# Copyright (c) 2023-2025, Songlin Yang, Yu Zhang import warnings import torch import triton import triton.language as tl from einops import reduce from fla.ops.utils import prepare_chunk_indices from fla.ops.utils.cumsum import chunk_global_cumsum from fla.ops.utils.op import exp2, log2 from fla.utils import autocast_custom_bwd, autocast_custom_fwd, check_shared_mem, contiguous @triton.heuristics({ 'USE_G': lambda args: args['g_cumsum'] is not None, 'IS_VARLEN': lambda args: args['cu_seqlens'] is not None, }) @triton.jit def parallel_attn_fwd_kernel( q, k, v, o, g_cumsum, lse, scale, cu_seqlens, chunk_indices, T, B: tl.constexpr, H: tl.constexpr, HQ: tl.constexpr, G: tl.constexpr, K: tl.constexpr, V: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr, BK: tl.constexpr, BV: tl.constexpr, USE_G: tl.constexpr, IS_VARLEN: tl.constexpr, ): i_v, i_t, i_bh = tl.program_id(0), tl.program_id(1), tl.program_id(2) i_b, i_hq = i_bh // HQ, i_bh % HQ i_h = i_hq // G if IS_VARLEN: i_n, i_t = tl.load(chunk_indices + i_t * 2).to(tl.int32), tl.load(chunk_indices + i_t * 2 + 1).to(tl.int32) bos, eos = tl.load(cu_seqlens + i_n).to(tl.int32), tl.load(cu_seqlens + i_n + 1).to(tl.int32) T = eos - bos else: i_n = i_b bos, eos = i_n * T, i_n * T + T RCP_LN2: tl.constexpr = 1.4426950216 p_q = tl.make_block_ptr(q + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_t * BT, 0), (BT, BK), (1, 0)) p_o = tl.make_block_ptr(o + (bos * HQ + i_hq) * V, (T, V), (HQ*V, 1), (i_t * BT, i_v * BV), (BT, BV), (1, 0)) p_lse = tl.make_block_ptr(lse + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) # the Q block is kept in the shared memory throughout the whole kernel # [BT, BK] b_q = tl.load(p_q, boundary_check=(0, 1)) # [BT, BV] b_o = tl.zeros([BT, BV], dtype=tl.float32) b_m = tl.full([BT], float('-inf'), dtype=tl.float32) b_acc = tl.zeros([BT], dtype=tl.float32) if USE_G: p_g = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) b_gq = tl.load(p_g, boundary_check=(0,)).to(tl.float32) else: b_gq = None for i_s in range(0, i_t * BT, BS): p_k = tl.make_block_ptr(k + (bos * H + i_h) * K, (K, T), (1, H*K), (0, i_s), (BK, BS), (0, 1)) p_v = tl.make_block_ptr(v + (bos * H + i_h) * V, (T, V), (H*V, 1), (i_s, i_v * BV), (BS, BV), (1, 0)) # [BK, BS] b_k = tl.load(p_k, boundary_check=(0, 1)) # [BS, BV] b_v = tl.load(p_v, boundary_check=(0, 1)) # [BT, BS] b_s = tl.dot(b_q, b_k) * scale * RCP_LN2 if USE_G: o_k = i_s + tl.arange(0, BS) m_k = o_k < T b_gk = tl.load(g_cumsum + (bos + o_k) * HQ + i_hq, mask=m_k, other=0).to(tl.float32) b_s += b_gq[:, None] - b_gk[None, :] # [BT, BS] b_m, b_mp = tl.maximum(b_m, tl.max(b_s, 1)), b_m b_r = exp2(b_mp - b_m) # [BT, BS] b_p = exp2(b_s - b_m[:, None]) # [BT] b_acc = b_acc * b_r + tl.sum(b_p, 1) # [BT, BV] b_o = b_o * b_r[:, None] + tl.dot(b_p.to(b_q.dtype), b_v) b_mp = b_m # [BT] o_q = i_t * BT + tl.arange(0, BT) for i_s in range(i_t * BT, min((i_t + 1) * BT, T), BS): p_k = tl.make_block_ptr(k + (bos * H + i_h) * K, (K, T), (1, H*K), (0, i_s), (BK, BS), (0, 1)) p_v = tl.make_block_ptr(v + (bos * H + i_h) * V, (T, V), (H*V, 1), (i_s, i_v * BV), (BS, BV), (1, 0)) # [BS] o_k = i_s + tl.arange(0, BS) m_k = o_k < T # [BK, BS] b_k = tl.load(p_k, boundary_check=(0, 1)) # [BS, BV] b_v = tl.load(p_v, boundary_check=(0, 1)) # [BT, BS] b_s = tl.dot(b_q, b_k) * scale * RCP_LN2 if USE_G: b_gk = tl.load(g_cumsum + (bos + o_k) * HQ + i_hq, mask=m_k, other=0).to(tl.float32) b_s += b_gq[:, None] - b_gk[None, :] b_s = tl.where((o_q[:, None] >= o_k[None, :]) & m_k[None, :], b_s, float('-inf')) # [BT] b_m, b_mp = tl.maximum(b_m, tl.max(b_s, 1)), b_m b_r = exp2(b_mp - b_m) # [BT, BS] b_p = exp2(b_s - b_m[:, None]) # [BT] b_acc = b_acc * b_r + tl.sum(b_p, 1) # [BT, BV] b_o = b_o * b_r[:, None] + tl.dot(b_p.to(b_q.dtype), b_v) b_mp = b_m b_o = b_o / b_acc[:, None] b_m += log2(b_acc) tl.store(p_o, b_o.to(p_o.dtype.element_ty), boundary_check=(0, 1)) tl.store(p_lse, b_m.to(p_lse.dtype.element_ty), boundary_check=(0,)) @triton.jit def parallel_attn_bwd_kernel_preprocess( o, do, delta, B: tl.constexpr, V: tl.constexpr, ): i_n = tl.program_id(0) o_d = tl.arange(0, B) m_d = o_d < V b_o = tl.load(o + i_n * V + o_d, mask=m_d, other=0) b_do = tl.load(do + i_n * V + o_d, mask=m_d, other=0).to(tl.float32) b_delta = tl.sum(b_o * b_do) tl.store(delta + i_n, b_delta.to(delta.dtype.element_ty)) @triton.heuristics({ 'USE_G': lambda args: args['g_cumsum'] is not None, 'IS_VARLEN': lambda args: args['cu_seqlens'] is not None, }) @triton.jit(do_not_specialize=['T']) def parallel_attn_bwd_kernel_dq( q, k, v, lse, delta, do, dq, dg_cumsum, g_cumsum, scale, cu_seqlens, chunk_indices, T, B: tl.constexpr, H: tl.constexpr, HQ: tl.constexpr, G: tl.constexpr, K: tl.constexpr, V: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr, BK: tl.constexpr, BV: tl.constexpr, IS_VARLEN: tl.constexpr, USE_G: tl.constexpr, ): i_v, i_t, i_bh = tl.program_id(0), tl.program_id(1), tl.program_id(2) i_b, i_hq = i_bh // HQ, i_bh % HQ i_h = i_hq // G if IS_VARLEN: i_n, i_t = tl.load(chunk_indices + i_t * 2).to(tl.int32), tl.load(chunk_indices + i_t * 2 + 1).to(tl.int32) bos, eos = tl.load(cu_seqlens + i_n).to(tl.int32), tl.load(cu_seqlens + i_n + 1).to(tl.int32) T = eos - bos else: i_n = i_b bos, eos = i_n * T, i_n * T + T # NOTE: we must multiply RCP_LN2 after tl.dot for high precision RCP_LN2: tl.constexpr = 1.4426950216 p_q = tl.make_block_ptr(q + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_t * BT, 0), (BT, BK), (1, 0)) p_dq = tl.make_block_ptr(dq + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_t * BT, 0), (BT, BK), (1, 0)) p_do = tl.make_block_ptr(do + (bos * HQ + i_hq) * V, (T, V), (HQ*V, 1), (i_t * BT, i_v * BV), (BT, BV), (1, 0)) p_lse = tl.make_block_ptr(lse + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) p_delta = tl.make_block_ptr(delta + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) # [BT, BK] b_q = tl.load(p_q, boundary_check=(0, 1)) # [BT, BV] b_do = tl.load(p_do, boundary_check=(0, 1)) # [BT] b_lse = tl.load(p_lse, boundary_check=(0,)) b_delta = tl.load(p_delta, boundary_check=(0,)) # [BT, BK] b_dq = tl.zeros([BT, BK], dtype=tl.float32) if USE_G: b_dg = tl.zeros([BT], dtype=tl.float32) p_gq = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) b_gq = tl.load(p_gq, boundary_check=(0,)).to(tl.float32) else: b_gq = None b_dg = None o_q = i_t * BT + tl.arange(0, BT) for i_s in range(0, i_t * BT, BS): p_k = tl.make_block_ptr(k + (bos * H + i_h) * K, (K, T), (1, H*K), (0, i_s), (BK, BS), (0, 1)) p_v = tl.make_block_ptr(v + (bos * H + i_h) * V, (V, T), (1, H*V), (i_v * BV, i_s), (BV, BS), (0, 1)) o_k = i_s + tl.arange(0, BS) m_k = o_k < T # [BK, BS] b_k = tl.load(p_k, boundary_check=(0, 1)) # [BV, BS] b_v = tl.load(p_v, boundary_check=(0, 1)) # [BT, BS] b_s = tl.dot(b_q, b_k) * scale * RCP_LN2 if USE_G: b_gk = tl.load(g_cumsum + (bos + o_k) * HQ + i_hq, mask=m_k, other=0).to(tl.float32) b_s += b_gq[:, None] - b_gk[None, :] b_s = tl.where((o_q[:, None] >= o_k[None, :]) & m_k[None, :], b_s, float('-inf')) b_p = exp2(b_s - b_lse[:, None]) # [BT, BV] @ [BV, BS] -> [BT, BS] b_dp = tl.dot(b_do, b_v) b_ds = b_p * (b_dp.to(tl.float32) - b_delta[:, None]) # [BT, BS] @ [BS, BK] -> [BT, BK] b_dq += tl.dot(b_ds.to(b_k.dtype), tl.trans(b_k)) if USE_G: b_dg += tl.sum(b_ds, 1) # [BT] o_q = i_t * BT + tl.arange(0, BT) for i_s in range(i_t * BT, min((i_t + 1) * BT, T), BS): p_k = tl.make_block_ptr(k + (bos * H + i_h) * K, (K, T), (1, H*K), (0, i_s), (BK, BS), (0, 1)) p_v = tl.make_block_ptr(v + (bos * H + i_h) * V, (V, T), (1, H*V), (i_v * BV, i_s), (BV, BS), (0, 1)) # [BS] o_k = i_s + tl.arange(0, BS) m_k = o_k < T # [BK, BS] b_k = tl.load(p_k, boundary_check=(0, 1)) # [BV, BS] b_v = tl.load(p_v, boundary_check=(0, 1)) # [BT, BS] b_s = tl.dot(b_q, b_k) * scale * RCP_LN2 if USE_G: p_gk = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) b_gk = tl.load(p_gk, boundary_check=(0,)).to(tl.float32) b_s += b_gq[:, None] - b_gk[None, :] b_p = tl.where((o_q[:, None] >= o_k[None, :]) & m_k[None, :], exp2(b_s - b_lse[:, None]), 0) # [BT, BV] @ [BV, BS] -> [BT, BS] b_dp = tl.dot(b_do, b_v) b_ds = b_p * (b_dp.to(tl.float32) - b_delta[:, None]) # [BT, BS] @ [BS, BK] -> [BT, BK] b_dq += tl.dot(b_ds.to(b_k.dtype), tl.trans(b_k)) if USE_G: b_dg += tl.sum(b_ds, 1) b_dq *= scale tl.store(p_dq, b_dq.to(p_dq.dtype.element_ty), boundary_check=(0, 1)) if USE_G: p_dg = tl.make_block_ptr(dg_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) tl.store(p_dg, b_dg.to(p_dg.dtype.element_ty), boundary_check=(0,)) @triton.heuristics({ 'USE_G': lambda args: args['g_cumsum'] is not None, 'IS_VARLEN': lambda args: args['cu_seqlens'] is not None, }) @triton.jit(do_not_specialize=['T']) def