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import glob
import logging
import re
import time
from collections import defaultdict
import os
import sys
import shutil
import types
import numpy as np
import torch
import torch.nn.functional as F
import torch.distributed as dist
from torch import nn
def tensors_to_scalars(metrics):
new_metrics = {}
for k, v in metrics.items():
if isinstance(v, torch.Tensor):
v = v.item()
if type(v) is dict:
v = tensors_to_scalars(v)
new_metrics[k] = v
return new_metrics
class AvgrageMeter(object):
def __init__(self):
self.reset()
def reset(self):
self.avg = 0
self.sum = 0
self.cnt = 0
def update(self, val, n=1):
self.sum += val * n
self.cnt += n
self.avg = self.sum / self.cnt
def collate_1d(values, pad_idx=0, left_pad=False, shift_right=False, max_len=None, shift_id=1):
"""Convert a list of 1d tensors into a padded 2d tensor."""
size = max(v.size(0) for v in values) if max_len is None else max_len
res = values[0].new(len(values), size).fill_(pad_idx)
def copy_tensor(src, dst):
assert dst.numel() == src.numel()
if shift_right:
dst[1:] = src[:-1]
dst[0] = shift_id
else:
dst.copy_(src)
for i, v in enumerate(values):
copy_tensor(v, res[i][size - len(v):] if left_pad else res[i][:len(v)])
return res
def collate_2d(values, pad_idx=0, left_pad=False, shift_right=False, max_len=None):
"""Convert a list of 2d tensors into a padded 3d tensor."""
size = max(v.size(0) for v in values) if max_len is None else max_len
res = values[0].new(len(values), size, values[0].shape[1]).fill_(pad_idx)
def copy_tensor(src, dst):
assert dst.numel() == src.numel()
if shift_right:
dst[1:] = src[:-1]
else:
dst.copy_(src)
for i, v in enumerate(values):
copy_tensor(v, res[i][size - len(v):] if left_pad else res[i][:len(v)])
return res
def _is_batch_full(batch, num_tokens, max_tokens, max_sentences):
if len(batch) == 0:
return 0
if len(batch) == max_sentences:
return 1
if num_tokens > max_tokens:
return 1
return 0
def batch_by_size(
indices, num_tokens_fn, max_tokens=None, max_sentences=None,
required_batch_size_multiple=1, distributed=False
):
"""
Yield mini-batches of indices bucketed by size. Batches may contain
sequences of different lengths.
Args:
indices (List[int]): ordered list of dataset indices
num_tokens_fn (callable): function that returns the number of tokens at
a given index
max_tokens (int, optional): max number of tokens in each batch
(default: None).
max_sentences (int, optional): max number of sentences in each
batch (default: None).
required_batch_size_multiple (int, optional): require batch size to
be a multiple of N (default: 1).
"""
max_tokens = max_tokens if max_tokens is not None else sys.maxsize
max_sentences = max_sentences if max_sentences is not None else sys.maxsize
bsz_mult = required_batch_size_multiple
if isinstance(indices, types.GeneratorType):
indices = np.fromiter(indices, dtype=np.int64, count=-1)
sample_len = 0
sample_lens = []
batch = []
batches = []
for i in range(len(indices)):
idx = indices[i]
num_tokens = num_tokens_fn(idx)
sample_lens.append(num_tokens)
sample_len = max(sample_len, num_tokens)
assert sample_len <= max_tokens, (
"sentence at index {} of size {} exceeds max_tokens "
"limit of {}!".format(idx, sample_len, max_tokens)
)
num_tokens = (len(batch) + 1) * sample_len
if _is_batch_full(batch, num_tokens, max_tokens, max_sentences):
mod_len = max(
bsz_mult * (len(batch) // bsz_mult),
len(batch) % bsz_mult,
)
batches.append(batch[:mod_len])
batch = batch[mod_len:]
sample_lens = sample_lens[mod_len:]
sample_len = max(sample_lens) if len(sample_lens) > 0 else 0
batch.append(idx)
if len(batch) > 0:
batches.append(batch)
return batches
def make_positions(tensor, padding_idx):
"""Replace non-padding symbols with their position numbers.
Position numbers begin at padding_idx+1. Padding symbols are ignored.
"""
# The series of casts and type-conversions here are carefully
# balanced to both work with ONNX export and XLA. In particular XLA
# prefers ints, cumsum defaults to output longs, and ONNX doesn't know
# how to handle the dtype kwarg in cumsum.
mask = tensor.ne(padding_idx).int()
return (
torch.cumsum(mask, dim=1).type_as(mask) * mask
).long() + padding_idx
def softmax(x, dim):
return F.softmax(x, dim=dim, dtype=torch.float32)
def unpack_dict_to_list(samples):
samples_ = []
bsz = samples.get('outputs').size(0)
for i in range(bsz):
res = {}
for k, v in samples.items():
try:
res[k] = v[i]
except:
pass
samples_.append(res)
return samples_
def load_ckpt(cur_model, ckpt_base_dir, prefix_in_ckpt='model', force=True, strict=True):
if os.path.isfile(ckpt_base_dir):
base_dir = os.path.dirname(ckpt_base_dir)
checkpoint_path = [ckpt_base_dir]
else:
base_dir = ckpt_base_dir
checkpoint_path = sorted(glob.glob(f'{base_dir}/model_ckpt_steps_*.ckpt'), key=
lambda x: int(re.findall(f'{base_dir}/model_ckpt_steps_(\d+).ckpt', x.replace('\\','/'))[0]))
if len(checkpoint_path) > 0:
checkpoint_path = checkpoint_path[-1]
state_dict = torch.load(checkpoint_path, map_location="cpu")["state_dict"]
state_dict = {k[len(prefix_in_ckpt) + 1:]: v for k, v in state_dict.items()
if k.startswith(f'{prefix_in_ckpt}.')}
if not strict:
cur_model_state_dict = cur_model.state_dict()
unmatched_keys = []
for key, param in state_dict.items():
if key in cur_model_state_dict:
new_param = cur_model_state_dict[key]
if new_param.shape != param.shape:
unmatched_keys.append(key)
print("| Unmatched keys: ", key, new_param.shape, param.shape)
for key in unmatched_keys:
del state_dict[key]
cur_model.load_state_dict(state_dict, strict=strict)
print(f"| load '{prefix_in_ckpt}' from '{checkpoint_path}'.")
else:
e_msg = f"| ckpt not found in {base_dir}."
if force:
assert False, e_msg
else:
print(e_msg)
def remove_padding(x, padding_idx=0):
if x is None:
return None
assert len(x.shape) in [1, 2]
if len(x.shape) == 2: # [T, H]
return x[np.abs(x).sum(-1) != padding_idx]
elif len(x.shape) == 1: # [T]
return x[x != padding_idx]
class Timer:
timer_map = {}
def __init__(self, name, print_time=False):
if name not in Timer.timer_map:
Timer.timer_map[name] = 0
self.name = name
self.print_time = print_time
def __enter__(self):
self.t = time.time()
def __exit__(self, exc_type, exc_val, exc_tb):
Timer.timer_map[self.name] += time.time() - self.t
if self.print_time:
print(self.name, Timer.timer_map[self.name])
def print_arch(model, model_name='model'):
#print(f"| {model_name} Arch: ", model)
num_params(model, model_name=model_name)
def num_params(model, print_out=True, model_name="model"):
parameters = filter(lambda p: p.requires_grad, model.parameters())
parameters = sum([np.prod(p.size()) for p in parameters]) / 1_000_000
if print_out:
print(f'| {model_name} Trainable Parameters: %.3fM' % parameters)
return parameters
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