#include nx::NpdmHeader::NpdmHeader() { clear(); } nx::NpdmHeader::NpdmHeader(const NpdmHeader & other) { *this = other; } void nx::NpdmHeader::operator=(const NpdmHeader & other) { if (other.getBytes().size()) { fromBytes(other.getBytes().data(), other.getBytes().size()); } else { clear(); mInstructionType = other.mInstructionType; mProcAddressSpaceType = other.mProcAddressSpaceType; mMainThreadPriority = other.mMainThreadPriority; mMainThreadCpuId = other.mMainThreadCpuId; mVersion = other.mVersion; mMainThreadStackSize = other.mMainThreadStackSize; mName = other.mName; mProductCode = other.mProductCode; mAciPos = other.mAciPos; mAcidPos = other.mAcidPos; } } bool nx::NpdmHeader::operator==(const NpdmHeader & other) const { return (mInstructionType == other.mInstructionType) \ && (mProcAddressSpaceType == other.mProcAddressSpaceType) \ && (mMainThreadPriority == other.mMainThreadPriority) \ && (mMainThreadCpuId == other.mMainThreadCpuId) \ && (mVersion == other.mVersion) \ && (mMainThreadStackSize == other.mMainThreadStackSize) \ && (mName == other.mName) \ && (mProductCode == other.mProductCode) \ && (mAciPos == other.mAciPos) \ && (mAcidPos == other.mAcidPos); } bool nx::NpdmHeader::operator!=(const NpdmHeader & other) const { return !(*this == other); } void nx::NpdmHeader::toBytes() { mRawBinary.alloc(sizeof(sNpdmHeader)); sNpdmHeader* hdr = (sNpdmHeader*)mRawBinary.data(); hdr->st_magic = npdm::kNpdmStructMagic; byte_t flag = ((byte_t)(mInstructionType & 1) | (byte_t)((mProcAddressSpaceType & 3) << 1)) & 0xf; hdr->flags = flag; hdr->main_thread_priority = mMainThreadPriority; hdr->main_thread_cpu_id = mMainThreadCpuId; hdr->version = mVersion; hdr->main_thread_stack_size = mMainThreadStackSize; strncpy(hdr->name, mName.c_str(), npdm::kNameMaxLen); strncpy(hdr->product_code, mProductCode.c_str(), npdm::kProductCodeMaxLen); calculateOffsets(); hdr->aci.offset = (uint32_t)mAciPos.offset; hdr->aci.size = (uint32_t)mAciPos.size; hdr->acid.offset = (uint32_t)mAcidPos.offset; hdr->acid.size = (uint32_t)mAcidPos.size; } void nx::NpdmHeader::fromBytes(const byte_t* data, size_t len) { if (len < sizeof(sNpdmHeader)) { throw fnd::Exception(kModuleName, "NPDM header too small"); } // clear internal members clear(); mRawBinary.alloc(sizeof(sNpdmHeader)); memcpy(mRawBinary.data(), data, mRawBinary.size()); sNpdmHeader* hdr = (sNpdmHeader*)mRawBinary.data(); if (hdr->st_magic.get() != npdm::kNpdmStructMagic) { throw fnd::Exception(kModuleName, "NPDM header corrupt"); } byte_t flag = hdr->flags & 0xf; mInstructionType = (npdm::InstructionType)(flag & 1); mProcAddressSpaceType = (npdm::ProcAddrSpaceType)((flag >> 1) & 3); mMainThreadPriority = hdr->main_thread_priority; mMainThreadCpuId = hdr->main_thread_cpu_id; mVersion = hdr->version.get(); mMainThreadStackSize = hdr->main_thread_stack_size.get(); mName = std::string(hdr->name, npdm::kNameMaxLen); if (mName[0] == '\0') { mName.clear(); } mProductCode = std::string(hdr->product_code, npdm::kProductCodeMaxLen); if (mProductCode[0] == '\0') { mProductCode.clear(); } mAciPos.offset = hdr->aci.offset.get(); mAciPos.size = hdr->aci.size.get(); mAcidPos.offset = hdr->acid.offset.get(); mAcidPos.size = hdr->acid.size.get(); } const fnd::Vec& nx::NpdmHeader::getBytes() const { return mRawBinary; } void nx::NpdmHeader::clear() { mRawBinary.clear(); mInstructionType = npdm::INSTR_64BIT; mProcAddressSpaceType = npdm::ADDR_SPACE_64BIT; mMainThreadPriority = 0; mMainThreadCpuId = 0; mVersion = 0; mMainThreadStackSize = 0; mName.clear(); mProductCode.clear(); mAciPos.offset = 0; mAciPos.size = 0; mAcidPos.offset = 0; mAcidPos.size = 0; } size_t nx::NpdmHeader::getNpdmSize() const { return _MAX(mAcidPos.offset + mAcidPos.size, mAciPos.offset + mAciPos.size); } nx::npdm::InstructionType nx::NpdmHeader::getInstructionType() const { return mInstructionType; } void nx::NpdmHeader::setInstructionType(npdm::InstructionType type) { mInstructionType = type; } nx::npdm::ProcAddrSpaceType nx::NpdmHeader::getProcAddressSpaceType() const { return mProcAddressSpaceType; } void nx::NpdmHeader::setProcAddressSpaceType(npdm::ProcAddrSpaceType type) { mProcAddressSpaceType = type; } byte_t nx::NpdmHeader::getMainThreadPriority() const { return mMainThreadPriority; } void nx::NpdmHeader::setMainThreadPriority(byte_t priority) { if (priority > npdm::kMaxPriority) { throw fnd::Exception(kModuleName, "Illegal main thread priority (range 0-63)"); } mMainThreadPriority = priority; } byte_t nx::NpdmHeader::getMainThreadCpuId() const { return mMainThreadCpuId; } void nx::NpdmHeader::setMainThreadCpuId(byte_t core_num) { mMainThreadCpuId = core_num; } uint32_t nx::NpdmHeader::getVersion() const { return mVersion; } void nx::NpdmHeader::setVersion(uint32_t version) { mVersion = version; } uint32_t nx::NpdmHeader::getMainThreadStackSize() const { return mMainThreadStackSize; } void nx::NpdmHeader::setMainThreadStackSize(uint32_t size) { mMainThreadStackSize = size; } const std::string & nx::NpdmHeader::getName() const { return mName; } void nx::NpdmHeader::setName(const std::string & name) { if (name.length() > npdm::kNameMaxLen) { throw fnd::Exception(kModuleName, "Name is too long"); } mName = name; } const std::string & nx::NpdmHeader::getProductCode() const { return mProductCode; } void nx::NpdmHeader::setProductCode(const std::string & product_code) { if (product_code.length() > npdm::kProductCodeMaxLen) { throw fnd::Exception(kModuleName, "Product Code is too long"); } mProductCode = product_code; } const nx::NpdmHeader::sSection & nx::NpdmHeader::getAciPos() const { return mAciPos; } void nx::NpdmHeader::setAciSize(size_t size) { mAciPos.size = size; } const nx::NpdmHeader::sSection & nx::NpdmHeader::getAcidPos() const { return mAcidPos; } void nx::NpdmHeader::setAcidSize(size_t size) { mAcidPos.size = size; } void nx::NpdmHeader::calculateOffsets() { mAcidPos.offset = align(sizeof(sNpdmHeader), npdm::kNpdmAlignSize); mAciPos.offset = mAcidPos.offset + align(mAcidPos.size, npdm::kNpdmAlignSize); }