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rust/compiler/rustc_codegen_llvm/src/abi.rs
Seth Pellegrino 897c7bb23b feat: riscv-interrupt-{m,s} calling conventions 
Similar to prior support added for the mips430, avr, and x86 targets
this change implements the rough equivalent of clang's
[`__attribute__((interrupt))`][clang-attr] for riscv targets, enabling
e.g.

```rust
static mut CNT: usize = 0;

pub extern "riscv-interrupt-m" fn isr_m() {
    unsafe {
        CNT += 1;
    }
}
```

to produce highly effective assembly like:

```asm
pub extern "riscv-interrupt-m" fn isr_m() {
420003a0:       1141                    addi    sp,sp,-16
    unsafe {
        CNT += 1;
420003a2:       c62a                    sw      a0,12(sp)
420003a4:       c42e                    sw      a1,8(sp)
420003a6:       3fc80537                lui     a0,0x3fc80
420003aa:       63c52583                lw      a1,1596(a0) # 3fc8063c <_ZN12esp_riscv_rt3CNT17hcec3e3a214887d53E.0>
420003ae:       0585                    addi    a1,a1,1
420003b0:       62b52e23                sw      a1,1596(a0)
    }
}
420003b4:       4532                    lw      a0,12(sp)
420003b6:       45a2                    lw      a1,8(sp)
420003b8:       0141                    addi    sp,sp,16
420003ba:       30200073                mret
```

(disassembly via `riscv64-unknown-elf-objdump -C -S --disassemble ./esp32c3-hal/target/riscv32imc-unknown-none-elf/release/examples/gpio_interrupt`)

This outcome is superior to hand-coded interrupt routines which, lacking
visibility into any non-assembly body of the interrupt handler, have to
be very conservative and save the [entire CPU state to the stack
frame][full-frame-save]. By instead asking LLVM to only save the
registers that it uses, we defer the decision to the tool with the best
context: it can more accurately account for the cost of spills if it
knows that every additional register used is already at the cost of an
implicit spill.

At the LLVM level, this is apparently [implemented by] marking every
register as "[callee-save]," matching the semantics of an interrupt
handler nicely (it has to leave the CPU state just as it found it after
its `{m|s}ret`).

This approach is not suitable for every interrupt handler, as it makes
no attempt to e.g. save the state in a user-accessible stack frame. For
a full discussion of those challenges and tradeoffs, please refer to
[the interrupt calling conventions RFC][rfc].

Inside rustc, this implementation differs from prior art because LLVM
does not expose the "all-saved" function flavor as a calling convention
directly, instead preferring to use an attribute that allows for
differentiating between "machine-mode" and "superivsor-mode" interrupts.

Finally, some effort has been made to guide those who may not yet be
aware of the differences between machine-mode and supervisor-mode
interrupts as to why no `riscv-interrupt` calling convention is exposed
through rustc, and similarly for why `riscv-interrupt-u` makes no
appearance (as it would complicate future LLVM upgrades).

[clang-attr]: https://clang.llvm.org/docs/AttributeReference.html#interrupt-risc-v
[full-frame-save]: 9281af2ecf/src/lib.rs (L440-L469)
[implemented by]: b7fb2a3fec/llvm/lib/Target/RISCV/RISCVRegisterInfo.cpp (L61-L67)
[callee-save]: 973f1fe7a8/llvm/lib/Target/RISCV/RISCVCallingConv.td (L30-L37)
[rfc]: https://github.com/rust-lang/rfcs/pull/3246
2023-08-08 18:09:56 -07:00

591 lines
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Rust
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use crate::attributes;
use crate::builder::Builder;
use crate::context::CodegenCx;
use crate::llvm::{self, Attribute, AttributePlace};
use crate::type_::Type;
use crate::type_of::LayoutLlvmExt;
use crate::value::Value;
use rustc_codegen_ssa::mir::operand::OperandValue;
use rustc_codegen_ssa::mir::place::PlaceRef;
use rustc_codegen_ssa::traits::*;
use rustc_codegen_ssa::MemFlags;
use rustc_middle::bug;
use rustc_middle::ty::layout::LayoutOf;
pub use rustc_middle::ty::layout::{FAT_PTR_ADDR, FAT_PTR_EXTRA};
use rustc_middle::ty::Ty;
use rustc_session::config;
use rustc_target::abi::call::ArgAbi;
pub use rustc_target::abi::call::*;
