2026-02-06 22:55:58
When we first started building products for startups, we treated “on the cloud” and “cloud-native” like the same thing. Get it deployed, make sure it runs, move on.
Then real usage happened.
We saw products slow down under traffic spikes. Small failures would ripple into bigger issues. Scaling meant manual tweaks.
Deployments felt heavier than they should have. None of this was dramatic, just the kind of friction that slowly eats into a product’s reliability and a team’s time.
Over time, we learned that building for the cloud is different from just building on the cloud.
What changed for us wasn’t some big rewrite. It was getting better at the basics:
This shift made launches calmer, updates smoother, and scaling far less stressful, for us and for the teams we work with.
We’ve been refining how we approach cloud-native builds and automation across SaaS and web projects, and it’s been a clear upgrade in how products behave in the real world.
Would love to hear how your team learned the difference between “hosted on the cloud” and “built for the cloud.”
2026-02-06 22:42:42
You know that feeling when you've just finished migrating your entire codebase from GPT-4 to Claude — rewriting API calls, fixing response parsing, updating streaming logic — and then Google drops a new Gemini with benchmarks that make everything else look like a calculator from 1995?
Yeah. I've been there. Multiple times.
After the third migration in six months, I sat down and thought: why am I rewriting integration code when the only thing that changes is which HTTP endpoint I'm hitting? The request is JSON. The response is JSON. The models all take messages in, text out. Why does switching providers feel like changing the engine on a moving car?
That's how I ended up looking at LM-Proxy — and it changed the way I architect LLM-powered applications. Let me walk you through what it is, why it matters, and how to set it up in under 5 minutes.
Here's the typical evolution of an LLM-powered project:
Month 1: "We'll just use OpenAI. One provider, one SDK, simple."
Month 3: "Claude is actually better for our summarization task. Let's add Anthropic too." You now have two different SDKs, two authentication flows, two response formats, and an if/else that haunts your dreams.
Month 5: "Gemini Flash is way cheaper for simple queries. Let's route the easy stuff there." Your routing logic now lives in three different files, you have provider-specific error handling everywhere, and your new developer spent two days just understanding which API key goes where.
Month 7: Someone asks "can we add a local model for sensitive data?" and you start updating your LinkedIn.
The root cause is simple: every LLM provider decided to invent their own API format, even though they all do fundamentally the same thing. OpenAI's format became the de facto standard, but Anthropic, Google, and others each have their own quirks, authentication schemes, and streaming protocols.
What you actually need is a reverse proxy — a single endpoint that speaks OpenAI's API format on the outside, but can talk to any provider on the inside.
LM-Proxy is a lightweight, OpenAI-compatible HTTP proxy/gateway built with Python and FastAPI. Here's the pitch in one sentence:
Your app talks to one API (OpenAI format). LM-Proxy talks to everyone else.
It supports OpenAI, Anthropic, Google (AI Studio and Vertex AI), local PyTorch models, and anything that speaks OpenAI's API format — all through a single /v1/chat/completions endpoint. Requires Python 3.11+.
But "another LLM gateway" isn't what makes it interesting. Here's what does:
No Kubernetes. No Redis. No Kafka. No 47-microservice architecture. It's a single Python package:
pip install lm-proxy
One TOML config file. One command to start:
lm-proxy
That's it. You can have it running on a $5/month VPS, inside a Docker container, or even embedded directly into your Python application as a library (since it's built on FastAPI, you can import and mount it as a sub-app). The entire core is minimal by design — no bloat, no enterprise-grade complexity for a problem that doesn't need it.
Here's a complete, working config that routes GPT requests to OpenAI, Claude to Anthropic, and Gemini to Google:
host = "0.0.0.0"
port = 8000
[connections.openai]
api_type = "open_ai"
api_base = "https://api.openai.com/v1/"
api_key = "env:OPENAI_API_KEY"
[connections.anthropic]
api_type = "anthropic"
api_key = "env:ANTHROPIC_API_KEY"
[connections.google]
api_type = "google_ai_studio"
api_key = "env:GOOGLE_API_KEY"
[routing]
"gpt*" = "openai.*"
"claude*" = "anthropic.*"
"gemini*" = "google.*"
"*" = "openai.gpt-4o-mini" # fallback
[groups.default]
api_keys = ["my-team-api-key-1", "my-team-api-key-2"]
Read that config top to bottom. You understood it in 30 seconds, didn't you? No YAML indentation nightmares, no 200-line JSON blobs — just clean TOML with obvious semantics. (YAML, JSON, and Python config formats are also supported, by the way.)
