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	# Copyright (c) 2023, Tri Dao.

	from typing import Optional, Union

	import torch
	import torch.nn as nn

	# isort: off
	# We need to import the CUDA kernels after importing torch
	from ._ops import ops

	# isort: on


	def maybe_contiguous(x):
	return x.contiguous() if x is not None and x.stride(-1) != 1 else x


	def _flash_attn_forward(
	q,
	k,
	v,
	k_new,
	v_new,
	qv,
	out,
	cu_seqlens_q,
	cu_seqlens_k,
	cu_seqlens_k_new,
	seqused_q,
	seqused_k,
	max_seqlen_q,
	max_seqlen_k,
	page_table,
	kv_batch_idx,
	leftpad_k,
	rotary_cos,
	rotary_sin,
	seqlens_rotary,
	q_descale,
	k_descale,
	v_descale,
	softmax_scale,
	causal,
	window_size=(-1, -1),
	softcap=0.0,
	rotary_interleaved=True,
	scheduler_metadata=None,
	num_splits=1,
	pack_gqa=None,
	sm_margin=0,
	s_aux=None):
	q, k, k_new, v_new = [maybe_contiguous(x) for x in (q, k, k_new, v_new)]
	v = v.contiguous() if v.stride(-1) != 1 and v.stride(-3) != 1 else v
	cu_seqlens_q, cu_seqlens_k, cu_seqlens_k_new = [
	maybe_contiguous(x) for x in (cu_seqlens_q, cu_seqlens_k, cu_seqlens_k_new)
	]
	seqused_q, seqused_k = [maybe_contiguous(x) for x in (seqused_q, seqused_k)]
	page_table, kv_batch_idx, leftpad_k = [
	maybe_contiguous(x) for x in (page_table, kv_batch_idx, leftpad_k)
	]
	rotary_cos, rotary_sin = [maybe_contiguous(x) for x in (rotary_cos, rotary_sin)]
	seqlens_rotary = maybe_contiguous(seqlens_rotary)
	out, softmax_lse, *rest = ops.fwd(
	q,
	k,
	v,
	k_new,
	v_new,
	qv,
	out,
	cu_seqlens_q,
	cu_seqlens_k,
	cu_seqlens_k_new,
	seqused_q,
	seqused_k,
	max_seqlen_q,
	max_seqlen_k,
	page_table,
	kv_batch_idx,
	leftpad_k,
	rotary_cos,
	rotary_sin,
	seqlens_rotary,
	q_descale,
	k_descale,
	v_descale,
	softmax_scale,
	causal,
	window_size[0],
	window_size[1],
	softcap,
	rotary_interleaved,
	scheduler_metadata,
	num_splits,
	pack_gqa,
	sm_margin,
	s_aux
	)
	return out, softmax_lse, *rest


	def _flash_attn_backward(
	dout,
	q,
	k,
	v,
	out,
	softmax_lse,
	cu_seqlens_q,
	cu_seqlens_k,
	sequed_q,
	sequed_k,
	max_seqlen_q,
	max_seqlen_k,
	dq,
	dk,
	dv,
	softmax_scale,
	causal,
	window_size=(-1, -1),
	softcap=0.0,
	deterministic=False,
	sm_margin=0,
	):
	# dq, dk, dv are allocated by us so they should already be contiguous
	dout, q, k, v, out = [maybe_contiguous(x) for x in (dout, q, k, v, out)]
	dq, dk, dv, softmax_d, *rest = ops.bwd(
	dout,
	q,
	k,
	v,
	out,
	softmax_lse,
	dq,
	dk,
	dv,
	cu_seqlens_q,
	cu_seqlens_k,
	sequed_q,
	sequed_k,
	max_seqlen_q,
	max_seqlen_k,
	softmax_scale,
	causal,
	window_size[0],
	window_size[1],
	softcap,
	deterministic,
	sm_margin,
	)
	return dq, dk, dv, softmax_d


