| name | firebase-database |
| description | Use when syncing real-time data, structuring JSON trees, reading/writing, creating listeners, enabling offline persistence, managing presence, sharding, or writing security rules. |
Firebase Realtime Database Skill
This skill defines how to correctly implement Firebase Realtime Database in Flutter applications, covering data modeling, queries, real-time sync, offline support, and security rules.
When to Use
Use this skill when working with Firebase Realtime Database for simple data models, low-latency sync, or presence functionality. For rich data models requiring complex queries and high scalability, use Cloud Firestore instead.
1. Database Selection
Choose Realtime Database when the app needs:
- Simple data models with simple lookups.
- Extremely low-latency synchronization (typical response times under 10ms).
- Deep queries that return an entire subtree by default.
- Access to data at any granularity, down to individual leaf-node values.
- Frequent state-syncing with built-in presence functionality.
Choose Cloud Firestore instead for rich data models requiring queryability, scalability, and high availability.
2. Setup and Configuration
flutter pub add firebase_database
import 'package:firebase_database/firebase_database.dart';
// After Firebase.initializeApp():
final DatabaseReference ref = FirebaseDatabase.instance.ref();
- Select the database location closest to users.
- Enable persistence for offline capabilities:
FirebaseDatabase.instance.setPersistenceEnabled(true);
FirebaseDatabase.instance.setPersistenceCacheSizeBytes(10000000); // 10MB
Setup Checklist
- Confirm
Firebase.initializeApp() completes before accessing FirebaseDatabase.instance.
- Set persistence before any read/write operations.
- Verify connectivity by writing a test value and reading it back.
3. Data Structure
- Structure data as a flattened JSON tree — avoid deep nesting.
- Maximum nesting depth is 32 levels.
- Design the data structure to support the most common queries.
- Use push IDs for unique identifiers in list-type data:
final newPostKey = FirebaseDatabase.instance.ref().child('posts').push().key;
- Denormalize data when necessary — Realtime Database does not support joins.
- Custom keys must be UTF-8 encoded, max 768 bytes, and cannot contain
. $ # [ ] / or ASCII control characters 0-31 or 127.
Flattened Structure Example
// Instead of nesting chat messages inside rooms:
// rooms/roomId/messages/messageId/...
// Flatten into separate top-level paths:
// rooms/roomId: { name: "General", createdBy: "uid1" }
// room-members/roomId: { uid1: true, uid2: true }
// room-messages/roomId/messageId: { text: "Hello", sender: "uid1", timestamp: ... }
This pattern allows reading room metadata without downloading all messages.
4. Indexing and Querying
- Queries can sort or filter on a property, but not both in the same query.
- Use
.indexOn in security rules to index frequently queried fields:
{
"rules": {
"dinosaurs": {
".indexOn": ["height", "length"]
}
}
}
- Queries are deep by default and return the entire subtree.
- Sort with
orderByChild(), orderByKey(), or orderByValue():
final query = FirebaseDatabase.instance.ref("dinosaurs").orderByChild("height");
- Limit results with
limitToFirst() or limitToLast():
final query = ref.orderByChild("height").limitToFirst(10);
- Range queries using
startAt(), endAt(), and equalTo():
// Find users whose name starts with "A"
final query = ref.child("users")
.orderByChild("name")
.startAt("A")
.endAt("A\uf8ff");
5. Read and Write Operations
Read once:
final snapshot = await FirebaseDatabase.instance.ref('users/123').get();
if (snapshot.exists) {
print(snapshot.value);
}
Real-time listener:
final subscription = FirebaseDatabase.instance
.ref('users/123')
.onValue
.listen((event) {
final data = event.snapshot.value;
print(data);
});
// Cancel when no longer needed:
subscription.cancel();
A DatabaseEvent fires every time data changes at the reference, including changes to children.
Write (replace):
await ref.set({
"name": "John",
"age": 18,
"created_at": ServerValue.timestamp,
});
Update (partial):
await ref.update({"age": 19});
Atomic transaction:
final result = await FirebaseDatabase.instance
.ref('posts/123/likes')
.runTransaction((currentValue) {
return Transaction.success((currentValue as int? ?? 0) + 1);
});
print('Likes: ${result.snapshot.value}');
Multi-path atomic update:
final updates = <String, dynamic>{
'posts/$postId': postData,
'user-posts/$uid/$postId': postData,
};
await FirebaseDatabase.instance.ref().update(updates);
- Keep individual write operations under 256KB.
- Use listeners for real-time updates rather than polling.
6. Designing for Scale
- Realtime Database scales to ~200,000 concurrent connections and 1,000 writes/second per database. For higher scale, shard data across multiple database instances.
- Avoid storing large blobs — use Firebase Storage for files.
- Use server timestamps for consistent time tracking:
await FirebaseDatabase.instance.ref('posts/123/timestamp').set(ServerValue.timestamp);
- Implement fan-out patterns for data accessed from multiple paths.
- Avoid deep nesting — it leads to performance issues when retrieving data.
7. Offline Capabilities and Presence
FirebaseDatabase.instance.setPersistenceEnabled(true);
// Keep critical paths synced when offline
FirebaseDatabase.instance.ref('important-data').keepSynced(true);
Connection State and Presence
// Detect connection state
FirebaseDatabase.instance.ref('.info/connected').onValue.listen((event) {
final connected = event.snapshot.value as bool? ?? false;
if (connected) {
// Set online status and configure onDisconnect cleanup
final presenceRef = FirebaseDatabase.instance.ref('status/${uid}');
presenceRef.set({'online': true, 'last_seen': ServerValue.timestamp});
presenceRef.onDisconnect().set({
'online': false,
'last_seen': ServerValue.timestamp,
});
}
});
- Use value events (
onValue) to read data and get notified of updates — optimized for online/offline transitions.
- Use
get() only when data is needed once; it probes local cache if the server is unavailable.
onDisconnect() operations are executed server-side, ensuring cleanup even if the app crashes.
8. Security
{
"rules": {
"users": {
"$uid": {
".read": "$uid === auth.uid",
".write": "$uid === auth.uid"
}
}
}
}
- Use
.read, .write, .validate, and .indexOn to control access and validate data.
- Read and write rules cascade in Realtime Database — a parent rule granting access cannot be revoked by a child rule.
- Use the
auth variable to authenticate users in security rules.
Data Validation Example
{
"rules": {
"messages": {
"$messageId": {
".validate": "newData.hasChildren(['text', 'sender', 'timestamp'])",
"text": {
".validate": "newData.isString() && newData.val().length <= 500"
}
}
}
}
}
- Test rules thoroughly using the Firebase console's rules simulator.
- Use the Firebase Emulator Suite for local testing.
References