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authorHaibo Xu <haibo.xu@arm.com>2019-10-25 03:09:59 +0000
committerHaibo Xu <haibo.xu@arm.com>2020-02-10 02:46:05 +0000
commit9cbf5a3dcc71d85cd857f117d4b7189a101be9c1 (patch)
tree19227da9f4b907bca43d4a7014407d144a9ff081 /pkg/cpuid/cpuid_x86.go
parent17b9f5e66238bde1e4ed3bd9e5fb67342c8b58ec (diff)
Enable pkg/cpuid support on arm64.
Fixes #1255 Signed-off-by: Haibo Xu <haibo.xu@arm.com> Change-Id: I8614e6f3ee321c2989567e4e712aa8f28cc9db14
Diffstat (limited to 'pkg/cpuid/cpuid_x86.go')
-rw-r--r--pkg/cpuid/cpuid_x86.go1100
1 files changed, 1100 insertions, 0 deletions
diff --git a/pkg/cpuid/cpuid_x86.go b/pkg/cpuid/cpuid_x86.go
new file mode 100644
index 000000000..333ca0a04
--- /dev/null
+++ b/pkg/cpuid/cpuid_x86.go
@@ -0,0 +1,1100 @@
+// Copyright 2019 The gVisor Authors.
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// +build i386 amd64
+
+package cpuid
+
+import (
+ "bytes"
+ "fmt"
+ "io/ioutil"
+ "strconv"
+ "strings"
+
+ "gvisor.dev/gvisor/pkg/log"
+)
+
+// Common references for CPUID leaves and bits:
+//
+// Intel:
+// * Intel SDM Volume 2, Chapter 3.2 "CPUID" (more up-to-date)
+// * Intel Application Note 485 (more detailed)
+//
+// AMD:
+// * AMD64 APM Volume 3, Appendix 3 "Obtaining Processor Information ..."
+
+// block is a collection of 32 Feature bits.
+type block int
+
+const blockSize = 32
+
+// Feature bits are numbered according to "blocks". Each block is 32 bits, and
+// feature bits from the same source (cpuid leaf/level) are in the same block.
+func featureID(b block, bit int) Feature {
+ return Feature(32*int(b) + bit)
+}
+
+// Block 0 constants are all of the "basic" feature bits returned by a cpuid in
+// ecx with eax=1.
+const (
+ X86FeatureSSE3 Feature = iota
+ X86FeaturePCLMULDQ
+ X86FeatureDTES64
+ X86FeatureMONITOR
+ X86FeatureDSCPL
+ X86FeatureVMX
+ X86FeatureSMX
+ X86FeatureEST
+ X86FeatureTM2
+ X86FeatureSSSE3 // Not a typo, "supplemental" SSE3.
+ X86FeatureCNXTID
+ X86FeatureSDBG
+ X86FeatureFMA
+ X86FeatureCX16
+ X86FeatureXTPR
+ X86FeaturePDCM
+ _ // ecx bit 16 is reserved.
+ X86FeaturePCID
+ X86FeatureDCA
+ X86FeatureSSE4_1
+ X86FeatureSSE4_2
+ X86FeatureX2APIC
+ X86FeatureMOVBE
+ X86FeaturePOPCNT
+ X86FeatureTSCD
+ X86FeatureAES
+ X86FeatureXSAVE
+ X86FeatureOSXSAVE
+ X86FeatureAVX
+ X86FeatureF16C
+ X86FeatureRDRAND
+ _ // ecx bit 31 is reserved.
+)
+
+// Block 1 constants are all of the "basic" feature bits returned by a cpuid in
+// edx with eax=1.
+const (
+ X86FeatureFPU Feature = 32 + iota
+ X86FeatureVME
+ X86FeatureDE
+ X86FeaturePSE
+ X86FeatureTSC
+ X86FeatureMSR
+ X86FeaturePAE
+ X86FeatureMCE
+ X86FeatureCX8
+ X86FeatureAPIC
+ _ // edx bit 10 is reserved.
+ X86FeatureSEP
+ X86FeatureMTRR
+ X86FeaturePGE
+ X86FeatureMCA
+ X86FeatureCMOV
+ X86FeaturePAT
+ X86FeaturePSE36
+ X86FeaturePSN
+ X86FeatureCLFSH
+ _ // edx bit 20 is reserved.
+ X86FeatureDS
+ X86FeatureACPI
+ X86FeatureMMX
+ X86FeatureFXSR
+ X86FeatureSSE
+ X86FeatureSSE2
+ X86FeatureSS
+ X86FeatureHTT
+ X86FeatureTM
+ X86FeatureIA64
+ X86FeaturePBE
+)
+
+// Block 2 bits are the "structured extended" features returned in ebx for
+// eax=7, ecx=0.
+const (
+ X86FeatureFSGSBase Feature = 2*32 + iota
+ X86FeatureTSC_ADJUST
+ _ // ebx bit 2 is reserved.
+ X86FeatureBMI1
+ X86FeatureHLE
+ X86FeatureAVX2
+ X86FeatureFDP_EXCPTN_ONLY
+ X86FeatureSMEP
+ X86FeatureBMI2
+ X86FeatureERMS
+ X86FeatureINVPCID
+ X86FeatureRTM
+ X86FeatureCQM
+ X86FeatureFPCSDS
+ X86FeatureMPX
+ X86FeatureRDT
+ X86FeatureAVX512F
+ X86FeatureAVX512DQ
+ X86FeatureRDSEED
+ X86FeatureADX
+ X86FeatureSMAP
+ X86FeatureAVX512IFMA
+ X86FeaturePCOMMIT
+ X86FeatureCLFLUSHOPT
+ X86FeatureCLWB
+ X86FeatureIPT // Intel processor trace.
