libgo/go/net/netip/slow_test.go - gcc - Git at Google

 // Copyright 2020 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package netip_test

 import (
 	"fmt"
 	. "net/netip"
 	"strconv"
 	"strings"
 )

 // zeros is a slice of eight stringified zeros. It's used in
 // parseIPSlow to construct slices of specific amounts of zero fields,
 // from 1 to 8.
 var zeros = []string{"0", "0", "0", "0", "0", "0", "0", "0"}

 // parseIPSlow is like ParseIP, but aims for readability above
 // speed. It's the reference implementation for correctness checking
 // and against which we measure optimized parsers.
 //
 // parseIPSlow understands the following forms of IP addresses:
 //  - Regular IPv4: 1.2.3.4
 //  - IPv4 with many leading zeros: 0000001.0000002.0000003.0000004
 //  - Regular IPv6: 1111:2222:3333:4444:5555:6666:7777:8888
 //  - IPv6 with many leading zeros: 00000001:0000002:0000003:0000004:0000005:0000006:0000007:0000008
 //  - IPv6 with zero blocks elided: 1111:2222::7777:8888
 //  - IPv6 with trailing 32 bits expressed as IPv4: 1111:2222:3333:4444:5555:6666:77.77.88.88
 //
 // It does not process the following IP address forms, which have been
 // varyingly accepted by some programs due to an under-specification
 // of the shapes of IPv4 addresses:
 //
 //  - IPv4 as a single 32-bit uint: 4660 (same as "1.2.3.4")
 //  - IPv4 with octal numbers: 0300.0250.0.01 (same as "192.168.0.1")
 //  - IPv4 with hex numbers: 0xc0.0xa8.0x0.0x1 (same as "192.168.0.1")
 //  - IPv4 in "class-B style": 1.2.52 (same as "1.2.3.4")
 //  - IPv4 in "class-A style": 1.564 (same as "1.2.3.4")
 func parseIPSlow(s string) (Addr, error) {
 	// Identify and strip out the zone, if any. There should be 0 or 1
 	// '%' in the string.
 	var zone string
 	fs := strings.Split(s, "%")
 	switch len(fs) {
 	case 1:
 		// No zone, that's fine.
 	case 2:
 		s, zone = fs[0], fs[1]
 		if zone == "" {
 			return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): no zone after zone specifier", s)
 		}
 	default:
 		return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): too many zone specifiers", s) // TODO: less specific?
 	}

 	// IPv4 by itself is easy to do in a helper.
 	if strings.Count(s, ":") == 0 {
 		if zone != "" {
 			return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): IPv4 addresses cannot have a zone", s)
 		}
 		return parseIPv4Slow(s)
 	}

 	normal, err := normalizeIPv6Slow(s)
 	if err != nil {
 		return Addr{}, err
 	}

 	// At this point, we've normalized the address back into 8 hex
 	// fields of 16 bits each. Parse that.
 	fs = strings.Split(normal, ":")
 	if len(fs) != 8 {
 		return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): wrong size address", s)
 	}
 	var ret [16]byte
 	for i, f := range fs {
 		a, b, err := parseWord(f)
 		if err != nil {
 			return Addr{}, err
 		}
 		ret[i*2] = a
 		ret[i*2+1] = b
 	}

 	return AddrFrom16(ret).WithZone(zone), nil
 }

 // normalizeIPv6Slow expands s, which is assumed to be an IPv6
 // address, to its canonical text form.
 //
 // The canonical form of an IPv6 address is 8 colon-separated fields,
 // where each field should be a hex value from 0 to ffff. This
 // function does not verify the contents of each field.
 //
 // This function performs two transformations:
 //  - The last 32 bits of an IPv6 address may be represented in
 //    IPv4-style dotted quad form, as in 1:2:3:4:5:6:7.8.9.10. That
 //    address is transformed to its hex equivalent,
 //    e.g. 1:2:3:4:5:6:708:90a.
 //  - An address may contain one "::", which expands into as many
 //    16-bit blocks of zeros as needed to make the address its correct
 //    full size. For example, fe80::1:2 expands to fe80:0:0:0:0:0:1:2.
 //
 // Both short forms may be present in a single address,
 // e.g. fe80::1.2.3.4.
 func normalizeIPv6Slow(orig string) (string, error) {
 	s := orig

 	// Find and convert an IPv4 address in the final field, if any.
 	i := strings.LastIndex(s, ":")
 	if i == -1 {
 		return "", fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", orig)
 	}
 	if strings.Contains(s[i+1:], ".") {
 		ip, err := parseIPv4Slow(s[i+1:])
 		if err != nil {
 			return "", err
 		}
 		a4 := ip.As4()
 		s = fmt.Sprintf("%s:%02x%02x:%02x%02x", s[:i], a4[0], a4[1], a4[2], a4[3])
 	}

