; RUN: opt -passes='loop(unswitch),verify' -enable-nontrivial-unswitch -S < %s | FileCheck %s ; RUN: opt -simple-loop-unswitch -enable-nontrivial-unswitch -S < %s | FileCheck %s declare i32 @a() declare i32 @b() declare i32 @c() declare i32 @d() declare void @sink1(i32) declare void @sink2(i32) declare i1 @cond() declare i32 @cond.i32() ; Negative test: we cannot unswitch convergent calls. define void @test_no_unswitch_convergent(i1* %ptr, i1 %cond) { ; CHECK-LABEL: @test_no_unswitch_convergent( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin ; ; We shouldn't have unswitched into any other block either. ; CHECK-NOT: br i1 %cond loop_begin: br i1 %cond, label %loop_a, label %loop_b ; CHECK: loop_begin: ; CHECK-NEXT: br i1 %cond, label %loop_a, label %loop_b loop_a: call i32 @a() convergent br label %loop_latch loop_b: call i32 @b() br label %loop_latch loop_latch: %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit loop_exit: ret void } ; Negative test: we cannot unswitch noduplicate calls. define void @test_no_unswitch_noduplicate(i1* %ptr, i1 %cond) { ; CHECK-LABEL: @test_no_unswitch_noduplicate( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin ; ; We shouldn't have unswitched into any other block either. ; CHECK-NOT: br i1 %cond loop_begin: br i1 %cond, label %loop_a, label %loop_b ; CHECK: loop_begin: ; CHECK-NEXT: br i1 %cond, label %loop_a, label %loop_b loop_a: call i32 @a() noduplicate br label %loop_latch loop_b: call i32 @b() br label %loop_latch loop_latch: %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit loop_exit: ret void } declare i32 @__CxxFrameHandler3(...) ; Negative test: we cannot unswitch when tokens are used across blocks as we ; might introduce PHIs. define void @test_no_unswitch_cross_block_token(i1* %ptr, i1 %cond) nounwind personality i32 (...)* @__CxxFrameHandler3 { ; CHECK-LABEL: @test_no_unswitch_cross_block_token( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin ; ; We shouldn't have unswitched into any other block either. ; CHECK-NOT: br i1 %cond loop_begin: br i1 %cond, label %loop_a, label %loop_b ; CHECK: loop_begin: ; CHECK-NEXT: br i1 %cond, label %loop_a, label %loop_b loop_a: call i32 @a() br label %loop_cont loop_b: call i32 @b() br label %loop_cont loop_cont: invoke i32 @a() to label %loop_latch unwind label %loop_catch loop_latch: br label %loop_begin loop_catch: %catch = catchswitch within none [label %loop_catch_latch, label %loop_exit] unwind to caller loop_catch_latch: %catchpad_latch = catchpad within %catch [] catchret from %catchpad_latch to label %loop_begin loop_exit: %catchpad_exit = catchpad within %catch [] catchret from %catchpad_exit to label %exit exit: ret void } ; Non-trivial loop unswitching where there are two distinct trivial conditions ; to unswitch within the loop. define i32 @test1(i1* %ptr, i1 %cond1, i1 %cond2) { ; CHECK-LABEL: @test1( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: br i1 %cond1, label %loop_a, label %loop_b loop_a: call i32 @a() br label %latch ; The 'loop_a' unswitched loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: br label %loop_a.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %latch.us ; ; CHECK: latch.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: br label %loop_exit loop_b: br i1 %cond2, label %loop_b_a, label %loop_b_b ; The second unswitched condition. ; ; CHECK: entry.split: ; CHECK-NEXT: br i1 %cond2, label %entry.split.split.us, label %entry.split.split loop_b_a: call i32 @b() br label %latch ; The 'loop_b_a' unswitched loop. ; ; CHECK: entry.split.split.us: ; CHECK-NEXT: br label %loop_begin.us1 ; ; CHECK: loop_begin.us1: ; CHECK-NEXT: br label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: br label %loop_b_a.us ; ; CHECK: loop_b_a.us: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %latch.us2 ; ; CHECK: latch.us2: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us1, label %loop_exit.split.split.us ; ; CHECK: loop_exit.split.split.us: ; CHECK-NEXT: br label %loop_exit.split loop_b_b: call i32 @c() br label %latch ; The 'loop_b_b' unswitched loop. ; ; CHECK: entry.split.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: br label %loop_b_b ; ; CHECK: loop_b_b: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %latch ; ; CHECK: latch: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit.split.split ; ; CHECK: loop_exit.split.split: ; CHECK-NEXT: br label %loop_exit.split latch: %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit loop_exit: ret i32 0 ; CHECK: loop_exit.split: ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: ret } define i32 @test2(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr, i32* %c.ptr) { ; CHECK-LABEL: @test2( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr br i1 %cond1, label %loop_a, label %loop_b loop_a: %a = load i32, i32* %a.ptr %ac = load i32, i32* %c.ptr br i1 %v, label %loop_begin, label %loop_exit ; The 'loop_a' unswitched loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br label %loop_a.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[AC:.*]] = load i32, i32* %c.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.backedge.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_a.us ] ; CHECK-NEXT: %[[AC_LCSSA:.*]] = phi i32 [ %[[AC]], %loop_a.us ] ; CHECK-NEXT: br label %loop_exit loop_b: %b = load i32, i32* %b.ptr %bc = load i32, i32* %c.ptr br i1 %v, label %loop_begin, label %loop_exit ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[BC:.*]] = load i32, i32* %c.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.backedge, label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b ] ; CHECK-NEXT: %[[BC_LCSSA:.*]] = phi i32 [ %[[BC]], %loop_b ] ; CHECK-NEXT: br label %loop_exit loop_exit: %ab.phi = phi i32 [ %a, %loop_a ], [ %b, %loop_b ] %c.phi = phi i32 [ %ac, %loop_a ], [ %bc, %loop_b ] %result = add i32 %ab.phi, %c.phi ret i32 %result ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[B_LCSSA]], %loop_exit.split ], [ %[[A_LCSSA]], %loop_exit.split.us ] ; CHECK-NEXT: %[[C_PHI:.*]] = phi i32 [ %[[BC_LCSSA]], %loop_exit.split ], [ %[[AC_LCSSA]], %loop_exit.split.us ] ; CHECK-NEXT: %[[RESULT:.*]] = add i32 %[[AB_PHI]], %[[C_PHI]] ; CHECK-NEXT: ret i32 %[[RESULT]] } ; Test a non-trivial unswitch of an exiting edge to an exit block with other ; in-loop predecessors. define i32 @test3a(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test3a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_exit, label %loop_b ; The 'loop_exit' clone. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_begin.us ] ; CHECK-NEXT: br label %loop_exit loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %loop_begin, label %loop_exit ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b ] ; CHECK-NEXT: br label %loop_exit loop_exit: %ab.phi = phi i32 [ %a, %loop_begin ], [ %b, %loop_b ] ret i32 %ab.phi ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[B_LCSSA]], %loop_exit.split ], [ %[[A_LCSSA]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[AB_PHI]] } ; Test a non-trivial unswitch of an exiting edge to an exit block with other ; in-loop predecessors. This is the same as @test3a but with the reversed order ; of successors so that the exiting edge is *not* the cloned edge. define i32 @test3b(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test3b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_b, label %loop_exit ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b.us ] ; CHECK-NEXT: br label %loop_exit loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %loop_begin, label %loop_exit ; The original loop, now non-looping due to unswitching.. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: br label %loop_exit loop_exit: %ab.phi = phi i32 [ %b, %loop_b ], [ %a, %loop_begin ] ret i32 %ab.phi ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[A]], %loop_exit.split ], [ %[[B_LCSSA]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[AB_PHI]] } ; Test a non-trivial unswitch of an exiting edge to an exit block with no other ; in-loop predecessors. define void @test4a(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test4a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_exit1, label %loop_b ; The 'loop_exit' clone. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit1.split.us ; ; CHECK: loop_exit1.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_begin.us ] ; CHECK-NEXT: br label %loop_exit1 loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %loop_begin, label %loop_exit2 ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit2 loop_exit1: %a.phi = phi i32 [ %a, %loop_begin ] call void @sink1(i32 %a.phi) ret void ; CHECK: loop_exit1: ; CHECK-NEXT: call void @sink1(i32 %[[A_LCSSA]]) ; CHECK-NEXT: ret void loop_exit2: %b.phi = phi i32 [ %b, %loop_b ] call void @sink2(i32 %b.phi) ret void ; CHECK: loop_exit2: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b ] ; CHECK-NEXT: call void @sink2(i32 %[[B_LCSSA]]) ; CHECK-NEXT: ret void } ; Test a non-trivial unswitch of an exiting edge to an exit block with no other ; in-loop predecessors. This is the same as @test4a but with the edges reversed ; so that the exiting edge is *not* the cloned edge. define void @test4b(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test4b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_b, label %loop_exit1 ; The 'loop_b' clone. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us, label %loop_exit2.split.us ; ; CHECK: loop_exit2.split.us: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b.us ] ; CHECK-NEXT: br label %loop_exit2 loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %loop_begin, label %loop_exit2 ; The 'loop_exit' unswitched path. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit1 loop_exit1: %a.phi = phi i32 [ %a, %loop_begin ] call void @sink1(i32 %a.phi) ret void ; CHECK: loop_exit1: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A]], %loop_begin ] ; CHECK-NEXT: call void @sink1(i32 %[[A_PHI]]) ; CHECK-NEXT: ret void loop_exit2: %b.phi = phi i32 [ %b, %loop_b ] call void @sink2(i32 %b.phi) ret void ; CHECK: loop_exit2: ; CHECK-NEXT: call void @sink2(i32 %[[B_LCSSA]]) ; CHECK-NEXT: ret void } ; Test a non-trivial unswitch of an exiting edge to an exit block with no other ; in-loop predecessors. This is the same as @test4a but with a common merge ; block after the independent loop exits. This requires a different structural ; update to the dominator tree. define void @test4c(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test4c( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_exit1, label %loop_b ; The 'loop_exit' clone. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit1.split.us ; ; CHECK: loop_exit1.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_begin.us ] ; CHECK-NEXT: br label %loop_exit1 loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %loop_begin, label %loop_exit2 ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit2 loop_exit1: %a.phi = phi i32 [ %a, %loop_begin ] call void @sink1(i32 %a.phi) br label %exit ; CHECK: loop_exit1: ; CHECK-NEXT: call void @sink1(i32 %[[A_LCSSA]]) ; CHECK-NEXT: br label %exit loop_exit2: %b.phi = phi i32 [ %b, %loop_b ] call void @sink2(i32 %b.phi) br label %exit ; CHECK: loop_exit2: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b ] ; CHECK-NEXT: call void @sink2(i32 %[[B_LCSSA]]) ; CHECK-NEXT: br label %exit exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; Test that we can unswitch a condition out of multiple layers of a loop nest. define i32 @test5(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test5( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %loop_begin.split.us, label %entry.split ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: br label %loop_begin.split loop_begin: br label %inner_loop_begin inner_loop_begin: %v = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %cond1, label %loop_exit, label %inner_loop_b ; The 'loop_exit' clone. ; ; CHECK: loop_begin.split.us: ; CHECK-NEXT: br label %inner_loop_begin.us ; ; CHECK: inner_loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit.loopexit.split.us ; ; CHECK: loop_exit.loopexit.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %inner_loop_begin.us ] ; CHECK-NEXT: br label %loop_exit inner_loop_b: %b = load i32, i32* %b.ptr br i1 %v, label %inner_loop_begin, label %loop_latch ; The 'inner_loop_b' unswitched loop. ; ; CHECK: loop_begin.split: ; CHECK-NEXT: br label %inner_loop_begin ; ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_b ; ; CHECK: inner_loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_begin, label %loop_latch loop_latch: %b.phi = phi i32 [ %b, %inner_loop_b ] %v2 = load i1, i1* %ptr br i1 %v2, label %loop_begin, label %loop_exit ; CHECK: loop_latch: ; CHECK-NEXT: %[[B_INNER_LCSSA:.