	class FlashAttnQKVPackedFunc(torch.autograd.Function):
	@staticmethod
	def forward(
	ctx,
	qkv,
	softmax_scale,
	causal,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	deterministic=False,
	num_heads_q=None,
	):
	if softmax_scale is None:
	softmax_scale = qkv.shape[-1] ** (-0.5)
	if qkv.dim() == 5:
	assert qkv.shape[-3] == 3
	q, k, v = qkv.unbind(dim=-3)
	else:
	assert qkv.dim() == 4
	assert num_heads_q is not None
	num_heads_k = (qkv.shape[2] - num_heads_q) // 2
	assert num_heads_k * 2 + num_heads_q == qkv.shape[2]
	q, k, v = qkv.split([num_heads_q, num_heads_k, num_heads_k], dim=-2)
	out, softmax_lse, *rest = _flash_attn_forward(
	q,
	k,
	v,
	None, None, # k_new, v_new
	None, # qv
	None, # out
	None, None, None, # cu_seqlens_q/k/k_new
	None, None, # seqused_q/k
	None, None, # max_seqlen_q/k
	None, None, None, # page_table, kv_batch_idx, leftpad_k,
	None, None, None, # rotary_cos/sin, seqlens_rotary
	q_descale, k_descale, v_descale,
	softmax_scale,
	causal=causal,
	window_size=window_size,
	softcap=softcap,
	)
	# ctx.save_for_backward(q, k, v, out_padded, softmax_lse)
	ctx.save_for_backward(q, k, v, out, softmax_lse)
	ctx.softmax_scale = softmax_scale
	ctx.causal = causal
	ctx.window_size = window_size
	ctx.softcap = softcap
	ctx.deterministic = deterministic
	ctx.ndim = qkv.dim()
	# return out, softmax_lse
	return out

	@staticmethod
	def backward(ctx, dout, *args):
	q, k, v, out, softmax_lse = ctx.saved_tensors
	if ctx.ndim == 5:
	qkv_shape = q.shape[:-2] + (3, *q.shape[-2:])
	dqkv = torch.empty(qkv_shape, dtype=q.dtype, device=q.device)
	dq, dk, dv = dqkv.unbind(dim=-3)
	else:
	num_heads_q = q.shape[2]
	num_heads_k = k.shape[2]
	qkv_shape = q.shape[:-2] + (num_heads_q + num_heads_k * 2, *q.shape[-1:])
	dqkv = torch.empty(qkv_shape, dtype=q.dtype, device=q.device)
	dq, dk, dv = dqkv.split([num_heads_q, num_heads_k, num_heads_k], dim=-2)
	_flash_attn_backward(
	dout,
	q,
	k,
	v,
	out,
	softmax_lse,
	None, None, # cu_seqlens_q, cu_seqlens_k,
	None, None, # sequed_q, sequed_k,
	None, None, # max_seqlen_q, max_seqlen_k,
	dq,
	dk,
	dv,
	ctx.softmax_scale,
	ctx.causal,
	ctx.window_size,
	ctx.softcap,
	ctx.deterministic,
	)
	dqkv = dqkv[..., : dout.shape[-1]] # We could have padded the head dimension
	return dqkv, None, None, None, None, None, None, None, None, None, None


	class FlashAttnFunc(torch.autograd.Function):

	@staticmethod
	def forward(
	ctx,
	q,
	k,
	v,
	softmax_scale,
	causal,
	qv=None,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	num_splits=1,
	pack_gqa=None,
	deterministic=False,
	sm_margin=0,
	s_aux=None,
	):
	if softmax_scale is None:
	softmax_scale = (q.shape[-1] + (qv.shape[-1] if qv is not None else 0)) ** (-0.5)
	# out, q, k, v, out_padded, softmax_lse = _flash_attn_forward(
	out, softmax_lse, *rest = _flash_attn_forward(
	q,
	k,
	v,
	None, None, # k_new, v_new
	qv, # qv
	None, # out
	None, None, None, # cu_seqlens_q/k/k_new
	None, None, # seqused_q/k
	None, None, # max_seqlen_q/k
	None, None, None, # page_table, kv_batch_idx, leftpad_k,
	None, None, None, # rotary_cos/sin, seqlens_rotary
	q_descale, k_descale, v_descale,
	softmax_scale,
	causal=causal,
	window_size=window_size,
	softcap=softcap,
	num_splits=num_splits,
	pack_gqa=pack_gqa,
	sm_margin=sm_margin,
	s_aux=s_aux,
	)
	# ctx.save_for_backward(q, k, v, out_padded, softmax_lse)
	ctx.save_for_backward(q, k, v, out, softmax_lse)
	ctx.softmax_scale = softmax_scale
	ctx.causal = causal
	ctx.window_size = window_size
	ctx.softcap = softcap
	ctx.deterministic = deterministic
	ctx.sm_margin = sm_margin
	return out, softmax_lse

