mlir/test/Target/LLVMIR/import.ll - llvm-project - Git at Google

 ; RUN: mlir-translate -import-llvm %s | FileCheck %s

 %struct.t = type {}
 %struct.s = type { %struct.t, i64 }

 ; CHECK: llvm.mlir.global external @g1() {alignment = 8 : i64} : !llvm.struct<"struct.s", (struct<"struct.t", ()>, i64)>
 @g1 = external global %struct.s, align 8
 ; CHECK: llvm.mlir.global external @g2() {alignment = 8 : i64} : f64
 @g2 = external global double, align 8
 ; CHECK: llvm.mlir.global internal @g3("string")
 @g3 = internal global [6 x i8] c"string"

 ; CHECK: llvm.mlir.global external @g5() : vector<8xi32>
 @g5 = external global <8 x i32>

 ; CHECK: llvm.mlir.global private @alig32(42 : i64) {alignment = 32 : i64} : i64
 @alig32 = private global i64 42, align 32

 ; CHECK: llvm.mlir.global private @alig64(42 : i64) {alignment = 64 : i64} : i64
 @alig64 = private global i64 42, align 64

 @g4 = external global i32, align 8
 ; CHECK: llvm.mlir.global internal constant @int_gep() : !llvm.ptr<i32> {
 ; CHECK-DAG:   %[[addr:[0-9]+]] = llvm.mlir.addressof @g4 : !llvm.ptr<i32>
 ; CHECK-DAG:   %[[c2:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
 ; CHECK-NEXT:  %[[gepinit:[0-9]+]] = llvm.getelementptr %[[addr]][%[[c2]]] : (!llvm.ptr<i32>, i32) -> !llvm.ptr<i32>
 ; CHECK-NEXT:  llvm.return %[[gepinit]] : !llvm.ptr<i32>
 ; CHECK-NEXT: }
 @int_gep = internal constant i32* getelementptr (i32, i32* @g4, i32 2)

 ;
 ; Linkage attribute.
 ;

 ; CHECK: llvm.mlir.global private @private(42 : i32) : i32
 @private = private global i32 42
 ; CHECK: llvm.mlir.global internal @internal(42 : i32) : i32
 @internal = internal global i32 42
 ; CHECK: llvm.mlir.global available_externally @available_externally(42 : i32) : i32
 @available_externally = available_externally global i32 42
 ; CHECK: llvm.mlir.global linkonce @linkonce(42 : i32) : i32
 @linkonce = linkonce global i32 42
 ; CHECK: llvm.mlir.global weak @weak(42 : i32) : i32
 @weak = weak global i32 42
 ; CHECK: llvm.mlir.global common @common(0 : i32) : i32
 @common = common global i32 zeroinitializer
 ; CHECK: llvm.mlir.global appending @appending(dense<[0, 1]> : tensor<2xi32>) : !llvm.array<2 x i32>
 @appending = appending global [2 x i32] [i32 0, i32 1]
 ; CHECK: llvm.mlir.global extern_weak @extern_weak() : i32
 @extern_weak = extern_weak global i32
 ; CHECK: llvm.mlir.global linkonce_odr @linkonce_odr(42 : i32) : i32
 @linkonce_odr = linkonce_odr global i32 42
 ; CHECK: llvm.mlir.global weak_odr @weak_odr(42 : i32) : i32
 @weak_odr = weak_odr global i32 42
 ; CHECK: llvm.mlir.global external @external() : i32
 @external = external global i32

 ;
 ; UnnamedAddr attribute.
 ;


 ; CHECK: llvm.mlir.global private constant @no_unnamed_addr(42 : i64) : i64
 @no_unnamed_addr = private constant i64 42
 ; CHECK: llvm.mlir.global private local_unnamed_addr constant @local_unnamed_addr(42 : i64) : i64
 @local_unnamed_addr = private local_unnamed_addr constant i64 42
 ; CHECK: llvm.mlir.global private unnamed_addr constant @unnamed_addr(42 : i64) : i64
 @unnamed_addr = private unnamed_addr constant i64 42

 ;
 ; Section attribute
 ;

 ; CHECK: llvm.mlir.global internal constant @sectionvar("teststring")  {section = ".mysection"}
 @sectionvar = internal constant [10 x i8] c"teststring", section ".mysection"

 ;
 ; Sequential constants.
 ;

