FastVLM_SANA / ml-stable-diffusion /mlx /python /tests /test_fast_sdpa.py

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	import math
	import unittest

	import mlx.core as mx
	import mlx_tests
	import numpy as np


	def mlx_ref_attn(q, k, v, scale=1.0, mask=None, sinks=None):
	q_dtype = q.dtype
	q = q * mx.array(scale, q_dtype)
	n_q_heads = q.shape[-3]
	n_kv_heads = k.shape[-3]
	n_repeats = n_q_heads // n_kv_heads

	B = q.shape[0]
	L = q.shape[2]
	kL = k.shape[2]

	if n_repeats > 1:
	q = mx.reshape(q, [B, n_kv_heads, n_repeats, L, -1])
	k = mx.expand_dims(k, 2)
	v = mx.expand_dims(v, 2)

	scores = q @ mx.swapaxes(k, -1, -2)
	if mask is not None:

	if mask == "causal":
	q_offset = max(0, kL - L)
	q_indices = mx.arange(q_offset, q_offset + L)
	k_indices = mx.arange(kL)
	mask = q_indices[:, None] >= k_indices[None]

	if n_repeats > 1 and mask.ndim >= 3:
	if mask.shape[-3] == 1:
	mask = mx.expand_dims(mask, -3)
	else:
	mask = mx.unflatten(mask, -3, (n_kv_heads, n_repeats))

	if mask.dtype == mx.bool_:
	scores = mx.where(mask, scores, mx.finfo(scores.dtype).min)
	else:
	scores += mask

	if sinks is not None:
	sinks = mx.expand_dims(sinks, (0, 2, 3))
	if n_repeats > 1:
	sinks = mx.unflatten(sinks, 1, (n_kv_heads, n_repeats))
	score_shape = list(scores.shape)
	score_shape[-1] = 1
	sinks = mx.broadcast_to(sinks, score_shape)
	scores = mx.concatenate([sinks, scores], axis=-1)

	scores = mx.softmax(scores, axis=-1, precise=True)
	if sinks is not None:
	scores = scores[..., 1:]

	out = scores @ v
	if n_repeats > 1:
	out = mx.reshape(out, [B, n_q_heads, L, -1])

	return out


	def do_attention(f, q, k, v, scale, mask=None, transpose=False):
	if transpose:
	q_t = mx.transpose(q, (0, 2, 1, 3))
	k_t = mx.transpose(k, (0, 2, 1, 3))
	v_t = mx.transpose(v, (0, 2, 1, 3))
	o_t = f(q_t, k_t, v_t, scale=scale, mask=mask)
	return mx.transpose(o_t, (0, 2, 1, 3))
	else:
	return f(q, k, v, scale=scale, mask=mask)


	def prepare_inputs(B, qL, kL, D, qH, kH, mask, transpose, dtype):
	np.random.seed(0)
	np_dtype = getattr(np, dtype)

	shape_q = (B, qL, qH, D) if transpose else (B, qH, qL, D)
	shape_kv = (B, kL, kH, D) if transpose else (B, kH, kL, D)

	scale = 1.0 / math.sqrt(D)

	q_np = np.random.normal(0.0, 0.5, shape_q).astype(np_dtype)
	k_np = np.random.normal(0.0, 0.5, shape_kv).astype(np_dtype)
	v_np = np.random.normal(0.0, scale, shape_kv).astype(np_dtype)

	q_mx = mx.array(q_np)
	k_mx = mx.array(k_np)
	v_mx = mx.array(v_np)

	if mask is not None:
	if mask == "additive":
	mask_np = np.random.normal(0.0, 0.5, (B, qH, qL, kL)).astype(np_dtype)
	mask = mx.array(mask_np)
	elif mask == "bool":
	mask_np = np.random.uniform(0.0, 1.0, (B, qH, qL, kL)) < 0.5
	mask = mx.array(mask_np)

	return q_mx, k_mx, v_mx, scale, mask


	# SDPA for MHA (n_heads == n_kv_heads)
	def mlx_primitives_sdpa(q, k, v, scale, mask=None):
	p = (q * scale) @ k.transpose(0, 1, 3, 2)
	if mask is not None:
	if mask == "causal":
	q_offset = max(0, k.shape[2] - q.shape[2])
	q_indices = mx.arange(q_offset, q_offset + q.shape[2])
	k_indices = mx.arange(k.shape[2])
	mask = q_indices[:, None] >= k_indices[None]
	p = mx.where(mask, p, mx.finfo(mx.float32).min)
	elif mask.dtype == mx.bool_:
	p = mx.where(mask, p, mx.finfo(mx.float32).min)
	else:
	p += mask
	scores = mx.softmax(p.astype(mx.float32), axis=-1).astype(p.dtype)
	return scores @ v


