clang/test/CodeGen/aarch64-arguments.c - toolchain/llvm-project - Gitiles

 // RUN: %clang_cc1 -triple aarch64-none-linux-gnu -emit-llvm -w -o - %s | FileCheck -check-prefix=PCS %s

 // Sign extension is performed by the callee on AArch64, which means
 // that we *shouldn't* tag arguments and returns with their extension.

 // PCS-LABEL: define i8 @f0(i16 %a)
 char f0(short a) {
   return a;
 }

 // PCS: define [1 x i64] @f1()
 struct s1 { char f0; };
 struct s1 f1(void) {}

 // PCS: define [1 x i64] @f2()
 struct s2 { short f0; };
 struct s2 f2(void) {}

 // PCS: define [1 x i64] @f3()
 struct s3 { int f0; };
 struct s3 f3(void) {}

 // PCS: define [1 x i64] @f4()
 struct s4 { struct s4_0 { int f0; } f0; };
 struct s4 f4(void) {}

 // PCS: define [1 x i64] @f5()
 struct s5 { struct { } f0; int f1; };
 struct s5 f5(void) {}

 // PCS: define  [1 x i64] @f6()
 struct s6 { int f0[1]; };
 struct s6 f6(void) {}

 // PCS-LABEL: define void @f7()
 struct s7 { struct { int : 0; } f0; };
 struct s7 f7(void) {}

 // PCS-LABEL: define  void @f8()
 struct s8 { struct { int : 0; } f0[1]; };
 struct s8 f8(void) {}

 // PCS: define [1 x i64] @f9()
 struct s9 { long f0; int : 0; };
 struct s9 f9(void) {}

 // PCS: define [1 x i64] @f10()
 struct s10 { long f0; int : 0; int : 0; };
 struct s10 f10(void) {}

 // PCS: define [1 x i64] @f11()
 struct s11 { int : 0; long f0; };
 struct s11 f11(void) {}

 // PCS: define [1 x i64] @f12()
 union u12 { char f0; short f1; int f2; long f3; };
 union u12 f12(void) {}

 // PCS-LABEL: define %struct.s13 @f13()
 struct s13 { float f0; };
 struct s13 f13(void) {}

 // PCS-LABEL: define %union.u14 @f14()
 union u14 { float f0; };
 union u14 f14(void) {}

 // PCS-LABEL: define void @f15()
 void f15(struct s7 a0) {}

 // PCS-LABEL: define void @f16()
 void f16(struct s8 a0) {}

 // PCS: define [1 x i64] @f17()
 struct s17 { short f0 : 13; char f1 : 4; };
 struct s17 f17(void) {}

 // PCS: define [1 x i64] @f18()
 struct s18 { short f0; char f1 : 4; };
 struct s18 f18(void) {}

 // PCS: define [1 x i64] @f19()
 struct s19 { long f0; struct s8 f1; };
 struct s19 f19(void) {}

 // PCS: define [1 x i64] @f20()
 struct s20 { struct s8 f1; long f0; };
 struct s20 f20(void) {}

 // PCS: define [1 x i64] @f21()
 struct s21 { struct {} f1; long f0 : 4; };
 struct s21 f21(void) {}

 // PCS: define { float, float } @f22()
 // PCS: define { double, double } @f23(
 _Complex float      f22(void) {}
 _Complex double     f23(void) {}

 // PCS: define [1 x i64] @f24()
 struct s24 { _Complex char f0; };
 struct s24 f24() {}

 // PCS: define [1 x i64] @f25()
 struct s25 { _Complex short f0; };
 struct s25 f25() {}

 // PCS: define [1 x i64] @f26()
 struct s26 { _Complex int f0; };
 struct s26 f26() {}

 // PCS: define [2 x i64] @f27()
 struct s27 { _Complex long f0; };
 struct s27 f27() {}

 // PCS-LABEL: define void @f28(i8 %a, i16 %b, i32 %c, i64 %d, float %e, double %f)
 void f28(char a, short b, int c, long d, float e, double f) {}

 // PCS: define void @f29([2 x i64] %a
 struct s29 { int arr[4]; };
 void f29(struct s29 a) {}

