forked from OSchip/llvm-project
430 lines
18 KiB
LLVM
430 lines
18 KiB
LLVM
; RUN: opt -basicaa -loop-accesses -analyze < %s | FileCheck %s -check-prefix=LAA
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; RUN: opt -passes='require<aa>,require<scalar-evolution>,require<aa>,loop(print-access-info)' -aa-pipeline='basic-aa' -disable-output < %s 2>&1 | FileCheck %s --check-prefix=LAA
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; RUN: opt -loop-versioning -S < %s | FileCheck %s -check-prefix=LV
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target datalayout = "e-m:o-i64:64-f80:128-n8:16:32:64-S128"
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; For this loop:
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; unsigned index = 0;
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; for (int i = 0; i < n; i++) {
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; A[2 * index] = A[2 * index] + B[i];
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; index++;
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; }
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;
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; SCEV is unable to prove that A[2 * i] does not overflow.
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;
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; Analyzing the IR does not help us because the GEPs are not
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; affine AddRecExprs. However, we can turn them into AddRecExprs
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; using SCEV Predicates.
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;
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; Once we have an affine expression we need to add an additional NUSW
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; to check that the pointers don't wrap since the GEPs are not
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; inbound.
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; LAA-LABEL: f1
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; LAA: Memory dependences are safe{{$}}
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; LAA: SCEV assumptions:
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; LAA-NEXT: {0,+,2}<%for.body> Added Flags: <nusw>
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; LAA-NEXT: {%a,+,4}<%for.body> Added Flags: <nusw>
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; The expression for %mul_ext as analyzed by SCEV is
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; (zext i32 {0,+,2}<%for.body> to i64)
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; We have added the nusw flag to turn this expression into the SCEV expression:
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; i64 {0,+,2}<%for.body>
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; LAA: [PSE] %arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext:
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; LAA-NEXT: ((2 * (zext i32 {0,+,2}<%for.body> to i64)) + %a)
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; LAA-NEXT: --> {%a,+,4}<%for.body>
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; LV-LABEL: f1
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; LV-LABEL: for.body.lver.check
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; LV: [[BETrunc:%[^ ]*]] = trunc i64 [[BE:%[^ ]*]] to i32
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; LV-NEXT: [[OFMul:%[^ ]*]] = call { i32, i1 } @llvm.umul.with.overflow.i32(i32 2, i32 [[BETrunc]])
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; LV-NEXT: [[OFMulResult:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 0
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; LV-NEXT: [[OFMulOverflow:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 1
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; LV-NEXT: [[AddEnd:%[^ ]*]] = add i32 0, [[OFMulResult]]
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; LV-NEXT: [[SubEnd:%[^ ]*]] = sub i32 0, [[OFMulResult]]
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; LV-NEXT: [[CmpNeg:%[^ ]*]] = icmp ugt i32 [[SubEnd]], 0
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; LV-NEXT: [[CmpPos:%[^ ]*]] = icmp ult i32 [[AddEnd]], 0
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 false, i1 [[CmpNeg]], i1 [[CmpPos]]
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; LV-NEXT: [[BECheck:%[^ ]*]] = icmp ugt i64 [[BE]], 4294967295
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; LV-NEXT: [[CheckOr0:%[^ ]*]] = or i1 [[Cmp]], [[BECheck]]
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; LV-NEXT: [[PredCheck0:%[^ ]*]] = or i1 [[CheckOr0]], [[OFMulOverflow]]
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; LV-NEXT: [[Or0:%[^ ]*]] = or i1 false, [[PredCheck0]]
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; LV-NEXT: [[OFMul1:%[^ ]*]] = call { i64, i1 } @llvm.umul.with.overflow.i64(i64 4, i64 [[BE]])
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; LV-NEXT: [[OFMulResult1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 0
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; LV-NEXT: [[OFMulOverflow1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 1
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; LV-NEXT: [[AddEnd1:%[^ ]*]] = add i64 %a2, [[OFMulResult1]]
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; LV-NEXT: [[SubEnd1:%[^ ]*]] = sub i64 %a2, [[OFMulResult1]]
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; LV-NEXT: [[CmpNeg1:%[^ ]*]] = icmp ugt i64 [[SubEnd1]], %a2
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; LV-NEXT: [[CmpPos1:%[^ ]*]] = icmp ult i64 [[AddEnd1]], %a2
