[pref] qwen3_next add triton ops : fused_sigmoid_gating_delta_rule_update (#4818)

### What this PR does / why we need it?
qwen3_next add fused_sigmoid_gating_delta_rule_update op which fused
fused_gdn_gating+fused_recurrent_gated_delta_rule

- vLLM version: v0.12.0
- vLLM main:
ad32e3e19c

Signed-off-by: wangxiaoxin-sherie <wangxiaoxin7@huawei.com>
Co-authored-by: wangxiaoxin-sherie <wangxiaoxin7@huawei.com>

vllm_ascend/ops/triton/fla/sigmoid_gating.py

@@ -11,6 +11,7 @@
 
 import os
 
+import torch
 from vllm.triton_utils import tl, tldevice, triton
 
 if os.environ.get('FLA_USE_FAST_OPS', '0') == '1':
@@ -169,3 +170,228 @@ def fused_recurrent_gated_delta_rule_fwd_kernel(
             p_ht = ht + (bos + i_t) * stride_final_state_token
         p_ht = p_ht + i_hv * K * V + o_k[:, None] * V + o_v[None, :]
         tl.store(p_ht, b_h.to(p_ht.dtype.element_ty), mask=mask_h)
+
+
+@triton.heuristics({
+    "USE_INITIAL_STATE": lambda args: args["h0_source"] is not None,
+    "IS_VARLEN": lambda args: args["cu_seqlens"] is not None,
+})
+@triton.jit(do_not_specialize=["T"])
+def fused_sigmoid_gating_delta_rule_update_kernel(
+    A_log,
+    a,
+    dt_bias,
+    softplus_beta,
+    softplus_threshold,
+    q,
+    k,
+    v,
+    b,
+    o,
+    h0_source,
+    h0_indices,
+    cu_seqlens,
+    scale,
+    T,
+    B: tl.constexpr,
+    H: tl.constexpr,
+    HV: tl.constexpr,
+    K: tl.constexpr,
+    V: tl.constexpr,
+    BK: tl.constexpr,
+    BV: tl.constexpr,
+    USE_INITIAL_STATE: tl.constexpr,
+    USE_QK_L2NORM_IN_KERNEL: tl.constexpr,
+    IS_VARLEN: tl.constexpr,
+):
+    """
+    Fused kernel that combines sigmoid gating computation with recurrent delta rule update.
+    """
+    i_k, i_v, i_nh = tl.program_id(0), tl.program_id(1), tl.program_id(2)
+    i_n, i_hv = i_nh // HV, i_nh % HV
+    i_h = i_hv // (HV // H)
+
+    if IS_VARLEN:
+        bos, eos = (
+            tl.load(cu_seqlens + i_n).to(tl.int64),
+            tl.load(cu_seqlens + i_n + 1).to(tl.int64),
+        )
+        all = T
+        T = eos - bos
+    else:
+        bos, eos = i_n * T, i_n * T + T
+        all = B * T
+
+    o_k = i_k * BK + tl.arange(0, BK)
+    o_v = i_v * BV + tl.arange(0, BV)
+
+    p_q = q + (bos * H + i_h) * K + o_k
+    p_k = k + (bos * H + i_h) * K + o_k
+    p_v = v + (bos * HV + i_hv) * V + o_v
+    p_b = b + bos * HV + i_hv
+    p_o = o + ((i_k * all + bos) * HV + i_hv) * V + o_v
+
+    # Gating computation pointers
+    p_A_log = A_log + i_hv
+    p_a = a + bos * HV + i_hv
+    p_dt_bias = dt_bias + i_hv
+
+    mask_k = o_k < K
+    mask_v = o_v < V
+    mask_h = mask_k[:, None] & mask_v[None, :]
+
+    b_h = tl.zeros([BK, BV], dtype=tl.float32)
+    if USE_INITIAL_STATE:
+        idx = tl.load(h0_indices + i_n)
+        # if idx >= 0:
+        tmp0 = tl.where(idx < 0, 0, idx)
+        p_h0 = (h0_source + tmp0 * HV * K * V + i_hv * K * V +
+                o_k[:, None] * V + o_v[None, :])
+        temp1 = tl.load(p_h0, mask=mask_h, other=0).to(tl.float32)
+        temp2 = tl.zeros_like(temp1)
+        value0 = tl.where(idx < 0, temp2, temp1)
+        b_h += value0  # tl.load(p_h0, mask=mask_h, other=0).to(tl.float32)
+
+    for i in range(0, T):
+        # Load inputs
+        b_q = tl.load(p_q + i * H * K, mask=mask_k, other=0).to(tl.float32)
+        b_k = tl.load(p_k + i * H * K, mask=mask_k, other=0).to(tl.float32)
+        b_v = tl.load(p_v + i * HV * V, mask=mask_v, other=0).to(tl.float32)
+        b_b = tl.load(p_b + i * HV).to(tl.float32)
+
+        # Compute sigmoid gating
+        # Load gating parameters
+        b_A_log = tl.load(p_A_log).to(tl.float32)
+        b_a = tl.load(p_a + i * HV).to(tl.float32)
+        b_dt_bias = tl.load(p_dt_bias).to(tl.float32)
+
+        # Compute g = -exp(A_log) * softplus(a + dt_bias)
+        x = b_a + b_dt_bias
+        beta_x = softplus_beta * x
+        # Apply softplus with numerical stability
+        softplus_x = tl.where(
