void KernelPatcher::onKextSummariesUpdated() {
if (that) {
// macOS 10.12 generates an interrupt during this call but unlike 10.11 and below
// it never stops handling interrupts hanging forever inside hndl_allintrs.
// This happens even with cpus=1, and the reason is not fully understood.
//
// For this reason on 10.12 and above the outer function is routed, and so far it
// seems to cause fewer issues. Regarding syncing:
// - the only place modifying gLoadedKextSummaries is updateLoadedKextSummaries;
// - updateLoadedKextSummaries is called from load/unload separately;
// - sKextSummariesLock is not exported or visible.
// As a result no syncing should be necessary but there are guards for future
// changes and in case of any misunderstanding.
if (getKernelVersion() >= KernelVersion::Sierra) {
if (OSIncrementAtomic(&updateSummariesEntryCount) != 0) {
panic("onKextSummariesUpdated entered another time");
}
that->orgUpdateLoadedKextSummaries();
}
DBGLOG("patcher @ invoked at kext loading/unloading");
if (that->khandlers.size() > 0 && that->loadedKextSummaries) {
auto num = (*that->loadedKextSummaries)->numSummaries;
if (num > 0) {
OSKextLoadedKextSummary &last = (*that->loadedKextSummaries)->summaries[num-1];
DBGLOG("patcher @ last kext is %llX and its name is %.*s", last.address, KMOD_MAX_NAME, last.name);
// We may add khandlers items inside the handler
for (size_t i = 0; i < that->khandlers.size(); i++) {
if (!strncmp(that->khandlers[i]->id, last.name, KMOD_MAX_NAME)) {
DBGLOG("patcher @ caught the right kext at %llX, invoking handler", last.address);
that->khandlers[i]->address = last.address;
that->khandlers[i]->size = last.size;
that->khandlers[i]->handler(that->khandlers[i]);
// Remove the item
that->khandlers.erase(i);
break;
}
}
} else {
SYSLOG("patcher @ no kext is currently loaded, this should not happen");
}
}
if (getKernelVersion() >= KernelVersion::Sierra && OSDecrementAtomic(&updateSummariesEntryCount) != 1) {
panic("onKextSummariesUpdated left another time");
}
}
}
int sectionToSlave(int cpuf, int fd, int * EntryPoint)
{
int i = 0, err = 0;
int BootSection = -2;
int LastSection = -2;
unsigned long ramStart = 0;
unsigned char kernelVersion = getKernelVersion();
if(kernelVersion == 23 || kernelVersion == 24)
{
cop_properties_t cop;
err = ioctl(cpuf,STCOP_GET_PROPERTIES,&cop);
if(err < 0)
{
printf("error ioctl STCOP_GET_PROPERTIES\n");
return 1;
}
printf("base_address 0x%.8lx\n", cop.cp_ram_start);
ramStart = cop.cp_ram_start;
}
for(i = 0; i < IndexCounter; i++) {
if(IndexTable[i].Size > 0 && (IndexTable[i].Flags & SEC_LOAD == SEC_LOAD)) {
if (0 == strncmp(".boot", IndexTable[i].Name, 5)) {
/* defer the loading of the (relocatable) .boot section until we know where to
* relocate it to.
