third_party/llvm-7.0/llvm/test/CodeGen/WebAssembly/reg-stackify.ll - SwiftShader - Git at Google

 ; RUN: llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt -disable-wasm-explicit-locals -verify-machineinstrs | FileCheck %s

 ; Test the register stackifier pass.

 target datalayout = "e-m:e-p:32:32-i64:64-n32:64-S128"
 target triple = "wasm32-unknown-unknown"

 ; No because of pointer aliasing.

 ; CHECK-LABEL: no0:
 ; CHECK: return $1{{$}}
 define i32 @no0(i32* %p, i32* %q) {
   %t = load i32, i32* %q
   store i32 0, i32* %p
   ret i32 %t
 }

 ; No because of side effects.

 ; CHECK-LABEL: no1:
 ; CHECK: return $1{{$}}
 define i32 @no1(i32* %p, i32* dereferenceable(4) %q) {
   %t = load volatile i32, i32* %q, !invariant.load !0
   store volatile i32 0, i32* %p
   ret i32 %t
 }

 ; Yes because of invariant load and no side effects.

 ; CHECK-LABEL: yes0:
 ; CHECK: return $pop{{[0-9]+}}{{$}}
 define i32 @yes0(i32* %p, i32* dereferenceable(4) %q) {
   %t = load i32, i32* %q, !invariant.load !0
   store i32 0, i32* %p
   ret i32 %t
 }

 ; Yes because of no intervening side effects.

 ; CHECK-LABEL: yes1:
 ; CHECK: return $pop0{{$}}
 define i32 @yes1(i32* %q) {
   %t = load volatile i32, i32* %q
   ret i32 %t
 }

 ; Yes because undefined behavior can be sunk past a store.

 ; CHECK-LABEL: sink_trap:
 ; CHECK: return $pop{{[0-9]+}}{{$}}
 define i32 @sink_trap(i32 %x, i32 %y, i32* %p) {
   %t = sdiv i32 %x, %y
   store volatile i32 0, i32* %p
   ret i32 %t
 }

 ; Yes because the call is readnone.

 ; CHECK-LABEL: sink_readnone_call:
 ; CHECK: return $pop0{{$}}
 declare i32 @readnone_callee() readnone nounwind
 define i32 @sink_readnone_call(i32 %x, i32 %y, i32* %p) {
   %t = call i32 @readnone_callee()
   store volatile i32 0, i32* %p
   ret i32 %t
 }

 ; No because the call is readonly and there's an intervening store.

 ; CHECK-LABEL: no_sink_readonly_call:
 ; CHECK: return ${{[0-9]+}}{{$}}
 declare i32 @readonly_callee() readonly nounwind
 define i32 @no_sink_readonly_call(i32 %x, i32 %y, i32* %p) {
   %t = call i32 @readonly_callee()
   store i32 0, i32* %p
   ret i32 %t
 }

 ; Don't schedule stack uses into the stack. To reduce register pressure, the
 ; scheduler might be tempted to move the definition of $2 down. However, this
 ; would risk getting incorrect liveness if the instructions are later
 ; rearranged to make the stack contiguous.

 ; CHECK-LABEL: stack_uses:
 ; CHECK: .param i32, i32, i32, i32{{$}}
 ; CHECK-NEXT: .result i32{{$}}
 ; CHECK-NEXT: block   {{$}}
 ; CHECK-NEXT: i32.const   $push[[L13:[0-9]+]]=, 1{{$}}
 ; CHECK-NEXT: i32.lt_s    $push[[L0:[0-9]+]]=, $0, $pop[[L13]]{{$}}
 ; CHECK-NEXT: i32.const   $push[[L1:[0-9]+]]=, 2{{$}}
 ; CHECK-NEXT: i32.lt_s    $push[[L2:[0-9]+]]=, $1, $pop[[L1]]{{$}}
 ; CHECK-NEXT: i32.xor     $push[[L5:[0-9]+]]=, $pop[[L0]], $pop[[L2]]{{$}}
 ; CHECK-NEXT: i32.const   $push[[L12:[0-9]+]]=, 1{{$}}
 ; CHECK-NEXT: i32.lt_s    $push[[L3:[0-9]+]]=, $2, $pop[[L12]]{{$}}
 ; CHECK-NEXT: i32.const   $push[[L11:[0-9]+]]=, 2{{$}}
 ; CHECK-NEXT: i32.lt_s    $push[[L4:[0-9]+]]=, $3, $pop[[L11]]{{$}}
 ; CHECK-NEXT: i32.xor     $push[[L6:[0-9]+]]=, $pop[[L3]], $pop[[L4]]{{$}}
 ; CHECK-NEXT: i32.xor     $push[[L7:[0-9]+]]=, $pop[[L5]], $pop[[L6]]{{$}}
 ; CHECK-NEXT: i32.const   $push10=, 1{{$}}
 ; CHECK-NEXT: i32.ne      $push8=, $pop7, $pop10{{$}}
 ; CHECK-NEXT: br_if       0, $pop8{{$}}
 ; CHECK-NEXT: i32.const   $push9=, 0{{$}}
 ; CHECK-NEXT: return      $pop9{{$}}
 ; CHECK-NEXT: .LBB7_2:
 ; CHECK-NEXT: end_block{{$}}
 ; CHECK-NEXT: i32.const   $push14=, 1{{$}}
 ; CHECK-NEXT: return      $pop14{{$}}
 define i32 @stack_uses(i32 %x, i32 %y, i32 %z, i32 %w) {
 entry:
   %c = icmp sle i32 %x, 0
   %d = icmp sle i32 %y, 1
   %e = icmp sle i32 %z, 0
   %f = icmp sle i32 %w, 1
   %g = xor i1 %c, %d
   %h = xor i1 %e, %f
   %i = xor i1 %g, %h
   br i1 %i, label %true, label %false
 true:
   ret i32 0
 false:
   ret i32 1
 }

 ; Test an interesting case where the load has multiple uses and cannot
 ; be trivially stackified. However, it can be stackified with a tee_local.

