add back in the archived code
This commit is contained in:
@@ -13,4 +13,496 @@ WHY ARCHIVED: Superseded by the current fmha.py which has:
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This backup uses the old TMEM round-trip approach which is
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FUNDAMENTALLY BROKEN (Ld32x32bOp/St32x32bOp column mismatch,
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even NO-OP round-trip produces ~3% error).
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FMHA kernel: QK -> online softmax -> PV (CuTeDSL, Blackwell SM100).
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Migrated from tests/unit/test_fmha_v3_stage_c.py — Stage C proven path.
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P stored to TMEM via register bridge, PV reads from TMEM.
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O rescale via correction_rescale atoms, O normalization via TMEM round-trip.
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"""
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import torch, cutlass, cutlass.cute as cute, cutlass.utils as utils, cutlass.pipeline as pipeline
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from cutlass.cute.nvgpu import cpasync, tcgen05
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from cutlass import Float32, BFloat16, Int32, Boolean, const_expr
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from cutlass.utils import LayoutEnum
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from cutlass.utils.tmem_allocator import find_tmem_tensor_col_offset
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from cutlass.utils.blackwell_helpers import get_smem_store_op
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import cuda.bindings.driver as cuda
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import cutlass.torch as ct
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import math
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class FmhaKernel:
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def __init__(self, head_dim=64, s_k=128, scale_softmax=None, use_smem_p=None, normalize=True):
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self.head_dim = head_dim
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self.s_k = s_k
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self.n_kv_tiles = s_k // 128
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self.pv_n_tile = min(head_dim, 256) # tcgen05 MMA max N=256
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self.n_pv_tiles = head_dim // self.pv_n_tile
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self.use_smem_p = use_smem_p if use_smem_p is not None else (head_dim > 64)
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self.normalize = normalize # D5a: False = emit un-normalized O + lse
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self.acc_dtype = Float32; self.qk_acc_dtype = Float32
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self.q_dtype = BFloat16; self.o_dtype = BFloat16; self.c_dtype = BFloat16
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self.use_2cta_instrs = False; self.epilog_sync_bar_id = 1
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self.cluster_shape_mn = (1, 1); self.cta_group = tcgen05.CtaGroup.ONE
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self.epilogue_warp_id = (0,1,2,3); self.mma_warp_id = 4; self.tma_warp_id = 5
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self.threads_per_cta = 192; self.num_c_stage = 2
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self.kv_stage = 2; self.q_stage = 1; self.num_c_stage = 2
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self.scale_softmax = scale_softmax if scale_softmax is not None else 1.0 / math.sqrt(self.head_dim)
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self.scale_softmax_log2 = self.scale_softmax * math.log2(math.e)
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def _setup(self, qk_mma, pv_mma):
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qk_ik = cute.size(qk_mma.shape_mnk, mode=[2])
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self.qk_mma_tiler = (128, 128, qk_ik * 4)
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pv_ik = cute.size(pv_mma.shape_mnk, mode=[2])
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self.pv_mma_tiler = (128, self.pv_n_tile, pv_ik * (128 // pv_ik))
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self.mma_tiler = self.qk_mma_tiler
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self.cluster_layout_vmnk = cute.tiled_divide(cute.make_layout((1,1,1)), (qk_mma.thr_id.shape,))
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self.cta_tile_shape_mnk = (self.qk_mma_tiler[0]//cute.size(qk_mma.thr_id.shape), self.pv_n_tile, self.qk_mma_tiler[2])
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self.c_layout = LayoutEnum.ROW_MAJOR
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self.epi_tile = utils.sm100.compute_epilogue_tile_shape(self.cta_tile_shape_mnk, False, self.c_layout, self.o_dtype)
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self.num_ab_stage = 1; self.num_acc_stage = 1
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self.q_smem_s = utils.sm100.make_smem_layout_a(qk_mma, self.qk_mma_tiler, self.q_dtype, self.q_stage)
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self.k_smem_s = utils.sm100.make_smem_layout_b(qk_mma, self.qk_mma_tiler, self.q_dtype, self.kv_stage)
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self.v_smem_s = utils.sm100.make_smem_layout_b(pv_mma, self.pv_mma_tiler, self.q_dtype, self.kv_stage)
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self.c_smem_s = utils.sm100.make_smem_layout_epi(self.o_dtype, self.c_layout, self.epi_tile, 2)
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self.p_tmem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
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# P SMEM layout (PV A-operand) — used for SMEM-P path
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self.p_smem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
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qk_thr = qk_mma.get_slice(0); qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
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tStS = qk_thr.make_fragment_C(qk_as)
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pv_thr = pv_mma.get_slice(0); pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
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tOtO = pv_thr.make_fragment_C(pv_as)
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self.tmem_s0_offset = 0
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if not self.use_smem_p:
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# TMEM-P: S at 0, P at 32, O after P and S
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self.tmem_p0_offset = 32
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p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
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p_end = self.tmem_p0_offset + p_cols_fp32
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s_cols = self.qk_mma_tiler[1]
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o_after = max(s_cols, p_end)
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self.tmem_o0_offset = ((o_after + 31) // 32) * 32
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o_cols = find_tmem_tensor_col_offset(tOtO)
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total = self.tmem_o0_offset + o_cols
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else:
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# SMEM-P: P not in TMEM. S and O share TMEM (sequential).
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self.tmem_p0_offset = -1 # unused
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self.tmem_o0_offset = 0
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s_cols = self.qk_mma_tiler[1]
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o_cols = find_tmem_tensor_col_offset(tOtO)
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total = max(s_cols, o_cols)
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self.num_tmem_alloc_cols = 1
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while self.num_tmem_alloc_cols < total:
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self.num_tmem_alloc_cols *= 2
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# tOrP0 offset: BF16 elements from TMEM base to P0 (TMEM-P only)
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# = tmem_p0_offset * (FP32_width / BF16_width) if TMEM-P, else 0
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self.tOrP0_offset = max(self.tmem_p0_offset, 0) * 2 # Python int
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cta = cute.size(qk_mma.thr_id.shape)
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q_s = cute.slice_(self.q_smem_s,(None,None,None,0))
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k_s = cute.slice_(self.k_smem_s,(None,None,None,0))
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v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
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self.q_tx_bytes = cute.size_in_bytes(self.q_dtype, q_s) * cta
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self.kv_tx_bytes = (cute.size_in_bytes(self.q_dtype, k_s) +
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cute.size_in_bytes(self.q_dtype, v_s)) * cta
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@cute.jit
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def __call__(self, q, k, v, c, stream, lse=None):
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self.q_dtype = q.element_type; self.o_dtype = c.element_type; self.c_dtype = self.o_dtype
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self.a_major = LayoutEnum.from_tensor(q).mma_major_mode()
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self.b_major = LayoutEnum.from_tensor(k).mma_major_mode()
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v_fmha = cute.make_tensor(
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v.iterator,
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cute.make_layout(
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(self.pv_n_tile, self.s_k, 1),
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stride=(1, self.pv_n_tile, self.pv_n_tile * self.s_k),
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),
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)
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self.v_major = LayoutEnum.from_tensor(v_fmha).mma_major_mode()
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self.c_layout = LayoutEnum.from_tensor(c)
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qk_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, self.a_major, self.b_major, self.qk_acc_dtype, self.cta_group, (128,128), tcgen05.OperandSource.SMEM)
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pv_a_major = self.a_major if self.use_smem_p else cute.nvgpu.OperandMajorMode.K
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pv_source = tcgen05.OperandSource.SMEM if self.use_smem_p else tcgen05.OperandSource.TMEM
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pv_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, pv_a_major, self.v_major, self.qk_acc_dtype, self.cta_group, (128,self.pv_n_tile), pv_source)
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self._setup(qk_mma, pv_mma)
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q_s = cute.slice_(self.q_smem_s,(None,None,None,0)); k_s = cute.slice_(self.k_smem_s,(None,None,None,0)); v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
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tma_q,mQ = cute.nvgpu.make_tiled_tma_atom_A(utils.sm100.cluster_shape_to_tma_atom_A(self.cluster_shape_mn,qk_mma.thr_id),q,q_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
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tma_k,mK = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,qk_mma.thr_id),k,k_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
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tma_v,mV = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,pv_mma.thr_id),v_fmha,v_s,self.pv_mma_tiler,pv_mma,self.cluster_layout_vmnk.shape)
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epi_s = cute.select(self.c_smem_s,mode=[0,1])
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tma_c,mC = cpasync.make_tiled_tma_atom(cpasync.CopyBulkTensorTileS2GOp(),c,epi_s,self.epi_tile)
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# Always create a valid mLSE tensor for the kernel.
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# CuTeDSL doesn't support None parameters in @cute.kernel.
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# For normalize=True, mLSE is unused (dead-code-eliminated by compiler).
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if const_expr(lse is None):
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lse = cute.make_tensor(c.iterator, cute.make_layout((1,), stride=(0,)))
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self._kernel(qk_mma,pv_mma,tma_q,mQ,tma_k,mK,tma_v,mV,tma_c,mC,self.cluster_layout_vmnk,self.q_smem_s,self.k_smem_s,self.v_smem_s,self.p_tmem_s,self.p_smem_s,self.c_smem_s,self.epi_tile,lse).launch(grid=(1,1,1),block=[self.threads_per_cta,1,1],stream=stream)
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@cute.kernel
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def _kernel(self, qk_mma, pv_mma, tma_q, mQ, tma_k, mK, tma_v, mV, tma_c, mC, cl_vmnk, q_smem_s, k_smem_s, v_smem_s, p_tmem_s, p_smem_s, c_smem_s, epi_tile, mLSE):
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warp_idx = cute.arch.make_warp_uniform(cute.arch.warp_idx())
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tidx,_,_ = cute.arch.thread_idx()
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if warp_idx == self.tma_warp_id:
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cpasync.prefetch_descriptor(tma_q); cpasync.prefetch_descriptor(tma_k); cpasync.prefetch_descriptor(tma_v); cpasync.prefetch_descriptor(tma_c)
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@cute.struct
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class SS:
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q_bar: cute.struct.MemRange[cutlass.Int64, self.q_stage*2]
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kv_bar: cute.struct.MemRange[cutlass.Int64, self.kv_stage*2]
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s_bar: cute.struct.MemRange[cutlass.Int64, 2]
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acc_bar: cute.struct.MemRange[cutlass.Int64, self.num_acc_stage*2]
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tmem_dealloc: cutlass.Int64; holding: cutlass.Int32
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smem = utils.SmemAllocator(); st = smem.allocate(SS)
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qp,qc = pipeline.PipelineTmaUmma.create(barrier_storage=st.q_bar.data_ptr(),num_stages=self.q_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.q_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
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kvp,kvc = pipeline.PipelineTmaUmma.create(barrier_storage=st.kv_bar.data_ptr(),num_stages=self.kv_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.kv_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
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s_prod,s_cons = pipeline.PipelineUmmaAsync.create(barrier_storage=st.s_bar.data_ptr(),num_stages=1,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,32*len(self.epilogue_warp_id))).make_participants()
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softmax_done_bar = pipeline.NamedBarrier(barrier_id=3, num_threads=32 + 32*len(self.epilogue_warp_id))
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final_o_bar = pipeline.NamedBarrier(barrier_id=4, num_threads=32 + 32*len(self.epilogue_warp_id))
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acc_pipe = pipeline.PipelineUmmaAsync.create(barrier_storage=st.acc_bar.data_ptr(),num_stages=self.num_acc_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,len(self.epilogue_warp_id)),cta_layout_vmnk=cl_vmnk,defer_sync=True)
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tmem_bar = pipeline.NamedBarrier(barrier_id=2,num_threads=32*len((self.mma_warp_id,*self.epilogue_warp_id)))
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tmem = utils.TmemAllocator(st.holding.ptr,barrier_for_retrieve=tmem_bar,allocator_warp_id=self.epilogue_warp_id[0],is_two_cta=cute.size(qk_mma.thr_id.shape)==2,two_cta_tmem_dealloc_mbar_ptr=st.tmem_dealloc.ptr)
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pipeline.pipeline_init_arrive(cluster_shape_mn=cl_vmnk,is_relaxed=True)
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sQ = smem.allocate_tensor(element_type=self.q_dtype,layout=q_smem_s.outer,byte_alignment=128,swizzle=q_smem_s.inner)
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sK = smem.allocate_tensor(element_type=self.q_dtype,layout=k_smem_s.outer,byte_alignment=128,swizzle=k_smem_s.inner)
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sV = smem.allocate_tensor(element_type=self.q_dtype,layout=v_smem_s.outer,byte_alignment=128,swizzle=v_smem_s.inner)
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sC = smem.allocate_tensor(element_type=self.o_dtype,layout=c_smem_s.outer,byte_alignment=128,swizzle=c_smem_s.inner)
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sP = smem.allocate_tensor(element_type=self.q_dtype,layout=p_smem_s.outer,byte_alignment=128,swizzle=p_smem_s.inner)
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gQ = cute.local_tile(mQ,cute.slice_(self.qk_mma_tiler,(None,0,None)),(None,None,None))
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gK = cute.local_tile(mK,cute.slice_(self.qk_mma_tiler,(0,None,None)),(None,None,None))
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gV = cute.local_tile(mV,cute.slice_(self.pv_mma_tiler,(0,None,None)),(None,None,None))
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gC = cute.local_tile(mC,cute.slice_(self.pv_mma_tiler,(None,None,0)),(None,None,None))
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n_kv_tiles = cute.size(gK, mode=[3])
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qk_thr = qk_mma.get_slice(0); pv_thr = pv_mma.get_slice(0)
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tCgQ = qk_thr.partition_A(gQ); tCgK = qk_thr.partition_B(gK)
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tCgV = pv_thr.partition_B(gV); tCgC = pv_thr.partition_C(gC)
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a_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,0,None,0)).shape)
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tAsQ,tAgQ = cpasync.tma_partition(tma_q,0,a_lay,cute.group_modes(sQ,0,3),cute.group_modes(tCgQ,0,3))
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b_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,None,0,0)).shape)
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tBsK,tBgK = cpasync.tma_partition(tma_k,0,b_lay,cute.group_modes(sK,0,3),cute.group_modes(tCgK,0,3))
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tVsV,tVgV = cpasync.tma_partition(tma_v,0,b_lay,cute.group_modes(sV,0,3),cute.group_modes(tCgV,0,3))
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tAgQ = tAgQ[(None,0,None,0)]; tBgK = tBgK[(None,0,None,0)]; tVgV = tVgV[(None,0,None,0)]
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tCrQ = qk_mma.make_fragment_A(sQ); tCrK = qk_mma.make_fragment_B(sK)
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tCrV = pv_mma.make_fragment_B(sV)
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qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
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tStS = qk_thr.make_fragment_C(qk_as)
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tStS0 = cute.make_tensor(tStS.iterator + self.tmem_s0_offset, tStS.layout)
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pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
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tOtO = pv_thr.make_fragment_C(pv_as)
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tOtO0 = cute.make_tensor(tOtO.iterator + self.tmem_o0_offset, tOtO.layout)
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# PV A-operand: define both tOrP0 (TMEM-P) and tCrP (SMEM-P) unconditionally.
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# CuTeDSL scoping: variables must be assigned unconditionally (no if/else).
