| name | databricks-ml-training |
| description | Train ML models on Databricks. Use for: classification/regression/deep-learning (XGBoost, scikit-learn, LightGBM, PyTorch) with Optuna, @prod/@challenger aliases, batch scoring (spark_udf for plain models, fe.score_batch for feature-store-backed), custom PyFunc, custom ResponsesAgent (LangGraph + UC Function/Vector Search); UC feature tables + FeatureLookup + point-in-time joins + Lakebase online store; declarative Feature Views (create_feature, DeltaTableSource, RollingWindow/SlidingWindow/TumblingWindow, materialize_features, streaming Kafka features). NOT for: endpoint ops (databricks-model-serving), MLflow evaluation (databricks-mlflow-evaluation). |
| compatibility | Requires databricks CLI (>= v0.294.0) |
| metadata | {"version":"0.1.0"} |
| parent | databricks-core |
ML Training on Databricks
FIRST: Use the parent databricks-core skill for CLI basics, authentication, and profile selection.
Train with MLflow → register to Unity Catalog → consume the same artifact as either a batch Spark UDF over Delta or (when low-latency is required) a real-time serving endpoint.
Always train on Databricks (serverless job or notebook), never in the local Python process the agent is running in. Local training has no access to the silver tables, no MLflow tracking server, no UC registry path, and dies if the chat session drops — submit databricks jobs submit --no-wait (see "Train + deploy as a serverless job" below). Only fall back to local execution if the user explicitly asks for it.
If you need to deploy a real time model serving endpoint after the model is registered (creating endpoints, traffic config, version-swapping, querying, Foundation Model API endpoints), see databricks-model-serving.
| Consumption | When | How |
|---|
| Batch UDF | Dashboards, daily/hourly scores, predictions read by Genie/Dashboards or an app (often synced to a Lakebase table) | mlflow.pyfunc.spark_udf(...) → INSERT INTO gold_predictions. If the model was logged with fe.log_model(training_set=...), use fe.score_batch() instead — see the Feature Engineering section below. |
| Real-time endpoint | Score on a user action (fraud at authorization, rec at page load) — sub-100ms | mlflow.deployments.get_deploy_client() (classical) / agents.deploy() (agents). Endpoint lifecycle: see databricks-model-serving. |
Default Canonical flow
silver_<features> + silver_<labels>
▼
notebook (as a serverless job):
├── train with mlflow.autolog (XGBoost / sklearn / etc.)
├── mlflow.register_model → UC: {catalog}.{schema}.{model}
├── set_registered_model_alias(name, "prod", version)
└── spark_udf(@prod) over latest features → MERGE into gold_predictions
▼
gold_<entity>_predictions ◄── dashboards, apps, Genie read this
Feature-store-backed models diverge here. If training used fe.log_model(training_set=...), replace spark_udf(@prod) with fe.score_batch(model_uri, df=<keys_only>) — it auto-joins features via the model's registered feature lineage. See the Feature Engineering section below.
One notebook, one artifact. Re-running = retraining. Gold is where truth lives — read paths never call the model directly. Keep label-window logic (failure occurred within 7 days) in the notebook during dev; once stable, promote to a silver materialized view in SDP.
Train and register (the 90% case)
mlflow.autolog() captures params, metrics, code, and the model artifact for every run; registered_model_name=... auto-registers the best run to UC (auto-incremented version). Wrap training with Optuna so each trial is a child run and the best one is what gets registered.
Always mlflow.set_registry_uri("databricks-uc") — without it, models land in the deprecated workspace registry. The experiment's parent folder must exist — set_experiment does NOT auto-create it (fails with NOT_FOUND: Parent directory does not exist). Pre-create it once with databricks workspace mkdirs before the job runs.
databricks workspace mkdirs /Users/me@example.com/turbine_project
Use the Databricks notebook source format (# Databricks notebook source header, # COMMAND ---------- separators, # MAGIC %md/%sql magics for markdown/SQL cells):
import mlflow, mlflow.xgboost, optuna
from mlflow.tracking import MlflowClient
from xgboost import XGBClassifier
from sklearn.metrics import roc_auc_score
mlflow.set_registry_uri("databricks-uc")
mlflow.set_experiment("/Users/me@example.com/turbine_project/mlflow_experiment")
CATALOG, SCHEMA, NAME = "ai_demo_gen", "wind_farm", "turbine_failure"
FULL_NAME = f"{CATALOG}.{SCHEMA}.{NAME}"
mlflow.xgboost.autolog(log_input_examples=True)
def objective(trial):
params = {
"n_estimators": trial.suggest_int("n_estimators", 100, 400),
"max_depth": trial.suggest_int("max_depth", 3, 10),
"learning_rate": trial.suggest_float("learning_rate", 0.01, 0.3, log=True),
}
with mlflow.start_run(nested=True):
m = XGBClassifier(**params).fit(X_train, y_train)
return roc_auc_score(y_test, m.predict_proba(X_test)[:, 1])
with mlflow.start_run(run_name="hpo") as parent:
study = optuna.create_study(direction="maximize")
study.optimize(objective, n_trials=20)
with mlflow.start_run(run_name="best"):
best = XGBClassifier(**study.best_params).fit(X_train, y_train)
mlflow.log_metric("val_auc", study.best_value)
info = mlflow.xgboost.log_model(best, name="model", registered_model_name=FULL_NAME)
client = MlflowClient(registry_uri="databricks-uc")
client.set_registered_model_alias(FULL_NAME, "prod", info.registered_model_version)
Framework autolog: mlflow.{sklearn,xgboost,lightgbm,pytorch,tensorflow,spark}.autolog().
