Top 30 Domande da Colloquio React
Guida completa alle 30 domande più frequenti nei colloqui tecnici React, con risposte dettagliate ed esempi di codice.
I colloqui tecnici React valutano la comprensione dei concetti fondamentali, dei pattern avanzati e delle best practice. Questa guida raccoglie le 30 domande più frequenti, con risposte dettagliate ed esempi di codice per prepararsi al colloquio in modo efficace.
Consiglio di preparazione
Queste domande sono organizzate per livello di difficoltà. Padroneggiare i fondamenti prima di affrontare i concetti avanzati permette di costruire una preparazione più solida.
Fondamenti di React
1. Che cos'è il Virtual DOM e perché React lo utilizza?
Il Virtual DOM è una rappresentazione leggera in JavaScript del DOM reale. React utilizza questa astrazione per ottimizzare gli aggiornamenti dell'interfaccia.
Il processo si svolge in tre fasi: React crea prima una copia virtuale del DOM, poi confronta questa copia con la versione precedente quando si verificano cambiamenti (algoritmo di diffing) e infine applica al DOM reale solo le modifiche necessarie (reconciliation).
jsx
// Simplified example of the concept
// When state changes, React doesn't recreate the entire DOM
function Counter() {
const [count, setCount] = useState(0)
// Only the span containing count will be updated in the real DOM
// The rest of the component is untouched
return (
<div>
<h1>Counter</h1>
<span>{count}</span>
<button onClick={() => setCount(count + 1)}>+1</button>
</div>
)
}Questo approccio evita operazioni costose sul DOM e consente aggiornamenti performanti anche in interfacce complesse.
2. Qual è la differenza tra componenti funzionali e componenti classe?
I componenti funzionali sono funzioni JavaScript che ricevono props e restituiscono JSX. Da React 16.8 gli hook permettono di usare stato e ciclo di vita all'interno dei componenti funzionali.
jsx
// Functional component (recommended)
// More concise, easier to test, supports hooks
function Welcome({ name }) {
const [visits, setVisits] = useState(0)
useEffect(() => {
setVisits(v => v + 1)
}, [])
return <h1>Hello {name}, visit #{visits}</h1>
}
// Class component (legacy)
// More verbose, requires this binding
class WelcomeClass extends React.Component {
state = { visits: 0 }
componentDidMount() {
this.setState(prev => ({ visits: prev.visits + 1 }))
}
render() {
return <h1>Hello {this.props.name}, visit #{this.state.visits}</h1>
}
}I componenti funzionali sono oggi lo standard. I componenti classe restano supportati ma non sono più consigliati per i nuovi progetti.
3. Come funziona JSX?
JSX è un'estensione di sintassi per JavaScript che permette di scrivere markup all'interno del codice. Non è HTML, ma JavaScript sotto mentite spoglie.
jsx
// What we write (JSX)
const element = (
<div className="container">
<h1>Title</h1>
<p>Paragraph</p>
</div>
)
// What Babel compiles (pure JavaScript)
const element = React.createElement(
'div',
{ className: 'container' },
React.createElement('h1', null, 'Title'),
React.createElement('p', null, 'Paragraph')
)Tra le differenze rispetto all'HTML: className al posto di class, htmlFor al posto di for, camelCase per gli attributi (onClick, tabIndex) e chiusura obbligatoria dei tag auto-chiudenti.
4. Qual è la differenza tra state e props?
Le props sono dati passati da un componente padre a un figlio. Sono in sola lettura. Lo state è lo stato interno di un componente, modificabile tramite setter.
UserCard.jsxjsx
// name and role are props (immutable)
function UserCard({ name, role }) {
// isExpanded is state (mutable)
const [isExpanded, setIsExpanded] = useState(false)
return (
<div className="card">
<h2>{name}</h2>
<p>{role}</p>
{/* Modifying state triggers a re-render */}
<button onClick={() => setIsExpanded(!isExpanded)}>
{isExpanded ? 'Collapse' : 'Details'}
</button>
{isExpanded && <UserDetails name={name} />}
</div>
)
}
// Usage
<UserCard name="Alice" role="Developer" />La regola fondamentale: le props scendono dall'alto (padre → figlio), lo state è locale a ciascun componente.
5. Perché le key sono importanti nelle liste?
Le key aiutano React a identificare quali elementi sono stati modificati, aggiunti o rimossi in una lista. Senza key uniche e stabili React può presentare comportamenti inattesi.
jsx
// ❌ Bad practice: index as key
// Problem: if order changes, React loses tracking
{items.map((item, index) => (
<ListItem key={index} item={item} />
))}
// ✅ Good practice: unique and stable identifier
{items.map(item => (
<ListItem key={item.id} item={item} />
))}
// Concrete example of the problem with indices
function TodoList() {
const [todos, setTodos] = useState([
{ id: 1, text: 'Learn React' },
{ id: 2, text: 'Create a project' }
])
// When deleting the first element with key={index}
// React will think element 0's content changed
// instead of understanding an element was removed
return (
<ul>
{todos.map(todo => (
<li key={todo.id}>{todo.text}</li>
))}
</ul>
)
}React Hooks
6. Spiegare useState e le sue insidie comuni
useState gestisce lo stato locale in un componente funzionale. Il setter può ricevere un valore oppure una funzione di aggiornamento.
