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https://github.com/FliegendeWurst/cursive.git
synced 2024-11-23 17:35:00 +00:00
111 lines
3.3 KiB
Rust
111 lines
3.3 KiB
Rust
extern crate cursive;
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use std::sync::mpsc;
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use std::thread;
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use std::time::Duration;
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use cursive::Cursive;
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use cursive::Printer;
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use cursive::view::{View, FullView};
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fn main() {
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// As usual, create the Cursive root
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let mut siv = Cursive::new();
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// We want to refresh the page even when no input is given.
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siv.set_fps(10);
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siv.add_global_callback('q', |s| s.quit());
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// A channel will communicate data from our running task to the UI.
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let (tx, rx) = mpsc::channel();
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// Generate data in a separate thread.
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thread::spawn(|| {
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generate_logs(tx);
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});
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// And sets the view to read from the other end of the channel.
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// (We use FullView to force fullscreen because
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// we have no min_size for the BufferView).
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siv.add_layer(FullView::new(BufferView::new(200, rx)));
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siv.run();
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}
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// We will only simulate log generation here.
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// In real life, this may come from a running task, a separate process, ...
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fn generate_logs(tx: mpsc::Sender<String>) {
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let mut i = 1;
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loop {
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let line = format!("Interesting log line {}", i);
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i += 1;
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// The send will fail when the other side is dropped.
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// (When the application ends).
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match tx.send(line) {
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Err(_) => return,
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Ok(_) => (),
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}
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thread::sleep(Duration::from_millis(30));
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}
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}
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// Let's define a buffer view, that shows the last lines from a stream.
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struct BufferView {
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// We will emulate a ring buffer
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buffer: Vec<String>,
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// Current position in the buffer
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pos: usize,
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// Receiving end of the stream
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rx: mpsc::Receiver<String>,
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}
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impl BufferView {
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// Creates a new view with the given buffer size
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fn new(size: usize, rx: mpsc::Receiver<String>) -> Self {
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BufferView {
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rx: rx,
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buffer: (0..size).map(|_| String::new()).collect(),
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pos: 0,
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}
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}
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// Reads available data from the stream into the buffer
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fn update(&mut self) {
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let mut i = self.pos;
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while let Ok(line) = self.rx.try_recv() {
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self.buffer[i] = line;
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i = (i + 1) % self.buffer.len();
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}
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self.pos = i;
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}
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// Chain together the two parts of the buffer to appear as a circular one.
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// The signature is quite ugly, but basically we return an iterator:
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// a Chain of two slice iterators.
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fn ring<'a>(&'a self)
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-> std::iter::Chain<std::slice::Iter<'a, String>, std::slice::Iter<'a, String>> {
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// The main buffer is "circular" starting at self.pos
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// So we chain the two parts as one
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self.buffer[self.pos..].iter().chain(self.buffer[..self.pos].iter())
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}
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}
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impl View for BufferView {
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fn draw(&mut self, printer: &Printer) {
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// Before drawing, we'll want to update the buffer
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self.update();
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// If the buffer is large enough, we'll discard the beginning and keep the end.
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// If the buffer is too small, only print a part of it with an offset.
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let (discard, offset) = if self.buffer.len() > printer.size.y as usize {
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(self.buffer.len() - printer.size.y as usize, 0)
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} else {
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(0, printer.size.y - self.buffer.len())
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};
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for (i, line) in self.ring().skip(discard).enumerate() {
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printer.print((0, offset + i), line);
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}
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}
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}
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