	# SDPA for GQA (n_heads > n_kv_heads, n_kv_heads > 1, n_heads % n_kv_heads == 0)
	def mlx_primitives_sdpa_with_gqa(q, k, v, scale, mask=None):
	n_repeats = q.shape[1] // k.shape[1]

	# borrowing kv cache tiling from mlx-examples/llms/mistral/mistral.py
	n_heads = q.shape[1]
	B = q.shape[0]
	L = k.shape[2]

	def repeat(a):
	a = mx.concatenate([mx.expand_dims(a, 2)] * n_repeats, axis=2)
	return a.reshape([B, n_heads, L, -1])

	k, v = map(repeat, (k, v))

	return mlx_primitives_sdpa(q, k, v, scale, mask=mask)


	class TestFastSelfAttentionSDPA(mlx_tests.MLXTestCase):
	def test_fast_sdpa(self):
	# Not yet supported:
	# * K pre-transposed in kernel, V pre-transposed in kernel
	np.random.seed(0)
	R = 20
	L = R
	Dk = 64
	H = 3
	scale = float(1.0 / np.sqrt(Dk))
	q_npy = np.random.normal(0.0, 1.0, (1, H, R, Dk)).astype(np.float32)
	k_npy = np.random.normal(0.0, 1.0, (1, H, L, Dk)).astype(np.float32)
	v_npy = np.random.normal(0.0, 1.0, (1, H, L, Dk)).astype(np.float32)

	q_mlx = mx.array(q_npy)
	k_mlx = mx.array(k_npy)
	v_mlx = mx.array(v_npy)

	reference = mlx_primitives_sdpa(q_mlx, k_mlx, v_mlx, scale)

	o_mlx = mx.fast.scaled_dot_product_attention(
	q_mlx, k_mlx, v_mlx, scale=scale, mask=None
	)

	self.assertListEqual(list(reference.shape), list(o_mlx.shape))
	self.assertTrue(mx.allclose(o_mlx, reference, atol=1e-4))

	dtypes = [np.float32]

	Dk = 64

	if self.is_apple_silicon or mx.cuda.is_available():
	dtypes.append(np.half)

	for SEQUENCE_LENGTH in [63, 129, 400]:
	for DTYPE in dtypes:
	B = 2
	H = 24
	n_kv_heads = H
	q_npy = np.random.normal(0.0, 1.0, (B, H, SEQUENCE_LENGTH, Dk)).astype(
	DTYPE
	)
	k_npy = np.random.normal(
	0.0, 1.0, (B, n_kv_heads, SEQUENCE_LENGTH, Dk)
	).astype(DTYPE)
	v_npy = np.random.normal(
	0.0, 1.0, (B, n_kv_heads, SEQUENCE_LENGTH, Dk)
	).astype(DTYPE)

	q_mlx = mx.array(q_npy)
	k_mlx = mx.array(k_npy)
	v_mlx = mx.array(v_npy)

	reference = mlx_primitives_sdpa_with_gqa(q_mlx, k_mlx, v_mlx, scale)
	o_mlx = mx.fast.scaled_dot_product_attention(
	q_mlx,
	k_mlx,
	v_mlx,
	scale=scale,
	)

	self.assertListEqual(list(reference.shape), list(o_mlx.shape))
	rtol = 1e-3
	atol = 1e-2

	if SEQUENCE_LENGTH > 500:
	rtol = 1e-2

	if DTYPE == np.half:
	rtol = 1e-2

	self.assertTrue(mx.allclose(o_mlx, reference, rtol=rtol, atol=atol))


	class TestFastSDPA(mlx_tests.MLXTestCase):
	def test_fast_sdpa(self):
	# Not yet supported:
	# * K pre-transposed in kernel, V pre-transposed in kernel
	np.random.seed(0)
	L = 43
	R = 1
	Dk = 128
	scale = float(1.0 / np.sqrt(128.0))
	q_npy = np.random.normal(0.0, 1.0, (1, 32, R, Dk)).astype(np.float32)
	k_npy = np.random.normal(0.0, 1.0, (1, 32, L, Dk)).astype(np.float32)
	v_npy = np.random.normal(0.0, 1.0, (1, 32, L, Dk)).astype(np.float32)

