func countWild(src rbacService) int {
// If Partition is wildcard, panic because it's not supported
if src.PartitionOrDefault() == structs.WildcardSpecifier {
panic("invalid state: intention references wildcard partition")
}
if src.Peer == structs.WildcardSpecifier {
panic("invalid state: intention references wildcard peer")
}
// If NS is wildcard, it must be 2 since wildcards only follow exact
if src.NamespaceOrDefault() == structs.WildcardSpecifier {
return 2
}
// Same reasoning as above, a wildcard can only follow an exact value
// and an exact value cannot follow a wildcard, so if name is a wildcard
// we must have exactly one.
if src.Name == structs.WildcardSpecifier {
return 1
}
return 0
}
func andPrincipals(ids []*envoy_rbac_v3.Principal) *envoy_rbac_v3.Principal {
return &envoy_rbac_v3.Principal{
Identifier: &envoy_rbac_v3.Principal_AndIds{
AndIds: &envoy_rbac_v3.Principal_Set{
Ids: ids,
},
},
}
}
func orPrincipals(ids []*envoy_rbac_v3.Principal) *envoy_rbac_v3.Principal {
return &envoy_rbac_v3.Principal{
Identifier: &envoy_rbac_v3.Principal_OrIds{
OrIds: &envoy_rbac_v3.Principal_Set{
Ids: ids,
},
},
}
}
func notPrincipal(id *envoy_rbac_v3.Principal) *envoy_rbac_v3.Principal {
return &envoy_rbac_v3.Principal{
Identifier: &envoy_rbac_v3.Principal_NotId{
NotId: id,
},
}
}
func idPrincipal(src rbacService) *envoy_rbac_v3.Principal {
pattern := makeSpiffePattern(src)
return authenticatedPatternPrincipal(pattern)
}
func authenticatedPatternPrincipal(pattern string) *envoy_rbac_v3.Principal {
return &envoy_rbac_v3.Principal{
Identifier: &envoy_rbac_v3.Principal_Authenticated_{
Authenticated: &envoy_rbac_v3.Principal_Authenticated{
PrincipalName: &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_SafeRegex{
SafeRegex: makeEnvoyRegexMatch(pattern),
},
},
},
},
}
}
func xfccPrincipal(src rbacService) *envoy_rbac_v3.Principal {
// Same match we normally would use.
idPattern := makeSpiffePattern(src)
// Remove the leading ^ and trailing $.
idPattern = idPattern[1 : len(idPattern)-1]
// Anchor to the first XFCC component
pattern := `^[^,]+;URI=` + idPattern + `(?:,.*)?$`
// By=spiffe://8c7db6d3-e4ee-aa8c-488c-dbedd3772b78.consul/gateway/mesh/dc/dc2;
// Hash=2a2db78ac351a05854a0abd350631bf98cc0eb827d21f4ed5935ccd287779eb6;
// Cert="-----BEGIN%20CERTIFICATE-----<SNIP>";
// Chain="-----BEGIN%20CERTIFICATE-----<SNIP>";
// Subject="";
// URI=spiffe://5583c38e-c1c0-fd1e-2079-170bb2f396ad.consul/ns/default/dc/dc1/svc/pong,
return &envoy_rbac_v3.Principal{
Identifier: &envoy_rbac_v3.Principal_Header{
Header: &envoy_route_v3.HeaderMatcher{
Name: "x-forwarded-client-cert",
HeaderMatchSpecifier: &envoy_route_v3.HeaderMatcher_StringMatch{
StringMatch: &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_SafeRegex{
SafeRegex: makeEnvoyRegexMatch(pattern),
},
},
},
},
},
}
}
const anyPath = `[^/]+`
2023-01-06 17:13:40 +00:00
const trustDomain = anyPath + "." + anyPath
// downstreamServiceIdentityMatcher needs to match XFCC headers in two cases:
// 1. Requests to cluster peered services through a mesh gateway. In this case, the XFCC header looks like the following (I added a new line after each ; for readability)
// By=spiffe://950df996-caef-ddef-ec5f-8d18a153b7b2.consul/gateway/mesh/dc/alpha;
// Hash=...;
// Cert=...;
// Chain=...;
// Subject="";
// URI=spiffe://c7e1d24a-eed8-10a3-286a-52bdb6b6a6fd.consul/ns/default/dc/primary/svc/s1,By=spiffe://950df996-caef-ddef-ec5f-8d18a153b7b2.consul/ns/default/dc/alpha/svc/s2;
// Hash=...;
// Cert=...;
// Chain=...;
// Subject="";
// URI=spiffe://950df996-caef-ddef-ec5f-8d18a153b7b2.consul/gateway/mesh/dc/alpha
//
// 2. Requests directly to another service
// By=spiffe://ae9dbea8-c1dd-7356-b211-c564f7917100.consul/ns/default/dc/primary/svc/s2;
// Hash=396218588ebc1655d32a49b68cedd6b66b9de7b3d69d0c0451bc5818132377d0;
// Cert=...;
// Chain=...;
// Subject="";
// URI=spiffe://ae9dbea8-c1dd-7356-b211-c564f7917100.consul/ns/default/dc/primary/svc/s1
//
// In either case, the regex matches the downstream service's spiffe id because mesh gateways use a different spiffe id format.