+ X86FeatureAVX512PF
+ X86FeatureAVX512ER
+ X86FeatureAVX512CD
+ X86FeatureSHA
+ X86FeatureAVX512BW
+ X86FeatureAVX512VL
+)
+
+// Block 3 bits are the "extended" features returned in ecx for eax=7, ecx=0.
+const (
+ X86FeaturePREFETCHWT1 Feature = 3*32 + iota
+ X86FeatureAVX512VBMI
+ X86FeatureUMIP
+ X86FeaturePKU
+ X86FeatureOSPKE
+ X86FeatureWAITPKG
+ X86FeatureAVX512_VBMI2
+ _ // ecx bit 7 is reserved
+ X86FeatureGFNI
+ X86FeatureVAES
+ X86FeatureVPCLMULQDQ
+ X86FeatureAVX512_VNNI
+ X86FeatureAVX512_BITALG
+ X86FeatureTME
+ X86FeatureAVX512_VPOPCNTDQ
+ _ // ecx bit 15 is reserved
+ X86FeatureLA57
+ // ecx bits 17-21 are reserved
+ _
+ _
+ _
+ _
+ _
+ X86FeatureRDPID
+ // ecx bits 23-24 are reserved
+ _
+ _
+ X86FeatureCLDEMOTE
+ _ // ecx bit 26 is reserved
+ X86FeatureMOVDIRI
+ X86FeatureMOVDIR64B
+)
+
+// Block 4 constants are for xsave capabilities in CPUID.(EAX=0DH,ECX=01H):EAX.
+// The CPUID leaf is available only if 'X86FeatureXSAVE' is present.
+const (
+ X86FeatureXSAVEOPT Feature = 4*32 + iota
+ X86FeatureXSAVEC
+ X86FeatureXGETBV1
+ X86FeatureXSAVES
+ // EAX[31:4] are reserved.
+)
+
+// Block 5 constants are the extended feature bits in
+// CPUID.(EAX=0x80000001):ECX.
+const (
+ X86FeatureLAHF64 Feature = 5*32 + iota
+ X86FeatureCMP_LEGACY
+ X86FeatureSVM
+ X86FeatureEXTAPIC
+ X86FeatureCR8_LEGACY
+ X86FeatureLZCNT
+ X86FeatureSSE4A
+ X86FeatureMISALIGNSSE
+ X86FeaturePREFETCHW
+ X86FeatureOSVW
+ X86FeatureIBS
+ X86FeatureXOP
+ X86FeatureSKINIT
+ X86FeatureWDT
+ _ // ecx bit 14 is reserved.
+ X86FeatureLWP
+ X86FeatureFMA4
+ X86FeatureTCE
+ _ // ecx bit 18 is reserved.
+ _ // ecx bit 19 is reserved.
+ _ // ecx bit 20 is reserved.
+ X86FeatureTBM
+ X86FeatureTOPOLOGY
+ X86FeaturePERFCTR_CORE
+ X86FeaturePERFCTR_NB
+ _ // ecx bit 25 is reserved.
+ X86FeatureBPEXT
+ X86FeaturePERFCTR_TSC
+ X86FeaturePERFCTR_LLC
+ X86FeatureMWAITX
+ // ECX[31:30] are reserved.
+)
+
+// Block 6 constants are the extended feature bits in
+// CPUID.(EAX=0x80000001):EDX.
+//
+// These are sparse, and so the bit positions are assigned manually.
+const (
+ // On AMD, EDX[24:23] | EDX[17:12] | EDX[9:0] are duplicate features
+ // also defined in block 1 (in identical bit positions). Those features
+ // are not listed here.
+ block6DuplicateMask = 0x183f3ff
+
+ X86FeatureSYSCALL Feature = 6*32 + 11
+ X86FeatureNX Feature = 6*32 + 20
+ X86FeatureMMXEXT Feature = 6*32 + 22
+ X86FeatureFXSR_OPT Feature = 6*32 + 25
+ X86FeatureGBPAGES Feature = 6*32 + 26
+ X86FeatureRDTSCP Feature = 6*32 + 27
+ X86FeatureLM Feature = 6*32 + 29
+ X86Feature3DNOWEXT Feature = 6*32 + 30
+ X86Feature3DNOW Feature = 6*32 + 31
+)
+
+// linuxBlockOrder defines the order in which linux organizes the feature
+// blocks. Linux also tracks feature bits in 32-bit blocks, but in an order
+// which doesn't match well here, so for the /proc/cpuinfo generation we simply
+// re-map the blocks to Linux's ordering and then go through the bits in each
+// block.
+var linuxBlockOrder = []block{1, 6, 0, 5, 2, 4, 3}
+
+// To make emulation of /proc/cpuinfo easy, these names match the names of the
+// basic features in Linux defined in arch/x86/kernel/cpu/capflags.c.
+var x86FeatureStrings = map[Feature]string{
+ // Block 0.
