[llvm][AArch64] Handle arrays of struct properly (from IR)

This only applies to FastIsel. GlobalIsel seems to sidestep
the issue.

This fixes https://bugs.llvm.org/show_bug.cgi?id=46996

One of the things we do in llvm is decide if a type needs
consecutive registers. Previously, we just checked if it
was an array or not.
(plus an SVE specific check that is not changing here)

This causes some confusion when you arbitrary IR like:
```
%T1 = type { double, i1 };
define [ 1 x %T1 ] @foo() {
entry:
  ret [ 1 x %T1 ] zeroinitializer
}
```

We see it is an array so we call CC_AArch64_Custom_Block
which bails out when it sees the i1, a type we don't want
to put into a block.

This leaves the location of the double in some kind of
intermediate state and leads to odd codegen. Which then crashes
the backend because it doesn't know how to implement
what it's been asked for.

You get this:
```
  renamable $d0 = FMOVD0
  $w0 = COPY killed renamable $d0
```

Rather than this:
```
  $d0 = FMOVD0
  $w0 = COPY $wzr
```

The backend knows how to copy 64 bit to 64 bit registers,
but not 64 to 32. It can certainly be taught how but the real
issue seems to be us even trying to assign a register block
in the first place.

This change makes the logic of
AArch64TargetLowering::functionArgumentNeedsConsecutiveRegisters
a bit more in depth. If we find an array, also check that all the
nested aggregates in that array have a single member type.

Then CC_AArch64_Custom_Block's assumption of a type that looks
like [ N x type ] will be valid and we get the expected codegen.

New tests have been added to exercise these situations. Note that
some of the output is not ABI compliant. The aim of this change is
to simply handle these situations and not to make our processing
of arbitrary IR ABI compliant.

Reviewed By: efriedma

Differential Revision: https://reviews.llvm.org/D104123
This commit is contained in:
David Spickett 2021-06-09 16:36:39 +00:00
parent 87784cc6fb
commit e4ecd83fe9
10 changed files with 540 additions and 21 deletions

View File

@ -4001,7 +4001,8 @@ public:
/// must be passed in a block of consecutive registers.
virtual bool
functionArgumentNeedsConsecutiveRegisters(Type *Ty, CallingConv::ID CallConv,
bool isVarArg) const {
bool isVarArg,
const DataLayout &DL) const {
return false;
}

View File

@ -224,7 +224,7 @@ void CallLowering::splitToValueTypes(const ArgInfo &OrigArg,
assert(OrigArg.Regs.size() == SplitVTs.size() && "Regs / types mismatch");
bool NeedsRegBlock = TLI->functionArgumentNeedsConsecutiveRegisters(
OrigArg.Ty, CallConv, false);
OrigArg.Ty, CallConv, false, DL);
for (unsigned i = 0, e = SplitVTs.size(); i < e; ++i) {
Type *SplitTy = SplitVTs[i].getTypeForEVT(Ctx);
SplitArgs.emplace_back(OrigArg.Regs[i], SplitTy, OrigArg.Flags[0],

View File

@ -1035,7 +1035,7 @@ bool FastISel::lowerCallTo(CallLoweringInfo &CLI) {
if (Arg.IsByVal)
FinalType = cast<PointerType>(Arg.Ty)->getElementType();
bool NeedsRegBlock = TLI.functionArgumentNeedsConsecutiveRegisters(
FinalType, CLI.CallConv, CLI.IsVarArg);
FinalType, CLI.CallConv, CLI.IsVarArg, DL);
ISD::ArgFlagsTy Flags;
if (Arg.IsZExt)

