// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: BUSL-1.1 package acl import ( "github.com/armon/go-radix" ) type policyAuthorizer struct { // aclRule contains the acl management policy. aclRule *policyAuthorizerRule // agentRules contain the exact-match agent policies agentRules *radix.Tree // identityRules contains the identity exact-match policies identityRules *radix.Tree // intentionRules contains the service intention exact-match policies intentionRules *radix.Tree // trafficPermissionsRules contains the service intention exact-match policies trafficPermissionsRules *radix.Tree // keyRules contains the key exact-match policies keyRules *radix.Tree // nodeRules contains the node exact-match policies nodeRules *radix.Tree // serviceRules contains the service exact-match policies serviceRules *radix.Tree // sessionRules contains the session exact-match policies sessionRules *radix.Tree // eventRules contains the user event exact-match policies eventRules *radix.Tree // preparedQueryRules contains the prepared query exact-match policies preparedQueryRules *radix.Tree // keyringRule contains the keyring policies. The keyring has // a very simple yes/no without prefix matching, so here we // don't need to use a radix tree. keyringRule *policyAuthorizerRule // operatorRule contains the operator policies. operatorRule *policyAuthorizerRule // meshRule contains the mesh policies. meshRule *policyAuthorizerRule // peeringRule contains the peering policies. peeringRule *policyAuthorizerRule // embedded enterprise policy authorizer enterprisePolicyAuthorizer } // policyAuthorizerRule is a struct to hold an ACL policy decision along // with extra Consul Enterprise specific policy type policyAuthorizerRule struct { // decision is the enforcement decision for this rule access AccessLevel // Embedded Consul Enterprise specific policy EnterpriseRule } // policyAuthorizerRadixLeaf is used as the main // structure for storing in the radix.Tree's within the // PolicyAuthorizer type policyAuthorizerRadixLeaf struct { exact *policyAuthorizerRule prefix *policyAuthorizerRule } // getPolicy first attempts to get an exact match for the segment from the "exact" tree and then falls // back to getting the policy for the longest prefix from the "prefix" tree func getPolicy(segment string, tree *radix.Tree) (policy *policyAuthorizerRule, found bool) { found = false tree.WalkPath(segment, func(path string, leaf interface{}) bool { policies := leaf.(*policyAuthorizerRadixLeaf) if policies.exact != nil && path == segment { found = true policy = policies.exact return true } if policies.prefix != nil { found = true policy = policies.prefix } return false }) return } // insertPolicyIntoRadix will insert or update part of the leaf node within the radix tree corresponding to the // given segment. To update only one of the exact match or prefix match policy, set the value you want to leave alone // to nil when calling the function. func insertPolicyIntoRadix(segment string, policy string, ent *EnterpriseRule, tree *radix.Tree, prefix bool) error { al, err := AccessLevelFromString(policy) if err != nil { return err } policyRule := policyAuthorizerRule{ access: al, } if ent != nil { policyRule.EnterpriseRule = *ent } var policyLeaf *policyAuthorizerRadixLeaf leaf, found := tree.Get(segment) if found { policyLeaf = leaf.(*policyAuthorizerRadixLeaf) } else { policyLeaf = &policyAuthorizerRadixLeaf{} tree.Insert(segment, policyLeaf) } if prefix { policyLeaf.prefix = &policyRule } else { policyLeaf.exact = &policyRule } return nil } // enforce is a convenience function to func enforce(rule AccessLevel, requiredPermission AccessLevel) EnforcementDecision { switch rule { case AccessWrite: // grants read, list and write permissions return Allow case AccessList: // grants read and list permissions if requiredPermission == AccessList || requiredPermission == AccessRead { return Allow } else { return Deny } case AccessRead: // grants just read permissions if requiredPermission == AccessRead { return Allow } else { return Deny } case AccessDeny: // explicit denial - do not recurse return Deny default: // need to recurse as there was no specific