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- import torch
- import numpy as np
- import apex
- import syncbn
- import os
- import argparse
- import torch.optim as optim
- def compare(desc, inp1, inp2, error):
- a = inp1.clone().detach().cpu().numpy()
- b = inp2.clone().detach().cpu().numpy()
- close = np.allclose(a,b, error, error)
- if not close:
- print(desc, close)
- z = a - b
- index = (np.abs(z) >= error + error * np.abs(b)).nonzero()
- print("dif : ", z[index])
- print("inp1 : ", a[index])
- print("inp2 : ", b[index])
- return close
- feature_size = 10
- space_size = 40
- batch_size = 32
- from apex.parallel import DistributedDataParallel as DDP
- parser = argparse.ArgumentParser()
- parser.add_argument("--local_rank", default=0, type=int)
- parser.add_argument("--fp16", action='store_true', default=False)
- parser.add_argument("--fp64", action='store_true', default=False)
- parser.add_argument("--group_size", default=0, type=int)
- args = parser.parse_args()
- try:
- args.world_size = int(os.environ['WORLD_SIZE'])
- except:
- print("This is a multi-gpu test. To run it please use 'python -m torch.distributed.launch --nproc_per_node=<num gpus> test_groups.py <more options>'")
- exit(1)
- torch.cuda.set_device(args.local_rank)
- torch.distributed.init_process_group(backend='nccl', init_method='env://')
- start = (args.local_rank%args.group_size) * batch_size//args.group_size
- finish = (args.local_rank%args.group_size + 1) * batch_size//args.group_size
- error = 1e-5
- dtype = np.float32
- if args.fp16:
- error = 1e-3
- dtype = np.float16
- elif args.fp64:
- error = 1e-8
- dtype = np.float64
- np.random.seed(18 + args.local_rank//args.group_size)
- inp = np.random.randn(batch_size, feature_size, space_size, space_size).astype(dtype)
- grad = np.random.randn(batch_size, feature_size, space_size, space_size).astype(dtype)
- weight = np.random.randn(feature_size).astype(dtype)
- bias = np.random.randn(feature_size).astype(dtype)
- type_tensor = torch.cuda.FloatTensor
- if args.fp16:
- type_tensor = torch.cuda.HalfTensor
- if args.fp64:
- type_tensor = torch.cuda.DoubleTensor
- ref_tensor = torch.cuda.DoubleTensor
- inp_t = type_tensor(inp)
- weight_t = type_tensor(weight)
- bias_t = type_tensor(bias)
- inp_r = ref_tensor(inp.transpose(1, 0, 2, 3).reshape(feature_size, -1))
- inp2_r = ref_tensor(inp)
- weight_r = ref_tensor(weight).view(-1, 1, 1)
- bias_r = ref_tensor(bias).view(-1, 1, 1)
- grad_output_t = type_tensor(grad)
- m = inp_r.mean(1)
- b_v = inp_r.var(1, unbiased=False)
- unb_v = inp_r.var(1, unbiased=True)
- eps = 1e-5
- mean, var_biased = syncbn.welford_mean_var(inp_t)
- inv_std = 1.0 / torch.sqrt(var_biased + eps)
- bn = torch.nn.BatchNorm2d(feature_size).cuda()
- bn.momentum = 1.0
- bn.weight.data = weight_t.clone()
- bn.bias.data = bias_t.clone()
- if args.fp16:
- bn.half()
- if args.fp64:
- bn.double()
- bn = DDP(bn)
- inp_bn = inp_t.clone().requires_grad_()
- grad_bn = grad_output_t.clone().detach()
- out_bn = bn(inp_bn)
- out_bn.backward(grad_bn)
- # compensating the averaging over processes done by DDP
- # in order to produce mathematically equivalent result
- # https://github.com/NVIDIA/apex/issues/134#issuecomment-458307368
- for param in bn.parameters():
- param.grad = param.grad / args.group_size
- bn_opt = optim.SGD(bn.parameters(), lr=1.0)
- sbn = apex.parallel.SyncBatchNorm(feature_size, process_group=apex.parallel.create_syncbn_process_group(args.group_size)).cuda()
