# -*- coding: utf-8 -*- # Copyright (c) 2023, Tri Dao. # https://github.com/state-spaces/mamba/blob/fb7b5310fa865dbd62aa059b1e26f2b431363e2a/mamba_ssm/ops/triton/layernorm.py # Implement residual + layer_norm / rms_norm. # Based on the Triton LayerNorm tutorial: https://triton-lang.org/main/getting-started/tutorials/05-layer-norm.html # For the backward pass, we keep weight_grad and bias_grad in registers and accumulate. # This is faster for dimensions up to 8k, but after that it's much slower due to register spilling. # The models we train have hidden dim up to 8k anyway (e.g. Llama 70B), so this is fine. from __future__ import annotations from functools import partial import torch import torch.nn as nn import torch.nn.functional as F import triton import triton.language as tl from einops import rearrange from torch.distributed import DeviceMesh from torch.distributed.tensor import DTensor, Replicate, Shard, distribute_module from torch.distributed.tensor.parallel import ParallelStyle from fla.utils import get_multiprocessor_count, input_guard def layer_norm_ref( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, upcast: bool = False ): dtype = x.dtype if upcast: weight = weight.float() bias = bias.float() if bias is not None else None if upcast: x = x.float() residual = residual.float() if residual is not None else residual if residual is not None: x = (x + residual).to(x.dtype) out = F.layer_norm(x.to(weight.dtype), x.shape[-1:], weight=weight, bias=bias, eps=eps).to( dtype ) return out if not prenorm else (out, x) def rms_norm_ref( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, upcast: bool = False ): dtype = x.dtype if upcast: weight = weight.float() bias = bias.float() if bias is not None else None if upcast: x = x.float() residual = residual.float() if residual is not None else residual if residual is not None: x = (x + residual).to(x.dtype) rstd = 1 / torch.sqrt((x.square()).mean(dim=-1, keepdim=True) + eps) out = (x * rstd * weight) + bias if bias is not None else (x * rstd * weight) out = out.to(dtype) return out if not prenorm else (out, x) def group_norm_ref( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, num_groups: int, residual: torch.Tensor = None, eps: float = 1e-5, is_rms_norm: bool = False, prenorm: bool = False, upcast: bool = False ): dtype = x.dtype if upcast: weight = weight.float() bias = bias.float() if bias is not None else None if upcast: x = x.float() residual = residual.float() if residual is not None else residual if residual is not None: x = (x + residual).to(x.dtype) residual = x x, weight = [ rearrange(data, "... (g d) -> ... g d", g=num_groups) for data in (x, weight) ] if bias is not None: bias = rearrange(bias, '... (g d) -> ... g d', g=num_groups) if not is_rms_norm: mean = x.mean(dim=-1, keepdim=True) x = x - mean rstd = 1 / torch.sqrt((x.square()).mean(dim=-1, keepdim=True) + eps) out = (x * rstd * weight) + bias if bias is not None else (x * rstd * weight) out = rearrange(out, "... g d -> ... (g d)") out = out.to(dtype) return out if not prenorm else (out, residual) class GroupNormRef(nn.Module): def __init__( self, num_groups: int, hidden_size: int, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5, is_rms_norm: bool = False ) -> GroupNormRef: super().