libvaxis/examples/text_input.zig
Tim Culverhouse 59abd7d7d4 refactor(vaxis): move tty out of vaxis
Refactor to move the tty out of the vaxis struct. All vaxis writes now
take an io.AnyWriter
2024-05-29 11:33:39 -05:00

156 lines
5.9 KiB
Zig

const std = @import("std");
const vaxis = @import("vaxis");
const Cell = vaxis.Cell;
const TextInput = vaxis.widgets.TextInput;
const border = vaxis.widgets.border;
const log = std.log.scoped(.main);
// Our Event. This can contain internal events as well as Vaxis events.
// Internal events can be posted into the same queue as vaxis events to allow
// for a single event loop with exhaustive switching. Booya
const Event = union(enum) {
key_press: vaxis.Key,
mouse: vaxis.Mouse,
winsize: vaxis.Winsize,
focus_in,
focus_out,
foo: u8,
};
pub fn main() !void {
var gpa = std.heap.GeneralPurposeAllocator(.{}){};
defer {
const deinit_status = gpa.deinit();
//fail test; can't try in defer as defer is executed after we return
if (deinit_status == .leak) {
log.err("memory leak", .{});
}
}
const alloc = gpa.allocator();
// Initalize a tty
var tty = try vaxis.Tty.init();
defer tty.deinit();
// Use a buffered writer for better performance. There are a lot of writes
// in the render loop and this can have a significant savings
var buffered_writer = tty.bufferedWriter();
const writer = buffered_writer.writer().any();
// Initialize Vaxis
var vx = try vaxis.init(alloc, .{});
defer vx.deinit(tty.anyWriter(), alloc);
var loop: vaxis.Loop(Event) = .{
.vaxis = &vx,
.tty = &tty,
};
try loop.init();
// Start the read loop. This puts the terminal in raw mode and begins
// reading user input
try loop.start();
defer loop.stop();
// Optionally enter the alternate screen
try vx.enterAltScreen(writer);
// We'll adjust the color index every keypress for the border
var color_idx: u8 = 0;
// init our text input widget. The text input widget needs an allocator to
// store the contents of the input
var text_input = TextInput.init(alloc, &vx.unicode);
defer text_input.deinit();
// Sends queries to terminal to detect certain features. This should
// _always_ be called, but is left to the application to decide when
// try vx.queryTerminal();
try vx.setMouseMode(writer, true);
try buffered_writer.flush();
// The main event loop. Vaxis provides a thread safe, blocking, buffered
// queue which can serve as the primary event queue for an application
while (true) {
// nextEvent blocks until an event is in the queue
const event = loop.nextEvent();
log.debug("event: {}", .{event});
// exhaustive switching ftw. Vaxis will send events if your Event
// enum has the fields for those events (ie "key_press", "winsize")
switch (event) {
.key_press => |key| {
color_idx = switch (color_idx) {
255 => 0,
else => color_idx + 1,
};
if (key.matches('c', .{ .ctrl = true })) {
break;
} else if (key.matches('l', .{ .ctrl = true })) {
vx.queueRefresh();
} else if (key.matches('n', .{ .ctrl = true })) {
try vx.notify(tty.anyWriter(), "vaxis", "hello from vaxis");
loop.stop();
var child = std.process.Child.init(&.{"nvim"}, alloc);
_ = try child.spawnAndWait();
try loop.start();
try vx.enterAltScreen(tty.anyWriter());
vx.queueRefresh();
} else if (key.matches(vaxis.Key.enter, .{})) {
text_input.clearAndFree();
} else {
try text_input.update(.{ .key_press = key });
}
},
// winsize events are sent to the application to ensure that all
// resizes occur in the main thread. This lets us avoid expensive
// locks on the screen. All applications must handle this event
// unless they aren't using a screen (IE only detecting features)
//
// This is the only call that the core of Vaxis needs an allocator
// for. The allocations are because we keep a copy of each cell to
// optimize renders. When resize is called, we allocated two slices:
// one for the screen, and one for our buffered screen. Each cell in
// the buffered screen contains an ArrayList(u8) to be able to store
// the grapheme for that cell Each cell is initialized with a size
// of 1, which is sufficient for all of ASCII. Anything requiring
// more than one byte will incur an allocation on the first render
// after it is drawn. Thereafter, it will not allocate unless the
// screen is resized
.winsize => |ws| try vx.resize(alloc, ws, tty.anyWriter()),
else => {},
}
// vx.window() returns the root window. This window is the size of the
// terminal and can spawn child windows as logical areas. Child windows
// cannot draw outside of their bounds
const win = vx.window();
// Clear the entire space because we are drawing in immediate mode.
// vaxis double buffers the screen. This new frame will be compared to
// the old and only updated cells will be drawn
win.clear();
// draw the text_input using a bordered window
const style: vaxis.Style = .{
.fg = .{ .index = color_idx },
};
const child = win.child(.{
.x_off = win.width / 2 - 20,
.y_off = win.height / 2 - 3,
.width = .{ .limit = 40 },
.height = .{ .limit = 3 },
.border = .{
.where = .all,
.style = style,
},
});
text_input.draw(child);
// Render the screen
try vx.render(writer);
try buffered_writer.flush();
}
}