AuroraRuntime/Source/Process/Process.cpp
J Reece Wilson 48b6994f61 [+] LSFromFdNonblocking
[*] Other Linux progression
2022-04-05 03:36:39 +01:00

568 lines
16 KiB
C++

/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Process.cpp
Date: 2021-8-20
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Process.hpp"
#if defined(AURORA_IS_POSIX_DERIVED)
#include <stdlib.h>
#include <dlfcn.h>
#include <sys/types.h>
#include <sys/stat.h>
#endif
#if defined(AURORA_PLATFORM_WIN32)
#include <Softpub.h>
#include <wincrypt.h>
#include <wintrust.h>
#endif
#include <Source/IO/FS/FS.hpp>
#include <Source/IO/FS/Resources.hpp>
#include "ProcessMap.hpp"
namespace Aurora::Process
{
static AuThreadPrimitives::SpinLock gSpinLock;
static AuHashMap<AuString, void *> gModuleHandles;
static const bool kIsMainSigned = false;
static constexpr const char *GetPlatformString(Build::EPlatform platform)
{
switch (platform)
{
case Build::EPlatform::ePlatformWin32:
return ".Win32";
case Build::EPlatform::ePlatformLinux:
return ".Linux";
case Build::EPlatform::ePlatformAndroid:
return ".Android";
case Build::EPlatform::ePlatformAppleMacOS:
return ".Mac";
case Build::EPlatform::ePlatformIos:
return ".iOS";
case Build::EPlatform::eKernelBsd:
return ".BSD";
default:
return nullptr;
}
}
static constexpr const char *GetPlatformExt(Build::EPlatform platform)
{
switch (platform)
{
case Build::EPlatform::ePlatformWin32:
return ".dll";
case Build::EPlatform::ePlatformLinux:
case Build::EPlatform::ePlatformAndroid:
case Build::EPlatform::eKernelBsd:
return ".so";
case Build::EPlatform::ePlatformAppleMacOS:
case Build::EPlatform::ePlatformIos:
return ".dylib";
default:
return nullptr;
}
}
static constexpr const char *GetArchString(Build::EArchitecture architecture)
{
switch (architecture)
{
case Build::EArchitecture::eX86_32:
return ".x86_32";
case Build::EArchitecture::eX86_64:
return ".x86_64";
case Build::EArchitecture::eAArch64:
return ".arm";
default:
return nullptr;
}
}
static AuString ConstructAuDllSuffixUncached()
{
auto platform = GetPlatformString(Build::kCurrentPlatform);
auto architecture = GetArchString(Build::kCurrentArchitecture);
auto ext = GetPlatformExt(Build::kCurrentPlatform);
AuString ret;
#if defined(DEBUG)
ret += ".Debug";
#elif defined(STAGING)
ret += ".Stage";
#elif defined(SHIP)
ret += ".Ship";
#endif
if (platform)
{
ret += platform;
}
if (architecture)
{
ret += architecture;
}
if (ext)
{
ret += ext;
}
return ret;
}
static const AuString& ConstructAuDllSuffix()
{
static AuString dllSuffixString {};
if (dllSuffixString.empty()) dllSuffixString = ConstructAuDllSuffix();
dllSuffixString = ConstructAuDllSuffixUncached();
return dllSuffixString;
}
#if defined(AURORA_PLATFORM_WIN32)
bool VerifyEmbeddedSignature(const wchar_t *path, HANDLE handle)
{
LONG lStatus;
DWORD dwLastError;
WINTRUST_FILE_INFO FileData;
memset(&FileData, 0, sizeof(FileData));
FileData.cbStruct = sizeof(WINTRUST_FILE_INFO);
FileData.pcwszFilePath = path;
FileData.hFile = handle;
FileData.pgKnownSubject = NULL;
GUID WVTPolicyGUID = WINTRUST_ACTION_GENERIC_VERIFY_V2;
WINTRUST_DATA WinTrustData;
// Initialize the WinVerifyTrust input data structure.
// Default all fields to 0.
memset(&WinTrustData, 0, sizeof(WinTrustData));
WinTrustData.cbStruct = sizeof(WinTrustData);
// Use default code signing EKU.
WinTrustData.pPolicyCallbackData = NULL;
// No data to pass to SIP.
WinTrustData.pSIPClientData = NULL;
// Disable WVT UI.
WinTrustData.dwUIChoice = WTD_UI_NONE;
// Revocation checking.constexpr
WinTrustData.fdwRevocationChecks = WTD_REVOKE_WHOLECHAIN;
// Verify an embedded signature on a file.
WinTrustData.dwUnionChoice = WTD_CHOICE_FILE;
// Verify action.
WinTrustData.dwStateAction = WTD_STATEACTION_VERIFY;
// Verification sets this value.
WinTrustData.hWVTStateData = NULL;
// Not used.