__init__() if hidden_size % num_groups != 0: raise ValueError('num_channels must be divisible by num_groups') self.num_groups = num_groups self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.is_rms_norm = is_rms_norm self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.num_groups}, {self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" if self.is_rms_norm: s += f", is_rms_norm={self.is_rms_norm}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, residual=None, prenorm=False): return group_norm_ref( x, self.weight, self.bias, num_groups=self.num_groups, residual=residual, eps=self.eps, is_rms_norm=self.is_rms_norm, prenorm=prenorm, upcast=True ) @triton.autotune( configs=[ triton.Config({}, num_warps=num_warps, num_stages=num_stages) for num_warps in [1, 2, 4, 8, 16, 32] for num_stages in [2, 3, 4] ], key=["N", "HAS_RESIDUAL", "STORE_RESIDUAL_OUT", "IS_RMS_NORM", "HAS_BIAS"], ) @triton.jit def layer_norm_fwd_kernel( X, # pointer to the input Y, # pointer to the output W, # pointer to the weights B, # pointer to the biases RESIDUAL, # pointer to the residual RESIDUAL_OUT, # pointer to the residual Mean, # pointer to the mean Rstd, # pointer to the 1/std N, # number of columns in X G, # number of groups eps, # epsilon to avoid division by zero IS_RMS_NORM: tl.constexpr, BLOCK_N: tl.constexpr, HAS_RESIDUAL: tl.constexpr, STORE_RESIDUAL_OUT: tl.constexpr, HAS_WEIGHT: tl.constexpr, HAS_BIAS: tl.constexpr ): # Map the program id to the row of X and Y it should compute. row = tl.program_id(0) group = row % G X += row * N Y += row * N if HAS_RESIDUAL: RESIDUAL += row * N if STORE_RESIDUAL_OUT: RESIDUAL_OUT += row * N # Compute mean and variance cols = tl.arange(0, BLOCK_N) x = tl.load(X + cols, mask=cols < N, other=0.0).to(tl.float32) if HAS_RESIDUAL: residual = tl.load(RESIDUAL + cols, mask=cols < N, other=0.0).to(tl.float32) x += residual if STORE_RESIDUAL_OUT: tl.store(RESIDUAL_OUT + cols, x, mask=cols < N) if not IS_RMS_NORM: mean = tl.sum(x, axis=0) / N tl.store(Mean + row, mean) xbar = tl.where(cols < N, x - mean, 0.0) var = tl.sum(xbar * xbar, axis=0) / N else: xbar = tl.where(cols < N, x, 0.0) var = tl.sum(xbar * xbar, axis=0) / N rstd = 1 / tl.sqrt(var + eps) tl.store(Rstd + row, rstd) # Normalize and apply linear transformation mask = cols < N if HAS_WEIGHT: w = tl.load(W + group * N + cols, mask=mask).to(tl.float32) if HAS_BIAS: b = tl.load(B + group * N + cols, mask=mask).to(tl.float32) x_hat = (x - mean) * rstd if not IS_RMS_NORM else x * rstd y = tl.fma(x_hat, w, b) if HAS_WEIGHT and HAS_BIAS else \ x_hat * w if HAS_WEIGHT else \ x_hat + b if HAS_BIAS else x_hat # Write output y = tl.cast(y, dtype=Y.dtype.element_ty, fp_downcast_rounding="rtne") tl.store(Y + cols, y, mask=mask) def layer_norm_fwd( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, eps: float, residual: torch.Tensor = None, out_dtype: torch.dtype = None, residual_dtype: torch.dtype = None, is_rms_norm: bool = False, num_groups: int = 1 ): if residual is not None: residual_dtype = residual.dtype M, N, G = *x.shape, num_groups if residual is not None: assert residual.shape == (M, N) if weight is not None: assert weight.shape == (G * N,) if bias is not None: assert bias.shape == (G * N,) # allocate output y = torch.empty_like(x, dtype=x.dtype if out_dtype is None else out_dtype) if residual is not None or (residual_dtype is not None and residual_dtype != x.dtype): residual_out = torch.empty(M, N, device=x.device, dtype=residual_dtype) else: residual_out = None mean = torch.empty((M,), dtype=torch.float32, device=x.device) if not is_rms_norm else None rstd = torch.empty((M,), dtype=torch.float32, device=x.device) # Less than 64KB per feature: enqueue fused kernel MAX_FUSED_SIZE = 65536 // x.element_size() BLOCK_N = min(MAX_FUSED_SIZE, triton.next_power_of_2(N)) if N > BLOCK_N: raise