rust-analyzer/crates/ide-ssr/src/resolving.rs
2024-07-18 08:49:10 +02:00

311 lines
12 KiB
Rust

//! This module is responsible for resolving paths within rules.
use hir::AsAssocItem;
use ide_db::FxHashMap;
use parsing::Placeholder;
use syntax::{
ast::{self, HasGenericArgs},
SmolStr, SyntaxKind, SyntaxNode, SyntaxToken,
};
use crate::{errors::error, parsing, SsrError};
pub(crate) struct ResolutionScope<'db> {
scope: hir::SemanticsScope<'db>,
node: SyntaxNode,
}
pub(crate) struct ResolvedRule {
pub(crate) pattern: ResolvedPattern,
pub(crate) template: Option<ResolvedPattern>,
pub(crate) index: usize,
}
pub(crate) struct ResolvedPattern {
pub(crate) placeholders_by_stand_in: FxHashMap<SmolStr, parsing::Placeholder>,
pub(crate) node: SyntaxNode,
// Paths in `node` that we've resolved.
pub(crate) resolved_paths: FxHashMap<SyntaxNode, ResolvedPath>,
pub(crate) ufcs_function_calls: FxHashMap<SyntaxNode, UfcsCallInfo>,
pub(crate) contains_self: bool,
}
pub(crate) struct ResolvedPath {
pub(crate) resolution: hir::PathResolution,
/// The depth of the ast::Path that was resolved within the pattern.
pub(crate) depth: u32,
}
pub(crate) struct UfcsCallInfo {
pub(crate) call_expr: ast::CallExpr,
pub(crate) function: hir::Function,
pub(crate) qualifier_type: Option<hir::Type>,
}
impl ResolvedRule {
pub(crate) fn new(
rule: parsing::ParsedRule,
resolution_scope: &ResolutionScope<'_>,
index: usize,
) -> Result<ResolvedRule, SsrError> {
let resolver =
Resolver { resolution_scope, placeholders_by_stand_in: rule.placeholders_by_stand_in };
let resolved_template = match rule.template {
Some(template) => Some(resolver.resolve_pattern_tree(template)?),
None => None,
};
Ok(ResolvedRule {
pattern: resolver.resolve_pattern_tree(rule.pattern)?,
template: resolved_template,
index,
})
}
pub(crate) fn get_placeholder(&self, token: &SyntaxToken) -> Option<&Placeholder> {
if token.kind() != SyntaxKind::IDENT {
return None;
}
self.pattern.placeholders_by_stand_in.get(token.text())
}
}
struct Resolver<'a, 'db> {
resolution_scope: &'a ResolutionScope<'db>,
placeholders_by_stand_in: FxHashMap<SmolStr, parsing::Placeholder>,
}
impl Resolver<'_, '_> {
fn resolve_pattern_tree(&self, pattern: SyntaxNode) -> Result<ResolvedPattern, SsrError> {
use syntax::ast::AstNode;
use syntax::{SyntaxElement, T};
let mut resolved_paths = FxHashMap::default();
self.resolve(pattern.clone(), 0, &mut resolved_paths)?;
let ufcs_function_calls = resolved_paths
.iter()
.filter_map(|(path_node, resolved)| {
if let Some(grandparent) = path_node.parent().and_then(|parent| parent.parent()) {
if let Some(call_expr) = ast::CallExpr::cast(grandparent.clone()) {
if let hir::PathResolution::Def(hir::ModuleDef::Function(function)) =
resolved.resolution
{
if function.as_assoc_item(self.resolution_scope.scope.db).is_some() {
let qualifier_type =
self.resolution_scope.qualifier_type(path_node);
return Some((
grandparent,
UfcsCallInfo { call_expr, function, qualifier_type },
));
}
}
}
}
None
})
.collect();
let contains_self =
pattern.descendants_with_tokens().any(|node_or_token| match node_or_token {
SyntaxElement::Token(t) => t.kind() == T![self],
_ => false,
});
Ok(ResolvedPattern {
node: pattern,
resolved_paths,
placeholders_by_stand_in: self.placeholders_by_stand_in.clone(),
ufcs_function_calls,
contains_self,
})
}
fn resolve(
&self,
node: SyntaxNode,
depth: u32,
resolved_paths: &mut FxHashMap<SyntaxNode, ResolvedPath>,
) -> Result<(), SsrError> {
use syntax::ast::AstNode;
if let Some(path) = ast::Path::cast(node.clone()) {
if is_self(&path) {
// Self cannot be resolved like other paths.
return Ok(());
}
// Check if this is an appropriate place in the path to resolve. If the path is
// something like `a::B::<i32>::c` then we want to resolve `a::B`. If the path contains
// a placeholder. e.g. `a::$b::c` then we want to resolve `a`.
if !path_contains_type_arguments(path.qualifier())
&& !self.path_contains_placeholder(&path)
{
let resolution = self
.resolution_scope
.resolve_path(&path)
.ok_or_else(|| error!("Failed to resolve path `{}`", node.text()))?;
if self.ok_to_use_path_resolution(&resolution) {
resolved_paths.insert(node, ResolvedPath { resolution, depth });
return Ok(());
}
}
}
for node in node.children() {
self.resolve(node, depth + 1, resolved_paths)?;
}
Ok(())
}
/// Returns whether `path` contains a placeholder, but ignores any placeholders within type
/// arguments.
