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This document gives a basic primer on the wide subject of release signing. See under Further reading for links to authoritative sources of deeper information.

Release managers are the target audience.

This document is informative and does not constitute policy.


All new RSA keys generated should be at least 4096 bits. Do not generate new DSA keys.

Recent research has revealed weaknesses in SHA-1, and thus in the DSA and 1024 bit RSA OpenPGP keys which must use this algorithm. Though no realistic attacks have been made public, experience with similar weaknesses in MD5 suggests that further advances may well lead to practical attacks within the next few years. This accords with current NIST guidance on DSA.

The future impact of this weakness on Apache can be mitigated by action now. What needs to be done is a little involved. So, complete instructions have been prepared. Please read and follow them.

How to find the length of your key is described here.


Help Wanted!

Help to finish this document by contributing documentation patches ! If the information you seek isn't in this document, then please submit a patch once the infrastructure folks have answered your question.

Further Reading

Note this is not normative

Basic facts

Every artifact distributed by the Apache Software Foundation must be accompanied by one file containing an OpenPGP compatible ASCII armored detached signature and another file containing a (SHA or MD5) checksum.

MD5 hashes are deprecated; please use SHA for new releases.

The names of these files must be formed by adding to the name of the artifact the following suffixes:

Release managers must not store private keys used to sign Apache releases on ASF hardware.

See Release policy for details.

The KEYS File

The KEYS file is a plain text file containing the public key signatures of the release managers (and optionally other committers) for the project. For example, Apache Ant KEYS. It is traditional to include the following header (which explains its usage):

This file contains the PGP keys of various developers.

Users: pgp < KEYS or gpg --import KEYS

Developers: pgp -kxa <your name> and append it to this file. or (pgpk -ll <your name> && pgpk -xa <your name>) >> this file. or (gpg --list-sigs <your name> && gpg --armor --export <your name>) >> this file.

The commands above will generate a descriptive comment describing the key, followed by the key itself. [Key handling software ignores the comments when importing a key file]

The KEYS file is stored alongside the release archives to which it applies, e.g. at the top level of the ASF mirror area for the project. This is to ensure that it is available for download by users, and that it is automatically archived with historic releases.

For example, the Ant KEYS file is in the directory http://www.apache.org/dist/ant. The corresponding SVN area is at https://dist.apache.org/repos/dist/release/ant.

Since the KEYS may be needed to check signatures for archived releases, it is important that all keys that have ever been used to sign releases are retained in the file. Entries should only be added (as described above), not removed.

Note: this system will be replaced by a better process in the near future. In preparation, please ensure that public keys are connected as strongly as possible to the Apache web of trust and are available from the major public key servers.

Applied cryptography is a subject that has considerable depth. Luckily, it's possible to get started signing releases without being an expert. Just remember that (from time to time) you will encounter situations that will require research and learning. Hopefully the FAQ will be a reasonable first port of call.

You will need an application to manage keys and create signatures. GNU Privacy Guard is recommended and the Apache documentation generally assumes that's what you're using. (Documentation patches for other tools welcomed.) Read the Apache usage guide and keep the manual handy. Note that GnuPG can handle MD5 and SHA checksums as well as PGP signatures. It is your one-stop shop, cross-platform tool for release signing and verification.

It can be hard for newbies to be confident that they have executed operations correctly. Consider doing some practice first.

Why We Sign Releases

A signature allows anyone to verify that a file is identical to the one created by the Apache release manager. Using a signature:

OpenPGP signatures confer the usual advantages of digital signatures: authentication, integrity and non-repudiation. MD5 and SHA checksums only provide the integrity part as they are not encrypted.

Security Basics

Key Basics

To sign releases, you need to generate a new master key-pair for code signing. Follow these instructions.

Signing Basics

Signatures should be ASCII armored and detached.

Your public key should be exported and the result appended to the appropriate KEYS file(s).

That's all you need to know to sign a release.

How Do I Sign A Release?

Create a OpenPGP compatible ASCII armored detached signature for the released artifact. Upload the signature with the released artifact.

See here for a basic overview.

What Is an OpenPGP Compatible ASCII Armored Detached Signature?

