/* Copyright (C) 2019 Mr Goldberg This file is part of the Goldberg Emulator The Goldberg Emulator is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. The Goldberg Emulator is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the Goldberg Emulator; if not, see . */ #include "dll/base.h" #include "dll/settings_parser.h" #ifndef EMU_RELEASE_BUILD #include "dbg_log/dbg_log.hpp" #endif std::recursive_mutex global_mutex{}; // some arbitrary counter/time for reference const std::chrono::time_point startup_counter = std::chrono::high_resolution_clock::now(); const std::chrono::time_point startup_time = std::chrono::system_clock::now(); #ifndef EMU_RELEASE_BUILD dbg_log dbg_logger(get_full_program_path() + "STEAM_LOG.txt"); #endif #ifdef __WINDOWS__ void randombytes(char *buf, size_t size) { // NT_SUCCESS is: return value >= 0, including Ntdef.h causes so many errors while (BCryptGenRandom(NULL, (PUCHAR) buf, (ULONG) size, BCRYPT_USE_SYSTEM_PREFERRED_RNG) < 0) { PRINT_DEBUG("ERROR"); Sleep(100); } } std::string get_env_variable(const std::string &name) { wchar_t env_variable[1024]{}; DWORD ret = GetEnvironmentVariableW(utf8_decode(name).c_str(), env_variable, _countof(env_variable)); if (ret <= 0 || !env_variable[0]) { return std::string(); } env_variable[ret] = 0; return utf8_encode(env_variable); } bool set_env_variable(const std::string &name, const std::string &value) { return SetEnvironmentVariableW(utf8_decode(name).c_str(), utf8_decode(value).c_str()); } #else static int fd = -1; void randombytes(char *buf, size_t size) { int i; if (fd == -1) { for (;;) { fd = open("/dev/urandom",O_RDONLY); if (fd != -1) break; sleep(1); } } while (size > 0) { if (size < 1048576) i = size; else i = 1048576; i = read(fd,buf,i); if (i < 1) { sleep(1); continue; } buf += i; size -= i; } } std::string get_env_variable(const std::string &name) { char *env = getenv(name.c_str()); if (!env) { return std::string(); } return std::string(env); } bool set_env_variable(const std::string &name, const std::string &value) { return setenv(name.c_str(), value.c_str(), 1) == 0; } #endif unsigned generate_account_id() { int a; randombytes((char *)&a, sizeof(a)); a = abs(a); if (!a) ++a; return a; } CSteamID generate_steam_anon_user() { return CSteamID(generate_account_id(), k_unSteamUserDefaultInstance, k_EUniversePublic, k_EAccountTypeAnonUser); } SteamAPICall_t generate_steam_api_call_id() { static SteamAPICall_t a; std::lock_guard lock(global_mutex); randombytes((char *)&a, sizeof(a)); ++a; if (a == 0) ++a; return a; } CSteamID generate_steam_id_user() { return CSteamID(generate_account_id(), k_unSteamUserDefaultInstance, k_EUniversePublic, k_EAccountTypeIndividual); } CSteamID generate_steam_id_server() { return CSteamID(generate_account_id(), k_unSteamUserDefaultInstance, k_EUniversePublic, k_EAccountTypeGameServer); } CSteamID generate_steam_id_anonserver() { return CSteamID(generate_account_id(), k_unSteamUserDefaultInstance, k_EUniversePublic, k_EAccountTypeAnonGameServer); } CSteamID generate_steam_id_lobby() { return CSteamID(generate_account_id(), k_EChatInstanceFlagLobby | k_EChatInstanceFlagMMSLobby, k_EUniversePublic, k_EAccountTypeChat); } bool check_timedout(std::chrono::high_resolution_clock::time_point old, double timeout) { if (timeout == 0.0) return true; std::chrono::high_resolution_clock::time_point now = std::chrono::high_resolution_clock::now(); if (std::chrono::duration_cast>(now - old).count() > timeout) { return true; } return false; } #ifdef __LINUX__ std::string get_lib_path() { std::string dir = "/proc/self/map_files"; DIR *dp; int i = 0; struct dirent *ep; dp = opendir (dir.c_str()); uintptr_t p = (uintptr_t)&get_lib_path; if (dp != NULL) { while ((ep = readdir (dp))) { if (memcmp(ep->d_name, ".", 2) != 0 && memcmp(ep->d_name, "..", 3) != 0) { char *upper = NULL; uintptr_t lower_bound = strtoull(ep->d_name, &upper, 16); if (lower_bound) { ++upper; uintptr_t upper_bound = strtoull(upper, &upper, 16); if (upper_bound && (lower_bound < p && p < upper_bound)) { std::string path = dir + PATH_SEPARATOR + ep->d_name; char link[PATH_MAX] = {}; if (readlink(path.c_str(), link, sizeof(link)) > 0) { std::string lib_path = link; (void) closedir (dp); return link; } } } i++; } } (void) closedir (dp); } return "."; } #endif std::string get_full_lib_path() { std::string program_path; #if defined(__WINDOWS__) wchar_t DllPath[2048] = {0}; GetModuleFileNameW((HINSTANCE)&__ImageBase, DllPath, _countof(DllPath)); program_path = utf8_encode(DllPath); #else program_path = get_lib_path(); #endif return program_path; } std::string get_full_program_path() { std::string env_program_path = get_env_variable("GseAppPath"); if (env_program_path.length()) { if (env_program_path.back() != PATH_SEPARATOR[0]) { env_program_path = env_program_path.append(PATH_SEPARATOR); } return env_program_path; } std::string program_path{}; program_path = get_full_lib_path(); return program_path.substr(0, program_path.rfind(PATH_SEPARATOR)).append(PATH_SEPARATOR); } std::string get_current_path() { std::string path; #if defined(STEAM_WIN32) char *buffer = _getcwd( NULL, 0 ); #else char *buffer = get_current_dir_name(); #endif if (buffer) { path = buffer; path.append(PATH_SEPARATOR); free(buffer); } return path; } std::string canonical_path(const std::string &path) { std::string output; #if defined(STEAM_WIN32) wchar_t *buffer = _wfullpath(NULL, utf8_decode(path).c_str(), 0); if (buffer) { output = utf8_encode(buffer); free(buffer); } #else char *buffer = canonicalize_file_name(path.c_str()); if (buffer) { output = buffer; free(buffer); } #endif return output; } bool file_exists_(const std::string &full_path) { #if defined(STEAM_WIN32) struct _stat buffer{}; if (_wstat(utf8_decode(full_path).c_str(), &buffer) != 0) return false; if ( buffer.st_mode & S_IFDIR) return false; #else struct stat buffer{}; if (stat(full_path.c_str(), &buffer) != 0) return false; if (S_ISDIR(buffer.st_mode)) return false; #endif return true; } unsigned int file_size_(const std::string &full_path) { #if defined(STEAM_WIN32) struct _stat buffer{}; if (_wstat(utf8_decode(full_path).c_str(), &buffer) != 0) return 0; #else struct stat buffer{}; if (stat (full_path.c_str(), &buffer) != 0) return 0; #endif return buffer.st_size; } #ifdef EMU_EXPERIMENTAL_BUILD #ifdef __WINDOWS__ struct ips_test { uint32_t ip_from; uint32_t ip_to; }; static std::vector whitelist_ips; void set_whitelist_ips(uint32_t *from, uint32_t *to, unsigned num_ips) { whitelist_ips.clear(); for (unsigned i = 0; i < num_ips; ++i) { struct ips_test ip_a; PRINT_DEBUG("from: %hhu.%hhu.%hhu.%hhu", ((unsigned char *)&from[i])[0], ((unsigned char *)&from[i])[1], ((unsigned char *)&from[i])[2], ((unsigned char *)&from[i])[3]); PRINT_DEBUG("to: %hhu.%hhu.%hhu.