Ripple President Says RLUSD Could Overtake USDC: How This Could Impact XRP
Stablecoins have become one of the fastest growing sectors in the crypto industry. The conversation intensified recently after a new statement from Ripple leadership. Ripple president Monica Long made a bold remark about the future of the company’s stablecoin during an event in Australia.
Her comment raised a larger question for the market. Could RLUSD eventually challenge one of the biggest stablecoins in the industry, and what would that mean for XRP?
Crypto commentator Crypto AiMan discussed the clip in a recent video on his YouTube channel. The video focuses on Long’s statement that Ripple’s RLUSD stablecoin could eventually surpass USDC in size. That possibility matters because RLUSD operates on infrastructure connected to the XRP Ledger.
Crypto AiMan explains that Monica Long recently spoke about the long term potential of RLUSD. Long stated during the discussion that RLUSD could flip USDC in the future. Such a move would represent a dramatic change in the stablecoin market.
The numbers illustrate why the statement drew attention. RLUSD currently has a market value close to $1.5 billion. USDC remains one of the largest stablecoins with roughly $77 billion in circulation. That gap means RLUSD would need a growth of more than 50 times to reach the same level as USDC.
Crypto AiMan notes that the comparison becomes interesting because RLUSD runs through the XRP ecosystem. The infrastructure that supports the stablecoin connects to the XRP Ledger, which processes the transactions that move value across the network.
The analyst explains that growth in the RLUSD ecosystem could increase activity on the XRP Ledger. That connection leads to a simple question. Greater stablecoin adoption may increase the volume of transactions that interact with XRP infrastructure.
XRP Ledger Activity Could Expand If RLUSD Adoption Grows
Crypto AiMan emphasizes the role of the XRP Ledger in the discussion. The XRP network processes transactions for multiple digital asset services. RLUSD uses that infrastructure on the back end.
The XRP ecosystem already supports decentralized exchange activity on the ledger. Crypto AiMan notes that Monica Long also discussed the potential for higher decentralized exchange volume. Long indicated that XRP Ledger DEX volume could increase significantly over time.
Ripple has already processed more than $70 billion in digital asset transactions across its network. Long described stablecoins as an important component of future payment infrastructure. Many companies now explore blockchain rails to settle payments and transfers more efficiently.
Crypto AiMan explains that Ripple has spent years building relationships with financial companies and payment providers. Those connections create possible pathways for stablecoin usage through the Ripple ecosystem.
Stablecoin Market Growth Could Become A Major Catalyst For XRP Infrastructure
Crypto AiMan also points to the broader growth of the stablecoin sector. Monica Long stated that the stablecoin market could expand toward $3 trillion over the next several years. Such expansion would represent a massive increase from current levels.
Ripple aims to position RLUSD inside that growing market. Long explained that Ripple already has payment use cases and enterprise partners that require stablecoin settlement.
Read Also: Oil Shock Sends Warning to Markets as Bitcoin and Stocks Risk Deeper Crash
Crypto AiMan argues that increased RLUSD adoption could send more transaction volume through the XRP ecosystem. Ripple’s broader network of companies and financial integrations could also play a role in future stablecoin usage.
Stablecoins continue to gain importance across global finance as companies explore blockchain payment systems. The next few years will reveal how large the sector becomes and which networks capture the most activity.
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The post Ripple President Says RLUSD Could Overtake USDC: How This Could Impact XRP appeared first on CaptainAltcoin.