It is an OpenPGP compatible ASCII armored detached signature.

To create one using GNU Privacy Guard for file foo.tar.gz type:

   $ gpg --armor --output foo.tar.gz.asc --detach-sig foo.tar.gz 

What Is OpenPGP?

OpenPGP is an RFC describing a system for interoperable public key cryptography. Various implementations exist. Apache recommends GNU Privacy Guard.

GNU Privacy Guard (GnuPG) is an open source OpenPGP compatible implementation. It comes with good documentation describing not just GnuPG but also giving a good general introduction to public key cryptography. A guide to using GnuPG at Apache is available.

What Is Public Key Cryptography?

Public key cryptography is asymmetric. One key can be used to encrypt a message which only the other key can decrypt. Knowledge of the first key can be made public without compromising the security of the second key. One key is therefore called the public key and one the private key.

When using public key cryptography, the public key can be freely distributed but the private key must be secret. It is vital that private key files are protected. Private keys are typically stored in files protected by symmetric encryption. Strong passphrases must be chosen to protect them.

What Is An Detached Signature?

A digital signature is created from an original document using a private key. Possession of the corresponding public key allows verification that a given file is identical to the original document. An attached signature is attached to the document whereas a detached signature is contained in a separate file.

What Is ASCII Armoring?

An encoding format that converts a binary file into a string of ASCII characters. This format is more human readable and more portable.

What Is An MD5 Checksum?

MD5 is a well known message digest algorithm.

Many tools are available to calculate these sums. For example, OpenSSL can be used:

$ openssl md5 < file
Platform specific applications are also common. For example md5sum on linux:
$ md5sum file
With GnuPG:
  $ gpg --print-md MD5 [fileName] > [fileName].md5

Please run the command in the same directory as the file so the output only contains the file name with no directory prefixes.

Please note that the security of MD5 is now questionable and is only useful as part of a defense in depth.

What is a SHA checksum?

Like MD5 , SHA is another message digest algorithm.

Using GnuPG, you can create a SHA1 signature as follows:

  $ gpg --print-md SHA1 [fileName] > [fileName].sha1
Please note that further use of SHA-1 should be avoided.

SHA256 and SHA512 use the same SHA algorithm family with longer hash lengths (256 and 512 bits respectively). These longer variations are less vulnerable to the weaknesses found in the algorithm family than SHA1. SHA512 is recommended.

To create a SHA512 checksum use:

  $ gpg --print-md SHA512 [fileName] > [fileName].sha512

Please run the command in the same directory as the file so the output only contains the file name with no directory prefixes.

Other members of the SHA family (with different hash lengths) are rarely used.

This family of algorithms will be retired once SHA3 is available.

What Is A Message Digest Algorithm?

A message digest algorithm takes a document and produces a much smaller hash of that document. A good algorithm will produce different digests for very similar documents. A good algorithm makes it infeasible to create a message matching a given hash.

A trusted digest for a document can be used to verify the contents of an untrusted file. The small size of the digest allows it to be delivered over a secure but expensive channel whilst the untrusted file is delivered over an insecure but inexpensive one. This is useful when distributing releases.

What Is A Web Of Trust?

It is difficult to personally verify the identity of all useful public keys. However, having verified the identity of only a small number of public keys it is possible to deduce the identity of public keys trusted by the owners of these keys. This process can be repeated. This extended graph of trusted identities is termed a web of trust.

Webs of trust can be used to solve the problem of verifying the identity of public keys.

Note: in order to take full advantage of a web of trust, it is important to actively build your web of trust into the major public webs of trust. Conferences are an ideal opportunity but you must come prepared.

For more information read Henk Penning's Apache home page and the GNU Privacy Guard User Guide.

How Do I Link Into A Public Web of Trust?

By an existing member of that web of trust signing your public key to verify your identity. See Henk Penning's Key Signing HOWTO

A short guide is available.

What Is A Key Signing Party?

A key signing party is a meeting organised to allow the exchange of public keys and so extension of the web of trust.

See the Keysigning Party HOWTO and Henk Penning's Key Signing HOWTO

How Can I Link My Key Into The Apache Web of Trust?

