rust/tests/mir-opt/gvn.rs

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//@ test-mir-pass: GVN
//@ compile-flags: -Zdump-mir-exclude-alloc-bytes
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// EMIT_MIR_FOR_EACH_PANIC_STRATEGY
//@ only-64bit
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#![feature(rustc_attrs)]
#![feature(custom_mir)]
#![feature(core_intrinsics)]
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#![feature(freeze)]
#![allow(ambiguous_wide_pointer_comparisons)]
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#![allow(unconditional_panic)]
#![allow(unused)]
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use std::intrinsics::mir::*;
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use std::marker::Freeze;
use std::mem::transmute;
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struct S<T>(T);
fn subexpression_elimination(x: u64, y: u64, mut z: u64) {
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// CHECK-LABEL: fn subexpression_elimination(
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// CHECK: [[add:_.*]] = Add(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[add]])
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opaque(x + y);
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// CHECK: [[mul:_.*]] = Mul(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[mul]])
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opaque(x * y);
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// CHECK: [[sub:_.*]] = Sub(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[sub]])
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opaque(x - y);
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// CHECK: [[div:_.*]] = Div(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[div]])
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opaque(x / y);
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// CHECK: [[rem:_.*]] = Rem(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[rem]])
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opaque(x % y);
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// CHECK: [[and:_.*]] = BitAnd(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[and]])
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opaque(x & y);
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// CHECK: [[or:_.*]] = BitOr(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[or]])
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opaque(x | y);
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// CHECK: [[xor:_.*]] = BitXor(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[xor]])
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opaque(x ^ y);
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// CHECK: [[shl:_.*]] = Shl(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[shl]])
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opaque(x << y);
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// CHECK: [[shr:_.*]] = Shr(copy _1, copy _2);
// CHECK: opaque::<u64>(copy [[shr]])
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opaque(x >> y);
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// CHECK: [[int:_.*]] = copy _1 as u32 (IntToInt);
// CHECK: opaque::<u32>(copy [[int]])
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opaque(x as u32);
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// CHECK: [[float:_.*]] = copy _1 as f32 (IntToFloat);
// CHECK: opaque::<f32>(copy [[float]])
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opaque(x as f32);
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// CHECK: [[wrap:_.*]] = S::<u64>(copy _1);
// CHECK: opaque::<S<u64>>(copy [[wrap]])
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opaque(S(x));
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// CHECK: opaque::<u64>(copy _1)
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opaque(S(x).0);
// Those are duplicates to substitute somehow.
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// CHECK: opaque::<u64>(copy [[add]])
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opaque(x + y);
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// CHECK: opaque::<u64>(copy [[mul]])
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opaque(x * y);
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// CHECK: opaque::<u64>(copy [[sub]])
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opaque(x - y);
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// CHECK: opaque::<u64>(copy [[div]])
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opaque(x / y);
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// CHECK: opaque::<u64>(copy [[rem]])
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opaque(x % y);
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// CHECK: opaque::<u64>(copy [[and]])
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opaque(x & y);
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// CHECK: opaque::<u64>(copy [[or]])
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opaque(x | y);
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// CHECK: opaque::<u64>(copy [[xor]])
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opaque(x ^ y);
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// CHECK: opaque::<u64>(copy [[shl]])
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opaque(x << y);
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// CHECK: opaque::<u64>(copy [[shr]])
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opaque(x >> y);
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// CHECK: opaque::<u32>(copy [[int]])
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opaque(x as u32);
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// CHECK: opaque::<f32>(copy [[float]])
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opaque(x as f32);
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// CHECK: opaque::<S<u64>>(copy [[wrap]])
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opaque(S(x));
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// CHECK: opaque::<u64>(copy _1)
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opaque(S(x).0);
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// We can substitute through a complex expression.
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// CHECK: [[compound:_.*]] = Sub(copy [[mul]], copy _2);
// CHECK: opaque::<u64>(copy [[compound]])
// CHECK: opaque::<u64>(copy [[compound]])
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opaque((x * y) - y);
opaque((x * y) - y);
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// We can substitute through an immutable reference too.
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// CHECK: [[ref:_.*]] = &_3;
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// CHECK: [[deref:_.*]] = copy (*[[ref]]);
// CHECK: [[addref:_.*]] = Add(copy [[deref]], copy _1);
// CHECK: opaque::<u64>(copy [[addref]])
// CHECK: opaque::<u64>(copy [[addref]])
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let a = &z;
opaque(*a + x);
opaque(*a + x);
// But not through a mutable reference or a pointer.
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// CHECK: [[mut:_.*]] = &mut _3;
// CHECK: [[addmut:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addmut]])
// CHECK: [[addmut2:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addmut2]])
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let b = &mut z;
opaque(*b + x);
opaque(*b + x);
unsafe {
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// CHECK: [[raw:_.*]] = &raw const _3;
// CHECK: [[addraw:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addraw]])
// CHECK: [[addraw2:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addraw2]])
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let c = &raw const z;
opaque(*c + x);
opaque(*c + x);
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// CHECK: [[ptr:_.*]] = &raw mut _3;
// CHECK: [[addptr:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addptr]])
// CHECK: [[addptr2:_.*]] = Add(
// CHECK: opaque::<u64>(move [[addptr2]])
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let d = &raw mut z;
opaque(*d + x);
opaque(*d + x);
}
// We can substitute again, but not with the earlier computations.
// Important: `e` is not `a`!
