mirror of
https://github.com/rust-lang/rust-clippy
synced 2024-12-23 03:23:33 +00:00
cc622608db
`must_use_unit` lints unit-returning functions with a `#[must_use]` attribute, suggesting to remove it. `double_must_use` lints functions with a plain `#[must_use]` attribute, but which return a type which is already `#[must_use]`, so the attribute has no benefit. `must_use_candidate` is a pedantic lint that lints functions and methods that return some non-unit type that is not already `#[must_use]` and suggests to add the annotation.
344 lines
11 KiB
Rust
344 lines
11 KiB
Rust
//! lint on manually implemented checked conversions that could be transformed into `try_from`
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use if_chain::if_chain;
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use rustc::hir::*;
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use rustc::lint::{in_external_macro, LateContext, LateLintPass, LintArray, LintContext, LintPass};
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use rustc::{declare_lint_pass, declare_tool_lint};
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use rustc_errors::Applicability;
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use syntax::ast::LitKind;
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use crate::utils::{snippet_with_applicability, span_lint_and_sugg, SpanlessEq};
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declare_clippy_lint! {
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/// **What it does:** Checks for explicit bounds checking when casting.
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///
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/// **Why is this bad?** Reduces the readability of statements & is error prone.
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///
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/// **Known problems:** None.
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///
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/// **Example:**
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/// ```rust
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/// # let foo: u32 = 5;
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/// # let _ =
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/// foo <= i32::max_value() as u32
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/// # ;
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/// ```
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///
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/// Could be written:
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///
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/// ```rust
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/// # use std::convert::TryFrom;
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/// # let foo = 1;
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/// # let _ =
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/// i32::try_from(foo).is_ok()
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/// # ;
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/// ```
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pub CHECKED_CONVERSIONS,
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pedantic,
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"`try_from` could replace manual bounds checking when casting"
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}
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declare_lint_pass!(CheckedConversions => [CHECKED_CONVERSIONS]);
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impl<'a, 'tcx> LateLintPass<'a, 'tcx> for CheckedConversions {
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fn check_expr(&mut self, cx: &LateContext<'_, '_>, item: &Expr) {
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let result = if_chain! {
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if !in_external_macro(cx.sess(), item.span);
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if let ExprKind::Binary(op, ref left, ref right) = &item.kind;
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then {
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match op.node {
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BinOpKind::Ge | BinOpKind::Le => single_check(item),
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BinOpKind::And => double_check(cx, left, right),
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_ => None,
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}
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} else {
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None
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}
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};
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if_chain! {
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if let Some(cv) = result;
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if let Some(to_type) = cv.to_type;
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then {
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let mut applicability = Applicability::MachineApplicable;
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let snippet = snippet_with_applicability(cx, cv.expr_to_cast.span, "_", &mut
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applicability);
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span_lint_and_sugg(
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cx,
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CHECKED_CONVERSIONS,
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item.span,
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"Checked cast can be simplified.",
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"try",
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format!("{}::try_from({}).is_ok()",
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to_type,
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snippet),
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applicability
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);
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}
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}
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}
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}
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/// Searches for a single check from unsigned to _ is done
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/// todo: check for case signed -> larger unsigned == only x >= 0
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fn single_check(expr: &Expr) -> Option<Conversion<'_>> {
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check_upper_bound(expr).filter(|cv| cv.cvt == ConversionType::FromUnsigned)
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}
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/// Searches for a combination of upper & lower bound checks
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fn double_check<'a>(cx: &LateContext<'_, '_>, left: &'a Expr, right: &'a Expr) -> Option<Conversion<'a>> {
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let upper_lower = |l, r| {
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let upper = check_upper_bound(l);
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let lower = check_lower_bound(r);
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transpose(upper, lower).and_then(|(l, r)| l.combine(r, cx))
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};
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upper_lower(left, right).or_else(|| upper_lower(right, left))
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}
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/// Contains the result of a tried conversion check
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#[derive(Clone, Debug)]
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struct Conversion<'a> {
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cvt: ConversionType,
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expr_to_cast: &'a Expr,
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to_type: Option<&'a str>,
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}
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/// The kind of conversion that is checked
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#[derive(Copy, Clone, Debug, PartialEq)]
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enum ConversionType {