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 false, i1 [[CmpNeg1]], i1 [[CmpPos1]]
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; LV-NEXT: [[PredCheck1:%[^ ]*]] = or i1 [[Cmp]], [[OFMulOverflow1]]
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; LV: [[FinalCheck:%[^ ]*]] = or i1 [[Or0]], [[PredCheck1]]
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; LV: br i1 [[FinalCheck]], label %for.body.ph.lver.orig, label %for.body.ph
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define void @f1(i16* noalias %a,
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i16* noalias %b, i64 %N) {
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entry:
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br label %for.body
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for.body: ; preds = %for.body, %entry
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%ind = phi i64 [ 0, %entry ], [ %inc, %for.body ]
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%ind1 = phi i32 [ 0, %entry ], [ %inc1, %for.body ]
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%mul = mul i32 %ind1, 2
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%mul_ext = zext i32 %mul to i64
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%arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext
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%loadA = load i16, i16* %arrayidxA, align 2
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%arrayidxB = getelementptr i16, i16* %b, i64 %ind
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%loadB = load i16, i16* %arrayidxB, align 2
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%add = mul i16 %loadA, %loadB
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store i16 %add, i16* %arrayidxA, align 2
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%inc = add nuw nsw i64 %ind, 1
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%inc1 = add i32 %ind1, 1
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%exitcond = icmp eq i64 %inc, %N
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br i1 %exitcond, label %for.end, label %for.body
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for.end: ; preds = %for.body
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ret void
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}
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; For this loop:
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; unsigned index = n;
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; for (int i = 0; i < n; i++) {
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; A[2 * index] = A[2 * index] + B[i];
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; index--;
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; }
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;
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; the SCEV expression for 2 * index is not an AddRecExpr
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; (and implictly not affine). However, we are able to make assumptions
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; that will turn the expression into an affine one and continue the
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; analysis.
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;
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; Once we have an affine expression we need to add an additional NUSW
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; to check that the pointers don't wrap since the GEPs are not
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; inbounds.
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;
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; This loop has a negative stride for A, and the nusw flag is required in
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; order to properly extend the increment from i32 -4 to i64 -4.
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; LAA-LABEL: f2
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; LAA: Memory dependences are safe{{$}}
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; LAA: SCEV assumptions:
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; LAA-NEXT: {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> Added Flags: <nusw>
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; LAA-NEXT: {((2 * (zext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body> Added Flags: <nusw>
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; The expression for %mul_ext as analyzed by SCEV is
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; (zext i32 {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> to i64)
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; We have added the nusw flag to turn this expression into the following SCEV:
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; i64 {zext i32 (2 * (trunc i64 %N to i32)) to i64,+,-2}<%for.body>
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; LAA: [PSE] %arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext:
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; LAA-NEXT: ((2 * (zext i32 {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> to i64)) + %a)
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; LAA-NEXT: --> {((2 * (zext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body>
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; LV-LABEL: f2
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; LV-LABEL: for.body.lver.check
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; LV: [[OFMul:%[^ ]*]] = call { i32, i1 } @llvm.umul.with.overflow.i32(i32 2, i32 [[BETrunc:%[^ ]*]])
