A fast and portable C++17 library for Oblivious Transfer extension (OTe). The primary design goal of this library to obtain high performance while being easy to use. This library currently implements:
- The semi-honest 1-out-of-2 OT [IKNP03].
- The semi-honest 1-out-of-2 Silent OT [BCGIKRS19].
- The semi-honest 1-out-of-2 Silent OT [CRR21].
- The semi-honest 1-out-of-2 Delta-OT [IKNP03],[BLNNOOSS15].
- The semi-honest 1-out-of-N OT [KKRT16].
- The malicious secure 1-out-of-2 OT [KOS15].
- The malicious secure 1-out-of-2 Delta-OT [KOS15],[BLNNOOSS15].
- The malicious secure 1-out-of-N OT [OOS16].
- The malicious secure approximate K-out-of-N OT [RR16].
- The malicious secure 1-out-of-2 base OT [NP01].
- The malicious secure 1-out-of-2 base OT [CO15] (Faster Linux ASM version disabled by default).
- The malicious secure 1-out-of-2 base OT [MR19]
- Several malicious secure batched 1-out-of-2 base OTs from [MRR21]
This library provides several different classes of OT protocols. First is the
base OT protocol of [NP01, CO15, MR19, MRR21]. These protocol bootstraps all the other
OT extension protocols. Within the OT extension protocols, we have 1-out-of-2,
1-out-of-N and K-out-of-N, both in the semi-honest and malicious settings. See The frontend
or libOTe_Tests
folder for examples.
All implementations are highly optimized using fast SSE instructions and vectorization to obtain optimal performance both in the single and multi-threaded setting. See the Performance section for a comparison between protocols and to other libraries.
Networking can be performed using both the sockets provided by the library and external socket classes. See the networking tutorial for an example.
The library is cross platform and has been tested on Windows, Mac and Linux. There is one mandatory dependency on Boost 1.75 (networking), and three optional dependencies on libsodium, Relic, or SimplestOT (Unix only) for Base OTs. CMake 3.15+ is required and the build script assumes python 3.
The library can be built as
git clone --recursive https://github.com/osu-crypto/libOTe.git
cd libOTe
python build.py --setup --boost --relic
python build.py -- -D ENABLE_RELIC=ON -D ENABLE_ALL_OT=ON
The main executable with examples is frontend
and is located in the build directory, eg out/build/linux/frontend/frontend.exe, out/build/x64-Release/frontend/Release/frontend.exe
depending on the OS.
LibOTe can be built with various only the selected protocols enabled. -D ENABLE_ALL_OT=ON
will enable all available protocols depending on platform/dependancies. The ON
/OFF
options include
Malicious base OT:
ENABLE_SIMPLESTOT
the SimplestOT [CO15] protocol (relic or sodium).ENABLE_SIMPLESTOT_ASM
the SimplestOT base OT protocol [CO15] protocol (linux assembly).ENABLE_MRR
the McQuoid Rosulek Roy [MRR20] protocol (relic or sodium).ENABLE_MRR_TWIST
the McQuoid Rosulek Roy [MRR21] protocol (sodium fork).ENABLE_MR
the Masny Rindal [MR19] protocol (relic or sodium).ENABLE_MR_KYBER
the Masny Rindal [MR19] protocol (Kyber fork).ENABLE_NP
the Naor Pinkas [NP01] base OT (relic or sodium).
1-out-of-2 OT Extension:
ENABLE_IKNP
the Ishai et al [IKNP03] semi-honest protocol.ENABLE_KOS
the Keller et al [KOS15] malicious protocol.ENABLE_DELTA_KOS
the Burra et al [BLNNOOSS15],[KOS15] malicious Delta-OT protocol.ENABLE_SILENTOT
the Couteau et al [CRR21],[BCGIKRS19] semi-honest/malicious protocol.
Vole:
ENABLE_SILENT_VOLE
the Couteau et al [CRR21] semi-honest/malicious protocol.
Addiition options can be set for cryptoTools. See the cmake output.
Dependancies can be managed via the build.py
script or or installed via an external tool. If an external tool is used install to system location or set -D CMAKE_PREFIX_PATH=path/to/install
.
Boost The library requires boost and can be fetched as
python build.py --setup --boost
Enabling/Disabling Relic (for base OTs): The library can be built with Relic as
python build.py --setup --relic
python build.py -- -D ENABLE_RELIC=ON
Relic can be disabled by removing --relic
from the setup and setting -D ENABLE_RELIC=OFF
.
Enabling/Disabling libsodium (for base OTs): The library can be built with libsodium as
python build.py --setup --sodium
python build.py -- -D ENABLE_SODIUM=ON
libsodium can be disabled by removing --sodium
from the setup and setting -D ENABLE_SODIUM=OFF
. The McQuoid Rosulek Roy 2021 Base OTs uses a twisted curve which additionally require the noclamp
option for Montgomery curves and is currently only in a fork of libsodium. If you prefer the stable libsodium, then install it and add -D SODIUM_MONTGOMERY=OFF
as a cmake argument to libOTe.
libOTe can be installed and linked the same way as other cmake projects. By default the dependancies are not installed. To install all dependancies, run the following
python build.py --setup --boost --relic --sodium --install
You can also selectively install the dependancies. The install location can be specifying as --install=path/to/installation
. Otherwise the system default is used.
The main library is similarly installed as
python build.py --install
By default, sudo is not used. If installation requires sudo access, then add --sudo
to the build.py
script arguments. See python build.py --help
for full details.
libOTe can be linked via cmake as
find_package(libOTe REQUIRED)
target_link_libraries(myProject oc::libOTe)
Other exposed targets are oc::cryptoTools, oc::tests_cryptoTools, oc::libOTe_Tests
. In addition, cmake variables libOTe_LIB, libOTe_INC, ENABLE_XXX
will be defined, where XXX
is one of the libOTe options.