Aliases, not stages: UC dropped Staging/Production. Use movable @prod/@challenger; load with models:/{full_name}@prod. Promoting a new version is one set_registered_model_alias call.
Consume: batch scoring over Delta
The cheap, default path for models NOT backed by feature tables. Load the registered model as a Spark UDF and score a Delta table; write predictions to a gold table that downstream consumers read. For feature-store-backed models (logged with fe.log_model(training_set=...)), skip spark_udf entirely and use fe.score_batch() — see the Feature Engineering section.
import mlflow
from pyspark.sql import functions as F
predict = mlflow.pyfunc.spark_udf(
spark,
model_uri=f"models:/{FULL_NAME}@prod",
env_manager="local",
)
features = spark.table(f"{CATALOG}.{SCHEMA}.silver_turbine_features_latest")
feature_cols = [c for c in features.columns if c != "turbine_id"]
scored = features.withColumn("risk_score", predict(*[features[c] for c in feature_cols]))
scored.select("turbine_id", "risk_score", F.current_timestamp().alias("scored_at")) \
.write.mode("overwrite").saveAsTable(f"{CATALOG}.{SCHEMA}.gold_turbine_predictions")
For incremental scoring with history, MERGE into the predictions table instead of overwrite.
Real-time serving (when required)
After registering a model to UC, deploy it behind a Model Serving endpoint. The dev-side call is mlflow.deployments.get_deploy_client("databricks").create_endpoint(...) for classical ML or agents.deploy(...) for ResponsesAgents. First deploy is ~5 min for classical ML.
For endpoint create / update / version-swap, traffic config, AI Gateway, querying, the state.ready + state.config_update two-field readiness check, and Foundation Model API endpoints, see databricks-model-serving.
Train + deploy as a serverless job
Training notebooks run a few minutes (Optuna + UC register; endpoint warmup adds 5–15 min if you also deploy). Submit as a serverless one-time run so the CLI doesn't block. The notebook ends with dbutils.notebook.exit(json.dumps({...})) so the structured result (model_version, val_auc, endpoint_name) reaches .notebook_output.result.
databricks workspace import /Workspace/Users/me@example.com/turbine_project/train \
--file ./train_notebook.py --format SOURCE --language PYTHON --overwrite
RUN_ID=$(databricks jobs submit --no-wait --json '{
"run_name": "turbine-train-and-deploy",
"tasks": [{
"task_key": "train",
"notebook_task": {"notebook_path": "/Workspace/Users/me@example.com/turbine_project/train"},
"environment_key": "ml_env"
}],
"environments": [{
"environment_key": "ml_env",
"spec": {
"client": "4",
"dependencies": ["mlflow==3.1.0", "xgboost==2.1.3", "optuna==4.1.0", "scikit-learn==1.5.2"]
}
}]
}' | jq -r .run_id)
for _ in $(seq 60); do
STATE=$(databricks jobs get-run "$RUN_ID" | jq -r '.state.life_cycle_state // "UNKNOWN"')
echo "$(date +%H:%M:%S) $STATE"
[[ "$STATE" =~ ^(TERMINATED|SKIPPED|INTERNAL_ERROR)$ ]] && break
sleep 30
done
[[ "$STATE" =~ ^(TERMINATED|SKIPPED|INTERNAL_ERROR)$ ]] || { databricks jobs cancel-run "$RUN_ID"; exit 1; }
RESULT=$(databricks jobs get-run "$RUN_ID" | jq -r '.state.result_state // "UNKNOWN"')
echo "result_state=$RESULT"
[[ "$RESULT" == "SUCCESS" ]] || { echo "Run did not succeed"; exit 1; }
TASK_RUN_ID=$(databricks jobs get-run "$RUN_ID" | jq -r '.tasks[0].run_id')
databricks jobs get-run-output "$TASK_RUN_ID" | jq '.notebook_output.result'
Common jobs submit traps to be aware of: environments[].spec.client: "4" is required on serverless notebook tasks; use the TASK run_id (tasks[0].run_id) — NOT the submit run_id — for get-run-output; print() is unreliable on serverless one-time runs (use dbutils.notebook.exit(json.dumps(...))); jobs submit rejects tags. For the broader databricks-jobs skill, see databricks-jobs.
