Ofir Arkin
Managing Security Architect
E.T. Can’t Phone Home Security Issues with VoIP
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Agenda
VoIP Overview
The VoIP Threat Module
The Session Initiation Protocol
The Session Initiation Protocol Threat Module
The RTP Protocol
The RTP Threat Module
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Overview
IP Telephony, VoIP and VON
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Overview
IP Telephony is defined as the use of IP networks to transmit both voice and data packets
VON (or Internet Telephony) is used to describe the usage of the Internet to transmit both voice and data packets
VoIP is used to describe the usage of managed IP networks to transmit both voice and data packets (usually associated with Carrier-Class networks)
In the course of History VON was the predecessor of VoIP, and its success led to the interest and development of IP Telephony and VoIP
Do you remember VocalTEC’s Internet Phone?
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Overview
The IETF has defined many standard track IP Telephony protocols
Many IP Telephony protocols are still under a development / draft stage at the IETF
The IP Telephony protocols defined by the IETF can be used with different IP Telephony architectures:
– Internet Telephony
– Internet Telephony Service Providers (ITSPs)
– Corporate LANs
– Converged Network Architecture
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Overview
The protocols combining any IP Telephony architecture are divided into the following roles:
– Signaling Protocols
– Media Transport Protocols
– Supporting Protocols
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Overview – Signaling Protocols
The VoIP Signaling Protocols perform the following services:
– Locate a User – The ability to locate another user which whom a user wish to communicate with
– Session Establishment – The ability of the called party to accept a call, reject a call, or redirect the call to another location or service
– Session Setup Negotiation – The ability of the communicating parties to negotiate the set of parameters to use during the session, this includes, but not limited to, Audio encoding
– Modify a Session – The ability to change a session’s parameters such as using a different Audio encoding, adding/removing a session participant, etc.
– Teardown a Sessions – The ability to end a session
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Overview – Media Transport Protocols
The Media Transport Protocols are used to carry voice samples (such as RTP)
The media transport protocols are able to use a codec to digitize voice and to compress it into small samples that will be encapsulated within an IP transport protocol and transported using an IP network
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Overview – Supporting Protocols
These are the protocols which supports the various IP Telephony architectures:
For example:
– Quality of Service (QoS) protocols (DiffServ, IntServ, RSVP, MPLS, 802.1q)
– DNS (with or without extensions)
– Routing – TRIP (Telephony Routing over IP)
– Etc.
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OverviewIETF’s VoIP Architecture
The IETF’s VoIP architecture is based on a number of protocols, each of which is only a small part of the complete solution
Therefore the IETF’s VoIP architecture is a very flexible one
A Telephony Architecture which connects the PSTN with VoIP–based Network(s) has to have elements which will translate signaling and voice samples between the PSTN and the VoIP IP Network and vice versa. Therefore some gateways are introduced with the infrastructure
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Overview – VoIP Signaling Protocols, Definitions IETF’s VoIP Architecture
Media Gateway (MG) – A network element which converts audio signals carried on telephone circuits into data packets carried in packet switched networks, and vice versa
Media Gateway Controller (MGC) – Used to control a Media Gateway
Signaling Gateway (SG) – A network element which converts SS7 signaling information from the PSTN into formats understood by the network elements in the IP network, and presents an accurate view of the elements of the IP network to the SS7 network (and vice versa)
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Overview – VoIP Signaling ProtocolsIETF’s VoIP Architecture
The VoIP signaling protocols with the IETF’s VoIP Architecture can be divided into the following categories:
– Protocols used between the Media Gateway and the Media Gateways Controllers (such as MGCP and the Megaco protocols), known as Gateway Control Protocols (GCP)
– Protocols used between the Media Gateway and the Signaling Gateway (such as SCTP, M2UA, M3UA)
– Protocols used between Media Gateway Controllers (MGCs) to initiate a session between users (such as SIP)
– Protocols used within the IP Network (SIP…)
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The IETF’s VoIP Architecture
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Internet Telephony Architecture Using SIP
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Overview – Security
“...It is no longer necessary to have a separate network for voice...”
With VoIP the Internet Protocol (IP) is the vessel for voice transmission, therefore we inherit the security problems associated with the IP protocol
The security issues are more complex because of the nature of speech (voice quality), and other conditions VoIP needs to meet in order to fulfill its promise as the next generation in Telecommunication
Other security issues arise from the VoIP protocols themselves and from the different architectures in which IP Telephony can be deployed
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Mr. Zerga and the IP Phone
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The VoIP Threat Module
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The VoIP Threat ModuleOverview [1]
The VoIP (and IP Telephony) threat module is combined from different number of issues:
– The Usage of IP: The IP protocol’s security weaknesses are inherited (sniffing, spoofing, reply attacks and all the rest of the family)
– There is no separation of networks: The signaling and media share the same network (they are not separated as with the PSTN). It lowers the bar regarding potentially misuse of IP Telephony
– The nature of speech: Issues such as Delay, Latency, Jitter, Packet Loss, Speech Coding Techniques, Network Availability, Managing Access & Priority, etc. There is a burden on maintaining adequate speech quality
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The VoIP Threat ModuleOverview [2]
Continued…
– The VoIP Protocols themselves
– Supporting Protocols (DNS…)
– VoIP Infrastructure (Phones, Special Servers…)
– Supporting Infrastructure (Switches, Routers…)
– Different IP Telephony Architectures (leads to different security risks)
– Physical Security
– …and Supporting Technologies
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VoIP-based Protocols
Integrity
Confidentiality
Authentication
Non–Repudiation
Call Tracking
Call Hijacking
Eavesdropping
Active modifications
Denial of Service
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VoIP-based Protocols (& Architecture)
The placement of the intelligence
– With the PSTN today the signaling intelligence is with the Switches
– The phones are just “dumb devices”
– In the future everything we know today will be changed (we see the signs today with the VoIP technology)
– With some of the VoIP signaling protocols (like SIP) the intelligence is placed at the edges – the IP phones themselves
– This opens up a wider window opportunity for problems initiated by an end user
– As we know, not all clients are born equal – a.k.a. some will be malicious
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VoIP-based Protocols
Authentication
– An IBM Executive Quote from the early days of the PCs:
“Our goal is to make the computer as easy to use as the telephone”
– Authentication…of what exactly? – Importance of Device authentication vs. the failure of user authentication
– Or Who the hack wants to authenticate each time he needs to use the IP phone?