 ; CHECK: llvm.mlir.global internal constant @vector_constant(dense<[1, 2]> : vector<2xi32>) : vector<2xi32>
 @vector_constant = internal constant <2 x i32> <i32 1, i32 2>
 ; CHECK: llvm.mlir.global internal constant @array_constant(dense<[1.000000e+00, 2.000000e+00]> : tensor<2xf32>) : !llvm.array<2 x f32>
 @array_constant = internal constant [2 x float] [float 1., float 2.]
 ; CHECK: llvm.mlir.global internal constant @nested_array_constant(dense<[{{\[}}1, 2], [3, 4]]> : tensor<2x2xi32>) : !llvm.array<2 x array<2 x i32>>
 @nested_array_constant = internal constant [2 x [2 x i32]] [[2 x i32] [i32 1, i32 2], [2 x i32] [i32 3, i32 4]]
 ; CHECK: llvm.mlir.global internal constant @nested_array_constant3(dense<[{{\[}}[1, 2], [3, 4]]]> : tensor<1x2x2xi32>) : !llvm.array<1 x array<2 x array<2 x i32>>>
 @nested_array_constant3 = internal constant [1 x [2 x [2 x i32]]] [[2 x [2 x i32]] [[2 x i32] [i32 1, i32 2], [2 x i32] [i32 3, i32 4]]]
 ; CHECK: llvm.mlir.global internal constant @nested_array_vector(dense<[{{\[}}[1, 2], [3, 4]]]> : vector<1x2x2xi32>) : !llvm.array<1 x array<2 x vector<2xi32>>>
 @nested_array_vector = internal constant [1 x [2 x <2 x i32>]] [[2 x <2 x i32>] [<2 x i32> <i32 1, i32 2>, <2 x i32> <i32 3, i32 4>]]

 ;
 ; Linkage on functions.
 ;

 ; CHECK: llvm.func internal @func_internal
 define internal void @func_internal() {
   ret void
 }

 ; CHECK: llvm.func @fe(i32) -> f32
 declare float @fe(i32)

 ; FIXME: function attributes.
 ; CHECK-LABEL: llvm.func internal @f1(%arg0: i64) -> i32 {
 ; CHECK-DAG: %[[c2:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
 ; CHECK-DAG: %[[c42:[0-9]+]] = llvm.mlir.constant(42 : i32) : i32
 ; CHECK-DAG: %[[c1:[0-9]+]] = llvm.mlir.constant(true) : i1
 ; CHECK-DAG: %[[c43:[0-9]+]] = llvm.mlir.constant(43 : i32) : i32
 define internal dso_local i32 @f1(i64 %a) norecurse {
 entry:
 ; CHECK: %{{[0-9]+}} = llvm.inttoptr %arg0 : i64 to !llvm.ptr<i64>
   %aa = inttoptr i64 %a to i64*
 ; %[[addrof:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
 ; %[[addrof2:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
 ; %{{[0-9]+}} = llvm.inttoptr %arg0 : i64 to !llvm.ptr<i64>
 ; %{{[0-9]+}} = llvm.ptrtoint %[[addrof2]] : !llvm.ptr<f64> to i64
 ; %{{[0-9]+}} = llvm.getelementptr %[[addrof]][%3] : (!llvm.ptr<f64>, i32) -> !llvm.ptr<f64>
   %bb = ptrtoint double* @g2 to i64
   %cc = getelementptr double, double* @g2, i32 2
 ; CHECK: %[[b:[0-9]+]] = llvm.trunc %arg0 : i64 to i32
   %b = trunc i64 %a to i32
 ; CHECK: %[[c:[0-9]+]] = llvm.call @fe(%[[b]]) : (i32) -> f32
   %c = call float @fe(i32 %b)
 ; CHECK: %[[d:[0-9]+]] = llvm.fptosi %[[c]] : f32 to i32
   %d = fptosi float %c to i32
 ; FIXME: icmp should return i1.
 ; CHECK: %[[e:[0-9]+]] = llvm.icmp "ne" %[[d]], %[[c2]] : i32
   %e = icmp ne i32 %d, 2
 ; CHECK: llvm.cond_br %[[e]], ^bb1, ^bb2
   br i1 %e, label %if.then, label %if.end

 ; CHECK: ^bb1:
 if.then:
 ; CHECK: llvm.return %[[c42]] : i32
   ret i32 42

 ; CHECK: ^bb2:
 if.end:
 ; CHECK: %[[orcond:[0-9]+]] = llvm.or %[[e]], %[[c1]] : i1
   %or.cond = or i1 %e, 1
 ; CHECK: llvm.return %[[c43]]
   ret i32 43
 }

 ; Test that instructions that dominate can be out of sequential order.
 ; CHECK-LABEL: llvm.func @f2(%arg0: i64) -> i64 {
 ; CHECK-DAG: %[[c3:[0-9]+]] = llvm.mlir.constant(3 : i64) : i64
 define i64 @f2(i64 %a) noduplicate {
 entry:
 ; CHECK: llvm.br ^bb2
   br label %next

 ; CHECK: ^bb1:
 end:
 ; CHECK: llvm.return %1
   ret i64 %b

 ; CHECK: ^bb2:
 next:
 ; CHECK: %1 = llvm.add %arg0, %[[c3]] : i64
   %b = add i64 %a, 3
 ; CHECK: llvm.br ^bb1
   br label %end
 }

