from dataclasses import dataclass import torch import math import bitsandbytes as bnb import bitsandbytes.functional as F tensor = torch.Tensor """ This class pools outlier dimensions across layers. This is particularly important for small models where outlier features are less systematic and occur with low frequency. """ class GlobalOutlierPooler(object): _instance = None def __init__(self): raise RuntimeError("Call get_instance() instead") def initialize(self): self.outliers = set() self.model_dim = None @classmethod def get_instance(cls): if cls._instance is None: cls._instance = cls.__new__(cls) cls._instance.initialize() return cls._instance def add_outliers(self, outlier_idx, feature_dim): if self.model_dim is None: self.model_dim = feature_dim if feature_dim != self.model_dim: return # we do not encode outliers for the 2nd FFN layer self.outliers.update(outlier_idx.tolist()) def get_current_outlier_idx(self): return torch.Tensor(list(self.outliers)).to(torch.int64) class MatMul8bit(torch.autograd.Function): @staticmethod def forward(ctx, A, B, out=None, quant_type="vector", precision=[8, 8, 8]): if precision[0] != 8: with torch.no_grad(): output = torch.matmul(A, B) else: if len(B.shape) == 2: dim = 0 else: dim = 1 qA, SA = F.vectorwise_quant(A, dim=-1, quant_type=quant_type) qB, SB = F.vectorwise_quant(B, dim=dim, quant_type=quant_type) iout = F.igemm(qA, qB) output = F.vectorwise_mm_dequant(iout, SA, SB, A.dtype, quant_type) if A.requires_grad or B.requires_grad: ctx.save_for_backward(A, B) ctx.quant_type = quant_type ctx.precision = precision return output @staticmethod def backward(ctx, grad_output): A, B = ctx.saved_tensors quant_type = ctx.quant_type precision = ctx.precision grad_A = grad_B = None if B.requires_grad: if len(A.shape) == 3: dims = [0, 1] # bsi -> ibs permute_dim = [0, 2, 1] else: dims = [0] # bs -> sb permute_dim = [1, 0] if precision[1] != 8: with torch.no_grad(): grad_B = torch.matmul(A.permute(permute_dim), grad_output) else: if len(B.shape) == 2 and len(A.shape) == 3: grad_output = grad_output.contiguous() if not grad_output.is_contiguous(): grad_output.contiguous() qgrad_output, S1 = F.vectorwise_quant( grad_output.view(-1, grad_output.shape[2]), dim=0, quant_type=quant_type, ) if not A.is_contiguous(): A = A.contiguous() qA, S2 = F.vectorwise_quant( A.view(-1, A.shape[2]), dim=0, quant_type=quant_type ) igrad_B = F.igemm(qA.t(), qgrad_output) grad_B = F.vectorwise_mm_dequant( igrad_B, S2.t(), S1, grad_output.dtype, quant_type ) else: qgrad_output, S1 = F.vectorwise_quant( grad_output, dim=dims, quant_type=quant_type ) qA, S2 = F.vectorwise_quant( A, dim=dims, quant_type=quant_type ) igrad_B = F.igemm(qA.permute(permute_dim), qgrad_output) grad_B = F.vectorwise_mm_dequant( igrad_B, S2.permute(permute_dim), S1, grad_output.dtype, quant_type, ) if A.requires_grad: if len(grad_output.shape) == 3: dims = [2] else: dims = [1] if len(B.shape) == 3: # bio -> boi permute_dim = [0, 2, 1] dim_B = dims else: # io -> oi permute_dim = [1, 0] dim_B = [1] if precision[2] != 8: with torch.no_grad(): grad_A = torch.matmul(grad_output, B.permute(permute_dim)) else: qgrad_output, S1 = F.vectorwise_quant( grad_output, dim=dims, quant_type=quant_type ) qB, S3 = F.vectorwise_quant(B, dim=dim_B, quant_type=quant_type) igrad_A = F.igemm(qgrad_output, qB.permute(permute_dim)) grad_A = F.vectorwise_mm_dequant( igrad_A, S1, S3.permute(permute_dim), grad_output.dtype, quant_type, ) return grad_A, grad_B, None, None, None mm_cublas = MatMul8bit.apply bmm_cublas = MatMul8bit.apply matmul_cublas = MatMul8bit.apply @dataclass class MatmulLtState: CB = None CxB = None SB = None SCB = None CxBt = None SBt = None CBt = None subB = None outlier_pool = None has_accumulated_gradients = False threshold = 0.0 idx = None is_training = True has_fp16_weights = True use_pool = False formatB = F.get_special_format_str() def reset_grads(self): self.CB = None self.CxB = None self.SB = None self.SCB = None self.CxBt = None self.SBt = None self.CBt = None class MatMul8bitLt(torch.autograd.Function): @staticmethod def forward(ctx, A, B, out=None, state=MatmulLtState()): # default to pytorch behavior if inputs are empty ctx.is_empty = False if math.prod(A.shape) == 0: ctx.is_empty = True ctx.A = A ctx.B = B if A.shape[-1] == B.shape[0]: return torch.empty(A.shape[:-1]+B.shape[1:], dtype=torch.float16, device=A.device) else: return torch.empty(A.shape[:-1]+B.shape[:1], dtype=torch.float16, device=A.device) # 1. Quantize A # 2. Quantize B # 3. Matmul # 4. Mixed-precision decomposition matmul # 5. Save state requires_gradA = A.requires_grad requires_gradB = B.requires_grad formatB = state.formatB input_shape = A.shape if state.outlier_pool is None: state.outlier_pool = GlobalOutlierPooler.get_instance() assert ( A.dtype == torch.float16 ), f"The input data type needs to be fp16 but {A.dtype} was found!" # 1. Quantize A if len(A.shape) == 3: A = A.view(-1, A.shape[-1]).contiguous() CA, CAt, SCA, SCAt, coo_tensorA = F.double_quant( A, threshold=state.threshold ) if state.threshold > 0.0 and coo_tensorA is not None: if state.has_fp16_weights: idx = torch.unique(coo_tensorA.colidx).long() CA[:, idx] = 0 CAt[:, idx] = 0 subA = A[:, idx] state.subB = B[:, idx].t().contiguous() state.idx = idx else: if state.CxB is None: # B in in 8-bit row-major, we can transform it back to 16-bit to extract outlier dimensions # we also need to convert it to the turing/ampere format state.CxB, state.SB = F.transform( state.CB, to_order=formatB ) # state.B = (state.CB.float()*(state.SCB.view(-1, 1)/127)).half() # if state.threshold > 0.0 and coo_tensorA is not None and state.idx is None and state.CB is not None: # # generate outlier index and subB # outlier_idx = torch.unique(coo_tensorA.colidx).long() # state.outlier_pool.add_outliers(outlier_idx, A.shape[-1]) # if state.use_pool and state.outlier_pool.model_dim == A.shape[-1]: # # do not use pool for 2nd FFN layer # state.idx = state.outlier_pool.get_current_outlier_idx().to(A.device) # else: # state.idx = outlier_idx # state.subB = (state.CB[:, state.idx].float().t().contiguous()*(state.SCB/127)).half() # if state.idx is not None: # # extract outliers # CA[:, state.idx] = 0 # CAt[:, state.idx] = 0 # subA = A[:, state.idx] # else: # subA = None else: if not state.has_fp16_weights and state.CxB is None: state.CxB, state.SB = F.transform(state.CB, to_order=formatB) subA = None # 2. Quantize B if state.has_fp16_weights: has_grad = True if (getattr(B, "grad", None) is not None) else False is_transposed = not B.is_contiguous() and B.shape[0] == B.stride(1) if is_transposed: B = B.contiguous() if (state.is_training and not has_grad) or state.CxB is None: state.reset_grads() ( CB, state.CBt, state.SCB, state.SCBt, coo_tensorB, ) = F.double_quant(B) state.CxB, state.SB = F.transform(CB, to_order=formatB) else: has_grad = False if coo_tensorA is not None and not state.has_fp16_weights: # extract outliers outlier_idx = torch.unique(coo_tensorA.colidx) state.idx = outlier_idx # state.outlier_pool.add_outliers(outlier_idx, A.shape[-1]) # if state.use_pool and state.outlier_pool.model_dim == A.shape[-1]: # # do not use pool for 2nd FFN layer # state.idx = state.outlier_pool.get_current_outlier_idx().to(A.device) # else: # state.idx = outlier_idx outliers = F.extract_outliers(state.CxB, state.SB, state.idx.int()) state.subB = ( (outliers * state.SCB.view(-1, 1) / 127.0) .t() .contiguous() .half() ) CA[:, state.idx.long()] = 0 CAt[:, state.idx.long()] = 0 subA = A[:, state.idx.long()] shapeB = state.SB[0] if len(input_shape) == 3: output_shape = (input_shape[0], input_shape[1], shapeB[0]) else: output_shape = (input_shape[0], shapeB[0]) # 3. Matmul C32A, SA = F.transform(CA, "col32") out32, Sout32 = F.igemmlt(C32A, state.CxB, SA, state.SB) output = F.mm_dequant(out32, Sout32, SCA, state.SCB) # 4. Mixed-precision decomposition matmul if coo_tensorA is not None and subA is not None: output += torch.matmul(subA, state.subB) # 5. Save state ctx.state = state ctx.formatB = formatB ctx.grad_shape = input_shape ctx.req_grads = [requires_gradA, requires_gradB] if requires_gradA or requires_gradB: ctx.tensors = (CAt, subA) ctx.tensor_states = (SCAt, state.idx) else: ctx.tensors = [None, None] ctx.tensor_states = (None, None) ctx.save_for_backward(None, None) # clone_func = torch.clone if len(output_shape) == 3 else lambda x : x clone_func = torch.clone return clone_func(output.view(output_shape)) @staticmethod def backward(ctx, grad_output): if ctx.is_empty: return torch.zeros_like(ctx.A), torch.zeros_like(ctx.B), None, None req_gradA, req_gradB = ctx.req_grads CAt, subA = ctx.tensors SCAt, idx = ctx.tensor_states formatB = ctx.formatB state = ctx.state assert ( state.has_fp16_weights ), "Backprop only supported for fp16 weights." if len(grad_output.shape) == 3: grad_output = grad_output.view( -1, grad_output.shape[-1] ).contiguous() grad_A = grad_B = None Cgrad, Cgradt, SCgrad, SCgradt, coo_tensor = F.double_quant(grad_output) if req_gradB: CxAt, SAt = F.transform(CAt, formatB, transpose=True) C32grad, Sgrad = F.transform(Cgradt, "col32", transpose=True) gradB32, SgradB32 = F.igemmlt(C32grad, CxAt, Sgrad, SAt) grad_B = F.mm_dequant(gradB32, SgradB32, SCgradt, SCAt) if state.threshold > 0.0 and subA is not None: grad_B[:, idx] += torch.matmul(grad_output.t(), subA) if req_gradA: C32grad, Sgrad = F.transform(Cgrad, "col32") if state.CxBt is None: state.CxBt, state.SBt = F.transform( state.CBt, to_order=formatB, transpose=True ) gradA32, SgradA32 = F.igemmlt(C32grad, state.CxBt, Sgrad, state.SBt) grad_A = F.mm_dequant(gradA32, SgradA32, SCgrad, state.SCBt).view( ctx.grad_shape ) return grad_A, grad_B, None, None matmul = MatMul8bitLt.apply def matmul( A: tensor, B: tensor, out: tensor = None, state: MatmulLtState = None, threshold=0.0, ): state = state or MatmulLtState() if threshold > 0.0: state.threshold = threshold return MatMul8bitLt.apply(A, B, out, state)