– Re-Authentication at predetermined intervals
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VoIP-based Infrastructure
The devices
– Phones (usually are not that powerful devices)
– Servers (SIP Proxy, SIP Registrar, SIP Redirect, Gatekeepers, Media GWs, Media GW Controllers, Signaling GWs, etc)
Gaining Unauthorized Access
– Remote Access (not on the same local LAN)
Management interfaces
Abusing Authentication issues
Manipulation of settings
Perform Call tracking
Etc.
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VoIP-based Infrastructure
– Physical Access
To the Phone
– Hard resets
– Soft resets
– Device configuration and manipulation of settings
– Call tracking
– Uploading firmware, adding changing functionality and/or adding a permanent backdoor…
– etc.
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VoIP-based Infrastructure
– Physical Access (continued)
To the Network (more later…)
– Free Phone Calls
– Eavesdropping
– Bypassing Filtering
– Bypassing QoS restrictions
– Etc.
To other VoIP-based devices (you get the picture…)
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VoIP-based InfrastructureAvailability
Shared infrastructure is bad!
– Do you really wish to put the tag of critical infrastructure on a shared infrastructure?
– Knock the Switches Off (from the regular data network) and you knocked the Voice network as well…
– Do you trust VLANs?
No Electricity No Service
– No ability to call emergency services (Violates E911 regulations)
– “G, here goes our Carrier Grade availability…”
– Connectivity to different offices in a corporate scenario
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VoIP-based InfrastructureAvailability
Costs of redundancy, and UPSs for every switch and router at the last mile (for a carrier) or in a corporate…
Denial of Service
Even more easy with VoIP, since you really do not need to be “that smart” and use too much traffic, but still you can cause outage in the whole network, a neighborhood, or a building, or on a single end-user (depends on your point of presence in the network) a corporate, etc.
Last – Mile Availability problems (in a carrier-grade network)
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The VoIP Threat ModulePhysical Security
Who said Physical Security?
The Last – Mile is our main concern:
– Access to the Physical Wire (and to equipment) – If achieved all is downhill from there (this holds true for any architecture using VoIP as well)
– Equipment is likely to be stolen – Routers and switches are nice decorations for a room
– Physical Tempering – “Cut the cord Luke”
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The VoIP Threat ModulePhysical Security
Bypassing simple packet shaping mechanisms
Getting into the VoIP VLAN – An end-of-game
Alice’s PCAlice's IP Phone
Voice
Data
Alice's IP Phone
Voice
Data
Mikasa Sukasa
Packet Shaping for QoS(DiffServ)
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The VoIP Threat ModulePhysical Security
IP PhoneIP Phone
PCPC
IP PhoneIP Phone
PCPC
100BaseT Hub
100BaseT Switch
100BaseT Switch
100BaseT Switch
100BaseT
100BaseT
100BaseT
100BaseT
100BaseT
100BaseT
Eavesdropping can be achieved easily if there is access to the wire, with no specialized equipment other than a hub, a knife, and a clipper.
– Between the IP Phone (or Customer Premises Gateway) and the Switch
– Between two switches
With both scenarios we bypassed any QoS mechanism used.
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The VoIP Threat ModulePhysical Security – Free Phone Calls
An “Advantage” Over Phreaking of this sort because the eavesdropper can also have free calls without the knowledge of the subscriber…
For example, using a different Call-ID to differentiate between calls destined to the phreaker to the calls destined to the owner of the line
Alice's IP Phone
Voice
Data
Mikasa Sukasa
I am representing thephysical address of the IP
Phone
I am representing thephysical address of the
Switch
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The VoIP Threat ModuleAccess Technologies
The Security issues are not limited to “traditional” technologies only
Various Access Technologies with a Converged Network Architecture are susceptible to attacks
One notable example is Broadband Wireless Access Networks using LMDS (Local Multipoint Distribution Service). When encryption is used between the Base Station to a residential transceiver cripples the connection so badly some manufactures of LMDS equipment admit it is useless…
All you need to have is the right equipment…
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The VoIP Threat ModuleAccess Technologies
Base Station
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Other Rants
Regulations – It is the IETF policy not to worry about the hooks for wiretapping, but without this ability no service provider will be able to deploy VoIP (at least in the USA, UK and other countries)
Fraud
and more…
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The Session Initiation Protocol
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SIP History
SIP was developed within the mmusic working group in the IETF
The work on SIP began in 1995
Proposed Standard RFC 2543 in February 1999
Authors – Handley (ACIRI), Schulzrinne (Columbia University), Schooler (Cal Tech), & Rosenberg (Bell Labs)
SIP is part of the Internet Multimedia Conferencing Suite
New SIP RFC (draft-ietf-sip-rfc2543bis-09) is in the IESG final approval loop (should be RFC 3261)
Authors – Rosenberg (dynamicsoft), Schulzrinne (Columbia University), Camarillo (Ericsson), Johnston (Worldcom), Peterson (Neustar) , Sparks (dynamicsoft), Handley (ACIRI), Schooler (AT&T)
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What is the Session Initiation Protocol?
“SIP is an application-layer control protocol that can establish, modify, and terminate multimedia sessions (conferences) such as Internet telephony calls. SIP can also invite participants to already existing sessions, such as multicast conferences. Media can be added to (and removed from) an existing session. SIP transparently supports name mapping and redirection services, which supports personal mobility – users can maintain a single externally visible identifier regardless of their network location”.
