
from phi.flow import *
from phi.tf.flow import *
from phi.jax.stax.flow import *
from phi.torch.flow import *

2025-02-28 18:59:53.092046: E external/local_xla/xla/stream_executor/cuda/cuda_fft.cc:477] Unable to register cuFFT factory: Attempting to register factory for plugin cuFFT when one has already been registered
WARNING: All log messages before absl::InitializeLog() is called are written to STDERR
E0000 00:00:1740769193.106527    2203 cuda_dnn.cc:8310] Unable to register cuDNN factory: Attempting to register factory for plugin cuDNN when one has already been registered
E0000 00:00:1740769193.110906    2203 cuda_blas.cc:1418] Unable to register cuBLAS factory: Attempting to register factory for plugin cuBLAS when one has already been registered
2025-02-28 18:59:53.127566: I tensorflow/core/platform/cpu_feature_guard.cc:210] This TensorFlow binary is optimized to use available CPU instructions in performance-critical operations.
To enable the following instructions: AVX2 FMA, in other operations, rebuild TensorFlow with the appropriate compiler flags.
2025-02-28 18:59:55.294772: E external/local_xla/xla/stream_executor/cuda/cuda_driver.cc:152] failed call to cuInit: INTERNAL: CUDA error: Failed call to cuInit: UNKNOWN ERROR (303)


backend.default_backend().list_devices('GPU')

[]


backend.default_backend().list_devices('CPU')

[torch device 'CPU' (CPU 'cpu') | 15990 MB | 4 processors | ]


assert backend.default_backend().set_default_device('CPU')


math.set_global_precision(32)  # single precision is the default
x32 = math.random_normal(batch(b=4))

with math.precision(64):  ## operations within this context will use 32 bit floats
    x64 = math.to_float(x32)


data = math.random_normal(batch(examples=10)) * .1  # batch of scalar values
data = math.random_uniform(batch(examples=10), channel(vector='x,y'))  # batch of vectors
data

(examplesᵇ=10, vectorᶜ=x,y) 0.551 ± 0.314 (3e-02...9e-01)


data.examples[0]

(x=0.932, y=0.895)


print(data)
print(f"{data:full:shape:dtype:color:.1f}")

(examplesᵇ=10, vectorᶜ=x,y) 0.551 ± 0.314 (3e-02...9e-01)
(examplesᵇ=10, vectorᶜ=x,y)
[[0.9, 0.9],
 [0.5, 0.7],
 [0.1, 0.0],
 [0.3, 0.8],
 [0.5, 0.6],
 [0.7, 0.9],
 [0.9, 0.8],
 [0.4, 0.8],
 [0.0, 0.2],
 [0.8, 0.1]]


data = math.random_uniform(spatial(x=8, y=6))
vis.plot(data)  # or vis.show(data)

/opt/hostedtoolcache/Python/3.12.9/x64/lib/python3.12/site-packages/phi/vis/_matplotlib/_matplotlib_plots.py:167: UserWarning: This figure includes Axes that are not compatible with tight_layout, so results might be incorrect.
  plt.tight_layout()  # because subplot titles can be added after figure creation


data.numpy(order='x,y')

array([[0.7117158 , 0.7819734 , 0.46078986, 0.7632882 , 0.9983441 ,
        0.87600124],
       [0.8105186 , 0.0474633 , 0.42952222, 0.34084898, 0.4319815 ,
        0.8809404 ],
       [0.42782837, 0.8493887 , 0.8199676 , 0.5723619 , 0.8848299 ,
        0.14131516],
       [0.40969414, 0.36407202, 0.86129844, 0.87103117, 0.54137987,
        0.9451648 ],
       [0.94180036, 0.5700126 , 0.32170886, 0.9192251 , 0.36841327,
        0.99123365],
       [0.3243165 , 0.7712629 , 0.6265182 , 0.12021291, 0.85183316,
        0.03610802],
       [0.03077155, 0.1386311 , 0.7911339 , 0.6066651 , 0.17137617,
        0.6743576 ],
       [0.8729119 , 0.21536678, 0.8630131 , 0.35792142, 0.0314253 ,
        0.9223388 ]], dtype=float32)


math.reshaped_native(data, ['extra', data.shape], to_numpy=True)

