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# Copyright © 2023 Apple Inc.
import unittest
import mlx.core as mx
import mlx.nn as nn
import mlx_tests
import numpy as np
class TestLosses(mlx_tests.MLXTestCase):
def test_cross_entropy(self):
# No weights, no label smoothing
logits = mx.array([[0.0, -float("inf")], [-float("inf"), 0.0]])
indices = mx.array([0, 1])
expected = mx.array([0.0, 0.0])
loss = nn.losses.cross_entropy(logits, indices, reduction="none")
self.assertTrue(mx.allclose(loss, expected))
probs = mx.array([[1.0, 0.0], [0.0, 1.0]])
loss = nn.losses.cross_entropy(logits, probs, reduction="none")
self.assertTrue(mx.isnan(loss).all()) # produce NaNs, like PyTorch
# With weights, no label smoothing
logits = mx.array([[2.0, -1.0], [-1.0, 2.0]])
indices = mx.array([0, 1])
weights = mx.array([1.0, 2.0])
expected = mx.array([0.04858735, 0.0971747])
loss = nn.losses.cross_entropy(
logits, indices, weights=weights, reduction="none"
)
self.assertTrue(mx.allclose(loss, expected))
probs = mx.array([[1.0, 0.0], [0.0, 1.0]])
loss = nn.losses.cross_entropy(logits, probs, weights=weights, reduction="none")
self.assertTrue(mx.allclose(loss, expected))
# No weights, with label smoothing
logits = mx.array([[2.0, -1.0], [-1.0, 2.0]])
indices = mx.array([0, 1])
expected = mx.array([0.498587, 0.498587])
loss = nn.losses.cross_entropy(
logits, indices, label_smoothing=0.3, reduction="none"
)
self.assertTrue(mx.allclose(loss, expected))
probs = mx.array([[1.0, 0.0], [0.0, 1.0]])
loss = nn.losses.cross_entropy(
logits, probs, label_smoothing=0.3, reduction="none"
)
self.assertTrue(mx.allclose(loss, expected))
# With weights and label smoothing
logits = mx.array([[2.0, -1.0], [-1.0, 2.0]])
indices = mx.array([0, 1])
weights = mx.array([1.0, 2.0])
expected = mx.array([0.49858734, 0.9971747])
loss = nn.losses.cross_entropy(
logits, indices, weights=weights, label_smoothing=0.3, reduction="none"
)
self.assertTrue(mx.allclose(loss, expected))
# Test a different axis
logits = mx.random.normal((4, 8))
targets = mx.array([1, 2, 3, 0])
loss = nn.losses.cross_entropy(
logits.T,
targets,
axis=0,
)
targets = mx.array([1, 2, 3, 0])
expected = nn.losses.cross_entropy(
logits,
targets,
axis=-1,
)
self.assertTrue(mx.allclose(loss, expected))
def test_binary_cross_entropy(self):
def _test_logits_as_inputs():
logits = mx.array([0.105361, 0.223144, 1.20397, 0.916291])
targets = mx.array([0, 0, 1, 1])
# Test with reduction 'none'
losses_none = nn.losses.binary_cross_entropy(
logits, targets, reduction="none"
)
expected_none = mx.array([0.747215, 0.810930, 0.262365, 0.336472])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.binary_cross_entropy(
logits, targets, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.binary_cross_entropy(
logits, targets, reduction="sum"
)
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
# With weights, no label smoothing
weights = mx.array([1.0, 2.0, 1.0, 2.0])
expected = mx.array([0.747215, 1.62186, 0.262365, 0.672944])
loss = nn.losses.binary_cross_entropy(
logits, targets, weights=weights, reduction="none"
)
self.assertTrue(mx.allclose(loss, expected))
def _test_probs_as_inputs():
probs = mx.array([0.5, 0.6, 0.7, 0.8])
targets = mx.array([0, 0, 1, 1])
# Test with reduction 'none'
losses_none = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="none"
)
expected_none = mx.array([0.693147, 0.916291, 0.356675, 0.223144])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="sum"
)
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
def _test_tiny_probs_as_inputs():
TINY_PROB = 1e-59
probs = mx.array([0, TINY_PROB, 1 - TINY_PROB, 1])
targets = mx.array([0, 0, 1, 1])
losses_none = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="none"
)
expected_none = mx.array([0.0, TINY_PROB, TINY_PROB, 0.0])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.binary_cross_entropy(
probs, targets, with_logits=False, reduction="sum"
)
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