*/
BootSection = i;
continue;
}
err = writeToSlave(cpuf, fd, IndexTable[i].DestinationAddress - ramStart,
IndexTable[i].SourceAddress, IndexTable[i].Size);
if(err != 0) return 1;
LastSection = i;
}
}
if(BootSection != -2) {
//Add relocated .boot
unsigned int Alignment = 8;
unsigned int DestinationAddress = (IndexTable[LastSection].DestinationAddress + IndexTable[LastSection].Size
+ (1 << Alignment)) & ~((1 << Alignment) - 1);
err = writeToSlave(cpuf, fd, DestinationAddress - ramStart,
IndexTable[BootSection].SourceAddress, IndexTable[BootSection].Size);
if(err != 0) return 1;
*EntryPoint = DestinationAddress;
} else {
//We allready have the EntryPoint
}
return 0;
}
void KernelPatcher::setupKextListening() {
// We have already done this
if (that) return;
loadedKextSummaries = reinterpret_cast<OSKextLoadedKextSummaryHeader **>(solveSymbol(KernelID, "_gLoadedKextSummaries"));
if (loadedKextSummaries) {
DBGLOG("patcher @ _gLoadedKextSummaries address %p", loadedKextSummaries);
} else {
code = Error::NoSymbolFound;
return;
}
bool hookOuter = getKernelVersion() >= KernelVersion::Sierra;
mach_vm_address_t s = solveSymbol(KernelID, hookOuter ?
"__ZN6OSKext25updateLoadedKextSummariesEv" :
"_OSKextLoadedKextSummariesUpdated");
if (s) {
DBGLOG("patcher @ kext summaries (%d) address %llX value %llX", hookOuter, s, *reinterpret_cast<uint64_t *>(s));
} else {
code = Error::NoSymbolFound;
return;
}
if (hookOuter) {
orgUpdateLoadedKextSummaries = reinterpret_cast<void(*)(void)>(
routeFunction(s, reinterpret_cast<mach_vm_address_t>(onKextSummariesUpdated), true, true)
);
} else {
routeFunction(s, reinterpret_cast<mach_vm_address_t>(onKextSummariesUpdated));
}
if (getError() == Error::NoError) {
// Allow static functions to access the patcher body
that = this;
}
}
void GLPlatform::detect(OpenGLPlatformInterface platformInterface)
{
m_platformInterface = platformInterface;
m_vendor = (const char*)glGetString(GL_VENDOR);
m_renderer = (const char*)glGetString(GL_RENDERER);
m_version = (const char*)glGetString(GL_VERSION);
// Parse the OpenGL version
const QList<QByteArray> versionTokens = m_version.split(' ');
if (versionTokens.count() > 0) {
const QByteArray version = QByteArray(m_version);
m_glVersion = parseVersionString(version);
if (platformInterface == EglPlatformInterface) {
// only EGL can have OpenGLES, GLX is OpenGL only
if (version.startsWith("OpenGL ES")) {
// from GLES 2: "Returns a version or release number of the form OpenGL<space>ES<space><version number><space><vendor-specific information>."
// from GLES 3: "Returns a version or release number." and "The version number uses one of these forms: major_number.minor_number major_number.minor_number.release_number"
m_gles = true;
}
}
}
if (!isGLES() && m_glVersion >= kVersionNumber(3, 0)) {
int count;
glGetIntegerv(GL_NUM_EXTENSIONS, &count);
for (int i = 0; i < count; i++) {
const char *name = (const char *) glGetStringi(GL_EXTENSIONS, i);
m_extensions.insert(name);
}
} else {
const QByteArray extensions = (const char *) glGetString(GL_EXTENSIONS);
m_extensions = QSet<QByteArray>::fromList(extensions.split(' '));
}
// Parse the Mesa version
const int mesaIndex = versionTokens.indexOf("Mesa");
if (mesaIndex != -1) {
const QByteArray version = versionTokens.at(mesaIndex + 1);
m_mesaVersion = parseVersionString(version);
}
if (platformInterface == EglPlatformInterface) {
if (isGLES()) {
m_supportsGLSL = true;
m_textureNPOT = true;
} else {