	@staticmethod
	def backward(ctx, dout, *args):
	q, k, v, out, softmax_lse = ctx.saved_tensors
	dq, dk, dv = torch.empty_like(q), torch.empty_like(k), torch.empty_like(v)
	_flash_attn_backward(
	dout,
	q,
	k,
	v,
	out,
	softmax_lse,
	None, None, # cu_seqlens_q, cu_seqlens_k,
	None, None, # sequed_q, sequed_k,
	None, None, # max_seqlen_q, max_seqlen_k,
	dq,
	dk,
	dv,
	ctx.softmax_scale,
	ctx.causal,
	ctx.window_size,
	ctx.softcap,
	ctx.deterministic,
	ctx.sm_margin,
	)
	dq = dq[..., : dout.shape[-1]] # We could have padded the head dimension
	dk = dk[..., : dout.shape[-1]]
	dv = dv[..., : dout.shape[-1]]
	return dq, dk, dv, None, None, None, None, None, None, None, None, None, None, None, None, None, None


	class FlashAttnVarlenFunc(torch.autograd.Function):

	@staticmethod
	def forward(
	ctx,
	q,
	k,
	v,
	cu_seqlens_q,
	cu_seqlens_k,
	seqused_q,
	seqused_k,
	max_seqlen_q,
	max_seqlen_k,
	softmax_scale,
	causal,
	qv=None,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	num_splits=1,
	pack_gqa=None,
	deterministic=False,
	sm_margin=0,
	s_aux=None,
	):
	if softmax_scale is None:
	softmax_scale = (q.shape[-1] + (qv.shape[-1] if qv is not None else 0)) ** (-0.5)
	# out, q, k, v, out_padded, softmax_lse = _flash_attn_varlen_forward(
	out, softmax_lse, *rest = _flash_attn_forward(
	q,
	k,
	v,
	None, None, # k_new, v_new
	qv, # qv
	None, # out
	cu_seqlens_q,
	cu_seqlens_k,
	None, # cu_seqlens_k_new
	seqused_q,
	seqused_k,
	max_seqlen_q,
	max_seqlen_k,
	None, None, None, # page_table, kv_batch_idx, leftpad_k,
	None, None, None, # rotary_cos/sin, seqlens_rotary
	q_descale, k_descale, v_descale,
	softmax_scale,
	causal=causal,
	window_size=window_size,
	softcap=softcap,
	num_splits=num_splits,
	pack_gqa=pack_gqa,
	sm_margin=sm_margin,
	s_aux=s_aux,
	)
	# ctx.save_for_backward(q, k, v, out_padded, softmax_lse, cu_seqlens_q, cu_seqlens_k, seqused_q, seqused_k)
	ctx.save_for_backward(q, k, v, out, softmax_lse, cu_seqlens_q, cu_seqlens_k, seqused_q, seqused_k)
	ctx.max_seqlen_q = max_seqlen_q
	ctx.max_seqlen_k = max_seqlen_k
	ctx.softmax_scale = softmax_scale
	ctx.causal = causal
	ctx.window_size = window_size
	ctx.softcap = softcap
	ctx.deterministic = deterministic
	ctx.sm_margin = sm_margin
	return out, softmax_lse

	@staticmethod
	def backward(ctx, dout, *args):
	q, k, v, out, softmax_lse, cu_seqlens_q, cu_seqlens_k, seqused_q, seqused_k = ctx.saved_tensors
	dq, dk, dv = torch.empty_like(q), torch.empty_like(k), torch.empty_like(v)
	_flash_attn_backward(
	dout,
	q,
	k,
	v,
	out,
	softmax_lse,
	cu_seqlens_q,
	cu_seqlens_k,
	seqused_q,
	seqused_k,
	ctx.max_seqlen_q,
	ctx.max_seqlen_k,
	dq,
	dk,
	dv,
	ctx.softmax_scale,
	ctx.causal,
	ctx.window_size,
	ctx.softcap,
	ctx.deterministic,
	ctx.sm_margin,
	)
	dq = dq[..., : dout.shape[-1]] # We could have padded the head dimension
	dk = dk[..., : dout.shape[-1]]
	dv = dv[..., : dout.shape[-1]]
	return dq, dk, dv, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None, None