%hhu", ((unsigned char *)&to[i])[0], ((unsigned char *)&to[i])[1], ((unsigned char *)&to[i])[2], ((unsigned char *)&to[i])[3]); ip_a.ip_from = ntohl(from[i]); ip_a.ip_to = ntohl(to[i]); if (ip_a.ip_to < ip_a.ip_from) continue; if ((ip_a.ip_to - ip_a.ip_from) > (1 << 25)) continue; PRINT_DEBUG("added ip to whitelist"); whitelist_ips.push_back(ip_a); } } static bool is_whitelist_ip(unsigned char *ip) { uint32_t ip_temp = 0; memcpy(&ip_temp, ip, sizeof(ip_temp)); ip_temp = ntohl(ip_temp); for (auto &i : whitelist_ips) { if (i.ip_from <= ip_temp && ip_temp <= i.ip_to) { PRINT_DEBUG("IP IS WHITELISTED %hhu.%hhu.%hhu.%hhu", ip[0], ip[1], ip[2], ip[3]); return true; } } return false; } static bool is_lan_ipv4(unsigned char *ip) { PRINT_DEBUG("CHECK LAN IP %hhu.%hhu.%hhu.%hhu", ip[0], ip[1], ip[2], ip[3]); if (is_whitelist_ip(ip)) return true; if (ip[0] == 127) return true; if (ip[0] == 10) return true; if (ip[0] == 192 && ip[1] == 168) return true; if (ip[0] == 169 && ip[1] == 254 && ip[2] != 0) return true; if (ip[0] == 172 && ip[1] >= 16 && ip[1] <= 31) return true; if ((ip[0] == 100) && ((ip[1] & 0xC0) == 0x40)) return true; if (ip[0] == 239) return true; //multicast if (ip[0] == 0) return true; //Current network if (ip[0] == 192 && (ip[1] == 18 || ip[1] == 19)) return true; //Used for benchmark testing of inter-network communications between two separate subnets. if (ip[0] >= 224) return true; //ip multicast (224 - 239) future use (240.0.0.0 - 255.255.255.254) broadcast (255.255.255.255) return false; } static bool is_lan_ip(const sockaddr *addr, int namelen) { if (!namelen) return false; if (addr->sa_family == AF_INET) { struct sockaddr_in *addr_in = (struct sockaddr_in *)addr; unsigned char ip[4]; memcpy(ip, &addr_in->sin_addr, sizeof(ip)); if (is_lan_ipv4(ip)) return true; } else if (addr->sa_family == AF_INET6) { struct sockaddr_in6 *addr_in6 = (struct sockaddr_in6 *)addr; unsigned char ip[16]; unsigned char zeroes[16] = {}; memcpy(ip, &addr_in6->sin6_addr, sizeof(ip)); PRINT_DEBUG("CHECK LAN IP6 %hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu.%hhu", ip[0], ip[1], ip[2], ip[3], ip[4], ip[5], ip[6], ip[7], ip[8], ip[9], ip[10], ip[11], ip[12], ip[13], ip[14], ip[15]); if (((ip[0] == 0xFF) && (ip[1] < 3) && (ip[15] == 1)) || ((ip[0] == 0xFE) && ((ip[1] & 0xC0) == 0x80))) return true; if (memcmp(zeroes, ip, sizeof(ip)) == 0) return true; if (memcmp(zeroes, ip, sizeof(ip) - 1) == 0 && ip[15] == 1) return true; if (ip[0] == 0xff) return true; //multicast if (ip[0] == 0xfc) return true; //unique local if (ip[0] == 0xfd) return true; //unique local unsigned char ipv4_mapped[12] = {}; ipv4_mapped[10] = 0xFF; ipv4_mapped[11] = 0xFF; if (memcmp(ipv4_mapped, ip, sizeof(ipv4_mapped)) == 0) { if (is_lan_ipv4(ip + 12)) return true; } } PRINT_DEBUG("NOT LAN IP"); return false; } int ( WINAPI *Real_SendTo )( SOCKET s, const char *buf, int len, int flags, const sockaddr *to, int tolen) = sendto; int ( WINAPI *Real_Connect )( SOCKET s, const sockaddr *addr, int namelen ) = connect; int ( WINAPI *Real_WSAConnect )( SOCKET s, const sockaddr *addr, int namelen, LPWSABUF lpCallerData, LPWSABUF lpCalleeData, LPQOS lpSQOS, LPQOS lpGQOS) = WSAConnect; static int WINAPI Mine_SendTo( SOCKET s, const char *buf, int len, int flags, const sockaddr *to, int tolen) { PRINT_DEBUG_ENTRY(); if (is_lan_ip(to, tolen)) { return Real_SendTo( s, buf, len, flags, to, tolen ); } else { return len; } } static int WINAPI Mine_Connect( SOCKET s, const sockaddr *addr, int namelen ) { PRINT_DEBUG_ENTRY(); if (is_lan_ip(addr, namelen)) { return