use rustc_target::abi::{self, HasDataLayout, Int};
pub use rustc_target::spec::abi::Abi;
use rustc_target::spec::SanitizerSet;
use libc::c_uint;
use smallvec::SmallVec;
pub trait ArgAttributesExt {
fn apply_attrs_to_llfn(&self, idx: AttributePlace, cx: &CodegenCx<'_, '_>, llfn: &Value);
fn apply_attrs_to_callsite(
&self,
idx: AttributePlace,
cx: &CodegenCx<'_, '_>,
callsite: &Value,
);
}
const ABI_AFFECTING_ATTRIBUTES: [(ArgAttribute, llvm::AttributeKind); 1] =
[(ArgAttribute::InReg, llvm::AttributeKind::InReg)];
const OPTIMIZATION_ATTRIBUTES: [(ArgAttribute, llvm::AttributeKind); 5] = [
(ArgAttribute::NoAlias, llvm::AttributeKind::NoAlias),
(ArgAttribute::NoCapture, llvm::AttributeKind::NoCapture),
(ArgAttribute::NonNull, llvm::AttributeKind::NonNull),
(ArgAttribute::ReadOnly, llvm::AttributeKind::ReadOnly),
(ArgAttribute::NoUndef, llvm::AttributeKind::NoUndef),
];
fn get_attrs<'ll>(this: &ArgAttributes, cx: &CodegenCx<'ll, '_>) -> SmallVec<[&'ll Attribute; 8]> {
let mut regular = this.regular;
let mut attrs = SmallVec::new();
// ABI-affecting attributes must always be applied
for (attr, llattr) in ABI_AFFECTING_ATTRIBUTES {
if regular.contains(attr) {
attrs.push(llattr.create_attr(cx.llcx));
}
}
if let Some(align) = this.pointee_align {
attrs.push(llvm::CreateAlignmentAttr(cx.llcx, align.bytes()));
}
match this.arg_ext {
ArgExtension::None => {}
ArgExtension::Zext => attrs.push(llvm::AttributeKind::ZExt.create_attr(cx.llcx)),
ArgExtension::Sext => attrs.push(llvm::AttributeKind::SExt.create_attr(cx.llcx)),
}
// Only apply remaining attributes when optimizing
if cx.sess().opts.optimize != config::OptLevel::No {
let deref = this.pointee_size.bytes();
if deref != 0 {
if regular.contains(ArgAttribute::NonNull) {
attrs.push(llvm::CreateDereferenceableAttr(cx.llcx, deref));
} else {
attrs.push(llvm::CreateDereferenceableOrNullAttr(cx.llcx, deref));
}
regular -= ArgAttribute::NonNull;
}
for (attr, llattr) in OPTIMIZATION_ATTRIBUTES {
if regular.contains(attr) {
attrs.push(llattr.create_attr(cx.llcx));
}
}
} else if cx.tcx.sess.opts.unstable_opts.sanitizer.contains(SanitizerSet::MEMORY) {
// If we're not optimising, *but* memory sanitizer is on, emit noundef, since it affects
// memory sanitizer's behavior.
if regular.contains(ArgAttribute::NoUndef) {
attrs.push(llvm::AttributeKind::NoUndef.create_attr(cx.llcx));
}
}
attrs
}
impl ArgAttributesExt for ArgAttributes {
fn apply_attrs_to_llfn(&self, idx: AttributePlace, cx: &CodegenCx<'_, '_>, llfn: &Value) {
let attrs = get_attrs(self, cx);
attributes::apply_to_llfn(llfn, idx, &attrs);
}
fn apply_attrs_to_callsite(
&self,
idx: AttributePlace,
cx: &CodegenCx<'_, '_>,
callsite: &Value,
) {
let attrs = get_attrs(self, cx);
attributes::apply_to_callsite(callsite, idx, &attrs);
}
}
pub trait LlvmType {
fn llvm_type<'ll>(&self, cx: &CodegenCx<'ll, '_>) -> &'ll Type;
}
impl LlvmType for Reg {
fn llvm_type<'ll>(&self, cx: &CodegenCx<'ll, '_>) -> &'ll Type {
match self.kind {
RegKind::Integer => cx.type_ix(self.size.bits()),
RegKind::Float => match self.size.bits() {
32 => cx.type_f32(),
64 => cx.type_f64(),
_ => bug!("unsupported float: {:?}", self),
},
RegKind::Vector => cx.type_vector(cx.type_i8(), self.size.bytes()),
}
}
}
impl LlvmType for CastTarget {
fn llvm_type<'ll>(&self, cx: &CodegenCx<'ll, '_>) -> &'ll Type {
let rest_ll_unit = self.rest.unit.llvm_type(cx);
let (rest_count, rem_bytes) = if self.rest.unit.size.bytes() == 0 {
(0, 0)
} else {
(
self.rest.total.bytes() / self.rest.unit.size.bytes(),
self.rest.total.bytes() % self.rest.unit.size.bytes(),
)
};
if self.prefix.iter().all(|x| x.is_none()) {
// Simplify to a single unit when there is no prefix and size <= unit size
if self.rest.total <= self.rest.unit.size {
return rest_ll_unit;
}
// Simplify to array when all chunks are the same size and type
if rem_bytes == 0 {
return cx.type_array(rest_ll_unit, rest_count);
}
}
// Create list of fields in the main structure
let mut args: Vec<_> = self
.prefix
.iter()
.flat_map(|option_reg| option_reg.map(|reg| reg.llvm_type(cx)))
.chain((0..rest_count).map(|_| rest_ll_unit))
.collect();
// Append final integer
if rem_bytes != 0 {
// Only integers can be really split further.
