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

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

 ; CHECK-LABEL: @int_constants
 define void @int_constants(i16 %arg0, i32 %arg1, i1 %arg2) {
   ; CHECK:  %[[C0:.+]] = llvm.mlir.constant(42 : i16) : i16
   ; CHECK:  %[[C1:.+]] = llvm.mlir.constant(7 : i32) : i32
   ; CHECK:  %[[C2:.+]] = llvm.mlir.constant(true) : i1

   ; CHECK:  llvm.add %[[C0]], %{{.*}} : i16
   %1 = add i16 42, %arg0
   ; CHECK:  llvm.add %[[C1]], %{{.*}} : i32
   %2 = add i32 7, %arg1
   ; CHECK:  llvm.or %[[C2]], %{{.*}} : i1
   %3 = or i1 1, %arg2
   ret void
 }

 ; // -----

 ; CHECK-LABEL: @float_constants
 define void @float_constants(half %arg0, bfloat %arg1, fp128 %arg2, x86_fp80 %arg3) {
   ; CHECK:  %[[C0:.+]] = llvm.mlir.constant(1.000000e+00 : f16) : f16
   ; CHECK:  %[[C1:.+]] = llvm.mlir.constant(1.000000e+00 : bf16) : bf16
   ; CHECK:  %[[C2:.+]] = llvm.mlir.constant(0.000000e+00 : f128) : f128
   ; CHECK:  %[[C3:.+]] = llvm.mlir.constant(7.000000e+00 : f80) : f80

   ; CHECK:  llvm.fadd %[[C0]], %{{.*}} : f16
   %1 = fadd half 1.0, %arg0
   ; CHECK:  llvm.fadd %[[C1]], %{{.*}} : bf16
   %2 = fadd bfloat 1.0, %arg1
   ; CHECK:  llvm.fadd %[[C2]], %{{.*}} : f128
   %3 = fadd fp128 0xL00000000000000000000000000000000, %arg2
   ; CHECK:  llvm.fadd %[[C3]], %{{.*}} : f80
   %4 = fadd x86_fp80 0xK4001E000000000000000, %arg3
   ret void
 }

 ; // -----

 ; CHECK-LABEL: @undef_constant
 define void @undef_constant(i32 %arg0) {
   ; CHECK:  %[[UNDEF:.+]] = llvm.mlir.undef : i32
   ; CHECK:  llvm.add %[[UNDEF]], %{{.*}} : i32
   %1 = add i32 undef, %arg0
   ret void
 }

 ; // -----

 ; CHECK-LABEL: @poison_constant
 define void @poison_constant(double %arg0) {
   ; CHECK:  %[[POISON:.+]] = llvm.mlir.poison : f64
   ; CHECK:  llvm.fadd %[[POISON]], %{{.*}} : f64
   %1 = fadd double poison, %arg0
   ret void
 }

 ; // -----

 ; CHECK-LABEL: @null_constant
 define ptr @null_constant() {
   ; CHECK:  %[[NULL:[0-9]+]] = llvm.mlir.zero : !llvm.ptr
   ; CHECK:  llvm.return %[[NULL]] : !llvm.ptr
   ret ptr null
 }

 ; // -----

 @global = external global i32, align 8

 ; CHECK-LABEL: @gep_const_expr
 define ptr @gep_const_expr() {
   ; CHECK-DAG:  %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
   ; CHECK-DAG:  %[[IDX:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
   ; CHECK-DAG:  %[[GEP:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX]]] : (!llvm.ptr, i32) -> !llvm.ptr
   ; CHECK-DAG:  llvm.return %[[GEP]] : !llvm.ptr
   ret ptr getelementptr (i32, ptr @global, i32 2)
 }

 ; // -----

 @global = external global i32, align 8

 ; CHECK-LABEL: @const_expr_with_duplicate
 define i64 @const_expr_with_duplicate() {
   ; CHECK-DAG:  %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
   ; CHECK-DAG:  %[[IDX:[0-9]+]] = llvm.mlir.constant(7 : i32) : i32
   ; CHECK-DAG:  %[[GEP:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX]]] : (!llvm.ptr, i32) -> !llvm.ptr
   ; CHECK-DAG:  %[[DUP:[0-9]+]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr to i64

