package acl import ( "github.com/armon/go-radix" ) var ( // allowAll is a singleton policy which allows all // non-management actions allowAll ACL // denyAll is a singleton policy which denies all actions denyAll ACL // manageAll is a singleton policy which allows all // actions, including management manageAll ACL ) func init() { // Setup the singletons allowAll = &StaticACL{ allowManage: false, defaultAllow: true, } denyAll = &StaticACL{ allowManage: false, defaultAllow: false, } manageAll = &StaticACL{ allowManage: true, defaultAllow: true, } } // ACL is the interface for policy enforcement. type ACL interface { // KeyRead checks for permission to read a given key KeyRead(string) bool // KeyWrite checks for permission to write a given key KeyWrite(string) bool // KeyWritePrefix checks for permission to write to an // entire key prefix. This means there must be no sub-policies // that deny a write. KeyWritePrefix(string) bool // ServiceWrite checks for permission to read a given service ServiceWrite(string) bool // ServiceRead checks for permission to read a given service ServiceRead(string) bool // EventRead determines if a specific event can be queried. EventRead(string) bool // EventWrite determines if a specific event may be fired. EventWrite(string) bool // KeyringRead determines if the encryption keyring used in // the gossip layer can be read. KeyringRead() bool // KeyringWrite determines if the keyring can be manipulated KeyringWrite() bool // ACLList checks for permission to list all the ACLs ACLList() bool // ACLModify checks for permission to manipulate ACLs ACLModify() bool } // StaticACL is used to implement a base ACL policy. It either // allows or denies all requests. This can be used as a parent // ACL to act in a blacklist or whitelist mode. type StaticACL struct { allowManage bool defaultAllow bool } func (s *StaticACL) KeyRead(string) bool { return s.defaultAllow } func (s *StaticACL) KeyWrite(string) bool { return s.defaultAllow } func (s *StaticACL) KeyWritePrefix(string) bool { return s.defaultAllow } func (s *StaticACL) ServiceRead(string) bool { return s.defaultAllow } func (s *StaticACL) ServiceWrite(string) bool { return s.defaultAllow } func (s *StaticACL) EventRead(string) bool { return s.defaultAllow } func (s *StaticACL) EventWrite(string) bool { return s.defaultAllow } func (s *StaticACL) KeyringRead() bool { return s.defaultAllow } func (s *StaticACL) KeyringWrite() bool { return s.defaultAllow } func (s *StaticACL) ACLList() bool { return s.allowManage } func (s *StaticACL) ACLModify() bool { return s.allowManage } // AllowAll returns an ACL rule that allows all operations func AllowAll() ACL { return allowAll } // DenyAll returns an ACL rule that denies all operations func DenyAll() ACL { return denyAll } // ManageAll returns an ACL rule that can manage all resources func ManageAll() ACL { return manageAll } // RootACL returns a possible ACL if the ID matches a root policy func RootACL(id string) ACL { switch id { case "allow": return allowAll case "deny": return denyAll case "manage": return manageAll default: return nil } } // PolicyACL is used to wrap a set of ACL policies to provide // the ACL interface. type PolicyACL struct { // parent is used to resolve policy if we have // no matching rule. parent ACL // keyRules contains the key policies keyRules *radix.Tree // serviceRules contains the service policies serviceRules *radix.Tree // eventRules contains the user event policies eventRules *radix.Tree // keyringRules contains the keyring policies. The keyring has // a very simple yes/no without prefix mathing, so here we // don't need to use a radix tree. keyringRule string } // New is used to construct a policy based ACL from a set of policies // and a parent policy to resolve missing cases. func New(parent ACL, policy *Policy) (*PolicyACL, error) { p := &PolicyACL{ parent: parent, keyRules: radix.New(), serviceRules: radix.New(), eventRules: radix.New(), } // Load the key policy for _, kp := range policy.Keys { p.keyRules.Insert(kp.Prefix, kp.Policy) } // Load the service policy for _, sp := range policy.Services { p.serviceRules.Insert(sp.Name, sp.Policy) } // Load the event policy for _, ep := range policy.Events { p.eventRules.Insert(ep.Event, ep.Policy) } // Load the keyring policy p.keyringRule = policy.Keyring return p, nil } // KeyRead returns if a key is allowed to be read func (p *PolicyACL) KeyRead(key string) bool { // Look for a matching rule _, rule, ok := p.keyRules.LongestPrefix(key) if ok { switch rule.