 ; CHECK-LABEL: multiple_uses:
 ; CHECK: .param       i32, i32, i32{{$}}
 ; CHECK-NEXT: block   {{$}}
 ; CHECK-NEXT: i32.load    $push[[NUM0:[0-9]+]]=, 0($2){{$}}
 ; CHECK-NEXT: tee_local   $push[[NUM1:[0-9]+]]=, $3=, $pop[[NUM0]]{{$}}
 ; CHECK-NEXT: i32.ge_u    $push[[NUM2:[0-9]+]]=, $pop[[NUM1]], $1{{$}}
 ; CHECK-NEXT: br_if       0, $pop[[NUM2]]{{$}}
 ; CHECK-NEXT: i32.lt_u    $push[[NUM3:[0-9]+]]=, $3, $0{{$}}
 ; CHECK-NEXT: br_if       0, $pop[[NUM3]]{{$}}
 ; CHECK-NEXT: i32.store   0($2), $3{{$}}
 ; CHECK-NEXT: .LBB8_3:
 ; CHECK-NEXT: end_block{{$}}
 ; CHECK-NEXT: return{{$}}
 define void @multiple_uses(i32* %arg0, i32* %arg1, i32* %arg2) nounwind {
 bb:
   br label %loop

 loop:
   %tmp7 = load i32, i32* %arg2
   %tmp8 = inttoptr i32 %tmp7 to i32*
   %tmp9 = icmp uge i32* %tmp8, %arg1
   %tmp10 = icmp ult i32* %tmp8, %arg0
   %tmp11 = or i1 %tmp9, %tmp10
   br i1 %tmp11, label %back, label %then

 then:
   store i32 %tmp7, i32* %arg2
   br label %back

 back:
   br i1 undef, label %return, label %loop

 return:
   ret void
 }

 ; Don't stackify stores effects across other instructions with side effects.

 ; CHECK:      side_effects:
 ; CHECK:      store
 ; CHECK-NEXT: call
 ; CHECK:      store
 ; CHECK-NEXT: call
 declare void @evoke_side_effects()
 define hidden void @stackify_store_across_side_effects(double* nocapture %d) {
 entry:
   store double 2.0, double* %d
   call void @evoke_side_effects()
   store double 2.0, double* %d
   call void @evoke_side_effects()
   ret void
 }

 ; Div instructions have side effects and can't be reordered, but this entire
 ; function should still be able to be stackified because it's already in
 ; tree order.

 ; CHECK-LABEL: div_tree:
 ; CHECK: .param i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32{{$}}
 ; CHECK-NEXT: .result     i32{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L0:[0-9]+]]=, $0, $1{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L1:[0-9]+]]=, $2, $3{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L2:[0-9]+]]=, $pop[[L0]], $pop[[L1]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L3:[0-9]+]]=, $4, $5{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L4:[0-9]+]]=, $6, $7{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L5:[0-9]+]]=, $pop[[L3]], $pop[[L4]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L6:[0-9]+]]=, $pop[[L2]], $pop[[L5]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L7:[0-9]+]]=, $8, $9{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L8:[0-9]+]]=, $10, $11{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L9:[0-9]+]]=, $pop[[L7]], $pop[[L8]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L10:[0-9]+]]=, $12, $13{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L11:[0-9]+]]=, $14, $15{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L12:[0-9]+]]=, $pop[[L10]], $pop[[L11]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L13:[0-9]+]]=, $pop[[L9]], $pop[[L12]]{{$}}
 ; CHECK-NEXT: i32.div_s   $push[[L14:[0-9]+]]=, $pop[[L6]], $pop[[L13]]{{$}}
 ; CHECK-NEXT: return      $pop[[L14]]{{$}}
 define i32 @div_tree(i32 %a, i32 %b, i32 %c, i32 %d, i32 %e, i32 %f, i32 %g, i32 %h, i32 %i, i32 %j, i32 %k, i32 %l, i32 %m, i32 %n, i32 %o, i32 %p) {
 entry:
   %div = sdiv i32 %a, %b
   %div1 = sdiv i32 %c, %d
   %div2 = sdiv i32 %div, %div1
   %div3 = sdiv i32 %e, %f
   %div4 = sdiv i32 %g, %h
   %div5 = sdiv i32 %div3, %div4
   %div6 = sdiv i32 %div2, %div5
   %div7 = sdiv i32 %i, %j
   %div8 = sdiv i32 %k, %l
   %div9 = sdiv i32 %div7, %div8
   %div10 = sdiv i32 %m, %n
   %div11 = sdiv i32 %o, %p
   %div12 = sdiv i32 %div10, %div11
   %div13 = sdiv i32 %div9, %div12
   %div14 = sdiv i32 %div6, %div13
   ret i32 %div14
 }

 ; A simple multiple-use case.

 ; CHECK-LABEL: simple_multiple_use:
 ; CHECK:  .param      i32, i32{{$}}
 ; CHECK-NEXT:  i32.mul     $push[[NUM0:[0-9]+]]=, $1, $0{{$}}
 ; CHECK-NEXT:  tee_local   $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
 ; CHECK-NEXT:  call        use_a@FUNCTION, $pop[[NUM1]]{{$}}
 ; CHECK-NEXT:  call        use_b@FUNCTION, $[[NUM2]]{{$}}
 ; CHECK-NEXT:  return{{$}}
 declare void @use_a(i32)
 declare void @use_b(i32)
 define void @simple_multiple_use(i32 %x, i32 %y) {
   %mul = mul i32 %y, %x
   call void @use_a(i32 %mul)
   call void @use_b(i32 %mul)
   ret void
 }

 ; Multiple uses of the same value in one instruction.

 ; CHECK-LABEL: multiple_uses_in_same_insn:
 ; CHECK:  .param      i32, i32{{$}}
 ; CHECK-NEXT:  i32.mul     $push[[NUM0:[0-9]+]]=, $1, $0{{$}}
 ; CHECK-NEXT:  tee_local   $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
 ; CHECK-NEXT:  call        use_2@FUNCTION, $pop[[NUM1]], $[[NUM2]]{{$}}
 ; CHECK-NEXT:  return{{$}}
 declare void @use_2(i32, i32)
 define void @multiple_uses_in_same_insn(i32 %x, i32 %y) {
   %mul = mul i32 %y, %x
   call void @use_2(i32 %mul, i32 %mul)
   ret void
 }

 ; Commute operands to achieve better stackifying.