The env: prefix pulls secrets from environment variables (or .env files), so your API keys never touch version control.
The [routing] section is where the magic happens. Keys are glob patterns that match against the model name your client sends. The .* suffix means "pass the model name as-is to the provider." So when your client asks for claude-sonnet-4-5-20250929, LM-Proxy forwards exactly that to Anthropic's API. No mapping tables, no model ID translation files — it just works.
You can also pin patterns to specific models:
[routing]
"custom*" = "local.llama-7b" # Any "custom*" request → local Llama
"gpt-3.5*" = "openai.gpt-3.5-turbo" # Pin to a specific model
"*" = "openai.gpt-4o-mini" # Everything else → cheap fallback
This means your client code never changes. Want to try a new model? Update one line in the config. Want to A/B test two providers? Add a routing rule. Want to deprecate a model? Redirect the pattern to something else. Zero code changes.
This is the feature that makes LM-Proxy production-ready rather than just a toy.
LM-Proxy maintains two layers of API keys:
# Premium users get everything
[groups.premium]
api_keys = ["premium-key-1", "premium-key-2"]
allowed_connections = "*"
# Free tier gets OpenAI only
[groups.free]
api_keys = ["free-key-1"]
allowed_connections = "openai"
# Internal tools get local models only
[groups.internal]
api_keys = ["internal-key-1"]
allowed_connections = "local"
Your upstream API keys are never exposed to clients. You can rotate them without updating any client configuration. You can create granular access tiers — premium users get Claude Opus, free users get GPT-4o-mini, internal tools use local models. All managed in one config file.
It even supports external authentication — you can validate virtual API keys against Keycloak, Auth0, or any OIDC provider:
[api_key_check]
class = "lm_proxy.api_key_check.CheckAPIKeyWithRequest"
method = "POST"
url = "http://keycloak:8080/realms/master/protocol/openid-connect/userinfo"
response_as_user_info = true
use_cache = true
cache_ttl = 60
[api_key_check.headers]
Authorization = "Bearer {api_key}"
Your existing OAuth tokens become LLM API keys automatically. And if the built-in validators don't fit, you can write a custom one — just a Python function that takes an API key string and returns a group name.
SSE streaming works out of the box. Your clients get real-time token-by-token responses regardless of which provider is actually generating them. The proxy handles the format translation transparently — Anthropic's streaming format becomes OpenAI-compatible SSE events before they reach your client.
LM-Proxy isn't just a standalone service — it's also an importable Python package. Since it's built on FastAPI, you can mount it inside your existing application, use it in integration tests, or compose it with other ASGI middleware. No need to run a separate process if you don't want to.
Let me walk through a concrete scenario. You're building a SaaS product that uses LLMs. You want GPT-4o for complex reasoning, Claude Sonnet for long-document processing, and Gemini Flash for cheap classification.
Step 1: Install
pip install lm-proxy
Step 2: Create .env
OPENAI_API_KEY=sk-...
ANTHROPIC_API_KEY=sk-ant-...
GOOGLE_API_KEY=AI...
Step 3: Create config.toml
host = "0.0.0.0"
port = 8000
[connections.openai]
api_type = "open_ai"
api_base = "https://api.openai.com/v1/"
api_key = "env:OPENAI_API_KEY"
[connections.anthropic]
api_type = "anthropic"
api_key = "env:ANTHROPIC_API_KEY"
[connections.google]
api_type = "google_ai_studio"
api_key = "env:GOOGLE_API_KEY"
[routing]
"gpt*" = "openai.*"
"claude*" = "anthropic.*"
"gemini*" = "google.*"
"*" = "google.gemini-2.0-flash"
[groups.backend]
api_keys = ["backend-service-key"]
allowed_connections = "*"
[groups.frontend]
api_keys = ["frontend-widget-key"]
allowed_connections = "google" # cheap models only
Step 4: Run
lm-proxy
Step 5: Use from your app
from openai import OpenAI
client = OpenAI(
api_key="backend-service-key",
base_url="http://localhost:8000/v1"
)
# Complex reasoning → GPT-4o
response = client.chat.completions.create(
model="gpt-5.2",
messages=[{"role": "user", "content": "Analyze this contract..."}]
)
# Long document → Claude
response = client.chat.completions.create(
model="claude-opus-4-6",
messages=[{"role": "user", "content": "Summarize this 100-page report..."}]
)
# Quick classification → Gemini Flash (cheap)
response = client.chat.completions.create(
model="gemini-2.0-flash",
messages=[{"role": "user", "content": "Is this email spam? ..."}]
)
One client. One base URL. Three providers. And tomorrow, when someone releases a model that's 50% cheaper, you change one line in config.toml and restart the server. Your application code stays the same.
