//! Computes color for a single element.
use hir::{AsAssocItem, Semantics};
use ide_db::{
defs::{Definition, NameClass, NameRefClass},
RootDatabase, SymbolKind,
};
use rustc_hash::FxHashMap;
use syntax::{
ast, AstNode, AstToken, NodeOrToken, SyntaxElement,
SyntaxKind::{self, *},
SyntaxNode, SyntaxToken, T,
};
use crate::{
syntax_highlighting::tags::{HlOperator, HlPunct},
Highlight, HlMod, HlTag,
};
pub(super) fn element(
sema: &Semantics<RootDatabase>,
krate: Option<hir::Crate>,
bindings_shadow_count: &mut FxHashMap<hir::Name, u32>,
syntactic_name_ref_highlighting: bool,
element: SyntaxElement,
) -> Option<(Highlight, Option<u64>)> {
let db = sema.db;
let mut binding_hash = None;
let highlight: Highlight = match element.kind() {
FN => {
bindings_shadow_count.clear();
return None;
}
// Highlight definitions depending on the "type" of the definition.
NAME => {
let name = element.into_node().and_then(ast::Name::cast).unwrap();
let name_kind = NameClass::classify(sema, &name);
if let Some(NameClass::Definition(Definition::Local(local))) = &name_kind {
if let Some(name) = local.name(db) {
let shadow_count = bindings_shadow_count.entry(name.clone()).or_default();
*shadow_count += 1;
binding_hash = Some(calc_binding_hash(&name, *shadow_count))
}
};
match name_kind {
Some(NameClass::ExternCrate(_)) => SymbolKind::Module.into(),
Some(NameClass::Definition(def)) => {
highlight_def(db, krate, def) | HlMod::Definition
}
Some(NameClass::ConstReference(def)) => highlight_def(db, krate, def),
Some(NameClass::PatFieldShorthand { field_ref, .. }) => {
let mut h = HlTag::Symbol(SymbolKind::Field).into();
if let Definition::Field(field) = field_ref {
if let hir::VariantDef::Union(_) = field.parent_def(db) {
h |= HlMod::Unsafe;
}
}
h
}
None => highlight_name_by_syntax(name) | HlMod::Definition,
}
}
// Highlight references like the definitions they resolve to
NAME_REF if element.ancestors().any(|it| it.kind() == ATTR) => {
// even though we track whether we are in an attribute or not we still need this special case
// as otherwise we would emit unresolved references for name refs inside attributes
SymbolKind::Function.into()
}
NAME_REF => {
let name_ref = element.into_node().and_then(ast::NameRef::cast).unwrap();
highlight_func_by_name_ref(sema, krate, &name_ref).unwrap_or_else(|| {
let is_self = name_ref.self_token().is_some();
let h = match NameRefClass::classify(sema, &name_ref) {
Some(name_kind) => match name_kind {
NameRefClass::ExternCrate(_) => SymbolKind::Module.into(),
NameRefClass::Definition(def) => {
if let Definition::Local(local) = &def {
if let Some(name) = local.name(db) {
let shadow_count =
bindings_shadow_count.entry(name.clone()).or_default();
binding_hash = Some(calc_binding_hash(&name, *shadow_count))
}
};
let mut h = highlight_def(db, krate, def);
if let Definition::Local(local) = &def {
if is_consumed_lvalue(name_ref.syntax().clone().into(), local, db) {
h |= HlMod::Consuming;
}
}
if let Some(parent) = name_ref.syntax().parent() {
if matches!(parent.kind(), FIELD_EXPR | RECORD_PAT_FIELD) {
if let Definition::Field(field) = def {
if let hir::VariantDef::Union(_) = field.parent_def(db) {
h |= HlMod::Unsafe;
}
}
}
}
h
}
NameRefClass::FieldShorthand { .. } => SymbolKind::Field.into(),
},
None if syntactic_name_ref_highlighting => {
