//===- llvm/unittests/ADT/BitTest.cpp - tests ---===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "llvm/ADT/bit.h" #include "gtest/gtest.h" #include #include using namespace llvm; namespace { TEST(BitTest, BitCast) { static const uint8_t kValueU8 = 0x80; EXPECT_TRUE(llvm::bit_cast(kValueU8) < 0); static const uint16_t kValueU16 = 0x8000; EXPECT_TRUE(llvm::bit_cast(kValueU16) < 0); static const float kValueF32 = 5632.34f; EXPECT_FLOAT_EQ(kValueF32, llvm::bit_cast(llvm::bit_cast(kValueF32))); static const double kValueF64 = 87987234.983498; EXPECT_DOUBLE_EQ(kValueF64, llvm::bit_cast(llvm::bit_cast(kValueF64))); } // In these first two tests all of the original_uintx values are truncated // except for 64. We could avoid this, but there's really no point. TEST(BitTest, ByteSwapUnsignedRoundTrip) { // The point of the bit twiddling of magic is to test with and without bits // in every byte. uint64_t value = 1; for (std::size_t i = 0; i <= sizeof(value); ++i) { uint8_t original_uint8 = static_cast(value); EXPECT_EQ(original_uint8, llvm::byteswap(llvm::byteswap(original_uint8))); uint16_t original_uint16 = static_cast(value); EXPECT_EQ(original_uint16, llvm::byteswap(llvm::byteswap(original_uint16))); uint32_t original_uint32 = static_cast(value); EXPECT_EQ(original_uint32, llvm::byteswap(llvm::byteswap(original_uint32))); uint64_t original_uint64 = static_cast(value); EXPECT_EQ(original_uint64, llvm::byteswap(llvm::byteswap(original_uint64))); value = (value << 8) | 0x55; // binary 0101 0101. } } TEST(BitTest, ByteSwapSignedRoundTrip) { // The point of the bit twiddling of magic is to test with and without bits // in every byte. uint64_t value = 1; for (std::size_t i = 0; i <= sizeof(value); ++i) { int8_t original_int8 = static_cast(value); EXPECT_EQ(original_int8, llvm::byteswap(llvm::byteswap(original_int8))); int16_t original_int16 = static_cast(value); EXPECT_EQ(original_int16, llvm::byteswap(llvm::byteswap(original_int16))); int32_t original_int32 = static_cast(value); EXPECT_EQ(original_int32, llvm::byteswap(llvm::byteswap(original_int32))); int64_t original_int64 = static_cast(value); EXPECT_EQ(original_int64, llvm::byteswap(llvm::byteswap(original_int64))); // Test other sign. value *= -1; original_int8 = static_cast(value); EXPECT_EQ(original_int8, llvm::byteswap(llvm::byteswap(original_int8))); original_int16 = static_cast(value); EXPECT_EQ(original_int16, llvm::byteswap(llvm::byteswap(original_int16))); original_int32 = static_cast(value); EXPECT_EQ(original_int32, llvm::byteswap(llvm::byteswap(original_int32))); original_int64 = static_cast(value); EXPECT_EQ(original_int64, llvm::byteswap(llvm::byteswap(original_int64))); // Return to normal sign and twiddle. value *= -1; value = (value << 8) | 0x55; // binary 0101 0101. } } TEST(BitTest, ByteSwap) { // Unsigned types. EXPECT_EQ(uint8_t(0x11), llvm::byteswap(uint8_t(0x11))); EXPECT_EQ(uint16_t(0x1122), llvm::byteswap(uint16_t(0x2211))); EXPECT_EQ(uint32_t(0x11223344), llvm::byteswap(uint32_t(0x44332211))); EXPECT_EQ(uint64_t(0x1122334455667788ULL), llvm::byteswap(uint64_t(0x8877665544332211ULL))); // Signed types. EXPECT_EQ(int8_t(0x11), llvm::byteswap(int8_t(0x11))); EXPECT_EQ(int16_t(0x1122), llvm::byteswap(int16_t(0x2211))); EXPECT_EQ(int32_t(0x11223344), llvm::byteswap(int32_t(0x44332211))); EXPECT_EQ(int64_t(0x1122334455667788LL), llvm::byteswap(int64_t(0x8877665544332211LL))); } TEST(BitTest, HasSingleBit) { EXPECT_FALSE(llvm::has_single_bit(0U)); EXPECT_FALSE(llvm::has_single_bit(0ULL)); EXPECT_FALSE(llvm::has_single_bit(~0U)); EXPECT_FALSE(llvm::has_single_bit(~0ULL)); EXPECT_TRUE(llvm::has_single_bit(1U)); EXPECT_TRUE(llvm::has_single_bit(1ULL)); static const int8_t kValueS8 = -128; EXPECT_TRUE(llvm::has_single_bit(static_cast(kValueS8))); static const int16_t kValueS16 = -32768; EXPECT_TRUE(llvm::has_single_bit(static_cast(kValueS16))); } TEST(BitTest, BitFloor) { EXPECT_EQ(0u, llvm::bit_floor(uint8_t(0))); EXPECT_EQ(0u, llvm::bit_floor(uint16_t(0))); EXPECT_EQ(0u, llvm::bit_floor(uint32_t(0))); EXPECT_EQ(0u, llvm::bit_floor(uint64_t(0))); EXPECT_EQ(1u, llvm::bit_floor(uint8_t(1))); EXPECT_EQ(1u, llvm::bit_floor(uint16_t(1))); EXPECT_EQ(1u, llvm::bit_floor(uint32_t(1))); EXPECT_EQ(1u, llvm::bit_floor(uint64_t(1))); EXPECT_EQ(2u, llvm::bit_floor(uint8_t(2))); EXPECT_EQ(2u, llvm::bit_floor(uint16_t(2))); EXPECT_EQ(2u, llvm::bit_floor(uint32_t(2))); EXPECT_EQ(2u, llvm::bit_floor(uint64_t(2))); EXPECT_EQ(2u, llvm::bit_floor(uint8_t(3))); EXPECT_EQ(2u, llvm::bit_floor(uint16_t(3))); EXPECT_EQ(2u, llvm::bit_floor(uint32_t(3))); EXPECT_EQ(2u, llvm::bit_floor(uint64_t(3))); EXPECT_EQ(4u, llvm::bit_floor(uint8_t(4))); EXPECT_EQ(4u, llvm::bit_floor(uint16_t(4))); EXPECT_EQ(4u, llvm::bit_floor(uint32_t(4))); EXPECT_EQ(4u, llvm::bit_floor(uint64_t(4))); EXPECT_EQ(0x40u, llvm::bit_floor(uint8_t(0x7f))); EXPECT_EQ(0x4000u, llvm::bit_floor(uint16_t(0x7fff))); EXPECT_EQ(0x40000000u, llvm::bit_floor(uint32_t(0x7fffffffu))); EXPECT_EQ(0x4000000000000000ull, llvm::bit_floor(uint64_t(0x7fffffffffffffffull))); EXPECT_EQ(0x80u, llvm::bit_floor(uint8_t(0x80))); EXPECT_EQ(0x8000u, llvm::bit_floor(uint16_t(0x8000