; REQUIRES: asserts ; RUN: opt -passes=loop-vectorize -force-vector-interleave=1 -force-vector-width=8 -S -debug %s 2>&1 | FileCheck %s define void @iv_no_binary_op_in_descriptor(i1 %c, ptr %dst) { ; CHECK-LABEL: LV: Checking a loop in 'iv_no_binary_op_in_descriptor' ; CHECK: VPlan 'Initial VPlan for VF={8},UF>=1' { ; CHECK-NEXT: Live-in vp<[[VF:%.+]]> = VF ; CHECK-NEXT: Live-in vp<[[VFxUF:%.+]]> = VF * UF ; CHECK-NEXT: Live-in vp<[[VEC_TC:%.+]]> = vector-trip-count ; CHECK-NEXT: Live-in ir<1000> = original trip-count ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: Successor(s): scalar.ph, vector.ph ; 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 ; CHECK-NEXT: ir<%iv> = WIDEN-INDUCTION ir<0>, ir<1>, vp<[[VF]]> ; CHECK-NEXT: vp<[[STEPS:%.+]]> = SCALAR-STEPS vp<[[CAN_IV]]>, ir<1> ; CHECK-NEXT: CLONE ir<%gep> = getelementptr inbounds ir<%dst>, vp<[[STEPS:%.+]]> ; CHECK-NEXT: vp<[[VEC_PTR:%.+]]> = vector-pointer ir<%gep> ; CHECK-NEXT: WIDEN store vp<[[VEC_PTR]]>, ir<%iv> ; CHECK-NEXT: EMIT vp<[[CAN_INC:%.+]]> = add nuw vp<[[CAN_IV]]>, vp<[[VFxUF]]> ; CHECK-NEXT: EMIT branch-on-count vp<[[CAN_INC]]>, vp<[[VEC_TC]]> ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; CHECK-NEXT: Successor(s): middle.block ; CHECK-EMPTY: ; CHECK-NEXT: middle.block: ; CHECK-NEXT: EMIT vp<[[CMP:%.+]]> = icmp eq ir<1000>, vp<[[VEC_TC]]> ; CHECK-NEXT: EMIT branch-on-cond vp<[[CMP]]> ; 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: EMIT-SCALAR vp<[[RESUME:%.+]]> = phi [ vp<[[VEC_TC]]>, middle.block ], [ ir<0>, ir-bb ] ; CHECK-NEXT: Successor(s): ir-bb ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: IR %iv = phi i64 [ 0, %entry ], [ %iv.next.p, %loop.latch ] (extra operand: vp<[[RESUME]]> from scalar.ph) ; CHECK: IR %iv.next = add i64 %iv, 1 ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; entry: br label %loop.header loop.header: %iv = phi i64 [ 0, %entry ], [ %iv.next.p, %loop.latch ] %gep = getelementptr inbounds i64, ptr %dst, i64 %iv store i64 %iv, ptr %gep, align 8 %iv.next = add i64 %iv, 1 br label %loop.latch loop.latch: %iv.next.p = phi i64 [ %iv.next, %loop.header ] %exitcond.not = icmp eq i64 %iv.next.p, 1000 br i1 %exitcond.not, label %exit, label %loop.header exit: ret void } ; Check that VPWidenIntOrFPInductionRecipe is expanded into smaller recipes in ; the final VPlan. define void @iv_expand(ptr %p, i64 %n) { ; CHECK-LABEL: LV: Checking a loop in 'iv_expand' ; CHECK: VPlan 'Initial VPlan for VF={8},UF>=1' { ; CHECK: vector loop: { ; CHECK-NEXT: vector.body: ; CHECK-NEXT: EMIT