Tensor Neural Engine Kompanion. An util library based on PyTorch and PyTorch Lightning.
Project description
TensorNeko
Tensor Neural Engine Kompanion. An util library based on PyTorch and PyTorch Lightning.
Install
pip install tensorneko
To use the library without PyTorch and PyTorch Lightning, you can install the util library (support Python 3.7 ~ 3.10) with following command.
pip install tensorneko_util
Neko Layers and Modules
Build an MLP with linear layers. The activation and normalization will be placed in the hidden layers.
784 -> 1024 -> 512 -> 10
import tensorneko as neko
import torch.nn
mlp = neko.module.MLP(
neurons=[784, 1024, 512, 10],
build_activation=torch.nn.ReLU,
build_normalization=[
lambda: torch.nn.BatchNorm1d(1024),
lambda: torch.nn.BatchNorm1d(512)
],
dropout_rate=0.5
)
Build a Conv2d with activation and normalization.
import tensorneko as neko
import torch.nn
conv2d = neko.layer.Conv2d(
in_channels=256,
out_channels=1024,
kernel_size=(3, 3),
padding=(1, 1),
build_activation=torch.nn.ReLU,
build_normalization=lambda: torch.nn.BatchNorm2d(256),
normalization_after_activation=False
)
All modules and layers
layers:
Concatenate
Conv
,Conv1d
,Conv2d
,Conv3d
Linear
Log
PatchEmbedding2d
PositionalEmbedding
Reshape
Stack
modules:
DenseBlock
InceptionModule
MLP
ResidualBlock
andResidualModule
AttentionModule
,TransformerEncoderBlock
andTransformerEncoder
Neko modules
All tensorneko.layer
and tensorneko.module
are NekoModule
. They can be used in
fn.py pipe operation.
from tensorneko.layer import Linear
from torch.nn import ReLU
import torch
linear0 = Linear(16, 128, build_activation=ReLU)
linear1 = Linear(128, 1)
f = linear0 >> linear1
print(f(torch.rand(16)).shape)
# torch.Size([1])
Neko IO
Easily load and save different modal data.
import tensorneko as neko
from tensorneko.io.text.text_reader import json_data
from typing import List
# read video (Temporal, Channel, Height, Width)
video_tensor, audio_tensor, video_info = neko.io.read.video.of("path/to/video.mp4")
# write video
neko.io.write.video.to("path/to/video.mp4",
video_tensor, video_info.video_fps,
audio_tensor, video_info.audio_fps
)
# read audio (Channel, Temporal)
audio_tensor, sample_rate = neko.io.read.audio.of("path/to/audio.wav")
# write audio
neko.io.write.audio.to("path/to/audio.wav", audio_tensor, sample_rate)
# read image (Channel, Height, Width) with float value in range [0, 1]
image_tensor = neko.io.read.image.of("path/to/image.png")
# write image
neko.io.write.image.to_png("path/to/image.png", image_tensor)
neko.io.write.image.to_jpeg("path/to/image.jpg", image_tensor)
# read plain text
text_string = neko.io.read.text.of("path/to/text.txt")
# write plain text
neko.io.write.text.to("path/to/text.txt", text_string)
# read json as DataFrame
json_df = neko.io.read.text.of_json("path/to/json.json", to_df=True)
# read json as an object
@json_data
class JsonData:
x: int
y: int
json_obj: List[JsonData] = neko.io.read.text.of_json("path/to/json.json", cls=List[JsonData])
# read json as a dict or list
json_dict = neko.io.read.text.of_json("path/to/json.json")
# write json
neko.io.write.text.to_json("path/to/json.json", json_dict)
Neko preprocessing
import tensorneko.preprocess.resize
import tensorneko as neko
# A video tensor with (120, 3, 720, 1280)
video = neko.io.read.video.of("example/video.mp4")
# Get a resized tensor with (120, 3, 256, 256)
tensorneko.preprocess.resize.resize_video(video, (256, 256))
All preprocessing utils
resize_video
resize_image
padding_video
padding_audio
Neko Visualization
Variable Web Watcher
Start a web server to watch the variable status when the program (e.g. training, inference, data preprocessing) is running.
import time
from tensorneko.visualization.watcher import *
data_list = ... # a list of data
def preprocessing(d): ...
# initialize the components
pb = ProgressBar("Processing", total=len(data_list))
logger = Logger("Log message")
var = Variable("Some Value", 0)
line_chart = LineChart("Line Chart", "x", "y")
view = View("Data preprocessing").add_all()
t0 = time.time()
# open server when the code block in running.
with Server(view, port=8000):
for i, data in enumerate(data_list):
preprocessing(data) # do some processing here
x = time.time() - t0 # time since the start of the program
y = i # processed number of data
line_chart.add(x, y) # add to the line chart
logger.log("Some messages") # log messages to the server
var.value = ... # keep tracking a variable
pb.add(1) # update the progress bar by add 1
When the script is running, go to 127.0.0.1:8000
to keep tracking the status.