	q_mlx = mx.array(q_npy)
	k_mlx = mx.array(k_npy)
	v_mlx = mx.array(v_npy)

	reference = mlx_primitives_sdpa(q_mlx, k_mlx, v_mlx, scale)

	o_mlx = mx.fast.scaled_dot_product_attention(
	q_mlx, k_mlx, v_mlx, scale=scale, mask=None
	)

	self.assertListEqual(list(reference.shape), list(o_mlx.shape))
	self.assertTrue(mx.allclose(o_mlx, reference, atol=1e-4))

	B = 1
	H = 32
	dtypes = [np.float32]
	if self.is_apple_silicon or mx.cuda.is_available():
	dtypes.append(np.half)

	for SEQUENCE_LENGTH in [1, 7, 9, 32, 63, 67, 129, 400, 2000]:
	for DO_GQA in [0, 1]:
	for DTYPE in dtypes:
	n_kv_heads = 8 if DO_GQA else 32
	q_npy = np.random.normal(0.0, 1.0, (B, H, R, Dk)).astype(DTYPE)
	k_npy = np.random.normal(
	0.0, 1.0, (B, n_kv_heads, SEQUENCE_LENGTH, Dk)
	).astype(DTYPE)
	v_npy = np.random.normal(
	0.0, 1.0, (B, n_kv_heads, SEQUENCE_LENGTH, Dk)
	).astype(DTYPE)

	q_mlx = mx.array(q_npy)
	k_mlx = mx.array(k_npy)
	v_mlx = mx.array(v_npy)

	reference = mlx_primitives_sdpa_with_gqa(q_mlx, k_mlx, v_mlx, scale)
	o_mlx = mx.fast.scaled_dot_product_attention(
	q_mlx, k_mlx, v_mlx, scale=scale
	)

	self.assertListEqual(list(reference.shape), list(o_mlx.shape))
	rtol = 1e-5
	atol = 1e-1

	if SEQUENCE_LENGTH > 500:
	rtol = 1e-2

	if DTYPE == np.half:
	rtol = 1e-2

	self.assertTrue(mx.allclose(o_mlx, reference, rtol=rtol, atol=atol))
	q = mx.random.normal(shape=(1, 32, 1, Dk))
	k = mx.random.normal(shape=(1, 32, 32, Dk))
	v = mx.random.normal(shape=(1, 32, 128, Dk))

	atol = 1e-6
	y = mlx_primitives_sdpa(q, k, v[:, :, :32], scale)
	y_hat = mx.fast.scaled_dot_product_attention(q, k, v[:, :, :32], scale=scale)
	self.assertTrue(mx.allclose(y, y_hat, atol=atol))

	# Test with per-example mask
	q = mx.random.normal(shape=(2, 8, 4, 32))
	k = mx.random.normal(shape=(2, 2, 8, 32))
	v = mx.random.normal(shape=(2, 2, 8, 32))
	mask = 10 * mx.random.normal(shape=(2, 1, 4, 8))
	y = mlx_primitives_sdpa_with_gqa(q, k, v, scale, mask=mask)
	y_hat = mx.fast.scaled_dot_product_attention(q, k, v, scale=scale, mask=mask)
	self.assertTrue(mx.allclose(y, y_hat, atol=atol))

	# Test with boolean causal mask
	indices = mx.arange(8)
	bool_mask = indices[:, None] >= indices[None]
	additive_mask = (~bool_mask).astype(mx.float32) * mx.finfo(mx.float32).min
	x = mx.random.normal(shape=(1, 2, 8, 32))
	y = mlx_primitives_sdpa_with_gqa(x, x, x, scale, mask=additive_mask)
	y_hat = mx.fast.scaled_dot_product_attention(
	x, x, x, scale=scale, mask=bool_mask
	)
	self.assertTrue(mx.allclose(y, y_hat, atol=atol))

	def test_fast_sdpa_vector_kv_transposed_head_seq(self):
	D = 64
	Nq = 4
	Nkv = 1
	scale = 1.0
	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, 1, D))

