| name | error-handling |
| description | Master error handling patterns across languages including exceptions, Result types, error propagation, and graceful degradation to build resilient applications. Use when implementing error handling, designing APIs, or improving application reliability. |
Error Handling Patterns
Build resilient applications with robust error handling strategies that gracefully handle failures and provide excellent debugging experiences.
When to Use This Skill
- Implementing error handling in new features
- Designing error-resilient APIs
- Debugging production issues
- Improving application reliability
- Creating better error messages for users and developers
- Implementing retry and circuit breaker patterns
- Handling async/concurrent errors
- Building fault-tolerant distributed systems
Core Concepts
1. Error Handling Philosophies
Exceptions vs Result Types:
- Exceptions: Traditional try-catch, disrupts control flow
- Result Types: Explicit success/failure, functional approach
- Error Codes: C-style, requires discipline
- Option/Maybe Types: For nullable values
When to Use Each:
- Exceptions: Unexpected errors, exceptional conditions
- Result Types: Expected errors, validation failures
- Panics/Crashes: Unrecoverable errors, programming bugs
2. Error Categories
Recoverable Errors:
- Network timeouts
- Missing files
- Invalid user input
- API rate limits
Unrecoverable Errors:
- Out of memory
- Stack overflow
- Programming bugs (null pointer, etc.)
Core Philosophy (Senior Dev Pattern)
- Errors are Values: Return errors explicitly instead of throwing them (except for crashes).
- Type Safety: Use discriminated unions to make invalid states unrepresentable.
- Exhaustiveness: Force the compiler to ensure all error cases are handled.
- Separation: Business logic returns results; UI/Controllers decide user feedback.
Language-Specific Patterns
Python Error Handling
Custom Exception Hierarchy:
class ApplicationError(Exception):
"""Base exception for all application errors."""
def __init__(self, message: str, code: str = None, details: dict = None):
super().__init__(message)
self.code = code
self.details = details or {}
self.timestamp = datetime.utcnow()
class ValidationError(ApplicationError):
"""Raised when validation fails."""
pass
class NotFoundError(ApplicationError):
"""Raised when resource not found."""
pass
class ExternalServiceError(ApplicationError):
"""Raised when external service fails."""
def __init__(self, message: str, service: str, **kwargs):
super().__init__(message, **kwargs)
self.service = service
def get_user(user_id: str) -> User:
user = db.query(User).filter_by(id=user_id).first()
if not user:
raise NotFoundError(
f"User not found",
code="USER_NOT_FOUND",
details={"user_id": user_id}
)
return user
Context Managers for Cleanup:
from contextlib import contextmanager
@contextmanager
def database_transaction(session):
"""Ensure transaction is committed or rolled back."""
try:
yield session
session.commit()
except Exception as e:
session.rollback()
raise
finally:
session.close()
with database_transaction(db.session) as session:
user = User(name="Alice")
session.add(user)
Retry with Exponential Backoff:
import time
from functools import wraps
from typing import TypeVar, Callable
T = TypeVar('T')
def retry(
max_attempts: int = 3,
backoff_factor: float = 2.0,
exceptions: tuple = (Exception,)
):
"""Retry decorator with exponential backoff."""
def decorator(func: Callable[..., T]) -> Callable[..., T]:
@wraps(func)
def wrapper(*args, **kwargs) -> T:
last_exception = None
for attempt in range(max_attempts):
try:
return func(*args, **kwargs)
except exceptions as e:
last_exception = e
if attempt < max_attempts - 1:
sleep_time = backoff_factor ** attempt
time.sleep(sleep_time)
continue
raise
raise last_exception
return wrapper
return decorator
@retry(max_attempts=3, exceptions=(NetworkError,))
def fetch_data(url: str) -> dict:
response = requests.get(url, timeout=5)
response.raise_for_status()
return response.json()
TypeScript/JavaScript Error Handling (Modern)
Detailed Guide: See typescript-patterns.md for the "Senior Dev" pattern using Result types and Discriminated Unions.
Key principles covered in module:
- Errors as Values (Result Pattern)
- Type-Safe Discriminated Unions (
reason codes)
- Exhaustive Switch Handling
- Clean Logic/UI Separation
Rust Error Handling
Result and Option Types:
Universal Patterns
Pattern 1: Circuit Breaker
Prevent cascading failures in distributed systems.
