2025-12-03 19:09:46
Hi everyone! 👋
I was tired of "Unfollowers" apps that require a monthly subscription, show tons of ads, or worse—ask for my Instagram password (which is a huge security risk).
So, being a developer, I decided to build a safe, open-source alternative. I took inspiration from existing community scripts and wrapped them into a modern, user-friendly tool with a brand new Glassmorphism UI and Mobile support.
It's a script that runs locally in your browser console. It scans your followers/following lists using your active session and shows you exactly who isn't following you back.
(The tool running on Desktop)
You don't need to install Node.js or clone the repo if you just want to use it.
For those interested in the code, the project is built using:
It is completely Open Source. You can audit the code, contribute, or give it a star ⭐️ here:
👉 GitHub Repository: EdvinCodes/InstagramUnfollowers
This project is heavily based on community knowledge, and I want to keep improving it.
If you find any bugs or have suggestions, please let me know in the comments below or email me directly at: [email protected].
Hope it helps you clean up your feed! Happy coding! 🚀
2025-12-03 19:01:24
In the previous blog post, we highlighted some of the new features in SeaORM 2.0. In this post, we're going to take a closer look to some of the changes under the hood.
Entity::insert_many
#2628 We've received many issue reports around the insert_many API. Previously, insert_many shares the same helper struct with insert_one, which led to an awkard API:
let res = Bakery::insert_many(std::iter::empty())
.on_empty_do_nothing() // <- you needed to add this,
// otherwise insert empty [] would lead to error
.exec(db)
.await;
assert!(matches!(res, Ok(TryInsertResult::Empty)));
After careful consideration, we made a number of changes in 2.0:
Insert::add) that can panicInsertMany, last_insert_id is now Option<Value>
None (for last_insert_id) or vec![] (when returning) is returned on executionTryInsert API is unchangedi.e. now last_insert_id is Option<Value> for InsertMany:
struct InsertManyResult<A: ActiveModelTrait>
{
pub last_insert_id: Option<<PrimaryKey<A> as PrimaryKeyTrait>::ValueType>,
}
Which means the awkardness is removed:
let res = Entity::insert_many::<ActiveModel, _>([]).exec(db).await;
assert_eq!(res?.last_insert_id, None); // insert nothing return None
let res = Entity::insert_many([ActiveModel { id: Set(1) }, ActiveModel { id: Set(2) }])
.exec(db)
.await;
assert_eq!(res?.last_insert_id, Some(2)); // insert something return Some
Exec with returning now returns a Vec<Model>, so it feels intuitive:
assert!(
Entity::insert_many::<ActiveModel, _>([])
.exec_with_returning(db)
.await?
.is_empty() // no footgun, nice
);
assert_eq!(
Entity::insert_many([
ActiveModel {
id: NotSet,
value: Set("two".into()),
}
])
.exec_with_returning(db)
.await
.unwrap(),
[
Model {
id: 2,
value: "two".into(),
}
]
);
Same on conflict API as before:
let res = Entity::insert_many([ActiveModel { id: Set(3) }, ActiveModel { id: Set(4) }])
.on_conflict_do_nothing()
.exec(db)
.await;
assert!(matches!(conflict_insert, Ok(TryInsertResult::Conflicted)));
ConnectionTrait API
#2657
We overhauled the ConnectionTrait API. execute, query_one, query_all, stream now takes in SeaQuery statement instead of raw SQL statement.
So you don't have to access the backend to build the query yourself.
// old
let query: SelectStatement = Entity::find().filter(..).into_query();
let backend = self.db.get_database_backend();
let stmt = backend.build(&query);
let rows = self.db.query_all(stmt).await?;
// new
let query: SelectStatement = Entity::find().filter(..).into_query();
let rows = self.db.query_all(&query).await?;
A new set of methods execute_raw, query_one_raw, query_all_raw, stream_raw is added, so you can still do the following:
let backend = self.db.get_database_backend();
let stmt = backend.build(&query);
// new
let rows = self.db.query_all_raw(stmt).await?;
UpdateOne / DeleteOne
#2726 UpdateOne and DeleteOne no longer implement QueryFilter and QueryTrait
directly. Those implementations could expose an incomplete SQL query with an incomplete condition that touches too many records.
// bad: the following is basically update all
let query: UpdateStatement = Update::one(cake::ActiveModel::default()).into_query();
To generate the right condition, we must make sure that the primary key is set on the input ActiveModel by
calling the validate() method:
Update::one(active_model)
+ .validate()? // checks the query; may yield PrimaryKeyNotSet error
.build(DbBackend::Postgres)
If you need to access the generated SQL query, convert into ValidatedUpdateOne/ValidatedDeleteOne first.
error[E0599]: no method named `build` found for struct `query::update::UpdateOne` in the current scope
--> src/entity/column.rs:607:22
|
> | / Update::one(active_model)
> | | .build(DbBackend::Postgres)
| | -^^^^^ method not found in `UpdateOne<A>`
| |_____________________|
|
has_many_via for reverse has many relation
Consider the following entities:
#[derive(Clone, Debug, PartialEq, Eq, DeriveEntityModel)]
#[sea_orm(table_name = "bakery")]
pub struct Model {
#[sea_orm(primary_key)]
pub id: i32,
pub name: String,
pub manager_id: i32,
pub cashier_id: i32,
}
#[derive(Copy, Clone, Debug, EnumIter, DeriveRelation)]
pub enum Relation {
#[sea_orm(
belongs_to = "super::worker::Entity",
from = "Column::ManagerId",
to = "super::worker::Column::Id"
)]
Manager,
#[sea_orm(
belongs_to = "super::worker::Entity",
from = "Column::CashierId",
to = "super::worker::Column::Id"
)]
Cashier,
}
#[derive(Clone, Debug, PartialEq, Eq, DeriveEntityModel)]
#[sea_orm(table_name = "worker")]
pub struct Model {
#[sea_orm(primary_key)]
pub id: i32,
pub name: String,
}
There exist two relations between them:
Bakery -> Worker (Manager)
-> Worker (Cashier)
It's now possible to define the inverse side of the relations in Worker:
#[derive(Clone, Debug, PartialEq, Eq, DeriveEntityModel)]
#[sea_orm(table_name = "worker")]
pub struct Model {
#[sea_orm(primary_key)]
pub id: i32,
pub name: String,
}
#[derive(Copy, Clone, Debug, EnumIter, DeriveRelation)]
pub enum Relation {
#[sea_orm(has_many = "super::bakery::Entity", via = "Relation::Manager")]
BakeryManager,
#[sea_orm(has_many = "super::bakery::Entity", via = "Relation::Cashier")]
BakeryCashier,
}
These relations can then be used in queries:
assert_eq!(
worker::Entity::find().join(
JoinType::LeftJoin,
worker::Relation::BakeryManager.def(),
)
.build(DbBackend::Sqlite)
.to_string(),
r#"SELECT "worker"."id", "worker"."name" FROM "worker"
LEFT JOIN "bakery" ON "worker"."id" = "bakery"."manager_id""#
);
You can already use TransactionTrait as a generic parameter to define functions accepting any connection object that can initiate transactions.
