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# Copyright Lightning AI. Licensed under the Apache License 2.0, see LICENSE file.
from typing import Any, Literal, Optional
import torch
# import torch._dynamo.config
# import torch._inductor.config
from litgpt.model import GPT
from utils.snac_utils import layershift, snac_config
from tqdm import tqdm
def multinomial_num_samples_1(probs: torch.Tensor) -> torch.Tensor:
if torch._dynamo.is_compiling():
# Faster alternative to `torch.multinomial(probs, num_samples=1)` that is also CUDAGraph friendly
distribution = torch.empty_like(probs).exponential_(1)
return torch.argmax(probs / distribution, dim=-1, keepdim=True)
return torch.multinomial(probs, num_samples=1)
def sample_top_p(logits: torch.Tensor, top_p: float) -> torch.Tensor:
sorted_logits, sorted_indices = torch.sort(logits, descending=False)
cumulative_probs = sorted_logits.softmax(dim=-1).cumsum(dim=-1)
# Example:
# sorted_probs=[0.1, 0.15, 0.2, 0.25, 0.3] -> sorted_cumprobs=[0.1, 0.25, 0.45, 0.7, 1.0]
# sorted_indices_to_remove = [1, 1, 0, 0, 0] if top_p=0.7
sorted_indices_to_remove = cumulative_probs <= (1 - top_p)
# Keep at least 1 token always to prevent the case where no token is selected
# In this case the most probable one is always kept
sorted_indices_to_remove[-1:] = 0
indices_to_remove = sorted_indices_to_remove.scatter(
0, sorted_indices, sorted_indices_to_remove
)
logits = logits.masked_fill(indices_to_remove, float("-inf"))
return logits
def sample(
logits: torch.Tensor,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
) -> torch.Tensor:
if top_p < 0.0 or top_p > 1.0:
raise ValueError(f"top_p must be in [0, 1], got {top_p}")
logits = logits[0, -1]
# optionally crop the logits to only the top k options
if top_k is not None:
v, i = torch.topk(logits, min(top_k, logits.size(-1)))
# do not use `torch.where` as in nanogpt because it will repeat top-k collisions
logits = torch.full_like(logits, float("-inf")).scatter_(-1, i, v)
# optionally scale the logits and sample from a probability distribution
if temperature > 0.0 or top_p > 0.0:
if temperature > 0.0:
logits = logits / temperature
# optionally crop the logits to smallest set of logits with a cumulative probability above top_p
if top_p < 1.0:
logits = sample_top_p(logits, top_p)
probs = torch.nn.functional.softmax(logits, dim=-1)
return multinomial_num_samples_1(probs)
return torch.argmax(logits, dim=-1, keepdim=True)
def next_token(
model: GPT, input_pos: torch.Tensor, x: list, **kwargs: Any
) -> torch.Tensor:
input_pos = input_pos.to(model.device)
logits_a, logit_t = model(None, x, None, input_pos)
next_audio_tokens = []
for logit_a in logits_a:
next_a = sample(logit_a, **kwargs).to(dtype=x[0].dtype)
next_audio_tokens.append(next_a)
next_t = sample(logit_t, **kwargs).to(dtype=x[0].dtype)
return next_audio_tokens, next_t
def next_token_asr(
model: GPT,
input_pos: torch.Tensor,
audio_features: torch.tensor,
lens: int,
input_ids: list,
**kwargs: Any,
) -> torch.Tensor:
input_pos = input_pos.to(model.device)
input_ids = [input_id.to(model.device) for input_id in input_ids]
logits_a, logit_t = model(audio_features, input_ids, None, input_pos, whisper_lens=lens)
next_audio_tokens = []
for logit_a in logits_a:
next_a = sample(logit_a, **kwargs).to(dtype=input_ids[0].dtype)
next_audio_tokens.append(next_a)
next_t = sample(logit_t, **kwargs).to(dtype=input_ids[0].dtype)
return next_audio_tokens, next_t
def next_token_A1T2(
model: GPT,
audio_features: torch.tensor,
input_ids: list,
whisper_lens: int,
task: list,
input_pos: torch.Tensor,
**kwargs: Any,
) -> torch.Tensor:
input_pos = input_pos.to(model.device)
input_ids = [input_id.to(model.device) for input_id in input_ids]
logits_a, logit_t = model(
audio_features, input_ids, None, input_pos, whisper_lens=whisper_lens, task=task
)
next_audio_tokens = []
for logit_a in logits_a:
next_a = sample(logit_a, **kwargs).to(dtype=input_ids[0].dtype)
next_audio_tokens.append(next_a)
next_t = sample(logit_t, **kwargs).to(dtype=input_ids[0].dtype)
return next_audio_tokens, next_t
def next_token_A1T1(
model: GPT,
audio_features: torch.tensor,
input_ids: list,
whisper_lens: int,
task: list,
input_pos: torch.Tensor,
**kwargs: Any,
) -> torch.Tensor:
input_pos = input_pos.to(model.device)
input_ids = [input_id.to(model.device) for input_id in input_ids]
logits_a, logit_t = model(
