#include nn::hac::KernelCapabilityBinary::KernelCapabilityBinary() {} nn::hac::KernelCapabilityBinary::KernelCapabilityBinary(const KernelCapabilityBinary & other) { *this = other; } void nn::hac::KernelCapabilityBinary::operator=(const KernelCapabilityBinary & other) { clear(); mThreadInfo = other.mThreadInfo; mSystemCalls = other.mSystemCalls; mMemoryMap = other.mMemoryMap; mInterupts = other.mInterupts; mMiscParams = other.mMiscParams; mKernelVersion = other.mKernelVersion; mHandleTableSize = other.mHandleTableSize; mMiscFlags = other.mMiscFlags; } bool nn::hac::KernelCapabilityBinary::operator==(const KernelCapabilityBinary & other) const { return (mThreadInfo == other.mThreadInfo) \ && (mSystemCalls == other.mSystemCalls) \ && (mMemoryMap == other.mMemoryMap) \ && (mInterupts == other.mInterupts) \ && (mMiscParams == other.mMiscParams) \ && (mKernelVersion == other.mKernelVersion) \ && (mHandleTableSize == other.mHandleTableSize) \ && (mMiscFlags == other.mMiscFlags); } bool nn::hac::KernelCapabilityBinary::operator!=(const KernelCapabilityBinary & other) const { return !(*this == other); } void nn::hac::KernelCapabilityBinary::toBytes() { fnd::List caps; // get kernel capabiliteis mThreadInfo.exportKernelCapabilityList(caps); mSystemCalls.exportKernelCapabilityList(caps); mMemoryMap.exportKernelCapabilityList(caps); mInterupts.exportKernelCapabilityList(caps); mMiscParams.exportKernelCapabilityList(caps); mKernelVersion.exportKernelCapabilityList(caps); mHandleTableSize.exportKernelCapabilityList(caps); mMiscFlags.exportKernelCapabilityList(caps); // allocate memory mRawBinary.alloc(caps.size() * sizeof(uint32_t)); // write to binary uint32_t* raw_caps = (uint32_t*)mRawBinary.data(); for (size_t i = 0; i < caps.size(); i++) { raw_caps[i] = le_word(caps[i].getCap()); } } void nn::hac::KernelCapabilityBinary::fromBytes(const byte_t * data, size_t len) { if ((len % sizeof(uint32_t)) != 0) { throw fnd::Exception(kModuleName, "KernelCapabilityEntry list must be aligned to 4 bytes"); } // save copy of KernelCapabilityBinary mRawBinary.alloc(len); memcpy(mRawBinary.data(), data, len); fnd::List threadInfoCaps; fnd::List systemCallCaps; fnd::List memoryMapCaps; fnd::List interuptCaps; fnd::List miscParamCaps; fnd::List kernelVersionCaps; fnd::List handleTableSizeCaps; fnd::List miscFlagsCaps; const uint32_t* raw_caps = (const uint32_t*)mRawBinary.data(); size_t cap_num = mRawBinary.size() / sizeof(uint32_t); KernelCapabilityEntry cap; for (size_t i = 0; i < cap_num; i++) { cap.setCap(le_word(raw_caps[i])); switch (cap.getType()) { case (kc::KC_THREAD_INFO) : threadInfoCaps.addElement(cap); break; case (kc::KC_ENABLE_SYSTEM_CALLS): systemCallCaps.addElement(cap); break; case (kc::KC_MEMORY_MAP): case (kc::KC_IO_MEMORY_MAP): memoryMapCaps.addElement(cap); break; case (kc::KC_ENABLE_INTERUPTS): interuptCaps.addElement(cap); break; case (kc::KC_MISC_PARAMS): miscParamCaps.addElement(cap); break; case (kc::KC_KERNEL_VERSION): kernelVersionCaps.addElement(cap); break; case (kc::KC_HANDLE_TABLE_SIZE): handleTableSizeCaps.addElement(cap); break; case (kc::KC_MISC_FLAGS): miscFlagsCaps.addElement(cap); break; default: throw fnd::Exception(kModuleName, "Unsupported kernel capability type"); } } mThreadInfo.importKernelCapabilityList(threadInfoCaps); mSystemCalls.importKernelCapabilityList(systemCallCaps); mMemoryMap.importKernelCapabilityList(memoryMapCaps); mInterupts.importKernelCapabilityList(interuptCaps); mMiscParams.importKernelCapabilityList(miscParamCaps); mKernelVersion.importKernelCapabilityList(kernelVersionCaps); mHandleTableSize.importKernelCapabilityList(handleTableSizeCaps); mMiscFlags.importKernelCapabilityList(miscFlagsCaps); } const fnd::Vec& nn::hac::KernelCapabilityBinary::getBytes() const { return mRawBinary; } void nn::hac::KernelCapabilityBinary::clear() { mRawBinary.clear(); mThreadInfo.clear(); mSystemCalls.clear(); mMemoryMap.clear(); mInterupts.clear(); mMiscParams.clear(); mKernelVersion.clear(); mHandleTableSize.clear(); mMiscFlags.clear(); } const nn::hac::ThreadInfoHandler & nn::hac::KernelCapabilityBinary::getThreadInfo() const { return mThreadInfo; } nn::hac::ThreadInfoHandler & nn::hac::KernelCapabilityBinary::getThreadInfo() { return mThreadInfo; } const nn::hac::SystemCallHandler & nn::hac::KernelCapabilityBinary::getSystemCalls() const { return mSystemCalls; } nn::hac::SystemCallHandler & nn::hac::KernelCapabilityBinary::getSystemCalls() { return mSystemCalls; } const nn::hac::MemoryMappingHandler & nn::hac::KernelCapabilityBinary::getMemoryMaps() const { return mMemoryMap; } nn::hac::MemoryMappingHandler & nn::hac::KernelCapabilityBinary::getMemoryMaps() { return mMemoryMap; } const nn::hac::InteruptHandler & nn::hac::KernelCapabilityBinary::getInterupts() const { return mInterupts; } nn::hac::InteruptHandler & nn::hac::KernelCapabilityBinary::getInterupts() { return mInterupts; } const nn::hac::MiscParamsHandler & nn::hac::KernelCapabilityBinary::getMiscParams() const { return mMiscParams; } nn::hac::MiscParamsHandler & nn::hac::KernelCapabilityBinary::getMiscParams() { return mMiscParams; } const nn::hac::KernelVersionHandler & nn::hac::KernelCapabilityBinary::getKernelVersion() const { return mKernelVersion; } nn::hac::KernelVersionHandler & nn::hac::KernelCapabilityBinary::getKernelVersion() { return mKernelVersion; } const nn::hac::HandleTableSizeHandler & nn::hac::KernelCapabilityBinary::getHandleTableSize() const { return mHandleTableSize; } nn::hac::HandleTableSizeHandler & nn::hac::KernelCapabilityBinary::getHandleTableSize() { return mHandleTableSize; } const nn::hac::MiscFlagsHandler & nn::hac::KernelCapabilityBinary::getMiscFlags() const { return mMiscFlags; } nn::hac::MiscFlagsHandler & nn::hac::KernelCapabilityBinary::getMiscFlags() { return mMiscFlags; }