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//===- llvm/unittest/ADT/APSIntTest.cpp - APSInt unit tests ---------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/APSInt.h"
#include "gtest/gtest.h"
using namespace llvm;
namespace {
TEST(APSIntTest, MoveTest) {
APSInt A(32, true);
EXPECT_TRUE(A.isUnsigned());
APSInt B(128, false);
A = B;
EXPECT_FALSE(A.isUnsigned());
APSInt C(B);
EXPECT_FALSE(C.isUnsigned());
APInt Wide(256, 0);
const uint64_t *Bits = Wide.getRawData();
APSInt D(std::move(Wide));
EXPECT_TRUE(D.isUnsigned());
EXPECT_EQ(Bits, D.getRawData()); // Verify that "Wide" was really moved.
A = APSInt(64, true);
EXPECT_TRUE(A.isUnsigned());
Wide = APInt(128, 1);
Bits = Wide.getRawData();
A = std::move(Wide);
EXPECT_TRUE(A.isUnsigned());
EXPECT_EQ(Bits, A.getRawData()); // Verify that "Wide" was really moved.
}
TEST(APSIntTest, get) {
EXPECT_TRUE(APSInt::get(7).isSigned());
EXPECT_EQ(64u, APSInt::get(7).getBitWidth());
EXPECT_EQ(7u, APSInt::get(7).getZExtValue());
EXPECT_EQ(7, APSInt::get(7).getSExtValue());
EXPECT_TRUE(APSInt::get(-7).isSigned());
EXPECT_EQ(64u, APSInt::get(-7).getBitWidth());
EXPECT_EQ(-7, APSInt::get(-7).getSExtValue());
EXPECT_EQ(UINT64_C(0) - 7, APSInt::get(-7).getZExtValue());
}
TEST(APSIntTest, getUnsigned) {
EXPECT_TRUE(APSInt::getUnsigned(7).isUnsigned());
EXPECT_EQ(64u, APSInt::getUnsigned(7).getBitWidth());
EXPECT_EQ(7u, APSInt::getUnsigned(7).getZExtValue());
EXPECT_EQ(7, APSInt::getUnsigned(7).getSExtValue());
EXPECT_TRUE(APSInt::getUnsigned(-7).isUnsigned());
EXPECT_EQ(64u, APSInt::getUnsigned(-7).getBitWidth());
EXPECT_EQ(-7, APSInt::getUnsigned(-7).getSExtValue());
EXPECT_EQ(UINT64_C(0) - 7, APSInt::getUnsigned(-7).getZExtValue());
}
TEST(APSIntTest, getExtValue) {
EXPECT_TRUE(APSInt(APInt(3, 7), true).isUnsigned());
EXPECT_TRUE(APSInt(APInt(3, 7), false).isSigned());
EXPECT_TRUE(APSInt(APInt(4, 7), true).isUnsigned());
EXPECT_TRUE(APSInt(APInt(4, 7), false).isSigned());
EXPECT_TRUE(APSInt(APInt(4, -7), true).isUnsigned());
EXPECT_TRUE(APSInt(APInt(4, -7), false).isSigned());
EXPECT_EQ(7, APSInt(APInt(3, 7), true).getExtValue());
EXPECT_EQ(-1, APSInt(APInt(3, 7), false).getExtValue());
EXPECT_EQ(7, APSInt(APInt(4, 7), true).getExtValue());
EXPECT_EQ(7, APSInt(APInt(4, 7), false).getExtValue());
EXPECT_EQ(9, APSInt(APInt(4, -7), true).getExtValue());
EXPECT_EQ(-7, APSInt(APInt(4, -7), false).getExtValue());
}
TEST(APSIntTest, compareValues) {
auto U = [](uint64_t V) { return APSInt::getUnsigned(V); };
auto S = [](int64_t V) { return APSInt::get(V); };
// Bit-width matches and is-signed.
EXPECT_TRUE(APSInt::compareValues(S(7), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8), S(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(7), S(7)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8), S(-7)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-7)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-8)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-8), S(-7)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-7)) == 0);
// Bit-width matches and not is-signed.
EXPECT_TRUE(APSInt::compareValues(U(7), U(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8), U(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7), U(7)) == 0);
// Bit-width matches and mixed signs.
EXPECT_TRUE(APSInt::compareValues(U(7), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8), S(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7), S(7)) == 0);
EXPECT_TRUE(APSInt::compareValues(U(8), S(-7)) > 0);
// Bit-width mismatch and is-signed.
EXPECT_TRUE(APSInt::compareValues(S(7).trunc(32), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8).trunc(32), S(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(7).trunc(32), S(7)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7).trunc(32), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8).trunc(32), S(-7)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-7).trunc(32), S(-7)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7).trunc(32), S(-8)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-8).trunc(32), S(-7)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(-7).trunc(32), S(-7)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(7), S(8).trunc(32)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8), S(7).trunc(32)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(7), S(7).trunc(32)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(8).trunc(32)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(8), S(-7).trunc(32)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-7).trunc(32)) == 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-8).trunc(32)) > 0);
EXPECT_TRUE(APSInt::compareValues(S(-8), S(-7).trunc(32)) < 0);
EXPECT_TRUE(APSInt::compareValues(S(-7), S(-7).trunc(32)) == 0);
// Bit-width mismatch and not is-signed.
EXPECT_TRUE(APSInt::compareValues(U(7), U(8).trunc(32)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8), U(7).trunc(32)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7), U(7).trunc(32)) == 0);
EXPECT_TRUE(APSInt::compareValues(U(7).trunc(32), U(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8).trunc(32), U(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7).trunc(32), U(7)) == 0);
// Bit-width mismatch and mixed signs.
EXPECT_TRUE(APSInt::compareValues(U(7).trunc(32), S(8)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8).trunc(32), S(7)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7).trunc(32), S(7)) == 0);
EXPECT_TRUE(APSInt::compareValues(U(8).trunc(32), S(-7)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7), S(8).trunc(32)) < 0);
EXPECT_TRUE(APSInt::compareValues(U(8), S(7).trunc(32)) > 0);
EXPECT_TRUE(APSInt::compareValues(U(7), S(7).trunc(32)) == 0);
EXPECT_TRUE(APSInt::compareValues(U(8), S(-7).trunc(32)) > 0);
}
TEST(APSIntTest, FromString) {
EXPECT_EQ(APSInt("1").getExtValue(), 1);
EXPECT_EQ(APSInt("-1").getExtValue(), -1);
EXPECT_EQ(APSInt("0").getExtValue(), 0);
EXPECT_EQ(APSInt("56789").getExtValue(), 56789);
EXPECT_EQ(APSInt("-1234").getExtValue(), -1234);
}
#if defined(GTEST_HAS_DEATH_TEST) && !defined(NDEBUG)
TEST(APSIntTest, StringDeath) {
EXPECT_DEATH(APSInt(""), "Invalid string length");
EXPECT_DEATH(APSInt("1a"), "Invalid character in digit string");
}
#endif
} // end anonymous namespace
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