/* This file is part of solidity. solidity is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. solidity is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with solidity. If not, see . */ // SPDX-License-Identifier: GPL-3.0 #include #include #include #include using namespace std; using namespace solidity; using namespace solidity::smtutil; using namespace solidity::frontend::smt; BlockchainVariable::BlockchainVariable( string _name, map _members, EncodingContext& _context ): m_name(move(_name)), m_members(move(_members)), m_context(_context) { vector members; vector sorts; for (auto const& [component, sort]: m_members) { members.emplace_back(component); sorts.emplace_back(sort); m_componentIndices[component] = static_cast(members.size() - 1); } m_tuple = make_unique( make_shared(m_name + "_type", members, sorts), m_name, m_context ); } smtutil::Expression BlockchainVariable::member(string const& _member) const { return m_tuple->component(m_componentIndices.at(_member)); } smtutil::Expression BlockchainVariable::assignMember(string const& _member, smtutil::Expression const& _value) { vector args; for (auto const& m: m_members) if (m.first == _member) args.emplace_back(_value); else args.emplace_back(member(m.first)); m_tuple->increaseIndex(); auto tuple = m_tuple->currentValue(); auto sortExpr = smtutil::Expression(make_shared(tuple.sort), tuple.name); m_context.addAssertion(tuple == smtutil::Expression::tuple_constructor(sortExpr, args)); return m_tuple->currentValue(); } void SymbolicState::reset() { m_error.resetIndex(); m_thisAddress.resetIndex(); m_state.reset(); m_tx.reset(); m_crypto.reset(); if (m_abi) m_abi->reset(); } smtutil::Expression SymbolicState::balances() const { return m_state.member("balances"); } smtutil::Expression SymbolicState::balance() const { return balance(thisAddress()); } smtutil::Expression SymbolicState::balance(smtutil::Expression _address) const { return smtutil::Expression::select(balances(), move(_address)); } smtutil::Expression SymbolicState::blockhash(smtutil::Expression _blockNumber) const { return smtutil::Expression::select(m_tx.member("blockhash"), move(_blockNumber)); } void SymbolicState::newBalances() { auto tupleSort = dynamic_pointer_cast(stateSort()); auto balanceSort = tupleSort->components.at(tupleSort->memberToIndex.at("balances")); SymbolicVariable newBalances(balanceSort, "fresh_balances_" + to_string(m_context.newUniqueId()), m_context); m_state.assignMember("balances", newBalances.currentValue()); } void SymbolicState::transfer(smtutil::Expression _from, smtutil::Expression _to, smtutil::Expression _value) { unsigned indexBefore = m_state.index(); addBalance(_from, 0 - _value); addBalance(_to, move(_value)); unsigned indexAfter = m_state.index(); solAssert(indexAfter > indexBefore, ""); m_state.newVar(); /// Do not apply the transfer operation if _from == _to. auto newState = smtutil::Expression::ite( move(_from) == move(_to), m_state.value(indexBefore), m_state.value(indexAfter) ); m_context.addAssertion(m_state.value() == newState); } void SymbolicState::addBalance(smtutil::Expression _address, smtutil::Expression _value) { auto newBalances = smtutil::Expression::store( balances(), _address, balance(_address) + move(_value) ); m_state.assignMember("balances", newBalances); } smtutil::Expression SymbolicState::txMember(string const& _member) const { return m_tx.member(_member); } smtutil::Expression SymbolicState::txTypeConstraints() const { return smt::symbolicUnknownConstraints(m_tx.member("block.basefee"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("block.chainid"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("block.coinbase"), TypeProvider::address()) && smt::symbolicUnknownConstraints(m_tx.member("block.difficulty"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("block.gaslimit"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("block.number"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("block.timestamp"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("msg.sender"), TypeProvider::address()) && smt::symbolicUnknownConstraints(m_tx.member("msg.value"), TypeProvider::uint256()) && smt::symbolicUnknownConstraints(m_tx.member("tx.origin"), TypeProvider::address()) && smt::symbolicUnknownConstraints(m_tx.member("tx.gasprice"), TypeProvider::uint256()); } smtutil::Expression SymbolicState::txNonPayableConstraint() const { return m_tx.member("msg.value") == 0; } smtutil::Expression SymbolicState::txFunctionConstraints(FunctionDefinition const& _function) const { smtutil::Expression conj = _function.isPayable() ? smtutil::Expression(true) : txNonPayableConstraint(); if (_function.isPartOfExternalInterface()) { auto sig = TypeProvider::function(_function)->externalIdentifier(); conj = conj && m_tx.member("msg.sig") == sig; auto b0 = sig >> (3 * 8); auto b1 = (sig & 0x00ff0000) >> (2 * 8); auto b2 = (sig & 0x0000ff00) >> (1 * 8); auto b3 = (sig & 0x000000ff); auto