The secure variant of http created for the necessity of encryption on the modern web. Currently this page is pretty much just a guide on how to create certificates for web hosting.

Does not have a central authority to confirm the certificate as valid, but it does encrypt the connection, good for local networks and stuff on the web, but is not recommended nor ideal for security. It is assumed that you have the necessary packages installed prior to running these commands.

We can create a self-signed key and certificate pair with OpenSSL in a single command:

sudo openssl req -x509 -nodes -days 365 -newkey rsa:2048 -keyout /etc/ssl/private/THEKEY-selfsigned.key -out /etc/ssl/certs/THECERT-selfsigned.crt

You will be asked a series of questions. Before we go over that, let's take a look at what is happening in the command we are issuing:

• openssl: This is the basic command line tool for creating and managing OpenSSL certificates, keys, and other files.

• req: This subcommand specifies that we want to use X.509 certificate signing request (CSR) management. The “X.509” is a public key infrastructure standard that SSL and TLS adheres to for its key and certificate management. We want to create a new X.509 cert, so we are using this subcommand.

• x509: This further modifies the previous subcommand by telling the utility that we want to make a self-signed certificate instead of generating a certificate signing request, as would normally happen.

• nodes: This tells OpenSSL to skip the option to secure our certificate with a passphrase. We need Apache to be able to read the file, without user intervention, when the server starts up. A passphrase would prevent this from happening because we would have to enter it after every restart.

• days 365: This option sets the length of time that the certificate will be considered valid. We set it for one year here.

• newkey rsa:2048: This specifies that we want to generate a new certificate and a new key at the same time. We did not create the key that is required to sign the certificate in a previous step, so we need to create it along with the certificate. The rsa:2048 portion tells it to make an RSA key that is 2048 bits long.

• keyout: This line tells OpenSSL where to place the generated private key file that we are creating.

• out: This tells OpenSSL where to place the certificate that we are creating.

As we stated above, these options will create both a key file and a certificate. We will be asked a few questions about our server in order to embed the information correctly in the certificate.

Fill out the prompts appropriately. The most important line is the one that requests the Common Name (e.g. server FQDN or YOUR name). You need to enter the domain name associated with your server or, more likely, your server's public IP address.

The entirety of the prompts will look something like this:

Output

Country Name (2 letter code) [AU]:US
State or Province Name (full name) [Some-State]:New York
Locality Name (eg, city) []:New York City
Organization Name (eg, company) [Internet Widgits Pty Ltd]:Bouncy Castles, Inc.
Organizational Unit Name (eg, section) []:Ministry of Water Slides
Common Name (e.g. server FQDN or YOUR name) []:server_IP_address
Email Address []:admin@your_domain.com

Both of the files you created will be placed in the appropriate subdirectories of the /etc/ssl directory.

While we are using OpenSSL, we should also create a strong Diffie-Hellman group, which is used in negotiating Perfect Forward Secrecy with clients.

We can do this by typing:

sudo openssl dhparam -out /etc/ssl/certs/dhparam.pem 2048

This may take a few minutes, but when it's done you will have a strong DH group at /etc/ssl/certs/dhparam.pem that we can use in our configuration.