int main() { const RegisterDictionary *regdict = RegisterDictionary::dictionary_i386(); SymbolicSemantics::RiscOperatorsPtr ops = SymbolicSemantics::RiscOperators::instance(regdict); RegisterStateGenericPtr rstate = RegisterStateGeneric::promote(ops->get_state()->get_register_state()); SValuePtr x; Formatter fmt; fmt.set_line_prefix(" "); // Write all 32 bits of a register std::cout <<"write reg@0+32\n"; RegisterDescriptor r_0_32(x86_regclass_gpr, 0, 0, 32); rstate->writeRegister(r_0_32, ops->undefined_(32), ops.get()); rstate->print(std::cout, fmt); // Write low-order 16 bits of a register std::cout <<"\nwrite reg@0+16\n"; RegisterDescriptor r_0_16(x86_regclass_gpr, 0, 0, 16); rstate->writeRegister(r_0_16, ops->undefined_(16), ops.get()); rstate->print(std::cout, fmt); // Read bits 8-31. Bits [8-15] are from one register and [16-31] are from another std::cout <<"\nread reg@8+24\n"; RegisterDescriptor r_8_24(x86_regclass_gpr, 0, 8, 24); x = rstate->readRegister(r_8_24, ops.get()); std::cout <<" got " <<*x <<"\n"; rstate->print(std::cout, fmt); }
NoOperation::NoOperation(Disassembler *disassembler) { normalizer_ = StateNormalizer::instance(); if (disassembler) { const RegisterDictionary *registerDictionary = disassembler->get_registers(); ASSERT_not_null(registerDictionary); size_t addrWidth = disassembler->instructionPointerRegister().get_nbits(); SMTSolver *solver = NULL; SymbolicSemantics::RiscOperatorsPtr ops = SymbolicSemantics::RiscOperators::instance(registerDictionary, solver); ops->computingDefiners(SymbolicSemantics::TRACK_NO_DEFINERS); ops->computingMemoryWriters(SymbolicSemantics::TRACK_LATEST_WRITER); // necessary to erase non-written memory BaseSemantics::MemoryCellListPtr mstate = BaseSemantics::MemoryCellList::promote(ops->get_state()->get_memory_state()); ASSERT_not_null(mstate); mstate->occlusionsErased(true); cpu_ = disassembler->dispatcher()->create(ops, addrWidth, registerDictionary); } }