rust-clippy/tests/ui/default_numeric_fallback_f64.rs

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// run-rustfix
// aux-build:macro_rules.rs
#![warn(clippy::default_numeric_fallback)]
#![allow(
unused,
clippy::never_loop,
clippy::no_effect,
clippy::unnecessary_operation,
clippy::branches_sharing_code,
clippy::match_single_binding,
clippy::let_unit_value
)]
#[macro_use]
extern crate macro_rules;
mod basic_expr {
fn test() {
// Should lint unsuffixed literals typed `f64`.
let x = 0.12;
let x = [1., 2., 3.];
let x = if true { (1., 2.) } else { (3., 4.) };
let x = match 1. {
_ => 1.,
};
// Should NOT lint suffixed literals.
let x = 0.12_f64;
// Should NOT lint literals in init expr if `Local` has a type annotation.
let x: f64 = 0.1;
let x: [f64; 3] = [1., 2., 3.];
let x: (f64, f64) = if true { (1., 2.) } else { (3., 4.) };
let x: _ = 1.;
}
}
mod nested_local {
fn test() {
let x: _ = {
// Should lint this because this literal is not bound to any types.
let y = 1.;
// Should NOT lint this because this literal is bound to `_` of outer `Local`.
1.
};
let x: _ = if true {
// Should lint this because this literal is not bound to any types.
let y = 1.;
// Should NOT lint this because this literal is bound to `_` of outer `Local`.
1.
} else {
// Should lint this because this literal is not bound to any types.
let y = 1.;
// Should NOT lint this because this literal is bound to `_` of outer `Local`.
2.
};
}
}
mod function_def {
fn ret_f64() -> f64 {
// Even though the output type is specified,
// this unsuffixed literal is linted to reduce heuristics and keep codebase simple.
1.
}
fn test() {
// Should lint this because return type is inferred to `f64` and NOT bound to a concrete
// type.
let f = || -> _ { 1. };
// Even though the output type is specified,
// this unsuffixed literal is linted to reduce heuristics and keep codebase simple.
let f = || -> f64 { 1. };
}
}
mod function_calls {
fn concrete_arg(f: f64) {}
fn generic_arg<T>(t: T) {}
fn test() {
// Should NOT lint this because the argument type is bound to a concrete type.
concrete_arg(1.);
// Should lint this because the argument type is inferred to `f64` and NOT bound to a concrete type.
generic_arg(1.);
// Should lint this because the argument type is inferred to `f64` and NOT bound to a concrete type.
let x: _ = generic_arg(1.);
}
}
mod struct_ctor {
struct ConcreteStruct {
x: f64,
}
struct GenericStruct<T> {
x: T,
}
fn test() {
// Should NOT lint this because the field type is bound to a concrete type.
ConcreteStruct { x: 1. };
// Should lint this because the field type is inferred to `f64` and NOT bound to a concrete type.
GenericStruct { x: 1. };
// Should lint this because the field type is inferred to `f64` and NOT bound to a concrete type.
let _ = GenericStruct { x: 1. };
}
}
mod enum_ctor {
enum ConcreteEnum {
X(f64),
}
enum GenericEnum<T> {
X(T),
}
fn test() {
// Should NOT lint this because the field type is bound to a concrete type.
ConcreteEnum::X(1.);
// Should lint this because the field type is inferred to `f64` and NOT bound to a concrete type.
GenericEnum::X(1.);
}
}
mod method_calls {
struct StructForMethodCallTest;
impl StructForMethodCallTest {
fn concrete_arg(&self, f: f64) {}
fn generic_arg<T>(&self, t: T) {}
}
fn test() {
let s = StructForMethodCallTest {};
// Should NOT lint this because the argument type is bound to a concrete type.
s.concrete_arg(1.);
// Should lint this because the argument type is bound to a concrete type.
s.generic_arg(1.);
}
}
mod in_macro {
macro_rules! internal_macro {
() => {
let x = 22.;
};
}
// Should lint in internal macro.
fn internal() {
internal_macro!();
}
// Should NOT lint in external macro.
fn external() {
default_numeric_fallback!();
}
}
fn main() {}