 	// Find and expand a ::, if any.
 	fs := strings.Split(s, "::")
 	switch len(fs) {
 	case 1:
 		// No ::, nothing to do.
 	case 2:
 		lhs, rhs := fs[0], fs[1]
 		// Found a ::, figure out how many zero blocks need to be
 		// inserted.
 		nblocks := strings.Count(lhs, ":") + strings.Count(rhs, ":")
 		if lhs != "" {
 			nblocks++
 		}
 		if rhs != "" {
 			nblocks++
 		}
 		if nblocks > 7 {
 			return "", fmt.Errorf("netaddr.ParseIP(%q): address too long", orig)
 		}
 		fs = nil
 		// Either side of the :: can be empty. We don't want empty
 		// fields to feature in the final normalized address.
 		if lhs != "" {
 			fs = append(fs, lhs)
 		}
 		fs = append(fs, zeros[:8-nblocks]...)
 		if rhs != "" {
 			fs = append(fs, rhs)
 		}
 		s = strings.Join(fs, ":")
 	default:
 		// Too many ::
 		return "", fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", orig)
 	}

 	return s, nil
 }

 // parseIPv4Slow parses and returns an IPv4 address in dotted quad
 // form, e.g. "192.168.0.1". It is slow but easy to read, and the
 // reference implementation against which we compare faster
 // implementations for correctness.
 func parseIPv4Slow(s string) (Addr, error) {
 	fs := strings.Split(s, ".")
 	if len(fs) != 4 {
 		return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", s)
 	}
 	var ret [4]byte
 	for i := range ret {
 		val, err := strconv.ParseUint(fs[i], 10, 8)
 		if err != nil {
 			return Addr{}, err
 		}
 		ret[i] = uint8(val)
 	}
 	return AddrFrom4([4]byte{ret[0], ret[1], ret[2], ret[3]}), nil
 }

 // parseWord converts a 16-bit hex string into its corresponding
 // two-byte value.
 func parseWord(s string) (byte, byte, error) {
 	ret, err := strconv.ParseUint(s, 16, 16)
 	if err != nil {
 		return 0, 0, err
 	}
 	return uint8(ret >> 8), uint8(ret), nil
 }
	// Copyright 2020 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package netip_test

	import (
	"fmt"
	. "net/netip"
	"strconv"
	"strings"
	)

	// zeros is a slice of eight stringified zeros. It's used in
	// parseIPSlow to construct slices of specific amounts of zero fields,
	// from 1 to 8.
	var zeros = []string{"0", "0", "0", "0", "0", "0", "0", "0"}

	// parseIPSlow is like ParseIP, but aims for readability above
	// speed. It's the reference implementation for correctness checking
	// and against which we measure optimized parsers.
	//
	// parseIPSlow understands the following forms of IP addresses:
	// - Regular IPv4: 1.2.3.4
	// - IPv4 with many leading zeros: 0000001.0000002.0000003.0000004
	// - Regular IPv6: 1111:2222:3333:4444:5555:6666:7777:8888
	// - IPv6 with many leading zeros: 00000001:0000002:0000003:0000004:0000005:0000006:0000007:0000008
	// - IPv6 with zero blocks elided: 1111:2222::7777:8888
	// - IPv6 with trailing 32 bits expressed as IPv4: 1111:2222:3333:4444:5555:6666:77.77.88.88
	//
	// It does not process the following IP address forms, which have been
	// varyingly accepted by some programs due to an under-specification
	// of the shapes of IPv4 addresses:
	//
	// - IPv4 as a single 32-bit uint: 4660 (same as "1.2.3.4")
	// - IPv4 with octal numbers: 0300.0250.0.01 (same as "192.168.0.1")
	// - IPv4 with hex numbers: 0xc0.0xa8.0x0.0x1 (same as "192.168.0.1")
	// - IPv4 in "class-B style": 1.2.52 (same as "1.2.3.4")
	// - IPv4 in "class-A style": 1.564 (same as "1.2.3.4")
	func parseIPSlow(s string) (Addr, error) {
	// Identify and strip out the zone, if any. There should be 0 or 1
	// '%' in the string.
	var zone string
	fs := strings.Split(s, "%")
	switch len(fs) {
	case 1:
	// No zone, that's fine.
	case 2:
	s, zone = fs[0], fs[1]
	if zone == "" {
	return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): no zone after zone specifier", s)
	}
	default:
	return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): too many zone specifiers", s) // TODO: less specific?
	}