+ X86FeatureSSE3: "pni",
+ X86FeaturePCLMULDQ: "pclmulqdq",
+ X86FeatureDTES64: "dtes64",
+ X86FeatureMONITOR: "monitor",
+ X86FeatureDSCPL: "ds_cpl",
+ X86FeatureVMX: "vmx",
+ X86FeatureSMX: "smx",
+ X86FeatureEST: "est",
+ X86FeatureTM2: "tm2",
+ X86FeatureSSSE3: "ssse3",
+ X86FeatureCNXTID: "cid",
+ X86FeatureSDBG: "sdbg",
+ X86FeatureFMA: "fma",
+ X86FeatureCX16: "cx16",
+ X86FeatureXTPR: "xtpr",
+ X86FeaturePDCM: "pdcm",
+ X86FeaturePCID: "pcid",
+ X86FeatureDCA: "dca",
+ X86FeatureSSE4_1: "sse4_1",
+ X86FeatureSSE4_2: "sse4_2",
+ X86FeatureX2APIC: "x2apic",
+ X86FeatureMOVBE: "movbe",
+ X86FeaturePOPCNT: "popcnt",
+ X86FeatureTSCD: "tsc_deadline_timer",
+ X86FeatureAES: "aes",
+ X86FeatureXSAVE: "xsave",
+ X86FeatureAVX: "avx",
+ X86FeatureF16C: "f16c",
+ X86FeatureRDRAND: "rdrand",
+
+ // Block 1.
+ X86FeatureFPU: "fpu",
+ X86FeatureVME: "vme",
+ X86FeatureDE: "de",
+ X86FeaturePSE: "pse",
+ X86FeatureTSC: "tsc",
+ X86FeatureMSR: "msr",
+ X86FeaturePAE: "pae",
+ X86FeatureMCE: "mce",
+ X86FeatureCX8: "cx8",
+ X86FeatureAPIC: "apic",
+ X86FeatureSEP: "sep",
+ X86FeatureMTRR: "mtrr",
+ X86FeaturePGE: "pge",
+ X86FeatureMCA: "mca",
+ X86FeatureCMOV: "cmov",
+ X86FeaturePAT: "pat",
+ X86FeaturePSE36: "pse36",
+ X86FeaturePSN: "pn",
+ X86FeatureCLFSH: "clflush",
+ X86FeatureDS: "dts",
+ X86FeatureACPI: "acpi",
+ X86FeatureMMX: "mmx",
+ X86FeatureFXSR: "fxsr",
+ X86FeatureSSE: "sse",
+ X86FeatureSSE2: "sse2",
+ X86FeatureSS: "ss",
+ X86FeatureHTT: "ht",
+ X86FeatureTM: "tm",
+ X86FeatureIA64: "ia64",
+ X86FeaturePBE: "pbe",
+
+ // Block 2.
+ X86FeatureFSGSBase: "fsgsbase",
+ X86FeatureTSC_ADJUST: "tsc_adjust",
+ X86FeatureBMI1: "bmi1",
+ X86FeatureHLE: "hle",
+ X86FeatureAVX2: "avx2",
+ X86FeatureSMEP: "smep",
+ X86FeatureBMI2: "bmi2",
+ X86FeatureERMS: "erms",
+ X86FeatureINVPCID: "invpcid",
+ X86FeatureRTM: "rtm",
+ X86FeatureCQM: "cqm",
+ X86FeatureMPX: "mpx",
+ X86FeatureRDT: "rdt_a",
+ X86FeatureAVX512F: "avx512f",
+ X86FeatureAVX512DQ: "avx512dq",
+ X86FeatureRDSEED: "rdseed",
+ X86FeatureADX: "adx",
+ X86FeatureSMAP: "smap",
+ X86FeatureCLWB: "clwb",
+ X86FeatureAVX512PF: "avx512pf",
+ X86FeatureAVX512ER: "avx512er",
+ X86FeatureAVX512CD: "avx512cd",
+ X86FeatureSHA: "sha_ni",
+ X86FeatureAVX512BW: "avx512bw",
+ X86FeatureAVX512VL: "avx512vl",
+
+ // Block 3.
+ X86FeatureAVX512VBMI: "avx512vbmi",
+ X86FeatureUMIP: "umip",
+ X86FeaturePKU: "pku",
+ X86FeatureOSPKE: "ospke",
+ X86FeatureWAITPKG: "waitpkg",
+ X86FeatureAVX512_VBMI2: "avx512_vbmi2",
+ X86FeatureGFNI: "gfni",
+ X86FeatureVAES: "vaes",
+ X86FeatureVPCLMULQDQ: "vpclmulqdq",
+ X86FeatureAVX512_VNNI: "avx512_vnni",
+ X86FeatureAVX512_BITALG: "avx512_bitalg",
+ X86FeatureTME: "tme",
+ X86FeatureAVX512_VPOPCNTDQ: "avx512_vpopcntdq",
+ X86FeatureLA57: "la57",
+ X86FeatureRDPID: "rdpid",
+ X86FeatureCLDEMOTE: "cldemote",
+ X86FeatureMOVDIRI: "movdiri",
+ X86FeatureMOVDIR64B: "movdir64b",
+
+ // Block 4.
+ X86FeatureXSAVEOPT: "xsaveopt",
+ X86FeatureXSAVEC: "xsavec",
+ X86FeatureXGETBV1: "xgetbv1",
+ X86FeatureXSAVES: "xsaves",
+
+ // Block 5.
