Index: llvm/trunk/lib/Transforms/Utils/LoopUtils.cpp
===================================================================
--- llvm/trunk/lib/Transforms/Utils/LoopUtils.cpp
+++ llvm/trunk/lib/Transforms/Utils/LoopUtils.cpp
@@ -553,22 +553,13 @@
   if (!Previous || !TheLoop->contains(Previous) || isa<PHINode>(Previous))
     return false;
 
+  // Ensure every user of the phi node is dominated by the previous value.
+  // The dominance requirement ensures the loop vectorizer will not need to
+  // vectorize the initial value prior to the first iteration of the loop.
   for (User *U : Phi->users())
     if (auto *I = dyn_cast<Instruction>(U)) {
-      // Ensure every user of the phi node is dominated by the previous value.
-      // The dominance requirement ensures the loop vectorizer will not need to
-      // vectorize the initial value prior to the first iteration of the loop.
       if (!DT->dominates(Previous, I))
         return false;
-      // When the phi node has users outside the loop, the current logic for
-      // fixFirstOrderRecurrences may generate incorrect code. Specifically, we
-      // extract the last element from the vectorized phi, which would be the
-      // update to the phi before exiting the loop. However, what we want is the
-      // previous phi value before the update (i.e. the second last update
-      // before end of the vectorized loop).
-      // See added test cases in first-order-recurrence.ll
-      if (!TheLoop->contains(I))
-        return false;
     }
 
   return true;
Index: llvm/trunk/lib/Transforms/Vectorize/LoopVectorize.cpp
===================================================================
--- llvm/trunk/lib/Transforms/Vectorize/LoopVectorize.cpp
+++ llvm/trunk/lib/Transforms/Vectorize/LoopVectorize.cpp
@@ -4078,24 +4078,34 @@
   VecPhi->addIncoming(Incoming, LI->getLoopFor(LoopVectorBody)->getLoopLatch());
 
   // Extract the last vector element in the middle block. This will be the
-  // initial value for the recurrence when jumping to the scalar loop. 
-  // FIXME: Note that the last vector element need not always be the correct one:
-  // consider a loop  where we have phi uses outside the loop - we need the
-  // second last iteration value and not the last one). For now, we avoid
-  // considering such cases as firstOrderRecurrences (see
-  // isFirstOrderRecurrence).
-  auto *Extract = Incoming;
+  // initial value for the recurrence when jumping to the scalar loop.
+  auto *ExtractForScalar = Incoming;
   if (VF > 1) {
     Builder.SetInsertPoint(LoopMiddleBlock->getTerminator());
-    Extract = Builder.CreateExtractElement(Extract, Builder.getInt32(VF - 1),
-                                           "vector.recur.extract");
+    ExtractForScalar = Builder.CreateExtractElement(
+        ExtractForScalar, Builder.getInt32(VF - 1), "vector.recur.extract");
   }
+  // Extract the second last element in the middle block if the
+  // Phi is used outside the loop. We need to extract the phi itself
+  // and not the last element (the phi update in the current iteration). This
+  // will be the value when jumping to the exit block from the LoopMiddleBlock,
+  // when the scalar loop is not run at all.
+  Value *ExtractForPhiUsedOutsideLoop = nullptr;
+  if (VF > 1)
+    ExtractForPhiUsedOutsideLoop = Builder.CreateExtractElement(
+        Incoming, Builder.getInt32(VF - 2), "vector.recur.extract.for.phi");
+  // When loop is unrolled without vectorizing, initialize
+  // ExtractForPhiUsedOutsideLoop with the value just prior to unrolled value of
+  // `Incoming`. This is analogous to the vectorized case above: extracting the
+  // second last element when VF > 1.
+  else if (UF > 1)
+    ExtractForPhiUsedOutsideLoop = PreviousParts[UF - 2];
 
   // Fix the initial value of the original recurrence in the scalar loop.
   Builder.SetInsertPoint(&*LoopScalarPreHeader->begin());
   auto *Start = Builder.CreatePHI(Phi->getType(), 2, "scalar.recur.init");
   for (auto *BB : predecessors(LoopScalarPreHeader)) {
-    auto *Incoming = BB == LoopMiddleBlock ? Extract : ScalarInit;
+    auto *Incoming = BB == LoopMiddleBlock ? ExtractForScalar : ScalarInit;
     Start->addIncoming(Incoming, BB);
   }
 
@@ -4112,7 +4122,7 @@
     if (!LCSSAPhi)
       break;
     if (LCSSAPhi->getIncomingValue(0) == Phi) {
-      LCSSAPhi->addIncoming(Extract, LoopMiddleBlock);
+      LCSSAPhi->addIncoming(ExtractForPhiUsedOutsideLoop, LoopMiddleBlock);
       break;
     }
   }
Index: llvm/trunk/test/Transforms/LoopVectorize/AArch64/loop-vectorization-factors.ll
===================================================================
--- llvm/trunk/test/Transforms/LoopVectorize/AArch64/loop-vectorization-factors.ll
+++ llvm/trunk/test/Transforms/LoopVectorize/AArch64/loop-vectorization-factors.ll
@@ -234,15 +234,27 @@
   br i1 %exitcond, label %for.cond.cleanup, label %for.body
 }
 