m_supportsGLSL = m_extensions.contains("GL_ARB_shader_objects") &&
m_extensions.contains("GL_ARB_fragment_shader") &&
m_extensions.contains("GL_ARB_vertex_shader");
m_textureNPOT = m_extensions.contains("GL_ARB_texture_non_power_of_two");
}
} else if (platformInterface == GlxPlatformInterface) {
m_supportsGLSL = m_extensions.contains("GL_ARB_shader_objects") &&
m_extensions.contains("GL_ARB_fragment_shader") &&
m_extensions.contains("GL_ARB_vertex_shader");
m_textureNPOT = m_extensions.contains("GL_ARB_texture_non_power_of_two");
}
m_serverVersion = getXServerVersion();
m_kernelVersion = getKernelVersion();
m_glslVersion = 0;
m_glsl_version.clear();
if (m_supportsGLSL) {
// Parse the GLSL version
m_glsl_version = (const char*)glGetString(GL_SHADING_LANGUAGE_VERSION);
m_glslVersion = parseVersionString(m_glsl_version);
}
m_chipset = QByteArrayLiteral("Unknown");
m_preferBufferSubData = false;
// Mesa classic drivers
// ====================================================
// Radeon
if (m_renderer.startsWith("Mesa DRI R")) {
// Sample renderer string: Mesa DRI R600 (RV740 94B3) 20090101 x86/MMX/SSE2 TCL DRI2
const QList<QByteArray> tokens = m_renderer.split(' ');
const QByteArray chipClass = tokens.at(2);
m_chipset = tokens.at(3).mid(1, -1); // Strip the leading '('
if (chipClass == "R100")
// Vendor: Tungsten Graphics, Inc.
m_driver = Driver_R100;
else if (chipClass == "R200")
// Vendor: Tungsten Graphics, Inc.
m_driver = Driver_R200;
else if (chipClass == "R300")
// Vendor: DRI R300 Project
m_driver = Driver_R300C;
else if (chipClass == "R600")
// Vendor: Advanced Micro Devices, Inc.
m_driver = Driver_R600C;
m_chipClass = detectRadeonClass(m_chipset);
}
// Intel
else if (m_renderer.contains("Intel")) {
// Vendor: Tungsten Graphics, Inc.
// Sample renderer string: Mesa DRI Mobile Intel® GM45 Express Chipset GEM 20100328 2010Q1
QByteArray chipset;
if (m_renderer.startsWith("Intel(R) Integrated Graphics Device"))
chipset = "IGD";
else
chipset = m_renderer;
m_driver = Driver_Intel;
m_chipClass = detectIntelClass(chipset);
}
// Gallium drivers
// ====================================================
else if (m_renderer.contains("Gallium")) {
// Sample renderer string: Gallium 0.4 on AMD RV740
const QList<QByteArray> tokens = m_renderer.split(' ');
m_galliumVersion = parseVersionString(tokens.at(1));
m_chipset = (tokens.at(3) == "AMD" || tokens.at(3) == "ATI") ?
tokens.at(4) : tokens.at(3);
// R300G
if (m_vendor == QByteArrayLiteral("X.Org R300 Project")) {
m_chipClass = detectRadeonClass(m_chipset);
m_driver = Driver_R300G;
}
// R600G
else if (m_vendor == "X.Org" &&
(m_renderer.contains("R6") ||
m_renderer.contains("R7") ||
m_renderer.contains("RV6") ||
m_renderer.contains("RV7") ||
m_renderer.contains("RS780") ||
m_renderer.contains("RS880") ||
m_renderer.contains("CEDAR") ||
m_renderer.contains("REDWOOD") ||
m_renderer.contains("JUNIPER") ||
m_renderer.contains("CYPRESS") ||
m_renderer.contains("HEMLOCK") ||
m_renderer.contains("PALM") ||
m_renderer.contains("EVERGREEN") ||
m_renderer.contains("SUMO") ||
m_renderer.contains("SUMO2") ||
m_renderer.contains("BARTS") ||
m_renderer.contains("TURKS") ||
m_renderer.contains("CAICOS") ||
m_renderer.contains("CAYMAN"))) {
m_chipClass = detectRadeonClass(m_chipset);
m_driver = Driver_R600G;
}
// Nouveau
else if (m_vendor == "nouveau") {
m_chipClass = detectNVidiaClass(m_chipset);
m_driver = Driver_Nouveau;
}
// softpipe
else if (m_vendor == "VMware, Inc." && m_chipset == "softpipe" ) {
