代码拉取完成,页面将自动刷新
import os
import math
import inspect
import torch
import importlib
import amp_C
from apex.multi_tensor_apply import multi_tensor_applier
import torch.distributed.distributed_c10d as c10d
# Fallback to private fields if using older PyTorch version
try:
import torch.distributed.distributed_c10d.get_process_group_ranks
except ImportError:
def get_process_group_ranks(group):
return list(c10d._pg_group_ranks[group].keys())
_make_nccl_premul_sum = getattr(torch.distributed, "_make_nccl_premul_sum", None)
# Ref: https://github.com/pytorch/pytorch/pull/81272
if _make_nccl_premul_sum is None:
if hasattr(torch.distributed, "make_nccl_premul_sum"):
_make_nccl_premul_sum = torch.distributed.make_nccl_premul_sum
class DistributedFusedLAMB(torch.optim.Optimizer):
"""Implements LAMB algorithm.
Currently GPU-only. Requires Apex to be installed via
``pip install -v --no-cache-dir --global-option="--cpp_ext" --global-option="--cuda_ext" ./``.
This version of fused LAMB implements 2 fusions.
* Fusion of the LAMB update's elementwise operations
* A multi-tensor apply launch that batches the elementwise updates applied to all the model's parameters into one or a few kernel launches.
:class:`apex.optimizers.FusedLAMB`'s usage is identical to any ordinary Pytorch optimizer::
opt = apex.optimizers.FusedLAMB(model.parameters(), lr = ....)
...
opt.step()
:class:`apex.optimizers.FusedLAMB` may be used with or without Amp. If you wish to use :class:`FusedLAMB` with Amp,
you may choose any ``opt_level``::
opt = apex.optimizers.FusedLAMB(model.parameters(), lr = ....)
model, opt = amp.initialize(model, opt, opt_level="O0" or "O1 or "O2")
...
opt.step()
In general, ``opt_level="O1"`` is recommended.
LAMB was proposed in `Large Batch Optimization for Deep Learning: Training BERT in 76 minutes`_.
Arguments:
params (iterable): iterable of parameters to optimize or dicts defining
parameter groups.
lr (float, optional): learning rate. (default: 1e-3)
betas (Tuple[float, float], optional): coefficients used for computing
running averages of gradient and its norm. (default: (0.9, 0.999))
eps (float, optional): term added to the denominator to improve
numerical stability. (default: 1e-8)
weight_decay (float, optional): weight decay (L2 penalty) (default: 0)
amsgrad (boolean, optional): whether to use the AMSGrad variant of this
algorithm from the paper `On the Convergence of Adam and Beyond`_
NOT SUPPORTED now! (default: False)
adam_w_mode (boolean, optional): Apply L2 regularization or weight decay
True for decoupled weight decay(also known as AdamW) (default: True)
grad_averaging (bool, optional): whether apply (1-beta2) to grad when
calculating running averages of gradient. (default: True)
set_grad_none (bool, optional): whether set grad to None when zero_grad()
method is called. (default: True)
max_grad_norm (float, optional): value used to clip global grad norm
(default: 1.0)
use_nvlamb (boolean, optional): Apply adaptive learning rate to 0.0
weight decay parameter (default: False)
step_supports_amp_scaling(boolean, optional): whether to use customized
gradient unscaling logic (default: True)
.. _Large Batch Optimization for Deep Learning - Training BERT in 76 minutes:
https://arxiv.org/abs/1904.00962
.. _On the Convergence of Adam and Beyond:
https://openreview.net/forum?id=ryQu7f-RZ
"""
class AtomicCounter(object):
def __init__(self):
self.value = 0
self.order = []
import threading
self._lock = threading.Lock()
def add(self, idx):
with self._lock:
self.value += 1
self.order.append(idx)
def __init__(self, params,
lr=1e-3, bias_correction = True, grad_averaging=True,
betas=(0.9, 0.999), eps=1e-8,
weight_decay=0., max_grad_norm=0.,
adam_w_mode=True, use_nvlamb=False,
step_supports_amp_scaling=True, overlap_reductions=True,
dwu_group_size=0, dwu_num_blocks=4, dwu_num_chunks=4,
dwu_num_rs_pg=1, dwu_num_ar_pg=4, dwu_num_ag_pg=0, fused_norm=False,
e5m2_allgather=False, verbose=False, clip_after_ar=True,
full_ar=False, set_param_views_to_flat_buffer=False, skip_allgather=False,
fuse_scale=False, param_order=None, nccl_allgather_channels=0):
defaults = dict(lr=lr, bias_correction=bias_correction,
betas=betas, eps=eps, weight_decay=weight_decay,
grad_averaging=grad_averaging,
max_grad_norm=max_grad_norm)
super(DistributedFusedLAMB, self).__init__(params, defaults)
global fused_adam_cuda, distributed_lamb_cuda
fused_adam_cuda = importlib.import_module("fused_adam_cuda")
distributed_lamb_cuda = importlib.import_module("distributed_lamb_cuda")
self._overflow_buf = torch.cuda.IntTensor([0])
self._has_overflow = False
self.multi_tensor_lamb_compute_update_term = distributed_lamb_cuda.multi_tensor_lamb_compute_update_term
self.multi_tensor_lamb_update_weights = distributed_lamb_cuda.multi_tensor_lamb_update_weights
import amp_C
self.multi_tensor_l2norm = amp_C.multi_tensor_l2norm
self._grad_averaging = grad_averaging
self._adam_w_mode = 1 if adam_w_mode else 0
self._use_nvlamb = use_nvlamb
self._step_supports_amp_scaling = step_supports_amp_scaling
self._is_accumulation_step = False
