mirror of
https://github.com/klzgrad/naiveproxy.git
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391 lines
16 KiB
C++
391 lines
16 KiB
C++
// Copyright 2017 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "net/ntlm/ntlm.h"
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#include <string.h>
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#include "base/logging.h"
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#include "base/md5.h"
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#include "base/strings/utf_string_conversions.h"
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#include "net/base/net_string_util.h"
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#include "net/ntlm/ntlm_buffer_writer.h"
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#include "third_party/boringssl/src/include/openssl/des.h"
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#include "third_party/boringssl/src/include/openssl/hmac.h"
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#include "third_party/boringssl/src/include/openssl/md4.h"
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#include "third_party/boringssl/src/include/openssl/md5.h"
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namespace net {
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namespace ntlm {
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namespace {
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// Takes the parsed target info in |av_pairs| and performs the following
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// actions.
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//
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// 1) If a |TargetInfoAvId::kTimestamp| AvPair exists, |server_timestamp|
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// is set to the payload.
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// 2) If |is_mic_enabled| is true, the existing |TargetInfoAvId::kFlags| AvPair
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// will have the |TargetInfoAvFlags::kMicPresent| bit set. If an existing
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// flags AvPair does not already exist, a new one is added with the value of
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// |TargetInfoAvFlags::kMicPresent|.
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// 3) If |is_epa_enabled| is true, two new AvPair entries will be added to
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// |av_pairs|. The first will be of type |TargetInfoAvId::kChannelBindings|
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// and contains MD5(|channel_bindings|) as the payload. The second will be
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// of type |TargetInfoAvId::kTargetName| and contains |spn| as a little
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// endian UTF16 string.
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// 4) Sets |target_info_len| to the size of |av_pairs| when serialized into
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// a payload.
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void UpdateTargetInfoAvPairs(bool is_mic_enabled,
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bool is_epa_enabled,
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const std::string& channel_bindings,
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const std::string& spn,
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std::vector<AvPair>* av_pairs,
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uint64_t* server_timestamp,
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size_t* target_info_len) {
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// Do a pass to update flags and calculate current length and
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// pull out the server timestamp if it is there.
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*server_timestamp = UINT64_MAX;
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*target_info_len = 0;
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bool need_flags_added = is_mic_enabled;
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for (AvPair& pair : *av_pairs) {
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*target_info_len += pair.avlen + kAvPairHeaderLen;
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switch (pair.avid) {
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case TargetInfoAvId::kFlags:
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// The parsing phase already set the payload to the |flags| field.
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if (is_mic_enabled) {
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pair.flags = pair.flags | TargetInfoAvFlags::kMicPresent;
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}
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need_flags_added = false;
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break;
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case TargetInfoAvId::kTimestamp:
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// The parsing phase already set the payload to the |timestamp| field.
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*server_timestamp = pair.timestamp;
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break;
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case TargetInfoAvId::kEol:
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case TargetInfoAvId::kChannelBindings:
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case TargetInfoAvId::kTargetName:
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// The terminator, |kEol|, should already have been removed from the
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// end of the list and would have been rejected if it has been inside
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// the list. Additionally |kChannelBindings| and |kTargetName| pairs
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// would have been rejected during the initial parsing. See
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// |NtlmBufferReader::ReadTargetInfo|.
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NOTREACHED();
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break;
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default:
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// Ignore entries we don't care about.
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break;
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}
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}
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if (need_flags_added) {
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DCHECK(is_mic_enabled);
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AvPair flags_pair(TargetInfoAvId::kFlags, sizeof(uint32_t));
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flags_pair.flags = TargetInfoAvFlags::kMicPresent;
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av_pairs->push_back(flags_pair);
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*target_info_len += kAvPairHeaderLen + flags_pair.avlen;
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}
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if (is_epa_enabled) {
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Buffer channel_bindings_hash(kChannelBindingsHashLen, 0);
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// Hash the channel bindings if they exist otherwise they remain zeros.
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if (!channel_bindings.empty()) {
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GenerateChannelBindingHashV2(channel_bindings, &channel_bindings_hash[0]);
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}
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av_pairs->emplace_back(TargetInfoAvId::kChannelBindings,
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std::move(channel_bindings_hash));
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// Convert the SPN to little endian unicode.