assert_eq!(self.rest.unit.kind, RegKind::Integer);
args.push(cx.type_ix(rem_bytes * 8));
}
cx.type_struct(&args, false)
}
}
pub trait ArgAbiExt<'ll, 'tcx> {
fn memory_ty(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type;
fn store(
&self,
bx: &mut Builder<'_, 'll, 'tcx>,
val: &'ll Value,
dst: PlaceRef<'tcx, &'ll Value>,
);
fn store_fn_arg(
&self,
bx: &mut Builder<'_, 'll, 'tcx>,
idx: &mut usize,
dst: PlaceRef<'tcx, &'ll Value>,
);
}
impl<'ll, 'tcx> ArgAbiExt<'ll, 'tcx> for ArgAbi<'tcx, Ty<'tcx>> {
/// Gets the LLVM type for a place of the original Rust type of
/// this argument/return, i.e., the result of `type_of::type_of`.
fn memory_ty(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type {
self.layout.llvm_type(cx)
}
/// Stores a direct/indirect value described by this ArgAbi into a
/// place for the original Rust type of this argument/return.
/// Can be used for both storing formal arguments into Rust variables
/// or results of call/invoke instructions into their destinations.
fn store(
&self,
bx: &mut Builder<'_, 'll, 'tcx>,
val: &'ll Value,
dst: PlaceRef<'tcx, &'ll Value>,
) {
if self.is_ignore() {
return;
}
if self.is_sized_indirect() {
OperandValue::Ref(val, None, self.layout.align.abi).store(bx, dst)
} else if self.is_unsized_indirect() {
bug!("unsized `ArgAbi` must be handled through `store_fn_arg`");
} else if let PassMode::Cast(cast, _) = &self.mode {
// FIXME(eddyb): Figure out when the simpler Store is safe, clang
// uses it for i16 -> {i8, i8}, but not for i24 -> {i8, i8, i8}.
let can_store_through_cast_ptr = false;
if can_store_through_cast_ptr {
bx.store(val, dst.llval, self.layout.align.abi);
} else {
// The actual return type is a struct, but the ABI
// adaptation code has cast it into some scalar type. The
// code that follows is the only reliable way I have
// found to do a transform like i64 -> {i32,i32}.
// Basically we dump the data onto the stack then memcpy it.
//
// Other approaches I tried:
// - Casting rust ret pointer to the foreign type and using Store
// is (a) unsafe if size of foreign type > size of rust type and
// (b) runs afoul of strict aliasing rules, yielding invalid
// assembly under -O (specifically, the store gets removed).
// - Truncating foreign type to correct integral type and then
// bitcasting to the struct type yields invalid cast errors.
// We instead thus allocate some scratch space...
let scratch_size = cast.size(bx);
let scratch_align = cast.align(bx);
let llscratch = bx.alloca(cast.llvm_type(bx), scratch_align);
bx.lifetime_start(llscratch, scratch_size);
// ... where we first store the value...
bx.store(val, llscratch, scratch_align);
// ... and then memcpy it to the intended destination.
