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repline: Promote to its own crate!

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cl-repl: Major refactor based on the design of typeck.rs
This commit is contained in:
John 2024-04-19 07:30:17 -05:00
parent 01ffdb67a6
commit 2a62a1c714
21 changed files with 967 additions and 1114 deletions
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1
Cargo.toml
View File

@ -8,6 +8,7 @@ members = [
"cl-ast",
"cl-parser",
"cl-lexer",
"repline",
]
resolver = "2"

3
cl-repl/Cargo.toml
View File

@ -15,9 +15,8 @@ cl-lexer = { path = "../cl-lexer" }
cl-token = { path = "../cl-token" }
cl-parser = { path = "../cl-parser" }
cl-interpret = { path = "../cl-interpret" }
crossterm = "0.27.0"
repline = { path = "../repline" }
argh = "0.1.12"
[dev-dependencies]
cl-structures = { path = "../cl-structures" }
cl-typeck = { path = "../cl-typeck" }

67
cl-repl/examples/typeck.rs
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@ -4,10 +4,10 @@ use cl_ast::{
};
use cl_lexer::Lexer;
use cl_parser::Parser;
use cl_repl::repline::{error::Error as RlError, Repline};
use cl_typeck::{
definition::Def, name_collector::NameCollectable, project::Project, type_resolver::resolve,
};
use repline::{error::Error as RlError, prebaked::*};
use std::error::Error;
// Path to display in standard library errors
@ -40,53 +40,21 @@ fn main() -> Result<(), Box<dyn Error>> {
unsafe { TREES.push(code) }.collect_in_root(&mut prj)?;
main_menu(&mut prj)
}
pub enum Response {
Accept,
Deny,
Break,
}
fn read_and(
color: &str,
begin: &str,
mut f: impl FnMut(&str) -> Result<Response, Box<dyn Error>>,
) -> Result<(), Box<dyn Error>> {
let mut rl = Repline::new(color, begin, "? >");
loop {
let line = match rl.read() {
Err(RlError::CtrlC(_)) => break,
Err(RlError::CtrlD(line)) => {
rl.deny();
line
}
Ok(line) => line,
Err(e) => Err(e)?,
};
print!("\x1b[G\x1b[J");
match f(&line) {
Ok(Response::Accept) => rl.accept(),
Ok(Response::Deny) => rl.deny(),
Ok(Response::Break) => break,
Err(e) => print!("\x1b[40G\x1bJ\x1b[91m{e}\x1b[0m"),
}
}
main_menu(&mut prj)?;
Ok(())
}
fn main_menu(prj: &mut Project) -> Result<(), Box<dyn Error>> {
fn main_menu(prj: &mut Project) -> Result<(), RlError> {
banner();
read_and(C_MAIN, "mu>", |line| {
read_and(C_MAIN, "mu>", "? >", |line| {
match line.trim() {
"c" | "code" => enter_code(prj),
"clear" => clear(),
"c" | "code" => enter_code(prj)?,
"clear" => clear()?,
"e" | "exit" => return Ok(Response::Break),
"l" | "list" => list_types(prj),
"q" | "query" => query_type_expression(prj),
"r" | "resolve" => resolve_all(prj),
"d" | "desugar" => live_desugar(),
"q" | "query" => query_type_expression(prj)?,
"r" | "resolve" => resolve_all(prj)?,
"d" | "desugar" => live_desugar()?,
"h" | "help" => {
println!(
"Valid commands are:
@ -102,12 +70,12 @@ fn main_menu(prj: &mut Project) -> Result<(), Box<dyn Error>> {
}
_ => Err(r#"Invalid command. Type "help" to see the list of valid commands."#)?,
}
.map(|_| Response::Accept)
Ok(Response::Accept)
})
}
fn enter_code(prj: &mut Project) -> Result<(), Box<dyn Error>> {
read_and(C_CODE, "cl>", |line| {
fn enter_code(prj: &mut Project) -> Result<(), RlError> {
read_and(C_CODE, "cl>", "? >", |line| {
if line.trim().is_empty() {
return Ok(Response::Break);
}
@ -120,8 +88,8 @@ fn enter_code(prj: &mut Project) -> Result<(), Box<dyn Error>> {
})
}
fn live_desugar() -> Result<(), Box<dyn Error>> {
read_and(C_RESV, "se>", |line| {
fn live_desugar() -> Result<(), RlError> {
read_and(C_RESV, "se>", "? >", |line| {
let code = Parser::new(Lexer::new(line)).stmt()?;
println!("Raw, as parsed:\n{C_LISTING}{code}\x1b[0m");
@ -135,8 +103,8 @@ fn live_desugar() -> Result<(), Box<dyn Error>> {
})
}
fn query_type_expression(prj: &mut Project) -> Result<(), Box<dyn Error>> {
read_and(C_RESV, "ty>", |line| {
fn query_type_expression(prj: &mut Project) -> Result<(), RlError> {
read_and(C_RESV, "ty>", "? >", |line| {
if line.trim().is_empty() {
return Ok(Response::Break);
}
@ -156,7 +124,7 @@ fn resolve_all(prj: &mut Project) -> Result<(), Box<dyn Error>> {
Ok(())
}
fn list_types(prj: &mut Project) -> Result<(), Box<dyn Error>> {
fn list_types(prj: &mut Project) {
println!(" name\x1b[30G type");
for (idx, Def { name, vis, kind, .. }) in prj.pool.iter().enumerate() {
print!("{idx:3}: {vis}");
@ -165,7 +133,6 @@ fn list_types(prj: &mut Project) -> Result<(), Box<dyn Error>> {
}
println!("{name}\x1b[30G| {kind}");
}
Ok(())
}
fn pretty_def(def: &Def, id: impl Into<usize>) {

2
cl-repl/examples/yaml.rs
View File

@ -2,7 +2,7 @@
use cl_lexer::Lexer;
use cl_parser::Parser;
use cl_repl::repline::{error::Error as RlError, Repline};
use repline::{error::Error as RlError, Repline};
use std::error::Error;
fn main() -> Result<(), Box<dyn Error>> {

14
cl-repl/src/ansi.rs Normal file
View File

@ -0,0 +1,14 @@
//! ANSI escape sequences
pub const RED: &str = "\x1b[31m";
pub const GREEN: &str = "\x1b[32m"; // the color of type checker mode
pub const CYAN: &str = "\x1b[36m";
pub const BRIGHT_GREEN: &str = "\x1b[92m";
pub const BRIGHT_BLUE: &str = "\x1b[94m";
pub const BRIGHT_MAGENTA: &str = "\x1b[95m";
pub const BRIGHT_CYAN: &str = "\x1b[96m";
pub const RESET: &str = "\x1b[0m";
pub const OUTPUT: &str = "\x1b[38;5;117m";
pub const CLEAR_LINES: &str = "\x1b[G\x1b[J";
pub const CLEAR_ALL: &str = "\x1b[H\x1b[2J";

51
cl-repl/src/args.rs Normal file
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@ -0,0 +1,51 @@
//! Handles argument parsing (currently using the [argh] crate)
use argh::FromArgs;
use std::{io::IsTerminal, path::PathBuf, str::FromStr};
/// The Conlang prototype debug interface
#[derive(Clone, Debug, FromArgs, PartialEq, Eq, PartialOrd, Ord)]
pub struct Args {
/// the main source file
#[argh(positional)]
pub file: Option<PathBuf>,
/// files to include
#[argh(option, short = 'I')]
pub include: Vec<PathBuf>,
/// the CLI operating mode (`f`mt | `l`ex | `r`un)
#[argh(option, short = 'm', default = "Default::default()")]
pub mode: Mode,
/// whether to start the repl (`true` or `false`)
#[argh(option, short = 'r', default = "is_terminal()")]
pub repl: bool,
}
/// gets whether stdin AND stdout are a terminal, for pipelining
pub fn is_terminal() -> bool {
std::io::stdin().is_terminal() && std::io::stdout().is_terminal()
}
/// The CLI's operating mode
#[derive(Clone, Copy, Debug, Default, PartialEq, Eq, PartialOrd, Ord)]
pub enum Mode {
#[default]
Menu,
Lex,
Fmt,
Run,
}
impl FromStr for Mode {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
Ok(match s {
"f" | "fmt" | "p" | "pretty" => Mode::Fmt,
"l" | "lex" | "tokenize" | "token" => Mode::Lex,
"r" | "run" => Mode::Run,
_ => Err("Recognized modes are: 'r' \"run\", 'f' \"fmt\", 'l' \"lex\"")?,
})
}
}

