This fork of Sequoia-PGP leverages
sdkms-client-rust to perform OpenPGP operations with keys
stored in the Fortanix Data Security Manager, adding options to the
existing CLI Sequoia frontend, sq
.
Sequoia-PGP defines the Decryptor and Signer traits for low-level cryptographic operations with secret key material, and abstracts over these traits for PGP formatting. This fork implements Decryptor and Signer for secrets stored inside Fortanix DSM, enabling the production of PGP material without the need to export private keys.
Install requirements for rust-mbedtls. The following variables need to be set in order to communicate with DSM.
FORTANIX_API_ENDPOINT
, your DSM API endpoint,FORTANIX_API_KEY
, your app's API key. It overridesFORTANIX_PKCS12_ID
.FORTANIX_PKCS12_ID
, the absolute path of a PKCS12 identity file, for certificate-based authentication. Given a PKCS8 pairprivate.key
andpublic.crt
, the public certificate needs to be configured in DSM for your app, and the PKCS12 file can be generated with e.g.If a password is set for the PKCS12 file, thenopenssl pkcs12 -export -out identity.pfx -inkey private.key -in public.crt
sq-dsm
will ask for it on each key usage (which can happen several times on one PGP operation), unless theFORTANIX_PKCS12_PASSPHRASE
environment variable is set (see below).FORTANIX_PKCS12_PASSPHRASE
, the passphrase to unlock the identity file generated above. If the password is incorrect,sq-dsm
will ask for it on each operation.FORTANIX_APP_UUID
, the UUID of your DSM app, for certificate-based authentication (e.g., this environment variable is used together withFORTANIX_PKCS12_ID
).
In the following example, Alice holds a PGP key whose secrets are stored in DSM, and Bob and Charlie hold regular PGP keys.
- Generate a DSM key for Alice, and local keys for Bob and Charlie
$ sq key generate --dsm-key="alice" --cipher-suite="nistp521" --userid="Alice <[email protected]>"
$ sq key generate --cipher-suite="rsa3k" --userid="Bob <[email protected]> --export="bob.asc"
$ sq key generate --userid="Charlie <[email protected]> --export="charlie.asc"
- Recover Alice's Transferable Public Key (TPK)
$ sq key extract-cert --dsm-key="alice" > alice.asc
- Create a file, sign it with Alices's key, and verify it
$ echo "Hello, World!" > msg.txt
$ sq sign --dsm-key="alice" msg.txt > msg.txt.signed
$ sq verify --signer-cert=alice.asc msg.txt.signed
Good signature from B4C961DE2204FD02
Hello, World!
1 good signature.
- Encrypt a file to Alice, signed by Bob, and decrypt it
$ sq encrypt --recipient-cert=alice.asc --signer-key=bob.asc msg.txt > to_alice.asc
$ sq decrypt --dsm-key="alice" --signer-cert=bob.asc to_alice.asc
Encrypted using AES with 256-bit key
Compressed using ZIP
Good signature from DC4358B3EA20F2C6
Hello, World!
1 good signature.
- Encrypt a file to Charlie, signed by both Alice and Bob, and decrypt it
$ sq encrypt --recipient-cert=charlie.asc --signer-dsm-key=alice --signer-key=bob.asc msg.txt > to_charlie.asc
$ sq decrypt --recipient-key=charlie.asc --signer-cert=alice.asc --signer-cert=bob.asc to_charlie.asc
Encrypted using AES with 256-bit key
Compressed using ZIP
Good signature from B4C961DE2204FD02
Good signature from DC4358B3EA20F2C6
Hello, World!
2 good signatures.
Sequoia is a cool new OpenPGP implementation. It consists of several crates, providing both a low-level and a high-level API for dealing with OpenPGP data.
The low-level API can be found in the openpgp crate. This crate aims to provide a complete implementation of OpenPGP as defined by RFC 4880 as well as several extensions (e.g., RFC 6637, which describes ECC cryptography for OpenPGP, and RFC 4880bis, the draft of the next OpenPGP standard). This includes support for unbuffered message processing.
The openpgp crate tries hard to avoid dictating how OpenPGP should be used. This doesn't mean that we don't have opinions about how OpenPGP should be used in a number of common scenarios (for instance, message validation).
