The libdecaf library is for elliptic curve research and practical application. It currently supports Ed448-Goldilocks and Curve25519.
The goals of this library are:
- Implementing the X25519, X448 key exchange protocols (RFC 7748).
- Implementing the Ed25519 and EdDSA-Ed448 signature schemes (RFC 8032).
- Providing a platform for research and development of advanced cryptographic schemes using twisted Edwards curves.
This library is intended for developers who have experience with cryptography. It doesn't (yet?) include documentation on how to use digital signatures or key exchange securely. Consult your local cryptographer for advice.
Because this is new software, please expect it to have bugs, perhaps even critical security bugs. If you are using it, please sign up for updates:
- Security-critical announcements (very low volume, God willing): decaf-security@googlegroups.com, join at https://groups.google.com/forum/#!forum/decaf-security
- New version announcements (low volume): decaf-announce@googlegroups.com, join at https://groups.google.com/forum/#!forum/decaf-annonuce
- Library discussion (potentially more volume): decaf-discuss@googlegroups.com, join at https://groups.google.com/forum/#!forum/decaf-discuss
This is a multi-purpose elliptic curve library. There is a C library, and a set of C++ wrapper headers. The C++ code consists entirely of inline calls, and has no compiled component.
The library implements a fairly complete suite of operations on the supported curves:
- Point and scalar serialization and deserialization.
- Point addition, subtraction, doubling, and equality.
- Point multiplication by scalars. Accelerated double- and dual-scalar multiply.
- Scalar addition, subtraction, multiplication, division, and equality.
- Construction of precomputed tables from points. Precomputed scalarmul.
- Hashing to the curve with an Elligator variant. Inverse of elligator for steganography. These are useful for advanced protocols such as password-authenticated key exchange (PAKE) and verifiable random functions (VRFs).
Internally, the library uses twisted Edwards curves with the "decaf" and "ristretto" technique to remove the curve's cofactor of 4 or 8. The upshot is that systems using the "decaf" interface will be using a prime-order group, which mitigates one of the few disadvantages of Edwards curves. However, this means that it is not able to implement systems which care about cofactor information.
The goal of this library is not only to follow best practices, but to make it easier for clients of the library to follow best practices. With a few well-marked exceptions, the functions in this library should be strongly constant-time: they do not allow secret data to flow to array indices, nor to control decisions except for a final failure check. Furthermore, the C++ wrapping uses RAII to automatically clear sensitive data, and has interfaces designed to prevent certain mistakes.
The library additionally supports two cryptosystems defined by the Crypto Forum Research Group (CFRG): the X448/X25519 Diffie-Hellman functions (RFC 7748), and the EdDSA signature scheme (RFC 8032). Future versions might support additional operations on these curves, such as precomputed signature verification.
The Decaf library doesn't implement much symmetric crypto, but it does contain the hash functions required by the CFRG cryptosystems: SHA512, SHA-3 and SHAKE.
The "decaf" technique is described in https://eprint.iacr.org/2015/673 While the title of that paper is "removing cofactors through point compression", it might be more accurate to say "through quotients and isogenies". The internal representation of points is as "even" elements of a twisted Edwards curve with a=-1. Using this subgroup removes a factor of 2 from the cofactor. The remaining factor of 2 or 4 is removed with a quotient group: any two points which differ by an element of the 2- or 4-torsion subgroup are considered equal to each other.
When a point is written out to wire format, it is converted (by isogeny) to a Jacobi quartic curve, which is halfway between an Edwards curve and a Montgomery curve. One of the 4 or 8 equivalent points on the Jacobi quartic is chosen (it is "distinguished" according to certain criteria, such as having a positive x-coordinate). The x-coordinate of this point is written out. The y-coordinate is not written out, but the decoder knows which of the two possible y-coordinates is correct because of the distinguishing rules. See the paper for more details.
As of v0.9.4, libdecaf uses the "Ristretto" variant of this encoding. See https://www.ristretto.group for details, once that site is up.
cmake -DCMAKE_INSTALL_PREFIX= make make install
Most C source code is generated through a python script during the build. Some files holding tables are generated in one more step building an executable to generate them. They are thus stored in the source tree to help cross-compilation. The build script update them when their dependencies are modified, to build only these files:
make decaf_tables
To enable testing, use -DENABLE_TESTS=On in your cmake command: cmake -DENABLE_TESTS=On make make test
Doxygen generated documentation is located in ./doc directory in the binary tree after running
make doc
Most of the source files here are by Mike Hamburg. Those files are (c) 2014-2017 Cryptography Research, Inc (a division of Rambus). All of these files are usable under the MIT license contained in LICENSE.txt.
As mentioned in the license, there is absolutely NO WARRANTY on any of this code. This code might well have security-critical bugs despite my best efforts.
I've attempted to protect against timing attacks and invalid point attacks, but as of yet I've made no attempt to protect against power analysis.