12
cl-repl/src/bin/conlang.rs
View File

@ -1,13 +1,5 @@
use cl_repl::{cli::run, tools::is_terminal};
use std::error::Error;
use cl_repl::cli::run;
fn main() -> Result<(), Box<dyn Error>> {
if is_terminal() {
println!(
"--- {} v{} 💪🦈 ---",
env!("CARGO_BIN_NAME"),
env!("CARGO_PKG_VERSION"),
);
}
fn main() -> Result<(), Box<dyn std::error::Error>> {
run(argh::from_env())
}

89
cl-repl/src/cli.rs Normal file
View File

@ -0,0 +1,89 @@
//! Implement's the command line interface
use crate::{
args::{Args, Mode},
ctx::Context,
menu,
tools::print_token,
};
use cl_interpret::{env::Environment, interpret::Interpret, temp_type_impl::ConValue};
use cl_lexer::Lexer;
use cl_parser::Parser;
use std::{error::Error, path::Path};
/// Run the command line interface
pub fn run(args: Args) -> Result<(), Box<dyn Error>> {
let Args { file, include, mode, repl } = args;
let mut env = Environment::new();
for path in include {
load_file(&mut env, path)?;
}
if repl {
if let Some(file) = file {
load_file(&mut env, file)?;
}
let mut ctx = Context::with_env(env);
match mode {
Mode::Menu => menu::main_menu(&mut ctx)?,
Mode::Lex => menu::lex(&mut ctx)?,
Mode::Fmt => menu::fmt(&mut ctx)?,
Mode::Run => menu::run(&mut ctx)?,
}
} else {
let code = match &file {
Some(file) => std::fs::read_to_string(file)?,
None => std::io::read_to_string(std::io::stdin())?,
};
match mode {
Mode::Lex => lex_code(&code, file),
Mode::Fmt => fmt_code(&code),
Mode::Run | Mode::Menu => run_code(&code, &mut env),
}?;
}
Ok(())
}
fn load_file(
env: &mut Environment,
path: impl AsRef<Path>,
) -> Result<ConValue, Box<dyn Error>> {
let file = std::fs::read_to_string(path)?;
let code = Parser::new(Lexer::new(&file)).file()?;
Ok(env.eval(&code)?)
}
fn lex_code(code: &str, path: Option<impl AsRef<Path>>) -> Result<(), Box<dyn Error>> {
for token in Lexer::new(code) {
if let Some(path) = &path {
print!("{}:", path.as_ref().display());
}
match token {
Ok(token) => print_token(&token),
Err(e) => println!("{e}"),
}
}
Ok(())
}
fn fmt_code(code: &str) -> Result<(), Box<dyn Error>> {
let code = Parser::new(Lexer::new(code)).file()?;
println!("{code}");
Ok(())
}
fn run_code(code: &str, env: &mut Environment) -> Result<(), Box<dyn Error>> {
let code = Parser::new(Lexer::new(code)).file()?;
match code.interpret(env)? {
ConValue::Empty => {}
ret => println!("{ret}"),
}
if env.get("main").is_ok() {
match env.call("main", &[])? {
ConValue::Empty => {}
ret => println!("{ret}"),
}
}
Ok(())
}

26
cl-repl/src/ctx.rs Normal file
View File

@ -0,0 +1,26 @@
use cl_interpret::{
env::Environment, error::IResult, interpret::Interpret, temp_type_impl::ConValue,
};
#[derive(Clone, Debug)]
pub struct Context {
pub env: Environment,
}
impl Context {
pub fn new() -> Self {
Self { env: Environment::new() }
}
pub fn with_env(env: Environment) -> Self {
Self { env }
}
pub fn run(&mut self, code: &impl Interpret) -> IResult<ConValue> {
code.interpret(&mut self.env)
}
}
impl Default for Context {
fn default() -> Self {
Self::new()
}
}