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; LV-NEXT: [[OFMulResult:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 0
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; LV-NEXT: [[OFMulOverflow:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 1
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; LV-NEXT: [[AddEnd:%[^ ]*]] = add i32 [[Start:%[^ ]*]], [[OFMulResult]]
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; LV-NEXT: [[SubEnd:%[^ ]*]] = sub i32 [[Start]], [[OFMulResult]]
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; LV-NEXT: [[CmpNeg:%[^ ]*]] = icmp ugt i32 [[SubEnd]], [[Start]]
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; LV-NEXT: [[CmpPos:%[^ ]*]] = icmp ult i32 [[AddEnd]], [[Start]]
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg]], i1 [[CmpPos]]
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; LV-NEXT: [[BECheck:%[^ ]*]] = icmp ugt i64 [[BE]], 4294967295
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; LV-NEXT: [[CheckOr0:%[^ ]*]] = or i1 [[Cmp]], [[BECheck]]
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; LV-NEXT: [[PredCheck0:%[^ ]*]] = or i1 [[CheckOr0]], [[OFMulOverflow]]
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; LV-NEXT: [[Or0:%[^ ]*]] = or i1 false, [[PredCheck0]]
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; LV: [[OFMul1:%[^ ]*]] = call { i64, i1 } @llvm.umul.with.overflow.i64(i64 4, i64 [[BE]])
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; LV-NEXT: [[OFMulResult1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 0
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; LV-NEXT: [[OFMulOverflow1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 1
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; LV-NEXT: [[AddEnd1:%[^ ]*]] = add i64 [[Start:%[^ ]*]], [[OFMulResult1]]
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; LV-NEXT: [[SubEnd1:%[^ ]*]] = sub i64 [[Start]], [[OFMulResult1]]
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; LV-NEXT: [[CmpNeg1:%[^ ]*]] = icmp ugt i64 [[SubEnd1]], [[Start]]
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; LV-NEXT: [[CmpPos1:%[^ ]*]] = icmp ult i64 [[AddEnd1]], [[Start]]
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg1]], i1 [[CmpPos1]]
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; LV-NEXT: [[PredCheck1:%[^ ]*]] = or i1 [[Cmp]], [[OFMulOverflow1]]
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; LV: [[FinalCheck:%[^ ]*]] = or i1 [[Or0]], [[PredCheck1]]
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; LV: br i1 [[FinalCheck]], label %for.body.ph.lver.orig, label %for.body.ph
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define void @f2(i16* noalias %a,
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i16* noalias %b, i64 %N) {
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entry:
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%TruncN = trunc i64 %N to i32
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br label %for.body
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for.body: ; preds = %for.body, %entry
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%ind = phi i64 [ 0, %entry ], [ %inc, %for.body ]
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%ind1 = phi i32 [ %TruncN, %entry ], [ %dec, %for.body ]
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%mul = mul i32 %ind1, 2
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%mul_ext = zext i32 %mul to i64
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%arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext
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%loadA = load i16, i16* %arrayidxA, align 2
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%arrayidxB = getelementptr i16, i16* %b, i64 %ind
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%loadB = load i16, i16* %arrayidxB, align 2
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%add = mul i16 %loadA, %loadB
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store i16 %add, i16* %arrayidxA, align 2
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%inc = add nuw nsw i64 %ind, 1
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%dec = sub i32 %ind1, 1
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%exitcond = icmp eq i64 %inc, %N
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br i1 %exitcond, label %for.end, label %for.body
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for.end: ; preds = %for.body
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ret void
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}
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; We replicate the tests above, but this time sign extend 2 * index instead
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; of zero extending it.
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; LAA-LABEL: f3
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; LAA: Memory dependences are safe{{$}}
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; LAA: SCEV assumptions:
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; LAA-NEXT: {0,+,2}<%for.body> Added Flags: <nssw>
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; LAA-NEXT: {%a,+,4}<%for.body> Added Flags: <nusw>
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; The expression for %mul_ext as analyzed by SCEV is
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; i64 (sext i32 {0,+,2}<%for.body> to i64)
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; We have added the nssw flag to turn this expression into the following SCEV:
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; i64 {0,+,2}<%for.body>
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; LAA: [PSE] %arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext:
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; LAA-NEXT: ((2 * (sext i32 {0,+,2}<%for.body> to i64)) + %a)
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; LAA-NEXT: --> {%a,+,4}<%for.body>
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; LV-LABEL: f3
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; LV-LABEL: for.body.lver.check
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; LV: [[OFMul:%[^ ]*]] = call { i32, i1 } @llvm.umul.with.overflow.i32(i32 2, i32 [[BETrunc:%[^ ]*]])
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; LV-NEXT: [[OFMulResult:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 0
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; LV-NEXT: [[OFMulOverflow:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 1
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; LV-NEXT: [[AddEnd:%[^ ]*]] = add i32 0, [[OFMulResult]]
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; LV-NEXT: [[SubEnd:%[^ ]*]] = sub i32 0, [[OFMulResult]]
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; LV-NEXT: [[CmpNeg:%[^ ]*]] = icmp sgt i32 [[SubEnd]], 0
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; LV-NEXT: [[CmpPos:%[^ ]*]] = icmp slt i32 [[AddEnd]], 0
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 false, i1 [[CmpNeg]], i1 [[CmpPos]]
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; LV-NEXT: [[BECheck:%[^ ]*]] = icmp ugt i64 [[BE]], 4294967295
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; LV-NEXT: [[CheckOr0:%[^ ]*]] = or i1 [[Cmp]], [[BECheck]]
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; LV-NEXT: [[PredCheck0:%[^ ]*]] = or i1 [[CheckOr0]], [[OFMulOverflow]]
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; LV-NEXT: [[Or0:%[^ ]*]] = or i1 false, [[PredCheck0]]
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; LV: [[OFMul1:%[^ ]*]] = call { i64, i1 } @llvm.umul.with.overflow.i64(i64 4, i64 [[BE:%[^ ]*]])
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; LV-NEXT: [[OFMulResult1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 0
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; LV-NEXT: [[OFMulOverflow1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 1
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; LV-NEXT: [[AddEnd1:%[^ ]*]] = add i64 %a2, [[OFMulResult1]]
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; LV-NEXT: [[SubEnd1:%[^ ]*]] = sub i64 %a2, [[OFMulResult1]]
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; LV-NEXT: [[CmpNeg1:%[^ ]*]] = icmp ugt i64 [[SubEnd1]], %a2
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; LV-NEXT: [[CmpPos1:%[^ ]*]] = icmp ult i64 [[AddEnd1]], %a2
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 false, i1 [[CmpNeg1]], i1 [[CmpPos1]]
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; LV-NEXT: [[PredCheck1:%[^ ]*]] = or i1 [[Cmp]], [[OFMulOverflow1]]
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; LV: [[FinalCheck:%[^ ]*]] = or i1 [[Or0]], [[PredCheck1]]
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; LV: br i1 [[FinalCheck]], label %for.body.ph.lver.orig, label %for.body.ph
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define void @f3(i16* noalias %a,
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i16* noalias %b, i64 %N) {
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entry:
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br label %for.body
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for.body: ; preds = %for.body, %entry
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%ind = phi i64 [ 0, %entry ], [ %inc, %for.body ]
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%ind1 = phi i32 [ 0, %entry ], [ %inc1, %for.body ]
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%mul = mul i32 %ind1, 2
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%mul_ext = sext i32 %mul to i64
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%arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext
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%loadA = load i16, i16* %arrayidxA, align 2
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%arrayidxB = getelementptr i16, i16* %b, i64 %ind
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%loadB = load i16, i16* %arrayidxB, align 2
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%add = mul i16 %loadA, %loadB
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store i16 %add, i16* %arrayidxA, align 2
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%inc = add nuw nsw i64 %ind, 1
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%inc1 = add i32 %ind1, 1
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%exitcond = icmp eq i64 %inc, %N
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br i1 %exitcond, label %for.end, label %for.body
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for.end: ; preds = %for.body
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ret void
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}
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; LAA-LABEL: f4
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; LAA: Memory dependences are safe{{$}}
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; LAA: SCEV assumptions:
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; LAA-NEXT: {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> Added Flags: <nssw>