audio_features, input_ids, None, input_pos, whisper_lens=whisper_lens, task=task
)
next_t = sample(logit_t, **kwargs).to(dtype=input_ids[0].dtype)
return next_t
def next_token_image_batch(model: GPT,
audio_features: torch.tensor,
clip_features: torch.tensor,
input_ids: list,
whisper_lens: int,
task: list,
input_pos: torch.Tensor,
**kwargs: Any) -> torch.Tensor:
input_pos = input_pos.to(model.device)
input_ids = [input_id.to(model.device) for input_id in input_ids]
logits_a,logit_t = model(audio_features, input_ids, clip_features,
input_pos, whisper_lens=whisper_lens, task=task)
for i in range(7):
logits_a[i] = logits_a[i][0].unsqueeze(0)
logit_t = logit_t[1].unsqueeze(0)
next_audio_tokens = []
for logit_a in logits_a:
next_a = sample(logit_a, **kwargs).to(dtype=input_ids[0].dtype)
next_audio_tokens.append(next_a)
next_t = sample(logit_t, **kwargs).to(dtype=input_ids[0].dtype)
return next_audio_tokens, next_t
# torch._dynamo.config.automatic_dynamic_shapes = True
# torch._inductor.config.triton.unique_kernel_names = True
# torch._inductor.config.coordinate_descent_tuning = True
# next_token = torch.compile(next_token, mode="reduce-overhead")
@torch.inference_mode()
def generate(
model: GPT,
input_ids: list,
max_returned_tokens: int,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
# print("eos_id_a:", eos_id_a)
# print("eos_id_t:", eos_id_t)
# print("pad_id:", pad_id)
"""
Takes a conditioning sequence (prompt) as input and continues to generate as many tokens as requested.
The implementation of this function is modified from A. Karpathy's nanoGPT.
Args:
model: The model to use.
prompt: Tensor of shape (T) with indices of the prompt sequence.
max_returned_tokens: The maximum number of tokens to return (given plus generated).
temperature: Scales the predicted logits by 1 / temperature.
top_k: If specified, only sample among the tokens with the k highest probabilities.
top_p: If specified, it represents the cumulative probability threshold to consider in the sampling process.
In top-p sampling, the next token is sampled from the highest probability tokens
whose cumulative probability exceeds the threshold `top_p`. When specified,
it must be `0 <= top_p <= 1`. Here, `top_p=0` is equivalent
to sampling the most probable token, while `top_p=1` samples from the whole distribution.
It can be used in conjunction with `top_k` and `temperature` with the following order
of application:
1. `top_k` sampling
2. `temperature` scaling
3. `top_p` sampling
For more details, see https://arxiv.org/abs/1904.09751
or https://huyenchip.com/2024/01/16/sampling.html#top_p
eos_id: If specified, stop generating any more token once the <eos> token is triggered.
include_prompt: If true (default) prepends the prompt (after applying the prompt style) to the output.
"""
T = input_ids[0].size(0)
device = input_ids[0].device
assert max_returned_tokens > T
if model.max_seq_length < max_returned_tokens - 1:
# rolling the kv cache based on the `input_pos` value would be necessary. However, doing so would introduce a
# data dependency on the `input_pos` tensor and impact model compilation. Since this setting is uncommon, we do
# not support it to avoid negatively impacting the overall speed
raise NotImplementedError(
f"max_seq_length {model.max_seq_length} needs to be >= {max_returned_tokens - 1}"
)
for input_id in input_ids:
input_id = [input_id]
(
tokens_A1,
tokens_A2,
tokens_A3,
tokens_A4,
tokens_A5,
tokens_A6,
tokens_A7,
tokens_T,
) = input_ids
tokens_A1_output = [tokens_A1]
tokens_A2_output = [tokens_A2]
tokens_A3_output = [tokens_A3]
tokens_A4_output = [tokens_A4]
tokens_A5_output = [tokens_A5]
tokens_A6_output = [tokens_A6]
tokens_A7_output = [tokens_A7]
tokens_T_output = [tokens_T]
list_output = [
tokens_A1_output,
tokens_A2_output,
tokens_A3_output,
tokens_A4_output,
tokens_A5_output,
tokens_A6_output,
tokens_A7_output,
tokens_T_output,
]
input_pos = torch.tensor([T], device=device)
model_input_ids = [
tokens_A1.view(1, -1),
tokens_A2.view(1, -1),
tokens_A3.view(1, -1),
tokens_A4.view(1, -1),
tokens_A5.view(1, -1),
tokens_A6.view(1, -1),
tokens_A7.view(1, -1),
tokens_T.view(1, -1),
]
tokens_A, token_T = next_token(
model,
torch.arange(0, T, device=device),
model_input_ids,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
for i in range(7):
list_output[i].append(tokens_A[i].clone())
list_output[7].append(token_T.clone())
# prepare the input for the next iteration
for i in range(7):
