Transport Layer Security

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Template:IPstack Transport Layer Security (TLS) and its predecessor, Secure Sockets Layer (SSL), are cryptographic protocols designed to provide communication security over the Internet.<ref>Template:Cite web</ref> They use X.509 certificates and hence asymmetric cryptography to authenticate the counterparty with whom they are communicating, and to exchange a symmetric key. This session key is then used to encrypt data flowing between the parties. This allows for data/message confidentiality, and message authentication codes for message integrity and as a by-product, message authentication. Several versions of the protocols are in widespread use in applications such as web browsing, electronic mail, Internet faxing, instant messaging, and voice-over-IP (VoIP). An important property in this context is forward secrecy, so the short-term session key cannot be derived from the long-term asymmetric secret key.<ref>SSL: Intercepted today, decrypted tomorrow, Netcraft, 2013-06-25.</ref>

As a consequence of choosing X.509 certificates, certificate authorities and a public key infrastructure are necessary to verify the relation between a certificate and its owner, as well as to generate, sign, and administer the validity of certificates. While this can be more beneficial than verifying the identities via a web of trust, the 2013 mass surveillance disclosures made it more widely known that certificate authorities are a weak point from a security standpoint, allowing man-in-the-middle attacks (MITM).<ref>Law Enforcement Appliance Subverts SSL, Wired, 2010-04-03.</ref><ref>New Research Suggests That Governments May Fake SSL Certificates, EFF, 2010-03-24.</ref>

In the Internet Protocol Suite, TLS and SSL encrypt the data of network connections in the application layer. In OSI model equivalences, TLS/SSL is initialized at layer 5 (session layer) and works at layer 6 (the presentation layer).Template:Citation needed The session layer has a handshake using an asymmetric cipher in order to establish cipher settings and a shared key for that session; then the presentation layer encrypts the rest of the communication using a symmetric cipher and that session key. In both models, TLS and SSL work on behalf of the underlying transport layer, whose segments carry encrypted data.

TLS is an Internet Engineering Task Force (IETF) standards track protocol, first defined in 1999 and last updated in RFC 5246 (August 2008) and RFC 6176 (March 2011). It is based on the earlier SSL specifications (1994, 1995, 1996) developed by Netscape Communications<ref>Template:Cite web</ref> for adding the HTTPS protocol to their Navigator web browser.

Description

The TLS protocol allows client-server applications to communicate across a network in a way designed to prevent eavesdropping and tampering.

Since protocols can operate either with or without TLS (or SSL), it is necessary for the client to indicate to the server the setup of a TLS connection. There are two main ways of achieving this. One option is to use a different port number for TLS connections (for example, port 443 for HTTPS). The other is for the client to request that the server switches the connection to TLS using a protocol-specific mechanism (for example, STARTTLS for mail and news protocols).

Once the client and server have agreed to use TLS, they negotiate a stateful connection by using a handshaking procedure.<ref>"SSL/TLS in Detail". Microsoft TechNet. Updated July 31, 2003. </ref> During this handshake, the client and server agree on various parameters used to establish the connection's security:

  1. The client sends the server the client's SSL version number, cipher settings, session-specific data, and other information that the server needs to communicate with the client using SSL.
  2. The server sends the client the server's SSL version number, cipher settings, session-specific data, and other information that the client needs to communicate with the server over SSL. The server also sends its own certificate, and if the client is requesting a server resource that requires client authentication, the server requests the client's certificate.
  3. The client uses the information sent by the server to authenticate the server—e.g., in the case of a web browser connecting to a web server, the browser checks whether the received certificate's subject name actually matches the name of the server being contacted, whether the issuer of the certificate is a trusted certificate authority, whether the certificate has expired, and, ideally, whether the certificate has been revoked.<ref>Checking for certificate revocation can slow down browsing, so browsers generally don't perform this check unless so configured.</ref> If the server cannot be authenticated, the user is warned of the problem and informed that an encrypted and authenticated connection cannot be established. If the server can be successfully authenticated, the client proceeds to the next step.
  4. Using all data generated in the handshake thus far, the client (with the cooperation of the server, depending on the cipher in use) creates the pre-master secret for the session, encrypts it with the server's public key (obtained from the server's certificate, sent in step 2), and then sends the encrypted pre-master secret to the server.
  5. If the server has requested client authentication (an optional step in the handshake), the client also signs another piece of data that is unique to this handshake and known by both the client and server. In this case, the client sends both the signed data and the client's own certificate to the server along with the encrypted pre-master secret.
  6. If the server has requested client authentication, the server attempts to authenticate the client. If the client cannot be authenticated, the session ends. If the client can be successfully authenticated, or if the server has decided to forego authenticating the client during this session, the server uses its private key to decrypt the pre-master secret, and then performs a series of steps (which the client also performs, starting from the same pre-master secret) to generate the master secret.
  7. Both the client and the server use the master secret to generate the session keys, which are symmetric keys used to encrypt and decrypt information exchanged during the SSL session and to verify its integrity (that is, to detect any changes in the data between the time it was sent and the time it is received over the SSL connection).
  8. The client sends a message to the server informing it that future messages from the client will be encrypted with the session key. It then sends a separate (encrypted) message indicating that the client portion of the handshake is finished.
  9. The server sends a message to the client informing it that future messages from the server will be encrypted with the session key. It then sends a separate (encrypted) message indicating that the server portion of the handshake is finished.

The SSL handshake is now complete and the session begins. The client and the server use the session keys to encrypt and decrypt the data they send to each other and to validate its integrity.

This is the normal operation condition of the secure channel. At any time, due to internal or external stimulus (either automation or user intervention), either side may renegotiate the connection, in which case the process repeats itself.<ref>Template:Cite web</ref>

This concludes the handshake and begins the secured connection, which is encrypted and decrypted with the key material until the connection closes.

If any one of the above steps fails, the TLS handshake fails, and the connection is not created.

In step 3, the client must check a chain of "signatures" from a "root of trust" built into, or added to, the client. The client must also check that none of these have been revoked; this is not often implemented correctly,Template:Citation needed but is a requirement of any public-key authentication system. If the particular signer beginning this server's chain is trusted, and all signatures in the chain remain trusted, then the Certificate (thus the server) is trusted.

History and development

Secure Network Programming API

Early research efforts towards transport layer security included the Secure Network Programming (SNP) application programming interface (API), which in 1993 explored the approach of having a secure transport layer API closely resembling Berkeley sockets, to facilitate retrofitting preexisting network applications with security measures.<ref name="Woo94">Thomas Y. C. Woo, Raghuram Bindignavle, Shaowen Su and Simon S. Lam, SNP: An interface for secure network programming Proceedings USENIX Summer Technical Conference, June 1994</ref>

SSL 1.0, 2.0 and 3.0

The SSL protocol was originally developed by Netscape.<ref>Template:Cite web</ref> Version 1.0 was never publicly released; version 2.0 was released in February 1995 but "contained a number of security flaws which ultimately led to the design of SSL version 3.0."<ref>Rescorla 2001</ref> SSL version 3.0, released in 1996, was a complete redesign of the protocol produced by Paul Kocher working with Netscape engineers Phil Karlton and Alan Freier. Newer versions of SSL/TLS are based on SSL 3.0. The 1996 draft of SSL 3.0 was published by IETF as a historical document in RFC 6101.