Matplotlib wrappers
Display an image of (C, H, W) shape by plt.imshow
wrapper.
import tensorneko as neko
import matplotlib.pyplot as plt
image_tensor = ... # an image tensor with shape (C, H, W)
neko.visualization.matplotlib.imshow(image_tensor)
plt.show()
Predefined colors
Several aesthetic colors are predefined.
import tensorneko as neko
import matplotlib.pyplot as plt
# use with matplotlib
plt.plot(..., color=neko.visualization.Colors.RED)
# the palette for seaborn is also available
from tensorneko_util.visualization.seaborn import palette
import seaborn as sns
sns.set_palette(palette)
Neko Model
Build and train a simple model for classifying MNIST with MLP.
from typing import Optional, Union, Sequence, Dict, List
import torch.nn
from torch import Tensor
from torch.optim import Adam
from torchmetrics import Accuracy
from pytorch_lightning.callbacks import ModelCheckpoint
import tensorneko as neko
from tensorneko.util import get_activation, get_loss
class MnistClassifier(neko.NekoModel):
def __init__(self, name: str, mlp_neurons: List[int], activation: str, dropout_rate: float, loss: str,
learning_rate: float, weight_decay: float
):
super().__init__(name)
self.weight_decay = weight_decay
self.learning_rate = learning_rate
self.flatten = torch.nn.Flatten()
self.mlp = neko.module.MLP(
neurons=mlp_neurons,
build_activation=get_activation(activation),
dropout_rate=dropout_rate
)
self.loss_func = get_loss(loss)()
self.acc_func = Accuracy()
def forward(self, x):
# (batch, 28, 28)
x = self.flatten(x)
# (batch, 768)
x = self.mlp(x)
# (batch, 10)
return x
def training_step(self, batch: Optional[Union[Tensor, Sequence[Tensor]]] = None, batch_idx: Optional[int] = None,
optimizer_idx: Optional[int] = None, hiddens: Optional[Tensor] = None
) -> Dict[str, Tensor]:
x, y = batch
logit = self(x)
prob = logit.sigmoid()
loss = self.loss_func(logit, y)
acc = self.acc_func(prob.max(dim=1)[1], y)
return {"loss": loss, "acc": acc}
def validation_step(self, batch: Optional[Union[Tensor, Sequence[Tensor]]] = None, batch_idx: Optional[int] = None,
dataloader_idx: Optional[int] = None
) -> Dict[str, Tensor]:
x, y = batch
logit = self(x)
prob = logit.sigmoid()
loss = self.loss_func(logit, y)
acc = self.acc_func(prob.max(dim=1)[1], y)
return {"loss": loss, "acc": acc}
def configure_optimizers(self):
optimizer = Adam(self.parameters(), lr=self.learning_rate, betas=(0.5, 0.9), weight_decay=self.weight_decay)
return {
"optimizer": optimizer
}
model = MnistClassifier("mnist_mlp_classifier", [784, 1024, 512, 10], "ReLU", 0.5, "CrossEntropyLoss", 1e-4, 1e-4)
dm = ... # The MNIST datamodule from PyTorch Lightning
trainer = neko.NekoTrainer(log_every_n_steps=0, gpus=1, logger=model.name, precision=32,
checkpoint_callback=ModelCheckpoint(dirpath="./ckpt",
save_last=True, filename=model.name + "-{epoch}-{val_acc:.3f}", monitor="val_acc", mode="max"
))
trainer.fit(model, dm)
Neko Notebook Helpers
Here are some helper functions to better interact with Jupyter Notebook.
import tensorneko as neko
# display a video
neko.notebook.display.video("path/to/video.mp4")
# display an audio
neko.notebook.display.audio("path/to/audio.wav")
# display a code file
neko.notebook.display.code("path/to/code.java")
Neko Utilities
StringGetter
: Get PyTorch class from string.
import tensorneko as neko
activation = neko.util.get_activation("leakyRelu")()
__
: The arguments to pipe operator. (Inspired from fn.py)
from tensorneko.util import __, _
result = __(20) >> (_ + 1) >> (_ * 2) >> __.get
print(result)
# 42
Seq
: A collection wrapper for method chaining.
from tensorneko.util import Seq, _
# using method chaining
seq = Seq.of(1, 2, 3).map(_ + 1).filter(_ % 2 == 0).map(_ * 2).take(2).to_list()
# return [4, 8]
# using bit shift operator to chain the sequence
seq = Seq.of(1, 2, 3) << Seq.of(2, 3, 4) << [3, 4, 5]
# return Seq(1, 2, 3, 2, 3, 4, 3, 4, 5)
Option
: A monad for dealing with data.
from tensorneko.util import return_option
@return_option
def get_data():
if some_condition:
return 1
else:
return None
def process_data(n: int):
if condition(n):
return n
else:
return None
data = get_data()
data = data.map(process_data).get_or_else(-1) # if the response is None, return -1
Seed
: The universal seed for numpy
, torch
and Python random
.
from tensorneko.util import Seed
from torch.utils.data import DataLoader
# set seed to 42 for all numpy, torch and python random
Seed.set(42)
# Apply seed to parallel workers of DataLoader
DataLoader(
train_dataset,
batch_size=batch_size,
num_workers=num_workers,
worker_init_fn=Seed.get_loader_worker_init(),
generator=Seed.get_torch_generator()
)
dispatch
: Multi-dispatch implementation for Python.
To my knowledge, 3 popular multi-dispatch libraries still have critical limitations. plum doesn't support static methods, mutipledispatch doesn't support Python type annotation syntax and multimethod doesn't support default augments. TensorNeko can do it all.
from tensorneko.util import dispatch
class DispatchExample:
@staticmethod
@dispatch
def go() -> None:
print("Go0")
@staticmethod
@dispatch
def go(x: int) -> None:
print("Go1")
@staticmethod
@dispatch
def go(x: float, y: float = 1.0) -> None:
print("Go2")
@dispatch
def come(x: int) -> str:
return "Come1"
@dispatch.of(str)
def come(x) -> str:
return "Come2"
Utilities list:
reduce_dict_by
summarize_dict_by
identity
generate_inf_seq
compose
listdir
with_printed
with_printed_shape
is_bad_num
ifelse
dict_add
count_parameters
as_list
list_to_dict
ref
get_activation
get_loss
Seed
dispatch
__
Seq
return_option
andOption
AverageMeter
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