//! This module generates AST datatype used by rust-analyzer.
//!
//! Specifically, it generates the `SyntaxKind` enum and a number of newtype
//! wrappers around `SyntaxNode` which implement `ra_syntax::AstNode`.
use std::{
borrow::Cow,
collections::{BTreeSet, HashSet},
};
use proc_macro2::{Punct, Spacing};
use quote::{format_ident, quote};
use crate::{
ast_src::{AstSrc, FieldSrc, KindsSrc, AST_SRC, KINDS_SRC},
codegen::{self, update, Mode},
project_root, Result,
};
pub fn generate_syntax(mode: Mode) -> Result<()> {
let syntax_kinds_file = project_root().join(codegen::SYNTAX_KINDS);
let syntax_kinds = generate_syntax_kinds(KINDS_SRC)?;
update(syntax_kinds_file.as_path(), &syntax_kinds, mode)?;
let ast_nodes_file = project_root().join(codegen::AST_NODES);
let contents = generate_nodes(KINDS_SRC, AST_SRC)?;
update(ast_nodes_file.as_path(), &contents, mode)?;
let ast_tokens_file = project_root().join(codegen::AST_TOKENS);
let contents = generate_tokens(KINDS_SRC, AST_SRC)?;
update(ast_tokens_file.as_path(), &contents, mode)?;
Ok(())
}
#[derive(Debug, Default, Clone)]
struct ElementKinds {
kinds: BTreeSet<proc_macro2::Ident>,
has_nodes: bool,
has_tokens: bool,
}
fn generate_tokens(kinds: KindsSrc<'_>, grammar: AstSrc<'_>) -> Result<String> {
let all_token_kinds: Vec<_> = kinds
.punct
.into_iter()
.map(|(_, kind)| kind)
.copied()
.map(|x| x.into())
.chain(
kinds
.keywords
.into_iter()
.chain(kinds.contextual_keywords.into_iter())
.map(|name| Cow::Owned(format!("{}_KW", to_upper_snake_case(&name)))),
)
.chain(kinds.literals.into_iter().copied().map(|x| x.into()))
.chain(kinds.tokens.into_iter().copied().map(|x| x.into()))
.collect();
let tokens = all_token_kinds.iter().map(|kind_str| {
let kind_str = &**kind_str;
let kind = format_ident!("{}", kind_str);
let name = format_ident!("{}", to_pascal_case(kind_str));
quote! {
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct #name {
pub(crate) syntax: SyntaxToken,
}
impl std::fmt::Display for #name {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Display::fmt(&self.syntax, f)
}
}
impl AstToken for #name {
fn can_cast(kind: SyntaxKind) -> bool { kind == #kind }
fn cast(syntax: SyntaxToken) -> Option<Self> {
if Self::can_cast(syntax.kind()) { Some(Self { syntax }) } else { None }
}
fn syntax(&self) -> &SyntaxToken { &self.syntax }
}
}
});
let enums = grammar.token_enums.iter().map(|en| {
let variants = en.variants.iter().map(|var| format_ident!("{}", var)).collect::<Vec<_>>();
let name = format_ident!("{}", en.name);
let kinds = variants
.iter()
.map(|name| format_ident!("{}", to_upper_snake_case(&name.to_string())))
.collect::<Vec<_>>();
assert!(en.traits.is_empty());
quote! {
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub enum #name {
#(#variants(#variants),)*
}
#(
impl From<#variants> for #name {
fn from(node: #variants) -> #name {
#name::#variants(node)
}
}
)*
impl std::fmt::Display for #name {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Display::fmt(self.syntax(), f)
}
}
impl AstToken for #name {
fn can_cast(kind: SyntaxKind) -> bool {
match kind {
#(#kinds)|* => true,
_ => false,
}
}
fn cast(syntax: SyntaxToken) -> Option<Self> {
let res = match syntax.kind() {
#(
#kinds => #name::#variants(#variants { syntax }),
)*
_ => return None,
};
Some(res)
}
fn syntax(&self) -> &SyntaxToken {
match self {
#(
#name::#variants(it) => &it.syntax,
)*
}
}
}
}
});
crate::reformat(quote! {
use crate::{SyntaxToken, SyntaxKind::{self, *}, ast::AstToken};
#(#tokens)*
#(#enums)*
})
}
fn generate_nodes(kinds: KindsSrc<'_>, grammar: AstSrc<'_>) -> Result<String> {
let all_token_kinds: Vec<_> = kinds
.punct
.into_iter()
.map(|(_, kind)| kind)
.copied()
.map(|x| x.into())
.chain(
kinds
.keywords
.into_iter()
