Overview

execution locals: killing global state (including thread locals)

This module provides execution locals aka "xlocal" objects which implement a more restricted variant of "thread locals". An execution local allows to manage attributes on a per-execution basis in a manner similar to how real locals work:

  • Invoked functions cannot change the binding for the invoking function
  • existence of a binding is local to a code block (and everything it calls)

Attribute bindings for an xlocal objects will not leak outside a context-managed code block and they will not leak to other threads of greenlets. By contrast, both process-globals and so called "thread locals" do not implement the above properties.

Let's look at a basic example:

# content of example.py

from xlocal import xlocal

xcurrent = xlocal()

def output():
    print "hello world", xcurrent.x

if __name__ == "__main__":
    with xcurrent(x=1):
        output()

If we execute this module, the output() function will see a xcurrent.x==1 binding:

$ python example.py
hello world 1

Here is what happens in detail: xcurrent(x=1) returns a context manager which sets/resets the x attribute on the xcurrent object. While remaining in the same thread/greenlet, all code triggered by the with-body (in this case just the output() function) can access xcurrent.x. Outside the with- body xcurrent.x would raise an AttributeError. It is also not allowed to directly set xcurrent attributes; you always have to explicitely mark their life-cycle with a with-statement. This means that invoked code:

  • cannot rebind xlocal state of its invoking functions (no side effects, yay!)
  • xlocal state does not leak outside the with-context (lifecylcle control)

Another module may now reuse the example code:

# content of example_call.py
import example

with example.xcurrent(x=3):
    example.output()

which when running ...:

$ python example_call.py
hello world 3

will cause the example.output() function to print the xcurrent.x binding as defined at the invoking with xcurrent(x=42) statement.

Other threads or greenlets will never see this xcurrent.x binding; they may even set and read their own distincit xcurrent.x object. This means that all threads/greenlets can concurrently call into a function which will always see the execution specific x attribute.

Usage in frameworks and libraries invoking "handlers"

When invoking plugin code or handler code to perform work, you may not want to pass around all state that might ever be needed. Instead of using a global or thread local you can safely pass around such state in execution locals. Here is a pseudo example:

xcurrent = xlocal.new()

def with_xlocal(func, **kwargs):
    with xcurrent(**kwargs):
        func()

def handle_request(request):
    func = gethandler(request)  # some user code
    spawn(with_xlocal(func, request=request))

handle_request will run a user-provided handler function in a newly spawned execution unit (for example spawn might map to threading.Thread(...).start() or to gevent.spawn(...)). The generic with_xlocal helper wraps the execution of the handler function so that it will see a xcurrent.request binding. Multiple spawns may execute concurrently and xcurrent.request will carry the execution-specific request object in each of them.

Issues worth noting

If a method memorizes an attribute of an execution local, for example the above xcurrent.request, then it will keep a reference to the exact request object, not the per-execution one. If you want to keep a per-execution local, you can do it this way for example:

Class Renderer:
    @property
    def request(self):
        return xcurrent.request

this means that Renderer instances will have an execution-local self.request object even if the life-cycle of the instance crosses execution units.

Another issue is that if you spawn new execution units, they will not implicitely inherit execution locals. Instead you have to wrap your spawning function to explicitely set execution locals, similar to what we did in the above "invoking handlers" section.