access level set return Default } } func defaultIsAllow(decision EnforcementDecision) EnforcementDecision { switch decision { case Allow, Default: return Allow default: return Deny } } func (p *policyAuthorizer) loadRules(policy *PolicyRules) error { // Load the agent policy (exact matches) for _, ap := range policy.Agents { if err := insertPolicyIntoRadix(ap.Node, ap.Policy, nil, p.agentRules, false); err != nil { return err } } // Load the agent policy (prefix matches) for _, ap := range policy.AgentPrefixes { if err := insertPolicyIntoRadix(ap.Node, ap.Policy, nil, p.agentRules, true); err != nil { return err } } // Load the identity policy (exact matches) for _, id := range policy.Identities { if err := insertPolicyIntoRadix(id.Name, id.Policy, &id.EnterpriseRule, p.identityRules, false); err != nil { return err } intention := id.Intentions if intention == "" { switch id.Policy { case PolicyRead, PolicyWrite: intention = PolicyRead default: intention = PolicyDeny } } if err := insertPolicyIntoRadix(id.Name, intention, &id.EnterpriseRule, p.trafficPermissionsRules, false); err != nil { return err } } // Load the identity policy (prefix matches) for _, id := range policy.IdentityPrefixes { if err := insertPolicyIntoRadix(id.Name, id.Policy, &id.EnterpriseRule, p.identityRules, true); err != nil { return err } intention := id.Intentions if intention == "" { switch id.Policy { case PolicyRead, PolicyWrite: intention = PolicyRead default: intention = PolicyDeny } } if err := insertPolicyIntoRadix(id.Name, intention, &id.EnterpriseRule, p.trafficPermissionsRules, true); err != nil { return err } } // Load the key policy (exact matches) for _, kp := range policy.Keys { if err := insertPolicyIntoRadix(kp.Prefix, kp.Policy, &kp.EnterpriseRule, p.keyRules, false); err != nil { return err } } // Load the key policy (prefix matches) for _, kp := range policy.KeyPrefixes { if err := insertPolicyIntoRadix(kp.Prefix, kp.Policy, &kp.EnterpriseRule, p.keyRules, true); err != nil { return err } } // Load the node policy (exact matches) for _, np := range policy.Nodes { if err := insertPolicyIntoRadix(np.Name, np.Policy, &np.EnterpriseRule, p.nodeRules, false); err != nil { return err } } // Load the node policy (prefix matches) for _, np := range policy.NodePrefixes { if err := insertPolicyIntoRadix(np.Name, np.Policy, &np.EnterpriseRule, p.nodeRules, true); err != nil { return err } } // Load the service policy (exact matches) for _, sp := range policy.Services { if err := insertPolicyIntoRadix(sp.Name, sp.Policy, &sp.EnterpriseRule, p.serviceRules, false); err != nil { return err } intention := sp.Intentions if intention == "" { switch sp.Policy { case PolicyRead, PolicyWrite: intention = PolicyRead default: intention = PolicyDeny } } if err := insertPolicyIntoRadix(sp.Name, intention, &sp.EnterpriseRule, p.intentionRules, false); err != nil { return err } } // Load the service policy (prefix matches) for _, sp := range policy.ServicePrefixes { if err := insertPolicyIntoRadix(sp.Name, sp.Policy, &sp.EnterpriseRule, p.serviceRules, true); err != nil { return err } intention := sp.Intentions if intention == "" { switch sp.Policy { case PolicyRead, PolicyWrite: intention = PolicyRead default: intention = PolicyDeny } } if err := insertPolicyIntoRadix(sp.Name, intention, &sp.EnterpriseRule, p.intentionRules, true); err != nil { return err } } // Load the session policy (exact matches) for _, sp := range policy.Sessions { if err := insertPolicyIntoRadix(sp.Node, sp.Policy, nil, p.sessionRules, false); err != nil { return err } } // Load the session policy (prefix matches) for _, sp := range policy.SessionPrefixes { if err := insertPolicyIntoRadix(sp.Node, sp.Policy, nil, p.sessionRules, true); err != nil { return err } } // Load the event policy (exact matches) for _, ep := range policy.Events { if err := insertPolicyIntoRadix(ep.Event, ep.Policy, nil, p.eventRules, false); err != nil { return err } } // Load the event policy (prefix matches) for _, ep := range policy.EventPrefixes { if err := insertPolicyIntoRadix(ep.Event, ep.Policy, nil, p.eventRules, true); err != nil { return err } } // Load the prepared query policy (exact matches) for _, qp := range policy.PreparedQueries { if err := insertPolicyIntoRadix(qp.Prefix, qp.Policy, nil, p.preparedQueryRules, false); err != nil { return err } } // Load the prepared query policy (prefix matches) for _, qp := range policy.PreparedQueryPrefixes { if err := insertPolicyIntoRadix(qp.Prefix, qp.Policy, nil, p.preparedQueryRules, true); err != nil { return err } } // Load the acl policy if policy.ACL != "" { access, err := AccessLevelFromString(policy.ACL) if err != nil { return err } p.aclRule = &policyAuthorizerRule{access: access} } // Load the keyring policy if policy.Keyring != "" { access, err := AccessLevelFromString(policy.Keyring) if err != nil { return err } p.keyringRule = &policyAuthorizerRule{access: access} } // Load the operator policy if policy.Operator != "" { access, err := AccessLevelFromString(policy.Operator) if err != nil { return err } p.operatorRule = &policyAuthorizerRule{access: access} } // Load the mesh policy if policy.Mesh != "" { access, err := AccessLevelFromString(policy.Mesh) if err != nil { return err } p.meshRule = &policyAuthorizerRule{access: access} } // Load the peering policy if policy.Peering != "" { access, err := AccessLevelFromString(policy.Peering) if err != nil { return err } p.peeringRule = &policyAuthorizerRule{access: access} } return nil } func newPolicyAuthorizer(policies []*Policy, ent *Config) (*policyAuthorizer, error) { policy := MergePolicies(policies) return newPolicyAuthorizerFromRules(&policy.PolicyRules, ent) } func newPolicyAuthorizerFromRules(rules *PolicyRules, ent *Config) (*policyAuthorizer, error) { p := &policyAuthorizer{ agentRules: radix.New(), identityRules: radix.New(), intentionRules: radix.New(), trafficPermissionsRules: radix.New(), keyRules: radix.New(), nodeRules: radix.New(), serviceRules: radix.New(), sessionRules: radix.New(), eventRules: radix.New(), preparedQueryRules: radix.New(), } p.enterprisePolicyAuthorizer.init(ent) if err := p.loadRules(rules); err != nil { return nil, err } return p, nil } // enforceCallbacks are to be passed to anyAllowed or allAllowed. The interface{} // parameter will be a value stored in the radix.Tree passed to those functions. // prefixOnly indicates that only we only want to consider the prefix matching rule // if any. The return value indicates whether this one leaf node in the tree would // allow, deny or make no decision regarding some authorization. type enforceCallback func(raw interface{}, prefixOnly bool) EnforcementDecision func anyAllowed(tree *radix.Tree, enforceFn enforceCallback) EnforcementDecision { decision := Default // special case for handling a catch-all prefix rule. If the rule would Deny access then our default decision // should be to Deny, but this decision should still be overridable with other more specific rules. if raw, found := tree.Get(""); found { decision = enforceFn(raw, true) if decision == Allow { return Allow } } tree.Walk(func(path string, raw interface{}) bool { if enforceFn(raw, false) == Allow { decision = Allow return true } return false }) return decision } func allAllowed(tree *radix.Tree, enforceFn enforceCallback) EnforcementDecision { decision := Default // look for a "" prefix rule if raw, found := tree.Get(""); found { // ensure that the empty prefix rule would allow the access // if it does allow it we still must check all the other rules to ensure // nothing overrides the top level grant with a different access level // if not we can return early decision = enforceFn(raw, true) // the top level prefix rule denied access so we can return early. if decision == Deny { return Deny } } tree.Walk(func(path string, raw interface{}) bool { if enforceFn(raw, false) == Deny { decision = Deny return true } return false }) return decision } func (authz *policyAuthorizer) anyAllowed(tree *radix.Tree, requiredPermission AccessLevel) EnforcementDecision { return anyAllowed(tree, func(raw interface{}, prefixOnly bool) EnforcementDecision { leaf := raw.