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terminal: start pulling out stream processing into dedicated type

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This commit is contained in:
Mitchell Hashimoto
2022-05-10 19:01:32 -07:00
parent de7d950052
commit bc7b3a0996
2 changed files with 274 additions and 0 deletions
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4
src/terminal/main.zig
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@ -1,9 +1,13 @@
const stream = @import("stream.zig");
pub const Terminal = @import("Terminal.zig");
pub const Parser = @import("Parser.zig");
pub const Stream = stream.Stream;
// Not exported because they're just used for tests.
test {
_ = stream;
_ = Parser;
_ = Terminal;

270
src/terminal/stream.zig Normal file
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@ -0,0 +1,270 @@
const std = @import("std");
const testing = std.testing;
const Parser = @import("Parser.zig");
const ansi = @import("ansi.zig");
const csi = @import("csi.zig");
const trace = @import("../tracy/tracy.zig").trace;
const log = std.log.scoped(.stream);
/// Returns a type that can process a stream of tty control characters.
/// This will call various callback functions on type T. Type T only has to
/// implement the callbacks it cares about; any unimplemented callbacks will
/// logged at runtime.
///
/// To figure out what callbacks exist, search the source for "hasDecl". This
/// isn't ideal but for now that's the best approach.
///
/// This is implemented this way because we purposely do NOT want dynamic
/// dispatch for performance reasons. The way this is implemented forces
/// comptime resolution for all function calls.
pub fn Stream(comptime T: type) type {
return struct {
const Self = @This();
handler: T,
parser: Parser = .{},
/// Process a string of characters.
pub fn nextSlice(self: *Self, c: []const u8) !void {
const tracy = trace(@src());
defer tracy.end();
for (c) |single| try self.next(single);
}
/// Process the next character and call any callbacks if necessary.
pub fn next(self: *Self, c: u8) !void {
const tracy = trace(@src());
defer tracy.end();
//log.debug("char: {}", .{c});
const actions = self.parser.next(c);
for (actions) |action_opt| {
//if (action_opt) |action| log.info("action: {}", .{action});
switch (action_opt orelse continue) {
.print => |p| if (@hasDecl(T, "print")) try self.handler.print(p),
.execute => |code| if (@hasDecl(T, "execute")) try self.handler.execute(code),
.csi_dispatch => |csi| try self.csiDispatch(csi),
.esc_dispatch => |esc| try self.escDispatch(esc),
.osc_dispatch => |cmd| log.warn("unhandled OSC: {}", .{cmd}),
.dcs_hook => |dcs| log.warn("unhandled DCS hook: {}", .{dcs}),
.dcs_put => |code| log.warn("unhandled DCS put: {}", .{code}),
.dcs_unhook => log.warn("unhandled DCS unhook", .{}),
}
}
}
fn csiDispatch(self: *Self, action: Parser.Action.CSI) !void {
switch (action.final) {
// CUF - Cursor Right
'C' => if (@hasDecl(T, "cursorRight")) try self.handler.cursorRight(
switch (action.params.len) {
0 => 1,
1 => action.params[0],
else => {
log.warn("invalid cursor right command: {}", .{action});
return;
},
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// HPA - Cursor Horizontal Position Absolute
// TODO: test
'G', '`' => if (@hasDecl(T, "setCursorCol")) try self.handler.setCursorCol(
switch (action.params.len) {
0 => 1,
1 => action.params[0],
else => log.warn("invalid HPA command: {}", .{action}),
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// CUP - Set Cursor Position.
