Applicability of Interfaces to Network Security Functions to Network-Based Security Services
Department of Software
Sungkyunkwan University2066 Seobu-Ro, Jangan-GuSuwonGyeonggi-Do16419Republic of Korea+82 31 299 4957+82 31 290 7996pauljeong@skku.eduhttp://iotlab.skku.edu/people-jaehoon-jeong.php
Department of Software
Sungkyunkwan University2066 Seobu-Ro, Jangan-GuSuwonGyeonggi-Do16419Republic of Korea+82 31 290 7222+82 31 299 6673swhyun77@skku.eduhttp://imtl.skku.ac.kr/
Korea Telecom
70 Yuseong-Ro, Yuseong-GuDaejeon305-811Republic of Korea+82 42 870 8409taejin.ahn@kt.com
Huawei
7453 Hickory HillSalineMI48176USA+1-734-604-0332shares@ndzh.com
Telefonica I+D
Jose Manuel Lara, 9Seville41013Spain+34 682 051 091diego.r.lopez@telefonica.comInternet-Draft
This document describes the applicability of Interface to Network Security Functions (I2NSF) to network-based security services in Network Functions Virtualization (NFV) environments, such as firewall, deep packet inspection, or attack mitigation engines.
Interface to Network Security Functions (I2NSF) defined a framework and interfaces for interacting with Network Security Functions (NSFs).
The I2NSF framework allows heterogeneous NSFs developed by different security solution vendors to be used in the NFV environment by utilizing the capabilities of such products and the virtualization of security functions in the NFV platform.
In the I2NSF framework, each NSF initially registers the profile of its own capabilities into the system in order for themselves to be available in the system. In addition, the Security Controller registers itself to the I2NSF user so that the user can request security services to the Security Controller.
This document describes the applicability of I2NSF framework to network-based security services with a use case of time-dependent web access control. This document also describes integrating I2NSF framework with Software-Defined Networking (SDN) technology for efficient security services and use cases, such as firewall , Deep Packet Inspection (DPI), and Distributed Denial of Service (DDoS) attack mitigation. We implemented the I2NSF framework based on SDN for these use cases, and the implementation successfully verified the effectiveness of the I2NSF framework.
This document uses the terminology described in , , , , , , , , , , , , , , and .
In addition, the following terms are defined below:
Software-Defined Networking (SDN): A set of techniques that enables to directly
program, orchestrate, control, and manage network resources, which
facilitates the design, delivery and operation of network services in a
dynamic and scalable manner .
Firewall: A service function at the junction of two
network segments that inspects every packet that attempts to cross the
boundary. It also rejects any packet that does not satisfy certain
criteria for, for example, disallowed port numbers or IP addresses.
Centralized Firewall System: A centralized firewall that can establish and
distribute policy rules into network resources for efficient
firewall management. These rules can be managed dynamically by a centralized
server for firewall. SDN can work as a network-based firewall system through
a standard interface between an SDN switch and a firewall function as a vitual network function (VNF).
Centralized VoIP Security System: A centralized security system that
handles the security functions required for VoIP and VoLTE services. SDN can work
as a network-based security system through a standard interface between an SDN switch and a VoIP/VoLTE security function as a VNF.
Centralized DDoS-attack Mitigation System: A centralized mitigator that can
establish and distribute access control policy rules into network resources
for efficient DDoS-attack mitigation. These rules can be managed
dynamically by a centralized server for DDoS-attack mitigation.
The SDN controller and switches can cooperatively work as a network-based firewall system through a standard interface between an SDN switch and a firewall function as a VNF running in the SDN controller.
This section describes an I2NSF framework and its use case. shows an I2NSF framework to support network-based security services. As shown in , I2NSF User can use security functions by delivering high-level security policies, which specify security requirements the I2NSF user wants to enforce, to the Security Controller via the Consumer-Facing Interface .