bx.memcpy(
dst.llval,
self.layout.align.abi,
llscratch,
scratch_align,
bx.const_usize(self.layout.size.bytes()),
MemFlags::empty(),
);
bx.lifetime_end(llscratch, scratch_size);
}
} else {
OperandValue::Immediate(val).store(bx, dst);
}
}
fn store_fn_arg(
&self,
bx: &mut Builder<'_, 'll, 'tcx>,
idx: &mut usize,
dst: PlaceRef<'tcx, &'ll Value>,
) {
let mut next = || {
let val = llvm::get_param(bx.llfn(), *idx as c_uint);
*idx += 1;
val
};
match self.mode {
PassMode::Ignore => {}
PassMode::Pair(..) => {
OperandValue::Pair(next(), next()).store(bx, dst);
}
PassMode::Indirect { attrs: _, extra_attrs: Some(_), on_stack: _ } => {
OperandValue::Ref(next(), Some(next()), self.layout.align.abi).store(bx, dst);
}
PassMode::Direct(_)
| PassMode::Indirect { attrs: _, extra_attrs: None, on_stack: _ }
| PassMode::Cast(..) => {
let next_arg = next();
self.store(bx, next_arg, dst);
}
}
}
}
impl<'ll, 'tcx> ArgAbiMethods<'tcx> for Builder<'_, 'll, 'tcx> {
fn store_fn_arg(
&mut self,
arg_abi: &ArgAbi<'tcx, Ty<'tcx>>,
idx: &mut usize,
dst: PlaceRef<'tcx, Self::Value>,
) {
arg_abi.store_fn_arg(self, idx, dst)
}
fn store_arg(
&mut self,
arg_abi: &ArgAbi<'tcx, Ty<'tcx>>,
val: &'ll Value,
dst: PlaceRef<'tcx, &'ll Value>,
) {
arg_abi.store(self, val, dst)
}
fn arg_memory_ty(&self, arg_abi: &ArgAbi<'tcx, Ty<'tcx>>) -> &'ll Type {
arg_abi.memory_ty(self)
}
}
pub trait FnAbiLlvmExt<'ll, 'tcx> {
fn llvm_type(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type;
fn ptr_to_llvm_type(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type;
fn llvm_cconv(&self) -> llvm::CallConv;
fn apply_attrs_llfn(&self, cx: &CodegenCx<'ll, 'tcx>, llfn: &'ll Value);
fn apply_attrs_callsite(&self, bx: &mut Builder<'_, 'll, 'tcx>, callsite: &'ll Value);
}
impl<'ll, 'tcx> FnAbiLlvmExt<'ll, 'tcx> for FnAbi<'tcx, Ty<'tcx>> {
fn llvm_type(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type {
// Ignore "extra" args from the call site for C variadic functions.
// Only the "fixed" args are part of the LLVM function signature.
let args =
if self.c_variadic { &self.args[..self.fixed_count as usize] } else { &self.args };
// This capacity calculation is approximate.
let mut llargument_tys = Vec::with_capacity(
self.args.len() + if let PassMode::Indirect { .. } = self.ret.mode { 1 } else { 0 },
);
let llreturn_ty = match &self.ret.mode {
PassMode::Ignore => cx.type_void(),
PassMode::Direct(_) | PassMode::Pair(..) => self.ret.layout.immediate_llvm_type(cx),
PassMode::Cast(cast, _) => cast.llvm_type(cx),
PassMode::Indirect { .. } => {
llargument_tys.push(cx.type_ptr());
cx.type_void()
}
};
for arg in args {
let llarg_ty = match &arg.mode {
PassMode::Ignore => continue,
PassMode::Direct(_) => arg.layout.immediate_llvm_type(cx),
PassMode::Pair(..) => {
llargument_tys.push(arg.layout.scalar_pair_element_llvm_type(cx, 0, true));
llargument_tys.push(arg.layout.scalar_pair_element_llvm_type(cx, 1, true));
continue;
}
PassMode::Indirect { attrs: _, extra_attrs: Some(_), on_stack: _ } => {
let ptr_ty = Ty::new_mut_ptr(cx.tcx, arg.layout.ty);
let ptr_layout = cx.layout_of(ptr_ty);
llargument_tys.push(ptr_layout.scalar_pair_element_llvm_type(cx, 0, true));
llargument_tys.push(ptr_layout.scalar_pair_element_llvm_type(cx, 1, true));
continue;
}
PassMode::Cast(cast, pad_i32) => {
// add padding
if *pad_i32 {
llargument_tys.push(Reg::i32().llvm_type(cx));
}
cast.llvm_type(cx)
}
PassMode::Indirect { attrs: _, extra_attrs: None, on_stack: _ } => cx.type_ptr(),
};
llargument_tys.push(llarg_ty);
}
if self.c_variadic {
cx.type_variadic_func(&llargument_tys, llreturn_ty)
