Usage

Gimmecert provides a simple and clean CLI interface for all actions.

Description of all available commands, manadatory arguments, and optional arguments is also made available via CLI by either using the help flag (-h / --help) or help command.

Running the tool without any command or argument will output short usage instructions listing available commands.

To get more detailed general help on tool usage, and list of available commands with short description on what they do, run one of the following:

gimmecert -h
gimmecert --help
gimmecert help

To get more details on specific command, along what mandatory and positional arguments are available, simply provide the help flag when running them. For example:

gimmecert init -h
gimmecert init --help

Quickstart

Gimmecert stores all of its artefacts within the .gimmecert sub-directory (relative to where the command is run).

Start off by switching to your project directory:

cd ~/myproject/

Initialise the necessary directories and CA hierarchy:

gimmecert init

This will create a single CA, providing the following artifacts:

  • .gimmecert/ca/level1.key.pem (private key)
  • .gimmecert/ca/level1.cert.pem (certificate)
  • .gimmecert/ca/chain-full.cert.pem (full CA chain, in this case same as level1.cert.pem)

Issue a server certificate:

gimmecert server myserver1

This will create the following artifacts for the server:

  • .gimmecert/server/myserver1.key.pem (private key)
  • .gimmecert/server/myserver1.cert.pem (certificate)

Resulting certificate will include its own name as one of the DNS subject alternative names.

Issue a client certificate:

gimmecert client myclient1

This will create the following artifacts for the client:

  • .gimmecert/client/myclient1.key.pem (private key)
  • .gimmecert/client/myclient1.cert.pem (certificate)

Issue a server certificate with additional DNS subject alternative names:

gimmecert server myserver2 myserver2.local service.example.com

This will create the following artifacts for the server:

  • .gimmecert/server/myserver2.key.pem (private key)
  • .gimmecert/server/myserver2.cert.pem (certificate)

This time around, the myserver2 certificate will include myserver2, myserver2.local, and service.example.com as DNS subject alternative names.

Issue a server certificate by passing-in certificate signing request (CSR) from which the public key should be extracted:

openssl req -new -newkey rsa:2048 -nodes -keyout "/tmp/myserver3.key.pem" -subj "/CN=ignoredname" -out "/tmp/myserver3.csr.pem"
gimmecert server --csr /tmp/myserver3.csr.pem myserver3

This will create the following artifacts for the server:

  • .gimmecert/server/myserver3.csr.pem (CSR)
  • .gimmecert/server/myserver3.cert.pem (certificate)

Renew existing certificates, keeping the same private key and naming:

gimmecert renew server myserver1
gimmecert renew server myclient1

Show information about CA hierarchy and issued certificates:

gimmecert status

Initialisation

Initialisation has to be run one before being being able to issue server and client certificates. This is done with:

gimmecert init

Initialisation will:

  • Set-up a local directory.
  • Initialise the CA hierarchy used for issuing server and client certificates. This includes creation of CA private keys (RSA 2048), as well as issuance of corresponding certificates.

If you attempt to run initialisation from the same directory twice, Gimmecert will refuse to do so. Should you need to recreate the hierarchy, simply remove the .gimmcert/ directory, and start over. Keep in mind you will need to throw away all of generated key material and certificates.

The following directories are created as part of initialisation process:

  • .gimmecert/, base directory.
  • .gimmecert/ca/, used for storing CA private keys and certificates.
  • .gimmecert/server/, used for storing server private keys and certificates.
  • .gimmecert/client/, used for storing client private keys and certificates.

Both CA private keys and certificates are stored as OpenSSL-style PEM files. The naming convention for keys is levelN.key.pem, while for certificates it is levelN.cert.pem. N corresponds to CA level. Level 1 is the root/self-signed CA, level 2 is CA signed by level 1 CA and so forth.

In addition to individual CA certificates, Gimmecert will also store the full certificate chain (including the level 1 CA certificate) in file chain-full.cert.pem.