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// CHECK: [[ref2:_.*]] = &_3;
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// CHECK: [[deref2:_.*]] = copy (*[[ref2]]);
// CHECK: [[addref2:_.*]] = Add(copy [[deref2]], copy _1);
// CHECK: opaque::<u64>(copy [[addref2]])
// CHECK: opaque::<u64>(copy [[addref2]])
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let e = &z;
opaque(*e + x);
opaque(*e + x);
}
fn wrap_unwrap<T: Copy>(x: T) -> T {
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// CHECK-LABEL: fn wrap_unwrap(
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// CHECK: [[some:_.*]] = Option::<T>::Some(copy _1);
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// CHECK: switchInt(const 1_isize)
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// CHECK: _0 = copy _1;
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match Some(x) {
Some(y) => y,
None => panic!(),
}
}
fn repeated_index<T: Copy, const N: usize>(x: T, idx: usize) {
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// CHECK-LABEL: fn repeated_index(
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// CHECK: [[a:_.*]] = [copy _1; N];
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let a = [x; N];
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// CHECK: opaque::<T>(copy _1)
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opaque(a[0]);
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// CHECK: opaque::<T>(copy _1)
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opaque(a[idx]);
}
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fn unary(x: i64) {
// CHECK-LABEL: fn unary(
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// CHECK: opaque::<i64>(copy _1)
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opaque(--x); // This is `x`.
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// CHECK: [[b:_.*]] = Lt(copy _1, const 13_i64);
// CHECK: opaque::<bool>(copy [[b]])
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let b = x < 13;
opaque(!!b); // This is `b`.
// Both lines should test the same thing.
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// CHECK: [[c:_.*]] = Ne(copy _1, const 15_i64);
// CHECK: opaque::<bool>(copy [[c]])
// CHECK: opaque::<bool>(copy [[c]])
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opaque(x != 15);
opaque(!(x == 15));
// Both lines should test the same thing.
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// CHECK: [[d:_.*]] = Eq(copy _1, const 35_i64);
// CHECK: opaque::<bool>(copy [[d]])
// CHECK: opaque::<bool>(copy [[d]])
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opaque(x == 35);
opaque(!(x != 35));
}
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/// Verify symbolic integer arithmetic simplifications.
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fn arithmetic(x: u64) {
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// CHECK-LABEL: fn arithmetic(
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// CHECK: opaque::<u64>(copy _1)
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opaque(x + 0);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x - 0);
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// CHECK: opaque::<u64>(const 0_u64)
opaque(x - x);
// CHECK: opaque::<u64>(const 0_u64)
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opaque(x * 0);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x * 1);
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// CHECK: assert(!const true, "attempt to divide `{}` by zero",
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// CHECK: [[div0:_.*]] = Div(copy _1, const 0_u64);
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// CHECK: opaque::<u64>(move [[div0]])
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opaque(x / 0);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x / 1);
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// CHECK: opaque::<u64>(const 0_u64)
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opaque(0 / x);
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// CHECK: [[odiv:_.*]] = Div(const 1_u64, copy _1);
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// CHECK: opaque::<u64>(move [[odiv]])
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opaque(1 / x);
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// CHECK: assert(!const true, "attempt to calculate the remainder of `{}` with a divisor of zero"
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// CHECK: [[rem0:_.*]] = Rem(copy _1, const 0_u64);
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// CHECK: opaque::<u64>(move [[rem0]])
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opaque(x % 0);
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// CHECK: opaque::<u64>(const 0_u64)
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opaque(x % 1);
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// CHECK: opaque::<u64>(const 0_u64)
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opaque(0 % x);
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// CHECK: [[orem:_.*]] = Rem(const 1_u64, copy _1);
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// CHECK: opaque::<u64>(move [[orem]])
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opaque(1 % x);
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// CHECK: opaque::<u64>(const 0_u64)
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opaque(x & 0);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x & u64::MAX);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x | 0);
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// CHECK: opaque::<u64>(const u64::MAX)
opaque(x | u64::MAX);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x ^ 0);
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// CHECK: opaque::<u64>(const 0_u64)
opaque(x ^ x);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x >> 0);
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// CHECK: opaque::<u64>(copy _1)
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opaque(x << 0);
}
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fn comparison(x: u64, y: u64) {
// CHECK-LABEL: fn comparison(
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// CHECK: opaque::<bool>(const true)
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opaque(x == x);
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// CHECK: opaque::<bool>(const false)
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opaque(x != x);
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// CHECK: [[eqxy:_.*]] = Eq(copy _1, copy _2);
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// CHECK: opaque::<bool>(move [[eqxy]])
opaque(x == y);
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// CHECK: [[nexy:_.*]] = Ne(copy _1, copy _2);
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// CHECK: opaque::<bool>(move [[nexy]])
opaque(x != y);
}
/// Verify symbolic integer arithmetic simplifications on checked ops.
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#[rustc_inherit_overflow_checks]
fn arithmetic_checked(x: u64) {
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// CHECK-LABEL: fn arithmetic_checked(
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// CHECK: assert(!const false,
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// CHECK: opaque::<u64>(copy _1)
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opaque(x + 0);
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// CHECK: assert(!const false,
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// CHECK: opaque::<u64>(copy _1)
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opaque(x - 0);
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// CHECK: assert(!const false,
// CHECK: opaque::<u64>(const 0_u64)
opaque(x - x);
// CHECK: assert(!const false,
// CHECK: opaque::<u64>(const 0_u64)
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opaque(x * 0);
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// CHECK: assert(!const false,
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// CHECK: opaque::<u64>(copy _1)
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opaque(x * 1);
}
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/// Verify that we do not apply arithmetic simplifications on floats.
