Agents python-type-safety
Python type safety with type hints, generics, protocols, and strict type checking. Use when adding type annotations, implementing generic classes, defining structural interfaces, or configuring mypy/pyright.
install
source · Clone the upstream repo
git clone https://github.com/wshobson/agents
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/wshobson/agents "$T" && mkdir -p ~/.claude/skills && cp -r "$T/plugins/python-development/skills/python-type-safety" ~/.claude/skills/wshobson-agents-python-type-safety && rm -rf "$T"
manifest:
plugins/python-development/skills/python-type-safety/SKILL.mdsource content
Python Type Safety
Leverage Python's type system to catch errors at static analysis time. Type annotations serve as enforced documentation that tooling validates automatically.
When to Use This Skill
- Adding type hints to existing code
- Creating generic, reusable classes
- Defining structural interfaces with protocols
- Configuring mypy or pyright for strict checking
- Understanding type narrowing and guards
- Building type-safe APIs and libraries
Core Concepts
1. Type Annotations
Declare expected types for function parameters, return values, and variables.
2. Generics
Write reusable code that preserves type information across different types.
3. Protocols
Define structural interfaces without inheritance (duck typing with type safety).
4. Type Narrowing
Use guards and conditionals to narrow types within code blocks.
Quick Start
def get_user(user_id: str) -> User | None: """Return type makes 'might not exist' explicit.""" ... # Type checker enforces handling None case user = get_user("123") if user is None: raise UserNotFoundError("123") print(user.name) # Type checker knows user is User here
Fundamental Patterns
Pattern 1: Annotate All Public Signatures
Every public function, method, and class should have type annotations.
def get_user(user_id: str) -> User: """Retrieve user by ID.""" ... def process_batch( items: list[Item], max_workers: int = 4, ) -> BatchResult[ProcessedItem]: """Process items concurrently.""" ... class UserRepository: def __init__(self, db: Database) -> None: self._db = db async def find_by_id(self, user_id: str) -> User | None: """Return User if found, None otherwise.""" ... async def find_by_email(self, email: str) -> User | None: ... async def save(self, user: User) -> User: """Save and return user with generated ID.""" ...
Use
mypy --strictpyrightPattern 2: Use Modern Union Syntax
Python 3.10+ provides cleaner union syntax.
# Preferred (3.10+) def find_user(user_id: str) -> User | None: ... def parse_value(v: str) -> int | float | str: ... # Older style (still valid, needed for 3.9) from typing import Optional, Union def find_user(user_id: str) -> Optional[User]: ...
Pattern 3: Type Narrowing with Guards
Use conditionals to narrow types for the type checker.
def process_user(user_id: str) -> UserData: user = find_user(user_id) if user is None: raise UserNotFoundError(f"User {user_id} not found") # Type checker knows user is User here, not User | None return UserData( name=user.name, email=user.email, ) def process_items(items: list[Item | None]) -> list[ProcessedItem]: # Filter and narrow types valid_items = [item for item in items if item is not None] # valid_items is now list[Item] return [process(item) for item in valid_items]
Pattern 4: Generic Classes
Create type-safe reusable containers.
from typing import TypeVar, Generic T = TypeVar("T") E = TypeVar("E", bound=Exception) class Result(Generic[T, E]): """Represents either a success value or an error.""" def __init__( self, value: T | None = None, error: E | None = None, ) -> None: if (value is None) == (error is None): raise ValueError("Exactly one of value or error must be set") self._value = value self._error = error @property def is_success(self) -> bool: return self._error is None @property def is_failure(self) -> bool: return self._error is not None def unwrap(self) -> T: """Get value or raise the error.""" if self._error is not None: raise self._error return self._value # type: ignore[return-value] def unwrap_or(self, default: T) -> T: """Get value or return default.""" if self._error is not None: return default return self._value # type: ignore[return-value] # Usage preserves types def parse_config(path: str) -> Result[Config, ConfigError]: try: return Result(value=Config.from_file(path)) except ConfigError as e: return Result(error=e) result = parse_config("config.yaml") if result.is_success: config = result.unwrap() # Type: Config
Advanced Patterns
Pattern 5: Generic Repository
Create type-safe data access patterns.
from typing import TypeVar, Generic from abc import ABC, abstractmethod T = TypeVar("T") ID = TypeVar("ID") class Repository(ABC, Generic[T, ID]): """Generic repository interface.""" @abstractmethod async def get(self, id: ID) -> T | None: """Get entity by ID.""" ... @abstractmethod async def save(self, entity: T) -> T: """Save and return entity.""" ... @abstractmethod async def delete(self, id: ID) -> bool: """Delete entity, return True if existed.""" ... class UserRepository(Repository[User, str]): """Concrete repository for Users with string IDs.""" async def get(self, id: str) -> User | None: row = await self._db.fetchrow( "SELECT * FROM users WHERE id = $1", id ) return User(**row) if row else None async def save(self, entity: User) -> User: ... async def delete(self, id: str) -> bool: ...