m_driver = Driver_Softpipe;
}
// llvmpipe
else if (m_vendor == "VMware, Inc." && m_chipset == "llvmpipe") {
m_driver = Driver_Llvmpipe;
}
// SVGA3D
else if (m_vendor == "VMware, Inc." && m_chipset.contains("SVGA3D")) {
m_driver = Driver_VMware;
}
}
// Properietary drivers
// ====================================================
else if (m_vendor == "ATI Technologies Inc.") {
m_chipClass = detectRadeonClass(m_renderer);
m_driver = Driver_Catalyst;
if (versionTokens.count() > 1 && versionTokens.at(2)[0] == '(')
m_driverVersion = parseVersionString(versionTokens.at(1));
else if (versionTokens.count() > 0)
m_driverVersion = parseVersionString(versionTokens.at(0));
else
m_driverVersion = 0;
}
else if (m_vendor == "NVIDIA Corporation") {
m_chipClass = detectNVidiaClass(m_renderer);
m_driver = Driver_NVidia;
int index = versionTokens.indexOf("NVIDIA");
if (versionTokens.count() > index)
m_driverVersion = parseVersionString(versionTokens.at(index + 1));
else
m_driverVersion = 0;
}
else if (m_renderer == "Software Rasterizer") {
m_driver = Driver_Swrast;
}
// Virtual Hardware
// ====================================================
else if (m_vendor == "Humper" && m_renderer == "Chromium") {
// Virtual Box
m_driver = Driver_VirtualBox;
const int index = versionTokens.indexOf("Chromium");
if (versionTokens.count() > index)
m_driverVersion = parseVersionString(versionTokens.at(index + 1));
else
m_driverVersion = 0;
}
// Driver/GPU specific features
// ====================================================
if (isRadeon()) {
// R200 technically has a programmable pipeline, but since it's SM 1.4,
// it's too limited to to be of any practical value to us.
if (m_chipClass < R300)
m_supportsGLSL = false;
m_limitedGLSL = false;
m_limitedNPOT = false;
if (m_chipClass < R600) {
if (driver() == Driver_Catalyst)
m_textureNPOT = m_limitedNPOT = false; // Software fallback
else if (driver() == Driver_R300G)
m_limitedNPOT = m_textureNPOT;
m_limitedGLSL = m_supportsGLSL;
}
if (m_chipClass < R300) {
// fallback to XRender for R100 and R200
m_recommendedCompositor = XRenderCompositing;
} else if (m_chipClass < R600) {
// XRender due to NPOT limitations not supported by KWin's shaders
m_recommendedCompositor = XRenderCompositing;
} else {
m_recommendedCompositor = OpenGL2Compositing;
}
if (driver() == Driver_R600G ||
(driver() == Driver_R600C && m_renderer.contains("DRI2"))) {
m_looseBinding = true;
}
}
if (isNvidia()) {
if (m_driver == Driver_NVidia && m_chipClass < NV40)
m_supportsGLSL = false; // High likelihood of software emulation
if (m_driver == Driver_NVidia) {
m_looseBinding = true;
m_preferBufferSubData = true;
}
if (m_chipClass < NV40) {
m_recommendedCompositor = XRenderCompositing;
} else {
m_recommendedCompositor = OpenGL2Compositing;
}
m_limitedNPOT = m_textureNPOT && m_chipClass < NV40;
m_limitedGLSL = m_supportsGLSL && m_chipClass < G80;
}
if (isIntel()) {
if (m_chipClass < I915)
m_supportsGLSL = false;
m_limitedGLSL = m_supportsGLSL && m_chipClass < I965;
// see https://bugs.freedesktop.org/show_bug.cgi?id=80349#c1
m_looseBinding = false;
if (m_chipClass < I915) {
m_recommendedCompositor = XRenderCompositing;
} else {
m_recommendedCompositor = OpenGL2Compositing;
}
}
if (isMesaDriver() && platformInterface == EglPlatformInterface) {
// According to the reference implementation in
// mesa/demos/src/egl/opengles1/texture_from_pixmap
// the mesa egl implementation does not require a strict binding (so far).