In SeaORM 2.0, there are new database-connection-like objects: RestrictedConnection and RestrictedTransaction. They implement ConnectionTrait and TransactionTrait, and behaves just like normal DatabaseConnections except that they performs additional checks on queries.
| Connection type | Associated transaction type |
|---|---|
DatabaseConnection |
DatabaseTransaction |
RestrictedConnection |
RestrictedTransaction |
// new connection type
pub struct RestrictedConnection {
conn: DatabaseConnection, // just a wrapper
user_id: UserId,
}
impl TransactionTrait for RestrictedConnection {
type Transaction = RestrictedTransaction; // added associated type
}
Meaning the following would continue to work:
// accepts any one of DatabaseConnection / DatabaseTransaction / RestrictedConnection / RestrictedTransaction.
// nested transactions will be spawned for transaction objects
async fn perform_actions<C: TransactionTrait>(
db: &C,
actions: &[Action],
) -> Result<(), DbErr> {
let txn = db.begin().await?;
for action in actions {
txn.execute(perform(action)).await?;
}
txn.commit().await
}
SeaORM has a large API surface. We've already removed a great number of unwraps from the codebase in 1.0 release, but some panics due to "mis-use of API" can still happen.
Once again, we've tried to remove the remaining panics.
BackendNotSupported. Previously, it panics with e.g. "Database backend doesn't support RETURNING"
let result = cake::Entity::insert_many([])
.exec_with_returning_keys(db)
.await;
if db.support_returning() {
// Postgres and SQLite
assert_eq!(result.unwrap(), []);
} else {
// MySQL
assert!(matches!(result, Err(DbErr::BackendNotSupported { .. })));
}
PrimaryKeyNotSet. Previously, it panics with "PrimaryKey is not set"
assert!(matches!(
Update::one(cake::ActiveModel {
..Default::default()
})
.exec(&db)
.await,
Err(DbErr::PrimaryKeyNotSet { .. })
));
Schema::create_enum_from_active_enum
// method can now return None
fn create_enum_from_active_enum<A>(&self) -> Option<TypeCreateStatement>
/// Add a Model to `Insert`
///
/// # Panics
///
/// Panics if the rows have different column sets from what've previously
/// been cached in the query statement
- pub fn add<M>(mut self, m: M) -> Self
These are small touch‑ups, but added up they can make a big difference.
= ANY
Added ColumnTrait::eq_any as a shorthand for the = ANY operator. Postgres only.
// old: have to import sea-query
use sea_orm::sea_query::{Expr, extension::postgres::PgFunc};
cake::Entity::find()
.filter(
// have to qualify column manually
Expr::col((cake::Entity, cake::Column::Id)).eq(PgFunc::any(vec![4, 5]))
);
// new: just use sea-orm
assert_eq!(
cake::Entity::find()
.filter(cake::Column::Id.eq_any(vec![4, 5]))
.build(DbBackend::Postgres)
.to_string(),
r#"SELECT "cake"."id", "cake"."name" FROM "cake"
WHERE "cake"."id" = ANY(ARRAY [4,5])"#
);
big_pk_auto
// old
pub fn pk_auto<T: IntoIden>(name: T) -> ColumnDef {
integer(name).auto_increment().primary_key().take()
}
// new: same as above but use big integer
pub fn big_pk_auto<T: IntoIden>(name: T) -> ColumnDef {
big_integer(name).auto_increment().primary_key().take()
}
chrono::Utc to entity prelude
pub type ChronoUtc = chrono::Utc;
We can now rely on sea-orm's re-export:
// old: chrono has to be added in Cargo.toml
let ts: ChronoDateTimeUtc = chrono::Utc::now();
// new: use sea-orm's re-export
let ts: ChronoDateTimeUtc = ChronoUtc::now();
&'static str in identifiers
#2667 Changed IdenStatic and EntityName definition. This change stemmed from the revamp of the Iden type system in SeaQuery, in which &'static str now has slightly less overhead.
trait IdenStatic {
fn as_str(&self) -> &'static str; // added static lifetime
}
trait EntityName {
fn table_name(&self) -> &'static str; // added static lifetime
}
QueryBuilder is no longer object safe
Removed DbBackend::get_query_builder() because QueryBuilder is no longer object safe. This change improved query building performance by 5-10%.
impl DbBackend {
// This is removed
- fn get_query_builder(&self) -> Box<dyn QueryBuilder>;
}
Previously dyn SqlWriter is used everywhere.
fn prepare_table_create_statement(
&self,
create: &TableCreateStatement,
sql: &mut dyn SqlWriter,
);
Now, it's a generic method:
fn prepare_table_create_statement(
&self,
create: &TableCreateStatement,
sql: &mut impl SqlWriter, // note the impl
);
This change shouldn't impact most users because we have the following API:
pub trait StatementBuilder {
fn build(&self, db_backend: &DbBackend) -> Statement;
}
// implemented for SelectStatement, InsertStatement, UpdateStatement, DeleteStatement, etc
Database Connection
#2671 DatabaseConnection is changed from enum to struct. The original enum is moved into DatabaseConnection::inner. The new enum is named DatabaseConnectionType.
This allows DatabaseConnection to hold additional metadata.
// old
pub enum DatabaseConnection {
SqlxMySqlPoolConnection(crate::SqlxMySqlPoolConnection),
SqlxPostgresPoolConnection(crate::SqlxPostgresPoolConnection),
SqlxSqlitePoolConnection(crate::SqlxSqlitePoolConnection),
..
}
// new
pub struct DatabaseConnection {
pub inner: DatabaseConnectionType,
..
}
pub enum DatabaseConnectionType {
SqlxMySqlPoolConnection(crate::SqlxMySqlPoolConnection),
SqlxPostgresPoolConnection(crate::SqlxPostgresPoolConnection),
SqlxSqlitePoolConnection(crate::SqlxSqlitePoolConnection),
..
}
Derive Custom Column
#2667 Removed DeriveCustomColumn macro and default_as_str trait method. This was a legacy of the expanded entity format.
