llvm/test/CodeGen/AArch64/inlineasm-X-constraint.ll - toolchain/llvm-project - Gitiles

 ; RUN: llc -mtriple=aarch64-none-linux-gnu < %s -o - | FileCheck %s

 ; The following functions test the use case where an X constraint is used to
 ; add a dependency between an assembly instruction (vmsr in this case) and
 ; another instruction. In each function, we use a different type for the
 ; X constraint argument.
 ;
 ; We can something similar from the following C code:
 ; double f1(double f, int pscr_value) {
 ;   asm volatile("msr fpsr,%1" : "=X" ((f)): "r" (pscr_value));
 ;   return f+f;
 ; }

 ; CHECK-LABEL: f1
 ; CHECK: msr FPSR
 ; CHECK: fadd d

 define  double @f1(double %f, i32 %pscr_value) {
 entry:
   %f.addr = alloca double, align 8
   store double %f, double* %f.addr, align 8
   call void asm sideeffect "msr fpsr,$1", "=*X,r"(double* nonnull %f.addr, i32 %pscr_value) nounwind
   %0 = load double, double* %f.addr, align 8
   %add = fadd double %0, %0
   ret double %add
 }

 ; int f2(int f, int pscr_value) {
 ;   asm volatile("msr fpsr,$1" : "=X" ((f)): "r" (pscr_value));
 ;   return f*f;
 ; }

 ; CHECK-LABEL: f2
 ; CHECK: msr FPSR
 ; CHECK: mul
 define  i32 @f2(i32 %f, i32 %pscr_value) {
 entry:
   %f.addr = alloca i32, align 4
   store i32 %f, i32* %f.addr, align 4
   call void asm sideeffect "msr fpsr,$1", "=*X,r"(i32* nonnull %f.addr, i32 %pscr_value) nounwind
   %0 = load i32, i32* %f.addr, align 4
   %mul = mul i32 %0, %0
   ret i32 %mul
 }

 ; typedef signed char int8_t;
 ; typedef __attribute__((neon_vector_type(8))) int8_t int8x8_t;
 ; void f3 (void)
 ; {
 ;   int8x8_t vector_res_int8x8;
 ;   unsigned int fpscr;
 ;   asm volatile ("msr fpsr,$1" : "=X" ((vector_res_int8x8)) : "r" (fpscr));
 ;   return vector_res_int8x8 * vector_res_int8x8;
 ; }

 ; CHECK-LABEL: f3
 ; CHECK: msr FPSR
 ; CHECK: mul
 define  <8 x i8> @f3() {
 entry:
   %vector_res_int8x8 = alloca <8 x i8>, align 8
   %0 = getelementptr inbounds <8 x i8>, <8 x i8>* %vector_res_int8x8, i32 0, i32 0
   call void asm sideeffect "msr fpsr,$1", "=*X,r"(<8 x i8>* nonnull %vector_res_int8x8, i32 undef) nounwind
   %1 = load <8 x i8>, <8 x i8>* %vector_res_int8x8, align 8
   %mul = mul <8 x i8> %1, %1
   ret <8 x i8> %mul
 }

 ; We can emit integer constants.
 ; We can get this from:
 ; void f() {
 ;   int x = 2;
 ;   asm volatile ("add x0, x0, %0" : : "X" (x));
 ; }
 ;
 ; CHECK-LABEL: f4
 ; CHECK: add x0, x0, #2
 define void @f4() {
 entry:
   tail call void asm sideeffect "add x0, x0, $0", "X"(i32 2)
   ret void
 }

 ; We can emit function labels. This is equivalent to the following C code:
 ; void f(void) {
 ;   void (*x)(void) = &foo;
 ;   asm volatile ("bl %0" : : "X" (x));
 ; }
 ; CHECK-LABEL: f5
 ; CHECK: bl f4
 define void @f5() {
 entry:
   tail call void asm sideeffect "bl $0", "X"(void ()* nonnull @f4)
   ret void
 }

 declare void @foo(...)