   ; Verify the duplicate sub expression is converted only once.
   ; CHECK-DAG:  %[[SUM:[0-9]+]] = llvm.add %[[DUP]], %[[DUP]] : i64
   ; CHECK-DAG:  llvm.return %[[SUM]] : i64
   ret i64 add (i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64),
                i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64))
 }

 ; // -----

 @global = external global i32, align 8

 ; CHECK-LABEL: @const_expr_with_aggregate()
 define i64 @const_expr_with_aggregate() {
   ; Compute the vector elements.
   ; CHECK-DAG:  %[[VAL1:[0-9]+]] = llvm.mlir.constant(33 : i64) : i64
   ; CHECK-DAG:  %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
   ; CHECK-DAG:  %[[IDX1:[0-9]+]] = llvm.mlir.constant(7 : i32) : i32
   ; CHECK-DAG:  %[[GEP1:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX1]]] : (!llvm.ptr, i32) -> !llvm.ptr
   ; CHECK-DAG:  %[[VAL2:[0-9]+]] = llvm.ptrtoint %[[GEP1]] : !llvm.ptr to i64

   ; Fill the vector.
   ; CHECK-DAG:  %[[VEC1:[0-9]+]] = llvm.mlir.undef : vector<2xi64>
   ; CHECK-DAG:  %[[IDX2:[0-9]+]] = llvm.mlir.constant(0 : i32) : i32
   ; CHECK-DAG:  %[[VEC2:[0-9]+]] = llvm.insertelement %[[VAL1]], %[[VEC1]][%[[IDX2]] : i32] : vector<2xi64>
   ; CHECK-DAG:  %[[IDX3:[0-9]+]] = llvm.mlir.constant(1 : i32) : i32
   ; CHECK-DAG:  %[[VEC3:[0-9]+]] = llvm.insertelement %[[VAL2]], %[[VEC2]][%[[IDX3]] : i32] : vector<2xi64>
   ; CHECK-DAG:  %[[IDX4:[0-9]+]] = llvm.mlir.constant(42 : i32) : i32

   ; Compute the extract index.
   ; CHECK-DAG:  %[[GEP2:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX4]]] : (!llvm.ptr, i32) -> !llvm.ptr
   ; CHECK-DAG:  %[[IDX5:[0-9]+]] = llvm.ptrtoint %[[GEP2]] : !llvm.ptr to i64

   ; Extract the vector element.
   ; CHECK-DAG:  %[[ELEM:[0-9]+]] = llvm.extractelement %[[VEC3]][%[[IDX5]] : i64] : vector<2xi64>
   ; CHECK-DAG:  llvm.return %[[ELEM]] : i64
   ret i64 extractelement (
     <2 x i64> <i64 33, i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64)>,
     i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 42) to i64))
 }

 ; // -----

 ; Verify the function constant import.

 ; Calling a function that has not been defined yet.
 ; CHECK-LABEL: @function_address_before_def
 define i32 @function_address_before_def() {
   %1 = alloca ptr
   ; CHECK:  %[[FUN:.*]] = llvm.mlir.addressof @callee : !llvm.ptr
   ; CHECK:  llvm.store %[[FUN]], %[[PTR:.*]] : !llvm.ptr, !llvm.ptr
   store ptr @callee, ptr %1
   ; CHECK:  %[[INDIR:.*]] = llvm.load %[[PTR]] : !llvm.ptr -> !llvm.ptr
   %2 = load ptr, ptr %1
   ; CHECK:  llvm.call %[[INDIR]]() : !llvm.ptr, () -> i32
   %3 = call i32 %2()
   ret i32 %3
 }

 define i32 @callee() {
   ret i32 42
 }

 ; Calling a function that has been defined.
 ; CHECK-LABEL: @function_address_after_def
 define i32 @function_address_after_def() {
   %1 = alloca ptr
   ; CHECK:  %[[FUN:.*]] = llvm.mlir.addressof @callee : !llvm.ptr
   ; CHECK:  llvm.store %[[FUN]], %[[PTR:.*]] : !llvm.ptr, !llvm.ptr
   store ptr @callee, ptr %1
   ; CHECK:  %[[INDIR:.*]] = llvm.load %[[PTR]] : !llvm.ptr -> !llvm.ptr
   %2 = load ptr, ptr %1
   ; CHECK:  llvm.call %[[INDIR]]() : !llvm.ptr, () -> i32
   %3 = call i32 %2()
   ret i32 %3
 }

 ; // -----

 ; Verify the aggregate constant import.