*]] = phi i32 [ %[[B]], %inner_loop_b ] ; CHECK-NEXT: %[[V2:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V2]], label %loop_begin, label %loop_exit.loopexit1 loop_exit: %ab.phi = phi i32 [ %a, %inner_loop_begin ], [ %b.phi, %loop_latch ] ret i32 %ab.phi ; CHECK: loop_exit.loopexit: ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit.loopexit1: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B_INNER_LCSSA]], %loop_latch ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.loopexit ], [ %[[B_LCSSA]], %loop_exit.loopexit1 ] ; CHECK-NEXT: ret i32 %[[AB_PHI]] } ; Test that we can unswitch a condition where we end up only cloning some of ; the nested loops and needing to delete some of the nested loops. define i32 @test6(i1* %ptr, i1 %cond1, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test6( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: %v = load i1, i1* %ptr br i1 %cond1, label %loop_a, label %loop_b loop_a: br label %loop_a_inner loop_a_inner: %va = load i1, i1* %ptr %a = load i32, i32* %a.ptr br i1 %va, label %loop_a_inner, label %loop_a_inner_exit loop_a_inner_exit: %a.lcssa = phi i32 [ %a, %loop_a_inner ] br label %latch ; The 'loop_a' cloned loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br label %loop_a.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: br label %loop_a_inner.us ; ; CHECK: loop_a_inner.us ; CHECK-NEXT: %[[VA:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br i1 %[[VA]], label %loop_a_inner.us, label %loop_a_inner_exit.us ; ; CHECK: loop_a_inner_exit.us: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A]], %loop_a_inner.us ] ; CHECK-NEXT: br label %latch.us ; ; CHECK: latch.us: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %loop_a_inner_exit.us ] ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_PHI]], %latch.us ] ; CHECK-NEXT: br label %loop_exit loop_b: br label %loop_b_inner loop_b_inner: %vb = load i1, i1* %ptr %b = load i32, i32* %b.ptr br i1 %vb, label %loop_b_inner, label %loop_b_inner_exit loop_b_inner_exit: %b.lcssa = phi i32 [ %b, %loop_b_inner ] br label %latch latch: %ab.phi = phi i32 [ %a.lcssa, %loop_a_inner_exit ], [ %b.lcssa, %loop_b_inner_exit ] br i1 %v, label %loop_begin, label %loop_exit ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: br label %loop_b_inner ; ; CHECK: loop_b_inner ; CHECK-NEXT: %[[VB:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[VB]], label %loop_b_inner, label %loop_b_inner_exit ; ; CHECK: loop_b_inner_exit: ; CHECK-NEXT: %[[B_INNER_LCSSA:.*]] = phi i32 [ %[[B]], %loop_b_inner ] ; CHECK-NEXT: br label %latch ; ; CHECK: latch: ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B_INNER_LCSSA]], %latch ] ; CHECK-NEXT: br label %loop_exit loop_exit: %ab.lcssa = phi i32 [ %ab.phi, %latch ] ret i32 %ab.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[B_LCSSA]], %loop_exit.split ], [ %[[A_LCSSA]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[AB_PHI]] } ; Test that when unswitching a deeply nested loop condition in a way that ; produces a non-loop clone that can reach multiple exit blocks which are part ; of different outer loops we correctly divide the cloned loop blocks between ; the outer loops based on reachability. define i32 @test7a(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test7a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %a = load i32, i32* %a.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %a.phi = phi i32 [ %a, %loop_begin ], [ %a2, %inner_inner_loop_exit ] %cond = load i1, i1* %cond.ptr %b = load i32, i32* %b.ptr br label %inner_inner_loop_begin ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A]], %loop_begin ], [ %[[A2:.*]], %inner_inner_loop_exit ] ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_begin.split.us, label %inner_loop_begin.split inner_inner_loop_begin: %v1 = load i1, i1* %ptr br i1 %v1, label %inner_inner_loop_a, label %inner_inner_loop_b inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_exit, label %inner_inner_loop_c inner_inner_loop_b: %v3 = load i1, i1* %ptr br i1 %v3, label %inner_inner_loop_exit, label %inner_inner_loop_c inner_inner_loop_c: %v4 = load i1, i1* %ptr br i1 %v4, label %inner_loop_exit, label %inner_inner_loop_d inner_inner_loop_d: br i1 %cond, label %inner_loop_exit, label %inner_inner_loop_begin ; The cloned copy that always exits with the adjustments required to fix up ; loop exits. ; ; CHECK: inner_loop_begin.split.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a.us, label %inner_inner_loop_b.us ; ; CHECK: inner_inner_loop_b.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit.split.us, label %inner_inner_loop_c.us.loopexit ; ; CHECK: inner_inner_loop_a.us: ; CHECK-NEXT: %[[A_NEW_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_begin.us ] ; CHECK-NEXT: %[[B_NEW_LCSSA:.*]] = phi i32 [ %[[B]], %inner_inner_loop_begin.us ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.us, label %inner_inner_loop_c.us ; ; CHECK: inner_inner_loop_c.us.loopexit: ; CHECK-NEXT: br label %inner_inner_loop_c.us ; ; CHECK: inner_inner_loop_c.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit.split.us, label %inner_inner_loop_d.us ; ; CHECK: inner_inner_loop_d.us: ; CHECK-NEXT: br label %inner_loop_exit.loopexit.split ; ; CHECK: inner_inner_loop_exit.split.us: ; CHECK-NEXT: br label %inner_inner_loop_exit ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A_NEW_LCSSA]], %inner_inner_loop_a.us ] ; CHECK-NEXT: %[[B_LCSSA_US:.*]] = phi i32 [ %[[B_NEW_LCSSA]], %inner_inner_loop_a.us ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: inner_loop_exit.loopexit.split.us: ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; The original copy that continues to loop. ; ; CHECK: inner_loop_begin.split: ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a, label %inner_inner_loop_b ; ; CHECK: inner_inner_loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split, label %inner_inner_loop_c ; ; CHECK: inner_inner_loop_b: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit.split, label %inner_inner_loop_c ; ; CHECK: inner_inner_loop_c: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit.split, label %inner_inner_loop_d ; ; CHECK: inner_inner_loop_d: ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_exit.split: ; CHECK-NEXT: br label %inner_inner_loop_exit inner_inner_loop_exit: %a2 = load i32, i32* %a.ptr %v5 = load i1, i1* %ptr br i1 %v5, label %inner_loop_exit, label %inner_loop_begin ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[A2]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit1, label %inner_loop_begin inner_loop_exit: br label %loop_begin ; CHECK: inner_loop_exit.loopexit.split: ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: br label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a.phi, %inner_inner_loop_a ] %b.lcssa = phi i32 [ %b, %inner_inner_loop_a ] %result = add i32 %a.lcssa, %b.lcssa ret i32 %result ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_a ] ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %inner_inner_loop_a ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.split ], [ %[[A_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: %[[B_PHI:.*]] = phi i32 [ %[[B_LCSSA]], %loop_exit.split ], [ %[[B_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: %[[RESULT:.*]] = add i32 %[[A_PHI]], %[[B_PHI]] ; CHECK-NEXT: ret i32 %[[RESULT]] } ; Same pattern as @test7a but here the original loop becomes a non-loop that ; can reach multiple exit blocks which are part of different outer loops. define i32 @test7b(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test7b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %a = load i32, i32* %a.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %a.phi = phi i32 [ %a, %loop_begin ], [ %a2, %inner_inner_loop_exit ] %cond = load i1, i1* %cond.ptr %b = load i32, i32* %b.ptr br label %inner_inner_loop_begin ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A]], %loop_begin ], [ %[[A2:.*]], %inner_inner_loop_exit ] ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_begin.split.us, label %inner_loop_begin.split inner_inner_loop_begin: %v1 = load i1, i1* %ptr br i1 %v1, label %inner_inner_loop_a, label %inner_inner_loop_b inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_exit, label %inner_inner_loop_c inner_inner_loop_b: %v3 = load i1, i1* %ptr br i1 %v3, label %inner_inner_loop_exit, label %inner_inner_loop_c inner_inner_loop_c: %v4 = load i1, i1* %ptr br i1 %v4, label %inner_loop_exit, label %inner_inner_loop_d inner_inner_loop_d: br i1 %cond, label %inner_inner_loop_begin, label %inner_loop_exit ; The cloned copy that continues looping. ; ; CHECK: inner_loop_begin.split.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a.us, label %inner_inner_loop_b.us ; ; CHECK: inner_inner_loop_b.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit.split.us, label %inner_inner_loop_c.us ; ; CHECK: inner_inner_loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.us, label %inner_inner_loop_c.us ; ; CHECK: inner_inner_loop_c.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit.split.us, label %inner_inner_loop_d.us ; ; CHECK: inner_inner_loop_d.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_exit.split.us: ; CHECK-NEXT: br label %inner_inner_loop_exit ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_a.us ] ; CHECK-NEXT: %[[B_LCSSA_US:.*]] = phi i32 [ %[[B]], %inner_inner_loop_a.us ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: inner_loop_exit.loopexit.split.us: ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; The original copy that now always exits and needs adjustments for exit ; blocks. ; ; CHECK: inner_loop_begin.split: ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a, label %inner_inner_loop_b ; ; CHECK: inner_inner_loop_a: ; CHECK-NEXT: %[[A_NEW_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_begin ] ; CHECK-NEXT: %[[B_NEW_LCSSA:.*]] = phi i32 [ %[[B]], %inner_inner_loop_begin ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split, label %inner_inner_loop_c ; ; CHECK: inner_inner_loop_b: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit.split, label %inner_inner_loop_c.loopexit ; ; CHECK: inner_inner_loop_c.loopexit: ; CHECK-NEXT: br label %inner_inner_loop_c ; ; CHECK: inner_inner_loop_c: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit.split, label %inner_inner_loop_d ; ; CHECK: inner_inner_loop_d: ; CHECK-NEXT: br label %inner_loop_exit.loopexit.split ; ; CHECK: inner_inner_loop_exit.split: ; CHECK-NEXT: br label %inner_inner_loop_exit inner_inner_loop_exit: %a2 = load i32, i32* %a.ptr %v5 = load i1, i1* %ptr br i1 %v5, label %inner_loop_exit, label %inner_loop_begin ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[A2]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit1, label %inner_loop_begin inner_loop_exit: br label %loop_begin ; CHECK: inner_loop_exit.loopexit.split: ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: br label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a.phi, %inner_inner_loop_a ] %b.lcssa = phi i32 [ %b, %inner_inner_loop_a ] %result = add i32 %a.lcssa, %b.lcssa ret i32 %result ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_NEW_LCSSA]], %inner_inner_loop_a ] ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B_NEW_LCSSA]], %inner_inner_loop_a ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.split ], [ %[[A_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: %[[B_PHI:.*]] = phi i32 [ %[[B_LCSSA]], %loop_exit.split ], [ %[[B_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: %[[RESULT:.*]] = add i32 %[[A_PHI]], %[[B_PHI]] ; CHECK-NEXT: ret i32 %[[RESULT]] } ; Test that when the exit block set of an inner loop changes to start at a less ; high level of the loop nest we correctly hoist the loop up the nest. define i32 @test8a(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test8a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %a = load i32, i32* %a.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %a.phi = phi i32 [ %a, %loop_begin ], [ %a2, %inner_inner_loop_exit ] %cond = load i1, i1* %cond.ptr %b = load i32, i32* %b.ptr br label %inner_inner_loop_begin ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A]], %loop_begin ], [ %[[A2:.*]], %inner_inner_loop_exit ] ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_begin.split.us, label %inner_loop_begin.split inner_inner_loop_begin: %v1 = load i1, i1* %ptr br i1 %v1, label %inner_inner_loop_a, label %inner_inner_loop_b inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_inner_loop_latch, label %inner_loop_exit inner_inner_loop_b: br i1 %cond, label %inner_inner_loop_latch, label %inner_inner_loop_exit inner_inner_loop_latch: br label %inner_inner_loop_begin ; The cloned region is now an exit from the inner loop. ; ; CHECK: inner_loop_begin.split.us: ; CHECK-NEXT: %[[A_INNER_INNER_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_begin ] ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a.us, label %inner_inner_loop_b.us ; ; CHECK: inner_inner_loop_b.us: ; CHECK-NEXT: br label %inner_inner_loop_latch.us ; ; CHECK: inner_inner_loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_latch.us, label %inner_loop_exit.loopexit.split.us ; ; CHECK: inner_inner_loop_latch.