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@ -1933,7 +1933,7 @@ void SelectionDAGBuilder::visitRet(const ReturnInst &I) {
bool NeedsRegBlock = TLI.functionArgumentNeedsConsecutiveRegisters(
I.getOperand(0)->getType(), F->getCallingConv(),
/*IsVarArg*/ false);
/*IsVarArg*/ false, DL);
ISD::NodeType ExtendKind = ISD::ANY_EXTEND;
if (F->getAttributes().hasAttribute(AttributeList::ReturnIndex,
@ -9432,7 +9432,7 @@ TargetLowering::LowerCallTo(TargetLowering::CallLoweringInfo &CLI) const {
CLI.IsTailCall = false;
} else {
bool NeedsRegBlock = functionArgumentNeedsConsecutiveRegisters(
CLI.RetTy, CLI.CallConv, CLI.IsVarArg);
CLI.RetTy, CLI.CallConv, CLI.IsVarArg, DL);
for (unsigned I = 0, E = RetTys.size(); I != E; ++I) {
ISD::ArgFlagsTy Flags;
if (NeedsRegBlock) {
@ -9492,7 +9492,7 @@ TargetLowering::LowerCallTo(TargetLowering::CallLoweringInfo &CLI) const {
if (Args[i].IsByVal)
FinalType = cast<PointerType>(Args[i].Ty)->getElementType();
bool NeedsRegBlock = functionArgumentNeedsConsecutiveRegisters(
FinalType, CLI.CallConv, CLI.IsVarArg);
FinalType, CLI.CallConv, CLI.IsVarArg, DL);
for (unsigned Value = 0, NumValues = ValueVTs.size(); Value != NumValues;
++Value) {
EVT VT = ValueVTs[Value];
@ -10043,7 +10043,7 @@ void SelectionDAGISel::LowerArguments(const Function &F) {
if (Arg.hasAttribute(Attribute::ByVal))
FinalType = Arg.getParamByValType();
bool NeedsRegBlock = TLI->functionArgumentNeedsConsecutiveRegisters(
FinalType, F.getCallingConv(), F.isVarArg());
FinalType, F.getCallingConv(), F.isVarArg(), DL);
for (unsigned Value = 0, NumValues = ValueVTs.size();
Value != NumValues; ++Value) {
EVT VT = ValueVTs[Value];

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@ -31,6 +31,7 @@
#include "llvm/ADT/Twine.h"
#include "llvm/Analysis/ObjCARCUtil.h"
#include "llvm/Analysis/VectorUtils.h"
#include "llvm/CodeGen/Analysis.h"
#include "llvm/CodeGen/CallingConvLower.h"
#include "llvm/CodeGen/MachineBasicBlock.h"
#include "llvm/CodeGen/MachineFrameInfo.h"
@ -17210,15 +17211,17 @@ Value *AArch64TargetLowering::emitStoreConditional(IRBuilderBase &Builder,
}
bool AArch64TargetLowering::functionArgumentNeedsConsecutiveRegisters(
Type *Ty, CallingConv::ID CallConv, bool isVarArg) const {
if (Ty->isArrayTy())
return true;
Type *Ty, CallingConv::ID CallConv, bool isVarArg,
const DataLayout &DL) const {
if (!Ty->isArrayTy()) {
const TypeSize &TySize = Ty->getPrimitiveSizeInBits();
if (TySize.isScalable() && TySize.getKnownMinSize() > 128)
return true;
return TySize.isScalable() && TySize.getKnownMinSize() > 128;
}
return false;
// All non aggregate members of the type must have the same type
SmallVector<EVT> ValueVTs;
ComputeValueVTs(*this, DL, Ty, ValueVTs);
return is_splat(ValueVTs);
}
bool AArch64TargetLowering::shouldNormalizeToSelectSequence(LLVMContext &,

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@ -801,9 +801,10 @@ public:
MachineMemOperand::Flags getTargetMMOFlags(
const Instruction &I) const override;
bool functionArgumentNeedsConsecutiveRegisters(Type *Ty,
CallingConv::ID CallConv,
bool isVarArg) const override;
bool functionArgumentNeedsConsecutiveRegisters(
Type *Ty, CallingConv::ID CallConv, bool isVarArg,
const DataLayout &DL) const override;
/// Used for exception handling on Win64.
bool needsFixedCatchObjects() const override;

View File

@ -20131,7 +20131,8 @@ Align ARMTargetLowering::getABIAlignmentForCallingConv(
/// [N x i32] or [N x i64]. This allows front-ends to skip emitting padding when
/// passing according to AAPCS rules.
bool ARMTargetLowering::functionArgumentNeedsConsecutiveRegisters(
Type *Ty, CallingConv::ID CallConv, bool isVarArg) const {
Type *Ty, CallingConv::ID CallConv, bool isVarArg,
const DataLayout &DL) const {
if (getEffectiveCallingConv(CallConv, isVarArg) !=
CallingConv::ARM_AAPCS_VFP)
return false;