// This is no longer supported:
#[derive(Copy, Clone, Debug, EnumIter, DeriveCustomColumn)]
pub enum Column {
Id,
Name,
}
impl IdenStatic for Column {
fn as_str(&self) -> &str {
match self {
Self::Name => "my_name",
_ => self.default_as_str(),
}
}
}
// Do the following instead:
#[derive(Copy, Clone, Debug, EnumIter, DeriveColumn)]
pub enum Column {
Id,
#[sea_orm(column_name = "my_name")]
Name,
}
tokio is now used in place of async-std in sea-orm-cli and examples as async-std has been deprecated.3.35 which was released in 2021, it should be the default by now.strum to 0.27
SQL Server for SeaORM offers the same SeaORM API for MSSQL. We ported all test cases and examples, complemented by MSSQL specific documentation. If you are building enterprise software, you can request commercial access. It is currently based on SeaORM 1.0, but we will offer free upgrade to existing users when SeaORM 2.0 is finalized.
SeaORM Pro is an admin panel solution allowing you to quickly and easily launch an admin panel for your application - frontend development skills not required, but certainly nice to have!
SeaORM Pro will be updated to support the latest features in SeaORM 2.0.
Features:
SeaORM 2.0 is shaping up to be our most significant release yet - with a few breaking changes, plenty of enhancements, and a clear focus on developer experience. We'll dive into Role Based Access Control in the next post, so keep an eye out for the next update!
SeaORM 2.0 will launch alongside SeaQuery 1.0. If you make extensive use of SeaORM's underlying query builder, we recommend checking out our earlier blog post on SeaQuery 1.0 to get familiar with the changes.
SeaORM 2.0 has reached its release candidate phase. We'd love for you to try it out and help shape the final release by sharing your feedback.
The Rustacean Sticker Pack is the perfect way to express your passion for Rust.
Our stickers are made with a premium water-resistant vinyl with a unique matte finish.
Sticker Pack Contents:
Support SeaQL and get a Sticker Pack!
2025-12-03 19:00:07
A technical perspective on browser automation internals, protocol architectures, and when to use what.
Browser automation comes down to two fundamental approaches:
WebDriver - W3C standardized, cross-browser, high-level abstraction over HTTP REST.
CDP - Chrome's native debugging protocol, WebSocket-based, low-level access to browser internals.
Both solve browser automation. Neither is universally "better." Your use case dictates the choice.
┌──────────────┐ HTTP/REST ┌──────────────┐ Native ┌─────────────┐
│ Client │ ◄────────────► │ Driver │ ◄──────────► │ Browser │
│ (Selenium) │ Port 4444 │ (chromedriver│ Protocol │ (Chrome) │
└──────────────┘ │ geckodriver)│ └─────────────┘
└──────────────┘
Three-tier model:
The middleman tax: Every command pays HTTP overhead + driver process latency.
┌──────────────┐ WebSocket ┌─────────────┐
│ Client │ ◄────────────► │ Browser │
│ (Direct) │ Port 9222 │ (Chrome) │
└──────────────┘ └─────────────┘
Two-tier model:
No middleman. Direct protocol access. Events pushed in real-time.
WebDriver is a W3C Recommendation since 2018. It defines a REST API for browser automation with focus on cross-browser compatibility.
HTTP/REST with JSON payloads:
POST /session HTTP/1.1
Content-Type: application/json
{
"capabilities": {
"browserName": "chrome",
"browserVersion": "120"
}
}
# Create session
POST /session
→ {"sessionId": "abc123", "capabilities": {...}}
# All subsequent commands use session ID
POST /session/abc123/url
GET /session/abc123/title
POST /session/abc123/element
DELETE /session/abc123
| Endpoint | Method | Purpose |
|---|---|---|
/session |
POST | Create new session |
/session/{id} |
DELETE | End session |
/session/{id}/url |
POST | Navigate to URL |
/session/{id}/url |
GET | Get current URL |
/session/{id}/title |
GET | Get page title |
/session/{id}/element |
POST | Find element |
/session/{id}/element/{eid}/click |
POST | Click element |
/session/{id}/element/{eid}/value |
POST | Send keys |
/session/{id}/screenshot |
GET | Capture screenshot |
/session/{id}/execute/sync |
POST | Execute JS |
{
"using": "css selector",
"value": "button.submit"
}
Supported locators:
css selectorlink textpartial link texttag namexpath# 1. Create session
curl -X POST http://localhost:4444/session \
-H "Content-Type: application/json" \
-d '{"capabilities": {"browserName": "chrome"}}'
# Response: {"value": {"sessionId": "xyz789", ...}}
# 2. Navigate
curl -X POST http://localhost:4444/session/xyz789/url \
-H "Content-Type: application/json" \
-d '{"url": "https://example.com"}'
# 3. Find element
curl -X POST http://localhost:4444/session/xyz789/element \
-H "Content-Type: application/json" \
-d '{"using": "css selector", "value": "h1"}'
# Response: {"value": {"element-6066-...": "element-id-123"}}
# 4. Get text
curl http://localhost:4444/session/xyz789/element/element-id-123/text
# Response: {"value": "Example Domain"}
# 5. Screenshot
curl http://localhost:4444/session/xyz789/screenshot
# Response: {"value": "iVBORw0KGgo...base64..."}
# 6. Cleanup
curl -X DELETE http://localhost:4444/session/xyz789
console.log outputCDP is Chrome's native debugging protocol. It's what DevTools uses internally. Direct access to 61 domains covering every browser capability.
Bidirectional WebSocket with JSON-RPC:
Client Browser
│ │
│──── {"id":1,"method":"Page.navigate", ───►
│ "params":{"url":"..."}} │
│ │
│◄─── {"id":1,"result":{"frameId":...}} ───
│ │
│◄─── {"method":"Page.loadEventFired", ────
│ "params":{"timestamp":...}} │
│ │
Three message types:
id + method)id + result/error)method only, no id)CDP organizes into domains. Each domain has methods and events.
