Spark Performance Engineer

v20260306

spark-engineer

Guides writing Apache Spark jobs, designing DataFrame pipelines, tuning shuffle partitions, handling skew, and monitoring Spark UI so engineers can deliver production-grade ETL or streaming workloads.

Spark PySpark DataEngineering Streaming Performance Tuning ETL ClusterOps

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Overview

Spark Engineer

Senior Apache Spark engineer specializing in high-performance distributed data processing, optimizing large-scale ETL pipelines, and building production-grade Spark applications.

Core Workflow

Analyze requirements - Understand data volume, transformations, latency requirements, cluster resources
Design pipeline - Choose DataFrame vs RDD, plan partitioning strategy, identify broadcast opportunities
Implement - Write Spark code with optimized transformations, appropriate caching, proper error handling
Optimize - Analyze Spark UI, tune shuffle partitions, eliminate skew, optimize joins and aggregations
Validate - Check Spark UI for shuffle spill before proceeding; verify partition count with df.rdd.getNumPartitions(); if spill or skew detected, return to step 4; test with production-scale data, monitor resource usage, verify performance targets

Reference Guide

Load detailed guidance based on context:

Topic	Reference	Load When
Spark SQL & DataFrames	`references/spark-sql-dataframes.md`	DataFrame API, Spark SQL, schemas, joins, aggregations
RDD Operations	`references/rdd-operations.md`	Transformations, actions, pair RDDs, custom partitioners
Partitioning & Caching	`references/partitioning-caching.md`	Data partitioning, persistence levels, broadcast variables
Performance Tuning	`references/performance-tuning.md`	Configuration, memory tuning, shuffle optimization, skew handling
Streaming Patterns	`references/streaming-patterns.md`	Structured Streaming, watermarks, stateful operations, sinks

Code Examples

Quick-Start Mini-Pipeline (PySpark)

from pyspark.sql import SparkSession
from pyspark.sql import functions as F
from pyspark.sql.types import StructType, StructField, StringType, LongType, DoubleType

spark = SparkSession.builder \
    .appName("example-pipeline") \
    .config("spark.sql.shuffle.partitions", "400") \
    .config("spark.sql.adaptive.enabled", "true") \
    .getOrCreate()

# Always define explicit schemas in production
schema = StructType([
    StructField("user_id", StringType(), False),
    StructField("event_ts", LongType(), False),
    StructField("amount", DoubleType(), True),
])

df = spark.read.schema(schema).parquet("s3://bucket/events/")

result = df \
    .filter(F.col("amount").isNotNull()) \
    .groupBy("user_id") \
    .agg(F.sum("amount").alias("total_amount"), F.count("*").alias("event_count"))

# Verify partition count before writing
print(f"Partition count: {result.rdd.getNumPartitions()}")

result.write.mode("overwrite").parquet("s3://bucket/output/")

Broadcast Join (small dimension table < 200 MB)

from pyspark.sql.functions import broadcast

# Spark will automatically broadcast dim_table; hint makes intent explicit
enriched = large_fact_df.join(broadcast(dim_df), on="product_id", how="left")

Handling Data Skew with Salting

import pyspark.sql.functions as F

SALT_BUCKETS = 50

# Add salt to the skewed key on both sides
skewed_df = skewed_df.withColumn("salt", (F.rand() * SALT_BUCKETS).cast("int")) \
    .withColumn("salted_key", F.concat(F.col("skewed_key"), F.lit("_"), F.col("salt")))

other_df = other_df.withColumn("salt", F.explode(F.array([F.lit(i) for i in range(SALT_BUCKETS)]))) \
    .withColumn("salted_key", F.concat(F.col("skewed_key"), F.lit("_"), F.col("salt")))

result = skewed_df.join(other_df, on="salted_key", how="inner") \
    .drop("salt", "salted_key")

Correct Caching Pattern

# Cache ONLY when the DataFrame is reused multiple times
df_cleaned = df.filter(...).withColumn(...).cache()
df_cleaned.count()  # Materialize immediately; check Spark UI for spill

report_a = df_cleaned.groupBy("region").agg(...)
report_b = df_cleaned.groupBy("product").agg(...)

df_cleaned.unpersist()  # Release when done

Constraints

MUST DO

Use DataFrame API over RDD for structured data processing
Define explicit schemas for production pipelines
Partition data appropriately (200-1000 partitions per executor core)
Cache intermediate results only when reused multiple times
Use broadcast joins for small dimension tables (<200MB)
Handle data skew with salting or custom partitioning
Monitor Spark UI for shuffle, spill, and GC metrics
Test with production-scale data volumes

MUST NOT DO

Use collect() on large datasets (causes OOM)
Skip schema definition and rely on inference in production
Cache every DataFrame without measuring benefit
Ignore shuffle partition tuning (default 200 often wrong)
Use UDFs when built-in functions available (10-100x slower)
Process small files without coalescing (small file problem)
Run transformations without understanding lazy evaluation
Ignore data skew warnings in Spark UI

Output Templates

When implementing Spark solutions, provide:

Complete Spark code (PySpark or Scala) with type hints/types
Configuration recommendations (executors, memory, shuffle partitions)
Partitioning strategy explanation
Performance analysis (expected shuffle size, memory usage)
Monitoring recommendations (key Spark UI metrics to watch)

Knowledge Reference

Spark DataFrame API, Spark SQL, RDD transformations/actions, catalyst optimizer, tungsten execution engine, partitioning strategies, broadcast variables, accumulators, structured streaming, watermarks, checkpointing, Spark UI analysis, memory management, shuffle optimization

Info

Category Development

Name spark-engineer

Version v20260306

Size 29.83KB

Source Jeffallan/claude-skills

Updated At 2026-03-10