Subject DN naming convention for all CAs is CN=BASENAME Level N CA. N is the CA level, while BASENAME is by default equal to current (working) directory name.

By defualt the tool will initialise a one-level CA hierarchy (i.e. just the root CA).

Both the base name and CA hierarchy depth can be easily overridden by providing options (both long and short forms are available):

gimmecert init --ca-base-name "My Project" --ca-hierarchy-depth 3
gimmecert init -b "My Project" -d 3

The above examples would both result in creation of the following CA artifacts:

  • .gimmecert/ca/level1.key.pem
  • .gimmecert/ca/level1.cert.pem (subject DN My Project Level 1 CA)
  • .gimmecert/ca/level2.key.pem
  • .gimmecert/ca/level2.cert.pem (subject DN My Project Level 2 CA)
  • .gimmecert/ca/level3.key.pem
  • .gimmecert/ca/level3.cert.pem (subject DN My Project Level 3 CA)
  • .gimmecert/ca/chain-full.cert.pem

Issuing server certificates

Server certificates can be issued once the initialisation is complete. Command supports passing-in additional DNS subject alternative names as additional positional arguments:

gimmecert server NAME [DNS_NAME [DNS_NAME ...]]

The command will:

  • Generate a 2048-bit RSA private key.
  • Issue a certificate associated with the generated private key using the leaf CA (the one deepest in hierachy).

Resulting private keys and certificates are stored within directory .gimmecert/server/. Private key naming convention is NAME.key.pem, while certificates are stored as NAME.cert.pem. In both cases the OpenSSL-style PEM format is used for storage.

Subject DN naming convention for server certificates is CN=NAME, where NAME is passed-in via positional argument.

By default the certificate will include the passed-in server name as one of its DNS subject alternative names, but additional DNS names can be passed-in as well. For example:

gimmecert server myserver myserver.local service.example.com

Key usage and extended key usage in certificate are set typical TLS server use (e.g. digital signature + key encipherment for KU, and TLS WWW server authentication for EKU).

Rerunning the command will not overwrite existing data.

Note

For changing the list of additional subject alternative names included in already issued server certificates, see the --update-dns-names option in the gimmecert renew command.

In addition to generating a private key, it is also possible to pass-in a certificate signing request (CSR). If specified path is a dash (-), CSR is read from standard input. The resulting certificate will contain public key from the CSR. All other information stored in the CSR (naming, extensions) is ignored. For example:

# Issue server certificate by passing-in path to a generated CSR.
gimmecert server --csr /tmp/myown.csr.pem myserver

# Issue server certificate by reading the CSR from standard input.
gimmecert server --csr - myserver

# Issue server certificate by reading the CSR from standard input,
# using redirection.
gimmecert server --csr - myserver < /tmp/myown.csr.pem

The passed-in CSR will be stored alongside certificate, under .gimmecert/server/NAME.csr.pem.

Issuing client certificates

Client certificates can be issued once the initialisation is complete. Command accepts a single positional argument:

gimmecert client NAME

The command will:

  • Generate a 2048-bit RSA private key.
  • Issue a certificate associated with the generated private key using the leaf CA (the one deepest in hierachy).

Rerunning the command will not overwrite existing data.

Resulting private keys and certificates are stored within directory .gimmecert/client/. Private key naming convention is NAME.key.pem, while certificates are stored as NAME.cert.pem. In both cases the OpenSSL-style PEM format is used for storage.

Subject DN naming convention for client certificates is CN=NAME, where NAME is passed-in via positional argument.

Key usage and extended key usage in certificate are set typical TLS client use (e.g. digital signature + key encipherment for KU, and TLS WWW client authentication for EKU).

In addition to generating a private key, it is also possible to pass-in a certificate signing request (CSR). If specified path is a dash (-), CSR is read from standard input. The resulting certificate will contain public key from the CSR. All other information stored in the CSR (naming, extensions) is ignored. For example:

# Issue client certificate by passing-in path to a generated CSR.
gimmecert client --csr /tmp/myown.csr.pem myclient

# Issue client certificate by reading the CSR from standard input.
gimmecert client --csr - myclient

# Issue client certificate by reading the CSR from standard input,
# using redirection.
gimmecert client --csr - myclient < /tmp/myown.csr.pem

The passed-in CSR will be stored alongside certificate, under .gimmecert/client/NAME.csr.pem.

