naiveproxy/net/base/ip_address.cc

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2018-01-28 21:32:06 +03:00
// Copyright (c) 2015 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/base/ip_address.h"
#include <algorithm>
#include <climits>
#include "base/containers/stack_container.h"
#include "base/strings/string_piece.h"
#include "base/strings/string_split.h"
#include "base/strings/stringprintf.h"
#include "net/base/parse_number.h"
#include "url/gurl.h"
#include "url/url_canon_ip.h"
namespace net {
namespace {
// The prefix for IPv6 mapped IPv4 addresses.
// https://tools.ietf.org/html/rfc4291#section-2.5.5.2
const uint8_t kIPv4MappedPrefix[] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0xFF, 0xFF};
// Note that this function assumes:
// * |ip_address| is at least |prefix_length_in_bits| (bits) long;
// * |ip_prefix| is at least |prefix_length_in_bits| (bits) long.
bool IPAddressPrefixCheck(const IPAddressBytes& ip_address,
const uint8_t* ip_prefix,
size_t prefix_length_in_bits) {
// Compare all the bytes that fall entirely within the prefix.
size_t num_entire_bytes_in_prefix = prefix_length_in_bits / 8;
for (size_t i = 0; i < num_entire_bytes_in_prefix; ++i) {
if (ip_address[i] != ip_prefix[i])
return false;
}
// In case the prefix was not a multiple of 8, there will be 1 byte
// which is only partially masked.
size_t remaining_bits = prefix_length_in_bits % 8;
if (remaining_bits != 0) {
uint8_t mask = 0xFF << (8 - remaining_bits);
size_t i = num_entire_bytes_in_prefix;
if ((ip_address[i] & mask) != (ip_prefix[i] & mask))
return false;
}
return true;
}
// Returns true if |ip_address| matches any of the reserved IPv4 ranges. This
// method operates on a blacklist of reserved IPv4 ranges. Some ranges are
// consolidated.
// Sources for info:
// www.iana.org/assignments/ipv4-address-space/ipv4-address-space.xhtml
// www.iana.org/assignments/iana-ipv4-special-registry/
// iana-ipv4-special-registry.xhtml
bool IsReservedIPv4(const IPAddressBytes& ip_address) {
// Different IP versions have different range reservations.
DCHECK_EQ(IPAddress::kIPv4AddressSize, ip_address.size());
struct {
const uint8_t address[4];
size_t prefix_length_in_bits;
} static const kReservedIPv4Ranges[] = {
{{0, 0, 0, 0}, 8}, {{10, 0, 0, 0}, 8}, {{100, 64, 0, 0}, 10},
{{127, 0, 0, 0}, 8}, {{169, 254, 0, 0}, 16}, {{172, 16, 0, 0}, 12},
{{192, 0, 2, 0}, 24}, {{192, 88, 99, 0}, 24}, {{192, 168, 0, 0}, 16},
{{198, 18, 0, 0}, 15}, {{198, 51, 100, 0}, 24}, {{203, 0, 113, 0}, 24},
{{224, 0, 0, 0}, 3}};
for (const auto& range : kReservedIPv4Ranges) {
if (IPAddressPrefixCheck(ip_address, range.address,
range.prefix_length_in_bits)) {
return true;
}
}
return false;
}
// Returns true if |ip_address| matches any of the reserved IPv6 ranges. This
// method operates on a whitelist of non-reserved IPv6 ranges. All IPv6
// addresses outside these ranges are reserved.
// Sources for info:
// www.iana.org/assignments/ipv6-address-space/ipv6-address-space.xhtml
bool IsReservedIPv6(const IPAddressBytes& ip_address) {
// Different IP versions have different range reservations.