jsx
// Declaration with initial value
const [count, setCount] = useState(0)
// ❌ Pitfall: multiple updates in the same cycle
function increment() {
setCount(count + 1) // count = 0, sets 1
setCount(count + 1) // count = 0 still, sets 1
setCount(count + 1) // count = 0 still, sets 1
// Final result: 1 (not 3)
}
// ✅ Solution: use the update function
function incrementCorrect() {
setCount(prev => prev + 1) // 0 → 1
setCount(prev => prev + 1) // 1 → 2
setCount(prev => prev + 1) // 2 → 3
// Final result: 3
}
// ❌ Pitfall: object mutation
const [user, setUser] = useState({ name: 'Alice', age: 25 })
user.age = 26 // Direct mutation, no re-render
// ✅ Solution: create a new object
setUser({ ...user, age: 26 })
// or
setUser(prev => ({ ...prev, age: 26 }))7. Come funziona useEffect con l'array delle dipendenze?
useEffect esegue effetti collaterali dopo il render. L'array delle dipendenze controlla quando l'effetto viene eseguito.
jsx
// Executed on every render (rare, usually avoid)
useEffect(() => {
console.log('Render completed')
})
// Executed only on mount (equivalent to componentDidMount)
useEffect(() => {
console.log('Component mounted')
// Cleanup on unmount (equivalent to componentWillUnmount)
return () => {
console.log('Component unmounted')
}
}, [])
// Executed when userId changes
useEffect(() => {
async function fetchUser() {
const response = await fetch(`/api/users/${userId}`)
const data = await response.json()
setUser(data)
}
fetchUser()
}, [userId])
// ❌ Missing dependency - subtle bug
useEffect(() => {
const timer = setInterval(() => {
setCount(count + 1) // count is "captured" at its initial value
}, 1000)
return () => clearInterval(timer)
}, []) // count is missing from dependencies
// ✅ Fix with update function
useEffect(() => {
const timer = setInterval(() => {
setCount(prev => prev + 1) // No need for count in deps
}, 1000)
return () => clearInterval(timer)
}, [])Regola ESLint
Abilitare sempre eslint-plugin-react-hooks per rilevare le dipendenze mancanti. Questa regola previene molti bug difficili da diagnosticare.
8. Quando usare useMemo e useCallback?
Questi hook permettono la memoizzazione per evitare ricalcoli o ricreazioni inutili. Occorre però non abusarne.
jsx
// useMemo: memoizes a computed value
function ProductList({ products, filter }) {
// Recalculated only if products or filter change
const filteredProducts = useMemo(() => {
console.log('Filtering...')
return products.filter(p => p.category === filter)
}, [products, filter])
return <ul>{filteredProducts.map(p => <li key={p.id}>{p.name}</li>)}</ul>
}
// useCallback: memoizes a function
function ParentComponent() {
const [count, setCount] = useState(0)
// Without useCallback, handleClick is recreated on every render
// Causing unnecessary re-renders of ExpensiveChild
const handleClick = useCallback((id) => {
console.log('Clicked:', id)
}, []) // Empty deps = stable function
return (
<>
<span>{count}</span>
<button onClick={() => setCount(c => c + 1)}>+</button>
{/* React.memo on ExpensiveChild for this to be effective */}
<ExpensiveChild onClick={handleClick} />
</>
)
}
// ❌ Over-optimization: not needed here
const SimpleComponent = () => {
// This calculation is trivial, useMemo adds overhead
const doubled = useMemo(() => 2 * 2, [])
return <span>{doubled}</span>
}Questi hook vanno utilizzati solo quando è stato individuato un problema di performance o per stabilizzare riferimenti passati a componenti memoizzati.
9. Come funziona useRef e quali sono i suoi casi d'uso?
useRef crea un riferimento mutabile che persiste tra i render senza innescare un re-render quando cambia.
jsx
// Case 1: Access a DOM element
function TextInput() {
const inputRef = useRef(null)
const focusInput = () => {
inputRef.current.focus()
}
return (
<>
<input ref={inputRef} type="text" />
<button onClick={focusInput}>Focus</button>
</>
)
}
// Case 2: Store a mutable value without re-render
function Timer() {
const [seconds, setSeconds] = useState(0)
const intervalRef = useRef(null)
const start = () => {
// Store the interval ID to be able to stop it
intervalRef.current = setInterval(() => {
setSeconds(s => s + 1)
}, 1000)
}
const stop = () => {
clearInterval(intervalRef.current)
}
return (
<div>
<span>{seconds}s</span>
<button onClick={start}>Start</button>
<button onClick={stop}>Stop</button>
</div>
)
}
// Case 3: Keep the previous value
function usePrevious(value) {
const ref = useRef()
useEffect(() => {
ref.current = value
}, [value])
return ref.current
}10. Spiegare useContext e quando utilizzarlo
useContext accede a un context React senza prop drilling. Ideale per dati globali come tema o utente autenticato.
