Credit Default Prediction with XGBoost & NVIDIA RAPIDS#
In this tutorial, we will use NVIDIA RAPIDS cudf
DataFrame library for preprocessing
data and XGBoost, an optimized gradient boosting library, for credit default prediction.
We’ll learn how to declare NVIDIA A100
for our training function and ImageSpec
for specifying our python dependencies.
Run on Union Serverless
Once you have a Union account, install union
:
pip install union
Then run the following commands to run the workflow:
git clone https://github.com/unionai/unionai-examples
cd unionai-examples/tutorials/credit_default
union run --remote credit_default.py credit_default_wf
The source code for this tutorial can be found here .
Declaring workflow dependencies#
First, we start by importing all the dependencies that is required by this workflow:
import os
import gc
from pathlib import Path
from typing import Tuple
import fsspec
from flytekit import task, workflow, current_context, Resources, ImageSpec, Deck
from flytekit.types.file import FlyteFile
from flytekit.extras.accelerators import A100
We download the credit default dataset and return the dataset as two FlyteFile
s. With
cache=True
the results of this task will be cached. This means that downstream
tasks that use the data will use the cached version and do not need to re-download the
data again. For this example, we use a subset of the data so the task completes quickly.
@task(cache=True, cache_version="v5", requests=Resources(cpu="2", mem="4Gi"))
def download_data() -> Tuple[FlyteFile, FlyteFile]:
working_dir = Path(current_context().working_directory)
train_data = working_dir / "train.parquet"
train_label_data = working_dir / "train_label.parquet"
_download_file(
"https://github.com/thomasjpfan/credit-data/raw/main/train/part_0.parquet",
train_data,
)
_download_file(
"https://github.com/thomasjpfan/credit-data/raw/main/train_labels.parquet",
train_label_data,
)
return train_data, train_label_data
Defining Python Dependencies#
We use flytekit
’s ImageSpec
to specify the python packages that is required by the
XGBoost training task and preprocessing with cudf
.
credit_default_image = ImageSpec(
name="credit-default",
conda_packages=[
"cudf=24.08",
"scikit-learn==1.4.*",
"pytorch-cuda=12.1",
"pytorch==2.4.0",
],
packages=["union", "xgboost==2.1.1"],
conda_channels=["nvidia", "pytorch", "rapidsai"],
python_version="3.11",
registry=os.environ.get("IMAGE_SPEC_REGISTRY"),
)
Training with XGBoost with NVIDIA’s A100#
Next, we define our XGBoost training job using flytekit
’s @task
. We set the
container_image
to credit_default_image
so that this task runs with the required python
packages. We easily configure this task to run on A100
s by setting accelerator=A100
.
The training task uses RAPID’s cudf
DataFrame library for preprocessing and passed to
XGBoost
for training.
@task(
requests=Resources(gpu="1"),
accelerator=A100,
container_image=credit_default_image,
cache=True,
cache_version="v0",
)
def train_xgboost(
train_data: FlyteFile, train_labels: FlyteFile
) -> Tuple[FlyteFile, float]:
import cudf
train_data.download()
train_labels.download()
train_df = cudf.read_parquet(train_data.path)
train_labels = cudf.read_parquet(train_labels.path)
train = train_df.merge(train_labels, on="customer_ID", how="left")
X_train, y_train, X_test, y_test = prepare_for_training(train)
model = get_xgb_model()
model.fit(X_train, y_train, eval_set=[(X_test, y_test)], verbose=100)
ctx = current_context()
working_dir = Path(ctx.working_directory)
model_path = working_dir / "model.ubj"
model.save_model(model_path)
return model_path, model.best_score
Plot feature importances#
XGBoost’s feature importances represent the relative importance of each feature in making predictions. In this next task, we use a Flyte Deck to plot the feature importances with matplotlib:
matplotlib_image = ImageSpec(
"plot-xgboost",
packages=[
"xgboost==2.1.0",
"matplotlib==3.9.1",
"union",
"scikit-learn==1.4.*",
],
registry=os.environ.get("IMAGE_SPEC_REGISTRY"),
)
@task(container_image=matplotlib_image, enable_deck=True)
def plot_feature_importances(model: FlyteFile):
import matplotlib.pyplot as plt
from xgboost import plot_importance
model.download()
xgb_model = get_xgb_model()
xgb_model.load_model(model.path)
fig, ax = plt.subplots(figsize=(8, 6))
plot_importance(xgb_model, max_num_features=15, ax=ax)
importances_deck = Deck("Feature Importance", _fig_to_html(fig))
decks = current_context().decks
decks.insert(0, importances_deck)
Full Workflow#
Finally, we define the workflow that calls download_data
and passes it’s output
to train_xgboost
. We run the workflow by:
union run --remote credit_default.py credit_default_wf
@workflow
def credit_default_wf() -> Tuple[FlyteFile, float]:
train_data, train_labels = download_data()
model, best_score = train_xgboost(train_data=train_data, train_labels=train_labels)
plot_feature_importances(model=model)
return model, best_score
Appendix#
The following are helper functions used by our Flyte tasks. They include functions that download files, configure nvidia library, preprocessing data, and configuring the XGBoost model.