Text in this section was taken from draft-ietf-sip-rfc2543bis-09
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What is the Session Initiation Protocol?
SIP supports five facets of establishing and terminating multimedia communications:
– User location: determination of the end system to be used for communication;
– User availability: determination of the willingness of the called party to engage in communications;
– User capabilities: determination of the media and media parameters to be used;
– Session setup: “ringing”, establishment of session parameters at both called and calling party;
– Session management: including transfer and termination of sessions, modifying session parameters, and invoking services.
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Overview of Operation
The example shows the basic functions of SIP: location of an end point, signal of a desire to communicate, negotiation of session parameters to establish the session, and teardown of the session once established.
This is a typical example of a SIP message exchange between two users, Alice and Bob. In this example, Alice uses a SIP application on her PC (referred to as a softphone) to call Bob on his SIP phone over the Internet. Also shown are two SIP proxy servers that act on behalf of Alice and Bob to facilitate the session establishment. This typical arrangement is often referred to as the “SIP trapezoid” as shown by the geometric shape of the dashed lines
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Overview of Operation
Alice “calls” Bob using his SIP identity, a type of Uniform Resource Identifier (URI) called a SIP URI. It has a similar form to an email address, typically containing a username and a host name. In this case, it is sip:[email protected], where biloxi.com is the domain of Bob’s SIP service provider (which can be an enterprise, retail provider, etc). Alice also has a SIP URI of sip:[email protected]. Alice might have typed in Bob’s URI or perhaps clicked on a hyperlink or an entry in an address book
SIP is based on an HTTP-like request/response transaction model. Each transaction consists of a request that invokes a particular method, or function, on the server and at least one response
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Overview of Operation
In this example, the transaction begins with Alice’s softphone sending an INVITE request addressed to Bob’s SIP URI. INVITE is an example of a SIP method that specifies the action that the requestor (Alice) wants the server (Bob) to take.
The INVITE request contains a number of header fields. Header fields are named attributes that provide additional information about a message. The ones present in an INVITE include a unique identifier for the call, the destination address, Alice’s address, and information about the type of session that Alice wishes to establish with Bob.
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Overview of Operation – INVITE
INVITE sip:[email protected] SIP/2.0
Via: SIP/2.0/UDP pc33.atlanta.com;branch=z9hG4bK776asdhds
Max-Forwards: 70
To: Bob <sip:[email protected]>
From: Alice <sip:[email protected]>;tag=1928301774
Call-ID: [email protected]
CSeq: 314159 INVITE
Contact: <sip:[email protected]>
Content-Type: application/sdp
Content-Length: 142
(Alice’s SDP not shown)
The Method name
The address which Alice is expecting to receive responses. This parameter indicates the path the return message needs to take
A display name and a SIP or SIPS URI towards which the request was originally directed
Contains a globally unique identifier for this call
Contains an integer (traditional sequence number) and a method nameContains a SIP or SIPS
URI that represents a direct route to Alice
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Overview of Operation
The details of the session, type of media, codec, sampling rate, etc. are not described using SIP. Rather, the body of a SIP message contains a description of the session, encoded in some other protocol format. One such format is the Session Description Protocol (SDP) (RFC 2327). This SDP message (not shown in the example) is carried by the SIP message in a way that is analogous to a document attachment being carried by an email message, or a web page being carried in an HTTP message
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Overview of Operation
F1: Since the softphone does not know the location of Bob or the SIP server in the biloxi.com domain, the softphone sends the INVITE to the SIP server that serves Alice’s domain,atlanta.com
F3: the proxy server receives the INVITE request and sends a 100 (Trying) response back to Alice’s softphone. The 100 (Trying) response indicates that the INVITE has been received and that the proxy is working on her behalf to route the INVITE to the destination. This response contains the same To, From, Call-ID,CSeq and branch parameter in the Via as the INVITE, which allows Alice’s softphone to correlate this response to the sent INVITE.
F2: The atlanta.com proxy server locates the proxy server at biloxi.com, possibly by performing a particular type of DNS (Domain Name Service) lookup to find the SIP server that serves the biloxi.com domain. As a result, it obtains theIP address of the biloxi.com proxy server and forwards, or proxies, the INVITE request there. Before forwarding the request, the atlanta.com proxy server adds an additional Via header field value that contains its own address (the INVITE already contains Alice’s address in the first Via).
F5: The biloxi.com proxy serverreceives the INVITE and responds with a 100 (Trying) response back to the atlanta.com proxy server to indicate that it has received the INVITE and is processing the request.
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Overview of Operation
F4: The proxy server consults a database,generically called a location service, that contains the current IP address of Bob. The biloxi.com proxy server adds another Via header field value with its own address to the INVITE and proxies it to Bob’s SIP phone.
F6: Bob’s SIP phone receives the INVITE and alerts Bob to the incoming call from Alice so that Bob can decide whether to answer the call, that is, Bob’s phone rings. Bob’s SIP phone indicates this in a 180 (Ringing) response, which is routed back through the two proxies in the reverse direction.
Each proxy usesthe Via header field to determine where to send the response and removes its own address from the top. As a result, although DNS and location service lookups were required to route the initial INVITE, the 180 (Ringing) response can be returned to the caller without lookups or without state being maintained in the proxies. This also has the desirable property that each proxy that sees the INVITE will also see all responses to the INVITE.
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Overview of Operation
F9: Bob decides to answer the call. When he picks up the handset, his SIP phone sends a200 (OK) response to indicate that the call has been answered. The 200 (OK) contains a message body with the SDP media description of the type of session that Bob is willing to establish with Alice. As a result, there is a two-phase exchange of SDP messages: Alice sent one to Bob, and Bob sent one back to Alice. This two-phase exchange provides basic negotiation capabilities and is based on a simple offer/answer model of SDP exchange. If Bob did not wish to answer the call or was busy on another call, an error response would have been sent instead of the 200 (OK), which would have resulted in no media session being established.