The obvious question: "How is this different from LiteLLM?"
Let's be honest — LiteLLM is the 800-pound gorilla in this space. With 33k+ GitHub stars, 2000+ supported LLMs, an AWS Marketplace listing, and features like spend tracking dashboards, guardrails, caching, rate limiting, SSO, and MCP integration, it's a full-blown enterprise platform. It also offers both a Python SDK and an HTTP proxy server, so architecturally it covers similar ground.
So why would you choose LM-Proxy instead?
The same reason you'd choose Flask over Django, or SQLite over PostgreSQL. Not everything needs the full enterprise stack.
| LM-Proxy | LiteLLM Proxy | |
|---|---|---|
| Philosophy | Minimal core, extend as needed | Batteries included |
| Setup complexity |
pip install lm-proxy + one TOML file |
pip install 'litellm[proxy]' + YAML + optional DB |
| Dependencies | FastAPI + MicroCore (lightweight) | Heavier dependency tree |
| Config format | TOML / YAML / JSON / Python | YAML |
| Embeddable as library | First-class use case | Supported but discouraged by docs |
| Virtual keys + groups | Built-in | Built-in (more advanced) |
| OIDC / Keycloak auth | Built-in | Built-in (more advanced: JWT validation, role mapping, SSO UI) |
| Spend tracking, guardrails, caching | Not built-in (extensible via add-ons) | Built-in |
| Admin UI | No | Yes |
| Supported providers | All major providers + local models / embedded inference | All major providers |
Choose LM-Proxy when: you want a lightweight, easy-to-embed proxy with a tiny footprint, Python-config extensibility, and you don't need 90% of the enterprise features. It's ideal for small teams, personal projects, or when you want a gateway you can fully understand by reading the source in an afternoon.
Choose LiteLLM when: you need enterprise-grade spend tracking, a management UI, dozens of integrations, guardrails, caching, and support for 100+ providers and integrations out of the box.
Other alternatives like Portkey lean even more enterprise. LM-Proxy intentionally occupies the "just enough gateway" niche — powerful enough for production, simple enough that your config file is the documentation.
Credit where it's due — LM-Proxy already covers more ground than you might expect from a "lightweight" tool:
JsonLogWriter and LogEntryTransformer (tracks tokens, duration, group, connection, remote address), plus the lm-proxy-db-connector add-on for writing logs to PostgreSQL, MySQL, SQLite, and other databases via SQLAlchemyThat said, the project is still evolving (latest release: v3.0.0), and a few things remain on my personal wishlist:
expand_wildcards mode for /v1/models is planned but not yet implemented — for now you need to list models explicitly in the routing configThe extensibility-by-design philosophy means most of these can be added as add-ons without touching the core — and the DB connector already demonstrates this pattern nicely. The codebase is MIT licensed and small enough to read end-to-end in an afternoon.
If you're working with multiple LLM providers (or think you might in the future), stop writing provider-specific integration code. Set up LM-Proxy as a gateway, point all your services at it, and never think about API format differences again.
pip install lm-proxy
Have you tried LM-Proxy or a similar LLM gateway? What's your approach to multi-provider LLM integration? Share your experience in the comments.
2026-02-06 22:39:31
When I first started learning Power BI, I thought data analysis was mostly about building charts and dashboards.
I was wrong.
What I quickly realized is that most of the work happens before the visuals. Real-world data is messy, inconsistent and often confusing and Power BI is only powerful when you know how to translate that mess into something meaningful.
This article explains how analysts (especially beginners like me) use Power BI to move from messy data, through DAX and finally into dashboards that actually drive action.
You open that CSV file or connect to that database feeling optimistic. You're ready to build some dashboards, create insights, change the world. Then you see it: dates formatted as text, customer names spelled seventeen different ways, empty cells scattered around like landmines, numbers mixed with currency symbols, and columns labeled "Field_47" with zero documentation.
