Getting Started with ScalarDB by Using Kotlin
This getting started tutorial explains how to configure your preferred database in ScalarDB and set up a basic electronic money application by using Kotlin. Since Kotlin has Java interoperability, you can use ScalarDB directly from Kotlin.
The electronic money application is simplified for this tutorial and isn't suitable for a production environment.
Install a JDK​
Because ScalarDB is written in Java, you must have one of the following Java Development Kits (JDKs) installed in your environment:
- Oracle JDK LTS version (8, 11, or 17)
- OpenJDK LTS version (8, 11, or 17)
We recommend using the LTS versions mentioned above, but other non-LTS versions may work.
In addition, other JDKs should work with ScalarDB, but we haven't tested them.
Clone the scalardb
repository​
Open a terminal window, and go to your working directory. Then, clone the scalardb repository by running the following command:
$ git clone https://github.com/scalar-labs/scalardb
Then, go to the scalardb/docs/getting-started-kotlin
directory in the cloned repository by running the following command:
$ cd scalardb/docs/getting-started-kotlin
Set up your database for ScalarDB​
Select your database, and follow the instructions to configure it for ScalarDB.
For a list of databases that ScalarDB supports, see Supported Databases.
- Cassandra
- Cosmos DB for NoSQL
- DynamoDB
- JDBC databases
Confirm that you have Cassandra installed. If Cassandra isn't installed, visit Downloading Cassandra.
Configure Cassandra
Open cassandra.yaml in your preferred IDE. Then, change commitlog_sync
from periodic
to batch
so that you don't lose data if a quorum of replica nodes goes down.
Configure ScalarDB
The following instructions assume that you have properly installed and configured the JDK and Cassandra in your local environment, and Cassandra is running on your localhost.
The scalardb.properties file in the docs/getting-started-kotlin
directory holds database configurations for ScalarDB. The following is a basic configuration for Cassandra. Be sure to change the values for scalar.db.username
and scalar.db.password
as described.
# The Cassandra storage implementation is used for Consensus Commit.
scalar.db.storage=cassandra
# Comma-separated contact points.
scalar.db.contact_points=localhost
# The port number for all the contact points.
scalar.db.contact_port=9042
# The username and password to access the database.
scalar.db.username=<USER_NAME>
scalar.db.password=<USER_PASSWORD>
To use Azure Cosmos DB for NoSQL, you must have an Azure account. If you don't have an Azure account, visit Create an Azure Cosmos DB account.
Configure Cosmos DB for NoSQL
Set the default consistency level to Strong according to the official document at Configure the default consistency level.
Configure ScalarDB
The following instructions assume that you have properly installed and configured the JDK in your local environment and properly configured your Cosmos DB for NoSQL account in Azure.
The scalardb.properties file in the docs/getting-started-kotlin
directory holds database configurations for ScalarDB. Be sure to change the values for scalar.db.contact_points
and scalar.db.password
as described.
# The Cosmos DB for NoSQL storage implementation is used for Consensus Commit.
scalar.db.storage=cosmos
# The Cosmos DB for NoSQL URI.
scalar.db.contact_points=<COSMOS_DB_FOR_NOSQL_URI>
# The Cosmos DB for NoSQL key to access the database.
scalar.db.password=<COSMOS_DB_FOR_NOSQL_KEY>
You can use a primary key or a secondary key as the value for scalar.db.password
.
To use Amazon DynamoDB, you must have an AWS account. If you don't have an AWS account, visit Getting started: Are you a first-time AWS user?.
Configure ScalarDB
The following instructions assume that you have properly installed and configured the JDK in your local environment.
The scalardb.properties file in the docs/getting-started-kotlin
directory holds database configurations for ScalarDB. Be sure to change the values for scalar.db.contact_points
, scalar.db.username
, and scalar.db.password
as described.
# The DynamoDB storage implementation is used for Consensus Commit.
scalar.db.storage=dynamo
# The AWS region.
scalar.db.contact_points=<REGION>
# The AWS access key ID and secret access key to access the database.
scalar.db.username=<ACCESS_KEY_ID>
scalar.db.password=<SECRET_ACCESS_KEY>
Confirm that you have a JDBC database installed. For a list of supported JDBC databases, see Supported Databases.