(*policyAuthorizerRadixLeaf) decision := Default if leaf.prefix != nil { decision = enforce(leaf.prefix.access, requiredPermission) } if prefixOnly || decision == Allow || leaf.exact == nil { return decision } return enforce(leaf.exact.access, requiredPermission) }) } func (authz *policyAuthorizer) allAllowed(tree *radix.Tree, requiredPermission AccessLevel) EnforcementDecision { return allAllowed(tree, func(raw interface{}, prefixOnly bool) EnforcementDecision { leaf := raw.(*policyAuthorizerRadixLeaf) prefixDecision := Default if leaf.prefix != nil { prefixDecision = enforce(leaf.prefix.access, requiredPermission) } if prefixOnly || prefixDecision == Deny || leaf.exact == nil { return prefixDecision } decision := enforce(leaf.exact.access, requiredPermission) if decision == Default { // basically this means defer to the prefix decision as the // authorizer rule made no decision with an exact match rule return prefixDecision } return decision }) } // ACLRead checks if listing of ACLs is allowed func (p *policyAuthorizer) ACLRead(*AuthorizerContext) EnforcementDecision { if p.aclRule != nil { return enforce(p.aclRule.access, AccessRead) } return Default } // ACLWrite checks if modification of ACLs is allowed func (p *policyAuthorizer) ACLWrite(*AuthorizerContext) EnforcementDecision { if p.aclRule != nil { return enforce(p.aclRule.access, AccessWrite) } return Default } // AgentRead checks for permission to read from agent endpoints for a given // node. func (p *policyAuthorizer) AgentRead(node string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(node, p.agentRules); ok { return enforce(rule.access, AccessRead) } return Default } // AgentWrite checks for permission to make changes via agent endpoints for a // given node. func (p *policyAuthorizer) AgentWrite(node string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(node, p.agentRules); ok { return enforce(rule.access, AccessWrite) } return Default } // Snapshot checks if taking and restoring snapshots is allowed. func (p *policyAuthorizer) Snapshot(_ *AuthorizerContext) EnforcementDecision { if p.aclRule != nil { return enforce(p.aclRule.access, AccessWrite) } return Default } // EventRead is used to determine if the policy allows for a // specific user event to be read. func (p *policyAuthorizer) EventRead(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.eventRules); ok { return enforce(rule.access, AccessRead) } return Default } // EventWrite is used to determine if new events can be created // (fired) by the policy. func (p *policyAuthorizer) EventWrite(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.eventRules); ok { return enforce(rule.access, AccessWrite) } return Default } // IdentityRead checks for permission to read a given workload identity. func (p *policyAuthorizer) IdentityRead(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.identityRules); ok { return enforce(rule.access, AccessRead) } return Default } // IdentityReadAll checks for permission to read all workload identities. func (p *policyAuthorizer) IdentityReadAll(_ *AuthorizerContext) EnforcementDecision { return p.allAllowed(p.identityRules, AccessRead) } // IdentityWrite checks for permission to create or update a given // workload identity. func (p *policyAuthorizer) IdentityWrite(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.identityRules); ok { return enforce(rule.access, AccessWrite) } return Default } // IdentityWriteAny checks for write permission on any workload identity. func (p *policyAuthorizer) IdentityWriteAny(_ *AuthorizerContext) EnforcementDecision { return p.anyAllowed(p.identityRules, AccessWrite) } // IntentionDefaultAllow returns whether the default behavior when there are // no matching intentions is to allow or deny. func (p *policyAuthorizer) IntentionDefaultAllow(_ *AuthorizerContext) EnforcementDecision { // We always go up, this can't be determined by a policy. return Default } // IntentionRead checks if reading an intention is allowed. func (p *policyAuthorizer) IntentionRead(prefix string, _ *AuthorizerContext) EnforcementDecision { if prefix == "*" { return p.anyAllowed(p.intentionRules, AccessRead) } if rule, ok := getPolicy(prefix, p.intentionRules); ok { return enforce(rule.access, AccessRead) } return Default } // IntentionWrite checks if writing (creating, updating, or deleting) of an // intention is