It was hardcoded that if KORE_USE_PYTHON was defined we would
look at the passed argument on the command-line as the python
script or module to be run.
This won't work when adding more runtimes.
So instead call a kore_runtime_resolve() function that in
turn calls each available runtime its resolve function.
That resolve function will check if its a script / module
that it can load, and if so will load it.
This way we can remove all those KORE_USE_PYTHON blocks in the
Kore startup path and we pave the way for lua.
This commit adds improved hooks for Python and a new signal delivery hook.
For the Python API kore_worker_configure() and kore_worker_teardown() had
to be implemented before this commit. Now one can create a workerstart
and workerend method in their koreapp as those will be called when
they exist.
The new signal hook is either kore_worker_signal() or koreapp.signal.
This new hook is called after the worker event code handles the received
signal itself first.
With this commit there is also a new kore_signal_trap() API call allowing
you to more easily trap new signals. This API also also exported to the
Python part of the code under kore.sigtrap()
1) Add @kore.route as a decorator for Python.
This decorator can be used on non-class methods to automatically
declare their route and parameters.
Takes the same arguments as the kore.domain.route function that
exists today.
Provides a nice clean way of setting up Kore if you dont want
a whole class based approach.
2) Remove the requirement for the name for kore.server() and the
kore.domain(attach=) keywords.
Instead of no name was given, the name "default" is used in both
places resulting in less boilerplating.
3) Allow multiple routes to be defined for the same URI as long
as the methods are different. So you can have one method for GET /
and another for POST /.
All changes combined condense the initial experience of getting
a Kore Python app up and running:
eg:
import kore
kore.server(ip="127.0.0.1", port="8888", tls=False)
kore.domain("*")
@kore.route("/", methods=["get"])
async def index(req):
req.response(200, b'get method')
@kore.route("/", methods=["post"])
async def index_post(req)
req.response(200, b'post method')
In cases where a request is immediately completed in libcurl its multi
handle and no additional i/o is happening a coro can get stuck waiting
to be run.
Prevent this by lowering netwait from KORE_WAIT_INFINITE if there
are pending python coroutines.
A new hook in the koreapp class is called right before seccomp
is enabled. This hook receives a Kore seccomp object which has
the following methods:
seccomp.allow("syscall")
seccomp.allow_arg("syscall", arg, value)
seccomp.allow_flag("syscall", arg, flag)
seccomp.allow_mask("syscall", arg, mask)
seccomp.deny("syscall")
seccomp.deny_arg("syscall", arg, value, errno=EACCES)
seccomp.deny_flag("syscall", arg, flag, errno=EACCES)
seccomp.deny_mask("syscall", arg, mask, errno=EACCES)
This allows you to finetune the seccomp filters for your application
from inside your koreapp.
If built with PYTHON_CORO_DEBUG in CFLAGS Kore will spew out coroutine
traces while running. These traces include the filename, function and line
number where the coroutines are waking up, running and suspended.
- If Kore is built with PYTHON=1 you can now specify the module that
should be loaded on the command-line.
eg: $ kore -frn myapp
- Add skeleton generation for python applications to kodev.
eg: $ kodev create -p myapp
This should make it a whole lot easier to get started with kore python.
This adds kore.proc to the python runtime allowing async processing
handling:
The kore.proc method takes the command to run and an optional timeout
parameter in milliseconds. If the process did not exit normally after
that amount of time a TimeoutError exception is raised.
For instance:
async def run(cmd):
proc = kore.proc(cmd, 1000)
try:
await proc.send("hello")
proc.close_stdin()
except TimeoutError:
proc.kill()
retcode = await proc.reap()
return retcode
This means you can now do things like:
resp = await koresock.recv(1024)
await koresock.send(resp)
directly from page handlers if they are defined as async.
Adds lots more to the python goo such as fatalx(), bind_unix(),
task_create() and socket_wrap().
Mimics how the header files are installed on a system
as PREFIX/include/kore.
This is required for getting kodev to use the headers from the
kore_source option instead of requiring the kore headers to be
installed on the system even when building as a single_binary.