tdlight/td/mtproto/TcpTransport.cpp
levlam eb9ead582f Remove unneded includes of td/utils/loggging.h.
GitOrigin-RevId: 82a3b506dba5c9d5267dc0e2504a7093a7fa87db
2019-02-12 23:48:16 +03:00

201 lines
5.9 KiB
C++

//
// Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2019
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
#include "td/mtproto/TcpTransport.h"
#include "td/utils/as.h"
#include "td/utils/common.h"
#include "td/utils/Random.h"
#include "td/utils/Slice.h"
#include <algorithm>
namespace td {
namespace mtproto {
namespace tcp {
size_t IntermediateTransport::read_from_stream(ChainBufferReader *stream, BufferSlice *message, uint32 *quick_ack) {
CHECK(message);
size_t stream_size = stream->size();
size_t header_size = 4;
if (stream->size() < header_size) {
return header_size;
}
uint32 data_size;
auto it = stream->clone();
it.advance(header_size, MutableSlice(reinterpret_cast<uint8 *>(&data_size), sizeof(data_size)));
if (data_size & (1u << 31)) {
if (quick_ack) {
*quick_ack = data_size;
}
stream->advance(header_size);
return 0;
}
size_t total_size = data_size + header_size;
if (stream_size < total_size) {
// optimization
// stream->make_solid(total_size);
return total_size;
}
stream->advance(header_size);
*message = stream->cut_head(data_size).move_as_buffer_slice();
return 0;
}
void IntermediateTransport::write_prepare_inplace(BufferWriter *message, bool quick_ack) {
size_t size = message->size();
CHECK(size % 4 == 0);
CHECK(size < (1 << 24));
if (quick_ack) {
size |= static_cast<size_t>(1) << 31;
}
size_t prepend_size = 4;
MutableSlice prepend = message->prepare_prepend();
CHECK(prepend.size() >= prepend_size);
message->confirm_prepend(prepend_size);
size_t append_size = 0;
if (with_padding()) {
append_size = static_cast<uint32>(Random::secure_int32()) % 16;
MutableSlice append = message->prepare_append().truncate(append_size);
CHECK(append.size() == append_size);
Random::secure_bytes(append);
message->confirm_append(append.size());
}
as<uint32>(message->as_slice().begin()) = static_cast<uint32>(size + append_size);
}
void IntermediateTransport::init_output_stream(ChainBufferWriter *stream) {
const uint32 magic = with_padding() ? 0xdddddddd : 0xeeeeeeee;
stream->append(Slice(reinterpret_cast<const char *>(&magic), 4));
}
size_t AbridgedTransport::read_from_stream(ChainBufferReader *stream, BufferSlice *message, uint32 *quick_ack) {
if (stream->empty()) {
return 1;
}
uint8 byte = 0;
stream->clone().advance(1, MutableSlice(&byte, 1));
size_t header_size;
uint32 data_size;
if (byte < 0x7f) {
header_size = 1;
data_size = byte * 4u;
} else {
if (stream->size() < 4) {
return 4;
}
header_size = 4;
stream->clone().advance(4, MutableSlice(reinterpret_cast<char *>(&data_size), sizeof(data_size)));
data_size >>= 8;
data_size = data_size * 4;
}
size_t total_size = header_size + data_size;
if (stream->size() < total_size) {
// optimization
// stream->make_solid(total_size);
return total_size;
}
stream->advance(header_size);
*message = stream->cut_head(data_size).move_as_buffer_slice();
return 0;
}
void AbridgedTransport::write_prepare_inplace(BufferWriter *message, bool quick_ack) {
CHECK(!quick_ack);
size_t size = message->size() / 4;
CHECK(size % 4 == 0);
CHECK(size < 1 << 24);
size_t prepend_size = size >= 0x7f ? 4 : 1;
MutableSlice prepend = message->prepare_prepend();
CHECK(prepend.size() >= prepend_size);
message->confirm_prepend(prepend_size);
MutableSlice data = message->as_slice();
if (size >= 0x7f) {
uint32 size_encoded = 0x7f + (static_cast<uint32>(size) << 8);
as<uint32>(data.begin()) = size_encoded;
} else {
as<uint8>(data.begin()) = static_cast<uint8>(size);
}
}
void AbridgedTransport::init_output_stream(ChainBufferWriter *stream) {
stream->append("\xef");
}
void ObfuscatedTransport::init(ChainBufferReader *input, ChainBufferWriter *output) {
input_ = input;
output_ = output;
const size_t header_size = 64;
string header(header_size, '\0');
MutableSlice header_slice = header;
int32 try_cnt = 0;
while (true) {
try_cnt++;
CHECK(try_cnt < 10);
Random::secure_bytes(header_slice.ubegin(), header.size());
if (as<uint8>(header.data()) == 0xef) {
continue;
}
uint32 first_int = as<uint32>(header.data());
if (first_int == 0x44414548 || first_int == 0x54534f50 || first_int == 0x20544547 || first_int == 0x4954504f ||
first_int == 0xdddddddd || first_int == 0xeeeeeeee) {
continue;
}
uint32 second_int = as<uint32>(header.data() + sizeof(uint32));
if (second_int == 0) {
continue;
}
break;
}
// TODO: It is actually IntermediateTransport::init_output_stream, so it will work only with
// TransportImpl==IntermediateTransport
as<uint32>(header_slice.begin() + 56) = impl_.with_padding() ? 0xdddddddd : 0xeeeeeeee;
if (dc_id_ != 0) {
as<int16>(header_slice.begin() + 60) = dc_id_;
}
string rheader = header;
std::reverse(rheader.begin(), rheader.end());
UInt256 key = as<UInt256>(rheader.data() + 8);
if (secret_.size() == 17) {
secret_ = secret_.substr(1);
}
auto fix_key = [&](UInt256 &key) {
if (secret_.size() == 16) {
Sha256State state;
sha256_init(&state);
sha256_update(as_slice(key), &state);
sha256_update(secret_, &state);
sha256_final(&state, as_slice(key));
}
};
fix_key(key);
aes_ctr_byte_flow_.init(key, as<UInt128>(rheader.data() + 8 + 32));
aes_ctr_byte_flow_.set_input(input_);
aes_ctr_byte_flow_ >> byte_flow_sink_;
output_key_ = as<UInt256>(header.data() + 8);
fix_key(output_key_);
output_state_.init(output_key_, as<UInt128>(header.data() + 8 + 32));
output_->append(header_slice.substr(0, 56));
output_state_.encrypt(header_slice, header_slice);
output_->append(header_slice.substr(56, 8));
}
} // namespace tcp
} // namespace mtproto
} // namespace td