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base::string16 spn16 = base::UTF8ToUTF16(spn);
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NtlmBufferWriter spn_writer(spn16.length() * 2);
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bool spn_writer_result =
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spn_writer.WriteUtf16String(spn16) && spn_writer.IsEndOfBuffer();
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DCHECK(spn_writer_result);
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av_pairs->emplace_back(TargetInfoAvId::kTargetName, spn_writer.Pass());
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// Add the length of the two new AV Pairs to the total length.
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*target_info_len +=
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(2 * kAvPairHeaderLen) + kChannelBindingsHashLen + (spn16.length() * 2);
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}
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// Add extra space for the terminator at the end.
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*target_info_len += kAvPairHeaderLen;
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}
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Buffer WriteUpdatedTargetInfo(const std::vector<AvPair>& av_pairs,
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size_t updated_target_info_len) {
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bool result = true;
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NtlmBufferWriter writer(updated_target_info_len);
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for (const AvPair& pair : av_pairs) {
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result = writer.WriteAvPair(pair);
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DCHECK(result);
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}
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result = writer.WriteAvPairTerminator() && writer.IsEndOfBuffer();
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DCHECK(result);
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return writer.Pass();
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}
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// Reads 7 bytes (56 bits) from |key_56| and writes them into 8 bytes of
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// |key_64| with 7 bits in every byte. The least significant bits are
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// undefined and a subsequent operation will set those bits with a parity bit.
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// |key_56| must contain 7 bytes.
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// |key_64| must contain 8 bytes.
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void Splay56To64(const uint8_t* key_56, uint8_t* key_64) {
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key_64[0] = key_56[0];
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key_64[1] = key_56[0] << 7 | key_56[1] >> 1;
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key_64[2] = key_56[1] << 6 | key_56[2] >> 2;
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key_64[3] = key_56[2] << 5 | key_56[3] >> 3;
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key_64[4] = key_56[3] << 4 | key_56[4] >> 4;
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key_64[5] = key_56[4] << 3 | key_56[5] >> 5;
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key_64[6] = key_56[5] << 2 | key_56[6] >> 6;
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key_64[7] = key_56[6] << 1;
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}
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} // namespace
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void Create3DesKeysFromNtlmHash(const uint8_t* ntlm_hash, uint8_t* keys) {
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// Put the first 112 bits from |ntlm_hash| into the first 16 bytes of
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// |keys|.
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Splay56To64(ntlm_hash, keys);
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Splay56To64(ntlm_hash + 7, keys + 8);
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// Put the next 2x 7 bits in bytes 16 and 17 of |keys|, then
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// the last 2 bits in byte 18, then zero pad the rest of the final key.
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keys[16] = ntlm_hash[14];
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keys[17] = ntlm_hash[14] << 7 | ntlm_hash[15] >> 1;
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keys[18] = ntlm_hash[15] << 6;
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memset(keys + 19, 0, 5);
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}
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void GenerateNtlmHashV1(const base::string16& password, uint8_t* hash) {
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size_t length = password.length() * 2;
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NtlmBufferWriter writer(length);
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// The writer will handle the big endian case if necessary.
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bool result = writer.WriteUtf16String(password) && writer.IsEndOfBuffer();
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DCHECK(result);
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MD4(writer.GetBuffer().data(), writer.GetLength(), hash);
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}
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void GenerateResponseDesl(const uint8_t* hash,
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const uint8_t* challenge,
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uint8_t* response) {
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constexpr size_t block_count = 3;
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constexpr size_t block_size = sizeof(DES_cblock);
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static_assert(kChallengeLen == block_size,
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"kChallengeLen must equal block_size");
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static_assert(kResponseLenV1 == block_count * block_size,
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"kResponseLenV1 must equal block_count * block_size");
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const DES_cblock* challenge_block =
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reinterpret_cast<const DES_cblock*>(challenge);
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uint8_t keys[block_count * block_size];
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// Map the NTLM hash to three 8 byte DES keys, with 7 bits of the key in each
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// byte and the least significant bit set with odd parity. Then encrypt the
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// 8 byte challenge with each of the three keys. This produces three 8 byte
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// encrypted blocks into |response|.