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_loop_exit.loopexit.split.us: ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A_INNER_INNER_LCSSA]], %inner_inner_loop_a.us ] ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; The original region exits the loop earlier. ; ; CHECK: inner_loop_begin.split: ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a, label %inner_inner_loop_b ; ; CHECK: inner_inner_loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_latch, label %inner_loop_exit.loopexit.split ; ; CHECK: inner_inner_loop_b: ; CHECK-NEXT: br label %inner_inner_loop_exit ; ; CHECK: inner_inner_loop_latch: ; CHECK-NEXT: br label %inner_inner_loop_begin inner_inner_loop_exit: %a2 = load i32, i32* %a.ptr %v4 = load i1, i1* %ptr br i1 %v4, label %inner_loop_exit, label %inner_loop_begin ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[A2]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit1, label %inner_loop_begin inner_loop_exit: %v5 = load i1, i1* %ptr br i1 %v5, label %loop_exit, label %loop_begin ; CHECK: inner_loop_exit.loopexit.split: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_a ] ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: %[[A_INNER_US_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %inner_loop_exit.loopexit.split ], [ %[[A_INNER_LCSSA_US]], %inner_loop_exit.loopexit.split.us ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: %[[A_INNER_LCSSA2:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_exit ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA2]], %inner_loop_exit.loopexit1 ], [ %[[A_INNER_US_PHI]], %inner_loop_exit.loopexit ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit, label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a.phi, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; Same pattern as @test8a but where the original loop looses an exit block and ; needs to be hoisted up the nest. define i32 @test8b(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test8b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %a = load i32, i32* %a.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %a.phi = phi i32 [ %a, %loop_begin ], [ %a2, %inner_inner_loop_exit ] %cond = load i1, i1* %cond.ptr %b = load i32, i32* %b.ptr br label %inner_inner_loop_begin ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A]], %loop_begin ], [ %[[A2:.*]], %inner_inner_loop_exit ] ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_begin.split.us, label %inner_loop_begin.split inner_inner_loop_begin: %v1 = load i1, i1* %ptr br i1 %v1, label %inner_inner_loop_a, label %inner_inner_loop_b inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_inner_loop_latch, label %inner_loop_exit inner_inner_loop_b: br i1 %cond, label %inner_inner_loop_exit, label %inner_inner_loop_latch inner_inner_loop_latch: br label %inner_inner_loop_begin ; The cloned region is similar to before but with one earlier exit. ; ; CHECK: inner_loop_begin.split.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a.us, label %inner_inner_loop_b.us ; ; CHECK: inner_inner_loop_b.us: ; CHECK-NEXT: br label %inner_inner_loop_exit.split.us ; ; CHECK: inner_inner_loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_latch.us, label %inner_loop_exit.loopexit.split.us ; ; CHECK: inner_inner_loop_latch.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_exit.split.us: ; CHECK-NEXT: br label %inner_inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit.split.us: ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_a.us ] ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; The original region is now an exit in the preheader. ; ; CHECK: inner_loop_begin.split: ; CHECK-NEXT: %[[A_INNER_INNER_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_begin ] ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_a, label %inner_inner_loop_b ; ; CHECK: inner_inner_loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_latch, label %inner_loop_exit.loopexit.split ; ; CHECK: inner_inner_loop_b: ; CHECK-NEXT: br label %inner_inner_loop_latch ; ; CHECK: inner_inner_loop_latch: ; CHECK-NEXT: br label %inner_inner_loop_begin inner_inner_loop_exit: %a2 = load i32, i32* %a.ptr %v4 = load i1, i1* %ptr br i1 %v4, label %inner_loop_exit, label %inner_loop_begin ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[A2]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.loopexit1, label %inner_loop_begin inner_loop_exit: %v5 = load i1, i1* %ptr br i1 %v5, label %loop_exit, label %loop_begin ; CHECK: inner_loop_exit.loopexit.split: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A_INNER_INNER_LCSSA]], %inner_inner_loop_a ] ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: %[[A_INNER_US_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %inner_loop_exit.loopexit.split ], [ %[[A_INNER_LCSSA_US]], %inner_loop_exit.loopexit.split.us ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: %[[A_INNER_LCSSA2:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_inner_loop_exit ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA2]], %inner_loop_exit.loopexit1 ], [ %[[A_INNER_US_PHI]], %inner_loop_exit.loopexit ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit, label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a.phi, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; Test for when unswitching produces a clone of an inner loop but ; the clone no longer has an exiting edge *at all* and loops infinitely. ; Because it doesn't ever exit to the outer loop it is no longer an inner loop ; but needs to be hoisted up the nest to be a top-level loop. define i32 @test9a(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test9a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %b = load i32, i32* %b.ptr %cond = load i1, i1* %cond.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %loop_begin.split.us, label %loop_begin.split inner_loop_begin: %a = load i32, i32* %a.ptr br i1 %cond, label %inner_loop_latch, label %inner_loop_exit inner_loop_latch: call void @sink1(i32 %b) br label %inner_loop_begin ; The cloned inner loop ends up as an infinite loop and thus being a top-level ; loop with the preheader as an exit block of the outer loop. ; ; CHECK: loop_begin.split.us ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_begin ] ; CHECK-NEXT: br label %inner_loop_begin.us ; ; CHECK: inner_loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_latch.us ; ; CHECK: inner_loop_latch.us: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: br label %inner_loop_begin.us ; ; The original loop becomes boring non-loop code. ; ; CHECK: loop_begin.split ; CHECK-NEXT: br label %inner_loop_begin ; ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_exit inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_loop_begin ] %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A]], %inner_loop_begin ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; The same core pattern as @test9a, but instead of the cloned loop becoming an ; infinite loop, the original loop has its only exit unswitched and the ; original loop becomes infinite and must be hoisted out of the loop nest. define i32 @test9b(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test9b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %b = load i32, i32* %b.ptr %cond = load i1, i1* %cond.ptr br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %loop_begin.split.us, label %loop_begin.split inner_loop_begin: %a = load i32, i32* %a.ptr br i1 %cond, label %inner_loop_exit, label %inner_loop_latch inner_loop_latch: call void @sink1(i32 %b) br label %inner_loop_begin ; The cloned inner loop becomes a boring non-loop. ; ; CHECK: loop_begin.split.us ; CHECK-NEXT: br label %inner_loop_begin.us ; ; CHECK: inner_loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_exit.split.us ; ; CHECK: inner_loop_exit.split.us ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A]], %inner_loop_begin.us ] ; CHECK-NEXT: br label %inner_loop_exit ; ; The original loop becomes an infinite loop and thus a top-level loop with the ; preheader as an exit block for the outer loop. ; ; CHECK: loop_begin.split ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %loop_begin ] ; CHECK-NEXT: br label %inner_loop_begin ; ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_latch ; ; CHECK: inner_loop_latch: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: br label %inner_loop_begin inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_loop_begin ] %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_LCSSA_US]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; Test that requires re-forming dedicated exits for the cloned loop. define i32 @test10a(i1* %ptr, i1 %cond, i32* %a.ptr) { ; CHECK-LABEL: @test10a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond, label %entry.split.us, label %entry.split loop_begin: %a = load i32, i32* %a.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_a, label %loop_b loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_exit, label %loop_begin loop_b: br i1 %cond, label %loop_exit, label %loop_begin ; The cloned loop with one edge as a direct exit. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a.us, label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: %[[A_LCSSA_B:.*]] = phi i32 [ %[[A]], %loop_begin.us ] ; CHECK-NEXT: br label %loop_exit.split.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.us.loopexit, label %loop_begin.backedge.us ; ; CHECK: loop_begin.backedge.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_exit.split.us.loopexit: ; CHECK-NEXT: %[[A_LCSSA_A:.*]] = phi i32 [ %[[A]], %loop_a.us ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_PHI_US:.*]] = phi i32 [ %[[A_LCSSA_B]], %loop_b.us ], [ %[[A_LCSSA_A]], %loop_exit.split.us.loopexit ] ; CHECK-NEXT: br label %loop_exit ; The original loop without one 'loop_exit' edge. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a, label %loop_b ; ; CHECK: loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split, label %loop_begin.backedge ; ; CHECK: loop_begin.backedge: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_b: ; CHECK-NEXT: br label %loop_begin.backedge ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_a ] ; CHECK-NEXT: br label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a, %loop_a ], [ %a, %loop_b ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.split ], [ %[[A_PHI_US]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[A_PHI]] } ; Test that requires re-forming dedicated exits for the original loop. define i32 @test10b(i1* %ptr, i1 %cond, i32* %a.ptr) { ; CHECK-LABEL: @test10b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond, label %entry.split.us, label %entry.split loop_begin: %a = load i32, i32* %a.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_a, label %loop_b loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_begin, label %loop_exit loop_b: br i1 %cond, label %loop_begin, label %loop_exit ; The cloned loop without one of the exits. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a.us, label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: br label %loop_begin.backedge.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.backedge.us, label %loop_exit.split.us ; ; CHECK: loop_begin.backedge.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A]], %loop_a.us ] ; CHECK-NEXT: br label %loop_exit ; The original loop without one 'loop_exit' edge. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a, label %loop_b ; ; CHECK: loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.backedge, label %loop_exit.split.loopexit ; ; CHECK: loop_begin.backedge: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_b: ; CHECK-NEXT: %[[A_LCSSA_B:.*]] = phi i32 [ %[[A]], %loop_begin ] ; CHECK-NEXT: br label %loop_exit.split ; ; CHECK: loop_exit.split.loopexit: ; CHECK-NEXT: %[[A_LCSSA_A:.*]] = phi i32 [ %[[A]], %loop_a ] ; CHECK-NEXT: br label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[A_PHI_SPLIT:.*]] = phi i32 [ %[[A_LCSSA_B]], %loop_b ], [ %[[A_LCSSA_A]], %loop_exit.split.loopexit ] ; CHECK-NEXT: br label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a, %loop_a ], [ %a, %loop_b ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_PHI_SPLIT]], %loop_exit.split ], [ %[[A_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[A_PHI]] } ; Check that if a cloned inner loop after unswitching doesn't loop and directly ; exits even an outer loop, we don't add the cloned preheader to the outer ; loop and do add the needed LCSSA phi nodes for the new exit block from the ; outer loop. define i32 @test11a(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test11a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %b = load i32, i32* %b.