Nagram/TMessagesProj/jni/libtgvoip2/os/windows/CXWrapper.cpp

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2020-03-30 12:00:09 +00:00
#include <stdlib.h>
#include <string.h>
#include <windows.h>
#include <vector>
#include <string>
#include <collection.h>
#include "CXWrapper.h"
#include <wrl.h>
#include <robuffer.h>
using namespace Windows::Storage::Streams;
using namespace Microsoft::WRL;
using namespace libtgvoip;
using namespace Platform;
using namespace tgvoip;
using namespace Windows::Security::Cryptography;
using namespace Windows::Security::Cryptography::Core;
using namespace Windows::Storage::Streams;
using namespace Windows::Data::Json;
using namespace Windows::Phone::Media::Devices;
//CryptographicHash^ MicrosoftCryptoImpl::sha1Hash;
//CryptographicHash^ MicrosoftCryptoImpl::sha256Hash;
HashAlgorithmProvider^ MicrosoftCryptoImpl::sha1Provider;
HashAlgorithmProvider^ MicrosoftCryptoImpl::sha256Provider;
SymmetricKeyAlgorithmProvider^ MicrosoftCryptoImpl::aesKeyProvider;
/*struct tgvoip_cx_data{
VoIPControllerWrapper^ self;
};*/
VoIPControllerWrapper::VoIPControllerWrapper(){
VoIPController::crypto.aes_ige_decrypt=MicrosoftCryptoImpl::AesIgeDecrypt;
VoIPController::crypto.aes_ige_encrypt=MicrosoftCryptoImpl::AesIgeEncrypt;
VoIPController::crypto.aes_ctr_encrypt = MicrosoftCryptoImpl::AesCtrEncrypt;
VoIPController::crypto.sha1=MicrosoftCryptoImpl::SHA1;
VoIPController::crypto.sha256=MicrosoftCryptoImpl::SHA256;
VoIPController::crypto.rand_bytes=MicrosoftCryptoImpl::RandBytes;
MicrosoftCryptoImpl::Init();
controller=new VoIPController();
controller->implData=(void*)this;
VoIPController::Callbacks callbacks={0};
callbacks.connectionStateChanged=VoIPControllerWrapper::OnStateChanged;
callbacks.signalBarCountChanged=VoIPControllerWrapper::OnSignalBarsChanged;
controller->SetCallbacks(callbacks);
}
VoIPControllerWrapper::~VoIPControllerWrapper(){
controller->Stop();
delete controller;
}
void VoIPControllerWrapper::Start(){
controller->Start();
}
void VoIPControllerWrapper::Connect(){
controller->Connect();
}
void VoIPControllerWrapper::SetPublicEndpoints(const Platform::Array<libtgvoip::Endpoint^>^ endpoints, bool allowP2P, int32_t connectionMaxLayer){
std::vector<tgvoip::Endpoint> eps;
for (unsigned int i = 0; i < endpoints->Length; i++)
{
libtgvoip::Endpoint^ _ep = endpoints[i];
tgvoip::Endpoint ep;
ep.id = _ep->id;
ep.type = tgvoip::Endpoint::Type::UDP_RELAY;
char buf[128];
if (_ep->ipv4){
WideCharToMultiByte(CP_UTF8, 0, _ep->ipv4->Data(), -1, buf, sizeof(buf), NULL, NULL);
ep.address = NetworkAddress::IPv4(buf);
}
if (_ep->ipv6){
WideCharToMultiByte(CP_UTF8, 0, _ep->ipv6->Data(), -1, buf, sizeof(buf), NULL, NULL);
ep.v6address = NetworkAddress::IPv6(buf);
}
ep.port = _ep->port;
if (_ep->peerTag->Length != 16)
throw ref new Platform::InvalidArgumentException("Peer tag must be exactly 16 bytes long");
memcpy(ep.peerTag, _ep->peerTag->Data, 16);
eps.push_back(ep);
}
controller->SetRemoteEndpoints(eps, allowP2P, connectionMaxLayer);
}
void VoIPControllerWrapper::SetNetworkType(NetworkType type){
controller->SetNetworkType((int)type);
}
void VoIPControllerWrapper::SetMicMute(bool mute){
controller->SetMicMute(mute);
