rust-clippy/clippy_lints/src/utils/mod.rs
2020-11-25 12:22:58 +01:00

1723 lines
56 KiB
Rust
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#[macro_use]
pub mod sym;
#[allow(clippy::module_name_repetitions)]
pub mod ast_utils;
pub mod attrs;
pub mod author;
pub mod camel_case;
pub mod comparisons;
pub mod conf;
pub mod constants;
mod diagnostics;
pub mod eager_or_lazy;
pub mod higher;
mod hir_utils;
pub mod inspector;
pub mod internal_lints;
pub mod numeric_literal;
pub mod paths;
pub mod ptr;
pub mod qualify_min_const_fn;
pub mod sugg;
pub mod usage;
pub mod visitors;
pub use self::attrs::*;
pub use self::diagnostics::*;
pub use self::hir_utils::{both, eq_expr_value, over, SpanlessEq, SpanlessHash};
use std::borrow::Cow;
use std::collections::hash_map::Entry;
use std::hash::BuildHasherDefault;
use std::mem;
use if_chain::if_chain;
use rustc_ast::ast::{self, Attribute, LitKind};
use rustc_attr as attr;
use rustc_data_structures::fx::FxHashMap;
use rustc_errors::Applicability;
use rustc_hir as hir;
use rustc_hir::def::{DefKind, Res};
use rustc_hir::def_id::{DefId, CRATE_DEF_INDEX, LOCAL_CRATE};
use rustc_hir::intravisit::{NestedVisitorMap, Visitor};
use rustc_hir::Node;
use rustc_hir::{
def, Arm, Block, Body, Constness, Crate, Expr, ExprKind, FnDecl, HirId, ImplItem, ImplItemKind, Item, ItemKind,
MatchSource, Param, Pat, PatKind, Path, PathSegment, QPath, TraitItem, TraitItemKind, TraitRef, TyKind, Unsafety,
};
use rustc_infer::infer::TyCtxtInferExt;
use rustc_lint::{LateContext, Level, Lint, LintContext};
use rustc_middle::hir::map::Map;
use rustc_middle::ty::subst::{GenericArg, GenericArgKind};
use rustc_middle::ty::{self, layout::IntegerExt, Ty, TyCtxt, TypeFoldable};
use rustc_session::Session;
use rustc_span::hygiene::{ExpnKind, MacroKind};
use rustc_span::source_map::original_sp;
use rustc_span::sym as rustc_sym;
use rustc_span::symbol::{self, kw, Symbol};
use rustc_span::{BytePos, Pos, Span, DUMMY_SP};
use rustc_target::abi::Integer;
use rustc_trait_selection::traits::query::normalize::AtExt;
use semver::{Version, VersionReq};
use smallvec::SmallVec;
use crate::consts::{constant, Constant};
pub fn parse_msrv(msrv: &str, sess: Option<&Session>, span: Option<Span>) -> Option<VersionReq> {
if let Ok(version) = VersionReq::parse(msrv) {
return Some(version);
} else if let Some(sess) = sess {
if let Some(span) = span {
sess.span_err(span, &format!("`{}` is not a valid Rust version", msrv));
}
}
None
}
pub fn meets_msrv(msrv: Option<&VersionReq>, lint_msrv: &Version) -> bool {
msrv.map_or(true, |msrv| !msrv.matches(lint_msrv))
}
macro_rules! extract_msrv_attr {
(LateContext) => {
extract_msrv_attr!(@LateContext, ());
};
(EarlyContext) => {
extract_msrv_attr!(@EarlyContext);
};
(@$context:ident$(, $call:tt)?) => {
fn enter_lint_attrs(&mut self, cx: &rustc_lint::$context<'tcx>, attrs: &'tcx [rustc_ast::ast::Attribute]) {
use $crate::utils::get_unique_inner_attr;
match get_unique_inner_attr(cx.sess$($call)?, attrs, "msrv") {
Some(msrv_attr) => {
if let Some(msrv) = msrv_attr.value_str() {
self.msrv = $crate::utils::parse_msrv(
&msrv.to_string(),
Some(cx.sess$($call)?),
Some(msrv_attr.span),
);
} else {
cx.sess$($call)?.span_err(msrv_attr.span, "bad clippy attribute");
}
},
_ => (),
}
}
};
}
/// Returns `true` if the two spans come from differing expansions (i.e., one is
/// from a macro and one isn't).
#[must_use]
pub fn differing_macro_contexts(lhs: Span, rhs: Span) -> bool {
rhs.ctxt() != lhs.ctxt()
}
/// Returns `true` if the given `NodeId` is inside a constant context
///
/// # Example
///
/// ```rust,ignore
/// if in_constant(cx, expr.hir_id) {
/// // Do something
/// }
/// ```
pub fn in_constant(cx: &LateContext<'_>, id: HirId) -> bool {
let parent_id = cx.tcx.hir().get_parent_item(id);
match cx.tcx.hir().get(parent_id) {
Node::Item(&Item {
kind: ItemKind::Const(..) | ItemKind::Static(..),
..
})
| Node::TraitItem(&TraitItem {
kind: TraitItemKind::Const(..),
..
})
| Node::ImplItem(&ImplItem {
kind: ImplItemKind::Const(..),
..
})
| Node::AnonConst(_) => true,
Node::Item(&Item {
kind: ItemKind::Fn(ref sig, ..),
..
})
| Node::ImplItem(&ImplItem {
kind: ImplItemKind::Fn(ref sig, _),
..
}) => sig.header.constness == Constness::Const,
_ => false,
}
}
/// Returns `true` if this `span` was expanded by any macro.
#[must_use]
pub fn in_macro(span: Span) -> bool {
if span.from_expansion() {
!matches!(span.ctxt().outer_expn_data().kind, ExpnKind::Desugaring(..))
} else {
false
}
}
// If the snippet is empty, it's an attribute that was inserted during macro
// expansion and we want to ignore those, because they could come from external
// sources that the user has no control over.
// For some reason these attributes don't have any expansion info on them, so
// we have to check it this way until there is a better way.
pub fn is_present_in_source<T: LintContext>(cx: &T, span: Span) -> bool {
if let Some(snippet) = snippet_opt(cx, span) {
if snippet.is_empty() {
return false;
}
}
true
}
/// Checks if given pattern is a wildcard (`_`)
pub fn is_wild<'tcx>(pat: &impl std::ops::Deref<Target = Pat<'tcx>>) -> bool {
matches!(pat.kind, PatKind::Wild)
}
/// Checks if type is struct, enum or union type with the given def path.
///
/// If the type is a diagnostic item, use `is_type_diagnostic_item` instead.