DCHECK_EQ(IPAddress::kIPv6AddressSize, ip_address.size());
struct {
const uint8_t address_prefix[2];
size_t prefix_length_in_bits;
} static const kPublicIPv6Ranges[] = {
// 2000::/3 -- Global Unicast
{{0x20, 0}, 3},
// ff00::/8 -- Multicast
{{0xff, 0}, 8},
};
for (const auto& range : kPublicIPv6Ranges) {
if (IPAddressPrefixCheck(ip_address, range.address_prefix,
range.prefix_length_in_bits)) {
return false;
}
}
return true;
}
bool ParseIPLiteralToBytes(const base::StringPiece& ip_literal,
IPAddressBytes* bytes) {
// |ip_literal| could be either an IPv4 or an IPv6 literal. If it contains
// a colon however, it must be an IPv6 address.
if (ip_literal.find(':') != base::StringPiece::npos) {
// GURL expects IPv6 hostnames to be surrounded with brackets.
std::string host_brackets = "[";
ip_literal.AppendToString(&host_brackets);
host_brackets.push_back(']');
url::Component host_comp(0, host_brackets.size());
// Try parsing the hostname as an IPv6 literal.
bytes->Resize(16); // 128 bits.
return url::IPv6AddressToNumber(host_brackets.data(), host_comp,
bytes->data());
}
// Otherwise the string is an IPv4 address.
bytes->Resize(4); // 32 bits.
url::Component host_comp(0, ip_literal.size());
int num_components;
url::CanonHostInfo::Family family = url::IPv4AddressToNumber(
ip_literal.data(), host_comp, bytes->data(), &num_components);
return family == url::CanonHostInfo::IPV4;
}
} // namespace
IPAddressBytes::IPAddressBytes() : size_(0) {}
IPAddressBytes::IPAddressBytes(const uint8_t* data, size_t data_len) {
Assign(data, data_len);
}
IPAddressBytes::~IPAddressBytes() = default;
IPAddressBytes::IPAddressBytes(IPAddressBytes const& other) = default;
void IPAddressBytes::Assign(const uint8_t* data, size_t data_len) {
size_ = data_len;
CHECK_GE(16u, data_len);
std::copy_n(data, data_len, bytes_.data());
}
bool IPAddressBytes::operator<(const IPAddressBytes& other) const {
if (size_ == other.size_)
return std::lexicographical_compare(begin(), end(), other.begin(),
other.end());
return size_ < other.size_;
}
bool IPAddressBytes::operator==(const IPAddressBytes& other) const {
return size_ == other.size_ && std::equal(begin(), end(), other.begin());
}
bool IPAddressBytes::operator!=(const IPAddressBytes& other) const {
return !(*this == other);
}
IPAddress::IPAddress() = default;
IPAddress::IPAddress(const IPAddress& other) = default;
IPAddress::IPAddress(const IPAddressBytes& address) : ip_address_(address) {}
IPAddress::IPAddress(const uint8_t* address, size_t address_len)
: ip_address_(address, address_len) {}
IPAddress::IPAddress(uint8_t b0, uint8_t b1, uint8_t b2, uint8_t b3) {
ip_address_.push_back(b0);
ip_address_.push_back(b1);
ip_address_.push_back(b2);
ip_address_.push_back(b3);
}
IPAddress::IPAddress(uint8_t b0,
uint8_t b1,
uint8_t b2,
uint8_t b3,
uint8_t b4,
uint8_t b5,
uint8_t b6,
uint8_t b7,
uint8_t b8,
uint8_t b9,
uint8_t b10,
uint8_t b11,
uint8_t b12,
uint8_t b13,
uint8_t b14,
uint8_t b15) {
ip_address_.push_back(b0);
ip_address_.push_back(b1);
ip_address_.push_back(b2);
ip_address_.push_back(b3);
ip_address_.push_back(b4);
ip_address_.push_back(b5);
ip_address_.push_back(b6);
ip_address_.push_back(b7);
ip_address_.push_back(b8);
ip_address_.push_back(b9);
ip_address_.push_back(b10);
ip_address_.push_back(b11);
ip_address_.push_back(b12);
ip_address_.push_back(b13);
ip_address_.push_back(b14);
ip_address_.push_back(b15);
}
IPAddress::~IPAddress() = default;
bool IPAddress::IsIPv4() const {
return ip_address_.size() == kIPv4AddressSize;
}
bool IPAddress::IsIPv6() const {
return ip_address_.size() == kIPv6AddressSize;
}
bool IPAddress::IsValid() const {
return IsIPv4() || IsIPv6();
}
bool IPAddress::IsReserved() const {
if (IsIPv4()) {
return IsReservedIPv4(ip_address_);
} else if (IsIPv6()) {
return IsReservedIPv6(ip_address_);
}
return false;
}
bool IPAddress::IsZero() const {
for (auto x : ip_address_) {
if (x != 0)
return false;
}
return !empty();
}
bool IPAddress::IsIPv4MappedIPv6() const {
return IsIPv6() && IPAddressStartsWith(*this, kIPv4MappedPrefix);
}
bool IPAddress::AssignFromIPLiteral(const base::StringPiece& ip_literal) {
IPAddressBytes number;
// TODO(rch): change the contract so ip_address_ is cleared on failure,
// to avoid needing this temporary at all.