RuntimeError("This layer norm doesn't support feature dim >= 64KB.") # heuristics for number of warps layer_norm_fwd_kernel[(M,)]( x, y, weight, bias, residual, residual_out, mean, rstd, N, G, eps, is_rms_norm, BLOCK_N, residual is not None, residual_out is not None, weight is not None, bias is not None, ) # residual_out is None if residual is None and residual_dtype == input_dtype return y, mean, rstd, residual_out if residual_out is not None else x @triton.heuristics({ "RECOMPUTE_OUTPUT": lambda args: args["Y"] is not None }) @triton.autotune( configs=[ triton.Config({}, num_warps=num_warps, num_stages=num_stages) for num_warps in [1, 2, 4, 8, 16, 32] for num_stages in [2, 3, 4] ], key=["N", "HAS_DRESIDUAL", "STORE_DRESIDUAL", "IS_RMS_NORM", "HAS_BIAS"], ) @triton.jit def layer_norm_bwd_kernel( X, # pointer to the input W, # pointer to the weights B, # pointer to the biases Y, # pointer to the output to be recomputed DY, # pointer to the output gradient DX, # pointer to the input gradient DW, # pointer to the partial sum of weights gradient DB, # pointer to the partial sum of biases gradient DRESIDUAL, DRESIDUAL_IN, Mean, # pointer to the mean Rstd, # pointer to the 1/std M, # number of rows in X N, # number of columns in X G, # number of groups rows_per_program, programs_per_group, IS_RMS_NORM: tl.constexpr, BLOCK_N: tl.constexpr, HAS_DRESIDUAL: tl.constexpr, STORE_DRESIDUAL: tl.constexpr, HAS_WEIGHT: tl.constexpr, HAS_BIAS: tl.constexpr, RECOMPUTE_OUTPUT: tl.constexpr, ): row_block_id = tl.program_id(0) group_id, program_id_in_group = row_block_id // programs_per_group, row_block_id % programs_per_group row_start = group_id + program_id_in_group * G * rows_per_program row_end = min(row_start + G * rows_per_program, M) cols = tl.arange(0, BLOCK_N) mask = cols < N if HAS_WEIGHT: w = tl.load(W + group_id * N + cols, mask=mask).to(tl.float32) dw = tl.zeros((BLOCK_N,), dtype=tl.float32) if RECOMPUTE_OUTPUT and HAS_BIAS: b = tl.load(B + group_id * N + cols, mask=mask, other=0.0).to(tl.float32) if HAS_BIAS: db = tl.zeros((BLOCK_N,), dtype=tl.float32) for row in range(row_start, row_end, G): # Load data to SRAM x = tl.load(X + row * N + cols, mask=mask, other=0).to(tl.float32) dy = tl.load(DY + row * N + cols, mask=mask, other=0).to(tl.float32) if not IS_RMS_NORM: mean = tl.load(Mean + row) rstd = tl.load(Rstd + row) # Compute dx xhat = (x - mean) * rstd if not IS_RMS_NORM else x * rstd xhat = tl.where(mask, xhat, 0.0) if RECOMPUTE_OUTPUT: y = xhat * w if HAS_WEIGHT else xhat if HAS_BIAS: y = y + b tl.store(Y + row * N + cols, y, mask=mask) wdy = dy if HAS_WEIGHT: wdy = dy * w dw += dy * xhat if HAS_BIAS: db += dy if not IS_RMS_NORM: c1 = tl.sum(xhat * wdy, axis=0) / N c2 = tl.sum(wdy, axis=0) / N dx = (wdy - (xhat * c1 + c2)) * rstd else: c1 = tl.sum(xhat * wdy, axis=0) / N dx = (wdy - xhat * c1) * rstd if HAS_DRESIDUAL: dres = tl.load(DRESIDUAL + row * N + cols, mask=mask, other=0).to(tl.float32) dx += dres # Write dx dx = tl.cast(dx, dtype=DX.dtype.element_ty, fp_downcast_rounding="rtne") if STORE_DRESIDUAL: tl.store(DRESIDUAL_IN + row * N + cols, dx, mask=mask) tl.store(DX + row * N + cols, dx, mask=mask) if HAS_WEIGHT: tl.store(DW + row_block_id * N + cols, dw, mask=mask) if HAS_BIAS: tl.store(DB + row_block_id * N + cols, db, mask=mask) def layer_norm_bwd( dy: torch.Tensor, x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, eps: float, mean: torch.Tensor, rstd: torch.Tensor, dresidual: torch.Tensor = None, has_residual: bool = False, is_rms_norm: bool = False, x_dtype: torch.dtype = None, recompute_output: bool = False, num_groups: int = 1 ): M, N, G = *x.shape, num_groups assert dy.shape == (M, N) if dresidual is not None: assert dresidual.shape == (M, N) if weight is not None: assert weight.shape == (G * N,) if bias is not None: assert bias.shape == (G * N,) # allocate output dx = torch.empty_like(x) if x_dtype is None else torch.empty(M, N, dtype=x_dtype, device=x.device) dresidual_in = torch.empty_like(x) if has_residual and dx.dtype != x.dtype else None y = torch.empty(M, N, dtype=dy.dtype, device=dy.device) if recompute_output else None # Less than 64KB per feature: enqueue fused kernel MAX_FUSED_SIZE = 65536 // x.element_size() BLOCK_N = min(MAX_FUSED_SIZE, triton.next_power_of_2(N)) if N > BLOCK_N: raise RuntimeError("This layer norm doesn't support feature dim >= 64KB.") # each program handles one group only S = triton.cdiv(get_multiprocessor_count(x.device.index), G) * G dw = torch.empty((S, N), dtype=torch.float32, device=weight.device) if weight is not None else None db = torch.empty((S, N), dtype=torch.float32, device=bias.device) if bias is not None else None rows_per_program = triton.cdiv(M, S) programs_per_group = S // G grid = (S,) layer_norm_bwd_kernel[grid]( x, weight, bias, y, dy, dx, dw, db, dresidual, dresidual_in, mean, rstd, M, N, G, rows_per_program, programs_per_group, is_rms_norm, BLOCK_N, dresidual is not None, dresidual_in is not None, weight is not None, bias is not None, ) dw = dw.view(G, -1, N).sum(1).to(weight).view_as(weight) if weight is not None else None db = db.view(G, -1, N).sum(1).to(bias).view_as(bias) if bias is not None else None # Don't need to compute dresidual_in separately in this case if has_residual and dx.dtype == x.dtype: dresidual_in = dx return (dx, dw, db, dresidual_in) if not recompute_output else (dx, dw, db, dresidual_in, y) class LayerNormFunction(torch.autograd.Function): @staticmethod @input_guard def forward( ctx, x, weight, bias, residual=None, eps=1e-5, prenorm=False, residual_in_fp32=False, is_rms_norm=False, num_groups=1 ): x_shape_og = x.shape if x.shape[-1] % num_groups != 0: raise ValueError('num_channels must be divisible by num_groups') # reshape input data into 2D tensor x = x.reshape(-1, (x.shape[-1] // num_groups)) if residual is not None: assert residual.shape == x_shape_og residual = residual.reshape_as(x) residual_dtype = ( residual.dtype if residual is not None else (torch.float32 if residual_in_fp32 else None) ) y, mean, rstd, residual_out = layer_norm_fwd( x, weight, bias, eps, residual, residual_dtype=residual_dtype, is_rms_norm=is_rms_norm, num_groups=num_groups ) ctx.save_for_backward(residual_out, weight, bias, mean, rstd) ctx.x_shape_og = x_shape_og ctx.eps = eps ctx.is_rms_norm = is_rms_norm ctx.num_groups = num_groups ctx.has_residual = residual is not None ctx.prenorm = prenorm ctx.x_dtype = x.dtype y = y.reshape(x_shape_og) return y if not prenorm else (y, residual_out.reshape(x_shape_og)) @staticmethod @input_guard def backward(ctx, dy, *args): x, weight, bias, mean, rstd = ctx.saved_tensors dy = dy.reshape(-1, (dy.shape[-1] // ctx.num_groups)) assert dy.shape == x.shape if ctx.prenorm: dresidual = args[0] dresidual = dresidual.reshape(-1, x.shape[-1]) assert dresidual.shape == x.shape else: dresidual = None dx, dw, db, dresidual_in = layer_norm_bwd( dy, x, weight, bias, ctx.eps, mean, rstd, dresidual, ctx.has_residual, ctx.is_rms_norm, x_dtype=ctx.x_dtype, num_groups=ctx.num_groups ) return ( dx.reshape(ctx.x_shape_og), dw, db, dresidual_in.reshape(ctx.x_shape_og) if ctx.has_residual