def _download_file(src, dest):
"""Download file from src to dest."""
with fsspec.open(src, mode="rb") as r:
with dest.open("wb") as w:
w.write(r.read())
def preprocess(df):
"""Preprocessing dataframe by dropping duplicates based on cid."""
return (
df.sort_values(["cid", "S_2"])
.drop_duplicates("cid", keep="last")
.sort_values("cid")
.reset_index(drop=True)
)
def prepare_for_training(train):
"""Split data into training and validation."""
train["cid"], _ = train.customer_ID.factorize()
mask = train["cid"] % 4 == 0
tr, va = train.loc[~mask], train.loc[mask]
tr = preprocess(tr)
va = preprocess(va)
# prepare for training
not_used = [
i for i in tr.columns if i in ["cid", "target", "S_2"] or tr[i].dtype == "O"
]
not_used += [
"B_30",
"B_38",
"D_114",
"D_116",
"D_117",
"D_120",
"D_126",
"D_63",
"D_64",
"D_66",
"D_68",
]
X_train = tr.drop(not_used, axis=1)
y_train = tr["target"]
X_test = va.drop(not_used, axis=1)
y_test = va["target"]
for i in X_train.columns:
X_train[i] = X_train[i].astype("float32")
X_test[i] = X_test[i].astype("float32")
del train, tr, va
gc.collect()
return X_train, y_train, X_test, y_test
def amex_metric_np(target, preds) -> float:
"""Custom metric based on the evaluation metric from
https://www.kaggle.com/competitions/amex-default-prediction/overview."""
import numpy as np
indices = np.argsort(preds)[::-1]
preds, target = preds[indices], target[indices]
weight = 20.0 - target * 19.0
cum_norm_weight = (weight / weight.sum()).cumsum()
four_pct_mask = cum_norm_weight <= 0.04
d = np.sum(target[four_pct_mask]) / np.sum(target)
weighted_target = target * weight
lorentz = (weighted_target / weighted_target.sum()).cumsum()
gini = ((lorentz - cum_norm_weight) * weight).sum()
n_pos = np.sum(target)
n_neg = target.shape[0] - n_pos
gini_max = 10 * n_neg * (n_pos + 20 * n_neg - 19) / (n_pos + 20 * n_neg)
g = gini / gini_max
return 0.5 * (g + d)
def get_xgb_model():
"""Create XGBoost model with amex_metric evaluation."""
import xgboost as xgb
max_depth = 7
num_trees = 1000
min_child_weight = 50
early_stop = xgb.callback.EarlyStopping(
rounds=10, maximize=True, metric_name="amex_metric_np", data_name="validation_0"
)
model = xgb.XGBClassifier(
tree_method="hist",
objective="binary:logistic",
max_depth=max_depth,
n_estimators=num_trees,
min_child_weight=min_child_weight,
eval_metric=amex_metric_np,
callbacks=[early_stop],
device="cuda",
)
return model
def _fig_to_html(fig) -> str:
"""Convert matplotlib figure to html."""
import io
import base64
fig_bytes = io.BytesIO()
fig.savefig(fig_bytes, format="jpg")
fig_bytes.seek(0)
image_base64 = base64.b64encode(fig_bytes.read()).decode()
return f'<img src="data:image/png;base64,{image_base64}" alt="Rendered Image" />'