highlight_name_ref_by_syntax(name_ref, sema, krate)
}
None => HlTag::UnresolvedReference.into(),
};
if h.tag == HlTag::Symbol(SymbolKind::Module) && is_self {
SymbolKind::SelfParam.into()
} else {
h
}
})
}
// Simple token-based highlighting
COMMENT => {
let comment = element.into_token().and_then(ast::Comment::cast)?;
let h = HlTag::Comment;
match comment.kind().doc {
Some(_) => h | HlMod::Documentation,
None => h.into(),
}
}
STRING | BYTE_STRING => HlTag::StringLiteral.into(),
ATTR => HlTag::Attribute.into(),
INT_NUMBER if element.ancestors().nth(1).map_or(false, |it| it.kind() == FIELD_EXPR) => {
SymbolKind::Field.into()
}
INT_NUMBER | FLOAT_NUMBER => HlTag::NumericLiteral.into(),
BYTE => HlTag::ByteLiteral.into(),
CHAR => HlTag::CharLiteral.into(),
QUESTION => HlTag::Operator(HlOperator::Other) | HlMod::ControlFlow,
LIFETIME => {
let lifetime = element.into_node().and_then(ast::Lifetime::cast).unwrap();
match NameClass::classify_lifetime(sema, &lifetime) {
Some(NameClass::Definition(def)) => {
highlight_def(db, krate, def) | HlMod::Definition
}
None => match NameRefClass::classify_lifetime(sema, &lifetime) {
Some(NameRefClass::Definition(def)) => highlight_def(db, krate, def),
_ => SymbolKind::LifetimeParam.into(),
},
_ => Highlight::from(SymbolKind::LifetimeParam) | HlMod::Definition,
}
}
p if p.is_punct() => match p {
T![&] if parent_matches::<ast::BinExpr>(&element) => HlOperator::Bitwise.into(),
T![&] => {
let h = HlTag::Operator(HlOperator::Other).into();
let is_unsafe = element
.parent()
.and_then(ast::RefExpr::cast)
.map_or(false, |ref_expr| sema.is_unsafe_ref_expr(&ref_expr));
if is_unsafe {
h | HlMod::Unsafe
} else {
h
}
}
T![::] | T![->] | T![=>] | T![..] | T![=] | T![@] | T![.] => HlOperator::Other.into(),
T![!] if parent_matches::<ast::MacroCall>(&element) => SymbolKind::Macro.into(),
T![!] if parent_matches::<ast::NeverType>(&element) => HlTag::BuiltinType.into(),
T![!] if parent_matches::<ast::PrefixExpr>(&element) => HlOperator::Logical.into(),
T![*] if parent_matches::<ast::PtrType>(&element) => HlTag::Keyword.into(),
T![*] if parent_matches::<ast::PrefixExpr>(&element) => {
let prefix_expr = element.parent().and_then(ast::PrefixExpr::cast)?;
let expr = prefix_expr.expr()?;
let ty = sema.type_of_expr(&expr)?;
if ty.is_raw_ptr() {
HlTag::Operator(HlOperator::Other) | HlMod::Unsafe
} else if let Some(ast::PrefixOp::Deref) = prefix_expr.op_kind() {
HlOperator::Other.into()
} else {
HlPunct::Other.into()
}
}
T![-] if parent_matches::<ast::PrefixExpr>(&element) => {
let prefix_expr = element.parent().and_then(ast::PrefixExpr::cast)?;
let expr = prefix_expr.expr()?;
match expr {
ast::Expr::Literal(_) => HlTag::NumericLiteral,
_ => HlTag::Operator(HlOperator::Other),
}
.into()
}
_ if parent_matches::<ast::PrefixExpr>(&element) => HlOperator::Other.into(),
T![+] | T![-] | T![*] | T![/] | T![+=] | T![-=] | T![*=] | T![/=]
if parent_matches::<ast::BinExpr>(&element) =>
{
HlOperator::Arithmetic.into()
}
T![|] | T![&] | T![!] | T![^] | T![|=] | T![&=] | T![^=]
if parent_matches::<ast::BinExpr>(&element) =>
{
HlOperator::Bitwise.into()
}
T![&&] | T![||] if parent_matches::<ast::BinExpr>(&element) => {
HlOperator::Logical.into()
}
T![>] | T![<] | T![==] | T![>=] | T![<=] | T![!=]
if parent_matches::<ast::BinExpr>(&element) =>
{