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fn arithmetic_float(x: f64) {
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// CHECK-LABEL: fn arithmetic_float(
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// CHECK: [[add:_.*]] = Add(copy _1, const 0f64);
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// CHECK: opaque::<f64>(move [[add]])
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opaque(x + 0.);
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// CHECK: [[sub:_.*]] = Sub(copy _1, const 0f64);
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// CHECK: opaque::<f64>(move [[sub]])
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opaque(x - 0.);
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// CHECK: [[mul:_.*]] = Mul(copy _1, const 0f64);
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// CHECK: opaque::<f64>(move [[mul]])
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opaque(x * 0.);
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// CHECK: [[div0:_.*]] = Div(copy _1, const 0f64);
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// CHECK: opaque::<f64>(move [[div0]])
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opaque(x / 0.);
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// CHECK: [[zdiv:_.*]] = Div(const 0f64, copy _1);
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// CHECK: opaque::<f64>(move [[zdiv]])
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opaque(0. / x);
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// CHECK: [[rem0:_.*]] = Rem(copy _1, const 0f64);
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// CHECK: opaque::<f64>(move [[rem0]])
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opaque(x % 0.);
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// CHECK: [[zrem:_.*]] = Rem(const 0f64, copy _1);
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// CHECK: opaque::<f64>(move [[zrem]])
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opaque(0. % x);
// Those are not simplifiable to `true`/`false`, thanks to NaNs.
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// CHECK: [[eq:_.*]] = Eq(copy _1, copy _1);
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// CHECK: opaque::<bool>(move [[eq]])
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opaque(x == x);
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// CHECK: [[ne:_.*]] = Ne(copy _1, copy _1);
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// CHECK: opaque::<bool>(move [[ne]])
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opaque(x != x);
}
fn cast() {
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// CHECK-LABEL: fn cast(
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let i = 1_i64;
let u = 1_u64;
let f = 1_f64;
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// CHECK: opaque::<u8>(const 1_u8)
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opaque(i as u8);
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// CHECK: opaque::<u16>(const 1_u16)
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opaque(i as u16);
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// CHECK: opaque::<u32>(const 1_u32)
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opaque(i as u32);
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// CHECK: opaque::<u64>(const 1_u64)
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opaque(i as u64);
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// CHECK: opaque::<i8>(const 1_i8)
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opaque(i as i8);
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// CHECK: opaque::<i16>(const 1_i16)
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opaque(i as i16);
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// CHECK: opaque::<i32>(const 1_i32)
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opaque(i as i32);
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// CHECK: opaque::<i64>(const 1_i64)
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opaque(i as i64);
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// CHECK: opaque::<f32>(const 1f32)
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opaque(i as f32);
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// CHECK: opaque::<f64>(const 1f64)
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opaque(i as f64);
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// CHECK: opaque::<u8>(const 1_u8)
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opaque(u as u8);
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// CHECK: opaque::<u16>(const 1_u16)
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opaque(u as u16);
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// CHECK: opaque::<u32>(const 1_u32)
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opaque(u as u32);
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// CHECK: opaque::<u64>(const 1_u64)
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opaque(u as u64);
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// CHECK: opaque::<i8>(const 1_i8)
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opaque(u as i8);
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// CHECK: opaque::<i16>(const 1_i16)
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opaque(u as i16);
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// CHECK: opaque::<i32>(const 1_i32)
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opaque(u as i32);
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// CHECK: opaque::<i64>(const 1_i64)
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opaque(u as i64);
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// CHECK: opaque::<f32>(const 1f32)
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opaque(u as f32);
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// CHECK: opaque::<f64>(const 1f64)
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opaque(u as f64);
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// CHECK: opaque::<u8>(const 1_u8)
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opaque(f as u8);
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// CHECK: opaque::<u16>(const 1_u16)
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opaque(f as u16);
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// CHECK: opaque::<u32>(const 1_u32)
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opaque(f as u32);
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// CHECK: opaque::<u64>(const 1_u64)
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opaque(f as u64);
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// CHECK: opaque::<i8>(const 1_i8)
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opaque(f as i8);
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// CHECK: opaque::<i16>(const 1_i16)
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opaque(f as i16);
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// CHECK: opaque::<i32>(const 1_i32)
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opaque(f as i32);
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// CHECK: opaque::<i64>(const 1_i64)
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opaque(f as i64);
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// CHECK: opaque::<f32>(const 1f32)
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opaque(f as f32);
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// CHECK: opaque::<f64>(const 1f64)
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opaque(f as f64);
}
fn multiple_branches(t: bool, x: u8, y: u8) {
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// CHECK-LABEL: fn multiple_branches(
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// CHECK: switchInt(copy _1) -> [0: [[bbf:bb.*]], otherwise: [[bbt:bb.*]]];
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if t {
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// CHECK: [[bbt]]: {
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// CHECK: [[a:_.*]] = Add(copy _2, copy _3);
// CHECK: opaque::<u8>(copy [[a]])
// CHECK: opaque::<u8>(copy [[a]])
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// CHECK: goto -> [[bbc:bb.*]];
opaque(x + y);
opaque(x + y);
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} else {
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// CHECK: [[bbf]]: {
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// CHECK: [[b:_.*]] = Add(copy _2, copy _3);
// CHECK: opaque::<u8>(copy [[b]])
// CHECK: opaque::<u8>(copy [[b]])
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// CHECK: goto -> [[bbc:bb.*]];
opaque(x + y);
opaque(x + y);
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}
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// Neither `a` nor `b` dominate `c`, so we cannot reuse any of them.
// CHECK: [[bbc]]: {
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// CHECK: [[c:_.*]] = Add(copy _2, copy _3);
// CHECK: opaque::<u8>(copy [[c]])
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opaque(x + y);
// `c` dominates both calls, so we can reuse it.
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if t {
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// CHECK: opaque::<u8>(copy [[c]])
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opaque(x + y);
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} else {
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// CHECK: opaque::<u8>(copy [[c]])
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opaque(x + y);
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}
}
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/// Verify that we do not reuse a `&raw? mut?` rvalue.