Real_Connect(s, addr, namelen); } else { WSASetLastError(WSAECONNREFUSED); return SOCKET_ERROR; } } static int WINAPI Mine_WSAConnect( SOCKET s, const sockaddr *addr, int namelen, LPWSABUF lpCallerData, LPWSABUF lpCalleeData, LPQOS lpSQOS, LPQOS lpGQOS) { PRINT_DEBUG_ENTRY(); if (is_lan_ip(addr, namelen)) { return Real_WSAConnect(s, addr, namelen, lpCallerData, lpCalleeData, lpSQOS, lpGQOS); } else { WSASetLastError(WSAECONNREFUSED); return SOCKET_ERROR; } } inline bool file_exists (const std::string& name) { struct stat buffer; return (stat (name.c_str(), &buffer) == 0); } #ifdef DETOURS_64BIT #define DLL_NAME "steam_api64.dll" #else #define DLL_NAME "steam_api.dll" #endif HMODULE (WINAPI *Real_GetModuleHandleA)(LPCSTR lpModuleName) = GetModuleHandleA; HMODULE WINAPI Mine_GetModuleHandleA(LPCSTR lpModuleName) { PRINT_DEBUG("%s", lpModuleName); if (!lpModuleName) return Real_GetModuleHandleA(lpModuleName); std::string in(lpModuleName); if (in == std::string(DLL_NAME)) { in = std::string("crack") + in; } return Real_GetModuleHandleA(in.c_str()); } static void redirect_crackdll() { DetourTransactionBegin(); DetourUpdateThread( GetCurrentThread() ); DetourAttach( reinterpret_cast(&Real_GetModuleHandleA), reinterpret_cast(Mine_GetModuleHandleA) ); DetourTransactionCommit(); } static void unredirect_crackdll() { DetourTransactionBegin(); DetourUpdateThread( GetCurrentThread() ); DetourDetach( reinterpret_cast(&Real_GetModuleHandleA), reinterpret_cast(Mine_GetModuleHandleA) ); DetourTransactionCommit(); } HMODULE crack_dll_handle{}; static void load_crack_dll() { std::string path(get_full_program_path() + "crack" + DLL_NAME); PRINT_DEBUG("searching for crack file '%s'", path.c_str()); if (file_exists(path)) { redirect_crackdll(); crack_dll_handle = LoadLibraryW(utf8_decode(path).c_str()); unredirect_crackdll(); PRINT_DEBUG("Loaded crack file"); } } #include "dll/local_storage.h" static void load_dlls() { std::string path(Local_Storage::get_game_settings_path() + "load_dlls" + PATH_SEPARATOR); std::vector paths(Local_Storage::get_filenames_path(path)); for (auto & p: paths) { std::string full_path(path + p); if (!common_helpers::ends_with_i(full_path, ".dll")) continue; PRINT_DEBUG("loading '%s'", full_path.c_str()); if (LoadLibraryW(utf8_decode(full_path).c_str())) { PRINT_DEBUG(" LOADED"); } else { PRINT_DEBUG(" FAILED, error 0x%X", GetLastError()); } } } //For some reason when this function is optimized it breaks the shogun 2 prophet (reloaded) crack. #pragma optimize( "", off ) bool crack_SteamAPI_RestartAppIfNecessary(uint32 unOwnAppID) { if (crack_dll_handle) { bool (__stdcall* restart_app)(uint32) = (bool (__stdcall *)(uint32))GetProcAddress(crack_dll_handle, "SteamAPI_RestartAppIfNecessary"); if (restart_app) { PRINT_DEBUG("Calling crack SteamAPI_RestartAppIfNecessary"); redirect_crackdll(); bool ret = restart_app(unOwnAppID); unredirect_crackdll(); return ret; } } return false; } #pragma optimize( "", on ) bool crack_SteamAPI_Init() { if (crack_dll_handle) { bool (__stdcall* init_app)() = (bool (__stdcall *)())GetProcAddress(crack_dll_handle, "SteamAPI_Init"); if (init_app) { PRINT_DEBUG("Calling crack SteamAPI_Init"); redirect_crackdll(); bool ret = init_app(); unredirect_crackdll(); return ret; } } return false; } HINTERNET (WINAPI *Real_WinHttpConnect)( IN HINTERNET hSession, IN LPCWSTR pswzServerName, IN INTERNET_PORT nServerPort, IN DWORD dwReserved ); HINTERNET