A library for easily generating Quil programs to be executed using the Rigetti Forest platform. pyQuil is licensed under the Apache 2.0 license.
Documentation is hosted at http://pyquil.readthedocs.io/en/latest/
You can install pyQuil directly from the Python package manager pip using:
pip install pyquil
To instead install pyQuil from source, clone this repository, cd into it, and run:
pip install -e .
This will also install pyQuil's dependencies (requests >= 2.4.2 and NumPy >= 1.10) if you do not already have them.
pyQuil can be used to build and manipulate Quil programs without restriction. However, to run programs (e.g., to get wavefunctions, get multishot experiment data), you will need an API key for Rigetti Forest. This will allow you to run your programs on the Rigetti Quantum Virtual Machine (QVM) or on a real quantum processor (QPU).
Once you have your key, you need to set up configuration in the file .pyquil_config which
pyQuil will attempt to find in your home directory by default. (You can change this location by setting the
environment variable PYQUIL_CONFIG to the path of the file.) Loading the pyquil.forest module
will print a warning if this is not found. The configuration file is in INI format and should
contain all the information required to connect to Forest:
[Rigetti Forest]
url: <URL to Rigetti Forest or QVM endpoint>
key: <Rigetti Forest API key>If url is not specified, it will default to https://api.rigetti.com/qvm. In addition to the
above, the fields https_cert and https_key are supported for direct HTTPS connections to QVMs.
https_cert: <path to signed HTTPS certificate and key>
https_key: <path to separate key file, if different from the above>Here is how to construct a Bell state program and how to compute the amplitudes of its wavefunction:
>>> import pyquil.quil as pq
>>> import pyquil.forest as forest
>>> from pyquil.gates import *
>>> qvm = forest.Connection()
>>> p = pq.Program(H(0), CNOT(0,1))
<pyquil.pyquil.Program object at 0x101ebfb50>
>>> qvm.wavefunction(p)[0]
[(0.7071067811865475+0j), 0j, 0j, (0.7071067811865475+0j)]How to do a simulated multishot experiment measuring qubits 0 and 1 of a Bell state. (Of course,
each measurement pair will be 00 or 11.)
>>> import pyquil.quil as pq
>>> import pyquil.forest as forest
>>> qvm = forest.Connection()
>>> p = pq.Program()
>>> p.inst(H(0),
... CNOT(0, 1),
... MEASURE(0, 0),
... MEASURE(1, 1))
<pyquil.pyquil.Program object at 0x101ebfc50>
>>> print p
H 0
CNOT 0 1
MEASURE 0 [0]
MEASURE 1 [1]
>>> qvm.run(p, [0, 1], 10)
[[0, 0], [1, 1], [1, 1], [0, 0], [0, 0], [1, 1], [0, 0], [0, 0], [0, 0], [0, 0]]We use sphinx to build the documentation. To do this, navigate into pyQuil's top-level directory and run:
sphinx-build -b html docs/source docs/_build
To view the docs navigate to the newly-created docs/_build directory and open
the index.html file in a browser. Note that we use the Read the Docs theme for
our documentation, so this may need to be installed using pip install sphinx_rtd_theme.
We use pytest for testing. Tests can be run from the top-level directory using:
pytest --cov=pyquil
If you use pyquil, grove or other parts of Forest in your research, please cite it as follows:
bibTeX:
@misc{1608.03355,
title={A Practical Quantum Instruction Set Architecture},
author={Smith, Robert S and Curtis, Michael J and Zeng, William J},
journal={arXiv preprint arXiv:1608.03355},
year={2016}
}
Text:
R. Smith, M. J. Curtis and W. J. Zeng, "A Practical Quantum Instruction Set Architecture," (2015),
arXiv:1608.03355 [quant-ph], https://arxiv.org/abs/1608.03355