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Create3DesKeysFromNtlmHash(hash, keys);
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for (size_t ix = 0; ix < block_count * block_size; ix += block_size) {
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DES_cblock* key_block = reinterpret_cast<DES_cblock*>(keys + ix);
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DES_cblock* response_block = reinterpret_cast<DES_cblock*>(response + ix);
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DES_key_schedule key_schedule;
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DES_set_odd_parity(key_block);
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DES_set_key(key_block, &key_schedule);
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DES_ecb_encrypt(challenge_block, response_block, &key_schedule,
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DES_ENCRYPT);
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}
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}
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void GenerateNtlmResponseV1(const base::string16& password,
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const uint8_t* challenge,
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uint8_t* ntlm_response) {
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uint8_t ntlm_hash[kNtlmHashLen];
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GenerateNtlmHashV1(password, ntlm_hash);
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GenerateResponseDesl(ntlm_hash, challenge, ntlm_response);
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}
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void GenerateResponsesV1(const base::string16& password,
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const uint8_t* server_challenge,
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uint8_t* lm_response,
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uint8_t* ntlm_response) {
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GenerateNtlmResponseV1(password, server_challenge, ntlm_response);
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// In NTLM v1 (with LMv1 disabled), the lm_response and ntlm_response are the
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// same. So just copy the ntlm_response into the lm_response.
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memcpy(lm_response, ntlm_response, kResponseLenV1);
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}
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void GenerateLMResponseV1WithSessionSecurity(const uint8_t* client_challenge,
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uint8_t* lm_response) {
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// In NTLM v1 with Session Security (aka NTLM2) the lm_response is 8 bytes of
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// client challenge and 16 bytes of zeros. (See 3.3.1)
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memcpy(lm_response, client_challenge, kChallengeLen);
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memset(lm_response + kChallengeLen, 0, kResponseLenV1 - kChallengeLen);
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}
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void GenerateSessionHashV1WithSessionSecurity(const uint8_t* server_challenge,
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const uint8_t* client_challenge,
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uint8_t* session_hash) {
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MD5_CTX ctx;
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MD5_Init(&ctx);
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MD5_Update(&ctx, server_challenge, kChallengeLen);
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MD5_Update(&ctx, client_challenge, kChallengeLen);
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MD5_Final(session_hash, &ctx);
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}
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void GenerateNtlmResponseV1WithSessionSecurity(const base::string16& password,
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const uint8_t* server_challenge,
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const uint8_t* client_challenge,
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uint8_t* ntlm_response) {
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// Generate the NTLMv1 Hash.
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uint8_t ntlm_hash[kNtlmHashLen];
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GenerateNtlmHashV1(password, ntlm_hash);
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// Generate the NTLMv1 Session Hash.
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uint8_t session_hash[kNtlmHashLen];
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GenerateSessionHashV1WithSessionSecurity(server_challenge, client_challenge,
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session_hash);
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// Only the first 8 bytes of |session_hash| are actually used.
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GenerateResponseDesl(ntlm_hash, session_hash, ntlm_response);
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}
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void GenerateResponsesV1WithSessionSecurity(const base::string16& password,
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const uint8_t* server_challenge,
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const uint8_t* client_challenge,
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uint8_t* lm_response,
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uint8_t* ntlm_response) {
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GenerateLMResponseV1WithSessionSecurity(client_challenge, lm_response);
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GenerateNtlmResponseV1WithSessionSecurity(password, server_challenge,
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client_challenge, ntlm_response);
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}
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void GenerateNtlmHashV2(const base::string16& domain,
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const base::string16& username,
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const base::string16& password,
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uint8_t* v2_hash) {
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// NOTE: According to [MS-NLMP] Section 3.3.2 only the username and not the
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// domain is uppercased.
