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generate_samples.py
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generate_samples.py
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# coding=utf-8
# Copyright (c) 2019, NVIDIA CORPORATION. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Sample Generate GPT2"""
import os
import torch
import torch.nn.functional as F
import time
from datetime import datetime
from arguments import get_args
from pretrain_glm import initialize_distributed
from pretrain_glm import set_random_seed
from pretrain_glm import get_masks_and_position_ids
from utils import load_checkpoint
from configure_data import prepare_tokenizer
from generation_utils import BeamSearchScorer
import mpu
from train_utils import get_model
from generation_utils import top_k_logits
def setup_model(args):
"""Setup model and optimizer."""
model = get_model(args, model_type="generation")
# if args.deepspeed:
# print_rank_0("DeepSpeed is enabled.")
#
# model, _, _, _ = deepspeed.initialize(
# model=model,
# model_parameters=model.parameters(),
# args=args,
# mpu=mpu,
# dist_init_required=False
# )
if args.load_pretrained is not None:
args.no_load_optim = True
args.load = args.load_pretrained
_ = load_checkpoint(
model, None, None, args, no_load_rng=True)
# if args.deepspeed:
# model = model.module
return model
def get_batch(context_tokens, device, args):
tokens = context_tokens
tokens = tokens.view(args.batch_size, -1).contiguous()
tokens = tokens.to(device)
# Get the masks and postition ids.
if args.block_lm:
attention_mask = torch.tensor([tokens.size(1)], device=device, dtype=torch.long)
position_ids = torch.arange(tokens.size(1), device=device, dtype=torch.long)
if not args.no_block_position:
block_position_ids = torch.zeros(tokens.size(1), device=device, dtype=torch.long)
position_ids = torch.stack((position_ids, block_position_ids), dim=0)
position_ids = position_ids.unsqueeze(0)
else:
attention_mask, loss_mask, position_ids = get_masks_and_position_ids(
tokens,
args.eod_token,
reset_position_ids=False,
reset_attention_mask=False,
set_loss_mask=False,
mem_length=args.mem_length)
return tokens, attention_mask, position_ids
def sample_sequence(model, tokenizer, context_tokens, context_length, args, device, mems=None, end_tokens=None):
if not args.block_lm:
context_tokens, attention_mask, position_ids = get_batch(context_tokens, device, args)
tokens = torch.empty((args.num_beams, 0), device=context_tokens.device, dtype=torch.long)
else:
tokens = context_tokens.new_full((1, 1), tokenizer.get_command('sop').Id)
counter = 0
if mems is None:
mems = []
if end_tokens is None:
end_tokens = [args.eod_token]
if args.num_beams > 1:
beam_scorer = BeamSearchScorer(
batch_size=1,
max_length=args.out_seq_length,
num_beams=args.num_beams,
device=context_tokens.device,
length_penalty=args.length_penalty,
do_early_stopping=False,
)
beam_scores = torch.zeros(1, dtype=torch.float, device=context_tokens.device)
last_beam_num = 1
while counter < args.out_seq_length:
if counter == 0 and not args.block_lm:
next_token_logits, *mems = model(context_tokens, position_ids, attention_mask, *mems)
else:
if args.block_lm:
if args.no_block_position:
position_ids = context_tokens.new_full((last_beam_num, 1), context_length + counter)
else:
position_ids = context_tokens.new_ones(last_beam_num, 2, 1)
position_ids[:, 0] = context_length
position_ids[:, 1] = counter + 1
attention_mask = context_tokens.new_zeros([1], device=context_tokens.device, dtype=torch.long)