WinTrustData.pwszURLReference = NULL;
// This is not applicable if there is no UI because it changes
// the UI to accommodate running applications instead of
// installing applications.
WinTrustData.dwUIContext = 0;
// Set pFile.
WinTrustData.pFile = &FileData;
// WinVerifyTrust verifies signatures as specified by the GUID
// and Wintrust_Data.
lStatus = WinVerifyTrust(
NULL,
&WVTPolicyGUID,
&WinTrustData);
bool status {};
switch (lStatus)
{
case ERROR_SUCCESS:
status = true;
break;
case TRUST_E_NOSIGNATURE:
// The file was not signed or had a signature
// that was not valid.
// Get the reason for no signature.
dwLastError = GetLastError();
if (TRUST_E_NOSIGNATURE == dwLastError ||
TRUST_E_SUBJECT_FORM_UNKNOWN == dwLastError ||
TRUST_E_PROVIDER_UNKNOWN == dwLastError)
{
SysPushErrorCrypt("The file is not signed.");
}
else
{
SysPushErrorCrypt("An unknown error occurred trying to verify the signature of the file.");
}
break;
case TRUST_E_EXPLICIT_DISTRUST:
SysPushErrorCrypt("The signature is present, but specifically disallowed.");
break;
case TRUST_E_SUBJECT_NOT_TRUSTED:
SysPushErrorCrypt("The signature is present, but not trusted.");
break;
case CRYPT_E_SECURITY_SETTINGS:
SysPushErrorCrypt("CRYPT_E_SECURITY_SETTINGS - The hash "
"representing the subject or the publisher wasn't "
"explicitly trusted by the admin and admin policy "
"has disabled user trust. No signature, publisher "
"or timestamp errors.");
break;
default:
SysPushErrorCrypt("Dependency Injection Error");
break;
}
WinTrustData.dwStateAction = WTD_STATEACTION_CLOSE;
lStatus = WinVerifyTrust(
NULL,
&WVTPolicyGUID,
&WinTrustData);
return status;
}
#endif
static bool LoadModule(const AuString &name, const AuString &path)
{
#if defined(AURORA_IS_MODERNNT_DERIVED)
auto handle = LoadLibraryW(Locale::ConvertFromUTF8(path).c_str());
if (handle == INVALID_HANDLE_VALUE)
{
SysPushErrorNested("Could't link dynamic library {}", path);
return {};
}
#else
auto handle = dlopen(path.c_str(), RTLD_DEEPBIND);
if (handle == nullptr)
{
SysPushErrorNested("Could't link dynamic library {}", path);
return {};
}
#endif
gModuleHandles.insert(AuMakePair(name, (void *)handle));
return true;
}
static bool TryLoadModule(const AuString &path,
#if defined(AURORA_IS_MODERNNT_DERIVED)
const AuString &abs,
#endif
const ModuleLoadRequest &request,
bool &fail
)
{
fail = false;
auto pathNrml = AuIOFS::NormalizePathRet(path);
#if defined(AURORA_IS_MODERNNT_DERIVED)
auto widePath = Locale::ConvertFromUTF8(pathNrml);
auto mitigateTimeOfUse = CreateFileW(widePath.c_str(), GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL);
if (mitigateTimeOfUse == INVALID_HANDLE_VALUE)
{
SysPushErrorNested("Couldn't open existing file. Race exploit?");
fail = true;
return false;
}
auto absPath = AuIOFS::NormalizePathRet(abs);
#endif
if (request.verify || (kIsMainSigned || request.enableMitigations))
{
#if defined(AURORA_PLATFORM_WIN32)
if (!VerifyEmbeddedSignature(widePath.c_str(), mitigateTimeOfUse))
{
SysPushErrorNested("Couldn't verify file {}", path);
fail = true;
AuWin32CloseHandle(mitigateTimeOfUse);
return false;
}
#else
AuLogWarn("Can't verify {} on this platform", path);
#endif
}
#if defined(AURORA_IS_POSIX_DERIVED)
if (request.enableMitigations && request.unixCheckPlusX)
{
struct stat sb;
if (stat(pathNrml.data(), &sb) != 0)
{
SysPushErrorNested("Couldn't open existing file. Race exploit?");
fail = true;
return false;
}
if ((sb.st_mode & S_IXUSR) == 0)
{
fail = true;
return false;
}
}
#endif
#if defined(AURORA_IS_MODERNNT_DERIVED)
auto returnValue = LoadModule(absPath);
#else
auto returnValue = LoadModule(pathNrml);
#endif
#if defined(AURORA_IS_MODERNNT_DERIVED)
// Still doesnt stop hotswaps, and idc
// Glitching would require software to time the attack
// ...requiring a certain degree of access (code execution) + effort