+            beta_x <= softplus_threshold,
+            (1.0 / softplus_beta) * tl.log(1.0 + tl.exp(beta_x)),
+            x,
+        )
+        b_g = -tl.exp(b_A_log) * softplus_x
+
+        # Compute beta = sigmoid(b)
+        b_beta = 1.0 / (1.0 + tl.exp(-b_b))
+
+        # Apply L2 normalization if enabled
+        if USE_QK_L2NORM_IN_KERNEL:
+            b_q = b_q / (tl.sqrt(tl.sum(b_q * b_q)) + 1e-6)
+            b_k = b_k / (tl.sqrt(tl.sum(b_k * b_k)) + 1e-6)
+
+        b_q = b_q * scale
+
+        # Apply gating to hidden state: h *= exp(g)
+        b_h *= tl.exp(b_g)
+
+        # Delta rule: v -= sum(h * k, dim=0)
+        b_v -= tl.sum(b_h * b_k[:, None], 0)
+
+        # Apply beta gating: v *= beta
+        b_v *= b_beta
+
+        # Update hidden state: h += k[:, None] * v[None, :]
+        b_h += b_k[:, None] * b_v[None, :]
+
+        # Compute output: o = sum(h * q, dim=0)
+        b_o = tl.sum(b_h * b_q[:, None], 0)
+        tl.store(p_o + i * HV * V, b_o.to(p_o.dtype.element_ty), mask=mask_v)
+
+        # # Update pointers for next timestep
+        # p_q += H * K
+        # p_k += H * K
+        # p_o += HV * V
+        # p_v += HV * V
+        # p_b += HV
+        # p_a += HV
+
+    # Store final state back to h0_source with bounds checking
+    if USE_INITIAL_STATE:
+        idx = tl.load(h0_indices + i_n)
+        if idx >= 0:
+            p_h0 = (h0_source + idx * HV * K * V + i_hv * K * V +
+                    o_k[:, None] * V + o_v[None, :])
+            tl.store(p_h0, b_h.to(p_h0.dtype.element_ty), mask=mask_h)
+
+
+def fused_sigmoid_gating_delta_rule_update(
+    A_log: torch.Tensor,
+    a: torch.Tensor,
+    dt_bias: torch.Tensor,
+    softplus_beta: float,
+    softplus_threshold: float,
+    q: torch.Tensor,
+    k: torch.Tensor,
+    v: torch.Tensor,
+    b: torch.Tensor,
+    initial_state_source: torch.Tensor,
+    initial_state_indices: torch.Tensor,
+    scale: float = None,
+    use_qk_l2norm_in_kernel: bool = False,
+    cu_seqlens: torch.Tensor = None,
+):
+    """
+    Fused triton implementation of sigmoid gating delta rule update.
+    This function uses a single fused kernel that combines both sigmoid gating computation
+    and the recurrent delta rule update for better performance.
+    """
+    B, T, H, K, V = *k.shape, v.shape[-1]
+    HV = v.shape[2]
+    N = B if cu_seqlens is None else len(cu_seqlens) - 1
+    BK, BV = triton.next_power_of_2(K), min(triton.next_power_of_2(V), 64)
+    NK, NV = triton.cdiv(K, BK), triton.cdiv(V, BV)
+    assert NK == 1, "NK > 1 is not supported yet"
+    num_stages = 3
+    num_warps = 1
+
+    if scale is None:
+        scale = k.shape[-1]**-0.5
+    else:
+        assert scale > 0, "scale must be positive"
+
+    o = q.new_empty(NK, *v.shape)
+    grid = (NK, NV, N * HV)
+
+    if not initial_state_indices.is_contiguous():
+        initial_state_indices = initial_state_indices.contiguous()
+    if not initial_state_source.is_contiguous():
+        initial_state_source_contiguous = initial_state_source.contiguous()
+    if not cu_seqlens.is_contiguous():
+        cu_seqlens = cu_seqlens.contiguous()
+
+    fused_sigmoid_gating_delta_rule_update_kernel[grid](
+        A_log=A_log,
+        a=a,
+        dt_bias=dt_bias,
+        softplus_beta=softplus_beta,
+        softplus_threshold=softplus_threshold,
+        q=q,
+        k=k,
+        v=v,
+        b=b,
+        o=o,
+        h0_source=initial_state_source_contiguous,
+        h0_indices=initial_state_indices,
+        cu_seqlens=cu_seqlens,
+        scale=scale,
+        T=T,
+        B=B,
+        H=H,
+        HV=HV,
+        K=K,
+        V=V,
+        BK=BK,
+        BV=BV,
+        USE_QK_L2NORM_IN_KERNEL=use_qk_l2norm_in_kernel,
+        num_warps=num_warps,
+        num_stages=num_stages,
+    )
+    initial_state_source.copy_(
+        initial_state_source_contiguous.view_as(initial_state_source))
+    o = o.squeeze(0)
+    return o