if (!ParseIPLiteralToBytes(ip_literal, &number))
return false;
ip_address_ = number;
return true;
}
std::vector<uint8_t> IPAddress::CopyBytesToVector() const {
return std::vector<uint8_t>(ip_address_.begin(), ip_address_.end());
}
// static
IPAddress IPAddress::IPv4Localhost() {
static const uint8_t kLocalhostIPv4[] = {127, 0, 0, 1};
return IPAddress(kLocalhostIPv4);
}
// static
IPAddress IPAddress::IPv6Localhost() {
static const uint8_t kLocalhostIPv6[] = {0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 1};
return IPAddress(kLocalhostIPv6);
}
// static
IPAddress IPAddress::AllZeros(size_t num_zero_bytes) {
CHECK_LE(num_zero_bytes, 16u);
IPAddress result;
for (size_t i = 0; i < num_zero_bytes; ++i)
result.ip_address_.push_back(0u);
return result;
}
// static
IPAddress IPAddress::IPv4AllZeros() {
return AllZeros(kIPv4AddressSize);
}
// static
IPAddress IPAddress::IPv6AllZeros() {
return AllZeros(kIPv6AddressSize);
}
bool IPAddress::operator==(const IPAddress& that) const {
return ip_address_ == that.ip_address_;
}
bool IPAddress::operator!=(const IPAddress& that) const {
return ip_address_ != that.ip_address_;
}
bool IPAddress::operator<(const IPAddress& that) const {
// Sort IPv4 before IPv6.
if (ip_address_.size() != that.ip_address_.size()) {
return ip_address_.size() < that.ip_address_.size();
}
return ip_address_ < that.ip_address_;
}
std::string IPAddress::ToString() const {
std::string str;
url::StdStringCanonOutput output(&str);
if (IsIPv4()) {
url::AppendIPv4Address(ip_address_.data(), &output);
} else if (IsIPv6()) {
url::AppendIPv6Address(ip_address_.data(), &output);
}
output.Complete();
return str;
}
std::string IPAddressToStringWithPort(const IPAddress& address, uint16_t port) {
std::string address_str = address.ToString();
if (address_str.empty())
return address_str;
if (address.IsIPv6()) {
// Need to bracket IPv6 addresses since they contain colons.
return base::StringPrintf("[%s]:%d", address_str.c_str(), port);
}
return base::StringPrintf("%s:%d", address_str.c_str(), port);
}
std::string IPAddressToPackedString(const IPAddress& address) {
return std::string(reinterpret_cast<const char*>(address.bytes().data()),
address.size());
}
IPAddress ConvertIPv4ToIPv4MappedIPv6(const IPAddress& address) {
DCHECK(address.IsIPv4());
// IPv4-mapped addresses are formed by:
// <80 bits of zeros> + <16 bits of ones> + <32-bit IPv4 address>.
