llvm-6502/test/CodeGen/X86/x86-shrink-wrapping.ll

; RUN: llc %s -o - -enable-shrink-wrap=true | FileCheck %s --check-prefix=CHECK --check-prefix=ENABLE
; RUN: llc %s -o - -enable-shrink-wrap=false | FileCheck %s --check-prefix=CHECK --check-prefix=DISABLE
;
; Note: Lots of tests use inline asm instead of regular calls.
; This allows to have a better control on what the allocation will do.
; Otherwise, we may have spill right in the entry block, defeating
; shrink-wrapping. Moreover, some of the inline asm statement (nop)
; are here to ensure that the related paths do not end up as critical
; edges.
target datalayout = "e-m:o-i64:64-i128:128-n32:64-S128"
target triple = "x86_64-apple-macosx"


; Initial motivating example: Simple diamond with a call just on one side.
; CHECK-LABEL: foo:
;
; Compare the arguments and jump to exit.
; No prologue needed.
; ENABLE: movl %edi, [[ARG0CPY:%e[a-z]+]]
; ENABLE-NEXT: cmpl %esi, [[ARG0CPY]]
; ENABLE-NEXT: jge [[EXIT_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; (What we push does not matter. It should be some random sratch register.)
; CHECK: pushq
;
; Compare the arguments and jump to exit.
; After the prologue is set.
; DISABLE: movl %edi, [[ARG0CPY:%e[a-z]+]]
; DISABLE-NEXT: cmpl %esi, [[ARG0CPY]]
; DISABLE-NEXT: jge [[EXIT_LABEL:LBB[0-9_]+]]
;
; Store %a in the alloca.
; CHECK: movl [[ARG0CPY]], 4(%rsp)
; Set the alloca address in the second argument.
; CHECK-NEXT: leaq 4(%rsp), %rsi
; Set the first argument to zero.
; CHECK-NEXT: xorl %edi, %edi
; CHECK-NEXT: callq _doSomething
;
; With shrink-wrapping, epilogue is just after the call.
; ENABLE-NEXT: addq $8, %rsp
;
; CHECK: [[EXIT_LABEL]]:
;
; Without shrink-wrapping, epilogue is in the exit block.
; Epilogue code. (What we pop does not matter.)
; DISABLE-NEXT: popq
;
; CHECK-NEXT: retq
define i32 @foo(i32 %a, i32 %b) {
  %tmp = alloca i32, align 4
  %tmp2 = icmp slt i32 %a, %b
  br i1 %tmp2, label %true, label %false

true:
  store i32 %a, i32* %tmp, align 4
  %tmp4 = call i32 @doSomething(i32 0, i32* %tmp)
  br label %false

false:
  %tmp.0 = phi i32 [ %tmp4, %true ], [ %a, %0 ]
  ret i32 %tmp.0
}

; Function Attrs: optsize
declare i32 @doSomething(i32, i32*)


; Check that we do not perform the restore inside the loop whereas the save
; is outside.
; CHECK-LABEL: freqSaveAndRestoreOutsideLoop:
;
; Shrink-wrapping allows to skip the prologue in the else case.
; ENABLE: testl %edi, %edi  
; ENABLE: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; Make sure we save the CSR used in the inline asm: rbx.
; CHECK: pushq %rbx
;
; DISABLE: testl %edi, %edi
; DISABLE: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; SUM is in %esi because it is coalesced with the second
; argument on the else path.
; CHECK: xorl [[SUM:%esi]], [[SUM]]
; CHECK-NEXT: movl $10, [[IV:%e[a-z]+]]
;
; Next BB.
; CHECK: [[LOOP:LBB[0-9_]+]]: ## %for.body
; CHECK: movl $1, [[TMP:%e[a-z]+]]
; CHECK: addl [[TMP]], [[SUM]]
; CHECK-NEXT: decl [[IV]]
; CHECK-NEXT: jne [[LOOP]]
;
; Next BB.
; SUM << 3.
; CHECK: shll $3, [[SUM]]
;
; Jump to epilogue.
; DISABLE: jmp [[EPILOG_BB:LBB[0-9_]+]]
;
; DISABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; DISABLE: addl %esi, %esi
; DISABLE: [[EPILOG_BB]]: ## %if.end
;
; Epilogue code.
; CHECK-DAG: popq %rbx
; CHECK-DAG: movl %esi, %eax
; CHECK: retq
;
; ENABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; ENABLE: addl %esi, %esi
; ENABLE-NEXT: movl %esi, %eax
; ENABLE-NEXT: retq
define i32 @freqSaveAndRestoreOutsideLoop(i32 %cond, i32 %N) {
entry:
  %tobool = icmp eq i32 %cond, 0
  br i1 %tobool, label %if.else, label %for.preheader