	def flash_attn_qkvpacked_func(
	qkv,
	softmax_scale=None,
	causal=False,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	deterministic=False,
	num_heads_q=None,
	):
	"""dropout_p should be set to 0.0 during evaluation
	If Q, K, V are already stacked into 1 tensor, this function will be faster than
	calling flash_attn_func on Q, K, V since the backward pass avoids explicit concatenation
	of the gradients of Q, K, V.
	For multi-query and grouped-query attention (MQA/GQA), please see
	flash_attn_kvpacked_func and flash_attn_func.

	If window_size != (-1, -1), implements sliding window local attention. Query at position i
	will only attend to keys between [i - window_size[0], i + window_size[1]] inclusive.

	Arguments:
	qkv: (batch_size, seqlen, 3, nheads, headdim)
	dropout_p: float. Dropout probability.
	softmax_scale: float. The scaling of QK^T before applying softmax.
	Default to 1 / sqrt(headdim).
	causal: bool. Whether to apply causal attention mask (e.g., for auto-regressive modeling).
	window_size: (left, right). If not (-1, -1), implements sliding window local attention.
	softcap: float. Anything > 0 activates softcapping attention.
	alibi_slopes: (nheads,) or (batch_size, nheads), fp32. A bias of (-alibi_slope * \|i - j\|) is added to
	the attention score of query i and key j.
	deterministic: bool. Whether to use the deterministic implementation of the backward pass,
	which is slightly slower and uses more memory. The forward pass is always deterministic.
	return_attn_probs: bool. Whether to return the attention probabilities. This option is for
	testing only. The returned probabilities are not guaranteed to be correct
	(they might not have the right scaling).
	Return:
	out: (batch_size, seqlen, nheads, headdim).
	softmax_lse [optional, if return_attn_probs=True]: (batch_size, nheads, seqlen). The
	logsumexp of each row of the matrix QK^T * scaling (e.g., log of the softmax
	normalization factor).
	S_dmask [optional, if return_attn_probs=True]: (batch_size, nheads, seqlen, seqlen).
	The output of softmax (possibly with different scaling). It also encodes the dropout
	pattern (negative means that location was dropped, nonnegative means it was kept).
	"""
	return FlashAttnQKVPackedFunc.apply(
	qkv,
	softmax_scale,
	causal,
	q_descale, k_descale, v_descale,
	window_size,
	softcap,
	deterministic,
	num_heads_q,
	)


	def flash_attn_func(
	q,
	k,
	v,
	softmax_scale=None,
	causal=False,
	qv=None,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	num_splits=1,
	pack_gqa=None,
	deterministic=False,
	sm_margin=0,
	s_aux=None,
	):
	"""dropout_p should be set to 0.0 during evaluation
	Supports multi-query and grouped-query attention (MQA/GQA) by passing in KV with fewer heads
	than Q. Note that the number of heads in Q must be divisible by the number of heads in KV.
	For example, if Q has 6 heads and K, V have 2 heads, head 0, 1, 2 of Q will attention to head
	0 of K, V, and head 3, 4, 5 of Q will attention to head 1 of K, V.

	If causal=True, the causal mask is aligned to the bottom right corner of the attention matrix.
	For example, if seqlen_q = 2 and seqlen_k = 5, the causal mask (1 = keep, 0 = masked out) is:
	1 1 1 1 0
	1 1 1 1 1
	If seqlen_q = 5 and seqlen_k = 2, the causal mask is:
	0 0
	0 0
	0 0
	1 0
	1 1
	If the row of the mask is all zero, the output will be zero.

	If window_size != (-1, -1), implements sliding window local attention. Query at position i
	will only attend to keys between
	[i + seqlen_k - seqlen_q - window_size[0], i + seqlen_k - seqlen_q + window_size[1]] inclusive.