_test_logits_as_inputs()
_test_probs_as_inputs()
_test_tiny_probs_as_inputs()
def test_l1_loss(self):
predictions = mx.array([0.5, 0.2, 0.9, 0.0])
targets = mx.array([0.5, 0.2, 0.9, 0.0])
# Expected result
expected_none = mx.array([0, 0, 0, 0]).astype(mx.float32)
expected_sum = mx.sum(expected_none)
expected_mean = mx.mean(expected_none)
losses = nn.losses.l1_loss(predictions, targets, reduction="none")
self.assertTrue(
mx.array_equal(losses, expected_none),
"Test failed for l1_loss --reduction='none'",
)
losses = nn.losses.l1_loss(predictions, targets, reduction="sum")
self.assertTrue(mx.array_equal(losses, expected_sum))
losses = nn.losses.l1_loss(predictions, targets, reduction="mean")
self.assertTrue(mx.array_equal(losses, expected_mean))
def test_mse_loss(self):
predictions = mx.array([0.5, 0.2, 0.9, 0.0])
targets = mx.array([0.7, 0.1, 0.8, 0.2])
expected_none = mx.array([0.04, 0.01, 0.01, 0.04])
expected_mean = mx.mean(expected_none)
expected_sum = mx.sum(expected_none)
# Test with reduction 'none'
losses_none = nn.losses.mse_loss(predictions, targets, reduction="none")
self.assertTrue(
np.allclose(losses_none, expected_none, 1e-5),
"Test case failed for mse_loss --reduction='none'",
)
# Test with reduction 'mean'
losses_mean = nn.losses.mse_loss(predictions, targets, reduction="mean")
self.assertEqual(
losses_mean,
expected_mean,
"Test case failed for mse_loss --reduction='mean'",
)
# Test with reduction 'sum'
losses_sum = nn.losses.mse_loss(predictions, targets, reduction="sum")
self.assertEqual(
losses_sum, expected_sum, "Test case failed for mse_loss --reduction='sum'"
)
def test_smooth_l1_loss(self):
predictions = mx.array([1.5, 2.5, 0.5, 3.5])
targets = mx.array([1.0, 2.0, 0.5, 2.5])
beta = 1.0
# Expected results
expected_none = mx.array([0.125, 0.125, 0.0, 0.5])
expected_sum = mx.sum(expected_none)
expected_mean = mx.mean(expected_none)
# Test with reduction 'none'
loss_none = nn.losses.smooth_l1_loss(
predictions, targets, beta, reduction="none"
)
self.assertTrue(
mx.array_equal(loss_none, expected_none),
"Test case failed for smooth_l1_loss --reduction='none'",
)
# Test with reduction 'sum'
loss_sum = nn.losses.smooth_l1_loss(predictions, targets, beta, reduction="sum")
self.assertEqual(
loss_sum,
expected_sum,
"Test case failed for smooth_l1_loss --reduction='sum'",
)
# Test with reduction 'mean'
loss_mean = nn.losses.smooth_l1_loss(
predictions, targets, beta, reduction="mean"
)
self.assertEqual(
loss_mean,
expected_mean,
"Test case failed for smooth_l1_loss --reduction='mean'",
)
def test_nll_loss(self):
logits = mx.array([[0.0, -float("inf")], [-float("inf"), 0.0]])
targets = mx.array([0, 1])
# Test with reduction 'none'
losses_none = nn.losses.nll_loss(logits, targets, reduction="none")
expected_none = mx.array([0.0, 0.0])
self.assertTrue(mx.array_equal(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.nll_loss(logits, targets, reduction="mean")
expected_mean = mx.mean(expected_none)
self.assertEqual(losses_mean, expected_mean)
# Test with reduction 'sum'
losses_sum = nn.losses.nll_loss(logits, targets, reduction="sum")
expected_sum = mx.sum(expected_none)
self.assertEqual(losses_sum, expected_sum)
def test_gaussian_nll_loss(self):
inputs = mx.array([[0.1, 0.2], [0.3, 0.4]])
targets = mx.array([[0.2, 0.1], [0.1, 0.2]])
vars = mx.array([[0.1, 0.2], [0.3, 0.4]])
# Test with reduction 'none', full=False
losses_none = nn.losses.gaussian_nll_loss(
inputs, targets, vars, reduction="none"
)
expected_none = mx.array([[-1.101293, -0.779719], [-0.535320, -0.408145]])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean', full=False
losses_mean = nn.losses.gaussian_nll_loss(
inputs, targets, vars, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum', full=False
losses_sum = nn.losses.gaussian_nll_loss(inputs, targets, vars, reduction="sum")
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