451
cl-repl/src/lib.rs
View File

@ -1,446 +1,11 @@
//! Utilities for cl-frontend
//! The Conlang REPL, based on [repline]
//!
//! # TODO
//! - [ ] Readline-like line editing
//! - [ ] Raw mode?
//! Uses [argh] for argument parsing.
#![warn(clippy::all)]
pub mod ansi {
// ANSI color escape sequences
pub const ANSI_RED: &str = "\x1b[31m";
pub const ANSI_GREEN: &str = "\x1b[32m"; // the color of type checker mode
pub const ANSI_CYAN: &str = "\x1b[36m";
// pub const ANSI_BRIGHT_GREEN: &str = "\x1b[92m";
pub const ANSI_BRIGHT_BLUE: &str = "\x1b[94m";
pub const ANSI_BRIGHT_MAGENTA: &str = "\x1b[95m";
// const ANSI_BRIGHT_CYAN: &str = "\x1b[96m";
pub const ANSI_RESET: &str = "\x1b[0m";
pub const ANSI_OUTPUT: &str = "\x1b[38;5;117m";
pub const ANSI_CLEAR_LINES: &str = "\x1b[G\x1b[J";
}
pub mod args {
use crate::tools::is_terminal;
use argh::FromArgs;
use std::{path::PathBuf, str::FromStr};
/// The Conlang prototype debug interface
#[derive(Clone, Debug, FromArgs, PartialEq, Eq, PartialOrd, Ord)]
pub struct Args {
/// the main source file
#[argh(positional)]
pub file: Option<PathBuf>,
/// files to include
#[argh(option, short = 'I')]
pub include: Vec<PathBuf>,
/// the Repl mode to start in
#[argh(option, short = 'm', default = "Default::default()")]
pub mode: Mode,
/// whether to start the repl (`true` or `false`)
#[argh(option, short = 'r', default = "is_terminal()")]
pub repl: bool,
}
/// The CLI's operating mode
#[derive(Clone, Copy, Debug, Default, PartialEq, Eq, PartialOrd, Ord)]
pub enum Mode {
Tokenize,
Beautify,
#[default]
Interpret,
}
impl Mode {
pub fn ansi_color(self) -> &'static str {
use super::ansi::*;
match self {
Mode::Tokenize => ANSI_BRIGHT_BLUE,
Mode::Beautify => ANSI_BRIGHT_MAGENTA,
Mode::Interpret => ANSI_CYAN,
}
}
}
impl FromStr for Mode {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
Ok(match s {
"i" | "interpret" | "r" | "run" => Mode::Interpret,
"b" | "beautify" | "p" | "pretty" => Mode::Beautify,
"t" | "tokenize" | "token" => Mode::Tokenize,
_ => Err("Recognized modes are: 'r' \"run\", 'p' \"pretty\", 't' \"token\"")?,
})
}
}
}
pub mod program {
use cl_ast::ast;
use cl_interpret::{
env::Environment, error::IResult, interpret::Interpret, temp_type_impl::ConValue,
};
use cl_lexer::Lexer;
use cl_parser::{error::PResult, Parser};
use std::fmt::Display;
pub struct Parsable;
pub enum Parsed {
File(ast::File),
Stmt(ast::Stmt),
}
pub struct Program<'t, Variant> {
text: &'t str,
data: Variant,
}
impl<'t, V> Program<'t, V> {
pub fn lex(&self) -> Lexer {
Lexer::new(self.text)
}
}
impl<'t> Program<'t, Parsable> {
pub fn new(text: &'t str) -> Self {
Self { text, data: Parsable }
}
pub fn parse(self) -> PResult<Program<'t, Parsed>> {
self.parse_file().or_else(|_| self.parse_stmt())
}
pub fn parse_stmt(&self) -> PResult<Program<'t, Parsed>> {
let stmt = Parser::new(self.lex()).stmt()?;
// let stmt = WhileElseDesugar.fold_stmt(stmt);
Ok(Program { data: Parsed::Stmt(stmt), text: self.text })
}
pub fn parse_file(&self) -> PResult<Program<'t, Parsed>> {
let file = Parser::new(self.lex()).file()?;
// let file = WhileElseDesugar.fold_file(file);
Ok(Program { data: Parsed::File(file), text: self.text })
}
}
impl<'t> Program<'t, Parsed> {
pub fn debug(&self) {
match &self.data {
Parsed::File(v) => eprintln!("{v:?}"),
Parsed::Stmt(v) => eprintln!("{v:?}"),
}
}
pub fn print(&self) {
match &self.data {
Parsed::File(v) => println!("{v}"),
Parsed::Stmt(v) => println!("{v}"),
};
}
pub fn run(&self, env: &mut Environment) -> IResult<ConValue> {
match &self.data {
Parsed::File(v) => v.interpret(env),
Parsed::Stmt(v) => v.interpret(env),
}
}
}
impl<'t> Display for Program<'t, Parsed> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match &self.data {
Parsed::File(v) => write!(f, "{v}"),
Parsed::Stmt(v) => write!(f, "{v}"),
}
}
}
}
pub mod cli {
//! Implement's the command line interface
use crate::{
args::{Args, Mode},
program::{Parsable, Program},
repl::Repl,
tools::print_token,
};
use cl_interpret::{env::Environment, temp_type_impl::ConValue};
use cl_lexer::Lexer;
use cl_parser::Parser;
use std::{error::Error, path::Path};
/// Run the command line interface
pub fn run(args: Args) -> Result<(), Box<dyn Error>> {
let Args { file, include, mode, repl } = args;
let mut env = Environment::new();
for path in include {
load_file(&mut env, path)?;
}
if repl {
if let Some(file) = file {
load_file(&mut env, file)?;
}
Repl::with_env(mode, env).repl()
} else {
let code = match &file {
Some(file) => std::fs::read_to_string(file)?,
None => std::io::read_to_string(std::io::stdin())?,
};
let code = Program::new(&code);
match mode {
Mode::Tokenize => tokenize(code, file),
Mode::Beautify => beautify(code),
Mode::Interpret => interpret(code, &mut env),
}?;
}
Ok(())
}
fn load_file(
env: &mut Environment,
path: impl AsRef<Path>,
) -> Result<ConValue, Box<dyn Error>> {
let file = std::fs::read_to_string(path)?;
let code = Parser::new(Lexer::new(&file)).file()?;
env.eval(&code).map_err(Into::into)
}
fn tokenize(
code: Program<Parsable>,
path: Option<impl AsRef<Path>>,
) -> Result<(), Box<dyn Error>> {
for token in code.lex() {
if let Some(ref path) = path {
print!("{}:", path.as_ref().display());
}
match token {
Ok(token) => print_token(&token),
Err(e) => println!("{e}"),
}
}
Ok(())
}
fn beautify(code: Program<Parsable>) -> Result<(), Box<dyn Error>> {
code.parse()?.print();
Ok(())
}
fn interpret(code: Program<Parsable>, env: &mut Environment) -> Result<(), Box<dyn Error>> {
match code.parse()?.run(env)? {
ConValue::Empty => {}
ret => println!("{ret}"),
}
if env.get("main").is_ok() {
match env.call("main", &[])? {
ConValue::Empty => {}
ret => println!("{ret}"),
}
}
Ok(())
}
}
pub mod repl {
use crate::{
ansi::*,
args::Mode,
program::{Parsable, Parsed, Program},
tools::print_token,
};
use cl_interpret::{env::Environment, temp_type_impl::ConValue};
use std::fmt::Display;
/// Implements the interactive interpreter
#[derive(Clone, Debug)]
pub struct Repl {
prompt_again: &'static str, // " ?>"
prompt_begin: &'static str, // "cl>"
prompt_error: &'static str, // "! >"
prompt_succs: &'static str, // " ->"
env: Environment,
mode: Mode,
}
impl Default for Repl {
fn default() -> Self {
Self {
prompt_begin: "cl>",
prompt_again: " ?>",
prompt_error: "! >",
prompt_succs: " =>",
env: Default::default(),
mode: Default::default(),
}
}
}
/// Prompt functions
impl Repl {
pub fn prompt_result<T: Display, E: Display>(&self, res: Result<T, E>) {
match &res {
Ok(v) => self.prompt_succs(v),
Err(e) => self.prompt_error(e),
}
}
pub fn prompt_error(&self, err: &impl Display) {
let Self { prompt_error: prompt, .. } = self;
println!("{ANSI_CLEAR_LINES}{ANSI_RED}{prompt} {err}{ANSI_RESET}")
}
pub fn prompt_succs(&self, value: &impl Display) {
let Self { prompt_succs: _prompt, .. } = self;
println!("{ANSI_GREEN}{value}{ANSI_RESET}")
}
/// Resets the cursor to the start of the line, clears the terminal,
/// and sets the output color
pub fn begin_output(&self) {
print!("{ANSI_CLEAR_LINES}{ANSI_OUTPUT}")
}
pub fn clear_line(&self) {}
}
/// The actual REPL
impl Repl {
/// Constructs a new [Repl] with the provided [Mode]
pub fn new(mode: Mode) -> Self {
Self { mode, ..Default::default() }
}
/// Constructs a new [Repl] with the provided [Mode] and [Environment]
pub fn with_env(mode: Mode, env: Environment) -> Self {
Self { mode, env, ..Default::default() }
}
/// Runs the main REPL loop
pub fn repl(&mut self) {
use crate::repline::{error::Error, Repline};
let mut rl = Repline::new(self.mode.ansi_color(), self.prompt_begin, self.prompt_again);
fn clear_line() {
print!("\x1b[G\x1b[J");
}
loop {
let buf = match rl.read() {
Ok(buf) => buf,
// Ctrl-C: break if current line is empty
Err(Error::CtrlC(buf)) => {
if buf.is_empty() || buf.ends_with('\n') {
return;
}
rl.accept();
println!("Cancelled. (Press Ctrl+C again to quit.)");
continue;
}
// Ctrl-D: reset input, and parse it for errors
Err(Error::CtrlD(buf)) => {
rl.deny();
if let Err(e) = Program::new(&buf).parse() {
clear_line();
self.prompt_error(&e);
}
continue;
}
Err(e) => {
self.prompt_error(&e);
return;
}
};
self.begin_output();
if self.command(&buf) {
rl.deny();
rl.set_color(self.mode.ansi_color());
continue;
}
let code = Program::new(&buf);
if self.mode == Mode::Tokenize {
self.tokenize(&code);
rl.deny();
continue;
}
match code.lex().into_iter().find(|l| l.is_err()) {
None => {}
Some(Ok(_)) => unreachable!(),
Some(Err(error)) => {
rl.deny();
self.prompt_error(&error);
continue;
}
}
if let Ok(mut code) = code.parse() {
rl.accept();
self.dispatch(&mut code);
}
}
}
fn help(&self) {
println!(
"Commands:\n- $tokens\n Tokenize Mode:\n Outputs information derived by the Lexer\n- $pretty\n Beautify Mode:\n Pretty-prints the input\n- $run\n Interpret Mode:\n Interprets the input using Conlang\'s work-in-progress interpreter\n- $mode\n Prints the current mode\n- $help\n Prints this help message"
);
}
fn command(&mut self, line: &str) -> bool {
let Some(line) = line.trim().strip_prefix('$') else {
return false;
};
if let Ok(mode) = line.parse() {
self.mode = mode;
} else {
match line {
"$run" => self.mode = Mode::Interpret,
"mode" => println!("{:?} Mode", self.mode),
"help" => self.help(),
_ => return false,
}
}
true
}
/// Dispatches calls to repl functions based on the program
fn dispatch(&mut self, code: &mut Program<Parsed>) {
match self.mode {
Mode::Tokenize => {}
Mode::Beautify => self.beautify(code),
Mode::Interpret => self.interpret(code),
}
}
fn tokenize(&mut self, code: &Program<Parsable>) {
for token in code.lex() {
match token {
Ok(token) => print_token(&token),
Err(e) => println!("{e}"),
}
}
}
fn interpret(&mut self, code: &Program<Parsed>) {
match code.run(&mut self.env) {
Ok(ConValue::Empty) => {}
res => self.prompt_result(res),
}
}
fn beautify(&mut self, code: &Program<Parsed>) {
code.print()
}
}
}
pub mod tools {
use cl_token::Token;
use std::io::IsTerminal;
/// Prints a token in the particular way cl-repl does
pub fn print_token(t: &Token) {
println!(
"{:02}:{:02}: {:#19} │{}│",
t.line(),
t.col(),
t.ty(),
t.data(),
)
}
/// gets whether stdin AND stdout are a terminal, for pipelining
pub fn is_terminal() -> bool {
std::io::stdin().is_terminal() && std::io::stdout().is_terminal()
}
}
pub mod repline;
pub mod ansi;
pub mod args;
pub mod cli;
pub mod ctx;
pub mod menu;
pub mod tools;