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fn references(mut x: impl Sized) {
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// CHECK-LABEL: fn references(
// CHECK: [[ref1:_.*]] = &_1;
// CHECK: opaque::<&impl Sized>(move [[ref1]])
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opaque(&x);
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// CHECK: [[ref2:_.*]] = &_1;
// CHECK: opaque::<&impl Sized>(move [[ref2]])
opaque(&x);
// CHECK: [[ref3:_.*]] = &mut _1;
// CHECK: opaque::<&mut impl Sized>(move [[ref3]])
opaque(&mut x);
// CHECK: [[ref4:_.*]] = &mut _1;
// CHECK: opaque::<&mut impl Sized>(move [[ref4]])
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opaque(&mut x);
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// CHECK: [[ref5:_.*]] = &raw const _1;
// CHECK: opaque::<*const impl Sized>(move [[ref5]])
opaque(&raw const x);
// CHECK: [[ref6:_.*]] = &raw const _1;
// CHECK: opaque::<*const impl Sized>(move [[ref6]])
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opaque(&raw const x);
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// CHECK: [[ref7:_.*]] = &raw mut _1;
// CHECK: opaque::<*mut impl Sized>(move [[ref7]])
opaque(&raw mut x);
// CHECK: [[ref8:_.*]] = &raw mut _1;
// CHECK: opaque::<*mut impl Sized>(move [[ref8]])
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opaque(&raw mut x);
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let r = &mut x;
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let s = S(r).0; // Obfuscate `r`. Following lines should still reborrow `r`.
// CHECK: [[ref9:_.*]] = &mut _1;
// CHECK: [[ref10:_.*]] = &(*[[ref9]]);
// CHECK: opaque::<&impl Sized>(move [[ref10]])
opaque(&*s);
// CHECK: [[ref11:_.*]] = &mut (*[[ref9]]);
// CHECK: opaque::<&mut impl Sized>(move [[ref11]])
opaque(&mut *s);
// CHECK: [[ref12:_.*]] = &raw const (*[[ref9]]);
// CHECK: opaque::<*const impl Sized>(move [[ref12]])
opaque(&raw const *s);
// CHECK: [[ref12:_.*]] = &raw mut (*[[ref9]]);
// CHECK: opaque::<*mut impl Sized>(move [[ref12]])
opaque(&raw mut *s);
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}
fn dereferences(t: &mut u32, u: &impl Copy, s: &S<u32>) {
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// CHECK-LABEL: fn dereferences(
// Do not reuse dereferences of `&mut`.
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// CHECK: [[st1:_.*]] = copy (*_1);
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// CHECK: opaque::<u32>(move [[st1]])
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// CHECK: [[st2:_.*]] = copy (*_1);
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// CHECK: opaque::<u32>(move [[st2]])
opaque(*t);
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opaque(*t);
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// Do not reuse dereferences of `*const`.
// CHECK: [[raw:_.*]] = &raw const (*_1);
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// CHECK: [[st3:_.*]] = copy (*[[raw]]);
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// CHECK: opaque::<u32>(move [[st3]])
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// CHECK: [[st4:_.*]] = copy (*[[raw]]);
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// CHECK: opaque::<u32>(move [[st4]])
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let z = &raw const *t;
unsafe { opaque(*z) };
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unsafe { opaque(*z) };
// Do not reuse dereferences of `*mut`.
// CHECK: [[ptr:_.*]] = &raw mut (*_1);
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// CHECK: [[st5:_.*]] = copy (*[[ptr]]);
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// CHECK: opaque::<u32>(move [[st5]])
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// CHECK: [[st6:_.*]] = copy (*[[ptr]]);
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// CHECK: opaque::<u32>(move [[st6]])
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let z = &raw mut *t;
unsafe { opaque(*z) };
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unsafe { opaque(*z) };
// We can reuse dereferences of `&Freeze`.
// CHECK: [[ref:_.*]] = &(*_1);
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// CHECK: [[st7:_.*]] = copy (*[[ref]]);
// CHECK: opaque::<u32>(copy [[st7]])
// CHECK: opaque::<u32>(copy [[st7]])
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let z = &*t;
opaque(*z);
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opaque(*z);
// But not in reborrows.
// CHECK: [[reborrow:_.*]] = &(*[[ref]]);
// CHECK: opaque::<&u32>(move [[reborrow]])
opaque(&*z);
// `*u` is not Freeze, so we cannot reuse.
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// CHECK: [[st8:_.*]] = copy (*_2);
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// CHECK: opaque::<impl Copy>(move [[st8]])
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// CHECK: [[st9:_.*]] = copy (*_2);
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// CHECK: opaque::<impl Copy>(move [[st9]])
opaque(*u);
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opaque(*u);
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// `*s` is not Copy, but `(*s).0` is, so we can reuse.
// CHECK: [[st10:_.*]] = copy ((*_3).0: u32);
// CHECK: opaque::<u32>(copy [[st10]])
// CHECK: opaque::<u32>(copy [[st10]])
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opaque(s.0);
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opaque(s.0);
}
fn slices() {
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// CHECK-LABEL: fn slices(
// CHECK: {{_.*}} = const "
// CHECK-NOT: {{_.*}} = const "
let s = "my favourite slice"; // This is a `Const::Slice` in MIR.
opaque(s);
let t = s; // This should be the same pointer, so cannot be a `Const::Slice`.