/// If you change the signature, remember to update the internal lint `MatchTypeOnDiagItem`
pub fn match_type(cx: &LateContext<'_>, ty: Ty<'_>, path: &[&str]) -> bool {
match ty.kind() {
ty::Adt(adt, _) => match_def_path(cx, adt.did, path),
_ => false,
}
}
/// Checks if the type is equal to a diagnostic item
///
/// If you change the signature, remember to update the internal lint `MatchTypeOnDiagItem`
pub fn is_type_diagnostic_item(cx: &LateContext<'_>, ty: Ty<'_>, diag_item: Symbol) -> bool {
match ty.kind() {
ty::Adt(adt, _) => cx.tcx.is_diagnostic_item(diag_item, adt.did),
_ => false,
}
}
/// Checks if the type is equal to a lang item
pub fn is_type_lang_item(cx: &LateContext<'_>, ty: Ty<'_>, lang_item: hir::LangItem) -> bool {
match ty.kind() {
ty::Adt(adt, _) => cx.tcx.lang_items().require(lang_item).unwrap() == adt.did,
_ => false,
}
}
/// Checks if the method call given in `expr` belongs to the given trait.
pub fn match_trait_method(cx: &LateContext<'_>, expr: &Expr<'_>, path: &[&str]) -> bool {
let def_id = cx.typeck_results().type_dependent_def_id(expr.hir_id).unwrap();
let trt_id = cx.tcx.trait_of_item(def_id);
trt_id.map_or(false, |trt_id| match_def_path(cx, trt_id, path))
}
/// Checks if an expression references a variable of the given name.
pub fn match_var(expr: &Expr<'_>, var: Symbol) -> bool {
if let ExprKind::Path(QPath::Resolved(None, ref path)) = expr.kind {
if let [p] = path.segments {
return p.ident.name == var;
}
}
false
}
pub fn last_path_segment<'tcx>(path: &QPath<'tcx>) -> &'tcx PathSegment<'tcx> {
match *path {
QPath::Resolved(_, ref path) => path.segments.last().expect("A path must have at least one segment"),
QPath::TypeRelative(_, ref seg) => seg,
QPath::LangItem(..) => panic!("last_path_segment: lang item has no path segments"),
}
}
pub fn single_segment_path<'tcx>(path: &QPath<'tcx>) -> Option<&'tcx PathSegment<'tcx>> {
match *path {
QPath::Resolved(_, ref path) => path.segments.get(0),
QPath::TypeRelative(_, ref seg) => Some(seg),
QPath::LangItem(..) => None,
}
}
/// Matches a `QPath` against a slice of segment string literals.
///
/// There is also `match_path` if you are dealing with a `rustc_hir::Path` instead of a
/// `rustc_hir::QPath`.
///
/// # Examples
/// ```rust,ignore
/// match_qpath(path, &["std", "rt", "begin_unwind"])
/// ```
pub fn match_qpath(path: &QPath<'_>, segments: &[&str]) -> bool {
match *path {
QPath::Resolved(_, ref path) => match_path(path, segments),
QPath::TypeRelative(ref ty, ref segment) => match ty.kind {
TyKind::Path(ref inner_path) => {
if let [prefix @ .., end] = segments {
if match_qpath(inner_path, prefix) {
return segment.ident.name.as_str() == *end;
}
}
false
},
_ => false,
},
QPath::LangItem(..) => false,
}
}
/// Matches a `Path` against a slice of segment string literals.
///
/// There is also `match_qpath` if you are dealing with a `rustc_hir::QPath` instead of a
/// `rustc_hir::Path`.
///
/// # Examples
///
/// ```rust,ignore
/// if match_path(&trait_ref.path, &paths::HASH) {
/// // This is the `std::hash::Hash` trait.
/// }
///
/// if match_path(ty_path, &["rustc", "lint", "Lint"]) {
/// // This is a `rustc_middle::lint::Lint`.
/// }
/// ```
pub fn match_path(path: &Path<'_>, segments: &[&str]) -> bool {
path.segments
.iter()
.rev()
.zip(segments.iter().rev())
.all(|(a, b)| a.ident.name.as_str() == *b)
}
/// Matches a `Path` against a slice of segment string literals, e.g.
///
/// # Examples
/// ```rust,ignore
/// match_path_ast(path, &["std", "rt", "begin_unwind"])
/// ```
pub fn match_path_ast(path: &ast::Path, segments: &[&str]) -> bool {
path.segments
.iter()
.rev()
.zip(segments.iter().rev())
.all(|(a, b)| a.ident.name.as_str() == *b)
}
/// Gets the definition associated to a path.
pub fn path_to_res(cx: &LateContext<'_>, path: &[&str]) -> Option<def::Res> {
let crates = cx.tcx.crates();
let krate = crates
.iter()
.find(|&&krate| cx.tcx.crate_name(krate).as_str() == path[0]);
if let Some(krate) = krate {
let krate = DefId {
krate: *krate,
index: CRATE_DEF_INDEX,
};
let mut current_item = None;
let mut items = cx.tcx.item_children(krate);
let mut path_it = path.iter().skip(1).peekable();
loop {
let segment = match path_it.next() {
Some(segment) => segment,
None => return None,
};
// `get_def_path` seems to generate these empty segments for extern blocks.
// We can just ignore them.
if segment.is_empty() {
continue;
}
let result = SmallVec::<[_; 8]>::new();
for item in mem::replace(&mut items, cx.tcx.arena.alloc_slice(&result)).iter() {
if item.ident.name.as_str() == *segment {
if path_it.peek().is_none() {
return Some(item.res);
}
current_item = Some(item);
items = cx.tcx.item_children(item.res.def_id());
break;
}
}
// The segment isn't a child_item.
// Try to find it under an inherent impl.
if_chain! {
if path_it.peek().is_none();
if let Some(current_item) = current_item;
let item_def_id = current_item.res.def_id();
if cx.tcx.def_kind(item_def_id) == DefKind::Struct;
then {
// Bad `find_map` suggestion. See #4193.
#[allow(clippy::find_map)]
return cx.tcx.inherent_impls(item_def_id).iter()
.flat_map(|&impl_def_id| cx.tcx.item_children(impl_def_id))
.find(|item| item.ident.name.as_str() == *segment)
.map(|item| item.res);
}
}
}
} else {
None
}
}
pub fn qpath_res(cx: &LateContext<'_>, qpath: &hir::QPath<'_>, id: hir::HirId) -> Res {
match qpath {
hir::QPath::Resolved(_, path) => path.res,
hir::QPath::TypeRelative(..) | hir::QPath::LangItem(..) => {
if cx.tcx.has_typeck_results(id.owner.to_def_id()) {
cx.tcx.typeck(id.owner).qpath_res(qpath, id)
} else {
Res::Err
}
},
}
}
/// Convenience function to get the `DefId` of a trait by path.
/// It could be a trait or trait alias.
pub fn get_trait_def_id(cx: &LateContext<'_>, path: &[&str]) -> Option<DefId> {
let res = match path_to_res(cx, path) {
Some(res) => res,
None => return None,
};
match res {
Res::Def(DefKind::Trait | DefKind::TraitAlias, trait_id) => Some(trait_id),
Res::Err => unreachable!("this trait resolution is impossible: {:?}", &path),
_ => None,
}
}
/// Checks whether a type implements a trait.
/// See also `get_trait_def_id`.
pub fn implements_trait<'tcx>(
cx: &LateContext<'tcx>,
ty: Ty<'tcx>,
trait_id: DefId,
ty_params: &[GenericArg<'tcx>],
) -> bool {
// Do not check on infer_types to avoid panic in evaluate_obligation.
if ty.has_infer_types() {
return false;
}
let ty = cx.tcx.erase_regions(ty);
if ty.has_escaping_bound_vars() {
return false;
}
let ty_params = cx.tcx.mk_substs(ty_params.iter());
cx.tcx.type_implements_trait((trait_id, ty, ty_params, cx.param_env))
}
/// Gets the `hir::TraitRef` of the trait the given method is implemented for.