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use crate::{ansi, ctx};
use cl_lexer::Lexer;
use cl_parser::Parser;
use repline::{error::ReplResult, prebaked::*};
fn clear() {
println!("{}", ansi::CLEAR_ALL);
banner()
}
pub fn banner() {
println!("--- conlang v{} 💪🦈 ---\n", env!("CARGO_PKG_VERSION"))
}
/// Presents a selection interface to the user
pub fn main_menu(ctx: &mut ctx::Context) -> ReplResult<()> {
banner();
read_and(ansi::GREEN, "mu>", " ?>", |line| {
match line.trim() {
"clear" => clear(),
"l" | "lex" => lex(ctx)?,
"f" | "fmt" => fmt(ctx)?,
"r" | "run" => run(ctx)?,
"q" | "quit" => return Ok(Response::Break),
"h" | "help" => println!(
"Valid commands
lex (l): Spin up a lexer, and lex some lines
fmt (f): Format the input
run (r): Enter the REPL, and evaluate some statements
help (h): Print this list
quit (q): Exit the program"
),
_ => Err("Unknown command. Type \"help\" for help")?,
}
Ok(Response::Accept)
})
}
pub fn run(ctx: &mut ctx::Context) -> ReplResult<()> {
read_and(ansi::CYAN, "cl>", " ?>", |line| {
let code = Parser::new(Lexer::new(line)).stmt()?;
print!("{}", ansi::OUTPUT);
match ctx.run(&code) {
Ok(v) => println!("{}{v}", ansi::RESET),
Err(e) => println!("{}! > {e}{}", ansi::RED, ansi::RESET),
}
Ok(Response::Accept)
})
}
pub fn lex(_ctx: &mut ctx::Context) -> ReplResult<()> {
read_and(ansi::BRIGHT_BLUE, "lx>", " ?>", |line| {
for token in Lexer::new(line) {
match token {
Ok(token) => crate::tools::print_token(&token),
Err(e) => eprintln!("! > {}{e}{}", ansi::RED, ansi::RESET),
}
}
Ok(Response::Accept)
})
}
pub fn fmt(_ctx: &mut ctx::Context) -> ReplResult<()> {
read_and(ansi::BRIGHT_MAGENTA, "cl>", " ?>", |line| {
let mut p = Parser::new(Lexer::new(line));
match p.stmt() {
Ok(code) => println!("{}{code}{}", ansi::OUTPUT, ansi::RESET),
Err(e) => Err(e)?,
}
Ok(Response::Accept)
})
}