 // PCS-LABEL: define void @f30(%struct.s30* %a)
 struct s30 { int arr[4]; char c;};
 void f30(struct s30 a) {}

 // PCS: define void @f31([4 x double] %a
 struct s31 { double arr[4]; };
 void f31(struct s31 a) {}

 // PCS-LABEL: define void @f32(%struct.s32* %a)
 struct s32 { float arr[5]; };
 void f32(struct s32 a) {}

 // Not the only solution, but it *is* an HFA.
 // PCS: define void @f33([3 x float] %a.coerce0, float %a.coerce1)
 struct s33 { float arr[3]; float a; };
 void f33(struct s33 a) {}

 // PCS-LABEL: define void @f34(%struct.s34* noalias sret
 struct s34 { int a[4]; char b };
 struct s34 f34(void) {}

 // PCS-LABEL: define void @f35()
 struct s35 {};
 void f35(struct s35 a) {}

 // Check padding is added:
 // PCS: @f36(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s36* byval align 8 %stacked)
 struct s36 { long a, b; };
 void f36(int x0, int x1, int x2, int x3, int x4, int x5, int x6, struct s36 stacked) {}

 // But only once:
 // PCS: @f37(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s37* byval align 8 %stacked, %struct.s37* byval align 8 %stacked2)
 struct s37 { long a, b; };
 void f37(int x0, int x1, int x2, int x3, int x4, int x5, int x6, struct s37 stacked, struct s37 stacked2) {}

 // Check for HFA padding args. Also, they should not end up on the stack in a
 // way which will have holes in when lowered further by LLVM. In particular [3 x
 // float] would be unacceptable.

 // PCS: @f38(float %s0, double %d1, float %s2, float %s3, float %s4, float %s5, [2 x float], %struct.s38* byval align 4 %stacked)
 struct s38 { float a, b, c; };
 void f38(float s0, double d1, float s2, float s3, float s4, float s5, struct s38 stacked) {}

 // Check both VFP and integer arguments are padded (also that pointers and enums
 // get counted as integer types correctly).
 struct s39_int { long a, b; };
 struct s39_float { float a, b, c, d; };
 enum s39_enum { Val1, Val2 };
 // PCS: @f39(float %s0, i32 %x0, float %s1, i32* %x1, float %s2, i32 %x2, float %s3, float %s4, i32 %x3, [3 x float], %struct.s39_float* byval align 4 %stacked, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s39_int* byval align 8 %stacked2)
 void f39(float s0, int x0, float s1, int *x1, float s2, enum s39_enum x2, float s3, float s4,
          int x3, struct s39_float stacked, int x4, int x5, int x6,
          struct s39_int stacked2) {}

 struct s40 { __int128 a; };
 // PCS: @f40(i32 %x0, [1 x i128] %x2_3.coerce, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s40* byval align 16 %stacked)
 void f40(int x0, struct s40 x2_3, int x4, int x5, int x6, struct s40 stacked) {}

 // Checking: __int128 will get properly aligned type, with padding so big struct doesn't use x7.
 struct s41 { int arr[5]; };
 // PCS: @f41(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], i128* byval align 16, %struct.s41* %stacked2)
 int f41(int x0, int x1, int x2, int x3, int x4, int x5, int x6, __int128 stacked, struct s41 stacked2) {}

 // Checking: __int128 needing to be aligned in registers will consume correct
 // number. Previously padding was inserted before "stacked" because x6_7 was
 // "allocated" to x5 and x6 by clang.
 // PCS: @f42(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i128 %x6_7, i128* byval align 16)
 void f42(int x0, int x1, int x2, int x3, int x4, __int128 x6_7, __int128 stacked) {}

 // Checking: __fp16 is extended to double when calling variadic functions
 void variadic(int a, ...);
 void f43(__fp16 *in) {
   variadic(42, *in);
 // PCS: call void (i32, ...)* @variadic(i32 42, double
 }

 // Checking: `double' and `long double' have different machine types, so cannot both be in an HFA
 struct s44 { long double a; double b; };
 // PCS: define void @f44(%struct.s44*
 struct s44 f44() {}
	// RUN: %clang_cc1 -triple aarch64-none-linux-gnu -emit-llvm -w -o - %s \| FileCheck -check-prefix=PCS %s

	// Sign extension is performed by the callee on AArch64, which means
	// that we shouldn't tag arguments and returns with their extension.

