Strawberry Fields is a full-stack Python library for designing, simulating, and optimizing continuous variable (CV) quantum optical circuits.
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Post release to address changes to the documentation.
Published by josh146 over 2 years ago
Program Xanadu’s new Borealis hardware device via Strawberry Fields and Xanadu Cloud. (#714)
Borealis is a cloud-accessible photonic quantum computer, offering full programmability over all of its gates and capable of quantum advantage. Its hardware is based on time-domain multiplexing (TDM); a single squeezed-light source emits batches of 216 time-ordered squeezed-light pulses that interfere with one another with the help of optical delay loops, programmable beamsplitters, and phase shifters.
GBS data visualization functions are added. (#714)
A set of TDM compilers are added, including a Borealis compiler which compiles and validates programs against the hardware specification and calibration certificate. (#714)
A remove_loss
utility function is added to the program_utils
module, allowing for the removal of LossChannels
from Strawberry Fields programs. (#714)
Cropping vacuum modes from TDM program results is now possible by passing crop=True
as a run option. (#714)
n, N = get_mode_indices(delays)
prog = sf.TDMProgram(N)
with prog.context(*gate_args) as (p, q):
ops.Sgate(p[0]) | q[n[0]]
for i in range(len(delays)):
ops.Rgate(p[2 * i + 1]) | q[n[i]]
ops.BSgate(p[2 * i + 2], np.pi / 2) | (q[n[i + 1]], q[n[i]])
ops.MeasureX | q[0]
eng = sf.Engine("gaussian")
results = eng.run(prog, crop=True)
Resulting samples from TDM jobs return only the non-empty mode measurements when setting the crop
option to True
in the program run_options
or as a keyword argument in the engine run
method. (#714)
Realistic loss can be added to a Borealis circuit for local simulation execution. (#714)
compile_options = {
"device": device, # hardware device object needed
"realistic_loss": True,
}
eng = sf.Engine("gaussian")
results = eng.run(prog, compile_options=compile_options)
Utility functions are added to allow for easier Borealis program and parameter creation. (#714)
Functions are added for analyzing GBS results for comparisons with classical simulations. (#714)
A locked program can now be (un)rolled, and automatically restores the lock if previously in place. (#703)
Rolling and unrolling now only happens in place, and no longer returns the (un)rolled circuit. (#702)
Program.assert_number_of_modes
and Program.assert_max_number_of_measurements
are combined into a single assert_modes
method. (#709)
Job results can now be retrieved without converting integers to np.int64
objects by setting integer_overflow_protection=False
(default True
) when running a program via RemoteEngine.run()
. (#712)
The TDM module is refactored to contain program.py
, with the TDMProgram
class, and utils.py
, with various utility functions. (#714)
The Compiler
base class is updated to allow for setting a rigid circuit layout to validate a program during compilation. (#714)
The Compiler
base class now contains methods that can be overwritten to provide subclass compilers with loss-additions (e.g., to add realistic loss to a circuit) and program parameter updates. (#714)
Trying to unroll an already unrolled program with a different number of shots works as expected. (#702)
Fixed bug with vacuum modes missing. (#702)
Validating parameters now works with nested parameter arrays. (#711)
Store correct rolled circuit before unrolling (fixes issue when rolled circuit has changed due to e.g., compilation). (#710)
The centralized Xanadu Sphinx Theme is now used to style the Sphinx documentation. (#701)
The documentation on Gaussian circuit operations is fixed so that it's properly rendered. (#714)
This release contains contributions from (in alphabetical order):
Mikhail Andrenkov, Sebastian Duque, Luke Helt, Theodor Isacsson, Josh Izaac, Fabian Laudenbach
Published by thisac over 2 years ago
Device.layout
and Device.gate_parameters
may now return None
. This can happen when a remote simulator device is used. (#661)
A new interferometer decomposition method is implemented following the proposal of the paper Simple factorization of unitary transformations. (#665)
import numpy as np
import strawberryfields as sf
from strawberryfields import ops
U = np.array([[-0.39302099+0.28732291j, 0.83734522+0.24866248j],
[ 0.00769051+0.87345344j, -0.3847068 +0.29836325j]])
prog = sf.Program(2)
with prog.context as q:
ops.Interferometer(U, mesh="sun_compact") | q
A Device.certificate
method is added which returns the hardware device certificate. (#679)
>>> import strawberryfields as sf
>>> eng = sf.RemoteEngine("X8")
>>> print(eng.device.certificate)
{'target': 'X8_01' ... }
Setting shots=None
in the engine or program run options will not execute any measurements applied on the circuit. (#682)
import strawberryfields as sf
from strawberryfields import ops
prog = sf.Program(1)
eng = sf.Engine("gaussian")
with prog.context as q:
ops.Sgate(0.5) | q[0]
ops.MeasureFock() | q
results = eng.run(prog, shots=None)
# samples will output an empty list []
print(results.samples)
# the resulting Gaussian state is still accessible
# via its vector of means and covariance matrix
print(results.state.means())
print(results.state.cov())
There's a program_equivalence
function in strawberryfields/program_utils.py
which checks Strawberry Fields programs for equivalence. (#686)
An equality operator is implemented for strawberryfields.Program
, checking that the exact same gates and respective parameters, are applied in order. (#686)
import strawberryfields as sf
from strawberryfields import ops
prog_1 = sf.Program(1)
prog_2 = sf.Program(1)
with prog.context as q:
ops.Sgate(0.42) | q[0]
ops.MeasureFock() | q
with prog.context as q:
ops.Sgate(0.42) | q[0]
ops.MeasureFock() | q
assert prog_1 == prog_2
A Program.equivalence
convenience method is added which calls the program_equivalence
utility function. (#686)
prog_1 = sf.Program(1)
prog_2 = sf.Program(1)
with prog.context as q:
ops.Sgate(1.1) | q[0]
ops.MeasureFock() | q
with prog.context as q:
ops.Sgate(0.42) | q[0]
ops.MeasureFock() | q
assert prog_1.equivalence(prog_2, compare_params=False)
A Device.validate_target
static method is added which checks that the target in the layout is the same as the target field in the specification. This check is also performed at Device
initialization. (#687)
Tests are run in random order and the seed for NumPy's and Python's random number generators are set by pytest-randomly
. (#692)
Adds support for Python 3.10. #695
DeviceSpec
is renamed to Device
, which now also contains more than only the device specification. (#679)
>>> import strawberryfields as sf
>>> eng = sf.RemoteEngine("X8")
>>> isinstance(eng.device, sf.Device)
True
>>> print(eng.device.target)
X8_01
It's now possible to show graphs using the plot apps layer when not run in notebooks. (#669)
program.compile
now raises an error if the device specification contains gate parameters but no circuit layout. Without a layout, the gate parameters cannot be validated against the device specification. (#661)
The teleportation tutorial examples/teleportation.py
now uses the correct value (now phi = 0
instead of phi = np.pi / 2
) for the phase shift of the beamsplitters. (#674)
Program.compile()
returns a deep copy of the program attributes, except for the circuit and the register references. (#688)
This release contains contributions from (in alphabetical order):
Sebastian Duque, Theodor Isacsson, Jon Schlipf, Hossein Seifoory
Published by thisac almost 3 years ago
A Result.metadata
property is added to retrieve the metadata of a job result. (#663)
A setter method for Result.state
is added for setting a state for a local simulation if a state has not previously been set. (#663)
Functions are now available to convert between XIR and Strawberry Fields programs. (#643)
For example,
prog = sf.Program(3)
eng = sf.Engine("gaussian")
with prog.context as q:
ops.Sgate(0, 0) | q[0]
ops.Sgate(1, 0) | q[1]
ops.BSgate(0.45, 0.0) | (q[0], q[2])
ops.MeasureFock() | q[0]
xir_prog = sf.io.to_xir(prog)
resulting in the following XIR script
>>> print(xir_prog.serialize())
Sgate(0, 0) | [0];
Sgate(1, 0) | [1];
BSgate(0.45, 0.0) | [0, 2];
MeasureFock | [0];
The TDMProgram.compile_info
and TDMProgram.target
fields are now set when a TDMProgram
is compiled using the "TDM" compiler. (#659)
Updates Program.assert_max_number_of_measurements
to expect the maximum number of measurements from the device specification as a flat dictionary entry instead of a nested one. (#662)
"modes": {
"pnr_max": 20,
"homodyne_max": 1000,
"heterodyne_max": 1000,
}
instead of
"modes": {
"max": {
"pnr": 20,
"homodyne": 1000,
"heterodyne": 1000,
}
}
This release contains contributions from (in alphabetical order):
Theodor Isacsson
Published by thisac almost 3 years ago
The generic multimode Gaussian gate Ggate
is now available in the sf.ops
module with the backend choice of tf
. The N mode Ggate
can be parametrized by a real symplectic matrix S
(size 2N * 2N
) and a diplacement vector d
(size N
). You can also obtain the gradients of the Ggate gate via TensorFlow's tape.gradient
(#599) (#606)
from thewalrus.random import random_symplectic
num_mode = 2
cutoff = 10
S = tf.Variable(random_symplectic(num_mode))
d = tf.Variable(np.random.random(2 * num_mode))
eng = sf.Engine("tf", backend_options={"cutoff_dim": cutoff})
prog = sf.Program(2)
with prog.context as q:
sf.ops.Ggate(S, d) | (q[0], q[1])
state_out = eng.run(prog).state.ket()
Note that in order to update the parameter S
by using its gradient, you cannot use gradient descent directly (as the unitary would not be symplectic after the update). Please use the function sf.backends.tfbackend.update_symplectic
which is designed specifically for this purpose.