 ; CHECK-DAG:  %[[C0:.+]] = llvm.mlir.constant(9 : i32) : i32
 ; CHECK-DAG:  %[[C1:.+]] = llvm.mlir.constant(4 : i8) : i8
 ; CHECK-DAG:  %[[C2:.+]] = llvm.mlir.constant(8 : i16) : i16
 ; CHECK-DAG:  %[[C3:.+]] = llvm.mlir.constant(7 : i32) : i32
 ; CHECK-DAG:  %[[ROOT:.+]] = llvm.mlir.undef : !llvm.struct<"simple_agg_type", (i32, i8, i16, i32)>
 ; CHECK-DAG:  %[[CHAIN0:.+]] = llvm.insertvalue %[[C0]], %[[ROOT]][0]
 ; CHECK-DAG:  %[[CHAIN1:.+]] = llvm.insertvalue %[[C1]], %[[CHAIN0]][1]
 ; CHECK-DAG:  %[[CHAIN2:.+]] = llvm.insertvalue %[[C2]], %[[CHAIN1]][2]
 ; CHECK-DAG:  %[[CHAIN3:.+]] = llvm.insertvalue %[[C3]], %[[CHAIN2]][3]
 ; CHECK-DAG:  llvm.return %[[CHAIN3]]
 %simple_agg_type = type {i32, i8, i16, i32}
 @simple_agg = global %simple_agg_type {i32 9, i8 4, i16 8, i32 7}

 ; CHECK-DAG:  %[[C1:.+]] = llvm.mlir.constant(1 : i32) : i32
 ; CHECK-DAG:  %[[C2:.+]] = llvm.mlir.constant(2 : i8) : i8
 ; CHECK-DAG:  %[[C3:.+]] = llvm.mlir.constant(3 : i16) : i16
 ; CHECK-DAG:  %[[C4:.+]] = llvm.mlir.constant(4 : i32) : i32
 ; CHECK-DAG:  %[[NESTED:.+]] = llvm.mlir.undef : !llvm.struct<"simple_agg_type", (i32, i8, i16, i32)>
 ; CHECK-DAG:  %[[CHAIN0:.+]] = llvm.insertvalue %[[C1]], %[[NESTED]][0]
 ; CHECK-DAG:  %[[CHAIN1:.+]] = llvm.insertvalue %[[C2]], %[[CHAIN0]][1]
 ; CHECK-DAG:  %[[CHAIN2:.+]] = llvm.insertvalue %[[C3]], %[[CHAIN1]][2]
 ; CHECK-DAG:  %[[CHAIN3:.+]] = llvm.insertvalue %[[C4]], %[[CHAIN2]][3]
 ; CHECK-DAG:  %[[NULL:.+]] = llvm.mlir.zero : !llvm.ptr
 ; CHECK-DAG:  %[[ROOT:.+]] = llvm.mlir.undef : !llvm.struct<"nested_agg_type", (struct<"simple_agg_type", (i32, i8, i16, i32)>, ptr)>
 ; CHECK-DAG:  %[[CHAIN4:.+]] = llvm.insertvalue %[[CHAIN3]], %[[ROOT]][0]
 ; CHECK-DAG:  %[[CHAIN5:.+]] = llvm.insertvalue %[[NULL]], %[[CHAIN4]][1]
 ; CHECK-DAG:  llvm.return %[[CHAIN5]]
 %nested_agg_type = type {%simple_agg_type, ptr}
 @nested_agg = global %nested_agg_type { %simple_agg_type{i32 1, i8 2, i16 3, i32 4}, ptr null }