opaque(t);
assert_eq!(s.as_ptr(), t.as_ptr());
let u = unsafe { transmute::<&str, &[u8]>(s) };
opaque(u);
assert_eq!(s.as_ptr(), u.as_ptr());
}
#[custom_mir(dialect = "analysis")]
fn duplicate_slice() -> (bool, bool) {
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// CHECK-LABEL: fn duplicate_slice(
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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mir! {
let au: u128;
let bu: u128;
let cu: u128;
let du: u128;
let c: &str;
let d: &str;
{
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// CHECK: [[a:_.*]] = (const "a",);
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// CHECK: [[au:_.*]] = copy ([[a]].0: &str) as u128 (Transmute);
let a = ("a",);
Call(au = transmute::<_, u128>(a.0), ReturnTo(bb1), UnwindContinue())
}
bb1 = {
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// CHECK: [[c:_.*]] = identity::<&str>(copy ([[a]].0: &str))
Call(c = identity(a.0), ReturnTo(bb2), UnwindContinue())
}
bb2 = {
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// CHECK: [[cu:_.*]] = copy [[c]] as u128 (Transmute);
Call(cu = transmute::<_, u128>(c), ReturnTo(bb3), UnwindContinue())
}
bb3 = {
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// This slice is different from `a.0`. Hence `bu` is not `au`.
// CHECK: [[b:_.*]] = const "a";
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// CHECK: [[bu:_.*]] = copy [[b]] as u128 (Transmute);
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let b = "a";
Call(bu = transmute::<_, u128>(b), ReturnTo(bb4), UnwindContinue())
}
bb4 = {
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// This returns a copy of `b`, which is not `a`.
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// CHECK: [[d:_.*]] = identity::<&str>(copy [[b]])
Call(d = identity(b), ReturnTo(bb5), UnwindContinue())
}
bb5 = {
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// CHECK: [[du:_.*]] = copy [[d]] as u128 (Transmute);
Call(du = transmute::<_, u128>(d), ReturnTo(bb6), UnwindContinue())
}
bb6 = {
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// `direct` must not fold to `true`, as `indirect` will not.
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// CHECK: = Eq(copy [[au]], copy [[bu]]);
// CHECK: = Eq(copy [[cu]], copy [[du]]);
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let direct = au == bu;
let indirect = cu == du;
RET = (direct, indirect);
Return()
}
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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}
}
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fn repeat() {
// CHECK-LABEL: fn repeat(
// CHECK: = [const 5_i32; 10];
let val = 5;
let array = [val, val, val, val, val, val, val, val, val, val];
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}
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/// Verify that we do not merge fn pointers created by casts.
fn fn_pointers() {
// CHECK-LABEL: fn fn_pointers(
// CHECK: [[f:_.*]] = identity::<u8> as fn(u8) -> u8 (PointerCoercion(ReifyFnPointer
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// CHECK: opaque::<fn(u8) -> u8>(copy [[f]])
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let f = identity as fn(u8) -> u8;
opaque(f);
// CHECK: [[g:_.*]] = identity::<u8> as fn(u8) -> u8 (PointerCoercion(ReifyFnPointer
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// CHECK: opaque::<fn(u8) -> u8>(copy [[g]])
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let g = identity as fn(u8) -> u8;
opaque(g);
// CHECK: [[cf:_.*]] = const {{.*}} as fn() (PointerCoercion(ClosureFnPointer
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// CHECK: opaque::<fn()>(copy [[cf]])
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let closure = || {};
let cf = closure as fn();
opaque(cf);
// CHECK: [[cg:_.*]] = const {{.*}} as fn() (PointerCoercion(ClosureFnPointer
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// CHECK: opaque::<fn()>(copy [[cg]])
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let cg = closure as fn();
opaque(cg);
}
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/// Verify that we do not create a `ConstValue::Indirect` backed by a static's AllocId.
#[custom_mir(dialect = "analysis")]
fn indirect_static() {
static A: Option<u8> = None;
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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mir! {
{
let ptr = Static(A);
let out = Field::<u8>(Variant(*ptr, 1), 0);
Return()
}
}
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}
/// Verify that having constant index `u64::MAX` does not yield to an overflow in rustc.
fn constant_index_overflow<T: Copy>(x: &[T]) {
// CHECK-LABEL: fn constant_index_overflow(
// CHECK: debug a => [[a:_.*]];
// CHECK: debug b => [[b:_.*]];
// CHECK: [[a]] = const usize::MAX;
// CHECK-NOT: = (*_1)[{{.*}} of 0];
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// CHECK: [[b]] = copy (*_1)[[[a]]];
// CHECK-NOT: = (*_1)[{{.*}} of 0];
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// CHECK: [[b]] = copy (*_1)[0 of 1];
// CHECK-NOT: = (*_1)[{{.*}} of 0];
let a = u64::MAX as usize;
let b = if a < x.len() { x[a] } else { x[0] };
opaque(b)
}
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/// Check that we do not attempt to simplify anything when there is provenance.
fn wide_ptr_provenance() {
// CHECK-LABEL: fn wide_ptr_provenance(
let a: *const dyn Send = &1 as &dyn Send;
let b: *const dyn Send = &1 as &dyn Send;
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// CHECK: [[eqp:_.*]] = Eq(copy [[a:_.*]], copy [[b:_.*]]);
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// CHECK: opaque::<bool>(move [[eqp]])
opaque(a == b);
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// CHECK: [[nep:_.*]] = Ne(copy [[a]], copy [[b]]);
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// CHECK: opaque::<bool>(move [[nep]])
opaque(a != b);
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// CHECK: [[ltp:_.*]] = Lt(copy [[a]], copy [[b]]);
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// CHECK: opaque::<bool>(move [[ltp]])
opaque(a < b);
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// CHECK: [[lep:_.*]] = Le(copy [[a]], copy [[b]]);
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// CHECK: opaque::<bool>(move [[lep]])
opaque(a <= b);
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// CHECK: [[gtp:_.*]] = Gt(copy [[a]], copy [[b]]);
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// CHECK: opaque::<bool>(move [[gtp]])
opaque(a > b);
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// CHECK: [[gep:_.*]] = Ge(copy [[a]], copy [[b]]);
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// CHECK: opaque::<bool>(move [[gep]])
opaque(a >= b);
}
/// Both pointers come form the same allocation, so we could probably fold the comparisons.