def overlap_loss(state, objective):
return -tf.abs(tf.reduce_sum(tf.math.conj(state) * objective)) ** 2
def norm_loss(state):
return -tf.abs(tf.linalg.norm(state)) ** 2
def loss(state, objective):
return overlap_loss(state, objective) + norm_loss(state)
num_mode = 1
cutoff = 10
S = tf.Variable(random_symplectic(num_mode))
d = tf.Variable(np.random.random(2 * num_mode))
kappa = tf.Variable(0.3)
objective = tf.Variable(np.eye(cutoff)[1], dtype=tf.complex64)
adam = tf.keras.optimizers.Adam(learning_rate=0.01)
eng = sf.Engine("tf", backend_options={"cutoff_dim": cutoff})
prog = sf.Program(1)
with prog.context as q:
sf.ops.Ggate(S, d) | q
sf.ops.Kgate(kappa) | q
loss_vals = []
for _ in range(200):
with tf.GradientTape() as tape:
state_out = eng.run(prog).state.ket()
loss_val = loss(state_out, objective)
eng.reset()
grad_S, gradients_d, gradients_kappa = tape.gradient(loss_val, [S, d, kappa])
adam.apply_gradients(zip([gradients_d, gradients_kappa], [d, kappa]))
update_symplectic(S, grad_S, lr=0.1) # update S here
loss_vals.append(loss_val)
Complex parameters of the Catstate
operation are expected in polar form as two separate real parameters. (#441)
The sf
CLI has been removed in favour of the Xanadu Cloud Client. (#642)
Configuring account credentials using:
Strawberry Fields v0.19.0
$ sf configure --token "foo"
Strawberry Fields v0.20.0
$ xcc config set REFRESH_TOKEN "foo"
Successfully updated REFRESH_TOKEN setting to 'foo'.
Verifying your connection to the Xanadu Cloud using:
Strawberry Fields v0.19.0
$ sf --ping
You have successfully authenticated to the platform!
Strawberry Fields v0.20.0
$ xcc ping
Successfully connected to the Xanadu Cloud.
Submitting a Blackbird circuit to the Xanadu Cloud using:
Strawberry Fields v0.19.0
$ # Version 0.19.0
$ sf run "foo.xbb"
Executing program on remote hardware...
2021-11-02 03:04:05,06 - INFO - The device spec X8_01 has been successfully retrieved.
2021-11-02 03:04:05,07 - INFO - Compiling program for device X8_01 using compiler Xunitary.
2021-11-02 03:04:05,08 - INFO - Job b185a63c-f302-4adb-acf8-b6e4e413c11d was successfully submitted.
2021-11-02 03:04:05,09 - INFO - The remote job b185a63c-f302-4adb-acf8-b6e4e413c11d has been completed.
[[0 0 0 0]
[0 0 0 0]
[0 0 0 0]
[0 0 0 0]]
Strawberry Fields v0.20.0
$ xcc job submit --name "bar" --target "X8_01" --circuit "$(cat foo.xbb)"
{
"id": "0b0f5a46-46d8-4157-8005-45a4764361ba", # Use this ID below.
"name": "bar",
"status": "open",
"target": "X8_01",
"language": "blackbird:1.0",
"created_at": "2021-11-02 03:04:05,10",
"finished_at": null,
"running_time": null,
"metadata": {}
}
$ xcc job get 0b0f5a46-46d8-4157-8005-45a4764361ba --result
{
"output": [
"[[0 0 0 0]\n[0 0 0 0]\n[0 0 0 0]\n[0 0 0 0]]"
]
}
The sf.api.Connection
class has been replaced with the xcc.Connection class. (#645)
Previously, in Strawberry Fields v0.19.0, an sf.RemoteEngine
can be instantiated with a custom Xanadu Cloud connection as follows:
import strawberryfields as sf
import strawberryfields.api
connection = strawberryfields.api.Connection(
token="Xanadu Cloud API key goes here",
host="platform.strawberryfields.ai",
port=443,
use_ssl=True,
)
engine = sf.RemoteEngine("X8", connection=connection)
In Strawberry Fields v0.20.0, the same result can be achieved using
import strawberryfields as sf
import xcc
connection = xcc.Connection(
refresh_token="Xanadu Cloud API key goes here", # See "token" argument above.
host="platform.strawberryfields.ai",
port=443,
tls=True, # See "use_ssl" argument above.
)
engine = sf.RemoteEngine("X8", connection=connection)
The sf.configuration
module has been replaced with the xcc.Settings class. (#649)
This means that Xanadu Cloud credentials are now stored in exactly one location, the path to which depends on your operating system:
Windows: C:\Users\%USERNAME%\AppData\Local\Xanadu\xanadu-cloud\.env
MacOS: /home/$USER/Library/Application\ Support/xanadu-cloud/.env
Linux: /home/$USER/.config/xanadu-cloud/.env
The format of the configuration file has also changed to .env and the names of some fields have been updated. For example,
# Strawberry Fields v0.19.0 (config.toml)
[api]
authentication_token = "Xanadu Cloud API key goes here"
hostname = "platform.strawberryfields.ai"
port = 443
use_ssl = true
is equivalent to
# Strawberry Fields v0.20.0 (.env)
XANADU_CLOUD_REFRESH_TOKEN='Xanadu Cloud API key goes here'
XANADU_CLOUD_HOST='platform.strawberryfields.ai'
XANADU_CLOUD_PORT=443
XANADU_CLOUD_TLS=True
Similarly, the names of the configuration environment variables have changed from
# Strawberry Fields v0.19.0
export SF_API_AUTHENTICATION_TOKEN="Xanadu Cloud API key goes here"
export SF_API_HOSTNAME="platform.strawberryfields.ai"
export SF_API_PORT=443
export SF_API_USE_SSL=true
to
# Strawberry Fields v0.20.0
export XANADU_CLOUD_REFRESH_TOKEN="Xanadu Cloud API key goes here"
export XANADU_CLOUD_HOST="platform.strawberryfields.ai"
export XANADU_CLOUD_PORT=443
export XANADU_CLOUD_TLS=true
Finally, strawberryfields.store_account()
has been replaced such that
# Strawberry Fields v0.19.0
import strawberryfields as sf
sf.store_account("Xanadu Cloud API key goes here")
becomes
# Strawberry Fields v0.20.0
import xcc
xcc.Settings(REFRESH_TOKEN="Xanadu Cloud API key goes here").save()
The sf.api.Job
class has been replaced with the xcc.Job class. (#650)
A Job
object is returned when running jobs asynchronously. In previous versions of Strawberry Fields (v0.19.0 and lower), the Job
object can be used as follows:
>>> job = engine.run_async(program, shots=1)
>>> job.status
'queued'
>>> job.result
InvalidJobOperationError
>>> job.refresh()
>>> job.status
'complete'
>>> job.result
[[0 1 0 2 1 0 0 0]]
In Strawberry Fields v0.20.0, the Job
object works slightly differently:
>>> job = engine.run_async(program, shots=1)
>>> job.status
'queued'
>>> job.wait()
>>> job.status
'complete'
>>> job.result
{'output': [array([[0 1 0 2 1 0 0 0]])]}
The job.wait()
method is a blocking method that will wait for the job to finish. Alternatively, job.clear()
can be called to clear the cache, allowing job.status
to re-fetch the job status.