My first real dataset had all of this plus duplicate records of the same transactions. I remember staring at it thinking, "Did I get bad data? Should I ask for a cleaner version?"
Then I learned the truth: this is normal. This is the job. Messy data isn't bad data,it's just raw. And if you can't translate raw data into something usable, none of the fancy dashboard skills matter.
When I first crack open a messy dataset, I'm hunting for specific problems. Here's what trips up most analyses before they even start:
This drives me nuts but it's everywhere. You'll have one column with "New York," "NY," "new york," and "N.Y." all meaning the same thing. Power BI doesn't know they're the same, so your visuals will treat them as four separate categories. Your boss asks why sales are split across four different locations and you look like you don't know what you're doing.
These are trickier than they seem. Sometimes a blank means "we don't know." Sometimes it means "zero." Sometimes it means "this doesn't apply." You have to figure out which one it is, because filling in blanks with zeros when they actually mean "unknown" will completely screw up your averages and totals.
I learned this the hard way when my average order value calculation was totally wrong because I'd replaced nulls with zeros.
This is a constant headache. Dates stored as text, numbers stored as text, percentages stored as whole numbers (so 85% shows up as 85.00 instead of 0.85). Power Query's type detection helps, but you can't just trust it blindly.
I once built an entire time series analysis before realizing my dates were still text and none of my date hierarchies worked.
These happen more than you'd think. Maybe the same transaction got logged twice. Maybe someone entered the same customer with slightly different info. You need to spot these and decide whether to keep both records, merge them or delete the duplicates entirely.
This step completely changed how I viewed data analysis. Instead of rushing to build visuals, I learned to slow down and ask: Can this data be trusted? If the answer is no, everything that follows becomes unreliable.
In Power BI, the translation process starts in Power Query. This is where analysts prepare data so Power BI can analyze it correctly.
Here's my actual workflow when I'm cleaning data:
First, I use Power Query to get a feel for what I'm working with. I turn on the column quality, column distribution and column profile options. These show you at a glance how many nulls you have, how many distinct values, whether you have outliers. It's like getting an X-ray of your data before you operate on it.
Then I start fixing things systematically:
Standardizing text - I use TRIM and CLEAN to get rid of weird spacing. I use Replace Values for common inconsistencies. For the "New York" problem I mentioned earlier, I create a conditional column or use Replace Values to make everything consistent.
Fixing data types - I manually set every single column type because auto-detect has burned me too many times. Date/Time for dates, Decimal Number for currency, Whole Number for counts, Text for IDs (even if they look like numbers—trust me on this one).
Handling missing data intentionally - Sometimes I filter out incomplete rows. Sometimes I replace nulls with "Unknown" or "Not Provided" for categorical data. For numbers, it depends on context—sometimes zero makes sense, sometimes you need to leave it null, sometimes you calculate an average to fill it in.
Removing junk - Duplicate records go away. Irrelevant columns get deleted. Rows that are clearly data entry errors get filtered out (like that one time I found a customer age of 247).
Splitting and combining - I split columns so each one represents a single piece of information. A "Full Name" column becomes "First Name" and "Last Name." A messy address becomes separate fields for street, city, state, zip.
Renaming everything - I rename columns to clearly describe what they contain. "Col_17" becomes "Customer_Acquisition_Date." Future me always thanks past me for this.
This is where you earn your money as an analyst. Nobody sees this work, but it's the foundation of everything.
Once the data is clean, the next challenge is structuring it properly. Power BI doesn't just display tables—it uses relationships between them to filter and calculate data correctly.
As a beginner, the biggest concept I learned was the difference between fact tables and dimension tables:
Fact tables hold the transactions, the events, the things that happened. Sales records. Website visits. Support tickets. These tables tend to be long—lots of rows.
Dimension tables describe the context around those facts. Customer information. Product catalogs. Date tables. Geography. These tables tend to be wide—lots of attributes about each thing.
By connecting these tables using clear one-to-many relationships (one customer can have many sales, one product can appear in many transactions), Power BI can filter visuals correctly, respond properly to slicers, and produce accurate aggregations.
I'll be honest,I didn't understand why this mattered until I built a dashboard without proper relationships. When someone clicked a slicer to filter by region, only some of the visuals updated. Others showed the wrong numbers. It was a mess.
A good data model doesn't look exciting, but it makes dashboards behave the way users expect. Without it, even clean data produces confusing results.
