In a bold forecast that has captured the attention of investors worldwide, JPMorgan Chase has projected that gold prices could soar to $6,000 per ounce by 2028, representing a substantial increase from current levels.In a bold forecast that has captured the attention of investors worldwide, JPMorgan Chase has projected that gold prices could soar to $6,000 per ounce by 2028, representing a substantial increase from current levels.
JPMorgan Predicts Gold Price Will Reach $6,000 per Ounce by 2028
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In a bold forecast that has captured the attention of investors worldwide, JPMorgan Chase has projected that gold prices could soar to $6,000 per ounce by 2028, representing a substantial increase from current levels.
Historic Price Projection
JPMorgan's ambitious price target of $6,000 per ounce would mark a significant milestone in gold market history. The projection suggests the precious metal could more than double from recent trading levels, offering potentially substantial returns for investors over the next three years.
Driving Factors Behind the Forecast
The banking giant's bullish outlook on gold is underpinned by several key factors. These include ongoing geopolitical uncertainties, persistent inflation concerns, central bank gold purchases, and the potential weakening of major fiat currencies. JPMorgan analysts point to increased institutional demand and gold's role as a safe-haven asset during economic turbulence.
Market Reaction
The forecast has generated considerable discussion among precious metals traders and investment strategists. Many market participants view JPMorgan's prediction as validation of gold's long-term investment appeal, while others remain cautious about such aggressive price targets.
Investment Implications
If JPMorgan's forecast materializes, investors holding gold-related assets could see significant portfolio appreciation. The projection has already sparked renewed interest in gold bullion, gold mining stocks, and gold-backed exchange-traded funds (ETFs).
Historical Context
Gold has historically served as a hedge against inflation and economic uncertainty. The metal's price has experienced substantial volatility over decades, with previous peaks driven by similar macroeconomic conditions that JPMorgan now identifies as potential catalysts for the projected rally.
Expert Perspectives
While JPMorgan's $6,000 price target represents an optimistic scenario, other financial institutions have also raised their long-term gold forecasts, though typically to more conservative levels. The consensus among analysts suggests continued strength in gold markets, even if the exact trajectory remains uncertain.
Strategic Considerations
Investors considering gold exposure should evaluate their portfolio allocation strategies, risk tolerance, and investment timeline. Diversification remains crucial, as commodity price predictions carry inherent uncertainty despite institutional backing.
The coming years will reveal whether JPMorgan's bold prediction proves accurate as global economic conditions continue to evolve.
Disclaimer: The articles published on this page are written by independent contributors and do not necessarily reflect the official views of MEXC. All content is intended for informational and educational purposes only and is not responsible for any actions taken based on the information provided. The content does not constitute financial, legal, or other professional advice, nor should it be considered a recommendation or endorsement by MEXC. Cryptocurrency markets are highly volatile — please conduct your own research and consult a licensed financial advisor before making any investment decisions.
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MySQL Single Leader Replication with Node.js and Docker
Modern applications demand high availability and the ability to scale reads without compromising performance. One of the most common strategies to achieve this is Replication. In this setup, we configured a single database to act as the leader (master) and handle all write operations, while three replicas handle read operations.
In this article, we’ll walk through how to set up MySQL single-leader replication on your local machine using Docker. Once the replication is working, we’ll connect it to a Node.js application using Sequelize ORM, so that reads are routed to the replica and writes go to the master. By the end, you’ll have a working environment where you can see replication in real time
Prerequisites
knowledge of database replication
Background knowledge of docker and docker compose
Background knowledge of Nodejs and how to run a NodeJS server
An Overview of what we are building
Setup
Setup our database servers on docker compose
in the root of our project directory, create a file named docker-compose.yml with the following content to setup our mysql primary and replica databases.
\ \
name: "learn-replica" volumes: mysqlMasterDatabase: mysqlSlaveDatabase: mysqlSlaveDatabaseII: mysqlSlaveDatabaseIII: networks: mysql-replication-network: services: mysql-master: image: mysql:latest container_name: mysql-master command: --server-id=1 --log-bin=ON environment: MYSQL_ROOT_PASSWORD: master MYSQL_DATABASE: replicaDb ports: - "3306:3306" volumes: - mysqlMasterDatabase:/var/lib/mysql networks: - mysql-replication-network mysql-slave: image: mysql:latest container_name: mysql-slave command: --server-id=2 --log-bin=ON environment: MYSQL_ROOT_PASSWORD: slave MYSQL_DATABASE: replicaDb MYSQL_ROOT_HOST: "%" ports: - "3307:3306" volumes: - mysqlSlaveDatabase:/var/lib/mysql depends_on: - mysql-master networks: - mysql-replication-network mysql-slaveII: image: mysql:latest container_name: mysql-slaveII command: --server-id=2 --log-bin=ON environment: MYSQL_ROOT_PASSWORD: slave MYSQL_DATABASE: replicaDb MYSQL_ROOT_HOST: "%" ports: - "3308:3306" volumes: - mysqlSlaveDatabaseII:/var/lib/mysql depends_on: - mysql-master networks: - mysql-replication-network mysql-slaveIII: image: mysql:latest container_name: mysql-slaveIII command: --server-id=3 --log-bin=ON environment: MYSQL_ROOT_PASSWORD: slave MYSQL_DATABASE: replicaDb MYSQL_ROOT_HOST: "%" ports: - "3309:3306" volumes: - mysqlSlaveDatabaseIII:/var/lib/mysql depends_on: - mysql-master networks: - mysql-replication-network
In this setup, I’m creating a master database container called mysql-master and 3 replica containers called mysql-slave, mysql-slaveII and mysql-slaveIII. I won’t go too deep into the docker-compose.yml file since it’s just a basic setup, but I do want to walk you through the command line instructions used in all four services because that’s where things get interesting.
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:
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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.
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