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* add files associated with lre scaling * change docstring for zne/layer_scaling * num layers without measurements * add scale factor vectors required for multivariate extrapolation * all private functions required for lre * lre noise scaling only for cirq circuits * mypy * change import cirq to from cirq import * make num_chunks optional * error message: degree and fold_multiplier * init + apidoc * docstring * vincent's feedback: quick fixes * add admonition * decorator * undo decorator * cleanup * alessandro's feedback: check for negative num_chunks, tests for chunking function, enumerate * add raises error details to the docstrings * alessandro's feedback * alessandro's feedback - get rid of expected_chunks * vincent's comments: cleanup docstrings
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# Copyright (C) Unitary Fund | ||
# | ||
# This source code is licensed under the GPL license (v3) found in the | ||
# LICENSE file in the root directory of this source tree. | ||
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"""Methods for scaling noise in circuits by layers and using multivariate extrapolation.""" | ||
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from mitiq.lre.multivariate_scaling.layerwise_folding import multivariate_layer_scaling |
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# Copyright (C) Unitary Fund | ||
# | ||
# This source code is licensed under the GPL license (v3) found in the | ||
# LICENSE file in the root directory of this source tree. | ||
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"""Functions for layerwise folding of input circuits to allow for multivariate | ||
extrapolation as defined in :cite:`Russo_2024_LRE`. | ||
""" | ||
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import itertools | ||
from copy import deepcopy | ||
from typing import Any, Callable, List, Optional, Tuple | ||
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import numpy as np | ||
from cirq import Circuit | ||
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from mitiq import QPROGRAM | ||
from mitiq.utils import _append_measurements, _pop_measurements | ||
from mitiq.zne.scaling import fold_gates_at_random | ||
from mitiq.zne.scaling.folding import _check_foldable | ||
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def _get_num_layers_without_measurements(input_circuit: Circuit) -> int: | ||
"""Checks if the circuit has non-terminal measurements and returns the | ||
number of layers in the input circuit without the terminal measurements. | ||
Args: | ||
input_circuit: Circuit of interest. | ||
Returns: | ||
num_layers: the number of layers in the input circuit without the | ||
terminal measurements. | ||
""" | ||
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_check_foldable(input_circuit) | ||
circuit = deepcopy(input_circuit) | ||
_pop_measurements(circuit) | ||
return len(circuit) | ||
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def _get_chunks( | ||
input_circuit: Circuit, num_chunks: Optional[int] = None | ||
) -> List[Circuit]: | ||
"""Splits a circuit into approximately equal chunks. | ||
Adapted from: | ||
https://stackoverflow.com/questions/2130016/splitting-a-list-into-n-parts-of-approximately-equal-length | ||
Args: | ||
input_circuit: Circuit of interest. | ||
num_chunks: Number of desired approximately equal chunks, | ||
* when num_chunks == num_layers, the original circuit is | ||
returned. | ||
* when num_chunks == 1, the entire circuit is chunked into 1 | ||
layer. | ||
Returns: | ||
split_circuit: Circuit of interest split into approximately equal | ||
chunks. | ||
Raises: | ||
ValueError: | ||
When the number of chunks for the input circuit is larger than | ||
the number of layers in the input circuit. | ||
ValueError: | ||
When the number of chunks is less than 1. | ||
""" | ||
num_layers = _get_num_layers_without_measurements(input_circuit) | ||
if num_chunks is None: | ||
num_chunks = num_layers | ||
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if num_chunks < 1: | ||
raise ValueError( | ||
"Number of chunks should be greater than or equal to 1." | ||
) | ||
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if num_chunks > num_layers: | ||
raise ValueError( | ||
f"Number of chunks {num_chunks} cannot be greater than the number" | ||
f" of layers {num_layers}." | ||
) | ||
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k, m = divmod(num_layers, num_chunks) | ||
return [ | ||
input_circuit[i * k + min(i, m) : (i + 1) * k + min(i + 1, m)] | ||
for i in range(num_chunks) | ||
] | ||