Core domains:
| Domain | Methods | Events | Purpose |
|---|---|---|---|
| Page | 25+ | 15+ | Navigation, lifecycle, screenshots |
| Runtime | 20+ | 10+ | JS execution, console |
| DOM | 30+ | 10+ | Document structure |
| Network | 15+ | 20+ | HTTP traffic |
| Input | 5+ | 0 | Mouse, keyboard, touch |
| Emulation | 20+ | 0 | Device simulation |
| Target | 15+ | 5+ | Tab/window management |
| Debugger | 25+ | 10+ | JS debugging |
| Profiler | 10+ | 5+ | CPU profiling |
| HeapProfiler | 10+ | 5+ | Memory profiling |
Before WebSocket, discover targets via HTTP:
# List all debuggable targets
curl http://localhost:9222/json/list
[
{
"id": "ABC123",
"type": "page",
"title": "New Tab",
"url": "chrome://newtab/",
"webSocketDebuggerUrl": "ws://localhost:9222/devtools/page/ABC123"
}
]
# Browser version
curl http://localhost:9222/json/version
{
"Browser": "Chrome/120.0.0.0",
"Protocol-Version": "1.3",
"webSocketDebuggerUrl": "ws://localhost:9222/devtools/browser/XYZ"
}
# Create new tab
curl http://localhost:9222/json/new?https://example.com
# Close tab
curl http://localhost:9222/json/close/ABC123
1. Navigation
// Enable Page domain first
→ {"id": 1, "method": "Page.enable"}
← {"id": 1, "result": {}}
// Navigate
→ {"id": 2, "method": "Page.navigate", "params": {"url": "https://example.com"}}
← {"id": 2, "result": {"frameId": "ABC", "loaderId": "XYZ"}}
// Events fired automatically
← {"method": "Page.frameStartedLoading", "params": {"frameId": "ABC"}}
← {"method": "Page.loadEventFired", "params": {"timestamp": 1234.56}}
← {"method": "Page.frameStoppedLoading", "params": {"frameId": "ABC"}}
2. JavaScript Evaluation
→ {"id": 1, "method": "Runtime.enable"}
← {"id": 1, "result": {}}
→ {"id": 2, "method": "Runtime.evaluate", "params": {
"expression": "document.title",
"returnByValue": true
}}
← {"id": 2, "result": {
"result": {"type": "string", "value": "Example Domain"}
}}
// Complex evaluation
→ {"id": 3, "method": "Runtime.evaluate", "params": {
"expression": "(() => { return {width: window.innerWidth, height: window.innerHeight}; })()",
"returnByValue": true
}}
← {"id": 3, "result": {
"result": {"type": "object", "value": {"width": 1920, "height": 1080}}
}}
3. DOM Operations
→ {"id": 1, "method": "DOM.enable"}
← {"id": 1, "result": {}}
→ {"id": 2, "method": "DOM.getDocument", "params": {"depth": 0}}
← {"id": 2, "result": {
"root": {"nodeId": 1, "nodeName": "#document", "childNodeCount": 2}
}}
→ {"id": 3, "method": "DOM.querySelector", "params": {"nodeId": 1, "selector": "h1"}}
← {"id": 3, "result": {"nodeId": 42}}
→ {"id": 4, "method": "DOM.getOuterHTML", "params": {"nodeId": 42}}
← {"id": 4, "result": {"outerHTML": "<h1>Example Domain</h1>"}}
4. Network Interception
→ {"id": 1, "method": "Network.enable"}
← {"id": 1, "result": {}}
// Events stream automatically
← {"method": "Network.requestWillBeSent", "params": {
"requestId": "req-1",
"request": {
"url": "https://example.com/api/data",
"method": "GET",
"headers": {"Accept": "application/json"}
},
"timestamp": 1234.56,
"type": "XHR"
}}
← {"method": "Network.responseReceived", "params": {
"requestId": "req-1",
"response": {
"status": 200,
"statusText": "OK",
"headers": {"content-type": "application/json"},
"mimeType": "application/json"
}
}}
← {"method": "Network.loadingFinished", "params": {
"requestId": "req-1",
"encodedDataLength": 1234
}}
// Get response body
→ {"id": 2, "method": "Network.getResponseBody", "params": {"requestId": "req-1"}}
← {"id": 2, "result": {"body": "{\"data\": [...]}", "base64Encoded": false}}
5. Screenshots
→ {"id": 1, "method": "Page.captureScreenshot", "params": {
"format": "png",
"quality": 100,
"fromSurface": true
}}
← {"id": 1, "result": {"data": "iVBORw0KGgoAAAANSUhEUgAAA..."}}
// Full page screenshot
→ {"id": 2, "method": "Page.captureScreenshot", "params": {
"format": "png",
"captureBeyondViewport": true
}}
// Specific region
→ {"id": 3, "method": "Page.captureScreenshot", "params": {
"format": "jpeg",
"quality": 80,
"clip": {"x": 0, "y": 0, "width": 800, "height": 600, "scale": 1}
}}
6. Input Simulation
// Mouse click
→ {"id": 1, "method": "Input.dispatchMouseEvent", "params": {
"type": "mousePressed",
"x": 100, "y": 200,
"button": "left",
"clickCount": 1
}}
← {"id": 1, "result": {}}
→ {"id": 2, "method": "Input.dispatchMouseEvent", "params": {
"type": "mouseReleased",
"x": 100, "y": 200,
"button": "left",
"clickCount": 1
}}
// Type text
→ {"id": 3, "method": "Input.insertText", "params": {"text": "Hello World"}}
// Key press
→ {"id": 4, "method": "Input.dispatchKeyEvent", "params": {
"type": "keyDown",
"key": "Enter",
"code": "Enter",
"windowsVirtualKeyCode": 13
}}
→ {"id": 5, "method": "Input.dispatchKeyEvent", "params": {
"type": "keyUp",
"key": "Enter",
"code": "Enter"
}}
7. Console Capture
→ {"id": 1, "method": "Runtime.enable"}
← {"id": 1, "result": {}}
// Console events stream automatically
← {"method": "Runtime.consoleAPICalled", "params": {
"type": "log",
"args": [{"type": "string", "value": "Hello from page"}],
"timestamp": 1234567890.123
}}
← {"method": "Runtime.consoleAPICalled", "params": {
"type": "error",
"args": [{"type": "string", "value": "Something went wrong"}],
"stackTrace": {...}
}}
8. Performance Metrics
→ {"id": 1, "method": "Performance.enable"}
← {"id": 1, "result": {}}
→ {"id": 2, "method": "Performance.getMetrics"}
← {"id": 2, "result": {
"metrics": [
{"name": "Timestamp", "value": 1234.56},
{"name": "Documents", "value": 1},
{"name": "Frames", "value": 1},
{"name": "JSEventListeners", "value": 42},
{"name": "Nodes", "value": 150},
{"name": "LayoutCount", "value": 3},
{"name": "RecalcStyleCount", "value": 5},
{"name": "JSHeapUsedSize", "value": 10485760},
{"name": "JSHeapTotalSize", "value": 16777216}
]
}}
| Aspect | WebDriver | CDP |
|---|---|---|
| Specification | W3C Standard | Chrome Internal |
| Transport | HTTP REST | WebSocket |
| Connection | Request/Response | Persistent + Events |
