In this section:
The SBC Core supports the exchange of SIP signaling over Transport Layer Security (TLS), an IETF protocol for securing communications across an untrusted network. Normally, SIP packets travel in plain text over TCP or UDP connections. Secure SIP is a security measure that uses TLS, the successor to the Secure Sockets Layer (SSL) protocol. TLS operates just above the transport layer (Layer 4) and provides peer authentication, confidentiality and message integrity.
The SBC supports TLS versions 1.0, 1.1, 1.2, and 1.3 with server-only authentication (in which only the server is authenticated at the TLS layer) and mutual authentication (in which both the TLS client and server are authenticated at the TLS layer). TLS is an effective measure to a number of threats including theft of service, disruption of service, compromise of confidentiality, and compromise of service integrity.
SIP over TLS may be independently configured on each hop between SIP devices. SIP transport type selection is typically configured via the IP Signaling Profile, and may also be provisioned on the SIP trunk group or identified via a DNS lookup.
If a zone's sipSigPort
is configured for transportProtocolsAllowed
= sip-tls-tcp
, the SBC increments the configured portNumber
by 1 and uses it as the new port number for SIP over TLS signaling. The SBC then opens a TCP socket for SIP over TLS for the new TCP port number.
Example: When sipSigPort
is configured with a portNumber
of 5060 and transportProtocolsAllowed
= sip-tls-tcp
, the SBC listens on TCP port 5061 for SIP over TLS.
The SBC uses SIP over TLS in several scenarios as illustrated in the figure below .
Figure 1: SIP over TLS Usage Scenarios
In most scenarios, the SBC Core does not support ECC certificates for TLS Handshake. Specifically, the SBC Core does not support ECC certificates for TLS handshake when it acts as a TLS “server-only,” although it can support the certificates when acting as TLS client in the configured “server-and-client” role.
The table below describes the interrelationship between each of these scenarios, the TLS role (server or client/server), and the authentication requirements.
TLS Usage Scenarios
Usage Scenario | Usage Description | TLS Role | Authentication Requirements |
---|---|---|---|
Residential Access | Between a subscriber SIP User Agent (UA) and an SBC. | Server | Server-only authentication. This is intended for use in conjunction with authenticated SIP registration. A peer is blocked from using any services until a successful SIP registration is performed. A separate registrar is deployed to challenge and authenticate the registration. The registrar should be configured to require authentication on the registration; however the SBC does not check or enforce this. |
Enterprise Access | Between an enterprise PBX and an SBC. | Server | Mutual TLS authentication for static (non-registering) IP PBX. Server-only Authentication for registering PBX. |
Inter-Carrier Peering | Between a SIP proxy or Back-to-Back User Agent (B2B UA) belonging to another administrative domain and an SBC. | Client or Server | Mutual TLS authentication. |
Intra-Carrier Peering | Between an SBC and a SIP proxy or a B2B UA belonging to the same administrative domain. | Client or Server | Mutual TLS authentication |
Deployments may involve two or more of the above scenarios and include different transports (SIP over TLS, SIP over TCP, or SIP over UDP) simultaneously on separate legs of the same signaling path.