 ; CHECK-LABEL: commute:
 ; CHECK-NOT: param
 ; CHECK:  .result     i32{{$}}
 ; CHECK-NEXT:  i32.call    $push0=, red@FUNCTION{{$}}
 ; CHECK-NEXT:  i32.call    $push1=, green@FUNCTION{{$}}
 ; CHECK-NEXT:  i32.add     $push2=, $pop0, $pop1{{$}}
 ; CHECK-NEXT:  i32.call    $push3=, blue@FUNCTION{{$}}
 ; CHECK-NEXT:  i32.add     $push4=, $pop2, $pop3{{$}}
 ; CHECK-NEXT:  return      $pop4{{$}}
 declare i32 @red()
 declare i32 @green()
 declare i32 @blue()
 define i32 @commute() {
   %call = call i32 @red()
   %call1 = call i32 @green()
   %add = add i32 %call1, %call
   %call2 = call i32 @blue()
   %add3 = add i32 %add, %call2
   ret i32 %add3
 }

 ; Don't stackify a register when it would move a the def of the register past
 ; an implicit get_local for the register.

 ; CHECK-LABEL: no_stackify_past_use:
 ; CHECK:      i32.call        $1=, callee@FUNCTION, $0
 ; CHECK-NEXT: i32.const       $push0=, 1
 ; CHECK-NEXT: i32.add         $push1=, $0, $pop0
 ; CHECK-NEXT: i32.call        $push2=, callee@FUNCTION, $pop1
 ; CHECK-NEXT: i32.sub         $push3=, $pop2, $1
 ; CHECK-NEXT: i32.div_s       $push4=, $pop3, $1
 ; CHECK-NEXT: return          $pop4
 declare i32 @callee(i32)
 define i32 @no_stackify_past_use(i32 %arg) {
   %tmp1 = call i32 @callee(i32 %arg)
   %tmp2 = add i32 %arg, 1
   %tmp3 = call i32 @callee(i32 %tmp2)
   %tmp5 = sub i32 %tmp3, %tmp1
   %tmp6 = sdiv i32 %tmp5, %tmp1
   ret i32 %tmp6
 }

 ; This is the same as no_stackify_past_use, except using a commutative operator,
 ; so we can reorder the operands and stackify.

 ; CHECK-LABEL: commute_to_fix_ordering:
 ; CHECK: i32.call        $push[[L0:.+]]=, callee@FUNCTION, $0
 ; CHECK: tee_local       $push[[L1:.+]]=, $1=, $pop[[L0]]
 ; CHECK: i32.const       $push0=, 1
 ; CHECK: i32.add         $push1=, $0, $pop0
 ; CHECK: i32.call        $push2=, callee@FUNCTION, $pop1
 ; CHECK: i32.add         $push3=, $1, $pop2
 ; CHECK: i32.mul         $push4=, $pop[[L1]], $pop3
 ; CHECK: return          $pop4
 define i32 @commute_to_fix_ordering(i32 %arg) {
   %tmp1 = call i32 @callee(i32 %arg)
   %tmp2 = add i32 %arg, 1
   %tmp3 = call i32 @callee(i32 %tmp2)
   %tmp5 = add i32 %tmp3, %tmp1
   %tmp6 = mul i32 %tmp5, %tmp1
   ret i32 %tmp6
 }

 ; Stackify individual defs of virtual registers with multiple defs.

 ; CHECK-LABEL: multiple_defs:
 ; CHECK:        f64.add         $push[[NUM0:[0-9]+]]=, ${{[0-9]+}}, $pop{{[0-9]+}}{{$}}
 ; CHECK-NEXT:   tee_local       $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
 ; CHECK-NEXT:   f64.select      $push{{[0-9]+}}=, $pop{{[0-9]+}}, $pop[[NUM1]], ${{[0-9]+}}{{$}}
 ; CHECK:        $[[NUM2]]=,
 define void @multiple_defs(i32 %arg, i32 %arg1, i1 %arg2, i1 %arg3, i1 %arg4) {
 bb:
   br label %bb5

 bb5:                                              ; preds = %bb21, %bb
   %tmp = phi double [ 0.000000e+00, %bb ], [ %tmp22, %bb21 ]
   %tmp6 = phi double [ 0.000000e+00, %bb ], [ %tmp23, %bb21 ]
   %tmp7 = fcmp olt double %tmp6, 2.323450e+01
   br i1 %tmp7, label %bb8, label %bb21

 bb8:                                              ; preds = %bb17, %bb5
   %tmp9 = phi double [ %tmp19, %bb17 ], [ %tmp, %bb5 ]
   %tmp10 = fadd double %tmp6, -1.000000e+00
   %tmp11 = select i1 %arg2, double -1.135357e+04, double %tmp10
   %tmp12 = fadd double %tmp11, %tmp9
   br i1 %arg3, label %bb17, label %bb13

 bb13:                                             ; preds = %bb8
   %tmp14 = or i32 %arg1, 2
   %tmp15 = icmp eq i32 %tmp14, 14
   %tmp16 = select i1 %tmp15, double -1.135357e+04, double 0xBFCE147AE147B000
   br label %bb17

 bb17:                                             ; preds = %bb13, %bb8
   %tmp18 = phi double [ %tmp16, %bb13 ], [ %tmp10, %bb8 ]
   %tmp19 = fadd double %tmp18, %tmp12
   %tmp20 = fcmp olt double %tmp6, 2.323450e+01
   br i1 %tmp20, label %bb8, label %bb21

 bb21:                                             ; preds = %bb17, %bb5
   %tmp22 = phi double [ %tmp, %bb5 ], [ %tmp9, %bb17 ]
   %tmp23 = fadd double %tmp6, 1.000000e+00
   br i1 %arg4, label %exit, label %bb5
 exit:
   ret void
 }

 ; Don't move calls past loads
 ; CHECK-LABEL: no_stackify_call_past_load:
 ; CHECK: i32.call $0=, red
 ; CHECK: i32.const $push0=, 0
 ; CHECK: i32.load $1=, count($pop0)
 @count = hidden global i32 0, align 4
 define i32 @no_stackify_call_past_load() {
   %a = call i32 @red()
   %b = load i32, i32* @count, align 4
   call i32 @callee(i32 %a)
   ret i32 %b
   ; use of a
 }