+ X86FeatureLAHF64: "lahf_lm", // LAHF/SAHF in long mode
+ X86FeatureCMP_LEGACY: "cmp_legacy",
+ X86FeatureSVM: "svm",
+ X86FeatureEXTAPIC: "extapic",
+ X86FeatureCR8_LEGACY: "cr8_legacy",
+ X86FeatureLZCNT: "abm", // Advanced bit manipulation
+ X86FeatureSSE4A: "sse4a",
+ X86FeatureMISALIGNSSE: "misalignsse",
+ X86FeaturePREFETCHW: "3dnowprefetch",
+ X86FeatureOSVW: "osvw",
+ X86FeatureIBS: "ibs",
+ X86FeatureXOP: "xop",
+ X86FeatureSKINIT: "skinit",
+ X86FeatureWDT: "wdt",
+ X86FeatureLWP: "lwp",
+ X86FeatureFMA4: "fma4",
+ X86FeatureTCE: "tce",
+ X86FeatureTBM: "tbm",
+ X86FeatureTOPOLOGY: "topoext",
+ X86FeaturePERFCTR_CORE: "perfctr_core",
+ X86FeaturePERFCTR_NB: "perfctr_nb",
+ X86FeatureBPEXT: "bpext",
+ X86FeaturePERFCTR_TSC: "ptsc",
+ X86FeaturePERFCTR_LLC: "perfctr_llc",
+ X86FeatureMWAITX: "mwaitx",
+
+ // Block 6.
+ X86FeatureSYSCALL: "syscall",
+ X86FeatureNX: "nx",
+ X86FeatureMMXEXT: "mmxext",
+ X86FeatureFXSR_OPT: "fxsr_opt",
+ X86FeatureGBPAGES: "pdpe1gb",
+ X86FeatureRDTSCP: "rdtscp",
+ X86FeatureLM: "lm",
+ X86Feature3DNOWEXT: "3dnowext",
+ X86Feature3DNOW: "3dnow",
+}
+
+// These flags are parse only---they can be used for setting / unsetting the
+// flags, but will not get printed out in /proc/cpuinfo.
+var x86FeatureParseOnlyStrings = map[Feature]string{
+ // Block 0.
+ X86FeatureOSXSAVE: "osxsave",
+
+ // Block 2.
+ X86FeatureFDP_EXCPTN_ONLY: "fdp_excptn_only",
+ X86FeatureFPCSDS: "fpcsds",
+ X86FeatureIPT: "pt",
+ X86FeatureCLFLUSHOPT: "clfushopt",
+
+ // Block 3.
+ X86FeaturePREFETCHWT1: "prefetchwt1",
+}
+
+// intelCacheDescriptors describe the caches and TLBs on the system. They are
+// returned in the registers for eax=2. Intel only.
+type intelCacheDescriptor uint8
+
+// Valid cache/TLB descriptors. All descriptors can be found in Intel SDM Vol.
+// 2, Ch. 3.2, "CPUID", Table 3-12 "Encoding of CPUID Leaf 2 Descriptors".
+const (
+ intelNullDescriptor intelCacheDescriptor = 0
+ intelNoTLBDescriptor intelCacheDescriptor = 0xfe
+ intelNoCacheDescriptor intelCacheDescriptor = 0xff
+
+ // Most descriptors omitted for brevity as they are currently unused.
+)
+
+// CacheType describes the type of a cache, as returned in eax[4:0] for eax=4.
+type CacheType uint8
+
+const (
+ // cacheNull indicates that there are no more entries.
+ cacheNull CacheType = iota
+
+ // CacheData is a data cache.
+ CacheData
+
+ // CacheInstruction is an instruction cache.
+ CacheInstruction
+
+ // CacheUnified is a unified instruction and data cache.
+ CacheUnified
+)
+
+// Cache describes the parameters of a single cache on the system.
+//
+// +stateify savable
+type Cache struct {
+ // Level is the hierarchical level of this cache (L1, L2, etc).
+ Level uint32
+
+ // Type is the type of cache.
+ Type CacheType
+
+ // FullyAssociative indicates that entries may be placed in any block.
+ FullyAssociative bool
+
+ // Partitions is the number of physical partitions in the cache.
+ Partitions uint32
+
+ // Ways is the number of ways of associativity in the cache.
+ Ways uint32
+
+ // Sets is the number of sets in the cache.
+ Sets uint32
+
+ // InvalidateHierarchical indicates that WBINVD/INVD from threads
+ // sharing this cache acts upon lower level caches for threads sharing
+ // this cache.
+ InvalidateHierarchical bool
+
+ // Inclusive indicates that this cache is inclusive of lower cache
+ // levels.
+ Inclusive bool
+
+ // DirectMapped indicates that this cache is directly mapped from
+ // address, rather than using a hash function.
+ DirectMapped bool
+}
+
+// Just a way to wrap cpuid function numbers.
+type cpuidFunction uint32
+
+// The constants below are the lower or "standard" cpuid functions, ordered as
+// defined by the hardware.
+const (
+ vendorID cpuidFunction = iota // Returns vendor ID and largest standard function.
+ featureInfo // Returns basic feature bits and processor signature.
+ intelCacheDescriptors // Returns list of cache descriptors. Intel only.
+ intelSerialNumber // Returns processor serial number (obsolete on new hardware). Intel only.
+ intelDeterministicCacheParams // Returns deterministic cache information. Intel only.
+ monitorMwaitParams // Returns information about monitor/mwait instructions.
+ powerParams // Returns information about power management and thermal sensors.
+ extendedFeatureInfo // Returns extended feature bits.
+ _ // Function 0x8 is reserved.
+ intelDCAParams // Returns direct cache access information. Intel only.
+ intelPMCInfo // Returns information about performance monitoring features. Intel only.
+ intelX2APICInfo // Returns core/logical processor topology. Intel only.
+ _ // Function 0xc is reserved.
+ xSaveInfo // Returns information about extended state management.
+)
+
+// The "extended" functions start at 0x80000000.
+const (
+ extendedFunctionInfo cpuidFunction = 0x80000000 + iota // Returns highest available extended function in eax.
+ extendedFeatures // Returns some extended feature bits in edx and ecx.
+)
+
+// These are the extended floating point state features. They are used to
+// enumerate floating point features in XCR0, XSTATE_BV, etc.