1. Create the contextjsx
const ThemeContext = createContext({
theme: 'light',
toggleTheme: () => {}
})
// 2. Create the provider
function ThemeProvider({ children }) {
const [theme, setTheme] = useState('light')
const toggleTheme = useCallback(() => {
setTheme(prev => prev === 'light' ? 'dark' : 'light')
}, [])
// Memoize the value to avoid unnecessary re-renders
const value = useMemo(() => ({ theme, toggleTheme }), [theme, toggleTheme])
return (
<ThemeContext.Provider value={value}>
{children}
</ThemeContext.Provider>
)
}
// 3. Use the context
function ThemedButton() {
const { theme, toggleTheme } = useContext(ThemeContext)
return (
<button
onClick={toggleTheme}
className={theme === 'dark' ? 'bg-gray-800 text-white' : 'bg-white text-gray-800'}
>
{theme === 'dark' ? 'Light' : 'Dark'} mode
</button>
)
}
// 4. Wrap the application
function App() {
return (
<ThemeProvider>
<Header />
<Main />
<Footer />
</ThemeProvider>
)
}Pronto a superare i tuoi colloqui su React / Next.js?
Pratica con i nostri simulatori interattivi, flashcards e test tecnici.
Pattern avanzati
11. Che cos'è un Higher-Order Component (HOC)?
Un HOC è una funzione che riceve un componente e restituisce un nuovo componente arricchito. Meno diffuso dall'arrivo degli hook, ma ancora presente in alcune librerie.
jsx
// HOC that adds logging
function withLogging(WrappedComponent) {
return function WithLogging(props) {
useEffect(() => {
console.log(`${WrappedComponent.name} mounted with props:`, props)
return () => {
console.log(`${WrappedComponent.name} unmounted`)
}
}, [])
return <WrappedComponent {...props} />
}
}
// HOC that handles authentication
function withAuth(WrappedComponent) {
return function WithAuth(props) {
const { user, isLoading } = useAuth()
if (isLoading) return <LoadingSpinner />
if (!user) return <Navigate to="/login" />
return <WrappedComponent {...props} user={user} />
}
}
// Usage
const ProtectedDashboard = withAuth(Dashboard)
const LoggedButton = withLogging(Button)12. Spiegare il pattern Render Props
Il pattern Render Props condivide logica tra componenti tramite una prop che è una funzione.
jsx
// Component with render prop
function MouseTracker({ render }) {
const [position, setPosition] = useState({ x: 0, y: 0 })
useEffect(() => {
const handleMove = (e) => {
setPosition({ x: e.clientX, y: e.clientY })
}
window.addEventListener('mousemove', handleMove)
return () => window.removeEventListener('mousemove', handleMove)
}, [])
// Call the render function with data
return render(position)
}
// Usage
function App() {
return (
<MouseTracker
render={({ x, y }) => (
<div>
Position: {x}, {y}
</div>
)}
/>
)
}
// Modern version with custom hook (preferred)
function useMousePosition() {
const [position, setPosition] = useState({ x: 0, y: 0 })
useEffect(() => {
const handleMove = (e) => {
setPosition({ x: e.clientX, y: e.clientY })
}
window.addEventListener('mousemove', handleMove)
return () => window.removeEventListener('mousemove', handleMove)
}, [])
return position
}
function App() {
const { x, y } = useMousePosition()
return <div>Position: {x}, {y}</div>
}13. Come creare un custom hook?
I custom hook estraggono e riutilizzano logica con stato tra i componenti.
useLocalStorage.jsjsx
function useLocalStorage(key, initialValue) {
// Initialize with localStorage value or default
const [storedValue, setStoredValue] = useState(() => {
try {
const item = window.localStorage.getItem(key)
return item ? JSON.parse(item) : initialValue
} catch (error) {
console.error(error)
return initialValue
}
})
// Setter wrapper that syncs with localStorage
const setValue = useCallback((value) => {
try {
// Support update functions
const valueToStore = value instanceof Function ? value(storedValue) : value
setStoredValue(valueToStore)
window.localStorage.setItem(key, JSON.stringify(valueToStore))
} catch (error) {
console.error(error)
}
}, [key, storedValue])
return [storedValue, setValue]
}
// Usage
function Settings() {
const [theme, setTheme] = useLocalStorage('theme', 'light')
const [fontSize, setFontSize] = useLocalStorage('fontSize', 16)
return (
<div>
<select value={theme} onChange={e => setTheme(e.target.value)}>
<option value="light">Light</option>
<option value="dark">Dark</option>
</select>
<input
type="range"
min="12"
max="24"
value={fontSize}
onChange={e => setFontSize(Number(e.target.value))}
/>
</div>
)
}14. Che cos'è il pattern Compound Components?