tokens_A[i] = tokens_A[i].clone() + shift + i * snac_config.padded_vocab_size
token_T = token_T.clone()
text_end = False
max_returned_tokens = 1000
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = [
token_a.view(1, -1).to(torch.int32) for token_a in tokens_A
] + [token_T.view(1, -1).to(torch.int32)]
tokens_A, token_T = next_token(
model,
input_pos,
model_input_ids,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if text_end:
token_T = torch.tensor([pad_id], device=device)
for i in range(7):
list_output[i].append(tokens_A[i].clone())
list_output[7].append(token_T.clone())
if tokens_A[-1] == eos_id_a:
break
if token_T == eos_id_t:
if generate_text:
break
text_end = True
for i in range(7):
tokens_A[i] = tokens_A[i].clone() + shift + i * snac_config.padded_vocab_size
token_T = token_T.clone()
input_pos = input_pos.add_(1)
for i in range(len(list_output)):
list_output[i] = torch.cat(list_output[i])
return list_output
@torch.inference_mode()
def generate_TA_BATCH(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 1000,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
assert max_returned_tokens > T
if model.max_seq_length < max_returned_tokens - 1:
raise NotImplementedError(
f"max_seq_length {model.max_seq_length} needs to be >= {max_returned_tokens - 1}"
)
input_pos = torch.tensor([T], device=device)
model_input_ids = input_ids
list_output = [[] for i in range(8)]
tokens_A, token_T = next_token_image_batch(
model,
audio_features.to(torch.float32).to(model.device),
None,
input_ids,
[T - 3, T - 3],
["A1T2", "A1T2"],
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
for i in range(7):
list_output[i].append(tokens_A[i].tolist()[0])
list_output[7].append(token_T.tolist()[0])
model_input_ids = [[] for i in range(8)]
for i in range(7):
tokens_A[i] = tokens_A[i].clone() + shift + i * snac_config.padded_vocab_size
model_input_ids[i].append(tokens_A[i].clone().to(device).to(torch.int32))
model_input_ids[i].append(torch.tensor([layershift(snac_config.end_of_audio, i)], device=device))
model_input_ids[i] = torch.stack(model_input_ids[i])
model_input_ids[-1].append(token_T.clone().to(torch.int32))
model_input_ids[-1].append(token_T.clone().to(torch.int32))
model_input_ids[-1] = torch.stack(model_input_ids[-1])
text_end = False
for _ in range(2, max_returned_tokens - T + 1):
tokens_A, token_T = next_token_image_batch(
model,
None,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if text_end:
token_T = torch.tensor([pad_id_t], device=device)
if tokens_A[-1] == eos_id_a:
break
if token_T == eos_id_t:
text_end = True
for i in range(7):
list_output[i].append(tokens_A[i].tolist()[0])
list_output[7].append(token_T.tolist()[0])
model_input_ids = [[] for i in range(8)]
for i in range(7):
tokens_A[i] = tokens_A[i].clone() + shift + i * snac_config.padded_vocab_size
model_input_ids[i].append(tokens_A[i].clone().to(device).to(torch.int32))
model_input_ids[i].append(
torch.tensor([layershift(snac_config.end_of_audio, i)], device=device)
)
model_input_ids[i] = torch.stack(model_input_ids[i])
model_input_ids[-1].append(token_T.clone().to(torch.int32))
model_input_ids[-1].append(token_T.clone().to(torch.int32))
model_input_ids[-1] = torch.stack(model_input_ids[-1])
input_pos = input_pos.add_(1)
return list_output
@torch.inference_mode()
def generate_TT(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 2048,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
output = []
token_T = next_token_A1T1(
model,
None,
input_ids,
None,
None,
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
output.append(token_T.clone().tolist()[0])
input_pos = torch.tensor([T], device=device)
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = []
for i in range(7):
model_input_ids.append(
torch.tensor([layershift(snac_config.end_of_audio, i)])
.view(1, -1)
.to(torch.int32)
.to(device)
)
model_input_ids.append(token_T.clone().view(1, -1).to(torch.int32).to(device))
token_T = next_token_A1T1(
model,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if token_T == eos_id_t:
break
output.append(token_T.clone().tolist()[0])
input_pos = input_pos.add_(1)
return output
@torch.inference_mode()
def generate_AT(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 2048,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
output = []
token_T = next_token_A1T1(
model,
audio_features.to(torch.float32).to(model.device),
input_ids,
[T - 3],
["AT"],