By meeting other Apache committers face-to-face and exchanging public keys. There are several ways to achieve this:

See Henk Penning's Key Signing HOWTO

What Does Verifying A Signature Mean?

Public key cryptography can be used to test whether a particular file is identical (in content) to an original by verifying a signature. The signature file is a digest of the original file signed by a private key which attests to the digest's authenticity.

For example, when using GNU Privacy Guard you verify the signature foo-1.0.tar.gz.asc for release foo-1.0.tar.gz using the following command:

$ gpg --verify foo-1.0.tar.gz.asc foo-1.0.tar.gz
A signature is valid, if gpg verifies the .asc as a good signature, and doesn't complain about expired or revoked keys. Technically :
$ gpg --verify --status-fd 1 foo-1.0.tar.gz.asc foo-1.0.tar.gz
should classify the .asc as a GOODSIG.

Trust is required in the identity of the public key that made the signature and that the signature is for the original in question (and not some other file). When verifying a release from an untrusted source (for example, over P2P file sharing or from a mirror) it is therefore important to download the signature from a trusted source. Signatures for all Apache releases are available directly from www.apache.org and should be downloaded from there.

How Can I Check The Integrity Of A Release?

MD5 and SHA checksums provide a simple, means of verifying the integrity of a download. You can simply create a checksum (in the same way as the release manager) after download, and compare the result to the checksum downloaded from the main Apache site. Obviously, this process does not provide for authentication and non-repudiation as anybody can create the same checksum.

The integrity of a release can also be checked by verifying the signature. More knowledge is required to correctly interpret the result but it does provide authentication and non-repudiation. If you are connected to the Apache web of trust then this also offers superior security.

What Does 'Public Key Not Found' Mean (When Verifying A Signature)?

Before a signature can be verified, the public key is required.

For example, when using GNU Privacy Guard if you have never imported the appropriate public key a message similar to the following will be displayed:

$ gpg --verify foo-1.0.tar.gz.asc foo-1.0.tar.gz
gpg: Signature made Mon Sep 26 22:26:18 2005 BST using RSA key ID 00000000
gpg: Can't check signature: public key not found
Unknown keys can often be downloaded from public key servers. However, these should only be trusted through a web of trust.

Apache projects normally keep the developers' public keys in a file called KEYS. You may be able to find that file on the project's website, or in their code repository. Use

  $ gpg --import KEYS
to import the public keys.

What is a Trusted Key?

OpenPGP uses a web of trust. The owner of a public key who trusts the identity of a second key may mark this key as trusted by signing it. This has several major effects:

The transitive nature of the web of trust places a responsibility on the owner to verify the identity of the owner of those keys marked as trusted.

For more information read Henk Penning's Apache home page and the GNU Privacy Guard User Guide.

What Is The Difference Between A Valid Signature from an Untrusted Key And An Invalid Signature from an Untrusted Key?

Trustfulness and validity are different concepts. You may elect to trust the identity of a key to various degrees (or not at all). For a particular key, a particular signature for a particular file may be valid (in other words, created by the private key from an identical file) or invalid (either corrupt or created from a different file).

You should not trust a file with an invalid signature. You can trust a file with a valid signature as much as you trust the identity of key that was used to verify the signature.

For example, when using GNU Privacy Guard a message similar to the following indicates that the signature is invalid:

$ gpg --verify foo-1.0.tar.gz.asc foo-1.0.tar.gz
gpg: Signature made Mon Sep 26 22:26:18 2005 BST using RSA key ID 00000000
gpg: BAD signature from "someone@example.org"
whereas a message similar to the following indicates that the signature is valid but for an untrusted key:
$ gpg --verify foo-1.0.tar.gz.asc foo-1.0.tar.gz
gpg: Signature made Mon Sep 26 22:05:28 2005 BST using RSA key ID 00000000
gpg: Good signature from "someone@example.org"
gpg:                 aka "someone@anotherdomain.org"
gpg: checking the trustdb
gpg: checking at depth 0 signed=1 ot(-/q/n/m/f/u)=0/0/0/0/0/1
gpg: checking at depth 1 signed=0 ot(-/q/n/m/f/u)=1/0/0/0/0/0
gpg: WARNING: This key is not certified with a trusted signature!
gpg:          There is no indication that the signature belongs to the
Primary key fingerprint: 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00
The fingerprint may be used to ascertain the appropriate level of trust to assign to the key.