 ; Don't move stores past loads if there may be aliasing
 ; CHECK-LABEL: no_stackify_store_past_load
 ; CHECK: i32.store 0($1), $0
 ; CHECK: i32.load {{.*}}, 0($2)
 ; CHECK: i32.call {{.*}}, callee@FUNCTION, $0{{$}}
 define i32 @no_stackify_store_past_load(i32 %a, i32* %p1, i32* %p2) {
   store i32 %a, i32* %p1
   %b = load i32, i32* %p2, align 4
   call i32 @callee(i32 %a)
   ret i32 %b
 }

 ; Can still stackify past invariant loads.
 ; CHECK-LABEL: store_past_invar_load
 ; CHECK: i32.store 0($1), $0
 ; CHECK: i32.call {{.*}}, callee@FUNCTION, $0
 ; CHECK: i32.load $push{{.*}}, 0($2)
 ; CHECK: return $pop
 define i32 @store_past_invar_load(i32 %a, i32* %p1, i32* dereferenceable(4) %p2) {
   store i32 %a, i32* %p1
   %b = load i32, i32* %p2, !invariant.load !0
   call i32 @callee(i32 %a)
   ret i32 %b
 }

 ; CHECK-LABEL: ignore_dbg_value:
 ; CHECK-NEXT: .Lfunc_begin
 ; CHECK-NEXT: unreachable
 declare void @llvm.dbg.value(metadata, i64, metadata, metadata)
 define void @ignore_dbg_value() {
   call void @llvm.dbg.value(metadata i32 0, i64 0, metadata !7, metadata !9), !dbg !10
   unreachable
 }

 ; Don't stackify an expression that might use the stack into a return, since we
 ; might insert a prologue before the return.

 ; CHECK-LABEL: no_stackify_past_epilogue:
 ; CHECK: return ${{[0-9]+}}{{$}}
 declare i32 @use_memory(i32*)
 define i32 @no_stackify_past_epilogue() {
   %x = alloca i32
   %call = call i32 @use_memory(i32* %x)
   ret i32 %call
 }

 ; Stackify a loop induction variable into a loop comparison.

 ; CHECK-LABEL: stackify_indvar:
 ; CHECK:             i32.const   $push[[L5:.+]]=, 1{{$}}
 ; CHECK-NEXT:        i32.add     $push[[L4:.+]]=, $[[R0:.+]], $pop[[L5]]{{$}}
 ; CHECK-NEXT:        tee_local   $push[[L3:.+]]=, $[[R0]]=, $pop[[L4]]{{$}}
 ; CHECK-NEXT:        i32.ne      $push[[L2:.+]]=, $0, $pop[[L3]]{{$}}
 define void @stackify_indvar(i32 %tmp, i32* %v) #0 {
 bb:
   br label %bb3

 bb3:                                              ; preds = %bb3, %bb2
   %tmp4 = phi i32 [ %tmp7, %bb3 ], [ 0, %bb ]
   %tmp5 = load volatile i32, i32* %v, align 4
   %tmp6 = add nsw i32 %tmp5, %tmp4
   store volatile i32 %tmp6, i32* %v, align 4
   %tmp7 = add nuw nsw i32 %tmp4, 1
   %tmp8 = icmp eq i32 %tmp7, %tmp
   br i1 %tmp8, label %bb10, label %bb3

 bb10:                                             ; preds = %bb9, %bb
   ret void
 }

 ; Don't stackify a call past a __stack_pointer store.

 ; CHECK-LABEL: stackpointer_dependency:
 ; CHECK:      call {{.+}}, stackpointer_callee@FUNCTION,
 ; CHECK-NEXT: set_global __stack_pointer,
 declare i32 @stackpointer_callee(i8* readnone, i8* readnone)
 declare i8* @llvm.frameaddress(i32)
 define i32 @stackpointer_dependency(i8* readnone) {
   %2 = tail call i8* @llvm.frameaddress(i32 0)
   %3 = tail call i32 @stackpointer_callee(i8* %0, i8* %2)
   ret i32 %3
 }

 ; Stackify a call_indirect with respect to its ordering

 ; CHECK-LABEL: call_indirect_stackify:
 ; CHECK: i32.load  $push[[L4:.+]]=, 0($0)
 ; CHECK-NEXT: tee_local $push[[L3:.+]]=, $0=, $pop[[L4]]
 ; CHECK-NEXT: i32.load  $push[[L0:.+]]=, 0($0)
 ; CHECK-NEXT: i32.load  $push[[L1:.+]]=, 0($pop[[L0]])
 ; CHECK-NEXT: i32.call_indirect $push{{.+}}=, $pop[[L3]], $1, $pop[[L1]]
 %class.call_indirect = type { i32 (...)** }
 define i32 @call_indirect_stackify(%class.call_indirect** %objptr, i32 %arg) {
   %obj = load %class.call_indirect*, %class.call_indirect** %objptr
   %addr = bitcast %class.call_indirect* %obj to i32(%class.call_indirect*, i32)***
   %vtable = load i32(%class.call_indirect*, i32)**, i32(%class.call_indirect*, i32)*** %addr
   %vfn = getelementptr inbounds i32(%class.call_indirect*, i32)*, i32(%class.call_indirect*, i32)** %vtable, i32 0
   %f = load i32(%class.call_indirect*, i32)*, i32(%class.call_indirect*, i32)** %vfn
   %ret = call i32 %f(%class.call_indirect* %obj, i32 %arg)
   ret i32 %ret
 }

 !llvm.module.flags = !{!0}
 !llvm.dbg.cu = !{!1}

 !0 = !{i32 2, !"Debug Info Version", i32 3}
 !1 = distinct !DICompileUnit(language: DW_LANG_C99, file: !2, producer: "clang version 3.9.0 (trunk 266005) (llvm/trunk 266105)", isOptimized: false, runtimeVersion: 0, emissionKind: FullDebug, enums: !3)
 !2 = !DIFile(filename: "test.c", directory: "/")
 !3 = !{}
 !5 = distinct !DISubprogram(name: "test", scope: !2, file: !2, line: 10, type: !6, isLocal: false, isDefinition: true, scopeLine: 11, flags: DIFlagPrototyped, isOptimized: true, unit: !1, retainedNodes: !3)
 !6 = !DISubroutineType(types: !3)
 !7 = !DILocalVariable(name: "nzcnt", scope: !5, file: !2, line: 15, type: !8)
 !8 = !DIBasicType(name: "int", size: 32, align: 32, encoding: DW_ATE_signed)
 !9 = !DIExpression()
 !10 = !DILocation(line: 15, column: 6, scope: !5)
	; RUN: llc < %s -asm-verbose=false -disable-wasm-fallthrough-return-opt -disable-wasm-explicit-locals -verify-machineinstrs \| FileCheck %s

	; Test the register stackifier pass.

	target datalayout = "e-m:e-p:32:32-i64:64-n32:64-S128"
	target triple = "wasm32-unknown-unknown"

	; No because of pointer aliasing.