The sf.api.Result
class has been updated to support the Xanadu Cloud Client integration. (#651)
While Result.samples
should return the same type and shape as before, the Result.all_samples
property has been renamed to Result.samples_dict
and returns the samples as a dictionary with corresponding measured modes as keys.
>>> res = eng.run(prog, shots=3)
>>> res.samples
array([[1, 0], [0, 1], [1, 1]])
>>> res.samples_dict
{0: [np.array([1, 0, 1])], 1: [np.array([0, 1, 1])]}
The samples dictionary is only accessible for simulators.
The sf.api.DeviceSpec
class has been updated to support the Xanadu Cloud Client integration. (#644)
It now works as a container for a device specification dictionary. There are no more API connection usages, and DeviceSpec.target
is retrieved from the device specification rather than passed at initialization.
The api
subpackage has been removed and the contained DeviceSpec
and Result
classes have been moved to the root strawberryfields
folder. (#652)
They can now be imported as follows:
import strawberryfields as sf
# sf.DeviceSpec
# sf.Result
This release contains contributions from (in alphabetical order):
Mikhail Andrenkov, Sebastián Duque Mesa, Theodor Isacsson, Josh Izaac, Filippo Miatto, Nicolás Quesada, Antal Száva, Yuan Yao.
Published by thisac about 3 years ago
Compact decompositions as described in https://arxiv.org/abs/2104.07561, (rectangular_compact
and triangular_compact
) are now available in the sf.decompositions
module, and as options in the Interferometer
operation. (#584)
This decomposition allows for lower depth photonic circuits in physical devices by applying two independent phase shifts in parallel inside each Mach-Zehnder interferometer. rectangular_compact
reduces the layers of phase shifters from 2N+1 to N+2 for an N mode interferometer when compared to e.g. rectangular_MZ
.
Example:
import numpy as np
from strawberryfields import Program
from strawberryfields.ops import Interferometer
from scipy.stats import unitary_group
M = 10
# generate a 10x10 Haar random unitary
U = unitary_group.rvs(M)
prog = Program(M)
with prog.context as q:
Interferometer(U, mesh='rectangular_compact') | q
# check that applied unitary is correct
compiled_circuit = prog.compile(compiler="gaussian_unitary")
commands = compiled_circuit.circuit
S = commands[0].op.p[0] # symplectic transformation
Uout = S[:M,:M] + 1j * S[M:,:M] # unitary transformation
print(np.allclose(U, Uout))
A new compiler, GaussianMerge
, has been added. It is aimed at reducing calculation overhead for non-Gaussian circuits by minimizing the amount of Gaussian operations in a circuit, while retaining the same functionality. (#591)
GaussianMerge
merges Gaussian operations, where allowed, into GaussianTransform
and Dgate
operations. It utilizes the existing GaussianUnitary
compiler to merge operations and Directed Acyclic Graphs to determine which operations can be merged.
modes = 4
cutoff_dim = 6
# prepare an intial state with 4 photons in as many modes
initial_state = np.zeros([cutoff_dim] * modes, dtype=complex)
initial_state[1, 1, 1, 1] = 1
prog = sf.Program(4)
with prog.context as q:
ops.Ket(initial_state) | q # Initial state preparation
# Gaussian Layer
ops.S2gate(0.01, 0.01) | (q[0], q[1])
ops.BSgate(1.9, 1.7) | (q[1], q[2])
ops.BSgate(0.9, 0.2) | (q[0], q[1])
# Non-Gaussian Layer
ops.Kgate(0.5) | q[3]
ops.CKgate(0.7) | (q[2], q[3])
# Gaussian Layer
ops.BSgate(1.0, 0.4) | (q[0], q[1])
ops.BSgate(2.0, 1.5) | (q[1], q[2])
ops.Dgate(0.01) | q[0]
ops.Dgate(0.01) | q[0]
ops.Sgate(0.01, 0.01) | q[1]
# Non-Gaussian Layer
ops.Vgate(0.5) | q[2]
prog_merged = prog.compile(compiler="gaussian_merge")
A new operation, PassiveChannel
has been added. It allows for arbitrary linear/passive transformations (i.e., any operation which is linear in creation operators). Currently only supported by the gaussian
backend. (#600)
from strawberryfields.ops import PassiveChannel, Sgate
import strawberryfields as sf
from scipy.stats import unitary_group
import numpy as np
M = 4
circuit = sf.Program(M)
U1 = unitary_group.rvs(M)
U2 = unitary_group.rvs(M)
losses = np.random.random(M)
T = U2 @ np.diag(losses) @ U1
eng = sf.Engine(backend='gaussian')
circuit = sf.Program(M)
with circuit.context as q:
for i in range(M):
ops.Sgate(1) | q[i]
ops.PassiveChannel(T) | q
cov = eng.run(circuit).state.cov()
A new compiler, passive
, allows for a circuit which only consists of passive elements to be compiled into a single PassiveChannel
. (#600)
from strawberryfields.ops import BSgate, LossChannel, Rgate
import strawberryfields as sf
circuit = sf.Program(2)
with circuit.context as q:
Rgate(np.pi) | q[0]
BSgate(0.25 * np.pi, 0) | (q[0], q[1])
LossChannel(0.9) | q[1]
compiled_circuit = circuit.compile(compiler="passive")
>>> print(compiled_circuit)
PassiveChannel([[-0.7071+8.6596e-17j -0.7071+0.0000e+00j]
[-0.6708+8.2152e-17j 0.6708+0.0000e+00j]]) | (q[0], q[1])
backends/tfbackend/ops.py
is cleaned up to reduce line count, clarify function similarity across backend ops, and replace tensorflow.tensordot
with broadcasting. (#567)
Support is added for using a TDMProgram
to construct time-domain circuits with Fock measurements and multiple loops. (#601)
measure_threshold
in the gaussian
backend now supports displaced Gaussian states. (#615)
Speed improvements are addded to gaussian_unitary
compiler. (#603)
Adds native support in the Fock backend for the MZgate. (#610)
measure_threshold
is now supported in the bosonic
backend. (#618)
Fixes an unexpected behaviour that can result in increasing memory usage due to sympy.lambdify
caching too much data using linecache
. (#579)
Keeps symbolic expressions when converting a Strawberry Fields circuit to a Blackbird program by storing them as blackbird.RegRefTransforms
in the resulting Blackbird program. (#596)
Fixes a bug in the validation step of strawberryfields.tdm.TdmProgram.compile
which almost always used the wrong set of allowed gate parameter ranges to validate the parameters in a program. (#605)
The correct samples are now returned when running a TDMProgram
with several shots, where timebins % concurrent_modes != 0
. (#611)
Fixes the formula used for sampling generaldyne outcomes in the gaussian backend. (#614)
Measurement arguments are now stored as non-keyword arguments, instead of keyword arguments, in the resulting Blackbird program when using the io.to_blackbird()
converter function. (#622)
Factorials of numbers larger than 170 are now calculated using long integer arithmetic, using the flag exact=True
in scipy.special.factorial
, when calling sf.apps.similarity.orbit_cardinality
. (#628)
simulon
simulator target have been rewritten to simulon_gaussian
to reflect changes made on the Xanadu Quantum Cloud. The language has been modified to imply that multiple simulators could be available on XQC. (#576)
This release contains contributions from (in alphabetical order):
J. Eli Bourassa, Jake Bulmer, Sebastian Duque, Theodor Isacsson, Aaron Robertson, Jeremy Swinarton, Antal Száva, Federico Rueda, Yuan Yao.