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def _get_scale_factor_vectors( | ||
input_circuit: Circuit, | ||
degree: int, | ||
fold_multiplier: int, | ||
num_chunks: Optional[int] = None, | ||
) -> List[Tuple[Any, ...]]: | ||
"""Returns the patterned scale factor vectors required for multivariate | ||
extrapolation. | ||
Args: | ||
input_circuit: Circuit to be scaled. | ||
degree: Degree of the multivariate polynomial. | ||
fold_multiplier: Scaling gap required by unitary folding. | ||
num_chunks: Number of desired approximately equal chunks. | ||
Returns: | ||
scale_factor_vectors: A vector of scale factors where each | ||
component in the vector corresponds to the layer in the input | ||
circuit. | ||
""" | ||
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circuit_chunks = _get_chunks(input_circuit, num_chunks) | ||
num_layers = len(circuit_chunks) | ||
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# Find the exponents of all the monomial terms required for the folding | ||
# pattern. | ||
pattern_full = [] | ||
for i in range(degree + 1): | ||
for j in itertools.combinations_with_replacement(range(num_layers), i): | ||
pattern = np.zeros(num_layers, dtype=int) | ||
# Get the monomial terms in graded lexicographic order. | ||
for index in j: | ||
pattern[index] += 1 | ||
# Use the fold multiplier on the folding pattern to determine which | ||
# layers will be scaled. | ||
pattern_full.append(tuple(fold_multiplier * pattern)) | ||
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# Get the scale factor vectors. | ||
# The layers are scaled as 2n+1 due to unitary folding. | ||
return [ | ||
tuple(2 * num_folds + 1 for num_folds in pattern) | ||
for pattern in pattern_full | ||
] | ||
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def multivariate_layer_scaling( | ||
input_circuit: Circuit, | ||
degree: int, | ||
fold_multiplier: int, | ||
num_chunks: Optional[int] = None, | ||
folding_method: Callable[ | ||
[QPROGRAM, float], QPROGRAM | ||
] = fold_gates_at_random, | ||
) -> List[Circuit]: | ||
r""" | ||
Defines the noise scaling function required for Layerwise Richardson | ||
Extrapolation as defined in :cite:`Russo_2024_LRE`. | ||
Note that this method only works for the multivariate extrapolation | ||
methods. It does not allows a user to choose which layers in the input | ||
circuit will be scaled. | ||
.. seealso:: | ||
If you would prefer to choose the layers for unitary | ||
folding, use :func:`mitiq.zne.scaling.layer_scaling.get_layer_folding` | ||
instead. | ||
Args: | ||
input_circuit: Circuit to be scaled. | ||
degree: Degree of the multivariate polynomial. | ||
fold_multiplier: Scaling gap required by unitary folding. | ||
num_chunks: Number of desired approximately equal chunks. When the | ||
number of chunks is the same as the layers in the input circuit, | ||
the input circuit is unchanged. | ||
folding_method: Unitary folding method. Default is | ||
:func:`fold_gates_at_random`. | ||
Returns: | ||
Multiple folded variations of the input circuit. | ||
Raises: | ||
ValueError: | ||
When the degree for the multinomial is not greater than or | ||
equal to 1; when the fold multiplier to scale the circuit is | ||
greater than/equal to 1; when the number of chunks for a | ||
large circuit is 0 or when the number of chunks in a circuit is | ||
greater than the number of layers in the input circuit. | ||
""" | ||
if degree < 1: | ||
raise ValueError( | ||
"Multinomial degree must be greater than or equal to 1." | ||
) | ||
if fold_multiplier < 1: | ||
raise ValueError("Fold multiplier must be greater than or equal to 1.") | ||
circuit_copy = deepcopy(input_circuit) | ||
terminal_measurements = _pop_measurements(circuit_copy) | ||
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scaling_pattern = _get_scale_factor_vectors( | ||
circuit_copy, degree, fold_multiplier, num_chunks | ||
) | ||
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chunks = _get_chunks(circuit_copy, num_chunks) | ||
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multiple_folded_circuits = [] | ||
for scale_factor_vector in scaling_pattern: | ||
folded_circuit = Circuit() | ||
for chunk, scale_factor in zip(chunks, scale_factor_vector): | ||
if scale_factor == 1: | ||
folded_circuit += chunk | ||
else: | ||
chunks_circ = Circuit(chunk) | ||
folded_chunk_circ = folding_method(chunks_circ, scale_factor) | ||
folded_circuit += folded_chunk_circ | ||
_append_measurements(folded_circuit, terminal_measurements) | ||
multiple_folded_circuits.append(folded_circuit) | ||
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return multiple_folded_circuits |
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