	lengths = [43, 4096]
	for L in lengths:
	k = 5e-1 * mx.random.normal(shape=(1, L, Nkv, D))
	v = 5e-1 * mx.random.normal(shape=(1, L, Nkv, D))
	k = k.swapaxes(1, 2)
	v = v.swapaxes(1, 2)
	masks = [
	mx.array(True),
	mx.array([True] * (L - 10) + [False] * 10),
	mx.random.uniform(shape=(Nq, 1, L)) > 0.2,
	mx.random.uniform(shape=(L, 1, Nq)).T > 0.2,
	]

	for m in masks:
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=m)
	out = mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=m,
	)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_fast_sdpa_vector(self):
	D = 64
	L = 43
	Nq = 4
	Nkv = 1
	scale = 1.0
	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, 1, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))

	with self.assertRaises(ValueError):
	mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=mx.full((Nq, 2, L), False),
	)

	masks = [
	None,
	mx.array(True),
	mx.array([True] * (L - 10) + [False] * 10),
	mx.random.uniform(shape=(Nq, 1, L)) > 0.2,
	mx.random.uniform(shape=(L, 1, Nq)).T > 0.2,
	mx.random.uniform(shape=(Nq, 1, L)),
	mx.random.uniform(shape=(L, 1, Nq)).T,
	mx.log(mx.random.uniform(shape=(Nq, 1, L)) > 0.2),
	mx.log(mx.random.uniform(shape=(L, 1, Nq)).T > 0.2),
	"causal",
	]
	for m in masks:
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=m)
	out = mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=m,
	)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	L = 4096
	scale = 1.0
	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, 1, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))

	masks = [
	mx.array(True),
	mx.array([True] * (L - 10) + [False] * 10),
	mx.random.uniform(shape=(Nq, 1, L)) > 0.2,
	mx.random.uniform(shape=(L, 1, Nq)).T > 0.2,
	mx.random.uniform(shape=(Nq, 1, L)),
	mx.random.uniform(shape=(L, 1, Nq)).T,
	mx.log(mx.random.uniform(shape=(Nq, 1, L)) > 0.2),
	mx.log(mx.random.uniform(shape=(L, 1, Nq)).T > 0.2),
	"causal",
	]
	for m in masks:
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=m)
	out = mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=m,
	)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_fully_masked(self):
	Lkv = 8
	mask = mx.array(False)
	for D in [128]:
	for Lq in [1, 8, 32]:
	q = mx.random.normal(shape=(1, 4, Lq, D))
	k = mx.random.normal(shape=(1, 4, Lkv, D))
	v = mx.random.normal(shape=(1, 4, Lkv, D))

	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=mask, scale=1)
	self.assertFalse(mx.any(mx.isnan(out)))

	def test_inf_score(self):
	Lkv = 8
	for D in [4, 128]:
	for Lq in [1, 8]:
	q = mx.ones(shape=(1, 4, Lq, D))
	k = mx.ones(shape=(1, 4, Lkv, D))
	v = mx.random.normal(shape=(1, 4, Lkv, D))
	k[..., 0, :] = -float("inf")
	ref = mlx_primitives_sdpa(q, k, v, scale=1, mask=None)
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_fast_sdpa_few_query(self):
	D = 64
	L = 43
	Lq = 8
	Nq = 8
	Nkv = 1
	scale = 1.0
	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Lq, Nq, D))
	q = q.swapaxes(1, 2)
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))

	masks = [
	None,
	mx.array(True),
	mx.array([True] * (L - 10) + [False] * 10),
	mx.random.uniform(shape=(Nq, 1, L)) > 0.2,
	mx.random.uniform(shape=(L, 1, Nq)).T > 0.2,
	"causal",
	]
	for m in masks:
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=m)
	out = mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=m,
	)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	L = 4096
	scale = 1.0
	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, Lq, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))

	masks = [
	None,
	mx.array(True),
	mx.array([True] * (L - 10) + [False] * 10),
	mx.random.uniform(shape=(Nq, 1, L)) > 0.2,
	mx.random.uniform(shape=(L, 1, Nq)).T > 0.2,
	"causal",
	]
	for m in masks:
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=m)
	out = mx.fast.scaled_dot_product_attention(
	q,
	k,
	v,
	scale=scale,
	mask=m,
	)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	@unittest.skip("Different head and value dims is not enabled")
	def test_fast_sdpa_vector_value_dims(self):
	D = 192
	V = 128
	Nq = 4
	Nkv = 1
	scale = 1.0
	mx.random.seed(0)

	for L in [43, 128, 237, 8192]:
	q = 5e-1 * mx.random.normal(shape=(1, Nq, 1, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, V))
	ref = mlx_primitives_sdpa(q, k, v, scale)
	out = mx.fast.scaled_dot_product_attention(q, k, v, scale=scale)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_sdpa_vector_batched(self):
	D = 64
	q = mx.random.normal(shape=(2, 1, 3, D))
	k = mx.random.normal(shape=(2, 1, 3, D))
	v = mx.random.normal(shape=(2, 1, 3, D))