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MySQL Single Leader Replication with Node.js and Docker
command: --server-id=1 --log-bin=ON The --server-id option gives each MySQL server in your replication setup its own name tag. Each one has to be unique and without it, replication won’t work at all. Another cool option not included here is binlog_format=ROW. This tells MySQL how to keep track of changes before passing them along to the replicas. By default, MySQL already uses row-based replication, but you can explicitly set it to ROW to be sure or switch it to STATEMENT if you’d rather log the actual SQL statements instead of row-by-row changes. \ Run our containers on docker Now, in the terminal, we can run the following command to spin up our database containers: docker-compose up -d \ Setting Up Our Master (Primary) Server To configure our master server, we would have to first access the running instance on docker using the following command docker exec -it mysql-master bash This command opens an interactive Bash shell inside the running Docker container named mysql-master, allowing us to run commands directly inside that container. \ Now that we’re inside the container, we can access the MySQL server and start running commands. type: mysql -uroot -p This will log you into MySQL as the root user. You’ll be prompted to enter the password you set in your docker-compose.yml file. \ Next, we need to create a special user that our replicas will use to connect to the master server and pull data. Inside the MySQL prompt, run the following commands: \ CREATE USER 'repl_user'@'%' IDENTIFIED BY 'replication_pass'; GRANT REPLICATION SLAVE ON . TO 'repl_user'@'%'; FLUSH PRIVILEGES; Here’s what’s happening: CREATE USER makes a new MySQL user called repl_user with the password replication_pass. GRANT REPLICATION SLAVE gives this user permission to act as a replication client. FLUSH PRIVILEGES tells MySQL to reload the user permissions so they take effect immediately. \ Time to Configure the Replica (Secondary) Servers a. First, let’s access the replica containers the same way we did with the master. Run this command in your terminal for each of the replica containers: \ docker exec -it <replica_container_name> bash mysql -uroot -p <replica_container_name> should be replace with the name of the replica container you are trying to setup b. Now it’s time to tell our replica where to get its data from. While inside the replica’s MySQL shell, run the following command to configure replication using the master’s details: CHANGE REPLICATION SOURCE TO SOURCE_HOST='mysql-master', SOURCE_USER='repl_user', SOURCE_PASSWORD='replication_pass', GET_SOURCE_PUBLIC_KEY=1; With the replication settings in place, let’s fire up the replica and get it syncing with the master. Still inside the MySQL shell on the replica, run: START REPLICA; This starts the replication process. To make sure everything is working, check the replica’s status with:
SHOW REPLICA STATUS\G; Look for Replica_IO_Running and Replica_SQL_Running — if both say Yes, congratulations! 🎉 Your replica is now successfully connected to the master and replicating data in real time.
Testing Our Replication Setup from the Node.js App Now that our replication is successfully set up, we can configure our Node.js server to observe the real-time effect of data being replicated from the master server to the replica server whenever we write to it. We start by installing the following dependencies:
npm i express mysql2 sequelize \ Now create a folder called src in the root directory and add the following files inside that folder connection.js, index.js and model.js. Our current directory should look like this We can now set up our connections to our master and replica server in the connection.js file as shown below
const Sequelize = require("sequelize"); const sequelize = new Sequelize({ dialect: "mysql", replication: { write: { host: "127.0.0.1", username: "root", password: "master", database: "replicaDb", }, read: [ { host: "127.0.0.1", username: "root", password: "slave", database: "replicaDb", port: 3307 }, { host: "127.0.0.1", username: "root", password: "slave", database: "replicaDb", port: 3308 }, { host: "127.0.0.1", username: "root", password: "slave", database: "replicaDb", port: 3309 }, ], }, }); async function connectdb() { try { await sequelize.authenticate(); } catch (error) { console.error("❌ unable to connect to the follower database", error); } } connectdb(); module.exports = { sequelize, }; \ We can now create a User table in the model.js file
const {DataTypes} = require("sequelize"); const { sequelize } = require("./connection"); const User = sequelize.define("User", { name: { type: DataTypes.STRING, allowNull: false, }, email: { type: DataTypes.STRING, unique: true, allowNull: false, }, }); module.exports = User \ and finally in our index.js file we can start our server and listen for connections on port 3000. from the code sample below, all inserts or updates will be routed by sequelize to the master server. while all read queries will be routed to the read replicas.
const express = require("express"); const { sequelize } = require("./connection"); const User = require("./model"); const app = express(); app.use(express.json()); async function main() { await sequelize.sync({ alter: true }); app.get("/", (req, res) => { res.status(200).json({ message: "first step to setting server up", }); }); app.post("/user", async (req, res) => { const { email, name } = req.body; let newUser = await User.build({ name, email, }); // This INSERT will go to the write (master) connection newUser = newUser.save({ returning: false }); res.status(201).json({ message: "User successfully created", }); }); app.get("/user", async (req, res) => { // This SELECT query will go to one of the read replicas const users = await User.findAll(); res.status(200).json(users); }); app.listen(3000, () => { console.log("server has connected"); }); } main(); When you make a POST request to the /users endpoint, take a moment to check both the master and replica servers to observe how data is replicated in real time. Right now, we are relying on Sequelize to automatically route requests, which works for development but isn’t robust enough for a production environment. In particular, if the master node goes down, Sequelize cannot automatically redirect requests to a newly elected leader. In the next part of this series, we’ll explore strategies to handle these challenges
