Telethon/readthedocs/concepts/full-api.rst

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.. _full-api:
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============
The Full API
============
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.. important::
While you have access to this, you should always use the friendly
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methods listed on :ref:`client-ref` unless you have a better reason
not to, like a method not existing or you wanting more control.
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.. contents::
Introduction
============
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The :ref:`telethon-client` doesn't offer a method for every single request
the Telegram API supports. However, it's very simple to *call* or *invoke*
any request defined in Telegram's API.
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This section will teach you how to use what Telethon calls the `TL reference`_.
The linked page contains a list and a way to search through *all* types
generated from the definition of Telegram's API (in ``.tl`` file format,
hence the name). These types include requests and constructors.
.. note::
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The reason to keep both https://tl.telethon.dev and this
documentation alive is that the former allows instant search results
as you type, and a "Copy import" button. If you like namespaces, you
can also do ``from telethon.tl import types, functions``. Both work.
Telegram makes these ``.tl`` files public, which other implementations, such
as Telethon, can also use to generate code. These files are versioned under
what's called "layers". ``.tl`` files consist of thousands of definitions,
and newer layers often add, change, or remove them. Each definition refers
to either a Remote Procedure Call (RPC) function, or a type (which the
`TL reference`_ calls "constructors", as they construct particular type
instances).
As such, the `TL reference`_ is a good place to go to learn about all possible
requests, types, and what they look like. If you're curious about what's been
changed between layers, you can refer to the `TL diff`_ site.
Navigating the TL reference
===========================
Functions
---------
"Functions" is the term used for the Remote Procedure Calls (RPC) that can be
sent to Telegram to ask it to perform something (e.g. "send message"). These
requests have an associated return type. These can be invoked ("called"):
.. code-block:: python
client = TelegramClient(...)
function_instance = SomeRequest(...)
# Invoke the request
returned_type = await client(function_instance)
Whenever you find the type for a function in the `TL reference`_, the page
will contain the following information:
* What type of account can use the method. This information is regenerated
from time to time (by attempting to invoke the function under both account
types and finding out where it fails). Some requests can only be used by
bot accounts, others by user accounts, and others by both.
* The TL definition. This helps you get a feel for the what the function
looks like. This is not Python code. It just contains the definition in
a concise manner.
* "Copy import" button. Does what it says: it will copy the necessary Python
code to import the function to your system's clipboard for easy access.
* Returns. The returned type. When you invoke the function, this is what the
result will be. It also includes which of the constructors can be returned
inline, to save you a click.
* Parameters. The parameters accepted by the function, including their type,
whether they expect a list, and whether they're optional.
* Known RPC errors. A best-effort list of known errors the request may cause.
This list is not complete and may be out of date, but should provide an
overview of what could go wrong.
* Example. Autogenerated example, showcasing how you may want to call it.
Bear in mind that this is *autogenerated*. It may be spitting out non-sense.
The goal of this example is not to show you everything you can do with the
request, only to give you a feel for what it looks like to use it.
It is very important to click through the links and navigate to get the full
picture. A specific page will show you what the specific function returns and
needs as input parameters. But it may reference other types, so you need to
navigate to those to learn what those contain or need.
Types
-----
"Types" as understood by TL are not actually generated in Telethon.
They would be the "abstract base class" of the constructors, but since Python
is duck-typed, there is hardly any need to generate mostly unnecessary code.
The page for a type contains:
* Constructors. Every type will have one or more constructors. These
constructors *are* generated and can be immported and used.
* Requests returning this type. A helpful way to find out "what requests can
return this?". This is how you may learn what request you need to use to
obtain a particular instance of a type.
* Requests accepting this type as input. A helpful way to find out "what
requests can use this type as one of their input parameters?". This is how
you may learn where a type is used.
* Other types containing this type. A helpful way to find out "where else
does this type appear?". This is how you can walk back through nested
objects.
Constructors
------------
Constructors are used to create instances of a particular type, and are also
returned when invoking requests. You will have to create instances yourself
when invoking requests that need a particular type as input.