The basic algorithm was written by Dr. Taher Elgamal. As the Chief Scientist of Netscape, Taher was recognized as the "father of SSL".<ref name=Messmer>Template:Cite web</ref><ref name=Greene>Template:Cite web</ref>

TLS 1.0

TLS 1.0 was first defined in RFC 2246 in January 1999 as an upgrade of SSL Version 3.0. As stated in the RFC, "the differences between this protocol and SSL 3.0 are not dramatic, but they are significant enough to preclude interoperability between TLS 1.0 and SSL 3.0." TLS 1.0 does include a means by which a TLS implementation can downgrade the connection to SSL 3.0, thus weakening security.<ref name="urlnvlpubs.nist.gov">Template:Cite web</ref>Template:Rp

TLS 1.1

TLS 1.1 was defined in RFC 4346 in April 2006.<ref>Template:Cite web</ref> It is an update from TLS version 1.0. Significant differences in this version include:

TLS 1.2

TLS 1.2 was defined in RFC 5246 in August 2008. It is based on the earlier TLS 1.1 specification. Major differences include:

All TLS versions were further refined in RFC 6176 in March 2011 removing their backward compatibility with SSL such that TLS sessions will never negotiate the use of Secure Sockets Layer (SSL) version 2.0.

Template:AnchorTLS 1.3 (draft)

Template:As of, TLS 1.3 is a draft and details have not fixed yet.<ref>draft-ietf-tls-tls13-02</ref><ref>draft-ietf-tls-tls13-latest</ref> It is based on the earlier TLS 1.1 and 1.2 specification. Major differences from TLS 1.2 include:

  • Reworked handshake to provide 1-RTT mode.
  • Remove custom DHE groups.
  • Removed support for compression.
  • Removed support for static RSA and DH key exchange.
  • Removed support for non-AEAD ciphers (CBC mode of block ciphers, RC4).

Algorithm

Key exchange or key agreement

Before a client and server can begin to exchange information protected by TLS, they must securely exchange or agree upon an encryption key and a cipher to use when encrypting data (see Cipher). Among the methods used for key exchange/agreement are: public and private keys generated with RSA (denoted TLS_RSA in the TLS handshake protocol), Diffie-Hellman (denoted TLS_DH in the TLS handshake protocol), ephemeral Diffie-Hellman (denoted TLS_DHE in the handshake protocol), Elliptic Curve Diffie-Hellman (denoted TLS_ECDH), ephemeral Elliptic Curve Diffie-Hellman (TLS_ECDHE), anonymous Diffie-Hellman (TLS_DH_anon),<ref name=RFC5246>Template:Cite web</ref> and PSK (TLS_PSK).<ref name=RFC4279>Template:Cite web</ref>

The TLS_DH_anon and TLS_ECDH_anon key agreement methods do not authenticate the server or the user and hence are rarely used because those are vulnerable to Man-in-the-middle attack. Only TLS_DHE and TLS_ECDHE provide forward secrecy.

Public key certificates used during exchange/agreement also vary in the size of the public/private encryption keys used during the exchange and hence the robustness of the security provided. In July 2013, Google announced that it would no longer use 1024 bit public keys and would switch instead to 2048 bit keys to increase the security of the TLS encryption it provides to its users.<ref>Template:Cite web</ref>

Authentication and key exchange/agreement
Algorithm SSL 2.0 SSL 3.0 TLS 1.0 TLS 1.1 TLS 1.2
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Cipher

Cipher security against publicly known feasible attacks
Cipher Protocol version
Type Algorithm Strength (bits) SSL 2.0 SSL 3.0
<ref group="note" name="rfc5746">RFC 5746 must be implemented in order to fix a renegotiation flaw that would otherwise break this protocol.</ref><ref group="note" name="renegotiation">If libraries implement fixes listed in RFC 5746, this will violate the SSL 3.0 specification, which the IETF cannot change unlike TLS. Fortunately, most current libraries implement the fix and disregard the violation that this causes.</ref><ref group="note" name="BEAST">the BEAST attack breaks all block ciphers (CBC ciphers) used in SSL 3.0 and TLS 1.0 unless mitigated by the client. See #Web browsers.</ref>
TLS 1.0
<ref group="note" name="rfc5746"/><ref group="note" name="BEAST"/>
TLS 1.1
<ref group="note" name="rfc5746"/>
TLS 1.2
<ref group="note" name="rfc5746"/>
Block cipher
with
mode of operation
AES CBC<ref group="note" name="Lucky13"/> 128, 256 Template:N/a Template:N/a Template:Depends Template:Good Template:Good
AES GCM<ref name=aes-gcm>RFC 5288</ref><ref group="note" name="aead">AEAD ciphers (such as GCM and CCM) can be used in only TLS 1.2.</ref> Template:N/a Template:N/a Template:N/a Template:N/a Template:Good
AES CCM<ref name=aes-ccm>RFC 6655</ref><ref group="note" name="aead"/> Template:N/a Template:N/a Template:N/a Template:N/a Template:Good
CAMELLIA CBC<ref name=camellia-cbc>RFC 5932, RFC 6367</ref><ref group="note" name="Lucky13"/> 128, 256 Template:N/a Template:N/a Template:Depends Template:Good Template:Good
CAMELLIA GCM<ref name=camellia-gcm>RFC 6367</ref><ref group="note" name="aead"/> Template:N/a Template:N/a Template:N/a Template:N/a Template:Good
SEED CBC<ref name="seed-cbc">RFC 4162</ref><ref group="note" name="Lucky13"/> 128 Template:N/a Template:N/a Template:Depends Template:Good Template:Good
ARIA CBC<ref name=aria>RFC 6209</ref><ref group="note" name="Lucky13"/> 128, 256 Template:N/a Template:N/a Template:Depends Template:Good Template:Good
ARIA GCM<ref name=aria/><ref group="note" name="aead"/> Template:N/a Template:N/a Template:N/a Template:N/a Template:Good
IDEA CBC<ref group="note" name="Lucky13"/>Template:Refn 128 Template:Bad Template:Depends Template:Depends Template:Good Template:N/a
3DES EDE CBC<ref group="note" name="Lucky13">CBC ciphers can be attacked with the Lucky 13 attack if the library is not written carefully to eliminate timing side channels.</ref> 112Template:Refn Template:Bad Template:Depends Template:Depends Template:Depends Template:Depends
DES CBC<ref group="note" name="Lucky13"/><ref group="note" name="removal_from_tls1.2"/> 56 Template:Bad Template:Bad Template:Bad Template:Bad Template:N/a
40<ref group="note" name="EXPORT">40 bits strength of cipher suites were designed to operate at reduced key lengths in order to comply with US regulations about the export of cryptographic software containing certain strong encryption algorithms (see Export of cryptography from the United States). These weak suites are forbidden in TLS 1.1 and later.</ref> Template:Bad Template:Bad Template:Bad Template:N/a Template:N/a
RC2 CBC<ref group="note" name="Lucky13"/> 40<ref group="note" name="EXPORT"/> Template:Bad Template:Bad Template:Bad Template:N/a Template:N/a
Stream cipher CHACHA20+POLY1305<ref name="chacha20poly1305">draft-agl-tls-chacha20poly1305-04, draft-mavrogiannopoulos-chacha-tls-02</ref><ref group="note" name="aead"/> 256 Template:N/a Template:N/a Template:N/a Template:N/a Template:Good
RC4<ref group="note" name="RC4">the RC4 attacks weaken or break RC4 used in SSL/TLS</ref> 128 Template:Bad Template:Bad Template:Bad Template:Bad Template:Bad
40<ref group="note" name="EXPORT"/> Template:Bad Template:Bad Template:Bad Template:N/a Template:N/a
no encryption NULL - Template:N/a Template:Bad Template:Bad Template:Bad Template:Bad
Notes
1 }}
references-column-width references-column-count references-column-count-{{#if:1|{{{1}}}}} }} {{#if: references-column-width }} }}" style="{{#if: {{#iferror: {{#ifexpr: 1 > 1 }} Template:Column-width Template:Column-count }} {{#if: Template:Column-width }} }} list-style-type: {{#switch: "note" upper-alpha upper-roman lower-alpha lower-greek lower-roman = "note" #default = decimal}};"> <references group="note"></references>

Data integrity

Message authentication code (MAC) is used for data integrity. HMAC is used for CBC mode of block ciphers and stream ciphers. AEAD is used for Authenticated encryption such as GCM mode and CCM mode.