What Is A Public Key Fingerprint?

Public keys are long and even when ASCII armored are not very easy for humans to understand or compare. A fingerprint is a shorter digest of the key formatted in a way that makes it easier for humans to read and compare.

Why Infeasible And Not Impossible?

Responsible cryptography talks about infeasible cracks (rather than impossible ones) since this is more accurate. All current practical methods can be subjected to brute force attacks and so can be cracked. So, a good question is whether attacks are feasible given the current state of the art.

Where Should I Create The Signatures?

Creating signatures requires the private key. Limited copies should be kept of the private key and all must be kept confidential. Though the file used to store the private key is typically protected by encryption, it is vulnerable to dictionary attacks on the passphrase. This file must therefore be kept secret. So, signatures should be created on the machine used to store the private key.

It is important that the private key is stored on secure hardware with limited read permissions and is protected by a good passphrase. Consider using removable media or an isolated installation.

A master private key used to sign Apache artifacts (or to secure communications with the ASF) is particularly valuable. If you want or need to be able to create signatures for other purposes (for example, signing email messages) in other (less secure) locations it is recommended that you create multiple sub keys and use sub keys for signing in less secure locations.

The private key must not be store on any ASF machine. So, signatures must not be created on ASF machines.

What Is 'Insecure Memory' And Should I Be Worried?

When you use GNU Privacy Guard you may see a warning similar to:

gpg: WARNING: using insecure memory!
gpg: please see http://www.gnupg.org/faq.html for more information
If you are using GnuPG on Apache hardware, please read this. Sensitive operations using a private key must not be executed on ASF hardware.

If you encounter this issue elsewhere then it indicates that GnuPG cannot lock memory pages which means they may be swapped out to disc. It would then be feasible for an attacker who had gained access to the machine to read the private key from the swap file. For more details, read the FAQ.

What is a Passphrase?

The term passphrase is often used in cryptography for what might be better known as a password in other contexts. For example, an OpenPGP private key is typically stored to disc in an file encrypted by a symmetric cypher keyed by a passphrase. This passphrase is one of the weakest elements in the system: should anyone else gain access to the file then a dictionary attack will be feasible on a weak passphrase. So, choosing a strong passphrase is very important.

Passphrases are (unlike passwords) typically unlimited in length. Long passphrases are recommended. This allows sequences of (at least seven) unrelated words to be used as well as more conventional mixtures of symbols and alphanumerics.

Note that even a good passphrase will offer only limited protection. Given the encrypted file and enough time, a determined cracker will be able to break any passphrase. A good passphrase will buy important time in the event of a compromise but is no substitute for keeping the private key safe and secure in the first place.

What Is A Revocation Certificate?

OpenPGP defines a special type of signed message called a revocation certificate. This message indicates that the signer believes that the key is no longer trustworthy. Typically, the revocation certificate will be signed by the key to be revoked (though the key may specify that other keys should be trusted for revocation). The type of revocation and the comment included may be used to judge how much trust to place in a good signature by a revoked key.

A revocation certificate should be generated for each public key used. These should be stored safely, securely and separately from the public key.

Each revocation certificates has a type specifying a general (machine readable) reason for the revocation:

It is recommended that certificates are created to cover the first two cases. Note that if a key is lost or can no longer be accessed (due to media failure, say) it is best to assume that the key has been potentially compromised. It is recommended that revocation certificates are printed and stored safely to guard against media failure.

An ASCII armored revocation certificate for key bob can be generated and saved to revoke.asc using GNU Privacy Guard as follows:

$ gpg --output revoke.asc --armor --gen-revoke bob
The certificate produced should be securely stored.

If you are preparing a revocation certificate for future use, it is recommended that you test it. See safe practice.

How Do I Revoke A Key?

