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Return values larger than 2 registers using a return area pointer

LLVM and Cranelift disagree about how to return values that don't fit in the registers designated for return values. LLVM will force the entire return value to be passed by return area pointer, while Cranelift will look at each IR level return value independently and decide to pass it in a register or not, which would result in the return value being passed partially in registers and partially through a return area pointer.

While Cranelift may need to be fixed as the LLVM behavior is generally more correct with respect to the surface language, forcing this behavior in rustc itself makes it easier for other backends to conform to the Rust ABI and for the C ABI rustc already handles this behavior anyway.

In addition LLVM's decision to pass the return value in registers or using a return area pointer depends on how exactly the return type is lowered to an LLVM IR type. For example `Option<u128>` can be lowered as `{ i128, i128 }` in which case the x86_64 backend would use a return area pointer, or it could be passed as `{ i32, i128 }` in which case the x86_64 backend would pass it in registers by taking advantage of an LLVM ABI extension that allows using 3 registers for the x86_64 sysv call conv rather than the officially specified 2 registers.

This adjustment is only necessary for the Rust ABI as for other ABI's the calling convention implementations in rustc_target already ensure any return value which doesn't fit in the available amount of return registers is passed in the right way for the current target.

Helps with rust-lang/rustc_codegen_cranelift#1525
cc bytecodealliance/wasmtime#9250
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bors committed Oct 14, 2024
2 parents f6648f2 + 8ed77fd commit b8fe97a
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43 changes: 43 additions & 0 deletions compiler/rustc_ty_utils/src/abi.rs
Original file line number Diff line number Diff line change
Expand Up @@ -728,6 +728,49 @@ fn fn_abi_adjust_for_abi<'tcx>(
};
}

if arg_idx.is_none() && arg.layout.size > Pointer(AddressSpace::DATA).size(cx) * 2 {
// Return values larger than 2 registers using a return area
// pointer. LLVM and Cranelift disagree about how to return
// values that don't fit in the registers designated for return
// values. LLVM will force the entire return value to be passed
// by return area pointer, while Cranelift will look at each IR level
// return value independently and decide to pass it in a
// register or not, which would result in the return value
// being passed partially in registers and partially through a
// return area pointer.
//
// While Cranelift may need to be fixed as the LLVM behavior is
// generally more correct with respect to the surface language,
// forcing this behavior in rustc itself makes it easier for
// other backends to conform to the Rust ABI and for the C ABI
// rustc already handles this behavior anyway.
//
// In addition LLVM's decision to pass the return value in
// registers or using a return area pointer depends on how
// exactly the return type is lowered to an LLVM IR type. For
// example `Option<u128>` can be lowered as `{ i128, i128 }`
// in which case the x86_64 backend would use a return area
// pointer, or it could be passed as `{ i32, i128 }` in which
// case the x86_64 backend would pass it in registers by taking
// advantage of an LLVM ABI extension that allows using 3
// registers for the x86_64 sysv call conv rather than the
// officially specified 2 registers.
//
// FIXME: Technically we should look at the amount of available
// return registers rather than guessing that there are 2
// registers for return values. In practice only a couple of
// architectures have less than 2 return registers. None of
// which supported by Cranelift.
//
// NOTE: This adjustment is only necessary for the Rust ABI as
// for other ABI's the calling convention implementations in
// rustc_target already ensure any return value which doesn't
// fit in the available amount of return registers is passed in
// the right way for the current target.
arg.make_indirect();
return;
}

match arg.layout.abi {
Abi::Aggregate { .. } => {}

Expand Down
106 changes: 79 additions & 27 deletions tests/codegen/float/f128.rs
Original file line number Diff line number Diff line change
@@ -1,7 +1,11 @@
// 32-bit x86 returns `f32` and `f64` differently to avoid the x87 stack.
//@ revisions: x86 other
// 32-bit systems will return 128bit values using a return area pointer.
//@ revisions: x86 bit32 bit64
//@[x86] only-x86
//@[other] ignore-x86
//@[bit32] ignore-x86
//@[bit32] only-32bit
//@[bit64] ignore-x86
//@[bit64] only-64bit

// Verify that our intrinsics generate the correct LLVM calls for f128

Expand Down Expand Up @@ -52,42 +56,54 @@ pub fn f128_le(a: f128, b: f128) -> bool {
a <= b
}

// CHECK-LABEL: fp128 @f128_neg(
// x86-LABEL: void @f128_neg({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_neg({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_neg(
#[no_mangle]
pub fn f128_neg(a: f128) -> f128 {
// CHECK: fneg fp128
-a
}

// CHECK-LABEL: fp128 @f128_add(
// x86-LABEL: void @f128_add({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_add({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_add(
#[no_mangle]
pub fn f128_add(a: f128, b: f128) -> f128 {
// CHECK: fadd fp128 %{{.+}}, %{{.+}}
a + b
}

