llvm/test/Bitcode/thinlto-function-summary-refgraph.ll - toolchain/llvm-project - Gitiles

 ; Test to check both the callgraph and refgraph in summary
 ; RUN: opt -module-summary %s -o %t.o
 ; RUN: llvm-bcanalyzer -dump %t.o | FileCheck %s

 ; See if the calls and other references are recorded properly using the
 ; expected value id and other information as appropriate (callsite cout
 ; for calls). Use different linkage types for the various test cases to
 ; distinguish the test cases here (op1 contains the linkage type).
 ; Note that op3 contains the # non-call references.
 ; This also ensures that we didn't include a call or reference to intrinsic
 ; llvm.ctpop.i8.
 ; CHECK:       <GLOBALVAL_SUMMARY_BLOCK
 ; Function main contains call to func, as well as address reference to func:
 ; CHECK-DAG:    <PERMODULE {{.*}} op0=[[MAINID:[0-9]+]] op1=0 {{.*}} op3=1 op4=[[FUNCID:[0-9]+]] op5=[[FUNCID]] op6=1/>
 ; Function W contains a call to func3 as well as a reference to globalvar:
 ; CHECK-DAG:    <PERMODULE {{.*}} op0=[[WID:[0-9]+]] op1=5 {{.*}} op3=1 op4=[[GLOBALVARID:[0-9]+]] op5=[[FUNC3ID:[0-9]+]] op6=1/>
 ; Function X contains call to foo, as well as address reference to foo
 ; which is in the same instruction as the call:
 ; CHECK-DAG:    <PERMODULE {{.*}} op0=[[XID:[0-9]+]] op1=1 {{.*}} op3=1 op4=[[FOOID:[0-9]+]] op5=[[FOOID]] op6=1/>
 ; Function Y contains call to func2, and ensures we don't incorrectly add
 ; a reference to it when reached while earlier analyzing the phi using its
 ; return value:
 ; CHECK-DAG:    <PERMODULE {{.*}} op0=[[YID:[0-9]+]] op1=8 {{.*}} op3=0 op4=[[FUNC2ID:[0-9]+]] op5=1/>
 ; Function Z contains call to func2, and ensures we don't incorrectly add
 ; a reference to it when reached while analyzing subsequent use of its return
 ; value:
 ; CHECK-DAG:    <PERMODULE {{.*}} op0=[[ZID:[0-9]+]] op1=3 {{.*}} op3=0 op4=[[FUNC2ID:[0-9]+]] op5=1/>
 ; Variable bar initialization contains address reference to func:
 ; CHECK-DAG:    <PERMODULE_GLOBALVAR_INIT_REFS {{.*}} op0=[[BARID:[0-9]+]] op1=0 op2=[[FUNCID]]/>
 ; CHECK:  </GLOBALVAL_SUMMARY_BLOCK>

 ; CHECK-NEXT:  <VALUE_SYMTAB
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[BARID]] {{.*}} record string = 'bar'
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[FUNCID]] {{.*}} record string = 'func'
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[FOOID]] {{.*}} record string = 'foo'
 ; CHECK-DAG:    <FNENTRY {{.*}} op0=[[MAINID]] {{.*}} record string = 'main'
 ; CHECK-DAG:    <FNENTRY {{.*}} op0=[[WID]] {{.*}} record string = 'W'
 ; CHECK-DAG:    <FNENTRY {{.*}} op0=[[XID]] {{.*}} record string = 'X'
 ; CHECK-DAG:    <FNENTRY {{.*}} op0=[[YID]] {{.*}} record string = 'Y'
 ; CHECK-DAG:    <FNENTRY {{.*}} op0=[[ZID]] {{.*}} record string = 'Z'
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[FUNC2ID]] {{.*}} record string = 'func2'
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[FUNC3ID]] {{.*}} record string = 'func3'
 ; CHECK-DAG:    <ENTRY {{.*}} op0=[[GLOBALVARID]] {{.*}} record string = 'globalvar'
 ; CHECK:  </VALUE_SYMTAB>

 ; ModuleID = 'thinlto-function-summary-refgraph.ll'
 target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"
 target triple = "x86_64-unknown-linux-gnu"

 @bar = global void (...)* bitcast (void ()* @func to void (...)*), align 8

 @globalvar = global i32 0, align 4

 declare void @func() #0
 declare i32 @func2(...) #1
 declare void @foo(i8* %F) #0
 declare i32 @func3(i32* dereferenceable(4)) #2