///
/// Use this if you want to find the `TraitRef` of the `Add` trait in this example:
///
/// ```rust
/// struct Point(isize, isize);
///
/// impl std::ops::Add for Point {
/// type Output = Self;
///
/// fn add(self, other: Self) -> Self {
/// Point(0, 0)
/// }
/// }
/// ```
pub fn trait_ref_of_method<'tcx>(cx: &LateContext<'tcx>, hir_id: HirId) -> Option<&'tcx TraitRef<'tcx>> {
// Get the implemented trait for the current function
let parent_impl = cx.tcx.hir().get_parent_item(hir_id);
if_chain! {
if parent_impl != hir::CRATE_HIR_ID;
if let hir::Node::Item(item) = cx.tcx.hir().get(parent_impl);
if let hir::ItemKind::Impl{ of_trait: trait_ref, .. } = &item.kind;
then { return trait_ref.as_ref(); }
}
None
}
/// Checks whether this type implements `Drop`.
pub fn has_drop<'tcx>(cx: &LateContext<'tcx>, ty: Ty<'tcx>) -> bool {
match ty.ty_adt_def() {
Some(def) => def.has_dtor(cx.tcx),
None => false,
}
}
/// Returns the method names and argument list of nested method call expressions that make up
/// `expr`. method/span lists are sorted with the most recent call first.
pub fn method_calls<'tcx>(
expr: &'tcx Expr<'tcx>,
max_depth: usize,
) -> (Vec<Symbol>, Vec<&'tcx [Expr<'tcx>]>, Vec<Span>) {
let mut method_names = Vec::with_capacity(max_depth);
let mut arg_lists = Vec::with_capacity(max_depth);
let mut spans = Vec::with_capacity(max_depth);
let mut current = expr;
for _ in 0..max_depth {
if let ExprKind::MethodCall(path, span, args, _) = &current.kind {
if args.iter().any(|e| e.span.from_expansion()) {
break;
}
method_names.push(path.ident.name);
arg_lists.push(&**args);
spans.push(*span);
current = &args[0];
} else {
break;
}
}
(method_names, arg_lists, spans)
}
/// Matches an `Expr` against a chain of methods, and return the matched `Expr`s.
///
/// For example, if `expr` represents the `.baz()` in `foo.bar().baz()`,
/// `method_chain_args(expr, &["bar", "baz"])` will return a `Vec`
/// containing the `Expr`s for
/// `.bar()` and `.baz()`
pub fn method_chain_args<'a>(expr: &'a Expr<'_>, methods: &[&str]) -> Option<Vec<&'a [Expr<'a>]>> {
let mut current = expr;
let mut matched = Vec::with_capacity(methods.len());
for method_name in methods.iter().rev() {
// method chains are stored last -> first
if let ExprKind::MethodCall(ref path, _, ref args, _) = current.kind {
if path.ident.name.as_str() == *method_name {
if args.iter().any(|e| e.span.from_expansion()) {
return None;
}
matched.push(&**args); // build up `matched` backwards
current = &args[0] // go to parent expression
} else {
return None;
}
} else {
return None;
}
}
// Reverse `matched` so that it is in the same order as `methods`.
matched.reverse();
Some(matched)
}
/// Returns `true` if the provided `def_id` is an entrypoint to a program.
pub fn is_entrypoint_fn(cx: &LateContext<'_>, def_id: DefId) -> bool {
cx.tcx
.entry_fn(LOCAL_CRATE)
.map_or(false, |(entry_fn_def_id, _)| def_id == entry_fn_def_id.to_def_id())
}
/// Returns `true` if the expression is in the program's `#[panic_handler]`.
pub fn is_in_panic_handler(cx: &LateContext<'_>, e: &Expr<'_>) -> bool {
let parent = cx.tcx.hir().get_parent_item(e.hir_id);
let def_id = cx.tcx.hir().local_def_id(parent).to_def_id();
Some(def_id) == cx.tcx.lang_items().panic_impl()
}
/// Gets the name of the item the expression is in, if available.
pub fn get_item_name(cx: &LateContext<'_>, expr: &Expr<'_>) -> Option<Symbol> {
let parent_id = cx.tcx.hir().get_parent_item(expr.hir_id);
match cx.tcx.hir().find(parent_id) {
Some(
Node::Item(Item { ident, .. })
| Node::TraitItem(TraitItem { ident, .. })
| Node::ImplItem(ImplItem { ident, .. }),
) => Some(ident.name),
_ => None,
}
}
/// Gets the name of a `Pat`, if any.
pub fn get_pat_name(pat: &Pat<'_>) -> Option<Symbol> {
match pat.kind {
PatKind::Binding(.., ref spname, _) => Some(spname.name),
PatKind::Path(ref qpath) => single_segment_path(qpath).map(|ps| ps.ident.name),
PatKind::Box(ref p) | PatKind::Ref(ref p, _) => get_pat_name(&*p),
_ => None,
}
}
struct ContainsName {
name: Symbol,
result: bool,
}
impl<'tcx> Visitor<'tcx> for ContainsName {
type Map = Map<'tcx>;
fn visit_name(&mut self, _: Span, name: Symbol) {
if self.name == name {
self.result = true;
}
}
fn nested_visit_map(&mut self) -> NestedVisitorMap<Self::Map> {
NestedVisitorMap::None
}
}
/// Checks if an `Expr` contains a certain name.
pub fn contains_name(name: Symbol, expr: &Expr<'_>) -> bool {
let mut cn = ContainsName { name, result: false };
cn.visit_expr(expr);
cn.result
}
/// Converts a span to a code snippet if available, otherwise use default.
///
/// This is useful if you want to provide suggestions for your lint or more generally, if you want
/// to convert a given `Span` to a `str`.
///
/// # Example
/// ```rust,ignore
/// snippet(cx, expr.span, "..")
/// ```
pub fn snippet<'a, T: LintContext>(cx: &T, span: Span, default: &'a str) -> Cow<'a, str> {
snippet_opt(cx, span).map_or_else(|| Cow::Borrowed(default), From::from)
}
/// Same as `snippet`, but it adapts the applicability level by following rules:
///
/// - Applicability level `Unspecified` will never be changed.
/// - If the span is inside a macro, change the applicability level to `MaybeIncorrect`.
/// - If the default value is used and the applicability level is `MachineApplicable`, change it to
/// `HasPlaceholders`
pub fn snippet_with_applicability<'a, T: LintContext>(
cx: &T,
span: Span,
default: &'a str,
applicability: &mut Applicability,
) -> Cow<'a, str> {
if *applicability != Applicability::Unspecified && span.from_expansion() {
*applicability = Applicability::MaybeIncorrect;
}
snippet_opt(cx, span).map_or_else(
|| {
if *applicability == Applicability::MachineApplicable {
*applicability = Applicability::HasPlaceholders;
}
Cow::Borrowed(default)
},
From::from,
)
}
/// Same as `snippet`, but should only be used when it's clear that the input span is
/// not a macro argument.
pub fn snippet_with_macro_callsite<'a, T: LintContext>(cx: &T, span: Span, default: &'a str) -> Cow<'a, str> {
snippet(cx, span.source_callsite(), default)
}
/// Converts a span to a code snippet. Returns `None` if not available.
pub fn snippet_opt<T: LintContext>(cx: &T, span: Span) -> Option<String> {
cx.sess().source_map().span_to_snippet(span).ok()
}
/// Converts a span (from a block) to a code snippet if available, otherwise use default.
///
/// This trims the code of indentation, except for the first line. Use it for blocks or block-like
/// things which need to be printed as such.
///
/// The `indent_relative_to` arg can be used, to provide a span, where the indentation of the
/// resulting snippet of the given span.