The page for a constructor contains:
* Belongs to. The parent type. This is a link back to the types page for the
specific constructor. It also contains the sibling constructors inline, to
save you a click.
* Members. Both the input parameters *and* fields the constructor contains.
Using the TL reference
======================
After you've found a request you want to send, a good start would be to simply
copy and paste the autogenerated example into your script. Then you can simply
tweak it to your needs.
If you want to do it from scratch, first, make sure to import the request into
your code (either using the "Copy import" button near the top, or by manually
spelling out the package under ``telethon.tl.functions.*``).
Then, start reading the parameters one by one. If the parameter cannot be
omitted, you **will** need to specify it, so make sure to spell it out as
an input parameter when constructing the request instance. Let's look at
`PingRequest`_ for example. First, we copy the import:
.. code-block:: python
from telethon.tl.functions import PingRequest
Then, we look at the parameters:
ping_id - long
A single parameter, and it's a long (a integer number with a large range of
values). It doesn't say it can be omitted, so we must provide it, like so:
.. code-block:: python
PingRequest(
ping_id=48641868471
)
(In this case, the ping ID is a random number. You often have to guess what
the parameter needs just by looking at the name.)
Now that we have our request, we can invoke it:
.. code-block:: python
response = await client(PingRequest(
ping_id=48641868471
))
To find out what ``response`` looks like, we can do as the autogenerated
example suggests and "stringify" the result as a pretty-printed string:
.. code-block:: python
print(result.stringify())
This will print out the following:
.. code-block:: python
Pong(
msg_id=781875678118,
ping_id=48641868471
)
Which is a very easy way to get a feel for a response. You should nearly
always print the stringified result, at least once, when trying out requests,
to get a feel for what the response may look like.
But of course, you don't need to do that. Without writing any code, you could
have navigated through the "Returns" link to learn ``PingRequest`` returns a
``Pong``, which only has one constructor, and the constructor has two members,
``msg_id`` and ``ping_id``.
If you wanted to create your own ``Pong``, you would use both members as input
parameters:
.. code-block:: python
my_pong = Pong(
msg_id=781875678118,
ping_id=48641868471
)
(Yes, constructing object instances can use the same code that ``.stringify``
would return!)
And if you wanted to access the ``msg_id`` member, you would simply access it
like any other attribute access in Python:
.. code-block:: python
print(response.msg_id)
Example walkthrough
===================
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Say `client.send_message()
<telethon.client.messages.MessageMethods.send_message>` didn't exist,
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we could `use the search`_ to look for "message". There we would find
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:tl:`SendMessageRequest`, which we can work with.
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Every request is a Python class, and has the parameters needed for you
to invoke it. You can also call ``help(request)`` for information on
what input parameters it takes. Remember to "Copy import to the
clipboard", or your script won't be aware of this class! Now we have:
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.. code-block:: python
from telethon.tl.functions.messages import SendMessageRequest
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If you're going to use a lot of these, you may do:
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.. code-block:: python
from telethon.tl import types, functions
# We now have access to 'functions.messages.SendMessageRequest'
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We see that this request must take at least two parameters, a ``peer``
of type :tl:`InputPeer`, and a ``message`` which is just a Python
`str`\ ing.
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How can we retrieve this :tl:`InputPeer`? We have two options. We manually
construct one, for instance:
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.. code-block:: python
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from telethon.tl.types import InputPeerUser
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peer = InputPeerUser(user_id, user_hash)
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Or we call `client.get_input_entity()
<telethon.client.users.UserMethods.get_input_entity>`:
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.. code-block:: python
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import telethon
async def main():
peer = await client.get_input_entity('someone')
client.loop.run_until_complete(main())
.. note::
Remember that ``await`` must occur inside an ``async def``.
Every full API example assumes you already know and do this.