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@ -1,607 +0,0 @@
//! A small pseudo-multiline editing library
// #![allow(unused)]
pub mod error {
/// Result type for Repline
pub type ReplResult<T> = std::result::Result<T, Error>;
/// Borrowed error (does not implement [Error](std::error::Error)!)
#[derive(Debug)]
pub enum Error {
/// User broke with Ctrl+C
CtrlC(String),
/// User broke with Ctrl+D
CtrlD(String),
/// Invalid unicode codepoint
BadUnicode(u32),
/// Error came from [std::io]
IoFailure(std::io::Error),
/// End of input
EndOfInput,
}
impl std::error::Error for Error {}
impl std::fmt::Display for Error {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
Error::CtrlC(_) => write!(f, "Ctrl+C"),
Error::CtrlD(_) => write!(f, "Ctrl+D"),
Error::BadUnicode(u) => write!(f, "0x{u:x} is not a valid unicode codepoint"),
Error::IoFailure(s) => write!(f, "{s}"),
Error::EndOfInput => write!(f, "End of input"),
}
}
}
impl From<std::io::Error> for Error {
fn from(value: std::io::Error) -> Self {
Self::IoFailure(value)
}
}
}
pub mod chars {
//! Converts an <code>[Iterator]<Item = [u8]></code> into an
//! <code>[Iterator]<Item = [char]></code>
use super::error::*;
/// Converts an <code>[Iterator]<Item = [u8]></code> into an
/// <code>[Iterator]<Item = [char]></code>
#[derive(Clone, Debug)]
pub struct Chars<I: Iterator<Item = u8>>(pub I);
impl<I: Iterator<Item = u8>> Chars<I> {
pub fn new(bytes: I) -> Self {
Self(bytes)
}
}
impl<I: Iterator<Item = u8>> Iterator for Chars<I> {
type Item = ReplResult<char>;
fn next(&mut self) -> Option<Self::Item> {
let Self(bytes) = self;
let start = bytes.next()? as u32;
let (mut out, count) = match start {
start if start & 0x80 == 0x00 => (start, 0), // ASCII valid range
start if start & 0xe0 == 0xc0 => (start & 0x1f, 1), // 1 continuation byte
start if start & 0xf0 == 0xe0 => (start & 0x0f, 2), // 2 continuation bytes
start if start & 0xf8 == 0xf0 => (start & 0x07, 3), // 3 continuation bytes
_ => return None,
};
for _ in 0..count {
let cont = bytes.next()? as u32;
if cont & 0xc0 != 0x80 {
return None;
}
out = out << 6 | (cont & 0x3f);
}
Some(char::from_u32(out).ok_or(Error::BadUnicode(out)))
}
}
}
pub mod flatten {
//! Flattens an [Iterator] returning [`Result<T, E>`](Result) or [`Option<T>`](Option)
//! into a *non-[FusedIterator](std::iter::FusedIterator)* over `T`
/// Flattens an [Iterator] returning [`Result<T, E>`](Result) or [`Option<T>`](Option)
/// into a *non-[FusedIterator](std::iter::FusedIterator)* over `T`
pub struct Flatten<T, I: Iterator<Item = T>>(pub I);
impl<T, E, I: Iterator<Item = Result<T, E>>> Iterator for Flatten<Result<T, E>, I> {
type Item = T;
fn next(&mut self) -> Option<Self::Item> {
self.0.next()?.ok()
}
}
impl<T, I: Iterator<Item = Option<T>>> Iterator for Flatten<Option<T>, I> {
type Item = T;
fn next(&mut self) -> Option<Self::Item> {
self.0.next()?
}
}
}
pub mod raw {
//! Sets the terminal to [`raw`] mode for the duration of the returned object's lifetime.
/// Sets the terminal to raw mode for the duration of the returned object's lifetime.
pub fn raw() -> impl Drop {
Raw::default()
}
struct Raw();
impl Default for Raw {
fn default() -> Self {
std::thread::yield_now();
crossterm::terminal::enable_raw_mode()
.expect("should be able to transition into raw mode");
Raw()
}
}
impl Drop for Raw {
fn drop(&mut self) {
crossterm::terminal::disable_raw_mode()
.expect("should be able to transition out of raw mode");
// std::thread::yield_now();
}
}
}
mod out {
#![allow(unused)]
use std::io::{Result, Write};
/// A [Writer](Write) that flushes after every wipe
#[derive(Clone, Debug)]
pub(super) struct EagerWriter<W: Write> {
out: W,
}
impl<W: Write> EagerWriter<W> {
pub fn new(writer: W) -> Self {
Self { out: writer }
}
}
impl<W: Write> Write for EagerWriter<W> {
fn write(&mut self, buf: &[u8]) -> Result<usize> {
let out = self.out.write(buf)?;
self.out.flush()?;
Ok(out)
}
fn flush(&mut self) -> Result<()> {
self.out.flush()
}
}
}
use self::{chars::Chars, editor::Editor, error::*, flatten::Flatten, raw::raw};
use std::{
collections::VecDeque,
io::{stdout, Bytes, Read, Result, Write},
};
pub struct Repline<'a, R: Read> {
input: Chars<Flatten<Result<u8>, Bytes<R>>>,
history: VecDeque<String>, // previous lines
hindex: usize, // current index into the history buffer
ed: Editor<'a>, // the current line buffer
}
impl<'a, R: Read> Repline<'a, R> {
/// Constructs a [Repline] with the given [Reader](Read), color, begin, and again prompts.
pub fn with_input(input: R, color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self {
input: Chars(Flatten(input.bytes())),
history: Default::default(),
hindex: 0,
ed: Editor::new(color, begin, again),
}
}
/// Set the terminal prompt color
pub fn set_color(&mut self, color: &'a str) {
self.ed.color = color
}
/// Reads in a line, and returns it for validation
pub fn read(&mut self) -> ReplResult<String> {
const INDENT: &str = " ";
let mut stdout = stdout().lock();
let stdout = &mut stdout;
let _make_raw = raw();
// self.ed.begin_frame(stdout)?;
// self.ed.redraw_frame(stdout)?;
self.ed.print_head(stdout)?;
loop {
stdout.flush()?;
match self.input.next().ok_or(Error::EndOfInput)?? {
// Ctrl+C: End of Text. Immediately exits.
// Ctrl+D: End of Transmission. Ends the current line.
'\x03' => {
drop(_make_raw);
writeln!(stdout)?;
return Err(Error::CtrlC(self.ed.to_string()));
}
'\x04' => {
drop(_make_raw);
writeln!(stdout)?;
return Err(Error::CtrlD(self.ed.to_string()));
}
// Tab: extend line by 4 spaces
'\t' => {
self.ed.extend(INDENT.chars(), stdout)?;
}
// ignore newlines, process line feeds. Not sure how cross-platform this is.
'\n' => {}
'\r' => {
self.ed.push('\n', stdout)?;
return Ok(self.ed.to_string());
}
// Ctrl+Backspace in my terminal
'\x17' => {
self.ed.erase_word(stdout)?;
}
// Escape sequence
'\x1b' => self.escape(stdout)?,
// backspace
'\x08' | '\x7f' => {
let ed = &mut self.ed;
if ed.ends_with(INDENT.chars()) {
for _ in 0..INDENT.len() {
ed.pop(stdout)?;
}
} else {
ed.pop(stdout)?;
}
}
c if c.is_ascii_control() => {
if cfg!(debug_assertions) {
self.ed.extend(c.escape_debug(), stdout)?;
}
}
c => {
self.ed.push(c, stdout)?;
}
}
}
}
/// Handle ANSI Escape
fn escape<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
match self.input.next().ok_or(Error::EndOfInput)?? {
'[' => self.csi(w)?,
'O' => todo!("Process alternate character mode"),
other => self.ed.extend(other.escape_debug(), w)?,
}
Ok(())
}
/// Handle ANSI Control Sequence Introducer
fn csi<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
match self.input.next().ok_or(Error::EndOfInput)?? {
'A' => {
self.hindex = self.hindex.saturating_sub(1);
self.restore_history(w)?
}
'B' => {
self.hindex = self.hindex.saturating_add(1).min(self.history.len());
self.restore_history(w)?
}
'C' => self.ed.cursor_forward(1, w)?,
'D' => self.ed.cursor_back(1, w)?,
'H' => self.ed.home(w)?,
'F' => self.ed.end(w)?,
'3' => {
if let '~' = self.input.next().ok_or(Error::EndOfInput)?? {
let _ = self.ed.delete(w);
}
}
other => {
if cfg!(debug_assertions) {