	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1.0)
	ref = mlx_ref_attn(q, k, v)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	q = mx.random.normal(shape=(2, 4, 3, D))
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1.0)
	ref = mlx_ref_attn(q, k, v)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	q = mx.random.normal(shape=(2, 3, 4, D)).swapaxes(1, 2)
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1.0)
	ref = mlx_ref_attn(q, k, v)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	k = mx.random.normal(shape=(2, 3, 1, D)).swapaxes(1, 2)
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1.0)
	ref = mlx_ref_attn(q, k, v)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	q = mx.random.normal(shape=(2, 4, 3, D))
	k = mx.random.normal(shape=(2, 3, 2, D)).swapaxes(1, 2)
	v = mx.random.normal(shape=(2, 2, 3, D))
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=None, scale=1.0)
	ref = mlx_ref_attn(q, k, v)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	q = mx.random.normal(shape=(2, 4, 3, D))
	k = mx.random.normal(shape=(2, 1, 3, D))
	v = mx.random.normal(shape=(2, 1, 3, D))
	mask = 10 * mx.random.normal(shape=(1, 2, 3, 3)).swapaxes(0, 1)
	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=mask, scale=1.0)
	ref = mlx_ref_attn(q, k, v, mask=mask)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))


	class TestSDPA(mlx_tests.MLXTestCase):
	@property
	def dtypes(self):
	return ["float32", "float16"] if mx.metal.is_available() else ["float32"]

	def test_sdpa(self):
	if not mx.metal.is_available():
	return

	# fmt: off
	shapes_64 = (
	# ( B, qsl, ksl, head_dim, n_qh, n_kvh)
	( 1, 128, 128, 64, 32, 32),
	( 1, 64, 128, 64, 32, 32),
	( 1, 65, 128, 64, 32, 8),
	( 1, 64, 127, 64, 32, 8),
	( 1, 65, 127, 64, 32, 8),
	( 1, 127, 65, 64, 32, 8),
	)

	shapes_128 = (
	# ( B, qsl, ksl, head_dim, n_qh, n_kvh)
	( 1, 128, 128, 128, 32, 8),
	( 1, 64, 128, 128, 32, 8),
	( 1, 65, 127, 128, 32, 8),
	( 1, 127, 65, 128, 32, 8),
	)
	# fmt: on

	shapes = shapes_64 + shapes_128
	masks = [None, "additive", "bool", "causal"]
	transposes = (False, True)

	for dtype in self.dtypes:
	for t in transposes:
	for mask_str in masks:
	for B, qL, kL, D, qH, kH in shapes:
	with self.subTest(
	B=B,
	qsl=qL,
	ksl=kL,
	head_dim=D,
	n_q_heads=qH,
	n_kv_heads=kH,
	mask=mask_str,
	transpose=t,
	dtype=dtype,
	):

	np.random.seed(0)
	q_mx, k_mx, v_mx, scale, mask = prepare_inputs(
	B, qL, kL, D, qH, kH, mask_str, t, dtype
	)

	out_ref = do_attention(
	mlx_ref_attn, q_mx, k_mx, v_mx, scale, mask, t
	)

	out_fst = do_attention(
	mx.fast.scaled_dot_product_attention,
	q_mx,
	k_mx,
	v_mx,
	scale,
	mask,
	t,
	)

	atol = 2e-5 if dtype == "float32" else 3e-4

	self.assertListEqual(
	list(out_ref.shape), list(out_fst.shape)
	)

	diff = mx.abs(out_fst - out_ref) - atol * mx.abs(out_ref)
	self.assertLessEqual(mx.max(diff).item(), atol)

	def test_sdpa_broadcast_mask(self):
	mask = mx.array(True)
	D = 64
	Nq = 4
	Nkv = 1
	scale = 1.0
	L = 256