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Overview of Operation
SIP/2.0 200 OK
Via: SIP/2.0/UDP server10.biloxi.com;branch=z9hG4bKnashds8 ;received=192.0.2.3
Via: SIP/2.0/UDP bigbox3.site3.atlanta.com;branch=z9hG4bK77ef4c2312983.1 ;received=192.0.2.2
Via: SIP/2.0/UDP pc33.atlanta.com;branch=z9hG4bK776asdhds ;received=192.0.2.1
To: Bob <sip:[email protected]>;tag=a6c85cf 465
From: Alice <sip:[email protected]>;tag=1928301774 466
Call-ID: a84b4c76e66710
CSeq: 314159 INVITE
Contact: <sip:[email protected]>
Content-Type: application/sdp
Content-Length: 131 471
(Bob’s SDP not shown)
The first line of the response contains the response code (200) and the reason phrase (OK)
Added by Alice’s softphone
Added by atlanta.com SIP Proxy
Added by biloxy.com SIP Proxy
Contains a URI at which Bob can be directly reached at his SIP phone.
What method this 200 OK is sent for?
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Overview of OperationIn addition to DNS and location service lookups shown in this example, proxy servers can make flexible“routing decisions” to decide where to send a request. For example, if Bob’s SIP phone returned a 486 (Busy Here) response, the biloxi.com proxy server could proxy the INVITE to Bob’s voicemail server. A proxy server can also send an INVITE to a number of locations at the same time. This type of parallel search is known as forking.
Finally, Alice’s softphone sends an acknowledgement message, ACK to Bob’s SIP phone to confirm the reception of the final response (200 (OK)). In this example, the ACK is sent directly from Alice’s softphone to Bob’s SIP phone, bypassing the two proxies. This occurs because the endpoints have learned each other’s address from the Contact header fields through the INVITE/200 (OK) exchange, which was not known when the initial INVITE was sent. The lookups performed by the two proxies are no longer needed, so the proxies drop out of the call flow.
This completes the INVITE/200/ACK three-way handshake used to establish SIP sessions.
In this case, the 200 (OK) is routed back through the two proxies and is received by Alice’s softphone, which then stops the ringback tone and indicates that the call has been answered.
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Overview of Operation
Alice and Bob’s media session has now begun, and they send media packets using the format to which they agreed in the exchange of SDP. In general, the end-to-end media packets take a different path from the SIP signaling messages
During the session, either Alice or Bob may decide to change the characteristics of the media session. This is accomplished by sending a re-INVITE containing a new media description. This re-INVITE references the existing dialog so that the other party knows that it is to modify an existing session instead of establishing a new session. The other party sends a 200 (OK) to accept the change. The requestor responds to the 200 (OK) with an ACK. If the other party does not accept the change, he sends an error response such as 406 (Not Acceptable), which also receives an ACK. However, the failure of the re-INVITE does not cause the existing call to fail – the session continues using the previously negotiated characteristics
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Overview of OperationF13/F14: At the end of the call, Bob disconnects (hangs up) first and generates a BYE message. This BYE is routed directly to Alice’s softphone, again bypassing the proxies. Alice confirms receipt of the BYE with a 200 (OK) response, which terminates the session and the BYE transaction. No ACK is sent – an ACK is only sent in response to a response to an INVITE request.
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Overview of Operation – “Forced Routing”
In some cases, it may be useful for proxies in the SIP signaling path to see all the messaging between the endpoints for the duration of the session. For example, if the biloxi.com proxy server wished to remain in the SIP messaging path beyond the initial INVITE, it would add to the INVITE a required routing header field known as Record-Route that contained a URI resolving to the hostname or IP address of the proxy. This information would be received by both Bob’s SIP phone and (due to the Record-Route header field being passed back in the 200 (OK)) Alice’s softphone and stored for the duration of the dialog. The biloxi.com proxy server would then receive and proxy the ACK, BYE, and 200 (OK) to the BYE.
Each proxy can independently decide to receive subsequent messaging, and that messaging will go through all proxies that elect to receive it. This capability is frequently used for proxies that are providing mid-call features.
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Overview of Operation – Registration
Registration is one way that the biloxi.com server can learn the current location of Bob. Upon initialization, and at periodic intervals, Bob’s SIP phone sends REGISTER messages to a server in the biloxi.com domain known as a SIP Registrar. The REGISTER messages associate Bob’s SIP or SIPS URI (sip:[email protected]) with the machine into which he is currently logged. The registrar writes this association, also called a binding, to a database, called the location service, where it can be used by the proxy in the biloxi.com domain. Bob is not limited to registering from a single device. For example, both his SIP phone at home and the one in the office could send registrations. This information is stored together in the location service and allows a proxy to perform various types of searches to locate Bob. Similarly, more than one user can be registered on a single device at the same time.
The location service is just an abstract concept. It generally contains information that allows a proxy to input a URI and receive a set of zero or more URIs that tell the proxy where to send the request.
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Overview of Operation – Registration
F1 REGISTER Bob -> Registrar
REGISTER sip:registrar.biloxi.com SIP/2.0
Via: SIP/2.0/UDP bobspc.biloxi.com:5060;branch=z9hG4bKnashds7
Max-Forwards: 70
To: Bob <sip:[email protected]>
From: Bob <sip:[email protected]>;tag=456248
Call-ID: 843817637684230@998sdasdh09
CSeq: 1826 REGISTER
Contact: <sip:[email protected]>
Expires: 7200
Content-Length: 0
Associating Bob’s URI <sip:[email protected]> with the machine he is currently logged (the Contact information) <sip:[email protected]>
The information expires after 2 hours
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Overview of Operation – Registration
F2 200 OK Registrar -> Bob
SIP/2.0 200 OK
Via: SIP/2.0/UDP bobspc.biloxi.com:5060;branch=z9hG4bKnashds7 ;received=192.0.2.4
To: Bob <sip:[email protected]>
From: Bob <sip:[email protected]>;tag=456248
Call-ID: 843817637684230@998sdasdh09
CSeq: 1826 REGISTER
Contact: <sip:[email protected]>
Expires: 7200
Content-Length: 0
All Current Binding of <sip:[email protected]>
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Overview of Operation – CANCEL
The CANCEL request, as the name implies, is used to cancel a previous request sent by a client (only INVITEs). Specifically, it asks the UAS to cease processing the request and to generate an error response to that request.