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tP = cute.make_tensor(tStS.iterator, p_tmem_s.outer)
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tOrP_base = pv_thr.make_fragment_A(tP if not self.use_smem_p else sP)
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tOrP = tOrP_base[(None,None,None,0)]
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tCrP = pv_mma.make_fragment_A(sP)
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# tOrP0: PV A-operand with TMEM column offset for P0 (TMEM-P path).
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# self.tOrP0_offset is pre-computed in _setup as a Python int.
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# Use const_expr if/else for compile-time conditional.
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if const_expr(self.tOrP0_offset > 0):
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tOrP0 = cute.make_tensor(tOrP.iterator + self.tOrP0_offset, tOrP.layout)
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else:
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tOrP0 = tOrP
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tCtO_fake = pv_mma.make_fragment_C(cute.append(pv_as, self.num_acc_stage))
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pipeline.pipeline_init_wait(cluster_shape_mn=cl_vmnk)
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# ===== TMA LOAD warp =====
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if warp_idx == self.tma_warp_id:
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qp.reset(); qh = qp.acquire_and_advance()
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cute.copy(tma_q, tAgQ[(None, Int32(0))], tAsQ[(None, qh.index)], tma_bar_ptr=qh.barrier)
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qp.tail()
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kvp.reset(); pk = kvp.try_acquire()
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for kt in cutlass.range(0, self.n_kv_tiles, 1, unroll=1):
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kvh = kvp.acquire_and_advance(pk)
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cute.copy(tma_k, tBgK[(None, kt)], tBsK[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
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cute.copy(tma_v, tVgV[(None, kt)], tVsV[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
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pk = cutlass.Boolean(1)
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kvp.tail()
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# ===== MMA warp =====
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if warp_idx == self.mma_warp_id:
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tmem.wait_for_alloc()
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qc.reset(); qh = qc.wait_and_advance(); qh.release()
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kvc.reset(); pk = kvc.try_wait()
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acc_st = pipeline.make_pipeline_state(pipeline.PipelineUserType.Producer, self.num_acc_stage)
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acc_pipe.producer_acquire(acc_st)
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for kt in range(self.n_kv_tiles):
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kvh = kvc.wait_and_advance(pk); pk = cutlass.Boolean(1)
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sh = s_prod.acquire_and_advance()
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qk_mma.set(tcgen05.Field.ACCUMULATE, False)
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for kb in cutlass.range(cute.size(tCrQ, mode=[2]), unroll_full=True):
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cute.gemm(qk_mma, tStS0, tCrQ[(None,None,kb,0)], tCrK[(None,None,kb,kvh.index)], tStS0)
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qk_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
sh.commit()
|
||||
softmax_done_bar.arrive_and_wait()
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, kt != 0)
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: PV reads P from TMEM
|
||||
for kb in cutlass.range(cute.size(tOrP0, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tOrP0[(None,None,kb)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
else:
|
||||
# SMEM-P: PV reads P from SMEM
|
||||
for kb in cutlass.range(cute.size(tCrP, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tCrP[(None,None,kb,0)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
kvh.release()
|
||||
acc_pipe.producer_commit(acc_st); acc_st.advance()
|
||||
final_o_bar.arrive()
|
||||
acc_pipe.producer_tail(acc_st)
|
||||
|
||||
# ===== SOFTMAX + CORRECTION EPILOGUE warps =====
|
||||
if warp_idx < self.mma_warp_id:
|
||||
tmem.allocate(self.num_tmem_alloc_cols)
|
||||
tmem.wait_for_alloc()
|
||||
tmem_ptr = tmem.retrieve_ptr(self.qk_acc_dtype)
|
||||
sfw_idx = tidx % (32 * len(self.epilogue_warp_id))
|
||||
|
||||
# S load atoms
|
||||
tmem_load_atom = cute.make_copy_atom(tcgen05.copy.Ld32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_load = tcgen05.make_tmem_copy(tmem_load_atom, tStS0)
|
||||
thr_load = tiled_tmem_load.get_slice(sfw_idx)
|
||||
tTMEM_LOADtS = thr_load.partition_S(tStS0)
|
||||
cS = cute.make_identity_tensor((self.qk_mma_tiler[0], self.qk_mma_tiler[1]))
|
||||
tScS = qk_thr.partition_C(cS)
|
||||
tTMEM_LOADcS = thr_load.partition_D(tScS)
|
||||
|
||||
# P store atoms: TMEM-P (always defined, only used when use_smem_p=False)
|
||||
p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
|
||||
tStP_layout = cute.composition(tStS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
# Use 0 as P offset when SMEM-P (these atoms are never used, but must be valid)
|
||||
tStP0 = cute.make_tensor(tStS.iterator + max(self.tmem_p0_offset, 0), tStP_layout)
|
||||
tmem_store_atom = cute.make_copy_atom(tcgen05.copy.St32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_store = tcgen05.make_tmem_copy(tmem_store_atom, tStP0)
|
||||
thr_store = tiled_tmem_store.get_slice(sfw_idx)
|
||||
tTMEM_STOREtP = thr_store.partition_D(tStP0)
|
||||
tScP_layout = cute.composition(tScS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
tScP = cute.make_tensor(tScS.iterator, tScP_layout)
|
||||
tTMEM_STOREcP = thr_store.partition_S(tScP)
|
||||
|
||||
# P SMEM copy atoms: SMEM-P
|
||||
# Per CUTLASS LLM guidance: use make_cotiled_copy with TV layout
|
||||
# from TMEM load partition, remapped to sP's codomain.
|
||||
# atom_layout_tv: (tid, vid) -> sP address
|
||||
# data_layout: sP coord -> sP address (includes swizzle)
|
||||
#
|
||||
# Build the TV layout from the TMEM load, remapped to sP's codomain.
|
||||
# The TMEM load's TV layout maps (tid, vid) -> tStS_addr.
|
||||
# tStS layout: ((128,128),1,1):((65536,1),0,0) => addr = m*65536 + k
|
||||
# sP_stage layout: ((128,16),1,(4,2)):((64,1),0,(16,8192)) + swizzle S<3,4,3>
|
||||
#
|
||||
# We need: (tid, vid) -> sP_addr.
|
||||
# Approach: use composition(sP_2d, tv_layout) where sP_2d maps
|
||||
# flat P index -> sP_addr, and we "unflatten" the TV layout's
|
||||
# tStS addresses into flat P indices.
|
||||
#
|
||||
# tStS addr -> flat P index: addr // 65536 * 128 + addr % 65536
|
||||
# Since k < 128 and stride is 65536, flat_idx = (addr >> 16) * 128 + (addr & 0xFFFF)
|
||||
# This is NOT affine, so we can't represent it as a Layout.
|
||||
#
|
||||
# FALLBACK: Use the coordinate-indexed approach (scalar SMEM writes).
|
||||
# This works but gives ~0.04 cosine loss vs TMEM-P at hd=64.
|
||||
# The make_cotiled_copy approach is tracked for future optimization.
|
||||
_sP_nostage = sP[(None, None, None, 0)] # remove stage dim
|
||||
|
||||
row_max = -Float32.inf
|
||||
row_sum = Float32(0.0)
|
||||
scale_log2 = Float32(self.scale_softmax_log2)
|
||||
|
||||
# O rescale atoms (hand-constructed, using composition layout like CUTLASS correction_rescale)
|
||||
corr_tile_size = 16
|
||||
tOcO = pv_thr.partition_C(cS)
|
||||
tOtO_i_layout = cute.composition(tOtO0.layout, cute.make_layout((128, corr_tile_size)))
|
||||
tOcO_i_layout = cute.composition(tOcO.layout, cute.make_layout((128, corr_tile_size)))
|
||||
tOtO_i = cute.make_tensor(tOtO0.iterator, tOtO_i_layout)
|
||||
tOcO_i = cute.make_tensor(tOcO.iterator, tOcO_i_layout)
|
||||
tmem_load_o_atom = cute.make_copy_atom(
|
||||
tcgen05.copy.Ld32x32bOp(tcgen05.copy.Repetition(corr_tile_size)),
|
||||
self.acc_dtype,
|
||||
)
|
||||
tmem_store_o_atom = cute.make_copy_atom(
|
||||
tcgen05.copy.St32x32bOp(tcgen05.copy.Repetition(corr_tile_size)),
|
||||
self.acc_dtype,
|
||||
)
|
||||
tiled_tmem_load_o = tcgen05.make_tmem_copy(tmem_load_o_atom, tOtO_i)
|
||||
tiled_tmem_store_o = tcgen05.make_tmem_copy(tmem_store_o_atom, tOtO_i)
|
||||
thr_tmem_load_o = tiled_tmem_load_o.get_slice(sfw_idx)
|
||||
thr_tmem_store_o = tiled_tmem_store_o.get_slice(sfw_idx)
|
||||
tTMEM_LOADtO = thr_tmem_load_o.partition_S(tOtO_i)
|
||||
tTMEM_LOADcO = thr_tmem_load_o.partition_D(tOcO_i)
|
||||
tTMEM_STOREtO = thr_tmem_store_o.partition_D(tOtO_i)
|
||||
n_corr_tiles = self.pv_n_tile // corr_tile_size
|
||||
|
||||
for kt in range(self.n_kv_tiles):
|
||||
si_handle = s_cons.wait_and_advance()
|
||||
|
||||
tTMEM_LOADrS = cute.make_rmem_tensor(tTMEM_LOADcS.shape, self.qk_acc_dtype)
|
||||
cute.copy(tiled_tmem_load, tTMEM_LOADtS, tTMEM_LOADrS)
|
||||
cute.arch.fence_view_async_tmem_load()
|
||||
|
||||
old_row_max = row_max
|
||||
frg_cnt = 4
|
||||
frg_tile = cute.size(tTMEM_LOADrS) // frg_cnt
|
||||
tTMEM_LOADrS_frg = cute.logical_divide(tTMEM_LOADrS, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
row_max = cute.arch.fmax(row_max, tTMEM_LOADrS_frg[k, j] * scale_log2)
|
||||
|
||||
row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
row_max_safe = Float32(0.0)
|
||||
|
||||
acc_scale_ = old_row_max - row_max_safe
|
||||
acc_scale = cute.math.exp2(acc_scale_, fastmath=True)
|
||||
if old_row_max == -cutlass.Float32.inf:
|
||||
acc_scale = Float32(0.0)
|
||||
row_sum *= acc_scale
|
||||
|
||||
rP_words = cute.make_rmem_tensor(tTMEM_STOREcP.shape, self.qk_acc_dtype)
|
||||
rP_bf16 = cute.make_tensor(cute.recast_ptr(rP_words.iterator, dtype=self.q_dtype), tTMEM_LOADrS.layout)
|
||||
minus_row_max = Float32(0.0) - row_max_safe
|
||||
|
||||
rP_bf16_frg = cute.logical_divide(rP_bf16, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
tTMEM_LOADrS_frg[k, j] = tTMEM_LOADrS_frg[k, j] * scale_log2 + minus_row_max
|
||||
tTMEM_LOADrS_frg[k, j] = cute.math.exp2(tTMEM_LOADrS_frg[k, j], fastmath=True)
|
||||
row_sum = row_sum + tTMEM_LOADrS_frg[k, j]
|
||||
s_vec = tTMEM_LOADrS_frg[None, j].load()
|
||||
rP_bf16_frg[None, j].store(s_vec.to(self.q_dtype))
|
||||
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: store P to TMEM via register bridge
|
||||
cute.copy(tiled_tmem_store, rP_words, tTMEM_STOREtP)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
else:
|
||||
# SMEM-P: write P to sP using coordinate-indexed store.
|
||||
# Uses tTMEM_LOADcS identity tensor to get (m, k) coordinates.
|
||||
for j0 in range(32):
|
||||
for j1 in range(4):
|
||||
coord = tTMEM_LOADcS[(j0, 0), j1, 0, 0]
|
||||
m_coord = coord[0]
|
||||
k_coord = coord[1]
|
||||
k0 = k_coord % 16
|
||||
k1 = (k_coord // 16) % 4
|
||||
k2 = k_coord // 64
|
||||
_sP_nostage[(m_coord, k0), 0, (k1, k2)] = rP_bf16[(j0, 0), j1, 0, 0]
|
||||
cute.arch.fence_proxy("async.shared", space="cta")
|
||||
if kt > 0:
|
||||
tTMrO = cute.make_rmem_tensor(
|
||||
(tTMEM_LOADcO.shape, 128 // corr_tile_size), self.acc_dtype
|
||||
)
|
||||
for i in range(n_corr_tiles):
|
||||
tTMrO_i_ = tTMrO[None, i]
|
||||
tTMrO_i_layout = cute.composition(
|
||||
tTMrO_i_.layout, cute.make_layout(tTMrO.shape[0])
|
||||
)
|
||||
tTMrO_i = cute.make_tensor(tTMrO_i_.iterator, tTMrO_i_layout)
|
||||
tTMEM_LOADtO_i = cute.make_tensor(
|
||||
tTMEM_LOADtO.iterator + i * corr_tile_size,
|
||||
tTMEM_LOADtO.layout,
|
||||
)
|
||||
tTMEM_STOREtO_i = cute.make_tensor(
|
||||
tTMEM_STOREtO.iterator + i * corr_tile_size,
|
||||
tTMEM_STOREtO.layout,
|
||||
)
|
||||
cute.copy(tiled_tmem_load_o, tTMEM_LOADtO_i, tTMrO_i)
|
||||
for k in cutlass.range(cute.size(tTMrO_i), vectorize=True):
|
||||
tTMrO_i[k] = tTMrO_i[k] * acc_scale
|
||||
cute.copy(tiled_tmem_store_o, tTMrO_i, tTMEM_STOREtO_i)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
|
||||
si_handle.release()
|
||||
softmax_done_bar.arrive()