///
/// # Example
///
/// ```rust,ignore
/// snippet_block(cx, block.span, "..", None)
/// // where, `block` is the block of the if expr
/// if x {
/// y;
/// }
/// // will return the snippet
/// {
/// y;
/// }
/// ```
///
/// ```rust,ignore
/// snippet_block(cx, block.span, "..", Some(if_expr.span))
/// // where, `block` is the block of the if expr
/// if x {
/// y;
/// }
/// // will return the snippet
/// {
/// y;
/// } // aligned with `if`
/// ```
/// Note that the first line of the snippet always has 0 indentation.
pub fn snippet_block<'a, T: LintContext>(
cx: &T,
span: Span,
default: &'a str,
indent_relative_to: Option<Span>,
) -> Cow<'a, str> {
let snip = snippet(cx, span, default);
let indent = indent_relative_to.and_then(|s| indent_of(cx, s));
reindent_multiline(snip, true, indent)
}
/// Same as `snippet_block`, but adapts the applicability level by the rules of
/// `snippet_with_applicability`.
pub fn snippet_block_with_applicability<'a, T: LintContext>(
cx: &T,
span: Span,
default: &'a str,
indent_relative_to: Option<Span>,
applicability: &mut Applicability,
) -> Cow<'a, str> {
let snip = snippet_with_applicability(cx, span, default, applicability);
let indent = indent_relative_to.and_then(|s| indent_of(cx, s));
reindent_multiline(snip, true, indent)
}
/// Returns a new Span that extends the original Span to the first non-whitespace char of the first
/// line.
///
/// ```rust,ignore
/// let x = ();
/// // ^^
/// // will be converted to
/// let x = ();
/// // ^^^^^^^^^^
/// ```
pub fn first_line_of_span<T: LintContext>(cx: &T, span: Span) -> Span {
first_char_in_first_line(cx, span).map_or(span, |first_char_pos| span.with_lo(first_char_pos))
}
fn first_char_in_first_line<T: LintContext>(cx: &T, span: Span) -> Option<BytePos> {
let line_span = line_span(cx, span);
snippet_opt(cx, line_span).and_then(|snip| {
snip.find(|c: char| !c.is_whitespace())
.map(|pos| line_span.lo() + BytePos::from_usize(pos))
})
}
/// Returns the indentation of the line of a span
///
/// ```rust,ignore
/// let x = ();
/// // ^^ -- will return 0
/// let x = ();
/// // ^^ -- will return 4
/// ```
pub fn indent_of<T: LintContext>(cx: &T, span: Span) -> Option<usize> {
snippet_opt(cx, line_span(cx, span)).and_then(|snip| snip.find(|c: char| !c.is_whitespace()))
}
/// Returns the positon just before rarrow
///
/// ```rust,ignore
/// fn into(self) -> () {}
/// ^
/// // in case of unformatted code
/// fn into2(self)-> () {}
/// ^
/// fn into3(self) -> () {}
/// ^
/// ```
#[allow(clippy::needless_pass_by_value)]
pub fn position_before_rarrow(s: String) -> Option<usize> {
s.rfind("->").map(|rpos| {
let mut rpos = rpos;
let chars: Vec<char> = s.chars().collect();
while rpos > 1 {
if let Some(c) = chars.get(rpos - 1) {
if c.is_whitespace() {
rpos -= 1;
continue;
}
}
break;
}
rpos
})
}
/// Extends the span to the beginning of the spans line, incl. whitespaces.
///
/// ```rust,ignore
/// let x = ();
/// // ^^
/// // will be converted to
/// let x = ();
/// // ^^^^^^^^^^^^^^
/// ```
fn line_span<T: LintContext>(cx: &T, span: Span) -> Span {
let span = original_sp(span, DUMMY_SP);
let source_map_and_line = cx.sess().source_map().lookup_line(span.lo()).unwrap();
let line_no = source_map_and_line.line;
let line_start = source_map_and_line.sf.lines[line_no];
Span::new(line_start, span.hi(), span.ctxt())
}
/// Like `snippet_block`, but add braces if the expr is not an `ExprKind::Block`.
/// Also takes an `Option<String>` which can be put inside the braces.
pub fn expr_block<'a, T: LintContext>(
cx: &T,
expr: &Expr<'_>,
option: Option<String>,
default: &'a str,
indent_relative_to: Option<Span>,
) -> Cow<'a, str> {
let code = snippet_block(cx, expr.span, default, indent_relative_to);
let string = option.unwrap_or_default();
if expr.span.from_expansion() {
Cow::Owned(format!("{{ {} }}", snippet_with_macro_callsite(cx, expr.span, default)))
} else if let ExprKind::Block(_, _) = expr.kind {
Cow::Owned(format!("{}{}", code, string))
} else if string.is_empty() {
Cow::Owned(format!("{{ {} }}", code))
} else {
Cow::Owned(format!("{{\n{};\n{}\n}}", code, string))
}
}
/// Reindent a multiline string with possibility of ignoring the first line.
#[allow(clippy::needless_pass_by_value)]
pub fn reindent_multiline(s: Cow<'_, str>, ignore_first: bool, indent: Option<usize>) -> Cow<'_, str> {
let s_space = reindent_multiline_inner(&s, ignore_first, indent, ' ');
let s_tab = reindent_multiline_inner(&s_space, ignore_first, indent, '\t');
reindent_multiline_inner(&s_tab, ignore_first, indent, ' ').into()
}
fn reindent_multiline_inner(s: &str, ignore_first: bool, indent: Option<usize>, ch: char) -> String {
let x = s
.lines()
.skip(ignore_first as usize)
.filter_map(|l| {
if l.is_empty() {
None
} else {
// ignore empty lines
Some(l.char_indices().find(|&(_, x)| x != ch).unwrap_or((l.len(), ch)).0)
}
})
.min()
.unwrap_or(0);
let indent = indent.unwrap_or(0);
s.lines()
.enumerate()
.map(|(i, l)| {
if (ignore_first && i == 0) || l.is_empty() {
l.to_owned()
} else if x > indent {
l.split_at(x - indent).1.to_owned()
} else {
" ".repeat(indent - x) + l
}
})
.collect::<Vec<String>>()
.join("\n")
}
/// Gets the parent expression, if any - this is useful to constrain a lint.
pub fn get_parent_expr<'tcx>(cx: &LateContext<'tcx>, e: &Expr<'_>) -> Option<&'tcx Expr<'tcx>> {
let map = &cx.tcx.hir();
let hir_id = e.hir_id;
let parent_id = map.get_parent_node(hir_id);
if hir_id == parent_id {
return None;
}
map.find(parent_id).and_then(|node| {
if let Node::Expr(parent) = node {
Some(parent)
} else {
None
}
})
}
pub fn get_enclosing_block<'tcx>(cx: &LateContext<'tcx>, hir_id: HirId) -> Option<&'tcx Block<'tcx>> {
let map = &cx.tcx.hir();
let enclosing_node = map
.get_enclosing_scope(hir_id)
.and_then(|enclosing_id| map.find(enclosing_id));
enclosing_node.and_then(|node| match node {
Node::Block(block) => Some(block),
Node::Item(&Item {
kind: ItemKind::Fn(_, _, eid),
..
})
| Node::ImplItem(&ImplItem {
kind: ImplItemKind::Fn(_, eid),
..
}) => match cx.tcx.hir().body(eid).value.kind {
ExprKind::Block(ref block, _) => Some(block),
_ => None,
},
_ => None,
})
}
/// Returns the base type for HIR references and pointers.
pub fn walk_ptrs_hir_ty<'tcx>(ty: &'tcx hir::Ty<'tcx>) -> &'tcx hir::Ty<'tcx> {
match ty.kind {
TyKind::Ptr(ref mut_ty) | TyKind::Rptr(_, ref mut_ty) => walk_ptrs_hir_ty(&mut_ty.ty),
_ => ty,
}
}
/// Returns the base type for references and raw pointers, and count reference
/// depth.
pub fn walk_ptrs_ty_depth(ty: Ty<'_>) -> (Ty<'_>, usize) {
fn inner(ty: Ty<'_>, depth: usize) -> (Ty<'_>, usize) {
match ty.kind() {
ty::Ref(_, ty, _) => inner(ty, depth + 1),
_ => (ty, depth),
}
}
inner(ty, 0)
}
/// Checks whether the given expression is a constant integer of the given value.