# Test with reduction='none', full=True
losses_none_full = nn.losses.gaussian_nll_loss(
inputs, targets, vars, full=True, reduction="none"
)
expected_none_full = mx.array([[-0.182354, 0.139220], [0.383619, 0.510793]])
self.assertTrue(mx.allclose(losses_none_full, expected_none_full))
# Test with reduction='mean', full=True
losses_mean_full = nn.losses.gaussian_nll_loss(
inputs, targets, vars, full=True, reduction="mean"
)
expected_mean_full = mx.mean(expected_none_full)
self.assertTrue(mx.allclose(losses_mean_full, expected_mean_full))
# Test with reduction='sum', full=True
losses_sum_full = nn.losses.gaussian_nll_loss(
inputs, targets, vars, full=True, reduction="sum"
)
expected_sum_full = mx.sum(expected_none_full)
self.assertTrue(mx.allclose(losses_sum_full, expected_sum_full))
def test_kl_div_loss(self):
p_logits = mx.log(mx.array([[0.5, 0.5], [0.8, 0.2]]))
q_logits = mx.log(mx.array([[0.5, 0.5], [0.2, 0.8]]))
# Test with reduction 'none'
losses_none = nn.losses.kl_div_loss(p_logits, q_logits, reduction="none")
expected_none = mx.array([0.0, 0.831777])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.kl_div_loss(p_logits, q_logits, reduction="mean")
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.kl_div_loss(p_logits, q_logits, reduction="sum")
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
def test_triplet_loss(self):
anchors = mx.array([[1, 2, 3], [1, 2, 3]])
positives = mx.array([[4, 5, 6], [0, -1, 2]])
negatives = mx.array([[7, 8, 9], [3, 2, 3]])
# Test with reduction 'none'
losses_none = nn.losses.triplet_loss(
anchors, positives, negatives, reduction="none"
)
expected_none = mx.array([0, 2.31662])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.triplet_loss(
anchors, positives, negatives, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.triplet_loss(
anchors, positives, negatives, reduction="sum"
)
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
def test_hinge_loss(self):
inputs = mx.ones((2, 4))
targets = mx.zeros((2, 4))
loss = nn.losses.hinge_loss(inputs, targets, reduction="mean")
self.assertEqual(loss, 1.0)
def test_huber_loss(self):
inputs = mx.ones((2, 4))
targets = mx.zeros((2, 4))
loss = nn.losses.huber_loss(inputs, targets, reduction="mean")
self.assertEqual(loss, 0.5)
def test_log_cosh_loss(self):
inputs = mx.ones((2, 4))
targets = mx.zeros((2, 4))
loss = nn.losses.log_cosh_loss(inputs, targets, reduction="mean")
self.assertAlmostEqual(loss.item(), 0.433781, places=6)
def test_cosine_similarity_loss(self):
embeddings1 = mx.array([[0.5, 0.5, 0.2, 0.9], [0.1, 0.3, 0.5, 0.5]])
embeddings2 = mx.array([[0.6, 0.4, 0.3, 0.8], [0.2, 0.5, 0.6, 0.4]])
# Test with reduction 'none'
losses_none = nn.losses.cosine_similarity_loss(
embeddings1, embeddings2, reduction="none"
)
expected_none = mx.array([0.985344, 0.961074])
self.assertTrue(mx.allclose(losses_none, expected_none))
# Test with reduction 'mean'
losses_mean = nn.losses.cosine_similarity_loss(
embeddings1, embeddings2, reduction="mean"
)
expected_mean = mx.mean(expected_none)
self.assertTrue(mx.allclose(losses_mean, expected_mean))
# Test with reduction 'sum'
losses_sum = nn.losses.cosine_similarity_loss(
embeddings1, embeddings2, reduction="sum"
)
expected_sum = mx.sum(expected_none)
self.assertTrue(mx.allclose(losses_sum, expected_sum))
def test_margin_ranking_loss(self):
inputs1 = mx.array([-0.573409, -0.765166, -0.0638])
inputs2 = mx.array([0.75596, 0.225763, 0.256995])
targets = mx.array([1, 1, -1])
# Test with no margin
losses = nn.losses.margin_ranking_loss(
inputs1, inputs2, targets, reduction="none"
)
expected = mx.array([1.329369, 0.990929, 0.0])
self.assertTrue(mx.allclose(losses, expected))
# Test with margin
losses = nn.losses.margin_ranking_loss(
inputs1, inputs2, targets, margin=0.5, reduction="none"
)
expected = mx.array([1.829369, 1.490929, 0.179205])
self.assertTrue(mx.allclose(losses, expected))
if __name__ == "__main__":
mlx_tests.MLXTestRunner()
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