} else {
cx.type_func(&llargument_tys, llreturn_ty)
}
}
fn ptr_to_llvm_type(&self, cx: &CodegenCx<'ll, 'tcx>) -> &'ll Type {
cx.type_ptr_ext(cx.data_layout().instruction_address_space)
}
fn llvm_cconv(&self) -> llvm::CallConv {
self.conv.into()
}
fn apply_attrs_llfn(&self, cx: &CodegenCx<'ll, 'tcx>, llfn: &'ll Value) {
let mut func_attrs = SmallVec::<[_; 3]>::new();
if self.ret.layout.abi.is_uninhabited() {
func_attrs.push(llvm::AttributeKind::NoReturn.create_attr(cx.llcx));
}
if !self.can_unwind {
func_attrs.push(llvm::AttributeKind::NoUnwind.create_attr(cx.llcx));
}
if let Conv::RiscvInterrupt { kind } = self.conv {
func_attrs.push(llvm::CreateAttrStringValue(cx.llcx, "interrupt", kind.as_str()));
}
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Function, &{ func_attrs });
let mut i = 0;
let mut apply = |attrs: &ArgAttributes| {
attrs.apply_attrs_to_llfn(llvm::AttributePlace::Argument(i), cx, llfn);
i += 1;
i - 1
};
match &self.ret.mode {
PassMode::Direct(attrs) => {
attrs.apply_attrs_to_llfn(llvm::AttributePlace::ReturnValue, cx, llfn);
}
PassMode::Indirect { attrs, extra_attrs: _, on_stack } => {
assert!(!on_stack);
let i = apply(attrs);
let sret = llvm::CreateStructRetAttr(cx.llcx, self.ret.layout.llvm_type(cx));
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Argument(i), &[sret]);
}
PassMode::Cast(cast, _) => {
cast.attrs.apply_attrs_to_llfn(llvm::AttributePlace::ReturnValue, cx, llfn);
}
_ => {}
}
for arg in self.args.iter() {
match &arg.mode {
PassMode::Ignore => {}
PassMode::Indirect { attrs, extra_attrs: None, on_stack: true } => {
let i = apply(attrs);
let byval = llvm::CreateByValAttr(cx.llcx, arg.layout.llvm_type(cx));
attributes::apply_to_llfn(llfn, llvm::AttributePlace::Argument(i), &[byval]);
}
PassMode::Direct(attrs)
| PassMode::Indirect { attrs, extra_attrs: None, on_stack: false } => {
apply(attrs);
}
PassMode::Indirect { attrs, extra_attrs: Some(extra_attrs), on_stack } => {
assert!(!on_stack);
apply(attrs);
apply(extra_attrs);
}
PassMode::Pair(a, b) => {
apply(a);
apply(b);
}
PassMode::Cast(cast, pad_i32) => {
if *pad_i32 {
apply(&ArgAttributes::new());
}
apply(&cast.attrs);
}
}
}
}
fn apply_attrs_callsite(&self, bx: &mut Builder<'_, 'll, 'tcx>, callsite: &'ll Value) {
let mut func_attrs = SmallVec::<[_; 2]>::new();
if self.ret.layout.abi.is_uninhabited() {
func_attrs.push(llvm::AttributeKind::NoReturn.create_attr(bx.cx.llcx));
}
if !self.can_unwind {
func_attrs.push(llvm::AttributeKind::NoUnwind.create_attr(bx.cx.llcx));
}
attributes::apply_to_callsite(callsite, llvm::AttributePlace::Function, &{ func_attrs });
let mut i = 0;
let mut apply = |cx: &CodegenCx<'_, '_>, attrs: &ArgAttributes| {
attrs.apply_attrs_to_callsite(llvm::AttributePlace::Argument(i), cx, callsite);
i += 1;
i - 1
};
match &self.ret.mode {
PassMode::Direct(attrs) => {
attrs.apply_attrs_to_callsite(llvm::AttributePlace::ReturnValue, bx.cx, callsite);
}
PassMode::Indirect { attrs, extra_attrs: _, on_stack } => {
assert!(!on_stack);
let i = apply(bx.cx, attrs);
let sret = llvm::CreateStructRetAttr(bx.cx.llcx, self.ret.layout.llvm_type(bx));
attributes::apply_to_callsite(callsite, llvm::AttributePlace::Argument(i), &[sret]);
}
PassMode::Cast(cast, _) => {
cast.attrs.apply_attrs_to_callsite(
llvm::AttributePlace::ReturnValue,
&bx.cx,
callsite,
);
}
_ => {}
}
if let abi::Abi::Scalar(scalar) = self.ret.layout.abi {
// If the value is a boolean, the range is 0..2 and that ultimately
// become 0..0 when the type becomes i1, which would be rejected
// by the LLVM verifier.
