File: cpuid_test.go

package info (click to toggle)
golang-github-klauspost-cpuid 2.3.0-1
links: PTS, VCS
area: main
in suites: experimental, forky, sid
size: 1,280 kB
sloc: asm: 117; sh: 12; makefile: 3
file content (362 lines) | stat: -rw-r--r-- 9,723 bytes
// Copyright (c) 2015 Klaus Post, released under MIT License. See LICENSE file.

package cpuid

import (
	"fmt"
	"reflect"
	"strings"
	"testing"
)

func TestLastID(t *testing.T) {
	if lastID.String() != "lastID" {
		t.Fatal("stringer not updated, run go generate")
	}
}

func TestLastVendorID(t *testing.T) {
	if lastVendor.String() != "lastVendor" {
		t.Fatal("stringer not updated, run go generate")
	}
}

// There is no real way to test a CPU identifier, since results will
// obviously differ on each machine.
func TestCPUID(t *testing.T) {
	Detect()
	n := maxFunctionID()
	t.Logf("Max Function:0x%x", n)
	n = maxExtendedFunction()
	t.Logf("Max Extended Function:0x%x", n)
	t.Log("VendorString:", CPU.VendorString)
	t.Log("VendorID:", CPU.VendorID)
	t.Log("Name:", CPU.BrandName)
	t.Log("PhysicalCores:", CPU.PhysicalCores)
	t.Log("ThreadsPerCore:", CPU.ThreadsPerCore)
	t.Log("LogicalCores:", CPU.LogicalCores)
	t.Log("Family", CPU.Family, "Model:", CPU.Model, "Stepping:", CPU.Stepping)
	t.Log("Features:", strings.Join(CPU.FeatureSet(), ","))
	t.Log("Cacheline bytes:", CPU.CacheLine)
	t.Log("L1 Instruction Cache:", CPU.Cache.L1I, "bytes")
	t.Log("L1 Data Cache:", CPU.Cache.L1D, "bytes")
	t.Log("L2 Cache:", CPU.Cache.L2, "bytes")
	t.Log("L3 Cache:", CPU.Cache.L3, "bytes")
	t.Log("Hz:", CPU.Hz, "Hz")
	t.Log("VM:", CPU.VM())
	t.Log("BoostFreq:", CPU.BoostFreq, "Hz")
}

func TestExample(t *testing.T) {
	Detect()
	// Print basic CPU information:
	fmt.Println("Name:", CPU.BrandName)
	fmt.Println("PhysicalCores:", CPU.PhysicalCores)
	fmt.Println("ThreadsPerCore:", CPU.ThreadsPerCore)
	fmt.Println("LogicalCores:", CPU.LogicalCores)
	fmt.Println("Family", CPU.Family, "Model:", CPU.Model, "Vendor ID:", CPU.VendorID)
	fmt.Println("Features:", strings.Join(CPU.FeatureSet(), ","))
	fmt.Println("Cacheline bytes:", CPU.CacheLine)
	fmt.Println("L1 Data Cache:", CPU.Cache.L1D, "bytes")
	fmt.Println("L1 Instruction Cache:", CPU.Cache.L1D, "bytes")
	fmt.Println("L2 Cache:", CPU.Cache.L2, "bytes")
	fmt.Println("L3 Cache:", CPU.Cache.L3, "bytes")
	fmt.Println("Frequency", CPU.Hz, "hz")

	// Test if we have these specific features:
	if CPU.Supports(SSE, SSE2) {
		fmt.Println("We have Streaming SIMD 2 Extensions")
	}
}
func TestDumpCPUID(t *testing.T) {
	n := int(maxFunctionID())
	for i := 0; i <= n; i++ {
		a, b, c, d := cpuidex(uint32(i), 0)
		t.Logf("CPUID %08x: %08x-%08x-%08x-%08x", i, a, b, c, d)
		ex := uint32(1)
		for {
			a2, b2, c2, d2 := cpuidex(uint32(i), ex)
			if a2 == a && b2 == b && d2 == d || ex > 50 || a2 == 0 {
				break
			}
			t.Logf("CPUID %08x: %08x-%08x-%08x-%08x", i, a2, b2, c2, d2)
			a, b, c, d = a2, b2, c2, d2
			ex++
		}
	}
	n2 := maxExtendedFunction()
	for i := uint32(0x80000000); i <= n2; i++ {
		a, b, c, d := cpuid(i)
		t.Logf("CPUID %08x: %08x-%08x-%08x-%08x", i, a, b, c, d)
	}
}

func Example() {
	// Print basic CPU information:
	fmt.Println("Name:", CPU.BrandName)
	fmt.Println("PhysicalCores:", CPU.PhysicalCores)
	fmt.Println("ThreadsPerCore:", CPU.ThreadsPerCore)
	fmt.Println("LogicalCores:", CPU.LogicalCores)
	fmt.Println("Family", CPU.Family, "Model:", CPU.Model)
	fmt.Println("Features:", CPU.FeatureSet())
	fmt.Println("Cacheline bytes:", CPU.CacheLine)
}

func TestBrandNameZero(t *testing.T) {
	if len(CPU.BrandName) > 0 {
		// Cut out last byte
		last := []byte(CPU.BrandName[len(CPU.BrandName)-1:])
		if last[0] == 0 {
			t.Fatal("last byte was zero")
		} else if last[0] == 32 {
			t.Fatal("whitespace wasn't trimmed")
		}
	}
}