DAX was the part I found most intimidating at first. All those functions and syntax rules felt like learning a new programming language.
But over time, I realized that DAX isn't just about formulas—it's about defining meaning.
Instead of asking "How do I write this formula?", analysts ask:
Using DAX measures, Power BI allows calculations to adapt dynamically to filters, dates and user interaction. This is what transforms static numbers into insights.
A simple example: when I create a measure for Total Revenue, it's not just SUM(Sales[Amount]). I have to think about whether cancelled orders should be excluded. Whether I need to account for currency conversion. Whether partial refunds affect the number.
DAX is the bridge between raw numbers and real business questions. It's where you translate data into the language your stakeholders actually care about.
Here's what trips people up: knowing when to clean in Power Query versus when to handle it in DAX measures.
Generally, if it's structural (fixing data types, removing duplicates, standardizing categories), do it in Power Query. If it's calculation-based (like handling division by zero in a ratio, or computing year-over-year growth), do it in DAX.
Why? Power Query transformations happen once when you refresh your data. DAX calculations happen every time someone interacts with your report. If you try to do heavy transformations in DAX, your dashboards will be slow and painful to use.
Another thing—documentation is not optional. When I create a Power BI file, I keep notes about what I cleaned and why. Three months later when someone asks why you excluded certain records or how you defined "active customer," you need to have an answer. I use the Description field in Power Query steps and add comments to complex DAX measures.
Also, always keep a copy of your original raw data. Never overwrite source files. I learned this the hard way when I spent a day cleaning a dataset, saved over the original, then realized I'd filtered out records I actually needed.
Only after data is cleaned, modeled and measured does the dashboard truly matter.
Here's what I learned about dashboards: they're not meant to show everything—they're meant to guide attention. Early on, I tried cramming every possible metric onto one page. It looked impressive to me but confused everyone else.
Effective Power BI dashboards do a few things really well:
Using KPI cards or scorecards. The three or four numbers that actually matter get prominent placement. Everything else is secondary.
A single number like "450 sales this month" means nothing without context. But a line chart showing whether that's up or down from last month? That tells a story.
Users can slice by date, region, product category, whatever makes sense. This turns a static report into an interactive tool.
White space is your friend. Clear labels matter more than fancy visuals. If someone has to squint or ask what they're looking at, you've failed.
When dashboards are designed well, decision-makers don't need to ask for new reports. They can explore the data themselves and act immediately. That's when analysis turns into action.
You know you've translated your messy data successfully when you can build a visual and it just works. You don't have to keep going back to Power Query to fix "one more thing." Your slicers show the categories you expect. Your date hierarchies make sense. Your totals actually total correctly.
The goal isn't perfection—there's always another tweak you could make. The goal is reliable data that answers business questions without creating new confusion.
That's what this whole job is about, really. Taking information that's scattered and inconsistent and broken, and turning it into something someone can actually use to make a decision.
The dashboards and visualizations are just the final 10% that everyone sees. The real work happens in Power Query, in those transformation steps nobody ever asks about.
Learning Power BI taught me something important: data analysis is not about tools—it's about thinking.
Power BI simply provides the environment where analysts:
Once I understood this workflow, Power BI stopped feeling overwhelming and started making sense. The tool just facilitates the process. The real skill is knowing what questions to ask at each stage.
If you're just starting out, focus less on perfect visuals and more on understanding this process. Master the unglamorous parts first—the data cleaning, the relationships, the proper data types. Everything else becomes easier once the foundation is right.
And honestly? Once you get good at this part, the actual analysis becomes almost fun. Because you're working with data you trust, data you understand, data that's finally ready to tell you something true.
If you're learning Power BI, mastering how data flows from raw to actionable insight will save you months of confusion and make your dashboards far more valuable than any fancy visual ever could.
What's been your biggest challenge learning Power BI? Drop a comment below,I'd love to hear what trips people up or what clicked for you.
2026-02-06 22:26:00
Building serverless apps is great, right? Fast to build, scales easily. But sometimes, those database bills can be a surprise. Popular serverless databases often come with costs that grow quickly.
What if there was a different way? A simpler database designed for serverless that helps you manage costs better?
That's where Coldbase comes in.
Coldbase is a small, serverless-focused database. It uses affordable cloud storage, like AWS S3 or Azure Blob, to keep your data. It's a different approach to storing data in serverless environments. It is currently in Beta, and we welcome your feedback as we continue to refine it.