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@ -615,7 +615,8 @@ class VectorType;
/// Returns true if an argument of type Ty needs to be passed in a
/// contiguous block of registers in calling convention CallConv.
bool functionArgumentNeedsConsecutiveRegisters(
Type *Ty, CallingConv::ID CallConv, bool isVarArg) const override;
Type *Ty, CallingConv::ID CallConv, bool isVarArg,
const DataLayout &DL) const override;
/// If a physical register, this returns the register that receives the
/// exception address on entry to an EH pad.

View File

@ -1049,7 +1049,8 @@ namespace llvm {
/// Returns true if an argument of type Ty needs to be passed in a
/// contiguous block of registers in calling convention CallConv.
bool functionArgumentNeedsConsecutiveRegisters(
Type *Ty, CallingConv::ID CallConv, bool isVarArg) const override {
Type *Ty, CallingConv::ID CallConv, bool isVarArg,
const DataLayout &DL) const override {
// We support any array type as "consecutive" block in the parameter
// save area. The element type defines the alignment requirement and
// whether the argument should go in GPRs, FPRs, or VRs if available.

View File

@ -0,0 +1,511 @@
; RUN: llc -mtriple=aarch64-none-linux-gnu -o - %s | FileCheck %s
;; Check that the llvm aarch64 backend can handle arrays of
;; structs and vice versa when passed from IR.
;; (this layering is something clang would normally simplify)
;;
;; Some of these examples are not ABI compliant and they're not
;; meant to be. For instance according to the ABI an aggregate
;; with more than 4 members must go in memory. This restriction
;; is applied earlier in the compilation process so here we do
;; see 8 member types in registers.
;;
;; When we have more than 8 members we simply run out of registers
;; and that's what produces the 8 limit here.
;; Plain arrays
define [ 0 x double ] @array_0() {
; CHECK-LABEL: array_0:
; CHECK: ret
ret [ 0 x double ] zeroinitializer
}
define [ 1 x double ] @array_1() {
; CHECK-LABEL: array_1:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: ret
ret [ 1 x double ] zeroinitializer
}
define [ 8 x double ] @array_8() {
; CHECK-LABEL: array_8:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: movi d5, #0000000000000000
; CHECK-NEXT: movi d6, #0000000000000000
; CHECK-NEXT: movi d7, #0000000000000000
; CHECK-NEXT: ret
ret [ 8 x double ] zeroinitializer
}
;; > 8 items goes on the stack
define [ 9 x double ] @array_9() {
; CHECK-LABEL: array_9:
; CHECK: movi v0.2d, #0000000000000000
; CHECK-NEXT: str xzr, [x8, #64]
; CHECK-NEXT: stp q0, q0, [x8, #32]
; CHECK-NEXT: stp q0, q0, [x8]
; CHECK-NEXT: ret
ret [ 9 x double ] zeroinitializer
}
;; Won't use any registers, just checking for assumptions.
%T_STRUCT_0M = type { }
define %T_STRUCT_0M @struct_zero_fields() {
; CHECK-LABEL: struct_zero_fields:
; CHECK: ret
ret %T_STRUCT_0M zeroinitializer
}
define [ 1 x %T_STRUCT_0M ] @array_of_struct_zero_fields() {
; CHECK-LABEL: array_of_struct_zero_fields:
; CHECK: ret
ret [ 1 x %T_STRUCT_0M ] zeroinitializer
}
define [ 2 x %T_STRUCT_0M ] @array_of_struct_zero_fields_in_struct() {