 ; CHECK-DAG:  %[[NULL:.+]] = llvm.mlir.zero : !llvm.ptr
 ; CHECK-DAG:  %[[ROOT:.+]] = llvm.mlir.undef : vector<2x!llvm.ptr>
 ; CHECK-DAG:  %[[P0:.+]] = llvm.mlir.constant(0 : i32) : i32
 ; CHECK-DAG:  %[[CHAIN0:.+]] = llvm.insertelement %[[NULL]], %[[ROOT]][%[[P0]] : i32] : vector<2x!llvm.ptr>
 ; CHECK-DAG:  %[[P1:.+]] = llvm.mlir.constant(1 : i32) : i32
 ; CHECK-DAG:  %[[CHAIN1:.+]] = llvm.insertelement %[[NULL]], %[[CHAIN0]][%[[P1]] : i32] : vector<2x!llvm.ptr>
 ; CHECK-DAG:  llvm.return %[[CHAIN1]] : vector<2x!llvm.ptr>
 @vector_agg = global <2 x ptr> <ptr null, ptr null>

 ; // -----

 ; Verfiy the import of subsequent constant expressions with duplicates.

 @global = external global i32, align 8

 ; CHECK-LABEL: @const_exprs_with_duplicate
 define i64 @const_exprs_with_duplicate() {
   ; CHECK: %[[ADDR:.+]] = llvm.mlir.addressof @global : !llvm.ptr
   ; CHECK: llvm.getelementptr %[[ADDR]][%{{.*}}] : (!llvm.ptr, i32) -> !llvm.ptr
   %1 = add i64 1, ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64)

   ; Verify the address value is reused.
   ; CHECK: llvm.getelementptr %[[ADDR]][%{{.*}}] : (!llvm.ptr, i32) -> !llvm.ptr
   %2 = add i64 %1, ptrtoint (ptr getelementptr (i32, ptr @global, i32 42) to i64)
   ret i64 %2
 }

 ; // -----

 ; Verify the import of constant expressions with cyclic dependencies.

 @cyclic = internal constant i64 add (i64 ptrtoint (ptr @cyclic to i64), i64 ptrtoint (ptr @cyclic to i64))

 ; CHECK-LABEL: @cyclic
 ; CHECK:  %[[ADDR:.+]] = llvm.mlir.addressof @cyclic
 ; CHECK:  %[[VAL0:.+]] = llvm.ptrtoint %[[ADDR]]
 ; CHECK:  %[[VAL1:.+]] = llvm.add %[[VAL0]], %[[VAL0]]
 ; CHECK:  llvm.return %[[VAL1]]

 ; // -----

 declare void @extern_func()
 @const = dso_local constant i32 trunc (i64 sub (i64 ptrtoint (ptr dso_local_equivalent @extern_func to i64), i64 ptrtoint (ptr @const to i64)) to i32)

 ; CHECK: llvm.mlir.global external constant @const()
 ; CHECK:   %[[ADDR:.+]] = llvm.mlir.addressof @const : !llvm.ptr
 ; CHECK:   llvm.ptrtoint %[[ADDR]] : !llvm.ptr to i64
 ; CHECK:   llvm.dso_local_equivalent @extern_func : !llvm.ptr

 ; // -----

 declare i32 @extern_func()

 define void @call_extern_func() {
   call noundef i32 dso_local_equivalent @extern_func()
   ret void
 }

 ; CHECK-LABEL: @call_extern_func()
 ; CHECK: %[[DSO_EQ:.+]] = llvm.dso_local_equivalent @extern_func : !llvm.ptr
 ; CHECK: llvm.call %[[DSO_EQ]]() : !llvm.ptr, () -> (i32 {llvm.noundef})

 ; // -----

 define void @aliasee_func() {
   ret void
 }

 @alias_func = alias void (), ptr @aliasee_func
 define void @call_alias_func() {
   call void dso_local_equivalent @alias_func()
   ret void
 }

 ; CHECK-LABEL: @call_alias_func()
 ; CHECK: llvm.dso_local_equivalent @alias_func : !llvm.ptr
	; RUN: mlir-translate -import-llvm -split-input-file %s \| FileCheck %s