Serverless databases are great for many things, but their pricing can sometimes be high. They often charge based on how many reads and writes you do. As your app gets more users, these costs can increase quickly.
Coldbase takes a different path. It uses standard cloud storage (like S3 or Azure Blob) as its foundation. These services are known for being very affordable, especially for storing lots of data and handling many operations.
By building on this low-cost storage, Coldbase aims to give you significant savings on your database bill. We've seen it be much cheaper than some traditional options. For a more detailed look at the cost difference, you can check our comparison here.
Coldbase offers features to help you build serverless applications more efficiently:
Want to see Coldbase in action with a cloud storage backend? Here’s a simple example using AWS S3.
import { Db, S3Driver } from 'coldbase'
import { S3Client } from '@aws-sdk/client-s3'
interface User {
id: string
name: string
email: string
role: string
}
// Configure your S3 client
const s3Client = new S3Client({ region: 'us-east-1' })
// Instantiate S3Driver with your bucket name and S3 client
const db = new Db(new S3Driver('my-coldbase-bucket', s3Client))
const users = db.collection<User>('users')
// Add a new user
await users.put({ id: 'u1', name: 'Alice', email: '[email protected]', role: 'admin' })
// Find a user
const user = await users.get('u1')
console.log('Found user:', user)
// Get all admins
const admins = await users.find({ where: { role: 'admin' } })
console.log('Admins:', admins)
// Remove a user
await users.delete('u1')
console.log('User u1 deleted.')
Coldbase is a practical way to manage data in serverless applications, with a focus on cost-efficiency. If you're looking for an alternative to high database bills, consider giving Coldbase a try.
2026-02-06 22:20:43
I built a video generation workflow by combining n8n (a business automation tool) and Remotion (a React-based video framework).
In this post—the "Server Setup Edition"—I will share how to build an HTTP API server (Express) on a VPS to render Remotion videos, along with the specific pitfalls I encountered (such as memory shortages and bundling times).
The setup involves sending a POST request from n8n's "HTTP Request" node. The server receives parameters (like text and colors), renders the video on the server side, and returns the file path.
Since Remotion rendering uses a headless browser, it consumes significant resources, especially memory.
The structure is simple. The api directory contains the server logic, and src contains the React components for the video.
remotion-server/
├── src/
│ ├── Video.tsx # Video content (React component)
│ └── index.ts # Remotion entry point
├── api/
│ └── server.ts # Express server entry point
├── out/ # Destination for rendered videos
├── package.json
└── tsconfig.json
The key point here is the start script. Since the Remotion rendering process is heavy, I relaxed the Node.js heap memory limit.
{
"name": "remotion-server",
"version": "1.0.0",
"type": "module",
"scripts": {
"start": "node --max-old-space-size=3072 api/server.js"
},
"dependencies": {
"@remotion/bundler": "^4.0.0",
"@remotion/renderer": "^4.0.0",
"express": "^4.18.2",
"react": "^18.2.0",
"remotion": "^4.0.0"
},
"devDependencies": {
"@types/express": "^4.17.17",
"@types/node": "^20.0.0",
"typescript": "^5.0.0"
}
}
This is a simple video component that changes text and background color based on the received props.
import { AbsoluteFill, useCurrentFrame, interpolate } from 'remotion';
import React from 'react';
interface VideoProps {
text: string;
color: string;
}
export const MyVideo: React.FC<VideoProps> = ({ text, color }) => {
const frame = useCurrentFrame();
// Fade in between frames 0 and 30
const opacity = interpolate(frame, ,, {[1]
extrapolateRight: 'clamp',
});
return (
<AbsoluteFill
style={{
backgroundColor: color,
justifyContent: 'center',
alignItems: 'center',
}}
>
<h1 style={{ fontSize: 100, color: 'white', opacity }}>
{text}
</h1>
</AbsoluteFill>
);
};
This is the core implementation. To improve performance, I designed it to execute the Webpack bundle only once at server startup and cache the result for reuse.