Configure ScalarDB
The following instructions assume that you have properly installed and configured the JDK and JDBC database in your local environment, and the JDBC database is running on your localhost.
The scalardb.properties file in the docs/getting-started-kotlin
directory holds database configurations for ScalarDB. The following is a basic configuration for JDBC databases.
Be sure to uncomment the scalar.db.contact_points
variable and change the value of the JDBC database you are using, and change the values for scalar.db.username
and scalar.db.password
as described.
# The JDBC database storage implementation is used for Consensus Commit.
scalar.db.storage=jdbc
# The JDBC database URL for the type of database you are using.
# scalar.db.contact_points=jdbc:mysql://localhost:3306/
# scalar.db.contact_points=jdbc:oracle:thin:@//localhost:1521/
# scalar.db.contact_points=jdbc:postgresql://localhost:5432/
# scalar.db.contact_points=jdbc:sqlserver://localhost:1433;
# scalar.db.contact_points=jdbc:sqlite://localhost:3306.sqlite3?busy_timeout=10000
# The username and password for connecting to the database.
scalar.db.username=<USER_NAME>
scalar.db.password=<PASSWORD>
Create and load the database schema​
You need to define the database schema (the method in which the data will be organized) in the application. For details about the supported data types, see Data type mapping between ScalarDB and other databases.
For this tutorial, create a file named emoney.json in the scalardb/docs/getting-started-kotlin
directory. Then, add the following JSON code to define the schema.
{
"emoney.account": {
"transaction": true,
"partition-key": [
"id"
],
"clustering-key": [],
"columns": {
"id": "TEXT",
"balance": "INT"
}
}
}
To apply the schema, go to the scalardb
Releases page and download the ScalarDB Schema Loader that matches the version of ScalarDB that you are using to the getting-started
folder.
Then, run the following command, replacing <VERSION>
with the version of the ScalarDB Schema Loader that you downloaded:
$ java -jar scalardb-schema-loader-<VERSION>.jar --config scalardb.properties --schema-file emoney.json --coordinator
The --coordinator
option is specified because a table with transaction
set to true
exists in the schema. For details about configuring and loading a schema, see ScalarDB Schema Loader.
Execute transactions and retrieve data in the basic electronic money application​
After loading the schema, you can execute transactions and retrieve data in the basic electronic money application that is included in the repository that you cloned.
The application supports the following types of transactions:
- Create an account.
- Add funds to an account.
- Send funds between two accounts.
- Get an account balance.
When you first execute a Gradle command, Gradle will automatically install the necessary libraries.
Create an account with a balance​
You need an account with a balance so that you can send funds between accounts.
To create an account for customer1 that has a balance of 500, run the following command:
$ ./gradlew run --args="-action charge -amount 500 -to customer1"
Create an account without a balance​
After setting up an account that has a balance, you need another account for sending funds to.
To create an account for merchant1 that has a balance of 0, run the following command:
$ ./gradlew run --args="-action charge -amount 0 -to merchant1"
Add funds to an account​
You can add funds to an account in the same way that you created and added funds to an account in Create an account with a balance.
To add 500 to the account for customer1, run the following command:
$ ./gradlew run --args="-action charge -amount 500 -to customer1"
The account for customer1 will now have a balance of 1000.
Send electronic money between two accounts​
Now that you have created two accounts, with at least one of those accounts having a balance, you can send funds from one account to the other account.
To have customer1 pay 100 to merchant1, run the following command:
$ ./gradlew run --args="-action pay -amount 100 -from customer1 -to merchant1"
Get an account balance​
After sending funds from one account to the other, you can check the balance of each account.
To get the balance of customer1, run the following command:
$ ./gradlew run --args="-action getBalance -id customer1"
You should see the following output:
...
The balance for customer1 is 900
...
To get the balance of merchant1, run the following command:
$ ./gradlew run --args="-action getBalance -id merchant1"
You should see the following output:
...
The balance for merchant1 is 100
...
Reference​
To see the source code for the electronic money application used in this tutorial, see ElectronicMoney.kt
.