Published by josh146 over 3 years ago
simulon
simulator target have been rewritten to simulon_gaussian
to reflect changes made on the Xanadu Quantum Cloud. The language has been modified to imply that multiple simulators could be available on XQC. (#576)
This release contains contributions from (in alphabetical order):
Jeremy Swinarton.
Published by josh146 over 3 years ago
Adds the Bosonic backend, which can simulate states represented as linear combinations of Gaussian functions in phase space. (#533) (#538) (#539) (#541) (#546) (#549)
It can be regarded as a generalization of the Gaussian backend, since transformations on states correspond to modifications of the means and
covariances of each Gaussian in the linear combination, along with changes to the coefficients of the linear combination. Example states that can be expressed using the new backend include all Gaussian, Gottesman-Kitaev-Preskill,
cat and Fock states.
prog = sf.Program(1)
eng = sf.Engine('bosonic')
with prog.context as q:
sf.ops.GKP(epsilon=0.1) | q
sf.ops.MeasureX | q
results = eng.run(prog, shots=200)
samples = results.samples[:, 0]
plt.hist(samples, bins=100)
plt.show()
Adds the sf.ops.GKP
operation, which allows the Gottesman-Kitaev-Preskill state to be initialized on both the Bosonic and Fock backends. (#553) (#546)
GKP states are qubits, with the qubit state defined by:
where the computational basis states are
Adds the measurement-based squeezing gate MSgate
; a new front-end operation for the Bosonic backend. (#538) (#539) (#541)
MSgate
is an implementation of inline squeezing that can be performed by interacting the target state with an ancillary squeezed vacuum state at a beamsplitter, measuring the ancillary mode with homodyne, and then applying a feed-forward displacement. The channel is implemented either on average (as a Gaussian CPTP map) or in the single-shot implementation. If the single-shot implementation is used, the measurement outcome of the ancillary mode is stored in the results object.
prog = sf.Program(1)
eng = sf.Engine('bosonic')
with prog.context as q:
sf.ops.Catstate(alpha=2) | q
r = 0.3
# Average map
sf.ops.MSgate(r, phi=0, r_anc=1.2, eta_anc=1, avg=True) | q
# Single-shot map
sf.ops.MSgate(r, phi=0, r_anc=1.2, eta_anc=1, avg=False) | q
results = eng.run(prog)
ancilla_samples = results.ancilla_samples
xvec = np.arange(-5, 5, 0.01)
pvec = np.arange(-5, 5, 0.01)
wigner = results.state.wigner(0, xvec, pvec)
plt.contourf(xvec, pvec, wigner)
plt.show()
The tf
backend now accepts the Tensor DType as argument. (#562)
Allows high cutoff dimension to give numerically correct calculations:
prog = sf.Program(2)
eng = sf.Engine("tf", backend_options={"cutoff_dim": 50, "dtype": tf.complex128})
with prog.context as q:
Sgate(0.8) | q[0]
Sgate(0.8) | q[1]
BSgate(0.5,0.5) | (q[0], q[1])
BSgate(0.5,0.5) | (q[0], q[1])
state = eng.run(prog).state
N0, N0var = state.mean_photon(0)
N1, N1var = state.mean_photon(1)
print(N0)
print(N1)
print("analytical:", np.sinh(0.8)**2)
Program compilation has been modified to support the XQC simulation service, Simulon. (#545)
The sympmat
, rotation_matrix
, and haar_measure
functions have been removed from backends/shared_ops.py
. These functions are now imported from The Walrus. In addition, various outdated functionality from the shared_ops.py
file has been removed, including the caching of beamsplitter and squeezing pre-factors. (#560) (#558)
Sample processing in the TDMProgram
is now more efficient, by replacing calls to pop
with fancy indexing. (#548)
No VisibleDeprecationWarning
is raised when using the state wigner
method. (#564)
The backend utility module shared_ops.py
has been removed, with all of its functionality now provided by The Walrus. (#573)
Connection
objects now send requests to the platform API at version 0.2.0
instead of the incorrect version number 1.0.0
. (#540)
TDM programs now expect a flat (not nested) dictionary of modes
in device specifications obtained from the XQC platform API. (#566)
Fixes a bug in the CatState
operation, whereby the operation would return incorrect results for a high cutoff value. (#557) (#556)
The "Hardware" quickstart page has been renamed to "Xanadu Quantum Cloud" to encompass both hardware and cloud simulators. A new "Cloud simulator" entry has been added, describing how to submit programs to be executed via the XQC simulator. (#547)
Cleanup docs to make contribution easier. (#561)
Add development requirements and format script to make contribution easier. (#563)
This release contains contributions from (in alphabetical order):
J. Eli Bourassa, Guillaume Dauphinais, Ish Dhand, Theodor Isacsson, Josh Izaac, Leonhard Neuhaus, Nicolás Quesada, Aaron Robertson, Krishna Kumar Sabapathy, Jeremy Swinarton, Antal Száva, Ilan Tzitrin.
Published by josh146 almost 4 years ago
TDMProgram
objects can now be compiled and submitted via the API. (#476)
Wigner functions can be plotted directly via Strawberry Fields using Plot.ly. (#495)
prog = sf.Program(1)
eng = sf.Engine('fock', backend_options={"cutoff_dim": 10})
with prog.context as q:
gamma = 2
Vgate(gamma) | q[0]
state = eng.run(prog).state
xvec = np.arange(-4, 4, 0.01)
pvec = np.arange(-4, 4, 0.01)
mode = 0
sf.plot_wigner(state, mode, xvec, pvec, renderer="browser")
Fock state marginal probabilities can be plotted directly via Strawberry Fields using Plot.ly. (#510)
prog = sf.Program(1)
eng = sf.Engine('fock', backend_options={"cutoff_dim":5})
with prog.context as q:
Sgate(0.5) | q[0]
state = eng.run(prog).state
state.all_fock_probs()
modes = [0]
sf.plot_fock(state, modes, cutoff=5, renderer="browser")
Position and momentum quadrature probabilities can be plotted directly via Strawberry Fields using Plot.ly. (#510)
prog = sf.Program(1)
eng = sf.Engine('fock', backend_options={"cutoff_dim":5})
with prog.context as q:
Sgate(0.5) | q[0]
state = eng.run(prog).state
modes = [0]
xvec = np.arange(-4, 4, 0.1)
pvec = np.arange(-4, 4, 0.1)
sf.plot_quad(state, modes, xvec, pvec, renderer="browser")
Strawberry Fields code can be generated from a program (and an engine) by calling sf.io.generate_code(program, eng=engine)
. (#496)
Connection
objects now send versioned requests to the platform API. (#512)
TDMProgram
allows application of gates with more than one symbolic parameter. #492
The copies
option, when constructing a TDMProgram
, has been removed. Instead, the number of copies of a TDM algorithm can now be set by passing the shots
keyword argument to the eng.run()
method. (#489)
>>> with prog.context([1, 2], [3, 4]) as (p, q):
... ops.Sgate(0.7, 0) | q[1]
... ops.BSgate(p[0]) | (q[0], q[1])
... ops.MeasureHomodyne(p[1]) | q[0]
>>> eng = sf.Engine("gaussian")
>>> results = eng.run(prog, shots=3)
Furthermore, the TDMProgram.unrolled_circuit
attribute now only contains the single-shot unrolled circuit. Unrolling with multiple shots can still be specified via the unroll
method: TDMProgram.unroll(shots=60)
.