+const (
+ XSAVEFeatureX87 = 1 << 0
+ XSAVEFeatureSSE = 1 << 1
+ XSAVEFeatureAVX = 1 << 2
+ XSAVEFeatureBNDREGS = 1 << 3
+ XSAVEFeatureBNDCSR = 1 << 4
+ XSAVEFeatureAVX512op = 1 << 5
+ XSAVEFeatureAVX512zmm0 = 1 << 6
+ XSAVEFeatureAVX512zmm16 = 1 << 7
+ XSAVEFeaturePKRU = 1 << 9
+)
+
+var cpuFreqMHz float64
+
+// x86FeaturesFromString includes features from x86FeatureStrings and
+// x86FeatureParseOnlyStrings.
+var x86FeaturesFromString = make(map[string]Feature)
+
+// FeatureFromString returns the Feature associated with the given feature
+// string plus a bool to indicate if it could find the feature.
+func FeatureFromString(s string) (Feature, bool) {
+ f, b := x86FeaturesFromString[s]
+ return f, b
+}
+
+// String implements fmt.Stringer.
+func (f Feature) String() string {
+ if s := f.flagString(false); s != "" {
+ return s
+ }
+
+ block := int(f) / 32
+ bit := int(f) % 32
+ return fmt.Sprintf("<cpuflag %d; block %d bit %d>", f, block, bit)
+}
+
+func (f Feature) flagString(cpuinfoOnly bool) string {
+ if s, ok := x86FeatureStrings[f]; ok {
+ return s
+ }
+ if !cpuinfoOnly {
+ return x86FeatureParseOnlyStrings[f]
+ }
+ return ""
+}
+
+// FeatureSet is a set of Features for a CPU.
+//
+// +stateify savable
+type FeatureSet struct {
+ // Set is the set of features that are enabled in this FeatureSet.
+ Set map[Feature]bool
+
+ // VendorID is the 12-char string returned in ebx:edx:ecx for eax=0.
+ VendorID string
+
+ // ExtendedFamily is part of the processor signature.
+ ExtendedFamily uint8
+
+ // ExtendedModel is part of the processor signature.
+ ExtendedModel uint8
+
+ // ProcessorType is part of the processor signature.
+ ProcessorType uint8
+
+ // Family is part of the processor signature.
+ Family uint8
+
+ // Model is part of the processor signature.
+ Model uint8
+
+ // SteppingID is part of the processor signature.
+ SteppingID uint8
+
+ // Caches describes the caches on the CPU.
+ Caches []Cache
+
+ // CacheLine is the size of a cache line in bytes.
+ //
+ // All caches use the same line size. This is not enforced in the CPUID
+ // encoding, but is true on all known x86 processors.
+ CacheLine uint32
+}
+
+// FlagsString prints out supported CPU flags. If cpuinfoOnly is true, it is
+// equivalent to the "flags" field in /proc/cpuinfo.
+func (fs *FeatureSet) FlagsString(cpuinfoOnly bool) string {
+ var s []string
+ for _, b := range linuxBlockOrder {
+ for i := 0; i < blockSize; i++ {
+ if f := featureID(b, i); fs.Set[f] {
+ if fstr := f.flagString(cpuinfoOnly); fstr != "" {
+ s = append(s, fstr)
+ }
+ }
+ }
+ }
+ return strings.Join(s, " ")
+}
+
+// WriteCPUInfoTo is to generate a section of one cpu in /proc/cpuinfo. This is
+// a minimal /proc/cpuinfo, it is missing some fields like "microcode" that are
+// not always printed in Linux. The bogomips field is simply made up.
+func (fs FeatureSet) WriteCPUInfoTo(cpu uint, b *bytes.Buffer) {
+ fmt.Fprintf(b, "processor\t: %d\n", cpu)
+ fmt.Fprintf(b, "vendor_id\t: %s\n", fs.VendorID)
+ fmt.Fprintf(b, "cpu family\t: %d\n", ((fs.ExtendedFamily<<4)&0xff)|fs.Family)
+ fmt.Fprintf(b, "model\t\t: %d\n", ((fs.ExtendedModel<<4)&0xff)|fs.Model)
+ fmt.Fprintf(b, "model name\t: %s\n", "unknown") // Unknown for now.
+ fmt.Fprintf(b, "stepping\t: %s\n", "unknown") // Unknown for now.
+ fmt.Fprintf(b, "cpu MHz\t\t: %.3f\n", cpuFreqMHz)
+ fmt.Fprintln(b, "fpu\t\t: yes")
+ fmt.Fprintln(b, "fpu_exception\t: yes")
+ fmt.Fprintf(b, "cpuid level\t: %d\n", uint32(xSaveInfo)) // Same as ax in vendorID.
+ fmt.Fprintln(b, "wp\t\t: yes")
+ fmt.Fprintf(b, "flags\t\t: %s\n", fs.FlagsString(true))
+ fmt.Fprintf(b, "bogomips\t: %.02f\n", cpuFreqMHz) // It's bogus anyway.
+ fmt.Fprintf(b, "clflush size\t: %d\n", fs.CacheLine)
+ fmt.Fprintf(b, "cache_alignment\t: %d\n", fs.CacheLine)
+ fmt.Fprintf(b, "address sizes\t: %d bits physical, %d bits virtual\n", 46, 48)
+ fmt.Fprintln(b, "power management:") // This is always here, but can be blank.
+ fmt.Fprintln(b, "") // The /proc/cpuinfo file ends with an extra newline.