self._last_step = False
self._overlap_reductions = overlap_reductions
self._global_scale = None
self._num_blocks = dwu_num_blocks
self._num_chunks = dwu_num_chunks
self._e5m2_allgather = e5m2_allgather
self._verbose = verbose
self._clip_after_ar = clip_after_ar
self._full_ar = full_ar
self._fuse_scale = fuse_scale
self._L2_grad_norm = None
self._set_flat_param_view = set_param_views_to_flat_buffer
self._skip_ag = skip_allgather
self._fused_norm = fused_norm if not clip_after_ar else False
self._current_process_group = c10d._get_default_group()
self._available_ranks = get_process_group_ranks(self._current_process_group)
self._group_size = torch.cuda.device_count() if dwu_group_size <= 0 else dwu_group_size
self._world_size = torch.distributed.get_world_size()
self._num_groups = self._world_size // self._group_size
self._rank_in_group = torch.distributed.get_rank() % self._group_size
self._lr = torch.tensor(0.0, dtype=torch.float32, device='cuda')
self._resume_from_checkpoint = False
self._step = torch.cuda.IntTensor([0])
# Master weight, moment, gradient buffers
self._fp32_p, self._fp32_m, self._fp32_v, self._fp16_p, self._fp16_g = None, None, None, None, None
# Check if collectives have no_copy option
self._reduce_scatter_no_copy = (
'no_copy' in inspect.getfullargspec(torch.distributed.reduce_scatter).args
)
self._all_gather_no_copy = (
'no_copy' in inspect.getfullargspec(torch.distributed.all_gather).args
)
if "reduce_scatter_tensor" not in dir(torch.distributed):
torch.distributed.reduce_scatter_tensor = torch.distributed._reduce_scatter_base
if "all_gather_into_tensor" not in dir(torch.distributed):
torch.distributed.all_gather_into_tensor = torch.distributed._all_gather_base
self._num_rs_pg = dwu_num_rs_pg
self._num_ar_pg = dwu_num_ar_pg
self._num_ag_pg = dwu_num_ag_pg
if self._full_ar: # full all reduce, only need AR and AG groups
# l2_grad_norm may be reduced within a node to limit from memory reads
for group_i in range(self._num_groups):
ranks = [group_i*self._group_size+j for j in range(self._group_size)]
l2_grad_norm_pg = torch.distributed.new_group(ranks=ranks)
if torch.distributed.get_rank() in ranks:
self._l2_grad_norm_pg = l2_grad_norm_pg
self._ar_pg = []
# consider all the ranks
ranks = list(range(0, self._world_size))
for i in range(self._num_ar_pg):
if self._verbose:
print(f"creating new AR group {i}: {ranks}")
grp = torch.distributed.new_group(ranks=ranks)
if grp != torch.distributed.GroupMember.NON_GROUP_MEMBER:
if self._verbose:
print(f"group {i}: init barrier (device: {torch.cuda.current_device()})")
torch.distributed.barrier(group=grp, device_ids=[torch.cuda.current_device()])
if self._verbose:
print(f"created new AR group {i}: {ranks}")
if torch.distributed.get_rank() in ranks:
self._ar_pg.append(grp)
self._ar_st = [torch.cuda.Stream() for _ in range(self._num_ar_pg)]
if nccl_allgather_channels > 0:
os.putenv('NCCL_MAX_NCHANNELS', str(nccl_allgather_channels))
if self._num_ag_pg == 0:
self._ag_pg = self._ar_pg
self._ag_st = self._ar_st
self._num_ag_pg = self._num_ar_pg
else:
self._ag_pg = []
ranks = []
stride = torch.cuda.device_count()
for i in range(self._num_groups):
rs = list(range(i*stride, (i+1)*stride))
ranks.append(rs)
for rs in ranks:
for i in range(self._num_ag_pg):
grp = torch.distributed.new_group(ranks=rs)
if torch.distributed.get_rank() in rs:
if self._verbose:
print(f"creating AG group {i}: {rs}")
self._ag_pg.append(grp)
self._ag_st = [torch.cuda.Stream() for _ in range(self._num_ag_pg)]
else: # reduce-scatter + all-reduce, need RS, AR, AG groups
if self._num_groups > 1:
self._ar_pg = []
for dev_i in range(self._group_size):
ranks = [dev_i+j*self._group_size for j in range(self._num_groups)]
for i in range(self._num_ar_pg):
if self._verbose:
print(f"creating new AR group {i}: {ranks}")
grp = torch.distributed.new_group(ranks=ranks)
if grp != torch.distributed.GroupMember.NON_GROUP_MEMBER:
if self._verbose:
print(f"group {i}: init barrier (device: {torch.cuda.current_device()})")
torch.distributed.barrier(group=grp, device_ids=[torch.cuda.current_device()])
if self._verbose:
print(f"created new AR group {i}: {ranks}")
if torch.distributed.get_rank() in ranks:
self._ar_pg.append(grp)
self._ar_st = [torch.cuda.Stream() for _ in range(self._num_ar_pg)]
rs_ranks = []
for group_i in range(self._num_groups):
rs_ranks.append([group_i*self._group_size+j for j in range(self._group_size)])
self._rs_pg = []
for group_i in range(self._num_groups):
ranks = rs_ranks[group_i]
for i in range(self._num_rs_pg):
grp = torch.distributed.new_group(ranks=ranks)
if torch.distributed.get_rank() in ranks:
self._rs_pg.append(grp)
if self._verbose:
print(f"creating RS group : {ranks}")
l2_grad_norm_pg = torch.distributed.new_group(ranks=ranks)
if torch.distributed.get_rank() in ranks:
self._l2_grad_norm_pg = l2_grad_norm_pg
self._rs_st = [torch.cuda.Stream() for _ in range(self._num_rs_pg)]
if self._num_ag_pg == 0:
self._ag_pg = self._rs_pg
self._ag_st = self._rs_st
self._num_ag_pg = self._num_rs_pg
else:
self._ag_pg = []