Questo pattern crea componenti che collaborano in modo implicito, come i tag <select> e <option>.
jsx
// Shared context between components
const TabsContext = createContext()
function Tabs({ children, defaultValue }) {
const [activeTab, setActiveTab] = useState(defaultValue)
return (
<TabsContext.Provider value={{ activeTab, setActiveTab }}>
<div className="tabs">{children}</div>
</TabsContext.Provider>
)
}
function TabList({ children }) {
return <div className="tab-list" role="tablist">{children}</div>
}
function Tab({ value, children }) {
const { activeTab, setActiveTab } = useContext(TabsContext)
const isActive = activeTab === value
return (
<button
role="tab"
aria-selected={isActive}
className={`tab ${isActive ? 'active' : ''}`}
onClick={() => setActiveTab(value)}
>
{children}
</button>
)
}
function TabPanel({ value, children }) {
const { activeTab } = useContext(TabsContext)
if (activeTab !== value) return null
return (
<div role="tabpanel" className="tab-panel">
{children}
</div>
)
}
// Attach sub-components
Tabs.List = TabList
Tabs.Tab = Tab
Tabs.Panel = TabPanel
// Intuitive usage
function App() {
return (
<Tabs defaultValue="profile">
<Tabs.List>
<Tabs.Tab value="profile">Profile</Tabs.Tab>
<Tabs.Tab value="settings">Settings</Tabs.Tab>
<Tabs.Tab value="billing">Billing</Tabs.Tab>
</Tabs.List>
<Tabs.Panel value="profile">Profile content...</Tabs.Panel>
<Tabs.Panel value="settings">Settings content...</Tabs.Panel>
<Tabs.Panel value="billing">Billing content...</Tabs.Panel>
</Tabs>
)
}15. Come implementare il pattern Controlled vs Uncontrolled?
I componenti controllati hanno lo stato gestito da React, quelli non controllati usano direttamente il DOM.
jsx
// CONTROLLED component
// State is in React, component reflects that state
function ControlledInput() {
const [value, setValue] = useState('')
const handleSubmit = (e) => {
e.preventDefault()
console.log('Submitted value:', value)
}
return (
<form onSubmit={handleSubmit}>
<input
type="text"
value={value}
onChange={(e) => setValue(e.target.value)}
/>
<button type="submit">Submit</button>
</form>
)
}
// UNCONTROLLED component
// State is in the DOM, we read it when needed
function UncontrolledInput() {
const inputRef = useRef(null)
const handleSubmit = (e) => {
e.preventDefault()
console.log('Submitted value:', inputRef.current.value)
}
return (
<form onSubmit={handleSubmit}>
<input
type="text"
ref={inputRef}
defaultValue=""
/>
<button type="submit">Submit</button>
</form>
)
}
// Component that supports BOTH modes
function FlexibleInput({ value, defaultValue, onChange }) {
const isControlled = value !== undefined
const [internalValue, setInternalValue] = useState(defaultValue || '')
const currentValue = isControlled ? value : internalValue
const handleChange = (e) => {
if (!isControlled) {
setInternalValue(e.target.value)
}
onChange?.(e.target.value)
}
return (
<input
type="text"
value={currentValue}
onChange={handleChange}
/>
)
}Performance e ottimizzazione
16. Come funziona React.memo?
React.memo è un HOC che memoizza un componente per evitare re-render quando le props non sono cambiate.
jsx
// Memoized component
const ExpensiveList = React.memo(function ExpensiveList({ items, onItemClick }) {
console.log('ExpensiveList rendered')
return (
<ul>
{items.map(item => (
<li key={item.id} onClick={() => onItemClick(item.id)}>
{item.name}
</li>
))}
</ul>
)
})
// Parent using the memoized component
function Parent() {
const [count, setCount] = useState(0)
const [items] = useState([
{ id: 1, name: 'Item 1' },
{ id: 2, name: 'Item 2' }
])
// ❌ This function is recreated on every render
// So ExpensiveList re-renders despite memo
const handleClick = (id) => console.log(id)
// ✅ Stable function with useCallback
const handleClickStable = useCallback((id) => {
console.log(id)
}, [])
return (
<div>
<button onClick={() => setCount(c => c + 1)}>{count}</button>
<ExpensiveList items={items} onItemClick={handleClickStable} />
</div>
)
}
// Custom comparison
const MemoWithCustomCompare = React.memo(
function Component({ user, onClick }) {
return <div onClick={onClick}>{user.name}</div>
},
(prevProps, nextProps) => {
// Return true if props are equal (skip re-render)
return prevProps.user.id === nextProps.user.id
}
)17. Che cos'è il code splitting e React.lazy?
