#include "buffer.hpp" #include "data_interface_mock.hpp" #include #include #include #include #include #include #include #include namespace bios_bmc_smm_error_logger { namespace { using ::testing::_; using ::testing::ElementsAreArray; using ::testing::InSequence; using ::testing::Return; class BufferTest : public ::testing::Test { protected: BufferTest() : dataInterfaceMock(std::make_unique()), dataInterfaceMockPtr(dataInterfaceMock.get()) { bufferImpl = std::make_unique(std::move(dataInterfaceMock)); testInitializationHeader.bmcInterfaceVersion = testBmcInterfaceVersion; testInitializationHeader.queueSize = testQueueSize; testInitializationHeader.ueRegionSize = testUeRegionSize; std::transform(testMagicNumber.begin(), testMagicNumber.end(), testInitializationHeader.magicNumber.begin(), [](uint32_t number) -> little_uint32_t { return boost::endian::native_to_little(number); }); } ~BufferTest() override = default; // CircularBufferHeader size is 0x30, ensure the test region is bigger static constexpr size_t testRegionSize = 0x200; static constexpr uint32_t testBmcInterfaceVersion = 123; static constexpr uint32_t testQueueSize = 0x200; static constexpr uint16_t testUeRegionSize = 0x50; static constexpr std::array testMagicNumber = { 0x12345678, 0x22345678, 0x32345678, 0x42345678}; static constexpr size_t bufferHeaderSize = sizeof(struct CircularBufferHeader); struct CircularBufferHeader testInitializationHeader {}; std::unique_ptr dataInterfaceMock; DataInterfaceMock* dataInterfaceMockPtr; std::unique_ptr bufferImpl; }; TEST_F(BufferTest, BufferInitializeEraseFail) { InSequence s; EXPECT_CALL(*dataInterfaceMockPtr, getMemoryRegionSize()) .WillOnce(Return(testRegionSize)); EXPECT_THROW( try { // Test too big of a proposed buffer compared to the memori size uint16_t bigQueueSize = 0x201; uint16_t bigUeRegionSize = 0x50; bufferImpl->initialize(testBmcInterfaceVersion, bigQueueSize, bigUeRegionSize, testMagicNumber); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[initialize] Proposed queue size '513' is bigger than the BMC's allocated MMIO region of '512'"); throw; }, std::runtime_error); EXPECT_NE(bufferImpl->getCachedBufferHeader(), testInitializationHeader); EXPECT_CALL(*dataInterfaceMockPtr, getMemoryRegionSize()) .WillOnce(Return(testRegionSize)); const std::vector emptyArray(testQueueSize, 0); // Return a smaller write than the intended testRegionSize to test the error EXPECT_CALL(*dataInterfaceMockPtr, write(0, ElementsAreArray(emptyArray))) .WillOnce(Return(testQueueSize - 1)); EXPECT_THROW( try { bufferImpl->initialize(testBmcInterfaceVersion, testQueueSize, testUeRegionSize, testMagicNumber); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[initialize] Only erased '511'"); throw; }, std::runtime_error); EXPECT_NE(bufferImpl->getCachedBufferHeader(), testInitializationHeader); EXPECT_CALL(*dataInterfaceMockPtr, getMemoryRegionSize()) .WillOnce(Return(testRegionSize)); EXPECT_CALL(*dataInterfaceMockPtr, write(0, ElementsAreArray(emptyArray))) .WillOnce(Return(testQueueSize)); // Return a smaller write than the intended initializationHeader to test the // error EXPECT_CALL(*dataInterfaceMockPtr, write(0, _)).WillOnce(Return(0)); EXPECT_THROW( try { bufferImpl->initialize(testBmcInterfaceVersion, testQueueSize, testUeRegionSize, testMagicNumber); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[initialize] Only wrote '0' bytes of the header"); throw; }, std::runtime_error); EXPECT_NE(bufferImpl->getCachedBufferHeader(), testInitializationHeader); } TEST_F(BufferTest, BufferInitializePass) { InSequence s; EXPECT_CALL(*dataInterfaceMockPtr, getMemoryRegionSize()) .WillOnce(Return(testRegionSize)); const std::vector emptyArray(testQueueSize, 0); EXPECT_CALL(*dataInterfaceMockPtr, write(0, ElementsAreArray(emptyArray))) .WillOnce(Return(testQueueSize)); uint8_t* testInitializationHeaderPtr = reinterpret_cast(&testInitializationHeader); EXPECT_CALL(*dataInterfaceMockPtr, write(0, ElementsAreArray(testInitializationHeaderPtr, bufferHeaderSize))) .WillOnce(Return(bufferHeaderSize)); EXPECT_NO_THROW(bufferImpl->initialize(testBmcInterfaceVersion, testQueueSize, testUeRegionSize, testMagicNumber)); EXPECT_EQ(bufferImpl->getCachedBufferHeader(), testInitializationHeader); } TEST_F(BufferTest, BufferHeaderReadFail) { std::vector testBytesRead{}; EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(testBytesRead)); EXPECT_THROW( try { bufferImpl->readBufferHeader(); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "Buffer header read only read '0', expected '48'"); throw; }, std::runtime_error); } TEST_F(BufferTest, BufferHeaderReadPass) { uint8_t* testInitializationHeaderPtr = reinterpret_cast(&testInitializationHeader); std::vector testInitializationHeaderVector( testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(testInitializationHeaderVector)); EXPECT_NO_THROW(bufferImpl->readBufferHeader()); EXPECT_EQ(bufferImpl->getCachedBufferHeader(), testInitializationHeader); } TEST_F(BufferTest, BufferUpdateReadPtrFail) { // Return write size that is not 2 which is sizeof(little_uint16_t) constexpr size_t wrongWriteSize = 1; EXPECT_CALL(*dataInterfaceMockPtr, write(_, _)) .WillOnce(Return(wrongWriteSize)); EXPECT_THROW( try { bufferImpl->updateReadPtr(0); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[updateReadPtr] Wrote '1' bytes, instead of expected '3'"); throw; }, std::runtime_error); } TEST_F(BufferTest, BufferUpdateReadPtrPass) { constexpr size_t expectedWriteSize = 3; constexpr uint8_t expectedBmcReadPtrOffset = 0x21; // Check that we truncate the highest 24bits const uint32_t testNewReadPtr = 0x99881234; const std::vector expectedReadPtr{0x34, 0x12, 0x88}; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, ElementsAreArray(expectedReadPtr))) .WillOnce(Return(expectedWriteSize)); EXPECT_NO_THROW(bufferImpl->updateReadPtr(testNewReadPtr)); auto cachedHeader = bufferImpl->getCachedBufferHeader(); EXPECT_EQ(boost::endian::little_to_native(cachedHeader.bmcReadPtr), 0x881234); } TEST_F(BufferTest, BufferUpdateBmcFlagsFail) { // Return write size that is not 4 which is sizeof(little_uint32_t) constexpr size_t wrongWriteSize = 1; EXPECT_CALL(*dataInterfaceMockPtr, write(_, _)) .WillOnce(Return(wrongWriteSize)); EXPECT_THROW( try { bufferImpl->updateBmcFlags(static_cast(BmcFlags::ready)); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[updateBmcFlags] Wrote '1' bytes, instead of expected '4'"); throw; }, std::runtime_error); } TEST_F(BufferTest, BufferUpdateBmcFlagsPass) { constexpr size_t expectedWriteSize = 4; constexpr uint8_t expectedBmcReadPtrOffset = 0x1d; const std::vector expectedNewBmcFlagsVector{0x04, 0x0, 0x0, 0x00}; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, ElementsAreArray(expectedNewBmcFlagsVector))) .WillOnce(Return(expectedWriteSize)); EXPECT_NO_THROW( bufferImpl->updateBmcFlags(static_cast(BmcFlags::ready))); auto cachedHeader = bufferImpl->getCachedBufferHeader(); EXPECT_EQ(boost::endian::little_to_native(cachedHeader.bmcFlags), static_cast(BmcFlags::ready)); } class BufferWraparoundReadTest : public BufferTest { protected: BufferWraparoundReadTest() { initializeFuncMock(); } void initializeFuncMock() { // Initialize the memory and the cachedBufferHeader InSequence s; EXPECT_CALL(*dataInterfaceMockPtr, getMemoryRegionSize()) .WillOnce(Return(testRegionSize)); const std::vector emptyArray(testQueueSize, 0); EXPECT_CALL(*dataInterfaceMockPtr, write(0, ElementsAreArray(emptyArray))) .WillOnce(Return(testQueueSize)); EXPECT_CALL(*dataInterfaceMockPtr, write(0, _)) .WillOnce(Return(bufferHeaderSize)); EXPECT_NO_THROW(bufferImpl->initialize(testBmcInterfaceVersion, testQueueSize, testUeRegionSize, testMagicNumber)); } static