; CHECK-LABEL: array_of_struct_zero_fields_in_struct:
; CHECK: ret
ret [ 2 x %T_STRUCT_0M ] zeroinitializer
}
%T_STRUCT_1M = type { i32 }
define %T_STRUCT_1M @struct_one_field() {
; CHECK-LABEL: struct_one_field:
; CHECK: w0, wzr
; CHECK-NEXT: ret
ret %T_STRUCT_1M zeroinitializer
}
define [ 1 x %T_STRUCT_1M ] @array_of_struct_one_field() {
; CHECK-LABEL: array_of_struct_one_field:
; CHECK: w0, wzr
; CHECK-NEXT: ret
ret [ 1 x %T_STRUCT_1M ] zeroinitializer
}
;; This one will be a reg block
define [ 2 x %T_STRUCT_1M ] @array_of_struct_one_field_2() {
; CHECK-LABEL: array_of_struct_one_field_2:
; CHECK: w0, wzr
; CHECK: w1, wzr
; CHECK-NEXT: ret
ret [ 2 x %T_STRUCT_1M ] zeroinitializer
}
;; Different types for each field, will not be put in a reg block
%T_STRUCT_DIFFM = type { double, i32 }
define %T_STRUCT_DIFFM @struct_different_field_types() {
; CHECK-LABEL: struct_different_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: ret
ret %T_STRUCT_DIFFM zeroinitializer
}
define [ 1 x %T_STRUCT_DIFFM ] @array_of_struct_different_field_types() {
; CHECK-LABEL: array_of_struct_different_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: ret
ret [ 1 x %T_STRUCT_DIFFM ] zeroinitializer
}
define [ 2 x %T_STRUCT_DIFFM ] @array_of_struct_different_field_types_2() {
; CHECK-LABEL: array_of_struct_different_field_types_2:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: w1, wzr
; CHECK-NEXT: ret
ret [ 2 x %T_STRUCT_DIFFM ] zeroinitializer
}
;; Each field is the same type, can be put in a reg block
%T_STRUCT_SAMEM = type { double, double }
;; Here isn't a block as such, we just allocate two consecutive registers
define %T_STRUCT_SAMEM @struct_same_field_types() {
; CHECK-LABEL: struct_same_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: ret
ret %T_STRUCT_SAMEM zeroinitializer
}
define [ 1 x %T_STRUCT_SAMEM ] @array_of_struct_same_field_types() {
; CHECK-LABEL: array_of_struct_same_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: ret
ret [ 1 x %T_STRUCT_SAMEM ] zeroinitializer
}
define [ 2 x %T_STRUCT_SAMEM ] @array_of_struct_same_field_types_2() {
; CHECK-LABEL: array_of_struct_same_field_types_2:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: ret
ret [ 2 x %T_STRUCT_SAMEM ] zeroinitializer
}
;; Same field type but integer this time. Put into x registers instead.
%T_STRUCT_SAMEM_INT = type { i64, i64 }
define %T_STRUCT_SAMEM_INT @struct_same_field_types_int() {
; CHECK-LABEL: struct_same_field_types_int:
; CHECK: x0, xzr
; CHECK-NEXT: x1, xzr
; CHECK-NEXT: ret
ret %T_STRUCT_SAMEM_INT zeroinitializer
}
define [ 1 x %T_STRUCT_SAMEM_INT ] @array_of_struct_same_field_types_int() {
; CHECK-LABEL: array_of_struct_same_field_types_int:
; CHECK: x0, xzr
; CHECK-NEXT: x1, xzr
; CHECK-NEXT: ret
ret [ 1 x %T_STRUCT_SAMEM_INT ] zeroinitializer
}
define [ 2 x %T_STRUCT_SAMEM_INT ] @array_of_struct_same_field_types_int_2() {
; CHECK-LABEL: array_of_struct_same_field_types_int_2:
; CHECK: x0, xzr
; CHECK-NEXT: x1, xzr
; CHECK-NEXT: x2, xzr
; CHECK-NEXT: x3, xzr
; CHECK-NEXT: ret