allowed. func (p *policyAuthorizer) IntentionWrite(prefix string, _ *AuthorizerContext) EnforcementDecision { if prefix == "*" { return p.allAllowed(p.intentionRules, AccessWrite) } if rule, ok := getPolicy(prefix, p.intentionRules); ok { return enforce(rule.access, AccessWrite) } return Default } // TrafficPermissionsRead checks if reading of traffic permissions is allowed. func (p *policyAuthorizer) TrafficPermissionsRead(prefix string, _ *AuthorizerContext) EnforcementDecision { if prefix == "*" { return p.anyAllowed(p.trafficPermissionsRules, AccessRead) } if rule, ok := getPolicy(prefix, p.trafficPermissionsRules); ok { return enforce(rule.access, AccessRead) } return Default } // TrafficPermissionsWrite checks if writing (creating, updating, or deleting) of traffic // permissions is allowed. func (p *policyAuthorizer) TrafficPermissionsWrite(prefix string, _ *AuthorizerContext) EnforcementDecision { if prefix == "*" { return p.allAllowed(p.trafficPermissionsRules, AccessWrite) } if rule, ok := getPolicy(prefix, p.trafficPermissionsRules); ok { return enforce(rule.access, AccessWrite) } return Default } // KeyRead returns if a key is allowed to be read func (p *policyAuthorizer) KeyRead(key string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(key, p.keyRules); ok { return enforce(rule.access, AccessRead) } return Default } // KeyList returns if a key is allowed to be listed func (p *policyAuthorizer) KeyList(key string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(key, p.keyRules); ok { return enforce(rule.access, AccessList) } return Default } // KeyWrite returns if a key is allowed to be written func (p *policyAuthorizer) KeyWrite(key string, entCtx *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(key, p.keyRules); ok { decision := enforce(rule.access, AccessWrite) if decision == Allow { return defaultIsAllow(p.enterprisePolicyAuthorizer.enforce(&rule.EnterpriseRule, entCtx)) } return decision } return Default } // KeyWritePrefix returns if a prefix is allowed to be written // // This is mainly used to detect whether a whole tree within // the KV can be removed. For that reason we must be able to // delete everything under the prefix. First we must have "write" // on the prefix itself func (p *policyAuthorizer) KeyWritePrefix(prefix string, _ *AuthorizerContext) EnforcementDecision { // Conditions for Allow: // * The longest prefix match rule that would apply to the given prefix // grants AccessWrite // AND // * There are no rules (exact or prefix match) within/under the given prefix // that would NOT grant AccessWrite. // // Conditions for Deny: // * The longest prefix match rule that would apply to the given prefix // does not grant AccessWrite. // OR // * There is 1+ rules (exact or prefix match) within/under the given prefix // that do NOT grant AccessWrite. // // Conditions for Default: // * There is no prefix match rule that would apply to the given prefix. // AND // * There are no rules (exact or prefix match) within/under the given prefix // that would NOT grant AccessWrite. baseAccess := Default // Look for a prefix rule that would apply to the prefix we are checking // WalkPath starts at the root and walks down to the given prefix. // Therefore the last prefix rule we see is the one that matters p.keyRules.WalkPath(prefix, func(path string, leaf interface{}) bool { rule := leaf.(*policyAuthorizerRadixLeaf) if rule.prefix != nil { if rule.prefix.access != AccessWrite { baseAccess = Deny } else { baseAccess = Allow } } return false }) // baseAccess will be Deny only when a prefix rule was found and it didn't // grant AccessWrite. Otherwise the access level will be Default or Allow // neither of which should be returned right now. if baseAccess == Deny { return baseAccess } // Look if any of our children do not allow write access. This loop takes // into account both prefix and exact match rules. withinPrefixAccess := Default p.keyRules.WalkPrefix(prefix, func(path string, leaf interface{}) bool { rule := leaf.