.. | ||
.gitignore | ||
.goreleaser.yml | ||
.travis.yml | ||
CONTRIBUTING.txt | ||
cpuid_386.s | ||
cpuid_amd64.s | ||
cpuid_arm64.s | ||
cpuid.go | ||
detect_arm64.go | ||
detect_ref.go | ||
detect_x86.go | ||
featureid_string.go | ||
go.mod | ||
LICENSE | ||
os_darwin_arm64.go | ||
os_linux_arm64.go | ||
os_other_arm64.go | ||
os_safe_linux_arm64.go | ||
os_unsafe_linux_arm64.go | ||
README.md | ||
test-architectures.sh |
cpuid
Package cpuid provides information about the CPU running the current program.
CPU features are detected on startup, and kept for fast access through the life of the application. Currently x86 / x64 (AMD64/i386) and ARM (ARM64) is supported, and no external C (cgo) code is used, which should make the library very easy to use.
You can access the CPU information by accessing the shared CPU variable of the cpuid library.
Package home: https://github.com/klauspost/cpuid
installing
go get -u github.com/klauspost/cpuid/v2
using
modules.
Drop v2
for others.
example
package main
import (
"fmt"
"strings"
. "github.com/klauspost/cpuid/v2"
)
func main() {
// Print basic CPU information:
.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:", fmt.Sprintf(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")
fmt
// Test if we have these specific features:
if CPU.Supports(SSE, SSE2) {
.Println("We have Streaming SIMD 2 Extensions")
fmt}
}
Sample output:
>go run main.go
Name: AMD Ryzen 9 3950X 16-Core Processor
PhysicalCores: 16
ThreadsPerCore: 2
LogicalCores: 32
Family 23 Model: 113 Vendor ID: AMD
Features: ADX,AESNI,AVX,AVX2,BMI1,BMI2,CLMUL,CMOV,CX16,F16C,FMA3,HTT,HYPERVISOR,LZCNT,MMX,MMXEXT,NX,POPCNT,RDRAND,RDSEED,RDTSCP,SHA,SSE,SSE2,SSE3,SSE4,SSE42,SSE4A,SSSE3
Cacheline bytes: 64
L1 Data Cache: 32768 bytes
L1 Instruction Cache: 32768 bytes
L2 Cache: 524288 bytes
L3 Cache: 16777216 bytes
Frequency 0 hz
We have Streaming SIMD 2 Extensions
usage
The cpuid.CPU
provides access to CPU features. Use
cpuid.CPU.Supports()
to check for CPU features. A faster
cpuid.CPU.Has()
is provided which will usually be inlined
by the gc compiler.
Note that for some cpu/os combinations some features will not be
detected. amd64
has rather good support and should work
reliably on all platforms.
Note that hypervisors may not pass through all CPU features.
arm64 feature detection
Not all operating systems provide ARM features directly and there is no safe way to do so for the rest.
Currently arm64/linux
and arm64/freebsd
should be quite reliable. arm64/darwin
adds features
expected from the M1 processor, but a lot remains undetected.
A DetectARM()
can be used if you are able to control
your deployment, it will detect CPU features, but may crash if the OS
doesn’t intercept the calls. A -cpu.arm
flag for detecting
unsafe ARM features can be added. See below.
Note that currently only features are detected on ARM, no additional information is currently available.
flags
It is possible to add flags that affects cpu detection.
For this the Flags()
command is provided.
This must be called before flag.Parse()
AND
after the flags have been parsed Detect()
must be
called.
This means that any detection used in init()
functions
will not contain these flags.
Example:
package main
import (
"flag"
"fmt"
"strings"
"github.com/klauspost/cpuid/v2"
)
func main() {
.Flags()
cpuid.Parse()
flag.Detect()
cpuid
// Test if we have these specific features:
if cpuid.CPU.Supports(cpuid.SSE, cpuid.SSE2) {
.Println("We have Streaming SIMD 2 Extensions")
fmt}
}
license
This code is published under an MIT license. See LICENSE file for more information.