test/Transforms/SimpleLoopUnswitch/exponential-switch-unswitch.ll - llvm - Git at Google

 ;
 ; Here we have 5-way unswitchable switch with each successor also having an unswitchable
 ; exiting branch in it. If we start unswitching those branches we start duplicating the
 ; whole switch. This can easily lead to exponential behavior w/o proper control.
 ; On a real-life testcase there was 16-way switch and that took forever to compile w/o
 ; a cost control.
 ;
 ;
 ; When we use the stricted multiplier candidates formula (unscaled candidates == 0)
 ; we should be getting just a single loop.
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
 ; RUN:     -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
 ; RUN:     -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ; With relaxed candidates multiplier (unscaled candidates == 8) we should allow
 ; some unswitches to happen until siblings multiplier starts kicking in:
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-RELAX
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-RELAX
 ;
 ; With relaxed candidates multiplier (unscaled candidates == 8) and with relaxed
 ; siblings multiplier for top-level loops (toplevel-div == 8) we should get
 ; considerably more copies of the loop (especially top-level ones).
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=8 \
 ; RUN:     -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-RELAX2
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=8 \
 ; RUN:     -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-RELAX2
 ;
 ; We get hundreds of copies of the loop when cost multiplier is disabled:
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=false \
 ; RUN:     -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-MAX
 ;
 ; RUN: opt < %s -enable-unswitch-cost-multiplier=false \
 ; RUN:     -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-MAX

 ; Single loop nest, not unswitched
 ; LOOP1:     Loop at depth 1 containing:
 ; LOOP1-NOT: Loop at depth 1 containing:
 ; LOOP1:     Loop at depth 2 containing:
 ; LOOP1-NOT: Loop at depth 2 containing:
 ;
 ; Somewhat relaxed restrictions on candidates:
 ; LOOP-RELAX-COUNT-5:     Loop at depth 1 containing:
 ; LOOP-RELAX-NOT: Loop at depth 1 containing:
 ; LOOP-RELAX-COUNT-32:     Loop at depth 2 containing:
 ; LOOP-RELAX-NOT: Loop at depth 2 containing:
 ;
 ; Even more relaxed restrictions on candidates and siblings.
 ; LOOP-RELAX2-COUNT-11:     Loop at depth 1 containing:
 ; LOOP-RELAX2-NOT: Loop at depth 1 containing:
 ; LOOP-RELAX2-COUNT-40:     Loop at depth 2 containing:
 ; LOOP-RELAX-NOT: Loop at depth 2 containing:
 ;
 ; Unswitched as much as it could (with multiplier disabled).
 ; LOOP-MAX-COUNT-56:     Loop at depth 1 containing:
 ; LOOP-MAX-NOT: Loop at depth 1 containing:
 ; LOOP-MAX-COUNT-111:     Loop at depth 2 containing:
 ; LOOP-MAX-NOT: Loop at depth 2 containing:

 define i32 @loop_switch(i32* %addr, i32 %c1, i32 %c2) {
 entry:
   %addr1 = getelementptr i32, i32* %addr, i64 0
   %addr2 = getelementptr i32, i32* %addr, i64 1
   %check0 = icmp eq i32 %c2, 0
   %check1 = icmp eq i32 %c2, 31
   %check2 = icmp eq i32 %c2, 32
   %check3 = icmp eq i32 %c2, 33
   %check4 = icmp eq i32 %c2, 34
   br label %outer_loop

 outer_loop:
   %iv1 = phi i32 [0, %entry], [%iv1.next, %outer_latch]
   %iv1.next = add i32 %iv1, 1
   br label %inner_loop
 inner_loop:
   %iv2 = phi i32 [0, %outer_loop], [%iv2.next, %inner_latch]
   %iv2.next = add i32 %iv2, 1
   switch i32 %c1, label %inner_latch [
     i32 0, label %case0
     i32 1, label %case1
     i32 2, label %case2
     i32 3, label %case3
     i32 4, label %case4
   ]

 case4:
   br i1 %check4, label %exit, label %inner_latch
 case3:
   br i1 %check3, label %exit, label %inner_latch
 case2:
   br i1 %check2, label %exit, label %inner_latch
 case1:
   br i1 %check1, label %exit, label %inner_latch
 case0:
   br i1 %check0, label %exit, label %inner_latch

 inner_latch:
   store volatile i32 0, i32* %addr1
   %test_inner = icmp slt i32 %iv2, 50
   br i1 %test_inner, label %inner_loop, label %outer_latch

 outer_latch:
   store volatile i32 0, i32* %addr2
   %test_outer = icmp slt i32 %iv1, 50
   br i1 %test_outer, label %outer_loop, label %exit

