holey-bytes/lang/src/fmt.rs
2024-10-13 12:25:12 +02:00

507 lines
17 KiB
Rust

use {
crate::{
ident,
lexer::{self, Lexer, TokenKind},
parser::{self, CommentOr, CtorField, Expr, Poser, Radix, StructField},
},
core::{fmt, usize},
};
pub fn display_radix(radix: Radix, mut value: u64, buf: &mut [u8; 64]) -> &str {
fn conv_radix(d: u8) -> u8 {
match d {
0..=9 => d + b'0',
_ => d - 10 + b'A',
}
}
for (i, b) in buf.iter_mut().enumerate().rev() {
let d = (value % radix as u64) as u8;
value /= radix as u64;
*b = conv_radix(d);
if value == 0 {
return unsafe { core::str::from_utf8_unchecked(&buf[i..]) };
}
}
unreachable!()
}
pub fn minify(source: &mut str) -> usize {
fn needs_space(c: u8) -> bool {
matches!(c, b'a'..=b'z' | b'A'..=b'Z' | b'0'..=b'9' | 127..)
}
let mut writer = source.as_mut_ptr();
let mut reader = &source[..];
let mut prev_needs_whitecpace = false;
let mut prev_needs_newline = false;
loop {
let mut token = lexer::Lexer::new(reader).eat();
match token.kind {
TokenKind::Eof => break,
TokenKind::CtIdent | TokenKind::Directive => token.start -= 1,
_ => {}
}
let cpy_len = token.range().len();
let mut prefix = 0;
if prev_needs_whitecpace && needs_space(reader.as_bytes()[token.start as usize]) {
prefix = b' ';
debug_assert!(token.start != 0, "{reader}");
}
prev_needs_whitecpace = needs_space(reader.as_bytes()[token.end as usize - 1]);
let inbetween_new_lines =
reader[..token.start as usize].bytes().filter(|&b| b == b'\n').count()
+ token.kind.precedence().is_some() as usize;
let extra_prefix_new_lines = if inbetween_new_lines > 1 {
1 + token.kind.precedence().is_none() as usize
} else {
prev_needs_newline as usize
};
if token.kind == TokenKind::Comment && reader.as_bytes()[token.end as usize - 1] != b'/' {
prev_needs_newline = true;
prev_needs_whitecpace = false;
} else {
prev_needs_newline = false;
}
let sstr = reader[token.start as usize..].as_ptr();
reader = &reader[token.end as usize..];
unsafe {
if extra_prefix_new_lines != 0 {
for _ in 0..extra_prefix_new_lines {
writer.write(b'\n');
writer = writer.add(1);
}
} else if prefix != 0 {
writer.write(prefix);
writer = writer.add(1);
}
writer.copy_from(sstr, cpy_len);
writer = writer.add(cpy_len);
}
}
unsafe { writer.sub_ptr(source.as_mut_ptr()) }
}
pub struct Formatter<'a> {
source: &'a str,
depth: usize,
}
// we exclusively use `write_str` to reduce bloat
impl<'a> Formatter<'a> {
pub fn new(source: &'a str) -> Self {
Self { source, depth: 0 }
}
fn fmt_list<T: Poser, F: core::fmt::Write>(
&mut self,
f: &mut F,
trailing: bool,
end: &str,
sep: &str,
list: &[T],
fmt: impl Fn(&mut Self, &T, &mut F) -> fmt::Result,
) -> fmt::Result {
self.fmt_list_low(f, trailing, end, sep, list, |s, v, f| {
fmt(s, v, f)?;
Ok(true)
})
}
fn fmt_list_low<T: Poser, F: core::fmt::Write>(
&mut self,
f: &mut F,
trailing: bool,
end: &str,
sep: &str,
list: &[T],
fmt: impl Fn(&mut Self, &T, &mut F) -> Result<bool, fmt::Error>,
) -> fmt::Result {
if !trailing {
let mut first = true;
for expr in list {
if !core::mem::take(&mut first) {
f.write_str(sep)?;
f.write_str(" ")?;
}
first = !fmt(self, expr, f)?;
}
return f.write_str(end);
}
writeln!(f)?;
self.depth += 1;
let res = (|| {
for (i, stmt) in list.iter().enumerate() {
for _ in 0..self.depth {
f.write_str("\t")?;
}
let add_sep = fmt(self, stmt, f)?;
if add_sep {
f.write_str(sep)?;
}
if let Some(expr) = list.get(i + 1)
&& let Some(rest) = self.source.get(expr.posi() as usize..)