constexpr size_t expectedWriteSize = 3; static constexpr uint8_t expectedBmcReadPtrOffset = 0x21; static constexpr size_t expectedqueueOffset = 0x30 + testUeRegionSize; static constexpr size_t testMaxOffset = testQueueSize - testUeRegionSize - sizeof(struct CircularBufferHeader); uint8_t* testInitializationHeaderPtr = reinterpret_cast(&testInitializationHeader); }; TEST_F(BufferWraparoundReadTest, GetMaxOffsetTest) { EXPECT_EQ(bufferImpl->getMaxOffset(), testMaxOffset); } TEST_F(BufferWraparoundReadTest, ParamsTooBigFail) { InSequence s; size_t tooBigOffset = testMaxOffset + 1; EXPECT_THROW( try { bufferImpl->wraparoundRead(tooBigOffset, /* length */ 1); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[wraparoundRead] relativeOffset '385' was bigger than maxOffset '384'"); throw; }, std::runtime_error); size_t tooBigLength = testMaxOffset + 1; EXPECT_THROW( try { bufferImpl->wraparoundRead(/* relativeOffset */ 0, tooBigLength); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[wraparoundRead] length '385' was bigger " "than maxOffset '384'"); throw; }, std::runtime_error); } TEST_F(BufferWraparoundReadTest, NoWrapAroundReadFails) { InSequence s; size_t testLength = 0x10; size_t testOffset = 0x20; // Fail the first read std::vector shortTestBytesRead(testLength - 1); EXPECT_CALL(*dataInterfaceMockPtr, read(testOffset + expectedqueueOffset, testLength)) .WillOnce(Return(shortTestBytesRead)); EXPECT_THROW( try { bufferImpl->wraparoundRead(testOffset, testLength); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[wraparoundRead] Read '15' which was not the " "requested length of '16'"); throw; }, std::runtime_error); } TEST_F(BufferWraparoundReadTest, NoWrapAroundReadPass) { InSequence s; size_t testLength = 0x10; size_t testOffset = 0x20; // Successfully read all the requested length without a wrap around std::vector testBytesRead(testLength); EXPECT_CALL(*dataInterfaceMockPtr, read(testOffset + expectedqueueOffset, testLength)) .WillOnce(Return(testBytesRead)); // Call to updateReadPtr is triggered const std::vector expectedReadPtr{ static_cast(testOffset + testLength), 0x0, 0x0}; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, ElementsAreArray(expectedReadPtr))) .WillOnce(Return(expectedWriteSize)); EXPECT_THAT(bufferImpl->wraparoundRead(testOffset, testLength), ElementsAreArray(testBytesRead)); struct CircularBufferHeader cachedBufferHeader = bufferImpl->getCachedBufferHeader(); // The bmcReadPtr should have been updated EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), testOffset + testLength); } TEST_F(BufferWraparoundReadTest, WrapAroundReadFails) { InSequence s; size_t testBytesLeft = 3; size_t testLength = 0x10; size_t testOffset = testMaxOffset - (testLength - testBytesLeft); // Read until the end of the queue std::vector testBytesReadShort(testLength - testBytesLeft); EXPECT_CALL(*dataInterfaceMockPtr, read(testOffset + expectedqueueOffset, testLength - testBytesLeft)) .WillOnce(Return(testBytesReadShort)); // Read 1 byte short after wraparound std::vector testBytesLeftReadShort(testBytesLeft - 1); EXPECT_CALL(*dataInterfaceMockPtr, read(expectedqueueOffset, testBytesLeft)) .WillOnce(Return(testBytesLeftReadShort)); EXPECT_THROW( try { bufferImpl->wraparoundRead(testOffset, testLength); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[wraparoundRead] Buffer wrapped around but read '2' which was " "not the requested lenght of '3'"); throw; }, std::runtime_error); } TEST_F(BufferWraparoundReadTest, WrapAroundReadPasses) { InSequence s; size_t testBytesLeft = 3; size_t testLength = 0x10; size_t testOffset = testMaxOffset - (testLength - testBytesLeft); // Read to the end of the queue std::vector