 exit:                                            ; preds = %bci_0
   ret i32 1
 }
	;
	; Here we have 5-way unswitchable switch with each successor also having an unswitchable
	; exiting branch in it. If we start unswitching those branches we start duplicating the
	; whole switch. This can easily lead to exponential behavior w/o proper control.
	; On a real-life testcase there was 16-way switch and that took forever to compile w/o
	; a cost control.
	;
	;
	; When we use the stricted multiplier candidates formula (unscaled candidates == 0)
	; we should be getting just a single loop.
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
	; RUN: -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
	; RUN: -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	; With relaxed candidates multiplier (unscaled candidates == 8) we should allow
	; some unswitches to happen until siblings multiplier starts kicking in:
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-RELAX
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-RELAX
	;
	; With relaxed candidates multiplier (unscaled candidates == 8) and with relaxed
	; siblings multiplier for top-level loops (toplevel-div == 8) we should get
	; considerably more copies of the loop (especially top-level ones).
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=8 \
	; RUN: -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-RELAX2
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=8 -unswitch-siblings-toplevel-div=8 \
	; RUN: -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-RELAX2
	;
	; We get hundreds of copies of the loop when cost multiplier is disabled:
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=false \
	; RUN: -passes='loop(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-MAX
	;
	; RUN: opt < %s -enable-unswitch-cost-multiplier=false \
	; RUN: -passes='loop-mssa(unswitch<nontrivial>),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-MAX

	; Single loop nest, not unswitched
	; LOOP1: Loop at depth 1 containing:
	; LOOP1-NOT: Loop at depth 1 containing:
	; LOOP1: Loop at depth 2 containing:
	; LOOP1-NOT: Loop at depth 2 containing:
	;
	; Somewhat relaxed restrictions on candidates:
	; LOOP-RELAX-COUNT-5: Loop at depth 1 containing:
	; LOOP-RELAX-NOT: Loop at depth 1 containing:
	; LOOP-RELAX-COUNT-32: Loop at depth 2 containing:
	; LOOP-RELAX-NOT: Loop at depth 2 containing:
	;
	; Even more relaxed restrictions on candidates and siblings.
	; LOOP-RELAX2-COUNT-11: Loop at depth 1 containing:
	; LOOP-RELAX2-NOT: Loop at depth 1 containing:
	; LOOP-RELAX2-COUNT-40: Loop at depth 2 containing:
	; LOOP-RELAX-NOT: Loop at depth 2 containing:
	;
	; Unswitched as much as it could (with multiplier disabled).
	; LOOP-MAX-COUNT-56: Loop at depth 1 containing:
	; LOOP-MAX-NOT: Loop at depth 1 containing:
	; LOOP-MAX-COUNT-111: Loop at depth 2 containing:
	; LOOP-MAX-NOT: Loop at depth 2 containing:

	define i32 @loop_switch(i32* %addr, i32 %c1, i32 %c2) {
	entry:
	%addr1 = getelementptr i32, i32* %addr, i64 0
	%addr2 = getelementptr i32, i32* %addr, i64 1
	%check0 = icmp eq i32 %c2, 0
	%check1 = icmp eq i32 %c2, 31
	%check2 = icmp eq i32 %c2, 32
	%check3 = icmp eq i32 %c2, 33
	%check4 = icmp eq i32 %c2, 34
	br label %outer_loop

	outer_loop:
	%iv1 = phi i32 [0, %entry], [%iv1.next, %outer_latch]
	%iv1.next = add i32 %iv1, 1
	br label %inner_loop
	inner_loop:
	%iv2 = phi i32 [0, %outer_loop], [%iv2.next, %inner_latch]
	%iv2.next = add i32 %iv2, 1
	switch i32 %c1, label %inner_latch [
	i32 0, label %case0
	i32 1, label %case1
	i32 2, label %case2
	i32 3, label %case3
	i32 4, label %case4
	]

	case4:
	br i1 %check4, label %exit, label %inner_latch
	case3:
	br i1 %check3, label %exit, label %inner_latch
	case2:
	br i1 %check2, label %exit, label %inner_latch
	case1:
	br i1 %check1, label %exit, label %inner_latch
	case0:
	br i1 %check0, label %exit, label %inner_latch

	inner_latch:
	store volatile i32 0, i32* %addr1
	%test_inner = icmp slt i32 %iv2, 50
	br i1 %test_inner, label %inner_loop, label %outer_latch

	outer_latch:
	store volatile i32 0, i32* %addr2
	%test_outer = icmp slt i32 %iv1, 50
	br i1 %test_outer, label %outer_loop, label %exit

	exit: ; preds = %bci_0
	ret i32 1
	}