HlOperator::Comparison.into()
}
_ if parent_matches::<ast::BinExpr>(&element) => HlOperator::Other.into(),
_ if parent_matches::<ast::RangeExpr>(&element) => HlOperator::Other.into(),
_ if parent_matches::<ast::RangePat>(&element) => HlOperator::Other.into(),
_ if parent_matches::<ast::RestPat>(&element) => HlOperator::Other.into(),
_ if parent_matches::<ast::Attr>(&element) => HlTag::Attribute.into(),
kind => match kind {
T!['['] | T![']'] => HlPunct::Bracket,
T!['{'] | T!['}'] => HlPunct::Brace,
T!['('] | T![')'] => HlPunct::Parenthesis,
T![<] | T![>] => HlPunct::Angle,
T![,] => HlPunct::Comma,
T![:] => HlPunct::Colon,
T![;] => HlPunct::Semi,
T![.] => HlPunct::Dot,
_ => HlPunct::Other,
}
.into(),
},
k if k.is_keyword() => {
let h = Highlight::new(HlTag::Keyword);
match k {
T![await] => h | HlMod::Async | HlMod::ControlFlow,
T![break]
| T![continue]
| T![else]
| T![if]
| T![in]
| T![loop]
| T![match]
| T![return]
| T![while]
| T![yield] => h | HlMod::ControlFlow,
T![for] if !is_child_of_impl(&element) => h | HlMod::ControlFlow,
T![unsafe] => h | HlMod::Unsafe,
T![true] | T![false] => HlTag::BoolLiteral.into(),
// self is handled as either a Name or NameRef already
T![self] => return None,
T![ref] => element
.parent()
.and_then(ast::IdentPat::cast)
.and_then(|ident_pat| {
if sema.is_unsafe_ident_pat(&ident_pat) {
Some(HlMod::Unsafe)
} else {
None
}
})
.map(|modifier| h | modifier)
.unwrap_or(h),
T![async] => h | HlMod::Async,
_ => h,
}
}
_ => return None,
};
return Some((highlight, binding_hash));
fn calc_binding_hash(name: &hir::Name, shadow_count: u32) -> u64 {
fn hash<T: std::hash::Hash + std::fmt::Debug>(x: T) -> u64 {
use std::{collections::hash_map::DefaultHasher, hash::Hasher};
let mut hasher = DefaultHasher::new();
x.hash(&mut hasher);
hasher.finish()
}
hash((name, shadow_count))
}
}
fn highlight_def(db: &RootDatabase, krate: Option<hir::Crate>, def: Definition) -> Highlight {
let mut h = match def {
Definition::Macro(_) => Highlight::new(HlTag::Symbol(SymbolKind::Macro)),
Definition::Field(_) => Highlight::new(HlTag::Symbol(SymbolKind::Field)),
Definition::ModuleDef(def) => match def {
hir::ModuleDef::Module(_) => Highlight::new(HlTag::Symbol(SymbolKind::Module)),
hir::ModuleDef::Function(func) => {
let mut h = Highlight::new(HlTag::Symbol(SymbolKind::Function));
if let Some(item) = func.as_assoc_item(db) {
h |= HlMod::Associated;
match func.self_param(db) {
Some(sp) => {
if let hir::Access::Exclusive = sp.access(db) {
h |= HlMod::Mutable;
}
}
None => h |= HlMod::Static,
}
match item.container(db) {
hir::AssocItemContainer::Impl(i) => {
if i.trait_(db).is_some() {
h |= HlMod::Trait;
}
}
hir::AssocItemContainer::Trait(_t) => {
h |= HlMod::Trait;
}
}
}
if func.is_unsafe(db) {
h |= HlMod::Unsafe;
}
if func.is_async(db) {
h |= HlMod::Async;
}
h
}
hir::ModuleDef::Adt(adt) => {
let h = match adt {
hir::Adt::Struct(_) => HlTag::Symbol(SymbolKind::Struct),
hir::Adt::Enum(_) => HlTag::Symbol(SymbolKind::Enum),
hir::Adt::Union(_) => HlTag::Symbol(SymbolKind::Union),
};
Highlight::new(h)
}
hir::ModuleDef::Variant(_) => Highlight::new(HlTag::Symbol(SymbolKind::Variant)),
hir::ModuleDef::Const(konst) => {
let mut h = Highlight::new(HlTag::Symbol(SymbolKind::Const));
if let Some(item) = konst.as_assoc_item(db) {
h |= HlMod::Associated;