testBytesReadFirst{16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4}; EXPECT_CALL(*dataInterfaceMockPtr, read(testOffset + expectedqueueOffset, testLength - testBytesLeft)) .WillOnce(Return(testBytesReadFirst)); std::vector testBytesReadSecond{3, 2, 1}; EXPECT_CALL(*dataInterfaceMockPtr, read(expectedqueueOffset, testBytesLeft)) .WillOnce(Return(testBytesReadSecond)); // Call to updateReadPtr is triggered const std::vector expectedReadPtr{ static_cast(testBytesLeft), 0x0, 0x0}; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, ElementsAreArray(expectedReadPtr))) .WillOnce(Return(expectedWriteSize)); std::vector expectedBytes = {16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1}; EXPECT_THAT(bufferImpl->wraparoundRead(testOffset, testLength), ElementsAreArray(expectedBytes)); struct CircularBufferHeader cachedBufferHeader = bufferImpl->getCachedBufferHeader(); // The bmcReadPtr should have been updated to reflect the wraparound EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), testBytesLeft); } TEST_F(BufferWraparoundReadTest, WrapAroundCornerCasePass) { InSequence s; size_t testBytesLeft = 0; size_t testLength = 4; size_t testOffset = testMaxOffset - (testLength - testBytesLeft); // Read to the very end of the queue std::vector testBytes{4, 3, 2, 1}; EXPECT_CALL(*dataInterfaceMockPtr, read(testOffset + expectedqueueOffset, testLength)) .WillOnce(Return(testBytes)); // Call to updateReadPtr is triggered, since we read to the very end of the // buffer, update the readPtr up around to 0 const std::vector expectedReadPtr{0x0, 0x0, 0x0}; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, ElementsAreArray(expectedReadPtr))) .WillOnce(Return(expectedWriteSize)); EXPECT_THAT(bufferImpl->wraparoundRead(testOffset, testLength), ElementsAreArray(testBytes)); struct CircularBufferHeader cachedBufferHeader = bufferImpl->getCachedBufferHeader(); // The bmcReadPtr should have been updated to reflect the wraparound EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), 0); } class BufferEntryTest : public BufferWraparoundReadTest { protected: BufferEntryTest() { testEntryHeader.sequenceId = testSequenceId; testEntryHeader.entrySize = testEntrySize; testEntryHeader.checksum = testChecksum; testEntryHeader.rdeCommandType = testRdeCommandType; } ~BufferEntryTest() override = default; void wraparoundReadMock(const uint32_t relativeOffset, std::span expetedBytesOutput) { InSequence s; const uint32_t queueSizeToQueueEnd = testMaxOffset - relativeOffset; // This will wrap, split the read mocks in 2 if (expetedBytesOutput.size() > queueSizeToQueueEnd) { EXPECT_CALL(*dataInterfaceMockPtr, read(_, _)) .WillOnce(Return(std::vector( expetedBytesOutput.begin(), expetedBytesOutput.begin() + queueSizeToQueueEnd))); EXPECT_CALL(*dataInterfaceMockPtr, read(_, _)) .WillOnce(Return(std::vector( expetedBytesOutput.begin() + queueSizeToQueueEnd, expetedBytesOutput.end()))); } else { EXPECT_CALL(*dataInterfaceMockPtr, read(_, _)) .WillOnce(Return(std::vector( expetedBytesOutput.begin(), expetedBytesOutput.end()))); } EXPECT_CALL(*dataInterfaceMockPtr, write(_, _)) .WillOnce(Return(expectedWriteSize)); } static constexpr size_t entryHeaderSize = sizeof(struct QueueEntryHeader); static constexpr uint16_t testSequenceId = 0; static constexpr uint16_t testEntrySize = 0x20; static constexpr uint8_t testRdeCommandType = 0x01; // Calculated checksum for the header static constexpr uint8_t testChecksum = (testSequenceId ^ testEntrySize ^ testRdeCommandType); size_t testOffset = 0x0; struct QueueEntryHeader testEntryHeader {}; }; TEST_F(BufferEntryTest, ReadEntryHeaderPass) { uint8_t* testEntryHeaderPtr = reinterpret_cast(&testEntryHeader); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); wraparoundReadMock(testOffset, testEntryHeaderVector); EXPECT_EQ(bufferImpl->readEntryHeader(), testEntryHeader); // Check