import express from 'express';
import { bundle } from '@remotion/bundler';
import { renderMedia, selectComposition } from '@remotion/renderer';
import path from 'path';
import { fileURLToPath } from 'url';
import fs from 'fs';
const app = express();
app.use(express.json());
// Path resolution for ES Modules environment
const __filename = fileURLToPath(import.meta.url);
const __dirname = path.dirname(__filename);
// Keep bundle result in memory
let cachedBundleLocation: string | null = null;
// Create bundle at server startup
async function initializeBundle() {
console.log('Creating Webpack bundle...');
const entryPoint = path.resolve(__dirname, '../src/index.ts');
cachedBundleLocation = await bundle({
entryPoint,
webpackOverride: (config) => ({
...config,
cache: { type: 'filesystem' }, // Speed up build
}),
});
console.log('Bundle created:', cachedBundleLocation);
}
// Video generation endpoint
app.post('/render', async (req, res) => {
try {
const { text = 'Hello', color = '#000000' } = req.body;
if (!cachedBundleLocation) {
return res.status(500).json({ error: 'Bundle not initialized' });
}
// Select composition (video settings)
const composition = await selectComposition({
serveUrl: cachedBundleLocation,
id: 'MyVideo',
inputProps: { text, color },
});
// Generate output file path
const timestamp = Date.now();
const outputLocation = path.resolve(__dirname, `../out/video-${timestamp}.mp4`);
// Create directory
const outputDir = path.dirname(outputLocation);
if (!fs.existsSync(outputDir)) {
fs.mkdirSync(outputDir, { recursive: true });
}
console.log(`Rendering started: ${outputLocation}`);
// Execute rendering
await renderMedia({
composition,
serveUrl: cachedBundleLocation,
codec: 'h264',
outputLocation,
inputProps: { text, color },
});
console.log('Rendering completed.');
res.json({
success: true,
path: outputLocation,
filename: path.basename(outputLocation),
});
} catch (error) {
console.error('Render error:', error);
res.status(500).json({
error: 'Rendering failed',
message: error instanceof Error ? error.message : 'Unknown error',
});
}
});
// Startup process
const PORT = process.env.PORT || 3000;
initializeBundle()
.then(() => {
app.listen(PORT, () => {
console.log(`Server running on port ${PORT}`);
});
})
.catch((e) => {
console.error('Failed to start server:', e);
process.exit(1);
});
# Install dependencies
npm install
# TypeScript compilation
npx tsc
# Start server (with heap memory expansion)
npm start
Send a request from n8n or Curl as follows:
curl -X POST http://localhost:3000/render \
-H "Content-Type: application/json" \
-d '{"text":"Hello Zenn","color":"#3ea8ff"}'
Response:
{
"success": true,
"path": "/path/to/remotion-server/out/video-1738465200000.mp4",
"filename": "video-1738465200000.mp4"
}
Here are three major issues I faced during implementation and their solutions.
Initially, I executed the bundle() function for every request. This meant Webpack ran every time a video was generated, resulting in a wait time of over 5 minutes before rendering even started.
Solution:
I changed the logic to run bundling only once at server startup (initializeBundle) and cache the generated bundleLocation in a variable. This allows rendering to start immediately for all subsequent requests.
// NG: Executed inside every request
// app.post('/render', async (req, res) => {
// const bundleLocation = await bundle({ ... }); // Too heavy
// });
// OK: Executed once at startup and cached
let cachedBundleLocation: string | null = null;
await initializeBundle();
When running on a VPS (2GB memory plan), the process was frequently killed (Killed) during rendering. Remotion uses Chromium in headless mode, which consumes a lot of memory.
Solution:
I added the --max-old-space-size option to increase the Node.js heap size limit. I also highly recommend using a VPS with at least 4GB of RAM.
"scripts": {
"start": "node --max-old-space-size=3072 api/server.js"
}
I encountered issues where file paths drifted between the development environment and the production environment (when started with PM2, etc.).
process.cwd(): The directory where the command was executed (depends on launch location)__dirname: The directory where the script file is located (depends on file location)Solution:
I unified the path resolution by using __dirname (generated from import.meta.url since this is ESM) for specifying the entry point, resolving relative paths from there. This ensures stability regardless of where the command is run.
// NG: Path changes depending on where you launch
// const entryPoint = path.resolve(process.cwd(), 'src/index.ts');
// OK: Reliable as it's based on server.ts location
const entryPoint = path.resolve(__dirname, '../src/index.ts');
I have now completed an API server that can be called from n8n to generate videos at any time.
In this example, I simply saved the MP4 locally and returned the path. However, in a production environment, adding a process to upload the file to AWS S3 and return a signed URL would make it more practical.
Automated video generation can be applied to various use cases, such as automating SNS posts or creating personalized videos.
2026-02-06 22:18:55
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