.chain(kinds.contextual_keywords.into_iter())
.map(|name| Cow::Owned(format!("{}_KW", to_upper_snake_case(&name)))),
)
.chain(kinds.literals.into_iter().copied().map(|x| x.into()))
.chain(kinds.tokens.into_iter().copied().map(|x| x.into()))
.collect();
let mut token_kinds = HashSet::new();
for kind in &all_token_kinds {
let kind = &**kind;
let name = to_pascal_case(kind);
token_kinds.insert(name);
}
for en in grammar.token_enums {
token_kinds.insert(en.name.to_string());
}
let nodes = grammar.nodes.iter().map(|node| {
let name = format_ident!("{}", node.name);
let kind = format_ident!("{}", to_upper_snake_case(&name.to_string()));
let traits = node.traits.iter().map(|trait_name| {
let trait_name = format_ident!("{}", trait_name);
quote!(impl ast::#trait_name for #name {})
});
let methods = node.fields.iter().map(|(name, field)| {
let method_name = match field {
FieldSrc::Shorthand => format_ident!("{}", to_lower_snake_case(&name)),
_ => format_ident!("{}", name),
};
let ty = match field {
FieldSrc::Optional(ty) | FieldSrc::Many(ty) => ty,
FieldSrc::Shorthand => name,
};
let ty = format_ident!("{}", ty);
match field {
FieldSrc::Many(_) => {
quote! {
pub fn #method_name(&self) -> AstChildren<#ty> {
support::children(&self.syntax)
}
}
}
FieldSrc::Optional(_) | FieldSrc::Shorthand => {
let is_token = token_kinds.contains(&ty.to_string());
if is_token {
let method_name = format_ident!("{}_token", method_name);
quote! {
pub fn #method_name(&self) -> Option<#ty> {
support::token(&self.syntax)
}
}
} else {
quote! {
pub fn #method_name(&self) -> Option<#ty> {
support::child(&self.syntax)
}
}
}
}
}
});
quote! {
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct #name {
pub(crate) syntax: SyntaxNode,
}
impl AstNode for #name {
fn can_cast(kind: SyntaxKind) -> bool {
kind == #kind
}
fn cast(syntax: SyntaxNode) -> Option<Self> {
if Self::can_cast(syntax.kind()) { Some(Self { syntax }) } else { None }
}
fn syntax(&self) -> &SyntaxNode { &self.syntax }
}
#(#traits)*
impl #name {
#(#methods)*
}
}
});
let enums = grammar.enums.iter().map(|en| {
let variants = en.variants.iter().map(|var| format_ident!("{}", var)).collect::<Vec<_>>();
let name = format_ident!("{}", en.name);
let kinds = variants
.iter()
.map(|name| format_ident!("{}", to_upper_snake_case(&name.to_string())))
.collect::<Vec<_>>();
let traits = en.traits.iter().map(|trait_name| {
let trait_name = format_ident!("{}", trait_name);
quote!(impl ast::#trait_name for #name {})
});
quote! {
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub enum #name {
#(#variants(#variants),)*
}
#(
impl From<#variants> for #name {
fn from(node: #variants) -> #name {
#name::#variants(node)
}
}
)*
impl AstNode for #name {
fn can_cast(kind: SyntaxKind) -> bool {
match kind {
#(#kinds)|* => true,
_ => false,
}
}
fn cast(syntax: SyntaxNode) -> Option<Self> {
let res = match syntax.kind() {
#(
#kinds => #name::#variants(#variants { syntax }),
)*
_ => return None,
};
Some(res)
}
fn syntax(&self) -> &SyntaxNode {
match self {
#(
#name::#variants(it) => &it.syntax,
)*
}
}
}
#(#traits)*
}
});
let displays = grammar
.enums
.iter()
.map(|it| format_ident!("{}", it.name))
.chain(grammar.nodes.iter().map(|it| format_ident!("{}", it.name)))
.map(|name| {
quote! {
impl std::fmt::Display for #name {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Display::fmt(self.syntax(), f)
}
}
}
});
let defined_nodes: HashSet<_> = grammar.nodes.iter().map(|node| node.name).collect();
for node in kinds
.nodes
.iter()
.map(|kind| to_pascal_case(*kind))
.filter(|name| !defined_nodes.contains(&**name))
{
eprintln!("Warning: node {} not defined in ast source", node);
}
let ast = quote! {
use crate::{
SyntaxNode, SyntaxKind::{self, *},
ast::{self, AstNode, AstChildren, support},
