; RUN: opt -passes=loop-vectorize -force-vector-width=8 -force-vector-interleave=2 -disable-output -debug -S %s 2>&1 | FileCheck --check-prefixes=CHECK %s target datalayout = "e-m:o-i64:64-i128:128-n32:64-S128" ; REQUIRES: asserts ; Check if the vector loop condition can be simplified to true for a given ; VF/IC combination. define void @test_tc_less_than_16(ptr %A, i64 %N) { ; CHECK: LV: Scalarizing: %cmp = ; CHECK: VPlan 'Initial VPlan for VF={8},UF>=1' { ; CHECK-NEXT: Live-in vp<[[VFxUF:%.+]]> = VF * UF ; CHECK-NEXT: Live-in vp<[[VTC:%.+]]> = vector-trip-count ; CHECK-NEXT: vp<[[TC:%.+]]> = original trip-count ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: IR %and = and i64 %N, 15 ; CHECK-NEXT: EMIT vp<[[TC]]> = EXPAND SCEV (zext i4 (trunc i64 %N to i4) to i64) ; CHECK-NEXT: No successors ; CHECK-EMPTY: ; CHECK-NEXT: vector.ph: ; CHECK-NEXT: Successor(s): vector loop ; CHECK-EMPTY: ; CHECK-NEXT: vector loop: { ; CHECK-NEXT: vector.body: ; CHECK-NEXT: EMIT vp<[[CAN_IV:%.+]]> = CANONICAL-INDUCTION ir<0>, vp<[[CAN_IV_NEXT:%.+]]> ; CHECK-NEXT: vp<[[STEPS:%.+]]> = SCALAR-STEPS vp<[[CAN_IV]]>, ir<1> ; CHECK-NEXT: EMIT vp<[[PADD:%.+]]> = ptradd ir<%A>, vp<[[STEPS]]> ; CHECK-NEXT: vp<[[VPTR:%.]]> = vector-pointer vp<[[PADD]]> ; CHECK-NEXT: WIDEN ir<%l> = load vp<[[VPTR]]> ; CHECK-NEXT: WIDEN ir<%add> = add nsw ir<%l>, ir<10> ; CHECK-NEXT: vp<[[VPTR2:%.+]]> = vector-pointer vp<[[PADD]]> ; CHECK-NEXT: WIDEN store vp<[[VPTR2]]>, ir<%add> ; CHECK-NEXT: EMIT vp<[[CAN_IV_NEXT]]> = add nuw vp<[[CAN_IV:%.+]]>, vp<[[VFxUF]]> ; CHECK-NEXT: EMIT branch-on-count vp<[[CAN_IV_NEXT]]>, vp<[[VTC]]> ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; CHECK-NEXT: Successor(s): middle.block ; CHECK-EMPTY: ; CHECK-NEXT: middle.block: ; CHECK-NEXT: EMIT vp<[[C:%.+]]> = icmp eq vp<[[TC]]>, vp<[[VTC]]> ; CHECK-NEXT: EMIT branch-on-cond vp<[[C]]> ; CHECK-NEXT: Successor(s): ir-bb, scalar.ph ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: No successors ; CHECK-EMPTY: ; CHECK-NEXT: scalar.ph: ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; ; CHECK: Executing best plan with VF=8, UF=2 ; CHECK-NEXT: VPlan 'Final VPlan for VF={8},UF={2}' { ; CHECK-NEXT: Live-in vp<[[VFxUF:%.+]]> = VF * UF ; CHECK-NEXT: Live-in vp<[[VTC:%.+]]> = vector-trip-count ; CHECK-NEXT: vp<[[TC:%.+]]> = original trip-count ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: IR %and = and i64 %N, 15 ; CHECK-NEXT: EMIT vp<[[TC]]> = EXPAND SCEV (zext i4 (trunc i64 %N to i4) to i64) ; CHECK-NEXT: No successors ; CHECK-EMPTY: ; CHECK-NEXT: vector.ph: ; CHECK-NEXT: Successor(s): vector loop ; CHECK-EMPTY: ; CHECK-NEXT: vector loop: { ; CHECK-NEXT: vector.body: ; CHECK-NEXT: EMIT vp<[[CAN_IV:%.+]]> = CANONICAL-INDUCTION ir<0>, vp<[[CAN_IV_NEXT:%.+]]> ; CHECK-NEXT: vp<[[STEPS1:%.+]]> = SCALAR-STEPS vp<[[CAN_IV]]>, ir<1> ; CHECK-NEXT: EMIT vp<[[PADD1:%.+]]> = ptradd ir<%A>, vp<[[STEPS1]]> ; CHECK-NEXT: vp<[[VPTR1:%.]]> = vector-pointer vp<[[PADD1]]> ; CHECK-NEXT: vp<[[VPTR2:%.]]> = vector-pointer vp<[[PADD1]]>, ir<1> ; CHECK-NEXT: WIDEN ir<%l> = load vp<[[VPTR1]]> ; CHECK-NEXT: WIDEN ir<%l>.1 = load vp<[[VPTR2]]> ; CHECK-NEXT: WIDEN ir<%add> = add nsw ir<%l>, ir<10> ; CHECK-NEXT: WIDEN ir<%add>.1 = add nsw ir<%l>.1, ir<10> ; CHECK-NEXT: vp<[[VPTR3:%.+]]> = vector-pointer vp<[[PADD1]]> ; CHECK-NEXT: vp<[[VPTR4:%.+]]> = vector-pointer vp<[[PADD1]]>, ir<1> ; CHECK-NEXT: WIDEN store vp<[[VPTR3]]>, ir<%add> ; CHECK-NEXT: WIDEN store vp<[[VPTR4]]>, ir<%add>.1 ; CHECK-NEXT: EMIT vp<[[CAN_IV_NEXT]]> = add nuw vp<[[CAN_IV:%.+]]>, vp<[[VFxUF]]> ; CHECK-NEXT: EMIT branch-on-cond ir ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; CHECK-NEXT: Successor(s): middle.block ; CHECK-EMPTY: ; CHECK-NEXT: middle.block: ; CHECK-NEXT: EMIT vp<[[C:%.+]]> = icmp eq vp<[[TC]]>, vp<[[VTC]]> ; CHECK-NEXT: EMIT branch-on-cond vp<[[C]]> ; CHECK-NEXT: Successor(s): ir-bb, scalar.ph ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: No successors ; CHECK-EMPTY: ; CHECK-NEXT: scalar.ph: ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; entry: %and = and i64 %N, 15 br label %loop loop: %iv = phi i64 [ %and, %entry ], [ %iv.next, %loop ] %p.src = phi ptr [ %A, %entry ], [ %p.src.next, %loop ] %p.src.next = getelementptr inbounds i8, ptr %p.src, i64 1 %l = load i8, ptr %p.src, align 1 %add = add nsw i8 %l, 10 store i8 %add, ptr %p.src %iv.next = add nsw i64 %iv, -1 %cmp = icmp eq i64 %iv.next, 0 br i1 %cmp, label %exit, label %loop exit: ret void }