-; CHECK-LABEL: @add_phifail2(
-; CHECK-NOT: load <16 x i8>, <16 x i8>*
-; CHECK-NOT: add nuw nsw <16 x i32>
-; CHECK-NOT: store <16 x i8>
 ; Function Attrs: nounwind
-; FIXME: Currently, if we vectorize this loop, we will generate incorrect code
-; if %len evenly divides VF. Vectorized loop code gen returns a_phi = p[len -1],
-; whereas it should be the previous value a_phi = p[len -2]
+; When we vectorize this loop, we generate correct code
+; even when %len exactly divides VF (since we extract from the second last index
+; and pass this to the for.cond.cleanup block). Vectorized loop returns 
+; the correct value a_phi = p[len -2]
 define i8 @add_phifail2(i8* noalias nocapture readonly %p, i8* noalias nocapture %q, i32 %len) #0 {
+; CHECK-LABEL: @add_phifail2(
+; CHECK: vector.body:
+; CHECK:   %wide.load = load <16 x i8>, <16 x i8>*
+; CHECK:   %[[L1:.+]] = zext <16 x i8> %wide.load to <16 x i32>
+; CHECK:   add nuw nsw <16 x i32>
+; CHECK:   store <16 x i8>
+; CHECK:   add i64 %index, 16
+; CHECK:   icmp eq i64 %index.next, %n.vec
+; CHECK: middle.block:
+; CHECK:   %vector.recur.extract = extractelement <16 x i32> %[[L1]], i32 15
+; CHECK:   %vector.recur.extract.for.phi = extractelement <16 x i32> %[[L1]], i32 14
+; CHECK: for.cond.cleanup:
+; CHECK:   %a_phi.lcssa = phi i32 [ %scalar.recur, %for.body ], [ %vector.recur.extract.for.phi, %middle.block ]
+; CHECK:   %ret = trunc i32 %a_phi.lcssa to i8
+; CHECK:   ret i8 %ret
 entry:
   br label %for.body
 
Index: llvm/trunk/test/Transforms/LoopVectorize/first-order-recurrence.ll
===================================================================
--- llvm/trunk/test/Transforms/LoopVectorize/first-order-recurrence.ll
+++ llvm/trunk/test/Transforms/LoopVectorize/first-order-recurrence.ll
@@ -1,6 +1,7 @@
 ; RUN: opt < %s -loop-vectorize -force-vector-width=4 -force-vector-interleave=1 -dce -instcombine -S | FileCheck %s
 ; RUN: opt < %s -loop-vectorize -force-vector-width=4 -force-vector-interleave=2 -dce -instcombine -S | FileCheck %s --check-prefix=UNROLL
 ; RUN: opt < %s -loop-vectorize -force-vector-width=4 -force-vector-interleave=2 -S | FileCheck %s --check-prefix=UNROLL-NO-IC
+; RUN: opt < %s -loop-vectorize -force-vector-width=1 -force-vector-interleave=2 -S | FileCheck %s --check-prefix=UNROLL-NO-VF
 
 target datalayout = "e-m:e-i64:64-i128:128-n32:64-S128"
 
@@ -350,11 +351,35 @@
   ret void
 }
 
-; FIXME: we can vectorize this first order recurrence, by generating two
-; extracts - one for the phi `val.phi` and other for the phi update `addx`.
-; val.phi at end of loop is 94 + x.
-; CHECK-LABEL: extract_second_last_iteration
-; CHECK-NOT: vector.body
+; We vectorize this first order recurrence, by generating two
+; extracts for the phi `val.phi` - one at the last index and 
+; another at the second last index. We need these 2 extracts because 
+; the first order recurrence phi is used outside the loop, so we require the phi
+; itself and not its update (addx).
+; UNROLL-NO-IC-LABEL: extract_second_last_iteration
+; UNROLL-NO-IC: vector.body
+; UNROLL-NO-IC:   %step.add = add <4 x i32> %vec.ind, <i32 4, i32 4, i32 4, i32 4>
+; UNROLL-NO-IC:   %[[L1:.+]] = add <4 x i32> %vec.ind, %broadcast.splat
+; UNROLL-NO-IC:   %[[L2:.+]] = add <4 x i32> %step.add, %broadcast.splat
+; UNROLL-NO-IC:   %index.next = add i32 %index, 8
+; UNROLL-NO-IC:   icmp eq i32 %index.next, 96
+; UNROLL-NO-IC: middle.block
+; UNROLL-NO-IC:   icmp eq i32 96, 96
+; UNROLL-NO-IC:   %vector.recur.extract = extractelement <4 x i32> %[[L2]], i32 3
+; UNROLL-NO-IC:   %vector.recur.extract.for.phi = extractelement <4 x i32> %[[L2]], i32 2
+; UNROLL-NO-IC: for.end
+; UNROLL-NO-IC:   %val.phi.lcssa = phi i32 [ %scalar.recur, %for.body ], [ %vector.recur.extract.for.phi, %middle.block ]
+; Check the case when unrolled but not vectorized.
+; UNROLL-NO-VF-LABEL: extract_second_last_iteration
+; UNROLL-NO-VF: vector.body:
+; UNROLL-NO-VF:   %induction = add i32 %index, 0
+; UNROLL-NO-VF:   %induction1 = add i32 %index, 1
+; UNROLL-NO-VF:   %[[L1:.+]] = add i32 %induction, %x
+; UNROLL-NO-VF:   %[[L2:.+]] = add i32 %induction1, %x
+; UNROLL-NO-VF:   %index.next = add i32 %index, 2
+; UNROLL-NO-VF:   icmp eq i32 %index.next, 96
+; UNROLL-NO-VF: for.end:
+; UNROLL-NO-VF:   %val.phi.lcssa = phi i32 [ %scalar.recur, %for.body ], [ %[[L1]], %middle.block ]
 define i32 @extract_second_last_iteration(i32* %cval, i32 %x)  {
 entry:
   br label %for.body