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_latch, label %inner_loop_ph ; CHECK: loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_latch, label %inner_loop_ph inner_loop_ph: %cond = load i1, i1* %cond.ptr br label %inner_loop_begin ; CHECK: inner_loop_ph: ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_ph.split.us, label %inner_loop_ph.split inner_loop_begin: call void @sink1(i32 %b) %a = load i32, i32* %a.ptr br i1 %cond, label %loop_exit, label %inner_loop_a inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_loop_exit, label %inner_loop_begin ; The cloned path doesn't actually loop and is an exit from the outer loop as ; well. ; ; CHECK: inner_loop_ph.split.us: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %inner_loop_ph ] ; CHECK-NEXT: br label %inner_loop_begin.us ; ; CHECK: inner_loop_begin.us: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit.loopexit.split.us ; ; CHECK: loop_exit.loopexit.split.us: ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A]], %inner_loop_begin.us ] ; CHECK-NEXT: br label %loop_exit.loopexit ; ; The original remains a loop losing the exit edge. ; ; CHECK: inner_loop_ph.split: ; CHECK-NEXT: br label %inner_loop_begin ; ; CHECK: inner_loop_begin: ; CHECK-NEXT: call void @sink1(i32 %[[B]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_a ; ; CHECK: inner_loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit, label %inner_loop_begin inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_loop_a ] %v3 = load i1, i1* %ptr br i1 %v3, label %loop_latch, label %loop_exit ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A]], %inner_loop_a ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_latch, label %loop_exit.loopexit1 loop_latch: br label %loop_begin ; CHECK: loop_latch: ; CHECK-NEXT: br label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a, %inner_loop_begin ], [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit.loopexit: ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit.loopexit1: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %inner_loop_exit ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA_US]], %loop_exit.loopexit ], [ %[[A_LCSSA]], %loop_exit.loopexit1 ] ; CHECK-NEXT: ret i32 %[[A_PHI]] } ; Check that if the original inner loop after unswitching doesn't loop and ; directly exits even an outer loop, we remove the original preheader from the ; outer loop and add needed LCSSA phi nodes for the new exit block from the ; outer loop. define i32 @test11b(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test11b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: %b = load i32, i32* %b.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_latch, label %inner_loop_ph ; CHECK: loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_latch, label %inner_loop_ph inner_loop_ph: %cond = load i1, i1* %cond.ptr br label %inner_loop_begin ; CHECK: inner_loop_ph: ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_loop_ph.split.us, label %inner_loop_ph.split inner_loop_begin: call void @sink1(i32 %b) %a = load i32, i32* %a.ptr br i1 %cond, label %inner_loop_a, label %loop_exit inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_loop_exit, label %inner_loop_begin ; The cloned path continues to loop without the exit out of the entire nest. ; ; CHECK: inner_loop_ph.split.us: ; CHECK-NEXT: br label %inner_loop_begin.us ; ; CHECK: inner_loop_begin.us: ; CHECK-NEXT: call void @sink1(i32 %[[B]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_a.us ; ; CHECK: inner_loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_exit.split.us, label %inner_loop_begin.us ; ; CHECK: inner_loop_exit.split.us: ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A]], %inner_loop_a.us ] ; CHECK-NEXT: br label %inner_loop_exit ; ; The original remains a loop losing the exit edge. ; ; CHECK: inner_loop_ph.split: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %inner_loop_ph ] ; CHECK-NEXT: br label %inner_loop_begin ; ; CHECK: inner_loop_begin: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %loop_exit.loopexit inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_loop_a ] %v3 = load i1, i1* %ptr br i1 %v3, label %loop_latch, label %loop_exit ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_latch, label %loop_exit.loopexit1 loop_latch: br label %loop_begin ; CHECK: loop_latch: ; CHECK-NEXT: br label %loop_begin loop_exit: %a.lcssa = phi i32 [ %a, %inner_loop_begin ], [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit.loopexit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %inner_loop_begin ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit.loopexit1: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A_INNER_LCSSA_US]], %inner_loop_exit ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.loopexit ], [ %[[A_LCSSA_US]], %loop_exit.loopexit1 ] ; CHECK-NEXT: ret i32 %[[A_PHI]] } ; Like test11a, but checking that when the whole thing is wrapped in yet ; another loop, we correctly attribute the cloned preheader to that outermost ; loop rather than only handling the case where the preheader is not in any loop ; at all. define i32 @test12a(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test12a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %b = load i32, i32* %b.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %inner_loop_latch, label %inner_inner_loop_ph ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_latch, label %inner_inner_loop_ph inner_inner_loop_ph: %cond = load i1, i1* %cond.ptr br label %inner_inner_loop_begin ; CHECK: inner_inner_loop_ph: ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_inner_loop_ph.split.us, label %inner_inner_loop_ph.split inner_inner_loop_begin: call void @sink1(i32 %b) %a = load i32, i32* %a.ptr br i1 %cond, label %inner_loop_exit, label %inner_inner_loop_a inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_inner_loop_exit, label %inner_inner_loop_begin ; The cloned path doesn't actually loop and is an exit from the outer loop as ; well. ; ; CHECK: inner_inner_loop_ph.split.us: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %inner_inner_loop_ph ] ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_exit.loopexit.split.us ; ; CHECK: inner_loop_exit.loopexit.split.us: ; CHECK-NEXT: %[[A_INNER_INNER_LCSSA_US:.*]] = phi i32 [ %[[A]], %inner_inner_loop_begin.us ] ; CHECK-NEXT: br label %inner_loop_exit.loopexit ; ; The original remains a loop losing the exit edge. ; ; CHECK: inner_inner_loop_ph.split: ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: call void @sink1(i32 %[[B]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_inner_loop_a ; ; CHECK: inner_inner_loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit, label %inner_inner_loop_begin inner_inner_loop_exit: %a.inner_inner_lcssa = phi i32 [ %a, %inner_inner_loop_a ] %v3 = load i1, i1* %ptr br i1 %v3, label %inner_loop_latch, label %inner_loop_exit ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_INNER_LCSSA:.*]] = phi i32 [ %[[A]], %inner_inner_loop_a ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_latch, label %inner_loop_exit.loopexit1 inner_loop_latch: br label %inner_loop_begin ; CHECK: inner_loop_latch: ; CHECK-NEXT: br label %inner_loop_begin inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_inner_loop_begin ], [ %a.inner_inner_lcssa, %inner_inner_loop_exit ] %v4 = load i1, i1* %ptr br i1 %v4, label %loop_begin, label %loop_exit ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A_INNER_INNER_LCSSA]], %inner_inner_loop_exit ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A_INNER_INNER_LCSSA_US]], %inner_loop_exit.loopexit ], [ %[[A_INNER_LCSSA]], %inner_loop_exit.loopexit1 ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; Like test11b, but checking that when the whole thing is wrapped in yet ; another loop, we correctly sink the preheader to the outermost loop rather ; than only handling the case where the preheader is completely removed from ; a loop. define i32 @test12b(i1* %ptr, i1* %cond.ptr, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test12b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br label %loop_begin loop_begin: br label %inner_loop_begin ; CHECK: loop_begin: ; CHECK-NEXT: br label %inner_loop_begin inner_loop_begin: %b = load i32, i32* %b.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %inner_loop_latch, label %inner_inner_loop_ph ; CHECK: inner_loop_begin: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_latch, label %inner_inner_loop_ph inner_inner_loop_ph: %cond = load i1, i1* %cond.ptr br label %inner_inner_loop_begin ; CHECK: inner_inner_loop_ph: ; CHECK-NEXT: %[[COND:.*]] = load i1, i1* %cond.ptr ; CHECK-NEXT: br i1 %[[COND]], label %inner_inner_loop_ph.split.us, label %inner_inner_loop_ph.split inner_inner_loop_begin: call void @sink1(i32 %b) %a = load i32, i32* %a.ptr br i1 %cond, label %inner_inner_loop_a, label %inner_loop_exit inner_inner_loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %inner_inner_loop_exit, label %inner_inner_loop_begin ; The cloned path continues to loop without the exit out of the entire nest. ; ; CHECK: inner_inner_loop_ph.split.us: ; CHECK-NEXT: br label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_begin.us: ; CHECK-NEXT: call void @sink1(i32 %[[B]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_inner_loop_a.us ; ; CHECK: inner_inner_loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_inner_loop_exit.split.us, label %inner_inner_loop_begin.us ; ; CHECK: inner_inner_loop_exit.split.us: ; CHECK-NEXT: %[[A_INNER_INNER_LCSSA_US:.*]] = phi i32 [ %[[A]], %inner_inner_loop_a.us ] ; CHECK-NEXT: br label %inner_inner_loop_exit ; ; The original remains a loop losing the exit edge. ; ; CHECK: inner_inner_loop_ph.split: ; CHECK-NEXT: %[[B_LCSSA:.*]] = phi i32 [ %[[B]], %inner_inner_loop_ph ] ; CHECK-NEXT: br label %inner_inner_loop_begin ; ; CHECK: inner_inner_loop_begin: ; CHECK-NEXT: call void @sink1(i32 %[[B_LCSSA]]) ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: br label %inner_loop_exit.loopexit inner_inner_loop_exit: %a.inner_inner_lcssa = phi i32 [ %a, %inner_inner_loop_a ] %v3 = load i1, i1* %ptr br i1 %v3, label %inner_loop_latch, label %inner_loop_exit ; CHECK: inner_inner_loop_exit: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %inner_loop_latch, label %inner_loop_exit.loopexit1 inner_loop_latch: br label %inner_loop_begin ; CHECK: inner_loop_latch: ; CHECK-NEXT: br label %inner_loop_begin inner_loop_exit: %a.inner_lcssa = phi i32 [ %a, %inner_inner_loop_begin ], [ %a.inner_inner_lcssa, %inner_inner_loop_exit ] %v4 = load i1, i1* %ptr br i1 %v4, label %loop_begin, label %loop_exit ; CHECK: inner_loop_exit.loopexit: ; CHECK-NEXT: %[[A_INNER_LCSSA:.*]] = phi i32 [ %[[A]], %inner_inner_loop_begin ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit.loopexit1: ; CHECK-NEXT: %[[A_INNER_LCSSA_US:.*]] = phi i32 [ %[[A_INNER_INNER_LCSSA_US]], %inner_inner_loop_exit ] ; CHECK-NEXT: br label %inner_loop_exit ; ; CHECK: inner_loop_exit: ; CHECK-NEXT: %[[A_INNER_PHI:.*]] = phi i32 [ %[[A_INNER_LCSSA]], %inner_loop_exit.loopexit ], [ %[[A_INNER_LCSSA_US]], %inner_loop_exit.loopexit1 ] ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit loop_exit: %a.lcssa = phi i32 [ %a.inner_lcssa, %inner_loop_exit ] ret i32 %a.lcssa ; CHECK: loop_exit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A_INNER_PHI]], %inner_loop_exit ] ; CHECK-NEXT: ret i32 %[[A_LCSSA]] } ; Test where the cloned loop has an inner loop that has to be traversed to form ; the cloned loop, and where this inner loop has multiple blocks, and where the ; exiting block that connects the inner loop to the cloned loop is not the header ; block. This ensures that we correctly handle interesting corner cases of ; traversing back to the header when establishing the cloned loop. define i32 @test13a(i1* %ptr, i1 %cond, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test13a( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond, label %entry.split.us, label %entry.split loop_begin: %a = load i32, i32* %a.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_a, label %loop_b loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_exit, label %loop_latch loop_b: %b = load i32, i32* %b.ptr br i1 %cond, label %loop_b_inner_ph, label %loop_exit loop_b_inner_ph: br label %loop_b_inner_header loop_b_inner_header: %v3 = load i1, i1* %ptr br i1 %v3, label %loop_b_inner_latch, label %loop_b_inner_body loop_b_inner_body: %v4 = load i1, i1* %ptr br i1 %v4, label %loop_b_inner_latch, label %loop_b_inner_exit loop_b_inner_latch: br label %loop_b_inner_header loop_b_inner_exit: br label %loop_latch loop_latch: br label %loop_begin ; The cloned loop contains an inner loop within it. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a.us, label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br label %loop_b_inner_ph.us ; ; CHECK: loop_b_inner_ph.us: ; CHECK-NEXT: br label %loop_b_inner_header.us ; ; CHECK: loop_b_inner_header.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_b_inner_latch.us, label %loop_b_inner_body.us ; ; CHECK: loop_b_inner_body.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_b_inner_latch.us, label %loop_b_inner_exit.us ; ; CHECK: loop_b_inner_exit.us: ; CHECK-NEXT: br label %loop_latch.us ; ; CHECK: loop_b_inner_latch.us: ; CHECK-NEXT: br label %loop_b_inner_header.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.us, label %loop_latch.us ; ; CHECK: loop_latch.