|
||||
|
||||
# Wait for MMA's PV[N-1] to commit before reading O.
|
||||
final_o_bar.arrive_and_wait()
|
||||
|
||||
# === NO-OP TMEM round-trip: re-map O from MMA layout to epilog layout ===
|
||||
tTMrO_noop = cute.make_rmem_tensor(
|
||||
(tTMEM_LOADcO.shape, 128 // corr_tile_size), self.acc_dtype
|
||||
)
|
||||
for i in range(n_corr_tiles):
|
||||
tTMrO_i_ = tTMrO_noop[None, i]
|
||||
tTMrO_i_layout = cute.composition(
|
||||
tTMrO_i_.layout, cute.make_layout(tTMrO_noop.shape[0])
|
||||
)
|
||||
tTMrO_i = cute.make_tensor(tTMrO_i_.iterator, tTMrO_i_layout)
|
||||
tTMEM_LOADtO_i = cute.make_tensor(
|
||||
tTMEM_LOADtO.iterator + i * corr_tile_size,
|
||||
tTMEM_LOADtO.layout,
|
||||
)
|
||||
tTMEM_STOREtO_i = cute.make_tensor(
|
||||
tTMEM_STOREtO.iterator + i * corr_tile_size,
|
||||
tTMEM_STOREtO.layout,
|
||||
)
|
||||
cute.copy(tiled_tmem_load_o, tTMEM_LOADtO_i, tTMrO_i)
|
||||
cute.copy(tiled_tmem_store_o, tTMrO_i, tTMEM_STOREtO_i)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
|
||||
# === Final O normalization: O *= 1/row_sum ===
|
||||
# D5a: When normalize=False, skip normalization (emit un-normalized O + lse)
|
||||
if const_expr(self.normalize):
|
||||
inv_row_sum = Float32(1.0) / row_sum
|
||||
|
||||
tTMrO = cute.make_rmem_tensor(
|
||||
(tTMEM_LOADcO.shape, 128 // corr_tile_size), self.acc_dtype
|
||||
)
|
||||
|
||||
for i in range(n_corr_tiles):
|
||||
tTMrO_i_ = tTMrO[None, i]
|
||||
tTMrO_i_layout = cute.composition(
|
||||
tTMrO_i_.layout, cute.make_layout(tTMrO.shape[0])
|
||||
)
|
||||
tTMrO_i = cute.make_tensor(tTMrO_i_.iterator, tTMrO_i_layout)
|
||||
tTMEM_LOADtO_i = cute.make_tensor(
|
||||
tTMEM_LOADtO.iterator + i * corr_tile_size, tTMEM_LOADtO.layout
|
||||
)
|
||||
tTMEM_STOREtO_i = cute.make_tensor(
|
||||
tTMEM_STOREtO.iterator + i * corr_tile_size, tTMEM_STOREtO.layout
|
||||
)
|
||||
|
||||
cute.copy(tiled_tmem_load_o, tTMEM_LOADtO_i, tTMrO_i)
|
||||
if const_expr(self.normalize):
|
||||
for j in cutlass.range(cute.size(tTMrO_i), vectorize=True):
|
||||
tTMrO_i[j] = tTMrO_i[j] * inv_row_sum
|
||||
cute.copy(tiled_tmem_store_o, tTMrO_i, tTMEM_STOREtO_i)
|
||||
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
|
||||
# Epilogue: TMEM → SMEM → GMEM via TMA store.
|
||||
tCtO_base = cute.make_tensor(tmem_ptr + self.tmem_o0_offset, tCtO_fake.layout)
|
||||
acc_cons_st = pipeline.make_pipeline_state(
|
||||
pipeline.PipelineUserType.Consumer, self.num_acc_stage
|
||||
)
|
||||
c_grp = pipeline.CooperativeGroup(pipeline.Agent.Thread, 32 * len(self.epilogue_warp_id))
|
||||
c_pipe = pipeline.PipelineTmaStore.create(num_stages=self.num_c_stage, producer_group=c_grp)
|
||||
acc_cons_st = utils.gemm.sm100.epilogue_tma_store(
|
||||
self, tidx, warp_idx, tma_c, tCtO_base, sC, tCgC, epi_tile,
|
||||
0, const_expr(lambda x: x), (0, 0, 0),
|
||||
acc_cons_st, acc_pipe, c_pipe,
|
||||
)
|
||||
c_pipe.producer_tail()
|
||||
|
||||
# D5a: Write LSE (log-softmax) when normalize=False
|
||||
# lse = ln(row_sum) + row_max * ln(2)
|
||||
# row_max is in scale_log2 domain, multiply by ln(2) to convert.
|
||||
if const_expr(not self.normalize):
|
||||
_row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
_row_max_safe = Float32(0.0)
|
||||
if sfw_idx == 0:
|
||||
_ln2 = Float32(0.6931471805599453) # ln(2)
|
||||
lse_val = cute.math.log(row_sum, fastmath=True) + _row_max_safe * _ln2
|
||||
mLSE[0] = lse_val
|
||||
|
||||
tmem.relinquish_alloc_permit()
|
||||
tmem.free(tmem_ptr)
|
||||
|
||||
|
||||
@@ -3,4 +3,596 @@ ARCHIVED: FMHA kernel backup v2.
|
||||
|
||||
Intermediate state during the SMEM accumulator development.
|
||||
Superseded by the current fmha.py. Kept for git-archaeology only.
|
||||
|
||||
FMHA kernel: QK -> online softmax -> PV (CuTeDSL, Blackwell SM100).
|
||||
|
||||
Migrated from tests/unit/test_fmha_v3_stage_c.py — Stage C proven path.
|
||||
P stored to TMEM via register bridge, PV reads from TMEM.
|
||||
O rescale via SMEM accumulator (one-way TMEM→REGS→SMEM per kt iteration).
|
||||
Normalization via final TMA store (SMEM→GMEM).
|
||||
D1.5: TMEM round-trip is FUNDAMENTALLY broken (Ld32x32bOp/St32x32bOp column
|
||||
mapping mismatch). SMEM accumulator avoids round-trip entirely.
|
||||
"""
|
||||
import torch, cutlass, cutlass.cute as cute, cutlass.utils as utils, cutlass.pipeline as pipeline
|
||||
from cutlass.cute.nvgpu import cpasync, tcgen05
|
||||
from cutlass import Float32, BFloat16, Int32, Boolean, const_expr
|
||||
from cutlass.utils import LayoutEnum
|
||||
from cutlass.utils.tmem_allocator import find_tmem_tensor_col_offset
|
||||
from cutlass.utils.blackwell_helpers import get_smem_store_op
|
||||
from cutlass.utils.gemm.sm100 import (
|
||||
transform_partitioned_tensor_layout,
|
||||
epilogue_tmem_copy_and_partition,
|
||||
epilogue_smem_copy_and_partition,
|
||||
)
|
||||
# D1.5: TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken.
|
||||
# Even CUTLASS correction_rescale pattern produces catastrophic corruption.
|
||||
# SMEM accumulator approach: one-way TMEM→REGS→SMEM per kt iteration.
|
||||
import cuda.bindings.driver as cuda
|
||||
import cutlass.torch as ct
|
||||
import math
|
||||
|
||||
|
||||
class FmhaKernel:
|
||||
def __init__(self, head_dim=64, s_k=128, scale_softmax=None, use_smem_p=None, normalize=True, num_query_heads=1, batch_size=1, apply_swa_mask=False, is_causal=False, n_comp=None, apply_sink_bias=False):
|
||||
# D5c: n_comp = compressed KV length. Sink bias (attn_sink) applies to
|
||||
# positions >= n_comp. D3/D4 masks also only apply to SWA region.
|
||||
# When n_comp is None or 0, no offset (backward compatible).
|
||||
self.n_comp = n_comp if n_comp is not None else 0
|
||||
# apply_sink_bias: whether to add attn_sink logit bias to SWA positions.
|
||||
# Independent of n_comp — needed for all-SWA segments (n_comp=0) that still need sink bias.
|
||||
# When True, adds sink_bias to positions >= n_comp (which is 0 → all positions).
|
||||
self.apply_sink_bias = apply_sink_bias
|
||||
self.head_dim = head_dim
|
||||
self.s_k = s_k
|
||||
self.n_kv_tiles = s_k // 128
|
||||
self.pv_n_tile = min(head_dim, 256)
|
||||
# At hd=512, pv_n_tile=256 would need sV=64KB + sC=64KB = 128KB,
|
||||
# making total SMEM 256KB > 232KB limit. Use pv_n_tile=128 for hd=512
|
||||
# (4 PV GEMM passes instead of 2). TODO: overlap sQ/sV to enable pv_n_tile=256.
|
||||
if head_dim > 256:
|
||||
self.pv_n_tile = 128
|
||||
self.n_pv_tiles = head_dim // self.pv_n_tile
|
||||
self.use_smem_p = use_smem_p if use_smem_p is not None else (head_dim > 64)
|
||||
self.num_query_heads = num_query_heads
|
||||
self.batch_size = batch_size
|
||||
self.normalize = normalize # D5a: False = emit un-normalized O + lse
|
||||
self.apply_swa_mask = apply_swa_mask # D3: mask logits at positions >= swa_lens
|
||||
self.is_causal = is_causal # D4: causal mask (k_coord > m_coord) on SWA branch
|
||||
self.acc_dtype = Float32; self.qk_acc_dtype = Float32
|
||||
self.q_dtype = BFloat16; self.o_dtype = BFloat16; self.c_dtype = BFloat16
|
||||
self.use_2cta_instrs = False; self.epilog_sync_bar_id = 1
|
||||
self.cluster_shape_mn = (1, 1); self.cta_group = tcgen05.CtaGroup.ONE
|
||||
self.epilogue_warp_id = (0,1,2,3); self.mma_warp_id = 4; self.tma_warp_id = 5
|
||||
self.threads_per_cta = 192
|
||||
# K-dim sub-tiling: cap at 256 to keep sQ and sK within SMEM budget
|
||||
self.k_tile = min(head_dim, 256)
|
||||
self.n_k_sub_tiles = head_dim // self.k_tile
|
||||
self.kv_stage = 1 if head_dim > 128 else 2 # Reduce SMEM at large hd
|
||||
self.q_stage = 1
|
||||
self.num_c_stage = 1 if head_dim > 256 else 2 # Reduce SMEM at hd=512
|
||||
self.scale_softmax = scale_softmax if scale_softmax is not None else 1.0 / math.sqrt(self.head_dim)
|
||||
self.scale_softmax_log2 = self.scale_softmax * math.log2(math.e)
|
||||
|
||||
def _setup(self, qk_mma, pv_mma):
|
||||
qk_ik = cute.size(qk_mma.shape_mnk, mode=[2])
|
||||
# QK GEMM K-dim = head_dim. Each MMA sub-tile covers qk_ik*4 elements.
|
||||
# The tiler K must be head_dim so the QK loop iterates over all K sub-tiles.
|
||||
self.qk_mma_tiler = (128, 128, self.k_tile)
|
||||
pv_ik = cute.size(pv_mma.shape_mnk, mode=[2])
|
||||
self.pv_mma_tiler = (128, self.pv_n_tile, pv_ik * (128 // pv_ik))
|
||||
self.mma_tiler = self.qk_mma_tiler
|
||||
self.cluster_layout_vmnk = cute.tiled_divide(cute.make_layout((1,1,1)), (qk_mma.thr_id.shape,))
|
||||
self.cta_tile_shape_mnk = (self.qk_mma_tiler[0]//cute.size(qk_mma.thr_id.shape), self.pv_n_tile, self.qk_mma_tiler[2])
|
||||
self.c_layout = LayoutEnum.ROW_MAJOR
|
||||
self.epi_tile = utils.sm100.compute_epilogue_tile_shape(self.cta_tile_shape_mnk, False, self.c_layout, self.o_dtype)
|
||||
self.num_ab_stage = 1; self.num_acc_stage = 1
|
||||
self.q_smem_s = utils.sm100.make_smem_layout_a(qk_mma, self.qk_mma_tiler, self.q_dtype, self.q_stage)
|
||||
self.k_smem_s = utils.sm100.make_smem_layout_b(qk_mma, self.qk_mma_tiler, self.q_dtype, self.kv_stage)
|
||||
self.v_smem_s = utils.sm100.make_smem_layout_b(pv_mma, self.pv_mma_tiler, self.q_dtype, self.kv_stage)
|
||||
self.c_smem_s = utils.sm100.make_smem_layout_epi(self.o_dtype, self.c_layout, self.epi_tile, 2)
|
||||
self.p_tmem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
|
||||
# P SMEM layout (PV A-operand) — used for SMEM-P path
|
||||
self.p_smem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
|
||||
qk_thr = qk_mma.get_slice(0); qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
|
||||
tStS = qk_thr.make_fragment_C(qk_as)
|
||||
pv_thr = pv_mma.get_slice(0); pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
|
||||
tOtO = pv_thr.make_fragment_C(pv_as)
|
||||
self.tmem_s0_offset = 0
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: S at 0, P at 32, O after P and S
|
||||
self.tmem_p0_offset = 32
|
||||
p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
|
||||
p_end = self.tmem_p0_offset + p_cols_fp32
|
||||
s_cols = self.qk_mma_tiler[1]
|
||||
o_after = max(s_cols, p_end)
|
||||
self.tmem_o0_offset = ((o_after + 31) // 32) * 32
|
||||
o_cols = find_tmem_tensor_col_offset(tOtO)
|
||||
total = self.tmem_o0_offset + o_cols
|
||||
else:
|
||||
# SMEM-P: P not in TMEM. S and O share TMEM (sequential).
|
||||
self.tmem_p0_offset = -1 # unused
|
||||
self.tmem_o0_offset = 0
|
||||
s_cols = self.qk_mma_tiler[1]
|
||||
o_cols = find_tmem_tensor_col_offset(tOtO)
|
||||
total = max(s_cols, o_cols)
|
||||
self.num_tmem_alloc_cols = 1
|
||||
while self.num_tmem_alloc_cols < total:
|
||||
self.num_tmem_alloc_cols *= 2
|
||||
# tOrP0 offset: BF16 elements from TMEM base to P0 (TMEM-P only)
|
||||
# = tmem_p0_offset * (FP32_width / BF16_width) if TMEM-P, else 0
|
||||
self.tOrP0_offset = max(self.tmem_p0_offset, 0) * 2 # Python int
|
||||
cta = cute.size(qk_mma.thr_id.shape)
|
||||
q_s = cute.slice_(self.q_smem_s,(None,None,None,0))
|
||||
k_s = cute.slice_(self.k_smem_s,(None,None,None,0))
|
||||
v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
|
||||
self.q_tx_bytes = cute.size_in_bytes(self.q_dtype, q_s) * cta
|
||||
self.kv_tx_bytes = (cute.size_in_bytes(self.q_dtype, k_s) +
|
||||
cute.size_in_bytes(self.q_dtype, v_s)) * cta
|
||||
|
||||
@cute.jit
|
||||
def __call__(self, q, k, v, c, stream, lse=None, swa_len=None, sink_bias=None, row_sums=None):
|
||||
self.q_dtype = q.element_type; self.o_dtype = c.element_type; self.c_dtype = self.o_dtype
|
||||
self.a_major = LayoutEnum.from_tensor(q).mma_major_mode()
|
||||
self.b_major = LayoutEnum.from_tensor(k).mma_major_mode()
|
||||
v_fmha = cute.make_tensor(
|
||||
v.iterator,
|
||||
cute.make_layout(
|
||||
(self.pv_n_tile, self.s_k, 1),
|
||||
stride=(1, self.pv_n_tile, self.pv_n_tile * self.s_k),
|
||||
),
|
||||
)
|
||||
self.v_major = LayoutEnum.from_tensor(v_fmha).mma_major_mode()
|
||||
self.c_layout = LayoutEnum.from_tensor(c)
|
||||
qk_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, self.a_major, self.b_major, self.qk_acc_dtype, self.cta_group, (128,128), tcgen05.OperandSource.SMEM)
|
||||
pv_a_major = self.a_major if self.use_smem_p else cute.nvgpu.OperandMajorMode.K
|
||||
pv_source = tcgen05.OperandSource.SMEM if self.use_smem_p else tcgen05.OperandSource.TMEM
|
||||
pv_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, pv_a_major, self.v_major, self.qk_acc_dtype, self.cta_group, (128,self.pv_n_tile), pv_source)
|
||||
self._setup(qk_mma, pv_mma)
|
||||
q_s = cute.slice_(self.q_smem_s,(None,None,None,0)); k_s = cute.slice_(self.k_smem_s,(None,None,None,0)); v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
|
||||
tma_q,mQ = cute.nvgpu.make_tiled_tma_atom_A(utils.sm100.cluster_shape_to_tma_atom_A(self.cluster_shape_mn,qk_mma.thr_id),q,q_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
|
||||
tma_k,mK = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,qk_mma.thr_id),k,k_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
|
||||
tma_v,mV = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,pv_mma.thr_id),v_fmha,v_s,self.pv_mma_tiler,pv_mma,self.cluster_layout_vmnk.shape)
|
||||
epi_s = cute.select(self.c_smem_s,mode=[0,1])
|
||||
tma_c,mC = cpasync.make_tiled_tma_atom(cpasync.CopyBulkTensorTileS2GOp(),c,epi_s,self.epi_tile)
