src/tools/rust-analyzer/crates/hir-def/src/path/lower.rs - toolchain/rustc - Git at Google

 //! Transforms syntax into `Path` objects, ideally with accounting for hygiene

 use std::iter;

 use crate::{lower::LowerCtx, type_ref::ConstRef};

 use hir_expand::{
     mod_path::resolve_crate_root,
     name::{name, AsName},
 };
 use intern::Interned;
 use syntax::ast::{self, AstNode, HasTypeBounds};

 use crate::{
     path::{AssociatedTypeBinding, GenericArg, GenericArgs, ModPath, Path, PathKind},
     type_ref::{LifetimeRef, TypeBound, TypeRef},
 };

 /// Converts an `ast::Path` to `Path`. Works with use trees.
 /// It correctly handles `$crate` based path from macro call.
 pub(super) fn lower_path(ctx: &LowerCtx<'_>, mut path: ast::Path) -> Option<Path> {
     let mut kind = PathKind::Plain;
     let mut type_anchor = None;
     let mut segments = Vec::new();
     let mut generic_args = Vec::new();
     let span_map = ctx.span_map();
     loop {
         let segment = path.segment()?;

         if segment.coloncolon_token().is_some() {
             kind = PathKind::Abs;
         }

         match segment.kind()? {
             ast::PathSegmentKind::Name(name_ref) => {
                 if name_ref.text() == "$crate" {
                     break kind = resolve_crate_root(
                         ctx.db.upcast(),
                         span_map.span_for_range(name_ref.syntax().text_range()).ctx,
                     )
                     .map(PathKind::DollarCrate)
                     .unwrap_or(PathKind::Crate);
                 }
                 let name = name_ref.as_name();
                 let args = segment
                     .generic_arg_list()
                     .and_then(|it| lower_generic_args(ctx, it))
                     .or_else(|| {
                         lower_generic_args_from_fn_path(
                             ctx,
                             segment.param_list(),
                             segment.ret_type(),
                         )
                     })
                     .map(Interned::new);
                 if args.is_some() {
                     generic_args.resize(segments.len(), None);
                     generic_args.push(args);
                 }
                 segments.push(name);
             }
             ast::PathSegmentKind::SelfTypeKw => {
                 segments.push(name![Self]);
             }
             ast::PathSegmentKind::Type { type_ref, trait_ref } => {
                 assert!(path.qualifier().is_none()); // this can only occur at the first segment

                 let self_type = TypeRef::from_ast(ctx, type_ref?);

                 match trait_ref {
                     // <T>::foo
                     None => {
                         type_anchor = Some(Interned::new(self_type));
                         kind = PathKind::Plain;
                     }
                     // <T as Trait<A>>::Foo desugars to Trait<Self=T, A>::Foo
                     Some(trait_ref) => {
                         let Path::Normal { mod_path, generic_args: path_generic_args, .. } =
                             Path::from_src(ctx, trait_ref.path()?)?
                         else {
                             return None;
                         };
                         let num_segments = mod_path.segments().len();
                         kind = mod_path.kind;

                         segments.extend(mod_path.segments().iter().cloned().rev());
                         if let Some(path_generic_args) = path_generic_args {
                             generic_args.resize(segments.len() - num_segments, None);
                             generic_args.extend(Vec::from(path_generic_args).into_iter().rev());
                         } else {
                             generic_args.resize(segments.len(), None);
                         }

                         let self_type = GenericArg::Type(self_type);

                         // Insert the type reference (T in the above example) as Self parameter for the trait
                         let last_segment = generic_args.get_mut(segments.len() - num_segments)?;
                         *last_segment = Some(Interned::new(match last_segment.take() {
                             Some(it) => GenericArgs {
                                 args: iter::once(self_type)
                                     .chain(it.args.iter().cloned())
                                     .collect(),

