Skip to main content

MQT Bench - A MQT tool for Benchmarking Quantum Software Tools

Project description

PyPI License: MIT CI Bindings codecov

MQT Bench: Benchmarking Software and Design Automation Tools for Quantum Computing

MQT Bench is a quantum circuit benchmark suite with cross-level support, i.e., providing the same benchmark algorithms for different abstraction levels throughout the quantum computing software stack.

MQT Bench is part of the Munich Quantum Toolkit (MQT) developed by the Chair for Design Automation at the Technical University of Munich and is hosted at https://www.cda.cit.tum.de/mqtbench/.

This documentation explains how to use MQT Bench to create and filter benchmarks.

Abstraction Levels

It uses the structure proposed by the openQASM 3.0 specification [1] and offers benchmarks on four different abstraction levels:

  1. Algorithmic Level
  2. Target-independent Level
  3. Target-dependent Native Gates Level
  4. Target-dependent Mapped Level

An example is given in the following:

  1. Algorithmic Level

Variational Quantum Algorithms (VQAs) are an emerging class of quantum algorithms with a wide range of applications. A respective circuit is shown above, it represents an example of an ansatz function frequently used for Variational Quantum Eigensolvers (VQEs), a subclass of VQAs. On this abstraction level, the circuit is parameterized by the angles θi of the six single-qubit gates.

  1. Target-independent Level

VQAs are hybrid quantum-classical algorithms, where the parameters of the quantum ansatz are iteratively updated by a classical optimizer analogous to conventional gradient-based optimization. Consider again the circuit from the previous figure. Assuming these parameters have been determined, e.g., θi = −π for i = 0, ..., 5, they are now propagated and the resulting quantum circuit is shown above.

  1. Target-dependent Native Gates Level

Different quantum computer realizations support different native gate-sets. In our example, we consider the IBMQ Manila device as the target device which natively supports I, X, √X, Rz and CX gates. Consequently, the Ry gates in the previous figure have to be converted using only these native gates. In this case, they are substituted by a sequence of X and Rz gates (denoted as • with a phase of −π).

  1. Target-dependent Mapped Level

The architecture of the IBMQ Manila device is shown above on the right and it defines between which qubits a two-qubit operation may be performed. Since the circuit shown in the previous figure contains CX gates operating between all combination of qubits, there is no mapping directly matching the target architecture's layout. As a consequence, a non-trivial mapping followed by a round of optimization leads to the resulting circuit shown above on the left. This is also the reason for the different sequence of CX gates compared to the previous example.

This circuit is now executable on the IBMQ Manila device, since all hardware induced requirements are fulfilled.

Benchmark Selection

So far, the following benchmarks are implemented and provided:

  • Amplitude Estimation
  • Deutsch-Jozsa
  • GHZ State
  • Graph State
  • Ground State
  • Grover's (no ancilla)
  • Grover's (v-chain)
  • Portfolio Optimization with QAOA
  • Portfolio Optimization with VQE
  • Pricing Call Option
  • Pricing Put Option
  • Quantum Fourier Transformation (QFT)
  • QFT Entangled
  • Quantum Neural Network (QNN)
  • Quantum Phase Estimation (QPE) Exact
  • Quantum Phase Estimation (QPE) Inexact
  • Quantum Walk (no ancilla)
  • Quantum Walk (-chain)
  • Random Circuit
  • Routing
  • Shor's
  • Travelling Salesman
  • Variational Quantum Eigensolver (VQE)
  • VQE-ansätze with random values:
    • Efficient SU2 ansatz with Random Parameters
    • Real Amplitudes ansatz with Random Parameters
    • Two Local ansatz with Random Parameters
  • W-State

See the benchmark description for further details on the individual benchmarks.

