# -*- coding: utf-8 -*- # Copyright (c) 2023-2024, Yu Zhang, Songlin Yang from typing import Optional import torch import triton import triton.language as tl from ..utils import contiguous @triton.autotune( configs=[ triton.Config({'BT': 16}, num_warps=2), triton.Config({'BT': 16}, num_warps=4), triton.Config({'BT': 16}, num_warps=8), triton.Config({'BT': 32}, num_warps=2), triton.Config({'BT': 32}, num_warps=4), triton.Config({'BT': 32}, num_warps=8), triton.Config({'BT': 64}, num_warps=2), triton.Config({'BT': 64}, num_warps=4), triton.Config({'BT': 64}, num_warps=8), ], key=['S'] ) @triton.jit def logcumsumexp_fwd_kernel( s, z, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr ): i_bh = tl.program_id(0) o_i = tl.arange(0, BT) m_s = tl.where(o_i[:, None] >= o_i[None, :], 1., 0.) b_mp = tl.full([S,], float('-inf'), dtype=tl.float32) b_zp = tl.zeros([S,], dtype=tl.float32) for i_t in range(tl.cdiv(T, BT)): p_s = tl.make_block_ptr(s + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) p_z = tl.make_block_ptr(z + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) # [BT, S] b_s = tl.load(p_s, boundary_check=(0, 1)).to(tl.float32) # [S,] b_mc = tl.max(b_s, 0) # workaround for compiler bugs if i_t > 0: b_mc = tl.maximum(b_mp, b_mc) b_zp = b_zp * tl.exp(b_mp - b_mc) # [BT, S] b_s = tl.exp(b_s - b_mc) b_z = tl.dot(m_s, b_s, allow_tf32=False) + b_zp # [S,] b_zc = tl.max(b_z, 0) b_mp = b_mc b_zp = b_zc # [BT, BS] # small eps to prevent underflows b_z = tl.log(tl.where(b_z != 0, b_z, 1e-20)) + b_mc tl.store(p_z, b_z.to(p_z.dtype.element_ty), boundary_check=(0, 1)) @triton.autotune( configs=[ triton.Config({}, num_warps=2), triton.Config({}, num_warps=4), triton.Config({}, num_warps=8), ], key=['S'] ) @triton.jit def softmax_fwd_kernel( s, p, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr ): i_t, i_bh = tl.program_id(0), tl.program_id(1) p_s = tl.make_block_ptr(s + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) p_p = tl.make_block_ptr(p + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) # [BT, S] b_s = tl.load(p_s, boundary_check=(0, 1)).to(tl.float32) # [BT] b_m = tl.max(b_s, 1) # [BT, BS] b_s = tl.exp(b_s - b_m[:, None]) b_z = tl.sum(b_s, 1) b_p = tl.where(b_s != 0, b_s / b_z[:, None], 0.) tl.store(p_p, b_p.to(p_p.dtype.element_ty), boundary_check=(0, 1)) @triton.autotune( configs=[ triton.Config({}, num_warps=2), triton.Config({}, num_warps=4), triton.Config({}, num_warps=8), ], key=['S'] ) @triton.jit def softmax_bwd_kernel( p, dp, ds, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr ): i_t, i_bh = tl.program_id(0), tl.program_id(1) p_p = tl.make_block_ptr(p + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) p_dp = tl.make_block_ptr(dp + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) p_ds = tl.make_block_ptr(ds + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, 0), (BT, S), (1, 0)) # [BT, BS] b_p = tl.load(p_p, boundary_check=(0, 1)).to(tl.float32) b_dp = tl.load(p_dp, boundary_check=(0, 1)).to(tl.float32) # [BT,] b_pp = tl.sum(b_p * b_dp, 1) # [BT, BS] b_ds = b_p * b_dp - b_p * b_pp[:, None] tl.store(p_ds, b_ds.to(p_ds.dtype.element_ty), boundary_check=(0, 1)) @triton.autotune( configs=[ triton.Config({'BT': 16}, num_warps=2), triton.Config({'BT': 16}, num_warps=4), triton.Config({'BT': 16}, num_warps=8), triton.Config({'BT': 32}, num_warps=2), triton.Config({'BT': 32}, num_warps=4), triton.Config({'BT': 32}, num_warps=8), triton.Config({'BT': 64}, num_warps=2), triton.Config({'BT': 64}, num_warps=4), triton.Config({'BT': 64}, num_warps=8), ], key=['S'] ) @triton.jit def chunk_global_reversed_cumsum_vector_kernel( s, z, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr ): i_s, i_bh = tl.program_id(0), tl.program_id(1) o_i = tl.arange(0, BT) m_s = tl.where(o_i[:, None] <= o_i[None, :], 1., 0.) b_z = tl.zeros([BS], dtype=tl.float32) for i_t in range(tl.cdiv(T, BT) - 1, -1, -1): p_s = tl.make_block_ptr(s + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) p_z = tl.make_block_ptr(z + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) # [BT, BS] b_s = tl.load(p_s, boundary_check=(0, 1)).to(tl.float32) b_c = b_z[None, :] + tl.dot(m_s, b_s, allow_tf32=False) tl.store(p_z, b_c.to(p_z.dtype.element_ty), boundary_check=(0, 1)) if i_t >= 0: b_z += tl.sum(b_s, 0) @triton.autotune( configs=[ triton.Config({'BT': 16}, num_warps=2), triton.Config({'BT': 16}, num_warps=4), triton.Config({'BT': 16}, num_warps=8), triton.Config({'BT': 32}, num_warps=2), triton.Config({'BT': 32}, num_warps=4), triton.Config({'BT': 32}, num_warps=8), triton.Config({'BT': 64}, num_warps=2), triton.Config({'BT': 64}, num_warps=4), triton.Config({'BT': 64}, num_warps=8), ], key=['S'] ) @triton.jit def chunk_global_cumsum_vector_kernel( s, z, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr ): i_s, i_bh = tl.program_id(0), tl.program_id(1) o_i = tl.arange(0, BT) m_s = tl.where(o_i[:, None] >= o_i[None, :], 1., 0.) b_z = tl.zeros([BS], dtype=tl.float32) for i_t in range(tl.cdiv(T, BT)): p_s = tl.make_block_ptr(s + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) p_z = tl.make_block_ptr(z + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) # [BT, BS] b_s = tl.load(p_s, boundary_check=(0, 1)).to(tl.float32) b_c = b_z[None, :] + tl.dot(m_s, b_s, allow_tf32=False) tl.store(p_z, b_c.to(p_z.dtype.element_ty), boundary_check=(0, 1)) if i_t >= 0: b_z += tl.sum(b_s, 0) @triton.autotune( configs=[ triton.Config({'BT': 16}, num_warps=2), triton.Config({'BT': 32}, num_warps=4), triton.Config({'BT': 32}, num_warps=2), triton.Config({'BT': 64}, num_warps=8), triton.Config({'BT': 64}, num_warps=4), ], key=[] ) @triton.jit def chunk_global_reversed_cumsum_scalar_kernel( s, o, T: tl.constexpr, BT: tl.constexpr, ): i_bh = tl.program_id(0) b_z = tl.zeros([], dtype=tl.float32) for i_t in range(tl.cdiv(T, BT) - 1, -1, -1): p_s = tl.make_block_ptr(s + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) p_o = tl.make_block_ptr(o + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) b_s = tl.load(p_s, boundary_check=(0,)).to(tl.float32) b_zz = tl.sum(b_s, axis=0) b_z += b_zz b_o = b_s - tl.cumsum(b_s, axis=0) + b_z[None] tl.store(p_o, b_o.to(p_o.dtype.element_ty), boundary_check=(0,)) @triton.autotune( configs=[ triton.Config({'BT': 16}, num_warps=2), triton.Config({'BT': 32}, num_warps=4), triton.Config({'BT': 32}, num_warps=2), triton.Config({'BT': 64}, num_warps=8), triton.Config({'BT': 64}, num_warps=4), ], key=[] ) @triton.jit def chunk_global_cumsum_scalar_kernel( s, o, T: tl.constexpr, BT: tl.constexpr, ): i_bh = tl.program_id(0) b_z = tl.zeros([], dtype=tl.float32) for i_t in range(tl.cdiv(T, BT)): p_s = tl.make_block_ptr(s + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) p_o = tl.make_block_ptr(o + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) b_s = tl.load(p_s, boundary_check=(0,)).to(tl.float32) b_o = tl.cumsum(b_s, axis=0) + b_z[None] b_zz = tl.sum(b_s, axis=0) b_z += b_zz tl.store(p_o, b_o.to(p_o.dtype.element_ty), boundary_check=(0,)) @triton.autotune( configs=[ triton.Config({'BS': 16}, num_warps=2), triton.Config({'BS': 16}, num_warps=4), triton.Config({'BS': 16}, num_warps=8), triton.Config({'BS': 32}, num_warps=2), triton.Config({'BS': 32}, num_warps=4), triton.Config({'BS': 32}, num_warps=8), triton.Config({'BS': 64}, num_warps=2), triton.Config({'BS': 64}, num_warps=4), triton.Config({'BS': 64}, num_warps=8), ], key=['S', 'BT'] ) @triton.jit def chunk_local_cumsum_vector_kernel( s, o, s_s_h, s_s_t, s_s_d, T: tl.constexpr, S: tl.constexpr, BT: tl.constexpr, BS: tl.constexpr ): i_s, i_t, i_bh = tl.program_id(0), tl.program_id(1), tl.program_id(2) o_i = tl.arange(0, BT) m_s = tl.where(o_i[:, None] >= o_i[None, :], 1., 0.) p_s = tl.make_block_ptr(s + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) p_o = tl.make_block_ptr(o + i_bh * s_s_h, (T, S), (s_s_t, s_s_d), (i_t * BT, i_s * BS), (BT, BS), (1, 0)) # [BT, BS] b_s = tl.load(p_s, boundary_check=(0, 1)).to(tl.float32) b_o = tl.dot(m_s, b_s, allow_tf32=False) tl.store(p_o, b_o.to(p_o.dtype.element_ty), boundary_check=(0, 1)) @triton.autotune( configs=[ triton.Config({}, num_warps=1), triton.Config({}, num_warps=2), triton.Config({}, num_warps=4), triton.Config({}, num_warps=8) ], key=['BT'] ) @triton.jit def chunk_local_cumsum_scalar_kernel( s, o, T: tl.constexpr, BT: tl.constexpr, ): i_t, i_bh = tl.program_id(0), tl.program_id(1) p_s = tl.make_block_ptr(s + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) p_o = tl.make_block_ptr(o + i_bh * T, (T,), (1,), (i_t * BT,), (BT,), (0,)) # [BT, BS] b_s = tl.load(p_s, boundary_check=(0,)).to(tl.float32) b_o = tl.cumsum(b_s, axis=0) tl.store(p_o, b_o.to(p_o.dtype.element_ty), boundary_check=(0,)) def chunk_local_cumsum_vector(g, BT): B, H, T, S = g.shape NT = triton.cdiv(T, BT) g_org, g = g, torch.empty_like(g, dtype=torch.float) def grid(meta): return (triton.cdiv(meta['S'], meta['BS']), NT, B * H) # keep cummulative normalizer in fp32 # this kernel is equivalent to # g = g.view(B, H, NT, BT, -1).cumsum(-2).view(B, H, T, -1) chunk_local_cumsum_vector_kernel[grid]( g_org, g, g.stride(1), g.stride(2), g.stride(3), T=T, S=S, BT=BT ) return g def chunk_local_cumsum_scalar(g, BT): B, H, T = g.shape NT = triton.cdiv(T, BT) g_org, g = g, torch.empty_like(g, dtype=torch.float) grid = (NT, B * H) chunk_local_cumsum_scalar_kernel[grid]( g_org, g, T=T, BT=BT ) return g @contiguous def chunk_local_cumsum(g, BT): if len(g.shape) == 3: return chunk_local_cumsum_scalar(g, BT) elif len(g.shape) == 4: return chunk_local_cumsum_vector(g, BT) else: raise ValueError( f"Unsupported shape {g.shape}. Should be either (batch size, num_heads, seq_len, dim) or (batch_size, num_heads, seq_len)" ) @contiguous def chunk_global_reversed_cumsum_vector( s: torch.Tensor, dtype: Optional[torch.dtype] = None, ) -> torch.Tensor: B, H, T, S = s.shape BS = 32 dtype = dtype or s.dtype grid = (triton.cdiv(S, BS), B * H) z = torch.empty_like(s, dtype=dtype) chunk_global_reversed_cumsum_vector_kernel[grid]( s, z, s.stride(1), s.stride(2), s.stride(3), T=T, S=S, BS=BS ) return z @contiguous def chunk_global_reversed_cumsum_scalar( s: torch.Tensor, dtype: Optional[torch.dtype] = None, ) -> torch.Tensor: B, H, T = s.shape dtype = dtype or s.dtype grid = (B * H,) z = torch.empty_like(s, dtype=dtype) chunk_global_reversed_cumsum_scalar_kernel[grid]( s, z, T=T ) return z @contiguous def chunk_global_cumsum_vector( s: torch.Tensor, dtype: Optional[torch.dtype] = None, ) -> torch.Tensor: B, H, T, S = s.shape BS = 32 dtype = dtype or s.dtype grid = (triton.cdiv(S, BS), B * H) z = torch.empty_like(s, dtype=dtype) chunk_global_cumsum_vector_kernel[grid]( s, z, s.stride(1), s.stride(2), s.stride(3), T=T, S=S, BS=BS ) return z @contiguous def chunk_global_cumsum_scalar( s: torch.Tensor, dtype: Optional[torch.dtype] = None, ) -> torch.Tensor: B, H, T = s.shape dtype = dtype or s.dtype grid = (B * H,) z = torch.empty_like(s, dtype=dtype) chunk_global_cumsum_scalar_kernel[grid]( s, z, T=T ) return z @contiguous def chunk_global_cumsum(s, dtype=None): if len(s.shape) == 3: return chunk_global_cumsum_scalar(s, dtype) elif len(s.shape) == 4: return chunk_global_cumsum_vector(s, dtype) else: raise ValueError(f"Unsupported shape {s.shape}. " f"Should be either [batch size, num_heads, seq_len] or [batch_size, num_heads, seq_len, dim]") @contiguous def chunk_global_reversed_cumsum(s, dtype=None): if len(s.shape) == 3: return chunk_global_reversed_cumsum_scalar(s, dtype) elif len(s.shape) == 4: return chunk_global_reversed_cumsum_vector(s, dtype) else: raise ValueError(f"Unsupported shape {s.shape}. " f"Should be either [batch size, num_heads, seq_len] or [batch_size, num_heads, seq_len, dim]")