rope-embeddings (#20)

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	# Adapted from https://github.com/Dao-AILab/flash-attention/pull/556
	# Copyright (c) 2023, Tri Dao.

	import math
	from typing import Optional, Tuple, Union

	import torch
	from einops import rearrange, repeat
	try:
	from flash_attn.ops.triton.rotary import apply_rotary
	except ImportError:
	def apply_rotary(args, *kwargs):
	raise RuntimeError('RoPE requires flash-attention to be installed')


	def rotate_half(x, interleaved=False):
	if not interleaved:
	x1, x2 = x.chunk(2, dim=-1)
	return torch.cat((-x2, x1), dim=-1)
	else:
	x1, x2 = x[..., ::2], x[..., 1::2]
	return rearrange(torch.stack((-x2, x1), dim=-1), "... d two -> ... (d two)", two=2)


	def apply_rotary_emb_torch(x, cos, sin, interleaved=False):
	"""
	x: (batch_size, seqlen, nheads, headdim)
	cos, sin: (seqlen, rotary_dim / 2) or (batch_size, seqlen, rotary_dim / 2)
	"""
	ro_dim = cos.shape[-1] * 2
	assert ro_dim <= x.shape[-1]
	cos = repeat(cos, "... d -> ... 1 (2 d)" if not interleaved else "... d -> ... 1 (d 2)")
	sin = repeat(sin, "... d -> ... 1 (2 d)" if not interleaved else "... d -> ... 1 (d 2)")
	return torch.cat(
	[x[..., :ro_dim] * cos + rotate_half(x[..., :ro_dim], interleaved) * sin, x[..., ro_dim:]],
	dim=-1,
	)


	class ApplyRotaryEmb(torch.autograd.Function):
	@staticmethod
	def forward(
	ctx,
	x,
	cos,
	sin,
	interleaved=False,
	inplace=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	out = apply_rotary(
	x,
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	interleaved=interleaved,
	inplace=inplace,
	)
	if isinstance(seqlen_offsets, int):
	ctx.save_for_backward(cos, sin, cu_seqlens) # Can't save int with save_for_backward
	ctx.seqlen_offsets = seqlen_offsets
	else:
	ctx.save_for_backward(cos, sin, cu_seqlens, seqlen_offsets)
	ctx.seqlen_offsets = None
	ctx.interleaved = interleaved
	ctx.inplace = inplace
	ctx.max_seqlen = max_seqlen
	return out if not inplace else x

	@staticmethod
	def backward(ctx, do):
	seqlen_offsets = ctx.seqlen_offsets
	if seqlen_offsets is None:
	cos, sin, cu_seqlens, seqlen_offsets = ctx.saved_tensors
	else:
	cos, sin, cu_seqlens = ctx.saved_tensors
	# TD [2023-09-02]: For some reason Triton (2.0.0.post1) errors with
	# "[CUDA]: invalid device context", and cloning makes it work. Idk why. Triton 2.1.0 works.
	if not ctx.interleaved and not ctx.inplace:
	do = do.clone()
	dx = apply_rotary(
	do,
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	cu_seqlens=cu_seqlens,
	max_seqlen=ctx.max_seqlen,
	interleaved=ctx.interleaved,
	inplace=ctx.inplace,
	conjugate=True,
	)
	return dx, None, None, None, None, None, None, None


	def apply_rotary_emb(
	x,
	cos,
	sin,
	interleaved=False,
	inplace=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	"""
	Arguments:
	x: (batch_size, seqlen, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, nheads, headdim)
	cos, sin: (seqlen_rotary, rotary_dim / 2)
	interleaved: if True, rotate pairs of even and odd dimensions (GPT-J style) instead
	of 1st half and 2nd half (GPT-NeoX style).
	inplace: if True, apply rotary embedding in-place.
	seqlen_offsets: (batch_size,) or int. Each sequence in x is shifted by this amount.
	Most commonly used in inference when we have KV cache.
	cu_seqlens: (batch + 1,) or None
	max_seqlen: int
	Return:
	out: (batch_size, seqlen, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, nheads, headdim)
	rotary_dim must be <= headdim
	Apply rotary embedding to the first rotary_dim of x.
	"""
	return ApplyRotaryEmb.apply(
	x, cos, sin, interleaved, inplace, seqlen_offsets, cu_seqlens, max_seqlen
	)