                                 has_self_type: true,
                                 bindings: it.bindings.clone(),
                                 desugared_from_fn: it.desugared_from_fn,
                             },
                             None => GenericArgs {
                                 args: Box::new([self_type]),
                                 has_self_type: true,
                                 ..GenericArgs::empty()
                             },
                         }));
                     }
                 }
             }
             ast::PathSegmentKind::CrateKw => {
                 kind = PathKind::Crate;
                 break;
             }
             ast::PathSegmentKind::SelfKw => {
                 // don't break out if `self` is the last segment of a path, this mean we got a
                 // use tree like `foo::{self}` which we want to resolve as `foo`
                 if !segments.is_empty() {
                     kind = PathKind::Super(0);
                     break;
                 }
             }
             ast::PathSegmentKind::SuperKw => {
                 let nested_super_count = if let PathKind::Super(n) = kind { n } else { 0 };
                 kind = PathKind::Super(nested_super_count + 1);
             }
         }
         path = match qualifier(&path) {
             Some(it) => it,
             None => break,
         };
     }
     segments.reverse();
     if !generic_args.is_empty() {
         generic_args.resize(segments.len(), None);
         generic_args.reverse();
     }

     if segments.is_empty() && kind == PathKind::Plain && type_anchor.is_none() {
         // plain empty paths don't exist, this means we got a single `self` segment as our path
         kind = PathKind::Super(0);
     }

     // handle local_inner_macros :
     // Basically, even in rustc it is quite hacky:
     // https://github.com/rust-lang/rust/blob/614f273e9388ddd7804d5cbc80b8865068a3744e/src/librustc_resolve/macros.rs#L456
     // We follow what it did anyway :)
     if segments.len() == 1 && kind == PathKind::Plain {
         if let Some(_macro_call) = path.syntax().parent().and_then(ast::MacroCall::cast) {
             let syn_ctxt = span_map.span_for_range(path.segment()?.syntax().text_range()).ctx;
             if let Some(macro_call_id) = ctx.db.lookup_intern_syntax_context(syn_ctxt).outer_expn {
                 if ctx.db.lookup_intern_macro_call(macro_call_id).def.local_inner {
                     kind = match resolve_crate_root(ctx.db.upcast(), syn_ctxt) {
                         Some(crate_root) => PathKind::DollarCrate(crate_root),
                         None => PathKind::Crate,
                     }
                 }
             }
         }
     }

     let mod_path = Interned::new(ModPath::from_segments(kind, segments));
     return Some(Path::Normal {
         type_anchor,
         mod_path,
         generic_args: if generic_args.is_empty() { None } else { Some(generic_args.into()) },
     });

     fn qualifier(path: &ast::Path) -> Option<ast::Path> {
         if let Some(q) = path.qualifier() {
             return Some(q);
         }
         // FIXME: this bottom up traversal is not too precise.
         // Should we handle do a top-down analysis, recording results?
         let use_tree_list = path.syntax().ancestors().find_map(ast::UseTreeList::cast)?;
         let use_tree = use_tree_list.parent_use_tree();
         use_tree.path()
     }
 }

 pub(super) fn lower_generic_args(
     lower_ctx: &LowerCtx<'_>,
     node: ast::GenericArgList,
 ) -> Option<GenericArgs> {
     let mut args = Vec::new();
     let mut bindings = Vec::new();
     for generic_arg in node.generic_args() {
         match generic_arg {
             ast::GenericArg::TypeArg(type_arg) => {
                 let type_ref = TypeRef::from_ast_opt(lower_ctx, type_arg.ty());
                 args.push(GenericArg::Type(type_ref));
             }
             ast::GenericArg::AssocTypeArg(assoc_type_arg) => {
                 if assoc_type_arg.param_list().is_some() {
                     // We currently ignore associated return type bounds.
                     continue;
                 }
                 if let Some(name_ref) = assoc_type_arg.name_ref() {
                     let name = name_ref.as_name();
                     let args = assoc_type_arg
                         .generic_arg_list()
                         .and_then(|args| lower_generic_args(lower_ctx, args))
                         .map(Interned::new);
                     let type_ref = assoc_type_arg.ty().map(|it| TypeRef::from_ast(lower_ctx, it));
                     let bounds = if let Some(l) = assoc_type_arg.type_bound_list() {
                         l.bounds()
                             .map(|it| Interned::new(TypeBound::from_ast(lower_ctx, it)))
                             .collect()
                     } else {
                         Box::default()
                     };
                     bindings.push(AssociatedTypeBinding { name, args, type_ref, bounds });
                 }
             }
             ast::GenericArg::LifetimeArg(lifetime_arg) => {
                 if let Some(lifetime) = lifetime_arg.lifetime() {
                     let lifetime_ref = LifetimeRef::new(&lifetime);
                     args.push(GenericArg::Lifetime(lifetime_ref))
                 }
             }
             ast::GenericArg::ConstArg(arg) => {
                 let arg = ConstRef::from_const_arg(lower_ctx, Some(arg));
                 args.push(GenericArg::Const(arg))
             }
         }
     }

