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af9e09671c
Summary: This is a follow up on https://reviews.llvm.org/D71473#inline-647262. There's a caveat here that `Align(1)` relies on the compiler understanding of `Log2_64` implementation to produce good code. One could use `Align()` as a replacement but I believe it is less clear that the alignment is one in that case. Reviewers: xbolva00, courbet, bollu Subscribers: arsenm, dylanmckay, sdardis, nemanjai, jvesely, nhaehnle, hiraditya, kbarton, jrtc27, atanasyan, jsji, Jim, kerbowa, cfe-commits, llvm-commits Tags: #clang, #llvm Differential Revision: https://reviews.llvm.org/D73099
396 lines
12 KiB
C++
396 lines
12 KiB
C++
//=== - llvm/unittest/Support/Alignment.cpp - Alignment utility tests -----===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Support/Alignment.h"
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#include "gtest/gtest.h"
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#include <vector>
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#ifdef _MSC_VER
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// Disable warnings about potential divide by 0.
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#pragma warning(push)
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#pragma warning(disable : 4723)
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#endif
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using namespace llvm;
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namespace {
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TEST(AlignmentTest, AlignOfConstant) {
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EXPECT_EQ(Align::Of<uint8_t>(), Align(alignof(uint8_t)));
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EXPECT_EQ(Align::Of<uint16_t>(), Align(alignof(uint16_t)));
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EXPECT_EQ(Align::Of<uint32_t>(), Align(alignof(uint32_t)));
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EXPECT_EQ(Align::Of<uint64_t>(), Align(alignof(uint64_t)));
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}
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TEST(AlignmentTest, AlignConstant) {
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EXPECT_EQ(Align::Constant<1>(), Align(1));
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EXPECT_EQ(Align::Constant<2>(), Align(2));
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EXPECT_EQ(Align::Constant<4>(), Align(4));
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EXPECT_EQ(Align::Constant<8>(), Align(8));
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EXPECT_EQ(Align::Constant<16>(), Align(16));
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EXPECT_EQ(Align::Constant<32>(), Align(32));
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EXPECT_EQ(Align::Constant<64>(), Align(64));
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}
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TEST(AlignmentTest, AlignConstexprConstant) {
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constexpr Align kConstantAlign = Align::Of<uint64_t>();
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EXPECT_EQ(Align(alignof(uint64_t)), kConstantAlign);
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}
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std::vector<uint64_t> getValidAlignments() {
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std::vector<uint64_t> Out;
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for (size_t Shift = 0; Shift < 64; ++Shift)
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Out.push_back(1ULL << Shift);
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return Out;
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}
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TEST(AlignmentTest, AlignDefaultCTor) {
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EXPECT_EQ(Align().value(), 1ULL);
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}
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TEST(AlignmentTest, MaybeAlignDefaultCTor) {
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EXPECT_FALSE(MaybeAlign().hasValue());
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}
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TEST(AlignmentTest, ValidCTors) {
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for (uint64_t Value : getValidAlignments()) {
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EXPECT_EQ(Align(Value).value(), Value);
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EXPECT_EQ((*MaybeAlign(Value)).value(), Value);
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}
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}
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TEST(AlignmentTest, CheckMaybeAlignHasValue) {
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EXPECT_TRUE(MaybeAlign(1));
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EXPECT_TRUE(MaybeAlign(1).hasValue());
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EXPECT_FALSE(MaybeAlign(0));
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EXPECT_FALSE(MaybeAlign(0).hasValue());
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EXPECT_FALSE(MaybeAlign());
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EXPECT_FALSE(MaybeAlign().hasValue());
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}
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TEST(AlignmentTest, Division) {
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for (uint64_t Value : getValidAlignments()) {
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if (Value > 1) {
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EXPECT_EQ(Align(Value) / 2, Value / 2);
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EXPECT_EQ(MaybeAlign(Value) / 2, Value / 2);
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}
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}
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EXPECT_EQ(MaybeAlign(0) / 2, MaybeAlign(0));
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}
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TEST(AlignmentTest, AlignTo) {
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struct {
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uint64_t alignment;
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uint64_t offset;
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uint64_t rounded;
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const void *forgedAddr() const {
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// A value of any integral or enumeration type can be converted to a
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// pointer type.
