// Copyright(c) 2017-2018, Intel Corporation // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // * Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // * Neither the name of Intel Corporation nor the names of its contributors // may be used to endorse or promote products derived from this software // without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE // POSSIBILITY OF SUCH DAMAGE. #ifdef __cplusplus extern "C" { #endif #include #include #include #include "opae_int.h" #ifdef __cplusplus } #endif #include #include #include #include #include #include #include #include #include "mock/mock_opae.h" #include using namespace opae::testing; class enum_c_p : public mock_opae_p<2, none_> { protected: enum_c_p() {} virtual void test_setup() override { ASSERT_EQ(fpgaInitialize(NULL), FPGA_OK); filter_ = nullptr; ASSERT_EQ(fpgaGetProperties(nullptr, &filter_), FPGA_OK); num_matches_ = 0; } virtual void test_teardown() override { num_matches_ = 0; if (filter_ != nullptr) { EXPECT_EQ(fpgaDestroyProperties(&filter_), FPGA_OK); } fpgaFinalize(); } // Need a concrete way to determine the number of fpgas on the system // without relying on fpgaEnumerate() since that is the function that // is under test. virtual int GetNumFpgas() { if (platform_.mock_sysfs != nullptr) { return platform_.devices.size(); } int value; std::string cmd = "(ls -l /sys/class/fpga*/region*/*fme*/dev || " "ls -l /sys/class/fpga*/*intel*) | (wc -l)"; ExecuteCmd(cmd, value); return value; } virtual int GetNumMatchedFpga () { if (platform_.mock_sysfs != nullptr) { return 1; } int matches = 0; int socket_id; int i; for (i = 0; i < GetNumFpgas(); i++) { std::string cmd = "cat /sys/class/fpga*/*" + std::to_string(i) + "/*fme." + std::to_string(i) + "/socket_id"; ExecuteCmd(cmd, socket_id); if (socket_id == (int)platform_.devices[0].socket_id) { matches++; } } return matches; } int GetMatchedGuidFpgas() { if (platform_.mock_sysfs != nullptr) { return platform_.devices.size(); } int matches = 0; std::string afu_id; std::string afu_id_expected = platform_.devices[0].afu_guid; afu_id_expected.erase(std::remove(afu_id_expected.begin(), afu_id_expected.end(), '-'), afu_id_expected.end()); transform(afu_id_expected.begin(), afu_id_expected.end(), afu_id_expected.begin(), ::tolower); int i; for (i = 0; i < GetNumFpgas(); i++) { std::string cmd = "cat /sys/class/fpga*/*" + std::to_string(i) + "/*port." + std::to_string(i) + "/afu_id > output.txt"; EXPECT_EQ(std::system(cmd.c_str()), 0); std::ifstream file("output.txt"); EXPECT_TRUE(file.is_open()); EXPECT_TRUE(std::getline(file, afu_id)); file.close(); EXPECT_EQ(unlink("output.txt"), 0); if (afu_id == afu_id_expected) { matches++; } } return matches; } virtual int GetNumDeviceID() { if (platform_.mock_sysfs != nullptr) { return 1; } std::stringstream stream; stream << std::hex << platform_.devices[0].device_id; std::string device_id(stream.str()); int value; std::string cmd = "lspci | " "grep \'Processing accelerators: " "Intel Corporation\' | " "grep -oE \'[^ ]+$\' | " "grep " + device_id + " | " "wc -l"; ExecuteCmd(cmd, value); return value; } virtual void ExecuteCmd(std::string cmd, int &value) { std::string line; std::string command = cmd + " > output.txt"; EXPECT_EQ(std::system(command.c_str()), 0); std::ifstream file("output.txt"); ASSERT_TRUE(file.is_open()); EXPECT_TRUE(std::getline(file, line)); file.close(); EXPECT_EQ(std::system("rm output.txt"), 0); value = std::stoi(line); } fpga_properties filter_; uint32_t num_matches_; }; TEST_P(enum_c_p, nullfilter) { EXPECT_EQ( fpgaEnumerate(nullptr, 0, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas() * 2); uint32_t matches = 0; EXPECT_EQ(fpgaEnumerate(nullptr, 1, tokens_.data(), tokens_.size(), &matches), FPGA_INVALID_PARAM); } TEST_P(enum_c_p, nullmatches) { EXPECT_EQ(fpgaEnumerate(&filter_, 0, tokens_.data(), tokens_.size(), NULL), FPGA_INVALID_PARAM); EXPECT_EQ( fpgaEnumerate(&filter_, 0, tokens_.data(), tokens_.size(), &num_matches_), FPGA_INVALID_PARAM); } TEST_P(enum_c_p, nulltokens) { EXPECT_EQ(fpgaEnumerate(&filter_, 0, NULL, tokens_.size(), &num_matches_), FPGA_INVALID_PARAM); } TEST_P(enum_c_p, object_type) { ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_ACCELERATOR), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); EXPECT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); } TEST_P(enum_c_p, parent) { EXPECT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); fpga_token tok = nullptr; ASSERT_EQ(fpgaCloneToken(tokens_[0], &tok), FPGA_OK); DestroyTokens(); ASSERT_EQ(fpgaClearProperties(filter_), FPGA_OK); EXPECT_EQ(fpgaPropertiesSetParent(filter_, tok), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 1); EXPECT_EQ(fpgaDestroyToken(&tok), FPGA_OK); } TEST_P(enum_c_p, segment) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetSegment(filter_, device.segment), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); // multiply