     if args.is_empty() && bindings.is_empty() {
         return None;
     }
     Some(GenericArgs {
         args: args.into_boxed_slice(),
         has_self_type: false,
         bindings: bindings.into_boxed_slice(),
         desugared_from_fn: false,
     })
 }

 /// Collect `GenericArgs` from the parts of a fn-like path, i.e. `Fn(X, Y)
 /// -> Z` (which desugars to `Fn<(X, Y), Output=Z>`).
 fn lower_generic_args_from_fn_path(
     ctx: &LowerCtx<'_>,
     params: Option<ast::ParamList>,
     ret_type: Option<ast::RetType>,
 ) -> Option<GenericArgs> {
     let params = params?;
     let mut param_types = Vec::new();
     for param in params.params() {
         let type_ref = TypeRef::from_ast_opt(ctx, param.ty());
         param_types.push(type_ref);
     }
     let args = Box::new([GenericArg::Type(TypeRef::Tuple(param_types))]);
     let bindings = if let Some(ret_type) = ret_type {
         let type_ref = TypeRef::from_ast_opt(ctx, ret_type.ty());
         Box::new([AssociatedTypeBinding {
             name: name![Output],
             args: None,
             type_ref: Some(type_ref),
             bounds: Box::default(),
         }])
     } else {
         // -> ()
         let type_ref = TypeRef::Tuple(Vec::new());
         Box::new([AssociatedTypeBinding {
             name: name![Output],
             args: None,
             type_ref: Some(type_ref),
             bounds: Box::default(),
         }])
     };
     Some(GenericArgs { args, has_self_type: false, bindings, desugared_from_fn: true })
 }
	//! Transforms syntax into `Path` objects, ideally with accounting for hygiene

	use std::iter;

	use crate::{lower::LowerCtx, type_ref::ConstRef};

	use hir_expand::{
	mod_path::resolve_crate_root,
	name::{name, AsName},
	};
	use intern::Interned;
	use syntax::ast::{self, AstNode, HasTypeBounds};

	use crate::{
	path::{AssociatedTypeBinding, GenericArg, GenericArgs, ModPath, Path, PathKind},
	type_ref::{LifetimeRef, TypeBound, TypeRef},
	};

	/// Converts an `ast::Path` to `Path`. Works with use trees.
	/// It correctly handles `$crate` based path from macro call.
	pub(super) fn lower_path(ctx: &LowerCtx<'_>, mut path: ast::Path) -> Option<Path> {
	let mut kind = PathKind::Plain;
	let mut type_anchor = None;
	let mut segments = Vec::new();
	let mut generic_args = Vec::new();
	let span_map = ctx.span_map();
	loop {
	let segment = path.segment()?;

	if segment.coloncolon_token().is_some() {
	kind = PathKind::Abs;
	}

	match segment.kind()? {
	ast::PathSegmentKind::Name(name_ref) => {
	if name_ref.text() == "$crate" {
	break kind = resolve_crate_root(
	ctx.db.upcast(),
	span_map.span_for_range(name_ref.syntax().text_range()).ctx,
	)
	.map(PathKind::DollarCrate)
	.unwrap_or(PathKind::Crate);
	}
	let name = name_ref.as_name();
	let args = segment
	.generic_arg_list()
	.and_then(\|it\| lower_generic_args(ctx, it))
	.or_else(\|\| {
	lower_generic_args_from_fn_path(
	ctx,
	segment.param_list(),
	segment.ret_type(),
	)
	})
	.map(Interned::new);
	if args.is_some() {
	generic_args.resize(segments.len(), None);
	generic_args.push(args);
	}
	segments.push(name);
	}
	ast::PathSegmentKind::SelfTypeKw => {
	segments.push(name![Self]);
	}
	ast::PathSegmentKind::Type { type_ref, trait_ref } => {
	assert!(path.qualifier().is_none()); // this can only occur at the first segment