for group_i in range(self._num_groups):
ranks = rs_ranks[group_i]
for i in range(self._num_ag_pg):
grp = torch.distributed.new_group(ranks=ranks)
if torch.distributed.get_rank() in ranks:
self._ag_pg.append(grp)
if self._verbose:
print(f"creating AG group : {ranks}")
self._ag_st = [torch.cuda.Stream() for _ in range(self._num_ag_pg)]
for ag_pg in self._ag_pg:
torch.distributed.barrier(group=ag_pg)
self._l2_grad_norm_st = torch.cuda.Stream()
self._completion_st = torch.cuda.Stream()
self._step.record_stream(self._completion_st)
self._reductions_works = [None]*self._num_blocks
self._allgather_works = [None]*self._num_blocks
self._one = torch.cuda.IntTensor([1])
self._first_step = True
self._lazy_init_stage1_done, self._lazy_init_stage2_done = False, False
self._param_order = self.AtomicCounter()
p_offset = 0
p_i = 0
self._model_params = []
self._grad_accs = []
self._group_properties = []
for group in self.param_groups:
prev = None
beta1, beta2 = group['betas']
beta3 = 1.0 - beta1 if self._grad_averaging else 1.0
bias_correction = 1 if group['bias_correction'] else 0
eps = group['eps']
weight_decay = group['weight_decay']
for p in group['params']:
if not p.requires_grad:
continue
self._model_params.append(p)
self._group_properties.append((
weight_decay,
bias_correction,
beta1,
beta2,
beta3,
eps
))
p_grads_size = p.numel()
if self._set_flat_param_view:
if param_order:
# this is executed when param_order is specified by the user
self._param_order.add(param_order[p])
else:
self._param_order.add(p_i)
p_offset += p_grads_size
# Only enforce 128b alignment (64 * fp16) for non-consecutive parameters
# RNN is one example of consecutive parameters:
# (weight_ih, weight_hh, bias_ih, bias_hh)
if prev is not None and (prev.data_ptr() + prev.numel() * prev.element_size() != p.data_ptr()):
p_offset = ((p_offset + 63) // 64) * 64
prev = p
p_i += 1
if param_order:
self._param_order.order = torch.argsort(torch.tensor(self._param_order.order)).tolist()
self._grads_generated = [False]*len(self._model_params)
self._grads_fp16, self._grads_fp32 = [], []
if self._overlap_reductions:
self._current_block = self._num_blocks
self._net_total_param_size = p_offset
self._total_param_size = p_offset
dwu_min_page_size = 256 * self._num_blocks * self._num_chunks * self._group_size
self._total_param_size = ((self._total_param_size + dwu_min_page_size - 1) // dwu_min_page_size) * dwu_min_page_size
self._new_params = torch.zeros([self._total_param_size], dtype=torch.uint8 if self._e5m2_allgather else torch.float16, device='cuda')
def _lazy_init_stage1(self):
if self._lazy_init_stage1_done: return
p_i = 0
#self._model_params = []
#self._grad_accs = []
#self._group_properties = []
for group in self.param_groups:
for p in group['params']:
torch.distributed.broadcast(p, 0)
if not p.requires_grad:
continue
def wrapper(param, param_i):
param_tmp = param.expand_as(param)
grad_acc = param_tmp.grad_fn.next_functions[0][0]
def allreduce_hook(*unused):
if not self._set_flat_param_view:
if self._first_step:
# first time
self._param_order.add(param_i)
else:
idx = self._param_order.order.index(param_i)
self._do_overlapped_reduction(idx, param)
else:
if not self._first_step:
idx = self._param_order.order.index(param_i)
self._do_overlapped_reduction(idx, param)
grad_acc.register_hook(allreduce_hook)
self._grad_accs.append(grad_acc)
wrapper(p, p_i)
p_i += 1
self._block_size = self._total_param_size // self._num_blocks
self._chunk_size = self._block_size // self._num_chunks
self._shard_size = self._chunk_size // self._group_size
self._flat_grads = torch.zeros([self._total_param_size], dtype=torch.float16, device='cuda')
self._mega_shard_size = self._num_blocks * self._num_chunks * self._shard_size
# initialize master weights, moments buffers if not loaded from checkpoint
if self._fp32_p is None:
self._fp32_p = torch.zeros([self._mega_shard_size], dtype=torch.float32, device='cuda')
self._fp32_m = torch.zeros([self._mega_shard_size], dtype=torch.float32, device='cuda')
self._fp32_v = torch.zeros([self._mega_shard_size], dtype=torch.float32, device='cuda')
self._fp32_u = torch.zeros([self._mega_shard_size], dtype=torch.float32, device='cuda')
# FIXME: Rethink fp16 label since it's either uint8 or fp16
self._fp16_p = torch.zeros([self._mega_shard_size], dtype=torch.uint8 if self._e5m2_allgather else torch.float16, device='cuda')
self._fp16_g = torch.zeros([self._mega_shard_size], dtype=torch.float16, device='cuda')
def _flat_split(p):
def __blockify(p):
return [p[block_id*self._block_size:(block_id+1)*self._block_size] for block_id in range(self._num_blocks)]
def __chunkify(p):
return [p[chunk_id*self._chunk_size:(chunk_id+1)*self._chunk_size] for chunk_id in range(self._num_chunks)]
def __shardify(p):
return [p[shard_id*self._shard_size:(shard_id+1)*self._shard_size] for shard_id in range(self._group_size)]
list_of_blocks = __blockify(p)
list_of_list_of_chunks = [__chunkify(block) for block in list_of_blocks]
list_of_list_of_list_of_shards = [[__shardify(chunk) for chunk in chunks] for chunks in list_of_list_of_chunks]