	// IPv4 by itself is easy to do in a helper.
	if strings.Count(s, ":") == 0 {
	if zone != "" {
	return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): IPv4 addresses cannot have a zone", s)
	}
	return parseIPv4Slow(s)
	}

	normal, err := normalizeIPv6Slow(s)
	if err != nil {
	return Addr{}, err
	}

	// At this point, we've normalized the address back into 8 hex
	// fields of 16 bits each. Parse that.
	fs = strings.Split(normal, ":")
	if len(fs) != 8 {
	return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): wrong size address", s)
	}
	var ret [16]byte
	for i, f := range fs {
	a, b, err := parseWord(f)
	if err != nil {
	return Addr{}, err
	}
	ret[i*2] = a
	ret[i*2+1] = b
	}

	return AddrFrom16(ret).WithZone(zone), nil
	}

	// normalizeIPv6Slow expands s, which is assumed to be an IPv6
	// address, to its canonical text form.
	//
	// The canonical form of an IPv6 address is 8 colon-separated fields,
	// where each field should be a hex value from 0 to ffff. This
	// function does not verify the contents of each field.
	//
	// This function performs two transformations:
	// - The last 32 bits of an IPv6 address may be represented in
	// IPv4-style dotted quad form, as in 1:2:3:4:5:6:7.8.9.10. That
	// address is transformed to its hex equivalent,
	// e.g. 1:2:3:4:5:6:708:90a.
	// - An address may contain one "::", which expands into as many
	// 16-bit blocks of zeros as needed to make the address its correct
	// full size. For example, fe80::1:2 expands to fe80:0:0:0:0:0:1:2.
	//
	// Both short forms may be present in a single address,
	// e.g. fe80::1.2.3.4.
	func normalizeIPv6Slow(orig string) (string, error) {
	s := orig

	// Find and convert an IPv4 address in the final field, if any.
	i := strings.LastIndex(s, ":")
	if i == -1 {
	return "", fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", orig)
	}
	if strings.Contains(s[i+1:], ".") {
	ip, err := parseIPv4Slow(s[i+1:])
	if err != nil {
	return "", err
	}
	a4 := ip.As4()
	s = fmt.Sprintf("%s:%02x%02x:%02x%02x", s[:i], a4[0], a4[1], a4[2], a4[3])
	}

	// Find and expand a ::, if any.
	fs := strings.Split(s, "::")
	switch len(fs) {
	case 1:
	// No ::, nothing to do.
	case 2:
	lhs, rhs := fs[0], fs[1]
	// Found a ::, figure out how many zero blocks need to be
	// inserted.
	nblocks := strings.Count(lhs, ":") + strings.Count(rhs, ":")
	if lhs != "" {
	nblocks++
	}
	if rhs != "" {
	nblocks++
	}
	if nblocks > 7 {
	return "", fmt.Errorf("netaddr.ParseIP(%q): address too long", orig)
	}
	fs = nil
	// Either side of the :: can be empty. We don't want empty
	// fields to feature in the final normalized address.
	if lhs != "" {
	fs = append(fs, lhs)
	}
	fs = append(fs, zeros[:8-nblocks]...)
	if rhs != "" {
	fs = append(fs, rhs)
	}
	s = strings.Join(fs, ":")
	default:
	// Too many ::
	return "", fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", orig)
	}

	return s, nil
	}

	// parseIPv4Slow parses and returns an IPv4 address in dotted quad
	// form, e.g. "192.168.0.1". It is slow but easy to read, and the
	// reference implementation against which we compare faster
	// implementations for correctness.
	func parseIPv4Slow(s string) (Addr, error) {
	fs := strings.Split(s, ".")
	if len(fs) != 4 {
	return Addr{}, fmt.Errorf("netaddr.ParseIP(%q): invalid IP address", s)
	}
	var ret [4]byte
	for i := range ret {
	val, err := strconv.ParseUint(fs[i], 10, 8)
	if err != nil {
	return Addr{}, err
	}
	ret[i] = uint8(val)
	}
	return AddrFrom4([4]byte{ret[0], ret[1], ret[2], ret[3]}), nil
	}

	// parseWord converts a 16-bit hex string into its corresponding
	// two-byte value.
	func parseWord(s string) (byte, byte, error) {
	ret, err := strconv.ParseUint(s, 16, 16)
	if err != nil {
	return 0, 0, err
	}
	return uint8(ret >> 8), uint8(ret), nil
	}