fn wide_ptr_same_provenance() {
// CHECK-LABEL: fn wide_ptr_same_provenance(
let slice = &[1, 2];
let a: *const dyn Send = &slice[0] as &dyn Send;
let b: *const dyn Send = &slice[1] as &dyn Send;
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// CHECK: [[eqp:_.*]] = Eq(copy [[a:_.*]], copy [[b:_.*]]);
// CHECK: opaque::<bool>(move [[eqp]])
opaque(a == b);
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// CHECK: [[nep:_.*]] = Ne(copy [[a]], copy [[b]]);
// CHECK: opaque::<bool>(move [[nep]])
opaque(a != b);
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// CHECK: [[ltp:_.*]] = Lt(copy [[a]], copy [[b]]);
// CHECK: opaque::<bool>(move [[ltp]])
opaque(a < b);
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// CHECK: [[lep:_.*]] = Le(copy [[a]], copy [[b]]);
// CHECK: opaque::<bool>(move [[lep]])
opaque(a <= b);
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// CHECK: [[gtp:_.*]] = Gt(copy [[a]], copy [[b]]);
// CHECK: opaque::<bool>(move [[gtp]])
opaque(a > b);
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// CHECK: [[gep:_.*]] = Ge(copy [[a]], copy [[b]]);
// CHECK: opaque::<bool>(move [[gep]])
opaque(a >= b);
}
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/// Check that we do simplify when there is no provenance, and do not ICE.
fn wide_ptr_integer() {
// CHECK-LABEL: fn wide_ptr_integer(
// CHECK: debug a => [[a:_.*]];
// CHECK: debug b => [[b:_.*]];
let a: *const [u8] = unsafe { transmute((1usize, 1usize)) };
let b: *const [u8] = unsafe { transmute((1usize, 2usize)) };
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// CHECK: opaque::<bool>(const false)
opaque(a == b);
// CHECK: opaque::<bool>(const true)
opaque(a != b);
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// CHECK: opaque::<bool>(const true)
opaque(a < b);
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// CHECK: opaque::<bool>(const true)
opaque(a <= b);
// CHECK: opaque::<bool>(const false)
opaque(a > b);
// CHECK: opaque::<bool>(const false)
opaque(a >= b);
}
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#[custom_mir(dialect = "analysis", phase = "post-cleanup")]
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fn borrowed<T: Copy + Freeze>(x: T) {
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// CHECK-LABEL: fn borrowed(
// CHECK: bb0: {
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// CHECK-NEXT: _2 = copy _1;
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// CHECK-NEXT: _3 = &_1;
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// CHECK-NEXT: _0 = opaque::<&T>(copy _3)
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// CHECK: bb1: {
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// CHECK-NEXT: _0 = opaque::<T>(copy _1)
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// CHECK: bb2: {
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// CHECK-NEXT: _0 = opaque::<T>(copy _1)
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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mir! {
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{
let a = x;
let r1 = &x;
Call(RET = opaque(r1), ReturnTo(next), UnwindContinue())
}
next = {
Call(RET = opaque(a), ReturnTo(deref), UnwindContinue())
}
deref = {
Call(RET = opaque(*r1), ReturnTo(ret), UnwindContinue())
}
ret = {
Return()
}
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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}
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}
/// Generic type `T` is not known to be `Freeze`, so shared borrows may be mutable.
#[custom_mir(dialect = "analysis", phase = "post-cleanup")]
fn non_freeze<T: Copy>(x: T) {
// CHECK-LABEL: fn non_freeze(
// CHECK: bb0: {
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// CHECK-NEXT: _2 = copy _1;
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// CHECK-NEXT: _3 = &_1;
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// CHECK-NEXT: _0 = opaque::<&T>(copy _3)
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// CHECK: bb1: {
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// CHECK-NEXT: _0 = opaque::<T>(copy _2)
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// CHECK: bb2: {
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// CHECK-NEXT: _0 = opaque::<T>(copy (*_3))
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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mir! {
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{
let a = x;
let r1 = &x;
Call(RET = opaque(r1), ReturnTo(next), UnwindContinue())
}
next = {
Call(RET = opaque(a), ReturnTo(deref), UnwindContinue())
}
deref = {
Call(RET = opaque(*r1), ReturnTo(ret), UnwindContinue())
}
ret = {
Return()
}
Reformat `mir!` macro invocations to use braces. The `mir!` macro has multiple parts: - An optional return type annotation. - A sequence of zero or more local declarations. - A mandatory starting anonymous basic block, which is brace-delimited. - A sequence of zero of more additional named basic blocks. Some `mir!` invocations use braces with a "block" style, like so: ``` mir! { let _unit: (); { let non_copy = S(42); let ptr = std::ptr::addr_of_mut!(non_copy); // Inside `callee`, the first argument and `*ptr` are basically // aliasing places! Call(_unit = callee(Move(*ptr), ptr), ReturnTo(after_call), UnwindContinue()) } after_call = { Return() } } ``` Some invocations use parens with a "block" style, like so: ``` mir!( let x: [i32; 2]; let one: i32; { x = [42, 43]; one = 1; x = [one, 2]; RET = Move(x); Return() } ) ``` And some invocations uses parens with a "tighter" style, like so: ``` mir!({ SetDiscriminant(*b, 0); Return() }) ``` This last style is generally used for cases where just the mandatory starting basic block is present. Its braces are placed next to the parens. This commit changes all `mir!