Sign commits and tags with X.509 certificates
X.509 is a standard format for public key certificates issued by a public or private Public Key Infrastructure (PKI). Personal X.509 certificates are used for authentication or signing purposes such as S/MIME (Secure/Multipurpose Internet Mail Extensions). However, Git also supports signing of commits and tags with X.509 certificates in a similar way as with GPG (GnuPG, or GNU Privacy Guard). The main difference is the way GitLab determines whether or not the developer’s signature is trusted:
- For X.509, a root certificate authority is added to the GitLab trust store. (A trust store is a repository of trusted security certificates.) Combined with any required intermediate certificates in the signature, the developer’s certificate can be chained back to a trusted root certificate.
- For GPG, developers add their GPG key to their account.
GitLab uses its own certificate store and therefore defines the trust chain. For a commit or tag to be verified by GitLab:
- The signing certificate email must match a verified email address in GitLab.
- The GitLab instance must be able to establish a full trust chain from the certificate in the signature to a trusted certificate in the GitLab certificate store. This chain may include intermediate certificates supplied in the signature. You may need to add certificates, such as Certificate Authority root certificates, to the GitLab certificate store.
- The signing time must be in the time range of the certificate validity, which is usually up to three years.
- The signing time is equal to, or later than, the commit time.
If a commit’s status has already been determined and stored in the database, use the Rake task to re-check the status. Refer to the Troubleshooting section. GitLab checks certificate revocation lists on a daily basis with a background worker.
Limitations
- Certificates without
authorityKeyIdentifier
,subjectKeyIdentifier
, andcrlDistributionPoints
display as Unverified. We recommend using certificates from a PKI that are in line with RFC 5280. -
Setting values in the Extended Key Usage (EKU) section of your certificate in addition to the required Key Usage (KU) of
Digital Signature
is likely to cause your commits to display as Unverified. To resolve this, addemailProtection
to your EKU list. RFC 5280 specifies this limitation.To diagnose it, follow S/MIME verification with OpenSSL. If this change doesn’t resolve the issue, please provide feedback in issue 440189.
- In GitLab 16.2 and earlier, if you have more than one email in the Subject Alternative Name list in your signing certificate, only the first one is used to verify commits.
- In GitLab 15.1 and earlier, the
X509v3 Subject Key Identifier
(SKI) in the issuer certificate and the signing certificate must be 40 characters long. If your SKI is shorter, commits don’t show as verified in GitLab, and short subject key identifiers may also cause errors when accessing the project, such as ‘An error occurred while loading commit signatures’ andHTTP 422 Unprocessable Entity
errors.
Configure for signed commits
To sign your commits, tags, or both, you must:
- Obtain an X.509 key pair.
- Associate your X.509 certificate with Git.
- Sign and verify commits.
- Sign and verify tags.
Obtain an X.509 key pair
If your organization has Public Key Infrastructure (PKI), that PKI provides an S/MIME key. If you do not have an S/MIME key pair from a PKI, you can either create your own self-signed pair, or purchase a pair.
Associate your X.509 certificate with Git
To take advantage of X.509 signing, you need Git 2.19.0 or later. You can
check your Git version with the command git --version
.
If you have the correct version, you can proceed to configure Git.
Linux
Configure Git to use your key for signing:
signingkey=$( gpgsm --list-secret-keys | egrep '(key usage|ID)' | grep -B 1 digitalSignature | awk '/ID/ {print $2}' )
git config --global user.signingkey $signingkey
git config --global gpg.format x509
Windows and macOS
To configure Windows or macOS:
- Install S/MIME Sign by either:
- Downloading the installer.
- Running
brew install smimesign
on macOS.
- Get the ID of your certificate by running
smimesign --list-keys
. - Set your signing key by running
git config --global user.signingkey <ID>
, replacing<ID>
with the certificate ID. -
Configure X.509 with this command:
git config --global gpg.x509.program smimesign git config --global gpg.format x509
Sign and verify commits
After you have associated your X.509 certificate with Git you can sign your commits:
-
When you create a Git commit, add the
-S
flag:git commit -S -m "feat: x509 signed commits"
-
Push to GitLab, and check that your commits are verified with the
--show-signature
flag:git log --show-signature
-
If you don’t want to type the
-S
flag every time you commit, run this command for Git to sign your commits every time:git config --global commit.gpgsign true
Sign and verify tags
After you have associated your X.509 certificate with Git you can start signing your tags:
-
When you create a Git tag, add the
-s
flag:git tag -s v1.1.1 -m "My signed tag"
-
Push to GitLab and verify your tags are signed with this command:
git tag --verify v1.1.1
-
If you don’t want to type the
-s
flag every time you tag, run this command for Git to sign your tags each time:git config --global tag.gpgsign true
Related topics
Troubleshooting
For committers without administrator access, review the list of verification problems with signed commits for possible fixes. The other troubleshooting suggestions on this page require administrator access.