 ; Test arguments/phis.
 ; CHECK-LABEL: llvm.func @f2_phis(%arg0: i64) -> i64 {
 ; CHECK-DAG: %[[c3:[0-9]+]] = llvm.mlir.constant(3 : i64) : i64
 define i64 @f2_phis(i64 %a) noduplicate {
 entry:
 ; CHECK: llvm.br ^bb2
   br label %next

 ; CHECK: ^bb1(%1: i64):
 end:
   %c = phi i64 [ %b, %next ]
 ; CHECK: llvm.return %1
   ret i64 %c

 ; CHECK: ^bb2:
 next:
 ; CHECK: %2 = llvm.add %arg0, %[[c3]] : i64
   %b = add i64 %a, 3
 ; CHECK: llvm.br ^bb1
   br label %end
 }

 ; CHECK-LABEL: llvm.func @f3() -> !llvm.ptr<i32>
 define i32* @f3() {
 ; CHECK: %[[c:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
 ; CHECK: %[[b:[0-9]+]] = llvm.bitcast %[[c]] : !llvm.ptr<f64> to !llvm.ptr<i32>
 ; CHECK: llvm.return %[[b]] : !llvm.ptr<i32>
   ret i32* bitcast (double* @g2 to i32*)
 }

 ; CHECK-LABEL: llvm.func @f4() -> !llvm.ptr<i32>
 define i32* @f4() {
 ; CHECK: %[[b:[0-9]+]] = llvm.mlir.null : !llvm.ptr<i32>
 ; CHECK: llvm.return %[[b]] : !llvm.ptr<i32>
   ret i32* bitcast (double* null to i32*)
 }

 ; CHECK-LABEL: llvm.func @f5
 define void @f5(i32 %d) {
 ; FIXME: icmp should return i1.
 ; CHECK: = llvm.icmp "eq"
   %1 = icmp eq i32 %d, 2
 ; CHECK: = llvm.icmp "slt"
   %2 = icmp slt i32 %d, 2
 ; CHECK: = llvm.icmp "sle"
   %3 = icmp sle i32 %d, 2
 ; CHECK: = llvm.icmp "sgt"
   %4 = icmp sgt i32 %d, 2
 ; CHECK: = llvm.icmp "sge"
   %5 = icmp sge i32 %d, 2
 ; CHECK: = llvm.icmp "ult"
   %6 = icmp ult i32 %d, 2
 ; CHECK: = llvm.icmp "ule"
   %7 = icmp ule i32 %d, 2
 ; CHECK: = llvm.icmp "ugt"
   %8 = icmp ugt i32 %d, 2
   ret void
 }

 ; CHECK-LABEL: llvm.func @f6(%arg0: !llvm.ptr<func<void (i16)>>)
 define void @f6(void (i16) *%fn) {
 ; CHECK: %[[c:[0-9]+]] = llvm.mlir.constant(0 : i16) : i16
 ; CHECK: llvm.call %arg0(%[[c]])
   call void %fn(i16 0)
   ret void
 }

 ; CHECK-LABEL: llvm.func @FPArithmetic(%arg0: f32, %arg1: f32, %arg2: f64, %arg3: f64)
 define void @FPArithmetic(float %a, float %b, double %c, double %d) {
   ; CHECK: %[[a1:[0-9]+]] = llvm.mlir.constant(3.030000e+01 : f64) : f64
   ; CHECK: %[[a2:[0-9]+]] = llvm.mlir.constant(3.030000e+01 : f32) : f32
   ; CHECK: %[[a3:[0-9]+]] = llvm.fadd %[[a2]], %arg0 : f32
   %1 = fadd float 0x403E4CCCC0000000, %a
   ; CHECK: %[[a4:[0-9]+]] = llvm.fadd %arg0, %arg1 : f32
   %2 = fadd float %a, %b
   ; CHECK: %[[a5:[0-9]+]] = llvm.fadd %[[a1]], %arg2 : f64
   %3 = fadd double 3.030000e+01, %c
   ; CHECK: %[[a6:[0-9]+]] = llvm.fsub %arg0, %arg1 : f32
   %4 = fsub float %a, %b
   ; CHECK: %[[a7:[0-9]+]] = llvm.fsub %arg2, %arg3 : f64
   %5 = fsub double %c, %d
   ; CHECK: %[[a8:[0-9]+]] = llvm.fmul %arg0, %arg1 : f32
   %6 = fmul float %a, %b
   ; CHECK: %[[a9:[0-9]+]] = llvm.fmul %arg2, %arg3 : f64
   %7 = fmul double %c, %d
   ; CHECK: %[[a10:[0-9]+]] = llvm.fdiv %arg0, %arg1 : f32
   %8 = fdiv float %a, %b
   ; CHECK: %[[a12:[0-9]+]] = llvm.fdiv %arg2, %arg3 : f64
   %9 = fdiv double %c, %d
   ; CHECK: %[[a11:[0-9]+]] = llvm.frem %arg0, %arg1 : f32
   %10 = frem float %a, %b
   ; CHECK: %[[a13:[0-9]+]] = llvm.frem %arg2, %arg3 : f64
   %11 = frem double %c, %d
   ret void
 }