vp<%3> = CANONICAL-INDUCTION ir<0>, vp<%index.next> ; CHECK-NEXT: ir<%iv> = WIDEN-INDUCTION ir<0>, ir<1>, vp<%0> ; CHECK-NEXT: vp<%4> = SCALAR-STEPS vp<%3>, ir<1> ; CHECK-NEXT: CLONE ir<%q> = getelementptr ir<%p>, vp<%4> ; CHECK-NEXT: vp<%5> = vector-pointer ir<%q> ; CHECK-NEXT: WIDEN ir<%x> = load vp<%5> ; CHECK-NEXT: WIDEN ir<%y> = add ir<%x>, ir<%iv> ; CHECK-NEXT: vp<%6> = vector-pointer ir<%q> ; CHECK-NEXT: WIDEN store vp<%6>, ir<%y> ; CHECK-NEXT: EMIT vp<%index.next> = add nuw vp<%3>, vp<%1> ; CHECK-NEXT: EMIT branch-on-count vp<%index.next>, vp<%2> ; CHECK-NEXT: No successors ; CHECK-NEXT: } ; CHECK-NEXT: Successor(s): middle.block ; CHECK: VPlan 'Final VPlan for VF={8},UF={1}' ; CHECK-NEXT: Live-in ir<%n> = original trip-count ; CHECK-EMPTY: ; CHECK-NEXT: ir-bb: ; CHECK-NEXT: EMIT vp<%min.iters.check> = icmp ult ir<%n>, ir<8> ; CHECK-NEXT: EMIT branch-on-cond vp<%min.iters.check> ; CHECK-NEXT: Successor(s): ir-bb, vector.ph ; CHECK-EMPTY: ; CHECK: vector.ph: ; CHECK-NEXT: EMIT vp<%n.mod.vf> = urem ir<%n>, ir<8> ; CHECK-NEXT: EMIT vp<%n.vec> = sub ir<%n>, vp<%n.mod.vf> ; CHECK-NEXT: EMIT vp<[[STEP_VECTOR:%.+]]> = step-vector ; CHECK-NEXT: EMIT vp<[[BROADCAST_0:%.+]]> = broadcast ir<0> ; CHECK-NEXT: EMIT vp<[[BROADCAST_1:%.+]]> = broadcast ir<1> ; CHECK-NEXT: EMIT vp<[[MUL:%.+]]> = mul vp<[[STEP_VECTOR]]>, vp<[[BROADCAST_1]]> ; CHECK-NEXT: EMIT vp<[[INDUCTION:%.+]]> = add vp<[[BROADCAST_0]]>, vp<[[MUL]]> ; CHECK-NEXT: EMIT vp<[[BROADCAST_INC:%.+]]> = broadcast ir<8> ; CHECK-NEXT: Successor(s): vector.body ; CHECK-EMPTY: ; CHECK-NEXT: vector.body: ; CHECK-NEXT: EMIT-SCALAR vp<[[SCALAR_PHI:%.+]]> = phi [ ir<0>, vector.ph ], [ vp<%index.next>, vector.body ] ; CHECK-NEXT: WIDEN-PHI ir<%iv> = phi [ vp<[[INDUCTION]]>, vector.ph ], [ vp<%vec.ind.next>, vector.body ] ; CHECK-NEXT: CLONE ir<%q> = getelementptr ir<%p>, vp<[[SCALAR_PHI]]> ; CHECK-NEXT: WIDEN ir<%x> = load ir<%q> ; CHECK-NEXT: WIDEN ir<%y> = add ir<%x>, ir<%iv> ; CHECK-NEXT: WIDEN store ir<%q>, ir<%y> ; CHECK-NEXT: EMIT vp<%index.next> = add nuw vp<[[SCALAR_PHI]]>, ir<8> ; CHECK-NEXT: EMIT vp<%vec.ind.next> = add ir<%iv>, vp<[[BROADCAST_INC]]> ; CHECK-NEXT: EMIT branch-on-count vp<%index.next>, vp<%n.vec> ; CHECK-NEXT: Successor(s): middle.block, vector.body entry: br label %loop loop: %iv = phi i64 [0, %entry], [%iv.next, %loop] %q = getelementptr i64, ptr %p, i64 %iv %x = load i64, ptr %q %y = add i64 %x, %iv store i64 %y, ptr %q %iv.next = add i64 %iv, 1 %done = icmp eq i64 %iv.next, %n br i1 %done, label %exit, label %loop exit: ret void }