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base::string16 upper_username;
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bool result = ToUpper(username, &upper_username);
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DCHECK(result);
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uint8_t v1_hash[kNtlmHashLen];
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GenerateNtlmHashV1(password, v1_hash);
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NtlmBufferWriter input_writer((upper_username.length() + domain.length()) *
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2);
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bool writer_result = input_writer.WriteUtf16String(upper_username) &&
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input_writer.WriteUtf16String(domain) &&
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input_writer.IsEndOfBuffer();
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DCHECK(writer_result);
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unsigned int outlen = kNtlmHashLen;
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v2_hash =
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HMAC(EVP_md5(), v1_hash, sizeof(v1_hash), input_writer.GetBuffer().data(),
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input_writer.GetLength(), v2_hash, &outlen);
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DCHECK_NE(nullptr, v2_hash);
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DCHECK_EQ(sizeof(v1_hash), outlen);
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}
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Buffer GenerateProofInputV2(uint64_t timestamp,
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const uint8_t* client_challenge) {
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NtlmBufferWriter writer(kProofInputLenV2);
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bool result = writer.WriteUInt16(kProofInputVersionV2) &&
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writer.WriteZeros(6) && writer.WriteUInt64(timestamp) &&
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writer.WriteBytes(client_challenge, kChallengeLen) &&
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writer.WriteZeros(4) && writer.IsEndOfBuffer();
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DCHECK(result);
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return writer.Pass();
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}
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void GenerateNtlmProofV2(const uint8_t* v2_hash,
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const uint8_t* server_challenge,
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const Buffer& v2_input,
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const Buffer& target_info,
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uint8_t* v2_proof) {
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DCHECK_EQ(kProofInputLenV2, v2_input.size());
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bssl::ScopedHMAC_CTX ctx;
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HMAC_Init_ex(ctx.get(), v2_hash, kNtlmHashLen, EVP_md5(), NULL);
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DCHECK_EQ(kNtlmProofLenV2, HMAC_size(ctx.get()));
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HMAC_Update(ctx.get(), server_challenge, kChallengeLen);
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HMAC_Update(ctx.get(), v2_input.data(), v2_input.size());
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HMAC_Update(ctx.get(), target_info.data(), target_info.size());
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const uint32_t zero = 0;
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HMAC_Update(ctx.get(), reinterpret_cast<const uint8_t*>(&zero),
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sizeof(uint32_t));
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HMAC_Final(ctx.get(), v2_proof, nullptr);
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}
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void GenerateSessionBaseKeyV2(const uint8_t* v2_hash,
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const uint8_t* v2_proof,
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uint8_t* session_key) {
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unsigned int outlen = kSessionKeyLenV2;
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session_key = HMAC(EVP_md5(), v2_hash, kNtlmHashLen, v2_proof,
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kNtlmProofLenV2, session_key, &outlen);
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DCHECK_NE(nullptr, session_key);
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DCHECK_EQ(kSessionKeyLenV2, outlen);
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}
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void GenerateChannelBindingHashV2(const std::string& channel_bindings,
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uint8_t* channel_bindings_hash) {
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NtlmBufferWriter writer(kEpaUnhashedStructHeaderLen);
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bool result = writer.WriteZeros(16) &&
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writer.WriteUInt32(channel_bindings.length()) &&
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writer.IsEndOfBuffer();
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DCHECK(result);
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MD5_CTX ctx;
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MD5_Init(&ctx);
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MD5_Update(&ctx, writer.GetBuffer().data(), writer.GetBuffer().size());
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MD5_Update(&ctx, channel_bindings.data(), channel_bindings.size());
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MD5_Final(channel_bindings_hash, &ctx);
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}
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void GenerateMicV2(const uint8_t* session_key,
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const Buffer& negotiate_msg,
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const Buffer& challenge_msg,
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const Buffer& authenticate_msg,
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uint8_t* mic) {
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bssl::ScopedHMAC_CTX ctx;
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HMAC_Init_ex(ctx.get(), session_key, kNtlmHashLen, EVP_md5(), NULL);
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DCHECK_EQ(kMicLenV2, HMAC_size(ctx.get()));
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HMAC_Update(ctx.get(), negotiate_msg.data(), negotiate_msg.size());
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HMAC_Update(ctx.get(), challenge_msg.data(), challenge_msg.size());
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HMAC_Update(ctx.get(), authenticate_msg.data(), authenticate_msg.size());
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HMAC_Final(ctx.get(), mic, nullptr);
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}
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#if defined(__clang__)
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[[clang::optnone]] // TODO(crbug.com/769759) Clang crashes on this function.
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#endif
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NET_EXPORT_PRIVATE Buffer
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GenerateUpdatedTargetInfo(bool is_mic_enabled,
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bool is_epa_enabled,
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const std::string& channel_bindings,
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const std::string& spn,
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const std::vector<AvPair>& av_pairs,
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uint64_t* server_timestamp) {
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size_t updated_target_info_len = 0;
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std::vector<AvPair> updated_av_pairs(av_pairs);
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UpdateTargetInfoAvPairs(is_mic_enabled, is_epa_enabled, channel_bindings, spn,
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&updated_av_pairs, server_timestamp,
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&updated_target_info_len);
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return WriteUpdatedTargetInfo(updated_av_pairs, updated_target_info_len);
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}
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} // namespace ntlm
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} // namespace net
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