	// PCS-LABEL: define i8 @f0(i16 %a)
	char f0(short a) {
	return a;
	}

	// PCS: define [1 x i64] @f1()
	struct s1 { char f0; };
	struct s1 f1(void) {}

	// PCS: define [1 x i64] @f2()
	struct s2 { short f0; };
	struct s2 f2(void) {}

	// PCS: define [1 x i64] @f3()
	struct s3 { int f0; };
	struct s3 f3(void) {}

	// PCS: define [1 x i64] @f4()
	struct s4 { struct s4_0 { int f0; } f0; };
	struct s4 f4(void) {}

	// PCS: define [1 x i64] @f5()
	struct s5 { struct { } f0; int f1; };
	struct s5 f5(void) {}

	// PCS: define [1 x i64] @f6()
	struct s6 { int f0[1]; };
	struct s6 f6(void) {}

	// PCS-LABEL: define void @f7()
	struct s7 { struct { int : 0; } f0; };
	struct s7 f7(void) {}

	// PCS-LABEL: define void @f8()
	struct s8 { struct { int : 0; } f0[1]; };
	struct s8 f8(void) {}

	// PCS: define [1 x i64] @f9()
	struct s9 { long f0; int : 0; };
	struct s9 f9(void) {}

	// PCS: define [1 x i64] @f10()
	struct s10 { long f0; int : 0; int : 0; };
	struct s10 f10(void) {}

	// PCS: define [1 x i64] @f11()
	struct s11 { int : 0; long f0; };
	struct s11 f11(void) {}

	// PCS: define [1 x i64] @f12()
	union u12 { char f0; short f1; int f2; long f3; };
	union u12 f12(void) {}

	// PCS-LABEL: define %struct.s13 @f13()
	struct s13 { float f0; };
	struct s13 f13(void) {}

	// PCS-LABEL: define %union.u14 @f14()
	union u14 { float f0; };
	union u14 f14(void) {}

	// PCS-LABEL: define void @f15()
	void f15(struct s7 a0) {}

	// PCS-LABEL: define void @f16()
	void f16(struct s8 a0) {}

	// PCS: define [1 x i64] @f17()
	struct s17 { short f0 : 13; char f1 : 4; };
	struct s17 f17(void) {}

	// PCS: define [1 x i64] @f18()
	struct s18 { short f0; char f1 : 4; };
	struct s18 f18(void) {}

	// PCS: define [1 x i64] @f19()
	struct s19 { long f0; struct s8 f1; };
	struct s19 f19(void) {}

	// PCS: define [1 x i64] @f20()
	struct s20 { struct s8 f1; long f0; };
	struct s20 f20(void) {}

	// PCS: define [1 x i64] @f21()
	struct s21 { struct {} f1; long f0 : 4; };
	struct s21 f21(void) {}

	// PCS: define { float, float } @f22()
	// PCS: define { double, double } @f23(
	_Complex float f22(void) {}
	_Complex double f23(void) {}

	// PCS: define [1 x i64] @f24()
	struct s24 { _Complex char f0; };
	struct s24 f24() {}

	// PCS: define [1 x i64] @f25()
	struct s25 { _Complex short f0; };
	struct s25 f25() {}

	// PCS: define [1 x i64] @f26()
	struct s26 { _Complex int f0; };
	struct s26 f26() {}

	// PCS: define [2 x i64] @f27()
	struct s27 { _Complex long f0; };
	struct s27 f27() {}

	// PCS-LABEL: define void @f28(i8 %a, i16 %b, i32 %c, i64 %d, float %e, double %f)
	void f28(char a, short b, int c, long d, float e, double f) {}

	// PCS: define void @f29([2 x i64] %a
	struct s29 { int arr[4]; };
	void f29(struct s29 a) {}

	// PCS-LABEL: define void @f30(%struct.s30* %a)
	struct s30 { int arr[4]; char c;};
	void f30(struct s30 a) {}