Data integrity
Algorithm SSL 2.0 SSL 3.0 TLS 1.0 TLS 1.1 TLS 1.2
HMAC-MD5 Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
HMAC-SHA1

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HMAC-SHA256/384

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AEAD

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Applications and adoption

In applications design, TLS is usually implemented on top of any of the Transport Layer protocols, encapsulating the application-specific protocols such as HTTP, FTP, SMTP, NNTP and XMPP. Historically it has been used primarily with reliable transport protocols such as the Transmission Control Protocol (T*****). However, it has also been implemented with datagram-oriented transport protocols, such as the User Datagram Protocol (UDP) and the Datagram Congestion Control Protocol (DC*****), usage which has been standardized independently using the term Datagram Transport Layer Security (DTLS).

Websites

A prominent use of TLS is for securing World Wide Web traffic between the website and the browser carried by HTTP to form HTTPS. Notable applications are electronic commerce and asset management.

Website protocol support
Protocol
version
Website
support<ref name="trustworthy_ssl_pulse">As of September 4, 2014. Template:Cite web</ref>
Security<ref name="trustworthy_ssl_pulse"/><ref name="community.qualys">Template:Cite web</ref>
SSL 2.0 19.9% (−0.6%) Template:Bad
SSL 3.0 98.3% (−0.2%) Template:Depends
TLS 1.0 99.3% (±0.0%) Template:Depends
TLS 1.1 40.2% (+1.8%) Template:Depends
TLS 1.2 42.6% (+1.8%) Template:Depends
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Web browsers

Template:Further Template:As of, the latest version of all major web browsers support SSL 3.0, TLS 1.0, 1.1, and 1.2 enabled by default and mitigations against known attacks have been implemented.
However, there are still problems on several version of browsers which are not the latest but still supported:

  • support TLS 1.1 and 1.2 but disabled by default: Internet Explorer (8–10 for Windows 7 / Server 2018 R2, 10 for Windows 8 / Server 2012, Mobile 10 for Windows Phone 8), Opera 12
  • not support TLS 1.1 and 1.2: Internet Explorer (6-8 for Windows Server 2003, 7–9 for Windows Vista / Server 2008, Mobile 7 and 9 for Windows Phone 7.x), Safari 6 for Mac OS X 10.7 and 10.8
  • mitigations against known attacks have not been implemented: Safari 6 for Mac OS X 10.7

Template:Clear Template:TLS/SSL support history of web browsers

Libraries

Template:Main Most SSL and TLS programming libraries are free and open source software.

Library support for TLS/SSL
Implementation SSL 2.0
(insecure)
SSL 3.0 TLS 1.0 TLS 1.1 TLS 1.2
Botan Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:Yes Template:Yes
cryptlib Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
CyaSSL Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
GnuTLS Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:Yes Template:Yes
MatrixSSL Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:Yes Template:Yes
NSS Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:Yes<ref name=NSS-3.14>Template:Cite web</ref> Template:Yes<ref name=NSS-3.15.1>Template:Cite web</ref>
OpenSSL

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LibreSSL Template:Yes Template:Yes Template:Yes Template:Yes<ref name=openssl_changelog /> Template:Yes<ref name=openssl_changelog />
PolarSSL Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
SChannel XP / 2003<ref name=XP2003schannel>TLS cipher suites in Microsoft Windows XP and 2003</ref> Template:Partial Template:Yes Template:Partial

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SChannel 8 / 2012<ref name=Windows7schannel/> Template:Yes Template:Yes Template:Yes Template:Partial Template:Partial
SChannel 8.1 / 2012 R2<ref name=Windows7schannel/> Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
Secure Transport OS X 10.2-10.7 / iOS 1-4

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Secure Transport OS X 10.8-10.10 / iOS 5-8 Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:YesTemplate:Cref2 Template:YesTemplate:Cref2
SharkSSL Template:Yes Template:Yes Template:Yes Template:Yes Template:Yes
JSSE Template:YesTemplate:Cref2 Template:Yes Template:Yes Template:Yes Template:Yes
Implementation SSL 2.0
(insecure)
SSL 3.0 TLS 1.0 TLS 1.1 TLS 1.2

Template:Cnote2 begin Template:Cnote2 Template:Cnote2 Template:Cnote2 end

A paper presented at the 2012 ACM conference on computer and communications security<ref>Template:Cite book</ref> showed that few applications used some of these SSL libraries incorrectly, leading to vulnerabilities. According to the authors

"the root cause of most of these vulnerabilities is the terrible design of the APIs to the underlying SSL libraries. Instead of expressing high-level security properties of network tunnels such as confidentiality and authentication, these APIs expose low-level details of the SSL protocol to application developers. As a consequence, developers often use SSL APIs incorrectly, misinterpreting and misunderstanding their manifold parameters, options, side effects, and return values."

Other uses

The Simple Mail Transfer Protocol (SMTP) can also be protected by TLS. These applications use public key certificates to verify the identity of endpoints.

TLS can also be used to tunnel an entire network stack to create a VPN, as is the case with OpenVPN and OpenConnect. Many vendors now marry TLS's encryption and authentication capabilities with authorization. There has also been substantial development since the late 1990s in creating client technology outside of the browser to enable support for client/server applications. When compared against traditional IPsec VPN technologies, TLS has some inherent advantages in firewall and NAT traversal that make it easier to administer for large remote-access populations.

TLS is also a standard method to protect Session Initiation Protocol (SIP) application signaling. TLS can be used to provide authentication and encryption of the SIP signaling associated with VoIP and other SIP-based applications.Template:Citation needed

Security

SSL 2.0

SSL 2.0 is flawed in a variety of ways:<ref>Template:Cite journal</ref>

  • Identical cryptographic keys are used for message authentication and encryption.
  • SSL 2.0 has a weak MAC construction that uses the MD5 hash function with a secret prefix, making it vulnerable to length extension attacks.
  • SSL 2.0 does not have any protection for the handshake, meaning a man-in-the-middle downgrade attack can go undetected.
  • SSL 2.0 uses the T***** connection close to indicate the end of data. This means that truncation attacks are possible: the attacker simply forges a T***** FIN, leaving the recipient unaware of an illegitimate end of data message (SSL 3.0 fixes this problem by having an explicit closure alert).
  • SSL 2.0 assumes a single service and a fixed domain certificate, which clashes with the standard feature of virtual hosting in Web servers. This means that most websites are practically impaired from using SSL.

SSL 2.0 is disabled by default, beginning with Internet Explorer 7,<ref>Template:Cite web</ref> Mozilla Firefox 2,<ref>Template:Cite web</ref> Opera 9.5,<ref>"Opera 9.5 for Windows Changelog" at Opera.com: "Disabled SSL v2 and weak ciphers."</ref> and Safari. After it sends a TLS "ClientHello", if Mozilla Firefox finds that the server is unable to complete the handshake, it will attempt to fall back to using SSL 3.0 with an SSL 3.0 "ClientHello" in SSL 2.0 format to maximize the likelihood of successfully handshaking with older servers.<ref>Template:Cite web</ref> Support for SSL 2.0 (and weak 40-bit and 56-bit ciphers) has been removed completely from Opera as of version 10.<ref>"Opera 10 for Windows changelog" at Opera.com: "Removed support for SSL v2 and weak ciphers"</ref><ref>Template:Cite webTemplate:Dead link</ref>

SSL 3.0

SSL 3.0 improved upon SSL 2.0 by adding SHA-1–based ciphers and support for certificate authentication.