The high-level API can be found in the sequoia crate, which conveniently includes all the other crates. The high-level API include a public key store, and network access routines.
Please note that as of this writing the high-level API is very incomplete.
Sequoia includes a simple frontend sq
(crate sq) that
can be used to experiment with Sequoia and OpenPGP. It is also an
example of how to use various aspects of Sequoia.
Sequoia provides a C API for use in languages other than Rust. The glue code for the low-level interface can be found in the 'sequoia-openpgp-ffi' crate, glue for the high-level interface in the 'sequoia-ffi' crate.
The low-level API is quite feature-complete and can be used encrypt, decrypt, sign, and verify messages. It can create, inspect, and manipulate OpenPGP data on a very low-level.
The high-level API is effectively non-existent, though there is some functionality related to key servers and key stores.
The foreign function interface provides a C API for some of Sequoia's low- and high-level interfaces, but it is incomplete.
There is a mostly feature-complete command-line verification tool for detached messages called 'sqv'.
Sequoia is licensed under the GNU Library General Public License version 2 or any later version. See the file LICENSE.txt or visit https://www.gnu.org/licenses/lgpl-2.0.html for details.
If you want to use Sequoia from Rust, you can simply register the
dependency in your Cargo.toml
file as with any other project.
sequoia-openpgp = "*"
Note that we depend on a number of C libraries, which must be present along with their development packages. See Requirements section below.
Besides being a Rust crate, we also provide a C API, and bindings to other languages, see Bindings.
Sequoia is currently supported on a variety of platforms.
By default it uses the Nettle cryptographic library (version 3.4.1 or up) but it can be used with different cryptographic backends. At the time of writing, it also supports the native Windows Cryptographic API: Next Generation (CNG).
Various backends can be enabled via Cargo features,
e.g. crypto-nettle
or crypto-cng
and exactly one can be enabled at
a time.
Currently, the crypto-nettle
feature is enabled by default -
regardless of the operating system used. If you choose to enable a
different backend, please make sure to disable the default first.
To use the Windows CNG backend, use:
# Cargo.toml
[dependencies]
sequoia-openpgp = { version = "*", default-features = false, features = ["crypto-cng"] }
# When building locally
$ cargo build --manifest-path=openpgp/Cargo.toml --no-default-features --features crypto-cng
If you are developing a crate that depends on Sequoia, please ensure the users can opt into different backends. This is done by:
- disabling default features for
sequoia-openpgp
- providing top-level features for your crate that correspond to
crypto-*
ones insequoia-openpgp
- (Optionally) Select one by default yourself
Like so:
# Cargo.toml
[dependencies]
sequoia-openpgp = { version = "*", default-features = false }
[features]
# Pick a Sequoia backend enabled by default
default = ["seqouia-openpgp/crypto-nettle"]
# .. but allow others to select a different backend, as well
crypto-cng = ["sequoia-openpgp/crypto-cng"]
crypto-nettle = ["sequoia-openpgp/crypto-nettle"]
Once Cargo target-specific default features are implemented, it will be possible to automatically select a backend depending on the operating system used.
By default, Sequoia supports compression via flate2
and bzip2
crates, enabled by compression-deflate
and compression-bzip2
Cargo
features respectively (also available via compression
shorthand
feature).
To build all Sequoia components, simply execute cargo build [--release] --all
. Individual components may be built independently,
e.g. to build sq
, run cargo build [--release] -p sequoia-sq
, or
build sequoia-openpgp-ffi
to build a shared object with the C API.
The command line tool sq
can also be built using Docker:
$ docker build -t sq .
$ docker run --rm -i sq --help
For example retrieving a certificate and inspecting its contents:
$ docker run --rm -i sq keyserver get 653909A2F0E37C106F5FAF546C8857E0D8E8F074 > cert.asc
$ docker run --rm -i sq packet dump < cert.asc
To build Sequoia, you need at least Rust 1.56 and a few libraries, notably the Nettle cryptographic library version 3.4.1 or up. Please see below for OS-specific commands to install the needed libraries:
$ sudo apt install git rustc cargo clang libclang-dev make pkg-config nettle-dev libssl-dev capnproto libsqlite3-dev
Notes:
- You need at least
rustc
version 1.56. This is the version included in Debian 12 (bookworm) at the time of writing. You can use rustup if your distribution only includes an older Rust version. - You need at least Nettle 3.4.1. Both the versions in Debian 10 (Buster) and Debian 11 (Bullseye) are fine.