| Latency | Higher (HTTP per command) | Lower (single WS) |
| Message Format | JSON over HTTP | JSON-RPC over WS |
| Aspect | WebDriver | CDP |
|---|---|---|
| Components | Client + Driver + Browser | Client + Browser |
| Driver Required | Yes (chromedriver, etc.) | No |
| Version Coupling | Driver ↔ Browser tight | Protocol versioned |
| Port | 4444 (driver) | 9222 (browser) |
| Feature | WebDriver | CDP |
|---|---|---|
| Navigation | ✅ | ✅ |
| Element Interaction | ✅ | ✅ |
| JavaScript Execution | ✅ | ✅ |
| Screenshots | ✅ | ✅ |
| Cookies | ✅ | ✅ |
| Network Interception | ❌ | ✅ |
| Console Access | ❌ | ✅ |
| Performance Metrics | ❌ | ✅ |
| Real-time Events | ❌ | ✅ |
| DOM Debugging | ❌ | ✅ |
| CPU Profiling | ❌ | ✅ |
| Memory Profiling | ❌ | ✅ |
| Geolocation Emulation | Limited | ✅ |
| Device Emulation | Limited | ✅ |
| Request Blocking | ❌ | ✅ |
| Browser | WebDriver | CDP |
|---|---|---|
| Chrome | ✅ | ✅ |
| Edge | ✅ | ✅ (Chromium) |
| Firefox | ✅ | Partial |
| Safari | ✅ | ❌ |
| Opera | ✅ | ✅ (Chromium) |
| Tool | WebDriver | CDP |
|---|---|---|
| Selenium | Primary | Via BiDi |
| Puppeteer | ❌ | Primary |
| Playwright | Uses both | Uses both |
| Cypress | ❌ | Primary |
Modern tools use both:
Playwright:
- WebDriver for cross-browser compat
- CDP for Chrome-specific features
Selenium 4 BiDi:
- WebDriver base protocol
- CDP bridge for advanced features
We built a production-ready Rust CDP client with two abstraction layers.
cdp-protocol/
├── src/
│ ├── lib.rs # Public exports
│ ├── client.rs # Low-level CDP client (WebSocket, routing)
│ ├── agent.rs # High-level BrowserAgent (AI-friendly)
│ ├── types.rs # Protocol message types
│ └── error.rs # Error handling
├── examples/
│ ├── basic.rs # Low-level usage
│ ├── agent.rs # High-level AI agent
│ └── industrial.rs # Parallel scraping
└── Cargo.toml
[dependencies]
tokio = { version = "1", features = ["full"] }
tokio-tungstenite = "0.21"
serde = { version = "1", features = ["derive"] }
serde_json = "1"
reqwest = { version = "0.11", features = ["json"] }
base64 = "0.21"
tracing = "0.1"
Direct protocol access with convenience wrappers.
use cdp_protocol::{CdpClient, Result};
#[tokio::main]
async fn main() -> Result<()> {
// Discovery
let version = CdpClient::get_version("localhost", 9222).await?;
println!("Browser: {}", version.browser);
let targets = CdpClient::list_targets("localhost", 9222).await?;
for target in &targets {
println!(" - {} [{}]: {}", target.target_type, target.id, target.title);
}
// Connect
let client = CdpClient::connect_to_page("localhost", 9222).await?;
// Enable domains
client.enable_domain("Page").await?;
client.enable_domain("Runtime").await?;
client.enable_domain("DOM").await?;
// Navigate
let nav = client.navigate("https://example.com").await?;
println!("Frame ID: {}", nav.frame_id);
tokio::time::sleep(std::time::Duration::from_secs(2)).await;
// JavaScript
let title: String = client.eval("document.title").await?;
println!("Title: {}", title);
let result = client.evaluate("1 + 2 * 3").await?;
println!("Math: {:?}", result.result.value);
// DOM
let doc = client.get_document().await?;
let h1_id = client.query_selector(doc.node_id, "h1").await?;
if h1_id > 0 {
let html = client.get_outer_html(h1_id).await?;
println!("H1: {}", html);
}
// Screenshot
client.screenshot_to_file("example.png").await?;
// Cookies
let cookies = client.get_cookies().await?;
println!("Cookies: {}", cookies.len());
Ok(())
}
AI-friendly interface with JSON action dispatch.
use cdp_protocol::{BrowserAgent, BrowserAction, ActionResult};
#[tokio::main]
async fn main() -> Result<()> {
let agent = BrowserAgent::connect("localhost", 9222).await?;
// Programmatic
agent.execute(BrowserAction::Navigate {
url: "https://example.com".to_string(),
}).await;
agent.execute(BrowserAction::GetTitle).await;
// JSON (LLM tool calls)
agent.execute_json(r#"{"action": "navigate", "url": "https://rust-lang.org"}"#).await;
agent.execute_json(r#"{"action": "wait", "ms": 2000}"#).await;
agent.execute_json(r#"{"action": "screenshot", "path": "rust.png"}"#).await;
Ok(())
}
Fluent API for chaining:
use cdp_protocol::ActionBuilder;
let actions = ActionBuilder::new()
.navigate("https://www.google.com")
.wait(1500)
.fill("input[name='q']", "Rust programming")
.press_key("Enter")
.wait(2000)
.screenshot(Some("search.png"))
.build();
let results = agent.execute_many(actions).await;
pub enum BrowserAction {
// Navigation
Navigate { url: String },
GoBack,
GoForward,
Reload,
// Interaction
Click { selector: Option<String>, x: Option<f64>, y: Option<f64> },
Type { text: String, selector: Option<String> },
Fill { selector: String, value: String },
Submit { selector: Option<String> },
PressKey { key: String },
// Inspection
GetTitle,
GetUrl,
GetText,
GetContent { selector: Option<String> },
GetLinks,
GetAttributes { selector: String },
Exists { selector: String },
// Capture
Screenshot { path: Option<String> },
// Scripting
Evaluate { expression: String },
// Waiting
Wait { ms: u64 },
WaitForSelector { selector: String, timeout_ms: u64 },
// Layout
Scroll { x: f64, y: f64 },
SetViewport { width: i32, height: i32, mobile: bool },
// Metrics
GetMetrics,
}
let search_actions = vec![
BrowserAction::Navigate {
url: "https://duckduckgo.com".to_string(),
},
BrowserAction::Wait { ms: 1500 },
BrowserAction::Fill {
selector: "input[name='q']".to_string(),
value: "Rust programming language".to_string(),
},
BrowserAction::PressKey {
key: "Enter".to_string(),
},
BrowserAction::Wait { ms: 2000 },
BrowserAction::Screenshot {
path: Some("search_results.png".to_string()),
},
BrowserAction::GetTitle,
];
for action in search_actions {
let result = agent.execute(action).await;
if !result.is_success() {
println!("Failed: {:?}", result);
break;
}
}
let result = agent.execute(BrowserAction::Evaluate {
expression: r#"
(() => {
return {
viewport: {
width: window.innerWidth,
height: window.innerHeight
},
userAgent: navigator.userAgent,
