zircon/kernel/arch/x86/system_topology_test.cc - fuchsia - Git at Google

 // Copyright 2019 The Fuchsia Authors
 //
 // Use of this source code is governed by a MIT-style
 // license that can be found in the LICENSE file or at
 // https://opensource.org/licenses/MIT

 #include "arch/x86/system_topology.h"

 #include <lib/acpi_lite/testing/test_data.h>
 #include <lib/arch/testing/x86/fake-cpuid.h>
 #include <lib/system-topology.h>
 #include <lib/unittest/unittest.h>

 using system_topology::Graph;

 namespace {

 // Uses test data from a HP z840, dual socket Xeon E2690v4.
 bool test_cpus_z840() {
   BEGIN_TEST;

   arch::testing::FakeCpuidIo io(arch::testing::X86Microprocessor::kIntelXeonE5_2690_V4);
   fbl::Vector<zbi_topology_node_t> flat_topology;
   auto status = x86::GenerateFlatTopology(io, acpi_lite::testing::Z840AcpiParser(), &flat_topology);
   ASSERT_EQ(ZX_OK, status);

   int numa_count = 0;
   int die_count = 0;
   int cache_count = 0;
   int core_count = 0;
   int thread_count = 0;
   int last_numa = -1;
   int last_die = -1;
   int last_cache = -1;
   for (int i = 0; i < (int)flat_topology.size(); i++) {
     const auto& node = flat_topology[i];
     switch (node.entity_type) {
       case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
         last_numa = i;
         numa_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_DIE:
         EXPECT_EQ(last_numa, node.parent_index);
         last_die = i;
         die_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_CACHE:
         EXPECT_EQ(last_die, node.parent_index);
         last_cache = i;
         cache_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
         EXPECT_EQ(last_cache, node.parent_index);
         core_count++;
         thread_count += node.entity.processor.logical_id_count;
         break;
     }
   }

   // We expect two numa regions, two dies, two caches, and 28 cores.
   EXPECT_EQ(2u + 2u + 2u + 28u, flat_topology.size());
   EXPECT_EQ(2, numa_count);
   EXPECT_EQ(2, die_count);
   EXPECT_EQ(2, cache_count);
   EXPECT_EQ(28, core_count);
   EXPECT_EQ(56, thread_count);

   // Ensure the format can be parsed and validated by the system topology library.
   Graph graph;
   EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

   END_TEST;
 }

 // Uses test data from a Threadripper 2970wx system with x399 chipset.
 bool test_cpus_2970wx_x399() {
   BEGIN_TEST;

   arch::testing::FakeCpuidIo io(arch::testing::X86Microprocessor::kAmdRyzenThreadripper2970wx);
   fbl::Vector<zbi_topology_node_t> flat_topology;
   auto status =
       x86::GenerateFlatTopology(io, acpi_lite::testing::Sys2970wxAcpiParser(), &flat_topology);
   ASSERT_EQ(ZX_OK, status);

   int numa_count = 0;
   int die_count = 0;
   int core_count = 0;
   int cache_count = 0;
   int thread_count = 0;
   int last_numa = -1;
   int last_die = -1;
   int last_cache = -1;
   for (int i = 0; i < (int)flat_topology.size(); i++) {
     const auto& node = flat_topology[i];
     switch (node.entity_type) {
       case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
         last_numa = i;
         numa_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_DIE:
         EXPECT_EQ(last_numa, node.parent_index);
         last_die = i;
         die_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_CACHE:
         EXPECT_EQ(last_die, node.parent_index);
         last_cache = i;
         cache_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
         EXPECT_EQ(last_cache, node.parent_index);
         core_count++;
         thread_count += node.entity.processor.logical_id_count;
         break;
     }
   }

   EXPECT_EQ(4, numa_count);
   EXPECT_EQ(4, die_count);
   EXPECT_EQ(8, cache_count);
   EXPECT_EQ(24, core_count);
   EXPECT_EQ(48, thread_count);

   // Ensure the format can be parsed and validated by the system topology library.
   Graph graph;
   EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