from enum import Enum
from datetime import datetime, timedelta
from typing import Callable, TypeVar
T = TypeVar('T')
class CircuitState(Enum):
CLOSED = "closed"
OPEN = "open"
HALF_OPEN = "half_open"
class CircuitBreaker:
def __init__(
self,
failure_threshold: int = 5,
timeout: timedelta = timedelta(seconds=60),
success_threshold: int = 2
):
self.failure_threshold = failure_threshold
self.timeout = timeout
self.success_threshold = success_threshold
self.failure_count = 0
self.success_count = 0
self.state = CircuitState.CLOSED
self.last_failure_time = None
def call(self, func: Callable[[], T]) -> T:
if self.state == CircuitState.OPEN:
if datetime.now() - self.last_failure_time > self.timeout:
self.state = CircuitState.HALF_OPEN
self.success_count = 0
else:
raise Exception("Circuit breaker is OPEN")
try:
result = func()
self.on_success()
return result
except Exception as e:
self.on_failure()
raise
def on_success(self):
self.failure_count = 0
if self.state == CircuitState.HALF_OPEN:
self.success_count += 1
if self.success_count >= self.success_threshold:
self.state = CircuitState.CLOSED
self.success_count = 0
def on_failure(self):
self.failure_count += 1
self.last_failure_time = datetime.now()
if self.failure_count >= self.failure_threshold:
self.state = CircuitState.OPEN
circuit_breaker = CircuitBreaker()
def fetch_data():
return circuit_breaker.call(lambda: external_api.get_data())
Pattern 2: Error Aggregation
Collect multiple errors instead of failing on first error.
class ErrorCollector {
private errors: Error[] = [];
add(error: Error): void {
this.errors.push(error);
}
hasErrors(): boolean {
return this.errors.length > 0;
}
getErrors(): Error[] {
return [...this.errors];
}
throw(): never {
if (this.errors.length === 1) {
throw this.errors[0];
}
throw new AggregateError(
this.errors,
`${this.errors.length} errors occurred`,
);
}
}
function validateUser(data: any): User {
const errors = new ErrorCollector();
if (!data.email) {
errors.add(new ValidationError("Email is required"));
} else if (!isValidEmail(data.email)) {
errors.add(new ValidationError("Email is invalid"));
}
if (!data.name || data.name.length < 2) {
errors.add(new ValidationError("Name must be at least 2 characters"));
}
if (!data.age || data.age < 18) {
errors.add(new ValidationError("Age must be 18 or older"));
}
if (errors.hasErrors()) {
errors.throw();
}
return data as User;
}
Pattern 3: Graceful Degradation
Provide fallback functionality when errors occur.
from typing import Optional, Callable, TypeVar
T = TypeVar('T')
def with_fallback(
primary: Callable[[], T],
fallback: Callable[[], T],
log_error: bool = True
) -> T:
"""Try primary function, fall back to fallback on error."""
try:
return primary()
except Exception as e:
if log_error:
logger.error(f"Primary function failed: {e}")
return fallback()
def get_user_profile(user_id: str) -> UserProfile:
return with_fallback(
primary=lambda: fetch_from_cache(user_id),
fallback=lambda: fetch_from_database(user_id)
)
def get_exchange_rate(currency: str) -> float:
return (
try_function(lambda: api_provider_1.get_rate(currency))
or try_function(lambda: api_provider_2.get_rate(currency))
or try_function(lambda: cache.get_rate(currency))
or DEFAULT_RATE
)
def try_function(func: Callable[[], Optional[T]]) -> Optional[T]:
try:
return func()
except Exception:
return None
Best Practices
- Fail Fast: Validate input early, fail quickly
- Preserve Context: Include stack traces, metadata, timestamps
- Meaningful Messages: Explain what happened and how to fix it
- Log Appropriately: Error = log, expected failure = don't spam logs
- Handle at Right Level: Catch where you can meaningfully handle
- Clean Up Resources: Use try-finally, context managers, defer
- Don't Swallow Errors: Log or re-throw, don't silently ignore
- Type-Safe Errors: Use typed errors when possible
def process_order(order_id: str) -> Order:
"""Process order with comprehensive error handling."""
try:
if not order_id:
raise ValidationError("Order ID is required")
order = db.get_order(order_id)
if not order:
raise NotFoundError("Order", order_id)
try:
payment_result = payment_service.charge(order.total)
except PaymentServiceError as e:
logger.error(f"Payment failed for order {order_id}: {e}")
raise ExternalServiceError(
f"Payment processing failed",
service="payment_service",
details={"order_id": order_id, "amount": order.total}
) from e
order.status = "completed"
order.payment_id = payment_result.id
db.save(order)
return order
except ApplicationError:
raise
except Exception as e:
logger.exception(f"Unexpected error processing order {order_id}")
raise ApplicationError(
"Order processing failed",
code="INTERNAL_ERROR"
) from e
Common Pitfalls
- Catching Too Broadly:
except Exception hides bugs
- Empty Catch Blocks: Silently swallowing errors
- Logging and Re-throwing: Creates duplicate log entries
- Not Cleaning Up: Forgetting to close files, connections
- Poor Error Messages: "Error occurred" is not helpful
- Returning Error Codes: Use exceptions or Result types
- Ignoring Async Errors: Unhandled promise rejections