ret [ 2 x %T_STRUCT_SAMEM_INT ] zeroinitializer
}
;; An aggregate of more than 8 items must go in memory.
;; 4x2 struct fields = 8 items so it goes in a block.
define [ 4 x %T_STRUCT_SAMEM ] @array_of_struct_8_fields() {
; CHECK-LABEL: array_of_struct_8_fields:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: movi d5, #0000000000000000
; CHECK-NEXT: movi d6, #0000000000000000
; CHECK-NEXT: movi d7, #0000000000000000
; CHECK-NEXT: ret
ret [ 4 x %T_STRUCT_SAMEM ] zeroinitializer
}
;; 5x2 fields = 10 so it is returned in memory.
define [ 5 x %T_STRUCT_SAMEM ] @array_of_struct_in_memory() {
; CHECK-LABEL: array_of_struct_in_memory:
; CHECK: movi v0.2d, #0000000000000000
; CHECK-NEXT: stp q0, q0, [x8, #48]
; CHECK-NEXT: stp q0, q0, [x8, #16]
; CHECK-NEXT: str q0, [x8]
; CHECK-NEXT: ret
ret [ 5 x %T_STRUCT_SAMEM ] zeroinitializer
}
;; A struct whose field is an array.
%T_STRUCT_ARRAYM = type { [ 2 x double ]};
define %T_STRUCT_ARRAYM @struct_array_field() {
; CHECK-LABEL: struct_array_field:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: ret
ret %T_STRUCT_ARRAYM zeroinitializer
}
define [ 1 x %T_STRUCT_ARRAYM ] @array_of_struct_array_field() {
; CHECK-LABEL: array_of_struct_array_field:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: ret
ret [ 1 x %T_STRUCT_ARRAYM ] zeroinitializer
}
define [ 2 x %T_STRUCT_ARRAYM ] @array_of_struct_array_field_2() {
; CHECK-LABEL: array_of_struct_array_field_2:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: ret
ret [ 2 x %T_STRUCT_ARRAYM ] zeroinitializer
}
;; All non-aggregate fields must have the same type, all through the
;; overall aggreagate. This is false here because of the i32.
%T_NESTED_STRUCT_DIFFM = type {
[ 1 x { { double, double } } ],
[ 1 x { { double, i32 } } ]
};
define %T_NESTED_STRUCT_DIFFM @struct_nested_different_field_types() {
; CHECK-LABEL: struct_nested_different_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK: movi d1, #0000000000000000
; CHECK: movi d2, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: ret
ret %T_NESTED_STRUCT_DIFFM zeroinitializer
}
define [ 1 x %T_NESTED_STRUCT_DIFFM ] @array_of_struct_nested_different_field_types() {
; CHECK-LABEL: array_of_struct_nested_different_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK: movi d1, #0000000000000000
; CHECK: movi d2, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: ret
ret [ 1 x %T_NESTED_STRUCT_DIFFM ] zeroinitializer
}
define [ 2 x %T_NESTED_STRUCT_DIFFM ] @array_of_struct_nested_different_field_types_2() {
; CHECK-LABEL: array_of_struct_nested_different_field_types_2:
; CHECK: movi d0, #0000000000000000
; CHECK: movi d1, #0000000000000000
; CHECK: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: movi d5, #0000000000000000
; CHECK-NEXT: w0, wzr
; CHECK-NEXT: w1, wzr
; CHECK-NEXT: ret
ret [ 2 x %T_NESTED_STRUCT_DIFFM ] zeroinitializer
}
;; All fields here are the same type, more nesting to stress the recursive walk.
%T_NESTED_STRUCT_SAMEM = type {
{ { double} },
{ [ 2 x { double, double } ] }
};
define %T_NESTED_STRUCT_SAMEM @struct_nested_same_field_types() {