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A]], %loop_a.us ] ; CHECK-NEXT: br label %loop_exit ; ; And the original loop no longer contains an inner loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a, label %loop_b ; ; CHECK: loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.loopexit, label %loop_latch ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br label %loop_exit.split ; ; CHECK: loop_latch: ; CHECK-NEXT: br label %loop_begin loop_exit: %lcssa = phi i32 [ %a, %loop_a ], [ %b, %loop_b ] ret i32 %lcssa ; CHECK: loop_exit.split.loopexit: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_a ] ; CHECK-NEXT: br label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[B]], %loop_b ], [ %[[A_LCSSA]], %loop_exit.split.loopexit ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI_US:.*]] = phi i32 [ %[[AB_PHI]], %loop_exit.split ], [ %[[A_LCSSA_US]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[AB_PHI_US]] } ; Test where the original loop has an inner loop that has to be traversed to ; rebuild the loop, and where this inner loop has multiple blocks, and where ; the exiting block that connects the inner loop to the original loop is not ; the header block. This ensures that we correctly handle interesting corner ; cases of traversing back to the header when re-establishing the original loop ; still exists after unswitching. define i32 @test13b(i1* %ptr, i1 %cond, i32* %a.ptr, i32* %b.ptr) { ; CHECK-LABEL: @test13b( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond, label %entry.split.us, label %entry.split loop_begin: %a = load i32, i32* %a.ptr %v1 = load i1, i1* %ptr br i1 %v1, label %loop_a, label %loop_b loop_a: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_exit, label %loop_latch loop_b: %b = load i32, i32* %b.ptr br i1 %cond, label %loop_exit, label %loop_b_inner_ph loop_b_inner_ph: br label %loop_b_inner_header loop_b_inner_header: %v3 = load i1, i1* %ptr br i1 %v3, label %loop_b_inner_latch, label %loop_b_inner_body loop_b_inner_body: %v4 = load i1, i1* %ptr br i1 %v4, label %loop_b_inner_latch, label %loop_b_inner_exit loop_b_inner_latch: br label %loop_b_inner_header loop_b_inner_exit: br label %loop_latch loop_latch: br label %loop_begin ; The cloned loop doesn't contain an inner loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a.us, label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br label %loop_exit.split.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split.us.loopexit, label %loop_latch.us ; ; CHECK: loop_latch.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_exit.split.us.loopexit: ; CHECK-NEXT: %[[A_LCSSA_US:.*]] = phi i32 [ %[[A]], %loop_a.us ] ; CHECK-NEXT: br label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: %[[AB_PHI_US:.*]] = phi i32 [ %[[B]], %loop_b.us ], [ %[[A_LCSSA_US]], %loop_exit.split.us.loopexit ] ; CHECK-NEXT: br label %loop_exit ; ; But the original loop contains an inner loop that must be traversed.; ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[A:.*]] = load i32, i32* %a.ptr ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_a, label %loop_b ; ; CHECK: loop_a: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_exit.split, label %loop_latch ; ; CHECK: loop_b: ; CHECK-NEXT: %[[B:.*]] = load i32, i32* %b.ptr ; CHECK-NEXT: br label %loop_b_inner_ph ; ; CHECK: loop_b_inner_ph: ; CHECK-NEXT: br label %loop_b_inner_header ; ; CHECK: loop_b_inner_header: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_b_inner_latch, label %loop_b_inner_body ; ; CHECK: loop_b_inner_body: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_b_inner_latch, label %loop_b_inner_exit ; ; CHECK: loop_b_inner_latch: ; CHECK-NEXT: br label %loop_b_inner_header ; ; CHECK: loop_b_inner_exit: ; CHECK-NEXT: br label %loop_latch ; ; CHECK: loop_latch: ; CHECK-NEXT: br label %loop_begin loop_exit: %lcssa = phi i32 [ %a, %loop_a ], [ %b, %loop_b ] ret i32 %lcssa ; CHECK: loop_exit.split: ; CHECK-NEXT: %[[A_LCSSA:.*]] = phi i32 [ %[[A]], %loop_a ] ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[AB_PHI:.*]] = phi i32 [ %[[A_LCSSA]], %loop_exit.split ], [ %[[AB_PHI_US]], %loop_exit.split.us ] ; CHECK-NEXT: ret i32 %[[AB_PHI]] } define i32 @test20(i32* %var, i32 %cond1, i32 %cond2) { ; CHECK-LABEL: @test20( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: switch i32 %cond2, label %[[ENTRY_SPLIT_EXIT:.*]] [ ; CHECK-NEXT: i32 0, label %[[ENTRY_SPLIT_A:.*]] ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_A]] ; CHECK-NEXT: i32 13, label %[[ENTRY_SPLIT_B:.*]] ; CHECK-NEXT: i32 2, label %[[ENTRY_SPLIT_A]] ; CHECK-NEXT: i32 42, label %[[ENTRY_SPLIT_C:.*]] ; CHECK-NEXT: ] loop_begin: %var_val = load i32, i32* %var switch i32 %cond2, label %loop_exit [ i32 0, label %loop_a i32 1, label %loop_a i32 13, label %loop_b i32 2, label %loop_a i32 42, label %loop_c ] loop_a: call i32 @a() br label %loop_latch ; Unswitched 'a' loop. ; ; CHECK: [[ENTRY_SPLIT_A]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_A:.*]] ; ; CHECK: [[LOOP_BEGIN_A]]: ; CHECK-NEXT: %{{.*}} = load i32, i32* %var ; CHECK-NEXT: br label %[[LOOP_A:.*]] ; ; CHECK: [[LOOP_A]]: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %[[LOOP_LATCH_A:.*]] ; ; CHECK: [[LOOP_LATCH_A]]: ; CHECK: br label %[[LOOP_BEGIN_A]] loop_b: call i32 @b() br label %loop_latch ; Unswitched 'b' loop. ; ; CHECK: [[ENTRY_SPLIT_B]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_B:.*]] ; ; CHECK: [[LOOP_BEGIN_B]]: ; CHECK-NEXT: %{{.*}} = load i32, i32* %var ; CHECK-NEXT: br label %[[LOOP_B:.*]] ; ; CHECK: [[LOOP_B]]: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %[[LOOP_LATCH_B:.*]] ; ; CHECK: [[LOOP_LATCH_B]]: ; CHECK: br label %[[LOOP_BEGIN_B]] loop_c: call i32 @c() noreturn nounwind br label %loop_latch ; Unswitched 'c' loop. ; ; CHECK: [[ENTRY_SPLIT_C]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_C:.*]] ; ; CHECK: [[LOOP_BEGIN_C]]: ; CHECK-NEXT: %{{.*}} = load i32, i32* %var ; CHECK-NEXT: br label %[[LOOP_C:.*]] ; ; CHECK: [[LOOP_C]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[LOOP_LATCH_C:.*]] ; ; CHECK: [[LOOP_LATCH_C]]: ; CHECK: br label %[[LOOP_BEGIN_C]] loop_latch: br label %loop_begin loop_exit: %lcssa = phi i32 [ %var_val, %loop_begin ] ret i32 %lcssa ; Unswitched exit edge (no longer a loop). ; ; CHECK: [[ENTRY_SPLIT_EXIT]]: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V:.*]] = load i32, i32* %var ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: %[[LCSSA:.*]] = phi i32 [ %[[V]], %loop_begin ] ; CHECK-NEXT: ret i32 %[[LCSSA]] } ; Negative test: we do not switch when the loop contains unstructured control ; flows as it would significantly complicate the process as novel loops might ; be formed, etc. define void @test_no_unswitch_unstructured_cfg(i1* %ptr, i1 %cond) { ; CHECK-LABEL: @test_no_unswitch_unstructured_cfg( entry: br label %loop_begin loop_begin: br i1 %cond, label %loop_left, label %loop_right loop_left: %v1 = load i1, i1* %ptr br i1 %v1, label %loop_right, label %loop_merge loop_right: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_left, label %loop_merge loop_merge: %v3 = load i1, i1* %ptr br i1 %v3, label %loop_latch, label %loop_exit loop_latch: br label %loop_begin loop_exit: ret void } ; A test reduced out of 403.gcc with interesting nested loops that trigger ; multiple unswitches. A key component of this test is that there are multiple ; paths to reach an inner loop after unswitching, and one of them is via the ; predecessors of the unswitched loop header. That can allow us to find the loop ; through multiple different paths. define void @test21(i1 %a, i1 %b) { ; CHECK-LABEL: @test21( bb: br label %bb3 ; CHECK-NOT: br i1 %a ; ; CHECK: br i1 %a, label %[[BB_SPLIT_US:.*]], label %[[BB_SPLIT:.*]] ; ; CHECK-NOT: br i1 %a ; CHECK-NOT: br i1 %b ; ; CHECK: [[BB_SPLIT]]: ; CHECK: br i1 %b ; ; CHECK-NOT: br i1 %a ; CHECK-NOT: br i1 %b bb3: %tmp1.0 = phi i32 [ 0, %bb ], [ %tmp1.3, %bb23 ] br label %bb7 bb7: %tmp.0 = phi i1 [ true, %bb3 ], [ false, %bb19 ] %tmp1.1 = phi i32 [ %tmp1.0, %bb3 ], [ %tmp1.2.lcssa, %bb19 ] br i1 %tmp.0, label %bb11.preheader, label %bb23 bb11.preheader: br i1 %a, label %bb19, label %bb14.lr.ph bb14.lr.ph: br label %bb14 bb14: %tmp2.02 = phi i32 [ 0, %bb14.lr.ph ], [ 1, %bb14 ] br i1 %b, label %bb11.bb19_crit_edge, label %bb14 bb11.bb19_crit_edge: %split = phi i32 [ %tmp2.02, %bb14 ] br label %bb19 bb19: %tmp1.2.lcssa = phi i32 [ %split, %bb11.bb19_crit_edge ], [ %tmp1.1, %bb11.preheader ] %tmp21 = icmp eq i32 %tmp1.2.lcssa, 0 br i1 %tmp21, label %bb23, label %bb7 bb23: %tmp1.3 = phi i32 [ %tmp1.2.lcssa, %bb19 ], [ %tmp1.1, %bb7 ] br label %bb3 } ; A test reduced out of 400.perlbench that when unswitching the `%stop` ; condition clones a loop nest outside of a containing loop. This excercises a ; different cloning path from our other test cases and in turn verifying the ; resulting structure can catch any failures to correctly clone these nested ; loops. declare void @f() declare void @g() declare i32 @h(i32 %arg) define void @test22(i32 %arg) { ; CHECK-LABEL: define void @test22( entry: br label %loop1.header loop1.header: %stop = phi i1 [ true, %loop1.latch ], [ false, %entry ] %i = phi i32 [ %i.lcssa, %loop1.latch ], [ %arg, %entry ] ; CHECK: %[[I:.*]] = phi i32 [ %{{.*}}, %loop1.latch ], [ %arg, %entry ] br i1 %stop, label %loop1.exit, label %loop1.body.loop2.ph ; CHECK: br i1 %stop, label %loop1.exit, label %loop1.body.loop2.ph loop1.body.loop2.ph: br label %loop2.header ; Just check that the we unswitched the key condition and that leads to the ; inner loop header. ; ; CHECK: loop1.body.loop2.ph: ; CHECK-NEXT: br i1 %stop, label %[[SPLIT_US:.*]], label %[[SPLIT:.*]] ; ; CHECK: [[SPLIT_US]]: ; CHECK-NEXT: br label %[[LOOP2_HEADER_US:.*]] ; ; CHECK: [[LOOP2_HEADER_US]]: ; CHECK-NEXT: %{{.*}} = phi i32 [ %[[I]], %[[SPLIT_US]] ] ; ; CHECK: [[SPLIT]]: ; CHECK-NEXT: br label %[[LOOP2_HEADER:.*]] ; ; CHECK: [[LOOP2_HEADER]]: ; CHECK-NEXT: %{{.*}} = phi i32 [ %[[I]], %[[SPLIT]] ] loop2.header: %i.inner = phi i32 [ %i, %loop1.body.loop2.ph ], [ %i.next, %loop2.latch ] br label %loop3.header loop3.header: %sw = call i32 @h(i32 %i.inner) switch i32 %sw, label %loop3.exit [ i32 32, label %loop3.header i32 59, label %loop2.latch i32 36, label %loop1.latch ] loop2.latch: %i.next = add i32 %i.inner, 1 br i1 %stop, label %loop2.exit, label %loop2.header loop1.latch: %i.lcssa = phi i32 [ %i.inner, %loop3.header ] br label %loop1.header loop3.exit: call void @f() ret void loop2.exit: call void @g() ret void loop1.exit: call void @g() ret void } ; Test that when we are unswitching and need to rebuild the loop block set we ; correctly skip past inner loops. We want to use the inner loop to efficiently ; skip whole subregions of the outer loop blocks but just because the header of ; the outer loop is also the preheader of an inner loop shouldn't confuse this ; walk. define void @test23(i1 %arg, i1* %ptr) { ; CHECK-LABEL: define void @test23( entry: br label %outer.header ; CHECK: entry: ; CHECK-NEXT: br i1 %arg, ; ; Just verify that we unswitched the correct bits. We should call `@f` twice in ; one unswitch and `@f` and then `@g` in the other. ; CHECK: call void ; CHECK-SAME: @f ; CHECK: call void ; CHECK-SAME: @f ; ; CHECK: call void ; CHECK-SAME: @f ; CHECK: call void ; CHECK-SAME: @g outer.header: br label %inner.header inner.header: call void @f() br label %inner.latch inner.latch: %inner.cond = load i1, i1* %ptr br i1 %inner.cond, label %inner.header, label %outer.body outer.body: br i1 %arg, label %outer.body.left, label %outer.body.right outer.body.left: call void @f() br label %outer.latch outer.body.right: call void @g() br label %outer.latch outer.latch: %outer.cond = load i1, i1* %ptr br i1 %outer.cond, label %outer.header, label %exit exit: ret void } ; Non-trivial loop unswitching where there are two invariant conditions, but the ; second one is only in the cloned copy of the loop after unswitching. define i32 @test24(i1* %ptr, i1 %cond1, i1 %cond2) { ; CHECK-LABEL: @test24( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond1, label %entry.split.us, label %entry.split loop_begin: br i1 %cond1, label %loop_a, label %loop_b loop_a: br i1 %cond2, label %loop_a_a, label %loop_a_c ; The second unswitched condition. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br i1 %cond2, label %entry.split.us.split.us, label %entry.split.us.split loop_a_a: call i32 @a() br label %latch ; The 'loop_a_a' unswitched loop. ; ; CHECK: entry.split.us.split.us: ; CHECK-NEXT: br label %loop_begin.us.us ; ; CHECK: loop_begin.us.us: ; CHECK-NEXT: br label %loop_a.us.us ; ; CHECK: loop_a.us.us: ; CHECK-NEXT: br label %loop_a_a.us.us ; ; CHECK: loop_a_a.us.us: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %latch.us.us ; ; CHECK: latch.us.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us.us, label %loop_exit.split.us.split.us ; ; CHECK: loop_exit.split.us.split.us: ; CHECK-NEXT: br label %loop_exit.split loop_a_c: call i32 @c() br label %latch ; The 'loop_a_c' unswitched loop. ; ; CHECK: entry.split.us.split: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: br label %loop_a.