	; CHECK-LABEL: no0:
	; CHECK: return $1{{$}}
	define i32 @no0(i32* %p, i32* %q) {
	%t = load i32, i32* %q
	store i32 0, i32* %p
	ret i32 %t
	}

	; No because of side effects.

	; CHECK-LABEL: no1:
	; CHECK: return $1{{$}}
	define i32 @no1(i32* %p, i32* dereferenceable(4) %q) {
	%t = load volatile i32, i32* %q, !invariant.load !0
	store volatile i32 0, i32* %p
	ret i32 %t
	}

	; Yes because of invariant load and no side effects.

	; CHECK-LABEL: yes0:
	; CHECK: return $pop{{[0-9]+}}{{$}}
	define i32 @yes0(i32* %p, i32* dereferenceable(4) %q) {
	%t = load i32, i32* %q, !invariant.load !0
	store i32 0, i32* %p
	ret i32 %t
	}

	; Yes because of no intervening side effects.

	; CHECK-LABEL: yes1:
	; CHECK: return $pop0{{$}}
	define i32 @yes1(i32* %q) {
	%t = load volatile i32, i32* %q
	ret i32 %t
	}

	; Yes because undefined behavior can be sunk past a store.

	; CHECK-LABEL: sink_trap:
	; CHECK: return $pop{{[0-9]+}}{{$}}
	define i32 @sink_trap(i32 %x, i32 %y, i32* %p) {
	%t = sdiv i32 %x, %y
	store volatile i32 0, i32* %p
	ret i32 %t
	}

	; Yes because the call is readnone.

	; CHECK-LABEL: sink_readnone_call:
	; CHECK: return $pop0{{$}}
	declare i32 @readnone_callee() readnone nounwind
	define i32 @sink_readnone_call(i32 %x, i32 %y, i32* %p) {
	%t = call i32 @readnone_callee()
	store volatile i32 0, i32* %p
	ret i32 %t
	}

	; No because the call is readonly and there's an intervening store.

	; CHECK-LABEL: no_sink_readonly_call:
	; CHECK: return ${{[0-9]+}}{{$}}
	declare i32 @readonly_callee() readonly nounwind
	define i32 @no_sink_readonly_call(i32 %x, i32 %y, i32* %p) {
	%t = call i32 @readonly_callee()
	store i32 0, i32* %p
	ret i32 %t
	}

	; Don't schedule stack uses into the stack. To reduce register pressure, the
	; scheduler might be tempted to move the definition of $2 down. However, this
	; would risk getting incorrect liveness if the instructions are later
	; rearranged to make the stack contiguous.

	; CHECK-LABEL: stack_uses:
	; CHECK: .param i32, i32, i32, i32{{$}}
	; CHECK-NEXT: .result i32{{$}}
	; CHECK-NEXT: block {{$}}
	; CHECK-NEXT: i32.const $push[[L13:[0-9]+]]=, 1{{$}}
	; CHECK-NEXT: i32.lt_s $push[[L0:[0-9]+]]=, $0, $pop[[L13]]{{$}}
	; CHECK-NEXT: i32.const $push[[L1:[0-9]+]]=, 2{{$}}
	; CHECK-NEXT: i32.lt_s $push[[L2:[0-9]+]]=, $1, $pop[[L1]]{{$}}
	; CHECK-NEXT: i32.xor $push[[L5:[0-9]+]]=, $pop[[L0]], $pop[[L2]]{{$}}
	; CHECK-NEXT: i32.const $push[[L12:[0-9]+]]=, 1{{$}}
	; CHECK-NEXT: i32.lt_s $push[[L3:[0-9]+]]=, $2, $pop[[L12]]{{$}}
	; CHECK-NEXT: i32.const $push[[L11:[0-9]+]]=, 2{{$}}
	; CHECK-NEXT: i32.lt_s $push[[L4:[0-9]+]]=, $3, $pop[[L11]]{{$}}
	; CHECK-NEXT: i32.xor $push[[L6:[0-9]+]]=, $pop[[L3]], $pop[[L4]]{{$}}
	; CHECK-NEXT: i32.xor $push[[L7:[0-9]+]]=, $pop[[L5]], $pop[[L6]]{{$}}
	; CHECK-NEXT: i32.const $push10=, 1{{$}}
	; CHECK-NEXT: i32.ne $push8=, $pop7, $pop10{{$}}
	; CHECK-NEXT: br_if 0, $pop8{{$}}
	; CHECK-NEXT: i32.const $push9=, 0{{$}}
	; CHECK-NEXT: return $pop9{{$}}
	; CHECK-NEXT: .LBB7_2:
	; CHECK-NEXT: end_block{{$}}
	; CHECK-NEXT: i32.const $push14=, 1{{$}}
	; CHECK-NEXT: return $pop14{{$}}
	define i32 @stack_uses(i32 %x, i32 %y, i32 %z, i32 %w) {
	entry:
	%c = icmp sle i32 %x, 0
	%d = icmp sle i32 %y, 1
	%e = icmp sle i32 %z, 0
	%f = icmp sle i32 %w, 1
	%g = xor i1 %c, %d
	%h = xor i1 %e, %f
	%i = xor i1 %g, %h
	br i1 %i, label %true, label %false
	true:
	ret i32 0
	false:
	ret i32 1
	}

	; Test an interesting case where the load has multiple uses and cannot
	; be trivially stackified. However, it can be stackified with a tee_local.