else None, None, None, None, None, None ) def layer_norm( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False, is_rms_norm: bool = False ): return LayerNormFunction.apply( x, weight, bias, residual, eps, prenorm, residual_in_fp32, is_rms_norm ) def group_norm( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False, is_rms_norm: bool = False, num_groups: int = 1 ): return LayerNormFunction.apply( x, weight, bias, residual, eps, prenorm, residual_in_fp32, is_rms_norm, num_groups ) def rms_norm( x: torch.Tensor, weight: torch.Tensor, bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False ): return LayerNormFunction.apply( x, weight, bias, residual, eps, prenorm, residual_in_fp32, True ) def layer_norm_linear( x: torch.Tensor, norm_weight: torch.Tensor, norm_bias: torch.Tensor, linear_weight: torch.Tensor, linear_bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False, is_rms_norm: bool = False, num_groups: int = 1 ): return LayerNormLinearFunction.apply( x, norm_weight, norm_bias, linear_weight, linear_bias, residual, eps, prenorm, residual_in_fp32, is_rms_norm, num_groups ) def rms_norm_linear( x: torch.Tensor, norm_weight: torch.Tensor, norm_bias: torch.Tensor, linear_weight: torch.Tensor, linear_bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False ): return layer_norm_linear( x=x, norm_weight=norm_weight, norm_bias=norm_bias, linear_weight=linear_weight, linear_bias=linear_bias, residual=residual, eps=eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=True ) def group_norm_linear( x: torch.Tensor, norm_weight: torch.Tensor, norm_bias: torch.Tensor, linear_weight: torch.Tensor, linear_bias: torch.Tensor, residual: torch.Tensor = None, eps: float = 1e-5, prenorm: bool = False, residual_in_fp32: bool = False, is_rms_norm: bool = False, num_groups: int = 1 ): return layer_norm_linear( x=x, norm_weight=norm_weight, norm_bias=norm_bias, linear_weight=linear_weight, linear_bias=linear_bias, residual=residual, eps=eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=is_rms_norm, num_groups=num_groups ) class LayerNorm(nn.Module): def __init__( self, hidden_size: int, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5 ) -> LayerNorm: super().__init__() self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, residual=None, prenorm=False, residual_in_fp32=False): return layer_norm( x, self.weight, self.bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32 ) class GroupNorm(nn.Module): def __init__( self, num_groups: int, hidden_size: int, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5, is_rms_norm: bool = False ) -> GroupNorm: super().__init__() if hidden_size % num_groups != 0: raise ValueError('num_channels must be divisible by num_groups') self.num_groups = num_groups self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.is_rms_norm = is_rms_norm self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.num_groups}, {self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" if self.is_rms_norm: s += f", is_rms_norm={self.is_rms_norm}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, residual=None, prenorm=False, residual_in_fp32=False): return group_norm( x, self.weight, self.bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=self.is_rms_norm, num_groups=self.num_groups ) class RMSNorm(nn.Module): def __init__( self, hidden_size: int, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5 ) -> RMSNorm: super().