langfuse-performance-tuning
Optimize Langfuse tracing performance for high-throughput applications. Use when experiencing latency issues, optimizing trace overhead, or scaling Langfuse for production workloads. Trigger with phrases like "langfuse performance", "optimize langfuse", "langfuse latency", "langfuse overhead", "langfuse slow".
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langfuse-pack
Claude Code skill pack for Langfuse LLM observability (24 skills)
Installation
This skill is included in the langfuse-pack plugin:
/plugin install langfuse-pack@claude-code-plugins-plusClick to copy
Instructions
Langfuse Performance Tuning
Overview
Optimize Langfuse tracing for minimal overhead and maximum throughput: benchmark measurement, batch tuning, non-blocking patterns, payload optimization, sampling, and memory management.
Prerequisites
- Existing Langfuse integration
- Performance baseline to compare against
- Understanding of async patterns
Performance Targets
| Metric | Target | Critical |
|---|---|---|
| Trace creation overhead | < 1ms | < 5ms |
| Flush latency (batch) | < 100ms | < 500ms |
| Memory per active trace | < 1KB | < 5KB |
| CPU overhead | < 1% | < 5% |
Instructions
Step 1: Benchmark Current Performance
// scripts/benchmark-langfuse.ts
import { performance } from "perf_hooks";
import { startActiveObservation, updateActiveObservation } from "@langfuse/tracing";
import { LangfuseSpanProcessor } from "@langfuse/otel";
import { NodeSDK } from "@opentelemetry/sdk-node";
async function benchmark() {
const sdk = new NodeSDK({
spanProcessors: [new LangfuseSpanProcessor()],
});
sdk.start();
const iterations = 1000;
// Measure trace creation
const timings: number[] = [];
for (let i = 0; i < iterations; i++) {
const start = performance.now();
await startActiveObservation(`bench-${i}`, async () => {
updateActiveObservation({ input: { i }, output: { done: true } });
});
timings.push(performance.now() - start);
}
const sorted = timings.sort((a, b) => a - b);
console.log("=== Langfuse Performance Benchmark ===");
console.log(`Iterations: ${iterations}`);
console.log(`Mean: ${(sorted.reduce((a, b) => a + b) / sorted.length).toFixed(3)}ms`);
console.log(`P50: ${sorted[Math.floor(sorted.length * 0.5)].toFixed(3)}ms`);
console.log(`P95: ${sorted[Math.floor(sorted.length * 0.95)].toFixed(3)}ms`);
console.log(`P99: ${sorted[Math.floor(sorted.length * 0.99)].toFixed(3)}ms`);
const flushStart = performance.now();
await sdk.shutdown();
console.log(`Flush: ${(performance.now() - flushStart).toFixed(1)}ms`);
}
benchmark();
Step 2: Optimize Batch Configuration
// v4+: Tune OTel span processor
import { LangfuseSpanProcessor } from "@langfuse/otel";
import { NodeSDK } from "@opentelemetry/sdk-node";
const processor = new LangfuseSpanProcessor({
exportIntervalMillis: 10000, // Flush every 10s (default: 5000)
maxExportBatchSize: 100, // Larger batches = fewer API calls
maxQueueSize: 4096, // Buffer more events before dropping
});
const sdk = new NodeSDK({ spanProcessors: [processor] });
sdk.start();
// v3: Direct configuration
const langfuse = new Langfuse({
flushAt: 100, // Larger batches
flushInterval: 10000, // Less frequent flushes
requestTimeout: 30000, // Allow time for large batches
});
| Setting | Low Volume | High Volume | Ultra-High |
|---|---|---|---|
| Batch size | 15 | 50-100 | 200 |
| Flush interval | 5s | 10s | 30s |
| Queue size | 1024 | 4096 | 8192 |
Step 3: Non-Blocking Trace Wrapper
Ensure tracing never blocks your application's critical path:
import { observe, updateActiveObservation } from "@langfuse/tracing";
// The observe wrapper is already non-blocking for the trace submission.