	; CHECK-LABEL: multiple_uses:
	; CHECK: .param i32, i32, i32{{$}}
	; CHECK-NEXT: block {{$}}
	; CHECK-NEXT: i32.load $push[[NUM0:[0-9]+]]=, 0($2){{$}}
	; CHECK-NEXT: tee_local $push[[NUM1:[0-9]+]]=, $3=, $pop[[NUM0]]{{$}}
	; CHECK-NEXT: i32.ge_u $push[[NUM2:[0-9]+]]=, $pop[[NUM1]], $1{{$}}
	; CHECK-NEXT: br_if 0, $pop[[NUM2]]{{$}}
	; CHECK-NEXT: i32.lt_u $push[[NUM3:[0-9]+]]=, $3, $0{{$}}
	; CHECK-NEXT: br_if 0, $pop[[NUM3]]{{$}}
	; CHECK-NEXT: i32.store 0($2), $3{{$}}
	; CHECK-NEXT: .LBB8_3:
	; CHECK-NEXT: end_block{{$}}
	; CHECK-NEXT: return{{$}}
	define void @multiple_uses(i32* %arg0, i32* %arg1, i32* %arg2) nounwind {
	bb:
	br label %loop

	loop:
	%tmp7 = load i32, i32* %arg2
	%tmp8 = inttoptr i32 %tmp7 to i32*
	%tmp9 = icmp uge i32* %tmp8, %arg1
	%tmp10 = icmp ult i32* %tmp8, %arg0
	%tmp11 = or i1 %tmp9, %tmp10
	br i1 %tmp11, label %back, label %then

	then:
	store i32 %tmp7, i32* %arg2
	br label %back

	back:
	br i1 undef, label %return, label %loop

	return:
	ret void
	}

	; Don't stackify stores effects across other instructions with side effects.

	; CHECK: side_effects:
	; CHECK: store
	; CHECK-NEXT: call
	; CHECK: store
	; CHECK-NEXT: call
	declare void @evoke_side_effects()
	define hidden void @stackify_store_across_side_effects(double* nocapture %d) {
	entry:
	store double 2.0, double* %d
	call void @evoke_side_effects()
	store double 2.0, double* %d
	call void @evoke_side_effects()
	ret void
	}

	; Div instructions have side effects and can't be reordered, but this entire
	; function should still be able to be stackified because it's already in
	; tree order.

	; CHECK-LABEL: div_tree:
	; CHECK: .param i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32, i32{{$}}
	; CHECK-NEXT: .result i32{{$}}
	; CHECK-NEXT: i32.div_s $push[[L0:[0-9]+]]=, $0, $1{{$}}
	; CHECK-NEXT: i32.div_s $push[[L1:[0-9]+]]=, $2, $3{{$}}
	; CHECK-NEXT: i32.div_s $push[[L2:[0-9]+]]=, $pop[[L0]], $pop[[L1]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L3:[0-9]+]]=, $4, $5{{$}}
	; CHECK-NEXT: i32.div_s $push[[L4:[0-9]+]]=, $6, $7{{$}}
	; CHECK-NEXT: i32.div_s $push[[L5:[0-9]+]]=, $pop[[L3]], $pop[[L4]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L6:[0-9]+]]=, $pop[[L2]], $pop[[L5]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L7:[0-9]+]]=, $8, $9{{$}}
	; CHECK-NEXT: i32.div_s $push[[L8:[0-9]+]]=, $10, $11{{$}}
	; CHECK-NEXT: i32.div_s $push[[L9:[0-9]+]]=, $pop[[L7]], $pop[[L8]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L10:[0-9]+]]=, $12, $13{{$}}
	; CHECK-NEXT: i32.div_s $push[[L11:[0-9]+]]=, $14, $15{{$}}
	; CHECK-NEXT: i32.div_s $push[[L12:[0-9]+]]=, $pop[[L10]], $pop[[L11]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L13:[0-9]+]]=, $pop[[L9]], $pop[[L12]]{{$}}
	; CHECK-NEXT: i32.div_s $push[[L14:[0-9]+]]=, $pop[[L6]], $pop[[L13]]{{$}}
	; CHECK-NEXT: return $pop[[L14]]{{$}}
	define i32 @div_tree(i32 %a, i32 %b, i32 %c, i32 %d, i32 %e, i32 %f, i32 %g, i32 %h, i32 %i, i32 %j, i32 %k, i32 %l, i32 %m, i32 %n, i32 %o, i32 %p) {
	entry:
	%div = sdiv i32 %a, %b
	%div1 = sdiv i32 %c, %d
	%div2 = sdiv i32 %div, %div1
	%div3 = sdiv i32 %e, %f
	%div4 = sdiv i32 %g, %h
	%div5 = sdiv i32 %div3, %div4
	%div6 = sdiv i32 %div2, %div5
	%div7 = sdiv i32 %i, %j
	%div8 = sdiv i32 %k, %l
	%div9 = sdiv i32 %div7, %div8
	%div10 = sdiv i32 %m, %n
	%div11 = sdiv i32 %o, %p
	%div12 = sdiv i32 %div10, %div11
	%div13 = sdiv i32 %div9, %div12
	%div14 = sdiv i32 %div6, %div13
	ret i32 %div14
	}

	; A simple multiple-use case.

	; CHECK-LABEL: simple_multiple_use:
	; CHECK: .param i32, i32{{$}}
	; CHECK-NEXT: i32.mul $push[[NUM0:[0-9]+]]=, $1, $0{{$}}
	; CHECK-NEXT: tee_local $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
	; CHECK-NEXT: call use_a@FUNCTION, $pop[[NUM1]]{{$}}
	; CHECK-NEXT: call use_b@FUNCTION, $[[NUM2]]{{$}}
	; CHECK-NEXT: return{{$}}
	declare void @use_a(i32)
	declare void @use_b(i32)
	define void @simple_multiple_use(i32 %x, i32 %y) {
	%mul = mul i32 %y, %x
	call void @use_a(i32 %mul)
	call void @use_b(i32 %mul)
	ret void
	}

	; Multiple uses of the same value in one instruction.

	; CHECK-LABEL: multiple_uses_in_same_insn:
	; CHECK: .param i32, i32{{$}}
	; CHECK-NEXT: i32.mul $push[[NUM0:[0-9]+]]=, $1, $0{{$}}
	; CHECK-NEXT: tee_local $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
	; CHECK-NEXT: call use_2@FUNCTION, $pop[[NUM1]], $[[NUM2]]{{$}}
	; CHECK-NEXT: return{{$}}
	declare void @use_2(i32, i32)
	define void @multiple_uses_in_same_insn(i32 %x, i32 %y) {
	%mul = mul i32 %y, %x
	call void @use_2(i32 %mul, i32 %mul)
	ret void
	}

	; Commute operands to achieve better stackifying.

