compiler-builtins-zynq/examples/intrinsics.rs

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// By compiling this file we check that all the intrinsics we care about continue to be provided by
// the `compiler_builtins` crate regardless of the changes we make to it. If we, by mistake, stop
// compiling a C implementation and forget to implement that intrinsic in Rust, this file will fail
// to link due to the missing intrinsic (symbol).
#![allow(unused_features)]
#![cfg_attr(thumb, no_main)]
#![deny(dead_code)]
#![feature(alloc_system)]
#![feature(asm)]
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#![feature(compiler_builtins_lib)]
#![feature(core_float)]
#![feature(lang_items)]
#![feature(start)]
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#![feature(allocator_api)]
#![feature(panic_implementation)]
#![cfg_attr(windows, feature(panic_unwind))]
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#![no_std]
extern crate panic_implementation;
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#[cfg(not(thumb))]
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#[link(name = "c")]
extern {}
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// NOTE cfg(not(thumbv6m)) means that the operation is not supported on ARMv6-M at all. Not even
// compiler-rt provides a C/assembly implementation.
// Every function in this module maps will be lowered to an intrinsic by LLVM, if the platform
// doesn't have native support for the operation used in the function. ARM has a naming convention
// convention for its intrinsics that's different from other architectures; that's why some function
// have an additional comment: the function name is the ARM name for the intrinsic and the comment
// in the non-ARM name for the intrinsic.
mod intrinsics {
// trunccdfsf2
pub fn aeabi_d2f(x: f64) -> f32 {
x as f32
}
// fixdfsi
pub fn aeabi_d2i(x: f64) -> i32 {
x as i32
}
// fixdfdi
#[cfg(not(thumbv6m))]
pub fn aeabi_d2l(x: f64) -> i64 {
x as i64
}
#[cfg(thumbv6m)]
pub fn aeabi_d2l(_: f64) -> i64 {
0
}
// fixunsdfsi
pub fn aeabi_d2uiz(x: f64) -> u32 {
x as u32
}
// fixunsdfdi
#[cfg(not(thumbv6m))]
pub fn aeabi_d2ulz(x: f64) -> u64 {
x as u64
}
#[cfg(thumbv6m)]
pub fn aeabi_d2ulz(_: f64) -> u64 {
0
}
// adddf3
pub fn aeabi_dadd(a: f64, b: f64) -> f64 {
a + b
}
// eqdf2
#[cfg(not(thumbv6m))]
pub fn aeabi_dcmpeq(a: f64, b: f64) -> bool {
a == b
}
#[cfg(thumbv6m)]
pub fn aeabi_dcmpeq(_: f64, _: f64) -> bool {
true
}
// gtdf2
#[cfg(not(thumbv6m))]
pub fn aeabi_dcmpgt(a: f64, b: f64) -> bool {
a > b
}
#[cfg(thumbv6m)]
pub fn aeabi_dcmpgt(_: f64, _: f64) -> bool {
true
}
// ltdf2
#[cfg(not(thumbv6m))]
pub fn aeabi_dcmplt(a: f64, b: f64) -> bool {
a < b
}
#[cfg(thumbv6m)]
pub fn aeabi_dcmplt(_: f64, _: f64) -> bool {
true
}
// divdf3