/tmp/ipykernel_2203/2990683702.py:1: DeprecationWarning: phiml.math.reshaped_native() is deprecated. Use Tensor.native() instead.
  math.reshaped_native(data, ['extra', data.shape], to_numpy=True)

array([[0.7117158 , 0.7819734 , 0.46078986, 0.7632882 , 0.9983441 ,
        0.87600124, 0.8105186 , 0.0474633 , 0.42952222, 0.34084898,
        0.4319815 , 0.8809404 , 0.42782837, 0.8493887 , 0.8199676 ,
        0.5723619 , 0.8848299 , 0.14131516, 0.40969414, 0.36407202,
        0.86129844, 0.87103117, 0.54137987, 0.9451648 , 0.94180036,
        0.5700126 , 0.32170886, 0.9192251 , 0.36841327, 0.99123365,
        0.3243165 , 0.7712629 , 0.6265182 , 0.12021291, 0.85183316,
        0.03610802, 0.03077155, 0.1386311 , 0.7911339 , 0.6066651 ,
        0.17137617, 0.6743576 , 0.8729119 , 0.21536678, 0.8630131 ,
        0.35792142, 0.0314253 , 0.9223388 ]], dtype=float32)


points = math.tensor([(0, 0), (0, 1), (1, 0)], instance('points'), channel('vector'))
distances = points - math.rename_dims(points, 'points', 'others')
math.print(math.vec_length(distances))

[[0.       , 1.       , 1.       ],
 [1.       , 0.       , 1.4142135],
 [1.       , 1.4142135, 0.       ]]

/tmp/ipykernel_2203/2195475714.py:3: DeprecationWarning: phiml.math.length is deprecated in favor of phiml.math.norm
  math.print(math.vec_length(distances))


zero_grid = CenteredGrid(0, 0, x=32, y=32, bounds=Box(x=1, y=1))
y_grid = CenteredGrid((0, 1), extrapolation.BOUNDARY, x=32, y=32)
noise_grid = CenteredGrid(Noise(), extrapolation.PERIODIC, x=32, y=32)
sin_curve = CenteredGrid(lambda x: math.sin(x), extrapolation.PERIODIC, x=100, bounds=Box(x=2 * PI))

vis.plot(zero_grid, y_grid, noise_grid, sin_curve, size=(12, 3))


zero_grid = StaggeredGrid(0, 0, x=32, y=32, bounds=Box(x=1, y=1))
y_grid = StaggeredGrid((0, 1), extrapolation.BOUNDARY, x=32, y=32)
noise_grid = StaggeredGrid(Noise(), extrapolation.PERIODIC, x=32, y=32)
sin_curve = StaggeredGrid(lambda x: math.sin(x), extrapolation.PERIODIC, x=100, bounds=Box(x=2 * PI))

vis.plot(zero_grid, y_grid, noise_grid, sin_curve, size=(12, 3))

/opt/hostedtoolcache/Python/3.12.9/x64/lib/python3.12/site-packages/phiml/math/_shape.py:2769: RuntimeWarning: Stacking shapes with incompatible item names will result in item names being lost. For vector Got ('x', 'y') and ('x',)
  warnings.warn(f"Stacking shapes with incompatible item names will result in item names being lost. For {dim.name} Got {prev.slice_names} and {dim.slice_names}", RuntimeWarning)


vx = math.tensor(np.zeros([33, 32]), spatial('x,y'))
vy = math.tensor(np.zeros([32, 33]), spatial('x,y'))
StaggeredGrid(math.stack([vx, vy], dual(vector='x,y')), extrapolation.BOUNDARY)

vx = math.tensor(np.zeros([32, 32]), spatial('x,y'))
vy = math.tensor(np.zeros([32, 32]), spatial('x,y'))
StaggeredGrid(math.stack([vx, vy], dual(vector='x,y')), extrapolation.PERIODIC)

vx = math.tensor(np.zeros([31, 32]), spatial('x,y'))
vy = math.tensor(np.zeros([32, 31]), spatial('x,y'))
StaggeredGrid(math.stack([vx, vy], dual(vector='x,y')), 0)

Field[(xˢ=32, yˢ=32, vectorᶜ=x,y)]


def loss_function(x):
    return math.l2_loss(math.cos(x))

initial_guess = math.tensor([1, -1], math.batch('batch'))
math.minimize(loss_function, Solve('L-BFGS-B', 0, 1e-3, x0=initial_guess))