The Security Controller receives and analyzes the high-level security policies from an I2NSF User, and identifies what types of security capabilities are required to meet these high-level security policies. The Security Controller then identifies NSFs that have the required security capabilities, and generates low-level security policies for each of the NSFs so that the high-level security policies are eventually enforced by those NSFs. Finally, the Security Controller sends the generated low-level security policies to the NSFs .
The Security Controller requests NSFs to perform low-level security services via the NSF-Facing Interface. The NSFs are enabled as Virtual Network Functions (VNFs) on top of virtual machines through Network Functions Virtualization (NFV) . In addition, the Security Controller uses the I2NSF Registration Interface to communicate with Developer's Management System (called Developer's Mgmt System) for registering (or deregistering) the developer's NSFs into (or from) the NFV system using the I2NSF framework.
The Consumer-Facing Interface between an I2NSF User and the Security Controller
can be implemented using, for example, RESTCONF .
Data models specified by YANG describe high-level security policies to be specified by an I2NSF User. The data model defined in can be used for the I2NSF Consumer-Facing Interface.
The NSF-Facing Interface between Security Controller and NSFs
can be implemented using NETCONF .
YANG data models describe low-level security policies for the sake of NSFs, which are translated from the high-level security policies by the Security Controller. The data model defined in can be used for the I2NSF NSF-Facing Interface.
The Registration Interface between the Security Controller and the Developer's Mgmt System can be implemented by RESTCONF . The data model defined in can be used for the I2NSF Registration Interface.
Also, the I2NSF framework can enforce multiple chained NSFs for the low-level security policies by means of service function chaining (SFC) techniques for the I2NSF architecture described in .
The following describes a security service scenario using the I2NSF framework.
This service scenario assumes that an enterprise network administrator wants to control the staff members' access to Facebook during business hours. The following is an example high-level security policy rule that the administrator requests: Block the staff members' access to Facebook from 9 am to 6 pm. The administrator sends this high-level security policy to the security controller, then the security controller identifies required secuity capabilities, e.g., IP address and port number inspection capabilities and URL inspection capability. In this scenario, it is assumed that the IP address and port number inspection capabilities are required to check whether a received packet is an HTTP packet from a staff member. The URL inspection capability is required to check whether the target URL of a received packet is facebook.com or not.
The Security Controller maintains the security capabilities of each NSF running in the I2NSF system, which have been reported by the Developer's Management System via the Registation interface. Based on this information, the Security Controller identifies NSFs that can perform the IP address and port number inspection and URL inspection. In this scenario, it is assumed that an NSF of firewall has the IP address and port number inspection capabilities and an NSF of web filter has URL inspection capability.
The Security Controller generates low-level security rules for the NSFs to perform IP address and port number inspection, URL inspection, and time checking. Specifically, the Security Controller may interoperate with an access control server in the enterprise network in order to retrieve the information (e.g., IP address in use, company ID, and role) of each employee that is currently using the network. Based on the retrieved information, the Security Controller generates low-level security rules to check whether the source IP address of a received packet matches any one being used by a staff member. In addition, the low-level security rules should be able to determine that a received packet is of HTTP protocol. The low-level security rules for web filter checks that the target URL field of a received packet is equal to facebook.com. Finally, the Security Controller sends the low-level security rules of the IP address and port number inspection to the NSF of firewall and the low-level rules for URL inspection to the NSF of web filter.
The following describes how the time-dependent web access control service is enforced by the NSFs of firewall and web filter.
A staff member tries to access Fackbook.com during business hours, e.g., 10 am.
The packet is forwarded from the staff member's device to the firewall, and the firewall checks the source IP address and port number. Now the firewall identifies the received packet is an HTTP packet from the staff member.
The firewall triggers the web filter to further inspect the packet, and the packet is forwarded from the firewall to the web filter. Service Function Chaining (SFC) technology can be utilized to support such packet forwarding in the I2NSF framework .
The web filter checks the target URL field of the received packet, and realizes the packet is toward Facebook.com. The web filter then checks that the current time is in business hours. If so, the web filter drops the packet, and consequently the staff member's access to Facebook during business hours is blocked.