	# For backward compatibility
	apply_rotary_emb_func = apply_rotary_emb


	class ApplyRotaryEmbQKV_(torch.autograd.Function):
	@staticmethod
	def forward(
	ctx,
	qkv,
	cos,
	sin,
	cos_k=None,
	sin_k=None,
	interleaved=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	# batch, seqlen, three, nheads, headdim = qkv.shape
	assert qkv.shape[-3] == 3
	if cos_k is None and sin_k is None and qkv.is_contiguous():
	# Call 1 kernel instead of 2 kernels
	# We need qkv to be contiguous so that when we reshape to combine (3, nheads)
	# dimensions, we get the same tensor
	qk = rearrange(qkv[..., :2, :, :], "... t h d -> ... (t h) d")
	# qk = qkv[:, :, :2].reshape(batch, seqlen, -1, headdim)
	apply_rotary(
	qk,
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	interleaved=interleaved,
	inplace=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	else:
	cos_k = cos if cos_k is None else cos_k
	sin_k = sin if sin_k is None else sin_k
	q, k = qkv[..., 0, :, :], qkv[..., 1, :, :]
	apply_rotary(
	q,
	cos,
	sin,
	seqlen_offsets,
	interleaved=interleaved,
	inplace=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	apply_rotary(
	k,
	cos_k,
	sin_k,
	seqlen_offsets,
	interleaved=interleaved,
	inplace=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	ctx.save_for_backward(cos, sin, cos_k, sin_k)
	if isinstance(seqlen_offsets, int):
	ctx.save_for_backward(cos, sin, cos_k, sin_k, cu_seqlens)
	ctx.seqlen_offsets = seqlen_offsets
	else:
	ctx.save_for_backward(cos, sin, cos_k, sin_k, cu_seqlens, seqlen_offsets)
	ctx.seqlen_offsets = None
	ctx.max_seqlen = max_seqlen
	ctx.interleaved = interleaved
	return qkv

	@staticmethod
	def backward(ctx, dqkv):
	seqlen_offsets = ctx.seqlen_offsets
	if seqlen_offsets is None:
	cos, sin, cos_k, sin_k, cu_seqlens, seqlen_offsets = ctx.saved_tensors
	else:
	cos, sin, cos_k, sin_k, cu_seqlens = ctx.saved_tensors
	if cos_k is None and sin_k is None and dqkv.is_contiguous():
	# Call 1 kernel instead of 2 kernels
	# We need dqkv to be contiguous so that when we reshape to combine (3, nheads)
	# dimensions, we get the same tensor
	dqk = rearrange(dqkv[..., :2, :, :], "... t h d -> ... (t h) d")
	apply_rotary(
	dqk,
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	interleaved=ctx.interleaved,
	inplace=True,
	conjugate=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=ctx.max_seqlen,
	)
	else:
	cos_k = cos if cos_k is None else cos_k
	sin_k = sin if sin_k is None else sin_k
	dq, dk = dqkv[..., 0, :, :], dqkv[..., 1, :, :]
	apply_rotary(

	dq,
	cos,
	sin,
	seqlen_offsets,
	interleaved=ctx.interleaved,
	inplace=True,
	conjugate=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=ctx.max_seqlen,
	)
	apply_rotary(
	dk,
	cos_k,
	sin_k,
	seqlen_offsets,
	interleaved=ctx.interleaved,
	inplace=True,
	conjugate=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=ctx.max_seqlen,
	)
	return dqkv, None, None, None, None, None, None, None, None


