/** @file IA32-specific functions for unit-testing INTN and UINTN functions in SafeIntLib. Copyright (c) Microsoft Corporation.
Copyright (c) 2019 - 2020, Intel Corporation. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include extern "C" { #include #include } TEST(ConversionTestSuite, TestSafeInt32ToUintn) { RETURN_STATUS Status; INT32 Operand; UINTN Result; // // If Operand is non-negative, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeInt32ToUintn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((UINTN)0x5bababab, Result); // // Otherwise should result in an error status // Operand = (-1537977259); Status = SafeInt32ToUintn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeUint32ToIntn) { RETURN_STATUS Status; UINT32 Operand; INTN Result; // // If Operand is <= MAX_INTN, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeUint32ToIntn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x5bababab, Result); // // Otherwise should result in an error status // Operand = (0xabababab); Status = SafeUint32ToIntn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeIntnToInt32) { RETURN_STATUS Status; INTN Operand; INT32 Result; // // INTN is same as INT32 in IA32, so this is just a cast // Operand = 0x5bababab; Result = 0; Status = SafeIntnToInt32 (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x5bababab, Result); } TEST(ConversionTestSuite, TestSafeIntnToUint32) { RETURN_STATUS Status; INTN Operand; UINT32 Result; // // If Operand is non-negative, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeIntnToUint32 (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((UINT32)0x5bababab, Result); // // Otherwise should result in an error status // Operand = (-1537977259); Status = SafeIntnToUint32 (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeUintnToUint32) { RETURN_STATUS Status; UINTN Operand; UINT32 Result; // // UINTN is same as UINT32 in IA32, so this is just a cast // Operand = 0xabababab; Result = 0; Status = SafeUintnToUint32 (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0xabababab, Result); } TEST(ConversionTestSuite, TestSafeUintnToIntn) { RETURN_STATUS Status; UINTN Operand; INTN Result; // // If Operand is <= MAX_INTN, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeUintnToIntn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x5bababab, Result); // // Otherwise should result in an error status // Operand = (0xabababab); Status = SafeUintnToIntn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeUintnToInt64) { RETURN_STATUS Status; UINTN Operand; INT64 Result; // // UINTN is same as UINT32 in IA32, and UINT32 is a subset of // INT64, so this is just a cast // Operand = 0xabababab; Result = 0; Status = SafeUintnToInt64 (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0xabababab, Result); } TEST(ConversionTestSuite, TestSafeInt64ToIntn) { RETURN_STATUS Status; INT64 Operand; INTN Result; // // If Operand is between MIN_INTN and MAX_INTN2 inclusive, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeInt64ToIntn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x5bababab, Result); Operand = (-1537977259); Status = SafeInt64ToIntn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((-1537977259), Result); // // Otherwise should result in an error status // Operand = (0x5babababefefefef); Status = SafeInt64ToIntn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); Operand = (-6605562033422200815); Status = SafeInt64ToIntn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeInt64ToUintn) { RETURN_STATUS Status; INT64 Operand; UINTN Result; // // If Operand is between 0 and MAX_UINTN inclusive, then it's a cast // Operand = 0xabababab; Result = 0; Status = SafeInt64ToUintn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0xabababab, Result); // // Otherwise should result in an error status // Operand = (0x5babababefefefef); Status = SafeInt64ToUintn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); Operand = (-6605562033422200815); Status = SafeInt64ToUintn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeUint64ToIntn) { RETURN_STATUS Status; UINT64 Operand; INTN Result; // // If Operand is <= MAX_INTN, then it's a cast // Operand = 0x5bababab; Result = 0; Status = SafeUint64ToIntn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x5bababab, Result); // // Otherwise should result in an error status // Operand = (0xababababefefefef); Status = SafeUint64ToIntn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(ConversionTestSuite, TestSafeUint64ToUintn) { RETURN_STATUS Status; UINT64 Operand; UINTN Result; // // If Operand is <= MAX_UINTN, then it's a cast // Operand = 0xabababab; Result = 0; Status = SafeUint64ToUintn (Operand, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0xabababab, Result); // // Otherwise should result in an error status // Operand = (0xababababefefefef); Status = SafeUint64ToUintn (Operand, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(AdditionSubtractionTestSuite, TestSafeUintnAdd) { RETURN_STATUS Status; UINTN Augend; UINTN Addend; UINTN Result; // // If the result of addition doesn't overflow MAX_UINTN, then it's addition // Augend = 0x3a3a3a3a; Addend = 0x3a3a3a3a; Result = 0; Status = SafeUintnAdd (Augend, Addend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((UINTN)0x74747474, Result); // // Otherwise should result in an error status // Augend = 0xabababab; Addend = 0xbcbcbcbc; Status = SafeUintnAdd (Augend, Addend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(AdditionSubtractionTestSuite, TestSafeIntnAdd) { RETURN_STATUS Status; INTN Augend; INTN Addend; INTN Result; // // If the result of addition doesn't overflow MAX_INTN // and doesn't underflow MIN_INTN, then it's addition // Augend = 0x3a3a3a3a; Addend = 0x3a3a3a3a; Result = 0; Status = SafeIntnAdd (Augend, Addend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x74747474, Result); Augend = (-976894522); Addend = (-976894522); Status = SafeIntnAdd (Augend, Addend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((-1953789044), Result); // // Otherwise should result in an error status // Augend = 0x5a5a5a5a; Addend = 0x5a5a5a5a; Status = SafeIntnAdd (Augend, Addend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); Augend = (-1515870810); Addend = (-1515870810); Status = SafeIntnAdd (Augend, Addend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(AdditionSubtractionTestSuite, TestSafeUintnSub) { RETURN_STATUS Status; UINTN Minuend; UINTN Subtrahend; UINTN Result; // // If Minuend >= Subtrahend, then it's subtraction // Minuend = 0x5a5a5a5a; Subtrahend = 0x3b3b3b3b; Result = 0; Status = SafeUintnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((UINTN)0x1f1f1f1f, Result); // // Otherwise should result in an error status // Minuend = 0x5a5a5a5a; Subtrahend = 0x6d6d6d6d; Status = SafeUintnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(AdditionSubtractionTestSuite, TestSafeIntnSub) { RETURN_STATUS Status; INTN Minuend; INTN Subtrahend; INTN Result; // // If the result of subtractions doesn't overflow MAX_INTN or // underflow MIN_INTN, then it's subtraction // Minuend = 0x5a5a5a5a; Subtrahend = 0x3a3a3a3a; Result = 0; Status = SafeIntnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x20202020, Result); Minuend = 0x3a3a3a3a; Subtrahend = 0x5a5a5a5a; Status = SafeIntnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ ((-538976288), Result); // // Otherwise should result in an error status // Minuend = (-2054847098); Subtrahend = 2054847098; Status = SafeIntnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); Minuend = (2054847098); Subtrahend = (-2054847098); Status = SafeIntnSub (Minuend, Subtrahend, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(MultiplicationTestSuite, TestSafeUintnMult) { RETURN_STATUS Status; UINTN Multiplicand; UINTN Multiplier; UINTN Result; // // If the result of multiplication doesn't overflow MAX_UINTN, it will succeed // Multiplicand = 0xa122a; Multiplier = 0xd23; Result = 0; Status = SafeUintnMult (Multiplicand, Multiplier, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x844c9dbe, Result); // // Otherwise should result in an error status // Multiplicand = 0xa122a; Multiplier = 0xed23; Status = SafeUintnMult (Multiplicand, Multiplier, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); } TEST(MultiplicationTestSuite, TestSafeIntnMult) { RETURN_STATUS Status; INTN Multiplicand; INTN Multiplier; INTN Result; // // If the result of multiplication doesn't overflow MAX_INTN and doesn't // underflow MIN_UINTN, it will succeed // Multiplicand = 0x123456; Multiplier = 0x678; Result = 0; Status = SafeIntnMult (Multiplicand, Multiplier, &Result); ASSERT_EQ (Status, RETURN_SUCCESS); ASSERT_EQ (0x75c28c50, Result); // // Otherwise should result in an error status // Multiplicand = 0x123456; Multiplier = 0xabc; Status = SafeIntnMult (Multiplicand, Multiplier, &Result); ASSERT_EQ (RETURN_BUFFER_TOO_SMALL, Status); }