AuWin32CloseHandle(mitigateTimeOfUse);
#endif
return returnValue;
}
static bool TryLoadModule(const AuString &path, const AuString &auDll, const AuString &genericDll, const ModuleLoadRequest &request, bool &fail)
{
AuString a = path + "/" + auDll;
AuString b = path + "/" + genericDll;
#if defined(AURORA_IS_MODERNNT_DERIVED)
AuString aAbs = path + "/" + auDll + ".";
AuString bAbs = path + "/" + genericDll + ".";
#endif
if (AuIOFS::FileExists(a))
{
return TryLoadModule(a,
#if defined(AURORA_IS_MODERNNT_DERIVED)
aAbs,
#endif
request,
fail
);
}
if (AuIOFS::FileExists(b))
{
return TryLoadModule(b,
#if defined(AURORA_IS_MODERNNT_DERIVED)
bAbs,
#endif
request,
fail
);
}
return {};
}
static bool TryLoadModule(EModulePath path, const AuString &auDll, const AuString &genericDll, const ModuleLoadRequest &request)
{
AuString pathA, pathB;
switch (path)
{
case EModulePath::eModulePathCWD:
if (!Process::GetWorkingDirectory(pathA)) return false;
break;
case EModulePath::eProcessDirectory:
if (!Process::GetProcDirectory(pathA)) return false;
break;
case EModulePath::eModulePathSystemDir:
pathA = AuIOFS::GetSystemLibPath().value_or(AuString {});
pathB = AuIOFS::GetSystemLibPath2().value_or(AuString {});
if (pathA.empty()) return false;
break;
case EModulePath::eModulePathUserDir:
pathA = AuIOFS::GetUserLibPath().value_or(AuString {});
pathB = AuIOFS::GetUserLibPath2().value_or(AuString {});
if (pathA.empty()) return false;
break;
//case EModulePath::eOSSpecified:
//
// break;
case EModulePath::eSpecified:
break;
}
bool fail {};
if (pathA.size())
{
if (TryLoadModule(pathA, auDll, genericDll, request, fail))
{
return true;
}
if (fail)
{
return false;
}
}
if (pathB.size())
{
if (TryLoadModule(pathB, auDll, genericDll, request, fail))
{
return true;
}
if (fail)
{
return false;
}
}
if (path == EModulePath::eSpecified && request.specifiedSearchPaths)
{
for (const auto &val : *request.specifiedSearchPaths)
{
if (TryLoadModule(val, auDll, genericDll, request, fail))
{
return true;
}
if (fail)
{
return false;
}
}
}
return {};
}
AUKN_SYM bool LoadModule(const ModuleLoadRequest &request)
{
AU_LOCK_GUARD(gSpinLock);
auto h = gModuleHandles.find(request.mod);
if (h != gModuleHandles.end())
{
return true;
}
auto au = request.mod + ConstructAuDllSuffix();
auto base = request.mod;
auto ext = GetPlatformExt(Build::kCurrentPlatform);
if (ext && !Build::kIsNtDerived)
{
base += ext;
}
if (request.version.size())
{
au += "." + request.version;
base += "." + request.version;
}
if (ext && Build::kIsNtDerived)
{
base += ext;
}
auto searchPath = request.searchPath ? request.searchPath : &kUserOverloadableSearchPath;
for (EModulePath path : *searchPath)
{
if (TryLoadModule(path, au, base, request))
{
return true;
}
}
return false;
}
AUKN_SYM AuMach GetProcAddress(AuString mod, AuString symbol)
{
AU_LOCK_GUARD(gSpinLock);
auto h = gModuleHandles.find(mod);
if (h == gModuleHandles.end())
{
SysPushErrorGen("Module {} is not loaded", mod);
return {};
}
auto handle = h->second;
#if defined(AURORA_IS_MODERNNT_DERIVED)
auto ret = reinterpret_cast<AuMach>(::GetProcAddress(reinterpret_cast<HMODULE>(handle), symbol.c_str()));
#else
auto ret = reinterpret_cast<AuMach>(dlsym(handle, symbol.c_str()));
#endif
if (!ret)
{
SysPushErrorGen("Couldn't resolve symbol in module {} of mangled name '{}'", mod, symbol);
}
return ret;
}
AUKN_SYM void Exit(AuUInt32 exitcode)
{
#if defined(AURORA_PLATFORM_WIN32)
// TODO (Reece): ...
#endif
Aurora::RuntimeShutdown();
#if defined(AURORA_IS_MODERNNT_DERIVED)
ExitProcess(exitcode);
#elif defined(AURORA_IS_POSIX_DERIVED)
exit(exitcode);
#else
// ???
*(AuUInt32 *)0 = exitcode;
*(AuUInt32 *)0xFFFF = exitcode;
*(AuUInt32 *)0xFFFFFFFF = exitcode;
#endif
}
void InitProcess()
{
// TODO (reece): test if self is signed -> xref kIsMainSigned
InitProcessMap();
}
void DeinitProcess()
{
DeinitProcessMap();
}
}