To ensure that cmake can find libOTe, you can either install libOTe or build it locally and set -D CMAKE_PREFIX_PATH=path/to/libOTe
or provide its location as a cmake HINTS
, i.e. find_package(libOTe HINTS path/to/libOTe)
.
A minimal working example showing how to perform n
OTs using the IKNP protocol.
void minimal()
{
// Setup networking. See cryptoTools\frontend_cryptoTools\Tutorials\Network.cpp
IOService ios;
Channel senderChl = Session(ios, "localhost:1212", SessionMode::Server).addChannel();
Channel recverChl = Session(ios, "localhost:1212", SessionMode::Client).addChannel();
// The number of OTs.
int n = 100;
// The code to be run by the OT receiver.
auto recverThread = std::thread([&]() {
PRNG prng(sysRandomSeed());
IknpOtExtReceiver recver;
// Choose which messages should be received.
BitVector choices(n);
choices[0] = 1;
//...
// Receive the messages
std::vector<block, AlignedBlockAllocator> messages(n);
recver.receiveChosen(choices, messages, prng, recverChl);
// messages[i] = sendMessages[i][choices[i]];
});
PRNG prng(sysRandomSeed());
IknpOtExtSender sender;
// Choose which messages should be sent.
std::vector<std::array<block, 2>> sendMessages(n);
sendMessages[0] = { toBlock(54), toBlock(33) };
//...
// Send the messages.
sender.sendChosen(sendMessages, prng, senderChl);
recverThread.join();
}
Contact Peter Rindal [email protected] for any assistance on building or running the library.
Spread the word!
@misc{libOTe,
author = {Peter Rindal},
title = {{libOTe: an efficient, portable, and easy to use Oblivious Transfer Library}},
howpublished = {\url{https://github.com/osu-crypto/libOTe}},
}
This project has been placed in the public domain and/or MIT license. As such, you are unrestricted in how you use it, commercial or otherwise. However, no warranty of fitness is provided. If you found this project helpful, feel free to spread the word and cite us.
The running time in seconds for computing n=224 OTs on a single Intel
Xeon server (2 36-cores Intel Xeon CPU E5-2699 v3 @ 2.30GHz and 256GB of RAM
)
as of 11/16/2016. All timings shown reflect a "single" thread per party, with the
expection that network IO in libOTe is performed in the background by a separate thread.
Type | Security | Protocol | libOTe (SHA1/AES) | Encrypto Group (SHA256) | Apricot (AES-hash) | OOS16 (blake2) | emp-toolkit (AES-hash) |
---|---|---|---|---|---|---|---|
1-out-of-N (N=276) | malicious | OOS16 | 10.6 / 9.2 | ~ | ~ | 24** | ~ |
1-out-of-N (N=2128) | passive | KKRT16 | 9.2 / 6.7 | ~ | ~ | ~ | ~ |
1-out-of-2 Delta-OT | malicious | KOS15 | 1.9* | ~ | ~ | ~ | ~ |
1-out-of-2 Delta-OT | passive | KOS15 | 1.7* | ~ | ~ | ~ | ~ |
1-out-of-2 | malicious | ALSZ15 | ~ | 17.3 | ~ | ~ | 10 |
1-out-of-2 | malicious | KOS15 | 3.9 / 0.7 | ~ | 1.1 | ~ | 2.9 |
1-out-of-2 | passive | IKNP03 | 3.7 / 0.6 | 11.3 | 0.6 | ~ | 2.7 |
1-out-of-2 Base | malicious | CO15 | 1,592/~ | ~ | ~ | ~ | ~ |
1-out-of-2 Base | malicious | NP00 | 12,876/~ | ~ | ~ | ~ | ~ |
[NP01] - Moni Naor, Benny Pinkas, Efficient Oblivious Transfer Protocols.
[IKNP03] - Yuval Ishai and Joe Kilian and Kobbi Nissim and Erez Petrank, Extending Oblivious Transfers Efficiently.
[KOS15] - Marcel Keller and Emmanuela Orsini and Peter Scholl, Actively Secure OT Extension with Optimal Overhead. eprint/2015/546
[OOS16] - Michele Orrù and Emmanuela Orsini and Peter Scholl, Actively Secure 1-out-of-N OT Extension with Application to Private Set Intersection. eprint/2016/933
[KKRT16] - Vladimir Kolesnikov and Ranjit Kumaresan and Mike Rosulek and Ni Trieu, Efficient Batched Oblivious PRF with Applications to Private Set Intersection. eprint/2016/799
[RR16] - Peter Rindal and Mike Rosulek, Improved Private Set Intersection against Malicious Adversaries. eprint/2016/746
[BLNNOOSS15] - Sai Sheshank Burra and Enrique Larraia and Jesper Buus Nielsen and Peter Sebastian Nordholt and Claudio Orlandi and Emmanuela Orsini and Peter Scholl and Nigel P. Smart, High Performance Multi-Party Computation for Binary Circuits Based on Oblivious Transfer. eprint/2015/472
[ALSZ15] - Gilad Asharov and Yehuda Lindell and Thomas Schneider and Michael Zohner, More Efficient Oblivious Transfer Extensions with Security for Malicious Adversaries. eprint/2015/061
[CRR21] - Geoffroy Couteau ,Srinivasan Raghuraman and Peter Rindal, Silver: Silent VOLE and Oblivious Transfer from Hardness of Decoding Structured LDPC Codes.