This section describes an I2NSF framework with SDN for I2NSF applicability and use cases, such as firewall, deep packet inspection, and DDoS-attack mitigation functions. SDN enables some packet filtering rules to be enforced in the network switches by controlling their packet forwarding rules. By taking advantage of this capability of SDN, it is possible to optimize the process of security service enforcement in the I2NSF system.
shows an I2NSF framework with SDN networks to support network-based security services. In this system, the enforcement of security policy rules is divided into the SDN switches and NSFs. Especially, SDN switches enforce simple packet filtering rules that can be translated into their packet forwarding rules, whereas NSFs enforce NSF-related security rules requiring the security capabilities of the NSFs. For this purpose, the Security Controller instructs the Switch Controller via NSF-Facing Interface so that SDN switches can perform the required security services with flow tables under the supervision of the Switch Controller (i.e., SDN Controller).
The following subsections introduce three use cases for cloud-based security services:
(i) firewall system, (ii) deep packet inspection system, and (iii) attack mitigation system.
A centralized network firewall can manage
each network resource and firewall rules can be managed flexibly by a centralized
server for firewall (called Firewall). The centralized network firewall controls
each switch for the network resource management and the firewall rules can be
added or deleted dynamically.
The procedure of firewall operations in this system is as follows:
A switch forwards an unknown flow's packet to one of the Switch Controllers.
The Switch Controller forwards the unknown flow's packet to an appropriate security service application, such as the Firewall.
The Firewall analyzes, typically, the headers and contents of the packet.
If the Firewall regards the packet as a malicious one with a suspicious pattern, it reports the malicious packet to the Switch Controller.
The Switch Controller installs new rules (e.g., drop packets with the suspicious pattern) into underlying switches.
The suspected packets are dropped by these switches.
Existing SDN protocols can be used through
standard interfaces between the firewall application and switches .
Legacy firewalls have some challenges such as the expensive cost, performance,
management of access control, establishment of policy, and packet-based access
mechanism. The proposed framework can resolve the challenges through
the above centralized firewall system based on SDN as follows:
Cost: The cost of adding firewalls to network resources such as routers, gateways, and switches is substantial due to the reason that we need to add firewall on each network resource. To solve this, each network resource can be managed centrally such that a single firewall is manipulated by a centralized server.
Performance: The performance of firewalls is often slower than the link speed of network interfaces. Every network resource for firewall needs to check firewall rules according to network conditions. Firewalls can be adaptively deployed among network switches, depending on network conditions in the framework.
The management of access control: Since there may be hundreds of network resources in a network, the dynamic management of access control for security services like firewall is a challenge. In the framework, firewall rules can be dynamically added for new malware.
The establishment of policy: Policy should be established for each network resource. However, it is difficult to describe what flows are permitted or denied for firewall within a specific organization network under management. Thus, a centralized view is helpful to determine security policies for such a network.
Packet-based access mechanism: Packet-based access mechanism is not enough for firewall in practice since the basic unit of access control is usually users or applications. Therefore, application level rules can be defined and added to the firewall system through the centralized server.
A centralized VoIP/VoLTE
security system can monitor each VoIP/VoLTE flow and manage VoIP/VoLTE
security rules controlled by a centralized server for VoIP/VoLTE security
service called VoIP Intrusion Prevention System (IPS). The VoIP/VoLTE security system controls each switch
for the VoIP/VoLTE call flow management by manipulating the rules that can be added,
deleted or modified dynamically.
A centralized VoIP/VoLTE security system can cooperate with a network firewall to realize VoIP/VoLTE security service. Specifically, a network firewall performs basic security checks of an unknown flow's packet observed by a switch. If the network firewall detects that the packet is an unknown VoIP call flow's packet that exhibits some suspicious patterns, then it triggers the VoIP/VoLTE security system for more specialized security analysis of the suspicious VoIP call packet.