 ; Function Attrs: nounwind uwtable
 define weak_odr void @W() #0 {
 entry:
   %call = tail call i32 @func3(i32* nonnull dereferenceable(4) @globalvar)
   ret void
 }

 ; Function Attrs: nounwind uwtable
 define available_externally void @X() #0 {
 entry:
   call void @foo(i8* bitcast (void (i8*)* @foo to i8*))
   ret void
 }

 ; Function Attrs: nounwind uwtable
 define private i32 @Y(i32 %i) #0 {
 entry:
   %cmp3 = icmp slt i32 %i, 10
   br i1 %cmp3, label %while.body.preheader, label %while.end

 while.body.preheader:                             ; preds = %entry
   br label %while.body

 while.body:                                       ; preds = %while.body.preheader, %while.body
   %j.05 = phi i32 [ %add, %while.body ], [ 0, %while.body.preheader ]
   %i.addr.04 = phi i32 [ %inc, %while.body ], [ %i, %while.body.preheader ]
   %inc = add nsw i32 %i.addr.04, 1
   %call = tail call i32 (...) @func2() #2
   %add = add nsw i32 %call, %j.05
   %exitcond = icmp eq i32 %inc, 10
   br i1 %exitcond, label %while.end.loopexit, label %while.body

 while.end.loopexit:                               ; preds = %while.body
   %add.lcssa = phi i32 [ %add, %while.body ]
   br label %while.end

 while.end:                                        ; preds = %while.end.loopexit, %entry
   %j.0.lcssa = phi i32 [ 0, %entry ], [ %add.lcssa, %while.end.loopexit ]
   ret i32 %j.0.lcssa
 }

 ; Function Attrs: nounwind uwtable
 define linkonce_odr i32 @Z() #0 {
 entry:
   %call = tail call i32 (...) @func2() #2
   ret i32 %call
 }

 declare i8 @llvm.ctpop.i8(i8)

 ; Function Attrs: nounwind uwtable
 define i32 @main() #0 {
 entry:
   %retval = alloca i32, align 4
   %foo = alloca void (...)*, align 8
   store i32 0, i32* %retval, align 4
   store void (...)* bitcast (void ()* @func to void (...)*), void (...)** %foo, align 8
   %0 = load void (...)*, void (...)** %foo, align 8
   call void (...) %0()
   call void @func()
   call i8  @llvm.ctpop.i8( i8 10 )
   ret i32 0
 }
	; Test to check both the callgraph and refgraph in summary
	; RUN: opt -module-summary %s -o %t.o
	; RUN: llvm-bcanalyzer -dump %t.o \| FileCheck %s

	; See if the calls and other references are recorded properly using the
	; expected value id and other information as appropriate (callsite cout
	; for calls). Use different linkage types for the various test cases to
	; distinguish the test cases here (op1 contains the linkage type).
	; Note that op3 contains the # non-call references.
	; This also ensures that we didn't include a call or reference to intrinsic
	; llvm.ctpop.i8.
	; CHECK: <GLOBALVAL_SUMMARY_BLOCK
	; Function main contains call to func, as well as address reference to func:
	; CHECK-DAG: <PERMODULE {{.}} op0=[[MAINID:[0-9]+]] op1=0 {{.}} op3=1 op4=[[FUNCID:[0-9]+]] op5=[[FUNCID]] op6=1/>
	; Function W contains a call to func3 as well as a reference to globalvar:
	; CHECK-DAG: <PERMODULE {{.}} op0=[[WID:[0-9]+]] op1=5 {{.}} op3=1 op4=[[GLOBALVARID:[0-9]+]] op5=[[FUNC3ID:[0-9]+]] op6=1/>
	; Function X contains call to foo, as well as address reference to foo
	; which is in the same instruction as the call:
	; CHECK-DAG: <PERMODULE {{.}} op0=[[XID:[0-9]+]] op1=1 {{.}} op3=1 op4=[[FOOID:[0-9]+]] op5=[[FOOID]] op6=1/>
	; Function Y contains call to func2, and ensures we don't incorrectly add
	; a reference to it when reached while earlier analyzing the phi using its
	; return value:
	; CHECK-DAG: <PERMODULE {{.}} op0=[[YID:[0-9]+]] op1=8 {{.}} op3=0 op4=[[FUNC2ID:[0-9]+]] op5=1/>
	; Function Z contains call to func2, and ensures we don't incorrectly add
	; a reference to it when reached while analyzing subsequent use of its return
	; value:
	; CHECK-DAG: <PERMODULE {{.}} op0=[[ZID:[0-9]+]] op1=3 {{.}} op3=0 op4=[[FUNC2ID:[0-9]+]] op5=1/>
	; Variable bar initialization contains address reference to func:
	; CHECK-DAG: <PERMODULE_GLOBALVAR_INIT_REFS {{.*}} op0=[[BARID:[0-9]+]] op1=0 op2=[[FUNCID]]/>
	; CHECK: </GLOBALVAL_SUMMARY_BLOCK>