m_looseBinding = true;
}
if (isSoftwareEmulation()) {
if (m_driver < Driver_Llvmpipe) {
// we recommend XRender
m_recommendedCompositor = XRenderCompositing;
// Software emulation does not provide GLSL
m_limitedGLSL = m_supportsGLSL = false;
} else {
// llvmpipe does support GLSL
m_recommendedCompositor = OpenGL2Compositing;
m_limitedGLSL = false;
m_supportsGLSL = true;
}
}
if (m_chipClass == UnknownChipClass && m_driver == Driver_Unknown) {
// we don't know the hardware. Let's be optimistic and assume OpenGL compatible hardware
m_recommendedCompositor = OpenGL2Compositing;
m_supportsGLSL = true;
}
if (isVirtualBox()) {
m_virtualMachine = true;
m_recommendedCompositor = OpenGL2Compositing;
}
if (isVMware()) {
m_virtualMachine = true;
m_recommendedCompositor = OpenGL2Compositing;
}
// and force back to shader supported on gles, we wouldn't have got a context if not supported
if (isGLES()) {
m_supportsGLSL = true;
m_limitedGLSL = false;
}
}
HRESULT CaPerfDataWriter::setModulesPath()
{
HRESULT ret = S_OK;
char modules_path[OS_MAX_PATH];
getKernelVersion();
if (m_kVersion.empty())
{
return E_FAIL;
}
snprintf(modules_path, sizeof(modules_path), "%s/lib/modules/%s/kernel", m_rootDir.c_str(), m_kVersion.c_str());
m_kModulesPath = modules_path;
setModulesAbsolutePath(m_kModulesPath);
if (! m_kModuleNameMap.size())
{
return E_FAIL;
}
// Now iterate over the map and to m_kModuleAddrMap
for (kModuleNameMap::iterator it = m_kModuleNameMap.begin(), itEnd = m_kModuleNameMap.end(); it != itEnd; ++it)
{
m_kModuleAddrMap.insert(kModuleAddrMap::value_type(it->second.m_startAddress, it->second));
}
if (! m_kModuleAddrMap.size())
{
return E_FAIL;
}
// Now set the end address
kModuleAddrMap::iterator aiter = m_kModuleAddrMap.begin(), aiterEnd = m_kModuleAddrMap.end();
kModule* prev = &(aiter->second);
gtUInt64 endAddr = ~0ULL;
while (++aiter != aiterEnd)
{
kModule* curr = &(aiter->second);
endAddr = curr->m_startAddress - 1;
prev->setEndAddress(endAddr);
OS_OUTPUT_FORMAT_DEBUG_LOG(OS_DEBUG_LOG_EXTENSIVE, L"addr(0x%lx , 0x%lx)", prev->m_startAddress, prev->m_endAddress);
prev = curr;
}
// set endAddress for last entry
if (prev)
{
endAddr = ~0ULL;
prev->setEndAddress(endAddr);
}
return ret;
}
bool Configuration::getBootArguments() {
if (readArguments) return !isDisabled;
isDisabled = false;
char tmp[16];
isDisabled |= PE_parse_boot_argn(bootargOff, tmp, sizeof(tmp));
if (!PE_parse_boot_argn(bootargForce, tmp, sizeof(tmp))) {
isDisabled |= PE_parse_boot_argn("-s", tmp, sizeof(tmp));
isDisabled |= PE_parse_boot_argn("-x", tmp, sizeof(tmp));
if (!KernelPatcher::compatibleKernel(minKernel, maxKernel)) {
if (!PE_parse_boot_argn(bootargBeta, tmp, sizeof(tmp))) {
SYSLOG("config @ automatically disabling on an unsupported operating system");
isDisabled = true;
} else if (!isDisabled) {
SYSLOG("config @ force enabling on an unsupported operating system due to beta flag");
}
}
} else if (!isDisabled) {
SYSLOG("config @ force enabling due to force flag");
}
ADDPR(debugEnabled) = PE_parse_boot_argn(bootargDebug, tmp, sizeof(tmp));
allowDecompress = !PE_parse_boot_argn(bootargLowMem, tmp, sizeof(tmp));