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return reinterpret_cast<const void *>(offset);
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}
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} kTests[] = {
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// MaybeAlign
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{0, 0, 0},
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{0, 1, 1},
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{0, 5, 5},
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// MaybeAlign / Align
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{1, 0, 0},
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{1, 1, 1},
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{1, 5, 5},
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{2, 0, 0},
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{2, 1, 2},
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{2, 2, 2},
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{2, 7, 8},
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{2, 16, 16},
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{4, 0, 0},
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{4, 1, 4},
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{4, 4, 4},
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{4, 6, 8},
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};
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for (const auto &T : kTests) {
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MaybeAlign A(T.alignment);
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// Test MaybeAlign
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EXPECT_EQ(alignTo(T.offset, A), T.rounded);
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// Test Align
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if (A) {
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EXPECT_EQ(alignTo(T.offset, A.getValue()), T.rounded);
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EXPECT_EQ(alignAddr(T.forgedAddr(), A.getValue()), T.rounded);
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}
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}
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}
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TEST(AlignmentTest, Log2) {
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for (uint64_t Value : getValidAlignments()) {
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EXPECT_EQ(Log2(Align(Value)), Log2_64(Value));
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EXPECT_EQ(Log2(MaybeAlign(Value)), Log2_64(Value));
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}
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}
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TEST(AlignmentTest, MinAlign) {
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struct {
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uint64_t A;
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uint64_t B;
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uint64_t MinAlign;
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} kTests[] = {
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// MaybeAlign
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{0, 0, 0},
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{0, 8, 8},
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{2, 0, 2},
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// MaybeAlign / Align
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{1, 2, 1},
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{8, 4, 4},
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};
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for (const auto &T : kTests) {
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EXPECT_EQ(commonAlignment(MaybeAlign(T.A), MaybeAlign(T.B)), T.MinAlign);
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EXPECT_EQ(MinAlign(T.A, T.B), T.MinAlign);
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if (T.A) {
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EXPECT_EQ(commonAlignment(Align(T.A), MaybeAlign(T.B)), T.MinAlign);
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}
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if (T.B) {
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EXPECT_EQ(commonAlignment(MaybeAlign(T.A), Align(T.B)), T.MinAlign);
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}
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if (T.A && T.B) {
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EXPECT_EQ(commonAlignment(Align(T.A), Align(T.B)), T.MinAlign);
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}
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}
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}
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TEST(AlignmentTest, Encode_Decode) {
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for (uint64_t Value : getValidAlignments()) {
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{
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Align Actual(Value);
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Align Expected = decodeMaybeAlign(encode(Actual)).getValue();
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EXPECT_EQ(Expected, Actual);
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}
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{
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MaybeAlign Actual(Value);
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MaybeAlign Expected = decodeMaybeAlign(encode(Actual));
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EXPECT_EQ(Expected, Actual);
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}
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}
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MaybeAlign Actual(0);
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MaybeAlign Expected = decodeMaybeAlign(encode(Actual));
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EXPECT_EQ(Expected, Actual);
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}
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TEST(AlignmentTest, isAligned_isAddrAligned) {
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struct {
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uint64_t alignment;
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uint64_t offset;
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bool isAligned;
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const void *forgedAddr() const {
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// A value of any integral or enumeration type can be converted to a
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// pointer type.
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return reinterpret_cast<const void *>(offset);
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}
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} kTests[] = {
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{1, 0, true}, {1, 1, true}, {1, 5, true}, {2, 0, true},
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{2, 1, false}, {2, 2, true}, {2, 7, false}, {2, 16, true},
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{4, 0, true}, {4, 1, false}, {4, 4, true}, {4, 6, false},
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};
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for (const auto &T : kTests) {
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MaybeAlign A(T.alignment);
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// Test MaybeAlign
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EXPECT_EQ(isAligned(A, T.offset), T.isAligned);
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// Test Align
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if (A) {
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EXPECT_EQ(isAligned(A.getValue(), T.offset), T.isAligned);
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EXPECT_EQ(isAddrAligned(A.getValue(), T.forgedAddr()), T.isAligned);
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}
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}
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}
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TEST(AlignmentTest, offsetToAlignment) {
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struct {
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uint64_t alignment;
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uint64_t offset;
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uint64_t alignedOffset;
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const void *forgedAddr() const {
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// A value of any integral or enumeration type can be converted to a
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// pointer type.