// TestSGX tests SGX detection
func TestSGX(t *testing.T) {
	got := CPU.SGX.Available
	expected := CPU.featureSet.inSet(SGX)
	if got != expected {
		t.Fatalf("SGX: expected %v, got %v", expected, got)
	}
	t.Log("SGX Support:", got)

	if CPU.SGX.Available {
		var total uint64 = 0
		leaves := false
		for _, s := range CPU.SGX.EPCSections {
			t.Logf("SGX EPC section: base address 0x%x, size %v", s.BaseAddress, s.EPCSize)
			total += s.EPCSize
			leaves = true
		}
		if leaves && total == 0 {
			t.Fatal("SGX enabled without any available EPC memory")
		}
	}
}

// TestAMDMemEncryption tests AMDMemEncryption detection
func TestAMDMemEncryption(t *testing.T) {
	got := CPU.AMDMemEncryption.Available
	expected := CPU.featureSet.inSet(SME) || CPU.featureSet.inSet(SEV)
	if got != expected {
		t.Fatalf("AMDMemEncryption: expected %v, got %v", expected, got)
	}
	t.Log("AMDMemEncryption Support:", got)
}

func TestHas(t *testing.T) {
	Detect()
	defer Detect()
	feats := CPU.FeatureSet()
	for _, feat := range feats {
		f := ParseFeature(feat)
		if f == UNKNOWN {
			t.Error("Got unknown feature:", feat)
			continue
		}
		if !CPU.Has(f) {
			t.Error("CPU.Has returned false, want true")
		}
		if !CPU.Supports(f) {
			t.Error("CPU.Supports returned false, want true")
		}
		// Disable it.
		CPU.Disable(f)
		if CPU.Has(f) {
			t.Error("CPU.Has returned true, want false")
		}
		if CPU.Supports(f) {
			t.Error("CPU.Supports returned true, want false")
		}
		// Reenable
		CPU.Enable(f)
		if !CPU.Has(f) {
			t.Error("CPU.Has returned false, want true")
		}
		if !CPU.Supports(f) {
			t.Error("CPU.Supports returned false, want true")
		}
	}
}

// TestSGXLC tests SGX Launch Control detection
func TestSGXLC(t *testing.T) {
	got := CPU.SGX.LaunchControl
	expected := CPU.featureSet.inSet(SGXLC)
	if got != expected {
		t.Fatalf("SGX: expected %v, got %v", expected, got)
	}
	t.Log("SGX Launch Control Support:", got)
}

// Test VM function
func TestVM(t *testing.T) {
	got := CPU.VM()
	expected := CPU.featureSet.inSet(HYPERVISOR)
	if got != expected {
		t.Fatalf("TestVM: expected %v, got %v", expected, got)
	}
	t.Log("TestVM:", got)
}

// Test RTCounter function
func TestRtCounter(t *testing.T) {
	a := CPU.RTCounter()
	b := CPU.RTCounter()
	t.Log("CPU Counter:", a, b, b-a)
}

// Prints the value of Ia32TscAux()
func TestIa32TscAux(t *testing.T) {
	ecx := CPU.Ia32TscAux()
	t.Logf("Ia32TscAux:0x%x\n", ecx)
	if ecx != 0 {
		chip := (ecx & 0xFFF000) >> 12
		core := ecx & 0xFFF
		t.Log("Likely chip, core:", chip, core)
	}
}

func TestThreadsPerCoreNZ(t *testing.T) {
	if CPU.ThreadsPerCore == 0 {
		t.Fatal("threads per core is zero")
	}
}

// Prints the value of LogicalCPU()
func TestLogicalCPU(t *testing.T) {
	t.Log("Currently executing on cpu:", CPU.LogicalCPU())
}

func TestMaxFunction(t *testing.T) {
	expect := maxFunctionID()
	if CPU.maxFunc != expect {
		t.Fatal("Max function does not match, expected", expect, "but got", CPU.maxFunc)
	}
	expect = maxExtendedFunction()
	if CPU.maxExFunc != expect {
		t.Fatal("Max Extended function does not match, expected", expect, "but got", CPU.maxFunc)
	}
}