	; CHECK-LABEL: @int_constants
	define void @int_constants(i16 %arg0, i32 %arg1, i1 %arg2) {
	; CHECK: %[[C0:.+]] = llvm.mlir.constant(42 : i16) : i16
	; CHECK: %[[C1:.+]] = llvm.mlir.constant(7 : i32) : i32
	; CHECK: %[[C2:.+]] = llvm.mlir.constant(true) : i1

	; CHECK: llvm.add %[[C0]], %{{.*}} : i16
	%1 = add i16 42, %arg0
	; CHECK: llvm.add %[[C1]], %{{.*}} : i32
	%2 = add i32 7, %arg1
	; CHECK: llvm.or %[[C2]], %{{.*}} : i1
	%3 = or i1 1, %arg2
	ret void
	}

	; // -----

	; CHECK-LABEL: @float_constants
	define void @float_constants(half %arg0, bfloat %arg1, fp128 %arg2, x86_fp80 %arg3) {
	; CHECK: %[[C0:.+]] = llvm.mlir.constant(1.000000e+00 : f16) : f16
	; CHECK: %[[C1:.+]] = llvm.mlir.constant(1.000000e+00 : bf16) : bf16
	; CHECK: %[[C2:.+]] = llvm.mlir.constant(0.000000e+00 : f128) : f128
	; CHECK: %[[C3:.+]] = llvm.mlir.constant(7.000000e+00 : f80) : f80

	; CHECK: llvm.fadd %[[C0]], %{{.*}} : f16
	%1 = fadd half 1.0, %arg0
	; CHECK: llvm.fadd %[[C1]], %{{.*}} : bf16
	%2 = fadd bfloat 1.0, %arg1
	; CHECK: llvm.fadd %[[C2]], %{{.*}} : f128
	%3 = fadd fp128 0xL00000000000000000000000000000000, %arg2
	; CHECK: llvm.fadd %[[C3]], %{{.*}} : f80
	%4 = fadd x86_fp80 0xK4001E000000000000000, %arg3
	ret void
	}

	; // -----

	; CHECK-LABEL: @undef_constant
	define void @undef_constant(i32 %arg0) {
	; CHECK: %[[UNDEF:.+]] = llvm.mlir.undef : i32
	; CHECK: llvm.add %[[UNDEF]], %{{.*}} : i32
	%1 = add i32 undef, %arg0
	ret void
	}

	; // -----

	; CHECK-LABEL: @poison_constant
	define void @poison_constant(double %arg0) {
	; CHECK: %[[POISON:.+]] = llvm.mlir.poison : f64
	; CHECK: llvm.fadd %[[POISON]], %{{.*}} : f64
	%1 = fadd double poison, %arg0
	ret void
	}

	; // -----

	; CHECK-LABEL: @null_constant
	define ptr @null_constant() {
	; CHECK: %[[NULL:[0-9]+]] = llvm.mlir.zero : !llvm.ptr
	; CHECK: llvm.return %[[NULL]] : !llvm.ptr
	ret ptr null
	}

	; // -----

	@global = external global i32, align 8

	; CHECK-LABEL: @gep_const_expr
	define ptr @gep_const_expr() {
	; CHECK-DAG: %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
	; CHECK-DAG: %[[IDX:[0-9]+]] = llvm.mlir.constant(2 : i32) : i32
	; CHECK-DAG: %[[GEP:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX]]] : (!llvm.ptr, i32) -> !llvm.ptr
	; CHECK-DAG: llvm.return %[[GEP]] : !llvm.ptr
	ret ptr getelementptr (i32, ptr @global, i32 2)
	}

	; // -----

	@global = external global i32, align 8

	; CHECK-LABEL: @const_expr_with_duplicate
	define i64 @const_expr_with_duplicate() {
	; CHECK-DAG: %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
	; CHECK-DAG: %[[IDX:[0-9]+]] = llvm.mlir.constant(7 : i32) : i32
	; CHECK-DAG: %[[GEP:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX]]] : (!llvm.ptr, i32) -> !llvm.ptr
	; CHECK-DAG: %[[DUP:[0-9]+]] = llvm.ptrtoint %[[GEP]] : !llvm.ptr to i64