/// unlike `is_integer_literal`, this version does const folding
pub fn is_integer_const(cx: &LateContext<'_>, e: &Expr<'_>, value: u128) -> bool {
if is_integer_literal(e, value) {
return true;
}
let map = cx.tcx.hir();
let parent_item = map.get_parent_item(e.hir_id);
if let Some((Constant::Int(v), _)) = map
.maybe_body_owned_by(parent_item)
.and_then(|body_id| constant(cx, cx.tcx.typeck_body(body_id), e))
{
value == v
} else {
false
}
}
/// Checks whether the given expression is a constant literal of the given value.
pub fn is_integer_literal(expr: &Expr<'_>, value: u128) -> bool {
// FIXME: use constant folding
if let ExprKind::Lit(ref spanned) = expr.kind {
if let LitKind::Int(v, _) = spanned.node {
return v == value;
}
}
false
}
/// Returns `true` if the given `Expr` has been coerced before.
///
/// Examples of coercions can be found in the Nomicon at
/// <https://doc.rust-lang.org/nomicon/coercions.html>.
///
/// See `rustc_middle::ty::adjustment::Adjustment` and `rustc_typeck::check::coercion` for more
/// information on adjustments and coercions.
pub fn is_adjusted(cx: &LateContext<'_>, e: &Expr<'_>) -> bool {
cx.typeck_results().adjustments().get(e.hir_id).is_some()
}
/// Returns the pre-expansion span if is this comes from an expansion of the
/// macro `name`.
/// See also `is_direct_expn_of`.
#[must_use]
pub fn is_expn_of(mut span: Span, name: &str) -> Option<Span> {
loop {
if span.from_expansion() {
let data = span.ctxt().outer_expn_data();
let new_span = data.call_site;
if let ExpnKind::Macro(MacroKind::Bang, mac_name) = data.kind {
if mac_name.as_str() == name {
return Some(new_span);
}
}
span = new_span;
} else {
return None;
}
}
}
/// Returns the pre-expansion span if the span directly comes from an expansion
/// of the macro `name`.
/// The difference with `is_expn_of` is that in
/// ```rust,ignore
/// foo!(bar!(42));
/// ```
/// `42` is considered expanded from `foo!` and `bar!` by `is_expn_of` but only
/// `bar!` by
/// `is_direct_expn_of`.
#[must_use]
pub fn is_direct_expn_of(span: Span, name: &str) -> Option<Span> {
if span.from_expansion() {
let data = span.ctxt().outer_expn_data();
let new_span = data.call_site;
if let ExpnKind::Macro(MacroKind::Bang, mac_name) = data.kind {
if mac_name.as_str() == name {
return Some(new_span);
}
}
}
None
}
/// Convenience function to get the return type of a function.
pub fn return_ty<'tcx>(cx: &LateContext<'tcx>, fn_item: hir::HirId) -> Ty<'tcx> {
let fn_def_id = cx.tcx.hir().local_def_id(fn_item);
let ret_ty = cx.tcx.fn_sig(fn_def_id).output();
cx.tcx.erase_late_bound_regions(ret_ty)
}
/// Walks into `ty` and returns `true` if any inner type is the same as `other_ty`
pub fn contains_ty(ty: Ty<'_>, other_ty: Ty<'_>) -> bool {
ty.walk().any(|inner| match inner.unpack() {
GenericArgKind::Type(inner_ty) => ty::TyS::same_type(other_ty, inner_ty),
GenericArgKind::Lifetime(_) | GenericArgKind::Const(_) => false,
})
}
/// Returns `true` if the given type is an `unsafe` function.
pub fn type_is_unsafe_function<'tcx>(cx: &LateContext<'tcx>, ty: Ty<'tcx>) -> bool {
match ty.kind() {
ty::FnDef(..) | ty::FnPtr(_) => ty.fn_sig(cx.tcx).unsafety() == Unsafety::Unsafe,
_ => false,
}
}
pub fn is_copy<'tcx>(cx: &LateContext<'tcx>, ty: Ty<'tcx>) -> bool {
ty.is_copy_modulo_regions(cx.tcx.at(DUMMY_SP), cx.param_env)
}
/// Checks if an expression is constructing a tuple-like enum variant or struct
pub fn is_ctor_or_promotable_const_function(cx: &LateContext<'_>, expr: &Expr<'_>) -> bool {
if let ExprKind::Call(ref fun, _) = expr.kind {
if let ExprKind::Path(ref qp) = fun.kind {
let res = cx.qpath_res(qp, fun.hir_id);
return match res {
def::Res::Def(DefKind::Variant | DefKind::Ctor(..), ..) => true,
def::Res::Def(_, def_id) => cx.tcx.is_promotable_const_fn(def_id),
_ => false,
};
}
}
false
}
/// Returns `true` if a pattern is refutable.
// TODO: should be implemented using rustc/mir_build/thir machinery
pub fn is_refutable(cx: &LateContext<'_>, pat: &Pat<'_>) -> bool {
fn is_enum_variant(cx: &LateContext<'_>, qpath: &QPath<'_>, id: HirId) -> bool {
matches!(
cx.qpath_res(qpath, id),
def::Res::Def(DefKind::Variant, ..) | Res::Def(DefKind::Ctor(def::CtorOf::Variant, _), _)
)
}
fn are_refutable<'a, I: Iterator<Item = &'a Pat<'a>>>(cx: &LateContext<'_>, mut i: I) -> bool {
i.any(|pat| is_refutable(cx, pat))
}
match pat.kind {
PatKind::Wild => false,
PatKind::Binding(_, _, _, pat) => pat.map_or(false, |pat| is_refutable(cx, pat)),
PatKind::Box(ref pat) | PatKind::Ref(ref pat, _) => is_refutable(cx, pat),
PatKind::Lit(..) | PatKind::Range(..) => true,
PatKind::Path(ref qpath) => is_enum_variant(cx, qpath, pat.hir_id),
PatKind::Or(ref pats) => {
// TODO: should be the honest check, that pats is exhaustive set
are_refutable(cx, pats.iter().map(|pat| &**pat))
},
PatKind::Tuple(ref pats, _) => are_refutable(cx, pats.iter().map(|pat| &**pat)),
PatKind::Struct(ref qpath, ref fields, _) => {
is_enum_variant(cx, qpath, pat.hir_id) || are_refutable(cx, fields.iter().map(|field| &*field.pat))
},
PatKind::TupleStruct(ref qpath, ref pats, _) => {
is_enum_variant(cx, qpath, pat.hir_id) || are_refutable(cx, pats.iter().map(|pat| &**pat))
},
PatKind::Slice(ref head, ref middle, ref tail) => {
match &cx.typeck_results().node_type(pat.hir_id).kind() {
ty::Slice(..) => {
// [..] is the only irrefutable slice pattern.