The Result.samples
returned by TDM programs has been updated to return samples of shape (shots, spatial modes, timebins)
instead of (shots, spatial modes * timebins)
. (#489)
A sample post-processing function is added that allows users to move vacuum mode measurements from the first shots to the last shots, and potentially crop out the final shots containing these measurements. (#489)
pytest-randomly
is added to the SF tests. (#480)
TDMProgram
objects can now be serialized into Blackbird scripts, and vice versa. (#476)
Fixes a bug where Dgate
, Coherent
, and DisplacedSqueezed
do not support TensorFlow tensors if the tensor has an added dimension due to the existence of batching. (#507)
Fixes an issue with reshape_samples
where the samples were sometimes reshaped in the wrong way. (#489)
The list of modes is now correctly added to the Blackbird program when using the io.to_blackbird
function. (#476)
Fixes a bug where printing the Result
object containing samples from a time-domain job would result in an error. Printing the result object now correctly displays information about the results. (#493)
Removes the antlr4
requirement due to version conflicts. (#494)
TDMProgram.run_options
is now correctly used when running a TDM program. (#500)
Fixes a bug where a single parameter list passed to the TDMProgram
context results in an error. (#503)
TDMProgram
docstring is updated to make it clear that only Gaussian programs are allowed. (#519)
Clarifies special cases for the MZgate
in the docstring. (#479)
This release contains contributions from (in alphabetical order):
Tom Bromley, Jack Brown, Theodor Isacsson, Josh Izaac, Fabian Laudenbach, Tim Leisti, Nicolas Quesada, Antal Száva.
Published by josh146 almost 4 years ago
Adds the ability to construct time domain multiplexing algorithms via the new sf.TDMProgram
class, for highly scalable simulation of Gaussian states. (#440)
For example, creating and simulating a time domain program with 2 concurrent modes:
>>> import strawberryfields as sf
>>> from strawberryfields import ops
>>> prog = sf.TDMProgram(N=2)
>>> with prog.context([1, 2], [3, 4], copies=3) as (p, q):
... ops.Sgate(0.7, 0) | q[1]
... ops.BSgate(p[0]) | (q[0], q[1])
... ops.MeasureHomodyne(p[1]) | q[0]
>>> eng = sf.Engine("gaussian")
>>> results = eng.run(prog)
>>> print(results.all_samples)
{0: [array([1.26208025]), array([1.53910032]), array([-1.29648336]),
array([0.75743215]), array([-0.17850101]), array([-1.44751996])]}
For more details, see the code documentation.
Adds the function VibronicTransition
to the apps.qchem.vibronic
module. This function generates a custom Strawberry Fields operation for applying the Doktorov operator on a given state. (#451)
>>> from strawberryfields.apps.qchem.vibronic import VibronicTransition
>>> modes = 2
>>> p = sf.Program(modes)
>>> with p.context as q:
... VibronicTransition(U1, r, U2, alpha) | q
Adds the TimeEvolution
function to the apps.qchem.dynamics
module. This function generates a custom Strawberry Fields operation for applying a time evolution operator on a given state. (#455)
>>> modes = 2
>>> p = sf.Program(modes)
>>> with p.context as q:
... sf.ops.Fock(1) | q[0]
... sf.ops.Interferometer(Ul.T) | q
... TimeEvolution(w, t) | q
... sf.ops.Interferometer(Ul) | q
where w
is the normal mode frequencies, and t
the time in femtoseconds.
Molecular data and pre-generated samples for water and pyrrole have been added to the data module of the Applications layer of Strawberry Fields. For more details, please see the data module documentation (#463)
Adds the function read_gamess
to the qchem module to extract the atomic coordinates, atomic masses, vibrational frequencies, and normal modes of a molecule from the output file of a vibrational frequency calculation performed with the GAMESS quantum chemistry package. (#460)
>>> r, m, w, l = read_gamess('../BH_data.out')
>>> r # atomic coordinates
array([[0.0000000, 0.0000000, 0.0000000],
[1.2536039, 0.0000000, 0.0000000]])
>>> m # atomic masses
array([11.00931, 1.00782])
>>> w # vibrational frequencies
array([19.74, 19.73, 0.00, 0.00, 0.00, 2320.32])
>>> l # normal modes
array([[-0.0000000e+00, -7.5322000e-04, -8.7276210e-02, 0.0000000e+00,
8.2280900e-03, 9.5339055e-01],
[-0.0000000e+00, -8.7276210e-02, 7.5322000e-04, 0.0000000e+00,
9.5339055e-01, -8.2280900e-03],
[ 2.8846925e-01, -2.0000000e-08, 2.0000000e-08, 2.8846925e-01,
-2.0000000e-08, 2.0000000e-08],
[ 2.0000000e-08, 2.8846925e-01, -2.0000000e-08, 2.0000000e-08,
2.8846925e-01, -2.0000000e-08],
[-2.0000000e-08, 2.0000000e-08, 2.8846925e-01, -2.0000000e-08,
2.0000000e-08, 2.8846925e-01],
[-8.7279460e-02, 0.0000000e+00, 0.0000000e+00, 9.5342606e-01,
-0.0000000e+00, -0.0000000e+00]])
cancel_pending
JobStatus until the cancellation is confirmed. (#456)
Fixed a bug where the function reduced_dm
in backends/tfbackend/states.py
gives the wrong output when passing it several modes. (#471)
Fixed a bug in the function reduced_density_matrix
in backends/tfbackend/ops.py
which caused the wrong subsystems to be traced out. (#467) (#470)
Fixed a bug where decompositions to Mach-Zehnder interferometers would return incorrect results on NumPy 1.19. (#473)
The Walrus version 0.14 introduced modified function names. Affected functions have been updated in Strawberry Fields to avoid deprecation warnings. (#472)
Adds further testing and coverage descriptions to the developer documentation. This includes details regarding the Strawberry Fields test structure and test decorators. (#461)
Updates the minimum required version of TensorFlow in the development guide. (#468)
This release contains contributions from (in alphabetical order):
Juan Miguel Arrazola, Tom Bromley, Theodor Isacsson, Josh Izaac, Soran Jahangiri, Nathan Killoran, Fabian Laudenbach, Nicolás Quesada, Antal Száva, Ilan Tzitrin.
Published by josh146 about 4 years ago
"Xcov"
to "Xunitary"
. This compiler is slightly more strict and only compiles the unitary, not the initial squeezers, however avoids any unintentional permutations. (#445)
xcov
compiler. (#444)
README.rst
file and hardware access links. (#448)
This release contains contributions from (in alphabetical order):
Theodor Isacsson, Josh Izaac, Nathan Killoran, Nicolás Quesada, Antal Száva
Published by josh146 about 4 years ago
Adds the ability to train variational GBS circuits in the applications layer. (#387) (#388) (#391) (#393) (#414) (#415)
Trainable parameters can be embedded into a VGBS class:
from strawberryfields.apps import data, train
d = data.Mutag0()
embedding = train.Exp(d.modes)
n_mean = 5
vgbs = train.VGBS(d.adj, 5, embedding, threshold=False, samples=np.array(d[:1000]))
Properties of the variational GBS distribution for different choices of trainable parameters can then be inspected:
>>> params = 0.1 * np.ones(d.modes)
>>> vgbs.n_mean(params)
3.6776094165797364
A cost function can then be created and its value and gradient accessed:
>>> h = lambda x: np.sum(x)
>>> cost = train.Stochastic(h, vgbs)
>>> cost(params, n_samples=1000)
3.940396998165503
>>> cost.grad(params, n_samples=1000)
array([-0.54988876, -0.49270263, -0.6628071 , -1.13057762, -1.13568456,
-0.70180571, -0.6266806 , -0.68803539, -1.11032533, -1.12853718,
-0.59172261, -0.47830748, -0.96901676, -0.66938217, -0.85162006,
-0.27188134, -0.26955011])
For more details, see the VGBS training demo.
