#include namespace vm { namespace instrs { std::pair< std::uint64_t, std::uint64_t > decrypt_operand( transform::map_t &transforms, std::uint64_t operand, std::uint64_t rolling_key ) { const auto &generic_decrypt_0 = transforms[ transform::type::generic0 ]; const auto &key_decrypt = transforms[ transform::type::rolling_key ]; const auto &generic_decrypt_1 = transforms[ transform::type::generic1 ]; const auto &generic_decrypt_2 = transforms[ transform::type::generic2 ]; const auto &generic_decrypt_3 = transforms[ transform::type::generic3 ]; const auto &update_key = transforms[ transform::type::update_key ]; if ( generic_decrypt_0.mnemonic != ZYDIS_MNEMONIC_INVALID ) { operand = transform::apply( generic_decrypt_0.operands[ 0 ].size, generic_decrypt_0.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_0 ) ? generic_decrypt_0.operands[ 1 ].imm.value.u : 0 ); } // apply transformation with rolling decrypt key... operand = transform::apply( key_decrypt.operands[ 0 ].size, key_decrypt.mnemonic, operand, rolling_key ); // apply three generic transformations... { operand = transform::apply( generic_decrypt_1.operands[ 0 ].size, generic_decrypt_1.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_1 ) ? generic_decrypt_1.operands[ 1 ].imm.value.u : 0 ); operand = transform::apply( generic_decrypt_2.operands[ 0 ].size, generic_decrypt_2.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_2 ) ? generic_decrypt_2.operands[ 1 ].imm.value.u : 0 ); operand = transform::apply( generic_decrypt_3.operands[ 0 ].size, generic_decrypt_3.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_3 ) ? generic_decrypt_3.operands[ 1 ].imm.value.u : 0 ); } // update rolling key... auto result = transform::apply( update_key.operands[ 0 ].size, update_key.mnemonic, rolling_key, operand ); // update decryption key correctly... switch ( update_key.operands[ 0 ].size ) { case 8: rolling_key = ( rolling_key & ~0xFFull ) + result; break; case 16: rolling_key = ( rolling_key & ~0xFFFFull ) + result; break; default: rolling_key = result; break; } return { operand, rolling_key }; } std::pair< std::uint64_t, std::uint64_t > encrypt_operand( transform::map_t &transforms, std::uint64_t operand, std::uint64_t rolling_key ) { transform::map_t inverse; inverse_transforms( transforms, inverse ); const auto &generic_decrypt_0 = inverse[ transform::type::generic0 ]; const auto &key_decrypt = inverse[ transform::type::rolling_key ]; const auto &generic_decrypt_1 = inverse[ transform::type::generic1 ]; const auto &generic_decrypt_2 = inverse[ transform::type::generic2 ]; const auto &generic_decrypt_3 = inverse[ transform::type::generic3 ]; const auto &update_key = inverse[ transform::type::update_key ]; auto result = transform::apply( update_key.operands[ 0 ].size, update_key.mnemonic, rolling_key, operand ); // make sure we update the rolling decryption key correctly... switch ( update_key.operands[ 0 ].size ) { case 8: rolling_key = ( rolling_key & ~0xFFull ) + result; break; case 16: rolling_key = ( rolling_key & ~0xFFFFull ) + result; break; default: rolling_key = result; break; } { operand = transform::apply( generic_decrypt_3.operands[ 0 ].size, generic_decrypt_3.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_3 ) ? generic_decrypt_3.operands[ 1 ].imm.value.u : 0 ); operand = transform::apply( generic_decrypt_2.operands[ 0 ].size, generic_decrypt_2.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_2 ) ? generic_decrypt_2.operands[ 1 ].imm.value.u : 0 ); operand = transform::apply( generic_decrypt_1.operands[ 0 ].size, generic_decrypt_1.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_1 ) ? generic_decrypt_1.operands[ 1 ].imm.value.u : 0 ); } operand = transform::apply( key_decrypt.operands[ 0 ].size, key_decrypt.mnemonic, operand, rolling_key ); if ( generic_decrypt_0.mnemonic != ZYDIS_MNEMONIC_INVALID ) { operand = transform::apply( generic_decrypt_0.operands[ 0 ].size, generic_decrypt_0.mnemonic, operand, // check to see if this instruction has an IMM... transform::has_imm( &generic_decrypt_0 ) ? generic_decrypt_0.operands[ 1 ].imm.value.u : 0 ); } return { operand, rolling_key }; } bool get_rva_decrypt( const zydis_routine_t &vm_entry, std::vector< zydis_decoded_instr_t > &transform_instrs ) { // // find mov esi, [rsp+0xA0] // auto result = std::find_if( vm_entry.begin(), vm_entry.end(), []( const zydis_instr_t &instr_data ) -> bool { if ( instr_data.instr.mnemonic == ZYDIS_MNEMONIC_MOV && instr_data.instr.operand_count == 2 && instr_data.instr.operands[ 0 ].reg.value == ZYDIS_REGISTER_ESI && instr_data.instr.operands[ 1 ].mem.base == ZYDIS_REGISTER_RSP && instr_data.instr.operands[ 1 ].mem.disp.has_displacement && instr_data.instr.operands[ 1 ].mem.disp.value == 0xA0 ) return true; return false; } ); if ( result == vm_entry.end() ) return false; // // find the next three instruction with ESI as the dest... // for ( auto idx = 0u; idx < 3; ++idx ) { result = std::find_if( ++result, vm_entry.end(), []( const zydis_instr_t &instr_data ) -> bool { return instr_data.instr.operands[ 0 ].reg.value == ZYDIS_REGISTER_ESI; } ); if ( result == vm_entry.end() ) return false; transform_instrs.push_back( result->instr ); } return true; } std::optional< std::uint64_t > get_imm( vm::ctx_t &ctx, std::uint8_t imm_size, std::uintptr_t vip ) { if ( !imm_size ) return {}; return ctx.exec_type == vmp2::exec_type_t::forward ? *reinterpret_cast< std::uintptr_t * >( vip + ( imm_size / 8 ) ) : *reinterpret_cast< std::uintptr_t * >( vip - ( imm_size / 8 ) ); } std::optional< virt_instr_t > get( vm::ctx_t &ctx, vmp2::v2::entry_t &entry ) { virt_instr_t result; const auto &vm_handler = ctx.vm_handlers[ entry.handler_idx ]; const auto profile = vm_handler.profile; result.mnemonic_t = profile ? profile->mnemonic : vm::handler::mnemonic_t::INVALID; result.opcode = entry.handler_idx; result.trace_data = entry; if ( vm_handler.imm_size ) { result.operand.has_imm = true; const auto imm_val = get_imm( ctx, vm_handler.imm_size, entry.vip ); if ( !imm_val.has_value() ) return {}; result.operand.imm.u = imm_val.value(); } else result.operand.has_imm = false; return result; } } // namespace instrs } // namespace vm