	Arguments:
	q: (batch_size, seqlen, nheads, headdim)
	k: (batch_size, seqlen, nheads_k, headdim)
	v: (batch_size, seqlen, nheads_k, headdim)
	dropout_p: float. Dropout probability.
	softmax_scale: float. The scaling of QK^T before applying softmax.
	Default to 1 / sqrt(headdim).
	causal: bool. Whether to apply causal attention mask (e.g., for auto-regressive modeling).
	window_size: (left, right). If not (-1, -1), implements sliding window local attention.
	alibi_slopes: (nheads,) or (batch_size, nheads), fp32. A bias of
	(-alibi_slope * \|i + seqlen_k - seqlen_q - j\|)
	is added to the attention score of query i and key j.
	deterministic: bool. Whether to use the deterministic implementation of the backward pass,
	which is slightly slower and uses more memory. The forward pass is always deterministic.
	return_attn_probs: bool. Whether to return the attention probabilities. This option is for
	testing only. The returned probabilities are not guaranteed to be correct
	(they might not have the right scaling).
	Return:
	out: (batch_size, seqlen, nheads, headdim).
	softmax_lse [optional, if return_attn_probs=True]: (batch_size, nheads, seqlen). The
	logsumexp of each row of the matrix QK^T * scaling (e.g., log of the softmax
	normalization factor).
	"""
	return FlashAttnFunc.apply(
	q,
	k,
	v,
	softmax_scale,
	causal,
	qv,
	q_descale, k_descale, v_descale,
	window_size,
	softcap,
	num_splits,
	pack_gqa,
	deterministic,
	sm_margin,
	s_aux,
	)


	def flash_attn_varlen_func(
	q,
	k,
	v,
	cu_seqlens_q,
	cu_seqlens_k,
	max_seqlen_q,
	max_seqlen_k,
	seqused_q=None,
	seqused_k=None,
	softmax_scale=None,
	causal=False,
	qv=None,
	q_descale=None, k_descale=None, v_descale=None,
	window_size=(-1, -1),
	softcap=0.0,
	num_splits=1,
	pack_gqa=None,
	deterministic=False,
	sm_margin=0,
	s_aux=None,
	):
	return FlashAttnVarlenFunc.apply(
	q,
	k,
	v,
	cu_seqlens_q,
	cu_seqlens_k,
	seqused_q,
	seqused_k,
	max_seqlen_q,
	max_seqlen_k,
	softmax_scale,
	causal,
	qv,
	q_descale, k_descale, v_descale,
	window_size,
	softcap,
	num_splits,
	pack_gqa,
	deterministic,
	sm_margin,
	s_aux,
	)


	def flash_attn_combine(out_partial, lse_partial, out=None, out_dtype=None):
	return ops.fwd_combine(out_partial, lse_partial, out, out_dtype)


	def flash_attn_with_kvcache(
	q,
	k_cache,
	v_cache,
	k=None,
	v=None,
	qv=None,
	rotary_cos=None,
	rotary_sin=None,
	cache_seqlens: Optional[Union[(int, torch.Tensor)]] = None,
	cache_batch_idx: Optional[torch.Tensor] = None,
	cache_leftpad: Optional[torch.Tensor] = None,
	page_table: Optional[torch.Tensor] = None,
	cu_seqlens_q: Optional[torch.Tensor] = None,
	cu_seqlens_k_new: Optional[torch.Tensor] = None,
	max_seqlen_q: Optional[int] = None,
	rotary_seqlens: Optional[torch.Tensor] = None,
	q_descale: Optional[torch.Tensor] = None,
	k_descale: Optional[torch.Tensor] = None,
	v_descale: Optional[torch.Tensor] = None,
	softmax_scale=None,
	causal=False,
	window_size=(-1, -1), # -1 means infinite context window
	softcap=0.0, # 0.0 means deactivated
	rotary_interleaved=True,
	scheduler_metadata=None,
	num_splits=0, # Can be tuned for speed
	pack_gqa=None, # Can be tuned for speed
	sm_margin=0, # Can be tuned if some SMs are used for communication
	return_softmax_lse=False,
	s_aux=None,
	):
	"""
	If k and v are not None, k_cache and v_cache will be updated inplace with the new values from
	k and v. This is useful for incremental decoding: you can pass in the cached keys/values from
	the previous step, and update them with the new keys/values from the current step, and do
	attention with the updated cache, all in 1 kernel.