!head.is_empty() || middle.is_none() || !tail.is_empty()
},
ty::Array(..) => are_refutable(cx, head.iter().chain(middle).chain(tail.iter()).map(|pat| &**pat)),
_ => {
// unreachable!()
true
},
}
},
}
}
/// Checks for the `#[automatically_derived]` attribute all `#[derive]`d
/// implementations have.
pub fn is_automatically_derived(attrs: &[ast::Attribute]) -> bool {
attrs.iter().any(|attr| attr.has_name(rustc_sym::automatically_derived))
}
/// Remove blocks around an expression.
///
/// Ie. `x`, `{ x }` and `{{{{ x }}}}` all give `x`. `{ x; y }` and `{}` return
/// themselves.
pub fn remove_blocks<'tcx>(mut expr: &'tcx Expr<'tcx>) -> &'tcx Expr<'tcx> {
while let ExprKind::Block(ref block, ..) = expr.kind {
match (block.stmts.is_empty(), block.expr.as_ref()) {
(true, Some(e)) => expr = e,
_ => break,
}
}
expr
}
pub fn is_self(slf: &Param<'_>) -> bool {
if let PatKind::Binding(.., name, _) = slf.pat.kind {
name.name == kw::SelfLower
} else {
false
}
}
pub fn is_self_ty(slf: &hir::Ty<'_>) -> bool {
if_chain! {
if let TyKind::Path(ref qp) = slf.kind;
if let QPath::Resolved(None, ref path) = *qp;
if let Res::SelfTy(..) = path.res;
then {
return true
}
}
false
}
pub fn iter_input_pats<'tcx>(decl: &FnDecl<'_>, body: &'tcx Body<'_>) -> impl Iterator<Item = &'tcx Param<'tcx>> {
(0..decl.inputs.len()).map(move |i| &body.params[i])
}
/// Checks if a given expression is a match expression expanded from the `?`
/// operator or the `try` macro.
pub fn is_try<'tcx>(expr: &'tcx Expr<'tcx>) -> Option<&'tcx Expr<'tcx>> {
fn is_ok(arm: &Arm<'_>) -> bool {
if_chain! {
if let PatKind::TupleStruct(ref path, ref pat, None) = arm.pat.kind;
if match_qpath(path, &paths::RESULT_OK[1..]);
if let PatKind::Binding(_, hir_id, _, None) = pat[0].kind;
if let ExprKind::Path(QPath::Resolved(None, ref path)) = arm.body.kind;
if let Res::Local(lid) = path.res;
if lid == hir_id;
then {
return true;
}
}
false
}
fn is_err(arm: &Arm<'_>) -> bool {
if let PatKind::TupleStruct(ref path, _, _) = arm.pat.kind {
match_qpath(path, &paths::RESULT_ERR[1..])
} else {
false
}
}
if let ExprKind::Match(_, ref arms, ref source) = expr.kind {
// desugared from a `?` operator
if let MatchSource::TryDesugar = *source {
return Some(expr);
}
if_chain! {
if arms.len() == 2;
if arms[0].guard.is_none();
if arms[1].guard.is_none();
if (is_ok(&arms[0]) && is_err(&arms[1])) ||
(is_ok(&arms[1]) && is_err(&arms[0]));
then {
return Some(expr);
}
}
}
None
}
/// Returns `true` if the lint is allowed in the current context
///
/// Useful for skipping long running code when it's unnecessary
pub fn is_allowed(cx: &LateContext<'_>, lint: &'static Lint, id: HirId) -> bool {
cx.tcx.lint_level_at_node(lint, id).0 == Level::Allow
}
pub fn get_arg_name(pat: &Pat<'_>) -> Option<Symbol> {
match pat.kind {
PatKind::Binding(.., ident, None) => Some(ident.name),
PatKind::Ref(ref subpat, _) => get_arg_name(subpat),
_ => None,
}
}
pub fn int_bits(tcx: TyCtxt<'_>, ity: ast::IntTy) -> u64 {
Integer::from_attr(&tcx, attr::IntType::SignedInt(ity)).size().bits()
}
#[allow(clippy::cast_possible_wrap)]
/// Turn a constant int byte representation into an i128
pub fn sext(tcx: TyCtxt<'_>, u: u128, ity: ast::IntTy) -> i128 {
let amt = 128 - int_bits(tcx, ity);
((u as i128) << amt) >> amt
}
#[allow(clippy::cast_sign_loss)]
/// clip unused bytes
pub fn unsext(tcx: TyCtxt<'_>, u: i128, ity: ast::IntTy) -> u128 {
let amt = 128 - int_bits(tcx, ity);
((u as u128) << amt) >> amt
}
/// clip unused bytes
pub fn clip(tcx: TyCtxt<'_>, u: u128, ity: ast::UintTy) -> u128 {
let bits = Integer::from_attr(&tcx, attr::IntType::UnsignedInt(ity)).size().bits();
let amt = 128 - bits;
(u << amt) >> amt
}
/// Removes block comments from the given `Vec` of lines.
///
/// # Examples
///
/// ```rust,ignore
/// without_block_comments(vec!["/*", "foo", "*/"]);
/// // => vec![]
///
/// without_block_comments(vec!["bar", "/*", "foo", "*/"]);
/// // => vec!["bar"]
/// ```
pub fn without_block_comments(lines: Vec<&str>) -> Vec<&str> {
let mut without = vec![];
let mut nest_level = 0;
for line in lines {
if line.contains("/*") {
nest_level += 1;
continue;
} else if line.contains("*/") {
nest_level -= 1;
continue;
}
if nest_level == 0 {
without.push(line);
}
}
without
}
pub fn any_parent_is_automatically_derived(tcx: TyCtxt<'_>, node: HirId) -> bool {
let map = &tcx.hir();
let mut prev_enclosing_node = None;
let mut enclosing_node = node;
while Some(enclosing_node) != prev_enclosing_node {
if is_automatically_derived(map.attrs(enclosing_node)) {
return true;
}
prev_enclosing_node = Some(enclosing_node);
enclosing_node = map.get_parent_item(enclosing_node);
}
false
}
/// Returns true if ty has `iter` or `iter_mut` methods
pub fn has_iter_method(cx: &LateContext<'_>, probably_ref_ty: Ty<'_>) -> Option<&'static str> {
// FIXME: instead of this hard-coded list, we should check if `<adt>::iter`
// exists and has the desired signature. Unfortunately FnCtxt is not exported
// so we can't use its `lookup_method` method.
let into_iter_collections: [&[&str]; 13] = [
&paths::VEC,
&paths::OPTION,
&paths::RESULT,
&paths::BTREESET,
&paths::BTREEMAP,
&paths::VEC_DEQUE,
&paths::LINKED_LIST,
&paths::BINARY_HEAP,
&paths::HASHSET,
&paths::HASHMAP,
&paths::PATH_BUF,
&paths::PATH,
&paths::RECEIVER,
];
let ty_to_check = match probably_ref_ty.kind() {
ty::Ref(_, ty_to_check, _) => ty_to_check,
_ => probably_ref_ty,
};
let def_id = match ty_to_check.kind() {
ty::Array(..) => return Some("array"),
ty::Slice(..) => return Some("slice"),
ty::Adt(adt, _) => adt.did,
_ => return None,
};
for path in &into_iter_collections {
if match_def_path(cx, def_id, path) {
return Some(*path.last().unwrap());
}
}
None
}
/// Matches a function call with the given path and returns the arguments.