   END_TEST;
 }

 // Uses bad data to trigger the fallback topology, (everything flat).
 bool test_cpus_fallback() {
   BEGIN_TEST;

   // With an 'empty' CPUID data set (representing a pathological case) we would
   // expect enumeration to fall back to maximally flat description of one
   // thread to one core to one package, multiplied by the number of processors
   // enumerated by ACPI.
   arch::testing::FakeCpuidIo io;
   fbl::Vector<zbi_topology_node_t> flat_topology;
   auto status =
       x86::GenerateFlatTopology(io, acpi_lite::testing::PixelbookEveAcpiParser(), &flat_topology);
   ASSERT_EQ(ZX_OK, status);

   int numa_count = 0;
   int die_count = 0;
   int core_count = 0;
   int cache_count = 0;
   int thread_count = 0;
   for (int i = 0; i < (int)flat_topology.size(); i++) {
     const auto& node = flat_topology[i];
     switch (node.entity_type) {
       case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
         numa_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_DIE:
         die_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_CACHE:
         cache_count++;
         break;
       case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
         core_count++;
         thread_count += node.entity.processor.logical_id_count;
         break;
     }
   }

   EXPECT_EQ(0, numa_count);
   EXPECT_EQ(4, die_count);
   EXPECT_EQ(0, cache_count);
   EXPECT_EQ(4, core_count);
   EXPECT_EQ(4, thread_count);

   // Ensure the format can be parsed and validated by the system topology library.
   Graph graph;
   EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

   END_TEST;
 }

 }  // namespace

 UNITTEST_START_TESTCASE(x86_topology_tests)
 UNITTEST("Enumerate cpus using data from HP z840.", test_cpus_z840)
 UNITTEST("Enumerate cpus using data from ThreadRipper 2970wx/X399.", test_cpus_2970wx_x399)
 UNITTEST("Enumerate cpus using data triggering fallback.", test_cpus_fallback)
 UNITTEST_END_TESTCASE(x86_topology_tests, "x86_topology",
                       "Test determining x86 topology through CPUID/APIC.")
	// Copyright 2019 The Fuchsia Authors
	//
	// Use of this source code is governed by a MIT-style
	// license that can be found in the LICENSE file or at
	// https://opensource.org/licenses/MIT

	#include "arch/x86/system_topology.h"

	#include <lib/acpi_lite/testing/test_data.h>
	#include <lib/arch/testing/x86/fake-cpuid.h>
	#include <lib/system-topology.h>
	#include <lib/unittest/unittest.h>

	using system_topology::Graph;

	namespace {

	// Uses test data from a HP z840, dual socket Xeon E2690v4.
	bool test_cpus_z840() {
	BEGIN_TEST;

	arch::testing::FakeCpuidIo io(arch::testing::X86Microprocessor::kIntelXeonE5_2690_V4);
	fbl::Vector<zbi_topology_node_t> flat_topology;
	auto status = x86::GenerateFlatTopology(io, acpi_lite::testing::Z840AcpiParser(), &flat_topology);
	ASSERT_EQ(ZX_OK, status);

	int numa_count = 0;
	int die_count = 0;
	int cache_count = 0;
	int core_count = 0;
	int thread_count = 0;
	int last_numa = -1;
	int last_die = -1;
	int last_cache = -1;
	for (int i = 0; i < (int)flat_topology.size(); i++) {
	const auto& node = flat_topology[i];
	switch (node.entity_type) {
	case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
	last_numa = i;
	numa_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_DIE:
	EXPECT_EQ(last_numa, node.parent_index);
	last_die = i;
	die_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_CACHE:
	EXPECT_EQ(last_die, node.parent_index);
	last_cache = i;
	cache_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
	EXPECT_EQ(last_cache, node.parent_index);
	core_count++;
	thread_count += node.entity.processor.logical_id_count;
	break;
	}
	}

	// We expect two numa regions, two dies, two caches, and 28 cores.
	EXPECT_EQ(2u + 2u + 2u + 28u, flat_topology.size());
	EXPECT_EQ(2, numa_count);
	EXPECT_EQ(2, die_count);
	EXPECT_EQ(2, cache_count);
	EXPECT_EQ(28, core_count);
	EXPECT_EQ(56, thread_count);