by two to account for port/fme devices EXPECT_EQ(num_matches_, GetNumFpgas() * 2); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetSegment(filter_, invalid_device_.segment), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, bus) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetBus(filter_, device.bus), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); // multiply by two to account for port/fme devices EXPECT_EQ(num_matches_, 2); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetBus(filter_, invalid_device_.bus), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, device) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetDevice(filter_, device.device), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas() * 2); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetDevice(filter_, invalid_device_.device), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, function) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetFunction(filter_, device.function), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas() * (device.num_vfs == 0 ? 2 : 1)); num_matches_ = 0; DestroyTokens(); for (int i = 1; i < device.num_vfs+1; ++i) { ASSERT_EQ(fpgaPropertiesSetFunction(filter_, i), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 1); DestroyTokens(); } } TEST_P(enum_c_p, invalid_function) { ASSERT_EQ(fpgaPropertiesSetFunction(filter_, invalid_device_.function), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, vendor_id) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetVendorID(filter_, device.vendor_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas() * 2); } TEST_P(enum_c_p, invalid_vendor_id) { ASSERT_EQ(fpgaPropertiesSetVendorID(filter_, invalid_device_.vendor_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, device_id) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetDeviceID(filter_, device.device_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumDeviceID() * (device.num_vfs == 0 ? 2 : 1)); DestroyTokens(); num_matches_ = 0; for (int i = 1; i < device.num_vfs+1; ++i) { ASSERT_EQ(fpgaPropertiesSetDeviceID(filter_, device.device_id+i), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 1); DestroyTokens(); } } TEST_P(enum_c_p, invalid_device_id) { ASSERT_EQ(fpgaPropertiesSetDeviceID(filter_, invalid_device_.device_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, object_id_fme) { fpga_properties prop = nullptr; uint64_t object_id; ASSERT_EQ(fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); ASSERT_GT(num_matches_, 0); EXPECT_EQ(fpgaGetProperties(tokens_[0], &prop), FPGA_OK); EXPECT_EQ(fpgaPropertiesGetObjectID(prop, &object_id), FPGA_OK); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetObjectID(filter_, object_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 1); EXPECT_EQ(FPGA_OK, fpgaDestroyProperties(&prop)); } TEST_P(enum_c_p, object_id_fme_neg) { ASSERT_EQ(fpgaPropertiesSetObjectID(filter_, invalid_device_.fme_object_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, object_id_port) { fpga_properties prop = nullptr; uint64_t object_id; ASSERT_EQ(fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); ASSERT_GT(num_matches_, 0); EXPECT_EQ(fpgaGetProperties(tokens_[0], &prop), FPGA_OK); EXPECT_EQ(fpgaPropertiesGetObjectID(prop, &object_id), FPGA_OK); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetObjectID(filter_, object_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 1); EXPECT_EQ(FPGA_OK, fpgaDestroyProperties(&prop)); } TEST_P(enum_c_p, object_id_port_neg) { ASSERT_EQ(fpgaPropertiesSetObjectID(filter_, invalid_device_.port_object_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, guid) { auto device = platform_.devices[0]; // fme guid fpga_guid fme_guid, afu_guid, random_guid; ASSERT_EQ(uuid_parse(device.fme_guid, fme_guid), 0); ASSERT_EQ(uuid_parse(device.afu_guid, afu_guid), 0); ASSERT_EQ(uuid_parse(invalid_device_.afu_guid, random_guid), 0); ASSERT_EQ(fpgaPropertiesSetGUID(filter_, fme_guid), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, platform_.devices.size()); DestroyTokens(); // afu guid ASSERT_EQ(fpgaPropertiesSetGUID(filter_, afu_guid), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetMatchedGuidFpgas()); DestroyTokens(); // random guid ASSERT_EQ(fpgaPropertiesSetGUID(filter_, random_guid), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, clone_token01) { EXPECT_EQ( fpgaEnumerate(nullptr, 0, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); ASSERT_EQ(num_matches_, GetNumFpgas() * 2); fpga_token src = tokens_[0]; fpga_token dst = nullptr; EXPECT_EQ(fpgaCloneToken(src, &dst), FPGA_OK); EXPECT_EQ(fpgaDestroyToken(&dst), FPGA_OK); } TEST_P(enum_c_p, clone_wo_src_dst) { EXPECT_EQ( fpgaEnumerate(nullptr, 0, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas() * 