|
||||
# Always create a valid mLSE tensor for the kernel.
|
||||
# CuTeDSL doesn't support None parameters in @cute.kernel.
|
||||
if const_expr(lse is None):
|
||||
lse = cute.make_tensor(c.iterator, cute.make_layout((1,), stride=(0,)))
|
||||
if const_expr(swa_len is None):
|
||||
# No SWA masking — pass max int (no positions masked)
|
||||
swa_len = Int32(2147483647)
|
||||
else:
|
||||
swa_len = Int32(swa_len)
|
||||
# D5c: sink_bias is a per-head FP32 logit bias applied to SWA positions.
|
||||
# When None, pass 0.0 (no bias). The kernel reads sink_bias[0] for the
|
||||
# current head (n_h=1 in per-head launch mode).
|
||||
if const_expr(sink_bias is None):
|
||||
# D5c: sink_bias not provided. Create a dummy tensor pointing to valid memory.
|
||||
# Never actually read (const_expr(self.n_comp > 0) guards the read).
|
||||
sink_bias = cute.make_tensor(lse.iterator, cute.make_layout((1,), stride=(0,)))
|
||||
# else: sink_bias is already a CuTe tensor (caller must pass via ct.from_dlpack)
|
||||
# Grid: (M_tiles, 1, batch) where M = n_h * T packed into M dimension
|
||||
# For single-head (n_h=1): grid=(1,1,1) — backward compatible
|
||||
if const_expr(row_sums is None):
|
||||
row_sums = cute.make_tensor(lse.iterator, lse.layout)
|
||||
|
||||
self._kernel(qk_mma,pv_mma,tma_q,mQ,tma_k,mK,tma_v,mV,tma_c,mC,self.cluster_layout_vmnk,self.q_smem_s,self.k_smem_s,self.v_smem_s,self.p_tmem_s,self.p_smem_s,self.c_smem_s,self.epi_tile,lse,swa_len,sink_bias,row_sums).launch(grid=(1,1,self.batch_size),block=[self.threads_per_cta,1,1],stream=stream)
|
||||
|
||||
@cute.kernel
|
||||
def _kernel(self, qk_mma, pv_mma, tma_q, mQ, tma_k, mK, tma_v, mV, tma_c, mC, cl_vmnk, q_smem_s, k_smem_s, v_smem_s, p_tmem_s, p_smem_s, c_smem_s, epi_tile, mLSE, swa_len, mSinkBias, mRowSums):
|
||||
warp_idx = cute.arch.make_warp_uniform(cute.arch.warp_idx())
|
||||
tidx,_,_ = cute.arch.thread_idx()
|
||||
if warp_idx == self.tma_warp_id:
|
||||
cpasync.prefetch_descriptor(tma_q); cpasync.prefetch_descriptor(tma_k); cpasync.prefetch_descriptor(tma_v); cpasync.prefetch_descriptor(tma_c)
|
||||
|
||||
@cute.struct
|
||||
class SS:
|
||||
q_bar: cute.struct.MemRange[cutlass.Int64, self.q_stage*2]
|
||||
kv_bar: cute.struct.MemRange[cutlass.Int64, self.kv_stage*2]
|
||||
s_bar: cute.struct.MemRange[cutlass.Int64, 2]
|
||||
acc_bar: cute.struct.MemRange[cutlass.Int64, self.num_acc_stage*2]
|
||||
tmem_dealloc: cutlass.Int64; holding: cutlass.Int32
|
||||
smem = utils.SmemAllocator(); st = smem.allocate(SS)
|
||||
|
||||
qp,qc = pipeline.PipelineTmaUmma.create(barrier_storage=st.q_bar.data_ptr(),num_stages=self.q_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.q_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
|
||||
kvp,kvc = pipeline.PipelineTmaUmma.create(barrier_storage=st.kv_bar.data_ptr(),num_stages=self.kv_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.kv_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
|
||||
s_prod,s_cons = pipeline.PipelineUmmaAsync.create(barrier_storage=st.s_bar.data_ptr(),num_stages=1,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,32*len(self.epilogue_warp_id))).make_participants()
|
||||
softmax_done_bar = pipeline.NamedBarrier(barrier_id=3, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
final_o_bar = pipeline.NamedBarrier(barrier_id=4, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
# D1.5: pv_done_bar for SMEM accumulator approach.
|
||||
# MMA warp arrives after PV[kt] completes; softmax/epilogue warps wait
|
||||
# before moving O from TMEM to SMEM.
|
||||
pv_done_bar = pipeline.NamedBarrier(barrier_id=5, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
acc_pipe = pipeline.PipelineUmmaAsync.create(barrier_storage=st.acc_bar.data_ptr(),num_stages=self.num_acc_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,len(self.epilogue_warp_id)),cta_layout_vmnk=cl_vmnk,defer_sync=True)
|
||||
tmem_bar = pipeline.NamedBarrier(barrier_id=2,num_threads=32*len((self.mma_warp_id,*self.epilogue_warp_id)))
|
||||
tmem = utils.TmemAllocator(st.holding.ptr,barrier_for_retrieve=tmem_bar,allocator_warp_id=self.epilogue_warp_id[0],is_two_cta=cute.size(qk_mma.thr_id.shape)==2,two_cta_tmem_dealloc_mbar_ptr=st.tmem_dealloc.ptr)
|
||||
pipeline.pipeline_init_arrive(cluster_shape_mn=cl_vmnk,is_relaxed=True)
|
||||
|
||||
sQ = smem.allocate_tensor(element_type=self.q_dtype,layout=q_smem_s.outer,byte_alignment=128,swizzle=q_smem_s.inner)
|
||||
sK = smem.allocate_tensor(element_type=self.q_dtype,layout=k_smem_s.outer,byte_alignment=128,swizzle=k_smem_s.inner)
|
||||
# sV: independent allocation. At hd=512, pv_n_tile=128 keeps sV at 32KB.
|
||||
# TODO: overlap sQ/sV with pv_n_tile=256 for better math throughput.
|
||||
sV = smem.allocate_tensor(element_type=self.q_dtype,layout=v_smem_s.outer,byte_alignment=128,swizzle=v_smem_s.inner)
|
||||
sC = smem.allocate_tensor(element_type=self.o_dtype,layout=c_smem_s.outer,byte_alignment=128,swizzle=c_smem_s.inner)
|
||||
# sP layout: full layout for SMEM-P, tiny placeholder for TMEM-P (saves SMEM)
|
||||
if const_expr(self.use_smem_p):
|
||||
_p_layout = p_smem_s.outer
|
||||
_p_swizzle = p_smem_s.inner
|
||||
else:
|
||||
_p_layout = cute.make_layout(((1,1),1,(1,1),1))
|
||||
_p_swizzle = cute.make_layout(((1,1),1,(1,1),1))
|
||||
sP = smem.allocate_tensor(element_type=self.q_dtype,layout=_p_layout,byte_alignment=128,swizzle=_p_swizzle)
|
||||
|
||||
gQ = cute.local_tile(mQ,cute.slice_(self.qk_mma_tiler,(None,0,None)),(None,None,None))
|
||||
gK = cute.local_tile(mK,cute.slice_(self.qk_mma_tiler,(0,None,None)),(None,None,None))
|
||||
gV = cute.local_tile(mV,cute.slice_(self.pv_mma_tiler,(0,None,None)),(None,None,None))
|
||||
gC = cute.local_tile(mC,cute.slice_(self.pv_mma_tiler,(None,None,0)),(None,None,None))
|
||||
n_kv_tiles = cute.size(gK, mode=[3])
|
||||
|
||||
qk_thr = qk_mma.get_slice(0); pv_thr = pv_mma.get_slice(0)
|
||||
tCgQ = qk_thr.partition_A(gQ); tCgK = qk_thr.partition_B(gK)
|
||||
tCgV = pv_thr.partition_B(gV); tCgC = pv_thr.partition_C(gC)
|
||||
a_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,0,None,0)).shape)
|
||||
tAsQ,tAgQ = cpasync.tma_partition(tma_q,0,a_lay,cute.group_modes(sQ,0,3),cute.group_modes(tCgQ,0,3))
|
||||
b_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,None,0,0)).shape)
|
||||
tBsK,tBgK = cpasync.tma_partition(tma_k,0,b_lay,cute.group_modes(sK,0,3),cute.group_modes(tCgK,0,3))
|
||||
tVsV,tVgV = cpasync.tma_partition(tma_v,0,b_lay,cute.group_modes(sV,0,3),cute.group_modes(tCgV,0,3))
|
||||
tAgQ = tAgQ[(None,0,None,0)]; tBgK = tBgK[(None,0,None,0)]; tVgV = tVgV[(None,0,None,0)]
|
||||
|
||||
tCrQ = qk_mma.make_fragment_A(sQ); tCrK = qk_mma.make_fragment_B(sK)
|
||||
tCrV = pv_mma.make_fragment_B(sV)
|
||||
|
||||
qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
|
||||
tStS = qk_thr.make_fragment_C(qk_as)
|
||||
tStS0 = cute.make_tensor(tStS.iterator + self.tmem_s0_offset, tStS.layout)
|
||||
pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
|
||||
tOtO = pv_thr.make_fragment_C(pv_as)
|
||||
tOtO0 = cute.make_tensor(tOtO.iterator + self.tmem_o0_offset, tOtO.layout)
|
||||
|
||||
# PV A-operand: define both tOrP0 (TMEM-P) and tCrP (SMEM-P) unconditionally.
|
||||
# CuTeDSL scoping: variables must be assigned unconditionally (no if/else).
|
||||
tP = cute.make_tensor(tStS.iterator, p_tmem_s.outer)
|
||||
tOrP_base = pv_thr.make_fragment_A(tP if not self.use_smem_p else sP)
|
||||
tOrP = tOrP_base[(None,None,None,0)]
|
||||
# tCrP is only used in SMEM-P path. Define unconditionally for CuTeDSL scoping.
|
||||
tCrP = pv_mma.make_fragment_A(sP) if self.use_smem_p else pv_mma.make_fragment_A(tP)
|
||||
# tOrP0: PV A-operand with TMEM column offset for P0 (TMEM-P path).
|
||||
# self.tOrP0_offset is pre-computed in _setup as a Python int.
|
||||
# Use const_expr if/else for compile-time conditional.
|
||||
if const_expr(self.tOrP0_offset > 0):
|
||||
tOrP0 = cute.make_tensor(tOrP.iterator + self.tOrP0_offset, tOrP.layout)
|
||||
else:
|
||||
tOrP0 = tOrP
|
||||
|
||||
tCtO_fake = pv_mma.make_fragment_C(cute.append(pv_as, self.num_acc_stage))
|
||||
pipeline.pipeline_init_wait(cluster_shape_mn=cl_vmnk)
|
||||
|
||||
# ===== TMA LOAD warp =====
|
||||
if warp_idx == self.tma_warp_id:
|
||||
if const_expr(self.n_k_sub_tiles > 1):
|
||||
# K sub-tiling path (hd>256): use cutlass.range loop to avoid IR explosion
|
||||
# from Python range unrolling. The MLIR optimizer handles runtime loops
|
||||
# much better than unrolled copies of pipeline+GEMM code.
|
||||
qp.reset()
|
||||
kvp.reset()
|
||||
for k_sub in cutlass.range(0, self.n_k_sub_tiles, 1, unroll=1):
|
||||
qh = qp.acquire_and_advance()
|
||||
cute.copy(tma_q, tAgQ[(None, k_sub)], tAsQ[(None, qh.index)], tma_bar_ptr=qh.barrier)
|
||||
kvh = kvp.acquire_and_advance()
|
||||
cute.copy(tma_k, tBgK[(None, k_sub)], tBsK[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
# Load V[0]
|
||||
kvh_v = kvp.acquire_and_advance()
|
||||
cute.copy(tma_v, tVgV[(None, Int32(0))], tVsV[(None, kvh_v.index)], tma_bar_ptr=kvh_v.barrier)
|
||||
qp.tail()
|
||||
kvp.tail()
|
||||
else:
|
||||
# Original pipeline path (hd≤256)
|
||||
qp.reset(); qh = qp.acquire_and_advance()
|
||||
cute.copy(tma_q, tAgQ[(None, Int32(0))], tAsQ[(None, qh.index)], tma_bar_ptr=qh.barrier)
|
||||
qp.tail()
|
||||
kvp.reset(); pk = kvp.try_acquire()
|
||||
for kt in cutlass.range(0, self.n_kv_tiles, 1, unroll=1):
|
||||
kvh = kvp.acquire_and_advance(pk)
|
||||
cute.copy(tma_k, tBgK[(None, kt)], tBsK[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
cute.copy(tma_v, tVgV[(None, kt)], tVsV[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
pk = cutlass.Boolean(1)
|
||||
kvp.tail()
|
||||
|
||||
# ===== MMA warp =====
|
||||
if warp_idx == self.mma_warp_id:
|
||||
tmem.wait_for_alloc()
|
||||
if const_expr(self.n_k_sub_tiles > 1):
|
||||
# K sub-tiling path (hd>256): cutlass.range loop (runtime, not unrolled)
|
||||
qc.reset()
|
||||
kvc.reset()
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
for k_sub in cutlass.range(0, self.n_k_sub_tiles, 1, unroll=1):
|
||||
qh = qc.wait_and_advance(); qh.release()
|
||||
kvh = kvc.wait_and_advance()
|
||||
for kb in cutlass.range(cute.size(tCrQ, mode=[2]), unroll_full=True):
|
||||
cute.gemm(qk_mma, tStS0, tCrQ[(None,None,kb,0)], tCrK[(None,None,kb,kvh.index)], tStS0)
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
kvh.release()
|
||||
# After all k_sub: S has full QK for this kt
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
softmax_done_bar.arrive()
|
||||
softmax_done_bar.arrive_and_wait()
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
# Load V: consume from K/V pipeline
|
||||
kvh_v = kvc.wait_and_advance()
|
||||
if not self.use_smem_p:
|
||||
for kb in cutlass.range(cute.size(tOrP0, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tOrP0[(None,None,kb)], tCrV[(None,None,kb,kvh_v.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
else:
|
||||
for kb in cutlass.range(cute.size(tCrP, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tCrP[(None,None,kb,0)], tCrV[(None,None,kb,kvh_v.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
kvh_v.release()
|
||||
pv_done_bar.arrive() # D1.5: Signal epilogue warps O_kt ready in TMEM
|
||||
final_o_bar.arrive()
|
||||
else:
|
||||
# Original pipeline path (hd≤256)
|
||||
qc.reset(); qh = qc.wait_and_advance(); qh.release()
|
||||
kvc.reset(); pk = kvc.try_wait()
|
||||
acc_st = pipeline.make_pipeline_state(pipeline.PipelineUserType.Producer, self.num_acc_stage)
|
||||
acc_pipe.producer_acquire(acc_st)
|
||||
for kt in range(self.n_kv_tiles):
|
||||
kvh = kvc.wait_and_advance(pk); pk = cutlass.Boolean(1)
|
||||
sh = s_prod.acquire_and_advance()
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
for kb in cutlass.range(cute.size(tCrQ, mode=[2]), unroll_full=True):
|
||||
cute.gemm(qk_mma, tStS0, tCrQ[(None,None,kb,0)], tCrK[(None,None,kb,kvh.index)], tStS0)
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
sh.commit()
|
||||
softmax_done_bar.arrive_and_wait()
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, kt != 0)
|
||||
if not self.use_smem_p:
|
||||
for kb in cutlass.range(cute.size(tOrP0, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tOrP0[(None,None,kb)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
else:
|
||||
for kb in cutlass.range(cute.size(tCrP, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tCrP[(None,None,kb,0)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
kvh.release()
|
||||
pv_done_bar.arrive() # D1.5: Signal epilogue warps O_kt ready in TMEM
|
||||
acc_pipe.producer_commit(acc_st); acc_st.advance()
|
||||
final_o_bar.arrive()
|
||||
acc_pipe.producer_tail(acc_st)
|
||||
|
||||
# ===== SOFTMAX + CORRECTION EPILOGUE warps =====
|
||||
if warp_idx < self.mma_warp_id:
|
||||
tmem.allocate(self.num_tmem_alloc_cols)
|
||||
tmem.wait_for_alloc()
|
||||
tmem_ptr = tmem.retrieve_ptr(self.qk_acc_dtype)
|
||||
sfw_idx = tidx % (32 * len(self.epilogue_warp_id))
|
||||
|
||||
# S load atoms
|
||||
tmem_load_atom = cute.make_copy_atom(tcgen05.copy.Ld32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_load = tcgen05.make_tmem_copy(tmem_load_atom, tStS0)
|
||||
thr_load = tiled_tmem_load.get_slice(sfw_idx)
|
||||
tTMEM_LOADtS = thr_load.partition_S(tStS0)
|
||||
cS = cute.make_identity_tensor((self.qk_mma_tiler[0], self.qk_mma_tiler[1]))
|
||||
tScS = qk_thr.partition_C(cS)
|
||||
tTMEM_LOADcS = thr_load.partition_D(tScS)
|
||||
|
||||
# P store atoms: TMEM-P (always defined, only used when use_smem_p=False)
|
||||
p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
|
||||
tStP_layout = cute.composition(tStS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
# Use 0 as P offset when SMEM-P (these atoms are never used, but must be valid)
|
||||
tStP0 = cute.make_tensor(tStS.iterator + max(self.tmem_p0_offset, 0), tStP_layout)
|
||||
tmem_store_atom = cute.make_copy_atom(tcgen05.copy.St32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_store = tcgen05.make_tmem_copy(tmem_store_atom, tStP0)
|
||||
thr_store = tiled_tmem_store.get_slice(sfw_idx)
|
||||
tTMEM_STOREtP = thr_store.partition_D(tStP0)
|
||||
tScP_layout = cute.composition(tScS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
tScP = cute.make_tensor(tScS.iterator, tScP_layout)
|
||||
tTMEM_STOREcP = thr_store.partition_S(tScP)