parallel_attn_bwd_kernel_dkv( q, k, v, g_cumsum, lse, delta, do, dk, dv, dg_cumsum, cu_seqlens, chunk_indices, scale, T, B: tl.constexpr, H: tl.constexpr, HQ: tl.constexpr, G: tl.constexpr, K: tl.constexpr, V: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr, BK: tl.constexpr, BV: tl.constexpr, USE_G: tl.constexpr, IS_VARLEN: tl.constexpr, ): i_v, i_t, i_bh = tl.program_id(0), tl.program_id(1), tl.program_id(2) i_b, i_hq = i_bh // HQ, i_bh % HQ i_h = i_hq // G if IS_VARLEN: i_n, i_t = tl.load(chunk_indices + i_t * 2).to(tl.int32), tl.load(chunk_indices + i_t * 2 + 1).to(tl.int32) bos, eos = tl.load(cu_seqlens + i_n).to(tl.int32), tl.load(cu_seqlens + i_n + 1).to(tl.int32) T = eos - bos else: i_n = i_b bos, eos = i_n * T, i_n * T + T RCP_LN2: tl.constexpr = 1.4426950216 p_k = tl.make_block_ptr(k + (bos * H + i_h) * K, (T, K), (H*K, 1), (i_t * BT, 0), (BT, BK), (1, 0)) p_v = tl.make_block_ptr(v + (bos * H + i_h) * V, (T, V), (H*V, 1), (i_t * BT, i_v * BV), (BT, BV), (1, 0)) p_dk = tl.make_block_ptr(dk + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_t * BT, 0), (BT, BK), (1, 0)) p_dv = tl.make_block_ptr(dv + (bos * HQ + i_hq) * V, (T, V), (HQ*V, 1), (i_t * BT, i_v * BV), (BT, BV), (1, 0)) # [BT, BK] b_k = tl.load(p_k, boundary_check=(0, 1)) b_dk = tl.zeros([BT, BK], dtype=tl.float32) # [BT, BV] b_v = tl.load(p_v, boundary_check=(0, 1)) b_dv = tl.zeros([BT, BV], dtype=tl.float32) o_k = i_t * BT + tl.arange(0, BT) if USE_G: p_gk = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) b_gk = tl.load(p_gk, boundary_check=(0,)).to(tl.float32) b_dg = tl.zeros([BT], dtype=tl.float32) else: b_gk = None b_dg = None for i_s in range(i_t * BT, min((i_t + 1) * BT, T), BS): p_q = tl.make_block_ptr(q + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_s, 0), (BS, BK), (1, 0)) p_do = tl.make_block_ptr(do + (bos * HQ + i_hq) * V, (T, V), (HQ*V, 1), (i_s, i_v * BV), (BS, BV), (1, 0)) p_lse = tl.make_block_ptr(lse + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) p_delta = tl.make_block_ptr(delta + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) # [BS] o_q = i_s + tl.arange(0, BS) m_q = o_q < T # [BS, BK] b_q = tl.load(p_q, boundary_check=(0, 1)) # [BS, BV] b_do = tl.load(p_do, boundary_check=(0, 1)) # [BS] b_lse = tl.load(p_lse, boundary_check=(0,)) b_delta = tl.load(p_delta, boundary_check=(0,)) # [BT, BS] b_s = tl.dot(b_k, tl.trans(b_q)) * scale * RCP_LN2 if USE_G: p_gq = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) b_gq = tl.load(p_gq, boundary_check=(0,)).to(tl.float32) b_s += b_gq[None, :] - b_gk[:, None] b_p = tl.where((o_k[:, None] <= o_q[None, :]) & m_q[None, :], exp2(b_s - b_lse[None, :]), 0) # [BT, BS] @ [BS, BV] -> [BT, BV] b_dv += tl.dot(b_p.to(b_do.dtype), b_do) # [BT, BV] @ [BV, BS] -> [BT, BS] b_dp = tl.dot(b_v, tl.trans(b_do)) # [BT, BS] b_ds = b_p * (b_dp - b_delta[None, :]) # [BT, BS] @ [BS, BK] -> [BT, BK] b_dk += tl.dot(b_ds.to(b_q.dtype), b_q) if USE_G: b_dg -= tl.sum(b_ds, 1) for i_s in range((i_t + 1) * BT, tl.cdiv(T, BS) * BS, BS): p_q = tl.make_block_ptr(q + (bos * HQ + i_hq) * K, (T, K), (HQ*K, 1), (i_s, 0), (BS, BK), (1, 0)) p_do = tl.make_block_ptr(do + (bos * HQ + i_hq) * V, (T, V), (HQ*V, 1), (i_s, i_v * BV), (BS, BV), (1, 0)) p_lse = tl.make_block_ptr(lse + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) p_delta = tl.make_block_ptr(delta + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) # [BS] o_q = i_s + tl.arange(0, BS) m_q = o_q < T # [BS, BK] b_q = tl.load(p_q, boundary_check=(0, 1)) # [BS, BV] b_do = tl.load(p_do, boundary_check=(0, 1)) # [BS] b_lse = tl.load(p_lse, boundary_check=(0,)) b_delta = tl.load(p_delta, boundary_check=(0,)) # [BT, BS] b_s = tl.dot(b_k, tl.trans(b_q)) * scale * RCP_LN2 if USE_G: p_gq = tl.make_block_ptr(g_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_s,), (BS,), (0,)) b_gq = tl.load(p_gq, boundary_check=(0,)).to(tl.float32) b_s += b_gq[None, :] - b_gk[:, None] b_p = tl.where(m_q[None, :], exp2(b_s - b_lse[None, :]), 0) # [BT, BS] @ [BS, BV] -> [BT, BV] b_dv += tl.dot(b_p.to(b_do.dtype), b_do) # [BT, BV] @ [BV, BS] -> [BT, BS] b_dp = tl.dot(b_v, tl.trans(b_do)) # [BT, BS] b_ds = b_p * (b_dp - b_delta[None, :]) # [BT, BS] @ [BS, BK] -> [BT, BK] b_dk += tl.dot(b_ds.to(b_q.dtype), b_q) if USE_G: b_dg -= tl.sum(b_ds, 1) b_dk = b_dk * scale tl.store(p_dk, b_dk.to(p_dk.dtype.element_ty), boundary_check=(0, 1)) tl.store(p_dv, b_dv.to(p_dv.dtype.element_ty), boundary_check=(0, 1)) if USE_G: p_dg = tl.make_block_ptr(dg_cumsum + bos * HQ + i_hq, (T,), (HQ,), (i_t * BT,), (BT,), (0,)) tl.store(p_dg, b_dg.to(p_dg.dtype.element_ty), boundary_check=(0,)) def parallel_attn_fwd( q: torch.Tensor, k: torch.Tensor, v: torch.Tensor, g_cumsum: torch.Tensor, scale: float, cu_seqlens: torch.LongTensor | None = None, chunk_indices: torch.LongTensor | None = None, ): B, T, H, K, V = *k.shape, v.shape[-1] HQ = q.shape[2] G = HQ // H BT = 128 if check_shared_mem('hopper', q.device.index): BS = min(64, max(16, triton.next_power_of_2(T))) BK = min(256, max(16, triton.next_power_of_2(K))) BV = min(256, max(16, triton.next_power_of_2(V))) num_warps = 8 elif check_shared_mem('ampere', q.device.index): BS = min(32, max(16, triton.next_power_of_2(T))) BK = min(256, max(16, triton.next_power_of_2(K))) BV = min(128, max(16, triton.next_power_of_2(V))) num_warps = 4 else: BS = min(32, max(16, triton.next_power_of_2(T))) BK = min(256, max(16, triton.next_power_of_2(K))) BV = min(64, max(16, triton.next_power_of_2(V))) num_warps = 2 NK = triton.cdiv(K, BK) NV = triton.cdiv(V, BV) if chunk_indices is None and cu_seqlens is not None: chunk_indices = prepare_chunk_indices(cu_seqlens, BT) NT = triton.cdiv(T, BT) if cu_seqlens is None else len(chunk_indices) assert NK == 1, "The key dimension