// Envoy requires us to include the trailing and leading .* to properly extract the properly submatch.
const downstreamServiceIdentityMatcher = ".*URI=spiffe://(" + trustDomain +
")(?:/ap/(" + anyPath +
"))?/ns/(" + anyPath +
")/dc/(" + anyPath +
")/svc/([^/;,]+).*"
func parseXFCCToDynamicMetaHTTPFilter() (*envoy_http_v3.HttpFilter, error) {
var rules []*envoy_http_header_to_meta_v3.Config_Rule
fields := []struct {
name string
sub string
}{
{
name: "trust-domain",
sub: `\1`,
},
{
name: "partition",
sub: `\2`,
},
{
name: "namespace",
sub: `\3`,
},
{
name: "datacenter",
sub: `\4`,
},
{
name: "service",
sub: `\5`,
},
}
for _, f := range fields {
rules = append(rules, &envoy_http_header_to_meta_v3.Config_Rule{
Header: "x-forwarded-client-cert",
OnHeaderPresent: &envoy_http_header_to_meta_v3.Config_KeyValuePair{
MetadataNamespace: "consul",
Key: f.name,
RegexValueRewrite: &envoy_matcher_v3.RegexMatchAndSubstitute{
Pattern: &envoy_matcher_v3.RegexMatcher{
Regex: downstreamServiceIdentityMatcher,
EngineType: &envoy_matcher_v3.RegexMatcher_GoogleRe2{
GoogleRe2: &envoy_matcher_v3.RegexMatcher_GoogleRE2{},
},
},
Substitution: f.sub,
},
},
})
}
cfg := &envoy_http_header_to_meta_v3.Config{RequestRules: rules}
return makeEnvoyHTTPFilter("envoy.filters.http.header_to_metadata", cfg)
}
func makeSpiffePattern(src rbacService) string {
var (
host = src.TrustDomain
ap = src.PartitionOrDefault()
ns = src.NamespaceOrDefault()
svc = src.Name
)
// Validate proper wildcarding
if ns == structs.WildcardSpecifier && svc != structs.WildcardSpecifier {
panic(fmt.Sprintf("not possible to have a wildcarded namespace %q but an exact service %q", ns, svc))
}
if ap == structs.WildcardSpecifier {
panic("not possible to have a wildcarded source partition")
}
if src.Peer == structs.WildcardSpecifier {
panic("not possible to have a wildcarded source peer")
}
// Match on any namespace or service if it is a wildcard, or on a specific value otherwise.
if ns == structs.WildcardSpecifier {
ns = anyPath
}
if svc == structs.WildcardSpecifier {
svc = anyPath
}
// If service is imported from a peer, the SpiffeID must
// refer to its remote partition and trust domain.
if src.Peer != "" {
ap = src.ExportedPartition
host = src.TrustDomain
}
id := connect.SpiffeIDService{
Namespace: ns,
Service: svc,
Host: host,
// Datacenter is not verified by RBAC, so we match on any value.
Datacenter: anyPath,
// Partition can only ever be an exact value.
Partition: ap,
}
return fmt.Sprintf(`^%s://%s%s$`, id.URI().Scheme, id.Host, id.URI().Path)
}
func makeSpiffeMeshGatewayPattern(gwTrustDomain, gwPartition string) string {
id := connect.SpiffeIDMeshGateway{
Host: gwTrustDomain,
Partition: gwPartition,
// Datacenter is not verified by RBAC, so we match on any value.