///
/// Usage:
///
/// ```rust,ignore
/// if let Some(args) = match_function_call(cx, cmp_max_call, &paths::CMP_MAX);
/// ```
pub fn match_function_call<'tcx>(
cx: &LateContext<'tcx>,
expr: &'tcx Expr<'_>,
path: &[&str],
) -> Option<&'tcx [Expr<'tcx>]> {
if_chain! {
if let ExprKind::Call(ref fun, ref args) = expr.kind;
if let ExprKind::Path(ref qpath) = fun.kind;
if let Some(fun_def_id) = cx.qpath_res(qpath, fun.hir_id).opt_def_id();
if match_def_path(cx, fun_def_id, path);
then {
return Some(&args)
}
};
None
}
/// Checks if `Ty` is normalizable. This function is useful
/// to avoid crashes on `layout_of`.
pub fn is_normalizable<'tcx>(cx: &LateContext<'tcx>, param_env: ty::ParamEnv<'tcx>, ty: Ty<'tcx>) -> bool {
cx.tcx.infer_ctxt().enter(|infcx| {
let cause = rustc_middle::traits::ObligationCause::dummy();
infcx.at(&cause, param_env).normalize(ty).is_ok()
})
}
pub fn match_def_path<'tcx>(cx: &LateContext<'tcx>, did: DefId, syms: &[&str]) -> bool {
// We have to convert `syms` to `&[Symbol]` here because rustc's `match_def_path`
// accepts only that. We should probably move to Symbols in Clippy as well.
let syms = syms.iter().map(|p| Symbol::intern(p)).collect::<Vec<Symbol>>();
cx.match_def_path(did, &syms)
}
pub fn match_panic_call<'tcx>(cx: &LateContext<'tcx>, expr: &'tcx Expr<'_>) -> Option<&'tcx [Expr<'tcx>]> {
match_function_call(cx, expr, &paths::BEGIN_PANIC)
.or_else(|| match_function_call(cx, expr, &paths::BEGIN_PANIC_FMT))
.or_else(|| match_function_call(cx, expr, &paths::PANIC_ANY))
.or_else(|| match_function_call(cx, expr, &paths::PANICKING_PANIC))
.or_else(|| match_function_call(cx, expr, &paths::PANICKING_PANIC_FMT))
.or_else(|| match_function_call(cx, expr, &paths::PANICKING_PANIC_STR))
}
pub fn match_panic_def_id(cx: &LateContext<'_>, did: DefId) -> bool {
match_def_path(cx, did, &paths::BEGIN_PANIC)
|| match_def_path(cx, did, &paths::BEGIN_PANIC_FMT)
|| match_def_path(cx, did, &paths::PANIC_ANY)
|| match_def_path(cx, did, &paths::PANICKING_PANIC)
|| match_def_path(cx, did, &paths::PANICKING_PANIC_FMT)
|| match_def_path(cx, did, &paths::PANICKING_PANIC_STR)
}
/// Returns the list of condition expressions and the list of blocks in a
/// sequence of `if/else`.
/// E.g., this returns `([a, b], [c, d, e])` for the expression
/// `if a { c } else if b { d } else { e }`.
pub fn if_sequence<'tcx>(
mut expr: &'tcx Expr<'tcx>,
) -> (SmallVec<[&'tcx Expr<'tcx>; 1]>, SmallVec<[&'tcx Block<'tcx>; 1]>) {
let mut conds = SmallVec::new();
let mut blocks: SmallVec<[&Block<'_>; 1]> = SmallVec::new();
while let Some((ref cond, ref then_expr, ref else_expr)) = higher::if_block(&expr) {
conds.push(&**cond);
if let ExprKind::Block(ref block, _) = then_expr.kind {
blocks.push(block);
} else {
panic!("ExprKind::If node is not an ExprKind::Block");
}
if let Some(ref else_expr) = *else_expr {
expr = else_expr;
} else {
break;
}
}
// final `else {..}`
if !blocks.is_empty() {
if let ExprKind::Block(ref block, _) = expr.kind {
blocks.push(&**block);
}
}
(conds, blocks)
}
pub fn parent_node_is_if_expr(expr: &Expr<'_>, cx: &LateContext<'_>) -> bool {
let map = cx.tcx.hir();
let parent_id = map.get_parent_node(expr.hir_id);
let parent_node = map.get(parent_id);
match parent_node {
Node::Expr(e) => higher::if_block(&e).is_some(),
Node::Arm(e) => higher::if_block(&e.body).is_some(),
_ => false,
}
}
// Finds the attribute with the given name, if any
pub fn attr_by_name<'a>(attrs: &'a [Attribute], name: &'_ str) -> Option<&'a Attribute> {
attrs
.iter()
.find(|attr| attr.ident().map_or(false, |ident| ident.as_str() == name))
}
// Finds the `#[must_use]` attribute, if any
pub fn must_use_attr(attrs: &[Attribute]) -> Option<&Attribute> {
attr_by_name(attrs, "must_use")
}
// Returns whether the type has #[must_use] attribute
pub fn is_must_use_ty<'tcx>(cx: &LateContext<'tcx>, ty: Ty<'tcx>) -> bool {
match ty.kind() {
ty::Adt(ref adt, _) => must_use_attr(&cx.tcx.get_attrs(adt.did)).is_some(),
ty::Foreign(ref did) => must_use_attr(&cx.tcx.get_attrs(*did)).is_some(),
ty::Slice(ref ty)
| ty::Array(ref ty, _)
| ty::RawPtr(ty::TypeAndMut { ref ty, .. })
| ty::Ref(_, ref ty, _) => {
// for the Array case we don't need to care for the len == 0 case
// because we don't want to lint functions returning empty arrays
is_must_use_ty(cx, *ty)
},
ty::Tuple(ref substs) => substs.types().any(|ty| is_must_use_ty(cx, ty)),
ty::Opaque(ref def_id, _) => {
for (predicate, _) in cx.tcx.explicit_item_bounds(*def_id) {
if let ty::PredicateAtom::Trait(trait_predicate, _) = predicate.skip_binders() {
if must_use_attr(&cx.tcx.get_attrs(trait_predicate.trait_ref.def_id)).is_some() {
return true;
}
}
}
false
},
ty::Dynamic(binder, _) => {
for predicate in binder.skip_binder().iter() {
if let ty::ExistentialPredicate::Trait(ref trait_ref) = predicate {
if must_use_attr(&cx.tcx.get_attrs(trait_ref.def_id)).is_some() {
return true;
}
}
}
false
},
_ => false,
}
}
// check if expr is calling method or function with #[must_use] attribute
pub fn is_must_use_func_call(cx: &LateContext<'_>, expr: &Expr<'_>) -> bool {
let did = match expr.kind {
ExprKind::Call(ref path, _) => if_chain! {
if let ExprKind::Path(ref qpath) = path.kind;
if let def::Res::Def(_, did) = cx.qpath_res(qpath, path.hir_id);
then {
Some(did)
} else {
None
}
},
ExprKind::MethodCall(_, _, _, _) => cx.typeck_results().type_dependent_def_id(expr.hir_id),
_ => None,
};
did.map_or(false, |did| must_use_attr(&cx.tcx.get_attrs(did)).is_some())
}
pub fn is_no_std_crate(krate: &Crate<'_>) -> bool {
krate.item.attrs.iter().any(|attr| {
if let ast::AttrKind::Normal(ref attr, _) = attr.kind {
attr.path == symbol::sym::no_std
} else {
false
}
})
}
/// Check if parent of a hir node is a trait implementation block.
/// For example, `f` in
/// ```rust,ignore
/// impl Trait for S {
/// fn f() {}
/// }
/// ```
pub fn is_trait_impl_item(cx: &LateContext<'_>, hir_id: HirId) -> bool {
if let Some(Node::Item(item)) = cx.tcx.hir().find(cx.tcx.hir().get_parent_node(hir_id)) {
matches!(item.kind, ItemKind::Impl{ of_trait: Some(_), .. })
} else {
false
}
}
/// Check if it's even possible to satisfy the `where` clause for the item.