	; CHECK-LABEL: commute:
	; CHECK-NOT: param
	; CHECK: .result i32{{$}}
	; CHECK-NEXT: i32.call $push0=, red@FUNCTION{{$}}
	; CHECK-NEXT: i32.call $push1=, green@FUNCTION{{$}}
	; CHECK-NEXT: i32.add $push2=, $pop0, $pop1{{$}}
	; CHECK-NEXT: i32.call $push3=, blue@FUNCTION{{$}}
	; CHECK-NEXT: i32.add $push4=, $pop2, $pop3{{$}}
	; CHECK-NEXT: return $pop4{{$}}
	declare i32 @red()
	declare i32 @green()
	declare i32 @blue()
	define i32 @commute() {
	%call = call i32 @red()
	%call1 = call i32 @green()
	%add = add i32 %call1, %call
	%call2 = call i32 @blue()
	%add3 = add i32 %add, %call2
	ret i32 %add3
	}

	; Don't stackify a register when it would move a the def of the register past
	; an implicit get_local for the register.

	; CHECK-LABEL: no_stackify_past_use:
	; CHECK: i32.call $1=, callee@FUNCTION, $0
	; CHECK-NEXT: i32.const $push0=, 1
	; CHECK-NEXT: i32.add $push1=, $0, $pop0
	; CHECK-NEXT: i32.call $push2=, callee@FUNCTION, $pop1
	; CHECK-NEXT: i32.sub $push3=, $pop2, $1
	; CHECK-NEXT: i32.div_s $push4=, $pop3, $1
	; CHECK-NEXT: return $pop4
	declare i32 @callee(i32)
	define i32 @no_stackify_past_use(i32 %arg) {
	%tmp1 = call i32 @callee(i32 %arg)
	%tmp2 = add i32 %arg, 1
	%tmp3 = call i32 @callee(i32 %tmp2)
	%tmp5 = sub i32 %tmp3, %tmp1
	%tmp6 = sdiv i32 %tmp5, %tmp1
	ret i32 %tmp6
	}

	; This is the same as no_stackify_past_use, except using a commutative operator,
	; so we can reorder the operands and stackify.

	; CHECK-LABEL: commute_to_fix_ordering:
	; CHECK: i32.call $push[[L0:.+]]=, callee@FUNCTION, $0
	; CHECK: tee_local $push[[L1:.+]]=, $1=, $pop[[L0]]
	; CHECK: i32.const $push0=, 1
	; CHECK: i32.add $push1=, $0, $pop0
	; CHECK: i32.call $push2=, callee@FUNCTION, $pop1
	; CHECK: i32.add $push3=, $1, $pop2
	; CHECK: i32.mul $push4=, $pop[[L1]], $pop3
	; CHECK: return $pop4
	define i32 @commute_to_fix_ordering(i32 %arg) {
	%tmp1 = call i32 @callee(i32 %arg)
	%tmp2 = add i32 %arg, 1
	%tmp3 = call i32 @callee(i32 %tmp2)
	%tmp5 = add i32 %tmp3, %tmp1
	%tmp6 = mul i32 %tmp5, %tmp1
	ret i32 %tmp6
	}

	; Stackify individual defs of virtual registers with multiple defs.

	; CHECK-LABEL: multiple_defs:
	; CHECK: f64.add $push[[NUM0:[0-9]+]]=, ${{[0-9]+}}, $pop{{[0-9]+}}{{$}}
	; CHECK-NEXT: tee_local $push[[NUM1:[0-9]+]]=, $[[NUM2:[0-9]+]]=, $pop[[NUM0]]{{$}}
	; CHECK-NEXT: f64.select $push{{[0-9]+}}=, $pop{{[0-9]+}}, $pop[[NUM1]], ${{[0-9]+}}{{$}}
	; CHECK: $[[NUM2]]=,
	define void @multiple_defs(i32 %arg, i32 %arg1, i1 %arg2, i1 %arg3, i1 %arg4) {
	bb:
	br label %bb5

	bb5: ; preds = %bb21, %bb
	%tmp = phi double [ 0.000000e+00, %bb ], [ %tmp22, %bb21 ]
	%tmp6 = phi double [ 0.000000e+00, %bb ], [ %tmp23, %bb21 ]
	%tmp7 = fcmp olt double %tmp6, 2.323450e+01
	br i1 %tmp7, label %bb8, label %bb21

	bb8: ; preds = %bb17, %bb5
	%tmp9 = phi double [ %tmp19, %bb17 ], [ %tmp, %bb5 ]
	%tmp10 = fadd double %tmp6, -1.000000e+00
	%tmp11 = select i1 %arg2, double -1.135357e+04, double %tmp10
	%tmp12 = fadd double %tmp11, %tmp9
	br i1 %arg3, label %bb17, label %bb13

	bb13: ; preds = %bb8
	%tmp14 = or i32 %arg1, 2
	%tmp15 = icmp eq i32 %tmp14, 14
	%tmp16 = select i1 %tmp15, double -1.135357e+04, double 0xBFCE147AE147B000
	br label %bb17

	bb17: ; preds = %bb13, %bb8
	%tmp18 = phi double [ %tmp16, %bb13 ], [ %tmp10, %bb8 ]
	%tmp19 = fadd double %tmp18, %tmp12
	%tmp20 = fcmp olt double %tmp6, 2.323450e+01
	br i1 %tmp20, label %bb8, label %bb21

	bb21: ; preds = %bb17, %bb5
	%tmp22 = phi double [ %tmp, %bb5 ], [ %tmp9, %bb17 ]
	%tmp23 = fadd double %tmp6, 1.000000e+00
	br i1 %arg4, label %exit, label %bb5
	exit:
	ret void
	}

	; Don't move calls past loads
	; CHECK-LABEL: no_stackify_call_past_load:
	; CHECK: i32.call $0=, red
	; CHECK: i32.const $push0=, 0
	; CHECK: i32.load $1=, count($pop0)
	@count = hidden global i32 0, align 4
	define i32 @no_stackify_call_past_load() {
	%a = call i32 @red()
	%b = load i32, i32* @count, align 4
	call i32 @callee(i32 %a)
	ret i32 %b
	; use of a
	}