can not be larger than 256" o = torch.empty(B, T, HQ, V, dtype=v.dtype, device=q.device) lse = torch.empty(B, T, HQ, dtype=torch.float, device=q.device) grid = (NV, NT, B * HQ) parallel_attn_fwd_kernel[grid]( q=q, k=k, v=v, o=o, g_cumsum=g_cumsum, lse=lse, scale=scale, cu_seqlens=cu_seqlens, chunk_indices=chunk_indices, B=B, T=T, H=H, HQ=HQ, G=G, K=K, V=V, BT=BT, BS=BS, BK=BK, BV=BV, num_warps=num_warps, ) return o, lse def parallel_attn_bwd_preprocess( o: torch.Tensor, do: torch.Tensor, ): V = o.shape[-1] delta = torch.empty_like(o[..., 0], dtype=torch.float) parallel_attn_bwd_kernel_preprocess[(delta.numel(),)]( o=o, do=do, delta=delta, B=triton.next_power_of_2(V), V=V, ) return delta def parallel_attn_bwd( q: torch.Tensor, k: torch.Tensor, v: torch.Tensor, o: torch.Tensor, g_cumsum: torch.Tensor, lse: torch.Tensor, do: torch.Tensor, scale: float = None, chunk_size: int = 128, cu_seqlens: torch.LongTensor | None = None, chunk_indices: torch.LongTensor | None = None, ): B, T, H, K, V = *k.shape, v.shape[-1] HQ = q.shape[2] G = HQ // H if check_shared_mem('hopper'): BT = 128 BS = 64 BK = max(triton.next_power_of_2(K), 16) BV = max(triton.next_power_of_2(V), 16) num_warps = 8 elif check_shared_mem('ampere'): BS = 32 BK = max(triton.next_power_of_2(K), 16) BV = max(triton.next_power_of_2(V), 16) BT = 128 if K <= 64 else 64 num_warps = 4 else: BT = 64 BS = 32 BK = max(triton.next_power_of_2(K), 16) BV = min(max(triton.next_power_of_2(V), 16), 64) num_warps = 2 if chunk_indices is None and cu_seqlens is not None: chunk_indices = prepare_chunk_indices(cu_seqlens, BT) NT = triton.cdiv(T, BT) if cu_seqlens is None else len(chunk_indices) NV = triton.cdiv(V, BV) delta = parallel_attn_bwd_preprocess(o, do) dq = torch.empty(B, T, HQ, K, dtype=k.dtype if H == HQ else torch.float, device=q.device) dk = torch.empty(B, T, HQ, K, dtype=k.dtype if H == HQ else torch.float, device=q.device) dv = torch.empty(B, T, HQ, V, dtype=v.dtype if H == HQ else torch.float, device=q.device) grid = (NV, NT, B * HQ) dg_cumsum, dg_cumsum_k = None, None if g_cumsum is not None: dg_cumsum = torch.empty(B, T, HQ, dtype=torch.float, device=q.device) dg_cumsum_k = torch.empty(B, T, HQ, dtype=torch.float, device=q.device) parallel_attn_bwd_kernel_dq[grid]( q=q, k=k, v=v, g_cumsum=g_cumsum, lse=lse, delta=delta, do=do, dq=dq, dg_cumsum=dg_cumsum, cu_seqlens=cu_seqlens, chunk_indices=chunk_indices, scale=scale, T=T, B=B, H=H, HQ=HQ, G=G, K=K, V=V, BT=BT, BS=BS, BK=BK, BV=BV, num_warps=num_warps, ) parallel_attn_bwd_kernel_dkv[grid]( q=q, k=k, v=v, g_cumsum=g_cumsum, lse=lse, delta=delta, do=do, dk=dk, dv=dv, dg_cumsum=dg_cumsum_k, cu_seqlens=cu_seqlens, chunk_indices=chunk_indices, scale=scale, T=T, B=B, H=H, HQ=HQ, G=G, K=K, V=V, BT=BT, BS=BS, BK=BK, BV=BV, num_warps=num_warps, ) dk = reduce(dk, 'b t (h g) k -> b t h k', g=G, reduction='sum') dv = reduce(dv, 'b t (h g) v -> b