To revoke a key (given a certificate) using GNU Privacy Guard import the revocation certificate :

$ gpg --import revoke.asc 
gpg: key 4A03679A: "Some User <someuser@example.org>" revocation
certificate imported
gpg: Total number processed: 1
gpg:    new key revocations: 1

Where Should A Revocation Certificate Be Stored?

The revocation certificate should be stored securely and separately from the key it revokes. Burning onto CDROM or printing out onto hard copy are good solutions.

How Do I Distribute A Revocation Certificate?

In the event of a compromise, a revocation certificate needs to be distributed to those using the key. This process needs to be a mirror of the process by which the original key was distributed.

What Is The Difference Between Deleting And Revoking A Key?

When a key is deleted from a keyring, it is simply removed. It can be added again later.

When a key is revoked, the key is marked in the key ring. Whenever a message signed by this key is verified in the future, the user will be warned that the key has been revoked.

For example, when verifying a revoked key, GNU Privacy Guard issues the following comment:

$ gpg --verify message.asc.message 
gpg: Signature made Sat Apr  8 09:28:31 2006 BST using DSA key ID 4A03679A
gpg: Good signature from "Some User <someuser@example.org>"
gpg: checking the trustdb
gpg: checking at depth 0 signed=0 ot(-/q/n/m/f/u)=0/0/0/0/0/1
gpg: WARNING: This key has been revoked by its owner!
gpg:          This could mean that the signature is forgery.
gpg: reason for revocation: Key has been compromised
gpg: revocation comment: 
gpg: WARNING: This key is not certified with a trusted signature!
gpg:          There is no indication that the signature belongs to the
Primary key fingerprint: 82D1 169B E6F1 9D14 DA76  A5DD 968E 66E4 4A03 679A

Can I Mark A Key As Locally Trusted?

On occasion, a key may be trusted by the user (who understands the risks) but is not considered trustworthy enough to be exported to the web of trust.

OpenPGP allows keys to be signed as local only. These trust relationships will not be exported to the public web of trust but will be treated as trusted when the key ring is used locally.

For example, with GNU Privacy Guard use:

$ gpg --lsign-key someuser

How Can I Safely Practice Using OpenPGP?

Use separate environments each with a different practice keyring.

For example, using GNU Privacy Guard :

What Is The Difference Between A Public And A Private Key?

A public key is used for verifying signatures and encrypting messages, a private key for generating signatures and decrypting messages. Public keys can be freely distributed safely whereas private keys must be kept protected. More details here.

How Should My Code Signing Private Key Be Protected?

Anyone who possesses a copy of a private key used to sign releases can create doctored releases with valid signatures. If this person intends harm then the consequences could be serious indeed.

It is therefore very important that this private key is kept secret.

How Secure Does The Machine Used To Sign Releases Need To Be?

If the code signing machine is owned then it is only a matter of time before the key is compromised.

At a minimum, the machine should well maintained (kept up to date with security patches, use appropriate anti-virus and firewall software). The ideal is an isolated, well maintained installation used only for creating releases. This can be achieved with a little effort by creating an isolated installation on a separate hard disc (which is physically disconnected when not in use signing releases) or a live CD.

Which Applications Create OpenPGP Compatible Signatures?

There are many applications available (some commercial, some freeware, some software libre). Whichever one you choose, please subscribe to the appropriate security lists and keep the application fully patched.

Here are some used by ASF release managers:

How Safe Does The Private Key Need To Be?

It is vital that the private key is kept safe and secure. Though the file is encrypted using a passphrase , given enough time any determined cracker will be able to break that encryption. It is therefore essential that the private key file is kept safe and secure.

Basic precautions should include ensuring that the directories are readable only by the user.

However, it is recommended that for code signing keys additional measures are taken. The window of opportunity can be reduced by either using a isolated installation or by storing the private key on removable media (which should be removed to secure storage when not being used to sign releases).

What Does 'Isolated Installation' Mean?

An installation which is inaccessible when not being used to sign releases. For example, create an installation on a separate hard disc or use a live CD.

What Key Length Is Recommended?

There is no good, simple answer to this question.