else:
position_ids = context_tokens.new_ones((last_beam_num, 1)) * (context_length + counter - 1)
attention_mask = context_tokens.new_ones(last_beam_num, 1, 1, args.mem_length + 1,
device=context_tokens.device, dtype=torch.float)
last_token = tokens[:, -1:]
next_token_logits, *mems = model(last_token, position_ids, attention_mask, *mems)
next_token_logits = next_token_logits[:, -1]
if args.num_beams > 1:
next_token_scores = F.log_softmax(next_token_logits, dim=-1)
next_token_scores = next_token_scores + beam_scores[:, None].expand_as(next_token_scores)
vocab_size = next_token_scores.shape[-1]
next_token_scores = next_token_scores.view(1, last_beam_num * vocab_size)
probs = F.softmax(next_token_scores, dim=-1)
next_tokens = torch.multinomial(probs, num_samples=2 * args.num_beams)
next_token_scores = torch.gather(next_token_scores, -1, next_tokens)
next_token_scores, _indices = torch.sort(next_token_scores, descending=True, dim=1)
next_tokens = torch.gather(next_tokens, -1, _indices)
next_indices = next_tokens // vocab_size
next_tokens = next_tokens % vocab_size
# stateless
tokens = tokens.expand((args.num_beams, -1))
beam_outputs = beam_scorer.process(
tokens,
next_token_scores,
next_tokens,
next_indices,
eos_token_id=end_tokens,
mems=mems
)
beam_scores = beam_outputs["next_beam_scores"]
beam_next_tokens = beam_outputs["next_beam_tokens"]
beam_idx = beam_outputs["next_beam_indices"]
beam_next_tokens = beam_next_tokens.unsqueeze(-1)
tokens = torch.cat([tokens[beam_idx, :], beam_next_tokens], dim=-1)
mems = [mem[beam_idx] for mem in mems] if mems else None
if beam_scorer.is_done:
break
last_beam_num = args.num_beams
else:
next_token_logits /= args.temperature
next_token_logits = top_k_logits(next_token_logits, top_k=args.top_k, top_p=args.top_p)
log_probs = F.softmax(next_token_logits, dim=-1)
prev = torch.multinomial(log_probs, num_samples=1)[0]
is_end = prev.item() in end_tokens
if is_end:
break
prev = prev.view(1, 1)
tokens = prev if tokens is None else torch.cat((tokens, prev), dim=1)
counter += 1
if not args.block_lm and mpu.get_model_parallel_rank() == 0 and counter % 16 == 0:
output_tokens_list = tokens.view(-1).contiguous()
decode_tokens = tokenizer.DecodeIds(output_tokens_list.tolist())
if mpu.get_model_parallel_rank() == 0 and (counter % 128 == 0 or is_end):
os.system('clear')
trim_decode_tokens = decode_tokens
print(trim_decode_tokens, flush=True)
if args.num_beams > 1:
tokens, mems, _ = beam_scorer.finalize(tokens, beam_scores, next_tokens, next_indices, eos_token_id=args.eod_token,
mems=mems)
return torch.cat((context_tokens, tokens), dim=1), mems
def read_context(tokenizer, args, output):
terminate_runs, skip_run = 0, 0
if mpu.get_model_parallel_rank() == 0:
while True:
raw_text = input("\nContext prompt (stop to exit) >>> ")
if not raw_text:
print('Prompt should not be empty!')
continue
if raw_text == "stop":
terminate_runs = 1
break
generation_mask = '[gMASK]' if args.task_mask else '[MASK]'
if args.block_lm and 'MASK]' not in raw_text:
raw_text += ' ' + generation_mask
output.write(raw_text)
context_tokens = tokenizer.EncodeAsIds(raw_text).tokenization
if args.block_lm:
context_tokens = [tokenizer.get_command('ENC').Id] + context_tokens
if not raw_text.endswith('[gMASK]'):
context_tokens = context_tokens + [tokenizer.get_command('eos').Id]
context_length = len(context_tokens)
if context_length >= args.seq_length:
print("\nContext length", context_length,
"\nPlease give smaller context than the window length!")
