ml-pipeline
Designs and implements production-grade ML pipeline infrastructure: configures experiment tracking with MLflow or Weights & Biases, creates Kubeflow or Airflow DAGs for training orchestration, builds feature store schemas with Feast, deploys model registries, and automates retraining and validation workflows. Use when building ML pipelines, orchestrating training workflows, automating model lifecycle, implementing feature stores, managing experiment tracking systems, setting up DVC for data versioning, tuning hyperparameters, or configuring MLOps tooling like Kubeflow, Airflow, MLflow, or Prefect.
适合你,如果正在构建或维护ML训练与部署的基础设施
用别的 agent?下载 .zip 解压,把文件夹放进它的技能目录
~/.claude/skills/(项目级 .claude/skills/)~/.codex/skills/npx oh-my-skill add jeffallan/claude-skills/ml-pipelinecurl -fsSL https://oh-my-skill.com/install.sh | bash -s -- jeffallan/claude-skills/ml-pipelinenpx oh-my-skill verify jeffallan/claude-skills/ml-pipeline怎么用
商店整理自技能原文 · 版本 e8be415 · 表述以原文为准Claude 会帮你设计和实现生产级的机器学习流水线,包括配置实验跟踪、创建训练编排 DAG、构建特征存储、部署模型注册表,并自动化重新训练和验证流程。
当你需要构建 ML 流水线、编排训练工作流、自动化模型生命周期、实现特征存储、管理实验跟踪系统或配置 MLOps 工具时触发。
技能原文 SKILL.md
ML Pipeline Expert
Senior ML pipeline engineer specializing in production-grade machine learning infrastructure, orchestration systems, and automated training workflows.
Core Workflow
- Design pipeline architecture — Map data flow, identify stages, define interfaces between components
- Validate data schema — Run schema checks and distribution validation before any training begins; halt and report on failures
- Implement feature engineering — Build transformation pipelines, feature stores, and validation checks
- Orchestrate training — Configure distributed training, hyperparameter tuning, and resource allocation
- Track experiments — Log metrics, parameters, and artifacts; enable comparison and reproducibility
- Validate and deploy — Run model evaluation gates; implement A/B testing or shadow deployment before promotion
Reference Guide
Load detailed guidance based on context:
| Topic | Reference | Load When | |-------|-----------|-----------| | Feature Engineering | references/feature-engineering.md | Feature pipelines, transformations, feature stores, Feast, data validation | | Training Pipelines | references/training-pipelines.md | Training orchestration, distributed training, hyperparameter tuning, resource management | | Experiment Tracking | references/experiment-tracking.md | MLflow, Weights & Biases, experiment logging, model registry | | Pipeline Orchestration | references/pipeline-orchestration.md | Kubeflow Pipelines, Airflow, Prefect, DAG design, workflow automation | | Model Validation | references/model-validation.md | Evaluation strategies, validation workflows, A/B testing, shadow deployment |
Code Templates
MLflow Experiment Logging (minimal reproducible example)
import mlflow
import mlflow.sklearn
from sklearn.ensemble import RandomForestClassifier
from sklearn.model_selection import train_test_split
from sklearn.metrics import accuracy_score, f1_score
import numpy as np
# Pin random state for reproducibility
SEED = 42
np.random.seed(SEED)
mlflow.set_experiment("my-classifier-experiment")
with mlflow.start_run():
# Log all hyperparameters — never hardcode silently
params = {"n_estimators": 100, "max_depth": 5, "random_state": SEED}
mlflow.log_params(params)
model = RandomForestClassifier(**params)
model.fit(X_train, y_train)
preds = model.predict(X_test)
# Log metrics
mlflow.log_metric("accuracy", accuracy_score(y_test, preds))
mlflow.log_metric("f1", f1_score(y_test, preds, average="weighted"))
# Log and register the model artifact
mlflow.sklearn.log_model(model, artifact_path="model",
registered_model_name="my-classifier")
Kubeflow Pipeline Component (single-step template)
from kfp.v2 import dsl
from kfp.v2.dsl import component, Input, Output, Dataset, Model, Metrics
@component(base_image="python:3.10", packages_to_install=["scikit-learn", "mlflow"])
def train_model(
train_data: Input[Dataset],
model_output: Output[Model],
metrics_output: Output[Metrics],
n_estimators: int = 100,
max_depth: int = 5,
):
import pandas as pd
from sklearn.ensemble import RandomForestClassifier
import pickle, json
df = pd.read_csv(train_data.path)
X, y = df.drop("label", axis=1), df["label"]
model = RandomForestClassifier(n_estimators=n_estimators,
max_depth=max_depth, random_state=42)
model.fit(X, y)
with open(model_output.path, "wb") as f:
pickle.dump(model, f)
metrics_output.log_metric("train_samples", len(df))
@dsl.pipeline(name="training-pipeline")
def training_pipeline(data_path: str, n_estimators: int = 100):
train_step = train_model(n_estimators=n_estimators)
# Chain additional steps (validate, register, deploy) here
Data Validation Checkpoint (Great Expectations style)
import great_expectations as ge
def validate_training_data(df):
"""Run schema and distribution checks. Raise on failure — never skip."""
gdf = ge.from_pandas(df)
results = gdf.expect_column_values_to_not_be_null("label")
results &= gdf.expect_column_values_to_be_between("feature_1", 0, 1)
if not results["success"]:
raise ValueError(f"Data validation failed: {results['result']}")
return df # safe to proceed to training
Constraints
Always:
- Version all data, code, and models explicitly (DVC, Git tags, model registry)
- Pin dependencies and random seeds for reproducible training environments
- Log all hyperparameters, metrics, and artifacts to experiment tracking
- Validate data schema and distribution before training begins
- Use containerized environments; store credentials in secrets managers, never in code
- Implement error handling, retry logic, and pipeline alerting
- Separate training and inference code clearly
Never:
- Run training without experiment tracking or without logging hyperparameters
- Deploy a model without recorded validation metrics
- Use non-reproducible random states or skip data validation
- Ignore pipeline failures silently or mix credentials into pipeline code
Output Format
When implementing a pipeline, provide:
- Complete pipeline definition (Kubeflow DAG, Airflow DAG, or equivalent) — use the templates above as starting structure
- Feature engineering code with inline data validation calls
- Training script with MLflow (or equivalent) experiment logging
- Model evaluation code with explicit pass/fail thresholds
- Deployment configuration and rollback strategy
- Brief explanation of architecture decisions and reproducibility measures
Knowledge Reference
MLflow, Kubeflow Pipelines, Apache Airflow, Prefect, Feast, Weights & Biases, Neptune, DVC, Great Expectations, Ray, Horovod, Kubernetes, Docker, S3/GCS/Azure Blob, model registry patterns, feature store architecture, distributed training, hyperparameter optimization