 ;
 ; Functions as constants.
 ;

 ; Calling the function that has not been defined yet.
 ; CHECK-LABEL: @precaller
 define i32 @precaller() {
   %1 = alloca i32 ()*
   ; CHECK: %[[func:.*]] = llvm.mlir.addressof @callee : !llvm.ptr<func<i32 ()>>
   ; CHECK: llvm.store %[[func]], %[[loc:.*]]
   store i32 ()* @callee, i32 ()** %1
   ; CHECK: %[[indir:.*]] = llvm.load %[[loc]]
   %2 = load i32 ()*, i32 ()** %1
   ; CHECK: llvm.call %[[indir]]()
   %3 = call i32 %2()
   ret i32 %3
 }

 define i32 @callee() {
   ret i32 42
 }

 ; Calling the function that has been defined.
 ; CHECK-LABEL: @postcaller
 define i32 @postcaller() {
   %1 = alloca i32 ()*
   ; CHECK: %[[func:.*]] = llvm.mlir.addressof @callee : !llvm.ptr<func<i32 ()>>
   ; CHECK: llvm.store %[[func]], %[[loc:.*]]
   store i32 ()* @callee, i32 ()** %1
   ; CHECK: %[[indir:.*]] = llvm.load %[[loc]]
   %2 = load i32 ()*, i32 ()** %1
   ; CHECK: llvm.call %[[indir]]()
   %3 = call i32 %2()
   ret i32 %3
 }

 @_ZTIi = external dso_local constant i8*
 @_ZTIii= external dso_local constant i8**
 declare void @foo(i8*)
 declare i8* @bar(i8*)
 declare i32 @__gxx_personality_v0(...)

 ; CHECK-LABEL: @invokeLandingpad
 define i32 @invokeLandingpad() personality i8* bitcast (i32 (...)* @__gxx_personality_v0 to i8*) {
   ; CHECK: %[[a1:[0-9]+]] = llvm.bitcast %{{[0-9]+}} : !llvm.ptr<ptr<ptr<i8>>> to !llvm.ptr<i8>
   ; CHECK: %[[a3:[0-9]+]] = llvm.alloca %{{[0-9]+}} x i8 : (i32) -> !llvm.ptr<i8>
   %1 = alloca i8
   ; CHECK: llvm.invoke @foo(%[[a3]]) to ^bb2 unwind ^bb1 : (!llvm.ptr<i8>) -> ()
   invoke void @foo(i8* %1) to label %4 unwind label %2

 ; CHECK: ^bb1:
   ; CHECK: %{{[0-9]+}} = llvm.landingpad (catch %{{[0-9]+}} : !llvm.ptr<ptr<i8>>) (catch %[[a1]] : !llvm.ptr<i8>) (filter %{{[0-9]+}} : !llvm.array<1 x i8>) : !llvm.struct<(ptr<i8>, i32)>
   %3 = landingpad { i8*, i32 } catch i8** @_ZTIi catch i8* bitcast (i8*** @_ZTIii to i8*)
   ; FIXME: Change filter to a constant array once they are handled.
   ; Currently, even though it parses this, LLVM module is broken
           filter [1 x i8] [i8 1]
   resume { i8*, i32 } %3

 ; CHECK: ^bb2:
   ; CHECK: llvm.return %{{[0-9]+}} : i32
   ret i32 1

 ; CHECK: ^bb3:
   ; CHECK: %{{[0-9]+}} = llvm.invoke @bar(%[[a3]]) to ^bb2 unwind ^bb1 : (!llvm.ptr<i8>) -> !llvm.ptr<i8>
   %6 = invoke i8* @bar(i8* %1) to label %4 unwind label %2

 ; CHECK: ^bb4:
   ; CHECK: llvm.return %{{[0-9]+}} : i32
   ret i32 0
 }

 ;CHECK-LABEL: @useFreezeOp
 define i32 @useFreezeOp(i32 %x) {
   ;CHECK: %{{[0-9]+}} = llvm.freeze %{{[0-9a-z]+}} : i32
   %1 = freeze i32 %x
   %2 = add i8 10, 10
   ;CHECK: %{{[0-9]+}} = llvm.freeze %{{[0-9]+}} : i8
   %3 = freeze i8 %2
   %poison = add nsw i1 0, undef
   ret i32 0
 }

