rust/src/librustc_resolve/resolve_imports.rs
2015-11-14 16:21:30 +01:00

1097 lines
47 KiB
Rust

// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use self::ImportDirectiveSubclass::*;
use DefModifiers;
use Module;
use ModuleKind;
use Namespace::{self, TypeNS, ValueNS};
use NameBindings;
use NamespaceResult::{BoundResult, UnboundResult, UnknownResult};
use NamespaceResult;
use NameSearchType;
use ResolveResult;
use Resolver;
use UseLexicalScopeFlag;
use {names_to_string, module_to_string};
use {resolve_error, ResolutionError};
use build_reduced_graph;
use rustc::middle::def::*;
use rustc::middle::def_id::DefId;
use rustc::middle::privacy::*;
use syntax::ast::{NodeId, Name};
use syntax::attr::AttrMetaMethods;
use syntax::codemap::Span;
use std::mem::replace;
use std::rc::Rc;
/// Contains data for specific types of import directives.
#[derive(Copy, Clone,Debug)]
pub enum ImportDirectiveSubclass {
SingleImport(Name /* target */, Name /* source */),
GlobImport,
}
/// Whether an import can be shadowed by another import.
#[derive(Debug,PartialEq,Clone,Copy)]
pub enum Shadowable {
Always,
Never,
}
/// One import directive.
#[derive(Debug)]
pub struct ImportDirective {
pub module_path: Vec<Name>,
pub subclass: ImportDirectiveSubclass,
pub span: Span,
pub id: NodeId,
pub is_public: bool, // see note in ImportResolution about how to use this
pub shadowable: Shadowable,
}
impl ImportDirective {
pub fn new(module_path: Vec<Name>,
subclass: ImportDirectiveSubclass,
span: Span,
id: NodeId,
is_public: bool,
shadowable: Shadowable)
-> ImportDirective {
ImportDirective {
module_path: module_path,
subclass: subclass,
span: span,
id: id,
is_public: is_public,
shadowable: shadowable,
}
}
}
/// The item that an import resolves to.
#[derive(Clone,Debug)]
pub struct Target {
pub target_module: Rc<Module>,
pub bindings: Rc<NameBindings>,
pub shadowable: Shadowable,
}
impl Target {
pub fn new(target_module: Rc<Module>,
bindings: Rc<NameBindings>,
shadowable: Shadowable)
-> Target {
Target {
target_module: target_module,
bindings: bindings,
shadowable: shadowable,
}
}
}
/// An ImportResolution represents a particular `use` directive.
#[derive(Debug)]
pub struct ImportResolution {
/// Whether this resolution came from a `use` or a `pub use`. Note that this
/// should *not* be used whenever resolution is being performed. Privacy
/// testing occurs during a later phase of compilation.
pub is_public: bool,
// The number of outstanding references to this name. When this reaches
// zero, outside modules can count on the targets being correct. Before
// then, all bets are off; future imports could override this name.
// Note that this is usually either 0 or 1 - shadowing is forbidden the only
// way outstanding_references is > 1 in a legal program is if the name is
// used in both namespaces.
pub outstanding_references: usize,
/// The value that this `use` directive names, if there is one.
pub value_target: Option<Target>,
/// The source node of the `use` directive leading to the value target
/// being non-none
pub value_id: NodeId,
/// The type that this `use` directive names, if there is one.
pub type_target: Option<Target>,
/// The source node of the `use` directive leading to the type target
/// being non-none
pub type_id: NodeId,
}
impl ImportResolution {
pub fn new(id: NodeId, is_public: bool) -> ImportResolution {
ImportResolution {
type_id: id,
value_id: id,
outstanding_references: 0,
value_target: None,
type_target: None,
is_public: is_public,
}
}
pub fn target_for_namespace(&self, namespace: Namespace) -> Option<Target> {
match namespace {
TypeNS => self.type_target.clone(),
ValueNS => self.value_target.clone(),
}
}
pub fn id(&self, namespace: Namespace) -> NodeId {
match namespace {
TypeNS => self.type_id,
ValueNS => self.value_id,
}
}
pub fn shadowable(&self, namespace: Namespace) -> Shadowable {
let target = self.target_for_namespace(namespace);
if target.is_none() {
return Shadowable::Always;
}
target.unwrap().shadowable
}
pub fn set_target_and_id(&mut self, namespace: Namespace, target: Option<Target>, id: NodeId) {
match namespace {
TypeNS => {
self.type_target = target;
self.type_id = id;
}
ValueNS => {
self.value_target = target;
self.value_id = id;
}
}
}
}
struct ImportResolvingError {
span: Span,
path: String,
help: String,
}
struct ImportResolver<'a, 'b: 'a, 'tcx: 'b> {
resolver: &'a mut Resolver<'b, 'tcx>,
}
impl<'a, 'b:'a, 'tcx:'b> ImportResolver<'a, 'b, 'tcx> {
// Import resolution
//
// This is a fixed-point algorithm. We resolve imports until our efforts
// are stymied by an unresolved import; then we bail out of the current
// module and continue. We terminate successfully once no more imports
// remain or unsuccessfully when no forward progress in resolving imports
// is made.
