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Security Service. Why do we need security in distributed system? Examples: banking, e-commerce, personal info, classified info Distributed systems are inherently insecure network. Security Service. Security Requirements Confidentiality Integrity Accountability Availability
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Security Service • Why do we need security in distributed system? • Examples: banking, e-commerce, personal info, classified info • Distributed systems are inherently insecure • network Security Service
Security Service • Security Requirements • Confidentiality • Integrity • Accountability • Availability • threats to Security • Gaining access directly • Obtaining authorized user info and access • Obtaining info through monitoring the comm. Channel • Modifying messages on the comm. Channel • Performing untraceable malicious actions • Denying participations Security Service
Security Service • Categories of threats • Leakage: unauthorized disclosure of information • Tempering: unauthorized modification of information • Resource stealing: unauthorized use of computing resources • Vandalism: destruction of information • Combined threats • Methods of Attack • Masquerading: obtain the identity of legitimate users • Eavesdropping: listen to and decode request message • Tampering : modify request messages • Replaying: repetition of request messages • Infiltration: • Attacks by legitimate users • Obtaining a legitimate user’s identity • Smuggling client or server objects, virus,worms Security Service
Security Service • Security Service Features • Identification and authentication • Authorization and access control • Auditing • Communications security • Non-repudiation • Administration of security policy • Encryption • Encryption uses an algorithm and a key to convert plain text into cypher text and vice versa • secret key • Public key Security Service
Secret Key Encryption • secret keys are known to two parties and not disclosed to any others • Use the same key for both encrypting and decrypting messages • Encryption and decryption functions may be public • The encryption and decryption are performed after the stubs have completed request marshalling and unmarshalling and it has been recognized that the server object is not local • Encryption can be kept entirely transparent for client and server programmer • Encryption is done by middleware or by stubs that are created by middleware • Distribution of secret keys to large numbers of objects is too complex Client A Server B Called Caller Stub Stub • Acquire Kab • f(Kab, M) {M}kab • send • Acquire Kab • Receive • f’(Kab, {M}kab) M {M}kab Security Service
Public Key Encryption • Public key encryption generate pairs of keys of which one is made publicly available and the other is kept private • Number of keys is only linear in relation to the number of objects • The execution of encryption and decryption function is more complex Client A Server B Called Caller Stub Stub • Acquire Kab • f(Kpb, M) {M}kpb • send • Generate (Kpb, Ksb) • Publish Kpb • Receive • g(Ksb, {M}kpb) M {M}kpb Security Service
Key Distribution • Secure key distribution mechanisms are needed for both secret and public key encryption • Key distribution service • Service has to be a trusted service • The registration of object with that service has to be trustworthy • Needham/Schroeder protocol Security Service
Key Distribution • Distributing secret keys Key Distribution Server AS 1:C,S,NC 2:{NC, S, KCS, {KCS, C}KS}KC 3:{KCS, C}KS Server S Client C 4:{NS}Kcs 5:{NS-1}Kcs Security Service
Key Distribution • Distributing public keys Key Distribution Server AS 1:C,S 4:S, C 5:{KPC, A}KSAS 2:{KPS, S}KSAS 3:{NC, C}KPS Server S Client C 6:{NC, NS}KPC 7:{NS}KPS Security Service
Higher-Level Security Services • Security Service Features • Firewalls • Identification and authentication • Authorization and access control • Auditing • Non-repudiation • Communications security • Administration of security policy Security Service
Firewalls • Firewalls are gateways that tightly control message traffic between private and public networks • Levels of control can vary • Monitor and audit network traffic • Allow/disallow certain types of packet through • Does not impact a distributed object systems if comm. does not pass through firewall (both in private network, or both in public network, etc). • Distributed object firewalls that understand the message traffic exchanged between clients and servers • Firewalls between distributed objects have to understand the encoding of object request • Firewalls have to be integrated with encryption techniques Private Network Firewall Public Network Security Service
Firewalls outbound firewalls inbound firewalls FWC1 FWS1 FWS2 FWC2 Client Server enclave S2 enclave C1 enclave C2 enclave S1 Security Service
Types of Firewalls • Packet Filtering • Allow all kinds of packets, but only to this IP address and this port • Allow incoming traffic only from the specified IP subnets • Application-level gateways (Figure 12.4) • CORBA and Firewalls • HTTP Tunneling: an IIOP request is enclosed in an HTTP envelope and sent via the HTTP protocol (Figure 12.5) • GIOP Proxies: callbacks • Security Socket Layer • A protocol on top of TCP/IP that adds security capabilities • SSL API is an extension to the TCP/IP socket API • Encryption of messages • Authentication of the server based on digital certificates and signatures • Optional authentication of the cleint Security Service
Authentication • Authentication techniques establish trust in a principal and its credentials • Both client and server objects are necessary to be authenticated • Authentication is implemented using encryption • Challenge-response protocol :AuthenticationServer :Client authenticate() challenge response() credentials Security Service