self.ed.extend(other.escape_debug(), w)?;
}
}
}
Ok(())
}
/// Restores the currently selected history
pub fn restore_history<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
let Self { history, hindex, ed, .. } = self;
ed.undraw(w)?;
ed.clear();
ed.print_head(w)?;
if let Some(history) = history.get(*hindex) {
ed.extend(history.chars(), w)?
}
Ok(())
}
/// Append line to history and clear it
pub fn accept(&mut self) {
self.history_append(self.ed.iter().collect());
self.ed.clear();
self.hindex = self.history.len();
}
/// Append line to history
pub fn history_append(&mut self, mut buf: String) {
while buf.ends_with(char::is_whitespace) {
buf.pop();
}
if !self.history.contains(&buf) {
self.history.push_back(buf)
}
while self.history.len() > 20 {
self.history.pop_front();
}
}
/// Clear the line
pub fn deny(&mut self) {
self.ed.clear()
}
}
impl<'a> Repline<'a, std::io::Stdin> {
pub fn new(color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self::with_input(std::io::stdin(), color, begin, again)
}
}
pub mod editor {
use crossterm::{cursor::*, execute, queue, style::*, terminal::*};
use std::{collections::VecDeque, fmt::Display, io::Write};
use super::error::{Error, ReplResult};
fn is_newline(c: &char) -> bool {
*c == '\n'
}
fn write_chars<'a, W: Write>(
c: impl IntoIterator<Item = &'a char>,
w: &mut W,
) -> std::io::Result<()> {
for c in c {
write!(w, "{c}")?;
}
Ok(())
}
#[derive(Debug)]
pub struct Editor<'a> {
head: VecDeque<char>,
tail: VecDeque<char>,
pub color: &'a str,
begin: &'a str,
again: &'a str,
}
impl<'a> Editor<'a> {
pub fn new(color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self { head: Default::default(), tail: Default::default(), color, begin, again }
}
pub fn iter(&self) -> impl Iterator<Item = &char> {
self.head.iter()
}
pub fn undraw<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, .. } = self;
match head.iter().copied().filter(is_newline).count() {
0 => write!(w, "\x1b[0G"),
lines => write!(w, "\x1b[{}F", lines),
}?;
queue!(w, Clear(ClearType::FromCursorDown))?;
// write!(w, "\x1b[0J")?;
Ok(())
}
pub fn redraw<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, tail, color, begin, again } = self;
write!(w, "{color}{begin}\x1b[0m ")?;
// draw head
for c in head {
match c {
'\n' => write!(w, "\r\n{color}{again}\x1b[0m "),
_ => w.write_all({ *c as u32 }.to_le_bytes().as_slice()),
}?
}
// save cursor
execute!(w, SavePosition)?;
// draw tail
for c in tail {
match c {
'\n' => write!(w, "\r\n{color}{again}\x1b[0m "),
_ => write!(w, "{c}"),
}?
}
// restore cursor
execute!(w, RestorePosition)?;
Ok(())
}
pub fn prompt<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, color, begin, again, .. } = self;
queue!(
w,
MoveToColumn(0),
Print(color),
Print(if head.is_empty() { begin } else { again }),
ResetColor,
Print(' '),
)?;
Ok(())
}
pub fn print_head<W: Write>(&self, w: &mut W) -> ReplResult<()> {
self.prompt(w)?;
write_chars(
self.head.iter().skip(
self.head
.iter()
.rposition(is_newline)
.unwrap_or(self.head.len())
+ 1,
),
w,
)?;
Ok(())
}
pub fn print_tail<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { tail, .. } = self;
queue!(w, SavePosition, Clear(ClearType::UntilNewLine))?;
write_chars(tail.iter().take_while(|&c| !is_newline(c)), w)?;
queue!(w, RestorePosition)?;
Ok(())
}
pub fn push<W: Write>(&mut self, c: char, w: &mut W) -> ReplResult<()> {
// Tail optimization: if the tail is empty,
//we don't have to undraw and redraw on newline
if self.tail.is_empty() {
self.head.push_back(c);
match c {
'\n' => {
write!(w, "\r\n")?;
self.print_head(w)?;
}
c => {
queue!(w, Print(c))?;
}
};
return Ok(());
}
if '\n' == c {
self.undraw(w)?;
}
self.head.push_back(c);
match c {
'\n' => self.redraw(w)?,
_ => {
write!(w, "{c}")?;
self.print_tail(w)?;
}
}
Ok(())
}
pub fn pop<W: Write>(&mut self, w: &mut W) -> ReplResult<Option<char>> {
if let Some('\n') = self.head.back() {
self.undraw(w)?;
}
let c = self.head.pop_back();
// if the character was a newline, we need to go back a line
match c {
Some('\n') => self.redraw(w)?,
Some(_) => {
// go back a char
queue!(w, MoveLeft(1), Print(' '), MoveLeft(1))?;
self.print_tail(w)?;
}
None => {}
}
Ok(c)
}
pub fn extend<T: IntoIterator<Item = char>, W: Write>(
&mut self,
iter: T,
w: &mut W,
) -> ReplResult<()> {
for c in iter {
self.push(c, w)?;
}
Ok(())
}
pub fn restore(&mut self, s: &str) {
self.clear();
self.head.extend(s.chars())
}
pub fn clear(&mut self) {
self.head.clear();
self.tail.clear();
}
pub fn delete<W: Write>(&mut self, w: &mut W) -> ReplResult<char> {
match self.tail.front() {
Some('\n') => {
self.undraw(w)?;
let out = self.tail.pop_front();
self.redraw(w)?;
out
}
_ => {
let out = self.tail.pop_front();
self.print_tail(w)?;
out
}
}
.ok_or(Error::EndOfInput)
}
pub fn erase_word<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
while self.pop(w)?.filter(|c| !c.is_whitespace()).is_some() {}
Ok(())
}
pub fn len(&self) -> usize {
self.head.len() + self.tail.len()
}
pub fn is_empty(&self) -> bool {
self.head.is_empty() && self.tail.is_empty()
}
pub fn ends_with(&self, iter: impl DoubleEndedIterator<Item = char>) -> bool {
let mut iter = iter.rev();
let mut head = self.head.iter().rev();
loop {
match (iter.next(), head.next()) {
(None, _) => break true,
(Some(_), None) => break false,
(Some(a), Some(b)) if a != *b => break false,
(Some(_), Some(_)) => continue,
}
}
}
/// Moves the cursor back `steps` steps
pub fn cursor_back<W: Write>(&mut self, steps: usize, w: &mut W) -> ReplResult<()> {
for _ in 0..steps {
if let Some('\n') = self.head.back() {
self.undraw(w)?;
}
let Some(c) = self.head.pop_back() else {
return Ok(());
};
self.tail.push_front(c);
match c {
'\n' => self.redraw(w)?,
_ => queue!(w, MoveLeft(1))?,
}
}
Ok(())
}
/// Moves the cursor forward `steps` steps
pub fn cursor_forward<W: Write>(&mut self, steps: usize, w: &mut W) -> ReplResult<()> {
for _ in 0..steps {
if let Some('\n') = self.tail.front() {
self.undraw(w)?
}
let Some(c) = self.tail.pop_front() else {
return Ok(());
};
self.head.push_back(c);
match c {
'\n' => self.redraw(w)?,
_ => queue!(w, MoveRight(1))?,
}
}
Ok(())
}
/// Goes to the beginning of the current line
pub fn home<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
loop {
match self.head.back() {
Some('\n') | None => break Ok(()),
Some(_) => self.cursor_back(1, w)?,
}
}
}
/// Goes to the end of the current line
pub fn end<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
loop {
match self.tail.front() {
Some('\n') | None => break Ok(()),
Some(_) => self.cursor_forward(1, w)?,
}
}
}
}
impl<'a, 'e> IntoIterator for &'e Editor<'a> {
type Item = &'e char;
type IntoIter = std::iter::Chain<
std::collections::vec_deque::Iter<'e, char>,
std::collections::vec_deque::Iter<'e, char>,
>;
fn into_iter(self) -> Self::IntoIter {
self.head.iter().chain(self.tail.iter())
}
}
impl<'a> Display for Editor<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
use std::fmt::Write;
let Self { head, tail, .. } = self;
for c in head {
f.write_char(*c)?;
}
for c in tail {
f.write_char(*c)?;
}
Ok(())
}
}
}