language: navigator.language,
cookiesEnabled: navigator.cookieEnabled,
platform: navigator.platform
};
})()
"#.to_string(),
}).await;
use cdp_protocol::{CdpClient, Result};
use std::sync::Arc;
use std::time::Instant;
use tokio::sync::Semaphore;
const NUM_PAGES: usize = 50;
const MAX_CONCURRENT: usize = 10;
const URLS: &[&str] = &[
"https://www.rust-lang.org",
"https://www.google.com",
"https://github.com",
"https://stackoverflow.com",
"https://news.ycombinator.com",
"https://www.wikipedia.org",
"https://www.reddit.com",
"https://docs.rs",
"https://crates.io",
"https://www.mozilla.org",
];
#[tokio::main]
async fn main() -> Result<()> {
std::fs::create_dir_all("screenshots").ok();
let start = Instant::now();
let semaphore = Arc::new(Semaphore::new(MAX_CONCURRENT));
let mut handles = Vec::with_capacity(NUM_PAGES);
for i in 0..NUM_PAGES {
let url = URLS[i % URLS.len()].to_string();
let sem = semaphore.clone();
let handle = tokio::spawn(async move {
let _permit = sem.acquire().await.unwrap();
process_page(i, &url).await
});
handles.push(handle);
}
let mut success = 0;
let mut failed = 0;
for (i, handle) in handles.into_iter().enumerate() {
match handle.await {
Ok(Ok((title, elapsed))) => {
println!("[{:3}] ✓ {} ({:.1}s)", i, title, elapsed);
success += 1;
}
Ok(Err(e)) => {
println!("[{:3}] ✗ Error: {}", i, e);
failed += 1;
}
Err(e) => {
println!("[{:3}] ✗ Panic: {}", i, e);
failed += 1;
}
}
}
let total = start.elapsed();
println!("\nTotal: {:.2}s | Success: {} | Failed: {} | {:.2} pages/sec",
total.as_secs_f64(), success, failed,
NUM_PAGES as f64 / total.as_secs_f64());
Ok(())
}
async fn process_page(id: usize, url: &str) -> Result<(String, f64)> {
let start = Instant::now();
let target = CdpClient::create_tab("localhost", 9222, Some(url)).await?;
let ws_url = target.web_socket_debugger_url
.ok_or_else(|| cdp_protocol::CdpError::InvalidUrl("No WS URL".into()))?;
let client = CdpClient::connect(&ws_url).await?;
client.enable_domain("Page").await?;
client.enable_domain("Runtime").await?;
tokio::time::sleep(std::time::Duration::from_millis(2000)).await;
let title: String = client.eval("document.title").await
.unwrap_or_else(|_| "Unknown".to_string());
client.screenshot_to_file(&format!("screenshots/page_{:03}.png", id)).await?;
Ok((title, start.elapsed().as_secs_f64()))
}
Output:
=== Industrial Scraping Demo ===
Pages to process: 50
Max concurrent: 10
[ 0] ✓ Rust Programming Language (3.2s)
[ 1] ✓ Google (2.8s)
...
[ 49] ✓ Hacker News (2.9s)
Total: 18.42s | Success: 50 | Failed: 0 | 2.71 pages/sec
| Requirement | Recommendation |
|---|---|
| Cross-browser testing | WebDriver |
| Chrome-only, max performance | CDP |
| Network mocking | CDP |
| AI agent automation | CDP |
| Existing Selenium codebase | WebDriver (+ BiDi for CDP features) |
| Console/log capture | CDP |
| Performance profiling | CDP |
| Simple E2E tests | Either works |
WebDriver BiDi is bridging the gap - adding CDP-like capabilities to WebDriver. Selenium 4 already supports it. Eventually, you'll get the best of both worlds through a unified spec.
Until then:
2025-12-03 18:56:45
Python is currently the best tool for training machine learning models (AI), with many tools available in the Python ecosystem - like PyTorch and Hugging Face Transformers - it has never been easier to create a proof of concept for an AI model. We are big fans of Python because of how easy and flexible it is.
However, let's take a look at the deployment aspect of using the model.
When it comes to inference (running a trained model) on platforms where you need to run a model in a production environment or on a device that is not a computer, Python starts to show its disadvantages.
If you've tried deploying a PyTorch application before, then you already know the pain points involved in the process. You have to create a multi-gigabyte Docker container image just to run a simple Python script. The cold-starting time associated with a large interpreter is very slow, and the memory required to run these types of models makes it impossible to run on most consumer-level CPUs or edge devices.
Is it possible to benefit from all of the advantages of modern large language models (LLMs) and deploy them with significantly less overhead?
This is where Rust and Candle come into play.
Candle is a minimalistic machine learning (ML) framework created by Hugging Face. You can utilize Candle and run state-of-the-art AI models without having to depend on Python. When we combine Rust's ability to provide memory safety and speed with Microsoft Phi-3 (an advanced small language model), we can reach an entirely different level of performance.
In this guide, I will show you how to:
Ditch the heavy PyTorch dependency.
Load a quantized Phi-3 model directly in Rust.
Build a standalone, lightweight CLI tool that runs blazing-fast inference on a standard CPU.
No GPU required. No 5GB Docker images. Just pure, high-performance Rust.
Let's dive in.
*Step 1: Setting Up the Project
*
First, let's create a new Rust project. Open your terminal and run:cargo new rust-phi3-cpu
cd rust-phi3-cpu
Next, we need to add the Candle stack to our Cargo.toml. Since we are focusing on CPU inference, we will use the quantized features to keep the model lightweight and fast.
Open Cargo.toml and add the following dependencies:
[package]
name = "rust-phi3"
version = "0.1.0"
edition = "2021"
[dependencies]
anyhow = "1.0"
tokenizers = "0.19.1"
clap = { version = "4.4", features = ["derive"] }
candle-core = { git = "https://github.com/huggingface/candle.git", branch = "main" }
candle-transformers = { git = "https://github.com/huggingface/candle.git", branch = "main" }
candle-nn = { git = "https://github.com/huggingface/candle.git", branch = "main" }
We are using candle-transformers which has built-in support for GGUF (quantized) models. This is the secret sauce for running heavy models on a CPU efficiently.