	; Verify the duplicate sub expression is converted only once.
	; CHECK-DAG: %[[SUM:[0-9]+]] = llvm.add %[[DUP]], %[[DUP]] : i64
	; CHECK-DAG: llvm.return %[[SUM]] : i64
	ret i64 add (i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64),
	i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64))
	}

	; // -----

	@global = external global i32, align 8

	; CHECK-LABEL: @const_expr_with_aggregate()
	define i64 @const_expr_with_aggregate() {
	; Compute the vector elements.
	; CHECK-DAG: %[[VAL1:[0-9]+]] = llvm.mlir.constant(33 : i64) : i64
	; CHECK-DAG: %[[ADDR:[0-9]+]] = llvm.mlir.addressof @global : !llvm.ptr
	; CHECK-DAG: %[[IDX1:[0-9]+]] = llvm.mlir.constant(7 : i32) : i32
	; CHECK-DAG: %[[GEP1:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX1]]] : (!llvm.ptr, i32) -> !llvm.ptr
	; CHECK-DAG: %[[VAL2:[0-9]+]] = llvm.ptrtoint %[[GEP1]] : !llvm.ptr to i64

	; Fill the vector.
	; CHECK-DAG: %[[VEC1:[0-9]+]] = llvm.mlir.undef : vector<2xi64>
	; CHECK-DAG: %[[IDX2:[0-9]+]] = llvm.mlir.constant(0 : i32) : i32
	; CHECK-DAG: %[[VEC2:[0-9]+]] = llvm.insertelement %[[VAL1]], %[[VEC1]][%[[IDX2]] : i32] : vector<2xi64>
	; CHECK-DAG: %[[IDX3:[0-9]+]] = llvm.mlir.constant(1 : i32) : i32
	; CHECK-DAG: %[[VEC3:[0-9]+]] = llvm.insertelement %[[VAL2]], %[[VEC2]][%[[IDX3]] : i32] : vector<2xi64>
	; CHECK-DAG: %[[IDX4:[0-9]+]] = llvm.mlir.constant(42 : i32) : i32

	; Compute the extract index.
	; CHECK-DAG: %[[GEP2:[0-9]+]] = llvm.getelementptr %[[ADDR]][%[[IDX4]]] : (!llvm.ptr, i32) -> !llvm.ptr
	; CHECK-DAG: %[[IDX5:[0-9]+]] = llvm.ptrtoint %[[GEP2]] : !llvm.ptr to i64

	; Extract the vector element.
	; CHECK-DAG: %[[ELEM:[0-9]+]] = llvm.extractelement %[[VEC3]][%[[IDX5]] : i64] : vector<2xi64>
	; CHECK-DAG: llvm.return %[[ELEM]] : i64
	ret i64 extractelement (
	<2 x i64> <i64 33, i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64)>,
	i64 ptrtoint (ptr getelementptr (i32, ptr @global, i32 42) to i64))
	}

	; // -----

	; Verify the function constant import.

	; Calling a function that has not been defined yet.
	; CHECK-LABEL: @function_address_before_def
	define i32 @function_address_before_def() {
	%1 = alloca ptr
	; CHECK: %[[FUN:.*]] = llvm.mlir.addressof @callee : !llvm.ptr
	; CHECK: llvm.store %[[FUN]], %[[PTR:.*]] : !llvm.ptr, !llvm.ptr
	store ptr @callee, ptr %1
	; CHECK: %[[INDIR:.*]] = llvm.load %[[PTR]] : !llvm.ptr -> !llvm.ptr
	%2 = load ptr, ptr %1
	; CHECK: llvm.call %[[INDIR]]() : !llvm.ptr, () -> i32
	%3 = call i32 %2()
	ret i32 %3
	}

