from itertools import product import pytest import torch from torch import nn import bitsandbytes as bnb class MockArgs: def __init__(self, initial_data): for key in initial_data: setattr(self, key, initial_data[key]) class MLP8bit(torch.nn.Module): def __init__(self, dim1, dim2, has_fp16_weights=True, memory_efficient_backward=False, threshold=0.0): super().__init__() self.fc1 = bnb.nn.Linear8bitLt( dim1, dim2, has_fp16_weights=has_fp16_weights, memory_efficient_backward=memory_efficient_backward, threshold=threshold ) self.fc2 = bnb.nn.Linear8bitLt( dim2, dim1, has_fp16_weights=has_fp16_weights, memory_efficient_backward=memory_efficient_backward, threshold=threshold ) def forward(self, x): x = self.fc1(x) x = self.fc2(x) return x def get_args(): args = MockArgs([]) args.quant_type = "vector" args.use_8bit_training = "full" args.clip_freq = 9999 return args def assert_all_approx_close(a, b, atol=1e-8, rtol=1e-5, count=10): idx = torch.isclose(a, b, rtol, atol) sumval = (idx == 0).sum().item() if sumval > count: print(f"Too many values not close: assert {sumval} < {count}") torch.testing.assert_close(a, b, rtol, atol) class LinearFunction(torch.autograd.Function): @staticmethod def get_8bit_linear_trimmed(x, stochastic=False, trim_value=3.0): round_func = ( LinearFunction.round_stoachastic if stochastic else torch.round ) norm = math.sqrt(math.pi) / math.sqrt(2.0) # std = torch.abs(x).mean()*norm std = torch.std(x) max1 = std * trim_value x = x / max1 * 127 x = round_func(x) x[x > 127] = 127 x[x < -127] = -127 x = x / 127 * max1 return x def quant(x, quant_type, dim=1): if quant_type == "linear": max1 = torch.abs(x).max().float() xq = torch.round(x / max1 * 127).to(torch.int8) return xq, max1 elif quant_type == "vector": max1 = torch.amax(torch.abs(x), dim=dim, keepdim=True) xq = torch.round(x / max1 * 127).to(torch.int8) return xq, max1 elif quant_type == "min-max": maxA = torch.amax(x, dim=dim, keepdim=True).float() minA = torch.amin(x, dim=dim, keepdim=True).float() scale = (maxA - minA) / 2.0 xq = torch.round(127 * (x - minA - scale) / scale).to(torch.int8) return xq, (minA.float(), scale.float()) else: return None def dequant(xq, S1, S2, dtype, quant_type): if quant_type == "linear": norm = S1 * S2 / (127 * 127) # double cast needed to prevent overflows return (xq.float() * norm).to(dtype) elif quant_type == "vector": x = xq.float() if len(xq.shape) == 2 and len(S1.shape) == 3: S1 = S1.squeeze(0) if len(xq.shape) == 2 and len(S2.shape) == 3: S2 = S2.squeeze(0) # print(x.shape, S1.shape, S2.shape) if len(S1.shape) == 2: x *= S1.t() / 127 else: x *= S1 / 127 x *= S2 / 127 return x.to(dtype) else: return None def dequant_min_max(xq, A, B, SA, SB, dtype): offset = B.float().t().sum(0) * (SA[0] + SA[1]) x = xq.float() if len(xq.shape) == 2 and len(SB.shape) == 3: SB = SB.squeeze(0) if len(xq.shape) == 2 and len(SA.shape) == 3: SA = SA.squeeze(0) if len(SB.shape) == 2: x *= SB.t() / 127 else: x *= SB / 127 x *= SA[1] / 127 x += offset return x.to(dtype) def get_8bit_linear(x, stochastic=False): round_func = ( LinearFunction.round_stoachastic if stochastic else torch.round ) max1 = torch.abs(x).max() x = x / max1 * 127 x = round_func(x) / 127 * max1 # x = torch.round(x)/128*max1 return x @staticmethod def get_8bit_vector_wise(x, dim, stochastic=False): round_func = ( LinearFunction.round_stoachastic if stochastic else torch.round ) max1 = torch.amax(torch.abs(x), dim=dim, keepdim=True) max1[max1 == 0] = 1.0 x = (x * 127) / max1 x = round_func(x) / 127 * max1 return x @staticmethod def