Re-verify commits
GitLab stores the status of any checked commits in the database. You can use a Rake task to check the status of any previously checked commits.
After you make any changes, run this command:
sudo gitlab-rake gitlab:x509:update_signatures
Main verification checks
The code performs
these key checks,
which all must return verified
:
-
x509_certificate.nil?
should be false. -
x509_certificate.revoked?
should be false. -
verified_signature
should be true. -
user.nil?
should be false. -
user.verified_emails.include?(@email)
should be true. -
certificate_email == @email
should be true.
To investigate why a commit shows as Unverified
:
-
sudo gitlab-rails console
-
Identify the project (either by path or ID) and full commit SHA that you’re investigating. Use this information to create
signature
to run other checks against:project = Project.find_by_full_path('group/subgroup/project') project = Project.find_by_id('121') commit = project.repository.commit_by(oid: '87fdbd0f9382781442053b0b76da729344e37653') signedcommit=Gitlab::X509::Commit.new(commit) signature=Gitlab::X509::Signature.new(signedcommit.signature_text, signedcommit.signed_text, commit.committer_email, commit.created_at)
If you make changes to address issues identified running through the checks, restart the Rails console and run though the checks again from the start.
-
Check the certificate on the commit:
signature.x509_certificate.nil? signature.x509_certificate.revoked?
Both checks should return
false
:> signature.x509_certificate.nil? => false > signature.x509_certificate.revoked? => false
A known issue causes these checks to fail with
Validation failed: Subject key identifier is invalid
. -
Run a cryptographic check on the signature. The code must return
true
:signature.verified_signature
If it returns
false
then investigate this check further. -
Confirm the email addresses match on the commit and the signature:
- The Rails console displays the email addresses being compared.
- The final command must return
true
:
sigemail=signature.__send__:certificate_email commitemail=commit.committer_email sigemail == commitemail
In GitLab 16.2 and earlier, only the first email in the
Subject Alternative Name
list is compared. To display theSubject Alternative Name
list, run:signature.__send__ :get_certificate_extension,'subjectAltName'
If the developer’s email address is not the first one in the list, this check fails, and the commit is marked
unverified
. -
The email address on the commit must be associated with an account in GitLab. This check should return
false
:signature.user.nil?
-
Check the email address is associated with a user in GitLab. This check should return a user, such as
#<User id:1234 @user_handle>
:User.find_by_any_email(commit.committer_email)
If it returns
nil
, the email address is not associated with a user, and the check fails. -
Confirm the developer’s email address is verified. This check must return true:
signature.user.verified_emails.include?(commit.committer_email)
If the previous check returned
nil
, this command displays an error:NoMethodError (undefined method `verified_emails' for nil:NilClass)
-
The verification status is stored in the database. To display the database record:
pp CommitSignatures::X509CommitSignature.by_commit_sha(commit.sha);nil
If all the previous checks returned the correct values:
-
verification_status: "unverified"
indicates the database record needs updating. Use the Rake task. -
[]
indicates the database doesn’t have a record yet. Locate the commit in GitLab to check the signature and store the result.
-
Cryptographic verification checks
If GitLab determines that verified_signature
is false
, investigate the reason
in the Rails console. These checks require signature
to exist. Refer to the signature
step of the previous main verification checks.
-
Check the signature, without checking the issuer, returns
true
:signature.__send__ :valid_signature?
-
Check the signing time and date. This check must return
true
:signature.__send__ :valid_signing_time?
- The code allows for code signing certificates to expire.
-
A commit must be signed during the validity period of the certificate, and at or after the commit’s datestamp. Display the commit time and certificate details including
not_before
,not_after
with:commit.created_at pp signature.__send__ :cert; nil
-
Check the signature, including that TLS trust can be established. This check must return
true
:signature.__send__(:p7).verify([], signature.__send__(:cert_store), signature.__send__(:signed_text))
-
If this fails, add the missing certificates required to establish trust to the GitLab certificate store.
-
After adding more certificates, (if these troubleshooting steps then pass) run the Rake task to re-verify commits.
-
You can add additional certificates dynamically in the Rails console to check if this resolves the problem.
-
Retest the signature with a trust store
cert_store
that can be modified. It should still fail, withfalse
:cert_store = signature.__send__ :cert_store signature.__send__(:p7).verify([], cert_store, signature.__send__(:signed_text))
-
Add an additional certificate, and re-test:
cert_store.add_file("/etc/ssl/certs/my_new_root_ca.pem") signature.__send__(:p7).verify([], cert_store, signature.__send__(:signed_text))
-
-
Display the certificates that are included in the signature:
pp signature.__send__(:p7).certificates ; nil
-
Further investigation can be performed with OpenSSL on the command line.