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; LAA-NEXT: {((2 * (sext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body> Added Flags: <nusw>
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; The expression for %mul_ext as analyzed by SCEV is
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; i64 (sext i32 {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> to i64)
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; We have added the nssw flag to turn this expression into the following SCEV:
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; i64 {sext i32 (2 * (trunc i64 %N to i32)) to i64,+,-2}<%for.body>
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; LAA: [PSE] %arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext:
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; LAA-NEXT: ((2 * (sext i32 {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> to i64)) + %a)
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; LAA-NEXT: --> {((2 * (sext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body>
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; LV-LABEL: f4
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; LV-LABEL: for.body.lver.check
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; LV: [[OFMul:%[^ ]*]] = call { i32, i1 } @llvm.umul.with.overflow.i32(i32 2, i32 [[BETrunc:%[^ ]*]])
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; LV-NEXT: [[OFMulResult:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 0
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; LV-NEXT: [[OFMulOverflow:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 1
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; LV-NEXT: [[AddEnd:%[^ ]*]] = add i32 [[Start:%[^ ]*]], [[OFMulResult]]
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; LV-NEXT: [[SubEnd:%[^ ]*]] = sub i32 [[Start]], [[OFMulResult]]
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; LV-NEXT: [[CmpNeg:%[^ ]*]] = icmp sgt i32 [[SubEnd]], [[Start]]
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; LV-NEXT: [[CmpPos:%[^ ]*]] = icmp slt i32 [[AddEnd]], [[Start]]
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg]], i1 [[CmpPos]]
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; LV-NEXT: [[BECheck:%[^ ]*]] = icmp ugt i64 [[BE]], 4294967295
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; LV-NEXT: [[CheckOr0:%[^ ]*]] = or i1 [[Cmp]], [[BECheck]]
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; LV-NEXT: [[PredCheck0:%[^ ]*]] = or i1 [[CheckOr0]], [[OFMulOverflow]]
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; LV-NEXT: [[Or0:%[^ ]*]] = or i1 false, [[PredCheck0]]
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; LV: [[OFMul1:%[^ ]*]] = call { i64, i1 } @llvm.umul.with.overflow.i64(i64 4, i64 [[BE:%[^ ]*]])
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; LV-NEXT: [[OFMulResult1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 0
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; LV-NEXT: [[OFMulOverflow1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 1
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; LV-NEXT: [[AddEnd1:%[^ ]*]] = add i64 [[Start:%[^ ]*]], [[OFMulResult1]]
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; LV-NEXT: [[SubEnd1:%[^ ]*]] = sub i64 [[Start]], [[OFMulResult1]]
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; LV-NEXT: [[CmpNeg1:%[^ ]*]] = icmp ugt i64 [[SubEnd1]], [[Start]]
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; LV-NEXT: [[CmpPos1:%[^ ]*]] = icmp ult i64 [[AddEnd1]], [[Start]]
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; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg1]], i1 [[CmpPos1]]
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; LV-NEXT: [[PredCheck1:%[^ ]*]] = or i1 [[Cmp]], [[OFMulOverflow1]]
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; LV: [[FinalCheck:%[^ ]*]] = or i1 [[Or0]], [[PredCheck1]]
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; LV: br i1 [[FinalCheck]], label %for.body.ph.lver.orig, label %for.body.ph
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define void @f4(i16* noalias %a,
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i16* noalias %b, i64 %N) {
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entry:
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%TruncN = trunc i64 %N to i32
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br label %for.body
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for.body: ; preds = %for.body, %entry
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%ind = phi i64 [ 0, %entry ], [ %inc, %for.body ]
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%ind1 = phi i32 [ %TruncN, %entry ], [ %dec, %for.body ]
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|
|
%mul = mul i32 %ind1, 2
|
|
%mul_ext = sext i32 %mul to i64
|
|
|
|
%arrayidxA = getelementptr i16, i16* %a, i64 %mul_ext
|
|
%loadA = load i16, i16* %arrayidxA, align 2
|
|
|
|
%arrayidxB = getelementptr i16, i16* %b, i64 %ind
|
|
%loadB = load i16, i16* %arrayidxB, align 2
|
|
|
|
%add = mul i16 %loadA, %loadB
|
|
|
|
store i16 %add, i16* %arrayidxA, align 2
|
|
|
|
%inc = add nuw nsw i64 %ind, 1
|
|
%dec = sub i32 %ind1, 1
|
|
|
|
%exitcond = icmp eq i64 %inc, %N
|
|
br i1 %exitcond, label %for.end, label %for.body
|
|
|
|
for.end: ; preds = %for.body
|
|
ret void
|
|
}
|
|
|
|
; The following function is similar to the one above, but has the GEP
|
|
; to pointer %A inbounds. The index %mul doesn't have the nsw flag.
|
|
; This means that the SCEV expression for %mul can wrap and we need
|
|
; a SCEV predicate to continue analysis.
|
|
;
|
|
; We can still analyze this by adding the required no wrap SCEV predicates.