Feature vectors of graphs can now be calculated exactly in the apps.similarity
module of the applications layer. Datasets of pre-calculated feature vectors are available in apps.data
. (#390) (#401)
>>> from strawberryfields.apps import data
>>> from strawberryfields.apps.similarity import feature_vector_sampling
>>> samples = data.Mutag0()
>>> feature_vector_sampling(samples, [2, 4, 6])
[0.19035, 0.2047, 0.1539]
For more details, see the graph similarity demo.
A new strawberryfields.apps.qchem
module has been introduced, centralizing all quantum chemistry applications. This includes various new features and improvements:
Adds the apps.qchem.duschinsky()
function for generation of the Duschinsky rotation matrix and displacement vector which are needed to simulate a vibronic process with Strawberry Fields. (#434)
Adds the apps.qchem.dynamics
module for simulating vibrational quantum dynamics in molecules. (#402) (#411) (#419) (#421) (#423) (#430)
This includes:
dynamics.evolution()
constructs a custom operation that encodes the input chemical information. This custom operation can then be used within a Strawberry Fields Program
.
dynamics.sample_coherent()
, dynamics.sample_fock()
and dynamics.sample_tmsv()
functions allow for generation of samples from a variety of input states.
The probability of an excited state can then be estimated with the dynamics.prob()
function, which calculates the relative frequency of the excited state among the generated samples.
Finally, the dynamics.marginals()
function generates marginal distributions.
The sf.apps.vibronic
module has been relocated to within the qchem
module. As a result, the apps.sample.vibronic()
function is now accessible under apps.qchem.vibronic.sample()
, providing a single location for quantum chemistry functionality. (#416)
For more details, please see the qchem documentation.
The GaussianState
returned from simulations using the Gaussian backend now has feature parity with the FockState
object returned from the Fock backends. (#407)
In particular, it now supports the following methods:
GaussianState.dm()
GaussianState.ket()
GaussianState.all_fock_probs()
In addition, the existing GaussianState.reduced_dm()
method now supports multi-mode reduced density matrices.
Adds the sf.utils.samples_expectation
, sf.utils.samples_variance
and sf.utils.all_fock_probs_pnr
functions for obtaining counting statistics from samples. (#399)
Compilation of Strawberry Fields programs has been overhauled.
Strawberry Fields can now access the Xanadu Cloud device specifications API. The Connection
class has a new method Connection.get_device
, which returns a DeviceSpec
class. (#429) (#432)
New Xstrict
, Xcov
, and Xunitary
compilers for compiling programs into the X architecture have been added. (#358) (#438)
Finally, the strawberryfields.circuitspecs
module has been renamed to strawberryfields.compilers
.
Adds diagonal_expectation
method for the BaseFockState
class, which returns the expectation value of any operator that is diagonal in the number basis. (#389)
Adds parity_expectation
method as an instance of diagonal_expectation
for the BaseFockState
class, and its own function for BaseGaussianState
. This returns the expectation value of the parity operator, defined as (-1)^N. (#389)
Modifies the rectangular interferometer decomposition to make it more efficient for hardware devices. Rather than decomposing the interferometer using Clements :math:T
matrices, the decomposition now directly produces Mach-Zehnder interferometers corresponding to on-chip phases. (#363)
Changes the number_expectation
method for the BaseFockState
class to be an instance of diagonal_expectation
. (#389)
Increases the speed at which the following gates are generated: Dgate
, Sgate
, BSgate
and S2gate
by relying on a recursive implementation recently introduced in thewalrus
. This has substantial effects on the speed of the Fockbackend
and the TFbackend
, especially for high cutoff values. (#378) (#381)
All measurement samples can now be accessed via the results.all_samples
attribute, which returns a dictionary mapping the mod index to a list of measurement values. This is useful for cases where a single mode may be measured multiple times. (#433)
Removes support for Python 3.5. (#385)
Complex parameters now are expected in polar form as two separate real parameters. (#378)
This release contains contributions from (in alphabetical order):
Juan Miguel Arrazola, Tom Bromley, Jack Ceroni, Aroosa Ijaz, Theodor Isacsson, Josh Izaac, Nathan Killoran, Soran Jahangiri, Shreya P. Kumar, Filippo Miatto, Nicolás Quesada, Antal Száva
Published by josh146 over 4 years ago
Post release to address changes to the documentation.
Published by josh146 over 4 years ago
The "tf"
backend now supports TensorFlow 2.0 and above. (#283) (#320) (#323) (#361) (#372) (#373) (#374) (#375) (#377)
For more details and demonstrations of the new TensorFlow 2.0-compatible backend, see our optimization and machine learning tutorials.
For example, using TensorFlow 2.0 to train a variational photonic circuit:
eng = sf.Engine(backend="tf", backend_options={"cutoff_dim": 7})
prog = sf.Program(1)
with prog.context as q:
# Apply a single mode displacement with free parameters
Dgate(prog.params("a"), prog.params("p")) | q[0]
opt = tf.keras.optimizers.Adam(learning_rate=0.1)
alpha = tf.Variable(0.1)
phi = tf.Variable(0.1)
for step in range(50):
# reset the engine if it has already been executed
if eng.run_progs:
eng.reset()
with tf.GradientTape() as tape:
# execute the engine
results = eng.run(prog, args={'a': alpha, 'p': phi})
# get the probability of fock state |1>
prob = results.state.fock_prob([1])
# negative sign to maximize prob
loss = -prob
gradients = tape.gradient(loss, [alpha, phi])
opt.apply_gradients(zip(gradients, [alpha, phi]))
print("Value at step {}: {}".format(step, prob))
Adds the method number_expectation
that calculates the expectation value of the product of the number operators of a given set of modes. (#348)
prog = sf.Program(3)
with prog.context as q:
ops.Sgate(0.5) | q[0]
ops.Sgate(0.5) | q[1]
ops.Sgate(0.5) | q[2]
ops.BSgate(np.pi/3, 0.1) | (q[0], q[1])
ops.BSgate(np.pi/3, 0.1) | (q[1], q[2])
Executing this on the Fock backend,
>>> eng = sf.Engine("fock", backend_options={"cutoff_dim": 10})
>>> state = eng.run(prog).state
we can compute the expectation value <n_0 n_2>
:
>>> state.number_expectation([0, 2])
Add details to the error message for failed remote jobs. (#370)
The required version of The Walrus was increased to version 0.12, for
tensor number expectation support. (#380)
This release contains contributions from (in alphabetical order):
Tom Bromley, Theodor Isacsson, Josh Izaac, Nathan Killoran, Filippo Miatto, Nicolás Quesada, Antal Száva, Paul Tan.