// But protect against SDK crashes:
function safeObserve<T extends (...args: any[]) => Promise<any>>(
name: string,
fn: T
): T {
return (async (...args: Parameters<T>) => {
try {
return await observe({ name }, async () => {
updateActiveObservation({ input: args });
const result = await fn(...args);
updateActiveObservation({ output: result });
return result;
})();
} catch (error) {
// If tracing throws, run function without tracing
console.warn(`Tracing failed for ${name}:`, error);
return fn(...args);
}
}) as T;
}
Step 4: Payload Size Optimization
Large trace payloads slow down flush and increase costs:
function truncateForTrace(input: any, maxStringLen = 5000, maxArrayLen = 50): any {
if (typeof input === "string") {
return input.length > maxStringLen
? input.slice(0, maxStringLen) + `...[truncated ${input.length - maxStringLen} chars]`
: input;
}
if (Array.isArray(input)) {
return input.slice(0, maxArrayLen).map((item) => truncateForTrace(item));
}
if (input instanceof Buffer || input instanceof Uint8Array) {
return `[Binary: ${input.length} bytes]`;
}
if (typeof input === "object" && input !== null) {
const result: Record<string, any> = {};
for (const [key, value] of Object.entries(input)) {
result[key] = truncateForTrace(value);
}
return result;
}
return input;
}
// Usage
await startActiveObservation("process", async () => {
updateActiveObservation({
input: truncateForTrace(largeInput), // Truncated for trace
});
const result = await process(largeInput); // Full input to function
updateActiveObservation({ output: truncateForTrace(result) });
});
Step 5: Sampling for Ultra-High Volume
When you cannot afford to trace every request:
class TraceSampler {
private rate: number;
private windowMs = 60000;
private maxPerWindow: number;
private timestamps: number[] = [];
constructor(rate: number, maxPerMinute: number) {
this.rate = rate;
this.maxPerWindow = maxPerMinute;
}
shouldSample(isError = false): boolean {
if (isError) return true; // Always trace errors
const now = Date.now();
this.timestamps = this.timestamps.filter((t) => t > now - this.windowMs);
if (this.timestamps.length >= this.maxPerWindow) return false;
if (Math.random() > this.rate) return false;
this.timestamps.push(now);
return true;
}
}
const sampler = new TraceSampler(0.1, 1000); // 10%, max 1000/min
async function maybeTrace<T>(name: string, fn: () => Promise<T>, isError = false): Promise<T> {
if (!sampler.shouldSample(isError)) {
return fn(); // Skip tracing
}
return startActiveObservation(name, async () => {
updateActiveObservation({ metadata: { sampled: true } });
return fn();
});
}
Step 6: Memory Management
// Monitor trace-related memory usage
function logMemoryStats() {
const mem = process.memoryUsage();
console.log({
heapUsedMB: (mem.heapUsed / 1024 / 1024).toFixed(1),
rssMB: (mem.rss / 1024 / 1024).toFixed(1),
externalMB: (mem.external / 1024 / 1024).toFixed(1),
});
}
// Log every minute in production
setInterval(logMemoryStats, 60000);
Optimization Impact Matrix
| Optimization | Latency Impact | Throughput Impact | Effort |
|---|---|---|---|
| Increase batch size | High | High | Low |
| Non-blocking wrapper | High | Medium | Low |
| Payload truncation | Medium | Medium | Low |
| Sampling | High | Very High | Medium |
| Memory monitoring | Low | Low | Low |
Error Handling
| Issue | Cause | Solution |
|---|---|---|
| High P99 latency | Sync flush in hot path | Use non-blocking wrapper |
| Memory growth | No payload limits | Truncate inputs/outputs |
| Request timeouts | Batch too large | Reduce batch size or increase timeout |
| Dropped spans | Queue full | Increase maxQueueSize |