	def apply_rotary_emb_qkv_(
	qkv,
	cos,
	sin,
	cos_k=None,
	sin_k=None,
	interleaved=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	"""
	Arguments:
	qkv: (batch_size, seqlen, 3, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, 3, nheads, headdim)
	cos, sin: (seqlen, rotary_dim / 2)
	cos_k, sin_k: (seqlen, rotary_dim / 2), optional
	interleaved: if True, rotate pairs of even and odd dimensions (GPT-J style) instead of
	1st half and 2nd half (GPT-NeoX style).
	seqlen_offsets: (batch_size,) or int. Each sequence in Q and K is shifted by this amount.
	Most commonly used in inference when we have KV cache.
	cu_seqlens: (batch + 1,) or None
	max_seqlen: int
	Return:
	qkv: (batch_size, seqlen, 3, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, 3, nheads, headdim)
	rotary_dim must be <= headdim
	Apply rotary embedding inplace to the first rotary_dim of Q and K.
	"""
	return ApplyRotaryEmbQKV_.apply(
	qkv, cos, sin, cos_k, sin_k, interleaved, seqlen_offsets, cu_seqlens, max_seqlen
	)


	class ApplyRotaryEmbKV_(torch.autograd.Function):
	@staticmethod
	def forward(
	ctx,
	kv,
	cos,
	sin,
	interleaved=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	# batch, seqlen, two, nheads, headdim = kv.shape
	assert kv.shape[-3] == 2
	k = kv[..., 0, :, :]
	apply_rotary(
	k,
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	interleaved=interleaved,
	inplace=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	if isinstance(seqlen_offsets, int):
	ctx.save_for_backward(cos, sin, cu_seqlens) # Can't save int with save_for_backward
	ctx.seqlen_offsets = seqlen_offsets
	else:
	ctx.save_for_backward(cos, sin, cu_seqlens, seqlen_offsets)
	ctx.seqlen_offsets = None
	ctx.max_seqlen = max_seqlen
	ctx.interleaved = interleaved
	return kv

	@staticmethod
	def backward(ctx, dkv):
	seqlen_offsets = ctx.seqlen_offsets
	if seqlen_offsets is None:
	cos, sin, cu_seqlens, seqlen_offsets = ctx.saved_tensors
	else:
	cos, sin, cu_seqlens = ctx.saved_tensors
	apply_rotary(
	dkv[..., 0, :, :],
	cos,
	sin,
	seqlen_offsets=seqlen_offsets,
	interleaved=ctx.interleaved,
	inplace=True,
	conjugate=True,
	cu_seqlens=cu_seqlens,
	max_seqlen=ctx.max_seqlen,
	)
	return dkv, None, None, None, None, None, None


	apply_rotary_emb_kv_ = ApplyRotaryEmbKV_.apply


	def apply_rotary_emb_kv_(
	kv,
	cos,
	sin,
	interleaved=False,
	seqlen_offsets: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	):
	"""
	Arguments:
	kv: (batch_size, seqlen, 2, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, 2, nheads, headdim)
	cos, sin: (seqlen, rotary_dim / 2)
	interleaved: if True, rotate pairs of even and odd dimensions (GPT-J style) instead of
	1st half and 2nd half (GPT-NeoX style).
	seqlen_offsets: (batch_size,) or int. Each sequence in Q and K is shifted by this amount.
	Most commonly used in inference when we have KV cache.
	cu_seqlens: (batch + 1,) or None
	max_seqlen: int
	Return:
	kv: (batch_size, seqlen, 2, nheads, headdim) if cu_seqlens is None
	else (total_seqlen, 2, nheads, headdim)
	rotary_dim must be <= headdim
	Apply rotary embedding inplace to the first rotary_dim of K.
	"""
	return ApplyRotaryEmbKV_.apply(
	kv, cos, sin, interleaved, seqlen_offsets, cu_seqlens, max_seqlen
	)


	class RotaryEmbedding(torch.nn.Module):
	"""
	The rotary position embeddings from RoFormer_ (Su et. al).
	A crucial insight from the method is that the query and keys are
	transformed by rotation matrices which depend on the relative positions.