return list_of_blocks, list_of_list_of_chunks, list_of_list_of_list_of_shards
# note(crcrpar): the function below doesn't seem to be used at all.
# def _flat_split_no_shards(p):
# def __blockify(p):
# return [p[block_id*self._block_size:(block_id+1)*self._block_size] for block_id in range(self._num_blocks)]
# def __chunkify(p):
# return [p[chunk_id*self._chunk_size:(chunk_id+1)*self._chunk_size] for chunk_id in range(self._num_chunks)]
# list_of_blocks = __blockify(self._flat_grads)
# list_of_list_of_chunks = [__chunkify(block) for block in list_of_blocks]
# return list_of_blocks, list_of_list_of_chunks
def _full_packed_split(p):
def __shardify(p):
return [p[mega_shard*self._mega_shard_size:(mega_shard+1)*self._mega_shard_size] for mega_shard in range(self._group_size)]
def __blockify(p):
return [p[block_id*self._num_chunks*self._shard_size:(block_id+1)*self._num_chunks*self._shard_size] for block_id in range(self._num_blocks)]
def __chunkify(p):
return [p[chunk_id*self._shard_size:(chunk_id+1)*self._shard_size] for chunk_id in range(self._num_chunks)]
list_of_mega_shards = __shardify(p)
list_of_list_of_mega_blocks = [__blockify(mega_shard) for mega_shard in list_of_mega_shards]
list_of_list_of_list_of_mega_chunks = [[__chunkify(mega_block) for mega_block in mega_blocks] for mega_blocks in list_of_list_of_mega_blocks]
return list_of_mega_shards, list_of_list_of_mega_blocks, list_of_list_of_list_of_mega_chunks
def _packed_split(p):
def __packed_blockify(p):
packed_block_size = self._num_chunks*self._shard_size
return [p[block_id*packed_block_size:(block_id+1)*packed_block_size] for block_id in range(self._num_blocks)]
def __packed_chunkify(p):
# in the packed format, each chunk contains one shard, so packed_chunk_size == self._shard_size
return [p[chunk_id*self._shard_size:(chunk_id+1)*self._shard_size] for chunk_id in range(self._num_chunks)]
list_of_blocks = __packed_blockify(p)
list_of_list_of_chunks = [__packed_chunkify(block) for block in list_of_blocks]
return list_of_blocks, list_of_list_of_chunks
def _split_assign(shards):
packed_block_size = self._num_chunks*self._shard_size
list_of_list_of_chunks=[]
for block_id in range(self._num_blocks):
list_of_chunks=[]
for chunk_id in range(self._num_chunks):
#self._fp16_g[block_id*packed_block_size+chunk_id*self._shard_size:block_id*packed_block_size+(chunk_id+1)*self._shard_size] = shards[block_id][chunk_id][self._rank_in_group]
list_of_chunks.append( shards[block_id][chunk_id][self._rank_in_group])
list_of_list_of_chunks.append(list_of_chunks)
return list_of_list_of_chunks
self._new_params_mega_shards, self._new_params_mega_blocks, self._new_params_mega_chunks = _full_packed_split(self._new_params)
# this splitting scheme is needed when allgather needs to be split into multiple chunks in a contiguous way
self._new_params2_blocks, self._new_params2_chunks, self._new_params2_shards = _flat_split(self._new_params)
self._fp32_p_blocks, self._fp32_p_chunks = _packed_split(self._fp32_p)
self._fp32_m_blocks, self._fp32_m_chunks = _packed_split(self._fp32_m)
self._fp32_v_blocks, self._fp32_v_chunks = _packed_split(self._fp32_v)
self._fp32_u_blocks, self._fp32_u_chunks = _packed_split(self._fp32_u)
self._fp16_p_blocks, self._fp16_p_chunks = _packed_split(self._fp16_p)
if self._full_ar:
# for gradient all-reduce
self._flat_grads_blocks, self._flat_grads_chunks, self._flat_grads_shards = _flat_split(self._flat_grads)
# for weight update
self._fp16_g_chunks = _split_assign(self._flat_grads_shards)
else:
self._flat_grads_blocks, self._flat_grads_chunks, self._flat_grads_shards = _flat_split(self._flat_grads)
self._fp16_g_blocks, self._fp16_g_chunks = _packed_split(self._fp16_g)
self._lazy_init_stage1_done = True
def _lazy_init_stage2(self):
if self._lazy_init_stage2_done: return
if not self._set_flat_param_view:
# reversing is needed for overlapping allreduce and backprop, but currently not supported for flat param view
self._param_order.order.reverse()
# re-order model_params, grad_accs, group_properties lists
self._model_params = [self._model_params[i] for i in self._param_order.order]
self._grad_accs = [self._grad_accs[i] for i in self._param_order.order]
self._group_properties = [self._group_properties[i] for i in self._param_order.order]
def _get_flat_view(param):
if param.is_contiguous(memory_format=torch.channels_last):
K, C, H, W = param.shape
pv = param.as_strided(size=(K,H,W,C), stride=(H*W*C, W*C, C, 1))
elif param.is_contiguous(memory_format=torch.channels_last_3d):
K, C, D, H, W = param.shape
pv = param.as_strided(size=(K,D,H,W,C), stride=(D*H*W*C, H*W*C, W*C, C, 1))
else:
pv = param
return pv.view(-1)
# re-collect grads info (size, offset) after ordering
prev = None
p_offset = 0
self._grads_info = []
self._individual_flat_grads = []
for i, p in enumerate(self._model_params):
p_grads_size = p.numel()
self._grads_info.append({"param_grads_size":p_grads_size, "param_offset":p_offset})
self._individual_flat_grads.append(self._flat_grads[p_offset:p_offset+p_grads_size].view_as(p))
# for the first iteration
self._do_overlapped_reduction(i, p)
p_offset += p_grads_size
# Only enforce 128b alignment (64 * fp16) for non-consecutive parameters
# RNN is one example of consecutive parameters:
# (weight_ih, weight_hh, bias_ih, bias_hh)
if prev is not None and (prev.data_ptr() + prev.numel() * prev.element_size() != p.data_ptr()):
p_offset = ((p_offset + 63) // 64) * 64
prev = p
self._low_param_i = [0]*self._num_blocks
for block_id in range(self._num_blocks-1,-1,-1):
p_i = len(self._grads_info)-1