data = smtutil::Expression::tuple_get(m_tx.member("msg.data"), 0); conj = conj && smtutil::Expression::select(data, 0) == b0; conj = conj && smtutil::Expression::select(data, 1) == b1; conj = conj && smtutil::Expression::select(data, 2) == b2; conj = conj && smtutil::Expression::select(data, 3) == b3; auto length = smtutil::Expression::tuple_get(m_tx.member("msg.data"), 1); // TODO add ABI size of function input parameters here \/ conj = conj && length >= 4; } return conj; } void SymbolicState::prepareForSourceUnit(SourceUnit const& _source) { set abiCalls = SMTEncoder::collectABICalls(&_source); for (auto const& source: _source.referencedSourceUnits(true)) abiCalls += SMTEncoder::collectABICalls(source); buildABIFunctions(abiCalls); } /// Private helpers. void SymbolicState::buildABIFunctions(set const& _abiFunctions) { map functions; for (auto const* funCall: _abiFunctions) { auto t = dynamic_cast(funCall->expression().annotation().type); auto const& args = funCall->sortedArguments(); auto const& paramTypes = t->parameterTypes(); auto const& returnTypes = t->returnParameterTypes(); auto argTypes = [](auto const& _args) { return applyMap(_args, [](auto arg) { return arg->annotation().type; }); }; /// Since each abi.* function may have a different number of input/output parameters, /// we generically compute those types. vector inTypes; vector outTypes; if (t->kind() == FunctionType::Kind::ABIDecode) { /// abi.decode : (bytes, tuple_of_types(return_types)) -> (return_types) solAssert(args.size() == 2, "Unexpected number of arguments for abi.decode"); inTypes.emplace_back(TypeProvider::bytesMemory()); auto argType = args.at(1)->annotation().type; if (auto const* tupleType = dynamic_cast(argType)) for (auto componentType: tupleType->components()) { auto typeType = dynamic_cast(componentType); solAssert(typeType, ""); outTypes.emplace_back(typeType->actualType()); } else if (auto const* typeType = dynamic_cast(argType)) outTypes.emplace_back(typeType->actualType()); else solAssert(false, "Unexpected argument of abi.decode"); } else if (t->kind() == FunctionType::Kind::ABIEncodeCall) { // abi.encodeCall : (functionPointer, tuple_of_args_or_one_non_tuple_arg(arguments)) -> bytes solAssert(args.size() == 2, "Unexpected number of arguments for abi.encodeCall"); outTypes.emplace_back(TypeProvider::bytesMemory()); inTypes.emplace_back(args.at(0)->annotation().type); inTypes.emplace_back(args.at(1)->annotation().type); } else { outTypes = returnTypes; if ( t->kind() == FunctionType::Kind::ABIEncodeWithSelector || t->kind() == FunctionType::Kind::ABIEncodeWithSignature ) { /// abi.encodeWithSelector : (bytes4, one_or_more_types) -> bytes /// abi.encodeWithSignature : (string, one_or_more_types) -> bytes inTypes.emplace_back(paramTypes.front()); inTypes += argTypes(vector>(args.begin() + 1, args.end())); } else { /// abi.encode/abi.encodePacked : one_or_more_types -> bytes solAssert( t->kind() == FunctionType::Kind::ABIEncode || t->kind() == FunctionType::Kind::ABIEncodePacked, "" ); inTypes = argTypes(args); } } /// Rational numbers and string literals add the concrete values to the type name, /// so we replace them by uint256 and bytes since those are the same as their SMT types. /// TODO we could also replace all types by their ABI type. auto replaceTypes = [](auto& _types) { for (auto& t: _types) if (t->category() == frontend::Type::Category::RationalNumber) t = TypeProvider::uint256(); else if (t->category() == frontend::Type::Category::StringLiteral) t = TypeProvider::bytesMemory(); else if (auto userType = dynamic_cast(t)) t = &userType->underlyingType(); }; replaceTypes(inTypes); replaceTypes(outTypes); auto name = t->richIdentifier(); for (auto paramType: inTypes + outTypes) name += "_" + paramType->richIdentifier(); m_abiMembers[funCall] = {name, inTypes, outTypes}; if (functions.count(name)) continue; /// If there is only one input or output parameter, we use that type directly. /// Otherwise we create a tuple wrapping the necessary input or output types. auto typesToSort = [](auto const& _types, string const& _name) -> shared_ptr { if (_types.size() == 1) return smtSortAbstractFunction(*_types.front()); vector inNames; vector sorts; for (unsigned i = 0; i < _types.size(); ++i) { inNames.emplace_back(_name + "_input_" + to_string(i)); sorts.emplace_back(smtSortAbstractFunction(*_types.at(i))); } return make_shared( _name + "_input", inNames, sorts ); }; auto functionSort = make_shared( typesToSort(inTypes, name), typesToSort(outTypes, name) ); functions[name] = functionSort; } m_abi = make_unique("abi", move(functions), m_context); } smtutil::Expression SymbolicState::abiFunction(frontend::FunctionCall const* _funCall) { solAssert(m_abi, ""); return m_abi->member(get<0>(m_abiMembers.at(_funCall))); } SymbolicState::SymbolicABIFunction const& SymbolicState::abiFunctionTypes(FunctionCall const* _funCall) const { return m_abiMembers.at(_funCall); }