for.preheader:
  tail call void asm "nop", ""()
  br label %for.body

for.body:                                         ; preds = %entry, %for.body
  %i.05 = phi i32 [ %inc, %for.body ], [ 0, %for.preheader ]
  %sum.04 = phi i32 [ %add, %for.body ], [ 0, %for.preheader ]
  %call = tail call i32 asm "movl $$1, $0", "=r,~{ebx}"()
  %add = add nsw i32 %call, %sum.04
  %inc = add nuw nsw i32 %i.05, 1
  %exitcond = icmp eq i32 %inc, 10
  br i1 %exitcond, label %for.end, label %for.body

for.end:                                          ; preds = %for.body
  %shl = shl i32 %add, 3
  br label %if.end

if.else:                                          ; preds = %entry
  %mul = shl nsw i32 %N, 1
  br label %if.end

if.end:                                           ; preds = %if.else, %for.end
  %sum.1 = phi i32 [ %shl, %for.end ], [ %mul, %if.else ]
  ret i32 %sum.1
}

declare i32 @something(...)

; Check that we do not perform the shrink-wrapping inside the loop even
; though that would be legal. The cost model must prevent that.
; CHECK-LABEL: freqSaveAndRestoreOutsideLoop2:
; Prologue code.
; Make sure we save the CSR used in the inline asm: rbx.
; CHECK: pushq %rbx
; CHECK: nop
; CHECK: xorl [[SUM:%e[a-z]+]], [[SUM]]
; CHECK-NEXT: movl $10, [[IV:%e[a-z]+]]
; Next BB.
; CHECK: [[LOOP_LABEL:LBB[0-9_]+]]: ## %for.body
; CHECK: movl $1, [[TMP:%e[a-z]+]]
; CHECK: addl [[TMP]], [[SUM]]
; CHECK-NEXT: decl [[IV]]
; CHECK-NEXT: jne [[LOOP_LABEL]]
; Next BB.
; CHECK: ## %for.exit
; CHECK: nop
; CHECK: popq %rbx
; CHECK-NEXT: retq
define i32 @freqSaveAndRestoreOutsideLoop2(i32 %cond) {
entry:
  br label %for.preheader

for.preheader:
  tail call void asm "nop", ""()
  br label %for.body

for.body:                                         ; preds = %for.body, %entry
  %i.04 = phi i32 [ 0, %for.preheader ], [ %inc, %for.body ]
  %sum.03 = phi i32 [ 0, %for.preheader ], [ %add, %for.body ]
  %call = tail call i32 asm "movl $$1, $0", "=r,~{ebx}"()
  %add = add nsw i32 %call, %sum.03
  %inc = add nuw nsw i32 %i.04, 1
  %exitcond = icmp eq i32 %inc, 10
  br i1 %exitcond, label %for.exit, label %for.body

for.exit:
  tail call void asm "nop", ""()
  br label %for.end

for.end:                                          ; preds = %for.body
  ret i32 %add
}