+}
+
+const (
+ amdVendorID = "AuthenticAMD"
+ intelVendorID = "GenuineIntel"
+)
+
+// AMD returns true if fs describes an AMD CPU.
+func (fs *FeatureSet) AMD() bool {
+ return fs.VendorID == amdVendorID
+}
+
+// Intel returns true if fs describes an Intel CPU.
+func (fs *FeatureSet) Intel() bool {
+ return fs.VendorID == intelVendorID
+}
+
+// ErrIncompatible is returned by FeatureSet.HostCompatible if fs is not a
+// subset of the host feature set.
+type ErrIncompatible struct {
+ message string
+}
+
+// Error implements error.
+func (e ErrIncompatible) Error() string {
+ return e.message
+}
+
+// CheckHostCompatible returns nil if fs is a subset of the host feature set.
+func (fs *FeatureSet) CheckHostCompatible() error {
+ hfs := HostFeatureSet()
+
+ if diff := fs.Subtract(hfs); diff != nil {
+ return ErrIncompatible{fmt.Sprintf("CPU feature set %v incompatible with host feature set %v (missing: %v)", fs.FlagsString(false), hfs.FlagsString(false), diff)}
+ }
+
+ // The size of a cache line must match, as it is critical to correctly
+ // utilizing CLFLUSH. Other cache properties are allowed to change, as
+ // they are not important to correctness.
+ if fs.CacheLine != hfs.CacheLine {
+ return ErrIncompatible{fmt.Sprintf("CPU cache line size %d incompatible with host cache line size %d", fs.CacheLine, hfs.CacheLine)}
+ }
+
+ return nil
+}
+
+// Helper to convert 3 regs into 12-byte vendor ID.
+func vendorIDFromRegs(bx, cx, dx uint32) string {
+ bytes := make([]byte, 0, 12)
+ for i := uint(0); i < 4; i++ {
+ b := byte(bx >> (i * 8))
+ bytes = append(bytes, b)
+ }
+
+ for i := uint(0); i < 4; i++ {
+ b := byte(dx >> (i * 8))
+ bytes = append(bytes, b)
+ }
+
+ for i := uint(0); i < 4; i++ {
+ b := byte(cx >> (i * 8))
+ bytes = append(bytes, b)
+ }
+ return string(bytes)
+}
+
+// ExtendedStateSize returns the number of bytes needed to save the "extended
+// state" for this processor and the boundary it must be aligned to. Extended
+// state includes floating point registers, and other cpu state that's not
+// associated with the normal task context.
+//
+// Note: We can save some space here with an optimization where we use a
+// smaller chunk of memory depending on features that are actually enabled.
+// Currently we just use the largest possible size for simplicity (which is
+// about 2.5K worst case, with avx512).
+func (fs *FeatureSet) ExtendedStateSize() (size, align uint) {
+ if fs.UseXsave() {
+ // Leaf 0 of xsaveinfo function returns the size for currently
+ // enabled xsave features in ebx, the maximum size if all valid
+ // features are saved with xsave in ecx, and valid XCR0 bits in
+ // edx:eax.
+ _, _, maxSize, _ := HostID(uint32(xSaveInfo), 0)
+ return uint(maxSize), 64
+ }
+
+ // If we don't support xsave, we fall back to fxsave, which requires
+ // 512 bytes aligned to 16 bytes.
+ return 512, 16
+}
+
+// ValidXCR0Mask returns the bits that may be set to 1 in control register
+// XCR0.
+func (fs *FeatureSet) ValidXCR0Mask() uint64 {
+ if !fs.UseXsave() {
+ return 0
+ }
+ eax, _, _, edx := HostID(uint32(xSaveInfo), 0)
+ return uint64(edx)<<32 | uint64(eax)
+}
+
+// vendorIDRegs returns the 3 register values used to construct the 12-byte
+// vendor ID string for eax=0.
+func (fs *FeatureSet) vendorIDRegs() (bx, dx, cx uint32) {
+ for i := uint(0); i < 4; i++ {
+ bx |= uint32(fs.VendorID[i]) << (i * 8)
+ }
+
+ for i := uint(0); i < 4; i++ {
+ dx |= uint32(fs.VendorID[i+4]) << (i * 8)
+ }
+
+ for i := uint(0); i < 4; i++ {
+ cx |= uint32(fs.VendorID[i+8]) << (i * 8)
+ }
+ return
+}
+
+// signature returns the signature dword that's returned in eax when eax=1.
+func (fs *FeatureSet) signature() uint32 {
+ var s uint32
+ s |= uint32(fs.SteppingID & 0xf)
+ s |= uint32(fs.Model&0xf) << 4
+ s |= uint32(fs.Family&0xf) << 8
+ s |= uint32(fs.ProcessorType&0x3) << 12
+ s |= uint32(fs.ExtendedModel&0xf) << 16
+ s |= uint32(fs.ExtendedFamily&0xff) << 20
+ return s
+}
+
+// Helper to deconstruct signature dword.
+func signatureSplit(v uint32) (ef, em, pt, f, m, sid uint8) {
+ sid = uint8(v & 0xf)
+ m = uint8(v>>4) & 0xf
+ f = uint8(v>>8) & 0xf
+ pt = uint8(v>>12) & 0x3
+ em = uint8(v>>16) & 0xf
+ ef = uint8(v >> 20)
+ return
+}
+
+// Helper to convert blockwise feature bit masks into a set of features. Masks
+// must be provided in order for each block, without skipping them. If a block
+// does not matter for this feature set, 0 is specified.