	Other implementations are available in the Rotary Transformer repo_ and in
	GPT-NeoX_, GPT-NeoX was an inspiration

	.. _RoFormer: https://arxiv.org/abs/2104.09864
	.. _repo: https://github.com/ZhuiyiTechnology/roformer
	.. _GPT-NeoX: https://github.com/EleutherAI/gpt-neox

	If scale_base is not None, this implements XPos (Sun et al., https://arxiv.org/abs/2212.10554).
	A recommended value for scale_base is 512: https://github.com/HazyResearch/flash-attention/issues/96
	Reference: https://github.com/sunyt32/torchscale/blob/main/torchscale/component/xpos_relative_position.py
	"""

	def __init__(
	self,
	dim: int,
	base=10000.0,
	interleaved=False,
	scale_base=None,
	pos_idx_in_fp32=True,
	device=None,
	):
	"""
	interleaved: if True, rotate pairs of even and odd dimensions (GPT-J style) instead
	of 1st half and 2nd half (GPT-NeoX style).
	pos_idx_in_fp32: if True, the position indices [0.0, ..., seqlen - 1] are in fp32,
	otherwise they might be in lower precision.
	This option was added because previously (before 2023-07-02), when we construct
	the position indices, we use the dtype of self.inv_freq. In most cases this would
	be fp32, but if the model is trained in pure bf16 (not mixed precision), then
	self.inv_freq would be bf16, and the position indices are also in bf16.
	Because of the limited precision of bf16 (e.g. 1995.0 is rounded to 2000.0), the
	embeddings for some positions will coincide.
	To maintain compatibility with models previously trained in pure bf16,
	we add this option.
	"""
	super().__init__()
	self.dim = dim
	self.base = float(base)
	self.pos_idx_in_fp32 = pos_idx_in_fp32
	# Generate and save the inverse frequency buffer (non trainable)
	inv_freq = self._compute_inv_freq(device)
	self.register_buffer("inv_freq", inv_freq, persistent=False)
	self.interleaved = interleaved
	self.scale_base = scale_base
	scale = (
	(torch.arange(0, dim, 2, device=device, dtype=torch.float32) + 0.4 * dim) / (1.4 * dim)
	if scale_base is not None
	else None
	)
	self.register_buffer("scale", scale, persistent=False)

	self._seq_len_cached = 0
	self._cos_cached = None
	self._sin_cached = None
	self._cos_k_cached = None
	self._sin_k_cached = None

	def _compute_inv_freq(self, device=None):
	return 1.0 / (
	self.base
	** (torch.arange(0, self.dim, 2, device=device, dtype=torch.float32) / self.dim)
	)