Published by josh146 over 4 years ago
Adds initial support for the Xanadu's photonic quantum hardware. (#101) (#148) (#294) (#327) (#328) (#329) (#330) (#334) (#336) (#337) (#339)
Jobs can now be submitted to the Xanadu Quantum Cloud platform to be run on supported hardware using the new RemoteEngine
:
import strawberryfields as sf
from strawberryfields import ops
from strawberryfields.utils import random_interferometer
# replace AUTH_TOKEN with your Xanadu Quantum Cloud access token
con = sf.api.Connection(token="AUTH_TOKEN")
eng = sf.RemoteEngine("X8", connection=con)
prog = sf.Program(8)
U = random_interferometer(4)
with prog.context as q:
ops.S2gate(1.0) | (q[0], q[4])
ops.S2gate(1.0) | (q[1], q[5])
ops.S2gate(1.0) | (q[2], q[6])
ops.S2gate(1.0) | (q[3], q[7])
ops.Interferometer(U) | q[:4]
ops.Interferometer(U) | q[4:]
ops.MeasureFock() | q
result = eng.run(prog, shots=1000)
For more details, see the photonic hardware quickstart and tutorial.
Significantly speeds up the Fock backend of Strawberry Fields, through a variety of changes:
The Fock backend now uses The Walrus high performance implementations of the displacement, squeezing, two-mode squeezing, and beamsplitter operations. (#287) (#289)
Custom tensor contractions which make use of symmetry relations for the beamsplitter and the two-mode squeeze gate have been added, as well as more efficient contractions for diagonal operations in the Fock basis. (#292)
New sf
command line program for configuring Strawberry Fields for access to the Xanadu cloud platform, as well as submitting and executing jobs from the command line. (#146) (#312)
The new Strawberry Fields command line program sf
provides several utilities including:
sf configure [--token] [--local]
: configure the connection to the cloud platform
sf run input [--output FILE]
: submit and execute quantum programs from the command line
sf --ping
: verify your connection to the Xanadu cloud platform
For more details, see the documentation.
New configuration functions to load configuration from keyword arguments, environment variables, and configuration files. (#298) (#306)
This includes the ability to automatically store Xanadu cloud platform credentials in a configuration file using the new function
sf.store_account("AUTHENTICATION_TOKEN")
as well as from the command line,
$ sf configure --token AUTHENTICATION_TOKEN
Configuration files can be saved globally, or locally on a per-project basis. For more details, see the configuration documentation
Adds configuration functions for resetting, deleting configurations, as well as displaying available configuration files. (#359)
Adds the x_quad_values
and p_quad_values
methods to the state
class. This allows calculation of x and p quadrature probability distributions by integrating across the Wigner function. (#270)
Adds support in the applications layer for node-weighted graphs.
Sample from graphs with node weights using a special-purpose encoding (#295):
from strawberryfields.apps import sample
# generate a random graph
g = nx.erdos_renyi_graph(20, 0.6)
a = nx.to_numpy_array(g)
# define node weights
# and encode into the adjacency matrix
w = [i for i in range(20)]
a = sample.waw_matrix(a, w)
s = sample.sample(a, n_mean=10, n_samples=10)
s = sample.postselect(s, min_count=4, max_count=20)
s = sample.to_subgraphs(s, g)
Node weights can be input to search algorithms in the clique
and subgraph
modules (#296) (#297):
from strawberryfields.apps import clique
c = [clique.shrink(s_, g, node_select=w) for s_ in s]
[clique.search(c_, g, iterations=10, node_select=w) for c_ in c]
from strawberryfields.apps import subgraph
subgraph.search(s, g, min_size=5, max_size=8, node_select=w)
Moved Fock backend apply-gate functions to Circuit
class, and removed apply_gate_einsum
and Circuits._apply_gate
, since they were no longer used. (#293)
Results returned from all backends now have a unified type and shape. In addition, attempting to use batching, post-selection and feed-foward together with multiple shots now raises an error. (#300)
Modified the rectangular decomposition to ensure that identity-like unitaries are implemented with no swaps. (#311)
Symbolic Operation parameters are now compatible with TensorFlow 2.0 objects. (#282)
Added sympy>=1.5
to the list of dependencies. Removed the sympy.functions.atan2
workaround now that SymPy has been fixed. (#280)
Removed two unnecessary else statements that pylint complained about. (#290)
Fixed a bug in the MZgate
, where the internal and external phases were in the wrong order in both the docstring and the argument list. The new signature is MZgate(phase_in, phase_ex)
, matching the existing rectangular_symmetric
decomposition. (#301)
Updated the relevant methods in RemoteEngine
and Connection
to derive shots
from the Blackbird script or Program
if not explicitly specified. (#327)
Fixed a bug in homodyne measurements in the Fock backend, where computed probability values could occasionally include small negative values due to floating point precision error. (#364)
Fixed a bug that caused an exception when printing results with no state. (#367)
Improves the Takagi decomposition, by making explicit use of the eigendecomposition of real symmetric matrices. (#352)
This release contains contributions from (in alphabetical order):
Ville Bergholm, Tom Bromley, Jack Ceroni, Theodor Isacsson, Josh Izaac, Nathan Killoran, Shreya P Kumar,
Leonhard Neuhaus, Nicolás Quesada, Jeremy Swinarton, Antal Száva, Paul Tan, Zeid Zabaneh.
Published by josh146 over 4 years ago
Adds initial support for the Xanadu's photonic quantum hardware. (#101) (#148) (#294) (#327) (#328) (#329) (#330) (#334) (#336) (#337) (#339)
Jobs can now be submitted to the Xanadu cloud platform to be run on supported hardware using the new RemoteEngine
:
import strawberryfields as sf
from strawberryfields import ops
from strawberryfields.utils import random_interferometer
# replace AUTHENTICATION_TOKEN with your Xanadu cloud access token
con = sf.api.Connection(token="AUTH_TOKEN")
eng = sf.RemoteEngine("X8", connection=con)
prog = sf.Program(8)
U = random_interferometer(4)
with prog.context as q:
ops.S2gate(1.0) | (q[0], q[4])
ops.S2gate(1.0) | (q[1], q[5])
ops.S2gate(1.0) | (q[2], q[6])
ops.S2gate(1.0) | (q[3], q[7])
ops.Interferometer(U) | q[:4]
ops.Interferometer(U) | q[4:]
ops.MeasureFock() | q
result = eng.run(prog, shots=1000)
For more details, see the photonic hardware quickstart and tutorial.
Significantly speeds up the Fock backend of Strawberry Fields, through a variety of changes:
The Fock backend now uses The Walrus high performance implementations of the displacement, squeezing, two-mode squeezing, and beamsplitter operations. (#287) (#289)
Custom tensor contractions which make use of symmetry relations for the beamsplitter and the two-mode squeeze gate have been added, as well as more efficient contractions for diagonal operations in the Fock basis. (#292)
New sf
command line program for configuring Strawberry Fields for access to the Xanadu cloud platform, as well as submitting and executing jobs from the command line. (#146) (#312)
The new Strawberry Fields command line program sf
provides several utilities including:
sf configure [--token] [--local]
: configure the connection to the cloud platform
sf run input [--output FILE]
: submit and execute quantum programs from the command line
sf --ping
: verify your connection to the Xanadu cloud platform
For more details, see the documentation.
New configuration functions to load configuration from keyword arguments, environment variables, and configuration files. (#298) (#306)
This includes the ability to automatically store Xanadu cloud platform credentials in a configuration file using the new function
sf.store_account("AUTHENTICATION_TOKEN")
as well as from the command line,
$ sf configure --token AUTHENTICATION_TOKEN
Configuration files can be saved globally, or locally on a per-project basis. For more details, see the configuration documentation
Adds the x_quad_values
and p_quad_values
methods to the state
class. This allows calculation of x and p quadrature probability distributions by integrating across the Wigner function. (#270)
Adds support in the applications layer for node-weighted graphs.