/// Resolves all imports for the crate. This method performs the fixed-
/// point iteration.
fn resolve_imports(&mut self) {
let mut i = 0;
let mut prev_unresolved_imports = 0;
loop {
debug!("(resolving imports) iteration {}, {} imports left",
i,
self.resolver.unresolved_imports);
let module_root = self.resolver.graph_root.get_module();
let errors = self.resolve_imports_for_module_subtree(module_root.clone());
if self.resolver.unresolved_imports == 0 {
debug!("(resolving imports) success");
break;
}
if self.resolver.unresolved_imports == prev_unresolved_imports {
// resolving failed
if errors.len() > 0 {
for e in errors {
resolve_error(self.resolver,
e.span,
ResolutionError::UnresolvedImport(Some((&e.path, &e.help))));
}
} else {
// Report unresolved imports only if no hard error was already reported
// to avoid generating multiple errors on the same import.
// Imports that are still indeterminate at this point are actually blocked
// by errored imports, so there is no point reporting them.
self.resolver.report_unresolved_imports(module_root);
}
break;
}
i += 1;
prev_unresolved_imports = self.resolver.unresolved_imports;
}
}
/// Attempts to resolve imports for the given module and all of its
/// submodules.
fn resolve_imports_for_module_subtree(&mut self,
module_: Rc<Module>)
-> Vec<ImportResolvingError> {
let mut errors = Vec::new();
debug!("(resolving imports for module subtree) resolving {}",
module_to_string(&*module_));
let orig_module = replace(&mut self.resolver.current_module, module_.clone());
errors.extend(self.resolve_imports_for_module(module_.clone()));
self.resolver.current_module = orig_module;
build_reduced_graph::populate_module_if_necessary(self.resolver, &module_);
for (_, child_node) in module_.children.borrow().iter() {
match child_node.get_module_if_available() {
None => {
// Nothing to do.
}
Some(child_module) => {
errors.extend(self.resolve_imports_for_module_subtree(child_module));
}
}
}
for (_, child_module) in module_.anonymous_children.borrow().iter() {
errors.extend(self.resolve_imports_for_module_subtree(child_module.clone()));
}
errors
}
/// Attempts to resolve imports for the given module only.
fn resolve_imports_for_module(&mut self, module: Rc<Module>) -> Vec<ImportResolvingError> {
let mut errors = Vec::new();
if module.all_imports_resolved() {
debug!("(resolving imports for module) all imports resolved for {}",
module_to_string(&*module));
return errors;
}
let mut imports = module.imports.borrow_mut();
let import_count = imports.len();
let mut indeterminate_imports = Vec::new();
while module.resolved_import_count.get() + indeterminate_imports.len() < import_count {
let import_index = module.resolved_import_count.get();
match self.resolve_import_for_module(module.clone(), &imports[import_index]) {
ResolveResult::Failed(err) => {
let import_directive = &imports[import_index];
let (span, help) = match err {
Some((span, msg)) => (span, format!(". {}", msg)),
None => (import_directive.span, String::new()),
};
errors.push(ImportResolvingError {
span: span,
path: import_path_to_string(&import_directive.module_path,
import_directive.subclass),
help: help,
});
}
ResolveResult::Indeterminate => {}
ResolveResult::Success(()) => {
// count success
module.resolved_import_count
.set(module.resolved_import_count.get() + 1);
continue;
}
}
// This resolution was not successful, keep it for later
indeterminate_imports.push(imports.swap_remove(import_index));
}
imports.extend(indeterminate_imports);
errors
}
/// Attempts to resolve the given import. The return value indicates
/// failure if we're certain the name does not exist, indeterminate if we
/// don't know whether the name exists at the moment due to other
/// currently-unresolved imports, or success if we know the name exists.