while p_i > 0 and self._grads_info[p_i]["param_offset"] > block_id*self._block_size:
p_i -= 1
self._low_param_i[block_id] = p_i
#print("self._low_param_i", self._low_param_i)
# This paragraph does two things:
# 1) Copy model parameters into master buffer
# 2) Create tensor lists for unpacking new parameter tensor after all-gather
self._packed_flat_to_model_params_fp16 = []
self._packed_flat_to_model_params_fp32 = []
self._model_params_num = len(self._model_params)
self._contrib_tensor_list = []
self._contrib_min_param_i, self._contrib_max_param_i = -1, -1
self._contrib_update_frag_for_norm = []
self._contrib_model_param_for_norm_fp16 = []
self._contrib_model_param_for_norm_fp32 = []
self._contrib_model_param_for_norm_is_fp16 = []
self._model_param_is_contrib = []
self._contrib_group_properties = []
for shard_id in range(self._group_size):
for block_id in range(self._num_blocks):
for chunk_id in range(self._num_chunks):
flat_shard_start = (((block_id * self._num_chunks + chunk_id) * self._group_size) + shard_id) * self._shard_size
flat_shard_end = flat_shard_start + self._shard_size
for param_i, (p, grads_info, group_props) in enumerate(zip(self._model_params, self._grads_info, self._group_properties)):
flat_grad_start = grads_info["param_offset"]
flat_grad_end = flat_grad_start + grads_info["param_grads_size"]
clipped_start = (lambda a,b: a if a > b else b)(flat_grad_start, flat_shard_start)
clipped_end = (lambda a,b: a if a < b else b)(flat_grad_end, flat_shard_end)
if clipped_start < clipped_end:
grad_offset = clipped_start - flat_grad_start
grad_length = clipped_end - clipped_start
shard_offset = clipped_start - flat_shard_start
pf = _get_flat_view(p)
model_param_fragment = pf[grad_offset:grad_offset+grad_length]
new_param_packed_fragment = self._new_params_mega_chunks[shard_id][block_id][chunk_id][shard_offset:shard_offset+grad_length]
if model_param_fragment.dtype == torch.float16:
self._packed_flat_to_model_params_fp16.append( (new_param_packed_fragment, model_param_fragment) )
else:
self._packed_flat_to_model_params_fp32.append( (new_param_packed_fragment, model_param_fragment) )
if shard_id == self._rank_in_group:
self._model_param_is_contrib.append(param_i)
# copy model parameters into master buffer
master_param_fragment = self._fp32_p_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
opti_state_m_fragment = self._fp32_m_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
opti_state_v_fragment = self._fp32_v_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
opti_state_u_fragment = self._fp32_u_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
opti_state_g_fragment = self._fp16_g_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
opti_state_p_fragment = self._fp16_p_chunks[block_id][chunk_id][shard_offset:shard_offset+grad_length]
#print("model_param_fragment.size()=%s, new_param_packed_fragment.size()=%s, master_param_fragment.size()=%s" % (str(model_param_fragment.size()), str(new_param_packed_fragment.size()), str(master_param_fragment.size())))
if not self._resume_from_checkpoint:
master_param_fragment.copy_(model_param_fragment)
self._contrib_group_properties.append(group_props)
self._contrib_tensor_list.append((master_param_fragment, opti_state_m_fragment, opti_state_v_fragment, opti_state_u_fragment, opti_state_g_fragment, opti_state_p_fragment)) # p, m, v, u, g, p_copy
self._contrib_update_frag_for_norm.append(opti_state_u_fragment)
if p.dtype == torch.float16:
self._contrib_model_param_for_norm_fp16.append(p)
else:
self._contrib_model_param_for_norm_fp32.append(p)
self._contrib_model_param_for_norm_is_fp16.append(True if p.dtype == torch.float16 else False)
if self._contrib_min_param_i < 0: self._contrib_min_param_i = param_i
self._contrib_max_param_i = param_i
self._contrib_model_param_for_norm_num = len(self._contrib_model_param_for_norm_is_fp16)
if len(self._contrib_model_param_for_norm_fp16) == 0: self._contrib_model_param_for_norm_fp16 = None
if len(self._contrib_model_param_for_norm_fp32) == 0: self._contrib_model_param_for_norm_fp32 = None
self._contrib_model_param_for_norm_is_fp32 = torch.tensor([not is_fp16 for is_fp16 in self._contrib_model_param_for_norm_is_fp16], dtype=torch.bool, device='cuda')
self._contrib_model_param_for_norm_is_fp16 = torch.tensor([is_fp16 for is_fp16 in self._contrib_model_param_for_norm_is_fp16], dtype=torch.bool, device='cuda')
self._offsets = torch.tensor(self._model_param_is_contrib, dtype=torch.int64, device='cuda')
p, m, v, u, g, p_copy = list(zip(*self._contrib_tensor_list))
self._contrib_compute_update_term_tensor_list = [g, p, m, v, u]
self._contrib_update_weights_tensor_list = [u, p, p_copy]
math_type = self._fp32_u.dtype
decay, bias_correction, beta1, beta2, beta3, epsilon = list(zip(*self._contrib_group_properties))
self._contrib_beta1 = torch.tensor(beta1, dtype=math_type, device='cuda')
self._contrib_beta2 = torch.tensor(beta2, dtype=math_type, device='cuda')
self._contrib_beta3 = torch.tensor(beta3, dtype=math_type, device='cuda')
self._contrib_bias_correction = torch.tensor(bias_correction, dtype=torch.int, device='cuda')
self._contrib_epsilon = torch.tensor(epsilon, dtype=math_type, device='cuda')
self._contrib_weight_decay = torch.tensor(decay, dtype=math_type, device='cuda')
self._packed_flat_to_model_params_fp16 = list(zip(*self._packed_flat_to_model_params_fp16)) if len(self._packed_flat_to_model_params_fp16) > 0 else None
self._packed_flat_to_model_params_fp32 = list(zip(*self._packed_flat_to_model_params_fp32)) if len(self._packed_flat_to_model_params_fp32) > 0 else None