	let self_type = TypeRef::from_ast(ctx, type_ref?);

	match trait_ref {
	// <T>::foo
	None => {
	type_anchor = Some(Interned::new(self_type));
	kind = PathKind::Plain;
	}
	// <T as Trait<A>>::Foo desugars to Trait<Self=T, A>::Foo
	Some(trait_ref) => {
	let Path::Normal { mod_path, generic_args: path_generic_args, .. } =
	Path::from_src(ctx, trait_ref.path()?)?
	else {
	return None;
	};
	let num_segments = mod_path.segments().len();
	kind = mod_path.kind;

	segments.extend(mod_path.segments().iter().cloned().rev());
	if let Some(path_generic_args) = path_generic_args {
	generic_args.resize(segments.len() - num_segments, None);
	generic_args.extend(Vec::from(path_generic_args).into_iter().rev());
	} else {
	generic_args.resize(segments.len(), None);
	}

	let self_type = GenericArg::Type(self_type);

	// Insert the type reference (T in the above example) as Self parameter for the trait
	let last_segment = generic_args.get_mut(segments.len() - num_segments)?;
	*last_segment = Some(Interned::new(match last_segment.take() {
	Some(it) => GenericArgs {
	args: iter::once(self_type)
	.chain(it.args.iter().cloned())
	.collect(),

	has_self_type: true,
	bindings: it.bindings.clone(),
	desugared_from_fn: it.desugared_from_fn,
	},
	None => GenericArgs {
	args: Box::new([self_type]),
	has_self_type: true,
	..GenericArgs::empty()
	},
	}));
	}
	}
	}
	ast::PathSegmentKind::CrateKw => {
	kind = PathKind::Crate;
	break;
	}
	ast::PathSegmentKind::SelfKw => {
	// don't break out if `self` is the last segment of a path, this mean we got a
	// use tree like `foo::{self}` which we want to resolve as `foo`
	if !segments.is_empty() {
	kind = PathKind::Super(0);
	break;
	}
	}
	ast::PathSegmentKind::SuperKw => {
	let nested_super_count = if let PathKind::Super(n) = kind { n } else { 0 };
	kind = PathKind::Super(nested_super_count + 1);
	}
	}
	path = match qualifier(&path) {
	Some(it) => it,
	None => break,
	};
	}
	segments.reverse();
	if !generic_args.is_empty() {
	generic_args.resize(segments.len(), None);
	generic_args.reverse();
	}

	if segments.is_empty() && kind == PathKind::Plain && type_anchor.is_none() {
	// plain empty paths don't exist, this means we got a single `self` segment as our path
	kind = PathKind::Super(0);
	}

	// handle local_inner_macros :
	// Basically, even in rustc it is quite hacky:
	// https://github.com/rust-lang/rust/blob/614f273e9388ddd7804d5cbc80b8865068a3744e/src/librustc_resolve/macros.rs#L456
	// We follow what it did anyway :)
	if segments.len() == 1 && kind == PathKind::Plain {
	if let Some(_macro_call) = path.syntax().parent().and_then(ast::MacroCall::cast) {
	let syn_ctxt = span_map.span_for_range(path.segment()?.syntax().text_range()).ctx;
	if let Some(macro_call_id) = ctx.db.lookup_intern_syntax_context(syn_ctxt).outer_expn {
	if ctx.db.lookup_intern_macro_call(macro_call_id).def.local_inner {
	kind = match resolve_crate_root(ctx.db.upcast(), syn_ctxt) {
	Some(crate_root) => PathKind::DollarCrate(crate_root),
	None => PathKind::Crate,
	}
	}
	}
	}
	}

	let mod_path = Interned::new(ModPath::from_segments(kind, segments));
	return Some(Path::Normal {
	type_anchor,
	mod_path,
	generic_args: if generic_args.is_empty() { None } else { Some(generic_args.into()) },
	});