match item.container(db) {
hir::AssocItemContainer::Impl(i) => {
if i.trait_(db).is_some() {
h |= HlMod::Trait;
}
}
hir::AssocItemContainer::Trait(_t) => {
h |= HlMod::Trait;
}
}
}
h
}
hir::ModuleDef::Trait(trait_) => {
let mut h = Highlight::new(HlTag::Symbol(SymbolKind::Trait));
if trait_.is_unsafe(db) {
h |= HlMod::Unsafe;
}
h
}
hir::ModuleDef::TypeAlias(type_) => {
let mut h = Highlight::new(HlTag::Symbol(SymbolKind::TypeAlias));
if let Some(item) = type_.as_assoc_item(db) {
h |= HlMod::Associated;
match item.container(db) {
hir::AssocItemContainer::Impl(i) => {
if i.trait_(db).is_some() {
h |= HlMod::Trait;
}
}
hir::AssocItemContainer::Trait(_t) => {
h |= HlMod::Trait;
}
}
}
h
}
hir::ModuleDef::BuiltinType(_) => Highlight::new(HlTag::BuiltinType),
hir::ModuleDef::Static(s) => {
let mut h = Highlight::new(HlTag::Symbol(SymbolKind::Static));
if s.is_mut(db) {
h |= HlMod::Mutable;
h |= HlMod::Unsafe;
}
h
}
},
Definition::SelfType(_) => Highlight::new(HlTag::Symbol(SymbolKind::Impl)),
Definition::GenericParam(it) => match it {
hir::GenericParam::TypeParam(_) => Highlight::new(HlTag::Symbol(SymbolKind::TypeParam)),
hir::GenericParam::ConstParam(_) => {
Highlight::new(HlTag::Symbol(SymbolKind::ConstParam))
}
hir::GenericParam::LifetimeParam(_) => {
Highlight::new(HlTag::Symbol(SymbolKind::LifetimeParam))
}
},
Definition::Local(local) => {
let tag = if local.is_self(db) {
HlTag::Symbol(SymbolKind::SelfParam)
} else if local.is_param(db) {
HlTag::Symbol(SymbolKind::ValueParam)
} else {
HlTag::Symbol(SymbolKind::Local)
};
let mut h = Highlight::new(tag);
let ty = local.ty(db);
if local.is_mut(db) || ty.is_mutable_reference() {
h |= HlMod::Mutable;
}
if ty.as_callable(db).is_some() || ty.impls_fnonce(db) {
h |= HlMod::Callable;
}
h
}
Definition::Label(_) => Highlight::new(HlTag::Symbol(SymbolKind::Label)),
};
let is_from_other_crate = def.module(db).map(hir::Module::krate) != krate;
let is_builtin_type = matches!(def, Definition::ModuleDef(hir::ModuleDef::BuiltinType(_)));
if is_from_other_crate && !is_builtin_type {
h |= HlMod::Library;
}
h
}
fn highlight_func_by_name_ref(
sema: &Semantics<RootDatabase>,
krate: Option<hir::Crate>,
name_ref: &ast::NameRef,
) -> Option<Highlight> {
let mc = name_ref.syntax().parent().and_then(ast::MethodCallExpr::cast)?;
highlight_method_call(sema, krate, &mc)
}
fn highlight_method_call(
sema: &Semantics<RootDatabase>,
krate: Option<hir::Crate>,
method_call: &ast::MethodCallExpr,
) -> Option<Highlight> {
let func = sema.resolve_method_call(method_call)?;
let mut h = SymbolKind::Function.into();
h |= HlMod::Associated;
if func.is_unsafe(sema.db) || sema.is_unsafe_method_call(method_call) {
h |= HlMod::Unsafe;
}
if func.is_async(sema.db) {
h |= HlMod::Async;
}
if func.as_assoc_item(sema.db).and_then(|it| it.containing_trait(sema.db)).is_some() {
h |= HlMod::Trait;
}
if Some(func.module(sema.db).krate()) != krate {
h |= HlMod::Library;
}
if let Some(self_param) = func.self_param(sema.db) {
match self_param.access(sema.db) {
hir::Access::Shared => (),
hir::Access::Exclusive => h |= HlMod::Mutable,
hir::Access::Owned => {
if let Some(receiver_ty) =
method_call.receiver().and_then(|it| sema.type_of_expr(&it))
{
if !receiver_ty.is_copy(sema.db) {
h |= HlMod::Consuming
}
}
}
}
}
Some(h)
}