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: br label %loop_a_c.us ; ; CHECK: loop_a_c.us: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %latch ; ; CHECK: latch.us: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin.us, label %loop_exit.split.us.split ; ; CHECK: loop_exit.split.us.split: ; CHECK-NEXT: br label %loop_exit.split loop_b: call i32 @b() br label %latch ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: br label %loop_b ; ; CHECK: loop_b: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %latch ; ; CHECK: latch: ; CHECK-NEXT: %[[V:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V]], label %loop_begin, label %loop_exit.split ; ; CHECK: loop_exit.split: ; CHECK-NEXT: br label %loop_exit latch: %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit loop_exit: ret i32 0 ; CHECK: loop_exit: ; CHECK-NEXT: ret } ; Non-trivial partial loop unswitching of an invariant input to an 'or'. define i32 @test25(i1* %ptr, i1 %cond) { ; CHECK-LABEL: @test25( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: br i1 %cond, label %entry.split.us, label %entry.split loop_begin: %v1 = load i1, i1* %ptr %cond_or = or i1 %v1, %cond br i1 %cond_or, label %loop_a, label %loop_b loop_a: call i32 @a() br label %latch ; The 'loop_a' unswitched loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V1_US:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[OR_US:.*]] = or i1 %[[V1_US]], true ; CHECK-NEXT: br label %loop_a.us ; ; CHECK: loop_a.us: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %latch.us ; ; CHECK: latch.us: ; CHECK-NEXT: %[[V2_US:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V2_US]], label %loop_begin.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: br label %loop_exit loop_b: call i32 @b() br label %latch ; The original loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V1:.*]] = load i1, i1* %ptr ; CHECK-NEXT: %[[OR:.*]] = or i1 %[[V1]], false ; CHECK-NEXT: br i1 %[[OR]], label %loop_a, label %loop_b ; ; CHECK: loop_a: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %latch ; ; CHECK: loop_b: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %latch latch: %v2 = load i1, i1* %ptr br i1 %v2, label %loop_begin, label %loop_exit ; CHECK: latch: ; CHECK-NEXT: %[[V2:.*]] = load i1, i1* %ptr ; CHECK-NEXT: br i1 %[[V2]], label %loop_begin, label %loop_exit.split loop_exit: ret i32 0 ; CHECK: loop_exit.split: ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: ret } ; Non-trivial partial loop unswitching of multiple invariant inputs to an `and` ; chain. define i32 @test26(i1* %ptr1, i1* %ptr2, i1* %ptr3, i1 %cond1, i1 %cond2, i1 %cond3) { ; CHECK-LABEL: @test26( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: %[[INV_AND:.*]] = and i1 %cond3, %cond1 ; CHECK-NEXT: br i1 %[[INV_AND]], label %entry.split, label %entry.split.us loop_begin: %v1 = load i1, i1* %ptr1 %v2 = load i1, i1* %ptr2 %cond_and1 = and i1 %v1, %cond1 %cond_or1 = or i1 %v2, %cond2 %cond_and2 = and i1 %cond_and1, %cond_or1 %cond_and3 = and i1 %cond_and2, %cond3 br i1 %cond_and3, label %loop_a, label %loop_b ; The 'loop_b' unswitched loop. ; ; CHECK: entry.split.us: ; CHECK-NEXT: br label %loop_begin.us ; ; CHECK: loop_begin.us: ; CHECK-NEXT: %[[V1_US:.*]] = load i1, i1* %ptr1 ; CHECK-NEXT: %[[V2_US:.*]] = load i1, i1* %ptr2 ; CHECK-NEXT: %[[AND1_US:.*]] = and i1 %[[V1_US]], false ; CHECK-NEXT: %[[OR1_US:.*]] = or i1 %[[V2_US]], %cond2 ; CHECK-NEXT: %[[AND2_US:.*]] = and i1 %[[AND1_US]], %[[OR1_US]] ; CHECK-NEXT: %[[AND3_US:.*]] = and i1 %[[AND2_US]], false ; CHECK-NEXT: br label %loop_b.us ; ; CHECK: loop_b.us: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %latch.us ; ; CHECK: latch.us: ; CHECK-NEXT: %[[V3_US:.*]] = load i1, i1* %ptr3 ; CHECK-NEXT: br i1 %[[V3_US]], label %loop_begin.us, label %loop_exit.split.us ; ; CHECK: loop_exit.split.us: ; CHECK-NEXT: br label %loop_exit ; The original loop. ; ; CHECK: entry.split: ; CHECK-NEXT: br label %loop_begin ; ; CHECK: loop_begin: ; CHECK-NEXT: %[[V1:.*]] = load i1, i1* %ptr1 ; CHECK-NEXT: %[[V2:.*]] = load i1, i1* %ptr2 ; CHECK-NEXT: %[[AND1:.*]] = and i1 %[[V1]], true ; CHECK-NEXT: %[[OR1:.*]] = or i1 %[[V2]], %cond2 ; CHECK-NEXT: %[[AND2:.*]] = and i1 %[[AND1]], %[[OR1]] ; CHECK-NEXT: %[[AND3:.*]] = and i1 %[[AND2]], true ; CHECK-NEXT: br i1 %[[AND3]], label %loop_a, label %loop_b loop_a: call i32 @a() br label %latch ; CHECK: loop_a: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %latch loop_b: call i32 @b() br label %latch ; CHECK: loop_b: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %latch latch: %v3 = load i1, i1* %ptr3 br i1 %v3, label %loop_begin, label %loop_exit ; CHECK: latch: ; CHECK-NEXT: %[[V3:.*]] = load i1, i1* %ptr3 ; CHECK-NEXT: br i1 %[[V3]], label %loop_begin, label %loop_exit.split loop_exit: ret i32 0 ; CHECK: loop_exit.split: ; CHECK-NEXT: br label %loop_exit ; ; CHECK: loop_exit: ; CHECK-NEXT: ret } ; Non-trivial unswitching of a switch. define i32 @test27(i1* %ptr, i32 %cond) { ; CHECK-LABEL: @test27( entry: br label %loop_begin ; CHECK-NEXT: entry: ; CHECK-NEXT: switch i32 %cond, label %[[ENTRY_SPLIT_LATCH:.*]] [ ; CHECK-NEXT: i32 0, label %[[ENTRY_SPLIT_A:.*]] ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_B:.*]] ; CHECK-NEXT: i32 2, label %[[ENTRY_SPLIT_C:.*]] ; CHECK-NEXT: ] loop_begin: switch i32 %cond, label %latch [ i32 0, label %loop_a i32 1, label %loop_b i32 2, label %loop_c ] loop_a: call i32 @a() br label %latch ; Unswitched 'a' loop. ; ; CHECK: [[ENTRY_SPLIT_A]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_A:.*]] ; ; CHECK: [[LOOP_BEGIN_A]]: ; CHECK-NEXT: br label %[[LOOP_A:.*]] ; ; CHECK: [[LOOP_A]]: ; CHECK-NEXT: call i32 @a() ; CHECK-NEXT: br label %[[LOOP_LATCH_A:.*]] ; ; CHECK: [[LOOP_LATCH_A]]: ; CHECK-NEXT: %[[V_A:.*]] = load i1, i1* %ptr ; CHECK: br i1 %[[V_A]], label %[[LOOP_BEGIN_A]], label %[[LOOP_EXIT_A:.*]] ; ; CHECK: [[LOOP_EXIT_A]]: ; CHECK-NEXT: br label %loop_exit loop_b: call i32 @b() br label %latch ; Unswitched 'b' loop. ; ; CHECK: [[ENTRY_SPLIT_B]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_B:.*]] ; ; CHECK: [[LOOP_BEGIN_B]]: ; CHECK-NEXT: br label %[[LOOP_B:.*]] ; ; CHECK: [[LOOP_B]]: ; CHECK-NEXT: call i32 @b() ; CHECK-NEXT: br label %[[LOOP_LATCH_B:.*]] ; ; CHECK: [[LOOP_LATCH_B]]: ; CHECK-NEXT: %[[V_B:.*]] = load i1, i1* %ptr ; CHECK: br i1 %[[V_B]], label %[[LOOP_BEGIN_B]], label %[[LOOP_EXIT_B:.*]] ; ; CHECK: [[LOOP_EXIT_B]]: ; CHECK-NEXT: br label %loop_exit loop_c: call i32 @c() br label %latch ; Unswitched 'c' loop. ; ; CHECK: [[ENTRY_SPLIT_C]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_C:.*]] ; ; CHECK: [[LOOP_BEGIN_C]]: ; CHECK-NEXT: br label %[[LOOP_C:.*]] ; ; CHECK: [[LOOP_C]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[LOOP_LATCH_C:.*]] ; ; CHECK: [[LOOP_LATCH_C]]: ; CHECK-NEXT: %[[V_C:.*]] = load i1, i1* %ptr ; CHECK: br i1 %[[V_C]], label %[[LOOP_BEGIN_C]], label %[[LOOP_EXIT_C:.*]] ; ; CHECK: [[LOOP_EXIT_C]]: ; CHECK-NEXT: br label %loop_exit latch: %v = load i1, i1* %ptr br i1 %v, label %loop_begin, label %loop_exit ; Unswitched the 'latch' only loop. ; ; CHECK: [[ENTRY_SPLIT_LATCH]]: ; CHECK-NEXT: br label %[[LOOP_BEGIN_LATCH:.*]] ; ; CHECK: [[LOOP_BEGIN_LATCH]]: ; CHECK-NEXT: br label %[[LOOP_LATCH_LATCH:.*]] ; ; CHECK: [[LOOP_LATCH_LATCH]]: ; CHECK-NEXT: %[[V_LATCH:.*]] = load i1, i1* %ptr ; CHECK: br i1 %[[V_LATCH]], label %[[LOOP_BEGIN_LATCH]], label %[[LOOP_EXIT_LATCH:.*]] ; ; CHECK: [[LOOP_EXIT_LATCH]]: ; CHECK-NEXT: br label %loop_exit loop_exit: ret i32 0 ; CHECK: loop_exit: ; CHECK-NEXT: ret i32 0 } ; A test case designed to exercise unusual properties of switches: they ; can introduce multiple edges to successors. These need lots of special case ; handling as they get collapsed in many cases (domtree, the unswitch itself) ; but not in all cases (the PHI node operands). define i32 @test28(i32 %arg) { ; CHECK-LABEL: @test28( entry: br label %header ; CHECK-NEXT: entry: ; CHECK-NEXT: switch i32 %arg, label %[[ENTRY_SPLIT_C:.*]] [ ; CHECK-NEXT: i32 0, label %[[ENTRY_SPLIT_A:.*]] ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_A]] ; CHECK-NEXT: i32 2, label %[[ENTRY_SPLIT_B:.*]] ; CHECK-NEXT: i32 3, label %[[ENTRY_SPLIT_C]] ; CHECK-NEXT: ] header: %tmp = call i32 @d() %cmp1 = icmp eq i32 %tmp, 0 ; We set up a chain through all the successors of the switch that doesn't ; involve the switch so that we can have interesting PHI nodes in them. br i1 %cmp1, label %body.a, label %dispatch dispatch: ; Switch with multiple successors. We arrange the last successor to be the ; default to make the test case easier to read. This has a duplicate edge ; both to the default destination (which is completely superfluous but ; technically valid IR) and to a regular successor. switch i32 %arg, label %body.c [ i32 0, label %body.a i32 1, label %body.a i32 2, label %body.b i32 3, label %body.c ] body.a: %tmp.a.phi = phi i32 [ 0, %header ], [ %tmp, %dispatch ], [ %tmp, %dispatch ] %tmp.a = call i32 @a() %tmp.a.sum = add i32 %tmp.a.phi, %tmp.a br label %body.b ; Unswitched 'a' loop. ; ; CHECK: [[ENTRY_SPLIT_A]]: ; CHECK-NEXT: br label %[[HEADER_A:.*]] ; ; CHECK: [[HEADER_A]]: ; CHECK-NEXT: %[[TMP_A:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_A:.*]] = icmp eq i32 %[[TMP_A]], 0 ; CHECK-NEXT: br i1 %[[CMP1_A]], label %[[BODY_A_A:.*]], label %[[DISPATCH_A:.*]] ; ; CHECK: [[DISPATCH_A]]: ; CHECK-NEXT: br label %[[BODY_A_A]] ; ; CHECK: [[BODY_A_A]]: ; CHECK-NEXT: %[[TMP_A_PHI_A:.*]] = phi i32 [ 0, %[[HEADER_A]] ], [ %[[TMP_A]], %[[DISPATCH_A]] ] ; CHECK-NEXT: %[[TMP_A_A:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_A:.*]] = add i32 %[[TMP_A_PHI_A]], %[[TMP_A_A]] ; CHECK-NEXT: br label %[[BODY_B_A:.*]] ; ; CHECK: [[BODY_B_A]]: ; CHECK-NEXT: %[[TMP_B_PHI_A:.*]] = phi i32 [ %[[TMP_A_SUM_A]], %[[BODY_A_A]] ] ; CHECK-NEXT: %[[TMP_B_A:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_A:.*]] = add i32 %[[TMP_B_PHI_A]], %[[TMP_B_A]] ; CHECK-NEXT: br label %[[BODY_C_A:.*]] ; ; CHECK: [[BODY_C_A]]: ; CHECK-NEXT: %[[TMP_C_PHI_A:.*]] = phi i32 [ %[[TMP_B_SUM_A]], %[[BODY_B_A]] ] ; CHECK-NEXT: %[[TMP_C_A:.*]] = call i32 @c() ; CHECK-NEXT: %[[TMP_C_SUM_A:.*]] = add i32 %[[TMP_C_PHI_A]], %[[TMP_C_A]] ; CHECK-NEXT: br label %[[LATCH_A:.*]] ; ; CHECK: [[LATCH_A]]: ; CHECK-NEXT: %[[CMP2_A:.*]] = icmp slt i32 %[[TMP_C_SUM_A]], 42 ; CHECK: br i1 %[[CMP2_A]], label %[[HEADER_A]], label %[[LOOP_EXIT_A:.*]] ; ; CHECK: [[LOOP_EXIT_A]]: ; CHECK-NEXT: %[[LCSSA_A:.*]] = phi i32 [ %[[TMP_C_SUM_A]], %[[LATCH_A]] ] ; CHECK-NEXT: br label %exit body.b: %tmp.b.phi = phi i32 [ %tmp, %dispatch ], [ %tmp.a.sum, %body.a ] %tmp.b = call i32 @b() %tmp.b.sum = add i32 %tmp.b.phi, %tmp.b br label %body.c ; Unswitched 'b' loop. ; ; CHECK: [[ENTRY_SPLIT_B]]: ; CHECK-NEXT: br label %[[HEADER_B:.*]] ; ; CHECK: [[HEADER_B]]: ; CHECK-NEXT: %[[TMP_B:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_B:.*]] = icmp eq i32 %[[TMP_B]], 0 ; CHECK-NEXT: br i1 %[[CMP1_B]], label %[[BODY_A_B:.*]], label %[[DISPATCH_B:.*]] ; ; CHECK: [[DISPATCH_B]]: ; CHECK-NEXT: br label %[[BODY_B_B:.*]] ; ; CHECK: [[BODY_A_B]]: ; CHECK-NEXT: %[[TMP_A_PHI_B:.*]] = phi i32 [ 0, %[[HEADER_B]] ] ; CHECK-NEXT: %[[TMP_A_B:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_B:.*]] = add i32 %[[TMP_A_PHI_B]], %[[TMP_A_B]] ; CHECK-NEXT: br label %[[BODY_B_B:.*]] ; ; CHECK: [[BODY_B_B]]: ; CHECK-NEXT: %[[TMP_B_PHI_B:.*]] = phi i32 [ %[[TMP_B]], %[[DISPATCH_B]] ], [ %[[TMP_A_SUM_B]], %[[BODY_A_B]] ] ; CHECK-NEXT: %[[TMP_B_B:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_B:.*]] = add i32 %[[TMP_B_PHI_B]], %[[TMP_B_B]] ; CHECK-NEXT: br label %[[BODY_C_B:.*]] ; ; CHECK: [[BODY_C_B]]: ; CHECK-NEXT: %[[TMP_C_PHI_B:.*]] = phi i32 [ %[[TMP_B_SUM_B]], %[[BODY_B_B]] ] ; CHECK-NEXT: %[[TMP_C_B:.*]] = call i32 @c() ; CHECK-NEXT: %[[TMP_C_SUM_B:.*]] = add i32 %[[TMP_C_PHI_B]], %[[TMP_C_B]] ; CHECK-NEXT: br label %[[LATCH_B:.*]] ; ; CHECK: [[LATCH_B]]: ; CHECK-NEXT: %[[CMP2_B:.*]] = icmp slt i32 %[[TMP_C_SUM_B]], 42 ; CHECK: br i1 %[[CMP2_B]], label %[[HEADER_B]], label %[[LOOP_EXIT_B:.*]] ; ; CHECK: [[LOOP_EXIT_B]]: ; CHECK-NEXT: %[[LCSSA_B:.*]] = phi i32 [ %[[TMP_C_SUM_B]], %[[LATCH_B]] ] ; CHECK-NEXT: br label %[[EXIT_SPLIT:.*]] body.c: %tmp.c.phi = phi i32 [ %tmp, %dispatch ], [ %tmp, %dispatch ], [ %tmp.b.sum, %body.b ] %tmp.c = call i32 @c() %tmp.c.sum = add i32 %tmp.c.phi, %tmp.c br label %latch ; Unswitched 'c' loop. ; ; CHECK: [[ENTRY_SPLIT_C]]: ; CHECK-NEXT: br label %[[HEADER_C:.*]] ; ; CHECK: [[HEADER_C]]: ; CHECK-NEXT: %[[TMP_C:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_C:.*]] = icmp eq i32 %[[TMP_C]], 0 ; CHECK-NEXT: br i1 %[[CMP1_C]], label %[[BODY_A_C:.*]], label %[[DISPATCH_C:.*]] ; ; CHECK: [[DISPATCH_C]]: ; CHECK-NEXT: br label %[[BODY_C_C:.*]] ; ; CHECK: [[BODY_A_C]]: ; CHECK-NEXT: %[[TMP_A_PHI_C:.*]] = phi i32 [ 0, %[[HEADER_C]] ] ; CHECK-NEXT: %[[TMP_A_C:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_C:.*]] = add i32 %[[TMP_A_PHI_C]], %[[TMP_A_C]] ; CHECK-NEXT: br label %[[BODY_B_C:.*]] ; ; CHECK: [[BODY_B_C]]: ; CHECK-NEXT: %[[TMP_B_PHI_C:.*]] = phi i32 [ %[[TMP_A_SUM_C]], %[[BODY_A_C]] ] ; CHECK-NEXT: %[[TMP_B_C:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_C:.*]] = add i32 %[[TMP_B_PHI_C]], %[[TMP_B_C]] ; CHECK-NEXT: br label %[[BODY_C_C:.*]] ; ; CHECK: [[BODY_C_C]]: ; CHECK-NEXT: %[[TMP_C_PHI_C:.