(*policyAuthorizerRadixLeaf) if rule.prefix != nil && rule.prefix.access != AccessWrite { withinPrefixAccess = Deny return true } if rule.exact != nil && rule.exact.access != AccessWrite { withinPrefixAccess = Deny return true } return false }) // Deny the write if any sub-rules may be violated. If none are violated then // we can defer to the baseAccess. if withinPrefixAccess == Deny { return Deny } // either Default or Allow at this point. Allow if there was a prefix rule // that was applicable and it granted write access. Default if there was // no applicable rule. return baseAccess } // KeyringRead is used to determine if the keyring can be // read by the current ACL token. func (p *policyAuthorizer) KeyringRead(*AuthorizerContext) EnforcementDecision { if p.keyringRule != nil { return enforce(p.keyringRule.access, AccessRead) } return Default } // KeyringWrite determines if the keyring can be manipulated. func (p *policyAuthorizer) KeyringWrite(*AuthorizerContext) EnforcementDecision { if p.keyringRule != nil { return enforce(p.keyringRule.access, AccessWrite) } return Default } // MeshRead determines if the read-only mesh functions are allowed. func (p *policyAuthorizer) MeshRead(ctx *AuthorizerContext) EnforcementDecision { if p.meshRule != nil { return enforce(p.meshRule.access, AccessRead) } // default to OperatorRead access return p.OperatorRead(ctx) } // MeshWrite determines if the state-changing mesh functions are // allowed. func (p *policyAuthorizer) MeshWrite(ctx *AuthorizerContext) EnforcementDecision { if p.meshRule != nil { return enforce(p.meshRule.access, AccessWrite) } // default to OperatorWrite access return p.OperatorWrite(ctx) } // PeeringRead determines if the read-only peering functions are allowed. func (p *policyAuthorizer) PeeringRead(ctx *AuthorizerContext) EnforcementDecision { if p.peeringRule != nil { return enforce(p.peeringRule.access, AccessRead) } // default to OperatorRead access return p.OperatorRead(ctx) } // PeeringWrite determines if the state-changing peering functions are // allowed. func (p *policyAuthorizer) PeeringWrite(ctx *AuthorizerContext) EnforcementDecision { if p.peeringRule != nil { return enforce(p.peeringRule.access, AccessWrite) } // default to OperatorWrite access return p.OperatorWrite(ctx) } // OperatorRead determines if the read-only operator functions are allowed. func (p *policyAuthorizer) OperatorRead(*AuthorizerContext) EnforcementDecision { if p.operatorRule != nil { return enforce(p.operatorRule.access, AccessRead) } return Default } // OperatorWrite determines if the state-changing operator functions are // allowed. func (p *policyAuthorizer) OperatorWrite(*AuthorizerContext) EnforcementDecision { if p.operatorRule != nil { return enforce(p.operatorRule.access, AccessWrite) } return Default } // NodeRead checks if reading (discovery) of a node is allowed func (p *policyAuthorizer) NodeRead(name string, ctx *AuthorizerContext) EnforcementDecision { // When reading a node imported from a peer we consider it to be allowed when: // - The request comes from a locally authenticated service, meaning that it // has service:write permissions on some name. // - The requester has permissions to read all nodes in its local cluster, // therefore it can also read imported nodes. if ctx.PeerOrEmpty() != "" { if p.ServiceWriteAny(nil) == Allow { return Allow } return p.NodeReadAll(nil) } if rule, ok := getPolicy(name, p.nodeRules); ok { return enforce(rule.access, AccessRead) } return Default } func (p *policyAuthorizer) NodeReadAll(_ *AuthorizerContext) EnforcementDecision { return p.allAllowed(p.nodeRules, AccessRead) } // NodeWrite checks if writing (registering) a node is allowed func (p *policyAuthorizer) NodeWrite(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.nodeRules); ok { return enforce(rule.access, AccessWrite) } return Default } // PreparedQueryRead checks if reading (listing) of a prepared query is // allowed - this isn't execution, just listing its contents. func (p *policyAuthorizer) PreparedQueryRead(prefix string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(prefix, p.preparedQueryRules); ok { return enforce(rule.access, AccessRead) } return Default } // PreparedQueryWrite checks if writing (creating, updating, or deleting) of a // prepared query is allowed. func (p *policyAuthorizer) PreparedQueryWrite(prefix