; Check with a more complex case that we do not have save within the loop and
; restore outside.
; CHECK-LABEL: loopInfoSaveOutsideLoop:
;
; ENABLE: testl %edi, %edi
; ENABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; Make sure we save the CSR used in the inline asm: rbx.
; CHECK: pushq %rbx
;
; DISABLE: testl %edi, %edi
; DISABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; CHECK: nop
; CHECK: xorl [[SUM:%esi]], [[SUM]]
; CHECK-NEXT: movl $10, [[IV:%e[a-z]+]]
;
; CHECK: [[LOOP_LABEL:LBB[0-9_]+]]: ## %for.body
; CHECK: movl $1, [[TMP:%e[a-z]+]]
; CHECK: addl [[TMP]], [[SUM]]
; CHECK-NEXT: decl [[IV]]
; CHECK-NEXT: jne [[LOOP_LABEL]]
; Next BB.
; CHECK: nop
; CHECK: shll $3, [[SUM]]
;
; DISABLE: jmp [[EPILOG_BB:LBB[0-9_]+]]
;
; DISABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; DISABLE: addl %esi, %esi
; DISABLE: [[EPILOG_BB]]: ## %if.end
;
; Epilogue code.
; CHECK-DAG: popq %rbx
; CHECK-DAG: movl %esi, %eax
; CHECK: retq
;
; ENABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; ENABLE: addl %esi, %esi
; ENABLE-NEXT: movl %esi, %eax
; ENABLE-NEXT: retq
define i32 @loopInfoSaveOutsideLoop(i32 %cond, i32 %N) {
entry:
  %tobool = icmp eq i32 %cond, 0
  br i1 %tobool, label %if.else, label %for.preheader

for.preheader:
  tail call void asm "nop", ""()
  br label %for.body

for.body:                                         ; preds = %entry, %for.body
  %i.05 = phi i32 [ %inc, %for.body ], [ 0, %for.preheader ]
  %sum.04 = phi i32 [ %add, %for.body ], [ 0, %for.preheader ]
  %call = tail call i32 asm "movl $$1, $0", "=r,~{ebx}"()
  %add = add nsw i32 %call, %sum.04
  %inc = add nuw nsw i32 %i.05, 1
  %exitcond = icmp eq i32 %inc, 10
  br i1 %exitcond, label %for.end, label %for.body

for.end:                                          ; preds = %for.body
  tail call void asm "nop", "~{ebx}"()
  %shl = shl i32 %add, 3
  br label %if.end

if.else:                                          ; preds = %entry
  %mul = shl nsw i32 %N, 1
  br label %if.end

if.end:                                           ; preds = %if.else, %for.end
  %sum.1 = phi i32 [ %shl, %for.end ], [ %mul, %if.else ]
  ret i32 %sum.1
}

declare void @somethingElse(...)

; Check with a more complex case that we do not have restore within the loop and
; save outside.
; CHECK-LABEL: loopInfoRestoreOutsideLoop:
;
; ENABLE: testl %edi, %edi
; ENABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; Make sure we save the CSR used in the inline asm: rbx.
; CHECK: pushq %rbx
;
; DISABLE: testl %edi, %edi
; DISABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; CHECK: nop
; CHECK: xorl [[SUM:%esi]], [[SUM]]
; CHECK-NEXT: movl $10, [[IV:%e[a-z]+]]
;
; CHECK: [[LOOP_LABEL:LBB[0-9_]+]]: ## %for.body
; CHECK: movl $1, [[TMP:%e[a-z]+]]
; CHECK: addl [[TMP]], [[SUM]]
; CHECK-NEXT: decl [[IV]]
; CHECK-NEXT: jne [[LOOP_LABEL]]
; Next BB.
; CHECK: shll $3, [[SUM]]
;
; DISABLE: jmp [[EPILOG_BB:LBB[0-9_]+]]
;
; DISABLE: [[ELSE_LABEL]]: ## %if.else

; Shift second argument by one and store into returned register.
; DISABLE: addl %esi, %esi
; DISABLE: [[EPILOG_BB]]: ## %if.end
;
; Epilogue code.
; CHECK-DAG: popq %rbx
; CHECK-DAG: movl %esi, %eax
; CHECK: retq
;
; ENABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; ENABLE: addl %esi, %esi
; ENABLE-NEXT: movl %esi, %eax
; ENABLE-NEXT: retq
define i32 @loopInfoRestoreOutsideLoop(i32 %cond, i32 %N) #0 {
entry:
  %tobool = icmp eq i32 %cond, 0
  br i1 %tobool, label %if.else, label %if.then

if.then:                                          ; preds = %entry
  tail call void asm "nop", "~{ebx}"()
  br label %for.body

for.body:                                         ; preds = %for.body, %if.then
  %i.05 = phi i32 [ 0, %if.then ], [ %inc, %for.body ]
  %sum.04 = phi i32 [ 0, %if.then ], [ %add, %for.body ]
  %call = tail call i32 asm "movl $$1, $0", "=r,~{ebx}"()
  %add = add nsw i32 %call, %sum.04
  %inc = add nuw nsw i32 %i.05, 1
  %exitcond = icmp eq i32 %inc, 10
  br i1 %exitcond, label %for.end, label %for.body

for.end:                                          ; preds = %for.body
  %shl = shl i32 %add, 3
  br label %if.end

if.else:                                          ; preds = %entry
  %mul = shl nsw i32 %N, 1
  br label %if.end

if.end:                                           ; preds = %if.else, %for.end
  %sum.1 = phi i32 [ %shl, %for.end ], [ %mul, %if.else ]
  ret i32 %sum.1
}