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SignedToUnsigned,
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SignedToSigned,
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FromUnsigned,
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}
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impl<'a> Conversion<'a> {
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/// Combine multiple conversions if the are compatible
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pub fn combine(self, other: Self, cx: &LateContext<'_, '_>) -> Option<Conversion<'a>> {
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if self.is_compatible(&other, cx) {
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// Prefer a Conversion that contains a type-constraint
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Some(if self.to_type.is_some() { self } else { other })
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} else {
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None
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}
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}
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/// Checks if two conversions are compatible
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/// same type of conversion, same 'castee' and same 'to type'
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pub fn is_compatible(&self, other: &Self, cx: &LateContext<'_, '_>) -> bool {
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(self.cvt == other.cvt)
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&& (SpanlessEq::new(cx).eq_expr(self.expr_to_cast, other.expr_to_cast))
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&& (self.has_compatible_to_type(other))
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}
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/// Checks if the to-type is the same (if there is a type constraint)
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fn has_compatible_to_type(&self, other: &Self) -> bool {
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transpose(self.to_type.as_ref(), other.to_type.as_ref()).map_or(true, |(l, r)| l == r)
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}
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/// Try to construct a new conversion if the conversion type is valid
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fn try_new(expr_to_cast: &'a Expr, from_type: &str, to_type: &'a str) -> Option<Conversion<'a>> {
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ConversionType::try_new(from_type, to_type).map(|cvt| Conversion {
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cvt,
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expr_to_cast,
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to_type: Some(to_type),
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})
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}
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/// Construct a new conversion without type constraint
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fn new_any(expr_to_cast: &'a Expr) -> Conversion<'a> {
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Conversion {
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cvt: ConversionType::SignedToUnsigned,
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expr_to_cast,
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to_type: None,
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}
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}
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}
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impl ConversionType {
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/// Creates a conversion type if the type is allowed & conversion is valid
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#[must_use]
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fn try_new(from: &str, to: &str) -> Option<Self> {
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if UINTS.contains(&from) {
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Some(Self::FromUnsigned)
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} else if SINTS.contains(&from) {
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if UINTS.contains(&to) {
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Some(Self::SignedToUnsigned)
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} else if SINTS.contains(&to) {
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Some(Self::SignedToSigned)
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} else {
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None
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}
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} else {
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None
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}
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}
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}
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/// Check for `expr <= (to_type::max_value() as from_type)`
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fn check_upper_bound(expr: &Expr) -> Option<Conversion<'_>> {
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if_chain! {
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if let ExprKind::Binary(ref op, ref left, ref right) = &expr.kind;
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if let Some((candidate, check)) = normalize_le_ge(op, left, right);
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if let Some((from, to)) = get_types_from_cast(check, MAX_VALUE, INTS);
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then {
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Conversion::try_new(candidate, from, to)
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} else {
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None
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}
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}
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}
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/// Check for `expr >= 0|(to_type::min_value() as from_type)`
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fn check_lower_bound(expr: &Expr) -> Option<Conversion<'_>> {
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fn check_function<'a>(candidate: &'a Expr, check: &'a Expr) -> Option<Conversion<'a>> {
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(check_lower_bound_zero(candidate, check)).or_else(|| (check_lower_bound_min(candidate, check)))
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}
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// First of we need a binary containing the expression & the cast
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if let ExprKind::Binary(ref op, ref left, ref right) = &expr.kind {
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normalize_le_ge(op, right, left).and_then(|(l, r)| check_function(l, r))
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} else {
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None
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}
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}
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/// Check for `expr >= 0`
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fn check_lower_bound_zero<'a>(candidate: &'a Expr, check: &'a Expr) -> Option<Conversion<'a>> {
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if_chain! {
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if let ExprKind::Lit(ref lit) = &check.kind;
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if let LitKind::Int(0, _) = &lit.node;
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then {
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Some(Conversion::new_any(candidate))
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} else {
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None
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}
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}
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}
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/// Check for `expr >= (to_type::min_value() as from_type)`
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fn check_lower_bound_min<'a>(candidate: &'a Expr, check: &'a Expr) -> Option<Conversion<'a>> {
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if let Some((from, to)) = get_types_from_cast(check, MIN_VALUE, SINTS) {
