import contextlib import json import logging import os import re import shlex import signal import subprocess import sys from importlib import import_module from multiprocessing import get_context from multiprocessing.context import SpawnProcess from pathlib import Path from typing import TYPE_CHECKING, Any, Callable, Dict, Generator, Optional, Set, Tuple, Union import anyio from .filters import DefaultFilter from .main import Change, FileChange, awatch, watch if TYPE_CHECKING: try: from typing import Literal except ImportError: from typing_extensions import Literal # type: ignore[misc] __all__ = 'run_process', 'arun_process', 'detect_target_type', 'import_string' logger = logging.getLogger('watchfiles.main') def run_process( *paths: Union[Path, str], target: Union[str, Callable[..., Any]], args: Tuple[Any, ...] = (), kwargs: Optional[Dict[str, Any]] = None, target_type: "Literal['function', 'command', 'auto']" = 'auto', callback: Optional[Callable[[Set[FileChange]], None]] = None, watch_filter: Optional[Callable[[Change, str], bool]] = DefaultFilter(), debounce: int = 1_600, step: int = 50, debug: bool = False, sigint_timeout: int = 5, sigkill_timeout: int = 1, ) -> int: """ Run a process and restart it upon file changes. `run_process` can work in two ways: * Using `multiprocessing.Process` † to run a python function * Or, using `subprocess.Popen` to run a command !!! note **†** technically `multiprocessing.get_context('spawn').Process` to avoid forking and improve code reload/import. Internally, `run_process` uses [`watch`][watchfiles.watch] with `raise_interrupt=False` so the function exits cleanly upon `Ctrl+C`. Args: *paths: matches the same argument of [`watch`][watchfiles.watch] target: function or command to run args: arguments to pass to `target`, only used if `target` is a function kwargs: keyword arguments to pass to `target`, only used if `target` is a function target_type: type of target. Can be `'function'`, `'command'`, or `'auto'` in which case [`detect_target_type`][watchfiles.run.detect_target_type] is used to determine the type. callback: function to call on each reload, the function should accept a set of changes as the sole argument watch_filter: matches the same argument of [`watch`][watchfiles.watch] debounce: matches the same argument of [`watch`][watchfiles.watch] step: matches the same argument of [`watch`][watchfiles.watch] debug: matches the same argument of [`watch`][watchfiles.watch] sigint_timeout: the number of seconds to wait after sending sigint before sending sigkill sigkill_timeout: the number of seconds to wait after sending sigkill before raising an exception Returns: number of times the function was reloaded. ```py title="Example of run_process running a function" from watchfiles import run_process def callback(changes): print('changes detected:', changes) def foobar(a, b): print('foobar called with:', a, b) if __name__ == '__main__': run_process('./path/to/dir', target=foobar, args=(1, 2), callback=callback) ``` As well as using a `callback` function, changes can be accessed from within the target function, using the `WATCHFILES_CHANGES` environment variable. ```py title="Example of run_process accessing changes" from watchfiles import run_process def foobar(a, b, c): # changes will be an empty list "[]" the first time the function is called changes = os.getenv('WATCHFILES_CHANGES') changes = json.loads(changes) print('foobar called due to changes:', changes) if __name__ == '__main__': run_process('./path/to/dir', target=foobar, args=(1, 2, 3)) ``` Again with the target as `command`, `WATCHFILES_CHANGES` can be used to access changes. ```bash title="example.sh" echo "changers: ${WATCHFILES_CHANGES}" ``` ```py title="Example of run_process running a command" from watchfiles import run_process if __name__ == '__main__': run_process('.', target='./example.sh') ``` """ if target_type == 'auto': target_type = detect_target_type(target) logger.debug('running "%s" as %s', target, target_type) process = start_process(target, target_type, args, kwargs) reloads = 0 try: for changes in watch( *paths, watch_filter=watch_filter, debounce=debounce, step=step, debug=debug, raise_interrupt=False ): callback and callback(changes) process.stop(sigint_timeout=sigint_timeout, sigkill_timeout=sigkill_timeout) process = start_process(target, target_type, args, kwargs, changes) reloads += 1 finally: process.stop() return reloads async def arun_process( *paths: Union[Path, str], target: Union[str, Callable[..., Any]], args: Tuple[Any, ...] = (), kwargs: Optional[Dict[str, Any]] = None, target_type: "Literal['function', 'command', 'auto']" = 'auto', callback: Optional[Callable[[Set[FileChange]], Any]] = None, watch_filter: Optional[Callable[[Change, str], bool]] = DefaultFilter(), debounce: int = 1_600, step: int = 50, debug: bool = False, ) -> int: """ Async equivalent of [`run_process`][watchfiles.run_process], all arguments match those of `run_process` except `callback` which can be a coroutine. Starting and stopping the process and watching for changes is done in a separate thread. As with `run_process`, internally `arun_process` uses [`awatch`][watchfiles.awatch], however `KeyboardInterrupt` cannot be caught and suppressed in `awatch` so these errors need to be caught separately, see below. ```py title="Example of arun_process usage" import asyncio from watchfiles import arun_process async def callback(changes): await asyncio.sleep(0.1) print('changes detected:', changes) def foobar(a, b): print('foobar called with:', a, b) async def main(): await arun_process('.', target=foobar, args=(1, 2), callback=callback) if __name__ == '__main__': try: asyncio.run(main()) except KeyboardInterrupt: print('stopped via KeyboardInterrupt') ``` """ import inspect if target_type == 'auto': target_type = detect_target_type(target) logger.debug('running "%s" as %s', target, target_type) process = await anyio.to_thread.run_sync(start_process, target, target_type, args, kwargs) reloads = 0 async for changes in awatch(*paths, watch_filter=watch_filter, debounce=debounce, step=step, debug=debug): if callback is not None: r = callback(changes) if inspect.isawaitable(r): await r await anyio.to_thread.run_sync(process.stop) process = await anyio.to_thread.run_sync(start_process, target, target_type, args, kwargs, changes) reloads += 1 await anyio.to_thread.run_sync(process.stop) return reloads # Use spawn context to make sure code run in subprocess # does not reuse imported modules in main process/context spawn_context = get_context('spawn') def start_process( target: Union[str, Callable[..., Any]], target_type: "Literal['function', 'command']", args: Tuple[Any, ...], kwargs: Optional[Dict[str, Any]], changes: Optional[Set[FileChange]] = None, ) -> 'CombinedProcess': if changes is None: changes_env_var = '[]' else: changes_env_var = json.dumps([[c.raw_str(), p] for c, p in changes]) os.environ['WATCHFILES_CHANGES'] = changes_env_var process: 'Union[SpawnProcess, subprocess.Popen[bytes]]' if target_type == 'function': kwargs = kwargs or {} if isinstance(target, str): args = target, get_tty_path(), args, kwargs target_ = run_function kwargs = {} else: target_ = target process = spawn_context.Process(target=target_, args=args, kwargs=kwargs) process.start() else: if args or kwargs: logger.warning('ignoring args and kwargs for "command" target') assert isinstance(target, str), 'target must be a string to run as a command' popen_args = shlex.split(target) process = subprocess.Popen(popen_args) return CombinedProcess(process) def detect_target_type(target: Union[str, Callable[..., Any]]) -> "Literal['function', 'command']": """ Used by [`run_process`][watchfiles.run_process], [`arun_process`][watchfiles.arun_process] and indirectly the CLI to determine the target type with `target_type` is `auto`. Detects the target type - either `function` or `command`. This method is only called with `target_type='auto'`. The following logic is employed: * If `target` is not a string, it is assumed to be a function * If `target` ends with `.py` or `.sh`, it is assumed to be a command * Otherwise, the target is assumed to be a function if it matches the regex `[a-zA-Z0-9_]+(\\.[a-zA-Z0-9_]+)+` If this logic does not work for you, specify the target type explicitly using the `target_type` function argument or `--target-type` command line argument. Args: target: The target value Returns: either `'function'` or `'command'` """ if not isinstance(target, str): return 'function' elif target.endswith(('.py', '.sh')): return 'command' elif re.fullmatch(r'[a-zA-Z0-9_]+(\.[a-zA-Z0-9_]+)+', target): return 'function' else: return 'command' class CombinedProcess: def __init__(self, p: 'Union[SpawnProcess, subprocess.Popen[bytes]]'): self._p = p assert self.pid is not None, 'process not yet spawned' def stop(self, sigint_timeout: int = 5, sigkill_timeout: int = 1) -> None: os.environ.pop('WATCHFILES_CHANGES', None) if self.is_alive(): logger.debug('stopping process...') os.kill(self.pid, signal.SIGINT) try: self.join(sigint_timeout) except subprocess.TimeoutExpired: # Capture this exception to allow the self.exitcode to be reached. # This will allow the SIGKILL to be sent, otherwise it is swallowed up. logger.warning('SIGINT timed out after %r seconds', sigint_timeout) pass if self.exitcode is None: logger.warning('process has not terminated, sending SIGKILL') os.kill(self.pid, signal.SIGKILL) self.join(sigkill_timeout) else: logger.debug('process stopped') else: logger.warning('process already dead, exit code: %d', self.exitcode) def is_alive(self) -> bool: if isinstance(self._p, SpawnProcess): return self._p.is_alive() else: return self._p.poll() is None @property def pid(self) -> int: # we check the process has always been spawned when CombinedProcess is initialised return self._p.pid # type: ignore[return-value] def join(self, timeout: int) -> None: if isinstance(self._p, SpawnProcess): self._p.join(timeout) else: self._p.wait(timeout) @property def exitcode(self) -> Optional[int]: if isinstance(self._p, SpawnProcess): return self._p.exitcode else: return self._p.returncode def run_function(function: str, tty_path: Optional[str], args: Tuple[Any, ...], kwargs: Dict[str, Any]) -> None: with set_tty(tty_path): func = import_string(function) func(*args, **kwargs) def import_string(dotted_path: str) -> Any: """ Stolen approximately from django. Import a dotted module path and return the attribute/class designated by the last name in the path. Raise ImportError if the import fails. """ try: module_path, class_name = dotted_path.strip(' ').rsplit('.', 1) except ValueError as e: raise ImportError(f'"{dotted_path}" doesn\'t look like a module path') from e module = import_module(module_path) try: return getattr(module, class_name) except AttributeError as e: raise ImportError(f'Module "{module_path}" does not define a "{class_name}" attribute') from e def get_tty_path() -> Optional[str]: # pragma: no cover """ Return the path to the current TTY, if any. Virtually impossible to test in pytest, hence no cover. """ try: return os.ttyname(sys.stdin.fileno()) except OSError: # fileno() always fails with pytest return '/dev/tty' except AttributeError: # on Windows. No idea of a better solution return None @contextlib.contextmanager def set_tty(tty_path: Optional[str]) -> Generator[None, None, None]: if tty_path: try: with open(tty_path) as tty: # pragma: no cover sys.stdin = tty yield except OSError: # eg. "No such device or address: '/dev/tty'", see https://github.com/samuelcolvin/watchfiles/issues/40 yield else: # currently on windows tty_path is None and there's nothing we can do here yield