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Summary: Binary formats often include various enumerations or bitsets, but using endian-specific types for accessing them is tricky because they currently only support integral types. This is particularly true for scoped enums (enum class), as these are not implicitly convertible to integral types, and so one has to perform two casts just to read the enum value. This fixes that support by adding first-class support for enumeration types to endian-specific types. The support for them was already almost working -- all I needed to do was overload getSwappedBytes for enumeration types (which casts the enum to its underlying type and performs the conversion there). I also add some convenience template aliases to simplify declaring endian-specific enums. Reviewers: Bigcheese, zturner Subscribers: kristina, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D59141 llvm-svn: 355812
213 lines
7.8 KiB
C++
213 lines
7.8 KiB
C++
//===- unittests/Support/EndianTest.cpp - Endian.h 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/Endian.h"
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#include "llvm/Support/DataTypes.h"
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#include "gtest/gtest.h"
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#include <cstdlib>
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#include <ctime>
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using namespace llvm;
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using namespace support;
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#undef max
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namespace {
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TEST(Endian, Read) {
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// These are 5 bytes so we can be sure at least one of the reads is unaligned.
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unsigned char bigval[] = {0x00, 0x01, 0x02, 0x03, 0x04};
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unsigned char littleval[] = {0x00, 0x04, 0x03, 0x02, 0x01};
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int32_t BigAsHost = 0x00010203;
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EXPECT_EQ(BigAsHost, (endian::read<int32_t, big, unaligned>(bigval)));
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int32_t LittleAsHost = 0x02030400;
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EXPECT_EQ(LittleAsHost,(endian::read<int32_t, little, unaligned>(littleval)));
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EXPECT_EQ((endian::read<int32_t, big, unaligned>(bigval + 1)),
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(endian::read<int32_t, little, unaligned>(littleval + 1)));
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}
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TEST(Endian, ReadBitAligned) {
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// Simple test to make sure we properly pull out the 0x0 word.
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unsigned char littleval[] = {0x3f, 0x00, 0x00, 0x00, 0xc0, 0xff, 0xff, 0xff};
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unsigned char bigval[] = {0x00, 0x00, 0x00, 0x3f, 0xff, 0xff, 0xff, 0xc0};
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EXPECT_EQ(
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(endian::readAtBitAlignment<int, little, unaligned>(&littleval[0], 6)),
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0x0);
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EXPECT_EQ((endian::readAtBitAlignment<int, big, unaligned>(&bigval[0], 6)),
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0x0);
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// Test to make sure that signed right shift of 0xf0000000 is masked
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// properly.
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unsigned char littleval2[] = {0x00, 0x00, 0x00, 0xf0, 0x00, 0x00, 0x00, 0x00};
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unsigned char bigval2[] = {0xf0, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
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EXPECT_EQ(
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(endian::readAtBitAlignment<int, little, unaligned>(&littleval2[0], 4)),
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0x0f000000);
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EXPECT_EQ((endian::readAtBitAlignment<int, big, unaligned>(&bigval2[0], 4)),
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0x0f000000);
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// Test to make sure left shift of start bit doesn't overflow.
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EXPECT_EQ(
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(endian::readAtBitAlignment<int, little, unaligned>(&littleval2[0], 1)),
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0x78000000);
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EXPECT_EQ((endian::readAtBitAlignment<int, big, unaligned>(&bigval2[0], 1)),
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0x78000000);
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// Test to make sure 64-bit int doesn't overflow.
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unsigned char littleval3[] = {0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xf0,
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0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
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unsigned char bigval3[] = {0xf0, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
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0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
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EXPECT_EQ((endian::readAtBitAlignment<int64_t, little, unaligned>(
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&littleval3[0], 4)),
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0x0f00000000000000);
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EXPECT_EQ(
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(endian::readAtBitAlignment<int64_t, big, unaligned>(&bigval3[0], 4)),
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0x0f00000000000000);
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}
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TEST(Endian, WriteBitAligned) {
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// This test ensures that signed right shift of 0xffffaa is masked
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// properly.
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unsigned char bigval[8] = {0x00};
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endian::writeAtBitAlignment<int32_t, big, unaligned>(bigval, (int)0xffffaaaa,
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4);
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EXPECT_EQ(bigval[0], 0xff);
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EXPECT_EQ(bigval[1], 0xfa);
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EXPECT_EQ(bigval[2], 0xaa);
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EXPECT_EQ(bigval[3], 0xa0);
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EXPECT_EQ(bigval[4], 0x00);
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EXPECT_EQ(bigval[5], 0x00);
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EXPECT_EQ(bigval[6], 0x00);
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EXPECT_EQ(bigval[7], 0x0f);
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unsigned char littleval[8] = {0x00};
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endian::writeAtBitAlignment<int32_t, little, unaligned>(littleval,
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(int)0xffffaaaa, 4);
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EXPECT_EQ(littleval[0], 0xa0);
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EXPECT_EQ(littleval[1], 0xaa);
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EXPECT_EQ(littleval[2], 0xfa);
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EXPECT_EQ(littleval[3], 0xff);
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EXPECT_EQ(littleval[4], 0x0f);
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EXPECT_EQ(littleval[5], 0x00);
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EXPECT_EQ(littleval[6], 0x00);
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EXPECT_EQ(littleval[7], 0x00);
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// This test makes sure 1<<31 doesn't overflow.
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// Test to make sure left shift of start bit doesn't overflow.