(1.574, -1.574) along batchᵇ


def f(x):
    return 2 * x

math.solve_linear(f, 84, Solve('CG', 1e-5, x0=0))

tensor([42.])


from functools import partial

periodic_laplace = partial(math.laplace, padding=extrapolation.PERIODIC)
example_input = math.ones(spatial(x=3))
matrix, bias = math.matrix_from_function(periodic_laplace, example_input)
math.print(matrix)

x=0     -2.   1.   1.  along ~x
x=1      1.  -2.   1.  along ~x
x=2      1.   1.  -2.  along ~x


def f(x):
    return math.l2_loss(math.sin(x))

f_grid = CenteredGrid(f, x=100, y=100, bounds=Box(x=2*PI, y=2*PI))
vis.plot(f_grid)


def minimize(x0):
    with math.SolveTape(record_trajectories=True) as solves:
        math.minimize(f, Solve('BFGS', 0, 1e-5, x0=x0))
    return solves[0].x  # shape (trajectory, x, y, vector)

trajectories = CenteredGrid(minimize, x=8, y=8, bounds=Box(x=2*PI, y=2*PI)).values
segments = []
for start, end in zip(trajectories.trajectory[:-1].trajectory, trajectories.trajectory[1:].trajectory):
    segments.append(PointCloud(start, end - start, bounds=Box(x=2*PI, y=2*PI)))
anim_segments = field.stack(segments, batch('time'))
vis.plot(f_grid, anim_segments, overlay='args', animate='time', color='#FFFFFF', frame_time=500)

/tmp/ipykernel_2203/1489350838.py:9: UserWarning: bounds argument is deprecated since 2.5 and will be ignored.
  segments.append(PointCloud(start, end - start, bounds=Box(x=2*PI, y=2*PI)))

<Figure size 640x480 with 0 Axes>


net = dense_net(1, 1, layers=[8, 8], activation='ReLU')  # Implemented for PyTorch, TensorFlow, Jax-Stax
optimizer = adam(net, 1e-3)
BATCH = batch(batch=100)

def loss_function(data: Tensor):
    prediction = math.native_call(net, data)
    label = math.sin(data)
    return math.l2_loss(prediction - label), data, label

print(f"Initial loss: {loss_function(math.random_normal(BATCH))[0]}")
for i in range(100):
    loss, _data, _label = update_weights(net, optimizer, loss_function, data=math.random_normal(BATCH))
print(f"Final loss: {loss}")

Initial loss: (batchᵇ=100) 0.243 ± 0.230 (4e-07...7e-01)
Final loss: (batchᵇ=100) 0.214 ± 0.159 (3e-08...5e-01)


parameter_count(net)

97

Φ_Flow Cookbook¶

Import for NumPy, TensorFlow, Jax, PyTorch¶

Select GPU or CPU¶

Use 64 bit FP precision¶

Sample Random Values¶

Slice a Tensor¶

Print a `Tensor`¶

Plot a `Tensor`¶

Convert a `Tensor` to NumPy¶

Compute Pair-wise Distances¶

Construct a `CenteredGrid`¶

Construct a `StaggeredGrid`¶

Construct `StaggeredGrid` from NumPy Arrays¶

BFGS Optimization¶

Linear Solve¶

Sparse Matrix Construction¶

Sampling a Function¶

Plot Optimization Trajectories¶

Neural Network Training¶

Parameter Count¶

ΦFlow Cookbook¶

Import for NumPy, TensorFlow, Jax, PyTorch¶

Select GPU or CPU¶

Use 64 bit FP precision¶

Sample Random Values¶

Slice a Tensor¶

Print a Tensor¶

Plot a Tensor¶

Convert a Tensor to NumPy¶

Compute Pair-wise Distances¶

Construct a CenteredGrid¶

Construct a StaggeredGrid¶

Construct StaggeredGrid from NumPy Arrays¶

BFGS Optimization¶

Linear Solve¶

Sparse Matrix Construction¶

Sampling a Function¶

Plot Optimization Trajectories¶

Neural Network Training¶

Parameter Count¶

Φ_Flow Cookbook¶

Print a `Tensor`¶

Plot a `Tensor`¶

Convert a `Tensor` to NumPy¶

Construct a `CenteredGrid`¶

Construct a `StaggeredGrid`¶

Construct `StaggeredGrid` from NumPy Arrays¶