	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, L, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=mask)
	out = mx.fast.scaled_dot_product_attention(q, k, v, scale=scale, mask=mask)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_sdpa_noncontiguous_inputs(self):
	mask = mx.ones(shape=(4, 1, 7, 7), dtype=mx.bool_)
	mx.random.seed(0)
	q = mx.random.normal(shape=(4, 7, 32, 64)).swapaxes(1, 2)

	k = mx.random.normal(shape=(4, 7, 8, 64)).swapaxes(1, 2)
	v = mx.random.normal(shape=(4, 7, 8, 64)).swapaxes(1, 2)
	out = mx.fast.scaled_dot_product_attention(q, k, v, scale=1.0, mask=mask)
	ref = mlx_ref_attn(q, k, v, scale=1.0, mask=mask)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_sdpa_promote_mask(self):
	mask = mx.array(2.0, mx.bfloat16)
	D = 64
	Nq = 4
	Nkv = 1
	scale = 1.0
	L = 256

	mx.random.seed(0)
	q = 5e-1 * mx.random.normal(shape=(1, Nq, L, D))
	k = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	v = 5e-1 * mx.random.normal(shape=(1, Nkv, L, D))
	ref = mlx_primitives_sdpa(q, k, v, scale, mask=mask)
	out = mx.fast.scaled_dot_product_attention(q, k, v, scale=scale, mask=mask)
	self.assertTrue(mx.allclose(ref, out, atol=1e-4, rtol=1e-4))

	def test_sdpa_nan_bug(self):
	N = 128
	q_shape = (1, 1, N, 128)
	kv_shape = (1, 1, N, 128)
	q = mx.random.uniform(shape=q_shape)
	k = mx.random.uniform(shape=kv_shape)
	v = mx.random.uniform(shape=kv_shape)

	# Make boolean window causal mask
	linds = rinds = mx.arange(N)
	linds = linds[:, None]
	rinds = rinds[None]
	mask = linds >= rinds
	mask = mask & (linds <= rinds + 111)

	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=mask, scale=1.0)
	expected = mlx_ref_attn(q, k, v, mask=mask, scale=1.0)
	self.assertFalse(mx.isnan(out).any().item())
	self.assertLessEqual(mx.abs(out - expected).max().item(), 1e-4)

	# And an additive one
	mask = mx.log(mask)

	out = mx.fast.scaled_dot_product_attention(q, k, v, mask=mask, scale=1.0)
	expected = mlx_ref_attn(q, k, v, mask=mask, scale=1.0)
	self.assertFalse(mx.isnan(out).any().item())
	self.assertLessEqual(mx.abs(out - expected).max().item(), 1e-4)

	def test_sdpa_attention_sinks(self):
	B = 2
	N_q = N_kv = 8
	T_q = T_kv = 128
	D = 64

	q = mx.random.normal(shape=(B, N_q, T_q, D))
	k = mx.random.normal(shape=(B, N_kv, T_kv, D))
	v = mx.random.normal(shape=(B, N_kv, T_kv, D))
	scale = D**-0.5

	# sinks should promote to correct type
	sinks = mx.random.normal(shape=(N_q,))
	with self.assertRaises(ValueError):
	mx.fast.scaled_dot_product_attention(
	q.astype(mx.float16),
	k.astype(mx.float16),
	v.astype(mx.float16),
	scale=scale,
	sinks=sinks,
	)

	# Wrong shapes
	sinks = mx.random.normal(shape=(N_q + 1,))
	with self.assertRaises(ValueError):
	mx.fast.scaled_dot_product_attention(q, k, v, scale=scale, sinks=sinks)

	sinks = mx.random.normal(shape=())
	with self.assertRaises(ValueError):
	mx.fast.scaled_dot_product_attention(q, k, v, scale=scale, sinks=sinks)

	for T_kv in [128, 4096]:
	for T_q in [1, 128]:
	for N_kv in [2, 8]:
	q = mx.random.normal(shape=(B, N_q, T_q, D))
	k = mx.random.normal(shape=(B, N_kv, T_kv, D))
	v = mx.random.normal(shape=(B, N_kv, T_kv, D))
	sinks = 10 * mx.random.normal(shape=(N_q,))

	expected = mlx_ref_attn(q, k, v, scale, sinks=sinks)
	out = mx.fast.scaled_dot_product_attention(
	q, k, v, scale=scale, sinks=sinks
	)
	self.assertTrue(mx.allclose(out, expected, atol=1e-5))


	if __name__ == "__main__":
	mlx_tests.MLXTestRunner(failfast=True)