// This example will calculate the chip/core number on Linux
// Linux encodes numa id (<<12) and core id (8bit) into TSC_AUX.
func ExampleCPUInfo_Ia32TscAux() {
	ecx := CPU.Ia32TscAux()
	if ecx == 0 {
		fmt.Println("Unknown CPU ID")
		return
	}
	chip := (ecx & 0xFFF000) >> 12
	core := ecx & 0xFFF
	fmt.Println("Chip, Core:", chip, core)
}

func TestCombineFeatures(t *testing.T) {
	cpu := CPU
	for i := FeatureID(0); i < lastID; i++ {
		if cpu.Has(i) != cpu.HasAll(CombineFeatures(i)) {
			t.Errorf("id %d:%s mismatch", i, i.String())
		}
	}
}

// PMU test
func TestParseLeaf0AH(t *testing.T) {
	var fixedCounters3 flagSet
	var fixedCounters4 flagSet
	fixedCounters3.setIf(true, PMU_FIXEDCOUNTER_CYCLES, PMU_FIXEDCOUNTER_INSTRUCTIONS, PMU_FIXEDCOUNTER_REFCYCLES)
	fixedCounters4.setIf(true, PMU_FIXEDCOUNTER_CYCLES, PMU_FIXEDCOUNTER_INSTRUCTIONS, PMU_FIXEDCOUNTER_REFCYCLES, PMU_FIXEDCOUNTER_TOPDOWN_SLOTS)
	testCases := []struct {
		name         string
		eax          uint32
		ebx          uint32
		edx          uint32
		wantPMU      PerformanceMonitoringInfo
		wantFeatures flagSet
	}{
		{
			name:    "eax_is_zero",
			eax:     0,
			ebx:     0,
			edx:     0,
			wantPMU: PerformanceMonitoringInfo{},
		},
		{
			name: "v4, 3 fixed counters, 4 GP",
			eax:  0x7300404,
			ebx:  0x0,
			edx:  0x603,
			wantPMU: PerformanceMonitoringInfo{
				VersionID:     4,
				GPPMCWidth:    48,
				NumGPCounters: 4,
				NumFixedPMC:   3,
				FixedPMCWidth: 48,
			},
			wantFeatures: fixedCounters3,
		},
		{
			name: "v2, 4 fixed counters, 8 GP",
			eax:  0x8300802,
			ebx:  0x0,
			edx:  0x604,
			wantPMU: PerformanceMonitoringInfo{
				VersionID:     2,
				GPPMCWidth:    48,
				NumGPCounters: 8,
				NumFixedPMC:   4,
				FixedPMCWidth: 48,
			},
			wantFeatures: fixedCounters4,
		},
	}
	for _, tc := range testCases {
		var cpu CPUInfo
		tc.wantPMU.RawEAX = tc.eax
		tc.wantPMU.RawEBX = tc.ebx
		tc.wantPMU.RawEDX = tc.edx
		got := parseLeaf0AH(&cpu, tc.eax, tc.ebx, tc.edx)
		if !reflect.DeepEqual(tc.wantPMU, got) {
			t.Fatalf("PMU mismatch want: %v got: %v", tc.wantPMU, got)
		}
		if !cpu.featureSet.hasSet(tc.wantFeatures) {
			t.Fatalf("featureSet mismatch want: %v got: %v", tc.wantFeatures.Strings(), cpu.featureSet.Strings())
		}
	}

}

func BenchmarkFlags(b *testing.B) {
	var a bool
	var cpu = CPU
	b.Run("ids", func(b *testing.B) {
		for i := 0; i < b.N; i++ {
			a = cpu.Supports(CMOV, CMPXCHG8, X87, FXSR, MMX, SYSCALL, SSE, SSE2, CX16, LAHF, POPCNT, SSE3, SSE4, SSE42, SSSE3, AVX, AVX2, BMI1, BMI2, F16C, FMA3, LZCNT, MOVBE, OSXSAVE) || a
		}
		_ = a
	})
	b.Run("features", func(b *testing.B) {
		f := CombineFeatures(CMOV, CMPXCHG8, X87, FXSR, MMX, SYSCALL, SSE, SSE2, CX16, LAHF, POPCNT, SSE3, SSE4, SSE42, SSSE3, AVX, AVX2, BMI1, BMI2, F16C, FMA3, LZCNT, MOVBE, OSXSAVE)
		for i := 0; i < b.N; i++ {
			a = cpu.HasAll(f) || a
		}
		_ = a
	})
	b.Run("id", func(b *testing.B) {
		for i := 0; i < b.N; i++ {
			a = cpu.Has(CMOV) || a
		}
		_ = a
	})
	b.Run("feature", func(b *testing.B) {
		f := CombineFeatures(CMOV)
		for i := 0; i < b.N; i++ {
			a = cpu.HasAll(f) || a
		}
		_ = a
	})
}