/// If successful, the resolved bindings are written into the module.
fn resolve_import_for_module(&mut self,
module_: Rc<Module>,
import_directive: &ImportDirective)
-> ResolveResult<()> {
let mut resolution_result = ResolveResult::Failed(None);
let module_path = &import_directive.module_path;
debug!("(resolving import for module) resolving import `{}::...` in `{}`",
names_to_string(&module_path[..]),
module_to_string(&*module_));
// First, resolve the module path for the directive, if necessary.
let container = if module_path.is_empty() {
// Use the crate root.
Some((self.resolver.graph_root.get_module(), LastMod(AllPublic)))
} else {
match self.resolver.resolve_module_path(module_.clone(),
&module_path[..],
UseLexicalScopeFlag::DontUseLexicalScope,
import_directive.span,
NameSearchType::ImportSearch) {
ResolveResult::Failed(err) => {
resolution_result = ResolveResult::Failed(err);
None
}
ResolveResult::Indeterminate => {
resolution_result = ResolveResult::Indeterminate;
None
}
ResolveResult::Success(container) => Some(container),
}
};
match container {
None => {}
Some((containing_module, lp)) => {
// We found the module that the target is contained
// within. Attempt to resolve the import within it.
match import_directive.subclass {
SingleImport(target, source) => {
resolution_result = self.resolve_single_import(&module_,
containing_module,
target,
source,
import_directive,
lp);
}
GlobImport => {
resolution_result = self.resolve_glob_import(&module_,
containing_module,
import_directive,
lp);
}
}
}
}
// Decrement the count of unresolved imports.
match resolution_result {
ResolveResult::Success(()) => {
assert!(self.resolver.unresolved_imports >= 1);
self.resolver.unresolved_imports -= 1;
}
_ => {
// Nothing to do here; just return the error.
}
}
// Decrement the count of unresolved globs if necessary. But only if
// the resolution result is a success -- other cases will
// be handled by the main loop.
if resolution_result.success() {
match import_directive.subclass {
GlobImport => {
module_.dec_glob_count();
if import_directive.is_public {
module_.dec_pub_glob_count();
}
}
SingleImport(..) => {
// Ignore.
}
}
if import_directive.is_public {
module_.dec_pub_count();
}
}
return resolution_result;
}
fn resolve_single_import(&mut self,
module_: &Module,
target_module: Rc<Module>,
target: Name,
source: Name,
directive: &ImportDirective,
lp: LastPrivate)
-> ResolveResult<()> {
debug!("(resolving single import) resolving `{}` = `{}::{}` from `{}` id {}, last \
private {:?}",
target,
module_to_string(&*target_module),
source,
module_to_string(module_),
directive.id,
lp);
let lp = match lp {
LastMod(lp) => lp,
LastImport {..} => {
self.resolver
.session
.span_bug(directive.span, "not expecting Import here, must be LastMod")
}
};
// We need to resolve both namespaces for this to succeed.
//
let mut value_result = UnknownResult;
let mut type_result = UnknownResult;
// Search for direct children of the containing module.
build_reduced_graph::populate_module_if_necessary(self.resolver, &target_module);
match target_module.children.borrow().get(&source) {
None => {
// Continue.
}
Some(ref child_name_bindings) => {
// pub_err makes sure we don't give the same error twice.
let mut pub_err = false;
if child_name_bindings.defined_in_namespace(ValueNS) {
debug!("(resolving single import) found value binding");
value_result = BoundResult(target_module.clone(),
(*child_name_bindings).clone());
if directive.is_public && !child_name_bindings.is_public(ValueNS) {
let msg = format!("`{}` is private, and cannot be reexported", source);
let note_msg = format!("Consider marking `{}` as `pub` in the imported \
module",
source);
span_err!(self.resolver.session, directive.span, E0364, "{}", &msg);
self.resolver.session.span_note(directive.span, &note_msg);
pub_err = true;
}
}
if child_name_bindings.defined_in_namespace(TypeNS) {
debug!("(resolving single import) found type binding");
type_result = BoundResult(target_module.clone(),
(*child_name_bindings).clone());
if !pub_err && directive.is_public && !child_name_bindings.is_public(TypeNS) {
let msg = format!("`{}` is private, and cannot be reexported", source);
let note_msg = format!("Consider declaring module `{}` as a `pub mod`",
source);
span_err!(self.resolver.session, directive.span, E0365, "{}", &msg);
self.resolver.session.span_note(directive.span, &note_msg);
}
}
}
}
// Unless we managed to find a result in both namespaces (unlikely),
// search imports as well.