	// Ensure the format can be parsed and validated by the system topology library.
	Graph graph;
	EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

	END_TEST;
	}

	// Uses test data from a Threadripper 2970wx system with x399 chipset.
	bool test_cpus_2970wx_x399() {
	BEGIN_TEST;

	arch::testing::FakeCpuidIo io(arch::testing::X86Microprocessor::kAmdRyzenThreadripper2970wx);
	fbl::Vector<zbi_topology_node_t> flat_topology;
	auto status =
	x86::GenerateFlatTopology(io, acpi_lite::testing::Sys2970wxAcpiParser(), &flat_topology);
	ASSERT_EQ(ZX_OK, status);

	int numa_count = 0;
	int die_count = 0;
	int core_count = 0;
	int cache_count = 0;
	int thread_count = 0;
	int last_numa = -1;
	int last_die = -1;
	int last_cache = -1;
	for (int i = 0; i < (int)flat_topology.size(); i++) {
	const auto& node = flat_topology[i];
	switch (node.entity_type) {
	case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
	last_numa = i;
	numa_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_DIE:
	EXPECT_EQ(last_numa, node.parent_index);
	last_die = i;
	die_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_CACHE:
	EXPECT_EQ(last_die, node.parent_index);
	last_cache = i;
	cache_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
	EXPECT_EQ(last_cache, node.parent_index);
	core_count++;
	thread_count += node.entity.processor.logical_id_count;
	break;
	}
	}

	EXPECT_EQ(4, numa_count);
	EXPECT_EQ(4, die_count);
	EXPECT_EQ(8, cache_count);
	EXPECT_EQ(24, core_count);
	EXPECT_EQ(48, thread_count);

	// Ensure the format can be parsed and validated by the system topology library.
	Graph graph;
	EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

	END_TEST;
	}

	// Uses bad data to trigger the fallback topology, (everything flat).
	bool test_cpus_fallback() {
	BEGIN_TEST;

	// With an 'empty' CPUID data set (representing a pathological case) we would
	// expect enumeration to fall back to maximally flat description of one
	// thread to one core to one package, multiplied by the number of processors
	// enumerated by ACPI.
	arch::testing::FakeCpuidIo io;
	fbl::Vector<zbi_topology_node_t> flat_topology;
	auto status =
	x86::GenerateFlatTopology(io, acpi_lite::testing::PixelbookEveAcpiParser(), &flat_topology);
	ASSERT_EQ(ZX_OK, status);

	int numa_count = 0;
	int die_count = 0;
	int core_count = 0;
	int cache_count = 0;
	int thread_count = 0;
	for (int i = 0; i < (int)flat_topology.size(); i++) {
	const auto& node = flat_topology[i];
	switch (node.entity_type) {
	case ZBI_TOPOLOGY_ENTITY_NUMA_REGION:
	numa_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_DIE:
	die_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_CACHE:
	cache_count++;
	break;
	case ZBI_TOPOLOGY_ENTITY_PROCESSOR:
	core_count++;
	thread_count += node.entity.processor.logical_id_count;
	break;
	}
	}

	EXPECT_EQ(0, numa_count);
	EXPECT_EQ(4, die_count);
	EXPECT_EQ(0, cache_count);
	EXPECT_EQ(4, core_count);
	EXPECT_EQ(4, thread_count);

	// Ensure the format can be parsed and validated by the system topology library.
	Graph graph;
	EXPECT_EQ(ZX_OK, Graph::Initialize(&graph, flat_topology.data(), flat_topology.size()));

	END_TEST;
	}

	} // namespace

	UNITTEST_START_TESTCASE(x86_topology_tests)
	UNITTEST("Enumerate cpus using data from HP z840.", test_cpus_z840)
	UNITTEST("Enumerate cpus using data from ThreadRipper 2970wx/X399.", test_cpus_2970wx_x399)
	UNITTEST("Enumerate cpus using data triggering fallback.", test_cpus_fallback)
	UNITTEST_END_TESTCASE(x86_topology_tests, "x86_topology",
	"Test determining x86 topology through CPUID/APIC.")