 ;CHECK-LABEL: @useFenceInst
 define i32 @useFenceInst() {
   ;CHECK: llvm.fence syncscope("agent") seq_cst
   fence syncscope("agent") seq_cst
   ;CHECK: llvm.fence release
   fence release
   ;CHECK: llvm.fence seq_cst
   fence syncscope("") seq_cst
   ret i32 0
 }
	; RUN: mlir-translate -import-llvm %s \| FileCheck %s

	%struct.t = type {}
	%struct.s = type { %struct.t, i64 }

	; CHECK: llvm.mlir.global external @g1() {alignment = 8 : i64} : !llvm.struct<"struct.s", (struct<"struct.t", ()>, i64)>
	@g1 = external global %struct.s, align 8
	; CHECK: llvm.mlir.global external @g2() {alignment = 8 : i64} : f64
	@g2 = external global double, align 8
	; CHECK: llvm.mlir.global internal @g3("string")
	@g3 = internal global [6 x i8] c"string"

	; CHECK: llvm.mlir.global external @g5() : vector<8xi32>
	@g5 = external global <8 x i32>

	; CHECK: llvm.mlir.global private @alig32(42 : i64) {alignment = 32 : i64} : i64
	@alig32 = private global i64 42, align 32

	; CHECK: llvm.mlir.global private @alig64(42 : i64) {alignment = 64 : i64} : i64
	@alig64 = private global i64 42, align 64

	@g4 = external global i32, align 8
	; CHECK: llvm.mlir.global internal constant @int_gep() : !llvm.ptr<i32> {
	; CHECK-DAG: %[[addr:[0-9]+]] = llvm.mlir.addressof @g4 : !llvm.ptr<i32>
	; CHECK-DAG: %[[c2:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
	; CHECK-NEXT: %[[gepinit:[0-9]+]] = llvm.getelementptr %[[addr]][%[[c2]]] : (!llvm.ptr<i32>, i32) -> !llvm.ptr<i32>
	; CHECK-NEXT: llvm.return %[[gepinit]] : !llvm.ptr<i32>
	; CHECK-NEXT: }
	@int_gep = internal constant i32* getelementptr (i32, i32* @g4, i32 2)

	;
	; Linkage attribute.
	;

	; CHECK: llvm.mlir.global private @private(42 : i32) : i32
	@private = private global i32 42
	; CHECK: llvm.mlir.global internal @internal(42 : i32) : i32
	@internal = internal global i32 42
	; CHECK: llvm.mlir.global available_externally @available_externally(42 : i32) : i32
	@available_externally = available_externally global i32 42
	; CHECK: llvm.mlir.global linkonce @linkonce(42 : i32) : i32
	@linkonce = linkonce global i32 42
	; CHECK: llvm.mlir.global weak @weak(42 : i32) : i32
	@weak = weak global i32 42
	; CHECK: llvm.mlir.global common @common(0 : i32) : i32
	@common = common global i32 zeroinitializer
	; CHECK: llvm.mlir.global appending @appending(dense<[0, 1]> : tensor<2xi32>) : !llvm.array<2 x i32>
	@appending = appending global [2 x i32] [i32 0, i32 1]
	; CHECK: llvm.mlir.global extern_weak @extern_weak() : i32
	@extern_weak = extern_weak global i32
	; CHECK: llvm.mlir.global linkonce_odr @linkonce_odr(42 : i32) : i32
	@linkonce_odr = linkonce_odr global i32 42
	; CHECK: llvm.mlir.global weak_odr @weak_odr(42 : i32) : i32
	@weak_odr = weak_odr global i32 42
	; CHECK: llvm.mlir.global external @external() : i32
	@external = external global i32

	;
	; UnnamedAddr attribute.
	;


	; CHECK: llvm.mlir.global private constant @no_unnamed_addr(42 : i64) : i64
	@no_unnamed_addr = private constant i64 42
	; CHECK: llvm.mlir.global private local_unnamed_addr constant @local_unnamed_addr(42 : i64) : i64
	@local_unnamed_addr = private local_unnamed_addr constant i64 42
	; CHECK: llvm.mlir.global private unnamed_addr constant @unnamed_addr(42 : i64) : i64
	@unnamed_addr = private unnamed_addr constant i64 42

	;
	; Section attribute
	;

	; CHECK: llvm.mlir.global internal constant @sectionvar("teststring") {section = ".mysection"}
	@sectionvar = internal constant [10 x i8] c"teststring", section ".mysection"

	;
	; Sequential constants.
	;

