rust-clippy/clippy_lints/src/infinite_iter.rs

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use rustc_hir::{BorrowKind, Expr, ExprKind};
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use rustc_lint::{LateContext, LateLintPass};
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use rustc_session::{declare_lint_pass, declare_tool_lint};
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use crate::utils::{get_trait_def_id, higher, implements_trait, match_qpath, match_type, paths, span_lint};
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declare_clippy_lint! {
/// **What it does:** Checks for iteration that is guaranteed to be infinite.
///
/// **Why is this bad?** While there may be places where this is acceptable
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/// (e.g., in event streams), in most cases this is simply an error.
///
/// **Known problems:** None.
///
/// **Example:**
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/// ```no_run
/// use std::iter;
///
/// iter::repeat(1_u8).collect::<Vec<_>>();
/// ```
pub INFINITE_ITER,
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correctness,
"infinite iteration"
}
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declare_clippy_lint! {
/// **What it does:** Checks for iteration that may be infinite.
///
/// **Why is this bad?** While there may be places where this is acceptable
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/// (e.g., in event streams), in most cases this is simply an error.
///
/// **Known problems:** The code may have a condition to stop iteration, but
/// this lint is not clever enough to analyze it.
///
/// **Example:**
/// ```rust
/// let infinite_iter = 0..;
/// [0..].iter().zip(infinite_iter.take_while(|x| *x > 5));
/// ```
pub MAYBE_INFINITE_ITER,
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pedantic,
"possible infinite iteration"
}
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declare_lint_pass!(InfiniteIter => [INFINITE_ITER, MAYBE_INFINITE_ITER]);
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impl<'a, 'tcx> LateLintPass<'a, 'tcx> for InfiniteIter {
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fn check_expr(&mut self, cx: &LateContext<'a, 'tcx>, expr: &'tcx Expr<'_>) {
let (lint, msg) = match complete_infinite_iter(cx, expr) {
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Infinite => (INFINITE_ITER, "infinite iteration detected"),
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MaybeInfinite => (MAYBE_INFINITE_ITER, "possible infinite iteration detected"),
Finite => {
return;
},
};
span_lint(cx, lint, expr.span, msg)
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
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enum Finiteness {
Infinite,
MaybeInfinite,
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Finite,
}
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use self::Finiteness::{Finite, Infinite, MaybeInfinite};
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impl Finiteness {
#[must_use]
fn and(self, b: Self) -> Self {
match (self, b) {
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(Finite, _) | (_, Finite) => Finite,
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(MaybeInfinite, _) | (_, MaybeInfinite) => MaybeInfinite,
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_ => Infinite,
}
}
#[must_use]
fn or(self, b: Self) -> Self {
match (self, b) {
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(Infinite, _) | (_, Infinite) => Infinite,
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(MaybeInfinite, _) | (_, MaybeInfinite) => MaybeInfinite,
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_ => Finite,
}
}
}
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impl From<bool> for Finiteness {
#[must_use]
fn from(b: bool) -> Self {
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if b {
Infinite
} else {
Finite
}
}
}
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/// This tells us what to look for to know if the iterator returned by
/// this method is infinite
#[derive(Copy, Clone)]
enum Heuristic {
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/// infinite no matter what
Always,
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/// infinite if the first argument is
First,
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/// infinite if any of the supplied arguments is
Any,
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/// infinite if all of the supplied arguments are
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All,
}
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use self::Heuristic::{All, Always, Any, First};
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/// a slice of (method name, number of args, heuristic, bounds) tuples
/// that will be used to determine whether the method in question
/// returns an infinite or possibly infinite iterator. The finiteness
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/// is an upper bound, e.g., some methods can return a possibly
/// infinite iterator at worst, e.g., `take_while`.