The procedure of VoIP/VoLTE security operations in this system is as follows:
A switch forwards an unknown flow's packet to the Switch Controller, and the Switch Controller further forwards the unknown flow's packet to the Firewall for basic security inspection.
The Firewall analyzes the header fields of the packet, and figures out that this is an unknown VoIP call flow's signal packet (e.g., SIP packet) of a suspicious pattern.
The Firewall triggers an appropriate security service function, such as VoIP IPS, for detailed security analysis of the suspicious signal packet. That is, the firewall
sends the packet to the Service Function Forwarder (SFF) in the I2NSF framework , as shown in . The SFF forwards the suspicious signal packet to the VoIP IPS.
The VoIP IPS analyzes the headers and contents of the signal packet, such as calling number and session description headers .
If, for example, the VoIP IPS regards the packet as a spoofed packet by hackers or a scanning packet searching for VoIP/VoLTE devices, it drops the packet. In addition, the VoIP IPS requests the Switch Controller to block that packet and the subsequent packets that have the same call-id.
The Switch Controller installs new rules (e.g., drop packets) into underlying switches.
The illegal packets are dropped by these switches.
Existing SDN protocols can be used through standard interfaces between the VoIP IPS application and switches .
Legacy hardware based VoIP IPS has some challenges, such as provisioning time, the granularity of security, expensive cost, and the establishment of policy. The I2NSF framework can resolve the challenges through the above centralized VoIP/VoLTE security system based on SDN as follows:
Provisioning: The provisioning time of setting up a legacy VoIP IPS to network is substantial because it takes from some hours to some days. By managing the network resources centrally, VoIP IPS can provide more agility in provisioning both virtual and physical network resources from a central location.
The granularity of security: The security rules of a legacy VoIP IPS are compounded considering the granularity of security. The proposed framework can provide more granular security by centralizing security control into a switch controller. The VoIP IPS can effectively manage security rules throughout the network.
Cost: The cost of adding VoIP IPS to network resources, such as routers, gateways, and switches is substantial due to the reason that we need to add VoIP IPS on each network resource. To solve this, each network resource can be managed centrally such that a single VoIP IPS is manipulated by a centralized server.
The establishment of policy: Policy should be established for each network resource. However, it is difficult to describe what flows are permitted or denied for VoIP IPS within a specific organization network under management. Thus, a centralized view is helpful to determine security policies for such a network.
A centralized DDoS-attack mitigation
can manage each network resource and manipulate rules to each switch
through a centralized server for DDoS-attack mitigation (called DDoS-attack Mitigator).
The centralized DDoS-attack mitigation system defends servers against DDoS attacks
outside private network, that is, from public network.
Servers are categorized into stateless servers (e.g., DNS servers) and
stateful servers (e.g., web servers). For DDoS-attack mitigation,
traffic flows in switches are dynamically configured by traffic flow forwarding path management
according to the category of servers . Such a managenent should
consider the load balance among the switches for the defense against DDoS attacks.
The procedure of DDoS-attack mitigation operations in this system is as follows:
A Switch periodically reports an inter-arrival pattern of a flow's packets to one of the Switch Controllers.
The Switch Controller forwards the flow's inter-arrival pattern to an appropriate security service application, such as DDoS-attack Mitigator.
The DDoS-attack Mitigator analyzes the reported pattern for the flow.
If the DDoS-attack Mitigator regards the pattern as a DDoS attack, it computes a packet dropping probability corresponding to suspiciousness level and reports this DDoS-attack flow to Switch Controller.
The Switch Controller installs new rules into switches (e.g., forward packets with the suspicious inter-arrival pattern with a dropping probability).
The suspicious flow's packets are randomly dropped by switches with the dropping probability.
For the above centralized DDoS-attack mitigation system,
the existing SDN protocols can be used through standard interfaces between the DDoS-attack
mitigator application and switches .
The centralized DDoS-attack mitigation system has challenges similar to
the centralized firewall system.