fn highlight_name_by_syntax(name: ast::Name) -> Highlight {
let default = HlTag::UnresolvedReference;
let parent = match name.syntax().parent() {
Some(it) => it,
_ => return default.into(),
};
let tag = match parent.kind() {
STRUCT => SymbolKind::Struct,
ENUM => SymbolKind::Enum,
VARIANT => SymbolKind::Variant,
UNION => SymbolKind::Union,
TRAIT => SymbolKind::Trait,
TYPE_ALIAS => SymbolKind::TypeAlias,
TYPE_PARAM => SymbolKind::TypeParam,
RECORD_FIELD => SymbolKind::Field,
MODULE => SymbolKind::Module,
FN => SymbolKind::Function,
CONST => SymbolKind::Const,
STATIC => SymbolKind::Static,
IDENT_PAT => SymbolKind::Local,
_ => return default.into(),
};
tag.into()
}
fn highlight_name_ref_by_syntax(
name: ast::NameRef,
sema: &Semantics<RootDatabase>,
krate: Option<hir::Crate>,
) -> Highlight {
let default = HlTag::UnresolvedReference;
let parent = match name.syntax().parent() {
Some(it) => it,
_ => return default.into(),
};
match parent.kind() {
METHOD_CALL_EXPR => ast::MethodCallExpr::cast(parent)
.and_then(|it| highlight_method_call(sema, krate, &it))
.unwrap_or_else(|| SymbolKind::Function.into()),
FIELD_EXPR => {
let h = HlTag::Symbol(SymbolKind::Field);
let is_union = ast::FieldExpr::cast(parent)
.and_then(|field_expr| sema.resolve_field(&field_expr))
.map_or(false, |field| {
matches!(field.parent_def(sema.db), hir::VariantDef::Union(_))
});
if is_union {
h | HlMod::Unsafe
} else {
h.into()
}
}
PATH_SEGMENT => {
let path = match parent.parent().and_then(ast::Path::cast) {
Some(it) => it,
_ => return default.into(),
};
let expr = match path.syntax().parent().and_then(ast::PathExpr::cast) {
Some(it) => it,
_ => {
// within path, decide whether it is module or adt by checking for uppercase name
return if name.text().chars().next().unwrap_or_default().is_uppercase() {
SymbolKind::Struct
} else {
SymbolKind::Module
}
.into();
}
};
let parent = match expr.syntax().parent() {
Some(it) => it,
None => return default.into(),
};
match parent.kind() {
CALL_EXPR => SymbolKind::Function.into(),
_ => if name.text().chars().next().unwrap_or_default().is_uppercase() {
SymbolKind::Struct
} else {
SymbolKind::Const
}
.into(),
}
}
_ => default.into(),
}
}
fn is_consumed_lvalue(
node: NodeOrToken<SyntaxNode, SyntaxToken>,
local: &hir::Local,
db: &RootDatabase,
) -> bool {
// When lvalues are passed as arguments and they're not Copy, then mark them as Consuming.
parents_match(node, &[PATH_SEGMENT, PATH, PATH_EXPR, ARG_LIST]) && !local.ty(db).is_copy(db)
}
/// Returns true if the parent nodes of `node` all match the `SyntaxKind`s in `kinds` exactly.
fn parents_match(mut node: NodeOrToken<SyntaxNode, SyntaxToken>, mut kinds: &[SyntaxKind]) -> bool {
while let (Some(parent), [kind, rest @ ..]) = (&node.parent(), kinds) {
if parent.kind() != *kind {
return false;
}
// FIXME: Would be nice to get parent out of the match, but binding by-move and by-value
// in the same pattern is unstable: rust-lang/rust#68354.
node = node.parent().unwrap().into();
kinds = rest;
}
// Only true if we matched all expected kinds
kinds.len() == 0
}
#[inline]
fn parent_matches<N: AstNode>(element: &SyntaxElement) -> bool {
element.parent().map_or(false, |it| N::can_cast(it.kind()))
}
fn is_child_of_impl(element: &SyntaxElement) -> bool {
match element.parent() {
Some(e) => e.kind() == IMPL,
_ => false,
}
}