Il code splitting divide il bundle in chunk caricati on demand, riducendo il tempo di caricamento iniziale.
jsx
// Lazy loading components
const Dashboard = lazy(() => import('./Dashboard'))
const Settings = lazy(() => import('./Settings'))
const Profile = lazy(() => import('./Profile'))
function App() {
return (
<Suspense fallback={<LoadingSpinner />}>
<Routes>
<Route path="/dashboard" element={<Dashboard />} />
<Route path="/settings" element={<Settings />} />
<Route path="/profile" element={<Profile />} />
</Routes>
</Suspense>
)
}
// Conditional lazy loading
function FeaturePanel({ showAdvanced }) {
// Component is only loaded if needed
const AdvancedOptions = lazy(() => import('./AdvancedOptions'))
return (
<div>
<BasicOptions />
{showAdvanced && (
<Suspense fallback={<Skeleton />}>
<AdvancedOptions />
</Suspense>
)}
</div>
)
}
// Named exports with lazy
const { Chart } = lazy(() =>
import('./Charts').then(module => ({ default: module.Chart }))
)18. Come ottimizzare le liste lunghe?
Le liste lunghe possono causare problemi di performance. La virtualizzazione renderizza solo gli elementi visibili.
jsx
// With react-window (virtualization library)
import { FixedSizeList } from 'react-window'
function VirtualizedList({ items }) {
const Row = ({ index, style }) => (
<div style={style} className="list-item">
{items[index].name}
</div>
)
return (
<FixedSizeList
height={400}
width="100%"
itemCount={items.length}
itemSize={50}
>
{Row}
</FixedSizeList>
)
}
// Optimization without library: pagination
function PaginatedList({ items, pageSize = 20 }) {
const [page, setPage] = useState(0)
const paginatedItems = useMemo(() => {
const start = page * pageSize
return items.slice(start, start + pageSize)
}, [items, page, pageSize])
const totalPages = Math.ceil(items.length / pageSize)
return (
<div>
<ul>
{paginatedItems.map(item => (
<li key={item.id}>{item.name}</li>
))}
</ul>
<div className="pagination">
<button
onClick={() => setPage(p => p - 1)}
disabled={page === 0}
>
Previous
</button>
<span>{page + 1} / {totalPages}</span>
<button
onClick={() => setPage(p => p + 1)}
disabled={page >= totalPages - 1}
>
Next
</button>
</div>
</div>
)
}Soglia di virtualizzazione
La virtualizzazione diventa rilevante oltre alcune centinaia di elementi. Per liste più piccole la paginazione o il caricamento progressivo sono spesso sufficienti.
19. Come evitare re-render inutili?
Individuare ed eliminare i re-render inutili è fondamentale per le performance. Diverse tecniche aiutano a ottimizzare il rendering.
jsx
// Technique 1: Separate components
// ❌ Everything re-renders when count changes
function BadExample() {
const [count, setCount] = useState(0)
return (
<div>
<button onClick={() => setCount(c => c + 1)}>{count}</button>
<ExpensiveComponent /> {/* Unnecessary re-render */}
</div>
)
}
// ✅ ExpensiveComponent no longer re-renders
function GoodExample() {
return (
<div>
<Counter />
<ExpensiveComponent />
</div>
)
}
function Counter() {
const [count, setCount] = useState(0)
return <button onClick={() => setCount(c => c + 1)}>{count}</button>
}
// Technique 2: Pass children instead of rendering directly
// ✅ children is stable, no re-render of children
function ContextProvider({ children }) {
const [value, setValue] = useState(0)
return (
<Context.Provider value={value}>
{children} {/* children doesn't re-render when value changes */}
</Context.Provider>
)
}
// Technique 3: Use DevTools to identify re-renders
// React DevTools > Profiler > "Highlight updates when components render"20. Che cos'è l'automatic batching in React 18+?
React 18 raggruppa automaticamente gli aggiornamenti di stato per ridurre il numero di re-render.
jsx
// Before React 18: two re-renders
function handleClick() {
setCount(c => c + 1) // Re-render
setFlag(f => !f) // Re-render
}
// React 18+: single re-render (automatic batching)
function handleClick() {
setCount(c => c + 1) // Batched
setFlag(f => !f) // Batched
// Single re-render at the end
}
// Even in async callbacks (React 18 novelty)
async function handleSubmit() {
const response = await fetch('/api/submit')
// These two updates are batched
setData(response.data)
setLoading(false)
// Single re-render
}
// To force immediate re-render (rare)
import { flushSync } from 'react-dom'
function handleClick() {
flushSync(() => {
setCount(c => c + 1)
})
// DOM updated here
flushSync(() => {
setFlag(f => !f)
})
// DOM updated here
}Pronto a superare i tuoi colloqui su React / Next.js?
Pratica con i nostri simulatori interattivi, flashcards e test tecnici.