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
output.append(token_T.clone().tolist()[0])
input_pos = torch.tensor([T], device=device)
text_end = False
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = []
for i in range(7):
model_input_ids.append(
torch.tensor([layershift(snac_config.end_of_audio, i)])
.view(1, -1)
.to(torch.int32)
.to(device)
)
model_input_ids.append(token_T.clone().view(1, -1).to(torch.int32).to(device))
token_T = next_token_A1T1(
model,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if token_T == eos_id_t:
break
output.append(token_T.clone().tolist()[0])
input_pos = input_pos.add_(1)
return output
@torch.inference_mode()
def generate_TA(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 2048,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
output = [[] for _ in range(8)]
tokens_A, token_T = next_token_A1T2(
model,
None,
input_ids,
None,
None,
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
for i in range(7):
output[i].append(tokens_A[i].clone().tolist()[0])
output[7].append(token_T.clone().tolist()[0])
input_pos = torch.tensor([T], device=device)
text_end = False
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = []
for i in range(7):
model_input_ids.append(
layershift(tokens_A[i].clone(), i)
.view(1, -1)
.to(torch.int32)
.to(device)
)
model_input_ids.append(token_T.clone().view(1, -1).to(torch.int32).to(device))
tokens_A, token_T = next_token_A1T2(
model,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if text_end:
token_T = torch.tensor([pad_id_t], device=device)
if tokens_A[-1] == eos_id_a:
break
if token_T == eos_id_t:
text_end = True
for i in range(7):
output[i].append(tokens_A[i].clone().tolist()[0])
output[7].append(token_T.clone().tolist()[0])
input_pos = input_pos.add_(1)
return output
@torch.inference_mode()
def generate_AA(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 2048,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
output = [[] for _ in range(8)]
tokens_A, token_T = next_token_A1T2(
model,
audio_features.to(torch.float32).to(model.device),
input_ids,
[T - 3],
["A1T2"],
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
for i in range(7):
output[i].append(tokens_A[i].clone().tolist()[0])
output[7].append(token_T.clone().tolist()[0])
input_pos = torch.tensor([T], device=device)
text_end = False
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = []
for i in range(7):
model_input_ids.append(
layershift(tokens_A[i].clone(), i)
.view(1, -1)
.to(torch.int32)
.to(device)
)
model_input_ids.append(token_T.clone().view(1, -1).to(torch.int32).to(device))
tokens_A, token_T = next_token_A1T2(
model,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if text_end:
token_T = torch.tensor([pad_id_t], device=device)
if tokens_A[-1] == eos_id_a:
break
if token_T == eos_id_t:
# print("text_end")
text_end = True
for i in range(7):
output[i].append(tokens_A[i].clone().tolist()[0])
output[7].append(token_T.clone().tolist()[0])
input_pos = input_pos.add_(1)
return output
@torch.inference_mode()
def generate_ASR(
model: GPT,
audio_features: torch.Tensor,
input_ids: list,
leng,
task,
max_returned_tokens: int = 1200,
*,
temperature: float = 1.0,
top_k: Optional[int] = None,
top_p: float = 1.0,
eos_id_a: Optional[int] = None,
eos_id_t: Optional[int] = None,
pad_id_t: Optional[int] = None,
shift: Optional[int] = None,
include_prompt: bool = True,
generate_text=False,
) -> torch.Tensor:
T = input_ids[0].size(1)
device = input_ids[0].device
output = []
token_T = next_token_A1T1(
model,
audio_features.to(torch.float32).to(model.device),
input_ids,
[T - 3],
["asr"],
input_pos=torch.arange(0, T, device=device),
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
output.append(token_T.clone().tolist()[0])
input_pos = torch.tensor([T], device=device)
text_end = False
for _ in tqdm(range(2, max_returned_tokens - T + 1)):
model_input_ids = []
for i in range(7):
model_input_ids.append(
torch.tensor([layershift(snac_config.end_of_audio, i)])
.view(1, -1)
.to(torch.int32)
.to(device)
)
model_input_ids.append(token_T.clone().view(1, -1).to(torch.int32).to(device))
token_T = next_token_A1T1(
model,
None,
model_input_ids,
None,
None,
input_pos=input_pos,
temperature=temperature,
top_k=top_k,
top_p=top_p,
)
if token_T == eos_id_t:
break
output.append(token_T.clone().tolist()[0])
input_pos = input_pos.add_(1)
return output
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