	define i32 @callee() {
	ret i32 42
	}

	; Calling a function that has been defined.
	; CHECK-LABEL: @function_address_after_def
	define i32 @function_address_after_def() {
	%1 = alloca ptr
	; CHECK: %[[FUN:.*]] = llvm.mlir.addressof @callee : !llvm.ptr
	; CHECK: llvm.store %[[FUN]], %[[PTR:.*]] : !llvm.ptr, !llvm.ptr
	store ptr @callee, ptr %1
	; CHECK: %[[INDIR:.*]] = llvm.load %[[PTR]] : !llvm.ptr -> !llvm.ptr
	%2 = load ptr, ptr %1
	; CHECK: llvm.call %[[INDIR]]() : !llvm.ptr, () -> i32
	%3 = call i32 %2()
	ret i32 %3
	}

	; // -----

	; Verify the aggregate constant import.

	; CHECK-DAG: %[[C0:.+]] = llvm.mlir.constant(9 : i32) : i32
	; CHECK-DAG: %[[C1:.+]] = llvm.mlir.constant(4 : i8) : i8
	; CHECK-DAG: %[[C2:.+]] = llvm.mlir.constant(8 : i16) : i16
	; CHECK-DAG: %[[C3:.+]] = llvm.mlir.constant(7 : i32) : i32
	; CHECK-DAG: %[[ROOT:.+]] = llvm.mlir.undef : !llvm.struct<"simple_agg_type", (i32, i8, i16, i32)>
	; CHECK-DAG: %[[CHAIN0:.+]] = llvm.insertvalue %[[C0]], %[[ROOT]][0]
	; CHECK-DAG: %[[CHAIN1:.+]] = llvm.insertvalue %[[C1]], %[[CHAIN0]][1]
	; CHECK-DAG: %[[CHAIN2:.+]] = llvm.insertvalue %[[C2]], %[[CHAIN1]][2]
	; CHECK-DAG: %[[CHAIN3:.+]] = llvm.insertvalue %[[C3]], %[[CHAIN2]][3]
	; CHECK-DAG: llvm.return %[[CHAIN3]]
	%simple_agg_type = type {i32, i8, i16, i32}
	@simple_agg = global %simple_agg_type {i32 9, i8 4, i16 8, i32 7}

	; CHECK-DAG: %[[C1:.+]] = llvm.mlir.constant(1 : i32) : i32
	; CHECK-DAG: %[[C2:.+]] = llvm.mlir.constant(2 : i8) : i8
	; CHECK-DAG: %[[C3:.+]] = llvm.mlir.constant(3 : i16) : i16
	; CHECK-DAG: %[[C4:.+]] = llvm.mlir.constant(4 : i32) : i32
	; CHECK-DAG: %[[NESTED:.+]] = llvm.mlir.undef : !llvm.struct<"simple_agg_type", (i32, i8, i16, i32)>
	; CHECK-DAG: %[[CHAIN0:.+]] = llvm.insertvalue %[[C1]], %[[NESTED]][0]
	; CHECK-DAG: %[[CHAIN1:.+]] = llvm.insertvalue %[[C2]], %[[CHAIN0]][1]
	; CHECK-DAG: %[[CHAIN2:.+]] = llvm.insertvalue %[[C3]], %[[CHAIN1]][2]
	; CHECK-DAG: %[[CHAIN3:.+]] = llvm.insertvalue %[[C4]], %[[CHAIN2]][3]
	; CHECK-DAG: %[[NULL:.+]] = llvm.mlir.zero : !llvm.ptr
	; CHECK-DAG: %[[ROOT:.+]] = llvm.mlir.undef : !llvm.struct<"nested_agg_type", (struct<"simple_agg_type", (i32, i8, i16, i32)>, ptr)>
	; CHECK-DAG: %[[CHAIN4:.+]] = llvm.insertvalue %[[CHAIN3]], %[[ROOT]][0]
	; CHECK-DAG: %[[CHAIN5:.+]] = llvm.insertvalue %[[NULL]], %[[CHAIN4]][1]
	; CHECK-DAG: llvm.return %[[CHAIN5]]
	%nested_agg_type = type {%simple_agg_type, ptr}
	@nested_agg = global %nested_agg_type { %simple_agg_type{i32 1, i8 2, i16 3, i32 4}, ptr null }