round_stoachastic(x): sign = torch.sign(x) absx = torch.abs(x) decimal = absx - torch.floor(absx) rdm = torch.rand_like(decimal) return sign * (torch.floor(absx) + (rdm < decimal).to(x.dtype)) @staticmethod def fake_8bit_storage(w, exponent_bits): code = bnb.functional.create_dynamic_map(n=exponent_bits).to(w.device) absmax, C = bnb.functional.quantize_blockwise(w.data, code=code) out = bnb.functional.dequantize_blockwise(absmax, C, code) out = out.half() w.copy_(out) return out @staticmethod def fake_8bit_storage_quantile(w, args): code = bnb.functional.estimate_quantiles(w.data, offset=args.offset) # C = bnb.functional.quantize_no_absmax(code, w) # out = bnb.functional.dequantize_no_absmax(code, C, out=w.data) # print(out) # out = out.half() code /= torch.max(torch.abs(code)) absmax, C = bnb.functional.quantize_blockwise(w.data, code=code) out = bnb.functional.dequantize_blockwise(absmax, C, code) out = out.half() w.copy_(out) return out @staticmethod def fake_8bit_storage_stoachstic(w): rand = torch.rand(1024, device=w.device) absmax, C = bnb.functional.quantize_blockwise(w.data, rand=rand) out = bnb.functional.dequantize_blockwise(absmax, C) out = out.half() w.copy_(out) return out @staticmethod def fake_8bit_storage_with_max(w, topk=8): blocked_w = einops.rearrange(w.flatten(), "(h b) -> h b", b=256) max_val, idx = torch.sort(torch.abs(blocked_w), dim=1, descending=True) idx = idx[:, :topk] max_val = max_val[:, :topk] mask = torch.zeros_like(blocked_w) mask.scatter_(dim=1, index=idx, src=torch.ones_like(max_val)) mask = mask.bool() # 1. zero out max values # 2. quantize + dequantize # 3. write back max values # 4. copy matrix back to weight values = blocked_w[mask] blocked_w[mask] = 0 code = bnb.functional.create_dynamic_map() code = code.to(w.device) absmax, C = bnb.functional.quantize_blockwise(blocked_w.data) bnb.functional.dequantize_blockwise(absmax, C, out=blocked_w) blocked_w[mask] = values unblocked_w = blocked_w.flatten().view(w.shape) w.copy_(unblocked_w) return unblocked_w @staticmethod def forward(ctx, x, weight, bias=None, args=None): if args.use_8bit_training != "off": weight8, S1 = LinearFunction.quant(weight, args.quant_type, dim=1) x8, S2 = LinearFunction.quant(x, args.quant_type, dim=2) outputq = bnb.functional.igemm(x8, weight8.t()) output = LinearFunction.dequant( outputq, S1, S2, x.dtype, args.quant_type ) # if torch.rand(1) < 0.01: # output32 = torch.matmul(x, weight.t()) # err = torch.abs(output-output32).float() # relerr = err/(torch.abs(output32).float()+1e-8) # print(f'{err.mean().item():.4f}, {relerr.mean().item():.4f}', args.quant_type, 'forward', proxy) else: # output = torch.matmul(x, weight.t()) output = torch.einsum("bsi,oi->bso", x, weight) ctx.save_for_backward(x, weight, bias) ctx.args = args if bias is not None: output += bias.unsqueeze(0).expand_as(output) return output @staticmethod def backward(ctx, grad_output): x, weight, bias = ctx.saved_tensors args = ctx.args stochastic = False grad_input = grad_weight = grad_bias = None if bias is not None and ctx.needs_input_grad[2]: grad_bias = grad_output.sum(0) # weight and x are already 8bit # -> transform grad_output to 8-bit if args.use_8bit_training == "forward+wgrad": grad_output8, S1 = LinearFunction.quant( grad_output, args.quant_type, dim=[0, 1] ) x8, S2 = LinearFunction.quant(x, args.quant_type, dim=[0, 1]) grad_weight8 = bnb.functional.igemm(grad_output8, x8) grad_weight = LinearFunction.dequant( grad_weight8, S1, S2, grad_output.dtype, args.quant_type ) # grad_weight32 = torch.einsum('bso,bsi->oi', grad_output, x) grad_input = grad_output.matmul(weight) elif args.use_8bit_training == "full": grad_output8, S1 = LinearFunction.quant( grad_output, args.quant_type, dim=[0, 1] ) x8, S2 = LinearFunction.quant(x, args.quant_type, dim=[0, 1]) grad_weight8 = torch.zeros_like(weight, dtype=torch.int32) bnb.functional.igemm(grad_output8, x8, out=grad_weight8) grad_weight = LinearFunction.dequant( grad_weight8, S1, S2, grad_output.dtype, args.quant_type ) grad_output8, S1 = LinearFunction.quant( grad_output, args.quant_type, dim=2 ) weight8, S3 = LinearFunction.quant(weight, args.quant_type, dim=0) grad_input8 = bnb.functional.igemm(grad_output8, weight8) grad_input = LinearFunction.dequant( grad_input8, S1, S3, grad_output.dtype, args.quant_type ) else: grad_input = grad_output.matmul(weight) grad_weight = torch.einsum("bsi,bso->oi", x, grad_output) return grad_input, grad_weight, grad_bias, None class Linear8bit(nn.Module): def __init__(self, input_features, output_features, bias=True, args=None): super().__init__() self.input_features = input_features self.output_features = output_features self.args = args self.weight = nn.Parameter(torch.empty(output_features, input_features)) if bias: self.bias = nn.Parameter(torch.empty(output_features)) else: self.register_parameter("bias", None) torch.nn.init.xavier_uniform_(self.weight) if self.bias is not None: torch.nn.init.zeros_(self.bias) def forward(self, x): self.args.training = self.training return LinearFunction.apply(x, self.weight, self.bias, self.args) threshold = [0.0, 3.0] values = threshold names = [f"threshold_{vals}" for vals in values] @pytest.mark.parametrize("threshold", values, ids=names) def test_linear8bitlt_inference(threshold): l1 = bnb.nn.Linear8bitLt(32, 64, threshold=threshold).cuda().half() assert l1.weight.device.type == "cuda" assert l1.weight.dtype == torch.float16 l1.eval() for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = l1(b1) if i == 1: assert l1.state.CxB is not None def test_linear8bitlt_accumulated_gradient(): l1 = torch.nn.Sequential(*[bnb.nn.Linear8bitLt(32, 32).cuda().half() for i in range(2)]) l2 = torch.nn.Sequential(*[torch.nn.Linear(32, 32).cuda().half() for i in range(2)]) l1[0].weight.data.copy_(l2[0].weight.data) l1[1].weight.data.copy_(l2[1].weight.data) l1[0].bias.data.copy_(l2[0].bias.data) l1[1].bias.data.copy_(l2[1].bias.data) opt1 = bnb.optim.Adam32bit(l1.parameters(), lr=0.001) opt2 = bnb.optim.Adam32bit(l2.parameters(), lr=0.001) acc_steps = 10 for i in range(10): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = l1(b1) o2 = l2(b1) loss1 = o1.mean() loss2 = o2.mean() loss1.backward() loss2.backward() if i == 2: assert l1[0].state.CxB is not None assert l1[1].state.CxB is not None if i > 0 and i % acc_steps == 0: opt1.step() opt1.zero_grad(True) opt2.step() opt2.zero_grad(True) assert_all_approx_close( l1[0].weight, l2[0].weight, rtol=1.05, atol=0.01, count=2 ) assert_all_approx_close( l1[1].weight, l2[1].weight, rtol=1.05, atol=0.01, count=2 ) # we do this copy because otherwise we have small divergences over time that add up l1[0].weight.data.copy_(l2[0].weight.data) l1[1].weight.data.copy_(l2[1].weight.data) l1[0].bias.data.copy_(l2[0].bias.data) l1[1].bias.data.copy_(l2[1].bias.data) else: torch.testing.assert_close(l1[0].weight.grad, l2[0].weight.grad, atol=1e-3, rtol=1e-3) torch.testing.assert_close(l1[1].weight.grad, l2[1].weight.grad, atol=1e-3, rtol=1e-3) @pytest.mark.parametrize("threshold", [0.0, 2.0]) @pytest.mark.parametrize("memory_efficient_backward", [False]) def