Notes - MCS
Identification, Authentication and Authorization
Notes - MCS
Identification, Authentication and Authorization
  • Identification, Authentication and Authorization
  • Access Control Models
    • Access types
    • Least privilege principle
    • Access control models
      • Access control kinds
    • Access control kinds
    • Separation of duties
    • Segregation of duties
    • Information flow models
    • Multilevel security
    • Windows mandatory integrity control
    • Clark-Wilson Integrity Model
  • OAuth 2.0 Authorization Framework
    • Goal
    • Roles (RFC 6749)
    • Communication endpoints
    • Application (client)
    • OAuth tokens
    • OAuth flows
      • Code flow
      • Implicit flow
      • Resource owner password flow
      • Client credentials flow
    • Proof Key for Code Exchange (PKCE, RFC 7636)
    • Device authorization grant (RFC 8628)
    • Actual protocol flow
  • Linux Security Mechanisms
    • Mechanisms
    • Linux management privileges
    • Privilege Elevation
    • Capabilities
    • Files extended attributes (xattr)
    • File capabilities
    • Capability transfer across exec
    • Control groups (cgroups)
    • Linux Security Modules (LSM)
    • AppArmor
    • Confinement
  • Authentication Protocols
    • Identity attributes
    • Authentication
    • Authentication interactions
    • Authentication of people
      • Biometrics
      • Token-based OTP generators
      • PAP & CHAP (RFC 1334, 1992, RFC 1994, 1996)
      • S/Key (RFC 2289, 1998)
      • GSM
    • Host authentication
    • Service/server authentication
    • TLS (Transport Layer Security, RFC 8446)
    • SSH (Secure Shell, RFC 4251)
    • Single Sign-On (SSO)
    • Authentication metaprotocols
    • Authentication services
    • Key distribution services
  • PAM (Pluggable Authentication Modules)
    • Motivation
    • PAM
    • PAM APIs
    • Orchestration of PAM actions
    • Module invocation
    • Configuration files
    • PAM orchestration files
    • Scenario 1 – Local authentication
    • Scenario 2 – LDAP auth with local backoff
    • Scenario 3 – MS AD auth with local backoff
  • FIDO and FIDO2 framework
    • FIDO (Fast Identity Online) Alliance
    • Universal 2nd Factor (U2F) protocol
    • WebAuthn
    • Client to Authenticator Protocol (CTAP)
    • Passkeys
  • Authentication with Trusted Third Parties / KDCs
    • Shared-key authentication
    • Key Distribution Center (KDC) concept
    • Kerberos
  • Identity Management
    • Digital Identity
    • Identity Manager (IdM)
    • Identity Provider (IdP)
    • Authoritative source
    • Identity claim
    • Approachs
    • Credential
    • Privacy issues
    • Verifiable credential (VC)
    • Self-Sovereign Identity (SSI)
    • Interoperability
    • eIDAS
  • Anonymity and Privacy
    • Privacy
    • IEEE Digital Privacy Model
    • Privacy with computing technology
    • Privacy and companies
    • Privacy and IAA
    • Identification
    • Authentication
    • Anonymity
    • Microdata privacy issues
    • Microdata privacy enhancing
    • L-Diversity
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  • Basic approaches
  • Direct Approach
  • With password
  1. Authentication Protocols

Authentication interactions

Basic approaches

Direct approach:

  • Provide credentials.

  • Wait for a verdict.

  • Authenticator checks credentials against what it knows.

Challenge-response approach.

  • Get challenge.

  • Provide a response computed from the challenge and the credentials.

  • Wait for a verdict.

  • The authenticator checks the response for the challenge provided and the credentials it knows.

Direct Approach

With password

A password is matched with a stored value for a claimed identity.

Personal stored value:

  • Transformed by a unidirectional function.

    • Key Derivation Function (KDF).

    • Preferably slow!

    • Bcrypt, scrypt, Argon2, PBKDF2.

  • UNIX: DES hash + salt

  • Linux: KDF + salt

  • Windows: digest function

Advantage

  • Simplicity

  • Sharing

Problems

  • Usage of predictable passwords.

    • They enable dictionary attacks.

  • Different passwords for different systems.

    • To prevent impersonation by malicious admins.

    • Memory limitations.

  • Exchange along insecure communication channels.

    • Eavesdroppers can easily learn the password.

    • e.g. Unix remote services, PAP.

Last updated 1 year ago