}
int64 VoIPControllerWrapper::GetPreferredRelayID(){
return controller->GetPreferredRelayID();
}
int32_t VoIPControllerWrapper::GetConnectionMaxLayer(){
return tgvoip::VoIPController::GetConnectionMaxLayer();
}
void VoIPControllerWrapper::SetEncryptionKey(const Platform::Array<uint8>^ key, bool isOutgoing){
if(key->Length!=256)
throw ref new Platform::InvalidArgumentException("Encryption key must be exactly 256 bytes long");
controller->SetEncryptionKey((char*)key->Data, isOutgoing);
}
int VoIPControllerWrapper::GetSignalBarsCount(){
return controller->GetSignalBarsCount();
}
CallState VoIPControllerWrapper::GetConnectionState(){
return (CallState)controller->GetConnectionState();
}
TrafficStats^ VoIPControllerWrapper::GetStats(){
tgvoip::VoIPController::TrafficStats _stats;
controller->GetStats(&_stats);
TrafficStats^ stats = ref new TrafficStats();
stats->bytesSentWifi = _stats.bytesSentWifi;
stats->bytesSentMobile = _stats.bytesSentMobile;
stats->bytesRecvdWifi = _stats.bytesRecvdWifi;
stats->bytesRecvdMobile = _stats.bytesRecvdMobile;
return stats;
}
Platform::String^ VoIPControllerWrapper::GetDebugString(){
std::string log = controller->GetDebugString();
size_t len = sizeof(wchar_t)*(log.length() + 1);
wchar_t* wlog = (wchar_t*)malloc(len);
MultiByteToWideChar(CP_UTF8, 0, log.c_str(), -1, wlog, len / sizeof(wchar_t));
Platform::String^ res = ref new Platform::String(wlog);
free(wlog);
return res;
}
Platform::String^ VoIPControllerWrapper::GetDebugLog(){
std::string log=controller->GetDebugLog();
size_t len=sizeof(wchar_t)*(log.length()+1);
wchar_t* wlog=(wchar_t*)malloc(len);
MultiByteToWideChar(CP_UTF8, 0, log.c_str(), -1, wlog, len/sizeof(wchar_t));
Platform::String^ res=ref new Platform::String(wlog);
free(wlog);
return res;
}
Error VoIPControllerWrapper::GetLastError(){
return (Error)controller->GetLastError();
}
Platform::String^ VoIPControllerWrapper::GetVersion(){
const char* v=VoIPController::GetVersion();
wchar_t buf[32];
MultiByteToWideChar(CP_UTF8, 0, v, -1, buf, sizeof(buf));
return ref new Platform::String(buf);
}
void VoIPControllerWrapper::OnStateChanged(VoIPController* c, int state){
reinterpret_cast<VoIPControllerWrapper^>(c->implData)->OnStateChangedInternal(state);
}
void VoIPControllerWrapper::OnSignalBarsChanged(VoIPController* c, int count){
reinterpret_cast<VoIPControllerWrapper^>(c->implData)->OnSignalBarsChangedInternal(count);
}
void VoIPControllerWrapper::OnStateChangedInternal(int state){
CallStateChanged(this, (CallState)state);
}
void VoIPControllerWrapper::OnSignalBarsChangedInternal(int count){
SignalBarsChanged(this, count);
}
void VoIPControllerWrapper::SetConfig(VoIPConfig^ wrapper){
VoIPController::Config config{0};
config.initTimeout=wrapper->initTimeout;
config.recvTimeout=wrapper->recvTimeout;
config.dataSaving=(int)wrapper->dataSaving;
config.logFilePath;
config.statsDumpFilePath;
config.enableAEC=wrapper->enableAEC;
config.enableNS=wrapper->enableNS;
config.enableAGC=wrapper->enableAGC;
config.enableCallUpgrade=wrapper->enableCallUpgrade;
config.logPacketStats=wrapper->logPacketStats;
config.enableVolumeControl=wrapper->enableVolumeControl;
config.enableVideoSend=wrapper->enableVideoSend;