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use cl_token::Token;
/// Prints a token in the particular way [cl-repl](crate) does
pub fn print_token(t: &Token) {
println!(
"{:02}:{:02}: {:#19} │{}│",
t.line(),
t.col(),
t.ty(),
t.data(),
)
}

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[package]
name = "repline"
repository.workspace = true
version.workspace = true
authors.workspace = true
edition.workspace = true
license.workspace = true
publish.workspace = true
[dependencies]
crossterm = "0.27.0"

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//! The [Editor]
use crossterm::{cursor::*, execute, queue, style::*, terminal::*};
use std::{collections::VecDeque, fmt::Display, io::Write};
use super::error::{Error, ReplResult};
fn is_newline(c: &char) -> bool {
*c == '\n'
}
fn write_chars<'a, W: Write>(
c: impl IntoIterator<Item = &'a char>,
w: &mut W,
) -> std::io::Result<()> {
for c in c {
write!(w, "{c}")?;
}
Ok(())
}
#[derive(Clone, Debug)]
pub struct Editor<'a> {
head: VecDeque<char>,
tail: VecDeque<char>,
pub color: &'a str,
begin: &'a str,
again: &'a str,
}
impl<'a> Editor<'a> {
pub fn new(color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self { head: Default::default(), tail: Default::default(), color, begin, again }
}
pub fn iter(&self) -> impl Iterator<Item = &char> {
let Self { head, tail, .. } = self;
head.iter().chain(tail.iter())
}
pub fn undraw<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, .. } = self;
match head.iter().copied().filter(is_newline).count() {
0 => write!(w, "\x1b[0G"),
lines => write!(w, "\x1b[{}F", lines),
}?;
queue!(w, Clear(ClearType::FromCursorDown))?;
// write!(w, "\x1b[0J")?;
Ok(())
}
pub fn redraw<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, tail, color, begin, again } = self;
write!(w, "{color}{begin}\x1b[0m ")?;
// draw head
for c in head {
match c {
'\n' => write!(w, "\r\n{color}{again}\x1b[0m "),
_ => w.write_all({ *c as u32 }.to_le_bytes().as_slice()),
}?
}
// save cursor
execute!(w, SavePosition)?;
// draw tail
for c in tail {
match c {
'\n' => write!(w, "\r\n{color}{again}\x1b[0m "),
_ => write!(w, "{c}"),
}?
}
// restore cursor
execute!(w, RestorePosition)?;
Ok(())
}
pub fn prompt<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { head, color, begin, again, .. } = self;
queue!(
w,
MoveToColumn(0),
Print(color),
Print(if head.is_empty() { begin } else { again }),
ResetColor,
Print(' '),
)?;
Ok(())
}
pub fn print_head<W: Write>(&self, w: &mut W) -> ReplResult<()> {
self.prompt(w)?;
write_chars(
self.head.iter().skip(
self.head
.iter()
.rposition(is_newline)
.unwrap_or(self.head.len())
+ 1,
),
w,
)?;
Ok(())
}
pub fn print_tail<W: Write>(&self, w: &mut W) -> ReplResult<()> {
let Self { tail, .. } = self;
queue!(w, SavePosition, Clear(ClearType::UntilNewLine))?;
write_chars(tail.iter().take_while(|&c| !is_newline(c)), w)?;
queue!(w, RestorePosition)?;
Ok(())
}
pub fn push<W: Write>(&mut self, c: char, w: &mut W) -> ReplResult<()> {
// Tail optimization: if the tail is empty,
//we don't have to undraw and redraw on newline
if self.tail.is_empty() {
self.head.push_back(c);
match c {
'\n' => {
write!(w, "\r\n")?;
self.print_head(w)?;
}
c => {
queue!(w, Print(c))?;
}
};
return Ok(());
}
if '\n' == c {
self.undraw(w)?;
}
self.head.push_back(c);
match c {
'\n' => self.redraw(w)?,
_ => {
write!(w, "{c}")?;
self.print_tail(w)?;
}
}
Ok(())
}
pub fn pop<W: Write>(&mut self, w: &mut W) -> ReplResult<Option<char>> {
if let Some('\n') = self.head.back() {
self.undraw(w)?;
}
let c = self.head.pop_back();
// if the character was a newline, we need to go back a line
match c {
Some('\n') => self.redraw(w)?,
Some(_) => {
// go back a char
queue!(w, MoveLeft(1), Print(' '), MoveLeft(1))?;
self.print_tail(w)?;
}
None => {}
}
Ok(c)
}
pub fn extend<T: IntoIterator<Item = char>, W: Write>(
&mut self,
iter: T,
w: &mut W,
) -> ReplResult<()> {
for c in iter {
self.push(c, w)?;
}
Ok(())
}
pub fn restore(&mut self, s: &str) {
self.clear();
self.head.extend(s.chars())
}
pub fn clear(&mut self) {
self.head.clear();
self.tail.clear();
}
pub fn delete<W: Write>(&mut self, w: &mut W) -> ReplResult<char> {
match self.tail.front() {
Some('\n') => {
self.undraw(w)?;
let out = self.tail.pop_front();
self.redraw(w)?;
out
}
_ => {
let out = self.tail.pop_front();
self.print_tail(w)?;
out
}
}
.ok_or(Error::EndOfInput)
}
pub fn erase_word<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
while self.pop(w)?.filter(|c| !c.is_whitespace()).is_some() {}
Ok(())
}
pub fn len(&self) -> usize {
self.head.len() + self.tail.len()
}
pub fn is_empty(&self) -> bool {
self.head.is_empty() && self.tail.is_empty()
}
pub fn ends_with(&self, iter: impl DoubleEndedIterator<Item = char>) -> bool {
let mut iter = iter.rev();
let mut head = self.head.iter().rev();
loop {
match (iter.next(), head.next()) {
(None, _) => break true,
(Some(_), None) => break false,
(Some(a), Some(b)) if a != *b => break false,
(Some(_), Some(_)) => continue,
}
}
}
/// Moves the cursor back `steps` steps
pub fn cursor_back<W: Write>(&mut self, steps: usize, w: &mut W) -> ReplResult<()> {
for _ in 0..steps {
if let Some('\n') = self.head.back() {
self.undraw(w)?;
}
let Some(c) = self.head.pop_back() else {
return Ok(());
};
self.tail.push_front(c);
match c {
'\n' => self.redraw(w)?,
_ => queue!(w, MoveLeft(1))?,
}
}
Ok(())
}
/// Moves the cursor forward `steps` steps
pub fn cursor_forward<W: Write>(&mut self, steps: usize, w: &mut W) -> ReplResult<()> {
for _ in 0..steps {
if let Some('\n') = self.tail.front() {
self.undraw(w)?
}
let Some(c) = self.tail.pop_front() else {
return Ok(());
};
self.head.push_back(c);
match c {
'\n' => self.redraw(w)?,
_ => queue!(w, MoveRight(1))?,
}
}
Ok(())
}
/// Goes to the beginning of the current line
pub fn home<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
loop {
match self.head.back() {
Some('\n') | None => break Ok(()),
Some(_) => self.cursor_back(1, w)?,
}
}
}
/// Goes to the end of the current line
pub fn end<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
loop {
match self.tail.front() {
Some('\n') | None => break Ok(()),
Some(_) => self.cursor_forward(1, w)?,
}
}
}
}
impl<'a, 'e> IntoIterator for &'e Editor<'a> {
type Item = &'e char;
type IntoIter = std::iter::Chain<
std::collections::vec_deque::Iter<'e, char>,
std::collections::vec_deque::Iter<'e, char>,
>;
fn into_iter(self) -> Self::IntoIter {
self.head.iter().chain(self.tail.iter())
}
}
impl<'a> Display for Editor<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
use std::fmt::Write;
for c in self.iter() {
f.write_char(*c)?;
}
Ok(())
}
}

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use crate::iter::chars::BadUnicode;
/// Result type for Repline
pub type ReplResult<T> = std::result::Result<T, Error>;
/// Borrowed error (does not implement [Error](std::error::Error)!)
#[derive(Debug)]
pub enum Error {
/// User broke with Ctrl+C
CtrlC(String),
/// User broke with Ctrl+D
CtrlD(String),
/// Invalid unicode codepoint
BadUnicode(u32),
/// Error came from [std::io]
IoFailure(std::io::Error),
/// End of input
EndOfInput,
}
impl std::error::Error for Error {}
impl std::fmt::Display for Error {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
Error::CtrlC(_) => write!(f, "Ctrl+C"),
Error::CtrlD(_) => write!(f, "Ctrl+D"),
Error::BadUnicode(u) => write!(f, "\\u{{{u:x}}} is not a valid unicode codepoint"),
Error::IoFailure(s) => write!(f, "{s}"),
Error::EndOfInput => write!(f, "End of input"),
}
}
}
impl From<std::io::Error> for Error {
fn from(value: std::io::Error) -> Self {
Self::IoFailure(value)
}
}
impl From<BadUnicode> for Error {
fn from(value: BadUnicode) -> Self {
let BadUnicode(code) = value;
Self::BadUnicode(code)
}
}

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//! Shmancy iterator adapters
pub use chars::Chars;
pub use flatten::Flatten;
pub mod chars {
//! Converts an <code>[Iterator]<Item = [u8]></code> into an
//! <code>[Iterator]<Item = [Result]<[char], [BadUnicode]>></code>
/// Invalid unicode codepoint found when iterating over [Chars]
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub struct BadUnicode(pub u32);
impl std::error::Error for BadUnicode {}
impl std::fmt::Display for BadUnicode {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
let Self(code) = self;
write!(f, "Bad unicode: {code}")
}
}
/// Converts an <code>[Iterator]<Item = [u8]></code> into an
/// <code>[Iterator]<Item = [char]></code>
#[derive(Clone, Debug)]
pub struct Chars<I: Iterator<Item = u8>>(pub I);
impl<I: Iterator<Item = u8>> Iterator for Chars<I> {
type Item = Result<char, BadUnicode>;
fn next(&mut self) -> Option<Self::Item> {
let Self(bytes) = self;
let start = bytes.next()? as u32;
let (mut out, count) = match start {
start if start & 0x80 == 0x00 => (start, 0), // ASCII valid range
start if start & 0xe0 == 0xc0 => (start & 0x1f, 1), // 1 continuation byte
start if start & 0xf0 == 0xe0 => (start & 0x0f, 2), // 2 continuation bytes
start if start & 0xf8 == 0xf0 => (start & 0x07, 3), // 3 continuation bytes
_ => return None,
};
for _ in 0..count {
let cont = bytes.next()? as u32;
if cont & 0xc0 != 0x80 {
return None;
}
out = out << 6 | (cont & 0x3f);
}
Some(char::from_u32(out).ok_or(BadUnicode(out)))
}
}
}
pub mod flatten {
//! Flattens an [Iterator] returning [`Result<T, E>`](Result) or [`Option<T>`](Option)
//! into a *non-[FusedIterator](std::iter::FusedIterator)* over `T`
/// Flattens an [Iterator] returning [`Result<T, E>`](Result) or [`Option<T>`](Option)
/// into a *non-[FusedIterator](std::iter::FusedIterator)* over `T`
#[derive(Clone, Debug)]
pub struct Flatten<T, I: Iterator<Item = T>>(pub I);
impl<T, E, I: Iterator<Item = Result<T, E>>> Iterator for Flatten<Result<T, E>, I> {
type Item = T;
fn next(&mut self) -> Option<Self::Item> {
self.0.next()?.ok()
}
}
impl<T, I: Iterator<Item = Option<T>>> Iterator for Flatten<Option<T>, I> {
type Item = T;
fn next(&mut self) -> Option<Self::Item> {
self.0.next()?
}
}
}