	fn qualifier(path: &ast::Path) -> Option<ast::Path> {
	if let Some(q) = path.qualifier() {
	return Some(q);
	}
	// FIXME: this bottom up traversal is not too precise.
	// Should we handle do a top-down analysis, recording results?
	let use_tree_list = path.syntax().ancestors().find_map(ast::UseTreeList::cast)?;
	let use_tree = use_tree_list.parent_use_tree();
	use_tree.path()
	}
	}

	pub(super) fn lower_generic_args(
	lower_ctx: &LowerCtx<'_>,
	node: ast::GenericArgList,
	) -> Option<GenericArgs> {
	let mut args = Vec::new();
	let mut bindings = Vec::new();
	for generic_arg in node.generic_args() {
	match generic_arg {
	ast::GenericArg::TypeArg(type_arg) => {
	let type_ref = TypeRef::from_ast_opt(lower_ctx, type_arg.ty());
	args.push(GenericArg::Type(type_ref));
	}
	ast::GenericArg::AssocTypeArg(assoc_type_arg) => {
	if assoc_type_arg.param_list().is_some() {
	// We currently ignore associated return type bounds.
	continue;
	}
	if let Some(name_ref) = assoc_type_arg.name_ref() {
	let name = name_ref.as_name();
	let args = assoc_type_arg
	.generic_arg_list()
	.and_then(\|args\| lower_generic_args(lower_ctx, args))
	.map(Interned::new);
	let type_ref = assoc_type_arg.ty().map(\|it\| TypeRef::from_ast(lower_ctx, it));
	let bounds = if let Some(l) = assoc_type_arg.type_bound_list() {
	l.bounds()
	.map(\|it\| Interned::new(TypeBound::from_ast(lower_ctx, it)))
	.collect()
	} else {
	Box::default()
	};
	bindings.push(AssociatedTypeBinding { name, args, type_ref, bounds });
	}
	}
	ast::GenericArg::LifetimeArg(lifetime_arg) => {
	if let Some(lifetime) = lifetime_arg.lifetime() {
	let lifetime_ref = LifetimeRef::new(&lifetime);
	args.push(GenericArg::Lifetime(lifetime_ref))
	}
	}
	ast::GenericArg::ConstArg(arg) => {
	let arg = ConstRef::from_const_arg(lower_ctx, Some(arg));
	args.push(GenericArg::Const(arg))
	}
	}
	}

	if args.is_empty() && bindings.is_empty() {
	return None;
	}
	Some(GenericArgs {
	args: args.into_boxed_slice(),
	has_self_type: false,
	bindings: bindings.into_boxed_slice(),
	desugared_from_fn: false,
	})
	}

	/// Collect `GenericArgs` from the parts of a fn-like path, i.e. `Fn(X, Y)
	/// -> Z` (which desugars to `Fn<(X, Y), Output=Z>`).
	fn lower_generic_args_from_fn_path(
	ctx: &LowerCtx<'_>,
	params: Option<ast::ParamList>,
	ret_type: Option<ast::RetType>,
	) -> Option<GenericArgs> {
	let params = params?;
	let mut param_types = Vec::new();
	for param in params.params() {
	let type_ref = TypeRef::from_ast_opt(ctx, param.ty());
	param_types.push(type_ref);
	}
	let args = Box::new([GenericArg::Type(TypeRef::Tuple(param_types))]);
	let bindings = if let Some(ret_type) = ret_type {
	let type_ref = TypeRef::from_ast_opt(ctx, ret_type.ty());
	Box::new([AssociatedTypeBinding {
	name: name![Output],
	args: None,
	type_ref: Some(type_ref),
	bounds: Box::default(),
	}])
	} else {
	// -> ()
	let type_ref = TypeRef::Tuple(Vec::new());
	Box::new([AssociatedTypeBinding {
	name: name![Output],
	args: None,
	type_ref: Some(type_ref),
	bounds: Box::default(),
	}])
	};
	Some(GenericArgs { args, has_self_type: false, bindings, desugared_from_fn: true })
	}