	// PCS: define void @f31([4 x double] %a
	struct s31 { double arr[4]; };
	void f31(struct s31 a) {}

	// PCS-LABEL: define void @f32(%struct.s32* %a)
	struct s32 { float arr[5]; };
	void f32(struct s32 a) {}

	// Not the only solution, but it is an HFA.
	// PCS: define void @f33([3 x float] %a.coerce0, float %a.coerce1)
	struct s33 { float arr[3]; float a; };
	void f33(struct s33 a) {}

	// PCS-LABEL: define void @f34(%struct.s34* noalias sret
	struct s34 { int a[4]; char b };
	struct s34 f34(void) {}

	// PCS-LABEL: define void @f35()
	struct s35 {};
	void f35(struct s35 a) {}

	// Check padding is added:
	// PCS: @f36(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s36* byval align 8 %stacked)
	struct s36 { long a, b; };
	void f36(int x0, int x1, int x2, int x3, int x4, int x5, int x6, struct s36 stacked) {}

	// But only once:
	// PCS: @f37(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s37* byval align 8 %stacked, %struct.s37* byval align 8 %stacked2)
	struct s37 { long a, b; };
	void f37(int x0, int x1, int x2, int x3, int x4, int x5, int x6, struct s37 stacked, struct s37 stacked2) {}

	// Check for HFA padding args. Also, they should not end up on the stack in a
	// way which will have holes in when lowered further by LLVM. In particular [3 x
	// float] would be unacceptable.

	// PCS: @f38(float %s0, double %d1, float %s2, float %s3, float %s4, float %s5, [2 x float], %struct.s38* byval align 4 %stacked)
	struct s38 { float a, b, c; };
	void f38(float s0, double d1, float s2, float s3, float s4, float s5, struct s38 stacked) {}

	// Check both VFP and integer arguments are padded (also that pointers and enums
	// get counted as integer types correctly).
	struct s39_int { long a, b; };
	struct s39_float { float a, b, c, d; };
	enum s39_enum { Val1, Val2 };
	// PCS: @f39(float %s0, i32 %x0, float %s1, i32* %x1, float %s2, i32 %x2, float %s3, float %s4, i32 %x3, [3 x float], %struct.s39_float* byval align 4 %stacked, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s39_int* byval align 8 %stacked2)
	void f39(float s0, int x0, float s1, int *x1, float s2, enum s39_enum x2, float s3, float s4,
	int x3, struct s39_float stacked, int x4, int x5, int x6,
	struct s39_int stacked2) {}

	struct s40 { __int128 a; };
	// PCS: @f40(i32 %x0, [1 x i128] %x2_3.coerce, i32 %x4, i32 %x5, i32 %x6, [1 x i64], %struct.s40* byval align 16 %stacked)
	void f40(int x0, struct s40 x2_3, int x4, int x5, int x6, struct s40 stacked) {}

	// Checking: __int128 will get properly aligned type, with padding so big struct doesn't use x7.
	struct s41 { int arr[5]; };
	// PCS: @f41(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i32 %x5, i32 %x6, [1 x i64], i128* byval align 16, %struct.s41* %stacked2)
	int f41(int x0, int x1, int x2, int x3, int x4, int x5, int x6, __int128 stacked, struct s41 stacked2) {}

	// Checking: __int128 needing to be aligned in registers will consume correct
	// number. Previously padding was inserted before "stacked" because x6_7 was
	// "allocated" to x5 and x6 by clang.
	// PCS: @f42(i32 %x0, i32 %x1, i32 %x2, i32 %x3, i32 %x4, i128 %x6_7, i128* byval align 16)
	void f42(int x0, int x1, int x2, int x3, int x4, __int128 x6_7, __int128 stacked) {}

	// Checking: __fp16 is extended to double when calling variadic functions
	void variadic(int a, ...);
	void f43(__fp16 *in) {
	variadic(42, *in);
	// PCS: call void (i32, ...)* @variadic(i32 42, double
	}

	// Checking: `double' and `long double' have different machine types, so cannot both be in an HFA
	struct s44 { long double a; double b; };
	// PCS: define void @f44(%struct.s44*
	struct s44 f44() {}