config.enableVideoReceive=wrapper->enableVideoReceive;
if(wrapper->logFilePath!=nullptr&&!wrapper->logFilePath->IsEmpty()){
config.logFilePath = wstring(wrapper->logFilePath->Data());
}
if (wrapper->statsDumpFilePath != nullptr&&!wrapper->statsDumpFilePath->IsEmpty()){
config.statsDumpFilePath = wstring(wrapper->statsDumpFilePath->Data());
}
controller->SetConfig(config);
}
void VoIPControllerWrapper::SetProxy(ProxyProtocol protocol, Platform::String^ address, uint16_t port, Platform::String^ username, Platform::String^ password){
char _address[2000];
char _username[256];
char _password[256];
WideCharToMultiByte(CP_UTF8, 0, address->Data(), -1, _address, sizeof(_address), NULL, NULL);
WideCharToMultiByte(CP_UTF8, 0, username->Data(), -1, _username, sizeof(_username), NULL, NULL);
WideCharToMultiByte(CP_UTF8, 0, password->Data(), -1, _password, sizeof(_password), NULL, NULL);
controller->SetProxy((int)protocol, _address, port, _username, _password);
}
void VoIPControllerWrapper::SetAudioOutputGainControlEnabled(bool enabled){
controller->SetAudioOutputGainControlEnabled(enabled);
}
void VoIPControllerWrapper::SetInputVolume(float level){
controller->SetInputVolume(level);
}
void VoIPControllerWrapper::SetOutputVolume(float level){
controller->SetOutputVolume(level);
}
void VoIPControllerWrapper::UpdateServerConfig(Platform::String^ json){
std::string config=ToUtf8(json->Data(), json->Length());
ServerConfig::GetSharedInstance()->Update(config);
}
void VoIPControllerWrapper::SwitchSpeaker(bool external){
auto routingManager = AudioRoutingManager::GetDefault();
if (external){
routingManager->SetAudioEndpoint(AudioRoutingEndpoint::Speakerphone);
}
else{
if ((routingManager->AvailableAudioEndpoints & AvailableAudioRoutingEndpoints::Bluetooth) == AvailableAudioRoutingEndpoints::Bluetooth){
routingManager->SetAudioEndpoint(AudioRoutingEndpoint::Bluetooth);
}
else if ((routingManager->AvailableAudioEndpoints & AvailableAudioRoutingEndpoints::Earpiece) == AvailableAudioRoutingEndpoints::Earpiece){
routingManager->SetAudioEndpoint(AudioRoutingEndpoint::Earpiece);
}
}
}
void MicrosoftCryptoImpl::AesIgeEncrypt(uint8_t* in, uint8_t* out, size_t len, uint8_t* key, uint8_t* iv){
IBuffer^ keybuf=IBufferFromPtr(key, 32);
CryptographicKey^ _key=aesKeyProvider->CreateSymmetricKey(keybuf);
uint8_t tmpOut[16];
uint8_t* xPrev=iv+16;
uint8_t* yPrev=iv;
uint8_t x[16];
uint8_t y[16];
for(size_t offset=0;offset<len;offset+=16){
for (size_t i=0;i<16;i++){
if (offset+i < len){
x[i] = in[offset+i];
}
else{
x[i]=0;
}
}
XorInt128(x, yPrev, y);
IBuffer^ inbuf=IBufferFromPtr(y, 16);
IBuffer^ outbuf=CryptographicEngine::Encrypt(_key, inbuf, nullptr);
IBufferToPtr(outbuf, 16, tmpOut);
XorInt128(tmpOut, xPrev, y);
memcpy(xPrev, x, 16);
memcpy(yPrev, y, 16);
memcpy(out+offset, y, 16);
}
}
void MicrosoftCryptoImpl::AesIgeDecrypt(uint8_t* in, uint8_t* out, size_t len, uint8_t* key, uint8_t* iv){
IBuffer^ keybuf=IBufferFromPtr(key, 32);
CryptographicKey^ _key=aesKeyProvider->CreateSymmetricKey(keybuf);
uint8_t tmpOut[16];
uint8_t* xPrev=iv;
uint8_t* yPrev=iv+16;
uint8_t x[16];
uint8_t y[16];
for(size_t offset=0;offset<len;offset+=16){