Supported TLS/DTLS Crypto Suites Authentication Mechanism Confidentiality Cipher and Mode Integrity Cipher RSA-WITH-NULL-SHA The integrity cipher used for the TLS Record protocol. RSA-WITH-AES-128-CBC-SHA (default) Confidentiality cipher and mode for the TLS Record protocol. AES-128-CBC SHA-1 RSA-WITH-AES-128-CBC-SHA-256 Confidentiality cipher and mode for the TLS Record protocol with SHA-256 as the hash function. RSA-WITH-AES-256-CBC-SHA Confidentiality cipher and mode for the TLS Record protocol with AES 256 encryption. RSA AES-256-CBC SHA-1 RSA-WITH-AES-256-CBC-SHA-256* Confidentiality cipher and mode for the TLS Record protocol with AES 256 encryption and SHA-256 as the hash function. RSA AES-256-CBC SHA-256 TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA384** Confidentiality cipher and mode for the TLS Record with AES256 CBC and SHA384 as the hash function. Note: The SBC 11.1 and later versions do not support ECDH-ECDSA AES-256-CBC SHA-384 TLS_ECDH_ECDSA_WITH_AES_256_GCM_SHA384** Confidentiality cipher and mode for the TLS Record with AES256 GCM and SHA384 as the hash function. TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA Confidentiality cipher and mode for the TLS Record protocol using ECDHE (Elliptic Curve Diffie-Hellman key Exchange) with AES128 CBC and SHA as the hash function. TLS_ECDHE-RSA-WITH-AES-256-CBC-SHA-384* Confidentiality cipher and mode for the TLS Record protocol using ECDHE (Elliptic Curve Diffie-Hellman key Exchange) with AES256 CBC and SHA384 as the hash function. TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256 Confidentiality cipher and mode for the TLS Record protocol using ECDHE (Elliptic Curve Diffie-Hellman key Exchange) with AES128 GCM and SHA as the hash function. TLS_ECDHE-RSA-WITH-AES-256-GCM-SHA-384* Confidentiality cipher and mode for the TLS Record protocol using ECDHE (Elliptic Curve Diffie-Hellman key Exchange) with AES256 GCM and SHA384 as the hash function. TLS_RSA_WITH_AES_128_GCM_SHA256 Confidentiality cipher and mode for the TLS Record protocol with AES 128 GCM encryption and SHA-256 as the hash function. TLS_RSA_WITH_AES_256_GCM_SHA384 Confidentiality cipher and mode for the TLS Record protocol with AES 256 GCM encryption and SHA-384 as the hash function. TLS_AES_128_GCM_SHA256*** Confidentiality cipher and mode for the TLS Record with AES128 GCM and SHA256 as the hash function. TLS_AES_256_GCM_SHA384*** Confidentiality cipher and mode for the TLS Record with AES256 GCM and SHA384 as the hash function. TLS_CHACHA20_POLY1305_SHA256*** Confidentiality cipher and mode for the TLS Record with ChaCha20-Poly1305 and SHA256 as the hash function. * To use this cipher, enable TLS version 1.2 in the TLS Profile. ** To use this cipher, enable TLS version 1.2 in the TLS Profile and create SSL certificates using ECC keys. *** To use this cipher, enable TLS version 1.3 in the TLS Profile. TLS 1.3 does not support RSA. Certificates generated with RSA will not work with TLS 1.3. When the FIPS-140-3 mode is enabled, you cannot use the algorithms whose key exchange method is RSA, including: FIPS-140-2 is not supported in SBC 10.1.3 and later releases, and it is automatically converted to FIPS-140-3 as part of the upgrade. To verify the current status of FIPS certification, contact the Global Support Assistance Center:Public/Private Key Pair RSA NULL SHA-1 RSA RSA AES-128-CBC SHA-256 tls_ecdh_ecdsa_with_aes_256_cbc_sha384
. You must replace it with a valid Cipher before upgrading the SBC.ECDH-ECDSA AES-256-GCM SHA-384 ECDHE-RSA AES-128-CBC SHA-1 ECDHE-RSA AES-256-CBC SHA-384 ECDHE-RSA AES-128-GCM SHA-256 ECDHE-RSA AES-256-GCM SHA-384 RSA AES_128_GCM SHA-256 RSA AES_256_GCM SHA-384 Unique to each TLS client and server CTR SHA-256 Unique to each TLS client and server CTR SHA-384 Unique to each TLS client and server CTR SHA-256
The SBC and its peer devices use X.509 digital certificates to authenticate themselves for TLS. Local certificates in PKSC # 12 format (attesting to the identity of the SBC) and remote Certificate Authority (CA) certificates may be installed on the SBC in a common area (/opt/sonus/external/) where they are available to TLS.
Modified: for 12.1.2
When establishing a New Peer for a new session with the SBC using a full handshake (exchange and verification of certificates and keys), the SBC caches the session details. If the same peer attempts to reconnect in any scenario using the same session ID used in the new session full handshake, then that connection resumes using the cached session details by having only a partial handshake, which makes the session establishment quicker. Session resumption is only supported until the session resumption timer expires, which can range from 0 (no session resumption) to 86,400 seconds (24 hours).