html2pic/uuid/generator.go

package uuid

import (
	"crypto/md5"
	"crypto/rand"
	"crypto/sha1"
	"encoding/binary"
	"fmt"
	"hash"
	"io"
	"net"
	"os"
	"sync"
	"time"
)

// Difference in 100-nanosecond intervals between
// UUID epoch (October 15, 1582) and Unix epoch (January 1, 1970).
const epochStart = 122192928000000000

type epochFunc func() time.Time
type hwAddrFunc func() (net.HardwareAddr, error)

var (
	global = newRFC4122Generator()

	posixUID = uint32(os.Getuid())
	posixGID = uint32(os.Getgid())
)

// NewV1 returns UUID based on current timestamp and MAC address.
func NewV1() (UUID, error) {
	return global.NewV1()
}

// NewV2 returns DCE Security UUID based on POSIX UID/GID.
func NewV2(domain byte) (UUID, error) {
	return global.NewV2(domain)
}

// NewV3 returns UUID based on MD5 hash of namespace UUID and name.
func NewV3(ns UUID, name string) UUID {
	return global.NewV3(ns, name)
}

// NewV4 returns random generated UUID.
func NewV4() (UUID, error) {
	return global.NewV4()
}

// NewV5 returns UUID based on SHA-1 hash of namespace UUID and name.
func NewV5(ns UUID, name string) UUID {
	return global.NewV5(ns, name)
}

// Generator provides interface for generating UUIDs.
type Generator interface {
	NewV1() (UUID, error)
	NewV2(domain byte) (UUID, error)
	NewV3(ns UUID, name string) UUID
	NewV4() (UUID, error)
	NewV5(ns UUID, name string) UUID
}

// Default generator implementation.
type rfc4122Generator struct {
	clockSequenceOnce sync.Once
	hardwareAddrOnce  sync.Once
	storageMutex      sync.Mutex

	rand io.Reader

	epochFunc     epochFunc
	hwAddrFunc    hwAddrFunc
	lastTime      uint64
	clockSequence uint16
	hardwareAddr  [6]byte
}

func newRFC4122Generator() Generator {
	return &rfc4122Generator{
		epochFunc:  time.Now,
		hwAddrFunc: defaultHWAddrFunc,
		rand:       rand.Reader,
	}
}

// NewV1 returns UUID based on current timestamp and MAC address.
func (g *rfc4122Generator) NewV1() (UUID, error) {
	u := UUID{}

	timeNow, clockSeq, err := g.getClockSequence()
	if err != nil {
		return Nil, err
	}
	binary.BigEndian.PutUint32(u[0:], uint32(timeNow))
	binary.BigEndian.PutUint16(u[4:], uint16(timeNow>>32))
	binary.BigEndian.PutUint16(u[6:], uint16(timeNow>>48))
	binary.BigEndian.PutUint16(u[8:], clockSeq)

	hardwareAddr, err := g.getHardwareAddr()
	if err != nil {
		return Nil, err
	}
	copy(u[10:], hardwareAddr)

	u.SetVersion(V1)
	u.SetVariant(VariantRFC4122)

	return u, nil
}

// NewV2 returns DCE Security UUID based on POSIX UID/GID.
func (g *rfc4122Generator) NewV2(domain byte) (UUID, error) {
	u, err := g.NewV1()
	if err != nil {
		return Nil, err
	}

	switch domain {
	case DomainPerson:
		binary.BigEndian.PutUint32(u[:], posixUID)
	case DomainGroup:
		binary.BigEndian.PutUint32(u[:], posixGID)
	}

	u[9] = domain

	u.SetVersion(V2)
	u.SetVariant(VariantRFC4122)

	return u, nil
}

// NewV3 returns UUID based on MD5 hash of namespace UUID and name.
func (g *rfc4122Generator) NewV3(ns UUID, name string) UUID {
	u := newFromHash(md5.New(), ns, name)
	u.SetVersion(V3)
	u.SetVariant(VariantRFC4122)

	return u
}

// NewV4 returns random generated UUID.
func (g *rfc4122Generator) NewV4() (UUID, error) {
	u := UUID{}
	if _, err := g.rand.Read(u[:]); err != nil {
		return Nil, err
	}
	u.SetVersion(V4)
	u.SetVariant(VariantRFC4122)

	return u, nil
}

// NewV5 returns UUID based on SHA-1 hash of namespace UUID and name.
func (g *rfc4122Generator) NewV5(ns UUID, name string) UUID {
	u := newFromHash(sha1.New(), ns, name)
	u.SetVersion(V5)
	u.SetVariant(VariantRFC4122)

	return u
}

// Returns epoch and clock sequence.
func (g *rfc4122Generator) getClockSequence() (uint64, uint16, error) {
	var err error
	g.clockSequenceOnce.Do(func() {
		buf := make([]byte, 2)
		if _, err = g.rand.Read(buf); err != nil {
			return
		}
		g.clockSequence = binary.BigEndian.Uint16(buf)
	})
	if err != nil {
		return 0, 0, err
	}

	g.storageMutex.Lock()
	defer g.storageMutex.Unlock()

	timeNow := g.getEpoch()
	// Clock didn't change since last UUID generation.
	// Should increase clock sequence.
	if timeNow <= g.lastTime {
		g.clockSequence++
	}
	g.lastTime = timeNow

	return timeNow, g.clockSequence, nil
}

// Returns hardware address.
func (g *rfc4122Generator) getHardwareAddr() ([]byte, error) {
	var err error
	g.hardwareAddrOnce.Do(func() {
		if hwAddr, err := g.hwAddrFunc(); err == nil {
			copy(g.hardwareAddr[:], hwAddr)
			return
		}