` invocations to use braces with a "block" style. Why? - Consistency is good. - The contents of the invocation is a block of code, so it's odd to use parens. They are more normally used for function-like macros. - Most importantly, the next commit will enable rustfmt for `tests/mir-opt/`. rustfmt is more aggressive about formatting macros that use parens than macros that use braces. Without this commit's changes, rustfmt would break a couple of `mir!` macro invocations that use braces within `tests/mir-opt` by inserting an extraneous comma. E.g.: ``` mir!(type RET = (i32, bool);, { // extraneous comma after ';' RET.0 = 1; RET.1 = true; Return() }) ``` Switching those `mir!` invocations to use braces avoids that problem, resulting in this, which is nicer to read as well as being valid syntax: ``` mir! { type RET = (i32, bool); { RET.0 = 1; RET.1 = true; Return() } } ```
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}
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}
// Check that we can const-prop into `from_raw_parts`
fn slice_const_length(x: &[i32]) -> *const [i32] {
// CHECK-LABEL: fn slice_const_length(
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// CHECK: _0 = *const [i32] from (copy {{_[0-9]+}}, const 123_usize);
let ptr = x.as_ptr();
let len = 123;
std::intrinsics::aggregate_raw_ptr(ptr, len)
}
fn meta_of_ref_to_slice(x: *const i32) -> usize {
// CHECK-LABEL: fn meta_of_ref_to_slice
// CHECK: _0 = const 1_usize
let ptr: *const [i32] = std::intrinsics::aggregate_raw_ptr(x, 1);
std::intrinsics::ptr_metadata(ptr)
}
fn slice_from_raw_parts_as_ptr(x: *const u16, n: usize) -> (*const u16, *const f32) {
// CHECK-LABEL: fn slice_from_raw_parts_as_ptr
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// CHECK: _8 = copy _1 as *const f32 (PtrToPtr);
// CHECK: _0 = (copy _1, move _8);
let ptr: *const [u16] = std::intrinsics::aggregate_raw_ptr(x, n);
(ptr as *const u16, ptr as *const f32)
}
fn casts_before_aggregate_raw_ptr(x: *const u32) -> *const [u8] {
// CHECK-LABEL: fn casts_before_aggregate_raw_ptr
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// CHECK: _0 = *const [u8] from (copy _1, const 4_usize);
let x = x as *const [u8; 4];
let x = x as *const u8;
let x = x as *const ();
std::intrinsics::aggregate_raw_ptr(x, 4)
}
fn manual_slice_mut_len(x: &mut [i32]) -> usize {
// CHECK-LABEL: fn manual_slice_mut_len
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// CHECK: _0 = PtrMetadata(copy _1);
let x: *mut [i32] = x;
let x: *const [i32] = x;
std::intrinsics::ptr_metadata(x)
}
// `.len()` on arrays ends up being something like this
fn array_len(x: &mut [i32; 42]) -> usize {
// CHECK-LABEL: fn array_len
// CHECK: _0 = const 42_usize;
let x: &[i32] = x;
std::intrinsics::ptr_metadata(x)
}
#[custom_mir(dialect = "runtime")]
fn generic_cast_metadata<T, A: ?Sized, B: ?Sized>(ps: *const [T], pa: *const A, pb: *const B) {
// CHECK-LABEL: fn generic_cast_metadata
mir! {
{
// These tests check that we correctly do or don't elide casts
// when the pointee metadata do or don't match, respectively.
// Metadata usize -> (), do not optimize.
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// CHECK: [[T:_.+]] = copy _1 as
// CHECK-NEXT: PtrMetadata(copy [[T]])
let t1 = CastPtrToPtr::<_, *const T>(ps);
let m1 = PtrMetadata(t1);
// `(&A, [T])` has `usize` metadata, same as `[T]`, yes optimize.
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// CHECK: [[T:_.+]] = copy _1 as
// CHECK-NEXT: PtrMetadata(copy _1)
let t2 = CastPtrToPtr::<_, *const (&A, [T])>(ps);
let m2 = PtrMetadata(t2);
// Tail `A` and tail `B`, do not optimize.
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// CHECK: [[T:_.+]] = copy _2 as
// CHECK-NEXT: PtrMetadata(copy [[T]])
let t3 = CastPtrToPtr::<_, *const (T, B)>(pa);
let m3 = PtrMetadata(t3);
// Both have tail `A`, yes optimize.
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// CHECK: [[T:_.+]] = copy _2 as
// CHECK-NEXT: PtrMetadata(copy _2)
let t4 = CastPtrToPtr::<_, *const (T, A)>(pa);
let m4 = PtrMetadata(t4);
// Tail `B` and tail `A`, do not optimize.
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// CHECK: [[T:_.+]] = copy _3 as
// CHECK-NEXT: PtrMetadata(copy [[T]])
let t5 = CastPtrToPtr::<_, *mut A>(pb);
let m5 = PtrMetadata(t5);
// Both have tail `B`, yes optimize.
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// CHECK: [[T:_.+]] = copy _3 as
// CHECK-NEXT: PtrMetadata(copy _3)
let t6 = CastPtrToPtr::<_, *mut B>(pb);
let m6 = PtrMetadata(t6);
Return()
}
}
}
fn cast_pointer_eq(p1: *mut u8, p2: *mut u32, p3: *mut u32, p4: *mut [u32]) {
// CHECK-LABEL: fn cast_pointer_eq
// CHECK: debug p1 => [[P1:_1]];
// CHECK: debug p2 => [[P2:_2]];
// CHECK: debug p3 => [[P3:_3]];
// CHECK: debug p4 => [[P4:_4]];
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// CHECK: [[M1:_.+]] = copy [[P1]] as *const u32 (PtrToPtr);
// CHECK: [[M2:_.+]] = copy [[P2]] as *const u32 (PtrToPtr);
// CHECK: [[M3:_.+]] = copy [[P3]] as *const u32 (PtrToPtr);
// CHECK: [[M4:_.+]] = copy [[P4]] as *const u32 (PtrToPtr);
let m1 = p1 as *const u32;
let m2 = p2 as *const u32;
let m3 = p3 as *const u32;
let m4 = p4 as *const u32;
// CHECK-NOT: Eq
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// CHECK: Eq(copy [[M1]], copy [[M2]])
// CHECK-NOT: Eq
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// CHECK: Eq(copy [[P2]], copy [[P3]])
// CHECK-NOT: Eq
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// CHECK: Eq(copy [[M3]], copy [[M4]])
// CHECK-NOT: Eq
let eq_different_thing = m1 == m2;
let eq_optimize = m2 == m3;
let eq_thin_fat = m3 == m4;
// CHECK: _0 = const ();
}
// Transmuting can skip a pointer cast so long as it wasn't a fat-to-thin cast.