for (size_t i=0;i<16;i++){
if (offset+i < len){
x[i] = in[offset+i];
}
else{
x[i]=0;
}
}
XorInt128(x, yPrev, y);
IBuffer^ inbuf=IBufferFromPtr(y, 16);
IBuffer^ outbuf=CryptographicEngine::Decrypt(_key, inbuf, nullptr);
IBufferToPtr(outbuf, 16, tmpOut);
XorInt128(tmpOut, xPrev, y);
memcpy(xPrev, x, 16);
memcpy(yPrev, y, 16);
memcpy(out+offset, y, 16);
}
}
#define GETU32(pt) (((uint32_t)(pt)[0] << 24) ^ ((uint32_t)(pt)[1] << 16) ^ ((uint32_t)(pt)[2] << 8) ^ ((uint32_t)(pt)[3]))
#define PUTU32(ct, st) { (ct)[0] = (u8)((st) >> 24); (ct)[1] = (u8)((st) >> 16); (ct)[2] = (u8)((st) >> 8); (ct)[3] = (u8)(st); }
typedef uint8_t u8;
#define L_ENDIAN
/* increment counter (128-bit int) by 2^64 */
static void AES_ctr128_inc(unsigned char *counter) {
unsigned long c;
/* Grab 3rd dword of counter and increment */
#ifdef L_ENDIAN
c = GETU32(counter + 8);
c++;
PUTU32(counter + 8, c);
#else
c = GETU32(counter + 4);
c++;
PUTU32(counter + 4, c);
#endif
/* if no overflow, we're done */
if (c)
return;
/* Grab top dword of counter and increment */
#ifdef L_ENDIAN
c = GETU32(counter + 12);
c++;
PUTU32(counter + 12, c);
#else
c = GETU32(counter + 0);
c++;
PUTU32(counter + 0, c);
#endif
}
void MicrosoftCryptoImpl::AesCtrEncrypt(uint8_t* inout, size_t len, uint8_t* key, uint8_t* counter, uint8_t* ecount_buf, uint32_t* num){
unsigned int n;
unsigned long l = len;
//assert(in && out && key && counter && num);
//assert(*num < AES_BLOCK_SIZE);
IBuffer^ keybuf = IBufferFromPtr(key, 32);
CryptographicKey^ _key = aesKeyProvider->CreateSymmetricKey(keybuf);
n = *num;
while (l--) {
if (n == 0) {
IBuffer^ inbuf = IBufferFromPtr(counter, 16);
IBuffer^ outbuf = CryptographicEngine::Encrypt(_key, inbuf, nullptr);
IBufferToPtr(outbuf, 16, ecount_buf);
//AES_encrypt(counter, ecount_buf, key);
AES_ctr128_inc(counter);
}
*inout = *(inout++) ^ ecount_buf[n];
n = (n + 1) % 16;
}
*num = n;
}
void MicrosoftCryptoImpl::SHA1(uint8_t* msg, size_t len, uint8_t* out){
//EnterCriticalSection(&hashMutex);
IBuffer^ arr=IBufferFromPtr(msg, len);
CryptographicHash^ hash=sha1Provider->CreateHash();
hash->Append(arr);
IBuffer^ res=hash->GetValueAndReset();
IBufferToPtr(res, 20, out);
//LeaveCriticalSection(&hashMutex);
}
void MicrosoftCryptoImpl::SHA256(uint8_t* msg, size_t len, uint8_t* out){
//EnterCriticalSection(&hashMutex);
IBuffer^ arr=IBufferFromPtr(msg, len);
CryptographicHash^ hash=sha256Provider->CreateHash();
hash->Append(arr);
IBuffer^ res=hash->GetValueAndReset();
IBufferToPtr(res, 32, out);
//LeaveCriticalSection(&hashMutex);
}
void MicrosoftCryptoImpl::RandBytes(uint8_t* buffer, size_t len){
IBuffer^ res=CryptographicBuffer::GenerateRandom(len);
IBufferToPtr(res, len, buffer);
}
void MicrosoftCryptoImpl::Init(){
/*sha1Hash=HashAlgorithmProvider::OpenAlgorithm(HashAlgorithmNames::Sha1)->CreateHash();
sha256Hash=HashAlgorithmProvider::OpenAlgorithm(HashAlgorithmNames::Sha256)->CreateHash();*/
sha1Provider=HashAlgorithmProvider::OpenAlgorithm(HashAlgorithmNames::Sha1);
sha256Provider=HashAlgorithmProvider::OpenAlgorithm(HashAlgorithmNames::Sha256);
aesKeyProvider=SymmetricKeyAlgorithmProvider::OpenAlgorithm(SymmetricAlgorithmNames::AesEcb);
}