From a security standpoint, SSL 3.0 should be considered less desirable than TLS 1.0. The SSL 3.0 cipher suites have a weaker key derivation process; half of the master key that is established is fully dependent on the MD5 hash function, which is not resistant to collisions and is, therefore, not considered secure. Under TLS 1.0, the master key that is established depends on both MD5 and SHA-1 so its derivation process is not currently considered weak. It is for this reason that SSL 3.0 implementations cannot be validated under FIPS 140-2.<ref>Template:Cite web</ref>

TLS

TLS has a variety of security measures:

  • Protection against a downgrade of the protocol to a previous (less secure) version or a weaker cipher suite.
  • Numbering subsequent Application records with a sequence number and using this sequence number in the message authentication codes (MACs).
  • Using a message digest enhanced with a key (so only a key-holder can check the MAC). The HMAC construction used by most TLS cipher suites is specified in RFC 2104 (SSL 3.0 used a different hash-based MAC).
  • The message that ends the handshake ("Finished") sends a hash of all the exchanged handshake messages seen by both parties.
  • The pseudorandom function splits the input data in half and processes each one with a different hashing algorithm (MD5 and SHA-1), then XORs them together to create the MAC. This provides protection even if one of these algorithms is found to be vulnerable.

Attacks against TLS/SSL

Significant attacks against TLS/SSL are listed below:

Renegotiation attack

A vulnerability of the renegotiation procedure was discovered in August 2009 that can lead to plaintext injection attacks against SSL 3.0 and all current versions of TLS. For example, it allows an attacker who can hijack an https connection to splice their own requests into the beginning of the conversation the client has with the web server. The attacker can't actually decrypt the client-server communication, so it is different from a typical man-in-the-middle attack. A short-term fix is for web servers to stop allowing renegotiation, which typically will not require other changes unless client certificate authentication is used. To fix the vulnerability, a renegotiation indication extension was proposed for TLS. It will require the client and server to include and verify information about previous handshakes in any renegotiation handshakes.<ref>Template:Cite web</ref> This extension has become a proposed standard and has been assigned the number RFC 5746. The RFC has been implemented by several libraries.<ref>Template:Cite web</ref><ref>Template:Cite web</ref><ref>Template:Cite web</ref>

Version rollback attacks

Modifications to the original protocols, like False Start<ref>Template:Cite web</ref> (adopted and enabled by Google Chrome<ref>Template:Cite web</ref>) or Snap Start, have reportedly introduced limited TLS protocol version rollback attacks<ref>Template:Cite web</ref> or allowed modifications to the cipher suite list sent by the client to the server (an attacker may succeed in influencing the cipher suite selection in an attempt to downgrade the cipher suite strength, to use either a weaker symmetric encryption algorithm or a weaker key exchange<ref> Template:Cite web</ref>). A paper presented at an Association for Computing Machinery (ACM) conference on computer and communications security in 2012 demonstrates that the False Start extension is at risk: in certain circumstances it could allow an attacker to recover the encryption keys offline and to access the encrypted data.<ref> Template:Cite book </ref>

BEAST attack

On September 23, 2011 researchers Thai Duong and Juliano Rizzo demonstrated a proof of concept called BEAST (Browser Exploit Against SSL/TLS)<ref name=DuongRizzo>Template:Cite web</ref> using a Java applet to violate same origin policy constraints, for a long-known cipher block chaining (CBC) vulnerability in TLS 1.0.<ref name=DanGoodin>Template:Cite web</ref><ref name=combinator>Template:Cite web</ref> Practical exploits had not been previously demonstrated for this vulnerability, which was originally discovered by Phillip Rogaway<ref>Template:Cite web</ref> in 2002. The vulnerability of the attack had been fixed with TLS 1.1 in 2006, but TLS 1.1 had not seen wide adoption prior to this attack demonstration.

Mozilla updated the development versions of their NSS libraries to mitigate BEAST-like attacks. NSS is used by Mozilla Firefox and Google Chrome to implement SSL. Some web servers that have a broken implementation of the SSL specification may stop working as a result.<ref>Template:Cite web</ref>

Microsoft released Security Bulletin MS12-006 on January 10, 2012, which fixed the BEAST vulnerability by changing the way that the Windows Secure Channel (SChannel) component transmits encrypted network packets.<ref>Template:Cite web</ref>

Users of Windows 7, Windows 8 and Windows Server 2008 R2 can enable use of TLS 1.1 and 1.2, but this workaround will fail if it is not supported by the other end of the connection and will result in a fall-back to TLS 1.0.

Template:Anchor CRIME and BREACH attacks

Template:Main The authors of the BEAST attack are also the creators of the later CRIME attack, which can allow an attacker to recover the content of web cookies when data compression is used along with TLS.<ref>Template:Cite web</ref><ref>Template:Cite webTemplate:Dead link</ref> When used to recover the content of secret authentication cookies, it allows an attacker to perform session hijacking on an authenticated web session.

While the CRIME attack was presented as a general attack that could work effectively against a large number of protocols, including but not limited to TLS, and application-layer protocols such as SPDY or HTTP, only exploits against TLS and SPDY were demonstrated and largely mitigated in browsers and servers. The CRIME exploit against HTTP compression has not been mitigated at all, even though the authors of CRIME have warned that this vulnerability might be even more widespread than SPDY and TLS compression combined. In 2013 a new instance of the CRIME attack against HTTP compression, dubbed BREACH, was announced. Built based on the CRIME attack a BREACH attack can extract login tokens, email addresses or other sensitive information from TLS encrypted web traffic in as little as 30 seconds (depending on the number of bytes to be extracted), provided the attacker tricks the victim into visiting a malicious web link or is able to inject content into valid pages the user is visiting (ex: a wireless network under the control of the attacker).<ref name=Gooin20130801>Template:Cite web</ref> All versions of TLS and SSL are at risk from BREACH regardless of the encryption algorithm or cipher used.<ref>Template:Cite web</ref> Unlike previous instances of CRIME, which can be successfully defended against by turning off TLS compression or SPDY header compression, BREACH exploits HTTP compression which cannot realistically be turned off, as virtually all web servers rely upon it to improve data transmission speeds for users.<ref name=Gooin20130801/> This is a known limitation of TLS as it is susceptible to chosen-plaintext attack against the application-layer data it was meant to protect.

Padding attacks

Earlier TLS versions were vulnerable against the padding oracle attack discovered in 2002. A novel variant, called the Lucky Thir***** attack, was published in 2013. As of February 2013, TLS implementors were still working on developing fixes to protect against this form of attack.