Quantum Circuit Compiler Support

At the moment, two compilers are supported:

  1. Qiskit with the compiler settings: Optimization level 0 to 3
  2. TKET with the compiler settings: Line placement and graph placement

Native Gate-Set Support

So far, MQT Bench supports the following native gate-sets:

  1. IBMQ gate-set: ['rz', 'sx', 'x', 'cx', 'measure']
  2. Rigetti gate-set: ['rx', 'rz', 'cz', 'measure']
  3. IonQ gate-set: ['rxx', 'rz', 'ry', 'rx', 'measure']
  4. OQC gate-set: ['rz', 'sx', 'x', 'ecr', 'measure']
  5. Quantinuum gate-set: ['rzz', 'rz', 'ry', 'rx', 'measure']

Device Support

So far, MQT Bench supports the following devices:

  1. IBMQ Washington with 127 qubits
  2. IBMQ Montreal with 27 qubits
  3. Rigetti Aspen-M2 with 80 qubits
  4. IonQ Harmony with 11 qubits
  5. IonQ Aria 1 with 25 qubits
  6. OQC Lucy with 8 qubits
  7. Quantinuum H2 with 32 qubits

Repository Structure

  • src/mqt/: main source directory
    • bench: Directory for the MQT Bench package
    • bench/benchmarks: Directory for the benchmarks
    • benchviewer: Directory for the webpage (which can be started locally and is also hosted at https://www.cda.cit.tum.de/mqtbench/)
  • tests: Directory for the tests for MQT Bench

Repository Usage

There are three ways how to use this benchmark suite:

  1. Via the webpage hosted at https://www.cda.cit.tum.de/mqtbench/
  2. Via the pip package mqt.bench
  3. Directly via this repository

Since the first way is rather self-explanatory, the other two ways are explained in more detail in the following.

Usage via pip package

MQT Bench is available via PyPI

(venv) $ pip install mqt.bench

To generate a benchmark circuit on the algorithmic level, please use the get_benchmark method:

def get_benchmark(
    benchmark_name: str,
    level: Union[str, int],
    circuit_size: int = None,
    benchmark_instance_name: str = None,
    compiler: str = "qiskit",
    compiler_settings: mqt.bench.CompilerSettings = None,
    gate_set_name: str = "ibm",
    device_name: str = "ibm_washington",
):
    ...

The available parameters are:

  • benchmark_name: "ae", "dj", "grover-noancilla", "grover-v-chain", "ghz", "graphstate", "portfolioqaoa", "portfoliovqe", "qaoa", "qft", "qftentangled", "qnn", "qpeexact", "qpeinexact", "qwalk-noancilla", "qwalk-v-chain", "random", "realamprandom", "su2random", "twolocalrandom", "vqe", "wstate", "shor", "pricingcall", "pricingput", "groundstate", "routing", "tsp"
  • level: 0 or "alg", 1 or "indep", 2 or "nativegates", 3 or "mapped"
  • circuit_size: for most of the cases this is equal to number of qubits (all scalable benchmarks except "qwalk-v-chain" and "grover-v-chain") while for all other the qubit number is higher
  • compiler: "qiskit" or "tket"
  • compiler_settings: Optimization level for "qiskit" (0-3), placement for "tket" (lineplacement or graphplacement), exemplary shown:
from mqt.bench import CompilerSettings, QiskitSettings, TKETSettings

compiler_settings = CompilerSettings(
    qiskit=QiskitSettings(optimization_level=1),
    tket=TKETSettings(placement="lineplacement"),
)
  • gate_set_name: "ibm", "rigetti", "ionq", "oqc", or "quantinuum"
  • device_name: "ibm_washington", "ibm_montreal", "rigetti_aspen_m2", "ionq_harmony", "ionq_aria1", "oqc_lucy", or "quantinuum_h2"

