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.Dd $Mdocdate: February 12 2021 $
.Dt SSL 8
.Os
.Sh NAME
.Nm ssl
.Nd details for libssl and libcrypto
.Sh DESCRIPTION
This document describes some of the issues relating to the use of
the OpenSSL libssl and libcrypto libraries.
This document is intended as an overview of what the libraries do,
and what uses them.
.Pp
The libssl and libcrypto libraries implement the TLS version 1 protocol.
It is most commonly used by the HTTPS protocol for encrypted
web transactions, as can be done with
.Xr httpd 8 .
The libcrypto library is also used by various programs such as
.Xr ssh 1 ,
.Xr sshd 8 ,
and
.Xr isakmpd 8 .
.Sh SERVER CERTIFICATES
The most common uses of TLS will require you to generate a server
certificate, which is provided by your host as evidence of its identity
when clients make new connections.
The certificates reside in the
.Pa /etc/ssl
directory, with the keys in the
.Pa /etc/ssl/private
directory.
.Pp
Private keys can be encrypted using AES and a passphrase to protect their
integrity should the encrypted file be disclosed.
However, it is important to note that encrypted server keys mean that the
passphrase needs to be typed in every time the server is started.
If a passphrase is not used, you will need to be absolutely sure your
key file is kept secure.
.Sh GENERATING RSA SERVER CERTIFICATES FOR WEB SERVERS
To support HTTPS transactions in
.Xr httpd 8
you will need to generate an RSA certificate.
Start by creating a private key of the desired length:
.Bd -literal -offset indent
# openssl genrsa -out /etc/ssl/private/server.key 4096
.Ed
.Pp
Or, if you wish the key to be encrypted with a passphrase that you will
have to type in when starting servers
.Bd -literal -offset indent
# openssl genrsa -aes256 -out /etc/ssl/private/server.key 4096
.Ed
.Pp
If you are only generating a private key to use with
.Xr acme-client 1
(for example, with a non-default key length)
you may stop here.
.Pp
Otherwise, the next step is to generate a Certificate Signing Request (CSR)
which is used to get a Certificate Authority (CA) to sign your certificate.
To do this use the command:
.Bd -literal -offset indent
# openssl req -new -key /etc/ssl/private/server.key \e
  -out /etc/ssl/private/server.csr
.Ed
.Pp
This
.Pa server.csr
file can then be given to a Certificate Authority who will sign the key.
.Pp
You can also sign the key yourself, using the command:
.Bd -literal -offset indent
# openssl x509 -sha256 -req -days 365 \e
  -in /etc/ssl/private/server.csr \e
  -signkey /etc/ssl/private/server.key \e
  -out /etc/ssl/server.crt
.Ed
.Pp
Note that standard web browsers do not use the common name of a subject,
but instead require that subject alt names are provided.
This requires the use of
.Ar -extfile Pa server.ext
when self-signing.
.Bd -literal -offset indent
# this is an example server.ext file
subjectAltName=DNS:example.com,DNS:www.example.com
.Ed
.Pp
With
.Pa /etc/ssl/server.crt
and
.Pa /etc/ssl/private/server.key
in place, you should be able to start
.Xr httpd 8
with SSL configured, enabling HTTPS transactions with your machine on port 443.
.Pp
You will most likely want to generate a self-signed certificate in the
manner above along with your certificate signing request to test your
server's functionality even if you are going to have the certificate
signed by another Certificate Authority.
Once your Certificate Authority returns the signed certificate to you,
you can switch to using the new certificate by replacing the self-signed
.Pa /etc/ssl/server.crt
with the certificate signed by your Certificate Authority, and then
restarting
.Xr httpd 8 .
.Sh GENERATING ECDSA SERVER CERTIFICATES
First, generate a private ECDSA key.
The following command will use a NIST/SECG curve over a 384-bit
prime field:
.Bd -literal -offset indent
# openssl ecparam -name secp384r1 -genkey \e
  -noout -out /etc/ssl/private/eccert.key
.Ed
.Pp
Note that some Certificate Authorities will only issue certificates for
keys generated using prime256v1 parameters.
.Pp
If you are only generating a private key to use with
.Xr acme-client 1 ,
you may stop here.
Otherwise, the next step is to generate a Certificate Signing Request (CSR)
which is used to get a Certificate Authority (CA) to sign your certificate.
To do this use the command:
.Bd -literal -offset indent
# openssl req -key /etc/ssl/private/eccert.key -new \e
  -out /etc/ssl/private/eccert.csr
.Ed
.Pp
This
.Pa eccert.csr
file can then be given to a CA who will sign the key.
.Pp
You can also sign the key yourself, using the command:
.Bd -literal -offset indent
# openssl x509 -sha256 -req -days 365 \e
  -in /etc/ssl/private/eccert.csr \e
  -signkey /etc/ssl/private/eccert.key \e
  -out /etc/ssl/eccert.crt
.Ed
.Sh SEE ALSO
.Xr acme-client 1 ,
.Xr openssl 1 ,
.Xr ssh 1 ,
.Xr ssl 3 ,
.Xr httpd 8 ,
.Xr isakmpd 8 ,
.Xr rc 8 ,
.Xr smtpd 8 ,
.Xr sshd 8 ,
.Xr starttls 8
.Sh HISTORY
Prior to Sept 21, 2000,
there were problems shipping fully functional implementations of these
protocols, as such shipment would include shipping
.Em into
the United States.
RSA Data Security Inc (RSADSI) held the patent on the RSA algorithm in the
United States, and because of this, free implementations of RSA were
difficult to distribute and propagate.
(The RSA patent was probably more effective at preventing the adoption of
widespread international integrated crypto than the much maligned ITAR
restrictions were.)
Prior to
.Ox 2.8 ,
these libraries shipped without the RSA algorithm -- all such functions
were stubbed to fail.
Since RSA is a key component of SSL version 2, this meant that SSL version
2 would not work at all.
SSL version 3 and TLS version 1 allow for the exchange of keys via
mechanisms that do not involve RSA, and would work with the shipped version
of the libraries, assuming both ends could agree to a cipher suite and key
exchange that did not involve RSA.
Likewise, the SSH1 protocol in
.Xr ssh 1
uses RSA, so it was similarly encumbered.
.Pp
For instance, another typical alternative is DSA, which is not encumbered
by commercial patents (and lawyers).
.Pp
The HTTPS protocol used by web browsers (in modern incarnations) allows for
the use of SSL version 3 and TLS version 1, which in theory allows for
encrypted web transactions without using RSA.
Unfortunately, all the popular web browsers buy their cryptographic code
from RSADSI.
Predictably, RSADSI would prefer that web browsers used their patented
algorithm, and thus their libraries do not implement any non-RSA cipher and
keying combination.
The result of this was that while the HTTPS protocol allowed for many
cipher suites that did not require the use of patented algorithms, it was
very difficult to use these with the popular commercially available
software.
Prior to version 2.8,
.Ox
allowed users to download RSA enabled versions of the shared libssl and
libcrypto libraries which allowed users to enable full functionality without
recompiling the applications.
This method is now no longer needed, as the fully functional
libraries ship with the system.
However, this entire debacle is worth remembering when choosing
software and vendors.
.Pp
Due to multiple flaws in the protocols, SSL version 2 was removed in
.Ox 5.2
and SSL version 3 was disabled in
.Ox 5.7 .
Users and programs should use TLS version 1.2 instead.
.Pp
This document first appeared in
.Ox 2.5 .