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generate.py
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generate.py
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# Copyright (c) Meta Platforms, Inc. and affiliates.
# All rights reserved.
# This source code is licensed under the license found in the
# LICENSE file in the root directory of this source tree.
import itertools
import sys
import time
from pathlib import Path
from typing import Optional, Tuple
import torch
import torch._dynamo.config
import torch._inductor.config
def device_sync(device):
if "cuda" in device:
torch.cuda.synchronize(device)
elif ("cpu" in device) or ("mps" in device):
pass
else:
print(f"device={device} is not yet suppported")
torch._inductor.config.coordinate_descent_tuning = True
torch._inductor.config.triton.unique_kernel_names = True
torch._inductor.config.fx_graph_cache = True # Experimental feature to reduce compilation times, will be on by default in future
default_device = 'cuda' if torch.cuda.is_available() else 'cpu'
# support running without installing as a package
wd = Path(__file__).parent.parent.resolve()
sys.path.append(str(wd))
from model import Transformer
from tokenizer import get_tokenizer
def multinomial_sample_one_no_sync(probs_sort): # Does multinomial sampling without a cuda synchronization
q = torch.empty_like(probs_sort).exponential_(1)
return torch.argmax(probs_sort / q, dim=-1, keepdim=True).to(dtype=torch.int)
def logits_to_probs(logits, temperature: float = 1.0, top_k: Optional[int] = None):
logits = logits / max(temperature, 1e-5)
if top_k is not None:
v, _ = torch.topk(logits, min(top_k, logits.size(-1)))
pivot = v.select(-1, -1).unsqueeze(-1)
logits = torch.where(logits < pivot, -float("Inf"), logits)
probs = torch.nn.functional.softmax(logits, dim=-1)
return probs
def sample(logits, temperature: float = 1.0, top_k: Optional[int] = None):
probs = logits_to_probs(logits[0, -1], temperature, top_k)
idx_next = multinomial_sample_one_no_sync(probs)
return idx_next, probs
def prefill(model: Transformer, x: torch.Tensor, input_pos: torch.Tensor, **sampling_kwargs) -> torch.Tensor:
# input_pos: [B, S]
logits = model(x, input_pos)
return sample(logits, **sampling_kwargs)[0]
def decode_one_token(model: Transformer, x: torch.Tensor, input_pos: torch.Tensor, **sampling_kwargs) -> Tuple[torch.Tensor, torch.Tensor]:
# input_pos: [B, 1]
assert input_pos.shape[-1] == 1
logits = model(x, input_pos)
return sample(logits, **sampling_kwargs)
def decode_n_tokens(model: Transformer, cur_token: torch.Tensor, input_pos: torch.Tensor, num_new_tokens: int, callback=lambda _: _, **sampling_kwargs):
new_tokens, new_probs = [], []
for i in range(num_new_tokens):
with torch.backends.cuda.sdp_kernel(enable_flash=False, enable_mem_efficient=False, enable_math=True): # Actually better for Inductor to codegen attention here
next_token, next_prob = decode_one_token(
model, cur_token, input_pos, **sampling_kwargs
)
input_pos += 1
new_tokens.append(next_token.clone())
callback(new_tokens[-1])
new_probs.append(next_prob.clone())
cur_token = next_token.view(1, -1)
return new_tokens, new_probs
def model_forward(model, x, input_pos):
return model(x, input_pos)
def speculative_decode(
model: Transformer,
draft_model: Transformer,
cur_token: torch.Tensor,
input_pos: int,
speculate_k: int,
**sampling_kwargs
) -> torch.Tensor:
# draft model inference sequentially
device = cur_token.device
orig_input_pos = torch.tensor([input_pos], dtype=torch.int64, device=cur_token.device)
draft_tokens, draft_probs = decode_n_tokens(draft_model, cur_token.view(1, -1), orig_input_pos.clone(), speculate_k, **sampling_kwargs)
draft_tokens = torch.cat(draft_tokens)
# parallel inference on target model using draft tokens
target_logits = model_forward(
model,
torch.cat([cur_token.view(1), draft_tokens]).view(1, -1),
torch.arange(input_pos, input_pos + speculate_k + 1, device=cur_token.device)