	; CHECK-NEXT: <VALUE_SYMTAB
	; CHECK-DAG: <ENTRY {{.}} op0=[[BARID]] {{.}} record string = 'bar'
	; CHECK-DAG: <ENTRY {{.}} op0=[[FUNCID]] {{.}} record string = 'func'
	; CHECK-DAG: <ENTRY {{.}} op0=[[FOOID]] {{.}} record string = 'foo'
	; CHECK-DAG: <FNENTRY {{.}} op0=[[MAINID]] {{.}} record string = 'main'
	; CHECK-DAG: <FNENTRY {{.}} op0=[[WID]] {{.}} record string = 'W'
	; CHECK-DAG: <FNENTRY {{.}} op0=[[XID]] {{.}} record string = 'X'
	; CHECK-DAG: <FNENTRY {{.}} op0=[[YID]] {{.}} record string = 'Y'
	; CHECK-DAG: <FNENTRY {{.}} op0=[[ZID]] {{.}} record string = 'Z'
	; CHECK-DAG: <ENTRY {{.}} op0=[[FUNC2ID]] {{.}} record string = 'func2'
	; CHECK-DAG: <ENTRY {{.}} op0=[[FUNC3ID]] {{.}} record string = 'func3'
	; CHECK-DAG: <ENTRY {{.}} op0=[[GLOBALVARID]] {{.}} record string = 'globalvar'
	; CHECK: </VALUE_SYMTAB>

	; ModuleID = 'thinlto-function-summary-refgraph.ll'
	target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"
	target triple = "x86_64-unknown-linux-gnu"

	@bar = global void (...)* bitcast (void ()* @func to void (...)*), align 8

	@globalvar = global i32 0, align 4

	declare void @func() #0
	declare i32 @func2(...) #1
	declare void @foo(i8* %F) #0
	declare i32 @func3(i32* dereferenceable(4)) #2

	; Function Attrs: nounwind uwtable
	define weak_odr void @W() #0 {
	entry:
	%call = tail call i32 @func3(i32* nonnull dereferenceable(4) @globalvar)
	ret void
	}

	; Function Attrs: nounwind uwtable
	define available_externally void @X() #0 {
	entry:
	call void @foo(i8* bitcast (void (i8) @foo to i8*))
	ret void
	}

	; Function Attrs: nounwind uwtable
	define private i32 @Y(i32 %i) #0 {
	entry:
	%cmp3 = icmp slt i32 %i, 10
	br i1 %cmp3, label %while.body.preheader, label %while.end

	while.body.preheader: ; preds = %entry
	br label %while.body

	while.body: ; preds = %while.body.preheader, %while.body
	%j.05 = phi i32 [ %add, %while.body ], [ 0, %while.body.preheader ]
	%i.addr.04 = phi i32 [ %inc, %while.body ], [ %i, %while.body.preheader ]
	%inc = add nsw i32 %i.addr.04, 1
	%call = tail call i32 (...) @func2() #2
	%add = add nsw i32 %call, %j.05
	%exitcond = icmp eq i32 %inc, 10
	br i1 %exitcond, label %while.end.loopexit, label %while.body

	while.end.loopexit: ; preds = %while.body
	%add.lcssa = phi i32 [ %add, %while.body ]
	br label %while.end

	while.end: ; preds = %while.end.loopexit, %entry
	%j.0.lcssa = phi i32 [ 0, %entry ], [ %add.lcssa, %while.end.loopexit ]
	ret i32 %j.0.lcssa
	}

	; Function Attrs: nounwind uwtable
	define linkonce_odr i32 @Z() #0 {
	entry:
	%call = tail call i32 (...) @func2() #2
	ret i32 %call
	}

	declare i8 @llvm.ctpop.i8(i8)

	; Function Attrs: nounwind uwtable
	define i32 @main() #0 {
	entry:
	%retval = alloca i32, align 4
	%foo = alloca void (...)*, align 8
	store i32 0, i32* %retval, align 4
	store void (...)* bitcast (void ()* @func to void (...)), void (...)* %foo, align 8
	%0 = load void (...), void (...)* %foo, align 8
	call void (...) %0()
	call void @func()
	call i8 @llvm.ctpop.i8( i8 10 )
	ret i32 0
	}