if let Int(..) = scalar.primitive() {
if !scalar.is_bool() && !scalar.is_always_valid(bx) {
bx.range_metadata(callsite, scalar.valid_range(bx));
}
}
}
for arg in self.args.iter() {
match &arg.mode {
PassMode::Ignore => {}
PassMode::Indirect { attrs, extra_attrs: None, on_stack: true } => {
let i = apply(bx.cx, attrs);
let byval = llvm::CreateByValAttr(bx.cx.llcx, arg.layout.llvm_type(bx));
attributes::apply_to_callsite(
callsite,
llvm::AttributePlace::Argument(i),
&[byval],
);
}
PassMode::Direct(attrs)
| PassMode::Indirect { attrs, extra_attrs: None, on_stack: false } => {
apply(bx.cx, attrs);
}
PassMode::Indirect { attrs, extra_attrs: Some(extra_attrs), on_stack: _ } => {
apply(bx.cx, attrs);
apply(bx.cx, extra_attrs);
}
PassMode::Pair(a, b) => {
apply(bx.cx, a);
apply(bx.cx, b);
}
PassMode::Cast(cast, pad_i32) => {
if *pad_i32 {
apply(bx.cx, &ArgAttributes::new());
}
apply(bx.cx, &cast.attrs);
}
}
}
let cconv = self.llvm_cconv();
if cconv != llvm::CCallConv {
llvm::SetInstructionCallConv(callsite, cconv);
}
if self.conv == Conv::CCmseNonSecureCall {
// This will probably get ignored on all targets but those supporting the TrustZone-M
// extension (thumbv8m targets).
let cmse_nonsecure_call = llvm::CreateAttrString(bx.cx.llcx, "cmse_nonsecure_call");
attributes::apply_to_callsite(
callsite,
llvm::AttributePlace::Function,
&[cmse_nonsecure_call],
);
}
// Some intrinsics require that an elementtype attribute (with the pointee type of a
// pointer argument) is added to the callsite.
let element_type_index = unsafe { llvm::LLVMRustGetElementTypeArgIndex(callsite) };
if element_type_index >= 0 {
let arg_ty = self.args[element_type_index as usize].layout.ty;
let pointee_ty = arg_ty.builtin_deref(true).expect("Must be pointer argument").ty;
let element_type_attr = unsafe {
llvm::LLVMRustCreateElementTypeAttr(bx.llcx, bx.layout_of(pointee_ty).llvm_type(bx))
};
attributes::apply_to_callsite(
callsite,
llvm::AttributePlace::Argument(element_type_index as u32),
&[element_type_attr],
);
}
}
}
impl<'tcx> AbiBuilderMethods<'tcx> for Builder<'_, '_, 'tcx> {
fn get_param(&mut self, index: usize) -> Self::Value {
llvm::get_param(self.llfn(), index as c_uint)
}
}
impl From<Conv> for llvm::CallConv {
fn from(conv: Conv) -> Self {
match conv {
Conv::C | Conv::Rust | Conv::CCmseNonSecureCall | Conv::RiscvInterrupt { .. } => {
llvm::CCallConv
}
Conv::RustCold => llvm::ColdCallConv,
Conv::AmdGpuKernel => llvm::AmdGpuKernel,
Conv::AvrInterrupt => llvm::AvrInterrupt,
Conv::AvrNonBlockingInterrupt => llvm::AvrNonBlockingInterrupt,
Conv::ArmAapcs => llvm::ArmAapcsCallConv,
Conv::Msp430Intr => llvm::Msp430Intr,
Conv::PtxKernel => llvm::PtxKernel,
Conv::X86Fastcall => llvm::X86FastcallCallConv,
Conv::X86Intr => llvm::X86_Intr,
Conv::X86Stdcall => llvm::X86StdcallCallConv,
Conv::X86ThisCall => llvm::X86_ThisCall,
Conv::X86VectorCall => llvm::X86_VectorCall,
Conv::X86_64SysV => llvm::X86_64_SysV,
Conv::X86_64Win64 => llvm::X86_64_Win64,
}
}
}
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