)
target_probs = logits_to_probs(target_logits[0], **sampling_kwargs)
draft_probs = torch.stack(draft_probs)
# q: target prob, p: draft prob
# q >= p: always accept draft token
# q < p: q/p prob to accept draft token
p = draft_probs[torch.arange(0, speculate_k, device=device), draft_tokens]
q = target_probs[torch.arange(0, speculate_k, device=device), draft_tokens]
accept_draft_prob = torch.minimum(torch.ones(()), q[:speculate_k]/ p)
rejected_locations = (torch.rand_like(accept_draft_prob) > accept_draft_prob).nonzero()
if rejected_locations.shape[0] == 0: # All draft tokens have been accepted
accept_length = speculate_k + 1
last_token = multinomial_sample_one_no_sync(target_probs[-1])
# fill last token into draft model
model_forward(
draft_model,
draft_tokens[-1].view(1, -1),
orig_input_pos + speculate_k,
)
return torch.cat([draft_tokens, last_token])
else:
accept_length = rejected_locations[0].item()
p = draft_probs[accept_length]
q = target_probs[accept_length]
new = q - p
new = torch.where(new > 0, new, 0.0)
new = new / new.sum()
next_token = multinomial_sample_one_no_sync(new)
return torch.cat([draft_tokens[:accept_length], next_token])
@torch.no_grad()
def generate(
model: Transformer,
prompt: torch.Tensor,
max_new_tokens: int,
*,
interactive: bool,
draft_model: Transformer,
speculate_k: Optional[int] = 8,
callback = lambda x: x,
**sampling_kwargs
) -> torch.Tensor:
"""
Takes a conditioning sequence (prompt) as input and continues to generate as many tokens as requested.
"""
is_speculative = draft_model is not None
# create an empty tensor of the expected final shape and fill in the current tokens
T = prompt.size(0)
T_new = T + max_new_tokens
if interactive:
max_seq_length = 350
else:
max_seq_length = min(T_new, model.config.block_size)
device, dtype = prompt.device, prompt.dtype
max_seq_length = max_seq_length + speculate_k + 1 if is_speculative else max_seq_length
with torch.device(device):
model.setup_caches(max_batch_size=1, max_seq_length=max_seq_length)
if is_speculative and draft_model is not model:
draft_model.setup_caches(max_batch_size=1, max_seq_length=max_seq_length)
# create an empty tensor of the expected final shape and fill in the current tokens
empty = torch.empty(T_new, dtype=dtype, device=device)
empty[:T] = prompt
seq = empty
input_pos = torch.arange(0, T, device=device)
next_token = prefill(model, prompt.view(1, -1), input_pos, **sampling_kwargs).clone()
if is_speculative:
prefill(draft_model, prompt.view(1, -1), input_pos, **sampling_kwargs)
seq[T] = next_token
input_pos = torch.tensor([T], device=device, dtype=torch.int)
accept_counts = [0] * (speculate_k + 1)
if is_speculative:
input_pos = input_pos.item() # for speculative decoding easier to keep on host
while input_pos < T_new - 1:
cur_token = next_token.view(())
next_tokens = speculative_decode(
model, draft_model, cur_token, input_pos, speculate_k, **sampling_kwargs
)
accept_counts[len(next_tokens) - 1] += 1
num_added = min(T_new - input_pos - 1, len(next_tokens))
seq[input_pos + 1 : input_pos + num_added + 1] = next_tokens[: num_added]
for i in next_tokens[: num_added,]:
callback(i)
input_pos = input_pos + num_added
next_token = next_tokens[-1]
else:
generated_tokens, _ = decode_n_tokens(model, next_token.view(1, -1), input_pos, max_new_tokens - 1, callback=callback, **sampling_kwargs)
seq[T + 1:] = torch.cat(generated_tokens)
generate_stats = {
'accept_counts': accept_counts
}
return seq, generate_stats
def encode_tokens(tokenizer, string, bos=True, device=default_device):
tokens = tokenizer.encode(string)
if bos:
tokens = [tokenizer.bos_id()] + tokens
return torch.tensor(tokens, dtype=torch.int, device=device)
def _load_model(checkpoint_path, device, precision, use_tp):
use_cuda = 'cuda' in device
with torch.device('meta'):
model = Transformer.from_name(checkpoint_path.parent.name)
if "int8" in str(checkpoint_path):
print("Using int8 weight-only quantization!")