pub fn aeabi_ddiv(a: f64, b: f64) -> f64 {
a / b
}
// muldf3
pub fn aeabi_dmul(a: f64, b: f64) -> f64 {
a * b
}
// subdf3
pub fn aeabi_dsub(a: f64, b: f64) -> f64 {
a - b
}
// extendsfdf2
pub fn aeabi_f2d(x: f32) -> f64 {
x as f64
}
// fixsfsi
pub fn aeabi_f2iz(x: f32) -> i32 {
x as i32
}
// fixsfdi
#[cfg(not(thumbv6m))]
pub fn aeabi_f2lz(x: f32) -> i64 {
x as i64
}
#[cfg(thumbv6m)]
pub fn aeabi_f2lz(_: f32) -> i64 {
0
}
// fixunssfsi
pub fn aeabi_f2uiz(x: f32) -> u32 {
x as u32
}
// fixunssfdi
#[cfg(not(thumbv6m))]
pub fn aeabi_f2ulz(x: f32) -> u64 {
x as u64
}
#[cfg(thumbv6m)]
pub fn aeabi_f2ulz(_: f32) -> u64 {
0
}
// addsf3
pub fn aeabi_fadd(a: f32, b: f32) -> f32 {
a + b
}
// eqsf2
#[cfg(not(thumbv6m))]
pub fn aeabi_fcmpeq(a: f32, b: f32) -> bool {
a == b
}
#[cfg(thumbv6m)]
pub fn aeabi_fcmpeq(_: f32, _: f32) -> bool {
true
}
// gtsf2
#[cfg(not(thumbv6m))]
pub fn aeabi_fcmpgt(a: f32, b: f32) -> bool {
a > b
}
#[cfg(thumbv6m)]
pub fn aeabi_fcmpgt(_: f32, _: f32) -> bool {
true
}
// ltsf2
#[cfg(not(thumbv6m))]
pub fn aeabi_fcmplt(a: f32, b: f32) -> bool {
a < b
}
#[cfg(thumbv6m)]
pub fn aeabi_fcmplt(_: f32, _: f32) -> bool {
true
}
// divsf3
pub fn aeabi_fdiv(a: f32, b: f32) -> f32 {
a / b
}
// mulsf3
pub fn aeabi_fmul(a: f32, b: f32) -> f32 {
a * b
}
// subsf3
pub fn aeabi_fsub(a: f32, b: f32) -> f32 {
a - b
}
// floatsidf
pub fn aeabi_i2d(x: i32) -> f64 {
x as f64
}
// floatsisf
pub fn aeabi_i2f(x: i32) -> f32 {
x as f32
}
pub fn aeabi_idiv(a: i32, b: i32) -> i32 {
a.wrapping_div(b)
}
pub fn aeabi_idivmod(a: i32, b: i32) -> i32 {
a % b
}
// floatdidf
pub fn aeabi_l2d(x: i64) -> f64 {
x as f64
}
// floatdisf
pub fn aeabi_l2f(x: i64) -> f32 {
x as f32
}
// divdi3
pub fn aeabi_ldivmod(a: i64, b: i64) -> i64 {
a / b
}
// muldi3
pub fn aeabi_lmul(a: i64, b: i64) -> i64 {
a.wrapping_mul(b)
}
// floatunsidf
pub fn aeabi_ui2d(x: u32) -> f64 {
x as f64
}
// floatunsisf
pub fn aeabi_ui2f(x: u32) -> f32 {
x as f32
}
pub fn aeabi_uidiv(a: u32, b: u32) -> u32 {
a / b
}
pub fn aeabi_uidivmod(a: u32, b: u32) -> u32 {
a % b
}
// floatundidf
pub fn aeabi_ul2d(x: u64) -> f64 {
x as f64
}
// floatundisf
pub fn aeabi_ul2f(x: u64) -> f32 {
x as f32
}
// udivdi3
pub fn aeabi_uldivmod(a: u64, b: u64) -> u64 {
a * b
}
pub fn moddi3(a: i64, b: i64) -> i64 {
a % b
}
pub fn mulodi4(a: i64, b: i64) -> i64 {
a * b
}
pub fn umoddi3(a: u64, b: u64) -> u64 {
a % b
}
pub fn muloti4(a: u128, b: u128) -> Option<u128> {
a.checked_mul(b)
}
pub fn multi3(a: u128, b: u128) -> u128 {
a.wrapping_mul(b)
}
pub fn ashlti3(a: u128, b: usize) -> u128 {
a >> b
}
pub fn ashrti3(a: u128, b: usize) -> u128 {
a << b
}
pub fn lshrti3(a: i128, b: usize) -> i128 {
a >> b
}
pub fn udivti3(a: u128, b: u128) -> u128 {
a / b
}
pub fn umodti3(a: u128, b: u128) -> u128 {
a % b
}
pub fn divti3(a: i128, b: i128) -> i128 {