*]] = phi i32 [ %[[TMP_C]], %[[DISPATCH_C]] ], [ %[[TMP_B_SUM_C]], %[[BODY_B_C]] ] ; CHECK-NEXT: %[[TMP_C_C:.*]] = call i32 @c() ; CHECK-NEXT: %[[TMP_C_SUM_C:.*]] = add i32 %[[TMP_C_PHI_C]], %[[TMP_C_C]] ; CHECK-NEXT: br label %[[LATCH_C:.*]] ; ; CHECK: [[LATCH_C]]: ; CHECK-NEXT: %[[CMP2_C:.*]] = icmp slt i32 %[[TMP_C_SUM_C]], 42 ; CHECK: br i1 %[[CMP2_C]], label %[[HEADER_C]], label %[[LOOP_EXIT_C:.*]] ; ; CHECK: [[LOOP_EXIT_C]]: ; CHECK-NEXT: %[[LCSSA_C:.*]] = phi i32 [ %[[TMP_C_SUM_C]], %[[LATCH_C]] ] ; CHECK-NEXT: br label %[[EXIT_SPLIT]] latch: %cmp2 = icmp slt i32 %tmp.c.sum, 42 br i1 %cmp2, label %header, label %exit exit: %lcssa.phi = phi i32 [ %tmp.c.sum, %latch ] ret i32 %lcssa.phi ; CHECK: [[EXIT_SPLIT]]: ; CHECK-NEXT: %[[EXIT_PHI1:.*]] = phi i32 [ %[[LCSSA_C]], %[[LOOP_EXIT_C]] ], [ %[[LCSSA_B]], %[[LOOP_EXIT_B]] ] ; CHECK-NEXT: br label %exit ; CHECK: exit: ; CHECK-NEXT: %[[EXIT_PHI2:.*]] = phi i32 [ %[[EXIT_PHI1]], %[[EXIT_SPLIT]] ], [ %[[LCSSA_A]], %[[LOOP_EXIT_A]] ] ; CHECK-NEXT: ret i32 %[[EXIT_PHI2]] } ; Similar to @test28 but designed to have one of the duplicate edges be ; a loop exit edge as those can in some cases be special. Among other things, ; this includes an LCSSA phi with multiple entries despite being a dedicated ; exit block. define i32 @test29(i32 %arg) { ; CHECK-LABEL: define i32 @test29( entry: br label %header ; CHECK-NEXT: entry: ; CHECK-NEXT: switch i32 %arg, label %[[ENTRY_SPLIT_EXIT:.*]] [ ; CHECK-NEXT: i32 -1, label %[[ENTRY_SPLIT_EXIT]] ; CHECK-NEXT: i32 0, label %[[ENTRY_SPLIT_A:.*]] ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_B:.*]] ; CHECK-NEXT: i32 2, label %[[ENTRY_SPLIT_B]] ; CHECK-NEXT: ] header: %tmp = call i32 @d() %cmp1 = icmp eq i32 %tmp, 0 br i1 %cmp1, label %body.a, label %dispatch dispatch: switch i32 %arg, label %loop.exit1 [ i32 -1, label %loop.exit1 i32 0, label %body.a i32 1, label %body.b i32 2, label %body.b ] body.a: %tmp.a.phi = phi i32 [ 0, %header ], [ %tmp, %dispatch ] %tmp.a = call i32 @a() %tmp.a.sum = add i32 %tmp.a.phi, %tmp.a br label %body.b ; Unswitched 'a' loop. ; ; CHECK: [[ENTRY_SPLIT_A]]: ; CHECK-NEXT: br label %[[HEADER_A:.*]] ; ; CHECK: [[HEADER_A]]: ; CHECK-NEXT: %[[TMP_A:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_A:.*]] = icmp eq i32 %[[TMP_A]], 0 ; CHECK-NEXT: br i1 %[[CMP1_A]], label %[[BODY_A_A:.*]], label %[[DISPATCH_A:.*]] ; ; CHECK: [[DISPATCH_A]]: ; CHECK-NEXT: br label %[[BODY_A_A]] ; ; CHECK: [[BODY_A_A]]: ; CHECK-NEXT: %[[TMP_A_PHI_A:.*]] = phi i32 [ 0, %[[HEADER_A]] ], [ %[[TMP_A]], %[[DISPATCH_A]] ] ; CHECK-NEXT: %[[TMP_A_A:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_A:.*]] = add i32 %[[TMP_A_PHI_A]], %[[TMP_A_A]] ; CHECK-NEXT: br label %[[BODY_B_A:.*]] ; ; CHECK: [[BODY_B_A]]: ; CHECK-NEXT: %[[TMP_B_PHI_A:.*]] = phi i32 [ %[[TMP_A_SUM_A]], %[[BODY_A_A]] ] ; CHECK-NEXT: %[[TMP_B_A:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_A:.*]] = add i32 %[[TMP_B_PHI_A]], %[[TMP_B_A]] ; CHECK-NEXT: br label %[[LATCH_A:.*]] ; ; CHECK: [[LATCH_A]]: ; CHECK-NEXT: %[[CMP2_A:.*]] = icmp slt i32 %[[TMP_B_SUM_A]], 42 ; CHECK: br i1 %[[CMP2_A]], label %[[HEADER_A]], label %[[LOOP_EXIT_A:.*]] ; ; CHECK: [[LOOP_EXIT_A]]: ; CHECK-NEXT: %[[LCSSA_A:.*]] = phi i32 [ %[[TMP_B_SUM_A]], %[[LATCH_A]] ] ; CHECK-NEXT: br label %loop.exit2 body.b: %tmp.b.phi = phi i32 [ %tmp, %dispatch ], [ %tmp, %dispatch ], [ %tmp.a.sum, %body.a ] %tmp.b = call i32 @b() %tmp.b.sum = add i32 %tmp.b.phi, %tmp.b br label %latch ; Unswitched 'b' loop. ; ; CHECK: [[ENTRY_SPLIT_B]]: ; CHECK-NEXT: br label %[[HEADER_B:.*]] ; ; CHECK: [[HEADER_B]]: ; CHECK-NEXT: %[[TMP_B:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_B:.*]] = icmp eq i32 %[[TMP_B]], 0 ; CHECK-NEXT: br i1 %[[CMP1_B]], label %[[BODY_A_B:.*]], label %[[DISPATCH_B:.*]] ; ; CHECK: [[DISPATCH_B]]: ; CHECK-NEXT: br label %[[BODY_B_B]] ; ; CHECK: [[BODY_A_B]]: ; CHECK-NEXT: %[[TMP_A_PHI_B:.*]] = phi i32 [ 0, %[[HEADER_B]] ] ; CHECK-NEXT: %[[TMP_A_B:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_B:.*]] = add i32 %[[TMP_A_PHI_B]], %[[TMP_A_B]] ; CHECK-NEXT: br label %[[BODY_B_B:.*]] ; ; CHECK: [[BODY_B_B]]: ; CHECK-NEXT: %[[TMP_B_PHI_B:.*]] = phi i32 [ %[[TMP_B]], %[[DISPATCH_B]] ], [ %[[TMP_A_SUM_B]], %[[BODY_A_B]] ] ; CHECK-NEXT: %[[TMP_B_B:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_B:.*]] = add i32 %[[TMP_B_PHI_B]], %[[TMP_B_B]] ; CHECK-NEXT: br label %[[LATCH_B:.*]] ; ; CHECK: [[LATCH_B]]: ; CHECK-NEXT: %[[CMP2_B:.*]] = icmp slt i32 %[[TMP_B_SUM_B]], 42 ; CHECK: br i1 %[[CMP2_B]], label %[[HEADER_B]], label %[[LOOP_EXIT_B:.*]] ; ; CHECK: [[LOOP_EXIT_B]]: ; CHECK-NEXT: %[[LCSSA_B:.*]] = phi i32 [ %[[TMP_B_SUM_B]], %[[LATCH_B]] ] ; CHECK-NEXT: br label %[[LOOP_EXIT2_SPLIT:.*]] latch: %cmp2 = icmp slt i32 %tmp.b.sum, 42 br i1 %cmp2, label %header, label %loop.exit2 loop.exit1: %l1.phi = phi i32 [ %tmp, %dispatch ], [ %tmp, %dispatch ] br label %exit ; Unswitched 'exit' loop. ; ; CHECK: [[ENTRY_SPLIT_EXIT]]: ; CHECK-NEXT: br label %[[HEADER_EXIT:.*]] ; ; CHECK: [[HEADER_EXIT]]: ; CHECK-NEXT: %[[TMP_EXIT:.*]] = call i32 @d() ; CHECK-NEXT: %[[CMP1_EXIT:.*]] = icmp eq i32 %[[TMP_EXIT]], 0 ; CHECK-NEXT: br i1 %[[CMP1_EXIT]], label %[[BODY_A_EXIT:.*]], label %[[DISPATCH_EXIT:.*]] ; ; CHECK: [[DISPATCH_EXIT]]: ; CHECK-NEXT: %[[TMP_LCSSA:.*]] = phi i32 [ %[[TMP_EXIT]], %[[HEADER_EXIT]] ] ; CHECK-NEXT: br label %loop.exit1 ; ; CHECK: [[BODY_A_EXIT]]: ; CHECK-NEXT: %[[TMP_A_PHI_EXIT:.*]] = phi i32 [ 0, %[[HEADER_EXIT]] ] ; CHECK-NEXT: %[[TMP_A_EXIT:.*]] = call i32 @a() ; CHECK-NEXT: %[[TMP_A_SUM_EXIT:.*]] = add i32 %[[TMP_A_PHI_EXIT]], %[[TMP_A_EXIT]] ; CHECK-NEXT: br label %[[BODY_B_EXIT:.*]] ; ; CHECK: [[BODY_B_EXIT]]: ; CHECK-NEXT: %[[TMP_B_PHI_EXIT:.*]] = phi i32 [ %[[TMP_A_SUM_EXIT]], %[[BODY_A_EXIT]] ] ; CHECK-NEXT: %[[TMP_B_EXIT:.*]] = call i32 @b() ; CHECK-NEXT: %[[TMP_B_SUM_EXIT:.*]] = add i32 %[[TMP_B_PHI_EXIT]], %[[TMP_B_EXIT]] ; CHECK-NEXT: br label %[[LATCH_EXIT:.*]] ; ; CHECK: [[LATCH_EXIT]]: ; CHECK-NEXT: %[[CMP2_EXIT:.*]] = icmp slt i32 %[[TMP_B_SUM_EXIT]], 42 ; CHECK: br i1 %[[CMP2_EXIT]], label %[[HEADER_EXIT]], label %[[LOOP_EXIT_EXIT:.*]] ; ; CHECK: loop.exit1: ; CHECK-NEXT: %[[L1_PHI:.*]] = phi i32 [ %[[TMP_LCSSA]], %[[DISPATCH_EXIT]] ] ; CHECK-NEXT: br label %exit ; ; CHECK: [[LOOP_EXIT_EXIT]]: ; CHECK-NEXT: %[[L2_PHI:.*]] = phi i32 [ %[[TMP_B_SUM_EXIT]], %[[LATCH_EXIT]] ] ; CHECK-NEXT: br label %[[LOOP_EXIT2_SPLIT]] loop.exit2: %l2.phi = phi i32 [ %tmp.b.sum, %latch ] br label %exit ; CHECK: [[LOOP_EXIT2_SPLIT]]: ; CHECK-NEXT: %[[LOOP_EXIT_PHI1:.*]] = phi i32 [ %[[L2_PHI]], %[[LOOP_EXIT_EXIT]] ], [ %[[LCSSA_B]], %[[LOOP_EXIT_B]] ] ; CHECK-NEXT: br label %loop.exit2 ; ; CHECK: loop.exit2: ; CHECK-NEXT: %[[LOOP_EXIT_PHI2:.*]] = phi i32 [ %[[LOOP_EXIT_PHI1]], %[[LOOP_EXIT2_SPLIT]] ], [ %[[LCSSA_A]], %[[LOOP_EXIT_A]] ] ; CHECK-NEXT: br label %exit exit: %l.phi = phi i32 [ %l1.phi, %loop.exit1 ], [ %l2.phi, %loop.exit2 ] ret i32 %l.phi ; CHECK: exit: ; CHECK-NEXT: %[[EXIT_PHI:.*]] = phi i32 [ %[[L1_PHI]], %loop.exit1 ], [ %[[LOOP_EXIT_PHI2]], %loop.exit2 ] ; CHECK-NEXT: ret i32 %[[EXIT_PHI]] } ; Unswitch will not actually change the loop nest from: ; A < B < C define void @hoist_inner_loop0() { ; CHECK-LABEL: define void @hoist_inner_loop0( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: br label %b.header ; CHECK: a.header: ; CHECK-NEXT: br label %b.header b.header: %v1 = call i1 @cond() br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[B_HEADER_SPLIT_US:.*]], label %[[B_HEADER_SPLIT:.*]] ; ; CHECK: [[B_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[C_HEADER_US:.*]] ; ; CHECK: [[C_HEADER_US]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[B_LATCH_SPLIT_US:.*]] ; ; CHECK: [[B_LATCH_SPLIT_US]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: [[B_HEADER_SPLIT]]: ; CHECK-NEXT: br label %c.header c.header: call i32 @c() br i1 %v1, label %b.latch, label %c.latch ; CHECK: c.header: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %c.latch c.latch: %v2 = call i1 @cond() br i1 %v2, label %c.header, label %b.latch ; CHECK: c.latch: ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %c.header, label %[[B_LATCH_SPLIT:.*]] b.latch: %v3 = call i1 @cond() br i1 %v3, label %b.header, label %a.latch ; CHECK: [[B_LATCH_SPLIT]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: b.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %b.header, label %a.latch a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; Unswitch will transform the loop nest from: ; A < B < C ; into ; A < (B, C) define void @hoist_inner_loop1(i32* %ptr) { ; CHECK-LABEL: define void @hoist_inner_loop1( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: %x.a = load i32, i32* %ptr br label %b.header ; CHECK: a.header: ; CHECK-NEXT: %x.a = load i32, i32* %ptr ; CHECK-NEXT: br label %b.header b.header: %x.b = load i32, i32* %ptr %v1 = call i1 @cond() br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %x.b = load i32, i32* %ptr ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[B_HEADER_SPLIT_US:.*]], label %[[B_HEADER_SPLIT:.*]] ; ; CHECK: [[B_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[C_HEADER_US:.*]] ; ; CHECK: [[C_HEADER_US]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[B_LATCH_US:.*]] ; ; CHECK: [[B_LATCH_US]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: [[B_HEADER_SPLIT]]: ; CHECK-NEXT: %[[X_B_LCSSA:.*]] = phi i32 [ %x.b, %b.header ] ; CHECK-NEXT: br label %c.header c.header: call i32 @c() br i1 %v1, label %b.latch, label %c.latch ; CHECK: c.header: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %c.latch c.latch: ; Use values from other loops to check LCSSA form. store i32 %x.a, i32* %ptr store i32 %x.b, i32* %ptr %v2 = call i1 @cond() br i1 %v2, label %c.header, label %a.exit.c ; CHECK: c.latch: ; CHECK-NEXT: store i32 %x.a, i32* %ptr ; CHECK-NEXT: store i32 %[[X_B_LCSSA]], i32* %ptr ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %c.header, label %a.exit.c b.latch: %v3 = call i1 @cond() br i1 %v3, label %b.header, label %a.exit.b ; CHECK: b.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %b.header, label %a.exit.b a.exit.c: br label %a.latch ; CHECK: a.exit.c ; CHECK-NEXT: br label %a.latch a.exit.b: br label %a.latch ; CHECK: a.exit.b: ; CHECK-NEXT: br label %a.latch a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; Unswitch will transform the loop nest from: ; A < B < C ; into ; (A < B), C define void @hoist_inner_loop2(i32* %ptr) { ; CHECK-LABEL: define void @hoist_inner_loop2( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: %x.a = load i32, i32* %ptr br label %b.header ; CHECK: a.header: ; CHECK-NEXT: %x.a = load i32, i32* %ptr ; CHECK-NEXT: br label %b.header b.header: %x.b = load i32, i32* %ptr %v1 = call i1 @cond() br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %x.b = load i32, i32* %ptr ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[B_HEADER_SPLIT_US:.*]], label %[[B_HEADER_SPLIT:.*]] ; ; CHECK: [[B_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[C_HEADER_US:.*]] ; ; CHECK: [[C_HEADER_US]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[B_LATCH_US:.*]] ; ; CHECK: [[B_LATCH_US]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: [[B_HEADER_SPLIT]]: ; CHECK-NEXT: %[[X_A_LCSSA:.*]] = phi i32 [ %x.a, %b.header ] ; CHECK-NEXT: %[[X_B_LCSSA:.*]] = phi i32 [ %x.b, %b.header ] ; CHECK-NEXT: br label %c.header c.header: call i32 @c() br i1 %v1, label %b.latch, label %c.latch ; CHECK: c.header: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %c.latch c.latch: ; Use values from other loops to check LCSSA form. store i32 %x.a, i32* %ptr store i32 %x.b, i32* %ptr %v2 = call i1 @cond() br i1 %v2, label %c.header, label %exit ; CHECK: c.latch: ; CHECK-NEXT: store i32 %[[X_A_LCSSA]], i32* %ptr ; CHECK-NEXT: store i32 %[[X_B_LCSSA]], i32* %ptr ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %c.header, label %exit b.latch: %v3 = call i1 @cond() br i1 %v3, label %b.header, label %a.latch ; CHECK: b.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %b.header, label %a.latch a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; Same as @hoist_inner_loop2 but with a nested loop inside the hoisted loop. ; Unswitch will transform the loop nest from: ; A < B < C < D ; into ; (A < B), (C < D) define void @hoist_inner_loop3(i32* %ptr) { ; CHECK-LABEL: define void @hoist_inner_loop3( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: %x.a = load i32, i32* %ptr br label %b.header ; CHECK: a.header: ; CHECK-NEXT: %x.a = load i32, i32* %ptr ; CHECK-NEXT: br label %b.header b.header: %x.b = load i32, i32* %ptr %v1 = call i1 @cond() br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %x.b = load i32, i32* %ptr ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[B_HEADER_SPLIT_US:.*]], label %[[B_HEADER_SPLIT:.*]] ; ; CHECK: [[B_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[C_HEADER_US:.*]] ; ; CHECK: [[C_HEADER_US]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[B_LATCH_US:.*]] ; ; CHECK: [[B_LATCH_US]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: [[B_HEADER_SPLIT]]: ; CHECK-NEXT: %[[X_A_LCSSA:.*]] = phi i32 [ %x.a, %b.header ] ; CHECK-NEXT: %[[X_B_LCSSA:.