CANCEL has no effect on a request to which a UAS has already given a final response (200 OK).
A UAS that receives a CANCEL request for an INVITE, but has not yet sent a final response, would “stop ringing”, and then respond to the INVITE with a specific error response (a 487).
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Overview of Operation – CANCEL
If the UAS has already sent a final response for the original request, the CANCEL request has no effect on the processing of the original request, no effect on any session state, and no effect on the responses generated for the original request.
If the UAS did not find a matching transaction for the CANCEL according to the procedure above, it SHOULD respond to the CANCEL with a 481 (Call Leg/Transaction Does Not Exist).
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Overview of Operation – OPTIONS
The SIP method OPTIONS allows a UA to query another UA or a proxy server as to its capabilities. This allows a client to discover information about the supported methods, content types, extensions, codecs, etc. without ”ringing” the other party.
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Overview of Operation – OPTIONS
OPTIONS sip:[email protected] SIP/2.0
Via: SIP/2.0/UDP pc33.atlanta.com;branch=z9hG4bKhjhs8ass877
Max-Forwards: 70
To: <sip:[email protected]>
From: Alice <sip:[email protected]>;tag=1928301774
Call-ID: a84b4c76e66710
CSeq: 63104 OPTIONS
Contact: <sip:[email protected]>
Accept: application/sdp
Content-Length: 0
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Overview of Operation – OPTIONS
SIP/2.0 200 OK
Via: SIP/2.0/UDP pc33.atlanta.com;branch=z9hG4bKhjhs8ass877 ;received=192.0.2.4
To: <sip:[email protected]>;tag=93810874
From: Alice <sip:[email protected]>;tag=1928301774
Call-ID: a84b4c76e66710
CSeq: 63104 OPTIONS
Contact: <sip:[email protected]>
Contact: <mailto:[email protected]>
Allow: INVITE, ACK, CANCEL, OPTIONS, BYE
Accept: application/sdp
Accept-Encoding: gzip
Accept-Language: en
Supported: foo
Content-Type: application/sdp
Content-Length: 274
(SDP not shown)
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Protocol Components
User Agent Client (UAC)
– End Systems
– Send SIP Requests
User Agent Server (UAS)
– Listening for Incoming Requests
– Execute an “internal logic”/program to determine the appropriate response
User Agent
– UAC + UAS
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Protocol Components
Redirect Server
– Redirect “callers” (requests) to another Server
Proxy Server
– Relay Call Signaling (“Proxy requests to another server”)
– Can “fork” requests to multiple targets
– Able to maintain basic Call-State (or not)
Registrar
– Receives registrations requests regarding current user locations
– Stores the information at a “Location Server”
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SIP Methods (Core Methods)
INVITE
– Initiate Sessions
– Change a Session state via re-INVITEs
ACK
– Confirms Session Establishment
BYE
– Terminates Sessions
CANCEL
– Cancels an INVITE request sent by a client not already sent a final response for
OPTIONS
– Query another UA or a proxy server as to its capabilities
REGISTER
– Binds permanent address to the current location
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SIP Response Codes
1xy Information or Provisional - Request in progress but not yet completed
– 100 Trying
– 180 Ringing
– 181 Call is Being Forwarded
– 182 Queued
– 183 Session Progress
2xy Success - the request has completed successfully
– 200 OK
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SIP Response Codes
3xy Redirection - another location should be tried for the request
– 300 Multiple Options
– 301 Moved Permanently
– 302 Moved Temporarily
– 305 Use Proxy
– 380 Alternative Service
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SIP Response Codes
4xy Client Error – due to an error in the request, the request was not completed . The client SHOULD NOT retry the same request without modification (for example, adding appropriate authorization). However, the same request to a different server might be successful.