))); EXPECT_EQ(0x80000000u, llvm::bit_floor(uint32_t(0x80000000u))); EXPECT_EQ(0x8000000000000000ull, llvm::bit_floor(uint64_t(0x8000000000000000ull))); EXPECT_EQ(0x80u, llvm::bit_floor(uint8_t(0xff))); EXPECT_EQ(0x8000u, llvm::bit_floor(uint16_t(0xffff))); EXPECT_EQ(0x80000000u, llvm::bit_floor(uint32_t(0xffffffffu))); EXPECT_EQ(0x8000000000000000ull, llvm::bit_floor(uint64_t(0xffffffffffffffffull))); } TEST(BitTest, BitCeil) { EXPECT_EQ(1u, llvm::bit_ceil(uint8_t(0))); EXPECT_EQ(1u, llvm::bit_ceil(uint16_t(0))); EXPECT_EQ(1u, llvm::bit_ceil(uint32_t(0))); EXPECT_EQ(1u, llvm::bit_ceil(uint64_t(0))); EXPECT_EQ(1u, llvm::bit_ceil(uint8_t(1))); EXPECT_EQ(1u, llvm::bit_ceil(uint16_t(1))); EXPECT_EQ(1u, llvm::bit_ceil(uint32_t(1))); EXPECT_EQ(1u, llvm::bit_ceil(uint64_t(1))); EXPECT_EQ(2u, llvm::bit_ceil(uint8_t(2))); EXPECT_EQ(2u, llvm::bit_ceil(uint16_t(2))); EXPECT_EQ(2u, llvm::bit_ceil(uint32_t(2))); EXPECT_EQ(2u, llvm::bit_ceil(uint64_t(2))); EXPECT_EQ(4u, llvm::bit_ceil(uint8_t(3))); EXPECT_EQ(4u, llvm::bit_ceil(uint16_t(3))); EXPECT_EQ(4u, llvm::bit_ceil(uint32_t(3))); EXPECT_EQ(4u, llvm::bit_ceil(uint64_t(3))); EXPECT_EQ(4u, llvm::bit_ceil(uint8_t(4))); EXPECT_EQ(4u, llvm::bit_ceil(uint16_t(4))); EXPECT_EQ(4u, llvm::bit_ceil(uint32_t(4))); EXPECT_EQ(4u, llvm::bit_ceil(uint64_t(4))); // The result is the largest representable value for each type. EXPECT_EQ(0x80u, llvm::bit_ceil(uint8_t(0x7f))); EXPECT_EQ(0x8000u, llvm::bit_ceil(uint16_t(0x7fff))); EXPECT_EQ(0x80000000u, llvm::bit_ceil(uint32_t(0x7fffffffu))); EXPECT_EQ(0x8000000000000000ull, llvm::bit_ceil(uint64_t(0x7fffffffffffffffull))); } TEST(BitTest, BitWidth) { EXPECT_EQ(0, llvm::bit_width(uint8_t(0))); EXPECT_EQ(0, llvm::bit_width(uint16_t(0))); EXPECT_EQ(0, llvm::bit_width(uint32_t(0))); EXPECT_EQ(0, llvm::bit_width(uint64_t(0))); EXPECT_EQ(1, llvm::bit_width(uint8_t(1))); EXPECT_EQ(1, llvm::bit_width(uint16_t(1))); EXPECT_EQ(1, llvm::bit_width(uint32_t(1))); EXPECT_EQ(1, llvm::bit_width(uint64_t(1))); EXPECT_EQ(2, llvm::bit_width(uint8_t(2))); EXPECT_EQ(2, llvm::bit_width(uint16_t(2))); EXPECT_EQ(2, llvm::bit_width(uint32_t(2))); EXPECT_EQ(2, llvm::bit_width(uint64_t(2))); EXPECT_EQ(2, llvm::bit_width(uint8_t(3))); EXPECT_EQ(2, llvm::bit_width(uint16_t(3))); EXPECT_EQ(2, llvm::bit_width(uint32_t(3))); EXPECT_EQ(2, llvm::bit_width(uint64_t(3))); EXPECT_EQ(3, llvm::bit_width(uint8_t(4))); EXPECT_EQ(3, llvm::bit_width(uint16_t(4))); EXPECT_EQ(3, llvm::bit_width(uint32_t(4))); EXPECT_EQ(3, llvm::bit_width(uint64_t(4))); EXPECT_EQ(7, llvm::bit_width(uint8_t(0x7f))); EXPECT_EQ(15, llvm::bit_width(uint16_t(0x7fff))); EXPECT_EQ(31, llvm::bit_width(uint32_t(0x7fffffffu))); EXPECT_EQ(63, llvm::bit_width(uint64_t(0x7fffffffffffffffull))); EXPECT_EQ(8, llvm::bit_width(uint8_t(0x80))); EXPECT_EQ(16, llvm::bit_width(uint16_t(0x8000))); EXPECT_EQ(32, llvm::bit_width(uint32_t(0x80000000u))); EXPECT_EQ(64, llvm::bit_width(uint64_t(0x8000000000000000ull))); EXPECT_EQ(8, llvm::bit_width(uint8_t(0xff))); EXPECT_EQ(16, llvm::bit_width(uint16_t(0xffff))); EXPECT_EQ(32, llvm::bit_width(uint32_t(0xffffffffu))); EXPECT_EQ(64, llvm::bit_width(uint64_t(0xffffffffffffffffull))); } TEST(BitTest, CountlZero) { uint8_t Z8 = 0; uint16_t Z16 = 0; uint32_t Z32 = 0; uint64_t Z64 = 0; EXPECT_EQ(8, llvm::countl_zero(Z8)); EXPECT_EQ(16, llvm::countl_zero(Z16)); EXPECT_EQ(32, llvm::countl_zero(Z32)); EXPECT_EQ(64, llvm::countl_zero(Z64)); uint8_t NZ8 = 42; uint16_t NZ16 = 42; uint32_t NZ32 = 42; uint64_t NZ64 = 42; EXPECT_EQ(2, llvm::countl_zero(NZ8)); EXPECT_EQ(10, llvm::countl_zero(NZ16)); EXPECT_EQ(26, llvm::countl_zero(NZ32)); EXPECT_EQ(58, llvm::countl_zero(NZ64)); EXPECT_EQ(8, llvm::countl_zero(0x00F000FFu)); EXPECT_EQ(8, llvm::countl_zero(0x00F12345u)); for (unsigned i = 0; i <= 30; ++i) { EXPECT_EQ(int(31 - i), llvm::countl_zero(1u << i)); } EXPECT_EQ(8, llvm::countl_zero(0x00F1234500F12345ULL)); EXPECT_EQ(1, llvm::countl_zero(1ULL << 62)); for (unsigned i = 0; i <= 62; ++i) { EXPECT_EQ(int(63 - i), llvm::countl_zero(1ULL << i)); } } TEST(BitTest, CountrZero) { uint8_t Z8 = 0; uint16_t Z16 = 0; uint32_t Z32 = 0; uint64_t Z64 = 0; EXPECT_EQ(8, llvm::countr_zero(Z8)); EXPECT_EQ(16, llvm::countr_zero(Z16)); EXPECT_EQ(32, llvm::countr_zero(Z32)); EXPECT_EQ(64, llvm::countr_zero(Z64)); uint8_t NZ8 = 42; uint16_t NZ16 = 42; uint32_t NZ32 = 42; uint64_t NZ64 = 42; EXPECT_EQ(1, llvm::countr_zero(NZ8)); EXPECT_EQ(1, llvm::countr_zero(NZ16)); EXPECT_EQ(1, llvm::countr_zero(NZ32)); EXPECT_EQ(1, llvm::countr_zero(NZ64)); } TEST(BitTest, CountlOne) { for (int i = 30; i >= 0; --i) { // Start with all ones and unset some bit. EXPECT_EQ(31 - i, llvm::countl_one(0xFFFFFFFF ^ (1 << i))); } for (int i = 62; i >= 0; --i) { // Start with all ones and unset some bit. EXPECT_EQ(63 - i, llvm::countl_one(0xFFFFFFFFFFFFFFFFULL ^ (1LL << i))); } for (int i = 30; i >= 0; --i) { // Start with all ones and unset some bit. EXPECT_EQ(31 - i, llvm::countl_one(0xFFFFFFFF ^ (1 << i))); } } TEST(BitTest, CountrOne) { uint8_t AllOnes8 = ~(uint8_t)0; uint16_t AllOnes16 = ~(uint16_t)0; uint32_t AllOnes32 = ~(uint32_t)0; uint64_t AllOnes64 = ~(uint64_t)0; EXPECT_EQ(8, llvm::countr_one(AllOnes8)); EXPECT_EQ(16, llvm::countr_one(AllOnes16)); EXPECT_EQ(32, llvm::countr_one(AllOnes32)); EXPECT_EQ(64, llvm::countr_one(AllOnes64)); uint8_t X8 = 6; uint16_t X16 = 6; uint32_t X32 = 6; uint64_t X64 = 6; EXPECT_EQ(0, llvm::countr_one(X8)); EXPECT_EQ(0, llvm::countr_one(X16)); EXPECT_EQ(0, llvm::countr_one(X32)); EXPECT_EQ(0, llvm::countr_one(X64)); uint8_t Y8 = 23; uint16_t Y16 = 23; uint32_t Y32 = 23; uint64_t Y64 = 23; EXPECT_EQ(3, llvm::countr_one(Y8)); EXPECT_EQ(3, llvm::countr_one(Y16)); EXPECT_EQ(3, llvm::countr_one(Y32)); EXPECT_EQ(3, llvm::countr_one(Y64)); } TEST(BitTest, PopCount) { EXPECT_EQ(0, llvm::popcount(0U)); EXPECT_EQ(0, llvm::popcount(0ULL)); EXPECT_EQ(32, llvm::popcount(~0U)); EXPECT_EQ(64, llvm::popcount(~0ULL)); for (int I = 0; I != 32; ++I) EXPECT_EQ(1, llvm::popcount(1U << I)); } TEST(BitTest, Rotl) { EXPECT_EQ(0x53U, llvm::rotl(0x53, 0)); EXPECT_EQ(0x4dU, llvm::rotl(0x53, 2)); EXPECT_EQ(0xa6U, llvm::rotl(0x53, 9)); EXPECT_EQ(0x9aU, llvm::rotl(0x53, -5)); EXPECT_EQ(0xabcdU, llvm::rotl(0xabcd, 0)); EXPECT_EQ(0xf36aU, llvm::rotl(0xabcd, 6)); EXPECT_EQ(0xaf36U, llvm::rotl(0xabcd, 18)); EXPECT_EQ(0xf36aU, llvm::rotl(0xabcd, -10)); EXPECT_EQ(0xdeadbeefU, llvm::rotl(0xdeadbeef, 0)); EXPECT_EQ(0x7ddfbd5bU, llvm::rotl(0xdeadbeef, 17)); EXPECT_EQ(0x5b7ddfbdU, llvm::rotl(0xdeadbeef, 41)); EXPECT_EQ(0xb6fbbf7aU, llvm::rotl(0xdeadbeef, -22)); EXPECT_EQ(0x12345678deadbeefULL, llvm::rotl(0x12345678deadbeefULL, 0)); EXPECT_EQ(0xf56df77891a2b3c6ULL, llvm::rotl(0x12345678deadbeefULL, 35)); EXPECT_EQ(0x8d159e37ab6fbbc4ULL, llvm::rotl(0x12345678deadbeefULL, 70)); EXPECT_EQ(0xb7dde2468acf1bd5ULL, llvm::rotl(0x12345678deadbeefULL, -19)); } TEST(BitTest, Rotr) { EXPECT_EQ(0x53U, llvm::rotr(0x53, 0)); EXPECT_EQ(0xd4U, llvm::rotr(0x53, 2)); EXPECT_EQ(0xa9U, llvm::rotr(0x53, 9)); EXPECT_EQ(0x6aU, llvm::rotr(0x53, -5)); EXPECT_EQ(0xabcdU, llvm::rotr(0xabcd, 0)); EXPECT_EQ(0x36afU, llvm::rotr(0xabcd, 6)); EXPECT_EQ(0x6af3U, llvm::rotr(0xabcd, 18)); EXPECT_EQ(0x36afU, llvm::rotr(0xabcd, -10)); EXPECT_EQ(0xdeadbeefU, llvm::rotr(0xdeadbeef, 0)); EXPECT_EQ(0xdf77ef56U, llvm::rotr(0xdeadbeef, 17)); EXPECT_EQ(0x77ef56dfU, llvm::rotr(0xdeadbeef, 41)); EXPECT_EQ(0xbbf7ab6fU, llvm::rotr(0xdeadbeef, -22)); EXPECT_EQ(0x12345678deadbeefULL, llvm::rotr(0x12345678deadbeefULL, 0)); EXPECT_EQ(0x1bd5b7dde2468acfULL, llvm::rotr(0x12345678deadbeefULL, 35)); EXPECT_EQ(0xbc48d159e37ab6fbULL, llvm::rotr(0x12345678deadbeefULL, 70)); EXPECT_EQ(0xb3c6f56df77891a2ULL, llvm::rotr(0x12345678deadbeefULL, -19)); } } // anonymous namespace