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Conversion::try_new(candidate, from, to)
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} else {
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None
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}
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}
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/// Tries to extract the from- and to-type from a cast expression
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fn get_types_from_cast<'a>(expr: &'a Expr, func: &'a str, types: &'a [&str]) -> Option<(&'a str, &'a str)> {
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// `to_type::maxmin_value() as from_type`
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let call_from_cast: Option<(&Expr, &str)> = if_chain! {
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// to_type::maxmin_value(), from_type
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if let ExprKind::Cast(ref limit, ref from_type) = &expr.kind;
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if let TyKind::Path(ref from_type_path) = &from_type.kind;
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if let Some(from_sym) = int_ty_to_sym(from_type_path);
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then {
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Some((limit, from_sym))
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} else {
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None
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}
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};
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// `from_type::from(to_type::maxmin_value())`
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let limit_from: Option<(&Expr, &str)> = call_from_cast.or_else(|| {
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if_chain! {
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// `from_type::from, to_type::maxmin_value()`
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if let ExprKind::Call(ref from_func, ref args) = &expr.kind;
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// `to_type::maxmin_value()`
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if args.len() == 1;
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if let limit = &args[0];
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// `from_type::from`
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if let ExprKind::Path(ref path) = &from_func.kind;
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if let Some(from_sym) = get_implementing_type(path, INTS, FROM);
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then {
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Some((limit, from_sym))
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} else {
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None
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}
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}
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});
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if let Some((limit, from_type)) = limit_from {
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if_chain! {
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if let ExprKind::Call(ref fun_name, _) = &limit.kind;
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// `to_type, maxmin_value`
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if let ExprKind::Path(ref path) = &fun_name.kind;
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// `to_type`
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if let Some(to_type) = get_implementing_type(path, types, func);
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then {
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Some((from_type, to_type))
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} else {
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None
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}
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}
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} else {
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None
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}
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}
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/// Gets the type which implements the called function
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fn get_implementing_type<'a>(path: &QPath, candidates: &'a [&str], function: &str) -> Option<&'a str> {
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if_chain! {
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if let QPath::TypeRelative(ref ty, ref path) = &path;
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if path.ident.name.as_str() == function;
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if let TyKind::Path(QPath::Resolved(None, ref tp)) = &ty.kind;
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if let [int] = &*tp.segments;
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let name = &int.ident.name.as_str();
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then {
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candidates.iter().find(|c| name == *c).cloned()
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} else {
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None
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}
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}
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}
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/// Gets the type as a string, if it is a supported integer
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fn int_ty_to_sym(path: &QPath) -> Option<&str> {
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if_chain! {
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if let QPath::Resolved(_, ref path) = *path;
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if let [ty] = &*path.segments;
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let name = &ty.ident.name.as_str();
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then {
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INTS.iter().find(|c| name == *c).cloned()
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} else {
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None
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}
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}
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}
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/// (Option<T>, Option<U>) -> Option<(T, U)>
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fn transpose<T, U>(lhs: Option<T>, rhs: Option<U>) -> Option<(T, U)> {
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match (lhs, rhs) {
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(Some(l), Some(r)) => Some((l, r)),
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_ => None,
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}
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}
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/// Will return the expressions as if they were expr1 <= expr2
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fn normalize_le_ge<'a>(op: &BinOp, left: &'a Expr, right: &'a Expr) -> Option<(&'a Expr, &'a Expr)> {
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match op.node {
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BinOpKind::Le => Some((left, right)),
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BinOpKind::Ge => Some((right, left)),
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_ => None,
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}
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}
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// Constants
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const FROM: &str = "from";
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const MAX_VALUE: &str = "max_value";
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const MIN_VALUE: &str = "min_value";
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const UINTS: &[&str] = &["u8", "u16", "u32", "u64", "usize"];
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const SINTS: &[&str] = &["i8", "i16", "i32", "i64", "isize"];
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const INTS: &[&str] = &["u8", "u16", "u32", "u64", "usize", "i8", "i16", "i32", "i64", "isize"];
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