t h v', g=G, reduction='sum') if g_cumsum is not None: dg_cumsum.add_(dg_cumsum_k) return dq, dk, dv, dg_cumsum @torch.compile class ParallelAttentionFunction(torch.autograd.Function): @staticmethod @contiguous @autocast_custom_fwd def forward(ctx, q, k, v, g, scale, cu_seqlens, chunk_indices=None): ctx.dtype = q.dtype RCP_LN2: float = 1.4426950216 g_cumsum = chunk_global_cumsum(g, cu_seqlens=cu_seqlens, scale=RCP_LN2) if g is not None else None o, lse = parallel_attn_fwd( q=q, k=k, v=v, g_cumsum=g_cumsum, scale=scale, cu_seqlens=cu_seqlens, chunk_indices=chunk_indices, ) ctx.save_for_backward(q, k, v, o, g_cumsum, lse) ctx.cu_seqlens = cu_seqlens ctx.scale = scale return o.to(q.dtype) @staticmethod @contiguous @autocast_custom_bwd def backward(ctx, do): q, k, v, o, g_cumsum, lse = ctx.saved_tensors dq, dk, dv, dg = parallel_attn_bwd( q=q, k=k, v=v, o=o, g_cumsum=g_cumsum, lse=lse, do=do, scale=ctx.scale, cu_seqlens=ctx.cu_seqlens, ) if dg is not None: dg = chunk_global_cumsum(dg, cu_seqlens=ctx.cu_seqlens, reverse=True) return dq.to(q), dk.to(k), dv.to(v), dg, None, None, None def parallel_attn( q: torch.Tensor, k: torch.Tensor, v: torch.Tensor, g: torch.Tensor | None = None, scale: float | None = None, cu_seqlens: torch.LongTensor | None = None, head_first: bool = False, chunk_indices: torch.LongTensor | None = None, ) -> torch.Tensor: r""" Args: q (torch.Tensor): queries of shape `[B, T, HQ, K]`. k (torch.Tensor): keys of shape `[B, T, H, K]`. GQA will be applied if HQ is divisible by H. v (torch.Tensor): values of shape `[B, T, H, V]`. g (Optional[torch.Tensor]): log decay factors of shape `[B, T, H]`. scale (Optional[float]): Scale factor for attention scores. If not provided, it will default to `1 / sqrt(K)`. Default: `None`. cu_seqlens (torch.LongTensor): Cumulative sequence lengths of shape `[N+1]` used for variable-length training, consistent with the FlashAttention API. head_first (Optional[bool]): Whether the inputs are in the head-first format. Default: `False`. This argument has been deprecated. Returns: o (torch.Tensor): Outputs of shape `[B, T, HQ, V]`. """ if head_first: raise DeprecationWarning( "head_first is deprecated and will be removed in a future version. " "Please use head_first=False for now instead.", ) if not head_first and q.shape[1] < q.shape[2]: warnings.warn( f"Input tensor shape suggests potential format mismatch: seq_len ({q.shape[1]}) < num_heads ({q.shape[2]}). " "This may indicate the inputs were passed in head-first format [B, H, T, ...] " "when head_first=False was specified. " "Please verify your input tensor format matches the expected shape [B, T, H, ...].", ) if scale is None: scale = k.shape[-1] ** -0.5 if cu_seqlens is not None: assert q.shape[0] == 1, "batch size must be 1 when cu_seqlens are provided" o = ParallelAttentionFunction.apply(q, k, v, g, scale, cu_seqlens, chunk_indices) return o