test/Transforms/SimpleLoopUnswitch/exponential-nontrivial-unswitch-nested2.ll - llvm - Git at Google

 ;
 ; Here all the branches we unswitch are exiting from the inner loop.
 ; That means we should not be getting exponential behavior on inner-loop
 ; unswitch. In fact there should be just a single version of inner-loop,
 ; with possibly some outer loop copies.
 ;
 ; There should be just a single copy of each loop when strictest mutiplier
 ; candidates formula (unscaled candidates == 0) is enforced:

 ; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop(unswitch),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
 ; RUN:     -passes='loop(unswitch),print<loops>' -disable-output 2>&1 | FileCheck %s --check-prefixes=LOOP1
 ;
 ;
 ; When we relax the candidates part of a multiplier formula
 ; (unscaled candidates == 2) we start getting some unswitches in outer loops,
 ; which leads to siblings multiplier kicking in.
 ;
 ; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=3 -unswitch-siblings-toplevel-div=1 \
 ; RUN:     -passes='loop(unswitch),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-UNSCALE3-DIV1
 ;
 ; NB: sort -b is essential here and below, otherwise blanks might lead to different
 ; order depending on locale.
 ;
 ; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
 ; RUN:     -unswitch-num-initial-unscaled-candidates=3 -unswitch-siblings-toplevel-div=2 \
 ; RUN:     -passes='loop(unswitch),print<loops>' -disable-output 2>&1 | \
 ; RUN:     sort -b -k 1 | FileCheck %s --check-prefixes=LOOP-UNSCALE3-DIV2
 ;
 ; With disabled cost-multiplier we get maximal possible amount of unswitches.
 ;
 ; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=false \
 ; RUN:     -passes='loop(unswitch),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:
 ; LOOP1:     Loop at depth 3 containing:
 ; LOOP1-NOT:  Loop at depth 3 containing:
 ;
 ; Half unswitched loop nests, with unscaled3 and div1 it gets less depth1 loops unswitched
 ; since they have more cost.
 ; LOOP-UNSCALE3-DIV1-COUNT-4: Loop at depth 1 containing:
 ; LOOP-UNSCALE3-DIV1-NOT:      Loop at depth 1 containing:
 ; LOOP-UNSCALE3-DIV1-COUNT-1: Loop at depth 2 containing:
 ; LOOP-UNSCALE3-DIV1-NOT:      Loop at depth 2 containing:
 ; LOOP-UNSCALE3-DIV1-COUNT-1: Loop at depth 3 containing:
 ; LOOP-UNSCALE3-DIV1-NOT:      Loop at depth 3 containing:
 ;
 ; Half unswitched loop nests, with unscaled3 and div2 it gets more depth1 loops unswitched
 ; as div2 kicks in.
 ; LOOP-UNSCALE3-DIV2-COUNT-6: Loop at depth 1 containing:
 ; LOOP-UNSCALE3-DIV2-NOT:      Loop at depth 1 containing:
 ; LOOP-UNSCALE3-DIV2-COUNT-1: Loop at depth 2 containing:
 ; LOOP-UNSCALE3-DIV2-NOT:      Loop at depth 2 containing:
 ; LOOP-UNSCALE3-DIV2-COUNT-1: Loop at depth 3 containing:
 ; LOOP-UNSCALE3-DIV2-NOT:      Loop at depth 3 containing:
 ;
 ; Maximally unswitched (copy of the outer loop per each condition)
 ; LOOP-MAX-COUNT-6: Loop at depth 1 containing:
 ; LOOP-MAX-NOT:      Loop at depth 1 containing:
 ; LOOP-MAX-COUNT-1: Loop at depth 2 containing:
 ; LOOP-MAX-NOT:      Loop at depth 2 containing:
 ; LOOP-MAX-COUNT-1: Loop at depth 3 containing:
 ; LOOP-MAX-NOT:      Loop at depth 3 containing:

 declare void @bar()

 define void @loop_nested3_conds5(i32* %addr, i1 %c1, i1 %c2, i1 %c3, i1 %c4, i1 %c5) {
 entry:
   %addr1 = getelementptr i32, i32* %addr, i64 0
   %addr2 = getelementptr i32, i32* %addr, i64 1
   %addr3 = getelementptr i32, i32* %addr, i64 2
   br label %outer
 outer:
   %iv1 = phi i32 [0, %entry], [%iv1.next, %outer_latch]
   %iv1.next = add i32 %iv1, 1
   ;; skip nontrivial unswitch
   call void @bar()
   br label %middle
 middle:
   %iv2 = phi i32 [0, %outer], [%iv2.next, %middle_latch]
   %iv2.next = add i32 %iv2, 1
   ;; skip nontrivial unswitch
   call void @bar()
   br label %loop
 loop:
   %iv3 = phi i32 [0, %middle], [%iv3.next, %loop_latch]
   %iv3.next = add i32 %iv3, 1
   ;; skip nontrivial unswitch
   call void @bar()
   br i1 %c1, label %loop_next1_left, label %outer_latch
 loop_next1_left:
   br label %loop_next1
 loop_next1_right:
   br label %loop_next1

 loop_next1:
   br i1 %c2, label %loop_next2_left, label %outer_latch
 loop_next2_left:
   br label %loop_next2
 loop_next2_right:
   br label %loop_next2

 loop_next2:
   br i1 %c3, label %loop_next3_left, label %outer_latch
 loop_next3_left:
   br label %loop_next3
 loop_next3_right:
   br label %loop_next3

 loop_next3:
   br i1 %c4, label %loop_next4_left, label %outer_latch
 loop_next4_left:
   br label %loop_next4
 loop_next4_right:
   br label %loop_next4

 loop_next4:
   br i1 %c5, label %loop_latch_left, label %outer_latch
 loop_latch_left:
   br label %loop_latch
 loop_latch_right:
   br label %loop_latch

 loop_latch:
   store volatile i32 0, i32* %addr1
   %test_loop = icmp slt i32 %iv3, 50
   br i1 %test_loop, label %loop, label %middle_latch
 middle_latch:
   store volatile i32 0, i32* %addr2
   %test_middle = icmp slt i32 %iv2, 50
   br i1 %test_middle, label %middle, label %outer_latch
 outer_latch:
   store volatile i32 0, i32* %addr3
   %test_outer = icmp slt i32 %iv1, 50
   br i1 %test_outer, label %outer, label %exit
 exit:
   ret void
 }
	;
	; Here all the branches we unswitch are exiting from the inner loop.
	; That means we should not be getting exponential behavior on inner-loop
	; unswitch. In fact there should be just a single version of inner-loop,
	; with possibly some outer loop copies.
	;
	; There should be just a single copy of each loop when strictest mutiplier
	; candidates formula (unscaled candidates == 0) is enforced:

	; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop(unswitch),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=0 -unswitch-siblings-toplevel-div=16 \
	; RUN: -passes='loop(unswitch),print<loops>' -disable-output 2>&1 \| FileCheck %s --check-prefixes=LOOP1
	;
	;
	; When we relax the candidates part of a multiplier formula
	; (unscaled candidates == 2) we start getting some unswitches in outer loops,
	; which leads to siblings multiplier kicking in.
	;
	; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=3 -unswitch-siblings-toplevel-div=1 \
	; RUN: -passes='loop(unswitch),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-UNSCALE3-DIV1
	;
	; NB: sort -b is essential here and below, otherwise blanks might lead to different
	; order depending on locale.
	;
	; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=true \
	; RUN: -unswitch-num-initial-unscaled-candidates=3 -unswitch-siblings-toplevel-div=2 \
	; RUN: -passes='loop(unswitch),print<loops>' -disable-output 2>&1 \| \
	; RUN: sort -b -k 1 \| FileCheck %s --check-prefixes=LOOP-UNSCALE3-DIV2
	;
	; With disabled cost-multiplier we get maximal possible amount of unswitches.
	;
	; RUN: opt < %s -enable-nontrivial-unswitch -enable-unswitch-cost-multiplier=false \
	; RUN: -passes='loop(unswitch),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:
	; LOOP1: Loop at depth 3 containing:
	; LOOP1-NOT: Loop at depth 3 containing:
	;
	; Half unswitched loop nests, with unscaled3 and div1 it gets less depth1 loops unswitched
	; since they have more cost.
	; LOOP-UNSCALE3-DIV1-COUNT-4: Loop at depth 1 containing:
	; LOOP-UNSCALE3-DIV1-NOT: Loop at depth 1 containing:
	; LOOP-UNSCALE3-DIV1-COUNT-1: Loop at depth 2 containing:
	; LOOP-UNSCALE3-DIV1-NOT: Loop at depth 2 containing:
	; LOOP-UNSCALE3-DIV1-COUNT-1: Loop at depth 3 containing:
	; LOOP-UNSCALE3-DIV1-NOT: Loop at depth 3 containing:
	;
	; Half unswitched loop nests, with unscaled3 and div2 it gets more depth1 loops unswitched
	; as div2 kicks in.
	; LOOP-UNSCALE3-DIV2-COUNT-6: Loop at depth 1 containing:
	; LOOP-UNSCALE3-DIV2-NOT: Loop at depth 1 containing:
	; LOOP-UNSCALE3-DIV2-COUNT-1: Loop at depth 2 containing:
	; LOOP-UNSCALE3-DIV2-NOT: Loop at depth 2 containing:
	; LOOP-UNSCALE3-DIV2-COUNT-1: Loop at depth 3 containing:
	; LOOP-UNSCALE3-DIV2-NOT: Loop at depth 3 containing:
	;
	; Maximally unswitched (copy of the outer loop per each condition)
	; LOOP-MAX-COUNT-6: Loop at depth 1 containing:
	; LOOP-MAX-NOT: Loop at depth 1 containing:
	; LOOP-MAX-COUNT-1: Loop at depth 2 containing:
	; LOOP-MAX-NOT: Loop at depth 2 containing:
	; LOOP-MAX-COUNT-1: Loop at depth 3 containing:
	; LOOP-MAX-NOT: Loop at depth 3 containing:

	declare void @bar()

	define void @loop_nested3_conds5(i32* %addr, i1 %c1, i1 %c2, i1 %c3, i1 %c4, i1 %c5) {
	entry:
	%addr1 = getelementptr i32, i32* %addr, i64 0
	%addr2 = getelementptr i32, i32* %addr, i64 1
	%addr3 = getelementptr i32, i32* %addr, i64 2
	br label %outer
	outer:
	%iv1 = phi i32 [0, %entry], [%iv1.next, %outer_latch]
	%iv1.next = add i32 %iv1, 1
	;; skip nontrivial unswitch
	call void @bar()
	br label %middle
	middle:
	%iv2 = phi i32 [0, %outer], [%iv2.next, %middle_latch]
	%iv2.next = add i32 %iv2, 1
	;; skip nontrivial unswitch
	call void @bar()
	br label %loop
	loop:
	%iv3 = phi i32 [0, %middle], [%iv3.next, %loop_latch]
	%iv3.next = add i32 %iv3, 1
	;; skip nontrivial unswitch
	call void @bar()
	br i1 %c1, label %loop_next1_left, label %outer_latch
	loop_next1_left:
	br label %loop_next1
	loop_next1_right:
	br label %loop_next1

	loop_next1:
	br i1 %c2, label %loop_next2_left, label %outer_latch
	loop_next2_left:
	br label %loop_next2
	loop_next2_right:
	br label %loop_next2

	loop_next2:
	br i1 %c3, label %loop_next3_left, label %outer_latch
	loop_next3_left:
	br label %loop_next3
	loop_next3_right:
	br label %loop_next3

	loop_next3:
	br i1 %c4, label %loop_next4_left, label %outer_latch
	loop_next4_left:
	br label %loop_next4
	loop_next4_right:
	br label %loop_next4

	loop_next4:
	br i1 %c5, label %loop_latch_left, label %outer_latch
	loop_latch_left:
	br label %loop_latch
	loop_latch_right:
	br label %loop_latch

	loop_latch:
	store volatile i32 0, i32* %addr1
	%test_loop = icmp slt i32 %iv3, 50
	br i1 %test_loop, label %loop, label %middle_latch
	middle_latch:
	store volatile i32 0, i32* %addr2
	%test_middle = icmp slt i32 %iv2, 50
	br i1 %test_middle, label %middle, label %outer_latch
	outer_latch:
	store volatile i32 0, i32* %addr3
	%test_outer = icmp slt i32 %iv1, 50
	br i1 %test_outer, label %outer, label %exit
	exit:
	ret void
	}