RC4 attacks

In spite of existing attacks on RC4 that break it, the cipher suites based on RC4 in SSL and TLS were at one time considered secure because of the way the cipher was used in these protocols defeated the attacks that broke RC4 until new attacks disclosed in March 2013 allowed RC4 in TLS to be feasibly completely broken. In 2011 the RC4 suite was actually recommended as a work around for the BEAST attack.<ref>security – Safest ciphers to use with the BEAST? (TLS 1.0 exploit) I've read that RC4 is immune – Server Fault</ref> In 2013 a vulnerability was discovered in RC4 suggesting it was not a good workaround for BEAST.<ref name="community.qualys"/> An attack scenario was proposed by AlFardan, Bernstein, Paterson, Poettering and Schuldt that used newly discovered statistical biases in the RC4 key table<ref>Template:Cite journal</ref> to recover parts of the plaintext with a large number of TLS encryptions.<ref>Template:Cite web</ref><ref>Template:Cite web</ref> A double-byte bias attack on RC4 in TLS and SSL that requires 13 × 220 encryptions to break RC4 was unveiled on 8 July 2013, and it was described as "feasible" in the accompanying presentation at the 22nd USENIX Security Symposium on August 15, 2013.<ref>Template:Cite journal</ref><ref>Template:Cite conference</ref>

However, many modern browsers have been designed to defeat BEAST attacks (except Safari for Mac OS X 10.8 or earlier, for iOS 6 or earlier, and for Windows; see #Web browsers). As a result, RC4 is not the best choice for TLS 1.0 anymore. The CBC ciphers which were affected by the BEAST attack in the past are becoming a more popular choice for protection.<ref name="best-practices"/>

Microsoft recommends disabling RC4 where possible.<ref>Template:Cite web</ref><ref>Template:Cite web</ref>

Truncation attack

A TLS truncation attack blocks a victim's account logout requests so that the user unknowingly remains logged into a web service. When the request to sign out is sent, the attacker injects an unencrypted T***** FIN message (no more data from sender) to close the connection. The server therefore doesn't receive the logout request and is unaware of the abnormal termination.<ref name=register20130801>Template:Cite web</ref>

Published in July 2013,<ref>Template:Cite web</ref> the attack causes web services such as Gmail and Hotmail to display a page that informs the user that they have successfully signed-out, while ensuring that the user's browser maintains authorization with the service, allowing an attacker with subsequent access to the browser to access and take over control of the user's logged-in account. The attack does not rely on installing malware on the victim's computer; attackers need only place themselves between the victim and the web server (e.g., by setting up a rogue wireless hotspot).<ref name=register20130801/> This vulnerability also requires access to the victim's computer.

Heartbleed Bug

The Heartbleed bug is a serious vulnerability in the popular OpenSSL cryptographic software library, affecting versions 1.0.1 to 1.0.1f. This weakness allows stealing the information protected, under normal conditions, by the SSL/TLS encryption used to secure the data payloads. SSL/TLS provides communication security and privacy over the Internet for applications such as web, email, instant messaging (IM) and some virtual private networks (VPNs).<ref>Template:Cite web</ref>

The Heartbleed bug allows anyone on the Internet to read the memory of the systems protected by the vulnerable versions of the OpenSSL software. This compromises the secret keys used to identify the service providers and to encrypt the traffic, the names and passwords of the users and the actual content. This allows attackers to eavesdrop on communications, steal data directly from the services and users and to impersonate services and users.<ref>Template:Cite web</ref>

Survey of websites

Template:As of, Trustworthy Internet Movement estimate the ratio of websites that are vulnerable to TLS attacks.<ref name="trustworthy_ssl_pulse" />

Survey of the TLS vulnerabilities of the most popular websites
Attacks Security
Insecure Depends Secure Other
Renegotiation attack Template:N/A Template:Bad Template:Partial Template:Good 5.9% (−0.1%)
not support
RC4 attacks Template:Bad Template:Bad Template:Partial Template:Good Template:N/A
BEAST attack Template:N/A Template:Bad Template:N/A Template:N/A Template:N/A
CRIME attack Template:N/A Template:Bad Template:N/A Template:N/A Template:N/A
Heartbleed Template:N/A Template:Bad Template:N/A Template:N/A Template:N/A
CVE-2014-0224 Template:N/A Template:Bad Template:Partial Template:Good 0.9% (+0.2%)
unknown

Forward secrecy

Template:Main Forward secrecy is a property of cryptographic systems which ensures that a session key derived from a set of public and private keys will not be compromised if one of the private keys is compromised in the future.<ref>Template:Cite journal</ref> An implementation of TLS can provide forward secrecy by requiring the use of ephemeral Diffie-Hellman key exchange to establish session keys, and some notable TLS implementations do so exclusively: e.g., Gmail and other Google HTTPS services that use OpenSSL.<ref>Template:Cite web</ref> However, many clients and servers supporting TLS (including browsers and web servers) are not configured to implement such restrictions.<ref>Template:Cite web</ref><ref>Template:Cite web</ref> Without forward secrecy, if the server's private key is compromised, not only will all future TLS-encrypted sessions using that server certificate be compromised, but also any past sessions that used it as well (provided of course that these past sessions were intercepted and stored at the time of transmission).<ref>Discussion on the TLS mailing list in October 2007</ref> In practice, unless a web service uses Diffie-Hellman key exchange to implement forward secrecy, all of the encrypted web traffic to and from that service can be decrypted by a third party if it obtains the server's master (private) key; e.g., by means of a court order.<ref>Template:Cite web</ref>

Even where Diffie-Hellman key exchange is implemented, server-side session management mechanisms can impact forward secrecy. The use of TLS session tickets (a TLS extension) causes the session to be protected by AES128-CBC-SHA256 regardless of any other negotiated TLS parameters, including forward secrecy ciphersuites, and the long-lived TLS session ticket keys defeat the attempt to implement forward secrecy.<ref name="botchingpfs"/><ref name="ticketsecwp"/><ref name="ticketsecslides"/>

Since late 2011, Google has provided forward secrecy with TLS by default to users of its Gmail service, along with Google Docs and encrypted search among other services.<ref name="googleLongTerm">Template:Cite web</ref> Since November 2013, Twitter has provided forward secrecy with TLS to users of its service.<ref>Template:Cite web</ref> Template:As of, 12.6% of TLS-enabled websites are configured to use cipher suites that provide forward secrecy to web browsers.<ref name="trustworthy_ssl_pulse" />

Avoiding Triple-DES CBC

Some experts recommend avoiding Triple-DES CBC. Since the last supported ciphers developed to support any program using Windows XP's SSL/TLS library like Internet Explorer on Windows XP are RC4 and Triple-DES, this makes it difficult to support SSL for any program using this library on XP.<ref name="best-practices"/>

Dealing with MITM attacks

Template:Main

Certificate pinning

One way to detect and block many kinds of MITM attacks is "certificate pinning", sometimes called "SSL pinning".<ref> "Certificate Pinning". </ref> A client that does certificate pinning adds an extra step to the normal TLS protocol or SSL protocol: After obtaining the server's certificate in the standard way, the client checks the server's certificate against trusted validation data. Typically the trusted validation data is bundled with the application, in the form of a trusted copy of that certificate, or a trusted hash or fingerprint of that certificate or the certificate's public key. For example, Chromium and Google Chrome include validation data for the *.google.com certificate that detected fraudulent certificates in 2011.

In other systems the client hopes that the first time it obtains a server's certificate it is trustworthy and stores it; during later sessions with that server, the client checks the server's certificate against the stored certificate to guard against later MITM attacks.

Perspectives Project

The Perspectives Project<ref>Perspectives Project</ref> operates network notaries that clients can use to detect if a site's certificate has changed. By their nature, man-in-the-middle attacks place the attacker between the destination and a single specific target. As such, Perspectives would warn the target that the certificate delivered to the web browser does not match the certificate seen from other perspectives - the perspectives of other users in different times and places. Use of network notaries from a multitude of perspectives makes it possible for a target to detect an attack even if a certificate appears to be completely valid.

Protocol details

The TLS protocol exchanges records—which encapsulate the data to be exchanged in a specific format (see below). Each record can be compressed, padded, appended with a message authentication code (MAC), or encrypted, all depending on the state of the connection. Each record has a content type field that designates the type of data encapsulated, a length field and a TLS version field. The data encapsulated may be control or procedural messages of the TLS itself, or simply the application data needed to be transferred by TLS. The specifications (cipher suite, keys etc.) required to exchange application data by TLS, are agreed upon in the "TLS handshake" between the client requesting the data and the server responding to requests. The protocol therefore defines both the structure of payloads transferred in TLS and the procedure to establish and monitor the transfer.