– 400 Bad Request
– 401 Unauthorized
– 402 Payment Required
– 403 Forbidden
– 404 Not Found
– 405 Method Not Allowed
– 406 Not Acceptable
– 407 Proxy Authentication Required
– 408 Request Timeout
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SIP Response Codes
– 410 Gone
– 413 Request Entity Too Large
– 414 Request URI Too Long
– 415 Unsupported Media Type
– 416 Unsupported Media Scheme
– 420 Bad Extension
– 421 Extension Required
– 423 Interval Too Brief
– 480 Temporarily Unavailable
– 481 Call/Transaction Does Not Exist
– 482 Loop Detected
– 483 Too Many Hops
– 484 Address Incomplete
– 485 Ambiguous
– 486 Busy Here
– 487 Request Terminated
– 488 Not Acceptable Here
– 491 Request Pending
– 493 Undecipherable
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SIP Response Codes
5xy Server Failure – the request was not completed due to error in recipient. Can be retried at another location
– 500 Server Internal Error
– 501 Not Implemented
– 502 Bad Gateway
– 503 Service Unavailable
– 504 Server Time-Out
– 505 Version Not Supported
– 513 Message Too Large
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SIP Response Codes
6xy Global Failure – request was failed and should not be retried again
– 600 Busy Everywhere
– 603 Decline
– 604 Does Not Exist Anywhere
– 606 Not Acceptable
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SIP Architecture (I – Proxy)
SIP UA [A]
SIP Proxy
DNS Server
SIP UA [B]
Location Service
SIP Proxy
SIP Registrar1. Register
2. Store
sip.atlanta.com
sip.biloxy.com
3. INVITE
5+6. DNS Query 7. FW: INVITE 9+10. Query & Respond
11. FW: INVITE
4. 100 Trying
8. 100 Trying
12. 180 Ringing
13. 180 Ringing
14. 180 Ringing
15. 200 OK
16. 200 OK
17. 200 OK 18. ACK
19. Media Transport is opened
20. BYE
21. 200 OK
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SIP Architecture (II – Proxy & Redirect)
SIP UA [A]
SIP Proxy
DNS Server
SIP UA [B]
Location Service
SIP Proxy
SIP Registrar1. Register
2. Store
sip.atlanta.com
sip.biloxy.com
3. INVITE
5+6. DNS Query 9. FW: INVITE 11+12. Query & Respond
13. FW: INVITE
4. 100 Trying
10. 100 Trying
14. 180 Ringing
15. 180 Ringing
16. 180 Ringing
17. 200 OK
18. 200 OK
19. 200 OK 20. ACK
21. Media Transport is opened
22. BYE
23. 200 OK
SIP Redirect Server
sip.new-york.com
7. FW
: INVIT
E
8. Redire
ct: sip
.bilo
xy.com
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SIP Architecture (III – The Principle of Mobility)
SIP UA [A]
SIP Proxy
DNS Server
SIP UA [B]
Location Service
SIP Proxy
SIP Registrar1. Register
2. Store
sip.atlanta.com
sip.biloxy.com
3. INVITE
5+6. DNS Query 7. FW: INVITE 9+10. Query & Respond
11. FW: INVITE
4. 100 Trying
8. 100 Trying
12. 3xx Redirect
13. FW: Redirect
SIP UA [B]
14. FW: INVITE
15. 180 Ringing
16. 180 Ringing
17. 200 OK
18. 200 OK 19. ACK
20. Media Transport is Open
21. Bye
22. 200 OK
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SIP Message Structure
Some Other Time
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The Change of Tides
With RFC 2543 UDP was used as the underlying transport protocol for SIP
The IETF demanded that with the new version of SIP, Security will be an integral part of the protocol
Since UDP is hard to secure (IPSec only) the authors of the new version of the protocol turned to TCP. Up until that point they argued that UDP is a better solution for transport of SIP signaling (no retransmissions, and other…)
So Dorothy had to buckle up because Kansas gone bye bye…
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The SIP Threat Module
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SIP Threat Module
Assumption:
An Attacker Is On the Wire
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Threats
Denial-of-Service
– CANCEL
– BYE
– Using response codes
– ICMP Error Messages for UDP datagrams
Call Hijacking
– Through the Registrar
– Through the usage of 3xy response code messages
– Mid-Session tricks
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Threats
MITM Attacks
– Through the usage of 301 & 302 Response codes
– Through the usage of 305 (Use Proxy) response code
No intelligence/control of the Media stream during a session
Covert Channels
– Unknown Header fields
Enumerating
– OPTIONS
– Call – Leg does not exists
– Max - Forwards
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Threats
Wiretapping
– Who’s in my path?
– SIP Proxies are allowed to send messages through a set of additional proxies
Call Tracking
Clients are Malicious
Design Issues
Predictable Values
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Denial of Service – CANCEL
SIP UA [A]
SIP Proxy
DNS Server
SIP UA [B]
Location Service
SIP Proxy
SIP Registrar1. Register
2. Store
sip.atlanta.com
sip.biloxy.com
3. INVITE
5+6. DNS Query7. FW: INVITE 9+10. Query & Respond
11. FW: INVITE
4. 100 Trying
8. 100 Trying
12. 180 Ringing
13. 180 Ringing
SIP UA [C]
15. CANCEL
14. 180 Ringing
The CANCEL needs to “hit” Bob’s SIP Phone before it sends the 200 OK. This is a Denial-of-Service on Bob
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Denial of Service – CANCEL
SIP UA [A]
SIP Proxy
DNS Server
SIP UA [B]
Location Service
SIP Proxy
SIP Registrar1. Register
2. Store
sip.atlanta.com
sip.biloxy.com
3. INVITE
5+6. DNS Query 7. FW: INVITE 9+10. Query & Respond
11. FW: INVITE
4. 100 Trying
8. 100 Trying
12. 180 Ringing
13. 180 RingingSIP UA [C]
15. CANCEL14. 180 Ringing
The CANCEL needs to “hit” Bob’s SIP Phone before it sends the 200 OK. This is a Denial-of-Service on Alice. Whenever Alice sends an INVITE, carol will CANCEL it.
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Denial of Service – BYE
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
SIP Proxy
SIP UA [A]
SIP Proxy 1. Register
2. Store
As soon as the 200OK will be sent from Bob’s SIP Phone to Alice’s SIP Phone, Carol will send a BYE request to either Bob or Alice or both
3. INVITE
4. 100 Trying
5. FW: INVITE
6. 100 Trying
8. Reply
9. FW: INVITE
7. Query
10. 100 Trying
11. FW: 100 Trying
12. FW: 100 Trying
13. 200 OK14. FW: 200 OK
16. BYE
15. FW: 200 OK
sip.atlanta.com
sip.biloxy.com
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Denial of Service – BYE (to Alice)
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
SIP Proxy
SIP UA [A]
SIP Proxy
The 200OK is sent to acknowledge the BYE request
16. BYE
17. FW: BYE
18. FW: BYE
19. 200 OK
20. FW: 200 OK21. FW: 200 OK
200 OK received (The transaction is non-existent on Alice’s SIP Phone ONLY)
22. Any SIP Message
The “session” does not exist on the SIP Proxy anymore, but it will pass the message
23. FW: Any SIP Message
24. FW: Any SIP Message25. 481 Call/Transaction Does Not Exist
26. 481 Call/Transaction Does Not Exist
27. 481 Call/Transaction Does Not Exist
We got a mismatch
sip.atlanta.com
sip.biloxy.com
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Denial of Service – BYE (to Bob)
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
SIP Proxy
SIP UA [A]
SIP Proxy
17. 200 OK18. FW: 200 OK
16. BYE
19. FW: 200 OK
The “session” does not exist any more on Bob’s SIP Phone
sip.atlanta.com
sip.biloxy.com
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Denial of Service – BYE (to Both)
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
SIP Proxy
SIP UA [A]
SIP Proxy
16. BYE (B->A)
17. 200 OK
When a fake BYE will be sent to one of the participants in a dialog, that participant will generate a 200 OK reply. To avoid detection the BYE will be sent simultaneously to both participants, and the 200 OK responses, although generated for a different message will not be suspected (Sequence of both BYE will be the same)
18. FW: 200 OK17’. 200 OK
16. BYE (A->B)
The malicious party will send the BYE request not through the SIP Proxies but direct to the dialog participants. This to avoid cases in which a stateful proxy might take action for the BYE SIP request.