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const HEURISTICS: [(&str, usize, Heuristic, Finiteness); 19] = [
("zip", 2, All, Infinite),
("chain", 2, Any, Infinite),
("cycle", 1, Always, Infinite),
("map", 2, First, Infinite),
("by_ref", 1, First, Infinite),
("cloned", 1, First, Infinite),
("rev", 1, First, Infinite),
("inspect", 1, First, Infinite),
("enumerate", 1, First, Infinite),
("peekable", 2, First, Infinite),
("fuse", 1, First, Infinite),
("skip", 2, First, Infinite),
("skip_while", 1, First, Infinite),
("filter", 2, First, Infinite),
("filter_map", 2, First, Infinite),
("flat_map", 2, First, Infinite),
("unzip", 1, First, Infinite),
("take_while", 2, First, MaybeInfinite),
("scan", 3, First, MaybeInfinite),
];
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fn is_infinite(cx: &LateContext<'_, '_>, expr: &Expr<'_>) -> Finiteness {
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match expr.kind {
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ExprKind::MethodCall(ref method, _, ref args) => {
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for &(name, len, heuristic, cap) in &HEURISTICS {
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if method.ident.name.as_str() == name && args.len() == len {
return (match heuristic {
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Always => Infinite,
First => is_infinite(cx, &args[0]),
Any => is_infinite(cx, &args[0]).or(is_infinite(cx, &args[1])),
All => is_infinite(cx, &args[0]).and(is_infinite(cx, &args[1])),
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})
.and(cap);
}
}
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if method.ident.name == sym!(flat_map) && args.len() == 2 {
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if let ExprKind::Closure(_, _, body_id, _, _) = args[1].kind {
let body = cx.tcx.hir().body(body_id);
return is_infinite(cx, &body.value);
}
}
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Finite
},
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ExprKind::Block(ref block, _) => block.expr.as_ref().map_or(Finite, |e| is_infinite(cx, e)),
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ExprKind::Box(ref e) | ExprKind::AddrOf(BorrowKind::Ref, _, ref e) => is_infinite(cx, e),
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ExprKind::Call(ref path, _) => {
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if let ExprKind::Path(ref qpath) = path.kind {
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match_qpath(qpath, &paths::REPEAT).into()
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} else {
Finite
}
},
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ExprKind::Struct(..) => higher::range(cx, expr).map_or(false, |r| r.end.is_none()).into(),
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_ => Finite,
}
}
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/// the names and argument lengths of methods that *may* exhaust their
/// iterators
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const POSSIBLY_COMPLETING_METHODS: [(&str, usize); 6] = [
("find", 2),
("rfind", 2),
("position", 2),
("rposition", 2),
("any", 2),
("all", 2),
];
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/// the names and argument lengths of methods that *always* exhaust
/// their iterators
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const COMPLETING_METHODS: [(&str, usize); 12] = [
("count", 1),
("fold", 3),
("for_each", 2),
("partition", 2),
("max", 1),
("max_by", 2),
("max_by_key", 2),
("min", 1),
("min_by", 2),
("min_by_key", 2),
("sum", 1),
("product", 1),
];
/// the paths of types that are known to be infinitely allocating
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const INFINITE_COLLECTORS: [&[&str]; 8] = [
&paths::BINARY_HEAP,
&paths::BTREEMAP,
&paths::BTREESET,
&paths::HASHMAP,
&paths::HASHSET,
&paths::LINKED_LIST,
&paths::VEC,
&paths::VEC_DEQUE,
];
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fn complete_infinite_iter(cx: &LateContext<'_, '_>, expr: &Expr<'_>) -> Finiteness {
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match expr.kind {
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ExprKind::MethodCall(ref method, _, ref args) => {
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for &(name, len) in &COMPLETING_METHODS {
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if method.ident.name.as_str() == name && args.len() == len {
return is_infinite(cx, &args[0]);
}
}
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for &(name, len) in &POSSIBLY_COMPLETING_METHODS {
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if method.ident.name.as_str() == name && args.len() == len {
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return MaybeInfinite.and(is_infinite(cx, &args[0]));
}
}
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if method.ident.name == sym!(last) && args.len() == 1 {
let not_double_ended = get_trait_def_id(cx, &paths::DOUBLE_ENDED_ITERATOR)
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.map_or(false, |id| !implements_trait(cx, cx.tables.expr_ty(&args[0]), id, &[]));
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if not_double_ended {
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return is_infinite(cx, &args[0]);
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}
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} else if method.ident.name == sym!(collect) {
let ty = cx.tables.expr_ty(expr);
if INFINITE_COLLECTORS.iter().any(|path| match_type(cx, ty, path)) {
return is_infinite(cx, &args[0]);
}
}
},
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ExprKind::Binary(op, ref l, ref r) => {
if op.node.is_comparison() {
return is_infinite(cx, l).and(is_infinite(cx, r)).and(MaybeInfinite);
}
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}, // TODO: ExprKind::Loop + Match
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_ => (),
}
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Finite
}