React moderno (18+)
21. Spiegare useTransition e useDeferredValue
Questi hook contrassegnano gli aggiornamenti come non urgenti per mantenere l'interfaccia reattiva.
jsx
// useTransition: mark an update as non-urgent
function SearchResults() {
const [query, setQuery] = useState('')
const [results, setResults] = useState([])
const [isPending, startTransition] = useTransition()
const handleChange = (e) => {
// Urgent update: input stays responsive
setQuery(e.target.value)
// Non-urgent update: can be interrupted
startTransition(() => {
const filtered = filterLargeDataset(e.target.value)
setResults(filtered)
})
}
return (
<div>
<input value={query} onChange={handleChange} />
{isPending && <span>Searching...</span>}
<ul>
{results.map(r => <li key={r.id}>{r.name}</li>)}
</ul>
</div>
)
}
// useDeferredValue: defer a value
function DeferredSearch() {
const [query, setQuery] = useState('')
// deferredQuery is "behind" during rapid updates
const deferredQuery = useDeferredValue(query)
// Show indicator during the "lag"
const isStale = query !== deferredQuery
return (
<div>
<input value={query} onChange={e => setQuery(e.target.value)} />
<div style={{ opacity: isStale ? 0.5 : 1 }}>
{/* Uses deferred value, fewer calculations */}
<ExpensiveList filter={deferredQuery} />
</div>
</div>
)
}22. Come funziona Suspense per il data fetching?
Suspense gestisce gli stati di caricamento in modo dichiarativo. Con React 18+ si estende anche al data fetching.
With a compatible library (React Query, Relay, etc.)jsx
function UserProfile({ userId }) {
return (
<Suspense fallback={<ProfileSkeleton />}>
<ProfileContent userId={userId} />
</Suspense>
)
}
// The component "suspends" during loading
function ProfileContent({ userId }) {
// This function suspends if data isn't ready
const user = useUserData(userId)
return (
<div>
<h1>{user.name}</h1>
<p>{user.bio}</p>
</div>
)
}
// Nested Suspense boundaries
function Dashboard() {
return (
<Suspense fallback={<DashboardSkeleton />}>
<Header />
<div className="grid">
<Suspense fallback={<StatsSkeleton />}>
<Stats />
</Suspense>
<Suspense fallback={<ChartSkeleton />}>
<Chart />
</Suspense>
<Suspense fallback={<TableSkeleton />}>
<RecentActivity />
</Suspense>
</div>
</Suspense>
)
}23. Che cos'è useActionState (React 19)?
useActionState (in precedenza useFormState) semplifica la gestione dei form con le Server Actions.
actions.jsjsx
'use server'
async function submitForm(prevState, formData) {
const email = formData.get('email')
const password = formData.get('password')
// Validation
if (!email || !password) {
return { error: 'All fields are required' }
}
try {
await createUser({ email, password })
return { success: true, message: 'Account created!' }
} catch (e) {
return { error: e.message }
}
}
// Component
function SignupForm() {
const [state, formAction, isPending] = useActionState(submitForm, {})
return (
<form action={formAction}>
{state.error && (
<div className="error">{state.error}</div>
)}
{state.success && (
<div className="success">{state.message}</div>
)}
<input name="email" type="email" placeholder="Email" />
<input name="password" type="password" placeholder="Password" />
<button type="submit" disabled={isPending}>
{isPending ? 'Creating...' : 'Create account'}
</button>
</form>
)
}24. Come funzionano i Server Components?
I Server Components vengono eseguiti esclusivamente sul server, riducendo il JavaScript inviato al client.
ServerComponent.jsxjsx
// No "use client" = Server Component by default
import { prisma } from '@/lib/prisma'
// async/await directly in the component
export default async function ProductList() {
// Direct database call (no API)
const products = await prisma.product.findMany({
orderBy: { createdAt: 'desc' },
take: 10
})
return (
<div>
<h2>Recent Products</h2>
<ul>
{products.map(product => (
<li key={product.id}>
{product.name} - ${product.price}
{/* Can include Client Components */}
<AddToCartButton productId={product.id} />
</li>
))}
</ul>
</div>
)
}
// AddToCartButton.jsx
'use client'
// This component needs interactivity
export function AddToCartButton({ productId }) {
const [isPending, startTransition] = useTransition()
const handleClick = () => {
startTransition(async () => {
await addToCart(productId)
})
}
return (
<button onClick={handleClick} disabled={isPending}>
{isPending ? '...' : 'Add'}
</button>
)
}25. Spiegare lo streaming SSR con React 18
Lo streaming SSR invia l'HTML al browser in modo progressivo invece di attendere il rendering completo.
app/page.jsx (Next.js App Router)jsx
import { Suspense } from 'react'
export default function Page() {
return (
<div>
{/* Immediate render */}
<Header />
{/* Streamed when ready */}
<Suspense fallback={<MainContentSkeleton />}>
<MainContent />
</Suspense>
{/* Streamed independently */}
<Suspense fallback={<SidebarSkeleton />}>
<Sidebar />
</Suspense>
{/* Immediate render */}
<Footer />
</div>
)
}
// The browser receives:
// 1. HTML shell with Header, skeletons, Footer
// 2. MainContent when its request completes
// 3. Sidebar when its request completes
// loading.jsx for route-level streaming
export default function Loading() {
return <PageSkeleton />
}Gestione dello stato
26. Quando usare Redux, Context API o altre soluzioni?
La scelta dipende dalla complessità dello stato e dalle esigenze del progetto.
