Why Use This
This skill provides specialized capabilities for jeremylongshore's codebase.
Use Cases
- Developing new features in the jeremylongshore repository
- Refactoring existing code to follow jeremylongshore standards
- Understanding and working with jeremylongshore's codebase structure
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Updated At Jan 11, 2026, 10:30 PM
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---
name: clay-performance-tuning
description: |
Optimize Clay API performance with caching, batching, and connection pooling.
Use when experiencing slow API responses, implementing caching strategies,
or optimizing request throughput for Clay integrations.
Trigger with phrases like "clay performance", "optimize clay",
"clay latency", "clay caching", "clay slow", "clay batch".
allowed-tools: Read, Write, Edit
version: 1.0.0
license: MIT
author: Jeremy Longshore <jeremy@intentsolutions.io>
---
# Clay Performance Tuning
## Overview
Optimize Clay API performance with caching, batching, and connection pooling.
## Prerequisites
- Clay SDK installed
- Understanding of async patterns
- Redis or in-memory cache available (optional)
- Performance monitoring in place
## Latency Benchmarks
| Operation | P50 | P95 | P99 |
|-----------|-----|-----|-----|
| Read | 50ms | 150ms | 300ms |
| Write | 100ms | 250ms | 500ms |
| List | 75ms | 200ms | 400ms |
## Caching Strategy
### Response Caching
```typescript
import { LRUCache } from 'lru-cache';
const cache = new LRUCache<string, any>({
max: 1000,
ttl: 60000, // 1 minute
updateAgeOnGet: true,
});
async function cachedClayRequest<T>(
key: string,
fetcher: () => Promise<T>,
ttl?: number
): Promise<T> {
const cached = cache.get(key);
if (cached) return cached as T;
const result = await fetcher();
cache.set(key, result, { ttl });
return result;
}
```
### Redis Caching (Distributed)
```typescript
import Redis from 'ioredis';
const redis = new Redis(process.env.REDIS_URL);
async function cachedWithRedis<T>(
key: string,
fetcher: () => Promise<T>,
ttlSeconds = 60
): Promise<T> {
const cached = await redis.get(key);
if (cached) return JSON.parse(cached);
const result = await fetcher();
await redis.setex(key, ttlSeconds, JSON.stringify(result));
return result;
}
```
## Request Batching
```typescript
import DataLoader from 'dataloader';
const clayLoader = new DataLoader<string, any>(
async (ids) => {
// Batch fetch from Clay
const results = await clayClient.batchGet(ids);
return ids.map(id => results.find(r => r.id === id) || null);
},
{
maxBatchSize: 100,
batchScheduleFn: callback => setTimeout(callback, 10),
}
);
// Usage - automatically batched
const [item1, item2, item3] = await Promise.all([
clayLoader.load('id-1'),
clayLoader.load('id-2'),
clayLoader.load('id-3'),
]);
```
## Connection Optimization
```typescript
import { Agent } from 'https';
// Keep-alive connection pooling
const agent = new Agent({
keepAlive: true,
maxSockets: 10,
maxFreeSockets: 5,
timeout: 30000,
});
const client = new ClayClient({
apiKey: process.env.CLAY_API_KEY!,
httpAgent: agent,
});
```
## Pagination Optimization
```typescript
async function* paginatedClayList<T>(
fetcher: (cursor?: string) => Promise<{ data: T[]; nextCursor?: string }>
): AsyncGenerator<T> {
let cursor: string | undefined;
do {
const { data, nextCursor } = await fetcher(cursor);
for (const item of data) {
yield item;
}
cursor = nextCursor;
} while (cursor);
}
// Usage
for await (const item of paginatedClayList(cursor =>
clayClient.list({ cursor, limit: 100 })
)) {
await process(item);
}
```
## Performance Monitoring
```typescript
async function measuredClayCall<T>(
operation: string,
fn: () => Promise<T>
): Promise<T> {
const start = performance.now();
try {
const result = await fn();
const duration = performance.now() - start;
console.log({ operation, duration, status: 'success' });
return result;
} catch (error) {
const duration = performance.now() - start;
console.error({ operation, duration, status: 'error', error });
throw error;
}
}
```
## Instructions
### Step 1: Establish Baseline
Measure current latency for critical Clay operations.
### Step 2: Implement Caching
Add response caching for frequently accessed data.
### Step 3: Enable Batching
Use DataLoader or similar for automatic request batching.
### Step 4: Optimize Connections
Configure connection pooling with keep-alive.
## Output
- Reduced API latency
- Caching layer implemented
- Request batching enabled
- Connection pooling configured
## Error Handling
| Issue | Cause | Solution |
|-------|-------|----------|
| Cache miss storm | TTL expired | Use stale-while-revalidate |
| Batch timeout | Too many items | Reduce batch size |
| Connection exhausted | No pooling | Configure max sockets |
| Memory pressure | Cache too large | Set max cache entries |
## Examples
### Quick Performance Wrapper
```typescript
const withPerformance = <T>(name: string, fn: () => Promise<T>) =>
measuredClayCall(name, () =>
cachedClayRequest(`cache:${name}`, fn)
);
```
## Resources
- [Clay Performance Guide](https://docs.clay.com/performance)
- [DataLoader Documentation](https://github.com/graphql/dataloader)
- [LRU Cache Documentation](https://github.com/isaacs/node-lru-cache)
## Next Steps
For cost optimization, see `clay-cost-tuning`. 
