Skip to main content

A library for creating quantum error correction circuits.

Project description

stimflow: annealed utilities for creating QEC circuits

stimflow is a library for creating quantum error correction circuits.

stimflow's design philosophy is to be a tool box, not a black box. For example, stimflow does not include a make_surface_code method. Instead it provides tools that can be used to more easily create a surface code circuit from scratch. The hope is that these tools then make it easier to create as-yet-unknown constructions in the future.

stimflow decomposes the circuit creation problem into making and combining chunks. A Chunk is a circuit combined with stabilizer flow assertions that the circuit is supposed to satisfy. stimflow provides tools for making chunks (stimflow.ChunkBuilder), verifying chunks (stimflow.Chunk.verify), debugging chunks (stimflow.Chunk.to_html_viewer), and compiling sequences of chunks into a complete final circuit (stimflow.ChunkCompiler).

stimflow also includes functionality for:

  • Transpiling (stimflow.transpile_to_z_basis_interaction_circuit(...))
  • Adding Noise (stimflow.NoiseModel.uniform_depolarizing(p).noisy_circuit(...))
  • Visualizing (stimflow.make_3d_model, stimflow.html_viewer)

Documentation

See stimflow's getting started notebook.

See stimflow's API reference.

Backwards Compatibility Warning

Stimflow does not currently guarantee backwards compatibility. There are parts of the library that do not yet feel like they have converged on the "right" way to do it, and I want to maintain the freedom to fix them later.

Example Usage: Surface Code Circuit

stimflow is not yet provided as a pypi package, so you cannot install it with pip. The installation can be done manually by copying the contents of this directory somewhere into your python path.

The following is python code that emits a surface code circuit.

import stimflow as sf


def make_surface_code(d: int) -> sf.StabilizerCode:
    """Defines the stabilizers and observables of a surface code."""
    tiles = []
    ds = [0, 1, 1j, 1 + 1j]
    for x in range(-1, d):
        for y in range(-1, d):
            m = x + 1j * y
            qs = [m + d for d in ds]
            qs = [q for q in qs
                  if 0 <= q.real < d and 0 <= q.imag < d]
            b = 'XZ'[(x + y) % 2]
            if b == 'X' and x in [-1, d - 1]:
                continue
            if b == 'Z' and y in [-1, d - 1]:
                continue
            tiles.append(sf.Tile(
                data_qubits=qs,
                bases=b,
                measure_qubit=m + 0.5 + 0.5j,
            ))

    patch = sf.Patch(tiles)
    obs_x = sf.PauliMap.from_xs([q for q in patch.data_set if q.real == 0]).with_obs_name('X')
    obs_z = sf.PauliMap.from_zs([q for q in patch.data_set if q.imag == 0]).with_obs_name('Z')
    return sf.StabilizerCode(patch, logicals=[(obs_x, obs_z)])


def make_idle_round(d: int) -> sf.Chunk:
    """Creates a circuit that performs one round of surface code stabilizer measurement."""
    code = make_surface_code(d=d)
    builder = sf.ChunkBuilder(allowed_qubits=code.used_set)
    mxs = [tile.measure_qubit for tile in code.tiles if tile.basis == 'X']
    mzs = [tile.measure_qubit for tile in code.tiles if tile.basis == 'Z']

    # Prepare measure qubits.
    builder.append("RX", mxs)
    builder.append("RZ", mzs)
    builder.append("TICK")

    # Perform entangling gates.
    dxs = [-0.5 - 0.5j, 0.5 - 0.5j, -0.5 + 0.5j, 0.5 + 0.5j]
    dzs = [dxs[0], dxs[2], dxs[1], dxs[3]]
    for k in range(4):
        builder.append(
            'CX',
            [(m, m + dxs[k]) for m in mxs] + [(m + dzs[k], m) for m in mzs],
            unknown_qubit_append_mode='skip',
        )
        builder.append("TICK")

    # Measure the measure qubits.
    builder.append("MX", mxs)
    builder.append("MZ", mzs)

    # Assert the circuit should be preparing and measuring the stabilizers.
    for tile in code.tiles:
        builder.add_flow(start=tile, measurements=[tile.measure_qubit])
        builder.add_flow(end=tile, measurements=[tile.measure_qubit])
    # Assert the circuit should be preserving the logical operators.
    for obs in code.flat_logicals:
        builder.add_flow(start=obs, end=obs)

    return builder.finish_chunk()


def main():
    # Create the code, verify its commutation relationships, and save a picture of it.
    code = make_surface_code(d=7)
    code.verify()
    code.to_svg().write_to('tmp.svg')

    # Create the circuit cycle, verify its operation, and create an interactive viewer.
    chunk = make_idle_round(d=7)
    chunk.to_html_viewer(background=code).write_to('tmp.html')
    chunk.verify()

    # Compile a physical memory experiment with alternating cycle orderings.
    compiler = sf.ChunkCompiler()
    compiler.append(code.transversal_init_chunk(basis='X'))
    compiler.append(sf.ChunkLoop(
        [chunk, chunk.time_reversed()],
        repetitions=5,
    ))
    compiler.append(code.transversal_measure_chunk(basis='X'))
    circuit = compiler.finish_circuit()

    # Add noise to the circuit, check its distance, and make another viewer.
    noisy_circuit = sf.NoiseModel.uniform_depolarizing(1e-3).noisy_circuit(circuit)
    distance = len(noisy_circuit.shortest_graphlike_error())
    assert distance == 7
    sf.html_viewer(noisy_circuit, background=code).write_to('tmp2.html')


if __name__ == "__main__":
    main()

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

stimflow-1.17.dev1782536076.tar.gz (243.8 kB view details)

Uploaded Source

File details

Details for the file stimflow-1.17.dev1782536076.tar.gz.

File metadata

  • Download URL: stimflow-1.17.dev1782536076.tar.gz
  • Upload date:
  • Size: 243.8 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.1.0 CPython/3.12.9

File hashes

Hashes for stimflow-1.17.dev1782536076.tar.gz
Algorithm Hash digest
SHA256 55d1e787eaf3192e74cc970c8905d6396e68dda7c2d743a7c68da0ab63e14f96
MD5 137475cd6d84b1dee74d7d7bc69c8fd5
BLAKE2b-256 f4ad3fa4c08ed07bb840618d38c157e1c2c52c6f8e1941ea2686f50aa9adaf5c

See more details on using hashes here.

Supported by

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