jsx
// Context API: simple state, few updates
// ✅ Good for: theme, user, preferences
const ThemeContext = createContext()
function ThemeProvider({ children }) {
const [theme, setTheme] = useState('light')
return (
<ThemeContext.Provider value={{ theme, setTheme }}>
{children}
</ThemeContext.Provider>
)
}
// Redux / Zustand: complex state, frequent updates
// ✅ Good for: cart, filters, complex business data
import { create } from 'zustand'
const useCartStore = create((set, get) => ({
items: [],
total: 0,
addItem: (product) => set((state) => {
const existing = state.items.find(i => i.id === product.id)
if (existing) {
return {
items: state.items.map(i =>
i.id === product.id ? { ...i, quantity: i.quantity + 1 } : i
)
}
}
return { items: [...state.items, { ...product, quantity: 1 }] }
}),
removeItem: (id) => set((state) => ({
items: state.items.filter(i => i.id !== id)
})),
getTotal: () => get().items.reduce((sum, i) => sum + i.price * i.quantity, 0)
}))
// React Query / SWR: server state (cache, refetch)
// ✅ Good for: API data, server synchronization
import { useQuery, useMutation } from '@tanstack/react-query'
function Products() {
const { data, isLoading } = useQuery({
queryKey: ['products'],
queryFn: () => fetch('/api/products').then(r => r.json())
})
const mutation = useMutation({
mutationFn: (newProduct) => fetch('/api/products', {
method: 'POST',
body: JSON.stringify(newProduct)
})
})
}27. Come implementare il pattern Reducer?
Il pattern Reducer centralizza la logica degli aggiornamenti di stato complessi.
jsx
// Define actions
const ACTIONS = {
ADD_TODO: 'ADD_TODO',
TOGGLE_TODO: 'TOGGLE_TODO',
DELETE_TODO: 'DELETE_TODO',
SET_FILTER: 'SET_FILTER'
}
// Pure reducer (no side effects)
function todoReducer(state, action) {
switch (action.type) {
case ACTIONS.ADD_TODO:
return {
...state,
todos: [
...state.todos,
{ id: Date.now(), text: action.payload, completed: false }
]
}
case ACTIONS.TOGGLE_TODO:
return {
...state,
todos: state.todos.map(todo =>
todo.id === action.payload
? { ...todo, completed: !todo.completed }
: todo
)
}
case ACTIONS.DELETE_TODO:
return {
...state,
todos: state.todos.filter(todo => todo.id !== action.payload)
}
case ACTIONS.SET_FILTER:
return { ...state, filter: action.payload }
default:
return state
}
}
// Usage with useReducer
function TodoApp() {
const [state, dispatch] = useReducer(todoReducer, {
todos: [],
filter: 'all'
})
const addTodo = (text) => {
dispatch({ type: ACTIONS.ADD_TODO, payload: text })
}
const toggleTodo = (id) => {
dispatch({ type: ACTIONS.TOGGLE_TODO, payload: id })
}
const filteredTodos = useMemo(() => {
switch (state.filter) {
case 'completed':
return state.todos.filter(t => t.completed)
case 'active':
return state.todos.filter(t => !t.completed)
default:
return state.todos
}
}, [state.todos, state.filter])
return (
<div>
<TodoForm onAdd={addTodo} />
<TodoList todos={filteredTodos} onToggle={toggleTodo} />
<FilterButtons
current={state.filter}
onChange={(f) => dispatch({ type: ACTIONS.SET_FILTER, payload: f })}
/>
</div>
)
}Testing
28. Come testare un componente React?
I test dei componenti verificano il rendering e il comportamento dell'interfaccia.
Button.test.jsxjsx
import { render, screen, fireEvent } from '@testing-library/react'
import userEvent from '@testing-library/user-event'
import Button from './Button'
describe('Button', () => {
// Basic rendering test
it('renders with correct text', () => {
render(<Button>Click me</Button>)
expect(screen.getByRole('button')).toHaveTextContent('Click me')
})
// Interaction test
it('calls onClick when clicked', async () => {
const handleClick = jest.fn()
render(<Button onClick={handleClick}>Click</Button>)
await userEvent.click(screen.getByRole('button'))
expect(handleClick).toHaveBeenCalledTimes(1)
})
// Disabled state test
it('does not call onClick when disabled', async () => {
const handleClick = jest.fn()
render(<Button disabled onClick={handleClick}>Click</Button>)
await userEvent.click(screen.getByRole('button'))
expect(handleClick).not.toHaveBeenCalled()
})
// Async state test
it('shows loading state', async () => {
render(<Button isLoading>Submit</Button>)
expect(screen.getByRole('button')).toBeDisabled()
expect(screen.getByTestId('spinner')).toBeInTheDocument()
})
})
// Testing a custom hook
import { renderHook, act } from '@testing-library/react'
import useCounter from './useCounter'
describe('useCounter', () => {
it('increments counter', () => {
const { result } = renderHook(() => useCounter(0))
act(() => {
result.current.increment()
})
expect(result.current.count).toBe(1)
})
})29. Come mockare le chiamate API nei test?