};
use super::tokens::*;
#(#nodes)*
#(#enums)*
#(#displays)*
};
let pretty = crate::reformat(ast)?;
Ok(pretty)
}
fn generate_syntax_kinds(grammar: KindsSrc<'_>) -> Result<String> {
let (single_byte_tokens_values, single_byte_tokens): (Vec<_>, Vec<_>) = grammar
.punct
.iter()
.filter(|(token, _name)| token.len() == 1)
.map(|(token, name)| (token.chars().next().unwrap(), format_ident!("{}", name)))
.unzip();
let punctuation_values = grammar.punct.iter().map(|(token, _name)| {
if "{}[]()".contains(token) {
let c = token.chars().next().unwrap();
quote! { #c }
} else {
let cs = token.chars().map(|c| Punct::new(c, Spacing::Joint));
quote! { #(#cs)* }
}
});
let punctuation =
grammar.punct.iter().map(|(_token, name)| format_ident!("{}", name)).collect::<Vec<_>>();
let full_keywords_values = &grammar.keywords;
let full_keywords =
full_keywords_values.iter().map(|kw| format_ident!("{}_KW", to_upper_snake_case(&kw)));
let all_keywords_values =
grammar.keywords.iter().chain(grammar.contextual_keywords.iter()).collect::<Vec<_>>();
let all_keywords_idents = all_keywords_values.iter().map(|kw| format_ident!("{}", kw));
let all_keywords = all_keywords_values
.iter()
.map(|name| format_ident!("{}_KW", to_upper_snake_case(&name)))
.collect::<Vec<_>>();
let literals =
grammar.literals.iter().map(|name| format_ident!("{}", name)).collect::<Vec<_>>();
let tokens = grammar.tokens.iter().map(|name| format_ident!("{}", name)).collect::<Vec<_>>();
let nodes = grammar.nodes.iter().map(|name| format_ident!("{}", name)).collect::<Vec<_>>();
let ast = quote! {
#![allow(bad_style, missing_docs, unreachable_pub)]
/// The kind of syntax node, e.g. `IDENT`, `USE_KW`, or `STRUCT_DEF`.
#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)]
#[repr(u16)]
pub enum SyntaxKind {
// Technical SyntaxKinds: they appear temporally during parsing,
// but never end up in the final tree
#[doc(hidden)]
TOMBSTONE,
#[doc(hidden)]
EOF,
#(#punctuation,)*
#(#all_keywords,)*
#(#literals,)*
#(#tokens,)*
#(#nodes,)*
// Technical kind so that we can cast from u16 safely
#[doc(hidden)]
__LAST,
}
use self::SyntaxKind::*;
impl SyntaxKind {
pub fn is_keyword(self) -> bool {
match self {
#(#all_keywords)|* => true,
_ => false,
}
}
pub fn is_punct(self) -> bool {
match self {
#(#punctuation)|* => true,
_ => false,
}
}
pub fn is_literal(self) -> bool {
match self {
#(#literals)|* => true,
_ => false,
}
}
pub fn from_keyword(ident: &str) -> Option<SyntaxKind> {
let kw = match ident {
#(#full_keywords_values => #full_keywords,)*
_ => return None,
};
Some(kw)
}
pub fn from_char(c: char) -> Option<SyntaxKind> {
let tok = match c {
#(#single_byte_tokens_values => #single_byte_tokens,)*
_ => return None,
};
Some(tok)
}
}
#[macro_export]
macro_rules! T {
#((#punctuation_values) => { $crate::SyntaxKind::#punctuation };)*
#((#all_keywords_idents) => { $crate::SyntaxKind::#all_keywords };)*
}
};
crate::reformat(ast)
}
fn to_upper_snake_case(s: &str) -> String {
let mut buf = String::with_capacity(s.len());
let mut prev = false;
for c in s.chars() {
if c.is_ascii_uppercase() && prev {
buf.push('_')
}
prev = true;
buf.push(c.to_ascii_uppercase());
}
buf
}
fn to_lower_snake_case(s: &str) -> String {
let mut buf = String::with_capacity(s.len());
let mut prev = false;
for c in s.chars() {
if c.is_ascii_uppercase() && prev {
buf.push('_')
}
prev = true;
buf.push(c.to_ascii_lowercase());
}
buf
}
fn to_pascal_case(s: &str) -> String {
let mut buf = String::with_capacity(s.len());
let mut prev_is_underscore = true;
for c in s.chars() {
if c == '_' {
prev_is_underscore = true;
} else if prev_is_underscore {
buf.push(c.to_ascii_uppercase());
prev_is_underscore = false;
} else {
buf.push(c.to_ascii_lowercase());
}
}
buf
}