Hereby, the mappings between shortened benchmark_name and actual benchmarks are:

benchmark_name Actual Benchmark
"ae" Amplitude Estimation (AE)
"dj" Deutsch-Jozsa
"grover-noancilla" Grover's (no ancilla)
"grover-v-chain" Grover's (v-chain)
"ghz" GHZ State
"graphstate" Graph State
"portfolioqaoa" Portfolio Optimization with QAOA
"portfoliovqe" Portfolio Optimization with VQE
"qaoa" Quantum Approximation Optimization Algorithm (QAOA)
"qft" Quantum Fourier Transformation (QFT)
"qftentangled" QFT Entangled
"qnn" Quantum Neural Network (QNN)
"qpeexact" Quantum Phase Estimation (QPE) exact
"qpeinexact" Quantum Phase Estimation (QPE) inexact
"qwalk-noancilla" Quantum Walk (no ancilla)
"qwalk-v-chain" Quantum Walk (v-chain)
"random" Random Quantum Circuit
"realamprandom" Real Amplitudes ansatz with Random Parameters
"su2random" Efficient SU2 ansatz with Random Parameters
"twolocalrandom" Two Local ansatz with Random Parameters
"vqe" Variational Quantum Eigensolver (VQE)
"wstate" W-State
"shor" Shor's
"pricingcall" Pricing Call Option
"pricingput" Pricing Put Option
"groundstate" Ground State
"routing" Routing
"tsp" Travelling Salesman

For example, in order to obtain the 5-qubit Deutsch-Josza benchmark on algorithm level, use the following:

from mqt.bench import get_benchmark

qc = get_benchmark("dj", "alg", 5)

Locally hosting the MQT Bench Viewer

Additionally, this python package includes the same webserver used for the hosting of the MQT Bench webpage.

After the mqt.bench Python package is installed via

(venv) $ pip install mqt.bench

the MQT Bench Viewer can be started from the terminal via

(venv) $ mqt.bench

This first searches for the most recent version of the benchmark files on GitHub and offers to download them. Afterwards, the webserver is started locally.

Usage directly via this repository

For that, the repository must be cloned and installed:

git clone https://github.com/cda-tum/MQTBench.git
cd MQTBench
pip install .

Afterwards, the package can be used as described [above](#Usage via pip package).

References:

In case you are using MQT Bench in your work, we would be thankful if you referred to it by citing the following publication:

@article{quetschlich2023mqtbench,
  title={{{MQT Bench}}: {Benchmarking Software and Design Automation Tools for Quantum Computing}},
  shorttitle = {{MQT Bench}},
  journal = {{Quantum}},
  author={Quetschlich, Nils and Burgholzer, Lukas and Wille, Robert},
  year={2023},
  note={{{MQT Bench}} is available at \url{https://www.cda.cit.tum.de/mqtbench/}},
}

which is also available on arXiv: a

[1] A.Cross et al., OpenQASM 3: A broader and deeper quantum assembly language, arXiv:2104.14722, 2021

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

mqt.bench-1.0.4.tar.gz (4.6 MB view details)

Uploaded Source

Built Distribution

mqt.bench-1.0.4-py3-none-any.whl (4.1 MB view details)

Uploaded Python 3

File details

Details for the file mqt.bench-1.0.4.tar.gz.

File metadata

  • Download URL: mqt.bench-1.0.4.tar.gz
  • Upload date:
  • Size: 4.6 MB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.2 CPython/3.11.5

File hashes

Hashes for mqt.bench-1.0.4.tar.gz
Algorithm Hash digest
SHA256 d87b097e18ee7f8a3c0002fbd2504bd16c5aee099c92e53b168b80c9e0dc7564
MD5 d2d832818977877a5b14c18fec34db87
BLAKE2b-256 3219356979af1f6bf667a509de6ac7d4bf62939bc260c9e330239da6bcd82031

See more details on using hashes here.

File details

Details for the file mqt.bench-1.0.4-py3-none-any.whl.

File metadata

  • Download URL: mqt.bench-1.0.4-py3-none-any.whl
  • Upload date:
  • Size: 4.1 MB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.2 CPython/3.11.5

File hashes

Hashes for mqt.bench-1.0.4-py3-none-any.whl
Algorithm Hash digest
SHA256 65815f92ab80542d5e6dd48e48bafbf464f9eda4f273346aaf5d08c40d1e62bf
MD5 29d47864ccfc86fab7aec610439f6b8e
BLAKE2b-256 6a2ff42ec4819868666e9d550db1436e785b8d088e58844316291ab1d5a0cb07

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page