the bmcReadPtr struct CircularBufferHeader cachedBufferHeader = bufferImpl->getCachedBufferHeader(); EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), testOffset + testEntryHeaderVector.size()); } TEST_F(BufferEntryTest, ReadEntryChecksumFail) { InSequence s; std::vector testEntryVector(testEntrySize); // Offset the checksum by 1 testEntryHeader.checksum += 1; uint8_t* testEntryHeaderPtr = reinterpret_cast(&testEntryHeader); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); wraparoundReadMock(testOffset, testEntryHeaderVector); wraparoundReadMock(testOffset + entryHeaderSize, testEntryVector); EXPECT_THROW( try { bufferImpl->readEntry(); } catch (const std::runtime_error& e) { // Calculation: testChecksum (0x21) XOR (0x22) = 3 EXPECT_STREQ(e.what(), "[readEntry] Checksum was '3', expected '0'"); throw; }, std::runtime_error); } TEST_F(BufferEntryTest, ReadEntryPassWraparound) { InSequence s; // We expect this will bump checksum up by "testEntrySize" = 0xff ^ 0xff ... // (20 times) = 0 therefore leave the checksum as is std::vector testEntryVector(testEntrySize, 0xff); uint8_t* testEntryHeaderPtr = reinterpret_cast(&testEntryHeader); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); // Set testOffset so that we can test the wraparound here at the header and // update the readPtr testOffset = testMaxOffset - 1; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, _)) .WillOnce(Return(expectedWriteSize)); EXPECT_NO_THROW(bufferImpl->updateReadPtr(testOffset)); wraparoundReadMock(testOffset, testEntryHeaderVector); wraparoundReadMock(testOffset + entryHeaderSize, testEntryVector); EntryPair testedEntryPair; EXPECT_NO_THROW(testedEntryPair = bufferImpl->readEntry()); EXPECT_EQ(testedEntryPair.first, testEntryHeader); EXPECT_THAT(testedEntryPair.second, ElementsAreArray(testEntryVector)); struct CircularBufferHeader cachedBufferHeader = bufferImpl->getCachedBufferHeader(); // The bmcReadPtr should have been updated to reflect the wraparound EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), entryHeaderSize + testEntrySize - 1); // Set testOffset so that we can test the wraparound here as well on our // second read for the entry (by 1 byte) testOffset = testMaxOffset - entryHeaderSize - 1; EXPECT_CALL(*dataInterfaceMockPtr, write(expectedBmcReadPtrOffset, _)) .WillOnce(Return(expectedWriteSize)); EXPECT_NO_THROW(bufferImpl->updateReadPtr(testOffset)); wraparoundReadMock(testOffset, testEntryHeaderVector); wraparoundReadMock(testOffset + entryHeaderSize, testEntryVector); EXPECT_NO_THROW(testedEntryPair = bufferImpl->readEntry()); EXPECT_EQ(testedEntryPair.first, testEntryHeader); EXPECT_THAT(testedEntryPair.second, ElementsAreArray(testEntryVector)); cachedBufferHeader = bufferImpl->getCachedBufferHeader(); // The bmcReadPtr should have been updated to reflect the wraparound EXPECT_EQ(boost::endian::little_to_native(cachedBufferHeader.bmcReadPtr), testEntrySize - 1); } class BufferReadErrorLogsTest : public BufferEntryTest { protected: BufferReadErrorLogsTest() = default; uint8_t* testEntryHeaderPtr = reinterpret_cast(&testEntryHeader); size_t entryAndHeaderSize = entryHeaderSize + testEntrySize; }; TEST_F(BufferReadErrorLogsTest, PtrsTooBigFail) { InSequence s; // Set the biosWritePtr too big testInitializationHeader.biosWritePtr = boost::endian::native_to_little((testMaxOffset + 1)); initializeFuncMock(); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); EXPECT_THROW( try { bufferImpl->readErrorLogs(); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[readErrorLogs] currentBiosWritePtr was '385' " "which was bigger than maxOffset '384'"); throw; }, std::runtime_error); // Reset the biosWritePtr and set the bmcReadPtr too big testInitializationHeader.biosWritePtr = 0; initializeFuncMock(); testInitializationHeader.bmcReadPtr = boost::endian::native_to_little((testMaxOffset + 1)); initializeFuncMock(); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); EXPECT_THROW( try { bufferImpl->readErrorLogs(); } catch (const std::runtime_error& e) { EXPECT_STREQ(e.what(), "[readErrorLogs] currentReadPtr was '385' " "which was bigger than maxOffset '384'"); throw; }, std::runtime_error); } TEST_F(BufferReadErrorLogsTest, IdenticalPtrsPass) { EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); EXPECT_NO_THROW(bufferImpl->readErrorLogs()); } TEST_F(BufferReadErrorLogsTest, NoWraparoundPass) { InSequence s; // Set the biosWritePtr to 1 entryHeader + entry size testInitializationHeader.biosWritePtr = boost::endian::native_to_little((entryAndHeaderSize)); initializeFuncMock(); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); std::vector testEntryVector(testEntrySize); wraparoundReadMock(/*relativeOffset=*/0, testEntryHeaderVector); wraparoundReadMock(/*relativeOffset=*/0 + entryHeaderSize, testEntryVector); std::vector entryPairs; EXPECT_NO_THROW(entryPairs = bufferImpl->readErrorLogs()); // Check that we only read one entryPair and that the content is correct EXPECT_EQ(entryPairs.size(), 1U); EXPECT_EQ(entryPairs[0].first, testEntryHeader); EXPECT_THAT(entryPairs[0].second, ElementsAreArray(testEntryVector)); } TEST_F(BufferReadErrorLogsTest, WraparoundMultiplEntryPass) { InSequence s; // Set the bmcReadPtr to 1 entryHeader + entry size from the "end" exactly uint32_t entryAndHeaderSizeAwayFromEnd = testMaxOffset - entryAndHeaderSize; testInitializationHeader.bmcReadPtr = boost::endian::native_to_little(entryAndHeaderSizeAwayFromEnd); // Set the biosWritePtr to 1 entryHeader + entry size from the "beginning" testInitializationHeader.biosWritePtr = entryAndHeaderSize; initializeFuncMock(); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); std::vector testEntryVector(testEntrySize); wraparoundReadMock(/*relativeOffset=*/entryAndHeaderSizeAwayFromEnd, testEntryHeaderVector); wraparoundReadMock(/*relativeOffset=*/entryAndHeaderSizeAwayFromEnd + entryHeaderSize, testEntryVector); wraparoundReadMock(/*relativeOffset=*/0 + entryAndHeaderSize, testEntryHeaderVector); wraparoundReadMock(/*relativeOffset=*/0 + entryAndHeaderSize + entryHeaderSize, testEntryVector); std::vector entryPairs; EXPECT_NO_THROW(entryPairs = bufferImpl->readErrorLogs()); // Check that we only read one entryPair and that the content is correct EXPECT_EQ(entryPairs.size(), 2); EXPECT_EQ(entryPairs[0].first, testEntryHeader); EXPECT_EQ(entryPairs[1].first, testEntryHeader); EXPECT_THAT(entryPairs[0].second, ElementsAreArray(testEntryVector)); EXPECT_THAT(entryPairs[1].second, ElementsAreArray(testEntryVector)); } TEST_F(BufferReadErrorLogsTest, WraparoundMismatchingPtrsFail) { InSequence s; testInitializationHeader.bmcReadPtr = boost::endian::native_to_little(0); // Make the biosWritePtr intentially 1 smaller than expected testInitializationHeader.biosWritePtr = boost::endian::native_to_little(entryAndHeaderSize - 1); initializeFuncMock(); EXPECT_CALL(*dataInterfaceMockPtr, read(0, bufferHeaderSize)) .WillOnce(Return(std::vector(testInitializationHeaderPtr, testInitializationHeaderPtr + bufferHeaderSize))); std::vector testEntryHeaderVector( testEntryHeaderPtr, testEntryHeaderPtr + entryHeaderSize); std::vector testEntryVector(testEntrySize); wraparoundReadMock(/*relativeOffset=*/0, testEntryHeaderVector); wraparoundReadMock(/*relativeOffset=*/0 + entryHeaderSize, testEntryVector); EXPECT_THROW( try { bufferImpl->readErrorLogs(); } catch (const std::runtime_error& e) { EXPECT_STREQ( e.what(), "[readErrorLogs] biosWritePtr '37' and bmcReaddPtr '38' " "are not identical after reading through all the logs"); throw; }, std::runtime_error); } } // namespace } // namespace bios_bmc_smm_error_logger