+func setFromBlockMasks(blocks ...uint32) map[Feature]bool {
+ s := make(map[Feature]bool)
+ for b, blockMask := range blocks {
+ for i := 0; i < blockSize; i++ {
+ if blockMask&1 != 0 {
+ s[featureID(block(b), i)] = true
+ }
+ blockMask >>= 1
+ }
+ }
+ return s
+}
+
+// blockMask returns the 32-bit mask associated with a block of features.
+func (fs *FeatureSet) blockMask(b block) uint32 {
+ var mask uint32
+ for i := 0; i < blockSize; i++ {
+ if fs.Set[featureID(b, i)] {
+ mask |= 1 << uint(i)
+ }
+ }
+ return mask
+}
+
+// Remove removes a Feature from a FeatureSet. It ignores features
+// that are not in the FeatureSet.
+func (fs *FeatureSet) Remove(feature Feature) {
+ delete(fs.Set, feature)
+}
+
+// Add adds a Feature to a FeatureSet. It ignores duplicate features.
+func (fs *FeatureSet) Add(feature Feature) {
+ fs.Set[feature] = true
+}
+
+// HasFeature tests whether or not a feature is in the given feature set.
+func (fs *FeatureSet) HasFeature(feature Feature) bool {
+ return fs.Set[feature]
+}
+
+// Subtract returns the features present in fs that are not present in other.
+// If all features in fs are present in other, Subtract returns nil.
+func (fs *FeatureSet) Subtract(other *FeatureSet) (diff map[Feature]bool) {
+ for f := range fs.Set {
+ if !other.Set[f] {
+ if diff == nil {
+ diff = make(map[Feature]bool)
+ }
+ diff[f] = true
+ }
+ }
+
+ return
+}
+
+// EmulateID emulates a cpuid instruction based on the feature set.
+func (fs *FeatureSet) EmulateID(origAx, origCx uint32) (ax, bx, cx, dx uint32) {
+ switch cpuidFunction(origAx) {
+ case vendorID:
+ ax = uint32(xSaveInfo) // 0xd (xSaveInfo) is the highest function we support.
+ bx, dx, cx = fs.vendorIDRegs()
+ case featureInfo:
+ // CLFLUSH line size is encoded in quadwords. Other fields in bx unsupported.
+ bx = (fs.CacheLine / 8) << 8
+ cx = fs.blockMask(block(0))
+ dx = fs.blockMask(block(1))
+ ax = fs.signature()
+ case intelCacheDescriptors:
+ if !fs.Intel() {
+ // Reserved on non-Intel.
+ return 0, 0, 0, 0
+ }
+
+ // "The least-significant byte in register EAX (register AL)
+ // will always return 01H. Software should ignore this value
+ // and not interpret it as an informational descriptor." - SDM
+ //
+ // We only support reporting cache parameters via
+ // intelDeterministicCacheParams; report as much here.
+ //
+ // We do not support exposing TLB information at all.
+ ax = 1 | (uint32(intelNoCacheDescriptor) << 8)
+ case intelDeterministicCacheParams:
+ if !fs.Intel() {
+ // Reserved on non-Intel.
+ return 0, 0, 0, 0
+ }
+
+ // cx is the index of the cache to describe.
+ if int(origCx) >= len(fs.Caches) {
+ return uint32(cacheNull), 0, 0, 0
+ }
+ c := fs.Caches[origCx]
+
+ ax = uint32(c.Type)
+ ax |= c.Level << 5
+ ax |= 1 << 8 // Always claim the cache is "self-initializing".
+ if c.FullyAssociative {
+ ax |= 1 << 9
+ }
+ // Processor topology not supported.
+
+ bx = fs.CacheLine - 1
+ bx |= (c.Partitions - 1) << 12
+ bx |= (c.Ways - 1) << 22
+
+ cx = c.Sets - 1
+
+ if !c.InvalidateHierarchical {
+ dx |= 1
+ }
+ if c.Inclusive {
+ dx |= 1 << 1
+ }
+ if !c.DirectMapped {
+ dx |= 1 << 2
+ }
+ case xSaveInfo:
+ if !fs.UseXsave() {
+ return 0, 0, 0, 0
+ }
+ return HostID(uint32(xSaveInfo), origCx)
+ case extendedFeatureInfo:
+ if origCx != 0 {
+ break // Only leaf 0 is supported.
+ }
+ bx = fs.blockMask(block(2))
+ cx = fs.blockMask(block(3))
+ case extendedFunctionInfo:
+ // We only support showing the extended features.
+ ax = uint32(extendedFeatures)
+ cx = 0
+ case extendedFeatures:
+ cx = fs.blockMask(block(5))
+ dx = fs.blockMask(block(6))
+ if fs.AMD() {
+ // AMD duplicates some block 1 features in block 6.
+ dx |= fs.blockMask(block(1)) & block6DuplicateMask
+ }
+ }
+
+ return
+}
+
+// UseXsave returns the choice of fp state saving instruction.
+func (fs *FeatureSet) UseXsave() bool {
+ return fs.HasFeature(X86FeatureXSAVE) && fs.HasFeature(X86FeatureOSXSAVE)
+}
+
+// UseXsaveopt returns true if 'fs' supports the "xsaveopt" instruction.
+func (fs *FeatureSet) UseXsaveopt() bool {
+ return fs.UseXsave() && fs.HasFeature(X86FeatureXSAVEOPT)
+}
+
+// HostID executes a native CPUID instruction.
+func HostID(axArg, cxArg uint32) (ax, bx, cx, dx uint32)
+
+// HostFeatureSet uses cpuid to get host values and construct a feature set
+// that matches that of the host machine. Note that there are several places
+// where there appear to be some unnecessary assignments between register names
+// (ax, bx, cx, or dx) and featureBlockN variables. This is to explicitly show
+// where the different feature blocks come from, to make the code easier to
+// inspect and read.