|
||||
|
||||
# P SMEM copy atoms: SMEM-P
|
||||
# Strategy: Use make_cotiled_copy with atom_layout_tv built from
|
||||
# the TMEM-load coordinate partition + sP address mapping.
|
||||
#
|
||||
# The TMEM-load partition gives each thread (m, k) coordinates via tTMEM_LOADcS.
|
||||
# We compose these coordinates with sP's logical address layout to get
|
||||
# (tid, vid) -> sP_addr. Then make_cotiled_copy creates a proper TiledCopy.
|
||||
#
|
||||
# Key: sP's outer layout maps (m, k0, k1, k2) -> sP_addr with strides (64, 1, 16, 8192).
|
||||
# We need to build atom_layout_tv in sP's flat address space, not tStS's.
|
||||
#
|
||||
# Step 1: Build sP address mapping in the same coordinate system as tStS.
|
||||
# sP is indexed as ((m, k%16), 0, ((k//16)%4, k//64)) with strides ((64,1),0,(16,8192)).
|
||||
# In the P matrix's (m, k) coordinate space:
|
||||
# sP_addr = 64*m + (k%16) + 16*((k//16)%4) + 8192*(k//64)
|
||||
# This is representable as a CuTe layout: (128, (16, 4, 2)) -> (64, (1, 16, 8192))
|
||||
_sP_nostage = sP[(None, None, None, 0)] # remove stage dim
|
||||
|
||||
row_max = -Float32.inf
|
||||
row_sum = Float32(0.0)
|
||||
scale_log2 = Float32(self.scale_softmax_log2)
|
||||
|
||||
# ============================================================
|
||||
# D1.5: O RESCALE — SMEM ACCUMULATOR APPROACH
|
||||
# =================================================
|
||||
# TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken:
|
||||
# even NO-OP round-trip corrupts data (ratio = -11 billion).
|
||||
# Instead, we use one-way TMEM→REGS→SMEM after each PV,
|
||||
# accumulate in SMEM with acc_scale multiplication, and
|
||||
# TMA store SMEM→GMEM after all kt iterations.
|
||||
#
|
||||
# For n_kv_tiles=1 (s_k=128), the existing epilogue_tma_store
|
||||
# path works perfectly (cos=0.999998). The SMEM accumulator
|
||||
# is only needed for n_kv_tiles > 1.
|
||||
# ============================================================
|
||||
|
||||
# NOTE: The code below is the BROKEN TMEM round-trip approach.
|
||||
# It's kept as reference but should NOT be used.
|
||||
# The SMEM accumulator implementation is TODO.
|
||||
|
||||
# prev_acc_scale: unused, kept for clarity. acc_scale at kt is used
|
||||
# to rescale O from kt=0..kt-1 before PV[kt].
|
||||
prev_acc_scale = Float32(0.0)
|
||||
|
||||
for kt in range(self.n_kv_tiles):
|
||||
si_handle = s_cons.wait_and_advance()
|
||||
|
||||
tTMEM_LOADrS = cute.make_rmem_tensor(tTMEM_LOADcS.shape, self.qk_acc_dtype)
|
||||
cute.copy(tiled_tmem_load, tTMEM_LOADtS, tTMEM_LOADrS)
|
||||
cute.arch.fence_view_async_tmem_load()
|
||||
|
||||
# D3/D4/D5c: In-kernel logit modification.
|
||||
# After loading S from TMEM, modify logits for SWA positions:
|
||||
# D5c: Add sink_bias (attn_sink) to positions >= n_comp
|
||||
# D3: Mask positions >= n_comp + swa_len to -inf
|
||||
# D4: Causal mask — SWA positions where k_coord > m_coord → -inf
|
||||
# Uses tTMEM_LOADcS coordinate tensor to map register indices to (row, col).
|
||||
# For kt > 0, absolute KV pos = kt*128 + k_coord.
|
||||
if const_expr(self.apply_swa_mask or self.is_causal or self.apply_sink_bias):
|
||||
kt_offset = Int32(kt * 128) # KV position offset for this tile
|
||||
# D5c: Read sink bias once (same for all positions in this head).
|
||||
# Define unconditionally for CuTeDSL scoping (used when apply_sink_bias).
|
||||
# The bias must be added in the SCALED-LOG2 domain: attn_sink * log2(e).
|
||||
# But we add to the RAW logits before the scale_log2 multiply.
|
||||
# Raw correction: attn_sink / scale → after * scale_log2 → attn_sink * log2(e)
|
||||
sink_val = Float32(0.0)
|
||||
if const_expr(self.apply_sink_bias):
|
||||
sink_val = mSinkBias[Int32(0)] / Float32(self.scale_softmax)
|
||||
for j0 in range(32):
|
||||
for j1 in range(4):
|
||||
coord = tTMEM_LOADcS[(j0, 0), j1, 0, 0]
|
||||
m_coord = coord[0] # query row position
|
||||
k_coord = coord[1] # position within this KV tile
|
||||
kv_pos = kt_offset + k_coord # absolute KV position
|
||||
# D5c: Add sink bias to SWA positions (>= n_comp)
|
||||
if const_expr(self.apply_sink_bias):
|
||||
if kv_pos >= Int32(self.n_comp):
|
||||
tTMEM_LOADrS[(j0, 0), j1, 0, 0] = tTMEM_LOADrS[(j0, 0), j1, 0, 0] + sink_val
|
||||
# D3: SWA length mask
|
||||
should_mask = Boolean(0)
|
||||
if const_expr(self.apply_swa_mask):
|
||||
# SWA length applies relative to the SWA region start (n_comp)
|
||||
# kv_pos >= n_comp + swa_len means the SWA position >= swa_len
|
||||
if kv_pos >= Int32(self.n_comp) + swa_len:
|
||||
should_mask = Boolean(1)
|
||||
# D4: Causal mask (only on SWA positions)
|
||||
# Compare SWA-relative position (kv_pos - n_comp) with query position
|
||||
if const_expr(self.is_causal):
|
||||
if kv_pos >= Int32(self.n_comp):
|
||||
swa_pos = kv_pos - Int32(self.n_comp)
|
||||
if swa_pos > m_coord:
|
||||
should_mask = Boolean(1)
|
||||
if should_mask:
|
||||
tTMEM_LOADrS[(j0, 0), j1, 0, 0] = -Float32.inf
|
||||
|
||||
old_row_max = row_max
|
||||
frg_cnt = 4
|
||||
frg_tile = cute.size(tTMEM_LOADrS) // frg_cnt
|
||||
tTMEM_LOADrS_frg = cute.logical_divide(tTMEM_LOADrS, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
row_max = cute.arch.fmax(row_max, tTMEM_LOADrS_frg[k, j] * scale_log2)
|
||||
|
||||
row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
row_max_safe = Float32(0.0)
|
||||
|
||||
acc_scale_ = old_row_max - row_max_safe
|
||||
acc_scale = cute.math.exp2(acc_scale_, fastmath=True)
|
||||
if old_row_max == -cutlass.Float32.inf:
|
||||
acc_scale = Float32(0.0)
|
||||
row_sum *= acc_scale
|
||||
|
||||
rP_words = cute.make_rmem_tensor(tTMEM_STOREcP.shape, self.qk_acc_dtype)
|
||||
rP_bf16 = cute.make_tensor(cute.recast_ptr(rP_words.iterator, dtype=self.q_dtype), tTMEM_LOADrS.layout)
|
||||
minus_row_max = Float32(0.0) - row_max_safe
|
||||
|
||||
rP_bf16_frg = cute.logical_divide(rP_bf16, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
tTMEM_LOADrS_frg[k, j] = tTMEM_LOADrS_frg[k, j] * scale_log2 + minus_row_max
|
||||
tTMEM_LOADrS_frg[k, j] = cute.math.exp2(tTMEM_LOADrS_frg[k, j], fastmath=True)
|
||||
row_sum = row_sum + tTMEM_LOADrS_frg[k, j]
|
||||
s_vec = tTMEM_LOADrS_frg[None, j].load()
|
||||
rP_bf16_frg[None, j].store(s_vec.to(self.q_dtype))
|
||||
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: store P to TMEM via register bridge
|
||||
cute.copy(tiled_tmem_store, rP_words, tTMEM_STOREtP)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
else:
|
||||
# SMEM-P: write P to sP using coordinate-indexed store.
|
||||
for j0 in range(32):
|
||||
for j1 in range(4):
|
||||
coord = tTMEM_LOADcS[(j0, 0), j1, 0, 0]
|
||||
m_coord = coord[0]
|
||||
k_coord = coord[1]
|
||||
k0 = k_coord % 16
|
||||
k1 = (k_coord // 16) % 4
|
||||
k2 = k_coord // 64
|
||||
_sP_nostage[(m_coord, k0), 0, (k1, k2)] = rP_bf16[(j0, 0), j1, 0, 0]
|
||||
cute.arch.fence_proxy("async.shared", space="cta")
|
||||
# D1.5: O rescale for kt > 0 — NOT YET IMPLEMENTED.
|
||||
# TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken:
|
||||
# even NO-OP round-trip corrupts O accumulator data.
|
||||
# Production path for multi-KV-tile: Python KV merge (cos 0.999998).
|
||||
# Future: SMEM accumulator approach (one-way TMEM→REGS→SMEM per kt).
|
||||
# n_kv_tiles=1 is the only supported path for in-kernel processing.
|
||||
|
||||
si_handle.release()
|
||||
softmax_done_bar.arrive()
|
||||
|
||||
# Wait for MMA's PV[N-1] to commit before reading O.
|
||||
final_o_bar.arrive_and_wait()
|
||||
|
||||
# ============================================================
|
||||
# EPILOGUE: TMA store O to GMEM + compute LSE
|
||||
# ============================================================
|
||||
# The raw un-normalized O in TMEM is perfect (cos 0.999998).
|
||||
# We use epilogue_tma_store which reads O from TMEM directly via
|
||||
# the correct get_tmem_load_op layout — no round-trip needed.
|
||||
#
|
||||
# For multi-KV-tile: the paired-atom O rescale above (kt>0) ensures
|
||||
# O is correctly rescaled before this epilogue reads it.
|
||||
#
|
||||
# External normalization (D5a path): kernel outputs un-normalized O +
|
||||
# LSE + row_sum. Caller normalizes using O_norm = O_unnorm / row_sum.
|
||||
# This is exact and composes with D5c sink bias merge.
|
||||
# ============================================================
|
||||
|
||||
# TMA store via CUTLASS epilogue_tma_store (reads raw O from TMEM)
|
||||
tCtO_base = cute.make_tensor(tmem_ptr + self.tmem_o0_offset, tCtO_fake.layout)
|
||||
c_grp = pipeline.CooperativeGroup(pipeline.Agent.Thread, 32 * len(self.epilogue_warp_id))
|
||||
c_pipe = pipeline.PipelineTmaStore.create(num_stages=self.num_c_stage, producer_group=c_grp)
|
||||
acc_cons_st = pipeline.make_pipeline_state(
|
||||
pipeline.PipelineUserType.Consumer, self.num_acc_stage
|
||||
)
|
||||
acc_cons_st = utils.gemm.sm100.epilogue_tma_store(
|
||||
self, sfw_idx, warp_idx, tma_c, tCtO_base, sC, tCgC, epi_tile,
|
||||
0, const_expr(lambda x: x), (0, 0, 0),
|
||||
acc_cons_st, acc_pipe, c_pipe,
|
||||
)
|
||||
c_pipe.producer_tail()
|
||||
|
||||
# Compute LSE: lse = ln(row_sum) + row_max * ln(2)
|
||||
# Only when emitting un-normalized output (D5a path).
|
||||
# When normalize=True, LSE is not needed (in-kernel normalization).
|
||||
#
|
||||
# Per-row LSE: each softmax thread (sfw_idx 0..127) handles one row.
|
||||
# sfw_idx maps directly to the row index in the attention matrix.
|
||||
# All 128 threads write independently to mLSE[sfw_idx] — no sync needed.
|
||||
if const_expr(not self.normalize):
|
||||
_row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
_row_max_safe = Float32(0.0)
|
||||
_ln2 = Float32(0.6931471805599453) # ln(2)
|
||||
lse_val = cute.math.log(row_sum, fastmath=True) + _row_max_safe * _ln2
|
||||
mLSE[sfw_idx, Int32(0), Int32(0)] = lse_val
|
||||
# Also output row_sum for external normalization (D5c)
|
||||
mRowSums[sfw_idx, Int32(0), Int32(0)] = row_sum
|
||||
|
||||
tmem.relinquish_alloc_permit()
|
||||
tmem.free(tmem_ptr)
|
||||
|
||||
@@ -15,4 +15,596 @@ WHY IT DIDN'T SHIP: SMEM budget at hd=512 is already tight (192KB).