installOrRecovery |= PE_parse_boot_argn("rp0", tmp, sizeof(tmp));
installOrRecovery |= PE_parse_boot_argn("rp", tmp, sizeof(tmp));
installOrRecovery |= PE_parse_boot_argn("container-dmg", tmp, sizeof(tmp));
installOrRecovery |= PE_parse_boot_argn("root-dmg", tmp, sizeof(tmp));
installOrRecovery |= PE_parse_boot_argn("auth-root-dmg", tmp, sizeof(tmp));
preferSlowMode = getKernelVersion() <= KernelVersion::Mavericks || installOrRecovery;
if (PE_parse_boot_argn(bootargSlow, tmp, sizeof(tmp))) {
preferSlowMode = true;
} else if (PE_parse_boot_argn(bootargFast, tmp, sizeof(tmp))) {
preferSlowMode = false;
}
if (!preferSlowMode && getKernelVersion() <= KernelVersion::Mavericks) {
// Since vm_shared_region_map_file interface is a little different
if (!isDisabled) SYSLOG("config @ enforcing -liluslow on Mavericks and lower");
preferSlowMode = true;
}
if (!preferSlowMode && installOrRecovery) {
// Since vdyld shared cache is not available
if (!isDisabled) SYSLOG("config @ enforcing -liluslow in installer or recovery");
preferSlowMode = true;
}
readArguments = true;
DBGLOG("config @ boot arguments disabled %d, debug %d, slow %d, decompress %d", isDisabled, ADDPR(debugEnabled), preferSlowMode, allowDecompress);
if (isDisabled) {
SYSLOG("init @ found a disabling argument or no arguments, exiting");
} else {
// Decide on booter
if (!preferSlowMode) {
policyOps.mpo_cred_check_label_update_execve = reinterpret_cast<mpo_cred_check_label_update_execve_t *>(policyCredCheckLabelUpdateExecve);
} else {
policyOps.mpo_mount_check_remount = policyCheckRemount;
}
}
return !isDisabled;
}
bool KernelPatcher::compatibleKernel(uint32_t min, uint32_t max) {
return (min == KernelAny || min <= getKernelVersion()) &&
(max == KernelAny || max >= getKernelVersion());
}
bool UserPatcher::hookMemoryAccess() {
// 10.12 and newer
mach_vm_address_t kern = patcher->solveSymbol(KernelPatcher::KernelID, "_cs_validate_range");
if (patcher->getError() == KernelPatcher::Error::NoError) {
orgCodeSignValidateRangeWrapper = reinterpret_cast<t_codeSignValidateRangeWrapper>(
patcher->routeFunction(kern, reinterpret_cast<mach_vm_address_t>(codeSignValidateRangeWrapper), true, true)
);
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to hook _cs_validate_range");
patcher->clearError();
return false;
}
} else if (static_cast<void>(patcher->clearError()),
static_cast<void>(kern = patcher->solveSymbol(KernelPatcher::KernelID, "_cs_validate_page")),
patcher->getError() == KernelPatcher::Error::NoError) {
orgCodeSignValidatePageWrapper = reinterpret_cast<t_codeSignValidatePageWrapper>(
patcher->routeFunction(kern, reinterpret_cast<mach_vm_address_t>(codeSignValidatePageWrapper), true, true)
);
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to hook _cs_validate_page");
patcher->clearError();
return false;
}
} else {
SYSLOG("user @ failed to resolve _cs_validate function");
patcher->clearError();
return false;
}
orgCurrentMap = reinterpret_cast<t_currentMap>(patcher->solveSymbol(KernelPatcher::KernelID, "_current_map"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _current_map");
patcher->clearError();
return false;
}
