Crates.io | telebot |
lib.rs | telebot |
version | 0.3.1 |
source | src |
created_at | 2016-12-22 10:15:44.280631 |
updated_at | 2019-12-10 07:20:47.999439 |
description | A wrapper around the telegram bot api, powered by futures |
homepage | |
repository | https://github.com/bytesnake/telebot |
max_upload_size | |
id | 7720 |
size | 553,333 |
This library allows you to write a Telegram Bot in the Rust language. It's an almost complete wrapper for the Telegram Bot API and uses hyper to send requests to the Telegram server. Each Telegram function call returns a future which carries the actual bot and the answer.
Add this to your Cargo.toml
[dependencies]
telebot = "0.3.0"
You need a nightly version of the Rust compiler, because procedural macros are not yet supported in the stable channel.
This example shows the basic usage of the telebot library. It creates a new handler for a simple "/reply" command and replies the received text. The tokio eventloop polls every 200ms for new updates and matches them with the registered events. If the command matches with "/reply" it will call the function and execute the returned future.
use telebot::Bot;
use futures::stream::Stream;
use std::env;
// import all available functions
use telebot::functions::*;
fn main() {
// Create the bot
let mut bot = Bot::new(&env::var("TELEGRAM_BOT_KEY").unwrap()).update_interval(200);
// Register a reply command which answers a message
let handle = bot.new_cmd("/reply")
.and_then(|(bot, msg)| {
let mut text = msg.text.unwrap().clone();
if text.is_empty() {
text = "<empty>".into();
}
bot.message(msg.chat.id, text).send()
})
.for_each(|_| Ok(()));
bot.run_with(handle);
}
The former example was very simple with just one handler and no error handling. If you want to see a further explained and illustrated one, please see here.
This crate uses custom derive to generate functions of the Telegram API. Therefore each complete function is described with a struct in functions.rs and the supplemental crate telebot-derive generates the complete signature. In order to find a function, the struct signature can be used. For example consider sendLocation:
/// Use this method to send point on the map. On success, the sent Message is returned.
#[derive(TelegramFunction, Serialize)]
#[call = "sendLocation"]
#[answer = "Message"]
#[function = "location"]
pub struct SendLocation {
chat_id: u32,
latitude: f32,
longitude: f32,
#[serde(skip_serializing_if="Option::is_none")]
disable_notification: Option<bool>,
#[serde(skip_serializing_if="Option::is_none")]
reply_to_message_id: Option<u32>,
#[serde(skip_serializing_if="Option::is_none")]
reply_markup: Option<NotImplemented>
}
The field "function" defines the name of the function in the local API. Each optional field in the struct can be changed by calling an additional function with the name of the field.
So for example to send the location of Paris to chat 432432 without notification: bot.location(432432, 48.8566, 2.3522).disable_notification(true).send()
Licensed under either of
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Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.