continue
break
else:
context_length = 0
terminate_runs_tensor = torch.cuda.LongTensor([terminate_runs])
torch.distributed.broadcast(terminate_runs_tensor, mpu.get_model_parallel_src_rank(),
group=mpu.get_model_parallel_group())
terminate_runs = terminate_runs_tensor[0].item()
if terminate_runs == 1:
return terminate_runs, None, None, None
context_length_tensor = torch.cuda.LongTensor([context_length])
torch.distributed.broadcast(context_length_tensor, mpu.get_model_parallel_src_rank(),
group=mpu.get_model_parallel_group())
context_length = context_length_tensor[0].item()
if mpu.get_model_parallel_rank() == 0:
context_tokens_tensor = torch.cuda.LongTensor(context_tokens)
else:
context_tokens_tensor = torch.cuda.LongTensor([0] * context_length)
torch.distributed.broadcast(context_tokens_tensor, mpu.get_model_parallel_src_rank(),
group=mpu.get_model_parallel_group())
if mpu.get_model_parallel_rank() != 0:
raw_text = tokenizer.DecodeIds(context_tokens_tensor.tolist())
return terminate_runs, raw_text, context_tokens_tensor, context_length
def generate_samples(model, tokenizer, args, device):
model.eval()
output_path = "./samples"
if not os.path.exists(output_path):
os.makedirs(output_path)
output_path = os.path.join(output_path, f"sample-{datetime.now().strftime('%m-%d-%H-%M')}.txt")
with torch.no_grad(), open(output_path, "w") as output:
while True:
torch.distributed.barrier(group=mpu.get_model_parallel_group())
terminate_runs, raw_text, context_tokens_tensor, context_length = read_context(tokenizer, args, output)
if terminate_runs == 1:
return
start_time = time.time()
if args.block_lm:
mems = []
tokens, attention_mask, position_ids = get_batch(context_tokens_tensor, device, args)
mask_tokens = ['MASK', 'sMASK', 'gMASK'] if args.task_mask else ['MASK']
mask_tokens = [tokenizer.get_command(token).Id for token in mask_tokens]
end_tokens = [tokenizer.get_command('eop').Id, args.eod_token]
mask_positions = []
for token in mask_tokens:
mask_positions += (context_tokens_tensor == token).nonzero(as_tuple=True)[0].tolist()
mask_positions.sort()
if args.no_block_position:
for mask_position in mask_positions:
position_ids[0, mask_position + 1:] += args.out_seq_length
_, *mems = model(tokens, position_ids, attention_mask, *mems)
for mask_position in mask_positions:
if args.no_block_position:
position = position_ids[0, mask_position].item()
else:
position = mask_position
tokens, mems = sample_sequence(model, tokenizer, tokens, position,
args, device, mems=mems, end_tokens=end_tokens)
else:
tokens, _ = sample_sequence(model, tokenizer, context_tokens_tensor, context_length, args, device)
output_tokens_list = tokens.view(-1).contiguous()
if mpu.get_model_parallel_rank() == 0:
os.system('clear')
print("\nTaken time {:.2f}\n".format(time.time() - start_time), flush=True)
print("\nContext:", raw_text, flush=True)
decode_tokens = tokenizer.DecodeIds(output_tokens_list[context_length:].tolist())
trim_decode_tokens = decode_tokens
print("\nGLM:", trim_decode_tokens, flush=True)
output.write(trim_decode_tokens + "\n")
torch.distributed.barrier(group=mpu.get_model_parallel_group())
def main():
"""Main training program."""
print('Generate Samples')
# Disable CuDNN.
torch.backends.cudnn.enabled = False
# Arguments.
args = get_args()
args.mem_length = args.seq_length + args.mem_length - 1
# Pytorch distributed.
initialize_distributed(args)
# Random seeds for reproducability.
set_random_seed(args.seed)
# get the tokenizer
tokenizer = prepare_tokenizer(args)
# Model, optimizer, and learning rate.
model = setup_model(args)
# setting default batch size to 1
args.batch_size = 1
# generate samples
generate_samples(model, tokenizer, args, torch.cuda.current_device())
if __name__ == "__main__":
main()