// TODO: test
'H' => if (@hasDecl(T, "setCursorPos")) switch (action.params.len) {
0 => try self.handler.setCursorPos(1, 1),
1 => try self.handler.setCursorPos(action.params[0], 1),
2 => try self.handler.setCursorPos(action.params[0], action.params[1]),
else => log.warn("invalid CUP command: {}", .{action}),
} else log.warn("unimplemented CSI callback: {}", .{action}),
// Erase Display
// TODO: test
'J' => if (@hasDecl(T, "eraseDisplay")) try self.eraseDisplay(
switch (action.params.len) {
0 => .below,
1 => mode: {
// TODO: use meta to get enum max
if (action.params[0] > 3) {
log.warn("invalid erase display command: {}", .{action});
return;
}
break :mode @intToEnum(
csi.EraseDisplay,
action.params[0],
);
},
else => {
log.warn("invalid erase display command: {}", .{action});
return;
},
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// Erase Line
'K' => if (@hasDecl(T, "eraseLine")) try self.handler.eraseLine(
switch (action.params.len) {
0 => .right,
1 => mode: {
// TODO: use meta to get enum max
if (action.params[0] > 3) {
log.warn("invalid erase line command: {}", .{action});
return;
}
break :mode @intToEnum(
csi.EraseLine,
action.params[0],
);
},
else => {
log.warn("invalid erase line command: {}", .{action});
return;
},
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// Delete Character (DCH)
'P' => if (@hasDecl(T, "deleteChars")) try self.handler.deleteChars(
switch (action.params.len) {
0 => 1,
1 => action.params[0],
else => {
log.warn("invalid delete characters command: {}", .{action});
return;
},
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// Erase Characters (ECH)
'X' => if (@hasDecl(T, "eraseChars")) try self.handler.eraseChars(
switch (action.params.len) {
0 => 1,
1 => action.params[0],
else => {
log.warn("invalid erase characters command: {}", .{action});
return;
},
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// VPA - Cursor Vertical Position Absolute
'd' => if (@hasDecl(T, "setCursorRow")) try self.handler.setCursorRow(
switch (action.params.len) {
0 => 1,
1 => action.params[0],
else => log.warn("invalid VPA command: {}", .{action}),
},
) else log.warn("unimplemented CSI callback: {}", .{action}),
// SGR - Select Graphic Rendition
'm' => if (@hasDecl(T, "selectGraphicRendition")) {
if (action.params.len == 0) {
// No values defaults to code 0
try self.handler.selectGraphicRendition(.default);
} else {
// Each parameter sets a separate aspect
for (action.params) |param| {
try self.handler.selectGraphicRendition(@intToEnum(
ansi.RenditionAspect,
param,
));
}
}
} else log.warn("unimplemented CSI callback: {}", .{action}),
else => if (@hasDecl(T, "csiUnimplemented"))
try self.handler.csiUnimplemented(action)
else
log.warn("unimplemented CSI action: {}", .{action}),
}
}
fn escDispatch(
self: *Self,
action: Parser.Action.ESC,
) !void {
switch (action.final) {
// RI - Reverse Index
'M' => if (@hasDecl(T, "reverseIndex")) switch (action.intermediates.len) {
0 => try self.reverseIndex(),
else => {
log.warn("invalid reverse index command: {}", .{action});
return;
},
} else log.warn("unimplemented ESC callback: {}", .{action}),
else => if (@hasDecl(T, "escUnimplemented"))
try self.handler.escUnimplemented(action)
else
log.warn("unimplemented ESC action: {}", .{action}),
}
}
};
}
test "stream: print" {
const H = struct {
c: ?u8 = 0,
pub fn print(self: *@This(), c: u8) !void {
self.c = c;
}
};
var s: Stream(H) = .{ .handler = .{} };
try s.next('x');
try testing.expectEqual(@as(u8, 'x'), s.handler.c.?);
}
test "stream: execute" {
const H = struct {
c: ?u8 = 0,
p: bool = false,
pub fn print(self: *@This(), c: u8) !void {
_ = c;
self.p = true;
}
pub fn execute(self: *@This(), c: u8) !void {
self.c = c;
}
};
var s: Stream(H) = .{ .handler = .{} };
try s.next('\n');
try testing.expect(!s.handler.p);
try testing.expectEqual(@as(u8, '\n'), s.handler.c.?);
}
test "stream: cursor right (CUF)" {
const H = struct {
amount: u16 = 0,
pub fn cursorRight(self: *@This(), v: u16) !void {
self.amount = v;
}
};
var s: Stream(H) = .{ .handler = .{} };
try s.nextSlice("\x1B[C");
try testing.expectEqual(@as(u16, 1), s.handler.amount);
try s.nextSlice("\x1B[5C");
try testing.expectEqual(@as(u16, 5), s.handler.amount);
s.handler.amount = 0;
try s.nextSlice("\x1B[5;4C");
try testing.expectEqual(@as(u16, 0), s.handler.amount);
}