let mut value_used_reexport = false;
let mut type_used_reexport = false;
match (value_result.clone(), type_result.clone()) {
(BoundResult(..), BoundResult(..)) => {} // Continue.
_ => {
// If there is an unresolved glob at this point in the
// containing module, bail out. We don't know enough to be
// able to resolve this import.
if target_module.pub_glob_count.get() > 0 {
debug!("(resolving single import) unresolved pub glob; bailing out");
return ResolveResult::Indeterminate;
}
// Now search the exported imports within the containing module.
match target_module.import_resolutions.borrow().get(&source) {
None => {
debug!("(resolving single import) no import");
// The containing module definitely doesn't have an
// exported import with the name in question. We can
// therefore accurately report that the names are
// unbound.
if value_result.is_unknown() {
value_result = UnboundResult;
}
if type_result.is_unknown() {
type_result = UnboundResult;
}
}
Some(import_resolution) if import_resolution.outstanding_references == 0 => {
fn get_binding(this: &mut Resolver,
import_resolution: &ImportResolution,
namespace: Namespace,
source: Name)
-> NamespaceResult {
// Import resolutions must be declared with "pub"
// in order to be exported.
if !import_resolution.is_public {
return UnboundResult;
}
match import_resolution.target_for_namespace(namespace) {
None => {
return UnboundResult;
}
Some(Target {
target_module,
bindings,
shadowable: _
}) => {
debug!("(resolving single import) found import in ns {:?}",
namespace);
let id = import_resolution.id(namespace);
// track used imports and extern crates as well
this.used_imports.insert((id, namespace));
this.record_import_use(id, source);
match target_module.def_id.get() {
Some(DefId{krate: kid, ..}) => {
this.used_crates.insert(kid);
}
_ => {}
}
return BoundResult(target_module, bindings);
}
}
}
// The name is an import which has been fully
// resolved. We can, therefore, just follow it.
if value_result.is_unknown() {
value_result = get_binding(self.resolver,
import_resolution,
ValueNS,
source);
value_used_reexport = import_resolution.is_public;
}
if type_result.is_unknown() {
type_result = get_binding(self.resolver,
import_resolution,
TypeNS,
source);
type_used_reexport = import_resolution.is_public;
}
}
Some(_) => {
// If target_module is the same module whose import we are resolving
// and there it has an unresolved import with the same name as `source`,
// then the user is actually trying to import an item that is declared
// in the same scope
//
// e.g
// use self::submodule;
// pub mod submodule;
//
// In this case we continue as if we resolved the import and let the
// check_for_conflicts_between_imports_and_items call below handle
// the conflict
match (module_.def_id.get(), target_module.def_id.get()) {
(Some(id1), Some(id2)) if id1 == id2 => {
if value_result.is_unknown() {
value_result = UnboundResult;
}
if type_result.is_unknown() {
type_result = UnboundResult;
}
}
_ => {
// The import is unresolved. Bail out.
debug!("(resolving single import) unresolved import; bailing out");
return ResolveResult::Indeterminate;
}
}
}
}
}
}
let mut value_used_public = false;
let mut type_used_public = false;
// If we didn't find a result in the type namespace, search the
// external modules.
match type_result {
BoundResult(..) => {}
_ => {
match target_module.external_module_children.borrow_mut().get(&source).cloned() {
None => {} // Continue.