; CHECK-LABEL: struct_nested_same_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: ret
ret %T_NESTED_STRUCT_SAMEM zeroinitializer
}
define [ 1 x %T_NESTED_STRUCT_SAMEM ] @array_of_struct_nested_same_field_types() {
; CHECK-LABEL: array_of_struct_nested_same_field_types:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: ret
ret [ 1 x %T_NESTED_STRUCT_SAMEM ] zeroinitializer
}
;; 2 x (1 + (2 x 2)) = 10 so this is returned in memory
define [ 2 x %T_NESTED_STRUCT_SAMEM ] @array_of_struct_nested_same_field_types_2() {
; CHECK-LABEL: array_of_struct_nested_same_field_types_2:
; CHECK: movi v0.2d, #0000000000000000
; CHECK-NEXT: stp q0, q0, [x8, #48]
; CHECK-NEXT: stp q0, q0, [x8, #16]
; CHECK-NEXT: str q0, [x8]
; CHECK-NEXT: ret
ret [ 2 x %T_NESTED_STRUCT_SAMEM ] zeroinitializer
}
;; Check combinations of call, return and argument passing
%T_IN_BLOCK = type [ 2 x { double, { double, double } } ]
define %T_IN_BLOCK @return_in_block() {
; CHECK-LABEL: return_in_block:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: movi d2, #0000000000000000
; CHECK-NEXT: movi d3, #0000000000000000
; CHECK-NEXT: movi d4, #0000000000000000
; CHECK-NEXT: movi d5, #0000000000000000
; CHECK-NEXT: ret
ret %T_IN_BLOCK zeroinitializer
}
@in_block_store = dso_local global %T_IN_BLOCK zeroinitializer, align 8
define void @caller_in_block() {
; CHECK-LABEL: caller_in_block:
; CHECK: bl return_in_block
; CHECK-NEXT: adrp x8, in_block_store
; CHECK-NEXT: add x8, x8, :lo12:in_block_store
; CHECK-NEXT: stp d0, d1, [x8]
; CHECK-NEXT: stp d2, d3, [x8, #16]
; CHECK-NEXT: stp d4, d5, [x8, #32]
; CHECK-NEXT: ldr x30, [sp], #16
; CHECK-NEXT: ret
%1 = call %T_IN_BLOCK @return_in_block()
store %T_IN_BLOCK %1, %T_IN_BLOCK* @in_block_store
ret void
}
define void @callee_in_block(%T_IN_BLOCK %a) {
; CHECK-LABEL: callee_in_block:
; CHECK: adrp x8, in_block_store
; CHECK-NEXT: add x8, x8, :lo12:in_block_store
; CHECK-NEXT: stp d4, d5, [x8, #32]
; CHECK-NEXT: stp d2, d3, [x8, #16]
; CHECK-NEXT: stp d0, d1, [x8]
; CHECK-NEXT: ret
store %T_IN_BLOCK %a, %T_IN_BLOCK* @in_block_store
ret void
}
define void @argument_in_block() {
; CHECK-LABEL: argument_in_block:
; CHECK: adrp x8, in_block_store
; CHECK-NEXT: add x8, x8, :lo12:in_block_store
; CHECK-NEXT: ldp d4, d5, [x8, #32]
; CHECK-NEXT: ldp d2, d3, [x8, #16]
; CHECK-NEXT: ldp d0, d1, [x8]
; CHECK-NEXT: bl callee_in_block
%1 = load %T_IN_BLOCK, %T_IN_BLOCK* @in_block_store
call void @callee_in_block(%T_IN_BLOCK %1)
ret void
}
%T_IN_MEMORY = type [ 3 x { double, { double, double } } ]
define %T_IN_MEMORY @return_in_memory() {
; CHECK-LABEL: return_in_memory:
; CHECK: movi v0.2d, #0000000000000000
; CHECK-NEXT: str xzr, [x8, #64]
; CHECK-NEXT: stp q0, q0, [x8, #32]
; CHECK-NEXT: stp q0, q0, [x8]
; CHECK-NEXT: ret
ret %T_IN_MEMORY zeroinitializer
}
@in_memory_store = dso_local global %T_IN_MEMORY zeroinitializer, align 8
define void @caller_in_memory() {
; CHECK-LABEL: caller_in_memory:
; CHECK: add x8, sp, #8
; CHECK-NEXT: bl return_in_memory
; CHECK-NEXT: ldr d0, [sp, #72]
; CHECK-NEXT: ldur q1, [sp, #24]