2); fpga_token src = tokens_[0]; fpga_token dst; EXPECT_EQ(fpgaCloneToken(NULL, &dst), FPGA_INVALID_PARAM); EXPECT_EQ(fpgaCloneToken(&src, NULL), FPGA_INVALID_PARAM); } TEST_P(enum_c_p, no_token_magic) { fpga_token src = nullptr, dst = nullptr; EXPECT_NE(fpgaCloneToken(&src, &dst), FPGA_OK); } TEST_P(enum_c_p, destroy_token) { opae_wrapped_token *dummy = new opae_wrapped_token; memset(dummy, 0, sizeof(opae_wrapped_token)); EXPECT_EQ(fpgaDestroyToken((fpga_token *)&dummy), FPGA_INVALID_PARAM); delete dummy; EXPECT_EQ(fpgaDestroyToken(nullptr), FPGA_INVALID_PARAM); } TEST_P(enum_c_p, num_slots) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetNumSlots(filter_, device.num_slots), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetNumSlots(filter_, invalid_device_.num_slots), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, bbs_id) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetBBSID(filter_, device.bbs_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, platform_.devices.size()); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetBBSID(filter_, invalid_device_.bbs_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, bbs_version) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetBBSVersion(filter_, device.bbs_version), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, platform_.devices.size()); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetBBSVersion(filter_, invalid_device_.bbs_version), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, state) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_ACCELERATOR), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetAcceleratorState(filter_, device.state), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetAcceleratorState(filter_, invalid_device_.state), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, num_mmio) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_ACCELERATOR), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetNumMMIO(filter_, device.num_mmio), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_DEVICE), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetNumMMIO(filter_, invalid_device_.num_mmio), FPGA_INVALID_PARAM); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST_P(enum_c_p, num_interrupts) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetObjectType(filter_, FPGA_ACCELERATOR), FPGA_OK); ASSERT_EQ(fpgaPropertiesSetNumInterrupts(filter_, device.num_interrupts), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); ASSERT_EQ( fpgaPropertiesSetNumInterrupts(filter_, invalid_device_.num_interrupts), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } TEST(wrapper, validate) { EXPECT_EQ(NULL, opae_validate_wrapped_token(NULL)); EXPECT_EQ(NULL, opae_validate_wrapped_handle(NULL)); EXPECT_EQ(NULL, opae_validate_wrapped_event_handle(NULL)); EXPECT_EQ(NULL, opae_validate_wrapped_object(NULL)); } INSTANTIATE_TEST_CASE_P(enum_c, enum_c_p, ::testing::ValuesIn(test_platform::platforms({}))); class enum_c_mock_p : public enum_c_p {}; TEST_P(enum_c_mock_p, clone_token02) { EXPECT_EQ( fpgaEnumerate(nullptr, 0, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); ASSERT_EQ(num_matches_, GetNumFpgas() * 2); fpga_token src = tokens_[0]; fpga_token dst = nullptr; // Invalidate the allocation of the wrapped token. system_->invalidate_malloc(0, "opae_allocate_wrapped_token"); EXPECT_EQ(fpgaCloneToken(src, &dst), FPGA_NO_MEMORY); } INSTANTIATE_TEST_CASE_P(enum_c, enum_c_mock_p, ::testing::ValuesIn(test_platform::mock_platforms())); class enum_c_err_p : public enum_c_p {}; TEST_P(enum_c_err_p, num_errors) { auto device = platform_.devices[0]; // fme num_errors ASSERT_EQ(fpgaPropertiesSetNumErrors(filter_, device.fme_num_errors), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); // afu num_errors ASSERT_EQ(fpgaPropertiesSetNumErrors(filter_, device.port_num_errors), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumFpgas()); DestroyTokens(); // invalid ASSERT_EQ( fpgaPropertiesSetNumErrors(filter_, invalid_device_.port_num_errors), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } INSTANTIATE_TEST_CASE_P(enum_c, enum_c_err_p, ::testing::ValuesIn(test_platform::platforms({ "skx-p","dcp-rc" }))); class enum_c_socket_p : public enum_c_p {}; TEST_P(enum_c_socket_p, socket_id) { auto device = platform_.devices[0]; ASSERT_EQ(fpgaPropertiesSetSocketID(filter_, device.socket_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, GetNumMatchedFpga() * 2); DestroyTokens(); ASSERT_EQ(fpgaPropertiesSetSocketID(filter_, invalid_device_.socket_id), FPGA_OK); EXPECT_EQ( fpgaEnumerate(&filter_, 1, tokens_.data(), tokens_.size(), &num_matches_), FPGA_OK); EXPECT_EQ(num_matches_, 0); } INSTANTIATE_TEST_CASE_P(enum_c, enum_c_socket_p, ::testing::ValuesIn(test_platform::platforms({ "skx-p","dcp-rc","dcp-vc" })));