; Check that we handle function with no frame information correctly.
; CHECK-LABEL: emptyFrame:
; CHECK: ## %entry
; CHECK-NEXT: xorl %eax, %eax
; CHECK-NEXT: retq
define i32 @emptyFrame() {
entry:
  ret i32 0
}

; Check that we handle inline asm correctly.
; CHECK-LABEL: inlineAsm:
;
; ENABLE: testl %edi, %edi
; ENABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; Make sure we save the CSR used in the inline asm: rbx.
; CHECK: pushq %rbx
;
; DISABLE: testl %edi, %edi
; DISABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; CHECK: nop
; CHECK: movl $10, [[IV:%e[a-z]+]]
;
; CHECK: [[LOOP_LABEL:LBB[0-9_]+]]: ## %for.body
; Inline asm statement.
; CHECK: addl $1, %ebx
; CHECK: decl [[IV]]
; CHECK-NEXT: jne [[LOOP_LABEL]]
; Next BB.
; CHECK: nop
; CHECK: xorl %esi, %esi
;
; DISABLE: jmp [[EPILOG_BB:LBB[0-9_]+]]
;
; DISABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; DISABLE: addl %esi, %esi
; DISABLE: [[EPILOG_BB]]: ## %if.end
;
; Epilogue code.
; CHECK-DAG: popq %rbx
; CHECK-DAG: movl %esi, %eax
; CHECK: retq
;
; ENABLE: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; ENABLE: addl %esi, %esi
; ENABLE-NEXT: movl %esi, %eax
; ENABLE-NEXT: retq
define i32 @inlineAsm(i32 %cond, i32 %N) {
entry:
  %tobool = icmp eq i32 %cond, 0
  br i1 %tobool, label %if.else, label %for.preheader

for.preheader:
  tail call void asm "nop", ""()
  br label %for.body

for.body:                                         ; preds = %entry, %for.body
  %i.03 = phi i32 [ %inc, %for.body ], [ 0, %for.preheader ]
  tail call void asm "addl $$1, %ebx", "~{ebx}"()
  %inc = add nuw nsw i32 %i.03, 1
  %exitcond = icmp eq i32 %inc, 10
  br i1 %exitcond, label %for.exit, label %for.body

for.exit:
  tail call void asm "nop", ""()
  br label %if.end

if.else:                                          ; preds = %entry
  %mul = shl nsw i32 %N, 1
  br label %if.end

if.end:                                           ; preds = %for.body, %if.else
  %sum.0 = phi i32 [ %mul, %if.else ], [ 0, %for.exit ]
  ret i32 %sum.0
}

; Check that we handle calls to variadic functions correctly.
; CHECK-LABEL: callVariadicFunc:
;
; ENABLE: testl %edi, %edi
; ENABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Prologue code.
; CHECK: pushq
;
; DISABLE: testl %edi, %edi
; DISABLE-NEXT: je [[ELSE_LABEL:LBB[0-9_]+]]
;
; Setup of the varags.
; CHECK: movl %esi, (%rsp)
; CHECK-NEXT: xorl %eax, %eax
; CHECK-NEXT: %esi, %edi
; CHECK-NEXT: %esi, %edx
; CHECK-NEXT: %esi, %r8d
; CHECK-NEXT: %esi, %r9d
; CHECK-NEXT: %esi, %ecx
; CHECK-NEXT: callq _someVariadicFunc
; CHECK-NEXT: movl %eax, %esi
; CHECK-NEXT: shll $3, %esi
;
; ENABLE-NEXT: addq $8, %rsp
; ENABLE-NEXT: movl %esi, %eax
; ENABLE-NEXT: retq
;
; DISABLE: jmp [[IFEND_LABEL:LBB[0-9_]+]]
;
; CHECK: [[ELSE_LABEL]]: ## %if.else
; Shift second argument by one and store into returned register.
; CHECK: addl %esi, %esi
;
; DISABLE: [[IFEND_LABEL]]: ## %if.end
;
; Epilogue code.
; CHECK-NEXT: movl %esi, %eax
; DISABLE-NEXT: popq
; CHECK-NEXT: retq
define i32 @callVariadicFunc(i32 %cond, i32 %N) {
entry:
  %tobool = icmp eq i32 %cond, 0
  br i1 %tobool, label %if.else, label %if.then