*]] = phi i32 [ %x.b, %b.header ] ; CHECK-NEXT: br label %c.header c.header: call i32 @c() br i1 %v1, label %b.latch, label %c.body ; CHECK: c.header: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %c.body c.body: %x.c = load i32, i32* %ptr br label %d.header ; CHECK: c.body: ; CHECK-NEXT: %x.c = load i32, i32* %ptr ; CHECK-NEXT: br label %d.header d.header: ; Use values from other loops to check LCSSA form. store i32 %x.a, i32* %ptr store i32 %x.b, i32* %ptr store i32 %x.c, i32* %ptr %v2 = call i1 @cond() br i1 %v2, label %d.header, label %c.latch ; CHECK: d.header: ; CHECK-NEXT: store i32 %[[X_A_LCSSA]], i32* %ptr ; CHECK-NEXT: store i32 %[[X_B_LCSSA]], i32* %ptr ; CHECK-NEXT: store i32 %x.c, i32* %ptr ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %d.header, label %c.latch c.latch: %v3 = call i1 @cond() br i1 %v3, label %c.header, label %exit ; CHECK: c.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %c.header, label %exit b.latch: %v4 = call i1 @cond() br i1 %v4, label %b.header, label %a.latch ; CHECK: b.latch: ; CHECK-NEXT: %v4 = call i1 @cond() ; CHECK-NEXT: br i1 %v4, label %b.header, label %a.latch a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; This test is designed to exercise checking multiple remaining exits from the ; loop being unswitched. ; Unswitch will transform the loop nest from: ; A < B < C < D ; into ; A < B < (C, D) define void @hoist_inner_loop4() { ; CHECK-LABEL: define void @hoist_inner_loop4( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: br label %b.header ; CHECK: a.header: ; CHECK-NEXT: br label %b.header b.header: br label %c.header ; CHECK: b.header: ; CHECK-NEXT: br label %c.header c.header: %v1 = call i1 @cond() br label %d.header ; CHECK: c.header: ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[C_HEADER_SPLIT_US:.*]], label %[[C_HEADER_SPLIT:.*]] ; ; CHECK: [[C_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[D_HEADER_US:.*]] ; ; CHECK: [[D_HEADER_US]]: ; CHECK-NEXT: call i32 @d() ; CHECK-NEXT: br label %[[C_LATCH_US:.*]] ; ; CHECK: [[C_LATCH_US]]: ; CHECK-NEXT: br label %c.latch ; ; CHECK: [[C_HEADER_SPLIT]]: ; CHECK-NEXT: br label %d.header d.header: call i32 @d() br i1 %v1, label %c.latch, label %d.exiting1 ; CHECK: d.header: ; CHECK-NEXT: call i32 @d() ; CHECK-NEXT: br label %d.exiting1 d.exiting1: %v2 = call i1 @cond() br i1 %v2, label %d.exiting2, label %a.latch ; CHECK: d.exiting1: ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %d.exiting2, label %a.latch d.exiting2: %v3 = call i1 @cond() br i1 %v3, label %d.exiting3, label %loopexit.d ; CHECK: d.exiting2: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %d.exiting3, label %loopexit.d d.exiting3: %v4 = call i1 @cond() br i1 %v4, label %d.latch, label %b.latch ; CHECK: d.exiting3: ; CHECK-NEXT: %v4 = call i1 @cond() ; CHECK-NEXT: br i1 %v4, label %d.latch, label %b.latch d.latch: br label %d.header ; CHECK: d.latch: ; CHECK-NEXT: br label %d.header c.latch: %v5 = call i1 @cond() br i1 %v5, label %c.header, label %loopexit.c ; CHECK: c.latch: ; CHECK-NEXT: %v5 = call i1 @cond() ; CHECK-NEXT: br i1 %v5, label %c.header, label %loopexit.c b.latch: br label %b.header ; CHECK: b.latch: ; CHECK-NEXT: br label %b.header a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header loopexit.d: br label %exit ; CHECK: loopexit.d: ; CHECK-NEXT: br label %exit loopexit.c: br label %exit ; CHECK: loopexit.c: ; CHECK-NEXT: br label %exit exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; Unswitch will transform the loop nest from: ; A < B < C < D ; into ; A < ((B < C), D) define void @hoist_inner_loop5(i32* %ptr) { ; CHECK-LABEL: define void @hoist_inner_loop5( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: %x.a = load i32, i32* %ptr br label %b.header ; CHECK: a.header: ; CHECK-NEXT: %x.a = load i32, i32* %ptr ; CHECK-NEXT: br label %b.header b.header: %x.b = load i32, i32* %ptr br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %x.b = load i32, i32* %ptr ; CHECK-NEXT: br label %c.header c.header: %x.c = load i32, i32* %ptr %v1 = call i1 @cond() br label %d.header ; CHECK: c.header: ; CHECK-NEXT: %x.c = load i32, i32* %ptr ; CHECK-NEXT: %v1 = call i1 @cond() ; CHECK-NEXT: br i1 %v1, label %[[C_HEADER_SPLIT_US:.*]], label %[[C_HEADER_SPLIT:.*]] ; ; CHECK: [[C_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[D_HEADER_US:.*]] ; ; CHECK: [[D_HEADER_US]]: ; CHECK-NEXT: call i32 @d() ; CHECK-NEXT: br label %[[C_LATCH_US:.*]] ; ; CHECK: [[C_LATCH_US]]: ; CHECK-NEXT: br label %c.latch ; ; CHECK: [[C_HEADER_SPLIT]]: ; CHECK-NEXT: %[[X_B_LCSSA:.*]] = phi i32 [ %x.b, %c.header ] ; CHECK-NEXT: %[[X_C_LCSSA:.*]] = phi i32 [ %x.c, %c.header ] ; CHECK-NEXT: br label %d.header d.header: call i32 @d() br i1 %v1, label %c.latch, label %d.latch ; CHECK: d.header: ; CHECK-NEXT: call i32 @d() ; CHECK-NEXT: br label %d.latch d.latch: ; Use values from other loops to check LCSSA form. store i32 %x.a, i32* %ptr store i32 %x.b, i32* %ptr store i32 %x.c, i32* %ptr %v2 = call i1 @cond() br i1 %v2, label %d.header, label %a.latch ; CHECK: d.latch: ; CHECK-NEXT: store i32 %x.a, i32* %ptr ; CHECK-NEXT: store i32 %[[X_B_LCSSA]], i32* %ptr ; CHECK-NEXT: store i32 %[[X_C_LCSSA]], i32* %ptr ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %d.header, label %a.latch c.latch: %v3 = call i1 @cond() br i1 %v3, label %c.header, label %b.latch ; CHECK: c.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %c.header, label %b.latch b.latch: br label %b.header ; CHECK: b.latch: ; CHECK-NEXT: br label %b.header a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } define void @hoist_inner_loop_switch(i32* %ptr) { ; CHECK-LABEL: define void @hoist_inner_loop_switch( entry: br label %a.header ; CHECK: entry: ; CHECK-NEXT: br label %a.header a.header: %x.a = load i32, i32* %ptr br label %b.header ; CHECK: a.header: ; CHECK-NEXT: %x.a = load i32, i32* %ptr ; CHECK-NEXT: br label %b.header b.header: %x.b = load i32, i32* %ptr %v1 = call i32 @cond.i32() br label %c.header ; CHECK: b.header: ; CHECK-NEXT: %x.b = load i32, i32* %ptr ; CHECK-NEXT: %v1 = call i32 @cond.i32() ; CHECK-NEXT: switch i32 %v1, label %[[B_HEADER_SPLIT:.*]] [ ; CHECK-NEXT: i32 1, label %[[B_HEADER_SPLIT_US:.*]] ; CHECK-NEXT: i32 2, label %[[B_HEADER_SPLIT_US]] ; CHECK-NEXT: i32 3, label %[[B_HEADER_SPLIT_US]] ; CHECK-NEXT: ] ; ; CHECK: [[B_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[C_HEADER_US:.*]] ; ; CHECK: [[C_HEADER_US]]: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %[[B_LATCH_US:.*]] ; ; CHECK: [[B_LATCH_US]]: ; CHECK-NEXT: br label %b.latch ; ; CHECK: [[B_HEADER_SPLIT]]: ; CHECK-NEXT: %[[X_A_LCSSA:.*]] = phi i32 [ %x.a, %b.header ] ; CHECK-NEXT: %[[X_B_LCSSA:.*]] = phi i32 [ %x.b, %b.header ] ; CHECK-NEXT: br label %c.header c.header: call i32 @c() switch i32 %v1, label %c.latch [ i32 1, label %b.latch i32 2, label %b.latch i32 3, label %b.latch ] ; CHECK: c.header: ; CHECK-NEXT: call i32 @c() ; CHECK-NEXT: br label %c.latch c.latch: ; Use values from other loops to check LCSSA form. store i32 %x.a, i32* %ptr store i32 %x.b, i32* %ptr %v2 = call i1 @cond() br i1 %v2, label %c.header, label %exit ; CHECK: c.latch: ; CHECK-NEXT: store i32 %[[X_A_LCSSA]], i32* %ptr ; CHECK-NEXT: store i32 %[[X_B_LCSSA]], i32* %ptr ; CHECK-NEXT: %v2 = call i1 @cond() ; CHECK-NEXT: br i1 %v2, label %c.header, label %exit b.latch: %v3 = call i1 @cond() br i1 %v3, label %b.header, label %a.latch ; CHECK: b.latch: ; CHECK-NEXT: %v3 = call i1 @cond() ; CHECK-NEXT: br i1 %v3, label %b.header, label %a.latch a.latch: br label %a.header ; CHECK: a.latch: ; CHECK-NEXT: br label %a.header exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void } ; A devilish pattern. This is a crafty, crafty test case designed to risk ; creating indirect cycles with trivial and non-trivial unswitching. The inner ; loop has a switch with a trivial exit edge that can be unswitched, but the ; rest of the switch cannot be unswitched because its cost is too high. ; However, the unswitching of the trivial edge creates a new switch in the ; outer loop. *This* switch isn't trivial, but has a low cost to unswitch. When ; we unswitch this switch from the outer loop, we will remove it completely and ; create a clone of the inner loop on one side. This clone will then again be ; viable for unswitching the inner-most loop. This lets us check that the ; unswitching doesn't end up cycling infinitely even when the cycle is ; indirect and due to revisiting a loop after cloning. define void @test30(i32 %arg) { ; CHECK-LABEL: define void @test30( entry: br label %outer.header ; CHECK-NEXT: entry: ; CHECK-NEXT: switch i32 %arg, label %[[ENTRY_SPLIT:.*]] [ ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_US:.*]] ; CHECK-NEXT: i32 2, label %[[ENTRY_SPLIT_US]] ; CHECK-NEXT: ] ; ; CHECK: [[ENTRY_SPLIT_US]]: ; CHECK-NEXT: switch i32 %arg, label %[[ENTRY_SPLIT_US_SPLIT:.*]] [ ; CHECK-NEXT: i32 1, label %[[ENTRY_SPLIT_US_SPLIT_US:.*]] ; CHECK-NEXT: ] outer.header: br label %inner.header inner.header: switch i32 %arg, label %inner.loopexit1 [ i32 1, label %inner.body1 i32 2, label %inner.body2 ] inner.body1: %a = call i32 @a() br label %inner.latch ; The (super convoluted) fully unswitched loop around `@a`. ; ; CHECK: [[ENTRY_SPLIT_US_SPLIT_US]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_US_US:.*]] ; ; CHECK: [[OUTER_HEADER_US_US]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_SPLIT_US_US:.*]] ; ; CHECK: [[OUTER_LATCH_US_US:.*]]: ; CHECK-NEXT: %[[OUTER_COND_US_US:.*]] = call i1 @cond() ; CHECK-NEXT: br i1 %[[OUTER_COND_US_US]], label %[[OUTER_HEADER_US_US]], label %[[EXIT_SPLIT_US_SPLIT_US:.*]] ; ; CHECK: [[OUTER_HEADER_SPLIT_US_US]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_SPLIT_SPLIT_US_US_US:.*]] ; ; CHECK: [[INNER_LOOPEXIT2_US_US:.*]]: ; CHECK-NEXT: br label %[[OUTER_LATCH_US_US]] ; ; CHECK: [[OUTER_HEADER_SPLIT_SPLIT_US_US_US]]: ; CHECK-NEXT: br label %[[INNER_HEADER_US_US_US:.*]] ; ; CHECK: [[INNER_HEADER_US_US_US]]: ; CHECK-NEXT: br label %[[INNER_BODY1_US_US_US:.*]] ; ; CHECK: [[INNER_BODY1_US_US_US]]: ; CHECK-NEXT: %[[A:.*]] = call i32 @a() ; CHECK-NEXT: br label %[[INNER_LATCH_US_US_US:.*]] ; ; CHECK: [[INNER_LATCH_US_US_US]]: ; CHECK-NEXT: %[[PHI_A:.*]] = phi i32 [ %[[A]], %[[INNER_BODY1_US_US_US]] ] ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 %[[PHI_A]]) ; CHECK-NEXT: %[[INNER_COND_US_US_US:.*]] = call i1 @cond() ; CHECK-NEXT: br i1 %[[INNER_COND_US_US_US]], label %[[INNER_HEADER_US_US_US]], label %[[INNER_LOOPEXIT2_SPLIT_US_US_US:.*]] ; ; CHECK: [[INNER_LOOPEXIT2_SPLIT_US_US_US]]: ; CHECK-NEXT: br label %[[INNER_LOOPEXIT2_US_US]] ; ; CHECK: [[EXIT_SPLIT_US_SPLIT_US]]: ; CHECK-NEXT: br label %[[EXIT_SPLIT_US:.*]] inner.body2: %b = call i32 @b() br label %inner.latch ; The fully unswitched loop around `@b`. ; ; CHECK: [[ENTRY_SPLIT_US_SPLIT]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_US:.*]] ; ; CHECK: [[OUTER_HEADER_US]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_SPLIT_US:.*]] ; ; CHECK: [[INNER_HEADER_US:.*]]: ; CHECK-NEXT: br label %[[INNER_BODY2_US:.*]] ; ; CHECK: [[INNER_BODY2_US]]: ; CHECK-NEXT: %[[B:.*]] = call i32 @b() ; CHECK-NEXT: br label %[[INNER_LATCH_US:.*]] ; ; CHECK: [[INNER_LATCH_US]]: ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 0) ; CHECK-NEXT: call void @sink1(i32 %[[B]]) ; CHECK-NEXT: %[[INNER_COND_US:.*]] = call i1 @cond() ; CHECK-NEXT: br i1 %[[INNER_COND_US]], label %[[INNER_HEADER_US]], label %[[INNER_LOOPEXIT2_SPLIT_US:.*]] ; ; CHECK: [[INNER_LOOPEXIT2_SPLIT_US]]: ; CHECK-NEXT: br label %[[INNER_LOOPEXIT2_US:.*]] ; ; CHECK: [[OUTER_LATCH_US:.*]]: ; CHECK-NEXT: %[[OUTER_COND_US:.*]] = call i1 @cond() ; CHECK-NEXT: br i1 %[[OUTER_COND_US]], label %[[OUTER_HEADER_US]], label %[[EXIT_SPLIT_US_SPLIT:.*]] ; ; CHECK: [[OUTER_HEADER_SPLIT_US]]: ; CHECK-NEXT: br label %[[OUTER_HEADER_SPLIT_SPLIT_US:.*]] ; ; CHECK: [[OUTER_HEADER_SPLIT_SPLIT_US]]: ; CHECK-NEXT: br label %[[INNER_HEADER_US]] ; ; CHECK: [[INNER_LOOPEXIT2_US]]: ; CHECK-NEXT: br label %[[OUTER_LATCH_US]] ; ; CHECK: [[EXIT_SPLIT_US]]: ; CHECK-NEXT: br label %exit inner.latch: %phi = phi i32 [ %a, %inner.body1 ], [ %b, %inner.body2 ] ; Make 10 junk calls here to ensure we're over the "50" cost threshold of ; non-trivial unswitching for this inner switch. call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 0) call void @sink1(i32 %phi) %inner.cond = call i1 @cond() br i1 %inner.cond, label %inner.header, label %inner.loopexit2 inner.loopexit1: br label %outer.latch ; The unswitched `loopexit1` path. ; ; CHECK: [[ENTRY_SPLIT]]: ; CHECK-NEXT: br label %[[OUTER_HEADER:.*]] ; ; CHECK: outer.header: ; CHECK-NEXT: br label %inner.loopexit1 ; ; CHECK: inner.loopexit1: ; CHECK-NEXT: br label %outer.latch ; ; CHECK: outer.latch: ; CHECK-NEXT: %outer.cond = call i1 @cond() ; CHECK-NEXT: br i1 %outer.cond, label %outer.header, label %[[EXIT_SPLIT:.*]] ; ; CHECK: [[EXIT_SPLIT]]: ; CHECK-NEXT: br label %exit inner.loopexit2: br label %outer.latch outer.latch: %outer.cond = call i1 @cond() br i1 %outer.cond, label %outer.header, label %exit exit: ret void ; CHECK: exit: ; CHECK-NEXT: ret void }