util-go/net/ipnet.go

package net

import (
	"net"
)

// Sub class net.IPNet so that we can add JSON marshalling and unmarshalling.
type IPNet struct {
	net.IPNet
}

// Version returns the IP version for an IPNet, or 0 if not a valid IP net.
func (i *IPNet) Version() int {
	if i.IP.To4() != nil {
		return 4
	} else if len(i.IP) == net.IPv6len {
		return 6
	}
	return 0
}

// IsNetOverlap is a utility function that returns true if the two subnet have an overlap.
func (i *IPNet) IsNetOverlap(n net.IPNet) bool {
	return n.Contains(i.IP) || i.Contains(n.IP)
}

// Network returns the masked IP network.
func (i *IPNet) Network() *IPNet {
	_, n, _ := ParseCIDR(i.String())
	return n
}

func ParseCIDR(c string) (*IP, *IPNet, error) {
	netIP, netIPNet, e := net.ParseCIDR(c)
	if netIPNet == nil || e != nil {
		return nil, nil, e
	}
	ip := &IP{netIP}
	ipnet := &IPNet{*netIPNet}

	// The base golang net library always uses a 4-byte IPv4 address in an
	// IPv4 IPNet, so for uniformity in the returned types, make sure the
	// IP address is also 4-bytes - this allows the user to safely assume
	// all IP addresses returned by this function use the same encoding
	// mechanism (not strictly required but better for testing and debugging).
	if ip4 := ip.IP.To4(); ip4 != nil {
		ip.IP = ip4
	}

	return ip, ipnet, nil
}

// Parse a CIDR or an IP address and return the IP, CIDR or error.  If an IP address
// string is supplied, then the CIDR returned is the fully masked IP address (i.e /32 or /128)
func ParseCIDROrIP(c string) (*IP, *IPNet, error) {
	// First try parsing as a CIDR.
	ip, cidr, err := ParseCIDR(c)
	if err == nil {
		return ip, cidr, nil
	}

	// That failed, so try parsing as an IP.
	ip = &IP{}
	if err2 := ip.UnmarshalText([]byte(c)); err2 == nil {
		if ip4 := ip.IP.To4(); ip4 != nil {
			ip.IP = ip4
		}
		n := ip.Network()
		return ip, n, nil
	}

	// That failed too, return the original error.
	return nil, nil, err
}

// String returns a friendly name for the network.  The standard net package
// implements String() on the pointer, which means it will not be invoked on a
// struct type, so we re-implement on the struct type.
func (i *IPNet) String() string {
	ip := &i.IPNet
	return ip.String()
}

// MustParseNetwork parses the string into a IPNet.  The IP address in the
// IPNet is masked.
func MustParseNetwork(c string) IPNet {
	_, cidr, err := ParseCIDR(c)
	if err != nil {
		panic(err)
	}
	return *cidr
}

// MustParseCIDR parses the string into a IPNet.  The IP address in the
// IPNet is not masked.
func MustParseCIDR(c string) IPNet {
	ip, cidr, err := ParseCIDR(c)
	if err != nil {
		panic(err)
	}
	n := IPNet{}
	n.IP = ip.IP
	n.Mask = cidr.Mask
	return n
}
wrapper for net.ip 2018-08-22 06:10:45 +00:00			`package net`

			`import (`
			`"net"`
			`)`

			`// Sub class net.IPNet so that we can add JSON marshalling and unmarshalling.`
			`type IPNet struct {`
			`net.IPNet`
			`}`

			`// Version returns the IP version for an IPNet, or 0 if not a valid IP net.`
			`func (i *IPNet) Version() int {`
			`if i.IP.To4() != nil {`
			`return 4`
			`} else if len(i.IP) == net.IPv6len {`
			`return 6`
			`}`
			`return 0`
			`}`

			`// IsNetOverlap is a utility function that returns true if the two subnet have an overlap.`
			`func (i *IPNet) IsNetOverlap(n net.IPNet) bool {`
			`return n.Contains(i.IP) \|\| i.Contains(n.IP)`
			`}`

			`// Network returns the masked IP network.`
			`func (i IPNet) Network() IPNet {`
			`_, n, _ := ParseCIDR(i.String())`
			`return n`
			`}`

			`func ParseCIDR(c string) (IP, IPNet, error) {`
			`netIP, netIPNet, e := net.ParseCIDR(c)`
			`if netIPNet == nil \|\| e != nil {`
			`return nil, nil, e`
			`}`
			`ip := &IP{netIP}`
			`ipnet := &IPNet{*netIPNet}`

			`// The base golang net library always uses a 4-byte IPv4 address in an`
			`// IPv4 IPNet, so for uniformity in the returned types, make sure the`
			`// IP address is also 4-bytes - this allows the user to safely assume`
			`// all IP addresses returned by this function use the same encoding`
			`// mechanism (not strictly required but better for testing and debugging).`
			`if ip4 := ip.IP.To4(); ip4 != nil {`
			`ip.IP = ip4`
			`}`

			`return ip, ipnet, nil`
			`}`

			`// Parse a CIDR or an IP address and return the IP, CIDR or error. If an IP address`
			`// string is supplied, then the CIDR returned is the fully masked IP address (i.e /32 or /128)`
			`func ParseCIDROrIP(c string) (IP, IPNet, error) {`
			`// First try parsing as a CIDR.`
			`ip, cidr, err := ParseCIDR(c)`
			`if err == nil {`
			`return ip, cidr, nil`
			`}`

			`// That failed, so try parsing as an IP.`
			`ip = &IP{}`
			`if err2 := ip.UnmarshalText([]byte(c)); err2 == nil {`
			`if ip4 := ip.IP.To4(); ip4 != nil {`
			`ip.IP = ip4`
			`}`
			`n := ip.Network()`
			`return ip, n, nil`
			`}`

			`// That failed too, return the original error.`
			`return nil, nil, err`
			`}`

			`// String returns a friendly name for the network. The standard net package`
			`// implements String() on the pointer, which means it will not be invoked on a`
			`// struct type, so we re-implement on the struct type.`
			`func (i *IPNet) String() string {`
			`ip := &i.IPNet`
			`return ip.String()`
			`}`

			`// MustParseNetwork parses the string into a IPNet. The IP address in the`
			`// IPNet is masked.`
			`func MustParseNetwork(c string) IPNet {`
			`_, cidr, err := ParseCIDR(c)`
			`if err != nil {`
			`panic(err)`
			`}`
			`return *cidr`
			`}`

			`// MustParseCIDR parses the string into a IPNet. The IP address in the`
			`// IPNet is not masked.`
			`func MustParseCIDR(c string) IPNet {`
			`ip, cidr, err := ParseCIDR(c)`
			`if err != nil {`
			`panic(err)`
			`}`
			`n := IPNet{}`
			`n.IP = ip.IP`
			`n.Mask = cidr.Mask`
			`return n`
			`}`