{
if insert_needed_semicolon(rest) {
f.write_str(";")?;
}
if preserve_newlines(&self.source[..expr.posi() as usize]) > 1 {
f.write_str("\n")?;
}
}
if add_sep {
f.write_str("\n")?;
}
}
Ok(())
})();
self.depth -= 1;
for _ in 0..self.depth {
f.write_str("\t")?;
}
f.write_str(end)?;
res
}
fn fmt_paren<F: core::fmt::Write>(
&mut self,
expr: &Expr,
f: &mut F,
cond: impl FnOnce(&Expr) -> bool,
) -> fmt::Result {
if cond(expr) {
f.write_str("(")?;
self.fmt(expr, f)?;
f.write_str(")")
} else {
self.fmt(expr, f)
}
}
pub fn fmt<F: core::fmt::Write>(&mut self, expr: &Expr, f: &mut F) -> fmt::Result {
macro_rules! impl_parenter {
($($name:ident => $pat:pat,)*) => {
$(
let $name = |e: &Expr| matches!(e, $pat);
)*
};
}
impl_parenter! {
unary => Expr::BinOp { .. },
postfix => Expr::UnOp { .. } | Expr::BinOp { .. },
consecutive => Expr::UnOp { .. },
}
match *expr {
Expr::Ct { value, .. } => {
f.write_str("$: ")?;
self.fmt(value, f)
}
Expr::String { literal, .. } => f.write_str(literal),
Expr::Comment { literal, .. } => f.write_str(literal),
Expr::Mod { path, .. } => write!(f, "@use(\"{path}\")"),
Expr::Field { target, name: field, .. } => {
self.fmt_paren(target, f, postfix)?;
f.write_str(".")?;
f.write_str(field)
}
Expr::Directive { name, args, .. } => {
f.write_str("@")?;
f.write_str(name)?;
f.write_str("(")?;
self.fmt_list(f, false, ")", ",", args, Self::fmt)
}
Expr::Struct { fields, trailing_comma, packed, .. } => {
if packed {
f.write_str("packed ")?;
}
write!(f, "struct {{")?;
self.fmt_list_low(f, trailing_comma, "}", ",", fields, |s, field, f| {
match field {
CommentOr::Or(StructField { name, ty, .. }) => {
f.write_str(name)?;
f.write_str(": ")?;
s.fmt(ty, f)?
}
CommentOr::Comment { literal, .. } => {
f.write_str(literal)?;
f.write_str("\n")?;
}
}
Ok(field.or().is_some())
})
}
Expr::Ctor { ty, fields, trailing_comma, .. } => {
if let Some(ty) = ty {
self.fmt_paren(ty, f, unary)?;
}
f.write_str(".{")?;
self.fmt_list(
f,
trailing_comma,
"}",
",",
fields,
|s: &mut Self, CtorField { name, value, .. }: &_, f| {
f.write_str(name)?;
if !matches!(value, &Expr::Ident { id, .. } if *name == &self.source[ident::range(id)]) {
f.write_str(": ")?;
s.fmt(value, f)?;
}
Ok(())
},
)
}
Expr::Tupl { ty, fields, trailing_comma, .. } => {
if let Some(ty) = ty {
self.fmt_paren(ty, f, unary)?;
}
f.write_str(".(")?;
self.fmt_list(f, trailing_comma, ")", ",", fields, Self::fmt)
}
Expr::Slice { item, size, .. } => {
f.write_str("[")?;
self.fmt(item, f)?;
if let Some(size) = size {
f.write_str("; ")?;
self.fmt(size, f)?;
}
f.write_str("]")
}
Expr::Index { base, index } => {
self.fmt(base, f)?;
f.write_str("[")?;
self.fmt(index, f)?;
f.write_str("]")
}
Expr::UnOp { op, val, .. } => {
f.write_str(op.name())?;
self.fmt_paren(val, f, unary)
}
Expr::Break { .. } => f.write_str("break"),
Expr::Continue { .. } => f.write_str("continue"),
Expr::If { cond, then, else_, .. } => {
f.write_str("if ")?;
self.fmt(cond, f)?;
f.write_str(" ")?;
self.fmt_paren(then, f, consecutive)?;
if let Some(e) = else_ {
f.write_str(" else ")?;
self.fmt(e, f)?;
}
Ok(())
}
Expr::Loop { body, .. } => {
f.write_str("loop ")?;
self.fmt(body, f)
}
Expr::Closure { ret, body, args, .. } => {
f.write_str("fn(")?;
self.fmt_list(f, false, "", ",", args, |s, arg, f| {
if arg.is_ct {
f.write_str("$")?;
}
f.write_str(arg.name)?;
f.write_str(": ")?;
s.fmt(&arg.ty, f)
})?;
f.write_str("): ")?;
self.fmt(ret, f)?;
f.write_str(" ")?;
self.fmt_paren(body, f, consecutive)?;
Ok(())
}
Expr::Call { func, args, trailing_comma } => {
self.fmt_paren(func, f, postfix)?;
f.write_str("(")?;
self.fmt_list(f, trailing_comma, ")", ",", args, Self::fmt)
}
Expr::Return { val: Some(val), .. } => {
f.write_str("return ")?;
self.fmt(val, f)
}
Expr::Return { val: None, .. } => f.write_str("return"),
Expr::Ident { pos, is_ct, .. } => {
if is_ct {
f.write_str("$")?;
}
f.write_str(&self.source[Lexer::restore(self.source, pos).eat().range()])
}
Expr::Block { stmts, .. } => {
f.write_str("{")?;
self.fmt_list(f, true, "}", "", stmts, Self::fmt)
}
Expr::Number { value, radix, .. } => {
