#include #include #include #include #include #include #include #include using testing::ElementsAreArray; constexpr auto hdrSize = sizeof(pldm_msg_hdr); TEST(PackPLDMMessage, BadPathTest) { struct pldm_header_info hdr; struct pldm_header_info* hdr_ptr = NULL; pldm_msg_hdr msg{}; // PLDM header information pointer is NULL auto rc = pack_pldm_header(hdr_ptr, &msg); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); // PLDM message pointer is NULL rc = pack_pldm_header(&hdr, nullptr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); // PLDM header information pointer and PLDM message pointer is NULL rc = pack_pldm_header(hdr_ptr, nullptr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); // RESERVED message type hdr.msg_type = PLDM_RESERVED; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); // Instance ID out of range hdr.msg_type = PLDM_REQUEST; hdr.instance = 32; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); // PLDM type out of range hdr.msg_type = PLDM_REQUEST; hdr.instance = 31; hdr.pldm_type = 64; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_ERROR_INVALID_PLDM_TYPE); } TEST(PackPLDMMessage, RequestMessageGoodPath) { struct pldm_header_info hdr; pldm_msg_hdr msg{}; // Message type is REQUEST and lower range of the field values hdr.msg_type = PLDM_REQUEST; hdr.instance = 0; hdr.pldm_type = 0; hdr.command = 0; auto rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(msg.request, 1); EXPECT_EQ(msg.datagram, 0); EXPECT_EQ(msg.instance_id, 0); EXPECT_EQ(msg.type, 0); EXPECT_EQ(msg.command, 0); // Message type is REQUEST and upper range of the field values hdr.instance = 31; hdr.pldm_type = 63; hdr.command = 255; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(msg.request, 1); EXPECT_EQ(msg.datagram, 0); EXPECT_EQ(msg.instance_id, 31); EXPECT_EQ(msg.type, 63); EXPECT_EQ(msg.command, 255); // Message type is PLDM_ASYNC_REQUEST_NOTIFY hdr.msg_type = PLDM_ASYNC_REQUEST_NOTIFY; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(msg.request, 1); EXPECT_EQ(msg.datagram, 1); EXPECT_EQ(msg.instance_id, 31); EXPECT_EQ(msg.type, 63); EXPECT_EQ(msg.command, 255); } TEST(PackPLDMMessage, ResponseMessageGoodPath) { struct pldm_header_info hdr; pldm_msg_hdr msg{}; // Message type is PLDM_RESPONSE and lower range of the field values hdr.msg_type = PLDM_RESPONSE; hdr.instance = 0; hdr.pldm_type = 0; hdr.command = 0; auto rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(msg.request, 0); EXPECT_EQ(msg.datagram, 0); EXPECT_EQ(msg.instance_id, 0); EXPECT_EQ(msg.type, 0); EXPECT_EQ(msg.command, 0); // Message type is PLDM_RESPONSE and upper range of the field values hdr.instance = 31; hdr.pldm_type = 63; hdr.command = 255; rc = pack_pldm_header(&hdr, &msg); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(msg.request, 0); EXPECT_EQ(msg.datagram, 0); EXPECT_EQ(msg.instance_id, 31); EXPECT_EQ(msg.type, 63); EXPECT_EQ(msg.command, 255); } TEST(UnpackPLDMMessage, BadPathTest) { struct pldm_header_info hdr; // PLDM message pointer is NULL auto rc = unpack_pldm_header(nullptr, &hdr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); } TEST(UnpackPLDMMessage, RequestMessageGoodPath) { struct pldm_header_info hdr; pldm_msg_hdr msg{}; // Unpack PLDM request message and lower range of field values msg.request = 1; auto rc = unpack_pldm_header(&msg, &hdr); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(hdr.msg_type, PLDM_REQUEST); EXPECT_EQ(hdr.instance, 0); EXPECT_EQ(hdr.pldm_type, 0); EXPECT_EQ(hdr.command, 0); // Unpack PLDM async request message and lower range of field values msg.datagram = 1; rc = unpack_pldm_header(&msg, &hdr); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(hdr.msg_type, PLDM_ASYNC_REQUEST_NOTIFY); // Unpack PLDM request message and upper range of field values msg.datagram = 0; msg.instance_id = 31; msg.type = 63; msg.command = 255; rc = unpack_pldm_header(&msg, &hdr); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(hdr.msg_type, PLDM_REQUEST); EXPECT_EQ(hdr.instance, 31); EXPECT_EQ(hdr.pldm_type, 63); EXPECT_EQ(hdr.command, 255); } TEST(UnpackPLDMMessage, ResponseMessageGoodPath) { struct pldm_header_info hdr; pldm_msg_hdr msg{}; // Unpack PLDM response message and lower range of field values auto rc = unpack_pldm_header(&msg, &hdr); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(hdr.msg_type, PLDM_RESPONSE); EXPECT_EQ(hdr.instance, 0); EXPECT_EQ(hdr.pldm_type, 0); EXPECT_EQ(hdr.command, 0); // Unpack PLDM response message and upper range of field values msg.instance_id = 31; msg.type = 63; msg.command = 255; rc = unpack_pldm_header(&msg, &hdr); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(hdr.msg_type, PLDM_RESPONSE); EXPECT_EQ(hdr.instance, 31); EXPECT_EQ(hdr.pldm_type, 63); EXPECT_EQ(hdr.command, 255); } TEST(GetPLDMCommands, testEncodeRequest) { uint8_t pldmType = 0x05; ver32_t version{0xff, 0xff, 0xff, 0xff}; std::array requestMsg{}; auto request = reinterpret_cast(requestMsg.data()); auto rc = encode_get_commands_req(0, pldmType, version, request); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(0, memcmp(request->payload, &pldmType, sizeof(pldmType))); EXPECT_EQ(0, memcmp(request->payload + sizeof(pldmType), &version, sizeof(version))); } TEST(GetPLDMCommands, testDecodeRequest) { uint8_t pldmType = 0x05; ver32_t version{0xff, 0xff, 0xff, 0xff}; uint8_t pldmTypeOut{}; ver32_t versionOut{0xff, 0xff, 0xff, 0xff}; std::array requestMsg{}; memcpy(requestMsg.data() + hdrSize, &pldmType, sizeof(pldmType)); memcpy(requestMsg.data() + sizeof(pldmType) + hdrSize, &version, sizeof(version)); auto request = reinterpret_cast(requestMsg.data()); auto rc = decode_get_commands_req(request, requestMsg.size() - hdrSize, &pldmTypeOut, &versionOut); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(pldmTypeOut, pldmType); EXPECT_EQ(0, memcmp(&versionOut, &version, sizeof(version))); } TEST(GetPLDMCommands, testEncodeResponse) { uint8_t completionCode = 0; std::array responseMsg{}; auto response = reinterpret_cast(responseMsg.data()); std::array commands{}; commands[0].byte = 1; commands[1].byte = 2; commands[2].byte = 3; auto rc = encode_get_commands_resp(0, PLDM_SUCCESS, commands.data(), response); EXPECT_EQ(rc, PLDM_SUCCESS); uint8_t* payload_ptr = response->payload; EXPECT_EQ(completionCode, payload_ptr[0]); EXPECT_EQ(1, payload_ptr[sizeof(completionCode)]); EXPECT_EQ(2, payload_ptr[sizeof(completionCode) + sizeof(commands[0].byte)]); EXPECT_EQ(3, payload_ptr[sizeof(completionCode) + sizeof(commands[0].byte) + sizeof(commands[1].byte)]); } TEST(GetPLDMTypes, testEncodeResponse) { uint8_t completionCode = 0; std::array responseMsg{}; auto response = reinterpret_cast(responseMsg.data()); std::array types{}; types[0].byte = 1; types[1].byte = 2; types[2].byte = 3; auto rc = encode_get_types_resp(0, PLDM_SUCCESS, types.data(), response); EXPECT_EQ(rc, PLDM_SUCCESS); uint8_t* payload_ptr = response->payload; EXPECT_EQ(completionCode, payload_ptr[0]); EXPECT_EQ(1, payload_ptr[sizeof(completionCode)]); EXPECT_EQ(2, payload_ptr[sizeof(completionCode) + sizeof(types[0].byte)]); EXPECT_EQ(3, payload_ptr[sizeof(completionCode) + sizeof(types[0].byte) + sizeof(types[1].byte)]); } TEST(GetPLDMTypes, testGoodDecodeResponse) { std::array responseMsg{}; responseMsg[1 + hdrSize] = 1; responseMsg[2 + hdrSize] = 2; responseMsg[3 + hdrSize] = 3; std::array outTypes{}; uint8_t completion_code; responseMsg[hdrSize] = PLDM_SUCCESS; auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_types_resp(response, responseMsg.size() - hdrSize, &completion_code, outTypes.data()); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(completion_code, PLDM_SUCCESS); EXPECT_EQ(responseMsg[1 + hdrSize], outTypes[0].byte); EXPECT_EQ(responseMsg[2 + hdrSize], outTypes[1].byte); EXPECT_EQ(responseMsg[3 + hdrSize], outTypes[2].byte); } TEST(GetPLDMTypes, testBadDecodeResponse) { std::array responseMsg{}; responseMsg[1 + hdrSize] = 1; responseMsg[2 + hdrSize] = 2; responseMsg[3 + hdrSize] = 3; std::array outTypes{}; uint8_t retcompletion_code = 0; responseMsg[hdrSize] = PLDM_SUCCESS; auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_types_resp(response, responseMsg.size() - hdrSize - 1, &retcompletion_code, outTypes.data()); EXPECT_EQ(rc, PLDM_ERROR_INVALID_LENGTH); } TEST(GetPLDMCommands, testGoodDecodeResponse) { std::array responseMsg{}; responseMsg[1 + hdrSize] = 1; responseMsg[2 + hdrSize] = 2; responseMsg[3 + hdrSize] = 3; std::array outTypes{}; uint8_t completion_code; responseMsg[hdrSize] = PLDM_SUCCESS; auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_commands_resp(response, responseMsg.size() - hdrSize, &completion_code, outTypes.data()); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(completion_code, PLDM_SUCCESS); EXPECT_EQ(responseMsg[1 + hdrSize], outTypes[0].byte); EXPECT_EQ(responseMsg[2 + hdrSize], outTypes[1].byte); EXPECT_EQ(responseMsg[3 + hdrSize], outTypes[2].byte); } TEST(GetPLDMCommands, testBadDecodeResponse) { std::array responseMsg{}; responseMsg[1 + hdrSize] = 1; responseMsg[2 + hdrSize] = 2; responseMsg[3 + hdrSize] = 3; std::array outTypes{}; uint8_t retcompletion_code = 0; responseMsg[hdrSize] = PLDM_SUCCESS; auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_commands_resp(response, responseMsg.size() - hdrSize - 1, &retcompletion_code, outTypes.data()); EXPECT_EQ(rc, PLDM_ERROR_INVALID_LENGTH); } TEST(GetPLDMVersion, testGoodEncodeRequest) { std::array requestMsg{}; auto request = reinterpret_cast(requestMsg.data()); uint8_t pldmType = 0x03; uint32_t transferHandle = 0x0; uint8_t opFlag = 0x01; auto rc = encode_get_version_req(0, transferHandle, opFlag, pldmType, request); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ( 0, memcmp(request->payload, &transferHandle, sizeof(transferHandle))); EXPECT_EQ(0, memcmp(request->payload + sizeof(transferHandle), &opFlag, sizeof(opFlag))); EXPECT_EQ(0, memcmp(request->payload + sizeof(transferHandle) + sizeof(opFlag), &pldmType, sizeof(pldmType))); } TEST(GetPLDMVersion, testBadEncodeRequest) { uint8_t pldmType = 0x03; uint32_t transferHandle = 0x0; uint8_t opFlag = 0x01; auto rc = encode_get_version_req(0, transferHandle, opFlag, pldmType, nullptr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); } TEST(GetPLDMVersion, testEncodeResponse) { uint8_t completionCode = 0; uint32_t transferHandle = 0; uint8_t flag = PLDM_START_AND_END; std::array responseMsg{}; auto response = reinterpret_cast(responseMsg.data()); ver32_t version = {0xff, 0xff, 0xff, 0xff}; auto rc = encode_get_version_resp(0, PLDM_SUCCESS, 0, PLDM_START_AND_END, &version, sizeof(ver32_t), response); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(completionCode, response->payload[0]); EXPECT_EQ(0, memcmp(response->payload + sizeof(response->payload[0]), &transferHandle, sizeof(transferHandle))); EXPECT_EQ(0, memcmp(response->payload + sizeof(response->payload[0]) + sizeof(transferHandle), &flag, sizeof(flag))); EXPECT_EQ(0, memcmp(response->payload + sizeof(response->payload[0]) + sizeof(transferHandle) + sizeof(flag), &version, sizeof(version))); } TEST(GetPLDMVersion, testDecodeRequest) { std::array requestMsg{}; uint32_t transferHandle = 0x0; uint32_t retTransferHandle = 0x0; uint8_t flag = PLDM_GET_FIRSTPART; uint8_t retFlag = PLDM_GET_FIRSTPART; uint8_t pldmType = PLDM_BASE; uint8_t retType = PLDM_BASE; memcpy(requestMsg.data() + hdrSize, &transferHandle, sizeof(transferHandle)); memcpy(requestMsg.data() + sizeof(transferHandle) + hdrSize, &flag, sizeof(flag)); memcpy(requestMsg.data() + sizeof(transferHandle) + sizeof(flag) + hdrSize, &pldmType, sizeof(pldmType)); auto request = reinterpret_cast(requestMsg.data()); auto rc = decode_get_version_req(request, requestMsg.size() - hdrSize, &retTransferHandle, &retFlag, &retType); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(transferHandle, retTransferHandle); EXPECT_EQ(flag, retFlag); EXPECT_EQ(pldmType, retType); } TEST(GetPLDMVersion, testDecodeResponse) { std::array responseMsg{}; uint32_t transferHandle = 0x0; uint32_t retTransferHandle = 0x0; uint8_t flag = PLDM_START_AND_END; uint8_t retFlag = PLDM_START_AND_END; uint8_t completionCode = 0; ver32_t version = {0xff, 0xff, 0xff, 0xff}; ver32_t versionOut; uint8_t completion_code; memcpy(responseMsg.data() + sizeof(completionCode) + hdrSize, &transferHandle, sizeof(transferHandle)); memcpy(responseMsg.data() + sizeof(completionCode) + sizeof(transferHandle) + hdrSize, &flag, sizeof(flag)); memcpy(responseMsg.data() + sizeof(completionCode) + sizeof(transferHandle) + sizeof(flag) + hdrSize, &version, sizeof(version)); auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_version_resp(response, responseMsg.size() - hdrSize, &completion_code, &retTransferHandle, &retFlag, &versionOut); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(transferHandle, retTransferHandle); EXPECT_EQ(flag, retFlag); EXPECT_EQ(versionOut.major, version.major); EXPECT_EQ(versionOut.minor, version.minor); EXPECT_EQ(versionOut.update, version.update); EXPECT_EQ(versionOut.alpha, version.alpha); } TEST(GetTID, testEncodeRequest) { pldm_msg request{}; auto rc = encode_get_tid_req(0, &request); ASSERT_EQ(rc, PLDM_SUCCESS); } TEST(GetTID, testEncodeResponse) { uint8_t completionCode = 0; std::array responseMsg{}; auto response = reinterpret_cast(responseMsg.data()); uint8_t tid = 1; auto rc = encode_get_tid_resp(0, PLDM_SUCCESS, tid, response); EXPECT_EQ(rc, PLDM_SUCCESS); uint8_t* payload = response->payload; EXPECT_EQ(completionCode, payload[0]); EXPECT_EQ(1, payload[sizeof(completionCode)]); } TEST(GetTID, testDecodeResponse) { std::array responseMsg{}; responseMsg[1 + hdrSize] = 1; uint8_t tid; uint8_t completion_code; responseMsg[hdrSize] = PLDM_SUCCESS; auto response = reinterpret_cast(responseMsg.data()); auto rc = decode_get_tid_resp(response, responseMsg.size() - hdrSize, &completion_code, &tid); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(completion_code, PLDM_SUCCESS); EXPECT_EQ(tid, 1); } TEST(MultipartReceive, testDecodeRequestPass) { constexpr uint8_t kPldmType = PLDM_BASE; constexpr uint8_t kFlag = PLDM_XFER_FIRST_PART; constexpr uint32_t kTransferCtx = 0x01; constexpr uint32_t kTransferHandle = 0x10; constexpr uint32_t kSectionOffset = 0x0; constexpr uint32_t kSectionLength = 0x10; uint8_t pldm_type = 0x0; uint8_t flag = PLDM_GET_FIRSTPART; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt = { .pldm_type = kPldmType, .transfer_opflag = kFlag, .transfer_ctx = kTransferCtx, .transfer_handle = kTransferHandle, .section_offset = kSectionOffset, .section_length = kSectionLength, }; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); int rc = decode_multipart_receive_req( pldm_request, req.size() - hdrSize, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length); EXPECT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(pldm_type, kPldmType); EXPECT_EQ(flag, kFlag); EXPECT_EQ(transfer_ctx, kTransferCtx); EXPECT_EQ(transfer_handle, kTransferHandle); EXPECT_EQ(section_offset, kSectionOffset); EXPECT_EQ(section_length, kSectionLength); } TEST(MultipartReceive, testDecodeRequestFailNullData) { EXPECT_EQ(decode_multipart_receive_req(NULL, 0, NULL, NULL, NULL, NULL, NULL, NULL), PLDM_ERROR_INVALID_DATA); } TEST(MultipartReceive, testDecodeRequestFailBadLength) { constexpr uint8_t kPldmType = PLDM_BASE; constexpr uint8_t kFlag = PLDM_XFER_FIRST_PART; uint8_t pldm_type; uint8_t flag; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt{}; req_pkt.pldm_type = kPldmType; req_pkt.transfer_opflag = kFlag; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); EXPECT_EQ(decode_multipart_receive_req( pldm_request, (req.size() - hdrSize) + 1, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length), PLDM_ERROR_INVALID_LENGTH); } TEST(MultipartReceive, testDecodeRequestFailBadPldmType) { constexpr uint8_t kPldmType = 0xff; constexpr uint8_t kFlag = PLDM_XFER_FIRST_PART; uint8_t pldm_type; uint8_t flag; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt{}; req_pkt.pldm_type = kPldmType; req_pkt.transfer_opflag = kFlag; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); EXPECT_EQ(decode_multipart_receive_req(pldm_request, req.size() - hdrSize, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length), PLDM_ERROR_INVALID_PLDM_TYPE); } TEST(MultipartReceive, testDecodeRequestFailBadTransferFlag) { constexpr uint8_t kPldmType = PLDM_BASE; constexpr uint8_t kFlag = PLDM_XFER_CURRENT_PART + 0x10; uint8_t pldm_type; uint8_t flag; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt{}; req_pkt.pldm_type = kPldmType; req_pkt.transfer_opflag = kFlag; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); EXPECT_EQ(decode_multipart_receive_req(pldm_request, req.size() - hdrSize, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length), PLDM_INVALID_TRANSFER_OPERATION_FLAG); } TEST(MultipartReceive, testDecodeRequestFailBadOffset) { constexpr uint8_t kPldmType = PLDM_BASE; constexpr uint8_t kFlag = PLDM_XFER_NEXT_PART; constexpr uint32_t kTransferHandle = 0x01; constexpr uint32_t kSectionOffset = 0x0; uint8_t pldm_type; uint8_t flag; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt{}; req_pkt.pldm_type = kPldmType; req_pkt.transfer_opflag = kFlag; req_pkt.transfer_handle = kTransferHandle; req_pkt.section_offset = kSectionOffset; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); EXPECT_EQ(decode_multipart_receive_req(pldm_request, req.size() - hdrSize, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length), PLDM_ERROR_INVALID_DATA); } TEST(MultipartReceive, testDecodeRequestFailBadHandle) { constexpr uint8_t kPldmType = PLDM_BASE; constexpr uint8_t kFlag = PLDM_XFER_NEXT_PART; constexpr uint32_t kSectionOffset = 0x100; constexpr uint32_t kTransferHandle = 0x0; uint8_t pldm_type; uint8_t flag; uint32_t transfer_ctx; uint32_t transfer_handle; uint32_t section_offset; uint32_t section_length; // Header values don't matter for this test. pldm_msg_hdr hdr{}; // Assign values to the packet struct and memcpy to ensure correct byte // ordering. pldm_multipart_receive_req req_pkt{}; req_pkt.pldm_type = kPldmType; req_pkt.transfer_opflag = kFlag; req_pkt.transfer_handle = kTransferHandle; req_pkt.section_offset = kSectionOffset; std::vector req(sizeof(hdr) + PLDM_MULTIPART_RECEIVE_REQ_BYTES); std::memcpy(req.data(), &hdr, sizeof(hdr)); std::memcpy(req.data() + sizeof(hdr), &req_pkt, sizeof(req_pkt)); pldm_msg* pldm_request = reinterpret_cast(req.data()); EXPECT_EQ(decode_multipart_receive_req(pldm_request, req.size() - hdrSize, &pldm_type, &flag, &transfer_ctx, &transfer_handle, §ion_offset, §ion_length), PLDM_ERROR_INVALID_DATA); } TEST(CcOnlyResponse, testEncode) { struct pldm_msg responseMsg; auto rc = encode_cc_only_resp(0 /*instance id*/, 1 /*pldm type*/, 2 /*command*/, 3 /*completion code*/, &responseMsg); EXPECT_EQ(rc, PLDM_SUCCESS); auto p = reinterpret_cast(&responseMsg); EXPECT_THAT(std::vector(p, p + sizeof(responseMsg)), ElementsAreArray({0, 1, 2, 3})); rc = encode_cc_only_resp(PLDM_INSTANCE_MAX + 1, 1, 2, 3, &responseMsg); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); rc = encode_cc_only_resp(0, 1, 2, 3, nullptr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); } TEST(SetTID, testGoodEncodeRequest) { uint8_t instanceId = 0; uint8_t tid = 0x01; std::array requestMsg{}; auto request = reinterpret_cast(requestMsg.data()); auto rc = encode_set_tid_req(instanceId, tid, request); ASSERT_EQ(rc, PLDM_SUCCESS); EXPECT_EQ(request->hdr.command, PLDM_SET_TID); EXPECT_EQ(request->hdr.type, PLDM_BASE); EXPECT_EQ(request->hdr.request, 1); EXPECT_EQ(request->hdr.datagram, 0); EXPECT_EQ(request->hdr.instance_id, instanceId); EXPECT_EQ(0, memcmp(request->payload, &tid, sizeof(tid))); } TEST(SetTID, testBadEncodeRequest) { uint8_t tid = 0x01; std::array requestMsg{}; auto request = reinterpret_cast(requestMsg.data()); auto rc = encode_set_tid_req(0, tid, nullptr); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); rc = encode_set_tid_req(0, 0, request); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); rc = encode_set_tid_req(0, 0xff, request); EXPECT_EQ(rc, PLDM_ERROR_INVALID_DATA); } #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateSuccess) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 0, .type = 0, .header_ver = 1, .command = 0x01, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), true); } #endif #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateFailInstanceID) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 1, .reserved = 0, .datagram = 0, .request = 0, .type = 0, .header_ver = 1, .command = 0x01, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), false); } #endif #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateFailRequest) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), false); } #endif #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateFailType) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 0, .type = 1, .header_ver = 1, .command = 0x01, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), false); } #endif #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateFailCommand) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 1, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 0, .type = 0, .header_ver = 1, .command = 0x02, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), false); } #endif #ifdef LIBPLDM_API_TESTING TEST(PldmMsgHdr, correlateFailRequestIsResponse) { static const struct pldm_msg_hdr req = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 0, .type = 0, .header_ver = 1, .command = 0x01, }; static const struct pldm_msg_hdr resp = { .instance_id = 0, .reserved = 0, .datagram = 0, .request = 0, .type = 0, .header_ver = 1, .command = 0x02, }; ASSERT_EQ(pldm_msg_hdr_correlate_response(&req, &resp), false); } #endif