// CHECK-LABEL: fp128 @f128_sub(
// x86-LABEL: void @f128_sub({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_sub({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_sub(
#[no_mangle]
pub fn f128_sub(a: f128, b: f128) -> f128 {
// CHECK: fsub fp128 %{{.+}}, %{{.+}}
a - b
}

// CHECK-LABEL: fp128 @f128_mul(
// x86-LABEL: void @f128_mul({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_mul({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_mul(
#[no_mangle]
pub fn f128_mul(a: f128, b: f128) -> f128 {
// CHECK: fmul fp128 %{{.+}}, %{{.+}}
a * b
}

// CHECK-LABEL: fp128 @f128_div(
// x86-LABEL: void @f128_div({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_div({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_div(
#[no_mangle]
pub fn f128_div(a: f128, b: f128) -> f128 {
// CHECK: fdiv fp128 %{{.+}}, %{{.+}}
a / b
}

// CHECK-LABEL: fp128 @f128_rem(
// x86-LABEL: void @f128_rem({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_rem({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_rem(
#[no_mangle]
pub fn f128_rem(a: f128, b: f128) -> f128 {
// CHECK: frem fp128 %{{.+}}, %{{.+}}
Expand Down Expand Up @@ -143,44 +159,56 @@ pub fn f128_as_f16(a: f128) -> f16 {
a as f16
}

// other-LABEL: float @f128_as_f32(
// x86-LABEL: i32 @f128_as_f32(
// bit32-LABEL: float @f128_as_f32(
// bit64-LABEL: float @f128_as_f32(
#[no_mangle]
pub fn f128_as_f32(a: f128) -> f32 {
// CHECK: fptrunc fp128 %{{.+}} to float
a as f32
}

// other-LABEL: double @f128_as_f64(
// x86-LABEL: void @f128_as_f64(
// bit32-LABEL: double @f128_as_f64(
// bit64-LABEL: double @f128_as_f64(
#[no_mangle]
pub fn f128_as_f64(a: f128) -> f64 {
// CHECK: fptrunc fp128 %{{.+}} to double
a as f64
}

// CHECK-LABEL: fp128 @f128_as_self(
// x86-LABEL: void @f128_as_self({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_as_self({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f128_as_self(
#[no_mangle]
pub fn f128_as_self(a: f128) -> f128 {
// CHECK: ret fp128 %{{.+}}
// x86: store fp128 %a, ptr %_0, align 16
// bit32: store fp128 %a, ptr %_0, align 16
// bit64: ret fp128 %{{.+}}
a as f128
}

// CHECK-LABEL: fp128 @f16_as_f128(
// x86-LABEL: void @f16_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f16_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f16_as_f128(
#[no_mangle]
pub fn f16_as_f128(a: f16) -> f128 {
// CHECK: fpext half %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @f32_as_f128(
// x86-LABEL: void @f32_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f32_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f32_as_f128(
#[no_mangle]
pub fn f32_as_f128(a: f32) -> f128 {
// CHECK: fpext float %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @f64_as_f128(
// x86-LABEL: void @f64_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f64_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f64_as_f128(
#[no_mangle]
pub fn f64_as_f128(a: f64) -> f128 {
// CHECK: fpext double %{{.+}} to fp128
Expand Down Expand Up @@ -216,7 +244,9 @@ pub fn f128_as_u64(a: f128) -> u64 {
a as u64
}

// CHECK-LABEL: i128 @f128_as_u128(
// x86-LABEL: void @f128_as_u128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_as_u128({{.*}}sret([16 x i8])
// bit64-LABEL: i128 @f128_as_u128(
#[no_mangle]
pub fn f128_as_u128(a: f128) -> u128 {
// CHECK: call i128 @llvm.fptoui.sat.i128.f128(fp128 %{{.+}})
Expand Down Expand Up @@ -250,7 +280,9 @@ pub fn f128_as_i64(a: f128) -> i64 {
a as i64
}

// CHECK-LABEL: i128 @f128_as_i128(
// x86-LABEL: void @f128_as_i128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f128_as_i128({{.*}}sret([16 x i8])
// bit64-LABEL: i128 @f128_as_i128(
#[no_mangle]
pub fn f128_as_i128(a: f128) -> i128 {
// CHECK: call i128 @llvm.fptosi.sat.i128.f128(fp128 %{{.+}})
Expand All @@ -259,70 +291,90 @@ pub fn f128_as_i128(a: f128) -> i128 {