from quantize import WeightOnlyInt8QuantHandler
simple_quantizer = WeightOnlyInt8QuantHandler(model)
model = simple_quantizer.convert_for_runtime()
if "int4" in str(checkpoint_path):
print("Using int4 weight-only quantization!")
path_comps = checkpoint_path.name.split(".")
groupsize = int(path_comps[-2][1:])
from quantize import WeightOnlyInt4QuantHandler
simple_quantizer = WeightOnlyInt4QuantHandler(model, groupsize)
model = simple_quantizer.convert_for_runtime()
checkpoint = torch.load(str(checkpoint_path), mmap=True, weights_only=True)
if "model" in checkpoint and "stories" in str(checkpoint_path):
checkpoint = checkpoint["model"]
model.load_state_dict(checkpoint, assign=True)
if use_tp:
from tp import apply_tp
print("Applying tensor parallel to model ...")
apply_tp(model)
model = model.to(device=device, dtype=precision)
return model.eval()
def _get_model_size(model):
model_size = 0
for name, child in model.named_children():
if not isinstance(child, torch.nn.Embedding):
model_size += sum(
[
p.numel() * p.dtype.itemsize
for p in itertools.chain(child.parameters(), child.buffers())
]
)
return model_size
B_INST, E_INST = "[INST]", "[/INST]"
def main(
prompt: str = "Hello, my name is",
interactive: bool = False,
num_samples: int = 5,
max_new_tokens: int = 100,
top_k: int = 200,
temperature: float = 0.8,
checkpoint_path: Path = Path("checkpoints/meta-Transformer/Transformer-2-7b-chat-hf/model.pth"),
compile: bool = True,
compile_prefill: bool = False,
profile: Optional[Path] = None,
draft_checkpoint_path: Optional[Path] = None,
speculate_k: int = 5,
device=default_device,
) -> None:
"""Generates text samples based on a pre-trained Transformer model and tokenizer.
"""
assert checkpoint_path.is_file(), checkpoint_path
tokenizer_path = checkpoint_path.parent / "tokenizer.model"
assert tokenizer_path.is_file(), str(tokenizer_path)
global print
from tp import maybe_init_dist
rank = maybe_init_dist()
use_tp = rank is not None
if use_tp:
if rank != 0:
# only print on rank 0
print = lambda *args, **kwargs: None
print(f"Using device={device}")
precision = torch.bfloat16
is_speculative = draft_checkpoint_path is not None
is_chat = "chat" in str(checkpoint_path)
print("Loading model ...")
t0 = time.time()
model = _load_model(checkpoint_path, device, precision, use_tp)
if is_speculative:
draft_model = _load_model(draft_checkpoint_path, device, precision, use_tp)
else:
draft_model = None
device_sync(device=device) # MKG
print(f"Time to load model: {time.time() - t0:.02f} seconds")
tokenizer = get_tokenizer(tokenizer_path, checkpoint_path)
encoded = encode_tokens(tokenizer, prompt, bos=True, device=device)
prompt_length = encoded.size(0)
torch.manual_seed(1234)
model_size = _get_model_size(model)
if compile:
if is_speculative and use_tp: # and ("cuda" in device):
torch._inductor.config.triton.cudagraph_trees = False # Bug with cudagraph trees in this case
if is_speculative:
global model_forward, logits_to_prob
model_forward = torch.compile(model_forward, mode="reduce-overhead", fullgraph=True)
global decode_one_token, prefill
decode_one_token = torch.compile(decode_one_token, mode="reduce-overhead", fullgraph=True)
# Uncomment to squeeze more perf out of prefill
if compile_prefill:
prefill = torch.compile(prefill, fullgraph=True, dynamic=True)
aggregate_metrics = {
'tokens_per_sec': [],
'accept_counts': [],
}
start = -1 if compile else 0
for i in range(start, num_samples):
device_sync(device=device) # MKG
if i >= 0 and interactive:
prompt = input("What is your prompt? ")
if is_chat:
prompt = f"{B_INST} {prompt.strip()} {E_INST}"
encoded = encode_tokens(tokenizer, prompt, bos=True, device=device)
if interactive and i >= 0:
buffer = []
period_id = tokenizer.encode('.')[0]
done_generating = False