test_linear8bitlt_no_fp16_weights(threshold, memory_efficient_backward): l1 = (bnb.nn.Linear8bitLt( 32, 64, threshold=threshold, has_fp16_weights=False, memory_efficient_backward=memory_efficient_backward).cuda().half()) assert l1.weight.dtype == torch.int8 l1.eval() for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = l1(b1) assert o1.dtype == torch.float16 mlp = MLP8bit(32, 64, threshold=threshold, has_fp16_weights=False).cuda() assert mlp.fc1.weight.dtype == torch.int8 assert mlp.fc2.weight.dtype == torch.int8 for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = mlp(b1) assert o1.dtype == torch.float16 if threshold > 0: assert mlp.fc1.state.idx is not None if threshold > 0: assert mlp.fc2.state.idx is not None mlp = ( MLP8bit(32, 64, threshold=threshold, has_fp16_weights=False) .cuda() .half() ) assert mlp.fc1.weight.dtype == torch.int8 assert mlp.fc2.weight.dtype == torch.int8 for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = mlp(b1) assert o1.dtype == torch.float16 if threshold > 0: assert mlp.fc1.state.idx is not None if threshold > 0: assert mlp.fc2.state.idx is not None mlp = ( MLP8bit(32, 64, threshold=threshold, has_fp16_weights=False) .half() .cuda() ) for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = mlp(b1) assert o1.dtype == torch.float16 if threshold > 0: assert mlp.fc1.state.idx is not None if threshold > 0: assert mlp.fc2.state.idx is not None assert mlp.fc1.weight.dtype == torch.int8 assert mlp.fc2.weight.dtype == torch.int8 mlp = ( MLP8bit( 32, 64, threshold=threshold, has_fp16_weights=False, memory_efficient_backward=memory_efficient_backward).half().to("cuda")) for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = mlp(b1) assert o1.dtype == torch.float16 if threshold > 0: assert mlp.fc1.state.idx is not None if threshold > 0: assert mlp.fc2.state.idx is not None assert mlp.fc1.weight.dtype == torch.int8 assert mlp.fc2.weight.dtype == torch.int8 assert mlp.fc1.weight.device.type == "cuda" assert mlp.fc2.weight.device.type == "cuda" mlp = MLP8bit( 32, 64, threshold=threshold, has_fp16_weights=False, memory_efficient_backward=memory_efficient_backward ) w1, w2 = mlp.fc1.weight.clone().cuda(), mlp.fc2.weight.clone().cuda() # grab weights before quantization, mlp = mlp.cuda().half() # and this line triggers quantization for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = mlp(b1) assert o1.dtype == torch.float16 if threshold > 0: assert mlp.fc1.state.idx is not None if threshold > 0: assert mlp.fc2.state.idx is not None assert mlp.fc1.weight.dtype == torch.int8 assert mlp.fc2.weight.dtype == torch.int8 assert mlp.fc1.weight.device.type == "cuda" assert mlp.fc2.weight.device.type == "cuda" if memory_efficient_backward: b1 = torch.randn(16, 8, 32, device="cuda", requires_grad=True, dtype=torch.half) o1 = mlp(b1) assert o1.dtype == torch.float16 assert o1.requires_grad grad_proj = torch.randn_like(o1) mlp.zero_grad() (o1 * grad_proj).sum().backward() grad_ref = grad_proj.flatten(2) @ w2.half() @ w1.half() scale = grad_ref.abs().mean() torch.testing.assert_close(b1.grad, grad_ref, rtol=0, atol=0.05 * scale) idx = torch.isclose(b1.grad, grad_ref, atol=0.01 * scale, rtol=0.1) assert (idx == 0).sum().item() <= b1.numel() * 0.005 @pytest.mark.parametrize("module", [lambda nin, nout, bias=True: bnb.nn.Linear8bitLt(nin, nout, bias=bias, has_fp16_weights=False), bnb.nn.LinearFP4], ids=['Int8Lt', 'FP4']) def test_linear_kbit_fp32_bias(module): # casts model to fp16 -> int8 automatically l1 = module(32, 64).cuda() assert l1.weight.dtype in [torch.int8, torch.uint8] assert l1.bias.dtype == torch.float32 for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() # casts bias to fp32 o1 = l1(b1) assert l1.bias.dtype == torch.float16 # casts model to fp16 -> int8 automatically l1 = module(32, 64, bias=False).cuda() assert l1.weight.dtype in [torch.int8, torch.uint8] assert l1.bias is None for i in range(100): b1 = torch.randn(16, 8, 32, device="cuda").half() o1 = l1(b1) assert l1.bias is None modules = [] modules.append(bnb.nn.Linear8bitLt) modules.append(bnb.nn.Linear4bit) modules.append(bnb.nn.LinearFP4) modules.append(bnb.nn.LinearNF4) modules.append(lambda d1, d2: bnb.nn.LinearFP4(d1, d2, compress_statistics=True)) modules.append(lambda d1, d2: bnb.nn.LinearNF4(d1, d2, compress_statistics=True)) names = ['Int8Lt', '4bit', 'FP4', 'NF4', 'FP4+C', 'NF4+C'] @pytest.mark.skipif(not torch.cuda.is_available(), reason="this test requires a GPU") @pytest.mark.parametrize("module", modules, ids=names) def test_kbit_backprop(module): b = 17 dim1 = 37 dim2 = 83 ref = nn.Sequential(*[torch.nn.Linear(dim1, dim2), torch.nn.Linear(dim2, 10)]) ref[1].weight.requires_grad = False torch.nn.init.kaiming_normal_(ref[0].weight) torch.nn.init.kaiming_normal_(ref[1].weight) kbit = nn.Sequential(*[torch.nn.Linear(dim1, dim2), module(dim2, 10)]) kbit[0].weight.detach().copy_(ref[0].weight) kbit[1].weight.detach().copy_(ref[1].weight) kbit[0].bias.detach().copy_(ref[0].bias) kbit[1].bias.detach().copy_(ref[1].bias) ref = ref.half().cuda() kbit = kbit.half().cuda() kbit = kbit.half().to('cuda') errs1 = [] errs2 = [] relerrs1 = [] relerrs2 = [] for i in range(100): batch = torch.randn(b, dim1).half().cuda() out1 = ref(batch) out2 = kbit(batch) out1.mean().backward() out2.mean().backward() grad1 = ref[0].weight.grad grad2 = kbit[0].weight.grad bgrad1 = ref[0].bias.grad bgrad2 = kbit[0].bias.grad err1 = (out1-out2).abs().float() err2 = (grad1-grad2).abs().float() relerr1 = (err1/(out1.abs().float()+1e-9)) relerr2 = (err2/(grad1.abs().float()+1e-9)) errs1.append(err1.mean().item()) errs2.append(err2.mean().item()) relerrs1.append(relerr1.mean().item()) relerrs2.append(relerr2.mean().item()) if isinstance(module, bnb.nn.Linear8bitLt): torch.testing.assert_close(grad1, grad2, atol=0.008, rtol=0.05) torch.testing.assert_close(bgrad1, bgrad2, atol=0.008, rtol=0.05) else: torch.testing.assert_close(grad1, grad2, atol=0.015, rtol=0.05) torch.testing.assert_close(bgrad1, bgrad2, atol=0.02, rtol=0.05) ref.zero_grad() kbit.zero_grad() assert kbit[0].weight.grad is None or kbit[0].weight.grad.sum().item() == 0 assert kbit[0].weight.grad is None or kbit[0].bias.grad.sum().item() == 0 print('out', sum(errs1)/len(errs1)) print('grad', sum(errs2)/len(errs2)) print('rel out', sum(relerrs1)/len(relerrs1)) print('rel grad', sum(relerrs2)/len(relerrs2)) def test_fp8linear(): b = 10 h = 1024 inp = torch.randn(b, h).cuda() fp32 = torch.nn.Linear(h, h*2).cuda() fp8 = bnb.research.nn.LinearFP8Mixed(h, h*2).cuda() fp32b = torch.nn.Linear(h*2, h).cuda() fp8b = bnb.research.nn.LinearFP8Mixed(h*2, h).cuda() fp8.weight.data.copy_(fp32.weight.data) fp8.bias.data.copy_(fp32.bias.data) fp8b.weight.data.copy_(fp32b.weight.data) fp8b.bias.data.copy_(fp32b.bias.data) a = fp32b(torch.nn.functional.gelu(fp32(inp))) b = fp8b(torch.nn.functional.gelu(fp8(inp))) err = (a-b).abs().mean() a.mean().backward() b.mean().backward() graderr = (fp8.weight.grad-fp32.weight.grad).abs().mean() bgraderr = (fp8.bias.grad-fp32.bias.grad).abs().mean() assert err < 0.05 assert graderr < 0.00002 assert bgraderr < 0.00002