__init__() self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, residual=None, prenorm=False, residual_in_fp32=False): return rms_norm( x, self.weight, self.bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, ) class LayerNormLinearFunction(torch.autograd.Function): @staticmethod @input_guard def forward( ctx, x, norm_weight, norm_bias, linear_weight, linear_bias, residual=None, eps=1e-5, prenorm=False, residual_in_fp32=False, is_rms_norm=False, num_groups=1 ): x_shape_og = x.shape if x.shape[-1] % num_groups != 0: raise ValueError('num_channels must be divisible by num_groups') # reshape input data into 2D tensor x = x.reshape(-1, (x.shape[-1] // num_groups)) if residual is not None: assert residual.shape == x_shape_og residual = residual.reshape_as(x) residual_dtype = ( residual.dtype if residual is not None else (torch.float32 if residual_in_fp32 else None) ) y, mean, rstd, residual_out = layer_norm_fwd( x, norm_weight, norm_bias, eps, residual, out_dtype=None if not torch.is_autocast_enabled() else torch.get_autocast_gpu_dtype(), residual_dtype=residual_dtype, is_rms_norm=is_rms_norm, num_groups=num_groups ) y = y.reshape(x_shape_og) dtype = torch.get_autocast_gpu_dtype() if torch.is_autocast_enabled() else y.dtype linear_weight = linear_weight.to(dtype) linear_bias = linear_bias.to(dtype) if linear_bias is not None else None out = F.linear(y.to(linear_weight.dtype), linear_weight, linear_bias) # We don't store y, will be recomputed in the backward pass to save memory ctx.save_for_backward(residual_out, norm_weight, norm_bias, linear_weight, mean, rstd) ctx.x_shape_og = x_shape_og ctx.eps = eps ctx.is_rms_norm = is_rms_norm ctx.num_groups = num_groups ctx.has_residual = residual is not None ctx.prenorm = prenorm ctx.x_dtype = x.dtype ctx.linear_bias_is_none = linear_bias is None return out if not prenorm else (out, residual_out.reshape(x_shape_og)) @staticmethod @input_guard def backward(ctx, dout, *args): x, norm_weight, norm_bias, linear_weight, mean, rstd = ctx.saved_tensors dout = dout.reshape(-1, dout.shape[-1]) dy = F.linear(dout, linear_weight.t()) dy = dy.reshape(-1, (dy.shape[-1] // ctx.num_groups)) dlinear_bias = None if ctx.linear_bias_is_none else dout.sum(0) assert dy.shape == x.shape if ctx.prenorm: dresidual = args[0] dresidual = dresidual.reshape(-1, x.shape[-1]) assert dresidual.shape == x.shape else: dresidual = None dx, dnorm_weight, dnorm_bias, dresidual_in, y = layer_norm_bwd( dy, x, norm_weight, norm_bias, ctx.eps, mean, rstd, dresidual, ctx.has_residual, ctx.is_rms_norm, x_dtype=ctx.x_dtype, recompute_output=True, num_groups=ctx.num_groups ) dlinear_weight = torch.einsum("bo,bi->oi", dout, y.view(-1, linear_weight.shape[-1])) return ( dx.reshape(ctx.x_shape_og), dnorm_weight, dnorm_bias, dlinear_weight, dlinear_bias, dresidual_in.reshape(ctx.x_shape_og) if ctx.has_residual else None, None, None, None, None, None ) class LayerNormLinear(nn.Module): def __init__( self, hidden_size, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5 ) -> LayerNormLinear: super().__init__() self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, weight, bias, residual=None, prenorm=False, residual_in_fp32=False): return layer_norm_linear( x=x, norm_weight=self.weight, norm_bias=self.bias, linear_weight=weight, linear_bias=bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=False ) class GroupNormLinear(nn.Module): def __init__( self, num_groups: int, hidden_size: int, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5, is_rms_norm: bool = False ) -> GroupNormLinear: super().