 ; This tests the behavior of the X constraint when used on functions pointers,
 ; or functions with a cast. In the first asm call we figure out that this
 ; is a function pointer and emit the label. However, in the second asm call
 ; we can't see through the bitcast and we end up having to lower this constraint
 ; to something else. This is not ideal, but it is a correct behaviour according
 ; to the definition of the X constraint.
 ;
 ; In this case (and other cases where we could have emitted something else),
 ; what we're doing with the X constraint is not particularly useful either,
 ; since the user could have used "r" in this situation for the same effect.

 ; CHECK-LABEL: f6
 ; CHECK: bl foo
 ; CHECK: br x

 define void @f6() nounwind {
 entry:
   tail call void asm sideeffect "bl $0", "X"(void (...)* @foo) nounwind
   tail call void asm sideeffect "br $0", "X"(void (...)* bitcast (void ()* @f4 to void (...)*)) nounwind
   ret void
 }

 ; The following IR can be generated from C code with a function like:
 ; void a() {
 ;   void* a = &&A;
 ;   asm volatile ("bl %0" : : "X" (a));
 ;  A:
 ;   return;
 ; }
 ;
 ; Ideally this would give the block address of bb, but it requires us to see
 ; through blockaddress, which we can't do at the moment. This might break some
 ; existing use cases where a user would expect to get a block label and instead
 ; gets the block address in a register. However, note that according to the
 ; "no constraints" definition this behaviour is correct (although not very nice).

 ; CHECK-LABEL: f7
 ; CHECK: bl
 define void @f7() {
   call void asm sideeffect "br $0", "X"( i8* blockaddress(@f7, %bb) )
   br label %bb
 bb:
   ret void
 }

 ; If we use a constraint "=*X", we should get a store back to *%x (in x0).
 ; CHECK-LABEL: f8
 ; CHECK: add	 [[Dest:x[0-9]+]], x0, x0
 ; CHECK: str	[[Dest]], [x0]
 define void @f8(i64 *%x) {
 entry:
   tail call void asm sideeffect "add $0, x0, x0", "=*X"(i64 *%x)
   ret void
 }
	; RUN: llc -mtriple=aarch64-none-linux-gnu < %s -o - \| FileCheck %s

	; The following functions test the use case where an X constraint is used to
	; add a dependency between an assembly instruction (vmsr in this case) and
	; another instruction. In each function, we use a different type for the
	; X constraint argument.
	;
	; We can something similar from the following C code:
	; double f1(double f, int pscr_value) {
	; asm volatile("msr fpsr,%1" : "=X" ((f)): "r" (pscr_value));
	; return f+f;
	; }

	; CHECK-LABEL: f1
	; CHECK: msr FPSR
	; CHECK: fadd d

	define double @f1(double %f, i32 %pscr_value) {
	entry:
	%f.addr = alloca double, align 8
	store double %f, double* %f.addr, align 8
	call void asm sideeffect "msr fpsr,$1", "=X,r"(double nonnull %f.addr, i32 %pscr_value) nounwind
	%0 = load double, double* %f.addr, align 8
	%add = fadd double %0, %0
	ret double %add
	}

	; int f2(int f, int pscr_value) {
	; asm volatile("msr fpsr,$1" : "=X" ((f)): "r" (pscr_value));
	; return f*f;
	; }

	; CHECK-LABEL: f2
	; CHECK: msr FPSR
	; CHECK: mul
	define i32 @f2(i32 %f, i32 %pscr_value) {
	entry:
	%f.addr = alloca i32, align 4
	store i32 %f, i32* %f.addr, align 4
	call void asm sideeffect "msr fpsr,$1", "=X,r"(i32 nonnull %f.addr, i32 %pscr_value) nounwind
	%0 = load i32, i32* %f.addr, align 4
	%mul = mul i32 %0, %0
	ret i32 %mul
	}