void MicrosoftCryptoImpl::XorInt128(uint8_t* a, uint8_t* b, uint8_t* out){
uint64_t* _a=reinterpret_cast<uint64_t*>(a);
uint64_t* _b=reinterpret_cast<uint64_t*>(b);
uint64_t* _out=reinterpret_cast<uint64_t*>(out);
_out[0]=_a[0]^_b[0];
_out[1]=_a[1]^_b[1];
}
void MicrosoftCryptoImpl::IBufferToPtr(IBuffer^ buffer, size_t len, uint8_t* out)
{
ComPtr<IBufferByteAccess> bufferByteAccess;
reinterpret_cast<IInspectable*>(buffer)->QueryInterface(IID_PPV_ARGS(&bufferByteAccess));
byte* hashBuffer;
bufferByteAccess->Buffer(&hashBuffer);
CopyMemory(out, hashBuffer, len);
}
IBuffer^ MicrosoftCryptoImpl::IBufferFromPtr(uint8_t* msg, size_t len)
{
ComPtr<NativeBuffer> nativeBuffer=Make<NativeBuffer>((byte *)msg, len);
return reinterpret_cast<IBuffer^>(nativeBuffer.Get());
}
/*Platform::String^ VoIPControllerWrapper::TestAesIge(){
MicrosoftCryptoImpl::Init();
Platform::String^ res="";
Platform::Array<uint8>^ data=ref new Platform::Array<uint8>(32);
Platform::Array<uint8>^ out=ref new Platform::Array<uint8>(32);
Platform::Array<uint8>^ key=ref new Platform::Array<uint8>(16);
Platform::Array<uint8>^ iv=ref new Platform::Array<uint8>(32);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("0000000000000000000000000000000000000000000000000000000000000000"), &data);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f"), &iv);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("000102030405060708090a0b0c0d0e0f"), &key);
MicrosoftCryptoImpl::AesIgeEncrypt(data->Data, out->Data, 32, key->Data, iv->Data);
res+=CryptographicBuffer::EncodeToHexString(CryptographicBuffer::CreateFromByteArray(out));
res+="\n";
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("1A8519A6557BE652E9DA8E43DA4EF4453CF456B4CA488AA383C79C98B34797CB"), &data);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f"), &iv);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("000102030405060708090a0b0c0d0e0f"), &key);
MicrosoftCryptoImpl::AesIgeDecrypt(data->Data, out->Data, 32, key->Data, iv->Data);
res+=CryptographicBuffer::EncodeToHexString(CryptographicBuffer::CreateFromByteArray(out));
res+="\n";
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("99706487A1CDE613BC6DE0B6F24B1C7AA448C8B9C3403E3467A8CAD89340F53B"), &data);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("6D656E746174696F6E206F6620494745206D6F646520666F72204F70656E5353"), &iv);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("5468697320697320616E20696D706C65"), &key);
MicrosoftCryptoImpl::AesIgeEncrypt(data->Data, out->Data, 32, key->Data, iv->Data);
res+=CryptographicBuffer::EncodeToHexString(CryptographicBuffer::CreateFromByteArray(out));
res+="\n";
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("4C2E204C6574277320686F70652042656E20676F74206974207269676874210A"), &data);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("6D656E746174696F6E206F6620494745206D6F646520666F72204F70656E5353"), &iv);
CryptographicBuffer::CopyToByteArray(CryptographicBuffer::DecodeFromHexString("5468697320697320616E20696D706C65"), &key);
MicrosoftCryptoImpl::AesIgeDecrypt(data->Data, out->Data, 32, key->Data, iv->Data);
res+=CryptographicBuffer::EncodeToHexString(CryptographicBuffer::CreateFromByteArray(out));
return res;
}*/