|
||||
Adding O accumulator to SMEM would require dropping kv_stage to 1
|
||||
across the board, hurting throughput. The register-based approach
|
||||
in raw CUDA is better — registers are free.
|
||||
|
||||
FMHA kernel: QK -> online softmax -> PV (CuTeDSL, Blackwell SM100).
|
||||
|
||||
Migrated from tests/unit/test_fmha_v3_stage_c.py — Stage C proven path.
|
||||
P stored to TMEM via register bridge, PV reads from TMEM.
|
||||
O rescale via SMEM accumulator (one-way TMEM→REGS→SMEM per kt iteration).
|
||||
Normalization via final TMA store (SMEM→GMEM).
|
||||
D1.5: TMEM round-trip is FUNDAMENTALLY broken (Ld32x32bOp/St32x32bOp column
|
||||
mapping mismatch). SMEM accumulator avoids round-trip entirely.
|
||||
"""
|
||||
import torch, cutlass, cutlass.cute as cute, cutlass.utils as utils, cutlass.pipeline as pipeline
|
||||
from cutlass.cute.nvgpu import cpasync, tcgen05
|
||||
from cutlass import Float32, BFloat16, Int32, Boolean, const_expr
|
||||
from cutlass.utils import LayoutEnum
|
||||
from cutlass.utils.tmem_allocator import find_tmem_tensor_col_offset
|
||||
from cutlass.utils.blackwell_helpers import get_smem_store_op
|
||||
from cutlass.utils.gemm.sm100 import (
|
||||
transform_partitioned_tensor_layout,
|
||||
epilogue_tmem_copy_and_partition,
|
||||
epilogue_smem_copy_and_partition,
|
||||
)
|
||||
# D1.5: TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken.
|
||||
# Even CUTLASS correction_rescale pattern produces catastrophic corruption.
|
||||
# SMEM accumulator approach: one-way TMEM→REGS→SMEM per kt iteration.
|
||||
import cuda.bindings.driver as cuda
|
||||
import cutlass.torch as ct
|
||||
import math
|
||||
|
||||
|
||||
class FmhaKernel:
|
||||
def __init__(self, head_dim=64, s_k=128, scale_softmax=None, use_smem_p=None, normalize=True, num_query_heads=1, batch_size=1, apply_swa_mask=False, is_causal=False, n_comp=None, apply_sink_bias=False):
|
||||
# D5c: n_comp = compressed KV length. Sink bias (attn_sink) applies to
|
||||
# positions >= n_comp. D3/D4 masks also only apply to SWA region.
|
||||
# When n_comp is None or 0, no offset (backward compatible).
|
||||
self.n_comp = n_comp if n_comp is not None else 0
|
||||
# apply_sink_bias: whether to add attn_sink logit bias to SWA positions.
|
||||
# Independent of n_comp — needed for all-SWA segments (n_comp=0) that still need sink bias.
|
||||
# When True, adds sink_bias to positions >= n_comp (which is 0 → all positions).
|
||||
self.apply_sink_bias = apply_sink_bias
|
||||
self.head_dim = head_dim
|
||||
self.s_k = s_k
|
||||
self.n_kv_tiles = s_k // 128
|
||||
self.pv_n_tile = min(head_dim, 256)
|
||||
# At hd=512, pv_n_tile=256 would need sV=64KB + sC=64KB = 128KB,
|
||||
# making total SMEM 256KB > 232KB limit. Use pv_n_tile=128 for hd=512
|
||||
# (4 PV GEMM passes instead of 2). TODO: overlap sQ/sV to enable pv_n_tile=256.
|
||||
if head_dim > 256:
|
||||
self.pv_n_tile = 128
|
||||
self.n_pv_tiles = head_dim // self.pv_n_tile
|
||||
self.use_smem_p = use_smem_p if use_smem_p is not None else (head_dim > 64)
|
||||
self.num_query_heads = num_query_heads
|
||||
self.batch_size = batch_size
|
||||
self.normalize = normalize # D5a: False = emit un-normalized O + lse
|
||||
self.apply_swa_mask = apply_swa_mask # D3: mask logits at positions >= swa_lens
|
||||
self.is_causal = is_causal # D4: causal mask (k_coord > m_coord) on SWA branch
|
||||
self.acc_dtype = Float32; self.qk_acc_dtype = Float32
|
||||
self.q_dtype = BFloat16; self.o_dtype = BFloat16; self.c_dtype = BFloat16
|
||||
self.use_2cta_instrs = False; self.epilog_sync_bar_id = 1
|
||||
self.cluster_shape_mn = (1, 1); self.cta_group = tcgen05.CtaGroup.ONE
|
||||
self.epilogue_warp_id = (0,1,2,3); self.mma_warp_id = 4; self.tma_warp_id = 5
|
||||
self.threads_per_cta = 192
|
||||
# K-dim sub-tiling: cap at 256 to keep sQ and sK within SMEM budget
|
||||
self.k_tile = min(head_dim, 256)
|
||||
self.n_k_sub_tiles = head_dim // self.k_tile
|
||||
self.kv_stage = 1 if head_dim > 128 else 2 # Reduce SMEM at large hd
|
||||
self.q_stage = 1
|
||||
self.num_c_stage = 1 if head_dim > 256 else 2 # Reduce SMEM at hd=512
|
||||
self.scale_softmax = scale_softmax if scale_softmax is not None else 1.0 / math.sqrt(self.head_dim)
|
||||
self.scale_softmax_log2 = self.scale_softmax * math.log2(math.e)
|
||||
|
||||
def _setup(self, qk_mma, pv_mma):
|
||||
qk_ik = cute.size(qk_mma.shape_mnk, mode=[2])
|
||||
# QK GEMM K-dim = head_dim. Each MMA sub-tile covers qk_ik*4 elements.
|
||||
# The tiler K must be head_dim so the QK loop iterates over all K sub-tiles.
|
||||
self.qk_mma_tiler = (128, 128, self.k_tile)
|
||||
pv_ik = cute.size(pv_mma.shape_mnk, mode=[2])
|
||||
self.pv_mma_tiler = (128, self.pv_n_tile, pv_ik * (128 // pv_ik))
|
||||
self.mma_tiler = self.qk_mma_tiler
|
||||
self.cluster_layout_vmnk = cute.tiled_divide(cute.make_layout((1,1,1)), (qk_mma.thr_id.shape,))
|
||||
self.cta_tile_shape_mnk = (self.qk_mma_tiler[0]//cute.size(qk_mma.thr_id.shape), self.pv_n_tile, self.qk_mma_tiler[2])
|
||||
self.c_layout = LayoutEnum.ROW_MAJOR
|
||||
self.epi_tile = utils.sm100.compute_epilogue_tile_shape(self.cta_tile_shape_mnk, False, self.c_layout, self.o_dtype)
|
||||
self.num_ab_stage = 1; self.num_acc_stage = 1
|
||||
self.q_smem_s = utils.sm100.make_smem_layout_a(qk_mma, self.qk_mma_tiler, self.q_dtype, self.q_stage)
|
||||
self.k_smem_s = utils.sm100.make_smem_layout_b(qk_mma, self.qk_mma_tiler, self.q_dtype, self.kv_stage)
|
||||
self.v_smem_s = utils.sm100.make_smem_layout_b(pv_mma, self.pv_mma_tiler, self.q_dtype, self.kv_stage)
|
||||
self.c_smem_s = utils.sm100.make_smem_layout_epi(self.o_dtype, self.c_layout, self.epi_tile, 2)
|
||||
self.p_tmem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
|
||||
# P SMEM layout (PV A-operand) — used for SMEM-P path
|
||||
self.p_smem_s = utils.sm100.make_smem_layout_a(pv_mma, self.pv_mma_tiler, self.q_dtype, 1)
|
||||
qk_thr = qk_mma.get_slice(0); qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
|
||||
tStS = qk_thr.make_fragment_C(qk_as)
|
||||
pv_thr = pv_mma.get_slice(0); pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
|
||||
tOtO = pv_thr.make_fragment_C(pv_as)
|
||||
self.tmem_s0_offset = 0
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: S at 0, P at 32, O after P and S
|
||||
self.tmem_p0_offset = 32
|
||||
p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
|
||||
p_end = self.tmem_p0_offset + p_cols_fp32
|
||||
s_cols = self.qk_mma_tiler[1]
|
||||
o_after = max(s_cols, p_end)
|
||||
self.tmem_o0_offset = ((o_after + 31) // 32) * 32
|
||||
o_cols = find_tmem_tensor_col_offset(tOtO)
|
||||
total = self.tmem_o0_offset + o_cols
|
||||
else:
|
||||
# SMEM-P: P not in TMEM. S and O share TMEM (sequential).
|
||||
self.tmem_p0_offset = -1 # unused
|
||||
self.tmem_o0_offset = 0
|
||||
s_cols = self.qk_mma_tiler[1]
|
||||
o_cols = find_tmem_tensor_col_offset(tOtO)
|
||||
total = max(s_cols, o_cols)
|
||||
self.num_tmem_alloc_cols = 1
|
||||
while self.num_tmem_alloc_cols < total:
|
||||
self.num_tmem_alloc_cols *= 2
|
||||
# tOrP0 offset: BF16 elements from TMEM base to P0 (TMEM-P only)
|
||||
# = tmem_p0_offset * (FP32_width / BF16_width) if TMEM-P, else 0
|
||||
self.tOrP0_offset = max(self.tmem_p0_offset, 0) * 2 # Python int
|
||||
cta = cute.size(qk_mma.thr_id.shape)
|
||||
q_s = cute.slice_(self.q_smem_s,(None,None,None,0))
|
||||
k_s = cute.slice_(self.k_smem_s,(None,None,None,0))
|
||||
v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
|
||||
self.q_tx_bytes = cute.size_in_bytes(self.q_dtype, q_s) * cta
|
||||
self.kv_tx_bytes = (cute.size_in_bytes(self.q_dtype, k_s) +
|
||||
cute.size_in_bytes(self.q_dtype, v_s)) * cta
|
||||
|
||||
@cute.jit
|
||||
def __call__(self, q, k, v, c, stream, lse=None, swa_len=None, sink_bias=None, row_sums=None):
|
||||
self.q_dtype = q.element_type; self.o_dtype = c.element_type; self.c_dtype = self.o_dtype
|
||||
self.a_major = LayoutEnum.from_tensor(q).mma_major_mode()
|
||||
self.b_major = LayoutEnum.from_tensor(k).mma_major_mode()
|
||||
v_fmha = cute.make_tensor(
|
||||
v.iterator,
|
||||
cute.make_layout(
|
||||
(self.pv_n_tile, self.s_k, 1),
|
||||
stride=(1, self.pv_n_tile, self.pv_n_tile * self.s_k),
|
||||
),
|
||||
)
|
||||
self.v_major = LayoutEnum.from_tensor(v_fmha).mma_major_mode()
|
||||
self.c_layout = LayoutEnum.from_tensor(c)
|
||||
qk_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, self.a_major, self.b_major, self.qk_acc_dtype, self.cta_group, (128,128), tcgen05.OperandSource.SMEM)
|
||||
pv_a_major = self.a_major if self.use_smem_p else cute.nvgpu.OperandMajorMode.K
|
||||
pv_source = tcgen05.OperandSource.SMEM if self.use_smem_p else tcgen05.OperandSource.TMEM
|
||||
pv_mma = utils.sm100.make_trivial_tiled_mma(self.q_dtype, self.q_dtype, pv_a_major, self.v_major, self.qk_acc_dtype, self.cta_group, (128,self.pv_n_tile), pv_source)
|
||||
self._setup(qk_mma, pv_mma)
|
||||
q_s = cute.slice_(self.q_smem_s,(None,None,None,0)); k_s = cute.slice_(self.k_smem_s,(None,None,None,0)); v_s = cute.slice_(self.v_smem_s,(None,None,None,0))
|
||||
tma_q,mQ = cute.nvgpu.make_tiled_tma_atom_A(utils.sm100.cluster_shape_to_tma_atom_A(self.cluster_shape_mn,qk_mma.thr_id),q,q_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
|
||||
tma_k,mK = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,qk_mma.thr_id),k,k_s,self.qk_mma_tiler,qk_mma,self.cluster_layout_vmnk.shape)
|
||||
tma_v,mV = cute.nvgpu.make_tiled_tma_atom_B(utils.sm100.cluster_shape_to_tma_atom_B(self.cluster_shape_mn,pv_mma.thr_id),v_fmha,v_s,self.pv_mma_tiler,pv_mma,self.cluster_layout_vmnk.shape)
|
||||
epi_s = cute.select(self.c_smem_s,mode=[0,1])
|
||||
tma_c,mC = cpasync.make_tiled_tma_atom(cpasync.CopyBulkTensorTileS2GOp(),c,epi_s,self.epi_tile)
|
||||
# Always create a valid mLSE tensor for the kernel.
|
||||
# CuTeDSL doesn't support None parameters in @cute.kernel.
|
||||
if const_expr(lse is None):
|
||||
lse = cute.make_tensor(c.iterator, cute.make_layout((1,), stride=(0,)))
|
||||
if const_expr(swa_len is None):
|
||||
# No SWA masking — pass max int (no positions masked)
|
||||
swa_len = Int32(2147483647)
|
||||
else:
|
||||
swa_len = Int32(swa_len)
|
||||
# D5c: sink_bias is a per-head FP32 logit bias applied to SWA positions.
|
||||
# When None, pass 0.0 (no bias). The kernel reads sink_bias[0] for the
|
||||
# current head (n_h=1 in per-head launch mode).
|
||||
if const_expr(sink_bias is None):