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When you're going to invoke an API method, most require you to pass an
:tl:`InputUser`, :tl:`InputChat`, or so on, this is why using
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`client.get_input_entity() <telethon.client.users.UserMethods.get_input_entity>`
is more straightforward (and often immediate, if you've seen the user before,
know their ID, etc.). If you also **need** to have information about the whole
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user, use `client.get_entity() <telethon.client.users.UserMethods.get_entity>`
instead:
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.. code-block:: python
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entity = await client.get_entity('someone')
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In the later case, when you use the entity, the library will cast it to
its "input" version for you. If you already have the complete user and
want to cache its input version so the library doesn't have to do this
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every time its used, simply call `telethon.utils.get_input_peer`:
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.. code-block:: python
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from telethon import utils
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peer = utils.get_input_peer(entity)
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.. note::
Since ``v0.16.2`` this is further simplified. The ``Request`` itself
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will call `client.get_input_entity
<telethon.client.users.UserMethods.get_input_entity>` for you when
required, but it's good to remember what's happening.
After this small parenthesis about `client.get_entity
<telethon.client.users.UserMethods.get_entity>` versus
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`client.get_input_entity() <telethon.client.users.UserMethods.get_input_entity>`,
we have everything we need. To invoke our
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request we do:
.. code-block:: python
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result = await client(SendMessageRequest(peer, 'Hello there!'))
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Message sent! Of course, this is only an example. There are over 250
methods available as of layer 80, and you can use every single of them
as you wish. Remember to use the right types! To sum up:
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.. code-block:: python
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result = await client(SendMessageRequest(
await client.get_input_entity('username'), 'Hello there!'
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))
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This can further be simplified to:
.. code-block:: python
result = await client(SendMessageRequest('username', 'Hello there!'))
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# Or even
result = await client(SendMessageRequest(PeerChannel(id), 'Hello there!'))
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.. note::
Note that some requests have a "hash" parameter. This is **not**
your ``api_hash``! It likely isn't your self-user ``.access_hash`` either.
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It's a special hash used by Telegram to only send a difference of new data
that you don't already have with that request, so you can leave it to 0,
and it should work (which means no hash is known yet).
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For those requests having a "limit" parameter, you can often set it to
zero to signify "return default amount". This won't work for all of them
though, for instance, in "messages.search" it will actually return 0 items.
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Requests in Parallel
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====================
The library will automatically merge outgoing requests into a single
*container*. Telegram's API supports sending multiple requests in a
single container, which is faster because it has less overhead and
the server can run them without waiting for others. You can also
force using a container manually:
.. code-block:: python
async def main():
# Letting the library do it behind the scenes
await asyncio.wait([
client.send_message('me', 'Hello'),
client.send_message('me', ','),
client.send_message('me', 'World'),
client.send_message('me', '.')
])
# Manually invoking many requests at once
await client([
SendMessageRequest('me', 'Hello'),
SendMessageRequest('me', ', '),
SendMessageRequest('me', 'World'),
SendMessageRequest('me', '.')
])
Note that you cannot guarantee the order in which they are run.
Try running the above code more than one time. You will see the
order in which the messages arrive is different.
If you use the raw API (the first option), you can use ``ordered``
to tell the server that it should run the requests sequentially.
This will still be faster than going one by one, since the server
knows all requests directly:
.. code-block:: python
await client([
SendMessageRequest('me', 'Hello'),
SendMessageRequest('me', ', '),
SendMessageRequest('me', 'World'),
SendMessageRequest('me', '.')
], ordered=True)
If any of the requests fails with a Telegram error (not connection
errors or any other unexpected events), the library will raise
`telethon.errors.common.MultiError`. You can ``except`` this
and still access the successful results:
.. code-block:: python
from telethon.errors import MultiError
try:
await client([
SendMessageRequest('me', 'Hello'),
SendMessageRequest('me', ''),
SendMessageRequest('me', 'World')
], ordered=True)
except MultiError as e:
# The first and third requests worked.
first = e.results[0]
third = e.results[2]
# The second request failed.
second = e.exceptions[1]
.. _TL reference: https://tl.telethon.dev
.. _TL diff: https://diff.telethon.dev
.. _PingRequest: https://tl.telethon.dev/methods/ping.html
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.. _use the search: https://tl.telethon.dev/?q=message&redirect=no