	If you pass in k / v, you must make sure that the cache is large enough to hold the new values.
	For example, the KV cache could be pre-allocated with the max sequence length, and you can use
	cache_seqlens to keep track of the current sequence lengths of each sequence in the batch.

	Also apply rotary embedding if rotary_cos and rotary_sin are passed in. The key @k will be
	rotated by rotary_cos and rotary_sin at indices cache_seqlens, cache_seqlens + 1, etc.
	If causal or local (i.e., window_size != (-1, -1)), the query @q will be rotated by rotary_cos
	and rotary_sin at indices cache_seqlens, cache_seqlens + 1, etc.
	If not causal and not local, the query @q will be rotated by rotary_cos and rotary_sin at
	indices cache_seqlens only (i.e. we consider all tokens in @q to be at position cache_seqlens).

	See tests/test_flash_attn.py::test_flash_attn_kvcache for examples of how to use this function.

	Supports multi-query and grouped-query attention (MQA/GQA) by passing in KV with fewer heads
	than Q. Note that the number of heads in Q must be divisible by the number of heads in KV.
	For example, if Q has 6 heads and K, V have 2 heads, head 0, 1, 2 of Q will attention to head
	0 of K, V, and head 3, 4, 5 of Q will attention to head 1 of K, V.

	If causal=True, the causal mask is aligned to the bottom right corner of the attention matrix.
	For example, if seqlen_q = 2 and seqlen_k = 5, the causal mask (1 = keep, 0 = masked out) is:
	1 1 1 1 0
	1 1 1 1 1
	If seqlen_q = 5 and seqlen_k = 2, the causal mask is:
	0 0
	0 0
	0 0
	1 0
	1 1
	If the row of the mask is all zero, the output will be zero.

	If window_size != (-1, -1), implements sliding window local attention. Query at position i
	will only attend to keys between
	[i + seqlen_k - seqlen_q - window_size[0], i + seqlen_k - seqlen_q + window_size[1]] inclusive.

	Note: Does not support backward pass.

	Arguments:
	q: (batch_size, seqlen, nheads, headdim)
	k_cache: (batch_size_cache, seqlen_cache, nheads_k, headdim) if there's no page_table,
	or (num_blocks, page_block_size, nheads_k, headdim) if there's a page_table (i.e. paged KV cache)
	page_block_size must be a multiple of 256.
	v_cache: (batch_size_cache, seqlen_cache, nheads_k, headdim_v) if there's no page_table,
	or (num_blocks, page_block_size, nheads_k, headdim_v) if there's a page_table (i.e. paged KV cache)
	k [optional]: (batch_size, seqlen_new, nheads_k, headdim). If not None, we concatenate
	k with k_cache, starting at the indices specified by cache_seqlens.
	v [optional]: (batch_size, seqlen_new, nheads_k, headdim_v). Similar to k.
	qv [optional]: (batch_size, seqlen, nheads, headdim_v)
	rotary_cos [optional]: (seqlen_ro, rotary_dim / 2). If not None, we apply rotary embedding
	to k and q. Only applicable if k and v are passed in. rotary_dim must be divisible by 16.
	rotary_sin [optional]: (seqlen_ro, rotary_dim / 2). Similar to rotary_cos.
	cache_seqlens: int, or (batch_size,), dtype torch.int32. The sequence lengths of the
	KV cache.
	cache_batch_idx: (batch_size,), dtype torch.int32. The indices used to index into the KV cache.
	If None, we assume that the batch indices are [0, 1, 2, ..., batch_size - 1].
	If the indices are not distinct, and k and v are provided, the values updated in the cache
	might come from any of the duplicate indices.
	cache_leftpad: (batch_size,), dtype torch.int32. The index that the KV cache starts. If None, assume 0.
	page_table [optional]: (batch_size, max_num_blocks_per_seq), dtype torch.int32.
	softmax_scale: float. The scaling of QK^T before applying softmax.
	Default to 1 / sqrt(headdim).
	causal: bool. Whether to apply causal attention mask (e.g., for auto-regressive modeling).
	window_size: (left, right). If not (-1, -1), implements sliding window local attention.
	softcap: float. Anything > 0 activates softcapping attention.
	rotary_interleaved: bool. Only applicable if rotary_cos and rotary_sin are passed in.
	If True, rotary embedding will combine dimensions 0 & 1, 2 & 3, etc. If False,
	rotary embedding will combine dimensions 0 & rotary_dim / 2, 1 & rotary_dim / 2 + 1
	(i.e. GPT-NeoX style).
	num_splits: int. If > 1, split the key/value into this many chunks along the sequence.
	If num_splits == 1, we don't split the key/value. If num_splits == 0, we use a heuristic
	to automatically determine the number of splits.
	Don't change this unless you know what you are doing.
	return_softmax_lse: bool. Whether to return the logsumexp of the attention scores.