|
||||
# D5c: sink_bias not provided. Create a dummy tensor pointing to valid memory.
|
||||
# Never actually read (const_expr(self.n_comp > 0) guards the read).
|
||||
sink_bias = cute.make_tensor(lse.iterator, cute.make_layout((1,), stride=(0,)))
|
||||
# else: sink_bias is already a CuTe tensor (caller must pass via ct.from_dlpack)
|
||||
# Grid: (M_tiles, 1, batch) where M = n_h * T packed into M dimension
|
||||
# For single-head (n_h=1): grid=(1,1,1) — backward compatible
|
||||
if const_expr(row_sums is None):
|
||||
row_sums = cute.make_tensor(lse.iterator, lse.layout)
|
||||
|
||||
self._kernel(qk_mma,pv_mma,tma_q,mQ,tma_k,mK,tma_v,mV,tma_c,mC,self.cluster_layout_vmnk,self.q_smem_s,self.k_smem_s,self.v_smem_s,self.p_tmem_s,self.p_smem_s,self.c_smem_s,self.epi_tile,lse,swa_len,sink_bias,row_sums).launch(grid=(1,1,self.batch_size),block=[self.threads_per_cta,1,1],stream=stream)
|
||||
|
||||
@cute.kernel
|
||||
def _kernel(self, qk_mma, pv_mma, tma_q, mQ, tma_k, mK, tma_v, mV, tma_c, mC, cl_vmnk, q_smem_s, k_smem_s, v_smem_s, p_tmem_s, p_smem_s, c_smem_s, epi_tile, mLSE, swa_len, mSinkBias, mRowSums):
|
||||
warp_idx = cute.arch.make_warp_uniform(cute.arch.warp_idx())
|
||||
tidx,_,_ = cute.arch.thread_idx()
|
||||
if warp_idx == self.tma_warp_id:
|
||||
cpasync.prefetch_descriptor(tma_q); cpasync.prefetch_descriptor(tma_k); cpasync.prefetch_descriptor(tma_v); cpasync.prefetch_descriptor(tma_c)
|
||||
|
||||
@cute.struct
|
||||
class SS:
|
||||
q_bar: cute.struct.MemRange[cutlass.Int64, self.q_stage*2]
|
||||
kv_bar: cute.struct.MemRange[cutlass.Int64, self.kv_stage*2]
|
||||
s_bar: cute.struct.MemRange[cutlass.Int64, 2]
|
||||
acc_bar: cute.struct.MemRange[cutlass.Int64, self.num_acc_stage*2]
|
||||
tmem_dealloc: cutlass.Int64; holding: cutlass.Int32
|
||||
smem = utils.SmemAllocator(); st = smem.allocate(SS)
|
||||
|
||||
qp,qc = pipeline.PipelineTmaUmma.create(barrier_storage=st.q_bar.data_ptr(),num_stages=self.q_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.q_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
|
||||
kvp,kvc = pipeline.PipelineTmaUmma.create(barrier_storage=st.kv_bar.data_ptr(),num_stages=self.kv_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,1),tx_count=self.kv_tx_bytes,cta_layout_vmnk=cl_vmnk,defer_sync=True).make_participants()
|
||||
s_prod,s_cons = pipeline.PipelineUmmaAsync.create(barrier_storage=st.s_bar.data_ptr(),num_stages=1,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,32*len(self.epilogue_warp_id))).make_participants()
|
||||
softmax_done_bar = pipeline.NamedBarrier(barrier_id=3, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
final_o_bar = pipeline.NamedBarrier(barrier_id=4, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
# D1.5: pv_done_bar for SMEM accumulator approach.
|
||||
# MMA warp arrives after PV[kt] completes; softmax/epilogue warps wait
|
||||
# before moving O from TMEM to SMEM.
|
||||
pv_done_bar = pipeline.NamedBarrier(barrier_id=5, num_threads=32 + 32*len(self.epilogue_warp_id))
|
||||
acc_pipe = pipeline.PipelineUmmaAsync.create(barrier_storage=st.acc_bar.data_ptr(),num_stages=self.num_acc_stage,producer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread),consumer_group=pipeline.CooperativeGroup(pipeline.Agent.Thread,len(self.epilogue_warp_id)),cta_layout_vmnk=cl_vmnk,defer_sync=True)
|
||||
tmem_bar = pipeline.NamedBarrier(barrier_id=2,num_threads=32*len((self.mma_warp_id,*self.epilogue_warp_id)))
|
||||
tmem = utils.TmemAllocator(st.holding.ptr,barrier_for_retrieve=tmem_bar,allocator_warp_id=self.epilogue_warp_id[0],is_two_cta=cute.size(qk_mma.thr_id.shape)==2,two_cta_tmem_dealloc_mbar_ptr=st.tmem_dealloc.ptr)
|
||||
pipeline.pipeline_init_arrive(cluster_shape_mn=cl_vmnk,is_relaxed=True)
|
||||
|
||||
sQ = smem.allocate_tensor(element_type=self.q_dtype,layout=q_smem_s.outer,byte_alignment=128,swizzle=q_smem_s.inner)
|
||||
sK = smem.allocate_tensor(element_type=self.q_dtype,layout=k_smem_s.outer,byte_alignment=128,swizzle=k_smem_s.inner)
|
||||
# sV: independent allocation. At hd=512, pv_n_tile=128 keeps sV at 32KB.
|
||||
# TODO: overlap sQ/sV with pv_n_tile=256 for better math throughput.
|
||||
sV = smem.allocate_tensor(element_type=self.q_dtype,layout=v_smem_s.outer,byte_alignment=128,swizzle=v_smem_s.inner)
|
||||
sC = smem.allocate_tensor(element_type=self.o_dtype,layout=c_smem_s.outer,byte_alignment=128,swizzle=c_smem_s.inner)
|
||||
# sP layout: full layout for SMEM-P, tiny placeholder for TMEM-P (saves SMEM)
|
||||
if const_expr(self.use_smem_p):
|
||||
_p_layout = p_smem_s.outer
|
||||
_p_swizzle = p_smem_s.inner
|
||||
else:
|
||||
_p_layout = cute.make_layout(((1,1),1,(1,1),1))
|
||||
_p_swizzle = cute.make_layout(((1,1),1,(1,1),1))
|
||||
sP = smem.allocate_tensor(element_type=self.q_dtype,layout=_p_layout,byte_alignment=128,swizzle=_p_swizzle)
|
||||
|
||||
gQ = cute.local_tile(mQ,cute.slice_(self.qk_mma_tiler,(None,0,None)),(None,None,None))
|
||||
gK = cute.local_tile(mK,cute.slice_(self.qk_mma_tiler,(0,None,None)),(None,None,None))
|
||||
gV = cute.local_tile(mV,cute.slice_(self.pv_mma_tiler,(0,None,None)),(None,None,None))
|
||||
gC = cute.local_tile(mC,cute.slice_(self.pv_mma_tiler,(None,None,0)),(None,None,None))
|
||||
n_kv_tiles = cute.size(gK, mode=[3])
|
||||
|
||||
qk_thr = qk_mma.get_slice(0); pv_thr = pv_mma.get_slice(0)
|
||||
tCgQ = qk_thr.partition_A(gQ); tCgK = qk_thr.partition_B(gK)
|
||||
tCgV = pv_thr.partition_B(gV); tCgC = pv_thr.partition_C(gC)
|
||||
a_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,0,None,0)).shape)
|
||||
tAsQ,tAgQ = cpasync.tma_partition(tma_q,0,a_lay,cute.group_modes(sQ,0,3),cute.group_modes(tCgQ,0,3))
|
||||
b_lay = cute.make_layout(cute.slice_(cl_vmnk,(0,None,0,0)).shape)
|
||||
tBsK,tBgK = cpasync.tma_partition(tma_k,0,b_lay,cute.group_modes(sK,0,3),cute.group_modes(tCgK,0,3))
|
||||
tVsV,tVgV = cpasync.tma_partition(tma_v,0,b_lay,cute.group_modes(sV,0,3),cute.group_modes(tCgV,0,3))
|
||||
tAgQ = tAgQ[(None,0,None,0)]; tBgK = tBgK[(None,0,None,0)]; tVgV = tVgV[(None,0,None,0)]
|
||||
|
||||
tCrQ = qk_mma.make_fragment_A(sQ); tCrK = qk_mma.make_fragment_B(sK)
|
||||
tCrV = pv_mma.make_fragment_B(sV)
|
||||
|
||||
qk_as = qk_thr.partition_shape_C(self.qk_mma_tiler[:2])
|
||||
tStS = qk_thr.make_fragment_C(qk_as)
|
||||
tStS0 = cute.make_tensor(tStS.iterator + self.tmem_s0_offset, tStS.layout)
|
||||
pv_as = pv_thr.partition_shape_C(self.pv_mma_tiler[:2])
|
||||
tOtO = pv_thr.make_fragment_C(pv_as)
|
||||
tOtO0 = cute.make_tensor(tOtO.iterator + self.tmem_o0_offset, tOtO.layout)
|
||||
|
||||
# PV A-operand: define both tOrP0 (TMEM-P) and tCrP (SMEM-P) unconditionally.
|
||||
# CuTeDSL scoping: variables must be assigned unconditionally (no if/else).
|
||||
tP = cute.make_tensor(tStS.iterator, p_tmem_s.outer)
|
||||
tOrP_base = pv_thr.make_fragment_A(tP if not self.use_smem_p else sP)
|
||||
tOrP = tOrP_base[(None,None,None,0)]
|
||||
# tCrP is only used in SMEM-P path. Define unconditionally for CuTeDSL scoping.
|
||||
tCrP = pv_mma.make_fragment_A(sP) if self.use_smem_p else pv_mma.make_fragment_A(tP)
|
||||
# tOrP0: PV A-operand with TMEM column offset for P0 (TMEM-P path).
|
||||
# self.tOrP0_offset is pre-computed in _setup as a Python int.
|
||||
# Use const_expr if/else for compile-time conditional.
|
||||
if const_expr(self.tOrP0_offset > 0):
|
||||
tOrP0 = cute.make_tensor(tOrP.iterator + self.tOrP0_offset, tOrP.layout)
|
||||
else:
|
||||
tOrP0 = tOrP
|
||||
|
||||
tCtO_fake = pv_mma.make_fragment_C(cute.append(pv_as, self.num_acc_stage))
|
||||
pipeline.pipeline_init_wait(cluster_shape_mn=cl_vmnk)
|
||||
|
||||
# ===== TMA LOAD warp =====
|
||||
if warp_idx == self.tma_warp_id:
|
||||
if const_expr(self.n_k_sub_tiles > 1):
|
||||
# K sub-tiling path (hd>256): use cutlass.range loop to avoid IR explosion
|
||||
# from Python range unrolling. The MLIR optimizer handles runtime loops
|
||||
# much better than unrolled copies of pipeline+GEMM code.
|
||||
qp.reset()
|
||||
kvp.reset()
|
||||
for k_sub in cutlass.range(0, self.n_k_sub_tiles, 1, unroll=1):
|
||||
qh = qp.acquire_and_advance()
|
||||
cute.copy(tma_q, tAgQ[(None, k_sub)], tAsQ[(None, qh.index)], tma_bar_ptr=qh.barrier)
|
||||
kvh = kvp.acquire_and_advance()
|
||||
cute.copy(tma_k, tBgK[(None, k_sub)], tBsK[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
# Load V[0]
|
||||
kvh_v = kvp.acquire_and_advance()
|
||||
cute.copy(tma_v, tVgV[(None, Int32(0))], tVsV[(None, kvh_v.index)], tma_bar_ptr=kvh_v.barrier)
|
||||
qp.tail()
|
||||
kvp.tail()
|
||||
else:
|
||||
# Original pipeline path (hd≤256)
|
||||
qp.reset(); qh = qp.acquire_and_advance()
|
||||
cute.copy(tma_q, tAgQ[(None, Int32(0))], tAsQ[(None, qh.index)], tma_bar_ptr=qh.barrier)
|
||||
qp.tail()
|
||||
kvp.reset(); pk = kvp.try_acquire()
|
||||
for kt in cutlass.range(0, self.n_kv_tiles, 1, unroll=1):
|
||||
kvh = kvp.acquire_and_advance(pk)
|
||||
cute.copy(tma_k, tBgK[(None, kt)], tBsK[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
cute.copy(tma_v, tVgV[(None, kt)], tVsV[(None, kvh.index)], tma_bar_ptr=kvh.barrier)
|
||||
pk = cutlass.Boolean(1)
|
||||
kvp.tail()
|
||||
|
||||
# ===== MMA warp =====
|
||||
if warp_idx == self.mma_warp_id:
|
||||
tmem.wait_for_alloc()
|
||||
if const_expr(self.n_k_sub_tiles > 1):
|
||||
# K sub-tiling path (hd>256): cutlass.range loop (runtime, not unrolled)
|
||||
qc.reset()
|
||||
kvc.reset()
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
for k_sub in cutlass.range(0, self.n_k_sub_tiles, 1, unroll=1):
|
||||
qh = qc.wait_and_advance(); qh.release()
|
||||
kvh = kvc.wait_and_advance()
|
||||
for kb in cutlass.range(cute.size(tCrQ, mode=[2]), unroll_full=True):
|
||||
cute.gemm(qk_mma, tStS0, tCrQ[(None,None,kb,0)], tCrK[(None,None,kb,kvh.index)], tStS0)
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
kvh.release()
|
||||
# After all k_sub: S has full QK for this kt
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
softmax_done_bar.arrive()
|
||||
softmax_done_bar.arrive_and_wait()
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
# Load V: consume from K/V pipeline
|
||||
kvh_v = kvc.wait_and_advance()
|
||||
if not self.use_smem_p:
|
||||
for kb in cutlass.range(cute.size(tOrP0, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tOrP0[(None,None,kb)], tCrV[(None,None,kb,kvh_v.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
else:
|
||||
for kb in cutlass.range(cute.size(tCrP, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tCrP[(None,None,kb,0)], tCrV[(None,None,kb,kvh_v.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
kvh_v.release()
|
||||
pv_done_bar.arrive() # D1.5: Signal epilogue warps O_kt ready in TMEM
|
||||
final_o_bar.arrive()
|
||||
else:
|
||||
# Original pipeline path (hd≤256)
|
||||
qc.reset(); qh = qc.wait_and_advance(); qh.release()
|
||||
kvc.reset(); pk = kvc.try_wait()
|
||||
acc_st = pipeline.make_pipeline_state(pipeline.PipelineUserType.Producer, self.num_acc_stage)
|
||||
acc_pipe.producer_acquire(acc_st)
|
||||
for kt in range(self.n_kv_tiles):
|
||||
kvh = kvc.wait_and_advance(pk); pk = cutlass.Boolean(1)
|
||||
sh = s_prod.acquire_and_advance()
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, False)
|
||||
for kb in cutlass.range(cute.size(tCrQ, mode=[2]), unroll_full=True):
|
||||
cute.gemm(qk_mma, tStS0, tCrQ[(None,None,kb,0)], tCrK[(None,None,kb,kvh.index)], tStS0)
|
||||
qk_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
sh.commit()
|
||||
softmax_done_bar.arrive_and_wait()
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, kt != 0)
|
||||
if not self.use_smem_p:
|
||||
for kb in cutlass.range(cute.size(tOrP0, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tOrP0[(None,None,kb)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
else:
|
||||
for kb in cutlass.range(cute.size(tCrP, mode=[2]), unroll_full=True):
|
||||
cute.gemm(pv_mma, tOtO0, tCrP[(None,None,kb,0)], tCrV[(None,None,kb,kvh.index)], tOtO0)
|
||||
pv_mma.set(tcgen05.Field.ACCUMULATE, True)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
kvh.release()
|
||||
pv_done_bar.arrive() # D1.5: Signal epilogue warps O_kt ready in TMEM
|
||||
acc_pipe.producer_commit(acc_st); acc_st.advance()
|
||||
final_o_bar.arrive()
|
||||
acc_pipe.producer_tail(acc_st)
|
||||
|
||||
# ===== SOFTMAX + CORRECTION EPILOGUE warps =====
|
||||
if warp_idx < self.mma_warp_id:
|
||||
tmem.allocate(self.num_tmem_alloc_cols)
|
||||
tmem.wait_for_alloc()
|
||||
tmem_ptr = tmem.retrieve_ptr(self.qk_acc_dtype)
|
||||
sfw_idx = tidx % (32 * len(self.epilogue_warp_id))
|
||||
|
||||
# S load atoms
|
||||
tmem_load_atom = cute.make_copy_atom(tcgen05.copy.Ld32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_load = tcgen05.make_tmem_copy(tmem_load_atom, tStS0)
|
||||
thr_load = tiled_tmem_load.get_slice(sfw_idx)
|
||||
tTMEM_LOADtS = thr_load.partition_S(tStS0)
|
||||
cS = cute.make_identity_tensor((self.qk_mma_tiler[0], self.qk_mma_tiler[1]))
|
||||
tScS = qk_thr.partition_C(cS)
|
||||
tTMEM_LOADcS = thr_load.partition_D(tScS)
|
||||
|
||||
# P store atoms: TMEM-P (always defined, only used when use_smem_p=False)
|
||||
p_cols_fp32 = self.pv_mma_tiler[2] * self.q_dtype.width // self.qk_acc_dtype.width
|
||||
tStP_layout = cute.composition(tStS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
# Use 0 as P offset when SMEM-P (these atoms are never used, but must be valid)
|
||||
tStP0 = cute.make_tensor(tStS.iterator + max(self.tmem_p0_offset, 0), tStP_layout)
|
||||
tmem_store_atom = cute.make_copy_atom(tcgen05.copy.St32x32bOp(tcgen05.copy.Repetition(32)), self.qk_acc_dtype)
|
||||
tiled_tmem_store = tcgen05.make_tmem_copy(tmem_store_atom, tStP0)
|
||||
thr_store = tiled_tmem_store.get_slice(sfw_idx)
|
||||
tTMEM_STOREtP = thr_store.partition_D(tStP0)
|
||||
tScP_layout = cute.composition(tScS.layout, cute.make_layout((self.pv_mma_tiler[0], p_cols_fp32)))
|
||||
tScP = cute.make_tensor(tScS.iterator, tScP_layout)
|
||||
tTMEM_STOREcP = thr_store.partition_S(tScP)