	; CHECK: llvm.mlir.global internal constant @vector_constant(dense<[1, 2]> : vector<2xi32>) : vector<2xi32>
	@vector_constant = internal constant <2 x i32> <i32 1, i32 2>
	; CHECK: llvm.mlir.global internal constant @array_constant(dense<[1.000000e+00, 2.000000e+00]> : tensor<2xf32>) : !llvm.array<2 x f32>
	@array_constant = internal constant [2 x float] [float 1., float 2.]
	; CHECK: llvm.mlir.global internal constant @nested_array_constant(dense<[{{\[}}1, 2], [3, 4]]> : tensor<2x2xi32>) : !llvm.array<2 x array<2 x i32>>
	@nested_array_constant = internal constant [2 x [2 x i32]] [[2 x i32] [i32 1, i32 2], [2 x i32] [i32 3, i32 4]]
	; CHECK: llvm.mlir.global internal constant @nested_array_constant3(dense<[{{\[}}[1, 2], [3, 4]]]> : tensor<1x2x2xi32>) : !llvm.array<1 x array<2 x array<2 x i32>>>
	@nested_array_constant3 = internal constant [1 x [2 x [2 x i32]]] [[2 x [2 x i32]] [[2 x i32] [i32 1, i32 2], [2 x i32] [i32 3, i32 4]]]
	; CHECK: llvm.mlir.global internal constant @nested_array_vector(dense<[{{\[}}[1, 2], [3, 4]]]> : vector<1x2x2xi32>) : !llvm.array<1 x array<2 x vector<2xi32>>>
	@nested_array_vector = internal constant [1 x [2 x <2 x i32>]] [[2 x <2 x i32>] [<2 x i32> <i32 1, i32 2>, <2 x i32> <i32 3, i32 4>]]

	;
	; Linkage on functions.
	;

	; CHECK: llvm.func internal @func_internal
	define internal void @func_internal() {
	ret void
	}

	; CHECK: llvm.func @fe(i32) -> f32
	declare float @fe(i32)

	; FIXME: function attributes.
	; CHECK-LABEL: llvm.func internal @f1(%arg0: i64) -> i32 {
	; CHECK-DAG: %[[c2:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
	; CHECK-DAG: %[[c42:[0-9]+]] = llvm.mlir.constant(42 : i32) : i32
	; CHECK-DAG: %[[c1:[0-9]+]] = llvm.mlir.constant(true) : i1
	; CHECK-DAG: %[[c43:[0-9]+]] = llvm.mlir.constant(43 : i32) : i32
	define internal dso_local i32 @f1(i64 %a) norecurse {
	entry:
	; CHECK: %{{[0-9]+}} = llvm.inttoptr %arg0 : i64 to !llvm.ptr<i64>
	%aa = inttoptr i64 %a to i64*
	; %[[addrof:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
	; %[[addrof2:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
	; %{{[0-9]+}} = llvm.inttoptr %arg0 : i64 to !llvm.ptr<i64>
	; %{{[0-9]+}} = llvm.ptrtoint %[[addrof2]] : !llvm.ptr<f64> to i64
	; %{{[0-9]+}} = llvm.getelementptr %[[addrof]][%3] : (!llvm.ptr<f64>, i32) -> !llvm.ptr<f64>
	%bb = ptrtoint double* @g2 to i64
	%cc = getelementptr double, double* @g2, i32 2
	; CHECK: %[[b:[0-9]+]] = llvm.trunc %arg0 : i64 to i32
	%b = trunc i64 %a to i32
	; CHECK: %[[c:[0-9]+]] = llvm.call @fe(%[[b]]) : (i32) -> f32
	%c = call float @fe(i32 %b)
	; CHECK: %[[d:[0-9]+]] = llvm.fptosi %[[c]] : f32 to i32
	%d = fptosi float %c to i32
	; FIXME: icmp should return i1.
	; CHECK: %[[e:[0-9]+]] = llvm.icmp "ne" %[[d]], %[[c2]] : i32
	%e = icmp ne i32 %d, 2
	; CHECK: llvm.cond_br %[[e]], ^bb1, ^bb2
	br i1 %e, label %if.then, label %if.end

	; CHECK: ^bb1:
	if.then:
	; CHECK: llvm.return %[[c42]] : i32
	ret i32 42

	; CHECK: ^bb2:
	if.end:
	; CHECK: %[[orcond:[0-9]+]] = llvm.or %[[e]], %[[c1]] : i1
	%or.cond = or i1 %e, 1
	; CHECK: llvm.return %[[c43]]
	ret i32 43
	}

	; Test that instructions that dominate can be out of sequential order.
	; CHECK-LABEL: llvm.func @f2(%arg0: i64) -> i64 {
	; CHECK-DAG: %[[c3:[0-9]+]] = llvm.mlir.constant(3 : i64) : i64
	define i64 @f2(i64 %a) noduplicate {
	entry:
	; CHECK: llvm.br ^bb2
	br label %next

	; CHECK: ^bb1:
	end:
	; CHECK: llvm.return %1
	ret i64 %b

	; CHECK: ^bb2:
	next:
	; CHECK: %1 = llvm.add %arg0, %[[c3]] : i64
	%b = add i64 %a, 3
	; CHECK: llvm.br ^bb1
	br label %end
	}