a / b
}
pub fn modti3(a: i128, b: i128) -> i128 {
a % b
}
}
fn run() {
use intrinsics::*;
// A copy of "test::black_box". Used to prevent LLVM from optimizing away the intrinsics during LTO
fn bb<T>(dummy: T) -> T {
unsafe { asm!("" : : "r"(&dummy)) }
dummy
}
bb(aeabi_d2f(bb(2.)));
bb(aeabi_d2i(bb(2.)));
bb(aeabi_d2l(bb(2.)));
bb(aeabi_d2uiz(bb(2.)));
bb(aeabi_d2ulz(bb(2.)));
bb(aeabi_dadd(bb(2.), bb(3.)));
bb(aeabi_dcmpeq(bb(2.), bb(3.)));
bb(aeabi_dcmpgt(bb(2.), bb(3.)));
bb(aeabi_dcmplt(bb(2.), bb(3.)));
bb(aeabi_ddiv(bb(2.), bb(3.)));
bb(aeabi_dmul(bb(2.), bb(3.)));
bb(aeabi_dsub(bb(2.), bb(3.)));
bb(aeabi_f2d(bb(2.)));
bb(aeabi_f2iz(bb(2.)));
bb(aeabi_f2lz(bb(2.)));
bb(aeabi_f2uiz(bb(2.)));
bb(aeabi_f2ulz(bb(2.)));
bb(aeabi_fadd(bb(2.), bb(3.)));
bb(aeabi_fcmpeq(bb(2.), bb(3.)));
bb(aeabi_fcmpgt(bb(2.), bb(3.)));
bb(aeabi_fcmplt(bb(2.), bb(3.)));
bb(aeabi_fdiv(bb(2.), bb(3.)));
bb(aeabi_fmul(bb(2.), bb(3.)));
bb(aeabi_fsub(bb(2.), bb(3.)));
bb(aeabi_i2d(bb(2)));
bb(aeabi_i2f(bb(2)));
bb(aeabi_idiv(bb(2), bb(3)));
bb(aeabi_idivmod(bb(2), bb(3)));
bb(aeabi_l2d(bb(2)));
bb(aeabi_l2f(bb(2)));
bb(aeabi_ldivmod(bb(2), bb(3)));
bb(aeabi_lmul(bb(2), bb(3)));
bb(aeabi_ui2d(bb(2)));
bb(aeabi_ui2f(bb(2)));
bb(aeabi_uidiv(bb(2), bb(3)));
bb(aeabi_uidivmod(bb(2), bb(3)));
bb(aeabi_ul2d(bb(2)));
bb(aeabi_ul2f(bb(2)));
bb(aeabi_uldivmod(bb(2), bb(3)));
bb(moddi3(bb(2), bb(3)));
bb(mulodi4(bb(2), bb(3)));
bb(umoddi3(bb(2), bb(3)));
bb(muloti4(bb(2), bb(2)));
bb(multi3(bb(2), bb(2)));
bb(ashlti3(bb(2), bb(2)));
bb(ashrti3(bb(2), bb(2)));
bb(lshrti3(bb(2), bb(2)));
bb(udivti3(bb(2), bb(2)));
bb(umodti3(bb(2), bb(2)));
bb(divti3(bb(2), bb(2)));
bb(modti3(bb(2), bb(2)));
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something_with_a_dtor(&|| assert_eq!(bb(1), 1));
extern {
fn rust_begin_unwind();
}
// if bb(false) {
unsafe { rust_begin_unwind(); }
// }
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}
fn something_with_a_dtor(f: &Fn()) {
struct A<'a>(&'a (Fn() + 'a));
impl<'a> Drop for A<'a> {
fn drop(&mut self) {
(self.0)();
}
}
let _a = A(f);
f();
}
#[cfg(not(thumb))]
#[start]
fn main(_: isize, _: *const *const u8) -> isize {
run();
0
}
#[cfg(thumb)]
#[no_mangle]
pub fn _start() -> ! {
run();
loop {}
}
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#[cfg(windows)]
#[link(name = "kernel32")]
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#[link(name = "msvcrt")]
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extern {}
// ARM targets need these symbols
#[no_mangle]
pub fn __aeabi_unwind_cpp_pr0() {}
#[no_mangle]
pub fn __aeabi_unwind_cpp_pr1() {}
#[cfg(not(windows))]
#[allow(non_snake_case)]
#[no_mangle]
pub fn _Unwind_Resume() {}
#[cfg(not(windows))]
#[lang = "eh_personality"]
#[no_mangle]
pub extern "C" fn eh_personality() {}