///
/// `trivial_bounds` feature allows functions with unsatisfiable bounds, for example:
///
/// ```ignore
/// fn foo() where i32: Iterator {
/// for _ in 2i32 {}
/// }
/// ```
pub fn fn_has_unsatisfiable_preds(cx: &LateContext<'_>, did: DefId) -> bool {
use rustc_trait_selection::traits;
let predicates =
cx.tcx
.predicates_of(did)
.predicates
.iter()
.filter_map(|(p, _)| if p.is_global() { Some(*p) } else { None });
traits::impossible_predicates(
cx.tcx,
traits::elaborate_predicates(cx.tcx, predicates)
.map(|o| o.predicate)
.collect::<Vec<_>>(),
)
}
/// Returns the `DefId` of the callee if the given expression is a function or method call.
pub fn fn_def_id(cx: &LateContext<'_>, expr: &Expr<'_>) -> Option<DefId> {
match &expr.kind {
ExprKind::MethodCall(..) => cx.typeck_results().type_dependent_def_id(expr.hir_id),
ExprKind::Call(
Expr {
kind: ExprKind::Path(qpath),
..
},
..,
) => cx.typeck_results().qpath_res(qpath, expr.hir_id).opt_def_id(),
_ => None,
}
}
pub fn run_lints(cx: &LateContext<'_>, lints: &[&'static Lint], id: HirId) -> bool {
lints.iter().any(|lint| {
matches!(
cx.tcx.lint_level_at_node(lint, id),
(Level::Forbid | Level::Deny | Level::Warn, _)
)
})
}
/// Returns true iff the given type is a primitive (a bool or char, any integer or floating-point
/// number type, a str, or an array, slice, or tuple of those types).
pub fn is_recursively_primitive_type(ty: Ty<'_>) -> bool {
match ty.kind() {
ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Str => true,
ty::Ref(_, inner, _) if *inner.kind() == ty::Str => true,
ty::Array(inner_type, _) | ty::Slice(inner_type) => is_recursively_primitive_type(inner_type),
ty::Tuple(inner_types) => inner_types.types().all(is_recursively_primitive_type),
_ => false,
}
}
/// Returns Option<String> where String is a textual representation of the type encapsulated in the
/// slice iff the given expression is a slice of primitives (as defined in the
/// `is_recursively_primitive_type` function) and None otherwise.
pub fn is_slice_of_primitives(cx: &LateContext<'_>, expr: &Expr<'_>) -> Option<String> {
let expr_type = cx.typeck_results().expr_ty_adjusted(expr);
let expr_kind = expr_type.kind();
let is_primitive = match expr_kind {
ty::Slice(element_type) => is_recursively_primitive_type(element_type),
ty::Ref(_, inner_ty, _) if matches!(inner_ty.kind(), &ty::Slice(_)) => {
if let ty::Slice(element_type) = inner_ty.kind() {
is_recursively_primitive_type(element_type)
} else {
unreachable!()
}
},
_ => false,
};
if is_primitive {
// if we have wrappers like Array, Slice or Tuple, print these
// and get the type enclosed in the slice ref
match expr_type.peel_refs().walk().nth(1).unwrap().expect_ty().kind() {
ty::Slice(..) => return Some("slice".into()),
ty::Array(..) => return Some("array".into()),
ty::Tuple(..) => return Some("tuple".into()),
_ => {
// is_recursively_primitive_type() should have taken care
// of the rest and we can rely on the type that is found
let refs_peeled = expr_type.peel_refs();
return Some(refs_peeled.walk().last().unwrap().to_string());
},
}
}
None
}
/// returns list of all pairs (a, b) from `exprs` such that `eq(a, b)`
/// `hash` must be comformed with `eq`
pub fn search_same<T, Hash, Eq>(exprs: &[T], hash: Hash, eq: Eq) -> Vec<(&T, &T)>
where
Hash: Fn(&T) -> u64,
Eq: Fn(&T, &T) -> bool,
{
if exprs.len() == 2 && eq(&exprs[0], &exprs[1]) {
return vec![(&exprs[0], &exprs[1])];
}
let mut match_expr_list: Vec<(&T, &T)> = Vec::new();
let mut map: FxHashMap<_, Vec<&_>> =
FxHashMap::with_capacity_and_hasher(exprs.len(), BuildHasherDefault::default());
for expr in exprs {
match map.entry(hash(expr)) {
Entry::Occupied(mut o) => {
for o in o.get() {
if eq(o, expr) {
match_expr_list.push((o, expr));
}
}
o.get_mut().push(expr);
},
Entry::Vacant(v) => {
v.insert(vec![expr]);
},
}
}
match_expr_list
}
#[macro_export]
macro_rules! unwrap_cargo_metadata {
($cx: ident, $lint: ident, $deps: expr) => {{
let mut command = cargo_metadata::MetadataCommand::new();
if !$deps {
command.no_deps();
}
match command.exec() {
Ok(metadata) => metadata,
Err(err) => {
span_lint($cx, $lint, DUMMY_SP, &format!("could not read cargo metadata: {}", err));
return;
},
}
}};
}
#[cfg(test)]
mod test {
use super::{reindent_multiline, without_block_comments};
#[test]
fn test_reindent_multiline_single_line() {
assert_eq!("", reindent_multiline("".into(), false, None));
assert_eq!("...", reindent_multiline("...".into(), false, None));
assert_eq!("...", reindent_multiline(" ...".into(), false, None));
assert_eq!("...", reindent_multiline("\t...".into(), false, None));
assert_eq!("...", reindent_multiline("\t\t...".into(), false, None));
}
#[test]
#[rustfmt::skip]
fn test_reindent_multiline_block() {
assert_eq!("\
if x {
y
} else {
z
}", reindent_multiline(" if x {
y
} else {
z
}".into(), false, None));
assert_eq!("\
if x {
\ty
} else {
\tz
}", reindent_multiline(" if x {
\ty
} else {
\tz
}".into(), false, None));
}
#[test]
#[rustfmt::skip]
fn test_reindent_multiline_empty_line() {
assert_eq!("\
if x {
y
} else {
z
}", reindent_multiline(" if x {
y
} else {
z
}".into(), false, None));
}
#[test]
#[rustfmt::skip]
fn test_reindent_multiline_lines_deeper() {
assert_eq!("\
if x {
y
} else {
z
}", reindent_multiline("\
if x {
y
} else {
z
}".into(), true, Some(8)));
}
#[test]
fn test_without_block_comments_lines_without_block_comments() {
let result = without_block_comments(vec!["/*", "", "*/"]);
println!("result: {:?}", result);
assert!(result.is_empty());
let result = without_block_comments(vec!["", "/*", "", "*/", "#[crate_type = \"lib\"]", "/*", "", "*/", ""]);
assert_eq!(result, vec!["", "#[crate_type = \"lib\"]", ""]);
let result = without_block_comments(vec!["/* rust", "", "*/"]);
assert!(result.is_empty());
let result = without_block_comments(vec!["/* one-line comment */"]);
assert!(result.is_empty());
let result = without_block_comments(vec!["/* nested", "/* multi-line", "comment", "*/", "test", "*/"]);
assert!(result.is_empty());
let result = without_block_comments(vec!["/* nested /* inline /* comment */ test */ */"]);
assert!(result.is_empty());
let result = without_block_comments(vec!["foo", "bar", "baz"]);
assert_eq!(result, vec!["foo", "bar", "baz"]);
}
}