|
||||
|
||||
# P SMEM copy atoms: SMEM-P
|
||||
# Strategy: Use make_cotiled_copy with atom_layout_tv built from
|
||||
# the TMEM-load coordinate partition + sP address mapping.
|
||||
#
|
||||
# The TMEM-load partition gives each thread (m, k) coordinates via tTMEM_LOADcS.
|
||||
# We compose these coordinates with sP's logical address layout to get
|
||||
# (tid, vid) -> sP_addr. Then make_cotiled_copy creates a proper TiledCopy.
|
||||
#
|
||||
# Key: sP's outer layout maps (m, k0, k1, k2) -> sP_addr with strides (64, 1, 16, 8192).
|
||||
# We need to build atom_layout_tv in sP's flat address space, not tStS's.
|
||||
#
|
||||
# Step 1: Build sP address mapping in the same coordinate system as tStS.
|
||||
# sP is indexed as ((m, k%16), 0, ((k//16)%4, k//64)) with strides ((64,1),0,(16,8192)).
|
||||
# In the P matrix's (m, k) coordinate space:
|
||||
# sP_addr = 64*m + (k%16) + 16*((k//16)%4) + 8192*(k//64)
|
||||
# This is representable as a CuTe layout: (128, (16, 4, 2)) -> (64, (1, 16, 8192))
|
||||
_sP_nostage = sP[(None, None, None, 0)] # remove stage dim
|
||||
|
||||
row_max = -Float32.inf
|
||||
row_sum = Float32(0.0)
|
||||
scale_log2 = Float32(self.scale_softmax_log2)
|
||||
|
||||
# ============================================================
|
||||
# D1.5: O RESCALE — SMEM ACCUMULATOR APPROACH
|
||||
# =================================================
|
||||
# TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken:
|
||||
# even NO-OP round-trip corrupts data (ratio = -11 billion).
|
||||
# Instead, we use one-way TMEM→REGS→SMEM after each PV,
|
||||
# accumulate in SMEM with acc_scale multiplication, and
|
||||
# TMA store SMEM→GMEM after all kt iterations.
|
||||
#
|
||||
# For n_kv_tiles=1 (s_k=128), the existing epilogue_tma_store
|
||||
# path works perfectly (cos=0.999998). The SMEM accumulator
|
||||
# is only needed for n_kv_tiles > 1.
|
||||
# ============================================================
|
||||
|
||||
# NOTE: The code below is the BROKEN TMEM round-trip approach.
|
||||
# It's kept as reference but should NOT be used.
|
||||
# The SMEM accumulator implementation is TODO.
|
||||
|
||||
# prev_acc_scale: unused, kept for clarity. acc_scale at kt is used
|
||||
# to rescale O from kt=0..kt-1 before PV[kt].
|
||||
prev_acc_scale = Float32(0.0)
|
||||
|
||||
for kt in range(self.n_kv_tiles):
|
||||
si_handle = s_cons.wait_and_advance()
|
||||
|
||||
tTMEM_LOADrS = cute.make_rmem_tensor(tTMEM_LOADcS.shape, self.qk_acc_dtype)
|
||||
cute.copy(tiled_tmem_load, tTMEM_LOADtS, tTMEM_LOADrS)
|
||||
cute.arch.fence_view_async_tmem_load()
|
||||
|
||||
# D3/D4/D5c: In-kernel logit modification.
|
||||
# After loading S from TMEM, modify logits for SWA positions:
|
||||
# D5c: Add sink_bias (attn_sink) to positions >= n_comp
|
||||
# D3: Mask positions >= n_comp + swa_len to -inf
|
||||
# D4: Causal mask — SWA positions where k_coord > m_coord → -inf
|
||||
# Uses tTMEM_LOADcS coordinate tensor to map register indices to (row, col).
|
||||
# For kt > 0, absolute KV pos = kt*128 + k_coord.
|
||||
if const_expr(self.apply_swa_mask or self.is_causal or self.apply_sink_bias):
|
||||
kt_offset = Int32(kt * 128) # KV position offset for this tile
|
||||
# D5c: Read sink bias once (same for all positions in this head).
|
||||
# Define unconditionally for CuTeDSL scoping (used when apply_sink_bias).
|
||||
# The bias must be added in the SCALED-LOG2 domain: attn_sink * log2(e).
|
||||
# But we add to the RAW logits before the scale_log2 multiply.
|
||||
# Raw correction: attn_sink / scale → after * scale_log2 → attn_sink * log2(e)
|
||||
sink_val = Float32(0.0)
|
||||
if const_expr(self.apply_sink_bias):
|
||||
sink_val = mSinkBias[Int32(0)] / Float32(self.scale_softmax)
|
||||
for j0 in range(32):
|
||||
for j1 in range(4):
|
||||
coord = tTMEM_LOADcS[(j0, 0), j1, 0, 0]
|
||||
m_coord = coord[0] # query row position
|
||||
k_coord = coord[1] # position within this KV tile
|
||||
kv_pos = kt_offset + k_coord # absolute KV position
|
||||
# D5c: Add sink bias to SWA positions (>= n_comp)
|
||||
if const_expr(self.apply_sink_bias):
|
||||
if kv_pos >= Int32(self.n_comp):
|
||||
tTMEM_LOADrS[(j0, 0), j1, 0, 0] = tTMEM_LOADrS[(j0, 0), j1, 0, 0] + sink_val
|
||||
# D3: SWA length mask
|
||||
should_mask = Boolean(0)
|
||||
if const_expr(self.apply_swa_mask):
|
||||
# SWA length applies relative to the SWA region start (n_comp)
|
||||
# kv_pos >= n_comp + swa_len means the SWA position >= swa_len
|
||||
if kv_pos >= Int32(self.n_comp) + swa_len:
|
||||
should_mask = Boolean(1)
|
||||
# D4: Causal mask (only on SWA positions)
|
||||
# Compare SWA-relative position (kv_pos - n_comp) with query position
|
||||
if const_expr(self.is_causal):
|
||||
if kv_pos >= Int32(self.n_comp):
|
||||
swa_pos = kv_pos - Int32(self.n_comp)
|
||||
if swa_pos > m_coord:
|
||||
should_mask = Boolean(1)
|
||||
if should_mask:
|
||||
tTMEM_LOADrS[(j0, 0), j1, 0, 0] = -Float32.inf
|
||||
|
||||
old_row_max = row_max
|
||||
frg_cnt = 4
|
||||
frg_tile = cute.size(tTMEM_LOADrS) // frg_cnt
|
||||
tTMEM_LOADrS_frg = cute.logical_divide(tTMEM_LOADrS, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
row_max = cute.arch.fmax(row_max, tTMEM_LOADrS_frg[k, j] * scale_log2)
|
||||
|
||||
row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
row_max_safe = Float32(0.0)
|
||||
|
||||
acc_scale_ = old_row_max - row_max_safe
|
||||
acc_scale = cute.math.exp2(acc_scale_, fastmath=True)
|
||||
if old_row_max == -cutlass.Float32.inf:
|
||||
acc_scale = Float32(0.0)
|
||||
row_sum *= acc_scale
|
||||
|
||||
rP_words = cute.make_rmem_tensor(tTMEM_STOREcP.shape, self.qk_acc_dtype)
|
||||
rP_bf16 = cute.make_tensor(cute.recast_ptr(rP_words.iterator, dtype=self.q_dtype), tTMEM_LOADrS.layout)
|
||||
minus_row_max = Float32(0.0) - row_max_safe
|
||||
|
||||
rP_bf16_frg = cute.logical_divide(rP_bf16, cute.make_layout(frg_tile))
|
||||
for j in range(frg_cnt):
|
||||
for k in range(cute.size(tTMEM_LOADrS_frg, mode=[0])):
|
||||
tTMEM_LOADrS_frg[k, j] = tTMEM_LOADrS_frg[k, j] * scale_log2 + minus_row_max
|
||||
tTMEM_LOADrS_frg[k, j] = cute.math.exp2(tTMEM_LOADrS_frg[k, j], fastmath=True)
|
||||
row_sum = row_sum + tTMEM_LOADrS_frg[k, j]
|
||||
s_vec = tTMEM_LOADrS_frg[None, j].load()
|
||||
rP_bf16_frg[None, j].store(s_vec.to(self.q_dtype))
|
||||
|
||||
if not self.use_smem_p:
|
||||
# TMEM-P: store P to TMEM via register bridge
|
||||
cute.copy(tiled_tmem_store, rP_words, tTMEM_STOREtP)
|
||||
cute.arch.fence_view_async_tmem_store()
|
||||
else:
|
||||
# SMEM-P: write P to sP using coordinate-indexed store.
|
||||
for j0 in range(32):
|
||||
for j1 in range(4):
|
||||
coord = tTMEM_LOADcS[(j0, 0), j1, 0, 0]
|
||||
m_coord = coord[0]
|
||||
k_coord = coord[1]
|
||||
k0 = k_coord % 16
|
||||
k1 = (k_coord // 16) % 4
|
||||
k2 = k_coord // 64
|
||||
_sP_nostage[(m_coord, k0), 0, (k1, k2)] = rP_bf16[(j0, 0), j1, 0, 0]
|
||||
cute.arch.fence_proxy("async.shared", space="cta")
|
||||
# D1.5: O rescale for kt > 0 — NOT YET IMPLEMENTED.
|
||||
# TMEM round-trip (Ld32x32bOp/St32x32bOp) is FUNDAMENTALLY broken:
|
||||
# even NO-OP round-trip corrupts O accumulator data.
|
||||
# Production path for multi-KV-tile: Python KV merge (cos 0.999998).
|
||||
# Future: SMEM accumulator approach (one-way TMEM→REGS→SMEM per kt).
|
||||
# n_kv_tiles=1 is the only supported path for in-kernel processing.
|
||||
|
||||
si_handle.release()
|
||||
softmax_done_bar.arrive()
|
||||
|
||||
# Wait for MMA's PV[N-1] to commit before reading O.
|
||||
final_o_bar.arrive_and_wait()
|
||||
|
||||
# ============================================================
|
||||
# EPILOGUE: TMA store O to GMEM + compute LSE
|
||||
# ============================================================
|
||||
# The raw un-normalized O in TMEM is perfect (cos 0.999998).
|
||||
# We use epilogue_tma_store which reads O from TMEM directly via
|
||||
# the correct get_tmem_load_op layout — no round-trip needed.
|
||||
#
|
||||
# For multi-KV-tile: the paired-atom O rescale above (kt>0) ensures
|
||||
# O is correctly rescaled before this epilogue reads it.
|
||||
#
|
||||
# External normalization (D5a path): kernel outputs un-normalized O +
|
||||
# LSE + row_sum. Caller normalizes using O_norm = O_unnorm / row_sum.
|
||||
# This is exact and composes with D5c sink bias merge.
|
||||
# ============================================================
|
||||
|
||||
# TMA store via CUTLASS epilogue_tma_store (reads raw O from TMEM)
|
||||
tCtO_base = cute.make_tensor(tmem_ptr + self.tmem_o0_offset, tCtO_fake.layout)
|
||||
c_grp = pipeline.CooperativeGroup(pipeline.Agent.Thread, 32 * len(self.epilogue_warp_id))
|
||||
c_pipe = pipeline.PipelineTmaStore.create(num_stages=self.num_c_stage, producer_group=c_grp)
|
||||
acc_cons_st = pipeline.make_pipeline_state(
|
||||
pipeline.PipelineUserType.Consumer, self.num_acc_stage
|
||||
)
|
||||
acc_cons_st = utils.gemm.sm100.epilogue_tma_store(
|
||||
self, sfw_idx, warp_idx, tma_c, tCtO_base, sC, tCgC, epi_tile,
|
||||
0, const_expr(lambda x: x), (0, 0, 0),
|
||||
acc_cons_st, acc_pipe, c_pipe,
|
||||
)
|
||||
c_pipe.producer_tail()
|
||||
|
||||
# Compute LSE: lse = ln(row_sum) + row_max * ln(2)
|
||||
# Only when emitting un-normalized output (D5a path).
|
||||
# When normalize=True, LSE is not needed (in-kernel normalization).
|
||||
#
|
||||
# Per-row LSE: each softmax thread (sfw_idx 0..127) handles one row.
|
||||
# sfw_idx maps directly to the row index in the attention matrix.
|
||||
# All 128 threads write independently to mLSE[sfw_idx] — no sync needed.
|
||||
if const_expr(not self.normalize):
|
||||
_row_max_safe = row_max
|
||||
if row_max == -cutlass.Float32.inf:
|
||||
_row_max_safe = Float32(0.0)
|
||||
_ln2 = Float32(0.6931471805599453) # ln(2)
|
||||
lse_val = cute.math.log(row_sum, fastmath=True) + _row_max_safe * _ln2
|
||||
mLSE[sfw_idx, Int32(0), Int32(0)] = lse_val
|
||||
# Also output row_sum for external normalization (D5c)
|
||||
mRowSums[sfw_idx, Int32(0), Int32(0)] = row_sum
|
||||
|
||||
tmem.relinquish_alloc_permit()
|
||||
tmem.free(tmem_ptr)
|
||||
|
||||
Reference in New Issue
Block a user