; This test exercises that we don't corrupt a loop-analysis when running loop ; unrolling in a way that deletes a loop. To do that, we first ensure the ; analysis is cached, then unroll the loop (deleting it) and make sure that the ; next function doesn't get a cache "hit" for this stale analysis result. ; ; RUN: opt -S -passes='loop(require),loop-unroll,loop(print-access-info)' -debug-pass-manager < %s 2>&1 | FileCheck %s ; ; CHECK: Starting llvm::Function pass manager run. ; CHECK: Running analysis: LoopAnalysis ; CHECK: Running analysis: InnerAnalysisManagerProxy< ; CHECK: Starting Loop pass manager run. ; CHECK: Running pass: RequireAnalysisPass<{{.*}}LoopAccessAnalysis ; CHECK: Running analysis: LoopAccessAnalysis on Loop at depth 2 containing: %inner1.header ; CHECK: Finished Loop pass manager run. ; CHECK: Starting Loop pass manager run. ; CHECK: Running pass: RequireAnalysisPass<{{.*}}LoopAccessAnalysis ; CHECK: Running analysis: LoopAccessAnalysis on Loop at depth 2 containing: %inner2.header ; CHECK: Finished Loop pass manager run. ; CHECK: Starting Loop pass manager run. ; CHECK: Running pass: RequireAnalysisPass<{{.*}}LoopAccessAnalysis ; CHECK: Running analysis: LoopAccessAnalysis on Loop at depth 1 containing: %outer.header ; CHECK: Finished Loop pass manager run. ; CHECK: Running pass: LoopUnrollPass ; CHECK: Clearing all analysis results for: inner2.header ; CHECK: Clearing all analysis results for: outer.header ; CHECK: Invalidating analysis: LoopAccessAnalysis on inner1.header ; CHECK-NOT: Invalidating analysis: LoopAccessAnalysis on inner1.header.1 ; CHECK: Starting Loop pass manager run. ; CHECK: Running pass: LoopAccessInfoPrinterPass ; CHECK: Running analysis: LoopAccessAnalysis on Loop at depth 1 containing: %inner1.header ; CHECK: Loop access info in function 'test': ; CHECK: inner1.header: ; CHECK: Finished Loop pass manager run. ; CHECK: Starting Loop pass manager run. ; CHECK: Running pass: LoopAccessInfoPrinterPass ; CHECK: Running analysis: LoopAccessAnalysis on Loop at depth 1 containing: %inner1.header.1 ; CHECK: Loop access info in function 'test': ; CHECK: inner1.header.1: ; CHECK: Finished Loop pass manager run. target triple = "x86_64-unknown-linux-gnu" define void @test(i32 %inner1.count) { ; CHECK-LABEL: define void @test( bb: br label %outer.ph outer.ph: br label %outer.header outer.header: %outer.i = phi i32 [ 0, %outer.ph ], [ %outer.i.next, %outer.latch ] br label %inner1.ph inner1.ph: br label %inner1.header inner1.header: %inner1.i = phi i32 [ 0, %inner1.ph ], [ %inner1.i.next, %inner1.header ] %inner1.i.next = add i32 %inner1.i, 1 %inner1.cond = icmp eq i32 %inner1.i, %inner1.count br i1 %inner1.cond, label %inner1.exit, label %inner1.header ; We should have two unrolled copies of this loop and nothing else. ; ; CHECK-NOT: icmp eq ; CHECK-NOT: br i1 ; CHECK: %[[COND1:.*]] = icmp eq i32 %{{.*}}, %inner1.count ; CHECK: br i1 %[[COND1]], ; CHECK-NOT: icmp eq ; CHECK-NOT: br i1 ; CHECK: %[[COND2:.*]] = icmp eq i32 %{{.*}}, %inner1.count ; CHECK: br i1 %[[COND2]], ; CHECK-NOT: icmp eq ; CHECK-NOT: br i1 inner1.exit: br label %inner2.ph inner2.ph: br label %inner2.header inner2.header: %inner2.i = phi i32 [ 0, %inner2.ph ], [ %inner2.i.next, %inner2.header ] %inner2.i.next = add i32 %inner2.i, 1 %inner2.cond = icmp eq i32 %inner2.i, 4 br i1 %inner2.cond, label %inner2.exit, label %inner2.header inner2.exit: br label %outer.latch outer.latch: %outer.i.next = add i32 %outer.i, 1 %outer.cond = icmp eq i32 %outer.i.next, 2 br i1 %outer.cond, label %outer.exit, label %outer.header outer.exit: br label %exit exit: ret void }