base::StackVector<uint8_t, 16> bytes;
bytes->insert(bytes->end(), std::begin(kIPv4MappedPrefix),
std::end(kIPv4MappedPrefix));
bytes->insert(bytes->end(), address.bytes().begin(), address.bytes().end());
return IPAddress(bytes->data(), bytes->size());
}
IPAddress ConvertIPv4MappedIPv6ToIPv4(const IPAddress& address) {
DCHECK(address.IsIPv4MappedIPv6());
base::StackVector<uint8_t, 16> bytes;
bytes->insert(bytes->end(),
address.bytes().begin() + arraysize(kIPv4MappedPrefix),
address.bytes().end());
return IPAddress(bytes->data(), bytes->size());
}
bool IPAddressMatchesPrefix(const IPAddress& ip_address,
const IPAddress& ip_prefix,
size_t prefix_length_in_bits) {
// Both the input IP address and the prefix IP address should be either IPv4
// or IPv6.
DCHECK(ip_address.IsValid());
DCHECK(ip_prefix.IsValid());
DCHECK_LE(prefix_length_in_bits, ip_prefix.size() * 8);
// In case we have an IPv6 / IPv4 mismatch, convert the IPv4 addresses to
// IPv6 addresses in order to do the comparison.
if (ip_address.size() != ip_prefix.size()) {
if (ip_address.IsIPv4()) {
return IPAddressMatchesPrefix(ConvertIPv4ToIPv4MappedIPv6(ip_address),
ip_prefix, prefix_length_in_bits);
}
return IPAddressMatchesPrefix(ip_address,
ConvertIPv4ToIPv4MappedIPv6(ip_prefix),
96 + prefix_length_in_bits);
}
return IPAddressPrefixCheck(ip_address.bytes(), ip_prefix.bytes().data(),
prefix_length_in_bits);
}
bool ParseCIDRBlock(const std::string& cidr_literal,
IPAddress* ip_address,
size_t* prefix_length_in_bits) {
// We expect CIDR notation to match one of these two templates:
// <IPv4-literal> "/" <number of bits>
// <IPv6-literal> "/" <number of bits>
std::vector<base::StringPiece> parts = base::SplitStringPiece(
cidr_literal, "/", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL);
if (parts.size() != 2)
return false;
// Parse the IP address.
if (!ip_address->AssignFromIPLiteral(parts[0]))
return false;
// Parse the prefix length.
uint32_t number_of_bits;
if (!ParseUint32(parts[1], &number_of_bits))
return false;
// Make sure the prefix length is in a valid range.
if (number_of_bits > ip_address->size() * 8)
return false;
*prefix_length_in_bits = number_of_bits;
return true;
}
bool ParseURLHostnameToAddress(const base::StringPiece& hostname,
IPAddress* ip_address) {
if (hostname.size() >= 2 && hostname.front() == '[' &&
hostname.back() == ']') {
// Strip the square brackets that surround IPv6 literals.
auto ip_literal =
base::StringPiece(hostname).substr(1, hostname.size() - 2);
return ip_address->AssignFromIPLiteral(ip_literal) && ip_address->IsIPv6();
}
return ip_address->AssignFromIPLiteral(hostname) && ip_address->IsIPv4();
}
unsigned CommonPrefixLength(const IPAddress& a1, const IPAddress& a2) {
DCHECK_EQ(a1.size(), a2.size());
for (size_t i = 0; i < a1.size(); ++i) {
unsigned diff = a1.bytes()[i] ^ a2.bytes()[i];
if (!diff)
continue;
for (unsigned j = 0; j < CHAR_BIT; ++j) {
if (diff & (1 << (CHAR_BIT - 1)))
return i * CHAR_BIT + j;
diff <<= 1;
}
NOTREACHED();
}
return a1.size() * CHAR_BIT;
}
unsigned MaskPrefixLength(const IPAddress& mask) {
base::StackVector<uint8_t, 16> all_ones;
all_ones->resize(mask.size(), 0xFF);
return CommonPrefixLength(mask,
IPAddress(all_ones->data(), all_ones->size()));
}
} // namespace net