string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(prefix, p.preparedQueryRules); ok { return enforce(rule.access, AccessWrite) } return Default } // ServiceRead checks if reading (discovery) of a service is allowed func (p *policyAuthorizer) ServiceRead(name string, ctx *AuthorizerContext) EnforcementDecision { // When reading a service imported from a peer we consider it to be allowed when: // - The request comes from a locally authenticated service, meaning that it // has service:write permissions on some name. // - The requester has permissions to read all services in its local cluster, // therefore it can also read imported services. if ctx.PeerOrEmpty() != "" { if p.ServiceWriteAny(nil) == Allow { return Allow } return p.ServiceReadAll(nil) } if rule, ok := getPolicy(name, p.serviceRules); ok { return enforce(rule.access, AccessRead) } return Default } func (p *policyAuthorizer) ServiceReadAll(_ *AuthorizerContext) EnforcementDecision { return p.allAllowed(p.serviceRules, AccessRead) } // ServiceReadPrefix determines whether service read is allowed within the given prefix. // // Access is allowed iff all the following are true: // - There's a read policy for the longest prefix that's shorter or equal to the provided prefix. // - There's no deny policy for any prefix that's longer than the given prefix. // - There's no deny policy for any exact match that's within the given prefix. func (p *policyAuthorizer) ServiceReadPrefix(prefix string, _ *AuthorizerContext) EnforcementDecision { access := Default // 1. Walk the prefix tree from root to the given prefix. Find the longest prefix matching ours, // and use that policy to determine our access as that is the most specific prefix, and it // should take precedence. p.serviceRules.WalkPath(prefix, func(path string, leaf interface{}) bool { rule := leaf.(*policyAuthorizerRadixLeaf) if rule.prefix != nil { switch rule.prefix.access { case AccessRead, AccessWrite: access = Allow default: access = Deny } } // Don't stop iteration because we want to visit all nodes down to our leaf to find the more specific match // as it should take precedence. return false }) // 2. Check rules "below" the given prefix. Access is allowed if there's no deny policy // for any prefix longer than ours or for any exact match that's within the prefix. p.serviceRules.WalkPrefix(prefix, func(path string, leaf interface{}) bool { rule := leaf.(*policyAuthorizerRadixLeaf) if rule.prefix != nil && (rule.prefix.access != AccessRead && rule.prefix.access != AccessWrite) { // If any prefix longer than the provided prefix has "deny" policy, then access is denied. access = Deny // We don't need to look at the rest of the tree in this case, so terminate early. return true } if rule.exact != nil && (rule.exact.access != AccessRead && rule.exact.access != AccessWrite) { // If any exact match policy has an explicit deny, then access is denied. access = Deny // We don't need to look at the rest of the tree in this case, so terminate early. return true } return false }) return access } // ServiceWrite checks if writing (registering) a service is allowed func (p *policyAuthorizer) ServiceWrite(name string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(name, p.serviceRules); ok { return enforce(rule.access, AccessWrite) } return Default } func (p *policyAuthorizer) ServiceWriteAny(_ *AuthorizerContext) EnforcementDecision { return p.anyAllowed(p.serviceRules, AccessWrite) } // SessionRead checks for permission to read sessions for a given node. func (p *policyAuthorizer) SessionRead(node string, _ *AuthorizerContext) EnforcementDecision { if rule, ok := getPolicy(node, p.sessionRules); ok { return enforce(rule.access, AccessRead) } return Default } // SessionWrite checks for permission to create sessions for a given node. func (p *policyAuthorizer) SessionWrite(node string, _ *AuthorizerContext) EnforcementDecision { // Check for an exact rule or catch-all if rule, ok := getPolicy(node, p.sessionRules); ok { return enforce(rule.access, AccessWrite) } return Default } func (p *policyAuthorizer) ToAllowAuthorizer() AllowAuthorizer { return AllowAuthorizer{Authorizer: p} }