Renewing certificates

Both client and server certificates can be renewed by simply providing the type and name. This is useful when a certificate has expired, and it should be renewed with identical naming and private key. Command requires two positional argumensts:

gimmecert renew (server|client) NAME

The command will:

  • By default keep the existing private key generated for end entity (new one can be requested as well).
  • Re-use naming and any extensions stored in existing certificate.
  • Overwrite the existing certificate with a new one.
  • Show information where the artifacts can be grabbed from.

To also generate a new private key during renewal, use the --new-private-key or -p option. For example:

gimmecert renew --new-private-key server myserver
gimmecert renew -p server my server

To replace the existing private key or CSR during renewal with a new CSR, use the --csr option and pass along path to the file. If specified path is a dash (-), CSR is read from standard input. For example:

gimmecert renew --csr /tmp/myserver.csr.pem server myserver
gimmecert renew --csr - server myserver < /tmp/myserver.csr.pem
gimmecert renew --csr - client myclient

If you initially made a mistake when providing additional DNS subject alternative names for a server certificate, you can easily fix this with the --update-dns-names or -u option:

# Replace existing additional names with just one name.
gimmecert renew server --update-dns-names "correctname.example.com" myserver

# Replace existing additional names with mutliple names.
gimmecert renew server --update-dns-names "correctname1.example.com,correctname2.example.com" myserver

# Remove additional names altogether.
gimmecert renew server --update-dns-names "" myserver

Getting information about CA hierarchy and issued certificates

In order to show information about the CA hierarchy and issued certificates simply run the status command:

gimmecert status

The command will:

  • Show default key algorithm used by the CA hierarchy.
  • Show information about every CA in generated hierarchy (subject DN, validity, certificate paths, whether the CA is used for issuing end entity certificates).
  • Show information about all issued server certificates (subject DN, DNS subject alternative names, key algorithm, validity, private key or CSR path, certificate path).
  • Show information about all issued client certificates (subject DN, validity, key algorithm, private key or CSR path, certificate path).

Validity of all certificates is shown in UTC.

Command can also be used for checking if Gimmecert has been initialised in local directory or not.

Key algorithm

Gimmecert by default generates 2048-bit RSA private keys for the entire CA hierarchy.

The key algorithm and parameters can also be explicitly specified for every command that generates private keys: init, server, client, and renew. This can be done using either the long form (--key-specification) or short form (-k) option, followed by the formatted key specification that designates the key algorithm and its associated generation parameters.

To request an RSA key, use the format rsa:KEY_SIZE. For ECDSA, the format is ecdsa:CURVE_NAME. Minimal size for RSA keys is 512, while for ECDSA you can pick between one of the following elliptic curves:

  • secp192r1
  • secp224r1
  • secp256k1
  • secp256r1
  • secp384r1
  • secp521r1

Key specification picked for the CA hierarchy is also by default used when generating private keys for end entities when no explicit key specification is provided. The sole exception to this rule is key generation during renewal. During renewals, if a new private key is requested, the current key algorithm and generation parameters of an entity are preserved.

The --key-specification option is mutually exclusive with the --csr option. In case of the renew command it can only be used together with the --new-private-key option.

Here are some examples on key specification usage:

# Initialise CA hierarchy using 3072-bit RSA keys.
gimmecert init --key-specification rsa:3072

# Issue a server certificate using the default key specification of
# the CA hierarchy.
gimmecert server myserver

# Issue a client certificate using ECDSA key specification.
gimmecert client -k ecdsa:secp521r1 myclient

# Renew a server certificate while requesting a new, 1024-bit RSA,
# private key.
gimmecert renew myserver --new-private-key -k rsa:1024