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//! A small pseudo-multiline editing library
mod editor;
mod iter;
mod raw;
pub mod error;
pub mod prebaked;
pub mod repline;
pub use error::Error;
pub use prebaked::{read_and, Response};
pub use repline::Repline;

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//! Here's a menu I prepared earlier!
//!
//! Constructs a [Repline] and repeatedly runs the provided closure on the input strings,
//! obeying the closure's [Response].
use std::error::Error;
use crate::{error::Error as RlError, repline::Repline};
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
/// Control codes for the [prebaked menu](read_and)
pub enum Response {
/// Accept the line, and save it to history
Accept,
/// Reject the line, and clear the buffer
Deny,
/// End the loop
Break,
/// Gather more input and try again
Continue,
}
/// Implements a basic menu loop using an embedded [Repline].
///
/// Repeatedly runs the provided closure on the input strings,
/// obeying the closure's [Response].
///
/// Captures and displays all user [Error]s.
///
/// # Keybinds
/// - `Ctrl+C` exits the loop
/// - `Ctrl+D` clears the input, but *runs the closure* with the old input
pub fn read_and<F>(color: &str, begin: &str, again: &str, mut f: F) -> Result<(), RlError>
where F: FnMut(&str) -> Result<Response, Box<dyn Error>> {
let mut rl = Repline::new(color, begin, again);
loop {
let line = match rl.read() {
Err(RlError::CtrlC(_)) => break,
Err(RlError::CtrlD(line)) => {
rl.deny();
line
}
Ok(line) => line,
Err(e) => Err(e)?,
};
print!("\x1b[G\x1b[J");
match f(&line) {
Ok(Response::Accept) => rl.accept(),
Ok(Response::Deny) => rl.deny(),
Ok(Response::Break) => break,
Ok(Response::Continue) => continue,
Err(e) => print!("\x1b[40G\x1b[A\x1bJ\x1b[91m{e}\x1b[0m\x1b[B"),
}
}
Ok(())
}

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//! Sets the terminal to [`raw`] mode for the duration of the returned object's lifetime.
/// Sets the terminal to raw mode for the duration of the returned object's lifetime.
pub fn raw() -> impl Drop {
Raw::default()
}
struct Raw();
impl Default for Raw {
fn default() -> Self {
std::thread::yield_now();
crossterm::terminal::enable_raw_mode()
.expect("should be able to transition into raw mode");
Raw()
}
}
impl Drop for Raw {
fn drop(&mut self) {
crossterm::terminal::disable_raw_mode()
.expect("should be able to transition out of raw mode");
}
}

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//! Prompts the user, reads the lines. Not much more to it than that.
//!
//! This module is in charge of parsing keyboard input and interpreting it for the line editor.
use crate::{editor::Editor, error::*, iter::*, raw::raw};
use std::{
collections::VecDeque,
io::{stdout, Bytes, Read, Result, Write},
};
/// Prompts the user, reads the lines. Not much more to it than that.
#[derive(Debug)]
pub struct Repline<'a, R: Read> {
input: Chars<Flatten<Result<u8>, Bytes<R>>>,
history: VecDeque<String>, // previous lines
hindex: usize, // current index into the history buffer
ed: Editor<'a>, // the current line buffer
}
impl<'a> Repline<'a, std::io::Stdin> {
pub fn new(color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self::with_input(std::io::stdin(), color, begin, again)
}
}
impl<'a, R: Read> Repline<'a, R> {
/// Constructs a [Repline] with the given [Reader](Read), color, begin, and again prompts.
pub fn with_input(input: R, color: &'a str, begin: &'a str, again: &'a str) -> Self {
Self {
input: Chars(Flatten(input.bytes())),
history: Default::default(),
hindex: 0,
ed: Editor::new(color, begin, again),
}
}
/// Set the terminal prompt color
pub fn set_color(&mut self, color: &'a str) {
self.ed.color = color
}
/// Append line to history and clear it
pub fn accept(&mut self) {
self.history_append(self.ed.to_string());
self.ed.clear();
self.hindex = self.history.len();
}
/// Clear the line
pub fn deny(&mut self) {
self.ed.clear()
}
/// Reads in a line, and returns it for validation
pub fn read(&mut self) -> ReplResult<String> {
const INDENT: &str = " ";
let mut stdout = stdout().lock();
let stdout = &mut stdout;
let _make_raw = raw();
// self.ed.begin_frame(stdout)?;
// self.ed.redraw_frame(stdout)?;
self.ed.print_head(stdout)?;
loop {
stdout.flush()?;
match self.input.next().ok_or(Error::EndOfInput)?? {
// Ctrl+C: End of Text. Immediately exits.
'\x03' => {
drop(_make_raw);
writeln!(stdout)?;
return Err(Error::CtrlC(self.ed.to_string()));
}
// Ctrl+D: End of Transmission. Ends the current line.
'\x04' => {
drop(_make_raw);
writeln!(stdout)?;
return Err(Error::CtrlD(self.ed.to_string()));
}
// Tab: extend line by 4 spaces
'\t' => {
self.ed.extend(INDENT.chars(), stdout)?;
}
// ignore newlines, process line feeds. Not sure how cross-platform this is.
'\n' => {}
'\r' => {
self.ed.push('\n', stdout)?;
return Ok(self.ed.to_string());
}
// Ctrl+Backspace in my terminal
'\x17' => {
self.ed.erase_word(stdout)?;
}
// Escape sequence
'\x1b' => self.escape(stdout)?,
// backspace
'\x08' | '\x7f' => {
let ed = &mut self.ed;
if ed.ends_with(INDENT.chars()) {
for _ in 0..INDENT.len() {
ed.pop(stdout)?;
}
} else {
ed.pop(stdout)?;
}
}
c if c.is_ascii_control() => {
if cfg!(debug_assertions) {
self.ed.extend(c.escape_debug(), stdout)?;
}
}
c => {
self.ed.push(c, stdout)?;
}
}
}
}
/// Handle ANSI Escape
fn escape<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
match self.input.next().ok_or(Error::EndOfInput)?? {
'[' => self.csi(w)?,
'O' => todo!("Process alternate character mode"),
other => self.ed.extend(other.escape_debug(), w)?,
}
Ok(())
}
/// Handle ANSI Control Sequence Introducer
fn csi<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
match self.input.next().ok_or(Error::EndOfInput)?? {
'A' => {
self.hindex = self.hindex.saturating_sub(1);
self.restore_history(w)?
}
'B' => {
self.hindex = self.hindex.saturating_add(1).min(self.history.len());
self.restore_history(w)?
}
'C' => self.ed.cursor_forward(1, w)?,
'D' => self.ed.cursor_back(1, w)?,
'H' => self.ed.home(w)?,
'F' => self.ed.end(w)?,
'3' => {
if let '~' = self.input.next().ok_or(Error::EndOfInput)?? {
let _ = self.ed.delete(w);
}
}
other => {
if cfg!(debug_assertions) {
self.ed.extend(other.escape_debug(), w)?;
}
}
}
Ok(())
}
/// Restores the currently selected history
fn restore_history<W: Write>(&mut self, w: &mut W) -> ReplResult<()> {
let Self { history, hindex, ed, .. } = self;
ed.undraw(w)?;
ed.clear();
ed.print_head(w)?;
if let Some(history) = history.get(*hindex) {
ed.extend(history.chars(), w)?
}
Ok(())
}
/// Append line to history
fn history_append(&mut self, mut buf: String) {
while buf.ends_with(char::is_whitespace) {
buf.pop();
}
if !self.history.contains(&buf) {
self.history.push_back(buf)
}
while self.history.len() > 20 {
self.history.pop_front();
}
}
}