Pattern 6: TypeVar with Bounds
Restrict generic parameters to specific types.
from typing import TypeVar from pydantic import BaseModel ModelT = TypeVar("ModelT", bound=BaseModel) def validate_and_create(model_cls: type[ModelT], data: dict) -> ModelT: """Create a validated Pydantic model from dict.""" return model_cls.model_validate(data) # Works with any BaseModel subclass class User(BaseModel): name: str email: str user = validate_and_create(User, {"name": "Alice", "email": "a@b.com"}) # user is typed as User # Type error: str is not a BaseModel subclass result = validate_and_create(str, {"name": "Alice"}) # Error!
Pattern 7: Protocols for Structural Typing
Define interfaces without requiring inheritance.
from typing import Protocol, runtime_checkable @runtime_checkable class Serializable(Protocol): """Any class that can be serialized to/from dict.""" def to_dict(self) -> dict: ... @classmethod def from_dict(cls, data: dict) -> "Serializable": ... # User satisfies Serializable without inheriting from it class User: def __init__(self, id: str, name: str) -> None: self.id = id self.name = name def to_dict(self) -> dict: return {"id": self.id, "name": self.name} @classmethod def from_dict(cls, data: dict) -> "User": return cls(id=data["id"], name=data["name"]) def serialize(obj: Serializable) -> str: """Works with any Serializable object.""" return json.dumps(obj.to_dict()) # Works - User matches the protocol serialize(User("1", "Alice")) # Runtime checking with @runtime_checkable isinstance(User("1", "Alice"), Serializable) # True
Pattern 8: Common Protocol Patterns
Define reusable structural interfaces.
from typing import Protocol class Closeable(Protocol): """Resource that can be closed.""" def close(self) -> None: ... class AsyncCloseable(Protocol): """Async resource that can be closed.""" async def close(self) -> None: ... class Readable(Protocol): """Object that can be read from.""" def read(self, n: int = -1) -> bytes: ... class HasId(Protocol): """Object with an ID property.""" @property def id(self) -> str: ... class Comparable(Protocol): """Object that supports comparison.""" def __lt__(self, other: "Comparable") -> bool: ... def __le__(self, other: "Comparable") -> bool: ...
Pattern 9: Type Aliases
Create meaningful type names.
Note: The
type Alias = ...TypeAlias# Python 3.12+ type statement (PEP 695) type UserId = str type UserDict = dict[str, Any] # Python 3.12+ type statement with generics (PEP 695) type Handler[T] = Callable[[Request], T] type AsyncHandler[T] = Callable[[Request], Awaitable[T]]
# Python 3.10-3.11 style (needed for broader compatibility) from typing import TypeAlias from collections.abc import Callable, Awaitable UserId: TypeAlias = str Handler: TypeAlias = Callable[[Request], Response]
# Usage def register_handler(path: str, handler: Handler[Response]) -> None: ...
Pattern 10: Callable Types
Type function parameters and callbacks.
from collections.abc import Callable, Awaitable # Sync callback ProgressCallback = Callable[[int, int], None] # (current, total) # Async callback AsyncHandler = Callable[[Request], Awaitable[Response]] # With named parameters (using Protocol) class OnProgress(Protocol): def __call__( self, current: int, total: int, *, message: str = "", ) -> None: ... def process_items( items: list[Item], on_progress: ProgressCallback | None = None, ) -> list[Result]: for i, item in enumerate(items): if on_progress: on_progress(i, len(items)) ...
Configuration
Strict Mode Checklist
For
mypy --strict# pyproject.toml [tool.mypy] python_version = "3.12" strict = true warn_return_any = true warn_unused_ignores = true disallow_untyped_defs = true disallow_incomplete_defs = true no_implicit_optional = true
Incremental adoption goals:
- All function parameters annotated
- All return types annotated
- Class attributes annotated
- Minimize
usage (acceptable for truly dynamic data)Any - Generic collections use type parameters (
notlist[str]
)list
For existing codebases, enable strict mode per-module using
# mypy: strictpyproject.tomlBest Practices Summary
- Annotate all public APIs - Functions, methods, class attributes
- Use
- Modern union syntax overT | NoneOptional[T] - Run strict type checking -
in CImypy --strict - Use generics - Preserve type info in reusable code
- Define protocols - Structural typing for interfaces
- Narrow types - Use guards to help the type checker
- Bound type vars - Restrict generics to meaningful types
- Create type aliases - Meaningful names for complex types
- Minimize
- Use specific types or generics.Any
is acceptable for truly dynamic data or when interfacing with untyped third-party codeAny - Document with types - Types are enforceable documentation