Sample from graphs with node weights using a special-purpose encoding (#295):
from strawberryfields.apps import sample
# generate a random graph
g = nx.erdos_renyi_graph(20, 0.6)
a = nx.to_numpy_array(g)
# define node weights
# and encode into the adjacency matrix
w = [i for i in range(20)]
a = sample.waw_matrix(a, w)
s = sample.sample(a, n_mean=10, n_samples=10)
s = sample.postselect(s, min_count=4, max_count=20)
s = sample.to_subgraphs(s, g)
Node weights can be input to search algorithms in the clique
and subgraph
modules (#296) (#297):
from strawberryfields.apps import clique
c = [clique.shrink(s_, g, node_select=w) for s_ in s]
[clique.search(c_, g, iterations=10, node_select=w) for c_ in c]
from strawberryfields.apps import subgraph
subgraph.search(s, g, min_size=5, max_size=8, node_select=w)
Moved Fock backend apply-gate functions to Circuit
class, and removed apply_gate_einsum
and Circuits._apply_gate
, since they were no longer used. (#293)
Results returned from all backends now have a unified type and shape. In addition, attempting to use batching, post-selection and feed-foward together with multiple shots now raises an error. (#300)
Modified the rectangular decomposition to ensure that identity-like unitaries are implemented with no swaps. (#311)
Symbolic Operation parameters are now compatible with TensorFlow 2.0 objects. (#282)
Added sympy>=1.5
to the list of dependencies. Removed the sympy.functions.atan2
workaround now that SymPy has been fixed. (#280)
Removed two unnecessary else statements that pylint complained about. (#290)
Fixed a bug in the MZgate
, where the internal and external phases were in the wrong order in both the docstring and the argument list. The new signature is MZgate(phase_in, phase_ex)
, matching the existing rectangular_symmetric
decomposition. (#301)
Updated the relevant methods in RemoteEngine
and Connection
to derive shots
from the Blackbird script or Program
if not explicitly specified. (#327)
This release contains contributions from (in alphabetical order):
Ville Bergholm, Tom Bromley, Jack Ceroni, Theodor Isacsson, Josh Izaac, Nathan Killoran, Shreya P Kumar,
Leonhard Neuhaus, Nicolás Quesada, Jeremy Swinarton, Antal Száva, Paul Tan, Zeid Zabaneh.
Published by trbromley almost 5 years ago
This is a very minor bugfix release, to address some installation issues with the previous v0.12.0.
Add new Strawberry Fields applications paper to documentation #274
Update figure for GBS device in documentation #275
Fix installation issue with incorrect minimum version number for thewalrus
, fix an incorrect URL in the README
, and add the applications data to the MANIFEST.in
file. #272 #277 #273 #278
This release contains contributions from (in alphabetical order):
Ville Bergholm, Tom Bromley, Nicolás Quesada, Paul Tan
Published by josh146 almost 5 years ago
A new applications layer, allowing users to interface samples generated from near-term photonic devices with problems of practical interest. The apps
package consists of the following modules:
The apps.sample
module, for encoding graphs and molecules into Gaussian boson sampling (GBS) and generating corresponding samples.
The apps.subgraph
module, providing a heuristic algorithm for finding dense subgraphs from GBS samples.
The apps.clique
module, providing tools to convert subgraphs sampled from GBS into cliques and a heuristic to search for larger cliques.
The apps.similarity
module, allowing users to embed graphs into high-dimensional feature spaces using GBS. Resulting feature vectors provide measures of graph similarity for machine learning tasks.
The apps.points
module, allowing users to sample subsets of points according to new point process that can be generated from a GBS device.
The apps.vibronic
module, providing functionality to construct the vibronic absorption spectrum of a molecule from GBS samples.
The documentation was improved and refactored. Changes include:
This release contains contributions from (in alphabetical order):
Juan Miguel Arrazola, Tom Bromley, Josh Izaac, Soran Jahangiri, Nicolás Quesada
Published by josh146 almost 5 years ago
Adds the MZgate to ops.py, representing a Mach-Zehnder interferometer. This is not a primitive of the existing simulator backends; rather, _decompose()
is defined, decomposing it into an external phase shift, two 50-50 beamsplitters, and an internal phase shift. #127
The Chip0Spec
circuit class now defines a compile
method, allowing arbitrary unitaries comprised of {Interferometer, BSgate, Rgate, MZgate}
operations to be validated and compiled to match the topology of chip0. #127
strawberryfields.ops.BipartiteGraphEmbed
quantum decomposition now added, allowing a bipartite graph to be embedded on a device that allows for initial two-mode squeezed states, and block diagonal unitaries.
Added threshold measurements, via the new operation MeasureThreshold
, and provided implementation of this operation in the Gaussian backend. #152
Programs can now have free parameters/arguments which are only bound to numerical values when the Program is executed, by supplying the actual argument values to the Engine.run
method. #163
The strawberryfields.ops.Measure
shorthand has been deprecated in favour of strawberryfields.ops.MeasureFock()
. #145
Several changes to the strawberryfields.decompositions
module: #127
The name clements
has been replaced with rectangular
to correspond with the shape of the resulting decomposition.
All interferometer decompositions (rectangular
, rectangular_phase_end
, rectangular_symmetric
, and triangular
) now have standardized outputs (tlist, diag, tilist)
, so they can easily be swapped.
Several changes to ops.Interferometer
: #127
The calculation of the ops.Interferometer decomposition has been moved from __init__
to _decompose()
, allowing the interferometer decomposition type to be set by a CircuitSpec
during compilation.
**kwargs
is now passed through from Operation.decompose
-> Gate.decompose
-> SpecificOp._decompose
, allowing decomposition options to be passed during compilation.
ops.Interferometer
now accepts the keyword argument mesh
to be set during initialization, allowing the user to specify the decomposition they want.
Moves the Program.compile_seq
method to CircuitSpecs.decompose
. This allows it to be accessed from the CircuitSpec.compile
method. Furthermore, it now must also be passed the program registers, as compilation may sometimes require this. #127
Parameter class is replaced by MeasuredParameter
and FreeParameter
, both inheriting from sympy.Symbol
. Fixed numeric parameters are handled by the built-in Python numeric classes and numpy arrays. #163
Parameter
, RegRefTransform
and convert
are removed. #163
Photon-counting measurements can now be done in the Gaussian backend for states with nonzero displacement. #154
Added a new test for the cubic phase gate #160
Added new integration tests for the Gaussian gates that are not primitive, i.e., P, CX, CZ, and S2. #173
Fixed bug in strawberryfields.decompositions.rectangular_symmetric
so its returned phases are all in the interval [0, 2*pi), and corrects the function docstring. #196
When using the 'gbs'
compilation target, the measured registers are now sorted in ascending order in the resulting compiled program. #144
Fixed typo in the Gaussian Boson Sampling example notebook. #133
Fixed a bug in the function smeanxp
of the Gaussian Backend simulator. #154
Clarified description of matrices that are accepted by graph embed operation. #147
Fixed typos in the documentation of the CX gate and BSgate #166 #167 #169
Published by josh146 over 5 years ago
Added the circuit_spec
attribute to BaseBackend
to denote which CircuitSpecs class should be used to validate programs for each backend #125.
Removed the return_state
keyword argument from LocalEngine.run()
. Now no state object is returned if modes==[]
. #126
Fixed a typo in the boson sampling tutorial. #133
Allows imported Blackbird programs to store target
options as default run options. During eng.run, if no run options are provided as a keyword argument, the engine will fall back on the run options stored within the program.
This fixes a bug where shots specified in Blackbird scripts were not being passed to eng.run
. #130
Removes ModuleNotFoundError
from the codebase, replacing all occurrences with ImportError
. Since ModuleNotFoundError
was only introduced in Python 3.6+, this fixes a bug where Strawberry Fields was not importable on Python 3.5 #124.
Updates the Chip0 template to use MeasureFock() | [0, 1, 2, 3], which will allow correct fock measurement behaviour when simulated on the Gaussian backend. #124
Fixed a bug in the GraphEmbed
op, which was not correctly determining when a unitary was the identity #128.