*Step 2: The Implementation
*
Now, open src/main.rs. We are going to build a simple CLI that accepts a prompt and generates text.
The logic is straightforward:
Load the Model: Read the .gguf file (Phi-3 Mini).
Tokenize: Convert the user's prompt into numbers (tokens).
Inference Loop: Feed tokens into the model one by one to generate the next word.
Here is the main.rs
use anyhow::{Error as E, Result};
use clap::Parser;
use candle_transformers::models::quantized_phi3 as model; // Using Phi-3 specific module
use candle_core::{Tensor, Device};
use candle_core::quantized::gguf_file;
use tokenizers::Tokenizer;
use std::io::Write;
#[derive(Parser, Debug)]
#[command(author, version, about, long_about = None)]
struct Args {
/// The prompt to run inference with
#[arg(short, long, default_value = "Physics is fun. Explain quantum physics to a 5-year-old in simple words:")]
prompt: String,
/// Path to the GGUF model file
#[arg(long, default_value = "Phi-3-mini-4k-instruct-q4.gguf")]
model_path: String,
}
fn main() -> Result<()> {
let args = Args::parse();
println!("Loading model from: {}", args.model_path);
// 1. Setup Device (CPU)
let device = Device::Cpu;
// 2. Load the GGUF Model
let mut file = std::fs::File::open(&args.model_path)
.map_err(|_| E::msg(format!("Could not find model file at {}. Did you download it?", args.model_path)))?;
// Read the GGUF content
let content = gguf_file::Content::read(&mut file)?;
// Load model weights (Flash Attention set to false for CPU)
let mut model = model::ModelWeights::from_gguf(false, content, &mut file, &device)?;
// 3. Load Tokenizer
println!("Loading tokenizer...");
let tokenizer = Tokenizer::from_file("tokenizer.json").map_err(E::msg)?;
// 4. Encode Prompt
let tokens = tokenizer.encode(args.prompt, true).map_err(E::msg)?;
let prompt_tokens = tokens.get_ids();
let mut all_tokens = prompt_tokens.to_vec();
// 5. Inference Loop
println!("Generating response...\n");
let mut to_generate = 100; // Generate 100 tokens max
let mut logits_processor = candle_transformers::generation::LogitsProcessor::new(299792458, None, None);
print!("Response: ");
std::io::stdout().flush()?;
let mut next_token = *prompt_tokens.last().unwrap();
for _ in 0..to_generate {
let input = Tensor::new(&[next_token], &device)?.unsqueeze(0)?;
let logits = model.forward(&input, all_tokens.len())?;
let logits = logits.squeeze(0)?;
next_token = logits_processor.sample(&logits)?;
all_tokens.push(next_token);
if let Some(t) = tokenizer.decode(&[next_token], true).ok() {
print!("{}", t);
std::io::stdout().flush()?;
}
}
println!("\n\nDone!");
Ok(())
}
*Step 3: Getting the Model Weights
*
Before we run this, we need the actual brain of the AI. Since we are optimizing for CPU, we will use the GGUF format (Quantized).
You can download the Phi-3-Mini-4k-Instruct (Quantized) from Hugging Face. Look for the q4_k_m.gguf version (approx. 2.3 GB).
Model: Phi-3-mini-4k-instruct-q4.gguf
Tokenizer: tokenizer.json (from the official repo)
*Step 4: Running the Demo
*
This is the moment of truth.
Before running, make sure to compile in release mode. Rust’s debug builds are optimized for debugging, not speed. For AI inference, the difference is massive (often 10x-100x slower in debug mode).
Run the following command in your terminal:cargo run --release -- --model-path "Phi-3-mini-4k-instruct-q4.gguf" --prompt "whatever you want:"
What happens next? You won't see a long delay while a Python interpreter spins up or massive libraries import. Instead, within milliseconds, you’ll see the tokens streaming to your console.
On my local machine (Surface / intel 8100Y), I am getting a smooth stream of tokens, fully generated on the CPU. No heavy lifting required.
The model weights file size is the same for both, but the deployment artifact size (the code + runtime) is drastically smaller in Rust.
This makes Rust an ideal candidate for Edge AI, IoT devices, or Serverless functions where startup time and memory footprint are critical costs.
Does this mean Python is dead? Absolutely not.
Python remains the best ecosystem for training, experimenting, and data science. However, when it's time to take that model and ship it to production—especially in resource-constrained environments—Rust is a superpower.
By using frameworks like Candle, we can run modern LLMs like Phi-3 on standard CPUs with incredible efficiency. We get the safety and speed of Rust without sacrificing the capabilities of modern AI.
2025-12-03 18:56:27
WebAssembly (WASM) is rapidly evolving into the “universal virtual machine”. Originally designed to let browsers run non‑JavaScript code, WASM has grown beyond its initial scope. Today, major toolchains such as C/C++, Rust, Go, Zig, and even higher‑level languages like Python and C# can compile to WASM, making it a powerful cross‑platform runtime.
Both the WASM Virtual Machine and the Java Virtual Machine (JVM) are stack‑based machines. This architectural similarity means that compiling from WASM bytecode to JVM bytecode is not only possible but practical. Projects like Chicory demonstrate this by translating WASM modules into native JVM classes.
This approach solves a long‑standing problem:
How do we reuse existing C/C++ libraries in modern toolchains without rewriting everything?
Traditionally, developers faced two choices:
Each has trade‑offs:
With WASM, we no longer need to choose between rewriting or wrapping. Instead:
This yields a pure JVM artifact — no external DLLs, no native dependencies — while still leveraging proven C/C++ libraries.
As a demonstration, we compiled a non‑trivial C/C++ library capable of rendering Microsoft Word .docx files to PDF. Using Chicory, we produced a native Java library published via Maven: WordSDK Java HelloWorld
Here’s how it integrates with e.g. Docx4J to produce a PDF:
WordSDK.Worker api=WordSDK.createWorker(options);
// Create an import stream for feeding into WordSDK
OutputStream importStream=api.createImportStream();
// feed the DOCX4J document into WordSDK
Docx4J.save(wordMLPackage, importStream, Docx4J.FLAG_NONE);
// generate an in-memory PDF for further processing...
final byte[] pdf=api.exportPDF();
The result: a native JVM library that consumes WASM‑compiled C/C++ code, seamlessly integrated into Java enterprise workflows. Go to WordSDK Java HelloWorld to give it a try!
One of the most common questions when introducing a new runtime layer is: “But how fast is it?”