self._lazy_init_stage2_done = True
self.complete_reductions()
self._first_step = False
def set_is_accumulation_step(self, is_accumulation_step):
self._is_accumulation_step = is_accumulation_step
def set_last_step(self, last_step):
self._last_step = last_step
def _get_flush_block(self):
flush_block = []
if self._current_block > 0 and self._grads_generated[self._low_param_i[self._current_block-1]]:
num_grads = len(self._grads_generated)
contiguous_idx = num_grads
while contiguous_idx > 0 and self._grads_generated[contiguous_idx-1]:
contiguous_idx -= 1
if contiguous_idx < num_grads and self._grads_info[contiguous_idx]["param_offset"] <= (self._current_block-1)*self._block_size:
self._current_block -= 1
start = self._current_block * self._block_size
end = (self._current_block+1) * self._block_size
flush_block = [start, end]
return flush_block
def _full_all_reduce_scale(self, block_id, scale):
works = [None]*self._num_chunks
if self._clip_after_ar:
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
ar_stream = self._ar_st[glob_chunk_id%self._num_ar_pg]
ar_stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(ar_stream):
works[chunk_id] = torch.distributed.all_reduce(self._flat_grads_chunks[block_id][chunk_id],group=self._ar_pg[glob_chunk_id%self._num_ar_pg],async_op=True,op=_make_nccl_premul_sum(scale))
else:
glob_chunk_id = block_id
ar_stream = self._ar_st[glob_chunk_id%self._num_ar_pg]
ar_stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(ar_stream):
works0 = torch.distributed.all_reduce(self._flat_grads_blocks[block_id],group=self._ar_pg[glob_chunk_id%self._num_ar_pg],async_op=True,op=_make_nccl_premul_sum(scale))
for i in range(self._num_chunks):
works[i]=works0
self._reductions_works[block_id] = works
def _full_all_reduce(self, block_id):
works = [None]*self._num_chunks
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
ar_stream = self._ar_st[glob_chunk_id%self._num_ar_pg]
ar_stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(ar_stream):
works[chunk_id] = torch.distributed.all_reduce(self._flat_grads_chunks[block_id][chunk_id],group=self._ar_pg[glob_chunk_id%self._num_ar_pg],async_op=True)
self._reductions_works[block_id] = works
def _reduce_scatter_and_all_reduce_scale(self, block_id, scale):
# Reduction within each node
# Changes gradient format from [block * chunk * shard] to [shard * block * chunk]
# The output format is the same as the fp32 master parameters
works = [None]*self._num_chunks
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
rs_stream = self._rs_st[glob_chunk_id%self._num_rs_pg]
rs_stream.wait_stream(torch.cuda.current_stream())
rs_stream.wait_stream(self._l2_grad_norm_st)
with torch.cuda.stream(rs_stream):
if self._reduce_scatter_no_copy:
works[chunk_id] = torch.distributed.reduce_scatter(
output=self._fp16_g_chunks[block_id][chunk_id],
input_list=self._flat_grads_shards[block_id][chunk_id],
group=self._rs_pg[glob_chunk_id%self._num_rs_pg],
async_op=True,
no_copy=True,
op=_make_nccl_premul_sum(scale),
)
else:
works[chunk_id] = torch.distributed.reduce_scatter_tensor(
output=self._fp16_g_chunks[block_id][chunk_id],
input=self._flat_grads_chunks[block_id][chunk_id],
group=self._rs_pg[glob_chunk_id%self._num_rs_pg],
async_op=True,
op=_make_nccl_premul_sum(scale),
)
# Reduction across nodes for each rank
if self._num_groups > 1:
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
ar_stream = self._ar_st[glob_chunk_id%self._num_ar_pg]
with torch.cuda.stream(ar_stream):
works[chunk_id].wait()
works[chunk_id] = torch.distributed.all_reduce(self._fp16_g_chunks[block_id][chunk_id],group=self._ar_pg[glob_chunk_id%self._num_ar_pg],async_op=True)
self._reductions_works[block_id] = works
def _reduce_scatter_and_all_reduce(self, block_id):
# Reduction within each node
# Changes gradient format from [block * chunk * shard] to [shard * block * chunk]
# The output format is the same as the fp32 master parameters
works = [None]*self._num_chunks
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
rs_stream = self._rs_st[glob_chunk_id%self._num_rs_pg]
rs_stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(rs_stream):
if self._reduce_scatter_no_copy:
works[chunk_id] = torch.distributed.reduce_scatter(
output=self._fp16_g_chunks[block_id][chunk_id],
input_list=self._flat_grads_shards[block_id][chunk_id],
group=self._rs_pg[glob_chunk_id%self._num_rs_pg],
async_op=True,
no_copy=True,
)
else:
works[chunk_id] = torch.distributed.reduce_scatter_tensor(
output = self._fp16_g_chunks[block_id][chunk_id],
input = self._flat_grads_chunks[block_id][chunk_id],
group = self._rs_pg[glob_chunk_id%self._num_rs_pg],
async_op = True,
)
# Reduction across nodes for each rank
if self._num_groups > 1:
for chunk_id in range(self._num_chunks):
glob_chunk_id = block_id * self._num_chunks + chunk_id
ar_stream = self._ar_st[glob_chunk_id%self._num_ar_pg]
with torch.cuda.stream(ar_stream):
works[chunk_id].wait()
works[chunk_id] = torch.distributed.all_reduce(self._fp16_g_chunks[block_id][chunk_id],group=self._ar_pg[glob_chunk_id%self._num_ar_pg],async_op=True)
self._reductions_works[block_id] = works
def _pipeline_block_reductions(self, block_id):
if self._clip_after_ar:
self._flatten_grad_mt(1.0/self._world_size)
if self._full_ar:
self._full_all_reduce(block_id)
else:
self._reduce_scatter_and_all_reduce(block_id)
# Compute L2 grad norm
if block_id == 0:
with torch.cuda.stream(self._l2_grad_norm_st):
for block_id in range(self._num_blocks):
for chunk_id in range(self._num_chunks):
self._reductions_works[block_id][chunk_id].wait()