Custom pyfunc
When sklearn/XGBoost autolog isn't enough — custom preprocessing, multiple sub-models, external API calls, ensemble logic. See references/custom-pyfunc.md for a full worked example. Two non-obvious things:
python_model="path/to/file.py" (file path, not class instance) + mlflow.models.set_model(MyModel()) at the end of that file. This is the "Models from Code" pattern — the file is logged verbatim, no pickling of the class.
mlflow.models.predict(model_uri=..., input_data=..., env_manager="uv") before deploying. Catches missing deps before the endpoint does.
Custom GenAI agents
Hand-rolled ResponsesAgent (LangGraph + UC Function tools + Vector Search retrieval) — see references/genai-agents.md.
Prefer no-code authoring via databricks-agent-bricks (Knowledge Assistants, Supervisor Agents) unless the user explicitly needs a custom LangGraph agent.
Feature Engineering: Feature Store & Feature Views
When to reach for Feature Engineering (either flavor) instead of a plain Delta table: when the same feature must be computed identically at training and serving time (no training/serving skew), the feature is time-dependent and needs point-in-time joins against labels (no future leakage), the feature needs to be served with <10ms latency via an online store, or the feature is shared across models with lineage tracked in UC. If none apply, a plain UC table is enough — the sections below can be skipped.
Default: don't use Feature Engineering unless one of the reasons above clearly applies or the user explicitly asked for it. It adds build time and complexity (an extra Delta table layer for FeatureLookup; a materialization pipeline for Feature Views). If you're unsure, use plain UC tables and add Feature Engineering later when a concrete need surfaces.
Two flavors, one train/score path (create_training_set → fe.log_model → fe.score_batch):
FeatureLookup API — you own the feature tables (compute, write, refresh); bind them to a training set via FeatureLookup + FeatureEngineeringClient. Reach for it when the features already exist as Delta tables or you want direct control over how they are computed. See references/feature-store.md.
- Feature Views (declarative, Public Preview,
databricks-feature-engineering>=0.16.0) — Databricks owns compute, materialization (Delta offline + Lakebase online), and refresh from a spec you declare (create_feature over DeltaTableSource; RollingWindow/SlidingWindow/TumblingWindow; create_stream for Kafka features). Reach for it when the feature is a formula you want Databricks to keep fresh. See references/feature-views.md.
Gotchas (the ones that cost time)
| Trap | Fix |
|---|
| Model lands in workspace registry, not UC | mlflow.set_registry_uri("databricks-uc") before logging |
| Endpoint returns PERMISSION_DENIED at first query | Pass resources=[...] to log_model (covers UC functions, VS indexes, other endpoints, Lakebase) — see references/genai-agents.md#resources-that-need-passthrough-auth for the full list |
Used transition_model_version_stage | Stages are deprecated in UC. Use client.set_registered_model_alias(name, "prod", version) |
spark_udf rebuilds a virtualenv on every call | Pass env_manager="local" when training+scoring share a runtime |
pip_requirements mismatch crashes endpoint at load | Pin exact versions; or pull live with f"mlflow=={get_distribution('mlflow').version}" |
agents.deploy() produced a weirdly-named endpoint | Pass endpoint_name=... explicitly. Auto-derived name is agents_<catalog>-<schema>-<model> |
Endpoint-lifecycle gotchas (readiness two-state, version-swap, Serving-UI SP filter) live in databricks-model-serving.
Reference files
| File | Contents |
|---|
| references/custom-pyfunc.md | Single end-to-end custom pyfunc example: artifacts, signature, code_paths, log → register → deploy → query. |
| references/genai-agents.md | Custom LangGraph ResponsesAgent with UC Function + Vector Search tools. create_text_output_item gotcha and the resources=[...] passthrough-auth list. For no-code agents prefer databricks-agent-bricks. |
| references/feature-store.md | Feature Engineering in Unity Catalog (standard FeatureLookup API): FeatureEngineeringClient, create_table with timeseries_column, FeatureLookup with point-in-time joins, fe.log_model with lineage, fe.score_batch (replaces spark_udf for FE models), and Lakebase online store via publish_table. Requires databricks-feature-engineering>=0.16.0. |
| references/feature-views.md | Feature Views (declarative Feature Engineering, Public Preview): create_feature over DeltaTableSource, RollingWindow/SlidingWindow/TumblingWindow aggregations, materialize_features (offline + online), streaming features off Kafka via create_stream, point-in-time training sets, and the Feature Serving Endpoint. Requires databricks-feature-engineering>=0.16.0. |
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