The proposed framework can resolve the challenges through the above centralized
DDoS-attack mitigation system based on SDN as follows:
Cost: The cost of adding DDoS-attack mitigators to network resources such as routers, gateways, and switches is substantial due to the reason that we need to add DDoS-attack mitigator on each network resource. To solve this, each network resource can be managed centrally such that a single DDoS-attack mitigator is manipulated by a centralized server.
Performance: The performance of DDoS-attack mitigators is often slower than the link speed of network interfaces. The checking of DDoS attacks may reduce the performance of the network interfaces. DDoS-attack mitigators can be adaptively deployed among network switches, depending on network conditions in the framework.
The management of network resources: Since there may be hundreds of network resources in an administered network, the dynamic management of network resources for performance (e.g., load balancing) is a challenge for DDoS-attack mitigation. In the framework, as dynamic network resource management, traffic flow forwarding path management can handle the load balancing of network switches . With this management, the current and near-future workload can be spread among the network switches for DDoS-attack mitigation. In addition, DDoS-attack mitigation rules can be dynamically added for new DDoS attacks.
The establishment of policy: Policy should be established for each network resource. However, it is difficult to describe what flows are permitted or denied for new DDoS-attacks (e.g., DNS reflection attack) within a specific organization network under management. Thus, a centralized view is helpful to determine security policies for such a network.
So far this document has described the procedure and impact of the three use cases for network-based security services using the I2NSF framework with SDN networks. To support these use cases in the proposed data-driven security service framework, YANG data models described in , , and can be used as Consumer-Facing Interface, NSF-Facing Interface, and Registration Interface, respectively, along with RESTCONF and NETCONF .
The I2NSF framework with SDN networks in this document is derived from the I2NSF
framework , so the security considerations of the
I2NSF framework should be included in this document.
Therefore, proper secure communication channels should be used the delivery of
control or management messages among the components in the proposed framework.
This document shares all the security issues of SDN that are specified
in the "Security Considerations" section of .
This work was supported by Institute for Information & communications Technology Promotion (IITP) grant funded by the Korea government (MSIP) (No.R-20160222-002755, Cloud based Security Intelligence Technology Development for the Customized Security Service Provisioning).
I2NSF is a group effort.
I2NSF has had a number of contributing authors.
The following are considered co-authors:
Hyoungshick Kim (Sungkyunkwan University) Jung-Soo Park (ETRI) Se-Hui Lee (Korea Telecom) Mohamed Boucadair (Orange) Framework for Interface to Network Security FunctionsYANG - A Data Modeling Language for the Network Configuration Protocol (NETCONF)Network Configuration Protocol (NETCONF)RESTCONF ProtocolInformation model for Client-Facing Interface to Security ControllerI2NSF Consumer-Facing Interface YANG Data ModelInformation Model of NSFs CapabilitiesI2NSF Network Security Functions-Facing Interface YANG Data ModelI2NSF Registration Interface Information ModelI2NSF Registration Interface YANG Data ModelService Function Chaining-Enabled I2NSF ArchitectureSoftware-Defined Networking: A Perspective from within a Service Provider EnvironmentFramework of Software-Defined NetworkingOpenFlow Switch Specification (Version 1.4.0)SDN ArchitectureBaseline Identity Management Terms and DefinitionsSecurity Architecture for Open Systems Interconnection for
CCITT ApplicationsAVANT-GUARD: Scalable and Vigilant Switch Flow Management in Software-Defined NetworksNetwork Functions Virtualisation (NFV); Architectural FrameworkSDP: Session Description ProtocolInterface to Network Security Functions (I2NSF) TerminologyOn Firewalls in Internet SecurityInterface to Network Security Functions (I2NSF): Problem Statement and Use Cases
The following changes have been made from draft-ietf-i2nsf-applicability-01:
In , a time-based web access control service is added as a general use case in the I2NSF framework.
In , the movitation of the I2NSF framework with SDN is explained, that is, supporting the divided security policy enforcement for efficient security service.
In , the centralized VoIP/VoLTE security system is clarified as a use case to explain the security service chaining using SFC technology.