	def _update_cos_sin_cache(self, seqlen, device=None, dtype=None):
	# Reset the tables if the sequence length has changed,
	# if we're on a new device (possibly due to tracing for instance),
	# or if we're switching from inference mode to training
	if (
	seqlen > self._seq_len_cached
	or self._cos_cached is None
	or self._cos_cached.device != device
	or self._cos_cached.dtype != dtype
	or (self.training and self._cos_cached.is_inference())
	):
	self._seq_len_cached = seqlen
	# We want fp32 here, not self.inv_freq.dtype, since the model could be loaded in bf16
	# And the output of arange can be quite large, so bf16 would lose a lot of precision.
	# However, for compatibility reason, we add an option to use the dtype of self.inv_freq.
	if self.pos_idx_in_fp32:
	t = torch.arange(seqlen, device=device, dtype=torch.float32)
	# We want fp32 here as well since inv_freq will be multiplied with t, and the output
	# will be large. Having it in bf16 will lose a lot of precision and cause the
	# cos & sin output to change significantly.
	# We want to recompute self.inv_freq if it was not loaded in fp32
	if self.inv_freq.dtype != torch.float32:
	inv_freq = self._compute_inv_freq(device=device)
	else:
	inv_freq = self.inv_freq
	else:
	t = torch.arange(seqlen, device=device, dtype=self.inv_freq.dtype)
	inv_freq = self.inv_freq
	# Don't do einsum, it converts fp32 to fp16 under AMP
	# freqs = torch.einsum("i,j->ij", t, self.inv_freq)
	freqs = torch.outer(t, inv_freq)
	if self.scale is None:
	self._cos_cached = torch.cos(freqs).to(dtype)
	self._sin_cached = torch.sin(freqs).to(dtype)
	else:
	power = (
	torch.arange(seqlen, dtype=self.scale.dtype, device=self.scale.device)
	- seqlen // 2
	) / self.scale_base
	scale = self.scale.to(device=power.device) ** rearrange(power, "s -> s 1")
	# We want the multiplication by scale to happen in fp32
	self._cos_cached = (torch.cos(freqs) * scale).to(dtype)
	self._sin_cached = (torch.sin(freqs) * scale).to(dtype)
	self._cos_k_cached = (torch.cos(freqs) / scale).to(dtype)
	self._sin_k_cached = (torch.sin(freqs) / scale).to(dtype)

	def forward(
	self,
	qkv: torch.Tensor,
	kv: Optional[torch.Tensor] = None,
	seqlen_offset: Union[int, torch.Tensor] = 0,
	cu_seqlens: Optional[torch.Tensor] = None,
	max_seqlen: Optional[int] = None,
	) -> Union[torch.Tensor, Tuple[torch.Tensor, torch.Tensor]]:
	"""
	qkv: (batch, seqlen, 3, nheads, headdim) if kv is none,
	else it's just q of shape (batch, seqlen, nheads, headdim)
	kv: (batch, seqlen, 2, nheads, headdim)
	seqlen_offset: (batch_size,) or int. Each sequence in x is shifted by this amount.
	Most commonly used in inference when we have KV cache.
	If it's a tensor of shape (batch_size,), then to update the cos / sin cache, one
	should pass in max_seqlen, which will update the cos / sin cache up to that length.
	Apply rotary embedding inplace to qkv and / or kv.
	"""
	if cu_seqlens is not None:
	assert max_seqlen is not None
	seqlen = qkv.shape[1] if max_seqlen is None else max_seqlen
	if max_seqlen is not None:
	self._update_cos_sin_cache(max_seqlen, device=qkv.device, dtype=qkv.dtype)
	elif isinstance(seqlen_offset, int):
	self._update_cos_sin_cache(seqlen + seqlen_offset, device=qkv.device, dtype=qkv.dtype)
	if kv is None:
	if self.scale is None:
	return apply_rotary_emb_qkv_(
	qkv,
	self._cos_cached,
	self._sin_cached,
	interleaved=self.interleaved,
	seqlen_offsets=seqlen_offset,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	else:
	return apply_rotary_emb_qkv_(
	qkv,
	self._cos_cached,
	self._sin_cached,
	self._cos_k_cached,
	self._sin_k_cached,
	interleaved=self.interleaved,
	seqlen_offsets=seqlen_offset,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	else:
	q = qkv
	q = apply_rotary_emb_func(
	q,
	self._cos_cached,
	self._sin_cached,
	interleaved=self.interleaved,
	inplace=True,
	seqlen_offsets=seqlen_offset,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	if self.scale is None:
	kv = apply_rotary_emb_kv_(
	kv,
	self._cos_cached,
	self._sin_cached,
	interleaved=self.interleaved,
	seqlen_offsets=seqlen_offset,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	else:
	kv = apply_rotary_emb_kv_(
	kv,
	self._cos_k_cached,
	self._sin_k_cached,
	interleaved=self.interleaved,
	seqlen_offsets=seqlen_offset,
	cu_seqlens=cu_seqlens,
	max_seqlen=max_seqlen,
	)
	return q, kv