# Since the packed format is contiguous after reductions, only one norm is needed
l2_grad_norm_sq = torch.empty([1], device='cuda')
if self._full_ar:
# this flattening of lists is to keep multi_tensor_apply function happy, it wants depth=1 for l2 norm computation
flat_list = [item for sublist in self._fp16_g_chunks for item in sublist]
l2_grad_norm_sq = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [flat_list], False)[0]**2
else:
l2_grad_norm_sq = self._fp16_g.norm(dtype=torch.float32, p=2)**2
torch.distributed.all_reduce(l2_grad_norm_sq, group=self._l2_grad_norm_pg)
self._L2_grad_norm = l2_grad_norm_sq.sqrt()
else:
# Copy model grads to flat grads buffer
self._flatten_grad_mt(1.0)
# Compute L2 grad norm
self._l2_grad_norm_st.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(self._l2_grad_norm_st):
if not self._fused_norm:
self._L2_grad_norm = self._flat_grads.norm(dtype=torch.float16, p=2).float()
torch.cuda.current_stream().wait_stream(self._l2_grad_norm_st)
# Apply clipping & pre-reduction scaling on grads
loss_scale = self.global_scale
max_grad_norm = loss_scale*self.defaults['max_grad_norm']
coeff = max_grad_norm /(1e-6+self.L2_grad_norm)
coeff = (coeff>1) * self._one + (coeff<=1) * coeff
tmp = torch.cat(((self._one), (coeff)))
index = (coeff+1>coeff).int()
scale = tmp.index_select(0, index).half()/self._world_size
if not self._fuse_scale:
self._flat_grads.mul_(scale)
if self._full_ar:
if self._fuse_scale:
self._full_all_reduce_scale(block_id, scale)
else:
self._full_all_reduce(block_id)
else:
if self._fuse_scale:
self._reduce_scatter_and_all_reduce_scale(block_id, scale)
else:
self._reduce_scatter_and_all_reduce(block_id)
if block_id == 0:
for block_id in range(self._num_blocks):
for chunk_id in range(self._num_chunks):
self._reductions_works[block_id][chunk_id].wait()
def __compute_contrib_param_norm(self):
if self._contrib_model_param_for_norm_fp16 is not None and self._contrib_model_param_for_norm_fp32 is not None:
gnorm_fp16 = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [self._contrib_model_param_for_norm_fp16], True)[1]
gnorm_fp32 = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [self._contrib_model_param_for_norm_fp32], True)[1]
gnorm = torch.empty(size=[self._contrib_model_param_for_norm_num], dtype=torch.bool, device='cuda')
gnorm.masked_scatter_(self._contrib_model_param_for_norm_is_fp16, gnorm_fp16)
gnorm.masked_scatter_(self._contrib_model_param_for_norm_is_fp32, gnorm_fp32)
elif self._contrib_model_param_for_norm_fp16 is not None:
gnorm = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [self._contrib_model_param_for_norm_fp16], True)[1]
elif self._contrib_model_param_for_norm_fp32 is not None:
gnorm = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [self._contrib_model_param_for_norm_fp32], True)[1]
return gnorm
def __compute_contrib_update_norm(self):
l2_norm = torch.zeros(size=[self._model_params_num], dtype=torch.float32, device='cuda')
local_contrib_l2_norm = multi_tensor_applier(self.multi_tensor_l2norm, self._overflow_buf, [self._contrib_update_frag_for_norm], True)[1] ** 2
l2_norm.scatter_(dim=0, index=self._offsets, src=local_contrib_l2_norm)
torch.distributed.all_reduce(l2_norm, group=self._ag_pg[0])
l2_norm = torch.sqrt(l2_norm)
return l2_norm
def _pipeline_step(self):
global_scale = self.global_scale
# if clip before ar, set max_grad_norm to 0
max_grad_norm = self.defaults['max_grad_norm'] * self._clip_after_ar
self._completion_st.wait_stream(self._l2_grad_norm_st)
global_grad_norm = self.L2_grad_norm
# check global_grad_norm and fill overflow_buf
is_finite = (global_grad_norm + 1 > global_grad_norm).int()
self._overflow_buf = self._one * (is_finite ^ self._one) # toggle between 0 and 1
if not self._clip_after_ar:
torch.distributed.all_reduce(is_finite,
op=torch.distributed.ReduceOp.MIN,
group=self._current_process_group)
torch.distributed.all_reduce(self._overflow_buf,
op=torch.distributed.ReduceOp.MAX,
group=self._current_process_group)
# increment step counter if no overflow
self._step += is_finite
self._completion_st.wait_stream(torch.cuda.current_stream())
self._completion_st.wait_stream(self._l2_grad_norm_st)
# Call step kernel once per step
# Call all-gather once per step
with torch.cuda.stream(self._completion_st):
for block_id in range(self._num_blocks):
for chunk_id in range(self._num_chunks):
self._reductions_works[block_id][chunk_id].wait()
param_norm = self.__compute_contrib_param_norm()
multi_tensor_applier(self.multi_tensor_lamb_compute_update_term,
self._overflow_buf,
self._contrib_compute_update_term_tensor_list, # g, p, m, v, u
self._contrib_beta1,
self._contrib_beta2,
self._contrib_beta3,
self._contrib_bias_correction,
self._step,
self._contrib_epsilon,
self._adam_w_mode,
self._contrib_weight_decay,
global_scale,
global_grad_norm,
max_grad_norm)
upd_norm = self.__compute_contrib_update_norm()
multi_tensor_applier(self.multi_tensor_lamb_update_weights,
self._overflow_buf,
self._contrib_update_weights_tensor_list, # u, p, p_copy
param_norm,
upd_norm,
self._offsets,
self._lr,
self._contrib_weight_decay,
global_grad_norm,
self._use_nvlamb)
if not self._skip_ag:
# allgather chunking is currently not supported for clip after allreduce
if not self._clip_after_ar:
for block in range(self._num_blocks):
for chunk in range(self._num_chunks):
if self._all_gather_no_copy:
torch.distributed.all_gather(
tensor_list = self._new_params2_shards[block][chunk],
tensor = self._fp16_p_chunks[block][chunk],
group = self._ag_pg[0],
no_copy = True,
)
else:
torch.distributed.all_gather_into_tensor(
output_tensor = self._new_params2_blocks[block],