	Return:
	out: (batch_size, seqlen, nheads, headdim).
	softmax_lse [optional, if return_softmax_lse=True]: (batch_size, nheads, seqlen). The
	logsumexp of each row of the matrix QK^T * scaling (e.g., log of the softmax
	normalization factor).
	"""
	assert k_cache.stride(-1) == 1, "k_cache must have contiguous last dimension"
	assert v_cache.stride(-1) == 1, "v_cache must have contiguous last dimension"
	if softmax_scale is None:
	softmax_scale = (q.shape[-1] + (qv.shape[-1] if qv is not None else 0)) ** (-0.5)
	if cache_seqlens is not None and isinstance(cache_seqlens, int):
	cache_seqlens = torch.full(
	(k_cache.shape[0],), cache_seqlens, dtype=torch.int32, device=k_cache.device
	)
	cache_seqlens = maybe_contiguous(cache_seqlens)
	out, softmax_lse, *rest = _flash_attn_forward(
	q,
	k_cache,
	v_cache,
	k,
	v,
	qv,
	None, # out
	cu_seqlens_q,
	None, # cu_seqlens_k
	cu_seqlens_k_new,
	None, # seqused_q
	cache_seqlens,
	max_seqlen_q,
	None, # max_seqlen_k
	page_table,
	cache_batch_idx,
	cache_leftpad,
	rotary_cos,
	rotary_sin,
	rotary_seqlens,
	q_descale, k_descale, v_descale,
	softmax_scale,
	causal=causal,
	window_size=window_size,
	softcap=softcap,
	rotary_interleaved=rotary_interleaved,
	scheduler_metadata=scheduler_metadata,
	num_splits=num_splits,
	pack_gqa=pack_gqa,
	sm_margin=sm_margin,
	s_aux=s_aux,
	)
	# return (out, softmax_lse) if return_softmax_lse else out
	return (out, softmax_lse, *rest) if return_softmax_lse else out


	def get_scheduler_metadata(
	batch_size, max_seqlen_q, max_seqlen_k, num_heads_q, num_heads_kv, headdim,
	cache_seqlens: torch.Tensor,
	qkv_dtype=torch.bfloat16,
	headdim_v=None,
	cu_seqlens_q: Optional[torch.Tensor] = None,
	cu_seqlens_k_new: Optional[torch.Tensor] = None,
	cache_leftpad: Optional[torch.Tensor] = None,
	page_size: Optional[int] = None,
	max_seqlen_k_new=0,
	causal=False,
	window_size=(-1, -1), # -1 means infinite context window
	has_softcap=False,
	num_splits=0, # Can be tuned for speed
	pack_gqa=None, # Can be tuned for speed
	sm_margin=0, # Can be tuned if some SMs are used for communication
	):
	cache_seqlens = maybe_contiguous(cache_seqlens)
	if headdim_v is None:
	headdim_v = headdim
	scheduler_metadata = ops.get_scheduler_metadata(
	batch_size, max_seqlen_q, max_seqlen_k, num_heads_q, num_heads_kv, headdim, headdim_v,
	qkv_dtype,
	cache_seqlens,
	cu_seqlens_q,
	None, # cu_seqlens_k
	cu_seqlens_k_new,
	None, # seqused_q
	cache_leftpad,
	page_size,
	max_seqlen_k_new,
	causal,
	window_size[0], window_size[1],
	has_softcap,
	num_splits,
	pack_gqa,
	sm_margin,
	)
	return scheduler_metadata