This document provides a guide to programming in Apiary.
Please also see our tutorial
and documentation.
This document focuses on our Postgres DBMS backend, we also support VoltDB
and will add other databases in the future.
An Apiary program is made up of functions. Apiary provides two types of functions: transactional functions, which can access or modify data and run as DBMS transactions, and stateless functions, which do not access the database. We expect transactional functions to be used for operations on data and stateless functions to be used for communicating with external services and for compute-intensive operations like machine learning inference.
To write a transactional function, simply subclass the PostgresFunction
class and implement your function in its runFunction method.
The first argument to a transactional function is always an ApiaryTransactionalContext object
automatically provided by Apiary and used to access its API. Functions may
have any number of additional arguments but can only take in and return
integers, strings, arrays of integers, and arrays of strings.
Here is an example of a transactional function that registers users in a social network
taken from our tutorial:
public class NectarRegister extends PostgresFunction {
private static final String checkExists = "SELECT * FROM WebsiteLogins WHERE Username=?";
private static final String register = "INSERT INTO WebsiteLogins(Username, Password) VALUES (?, ?);";
public static int runFunction(PostgresContext ctxt, String username, String password) throws SQLException {
ResultSet exists = ctxt.executeQuery(checkExists, username);
if (exists.next()) {
return 1; // Failed registration, username already exists.
}
ctxt.executeUpdate(register, username, password);
return 0;
}
}The ApiaryTransactionalContext object provides methods for updating and querying the database,
described in our documentation. It also provides methods for calling other functions,
described in more detail below.
To write a stateless function, simply subclass the StatelessFunction class
and implement your function in its runFunction method.
The first argument to a stateless function is always an ApiaryStatelessContext object
automatically provided by Apiary and used to access its API. Functions may
have any number of additional arguments but can only take in and return
integers, strings, arrays of integers, and arrays of strings.
Here is a mockup of a stateless function that uses an external notification service
to send a notification to a user:
public class Notify extends StatelessFunction {
public static void runFunction(ApiaryStatelessContext ctxt, String username, String message) {
// Use an external service to notify the user
// about some event, sending the input
// message to them.
}
}Apiary functions can call one another
either synchronously or asynchronously.
To call a function synchronously, use the callFunction method of
the function context (ApiaryTransactionalContext or ApiaryStatelessContext).
Synchronous calls execute and return inside the caller transaction
(if the caller is transactional).
Here's an example of when you might want to call a function synchronously,
in a bank transfer where you need to validate the transfer, withdraw, and deposit,
all in the same transaction:
public class BankTransfer extends PostgresFunction {
public static int runFunction(PostgresContext ctxt,
int senderAccountNumber, int receiverAccountNumber, int amount) {
int validation = ctxt.apiaryCallFunction("org.example.bank.transfer.validate", senderAccountNumber, receiverAccountNumber, amount).getInt();
if (validation == 0) { // Validation succeeded.
ctxt.apiaryCallFunction("org.example.bank.transfer.withdraw", senderAccountNumber, receiverAccountNumber, amount);
ctxt.apiaryCallFunction("org.example.bank.transfer.deposit", senderAccountNumber, receiverAccountNumber, amount);
return 0;
} else { // Validation did not succeed.
return 1;
}
}
}To call a function asynchronously, use the queueFunction method of the function context.
Asynchronous calls execute after their caller in a separate transaction.
They return a future which can be passed to another function or returned,
but cannot be dereferenced directly.
Here's an example of when you might want to call a function asynchronously,
where you want to notify a user that a message was sent to them but don't need to do it
in the same transaction that made the post:
public class SendMessage extends PostgresFunction {
private static final String addMessage = "INSERT INTO Messages(Sender, Receiver, MessageText) VALUES (?, ?, ?);";
public static ApiaryFuture runFunction(PostgresContext ctxt, String sender, String receiver, String message) {
ctxt.executeUpdate(addPost, sender, receiver, message);
ApiaryFuture notificationSuccess = ctxt.apiaryQueueFunction("Notify", receiver, message);
return notificationSuccess; // This will be dereferenced upon delievery, so the caller will receieve the actual success value.
}
}To run Apiary, you need to start up a worker that can communicate with the database
and run functions. To do this, first create a database connection
(e.g., PostgresConnection) and use it to create tables.
Then, start an ApiaryWorker and register your connection and functions with it.
For example, here is the code to initialize a Postgres connection,
create the tables used in the tutorial,
launch a worker, and then register the Postgres connection and the tutorial functions
with the worker:
PostgresConnection conn = new PostgresConnection("localhost", ApiaryConfig.postgresPort, "postgres", "dbos");
conn.createTable("WebsiteLogins", "Username VARCHAR(1000) PRIMARY KEY NOT NULL, Password VARCHAR(1000) NOT NULL");
conn.createTable("WebsitePosts", "Sender VARCHAR(1000) NOT NULL, Receiver VARCHAR(1000) NOT NULL, PostText VARCHAR(10000) NOT NULL");
ApiaryWorker apiaryWorker = new ApiaryWorker(new ApiaryNaiveScheduler(), 4, ApiaryConfig.postgres, ApiaryConfig.provenanceDefaultAddress);
apiaryWorker.registerConnection(ApiaryConfig.postgres, conn);
apiaryWorker.registerFunction("NectarRegister", ApiaryConfig.postgres, NectarRegister::new);
apiaryWorker.registerFunction("NectarLogin", ApiaryConfig.postgres, NectarLogin::new);
apiaryWorker.registerFunction("NectarAddPost", ApiaryConfig.postgres, NectarAddPost::new);
apiaryWorker.registerFunction("NectarGetPosts", ApiaryConfig.postgres, NectarGetPosts::new);
apiaryWorker.startServing();After a worker is running, you can launch clients to communicate with it and call functions. For example, in a social network application, to retrieve all messages sent to a user:
ApiaryWorkerClient client = new ApiaryWorkerClient("localhost");
String[] posts = client.executeFunction("GetMessages", username).getStringArray();Apiary captures data provenance information on all function executions
and all operations functions perform on data. This information is stored
in database tables (by default in Postgres, but we also support Vertica)
for easy querying. First, Apiary maintains a FuncInvocations
table storing information on all function invocations. Its schema is:
| Field | Type | Description |
|---|---|---|
| APIARY_TRANSACTION_ID | BIGINT | Postgres Transaction ID . |
| APIARY_TIMESTAMP | BIGINT | Unix epoch timestamp in microseconds. |
| APIARY_EXECUTIONID | BIGINT | Unique ID of program execution. |
| APIARY_ROLE | VARCHAR | Name of the role. |
| APIARY_PROCEDURENAME | VARCHAR | Function name. |
Then, for each database table in an application, Apiary
maintains an Events table tracking all operations that occured on the table:
| Field | Type | Description |
|---|---|---|
| APIARY_TRANSACTION_ID | BIGINT | Postgres Transaction ID . |
| APIARY_TIMESTAMP | BIGINT | Unix epoch timestamp in microseconds. |
| APIARY_OPERATION_TYPE | BIGINT | The type of the operation: 1 for inserts, 2 for deletes, 3 for updates, 4 for reads. |
| Table columns... | Any | The column values of the record being operated on. |
If you haven't already, please look at the tutorial and documentation. If you have any questions, feel free to contact us.