TLS handshake

When the connection starts, the record encapsulates a "control" protocol—the handshake messaging protocol  (content type 22). This protocol is used to exchange all the information required by both sides for the exchange of the actual application data by TLS. It defines the messages formatting or containing this information and the order of their exchange. These may vary according to the demands of the client and server—i.e., there are several possible procedures to set up the connection. This initial exchange results in a successful TLS connection (both parties ready to transfer application data with TLS) or an alert message (as specified below).

Basic TLS handshake

A simple connection example follows, illustrating a handshake where the server (but not the client) is authenticated by its certificate:

  1. Negotiation phase:
    • A client sends a ClientHello message specifying the highest TLS protocol version it supports, a random number, a list of suggested CipherSuites and suggested compression methods. If the client is attempting to perform a resumed handshake, it may send a session ID.
    • The server responds with a ServerHello message, containing the chosen protocol version, a random number, CipherSuite and compression method from the choices offered by the client. To confirm or allow resumed handshakes the server may send a session ID. The chosen protocol version should be the highest that both the client and server support. For example, if the client supports TLS1.1 and the server supports TLS1.2, TLS1.1 should be selected; SSL 3.0 should not be selected.
    • The server sends its Certificate message (depending on the selected cipher suite, this may be omitted by the server).<ref name="openpgp">These certificates are currently X.509, but RFC 6091 also specifies the use of OpenPGP-based certificates.</ref>
    • The server sends its ServerKeyExchange message (depending on the selected cipher suite, this may be omitted by the server). This message is sent for all DHE and DH_anon ciphersuites.<ref name=RFC5246>Template:Cite web</ref>
    • The server sends a ServerHelloDone message, indicating it is done with handshake negotiation.
    • The client responds with a ClientKeyExchange message, which may contain a PreMasterSecret, public key, or nothing. (Again, this depends on the selected cipher.) This PreMasterSecret is encrypted using the public key of the server certificate.
    • The client and server then use the random numbers and PreMasterSecret to compute a common secret, called the "master secret". All other key data for this connection is derived from this master secret (and the client- and server-generated random values), which is passed through a carefully designed pseudorandom function.
  2. The client now sends a ChangeCipherSpec record, essentially telling the server, "Everything I tell you from now on will be authenticated (and encrypted if encryption parameters were present in the server certificate)." The ChangeCipherSpec is itself a record-level protocol with content type of 20.
    • Finally, the client sends an authenticated and encrypted Finished message, containing a hash and MAC over the previous handshake messages.
    • The server will attempt to decrypt the client's Finished message and verify the hash and MAC. If the decryption or verification fails, the handshake is considered to have failed and the connection should be torn down.
  3. Finally, the server sends a ChangeCipherSpec, telling the client, "Everything I tell you from now on will be authenticated (and encrypted, if encryption was negotiated)."
    • The server sends its authenticated and encrypted Finished message.
    • The client performs the same decryption and verification.
  4. Application phase: at this point, the "handshake" is complete and the application protocol is enabled, with content type of 23. Application messages exchanged between client and server will also be authenticated and optionally encrypted exactly like in their Finished message. Otherwise, the content type will return 25 and the client will not authenticate.

Client-authenticated TLS handshake

The following full example shows a client being authenticated (in addition to the server like above) via TLS using certificates exchanged between both peers.

  1. Negotiation Phase:
    • A client sends a ClientHello message specifying the highest TLS protocol version it supports, a random number, a list of suggested cipher suites and compression methods.
    • The server responds with a ServerHello message, containing the chosen protocol version, a random number, cipher suite and compression method from the choices offered by the client. The server may also send a session id as part of the message to perform a resumed handshake.
    • The server sends its Certificate message (depending on the selected cipher suite, this may be omitted by the server).<ref name="openpgp"/>
    • The server sends its ServerKeyExchange message (depending on the selected cipher suite, this may be omitted by the server). This message is sent for all DHE and DH_anon ciphersuites.<ref name=RFC5246>Template:Cite web</ref>
    • The server requests a certificate from the client, so that the connection can be mutually authenticated, using a CertificateRequest message.
    • The server sends a ServerHelloDone message, indicating it is done with handshake negotiation.
    • The client responds with a Certificate message, which contains the client's certificate.
    • The client sends a ClientKeyExchange message, which may contain a PreMasterSecret, public key, or nothing. (Again, this depends on the selected cipher.) This PreMasterSecret is encrypted using the public key of the server certificate.
    • The client sends a CertificateVerify message, which is a signature over the previous handshake messages using the client's certificate's private key. This signature can be verified by using the client's certificate's public key. This lets the server know that the client has access to the private key of the certificate and thus owns the certificate.
    • The client and server then use the random numbers and PreMasterSecret to compute a common secret, called the "master secret". All other key data for this connection is derived from this master secret (and the client- and server-generated random values), which is passed through a carefully designed pseudorandom function.
  2. The client now sends a ChangeCipherSpec record, essentially telling the server, "Everything I tell you from now on will be authenticated (and encrypted if encryption was negotiated). " The ChangeCipherSpec is itself a record-level protocol and has type 20 and not 22.
    • Finally, the client sends an encrypted Finished message, containing a hash and MAC over the previous handshake messages.
    • The server will attempt to decrypt the client's Finished message and verify the hash and MAC. If the decryption or verification fails, the handshake is considered to have failed and the connection should be torn down.
  3. Finally, the server sends a ChangeCipherSpec, telling the client, "Everything I tell you from now on will be authenticated (and encrypted if encryption was negotiated). "
    • The server sends its own encrypted Finished message.
    • The client performs the same decryption and verification.
  4. Application phase: at this point, the "handshake" is complete and the application protocol is enabled, with content type of 23. Application messages exchanged between client and server will also be encrypted exactly like in their Finished message.

Resumed TLS handshake

Public key operations (e.g., RSA) are relatively expensive in terms of computational power. TLS provides a secure shortcut in the handshake mechanism to avoid these operations: resumed sessions. Resumed sessions are implemented using session IDs or session tickets.

Apart from the performance benefit, resumed sessions can also be used for single sign-on as it is guaranteed that both the original session as well as any resumed session originate from the same client. This is of particular importance for the FTP over TLS/SSL protocol which would otherwise suffer from a man-in-the-middle attack in which an attacker could intercept the contents of the secondary data connections.<ref>Template:Cite web</ref>

Session IDs

In an ordinary full handshake, the server sends a session id as part of the ServerHello message. The client associates this session id with the server's IP address and T***** port, so that when the client connects again to that server, it can use the session id to shortcut the handshake. In the server, the session id maps to the cryptographic parameters previously negotiated, specifically the "master secret". Both sides must have the same "master secret" or the resumed handshake will fail (this prevents an eavesdropper from using a session id). The random data in the ClientHello and ServerHello messages virtually guarantee that the generated connection keys will be different from in the previous connection. In the RFCs, this type of handshake is called an abbreviated handshake. It is also described in the literature as a restart handshake.

  1. Negotiation phase:
    • A client sends a ClientHello message specifying the highest TLS protocol version it supports, a random number, a list of suggested cipher suites and compression methods. Included in the message is the session id from the previous TLS connection.
    • The server responds with a ServerHello message, containing the chosen protocol version, a random number, cipher suite and compression method from the choices offered by the client. If the server recognizes the session id sent by the client, it responds with the same session id. The client uses this to recognize that a resumed handshake is being performed. If the server does not recognize the session id sent by the client, it sends a different value for its session id. This tells the client that a resumed handshake will not be performed. At this point, both the client and server have the "master secret" and random data to generate the key data to be used for this connection.
  2. The server now sends a ChangeCipherSpec record, essentially telling the client, "Everything I tell you from now on will be encrypted." The ChangeCipherSpec is itself a record-level protocol and has type 20 and not 22.
    • Finally, the server sends an encrypted Finished message, containing a hash and MAC over the previous handshake messages.
    • The client will attempt to decrypt the server's Finished message and verify the hash and MAC. If the decryption or verification fails, the handshake is considered to have failed and the connection should be torn down.
  3. Finally, the client sends a ChangeCipherSpec, telling the server, "Everything I tell you from now on will be encrypted. "
    • The client sends its own encrypted Finished message.
    • The server performs the same decryption and verification.
  4. Application phase: at this point, the "handshake" is complete and the application protocol is enabled, with content type of 23. Application messages exchanged between client and server will also be encrypted exactly like in their Finished message.
Session tickets

RFC 5077 extends TLS via use of session tickets, instead of session IDs. It defines a way to resume a TLS session without requiring that session-specific state is stored at the TLS server.