	; typedef signed char int8_t;
	; typedef __attribute__((neon_vector_type(8))) int8_t int8x8_t;
	; void f3 (void)
	; {
	; int8x8_t vector_res_int8x8;
	; unsigned int fpscr;
	; asm volatile ("msr fpsr,$1" : "=X" ((vector_res_int8x8)) : "r" (fpscr));
	; return vector_res_int8x8 * vector_res_int8x8;
	; }

	; CHECK-LABEL: f3
	; CHECK: msr FPSR
	; CHECK: mul
	define <8 x i8> @f3() {
	entry:
	%vector_res_int8x8 = alloca <8 x i8>, align 8
	%0 = getelementptr inbounds <8 x i8>, <8 x i8>* %vector_res_int8x8, i32 0, i32 0
	call void asm sideeffect "msr fpsr,$1", "=X,r"(<8 x i8> nonnull %vector_res_int8x8, i32 undef) nounwind
	%1 = load <8 x i8>, <8 x i8>* %vector_res_int8x8, align 8
	%mul = mul <8 x i8> %1, %1
	ret <8 x i8> %mul
	}

	; We can emit integer constants.
	; We can get this from:
	; void f() {
	; int x = 2;
	; asm volatile ("add x0, x0, %0" : : "X" (x));
	; }
	;
	; CHECK-LABEL: f4
	; CHECK: add x0, x0, #2
	define void @f4() {
	entry:
	tail call void asm sideeffect "add x0, x0, $0", "X"(i32 2)
	ret void
	}

	; We can emit function labels. This is equivalent to the following C code:
	; void f(void) {
	; void (*x)(void) = &foo;
	; asm volatile ("bl %0" : : "X" (x));
	; }
	; CHECK-LABEL: f5
	; CHECK: bl f4
	define void @f5() {
	entry:
	tail call void asm sideeffect "bl $0", "X"(void ()* nonnull @f4)
	ret void
	}

	declare void @foo(...)

	; This tests the behavior of the X constraint when used on functions pointers,
	; or functions with a cast. In the first asm call we figure out that this
	; is a function pointer and emit the label. However, in the second asm call
	; we can't see through the bitcast and we end up having to lower this constraint
	; to something else. This is not ideal, but it is a correct behaviour according
	; to the definition of the X constraint.
	;
	; In this case (and other cases where we could have emitted something else),
	; what we're doing with the X constraint is not particularly useful either,
	; since the user could have used "r" in this situation for the same effect.

	; CHECK-LABEL: f6
	; CHECK: bl foo
	; CHECK: br x

	define void @f6() nounwind {
	entry:
	tail call void asm sideeffect "bl $0", "X"(void (...)* @foo) nounwind
	tail call void asm sideeffect "br $0", "X"(void (...)* bitcast (void ()* @f4 to void (...)*)) nounwind
	ret void
	}

	; The following IR can be generated from C code with a function like:
	; void a() {
	; void* a = &&A;
	; asm volatile ("bl %0" : : "X" (a));
	; A:
	; return;
	; }
	;
	; Ideally this would give the block address of bb, but it requires us to see
	; through blockaddress, which we can't do at the moment. This might break some
	; existing use cases where a user would expect to get a block label and instead
	; gets the block address in a register. However, note that according to the
	; "no constraints" definition this behaviour is correct (although not very nice).

	; CHECK-LABEL: f7
	; CHECK: bl
	define void @f7() {
	call void asm sideeffect "br $0", "X"( i8* blockaddress(@f7, %bb) )
	br label %bb
	bb:
	ret void
	}

	; If we use a constraint "=X", we should get a store back to %x (in x0).
	; CHECK-LABEL: f8
	; CHECK: add [[Dest:x[0-9]+]], x0, x0
	; CHECK: str [[Dest]], [x0]
	define void @f8(i64 *%x) {
	entry:
	tail call void asm sideeffect "add $0, x0, x0", "=X"(i64 %x)
	ret void
	}