Some(module) => {
debug!("(resolving single import) found external module");
// track the module as used.
match module.def_id.get() {
Some(DefId{krate: kid, ..}) => {
self.resolver.used_crates.insert(kid);
}
_ => {}
}
let name_bindings =
Rc::new(Resolver::create_name_bindings_from_module(module));
type_result = BoundResult(target_module.clone(), name_bindings);
type_used_public = true;
}
}
}
}
// We've successfully resolved the import. Write the results in.
let mut import_resolutions = module_.import_resolutions.borrow_mut();
let import_resolution = import_resolutions.get_mut(&target).unwrap();
{
let mut check_and_write_import = |namespace, result: &_, used_public: &mut bool| {
let namespace_name = match namespace {
TypeNS => "type",
ValueNS => "value",
};
match *result {
BoundResult(ref target_module, ref name_bindings) => {
debug!("(resolving single import) found {:?} target: {:?}",
namespace_name,
name_bindings.def_for_namespace(namespace));
self.check_for_conflicting_import(&import_resolution,
directive.span,
target,
namespace);
self.check_that_import_is_importable(&**name_bindings,
directive.span,
target,
namespace);
let target = Some(Target::new(target_module.clone(),
name_bindings.clone(),
directive.shadowable));
import_resolution.set_target_and_id(namespace, target, directive.id);
import_resolution.is_public = directive.is_public;
*used_public = name_bindings.defined_in_public_namespace(namespace);
}
UnboundResult => {
// Continue.
}
UnknownResult => {
panic!("{:?} result should be known at this point", namespace_name);
}
}
};
check_and_write_import(ValueNS, &value_result, &mut value_used_public);
check_and_write_import(TypeNS, &type_result, &mut type_used_public);
}
self.check_for_conflicts_between_imports_and_items(module_,
import_resolution,
directive.span,
target);
if value_result.is_unbound() && type_result.is_unbound() {
let msg = format!("There is no `{}` in `{}`",
source,
module_to_string(&target_module));
return ResolveResult::Failed(Some((directive.span, msg)));
}
let value_used_public = value_used_reexport || value_used_public;
let type_used_public = type_used_reexport || type_used_public;
assert!(import_resolution.outstanding_references >= 1);
import_resolution.outstanding_references -= 1;
// Record what this import resolves to for later uses in documentation,
// this may resolve to either a value or a type, but for documentation
// purposes it's good enough to just favor one over the other.
let value_def_and_priv = import_resolution.value_target.as_ref().map(|target| {
let def = target.bindings.def_for_namespace(ValueNS).unwrap();
(def,
if value_used_public {
lp
} else {
DependsOn(def.def_id())
})
});
let type_def_and_priv = import_resolution.type_target.as_ref().map(|target| {
let def = target.bindings.def_for_namespace(TypeNS).unwrap();
(def,
if type_used_public {
lp
} else {
DependsOn(def.def_id())
})
});
let import_lp = LastImport {
value_priv: value_def_and_priv.map(|(_, p)| p),
value_used: Used,
type_priv: type_def_and_priv.map(|(_, p)| p),
type_used: Used,
};
if let Some((def, _)) = value_def_and_priv {
self.resolver.def_map.borrow_mut().insert(directive.id,
PathResolution {
base_def: def,
last_private: import_lp,
depth: 0,
});
}
if let Some((def, _)) = type_def_and_priv {
self.resolver.def_map.borrow_mut().insert(directive.id,
PathResolution {
base_def: def,
last_private: import_lp,
depth: 0,
});
}
debug!("(resolving single import) successfully resolved import");
return ResolveResult::Success(());
}
// Resolves a glob import. Note that this function cannot fail; it either
// succeeds or bails out (as importing * from an empty module or a module
// that exports nothing is valid). target_module is the module we are
// actually importing, i.e., `foo` in `use foo::*`.
fn resolve_glob_import(&mut self,
module_: &Module,
target_module: Rc<Module>,
import_directive: &ImportDirective,
lp: LastPrivate)
-> ResolveResult<()> {
let id = import_directive.id;
let is_public = import_directive.is_public;
// This function works in a highly imperative manner; it eagerly adds
// everything it can to the list of import resolutions of the module
// node.
debug!("(resolving glob import) resolving glob import {}", id);
// We must bail out if the node has unresolved imports of any kind
// (including globs).
if (*target_module).pub_count.get() > 0 {
debug!("(resolving glob import) target module has unresolved pub imports; bailing out");
return ResolveResult::Indeterminate;
}
// Add all resolved imports from the containing module.