When using session tickets, the TLS server stores its session-specific state in a session ticket and sends the session ticket to the TLS client for storing. The client resumes a TLS session by sending the session ticket to the server, and the server resumes the TLS session according to the session-specific state in the ticket. The session ticket is encrypted and authenticated by the server, and the server verifies its validity before using its contents.

One particular weakness of this method is that it always limits encryption and authentication security of the transmitted TLS session ticket to AES128-CBC-SHA256, no matter what other TLS parameters were negotiated for the actual TLS session.<ref name="ticketsecwp">Template:Cite web</ref> This means that the state information (the TLS session ticket) is not as well protected as the TLS session itself. Of particular concern is OpenSSL's storage of the keys in an application-wide context (SSL_CTX), i.e. for the life of the application, and not allowing for re-keying of the AES128-CBC-SHA256 TLS session tickets without resetting the application-wide OpenSSL context (which is uncommon, error-prone and often requires manual administrative intervention).<ref name="ticketsecslides">Template:Cite web</ref><ref name="botchingpfs">Template:Cite web</ref>

TLS record

This is the general format of all TLS records.

+ Byte +0 Byte +1 Byte +2 Byte +3
Byte
0
Content type  
Bytes
1..4
Version Length
(Major) (Minor) (bits 15..8) (bits 7..0)
Bytes
5..(m-1)
Protocol message(s)
Bytes
m..(p-1)
MAC (optional)
Bytes
p..(q-1)
Padding (block ciphers only)
Content type
This field identifies the Record Layer Protocol Type contained in this Record.
Content types
Hex Dec Type
0x14 20 ChangeCipherSpec
0x15 21 Alert
0x16 22 Handshake
0x17 23 Application
0x18 24 Heartbeat
Version
This field identifies the major and minor version of TLS for the contained message. For a ClientHello message, this need not be the highest version supported by the client.
Versions
Major
Version
Minor
Version
Version Type
3 0 SSL 3.0
3 1 TLS 1.0
3 2 TLS 1.1
3 3 TLS 1.2
Length
The length of Protocol message(s), MAC and Padding, not to exceed 214 bytes (16 KiB).
Protocol message(s)
One or more messages identified by the Protocol field. Note that this field may be encrypted depending on the state of the connection.
MAC and Padding
A message authentication code computed over the Protocol message, with additional key material included. Note that this field may be encrypted, or not included entirely, depending on the state of the connection.
No MAC or Padding can be present at end of TLS records before all cipher algorithms and parameters have been negotiated and handshaked and then confirmed by sending a CipherStateChange record (see below) for signalling that these parameters will take effect in all further records sent by the same peer.

Handshake protocol

Most messages exchanged during the setup of the TLS session are based on this record, unless an error or warning occurs and needs to be signaled by an Alert protocol record (see below), or the encryption mode of the session is modified by another record (see ChangeCipherSpec protocol below).

+ Byte +0 Byte +1 Byte +2 Byte +3
Byte
0
22  
Bytes
1..4
Version Length
(Major) (Minor) (bits 15..8) (bits 7..0)
Bytes
5..8
Message type Handshake message data length
(bits 23..16) (bits 15..8) (bits 7..0)
Bytes
9..(n-1)
Handshake message data
Bytes
n..(n+3)
Message type Handshake message data length
(bits 23..16) (bits 15..8) (bits 7..0)
Bytes
(n+4)..
Handshake message data
Message type
This field identifies the Handshake message type.
Message Types
Code Description
0 HelloRequest
1 ClientHello
2 ServerHello
4 NewSessionTicket
11 Certificate
12 ServerKeyExchange
13 CertificateRequest
14 ServerHelloDone
15 CertificateVerify
16 ClientKeyExchange
20 Finished
Handshake message data length
This is a 3-byte field indicating the length of the handshake data, not including the header.

Note that multiple Handshake messages may be combined within one record.

Alert protocol

This record should normally not be sent during normal handshaking or application exchanges. However, this message can be sent at any time during the handshake and up to the closure of the session. If this is used to signal a fatal error, the session will be closed immediately after sending this record, so this record is used to give a reason for this closure. If the alert level is flagged as a warning, the remote can decide to close the session if it decides that the session is not reliable enough for its needs (before doing so, the remote may also send its own signal).

+ Byte +0 Byte +1 Byte +2 Byte +3
Byte
0
21  
Bytes
1..4
Version Length
(Major) (Minor) 0 2
Bytes
5..6
Level Description  
Bytes
7..(p-1)
MAC (optional)
Bytes
p..(q-1)
Padding (block ciphers only)
Level
This field identifies the level of alert. If the level is fatal, the sender should close the session immediately. Otherwise, the recipient may decide to terminate the session itself, by sending its own fatal alert and closing the session itself immediately after sending it. The use of Alert records is optional, however if it is missing before the session closure, the session may be resumed automatically (with its handshakes).
Normal closure of a session after termination of the transported application should preferably be alerted with at least the Close notify Alert type (with a simple warning level) to prevent such automatic resume of a new session. Signalling explicitly the normal closure of a secure session before effectively closing its transport layer is useful to prevent or detect attacks (like attempts to truncate the securely transported data, if it intrinsically does not have a predetermined length or duration that the recipient of the secured data may expect).
Alert level types
Code Level type Connection state
1 warning connection or security may be unstable.
2 fatal connection or security may be compromised, or an unrecoverable error has occurred.
Description
This field identifies which type of alert is being sent.
Alert description types
Code Description Level types Note
0 Close notify warning/fatal
10 Unexpected message fatal
20 Bad record MAC fatal Possibly a bad SSL implementation, or payload has been tampered with e.g. FTP firewall rule on FTPS server.
21 Decryption failed fatal TLS only, reserved
22 Record overflow fatal TLS only
30 Decompression failure fatal
40 Handshake failure fatal
41 No certificate warning/fatal SSL 3.0 only, reserved
42 Bad certificate warning/fatal
43 Unsupported certificate warning/fatal e.g. certificate has only Server authentication usage enabled and is presented as a client certificate
44 Certificate revoked warning/fatal
45 Certificate expired warning/fatal Check server certificate expire also check no certificate in the chain presented has expired
46 Certificate unknown warning/fatal
47 Illegal parameter fatal
48 Unknown CA (Certificate authority) fatal TLS only
49 Access denied fatal TLS only – e.g. no client certificate has been presented (TLS: Blank certificate message or SSLv3: No Certificate alert), but server is configured to require one.
50 Decode error fatal TLS only
51 Decrypt error warning/fatal TLS only
60 Export restriction fatal TLS only, reserved
70 Protocol version fatal TLS only
71 Insufficient security fatal TLS only
80 Internal error fatal TLS only
90 User canceled fatal TLS only
100 No renegotiation warning TLS only
110 Unsupported extension warning TLS only
111 Certificate unobtainable warning TLS only
112 Unrecognized name warning TLS only; client's Server Name Indicator specified a hostname not supported by the server
113 Bad certificate status response fatal TLS only
114 Bad certificate hash value fatal TLS only
115 Unknown PSK identity (used in TLS-PSK and TLS-SRP) fatal TLS only
120 No Application Protocol fatal TLS only, client's ALPN did not contain any server-supported protocols

ChangeCipherSpec protocol

+ Byte +0 Byte +1 Byte +2 Byte +3
Byte
0
20  
Bytes
1..4
Version Length
(Major) (Minor) 0 1
Byte
5
CCS protocol type  
CCS protocol type
Currently only 1.