if.then:                                          ; preds = %entry
  %call = tail call i32 (i32, ...) @someVariadicFunc(i32 %N, i32 %N, i32 %N, i32 %N, i32 %N, i32 %N, i32 %N)
  %shl = shl i32 %call, 3
  br label %if.end

if.else:                                          ; preds = %entry
  %mul = shl nsw i32 %N, 1
  br label %if.end

if.end:                                           ; preds = %if.else, %if.then
  %sum.0 = phi i32 [ %shl, %if.then ], [ %mul, %if.else ]
  ret i32 %sum.0
}

declare i32 @someVariadicFunc(i32, ...)

; Check that we use LEA not to clobber EFLAGS.
%struct.temp_slot = type { %struct.temp_slot*, %struct.rtx_def*, %struct.rtx_def*, i32, i64, %union.tree_node*, %union.tree_node*, i8, i8, i32, i32, i64, i64 }
%union.tree_node = type { %struct.tree_decl }
%struct.tree_decl = type { %struct.tree_common, i8*, i32, i32, %union.tree_node*, i48, %union.anon, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %union.tree_node*, %struct.rtx_def*, %struct.rtx_def*, %union.anon.1, %union.tree_node*, %union.tree_node*, %union.tree_node*, i64, %struct.lang_decl* }
%struct.tree_common = type { %union.tree_node*, %union.tree_node*, i32 }
%union.anon = type { i64 }
%union.anon.1 = type { %struct.function* }
%struct.function = type { %struct.eh_status*, %struct.stmt_status*, %struct.expr_status*, %struct.emit_status*, %struct.varasm_status*, i8*, %union.tree_node*, %struct.function*, i32, i32, i32, i32, %struct.rtx_def*, %struct.ix86_args, %struct.rtx_def*, %struct.rtx_def*, i8*, %struct.initial_value_struct*, i32, %union.tree_node*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %union.tree_node*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, i64, %union.tree_node*, %union.tree_node*, %struct.rtx_def*, %struct.rtx_def*, i32, %struct.rtx_def**, %struct.temp_slot*, i32, i32, i32, %struct.var_refs_queue*, i32, i32, i8*, %union.tree_node*, %struct.rtx_def*, i32, i32, %struct.machine_function*, i32, i32, %struct.language_function*, %struct.rtx_def*, i24 }
%struct.eh_status = type opaque
%struct.stmt_status = type opaque
%struct.expr_status = type { i32, i32, i32, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def*, %struct.rtx_def* }
%struct.emit_status = type { i32, i32, %struct.rtx_def*, %struct.rtx_def*, %union.tree_node*, %struct.sequence_stack*, i32, i32, i8*, i32, i8*, %union.tree_node**, %struct.rtx_def** }
%struct.sequence_stack = type { %struct.rtx_def*, %struct.rtx_def*, %union.tree_node*, %struct.sequence_stack* }
%struct.varasm_status = type opaque
%struct.ix86_args = type { i32, i32, i32, i32, i32, i32, i32 }
%struct.initial_value_struct = type opaque
%struct.var_refs_queue = type { %struct.rtx_def*, i32, i32, %struct.var_refs_queue* }
%struct.machine_function = type opaque
%struct.language_function = type opaque
%struct.lang_decl = type opaque
%struct.rtx_def = type { i32, [1 x %union.rtunion_def] }
%union.rtunion_def = type { i64 }

declare hidden fastcc %struct.temp_slot* @find_temp_slot_from_address(%struct.rtx_def* readonly)