	; Don't move stores past loads if there may be aliasing
	; CHECK-LABEL: no_stackify_store_past_load
	; CHECK: i32.store 0($1), $0
	; CHECK: i32.load {{.*}}, 0($2)
	; CHECK: i32.call {{.*}}, callee@FUNCTION, $0{{$}}
	define i32 @no_stackify_store_past_load(i32 %a, i32* %p1, i32* %p2) {
	store i32 %a, i32* %p1
	%b = load i32, i32* %p2, align 4
	call i32 @callee(i32 %a)
	ret i32 %b
	}

	; Can still stackify past invariant loads.
	; CHECK-LABEL: store_past_invar_load
	; CHECK: i32.store 0($1), $0
	; CHECK: i32.call {{.*}}, callee@FUNCTION, $0
	; CHECK: i32.load $push{{.*}}, 0($2)
	; CHECK: return $pop
	define i32 @store_past_invar_load(i32 %a, i32* %p1, i32* dereferenceable(4) %p2) {
	store i32 %a, i32* %p1
	%b = load i32, i32* %p2, !invariant.load !0
	call i32 @callee(i32 %a)
	ret i32 %b
	}

	; CHECK-LABEL: ignore_dbg_value:
	; CHECK-NEXT: .Lfunc_begin
	; CHECK-NEXT: unreachable
	declare void @llvm.dbg.value(metadata, i64, metadata, metadata)
	define void @ignore_dbg_value() {
	call void @llvm.dbg.value(metadata i32 0, i64 0, metadata !7, metadata !9), !dbg !10
	unreachable
	}

	; Don't stackify an expression that might use the stack into a return, since we
	; might insert a prologue before the return.

	; CHECK-LABEL: no_stackify_past_epilogue:
	; CHECK: return ${{[0-9]+}}{{$}}
	declare i32 @use_memory(i32*)
	define i32 @no_stackify_past_epilogue() {
	%x = alloca i32
	%call = call i32 @use_memory(i32* %x)
	ret i32 %call
	}

	; Stackify a loop induction variable into a loop comparison.

	; CHECK-LABEL: stackify_indvar:
	; CHECK: i32.const $push[[L5:.+]]=, 1{{$}}
	; CHECK-NEXT: i32.add $push[[L4:.+]]=, $[[R0:.+]], $pop[[L5]]{{$}}
	; CHECK-NEXT: tee_local $push[[L3:.+]]=, $[[R0]]=, $pop[[L4]]{{$}}
	; CHECK-NEXT: i32.ne $push[[L2:.+]]=, $0, $pop[[L3]]{{$}}
	define void @stackify_indvar(i32 %tmp, i32* %v) #0 {
	bb:
	br label %bb3

	bb3: ; preds = %bb3, %bb2
	%tmp4 = phi i32 [ %tmp7, %bb3 ], [ 0, %bb ]
	%tmp5 = load volatile i32, i32* %v, align 4
	%tmp6 = add nsw i32 %tmp5, %tmp4
	store volatile i32 %tmp6, i32* %v, align 4
	%tmp7 = add nuw nsw i32 %tmp4, 1
	%tmp8 = icmp eq i32 %tmp7, %tmp
	br i1 %tmp8, label %bb10, label %bb3

	bb10: ; preds = %bb9, %bb
	ret void
	}

	; Don't stackify a call past a __stack_pointer store.

	; CHECK-LABEL: stackpointer_dependency:
	; CHECK: call {{.+}}, stackpointer_callee@FUNCTION,
	; CHECK-NEXT: set_global __stack_pointer,
	declare i32 @stackpointer_callee(i8* readnone, i8* readnone)
	declare i8* @llvm.frameaddress(i32)
	define i32 @stackpointer_dependency(i8* readnone) {
	%2 = tail call i8* @llvm.frameaddress(i32 0)
	%3 = tail call i32 @stackpointer_callee(i8* %0, i8* %2)
	ret i32 %3
	}

	; Stackify a call_indirect with respect to its ordering

	; CHECK-LABEL: call_indirect_stackify:
	; CHECK: i32.load $push[[L4:.+]]=, 0($0)
	; CHECK-NEXT: tee_local $push[[L3:.+]]=, $0=, $pop[[L4]]
	; CHECK-NEXT: i32.load $push[[L0:.+]]=, 0($0)
	; CHECK-NEXT: i32.load $push[[L1:.+]]=, 0($pop[[L0]])
	; CHECK-NEXT: i32.call_indirect $push{{.+}}=, $pop[[L3]], $1, $pop[[L1]]
	%class.call_indirect = type { i32 (...)** }
	define i32 @call_indirect_stackify(%class.call_indirect** %objptr, i32 %arg) {
	%obj = load %class.call_indirect, %class.call_indirect* %objptr
	%addr = bitcast %class.call_indirect* %obj to i32(%class.call_indirect, i32)**
	%vtable = load i32(%class.call_indirect, i32), i32(%class.call_indirect, i32)*** %addr
	%vfn = getelementptr inbounds i32(%class.call_indirect, i32), i32(%class.call_indirect, i32)* %vtable, i32 0
	%f = load i32(%class.call_indirect, i32), i32(%class.call_indirect, i32)* %vfn
	%ret = call i32 %f(%class.call_indirect* %obj, i32 %arg)
	ret i32 %ret
	}

	!llvm.module.flags = !{!0}
	!llvm.dbg.cu = !{!1}

	!0 = !{i32 2, !"Debug Info Version", i32 3}
	!1 = distinct !DICompileUnit(language: DW_LANG_C99, file: !2, producer: "clang version 3.9.0 (trunk 266005) (llvm/trunk 266105)", isOptimized: false, runtimeVersion: 0, emissionKind: FullDebug, enums: !3)
	!2 = !DIFile(filename: "test.c", directory: "/")
	!3 = !{}
	!5 = distinct !DISubprogram(name: "test", scope: !2, file: !2, line: 10, type: !6, isLocal: false, isDefinition: true, scopeLine: 11, flags: DIFlagPrototyped, isOptimized: true, unit: !1, retainedNodes: !3)
	!6 = !DISubroutineType(types: !3)
	!7 = !DILocalVariable(name: "nzcnt", scope: !5, file: !2, line: 15, type: !8)
	!8 = !DIBasicType(name: "int", size: 32, align: 32, encoding: DW_ATE_signed)
	!9 = !DIExpression()
	!10 = !DILocation(line: 15, column: 6, scope: !5)