Application protocol

+ Byte +0 Byte +1 Byte +2 Byte +3
Byte
0
23  
Bytes
1..4
Version Length
(Major) (Minor) (bits 15..8) (bits 7..0)
Bytes
5..(m-1)
Application data
Bytes
m..(p-1)
MAC (optional)
Bytes
p..(q-1)
Padding (block ciphers only)
Length
Length of Application data (excluding the protocol header and including the MAC and padding trailers)
MAC
20 bytes for the SHA-1-based HMAC, 16 bytes for the MD5-based HMAC.
Padding
Variable length; last byte contains the padding length.

Support for name-based virtual servers

From the application protocol point of view, TLS belongs to a lower layer, although the T*****/IP model is too coarse to show it. This means that the TLS handshake is usually (except in the STARTTLS case) performed before the application protocol can start. In the name-based virtual server feature being provided by the application layer, all co-hosted virtual servers share the same certificate because the server has to select and send a certificate immediately after the ClientHello message. This is a big problem in hosting environments because it means either sharing the same certificate among all customers or using a different IP address for each of them.

There are two known workarounds provided by X.509:

  • If all virtual servers belong to the same domain, a wildcard certificate can be used. Besides the loose host name selection that might be a problem or not, there is no common agreement about how to match wildcard certificates. Different rules are applied depending on the application protocol or software used.<ref name=SWITCH-vhosts>Template:Cite web</ref>
  • Add every virtual host name in the subjectAltName extension. The major problem being that the certificate needs to be reissued whenever a new virtual server is added.

In order to provide the server name, RFC 4366 Transport Layer Security (TLS) Extensions allow clients to include a Server Name Indication extension (SNI) in the extended ClientHello message. This extension hints the server immediately which name the client wishes to connect to, so the server can select the appropriate certificate to send to the client.

Standards

The current approved version of TLS is version 1.2, which is specified in:

  • RFC 5246: "The Transport Layer Security (TLS) Protocol Version 1.2".

The current standard replaces these former versions, which are now considered obsolete:

  • RFC 2246: "The TLS Protocol Version 1.0".
  • RFC 4346: "The Transport Layer Security (TLS) Protocol Version 1.1".

as well as the never standardized SSL 2.0 and 3.0:

  • Template:Cite web This Internet Draft defines the now completely broken SSL 2.0.
  • RFC 6101: "The Secure Sockets Layer (SSL) Protocol Version 3.0".

Other RFCs subsequently extended TLS.

Extensions to TLS 1.0 include:

  • RFC 2595: "Using TLS with IMAP, POP3 and ACAP". Specifies an extension to the IMAP, POP3 and ACAP services that allow the server and client to use transport-layer security to provide private, authenticated communication over the Internet.
  • RFC 2712: "Addition of Kerberos Cipher Suites to Transport Layer Security (TLS)". The 40-bit cipher suites defined in this memo appear only for the purpose of documenting the fact that those cipher suite codes have already been assigned.
  • RFC 2817: "Upgrading to TLS Within HTTP/1.1", explains how to use the Upgrade mechanism in HTTP/1.1 to initiate Transport Layer Security (TLS) over an existing T***** connection. This allows unsecured and secured HTTP traffic to share the same well known port (in this case, http: at 80 rather than https: at 443).
  • RFC 2818: "HTTP Over TLS", distinguishes secured traffic from insecure traffic by the use of a different 'server port'.
  • RFC 3207: "SMTP Service Extension for Secure SMTP over Transport Layer Security". Specifies an extension to the SMTP service that allows an SMTP server and client to use transport-layer security to provide private, authenticated communication over the Internet.
  • RFC 3268: "AES Ciphersuites for TLS". Adds Advanced Encryption Standard (AES) cipher suites to the previously existing symmetric ciphers.
  • RFC 3546: "Transport Layer Security (TLS) Extensions", adds a mechanism for negotiating protocol extensions during session initialisation and defines some extensions. Made obsolete by RFC 4366.
  • RFC 3749: "Transport Layer Security Protocol Compression Methods", specifies the framework for compression methods and the DEFLATE compression method.
  • RFC 3943: "Transport Layer Security (TLS) Protocol Compression Using Lempel-Ziv-Stac (LZS)".
  • RFC 4132: "Addition of Camellia Cipher Suites to Transport Layer Security (TLS)".
  • RFC 4162: "Addition of SEED Cipher Suites to Transport Layer Security (TLS)".
  • RFC 4217: "Securing FTP with TLS".
  • RFC 4279: "Pre-Shared Key Ciphersuites for Transport Layer Security (TLS)", adds three sets of new cipher suites for the TLS protocol to support authentication based on pre-shared keys.

Extensions to TLS 1.1 include:

  • RFC 4347: "Datagram Transport Layer Security" specifies a TLS variant that works over datagram protocols (such as UDP).
  • RFC 4366: "Transport Layer Security (TLS) Extensions" describes both a set of specific extensions and a generic extension mechanism.
  • RFC 4492: "Elliptic Curve Cryptography (ECC) Cipher Suites for Transport Layer Security (TLS)".
  • RFC 4680: "TLS Handshake Message for Supplemental Data".
  • RFC 4681: "TLS User Mapping Extension".
  • RFC 4785: "Pre-Shared Key (PSK) Ciphersuites with NULL Encryption for Transport Layer Security (TLS)".
  • RFC 5054: "Using the Secure Remote Password (SRP) Protocol for TLS Authentication". Defines the TLS-SRP ciphersuites.
  • RFC 5077: "Transport Layer Security (TLS) Session Resumption without Server-Side State".
  • RFC 5081: "Using OpenPGP Keys for Transport Layer Security (TLS) Authentication", obsoleted by RFC 6091.

Extensions to TLS 1.2 include:

  • RFC 5288: "AES Galois Counter Mode (GCM) Cipher Suites for TLS".
  • RFC 5289: "TLS Elliptic Curve Cipher Suites with SHA-256/384 and AES Galois Counter Mode (GCM)".
  • RFC 5746: "Transport Layer Security (TLS) Renegotiation Indication Extension".
  • RFC 5878: "Transport Layer Security (TLS) Authorization Extensions".
  • RFC 5932: "Camellia Cipher Suites for TLS"
  • RFC 6066: "Transport Layer Security (TLS) Extensions: Extension Definitions", includes Server Name Indication and OCSP stapling.
  • RFC 6091: "Using OpenPGP Keys for Transport Layer Security (TLS) Authentication".
  • RFC 6176: "Prohibiting Secure Sockets Layer (SSL) Version 2.0".
  • RFC 6209: "Addition of the ARIA Cipher Suites to Transport Layer Security (TLS)".
  • RFC 6347: "Datagram Transport Layer Security Version 1.2".
  • RFC 6367: "Addition of the Camellia Cipher Suites to Transport Layer Security (TLS)"
  • RFC 6460: "Suite B Profile for Transport Layer Security (TLS)".
  • RFC 6655: "AES-CCM Cipher Suites for Transport Layer Security (TLS)"
  • RFC 7027: "Elliptic Curve Cryptography (ECC) Brainpool Curves for Transport Layer Security (TLS)".

Encapsulations of TLS include:

  • RFC 5216: "The EAP-TLS Authentication Protocol"

See also

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References

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Further reading

External links

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