	; CHECK-DAG: %[[NULL:.+]] = llvm.mlir.zero : !llvm.ptr
	; CHECK-DAG: %[[ROOT:.+]] = llvm.mlir.undef : vector<2x!llvm.ptr>
	; CHECK-DAG: %[[P0:.+]] = llvm.mlir.constant(0 : i32) : i32
	; CHECK-DAG: %[[CHAIN0:.+]] = llvm.insertelement %[[NULL]], %[[ROOT]][%[[P0]] : i32] : vector<2x!llvm.ptr>
	; CHECK-DAG: %[[P1:.+]] = llvm.mlir.constant(1 : i32) : i32
	; CHECK-DAG: %[[CHAIN1:.+]] = llvm.insertelement %[[NULL]], %[[CHAIN0]][%[[P1]] : i32] : vector<2x!llvm.ptr>
	; CHECK-DAG: llvm.return %[[CHAIN1]] : vector<2x!llvm.ptr>
	@vector_agg = global <2 x ptr> <ptr null, ptr null>

	; // -----

	; Verfiy the import of subsequent constant expressions with duplicates.

	@global = external global i32, align 8

	; CHECK-LABEL: @const_exprs_with_duplicate
	define i64 @const_exprs_with_duplicate() {
	; CHECK: %[[ADDR:.+]] = llvm.mlir.addressof @global : !llvm.ptr
	; CHECK: llvm.getelementptr %[[ADDR]][%{{.*}}] : (!llvm.ptr, i32) -> !llvm.ptr
	%1 = add i64 1, ptrtoint (ptr getelementptr (i32, ptr @global, i32 7) to i64)

	; Verify the address value is reused.
	; CHECK: llvm.getelementptr %[[ADDR]][%{{.*}}] : (!llvm.ptr, i32) -> !llvm.ptr
	%2 = add i64 %1, ptrtoint (ptr getelementptr (i32, ptr @global, i32 42) to i64)
	ret i64 %2
	}

	; // -----

	; Verify the import of constant expressions with cyclic dependencies.

	@cyclic = internal constant i64 add (i64 ptrtoint (ptr @cyclic to i64), i64 ptrtoint (ptr @cyclic to i64))

	; CHECK-LABEL: @cyclic
	; CHECK: %[[ADDR:.+]] = llvm.mlir.addressof @cyclic
	; CHECK: %[[VAL0:.+]] = llvm.ptrtoint %[[ADDR]]
	; CHECK: %[[VAL1:.+]] = llvm.add %[[VAL0]], %[[VAL0]]
	; CHECK: llvm.return %[[VAL1]]

	; // -----

	declare void @extern_func()
	@const = dso_local constant i32 trunc (i64 sub (i64 ptrtoint (ptr dso_local_equivalent @extern_func to i64), i64 ptrtoint (ptr @const to i64)) to i32)

	; CHECK: llvm.mlir.global external constant @const()
	; CHECK: %[[ADDR:.+]] = llvm.mlir.addressof @const : !llvm.ptr
	; CHECK: llvm.ptrtoint %[[ADDR]] : !llvm.ptr to i64
	; CHECK: llvm.dso_local_equivalent @extern_func : !llvm.ptr

	; // -----

	declare i32 @extern_func()

	define void @call_extern_func() {
	call noundef i32 dso_local_equivalent @extern_func()
	ret void
	}

	; CHECK-LABEL: @call_extern_func()
	; CHECK: %[[DSO_EQ:.+]] = llvm.dso_local_equivalent @extern_func : !llvm.ptr
	; CHECK: llvm.call %[[DSO_EQ]]() : !llvm.ptr, () -> (i32 {llvm.noundef})

	; // -----

	define void @aliasee_func() {
	ret void
	}

	@alias_func = alias void (), ptr @aliasee_func
	define void @call_alias_func() {
	call void dso_local_equivalent @alias_func()
	ret void
	}

	; CHECK-LABEL: @call_alias_func()
	; CHECK: llvm.dso_local_equivalent @alias_func : !llvm.ptr