The good news: performance is excellent. Running WASM modules inside the JVM via Chicory is comparable to executing WASM in environments like Node.js. As with any virtual machine, there is a small overhead compared to native execution, but this is the same trade‑off developers already accept when running code in the JVM or other managed runtimes.
Huge credit to the Chicory project. Its ability to compile non‑trivial WASM modules into JVM classes is a game‑changer for developers bridging ecosystems.
We are curious to hear how this approach could fit into your enterprise workflows — and if you’ve experimented with this approach yourself, we’d love to learn from your experiences too.
2025-12-03 18:55:07
Hello there!👋🧔♂️ Today, we're exploring the three main service lifetimes: singleton, scoped, and transient.
Understanding dependency injection (DI) lifecycle management is crucial for building reliable applications. Get it wrong, and you might end up with memory leaks or shared state bugs. Get it right, and your code will be cleaner and easier to maintain!
When you register a service in a dependency injection container, you need to specify its *lifetime, how long the container should keep an instance alive. The three main lifetimes are:
Singleton is like having one shared tool that everyone uses. There's only one instance, and it lives for the entire lifetime of your application.
Key Characteristics:
Use singleton for:
// Register as singleton
services.AddSingleton<ICacheService, CacheService>();
services.AddSingleton<ILogger, Logger>();
// Example: Cache service
public class CacheService : ICacheService
{
private readonly Dictionary<string, object> _cache = new();
private readonly object _lock = new object();
public void Set<T>(string key, T value)
{
lock (_lock) { _cache[key] = value; }
}
public T Get<T>(string key)
{
lock (_lock)
{
return _cache.TryGetValue(key, out var value) ? (T)value : default(T);
}
}
}
⚠️ Watch out for:
// BAD: Singleton with mutable state
public class BadService
{
public string CurrentUserId { get; set; } // Shared across all requests!
}
IDisposable if holding resourcesScoped is like having a personal workspace for each task. In web applications, each HTTP request gets its own scope, and all scoped services share the same instance within that scope.
Key Characteristics:
Use scoped for:
// Register as scoped
services.AddScoped<IDbContext, ApplicationDbContext>();
services.AddScoped<IOrderService, OrderService>();
// Example: Database context
public class ApplicationDbContext : DbContext
{
public DbSet<Order> Orders { get; set; }
}
public class OrderService
{
private readonly ApplicationDbContext _context;
public OrderService(ApplicationDbContext context) =>
_context = context; // Same instance throughout the request
public async Task<Order> CreateOrder(Order order)
{
_context.Orders.Add(order);
await _context.SaveChangesAsync();
return order;
}
}
⚠️ Watch out for:
// BAD: Singleton depending on scoped service
public class BadSingleton
{
private readonly IScopedService _scoped; // Error!
}
// GOOD: Use IServiceProvider
public class GoodSingleton
{
private readonly IServiceProvider _serviceProvider;
public GoodSingleton(IServiceProvider serviceProvider) =>
_serviceProvider = serviceProvider;
public void DoWork()
{
using (var scope = _serviceProvider.CreateScope())
{
var scoped = scope.ServiceProvider.GetRequiredService<IScopedService>();
scoped.DoWork();
}
}
}
Transient is like getting a fresh tool every time you need one. Each time you request a transient service, you get a brand new instance. Important: Transient instances are NOT kept alive for the app lifetime, they're created on-demand and disposed when they go out of scope (garbage collected).
Key Characteristics:
Use transient for:
// Register as transient
services.AddTransient<IEmailService, EmailService>();
services.AddTransient<IValidator<Order>, OrderValidator>();
// Example: Validator service
public class OrderValidator : IValidator<Order>
{
public ValidationResult Validate(Order order)
{
var result = new ValidationResult();
if (order.Items == null || order.Items.Count == 0)
result.AddError("Order must have at least one item");
return result;
}
}
⚠️ Watch out for:
| Aspect | Singleton | Scoped | Transient |
|---|---|---|---|
| Instance Count | One for entire app | One per scope | New every time |
| Lifetime | Application lifetime | Scope lifetime (per request) | Shortest - disposed when out of scope |
| Memory Usage | Low (shared) | Medium | High (many instances created) |
| Thread Safety | Must be thread-safe | Usually not needed | Usually not needed |
| Disposal | When app shuts down | When scope ends | When garbage collected |
| Use Case | Stateless, expensive | Request-specific | Lightweight, stateless |
public void ConfigureServices(IServiceCollection services)
{
// Singleton: Shared across all requests
services.AddSingleton<ICacheService, CacheService>();
// Scoped: One per HTTP request
services.AddScoped<IDbContext, ApplicationDbContext>();
// Transient: New instance each time
services.AddTransient<IEmailService, EmailService>();
}
public class BackgroundWorker : BackgroundService
{
private readonly IServiceProvider _serviceProvider;
public BackgroundWorker(IServiceProvider serviceProvider) =>
_serviceProvider = serviceProvider;
protected override async Task ExecuteAsync(CancellationToken stoppingToken)
{
while (!stoppingToken.IsCancellationRequested)
{
// Create a scope for each iteration
using (var scope = _serviceProvider.CreateScope())
{
var scopedService = scope.ServiceProvider.GetRequiredService<IScopedService>();
await scopedService.DoWorkAsync();
}
await Task.Delay(1000, stoppingToken);
}
}
}
A service can only depend on services with equal or longer lifetimes.
Common Mistake:
// BAD: Singleton depending on scoped service
public class SingletonService
{
private readonly IScopedService _scoped; // Error!
}
// GOOD: Use IServiceProvider to create scope when needed
public class SingletonService
{
private readonly IServiceProvider _serviceProvider;
public SingletonService(IServiceProvider serviceProvider) =>
_serviceProvider = serviceProvider;
public void DoWork()
{
using (var scope = _serviceProvider.CreateScope())
{
var scoped = scope.ServiceProvider.GetRequiredService<IScopedService>();
scoped.DoWork();
}
}
}
IServiceProvider when you need to break the rules// Implement IDisposable for services that hold resources
public class ResourceService : IDisposable
{
private bool _disposed = false;
public void Dispose()
{
if (_disposed) return;
// Clean up resources
_disposed = true;
}
}
Understanding dependency injection lifetimes is crucial for building robust applications:
Singleton - One instance for the entire application:
Scoped - One instance per scope (request):
Transient - New instance every time:
The Golden Rules:
IDisposable for resource cleanupRemember, there's no one-size-fits-all answer. The right choice depends on your specific use case and performance requirements. Start with the most restrictive lifetime that works, and adjust as needed.
You've got this! 💪 Happy coding!