; CHECK-NEXT: ldur q2, [sp, #8]
; CHECK-NEXT: ldur q3, [sp, #56]
; CHECK-NEXT: ldur q4, [sp, #40]
; CHECK-NEXT: ldr x30, [sp, #80]
; CHECK-NEXT: adrp x8, in_memory_store
; CHECK-NEXT: add x8, x8, :lo12:in_memory_store
; CHECK-NEXT: stp q2, q1, [x8]
; CHECK-NEXT: stp q4, q3, [x8, #32]
; CHECK-NEXT: str d0, [x8, #64]
; CHECK-NEXT: add sp, sp, #96
; CHECK-NEXT: ret
%1 = call %T_IN_MEMORY @return_in_memory()
store %T_IN_MEMORY %1, %T_IN_MEMORY* @in_memory_store
ret void
}
define void @callee_in_memory(%T_IN_MEMORY %a) {
; CHECK-LABEL: callee_in_memory:
; CHECK: ldp q0, q1, [sp, #32]
; CHECK-NEXT: ldr d2, [sp, #64]
; CHECK-NEXT: ldp q3, q4, [sp]
; CHECK-NEXT: adrp x8, in_memory_store
; CHECK-NEXT: add x8, x8, :lo12:in_memory_store
; CHECK-NEXT: str d2, [x8, #64]
; CHECK-NEXT: stp q0, q1, [x8, #32]
; CHECK-NEXT: stp q3, q4, [x8]
; CHECK-NEXT: ret
store %T_IN_MEMORY %a, %T_IN_MEMORY* @in_memory_store
ret void
}
define void @argument_in_memory() {
; CHECK-LABEL: argument_in_memory:
; CHECK: adrp x8, in_memory_store
; CHECK-NEXT: add x8, x8, :lo12:in_memory_store
; CHECK-NEXT: ldp q0, q1, [x8]
; CHECK-NEXT: ldp q2, q3, [x8, #32]
; CHECK-NEXT: ldr d4, [x8, #64]
; CHECK-NEXT: stp q0, q1, [sp]
; CHECK-NEXT: stp q2, q3, [sp, #32]
; CHECK-NEXT: str d4, [sp, #64]
; CHECK-NEXT: bl callee_in_memory
%1 = load %T_IN_MEMORY, %T_IN_MEMORY* @in_memory_store
call void @callee_in_memory(%T_IN_MEMORY %1)
ret void
}
%T_NO_BLOCK = type [ 2 x { double, { i32 } } ]
define %T_NO_BLOCK @return_no_block() {
; CHECK-LABEL: return_no_block:
; CHECK: movi d0, #0000000000000000
; CHECK-NEXT: movi d1, #0000000000000000
; CHECK-NEXT: mov w0, wzr
; CHECK-NEXT: mov w1, wzr
; CHECK-NEXT: ret
ret %T_NO_BLOCK zeroinitializer
}
@no_block_store = dso_local global %T_NO_BLOCK zeroinitializer, align 8
define void @caller_no_block() {
; CHECK-LABEL: caller_no_block:
; CHECK: bl return_no_block
; CHECK-NEXT: adrp x8, no_block_store
; CHECK-NEXT: add x8, x8, :lo12:no_block_store
; CHECK-NEXT: str d0, [x8]
; CHECK-NEXT: str w0, [x8, #8]
; CHECK-NEXT: str d1, [x8, #16]
; CHECK-NEXT: str w1, [x8, #24]
; CHECK-NEXT: ldr x30, [sp], #16
; CHECK-NEXT: ret
%1 = call %T_NO_BLOCK @return_no_block()
store %T_NO_BLOCK %1, %T_NO_BLOCK* @no_block_store
ret void
}
define void @callee_no_block(%T_NO_BLOCK %a) {
; CHECK-LABEL: callee_no_block:
; CHECK: adrp x8, no_block_store
; CHECK-NEXT: add x8, x8, :lo12:no_block_store
; CHECK-NEXT: str w1, [x8, #24]
; CHECK-NEXT: str d1, [x8, #16]
; CHECK-NEXT: str w0, [x8, #8]
; CHECK-NEXT: str d0, [x8]
; CHECK-NEXT: ret
store %T_NO_BLOCK %a, %T_NO_BLOCK* @no_block_store
ret void
}
define void @argument_no_block() {
; CHECK-LABEL: argument_no_block:
; CHECK: adrp x8, no_block_store
; CHECK-NEXT: add x8, x8, :lo12:no_block_store
; CHECK-NEXT: ldr w1, [x8, #24]
; CHECK-NEXT: ldr d1, [x8, #16]
; CHECK-NEXT: ldr w0, [x8, #8]
; CHECK-NEXT: ldr d0, [x8]
; CHECK-NEXT: bl callee_no_block
; CHECK-NEXT: ldr x30, [sp], #16
; CHECK-NEXT: ret
%1 = load %T_NO_BLOCK, %T_NO_BLOCK* @no_block_store
call void @callee_no_block(%T_NO_BLOCK %1)
ret void
}