The Quantum Exact Simulation Toolkit is a high performance simulator of universal quantum circuits, state-vectors and density matrices. QuEST is written in C, hybridises OpenMP and MPI, and can run on a GPU. Needing only compilation, QuEST is easy to run both on laptops and supercomputers (in both C and C++), where it can take advantage of multicore, GPU-accelerated and networked machines to quickly simulate circuits on many qubits.
QuEST has a simple interface, independent of its run environment (on CPUs, GPUs or over networks),
hadamard(qubits, 0);
controlledNot(qubits, 0, 1);
rotateY(qubits, 0, .1);though is flexible
Vector v;
v.x = 1; v.y = .5; v.z = 0;
rotateAroundAxis(qubits, 0, 3.14/2, v);and powerful
// sqrt(X) with pi/4 global phase
ComplexMatrix2 u = {
.real = {{.5, .5}, { .5,.5}},
.imag = {{.5,-.5}, {-.5,.5}}};
unitary(qubits, 0, u);
int controls[] = {1, 2, 3, 4, 5};
multiControlledUnitary(qureg, controls, 5, 0, u);QuEST can simulate decoherence on mixed states, output QASM, perform measurements, apply general unitaries with any number of control and target qubits, and boasts cheap/fast access to the underlying numerical representation of the state. QuEST offers precision-agnostic real and imaginary (additionally include QuEST_complex.h) number types, the precision of which can be modified at compile-time, as can the target hardware.
Learn more about QuEST at quest.qtechtheory.org, or read the whitepaper. If you find QuEST useful, feel free to cite
Jones, T., Brown, A., Bush, I. et al.
QuEST and High Performance Simulation of Quantum Computers.
Sci Rep 9, 10736 (2019) doi:10.1038/s41598-019-47174-9
@article{Jones2019,
title={{QuEST} and high performance simulation of quantum computers},
author={Jones, Tyson and Brown, Anna and Bush, Ian and Benjamin, Simon C},
journal={Scientific reports},
volume={9},
number={1},
pages={1--11},
year={2019},
publisher={Nature Publishing Group}
}
Full documentation is available at quest.qtechtheory.org/docs, and the API is available here (all functions listed here). See also the tutorial.
For developers: To regenerate the API doc after making changes to the code, run
doxygen doxyconfig/configin the root directory. This will generate documentation inDoxygen_doc/html, the contents of which should be copied intodocs/). Make sure thatPROJECT_NUMBERindoxyconfig/configis up to date!
QuEST is contained entirely in the files in the QuEST/ folder. To use QuEST, copy this folder to your computer and include QuEST.h in your C or C++ code, and compile using cmake with the provided CMakeLists.txt file. See the tutorial for an introduction. We also include example submission scripts for using QuEST with SLURM and PBS.
MacOS and Linux users can clone this repository to your machine through the terminal:
git clone https://github.com/quest-kit/QuEST.git
cd QuESTCompile the example using
mkdir build
cd build
cmake ..
makethen run it with
./demoWindows users should install Build Tools for Visual Studio, CMake and MinGW-w64. Then, in a Developer Command Prompt for VS, run
git clone "https://github.com/quest-kit/QuEST.git"
cd QuESTmkdir build
cd build
cmake .. -G "MinGW Makefiles"
makedemo.exeAdditionally, you can run QuEST's rigorous unit tests in your own environment, which should take no longer than ten minutes.
mkdir build
cd build
cmake .. -DTESTING=ON
make
make testTo file a bug report or feature request, raise a github issue. For additional support, email [email protected]. You can view the list of contributors to QuEST in AUTHORS.txt.
QuEST uses the mt19937ar Mersenne Twister algorithm for random number generation, under the BSD licence. QuEST optionally (by additionally importing QuEST_complex.h) integrates the language agnostic complex type by Randy Meyers and Dr. Thomas Plum
Thanks to HQS Quantum simulations for contributing the mixDamping function.
QuEST is released under a MIT Licence
- PyQuEST-cffi: a python interface to QuEST based on cffi developed by HQS Quantum Simulations. Please note, PyQuEST-cffi is currently in the alpha stage and not an official QuEST project.
- QuESTlink: a Mathematica package allowing symbolic circuit manipulation and high performance simulation with remote accelerated hardware.