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return reinterpret_cast<const void *>(offset);
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}
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} kTests[] = {
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{1, 0, 0}, {1, 1, 0}, {1, 5, 0}, {2, 0, 0}, {2, 1, 1}, {2, 2, 0},
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{2, 7, 1}, {2, 16, 0}, {4, 0, 0}, {4, 1, 3}, {4, 4, 0}, {4, 6, 2},
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};
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for (const auto &T : kTests) {
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const Align A(T.alignment);
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EXPECT_EQ(offsetToAlignment(T.offset, A), T.alignedOffset);
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EXPECT_EQ(offsetToAlignedAddr(T.forgedAddr(), A), T.alignedOffset);
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}
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}
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TEST(AlignmentTest, AlignComparisons) {
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std::vector<uint64_t> ValidAlignments = getValidAlignments();
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std::sort(ValidAlignments.begin(), ValidAlignments.end());
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for (size_t I = 1; I < ValidAlignments.size(); ++I) {
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assert(I >= 1);
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const Align A(ValidAlignments[I - 1]);
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const Align B(ValidAlignments[I]);
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EXPECT_EQ(A, A);
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EXPECT_NE(A, B);
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EXPECT_LT(A, B);
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EXPECT_GT(B, A);
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EXPECT_LE(A, B);
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EXPECT_GE(B, A);
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EXPECT_LE(A, A);
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EXPECT_GE(A, A);
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EXPECT_EQ(A, A.value());
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EXPECT_NE(A, B.value());
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EXPECT_LT(A, B.value());
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EXPECT_GT(B, A.value());
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EXPECT_LE(A, B.value());
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EXPECT_GE(B, A.value());
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EXPECT_LE(A, A.value());
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EXPECT_GE(A, A.value());
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EXPECT_EQ(std::max(A, B), B);
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EXPECT_EQ(std::min(A, B), A);
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const MaybeAlign MA(ValidAlignments[I - 1]);
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const MaybeAlign MB(ValidAlignments[I]);
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EXPECT_EQ(MA, MA);
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EXPECT_NE(MA, MB);
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EXPECT_LT(MA, MB);
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EXPECT_GT(MB, MA);
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EXPECT_LE(MA, MB);
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EXPECT_GE(MB, MA);
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EXPECT_LE(MA, MA);
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EXPECT_GE(MA, MA);
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EXPECT_EQ(MA, MA ? (*MA).value() : 0);
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EXPECT_NE(MA, MB ? (*MB).value() : 0);
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EXPECT_LT(MA, MB ? (*MB).value() : 0);
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EXPECT_GT(MB, MA ? (*MA).value() : 0);
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EXPECT_LE(MA, MB ? (*MB).value() : 0);
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EXPECT_GE(MB, MA ? (*MA).value() : 0);
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EXPECT_LE(MA, MA ? (*MA).value() : 0);
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EXPECT_GE(MA, MA ? (*MA).value() : 0);
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EXPECT_EQ(std::max(A, B), B);
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EXPECT_EQ(std::min(A, B), A);
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}
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}
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TEST(AlignmentTest, Max) {
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// We introduce std::max here to test ADL.
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using std::max;
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// Uses llvm::max.
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EXPECT_EQ(max(MaybeAlign(), Align(2)), Align(2));
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EXPECT_EQ(max(Align(2), MaybeAlign()), Align(2));
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EXPECT_EQ(max(MaybeAlign(1), Align(2)), Align(2));
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EXPECT_EQ(max(Align(2), MaybeAlign(1)), Align(2));
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EXPECT_EQ(max(MaybeAlign(2), Align(2)), Align(2));
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EXPECT_EQ(max(Align(2), MaybeAlign(2)), Align(2));
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EXPECT_EQ(max(MaybeAlign(4), Align(2)), Align(4));
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EXPECT_EQ(max(Align(2), MaybeAlign(4)), Align(4));
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// Uses std::max.