	; Test arguments/phis.
	; CHECK-LABEL: llvm.func @f2_phis(%arg0: i64) -> i64 {
	; CHECK-DAG: %[[c3:[0-9]+]] = llvm.mlir.constant(3 : i64) : i64
	define i64 @f2_phis(i64 %a) noduplicate {
	entry:
	; CHECK: llvm.br ^bb2
	br label %next

	; CHECK: ^bb1(%1: i64):
	end:
	%c = phi i64 [ %b, %next ]
	; CHECK: llvm.return %1
	ret i64 %c

	; CHECK: ^bb2:
	next:
	; CHECK: %2 = llvm.add %arg0, %[[c3]] : i64
	%b = add i64 %a, 3
	; CHECK: llvm.br ^bb1
	br label %end
	}

	; CHECK-LABEL: llvm.func @f3() -> !llvm.ptr<i32>
	define i32* @f3() {
	; CHECK: %[[c:[0-9]+]] = llvm.mlir.addressof @g2 : !llvm.ptr<f64>
	; CHECK: %[[b:[0-9]+]] = llvm.bitcast %[[c]] : !llvm.ptr<f64> to !llvm.ptr<i32>
	; CHECK: llvm.return %[[b]] : !llvm.ptr<i32>
	ret i32* bitcast (double* @g2 to i32*)
	}

	; CHECK-LABEL: llvm.func @f4() -> !llvm.ptr<i32>
	define i32* @f4() {
	; CHECK: %[[b:[0-9]+]] = llvm.mlir.null : !llvm.ptr<i32>
	; CHECK: llvm.return %[[b]] : !llvm.ptr<i32>
	ret i32* bitcast (double* null to i32*)
	}

	; CHECK-LABEL: llvm.func @f5
	define void @f5(i32 %d) {
	; FIXME: icmp should return i1.
	; CHECK: = llvm.icmp "eq"
	%1 = icmp eq i32 %d, 2
	; CHECK: = llvm.icmp "slt"
	%2 = icmp slt i32 %d, 2
	; CHECK: = llvm.icmp "sle"
	%3 = icmp sle i32 %d, 2
	; CHECK: = llvm.icmp "sgt"
	%4 = icmp sgt i32 %d, 2
	; CHECK: = llvm.icmp "sge"
	%5 = icmp sge i32 %d, 2
	; CHECK: = llvm.icmp "ult"
	%6 = icmp ult i32 %d, 2
	; CHECK: = llvm.icmp "ule"
	%7 = icmp ule i32 %d, 2
	; CHECK: = llvm.icmp "ugt"
	%8 = icmp ugt i32 %d, 2
	ret void
	}

	; CHECK-LABEL: llvm.func @f6(%arg0: !llvm.ptr<func<void (i16)>>)
	define void @f6(void (i16) *%fn) {
	; CHECK: %[[c:[0-9]+]] = llvm.mlir.constant(0 : i16) : i16
	; CHECK: llvm.call %arg0(%[[c]])
	call void %fn(i16 0)
	ret void
	}

	; CHECK-LABEL: llvm.func @FPArithmetic(%arg0: f32, %arg1: f32, %arg2: f64, %arg3: f64)
	define void @FPArithmetic(float %a, float %b, double %c, double %d) {
	; CHECK: %[[a1:[0-9]+]] = llvm.mlir.constant(3.030000e+01 : f64) : f64
	; CHECK: %[[a2:[0-9]+]] = llvm.mlir.constant(3.030000e+01 : f32) : f32
	; CHECK: %[[a3:[0-9]+]] = llvm.fadd %[[a2]], %arg0 : f32
	%1 = fadd float 0x403E4CCCC0000000, %a
	; CHECK: %[[a4:[0-9]+]] = llvm.fadd %arg0, %arg1 : f32
	%2 = fadd float %a, %b
	; CHECK: %[[a5:[0-9]+]] = llvm.fadd %[[a1]], %arg2 : f64
	%3 = fadd double 3.030000e+01, %c
	; CHECK: %[[a6:[0-9]+]] = llvm.fsub %arg0, %arg1 : f32
	%4 = fsub float %a, %b
	; CHECK: %[[a7:[0-9]+]] = llvm.fsub %arg2, %arg3 : f64
	%5 = fsub double %c, %d
	; CHECK: %[[a8:[0-9]+]] = llvm.fmul %arg0, %arg1 : f32
	%6 = fmul float %a, %b
	; CHECK: %[[a9:[0-9]+]] = llvm.fmul %arg2, %arg3 : f64
	%7 = fmul double %c, %d
	; CHECK: %[[a10:[0-9]+]] = llvm.fdiv %arg0, %arg1 : f32
	%8 = fdiv float %a, %b
	; CHECK: %[[a12:[0-9]+]] = llvm.fdiv %arg2, %arg3 : f64
	%9 = fdiv double %c, %d
	; CHECK: %[[a11:[0-9]+]] = llvm.frem %arg0, %arg1 : f32
	%10 = frem float %a, %b
	; CHECK: %[[a13:[0-9]+]] = llvm.frem %arg2, %arg3 : f64
	%11 = frem double %c, %d
	ret void
	}