orgGetMapMin = reinterpret_cast<t_getMapMin>(patcher->solveSymbol(KernelPatcher::KernelID, "_get_map_min"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _get_map_min");
patcher->clearError();
return false;
}
orgGetTaskMap = reinterpret_cast<t_getTaskMap>(patcher->solveSymbol(KernelPatcher::KernelID, "_get_task_map"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _get_task_map");
patcher->clearError();
return false;
}
orgVmMapCheckProtection = reinterpret_cast<t_vmMapCheckProtection>(patcher->solveSymbol(KernelPatcher::KernelID, "_vm_map_check_protection"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _vm_map_check_protection");
patcher->clearError();
return false;
}
orgVmMapReadUser = reinterpret_cast<t_vmMapReadUser>(patcher->solveSymbol(KernelPatcher::KernelID, "_vm_map_read_user"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _vm_map_read_user");
patcher->clearError();
return false;
}
orgVmMapWriteUser = reinterpret_cast<t_vmMapWriteUser>(patcher->solveSymbol(KernelPatcher::KernelID, "_vm_map_write_user"));
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to resolve _vm_map_write_user");
patcher->clearError();
return false;
}
// On 10.12.1 b4 Apple decided not to let current_map point to the current process
// For this reason we have to obtain the map with the other methods
if (getKernelVersion() >= KernelVersion::Sierra) {
kern = patcher->solveSymbol(KernelPatcher::KernelID, "_proc_exec_switch_task");
if (patcher->getError() == KernelPatcher::Error::NoError) {
orgProcExecSwitchTask = reinterpret_cast<t_procExecSwitchTask>(
patcher->routeFunction(kern, reinterpret_cast<mach_vm_address_t>(procExecSwitchTask), true, true)
);
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to hook _proc_exec_switch_task");
patcher->clearError();
return false;
}
} else {
DBGLOG("user @ failed to resolve _proc_exec_switch_task");
patcher->clearError();
// This is not an error, early 10.12 versions have no such function
}
}
if (patchDyldSharedCache) {
kern = patcher->solveSymbol(KernelPatcher::KernelID, "_vm_shared_region_map_file");
if (patcher->getError() == KernelPatcher::Error::NoError) {
orgVmSharedRegionMapFile = reinterpret_cast<t_vmSharedRegionMapFile>(
patcher->routeFunction(kern, reinterpret_cast<mach_vm_address_t>(vmSharedRegionMapFile), true, true)
);
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to hook _vm_shared_region_map_file");
patcher->clearError();
return false;
}
} else {
SYSLOG("user @ failed to resolve _vm_shared_region_map_file");
patcher->clearError();
return false;
}
kern = patcher->solveSymbol(KernelPatcher::KernelID, "_vm_shared_region_slide");
if (patcher->getError() == KernelPatcher::Error::NoError) {
orgVmSharedRegionSlide = reinterpret_cast<t_vmSharedRegionSlide>(
patcher->routeFunction(kern, reinterpret_cast<mach_vm_address_t>(vmSharedRegionSlide), true, true)
);
if (patcher->getError() != KernelPatcher::Error::NoError) {
SYSLOG("user @ failed to hook _vm_shared_region_slide");
patcher->clearError();
return false;
}
} else {
SYSLOG("user @ failed to resolve _vm_shared_region_slide");
patcher->clearError();
return false;
}
}
return true;
}