|
|
|
|
; LAA-LABEL: f5
|
|
; LAA: Memory dependences are safe{{$}}
|
|
; LAA: SCEV assumptions:
|
|
; LAA-NEXT: {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> Added Flags: <nssw>
|
|
; LAA-NEXT: {((2 * (sext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body> Added Flags: <nusw>
|
|
|
|
; LAA: [PSE] %arrayidxA = getelementptr inbounds i16, i16* %a, i32 %mul:
|
|
; LAA-NEXT: ((2 * (sext i32 {(2 * (trunc i64 %N to i32)),+,-2}<%for.body> to i64))<nsw> + %a)<nsw>
|
|
; LAA-NEXT: --> {((2 * (sext i32 (2 * (trunc i64 %N to i32)) to i64)) + %a),+,-4}<%for.body>
|
|
|
|
; LV-LABEL: f5
|
|
; LV-LABEL: for.body.lver.check
|
|
; LV: [[OFMul:%[^ ]*]] = call { i32, i1 } @llvm.umul.with.overflow.i32(i32 2, i32 [[BETrunc:%[^ ]*]])
|
|
; LV-NEXT: [[OFMulResult:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 0
|
|
; LV-NEXT: [[OFMulOverflow:%[^ ]*]] = extractvalue { i32, i1 } [[OFMul]], 1
|
|
; LV-NEXT: [[AddEnd:%[^ ]*]] = add i32 [[Start:%[^ ]*]], [[OFMulResult]]
|
|
; LV-NEXT: [[SubEnd:%[^ ]*]] = sub i32 [[Start]], [[OFMulResult]]
|
|
; LV-NEXT: [[CmpNeg:%[^ ]*]] = icmp sgt i32 [[SubEnd]], [[Start]]
|
|
; LV-NEXT: [[CmpPos:%[^ ]*]] = icmp slt i32 [[AddEnd]], [[Start]]
|
|
; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg]], i1 [[CmpPos]]
|
|
; LV-NEXT: [[BECheck:%[^ ]*]] = icmp ugt i64 [[BE]], 4294967295
|
|
; LV-NEXT: [[CheckOr0:%[^ ]*]] = or i1 [[Cmp]], [[BECheck]]
|
|
; LV-NEXT: [[PredCheck0:%[^ ]*]] = or i1 [[CheckOr0]], [[OFMulOverflow]]
|
|
|
|
; LV-NEXT: [[Or0:%[^ ]*]] = or i1 false, [[PredCheck0]]
|
|
|
|
; LV: [[OFMul1:%[^ ]*]] = call { i64, i1 } @llvm.umul.with.overflow.i64(i64 4, i64 [[BE:%[^ ]*]])
|
|
; LV-NEXT: [[OFMulResult1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 0
|
|
; LV-NEXT: [[OFMulOverflow1:%[^ ]*]] = extractvalue { i64, i1 } [[OFMul1]], 1
|
|
; LV-NEXT: [[AddEnd1:%[^ ]*]] = add i64 [[Start:%[^ ]*]], [[OFMulResult1]]
|
|
; LV-NEXT: [[SubEnd1:%[^ ]*]] = sub i64 [[Start]], [[OFMulResult1]]
|
|
; LV-NEXT: [[CmpNeg1:%[^ ]*]] = icmp ugt i64 [[SubEnd1]], [[Start]]
|
|
; LV-NEXT: [[CmpPos1:%[^ ]*]] = icmp ult i64 [[AddEnd1]], [[Start]]
|
|
; LV-NEXT: [[Cmp:%[^ ]*]] = select i1 true, i1 [[CmpNeg1]], i1 [[CmpPos1]]
|
|
; LV-NEXT: [[PredCheck1:%[^ ]*]] = or i1 [[Cmp]], [[OFMulOverflow1]]
|
|
|
|
; LV: [[FinalCheck:%[^ ]*]] = or i1 [[Or0]], [[PredCheck1]]
|
|
; LV: br i1 [[FinalCheck]], label %for.body.ph.lver.orig, label %for.body.ph
|
|
define void @f5(i16* noalias %a,
|
|
i16* noalias %b, i64 %N) {
|
|
entry:
|
|
%TruncN = trunc i64 %N to i32
|
|
br label %for.body
|
|
|
|
for.body: ; preds = %for.body, %entry
|
|
%ind = phi i64 [ 0, %entry ], [ %inc, %for.body ]
|
|
%ind1 = phi i32 [ %TruncN, %entry ], [ %dec, %for.body ]
|
|
|
|
%mul = mul i32 %ind1, 2
|
|
|
|
%arrayidxA = getelementptr inbounds i16, i16* %a, i32 %mul
|
|
%loadA = load i16, i16* %arrayidxA, align 2
|
|
|
|
%arrayidxB = getelementptr inbounds i16, i16* %b, i64 %ind
|
|
%loadB = load i16, i16* %arrayidxB, align 2
|
|
|
|
%add = mul i16 %loadA, %loadB
|
|
|
|
store i16 %add, i16* %arrayidxA, align 2
|
|
|
|
%inc = add nuw nsw i64 %ind, 1
|
|
%dec = sub i32 %ind1, 1
|
|
|
|
%exitcond = icmp eq i64 %inc, %N
|
|
br i1 %exitcond, label %for.end, label %for.body
|
|
|
|
for.end: ; preds = %for.body
|
|
ret void
|
|
}
|