let import_resolutions = target_module.import_resolutions.borrow();
if module_.import_resolutions.borrow_state() != ::std::cell::BorrowState::Unused {
// In this case, target_module == module_
// This means we are trying to glob import a module into itself,
// and it is a no-go
debug!("(resolving glob imports) target module is current module; giving up");
return ResolveResult::Failed(Some((import_directive.span,
"Cannot glob-import a module into itself.".into())));
}
for (name, target_import_resolution) in import_resolutions.iter() {
debug!("(resolving glob import) writing module resolution {} into `{}`",
*name,
module_to_string(module_));
if !target_import_resolution.is_public {
debug!("(resolving glob import) nevermind, just kidding");
continue;
}
// Here we merge two import resolutions.
let mut import_resolutions = module_.import_resolutions.borrow_mut();
match import_resolutions.get_mut(name) {
Some(dest_import_resolution) => {
// Merge the two import resolutions at a finer-grained
// level.
match target_import_resolution.value_target {
None => {
// Continue.
}
Some(ref value_target) => {
self.check_for_conflicting_import(&dest_import_resolution,
import_directive.span,
*name,
ValueNS);
dest_import_resolution.value_target = Some(value_target.clone());
}
}
match target_import_resolution.type_target {
None => {
// Continue.
}
Some(ref type_target) => {
self.check_for_conflicting_import(&dest_import_resolution,
import_directive.span,
*name,
TypeNS);
dest_import_resolution.type_target = Some(type_target.clone());
}
}
dest_import_resolution.is_public = is_public;
continue;
}
None => {}
}
// Simple: just copy the old import resolution.
let mut new_import_resolution = ImportResolution::new(id, is_public);
new_import_resolution.value_target = target_import_resolution.value_target.clone();
new_import_resolution.type_target = target_import_resolution.type_target.clone();
import_resolutions.insert(*name, new_import_resolution);
}
// Add all children from the containing module.
build_reduced_graph::populate_module_if_necessary(self.resolver, &target_module);
for (&name, name_bindings) in target_module.children.borrow().iter() {
self.merge_import_resolution(module_,
target_module.clone(),
import_directive,
name,
name_bindings.clone());
}
// Add external module children from the containing module.
for (&name, module) in target_module.external_module_children.borrow().iter() {
let name_bindings = Rc::new(Resolver::create_name_bindings_from_module(module.clone()));
self.merge_import_resolution(module_,
target_module.clone(),
import_directive,
name,
name_bindings);
}
// Record the destination of this import
if let Some(did) = target_module.def_id.get() {
self.resolver.def_map.borrow_mut().insert(id,
PathResolution {
base_def: DefMod(did),
last_private: lp,
depth: 0,
});
}
debug!("(resolving glob import) successfully resolved import");
return ResolveResult::Success(());
}
fn merge_import_resolution(&mut self,
module_: &Module,
containing_module: Rc<Module>,
import_directive: &ImportDirective,
name: Name,
name_bindings: Rc<NameBindings>) {
let id = import_directive.id;
let is_public = import_directive.is_public;
let mut import_resolutions = module_.import_resolutions.borrow_mut();
let dest_import_resolution = import_resolutions.entry(name)
.or_insert_with(|| {
ImportResolution::new(id, is_public)
});
debug!("(resolving glob import) writing resolution `{}` in `{}` to `{}`",
name,
module_to_string(&*containing_module),
module_to_string(module_));
// Merge the child item into the import resolution.
{
let mut merge_child_item = |namespace| {
let modifier = DefModifiers::IMPORTABLE | DefModifiers::PUBLIC;
if name_bindings.defined_in_namespace_with(namespace, modifier) {
let namespace_name = match namespace {
TypeNS => "type",
ValueNS => "value",
};
debug!("(resolving glob import) ... for {} target", namespace_name);
if dest_import_resolution.shadowable(namespace) == Shadowable::Never {
let msg = format!("a {} named `{}` has already been imported in this \
module",
namespace_name,
name);
span_err!(self.resolver.session,
import_directive.span,
E0251,
"{}",
msg);
} else {
let target = Target::new(containing_module.clone(),
name_bindings.clone(),
import_directive.shadowable);
dest_import_resolution.set_target_and_id(namespace, Some(target), id);
}
}
};
merge_child_item(ValueNS);
merge_child_item(TypeNS);
}
dest_import_resolution.is_public = is_public;
self.check_for_conflicts_between_imports_and_items(module_,
dest_import_resolution,
import_directive.span,
name);
}
/// Checks that imported names and items don't have the same name.