		// Initialize hardwareAddr randomly in case
		// of real network interfaces absence.
		if _, err = g.rand.Read(g.hardwareAddr[:]); err != nil {
			return
		}
		// Set multicast bit as recommended by RFC 4122
		g.hardwareAddr[0] |= 0x01
	})
	if err != nil {
		return []byte{}, err
	}
	return g.hardwareAddr[:], nil
}

// Returns difference in 100-nanosecond intervals between
// UUID epoch (October 15, 1582) and current time.
func (g *rfc4122Generator) getEpoch() uint64 {
	return epochStart + uint64(g.epochFunc().UnixNano()/100)
}

// Returns UUID based on hashing of namespace UUID and name.
func newFromHash(h hash.Hash, ns UUID, name string) UUID {
	u := UUID{}
	h.Write(ns[:])
	h.Write([]byte(name))
	copy(u[:], h.Sum(nil))

	return u
}

// Returns hardware address.
func defaultHWAddrFunc() (net.HardwareAddr, error) {
	ifaces, err := net.Interfaces()
	if err != nil {
		return []byte{}, err
	}
	for _, iface := range ifaces {
		if len(iface.HardwareAddr) >= 6 {
			return iface.HardwareAddr, nil
		}
	}
	return []byte{}, fmt.Errorf("uuid: no HW address found")
}
Create & Init Project... 2018-09-11 10:57:48 +00:00			`package uuid`

			`import (`
			`"crypto/md5"`
			`"crypto/rand"`
			`"crypto/sha1"`
			`"encoding/binary"`
			`"fmt"`
			`"hash"`
			`"io"`
			`"net"`
			`"os"`
			`"sync"`
			`"time"`
			`)`

			`// Difference in 100-nanosecond intervals between`
			`// UUID epoch (October 15, 1582) and Unix epoch (January 1, 1970).`
			`const epochStart = 122192928000000000`

			`type epochFunc func() time.Time`
			`type hwAddrFunc func() (net.HardwareAddr, error)`

			`var (`
			`global = newRFC4122Generator()`

			`posixUID = uint32(os.Getuid())`
			`posixGID = uint32(os.Getgid())`
			`)`

			`// NewV1 returns UUID based on current timestamp and MAC address.`
			`func NewV1() (UUID, error) {`
			`return global.NewV1()`
			`}`

			`// NewV2 returns DCE Security UUID based on POSIX UID/GID.`
			`func NewV2(domain byte) (UUID, error) {`
			`return global.NewV2(domain)`
			`}`

			`// NewV3 returns UUID based on MD5 hash of namespace UUID and name.`
			`func NewV3(ns UUID, name string) UUID {`
			`return global.NewV3(ns, name)`
			`}`

			`// NewV4 returns random generated UUID.`
			`func NewV4() (UUID, error) {`
			`return global.NewV4()`
			`}`

			`// NewV5 returns UUID based on SHA-1 hash of namespace UUID and name.`
			`func NewV5(ns UUID, name string) UUID {`
			`return global.NewV5(ns, name)`
			`}`

			`// Generator provides interface for generating UUIDs.`
			`type Generator interface {`
			`NewV1() (UUID, error)`
			`NewV2(domain byte) (UUID, error)`
			`NewV3(ns UUID, name string) UUID`
			`NewV4() (UUID, error)`
			`NewV5(ns UUID, name string) UUID`
			`}`

			`// Default generator implementation.`
			`type rfc4122Generator struct {`
			`clockSequenceOnce sync.Once`
			`hardwareAddrOnce sync.Once`
			`storageMutex sync.Mutex`

			`rand io.Reader`

			`epochFunc epochFunc`
			`hwAddrFunc hwAddrFunc`
			`lastTime uint64`
			`clockSequence uint16`
			`hardwareAddr [6]byte`
			`}`

			`func newRFC4122Generator() Generator {`
			`return &rfc4122Generator{`
			`epochFunc: time.Now,`
			`hwAddrFunc: defaultHWAddrFunc,`
			`rand: rand.Reader,`
			`}`
			`}`

			`// NewV1 returns UUID based on current timestamp and MAC address.`
			`func (g *rfc4122Generator) NewV1() (UUID, error) {`
			`u := UUID{}`

			`timeNow, clockSeq, err := g.getClockSequence()`
			`if err != nil {`
			`return Nil, err`
			`}`
			`binary.BigEndian.PutUint32(u[0:], uint32(timeNow))`
			`binary.BigEndian.PutUint16(u[4:], uint16(timeNow>>32))`
			`binary.BigEndian.PutUint16(u[6:], uint16(timeNow>>48))`
			`binary.BigEndian.PutUint16(u[8:], clockSeq)`

