tecandrew/pytorch-apple-silicon-test.py

## pytorch-apple-silicon-test.py
import torch
import math

# this ensures that the current MacOS version is at least 12.3+
print(torch.backends.mps.is_available())
# this ensures that the current current PyTorch installation was built with MPS activated.
print(torch.backends.mps.is_built())

dtype = torch.float
device = torch.device("mps")

# Create random input and output data
x = torch.linspace(-math.pi, math.pi, 2000, device=device, dtype=dtype)
y = torch.sin(x)

# Randomly initialize weights
a = torch.randn((), device=device, dtype=dtype)
b = torch.randn((), device=device, dtype=dtype)
c = torch.randn((), device=device, dtype=dtype)
d = torch.randn((), device=device, dtype=dtype)

learning_rate = 1e-6
for t in range(2000):
    # Forward pass: compute predicted y
    y_pred = a + b * x + c * x ** 2 + d * x ** 3

    # Compute and print loss
    loss = (y_pred - y).pow(2).sum().item()
    if t % 100 == 99:
        print(t, loss)

# Backprop to compute gradients of a, b, c, d with respect to loss
    grad_y_pred = 2.0 * (y_pred - y)
    grad_a = grad_y_pred.sum()
    grad_b = (grad_y_pred * x).sum()
    grad_c = (grad_y_pred * x ** 2).sum()
    grad_d = (grad_y_pred * x ** 3).sum()

    # Update weights using gradient descent
    a -= learning_rate * grad_a
    b -= learning_rate * grad_b
    c -= learning_rate * grad_c
    d -= learning_rate * grad_d


print(f'Result: y = {a.item()} + {b.item()} x + {c.item()} x^2 + {d.item()} x^3')
	import torch
	import math

	# this ensures that the current MacOS version is at least 12.3+
	print(torch.backends.mps.is_available())
	# this ensures that the current current PyTorch installation was built with MPS activated.
	print(torch.backends.mps.is_built())

	dtype = torch.float
	device = torch.device("mps")

	# Create random input and output data
	x = torch.linspace(-math.pi, math.pi, 2000, device=device, dtype=dtype)
	y = torch.sin(x)

	# Randomly initialize weights
	a = torch.randn((), device=device, dtype=dtype)
	b = torch.randn((), device=device, dtype=dtype)
	c = torch.randn((), device=device, dtype=dtype)
	d = torch.randn((), device=device, dtype=dtype)

	learning_rate = 1e-6
	for t in range(2000):
	# Forward pass: compute predicted y
	y_pred = a + b * x + c * x ** 2 + d * x ** 3

	# Compute and print loss
	loss = (y_pred - y).pow(2).sum().item()
	if t % 100 == 99:
	print(t, loss)

	# Backprop to compute gradients of a, b, c, d with respect to loss
	grad_y_pred = 2.0 * (y_pred - y)
	grad_a = grad_y_pred.sum()
	grad_b = (grad_y_pred * x).sum()
	grad_c = (grad_y_pred * x ** 2).sum()
	grad_d = (grad_y_pred * x ** 3).sum()

	# Update weights using gradient descent
	a -= learning_rate * grad_a
	b -= learning_rate * grad_b
	c -= learning_rate * grad_c
	d -= learning_rate * grad_d


	print(f'Result: y = {a.item()} + {b.item()} x + {c.item()} x^2 + {d.item()} x^3')