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153
vllm_kunlun/ops/fla/fused_recurrent.py
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153
vllm_kunlun/ops/fla/fused_recurrent.py
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# SPDX-License-Identifier: Apache-2.0
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# SPDX-FileCopyrightText: Copyright contributors to the vLLM project
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# SPDX-FileCopyrightText: Songlin Yang, Yu Zhang
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#
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# This file contains code copied from the flash-linear-attention project.
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# The original source code was licensed under the MIT license and included
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# the following copyright notice:
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# Copyright (c) 2023-2025, Songlin Yang, Yu Zhang
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# ruff: noqa: E501
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from typing import Optional
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import torch
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import xtorch_ops
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class FusedRecurrentFunction(torch.autograd.Function):
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@staticmethod
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def forward(ctx,
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q: torch.Tensor,
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k: torch.Tensor,
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v: torch.Tensor,
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g: torch.Tensor,
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beta: torch.Tensor,
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scale: float,
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initial_state: torch.Tensor,
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inplace_final_state: bool = True,
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cu_seqlens: Optional[torch.LongTensor] = None,
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ssm_state_indices: Optional[torch.Tensor] = None,
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num_accepted_tokens: Optional[torch.Tensor] = None,
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use_qk_l2norm_in_kernel: bool = False):
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o, final_state = xtorch_ops.fused_recurrent_gated_delta_rule_fwdv2(
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q.contiguous(),
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k.contiguous(),
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v.contiguous(),
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g.contiguous(),
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beta.contiguous(),
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scale,
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initial_state,
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inplace_final_state=inplace_final_state,
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cu_seqlens=cu_seqlens,
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h0_indices=ssm_state_indices,
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num_accepted_tokens=num_accepted_tokens,
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use_qk_l2norm_in_kernel=use_qk_l2norm_in_kernel,
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)
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return o, final_state
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def fused_recurrent_gated_delta_rule(
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q: torch.Tensor,
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k: torch.Tensor,
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v: torch.Tensor,
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g: torch.Tensor,
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beta: torch.Tensor = None,
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scale: float = None,
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initial_state: torch.Tensor = None,
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inplace_final_state: bool = True,
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cu_seqlens: Optional[torch.LongTensor] = None,
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ssm_state_indices: Optional[torch.Tensor] = None,
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num_accepted_tokens: Optional[torch.Tensor] = None,
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use_qk_l2norm_in_kernel: bool = False,
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) -> tuple[torch.Tensor, torch.Tensor]:
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r"""
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Args:
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q (torch.Tensor):
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queries of shape `[B, T, H, K]`.
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k (torch.Tensor):
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keys of shape `[B, T, H, K]`.
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v (torch.Tensor):
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values of shape `[B, T, HV, V]`.
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GVA is applied if `HV > H`.
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g (torch.Tensor):
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g (decays) of shape `[B, T, HV]`.
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beta (torch.Tensor):
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betas of shape `[B, T, HV]`.
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scale (Optional[int]):
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Scale factor for the RetNet attention scores.
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If not provided, it will default to `1 / sqrt(K)`. Default: `None`.
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initial_state (Optional[torch.Tensor]):
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Initial state of shape `[N, HV, K, V]` for `N` input sequences.
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For equal-length input sequences, `N` equals the batch size `B`.
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Default: `None`.
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inplace_final_state: bool:
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Whether to store the final state in-place to save memory.
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Default: `True`.
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cu_seqlens (torch.LongTensor):
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Cumulative sequence lengths of shape `[N+1]` used for variable-length training,
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consistent with the FlashAttention API.
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ssm_state_indices (Optional[torch.Tensor]):
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Indices to map the input sequences to the initial/final states.
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num_accepted_tokens (Optional[torch.Tensor]):
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Number of accepted tokens for each sequence during decoding.
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Returns:
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o (torch.Tensor):
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Outputs of shape `[B, T, HV, V]`.
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final_state (torch.Tensor):
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Final state of shape `[N, HV, K, V]`.
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Examples::
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>>> import torch
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>>> import torch.nn.functional as F
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>>> from einops import rearrange
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>>> from fla.ops.gated_delta_rule import fused_recurrent_gated_delta_rule
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# inputs with equal lengths
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>>> B, T, H, HV, K, V = 4, 2048, 4, 8, 512, 512
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>>> q = torch.randn(B, T, H, K, device='cuda')
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>>> k = F.normalize(torch.randn(B, T, H, K, device='cuda'), p=2, dim=-1)
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>>> v = torch.randn(B, T, HV, V, device='cuda')
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>>> g = F.logsigmoid(torch.rand(B, T, HV, device='cuda'))
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>>> beta = torch.rand(B, T, HV, device='cuda').sigmoid()
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>>> h0 = torch.randn(B, HV, K, V, device='cuda')
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>>> o, ht = fused_gated_recurrent_delta_rule(
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q, k, v, g, beta,
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initial_state=h0,
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)
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# for variable-length inputs, the batch size `B` is expected to be 1 and `cu_seqlens` is required
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>>> q, k, v, g, beta = map(lambda x: rearrange(x, 'b t ... -> 1 (b t) ...'), (q, k, v, g, beta))
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# for a batch with 4 sequences, `cu_seqlens` with 5 start/end positions are expected
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>>> cu_seqlens = q.new_tensor([0, 2048, 4096, 6144, 8192], dtype=torch.long)
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>>> o_var, ht_var = fused_gated_recurrent_delta_rule(
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q, k, v, g, beta,
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initial_state=h0,
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cu_seqlens=cu_seqlens
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)
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"""
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if cu_seqlens is not None and q.shape[0] != 1:
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raise ValueError(
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f"The batch size is expected to be 1 rather than {q.shape[0]} when using `cu_seqlens`."
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f"Please flatten variable-length inputs before processing.")
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if scale is None:
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scale = k.shape[-1]**-0.5
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else:
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assert scale > 0, "scale must be positive"
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if beta is None:
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beta = torch.ones_like(q[..., 0])
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o, final_state = FusedRecurrentFunction.apply(
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q,
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k,
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v,
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g,
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beta,
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scale,
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initial_state,
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inplace_final_state,
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cu_seqlens,
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ssm_state_indices,
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num_accepted_tokens,
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use_qk_l2norm_in_kernel,
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)
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return o, final_state
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