19. FW: 200 OK
18’. FW: 200 OK 19’. FW: 200 OK
sip.atlanta.com
sip.biloxy.com
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Denial of Service – Using Response Codes
A malicious party can use several response codes in order to introduce a denial of service condition
– “4xx responses are definite failure responses from a particular server. The client SHOULD NOT retry the same request without modification (for example, adding appropriate authorization). However, the same request to a different server might be successful.”
– “5xx responses are failure responses given when a server itself has erred.”
– “6xx responses indicate that a server has definitive information about a particular user, not just the particular instance indicated in the Request-URI.”
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Call HijackUsing Manipulation of the Registration Records
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
SIP Proxy
SIP UA [A]
SIP Proxy1. Register
2. Store3. Register
4. Store
Associating Bob’s URI <sip:[email protected]> with the machine he is currently logged (the Contact information) <sip:[email protected]>
Associating Bob’s URI <sip:[email protected]> with the attacker’s machine <sip:[email protected]>
4. INVITE
5. 100 Trying
6. FW: INVITE
7. 100 Trying
8. Query
9. Reply
10. FW: INVITE
sip.atlanta.com
sip.biloxy.com
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Call Hijack Using Manipulation of the Registration Records
You can query the SIP Registrar for the list of addresses of a particular SIP URI
You will be given the list of addresses associated with your SIP URI with each successful registration
But does your UA will show it up? – Probably not (we tried this… NO!)
You can give your registration higher priority than the other record (not deleting other records)
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Call Hijack Using Manipulation of the Registration Records
Or, you can register with a lower priority and perform a denial of service on the higher priority entry, so the SIP Proxy will not be able to ‘deliver-to-it’ and will turn to the next entry with the Registrar
The Registrar can require the registering party (which can be a 3rd party as well) to authentication before receiving the registration information. But, since the characteristics of the registration with SIP requires registration each hour for the same SIP URI, by default, it is unlikely that a SIP phone user will authenticate to the Registrar each hour…
Instead, what most of the SIP-based phones does is store the username and password information with the phone (other attack venues) and perform autentication automatically for the user when required (not always works smoothly)
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Call Hijack Using 301 Moved Permanently Response Code
SIP UA [A]
SIP Proxy
1. INVITE
2. 100 Trying
sip.atlanta.com
SIP Proxy
sip.biloxy.com
SIP UA [B]
SIP UA [C]
SIP:carol@IP_ADDRESS
3. FW: INVITE
4. 301 Moved Permanently
“The user can no longer be found at the address in the Request-URI, and the requesting client SHOULD retry at the new address given by the Contact header field. The requestor SHOULD update any local directories, address books, and user location caches with this new value and redirect future requests to the address(es) listed.”
5. INVITE
The INVITE that was originally sent to [email protected], is now being sent to the address given with the 301 spoofed response code, bob@foobar_IP (carol’s SIP Phone). Therefore the query goes to Carol’s SIP phone rather than to Bob’s
6. FW: INVITE
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Call Hijack – Using 30y Messages
The location of the malicious entity can be anywhere (Alice’s network, Bob’s network, in-between networks)
One can also use the 302 Moved Temporarily Response Code:
– “The requesting client SHOULD retry the request at the new address(es) given by the Contact header field. The Request-URI of the new request uses the value of the Contact header field in the response.
The duration of the validity of the Contact URI can be indicated through an Expires header field or an expires parameter in the Contact header field. Both proxies and UAs MAY cache this URI for the duration of the expiration time. If there is no explicit expiration time, the address is only valid once for recursing, and MUST NOT be cached for future transactions. If the URI cached from the Contact header field fails, the Request-URI from the redirected request MAY be tried again a single time.”
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Call Hijack – Mid Session Tricks / ”Re-INVITE me baby one more time!”
“…this modification can involve changing addresses or ports, adding a media stream, deleting media stream, and so on…”, “this is accomplished by sending a new INVITE request within the same dialog that established the session”…”also known as Re-INVITE”
Hijack the signaling path – you are able to introduce new routing into the signaling path of a current session
Deny signaling from any side to your benefit
Can evolve to introducing other participants to the session
“Eavesdropping made easy”
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MITM Attacks
301 and 302 Response codes can be spoofed as responses coming from any SIP element:
– SIP Registrar
– SIP Proxy Server
– SIP Redirect Server
– SIP UA
More creativity – 305 Use Proxy Response Code
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MITM Attacks – 302 Moved Temporarily
SIP UA [A]
SIP Proxy
1. INVITE
2. 302 Moved Temporarily sip.atlanta.com
SIP Proxy
sip.biloxy.com
SIP UA [B]
“Carol’s Proxy”
302 Moved Temporarily - “The requesting client SHOULD retry the request at the new address(es) given by the Contact header field. The Request-URI of the new request uses the value of the Contact header field in the response.”
