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mips64.rs
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mips64.rs
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use crate::abi::call::{
ArgAbi, ArgAttribute, ArgAttributes, ArgExtension, CastTarget, FnAbi, PassMode, Reg, Uniform,
};
use crate::abi::{self, HasDataLayout, Size, TyAbiInterface};
fn extend_integer_width_mips<Ty>(arg: &mut ArgAbi<'_, Ty>, bits: u64) {
// Always sign extend u32 values on 64-bit mips
if let abi::Abi::Scalar(scalar) = arg.layout.abi {
if let abi::Int(i, signed) = scalar.primitive() {
if !signed && i.size().bits() == 32 {
if let PassMode::Direct(ref mut attrs) = arg.mode {
attrs.ext(ArgExtension::Sext);
return;
}
}
}
}
arg.extend_integer_width_to(bits);
}
fn float_reg<'a, Ty, C>(cx: &C, ret: &ArgAbi<'a, Ty>, i: usize) -> Option<Reg>
where
Ty: TyAbiInterface<'a, C> + Copy,
C: HasDataLayout,
{
match ret.layout.field(cx, i).abi {
abi::Abi::Scalar(scalar) => match scalar.primitive() {
abi::F32 => Some(Reg::f32()),
abi::F64 => Some(Reg::f64()),
_ => None,
},
_ => None,
}
}
fn classify_ret<'a, Ty, C>(cx: &C, ret: &mut ArgAbi<'a, Ty>)
where
Ty: TyAbiInterface<'a, C> + Copy,
C: HasDataLayout,
{
if !ret.layout.is_aggregate() {
extend_integer_width_mips(ret, 64);
return;
}
let size = ret.layout.size;
let bits = size.bits();
if bits <= 128 {
// Unlike other architectures which return aggregates in registers, MIPS n64 limits the
// use of float registers to structures (not unions) containing exactly one or two
// float fields.
if let abi::FieldsShape::Arbitrary { .. } = ret.layout.fields {
if ret.layout.fields.count() == 1 {
if let Some(reg) = float_reg(cx, ret, 0) {
ret.cast_to(reg);
return;
}
} else if ret.layout.fields.count() == 2 {
if let Some(reg0) = float_reg(cx, ret, 0) {
if let Some(reg1) = float_reg(cx, ret, 1) {
ret.cast_to(CastTarget::pair(reg0, reg1));
return;
}
}
}
}
// Cast to a uniform int structure
ret.cast_to(Uniform { unit: Reg::i64(), total: size });
} else {
ret.make_indirect();
}
}
fn classify_arg<'a, Ty, C>(cx: &C, arg: &mut ArgAbi<'a, Ty>)
where
Ty: TyAbiInterface<'a, C> + Copy,
C: HasDataLayout,
{
if !arg.layout.is_aggregate() {
extend_integer_width_mips(arg, 64);
return;
}
let dl = cx.data_layout();
let size = arg.layout.size;
let mut prefix = [None; 8];
let mut prefix_index = 0;
match arg.layout.fields {
abi::FieldsShape::Primitive => unreachable!(),
abi::FieldsShape::Array { .. } => {
// Arrays are passed indirectly
arg.make_indirect();
return;
}
abi::FieldsShape::Union(_) => {
// Unions and are always treated as a series of 64-bit integer chunks
}
abi::FieldsShape::Arbitrary { .. } => {
// Structures are split up into a series of 64-bit integer chunks, but any aligned
// doubles not part of another aggregate are passed as floats.
let mut last_offset = Size::ZERO;
for i in 0..arg.layout.fields.count() {
let field = arg.layout.field(cx, i);
let offset = arg.layout.fields.offset(i);
// We only care about aligned doubles
if let abi::Abi::Scalar(scalar) = field.abi {
if let abi::F64 = scalar.primitive() {
if offset.is_aligned(dl.f64_align.abi) {
// Insert enough integers to cover [last_offset, offset)
assert!(last_offset.is_aligned(dl.f64_align.abi));
for _ in 0..((offset - last_offset).bits() / 64)
.min((prefix.len() - prefix_index) as u64)
{
prefix[prefix_index] = Some(Reg::i64());
prefix_index += 1;
}
if prefix_index == prefix.len() {
break;
}
prefix[prefix_index] = Some(Reg::f64());
prefix_index += 1;
last_offset = offset + Reg::f64().size;
}
}
}
}
}
};
// Extract first 8 chunks as the prefix
let rest_size = size - Size::from_bytes(8) * prefix_index as u64;
arg.cast_to(CastTarget {
prefix,
rest: Uniform { unit: Reg::i64(), total: rest_size },
attrs: ArgAttributes {
regular: ArgAttribute::default(),
arg_ext: ArgExtension::None,
pointee_size: Size::ZERO,
pointee_align: None,
},
});
}
pub fn compute_abi_info<'a, Ty, C>(cx: &C, fn_abi: &mut FnAbi<'a, Ty>)
where
Ty: TyAbiInterface<'a, C> + Copy,
C: HasDataLayout,
{
if !fn_abi.ret.is_ignore() {
classify_ret(cx, &mut fn_abi.ret);
}
for arg in fn_abi.args.iter_mut() {
if arg.is_ignore() {
continue;
}
classify_arg(cx, arg);
}
}