(string) { case KeyPolicyRead: return true case KeyPolicyWrite: return true default: return false } } // No matching rule, use the parent. return p.parent.KeyRead(key) } // KeyWrite returns if a key is allowed to be written func (p *PolicyACL) KeyWrite(key string) bool { // Look for a matching rule _, rule, ok := p.keyRules.LongestPrefix(key) if ok { switch rule.(string) { case KeyPolicyWrite: return true default: return false } } // No matching rule, use the parent. return p.parent.KeyWrite(key) } // KeyWritePrefix returns if a prefix is allowed to be written func (p *PolicyACL) KeyWritePrefix(prefix string) bool { // Look for a matching rule that denies _, rule, ok := p.keyRules.LongestPrefix(prefix) if ok && rule.(string) != KeyPolicyWrite { return false } // Look if any of our children have a deny policy deny := false p.keyRules.WalkPrefix(prefix, func(path string, rule interface{}) bool { // We have a rule to prevent a write in a sub-directory! if rule.(string) != KeyPolicyWrite { deny = true return true } return false }) // Deny the write if any sub-rules may be violated if deny { return false } // If we had a matching rule, done if ok { return true } // No matching rule, use the parent. return p.parent.KeyWritePrefix(prefix) } // ServiceRead checks if reading (discovery) of a service is allowed func (p *PolicyACL) ServiceRead(name string) bool { // Check for an exact rule or catch-all _, rule, ok := p.serviceRules.LongestPrefix(name) if ok { switch rule { case ServicePolicyWrite: return true case ServicePolicyRead: return true default: return false } } // No matching rule, use the parent. return p.parent.ServiceRead(name) } // ServiceWrite checks if writing (registering) a service is allowed func (p *PolicyACL) ServiceWrite(name string) bool { // Check for an exact rule or catch-all _, rule, ok := p.serviceRules.LongestPrefix(name) if ok { switch rule { case ServicePolicyWrite: return true default: return false } } // No matching rule, use the parent. return p.parent.ServiceWrite(name) } // EventRead is used to determine if the policy allows for a // specific user event to be read. func (p *PolicyACL) EventRead(name string) bool { // Longest-prefix match on event names if _, rule, ok := p.eventRules.LongestPrefix(name); ok { switch rule { case EventPolicyRead: return true case EventPolicyWrite: return true default: return false } } // Nothing matched, use parent return p.parent.EventRead(name) } // EventWrite is used to determine if new events can be created // (fired) by the policy. func (p *PolicyACL) EventWrite(name string) bool { // Longest-prefix match event names if _, rule, ok := p.eventRules.LongestPrefix(name); ok { return rule == EventPolicyWrite } // No match, use parent return p.parent.EventWrite(name) } // KeyringRead is used to determine if the keyring can be // read by the current ACL token. func (p *PolicyACL) KeyringRead() bool { switch p.keyringRule { case KeyringPolicyRead, KeyringPolicyWrite: return true default: return false } } // KeyringWrite determines if the keyring can be manipulated. func (p *PolicyACL) KeyringWrite() bool { return p.keyringRule == KeyringPolicyWrite } // ACLList checks if listing of ACLs is allowed func (p *PolicyACL) ACLList() bool { return p.parent.ACLList() } // ACLModify checks if modification of ACLs is allowed func (p *PolicyACL) ACLModify() bool { return p.parent.ACLModify() }