Datacenter: anyPath,
}
return fmt.Sprintf(`^%s://%s%s$`, id.URI().Scheme, id.Host, id.URI().Path)
}
func anyPermission() *envoy_rbac_v3.Permission {
return &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_Any{Any: true},
}
}
func convertPermission(perm *structs.IntentionPermission) *envoy_rbac_v3.Permission {
// NOTE: this does not do anything with perm.Action
if perm.HTTP == nil {
return anyPermission()
}
var parts []*envoy_rbac_v3.Permission
switch {
case perm.HTTP.PathExact != "":
parts = append(parts, &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_UrlPath{
UrlPath: &envoy_matcher_v3.PathMatcher{
Rule: &envoy_matcher_v3.PathMatcher_Path{
Path: &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_Exact{
Exact: perm.HTTP.PathExact,
},
},
},
},
},
})
case perm.HTTP.PathPrefix != "":
parts = append(parts, &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_UrlPath{
UrlPath: &envoy_matcher_v3.PathMatcher{
Rule: &envoy_matcher_v3.PathMatcher_Path{
Path: &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_Prefix{
Prefix: perm.HTTP.PathPrefix,
},
},
},
},
},
})
case perm.HTTP.PathRegex != "":
parts = append(parts, &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_UrlPath{
UrlPath: &envoy_matcher_v3.PathMatcher{
Rule: &envoy_matcher_v3.PathMatcher_Path{
Path: &envoy_matcher_v3.StringMatcher{
MatchPattern: &envoy_matcher_v3.StringMatcher_SafeRegex{
SafeRegex: makeEnvoyRegexMatch(perm.HTTP.PathRegex),
},
},
},
},
},
})
}
for _, hdr := range perm.HTTP.Header {
eh := &envoy_route_v3.HeaderMatcher{
Name: hdr.Name,
}
switch {
case hdr.Exact != "":
eh.HeaderMatchSpecifier = &envoy_route_v3.HeaderMatcher_ExactMatch{
ExactMatch: hdr.Exact,
}
case hdr.Regex != "":
eh.HeaderMatchSpecifier = &envoy_route_v3.HeaderMatcher_SafeRegexMatch{
SafeRegexMatch: makeEnvoyRegexMatch(hdr.Regex),
}
case hdr.Prefix != "":
eh.HeaderMatchSpecifier = &envoy_route_v3.HeaderMatcher_PrefixMatch{
PrefixMatch: hdr.Prefix,
}
case hdr.Suffix != "":
eh.HeaderMatchSpecifier = &envoy_route_v3.HeaderMatcher_SuffixMatch{
SuffixMatch: hdr.Suffix,
}
case hdr.Present:
eh.HeaderMatchSpecifier = &envoy_route_v3.HeaderMatcher_PresentMatch{
PresentMatch: true,
}
default:
continue // skip this impossible situation
}
if hdr.Invert {
eh.InvertMatch = true
}
parts = append(parts, &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_Header{
Header: eh,
},
})
}
if len(perm.HTTP.Methods) > 0 {
methodHeaderRegex := strings.Join(perm.HTTP.Methods, "|")
eh := &envoy_route_v3.HeaderMatcher{
Name: ":method",
HeaderMatchSpecifier: &envoy_route_v3.HeaderMatcher_SafeRegexMatch{
SafeRegexMatch: makeEnvoyRegexMatch(methodHeaderRegex),
},
}
parts = append(parts, &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_Header{
Header: eh,
},
})
}
// NOTE: if for some reason we errantly allow a permission to be defined
// with a body of "http{}" then we'll end up treating that like "ANY" here.
return andPermissions(parts)
}
func notPermission(perm *envoy_rbac_v3.Permission) *envoy_rbac_v3.Permission {
return &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_NotRule{NotRule: perm},
}
}
func andPermissions(perms []*envoy_rbac_v3.Permission) *envoy_rbac_v3.Permission {
switch len(perms) {
case 0:
return anyPermission()
case 1:
return perms[0]
default:
return &envoy_rbac_v3.Permission{
Rule: &envoy_rbac_v3.Permission_AndRules{
AndRules: &envoy_rbac_v3.Permission_Set{
Rules: perms,
},
},
}
}
}