Credentials Credentials authenticated attributes Identity attributes Privileges Unauthenticated attributes Security Service
Access Control • Access control mechanisms decide whether or not an object request can be granted to a client object • A principal is a human user or a system entity that is registered in and authenticated to a system • Credentials contain the security attributes of a principal • Object invocation access policies determine whether a particular principal is allowed to perform an object request • Two forms of access policies: • Object invocation access policies are implemented by the object-oriented middleware • Application object access policies are enforced at an application level and implemented by the application developer Security Service
Perspective on Access Control • Client’s perspective • A request is either granted or not • Server’s perspective • Object invocation access policy is used: access control is transparent to the server programmer --- implemented by middleware • Application object access policy is used: server programmer must implement the access decision function. Input to the function is: • Credentials of the principal that requested an operation execution • Reference of the server object from which an execution is requested • Request operation • Parameters of the requested operation • Admin’s Perspective • Object invocation access policy is not transparent to admin. • Access rights define the modes of access that principals have to server objects • Access rights are often defined for types rather than objects Security Service
Security Service • Privileges and Privilege Delegation Scheme • Own privilege • Caller’s privilege • Combined privilege • Use both • Combine and generate new credentials Security Service
Security Model Credentials Credentials Client Target Object Current Current Binding ORB Security ORB Security Access Control Access Control Secure Invocation Secure Invocation ORB CORE Security Service
Security Service • Security Model • Clients, target objects, operation invocations • Building request transmitting the request executing an operation sending a reply • Figure 12.8 Security Service is closely tied with ORB and is not an independent object service, but an ORB service • Security-aware applications vs Security-unaware applications • Principles and Security Attributes (Figure 12.9) • Establish a security association: • usually, client trust, server authenticate • Binding between client and target • Security service provide current execution context (current) • Target object or Security Service decides operation permissions based on the current. (Access control …) • Auditing through auditing channel if required. Security Service
Security Conformance Levels • Security Conformance Levels • Level allows ORB security to be applied to applications that are not security-aware: authentication; security policies; provision of message integrity and confidentiality; access control policy • Level 2 = level 1 + enhanced integrity + trust + auditing Security Service
Security Service • Higher-Level Security Services • Firewalls: gateways that tightly control message traffic between private and public network • Authentication: establish trust in a principal and its credentials • Access control: decide whether or not an object request can be granted to a client object • Client: request is either granted or not • Server: • Performed by middleware (invocation policy define on object) • Server application make access control decisions based on the data: Request credentials References to server objects Requested operations Parameters to the requested operations • Admin: • Define the modes of access that principals have to server objects • Access rights are defined for types rather than objects Security Service
Security Service • Non-repudiation Services • Evidence Generation and Verification • Evidence Storage and Retrieval • Delivery Authority Security Service
Non-repudiation Services Object A Object B Dispute/ Judgement Service Req./Rep. Nonrepudiation Services Adjudicator Evidence Generation and Verification Service Req./Rep. Evidence Storage and Retrieval Delivery Authority Security Service
Security Service • Security Domains • Security Policies: • Hierarchy • Overlap • Conflict • Finding the Security Features of an ORB Get_service_information() • Authentication of a User Principal • Selecting Privileges Credentials: get_credentials(); set_privileges() • Making a Security Invocation Access_Decision object, access_allowed(); AuditDecision object, audit_needed(); audit_channel() Security Service
Security Service • Non-repudiation • Generate_token(): generate an unforgeable token to be used in the evidence • Verify_evidence(): check if evidence is valid • Form_complete_evidence(): use original token to generate further evidence, Security Service
Security Service • Application Security Interfaces • Common Security Types • Security Level 1 (for security-unaware applications) Interface Current:CORBA:Current{//PIDL Security::AttributeList get_attributes(in Security::AttributeTypeList attributes); }; For level 1, only allow the client to know what attributes are available • Security Level 2 (for security-aware applications) Current interface inherits the one form SecurityLevel1, extends functionality with references to the following objects: RequiredRights, AccessDecision, AuditDecision, and PrincipalAuthenticator, and Credentials objects. Security Service
Security Service • RequiredRights • Get_required_rights() • Set_required_rights() • PrincipalAuthenticator • Get_supported_authen_methods(); • Authenticate(); • Continue_authentication(); • Credentials • Copy() • Destroy() • Get_security_feature() • Get_attributes() • Set_privileges(); • Is_valid(); • Refresh(); Security Service
Security Service • Object • Get_policy() • Get_domain_managers() • Set_policy_overrides() Security Service