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unsigned char bigval2[8] = {0x00};
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endian::writeAtBitAlignment<int32_t, big, unaligned>(bigval2, (int)0xffffffff,
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1);
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EXPECT_EQ(bigval2[0], 0xff);
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EXPECT_EQ(bigval2[1], 0xff);
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EXPECT_EQ(bigval2[2], 0xff);
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EXPECT_EQ(bigval2[3], 0xfe);
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EXPECT_EQ(bigval2[4], 0x00);
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EXPECT_EQ(bigval2[5], 0x00);
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EXPECT_EQ(bigval2[6], 0x00);
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EXPECT_EQ(bigval2[7], 0x01);
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unsigned char littleval2[8] = {0x00};
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endian::writeAtBitAlignment<int32_t, little, unaligned>(littleval2,
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(int)0xffffffff, 1);
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EXPECT_EQ(littleval2[0], 0xfe);
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EXPECT_EQ(littleval2[1], 0xff);
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EXPECT_EQ(littleval2[2], 0xff);
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EXPECT_EQ(littleval2[3], 0xff);
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EXPECT_EQ(littleval2[4], 0x01);
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EXPECT_EQ(littleval2[5], 0x00);
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EXPECT_EQ(littleval2[6], 0x00);
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EXPECT_EQ(littleval2[7], 0x00);
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// Test to make sure 64-bit int doesn't overflow.
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unsigned char bigval64[16] = {0x00};
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endian::writeAtBitAlignment<int64_t, big, unaligned>(
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bigval64, (int64_t)0xffffffffffffffff, 1);
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EXPECT_EQ(bigval64[0], 0xff);
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EXPECT_EQ(bigval64[1], 0xff);
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EXPECT_EQ(bigval64[2], 0xff);
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EXPECT_EQ(bigval64[3], 0xff);
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EXPECT_EQ(bigval64[4], 0xff);
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EXPECT_EQ(bigval64[5], 0xff);
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EXPECT_EQ(bigval64[6], 0xff);
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EXPECT_EQ(bigval64[7], 0xfe);
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EXPECT_EQ(bigval64[8], 0x00);
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EXPECT_EQ(bigval64[9], 0x00);
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EXPECT_EQ(bigval64[10], 0x00);
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EXPECT_EQ(bigval64[11], 0x00);
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EXPECT_EQ(bigval64[12], 0x00);
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EXPECT_EQ(bigval64[13], 0x00);
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EXPECT_EQ(bigval64[14], 0x00);
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EXPECT_EQ(bigval64[15], 0x01);
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unsigned char littleval64[16] = {0x00};
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endian::writeAtBitAlignment<int64_t, little, unaligned>(
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littleval64, (int64_t)0xffffffffffffffff, 1);
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EXPECT_EQ(littleval64[0], 0xfe);
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EXPECT_EQ(littleval64[1], 0xff);
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EXPECT_EQ(littleval64[2], 0xff);
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EXPECT_EQ(littleval64[3], 0xff);
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EXPECT_EQ(littleval64[4], 0xff);
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EXPECT_EQ(littleval64[5], 0xff);
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EXPECT_EQ(littleval64[6], 0xff);
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EXPECT_EQ(littleval64[7], 0xff);
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EXPECT_EQ(littleval64[8], 0x01);
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EXPECT_EQ(littleval64[9], 0x00);
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EXPECT_EQ(littleval64[10], 0x00);
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EXPECT_EQ(littleval64[11], 0x00);
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EXPECT_EQ(littleval64[12], 0x00);
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EXPECT_EQ(littleval64[13], 0x00);
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EXPECT_EQ(littleval64[14], 0x00);
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EXPECT_EQ(littleval64[15], 0x00);
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}
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TEST(Endian, Write) {
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unsigned char data[5];
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endian::write<int32_t, big, unaligned>(data, -1362446643);
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EXPECT_EQ(data[0], 0xAE);
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EXPECT_EQ(data[1], 0xCA);
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EXPECT_EQ(data[2], 0xB6);
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EXPECT_EQ(data[3], 0xCD);
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endian::write<int32_t, big, unaligned>(data + 1, -1362446643);
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EXPECT_EQ(data[1], 0xAE);
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EXPECT_EQ(data[2], 0xCA);
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EXPECT_EQ(data[3], 0xB6);
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EXPECT_EQ(data[4], 0xCD);
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endian::write<int32_t, little, unaligned>(data, -1362446643);
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EXPECT_EQ(data[0], 0xCD);
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EXPECT_EQ(data[1], 0xB6);
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EXPECT_EQ(data[2], 0xCA);
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EXPECT_EQ(data[3], 0xAE);
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endian::write<int32_t, little, unaligned>(data + 1, -1362446643);
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EXPECT_EQ(data[1], 0xCD);
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EXPECT_EQ(data[2], 0xB6);
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EXPECT_EQ(data[3], 0xCA);
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EXPECT_EQ(data[4], 0xAE);
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}
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TEST(Endian, PackedEndianSpecificIntegral) {
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// These are 5 bytes so we can be sure at least one of the reads is unaligned.
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unsigned char big[] = {0x00, 0x01, 0x02, 0x03, 0x04};
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unsigned char little[] = {0x00, 0x04, 0x03, 0x02, 0x01};
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big32_t *big_val =
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reinterpret_cast<big32_t *>(big + 1);
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little32_t *little_val =
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reinterpret_cast<little32_t *>(little + 1);
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EXPECT_EQ(*big_val, *little_val);
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}
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TEST(Endian, PacketEndianSpecificIntegralAsEnum) {
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enum class Test : uint16_t { ONETWO = 0x0102, TWOONE = 0x0201 };
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unsigned char bytes[] = {0x01, 0x02};
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using LittleTest = little_t<Test>;
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using BigTest = big_t<Test>;
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EXPECT_EQ(Test::TWOONE, *reinterpret_cast<LittleTest *>(bytes));
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EXPECT_EQ(Test::ONETWO, *reinterpret_cast<BigTest *>(bytes));
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}
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} // end anon namespace
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