fn path_contains_placeholder(&self, path: &ast::Path) -> bool {
if let Some(segment) = path.segment() {
if let Some(name_ref) = segment.name_ref() {
if self.placeholders_by_stand_in.contains_key(name_ref.text().as_str()) {
return true;
}
}
}
if let Some(qualifier) = path.qualifier() {
return self.path_contains_placeholder(&qualifier);
}
false
}
fn ok_to_use_path_resolution(&self, resolution: &hir::PathResolution) -> bool {
match resolution {
hir::PathResolution::Def(hir::ModuleDef::Function(function))
if function.as_assoc_item(self.resolution_scope.scope.db).is_some() =>
{
if function.self_param(self.resolution_scope.scope.db).is_some() {
// If we don't use this path resolution, then we won't be able to match method
// calls. e.g. `Foo::bar($s)` should match `x.bar()`.
true
} else {
cov_mark::hit!(replace_associated_trait_default_function_call);
false
}
}
hir::PathResolution::Def(
def @ (hir::ModuleDef::Const(_) | hir::ModuleDef::TypeAlias(_)),
) if def.as_assoc_item(self.resolution_scope.scope.db).is_some() => {
// Not a function. Could be a constant or an associated type.
cov_mark::hit!(replace_associated_trait_constant);
false
}
_ => true,
}
}
}
impl<'db> ResolutionScope<'db> {
pub(crate) fn new(
sema: &hir::Semantics<'db, ide_db::RootDatabase>,
resolve_context: hir::FilePosition,
) -> Option<ResolutionScope<'db>> {
use syntax::ast::AstNode;
let file = sema.parse(resolve_context.file_id);
// Find a node at the requested position, falling back to the whole file.
let node = file
.syntax()
.token_at_offset(resolve_context.offset)
.left_biased()
.and_then(|token| token.parent())
.unwrap_or_else(|| file.syntax().clone());
let node = pick_node_for_resolution(node);
let scope = sema.scope(&node)?;
Some(ResolutionScope { scope, node })
}
/// Returns the function in which SSR was invoked, if any.
pub(crate) fn current_function(&self) -> Option<SyntaxNode> {
self.node.ancestors().find(|node| node.kind() == SyntaxKind::FN)
}
fn resolve_path(&self, path: &ast::Path) -> Option<hir::PathResolution> {
// First try resolving the whole path. This will work for things like
// `std::collections::HashMap`, but will fail for things like
// `std::collections::HashMap::new`.
if let Some(resolution) = self.scope.speculative_resolve(path) {
return Some(resolution);
}
// Resolution failed, try resolving the qualifier (e.g. `std::collections::HashMap` and if
// that succeeds, then iterate through the candidates on the resolved type with the provided
// name.
let resolved_qualifier = self.scope.speculative_resolve(&path.qualifier()?)?;
if let hir::PathResolution::Def(hir::ModuleDef::Adt(adt)) = resolved_qualifier {
let name = path.segment()?.name_ref()?;
let module = self.scope.module();
adt.ty(self.scope.db).iterate_path_candidates(
self.scope.db,
&self.scope,
&self.scope.visible_traits().0,
Some(module),
None,
|assoc_item| {
let item_name = assoc_item.name(self.scope.db)?;
if item_name.as_str() == name.text() {
Some(hir::PathResolution::Def(assoc_item.into()))
} else {
None
}
},
)
} else {
None
}
}
fn qualifier_type(&self, path: &SyntaxNode) -> Option<hir::Type> {
use syntax::ast::AstNode;
if let Some(path) = ast::Path::cast(path.clone()) {
if let Some(qualifier) = path.qualifier() {
if let Some(hir::PathResolution::Def(hir::ModuleDef::Adt(adt))) =
self.resolve_path(&qualifier)
{
return Some(adt.ty(self.scope.db));
}
}
}
None
}
}
fn is_self(path: &ast::Path) -> bool {
path.segment().map(|segment| segment.self_token().is_some()).unwrap_or(false)
}
/// Returns a suitable node for resolving paths in the current scope. If we create a scope based on
/// a statement node, then we can't resolve local variables that were defined in the current scope
/// (only in parent scopes). So we find another node, ideally a child of the statement where local
/// variable resolution is permitted.
fn pick_node_for_resolution(node: SyntaxNode) -> SyntaxNode {
match node.kind() {
SyntaxKind::EXPR_STMT => {
if let Some(n) = node.first_child() {
cov_mark::hit!(cursor_after_semicolon);
return n;
}
}
SyntaxKind::LET_STMT | SyntaxKind::IDENT_PAT => {
if let Some(next) = node.next_sibling() {
return pick_node_for_resolution(next);
}
}
SyntaxKind::NAME => {
if let Some(parent) = node.parent() {
return pick_node_for_resolution(parent);
}
}
_ => {}
}
node
}
/// Returns whether `path` or any of its qualifiers contains type arguments.
fn path_contains_type_arguments(path: Option<ast::Path>) -> bool {
if let Some(path) = path {
if let Some(segment) = path.segment() {
if segment.generic_arg_list().is_some() {
cov_mark::hit!(type_arguments_within_path);
return true;
}
}
return path_contains_type_arguments(path.qualifier());
}
false
}