__init__() if hidden_size % num_groups != 0: raise ValueError('num_channels must be divisible by num_groups') self.num_groups = num_groups self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.is_rms_norm = is_rms_norm self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.num_groups}, {self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" if self.is_rms_norm: s += f", is_rms_norm={self.is_rms_norm}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, weight, bias, residual=None, prenorm=False, residual_in_fp32=False): return layer_norm_linear( x=x, norm_weight=self.weight, norm_bias=self.bias, linear_weight=weight, linear_bias=bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=self.is_rms_norm, num_groups=self.num_groups ) class RMSNormLinear(nn.Module): def __init__( self, hidden_size, elementwise_affine: bool = True, bias: bool = False, eps: float = 1e-5 ) -> RMSNormLinear: super().__init__() self.hidden_size = hidden_size self.elementwise_affine = elementwise_affine self.eps = eps self.register_parameter("weight", None) self.register_parameter("bias", None) if elementwise_affine: self.weight = nn.Parameter(torch.empty(hidden_size)) if bias: self.bias = nn.Parameter(torch.empty(hidden_size)) self.reset_parameters() def reset_parameters(self): if self.elementwise_affine: nn.init.ones_(self.weight) if self.bias is not None: nn.init.zeros_(self.bias) def __repr__(self) -> str: s = f"{self.__class__.__name__}({self.hidden_size}" if not self.elementwise_affine: s += f", elementwise_affine={self.elementwise_affine}" s += f", eps={self.eps}" s += ")" return s def forward(self, x, weight, bias, residual=None, prenorm=False, residual_in_fp32=False): return layer_norm_linear( x=x, norm_weight=self.weight, norm_bias=self.bias, linear_weight=weight, linear_bias=bias, residual=residual, eps=self.eps, prenorm=prenorm, residual_in_fp32=residual_in_fp32, is_rms_norm=True ) class NormParallel(ParallelStyle): def __init__(self, *, sequence_dim: int = 1, use_local_output: bool = False): super().__init__() self.sequence_sharding = (Shard(sequence_dim),) self.use_local_output = use_local_output def _replicate_module_fn( self, name: str, module: nn.Module, device_mesh: DeviceMesh ): for p_name, param in module.named_parameters(): # simple replication with fixed ones_ init from LayerNorm/RMSNorm, which allow # us to simply just use from_local replicated_param = torch.nn.Parameter( DTensor.from_local(param, device_mesh, [Replicate()], run_check=False) ) module.register_parameter(p_name, replicated_param) @staticmethod def _prepare_input_fn(sequence_sharding, mod, inputs, device_mesh): input_tensor = inputs[0] if isinstance(input_tensor, DTensor): # if the passed in input DTensor is not sharded on the sequence dim, we need to redistribute it if input_tensor.placements != sequence_sharding: input_tensor = input_tensor.redistribute( placements=sequence_sharding, async_op=True ) return input_tensor elif isinstance(input_tensor, torch.Tensor): # assume the input passed in already sharded on the sequence dim and create the DTensor return DTensor.from_local( input_tensor, device_mesh, sequence_sharding, run_check=False ) else: raise ValueError( f"expecting input of {mod} to be a torch.Tensor or DTensor, but got {input_tensor}" ) @staticmethod def _prepare_output_fn(use_local_output, mod, outputs, device_mesh): return outputs.to_local() if use_local_output else outputs def _apply(self, module: nn.Module, device_mesh: DeviceMesh) -> nn.Module: return distribute_module( module, device_mesh, self._replicate_module_fn, partial(self._prepare_input_fn, self.sequence_sharding), partial(self._prepare_output_fn, self.use_local_output), )