-
Ensure any additional intermediate certificates and the root certificate are added to the certificate store. For consistency with how certificate chains are built on web servers:
- Git clients that are signing commits should include the certificate and all intermediate certificates in the signature.
- The GitLab certificate store should only contain the root.
If you remove a root certificate from the GitLab
trust store, such as when it expires, commit signatures which chain back to that
root display as unverified
.
S/MIME verification with OpenSSL
If there are issues with the signature, or if TLS trust fails, further debugging can be performed with OpenSSL on the command line.
Export the signature and the signed text, from the Rails console:
-
The initial two steps from the main verification checks are required so
signature
has been set. -
OpenSSL requires that PKCS7 PEM formatted data is bounded with
BEGIN PKCS7
andEND PKCS7
so this usually needs to be fixed:pkcs7_text = signature.signature_text.sub('-----BEGIN SIGNED MESSAGE-----', '-----BEGIN PKCS7-----') pkcs7_text = pkcs7_text.sub('-----END SIGNED MESSAGE-----', '-----END PKCS7-----')
-
Write out the signature and signed text:
f1=File.new('/tmp/signature_text.pk7.pem','w') f1 << pkcs7_text f1.close f2=File.new('/tmp/signed_text.txt','w') f2 << signature.signed_text f2.close
This data can now be investigated on the Linux command line using OpenSSL:
-
The PKCS #7 file containing the signature can be queried:
/opt/gitlab/embedded/bin/openssl pkcs7 -inform pem -print_certs \ -in /tmp/signature_text.pk7.pem -print -noout
It should include at least one
cert
section in the output; the signer’s certificate.There’s a lot of low level of detail in the output. Here’s an example of some of the structure and headings that should be present:
PKCS7: d.sign: cert: cert_info: issuer: validity: notBefore: notAfter: subject:
If developers’ code signing certificates are issued by an intermediate certificate authority, there should be additional certificate details:
PKCS7: d.sign: cert: cert_info: cert: cert_info:
-
Extract the certificate from the signature:
/opt/gitlab/embedded/bin/openssl pkcs7 -inform pem -print_certs \ -in /tmp/signature_text.pk7.pem -out /tmp/signature_cert.pem
If this step fails, the signature might be missing the signer’s certificate.
- Fix this issue on the Git client.
- The following step will fail, but if you copy the signer’s certificate to the
GitLab server, you can use that to do some testing using
-nointern -certfile signerscertificate.pem
.
-
Partially verify the commit, using the extracted certificate:
/opt/gitlab/embedded/bin/openssl smime -verify -binary -inform pem \ -in /tmp/signature_text.pk7.pem -content /tmp/signed_text.txt \ -noverify -certfile /tmp/signature_cert.pem -nointern
The output usually includes:
- The parent commit
- The name, email, and timestamp from the commit
- The commit text
-
Verification successful
(or similar)
This check is not the same as the check GitLab performs, because:
- It does not verify the signer’s certificate (
-noverify
) - The verification is done using the supplied
-certfile
rather than the one in the message (-nointern
)
-
Partially verify the commit using the certificate in the message:
/opt/gitlab/embedded/bin/openssl smime -verify -binary -inform pem \ -in /tmp/signature_text.pk7.pem -content /tmp/signed_text.txt \ -noverify
This should get the same result as the previous step, using the extracted certificate.
If the message is missing the certificate, the error includes
signer certificate not found
. -
Fully verify the commit:
/opt/gitlab/embedded/bin/openssl smime -verify -binary -inform pem \ -in /tmp/signature_text.pk7.pem -content /tmp/signed_text.txt
If this step fails, verification also fails in GitLab.
Resolve any errors, for example:
-
certificate verify error .. unable to get local issuer certificate
:- The trust chain couldn’t be established.
- This OpenSSL binary uses the GitLab trust store. Either the root certificate is missing from the trust store
or the signature is missing the intermediate certificates and a chain to a trusted root can’t be built.
- Intermediate certificates can be put in the trust store if it’s not possible to include them in the signature.
-
The procedure for adding certificates
to the trust store for packaged GitLab - using
/etc/gitlab/trusted-certs
.
- Test additional trusted certificates using OpenSSL with:
-CAfile /path/to/rootcertificate.pem
-
unsupported certificate purpose
:- The certificate must specify
Digital Signature
in theX509v3 Key Usage
section of the signer’s certificate. -
If the
X509v3 Extended Key Usage
(EKU) section is specified, it must includeemailProtection
. See RFC 5280 for more details:If there is no purpose consistent with both (Key Usage) extensions, then the certificate MUST NOT be used for any purpose.
If this addition to the EKU list doesn’t resolve the issue, please provide feedback in issue 440189.
- The certificate must specify
-
signer certificate not found
, either:- You have added the
-nointern
argument, but not supplied-certfile
. - The signature is missing the signer’s certificate.
- You have added the
-