WINAPI Mine_WinHttpConnect( IN HINTERNET hSession, IN LPCWSTR pswzServerName, IN INTERNET_PORT nServerPort, IN DWORD dwReserved ) { PRINT_DEBUG("%ls %u", pswzServerName, nServerPort); struct sockaddr_in ip4; struct sockaddr_in6 ip6; ip4.sin_family = AF_INET; ip6.sin6_family = AF_INET6; if ((InetPtonW(AF_INET, pswzServerName, &(ip4.sin_addr)) && is_lan_ip((sockaddr *)&ip4, sizeof(ip4))) || (InetPtonW(AF_INET6, pswzServerName, &(ip6.sin6_addr)) && is_lan_ip((sockaddr *)&ip6, sizeof(ip6)))) { return Real_WinHttpConnect(hSession, pswzServerName, nServerPort, dwReserved); } else { return Real_WinHttpConnect(hSession, L"127.1.33.7", nServerPort, dwReserved); } } HINTERNET (WINAPI *Real_WinHttpOpenRequest)( IN HINTERNET hConnect, IN LPCWSTR pwszVerb, IN LPCWSTR pwszObjectName, IN LPCWSTR pwszVersion, IN LPCWSTR pwszReferrer, IN LPCWSTR *ppwszAcceptTypes, IN DWORD dwFlags ); HINTERNET WINAPI Mine_WinHttpOpenRequest( IN HINTERNET hConnect, IN LPCWSTR pwszVerb, IN LPCWSTR pwszObjectName, IN LPCWSTR pwszVersion, IN LPCWSTR pwszReferrer, IN LPCWSTR *ppwszAcceptTypes, IN DWORD dwFlags ) { PRINT_DEBUG("%ls %ls %ls %ls %i", pwszVerb, pwszObjectName, pwszVersion, pwszReferrer, dwFlags); if (dwFlags & WINHTTP_FLAG_SECURE) { dwFlags ^= WINHTTP_FLAG_SECURE; } return Real_WinHttpOpenRequest(hConnect, pwszVerb, pwszObjectName, pwszVersion, pwszReferrer, ppwszAcceptTypes, dwFlags); } static bool network_functions_attached = false; BOOL WINAPI DllMain( HINSTANCE, DWORD dwReason, LPVOID ) { switch ( dwReason ) { case DLL_PROCESS_ATTACH: PRINT_DEBUG("experimental DLL_PROCESS_ATTACH"); if (!settings_disable_lan_only()) { PRINT_DEBUG("Hooking lan only functions"); DetourTransactionBegin(); DetourUpdateThread( GetCurrentThread() ); DetourAttach( reinterpret_cast(&Real_SendTo), reinterpret_cast(Mine_SendTo) ); DetourAttach( reinterpret_cast(&Real_Connect), reinterpret_cast(Mine_Connect) ); DetourAttach( reinterpret_cast(&Real_WSAConnect), reinterpret_cast(Mine_WSAConnect) ); HMODULE winhttp = GetModuleHandleA("winhttp.dll"); if (winhttp) { Real_WinHttpConnect = (decltype(Real_WinHttpConnect))GetProcAddress(winhttp, "WinHttpConnect"); DetourAttach( reinterpret_cast(&Real_WinHttpConnect), reinterpret_cast(Mine_WinHttpConnect) ); // Real_WinHttpOpenRequest = (decltype(Real_WinHttpOpenRequest))GetProcAddress(winhttp, "WinHttpOpenRequest"); // DetourAttach( reinterpret_cast(&Real_WinHttpOpenRequest), reinterpret_cast(Mine_WinHttpOpenRequest) ); } DetourTransactionCommit(); network_functions_attached = true; } load_crack_dll(); load_dlls(); break; case DLL_PROCESS_DETACH: PRINT_DEBUG("experimental DLL_PROCESS_DETACH"); if (network_functions_attached) { DetourTransactionBegin(); DetourUpdateThread( GetCurrentThread() ); DetourDetach( reinterpret_cast(&Real_SendTo), reinterpret_cast(Mine_SendTo) ); DetourDetach( reinterpret_cast(&Real_Connect), reinterpret_cast(Mine_Connect) ); DetourDetach( reinterpret_cast(&Real_WSAConnect), reinterpret_cast(Mine_WSAConnect) ); if (Real_WinHttpConnect) { DetourDetach( reinterpret_cast(&Real_WinHttpConnect), reinterpret_cast(Mine_WinHttpConnect) ); // DetourDetach( reinterpret_cast(&Real_WinHttpOpenRequest), reinterpret_cast(Mine_WinHttpOpenRequest) ); } DetourTransactionCommit(); } break; } return TRUE; } #else void set_whitelist_ips(uint32_t *from, uint32_t *to, unsigned num_ips) { } #endif #else void set_whitelist_ips(uint32_t *from, uint32_t *to, unsigned num_ips) { } #endif