The number of operations required to break a key by brute force increases with key size. However, the cost of using the key also rises. So, the planned usage of the key must be a consideration. Keys used for code signing will only be used rarely and in situations where performance is not the main concern. This is a reason to err in favor of long key lengths.

Over time, the practice cost of attacking a key (of a given length) by brute force falls as computing power increases. So, a key whose length seems adequate today may be seem too short in a few years time. This is a significant issue for long-lived keys such as those used to sign ASF releases. Again, this is a reason to err in the favor of longer key lengths.

Now that there is doubt about the medium term security of SHA-1 , the DSA keys and 1024 bit RSA keys (which depend on this algorithm) should be avoided for new keys. It is uncertain whether 2048 bit RSA keys will be strong enough to remain secure until SHA3 (and the next generation of standards) arrives. It is therefore recommended that new keys should be at least 4096 bit RSA (the longest widely supported key length).

Is MD5 Still Secure?

There is no good, simple answer to this question.

Though feasible collision attacks are known, they are still computationally expensive. MD5 may still be useful as an additional layer in a defense in depth. Not recommended.

Is SHA-1 Still Secure?

There is no good, simple answer to this question.

Research has revealed weaknesses in this algorithm. Though there are no practical attacks known at the time of writing, experiences with similar weaknesses in MD5 suggest that efforts should be made now to move away from this algorithm.

Breaking the longest members of this family ( SHA512 and SHA256 ) is still considered infeasible. Until SHA-3 is available, new uses of SHA-1 should be avoided and SHA512 (or SHA256) used instead.

Configuration instructions for GnuPG can be found here.

What is SHA-3?

SHA-3 is the designation for a new cryptographic hash algorithm to replace the SHA family. A public competition has selected Keccak. The full standard has not been released yet. Once the full standard is released work will need to be done to permit it to be used with OpenPGP.

Which Standard Crytographic Hash Algorithms Are Secure?

There is no good, simple answer to this question.

Feasible - though expensive - attacks on MD5 have been made public. Similar weaknesses have been found in the SHA family of hashes though practical attacks are not yet publically known. However, longer hash sizes offer considerable protection. So, larger members of the SHA family still look likely to be secure enough for a number of years.

RIPE has not been as well studied as either SHA or MD5. It is likely to offer no more security than SHA.

SHA512 is the strongest well studied widely used cryptographic hash. It is therefore the best recommendation until SHA3 is available.

How Do You Generate A Code Signing Key?

The exact mechanics are application dependent. For GnuPG (recommended), follow the strong key generation instructions. Please think about the right key length , configure the tool to avoid SHA-1 and choose a good passphrase. Use the recommended id and comment.

What OpenPGP User-ID Should I Choose For My Code Signing Key?

It is recommended that your Apache email address is used as the primary User-ID for the code signing key. For example, rdonkin@apache.org.

What OpenPGP Comment Should I Choose For My Code Signing Key?

It is recommended that the comment includes CODE SIGNING KEY. This makes clear the primary use for this key. This can be helpful if you later generate keys for other uses.

It is recommended that keys generated for other purposes include in the comment NOT FOR CODE SIGNING.

What Is A Public Key Server?

A public key server manages public keys. Available functions may vary but typically include upload , search and download.

Public key servers exist to distribute public keys. They do not vouch for the actual identity of the owner of each key. This must be established either directly or through a web of trust. Do not trust a key just because it has been downloaded from a key server.

The major public key servers synchronize their records regularly so a key uploaded to one should be disseminated to the rest.

Some well known public key servers:

Although the following is also well-known, at present it does not synchronise keys with other key servers, so should not be used as the only public server for your key:

How Do You Upload A Key To A Public Key Server?

There are two common ways to upload a key to a public key server :

For example using GNU Privacy Guard , the key with ID B1313DE2 can be exported to the default public key server by:

$ gpg --send-key B13131DE2
Note that each changed key must be exported separately.

How Can I Ensure My Local Web Of Trust Is Up To Date?

The public web of trust grows constantly as people sign new keys and upload the new signatures onto the network of public key servers. Public keys should be periodically refreshed to ensure that your local web of trust is as full as possible. Many OpenPGP clients allow keys to be easily refreshed by querying a public key server.