+func HostFeatureSet() *FeatureSet {
+ // eax=0 gets max supported feature and vendor ID.
+ _, bx, cx, dx := HostID(0, 0)
+ vendorID := vendorIDFromRegs(bx, cx, dx)
+
+ // eax=1 gets basic features in ecx:edx.
+ ax, bx, cx, dx := HostID(1, 0)
+ featureBlock0 := cx
+ featureBlock1 := dx
+ ef, em, pt, f, m, sid := signatureSplit(ax)
+ cacheLine := 8 * (bx >> 8) & 0xff
+
+ // eax=4, ecx=i gets details about cache index i. Only supported on Intel.
+ var caches []Cache
+ if vendorID == intelVendorID {
+ // ecx selects the cache index until a null type is returned.
+ for i := uint32(0); ; i++ {
+ ax, bx, cx, dx := HostID(4, i)
+ t := CacheType(ax & 0xf)
+ if t == cacheNull {
+ break
+ }
+
+ lineSize := (bx & 0xfff) + 1
+ if lineSize != cacheLine {
+ panic(fmt.Sprintf("Mismatched cache line size: %d vs %d", lineSize, cacheLine))
+ }
+
+ caches = append(caches, Cache{
+ Type: t,
+ Level: (ax >> 5) & 0x7,
+ FullyAssociative: ((ax >> 9) & 1) == 1,
+ Partitions: ((bx >> 12) & 0x3ff) + 1,
+ Ways: ((bx >> 22) & 0x3ff) + 1,
+ Sets: cx + 1,
+ InvalidateHierarchical: (dx & 1) == 0,
+ Inclusive: ((dx >> 1) & 1) == 1,
+ DirectMapped: ((dx >> 2) & 1) == 0,
+ })
+ }
+ }
+
+ // eax=7, ecx=0 gets extended features in ecx:ebx.
+ _, bx, cx, _ = HostID(7, 0)
+ featureBlock2 := bx
+ featureBlock3 := cx
+
+ // Leaf 0xd is supported only if CPUID.1:ECX.XSAVE[bit 26] is set.
+ var featureBlock4 uint32
+ if (featureBlock0 & (1 << 26)) != 0 {
+ featureBlock4, _, _, _ = HostID(uint32(xSaveInfo), 1)
+ }
+
+ // eax=0x80000000 gets supported extended levels. We use this to
+ // determine if there are any non-zero block 4 or block 6 bits to find.
+ var featureBlock5, featureBlock6 uint32
+ if ax, _, _, _ := HostID(uint32(extendedFunctionInfo), 0); ax >= uint32(extendedFeatures) {
+ // eax=0x80000001 gets AMD added feature bits.
+ _, _, cx, dx = HostID(uint32(extendedFeatures), 0)
+ featureBlock5 = cx
+ // Ignore features duplicated from block 1 on AMD. These bits
+ // are reserved on Intel.
+ featureBlock6 = dx &^ block6DuplicateMask
+ }
+
+ set := setFromBlockMasks(featureBlock0, featureBlock1, featureBlock2, featureBlock3, featureBlock4, featureBlock5, featureBlock6)
+ return &FeatureSet{
+ Set: set,
+ VendorID: vendorID,
+ ExtendedFamily: ef,
+ ExtendedModel: em,
+ ProcessorType: pt,
+ Family: f,
+ Model: m,
+ SteppingID: sid,
+ CacheLine: cacheLine,
+ Caches: caches,
+ }
+}
+
+// Reads max cpu frequency from host /proc/cpuinfo. Must run before
+// whitelisting. This value is used to create the fake /proc/cpuinfo from a
+// FeatureSet.
+func initCPUFreq() {
+ cpuinfob, err := ioutil.ReadFile("/proc/cpuinfo")
+ if err != nil {
+ // Leave it as 0... The standalone VDSO bails out in the same
+ // way.
+ log.Warningf("Could not read /proc/cpuinfo: %v", err)
+ return
+ }
+ cpuinfo := string(cpuinfob)
+
+ // We get the value straight from host /proc/cpuinfo. On machines with
+ // frequency scaling enabled, this will only get the current value
+ // which will likely be inaccurate. This is fine on machines with
+ // frequency scaling disabled.
+ for _, line := range strings.Split(cpuinfo, "\n") {
+ if strings.Contains(line, "cpu MHz") {
+ splitMHz := strings.Split(line, ":")
+ if len(splitMHz) < 2 {
+ log.Warningf("Could not read /proc/cpuinfo: malformed cpu MHz line")
+ return
+ }
+
+ // If there was a problem, leave cpuFreqMHz as 0.
+ var err error
+ cpuFreqMHz, err = strconv.ParseFloat(strings.TrimSpace(splitMHz[1]), 64)
+ if err != nil {
+ log.Warningf("Could not parse cpu MHz value %v: %v", splitMHz[1], err)
+ cpuFreqMHz = 0
+ return
+ }
+ return
+ }
+ }
+ log.Warningf("Could not parse /proc/cpuinfo, it is empty or does not contain cpu MHz")
+}
+
+func initFeaturesFromString() {
+ for f, s := range x86FeatureStrings {
+ x86FeaturesFromString[s] = f
+ }
+ for f, s := range x86FeatureParseOnlyStrings {
+ x86FeaturesFromString[s] = f
+ }
+}
+
+func init() {
+ // initCpuFreq must be run before whitelists are enabled.
+ initCPUFreq()
+ initFeaturesFromString()
+}