$ sudo pacman -S git cargo clang make pkg-config nettle openssl capnproto sqlite3 --needed
$ sudo dnf install git rustc cargo clang make pkg-config nettle-devel openssl-devel capnproto sqlite-devel
Development environment for use with nix-shell
or direnv
:
`shell.nix`
let
oxalica_overlay = import (builtins.fetchTarball
"https://github.com/oxalica/rust-overlay/archive/master.tar.gz");
nixpkgs = import <nixpkgs> { overlays = [ oxalica_overlay ]; };
rust_channel = nixpkgs.rust-bin.fromRustupToolchainFile ./rust-toolchain;
in with nixpkgs;
pkgs.mkShell {
buildInputs = [
nettle
openssl
sqlite
# for the python bindings
(python3.withPackages
(python-packages: with python-packages; [ setuptools pip ]))
];
nativeBuildInputs = [
(rust_channel.override{
extensions = [ "rust-src" "rust-std" ];
})
llvmPackages.clang
pkgconfig
capnproto
# for the python bindings
(python3.withPackages
(python-packages: with python-packages; [ setuptools pip ]))
# tools
codespell
];
RUST_BACKTRACE = 1;
# NixOS enables "fortify" by default, but that is incompatible with
# gcc -O0 in `make -Cffi examples`.
hardeningDisable = [ "fortify" ];
# compilation of -sys packages requires manually setting LIBCLANG_PATH
LIBCLANG_PATH = "${pkgs.llvmPackages.libclang.lib}/lib";
}
$ sudo port install cargo rust capnproto nettle pkgconfig coreutils
$ brew install rust capnp nettle
If building the transitive dependency nettle-sys
reports missing libclang.dylib
file make sure that DYLD_LIBRARY_PATH
is set correctly:
export DYLD_LIBRARY_PATH=/Library/Developer/CommandLineTools/usr/lib/
Please make sure to preserve line-endings when cloning the Sequoia
repository. The relevant git option is core.autocrlf
which must be
set to false
.
You can install the needed libraries with the following command:
$ pacboy -S base-devel toolchain:x clang:x bzip2:x nettle:x sqlite3:x capnproto:x
Due to Gitlab's Windows Shared Runners being somewhat slow, we only
run them automatically for MRs, which contain windows
in the branch
name. Please name your branch accordingly when contributing a patch
which might affect Windows.
To build Sequoia, you need to have capnp
tool installed.
Only the native Windows Cryptographic API (CNG) is supported, see Using Sequoia (Cryptography) section above.
When building, make sure to disable default features (to disable
Nettle) and enable the CNG via crypto-cng
Cargo feature:
$ cargo build --no-default-features --features crypto-cng,compression # Only change crypto backend
The FFI crate contains Python bindings. To disable building, testing,
and installing the Python bindings, use make PYTHON=disable
.
To build the Python bindings, you will need the Python headers, setuptools, pip, cffi, and pytest for Python3.
$ sudo apt install python3-dev python3-setuptools python3-cffi python3-pytest python3-pip
$ sudo dnf install python3-devel python3-setuptools python3-cffi python3-pytest python3-pip
$ sudo port install py-setuptools py-cffi py-pytest py-pip
# pkg install capnproto coreutils gmake lang/rust llvm nettle pkgconf py37-setuptools py37-pip python3 sqlite
Sequoia's documentation is hosted here: https://docs.sequoia-pgp.org/
The guide is hosted here: https://sequoia-pgp.org/guide/
You can join our mailing list by sending a mail to [email protected].
You can talk to us using IRC on freenode in #sequoia.
Please report bug and feature requests to our bugtracker. Please report security vulnerabilities to [email protected], preferably encrypted using OpenPGP. The certificate for this address can be found on our web site, via WKD, and on the keyserver.