fn check_for_conflicting_import(&mut self,
import_resolution: &ImportResolution,
import_span: Span,
name: Name,
namespace: Namespace) {
let target = import_resolution.target_for_namespace(namespace);
debug!("check_for_conflicting_import: {}; target exists: {}",
name,
target.is_some());
match target {
Some(ref target) if target.shadowable != Shadowable::Always => {
let ns_word = match namespace {
TypeNS => {
if let Some(ref ty_def) = *target.bindings.type_def.borrow() {
match ty_def.module_def {
Some(ref module) if module.kind.get() ==
ModuleKind::NormalModuleKind => "module",
Some(ref module) if module.kind.get() ==
ModuleKind::TraitModuleKind => "trait",
_ => "type",
}
} else {
"type"
}
}
ValueNS => "value",
};
span_err!(self.resolver.session,
import_span,
E0252,
"a {} named `{}` has already been imported in this module",
ns_word,
name);
let use_id = import_resolution.id(namespace);
let item = self.resolver.ast_map.expect_item(use_id);
// item is syntax::ast::Item;
span_note!(self.resolver.session,
item.span,
"previous import of `{}` here",
name);
}
Some(_) | None => {}
}
}
/// Checks that an import is actually importable
fn check_that_import_is_importable(&mut self,
name_bindings: &NameBindings,
import_span: Span,
name: Name,
namespace: Namespace) {
if !name_bindings.defined_in_namespace_with(namespace, DefModifiers::IMPORTABLE) {
let msg = format!("`{}` is not directly importable", name);
span_err!(self.resolver.session, import_span, E0253, "{}", &msg[..]);
}
}
/// Checks that imported names and items don't have the same name.
fn check_for_conflicts_between_imports_and_items(&mut self,
module: &Module,
import_resolution: &ImportResolution,
import_span: Span,
name: Name) {
// First, check for conflicts between imports and `extern crate`s.
if module.external_module_children
.borrow()
.contains_key(&name) {
match import_resolution.type_target {
Some(ref target) if target.shadowable != Shadowable::Always => {
let msg = format!("import `{0}` conflicts with imported crate in this module \
(maybe you meant `use {0}::*`?)",
name);
span_err!(self.resolver.session, import_span, E0254, "{}", &msg[..]);
}
Some(_) | None => {}
}
}
// Check for item conflicts.
let children = module.children.borrow();
let name_bindings = match children.get(&name) {
None => {
// There can't be any conflicts.
return;
}
Some(ref name_bindings) => (*name_bindings).clone(),
};
match import_resolution.value_target {
Some(ref target) if target.shadowable != Shadowable::Always => {
if let Some(ref value) = *name_bindings.value_def.borrow() {
span_err!(self.resolver.session,
import_span,
E0255,
"import `{}` conflicts with value in this module",
name);
if let Some(span) = value.value_span {
self.resolver.session.span_note(span, "conflicting value here");
}
}
}
Some(_) | None => {}
}
match import_resolution.type_target {
Some(ref target) if target.shadowable != Shadowable::Always => {
if let Some(ref ty) = *name_bindings.type_def.borrow() {
let (what, note) = match ty.module_def {
Some(ref module) if module.kind.get() == ModuleKind::NormalModuleKind =>
("existing submodule", "note conflicting module here"),
Some(ref module) if module.kind.get() == ModuleKind::TraitModuleKind =>
("trait in this module", "note conflicting trait here"),
_ => ("type in this module", "note conflicting type here"),
};
span_err!(self.resolver.session,
import_span,
E0256,
"import `{}` conflicts with {}",
name,
what);
if let Some(span) = ty.type_span {
self.resolver.session.span_note(span, note);
}
}
}
Some(_) | None => {}
}
}
}
fn import_path_to_string(names: &[Name], subclass: ImportDirectiveSubclass) -> String {
if names.is_empty() {
import_directive_subclass_to_string(subclass)
} else {
(format!("{}::{}",
names_to_string(names),
import_directive_subclass_to_string(subclass)))
.to_string()
}
}
fn import_directive_subclass_to_string(subclass: ImportDirectiveSubclass) -> String {
match subclass {
SingleImport(_, source) => source.to_string(),
GlobImport => "*".to_string(),
}
}
pub fn resolve_imports(resolver: &mut Resolver) {
let mut import_resolver = ImportResolver { resolver: resolver };
import_resolver.resolve_imports();
}