input_tensor = self._fp16_p_chunks[block][chunk],
group = self._ag_pg[0],
)
else:
if self._all_gather_no_copy:
torch.distributed.all_gather(
tensor_list = self._new_params_mega_shards,
tensor = self._fp16_p,
group = self._ag_pg[0],
no_copy = True,
)
else:
torch.distributed.all_gather_into_tensor(
output_tensor = self._new_params,
input_tensor = self._fp16_p,
group = self._ag_pg[0],
)
def _flatten_grad_mt(self, scale):
if len(self._grads_fp16) > 0:
self._overflow_buf.zero_()
if not self._fused_norm:
multi_tensor_applier(
amp_C.multi_tensor_scale,
self._overflow_buf,
list(zip(*self._grads_fp16)),
scale)
else:
self._L2_grad_norm=multi_tensor_applier(
amp_C.multi_tensor_l2norm_scale,
self._overflow_buf,
list(zip(*self._grads_fp16)),
scale, False)[0].float()
self._grads_fp16 = []
if len(self._grads_fp32) > 0:
self._overflow_buf.zero_()
if not self._fused_norm:
multi_tensor_applier(
amp_C.multi_tensor_scale,
self._overflow_buf,
list(zip(*self._grads_fp32)),
scale)
else:
self._L2_grad_norm=multi_tensor_applier(
amp_C.multi_tensor_l2norm_scale,
self._overflow_buf,
list(zip(*self._grads_fp32)),
scale, False)[0].float()
self._grads_fp32 = []
def _do_overlapped_reduction(self, param_i, param):
if not self._is_accumulation_step:
# handle overlapped reductions
if param.dtype == torch.float16:
self._grads_fp16.append( (param.grad, self._individual_flat_grads[param_i]) )
else:
self._grads_fp32.append( (param.grad, self._individual_flat_grads[param_i]) )
self._grads_generated[param_i]=True
if not self._first_step and not self._last_step:
if self._overlap_reductions:
flush_block = self._get_flush_block()
while flush_block:
block_id = flush_block[0] // self._block_size
self._pipeline_block_reductions(block_id)
flush_block = self._get_flush_block()
def set_global_scale(self, global_scale):
"""Set global scale.
"""
self._global_scale = global_scale
@property
def global_scale(self):
return self._global_scale
@property
def L2_grad_norm(self):
torch.cuda.current_stream().wait_stream(self._l2_grad_norm_st)
return self._L2_grad_norm
def complete_reductions(self):
"""Complete reductions if full pipeline is not selected or overlap is not allowed.
"""
if self._last_step:
# zero out gradients that have not been completed yet
for param_i, grad_generated in enumerate(self._grads_generated):
if not grad_generated:
grad_info = self._grads_info[param_i]
param_offset = grad_info["param_offset"]
param_size = grad_info["param_grads_size"]
self._flat_grads[param_offset:param_offset+param_size].zero_()
self._grads_generated[param_i] = True
if self._first_step or self._last_step or not self._overlap_reductions:
# nothing done so far, run full pipeline after reductions
for block_id in range(self._num_blocks-1,-1,-1):
self._pipeline_block_reductions(block_id)
torch.cuda.current_stream().wait_stream(self._l2_grad_norm_st)
self._current_block = self._num_blocks
self._grads_generated = [False]*len(self._grads_info)
def step(self, closure=None, grad_scaler=None):
loss = None
if closure is not None:
loss = closure()
self._pipeline_step()
if grad_scaler is not None:
found_inf = self._overflow_buf.float()
optimizer_state = grad_scaler._per_optimizer_states[id(self)]
current_device = torch.device('cuda', torch.cuda.current_device())
optimizer_state["found_inf_per_device"][current_device] = found_inf
self._completion_st.wait_stream(torch.cuda.current_stream())
if not self._set_flat_param_view:
with torch.cuda.stream(self._completion_st):
# Copy self._new_params to model params
with torch.no_grad():
if self._packed_flat_to_model_params_fp16 is not None:
multi_tensor_applier(
fused_adam_cuda.maybe_cast_mt,
self._overflow_buf,
self._packed_flat_to_model_params_fp16)
if self._packed_flat_to_model_params_fp32 is not None:
multi_tensor_applier(
fused_adam_cuda.maybe_cast_mt,
self._overflow_buf,
self._packed_flat_to_model_params_fp32)
torch.cuda.current_stream().wait_stream(self._completion_st)
self._reductions_works = [None]*self._num_blocks
self._allgather_works = [None]*self._num_blocks
return loss
def state_dict(self):
"""
Returns a dict containing the current state of this :class:`DistributedFusedAdam` instance.
Example::
checkpoint = {}
checkpoint['model'] = model.state_dict()
checkpoint['optimizer'] = optimizer.state_dict()
torch.save(checkpoint, "saved.pth")
"""
# save step, master weights and first/second moments
state_dict = {}
state_dict['step'] = self._step
state_dict['fp32_p'] = self._fp32_p
state_dict['fp32_m'] = self._fp32_m
state_dict['fp32_v'] = self._fp32_v
return state_dict
def load_state_dict(self, state_dict):
"""
Loads a state_dict created by an earlier call to state_dict().
If an DistributedFusedAdam instance was constructed from some ``init_optimizer``,
whose parameters in turn came from ``model``, it is expected that the user
will call ``model.load_state_dict()`` before
``optimizer.load_state_dict()`` is called.
Example::
model = torch.nn.Linear(D_in, D_out).cuda().half()
optimizer = torch.optim.SGD(model.parameters(), lr=1e-3)
optimizer = FP16_Optimizer(optimizer, static_loss_scale = 128.0)
...
checkpoint = torch.load("saved.pth")
model.load_state_dict(checkpoint['model'])
optimizer.load_state_dict(checkpoint['optimizer'])
"""
# restore step, master weights and first/second moments
self._step = state_dict['step']
self._fp32_p = state_dict['fp32_p'].to(device="cuda")
self._fp32_m = state_dict['fp32_m'].to(device="cuda")
self._fp32_v = state_dict['fp32_v'].to(device="cuda")
self._resume_from_checkpoint = True
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