unsafe fn cast_pointer_then_transmute(thin: *mut u32, fat: *mut [u8]) {
// CHECK-LABEL: fn cast_pointer_then_transmute
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// CHECK: [[UNUSED:_.+]] = copy _1 as *const () (PtrToPtr);
// CHECK: = copy _1 as usize (Transmute);
let thin_addr: usize = std::intrinsics::transmute(thin as *const ());
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// CHECK: [[TEMP2:_.+]] = copy _2 as *const () (PtrToPtr);
// CHECK: = move [[TEMP2]] as usize (Transmute);
let fat_addr: usize = std::intrinsics::transmute(fat as *const ());
}
#[custom_mir(dialect = "analysis")]
fn remove_casts_must_change_both_sides(mut_a: &*mut u8, mut_b: *mut u8) -> bool {
// CHECK-LABEL: fn remove_casts_must_change_both_sides(
mir! {
// We'd like to remove these casts, but we can't change *both* of them
// to be locals, so make sure we don't change one without the other, as
// that would be a type error.
{
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// CHECK: [[A:_.+]] = copy (*_1) as *const u8 (PtrToPtr);
let a = *mut_a as *const u8;
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// CHECK: [[B:_.+]] = copy _2 as *const u8 (PtrToPtr);
let b = mut_b as *const u8;
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// CHECK: _0 = Eq(copy [[A]], copy [[B]]);
RET = a == b;
Return()
}
}
}
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fn main() {
subexpression_elimination(2, 4, 5);
wrap_unwrap(5);
repeated_index::<u32, 7>(5, 3);
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unary(i64::MIN);
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arithmetic(5);
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comparison(5, 6);
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arithmetic_checked(5);
arithmetic_float(5.);
cast();
multiple_branches(true, 5, 9);
references(5);
dereferences(&mut 5, &6, &S(7));
slices();
let (direct, indirect) = duplicate_slice();
assert_eq!(direct, indirect);
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repeat();
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fn_pointers();
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indirect_static();
constant_index_overflow(&[5, 3]);
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wide_ptr_provenance();
wide_ptr_integer();
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borrowed(5);
non_freeze(5);
slice_const_length(&[1]);
meta_of_ref_to_slice(&42);
slice_from_raw_parts_as_ptr(&123, 456);
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}
#[inline(never)]
fn opaque(_: impl Sized) {}
#[inline(never)]
fn identity<T>(x: T) -> T {
x
}
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// EMIT_MIR gvn.subexpression_elimination.GVN.diff
// EMIT_MIR gvn.wrap_unwrap.GVN.diff
// EMIT_MIR gvn.repeated_index.GVN.diff
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// EMIT_MIR gvn.unary.GVN.diff
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// EMIT_MIR gvn.arithmetic.GVN.diff
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// EMIT_MIR gvn.comparison.GVN.diff
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// EMIT_MIR gvn.arithmetic_checked.GVN.diff
// EMIT_MIR gvn.arithmetic_float.GVN.diff
// EMIT_MIR gvn.cast.GVN.diff
// EMIT_MIR gvn.multiple_branches.GVN.diff
// EMIT_MIR gvn.references.GVN.diff
// EMIT_MIR gvn.dereferences.GVN.diff
// EMIT_MIR gvn.slices.GVN.diff
// EMIT_MIR gvn.duplicate_slice.GVN.diff
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// EMIT_MIR gvn.repeat.GVN.diff
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// EMIT_MIR gvn.fn_pointers.GVN.diff
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// EMIT_MIR gvn.indirect_static.GVN.diff
// EMIT_MIR gvn.constant_index_overflow.GVN.diff
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// EMIT_MIR gvn.wide_ptr_provenance.GVN.diff
// EMIT_MIR gvn.wide_ptr_same_provenance.GVN.diff
2023-12-30 17:37:50 -06:00
// EMIT_MIR gvn.wide_ptr_integer.GVN.diff
2024-04-07 11:23:16 -05:00
// EMIT_MIR gvn.borrowed.GVN.diff
// EMIT_MIR gvn.non_freeze.GVN.diff
// EMIT_MIR gvn.slice_const_length.GVN.diff
// EMIT_MIR gvn.meta_of_ref_to_slice.GVN.diff
// EMIT_MIR gvn.slice_from_raw_parts_as_ptr.GVN.diff
// EMIT_MIR gvn.casts_before_aggregate_raw_ptr.GVN.diff
// EMIT_MIR gvn.manual_slice_mut_len.GVN.diff
// EMIT_MIR gvn.array_len.GVN.diff
// EMIT_MIR gvn.generic_cast_metadata.GVN.diff
// EMIT_MIR gvn.cast_pointer_eq.GVN.diff
// EMIT_MIR gvn.cast_pointer_then_transmute.GVN.diff
// EMIT_MIR gvn.remove_casts_must_change_both_sides.GVN.diff