; CHECK-LABEL: useLEA:
; DISABLE: pushq 
;
; CHECK: testq   %rdi, %rdi
; CHECK-NEXT: je      [[CLEANUP:LBB[0-9_]+]]
;
; CHECK: movzwl  (%rdi), [[BF_LOAD:%e[a-z]+]]
; CHECK-NEXT: cmpl $66, [[BF_LOAD]]
; CHECK-NEXT: jne [[CLEANUP]]
;
; CHECK: movq 8(%rdi), %rdi
; CHECK-NEXT: movzwl (%rdi), %e[[BF_LOAD2:[a-z]+]]
; CHECK-NEXT: leal -54(%r[[BF_LOAD2]]), [[TMP:%e[a-z]+]]
; CHECK-NEXT: cmpl $14, [[TMP]]
; CHECK-NEXT: ja [[LOR_LHS_FALSE:LBB[0-9_]+]]
;
; CHECK: movl $24599, [[TMP2:%e[a-z]+]]
; CHECK-NEXT: btl [[TMP]], [[TMP2]]
; CHECK-NEXT: jb [[CLEANUP]]
;
; CHECK: [[LOR_LHS_FALSE]]: ## %lor.lhs.false
; CHECK: cmpl $134, %e[[BF_LOAD2]]
; CHECK-NEXT: je [[CLEANUP]]
;
; CHECK: cmpl $140, %e[[BF_LOAD2]]
; CHECK-NEXT: je [[CLEANUP]]
;
; ENABLE: pushq
; CHECK: callq _find_temp_slot_from_address
; CHECK-NEXT: testq   %rax, %rax
;
; The adjustment must use LEA here (or be moved above the test).
; ENABLE-NEXT: leaq 8(%rsp), %rsp
;
; CHECK-NEXT: je [[CLEANUP]]
;
; CHECK: movb $1, 57(%rax)
;
; CHECK: [[CLEANUP]]: ## %cleanup
; DISABLE: popq
; CHECK-NEXT: retq
define void @useLEA(%struct.rtx_def* readonly %x) {
entry:
  %cmp = icmp eq %struct.rtx_def* %x, null
  br i1 %cmp, label %cleanup, label %if.end

if.end:                                           ; preds = %entry
  %tmp = getelementptr inbounds %struct.rtx_def, %struct.rtx_def* %x, i64 0, i32 0
  %bf.load = load i32, i32* %tmp, align 8
  %bf.clear = and i32 %bf.load, 65535
  %cmp1 = icmp eq i32 %bf.clear, 66
  br i1 %cmp1, label %lor.lhs.false, label %cleanup

lor.lhs.false:                                    ; preds = %if.end
  %arrayidx = getelementptr inbounds %struct.rtx_def, %struct.rtx_def* %x, i64 0, i32 1, i64 0
  %rtx = bitcast %union.rtunion_def* %arrayidx to %struct.rtx_def**
  %tmp1 = load %struct.rtx_def*, %struct.rtx_def** %rtx, align 8
  %tmp2 = getelementptr inbounds %struct.rtx_def, %struct.rtx_def* %tmp1, i64 0, i32 0
  %bf.load2 = load i32, i32* %tmp2, align 8
  %bf.clear3 = and i32 %bf.load2, 65535
  switch i32 %bf.clear3, label %if.end.55 [
    i32 67, label %cleanup
    i32 68, label %cleanup
    i32 54, label %cleanup
    i32 55, label %cleanup
    i32 58, label %cleanup
    i32 134, label %cleanup
    i32 56, label %cleanup
    i32 140, label %cleanup
  ]

if.end.55:                                        ; preds = %lor.lhs.false
  %call = tail call fastcc %struct.temp_slot* @find_temp_slot_from_address(%struct.rtx_def* %tmp1) #2
  %cmp59 = icmp eq %struct.temp_slot* %call, null
  br i1 %cmp59, label %cleanup, label %if.then.60

if.then.60:                                       ; preds = %if.end.55
  %addr_taken = getelementptr inbounds %struct.temp_slot, %struct.temp_slot* %call, i64 0, i32 8
  store i8 1, i8* %addr_taken, align 1
  br label %cleanup

cleanup:                                          ; preds = %if.then.60, %if.end.55, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %lor.lhs.false, %if.end, %entry
  ret void
}