- sbn.momentum = 1.0
- sbn.weight.data = weight_t.clone()
- sbn.bias.data = bias_t.clone()
- if args.fp16:
- sbn.half()
- if args.fp64:
- sbn.double()
- sbn = DDP(sbn)
- sbn_opt = optim.SGD(sbn.parameters(), lr=1.0)
- inp_sbn = inp_t.clone().requires_grad_()
- grad_sbn = grad_output_t.clone().detach()
- out_sbn = sbn(inp_sbn[start:finish])
- out_sbn.backward(grad_sbn[start:finish])
- sbn_result = True
- bn_result = True
- if args.local_rank == 0:
- sbn_result = compare("comparing mean: ", mean, m, error) and sbn_result
- sbn_result = compare("comparing biased variance: ", var_biased, b_v, error) and sbn_result
- out = syncbn.batchnorm_forward(inp_t, mean, inv_std, weight_t, bias_t)
- out_r = weight_r * (inp2_r - m.view(-1, 1, 1)) * torch.rsqrt(b_v.view(-1,1,1) + eps) + bias_r
- if args.local_rank == 0:
- sbn_result = compare("comparing output: ", out, out_r, error) and sbn_result
- compare("comparing bn output: ", out_bn, out_r, error)
- grad_output_t = type_tensor(grad)
- grad_output_r = ref_tensor(grad.transpose(1, 0, 2, 3).reshape(feature_size, -1))
- grad_output2_r = ref_tensor(grad)
- grad_bias_r = grad_output_r.sum(1)
- grad_weight_r = ((inp2_r - m.view(-1, 1, 1)) * torch.rsqrt(b_v.view(-1,1,1) + eps) * grad_output2_r).transpose(1,0).contiguous().view(feature_size, -1).sum(1)
- mean_dy_r = grad_output_r.mean(1)
- mean_dy_xmu_r = ((inp2_r - m.view(-1, 1, 1)) * grad_output2_r).transpose(1,0).contiguous().view(feature_size, -1).mean(1)
- grad_input_r = (grad_output2_r - mean_dy_r.view(-1, 1, 1) - (inp2_r - m.view(-1, 1, 1)) / (b_v.view(-1,1,1) + eps) * mean_dy_xmu_r.view(-1, 1, 1) ) * torch.rsqrt(b_v.view(-1,1,1) + eps) * weight_r.view(-1,1,1)
- mean_dy, mean_dy_xmu, grad_weight, grad_bias = syncbn.reduce_bn(grad_output_t, inp_t, mean, inv_std, weight_t)
- grad_input = syncbn.batchnorm_backward(grad_output_t, inp_t, mean, inv_std, weight_t, mean_dy, mean_dy_xmu)
- if args.local_rank == 0:
- sbn_result = compare("comparing bias grad: ", grad_bias, grad_bias_r, error) and sbn_result
- sbn_result = compare("comparing weight grad: ", grad_weight, grad_weight_r, error) and sbn_result
- sbn_result = compare("comparing mean_dy grad: ", mean_dy, mean_dy_r, error) and sbn_result
- sbn_result = compare("comparing mean_dy_xmu grad: ", mean_dy_xmu, mean_dy_xmu_r, error) and sbn_result
- sbn_result = compare("comparing input grad: ", grad_input, grad_input_r, error) and sbn_result
- compare("comparing bn input grad: ", inp_bn.grad, grad_input_r, error)
- if args.local_rank == 0:
- sbn_result = compare("comparing running_mean: ", bn.module.running_mean.data, sbn.module.running_mean.data, error) and sbn_result
- sbn_result = compare("comparing running_variance: ", bn.module.running_var.data, sbn.module.running_var.data, error) and sbn_result
- # execute by both
- compare("comparing layers output: ", out_bn[start:finish], out_sbn, error) and sbn_result
- compare("comparing layers grad_input: ", inp_bn.grad[start:finish], inp_sbn.grad[start:finish], error) and sbn_result
- bn_opt.step()
- sbn_opt.step()
- if args.local_rank == 0:
- compare("comparing bn vs sbn bias: ", bn.module.bias, sbn.module.bias, error)
- compare("comparing bn vs sbn weight: ", bn.module.weight, sbn.module.weight, error)
- if sbn_result:
- print("====SBN group test passed")
- else:
- print("*SBN group test failed*")
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