f.write_str(match radix {
Radix::Decimal => "",
Radix::Hex => "0x",
Radix::Octal => "0o",
Radix::Binary => "0b",
})?;
let mut buf = [0u8; 64];
f.write_str(display_radix(radix, value as u64, &mut buf))
}
Expr::Bool { value, .. } => f.write_str(if value { "true" } else { "false" }),
Expr::Idk { .. } => f.write_str("idk"),
Expr::BinOp {
left,
op: TokenKind::Assign,
right: &Expr::BinOp { left: lleft, op, right },
} if left.pos() == lleft.pos() => {
self.fmt(left, f)?;
f.write_str(" ")?;
f.write_str(op.name())?;
f.write_str("= ")?;
self.fmt(right, f)
}
Expr::BinOp { right, op, left } => {
let pec_miss = |e: &Expr| {
matches!(
e, Expr::BinOp { op: lop, .. } if op.precedence() > lop.precedence()
)
};
self.fmt_paren(left, f, pec_miss)?;
if let Some(mut prev) = self.source.get(..right.pos() as usize) {
prev = prev.trim_end();
let estimate_bound =
prev.rfind(|c: char| c.is_ascii_whitespace()).map_or(prev.len(), |i| i + 1);
let exact_bound = lexer::Lexer::new(&prev[estimate_bound..]).last().start;
prev = &prev[..exact_bound as usize + estimate_bound];
if preserve_newlines(prev) > 0 {
f.write_str("\n")?;
for _ in 0..self.depth + 1 {
f.write_str("\t")?;
}
f.write_str(op.name())?;
f.write_str(" ")?;
} else {
f.write_str(" ")?;
f.write_str(op.name())?;
f.write_str(" ")?;
}
} else {
f.write_str(" ")?;
f.write_str(op.name())?;
f.write_str(" ")?;
}
self.fmt_paren(right, f, pec_miss)
}
}
}
}
pub fn preserve_newlines(source: &str) -> usize {
source[source.trim_end().len()..].bytes().filter(|&c| c == b'\n').count()
}
pub fn insert_needed_semicolon(source: &str) -> bool {
let kind = lexer::Lexer::new(source).eat().kind;
kind.precedence().is_some() || matches!(kind, TokenKind::Ctor | TokenKind::Tupl)
}
impl core::fmt::Display for parser::Ast {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
fmt_file(self.exprs(), &self.file, f)
}
}
pub fn fmt_file(exprs: &[Expr], file: &str, f: &mut impl fmt::Write) -> fmt::Result {
for (i, expr) in exprs.iter().enumerate() {
Formatter::new(file).fmt(expr, f)?;
if let Some(expr) = exprs.get(i + 1)
&& let Some(rest) = file.get(expr.pos() as usize..)
{
if insert_needed_semicolon(rest) {
write!(f, ";")?;
}
if preserve_newlines(&file[..expr.pos() as usize]) > 1 {
writeln!(f)?;
}
}
if i + 1 != exprs.len() {
writeln!(f)?;
}
}
Ok(())
}
#[cfg(test)]
pub mod test {
use {
crate::parser::{self, ParserCtx},
alloc::borrow::ToOwned,
std::{fmt::Write, string::String},
};
pub fn format(ident: &str, input: &str) {
let mut minned = input.to_owned();
let len = crate::fmt::minify(&mut minned);
minned.truncate(len);
let ast = parser::Ast::new(ident, minned, &mut ParserCtx::default(), &mut |_, _| Ok(0));
//log::error!(
// "{} / {} = {} | {} / {} = {}",
// ast.mem.size(),
// input.len(),
// ast.mem.size() as f32 / input.len() as f32,
// ast.mem.size(),
// ast.file.len(),
// ast.mem.size() as f32 / ast.file.len() as f32
//);
let mut output = String::new();
write!(output, "{ast}").unwrap();
let input_path = format!("formatter_{ident}.expected");
let output_path = format!("formatter_{ident}.actual");
std::fs::write(&input_path, input).unwrap();
std::fs::write(&output_path, output).unwrap();
let success = std::process::Command::new("diff")
.arg("-u")
.arg("--color")
.arg(&input_path)
.arg(&output_path)
.status()
.unwrap()
.success();
std::fs::remove_file(&input_path).unwrap();
std::fs::remove_file(&output_path).unwrap();
assert!(success, "test failed");
}
macro_rules! test {
($($name:ident => $input:expr;)*) => {$(
#[test]
fn $name() {
format(stringify!($name), $input);
}
)*};
}
test! {
comments => "// comment\n// comment\n\n// comment\n\n\
/* comment */\n/* comment */\n\n/* comment */";
some_ordinary_code => "loft := fn(): int return loft(1, 2, 3)";
some_arg_per_line_code => "loft := fn(): int return loft(\
\n\t1,\n\t2,\n\t3,\n)";
some_ordinary_struct => "loft := fn(): int return loft.{a: 1, b: 2}";
some_ordinary_fild_per_lin_struct => "loft := fn(): int return loft.{\
\n\ta: 1,\n\tb: 2,\n}";
code_block => "loft := fn(): int {\n\tloft()\n\treturn 1\n}";
}
}