	;
	; Functions as constants.
	;

	; Calling the function that has not been defined yet.
	; CHECK-LABEL: @precaller
	define i32 @precaller() {
	%1 = alloca i32 ()*
	; CHECK: %[[func:.*]] = llvm.mlir.addressof @callee : !llvm.ptr<func<i32 ()>>
	; CHECK: llvm.store %[[func]], %[[loc:.*]]
	store i32 ()* @callee, i32 ()** %1
	; CHECK: %[[indir:.*]] = llvm.load %[[loc]]
	%2 = load i32 (), i32 ()* %1
	; CHECK: llvm.call %[[indir]]()
	%3 = call i32 %2()
	ret i32 %3
	}

	define i32 @callee() {
	ret i32 42
	}

	; Calling the function that has been defined.
	; CHECK-LABEL: @postcaller
	define i32 @postcaller() {
	%1 = alloca i32 ()*
	; CHECK: %[[func:.*]] = llvm.mlir.addressof @callee : !llvm.ptr<func<i32 ()>>
	; CHECK: llvm.store %[[func]], %[[loc:.*]]
	store i32 ()* @callee, i32 ()** %1
	; CHECK: %[[indir:.*]] = llvm.load %[[loc]]
	%2 = load i32 (), i32 ()* %1
	; CHECK: llvm.call %[[indir]]()
	%3 = call i32 %2()
	ret i32 %3
	}

	@_ZTIi = external dso_local constant i8*
	@_ZTIii= external dso_local constant i8**
	declare void @foo(i8*)
	declare i8* @bar(i8*)
	declare i32 @__gxx_personality_v0(...)

	; CHECK-LABEL: @invokeLandingpad
	define i32 @invokeLandingpad() personality i8* bitcast (i32 (...)* @__gxx_personality_v0 to i8*) {
	; CHECK: %[[a1:[0-9]+]] = llvm.bitcast %{{[0-9]+}} : !llvm.ptr<ptr<ptr<i8>>> to !llvm.ptr<i8>
	; CHECK: %[[a3:[0-9]+]] = llvm.alloca %{{[0-9]+}} x i8 : (i32) -> !llvm.ptr<i8>
	%1 = alloca i8
	; CHECK: llvm.invoke @foo(%[[a3]]) to ^bb2 unwind ^bb1 : (!llvm.ptr<i8>) -> ()
	invoke void @foo(i8* %1) to label %4 unwind label %2

	; CHECK: ^bb1:
	; CHECK: %{{[0-9]+}} = llvm.landingpad (catch %{{[0-9]+}} : !llvm.ptr<ptr<i8>>) (catch %[[a1]] : !llvm.ptr<i8>) (filter %{{[0-9]+}} : !llvm.array<1 x i8>) : !llvm.struct<(ptr<i8>, i32)>
	%3 = landingpad { i8, i32 } catch i8* @_ZTIi catch i8* bitcast (i8*** @_ZTIii to i8*)
	; FIXME: Change filter to a constant array once they are handled.
	; Currently, even though it parses this, LLVM module is broken
	filter [1 x i8] [i8 1]
	resume { i8*, i32 } %3

	; CHECK: ^bb2:
	; CHECK: llvm.return %{{[0-9]+}} : i32
	ret i32 1

	; CHECK: ^bb3:
	; CHECK: %{{[0-9]+}} = llvm.invoke @bar(%[[a3]]) to ^bb2 unwind ^bb1 : (!llvm.ptr<i8>) -> !llvm.ptr<i8>
	%6 = invoke i8* @bar(i8* %1) to label %4 unwind label %2

	; CHECK: ^bb4:
	; CHECK: llvm.return %{{[0-9]+}} : i32
	ret i32 0
	}

	;CHECK-LABEL: @useFreezeOp
	define i32 @useFreezeOp(i32 %x) {
	;CHECK: %{{[0-9]+}} = llvm.freeze %{{[0-9a-z]+}} : i32
	%1 = freeze i32 %x
	%2 = add i8 10, 10
	;CHECK: %{{[0-9]+}} = llvm.freeze %{{[0-9]+}} : i8
	%3 = freeze i8 %2
	%poison = add nsw i1 0, undef
	ret i32 0
	}

	;CHECK-LABEL: @useFenceInst
	define i32 @useFenceInst() {
	;CHECK: llvm.fence syncscope("agent") seq_cst
	fence syncscope("agent") seq_cst
	;CHECK: llvm.fence release
	fence release
	;CHECK: llvm.fence seq_cst
	fence syncscope("") seq_cst
	ret i32 0
	}