Secure Hypertext Transfer Protocol


Secure Hypertext Transfer Protocol is an obsolete alternative to the HTTPS protocol for encrypting web communications carried over HTTP. It was developed by Eric Rescorla and Allan M. Schiffman, and published in 1999 as RFC 2660.
Web browsers typically use HTTP to communicate with web servers, sending and receiving information without encrypting it. For sensitive transactions, such as Internet e-commerce or online access to financial accounts, the browser and server must encrypt this information.
HTTPS and S-HTTP were both defined in the mid-1990s to address this need. S-HTTP was used by Spyglass's web server, while Netscape and Microsoft supported HTTPS rather than S-HTTP, leading to HTTPS becoming the de facto standard mechanism for securing web communications.

Comparison to HTTP over TLS

S-HTTP encrypts only the served page data and submitted data like POST fields, leaving the initiation of the protocol unchanged. Because of this, S-HTTP could be used concurrently with HTTP on the same port, as the unencrypted header would determine whether the rest of the transmission is encrypted.
In contrast, HTTP over TLS wraps the entire communication within Transport Layer Security, so the encryption starts before any protocol data is sent. This creates a name-based virtual hosting "chicken and egg" issue with determining which DNS name was intended for the request.
This means that HTTPS implementations without Server Name Indication support require a separate IP per DNS name, and all HTTPS implementations require a separate port for unambiguous use of encryption.
As documented in RFC 2817, HTTP can also be secured by implementing HTTP/1.1 Upgrade headers and upgrading to TLS. Running HTTP over TLS negotiated in this way, does not have the implications of HTTPS with regards to name-based virtual hosting, however, few implementations support this method.
In S-HTTP, the desired URL is not transmitted in the cleartext headers, but left blank; another set of headers is present inside the encrypted payload. In HTTP over TLS, all headers are inside the encrypted payload, and the server application does not generally have the opportunity to gracefully recover from TLS fatal errors.