/* int to float conversions */

// CHECK-LABEL: fp128 @u8_as_f128(
// x86-LABEL: void @u8_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @u8_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @u8_as_f128(
#[no_mangle]
pub fn u8_as_f128(a: u8) -> f128 {
// CHECK: uitofp i8 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @u16_as_f128(
// x86-LABEL: void @u16_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @u16_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @u16_as_f128(
#[no_mangle]
pub fn u16_as_f128(a: u16) -> f128 {
// CHECK: uitofp i16 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @u32_as_f128(
// x86-LABEL: void @u32_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @u32_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @u32_as_f128(
#[no_mangle]
pub fn u32_as_f128(a: u32) -> f128 {
// CHECK: uitofp i32 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @u64_as_f128(
// x86-LABEL: void @u64_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @u64_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @u64_as_f128(
#[no_mangle]
pub fn u64_as_f128(a: u64) -> f128 {
// CHECK: uitofp i64 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @u128_as_f128(
// x86-LABEL: void @u128_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @u128_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @u128_as_f128(
#[no_mangle]
pub fn u128_as_f128(a: u128) -> f128 {
// CHECK: uitofp i128 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @i8_as_f128(
// x86-LABEL: void @i8_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @i8_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @i8_as_f128(
#[no_mangle]
pub fn i8_as_f128(a: i8) -> f128 {
// CHECK: sitofp i8 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @i16_as_f128(
// x86-LABEL: void @i16_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @i16_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @i16_as_f128(
#[no_mangle]
pub fn i16_as_f128(a: i16) -> f128 {
// CHECK: sitofp i16 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @i32_as_f128(
// x86-LABEL: void @i32_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @i32_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @i32_as_f128(
#[no_mangle]
pub fn i32_as_f128(a: i32) -> f128 {
// CHECK: sitofp i32 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @i64_as_f128(
// x86-LABEL: void @i64_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @i64_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @i64_as_f128(
#[no_mangle]
pub fn i64_as_f128(a: i64) -> f128 {
// CHECK: sitofp i64 %{{.+}} to fp128
a as f128
}

// CHECK-LABEL: fp128 @i128_as_f128(
// x86-LABEL: void @i128_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @i128_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @i128_as_f128(
#[no_mangle]
pub fn i128_as_f128(a: i128) -> f128 {
// CHECK: sitofp i128 %{{.+}} to fp128
Expand Down
26 changes: 19 additions & 7 deletions tests/codegen/float/f16.rs
Original file line number Diff line number Diff line change
@@ -1,7 +1,11 @@
// 32-bit x86 returns `f32` and `f64` differently to avoid the x87 stack.
//@ revisions: x86 other
// 32-bit systems will return 128bit values using a return area pointer.
//@ revisions: x86 bit32 bit64
//@[x86] only-x86
//@[other] ignore-x86
//@[bit32] ignore-x86
//@[bit32] only-32bit
//@[bit64] ignore-x86
//@[bit64] only-64bit

// Verify that our intrinsics generate the correct LLVM calls for f16

Expand Down Expand Up @@ -145,23 +149,27 @@ pub fn f16_as_self(a: f16) -> f16 {
a as f16
}

// other-LABEL: float @f16_as_f32(
// x86-LABEL: i32 @f16_as_f32(
// bit32-LABEL: float @f16_as_f32(
// bit64-LABEL: float @f16_as_f32(
#[no_mangle]
pub fn f16_as_f32(a: f16) -> f32 {
// CHECK: fpext half %{{.+}} to float
a as f32
}

// other-LABEL: double @f16_as_f64(
// x86-LABEL: void @f16_as_f64(
// bit32-LABEL: double @f16_as_f64(
// bit64-LABEL: double @f16_as_f64(
#[no_mangle]
pub fn f16_as_f64(a: f16) -> f64 {
// CHECK: fpext half %{{.+}} to double
a as f64
}

// CHECK-LABEL: fp128 @f16_as_f128(
// x86-LABEL: void @f16_as_f128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f16_as_f128({{.*}}sret([16 x i8])
// bit64-LABEL: fp128 @f16_as_f128(
#[no_mangle]
pub fn f16_as_f128(a: f16) -> f128 {
// CHECK: fpext half %{{.+}} to fp128
Expand Down Expand Up @@ -218,7 +226,9 @@ pub fn f16_as_u64(a: f16) -> u64 {
a as u64
}

// CHECK-LABEL: i128 @f16_as_u128(
// x86-LABEL: void @f16_as_u128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f16_as_u128({{.*}}sret([16 x i8])
// bit64-LABEL: i128 @f16_as_u128(
#[no_mangle]
pub fn f16_as_u128(a: f16) -> u128 {
// CHECK: call i128 @llvm.fptoui.sat.i128.f16(half %{{.+}})
Expand Down Expand Up @@ -252,7 +262,9 @@ pub fn f16_as_i64(a: f16) -> i64 {
a as i64
}

// CHECK-LABEL: i128 @f16_as_i128(
// x86-LABEL: void @f16_as_i128({{.*}}sret([16 x i8])
// bit32-LABEL: void @f16_as_i128({{.*}}sret([16 x i8])
// bit64-LABEL: i128 @f16_as_i128(
#[no_mangle]
pub fn f16_as_i128(a: f16) -> i128 {
// CHECK: call i128 @llvm.fptosi.sat.i128.f16(half %{{.+}})
Expand Down
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