3. INVITE’
4. FW: INVITE’
5. 100 Trying
6. FW: INVITE
Carol is now acting as a SIP Proxy
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MITM Attacks – vs. Registrar
Location Service
SIP Registrar
SIP UA [B]
SIP UA [C]
1. Register
Bob’s SIP Phone performs a registration request
Carol is spoofing a 301 Moved Permanently response message allegedly coming from the REGISTRAR
2. 301 Moved Permanently
3. Register’4. 401 Unauthorized
5. Register’’ request with appropriate credentials
6. Confirm Registration
7. Register request for bob’s credentials8. Store
Carol has bob’s credentials – Game Over
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MITM Attacks – 305 Use Proxy, orWho’s your Daddy?
SIP UA [A]
SIP Proxy
1. INVITE
2. 305 Use Proxysip.atlanta.com
SIP Proxy
sip.biloxy.com
SIP UA [B]
“Carol’s Proxy”
“The requested resource MUST be accessed through the proxy given by the Contact field. The Contact field gives the URI of the proxy. The recipient is expected to repeat this single request via the proxy. 305 (Use Proxy) responses MUST only be generated by UASs. “
3. INVITE’
4. FW: INVITE
5. 100 Trying
6. FW: INVITE
Carol is now acting as a SIP Proxy
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No intelligence/control of the Media stream during a session
Signaling goes one way, Media goes another way
Some device needs to control the creation of Media streams – no media stream without the appropriate signaling (who came first the chicken or the egg problem)
If there is a modification to the Media stream along the “call” (through the usage of RTP or RTCP, for example) the SIP signaling protocol will not be aware of it
If the codec used will be changed using the media transport protocol SIP is simply blind.
In the case the media stream will be cut the SIP elements participating in the session (especially the SIP UAs) will not get indication that the media is cut… They will have to understand that the conversation was cut…
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No intelligence/control of the Media stream during a session
There is no control of the “pipeline” for the Media stream. Therefore a malicious party can change the codec used through the Media protocol used, and use a codec which demands more bandwidth (and therefore its usage will raise the packet loss and we will have a lower quality, or even a poor quality of speech)
No Provisioning what so ever on the Media stream
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Enumeration
If the UAS did not find a matching transaction for the CANCEL according to the procedure … it SHOULD respond to the CANCEL with a 481 (Call Leg/Transaction Does Not Exist).
OPTIONS method
The Max-Forwards header value represents the maximum number of SIP devices this request can route through. The default value is 70 (a nice rounded number)
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Covert Channels
If you will introduce a fake SIP header field with a SIP message it will be allowed across all components of a SIP based solution
Future header support – It Just Rock!
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Call Tracking
Defined as: “Logging of the source and destination of all numbers being called”
Capturing DTMFs along with other signaling traffic will give an attacker the opportunity to capture voice mail passwords (rings a bell?), calling card information, credit card information, or any other data entered using DTMF
With SIP all we need is to track INVITE messages
If the BYE is also recorded the duration of the call can also be tracked, and other bits of information
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Call Tracking
INVITE sip:[email protected] SIP/2.0
Via: SIP/2.0/UDP pc33.atlanta.com;branch=z9hG4bK776asdhds
Max-Forwards: 70
To: Bob <sip:[email protected]>
From: Alice <sip:[email protected]>;tag=1928301774
Call-ID: [email protected]
CSeq: 314159 INVITE
Contact: <sip:[email protected]>
Content-Type: application/sdp
Content-Length: 142
(Alice’s SDP not shown)
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Clients are Malicious
SIPs threat module according to the SIP WG does not include “malicious clients”
If I am using a malicious client (my stack instead of the manufacture’s stack or a modified one) and I am the called party, I can, for example, strip any Record-Route headers and not bother with those. As a direct response to this, not my client, and most importantly the caller will send signals beyond the “three-way SIP handshake” through any SIP Proxy as we like…
The “official SIP threat module” does not take into consideration that when two “friends” use the network they will be able to unveil the routing path with nearly no hassle (see example at the next slide)
There is also a lot more to this one
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Clients are Malicious
Location Service
SIP Registrar
SIP UA [B]
SIP Proxy
SIP UA [A]
SIP Proxy
A “conspirator” will have all the route taken (at least the entities that needs to be passed through) in the VIA headers
sip.atlanta.comsip.biloxy.com
Encrypted
SIP Proxy
sip.somewhere.com
Encrypted
Might be
Encrypted
Might be
Encrypted
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More Issues
Predicted Values
Firewalls & NAT
Bypassing the SIP Proxy = Bypassing Billing (where is my CDR syndrome)
No Control on Media streams = Bypassing Billing using tunneling with the Media streams protocols
Fraud – if you are only looking at CDRs produces – Well, you are a complete idxxx… Most important is to look at the network traffic
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Security Mechanisms with the SIP Protocol
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Security Mechanisms with the SIP Protocol
TLS support
– TLS is only good for TCP
– This means that if you wish to use UDP for the transport of your SIP messages you will not have security (accept for body encryption)
– It is only RECOMMENDED that a UA will be able to initiate a TLS based connection…
– Digital Certificated Usage and the missing piece – it is only for the SIP Servers to use digital certificates. Clients are not required to have one
– Without certificates at the client side we just have at the end of the process an encrypted communication channel between two parties without authenticating their identity
– 12 messages to establish a session, which according to the RFC needs to be kept alive all the time…
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Security Mechanisms with the SIP Protocol
S/MIME for message bodies (key distribution)
Digest Authentication
With encryption firewalls will be useless when they have the ability to really understand the protocol (remember Max-Forwards for example?)
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Multimedia Communication (RTP & RTCP)
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Multimedia Communication (RTP & RTCP)
The main concern is the ability to control any part of a media stream by manipulating the appropriate values…
This is done by manipulating the Sequence and Timestamp field values to higher values than they are currently. The affect is that media streams coming from the user we are attacking will not be accepted at the destination’s end because they will be discarded as ‘old’
More? – Some other time
Questions?
Ofir Arkin
Managing Security Architect
E.T. Can’t Phone Home Security Issues with VoIP