For example, to refresh all keys using GNU Privacy Guard use:

$ gpg --refresh-keys

How Do You Export A Key?

A public key can be exported using OpenPGP by using --export. Typically, the export should be ASCII armored. For example, to export all public keys to the command line use:

gpg --export --armor
In most cases, it is better to export all keys - this ensures that signatures made on other keys will be exported. However, it is possible to export just one key by specifying it on the command line.

Secret keys can also be exported. However, exporting secret keys poses a security risk and there are better solutions for most common use cases. For example, copying the GNUPGHOME directory (typically ~/.gnupg ) is a better way to transfer an OpenPGP keyring from one machine to another.

What Is A Key ID?

A key ID is similar to a fingerprint but is much smaller in length. There is no guarantee that key IDs are unique. Consequently, it is strongly recommended that the fingerprint is checked before signing a key. The key ID is typically used for locating keys and identifying keys already contained within the keyring. For these use cases, key ID should be unique enough in practice.

A short guide to discovering the key ID for a key is available.

What Is A Sub Key?

Each OpenPGP keyring has a single master key. This key is signing only. It may also optionally have a number of sub keys (for encryption and signing).

If you wish to sign emails using a key related to that used to sign code, it is recommended that a signing sub key is used.

How Do I A Use Sub Key To Sign Emails?

To keep a code signing key safe and secure it is recommended that the key is not kept on a hard disc on a regular development machine. This means that the master key should not be used directly to sign emails. However, there are occasions when digitally signed emails are desirable.

The recommended approach is to create a sub key for email signing and export it to the regular machine. The master key can then be kept safely offline. For more details, read:

Note that some public key servers do not handle sub keys correctly. It may be necessary to use one on the SKS network.

How Can I Find Out More?

See this.

Is There A Quick Way To Sign Several Distributions?

The private https://svn.apache.org/repos/private/committers repository contains scripts that assist with batch signing several distributions.

How Can I Transfer A Secret Key?

This is application dependent. Instructions for GnuPG are available.

Why Do Some People Have Two Keys?

When switching from an uncompromised key to another (typically stronger) one, it is convenient to use a transition period. During a transition, both keys are trustworthy but only (the newer) one is actively used to sign documents and certify links in the web of trust.

What Is A Transition Period (For Keys)?

When replacing one uncompromised key with a newer (typically longer) one, a transition period where both keys are trustworthy and participate in the web of trust allows - by trust transitivity - links to the old key to be used to trust signatures and links created by the new key. During a transition, both keys are trustworthy but only (the newer) one is actively used to sign documents and certify links in the web of trust.

How Should I Transition From A Short To A Longer Key?

If you have a short but uncompromised key and would like to transition to a longer one, follow these instructions.

If your key has been compromised then you MUST NOT transition but revoke the old key and replace with a new one immediately. DO NOT use a transition period.

I Have A New Key. Which Apache Documents Need To Be Updated?

A number of Apache documents need to be updated. Follow these instructions.

What Is RSA?

RSA is a well known public key cryptography algorithm which supports signing and encryption.

See further reading for more details.

How Do I Find The Length Of A Key?

The easiest way to discover the length of a key (with id KEYID ) is to use gpg --list-keys KEYID. This will print basic information about the key. The first line will include the size in the second column just before the id.

For example:

$ gpg --list-keys B1313DE2
pub   1024D/B1313DE2 2003-01-15
uid                  Robert Burrell Donkin (CODE SIGNING KEY) <rdonkin@apache.org>
uid                  Robert Burrell Donkin <robertburrelldonkin@gmail.com>
uid                  Robert Burrell Donkin <robertburrelldonkin@blueyonder.co.uk>
sub   4096R/40A882CB 2009-06-18 [expires: 2010-06-18]

$ gpg --list-keys A6EE6908 pub 8192R/A6EE6908 2009-08-07 uid Robert Burrell Donkin (CODE SIGNING KEY) <rdonkin@apache.org> sub 8192R/B800EFC1 2009-08-07

shows that key B1313DE2 has length 1024 and A6EE6908 length 8192.