def callback(x):
nonlocal done_generating
if done_generating:
return
buffer.append(tokenizer.decode([period_id] + x.tolist())[1:])
if x.item() == tokenizer.eos_id():
done_generating = True
if len(buffer) == 4 or done_generating:
print(''.join(buffer), end='', flush=True)
buffer.clear()
# print(, end='', flush=True)
else:
callback = lambda x : x
t0 = time.perf_counter()
import contextlib
if (i != num_samples - 1 or not profile) or (use_tp and rank != 0):
prof = contextlib.nullcontext()
else:
torch.profiler._utils._init_for_cuda_graphs()
prof = torch.profiler.profile()
with prof:
y, metrics = generate(
model,
encoded,
max_new_tokens,
draft_model=draft_model,
speculate_k=speculate_k,
interactive=interactive,
callback=callback,
temperature=temperature,
top_k=top_k,
)
aggregate_metrics['accept_counts'].append(metrics['accept_counts'])
if i == -1:
print(f"Compilation time: {time.perf_counter() - t0:.2f} seconds")
continue
if hasattr(prof, "export_chrome_trace"):
if use_tp:
prof.export_chrome_trace(f"{profile}_rank_{rank}.json")
else:
prof.export_chrome_trace(f"{profile}.json")
device_sync(device=device) # MKG
t = time.perf_counter() - t0
if not interactive:
print(tokenizer.decode(y.tolist()))
else:
print()
tokens_generated = y.size(0) - prompt_length
tokens_sec = tokens_generated / t
aggregate_metrics['tokens_per_sec'].append(tokens_sec)
print(f"Time for inference {i + 1}: {t:.02f} sec total, {tokens_sec:.02f} tokens/sec")
print(f"Bandwidth achieved: {model_size * tokens_sec / 1e9:.02f} GB/s")
print("==========")
if is_speculative:
counts_aggregated = [sum(i) for i in zip(*aggregate_metrics['accept_counts'])]
acceptance_probs = [i/sum(counts_aggregated) for i in counts_aggregated]
print(f"Acceptance probs: {acceptance_probs}")
print(f"Mean Accepted: {sum([idx * i for idx, i in enumerate(counts_aggregated)])/sum(counts_aggregated)}")
print(f"Average tokens/sec: {torch.mean(torch.tensor(aggregate_metrics['tokens_per_sec'])).item():.2f}")
print(f"Memory used: {torch.cuda.max_memory_reserved() / 1e9:.02f} GB")
if __name__ == '__main__':
import argparse
parser = argparse.ArgumentParser(description='Your CLI description.')
parser.add_argument('--prompt', type=str, default="Hello, my name is", help='Input prompt.')
parser.add_argument('--interactive', action='store_true', help='Whether to launch in interactive mode')
parser.add_argument('--num_samples', type=int, default=5, help='Number of samples.')
parser.add_argument('--max_new_tokens', type=int, default=200, help='Maximum number of new tokens.')
parser.add_argument('--top_k', type=int, default=200, help='Top-k for sampling.')
parser.add_argument('--temperature', type=float, default=0.8, help='Temperature for sampling.')
parser.add_argument('--checkpoint_path', type=Path, default=Path("checkpoints/meta-Transformer/Transformer-2-7b-chat-hf/model.pth"), help='Model checkpoint path.')
parser.add_argument('--compile', action='store_true', help='Whether to compile the model.')
parser.add_argument('--compile_prefill', action='store_true', help='Whether to compile the prefill (improves prefill perf, but higher compile times)')
parser.add_argument('--profile', type=Path, default=None, help='Profile path.')
parser.add_argument('--speculate_k', type=int, default=5, help='Speculative execution depth.')
parser.add_argument('--draft_checkpoint_path', type=Path, default=None, help='Draft checkpoint path.')
parser.add_argument('--device', type=str, default=default_device, help='Device to use')
args = parser.parse_args()
main(
args.prompt, args.interactive, args.num_samples, args.max_new_tokens, args.top_k,
args.temperature, args.checkpoint_path, args.compile, args.compile_prefill, args.profile, args.draft_checkpoint_path,
args.speculate_k, args.device
)