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EXPECT_EQ(max(Align(2), Align(4)), Align(4));
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EXPECT_EQ(max(MaybeAlign(2), MaybeAlign(4)), MaybeAlign(4));
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EXPECT_EQ(max(MaybeAlign(), MaybeAlign()), MaybeAlign());
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}
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TEST(AlignmentTest, AssumeAligned) {
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EXPECT_EQ(assumeAligned(0), Align(1));
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EXPECT_EQ(assumeAligned(0), Align());
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EXPECT_EQ(assumeAligned(1), Align(1));
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EXPECT_EQ(assumeAligned(1), Align());
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}
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// Death tests reply on assert which is disabled in release mode.
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#ifndef NDEBUG
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// We use a subset of valid alignments for DEATH_TESTs as they are particularly
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// slow.
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std::vector<uint64_t> getValidAlignmentsForDeathTest() {
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return {1, 1ULL << 31, 1ULL << 63};
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}
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std::vector<uint64_t> getNonPowerOfTwo() { return {3, 10, 15}; }
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TEST(AlignmentDeathTest, Log2) {
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EXPECT_DEATH(Log2(MaybeAlign(0)), ".* should be defined");
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}
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TEST(AlignmentDeathTest, CantConvertUnsetMaybe) {
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EXPECT_DEATH((MaybeAlign(0).getValue()), ".*");
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}
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TEST(AlignmentDeathTest, Division) {
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EXPECT_DEATH(Align(1) / 2, "Can't halve byte alignment");
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EXPECT_DEATH(MaybeAlign(1) / 2, "Can't halve byte alignment");
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EXPECT_DEATH(Align(8) / 0, "Divisor must be positive and a power of 2");
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EXPECT_DEATH(Align(8) / 3, "Divisor must be positive and a power of 2");
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}
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TEST(AlignmentDeathTest, InvalidCTors) {
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EXPECT_DEATH((Align(0)), "Value must not be 0");
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for (uint64_t Value : getNonPowerOfTwo()) {
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EXPECT_DEATH((Align(Value)), "Alignment is not a power of 2");
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EXPECT_DEATH((MaybeAlign(Value)),
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"Alignment is neither 0 nor a power of 2");
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}
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}
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TEST(AlignmentDeathTest, ComparisonsWithZero) {
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for (uint64_t Value : getValidAlignmentsForDeathTest()) {
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EXPECT_DEATH((void)(Align(Value) == 0), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) != 0), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) >= 0), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) <= 0), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) > 0), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) < 0), ".* should be defined");
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}
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}
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TEST(AlignmentDeathTest, CompareMaybeAlignToZero) {
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for (uint64_t Value : getValidAlignmentsForDeathTest()) {
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// MaybeAlign is allowed to be == or != 0
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(void)(MaybeAlign(Value) == 0);
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(void)(MaybeAlign(Value) != 0);
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EXPECT_DEATH((void)(MaybeAlign(Value) >= 0), ".* should be defined");
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EXPECT_DEATH((void)(MaybeAlign(Value) <= 0), ".* should be defined");
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EXPECT_DEATH((void)(MaybeAlign(Value) > 0), ".* should be defined");
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EXPECT_DEATH((void)(MaybeAlign(Value) < 0), ".* should be defined");
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}
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}
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TEST(AlignmentDeathTest, CompareAlignToUndefMaybeAlign) {
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for (uint64_t Value : getValidAlignmentsForDeathTest()) {
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EXPECT_DEATH((void)(Align(Value) == MaybeAlign(0)), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) != MaybeAlign(0)), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) >= MaybeAlign(0)), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) <= MaybeAlign(0)), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) > MaybeAlign(0)), ".* should be defined");
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EXPECT_DEATH((void)(Align(Value) < MaybeAlign(0)), ".* should be defined");
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}
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}
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TEST(AlignmentDeathTest, AlignAddr) {
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const void *const unaligned_high_ptr =
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reinterpret_cast<const void *>(std::numeric_limits<uintptr_t>::max() - 1);
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EXPECT_DEATH(alignAddr(unaligned_high_ptr, Align(16)), "Overflow");
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}
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#endif // NDEBUG
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} // end anonymous namespace
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#ifdef _MSC_VER
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#pragma warning(pop)
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#endif
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