			`hardwareAddr, err := g.getHardwareAddr()`
			`if err != nil {`
			`return Nil, err`
			`}`
			`copy(u[10:], hardwareAddr)`

			`u.SetVersion(V1)`
			`u.SetVariant(VariantRFC4122)`

			`return u, nil`
			`}`

			`// NewV2 returns DCE Security UUID based on POSIX UID/GID.`
			`func (g *rfc4122Generator) NewV2(domain byte) (UUID, error) {`
			`u, err := g.NewV1()`
			`if err != nil {`
			`return Nil, err`
			`}`

			`switch domain {`
			`case DomainPerson:`
			`binary.BigEndian.PutUint32(u[:], posixUID)`
			`case DomainGroup:`
			`binary.BigEndian.PutUint32(u[:], posixGID)`
			`}`

			`u[9] = domain`

			`u.SetVersion(V2)`
			`u.SetVariant(VariantRFC4122)`

			`return u, nil`
			`}`

			`// NewV3 returns UUID based on MD5 hash of namespace UUID and name.`
			`func (g *rfc4122Generator) NewV3(ns UUID, name string) UUID {`
			`u := newFromHash(md5.New(), ns, name)`
			`u.SetVersion(V3)`
			`u.SetVariant(VariantRFC4122)`

			`return u`
			`}`

			`// NewV4 returns random generated UUID.`
			`func (g *rfc4122Generator) NewV4() (UUID, error) {`
			`u := UUID{}`
			`if _, err := g.rand.Read(u[:]); err != nil {`
			`return Nil, err`
			`}`
			`u.SetVersion(V4)`
			`u.SetVariant(VariantRFC4122)`

			`return u, nil`
			`}`

			`// NewV5 returns UUID based on SHA-1 hash of namespace UUID and name.`
			`func (g *rfc4122Generator) NewV5(ns UUID, name string) UUID {`
			`u := newFromHash(sha1.New(), ns, name)`
			`u.SetVersion(V5)`
			`u.SetVariant(VariantRFC4122)`

			`return u`
			`}`

			`// Returns epoch and clock sequence.`
			`func (g *rfc4122Generator) getClockSequence() (uint64, uint16, error) {`
			`var err error`
			`g.clockSequenceOnce.Do(func() {`
			`buf := make([]byte, 2)`
			`if _, err = g.rand.Read(buf); err != nil {`
			`return`
			`}`
			`g.clockSequence = binary.BigEndian.Uint16(buf)`
			`})`
			`if err != nil {`
			`return 0, 0, err`
			`}`

			`g.storageMutex.Lock()`
			`defer g.storageMutex.Unlock()`

			`timeNow := g.getEpoch()`
			`// Clock didn't change since last UUID generation.`
			`// Should increase clock sequence.`
			`if timeNow <= g.lastTime {`
			`g.clockSequence++`
			`}`
			`g.lastTime = timeNow`

			`return timeNow, g.clockSequence, nil`
			`}`

			`// Returns hardware address.`
			`func (g *rfc4122Generator) getHardwareAddr() ([]byte, error) {`
			`var err error`
			`g.hardwareAddrOnce.Do(func() {`
			`if hwAddr, err := g.hwAddrFunc(); err == nil {`
			`copy(g.hardwareAddr[:], hwAddr)`
			`return`
			`}`

			`// Initialize hardwareAddr randomly in case`
			`// of real network interfaces absence.`
			`if _, err = g.rand.Read(g.hardwareAddr[:]); err != nil {`
			`return`
			`}`
			`// Set multicast bit as recommended by RFC 4122`
			`g.hardwareAddr[0] \|= 0x01`
			`})`
			`if err != nil {`
			`return []byte{}, err`
			`}`
			`return g.hardwareAddr[:], nil`
			`}`

			`// Returns difference in 100-nanosecond intervals between`
			`// UUID epoch (October 15, 1582) and current time.`
			`func (g *rfc4122Generator) getEpoch() uint64 {`
			`return epochStart + uint64(g.epochFunc().UnixNano()/100)`
			`}`

			`// Returns UUID based on hashing of namespace UUID and name.`
			`func newFromHash(h hash.Hash, ns UUID, name string) UUID {`
			`u := UUID{}`
			`h.Write(ns[:])`
			`h.Write([]byte(name))`
			`copy(u[:], h.Sum(nil))`

			`return u`
			`}`

			`// Returns hardware address.`
			`func defaultHWAddrFunc() (net.HardwareAddr, error) {`
			`ifaces, err := net.Interfaces()`
			`if err != nil {`
			`return []byte{}, err`
			`}`
			`for _, iface := range ifaces {`
			`if len(iface.HardwareAddr) >= 6 {`
			`return iface.HardwareAddr, nil`
			`}`
			`}`
			`return []byte{}, fmt.Errorf("uuid: no HW address found")`
			`}`