I mock isolano i test dalle dipendenze esterne.
jsx
// With MSW (Mock Service Worker) - recommended
import { setupServer } from 'msw/node'
import { http, HttpResponse } from 'msw'
const server = setupServer(
http.get('/api/users', () => {
return HttpResponse.json([
{ id: 1, name: 'Alice' },
{ id: 2, name: 'Bob' }
])
}),
http.post('/api/users', async ({ request }) => {
const body = await request.json()
return HttpResponse.json({ id: 3, ...body }, { status: 201 })
})
)
beforeAll(() => server.listen())
afterEach(() => server.resetHandlers())
afterAll(() => server.close())
test('loads and displays users', async () => {
render(<UserList />)
expect(screen.getByText('Loading...')).toBeInTheDocument()
await waitFor(() => {
expect(screen.getByText('Alice')).toBeInTheDocument()
expect(screen.getByText('Bob')).toBeInTheDocument()
})
})
// Override for a specific test
test('handles error state', async () => {
server.use(
http.get('/api/users', () => {
return HttpResponse.json({ error: 'Server error' }, { status: 500 })
})
)
render(<UserList />)
await waitFor(() => {
expect(screen.getByText('Loading error')).toBeInTheDocument()
})
})30. Come strutturare i test per una copertura ottimale?
Una strategia di test equilibrata combina diversi livelli di test.
jsx
// Recommended testing pyramid:
// - Many unit tests (fast, isolated)
// - Some integration tests (components + hooks)
// - Few E2E tests (critical scenarios)
// Unit tests: pure logic
// utils/formatPrice.test.js
describe('formatPrice', () => {
it('formats with 2 decimals', () => {
expect(formatPrice(10)).toBe('$10.00')
})
it('handles zero', () => {
expect(formatPrice(0)).toBe('$0.00')
})
})
// Integration tests: complete component
// features/Checkout/Checkout.test.jsx
describe('Checkout', () => {
it('completes purchase flow', async () => {
render(
<CartProvider>
<Checkout />
</CartProvider>
)
// Fill the form
await userEvent.type(screen.getByLabelText('Email'), 'test@example.com')
await userEvent.type(screen.getByLabelText('Card'), '4242424242424242')
// Submit
await userEvent.click(screen.getByRole('button', { name: 'Pay' }))
// Verify result
await waitFor(() => {
expect(screen.getByText('Order confirmed')).toBeInTheDocument()
})
})
})
// E2E tests with Playwright
// e2e/checkout.spec.ts
test('user can complete checkout', async ({ page }) => {
await page.goto('/products')
await page.click('[data-testid="add-to-cart-1"]')
await page.click('[data-testid="checkout-button"]')
await page.fill('[name="email"]', 'test@example.com')
await page.fill('[name="card"]', '4242424242424242')
await page.click('button[type="submit"]')
await expect(page.locator('text=Order confirmed')).toBeVisible()
})Conclusione
Queste 30 domande coprono le conoscenze essenziali di React richieste in fase di colloquio. Aree chiave da padroneggiare:
- ✅ Fondamenti: Virtual DOM, JSX, props vs state, componenti
- ✅ Hooks: useState, useEffect, useMemo, useCallback, useRef, useContext
- ✅ Pattern: HOC, Render Props, Compound Components, custom hook
- ✅ Performance: React.memo, lazy loading, virtualizzazione
- ✅ React moderno: Suspense, Transitions, Server Components
- ✅ Gestione dello stato: Context, Redux/Zustand, React Query
- ✅ Testing: React Testing Library, mock, strategia di testing
La preparazione a un colloquio React non si riduce alla memorizzazione. Esercitarsi con progetti reali aiuta a consolidare questi concetti e a spiegarli con naturalezza durante il colloquio.
Inizia a praticare!
Metti alla prova le tue conoscenze con i nostri simulatori di colloquio e test tecnici.
Tag
#react interview
#frontend interview
#react questions
#javascript
#technical interview
Condividi
Articoli correlati
React 19: Server Components in produzione - La guida completa
Implementare i Server Components di React 19 in produzione. Architettura, pattern, streaming, caching e ottimizzazioni per applicazioni ad alte prestazioni.
Domande colloquio Node.js Backend: Guida completa 2026
Le 25 domande più frequenti nei colloqui Node.js backend. Event loop, async/await, stream, clustering e performance spiegate con risposte dettagliate.
Domande per colloqui Laravel e PHP: le Top 25 nel 2026
Le 25 domande piu frequenti nei colloqui Laravel e PHP. Eloquent ORM, middleware, Artisan, code, test e architettura con risposte dettagliate ed esempi di codice.